From 58daab21cd043e1dc37024a7f99b396788372918 Mon Sep 17 00:00:00 2001 From: Daniel Baumann Date: Sat, 9 Mar 2024 14:19:48 +0100 Subject: Merging upstream version 1.44.3. Signed-off-by: Daniel Baumann --- fluent-bit/lib/luajit-3065c9/src/.gitignore | 7 + fluent-bit/lib/luajit-3065c9/src/Makefile | 726 ++ fluent-bit/lib/luajit-3065c9/src/Makefile.dep | 259 + fluent-bit/lib/luajit-3065c9/src/host/.gitignore | 3 + fluent-bit/lib/luajit-3065c9/src/host/README | 4 + fluent-bit/lib/luajit-3065c9/src/host/buildvm.c | 528 ++ fluent-bit/lib/luajit-3065c9/src/host/buildvm.h | 105 + .../lib/luajit-3065c9/src/host/buildvm_asm.c | 348 + .../lib/luajit-3065c9/src/host/buildvm_fold.c | 236 + .../lib/luajit-3065c9/src/host/buildvm_lib.c | 459 ++ .../lib/luajit-3065c9/src/host/buildvm_libbc.h | 81 + .../lib/luajit-3065c9/src/host/buildvm_peobj.c | 379 + fluent-bit/lib/luajit-3065c9/src/host/genlibbc.lua | 225 + .../lib/luajit-3065c9/src/host/genminilua.lua | 436 ++ fluent-bit/lib/luajit-3065c9/src/host/minilua.c | 7771 ++++++++++++++++++++ fluent-bit/lib/luajit-3065c9/src/jit/.gitignore | 1 + fluent-bit/lib/luajit-3065c9/src/jit/bc.lua | 190 + 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+ fluent-bit/lib/luajit-3065c9/src/lj_dispatch.c | 559 ++ fluent-bit/lib/luajit-3065c9/src/lj_dispatch.h | 164 + fluent-bit/lib/luajit-3065c9/src/lj_emit_arm.h | 361 + fluent-bit/lib/luajit-3065c9/src/lj_emit_arm64.h | 424 ++ fluent-bit/lib/luajit-3065c9/src/lj_emit_mips.h | 310 + fluent-bit/lib/luajit-3065c9/src/lj_emit_ppc.h | 238 + fluent-bit/lib/luajit-3065c9/src/lj_emit_x86.h | 572 ++ fluent-bit/lib/luajit-3065c9/src/lj_err.c | 1097 +++ fluent-bit/lib/luajit-3065c9/src/lj_err.h | 58 + fluent-bit/lib/luajit-3065c9/src/lj_errmsg.h | 200 + fluent-bit/lib/luajit-3065c9/src/lj_ff.h | 18 + fluent-bit/lib/luajit-3065c9/src/lj_ffrecord.c | 1574 ++++ fluent-bit/lib/luajit-3065c9/src/lj_ffrecord.h | 24 + fluent-bit/lib/luajit-3065c9/src/lj_frame.h | 297 + fluent-bit/lib/luajit-3065c9/src/lj_func.c | 191 + fluent-bit/lib/luajit-3065c9/src/lj_func.h | 24 + fluent-bit/lib/luajit-3065c9/src/lj_gc.c | 906 +++ fluent-bit/lib/luajit-3065c9/src/lj_gc.h | 136 + 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create mode 100644 fluent-bit/lib/luajit-3065c9/src/vm_x64.dasc create mode 100644 fluent-bit/lib/luajit-3065c9/src/vm_x86.dasc create mode 100644 fluent-bit/lib/luajit-3065c9/src/xb1build.bat create mode 100644 fluent-bit/lib/luajit-3065c9/src/xedkbuild.bat (limited to 'fluent-bit/lib/luajit-3065c9/src') diff --git a/fluent-bit/lib/luajit-3065c9/src/.gitignore b/fluent-bit/lib/luajit-3065c9/src/.gitignore new file mode 100644 index 00000000..1a30573c --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/.gitignore @@ -0,0 +1,7 @@ +luajit +lj_bcdef.h +lj_ffdef.h +lj_libdef.h +lj_recdef.h +lj_folddef.h +lj_vm.[sS] diff --git a/fluent-bit/lib/luajit-3065c9/src/Makefile b/fluent-bit/lib/luajit-3065c9/src/Makefile new file mode 100644 index 00000000..30d64be2 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/Makefile @@ -0,0 +1,726 @@ +############################################################################## +# LuaJIT Makefile. Requires GNU Make. +# +# Please read doc/install.html before changing any variables! +# +# Suitable for POSIX platforms (Linux, *BSD, OSX etc.). +# Also works with MinGW and Cygwin on Windows. +# Please check msvcbuild.bat for building with MSVC on Windows. +# +# Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +############################################################################## + +MAJVER= 2 +MINVER= 1 +RELVER= 0 +ABIVER= 5.1 +NODOTABIVER= 51 + +############################################################################## +############################# COMPILER OPTIONS ############################# +############################################################################## +# These options mainly affect the speed of the JIT compiler itself, not the +# speed of the JIT-compiled code. Turn any of the optional settings on by +# removing the '#' in front of them. Make sure you force a full recompile +# with "make clean", followed by "make" if you change any options. +# +DEFAULT_CC = gcc +# +# LuaJIT builds as a native 32 or 64 bit binary by default. +CC= $(DEFAULT_CC) +# +# Use this if you want to force a 32 bit build on a 64 bit multilib OS. +#CC= $(DEFAULT_CC) -m32 +# +# Since the assembler part does NOT maintain a frame pointer, it's pointless +# to slow down the C part by not omitting it. Debugging, tracebacks and +# unwinding are not affected -- the assembler part has frame unwind +# information and GCC emits it where needed (x64) or with -g (see CCDEBUG). +CCOPT= -O2 -fomit-frame-pointer +# Use this if you want to generate a smaller binary (but it's slower): +#CCOPT= -Os -fomit-frame-pointer +# Note: it's no longer recommended to use -O3 with GCC 4.x. +# The I-Cache bloat usually outweighs the benefits from aggressive inlining. +# +# Target-specific compiler options: +# +# x86/x64 only: For GCC 4.2 or higher and if you don't intend to distribute +# the binaries to a different machine you could also use: -march=native +# +CCOPT_x86= -march=i686 -msse -msse2 -mfpmath=sse +CCOPT_x64= +CCOPT_arm= +CCOPT_arm64= +CCOPT_ppc= +CCOPT_mips= +# +CCDEBUG= +# Uncomment the next line to generate debug information: +#CCDEBUG= -g +# +CCWARN= -Wall +# Uncomment the next line to enable more warnings: +#CCWARN+= -Wextra -Wdeclaration-after-statement -Wredundant-decls -Wshadow -Wpointer-arith +# +############################################################################## + +############################################################################## +################################ BUILD MODE ################################ +############################################################################## +# The default build mode is mixed mode on POSIX. On Windows this is the same +# as dynamic mode. +# +# Mixed mode creates a static + dynamic library and a statically linked luajit. +BUILDMODE= mixed +# +# Static mode creates a static library and a statically linked luajit. +#BUILDMODE= static +# +# Dynamic mode creates a dynamic library and a dynamically linked luajit. +# Note: this executable will only run when the library is installed! +#BUILDMODE= dynamic +# +############################################################################## + +############################################################################## +################################# FEATURES ################################# +############################################################################## +# Enable/disable these features as needed, but make sure you force a full +# recompile with "make clean", followed by "make". +XCFLAGS= +# +# Permanently disable the FFI extension to reduce the size of the LuaJIT +# executable. But please consider that the FFI library is compiled-in, +# but NOT loaded by default. It only allocates any memory, if you actually +# make use of it. +#XCFLAGS+= -DLUAJIT_DISABLE_FFI +# +# Features from Lua 5.2 that are unlikely to break existing code are +# enabled by default. Some other features that *might* break some existing +# code (e.g. __pairs or os.execute() return values) can be enabled here. +# Note: this does not provide full compatibility with Lua 5.2 at this time. +#XCFLAGS+= -DLUAJIT_ENABLE_LUA52COMPAT +# +# Disable the JIT compiler, i.e. turn LuaJIT into a pure interpreter. +#XCFLAGS+= -DLUAJIT_DISABLE_JIT +# +# Some architectures (e.g. PPC) can use either single-number (1) or +# dual-number (2) mode. Uncomment one of these lines to override the +# default mode. Please see LJ_ARCH_NUMMODE in lj_arch.h for details. +#XCFLAGS+= -DLUAJIT_NUMMODE=1 +#XCFLAGS+= -DLUAJIT_NUMMODE=2 +# +# Disable LJ_GC64 mode for x64. +#XCFLAGS+= -DLUAJIT_DISABLE_GC64 +# +############################################################################## + +############################################################################## +############################ DEBUGGING SUPPORT ############################# +############################################################################## +# Enable these options as needed, but make sure you force a full recompile +# with "make clean", followed by "make". +# Note that most of these are NOT suitable for benchmarking or release mode! +# +# Use the system provided memory allocator (realloc) instead of the +# bundled memory allocator. This is slower, but sometimes helpful for +# debugging. This option cannot be enabled on x64 without GC64, since +# realloc usually doesn't return addresses in the right address range. +# OTOH this option is mandatory for Valgrind's memcheck tool on x64 and +# the only way to get useful results from it for all other architectures. +#XCFLAGS+= -DLUAJIT_USE_SYSMALLOC +# +# This define is required to run LuaJIT under Valgrind. The Valgrind +# header files must be installed. You should enable debug information, too. +#XCFLAGS+= -DLUAJIT_USE_VALGRIND +# +# This is the client for the GDB JIT API. GDB 7.0 or higher is required +# to make use of it. See lj_gdbjit.c for details. Enabling this causes +# a non-negligible overhead, even when not running under GDB. +#XCFLAGS+= -DLUAJIT_USE_GDBJIT +# +# Turn on assertions for the Lua/C API to debug problems with lua_* calls. +# This is rather slow -- use only while developing C libraries/embeddings. +#XCFLAGS+= -DLUA_USE_APICHECK +# +# Turn on assertions for the whole LuaJIT VM. This significantly slows down +# everything. Use only if you suspect a problem with LuaJIT itself. +#XCFLAGS+= -DLUA_USE_ASSERT +# +############################################################################## +# You probably don't need to change anything below this line! +############################################################################## + +############################################################################## +# Host system detection. +############################################################################## + +ifeq (Windows,$(findstring Windows,$(OS))$(MSYSTEM)$(TERM)) + HOST_SYS= Windows +else + HOST_SYS:= $(shell uname -s) + ifneq (,$(findstring MINGW,$(HOST_SYS))) + HOST_SYS= Windows + HOST_MSYS= mingw + endif + ifneq (,$(findstring MSYS,$(HOST_SYS))) + HOST_SYS= Windows + HOST_MSYS= mingw + endif + ifneq (,$(findstring CYGWIN,$(HOST_SYS))) + HOST_SYS= Windows + HOST_MSYS= cygwin + endif +endif + +############################################################################## +# Flags and options for host and target. +############################################################################## + +# You can override the following variables at the make command line: +# CC HOST_CC STATIC_CC DYNAMIC_CC +# CFLAGS HOST_CFLAGS TARGET_CFLAGS +# LDFLAGS HOST_LDFLAGS TARGET_LDFLAGS TARGET_SHLDFLAGS +# LIBS HOST_LIBS TARGET_LIBS +# CROSS HOST_SYS TARGET_SYS TARGET_FLAGS +# +# Cross-compilation examples: +# make HOST_CC="gcc -m32" CROSS=i586-mingw32msvc- TARGET_SYS=Windows +# make HOST_CC="gcc -m32" CROSS=powerpc-linux-gnu- + +ASOPTIONS= $(CCOPT) $(CCWARN) $(XCFLAGS) $(CFLAGS) +CCOPTIONS= $(CCDEBUG) $(ASOPTIONS) +LDOPTIONS= $(CCDEBUG) $(LDFLAGS) + +HOST_CC= $(CC) +HOST_RM?= rm -f +# If left blank, minilua is built and used. You can supply an installed +# copy of (plain) Lua 5.1 or 5.2, plus Lua BitOp. E.g. with: HOST_LUA=lua +HOST_LUA= + +HOST_XCFLAGS= -I. +HOST_XLDFLAGS= +HOST_XLIBS= +HOST_ACFLAGS= $(CCOPTIONS) $(HOST_XCFLAGS) $(TARGET_ARCH) $(HOST_CFLAGS) +HOST_ALDFLAGS= $(LDOPTIONS) $(HOST_XLDFLAGS) $(HOST_LDFLAGS) +HOST_ALIBS= $(HOST_XLIBS) $(LIBS) $(HOST_LIBS) + +STATIC_CC = $(CROSS)$(CC) +DYNAMIC_CC = $(CROSS)$(CC) -fPIC +TARGET_CC= $(STATIC_CC) +TARGET_STCC= $(STATIC_CC) +TARGET_DYNCC= $(DYNAMIC_CC) +TARGET_LD= $(CROSS)$(CC) +TARGET_AR= $(CROSS)ar rcus +TARGET_STRIP= $(CROSS)strip + +TARGET_LIBPATH= $(or $(PREFIX),/usr/local)/$(or $(MULTILIB),lib) +TARGET_SONAME= libluajit-$(ABIVER).so.$(MAJVER) +TARGET_DYLIBNAME= libluajit-$(ABIVER).$(MAJVER).dylib +TARGET_DYLIBPATH= $(TARGET_LIBPATH)/$(TARGET_DYLIBNAME) +TARGET_DLLNAME= lua$(NODOTABIVER).dll +TARGET_DLLDOTANAME= libluajit-$(ABIVER).dll.a +TARGET_XSHLDFLAGS= -shared -fPIC -Wl,-soname,$(TARGET_SONAME) +TARGET_DYNXLDOPTS= + +TARGET_LFSFLAGS= -D_FILE_OFFSET_BITS=64 -D_LARGEFILE_SOURCE +TARGET_XCFLAGS= $(TARGET_LFSFLAGS) -U_FORTIFY_SOURCE +TARGET_XLDFLAGS= +TARGET_XLIBS= -lm +TARGET_TCFLAGS= $(CCOPTIONS) $(TARGET_XCFLAGS) $(TARGET_FLAGS) $(TARGET_CFLAGS) +TARGET_ACFLAGS= $(CCOPTIONS) $(TARGET_XCFLAGS) $(TARGET_FLAGS) $(TARGET_CFLAGS) +TARGET_ASFLAGS= $(ASOPTIONS) $(TARGET_XCFLAGS) $(TARGET_FLAGS) $(TARGET_CFLAGS) +TARGET_ALDFLAGS= $(LDOPTIONS) $(TARGET_XLDFLAGS) $(TARGET_FLAGS) $(TARGET_LDFLAGS) +TARGET_ASHLDFLAGS= $(LDOPTIONS) $(TARGET_XSHLDFLAGS) $(TARGET_FLAGS) $(TARGET_SHLDFLAGS) +TARGET_ALIBS= $(TARGET_XLIBS) $(LIBS) $(TARGET_LIBS) + +TARGET_TESTARCH=$(shell $(TARGET_CC) $(TARGET_TCFLAGS) -E lj_arch.h -dM) +ifneq (,$(findstring LJ_TARGET_X64 ,$(TARGET_TESTARCH))) + TARGET_LJARCH= x64 +else +ifneq (,$(findstring LJ_TARGET_X86 ,$(TARGET_TESTARCH))) + TARGET_LJARCH= x86 +else +ifneq (,$(findstring LJ_TARGET_ARM ,$(TARGET_TESTARCH))) + TARGET_LJARCH= arm +else +ifneq (,$(findstring LJ_TARGET_ARM64 ,$(TARGET_TESTARCH))) + ifneq (,$(findstring __AARCH64EB__ ,$(TARGET_TESTARCH))) + TARGET_ARCH= -D__AARCH64EB__=1 + endif + TARGET_LJARCH= arm64 +else +ifneq (,$(findstring LJ_TARGET_PPC ,$(TARGET_TESTARCH))) + ifneq (,$(findstring LJ_LE 1,$(TARGET_TESTARCH))) + TARGET_ARCH= -DLJ_ARCH_ENDIAN=LUAJIT_LE + else + TARGET_ARCH= -DLJ_ARCH_ENDIAN=LUAJIT_BE + endif + TARGET_LJARCH= ppc +else +ifneq (,$(findstring LJ_TARGET_MIPS ,$(TARGET_TESTARCH))) + ifneq (,$(findstring MIPSEL ,$(TARGET_TESTARCH))) + TARGET_ARCH= -D__MIPSEL__=1 + endif + ifneq (,$(findstring LJ_TARGET_MIPS64 ,$(TARGET_TESTARCH))) + TARGET_LJARCH= mips64 + else + TARGET_LJARCH= mips + endif +else + $(error Unsupported target architecture) +endif +endif +endif +endif +endif +endif + +ifneq (,$(findstring LJ_TARGET_PS3 1,$(TARGET_TESTARCH))) + TARGET_SYS= PS3 + TARGET_ARCH+= -D__CELLOS_LV2__ + TARGET_XCFLAGS+= -DLUAJIT_USE_SYSMALLOC + TARGET_XLIBS+= -lpthread +endif + +TARGET_XCFLAGS+= $(CCOPT_$(TARGET_LJARCH)) +TARGET_ARCH+= $(patsubst %,-DLUAJIT_TARGET=LUAJIT_ARCH_%,$(TARGET_LJARCH)) + +ifneq (,$(PREFIX)) +ifneq (/usr/local,$(PREFIX)) + TARGET_XCFLAGS+= -DLUA_ROOT=\"$(PREFIX)\" + ifneq (/usr,$(PREFIX)) + TARGET_DYNXLDOPTS= -Wl,-rpath,$(TARGET_LIBPATH) + endif +endif +endif +ifneq (,$(MULTILIB)) + TARGET_XCFLAGS+= -DLUA_MULTILIB=\"$(MULTILIB)\" +endif +ifneq (,$(LMULTILIB)) + TARGET_XCFLAGS+= -DLUA_LMULTILIB=\"$(LMULTILIB)\" +endif + +############################################################################## +# Target system detection. +############################################################################## + +TARGET_SYS?= $(HOST_SYS) +ifeq (Windows,$(TARGET_SYS)) + TARGET_STRIP+= --strip-unneeded + TARGET_XSHLDFLAGS= -shared -Wl,--out-implib,$(TARGET_DLLDOTANAME) + TARGET_DYNXLDOPTS= +else + TARGET_AR+= 2>/dev/null +ifeq (,$(shell $(TARGET_CC) -o /dev/null -c -x c /dev/null -fno-stack-protector 2>/dev/null || echo 1)) + TARGET_XCFLAGS+= -fno-stack-protector +endif +ifeq (Darwin,$(TARGET_SYS)) + ifeq (,$(MACOSX_DEPLOYMENT_TARGET)) + $(error missing: export MACOSX_DEPLOYMENT_TARGET=XX.YY) + endif + TARGET_STRIP+= -x + TARGET_XCFLAGS+= -DLUAJIT_UNWIND_EXTERNAL + TARGET_XSHLDFLAGS= -dynamiclib -single_module -undefined dynamic_lookup -fPIC + TARGET_DYNXLDOPTS= + TARGET_XSHLDFLAGS+= -install_name $(TARGET_DYLIBPATH) -compatibility_version $(MAJVER).$(MINVER) -current_version $(MAJVER).$(MINVER).$(RELVER) +else +ifeq (iOS,$(TARGET_SYS)) + TARGET_STRIP+= -x + TARGET_XSHLDFLAGS= -dynamiclib -single_module -undefined dynamic_lookup -fPIC + TARGET_DYNXLDOPTS= + TARGET_XSHLDFLAGS+= -install_name $(TARGET_DYLIBPATH) -compatibility_version $(MAJVER).$(MINVER) -current_version $(MAJVER).$(MINVER).$(RELVER) + ifeq (arm64,$(TARGET_LJARCH)) + TARGET_XCFLAGS+= -fno-omit-frame-pointer + endif +else + ifeq (,$(findstring LJ_NO_UNWIND 1,$(TARGET_TESTARCH))) + # Find out whether the target toolchain always generates unwind tables. + TARGET_TESTUNWIND=$(shell exec 2>/dev/null; echo 'extern void b(void);int a(void){b();return 0;}' | $(TARGET_CC) -c -x c - -o tmpunwind.o && { grep -qa -e eh_frame -e __unwind_info tmpunwind.o || grep -qU -e eh_frame -e __unwind_info tmpunwind.o; } && echo E; rm -f tmpunwind.o) + ifneq (,$(findstring E,$(TARGET_TESTUNWIND))) + TARGET_XCFLAGS+= -DLUAJIT_UNWIND_EXTERNAL + endif + endif + ifneq (SunOS,$(TARGET_SYS)) + ifneq (PS3,$(TARGET_SYS)) + TARGET_XLDFLAGS+= -Wl,-E + endif + endif + ifeq (Linux,$(TARGET_SYS)) + TARGET_XLIBS+= -ldl + endif + ifeq (GNU/kFreeBSD,$(TARGET_SYS)) + TARGET_XLIBS+= -ldl + endif +endif +endif +endif + +ifneq ($(HOST_SYS),$(TARGET_SYS)) + ifeq (Windows,$(TARGET_SYS)) + HOST_XCFLAGS+= -malign-double -DLUAJIT_OS=LUAJIT_OS_WINDOWS + else + ifeq (Linux,$(TARGET_SYS)) + HOST_XCFLAGS+= -DLUAJIT_OS=LUAJIT_OS_LINUX + else + ifeq (Darwin,$(TARGET_SYS)) + HOST_XCFLAGS+= -DLUAJIT_OS=LUAJIT_OS_OSX + else + ifeq (iOS,$(TARGET_SYS)) + HOST_XCFLAGS+= -DLUAJIT_OS=LUAJIT_OS_OSX -DTARGET_OS_IPHONE=1 + else + HOST_XCFLAGS+= -DLUAJIT_OS=LUAJIT_OS_OTHER + endif + endif + endif + endif +endif + +ifneq (,$(CCDEBUG)) + TARGET_STRIP= @: +endif + +############################################################################## +# Files and pathnames. +############################################################################## + +MINILUA_O= host/minilua.o +MINILUA_LIBS= -lm +MINILUA_T= host/minilua +MINILUA_X= $(MINILUA_T) + +ifeq (,$(HOST_LUA)) + HOST_LUA= $(MINILUA_X) + DASM_DEP= $(MINILUA_T) +endif + +DASM_DIR= ../dynasm +DASM= $(HOST_LUA) $(DASM_DIR)/dynasm.lua +DASM_XFLAGS= +DASM_AFLAGS= +DASM_ARCH= $(TARGET_LJARCH) + +ifneq (,$(findstring LJ_LE 1,$(TARGET_TESTARCH))) + DASM_AFLAGS+= -D ENDIAN_LE +else + DASM_AFLAGS+= -D ENDIAN_BE +endif +ifneq (,$(findstring LJ_ARCH_BITS 64,$(TARGET_TESTARCH))) + DASM_AFLAGS+= -D P64 +endif +ifneq (,$(findstring LJ_HASJIT 1,$(TARGET_TESTARCH))) + DASM_AFLAGS+= -D JIT +endif +ifneq (,$(findstring LJ_HASFFI 1,$(TARGET_TESTARCH))) + DASM_AFLAGS+= -D FFI +endif +ifneq (,$(findstring LJ_DUALNUM 1,$(TARGET_TESTARCH))) + DASM_AFLAGS+= -D DUALNUM +endif +ifneq (,$(findstring LJ_ARCH_HASFPU 1,$(TARGET_TESTARCH))) + DASM_AFLAGS+= -D FPU + TARGET_ARCH+= -DLJ_ARCH_HASFPU=1 +else + TARGET_ARCH+= -DLJ_ARCH_HASFPU=0 +endif +ifeq (,$(findstring LJ_ABI_SOFTFP 1,$(TARGET_TESTARCH))) + DASM_AFLAGS+= -D HFABI + TARGET_ARCH+= -DLJ_ABI_SOFTFP=0 +else + TARGET_ARCH+= -DLJ_ABI_SOFTFP=1 +endif +ifneq (,$(findstring LJ_NO_UNWIND 1,$(TARGET_TESTARCH))) + DASM_AFLAGS+= -D NO_UNWIND + TARGET_ARCH+= -DLUAJIT_NO_UNWIND +endif +DASM_AFLAGS+= -D VER=$(subst LJ_ARCH_VERSION_,,$(filter LJ_ARCH_VERSION_%,$(subst LJ_ARCH_VERSION ,LJ_ARCH_VERSION_,$(TARGET_TESTARCH)))) +ifeq (Windows,$(TARGET_SYS)) + DASM_AFLAGS+= -D WIN +endif +ifeq (x64,$(TARGET_LJARCH)) + ifeq (,$(findstring LJ_FR2 1,$(TARGET_TESTARCH))) + DASM_ARCH= x86 + endif +else +ifeq (arm,$(TARGET_LJARCH)) + ifeq (iOS,$(TARGET_SYS)) + DASM_AFLAGS+= -D IOS + endif +else +ifneq (,$(findstring LJ_TARGET_MIPSR6 ,$(TARGET_TESTARCH))) + DASM_AFLAGS+= -D MIPSR6 +endif +ifeq (ppc,$(TARGET_LJARCH)) + ifneq (,$(findstring LJ_ARCH_SQRT 1,$(TARGET_TESTARCH))) + DASM_AFLAGS+= -D SQRT + endif + ifneq (,$(findstring LJ_ARCH_ROUND 1,$(TARGET_TESTARCH))) + DASM_AFLAGS+= -D ROUND + endif + ifneq (,$(findstring LJ_ARCH_PPC32ON64 1,$(TARGET_TESTARCH))) + DASM_AFLAGS+= -D GPR64 + endif + ifeq (PS3,$(TARGET_SYS)) + DASM_AFLAGS+= -D PPE -D TOC + endif +endif +endif +endif + +DASM_FLAGS= $(DASM_XFLAGS) $(DASM_AFLAGS) +DASM_DASC= vm_$(DASM_ARCH).dasc + +BUILDVM_O= host/buildvm.o host/buildvm_asm.o host/buildvm_peobj.o \ + host/buildvm_lib.o host/buildvm_fold.o +BUILDVM_T= host/buildvm +BUILDVM_X= $(BUILDVM_T) + +HOST_O= $(MINILUA_O) $(BUILDVM_O) +HOST_T= $(MINILUA_T) $(BUILDVM_T) + +LJVM_S= lj_vm.S +LJVM_O= lj_vm.o +LJVM_BOUT= $(LJVM_S) +LJVM_MODE= elfasm + +LJLIB_O= lib_base.o lib_math.o lib_bit.o lib_string.o lib_table.o \ + lib_io.o lib_os.o lib_package.o lib_debug.o lib_jit.o lib_ffi.o \ + lib_buffer.o +LJLIB_C= $(LJLIB_O:.o=.c) + +LJCORE_O= lj_assert.o lj_gc.o lj_err.o lj_char.o lj_bc.o lj_obj.o lj_buf.o \ + lj_str.o lj_tab.o lj_func.o lj_udata.o lj_meta.o lj_debug.o \ + lj_prng.o lj_state.o lj_dispatch.o lj_vmevent.o lj_vmmath.o \ + lj_strscan.o lj_strfmt.o lj_strfmt_num.o lj_serialize.o \ + lj_api.o lj_profile.o \ + lj_lex.o lj_parse.o lj_bcread.o lj_bcwrite.o lj_load.o \ + lj_ir.o lj_opt_mem.o lj_opt_fold.o lj_opt_narrow.o \ + lj_opt_dce.o lj_opt_loop.o lj_opt_split.o lj_opt_sink.o \ + lj_mcode.o lj_snap.o lj_record.o lj_crecord.o lj_ffrecord.o \ + lj_asm.o lj_trace.o lj_gdbjit.o \ + lj_ctype.o lj_cdata.o lj_cconv.o lj_ccall.o lj_ccallback.o \ + lj_carith.o lj_clib.o lj_cparse.o \ + lj_lib.o lj_alloc.o lib_aux.o \ + $(LJLIB_O) lib_init.o + +LJVMCORE_O= $(LJVM_O) $(LJCORE_O) +LJVMCORE_DYNO= $(LJVMCORE_O:.o=_dyn.o) + +LIB_VMDEF= jit/vmdef.lua +LIB_VMDEFP= $(LIB_VMDEF) + +LUAJIT_O= luajit.o +LUAJIT_A= libluajit.a +LUAJIT_SO= libluajit.so +LUAJIT_T= luajit + +ALL_T= $(LUAJIT_T) $(LUAJIT_A) $(LUAJIT_SO) $(HOST_T) +ALL_HDRGEN= lj_bcdef.h lj_ffdef.h lj_libdef.h lj_recdef.h lj_folddef.h \ + host/buildvm_arch.h +ALL_GEN= $(LJVM_S) $(ALL_HDRGEN) $(LIB_VMDEFP) +WIN_RM= *.obj *.lib *.exp *.dll *.exe *.manifest *.pdb *.ilk +ALL_RM= $(ALL_T) $(ALL_GEN) *.o host/*.o $(WIN_RM) + +############################################################################## +# Build mode handling. +############################################################################## + +# Mixed mode defaults. +TARGET_O= $(LUAJIT_A) +TARGET_T= $(LUAJIT_T) $(LUAJIT_SO) +TARGET_DEP= $(LIB_VMDEF) $(LUAJIT_SO) + +ifeq (Windows,$(TARGET_SYS)) + TARGET_DYNCC= $(STATIC_CC) + LJVM_MODE= peobj + LJVM_BOUT= $(LJVM_O) + LUAJIT_T= luajit.exe + ifeq (cygwin,$(HOST_MSYS)) + LUAJIT_SO= cyg$(TARGET_DLLNAME) + else + LUAJIT_SO= $(TARGET_DLLNAME) + endif + # Mixed mode is not supported on Windows. And static mode doesn't work well. + # C modules cannot be loaded, because they bind to lua51.dll. + ifneq (static,$(BUILDMODE)) + BUILDMODE= dynamic + TARGET_XCFLAGS+= -DLUA_BUILD_AS_DLL + endif +endif +ifeq (Darwin,$(TARGET_SYS)) + LJVM_MODE= machasm +endif +ifeq (iOS,$(TARGET_SYS)) + LJVM_MODE= machasm +endif +ifeq (SunOS,$(TARGET_SYS)) + BUILDMODE= static +endif +ifeq (PS3,$(TARGET_SYS)) + BUILDMODE= static +endif + +ifeq (Windows,$(HOST_SYS)) + MINILUA_T= host/minilua.exe + BUILDVM_T= host/buildvm.exe + ifeq (,$(HOST_MSYS)) + MINILUA_X= host\minilua + BUILDVM_X= host\buildvm + ALL_RM:= $(subst /,\,$(ALL_RM)) + HOST_RM= del + endif +endif + +ifeq (static,$(BUILDMODE)) + TARGET_DYNCC= @: + TARGET_T= $(LUAJIT_T) + TARGET_DEP= $(LIB_VMDEF) +else +ifeq (dynamic,$(BUILDMODE)) + ifneq (Windows,$(TARGET_SYS)) + TARGET_CC= $(DYNAMIC_CC) + endif + TARGET_DYNCC= @: + LJVMCORE_DYNO= $(LJVMCORE_O) + TARGET_O= $(LUAJIT_SO) + TARGET_XLDFLAGS+= $(TARGET_DYNXLDOPTS) +else +ifeq (Darwin,$(TARGET_SYS)) + TARGET_DYNCC= @: + LJVMCORE_DYNO= $(LJVMCORE_O) +endif +ifeq (iOS,$(TARGET_SYS)) + TARGET_DYNCC= @: + LJVMCORE_DYNO= $(LJVMCORE_O) +endif +endif +endif + +Q= @ +E= @echo +#Q= +#E= @: + +############################################################################## +# Make targets. +############################################################################## + +default all: $(TARGET_T) + +amalg: + $(MAKE) all "LJCORE_O=ljamalg.o" + +clean: + $(HOST_RM) $(ALL_RM) + +libbc: + ./$(LUAJIT_T) host/genlibbc.lua -o host/buildvm_libbc.h $(LJLIB_C) + $(MAKE) all + +depend: + @for file in $(ALL_HDRGEN); do \ + test -f $$file || touch $$file; \ + done + @$(HOST_CC) $(HOST_ACFLAGS) -MM *.c host/*.c | \ + sed -e "s| [^ ]*/dasm_\S*\.h||g" \ + -e "s|^\([^l ]\)|host/\1|" \ + -e "s| lj_target_\S*\.h| lj_target_*.h|g" \ + -e "s| lj_emit_\S*\.h| lj_emit_*.h|g" \ + -e "s| lj_asm_\S*\.h| lj_asm_*.h|g" >Makefile.dep + @for file in $(ALL_HDRGEN); do \ + test -s $$file || $(HOST_RM) $$file; \ + done + +.PHONY: default all amalg clean libbc depend + +############################################################################## +# Rules for generated files. +############################################################################## + +$(MINILUA_T): $(MINILUA_O) + $(E) "HOSTLINK $@" + $(Q)$(HOST_CC) $(HOST_ALDFLAGS) -o $@ $(MINILUA_O) $(MINILUA_LIBS) $(HOST_ALIBS) + +host/buildvm_arch.h: $(DASM_DASC) $(DASM_DEP) $(DASM_DIR)/*.lua lj_arch.h lua.h luaconf.h + $(E) "DYNASM $@" + $(Q)$(DASM) $(DASM_FLAGS) -o $@ $(DASM_DASC) + +host/buildvm.o: $(DASM_DIR)/dasm_*.h + +$(BUILDVM_T): $(BUILDVM_O) + $(E) "HOSTLINK $@" + $(Q)$(HOST_CC) $(HOST_ALDFLAGS) -o $@ $(BUILDVM_O) $(HOST_ALIBS) + +$(LJVM_BOUT): $(BUILDVM_T) + $(E) "BUILDVM $@" + $(Q)$(BUILDVM_X) -m $(LJVM_MODE) -o $@ + +lj_bcdef.h: $(BUILDVM_T) $(LJLIB_C) + $(E) "BUILDVM $@" + $(Q)$(BUILDVM_X) -m bcdef -o $@ $(LJLIB_C) + +lj_ffdef.h: $(BUILDVM_T) $(LJLIB_C) + $(E) "BUILDVM $@" + $(Q)$(BUILDVM_X) -m ffdef -o $@ $(LJLIB_C) + +lj_libdef.h: $(BUILDVM_T) $(LJLIB_C) + $(E) "BUILDVM $@" + $(Q)$(BUILDVM_X) -m libdef -o $@ $(LJLIB_C) + +lj_recdef.h: $(BUILDVM_T) $(LJLIB_C) + $(E) "BUILDVM $@" + $(Q)$(BUILDVM_X) -m recdef -o $@ $(LJLIB_C) + +$(LIB_VMDEF): $(BUILDVM_T) $(LJLIB_C) + $(E) "BUILDVM $@" + $(Q)$(BUILDVM_X) -m vmdef -o $(LIB_VMDEFP) $(LJLIB_C) + +lj_folddef.h: $(BUILDVM_T) lj_opt_fold.c + $(E) "BUILDVM $@" + $(Q)$(BUILDVM_X) -m folddef -o $@ lj_opt_fold.c + +############################################################################## +# Object file rules. +############################################################################## + +%.o: %.c + $(E) "CC $@" + $(Q)$(TARGET_DYNCC) $(TARGET_ACFLAGS) -c -o $(@:.o=_dyn.o) $< + $(Q)$(TARGET_CC) $(TARGET_ACFLAGS) -c -o $@ $< + +%.o: %.S + $(E) "ASM $@" + $(Q)$(TARGET_DYNCC) $(TARGET_ASFLAGS) -c -o $(@:.o=_dyn.o) $< + $(Q)$(TARGET_CC) $(TARGET_ASFLAGS) -c -o $@ $< + +$(LUAJIT_O): + $(E) "CC $@" + $(Q)$(TARGET_STCC) $(TARGET_ACFLAGS) -c -o $@ $< + +$(HOST_O): %.o: %.c + $(E) "HOSTCC $@" + $(Q)$(HOST_CC) $(HOST_ACFLAGS) -c -o $@ $< + +include Makefile.dep + +############################################################################## +# Target file rules. +############################################################################## + +$(LUAJIT_A): $(LJVMCORE_O) + $(E) "AR $@" + $(Q)$(TARGET_AR) $@ $(LJVMCORE_O) + +# The dependency on _O, but linking with _DYNO is intentional. +$(LUAJIT_SO): $(LJVMCORE_O) + $(E) "DYNLINK $@" + $(Q)$(TARGET_LD) $(TARGET_ASHLDFLAGS) -o $@ $(LJVMCORE_DYNO) $(TARGET_ALIBS) + $(Q)$(TARGET_STRIP) $@ + +$(LUAJIT_T): $(TARGET_O) $(LUAJIT_O) $(TARGET_DEP) + $(E) "LINK $@" + $(Q)$(TARGET_LD) $(TARGET_ALDFLAGS) -o $@ $(LUAJIT_O) $(TARGET_O) $(TARGET_ALIBS) + $(Q)$(TARGET_STRIP) $@ + $(E) "OK Successfully built LuaJIT" + +############################################################################## diff --git a/fluent-bit/lib/luajit-3065c9/src/Makefile.dep b/fluent-bit/lib/luajit-3065c9/src/Makefile.dep new file mode 100644 index 00000000..1ad6701a --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/Makefile.dep @@ -0,0 +1,259 @@ +lib_aux.o: lib_aux.c lua.h luaconf.h lauxlib.h lj_obj.h lj_def.h \ + lj_arch.h lj_err.h lj_errmsg.h lj_state.h lj_trace.h lj_jit.h lj_ir.h \ + lj_dispatch.h lj_bc.h lj_traceerr.h lj_lib.h +lib_base.o: lib_base.c lua.h luaconf.h lauxlib.h lualib.h lj_obj.h \ + lj_def.h lj_arch.h lj_gc.h lj_err.h lj_errmsg.h lj_debug.h lj_buf.h \ + lj_str.h lj_tab.h lj_meta.h lj_state.h lj_frame.h lj_bc.h lj_ctype.h \ + lj_cconv.h lj_ff.h lj_ffdef.h lj_dispatch.h lj_jit.h lj_ir.h lj_char.h \ + lj_strscan.h lj_strfmt.h lj_lib.h lj_libdef.h +lib_bit.o: lib_bit.c lua.h luaconf.h lauxlib.h lualib.h lj_obj.h lj_def.h \ + lj_arch.h lj_err.h lj_errmsg.h lj_buf.h lj_gc.h lj_str.h lj_strscan.h \ + lj_strfmt.h lj_ctype.h lj_cdata.h lj_cconv.h lj_carith.h lj_ff.h \ + lj_ffdef.h lj_lib.h lj_libdef.h +lib_buffer.o: lib_buffer.c lua.h luaconf.h lauxlib.h lualib.h lj_obj.h \ + lj_def.h lj_arch.h lj_gc.h lj_err.h lj_errmsg.h lj_buf.h lj_str.h \ + lj_tab.h lj_udata.h lj_meta.h lj_ctype.h lj_cdata.h lj_cconv.h \ + lj_strfmt.h lj_serialize.h lj_lib.h lj_libdef.h +lib_debug.o: lib_debug.c lua.h luaconf.h lauxlib.h lualib.h lj_obj.h \ + lj_def.h lj_arch.h lj_gc.h lj_err.h lj_errmsg.h lj_debug.h lj_lib.h \ + lj_libdef.h +lib_ffi.o: lib_ffi.c lua.h luaconf.h lauxlib.h lualib.h lj_obj.h lj_def.h \ + lj_arch.h lj_gc.h lj_err.h lj_errmsg.h lj_str.h lj_tab.h lj_meta.h \ + lj_ctype.h lj_cparse.h lj_cdata.h lj_cconv.h lj_carith.h lj_ccall.h \ + lj_ccallback.h lj_clib.h lj_strfmt.h lj_ff.h lj_ffdef.h lj_lib.h \ + lj_libdef.h +lib_init.o: lib_init.c lua.h luaconf.h lauxlib.h lualib.h lj_arch.h +lib_io.o: lib_io.c lua.h luaconf.h lauxlib.h lualib.h lj_obj.h lj_def.h \ + lj_arch.h lj_gc.h lj_err.h lj_errmsg.h lj_buf.h lj_str.h lj_state.h \ + lj_strfmt.h lj_ff.h lj_ffdef.h lj_lib.h lj_libdef.h +lib_jit.o: lib_jit.c lua.h luaconf.h lauxlib.h lualib.h lj_obj.h lj_def.h \ + lj_arch.h lj_gc.h lj_err.h lj_errmsg.h lj_debug.h lj_str.h lj_tab.h \ + lj_state.h lj_bc.h lj_ctype.h lj_ir.h lj_jit.h lj_ircall.h lj_iropt.h \ + lj_target.h lj_target_*.h lj_trace.h lj_dispatch.h lj_traceerr.h \ + lj_vm.h lj_vmevent.h lj_lib.h luajit.h lj_libdef.h +lib_math.o: lib_math.c lua.h luaconf.h lauxlib.h lualib.h lj_obj.h \ + lj_def.h lj_arch.h lj_lib.h lj_vm.h lj_prng.h lj_libdef.h +lib_os.o: lib_os.c lua.h luaconf.h lauxlib.h lualib.h lj_obj.h lj_def.h \ + lj_arch.h lj_gc.h lj_err.h lj_errmsg.h lj_buf.h lj_str.h lj_lib.h \ + lj_libdef.h +lib_package.o: lib_package.c lua.h luaconf.h lauxlib.h lualib.h lj_obj.h \ + lj_def.h lj_arch.h lj_err.h lj_errmsg.h lj_lib.h +lib_string.o: lib_string.c lua.h luaconf.h lauxlib.h lualib.h lj_obj.h \ + lj_def.h lj_arch.h lj_gc.h lj_err.h lj_errmsg.h lj_buf.h lj_str.h \ + lj_tab.h lj_meta.h lj_state.h lj_ff.h lj_ffdef.h lj_bcdump.h lj_lex.h \ + lj_char.h lj_strfmt.h lj_lib.h lj_libdef.h +lib_table.o: lib_table.c lua.h luaconf.h lauxlib.h lualib.h lj_obj.h \ + lj_def.h lj_arch.h lj_gc.h lj_err.h lj_errmsg.h lj_buf.h lj_str.h \ + lj_tab.h lj_ff.h lj_ffdef.h lj_lib.h lj_libdef.h +lj_alloc.o: lj_alloc.c lj_def.h lua.h luaconf.h lj_arch.h lj_alloc.h \ + lj_prng.h +lj_api.o: lj_api.c lj_obj.h lua.h luaconf.h lj_def.h lj_arch.h lj_gc.h \ + lj_err.h lj_errmsg.h lj_debug.h lj_str.h lj_tab.h lj_func.h lj_udata.h \ + lj_meta.h lj_state.h lj_bc.h lj_frame.h lj_trace.h lj_jit.h lj_ir.h \ + lj_dispatch.h lj_traceerr.h lj_vm.h lj_strscan.h lj_strfmt.h +lj_asm.o: lj_asm.c lj_obj.h lua.h luaconf.h lj_def.h lj_arch.h lj_gc.h \ + lj_buf.h lj_str.h lj_tab.h lj_frame.h lj_bc.h lj_ctype.h lj_ir.h \ + lj_jit.h lj_ircall.h lj_iropt.h lj_mcode.h lj_trace.h lj_dispatch.h \ + lj_traceerr.h lj_snap.h lj_asm.h lj_vm.h lj_target.h lj_target_*.h \ + lj_emit_*.h lj_asm_*.h +lj_assert.o: lj_assert.c lj_obj.h lua.h luaconf.h lj_def.h lj_arch.h +lj_bc.o: lj_bc.c lj_obj.h lua.h luaconf.h lj_def.h lj_arch.h lj_bc.h \ + lj_bcdef.h +lj_bcread.o: lj_bcread.c lj_obj.h lua.h luaconf.h lj_def.h lj_arch.h \ + lj_gc.h lj_err.h lj_errmsg.h lj_buf.h lj_str.h lj_tab.h lj_bc.h \ + lj_ctype.h lj_cdata.h lualib.h lj_lex.h lj_bcdump.h lj_state.h \ + lj_strfmt.h +lj_bcwrite.o: lj_bcwrite.c lj_obj.h lua.h luaconf.h lj_def.h lj_arch.h \ + lj_gc.h lj_buf.h lj_str.h lj_bc.h lj_ctype.h lj_dispatch.h lj_jit.h \ + lj_ir.h lj_strfmt.h lj_bcdump.h lj_lex.h lj_err.h lj_errmsg.h lj_vm.h +lj_buf.o: lj_buf.c lj_obj.h lua.h luaconf.h lj_def.h lj_arch.h lj_gc.h \ + lj_err.h lj_errmsg.h lj_buf.h lj_str.h lj_tab.h lj_strfmt.h +lj_carith.o: lj_carith.c lj_obj.h lua.h luaconf.h lj_def.h lj_arch.h \ + lj_gc.h lj_err.h lj_errmsg.h lj_tab.h lj_meta.h lj_ir.h lj_ctype.h \ + lj_cconv.h lj_cdata.h lj_carith.h lj_strscan.h +lj_ccall.o: lj_ccall.c lj_obj.h lua.h luaconf.h lj_def.h lj_arch.h \ + lj_gc.h lj_err.h lj_errmsg.h lj_tab.h lj_ctype.h lj_cconv.h lj_cdata.h \ + lj_ccall.h lj_trace.h lj_jit.h lj_ir.h lj_dispatch.h lj_bc.h \ + lj_traceerr.h +lj_ccallback.o: lj_ccallback.c lj_obj.h lua.h luaconf.h lj_def.h \ + lj_arch.h lj_gc.h lj_err.h lj_errmsg.h lj_tab.h lj_state.h lj_frame.h \ + lj_bc.h lj_ctype.h lj_cconv.h lj_ccall.h lj_ccallback.h lj_target.h \ + lj_target_*.h lj_mcode.h lj_jit.h lj_ir.h lj_trace.h lj_dispatch.h \ + lj_traceerr.h lj_vm.h +lj_cconv.o: lj_cconv.c lj_obj.h lua.h luaconf.h lj_def.h lj_arch.h \ + lj_err.h lj_errmsg.h lj_buf.h lj_gc.h lj_str.h lj_tab.h lj_ctype.h \ + lj_cdata.h lj_cconv.h lj_ccallback.h +lj_cdata.o: lj_cdata.c lj_obj.h lua.h luaconf.h lj_def.h lj_arch.h \ + lj_gc.h lj_err.h lj_errmsg.h lj_tab.h lj_ctype.h lj_cconv.h lj_cdata.h +lj_char.o: lj_char.c lj_char.h lj_def.h lua.h luaconf.h +lj_clib.o: lj_clib.c lj_obj.h lua.h luaconf.h lj_def.h lj_arch.h lj_gc.h \ + lj_err.h lj_errmsg.h lj_tab.h lj_str.h lj_udata.h lj_ctype.h lj_cconv.h \ + lj_cdata.h lj_clib.h lj_strfmt.h +lj_cparse.o: lj_cparse.c lj_obj.h lua.h luaconf.h lj_def.h lj_arch.h \ + lj_gc.h lj_err.h lj_errmsg.h lj_buf.h lj_str.h lj_ctype.h lj_cparse.h \ + lj_frame.h lj_bc.h lj_vm.h lj_char.h lj_strscan.h lj_strfmt.h +lj_crecord.o: lj_crecord.c lj_obj.h lua.h luaconf.h lj_def.h lj_arch.h \ + lj_err.h lj_errmsg.h lj_tab.h lj_frame.h lj_bc.h lj_ctype.h lj_gc.h \ + lj_cdata.h lj_cparse.h lj_cconv.h lj_carith.h lj_clib.h lj_ccall.h \ + lj_ff.h lj_ffdef.h lj_ir.h lj_jit.h lj_ircall.h lj_iropt.h lj_trace.h \ + lj_dispatch.h lj_traceerr.h lj_record.h lj_ffrecord.h lj_snap.h \ + lj_crecord.h lj_strfmt.h +lj_ctype.o: lj_ctype.c lj_obj.h lua.h luaconf.h lj_def.h lj_arch.h \ + lj_gc.h lj_err.h lj_errmsg.h lj_str.h lj_tab.h lj_strfmt.h lj_ctype.h \ + lj_ccallback.h lj_buf.h +lj_debug.o: lj_debug.c lj_obj.h lua.h luaconf.h lj_def.h lj_arch.h \ + lj_err.h lj_errmsg.h lj_debug.h lj_buf.h lj_gc.h lj_str.h lj_tab.h \ + lj_state.h lj_frame.h lj_bc.h lj_strfmt.h lj_jit.h lj_ir.h +lj_dispatch.o: lj_dispatch.c lj_obj.h lua.h luaconf.h lj_def.h lj_arch.h \ + lj_err.h lj_errmsg.h lj_buf.h lj_gc.h lj_str.h lj_func.h lj_tab.h \ + lj_meta.h lj_debug.h lj_state.h lj_frame.h lj_bc.h lj_ff.h lj_ffdef.h \ + lj_strfmt.h lj_jit.h lj_ir.h lj_ccallback.h lj_ctype.h lj_trace.h \ + lj_dispatch.h lj_traceerr.h lj_profile.h lj_vm.h luajit.h +lj_err.o: lj_err.c lj_obj.h lua.h luaconf.h lj_def.h lj_arch.h lj_err.h \ + lj_errmsg.h lj_debug.h lj_str.h lj_func.h lj_state.h lj_frame.h lj_bc.h \ + lj_ff.h lj_ffdef.h lj_trace.h lj_jit.h lj_ir.h lj_dispatch.h \ + lj_traceerr.h lj_vm.h lj_strfmt.h +lj_ffrecord.o: lj_ffrecord.c lj_obj.h lua.h luaconf.h lj_def.h lj_arch.h \ + lj_err.h lj_errmsg.h lj_buf.h lj_gc.h lj_str.h lj_tab.h lj_frame.h \ + lj_bc.h lj_ff.h lj_ffdef.h lj_ir.h lj_jit.h lj_ircall.h lj_iropt.h \ + lj_trace.h lj_dispatch.h lj_traceerr.h lj_record.h lj_ffrecord.h \ + lj_crecord.h lj_vm.h lj_strscan.h lj_strfmt.h lj_serialize.h lj_recdef.h +lj_func.o: lj_func.c lj_obj.h lua.h luaconf.h lj_def.h lj_arch.h lj_gc.h \ + lj_func.h lj_trace.h lj_jit.h lj_ir.h lj_dispatch.h lj_bc.h \ + lj_traceerr.h lj_vm.h +lj_gc.o: lj_gc.c lj_obj.h lua.h luaconf.h lj_def.h lj_arch.h lj_gc.h \ + lj_err.h lj_errmsg.h lj_buf.h lj_str.h lj_tab.h lj_func.h lj_udata.h \ + lj_meta.h lj_state.h lj_frame.h lj_bc.h lj_ctype.h lj_cdata.h lj_trace.h \ + lj_jit.h lj_ir.h lj_dispatch.h lj_traceerr.h lj_vm.h +lj_gdbjit.o: lj_gdbjit.c lj_obj.h lua.h luaconf.h lj_def.h lj_arch.h \ + lj_gc.h lj_err.h lj_errmsg.h lj_debug.h lj_frame.h lj_bc.h lj_buf.h \ + lj_str.h lj_strfmt.h lj_jit.h lj_ir.h lj_dispatch.h +lj_ir.o: lj_ir.c lj_obj.h lua.h luaconf.h lj_def.h lj_arch.h lj_gc.h \ + lj_buf.h lj_str.h lj_tab.h lj_ir.h lj_jit.h lj_ircall.h lj_iropt.h \ + lj_trace.h lj_dispatch.h lj_bc.h lj_traceerr.h lj_ctype.h lj_cdata.h \ + lj_carith.h lj_vm.h lj_strscan.h lj_serialize.h lj_strfmt.h lj_prng.h +lj_lex.o: lj_lex.c lj_obj.h lua.h luaconf.h lj_def.h lj_arch.h lj_gc.h \ + lj_err.h lj_errmsg.h lj_buf.h lj_str.h lj_tab.h lj_ctype.h lj_cdata.h \ + lualib.h lj_state.h lj_lex.h lj_parse.h lj_char.h lj_strscan.h \ + lj_strfmt.h +lj_lib.o: lj_lib.c lauxlib.h lua.h luaconf.h lj_obj.h lj_def.h lj_arch.h \ + lj_gc.h lj_err.h lj_errmsg.h lj_str.h lj_tab.h lj_func.h lj_bc.h \ + lj_dispatch.h lj_jit.h lj_ir.h lj_ctype.h lj_vm.h lj_strscan.h \ + lj_strfmt.h lj_lex.h lj_bcdump.h lj_lib.h +lj_load.o: lj_load.c lua.h luaconf.h lauxlib.h lj_obj.h lj_def.h \ + lj_arch.h lj_gc.h lj_err.h lj_errmsg.h lj_buf.h lj_str.h lj_func.h \ + lj_frame.h lj_bc.h lj_vm.h lj_lex.h lj_bcdump.h lj_parse.h +lj_mcode.o: lj_mcode.c lj_obj.h lua.h luaconf.h lj_def.h lj_arch.h \ + lj_gc.h lj_err.h lj_errmsg.h lj_jit.h lj_ir.h lj_mcode.h lj_trace.h \ + lj_dispatch.h lj_bc.h lj_traceerr.h lj_prng.h lj_vm.h +lj_meta.o: lj_meta.c lj_obj.h lua.h luaconf.h lj_def.h lj_arch.h lj_gc.h \ + lj_err.h lj_errmsg.h lj_buf.h lj_str.h lj_tab.h lj_meta.h lj_frame.h \ + lj_bc.h lj_vm.h lj_strscan.h lj_strfmt.h lj_lib.h +lj_obj.o: lj_obj.c lj_obj.h lua.h luaconf.h lj_def.h lj_arch.h +lj_opt_dce.o: lj_opt_dce.c lj_obj.h lua.h luaconf.h lj_def.h lj_arch.h \ + lj_ir.h lj_jit.h lj_iropt.h +lj_opt_fold.o: lj_opt_fold.c lj_obj.h lua.h luaconf.h lj_def.h lj_arch.h \ + lj_buf.h lj_gc.h lj_str.h lj_tab.h lj_ir.h lj_jit.h lj_ircall.h \ + lj_iropt.h lj_trace.h lj_dispatch.h lj_bc.h lj_traceerr.h lj_ctype.h \ + lj_carith.h lj_vm.h lj_strscan.h lj_strfmt.h lj_folddef.h +lj_opt_loop.o: lj_opt_loop.c lj_obj.h lua.h luaconf.h lj_def.h lj_arch.h \ + lj_err.h lj_errmsg.h lj_buf.h lj_gc.h lj_str.h lj_ir.h lj_jit.h \ + lj_iropt.h lj_trace.h lj_dispatch.h lj_bc.h lj_traceerr.h lj_snap.h \ + lj_vm.h +lj_opt_mem.o: lj_opt_mem.c lj_obj.h lua.h luaconf.h lj_def.h lj_arch.h \ + lj_tab.h lj_ir.h lj_jit.h lj_iropt.h lj_ircall.h lj_dispatch.h lj_bc.h +lj_opt_narrow.o: lj_opt_narrow.c lj_obj.h lua.h luaconf.h lj_def.h \ + lj_arch.h lj_bc.h lj_ir.h lj_jit.h lj_iropt.h lj_trace.h lj_dispatch.h \ + lj_traceerr.h lj_vm.h lj_strscan.h +lj_opt_sink.o: lj_opt_sink.c lj_obj.h lua.h luaconf.h lj_def.h lj_arch.h \ + lj_ir.h lj_jit.h lj_iropt.h lj_target.h lj_target_*.h +lj_opt_split.o: lj_opt_split.c lj_obj.h lua.h luaconf.h lj_def.h \ + lj_arch.h lj_err.h lj_errmsg.h lj_buf.h lj_gc.h lj_str.h lj_ir.h \ + lj_jit.h lj_ircall.h lj_iropt.h lj_dispatch.h lj_bc.h lj_vm.h +lj_parse.o: lj_parse.c lj_obj.h lua.h luaconf.h lj_def.h lj_arch.h \ + lj_gc.h lj_err.h lj_errmsg.h lj_debug.h lj_buf.h lj_str.h lj_tab.h \ + lj_func.h lj_state.h lj_bc.h lj_ctype.h lj_strfmt.h lj_lex.h lj_parse.h \ + lj_vm.h lj_vmevent.h +lj_prng.o: lj_prng.c lj_def.h lua.h luaconf.h lj_arch.h lj_prng.h +lj_profile.o: lj_profile.c lj_obj.h lua.h luaconf.h lj_def.h lj_arch.h \ + lj_buf.h lj_gc.h lj_str.h lj_frame.h lj_bc.h lj_debug.h lj_dispatch.h \ + lj_jit.h lj_ir.h lj_trace.h lj_traceerr.h lj_profile.h luajit.h +lj_record.o: lj_record.c lj_obj.h lua.h luaconf.h lj_def.h lj_arch.h \ + lj_err.h lj_errmsg.h lj_str.h lj_tab.h lj_meta.h lj_frame.h lj_bc.h \ + lj_ctype.h lj_gc.h lj_ff.h lj_ffdef.h lj_debug.h lj_ir.h lj_jit.h \ + lj_ircall.h lj_iropt.h lj_trace.h lj_dispatch.h lj_traceerr.h \ + lj_record.h lj_ffrecord.h lj_snap.h lj_vm.h lj_prng.h +lj_serialize.o: lj_serialize.c lj_obj.h lua.h luaconf.h lj_def.h \ + lj_arch.h lj_err.h lj_errmsg.h lj_buf.h lj_gc.h lj_str.h lj_tab.h \ + lj_udata.h lj_ctype.h lj_cdata.h lj_ir.h lj_serialize.h +lj_snap.o: lj_snap.c lj_obj.h lua.h luaconf.h lj_def.h lj_arch.h lj_gc.h \ + lj_tab.h lj_state.h lj_frame.h lj_bc.h lj_ir.h lj_jit.h lj_iropt.h \ + lj_trace.h lj_dispatch.h lj_traceerr.h lj_snap.h lj_target.h \ + lj_target_*.h lj_ctype.h lj_cdata.h +lj_state.o: lj_state.c lj_obj.h lua.h luaconf.h lj_def.h lj_arch.h \ + lj_gc.h lj_err.h lj_errmsg.h lj_buf.h lj_str.h lj_tab.h lj_func.h \ + lj_meta.h lj_state.h lj_frame.h lj_bc.h lj_ctype.h lj_trace.h lj_jit.h \ + lj_ir.h lj_dispatch.h lj_traceerr.h lj_vm.h lj_prng.h lj_lex.h \ + lj_alloc.h luajit.h +lj_str.o: lj_str.c lj_obj.h lua.h luaconf.h lj_def.h lj_arch.h lj_gc.h \ + lj_err.h lj_errmsg.h lj_str.h lj_char.h lj_prng.h +lj_strfmt.o: lj_strfmt.c lj_obj.h lua.h luaconf.h lj_def.h lj_arch.h \ + lj_err.h lj_errmsg.h lj_buf.h lj_gc.h lj_str.h lj_meta.h lj_state.h \ + lj_char.h lj_strfmt.h lj_ctype.h lj_lib.h +lj_strfmt_num.o: lj_strfmt_num.c lj_obj.h lua.h luaconf.h lj_def.h \ + lj_arch.h lj_buf.h lj_gc.h lj_str.h lj_strfmt.h +lj_strscan.o: lj_strscan.c lj_obj.h lua.h luaconf.h lj_def.h lj_arch.h \ + lj_char.h lj_strscan.h +lj_tab.o: lj_tab.c lj_obj.h lua.h luaconf.h lj_def.h lj_arch.h lj_gc.h \ + lj_err.h lj_errmsg.h lj_tab.h +lj_trace.o: lj_trace.c lj_obj.h lua.h luaconf.h lj_def.h lj_arch.h \ + lj_gc.h lj_err.h lj_errmsg.h lj_debug.h lj_str.h lj_frame.h lj_bc.h \ + lj_state.h lj_ir.h lj_jit.h lj_iropt.h lj_mcode.h lj_trace.h \ + lj_dispatch.h lj_traceerr.h lj_snap.h lj_gdbjit.h lj_record.h lj_asm.h \ + lj_vm.h lj_vmevent.h lj_target.h lj_target_*.h lj_prng.h +lj_udata.o: lj_udata.c lj_obj.h lua.h luaconf.h lj_def.h lj_arch.h \ + lj_gc.h lj_err.h lj_errmsg.h lj_udata.h +lj_vmevent.o: lj_vmevent.c lj_obj.h lua.h luaconf.h lj_def.h lj_arch.h \ + lj_str.h lj_tab.h lj_state.h lj_dispatch.h lj_bc.h lj_jit.h lj_ir.h \ + lj_vm.h lj_vmevent.h +lj_vmmath.o: lj_vmmath.c lj_obj.h lua.h luaconf.h lj_def.h lj_arch.h \ + lj_ir.h lj_vm.h +ljamalg.o: ljamalg.c lua.h luaconf.h lauxlib.h lj_assert.c lj_obj.h \ + lj_def.h lj_arch.h lj_gc.c lj_gc.h lj_err.h lj_errmsg.h lj_buf.h \ + lj_str.h lj_tab.h lj_func.h lj_udata.h lj_meta.h lj_state.h lj_frame.h \ + lj_bc.h lj_ctype.h lj_cdata.h lj_trace.h lj_jit.h lj_ir.h lj_dispatch.h \ + lj_traceerr.h lj_vm.h lj_err.c lj_debug.h lj_ff.h lj_ffdef.h lj_strfmt.h \ + lj_char.c lj_char.h lj_bc.c lj_bcdef.h lj_obj.c lj_buf.c lj_str.c \ + lj_prng.h lj_tab.c lj_func.c lj_udata.c lj_meta.c lj_strscan.h lj_lib.h \ + lj_debug.c lj_prng.c lj_state.c lj_lex.h lj_alloc.h luajit.h \ + lj_dispatch.c lj_ccallback.h lj_profile.h lj_vmevent.c lj_vmevent.h \ + lj_vmmath.c lj_strscan.c lj_strfmt.c lj_strfmt_num.c lj_serialize.c \ + lj_serialize.h lj_api.c lj_profile.c lj_lex.c lualib.h lj_parse.h \ + lj_parse.c lj_bcread.c lj_bcdump.h lj_bcwrite.c lj_load.c lj_ctype.c \ + lj_cdata.c lj_cconv.h lj_cconv.c lj_ccall.c lj_ccall.h lj_ccallback.c \ + lj_target.h lj_target_*.h lj_mcode.h lj_carith.c lj_carith.h lj_clib.c \ + lj_clib.h lj_cparse.c lj_cparse.h lj_lib.c lj_ir.c lj_ircall.h \ + lj_iropt.h lj_opt_mem.c lj_opt_fold.c lj_folddef.h lj_opt_narrow.c \ + lj_opt_dce.c lj_opt_loop.c lj_snap.h lj_opt_split.c lj_opt_sink.c \ + lj_mcode.c lj_snap.c lj_record.c lj_record.h lj_ffrecord.h lj_crecord.c \ + lj_crecord.h lj_ffrecord.c lj_recdef.h lj_asm.c lj_asm.h lj_emit_*.h \ + lj_asm_*.h lj_trace.c lj_gdbjit.h lj_gdbjit.c lj_alloc.c lib_aux.c \ + lib_base.c lj_libdef.h lib_math.c lib_string.c lib_table.c lib_io.c \ + lib_os.c lib_package.c lib_debug.c lib_bit.c lib_jit.c lib_ffi.c \ + lib_buffer.c lib_init.c +luajit.o: luajit.c lua.h luaconf.h lauxlib.h lualib.h luajit.h lj_arch.h +host/buildvm.o: host/buildvm.c host/buildvm.h lj_def.h lua.h luaconf.h \ + lj_arch.h lj_obj.h lj_def.h lj_arch.h lj_gc.h lj_obj.h lj_bc.h lj_ir.h \ + lj_ircall.h lj_ir.h lj_jit.h lj_frame.h lj_bc.h lj_dispatch.h lj_ctype.h \ + lj_gc.h lj_ccall.h lj_ctype.h luajit.h \ + host/buildvm_arch.h lj_traceerr.h +host/buildvm_asm.o: host/buildvm_asm.c host/buildvm.h lj_def.h lua.h luaconf.h \ + lj_arch.h lj_bc.h lj_def.h lj_arch.h +host/buildvm_fold.o: host/buildvm_fold.c host/buildvm.h lj_def.h lua.h \ + luaconf.h lj_arch.h lj_obj.h lj_def.h lj_arch.h lj_ir.h lj_obj.h +host/buildvm_lib.o: host/buildvm_lib.c host/buildvm.h lj_def.h lua.h luaconf.h \ + lj_arch.h lj_obj.h lj_def.h lj_arch.h lj_bc.h lj_lib.h lj_obj.h \ + host/buildvm_libbc.h +host/buildvm_peobj.o: host/buildvm_peobj.c host/buildvm.h lj_def.h lua.h \ + luaconf.h lj_arch.h lj_bc.h lj_def.h lj_arch.h +host/minilua.o: host/minilua.c diff --git a/fluent-bit/lib/luajit-3065c9/src/host/.gitignore b/fluent-bit/lib/luajit-3065c9/src/host/.gitignore new file mode 100644 index 00000000..762ac2a0 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/host/.gitignore @@ -0,0 +1,3 @@ +minilua +buildvm +buildvm_arch.h diff --git a/fluent-bit/lib/luajit-3065c9/src/host/README b/fluent-bit/lib/luajit-3065c9/src/host/README new file mode 100644 index 00000000..abfcdaa7 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/host/README @@ -0,0 +1,4 @@ +The files in this directory are only used during the build process of LuaJIT. +For cross-compilation, they must be executed on the host, not on the target. + +These files should NOT be installed! diff --git a/fluent-bit/lib/luajit-3065c9/src/host/buildvm.c b/fluent-bit/lib/luajit-3065c9/src/host/buildvm.c new file mode 100644 index 00000000..9ee47ada --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/host/buildvm.c @@ -0,0 +1,528 @@ +/* +** LuaJIT VM builder. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +** +** This is a tool to build the hand-tuned assembler code required for +** LuaJIT's bytecode interpreter. It supports a variety of output formats +** to feed different toolchains (see usage() below). +** +** This tool is not particularly optimized because it's only used while +** _building_ LuaJIT. There's no point in distributing or installing it. +** Only the object code generated by this tool is linked into LuaJIT. +** +** Caveat: some memory is not free'd, error handling is lazy. +** It's a one-shot tool -- any effort fixing this would be wasted. +*/ + +#include "buildvm.h" +#include "lj_obj.h" +#include "lj_gc.h" +#include "lj_bc.h" +#if LJ_HASJIT +#include "lj_ir.h" +#include "lj_ircall.h" +#endif +#include "lj_frame.h" +#include "lj_dispatch.h" +#if LJ_HASFFI +#include "lj_ctype.h" +#include "lj_ccall.h" +#endif +#include "luajit.h" + +#if defined(_WIN32) +#include +#include +#endif + +/* ------------------------------------------------------------------------ */ + +/* DynASM glue definitions. */ +#define Dst ctx +#define Dst_DECL BuildCtx *ctx +#define Dst_REF (ctx->D) +#define DASM_CHECKS 1 + +#include "../dynasm/dasm_proto.h" + +/* Glue macros for DynASM. */ +static int collect_reloc(BuildCtx *ctx, uint8_t *addr, int idx, int type); + +#define DASM_EXTERN(ctx, addr, idx, type) \ + collect_reloc(ctx, addr, idx, type) + +/* ------------------------------------------------------------------------ */ + +/* Avoid trouble if cross-compiling for an x86 target. Speed doesn't matter. */ +#define DASM_ALIGNED_WRITES 1 + +/* Embed architecture-specific DynASM encoder. */ +#if LJ_TARGET_X86ORX64 +#include "../dynasm/dasm_x86.h" +#elif LJ_TARGET_ARM +#include "../dynasm/dasm_arm.h" +#elif LJ_TARGET_ARM64 +#include "../dynasm/dasm_arm64.h" +#elif LJ_TARGET_PPC +#include "../dynasm/dasm_ppc.h" +#elif LJ_TARGET_MIPS +#include "../dynasm/dasm_mips.h" +#else +#error "No support for this architecture (yet)" +#endif + +/* Embed generated architecture-specific backend. */ +#include "buildvm_arch.h" + +/* ------------------------------------------------------------------------ */ + +void owrite(BuildCtx *ctx, const void *ptr, size_t sz) +{ + if (fwrite(ptr, 1, sz, ctx->fp) != sz) { + fprintf(stderr, "Error: cannot write to output file: %s\n", + strerror(errno)); + exit(1); + } +} + +/* ------------------------------------------------------------------------ */ + +/* Emit code as raw bytes. Only used for DynASM debugging. */ +static void emit_raw(BuildCtx *ctx) +{ + owrite(ctx, ctx->code, ctx->codesz); +} + +/* -- Build machine code -------------------------------------------------- */ + +static const char *sym_decorate(BuildCtx *ctx, + const char *prefix, const char *suffix) +{ + char name[256]; + char *p; +#if LJ_64 + const char *symprefix = ctx->mode == BUILD_machasm ? "_" : ""; +#elif LJ_TARGET_XBOX360 + const char *symprefix = ""; +#else + const char *symprefix = ctx->mode != BUILD_elfasm ? "_" : ""; +#endif + sprintf(name, "%s%s%s", symprefix, prefix, suffix); + p = strchr(name, '@'); + if (p) { +#if LJ_TARGET_X86ORX64 + if (!LJ_64 && (ctx->mode == BUILD_coffasm || ctx->mode == BUILD_peobj)) + name[0] = name[1] == 'R' ? '_' : '@'; /* Just for _RtlUnwind@16. */ + else + *p = '\0'; +#elif LJ_TARGET_PPC && !LJ_TARGET_CONSOLE + /* Keep @plt etc. */ +#else + *p = '\0'; +#endif + } + p = (char *)malloc(strlen(name)+1); /* MSVC doesn't like strdup. */ + strcpy(p, name); + return p; +} + +#define NRELOCSYM (sizeof(extnames)/sizeof(extnames[0])-1) + +static int relocmap[NRELOCSYM]; + +/* Collect external relocations. */ +static int collect_reloc(BuildCtx *ctx, uint8_t *addr, int idx, int type) +{ + if (ctx->nreloc >= BUILD_MAX_RELOC) { + fprintf(stderr, "Error: too many relocations, increase BUILD_MAX_RELOC.\n"); + exit(1); + } + if (relocmap[idx] < 0) { + relocmap[idx] = ctx->nrelocsym; + ctx->relocsym[ctx->nrelocsym] = sym_decorate(ctx, "", extnames[idx]); + ctx->nrelocsym++; + } + ctx->reloc[ctx->nreloc].ofs = (int32_t)(addr - ctx->code); + ctx->reloc[ctx->nreloc].sym = relocmap[idx]; + ctx->reloc[ctx->nreloc].type = type; + ctx->nreloc++; +#if LJ_TARGET_XBOX360 + return (int)(ctx->code - addr) + 4; /* Encode symbol offset of .text. */ +#else + return 0; /* Encode symbol offset of 0. */ +#endif +} + +/* Naive insertion sort. Performance doesn't matter here. */ +static void sym_insert(BuildCtx *ctx, int32_t ofs, + const char *prefix, const char *suffix) +{ + ptrdiff_t i = ctx->nsym++; + while (i > 0) { + if (ctx->sym[i-1].ofs <= ofs) + break; + ctx->sym[i] = ctx->sym[i-1]; + i--; + } + ctx->sym[i].ofs = ofs; + ctx->sym[i].name = sym_decorate(ctx, prefix, suffix); +} + +/* Build the machine code. */ +static int build_code(BuildCtx *ctx) +{ + int status; + int i; + + /* Initialize DynASM structures. */ + ctx->nglob = GLOB__MAX; + ctx->glob = (void **)malloc(ctx->nglob*sizeof(void *)); + memset(ctx->glob, 0, ctx->nglob*sizeof(void *)); + ctx->nreloc = 0; + + ctx->globnames = globnames; + ctx->extnames = extnames; + ctx->relocsym = (const char **)malloc(NRELOCSYM*sizeof(const char *)); + ctx->nrelocsym = 0; + for (i = 0; i < (int)NRELOCSYM; i++) relocmap[i] = -1; + + ctx->dasm_ident = DASM_IDENT; + ctx->dasm_arch = DASM_ARCH; + + dasm_init(Dst, DASM_MAXSECTION); + dasm_setupglobal(Dst, ctx->glob, ctx->nglob); + dasm_setup(Dst, build_actionlist); + + /* Call arch-specific backend to emit the code. */ + ctx->npc = build_backend(ctx); + + /* Finalize the code. */ + (void)dasm_checkstep(Dst, -1); + if ((status = dasm_link(Dst, &ctx->codesz))) return status; + ctx->code = (uint8_t *)malloc(ctx->codesz); + if ((status = dasm_encode(Dst, (void *)ctx->code))) return status; + + /* Allocate symbol table and bytecode offsets. */ + ctx->beginsym = sym_decorate(ctx, "", LABEL_PREFIX "vm_asm_begin"); + ctx->sym = (BuildSym *)malloc((ctx->npc+ctx->nglob+1)*sizeof(BuildSym)); + ctx->nsym = 0; + ctx->bc_ofs = (int32_t *)malloc(ctx->npc*sizeof(int32_t)); + + /* Collect the opcodes (PC labels). */ + for (i = 0; i < ctx->npc; i++) { + int32_t ofs = dasm_getpclabel(Dst, i); + if (ofs < 0) return 0x22000000|i; + ctx->bc_ofs[i] = ofs; + if ((LJ_HASJIT || + !(i == BC_JFORI || i == BC_JFORL || i == BC_JITERL || i == BC_JLOOP || + i == BC_IFORL || i == BC_IITERL || i == BC_ILOOP)) && + (LJ_HASFFI || i != BC_KCDATA)) + sym_insert(ctx, ofs, LABEL_PREFIX_BC, bc_names[i]); + } + + /* Collect the globals (named labels). */ + for (i = 0; i < ctx->nglob; i++) { + const char *gl = globnames[i]; + int len = (int)strlen(gl); + if (!ctx->glob[i]) { + fprintf(stderr, "Error: undefined global %s\n", gl); + exit(2); + } + /* Skip the _Z symbols. */ + if (!(len >= 2 && gl[len-2] == '_' && gl[len-1] == 'Z')) + sym_insert(ctx, (int32_t)((uint8_t *)(ctx->glob[i]) - ctx->code), + LABEL_PREFIX, globnames[i]); + } + + /* Close the address range. */ + sym_insert(ctx, (int32_t)ctx->codesz, "", ""); + ctx->nsym--; + + dasm_free(Dst); + + return 0; +} + +/* -- Generate VM enums --------------------------------------------------- */ + +const char *const bc_names[] = { +#define BCNAME(name, ma, mb, mc, mt) #name, +BCDEF(BCNAME) +#undef BCNAME + NULL +}; + +#if LJ_HASJIT +const char *const ir_names[] = { +#define IRNAME(name, m, m1, m2) #name, +IRDEF(IRNAME) +#undef IRNAME + NULL +}; + +const char *const irt_names[] = { +#define IRTNAME(name, size) #name, +IRTDEF(IRTNAME) +#undef IRTNAME + NULL +}; + +const char *const irfpm_names[] = { +#define FPMNAME(name) #name, +IRFPMDEF(FPMNAME) +#undef FPMNAME + NULL +}; + +const char *const irfield_names[] = { +#define FLNAME(name, ofs) #name, +IRFLDEF(FLNAME) +#undef FLNAME + NULL +}; + +const char *const ircall_names[] = { +#define IRCALLNAME(cond, name, nargs, kind, type, flags) #name, +IRCALLDEF(IRCALLNAME) +#undef IRCALLNAME + NULL +}; + +static const char *const trace_errors[] = { +#define TREDEF(name, msg) msg, +#include "lj_traceerr.h" + NULL +}; +#endif + +#if LJ_HASJIT +static const char *lower(char *buf, const char *s) +{ + char *p = buf; + while (*s) { + *p++ = (*s >= 'A' && *s <= 'Z') ? *s+0x20 : *s; + s++; + } + *p = '\0'; + return buf; +} +#endif + +/* Emit C source code for bytecode-related definitions. */ +static void emit_bcdef(BuildCtx *ctx) +{ + int i; + fprintf(ctx->fp, "/* This is a generated file. DO NOT EDIT! */\n\n"); + fprintf(ctx->fp, "LJ_DATADEF const uint16_t lj_bc_ofs[] = {\n"); + for (i = 0; i < ctx->npc; i++) { + if (i != 0) + fprintf(ctx->fp, ",\n"); + fprintf(ctx->fp, "%d", ctx->bc_ofs[i]); + } +} + +/* Emit VM definitions as Lua code for debug modules. */ +static void emit_vmdef(BuildCtx *ctx) +{ +#if LJ_HASJIT + char buf[80]; +#endif + int i; + fprintf(ctx->fp, "-- This is a generated file. DO NOT EDIT!\n\n"); + fprintf(ctx->fp, "return {\n\n"); + + fprintf(ctx->fp, "bcnames = \""); + for (i = 0; bc_names[i]; i++) fprintf(ctx->fp, "%-6s", bc_names[i]); + fprintf(ctx->fp, "\",\n\n"); + +#if LJ_HASJIT + fprintf(ctx->fp, "irnames = \""); + for (i = 0; ir_names[i]; i++) fprintf(ctx->fp, "%-6s", ir_names[i]); + fprintf(ctx->fp, "\",\n\n"); + + fprintf(ctx->fp, "irfpm = { [0]="); + for (i = 0; irfpm_names[i]; i++) + fprintf(ctx->fp, "\"%s\", ", lower(buf, irfpm_names[i])); + fprintf(ctx->fp, "},\n\n"); + + fprintf(ctx->fp, "irfield = { [0]="); + for (i = 0; irfield_names[i]; i++) { + char *p; + lower(buf, irfield_names[i]); + p = strchr(buf, '_'); + if (p) *p = '.'; + fprintf(ctx->fp, "\"%s\", ", buf); + } + fprintf(ctx->fp, "},\n\n"); + + fprintf(ctx->fp, "ircall = {\n[0]="); + for (i = 0; ircall_names[i]; i++) + fprintf(ctx->fp, "\"%s\",\n", ircall_names[i]); + fprintf(ctx->fp, "},\n\n"); + + fprintf(ctx->fp, "traceerr = {\n[0]="); + for (i = 0; trace_errors[i]; i++) + fprintf(ctx->fp, "\"%s\",\n", trace_errors[i]); + fprintf(ctx->fp, "},\n\n"); +#endif +} + +/* -- Argument parsing ---------------------------------------------------- */ + +/* Build mode names. */ +static const char *const modenames[] = { +#define BUILDNAME(name) #name, +BUILDDEF(BUILDNAME) +#undef BUILDNAME + NULL +}; + +/* Print usage information and exit. */ +static void usage(void) +{ + int i; + fprintf(stderr, LUAJIT_VERSION " VM builder.\n"); + fprintf(stderr, LUAJIT_COPYRIGHT ", " LUAJIT_URL "\n"); + fprintf(stderr, "Target architecture: " LJ_ARCH_NAME "\n\n"); + fprintf(stderr, "Usage: buildvm -m mode [-o outfile] [infiles...]\n\n"); + fprintf(stderr, "Available modes:\n"); + for (i = 0; i < BUILD__MAX; i++) + fprintf(stderr, " %s\n", modenames[i]); + exit(1); +} + +/* Parse the output mode name. */ +static BuildMode parsemode(const char *mode) +{ + int i; + for (i = 0; modenames[i]; i++) + if (!strcmp(mode, modenames[i])) + return (BuildMode)i; + usage(); + return (BuildMode)-1; +} + +/* Parse arguments. */ +static void parseargs(BuildCtx *ctx, char **argv) +{ + const char *a; + int i; + ctx->mode = (BuildMode)-1; + ctx->outname = "-"; + for (i = 1; (a = argv[i]) != NULL; i++) { + if (a[0] != '-') + break; + switch (a[1]) { + case '-': + if (a[2]) goto err; + i++; + goto ok; + case '\0': + goto ok; + case 'm': + i++; + if (a[2] || argv[i] == NULL) goto err; + ctx->mode = parsemode(argv[i]); + break; + case 'o': + i++; + if (a[2] || argv[i] == NULL) goto err; + ctx->outname = argv[i]; + break; + default: err: + usage(); + break; + } + } +ok: + ctx->args = argv+i; + if (ctx->mode == (BuildMode)-1) goto err; +} + +int main(int argc, char **argv) +{ + BuildCtx ctx_; + BuildCtx *ctx = &ctx_; + int status, binmode; + + if (sizeof(void *) != 4*LJ_32+8*LJ_64) { + fprintf(stderr,"Error: pointer size mismatch in cross-build.\n"); + fprintf(stderr,"Try: make HOST_CC=\"gcc -m32\" CROSS=...\n\n"); + return 1; + } + + UNUSED(argc); + parseargs(ctx, argv); + + if ((status = build_code(ctx))) { + fprintf(stderr,"Error: DASM error %08x\n", status); + return 1; + } + + switch (ctx->mode) { + case BUILD_peobj: + case BUILD_raw: + binmode = 1; + break; + default: + binmode = 0; + break; + } + + if (ctx->outname[0] == '-' && ctx->outname[1] == '\0') { + ctx->fp = stdout; +#if defined(_WIN32) + if (binmode) + _setmode(_fileno(stdout), _O_BINARY); /* Yuck. */ +#endif + } else if (!(ctx->fp = fopen(ctx->outname, binmode ? "wb" : "w"))) { + fprintf(stderr, "Error: cannot open output file '%s': %s\n", + ctx->outname, strerror(errno)); + exit(1); + } + + switch (ctx->mode) { + case BUILD_elfasm: + case BUILD_coffasm: + case BUILD_machasm: + emit_asm(ctx); + emit_asm_debug(ctx); + break; + case BUILD_peobj: + emit_peobj(ctx); + break; + case BUILD_raw: + emit_raw(ctx); + break; + case BUILD_bcdef: + emit_bcdef(ctx); + emit_lib(ctx); + break; + case BUILD_vmdef: + emit_vmdef(ctx); + emit_lib(ctx); + fprintf(ctx->fp, "}\n\n"); + break; + case BUILD_ffdef: + case BUILD_libdef: + case BUILD_recdef: + emit_lib(ctx); + break; + case BUILD_folddef: + emit_fold(ctx); + break; + default: + break; + } + + fflush(ctx->fp); + if (ferror(ctx->fp)) { + fprintf(stderr, "Error: cannot write to output file: %s\n", + strerror(errno)); + exit(1); + } + fclose(ctx->fp); + + return 0; +} + diff --git a/fluent-bit/lib/luajit-3065c9/src/host/buildvm.h b/fluent-bit/lib/luajit-3065c9/src/host/buildvm.h new file mode 100644 index 00000000..18cd8848 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/host/buildvm.h @@ -0,0 +1,105 @@ +/* +** LuaJIT VM builder. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#ifndef _BUILDVM_H +#define _BUILDVM_H + +#include +#include +#include +#include +#include + +#include "lj_def.h" +#include "lj_arch.h" + +/* Hardcoded limits. Increase as needed. */ +#define BUILD_MAX_RELOC 200 /* Max. number of relocations. */ +#define BUILD_MAX_FOLD 4096 /* Max. number of fold rules. */ + +/* Prefix for scanned library definitions. */ +#define LIBDEF_PREFIX "LJLIB_" + +/* Prefix for scanned fold definitions. */ +#define FOLDDEF_PREFIX "LJFOLD" + +/* Prefixes for generated labels. */ +#define LABEL_PREFIX "lj_" +#define LABEL_PREFIX_BC LABEL_PREFIX "BC_" +#define LABEL_PREFIX_FF LABEL_PREFIX "ff_" +#define LABEL_PREFIX_CF LABEL_PREFIX "cf_" +#define LABEL_PREFIX_FFH LABEL_PREFIX "ffh_" +#define LABEL_PREFIX_LIBCF LABEL_PREFIX "lib_cf_" +#define LABEL_PREFIX_LIBINIT LABEL_PREFIX "lib_init_" + +/* Forward declaration. */ +struct dasm_State; + +/* Build modes. */ +#define BUILDDEF(_) \ + _(elfasm) _(coffasm) _(machasm) _(peobj) _(raw) \ + _(bcdef) _(ffdef) _(libdef) _(recdef) _(vmdef) \ + _(folddef) + +typedef enum { +#define BUILDENUM(name) BUILD_##name, +BUILDDEF(BUILDENUM) +#undef BUILDENUM + BUILD__MAX +} BuildMode; + +/* Code relocation. */ +typedef struct BuildReloc { + int32_t ofs; + int sym; + int type; +} BuildReloc; + +typedef struct BuildSym { + const char *name; + int32_t ofs; +} BuildSym; + +/* Build context structure. */ +typedef struct BuildCtx { + /* DynASM state pointer. Should be first member. */ + struct dasm_State *D; + /* Parsed command line. */ + BuildMode mode; + FILE *fp; + const char *outname; + char **args; + /* Code and symbols generated by DynASM. */ + uint8_t *code; + size_t codesz; + int npc, nglob, nsym, nreloc, nrelocsym; + void **glob; + BuildSym *sym; + const char **relocsym; + int32_t *bc_ofs; + const char *beginsym; + /* Strings generated by DynASM. */ + const char *const *globnames; + const char *const *extnames; + const char *dasm_ident; + const char *dasm_arch; + /* Relocations. */ + BuildReloc reloc[BUILD_MAX_RELOC]; +} BuildCtx; + +extern void owrite(BuildCtx *ctx, const void *ptr, size_t sz); +extern void emit_asm(BuildCtx *ctx); +extern void emit_peobj(BuildCtx *ctx); +extern void emit_lib(BuildCtx *ctx); +extern void emit_fold(BuildCtx *ctx); + +extern const char *const bc_names[]; +extern const char *const ir_names[]; +extern const char *const irt_names[]; +extern const char *const irfpm_names[]; +extern const char *const irfield_names[]; +extern const char *const ircall_names[]; + +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/host/buildvm_asm.c b/fluent-bit/lib/luajit-3065c9/src/host/buildvm_asm.c new file mode 100644 index 00000000..7baa011f --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/host/buildvm_asm.c @@ -0,0 +1,348 @@ +/* +** LuaJIT VM builder: Assembler source code emitter. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#include "buildvm.h" +#include "lj_bc.h" + +/* ------------------------------------------------------------------------ */ + +#if LJ_TARGET_X86ORX64 +/* Emit bytes piecewise as assembler text. */ +static void emit_asm_bytes(BuildCtx *ctx, uint8_t *p, int n) +{ + int i; + for (i = 0; i < n; i++) { + if ((i & 15) == 0) + fprintf(ctx->fp, "\t.byte %d", p[i]); + else + fprintf(ctx->fp, ",%d", p[i]); + if ((i & 15) == 15) putc('\n', ctx->fp); + } + if ((n & 15) != 0) putc('\n', ctx->fp); +} + +/* Emit relocation */ +static void emit_asm_reloc(BuildCtx *ctx, int type, const char *sym) +{ + switch (ctx->mode) { + case BUILD_elfasm: + if (type) + fprintf(ctx->fp, "\t.long %s-.-4\n", sym); + else + fprintf(ctx->fp, "\t.long %s\n", sym); + break; + case BUILD_coffasm: + fprintf(ctx->fp, "\t.def %s; .scl 3; .type 32; .endef\n", sym); + if (type) + fprintf(ctx->fp, "\t.long %s-.-4\n", sym); + else + fprintf(ctx->fp, "\t.long %s\n", sym); + break; + default: /* BUILD_machasm for relative relocations handled below. */ + fprintf(ctx->fp, "\t.long %s\n", sym); + break; + } +} + +static const char *const jccnames[] = { + "jo", "jno", "jb", "jnb", "jz", "jnz", "jbe", "ja", + "js", "jns", "jpe", "jpo", "jl", "jge", "jle", "jg" +}; + +/* Emit x86/x64 text relocations. */ +static void emit_asm_reloc_text(BuildCtx *ctx, uint8_t *cp, int n, + const char *sym) +{ + const char *opname = NULL; + if (--n < 0) goto err; + if (cp[n] == 0xe8) { + opname = "call"; + } else if (cp[n] == 0xe9) { + opname = "jmp"; + } else if (cp[n] >= 0x80 && cp[n] <= 0x8f && n > 0 && cp[n-1] == 0x0f) { + opname = jccnames[cp[n]-0x80]; + n--; + } else { +err: + fprintf(stderr, "Error: unsupported opcode for %s symbol relocation.\n", + sym); + exit(1); + } + emit_asm_bytes(ctx, cp, n); + if (strncmp(sym+(*sym == '_'), LABEL_PREFIX, sizeof(LABEL_PREFIX)-1)) { + /* Various fixups for external symbols outside of our binary. */ + if (ctx->mode == BUILD_elfasm) { + if (LJ_32) + fprintf(ctx->fp, "#if __PIC__\n\t%s lj_wrap_%s\n#else\n", opname, sym); + fprintf(ctx->fp, "\t%s %s@PLT\n", opname, sym); + if (LJ_32) + fprintf(ctx->fp, "#endif\n"); + return; + } else if (LJ_32 && ctx->mode == BUILD_machasm) { + fprintf(ctx->fp, "\t%s L%s$stub\n", opname, sym); + return; + } + } + fprintf(ctx->fp, "\t%s %s\n", opname, sym); +} +#else +/* Emit words piecewise as assembler text. */ +static void emit_asm_words(BuildCtx *ctx, uint8_t *p, int n) +{ + int i; + for (i = 0; i < n; i += 4) { + uint32_t ins = *(uint32_t *)(p+i); +#if LJ_TARGET_ARM64 && LJ_BE + ins = lj_bswap(ins); /* ARM64 instructions are always little-endian. */ +#endif + if ((i & 15) == 0) + fprintf(ctx->fp, "\t.long 0x%08x", ins); + else + fprintf(ctx->fp, ",0x%08x", ins); + if ((i & 15) == 12) putc('\n', ctx->fp); + } + if ((n & 15) != 0) putc('\n', ctx->fp); +} + +/* Emit relocation as part of an instruction. */ +static void emit_asm_wordreloc(BuildCtx *ctx, uint8_t *p, int n, + const char *sym) +{ + uint32_t ins; + emit_asm_words(ctx, p, n-4); + ins = *(uint32_t *)(p+n-4); +#if LJ_TARGET_ARM + if ((ins & 0xff000000u) == 0xfa000000u) { + fprintf(ctx->fp, "\tblx %s\n", sym); + } else if ((ins & 0x0e000000u) == 0x0a000000u) { + fprintf(ctx->fp, "\t%s%.2s %s\n", (ins & 0x01000000u) ? "bl" : "b", + &"eqnecsccmiplvsvchilsgeltgtle"[2*(ins >> 28)], sym); + } else { + fprintf(stderr, + "Error: unsupported opcode %08x for %s symbol relocation.\n", + ins, sym); + exit(1); + } +#elif LJ_TARGET_ARM64 + if ((ins >> 26) == 0x25u) { + fprintf(ctx->fp, "\tbl %s\n", sym); + } else { + fprintf(stderr, + "Error: unsupported opcode %08x for %s symbol relocation.\n", + ins, sym); + exit(1); + } +#elif LJ_TARGET_PPC +#if LJ_TARGET_PS3 +#define TOCPREFIX "." +#else +#define TOCPREFIX "" +#endif + if ((ins >> 26) == 16) { + fprintf(ctx->fp, "\t%s %d, %d, " TOCPREFIX "%s\n", + (ins & 1) ? "bcl" : "bc", (ins >> 21) & 31, (ins >> 16) & 31, sym); + } else if ((ins >> 26) == 18) { + fprintf(ctx->fp, "\t%s " TOCPREFIX "%s\n", (ins & 1) ? "bl" : "b", sym); + } else { + fprintf(stderr, + "Error: unsupported opcode %08x for %s symbol relocation.\n", + ins, sym); + exit(1); + } +#elif LJ_TARGET_MIPS + fprintf(stderr, + "Error: unsupported opcode %08x for %s symbol relocation.\n", + ins, sym); + exit(1); +#else +#error "missing relocation support for this architecture" +#endif +} +#endif + +#if LJ_TARGET_ARM +#define ELFASM_PX "%%" +#else +#define ELFASM_PX "@" +#endif + +/* Emit an assembler label. */ +static void emit_asm_label(BuildCtx *ctx, const char *name, int size, int isfunc) +{ + switch (ctx->mode) { + case BUILD_elfasm: +#if LJ_TARGET_PS3 + if (!strncmp(name, "lj_vm_", 6) && + strcmp(name, ctx->beginsym) && + !strstr(name, "hook")) { + fprintf(ctx->fp, + "\n\t.globl %s\n" + "\t.section \".opd\",\"aw\"\n" + "%s:\n" + "\t.long .%s,.TOC.@tocbase32\n" + "\t.size %s,8\n" + "\t.previous\n" + "\t.globl .%s\n" + "\t.hidden .%s\n" + "\t.type .%s, " ELFASM_PX "function\n" + "\t.size .%s, %d\n" + ".%s:\n", + name, name, name, name, name, name, name, name, size, name); + break; + } +#endif + fprintf(ctx->fp, + "\n\t.globl %s\n" + "\t.hidden %s\n" + "\t.type %s, " ELFASM_PX "%s\n" + "\t.size %s, %d\n" + "%s:\n", + name, name, name, isfunc ? "function" : "object", name, size, name); + break; + case BUILD_coffasm: + fprintf(ctx->fp, "\n\t.globl %s\n", name); + if (isfunc) + fprintf(ctx->fp, "\t.def %s; .scl 3; .type 32; .endef\n", name); + fprintf(ctx->fp, "%s:\n", name); + break; + case BUILD_machasm: + fprintf(ctx->fp, + "\n\t.private_extern %s\n" + "\t.no_dead_strip %s\n" + "%s:\n", name, name, name); + break; + default: + break; + } +} + +/* Emit alignment. */ +static void emit_asm_align(BuildCtx *ctx, int bits) +{ + switch (ctx->mode) { + case BUILD_elfasm: + case BUILD_coffasm: + fprintf(ctx->fp, "\t.p2align %d\n", bits); + break; + case BUILD_machasm: + fprintf(ctx->fp, "\t.align %d\n", bits); + break; + default: + break; + } +} + +/* ------------------------------------------------------------------------ */ + +/* Emit assembler source code. */ +void emit_asm(BuildCtx *ctx) +{ + int i, rel; + + fprintf(ctx->fp, "\t.file \"buildvm_%s.dasc\"\n", ctx->dasm_arch); + fprintf(ctx->fp, "\t.text\n"); + emit_asm_align(ctx, 4); + +#if LJ_TARGET_PS3 + emit_asm_label(ctx, ctx->beginsym, ctx->codesz, 0); +#else + emit_asm_label(ctx, ctx->beginsym, 0, 0); +#endif + if (ctx->mode != BUILD_machasm) + fprintf(ctx->fp, ".Lbegin:\n"); + +#if LJ_TARGET_ARM && defined(__GNUC__) && !LJ_NO_UNWIND + /* This should really be moved into buildvm_arm.dasc. */ +#if LJ_ARCH_HASFPU + fprintf(ctx->fp, + ".fnstart\n" + ".save {r5, r6, r7, r8, r9, r10, r11, lr}\n" + ".vsave {d8-d15}\n" + ".save {r4}\n" + ".pad #28\n"); +#else + fprintf(ctx->fp, + ".fnstart\n" + ".save {r4, r5, r6, r7, r8, r9, r10, r11, lr}\n" + ".pad #28\n"); +#endif +#endif +#if LJ_TARGET_MIPS + fprintf(ctx->fp, ".set nomips16\n.abicalls\n.set noreorder\n.set nomacro\n"); +#endif + + for (i = rel = 0; i < ctx->nsym; i++) { + int32_t ofs = ctx->sym[i].ofs; + int32_t next = ctx->sym[i+1].ofs; +#if LJ_TARGET_ARM && defined(__GNUC__) && !LJ_NO_UNWIND && LJ_HASFFI + if (!strcmp(ctx->sym[i].name, "lj_vm_ffi_call")) + fprintf(ctx->fp, + ".globl lj_err_unwind_arm\n" + ".personality lj_err_unwind_arm\n" + ".fnend\n" + ".fnstart\n" + ".save {r4, r5, r11, lr}\n" + ".setfp r11, sp\n"); +#endif + emit_asm_label(ctx, ctx->sym[i].name, next - ofs, 1); + while (rel < ctx->nreloc && ctx->reloc[rel].ofs <= next) { + BuildReloc *r = &ctx->reloc[rel]; + int n = r->ofs - ofs; +#if LJ_TARGET_X86ORX64 + if (r->type != 0 && + (ctx->mode == BUILD_elfasm || ctx->mode == BUILD_machasm)) { + emit_asm_reloc_text(ctx, ctx->code+ofs, n, ctx->relocsym[r->sym]); + } else { + emit_asm_bytes(ctx, ctx->code+ofs, n); + emit_asm_reloc(ctx, r->type, ctx->relocsym[r->sym]); + } + ofs += n+4; +#else + emit_asm_wordreloc(ctx, ctx->code+ofs, n, ctx->relocsym[r->sym]); + ofs += n; +#endif + rel++; + } +#if LJ_TARGET_X86ORX64 + emit_asm_bytes(ctx, ctx->code+ofs, next-ofs); +#else + emit_asm_words(ctx, ctx->code+ofs, next-ofs); +#endif + } + +#if LJ_TARGET_ARM && defined(__GNUC__) && !LJ_NO_UNWIND + fprintf(ctx->fp, +#if !LJ_HASFFI + ".globl lj_err_unwind_arm\n" + ".personality lj_err_unwind_arm\n" +#endif + ".fnend\n"); +#endif + + fprintf(ctx->fp, "\n"); + switch (ctx->mode) { + case BUILD_elfasm: +#if !(LJ_TARGET_PS3 || LJ_TARGET_PSVITA) + fprintf(ctx->fp, "\t.section .note.GNU-stack,\"\"," ELFASM_PX "progbits\n"); +#endif +#if LJ_TARGET_PPC && !LJ_TARGET_PS3 && !LJ_ABI_SOFTFP + /* Hard-float ABI. */ + fprintf(ctx->fp, "\t.gnu_attribute 4, 1\n"); +#endif + /* fallthrough */ + case BUILD_coffasm: + fprintf(ctx->fp, "\t.ident \"%s\"\n", ctx->dasm_ident); + break; + case BUILD_machasm: + fprintf(ctx->fp, + "\t.cstring\n" + "\t.ascii \"%s\\0\"\n", ctx->dasm_ident); + break; + default: + break; + } + fprintf(ctx->fp, "\n"); +} + diff --git a/fluent-bit/lib/luajit-3065c9/src/host/buildvm_fold.c b/fluent-bit/lib/luajit-3065c9/src/host/buildvm_fold.c new file mode 100644 index 00000000..edb55768 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/host/buildvm_fold.c @@ -0,0 +1,236 @@ +/* +** LuaJIT VM builder: IR folding hash table generator. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#include "buildvm.h" +#include "lj_obj.h" +#if LJ_HASJIT +#include "lj_ir.h" + +/* Context for the folding hash table generator. */ +static int lineno; +static uint32_t funcidx; +static uint32_t foldkeys[BUILD_MAX_FOLD]; +static uint32_t nkeys; + +/* Try to fill the hash table with keys using the hash parameters. */ +static int tryhash(uint32_t *htab, uint32_t sz, uint32_t r, int dorol) +{ + uint32_t i; + if (dorol && ((r & 31) == 0 || (r>>5) == 0)) + return 0; /* Avoid zero rotates. */ + memset(htab, 0xff, (sz+1)*sizeof(uint32_t)); + for (i = 0; i < nkeys; i++) { + uint32_t key = foldkeys[i]; + uint32_t k = key & 0xffffff; + uint32_t h = (dorol ? lj_rol(lj_rol(k, r>>5) - k, r&31) : + (((k << (r>>5)) - k) << (r&31))) % sz; + if (htab[h] != 0xffffffff) { /* Collision on primary slot. */ + if (htab[h+1] != 0xffffffff) { /* Collision on secondary slot. */ + /* Try to move the colliding key, if possible. */ + if (h < sz-1 && htab[h+2] == 0xffffffff) { + uint32_t k2 = htab[h+1] & 0xffffff; + uint32_t h2 = (dorol ? lj_rol(lj_rol(k2, r>>5) - k2, r&31) : + (((k2 << (r>>5)) - k2) << (r&31))) % sz; + if (h2 != h+1) return 0; /* Cannot resolve collision. */ + htab[h+2] = htab[h+1]; /* Move colliding key to secondary slot. */ + } else { + return 0; /* Collision. */ + } + } + htab[h+1] = key; + } else { + htab[h] = key; + } + } + return 1; /* Success, all keys could be stored. */ +} + +/* Print the generated hash table. */ +static void printhash(BuildCtx *ctx, uint32_t *htab, uint32_t sz) +{ + uint32_t i; + fprintf(ctx->fp, "static const uint32_t fold_hash[%d] = {\n0x%08x", + sz+1, htab[0]); + for (i = 1; i < sz+1; i++) + fprintf(ctx->fp, ",\n0x%08x", htab[i]); + fprintf(ctx->fp, "\n};\n\n"); +} + +/* Exhaustive search for the shortest semi-perfect hash table. */ +static void makehash(BuildCtx *ctx) +{ + uint32_t htab[BUILD_MAX_FOLD*2+1]; + uint32_t sz, r; + /* Search for the smallest hash table with an odd size. */ + for (sz = (nkeys|1); sz < BUILD_MAX_FOLD*2; sz += 2) { + /* First try all shift hash combinations. */ + for (r = 0; r < 32*32; r++) { + if (tryhash(htab, sz, r, 0)) { + printhash(ctx, htab, sz); + fprintf(ctx->fp, + "#define fold_hashkey(k)\t(((((k)<<%u)-(k))<<%u)%%%u)\n\n", + r>>5, r&31, sz); + return; + } + } + /* Then try all rotate hash combinations. */ + for (r = 0; r < 32*32; r++) { + if (tryhash(htab, sz, r, 1)) { + printhash(ctx, htab, sz); + fprintf(ctx->fp, + "#define fold_hashkey(k)\t(lj_rol(lj_rol((k),%u)-(k),%u)%%%u)\n\n", + r>>5, r&31, sz); + return; + } + } + } + fprintf(stderr, "Error: search for perfect hash failed\n"); + exit(1); +} + +/* Parse one token of a fold rule. */ +static uint32_t nexttoken(char **pp, int allowlit, int allowany) +{ + char *p = *pp; + if (p) { + uint32_t i; + char *q = strchr(p, ' '); + if (q) *q++ = '\0'; + *pp = q; + if (allowlit && !strncmp(p, "IRFPM_", 6)) { + for (i = 0; irfpm_names[i]; i++) + if (!strcmp(irfpm_names[i], p+6)) + return i; + } else if (allowlit && !strncmp(p, "IRFL_", 5)) { + for (i = 0; irfield_names[i]; i++) + if (!strcmp(irfield_names[i], p+5)) + return i; + } else if (allowlit && !strncmp(p, "IRCALL_", 7)) { + for (i = 0; ircall_names[i]; i++) + if (!strcmp(ircall_names[i], p+7)) + return i; + } else if (allowlit && !strncmp(p, "IRCONV_", 7)) { + for (i = 0; irt_names[i]; i++) { + const char *r = strchr(p+7, '_'); + if (r && !strncmp(irt_names[i], p+7, r-(p+7))) { + uint32_t j; + for (j = 0; irt_names[j]; j++) + if (!strcmp(irt_names[j], r+1)) + return (i << 5) + j; + } + } + } else if (allowlit && *p >= '0' && *p <= '9') { + for (i = 0; *p >= '0' && *p <= '9'; p++) + i = i*10 + (*p - '0'); + if (*p == '\0') + return i; + } else if (allowany && !strcmp("any", p)) { + return allowany; + } else { + for (i = 0; ir_names[i]; i++) + if (!strcmp(ir_names[i], p)) + return i; + } + fprintf(stderr, "Error: bad fold definition token \"%s\" at line %d\n", p, lineno); + exit(1); + } + return 0; +} + +/* Parse a fold rule. */ +static void foldrule(char *p) +{ + uint32_t op = nexttoken(&p, 0, 0); + uint32_t left = nexttoken(&p, 0, 0x7f); + uint32_t right = nexttoken(&p, 1, 0x3ff); + uint32_t key = (funcidx << 24) | (op << 17) | (left << 10) | right; + uint32_t i; + if (nkeys >= BUILD_MAX_FOLD) { + fprintf(stderr, "Error: too many fold rules, increase BUILD_MAX_FOLD.\n"); + exit(1); + } + /* Simple insertion sort to detect duplicates. */ + for (i = nkeys; i > 0; i--) { + if ((foldkeys[i-1]&0xffffff) < (key & 0xffffff)) + break; + if ((foldkeys[i-1]&0xffffff) == (key & 0xffffff)) { + fprintf(stderr, "Error: duplicate fold definition at line %d\n", lineno); + exit(1); + } + foldkeys[i] = foldkeys[i-1]; + } + foldkeys[i] = key; + nkeys++; +} + +/* Emit C source code for IR folding hash table. */ +void emit_fold(BuildCtx *ctx) +{ + char buf[256]; /* We don't care about analyzing lines longer than that. */ + const char *fname = ctx->args[0]; + FILE *fp; + + if (fname == NULL) { + fprintf(stderr, "Error: missing input filename\n"); + exit(1); + } + + if (fname[0] == '-' && fname[1] == '\0') { + fp = stdin; + } else { + fp = fopen(fname, "r"); + if (!fp) { + fprintf(stderr, "Error: cannot open input file '%s': %s\n", + fname, strerror(errno)); + exit(1); + } + } + + fprintf(ctx->fp, "/* This is a generated file. DO NOT EDIT! */\n\n"); + fprintf(ctx->fp, "static const FoldFunc fold_func[] = {\n"); + + lineno = 0; + funcidx = 0; + nkeys = 0; + while (fgets(buf, sizeof(buf), fp) != NULL) { + lineno++; + /* The prefix must be at the start of a line, otherwise it's ignored. */ + if (!strncmp(buf, FOLDDEF_PREFIX, sizeof(FOLDDEF_PREFIX)-1)) { + char *p = buf+sizeof(FOLDDEF_PREFIX)-1; + char *q = strchr(p, ')'); + if (p[0] == '(' && q) { + p++; + *q = '\0'; + foldrule(p); + } else if ((p[0] == 'F' || p[0] == 'X') && p[1] == '(' && q) { + p += 2; + *q = '\0'; + if (funcidx) + fprintf(ctx->fp, ",\n"); + if (p[-2] == 'X') + fprintf(ctx->fp, " %s", p); + else + fprintf(ctx->fp, " fold_%s", p); + funcidx++; + } else { + buf[strlen(buf)-1] = '\0'; + fprintf(stderr, "Error: unknown fold definition tag %s%s at line %d\n", + FOLDDEF_PREFIX, p, lineno); + exit(1); + } + } + } + fclose(fp); + fprintf(ctx->fp, "\n};\n\n"); + + makehash(ctx); +} +#else +void emit_fold(BuildCtx *ctx) +{ + UNUSED(ctx); +} +#endif + diff --git a/fluent-bit/lib/luajit-3065c9/src/host/buildvm_lib.c b/fluent-bit/lib/luajit-3065c9/src/host/buildvm_lib.c new file mode 100644 index 00000000..b125ea12 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/host/buildvm_lib.c @@ -0,0 +1,459 @@ +/* +** LuaJIT VM builder: library definition compiler. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#include "buildvm.h" +#include "lj_obj.h" +#include "lj_bc.h" +#include "lj_lib.h" +#include "buildvm_libbc.h" + +/* Context for library definitions. */ +static uint8_t obuf[8192]; +static uint8_t *optr; +static char modname[80]; +static size_t modnamelen; +static char funcname[80]; +static int modstate, regfunc; +static int ffid, recffid, ffasmfunc; + +enum { + REGFUNC_OK, + REGFUNC_NOREG, + REGFUNC_NOREGUV +}; + +static void libdef_name(const char *p, int kind) +{ + size_t n = strlen(p); + if (kind != LIBINIT_STRING) { + if (n > modnamelen && p[modnamelen] == '_' && + !strncmp(p, modname, modnamelen)) { + p += modnamelen+1; + n -= modnamelen+1; + } + } + if (n > LIBINIT_MAXSTR) { + fprintf(stderr, "Error: string too long: '%s'\n", p); + exit(1); + } + if (optr+1+n+2 > obuf+sizeof(obuf)) { /* +2 for caller. */ + fprintf(stderr, "Error: output buffer overflow\n"); + exit(1); + } + *optr++ = (uint8_t)(n | kind); + memcpy(optr, p, n); + optr += n; +} + +static void libdef_endmodule(BuildCtx *ctx) +{ + if (modstate != 0) { + char line[80]; + const uint8_t *p; + int n; + if (modstate == 1) + fprintf(ctx->fp, " (lua_CFunction)0"); + fprintf(ctx->fp, "\n};\n"); + fprintf(ctx->fp, "static const uint8_t %s%s[] = {\n", + LABEL_PREFIX_LIBINIT, modname); + line[0] = '\0'; + for (n = 0, p = obuf; p < optr; p++) { + n += sprintf(line+n, "%d,", *p); + if (n >= 75) { + fprintf(ctx->fp, "%s\n", line); + n = 0; + line[0] = '\0'; + } + } + fprintf(ctx->fp, "%s%d\n};\n#endif\n\n", line, LIBINIT_END); + } +} + +static void libdef_module(BuildCtx *ctx, char *p, int arg) +{ + UNUSED(arg); + if (ctx->mode == BUILD_libdef) { + libdef_endmodule(ctx); + optr = obuf; + *optr++ = (uint8_t)ffid; + *optr++ = (uint8_t)ffasmfunc; + *optr++ = 0; /* Hash table size. */ + modstate = 1; + fprintf(ctx->fp, "#ifdef %sMODULE_%s\n", LIBDEF_PREFIX, p); + fprintf(ctx->fp, "#undef %sMODULE_%s\n", LIBDEF_PREFIX, p); + fprintf(ctx->fp, "static const lua_CFunction %s%s[] = {\n", + LABEL_PREFIX_LIBCF, p); + } + modnamelen = strlen(p); + if (modnamelen > sizeof(modname)-1) { + fprintf(stderr, "Error: module name too long: '%s'\n", p); + exit(1); + } + strcpy(modname, p); +} + +static int find_ffofs(BuildCtx *ctx, const char *name) +{ + int i; + for (i = 0; i < ctx->nglob; i++) { + const char *gl = ctx->globnames[i]; + if (gl[0] == 'f' && gl[1] == 'f' && gl[2] == '_' && !strcmp(gl+3, name)) { + return (int)((uint8_t *)ctx->glob[i] - ctx->code); + } + } + fprintf(stderr, "Error: undefined fast function %s%s\n", + LABEL_PREFIX_FF, name); + exit(1); +} + +static void libdef_func(BuildCtx *ctx, char *p, int arg) +{ + if (arg != LIBINIT_CF) + ffasmfunc++; + if (ctx->mode == BUILD_libdef) { + if (modstate == 0) { + fprintf(stderr, "Error: no module for function definition %s\n", p); + exit(1); + } + if (regfunc == REGFUNC_NOREG) { + if (optr+1 > obuf+sizeof(obuf)) { + fprintf(stderr, "Error: output buffer overflow\n"); + exit(1); + } + *optr++ = LIBINIT_FFID; + } else { + if (arg != LIBINIT_ASM_) { + if (modstate != 1) fprintf(ctx->fp, ",\n"); + modstate = 2; + fprintf(ctx->fp, " %s%s", arg ? LABEL_PREFIX_FFH : LABEL_PREFIX_CF, p); + } + if (regfunc != REGFUNC_NOREGUV) obuf[2]++; /* Bump hash table size. */ + libdef_name(regfunc == REGFUNC_NOREGUV ? "" : p, arg); + } + } else if (ctx->mode == BUILD_ffdef) { + fprintf(ctx->fp, "FFDEF(%s)\n", p); + } else if (ctx->mode == BUILD_recdef) { + if (strlen(p) > sizeof(funcname)-1) { + fprintf(stderr, "Error: function name too long: '%s'\n", p); + exit(1); + } + strcpy(funcname, p); + } else if (ctx->mode == BUILD_vmdef) { + int i; + for (i = 1; p[i] && modname[i-1]; i++) + if (p[i] == '_') p[i] = '.'; + fprintf(ctx->fp, "\"%s\",\n", p); + } else if (ctx->mode == BUILD_bcdef) { + if (arg != LIBINIT_CF) + fprintf(ctx->fp, ",\n%d", find_ffofs(ctx, p)); + } + ffid++; + regfunc = REGFUNC_OK; +} + +static uint8_t *libdef_uleb128(uint8_t *p, uint32_t *vv) +{ + uint32_t v = *p++; + if (v >= 0x80) { + int sh = 0; v &= 0x7f; + do { v |= ((*p & 0x7f) << (sh += 7)); } while (*p++ >= 0x80); + } + *vv = v; + return p; +} + +static void libdef_fixupbc(uint8_t *p) +{ + uint32_t i, sizebc; + p += 4; + p = libdef_uleb128(p, &sizebc); + p = libdef_uleb128(p, &sizebc); + p = libdef_uleb128(p, &sizebc); + for (i = 0; i < sizebc; i++, p += 4) { + uint8_t op = p[libbc_endian ? 3 : 0]; + uint8_t ra = p[libbc_endian ? 2 : 1]; + uint8_t rc = p[libbc_endian ? 1 : 2]; + uint8_t rb = p[libbc_endian ? 0 : 3]; + if (!LJ_DUALNUM && op == BC_ISTYPE && rc == ~LJ_TNUMX+1) { + op = BC_ISNUM; rc++; + } + p[LJ_ENDIAN_SELECT(0, 3)] = op; + p[LJ_ENDIAN_SELECT(1, 2)] = ra; + p[LJ_ENDIAN_SELECT(2, 1)] = rc; + p[LJ_ENDIAN_SELECT(3, 0)] = rb; + } +} + +static void libdef_lua(BuildCtx *ctx, char *p, int arg) +{ + UNUSED(arg); + if (ctx->mode == BUILD_libdef) { + int i; + for (i = 0; libbc_map[i].name != NULL; i++) { + if (!strcmp(libbc_map[i].name, p)) { + int ofs = libbc_map[i].ofs; + int len = libbc_map[i+1].ofs - ofs; + obuf[2]++; /* Bump hash table size. */ + *optr++ = LIBINIT_LUA; + libdef_name(p, 0); + memcpy(optr, libbc_code + ofs, len); + libdef_fixupbc(optr); + optr += len; + return; + } + } + fprintf(stderr, "Error: missing libbc definition for %s\n", p); + exit(1); + } +} + +static uint32_t find_rec(char *name) +{ + char *p = (char *)obuf; + uint32_t n; + for (n = 2; *p; n++) { + if (strcmp(p, name) == 0) + return n; + p += strlen(p)+1; + } + if (p+strlen(name)+1 >= (char *)obuf+sizeof(obuf)) { + fprintf(stderr, "Error: output buffer overflow\n"); + exit(1); + } + strcpy(p, name); + return n; +} + +static void libdef_rec(BuildCtx *ctx, char *p, int arg) +{ + UNUSED(arg); + if (ctx->mode == BUILD_recdef) { + char *q; + uint32_t n; + for (; recffid+1 < ffid; recffid++) + fprintf(ctx->fp, ",\n0"); + recffid = ffid; + if (*p == '.') p = funcname; + q = strchr(p, ' '); + if (q) *q++ = '\0'; + n = find_rec(p); + if (q) + fprintf(ctx->fp, ",\n0x%02x00+(%s)", n, q); + else + fprintf(ctx->fp, ",\n0x%02x00", n); + } +} + +static void memcpy_endian(void *dst, void *src, size_t n) +{ + union { uint8_t b; uint32_t u; } host_endian; + host_endian.u = 1; + if (host_endian.b == LJ_ENDIAN_SELECT(1, 0)) { + memcpy(dst, src, n); + } else { + size_t i; + for (i = 0; i < n; i++) + ((uint8_t *)dst)[i] = ((uint8_t *)src)[n-i-1]; + } +} + +static void libdef_push(BuildCtx *ctx, char *p, int arg) +{ + UNUSED(arg); + if (ctx->mode == BUILD_libdef) { + int len = (int)strlen(p); + if (*p == '"') { + if (len > 1 && p[len-1] == '"') { + p[len-1] = '\0'; + libdef_name(p+1, LIBINIT_STRING); + return; + } + } else if (*p >= '0' && *p <= '9') { + char *ep; + double d = strtod(p, &ep); + if (*ep == '\0') { + if (optr+1+sizeof(double) > obuf+sizeof(obuf)) { + fprintf(stderr, "Error: output buffer overflow\n"); + exit(1); + } + *optr++ = LIBINIT_NUMBER; + memcpy_endian(optr, &d, sizeof(double)); + optr += sizeof(double); + return; + } + } else if (!strcmp(p, "lastcl")) { + if (optr+1 > obuf+sizeof(obuf)) { + fprintf(stderr, "Error: output buffer overflow\n"); + exit(1); + } + *optr++ = LIBINIT_LASTCL; + return; + } else if (len > 4 && !strncmp(p, "top-", 4)) { + if (optr+2 > obuf+sizeof(obuf)) { + fprintf(stderr, "Error: output buffer overflow\n"); + exit(1); + } + *optr++ = LIBINIT_COPY; + *optr++ = (uint8_t)atoi(p+4); + return; + } + fprintf(stderr, "Error: bad value for %sPUSH(%s)\n", LIBDEF_PREFIX, p); + exit(1); + } +} + +static void libdef_set(BuildCtx *ctx, char *p, int arg) +{ + UNUSED(arg); + if (ctx->mode == BUILD_libdef) { + if (p[0] == '!' && p[1] == '\0') p[0] = '\0'; /* Set env. */ + libdef_name(p, LIBINIT_STRING); + *optr++ = LIBINIT_SET; + obuf[2]++; /* Bump hash table size. */ + } +} + +static void libdef_regfunc(BuildCtx *ctx, char *p, int arg) +{ + UNUSED(ctx); UNUSED(p); + regfunc = arg; +} + +typedef void (*LibDefFunc)(BuildCtx *ctx, char *p, int arg); + +typedef struct LibDefHandler { + const char *suffix; + const char *stop; + const LibDefFunc func; + const int arg; +} LibDefHandler; + +static const LibDefHandler libdef_handlers[] = { + { "MODULE_", " \t\r\n", libdef_module, 0 }, + { "CF(", ")", libdef_func, LIBINIT_CF }, + { "ASM(", ")", libdef_func, LIBINIT_ASM }, + { "ASM_(", ")", libdef_func, LIBINIT_ASM_ }, + { "LUA(", ")", libdef_lua, 0 }, + { "REC(", ")", libdef_rec, 0 }, + { "PUSH(", ")", libdef_push, 0 }, + { "SET(", ")", libdef_set, 0 }, + { "NOREGUV", NULL, libdef_regfunc, REGFUNC_NOREGUV }, + { "NOREG", NULL, libdef_regfunc, REGFUNC_NOREG }, + { NULL, NULL, (LibDefFunc)0, 0 } +}; + +/* Emit C source code for library function definitions. */ +void emit_lib(BuildCtx *ctx) +{ + const char *fname; + + if (ctx->mode == BUILD_ffdef || ctx->mode == BUILD_libdef || + ctx->mode == BUILD_recdef) + fprintf(ctx->fp, "/* This is a generated file. DO NOT EDIT! */\n\n"); + else if (ctx->mode == BUILD_vmdef) + fprintf(ctx->fp, "ffnames = {\n[0]=\"Lua\",\n\"C\",\n"); + if (ctx->mode == BUILD_recdef) + fprintf(ctx->fp, "static const uint16_t recff_idmap[] = {\n0,\n0x0100"); + recffid = ffid = FF_C+1; + ffasmfunc = 0; + + while ((fname = *ctx->args++)) { + char buf[256]; /* We don't care about analyzing lines longer than that. */ + FILE *fp; + if (fname[0] == '-' && fname[1] == '\0') { + fp = stdin; + } else { + fp = fopen(fname, "r"); + if (!fp) { + fprintf(stderr, "Error: cannot open input file '%s': %s\n", + fname, strerror(errno)); + exit(1); + } + } + modstate = 0; + regfunc = REGFUNC_OK; + while (fgets(buf, sizeof(buf), fp) != NULL) { + char *p; + /* Simplistic pre-processor. Only handles top-level #if/#endif. */ + if (buf[0] == '#' && buf[1] == 'i' && buf[2] == 'f') { + int ok = 1; + if (!strcmp(buf, "#if LJ_52\n")) + ok = LJ_52; + else if (!strcmp(buf, "#if LJ_HASJIT\n")) + ok = LJ_HASJIT; + else if (!strcmp(buf, "#if LJ_HASFFI\n")) + ok = LJ_HASFFI; + else if (!strcmp(buf, "#if LJ_HASBUFFER\n")) + ok = LJ_HASBUFFER; + if (!ok) { + int lvl = 1; + while (fgets(buf, sizeof(buf), fp) != NULL) { + if (buf[0] == '#' && buf[1] == 'e' && buf[2] == 'n') { + if (--lvl == 0) break; + } else if (buf[0] == '#' && buf[1] == 'i' && buf[2] == 'f') { + lvl++; + } + } + continue; + } + } + for (p = buf; (p = strstr(p, LIBDEF_PREFIX)) != NULL; ) { + const LibDefHandler *ldh; + p += sizeof(LIBDEF_PREFIX)-1; + for (ldh = libdef_handlers; ldh->suffix != NULL; ldh++) { + size_t n, len = strlen(ldh->suffix); + if (!strncmp(p, ldh->suffix, len)) { + p += len; + n = ldh->stop ? strcspn(p, ldh->stop) : 0; + if (!p[n]) break; + p[n] = '\0'; + ldh->func(ctx, p, ldh->arg); + p += n+1; + break; + } + } + if (ldh->suffix == NULL) { + buf[strlen(buf)-1] = '\0'; + fprintf(stderr, "Error: unknown library definition tag %s%s\n", + LIBDEF_PREFIX, p); + exit(1); + } + } + } + fclose(fp); + if (ctx->mode == BUILD_libdef) { + libdef_endmodule(ctx); + } + } + + if (ctx->mode == BUILD_ffdef) { + fprintf(ctx->fp, "\n#undef FFDEF\n\n"); + fprintf(ctx->fp, + "#ifndef FF_NUM_ASMFUNC\n#define FF_NUM_ASMFUNC %d\n#endif\n\n", + ffasmfunc); + } else if (ctx->mode == BUILD_vmdef) { + fprintf(ctx->fp, "},\n\n"); + } else if (ctx->mode == BUILD_bcdef) { + int i; + fprintf(ctx->fp, "\n};\n\n"); + fprintf(ctx->fp, "LJ_DATADEF const uint16_t lj_bc_mode[] = {\n"); + fprintf(ctx->fp, "BCDEF(BCMODE)\n"); + for (i = ffasmfunc-1; i > 0; i--) + fprintf(ctx->fp, "BCMODE_FF,\n"); + fprintf(ctx->fp, "BCMODE_FF\n};\n\n"); + } else if (ctx->mode == BUILD_recdef) { + char *p = (char *)obuf; + fprintf(ctx->fp, "\n};\n\n"); + fprintf(ctx->fp, "static const RecordFunc recff_func[] = {\n" + "recff_nyi,\n" + "recff_c"); + while (*p) { + fprintf(ctx->fp, ",\nrecff_%s", p); + p += strlen(p)+1; + } + fprintf(ctx->fp, "\n};\n\n"); + } +} + diff --git a/fluent-bit/lib/luajit-3065c9/src/host/buildvm_libbc.h b/fluent-bit/lib/luajit-3065c9/src/host/buildvm_libbc.h new file mode 100644 index 00000000..276463b2 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/host/buildvm_libbc.h @@ -0,0 +1,81 @@ +/* This is a generated file. DO NOT EDIT! */ + +static const int libbc_endian = 0; + +static const uint8_t libbc_code[] = { +#if LJ_FR2 +/* math.deg */ 0,1,2,0,0,1,2,BC_MULVN,1,0,0,BC_RET1,1,2,0,241,135,158,166,3, +220,203,178,130,4, +/* math.rad */ 0,1,2,0,0,1,2,BC_MULVN,1,0,0,BC_RET1,1,2,0,243,244,148,165,20, +198,190,199,252,3, +/* string.len */ 0,1,2,0,0,0,3,BC_ISTYPE,0,5,0,BC_LEN,1,0,0,BC_RET1,1,2,0, +/* table.foreachi */ 0,2,10,0,0,0,15,BC_ISTYPE,0,12,0,BC_ISTYPE,1,9,0, +BC_KSHORT,2,1,0,BC_LEN,3,0,0,BC_KSHORT,4,1,0,BC_FORI,2,8,128,BC_MOV,6,1,0, +BC_MOV,8,5,0,BC_TGETR,9,5,0,BC_CALL,6,3,2,BC_ISEQP,6,0,0,BC_JMP,7,1,128, +BC_RET1,6,2,0,BC_FORL,2,248,127,BC_RET0,0,1,0, +/* table.foreach */ 0,2,11,0,0,1,16,BC_ISTYPE,0,12,0,BC_ISTYPE,1,9,0,BC_KPRI, +2,0,0,BC_MOV,3,0,0,BC_KNUM,4,0,0,BC_JMP,5,7,128,BC_MOV,7,1,0,BC_MOV,9,5,0, +BC_MOV,10,6,0,BC_CALL,7,3,2,BC_ISEQP,7,0,0,BC_JMP,8,1,128,BC_RET1,7,2,0, +BC_ITERN,5,3,3,BC_ITERL,5,247,127,BC_RET0,0,1,0,1,255,255,249,255,15, +/* table.getn */ 0,1,2,0,0,0,3,BC_ISTYPE,0,12,0,BC_LEN,1,0,0,BC_RET1,1,2,0, +/* table.remove */ 0,2,10,0,0,2,30,BC_ISTYPE,0,12,0,BC_LEN,2,0,0,BC_ISNEP,1,0, +0,BC_JMP,3,7,128,BC_ISEQN,2,0,0,BC_JMP,3,23,128,BC_TGETR,3,2,0,BC_KPRI,4,0,0, +BC_TSETR,4,2,0,BC_RET1,3,2,0,BC_JMP,3,18,128,BC_ISTYPE,1,14,0,BC_KSHORT,3,1,0, +BC_ISGT,3,1,0,BC_JMP,3,14,128,BC_ISGT,1,2,0,BC_JMP,3,12,128,BC_TGETR,3,1,0, +BC_ADDVN,4,1,1,BC_MOV,5,2,0,BC_KSHORT,6,1,0,BC_FORI,4,4,128,BC_SUBVN,8,1,7, +BC_TGETR,9,7,0,BC_TSETR,9,8,0,BC_FORL,4,252,127,BC_KPRI,4,0,0,BC_TSETR,4,2,0, +BC_RET1,3,2,0,BC_RET0,0,1,0,0,2, +/* table.move */ 0,5,12,0,0,0,35,BC_ISTYPE,0,12,0,BC_ISTYPE,1,14,0,BC_ISTYPE, +2,14,0,BC_ISTYPE,3,14,0,BC_ISNEP,4,0,0,BC_JMP,5,1,128,BC_MOV,4,0,0,BC_ISTYPE, +4,12,0,BC_ISGT,1,2,0,BC_JMP,5,24,128,BC_SUBVV,5,1,3,BC_ISLT,2,3,0,BC_JMP,6,4, +128,BC_ISLE,3,1,0,BC_JMP,6,2,128,BC_ISEQV,4,0,0,BC_JMP,6,9,128,BC_MOV,6,1,0, +BC_MOV,7,2,0,BC_KSHORT,8,1,0,BC_FORI,6,4,128,BC_ADDVV,10,5,9,BC_TGETR,11,9,0, +BC_TSETR,11,10,4,BC_FORL,6,252,127,BC_JMP,6,8,128,BC_MOV,6,2,0,BC_MOV,7,1,0, +BC_KSHORT,8,255,255,BC_FORI,6,4,128,BC_ADDVV,10,5,9,BC_TGETR,11,9,0,BC_TSETR, +11,10,4,BC_FORL,6,252,127,BC_RET1,4,2,0, +#else +/* math.deg */ 0,1,2,0,0,1,2,BC_MULVN,1,0,0,BC_RET1,1,2,0,241,135,158,166,3, +220,203,178,130,4, +/* math.rad */ 0,1,2,0,0,1,2,BC_MULVN,1,0,0,BC_RET1,1,2,0,243,244,148,165,20, +198,190,199,252,3, +/* string.len */ 0,1,2,0,0,0,3,BC_ISTYPE,0,5,0,BC_LEN,1,0,0,BC_RET1,1,2,0, +/* table.foreachi */ 0,2,9,0,0,0,15,BC_ISTYPE,0,12,0,BC_ISTYPE,1,9,0, +BC_KSHORT,2,1,0,BC_LEN,3,0,0,BC_KSHORT,4,1,0,BC_FORI,2,8,128,BC_MOV,6,1,0, +BC_MOV,7,5,0,BC_TGETR,8,5,0,BC_CALL,6,3,2,BC_ISEQP,6,0,0,BC_JMP,7,1,128, +BC_RET1,6,2,0,BC_FORL,2,248,127,BC_RET0,0,1,0, +/* table.foreach */ 0,2,10,0,0,1,16,BC_ISTYPE,0,12,0,BC_ISTYPE,1,9,0,BC_KPRI, +2,0,0,BC_MOV,3,0,0,BC_KNUM,4,0,0,BC_JMP,5,7,128,BC_MOV,7,1,0,BC_MOV,8,5,0, +BC_MOV,9,6,0,BC_CALL,7,3,2,BC_ISEQP,7,0,0,BC_JMP,8,1,128,BC_RET1,7,2,0, +BC_ITERN,5,3,3,BC_ITERL,5,247,127,BC_RET0,0,1,0,1,255,255,249,255,15, +/* table.getn */ 0,1,2,0,0,0,3,BC_ISTYPE,0,12,0,BC_LEN,1,0,0,BC_RET1,1,2,0, +/* table.remove */ 0,2,10,0,0,2,30,BC_ISTYPE,0,12,0,BC_LEN,2,0,0,BC_ISNEP,1,0, +0,BC_JMP,3,7,128,BC_ISEQN,2,0,0,BC_JMP,3,23,128,BC_TGETR,3,2,0,BC_KPRI,4,0,0, +BC_TSETR,4,2,0,BC_RET1,3,2,0,BC_JMP,3,18,128,BC_ISTYPE,1,14,0,BC_KSHORT,3,1,0, +BC_ISGT,3,1,0,BC_JMP,3,14,128,BC_ISGT,1,2,0,BC_JMP,3,12,128,BC_TGETR,3,1,0, +BC_ADDVN,4,1,1,BC_MOV,5,2,0,BC_KSHORT,6,1,0,BC_FORI,4,4,128,BC_SUBVN,8,1,7, +BC_TGETR,9,7,0,BC_TSETR,9,8,0,BC_FORL,4,252,127,BC_KPRI,4,0,0,BC_TSETR,4,2,0, +BC_RET1,3,2,0,BC_RET0,0,1,0,0,2, +/* table.move */ 0,5,12,0,0,0,35,BC_ISTYPE,0,12,0,BC_ISTYPE,1,14,0,BC_ISTYPE, +2,14,0,BC_ISTYPE,3,14,0,BC_ISNEP,4,0,0,BC_JMP,5,1,128,BC_MOV,4,0,0,BC_ISTYPE, +4,12,0,BC_ISGT,1,2,0,BC_JMP,5,24,128,BC_SUBVV,5,1,3,BC_ISLT,2,3,0,BC_JMP,6,4, +128,BC_ISLE,3,1,0,BC_JMP,6,2,128,BC_ISEQV,4,0,0,BC_JMP,6,9,128,BC_MOV,6,1,0, +BC_MOV,7,2,0,BC_KSHORT,8,1,0,BC_FORI,6,4,128,BC_ADDVV,10,5,9,BC_TGETR,11,9,0, +BC_TSETR,11,10,4,BC_FORL,6,252,127,BC_JMP,6,8,128,BC_MOV,6,2,0,BC_MOV,7,1,0, +BC_KSHORT,8,255,255,BC_FORI,6,4,128,BC_ADDVV,10,5,9,BC_TGETR,11,9,0,BC_TSETR, +11,10,4,BC_FORL,6,252,127,BC_RET1,4,2,0, +#endif +0 +}; + +static const struct { const char *name; int ofs; } libbc_map[] = { +{"math_deg",0}, +{"math_rad",25}, +{"string_len",50}, +{"table_foreachi",69}, +{"table_foreach",136}, +{"table_getn",213}, +{"table_remove",232}, +{"table_move",361}, +{NULL,508} +}; + diff --git a/fluent-bit/lib/luajit-3065c9/src/host/buildvm_peobj.c b/fluent-bit/lib/luajit-3065c9/src/host/buildvm_peobj.c new file mode 100644 index 00000000..b030f234 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/host/buildvm_peobj.c @@ -0,0 +1,379 @@ +/* +** LuaJIT VM builder: PE object emitter. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +** +** Only used for building on Windows, since we cannot assume the presence +** of a suitable assembler. The host and target byte order must match. +*/ + +#include "buildvm.h" +#include "lj_bc.h" + +#if LJ_TARGET_X86ORX64 + +/* Context for PE object emitter. */ +static char *strtab; +static size_t strtabofs; + +/* -- PE object definitions ----------------------------------------------- */ + +/* PE header. */ +typedef struct PEheader { + uint16_t arch; + uint16_t nsects; + uint32_t time; + uint32_t symtabofs; + uint32_t nsyms; + uint16_t opthdrsz; + uint16_t flags; +} PEheader; + +/* PE section. */ +typedef struct PEsection { + char name[8]; + uint32_t vsize; + uint32_t vaddr; + uint32_t size; + uint32_t ofs; + uint32_t relocofs; + uint32_t lineofs; + uint16_t nreloc; + uint16_t nline; + uint32_t flags; +} PEsection; + +/* PE relocation. */ +typedef struct PEreloc { + uint32_t vaddr; + uint32_t symidx; + uint16_t type; +} PEreloc; + +/* Cannot use sizeof, because it pads up to the max. alignment. */ +#define PEOBJ_RELOC_SIZE (4+4+2) + +/* PE symbol table entry. */ +typedef struct PEsym { + union { + char name[8]; + uint32_t nameref[2]; + } n; + uint32_t value; + int16_t sect; + uint16_t type; + uint8_t scl; + uint8_t naux; +} PEsym; + +/* PE symbol table auxiliary entry for a section. */ +typedef struct PEsymaux { + uint32_t size; + uint16_t nreloc; + uint16_t nline; + uint32_t cksum; + uint16_t assoc; + uint8_t comdatsel; + uint8_t unused[3]; +} PEsymaux; + +/* Cannot use sizeof, because it pads up to the max. alignment. */ +#define PEOBJ_SYM_SIZE (8+4+2+2+1+1) + +/* PE object CPU specific defines. */ +#if LJ_TARGET_X86 +#define PEOBJ_ARCH_TARGET 0x014c +#define PEOBJ_RELOC_REL32 0x14 /* MS: REL32, GNU: DISP32. */ +#define PEOBJ_RELOC_DIR32 0x06 +#define PEOBJ_RELOC_OFS 0 +#define PEOBJ_TEXT_FLAGS 0x60500020 /* 60=r+x, 50=align16, 20=code. */ +#elif LJ_TARGET_X64 +#define PEOBJ_ARCH_TARGET 0x8664 +#define PEOBJ_RELOC_REL32 0x04 /* MS: REL32, GNU: DISP32. */ +#define PEOBJ_RELOC_DIR32 0x02 +#define PEOBJ_RELOC_ADDR32NB 0x03 +#define PEOBJ_RELOC_OFS 0 +#define PEOBJ_TEXT_FLAGS 0x60500020 /* 60=r+x, 50=align16, 20=code. */ +#endif + +/* Section numbers (0-based). */ +enum { + PEOBJ_SECT_ABS = -2, + PEOBJ_SECT_UNDEF = -1, + PEOBJ_SECT_TEXT, +#if LJ_TARGET_X64 + PEOBJ_SECT_PDATA, + PEOBJ_SECT_XDATA, +#elif LJ_TARGET_X86 + PEOBJ_SECT_SXDATA, +#endif + PEOBJ_SECT_RDATA_Z, + PEOBJ_NSECTIONS +}; + +/* Symbol types. */ +#define PEOBJ_TYPE_NULL 0 +#define PEOBJ_TYPE_FUNC 0x20 + +/* Symbol storage class. */ +#define PEOBJ_SCL_EXTERN 2 +#define PEOBJ_SCL_STATIC 3 + +/* -- PE object emitter --------------------------------------------------- */ + +/* Emit PE object symbol. */ +static void emit_peobj_sym(BuildCtx *ctx, const char *name, uint32_t value, + int sect, int type, int scl) +{ + PEsym sym; + size_t len = strlen(name); + if (!strtab) { /* Pass 1: only calculate string table length. */ + if (len > 8) strtabofs += len+1; + return; + } + if (len <= 8) { + memcpy(sym.n.name, name, len); + memset(sym.n.name+len, 0, 8-len); + } else { + sym.n.nameref[0] = 0; + sym.n.nameref[1] = (uint32_t)strtabofs; + memcpy(strtab + strtabofs, name, len); + strtab[strtabofs+len] = 0; + strtabofs += len+1; + } + sym.value = value; + sym.sect = (int16_t)(sect+1); /* 1-based section number. */ + sym.type = (uint16_t)type; + sym.scl = (uint8_t)scl; + sym.naux = 0; + owrite(ctx, &sym, PEOBJ_SYM_SIZE); +} + +/* Emit PE object section symbol. */ +static void emit_peobj_sym_sect(BuildCtx *ctx, PEsection *pesect, int sect) +{ + PEsym sym; + PEsymaux aux; + if (!strtab) return; /* Pass 1: no output. */ + memcpy(sym.n.name, pesect[sect].name, 8); + sym.value = 0; + sym.sect = (int16_t)(sect+1); /* 1-based section number. */ + sym.type = PEOBJ_TYPE_NULL; + sym.scl = PEOBJ_SCL_STATIC; + sym.naux = 1; + owrite(ctx, &sym, PEOBJ_SYM_SIZE); + memset(&aux, 0, sizeof(PEsymaux)); + aux.size = pesect[sect].size; + aux.nreloc = pesect[sect].nreloc; + owrite(ctx, &aux, PEOBJ_SYM_SIZE); +} + +/* Emit Windows PE object file. */ +void emit_peobj(BuildCtx *ctx) +{ + PEheader pehdr; + PEsection pesect[PEOBJ_NSECTIONS]; + uint32_t sofs; + int i, nrsym; + union { uint8_t b; uint32_t u; } host_endian; + + sofs = sizeof(PEheader) + PEOBJ_NSECTIONS*sizeof(PEsection); + + /* Fill in PE sections. */ + memset(&pesect, 0, PEOBJ_NSECTIONS*sizeof(PEsection)); + memcpy(pesect[PEOBJ_SECT_TEXT].name, ".text", sizeof(".text")-1); + pesect[PEOBJ_SECT_TEXT].ofs = sofs; + sofs += (pesect[PEOBJ_SECT_TEXT].size = (uint32_t)ctx->codesz); + pesect[PEOBJ_SECT_TEXT].relocofs = sofs; + sofs += (pesect[PEOBJ_SECT_TEXT].nreloc = (uint16_t)ctx->nreloc) * PEOBJ_RELOC_SIZE; + /* Flags: 60 = read+execute, 50 = align16, 20 = code. */ + pesect[PEOBJ_SECT_TEXT].flags = PEOBJ_TEXT_FLAGS; + +#if LJ_TARGET_X64 + memcpy(pesect[PEOBJ_SECT_PDATA].name, ".pdata", sizeof(".pdata")-1); + pesect[PEOBJ_SECT_PDATA].ofs = sofs; + sofs += (pesect[PEOBJ_SECT_PDATA].size = 6*4); + pesect[PEOBJ_SECT_PDATA].relocofs = sofs; + sofs += (pesect[PEOBJ_SECT_PDATA].nreloc = 6) * PEOBJ_RELOC_SIZE; + /* Flags: 40 = read, 30 = align4, 40 = initialized data. */ + pesect[PEOBJ_SECT_PDATA].flags = 0x40300040; + + memcpy(pesect[PEOBJ_SECT_XDATA].name, ".xdata", sizeof(".xdata")-1); + pesect[PEOBJ_SECT_XDATA].ofs = sofs; + sofs += (pesect[PEOBJ_SECT_XDATA].size = 8*2+4+6*2); /* See below. */ + pesect[PEOBJ_SECT_XDATA].relocofs = sofs; + sofs += (pesect[PEOBJ_SECT_XDATA].nreloc = 1) * PEOBJ_RELOC_SIZE; + /* Flags: 40 = read, 30 = align4, 40 = initialized data. */ + pesect[PEOBJ_SECT_XDATA].flags = 0x40300040; +#elif LJ_TARGET_X86 + memcpy(pesect[PEOBJ_SECT_SXDATA].name, ".sxdata", sizeof(".sxdata")-1); + pesect[PEOBJ_SECT_SXDATA].ofs = sofs; + sofs += (pesect[PEOBJ_SECT_SXDATA].size = 4); + pesect[PEOBJ_SECT_SXDATA].relocofs = sofs; + /* Flags: 40 = read, 30 = align4, 02 = lnk_info, 40 = initialized data. */ + pesect[PEOBJ_SECT_SXDATA].flags = 0x40300240; +#endif + + memcpy(pesect[PEOBJ_SECT_RDATA_Z].name, ".rdata$Z", sizeof(".rdata$Z")-1); + pesect[PEOBJ_SECT_RDATA_Z].ofs = sofs; + sofs += (pesect[PEOBJ_SECT_RDATA_Z].size = (uint32_t)strlen(ctx->dasm_ident)+1); + /* Flags: 40 = read, 30 = align4, 40 = initialized data. */ + pesect[PEOBJ_SECT_RDATA_Z].flags = 0x40300040; + + /* Fill in PE header. */ + pehdr.arch = PEOBJ_ARCH_TARGET; + pehdr.nsects = PEOBJ_NSECTIONS; + pehdr.time = 0; /* Timestamp is optional. */ + pehdr.symtabofs = sofs; + pehdr.opthdrsz = 0; + pehdr.flags = 0; + + /* Compute the size of the symbol table: + ** @feat.00 + nsections*2 + ** + asm_start + nsym + ** + nrsym + */ + nrsym = ctx->nrelocsym; + pehdr.nsyms = 1+PEOBJ_NSECTIONS*2 + 1+ctx->nsym + nrsym; +#if LJ_TARGET_X64 + pehdr.nsyms += 1; /* Symbol for lj_err_unwind_win. */ +#endif + + /* Write PE object header and all sections. */ + owrite(ctx, &pehdr, sizeof(PEheader)); + owrite(ctx, &pesect, sizeof(PEsection)*PEOBJ_NSECTIONS); + + /* Write .text section. */ + host_endian.u = 1; + if (host_endian.b != LJ_ENDIAN_SELECT(1, 0)) { + fprintf(stderr, "Error: different byte order for host and target\n"); + exit(1); + } + owrite(ctx, ctx->code, ctx->codesz); + for (i = 0; i < ctx->nreloc; i++) { + PEreloc reloc; + reloc.vaddr = (uint32_t)ctx->reloc[i].ofs + PEOBJ_RELOC_OFS; + reloc.symidx = 1+2+ctx->reloc[i].sym; /* Reloc syms are after .text sym. */ + reloc.type = ctx->reloc[i].type ? PEOBJ_RELOC_REL32 : PEOBJ_RELOC_DIR32; + owrite(ctx, &reloc, PEOBJ_RELOC_SIZE); + } + +#if LJ_TARGET_X64 + { /* Write .pdata section. */ + uint32_t fcofs = (uint32_t)ctx->sym[ctx->nsym-1].ofs; + uint32_t pdata[3]; /* Start of .text, end of .text and .xdata. */ + PEreloc reloc; + pdata[0] = 0; pdata[1] = fcofs; pdata[2] = 0; + owrite(ctx, &pdata, sizeof(pdata)); + pdata[0] = fcofs; pdata[1] = (uint32_t)ctx->codesz; pdata[2] = 20; + owrite(ctx, &pdata, sizeof(pdata)); + reloc.vaddr = 0; reloc.symidx = 1+2+nrsym+2+2+1; + reloc.type = PEOBJ_RELOC_ADDR32NB; + owrite(ctx, &reloc, PEOBJ_RELOC_SIZE); + reloc.vaddr = 4; reloc.symidx = 1+2+nrsym+2+2+1; + reloc.type = PEOBJ_RELOC_ADDR32NB; + owrite(ctx, &reloc, PEOBJ_RELOC_SIZE); + reloc.vaddr = 8; reloc.symidx = 1+2+nrsym+2; + reloc.type = PEOBJ_RELOC_ADDR32NB; + owrite(ctx, &reloc, PEOBJ_RELOC_SIZE); + reloc.vaddr = 12; reloc.symidx = 1+2+nrsym+2+2+1; + reloc.type = PEOBJ_RELOC_ADDR32NB; + owrite(ctx, &reloc, PEOBJ_RELOC_SIZE); + reloc.vaddr = 16; reloc.symidx = 1+2+nrsym+2+2+1; + reloc.type = PEOBJ_RELOC_ADDR32NB; + owrite(ctx, &reloc, PEOBJ_RELOC_SIZE); + reloc.vaddr = 20; reloc.symidx = 1+2+nrsym+2; + reloc.type = PEOBJ_RELOC_ADDR32NB; + owrite(ctx, &reloc, PEOBJ_RELOC_SIZE); + } + { /* Write .xdata section. */ + uint16_t xdata[8+2+6]; + PEreloc reloc; + xdata[0] = 0x01|0x08|0x10; /* Ver. 1, uhandler/ehandler, prolog size 0. */ + xdata[1] = 0x0005; /* Number of unwind codes, no frame pointer. */ + xdata[2] = 0x4200; /* Stack offset 4*8+8 = aword*5. */ + xdata[3] = 0x3000; /* Push rbx. */ + xdata[4] = 0x6000; /* Push rsi. */ + xdata[5] = 0x7000; /* Push rdi. */ + xdata[6] = 0x5000; /* Push rbp. */ + xdata[7] = 0; /* Alignment. */ + xdata[8] = xdata[9] = 0; /* Relocated address of exception handler. */ + xdata[10] = 0x01; /* Ver. 1, no handler, prolog size 0. */ + xdata[11] = 0x1504; /* Number of unwind codes, fp = rbp, fpofs = 16. */ + xdata[12] = 0x0300; /* set_fpreg. */ + xdata[13] = 0x0200; /* stack offset 0*8+8 = aword*1. */ + xdata[14] = 0x3000; /* Push rbx. */ + xdata[15] = 0x5000; /* Push rbp. */ + owrite(ctx, &xdata, sizeof(xdata)); + reloc.vaddr = 2*8; reloc.symidx = 1+2+nrsym+2+2; + reloc.type = PEOBJ_RELOC_ADDR32NB; + owrite(ctx, &reloc, PEOBJ_RELOC_SIZE); + } +#elif LJ_TARGET_X86 + /* Write .sxdata section. */ + for (i = 0; i < nrsym; i++) { + if (!strcmp(ctx->relocsym[i], "_lj_err_unwind_win")) { + uint32_t symidx = 1+2+i; + owrite(ctx, &symidx, 4); + break; + } + } + if (i == nrsym) { + fprintf(stderr, "Error: extern lj_err_unwind_win not used\n"); + exit(1); + } +#endif + + /* Write .rdata$Z section. */ + owrite(ctx, ctx->dasm_ident, strlen(ctx->dasm_ident)+1); + + /* Write symbol table. */ + strtab = NULL; /* 1st pass: collect string sizes. */ + for (;;) { + strtabofs = 4; + /* Mark as SafeSEH compliant. */ + emit_peobj_sym(ctx, "@feat.00", 1, + PEOBJ_SECT_ABS, PEOBJ_TYPE_NULL, PEOBJ_SCL_STATIC); + + emit_peobj_sym_sect(ctx, pesect, PEOBJ_SECT_TEXT); + for (i = 0; i < nrsym; i++) + emit_peobj_sym(ctx, ctx->relocsym[i], 0, + PEOBJ_SECT_UNDEF, PEOBJ_TYPE_FUNC, PEOBJ_SCL_EXTERN); + +#if LJ_TARGET_X64 + emit_peobj_sym_sect(ctx, pesect, PEOBJ_SECT_PDATA); + emit_peobj_sym_sect(ctx, pesect, PEOBJ_SECT_XDATA); + emit_peobj_sym(ctx, "lj_err_unwind_win", 0, + PEOBJ_SECT_UNDEF, PEOBJ_TYPE_FUNC, PEOBJ_SCL_EXTERN); +#elif LJ_TARGET_X86 + emit_peobj_sym_sect(ctx, pesect, PEOBJ_SECT_SXDATA); +#endif + + emit_peobj_sym(ctx, ctx->beginsym, 0, + PEOBJ_SECT_TEXT, PEOBJ_TYPE_NULL, PEOBJ_SCL_EXTERN); + for (i = 0; i < ctx->nsym; i++) + emit_peobj_sym(ctx, ctx->sym[i].name, (uint32_t)ctx->sym[i].ofs, + PEOBJ_SECT_TEXT, PEOBJ_TYPE_FUNC, PEOBJ_SCL_EXTERN); + + emit_peobj_sym_sect(ctx, pesect, PEOBJ_SECT_RDATA_Z); + + if (strtab) + break; + /* 2nd pass: alloc strtab, write syms and copy strings. */ + strtab = (char *)malloc(strtabofs); + *(uint32_t *)strtab = (uint32_t)strtabofs; + } + + /* Write string table. */ + owrite(ctx, strtab, strtabofs); +} + +#else + +void emit_peobj(BuildCtx *ctx) +{ + UNUSED(ctx); + fprintf(stderr, "Error: no PE object support for this target\n"); + exit(1); +} + +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/host/genlibbc.lua b/fluent-bit/lib/luajit-3065c9/src/host/genlibbc.lua new file mode 100644 index 00000000..ba18812c --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/host/genlibbc.lua @@ -0,0 +1,225 @@ +---------------------------------------------------------------------------- +-- Lua script to dump the bytecode of the library functions written in Lua. +-- The resulting 'buildvm_libbc.h' is used for the build process of LuaJIT. +---------------------------------------------------------------------------- +-- Copyright (C) 2005-2022 Mike Pall. All rights reserved. +-- Released under the MIT license. See Copyright Notice in luajit.h +---------------------------------------------------------------------------- + +local ffi = require("ffi") +local bit = require("bit") +local vmdef = require("jit.vmdef") +local bcnames = vmdef.bcnames + +local format = string.format + +local isbe = (string.byte(string.dump(function() end), 5) % 2 == 1) + +local function usage(arg) + io.stderr:write("Usage: ", arg and arg[0] or "genlibbc", + " [-o buildvm_libbc.h] lib_*.c\n") + os.exit(1) +end + +local function parse_arg(arg) + local outfile = "-" + if not (arg and arg[1]) then + usage(arg) + end + if arg[1] == "-o" then + outfile = arg[2] + if not outfile then usage(arg) end + table.remove(arg, 1) + table.remove(arg, 1) + end + return outfile +end + +local function read_files(names) + local src = "" + for _,name in ipairs(names) do + local fp = assert(io.open(name)) + src = src .. fp:read("*a") + fp:close() + end + return src +end + +local function transform_lua(code) + local fixup = {} + local n = -30000 + code = string.gsub(code, "CHECK_(%w*)%((.-)%)", function(tp, var) + n = n + 1 + fixup[n] = { "CHECK", tp } + return format("%s=%d", var, n) + end) + code = string.gsub(code, "PAIRS%((.-)%)", function(var) + fixup.PAIRS = true + return format("nil, %s, 0x4dp80", var) + end) + return "return "..code, fixup +end + +local function read_uleb128(p) + local v = p[0]; p = p + 1 + if v >= 128 then + local sh = 7; v = v - 128 + repeat + local r = p[0] + v = v + bit.lshift(bit.band(r, 127), sh) + sh = sh + 7 + p = p + 1 + until r < 128 + end + return p, v +end + +-- ORDER LJ_T +local name2itype = { + str = 5, func = 9, tab = 12, int = 14, num = 15 +} + +local BC, BCN = {}, {} +for i=0,#bcnames/6-1 do + local name = bcnames:sub(i*6+1, i*6+6):gsub(" ", "") + BC[name] = i + BCN[i] = name +end +local xop, xra = isbe and 3 or 0, isbe and 2 or 1 +local xrc, xrb = isbe and 1 or 2, isbe and 0 or 3 + +local function fixup_dump(dump, fixup) + local buf = ffi.new("uint8_t[?]", #dump+1, dump) + local p = buf+5 + local n, sizebc + p, n = read_uleb128(p) + local start = p + p = p + 4 + p = read_uleb128(p) + p = read_uleb128(p) + p, sizebc = read_uleb128(p) + local startbc = tonumber(p - start) + local rawtab = {} + for i=0,sizebc-1 do + local op = p[xop] + if op == BC.KSHORT then + local rd = p[xrc] + 256*p[xrb] + rd = bit.arshift(bit.lshift(rd, 16), 16) + local f = fixup[rd] + if f then + if f[1] == "CHECK" then + local tp = f[2] + if tp == "tab" then rawtab[p[xra]] = true end + p[xop] = tp == "num" and BC.ISNUM or BC.ISTYPE + p[xrb] = 0 + p[xrc] = name2itype[tp] + else + error("unhandled fixup type: "..f[1]) + end + end + elseif op == BC.TGETV then + if rawtab[p[xrb]] then + p[xop] = BC.TGETR + end + elseif op == BC.TSETV then + if rawtab[p[xrb]] then + p[xop] = BC.TSETR + end + elseif op == BC.ITERC then + if fixup.PAIRS then + p[xop] = BC.ITERN + end + end + p = p + 4 + end + local ndump = ffi.string(start, n) + -- Fixup hi-part of 0x4dp80 to LJ_KEYINDEX. + ndump = ndump:gsub("\x80\x80\xcd\xaa\x04", "\xff\xff\xf9\xff\x0f") + return { dump = ndump, startbc = startbc, sizebc = sizebc } +end + +local function find_defs(src) + local defs = {} + for name, code in string.gmatch(src, "LJLIB_LUA%(([^)]*)%)%s*/%*(.-)%*/") do + local env = {} + local tcode, fixup = transform_lua(code) + local func = assert(load(tcode, "", nil, env))() + defs[name] = fixup_dump(string.dump(func, true), fixup) + defs[#defs+1] = name + end + return defs +end + +local function gen_header(defs) + local t = {} + local function w(x) t[#t+1] = x end + w("/* This is a generated file. DO NOT EDIT! */\n\n") + w("static const int libbc_endian = ") w(isbe and 1 or 0) w(";\n\n") + local s, sb = "", "" + for i,name in ipairs(defs) do + local d = defs[name] + s = s .. d.dump + sb = sb .. string.char(i) .. ("\0"):rep(d.startbc - 1) + .. (isbe and "\0\0\0\255" or "\255\0\0\0"):rep(d.sizebc) + .. ("\0"):rep(#d.dump - d.startbc - d.sizebc*4) + end + w("static const uint8_t libbc_code[] = {\n") + local n = 0 + for i=1,#s do + local x = string.byte(s, i) + local xb = string.byte(sb, i) + if xb == 255 then + local name = BCN[x] + local m = #name + 4 + if n + m > 78 then n = 0; w("\n") end + n = n + m + w("BC_"); w(name) + else + local m = x < 10 and 2 or (x < 100 and 3 or 4) + if xb == 0 then + if n + m > 78 then n = 0; w("\n") end + else + local name = defs[xb]:gsub("_", ".") + if n ~= 0 then w("\n") end + w("/* "); w(name); w(" */ ") + n = #name + 7 + end + n = n + m + w(x) + end + w(",") + end + w("\n0\n};\n\n") + w("static const struct { const char *name; int ofs; } libbc_map[] = {\n") + local m = 0 + for _,name in ipairs(defs) do + w('{"'); w(name); w('",'); w(m) w('},\n') + m = m + #defs[name].dump + end + w("{NULL,"); w(m); w("}\n};\n\n") + return table.concat(t) +end + +local function write_file(name, data) + if name == "-" then + assert(io.write(data)) + assert(io.flush()) + else + local fp = io.open(name) + if fp then + local old = fp:read("*a") + fp:close() + if data == old then return end + end + fp = assert(io.open(name, "w")) + assert(fp:write(data)) + assert(fp:close()) + end +end + +local outfile = parse_arg(arg) +local src = read_files(arg) +local defs = find_defs(src) +local hdr = gen_header(defs) +write_file(outfile, hdr) + diff --git a/fluent-bit/lib/luajit-3065c9/src/host/genminilua.lua b/fluent-bit/lib/luajit-3065c9/src/host/genminilua.lua new file mode 100644 index 00000000..e8e86c53 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/host/genminilua.lua @@ -0,0 +1,436 @@ +---------------------------------------------------------------------------- +-- Lua script to generate a customized, minified version of Lua. +-- The resulting 'minilua' is used for the build process of LuaJIT. +---------------------------------------------------------------------------- +-- Copyright (C) 2005-2022 Mike Pall. All rights reserved. +-- Released under the MIT license. See Copyright Notice in luajit.h +---------------------------------------------------------------------------- + +local sub, match, gsub = string.sub, string.match, string.gsub + +local LUA_VERSION = "5.1.5" +local LUA_SOURCE + +local function usage() + io.stderr:write("Usage: ", arg and arg[0] or "genminilua", + " lua-", LUA_VERSION, "-source-dir\n") + os.exit(1) +end + +local function find_sources() + LUA_SOURCE = arg and arg[1] + if not LUA_SOURCE then usage() end + if sub(LUA_SOURCE, -1) ~= "/" then LUA_SOURCE = LUA_SOURCE.."/" end + local fp = io.open(LUA_SOURCE .. "lua.h") + if not fp then + LUA_SOURCE = LUA_SOURCE.."src/" + fp = io.open(LUA_SOURCE .. "lua.h") + if not fp then usage() end + end + local all = fp:read("*a") + fp:close() + if not match(all, 'LUA_RELEASE%s*"Lua '..LUA_VERSION..'"') then + io.stderr:write("Error: version mismatch\n") + usage() + end +end + +local LUA_FILES = { +"lmem.c", "lobject.c", "ltm.c", "lfunc.c", "ldo.c", "lstring.c", "ltable.c", +"lgc.c", "lstate.c", "ldebug.c", "lzio.c", "lopcodes.c", +"llex.c", "lcode.c", "lparser.c", "lvm.c", "lapi.c", "lauxlib.c", +"lbaselib.c", "ltablib.c", "liolib.c", "loslib.c", "lstrlib.c", "linit.c", +} + +local REMOVE_LIB = {} +gsub([[ +collectgarbage dofile gcinfo getfenv getmetatable load print rawequal rawset +select tostring xpcall +foreach foreachi getn maxn setn +popen tmpfile seek setvbuf __tostring +clock date difftime execute getenv rename setlocale time tmpname +dump gfind len reverse +LUA_LOADLIBNAME LUA_MATHLIBNAME LUA_DBLIBNAME +]], "%S+", function(name) + REMOVE_LIB[name] = true +end) + +local REMOVE_EXTINC = { [""] = true, [""] = true, } + +local CUSTOM_MAIN = [[ +typedef unsigned int UB; +static UB barg(lua_State *L,int idx){ +union{lua_Number n;U64 b;}bn; +bn.n=lua_tonumber(L,idx)+6755399441055744.0; +if (bn.n==0.0&&!lua_isnumber(L,idx))luaL_typerror(L,idx,"number"); +return(UB)bn.b; +} +#define BRET(b) lua_pushnumber(L,(lua_Number)(int)(b));return 1; +static int tobit(lua_State *L){ +BRET(barg(L,1))} +static int bnot(lua_State *L){ +BRET(~barg(L,1))} +static int band(lua_State *L){ +int i;UB b=barg(L,1);for(i=lua_gettop(L);i>1;i--)b&=barg(L,i);BRET(b)} +static int bor(lua_State *L){ +int i;UB b=barg(L,1);for(i=lua_gettop(L);i>1;i--)b|=barg(L,i);BRET(b)} +static int bxor(lua_State *L){ +int i;UB b=barg(L,1);for(i=lua_gettop(L);i>1;i--)b^=barg(L,i);BRET(b)} +static int lshift(lua_State *L){ +UB b=barg(L,1),n=barg(L,2)&31;BRET(b<>n)} +static int arshift(lua_State *L){ +UB b=barg(L,1),n=barg(L,2)&31;BRET((int)b>>n)} +static int rol(lua_State *L){ +UB b=barg(L,1),n=barg(L,2)&31;BRET((b<>(32-n)))} +static int ror(lua_State *L){ +UB b=barg(L,1),n=barg(L,2)&31;BRET((b>>n)|(b<<(32-n)))} +static int bswap(lua_State *L){ +UB b=barg(L,1);b=(b>>24)|((b>>8)&0xff00)|((b&0xff00)<<8)|(b<<24);BRET(b)} +static int tohex(lua_State *L){ +UB b=barg(L,1); +int n=lua_isnone(L,2)?8:(int)barg(L,2); +const char *hexdigits="0123456789abcdef"; +char buf[8]; +int i; +if(n<0){n=-n;hexdigits="0123456789ABCDEF";} +if(n>8)n=8; +for(i=(int)n;--i>=0;){buf[i]=hexdigits[b&15];b>>=4;} +lua_pushlstring(L,buf,(size_t)n); +return 1; +} +static const struct luaL_Reg bitlib[] = { +{"tobit",tobit}, +{"bnot",bnot}, +{"band",band}, +{"bor",bor}, +{"bxor",bxor}, +{"lshift",lshift}, +{"rshift",rshift}, +{"arshift",arshift}, +{"rol",rol}, +{"ror",ror}, +{"bswap",bswap}, +{"tohex",tohex}, +{NULL,NULL} +}; +int main(int argc, char **argv){ + lua_State *L = luaL_newstate(); + int i; + luaL_openlibs(L); + luaL_register(L, "bit", bitlib); + if (argc < 2) return sizeof(void *); + lua_createtable(L, 0, 1); + lua_pushstring(L, argv[1]); + lua_rawseti(L, -2, 0); + lua_setglobal(L, "arg"); + if (luaL_loadfile(L, argv[1])) + goto err; + for (i = 2; i < argc; i++) + lua_pushstring(L, argv[i]); + if (lua_pcall(L, argc - 2, 0, 0)) { + err: + fprintf(stderr, "Error: %s\n", lua_tostring(L, -1)); + return 1; + } + lua_close(L); + return 0; +} +]] + +local function read_sources() + local t = {} + for i, name in ipairs(LUA_FILES) do + local fp = assert(io.open(LUA_SOURCE..name, "r")) + t[i] = fp:read("*a") + assert(fp:close()) + end + t[#t+1] = CUSTOM_MAIN + return table.concat(t) +end + +local includes = {} + +local function merge_includes(src) + return gsub(src, '#include%s*"([^"]*)"%s*\n', function(name) + if includes[name] then return "" end + includes[name] = true + local fp = assert(io.open(LUA_SOURCE..name, "r")) + local inc = fp:read("*a") + assert(fp:close()) + inc = gsub(inc, "#ifndef%s+%w+_h\n#define%s+%w+_h\n", "") + inc = gsub(inc, "#endif%s*$", "") + return merge_includes(inc) + end) +end + +local function get_license(src) + return match(src, "/%*+\n%* Copyright %(.-%*/\n") +end + +local function fold_lines(src) + return gsub(src, "\\\n", " ") +end + +local strings = {} + +local function save_str(str) + local n = #strings+1 + strings[n] = str + return "\1"..n.."\2" +end + +local function save_strings(src) + src = gsub(src, '"[^"\n]*"', save_str) + return gsub(src, "'[^'\n]*'", save_str) +end + +local function restore_strings(src) + return gsub(src, "\1(%d+)\2", function(numstr) + return strings[tonumber(numstr)] + end) +end + +local function def_istrue(def) + return def == "INT_MAX > 2147483640L" or + def == "LUAI_BITSINT >= 32" or + def == "SIZE_Bx < LUAI_BITSINT-1" or + def == "cast" or + def == "defined(LUA_CORE)" or + def == "MINSTRTABSIZE" or + def == "LUA_MINBUFFER" or + def == "HARDSTACKTESTS" or + def == "UNUSED" +end + +local head, defs = {[[ +#ifdef _MSC_VER +typedef unsigned __int64 U64; +#else +typedef unsigned long long U64; +#endif +int _CRT_glob = 0; +]]}, {} + +local function preprocess(src) + local t = { match(src, "^(.-)#") } + local lvl, on, oldon = 0, true, {} + for pp, def, txt in string.gmatch(src, "#(%w+) *([^\n]*)\n([^#]*)") do + if pp == "if" or pp == "ifdef" or pp == "ifndef" then + lvl = lvl + 1 + oldon[lvl] = on + on = def_istrue(def) + elseif pp == "else" then + if oldon[lvl] then + if on == false then on = true else on = false end + end + elseif pp == "elif" then + if oldon[lvl] then + on = def_istrue(def) + end + elseif pp == "endif" then + on = oldon[lvl] + lvl = lvl - 1 + elseif on then + if pp == "include" then + if not head[def] and not REMOVE_EXTINC[def] then + head[def] = true + head[#head+1] = "#include "..def.."\n" + end + elseif pp == "define" then + local k, sp, v = match(def, "([%w_]+)(%s*)(.*)") + if k and not (sp == "" and sub(v, 1, 1) == "(") then + defs[k] = gsub(v, "%a[%w_]*", function(tok) + return defs[tok] or tok + end) + else + t[#t+1] = "#define "..def.."\n" + end + elseif pp ~= "undef" then + error("unexpected directive: "..pp.." "..def) + end + end + if on then t[#t+1] = txt end + end + return gsub(table.concat(t), "%a[%w_]*", function(tok) + return defs[tok] or tok + end) +end + +local function merge_header(src, license) + local hdr = string.format([[ +/* This is a heavily customized and minimized copy of Lua %s. */ +/* It's only used to build LuaJIT. It does NOT have all standard functions! */ +]], LUA_VERSION) + return hdr..license..table.concat(head)..src +end + +local function strip_unused1(src) + return gsub(src, '( {"?([%w_]+)"?,%s+%a[%w_]*},\n)', function(line, func) + return REMOVE_LIB[func] and "" or line + end) +end + +local function strip_unused2(src) + return gsub(src, "Symbolic Execution.-}=", "") +end + +local function strip_unused3(src) + src = gsub(src, "extern", "static") + src = gsub(src, "\nstatic([^\n]-)%(([^)]*)%)%(", "\nstatic%1 %2(") + src = gsub(src, "#define lua_assert[^\n]*\n", "") + src = gsub(src, "lua_assert%b();?", "") + src = gsub(src, "default:\n}", "default:;\n}") + src = gsub(src, "lua_lock%b();", "") + src = gsub(src, "lua_unlock%b();", "") + src = gsub(src, "luai_threadyield%b();", "") + src = gsub(src, "luai_userstateopen%b();", "{}") + src = gsub(src, "luai_userstate%w+%b();", "") + src = gsub(src, "%(%(c==.*luaY_parser%)", "luaY_parser") + src = gsub(src, "trydecpoint%(ls,seminfo%)", + "luaX_lexerror(ls,\"malformed number\",TK_NUMBER)") + src = gsub(src, "int c=luaZ_lookahead%b();", "") + src = gsub(src, "luaL_register%(L,[^,]*,co_funcs%);\nreturn 2;", + "return 1;") + src = gsub(src, "getfuncname%b():", "NULL:") + src = gsub(src, "getobjname%b():", "NULL:") + src = gsub(src, "if%([^\n]*hookmask[^\n]*%)\n[^\n]*\n", "") + src = gsub(src, "if%([^\n]*hookmask[^\n]*%)%b{}\n", "") + src = gsub(src, "if%([^\n]*hookmask[^\n]*&&\n[^\n]*%b{}\n", "") + src = gsub(src, "(twoto%b()%()", "%1(size_t)") + src = gsub(src, "imaxstacksize)%)", "%1+p->numparams)") + src = gsub(src, "if%(sep==%-1%)(return'%[';)\nelse (luaX_lexerror%b();)", "if (sep!=-1)%2\n%1") + return gsub(src, "(default:{\nNode%*n=mainposition)", "/*fallthrough*/\n%1") +end + +local function func_gather(src) + local nodes, list = {}, {} + local pos, len = 1, #src + while pos < len do + local d, w = match(src, "^(#define ([%w_]+)[^\n]*\n)", pos) + if d then + local n = #list+1 + list[n] = d + nodes[w] = n + else + local s + d, w, s = match(src, "^(([%w_]+)[^\n]*([{;])\n)", pos) + if not d then + d, w, s = match(src, "^(([%w_]+)[^(]*%b()([{;])\n)", pos) + if not d then d = match(src, "^[^\n]*\n", pos) end + end + if s == "{" then + d = d..sub(match(src, "^%b{}[^;\n]*;?\n", pos+#d-2), 3) + if sub(d, -2) == "{\n" then + d = d..sub(match(src, "^%b{}[^;\n]*;?\n", pos+#d-2), 3) + end + end + local k, v = nil, d + if w == "typedef" then + if match(d, "^typedef enum") then + head[#head+1] = d + else + k = match(d, "([%w_]+);\n$") + if not k then k = match(d, "^.-%(.-([%w_]+)%)%(") end + end + elseif w == "enum" then + head[#head+1] = v + elseif w ~= nil then + k = match(d, "^[^\n]-([%w_]+)[(%[=]") + if k then + if w ~= "static" and k ~= "main" then v = "static "..d end + else + k = w + end + end + if w and k then + local o = nodes[k] + if o then nodes["*"..k] = o end + local n = #list+1 + list[n] = v + nodes[k] = n + end + end + pos = pos + #d + end + return nodes, list +end + +local function func_visit(nodes, list, used, n) + local i = nodes[n] + for m in string.gmatch(list[i], "[%w_]+") do + if nodes[m] then + local j = used[m] + if not j then + used[m] = i + func_visit(nodes, list, used, m) + elseif i < j then + used[m] = i + end + end + end +end + +local function func_collect(src) + local nodes, list = func_gather(src) + local used = {} + func_visit(nodes, list, used, "main") + for n,i in pairs(nodes) do + local j = used[n] + if j and j < i then used["*"..n] = j end + end + for n,i in pairs(nodes) do + if not used[n] then list[i] = "" end + end + return table.concat(list) +end + +find_sources() +local src = read_sources() +src = merge_includes(src) +local license = get_license(src) +src = fold_lines(src) +src = strip_unused1(src) +src = save_strings(src) +src = strip_unused2(src) +src = strip_comments(src) +src = preprocess(src) +src = strip_whitespace(src) +src = strip_unused3(src) +src = rename_tokens1(src) +src = func_collect(src) +src = rename_tokens2(src) +src = restore_strings(src) +src = fix_bugs_and_warnings(src) +src = merge_header(src, license) +io.write(src) diff --git a/fluent-bit/lib/luajit-3065c9/src/host/minilua.c b/fluent-bit/lib/luajit-3065c9/src/host/minilua.c new file mode 100644 index 00000000..76f32aed --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/host/minilua.c @@ -0,0 +1,7771 @@ +/* This is a heavily customized and minimized copy of Lua 5.1.5. */ +/* It's only used to build LuaJIT. It does NOT have all standard functions! */ +/****************************************************************************** +* Copyright (C) 1994-2012 Lua.org, PUC-Rio. All rights reserved. +* +* Permission is hereby granted, free of charge, to any person obtaining +* a copy of this software and associated documentation files (the +* "Software"), to deal in the Software without restriction, including +* without limitation the rights to use, copy, modify, merge, publish, +* distribute, sublicense, and/or sell copies of the Software, and to +* permit persons to whom the Software is furnished to do so, subject to +* the following conditions: +* +* The above copyright notice and this permission notice shall be +* included in all copies or substantial portions of the Software. +* +* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, +* EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF +* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. +* IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY +* CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, +* TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE +* SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. +******************************************************************************/ +#ifdef _MSC_VER +typedef unsigned __int64 U64; +#else +typedef unsigned long long U64; +#endif +int _CRT_glob = 0; +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +typedef enum{ +TM_INDEX, +TM_NEWINDEX, +TM_GC, +TM_MODE, +TM_EQ, +TM_ADD, +TM_SUB, +TM_MUL, +TM_DIV, +TM_MOD, +TM_POW, +TM_UNM, +TM_LEN, +TM_LT, +TM_LE, +TM_CONCAT, +TM_CALL, +TM_N +}TMS; +enum OpMode{iABC,iABx,iAsBx}; +typedef enum{ +OP_MOVE, +OP_LOADK, +OP_LOADBOOL, +OP_LOADNIL, +OP_GETUPVAL, +OP_GETGLOBAL, +OP_GETTABLE, +OP_SETGLOBAL, +OP_SETUPVAL, +OP_SETTABLE, +OP_NEWTABLE, +OP_SELF, +OP_ADD, +OP_SUB, +OP_MUL, +OP_DIV, +OP_MOD, +OP_POW, +OP_UNM, +OP_NOT, +OP_LEN, +OP_CONCAT, +OP_JMP, +OP_EQ, +OP_LT, +OP_LE, +OP_TEST, +OP_TESTSET, +OP_CALL, +OP_TAILCALL, +OP_RETURN, +OP_FORLOOP, +OP_FORPREP, +OP_TFORLOOP, +OP_SETLIST, +OP_CLOSE, +OP_CLOSURE, +OP_VARARG +}OpCode; +enum OpArgMask{ +OpArgN, +OpArgU, +OpArgR, +OpArgK +}; +typedef enum{ +VVOID, +VNIL, +VTRUE, +VFALSE, +VK, +VKNUM, +VLOCAL, +VUPVAL, +VGLOBAL, +VINDEXED, +VJMP, +VRELOCABLE, +VNONRELOC, +VCALL, +VVARARG +}expkind; +enum RESERVED{ +TK_AND=257,TK_BREAK, +TK_DO,TK_ELSE,TK_ELSEIF,TK_END,TK_FALSE,TK_FOR,TK_FUNCTION, +TK_IF,TK_IN,TK_LOCAL,TK_NIL,TK_NOT,TK_OR,TK_REPEAT, +TK_RETURN,TK_THEN,TK_TRUE,TK_UNTIL,TK_WHILE, +TK_CONCAT,TK_DOTS,TK_EQ,TK_GE,TK_LE,TK_NE,TK_NUMBER, +TK_NAME,TK_STRING,TK_EOS +}; +typedef enum BinOpr{ +OPR_ADD,OPR_SUB,OPR_MUL,OPR_DIV,OPR_MOD,OPR_POW, +OPR_CONCAT, +OPR_NE,OPR_EQ, +OPR_LT,OPR_LE,OPR_GT,OPR_GE, +OPR_AND,OPR_OR, +OPR_NOBINOPR +}BinOpr; +typedef enum UnOpr{OPR_MINUS,OPR_NOT,OPR_LEN,OPR_NOUNOPR}UnOpr; +#define LUA_QL(x)"'"x"'" +#define luai_apicheck(L,o){(void)L;} +#define lua_number2str(s,n)sprintf((s),"%.14g",(n)) +#define lua_str2number(s,p)strtod((s),(p)) +#define luai_numadd(a,b)((a)+(b)) +#define luai_numsub(a,b)((a)-(b)) +#define luai_nummul(a,b)((a)*(b)) +#define luai_numdiv(a,b)((a)/(b)) +#define luai_nummod(a,b)((a)-floor((a)/(b))*(b)) +#define luai_numpow(a,b)(pow(a,b)) +#define luai_numunm(a)(-(a)) +#define luai_numeq(a,b)((a)==(b)) +#define luai_numlt(a,b)((a)<(b)) +#define luai_numle(a,b)((a)<=(b)) +#define luai_numisnan(a)(!luai_numeq((a),(a))) +#define lua_number2int(i,d)((i)=(int)(d)) +#define lua_number2integer(i,d)((i)=(lua_Integer)(d)) +#define LUAI_THROW(L,c)longjmp((c)->b,1) +#define LUAI_TRY(L,c,a)if(setjmp((c)->b)==0){a} +#define lua_pclose(L,file)((void)((void)L,file),0) +#define lua_upvalueindex(i)((-10002)-(i)) +typedef struct lua_State lua_State; +typedef int(*lua_CFunction)(lua_State*L); +typedef const char*(*lua_Reader)(lua_State*L,void*ud,size_t*sz); +typedef void*(*lua_Alloc)(void*ud,void*ptr,size_t osize,size_t nsize); +typedef double lua_Number; +typedef ptrdiff_t lua_Integer; +static void lua_settop(lua_State*L,int idx); +static int lua_type(lua_State*L,int idx); +static const char* lua_tolstring(lua_State*L,int idx,size_t*len); +static size_t lua_objlen(lua_State*L,int idx); +static void lua_pushlstring(lua_State*L,const char*s,size_t l); +static void lua_pushcclosure(lua_State*L,lua_CFunction fn,int n); +static void lua_createtable(lua_State*L,int narr,int nrec); +static void lua_setfield(lua_State*L,int idx,const char*k); +#define lua_pop(L,n)lua_settop(L,-(n)-1) +#define lua_newtable(L)lua_createtable(L,0,0) +#define lua_pushcfunction(L,f)lua_pushcclosure(L,(f),0) +#define lua_strlen(L,i)lua_objlen(L,(i)) +#define lua_isfunction(L,n)(lua_type(L,(n))==6) +#define lua_istable(L,n)(lua_type(L,(n))==5) +#define lua_isnil(L,n)(lua_type(L,(n))==0) +#define lua_isboolean(L,n)(lua_type(L,(n))==1) +#define lua_isnone(L,n)(lua_type(L,(n))==(-1)) +#define lua_isnoneornil(L,n)(lua_type(L,(n))<=0) +#define lua_pushliteral(L,s)lua_pushlstring(L,""s,(sizeof(s)/sizeof(char))-1) +#define lua_setglobal(L,s)lua_setfield(L,(-10002),(s)) +#define lua_tostring(L,i)lua_tolstring(L,(i),NULL) +typedef struct lua_Debug lua_Debug; +typedef void(*lua_Hook)(lua_State*L,lua_Debug*ar); +struct lua_Debug{ +int event; +const char*name; +const char*namewhat; +const char*what; +const char*source; +int currentline; +int nups; +int linedefined; +int lastlinedefined; +char short_src[60]; +int i_ci; +}; +typedef unsigned int lu_int32; +typedef size_t lu_mem; +typedef ptrdiff_t l_mem; +typedef unsigned char lu_byte; +#define IntPoint(p)((unsigned int)(lu_mem)(p)) +typedef union{double u;void*s;long l;}L_Umaxalign; +typedef double l_uacNumber; +#define check_exp(c,e)(e) +#define UNUSED(x)((void)(x)) +#define cast(t,exp)((t)(exp)) +#define cast_byte(i)cast(lu_byte,(i)) +#define cast_num(i)cast(lua_Number,(i)) +#define cast_int(i)cast(int,(i)) +typedef lu_int32 Instruction; +#define condhardstacktests(x)((void)0) +typedef union GCObject GCObject; +typedef struct GCheader{ +GCObject*next;lu_byte tt;lu_byte marked; +}GCheader; +typedef union{ +GCObject*gc; +void*p; +lua_Number n; +int b; +}Value; +typedef struct lua_TValue{ +Value value;int tt; +}TValue; +#define ttisnil(o)(ttype(o)==0) +#define ttisnumber(o)(ttype(o)==3) +#define ttisstring(o)(ttype(o)==4) +#define ttistable(o)(ttype(o)==5) +#define ttisfunction(o)(ttype(o)==6) +#define ttisboolean(o)(ttype(o)==1) +#define ttisuserdata(o)(ttype(o)==7) +#define ttisthread(o)(ttype(o)==8) +#define ttislightuserdata(o)(ttype(o)==2) +#define ttype(o)((o)->tt) +#define gcvalue(o)check_exp(iscollectable(o),(o)->value.gc) +#define pvalue(o)check_exp(ttislightuserdata(o),(o)->value.p) +#define nvalue(o)check_exp(ttisnumber(o),(o)->value.n) +#define rawtsvalue(o)check_exp(ttisstring(o),&(o)->value.gc->ts) +#define tsvalue(o)(&rawtsvalue(o)->tsv) +#define rawuvalue(o)check_exp(ttisuserdata(o),&(o)->value.gc->u) +#define uvalue(o)(&rawuvalue(o)->uv) +#define clvalue(o)check_exp(ttisfunction(o),&(o)->value.gc->cl) +#define hvalue(o)check_exp(ttistable(o),&(o)->value.gc->h) +#define bvalue(o)check_exp(ttisboolean(o),(o)->value.b) +#define thvalue(o)check_exp(ttisthread(o),&(o)->value.gc->th) +#define l_isfalse(o)(ttisnil(o)||(ttisboolean(o)&&bvalue(o)==0)) +#define checkconsistency(obj) +#define checkliveness(g,obj) +#define setnilvalue(obj)((obj)->tt=0) +#define setnvalue(obj,x){TValue*i_o=(obj);i_o->value.n=(x);i_o->tt=3;} +#define setbvalue(obj,x){TValue*i_o=(obj);i_o->value.b=(x);i_o->tt=1;} +#define setsvalue(L,obj,x){TValue*i_o=(obj);i_o->value.gc=cast(GCObject*,(x));i_o->tt=4;checkliveness(G(L),i_o);} +#define setuvalue(L,obj,x){TValue*i_o=(obj);i_o->value.gc=cast(GCObject*,(x));i_o->tt=7;checkliveness(G(L),i_o);} +#define setthvalue(L,obj,x){TValue*i_o=(obj);i_o->value.gc=cast(GCObject*,(x));i_o->tt=8;checkliveness(G(L),i_o);} +#define setclvalue(L,obj,x){TValue*i_o=(obj);i_o->value.gc=cast(GCObject*,(x));i_o->tt=6;checkliveness(G(L),i_o);} +#define sethvalue(L,obj,x){TValue*i_o=(obj);i_o->value.gc=cast(GCObject*,(x));i_o->tt=5;checkliveness(G(L),i_o);} +#define setptvalue(L,obj,x){TValue*i_o=(obj);i_o->value.gc=cast(GCObject*,(x));i_o->tt=(8+1);checkliveness(G(L),i_o);} +#define setobj(L,obj1,obj2){const TValue*o2=(obj2);TValue*o1=(obj1);o1->value=o2->value;o1->tt=o2->tt;checkliveness(G(L),o1);} +#define setttype(obj,tt)(ttype(obj)=(tt)) +#define iscollectable(o)(ttype(o)>=4) +typedef TValue*StkId; +typedef union TString{ +L_Umaxalign dummy; +struct{ +GCObject*next;lu_byte tt;lu_byte marked; +lu_byte reserved; +unsigned int hash; +size_t len; +}tsv; +}TString; +#define getstr(ts)cast(const char*,(ts)+1) +#define svalue(o)getstr(rawtsvalue(o)) +typedef union Udata{ +L_Umaxalign dummy; +struct{ +GCObject*next;lu_byte tt;lu_byte marked; +struct Table*metatable; +struct Table*env; +size_t len; +}uv; +}Udata; +typedef struct Proto{ +GCObject*next;lu_byte tt;lu_byte marked; +TValue*k; +Instruction*code; +struct Proto**p; +int*lineinfo; +struct LocVar*locvars; +TString**upvalues; +TString*source; +int sizeupvalues; +int sizek; +int sizecode; +int sizelineinfo; +int sizep; +int sizelocvars; +int linedefined; +int lastlinedefined; +GCObject*gclist; +lu_byte nups; +lu_byte numparams; +lu_byte is_vararg; +lu_byte maxstacksize; +}Proto; +typedef struct LocVar{ +TString*varname; +int startpc; +int endpc; +}LocVar; +typedef struct UpVal{ +GCObject*next;lu_byte tt;lu_byte marked; +TValue*v; +union{ +TValue value; +struct{ +struct UpVal*prev; +struct UpVal*next; +}l; +}u; +}UpVal; +typedef struct CClosure{ +GCObject*next;lu_byte tt;lu_byte marked;lu_byte isC;lu_byte nupvalues;GCObject*gclist;struct Table*env; +lua_CFunction f; +TValue upvalue[1]; +}CClosure; +typedef struct LClosure{ +GCObject*next;lu_byte tt;lu_byte marked;lu_byte isC;lu_byte nupvalues;GCObject*gclist;struct Table*env; +struct Proto*p; +UpVal*upvals[1]; +}LClosure; +typedef union Closure{ +CClosure c; +LClosure l; +}Closure; +#define iscfunction(o)(ttype(o)==6&&clvalue(o)->c.isC) +typedef union TKey{ +struct{ +Value value;int tt; +struct Node*next; +}nk; +TValue tvk; +}TKey; +typedef struct Node{ +TValue i_val; +TKey i_key; +}Node; +typedef struct Table{ +GCObject*next;lu_byte tt;lu_byte marked; +lu_byte flags; +lu_byte lsizenode; +struct Table*metatable; +TValue*array; +Node*node; +Node*lastfree; +GCObject*gclist; +int sizearray; +}Table; +#define lmod(s,size)(check_exp((size&(size-1))==0,(cast(int,(s)&((size)-1))))) +#define twoto(x)((size_t)1<<(x)) +#define sizenode(t)(twoto((t)->lsizenode)) +static const TValue luaO_nilobject_; +#define ceillog2(x)(luaO_log2((x)-1)+1) +static int luaO_log2(unsigned int x); +#define gfasttm(g,et,e)((et)==NULL?NULL:((et)->flags&(1u<<(e)))?NULL:luaT_gettm(et,e,(g)->tmname[e])) +#define fasttm(l,et,e)gfasttm(G(l),et,e) +static const TValue*luaT_gettm(Table*events,TMS event,TString*ename); +#define luaM_reallocv(L,b,on,n,e)((cast(size_t,(n)+1)<=((size_t)(~(size_t)0)-2)/(e))?luaM_realloc_(L,(b),(on)*(e),(n)*(e)):luaM_toobig(L)) +#define luaM_freemem(L,b,s)luaM_realloc_(L,(b),(s),0) +#define luaM_free(L,b)luaM_realloc_(L,(b),sizeof(*(b)),0) +#define luaM_freearray(L,b,n,t)luaM_reallocv(L,(b),n,0,sizeof(t)) +#define luaM_malloc(L,t)luaM_realloc_(L,NULL,0,(t)) +#define luaM_new(L,t)cast(t*,luaM_malloc(L,sizeof(t))) +#define luaM_newvector(L,n,t)cast(t*,luaM_reallocv(L,NULL,0,n,sizeof(t))) +#define luaM_growvector(L,v,nelems,size,t,limit,e)if((nelems)+1>(size))((v)=cast(t*,luaM_growaux_(L,v,&(size),sizeof(t),limit,e))) +#define luaM_reallocvector(L,v,oldn,n,t)((v)=cast(t*,luaM_reallocv(L,v,oldn,n,sizeof(t)))) +static void*luaM_realloc_(lua_State*L,void*block,size_t oldsize, +size_t size); +static void*luaM_toobig(lua_State*L); +static void*luaM_growaux_(lua_State*L,void*block,int*size, +size_t size_elem,int limit, +const char*errormsg); +typedef struct Zio ZIO; +#define char2int(c)cast(int,cast(unsigned char,(c))) +#define zgetc(z)(((z)->n--)>0?char2int(*(z)->p++):luaZ_fill(z)) +typedef struct Mbuffer{ +char*buffer; +size_t n; +size_t buffsize; +}Mbuffer; +#define luaZ_initbuffer(L,buff)((buff)->buffer=NULL,(buff)->buffsize=0) +#define luaZ_buffer(buff)((buff)->buffer) +#define luaZ_sizebuffer(buff)((buff)->buffsize) +#define luaZ_bufflen(buff)((buff)->n) +#define luaZ_resetbuffer(buff)((buff)->n=0) +#define luaZ_resizebuffer(L,buff,size)(luaM_reallocvector(L,(buff)->buffer,(buff)->buffsize,size,char),(buff)->buffsize=size) +#define luaZ_freebuffer(L,buff)luaZ_resizebuffer(L,buff,0) +struct Zio{ +size_t n; +const char*p; +lua_Reader reader; +void*data; +lua_State*L; +}; +static int luaZ_fill(ZIO*z); +struct lua_longjmp; +#define gt(L)(&L->l_gt) +#define registry(L)(&G(L)->l_registry) +typedef struct stringtable{ +GCObject**hash; +lu_int32 nuse; +int size; +}stringtable; +typedef struct CallInfo{ +StkId base; +StkId func; +StkId top; +const Instruction*savedpc; +int nresults; +int tailcalls; +}CallInfo; +#define curr_func(L)(clvalue(L->ci->func)) +#define ci_func(ci)(clvalue((ci)->func)) +#define f_isLua(ci)(!ci_func(ci)->c.isC) +#define isLua(ci)(ttisfunction((ci)->func)&&f_isLua(ci)) +typedef struct global_State{ +stringtable strt; +lua_Alloc frealloc; +void*ud; +lu_byte currentwhite; +lu_byte gcstate; +int sweepstrgc; +GCObject*rootgc; +GCObject**sweepgc; +GCObject*gray; +GCObject*grayagain; +GCObject*weak; +GCObject*tmudata; +Mbuffer buff; +lu_mem GCthreshold; +lu_mem totalbytes; +lu_mem estimate; +lu_mem gcdept; +int gcpause; +int gcstepmul; +lua_CFunction panic; +TValue l_registry; +struct lua_State*mainthread; +UpVal uvhead; +struct Table*mt[(8+1)]; +TString*tmname[TM_N]; +}global_State; +struct lua_State{ +GCObject*next;lu_byte tt;lu_byte marked; +lu_byte status; +StkId top; +StkId base; +global_State*l_G; +CallInfo*ci; +const Instruction*savedpc; +StkId stack_last; +StkId stack; +CallInfo*end_ci; +CallInfo*base_ci; +int stacksize; +int size_ci; +unsigned short nCcalls; +unsigned short baseCcalls; +lu_byte hookmask; +lu_byte allowhook; +int basehookcount; +int hookcount; +lua_Hook hook; +TValue l_gt; +TValue env; +GCObject*openupval; +GCObject*gclist; +struct lua_longjmp*errorJmp; +ptrdiff_t errfunc; +}; +#define G(L)(L->l_G) +union GCObject{ +GCheader gch; +union TString ts; +union Udata u; +union Closure cl; +struct Table h; +struct Proto p; +struct UpVal uv; +struct lua_State th; +}; +#define rawgco2ts(o)check_exp((o)->gch.tt==4,&((o)->ts)) +#define gco2ts(o)(&rawgco2ts(o)->tsv) +#define rawgco2u(o)check_exp((o)->gch.tt==7,&((o)->u)) +#define gco2u(o)(&rawgco2u(o)->uv) +#define gco2cl(o)check_exp((o)->gch.tt==6,&((o)->cl)) +#define gco2h(o)check_exp((o)->gch.tt==5,&((o)->h)) +#define gco2p(o)check_exp((o)->gch.tt==(8+1),&((o)->p)) +#define gco2uv(o)check_exp((o)->gch.tt==(8+2),&((o)->uv)) +#define ngcotouv(o)check_exp((o)==NULL||(o)->gch.tt==(8+2),&((o)->uv)) +#define gco2th(o)check_exp((o)->gch.tt==8,&((o)->th)) +#define obj2gco(v)(cast(GCObject*,(v))) +static void luaE_freethread(lua_State*L,lua_State*L1); +#define pcRel(pc,p)(cast(int,(pc)-(p)->code)-1) +#define getline_(f,pc)(((f)->lineinfo)?(f)->lineinfo[pc]:0) +#define resethookcount(L)(L->hookcount=L->basehookcount) +static void luaG_typeerror(lua_State*L,const TValue*o, +const char*opname); +static void luaG_runerror(lua_State*L,const char*fmt,...); +#define luaD_checkstack(L,n)if((char*)L->stack_last-(char*)L->top<=(n)*(int)sizeof(TValue))luaD_growstack(L,n);else condhardstacktests(luaD_reallocstack(L,L->stacksize-5-1)); +#define incr_top(L){luaD_checkstack(L,1);L->top++;} +#define savestack(L,p)((char*)(p)-(char*)L->stack) +#define restorestack(L,n)((TValue*)((char*)L->stack+(n))) +#define saveci(L,p)((char*)(p)-(char*)L->base_ci) +#define restoreci(L,n)((CallInfo*)((char*)L->base_ci+(n))) +typedef void(*Pfunc)(lua_State*L,void*ud); +static int luaD_poscall(lua_State*L,StkId firstResult); +static void luaD_reallocCI(lua_State*L,int newsize); +static void luaD_reallocstack(lua_State*L,int newsize); +static void luaD_growstack(lua_State*L,int n); +static void luaD_throw(lua_State*L,int errcode); +static void*luaM_growaux_(lua_State*L,void*block,int*size,size_t size_elems, +int limit,const char*errormsg){ +void*newblock; +int newsize; +if(*size>=limit/2){ +if(*size>=limit) +luaG_runerror(L,errormsg); +newsize=limit; +} +else{ +newsize=(*size)*2; +if(newsize<4) +newsize=4; +} +newblock=luaM_reallocv(L,block,*size,newsize,size_elems); +*size=newsize; +return newblock; +} +static void*luaM_toobig(lua_State*L){ +luaG_runerror(L,"memory allocation error: block too big"); +return NULL; +} +static void*luaM_realloc_(lua_State*L,void*block,size_t osize,size_t nsize){ +global_State*g=G(L); +block=(*g->frealloc)(g->ud,block,osize,nsize); +if(block==NULL&&nsize>0) +luaD_throw(L,4); +g->totalbytes=(g->totalbytes-osize)+nsize; +return block; +} +#define resetbits(x,m)((x)&=cast(lu_byte,~(m))) +#define setbits(x,m)((x)|=(m)) +#define testbits(x,m)((x)&(m)) +#define bitmask(b)(1<<(b)) +#define bit2mask(b1,b2)(bitmask(b1)|bitmask(b2)) +#define l_setbit(x,b)setbits(x,bitmask(b)) +#define resetbit(x,b)resetbits(x,bitmask(b)) +#define testbit(x,b)testbits(x,bitmask(b)) +#define set2bits(x,b1,b2)setbits(x,(bit2mask(b1,b2))) +#define reset2bits(x,b1,b2)resetbits(x,(bit2mask(b1,b2))) +#define test2bits(x,b1,b2)testbits(x,(bit2mask(b1,b2))) +#define iswhite(x)test2bits((x)->gch.marked,0,1) +#define isblack(x)testbit((x)->gch.marked,2) +#define isgray(x)(!isblack(x)&&!iswhite(x)) +#define otherwhite(g)(g->currentwhite^bit2mask(0,1)) +#define isdead(g,v)((v)->gch.marked&otherwhite(g)&bit2mask(0,1)) +#define changewhite(x)((x)->gch.marked^=bit2mask(0,1)) +#define gray2black(x)l_setbit((x)->gch.marked,2) +#define valiswhite(x)(iscollectable(x)&&iswhite(gcvalue(x))) +#define luaC_white(g)cast(lu_byte,(g)->currentwhite&bit2mask(0,1)) +#define luaC_checkGC(L){condhardstacktests(luaD_reallocstack(L,L->stacksize-5-1));if(G(L)->totalbytes>=G(L)->GCthreshold)luaC_step(L);} +#define luaC_barrier(L,p,v){if(valiswhite(v)&&isblack(obj2gco(p)))luaC_barrierf(L,obj2gco(p),gcvalue(v));} +#define luaC_barriert(L,t,v){if(valiswhite(v)&&isblack(obj2gco(t)))luaC_barrierback(L,t);} +#define luaC_objbarrier(L,p,o){if(iswhite(obj2gco(o))&&isblack(obj2gco(p)))luaC_barrierf(L,obj2gco(p),obj2gco(o));} +#define luaC_objbarriert(L,t,o){if(iswhite(obj2gco(o))&&isblack(obj2gco(t)))luaC_barrierback(L,t);} +static void luaC_step(lua_State*L); +static void luaC_link(lua_State*L,GCObject*o,lu_byte tt); +static void luaC_linkupval(lua_State*L,UpVal*uv); +static void luaC_barrierf(lua_State*L,GCObject*o,GCObject*v); +static void luaC_barrierback(lua_State*L,Table*t); +#define sizestring(s)(sizeof(union TString)+((s)->len+1)*sizeof(char)) +#define sizeudata(u)(sizeof(union Udata)+(u)->len) +#define luaS_new(L,s)(luaS_newlstr(L,s,strlen(s))) +#define luaS_newliteral(L,s)(luaS_newlstr(L,""s,(sizeof(s)/sizeof(char))-1)) +#define luaS_fix(s)l_setbit((s)->tsv.marked,5) +static TString*luaS_newlstr(lua_State*L,const char*str,size_t l); +#define tostring(L,o)((ttype(o)==4)||(luaV_tostring(L,o))) +#define tonumber(o,n)(ttype(o)==3||(((o)=luaV_tonumber(o,n))!=NULL)) +#define equalobj(L,o1,o2)(ttype(o1)==ttype(o2)&&luaV_equalval(L,o1,o2)) +static int luaV_equalval(lua_State*L,const TValue*t1,const TValue*t2); +static const TValue*luaV_tonumber(const TValue*obj,TValue*n); +static int luaV_tostring(lua_State*L,StkId obj); +static void luaV_execute(lua_State*L,int nexeccalls); +static void luaV_concat(lua_State*L,int total,int last); +static const TValue luaO_nilobject_={{NULL},0}; +static int luaO_int2fb(unsigned int x){ +int e=0; +while(x>=16){ +x=(x+1)>>1; +e++; +} +if(x<8)return x; +else return((e+1)<<3)|(cast_int(x)-8); +} +static int luaO_fb2int(int x){ +int e=(x>>3)&31; +if(e==0)return x; +else return((x&7)+8)<<(e-1); +} +static int luaO_log2(unsigned int x){ +static const lu_byte log_2[256]={ +0,1,2,2,3,3,3,3,4,4,4,4,4,4,4,4,5,5,5,5,5,5,5,5,5,5,5,5,5,5,5,5, +6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6, +7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7, +7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7, +8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8, +8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8, +8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8, +8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8 +}; +int l=-1; +while(x>=256){l+=8;x>>=8;} +return l+log_2[x]; +} +static int luaO_rawequalObj(const TValue*t1,const TValue*t2){ +if(ttype(t1)!=ttype(t2))return 0; +else switch(ttype(t1)){ +case 0: +return 1; +case 3: +return luai_numeq(nvalue(t1),nvalue(t2)); +case 1: +return bvalue(t1)==bvalue(t2); +case 2: +return pvalue(t1)==pvalue(t2); +default: +return gcvalue(t1)==gcvalue(t2); +} +} +static int luaO_str2d(const char*s,lua_Number*result){ +char*endptr; +*result=lua_str2number(s,&endptr); +if(endptr==s)return 0; +if(*endptr=='x'||*endptr=='X') +*result=cast_num(strtoul(s,&endptr,16)); +if(*endptr=='\0')return 1; +while(isspace(cast(unsigned char,*endptr)))endptr++; +if(*endptr!='\0')return 0; +return 1; +} +static void pushstr(lua_State*L,const char*str){ +setsvalue(L,L->top,luaS_new(L,str)); +incr_top(L); +} +static const char*luaO_pushvfstring(lua_State*L,const char*fmt,va_list argp){ +int n=1; +pushstr(L,""); +for(;;){ +const char*e=strchr(fmt,'%'); +if(e==NULL)break; +setsvalue(L,L->top,luaS_newlstr(L,fmt,e-fmt)); +incr_top(L); +switch(*(e+1)){ +case's':{ +const char*s=va_arg(argp,char*); +if(s==NULL)s="(null)"; +pushstr(L,s); +break; +} +case'c':{ +char buff[2]; +buff[0]=cast(char,va_arg(argp,int)); +buff[1]='\0'; +pushstr(L,buff); +break; +} +case'd':{ +setnvalue(L->top,cast_num(va_arg(argp,int))); +incr_top(L); +break; +} +case'f':{ +setnvalue(L->top,cast_num(va_arg(argp,l_uacNumber))); +incr_top(L); +break; +} +case'p':{ +char buff[4*sizeof(void*)+8]; +sprintf(buff,"%p",va_arg(argp,void*)); +pushstr(L,buff); +break; +} +case'%':{ +pushstr(L,"%"); +break; +} +default:{ +char buff[3]; +buff[0]='%'; +buff[1]=*(e+1); +buff[2]='\0'; +pushstr(L,buff); +break; +} +} +n+=2; +fmt=e+2; +} +pushstr(L,fmt); +luaV_concat(L,n+1,cast_int(L->top-L->base)-1); +L->top-=n; +return svalue(L->top-1); +} +static const char*luaO_pushfstring(lua_State*L,const char*fmt,...){ +const char*msg; +va_list argp; +va_start(argp,fmt); +msg=luaO_pushvfstring(L,fmt,argp); +va_end(argp); +return msg; +} +static void luaO_chunkid(char*out,const char*source,size_t bufflen){ +if(*source=='='){ +strncpy(out,source+1,bufflen); +out[bufflen-1]='\0'; +} +else{ +if(*source=='@'){ +size_t l; +source++; +bufflen-=sizeof(" '...' "); +l=strlen(source); +strcpy(out,""); +if(l>bufflen){ +source+=(l-bufflen); +strcat(out,"..."); +} +strcat(out,source); +} +else{ +size_t len=strcspn(source,"\n\r"); +bufflen-=sizeof(" [string \"...\"] "); +if(len>bufflen)len=bufflen; +strcpy(out,"[string \""); +if(source[len]!='\0'){ +strncat(out,source,len); +strcat(out,"..."); +} +else +strcat(out,source); +strcat(out,"\"]"); +} +} +} +#define gnode(t,i)(&(t)->node[i]) +#define gkey(n)(&(n)->i_key.nk) +#define gval(n)(&(n)->i_val) +#define gnext(n)((n)->i_key.nk.next) +#define key2tval(n)(&(n)->i_key.tvk) +static TValue*luaH_setnum(lua_State*L,Table*t,int key); +static const TValue*luaH_getstr(Table*t,TString*key); +static TValue*luaH_set(lua_State*L,Table*t,const TValue*key); +static const char*const luaT_typenames[]={ +"nil","boolean","userdata","number", +"string","table","function","userdata","thread", +"proto","upval" +}; +static void luaT_init(lua_State*L){ +static const char*const luaT_eventname[]={ +"__index","__newindex", +"__gc","__mode","__eq", +"__add","__sub","__mul","__div","__mod", +"__pow","__unm","__len","__lt","__le", +"__concat","__call" +}; +int i; +for(i=0;itmname[i]=luaS_new(L,luaT_eventname[i]); +luaS_fix(G(L)->tmname[i]); +} +} +static const TValue*luaT_gettm(Table*events,TMS event,TString*ename){ +const TValue*tm=luaH_getstr(events,ename); +if(ttisnil(tm)){ +events->flags|=cast_byte(1u<metatable; +break; +case 7: +mt=uvalue(o)->metatable; +break; +default: +mt=G(L)->mt[ttype(o)]; +} +return(mt?luaH_getstr(mt,G(L)->tmname[event]):(&luaO_nilobject_)); +} +#define sizeCclosure(n)(cast(int,sizeof(CClosure))+cast(int,sizeof(TValue)*((n)-1))) +#define sizeLclosure(n)(cast(int,sizeof(LClosure))+cast(int,sizeof(TValue*)*((n)-1))) +static Closure*luaF_newCclosure(lua_State*L,int nelems,Table*e){ +Closure*c=cast(Closure*,luaM_malloc(L,sizeCclosure(nelems))); +luaC_link(L,obj2gco(c),6); +c->c.isC=1; +c->c.env=e; +c->c.nupvalues=cast_byte(nelems); +return c; +} +static Closure*luaF_newLclosure(lua_State*L,int nelems,Table*e){ +Closure*c=cast(Closure*,luaM_malloc(L,sizeLclosure(nelems))); +luaC_link(L,obj2gco(c),6); +c->l.isC=0; +c->l.env=e; +c->l.nupvalues=cast_byte(nelems); +while(nelems--)c->l.upvals[nelems]=NULL; +return c; +} +static UpVal*luaF_newupval(lua_State*L){ +UpVal*uv=luaM_new(L,UpVal); +luaC_link(L,obj2gco(uv),(8+2)); +uv->v=&uv->u.value; +setnilvalue(uv->v); +return uv; +} +static UpVal*luaF_findupval(lua_State*L,StkId level){ +global_State*g=G(L); +GCObject**pp=&L->openupval; +UpVal*p; +UpVal*uv; +while(*pp!=NULL&&(p=ngcotouv(*pp))->v>=level){ +if(p->v==level){ +if(isdead(g,obj2gco(p))) +changewhite(obj2gco(p)); +return p; +} +pp=&p->next; +} +uv=luaM_new(L,UpVal); +uv->tt=(8+2); +uv->marked=luaC_white(g); +uv->v=level; +uv->next=*pp; +*pp=obj2gco(uv); +uv->u.l.prev=&g->uvhead; +uv->u.l.next=g->uvhead.u.l.next; +uv->u.l.next->u.l.prev=uv; +g->uvhead.u.l.next=uv; +return uv; +} +static void unlinkupval(UpVal*uv){ +uv->u.l.next->u.l.prev=uv->u.l.prev; +uv->u.l.prev->u.l.next=uv->u.l.next; +} +static void luaF_freeupval(lua_State*L,UpVal*uv){ +if(uv->v!=&uv->u.value) +unlinkupval(uv); +luaM_free(L,uv); +} +static void luaF_close(lua_State*L,StkId level){ +UpVal*uv; +global_State*g=G(L); +while(L->openupval!=NULL&&(uv=ngcotouv(L->openupval))->v>=level){ +GCObject*o=obj2gco(uv); +L->openupval=uv->next; +if(isdead(g,o)) +luaF_freeupval(L,uv); +else{ +unlinkupval(uv); +setobj(L,&uv->u.value,uv->v); +uv->v=&uv->u.value; +luaC_linkupval(L,uv); +} +} +} +static Proto*luaF_newproto(lua_State*L){ +Proto*f=luaM_new(L,Proto); +luaC_link(L,obj2gco(f),(8+1)); +f->k=NULL; +f->sizek=0; +f->p=NULL; +f->sizep=0; +f->code=NULL; +f->sizecode=0; +f->sizelineinfo=0; +f->sizeupvalues=0; +f->nups=0; +f->upvalues=NULL; +f->numparams=0; +f->is_vararg=0; +f->maxstacksize=0; +f->lineinfo=NULL; +f->sizelocvars=0; +f->locvars=NULL; +f->linedefined=0; +f->lastlinedefined=0; +f->source=NULL; +return f; +} +static void luaF_freeproto(lua_State*L,Proto*f){ +luaM_freearray(L,f->code,f->sizecode,Instruction); +luaM_freearray(L,f->p,f->sizep,Proto*); +luaM_freearray(L,f->k,f->sizek,TValue); +luaM_freearray(L,f->lineinfo,f->sizelineinfo,int); +luaM_freearray(L,f->locvars,f->sizelocvars,struct LocVar); +luaM_freearray(L,f->upvalues,f->sizeupvalues,TString*); +luaM_free(L,f); +} +static void luaF_freeclosure(lua_State*L,Closure*c){ +int size=(c->c.isC)?sizeCclosure(c->c.nupvalues): +sizeLclosure(c->l.nupvalues); +luaM_freemem(L,c,size); +} +#define MASK1(n,p)((~((~(Instruction)0)<>0)&MASK1(6,0))) +#define SET_OPCODE(i,o)((i)=(((i)&MASK0(6,0))|((cast(Instruction,o)<<0)&MASK1(6,0)))) +#define GETARG_A(i)(cast(int,((i)>>(0+6))&MASK1(8,0))) +#define SETARG_A(i,u)((i)=(((i)&MASK0(8,(0+6)))|((cast(Instruction,u)<<(0+6))&MASK1(8,(0+6))))) +#define GETARG_B(i)(cast(int,((i)>>(((0+6)+8)+9))&MASK1(9,0))) +#define SETARG_B(i,b)((i)=(((i)&MASK0(9,(((0+6)+8)+9)))|((cast(Instruction,b)<<(((0+6)+8)+9))&MASK1(9,(((0+6)+8)+9))))) +#define GETARG_C(i)(cast(int,((i)>>((0+6)+8))&MASK1(9,0))) +#define SETARG_C(i,b)((i)=(((i)&MASK0(9,((0+6)+8)))|((cast(Instruction,b)<<((0+6)+8))&MASK1(9,((0+6)+8))))) +#define GETARG_Bx(i)(cast(int,((i)>>((0+6)+8))&MASK1((9+9),0))) +#define SETARG_Bx(i,b)((i)=(((i)&MASK0((9+9),((0+6)+8)))|((cast(Instruction,b)<<((0+6)+8))&MASK1((9+9),((0+6)+8))))) +#define GETARG_sBx(i)(GETARG_Bx(i)-(((1<<(9+9))-1)>>1)) +#define SETARG_sBx(i,b)SETARG_Bx((i),cast(unsigned int,(b)+(((1<<(9+9))-1)>>1))) +#define CREATE_ABC(o,a,b,c)((cast(Instruction,o)<<0)|(cast(Instruction,a)<<(0+6))|(cast(Instruction,b)<<(((0+6)+8)+9))|(cast(Instruction,c)<<((0+6)+8))) +#define CREATE_ABx(o,a,bc)((cast(Instruction,o)<<0)|(cast(Instruction,a)<<(0+6))|(cast(Instruction,bc)<<((0+6)+8))) +#define ISK(x)((x)&(1<<(9-1))) +#define INDEXK(r)((int)(r)&~(1<<(9-1))) +#define RKASK(x)((x)|(1<<(9-1))) +static const lu_byte luaP_opmodes[(cast(int,OP_VARARG)+1)]; +#define getBMode(m)(cast(enum OpArgMask,(luaP_opmodes[m]>>4)&3)) +#define getCMode(m)(cast(enum OpArgMask,(luaP_opmodes[m]>>2)&3)) +#define testTMode(m)(luaP_opmodes[m]&(1<<7)) +typedef struct expdesc{ +expkind k; +union{ +struct{int info,aux;}s; +lua_Number nval; +}u; +int t; +int f; +}expdesc; +typedef struct upvaldesc{ +lu_byte k; +lu_byte info; +}upvaldesc; +struct BlockCnt; +typedef struct FuncState{ +Proto*f; +Table*h; +struct FuncState*prev; +struct LexState*ls; +struct lua_State*L; +struct BlockCnt*bl; +int pc; +int lasttarget; +int jpc; +int freereg; +int nk; +int np; +short nlocvars; +lu_byte nactvar; +upvaldesc upvalues[60]; +unsigned short actvar[200]; +}FuncState; +static Proto*luaY_parser(lua_State*L,ZIO*z,Mbuffer*buff, +const char*name); +struct lua_longjmp{ +struct lua_longjmp*previous; +jmp_buf b; +volatile int status; +}; +static void luaD_seterrorobj(lua_State*L,int errcode,StkId oldtop){ +switch(errcode){ +case 4:{ +setsvalue(L,oldtop,luaS_newliteral(L,"not enough memory")); +break; +} +case 5:{ +setsvalue(L,oldtop,luaS_newliteral(L,"error in error handling")); +break; +} +case 3: +case 2:{ +setobj(L,oldtop,L->top-1); +break; +} +} +L->top=oldtop+1; +} +static void restore_stack_limit(lua_State*L){ +if(L->size_ci>20000){ +int inuse=cast_int(L->ci-L->base_ci); +if(inuse+1<20000) +luaD_reallocCI(L,20000); +} +} +static void resetstack(lua_State*L,int status){ +L->ci=L->base_ci; +L->base=L->ci->base; +luaF_close(L,L->base); +luaD_seterrorobj(L,status,L->base); +L->nCcalls=L->baseCcalls; +L->allowhook=1; +restore_stack_limit(L); +L->errfunc=0; +L->errorJmp=NULL; +} +static void luaD_throw(lua_State*L,int errcode){ +if(L->errorJmp){ +L->errorJmp->status=errcode; +LUAI_THROW(L,L->errorJmp); +} +else{ +L->status=cast_byte(errcode); +if(G(L)->panic){ +resetstack(L,errcode); +G(L)->panic(L); +} +exit(EXIT_FAILURE); +} +} +static int luaD_rawrunprotected(lua_State*L,Pfunc f,void*ud){ +struct lua_longjmp lj; +lj.status=0; +lj.previous=L->errorJmp; +L->errorJmp=&lj; +LUAI_TRY(L,&lj, +(*f)(L,ud); +); +L->errorJmp=lj.previous; +return lj.status; +} +static void correctstack(lua_State*L,TValue*oldstack){ +CallInfo*ci; +GCObject*up; +L->top=(L->top-oldstack)+L->stack; +for(up=L->openupval;up!=NULL;up=up->gch.next) +gco2uv(up)->v=(gco2uv(up)->v-oldstack)+L->stack; +for(ci=L->base_ci;ci<=L->ci;ci++){ +ci->top=(ci->top-oldstack)+L->stack; +ci->base=(ci->base-oldstack)+L->stack; +ci->func=(ci->func-oldstack)+L->stack; +} +L->base=(L->base-oldstack)+L->stack; +} +static void luaD_reallocstack(lua_State*L,int newsize){ +TValue*oldstack=L->stack; +int realsize=newsize+1+5; +luaM_reallocvector(L,L->stack,L->stacksize,realsize,TValue); +L->stacksize=realsize; +L->stack_last=L->stack+newsize; +correctstack(L,oldstack); +} +static void luaD_reallocCI(lua_State*L,int newsize){ +CallInfo*oldci=L->base_ci; +luaM_reallocvector(L,L->base_ci,L->size_ci,newsize,CallInfo); +L->size_ci=newsize; +L->ci=(L->ci-oldci)+L->base_ci; +L->end_ci=L->base_ci+L->size_ci-1; +} +static void luaD_growstack(lua_State*L,int n){ +if(n<=L->stacksize) +luaD_reallocstack(L,2*L->stacksize); +else +luaD_reallocstack(L,L->stacksize+n); +} +static CallInfo*growCI(lua_State*L){ +if(L->size_ci>20000) +luaD_throw(L,5); +else{ +luaD_reallocCI(L,2*L->size_ci); +if(L->size_ci>20000) +luaG_runerror(L,"stack overflow"); +} +return++L->ci; +} +static StkId adjust_varargs(lua_State*L,Proto*p,int actual){ +int i; +int nfixargs=p->numparams; +Table*htab=NULL; +StkId base,fixed; +for(;actualtop++); +fixed=L->top-actual; +base=L->top; +for(i=0;itop++,fixed+i); +setnilvalue(fixed+i); +} +if(htab){ +sethvalue(L,L->top++,htab); +} +return base; +} +static StkId tryfuncTM(lua_State*L,StkId func){ +const TValue*tm=luaT_gettmbyobj(L,func,TM_CALL); +StkId p; +ptrdiff_t funcr=savestack(L,func); +if(!ttisfunction(tm)) +luaG_typeerror(L,func,"call"); +for(p=L->top;p>func;p--)setobj(L,p,p-1); +incr_top(L); +func=restorestack(L,funcr); +setobj(L,func,tm); +return func; +} +#define inc_ci(L)((L->ci==L->end_ci)?growCI(L):(condhardstacktests(luaD_reallocCI(L,L->size_ci)),++L->ci)) +static int luaD_precall(lua_State*L,StkId func,int nresults){ +LClosure*cl; +ptrdiff_t funcr; +if(!ttisfunction(func)) +func=tryfuncTM(L,func); +funcr=savestack(L,func); +cl=&clvalue(func)->l; +L->ci->savedpc=L->savedpc; +if(!cl->isC){ +CallInfo*ci; +StkId st,base; +Proto*p=cl->p; +luaD_checkstack(L,p->maxstacksize+p->numparams); +func=restorestack(L,funcr); +if(!p->is_vararg){ +base=func+1; +if(L->top>base+p->numparams) +L->top=base+p->numparams; +} +else{ +int nargs=cast_int(L->top-func)-1; +base=adjust_varargs(L,p,nargs); +func=restorestack(L,funcr); +} +ci=inc_ci(L); +ci->func=func; +L->base=ci->base=base; +ci->top=L->base+p->maxstacksize; +L->savedpc=p->code; +ci->tailcalls=0; +ci->nresults=nresults; +for(st=L->top;sttop;st++) +setnilvalue(st); +L->top=ci->top; +return 0; +} +else{ +CallInfo*ci; +int n; +luaD_checkstack(L,20); +ci=inc_ci(L); +ci->func=restorestack(L,funcr); +L->base=ci->base=ci->func+1; +ci->top=L->top+20; +ci->nresults=nresults; +n=(*curr_func(L)->c.f)(L); +if(n<0) +return 2; +else{ +luaD_poscall(L,L->top-n); +return 1; +} +} +} +static int luaD_poscall(lua_State*L,StkId firstResult){ +StkId res; +int wanted,i; +CallInfo*ci; +ci=L->ci--; +res=ci->func; +wanted=ci->nresults; +L->base=(ci-1)->base; +L->savedpc=(ci-1)->savedpc; +for(i=wanted;i!=0&&firstResulttop;i--) +setobj(L,res++,firstResult++); +while(i-->0) +setnilvalue(res++); +L->top=res; +return(wanted-(-1)); +} +static void luaD_call(lua_State*L,StkId func,int nResults){ +if(++L->nCcalls>=200){ +if(L->nCcalls==200) +luaG_runerror(L,"C stack overflow"); +else if(L->nCcalls>=(200+(200>>3))) +luaD_throw(L,5); +} +if(luaD_precall(L,func,nResults)==0) +luaV_execute(L,1); +L->nCcalls--; +luaC_checkGC(L); +} +static int luaD_pcall(lua_State*L,Pfunc func,void*u, +ptrdiff_t old_top,ptrdiff_t ef){ +int status; +unsigned short oldnCcalls=L->nCcalls; +ptrdiff_t old_ci=saveci(L,L->ci); +lu_byte old_allowhooks=L->allowhook; +ptrdiff_t old_errfunc=L->errfunc; +L->errfunc=ef; +status=luaD_rawrunprotected(L,func,u); +if(status!=0){ +StkId oldtop=restorestack(L,old_top); +luaF_close(L,oldtop); +luaD_seterrorobj(L,status,oldtop); +L->nCcalls=oldnCcalls; +L->ci=restoreci(L,old_ci); +L->base=L->ci->base; +L->savedpc=L->ci->savedpc; +L->allowhook=old_allowhooks; +restore_stack_limit(L); +} +L->errfunc=old_errfunc; +return status; +} +struct SParser{ +ZIO*z; +Mbuffer buff; +const char*name; +}; +static void f_parser(lua_State*L,void*ud){ +int i; +Proto*tf; +Closure*cl; +struct SParser*p=cast(struct SParser*,ud); +luaC_checkGC(L); +tf=luaY_parser(L,p->z, +&p->buff,p->name); +cl=luaF_newLclosure(L,tf->nups,hvalue(gt(L))); +cl->l.p=tf; +for(i=0;inups;i++) +cl->l.upvals[i]=luaF_newupval(L); +setclvalue(L,L->top,cl); +incr_top(L); +} +static int luaD_protectedparser(lua_State*L,ZIO*z,const char*name){ +struct SParser p; +int status; +p.z=z;p.name=name; +luaZ_initbuffer(L,&p.buff); +status=luaD_pcall(L,f_parser,&p,savestack(L,L->top),L->errfunc); +luaZ_freebuffer(L,&p.buff); +return status; +} +static void luaS_resize(lua_State*L,int newsize){ +GCObject**newhash; +stringtable*tb; +int i; +if(G(L)->gcstate==2) +return; +newhash=luaM_newvector(L,newsize,GCObject*); +tb=&G(L)->strt; +for(i=0;isize;i++){ +GCObject*p=tb->hash[i]; +while(p){ +GCObject*next=p->gch.next; +unsigned int h=gco2ts(p)->hash; +int h1=lmod(h,newsize); +p->gch.next=newhash[h1]; +newhash[h1]=p; +p=next; +} +} +luaM_freearray(L,tb->hash,tb->size,TString*); +tb->size=newsize; +tb->hash=newhash; +} +static TString*newlstr(lua_State*L,const char*str,size_t l, +unsigned int h){ +TString*ts; +stringtable*tb; +if(l+1>(((size_t)(~(size_t)0)-2)-sizeof(TString))/sizeof(char)) +luaM_toobig(L); +ts=cast(TString*,luaM_malloc(L,(l+1)*sizeof(char)+sizeof(TString))); +ts->tsv.len=l; +ts->tsv.hash=h; +ts->tsv.marked=luaC_white(G(L)); +ts->tsv.tt=4; +ts->tsv.reserved=0; +memcpy(ts+1,str,l*sizeof(char)); +((char*)(ts+1))[l]='\0'; +tb=&G(L)->strt; +h=lmod(h,tb->size); +ts->tsv.next=tb->hash[h]; +tb->hash[h]=obj2gco(ts); +tb->nuse++; +if(tb->nuse>cast(lu_int32,tb->size)&&tb->size<=(INT_MAX-2)/2) +luaS_resize(L,tb->size*2); +return ts; +} +static TString*luaS_newlstr(lua_State*L,const char*str,size_t l){ +GCObject*o; +unsigned int h=cast(unsigned int,l); +size_t step=(l>>5)+1; +size_t l1; +for(l1=l;l1>=step;l1-=step) +h=h^((h<<5)+(h>>2)+cast(unsigned char,str[l1-1])); +for(o=G(L)->strt.hash[lmod(h,G(L)->strt.size)]; +o!=NULL; +o=o->gch.next){ +TString*ts=rawgco2ts(o); +if(ts->tsv.len==l&&(memcmp(str,getstr(ts),l)==0)){ +if(isdead(G(L),o))changewhite(o); +return ts; +} +} +return newlstr(L,str,l,h); +} +static Udata*luaS_newudata(lua_State*L,size_t s,Table*e){ +Udata*u; +if(s>((size_t)(~(size_t)0)-2)-sizeof(Udata)) +luaM_toobig(L); +u=cast(Udata*,luaM_malloc(L,s+sizeof(Udata))); +u->uv.marked=luaC_white(G(L)); +u->uv.tt=7; +u->uv.len=s; +u->uv.metatable=NULL; +u->uv.env=e; +u->uv.next=G(L)->mainthread->next; +G(L)->mainthread->next=obj2gco(u); +return u; +} +#define hashpow2(t,n)(gnode(t,lmod((n),sizenode(t)))) +#define hashstr(t,str)hashpow2(t,(str)->tsv.hash) +#define hashboolean(t,p)hashpow2(t,p) +#define hashmod(t,n)(gnode(t,((n)%((sizenode(t)-1)|1)))) +#define hashpointer(t,p)hashmod(t,IntPoint(p)) +static const Node dummynode_={ +{{NULL},0}, +{{{NULL},0,NULL}} +}; +static Node*hashnum(const Table*t,lua_Number n){ +unsigned int a[cast_int(sizeof(lua_Number)/sizeof(int))]; +int i; +if(luai_numeq(n,0)) +return gnode(t,0); +memcpy(a,&n,sizeof(a)); +for(i=1;isizearray) +return i-1; +else{ +Node*n=mainposition(t,key); +do{ +if(luaO_rawequalObj(key2tval(n),key)|| +(ttype(gkey(n))==(8+3)&&iscollectable(key)&& +gcvalue(gkey(n))==gcvalue(key))){ +i=cast_int(n-gnode(t,0)); +return i+t->sizearray; +} +else n=gnext(n); +}while(n); +luaG_runerror(L,"invalid key to "LUA_QL("next")); +return 0; +} +} +static int luaH_next(lua_State*L,Table*t,StkId key){ +int i=findindex(L,t,key); +for(i++;isizearray;i++){ +if(!ttisnil(&t->array[i])){ +setnvalue(key,cast_num(i+1)); +setobj(L,key+1,&t->array[i]); +return 1; +} +} +for(i-=t->sizearray;i<(int)sizenode(t);i++){ +if(!ttisnil(gval(gnode(t,i)))){ +setobj(L,key,key2tval(gnode(t,i))); +setobj(L,key+1,gval(gnode(t,i))); +return 1; +} +} +return 0; +} +static int computesizes(int nums[],int*narray){ +int i; +int twotoi; +int a=0; +int na=0; +int n=0; +for(i=0,twotoi=1;twotoi/2<*narray;i++,twotoi*=2){ +if(nums[i]>0){ +a+=nums[i]; +if(a>twotoi/2){ +n=twotoi; +na=a; +} +} +if(a==*narray)break; +} +*narray=n; +return na; +} +static int countint(const TValue*key,int*nums){ +int k=arrayindex(key); +if(0t->sizearray){ +lim=t->sizearray; +if(i>lim) +break; +} +for(;i<=lim;i++){ +if(!ttisnil(&t->array[i-1])) +lc++; +} +nums[lg]+=lc; +ause+=lc; +} +return ause; +} +static int numusehash(const Table*t,int*nums,int*pnasize){ +int totaluse=0; +int ause=0; +int i=sizenode(t); +while(i--){ +Node*n=&t->node[i]; +if(!ttisnil(gval(n))){ +ause+=countint(key2tval(n),nums); +totaluse++; +} +} +*pnasize+=ause; +return totaluse; +} +static void setarrayvector(lua_State*L,Table*t,int size){ +int i; +luaM_reallocvector(L,t->array,t->sizearray,size,TValue); +for(i=t->sizearray;iarray[i]); +t->sizearray=size; +} +static void setnodevector(lua_State*L,Table*t,int size){ +int lsize; +if(size==0){ +t->node=cast(Node*,(&dummynode_)); +lsize=0; +} +else{ +int i; +lsize=ceillog2(size); +if(lsize>(32-2)) +luaG_runerror(L,"table overflow"); +size=twoto(lsize); +t->node=luaM_newvector(L,size,Node); +for(i=0;ilsizenode=cast_byte(lsize); +t->lastfree=gnode(t,size); +} +static void resize(lua_State*L,Table*t,int nasize,int nhsize){ +int i; +int oldasize=t->sizearray; +int oldhsize=t->lsizenode; +Node*nold=t->node; +if(nasize>oldasize) +setarrayvector(L,t,nasize); +setnodevector(L,t,nhsize); +if(nasizesizearray=nasize; +for(i=nasize;iarray[i])) +setobj(L,luaH_setnum(L,t,i+1),&t->array[i]); +} +luaM_reallocvector(L,t->array,oldasize,nasize,TValue); +} +for(i=twoto(oldhsize)-1;i>=0;i--){ +Node*old=nold+i; +if(!ttisnil(gval(old))) +setobj(L,luaH_set(L,t,key2tval(old)),gval(old)); +} +if(nold!=(&dummynode_)) +luaM_freearray(L,nold,twoto(oldhsize),Node); +} +static void luaH_resizearray(lua_State*L,Table*t,int nasize){ +int nsize=(t->node==(&dummynode_))?0:sizenode(t); +resize(L,t,nasize,nsize); +} +static void rehash(lua_State*L,Table*t,const TValue*ek){ +int nasize,na; +int nums[(32-2)+1]; +int i; +int totaluse; +for(i=0;i<=(32-2);i++)nums[i]=0; +nasize=numusearray(t,nums); +totaluse=nasize; +totaluse+=numusehash(t,nums,&nasize); +nasize+=countint(ek,nums); +totaluse++; +na=computesizes(nums,&nasize); +resize(L,t,nasize,totaluse-na); +} +static Table*luaH_new(lua_State*L,int narray,int nhash){ +Table*t=luaM_new(L,Table); +luaC_link(L,obj2gco(t),5); +t->metatable=NULL; +t->flags=cast_byte(~0); +t->array=NULL; +t->sizearray=0; +t->lsizenode=0; +t->node=cast(Node*,(&dummynode_)); +setarrayvector(L,t,narray); +setnodevector(L,t,nhash); +return t; +} +static void luaH_free(lua_State*L,Table*t){ +if(t->node!=(&dummynode_)) +luaM_freearray(L,t->node,sizenode(t),Node); +luaM_freearray(L,t->array,t->sizearray,TValue); +luaM_free(L,t); +} +static Node*getfreepos(Table*t){ +while(t->lastfree-->t->node){ +if(ttisnil(gkey(t->lastfree))) +return t->lastfree; +} +return NULL; +} +static TValue*newkey(lua_State*L,Table*t,const TValue*key){ +Node*mp=mainposition(t,key); +if(!ttisnil(gval(mp))||mp==(&dummynode_)){ +Node*othern; +Node*n=getfreepos(t); +if(n==NULL){ +rehash(L,t,key); +return luaH_set(L,t,key); +} +othern=mainposition(t,key2tval(mp)); +if(othern!=mp){ +while(gnext(othern)!=mp)othern=gnext(othern); +gnext(othern)=n; +*n=*mp; +gnext(mp)=NULL; +setnilvalue(gval(mp)); +} +else{ +gnext(n)=gnext(mp); +gnext(mp)=n; +mp=n; +} +} +gkey(mp)->value=key->value;gkey(mp)->tt=key->tt; +luaC_barriert(L,t,key); +return gval(mp); +} +static const TValue*luaH_getnum(Table*t,int key){ +if(cast(unsigned int,key)-1sizearray)) +return&t->array[key-1]; +else{ +lua_Number nk=cast_num(key); +Node*n=hashnum(t,nk); +do{ +if(ttisnumber(gkey(n))&&luai_numeq(nvalue(gkey(n)),nk)) +return gval(n); +else n=gnext(n); +}while(n); +return(&luaO_nilobject_); +} +} +static const TValue*luaH_getstr(Table*t,TString*key){ +Node*n=hashstr(t,key); +do{ +if(ttisstring(gkey(n))&&rawtsvalue(gkey(n))==key) +return gval(n); +else n=gnext(n); +}while(n); +return(&luaO_nilobject_); +} +static const TValue*luaH_get(Table*t,const TValue*key){ +switch(ttype(key)){ +case 0:return(&luaO_nilobject_); +case 4:return luaH_getstr(t,rawtsvalue(key)); +case 3:{ +int k; +lua_Number n=nvalue(key); +lua_number2int(k,n); +if(luai_numeq(cast_num(k),nvalue(key))) +return luaH_getnum(t,k); +} +/*fallthrough*/ +default:{ +Node*n=mainposition(t,key); +do{ +if(luaO_rawequalObj(key2tval(n),key)) +return gval(n); +else n=gnext(n); +}while(n); +return(&luaO_nilobject_); +} +} +} +static TValue*luaH_set(lua_State*L,Table*t,const TValue*key){ +const TValue*p=luaH_get(t,key); +t->flags=0; +if(p!=(&luaO_nilobject_)) +return cast(TValue*,p); +else{ +if(ttisnil(key))luaG_runerror(L,"table index is nil"); +else if(ttisnumber(key)&&luai_numisnan(nvalue(key))) +luaG_runerror(L,"table index is NaN"); +return newkey(L,t,key); +} +} +static TValue*luaH_setnum(lua_State*L,Table*t,int key){ +const TValue*p=luaH_getnum(t,key); +if(p!=(&luaO_nilobject_)) +return cast(TValue*,p); +else{ +TValue k; +setnvalue(&k,cast_num(key)); +return newkey(L,t,&k); +} +} +static TValue*luaH_setstr(lua_State*L,Table*t,TString*key){ +const TValue*p=luaH_getstr(t,key); +if(p!=(&luaO_nilobject_)) +return cast(TValue*,p); +else{ +TValue k; +setsvalue(L,&k,key); +return newkey(L,t,&k); +} +} +static int unbound_search(Table*t,unsigned int j){ +unsigned int i=j; +j++; +while(!ttisnil(luaH_getnum(t,j))){ +i=j; +j*=2; +if(j>cast(unsigned int,(INT_MAX-2))){ +i=1; +while(!ttisnil(luaH_getnum(t,i)))i++; +return i-1; +} +} +while(j-i>1){ +unsigned int m=(i+j)/2; +if(ttisnil(luaH_getnum(t,m)))j=m; +else i=m; +} +return i; +} +static int luaH_getn(Table*t){ +unsigned int j=t->sizearray; +if(j>0&&ttisnil(&t->array[j-1])){ +unsigned int i=0; +while(j-i>1){ +unsigned int m=(i+j)/2; +if(ttisnil(&t->array[m-1]))j=m; +else i=m; +} +return i; +} +else if(t->node==(&dummynode_)) +return j; +else return unbound_search(t,j); +} +#define makewhite(g,x)((x)->gch.marked=cast_byte(((x)->gch.marked&cast_byte(~(bitmask(2)|bit2mask(0,1))))|luaC_white(g))) +#define white2gray(x)reset2bits((x)->gch.marked,0,1) +#define black2gray(x)resetbit((x)->gch.marked,2) +#define stringmark(s)reset2bits((s)->tsv.marked,0,1) +#define isfinalized(u)testbit((u)->marked,3) +#define markfinalized(u)l_setbit((u)->marked,3) +#define markvalue(g,o){checkconsistency(o);if(iscollectable(o)&&iswhite(gcvalue(o)))reallymarkobject(g,gcvalue(o));} +#define markobject(g,t){if(iswhite(obj2gco(t)))reallymarkobject(g,obj2gco(t));} +#define setthreshold(g)(g->GCthreshold=(g->estimate/100)*g->gcpause) +static void removeentry(Node*n){ +if(iscollectable(gkey(n))) +setttype(gkey(n),(8+3)); +} +static void reallymarkobject(global_State*g,GCObject*o){ +white2gray(o); +switch(o->gch.tt){ +case 4:{ +return; +} +case 7:{ +Table*mt=gco2u(o)->metatable; +gray2black(o); +if(mt)markobject(g,mt); +markobject(g,gco2u(o)->env); +return; +} +case(8+2):{ +UpVal*uv=gco2uv(o); +markvalue(g,uv->v); +if(uv->v==&uv->u.value) +gray2black(o); +return; +} +case 6:{ +gco2cl(o)->c.gclist=g->gray; +g->gray=o; +break; +} +case 5:{ +gco2h(o)->gclist=g->gray; +g->gray=o; +break; +} +case 8:{ +gco2th(o)->gclist=g->gray; +g->gray=o; +break; +} +case(8+1):{ +gco2p(o)->gclist=g->gray; +g->gray=o; +break; +} +default:; +} +} +static void marktmu(global_State*g){ +GCObject*u=g->tmudata; +if(u){ +do{ +u=u->gch.next; +makewhite(g,u); +reallymarkobject(g,u); +}while(u!=g->tmudata); +} +} +static size_t luaC_separateudata(lua_State*L,int all){ +global_State*g=G(L); +size_t deadmem=0; +GCObject**p=&g->mainthread->next; +GCObject*curr; +while((curr=*p)!=NULL){ +if(!(iswhite(curr)||all)||isfinalized(gco2u(curr))) +p=&curr->gch.next; +else if(fasttm(L,gco2u(curr)->metatable,TM_GC)==NULL){ +markfinalized(gco2u(curr)); +p=&curr->gch.next; +} +else{ +deadmem+=sizeudata(gco2u(curr)); +markfinalized(gco2u(curr)); +*p=curr->gch.next; +if(g->tmudata==NULL) +g->tmudata=curr->gch.next=curr; +else{ +curr->gch.next=g->tmudata->gch.next; +g->tmudata->gch.next=curr; +g->tmudata=curr; +} +} +} +return deadmem; +} +static int traversetable(global_State*g,Table*h){ +int i; +int weakkey=0; +int weakvalue=0; +const TValue*mode; +if(h->metatable) +markobject(g,h->metatable); +mode=gfasttm(g,h->metatable,TM_MODE); +if(mode&&ttisstring(mode)){ +weakkey=(strchr(svalue(mode),'k')!=NULL); +weakvalue=(strchr(svalue(mode),'v')!=NULL); +if(weakkey||weakvalue){ +h->marked&=~(bitmask(3)|bitmask(4)); +h->marked|=cast_byte((weakkey<<3)| +(weakvalue<<4)); +h->gclist=g->weak; +g->weak=obj2gco(h); +} +} +if(weakkey&&weakvalue)return 1; +if(!weakvalue){ +i=h->sizearray; +while(i--) +markvalue(g,&h->array[i]); +} +i=sizenode(h); +while(i--){ +Node*n=gnode(h,i); +if(ttisnil(gval(n))) +removeentry(n); +else{ +if(!weakkey)markvalue(g,gkey(n)); +if(!weakvalue)markvalue(g,gval(n)); +} +} +return weakkey||weakvalue; +} +static void traverseproto(global_State*g,Proto*f){ +int i; +if(f->source)stringmark(f->source); +for(i=0;isizek;i++) +markvalue(g,&f->k[i]); +for(i=0;isizeupvalues;i++){ +if(f->upvalues[i]) +stringmark(f->upvalues[i]); +} +for(i=0;isizep;i++){ +if(f->p[i]) +markobject(g,f->p[i]); +} +for(i=0;isizelocvars;i++){ +if(f->locvars[i].varname) +stringmark(f->locvars[i].varname); +} +} +static void traverseclosure(global_State*g,Closure*cl){ +markobject(g,cl->c.env); +if(cl->c.isC){ +int i; +for(i=0;ic.nupvalues;i++) +markvalue(g,&cl->c.upvalue[i]); +} +else{ +int i; +markobject(g,cl->l.p); +for(i=0;il.nupvalues;i++) +markobject(g,cl->l.upvals[i]); +} +} +static void checkstacksizes(lua_State*L,StkId max){ +int ci_used=cast_int(L->ci-L->base_ci); +int s_used=cast_int(max-L->stack); +if(L->size_ci>20000) +return; +if(4*ci_usedsize_ci&&2*8size_ci) +luaD_reallocCI(L,L->size_ci/2); +condhardstacktests(luaD_reallocCI(L,ci_used+1)); +if(4*s_usedstacksize&& +2*((2*20)+5)stacksize) +luaD_reallocstack(L,L->stacksize/2); +condhardstacktests(luaD_reallocstack(L,s_used)); +} +static void traversestack(global_State*g,lua_State*l){ +StkId o,lim; +CallInfo*ci; +markvalue(g,gt(l)); +lim=l->top; +for(ci=l->base_ci;ci<=l->ci;ci++){ +if(limtop)lim=ci->top; +} +for(o=l->stack;otop;o++) +markvalue(g,o); +for(;o<=lim;o++) +setnilvalue(o); +checkstacksizes(l,lim); +} +static l_mem propagatemark(global_State*g){ +GCObject*o=g->gray; +gray2black(o); +switch(o->gch.tt){ +case 5:{ +Table*h=gco2h(o); +g->gray=h->gclist; +if(traversetable(g,h)) +black2gray(o); +return sizeof(Table)+sizeof(TValue)*h->sizearray+ +sizeof(Node)*sizenode(h); +} +case 6:{ +Closure*cl=gco2cl(o); +g->gray=cl->c.gclist; +traverseclosure(g,cl); +return(cl->c.isC)?sizeCclosure(cl->c.nupvalues): +sizeLclosure(cl->l.nupvalues); +} +case 8:{ +lua_State*th=gco2th(o); +g->gray=th->gclist; +th->gclist=g->grayagain; +g->grayagain=o; +black2gray(o); +traversestack(g,th); +return sizeof(lua_State)+sizeof(TValue)*th->stacksize+ +sizeof(CallInfo)*th->size_ci; +} +case(8+1):{ +Proto*p=gco2p(o); +g->gray=p->gclist; +traverseproto(g,p); +return sizeof(Proto)+sizeof(Instruction)*p->sizecode+ +sizeof(Proto*)*p->sizep+ +sizeof(TValue)*p->sizek+ +sizeof(int)*p->sizelineinfo+ +sizeof(LocVar)*p->sizelocvars+ +sizeof(TString*)*p->sizeupvalues; +} +default:return 0; +} +} +static size_t propagateall(global_State*g){ +size_t m=0; +while(g->gray)m+=propagatemark(g); +return m; +} +static int iscleared(const TValue*o,int iskey){ +if(!iscollectable(o))return 0; +if(ttisstring(o)){ +stringmark(rawtsvalue(o)); +return 0; +} +return iswhite(gcvalue(o))|| +(ttisuserdata(o)&&(!iskey&&isfinalized(uvalue(o)))); +} +static void cleartable(GCObject*l){ +while(l){ +Table*h=gco2h(l); +int i=h->sizearray; +if(testbit(h->marked,4)){ +while(i--){ +TValue*o=&h->array[i]; +if(iscleared(o,0)) +setnilvalue(o); +} +} +i=sizenode(h); +while(i--){ +Node*n=gnode(h,i); +if(!ttisnil(gval(n))&& +(iscleared(key2tval(n),1)||iscleared(gval(n),0))){ +setnilvalue(gval(n)); +removeentry(n); +} +} +l=h->gclist; +} +} +static void freeobj(lua_State*L,GCObject*o){ +switch(o->gch.tt){ +case(8+1):luaF_freeproto(L,gco2p(o));break; +case 6:luaF_freeclosure(L,gco2cl(o));break; +case(8+2):luaF_freeupval(L,gco2uv(o));break; +case 5:luaH_free(L,gco2h(o));break; +case 8:{ +luaE_freethread(L,gco2th(o)); +break; +} +case 4:{ +G(L)->strt.nuse--; +luaM_freemem(L,o,sizestring(gco2ts(o))); +break; +} +case 7:{ +luaM_freemem(L,o,sizeudata(gco2u(o))); +break; +} +default:; +} +} +#define sweepwholelist(L,p)sweeplist(L,p,((lu_mem)(~(lu_mem)0)-2)) +static GCObject**sweeplist(lua_State*L,GCObject**p,lu_mem count){ +GCObject*curr; +global_State*g=G(L); +int deadmask=otherwhite(g); +while((curr=*p)!=NULL&&count-->0){ +if(curr->gch.tt==8) +sweepwholelist(L,&gco2th(curr)->openupval); +if((curr->gch.marked^bit2mask(0,1))&deadmask){ +makewhite(g,curr); +p=&curr->gch.next; +} +else{ +*p=curr->gch.next; +if(curr==g->rootgc) +g->rootgc=curr->gch.next; +freeobj(L,curr); +} +} +return p; +} +static void checkSizes(lua_State*L){ +global_State*g=G(L); +if(g->strt.nusestrt.size/4)&& +g->strt.size>32*2) +luaS_resize(L,g->strt.size/2); +if(luaZ_sizebuffer(&g->buff)>32*2){ +size_t newsize=luaZ_sizebuffer(&g->buff)/2; +luaZ_resizebuffer(L,&g->buff,newsize); +} +} +static void GCTM(lua_State*L){ +global_State*g=G(L); +GCObject*o=g->tmudata->gch.next; +Udata*udata=rawgco2u(o); +const TValue*tm; +if(o==g->tmudata) +g->tmudata=NULL; +else +g->tmudata->gch.next=udata->uv.next; +udata->uv.next=g->mainthread->next; +g->mainthread->next=o; +makewhite(g,o); +tm=fasttm(L,udata->uv.metatable,TM_GC); +if(tm!=NULL){ +lu_byte oldah=L->allowhook; +lu_mem oldt=g->GCthreshold; +L->allowhook=0; +g->GCthreshold=2*g->totalbytes; +setobj(L,L->top,tm); +setuvalue(L,L->top+1,udata); +L->top+=2; +luaD_call(L,L->top-2,0); +L->allowhook=oldah; +g->GCthreshold=oldt; +} +} +static void luaC_callGCTM(lua_State*L){ +while(G(L)->tmudata) +GCTM(L); +} +static void luaC_freeall(lua_State*L){ +global_State*g=G(L); +int i; +g->currentwhite=bit2mask(0,1)|bitmask(6); +sweepwholelist(L,&g->rootgc); +for(i=0;istrt.size;i++) +sweepwholelist(L,&g->strt.hash[i]); +} +static void markmt(global_State*g){ +int i; +for(i=0;i<(8+1);i++) +if(g->mt[i])markobject(g,g->mt[i]); +} +static void markroot(lua_State*L){ +global_State*g=G(L); +g->gray=NULL; +g->grayagain=NULL; +g->weak=NULL; +markobject(g,g->mainthread); +markvalue(g,gt(g->mainthread)); +markvalue(g,registry(L)); +markmt(g); +g->gcstate=1; +} +static void remarkupvals(global_State*g){ +UpVal*uv; +for(uv=g->uvhead.u.l.next;uv!=&g->uvhead;uv=uv->u.l.next){ +if(isgray(obj2gco(uv))) +markvalue(g,uv->v); +} +} +static void atomic(lua_State*L){ +global_State*g=G(L); +size_t udsize; +remarkupvals(g); +propagateall(g); +g->gray=g->weak; +g->weak=NULL; +markobject(g,L); +markmt(g); +propagateall(g); +g->gray=g->grayagain; +g->grayagain=NULL; +propagateall(g); +udsize=luaC_separateudata(L,0); +marktmu(g); +udsize+=propagateall(g); +cleartable(g->weak); +g->currentwhite=cast_byte(otherwhite(g)); +g->sweepstrgc=0; +g->sweepgc=&g->rootgc; +g->gcstate=2; +g->estimate=g->totalbytes-udsize; +} +static l_mem singlestep(lua_State*L){ +global_State*g=G(L); +switch(g->gcstate){ +case 0:{ +markroot(L); +return 0; +} +case 1:{ +if(g->gray) +return propagatemark(g); +else{ +atomic(L); +return 0; +} +} +case 2:{ +lu_mem old=g->totalbytes; +sweepwholelist(L,&g->strt.hash[g->sweepstrgc++]); +if(g->sweepstrgc>=g->strt.size) +g->gcstate=3; +g->estimate-=old-g->totalbytes; +return 10; +} +case 3:{ +lu_mem old=g->totalbytes; +g->sweepgc=sweeplist(L,g->sweepgc,40); +if(*g->sweepgc==NULL){ +checkSizes(L); +g->gcstate=4; +} +g->estimate-=old-g->totalbytes; +return 40*10; +} +case 4:{ +if(g->tmudata){ +GCTM(L); +if(g->estimate>100) +g->estimate-=100; +return 100; +} +else{ +g->gcstate=0; +g->gcdept=0; +return 0; +} +} +default:return 0; +} +} +static void luaC_step(lua_State*L){ +global_State*g=G(L); +l_mem lim=(1024u/100)*g->gcstepmul; +if(lim==0) +lim=(((lu_mem)(~(lu_mem)0)-2)-1)/2; +g->gcdept+=g->totalbytes-g->GCthreshold; +do{ +lim-=singlestep(L); +if(g->gcstate==0) +break; +}while(lim>0); +if(g->gcstate!=0){ +if(g->gcdept<1024u) +g->GCthreshold=g->totalbytes+1024u; +else{ +g->gcdept-=1024u; +g->GCthreshold=g->totalbytes; +} +} +else{ +setthreshold(g); +} +} +static void luaC_barrierf(lua_State*L,GCObject*o,GCObject*v){ +global_State*g=G(L); +if(g->gcstate==1) +reallymarkobject(g,v); +else +makewhite(g,o); +} +static void luaC_barrierback(lua_State*L,Table*t){ +global_State*g=G(L); +GCObject*o=obj2gco(t); +black2gray(o); +t->gclist=g->grayagain; +g->grayagain=o; +} +static void luaC_link(lua_State*L,GCObject*o,lu_byte tt){ +global_State*g=G(L); +o->gch.next=g->rootgc; +g->rootgc=o; +o->gch.marked=luaC_white(g); +o->gch.tt=tt; +} +static void luaC_linkupval(lua_State*L,UpVal*uv){ +global_State*g=G(L); +GCObject*o=obj2gco(uv); +o->gch.next=g->rootgc; +g->rootgc=o; +if(isgray(o)){ +if(g->gcstate==1){ +gray2black(o); +luaC_barrier(L,uv,uv->v); +} +else{ +makewhite(g,o); +} +} +} +typedef union{ +lua_Number r; +TString*ts; +}SemInfo; +typedef struct Token{ +int token; +SemInfo seminfo; +}Token; +typedef struct LexState{ +int current; +int linenumber; +int lastline; +Token t; +Token lookahead; +struct FuncState*fs; +struct lua_State*L; +ZIO*z; +Mbuffer*buff; +TString*source; +char decpoint; +}LexState; +static void luaX_init(lua_State*L); +static void luaX_lexerror(LexState*ls,const char*msg,int token); +#define state_size(x)(sizeof(x)+0) +#define fromstate(l)(cast(lu_byte*,(l))-0) +#define tostate(l)(cast(lua_State*,cast(lu_byte*,l)+0)) +typedef struct LG{ +lua_State l; +global_State g; +}LG; +static void stack_init(lua_State*L1,lua_State*L){ +L1->base_ci=luaM_newvector(L,8,CallInfo); +L1->ci=L1->base_ci; +L1->size_ci=8; +L1->end_ci=L1->base_ci+L1->size_ci-1; +L1->stack=luaM_newvector(L,(2*20)+5,TValue); +L1->stacksize=(2*20)+5; +L1->top=L1->stack; +L1->stack_last=L1->stack+(L1->stacksize-5)-1; +L1->ci->func=L1->top; +setnilvalue(L1->top++); +L1->base=L1->ci->base=L1->top; +L1->ci->top=L1->top+20; +} +static void freestack(lua_State*L,lua_State*L1){ +luaM_freearray(L,L1->base_ci,L1->size_ci,CallInfo); +luaM_freearray(L,L1->stack,L1->stacksize,TValue); +} +static void f_luaopen(lua_State*L,void*ud){ +global_State*g=G(L); +UNUSED(ud); +stack_init(L,L); +sethvalue(L,gt(L),luaH_new(L,0,2)); +sethvalue(L,registry(L),luaH_new(L,0,2)); +luaS_resize(L,32); +luaT_init(L); +luaX_init(L); +luaS_fix(luaS_newliteral(L,"not enough memory")); +g->GCthreshold=4*g->totalbytes; +} +static void preinit_state(lua_State*L,global_State*g){ +G(L)=g; +L->stack=NULL; +L->stacksize=0; +L->errorJmp=NULL; +L->hook=NULL; +L->hookmask=0; +L->basehookcount=0; +L->allowhook=1; +resethookcount(L); +L->openupval=NULL; +L->size_ci=0; +L->nCcalls=L->baseCcalls=0; +L->status=0; +L->base_ci=L->ci=NULL; +L->savedpc=NULL; +L->errfunc=0; +setnilvalue(gt(L)); +} +static void close_state(lua_State*L){ +global_State*g=G(L); +luaF_close(L,L->stack); +luaC_freeall(L); +luaM_freearray(L,G(L)->strt.hash,G(L)->strt.size,TString*); +luaZ_freebuffer(L,&g->buff); +freestack(L,L); +(*g->frealloc)(g->ud,fromstate(L),state_size(LG),0); +} +static void luaE_freethread(lua_State*L,lua_State*L1){ +luaF_close(L1,L1->stack); +freestack(L,L1); +luaM_freemem(L,fromstate(L1),state_size(lua_State)); +} +static lua_State*lua_newstate(lua_Alloc f,void*ud){ +int i; +lua_State*L; +global_State*g; +void*l=(*f)(ud,NULL,0,state_size(LG)); +if(l==NULL)return NULL; +L=tostate(l); +g=&((LG*)L)->g; +L->next=NULL; +L->tt=8; +g->currentwhite=bit2mask(0,5); +L->marked=luaC_white(g); +set2bits(L->marked,5,6); +preinit_state(L,g); +g->frealloc=f; +g->ud=ud; +g->mainthread=L; +g->uvhead.u.l.prev=&g->uvhead; +g->uvhead.u.l.next=&g->uvhead; +g->GCthreshold=0; +g->strt.size=0; +g->strt.nuse=0; +g->strt.hash=NULL; +setnilvalue(registry(L)); +luaZ_initbuffer(L,&g->buff); +g->panic=NULL; +g->gcstate=0; +g->rootgc=obj2gco(L); +g->sweepstrgc=0; +g->sweepgc=&g->rootgc; +g->gray=NULL; +g->grayagain=NULL; +g->weak=NULL; +g->tmudata=NULL; +g->totalbytes=sizeof(LG); +g->gcpause=200; +g->gcstepmul=200; +g->gcdept=0; +for(i=0;i<(8+1);i++)g->mt[i]=NULL; +if(luaD_rawrunprotected(L,f_luaopen,NULL)!=0){ +close_state(L); +L=NULL; +} +else +{} +return L; +} +static void callallgcTM(lua_State*L,void*ud){ +UNUSED(ud); +luaC_callGCTM(L); +} +static void lua_close(lua_State*L){ +L=G(L)->mainthread; +luaF_close(L,L->stack); +luaC_separateudata(L,1); +L->errfunc=0; +do{ +L->ci=L->base_ci; +L->base=L->top=L->ci->base; +L->nCcalls=L->baseCcalls=0; +}while(luaD_rawrunprotected(L,callallgcTM,NULL)!=0); +close_state(L); +} +#define getcode(fs,e)((fs)->f->code[(e)->u.s.info]) +#define luaK_codeAsBx(fs,o,A,sBx)luaK_codeABx(fs,o,A,(sBx)+(((1<<(9+9))-1)>>1)) +#define luaK_setmultret(fs,e)luaK_setreturns(fs,e,(-1)) +static int luaK_codeABx(FuncState*fs,OpCode o,int A,unsigned int Bx); +static int luaK_codeABC(FuncState*fs,OpCode o,int A,int B,int C); +static void luaK_setreturns(FuncState*fs,expdesc*e,int nresults); +static void luaK_patchtohere(FuncState*fs,int list); +static void luaK_concat(FuncState*fs,int*l1,int l2); +static int currentpc(lua_State*L,CallInfo*ci){ +if(!isLua(ci))return-1; +if(ci==L->ci) +ci->savedpc=L->savedpc; +return pcRel(ci->savedpc,ci_func(ci)->l.p); +} +static int currentline(lua_State*L,CallInfo*ci){ +int pc=currentpc(L,ci); +if(pc<0) +return-1; +else +return getline_(ci_func(ci)->l.p,pc); +} +static int lua_getstack(lua_State*L,int level,lua_Debug*ar){ +int status; +CallInfo*ci; +for(ci=L->ci;level>0&&ci>L->base_ci;ci--){ +level--; +if(f_isLua(ci)) +level-=ci->tailcalls; +} +if(level==0&&ci>L->base_ci){ +status=1; +ar->i_ci=cast_int(ci-L->base_ci); +} +else if(level<0){ +status=1; +ar->i_ci=0; +} +else status=0; +return status; +} +static Proto*getluaproto(CallInfo*ci){ +return(isLua(ci)?ci_func(ci)->l.p:NULL); +} +static void funcinfo(lua_Debug*ar,Closure*cl){ +if(cl->c.isC){ +ar->source="=[C]"; +ar->linedefined=-1; +ar->lastlinedefined=-1; +ar->what="C"; +} +else{ +ar->source=getstr(cl->l.p->source); +ar->linedefined=cl->l.p->linedefined; +ar->lastlinedefined=cl->l.p->lastlinedefined; +ar->what=(ar->linedefined==0)?"main":"Lua"; +} +luaO_chunkid(ar->short_src,ar->source,60); +} +static void info_tailcall(lua_Debug*ar){ +ar->name=ar->namewhat=""; +ar->what="tail"; +ar->lastlinedefined=ar->linedefined=ar->currentline=-1; +ar->source="=(tail call)"; +luaO_chunkid(ar->short_src,ar->source,60); +ar->nups=0; +} +static void collectvalidlines(lua_State*L,Closure*f){ +if(f==NULL||f->c.isC){ +setnilvalue(L->top); +} +else{ +Table*t=luaH_new(L,0,0); +int*lineinfo=f->l.p->lineinfo; +int i; +for(i=0;il.p->sizelineinfo;i++) +setbvalue(luaH_setnum(L,t,lineinfo[i]),1); +sethvalue(L,L->top,t); +} +incr_top(L); +} +static int auxgetinfo(lua_State*L,const char*what,lua_Debug*ar, +Closure*f,CallInfo*ci){ +int status=1; +if(f==NULL){ +info_tailcall(ar); +return status; +} +for(;*what;what++){ +switch(*what){ +case'S':{ +funcinfo(ar,f); +break; +} +case'l':{ +ar->currentline=(ci)?currentline(L,ci):-1; +break; +} +case'u':{ +ar->nups=f->c.nupvalues; +break; +} +case'n':{ +ar->namewhat=(ci)?NULL:NULL; +if(ar->namewhat==NULL){ +ar->namewhat=""; +ar->name=NULL; +} +break; +} +case'L': +case'f': +break; +default:status=0; +} +} +return status; +} +static int lua_getinfo(lua_State*L,const char*what,lua_Debug*ar){ +int status; +Closure*f=NULL; +CallInfo*ci=NULL; +if(*what=='>'){ +StkId func=L->top-1; +luai_apicheck(L,ttisfunction(func)); +what++; +f=clvalue(func); +L->top--; +} +else if(ar->i_ci!=0){ +ci=L->base_ci+ar->i_ci; +f=clvalue(ci->func); +} +status=auxgetinfo(L,what,ar,f,ci); +if(strchr(what,'f')){ +if(f==NULL)setnilvalue(L->top); +else setclvalue(L,L->top,f); +incr_top(L); +} +if(strchr(what,'L')) +collectvalidlines(L,f); +return status; +} +static int isinstack(CallInfo*ci,const TValue*o){ +StkId p; +for(p=ci->base;ptop;p++) +if(o==p)return 1; +return 0; +} +static void luaG_typeerror(lua_State*L,const TValue*o,const char*op){ +const char*name=NULL; +const char*t=luaT_typenames[ttype(o)]; +const char*kind=(isinstack(L->ci,o))? +NULL: +NULL; +if(kind) +luaG_runerror(L,"attempt to %s %s "LUA_QL("%s")" (a %s value)", +op,kind,name,t); +else +luaG_runerror(L,"attempt to %s a %s value",op,t); +} +static void luaG_concaterror(lua_State*L,StkId p1,StkId p2){ +if(ttisstring(p1)||ttisnumber(p1))p1=p2; +luaG_typeerror(L,p1,"concatenate"); +} +static void luaG_aritherror(lua_State*L,const TValue*p1,const TValue*p2){ +TValue temp; +if(luaV_tonumber(p1,&temp)==NULL) +p2=p1; +luaG_typeerror(L,p2,"perform arithmetic on"); +} +static int luaG_ordererror(lua_State*L,const TValue*p1,const TValue*p2){ +const char*t1=luaT_typenames[ttype(p1)]; +const char*t2=luaT_typenames[ttype(p2)]; +if(t1[2]==t2[2]) +luaG_runerror(L,"attempt to compare two %s values",t1); +else +luaG_runerror(L,"attempt to compare %s with %s",t1,t2); +return 0; +} +static void addinfo(lua_State*L,const char*msg){ +CallInfo*ci=L->ci; +if(isLua(ci)){ +char buff[60]; +int line=currentline(L,ci); +luaO_chunkid(buff,getstr(getluaproto(ci)->source),60); +luaO_pushfstring(L,"%s:%d: %s",buff,line,msg); +} +} +static void luaG_errormsg(lua_State*L){ +if(L->errfunc!=0){ +StkId errfunc=restorestack(L,L->errfunc); +if(!ttisfunction(errfunc))luaD_throw(L,5); +setobj(L,L->top,L->top-1); +setobj(L,L->top-1,errfunc); +incr_top(L); +luaD_call(L,L->top-2,1); +} +luaD_throw(L,2); +} +static void luaG_runerror(lua_State*L,const char*fmt,...){ +va_list argp; +va_start(argp,fmt); +addinfo(L,luaO_pushvfstring(L,fmt,argp)); +va_end(argp); +luaG_errormsg(L); +} +static int luaZ_fill(ZIO*z){ +size_t size; +lua_State*L=z->L; +const char*buff; +buff=z->reader(L,z->data,&size); +if(buff==NULL||size==0)return(-1); +z->n=size-1; +z->p=buff; +return char2int(*(z->p++)); +} +static void luaZ_init(lua_State*L,ZIO*z,lua_Reader reader,void*data){ +z->L=L; +z->reader=reader; +z->data=data; +z->n=0; +z->p=NULL; +} +static char*luaZ_openspace(lua_State*L,Mbuffer*buff,size_t n){ +if(n>buff->buffsize){ +if(n<32)n=32; +luaZ_resizebuffer(L,buff,n); +} +return buff->buffer; +} +#define opmode(t,a,b,c,m)(((t)<<7)|((a)<<6)|((b)<<4)|((c)<<2)|(m)) +static const lu_byte luaP_opmodes[(cast(int,OP_VARARG)+1)]={ +opmode(0,1,OpArgR,OpArgN,iABC) +,opmode(0,1,OpArgK,OpArgN,iABx) +,opmode(0,1,OpArgU,OpArgU,iABC) +,opmode(0,1,OpArgR,OpArgN,iABC) +,opmode(0,1,OpArgU,OpArgN,iABC) +,opmode(0,1,OpArgK,OpArgN,iABx) +,opmode(0,1,OpArgR,OpArgK,iABC) +,opmode(0,0,OpArgK,OpArgN,iABx) +,opmode(0,0,OpArgU,OpArgN,iABC) +,opmode(0,0,OpArgK,OpArgK,iABC) +,opmode(0,1,OpArgU,OpArgU,iABC) +,opmode(0,1,OpArgR,OpArgK,iABC) +,opmode(0,1,OpArgK,OpArgK,iABC) +,opmode(0,1,OpArgK,OpArgK,iABC) +,opmode(0,1,OpArgK,OpArgK,iABC) +,opmode(0,1,OpArgK,OpArgK,iABC) +,opmode(0,1,OpArgK,OpArgK,iABC) +,opmode(0,1,OpArgK,OpArgK,iABC) +,opmode(0,1,OpArgR,OpArgN,iABC) +,opmode(0,1,OpArgR,OpArgN,iABC) +,opmode(0,1,OpArgR,OpArgN,iABC) +,opmode(0,1,OpArgR,OpArgR,iABC) +,opmode(0,0,OpArgR,OpArgN,iAsBx) +,opmode(1,0,OpArgK,OpArgK,iABC) +,opmode(1,0,OpArgK,OpArgK,iABC) +,opmode(1,0,OpArgK,OpArgK,iABC) +,opmode(1,1,OpArgR,OpArgU,iABC) +,opmode(1,1,OpArgR,OpArgU,iABC) +,opmode(0,1,OpArgU,OpArgU,iABC) +,opmode(0,1,OpArgU,OpArgU,iABC) +,opmode(0,0,OpArgU,OpArgN,iABC) +,opmode(0,1,OpArgR,OpArgN,iAsBx) +,opmode(0,1,OpArgR,OpArgN,iAsBx) +,opmode(1,0,OpArgN,OpArgU,iABC) +,opmode(0,0,OpArgU,OpArgU,iABC) +,opmode(0,0,OpArgN,OpArgN,iABC) +,opmode(0,1,OpArgU,OpArgN,iABx) +,opmode(0,1,OpArgU,OpArgN,iABC) +}; +#define next(ls)(ls->current=zgetc(ls->z)) +#define currIsNewline(ls)(ls->current=='\n'||ls->current=='\r') +static const char*const luaX_tokens[]={ +"and","break","do","else","elseif", +"end","false","for","function","if", +"in","local","nil","not","or","repeat", +"return","then","true","until","while", +"..","...","==",">=","<=","~=", +"","","","", +NULL +}; +#define save_and_next(ls)(save(ls,ls->current),next(ls)) +static void save(LexState*ls,int c){ +Mbuffer*b=ls->buff; +if(b->n+1>b->buffsize){ +size_t newsize; +if(b->buffsize>=((size_t)(~(size_t)0)-2)/2) +luaX_lexerror(ls,"lexical element too long",0); +newsize=b->buffsize*2; +luaZ_resizebuffer(ls->L,b,newsize); +} +b->buffer[b->n++]=cast(char,c); +} +static void luaX_init(lua_State*L){ +int i; +for(i=0;i<(cast(int,TK_WHILE-257+1));i++){ +TString*ts=luaS_new(L,luaX_tokens[i]); +luaS_fix(ts); +ts->tsv.reserved=cast_byte(i+1); +} +} +static const char*luaX_token2str(LexState*ls,int token){ +if(token<257){ +return(iscntrl(token))?luaO_pushfstring(ls->L,"char(%d)",token): +luaO_pushfstring(ls->L,"%c",token); +} +else +return luaX_tokens[token-257]; +} +static const char*txtToken(LexState*ls,int token){ +switch(token){ +case TK_NAME: +case TK_STRING: +case TK_NUMBER: +save(ls,'\0'); +return luaZ_buffer(ls->buff); +default: +return luaX_token2str(ls,token); +} +} +static void luaX_lexerror(LexState*ls,const char*msg,int token){ +char buff[80]; +luaO_chunkid(buff,getstr(ls->source),80); +msg=luaO_pushfstring(ls->L,"%s:%d: %s",buff,ls->linenumber,msg); +if(token) +luaO_pushfstring(ls->L,"%s near "LUA_QL("%s"),msg,txtToken(ls,token)); +luaD_throw(ls->L,3); +} +static void luaX_syntaxerror(LexState*ls,const char*msg){ +luaX_lexerror(ls,msg,ls->t.token); +} +static TString*luaX_newstring(LexState*ls,const char*str,size_t l){ +lua_State*L=ls->L; +TString*ts=luaS_newlstr(L,str,l); +TValue*o=luaH_setstr(L,ls->fs->h,ts); +if(ttisnil(o)){ +setbvalue(o,1); +luaC_checkGC(L); +} +return ts; +} +static void inclinenumber(LexState*ls){ +int old=ls->current; +next(ls); +if(currIsNewline(ls)&&ls->current!=old) +next(ls); +if(++ls->linenumber>=(INT_MAX-2)) +luaX_syntaxerror(ls,"chunk has too many lines"); +} +static void luaX_setinput(lua_State*L,LexState*ls,ZIO*z,TString*source){ +ls->decpoint='.'; +ls->L=L; +ls->lookahead.token=TK_EOS; +ls->z=z; +ls->fs=NULL; +ls->linenumber=1; +ls->lastline=1; +ls->source=source; +luaZ_resizebuffer(ls->L,ls->buff,32); +next(ls); +} +static int check_next(LexState*ls,const char*set){ +if(!strchr(set,ls->current)) +return 0; +save_and_next(ls); +return 1; +} +static void buffreplace(LexState*ls,char from,char to){ +size_t n=luaZ_bufflen(ls->buff); +char*p=luaZ_buffer(ls->buff); +while(n--) +if(p[n]==from)p[n]=to; +} +static void read_numeral(LexState*ls,SemInfo*seminfo){ +do{ +save_and_next(ls); +}while(isdigit(ls->current)||ls->current=='.'); +if(check_next(ls,"Ee")) +check_next(ls,"+-"); +while(isalnum(ls->current)||ls->current=='_') +save_and_next(ls); +save(ls,'\0'); +buffreplace(ls,'.',ls->decpoint); +if(!luaO_str2d(luaZ_buffer(ls->buff),&seminfo->r)) +luaX_lexerror(ls,"malformed number",TK_NUMBER); +} +static int skip_sep(LexState*ls){ +int count=0; +int s=ls->current; +save_and_next(ls); +while(ls->current=='='){ +save_and_next(ls); +count++; +} +return(ls->current==s)?count:(-count)-1; +} +static void read_long_string(LexState*ls,SemInfo*seminfo,int sep){ +int cont=0; +(void)(cont); +save_and_next(ls); +if(currIsNewline(ls)) +inclinenumber(ls); +for(;;){ +switch(ls->current){ +case(-1): +luaX_lexerror(ls,(seminfo)?"unfinished long string": +"unfinished long comment",TK_EOS); +break; +case']':{ +if(skip_sep(ls)==sep){ +save_and_next(ls); +goto endloop; +} +break; +} +case'\n': +case'\r':{ +save(ls,'\n'); +inclinenumber(ls); +if(!seminfo)luaZ_resetbuffer(ls->buff); +break; +} +default:{ +if(seminfo)save_and_next(ls); +else next(ls); +} +} +}endloop: +if(seminfo) +seminfo->ts=luaX_newstring(ls,luaZ_buffer(ls->buff)+(2+sep), +luaZ_bufflen(ls->buff)-2*(2+sep)); +} +static void read_string(LexState*ls,int del,SemInfo*seminfo){ +save_and_next(ls); +while(ls->current!=del){ +switch(ls->current){ +case(-1): +luaX_lexerror(ls,"unfinished string",TK_EOS); +continue; +case'\n': +case'\r': +luaX_lexerror(ls,"unfinished string",TK_STRING); +continue; +case'\\':{ +int c; +next(ls); +switch(ls->current){ +case'a':c='\a';break; +case'b':c='\b';break; +case'f':c='\f';break; +case'n':c='\n';break; +case'r':c='\r';break; +case't':c='\t';break; +case'v':c='\v';break; +case'\n': +case'\r':save(ls,'\n');inclinenumber(ls);continue; +case(-1):continue; +default:{ +if(!isdigit(ls->current)) +save_and_next(ls); +else{ +int i=0; +c=0; +do{ +c=10*c+(ls->current-'0'); +next(ls); +}while(++i<3&&isdigit(ls->current)); +if(c>UCHAR_MAX) +luaX_lexerror(ls,"escape sequence too large",TK_STRING); +save(ls,c); +} +continue; +} +} +save(ls,c); +next(ls); +continue; +} +default: +save_and_next(ls); +} +} +save_and_next(ls); +seminfo->ts=luaX_newstring(ls,luaZ_buffer(ls->buff)+1, +luaZ_bufflen(ls->buff)-2); +} +static int llex(LexState*ls,SemInfo*seminfo){ +luaZ_resetbuffer(ls->buff); +for(;;){ +switch(ls->current){ +case'\n': +case'\r':{ +inclinenumber(ls); +continue; +} +case'-':{ +next(ls); +if(ls->current!='-')return'-'; +next(ls); +if(ls->current=='['){ +int sep=skip_sep(ls); +luaZ_resetbuffer(ls->buff); +if(sep>=0){ +read_long_string(ls,NULL,sep); +luaZ_resetbuffer(ls->buff); +continue; +} +} +while(!currIsNewline(ls)&&ls->current!=(-1)) +next(ls); +continue; +} +case'[':{ +int sep=skip_sep(ls); +if(sep>=0){ +read_long_string(ls,seminfo,sep); +return TK_STRING; +} +else if (sep!=-1)luaX_lexerror(ls,"invalid long string delimiter",TK_STRING); +return'['; +} +case'=':{ +next(ls); +if(ls->current!='=')return'='; +else{next(ls);return TK_EQ;} +} +case'<':{ +next(ls); +if(ls->current!='=')return'<'; +else{next(ls);return TK_LE;} +} +case'>':{ +next(ls); +if(ls->current!='=')return'>'; +else{next(ls);return TK_GE;} +} +case'~':{ +next(ls); +if(ls->current!='=')return'~'; +else{next(ls);return TK_NE;} +} +case'"': +case'\'':{ +read_string(ls,ls->current,seminfo); +return TK_STRING; +} +case'.':{ +save_and_next(ls); +if(check_next(ls,".")){ +if(check_next(ls,".")) +return TK_DOTS; +else return TK_CONCAT; +} +else if(!isdigit(ls->current))return'.'; +else{ +read_numeral(ls,seminfo); +return TK_NUMBER; +} +} +case(-1):{ +return TK_EOS; +} +default:{ +if(isspace(ls->current)){ +next(ls); +continue; +} +else if(isdigit(ls->current)){ +read_numeral(ls,seminfo); +return TK_NUMBER; +} +else if(isalpha(ls->current)||ls->current=='_'){ +TString*ts; +do{ +save_and_next(ls); +}while(isalnum(ls->current)||ls->current=='_'); +ts=luaX_newstring(ls,luaZ_buffer(ls->buff), +luaZ_bufflen(ls->buff)); +if(ts->tsv.reserved>0) +return ts->tsv.reserved-1+257; +else{ +seminfo->ts=ts; +return TK_NAME; +} +} +else{ +int c=ls->current; +next(ls); +return c; +} +} +} +} +} +static void luaX_next(LexState*ls){ +ls->lastline=ls->linenumber; +if(ls->lookahead.token!=TK_EOS){ +ls->t=ls->lookahead; +ls->lookahead.token=TK_EOS; +} +else +ls->t.token=llex(ls,&ls->t.seminfo); +} +static void luaX_lookahead(LexState*ls){ +ls->lookahead.token=llex(ls,&ls->lookahead.seminfo); +} +#define hasjumps(e)((e)->t!=(e)->f) +static int isnumeral(expdesc*e){ +return(e->k==VKNUM&&e->t==(-1)&&e->f==(-1)); +} +static void luaK_nil(FuncState*fs,int from,int n){ +Instruction*previous; +if(fs->pc>fs->lasttarget){ +if(fs->pc==0){ +if(from>=fs->nactvar) +return; +} +else{ +previous=&fs->f->code[fs->pc-1]; +if(GET_OPCODE(*previous)==OP_LOADNIL){ +int pfrom=GETARG_A(*previous); +int pto=GETARG_B(*previous); +if(pfrom<=from&&from<=pto+1){ +if(from+n-1>pto) +SETARG_B(*previous,from+n-1); +return; +} +} +} +} +luaK_codeABC(fs,OP_LOADNIL,from,from+n-1,0); +} +static int luaK_jump(FuncState*fs){ +int jpc=fs->jpc; +int j; +fs->jpc=(-1); +j=luaK_codeAsBx(fs,OP_JMP,0,(-1)); +luaK_concat(fs,&j,jpc); +return j; +} +static void luaK_ret(FuncState*fs,int first,int nret){ +luaK_codeABC(fs,OP_RETURN,first,nret+1,0); +} +static int condjump(FuncState*fs,OpCode op,int A,int B,int C){ +luaK_codeABC(fs,op,A,B,C); +return luaK_jump(fs); +} +static void fixjump(FuncState*fs,int pc,int dest){ +Instruction*jmp=&fs->f->code[pc]; +int offset=dest-(pc+1); +if(abs(offset)>(((1<<(9+9))-1)>>1)) +luaX_syntaxerror(fs->ls,"control structure too long"); +SETARG_sBx(*jmp,offset); +} +static int luaK_getlabel(FuncState*fs){ +fs->lasttarget=fs->pc; +return fs->pc; +} +static int getjump(FuncState*fs,int pc){ +int offset=GETARG_sBx(fs->f->code[pc]); +if(offset==(-1)) +return(-1); +else +return(pc+1)+offset; +} +static Instruction*getjumpcontrol(FuncState*fs,int pc){ +Instruction*pi=&fs->f->code[pc]; +if(pc>=1&&testTMode(GET_OPCODE(*(pi-1)))) +return pi-1; +else +return pi; +} +static int need_value(FuncState*fs,int list){ +for(;list!=(-1);list=getjump(fs,list)){ +Instruction i=*getjumpcontrol(fs,list); +if(GET_OPCODE(i)!=OP_TESTSET)return 1; +} +return 0; +} +static int patchtestreg(FuncState*fs,int node,int reg){ +Instruction*i=getjumpcontrol(fs,node); +if(GET_OPCODE(*i)!=OP_TESTSET) +return 0; +if(reg!=((1<<8)-1)&®!=GETARG_B(*i)) +SETARG_A(*i,reg); +else +*i=CREATE_ABC(OP_TEST,GETARG_B(*i),0,GETARG_C(*i)); +return 1; +} +static void removevalues(FuncState*fs,int list){ +for(;list!=(-1);list=getjump(fs,list)) +patchtestreg(fs,list,((1<<8)-1)); +} +static void patchlistaux(FuncState*fs,int list,int vtarget,int reg, +int dtarget){ +while(list!=(-1)){ +int next=getjump(fs,list); +if(patchtestreg(fs,list,reg)) +fixjump(fs,list,vtarget); +else +fixjump(fs,list,dtarget); +list=next; +} +} +static void dischargejpc(FuncState*fs){ +patchlistaux(fs,fs->jpc,fs->pc,((1<<8)-1),fs->pc); +fs->jpc=(-1); +} +static void luaK_patchlist(FuncState*fs,int list,int target){ +if(target==fs->pc) +luaK_patchtohere(fs,list); +else{ +patchlistaux(fs,list,target,((1<<8)-1),target); +} +} +static void luaK_patchtohere(FuncState*fs,int list){ +luaK_getlabel(fs); +luaK_concat(fs,&fs->jpc,list); +} +static void luaK_concat(FuncState*fs,int*l1,int l2){ +if(l2==(-1))return; +else if(*l1==(-1)) +*l1=l2; +else{ +int list=*l1; +int next; +while((next=getjump(fs,list))!=(-1)) +list=next; +fixjump(fs,list,l2); +} +} +static void luaK_checkstack(FuncState*fs,int n){ +int newstack=fs->freereg+n; +if(newstack>fs->f->maxstacksize){ +if(newstack>=250) +luaX_syntaxerror(fs->ls,"function or expression too complex"); +fs->f->maxstacksize=cast_byte(newstack); +} +} +static void luaK_reserveregs(FuncState*fs,int n){ +luaK_checkstack(fs,n); +fs->freereg+=n; +} +static void freereg(FuncState*fs,int reg){ +if(!ISK(reg)&®>=fs->nactvar){ +fs->freereg--; +} +} +static void freeexp(FuncState*fs,expdesc*e){ +if(e->k==VNONRELOC) +freereg(fs,e->u.s.info); +} +static int addk(FuncState*fs,TValue*k,TValue*v){ +lua_State*L=fs->L; +TValue*idx=luaH_set(L,fs->h,k); +Proto*f=fs->f; +int oldsize=f->sizek; +if(ttisnumber(idx)){ +return cast_int(nvalue(idx)); +} +else{ +setnvalue(idx,cast_num(fs->nk)); +luaM_growvector(L,f->k,fs->nk,f->sizek,TValue, +((1<<(9+9))-1),"constant table overflow"); +while(oldsizesizek)setnilvalue(&f->k[oldsize++]); +setobj(L,&f->k[fs->nk],v); +luaC_barrier(L,f,v); +return fs->nk++; +} +} +static int luaK_stringK(FuncState*fs,TString*s){ +TValue o; +setsvalue(fs->L,&o,s); +return addk(fs,&o,&o); +} +static int luaK_numberK(FuncState*fs,lua_Number r){ +TValue o; +setnvalue(&o,r); +return addk(fs,&o,&o); +} +static int boolK(FuncState*fs,int b){ +TValue o; +setbvalue(&o,b); +return addk(fs,&o,&o); +} +static int nilK(FuncState*fs){ +TValue k,v; +setnilvalue(&v); +sethvalue(fs->L,&k,fs->h); +return addk(fs,&k,&v); +} +static void luaK_setreturns(FuncState*fs,expdesc*e,int nresults){ +if(e->k==VCALL){ +SETARG_C(getcode(fs,e),nresults+1); +} +else if(e->k==VVARARG){ +SETARG_B(getcode(fs,e),nresults+1); +SETARG_A(getcode(fs,e),fs->freereg); +luaK_reserveregs(fs,1); +} +} +static void luaK_setoneret(FuncState*fs,expdesc*e){ +if(e->k==VCALL){ +e->k=VNONRELOC; +e->u.s.info=GETARG_A(getcode(fs,e)); +} +else if(e->k==VVARARG){ +SETARG_B(getcode(fs,e),2); +e->k=VRELOCABLE; +} +} +static void luaK_dischargevars(FuncState*fs,expdesc*e){ +switch(e->k){ +case VLOCAL:{ +e->k=VNONRELOC; +break; +} +case VUPVAL:{ +e->u.s.info=luaK_codeABC(fs,OP_GETUPVAL,0,e->u.s.info,0); +e->k=VRELOCABLE; +break; +} +case VGLOBAL:{ +e->u.s.info=luaK_codeABx(fs,OP_GETGLOBAL,0,e->u.s.info); +e->k=VRELOCABLE; +break; +} +case VINDEXED:{ +freereg(fs,e->u.s.aux); +freereg(fs,e->u.s.info); +e->u.s.info=luaK_codeABC(fs,OP_GETTABLE,0,e->u.s.info,e->u.s.aux); +e->k=VRELOCABLE; +break; +} +case VVARARG: +case VCALL:{ +luaK_setoneret(fs,e); +break; +} +default:break; +} +} +static int code_label(FuncState*fs,int A,int b,int jump){ +luaK_getlabel(fs); +return luaK_codeABC(fs,OP_LOADBOOL,A,b,jump); +} +static void discharge2reg(FuncState*fs,expdesc*e,int reg){ +luaK_dischargevars(fs,e); +switch(e->k){ +case VNIL:{ +luaK_nil(fs,reg,1); +break; +} +case VFALSE:case VTRUE:{ +luaK_codeABC(fs,OP_LOADBOOL,reg,e->k==VTRUE,0); +break; +} +case VK:{ +luaK_codeABx(fs,OP_LOADK,reg,e->u.s.info); +break; +} +case VKNUM:{ +luaK_codeABx(fs,OP_LOADK,reg,luaK_numberK(fs,e->u.nval)); +break; +} +case VRELOCABLE:{ +Instruction*pc=&getcode(fs,e); +SETARG_A(*pc,reg); +break; +} +case VNONRELOC:{ +if(reg!=e->u.s.info) +luaK_codeABC(fs,OP_MOVE,reg,e->u.s.info,0); +break; +} +default:{ +return; +} +} +e->u.s.info=reg; +e->k=VNONRELOC; +} +static void discharge2anyreg(FuncState*fs,expdesc*e){ +if(e->k!=VNONRELOC){ +luaK_reserveregs(fs,1); +discharge2reg(fs,e,fs->freereg-1); +} +} +static void exp2reg(FuncState*fs,expdesc*e,int reg){ +discharge2reg(fs,e,reg); +if(e->k==VJMP) +luaK_concat(fs,&e->t,e->u.s.info); +if(hasjumps(e)){ +int final; +int p_f=(-1); +int p_t=(-1); +if(need_value(fs,e->t)||need_value(fs,e->f)){ +int fj=(e->k==VJMP)?(-1):luaK_jump(fs); +p_f=code_label(fs,reg,0,1); +p_t=code_label(fs,reg,1,0); +luaK_patchtohere(fs,fj); +} +final=luaK_getlabel(fs); +patchlistaux(fs,e->f,final,reg,p_f); +patchlistaux(fs,e->t,final,reg,p_t); +} +e->f=e->t=(-1); +e->u.s.info=reg; +e->k=VNONRELOC; +} +static void luaK_exp2nextreg(FuncState*fs,expdesc*e){ +luaK_dischargevars(fs,e); +freeexp(fs,e); +luaK_reserveregs(fs,1); +exp2reg(fs,e,fs->freereg-1); +} +static int luaK_exp2anyreg(FuncState*fs,expdesc*e){ +luaK_dischargevars(fs,e); +if(e->k==VNONRELOC){ +if(!hasjumps(e))return e->u.s.info; +if(e->u.s.info>=fs->nactvar){ +exp2reg(fs,e,e->u.s.info); +return e->u.s.info; +} +} +luaK_exp2nextreg(fs,e); +return e->u.s.info; +} +static void luaK_exp2val(FuncState*fs,expdesc*e){ +if(hasjumps(e)) +luaK_exp2anyreg(fs,e); +else +luaK_dischargevars(fs,e); +} +static int luaK_exp2RK(FuncState*fs,expdesc*e){ +luaK_exp2val(fs,e); +switch(e->k){ +case VKNUM: +case VTRUE: +case VFALSE: +case VNIL:{ +if(fs->nk<=((1<<(9-1))-1)){ +e->u.s.info=(e->k==VNIL)?nilK(fs): +(e->k==VKNUM)?luaK_numberK(fs,e->u.nval): +boolK(fs,(e->k==VTRUE)); +e->k=VK; +return RKASK(e->u.s.info); +} +else break; +} +case VK:{ +if(e->u.s.info<=((1<<(9-1))-1)) +return RKASK(e->u.s.info); +else break; +} +default:break; +} +return luaK_exp2anyreg(fs,e); +} +static void luaK_storevar(FuncState*fs,expdesc*var,expdesc*ex){ +switch(var->k){ +case VLOCAL:{ +freeexp(fs,ex); +exp2reg(fs,ex,var->u.s.info); +return; +} +case VUPVAL:{ +int e=luaK_exp2anyreg(fs,ex); +luaK_codeABC(fs,OP_SETUPVAL,e,var->u.s.info,0); +break; +} +case VGLOBAL:{ +int e=luaK_exp2anyreg(fs,ex); +luaK_codeABx(fs,OP_SETGLOBAL,e,var->u.s.info); +break; +} +case VINDEXED:{ +int e=luaK_exp2RK(fs,ex); +luaK_codeABC(fs,OP_SETTABLE,var->u.s.info,var->u.s.aux,e); +break; +} +default:{ +break; +} +} +freeexp(fs,ex); +} +static void luaK_self(FuncState*fs,expdesc*e,expdesc*key){ +int func; +luaK_exp2anyreg(fs,e); +freeexp(fs,e); +func=fs->freereg; +luaK_reserveregs(fs,2); +luaK_codeABC(fs,OP_SELF,func,e->u.s.info,luaK_exp2RK(fs,key)); +freeexp(fs,key); +e->u.s.info=func; +e->k=VNONRELOC; +} +static void invertjump(FuncState*fs,expdesc*e){ +Instruction*pc=getjumpcontrol(fs,e->u.s.info); +SETARG_A(*pc,!(GETARG_A(*pc))); +} +static int jumponcond(FuncState*fs,expdesc*e,int cond){ +if(e->k==VRELOCABLE){ +Instruction ie=getcode(fs,e); +if(GET_OPCODE(ie)==OP_NOT){ +fs->pc--; +return condjump(fs,OP_TEST,GETARG_B(ie),0,!cond); +} +} +discharge2anyreg(fs,e); +freeexp(fs,e); +return condjump(fs,OP_TESTSET,((1<<8)-1),e->u.s.info,cond); +} +static void luaK_goiftrue(FuncState*fs,expdesc*e){ +int pc; +luaK_dischargevars(fs,e); +switch(e->k){ +case VK:case VKNUM:case VTRUE:{ +pc=(-1); +break; +} +case VJMP:{ +invertjump(fs,e); +pc=e->u.s.info; +break; +} +default:{ +pc=jumponcond(fs,e,0); +break; +} +} +luaK_concat(fs,&e->f,pc); +luaK_patchtohere(fs,e->t); +e->t=(-1); +} +static void luaK_goiffalse(FuncState*fs,expdesc*e){ +int pc; +luaK_dischargevars(fs,e); +switch(e->k){ +case VNIL:case VFALSE:{ +pc=(-1); +break; +} +case VJMP:{ +pc=e->u.s.info; +break; +} +default:{ +pc=jumponcond(fs,e,1); +break; +} +} +luaK_concat(fs,&e->t,pc); +luaK_patchtohere(fs,e->f); +e->f=(-1); +} +static void codenot(FuncState*fs,expdesc*e){ +luaK_dischargevars(fs,e); +switch(e->k){ +case VNIL:case VFALSE:{ +e->k=VTRUE; +break; +} +case VK:case VKNUM:case VTRUE:{ +e->k=VFALSE; +break; +} +case VJMP:{ +invertjump(fs,e); +break; +} +case VRELOCABLE: +case VNONRELOC:{ +discharge2anyreg(fs,e); +freeexp(fs,e); +e->u.s.info=luaK_codeABC(fs,OP_NOT,0,e->u.s.info,0); +e->k=VRELOCABLE; +break; +} +default:{ +break; +} +} +{int temp=e->f;e->f=e->t;e->t=temp;} +removevalues(fs,e->f); +removevalues(fs,e->t); +} +static void luaK_indexed(FuncState*fs,expdesc*t,expdesc*k){ +t->u.s.aux=luaK_exp2RK(fs,k); +t->k=VINDEXED; +} +static int constfolding(OpCode op,expdesc*e1,expdesc*e2){ +lua_Number v1,v2,r; +if(!isnumeral(e1)||!isnumeral(e2))return 0; +v1=e1->u.nval; +v2=e2->u.nval; +switch(op){ +case OP_ADD:r=luai_numadd(v1,v2);break; +case OP_SUB:r=luai_numsub(v1,v2);break; +case OP_MUL:r=luai_nummul(v1,v2);break; +case OP_DIV: +if(v2==0)return 0; +r=luai_numdiv(v1,v2);break; +case OP_MOD: +if(v2==0)return 0; +r=luai_nummod(v1,v2);break; +case OP_POW:r=luai_numpow(v1,v2);break; +case OP_UNM:r=luai_numunm(v1);break; +case OP_LEN:return 0; +default:r=0;break; +} +if(luai_numisnan(r))return 0; +e1->u.nval=r; +return 1; +} +static void codearith(FuncState*fs,OpCode op,expdesc*e1,expdesc*e2){ +if(constfolding(op,e1,e2)) +return; +else{ +int o2=(op!=OP_UNM&&op!=OP_LEN)?luaK_exp2RK(fs,e2):0; +int o1=luaK_exp2RK(fs,e1); +if(o1>o2){ +freeexp(fs,e1); +freeexp(fs,e2); +} +else{ +freeexp(fs,e2); +freeexp(fs,e1); +} +e1->u.s.info=luaK_codeABC(fs,op,0,o1,o2); +e1->k=VRELOCABLE; +} +} +static void codecomp(FuncState*fs,OpCode op,int cond,expdesc*e1, +expdesc*e2){ +int o1=luaK_exp2RK(fs,e1); +int o2=luaK_exp2RK(fs,e2); +freeexp(fs,e2); +freeexp(fs,e1); +if(cond==0&&op!=OP_EQ){ +int temp; +temp=o1;o1=o2;o2=temp; +cond=1; +} +e1->u.s.info=condjump(fs,op,cond,o1,o2); +e1->k=VJMP; +} +static void luaK_prefix(FuncState*fs,UnOpr op,expdesc*e){ +expdesc e2; +e2.t=e2.f=(-1);e2.k=VKNUM;e2.u.nval=0; +switch(op){ +case OPR_MINUS:{ +if(!isnumeral(e)) +luaK_exp2anyreg(fs,e); +codearith(fs,OP_UNM,e,&e2); +break; +} +case OPR_NOT:codenot(fs,e);break; +case OPR_LEN:{ +luaK_exp2anyreg(fs,e); +codearith(fs,OP_LEN,e,&e2); +break; +} +default:; +} +} +static void luaK_infix(FuncState*fs,BinOpr op,expdesc*v){ +switch(op){ +case OPR_AND:{ +luaK_goiftrue(fs,v); +break; +} +case OPR_OR:{ +luaK_goiffalse(fs,v); +break; +} +case OPR_CONCAT:{ +luaK_exp2nextreg(fs,v); +break; +} +case OPR_ADD:case OPR_SUB:case OPR_MUL:case OPR_DIV: +case OPR_MOD:case OPR_POW:{ +if(!isnumeral(v))luaK_exp2RK(fs,v); +break; +} +default:{ +luaK_exp2RK(fs,v); +break; +} +} +} +static void luaK_posfix(FuncState*fs,BinOpr op,expdesc*e1,expdesc*e2){ +switch(op){ +case OPR_AND:{ +luaK_dischargevars(fs,e2); +luaK_concat(fs,&e2->f,e1->f); +*e1=*e2; +break; +} +case OPR_OR:{ +luaK_dischargevars(fs,e2); +luaK_concat(fs,&e2->t,e1->t); +*e1=*e2; +break; +} +case OPR_CONCAT:{ +luaK_exp2val(fs,e2); +if(e2->k==VRELOCABLE&&GET_OPCODE(getcode(fs,e2))==OP_CONCAT){ +freeexp(fs,e1); +SETARG_B(getcode(fs,e2),e1->u.s.info); +e1->k=VRELOCABLE;e1->u.s.info=e2->u.s.info; +} +else{ +luaK_exp2nextreg(fs,e2); +codearith(fs,OP_CONCAT,e1,e2); +} +break; +} +case OPR_ADD:codearith(fs,OP_ADD,e1,e2);break; +case OPR_SUB:codearith(fs,OP_SUB,e1,e2);break; +case OPR_MUL:codearith(fs,OP_MUL,e1,e2);break; +case OPR_DIV:codearith(fs,OP_DIV,e1,e2);break; +case OPR_MOD:codearith(fs,OP_MOD,e1,e2);break; +case OPR_POW:codearith(fs,OP_POW,e1,e2);break; +case OPR_EQ:codecomp(fs,OP_EQ,1,e1,e2);break; +case OPR_NE:codecomp(fs,OP_EQ,0,e1,e2);break; +case OPR_LT:codecomp(fs,OP_LT,1,e1,e2);break; +case OPR_LE:codecomp(fs,OP_LE,1,e1,e2);break; +case OPR_GT:codecomp(fs,OP_LT,0,e1,e2);break; +case OPR_GE:codecomp(fs,OP_LE,0,e1,e2);break; +default:; +} +} +static void luaK_fixline(FuncState*fs,int line){ +fs->f->lineinfo[fs->pc-1]=line; +} +static int luaK_code(FuncState*fs,Instruction i,int line){ +Proto*f=fs->f; +dischargejpc(fs); +luaM_growvector(fs->L,f->code,fs->pc,f->sizecode,Instruction, +(INT_MAX-2),"code size overflow"); +f->code[fs->pc]=i; +luaM_growvector(fs->L,f->lineinfo,fs->pc,f->sizelineinfo,int, +(INT_MAX-2),"code size overflow"); +f->lineinfo[fs->pc]=line; +return fs->pc++; +} +static int luaK_codeABC(FuncState*fs,OpCode o,int a,int b,int c){ +return luaK_code(fs,CREATE_ABC(o,a,b,c),fs->ls->lastline); +} +static int luaK_codeABx(FuncState*fs,OpCode o,int a,unsigned int bc){ +return luaK_code(fs,CREATE_ABx(o,a,bc),fs->ls->lastline); +} +static void luaK_setlist(FuncState*fs,int base,int nelems,int tostore){ +int c=(nelems-1)/50+1; +int b=(tostore==(-1))?0:tostore; +if(c<=((1<<9)-1)) +luaK_codeABC(fs,OP_SETLIST,base,b,c); +else{ +luaK_codeABC(fs,OP_SETLIST,base,b,0); +luaK_code(fs,cast(Instruction,c),fs->ls->lastline); +} +fs->freereg=base+1; +} +#define hasmultret(k)((k)==VCALL||(k)==VVARARG) +#define getlocvar(fs,i)((fs)->f->locvars[(fs)->actvar[i]]) +#define luaY_checklimit(fs,v,l,m)if((v)>(l))errorlimit(fs,l,m) +typedef struct BlockCnt{ +struct BlockCnt*previous; +int breaklist; +lu_byte nactvar; +lu_byte upval; +lu_byte isbreakable; +}BlockCnt; +static void chunk(LexState*ls); +static void expr(LexState*ls,expdesc*v); +static void anchor_token(LexState*ls){ +if(ls->t.token==TK_NAME||ls->t.token==TK_STRING){ +TString*ts=ls->t.seminfo.ts; +luaX_newstring(ls,getstr(ts),ts->tsv.len); +} +} +static void error_expected(LexState*ls,int token){ +luaX_syntaxerror(ls, +luaO_pushfstring(ls->L,LUA_QL("%s")" expected",luaX_token2str(ls,token))); +} +static void errorlimit(FuncState*fs,int limit,const char*what){ +const char*msg=(fs->f->linedefined==0)? +luaO_pushfstring(fs->L,"main function has more than %d %s",limit,what): +luaO_pushfstring(fs->L,"function at line %d has more than %d %s", +fs->f->linedefined,limit,what); +luaX_lexerror(fs->ls,msg,0); +} +static int testnext(LexState*ls,int c){ +if(ls->t.token==c){ +luaX_next(ls); +return 1; +} +else return 0; +} +static void check(LexState*ls,int c){ +if(ls->t.token!=c) +error_expected(ls,c); +} +static void checknext(LexState*ls,int c){ +check(ls,c); +luaX_next(ls); +} +#define check_condition(ls,c,msg){if(!(c))luaX_syntaxerror(ls,msg);} +static void check_match(LexState*ls,int what,int who,int where){ +if(!testnext(ls,what)){ +if(where==ls->linenumber) +error_expected(ls,what); +else{ +luaX_syntaxerror(ls,luaO_pushfstring(ls->L, +LUA_QL("%s")" expected (to close "LUA_QL("%s")" at line %d)", +luaX_token2str(ls,what),luaX_token2str(ls,who),where)); +} +} +} +static TString*str_checkname(LexState*ls){ +TString*ts; +check(ls,TK_NAME); +ts=ls->t.seminfo.ts; +luaX_next(ls); +return ts; +} +static void init_exp(expdesc*e,expkind k,int i){ +e->f=e->t=(-1); +e->k=k; +e->u.s.info=i; +} +static void codestring(LexState*ls,expdesc*e,TString*s){ +init_exp(e,VK,luaK_stringK(ls->fs,s)); +} +static void checkname(LexState*ls,expdesc*e){ +codestring(ls,e,str_checkname(ls)); +} +static int registerlocalvar(LexState*ls,TString*varname){ +FuncState*fs=ls->fs; +Proto*f=fs->f; +int oldsize=f->sizelocvars; +luaM_growvector(ls->L,f->locvars,fs->nlocvars,f->sizelocvars, +LocVar,SHRT_MAX,"too many local variables"); +while(oldsizesizelocvars)f->locvars[oldsize++].varname=NULL; +f->locvars[fs->nlocvars].varname=varname; +luaC_objbarrier(ls->L,f,varname); +return fs->nlocvars++; +} +#define new_localvarliteral(ls,v,n)new_localvar(ls,luaX_newstring(ls,""v,(sizeof(v)/sizeof(char))-1),n) +static void new_localvar(LexState*ls,TString*name,int n){ +FuncState*fs=ls->fs; +luaY_checklimit(fs,fs->nactvar+n+1,200,"local variables"); +fs->actvar[fs->nactvar+n]=cast(unsigned short,registerlocalvar(ls,name)); +} +static void adjustlocalvars(LexState*ls,int nvars){ +FuncState*fs=ls->fs; +fs->nactvar=cast_byte(fs->nactvar+nvars); +for(;nvars;nvars--){ +getlocvar(fs,fs->nactvar-nvars).startpc=fs->pc; +} +} +static void removevars(LexState*ls,int tolevel){ +FuncState*fs=ls->fs; +while(fs->nactvar>tolevel) +getlocvar(fs,--fs->nactvar).endpc=fs->pc; +} +static int indexupvalue(FuncState*fs,TString*name,expdesc*v){ +int i; +Proto*f=fs->f; +int oldsize=f->sizeupvalues; +for(i=0;inups;i++){ +if(fs->upvalues[i].k==v->k&&fs->upvalues[i].info==v->u.s.info){ +return i; +} +} +luaY_checklimit(fs,f->nups+1,60,"upvalues"); +luaM_growvector(fs->L,f->upvalues,f->nups,f->sizeupvalues, +TString*,(INT_MAX-2),""); +while(oldsizesizeupvalues)f->upvalues[oldsize++]=NULL; +f->upvalues[f->nups]=name; +luaC_objbarrier(fs->L,f,name); +fs->upvalues[f->nups].k=cast_byte(v->k); +fs->upvalues[f->nups].info=cast_byte(v->u.s.info); +return f->nups++; +} +static int searchvar(FuncState*fs,TString*n){ +int i; +for(i=fs->nactvar-1;i>=0;i--){ +if(n==getlocvar(fs,i).varname) +return i; +} +return-1; +} +static void markupval(FuncState*fs,int level){ +BlockCnt*bl=fs->bl; +while(bl&&bl->nactvar>level)bl=bl->previous; +if(bl)bl->upval=1; +} +static int singlevaraux(FuncState*fs,TString*n,expdesc*var,int base){ +if(fs==NULL){ +init_exp(var,VGLOBAL,((1<<8)-1)); +return VGLOBAL; +} +else{ +int v=searchvar(fs,n); +if(v>=0){ +init_exp(var,VLOCAL,v); +if(!base) +markupval(fs,v); +return VLOCAL; +} +else{ +if(singlevaraux(fs->prev,n,var,0)==VGLOBAL) +return VGLOBAL; +var->u.s.info=indexupvalue(fs,n,var); +var->k=VUPVAL; +return VUPVAL; +} +} +} +static void singlevar(LexState*ls,expdesc*var){ +TString*varname=str_checkname(ls); +FuncState*fs=ls->fs; +if(singlevaraux(fs,varname,var,1)==VGLOBAL) +var->u.s.info=luaK_stringK(fs,varname); +} +static void adjust_assign(LexState*ls,int nvars,int nexps,expdesc*e){ +FuncState*fs=ls->fs; +int extra=nvars-nexps; +if(hasmultret(e->k)){ +extra++; +if(extra<0)extra=0; +luaK_setreturns(fs,e,extra); +if(extra>1)luaK_reserveregs(fs,extra-1); +} +else{ +if(e->k!=VVOID)luaK_exp2nextreg(fs,e); +if(extra>0){ +int reg=fs->freereg; +luaK_reserveregs(fs,extra); +luaK_nil(fs,reg,extra); +} +} +} +static void enterlevel(LexState*ls){ +if(++ls->L->nCcalls>200) +luaX_lexerror(ls,"chunk has too many syntax levels",0); +} +#define leavelevel(ls)((ls)->L->nCcalls--) +static void enterblock(FuncState*fs,BlockCnt*bl,lu_byte isbreakable){ +bl->breaklist=(-1); +bl->isbreakable=isbreakable; +bl->nactvar=fs->nactvar; +bl->upval=0; +bl->previous=fs->bl; +fs->bl=bl; +} +static void leaveblock(FuncState*fs){ +BlockCnt*bl=fs->bl; +fs->bl=bl->previous; +removevars(fs->ls,bl->nactvar); +if(bl->upval) +luaK_codeABC(fs,OP_CLOSE,bl->nactvar,0,0); +fs->freereg=fs->nactvar; +luaK_patchtohere(fs,bl->breaklist); +} +static void pushclosure(LexState*ls,FuncState*func,expdesc*v){ +FuncState*fs=ls->fs; +Proto*f=fs->f; +int oldsize=f->sizep; +int i; +luaM_growvector(ls->L,f->p,fs->np,f->sizep,Proto*, +((1<<(9+9))-1),"constant table overflow"); +while(oldsizesizep)f->p[oldsize++]=NULL; +f->p[fs->np++]=func->f; +luaC_objbarrier(ls->L,f,func->f); +init_exp(v,VRELOCABLE,luaK_codeABx(fs,OP_CLOSURE,0,fs->np-1)); +for(i=0;if->nups;i++){ +OpCode o=(func->upvalues[i].k==VLOCAL)?OP_MOVE:OP_GETUPVAL; +luaK_codeABC(fs,o,0,func->upvalues[i].info,0); +} +} +static void open_func(LexState*ls,FuncState*fs){ +lua_State*L=ls->L; +Proto*f=luaF_newproto(L); +fs->f=f; +fs->prev=ls->fs; +fs->ls=ls; +fs->L=L; +ls->fs=fs; +fs->pc=0; +fs->lasttarget=-1; +fs->jpc=(-1); +fs->freereg=0; +fs->nk=0; +fs->np=0; +fs->nlocvars=0; +fs->nactvar=0; +fs->bl=NULL; +f->source=ls->source; +f->maxstacksize=2; +fs->h=luaH_new(L,0,0); +sethvalue(L,L->top,fs->h); +incr_top(L); +setptvalue(L,L->top,f); +incr_top(L); +} +static void close_func(LexState*ls){ +lua_State*L=ls->L; +FuncState*fs=ls->fs; +Proto*f=fs->f; +removevars(ls,0); +luaK_ret(fs,0,0); +luaM_reallocvector(L,f->code,f->sizecode,fs->pc,Instruction); +f->sizecode=fs->pc; +luaM_reallocvector(L,f->lineinfo,f->sizelineinfo,fs->pc,int); +f->sizelineinfo=fs->pc; +luaM_reallocvector(L,f->k,f->sizek,fs->nk,TValue); +f->sizek=fs->nk; +luaM_reallocvector(L,f->p,f->sizep,fs->np,Proto*); +f->sizep=fs->np; +luaM_reallocvector(L,f->locvars,f->sizelocvars,fs->nlocvars,LocVar); +f->sizelocvars=fs->nlocvars; +luaM_reallocvector(L,f->upvalues,f->sizeupvalues,f->nups,TString*); +f->sizeupvalues=f->nups; +ls->fs=fs->prev; +if(fs)anchor_token(ls); +L->top-=2; +} +static Proto*luaY_parser(lua_State*L,ZIO*z,Mbuffer*buff,const char*name){ +struct LexState lexstate; +struct FuncState funcstate; +lexstate.buff=buff; +luaX_setinput(L,&lexstate,z,luaS_new(L,name)); +open_func(&lexstate,&funcstate); +funcstate.f->is_vararg=2; +luaX_next(&lexstate); +chunk(&lexstate); +check(&lexstate,TK_EOS); +close_func(&lexstate); +return funcstate.f; +} +static void field(LexState*ls,expdesc*v){ +FuncState*fs=ls->fs; +expdesc key; +luaK_exp2anyreg(fs,v); +luaX_next(ls); +checkname(ls,&key); +luaK_indexed(fs,v,&key); +} +static void yindex(LexState*ls,expdesc*v){ +luaX_next(ls); +expr(ls,v); +luaK_exp2val(ls->fs,v); +checknext(ls,']'); +} +struct ConsControl{ +expdesc v; +expdesc*t; +int nh; +int na; +int tostore; +}; +static void recfield(LexState*ls,struct ConsControl*cc){ +FuncState*fs=ls->fs; +int reg=ls->fs->freereg; +expdesc key,val; +int rkkey; +if(ls->t.token==TK_NAME){ +luaY_checklimit(fs,cc->nh,(INT_MAX-2),"items in a constructor"); +checkname(ls,&key); +} +else +yindex(ls,&key); +cc->nh++; +checknext(ls,'='); +rkkey=luaK_exp2RK(fs,&key); +expr(ls,&val); +luaK_codeABC(fs,OP_SETTABLE,cc->t->u.s.info,rkkey,luaK_exp2RK(fs,&val)); +fs->freereg=reg; +} +static void closelistfield(FuncState*fs,struct ConsControl*cc){ +if(cc->v.k==VVOID)return; +luaK_exp2nextreg(fs,&cc->v); +cc->v.k=VVOID; +if(cc->tostore==50){ +luaK_setlist(fs,cc->t->u.s.info,cc->na,cc->tostore); +cc->tostore=0; +} +} +static void lastlistfield(FuncState*fs,struct ConsControl*cc){ +if(cc->tostore==0)return; +if(hasmultret(cc->v.k)){ +luaK_setmultret(fs,&cc->v); +luaK_setlist(fs,cc->t->u.s.info,cc->na,(-1)); +cc->na--; +} +else{ +if(cc->v.k!=VVOID) +luaK_exp2nextreg(fs,&cc->v); +luaK_setlist(fs,cc->t->u.s.info,cc->na,cc->tostore); +} +} +static void listfield(LexState*ls,struct ConsControl*cc){ +expr(ls,&cc->v); +luaY_checklimit(ls->fs,cc->na,(INT_MAX-2),"items in a constructor"); +cc->na++; +cc->tostore++; +} +static void constructor(LexState*ls,expdesc*t){ +FuncState*fs=ls->fs; +int line=ls->linenumber; +int pc=luaK_codeABC(fs,OP_NEWTABLE,0,0,0); +struct ConsControl cc; +cc.na=cc.nh=cc.tostore=0; +cc.t=t; +init_exp(t,VRELOCABLE,pc); +init_exp(&cc.v,VVOID,0); +luaK_exp2nextreg(ls->fs,t); +checknext(ls,'{'); +do{ +if(ls->t.token=='}')break; +closelistfield(fs,&cc); +switch(ls->t.token){ +case TK_NAME:{ +luaX_lookahead(ls); +if(ls->lookahead.token!='=') +listfield(ls,&cc); +else +recfield(ls,&cc); +break; +} +case'[':{ +recfield(ls,&cc); +break; +} +default:{ +listfield(ls,&cc); +break; +} +} +}while(testnext(ls,',')||testnext(ls,';')); +check_match(ls,'}','{',line); +lastlistfield(fs,&cc); +SETARG_B(fs->f->code[pc],luaO_int2fb(cc.na)); +SETARG_C(fs->f->code[pc],luaO_int2fb(cc.nh)); +} +static void parlist(LexState*ls){ +FuncState*fs=ls->fs; +Proto*f=fs->f; +int nparams=0; +f->is_vararg=0; +if(ls->t.token!=')'){ +do{ +switch(ls->t.token){ +case TK_NAME:{ +new_localvar(ls,str_checkname(ls),nparams++); +break; +} +case TK_DOTS:{ +luaX_next(ls); +f->is_vararg|=2; +break; +} +default:luaX_syntaxerror(ls," or "LUA_QL("...")" expected"); +} +}while(!f->is_vararg&&testnext(ls,',')); +} +adjustlocalvars(ls,nparams); +f->numparams=cast_byte(fs->nactvar-(f->is_vararg&1)); +luaK_reserveregs(fs,fs->nactvar); +} +static void body(LexState*ls,expdesc*e,int needself,int line){ +FuncState new_fs; +open_func(ls,&new_fs); +new_fs.f->linedefined=line; +checknext(ls,'('); +if(needself){ +new_localvarliteral(ls,"self",0); +adjustlocalvars(ls,1); +} +parlist(ls); +checknext(ls,')'); +chunk(ls); +new_fs.f->lastlinedefined=ls->linenumber; +check_match(ls,TK_END,TK_FUNCTION,line); +close_func(ls); +pushclosure(ls,&new_fs,e); +} +static int explist1(LexState*ls,expdesc*v){ +int n=1; +expr(ls,v); +while(testnext(ls,',')){ +luaK_exp2nextreg(ls->fs,v); +expr(ls,v); +n++; +} +return n; +} +static void funcargs(LexState*ls,expdesc*f){ +FuncState*fs=ls->fs; +expdesc args; +int base,nparams; +int line=ls->linenumber; +switch(ls->t.token){ +case'(':{ +if(line!=ls->lastline) +luaX_syntaxerror(ls,"ambiguous syntax (function call x new statement)"); +luaX_next(ls); +if(ls->t.token==')') +args.k=VVOID; +else{ +explist1(ls,&args); +luaK_setmultret(fs,&args); +} +check_match(ls,')','(',line); +break; +} +case'{':{ +constructor(ls,&args); +break; +} +case TK_STRING:{ +codestring(ls,&args,ls->t.seminfo.ts); +luaX_next(ls); +break; +} +default:{ +luaX_syntaxerror(ls,"function arguments expected"); +return; +} +} +base=f->u.s.info; +if(hasmultret(args.k)) +nparams=(-1); +else{ +if(args.k!=VVOID) +luaK_exp2nextreg(fs,&args); +nparams=fs->freereg-(base+1); +} +init_exp(f,VCALL,luaK_codeABC(fs,OP_CALL,base,nparams+1,2)); +luaK_fixline(fs,line); +fs->freereg=base+1; +} +static void prefixexp(LexState*ls,expdesc*v){ +switch(ls->t.token){ +case'(':{ +int line=ls->linenumber; +luaX_next(ls); +expr(ls,v); +check_match(ls,')','(',line); +luaK_dischargevars(ls->fs,v); +return; +} +case TK_NAME:{ +singlevar(ls,v); +return; +} +default:{ +luaX_syntaxerror(ls,"unexpected symbol"); +return; +} +} +} +static void primaryexp(LexState*ls,expdesc*v){ +FuncState*fs=ls->fs; +prefixexp(ls,v); +for(;;){ +switch(ls->t.token){ +case'.':{ +field(ls,v); +break; +} +case'[':{ +expdesc key; +luaK_exp2anyreg(fs,v); +yindex(ls,&key); +luaK_indexed(fs,v,&key); +break; +} +case':':{ +expdesc key; +luaX_next(ls); +checkname(ls,&key); +luaK_self(fs,v,&key); +funcargs(ls,v); +break; +} +case'(':case TK_STRING:case'{':{ +luaK_exp2nextreg(fs,v); +funcargs(ls,v); +break; +} +default:return; +} +} +} +static void simpleexp(LexState*ls,expdesc*v){ +switch(ls->t.token){ +case TK_NUMBER:{ +init_exp(v,VKNUM,0); +v->u.nval=ls->t.seminfo.r; +break; +} +case TK_STRING:{ +codestring(ls,v,ls->t.seminfo.ts); +break; +} +case TK_NIL:{ +init_exp(v,VNIL,0); +break; +} +case TK_TRUE:{ +init_exp(v,VTRUE,0); +break; +} +case TK_FALSE:{ +init_exp(v,VFALSE,0); +break; +} +case TK_DOTS:{ +FuncState*fs=ls->fs; +check_condition(ls,fs->f->is_vararg, +"cannot use "LUA_QL("...")" outside a vararg function"); +fs->f->is_vararg&=~4; +init_exp(v,VVARARG,luaK_codeABC(fs,OP_VARARG,0,1,0)); +break; +} +case'{':{ +constructor(ls,v); +return; +} +case TK_FUNCTION:{ +luaX_next(ls); +body(ls,v,0,ls->linenumber); +return; +} +default:{ +primaryexp(ls,v); +return; +} +} +luaX_next(ls); +} +static UnOpr getunopr(int op){ +switch(op){ +case TK_NOT:return OPR_NOT; +case'-':return OPR_MINUS; +case'#':return OPR_LEN; +default:return OPR_NOUNOPR; +} +} +static BinOpr getbinopr(int op){ +switch(op){ +case'+':return OPR_ADD; +case'-':return OPR_SUB; +case'*':return OPR_MUL; +case'/':return OPR_DIV; +case'%':return OPR_MOD; +case'^':return OPR_POW; +case TK_CONCAT:return OPR_CONCAT; +case TK_NE:return OPR_NE; +case TK_EQ:return OPR_EQ; +case'<':return OPR_LT; +case TK_LE:return OPR_LE; +case'>':return OPR_GT; +case TK_GE:return OPR_GE; +case TK_AND:return OPR_AND; +case TK_OR:return OPR_OR; +default:return OPR_NOBINOPR; +} +} +static const struct{ +lu_byte left; +lu_byte right; +}priority[]={ +{6,6},{6,6},{7,7},{7,7},{7,7}, +{10,9},{5,4}, +{3,3},{3,3}, +{3,3},{3,3},{3,3},{3,3}, +{2,2},{1,1} +}; +static BinOpr subexpr(LexState*ls,expdesc*v,unsigned int limit){ +BinOpr op; +UnOpr uop; +enterlevel(ls); +uop=getunopr(ls->t.token); +if(uop!=OPR_NOUNOPR){ +luaX_next(ls); +subexpr(ls,v,8); +luaK_prefix(ls->fs,uop,v); +} +else simpleexp(ls,v); +op=getbinopr(ls->t.token); +while(op!=OPR_NOBINOPR&&priority[op].left>limit){ +expdesc v2; +BinOpr nextop; +luaX_next(ls); +luaK_infix(ls->fs,op,v); +nextop=subexpr(ls,&v2,priority[op].right); +luaK_posfix(ls->fs,op,v,&v2); +op=nextop; +} +leavelevel(ls); +return op; +} +static void expr(LexState*ls,expdesc*v){ +subexpr(ls,v,0); +} +static int block_follow(int token){ +switch(token){ +case TK_ELSE:case TK_ELSEIF:case TK_END: +case TK_UNTIL:case TK_EOS: +return 1; +default:return 0; +} +} +static void block(LexState*ls){ +FuncState*fs=ls->fs; +BlockCnt bl; +enterblock(fs,&bl,0); +chunk(ls); +leaveblock(fs); +} +struct LHS_assign{ +struct LHS_assign*prev; +expdesc v; +}; +static void check_conflict(LexState*ls,struct LHS_assign*lh,expdesc*v){ +FuncState*fs=ls->fs; +int extra=fs->freereg; +int conflict=0; +for(;lh;lh=lh->prev){ +if(lh->v.k==VINDEXED){ +if(lh->v.u.s.info==v->u.s.info){ +conflict=1; +lh->v.u.s.info=extra; +} +if(lh->v.u.s.aux==v->u.s.info){ +conflict=1; +lh->v.u.s.aux=extra; +} +} +} +if(conflict){ +luaK_codeABC(fs,OP_MOVE,fs->freereg,v->u.s.info,0); +luaK_reserveregs(fs,1); +} +} +static void assignment(LexState*ls,struct LHS_assign*lh,int nvars){ +expdesc e; +check_condition(ls,VLOCAL<=lh->v.k&&lh->v.k<=VINDEXED, +"syntax error"); +if(testnext(ls,',')){ +struct LHS_assign nv; +nv.prev=lh; +primaryexp(ls,&nv.v); +if(nv.v.k==VLOCAL) +check_conflict(ls,lh,&nv.v); +luaY_checklimit(ls->fs,nvars,200-ls->L->nCcalls, +"variables in assignment"); +assignment(ls,&nv,nvars+1); +} +else{ +int nexps; +checknext(ls,'='); +nexps=explist1(ls,&e); +if(nexps!=nvars){ +adjust_assign(ls,nvars,nexps,&e); +if(nexps>nvars) +ls->fs->freereg-=nexps-nvars; +} +else{ +luaK_setoneret(ls->fs,&e); +luaK_storevar(ls->fs,&lh->v,&e); +return; +} +} +init_exp(&e,VNONRELOC,ls->fs->freereg-1); +luaK_storevar(ls->fs,&lh->v,&e); +} +static int cond(LexState*ls){ +expdesc v; +expr(ls,&v); +if(v.k==VNIL)v.k=VFALSE; +luaK_goiftrue(ls->fs,&v); +return v.f; +} +static void breakstat(LexState*ls){ +FuncState*fs=ls->fs; +BlockCnt*bl=fs->bl; +int upval=0; +while(bl&&!bl->isbreakable){ +upval|=bl->upval; +bl=bl->previous; +} +if(!bl) +luaX_syntaxerror(ls,"no loop to break"); +if(upval) +luaK_codeABC(fs,OP_CLOSE,bl->nactvar,0,0); +luaK_concat(fs,&bl->breaklist,luaK_jump(fs)); +} +static void whilestat(LexState*ls,int line){ +FuncState*fs=ls->fs; +int whileinit; +int condexit; +BlockCnt bl; +luaX_next(ls); +whileinit=luaK_getlabel(fs); +condexit=cond(ls); +enterblock(fs,&bl,1); +checknext(ls,TK_DO); +block(ls); +luaK_patchlist(fs,luaK_jump(fs),whileinit); +check_match(ls,TK_END,TK_WHILE,line); +leaveblock(fs); +luaK_patchtohere(fs,condexit); +} +static void repeatstat(LexState*ls,int line){ +int condexit; +FuncState*fs=ls->fs; +int repeat_init=luaK_getlabel(fs); +BlockCnt bl1,bl2; +enterblock(fs,&bl1,1); +enterblock(fs,&bl2,0); +luaX_next(ls); +chunk(ls); +check_match(ls,TK_UNTIL,TK_REPEAT,line); +condexit=cond(ls); +if(!bl2.upval){ +leaveblock(fs); +luaK_patchlist(ls->fs,condexit,repeat_init); +} +else{ +breakstat(ls); +luaK_patchtohere(ls->fs,condexit); +leaveblock(fs); +luaK_patchlist(ls->fs,luaK_jump(fs),repeat_init); +} +leaveblock(fs); +} +static int exp1(LexState*ls){ +expdesc e; +int k; +expr(ls,&e); +k=e.k; +luaK_exp2nextreg(ls->fs,&e); +return k; +} +static void forbody(LexState*ls,int base,int line,int nvars,int isnum){ +BlockCnt bl; +FuncState*fs=ls->fs; +int prep,endfor; +adjustlocalvars(ls,3); +checknext(ls,TK_DO); +prep=isnum?luaK_codeAsBx(fs,OP_FORPREP,base,(-1)):luaK_jump(fs); +enterblock(fs,&bl,0); +adjustlocalvars(ls,nvars); +luaK_reserveregs(fs,nvars); +block(ls); +leaveblock(fs); +luaK_patchtohere(fs,prep); +endfor=(isnum)?luaK_codeAsBx(fs,OP_FORLOOP,base,(-1)): +luaK_codeABC(fs,OP_TFORLOOP,base,0,nvars); +luaK_fixline(fs,line); +luaK_patchlist(fs,(isnum?endfor:luaK_jump(fs)),prep+1); +} +static void fornum(LexState*ls,TString*varname,int line){ +FuncState*fs=ls->fs; +int base=fs->freereg; +new_localvarliteral(ls,"(for index)",0); +new_localvarliteral(ls,"(for limit)",1); +new_localvarliteral(ls,"(for step)",2); +new_localvar(ls,varname,3); +checknext(ls,'='); +exp1(ls); +checknext(ls,','); +exp1(ls); +if(testnext(ls,',')) +exp1(ls); +else{ +luaK_codeABx(fs,OP_LOADK,fs->freereg,luaK_numberK(fs,1)); +luaK_reserveregs(fs,1); +} +forbody(ls,base,line,1,1); +} +static void forlist(LexState*ls,TString*indexname){ +FuncState*fs=ls->fs; +expdesc e; +int nvars=0; +int line; +int base=fs->freereg; +new_localvarliteral(ls,"(for generator)",nvars++); +new_localvarliteral(ls,"(for state)",nvars++); +new_localvarliteral(ls,"(for control)",nvars++); +new_localvar(ls,indexname,nvars++); +while(testnext(ls,',')) +new_localvar(ls,str_checkname(ls),nvars++); +checknext(ls,TK_IN); +line=ls->linenumber; +adjust_assign(ls,3,explist1(ls,&e),&e); +luaK_checkstack(fs,3); +forbody(ls,base,line,nvars-3,0); +} +static void forstat(LexState*ls,int line){ +FuncState*fs=ls->fs; +TString*varname; +BlockCnt bl; +enterblock(fs,&bl,1); +luaX_next(ls); +varname=str_checkname(ls); +switch(ls->t.token){ +case'=':fornum(ls,varname,line);break; +case',':case TK_IN:forlist(ls,varname);break; +default:luaX_syntaxerror(ls,LUA_QL("=")" or "LUA_QL("in")" expected"); +} +check_match(ls,TK_END,TK_FOR,line); +leaveblock(fs); +} +static int test_then_block(LexState*ls){ +int condexit; +luaX_next(ls); +condexit=cond(ls); +checknext(ls,TK_THEN); +block(ls); +return condexit; +} +static void ifstat(LexState*ls,int line){ +FuncState*fs=ls->fs; +int flist; +int escapelist=(-1); +flist=test_then_block(ls); +while(ls->t.token==TK_ELSEIF){ +luaK_concat(fs,&escapelist,luaK_jump(fs)); +luaK_patchtohere(fs,flist); +flist=test_then_block(ls); +} +if(ls->t.token==TK_ELSE){ +luaK_concat(fs,&escapelist,luaK_jump(fs)); +luaK_patchtohere(fs,flist); +luaX_next(ls); +block(ls); +} +else +luaK_concat(fs,&escapelist,flist); +luaK_patchtohere(fs,escapelist); +check_match(ls,TK_END,TK_IF,line); +} +static void localfunc(LexState*ls){ +expdesc v,b; +FuncState*fs=ls->fs; +new_localvar(ls,str_checkname(ls),0); +init_exp(&v,VLOCAL,fs->freereg); +luaK_reserveregs(fs,1); +adjustlocalvars(ls,1); +body(ls,&b,0,ls->linenumber); +luaK_storevar(fs,&v,&b); +getlocvar(fs,fs->nactvar-1).startpc=fs->pc; +} +static void localstat(LexState*ls){ +int nvars=0; +int nexps; +expdesc e; +do{ +new_localvar(ls,str_checkname(ls),nvars++); +}while(testnext(ls,',')); +if(testnext(ls,'=')) +nexps=explist1(ls,&e); +else{ +e.k=VVOID; +nexps=0; +} +adjust_assign(ls,nvars,nexps,&e); +adjustlocalvars(ls,nvars); +} +static int funcname(LexState*ls,expdesc*v){ +int needself=0; +singlevar(ls,v); +while(ls->t.token=='.') +field(ls,v); +if(ls->t.token==':'){ +needself=1; +field(ls,v); +} +return needself; +} +static void funcstat(LexState*ls,int line){ +int needself; +expdesc v,b; +luaX_next(ls); +needself=funcname(ls,&v); +body(ls,&b,needself,line); +luaK_storevar(ls->fs,&v,&b); +luaK_fixline(ls->fs,line); +} +static void exprstat(LexState*ls){ +FuncState*fs=ls->fs; +struct LHS_assign v; +primaryexp(ls,&v.v); +if(v.v.k==VCALL) +SETARG_C(getcode(fs,&v.v),1); +else{ +v.prev=NULL; +assignment(ls,&v,1); +} +} +static void retstat(LexState*ls){ +FuncState*fs=ls->fs; +expdesc e; +int first,nret; +luaX_next(ls); +if(block_follow(ls->t.token)||ls->t.token==';') +first=nret=0; +else{ +nret=explist1(ls,&e); +if(hasmultret(e.k)){ +luaK_setmultret(fs,&e); +if(e.k==VCALL&&nret==1){ +SET_OPCODE(getcode(fs,&e),OP_TAILCALL); +} +first=fs->nactvar; +nret=(-1); +} +else{ +if(nret==1) +first=luaK_exp2anyreg(fs,&e); +else{ +luaK_exp2nextreg(fs,&e); +first=fs->nactvar; +} +} +} +luaK_ret(fs,first,nret); +} +static int statement(LexState*ls){ +int line=ls->linenumber; +switch(ls->t.token){ +case TK_IF:{ +ifstat(ls,line); +return 0; +} +case TK_WHILE:{ +whilestat(ls,line); +return 0; +} +case TK_DO:{ +luaX_next(ls); +block(ls); +check_match(ls,TK_END,TK_DO,line); +return 0; +} +case TK_FOR:{ +forstat(ls,line); +return 0; +} +case TK_REPEAT:{ +repeatstat(ls,line); +return 0; +} +case TK_FUNCTION:{ +funcstat(ls,line); +return 0; +} +case TK_LOCAL:{ +luaX_next(ls); +if(testnext(ls,TK_FUNCTION)) +localfunc(ls); +else +localstat(ls); +return 0; +} +case TK_RETURN:{ +retstat(ls); +return 1; +} +case TK_BREAK:{ +luaX_next(ls); +breakstat(ls); +return 1; +} +default:{ +exprstat(ls); +return 0; +} +} +} +static void chunk(LexState*ls){ +int islast=0; +enterlevel(ls); +while(!islast&&!block_follow(ls->t.token)){ +islast=statement(ls); +testnext(ls,';'); +ls->fs->freereg=ls->fs->nactvar; +} +leavelevel(ls); +} +static const TValue*luaV_tonumber(const TValue*obj,TValue*n){ +lua_Number num; +if(ttisnumber(obj))return obj; +if(ttisstring(obj)&&luaO_str2d(svalue(obj),&num)){ +setnvalue(n,num); +return n; +} +else +return NULL; +} +static int luaV_tostring(lua_State*L,StkId obj){ +if(!ttisnumber(obj)) +return 0; +else{ +char s[32]; +lua_Number n=nvalue(obj); +lua_number2str(s,n); +setsvalue(L,obj,luaS_new(L,s)); +return 1; +} +} +static void callTMres(lua_State*L,StkId res,const TValue*f, +const TValue*p1,const TValue*p2){ +ptrdiff_t result=savestack(L,res); +setobj(L,L->top,f); +setobj(L,L->top+1,p1); +setobj(L,L->top+2,p2); +luaD_checkstack(L,3); +L->top+=3; +luaD_call(L,L->top-3,1); +res=restorestack(L,result); +L->top--; +setobj(L,res,L->top); +} +static void callTM(lua_State*L,const TValue*f,const TValue*p1, +const TValue*p2,const TValue*p3){ +setobj(L,L->top,f); +setobj(L,L->top+1,p1); +setobj(L,L->top+2,p2); +setobj(L,L->top+3,p3); +luaD_checkstack(L,4); +L->top+=4; +luaD_call(L,L->top-4,0); +} +static void luaV_gettable(lua_State*L,const TValue*t,TValue*key,StkId val){ +int loop; +for(loop=0;loop<100;loop++){ +const TValue*tm; +if(ttistable(t)){ +Table*h=hvalue(t); +const TValue*res=luaH_get(h,key); +if(!ttisnil(res)|| +(tm=fasttm(L,h->metatable,TM_INDEX))==NULL){ +setobj(L,val,res); +return; +} +} +else if(ttisnil(tm=luaT_gettmbyobj(L,t,TM_INDEX))) +luaG_typeerror(L,t,"index"); +if(ttisfunction(tm)){ +callTMres(L,val,tm,t,key); +return; +} +t=tm; +} +luaG_runerror(L,"loop in gettable"); +} +static void luaV_settable(lua_State*L,const TValue*t,TValue*key,StkId val){ +int loop; +TValue temp; +for(loop=0;loop<100;loop++){ +const TValue*tm; +if(ttistable(t)){ +Table*h=hvalue(t); +TValue*oldval=luaH_set(L,h,key); +if(!ttisnil(oldval)|| +(tm=fasttm(L,h->metatable,TM_NEWINDEX))==NULL){ +setobj(L,oldval,val); +h->flags=0; +luaC_barriert(L,h,val); +return; +} +} +else if(ttisnil(tm=luaT_gettmbyobj(L,t,TM_NEWINDEX))) +luaG_typeerror(L,t,"index"); +if(ttisfunction(tm)){ +callTM(L,tm,t,key,val); +return; +} +setobj(L,&temp,tm); +t=&temp; +} +luaG_runerror(L,"loop in settable"); +} +static int call_binTM(lua_State*L,const TValue*p1,const TValue*p2, +StkId res,TMS event){ +const TValue*tm=luaT_gettmbyobj(L,p1,event); +if(ttisnil(tm)) +tm=luaT_gettmbyobj(L,p2,event); +if(ttisnil(tm))return 0; +callTMres(L,res,tm,p1,p2); +return 1; +} +static const TValue*get_compTM(lua_State*L,Table*mt1,Table*mt2, +TMS event){ +const TValue*tm1=fasttm(L,mt1,event); +const TValue*tm2; +if(tm1==NULL)return NULL; +if(mt1==mt2)return tm1; +tm2=fasttm(L,mt2,event); +if(tm2==NULL)return NULL; +if(luaO_rawequalObj(tm1,tm2)) +return tm1; +return NULL; +} +static int call_orderTM(lua_State*L,const TValue*p1,const TValue*p2, +TMS event){ +const TValue*tm1=luaT_gettmbyobj(L,p1,event); +const TValue*tm2; +if(ttisnil(tm1))return-1; +tm2=luaT_gettmbyobj(L,p2,event); +if(!luaO_rawequalObj(tm1,tm2)) +return-1; +callTMres(L,L->top,tm1,p1,p2); +return!l_isfalse(L->top); +} +static int l_strcmp(const TString*ls,const TString*rs){ +const char*l=getstr(ls); +size_t ll=ls->tsv.len; +const char*r=getstr(rs); +size_t lr=rs->tsv.len; +for(;;){ +int temp=strcoll(l,r); +if(temp!=0)return temp; +else{ +size_t len=strlen(l); +if(len==lr) +return(len==ll)?0:1; +else if(len==ll) +return-1; +len++; +l+=len;ll-=len;r+=len;lr-=len; +} +} +} +static int luaV_lessthan(lua_State*L,const TValue*l,const TValue*r){ +int res; +if(ttype(l)!=ttype(r)) +return luaG_ordererror(L,l,r); +else if(ttisnumber(l)) +return luai_numlt(nvalue(l),nvalue(r)); +else if(ttisstring(l)) +return l_strcmp(rawtsvalue(l),rawtsvalue(r))<0; +else if((res=call_orderTM(L,l,r,TM_LT))!=-1) +return res; +return luaG_ordererror(L,l,r); +} +static int lessequal(lua_State*L,const TValue*l,const TValue*r){ +int res; +if(ttype(l)!=ttype(r)) +return luaG_ordererror(L,l,r); +else if(ttisnumber(l)) +return luai_numle(nvalue(l),nvalue(r)); +else if(ttisstring(l)) +return l_strcmp(rawtsvalue(l),rawtsvalue(r))<=0; +else if((res=call_orderTM(L,l,r,TM_LE))!=-1) +return res; +else if((res=call_orderTM(L,r,l,TM_LT))!=-1) +return!res; +return luaG_ordererror(L,l,r); +} +static int luaV_equalval(lua_State*L,const TValue*t1,const TValue*t2){ +const TValue*tm; +switch(ttype(t1)){ +case 0:return 1; +case 3:return luai_numeq(nvalue(t1),nvalue(t2)); +case 1:return bvalue(t1)==bvalue(t2); +case 2:return pvalue(t1)==pvalue(t2); +case 7:{ +if(uvalue(t1)==uvalue(t2))return 1; +tm=get_compTM(L,uvalue(t1)->metatable,uvalue(t2)->metatable, +TM_EQ); +break; +} +case 5:{ +if(hvalue(t1)==hvalue(t2))return 1; +tm=get_compTM(L,hvalue(t1)->metatable,hvalue(t2)->metatable,TM_EQ); +break; +} +default:return gcvalue(t1)==gcvalue(t2); +} +if(tm==NULL)return 0; +callTMres(L,L->top,tm,t1,t2); +return!l_isfalse(L->top); +} +static void luaV_concat(lua_State*L,int total,int last){ +do{ +StkId top=L->base+last+1; +int n=2; +if(!(ttisstring(top-2)||ttisnumber(top-2))||!tostring(L,top-1)){ +if(!call_binTM(L,top-2,top-1,top-2,TM_CONCAT)) +luaG_concaterror(L,top-2,top-1); +}else if(tsvalue(top-1)->len==0) +(void)tostring(L,top-2); +else{ +size_t tl=tsvalue(top-1)->len; +char*buffer; +int i; +for(n=1;nlen; +if(l>=((size_t)(~(size_t)0)-2)-tl)luaG_runerror(L,"string length overflow"); +tl+=l; +} +buffer=luaZ_openspace(L,&G(L)->buff,tl); +tl=0; +for(i=n;i>0;i--){ +size_t l=tsvalue(top-i)->len; +memcpy(buffer+tl,svalue(top-i),l); +tl+=l; +} +setsvalue(L,top-n,luaS_newlstr(L,buffer,tl)); +} +total-=n-1; +last-=n-1; +}while(total>1); +} +static void Arith(lua_State*L,StkId ra,const TValue*rb, +const TValue*rc,TMS op){ +TValue tempb,tempc; +const TValue*b,*c; +if((b=luaV_tonumber(rb,&tempb))!=NULL&& +(c=luaV_tonumber(rc,&tempc))!=NULL){ +lua_Number nb=nvalue(b),nc=nvalue(c); +switch(op){ +case TM_ADD:setnvalue(ra,luai_numadd(nb,nc));break; +case TM_SUB:setnvalue(ra,luai_numsub(nb,nc));break; +case TM_MUL:setnvalue(ra,luai_nummul(nb,nc));break; +case TM_DIV:setnvalue(ra,luai_numdiv(nb,nc));break; +case TM_MOD:setnvalue(ra,luai_nummod(nb,nc));break; +case TM_POW:setnvalue(ra,luai_numpow(nb,nc));break; +case TM_UNM:setnvalue(ra,luai_numunm(nb));break; +default:break; +} +} +else if(!call_binTM(L,rb,rc,ra,op)) +luaG_aritherror(L,rb,rc); +} +#define runtime_check(L,c){if(!(c))break;} +#define RA(i)(base+GETARG_A(i)) +#define RB(i)check_exp(getBMode(GET_OPCODE(i))==OpArgR,base+GETARG_B(i)) +#define RKB(i)check_exp(getBMode(GET_OPCODE(i))==OpArgK,ISK(GETARG_B(i))?k+INDEXK(GETARG_B(i)):base+GETARG_B(i)) +#define RKC(i)check_exp(getCMode(GET_OPCODE(i))==OpArgK,ISK(GETARG_C(i))?k+INDEXK(GETARG_C(i)):base+GETARG_C(i)) +#define KBx(i)check_exp(getBMode(GET_OPCODE(i))==OpArgK,k+GETARG_Bx(i)) +#define dojump(L,pc,i){(pc)+=(i);} +#define Protect(x){L->savedpc=pc;{x;};base=L->base;} +#define arith_op(op,tm){TValue*rb=RKB(i);TValue*rc=RKC(i);if(ttisnumber(rb)&&ttisnumber(rc)){lua_Number nb=nvalue(rb),nc=nvalue(rc);setnvalue(ra,op(nb,nc));}else Protect(Arith(L,ra,rb,rc,tm));} +static void luaV_execute(lua_State*L,int nexeccalls){ +LClosure*cl; +StkId base; +TValue*k; +const Instruction*pc; +reentry: +pc=L->savedpc; +cl=&clvalue(L->ci->func)->l; +base=L->base; +k=cl->p->k; +for(;;){ +const Instruction i=*pc++; +StkId ra; +ra=RA(i); +switch(GET_OPCODE(i)){ +case OP_MOVE:{ +setobj(L,ra,RB(i)); +continue; +} +case OP_LOADK:{ +setobj(L,ra,KBx(i)); +continue; +} +case OP_LOADBOOL:{ +setbvalue(ra,GETARG_B(i)); +if(GETARG_C(i))pc++; +continue; +} +case OP_LOADNIL:{ +TValue*rb=RB(i); +do{ +setnilvalue(rb--); +}while(rb>=ra); +continue; +} +case OP_GETUPVAL:{ +int b=GETARG_B(i); +setobj(L,ra,cl->upvals[b]->v); +continue; +} +case OP_GETGLOBAL:{ +TValue g; +TValue*rb=KBx(i); +sethvalue(L,&g,cl->env); +Protect(luaV_gettable(L,&g,rb,ra)); +continue; +} +case OP_GETTABLE:{ +Protect(luaV_gettable(L,RB(i),RKC(i),ra)); +continue; +} +case OP_SETGLOBAL:{ +TValue g; +sethvalue(L,&g,cl->env); +Protect(luaV_settable(L,&g,KBx(i),ra)); +continue; +} +case OP_SETUPVAL:{ +UpVal*uv=cl->upvals[GETARG_B(i)]; +setobj(L,uv->v,ra); +luaC_barrier(L,uv,ra); +continue; +} +case OP_SETTABLE:{ +Protect(luaV_settable(L,ra,RKB(i),RKC(i))); +continue; +} +case OP_NEWTABLE:{ +int b=GETARG_B(i); +int c=GETARG_C(i); +sethvalue(L,ra,luaH_new(L,luaO_fb2int(b),luaO_fb2int(c))); +Protect(luaC_checkGC(L)); +continue; +} +case OP_SELF:{ +StkId rb=RB(i); +setobj(L,ra+1,rb); +Protect(luaV_gettable(L,rb,RKC(i),ra)); +continue; +} +case OP_ADD:{ +arith_op(luai_numadd,TM_ADD); +continue; +} +case OP_SUB:{ +arith_op(luai_numsub,TM_SUB); +continue; +} +case OP_MUL:{ +arith_op(luai_nummul,TM_MUL); +continue; +} +case OP_DIV:{ +arith_op(luai_numdiv,TM_DIV); +continue; +} +case OP_MOD:{ +arith_op(luai_nummod,TM_MOD); +continue; +} +case OP_POW:{ +arith_op(luai_numpow,TM_POW); +continue; +} +case OP_UNM:{ +TValue*rb=RB(i); +if(ttisnumber(rb)){ +lua_Number nb=nvalue(rb); +setnvalue(ra,luai_numunm(nb)); +} +else{ +Protect(Arith(L,ra,rb,rb,TM_UNM)); +} +continue; +} +case OP_NOT:{ +int res=l_isfalse(RB(i)); +setbvalue(ra,res); +continue; +} +case OP_LEN:{ +const TValue*rb=RB(i); +switch(ttype(rb)){ +case 5:{ +setnvalue(ra,cast_num(luaH_getn(hvalue(rb)))); +break; +} +case 4:{ +setnvalue(ra,cast_num(tsvalue(rb)->len)); +break; +} +default:{ +Protect( +if(!call_binTM(L,rb,(&luaO_nilobject_),ra,TM_LEN)) +luaG_typeerror(L,rb,"get length of"); +) +} +} +continue; +} +case OP_CONCAT:{ +int b=GETARG_B(i); +int c=GETARG_C(i); +Protect(luaV_concat(L,c-b+1,c);luaC_checkGC(L)); +setobj(L,RA(i),base+b); +continue; +} +case OP_JMP:{ +dojump(L,pc,GETARG_sBx(i)); +continue; +} +case OP_EQ:{ +TValue*rb=RKB(i); +TValue*rc=RKC(i); +Protect( +if(equalobj(L,rb,rc)==GETARG_A(i)) +dojump(L,pc,GETARG_sBx(*pc)); +) +pc++; +continue; +} +case OP_LT:{ +Protect( +if(luaV_lessthan(L,RKB(i),RKC(i))==GETARG_A(i)) +dojump(L,pc,GETARG_sBx(*pc)); +) +pc++; +continue; +} +case OP_LE:{ +Protect( +if(lessequal(L,RKB(i),RKC(i))==GETARG_A(i)) +dojump(L,pc,GETARG_sBx(*pc)); +) +pc++; +continue; +} +case OP_TEST:{ +if(l_isfalse(ra)!=GETARG_C(i)) +dojump(L,pc,GETARG_sBx(*pc)); +pc++; +continue; +} +case OP_TESTSET:{ +TValue*rb=RB(i); +if(l_isfalse(rb)!=GETARG_C(i)){ +setobj(L,ra,rb); +dojump(L,pc,GETARG_sBx(*pc)); +} +pc++; +continue; +} +case OP_CALL:{ +int b=GETARG_B(i); +int nresults=GETARG_C(i)-1; +if(b!=0)L->top=ra+b; +L->savedpc=pc; +switch(luaD_precall(L,ra,nresults)){ +case 0:{ +nexeccalls++; +goto reentry; +} +case 1:{ +if(nresults>=0)L->top=L->ci->top; +base=L->base; +continue; +} +default:{ +return; +} +} +} +case OP_TAILCALL:{ +int b=GETARG_B(i); +if(b!=0)L->top=ra+b; +L->savedpc=pc; +switch(luaD_precall(L,ra,(-1))){ +case 0:{ +CallInfo*ci=L->ci-1; +int aux; +StkId func=ci->func; +StkId pfunc=(ci+1)->func; +if(L->openupval)luaF_close(L,ci->base); +L->base=ci->base=ci->func+((ci+1)->base-pfunc); +for(aux=0;pfunc+auxtop;aux++) +setobj(L,func+aux,pfunc+aux); +ci->top=L->top=func+aux; +ci->savedpc=L->savedpc; +ci->tailcalls++; +L->ci--; +goto reentry; +} +case 1:{ +base=L->base; +continue; +} +default:{ +return; +} +} +} +case OP_RETURN:{ +int b=GETARG_B(i); +if(b!=0)L->top=ra+b-1; +if(L->openupval)luaF_close(L,base); +L->savedpc=pc; +b=luaD_poscall(L,ra); +if(--nexeccalls==0) +return; +else{ +if(b)L->top=L->ci->top; +goto reentry; +} +} +case OP_FORLOOP:{ +lua_Number step=nvalue(ra+2); +lua_Number idx=luai_numadd(nvalue(ra),step); +lua_Number limit=nvalue(ra+1); +if(luai_numlt(0,step)?luai_numle(idx,limit) +:luai_numle(limit,idx)){ +dojump(L,pc,GETARG_sBx(i)); +setnvalue(ra,idx); +setnvalue(ra+3,idx); +} +continue; +} +case OP_FORPREP:{ +const TValue*init=ra; +const TValue*plimit=ra+1; +const TValue*pstep=ra+2; +L->savedpc=pc; +if(!tonumber(init,ra)) +luaG_runerror(L,LUA_QL("for")" initial value must be a number"); +else if(!tonumber(plimit,ra+1)) +luaG_runerror(L,LUA_QL("for")" limit must be a number"); +else if(!tonumber(pstep,ra+2)) +luaG_runerror(L,LUA_QL("for")" step must be a number"); +setnvalue(ra,luai_numsub(nvalue(ra),nvalue(pstep))); +dojump(L,pc,GETARG_sBx(i)); +continue; +} +case OP_TFORLOOP:{ +StkId cb=ra+3; +setobj(L,cb+2,ra+2); +setobj(L,cb+1,ra+1); +setobj(L,cb,ra); +L->top=cb+3; +Protect(luaD_call(L,cb,GETARG_C(i))); +L->top=L->ci->top; +cb=RA(i)+3; +if(!ttisnil(cb)){ +setobj(L,cb-1,cb); +dojump(L,pc,GETARG_sBx(*pc)); +} +pc++; +continue; +} +case OP_SETLIST:{ +int n=GETARG_B(i); +int c=GETARG_C(i); +int last; +Table*h; +if(n==0){ +n=cast_int(L->top-ra)-1; +L->top=L->ci->top; +} +if(c==0)c=cast_int(*pc++); +runtime_check(L,ttistable(ra)); +h=hvalue(ra); +last=((c-1)*50)+n; +if(last>h->sizearray) +luaH_resizearray(L,h,last); +for(;n>0;n--){ +TValue*val=ra+n; +setobj(L,luaH_setnum(L,h,last--),val); +luaC_barriert(L,h,val); +} +continue; +} +case OP_CLOSE:{ +luaF_close(L,ra); +continue; +} +case OP_CLOSURE:{ +Proto*p; +Closure*ncl; +int nup,j; +p=cl->p->p[GETARG_Bx(i)]; +nup=p->nups; +ncl=luaF_newLclosure(L,nup,cl->env); +ncl->l.p=p; +for(j=0;jl.upvals[j]=cl->upvals[GETARG_B(*pc)]; +else{ +ncl->l.upvals[j]=luaF_findupval(L,base+GETARG_B(*pc)); +} +} +setclvalue(L,ra,ncl); +Protect(luaC_checkGC(L)); +continue; +} +case OP_VARARG:{ +int b=GETARG_B(i)-1; +int j; +CallInfo*ci=L->ci; +int n=cast_int(ci->base-ci->func)-cl->p->numparams-1; +if(b==(-1)){ +Protect(luaD_checkstack(L,n)); +ra=RA(i); +b=n; +L->top=ra+n; +} +for(j=0;jbase-n+j); +} +else{ +setnilvalue(ra+j); +} +} +continue; +} +} +} +} +#define api_checknelems(L,n)luai_apicheck(L,(n)<=(L->top-L->base)) +#define api_checkvalidindex(L,i)luai_apicheck(L,(i)!=(&luaO_nilobject_)) +#define api_incr_top(L){luai_apicheck(L,L->topci->top);L->top++;} +static TValue*index2adr(lua_State*L,int idx){ +if(idx>0){ +TValue*o=L->base+(idx-1); +luai_apicheck(L,idx<=L->ci->top-L->base); +if(o>=L->top)return cast(TValue*,(&luaO_nilobject_)); +else return o; +} +else if(idx>(-10000)){ +luai_apicheck(L,idx!=0&&-idx<=L->top-L->base); +return L->top+idx; +} +else switch(idx){ +case(-10000):return registry(L); +case(-10001):{ +Closure*func=curr_func(L); +sethvalue(L,&L->env,func->c.env); +return&L->env; +} +case(-10002):return gt(L); +default:{ +Closure*func=curr_func(L); +idx=(-10002)-idx; +return(idx<=func->c.nupvalues) +?&func->c.upvalue[idx-1] +:cast(TValue*,(&luaO_nilobject_)); +} +} +} +static Table*getcurrenv(lua_State*L){ +if(L->ci==L->base_ci) +return hvalue(gt(L)); +else{ +Closure*func=curr_func(L); +return func->c.env; +} +} +static int lua_checkstack(lua_State*L,int size){ +int res=1; +if(size>8000||(L->top-L->base+size)>8000) +res=0; +else if(size>0){ +luaD_checkstack(L,size); +if(L->ci->toptop+size) +L->ci->top=L->top+size; +} +return res; +} +static lua_CFunction lua_atpanic(lua_State*L,lua_CFunction panicf){ +lua_CFunction old; +old=G(L)->panic; +G(L)->panic=panicf; +return old; +} +static int lua_gettop(lua_State*L){ +return cast_int(L->top-L->base); +} +static void lua_settop(lua_State*L,int idx){ +if(idx>=0){ +luai_apicheck(L,idx<=L->stack_last-L->base); +while(L->topbase+idx) +setnilvalue(L->top++); +L->top=L->base+idx; +} +else{ +luai_apicheck(L,-(idx+1)<=(L->top-L->base)); +L->top+=idx+1; +} +} +static void lua_remove(lua_State*L,int idx){ +StkId p; +p=index2adr(L,idx); +api_checkvalidindex(L,p); +while(++ptop)setobj(L,p-1,p); +L->top--; +} +static void lua_insert(lua_State*L,int idx){ +StkId p; +StkId q; +p=index2adr(L,idx); +api_checkvalidindex(L,p); +for(q=L->top;q>p;q--)setobj(L,q,q-1); +setobj(L,p,L->top); +} +static void lua_replace(lua_State*L,int idx){ +StkId o; +if(idx==(-10001)&&L->ci==L->base_ci) +luaG_runerror(L,"no calling environment"); +api_checknelems(L,1); +o=index2adr(L,idx); +api_checkvalidindex(L,o); +if(idx==(-10001)){ +Closure*func=curr_func(L); +luai_apicheck(L,ttistable(L->top-1)); +func->c.env=hvalue(L->top-1); +luaC_barrier(L,func,L->top-1); +} +else{ +setobj(L,o,L->top-1); +if(idx<(-10002)) +luaC_barrier(L,curr_func(L),L->top-1); +} +L->top--; +} +static void lua_pushvalue(lua_State*L,int idx){ +setobj(L,L->top,index2adr(L,idx)); +api_incr_top(L); +} +static int lua_type(lua_State*L,int idx){ +StkId o=index2adr(L,idx); +return(o==(&luaO_nilobject_))?(-1):ttype(o); +} +static const char*lua_typename(lua_State*L,int t){ +UNUSED(L); +return(t==(-1))?"no value":luaT_typenames[t]; +} +static int lua_iscfunction(lua_State*L,int idx){ +StkId o=index2adr(L,idx); +return iscfunction(o); +} +static int lua_isnumber(lua_State*L,int idx){ +TValue n; +const TValue*o=index2adr(L,idx); +return tonumber(o,&n); +} +static int lua_isstring(lua_State*L,int idx){ +int t=lua_type(L,idx); +return(t==4||t==3); +} +static int lua_rawequal(lua_State*L,int index1,int index2){ +StkId o1=index2adr(L,index1); +StkId o2=index2adr(L,index2); +return(o1==(&luaO_nilobject_)||o2==(&luaO_nilobject_))?0 +:luaO_rawequalObj(o1,o2); +} +static int lua_lessthan(lua_State*L,int index1,int index2){ +StkId o1,o2; +int i; +o1=index2adr(L,index1); +o2=index2adr(L,index2); +i=(o1==(&luaO_nilobject_)||o2==(&luaO_nilobject_))?0 +:luaV_lessthan(L,o1,o2); +return i; +} +static lua_Number lua_tonumber(lua_State*L,int idx){ +TValue n; +const TValue*o=index2adr(L,idx); +if(tonumber(o,&n)) +return nvalue(o); +else +return 0; +} +static lua_Integer lua_tointeger(lua_State*L,int idx){ +TValue n; +const TValue*o=index2adr(L,idx); +if(tonumber(o,&n)){ +lua_Integer res; +lua_Number num=nvalue(o); +lua_number2integer(res,num); +return res; +} +else +return 0; +} +static int lua_toboolean(lua_State*L,int idx){ +const TValue*o=index2adr(L,idx); +return!l_isfalse(o); +} +static const char*lua_tolstring(lua_State*L,int idx,size_t*len){ +StkId o=index2adr(L,idx); +if(!ttisstring(o)){ +if(!luaV_tostring(L,o)){ +if(len!=NULL)*len=0; +return NULL; +} +luaC_checkGC(L); +o=index2adr(L,idx); +} +if(len!=NULL)*len=tsvalue(o)->len; +return svalue(o); +} +static size_t lua_objlen(lua_State*L,int idx){ +StkId o=index2adr(L,idx); +switch(ttype(o)){ +case 4:return tsvalue(o)->len; +case 7:return uvalue(o)->len; +case 5:return luaH_getn(hvalue(o)); +case 3:{ +size_t l; +l=(luaV_tostring(L,o)?tsvalue(o)->len:0); +return l; +} +default:return 0; +} +} +static lua_CFunction lua_tocfunction(lua_State*L,int idx){ +StkId o=index2adr(L,idx); +return(!iscfunction(o))?NULL:clvalue(o)->c.f; +} +static void*lua_touserdata(lua_State*L,int idx){ +StkId o=index2adr(L,idx); +switch(ttype(o)){ +case 7:return(rawuvalue(o)+1); +case 2:return pvalue(o); +default:return NULL; +} +} +static void lua_pushnil(lua_State*L){ +setnilvalue(L->top); +api_incr_top(L); +} +static void lua_pushnumber(lua_State*L,lua_Number n){ +setnvalue(L->top,n); +api_incr_top(L); +} +static void lua_pushinteger(lua_State*L,lua_Integer n){ +setnvalue(L->top,cast_num(n)); +api_incr_top(L); +} +static void lua_pushlstring(lua_State*L,const char*s,size_t len){ +luaC_checkGC(L); +setsvalue(L,L->top,luaS_newlstr(L,s,len)); +api_incr_top(L); +} +static void lua_pushstring(lua_State*L,const char*s){ +if(s==NULL) +lua_pushnil(L); +else +lua_pushlstring(L,s,strlen(s)); +} +static const char*lua_pushvfstring(lua_State*L,const char*fmt, +va_list argp){ +const char*ret; +luaC_checkGC(L); +ret=luaO_pushvfstring(L,fmt,argp); +return ret; +} +static const char*lua_pushfstring(lua_State*L,const char*fmt,...){ +const char*ret; +va_list argp; +luaC_checkGC(L); +va_start(argp,fmt); +ret=luaO_pushvfstring(L,fmt,argp); +va_end(argp); +return ret; +} +static void lua_pushcclosure(lua_State*L,lua_CFunction fn,int n){ +Closure*cl; +luaC_checkGC(L); +api_checknelems(L,n); +cl=luaF_newCclosure(L,n,getcurrenv(L)); +cl->c.f=fn; +L->top-=n; +while(n--) +setobj(L,&cl->c.upvalue[n],L->top+n); +setclvalue(L,L->top,cl); +api_incr_top(L); +} +static void lua_pushboolean(lua_State*L,int b){ +setbvalue(L->top,(b!=0)); +api_incr_top(L); +} +static int lua_pushthread(lua_State*L){ +setthvalue(L,L->top,L); +api_incr_top(L); +return(G(L)->mainthread==L); +} +static void lua_gettable(lua_State*L,int idx){ +StkId t; +t=index2adr(L,idx); +api_checkvalidindex(L,t); +luaV_gettable(L,t,L->top-1,L->top-1); +} +static void lua_getfield(lua_State*L,int idx,const char*k){ +StkId t; +TValue key; +t=index2adr(L,idx); +api_checkvalidindex(L,t); +setsvalue(L,&key,luaS_new(L,k)); +luaV_gettable(L,t,&key,L->top); +api_incr_top(L); +} +static void lua_rawget(lua_State*L,int idx){ +StkId t; +t=index2adr(L,idx); +luai_apicheck(L,ttistable(t)); +setobj(L,L->top-1,luaH_get(hvalue(t),L->top-1)); +} +static void lua_rawgeti(lua_State*L,int idx,int n){ +StkId o; +o=index2adr(L,idx); +luai_apicheck(L,ttistable(o)); +setobj(L,L->top,luaH_getnum(hvalue(o),n)); +api_incr_top(L); +} +static void lua_createtable(lua_State*L,int narray,int nrec){ +luaC_checkGC(L); +sethvalue(L,L->top,luaH_new(L,narray,nrec)); +api_incr_top(L); +} +static int lua_getmetatable(lua_State*L,int objindex){ +const TValue*obj; +Table*mt=NULL; +int res; +obj=index2adr(L,objindex); +switch(ttype(obj)){ +case 5: +mt=hvalue(obj)->metatable; +break; +case 7: +mt=uvalue(obj)->metatable; +break; +default: +mt=G(L)->mt[ttype(obj)]; +break; +} +if(mt==NULL) +res=0; +else{ +sethvalue(L,L->top,mt); +api_incr_top(L); +res=1; +} +return res; +} +static void lua_getfenv(lua_State*L,int idx){ +StkId o; +o=index2adr(L,idx); +api_checkvalidindex(L,o); +switch(ttype(o)){ +case 6: +sethvalue(L,L->top,clvalue(o)->c.env); +break; +case 7: +sethvalue(L,L->top,uvalue(o)->env); +break; +case 8: +setobj(L,L->top,gt(thvalue(o))); +break; +default: +setnilvalue(L->top); +break; +} +api_incr_top(L); +} +static void lua_settable(lua_State*L,int idx){ +StkId t; +api_checknelems(L,2); +t=index2adr(L,idx); +api_checkvalidindex(L,t); +luaV_settable(L,t,L->top-2,L->top-1); +L->top-=2; +} +static void lua_setfield(lua_State*L,int idx,const char*k){ +StkId t; +TValue key; +api_checknelems(L,1); +t=index2adr(L,idx); +api_checkvalidindex(L,t); +setsvalue(L,&key,luaS_new(L,k)); +luaV_settable(L,t,&key,L->top-1); +L->top--; +} +static void lua_rawset(lua_State*L,int idx){ +StkId t; +api_checknelems(L,2); +t=index2adr(L,idx); +luai_apicheck(L,ttistable(t)); +setobj(L,luaH_set(L,hvalue(t),L->top-2),L->top-1); +luaC_barriert(L,hvalue(t),L->top-1); +L->top-=2; +} +static void lua_rawseti(lua_State*L,int idx,int n){ +StkId o; +api_checknelems(L,1); +o=index2adr(L,idx); +luai_apicheck(L,ttistable(o)); +setobj(L,luaH_setnum(L,hvalue(o),n),L->top-1); +luaC_barriert(L,hvalue(o),L->top-1); +L->top--; +} +static int lua_setmetatable(lua_State*L,int objindex){ +TValue*obj; +Table*mt; +api_checknelems(L,1); +obj=index2adr(L,objindex); +api_checkvalidindex(L,obj); +if(ttisnil(L->top-1)) +mt=NULL; +else{ +luai_apicheck(L,ttistable(L->top-1)); +mt=hvalue(L->top-1); +} +switch(ttype(obj)){ +case 5:{ +hvalue(obj)->metatable=mt; +if(mt) +luaC_objbarriert(L,hvalue(obj),mt); +break; +} +case 7:{ +uvalue(obj)->metatable=mt; +if(mt) +luaC_objbarrier(L,rawuvalue(obj),mt); +break; +} +default:{ +G(L)->mt[ttype(obj)]=mt; +break; +} +} +L->top--; +return 1; +} +static int lua_setfenv(lua_State*L,int idx){ +StkId o; +int res=1; +api_checknelems(L,1); +o=index2adr(L,idx); +api_checkvalidindex(L,o); +luai_apicheck(L,ttistable(L->top-1)); +switch(ttype(o)){ +case 6: +clvalue(o)->c.env=hvalue(L->top-1); +break; +case 7: +uvalue(o)->env=hvalue(L->top-1); +break; +case 8: +sethvalue(L,gt(thvalue(o)),hvalue(L->top-1)); +break; +default: +res=0; +break; +} +if(res)luaC_objbarrier(L,gcvalue(o),hvalue(L->top-1)); +L->top--; +return res; +} +#define adjustresults(L,nres){if(nres==(-1)&&L->top>=L->ci->top)L->ci->top=L->top;} +#define checkresults(L,na,nr)luai_apicheck(L,(nr)==(-1)||(L->ci->top-L->top>=(nr)-(na))) +static void lua_call(lua_State*L,int nargs,int nresults){ +StkId func; +api_checknelems(L,nargs+1); +checkresults(L,nargs,nresults); +func=L->top-(nargs+1); +luaD_call(L,func,nresults); +adjustresults(L,nresults); +} +struct CallS{ +StkId func; +int nresults; +}; +static void f_call(lua_State*L,void*ud){ +struct CallS*c=cast(struct CallS*,ud); +luaD_call(L,c->func,c->nresults); +} +static int lua_pcall(lua_State*L,int nargs,int nresults,int errfunc){ +struct CallS c; +int status; +ptrdiff_t func; +api_checknelems(L,nargs+1); +checkresults(L,nargs,nresults); +if(errfunc==0) +func=0; +else{ +StkId o=index2adr(L,errfunc); +api_checkvalidindex(L,o); +func=savestack(L,o); +} +c.func=L->top-(nargs+1); +c.nresults=nresults; +status=luaD_pcall(L,f_call,&c,savestack(L,c.func),func); +adjustresults(L,nresults); +return status; +} +static int lua_load(lua_State*L,lua_Reader reader,void*data, +const char*chunkname){ +ZIO z; +int status; +if(!chunkname)chunkname="?"; +luaZ_init(L,&z,reader,data); +status=luaD_protectedparser(L,&z,chunkname); +return status; +} +static int lua_error(lua_State*L){ +api_checknelems(L,1); +luaG_errormsg(L); +return 0; +} +static int lua_next(lua_State*L,int idx){ +StkId t; +int more; +t=index2adr(L,idx); +luai_apicheck(L,ttistable(t)); +more=luaH_next(L,hvalue(t),L->top-1); +if(more){ +api_incr_top(L); +} +else +L->top-=1; +return more; +} +static void lua_concat(lua_State*L,int n){ +api_checknelems(L,n); +if(n>=2){ +luaC_checkGC(L); +luaV_concat(L,n,cast_int(L->top-L->base)-1); +L->top-=(n-1); +} +else if(n==0){ +setsvalue(L,L->top,luaS_newlstr(L,"",0)); +api_incr_top(L); +} +} +static void*lua_newuserdata(lua_State*L,size_t size){ +Udata*u; +luaC_checkGC(L); +u=luaS_newudata(L,size,getcurrenv(L)); +setuvalue(L,L->top,u); +api_incr_top(L); +return u+1; +} +#define luaL_getn(L,i)((int)lua_objlen(L,i)) +#define luaL_setn(L,i,j)((void)0) +typedef struct luaL_Reg{ +const char*name; +lua_CFunction func; +}luaL_Reg; +static void luaI_openlib(lua_State*L,const char*libname, +const luaL_Reg*l,int nup); +static int luaL_argerror(lua_State*L,int numarg,const char*extramsg); +static const char* luaL_checklstring(lua_State*L,int numArg, +size_t*l); +static const char* luaL_optlstring(lua_State*L,int numArg, +const char*def,size_t*l); +static lua_Integer luaL_checkinteger(lua_State*L,int numArg); +static lua_Integer luaL_optinteger(lua_State*L,int nArg, +lua_Integer def); +static int luaL_error(lua_State*L,const char*fmt,...); +static const char* luaL_findtable(lua_State*L,int idx, +const char*fname,int szhint); +#define luaL_argcheck(L,cond,numarg,extramsg)((void)((cond)||luaL_argerror(L,(numarg),(extramsg)))) +#define luaL_checkstring(L,n)(luaL_checklstring(L,(n),NULL)) +#define luaL_optstring(L,n,d)(luaL_optlstring(L,(n),(d),NULL)) +#define luaL_checkint(L,n)((int)luaL_checkinteger(L,(n))) +#define luaL_optint(L,n,d)((int)luaL_optinteger(L,(n),(d))) +#define luaL_typename(L,i)lua_typename(L,lua_type(L,(i))) +#define luaL_getmetatable(L,n)(lua_getfield(L,(-10000),(n))) +#define luaL_opt(L,f,n,d)(lua_isnoneornil(L,(n))?(d):f(L,(n))) +typedef struct luaL_Buffer{ +char*p; +int lvl; +lua_State*L; +char buffer[BUFSIZ]; +}luaL_Buffer; +#define luaL_addchar(B,c)((void)((B)->p<((B)->buffer+BUFSIZ)||luaL_prepbuffer(B)),(*(B)->p++=(char)(c))) +#define luaL_addsize(B,n)((B)->p+=(n)) +static char* luaL_prepbuffer(luaL_Buffer*B); +static int luaL_argerror(lua_State*L,int narg,const char*extramsg){ +lua_Debug ar; +if(!lua_getstack(L,0,&ar)) +return luaL_error(L,"bad argument #%d (%s)",narg,extramsg); +lua_getinfo(L,"n",&ar); +if(strcmp(ar.namewhat,"method")==0){ +narg--; +if(narg==0) +return luaL_error(L,"calling "LUA_QL("%s")" on bad self (%s)", +ar.name,extramsg); +} +if(ar.name==NULL) +ar.name="?"; +return luaL_error(L,"bad argument #%d to "LUA_QL("%s")" (%s)", +narg,ar.name,extramsg); +} +static int luaL_typerror(lua_State*L,int narg,const char*tname){ +const char*msg=lua_pushfstring(L,"%s expected, got %s", +tname,luaL_typename(L,narg)); +return luaL_argerror(L,narg,msg); +} +static void tag_error(lua_State*L,int narg,int tag){ +luaL_typerror(L,narg,lua_typename(L,tag)); +} +static void luaL_where(lua_State*L,int level){ +lua_Debug ar; +if(lua_getstack(L,level,&ar)){ +lua_getinfo(L,"Sl",&ar); +if(ar.currentline>0){ +lua_pushfstring(L,"%s:%d: ",ar.short_src,ar.currentline); +return; +} +} +lua_pushliteral(L,""); +} +static int luaL_error(lua_State*L,const char*fmt,...){ +va_list argp; +va_start(argp,fmt); +luaL_where(L,1); +lua_pushvfstring(L,fmt,argp); +va_end(argp); +lua_concat(L,2); +return lua_error(L); +} +static int luaL_newmetatable(lua_State*L,const char*tname){ +lua_getfield(L,(-10000),tname); +if(!lua_isnil(L,-1)) +return 0; +lua_pop(L,1); +lua_newtable(L); +lua_pushvalue(L,-1); +lua_setfield(L,(-10000),tname); +return 1; +} +static void*luaL_checkudata(lua_State*L,int ud,const char*tname){ +void*p=lua_touserdata(L,ud); +if(p!=NULL){ +if(lua_getmetatable(L,ud)){ +lua_getfield(L,(-10000),tname); +if(lua_rawequal(L,-1,-2)){ +lua_pop(L,2); +return p; +} +} +} +luaL_typerror(L,ud,tname); +return NULL; +} +static void luaL_checkstack(lua_State*L,int space,const char*mes){ +if(!lua_checkstack(L,space)) +luaL_error(L,"stack overflow (%s)",mes); +} +static void luaL_checktype(lua_State*L,int narg,int t){ +if(lua_type(L,narg)!=t) +tag_error(L,narg,t); +} +static void luaL_checkany(lua_State*L,int narg){ +if(lua_type(L,narg)==(-1)) +luaL_argerror(L,narg,"value expected"); +} +static const char*luaL_checklstring(lua_State*L,int narg,size_t*len){ +const char*s=lua_tolstring(L,narg,len); +if(!s)tag_error(L,narg,4); +return s; +} +static const char*luaL_optlstring(lua_State*L,int narg, +const char*def,size_t*len){ +if(lua_isnoneornil(L,narg)){ +if(len) +*len=(def?strlen(def):0); +return def; +} +else return luaL_checklstring(L,narg,len); +} +static lua_Number luaL_checknumber(lua_State*L,int narg){ +lua_Number d=lua_tonumber(L,narg); +if(d==0&&!lua_isnumber(L,narg)) +tag_error(L,narg,3); +return d; +} +static lua_Integer luaL_checkinteger(lua_State*L,int narg){ +lua_Integer d=lua_tointeger(L,narg); +if(d==0&&!lua_isnumber(L,narg)) +tag_error(L,narg,3); +return d; +} +static lua_Integer luaL_optinteger(lua_State*L,int narg, +lua_Integer def){ +return luaL_opt(L,luaL_checkinteger,narg,def); +} +static int luaL_getmetafield(lua_State*L,int obj,const char*event){ +if(!lua_getmetatable(L,obj)) +return 0; +lua_pushstring(L,event); +lua_rawget(L,-2); +if(lua_isnil(L,-1)){ +lua_pop(L,2); +return 0; +} +else{ +lua_remove(L,-2); +return 1; +} +} +static void luaL_register(lua_State*L,const char*libname, +const luaL_Reg*l){ +luaI_openlib(L,libname,l,0); +} +static int libsize(const luaL_Reg*l){ +int size=0; +for(;l->name;l++)size++; +return size; +} +static void luaI_openlib(lua_State*L,const char*libname, +const luaL_Reg*l,int nup){ +if(libname){ +int size=libsize(l); +luaL_findtable(L,(-10000),"_LOADED",1); +lua_getfield(L,-1,libname); +if(!lua_istable(L,-1)){ +lua_pop(L,1); +if(luaL_findtable(L,(-10002),libname,size)!=NULL) +luaL_error(L,"name conflict for module "LUA_QL("%s"),libname); +lua_pushvalue(L,-1); +lua_setfield(L,-3,libname); +} +lua_remove(L,-2); +lua_insert(L,-(nup+1)); +} +for(;l->name;l++){ +int i; +for(i=0;ifunc,nup); +lua_setfield(L,-(nup+2),l->name); +} +lua_pop(L,nup); +} +static const char*luaL_findtable(lua_State*L,int idx, +const char*fname,int szhint){ +const char*e; +lua_pushvalue(L,idx); +do{ +e=strchr(fname,'.'); +if(e==NULL)e=fname+strlen(fname); +lua_pushlstring(L,fname,e-fname); +lua_rawget(L,-2); +if(lua_isnil(L,-1)){ +lua_pop(L,1); +lua_createtable(L,0,(*e=='.'?1:szhint)); +lua_pushlstring(L,fname,e-fname); +lua_pushvalue(L,-2); +lua_settable(L,-4); +} +else if(!lua_istable(L,-1)){ +lua_pop(L,2); +return fname; +} +lua_remove(L,-2); +fname=e+1; +}while(*e=='.'); +return NULL; +} +#define bufflen(B)((B)->p-(B)->buffer) +#define bufffree(B)((size_t)(BUFSIZ-bufflen(B))) +static int emptybuffer(luaL_Buffer*B){ +size_t l=bufflen(B); +if(l==0)return 0; +else{ +lua_pushlstring(B->L,B->buffer,l); +B->p=B->buffer; +B->lvl++; +return 1; +} +} +static void adjuststack(luaL_Buffer*B){ +if(B->lvl>1){ +lua_State*L=B->L; +int toget=1; +size_t toplen=lua_strlen(L,-1); +do{ +size_t l=lua_strlen(L,-(toget+1)); +if(B->lvl-toget+1>=(20/2)||toplen>l){ +toplen+=l; +toget++; +} +else break; +}while(togetlvl); +lua_concat(L,toget); +B->lvl=B->lvl-toget+1; +} +} +static char*luaL_prepbuffer(luaL_Buffer*B){ +if(emptybuffer(B)) +adjuststack(B); +return B->buffer; +} +static void luaL_addlstring(luaL_Buffer*B,const char*s,size_t l){ +while(l--) +luaL_addchar(B,*s++); +} +static void luaL_pushresult(luaL_Buffer*B){ +emptybuffer(B); +lua_concat(B->L,B->lvl); +B->lvl=1; +} +static void luaL_addvalue(luaL_Buffer*B){ +lua_State*L=B->L; +size_t vl; +const char*s=lua_tolstring(L,-1,&vl); +if(vl<=bufffree(B)){ +memcpy(B->p,s,vl); +B->p+=vl; +lua_pop(L,1); +} +else{ +if(emptybuffer(B)) +lua_insert(L,-2); +B->lvl++; +adjuststack(B); +} +} +static void luaL_buffinit(lua_State*L,luaL_Buffer*B){ +B->L=L; +B->p=B->buffer; +B->lvl=0; +} +typedef struct LoadF{ +int extraline; +FILE*f; +char buff[BUFSIZ]; +}LoadF; +static const char*getF(lua_State*L,void*ud,size_t*size){ +LoadF*lf=(LoadF*)ud; +(void)L; +if(lf->extraline){ +lf->extraline=0; +*size=1; +return"\n"; +} +if(feof(lf->f))return NULL; +*size=fread(lf->buff,1,sizeof(lf->buff),lf->f); +return(*size>0)?lf->buff:NULL; +} +static int errfile(lua_State*L,const char*what,int fnameindex){ +const char*serr=strerror(errno); +const char*filename=lua_tostring(L,fnameindex)+1; +lua_pushfstring(L,"cannot %s %s: %s",what,filename,serr); +lua_remove(L,fnameindex); +return(5+1); +} +static int luaL_loadfile(lua_State*L,const char*filename){ +LoadF lf; +int status,readstatus; +int c; +int fnameindex=lua_gettop(L)+1; +lf.extraline=0; +if(filename==NULL){ +lua_pushliteral(L,"=stdin"); +lf.f=stdin; +} +else{ +lua_pushfstring(L,"@%s",filename); +lf.f=fopen(filename,"r"); +if(lf.f==NULL)return errfile(L,"open",fnameindex); +} +c=getc(lf.f); +if(c=='#'){ +lf.extraline=1; +while((c=getc(lf.f))!=EOF&&c!='\n'); +if(c=='\n')c=getc(lf.f); +} +if(c=="\033Lua"[0]&&filename){ +lf.f=freopen(filename,"rb",lf.f); +if(lf.f==NULL)return errfile(L,"reopen",fnameindex); +while((c=getc(lf.f))!=EOF&&c!="\033Lua"[0]); +lf.extraline=0; +} +ungetc(c,lf.f); +status=lua_load(L,getF,&lf,lua_tostring(L,-1)); +readstatus=ferror(lf.f); +if(filename)fclose(lf.f); +if(readstatus){ +lua_settop(L,fnameindex); +return errfile(L,"read",fnameindex); +} +lua_remove(L,fnameindex); +return status; +} +typedef struct LoadS{ +const char*s; +size_t size; +}LoadS; +static const char*getS(lua_State*L,void*ud,size_t*size){ +LoadS*ls=(LoadS*)ud; +(void)L; +if(ls->size==0)return NULL; +*size=ls->size; +ls->size=0; +return ls->s; +} +static int luaL_loadbuffer(lua_State*L,const char*buff,size_t size, +const char*name){ +LoadS ls; +ls.s=buff; +ls.size=size; +return lua_load(L,getS,&ls,name); +} +static void*l_alloc(void*ud,void*ptr,size_t osize,size_t nsize){ +(void)ud; +(void)osize; +if(nsize==0){ +free(ptr); +return NULL; +} +else +return realloc(ptr,nsize); +} +static int panic(lua_State*L){ +(void)L; +fprintf(stderr,"PANIC: unprotected error in call to Lua API (%s)\n", +lua_tostring(L,-1)); +return 0; +} +static lua_State*luaL_newstate(void){ +lua_State*L=lua_newstate(l_alloc,NULL); +if(L)lua_atpanic(L,&panic); +return L; +} +static int luaB_tonumber(lua_State*L){ +int base=luaL_optint(L,2,10); +if(base==10){ +luaL_checkany(L,1); +if(lua_isnumber(L,1)){ +lua_pushnumber(L,lua_tonumber(L,1)); +return 1; +} +} +else{ +const char*s1=luaL_checkstring(L,1); +char*s2; +unsigned long n; +luaL_argcheck(L,2<=base&&base<=36,2,"base out of range"); +n=strtoul(s1,&s2,base); +if(s1!=s2){ +while(isspace((unsigned char)(*s2)))s2++; +if(*s2=='\0'){ +lua_pushnumber(L,(lua_Number)n); +return 1; +} +} +} +lua_pushnil(L); +return 1; +} +static int luaB_error(lua_State*L){ +int level=luaL_optint(L,2,1); +lua_settop(L,1); +if(lua_isstring(L,1)&&level>0){ +luaL_where(L,level); +lua_pushvalue(L,1); +lua_concat(L,2); +} +return lua_error(L); +} +static int luaB_setmetatable(lua_State*L){ +int t=lua_type(L,2); +luaL_checktype(L,1,5); +luaL_argcheck(L,t==0||t==5,2, +"nil or table expected"); +if(luaL_getmetafield(L,1,"__metatable")) +luaL_error(L,"cannot change a protected metatable"); +lua_settop(L,2); +lua_setmetatable(L,1); +return 1; +} +static void getfunc(lua_State*L,int opt){ +if(lua_isfunction(L,1))lua_pushvalue(L,1); +else{ +lua_Debug ar; +int level=opt?luaL_optint(L,1,1):luaL_checkint(L,1); +luaL_argcheck(L,level>=0,1,"level must be non-negative"); +if(lua_getstack(L,level,&ar)==0) +luaL_argerror(L,1,"invalid level"); +lua_getinfo(L,"f",&ar); +if(lua_isnil(L,-1)) +luaL_error(L,"no function environment for tail call at level %d", +level); +} +} +static int luaB_setfenv(lua_State*L){ +luaL_checktype(L,2,5); +getfunc(L,0); +lua_pushvalue(L,2); +if(lua_isnumber(L,1)&&lua_tonumber(L,1)==0){ +lua_pushthread(L); +lua_insert(L,-2); +lua_setfenv(L,-2); +return 0; +} +else if(lua_iscfunction(L,-2)||lua_setfenv(L,-2)==0) +luaL_error(L, +LUA_QL("setfenv")" cannot change environment of given object"); +return 1; +} +static int luaB_rawget(lua_State*L){ +luaL_checktype(L,1,5); +luaL_checkany(L,2); +lua_settop(L,2); +lua_rawget(L,1); +return 1; +} +static int luaB_type(lua_State*L){ +luaL_checkany(L,1); +lua_pushstring(L,luaL_typename(L,1)); +return 1; +} +static int luaB_next(lua_State*L){ +luaL_checktype(L,1,5); +lua_settop(L,2); +if(lua_next(L,1)) +return 2; +else{ +lua_pushnil(L); +return 1; +} +} +static int luaB_pairs(lua_State*L){ +luaL_checktype(L,1,5); +lua_pushvalue(L,lua_upvalueindex(1)); +lua_pushvalue(L,1); +lua_pushnil(L); +return 3; +} +static int ipairsaux(lua_State*L){ +int i=luaL_checkint(L,2); +luaL_checktype(L,1,5); +i++; +lua_pushinteger(L,i); +lua_rawgeti(L,1,i); +return(lua_isnil(L,-1))?0:2; +} +static int luaB_ipairs(lua_State*L){ +luaL_checktype(L,1,5); +lua_pushvalue(L,lua_upvalueindex(1)); +lua_pushvalue(L,1); +lua_pushinteger(L,0); +return 3; +} +static int load_aux(lua_State*L,int status){ +if(status==0) +return 1; +else{ +lua_pushnil(L); +lua_insert(L,-2); +return 2; +} +} +static int luaB_loadstring(lua_State*L){ +size_t l; +const char*s=luaL_checklstring(L,1,&l); +const char*chunkname=luaL_optstring(L,2,s); +return load_aux(L,luaL_loadbuffer(L,s,l,chunkname)); +} +static int luaB_loadfile(lua_State*L){ +const char*fname=luaL_optstring(L,1,NULL); +return load_aux(L,luaL_loadfile(L,fname)); +} +static int luaB_assert(lua_State*L){ +luaL_checkany(L,1); +if(!lua_toboolean(L,1)) +return luaL_error(L,"%s",luaL_optstring(L,2,"assertion failed!")); +return lua_gettop(L); +} +static int luaB_unpack(lua_State*L){ +int i,e,n; +luaL_checktype(L,1,5); +i=luaL_optint(L,2,1); +e=luaL_opt(L,luaL_checkint,3,luaL_getn(L,1)); +if(i>e)return 0; +n=e-i+1; +if(n<=0||!lua_checkstack(L,n)) +return luaL_error(L,"too many results to unpack"); +lua_rawgeti(L,1,i); +while(i++e)e=pos; +for(i=e;i>pos;i--){ +lua_rawgeti(L,1,i-1); +lua_rawseti(L,1,i); +} +break; +} +default:{ +return luaL_error(L,"wrong number of arguments to "LUA_QL("insert")); +} +} +luaL_setn(L,1,e); +lua_rawseti(L,1,pos); +return 0; +} +static int tremove(lua_State*L){ +int e=aux_getn(L,1); +int pos=luaL_optint(L,2,e); +if(!(1<=pos&&pos<=e)) +return 0; +luaL_setn(L,1,e-1); +lua_rawgeti(L,1,pos); +for(;posu)luaL_error(L,"invalid order function for sorting"); +lua_pop(L,1); +} +while(lua_rawgeti(L,1,--j),sort_comp(L,-3,-1)){ +if(j0); +} +l=strlen(p); +if(l==0||p[l-1]!='\n') +luaL_addsize(&b,l); +else{ +luaL_addsize(&b,l-1); +luaL_pushresult(&b); +return 1; +} +} +} +static int read_chars(lua_State*L,FILE*f,size_t n){ +size_t rlen; +size_t nr; +luaL_Buffer b; +luaL_buffinit(L,&b); +rlen=BUFSIZ; +do{ +char*p=luaL_prepbuffer(&b); +if(rlen>n)rlen=n; +nr=fread(p,sizeof(char),rlen,f); +luaL_addsize(&b,nr); +n-=nr; +}while(n>0&&nr==rlen); +luaL_pushresult(&b); +return(n==0||lua_objlen(L,-1)>0); +} +static int g_read(lua_State*L,FILE*f,int first){ +int nargs=lua_gettop(L)-1; +int success; +int n; +clearerr(f); +if(nargs==0){ +success=read_line(L,f); +n=first+1; +} +else{ +luaL_checkstack(L,nargs+20,"too many arguments"); +success=1; +for(n=first;nargs--&&success;n++){ +if(lua_type(L,n)==3){ +size_t l=(size_t)lua_tointeger(L,n); +success=(l==0)?test_eof(L,f):read_chars(L,f,l); +} +else{ +const char*p=lua_tostring(L,n); +luaL_argcheck(L,p&&p[0]=='*',n,"invalid option"); +switch(p[1]){ +case'n': +success=read_number(L,f); +break; +case'l': +success=read_line(L,f); +break; +case'a': +read_chars(L,f,~((size_t)0)); +success=1; +break; +default: +return luaL_argerror(L,n,"invalid format"); +} +} +} +} +if(ferror(f)) +return pushresult(L,0,NULL); +if(!success){ +lua_pop(L,1); +lua_pushnil(L); +} +return n-first; +} +static int io_read(lua_State*L){ +return g_read(L,getiofile(L,1),1); +} +static int f_read(lua_State*L){ +return g_read(L,tofile(L),2); +} +static int io_readline(lua_State*L){ +FILE*f=*(FILE**)lua_touserdata(L,lua_upvalueindex(1)); +int sucess; +if(f==NULL) +luaL_error(L,"file is already closed"); +sucess=read_line(L,f); +if(ferror(f)) +return luaL_error(L,"%s",strerror(errno)); +if(sucess)return 1; +else{ +if(lua_toboolean(L,lua_upvalueindex(2))){ +lua_settop(L,0); +lua_pushvalue(L,lua_upvalueindex(1)); +aux_close(L); +} +return 0; +} +} +static int g_write(lua_State*L,FILE*f,int arg){ +int nargs=lua_gettop(L)-1; +int status=1; +for(;nargs--;arg++){ +if(lua_type(L,arg)==3){ +status=status&& +fprintf(f,"%.14g",lua_tonumber(L,arg))>0; +} +else{ +size_t l; +const char*s=luaL_checklstring(L,arg,&l); +status=status&&(fwrite(s,sizeof(char),l,f)==l); +} +} +return pushresult(L,status,NULL); +} +static int io_write(lua_State*L){ +return g_write(L,getiofile(L,2),1); +} +static int f_write(lua_State*L){ +return g_write(L,tofile(L),2); +} +static int io_flush(lua_State*L){ +return pushresult(L,fflush(getiofile(L,2))==0,NULL); +} +static int f_flush(lua_State*L){ +return pushresult(L,fflush(tofile(L))==0,NULL); +} +static const luaL_Reg iolib[]={ +{"close",io_close}, +{"flush",io_flush}, +{"input",io_input}, +{"lines",io_lines}, +{"open",io_open}, +{"output",io_output}, +{"read",io_read}, +{"type",io_type}, +{"write",io_write}, +{NULL,NULL} +}; +static const luaL_Reg flib[]={ +{"close",io_close}, +{"flush",f_flush}, +{"lines",f_lines}, +{"read",f_read}, +{"write",f_write}, +{"__gc",io_gc}, +{NULL,NULL} +}; +static void createmeta(lua_State*L){ +luaL_newmetatable(L,"FILE*"); +lua_pushvalue(L,-1); +lua_setfield(L,-2,"__index"); +luaL_register(L,NULL,flib); +} +static void createstdfile(lua_State*L,FILE*f,int k,const char*fname){ +*newfile(L)=f; +if(k>0){ +lua_pushvalue(L,-1); +lua_rawseti(L,(-10001),k); +} +lua_pushvalue(L,-2); +lua_setfenv(L,-2); +lua_setfield(L,-3,fname); +} +static void newfenv(lua_State*L,lua_CFunction cls){ +lua_createtable(L,0,1); +lua_pushcfunction(L,cls); +lua_setfield(L,-2,"__close"); +} +static int luaopen_io(lua_State*L){ +createmeta(L); +newfenv(L,io_fclose); +lua_replace(L,(-10001)); +luaL_register(L,"io",iolib); +newfenv(L,io_noclose); +createstdfile(L,stdin,1,"stdin"); +createstdfile(L,stdout,2,"stdout"); +createstdfile(L,stderr,0,"stderr"); +lua_pop(L,1); +lua_getfield(L,-1,"popen"); +newfenv(L,io_pclose); +lua_setfenv(L,-2); +lua_pop(L,1); +return 1; +} +static int os_pushresult(lua_State*L,int i,const char*filename){ +int en=errno; +if(i){ +lua_pushboolean(L,1); +return 1; +} +else{ +lua_pushnil(L); +lua_pushfstring(L,"%s: %s",filename,strerror(en)); +lua_pushinteger(L,en); +return 3; +} +} +static int os_remove(lua_State*L){ +const char*filename=luaL_checkstring(L,1); +return os_pushresult(L,remove(filename)==0,filename); +} +static int os_exit(lua_State*L){ +exit(luaL_optint(L,1,EXIT_SUCCESS)); +} +static const luaL_Reg syslib[]={ +{"exit",os_exit}, +{"remove",os_remove}, +{NULL,NULL} +}; +static int luaopen_os(lua_State*L){ +luaL_register(L,"os",syslib); +return 1; +} +#define uchar(c)((unsigned char)(c)) +static ptrdiff_t posrelat(ptrdiff_t pos,size_t len){ +if(pos<0)pos+=(ptrdiff_t)len+1; +return(pos>=0)?pos:0; +} +static int str_sub(lua_State*L){ +size_t l; +const char*s=luaL_checklstring(L,1,&l); +ptrdiff_t start=posrelat(luaL_checkinteger(L,2),l); +ptrdiff_t end=posrelat(luaL_optinteger(L,3,-1),l); +if(start<1)start=1; +if(end>(ptrdiff_t)l)end=(ptrdiff_t)l; +if(start<=end) +lua_pushlstring(L,s+start-1,end-start+1); +else lua_pushliteral(L,""); +return 1; +} +static int str_lower(lua_State*L){ +size_t l; +size_t i; +luaL_Buffer b; +const char*s=luaL_checklstring(L,1,&l); +luaL_buffinit(L,&b); +for(i=0;i0) +luaL_addlstring(&b,s,l); +luaL_pushresult(&b); +return 1; +} +static int str_byte(lua_State*L){ +size_t l; +const char*s=luaL_checklstring(L,1,&l); +ptrdiff_t posi=posrelat(luaL_optinteger(L,2,1),l); +ptrdiff_t pose=posrelat(luaL_optinteger(L,3,posi),l); +int n,i; +if(posi<=0)posi=1; +if((size_t)pose>l)pose=l; +if(posi>pose)return 0; +n=(int)(pose-posi+1); +if(posi+n<=pose) +luaL_error(L,"string slice too long"); +luaL_checkstack(L,n,"string slice too long"); +for(i=0;i=ms->level||ms->capture[l].len==(-1)) +return luaL_error(ms->L,"invalid capture index"); +return l; +} +static int capture_to_close(MatchState*ms){ +int level=ms->level; +for(level--;level>=0;level--) +if(ms->capture[level].len==(-1))return level; +return luaL_error(ms->L,"invalid pattern capture"); +} +static const char*classend(MatchState*ms,const char*p){ +switch(*p++){ +case'%':{ +if(*p=='\0') +luaL_error(ms->L,"malformed pattern (ends with "LUA_QL("%%")")"); +return p+1; +} +case'[':{ +if(*p=='^')p++; +do{ +if(*p=='\0') +luaL_error(ms->L,"malformed pattern (missing "LUA_QL("]")")"); +if(*(p++)=='%'&&*p!='\0') +p++; +}while(*p!=']'); +return p+1; +} +default:{ +return p; +} +} +} +static int match_class(int c,int cl){ +int res; +switch(tolower(cl)){ +case'a':res=isalpha(c);break; +case'c':res=iscntrl(c);break; +case'd':res=isdigit(c);break; +case'l':res=islower(c);break; +case'p':res=ispunct(c);break; +case's':res=isspace(c);break; +case'u':res=isupper(c);break; +case'w':res=isalnum(c);break; +case'x':res=isxdigit(c);break; +case'z':res=(c==0);break; +default:return(cl==c); +} +return(islower(cl)?res:!res); +} +static int matchbracketclass(int c,const char*p,const char*ec){ +int sig=1; +if(*(p+1)=='^'){ +sig=0; +p++; +} +while(++pL,"unbalanced pattern"); +if(*s!=*p)return NULL; +else{ +int b=*p; +int e=*(p+1); +int cont=1; +while(++ssrc_end){ +if(*s==e){ +if(--cont==0)return s+1; +} +else if(*s==b)cont++; +} +} +return NULL; +} +static const char*max_expand(MatchState*ms,const char*s, +const char*p,const char*ep){ +ptrdiff_t i=0; +while((s+i)src_end&&singlematch(uchar(*(s+i)),p,ep)) +i++; +while(i>=0){ +const char*res=match(ms,(s+i),ep+1); +if(res)return res; +i--; +} +return NULL; +} +static const char*min_expand(MatchState*ms,const char*s, +const char*p,const char*ep){ +for(;;){ +const char*res=match(ms,s,ep+1); +if(res!=NULL) +return res; +else if(ssrc_end&&singlematch(uchar(*s),p,ep)) +s++; +else return NULL; +} +} +static const char*start_capture(MatchState*ms,const char*s, +const char*p,int what){ +const char*res; +int level=ms->level; +if(level>=32)luaL_error(ms->L,"too many captures"); +ms->capture[level].init=s; +ms->capture[level].len=what; +ms->level=level+1; +if((res=match(ms,s,p))==NULL) +ms->level--; +return res; +} +static const char*end_capture(MatchState*ms,const char*s, +const char*p){ +int l=capture_to_close(ms); +const char*res; +ms->capture[l].len=s-ms->capture[l].init; +if((res=match(ms,s,p))==NULL) +ms->capture[l].len=(-1); +return res; +} +static const char*match_capture(MatchState*ms,const char*s,int l){ +size_t len; +l=check_capture(ms,l); +len=ms->capture[l].len; +if((size_t)(ms->src_end-s)>=len&& +memcmp(ms->capture[l].init,s,len)==0) +return s+len; +else return NULL; +} +static const char*match(MatchState*ms,const char*s,const char*p){ +init: +switch(*p){ +case'(':{ +if(*(p+1)==')') +return start_capture(ms,s,p+2,(-2)); +else +return start_capture(ms,s,p+1,(-1)); +} +case')':{ +return end_capture(ms,s,p+1); +} +case'%':{ +switch(*(p+1)){ +case'b':{ +s=matchbalance(ms,s,p+2); +if(s==NULL)return NULL; +p+=4;goto init; +} +case'f':{ +const char*ep;char previous; +p+=2; +if(*p!='[') +luaL_error(ms->L,"missing "LUA_QL("[")" after " +LUA_QL("%%f")" in pattern"); +ep=classend(ms,p); +previous=(s==ms->src_init)?'\0':*(s-1); +if(matchbracketclass(uchar(previous),p,ep-1)|| +!matchbracketclass(uchar(*s),p,ep-1))return NULL; +p=ep;goto init; +} +default:{ +if(isdigit(uchar(*(p+1)))){ +s=match_capture(ms,s,uchar(*(p+1))); +if(s==NULL)return NULL; +p+=2;goto init; +} +goto dflt; +} +} +} +case'\0':{ +return s; +} +case'$':{ +if(*(p+1)=='\0') +return(s==ms->src_end)?s:NULL; +else goto dflt; +} +default:dflt:{ +const char*ep=classend(ms,p); +int m=ssrc_end&&singlematch(uchar(*s),p,ep); +switch(*ep){ +case'?':{ +const char*res; +if(m&&((res=match(ms,s+1,ep+1))!=NULL)) +return res; +p=ep+1;goto init; +} +case'*':{ +return max_expand(ms,s,p,ep); +} +case'+':{ +return(m?max_expand(ms,s+1,p,ep):NULL); +} +case'-':{ +return min_expand(ms,s,p,ep); +} +default:{ +if(!m)return NULL; +s++;p=ep;goto init; +} +} +} +} +} +static const char*lmemfind(const char*s1,size_t l1, +const char*s2,size_t l2){ +if(l2==0)return s1; +else if(l2>l1)return NULL; +else{ +const char*init; +l2--; +l1=l1-l2; +while(l1>0&&(init=(const char*)memchr(s1,*s2,l1))!=NULL){ +init++; +if(memcmp(init,s2+1,l2)==0) +return init-1; +else{ +l1-=init-s1; +s1=init; +} +} +return NULL; +} +} +static void push_onecapture(MatchState*ms,int i,const char*s, +const char*e){ +if(i>=ms->level){ +if(i==0) +lua_pushlstring(ms->L,s,e-s); +else +luaL_error(ms->L,"invalid capture index"); +} +else{ +ptrdiff_t l=ms->capture[i].len; +if(l==(-1))luaL_error(ms->L,"unfinished capture"); +if(l==(-2)) +lua_pushinteger(ms->L,ms->capture[i].init-ms->src_init+1); +else +lua_pushlstring(ms->L,ms->capture[i].init,l); +} +} +static int push_captures(MatchState*ms,const char*s,const char*e){ +int i; +int nlevels=(ms->level==0&&s)?1:ms->level; +luaL_checkstack(ms->L,nlevels,"too many captures"); +for(i=0;il1)init=(ptrdiff_t)l1; +if(find&&(lua_toboolean(L,4)|| +strpbrk(p,"^$*+?.([%-")==NULL)){ +const char*s2=lmemfind(s+init,l1-init,p,l2); +if(s2){ +lua_pushinteger(L,s2-s+1); +lua_pushinteger(L,s2-s+l2); +return 2; +} +} +else{ +MatchState ms; +int anchor=(*p=='^')?(p++,1):0; +const char*s1=s+init; +ms.L=L; +ms.src_init=s; +ms.src_end=s+l1; +do{ +const char*res; +ms.level=0; +if((res=match(&ms,s1,p))!=NULL){ +if(find){ +lua_pushinteger(L,s1-s+1); +lua_pushinteger(L,res-s); +return push_captures(&ms,NULL,0)+2; +} +else +return push_captures(&ms,s1,res); +} +}while(s1++L,3,&l); +for(i=0;iL; +switch(lua_type(L,3)){ +case 3: +case 4:{ +add_s(ms,b,s,e); +return; +} +case 6:{ +int n; +lua_pushvalue(L,3); +n=push_captures(ms,s,e); +lua_call(L,n,1); +break; +} +case 5:{ +push_onecapture(ms,0,s,e); +lua_gettable(L,3); +break; +} +} +if(!lua_toboolean(L,-1)){ +lua_pop(L,1); +lua_pushlstring(L,s,e-s); +} +else if(!lua_isstring(L,-1)) +luaL_error(L,"invalid replacement value (a %s)",luaL_typename(L,-1)); +luaL_addvalue(b); +} +static int str_gsub(lua_State*L){ +size_t srcl; +const char*src=luaL_checklstring(L,1,&srcl); +const char*p=luaL_checkstring(L,2); +int tr=lua_type(L,3); +int max_s=luaL_optint(L,4,srcl+1); +int anchor=(*p=='^')?(p++,1):0; +int n=0; +MatchState ms; +luaL_Buffer b; +luaL_argcheck(L,tr==3||tr==4|| +tr==6||tr==5,3, +"string/function/table expected"); +luaL_buffinit(L,&b); +ms.L=L; +ms.src_init=src; +ms.src_end=src+srcl; +while(nsrc) +src=e; +else if(src=sizeof("-+ #0")) +luaL_error(L,"invalid format (repeated flags)"); +if(isdigit(uchar(*p)))p++; +if(isdigit(uchar(*p)))p++; +if(*p=='.'){ +p++; +if(isdigit(uchar(*p)))p++; +if(isdigit(uchar(*p)))p++; +} +if(isdigit(uchar(*p))) +luaL_error(L,"invalid format (width or precision too long)"); +*(form++)='%'; +strncpy(form,strfrmt,p-strfrmt+1); +form+=p-strfrmt+1; +*form='\0'; +return p; +} +static void addintlen(char*form){ +size_t l=strlen(form); +char spec=form[l-1]; +strcpy(form+l-1,"l"); +form[l+sizeof("l")-2]=spec; +form[l+sizeof("l")-1]='\0'; +} +static int str_format(lua_State*L){ +int top=lua_gettop(L); +int arg=1; +size_t sfl; +const char*strfrmt=luaL_checklstring(L,arg,&sfl); +const char*strfrmt_end=strfrmt+sfl; +luaL_Buffer b; +luaL_buffinit(L,&b); +while(strfrmttop) +luaL_argerror(L,arg,"no value"); +strfrmt=scanformat(L,strfrmt,form); +switch(*strfrmt++){ +case'c':{ +sprintf(buff,form,(int)luaL_checknumber(L,arg)); +break; +} +case'd':case'i':{ +addintlen(form); +sprintf(buff,form,(long)luaL_checknumber(L,arg)); +break; +} +case'o':case'u':case'x':case'X':{ +addintlen(form); +sprintf(buff,form,(unsigned long)luaL_checknumber(L,arg)); +break; +} +case'e':case'E':case'f': +case'g':case'G':{ +sprintf(buff,form,(double)luaL_checknumber(L,arg)); +break; +} +case'q':{ +addquoted(L,&b,arg); +continue; +} +case's':{ +size_t l; +const char*s=luaL_checklstring(L,arg,&l); +if(!strchr(form,'.')&&l>=100){ +lua_pushvalue(L,arg); +luaL_addvalue(&b); +continue; +} +else{ +sprintf(buff,form,s); +break; +} +} +default:{ +return luaL_error(L,"invalid option "LUA_QL("%%%c")" to " +LUA_QL("format"),*(strfrmt-1)); +} +} +luaL_addlstring(&b,buff,strlen(buff)); +} +} +luaL_pushresult(&b); +return 1; +} +static const luaL_Reg strlib[]={ +{"byte",str_byte}, +{"char",str_char}, +{"find",str_find}, +{"format",str_format}, +{"gmatch",gmatch}, +{"gsub",str_gsub}, +{"lower",str_lower}, +{"match",str_match}, +{"rep",str_rep}, +{"sub",str_sub}, +{"upper",str_upper}, +{NULL,NULL} +}; +static void createmetatable(lua_State*L){ +lua_createtable(L,0,1); +lua_pushliteral(L,""); +lua_pushvalue(L,-2); +lua_setmetatable(L,-2); +lua_pop(L,1); +lua_pushvalue(L,-2); +lua_setfield(L,-2,"__index"); +lua_pop(L,1); +} +static int luaopen_string(lua_State*L){ +luaL_register(L,"string",strlib); +createmetatable(L); +return 1; +} +static const luaL_Reg lualibs[]={ +{"",luaopen_base}, +{"table",luaopen_table}, +{"io",luaopen_io}, +{"os",luaopen_os}, +{"string",luaopen_string}, +{NULL,NULL} +}; +static void luaL_openlibs(lua_State*L){ +const luaL_Reg*lib=lualibs; +for(;lib->func;lib++){ +lua_pushcfunction(L,lib->func); +lua_pushstring(L,lib->name); +lua_call(L,1,0); +} +} +typedef unsigned int UB; +static UB barg(lua_State*L,int idx){ +union{lua_Number n;U64 b;}bn; +bn.n=lua_tonumber(L,idx)+6755399441055744.0; +if(bn.n==0.0&&!lua_isnumber(L,idx))luaL_typerror(L,idx,"number"); +return(UB)bn.b; +} +#define BRET(b)lua_pushnumber(L,(lua_Number)(int)(b));return 1; +static int tobit(lua_State*L){ +BRET(barg(L,1))} +static int bnot(lua_State*L){ +BRET(~barg(L,1))} +static int band(lua_State*L){ +int i;UB b=barg(L,1);for(i=lua_gettop(L);i>1;i--)b&=barg(L,i);BRET(b)} +static int bor(lua_State*L){ +int i;UB b=barg(L,1);for(i=lua_gettop(L);i>1;i--)b|=barg(L,i);BRET(b)} +static int bxor(lua_State*L){ +int i;UB b=barg(L,1);for(i=lua_gettop(L);i>1;i--)b^=barg(L,i);BRET(b)} +static int lshift(lua_State*L){ +UB b=barg(L,1),n=barg(L,2)&31;BRET(b<>n)} +static int arshift(lua_State*L){ +UB b=barg(L,1),n=barg(L,2)&31;BRET((int)b>>n)} +static int rol(lua_State*L){ +UB b=barg(L,1),n=barg(L,2)&31;BRET((b<>(32-n)))} +static int ror(lua_State*L){ +UB b=barg(L,1),n=barg(L,2)&31;BRET((b>>n)|(b<<(32-n)))} +static int bswap(lua_State*L){ +UB b=barg(L,1);b=(b>>24)|((b>>8)&0xff00)|((b&0xff00)<<8)|(b<<24);BRET(b)} +static int tohex(lua_State*L){ +UB b=barg(L,1); +int n=lua_isnone(L,2)?8:(int)barg(L,2); +const char*hexdigits="0123456789abcdef"; +char buf[8]; +int i; +if(n<0){n=-n;hexdigits="0123456789ABCDEF";} +if(n>8)n=8; +for(i=(int)n;--i>=0;){buf[i]=hexdigits[b&15];b>>=4;} +lua_pushlstring(L,buf,(size_t)n); +return 1; +} +static const struct luaL_Reg bitlib[]={ +{"tobit",tobit}, +{"bnot",bnot}, +{"band",band}, +{"bor",bor}, +{"bxor",bxor}, +{"lshift",lshift}, +{"rshift",rshift}, +{"arshift",arshift}, +{"rol",rol}, +{"ror",ror}, +{"bswap",bswap}, +{"tohex",tohex}, +{NULL,NULL} +}; +int main(int argc,char**argv){ +lua_State*L=luaL_newstate(); +int i; +luaL_openlibs(L); +luaL_register(L,"bit",bitlib); +if(argc<2)return sizeof(void*); +lua_createtable(L,0,1); +lua_pushstring(L,argv[1]); +lua_rawseti(L,-2,0); +lua_setglobal(L,"arg"); +if(luaL_loadfile(L,argv[1])) +goto err; +for(i=2;i -- BYTECODE -- [...] +-- print(bc.line(foo, 2)) --> 0002 KSTR 1 1 ; "hello" +-- +-- local out = { +-- -- Do something with each line: +-- write = function(t, ...) io.write(...) end, +-- close = function(t) end, +-- flush = function(t) end, +-- } +-- bc.dump(foo, out) +-- +------------------------------------------------------------------------------ + +-- Cache some library functions and objects. +local jit = require("jit") +assert(jit.version_num == 20100, "LuaJIT core/library version mismatch") +local jutil = require("jit.util") +local vmdef = require("jit.vmdef") +local bit = require("bit") +local sub, gsub, format = string.sub, string.gsub, string.format +local byte, band, shr = string.byte, bit.band, bit.rshift +local funcinfo, funcbc, funck = jutil.funcinfo, jutil.funcbc, jutil.funck +local funcuvname = jutil.funcuvname +local bcnames = vmdef.bcnames +local stdout, stderr = io.stdout, io.stderr + +------------------------------------------------------------------------------ + +local function ctlsub(c) + if c == "\n" then return "\\n" + elseif c == "\r" then return "\\r" + elseif c == "\t" then return "\\t" + else return format("\\%03d", byte(c)) + end +end + +-- Return one bytecode line. +local function bcline(func, pc, prefix) + local ins, m = funcbc(func, pc) + if not ins then return end + local ma, mb, mc = band(m, 7), band(m, 15*8), band(m, 15*128) + local a = band(shr(ins, 8), 0xff) + local oidx = 6*band(ins, 0xff) + local op = sub(bcnames, oidx+1, oidx+6) + local s = format("%04d %s %-6s %3s ", + pc, prefix or " ", op, ma == 0 and "" or a) + local d = shr(ins, 16) + if mc == 13*128 then -- BCMjump + return format("%s=> %04d\n", s, pc+d-0x7fff) + end + if mb ~= 0 then + d = band(d, 0xff) + elseif mc == 0 then + return s.."\n" + end + local kc + if mc == 10*128 then -- BCMstr + kc = funck(func, -d-1) + kc = format(#kc > 40 and '"%.40s"~' or '"%s"', gsub(kc, "%c", ctlsub)) + elseif mc == 9*128 then -- BCMnum + kc = funck(func, d) + if op == "TSETM " then kc = kc - 2^52 end + elseif mc == 12*128 then -- BCMfunc + local fi = funcinfo(funck(func, -d-1)) + if fi.ffid then + kc = vmdef.ffnames[fi.ffid] + else + kc = fi.loc + end + elseif mc == 5*128 then -- BCMuv + kc = funcuvname(func, d) + end + if ma == 5 then -- BCMuv + local ka = funcuvname(func, a) + if kc then kc = ka.." ; "..kc else kc = ka end + end + if mb ~= 0 then + local b = shr(ins, 24) + if kc then return format("%s%3d %3d ; %s\n", s, b, d, kc) end + return format("%s%3d %3d\n", s, b, d) + end + if kc then return format("%s%3d ; %s\n", s, d, kc) end + if mc == 7*128 and d > 32767 then d = d - 65536 end -- BCMlits + return format("%s%3d\n", s, d) +end + +-- Collect branch targets of a function. +local function bctargets(func) + local target = {} + for pc=1,1000000000 do + local ins, m = funcbc(func, pc) + if not ins then break end + if band(m, 15*128) == 13*128 then target[pc+shr(ins, 16)-0x7fff] = true end + end + return target +end + +-- Dump bytecode instructions of a function. +local function bcdump(func, out, all) + if not out then out = stdout end + local fi = funcinfo(func) + if all and fi.children then + for n=-1,-1000000000,-1 do + local k = funck(func, n) + if not k then break end + if type(k) == "proto" then bcdump(k, out, true) end + end + end + out:write(format("-- BYTECODE -- %s-%d\n", fi.loc, fi.lastlinedefined)) + local target = bctargets(func) + for pc=1,1000000000 do + local s = bcline(func, pc, target[pc] and "=>") + if not s then break end + out:write(s) + end + out:write("\n") + out:flush() +end + +------------------------------------------------------------------------------ + +-- Active flag and output file handle. +local active, out + +-- List handler. +local function h_list(func) + return bcdump(func, out) +end + +-- Detach list handler. +local function bclistoff() + if active then + active = false + jit.attach(h_list) + if out and out ~= stdout and out ~= stderr then out:close() end + out = nil + end +end + +-- Open the output file and attach list handler. +local function bcliston(outfile) + if active then bclistoff() end + if not outfile then outfile = os.getenv("LUAJIT_LISTFILE") end + if outfile then + out = outfile == "-" and stdout or assert(io.open(outfile, "w")) + else + out = stderr + end + jit.attach(h_list, "bc") + active = true +end + +-- Public module functions. +return { + line = bcline, + dump = bcdump, + targets = bctargets, + on = bcliston, + off = bclistoff, + start = bcliston -- For -j command line option. +} + diff --git a/fluent-bit/lib/luajit-3065c9/src/jit/bcsave.lua b/fluent-bit/lib/luajit-3065c9/src/jit/bcsave.lua new file mode 100644 index 00000000..f8ed3a1b --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/jit/bcsave.lua @@ -0,0 +1,690 @@ +---------------------------------------------------------------------------- +-- LuaJIT module to save/list bytecode. +-- +-- Copyright (C) 2005-2022 Mike Pall. All rights reserved. +-- Released under the MIT license. See Copyright Notice in luajit.h +---------------------------------------------------------------------------- +-- +-- This module saves or lists the bytecode for an input file. +-- It's run by the -b command line option. +-- +------------------------------------------------------------------------------ + +local jit = require("jit") +assert(jit.version_num == 20100, "LuaJIT core/library version mismatch") +local bit = require("bit") + +-- Symbol name prefix for LuaJIT bytecode. +local LJBC_PREFIX = "luaJIT_BC_" + +local type, assert = type, assert +local format = string.format +local tremove, tconcat = table.remove, table.concat + +------------------------------------------------------------------------------ + +local function usage() + io.stderr:write[[ +Save LuaJIT bytecode: luajit -b[options] input output + -l Only list bytecode. + -s Strip debug info (default). + -g Keep debug info. + -n name Set module name (default: auto-detect from input name). + -t type Set output file type (default: auto-detect from output name). + -a arch Override architecture for object files (default: native). + -o os Override OS for object files (default: native). + -e chunk Use chunk string as input. + -- Stop handling options. + - Use stdin as input and/or stdout as output. + +File types: c h obj o raw (default) +]] + os.exit(1) +end + +local function check(ok, ...) + if ok then return ok, ... end + io.stderr:write("luajit: ", ...) + io.stderr:write("\n") + os.exit(1) +end + +local function readfile(input) + if type(input) == "function" then return input end + if input == "-" then input = nil end + return check(loadfile(input)) +end + +local function savefile(name, mode) + if name == "-" then return io.stdout end + return check(io.open(name, mode)) +end + +local function set_stdout_binary(ffi) + ffi.cdef[[int _setmode(int fd, int mode);]] + ffi.C._setmode(1, 0x8000) +end + +------------------------------------------------------------------------------ + +local map_type = { + raw = "raw", c = "c", h = "h", o = "obj", obj = "obj", +} + +local map_arch = { + x86 = { e = "le", b = 32, m = 3, p = 0x14c, }, + x64 = { e = "le", b = 64, m = 62, p = 0x8664, }, + arm = { e = "le", b = 32, m = 40, p = 0x1c0, }, + arm64 = { e = "le", b = 64, m = 183, p = 0xaa64, }, + arm64be = { e = "be", b = 64, m = 183, }, + ppc = { e = "be", b = 32, m = 20, }, + mips = { e = "be", b = 32, m = 8, f = 0x50001006, }, + mipsel = { e = "le", b = 32, m = 8, f = 0x50001006, }, + mips64 = { e = "be", b = 64, m = 8, f = 0x80000007, }, + mips64el = { e = "le", b = 64, m = 8, f = 0x80000007, }, + mips64r6 = { e = "be", b = 64, m = 8, f = 0xa0000407, }, + mips64r6el = { e = "le", b = 64, m = 8, f = 0xa0000407, }, +} + +local map_os = { + linux = true, windows = true, osx = true, freebsd = true, netbsd = true, + openbsd = true, dragonfly = true, solaris = true, +} + +local function checkarg(str, map, err) + str = str:lower() + local s = check(map[str], "unknown ", err) + return type(s) == "string" and s or str +end + +local function detecttype(str) + local ext = str:lower():match("%.(%a+)$") + return map_type[ext] or "raw" +end + +local function checkmodname(str) + check(str:match("^[%w_.%-]+$"), "bad module name") + return str:gsub("[%.%-]", "_") +end + +local function detectmodname(str) + if type(str) == "string" then + local tail = str:match("[^/\\]+$") + if tail then str = tail end + local head = str:match("^(.*)%.[^.]*$") + if head then str = head end + str = str:match("^[%w_.%-]+") + else + str = nil + end + check(str, "cannot derive module name, use -n name") + return str:gsub("[%.%-]", "_") +end + +------------------------------------------------------------------------------ + +local function bcsave_tail(fp, output, s) + local ok, err = fp:write(s) + if ok and output ~= "-" then ok, err = fp:close() end + check(ok, "cannot write ", output, ": ", err) +end + +local function bcsave_raw(output, s) + if output == "-" and jit.os == "Windows" then + local ok, ffi = pcall(require, "ffi") + check(ok, "FFI library required to write binary file to stdout") + set_stdout_binary(ffi) + end + local fp = savefile(output, "wb") + bcsave_tail(fp, output, s) +end + +local function bcsave_c(ctx, output, s) + local fp = savefile(output, "w") + if ctx.type == "c" then + fp:write(format([[ +#ifdef __cplusplus +extern "C" +#endif +#ifdef _WIN32 +__declspec(dllexport) +#endif +const unsigned char %s%s[] = { +]], LJBC_PREFIX, ctx.modname)) + else + fp:write(format([[ +#define %s%s_SIZE %d +static const unsigned char %s%s[] = { +]], LJBC_PREFIX, ctx.modname, #s, LJBC_PREFIX, ctx.modname)) + end + local t, n, m = {}, 0, 0 + for i=1,#s do + local b = tostring(string.byte(s, i)) + m = m + #b + 1 + if m > 78 then + fp:write(tconcat(t, ",", 1, n), ",\n") + n, m = 0, #b + 1 + end + n = n + 1 + t[n] = b + end + bcsave_tail(fp, output, tconcat(t, ",", 1, n).."\n};\n") +end + +local function bcsave_elfobj(ctx, output, s, ffi) + ffi.cdef[[ +typedef struct { + uint8_t emagic[4], eclass, eendian, eversion, eosabi, eabiversion, epad[7]; + uint16_t type, machine; + uint32_t version; + uint32_t entry, phofs, shofs; + uint32_t flags; + uint16_t ehsize, phentsize, phnum, shentsize, shnum, shstridx; +} ELF32header; +typedef struct { + uint8_t emagic[4], eclass, eendian, eversion, eosabi, eabiversion, epad[7]; + uint16_t type, machine; + uint32_t version; + uint64_t entry, phofs, shofs; + uint32_t flags; + uint16_t ehsize, phentsize, phnum, shentsize, shnum, shstridx; +} ELF64header; +typedef struct { + uint32_t name, type, flags, addr, ofs, size, link, info, align, entsize; +} ELF32sectheader; +typedef struct { + uint32_t name, type; + uint64_t flags, addr, ofs, size; + uint32_t link, info; + uint64_t align, entsize; +} ELF64sectheader; +typedef struct { + uint32_t name, value, size; + uint8_t info, other; + uint16_t sectidx; +} ELF32symbol; +typedef struct { + uint32_t name; + uint8_t info, other; + uint16_t sectidx; + uint64_t value, size; +} ELF64symbol; +typedef struct { + ELF32header hdr; + ELF32sectheader sect[6]; + ELF32symbol sym[2]; + uint8_t space[4096]; +} ELF32obj; +typedef struct { + ELF64header hdr; + ELF64sectheader sect[6]; + ELF64symbol sym[2]; + uint8_t space[4096]; +} ELF64obj; +]] + local symname = LJBC_PREFIX..ctx.modname + local ai = assert(map_arch[ctx.arch]) + local is64, isbe = ai.b == 64, ai.e == "be" + + -- Handle different host/target endianess. + local function f32(x) return x end + local f16, fofs = f32, f32 + if ffi.abi("be") ~= isbe then + f32 = bit.bswap + function f16(x) return bit.rshift(bit.bswap(x), 16) end + if is64 then + local two32 = ffi.cast("int64_t", 2^32) + function fofs(x) return bit.bswap(x)*two32 end + else + fofs = f32 + end + end + + -- Create ELF object and fill in header. + local o = ffi.new(is64 and "ELF64obj" or "ELF32obj") + local hdr = o.hdr + if ctx.os == "bsd" or ctx.os == "other" then -- Determine native hdr.eosabi. + local bf = assert(io.open("/bin/ls", "rb")) + local bs = bf:read(9) + bf:close() + ffi.copy(o, bs, 9) + check(hdr.emagic[0] == 127, "no support for writing native object files") + else + hdr.emagic = "\127ELF" + hdr.eosabi = ({ freebsd=9, netbsd=2, openbsd=12, solaris=6 })[ctx.os] or 0 + end + hdr.eclass = is64 and 2 or 1 + hdr.eendian = isbe and 2 or 1 + hdr.eversion = 1 + hdr.type = f16(1) + hdr.machine = f16(ai.m) + hdr.flags = f32(ai.f or 0) + hdr.version = f32(1) + hdr.shofs = fofs(ffi.offsetof(o, "sect")) + hdr.ehsize = f16(ffi.sizeof(hdr)) + hdr.shentsize = f16(ffi.sizeof(o.sect[0])) + hdr.shnum = f16(6) + hdr.shstridx = f16(2) + + -- Fill in sections and symbols. + local sofs, ofs = ffi.offsetof(o, "space"), 1 + for i,name in ipairs{ + ".symtab", ".shstrtab", ".strtab", ".rodata", ".note.GNU-stack", + } do + local sect = o.sect[i] + sect.align = fofs(1) + sect.name = f32(ofs) + ffi.copy(o.space+ofs, name) + ofs = ofs + #name+1 + end + o.sect[1].type = f32(2) -- .symtab + o.sect[1].link = f32(3) + o.sect[1].info = f32(1) + o.sect[1].align = fofs(8) + o.sect[1].ofs = fofs(ffi.offsetof(o, "sym")) + o.sect[1].entsize = fofs(ffi.sizeof(o.sym[0])) + o.sect[1].size = fofs(ffi.sizeof(o.sym)) + o.sym[1].name = f32(1) + o.sym[1].sectidx = f16(4) + o.sym[1].size = fofs(#s) + o.sym[1].info = 17 + o.sect[2].type = f32(3) -- .shstrtab + o.sect[2].ofs = fofs(sofs) + o.sect[2].size = fofs(ofs) + o.sect[3].type = f32(3) -- .strtab + o.sect[3].ofs = fofs(sofs + ofs) + o.sect[3].size = fofs(#symname+2) + ffi.copy(o.space+ofs+1, symname) + ofs = ofs + #symname + 2 + o.sect[4].type = f32(1) -- .rodata + o.sect[4].flags = fofs(2) + o.sect[4].ofs = fofs(sofs + ofs) + o.sect[4].size = fofs(#s) + o.sect[5].type = f32(1) -- .note.GNU-stack + o.sect[5].ofs = fofs(sofs + ofs + #s) + + -- Write ELF object file. + local fp = savefile(output, "wb") + fp:write(ffi.string(o, ffi.sizeof(o)-4096+ofs)) + bcsave_tail(fp, output, s) +end + +local function bcsave_peobj(ctx, output, s, ffi) + ffi.cdef[[ +typedef struct { + uint16_t arch, nsects; + uint32_t time, symtabofs, nsyms; + uint16_t opthdrsz, flags; +} PEheader; +typedef struct { + char name[8]; + uint32_t vsize, vaddr, size, ofs, relocofs, lineofs; + uint16_t nreloc, nline; + uint32_t flags; +} PEsection; +typedef struct __attribute((packed)) { + union { + char name[8]; + uint32_t nameref[2]; + }; + uint32_t value; + int16_t sect; + uint16_t type; + uint8_t scl, naux; +} PEsym; +typedef struct __attribute((packed)) { + uint32_t size; + uint16_t nreloc, nline; + uint32_t cksum; + uint16_t assoc; + uint8_t comdatsel, unused[3]; +} PEsymaux; +typedef struct { + PEheader hdr; + PEsection sect[2]; + // Must be an even number of symbol structs. + PEsym sym0; + PEsymaux sym0aux; + PEsym sym1; + PEsymaux sym1aux; + PEsym sym2; + PEsym sym3; + uint32_t strtabsize; + uint8_t space[4096]; +} PEobj; +]] + local symname = LJBC_PREFIX..ctx.modname + local ai = assert(map_arch[ctx.arch]) + local is64 = ai.b == 64 + local symexport = " /EXPORT:"..symname..",DATA " + + -- The file format is always little-endian. Swap if the host is big-endian. + local function f32(x) return x end + local f16 = f32 + if ffi.abi("be") then + f32 = bit.bswap + function f16(x) return bit.rshift(bit.bswap(x), 16) end + end + + -- Create PE object and fill in header. + local o = ffi.new("PEobj") + local hdr = o.hdr + hdr.arch = f16(assert(ai.p)) + hdr.nsects = f16(2) + hdr.symtabofs = f32(ffi.offsetof(o, "sym0")) + hdr.nsyms = f32(6) + + -- Fill in sections and symbols. + o.sect[0].name = ".drectve" + o.sect[0].size = f32(#symexport) + o.sect[0].flags = f32(0x00100a00) + o.sym0.sect = f16(1) + o.sym0.scl = 3 + o.sym0.name = ".drectve" + o.sym0.naux = 1 + o.sym0aux.size = f32(#symexport) + o.sect[1].name = ".rdata" + o.sect[1].size = f32(#s) + o.sect[1].flags = f32(0x40300040) + o.sym1.sect = f16(2) + o.sym1.scl = 3 + o.sym1.name = ".rdata" + o.sym1.naux = 1 + o.sym1aux.size = f32(#s) + o.sym2.sect = f16(2) + o.sym2.scl = 2 + o.sym2.nameref[1] = f32(4) + o.sym3.sect = f16(-1) + o.sym3.scl = 2 + o.sym3.value = f32(1) + o.sym3.name = "@feat.00" -- Mark as SafeSEH compliant. + ffi.copy(o.space, symname) + local ofs = #symname + 1 + o.strtabsize = f32(ofs + 4) + o.sect[0].ofs = f32(ffi.offsetof(o, "space") + ofs) + ffi.copy(o.space + ofs, symexport) + ofs = ofs + #symexport + o.sect[1].ofs = f32(ffi.offsetof(o, "space") + ofs) + + -- Write PE object file. + local fp = savefile(output, "wb") + fp:write(ffi.string(o, ffi.sizeof(o)-4096+ofs)) + bcsave_tail(fp, output, s) +end + +local function bcsave_machobj(ctx, output, s, ffi) + ffi.cdef[[ +typedef struct +{ + uint32_t magic, cputype, cpusubtype, filetype, ncmds, sizeofcmds, flags; +} mach_header; +typedef struct +{ + mach_header; uint32_t reserved; +} mach_header_64; +typedef struct { + uint32_t cmd, cmdsize; + char segname[16]; + uint32_t vmaddr, vmsize, fileoff, filesize; + uint32_t maxprot, initprot, nsects, flags; +} mach_segment_command; +typedef struct { + uint32_t cmd, cmdsize; + char segname[16]; + uint64_t vmaddr, vmsize, fileoff, filesize; + uint32_t maxprot, initprot, nsects, flags; +} mach_segment_command_64; +typedef struct { + char sectname[16], segname[16]; + uint32_t addr, size; + uint32_t offset, align, reloff, nreloc, flags; + uint32_t reserved1, reserved2; +} mach_section; +typedef struct { + char sectname[16], segname[16]; + uint64_t addr, size; + uint32_t offset, align, reloff, nreloc, flags; + uint32_t reserved1, reserved2, reserved3; +} mach_section_64; +typedef struct { + uint32_t cmd, cmdsize, symoff, nsyms, stroff, strsize; +} mach_symtab_command; +typedef struct { + int32_t strx; + uint8_t type, sect; + int16_t desc; + uint32_t value; +} mach_nlist; +typedef struct { + int32_t strx; + uint8_t type, sect; + uint16_t desc; + uint64_t value; +} mach_nlist_64; +typedef struct +{ + int32_t magic, nfat_arch; +} mach_fat_header; +typedef struct +{ + int32_t cputype, cpusubtype, offset, size, align; +} mach_fat_arch; +typedef struct { + struct { + mach_header hdr; + mach_segment_command seg; + mach_section sec; + mach_symtab_command sym; + } arch[1]; + mach_nlist sym_entry; + uint8_t space[4096]; +} mach_obj; +typedef struct { + struct { + mach_header_64 hdr; + mach_segment_command_64 seg; + mach_section_64 sec; + mach_symtab_command sym; + } arch[1]; + mach_nlist_64 sym_entry; + uint8_t space[4096]; +} mach_obj_64; +typedef struct { + mach_fat_header fat; + mach_fat_arch fat_arch[2]; + struct { + mach_header hdr; + mach_segment_command seg; + mach_section sec; + mach_symtab_command sym; + } arch[2]; + mach_nlist sym_entry; + uint8_t space[4096]; +} mach_fat_obj; +typedef struct { + mach_fat_header fat; + mach_fat_arch fat_arch[2]; + struct { + mach_header_64 hdr; + mach_segment_command_64 seg; + mach_section_64 sec; + mach_symtab_command sym; + } arch[2]; + mach_nlist_64 sym_entry; + uint8_t space[4096]; +} mach_fat_obj_64; +]] + local symname = '_'..LJBC_PREFIX..ctx.modname + local isfat, is64, align, mobj = false, false, 4, "mach_obj" + if ctx.arch == "x64" then + is64, align, mobj = true, 8, "mach_obj_64" + elseif ctx.arch == "arm" then + isfat, mobj = true, "mach_fat_obj" + elseif ctx.arch == "arm64" then + is64, align, isfat, mobj = true, 8, true, "mach_fat_obj_64" + else + check(ctx.arch == "x86", "unsupported architecture for OSX") + end + local function aligned(v, a) return bit.band(v+a-1, -a) end + local be32 = bit.bswap -- Mach-O FAT is BE, supported archs are LE. + + -- Create Mach-O object and fill in header. + local o = ffi.new(mobj) + local mach_size = aligned(ffi.offsetof(o, "space")+#symname+2, align) + local cputype = ({ x86={7}, x64={0x01000007}, arm={7,12}, arm64={0x01000007,0x0100000c} })[ctx.arch] + local cpusubtype = ({ x86={3}, x64={3}, arm={3,9}, arm64={3,0} })[ctx.arch] + if isfat then + o.fat.magic = be32(0xcafebabe) + o.fat.nfat_arch = be32(#cpusubtype) + end + + -- Fill in sections and symbols. + for i=0,#cpusubtype-1 do + local ofs = 0 + if isfat then + local a = o.fat_arch[i] + a.cputype = be32(cputype[i+1]) + a.cpusubtype = be32(cpusubtype[i+1]) + -- Subsequent slices overlap each other to share data. + ofs = ffi.offsetof(o, "arch") + i*ffi.sizeof(o.arch[0]) + a.offset = be32(ofs) + a.size = be32(mach_size-ofs+#s) + end + local a = o.arch[i] + a.hdr.magic = is64 and 0xfeedfacf or 0xfeedface + a.hdr.cputype = cputype[i+1] + a.hdr.cpusubtype = cpusubtype[i+1] + a.hdr.filetype = 1 + a.hdr.ncmds = 2 + a.hdr.sizeofcmds = ffi.sizeof(a.seg)+ffi.sizeof(a.sec)+ffi.sizeof(a.sym) + a.seg.cmd = is64 and 0x19 or 0x1 + a.seg.cmdsize = ffi.sizeof(a.seg)+ffi.sizeof(a.sec) + a.seg.vmsize = #s + a.seg.fileoff = mach_size-ofs + a.seg.filesize = #s + a.seg.maxprot = 1 + a.seg.initprot = 1 + a.seg.nsects = 1 + ffi.copy(a.sec.sectname, "__data") + ffi.copy(a.sec.segname, "__DATA") + a.sec.size = #s + a.sec.offset = mach_size-ofs + a.sym.cmd = 2 + a.sym.cmdsize = ffi.sizeof(a.sym) + a.sym.symoff = ffi.offsetof(o, "sym_entry")-ofs + a.sym.nsyms = 1 + a.sym.stroff = ffi.offsetof(o, "sym_entry")+ffi.sizeof(o.sym_entry)-ofs + a.sym.strsize = aligned(#symname+2, align) + end + o.sym_entry.type = 0xf + o.sym_entry.sect = 1 + o.sym_entry.strx = 1 + ffi.copy(o.space+1, symname) + + -- Write Macho-O object file. + local fp = savefile(output, "wb") + fp:write(ffi.string(o, mach_size)) + bcsave_tail(fp, output, s) +end + +local function bcsave_obj(ctx, output, s) + local ok, ffi = pcall(require, "ffi") + check(ok, "FFI library required to write this file type") + if output == "-" and jit.os == "Windows" then + set_stdout_binary(ffi) + end + if ctx.os == "windows" then + return bcsave_peobj(ctx, output, s, ffi) + elseif ctx.os == "osx" then + return bcsave_machobj(ctx, output, s, ffi) + else + return bcsave_elfobj(ctx, output, s, ffi) + end +end + +------------------------------------------------------------------------------ + +local function bclist(input, output) + local f = readfile(input) + require("jit.bc").dump(f, savefile(output, "w"), true) +end + +local function bcsave(ctx, input, output) + local f = readfile(input) + local s = string.dump(f, ctx.strip) + local t = ctx.type + if not t then + t = detecttype(output) + ctx.type = t + end + if t == "raw" then + bcsave_raw(output, s) + else + if not ctx.modname then ctx.modname = detectmodname(input) end + if t == "obj" then + bcsave_obj(ctx, output, s) + else + bcsave_c(ctx, output, s) + end + end +end + +local function docmd(...) + local arg = {...} + local n = 1 + local list = false + local ctx = { + strip = true, arch = jit.arch, os = jit.os:lower(), + type = false, modname = false, + } + while n <= #arg do + local a = arg[n] + if type(a) == "string" and a:sub(1, 1) == "-" and a ~= "-" then + tremove(arg, n) + if a == "--" then break end + for m=2,#a do + local opt = a:sub(m, m) + if opt == "l" then + list = true + elseif opt == "s" then + ctx.strip = true + elseif opt == "g" then + ctx.strip = false + else + if arg[n] == nil or m ~= #a then usage() end + if opt == "e" then + if n ~= 1 then usage() end + arg[1] = check(loadstring(arg[1])) + elseif opt == "n" then + ctx.modname = checkmodname(tremove(arg, n)) + elseif opt == "t" then + ctx.type = checkarg(tremove(arg, n), map_type, "file type") + elseif opt == "a" then + ctx.arch = checkarg(tremove(arg, n), map_arch, "architecture") + elseif opt == "o" then + ctx.os = checkarg(tremove(arg, n), map_os, "OS name") + else + usage() + end + end + end + else + n = n + 1 + end + end + if list then + if #arg == 0 or #arg > 2 then usage() end + bclist(arg[1], arg[2] or "-") + else + if #arg ~= 2 then usage() end + bcsave(ctx, arg[1], arg[2]) + end +end + +------------------------------------------------------------------------------ + +-- Public module functions. +return { + start = docmd -- Process -b command line option. +} + diff --git a/fluent-bit/lib/luajit-3065c9/src/jit/dis_arm.lua b/fluent-bit/lib/luajit-3065c9/src/jit/dis_arm.lua new file mode 100644 index 00000000..18ab68df --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/jit/dis_arm.lua @@ -0,0 +1,689 @@ +---------------------------------------------------------------------------- +-- LuaJIT ARM disassembler module. +-- +-- Copyright (C) 2005-2022 Mike Pall. All rights reserved. +-- Released under the MIT license. See Copyright Notice in luajit.h +---------------------------------------------------------------------------- +-- This is a helper module used by the LuaJIT machine code dumper module. +-- +-- It disassembles most user-mode ARMv7 instructions +-- NYI: Advanced SIMD and VFP instructions. +------------------------------------------------------------------------------ + +local type = type +local sub, byte, format = string.sub, string.byte, string.format +local match, gmatch = string.match, string.gmatch +local concat = table.concat +local bit = require("bit") +local band, bor, ror, tohex = bit.band, bit.bor, bit.ror, bit.tohex +local lshift, rshift, arshift = bit.lshift, bit.rshift, bit.arshift + +------------------------------------------------------------------------------ +-- Opcode maps +------------------------------------------------------------------------------ + +local map_loadc = { + shift = 8, mask = 15, + [10] = { + shift = 20, mask = 1, + [0] = { + shift = 23, mask = 3, + [0] = "vmovFmDN", "vstmFNdr", + _ = { + shift = 21, mask = 1, + [0] = "vstrFdl", + { shift = 16, mask = 15, [13] = "vpushFdr", _ = "vstmdbFNdr", } + }, + }, + { + shift = 23, mask = 3, + [0] = "vmovFDNm", + { shift = 16, mask = 15, [13] = "vpopFdr", _ = "vldmFNdr", }, + _ = { + shift = 21, mask = 1, + [0] = "vldrFdl", "vldmdbFNdr", + }, + }, + }, + [11] = { + shift = 20, mask = 1, + [0] = { + shift = 23, mask = 3, + [0] = "vmovGmDN", "vstmGNdr", + _ = { + shift = 21, mask = 1, + [0] = "vstrGdl", + { shift = 16, mask = 15, [13] = "vpushGdr", _ = "vstmdbGNdr", } + }, + }, + { + shift = 23, mask = 3, + [0] = "vmovGDNm", + { shift = 16, mask = 15, [13] = "vpopGdr", _ = "vldmGNdr", }, + _ = { + shift = 21, mask = 1, + [0] = "vldrGdl", "vldmdbGNdr", + }, + }, + }, + _ = { + shift = 0, mask = 0 -- NYI ldc, mcrr, mrrc. + }, +} + +local map_vfps = { + shift = 6, mask = 0x2c001, + [0] = "vmlaF.dnm", "vmlsF.dnm", + [0x04000] = "vnmlsF.dnm", [0x04001] = "vnmlaF.dnm", + [0x08000] = "vmulF.dnm", [0x08001] = "vnmulF.dnm", + [0x0c000] = "vaddF.dnm", [0x0c001] = "vsubF.dnm", + [0x20000] = "vdivF.dnm", + [0x24000] = "vfnmsF.dnm", [0x24001] = "vfnmaF.dnm", + [0x28000] = "vfmaF.dnm", [0x28001] = "vfmsF.dnm", + [0x2c000] = "vmovF.dY", + [0x2c001] = { + shift = 7, mask = 0x1e01, + [0] = "vmovF.dm", "vabsF.dm", + [0x0200] = "vnegF.dm", [0x0201] = "vsqrtF.dm", + [0x0800] = "vcmpF.dm", [0x0801] = "vcmpeF.dm", + [0x0a00] = "vcmpzF.d", [0x0a01] = "vcmpzeF.d", + [0x0e01] = "vcvtG.dF.m", + [0x1000] = "vcvt.f32.u32Fdm", [0x1001] = "vcvt.f32.s32Fdm", + [0x1800] = "vcvtr.u32F.dm", [0x1801] = "vcvt.u32F.dm", + [0x1a00] = "vcvtr.s32F.dm", [0x1a01] = "vcvt.s32F.dm", + }, +} + +local map_vfpd = { + shift = 6, mask = 0x2c001, + [0] = "vmlaG.dnm", "vmlsG.dnm", + [0x04000] = "vnmlsG.dnm", [0x04001] = "vnmlaG.dnm", + [0x08000] = "vmulG.dnm", [0x08001] = "vnmulG.dnm", + [0x0c000] = "vaddG.dnm", [0x0c001] = "vsubG.dnm", + [0x20000] = "vdivG.dnm", + [0x24000] = "vfnmsG.dnm", [0x24001] = "vfnmaG.dnm", + [0x28000] = "vfmaG.dnm", [0x28001] = "vfmsG.dnm", + [0x2c000] = "vmovG.dY", + [0x2c001] = { + shift = 7, mask = 0x1e01, + [0] = "vmovG.dm", "vabsG.dm", + [0x0200] = "vnegG.dm", [0x0201] = "vsqrtG.dm", + [0x0800] = "vcmpG.dm", [0x0801] = "vcmpeG.dm", + [0x0a00] = "vcmpzG.d", [0x0a01] = "vcmpzeG.d", + [0x0e01] = "vcvtF.dG.m", + [0x1000] = "vcvt.f64.u32GdFm", [0x1001] = "vcvt.f64.s32GdFm", + [0x1800] = "vcvtr.u32FdG.m", [0x1801] = "vcvt.u32FdG.m", + [0x1a00] = "vcvtr.s32FdG.m", [0x1a01] = "vcvt.s32FdG.m", + }, +} + +local map_datac = { + shift = 24, mask = 1, + [0] = { + shift = 4, mask = 1, + [0] = { + shift = 8, mask = 15, + [10] = map_vfps, + [11] = map_vfpd, + -- NYI cdp, mcr, mrc. + }, + { + shift = 8, mask = 15, + [10] = { + shift = 20, mask = 15, + [0] = "vmovFnD", "vmovFDn", + [14] = "vmsrD", + [15] = { shift = 12, mask = 15, [15] = "vmrs", _ = "vmrsD", }, + }, + }, + }, + "svcT", +} + +local map_loadcu = { + shift = 0, mask = 0, -- NYI unconditional CP load/store. +} + +local map_datacu = { + shift = 0, mask = 0, -- NYI unconditional CP data. +} + +local map_simddata = { + shift = 0, mask = 0, -- NYI SIMD data. +} + +local map_simdload = { + shift = 0, mask = 0, -- NYI SIMD load/store, preload. +} + +local map_preload = { + shift = 0, mask = 0, -- NYI preload. +} + +local map_media = { + shift = 20, mask = 31, + [0] = false, + { --01 + shift = 5, mask = 7, + [0] = "sadd16DNM", "sasxDNM", "ssaxDNM", "ssub16DNM", + "sadd8DNM", false, false, "ssub8DNM", + }, + { --02 + shift = 5, mask = 7, + [0] = "qadd16DNM", "qasxDNM", "qsaxDNM", "qsub16DNM", + "qadd8DNM", false, false, "qsub8DNM", + }, + { --03 + shift = 5, mask = 7, + [0] = "shadd16DNM", "shasxDNM", "shsaxDNM", "shsub16DNM", + "shadd8DNM", false, false, "shsub8DNM", + }, + false, + { --05 + shift = 5, mask = 7, + [0] = "uadd16DNM", "uasxDNM", "usaxDNM", "usub16DNM", + "uadd8DNM", false, false, "usub8DNM", + }, + { --06 + shift = 5, mask = 7, + [0] = "uqadd16DNM", "uqasxDNM", "uqsaxDNM", "uqsub16DNM", + "uqadd8DNM", false, false, "uqsub8DNM", + }, + { --07 + shift = 5, mask = 7, + [0] = "uhadd16DNM", "uhasxDNM", "uhsaxDNM", "uhsub16DNM", + "uhadd8DNM", false, false, "uhsub8DNM", + }, + { --08 + shift = 5, mask = 7, + [0] = "pkhbtDNMU", false, "pkhtbDNMU", + { shift = 16, mask = 15, [15] = "sxtb16DMU", _ = "sxtab16DNMU", }, + "pkhbtDNMU", "selDNM", "pkhtbDNMU", + }, + false, + { --0a + shift = 5, mask = 7, + [0] = "ssatDxMu", "ssat16DxM", "ssatDxMu", + { shift = 16, mask = 15, [15] = "sxtbDMU", _ = "sxtabDNMU", }, + "ssatDxMu", false, "ssatDxMu", + }, + { --0b + shift = 5, mask = 7, + [0] = "ssatDxMu", "revDM", "ssatDxMu", + { shift = 16, mask = 15, [15] = "sxthDMU", _ = "sxtahDNMU", }, + "ssatDxMu", "rev16DM", "ssatDxMu", + }, + { --0c + shift = 5, mask = 7, + [3] = { shift = 16, mask = 15, [15] = "uxtb16DMU", _ = "uxtab16DNMU", }, + }, + false, + { --0e + shift = 5, mask = 7, + [0] = "usatDwMu", "usat16DwM", "usatDwMu", + { shift = 16, mask = 15, [15] = "uxtbDMU", _ = "uxtabDNMU", }, + "usatDwMu", false, "usatDwMu", + }, + { --0f + shift = 5, mask = 7, + [0] = "usatDwMu", "rbitDM", "usatDwMu", + { shift = 16, mask = 15, [15] = "uxthDMU", _ = "uxtahDNMU", }, + "usatDwMu", "revshDM", "usatDwMu", + }, + { --10 + shift = 12, mask = 15, + [15] = { + shift = 5, mask = 7, + "smuadNMS", "smuadxNMS", "smusdNMS", "smusdxNMS", + }, + _ = { + shift = 5, mask = 7, + [0] = "smladNMSD", "smladxNMSD", "smlsdNMSD", "smlsdxNMSD", + }, + }, + false, false, false, + { --14 + shift = 5, mask = 7, + [0] = "smlaldDNMS", "smlaldxDNMS", "smlsldDNMS", "smlsldxDNMS", + }, + { --15 + shift = 5, mask = 7, + [0] = { shift = 12, mask = 15, [15] = "smmulNMS", _ = "smmlaNMSD", }, + { shift = 12, mask = 15, [15] = "smmulrNMS", _ = "smmlarNMSD", }, + false, false, false, false, + "smmlsNMSD", "smmlsrNMSD", + }, + false, false, + { --18 + shift = 5, mask = 7, + [0] = { shift = 12, mask = 15, [15] = "usad8NMS", _ = "usada8NMSD", }, + }, + false, + { --1a + shift = 5, mask = 3, [2] = "sbfxDMvw", + }, + { --1b + shift = 5, mask = 3, [2] = "sbfxDMvw", + }, + { --1c + shift = 5, mask = 3, + [0] = { shift = 0, mask = 15, [15] = "bfcDvX", _ = "bfiDMvX", }, + }, + { --1d + shift = 5, mask = 3, + [0] = { shift = 0, mask = 15, [15] = "bfcDvX", _ = "bfiDMvX", }, + }, + { --1e + shift = 5, mask = 3, [2] = "ubfxDMvw", + }, + { --1f + shift = 5, mask = 3, [2] = "ubfxDMvw", + }, +} + +local map_load = { + shift = 21, mask = 9, + { + shift = 20, mask = 5, + [0] = "strtDL", "ldrtDL", [4] = "strbtDL", [5] = "ldrbtDL", + }, + _ = { + shift = 20, mask = 5, + [0] = "strDL", "ldrDL", [4] = "strbDL", [5] = "ldrbDL", + } +} + +local map_load1 = { + shift = 4, mask = 1, + [0] = map_load, map_media, +} + +local map_loadm = { + shift = 20, mask = 1, + [0] = { + shift = 23, mask = 3, + [0] = "stmdaNR", "stmNR", + { shift = 16, mask = 63, [45] = "pushR", _ = "stmdbNR", }, "stmibNR", + }, + { + shift = 23, mask = 3, + [0] = "ldmdaNR", { shift = 16, mask = 63, [61] = "popR", _ = "ldmNR", }, + "ldmdbNR", "ldmibNR", + }, +} + +local map_data = { + shift = 21, mask = 15, + [0] = "andDNPs", "eorDNPs", "subDNPs", "rsbDNPs", + "addDNPs", "adcDNPs", "sbcDNPs", "rscDNPs", + "tstNP", "teqNP", "cmpNP", "cmnNP", + "orrDNPs", "movDPs", "bicDNPs", "mvnDPs", +} + +local map_mul = { + shift = 21, mask = 7, + [0] = "mulNMSs", "mlaNMSDs", "umaalDNMS", "mlsDNMS", + "umullDNMSs", "umlalDNMSs", "smullDNMSs", "smlalDNMSs", +} + +local map_sync = { + shift = 20, mask = 15, -- NYI: brackets around N. R(D+1) for ldrexd/strexd. + [0] = "swpDMN", false, false, false, + "swpbDMN", false, false, false, + "strexDMN", "ldrexDN", "strexdDN", "ldrexdDN", + "strexbDMN", "ldrexbDN", "strexhDN", "ldrexhDN", +} + +local map_mulh = { + shift = 21, mask = 3, + [0] = { shift = 5, mask = 3, + [0] = "smlabbNMSD", "smlatbNMSD", "smlabtNMSD", "smlattNMSD", }, + { shift = 5, mask = 3, + [0] = "smlawbNMSD", "smulwbNMS", "smlawtNMSD", "smulwtNMS", }, + { shift = 5, mask = 3, + [0] = "smlalbbDNMS", "smlaltbDNMS", "smlalbtDNMS", "smlalttDNMS", }, + { shift = 5, mask = 3, + [0] = "smulbbNMS", "smultbNMS", "smulbtNMS", "smulttNMS", }, +} + +local map_misc = { + shift = 4, mask = 7, + -- NYI: decode PSR bits of msr. + [0] = { shift = 21, mask = 1, [0] = "mrsD", "msrM", }, + { shift = 21, mask = 3, "bxM", false, "clzDM", }, + { shift = 21, mask = 3, "bxjM", }, + { shift = 21, mask = 3, "blxM", }, + false, + { shift = 21, mask = 3, [0] = "qaddDMN", "qsubDMN", "qdaddDMN", "qdsubDMN", }, + false, + { shift = 21, mask = 3, "bkptK", }, +} + +local map_datar = { + shift = 4, mask = 9, + [9] = { + shift = 5, mask = 3, + [0] = { shift = 24, mask = 1, [0] = map_mul, map_sync, }, + { shift = 20, mask = 1, [0] = "strhDL", "ldrhDL", }, + { shift = 20, mask = 1, [0] = "ldrdDL", "ldrsbDL", }, + { shift = 20, mask = 1, [0] = "strdDL", "ldrshDL", }, + }, + _ = { + shift = 20, mask = 25, + [16] = { shift = 7, mask = 1, [0] = map_misc, map_mulh, }, + _ = { + shift = 0, mask = 0xffffffff, + [bor(0xe1a00000)] = "nop", + _ = map_data, + } + }, +} + +local map_datai = { + shift = 20, mask = 31, -- NYI: decode PSR bits of msr. Decode imm12. + [16] = "movwDW", [20] = "movtDW", + [18] = { shift = 0, mask = 0xf00ff, [0] = "nopv6", _ = "msrNW", }, + [22] = "msrNW", + _ = map_data, +} + +local map_branch = { + shift = 24, mask = 1, + [0] = "bB", "blB" +} + +local map_condins = { + [0] = map_datar, map_datai, map_load, map_load1, + map_loadm, map_branch, map_loadc, map_datac +} + +-- NYI: setend. +local map_uncondins = { + [0] = false, map_simddata, map_simdload, map_preload, + false, "blxB", map_loadcu, map_datacu, +} + +------------------------------------------------------------------------------ + +local map_gpr = { + [0] = "r0", "r1", "r2", "r3", "r4", "r5", "r6", "r7", + "r8", "r9", "r10", "r11", "r12", "sp", "lr", "pc", +} + +local map_cond = { + [0] = "eq", "ne", "hs", "lo", "mi", "pl", "vs", "vc", + "hi", "ls", "ge", "lt", "gt", "le", "al", +} + +local map_shift = { [0] = "lsl", "lsr", "asr", "ror", } + +------------------------------------------------------------------------------ + +-- Output a nicely formatted line with an opcode and operands. +local function putop(ctx, text, operands) + local pos = ctx.pos + local extra = "" + if ctx.rel then + local sym = ctx.symtab[ctx.rel] + if sym then + extra = "\t->"..sym + elseif band(ctx.op, 0x0e000000) ~= 0x0a000000 then + extra = "\t; 0x"..tohex(ctx.rel) + end + end + if ctx.hexdump > 0 then + ctx.out(format("%08x %s %-5s %s%s\n", + ctx.addr+pos, tohex(ctx.op), text, concat(operands, ", "), extra)) + else + ctx.out(format("%08x %-5s %s%s\n", + ctx.addr+pos, text, concat(operands, ", "), extra)) + end + ctx.pos = pos + 4 +end + +-- Fallback for unknown opcodes. +local function unknown(ctx) + return putop(ctx, ".long", { "0x"..tohex(ctx.op) }) +end + +-- Format operand 2 of load/store opcodes. +local function fmtload(ctx, op, pos) + local base = map_gpr[band(rshift(op, 16), 15)] + local x, ofs + local ext = (band(op, 0x04000000) == 0) + if not ext and band(op, 0x02000000) == 0 then + ofs = band(op, 4095) + if band(op, 0x00800000) == 0 then ofs = -ofs end + if base == "pc" then ctx.rel = ctx.addr + pos + 8 + ofs end + ofs = "#"..ofs + elseif ext and band(op, 0x00400000) ~= 0 then + ofs = band(op, 15) + band(rshift(op, 4), 0xf0) + if band(op, 0x00800000) == 0 then ofs = -ofs end + if base == "pc" then ctx.rel = ctx.addr + pos + 8 + ofs end + ofs = "#"..ofs + else + ofs = map_gpr[band(op, 15)] + if ext or band(op, 0xfe0) == 0 then + elseif band(op, 0xfe0) == 0x60 then + ofs = format("%s, rrx", ofs) + else + local sh = band(rshift(op, 7), 31) + if sh == 0 then sh = 32 end + ofs = format("%s, %s #%d", ofs, map_shift[band(rshift(op, 5), 3)], sh) + end + if band(op, 0x00800000) == 0 then ofs = "-"..ofs end + end + if ofs == "#0" then + x = format("[%s]", base) + elseif band(op, 0x01000000) == 0 then + x = format("[%s], %s", base, ofs) + else + x = format("[%s, %s]", base, ofs) + end + if band(op, 0x01200000) == 0x01200000 then x = x.."!" end + return x +end + +-- Format operand 2 of vector load/store opcodes. +local function fmtvload(ctx, op, pos) + local base = map_gpr[band(rshift(op, 16), 15)] + local ofs = band(op, 255)*4 + if band(op, 0x00800000) == 0 then ofs = -ofs end + if base == "pc" then ctx.rel = ctx.addr + pos + 8 + ofs end + if ofs == 0 then + return format("[%s]", base) + else + return format("[%s, #%d]", base, ofs) + end +end + +local function fmtvr(op, vr, sh0, sh1) + if vr == "s" then + return format("s%d", 2*band(rshift(op, sh0), 15)+band(rshift(op, sh1), 1)) + else + return format("d%d", band(rshift(op, sh0), 15)+band(rshift(op, sh1-4), 16)) + end +end + +-- Disassemble a single instruction. +local function disass_ins(ctx) + local pos = ctx.pos + local b0, b1, b2, b3 = byte(ctx.code, pos+1, pos+4) + local op = bor(lshift(b3, 24), lshift(b2, 16), lshift(b1, 8), b0) + local operands = {} + local suffix = "" + local last, name, pat + local vr + ctx.op = op + ctx.rel = nil + + local cond = rshift(op, 28) + local opat + if cond == 15 then + opat = map_uncondins[band(rshift(op, 25), 7)] + else + if cond ~= 14 then suffix = map_cond[cond] end + opat = map_condins[band(rshift(op, 25), 7)] + end + while type(opat) ~= "string" do + if not opat then return unknown(ctx) end + opat = opat[band(rshift(op, opat.shift), opat.mask)] or opat._ + end + name, pat = match(opat, "^([a-z0-9]*)(.*)") + if sub(pat, 1, 1) == "." then + local s2, p2 = match(pat, "^([a-z0-9.]*)(.*)") + suffix = suffix..s2 + pat = p2 + end + + for p in gmatch(pat, ".") do + local x = nil + if p == "D" then + x = map_gpr[band(rshift(op, 12), 15)] + elseif p == "N" then + x = map_gpr[band(rshift(op, 16), 15)] + elseif p == "S" then + x = map_gpr[band(rshift(op, 8), 15)] + elseif p == "M" then + x = map_gpr[band(op, 15)] + elseif p == "d" then + x = fmtvr(op, vr, 12, 22) + elseif p == "n" then + x = fmtvr(op, vr, 16, 7) + elseif p == "m" then + x = fmtvr(op, vr, 0, 5) + elseif p == "P" then + if band(op, 0x02000000) ~= 0 then + x = ror(band(op, 255), 2*band(rshift(op, 8), 15)) + else + x = map_gpr[band(op, 15)] + if band(op, 0xff0) ~= 0 then + operands[#operands+1] = x + local s = map_shift[band(rshift(op, 5), 3)] + local r = nil + if band(op, 0xf90) == 0 then + if s == "ror" then s = "rrx" else r = "#32" end + elseif band(op, 0x10) == 0 then + r = "#"..band(rshift(op, 7), 31) + else + r = map_gpr[band(rshift(op, 8), 15)] + end + if name == "mov" then name = s; x = r + elseif r then x = format("%s %s", s, r) + else x = s end + end + end + elseif p == "L" then + x = fmtload(ctx, op, pos) + elseif p == "l" then + x = fmtvload(ctx, op, pos) + elseif p == "B" then + local addr = ctx.addr + pos + 8 + arshift(lshift(op, 8), 6) + if cond == 15 then addr = addr + band(rshift(op, 23), 2) end + ctx.rel = addr + x = "0x"..tohex(addr) + elseif p == "F" then + vr = "s" + elseif p == "G" then + vr = "d" + elseif p == "." then + suffix = suffix..(vr == "s" and ".f32" or ".f64") + elseif p == "R" then + if band(op, 0x00200000) ~= 0 and #operands == 1 then + operands[1] = operands[1].."!" + end + local t = {} + for i=0,15 do + if band(rshift(op, i), 1) == 1 then t[#t+1] = map_gpr[i] end + end + x = "{"..concat(t, ", ").."}" + elseif p == "r" then + if band(op, 0x00200000) ~= 0 and #operands == 2 then + operands[1] = operands[1].."!" + end + local s = tonumber(sub(last, 2)) + local n = band(op, 255) + if vr == "d" then n = rshift(n, 1) end + operands[#operands] = format("{%s-%s%d}", last, vr, s+n-1) + elseif p == "W" then + x = band(op, 0x0fff) + band(rshift(op, 4), 0xf000) + elseif p == "T" then + x = "#0x"..tohex(band(op, 0x00ffffff), 6) + elseif p == "U" then + x = band(rshift(op, 7), 31) + if x == 0 then x = nil end + elseif p == "u" then + x = band(rshift(op, 7), 31) + if band(op, 0x40) == 0 then + if x == 0 then x = nil else x = "lsl #"..x end + else + if x == 0 then x = "asr #32" else x = "asr #"..x end + end + elseif p == "v" then + x = band(rshift(op, 7), 31) + elseif p == "w" then + x = band(rshift(op, 16), 31) + elseif p == "x" then + x = band(rshift(op, 16), 31) + 1 + elseif p == "X" then + x = band(rshift(op, 16), 31) - last + 1 + elseif p == "Y" then + x = band(rshift(op, 12), 0xf0) + band(op, 0x0f) + elseif p == "K" then + x = "#0x"..tohex(band(rshift(op, 4), 0x0000fff0) + band(op, 15), 4) + elseif p == "s" then + if band(op, 0x00100000) ~= 0 then suffix = "s"..suffix end + else + assert(false) + end + if x then + last = x + if type(x) == "number" then x = "#"..x end + operands[#operands+1] = x + end + end + + return putop(ctx, name..suffix, operands) +end + +------------------------------------------------------------------------------ + +-- Disassemble a block of code. +local function disass_block(ctx, ofs, len) + if not ofs then ofs = 0 end + local stop = len and ofs+len or #ctx.code + ctx.pos = ofs + ctx.rel = nil + while ctx.pos < stop do disass_ins(ctx) end +end + +-- Extended API: create a disassembler context. Then call ctx:disass(ofs, len). +local function create(code, addr, out) + local ctx = {} + ctx.code = code + ctx.addr = addr or 0 + ctx.out = out or io.write + ctx.symtab = {} + ctx.disass = disass_block + ctx.hexdump = 8 + return ctx +end + +-- Simple API: disassemble code (a string) at address and output via out. +local function disass(code, addr, out) + create(code, addr, out):disass() +end + +-- Return register name for RID. +local function regname(r) + if r < 16 then return map_gpr[r] end + return "d"..(r-16) +end + +-- Public module functions. +return { + create = create, + disass = disass, + regname = regname +} + diff --git a/fluent-bit/lib/luajit-3065c9/src/jit/dis_arm64.lua b/fluent-bit/lib/luajit-3065c9/src/jit/dis_arm64.lua new file mode 100644 index 00000000..531584a1 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/jit/dis_arm64.lua @@ -0,0 +1,1216 @@ +---------------------------------------------------------------------------- +-- LuaJIT ARM64 disassembler module. +-- +-- Copyright (C) 2005-2022 Mike Pall. All rights reserved. +-- Released under the MIT license. See Copyright Notice in luajit.h +-- +-- Contributed by Djordje Kovacevic and Stefan Pejic from RT-RK.com. +-- Sponsored by Cisco Systems, Inc. +---------------------------------------------------------------------------- +-- This is a helper module used by the LuaJIT machine code dumper module. +-- +-- It disassembles most user-mode AArch64 instructions. +-- NYI: Advanced SIMD and VFP instructions. +------------------------------------------------------------------------------ + +local type = type +local sub, byte, format = string.sub, string.byte, string.format +local match, gmatch, gsub = string.match, string.gmatch, string.gsub +local concat = table.concat +local bit = require("bit") +local band, bor, bxor, tohex = bit.band, bit.bor, bit.bxor, bit.tohex +local lshift, rshift, arshift = bit.lshift, bit.rshift, bit.arshift +local ror = bit.ror + +------------------------------------------------------------------------------ +-- Opcode maps +------------------------------------------------------------------------------ + +local map_adr = { -- PC-relative addressing. + shift = 31, mask = 1, + [0] = "adrDBx", "adrpDBx" +} + +local map_addsubi = { -- Add/subtract immediate. + shift = 29, mask = 3, + [0] = "add|movDNIg", "adds|cmnD0NIg", "subDNIg", "subs|cmpD0NIg", +} + +local map_logi = { -- Logical immediate. + shift = 31, mask = 1, + [0] = { + shift = 22, mask = 1, + [0] = { + shift = 29, mask = 3, + [0] = "andDNig", "orr|movDN0ig", "eorDNig", "ands|tstD0Nig" + }, + false -- unallocated + }, + { + shift = 29, mask = 3, + [0] = "andDNig", "orr|movDN0ig", "eorDNig", "ands|tstD0Nig" + } +} + +local map_movwi = { -- Move wide immediate. + shift = 31, mask = 1, + [0] = { + shift = 22, mask = 1, + [0] = { + shift = 29, mask = 3, + [0] = "movnDWRg", false, "movz|movDYRg", "movkDWRg" + }, false -- unallocated + }, + { + shift = 29, mask = 3, + [0] = "movnDWRg", false, "movz|movDYRg", "movkDWRg" + }, +} + +local map_bitf = { -- Bitfield. + shift = 31, mask = 1, + [0] = { + shift = 22, mask = 1, + [0] = { + shift = 29, mask = 3, + [0] = "sbfm|sbfiz|sbfx|asr|sxtw|sxth|sxtbDN12w", + "bfm|bfi|bfxilDN13w", + "ubfm|ubfiz|ubfx|lsr|lsl|uxth|uxtbDN12w" + } + }, + { + shift = 22, mask = 1, + { + shift = 29, mask = 3, + [0] = "sbfm|sbfiz|sbfx|asr|sxtw|sxth|sxtbDN12x", + "bfm|bfi|bfxilDN13x", + "ubfm|ubfiz|ubfx|lsr|lsl|uxth|uxtbDN12x" + } + } +} + +local map_datai = { -- Data processing - immediate. + shift = 23, mask = 7, + [0] = map_adr, map_adr, map_addsubi, false, + map_logi, map_movwi, map_bitf, + { + shift = 15, mask = 0x1c0c1, + [0] = "extr|rorDNM4w", [0x10080] = "extr|rorDNM4x", + [0x10081] = "extr|rorDNM4x" + } +} + +local map_logsr = { -- Logical, shifted register. + shift = 31, mask = 1, + [0] = { + shift = 15, mask = 1, + [0] = { + shift = 29, mask = 3, + [0] = { + shift = 21, mask = 7, + [0] = "andDNMSg", "bicDNMSg", "andDNMSg", "bicDNMSg", + "andDNMSg", "bicDNMSg", "andDNMg", "bicDNMg" + }, + { + shift = 21, mask = 7, + [0] ="orr|movDN0MSg", "orn|mvnDN0MSg", "orr|movDN0MSg", "orn|mvnDN0MSg", + "orr|movDN0MSg", "orn|mvnDN0MSg", "orr|movDN0Mg", "orn|mvnDN0Mg" + }, + { + shift = 21, mask = 7, + [0] = "eorDNMSg", "eonDNMSg", "eorDNMSg", "eonDNMSg", + "eorDNMSg", "eonDNMSg", "eorDNMg", "eonDNMg" + }, + { + shift = 21, mask = 7, + [0] = "ands|tstD0NMSg", "bicsDNMSg", "ands|tstD0NMSg", "bicsDNMSg", + "ands|tstD0NMSg", "bicsDNMSg", "ands|tstD0NMg", "bicsDNMg" + } + }, + false -- unallocated + }, + { + shift = 29, mask = 3, + [0] = { + shift = 21, mask = 7, + [0] = "andDNMSg", "bicDNMSg", "andDNMSg", "bicDNMSg", + "andDNMSg", "bicDNMSg", "andDNMg", "bicDNMg" + }, + { + shift = 21, mask = 7, + [0] = "orr|movDN0MSg", "orn|mvnDN0MSg", "orr|movDN0MSg", "orn|mvnDN0MSg", + "orr|movDN0MSg", "orn|mvnDN0MSg", "orr|movDN0Mg", "orn|mvnDN0Mg" + }, + { + shift = 21, mask = 7, + [0] = "eorDNMSg", "eonDNMSg", "eorDNMSg", "eonDNMSg", + "eorDNMSg", "eonDNMSg", "eorDNMg", "eonDNMg" + }, + { + shift = 21, mask = 7, + [0] = "ands|tstD0NMSg", "bicsDNMSg", "ands|tstD0NMSg", "bicsDNMSg", + "ands|tstD0NMSg", "bicsDNMSg", "ands|tstD0NMg", "bicsDNMg" + } + } +} + +local map_assh = { + shift = 31, mask = 1, + [0] = { + shift = 15, mask = 1, + [0] = { + shift = 29, mask = 3, + [0] = { + shift = 22, mask = 3, + [0] = "addDNMSg", "addDNMSg", "addDNMSg", "addDNMg" + }, + { + shift = 22, mask = 3, + [0] = "adds|cmnD0NMSg", "adds|cmnD0NMSg", + "adds|cmnD0NMSg", "adds|cmnD0NMg" + }, + { + shift = 22, mask = 3, + [0] = "sub|negDN0MSg", "sub|negDN0MSg", "sub|negDN0MSg", "sub|negDN0Mg" + }, + { + shift = 22, mask = 3, + [0] = "subs|cmp|negsD0N0MzSg", "subs|cmp|negsD0N0MzSg", + "subs|cmp|negsD0N0MzSg", "subs|cmp|negsD0N0Mzg" + }, + }, + false -- unallocated + }, + { + shift = 29, mask = 3, + [0] = { + shift = 22, mask = 3, + [0] = "addDNMSg", "addDNMSg", "addDNMSg", "addDNMg" + }, + { + shift = 22, mask = 3, + [0] = "adds|cmnD0NMSg", "adds|cmnD0NMSg", "adds|cmnD0NMSg", + "adds|cmnD0NMg" + }, + { + shift = 22, mask = 3, + [0] = "sub|negDN0MSg", "sub|negDN0MSg", "sub|negDN0MSg", "sub|negDN0Mg" + }, + { + shift = 22, mask = 3, + [0] = "subs|cmp|negsD0N0MzSg", "subs|cmp|negsD0N0MzSg", + "subs|cmp|negsD0N0MzSg", "subs|cmp|negsD0N0Mzg" + } + } +} + +local map_addsubsh = { -- Add/subtract, shifted register. + shift = 22, mask = 3, + [0] = map_assh, map_assh, map_assh +} + +local map_addsubex = { -- Add/subtract, extended register. + shift = 22, mask = 3, + [0] = { + shift = 29, mask = 3, + [0] = "addDNMXg", "adds|cmnD0NMXg", "subDNMXg", "subs|cmpD0NMzXg", + } +} + +local map_addsubc = { -- Add/subtract, with carry. + shift = 10, mask = 63, + [0] = { + shift = 29, mask = 3, + [0] = "adcDNMg", "adcsDNMg", "sbc|ngcDN0Mg", "sbcs|ngcsDN0Mg", + } +} + +local map_ccomp = { + shift = 4, mask = 1, + [0] = { + shift = 10, mask = 3, + [0] = { -- Conditional compare register. + shift = 29, mask = 3, + "ccmnNMVCg", false, "ccmpNMVCg", + }, + [2] = { -- Conditional compare immediate. + shift = 29, mask = 3, + "ccmnN5VCg", false, "ccmpN5VCg", + } + } +} + +local map_csel = { -- Conditional select. + shift = 11, mask = 1, + [0] = { + shift = 10, mask = 1, + [0] = { + shift = 29, mask = 3, + [0] = "cselDNMzCg", false, "csinv|cinv|csetmDNMcg", false, + }, + { + shift = 29, mask = 3, + [0] = "csinc|cinc|csetDNMcg", false, "csneg|cnegDNMcg", false, + } + } +} + +local map_data1s = { -- Data processing, 1 source. + shift = 29, mask = 1, + [0] = { + shift = 31, mask = 1, + [0] = { + shift = 10, mask = 0x7ff, + [0] = "rbitDNg", "rev16DNg", "revDNw", false, "clzDNg", "clsDNg" + }, + { + shift = 10, mask = 0x7ff, + [0] = "rbitDNg", "rev16DNg", "rev32DNx", "revDNx", "clzDNg", "clsDNg" + } + } +} + +local map_data2s = { -- Data processing, 2 sources. + shift = 29, mask = 1, + [0] = { + shift = 10, mask = 63, + false, "udivDNMg", "sdivDNMg", false, false, false, false, "lslDNMg", + "lsrDNMg", "asrDNMg", "rorDNMg" + } +} + +local map_data3s = { -- Data processing, 3 sources. + shift = 29, mask = 7, + [0] = { + shift = 21, mask = 7, + [0] = { + shift = 15, mask = 1, + [0] = "madd|mulDNMA0g", "msub|mnegDNMA0g" + } + }, false, false, false, + { + shift = 15, mask = 1, + [0] = { + shift = 21, mask = 7, + [0] = "madd|mulDNMA0g", "smaddl|smullDxNMwA0x", "smulhDNMx", false, + false, "umaddl|umullDxNMwA0x", "umulhDNMx" + }, + { + shift = 21, mask = 7, + [0] = "msub|mnegDNMA0g", "smsubl|smneglDxNMwA0x", false, false, + false, "umsubl|umneglDxNMwA0x" + } + } +} + +local map_datar = { -- Data processing, register. + shift = 28, mask = 1, + [0] = { + shift = 24, mask = 1, + [0] = map_logsr, + { + shift = 21, mask = 1, + [0] = map_addsubsh, map_addsubex + } + }, + { + shift = 21, mask = 15, + [0] = map_addsubc, false, map_ccomp, false, map_csel, false, + { + shift = 30, mask = 1, + [0] = map_data2s, map_data1s + }, + false, map_data3s, map_data3s, map_data3s, map_data3s, map_data3s, + map_data3s, map_data3s, map_data3s + } +} + +local map_lrl = { -- Load register, literal. + shift = 26, mask = 1, + [0] = { + shift = 30, mask = 3, + [0] = "ldrDwB", "ldrDxB", "ldrswDxB" + }, + { + shift = 30, mask = 3, + [0] = "ldrDsB", "ldrDdB" + } +} + +local map_lsriind = { -- Load/store register, immediate pre/post-indexed. + shift = 30, mask = 3, + [0] = { + shift = 26, mask = 1, + [0] = { + shift = 22, mask = 3, + [0] = "strbDwzL", "ldrbDwzL", "ldrsbDxzL", "ldrsbDwzL" + } + }, + { + shift = 26, mask = 1, + [0] = { + shift = 22, mask = 3, + [0] = "strhDwzL", "ldrhDwzL", "ldrshDxzL", "ldrshDwzL" + } + }, + { + shift = 26, mask = 1, + [0] = { + shift = 22, mask = 3, + [0] = "strDwzL", "ldrDwzL", "ldrswDxzL" + }, + { + shift = 22, mask = 3, + [0] = "strDszL", "ldrDszL" + } + }, + { + shift = 26, mask = 1, + [0] = { + shift = 22, mask = 3, + [0] = "strDxzL", "ldrDxzL" + }, + { + shift = 22, mask = 3, + [0] = "strDdzL", "ldrDdzL" + } + } +} + +local map_lsriro = { + shift = 21, mask = 1, + [0] = { -- Load/store register immediate. + shift = 10, mask = 3, + [0] = { -- Unscaled immediate. + shift = 26, mask = 1, + [0] = { + shift = 30, mask = 3, + [0] = { + shift = 22, mask = 3, + [0] = "sturbDwK", "ldurbDwK" + }, + { + shift = 22, mask = 3, + [0] = "sturhDwK", "ldurhDwK" + }, + { + shift = 22, mask = 3, + [0] = "sturDwK", "ldurDwK" + }, + { + shift = 22, mask = 3, + [0] = "sturDxK", "ldurDxK" + } + } + }, map_lsriind, false, map_lsriind + }, + { -- Load/store register, register offset. + shift = 10, mask = 3, + [2] = { + shift = 26, mask = 1, + [0] = { + shift = 30, mask = 3, + [0] = { + shift = 22, mask = 3, + [0] = "strbDwO", "ldrbDwO", "ldrsbDxO", "ldrsbDwO" + }, + { + shift = 22, mask = 3, + [0] = "strhDwO", "ldrhDwO", "ldrshDxO", "ldrshDwO" + }, + { + shift = 22, mask = 3, + [0] = "strDwO", "ldrDwO", "ldrswDxO" + }, + { + shift = 22, mask = 3, + [0] = "strDxO", "ldrDxO" + } + }, + { + shift = 30, mask = 3, + [2] = { + shift = 22, mask = 3, + [0] = "strDsO", "ldrDsO" + }, + [3] = { + shift = 22, mask = 3, + [0] = "strDdO", "ldrDdO" + } + } + } + } +} + +local map_lsp = { -- Load/store register pair, offset. + shift = 22, mask = 1, + [0] = { + shift = 30, mask = 3, + [0] = { + shift = 26, mask = 1, + [0] = "stpDzAzwP", "stpDzAzsP", + }, + { + shift = 26, mask = 1, + "stpDzAzdP" + }, + { + shift = 26, mask = 1, + [0] = "stpDzAzxP" + } + }, + { + shift = 30, mask = 3, + [0] = { + shift = 26, mask = 1, + [0] = "ldpDzAzwP", "ldpDzAzsP", + }, + { + shift = 26, mask = 1, + [0] = "ldpswDAxP", "ldpDzAzdP" + }, + { + shift = 26, mask = 1, + [0] = "ldpDzAzxP" + } + } +} + +local map_ls = { -- Loads and stores. + shift = 24, mask = 0x31, + [0x10] = map_lrl, [0x30] = map_lsriro, + [0x20] = { + shift = 23, mask = 3, + map_lsp, map_lsp, map_lsp + }, + [0x21] = { + shift = 23, mask = 3, + map_lsp, map_lsp, map_lsp + }, + [0x31] = { + shift = 26, mask = 1, + [0] = { + shift = 30, mask = 3, + [0] = { + shift = 22, mask = 3, + [0] = "strbDwzU", "ldrbDwzU" + }, + { + shift = 22, mask = 3, + [0] = "strhDwzU", "ldrhDwzU" + }, + { + shift = 22, mask = 3, + [0] = "strDwzU", "ldrDwzU" + }, + { + shift = 22, mask = 3, + [0] = "strDxzU", "ldrDxzU" + } + }, + { + shift = 30, mask = 3, + [2] = { + shift = 22, mask = 3, + [0] = "strDszU", "ldrDszU" + }, + [3] = { + shift = 22, mask = 3, + [0] = "strDdzU", "ldrDdzU" + } + } + }, +} + +local map_datafp = { -- Data processing, SIMD and FP. + shift = 28, mask = 7, + { -- 001 + shift = 24, mask = 1, + [0] = { + shift = 21, mask = 1, + { + shift = 10, mask = 3, + [0] = { + shift = 12, mask = 1, + [0] = { + shift = 13, mask = 1, + [0] = { + shift = 14, mask = 1, + [0] = { + shift = 15, mask = 1, + [0] = { -- FP/int conversion. + shift = 31, mask = 1, + [0] = { + shift = 16, mask = 0xff, + [0x20] = "fcvtnsDwNs", [0x21] = "fcvtnuDwNs", + [0x22] = "scvtfDsNw", [0x23] = "ucvtfDsNw", + [0x24] = "fcvtasDwNs", [0x25] = "fcvtauDwNs", + [0x26] = "fmovDwNs", [0x27] = "fmovDsNw", + [0x28] = "fcvtpsDwNs", [0x29] = "fcvtpuDwNs", + [0x30] = "fcvtmsDwNs", [0x31] = "fcvtmuDwNs", + [0x38] = "fcvtzsDwNs", [0x39] = "fcvtzuDwNs", + [0x60] = "fcvtnsDwNd", [0x61] = "fcvtnuDwNd", + [0x62] = "scvtfDdNw", [0x63] = "ucvtfDdNw", + [0x64] = "fcvtasDwNd", [0x65] = "fcvtauDwNd", + [0x68] = "fcvtpsDwNd", [0x69] = "fcvtpuDwNd", + [0x70] = "fcvtmsDwNd", [0x71] = "fcvtmuDwNd", + [0x78] = "fcvtzsDwNd", [0x79] = "fcvtzuDwNd" + }, + { + shift = 16, mask = 0xff, + [0x20] = "fcvtnsDxNs", [0x21] = "fcvtnuDxNs", + [0x22] = "scvtfDsNx", [0x23] = "ucvtfDsNx", + [0x24] = "fcvtasDxNs", [0x25] = "fcvtauDxNs", + [0x28] = "fcvtpsDxNs", [0x29] = "fcvtpuDxNs", + [0x30] = "fcvtmsDxNs", [0x31] = "fcvtmuDxNs", + [0x38] = "fcvtzsDxNs", [0x39] = "fcvtzuDxNs", + [0x60] = "fcvtnsDxNd", [0x61] = "fcvtnuDxNd", + [0x62] = "scvtfDdNx", [0x63] = "ucvtfDdNx", + [0x64] = "fcvtasDxNd", [0x65] = "fcvtauDxNd", + [0x66] = "fmovDxNd", [0x67] = "fmovDdNx", + [0x68] = "fcvtpsDxNd", [0x69] = "fcvtpuDxNd", + [0x70] = "fcvtmsDxNd", [0x71] = "fcvtmuDxNd", + [0x78] = "fcvtzsDxNd", [0x79] = "fcvtzuDxNd" + } + } + }, + { -- FP data-processing, 1 source. + shift = 31, mask = 1, + [0] = { + shift = 22, mask = 3, + [0] = { + shift = 15, mask = 63, + [0] = "fmovDNf", "fabsDNf", "fnegDNf", + "fsqrtDNf", false, "fcvtDdNs", false, false, + "frintnDNf", "frintpDNf", "frintmDNf", "frintzDNf", + "frintaDNf", false, "frintxDNf", "frintiDNf", + }, + { + shift = 15, mask = 63, + [0] = "fmovDNf", "fabsDNf", "fnegDNf", + "fsqrtDNf", "fcvtDsNd", false, false, false, + "frintnDNf", "frintpDNf", "frintmDNf", "frintzDNf", + "frintaDNf", false, "frintxDNf", "frintiDNf", + } + } + } + }, + { -- FP compare. + shift = 31, mask = 1, + [0] = { + shift = 14, mask = 3, + [0] = { + shift = 23, mask = 1, + [0] = { + shift = 0, mask = 31, + [0] = "fcmpNMf", [8] = "fcmpNZf", + [16] = "fcmpeNMf", [24] = "fcmpeNZf", + } + } + } + } + }, + { -- FP immediate. + shift = 31, mask = 1, + [0] = { + shift = 5, mask = 31, + [0] = { + shift = 23, mask = 1, + [0] = "fmovDFf" + } + } + } + }, + { -- FP conditional compare. + shift = 31, mask = 1, + [0] = { + shift = 23, mask = 1, + [0] = { + shift = 4, mask = 1, + [0] = "fccmpNMVCf", "fccmpeNMVCf" + } + } + }, + { -- FP data-processing, 2 sources. + shift = 31, mask = 1, + [0] = { + shift = 23, mask = 1, + [0] = { + shift = 12, mask = 15, + [0] = "fmulDNMf", "fdivDNMf", "faddDNMf", "fsubDNMf", + "fmaxDNMf", "fminDNMf", "fmaxnmDNMf", "fminnmDNMf", + "fnmulDNMf" + } + } + }, + { -- FP conditional select. + shift = 31, mask = 1, + [0] = { + shift = 23, mask = 1, + [0] = "fcselDNMCf" + } + } + } + }, + { -- FP data-processing, 3 sources. + shift = 31, mask = 1, + [0] = { + shift = 15, mask = 1, + [0] = { + shift = 21, mask = 5, + [0] = "fmaddDNMAf", "fnmaddDNMAf" + }, + { + shift = 21, mask = 5, + [0] = "fmsubDNMAf", "fnmsubDNMAf" + } + } + } + } +} + +local map_br = { -- Branches, exception generating and system instructions. + shift = 29, mask = 7, + [0] = "bB", + { -- Compare & branch, immediate. + shift = 24, mask = 3, + [0] = "cbzDBg", "cbnzDBg", "tbzDTBw", "tbnzDTBw" + }, + { -- Conditional branch, immediate. + shift = 24, mask = 3, + [0] = { + shift = 4, mask = 1, + [0] = { + shift = 0, mask = 15, + [0] = "beqB", "bneB", "bhsB", "bloB", "bmiB", "bplB", "bvsB", "bvcB", + "bhiB", "blsB", "bgeB", "bltB", "bgtB", "bleB", "balB" + } + } + }, false, "blB", + { -- Compare & branch, immediate. + shift = 24, mask = 3, + [0] = "cbzDBg", "cbnzDBg", "tbzDTBx", "tbnzDTBx" + }, + { + shift = 24, mask = 3, + [0] = { -- Exception generation. + shift = 0, mask = 0xe0001f, + [0x200000] = "brkW" + }, + { -- System instructions. + shift = 0, mask = 0x3fffff, + [0x03201f] = "nop" + }, + { -- Unconditional branch, register. + shift = 0, mask = 0xfffc1f, + [0x1f0000] = "brNx", [0x3f0000] = "blrNx", + [0x5f0000] = "retNx" + }, + } +} + +local map_init = { + shift = 25, mask = 15, + [0] = false, false, false, false, map_ls, map_datar, map_ls, map_datafp, + map_datai, map_datai, map_br, map_br, map_ls, map_datar, map_ls, map_datafp +} + +------------------------------------------------------------------------------ + +local map_regs = { x = {}, w = {}, d = {}, s = {} } + +for i=0,30 do + map_regs.x[i] = "x"..i + map_regs.w[i] = "w"..i + map_regs.d[i] = "d"..i + map_regs.s[i] = "s"..i +end +map_regs.x[31] = "sp" +map_regs.w[31] = "wsp" +map_regs.d[31] = "d31" +map_regs.s[31] = "s31" + +local map_cond = { + [0] = "eq", "ne", "cs", "cc", "mi", "pl", "vs", "vc", + "hi", "ls", "ge", "lt", "gt", "le", "al", +} + +local map_shift = { [0] = "lsl", "lsr", "asr", } + +local map_extend = { + [0] = "uxtb", "uxth", "uxtw", "uxtx", "sxtb", "sxth", "sxtw", "sxtx", +} + +------------------------------------------------------------------------------ + +-- Output a nicely formatted line with an opcode and operands. +local function putop(ctx, text, operands) + local pos = ctx.pos + local extra = "" + if ctx.rel then + local sym = ctx.symtab[ctx.rel] + if sym then + extra = "\t->"..sym + end + end + if ctx.hexdump > 0 then + ctx.out(format("%08x %s %-5s %s%s\n", + ctx.addr+pos, tohex(ctx.op), text, concat(operands, ", "), extra)) + else + ctx.out(format("%08x %-5s %s%s\n", + ctx.addr+pos, text, concat(operands, ", "), extra)) + end + ctx.pos = pos + 4 +end + +-- Fallback for unknown opcodes. +local function unknown(ctx) + return putop(ctx, ".long", { "0x"..tohex(ctx.op) }) +end + +local function match_reg(p, pat, regnum) + return map_regs[match(pat, p.."%w-([xwds])")][regnum] +end + +local function fmt_hex32(x) + if x < 0 then + return tohex(x) + else + return format("%x", x) + end +end + +local imm13_rep = { 0x55555555, 0x11111111, 0x01010101, 0x00010001, 0x00000001 } + +local function decode_imm13(op) + local imms = band(rshift(op, 10), 63) + local immr = band(rshift(op, 16), 63) + if band(op, 0x00400000) == 0 then + local len = 5 + if imms >= 56 then + if imms >= 60 then len = 1 else len = 2 end + elseif imms >= 48 then len = 3 elseif imms >= 32 then len = 4 end + local l = lshift(1, len)-1 + local s = band(imms, l) + local r = band(immr, l) + local imm = ror(rshift(-1, 31-s), r) + if len ~= 5 then imm = band(imm, lshift(1, l)-1) + rshift(imm, 31-l) end + imm = imm * imm13_rep[len] + local ix = fmt_hex32(imm) + if rshift(op, 31) ~= 0 then + return ix..tohex(imm) + else + return ix + end + else + local lo, hi = -1, 0 + if imms < 32 then lo = rshift(-1, 31-imms) else hi = rshift(-1, 63-imms) end + if immr ~= 0 then + lo, hi = ror(lo, immr), ror(hi, immr) + local x = immr == 32 and 0 or band(bxor(lo, hi), lshift(-1, 32-immr)) + lo, hi = bxor(lo, x), bxor(hi, x) + if immr >= 32 then lo, hi = hi, lo end + end + if hi ~= 0 then + return fmt_hex32(hi)..tohex(lo) + else + return fmt_hex32(lo) + end + end +end + +local function parse_immpc(op, name) + if name == "b" or name == "bl" then + return arshift(lshift(op, 6), 4) + elseif name == "adr" or name == "adrp" then + local immlo = band(rshift(op, 29), 3) + local immhi = lshift(arshift(lshift(op, 8), 13), 2) + return bor(immhi, immlo) + elseif name == "tbz" or name == "tbnz" then + return lshift(arshift(lshift(op, 13), 18), 2) + else + return lshift(arshift(lshift(op, 8), 13), 2) + end +end + +local function parse_fpimm8(op) + local sign = band(op, 0x100000) == 0 and 1 or -1 + local exp = bxor(rshift(arshift(lshift(op, 12), 5), 24), 0x80) - 131 + local frac = 16+band(rshift(op, 13), 15) + return sign * frac * 2^exp +end + +local function prefer_bfx(sf, uns, imms, immr) + if imms < immr or imms == 31 or imms == 63 then + return false + end + if immr == 0 then + if sf == 0 and (imms == 7 or imms == 15) then + return false + end + if sf ~= 0 and uns == 0 and (imms == 7 or imms == 15 or imms == 31) then + return false + end + end + return true +end + +-- Disassemble a single instruction. +local function disass_ins(ctx) + local pos = ctx.pos + local b0, b1, b2, b3 = byte(ctx.code, pos+1, pos+4) + local op = bor(lshift(b3, 24), lshift(b2, 16), lshift(b1, 8), b0) + local operands = {} + local suffix = "" + local last, name, pat + local map_reg + ctx.op = op + ctx.rel = nil + last = nil + local opat + opat = map_init[band(rshift(op, 25), 15)] + while type(opat) ~= "string" do + if not opat then return unknown(ctx) end + opat = opat[band(rshift(op, opat.shift), opat.mask)] or opat._ + end + name, pat = match(opat, "^([a-z0-9]*)(.*)") + local altname, pat2 = match(pat, "|([a-z0-9_.|]*)(.*)") + if altname then pat = pat2 end + if sub(pat, 1, 1) == "." then + local s2, p2 = match(pat, "^([a-z0-9.]*)(.*)") + suffix = suffix..s2 + pat = p2 + end + + local rt = match(pat, "[gf]") + if rt then + if rt == "g" then + map_reg = band(op, 0x80000000) ~= 0 and map_regs.x or map_regs.w + else + map_reg = band(op, 0x400000) ~= 0 and map_regs.d or map_regs.s + end + end + + local second0, immr + + for p in gmatch(pat, ".") do + local x = nil + if p == "D" then + local regnum = band(op, 31) + x = rt and map_reg[regnum] or match_reg(p, pat, regnum) + elseif p == "N" then + local regnum = band(rshift(op, 5), 31) + x = rt and map_reg[regnum] or match_reg(p, pat, regnum) + elseif p == "M" then + local regnum = band(rshift(op, 16), 31) + x = rt and map_reg[regnum] or match_reg(p, pat, regnum) + elseif p == "A" then + local regnum = band(rshift(op, 10), 31) + x = rt and map_reg[regnum] or match_reg(p, pat, regnum) + elseif p == "B" then + local addr = ctx.addr + pos + parse_immpc(op, name) + ctx.rel = addr + x = "0x"..tohex(addr) + elseif p == "T" then + x = bor(band(rshift(op, 26), 32), band(rshift(op, 19), 31)) + elseif p == "V" then + x = band(op, 15) + elseif p == "C" then + x = map_cond[band(rshift(op, 12), 15)] + elseif p == "c" then + local rn = band(rshift(op, 5), 31) + local rm = band(rshift(op, 16), 31) + local cond = band(rshift(op, 12), 15) + local invc = bxor(cond, 1) + x = map_cond[cond] + if altname and cond ~= 14 and cond ~= 15 then + local a1, a2 = match(altname, "([^|]*)|(.*)") + if rn == rm then + local n = #operands + operands[n] = nil + x = map_cond[invc] + if rn ~= 31 then + if a1 then name = a1 else name = altname end + else + operands[n-1] = nil + name = a2 + end + end + end + elseif p == "W" then + x = band(rshift(op, 5), 0xffff) + elseif p == "Y" then + x = band(rshift(op, 5), 0xffff) + local hw = band(rshift(op, 21), 3) + if altname and (hw == 0 or x ~= 0) then + name = altname + end + elseif p == "L" then + local rn = map_regs.x[band(rshift(op, 5), 31)] + local imm9 = arshift(lshift(op, 11), 23) + if band(op, 0x800) ~= 0 then + x = "["..rn..", #"..imm9.."]!" + else + x = "["..rn.."], #"..imm9 + end + elseif p == "U" then + local rn = map_regs.x[band(rshift(op, 5), 31)] + local sz = band(rshift(op, 30), 3) + local imm12 = lshift(arshift(lshift(op, 10), 20), sz) + if imm12 ~= 0 then + x = "["..rn..", #"..imm12.."]" + else + x = "["..rn.."]" + end + elseif p == "K" then + local rn = map_regs.x[band(rshift(op, 5), 31)] + local imm9 = arshift(lshift(op, 11), 23) + if imm9 ~= 0 then + x = "["..rn..", #"..imm9.."]" + else + x = "["..rn.."]" + end + elseif p == "O" then + local rn, rm = map_regs.x[band(rshift(op, 5), 31)] + local m = band(rshift(op, 13), 1) + if m == 0 then + rm = map_regs.w[band(rshift(op, 16), 31)] + else + rm = map_regs.x[band(rshift(op, 16), 31)] + end + x = "["..rn..", "..rm + local opt = band(rshift(op, 13), 7) + local s = band(rshift(op, 12), 1) + local sz = band(rshift(op, 30), 3) + -- extension to be applied + if opt == 3 then + if s == 0 then x = x.."]" + else x = x..", lsl #"..sz.."]" end + elseif opt == 2 or opt == 6 or opt == 7 then + if s == 0 then x = x..", "..map_extend[opt].."]" + else x = x..", "..map_extend[opt].." #"..sz.."]" end + else + x = x.."]" + end + elseif p == "P" then + local opcv, sh = rshift(op, 26), 2 + if opcv >= 0x2a then sh = 4 elseif opcv >= 0x1b then sh = 3 end + local imm7 = lshift(arshift(lshift(op, 10), 25), sh) + local rn = map_regs.x[band(rshift(op, 5), 31)] + local ind = band(rshift(op, 23), 3) + if ind == 1 then + x = "["..rn.."], #"..imm7 + elseif ind == 2 then + if imm7 == 0 then + x = "["..rn.."]" + else + x = "["..rn..", #"..imm7.."]" + end + elseif ind == 3 then + x = "["..rn..", #"..imm7.."]!" + end + elseif p == "I" then + local shf = band(rshift(op, 22), 3) + local imm12 = band(rshift(op, 10), 0x0fff) + local rn, rd = band(rshift(op, 5), 31), band(op, 31) + if altname == "mov" and shf == 0 and imm12 == 0 and (rn == 31 or rd == 31) then + name = altname + x = nil + elseif shf == 0 then + x = imm12 + elseif shf == 1 then + x = imm12..", lsl #12" + end + elseif p == "i" then + x = "#0x"..decode_imm13(op) + elseif p == "1" then + immr = band(rshift(op, 16), 63) + x = immr + elseif p == "2" then + x = band(rshift(op, 10), 63) + if altname then + local a1, a2, a3, a4, a5, a6 = + match(altname, "([^|]*)|([^|]*)|([^|]*)|([^|]*)|([^|]*)|(.*)") + local sf = band(rshift(op, 26), 32) + local uns = band(rshift(op, 30), 1) + if prefer_bfx(sf, uns, x, immr) then + name = a2 + x = x - immr + 1 + elseif immr == 0 and x == 7 then + local n = #operands + operands[n] = nil + if sf ~= 0 then + operands[n-1] = gsub(operands[n-1], "x", "w") + end + last = operands[n-1] + name = a6 + x = nil + elseif immr == 0 and x == 15 then + local n = #operands + operands[n] = nil + if sf ~= 0 then + operands[n-1] = gsub(operands[n-1], "x", "w") + end + last = operands[n-1] + name = a5 + x = nil + elseif x == 31 or x == 63 then + if x == 31 and immr == 0 and name == "sbfm" then + name = a4 + local n = #operands + operands[n] = nil + if sf ~= 0 then + operands[n-1] = gsub(operands[n-1], "x", "w") + end + last = operands[n-1] + else + name = a3 + end + x = nil + elseif band(x, 31) ~= 31 and immr == x+1 and name == "ubfm" then + name = a4 + last = "#"..(sf+32 - immr) + operands[#operands] = last + x = nil + elseif x < immr then + name = a1 + last = "#"..(sf+32 - immr) + operands[#operands] = last + x = x + 1 + end + end + elseif p == "3" then + x = band(rshift(op, 10), 63) + if altname then + local a1, a2 = match(altname, "([^|]*)|(.*)") + if x < immr then + name = a1 + local sf = band(rshift(op, 26), 32) + last = "#"..(sf+32 - immr) + operands[#operands] = last + x = x + 1 + else + name = a2 + x = x - immr + 1 + end + end + elseif p == "4" then + x = band(rshift(op, 10), 63) + local rn = band(rshift(op, 5), 31) + local rm = band(rshift(op, 16), 31) + if altname and rn == rm then + local n = #operands + operands[n] = nil + last = operands[n-1] + name = altname + end + elseif p == "5" then + x = band(rshift(op, 16), 31) + elseif p == "S" then + x = band(rshift(op, 10), 63) + if x == 0 then x = nil + else x = map_shift[band(rshift(op, 22), 3)].." #"..x end + elseif p == "X" then + local opt = band(rshift(op, 13), 7) + -- Width specifier . + if opt ~= 3 and opt ~= 7 then + last = map_regs.w[band(rshift(op, 16), 31)] + operands[#operands] = last + end + x = band(rshift(op, 10), 7) + -- Extension. + if opt == 2 + band(rshift(op, 31), 1) and + band(rshift(op, second0 and 5 or 0), 31) == 31 then + if x == 0 then x = nil + else x = "lsl #"..x end + else + if x == 0 then x = map_extend[band(rshift(op, 13), 7)] + else x = map_extend[band(rshift(op, 13), 7)].." #"..x end + end + elseif p == "R" then + x = band(rshift(op,21), 3) + if x == 0 then x = nil + else x = "lsl #"..x*16 end + elseif p == "z" then + local n = #operands + if operands[n] == "sp" then operands[n] = "xzr" + elseif operands[n] == "wsp" then operands[n] = "wzr" + end + elseif p == "Z" then + x = 0 + elseif p == "F" then + x = parse_fpimm8(op) + elseif p == "g" or p == "f" or p == "x" or p == "w" or + p == "d" or p == "s" then + -- These are handled in D/N/M/A. + elseif p == "0" then + if last == "sp" or last == "wsp" then + local n = #operands + operands[n] = nil + last = operands[n-1] + if altname then + local a1, a2 = match(altname, "([^|]*)|(.*)") + if not a1 then + name = altname + elseif second0 then + name, altname = a2, a1 + else + name, altname = a1, a2 + end + end + end + second0 = true + else + assert(false) + end + if x then + last = x + if type(x) == "number" then x = "#"..x end + operands[#operands+1] = x + end + end + + return putop(ctx, name..suffix, operands) +end + +------------------------------------------------------------------------------ + +-- Disassemble a block of code. +local function disass_block(ctx, ofs, len) + if not ofs then ofs = 0 end + local stop = len and ofs+len or #ctx.code + ctx.pos = ofs + ctx.rel = nil + while ctx.pos < stop do disass_ins(ctx) end +end + +-- Extended API: create a disassembler context. Then call ctx:disass(ofs, len). +local function create(code, addr, out) + local ctx = {} + ctx.code = code + ctx.addr = addr or 0 + ctx.out = out or io.write + ctx.symtab = {} + ctx.disass = disass_block + ctx.hexdump = 8 + return ctx +end + +-- Simple API: disassemble code (a string) at address and output via out. +local function disass(code, addr, out) + create(code, addr, out):disass() +end + +-- Return register name for RID. +local function regname(r) + if r < 32 then return map_regs.x[r] end + return map_regs.d[r-32] +end + +-- Public module functions. +return { + create = create, + disass = disass, + regname = regname +} + diff --git a/fluent-bit/lib/luajit-3065c9/src/jit/dis_arm64be.lua b/fluent-bit/lib/luajit-3065c9/src/jit/dis_arm64be.lua new file mode 100644 index 00000000..7337f5b7 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/jit/dis_arm64be.lua @@ -0,0 +1,12 @@ +---------------------------------------------------------------------------- +-- LuaJIT ARM64BE disassembler wrapper module. +-- +-- Copyright (C) 2005-2022 Mike Pall. All rights reserved. +-- Released under the MIT license. See Copyright Notice in luajit.h +---------------------------------------------------------------------------- +-- ARM64 instructions are always little-endian. So just forward to the +-- common ARM64 disassembler module. All the interesting stuff is there. +------------------------------------------------------------------------------ + +return require((string.match(..., ".*%.") or "").."dis_arm64") + diff --git a/fluent-bit/lib/luajit-3065c9/src/jit/dis_mips.lua b/fluent-bit/lib/luajit-3065c9/src/jit/dis_mips.lua new file mode 100644 index 00000000..05dc30fd --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/jit/dis_mips.lua @@ -0,0 +1,694 @@ +---------------------------------------------------------------------------- +-- LuaJIT MIPS disassembler module. +-- +-- Copyright (C) 2005-2022 Mike Pall. All rights reserved. +-- Released under the MIT/X license. See Copyright Notice in luajit.h +---------------------------------------------------------------------------- +-- This is a helper module used by the LuaJIT machine code dumper module. +-- +-- It disassembles all standard MIPS32R1/R2 instructions. +-- Default mode is big-endian, but see: dis_mipsel.lua +------------------------------------------------------------------------------ + +local type = type +local byte, format = string.byte, string.format +local match, gmatch = string.match, string.gmatch +local concat = table.concat +local bit = require("bit") +local band, bor, tohex = bit.band, bit.bor, bit.tohex +local lshift, rshift, arshift = bit.lshift, bit.rshift, bit.arshift + +------------------------------------------------------------------------------ +-- Extended opcode maps common to all MIPS releases +------------------------------------------------------------------------------ + +local map_srl = { shift = 21, mask = 1, [0] = "srlDTA", "rotrDTA", } +local map_srlv = { shift = 6, mask = 1, [0] = "srlvDTS", "rotrvDTS", } + +local map_cop0 = { + shift = 25, mask = 1, + [0] = { + shift = 21, mask = 15, + [0] = "mfc0TDW", [4] = "mtc0TDW", + [10] = "rdpgprDT", + [11] = { shift = 5, mask = 1, [0] = "diT0", "eiT0", }, + [14] = "wrpgprDT", + }, { + shift = 0, mask = 63, + [1] = "tlbr", [2] = "tlbwi", [6] = "tlbwr", [8] = "tlbp", + [24] = "eret", [31] = "deret", + [32] = "wait", + }, +} + +------------------------------------------------------------------------------ +-- Primary and extended opcode maps for MIPS R1-R5 +------------------------------------------------------------------------------ + +local map_movci = { shift = 16, mask = 1, [0] = "movfDSC", "movtDSC", } + +local map_special = { + shift = 0, mask = 63, + [0] = { shift = 0, mask = -1, [0] = "nop", _ = "sllDTA" }, + map_movci, map_srl, "sraDTA", + "sllvDTS", false, map_srlv, "sravDTS", + "jrS", "jalrD1S", "movzDST", "movnDST", + "syscallY", "breakY", false, "sync", + "mfhiD", "mthiS", "mfloD", "mtloS", + "dsllvDST", false, "dsrlvDST", "dsravDST", + "multST", "multuST", "divST", "divuST", + "dmultST", "dmultuST", "ddivST", "ddivuST", + "addDST", "addu|moveDST0", "subDST", "subu|neguDS0T", + "andDST", "or|moveDST0", "xorDST", "nor|notDST0", + false, false, "sltDST", "sltuDST", + "daddDST", "dadduDST", "dsubDST", "dsubuDST", + "tgeSTZ", "tgeuSTZ", "tltSTZ", "tltuSTZ", + "teqSTZ", false, "tneSTZ", false, + "dsllDTA", false, "dsrlDTA", "dsraDTA", + "dsll32DTA", false, "dsrl32DTA", "dsra32DTA", +} + +local map_special2 = { + shift = 0, mask = 63, + [0] = "maddST", "madduST", "mulDST", false, + "msubST", "msubuST", + [32] = "clzDS", [33] = "cloDS", + [63] = "sdbbpY", +} + +local map_bshfl = { + shift = 6, mask = 31, + [2] = "wsbhDT", + [16] = "sebDT", + [24] = "sehDT", +} + +local map_dbshfl = { + shift = 6, mask = 31, + [2] = "dsbhDT", + [5] = "dshdDT", +} + +local map_special3 = { + shift = 0, mask = 63, + [0] = "extTSAK", [1] = "dextmTSAP", [3] = "dextTSAK", + [4] = "insTSAL", [6] = "dinsuTSEQ", [7] = "dinsTSAL", + [32] = map_bshfl, [36] = map_dbshfl, [59] = "rdhwrTD", +} + +local map_regimm = { + shift = 16, mask = 31, + [0] = "bltzSB", "bgezSB", "bltzlSB", "bgezlSB", + false, false, false, false, + "tgeiSI", "tgeiuSI", "tltiSI", "tltiuSI", + "teqiSI", false, "tneiSI", false, + "bltzalSB", "bgezalSB", "bltzallSB", "bgezallSB", + false, false, false, false, + false, false, false, false, + false, false, false, "synciSO", +} + +local map_cop1s = { + shift = 0, mask = 63, + [0] = "add.sFGH", "sub.sFGH", "mul.sFGH", "div.sFGH", + "sqrt.sFG", "abs.sFG", "mov.sFG", "neg.sFG", + "round.l.sFG", "trunc.l.sFG", "ceil.l.sFG", "floor.l.sFG", + "round.w.sFG", "trunc.w.sFG", "ceil.w.sFG", "floor.w.sFG", + false, + { shift = 16, mask = 1, [0] = "movf.sFGC", "movt.sFGC" }, + "movz.sFGT", "movn.sFGT", + false, "recip.sFG", "rsqrt.sFG", false, + false, false, false, false, + false, false, false, false, + false, "cvt.d.sFG", false, false, + "cvt.w.sFG", "cvt.l.sFG", "cvt.ps.sFGH", false, + false, false, false, false, + false, false, false, false, + "c.f.sVGH", "c.un.sVGH", "c.eq.sVGH", "c.ueq.sVGH", + "c.olt.sVGH", "c.ult.sVGH", "c.ole.sVGH", "c.ule.sVGH", + "c.sf.sVGH", "c.ngle.sVGH", "c.seq.sVGH", "c.ngl.sVGH", + "c.lt.sVGH", "c.nge.sVGH", "c.le.sVGH", "c.ngt.sVGH", +} + +local map_cop1d = { + shift = 0, mask = 63, + [0] = "add.dFGH", "sub.dFGH", "mul.dFGH", "div.dFGH", + "sqrt.dFG", "abs.dFG", "mov.dFG", "neg.dFG", + "round.l.dFG", "trunc.l.dFG", "ceil.l.dFG", "floor.l.dFG", + "round.w.dFG", "trunc.w.dFG", "ceil.w.dFG", "floor.w.dFG", + false, + { shift = 16, mask = 1, [0] = "movf.dFGC", "movt.dFGC" }, + "movz.dFGT", "movn.dFGT", + false, "recip.dFG", "rsqrt.dFG", false, + false, false, false, false, + false, false, false, false, + "cvt.s.dFG", false, false, false, + "cvt.w.dFG", "cvt.l.dFG", false, false, + false, false, false, false, + false, false, false, false, + "c.f.dVGH", "c.un.dVGH", "c.eq.dVGH", "c.ueq.dVGH", + "c.olt.dVGH", "c.ult.dVGH", "c.ole.dVGH", "c.ule.dVGH", + "c.df.dVGH", "c.ngle.dVGH", "c.deq.dVGH", "c.ngl.dVGH", + "c.lt.dVGH", "c.nge.dVGH", "c.le.dVGH", "c.ngt.dVGH", +} + +local map_cop1ps = { + shift = 0, mask = 63, + [0] = "add.psFGH", "sub.psFGH", "mul.psFGH", false, + false, "abs.psFG", "mov.psFG", "neg.psFG", + false, false, false, false, + false, false, false, false, + false, + { shift = 16, mask = 1, [0] = "movf.psFGC", "movt.psFGC" }, + "movz.psFGT", "movn.psFGT", + false, false, false, false, + false, false, false, false, + false, false, false, false, + "cvt.s.puFG", false, false, false, + false, false, false, false, + "cvt.s.plFG", false, false, false, + "pll.psFGH", "plu.psFGH", "pul.psFGH", "puu.psFGH", + "c.f.psVGH", "c.un.psVGH", "c.eq.psVGH", "c.ueq.psVGH", + "c.olt.psVGH", "c.ult.psVGH", "c.ole.psVGH", "c.ule.psVGH", + "c.psf.psVGH", "c.ngle.psVGH", "c.pseq.psVGH", "c.ngl.psVGH", + "c.lt.psVGH", "c.nge.psVGH", "c.le.psVGH", "c.ngt.psVGH", +} + +local map_cop1w = { + shift = 0, mask = 63, + [32] = "cvt.s.wFG", [33] = "cvt.d.wFG", +} + +local map_cop1l = { + shift = 0, mask = 63, + [32] = "cvt.s.lFG", [33] = "cvt.d.lFG", +} + +local map_cop1bc = { + shift = 16, mask = 3, + [0] = "bc1fCB", "bc1tCB", "bc1flCB", "bc1tlCB", +} + +local map_cop1 = { + shift = 21, mask = 31, + [0] = "mfc1TG", "dmfc1TG", "cfc1TG", "mfhc1TG", + "mtc1TG", "dmtc1TG", "ctc1TG", "mthc1TG", + map_cop1bc, false, false, false, + false, false, false, false, + map_cop1s, map_cop1d, false, false, + map_cop1w, map_cop1l, map_cop1ps, +} + +local map_cop1x = { + shift = 0, mask = 63, + [0] = "lwxc1FSX", "ldxc1FSX", false, false, + false, "luxc1FSX", false, false, + "swxc1FSX", "sdxc1FSX", false, false, + false, "suxc1FSX", false, "prefxMSX", + false, false, false, false, + false, false, false, false, + false, false, false, false, + false, false, "alnv.psFGHS", false, + "madd.sFRGH", "madd.dFRGH", false, false, + false, false, "madd.psFRGH", false, + "msub.sFRGH", "msub.dFRGH", false, false, + false, false, "msub.psFRGH", false, + "nmadd.sFRGH", "nmadd.dFRGH", false, false, + false, false, "nmadd.psFRGH", false, + "nmsub.sFRGH", "nmsub.dFRGH", false, false, + false, false, "nmsub.psFRGH", false, +} + +local map_pri = { + [0] = map_special, map_regimm, "jJ", "jalJ", + "beq|beqz|bST00B", "bne|bnezST0B", "blezSB", "bgtzSB", + "addiTSI", "addiu|liTS0I", "sltiTSI", "sltiuTSI", + "andiTSU", "ori|liTS0U", "xoriTSU", "luiTU", + map_cop0, map_cop1, false, map_cop1x, + "beql|beqzlST0B", "bnel|bnezlST0B", "blezlSB", "bgtzlSB", + "daddiTSI", "daddiuTSI", false, false, + map_special2, "jalxJ", false, map_special3, + "lbTSO", "lhTSO", "lwlTSO", "lwTSO", + "lbuTSO", "lhuTSO", "lwrTSO", false, + "sbTSO", "shTSO", "swlTSO", "swTSO", + false, false, "swrTSO", "cacheNSO", + "llTSO", "lwc1HSO", "lwc2TSO", "prefNSO", + false, "ldc1HSO", "ldc2TSO", "ldTSO", + "scTSO", "swc1HSO", "swc2TSO", false, + false, "sdc1HSO", "sdc2TSO", "sdTSO", +} + +------------------------------------------------------------------------------ +-- Primary and extended opcode maps for MIPS R6 +------------------------------------------------------------------------------ + +local map_mul_r6 = { shift = 6, mask = 3, [2] = "mulDST", [3] = "muhDST" } +local map_mulu_r6 = { shift = 6, mask = 3, [2] = "muluDST", [3] = "muhuDST" } +local map_div_r6 = { shift = 6, mask = 3, [2] = "divDST", [3] = "modDST" } +local map_divu_r6 = { shift = 6, mask = 3, [2] = "divuDST", [3] = "moduDST" } +local map_dmul_r6 = { shift = 6, mask = 3, [2] = "dmulDST", [3] = "dmuhDST" } +local map_dmulu_r6 = { shift = 6, mask = 3, [2] = "dmuluDST", [3] = "dmuhuDST" } +local map_ddiv_r6 = { shift = 6, mask = 3, [2] = "ddivDST", [3] = "dmodDST" } +local map_ddivu_r6 = { shift = 6, mask = 3, [2] = "ddivuDST", [3] = "dmoduDST" } + +local map_special_r6 = { + shift = 0, mask = 63, + [0] = { shift = 0, mask = -1, [0] = "nop", _ = "sllDTA" }, + false, map_srl, "sraDTA", + "sllvDTS", false, map_srlv, "sravDTS", + "jrS", "jalrD1S", false, false, + "syscallY", "breakY", false, "sync", + "clzDS", "cloDS", "dclzDS", "dcloDS", + "dsllvDST", "dlsaDSTA", "dsrlvDST", "dsravDST", + map_mul_r6, map_mulu_r6, map_div_r6, map_divu_r6, + map_dmul_r6, map_dmulu_r6, map_ddiv_r6, map_ddivu_r6, + "addDST", "addu|moveDST0", "subDST", "subu|neguDS0T", + "andDST", "or|moveDST0", "xorDST", "nor|notDST0", + false, false, "sltDST", "sltuDST", + "daddDST", "dadduDST", "dsubDST", "dsubuDST", + "tgeSTZ", "tgeuSTZ", "tltSTZ", "tltuSTZ", + "teqSTZ", "seleqzDST", "tneSTZ", "selnezDST", + "dsllDTA", false, "dsrlDTA", "dsraDTA", + "dsll32DTA", false, "dsrl32DTA", "dsra32DTA", +} + +local map_bshfl_r6 = { + shift = 9, mask = 3, + [1] = "alignDSTa", + _ = { + shift = 6, mask = 31, + [0] = "bitswapDT", + [2] = "wsbhDT", + [16] = "sebDT", + [24] = "sehDT", + } +} + +local map_dbshfl_r6 = { + shift = 9, mask = 3, + [1] = "dalignDSTa", + _ = { + shift = 6, mask = 31, + [0] = "dbitswapDT", + [2] = "dsbhDT", + [5] = "dshdDT", + } +} + +local map_special3_r6 = { + shift = 0, mask = 63, + [0] = "extTSAK", [1] = "dextmTSAP", [3] = "dextTSAK", + [4] = "insTSAL", [6] = "dinsuTSEQ", [7] = "dinsTSAL", + [32] = map_bshfl_r6, [36] = map_dbshfl_r6, [59] = "rdhwrTD", +} + +local map_regimm_r6 = { + shift = 16, mask = 31, + [0] = "bltzSB", [1] = "bgezSB", + [6] = "dahiSI", [30] = "datiSI", + [23] = "sigrieI", [31] = "synciSO", +} + +local map_pcrel_r6 = { + shift = 19, mask = 3, + [0] = "addiupcS2", "lwpcS2", "lwupcS2", { + shift = 18, mask = 1, + [0] = "ldpcS3", { shift = 16, mask = 3, [2] = "auipcSI", [3] = "aluipcSI" } + } +} + +local map_cop1s_r6 = { + shift = 0, mask = 63, + [0] = "add.sFGH", "sub.sFGH", "mul.sFGH", "div.sFGH", + "sqrt.sFG", "abs.sFG", "mov.sFG", "neg.sFG", + "round.l.sFG", "trunc.l.sFG", "ceil.l.sFG", "floor.l.sFG", + "round.w.sFG", "trunc.w.sFG", "ceil.w.sFG", "floor.w.sFG", + "sel.sFGH", false, false, false, + "seleqz.sFGH", "recip.sFG", "rsqrt.sFG", "selnez.sFGH", + "maddf.sFGH", "msubf.sFGH", "rint.sFG", "class.sFG", + "min.sFGH", "mina.sFGH", "max.sFGH", "maxa.sFGH", + false, "cvt.d.sFG", false, false, + "cvt.w.sFG", "cvt.l.sFG", +} + +local map_cop1d_r6 = { + shift = 0, mask = 63, + [0] = "add.dFGH", "sub.dFGH", "mul.dFGH", "div.dFGH", + "sqrt.dFG", "abs.dFG", "mov.dFG", "neg.dFG", + "round.l.dFG", "trunc.l.dFG", "ceil.l.dFG", "floor.l.dFG", + "round.w.dFG", "trunc.w.dFG", "ceil.w.dFG", "floor.w.dFG", + "sel.dFGH", false, false, false, + "seleqz.dFGH", "recip.dFG", "rsqrt.dFG", "selnez.dFGH", + "maddf.dFGH", "msubf.dFGH", "rint.dFG", "class.dFG", + "min.dFGH", "mina.dFGH", "max.dFGH", "maxa.dFGH", + "cvt.s.dFG", false, false, false, + "cvt.w.dFG", "cvt.l.dFG", +} + +local map_cop1w_r6 = { + shift = 0, mask = 63, + [0] = "cmp.af.sFGH", "cmp.un.sFGH", "cmp.eq.sFGH", "cmp.ueq.sFGH", + "cmp.lt.sFGH", "cmp.ult.sFGH", "cmp.le.sFGH", "cmp.ule.sFGH", + "cmp.saf.sFGH", "cmp.sun.sFGH", "cmp.seq.sFGH", "cmp.sueq.sFGH", + "cmp.slt.sFGH", "cmp.sult.sFGH", "cmp.sle.sFGH", "cmp.sule.sFGH", + false, "cmp.or.sFGH", "cmp.une.sFGH", "cmp.ne.sFGH", + false, false, false, false, + false, "cmp.sor.sFGH", "cmp.sune.sFGH", "cmp.sne.sFGH", + false, false, false, false, + "cvt.s.wFG", "cvt.d.wFG", +} + +local map_cop1l_r6 = { + shift = 0, mask = 63, + [0] = "cmp.af.dFGH", "cmp.un.dFGH", "cmp.eq.dFGH", "cmp.ueq.dFGH", + "cmp.lt.dFGH", "cmp.ult.dFGH", "cmp.le.dFGH", "cmp.ule.dFGH", + "cmp.saf.dFGH", "cmp.sun.dFGH", "cmp.seq.dFGH", "cmp.sueq.dFGH", + "cmp.slt.dFGH", "cmp.sult.dFGH", "cmp.sle.dFGH", "cmp.sule.dFGH", + false, "cmp.or.dFGH", "cmp.une.dFGH", "cmp.ne.dFGH", + false, false, false, false, + false, "cmp.sor.dFGH", "cmp.sune.dFGH", "cmp.sne.dFGH", + false, false, false, false, + "cvt.s.lFG", "cvt.d.lFG", +} + +local map_cop1_r6 = { + shift = 21, mask = 31, + [0] = "mfc1TG", "dmfc1TG", "cfc1TG", "mfhc1TG", + "mtc1TG", "dmtc1TG", "ctc1TG", "mthc1TG", + false, "bc1eqzHB", false, false, + false, "bc1nezHB", false, false, + map_cop1s_r6, map_cop1d_r6, false, false, + map_cop1w_r6, map_cop1l_r6, +} + +local function maprs_popTS(rs, rt) + if rt == 0 then return 0 elseif rs == 0 then return 1 + elseif rs == rt then return 2 else return 3 end +end + +local map_pop06_r6 = { + maprs = maprs_popTS, [0] = "blezSB", "blezalcTB", "bgezalcTB", "bgeucSTB" +} +local map_pop07_r6 = { + maprs = maprs_popTS, [0] = "bgtzSB", "bgtzalcTB", "bltzalcTB", "bltucSTB" +} +local map_pop26_r6 = { + maprs = maprs_popTS, "blezcTB", "bgezcTB", "bgecSTB" +} +local map_pop27_r6 = { + maprs = maprs_popTS, "bgtzcTB", "bltzcTB", "bltcSTB" +} + +local function maprs_popS(rs, rt) + if rs == 0 then return 0 else return 1 end +end + +local map_pop66_r6 = { + maprs = maprs_popS, [0] = "jicTI", "beqzcSb" +} +local map_pop76_r6 = { + maprs = maprs_popS, [0] = "jialcTI", "bnezcSb" +} + +local function maprs_popST(rs, rt) + if rs >= rt then return 0 elseif rs == 0 then return 1 else return 2 end +end + +local map_pop10_r6 = { + maprs = maprs_popST, [0] = "bovcSTB", "beqzalcTB", "beqcSTB" +} +local map_pop30_r6 = { + maprs = maprs_popST, [0] = "bnvcSTB", "bnezalcTB", "bnecSTB" +} + +local map_pri_r6 = { + [0] = map_special_r6, map_regimm_r6, "jJ", "jalJ", + "beq|beqz|bST00B", "bne|bnezST0B", map_pop06_r6, map_pop07_r6, + map_pop10_r6, "addiu|liTS0I", "sltiTSI", "sltiuTSI", + "andiTSU", "ori|liTS0U", "xoriTSU", "aui|luiTS0U", + map_cop0, map_cop1_r6, false, false, + false, false, map_pop26_r6, map_pop27_r6, + map_pop30_r6, "daddiuTSI", false, false, + false, "dauiTSI", false, map_special3_r6, + "lbTSO", "lhTSO", false, "lwTSO", + "lbuTSO", "lhuTSO", false, false, + "sbTSO", "shTSO", false, "swTSO", + false, false, false, false, + false, "lwc1HSO", "bc#", false, + false, "ldc1HSO", map_pop66_r6, "ldTSO", + false, "swc1HSO", "balc#", map_pcrel_r6, + false, "sdc1HSO", map_pop76_r6, "sdTSO", +} + +------------------------------------------------------------------------------ + +local map_gpr = { + [0] = "r0", "r1", "r2", "r3", "r4", "r5", "r6", "r7", + "r8", "r9", "r10", "r11", "r12", "r13", "r14", "r15", + "r16", "r17", "r18", "r19", "r20", "r21", "r22", "r23", + "r24", "r25", "r26", "r27", "r28", "sp", "r30", "ra", +} + +------------------------------------------------------------------------------ + +-- Output a nicely formatted line with an opcode and operands. +local function putop(ctx, text, operands) + local pos = ctx.pos + local extra = "" + if ctx.rel then + local sym = ctx.symtab[ctx.rel] + if sym then extra = "\t->"..sym end + end + if ctx.hexdump > 0 then + ctx.out(format("%08x %s %-7s %s%s\n", + ctx.addr+pos, tohex(ctx.op), text, concat(operands, ", "), extra)) + else + ctx.out(format("%08x %-7s %s%s\n", + ctx.addr+pos, text, concat(operands, ", "), extra)) + end + ctx.pos = pos + 4 +end + +-- Fallback for unknown opcodes. +local function unknown(ctx) + return putop(ctx, ".long", { "0x"..tohex(ctx.op) }) +end + +local function get_be(ctx) + local pos = ctx.pos + local b0, b1, b2, b3 = byte(ctx.code, pos+1, pos+4) + return bor(lshift(b0, 24), lshift(b1, 16), lshift(b2, 8), b3) +end + +local function get_le(ctx) + local pos = ctx.pos + local b0, b1, b2, b3 = byte(ctx.code, pos+1, pos+4) + return bor(lshift(b3, 24), lshift(b2, 16), lshift(b1, 8), b0) +end + +-- Disassemble a single instruction. +local function disass_ins(ctx) + local op = ctx:get() + local operands = {} + local last = nil + ctx.op = op + ctx.rel = nil + + local opat = ctx.map_pri[rshift(op, 26)] + while type(opat) ~= "string" do + if not opat then return unknown(ctx) end + if opat.maprs then + opat = opat[opat.maprs(band(rshift(op,21),31), band(rshift(op,16),31))] + else + opat = opat[band(rshift(op, opat.shift), opat.mask)] or opat._ + end + end + local name, pat = match(opat, "^([a-z0-9_.]*)(.*)") + local altname, pat2 = match(pat, "|([a-z0-9_.|]*)(.*)") + if altname then pat = pat2 end + + for p in gmatch(pat, ".") do + local x = nil + if p == "S" then + x = map_gpr[band(rshift(op, 21), 31)] + elseif p == "T" then + x = map_gpr[band(rshift(op, 16), 31)] + elseif p == "D" then + x = map_gpr[band(rshift(op, 11), 31)] + elseif p == "F" then + x = "f"..band(rshift(op, 6), 31) + elseif p == "G" then + x = "f"..band(rshift(op, 11), 31) + elseif p == "H" then + x = "f"..band(rshift(op, 16), 31) + elseif p == "R" then + x = "f"..band(rshift(op, 21), 31) + elseif p == "A" then + x = band(rshift(op, 6), 31) + elseif p == "a" then + x = band(rshift(op, 6), 7) + elseif p == "E" then + x = band(rshift(op, 6), 31) + 32 + elseif p == "M" then + x = band(rshift(op, 11), 31) + elseif p == "N" then + x = band(rshift(op, 16), 31) + elseif p == "C" then + x = band(rshift(op, 18), 7) + if x == 0 then x = nil end + elseif p == "K" then + x = band(rshift(op, 11), 31) + 1 + elseif p == "P" then + x = band(rshift(op, 11), 31) + 33 + elseif p == "L" then + x = band(rshift(op, 11), 31) - last + 1 + elseif p == "Q" then + x = band(rshift(op, 11), 31) - last + 33 + elseif p == "I" then + x = arshift(lshift(op, 16), 16) + elseif p == "2" then + x = arshift(lshift(op, 13), 11) + elseif p == "3" then + x = arshift(lshift(op, 14), 11) + elseif p == "U" then + x = band(op, 0xffff) + elseif p == "O" then + local disp = arshift(lshift(op, 16), 16) + operands[#operands] = format("%d(%s)", disp, last) + elseif p == "X" then + local index = map_gpr[band(rshift(op, 16), 31)] + operands[#operands] = format("%s(%s)", index, last) + elseif p == "B" then + x = ctx.addr + ctx.pos + arshift(lshift(op, 16), 14) + 4 + ctx.rel = x + x = format("0x%08x", x) + elseif p == "b" then + x = ctx.addr + ctx.pos + arshift(lshift(op, 11), 9) + 4 + ctx.rel = x + x = format("0x%08x", x) + elseif p == "#" then + x = ctx.addr + ctx.pos + arshift(lshift(op, 6), 4) + 4 + ctx.rel = x + x = format("0x%08x", x) + elseif p == "J" then + local a = ctx.addr + ctx.pos + x = a - band(a, 0x0fffffff) + band(op, 0x03ffffff)*4 + ctx.rel = x + x = format("0x%08x", x) + elseif p == "V" then + x = band(rshift(op, 8), 7) + if x == 0 then x = nil end + elseif p == "W" then + x = band(op, 7) + if x == 0 then x = nil end + elseif p == "Y" then + x = band(rshift(op, 6), 0x000fffff) + if x == 0 then x = nil end + elseif p == "Z" then + x = band(rshift(op, 6), 1023) + if x == 0 then x = nil end + elseif p == "0" then + if last == "r0" or last == 0 then + local n = #operands + operands[n] = nil + last = operands[n-1] + if altname then + local a1, a2 = match(altname, "([^|]*)|(.*)") + if a1 then name, altname = a1, a2 + else name = altname end + end + end + elseif p == "1" then + if last == "ra" then + operands[#operands] = nil + end + else + assert(false) + end + if x then operands[#operands+1] = x; last = x end + end + + return putop(ctx, name, operands) +end + +------------------------------------------------------------------------------ + +-- Disassemble a block of code. +local function disass_block(ctx, ofs, len) + if not ofs then ofs = 0 end + local stop = len and ofs+len or #ctx.code + stop = stop - stop % 4 + ctx.pos = ofs - ofs % 4 + ctx.rel = nil + while ctx.pos < stop do disass_ins(ctx) end +end + +-- Extended API: create a disassembler context. Then call ctx:disass(ofs, len). +local function create(code, addr, out) + local ctx = {} + ctx.code = code + ctx.addr = addr or 0 + ctx.out = out or io.write + ctx.symtab = {} + ctx.disass = disass_block + ctx.hexdump = 8 + ctx.get = get_be + ctx.map_pri = map_pri + return ctx +end + +local function create_el(code, addr, out) + local ctx = create(code, addr, out) + ctx.get = get_le + return ctx +end + +local function create_r6(code, addr, out) + local ctx = create(code, addr, out) + ctx.map_pri = map_pri_r6 + return ctx +end + +local function create_r6_el(code, addr, out) + local ctx = create(code, addr, out) + ctx.get = get_le + ctx.map_pri = map_pri_r6 + return ctx +end + +-- Simple API: disassemble code (a string) at address and output via out. +local function disass(code, addr, out) + create(code, addr, out):disass() +end + +local function disass_el(code, addr, out) + create_el(code, addr, out):disass() +end + +local function disass_r6(code, addr, out) + create_r6(code, addr, out):disass() +end + +local function disass_r6_el(code, addr, out) + create_r6_el(code, addr, out):disass() +end + +-- Return register name for RID. +local function regname(r) + if r < 32 then return map_gpr[r] end + return "f"..(r-32) +end + +-- Public module functions. +return { + create = create, + create_el = create_el, + create_r6 = create_r6, + create_r6_el = create_r6_el, + disass = disass, + disass_el = disass_el, + disass_r6 = disass_r6, + disass_r6_el = disass_r6_el, + regname = regname +} + diff --git a/fluent-bit/lib/luajit-3065c9/src/jit/dis_mips64.lua b/fluent-bit/lib/luajit-3065c9/src/jit/dis_mips64.lua new file mode 100644 index 00000000..1236e524 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/jit/dis_mips64.lua @@ -0,0 +1,17 @@ +---------------------------------------------------------------------------- +-- LuaJIT MIPS64 disassembler wrapper module. +-- +-- Copyright (C) 2005-2022 Mike Pall. All rights reserved. +-- Released under the MIT license. See Copyright Notice in luajit.h +---------------------------------------------------------------------------- +-- This module just exports the big-endian functions from the +-- MIPS disassembler module. All the interesting stuff is there. +------------------------------------------------------------------------------ + +local dis_mips = require((string.match(..., ".*%.") or "").."dis_mips") +return { + create = dis_mips.create, + disass = dis_mips.disass, + regname = dis_mips.regname +} + diff --git a/fluent-bit/lib/luajit-3065c9/src/jit/dis_mips64el.lua b/fluent-bit/lib/luajit-3065c9/src/jit/dis_mips64el.lua new file mode 100644 index 00000000..7c478d2d --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/jit/dis_mips64el.lua @@ -0,0 +1,17 @@ +---------------------------------------------------------------------------- +-- LuaJIT MIPS64EL disassembler wrapper module. +-- +-- Copyright (C) 2005-2022 Mike Pall. All rights reserved. +-- Released under the MIT license. See Copyright Notice in luajit.h +---------------------------------------------------------------------------- +-- This module just exports the little-endian functions from the +-- MIPS disassembler module. All the interesting stuff is there. +------------------------------------------------------------------------------ + +local dis_mips = require((string.match(..., ".*%.") or "").."dis_mips") +return { + create = dis_mips.create_el, + disass = dis_mips.disass_el, + regname = dis_mips.regname +} + diff --git a/fluent-bit/lib/luajit-3065c9/src/jit/dis_mips64r6.lua b/fluent-bit/lib/luajit-3065c9/src/jit/dis_mips64r6.lua new file mode 100644 index 00000000..c5789ce4 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/jit/dis_mips64r6.lua @@ -0,0 +1,17 @@ +---------------------------------------------------------------------------- +-- LuaJIT MIPS64R6 disassembler wrapper module. +-- +-- Copyright (C) 2005-2022 Mike Pall. All rights reserved. +-- Released under the MIT license. See Copyright Notice in luajit.h +---------------------------------------------------------------------------- +-- This module just exports the r6 big-endian functions from the +-- MIPS disassembler module. All the interesting stuff is there. +------------------------------------------------------------------------------ + +local dis_mips = require((string.match(..., ".*%.") or "").."dis_mips") +return { + create = dis_mips.create_r6, + disass = dis_mips.disass_r6, + regname = dis_mips.regname +} + diff --git a/fluent-bit/lib/luajit-3065c9/src/jit/dis_mips64r6el.lua b/fluent-bit/lib/luajit-3065c9/src/jit/dis_mips64r6el.lua new file mode 100644 index 00000000..f67f6240 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/jit/dis_mips64r6el.lua @@ -0,0 +1,17 @@ +---------------------------------------------------------------------------- +-- LuaJIT MIPS64R6EL disassembler wrapper module. +-- +-- Copyright (C) 2005-2022 Mike Pall. All rights reserved. +-- Released under the MIT license. See Copyright Notice in luajit.h +---------------------------------------------------------------------------- +-- This module just exports the r6 little-endian functions from the +-- MIPS disassembler module. All the interesting stuff is there. +------------------------------------------------------------------------------ + +local dis_mips = require((string.match(..., ".*%.") or "").."dis_mips") +return { + create = dis_mips.create_r6_el, + disass = dis_mips.disass_r6_el, + regname = dis_mips.regname +} + diff --git a/fluent-bit/lib/luajit-3065c9/src/jit/dis_mipsel.lua b/fluent-bit/lib/luajit-3065c9/src/jit/dis_mipsel.lua new file mode 100644 index 00000000..a4fa6c60 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/jit/dis_mipsel.lua @@ -0,0 +1,17 @@ +---------------------------------------------------------------------------- +-- LuaJIT MIPSEL disassembler wrapper module. +-- +-- Copyright (C) 2005-2022 Mike Pall. All rights reserved. +-- Released under the MIT license. See Copyright Notice in luajit.h +---------------------------------------------------------------------------- +-- This module just exports the little-endian functions from the +-- MIPS disassembler module. All the interesting stuff is there. +------------------------------------------------------------------------------ + +local dis_mips = require((string.match(..., ".*%.") or "").."dis_mips") +return { + create = dis_mips.create_el, + disass = dis_mips.disass_el, + regname = dis_mips.regname +} + diff --git a/fluent-bit/lib/luajit-3065c9/src/jit/dis_ppc.lua b/fluent-bit/lib/luajit-3065c9/src/jit/dis_ppc.lua new file mode 100644 index 00000000..8f65f25a --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/jit/dis_ppc.lua @@ -0,0 +1,591 @@ +---------------------------------------------------------------------------- +-- LuaJIT PPC disassembler module. +-- +-- Copyright (C) 2005-2022 Mike Pall. All rights reserved. +-- Released under the MIT/X license. See Copyright Notice in luajit.h +---------------------------------------------------------------------------- +-- This is a helper module used by the LuaJIT machine code dumper module. +-- +-- It disassembles all common, non-privileged 32/64 bit PowerPC instructions +-- plus the e500 SPE instructions and some Cell/Xenon extensions. +-- +-- NYI: VMX, VMX128 +------------------------------------------------------------------------------ + +local type = type +local byte, format = string.byte, string.format +local match, gmatch, gsub = string.match, string.gmatch, string.gsub +local concat = table.concat +local bit = require("bit") +local band, bor, tohex = bit.band, bit.bor, bit.tohex +local lshift, rshift, arshift = bit.lshift, bit.rshift, bit.arshift + +------------------------------------------------------------------------------ +-- Primary and extended opcode maps +------------------------------------------------------------------------------ + +local map_crops = { + shift = 1, mask = 1023, + [0] = "mcrfXX", + [33] = "crnor|crnotCCC=", [129] = "crandcCCC", + [193] = "crxor|crclrCCC%", [225] = "crnandCCC", + [257] = "crandCCC", [289] = "creqv|crsetCCC%", + [417] = "crorcCCC", [449] = "cror|crmoveCCC=", + [16] = "b_lrKB", [528] = "b_ctrKB", + [150] = "isync", +} + +local map_rlwinm = setmetatable({ + shift = 0, mask = -1, +}, +{ __index = function(t, x) + local rot = band(rshift(x, 11), 31) + local mb = band(rshift(x, 6), 31) + local me = band(rshift(x, 1), 31) + if mb == 0 and me == 31-rot then + return "slwiRR~A." + elseif me == 31 and mb == 32-rot then + return "srwiRR~-A." + else + return "rlwinmRR~AAA." + end + end +}) + +local map_rld = { + shift = 2, mask = 7, + [0] = "rldiclRR~HM.", "rldicrRR~HM.", "rldicRR~HM.", "rldimiRR~HM.", + { + shift = 1, mask = 1, + [0] = "rldclRR~RM.", "rldcrRR~RM.", + }, +} + +local map_ext = setmetatable({ + shift = 1, mask = 1023, + + [0] = "cmp_YLRR", [32] = "cmpl_YLRR", + [4] = "twARR", [68] = "tdARR", + + [8] = "subfcRRR.", [40] = "subfRRR.", + [104] = "negRR.", [136] = "subfeRRR.", + [200] = "subfzeRR.", [232] = "subfmeRR.", + [520] = "subfcoRRR.", [552] = "subfoRRR.", + [616] = "negoRR.", [648] = "subfeoRRR.", + [712] = "subfzeoRR.", [744] = "subfmeoRR.", + + [9] = "mulhduRRR.", [73] = "mulhdRRR.", [233] = "mulldRRR.", + [457] = "divduRRR.", [489] = "divdRRR.", + [745] = "mulldoRRR.", + [969] = "divduoRRR.", [1001] = "divdoRRR.", + + [10] = "addcRRR.", [138] = "addeRRR.", + [202] = "addzeRR.", [234] = "addmeRR.", [266] = "addRRR.", + [522] = "addcoRRR.", [650] = "addeoRRR.", + [714] = "addzeoRR.", [746] = "addmeoRR.", [778] = "addoRRR.", + + [11] = "mulhwuRRR.", [75] = "mulhwRRR.", [235] = "mullwRRR.", + [459] = "divwuRRR.", [491] = "divwRRR.", + [747] = "mullwoRRR.", + [971] = "divwouRRR.", [1003] = "divwoRRR.", + + [15] = "iselltRRR", [47] = "iselgtRRR", [79] = "iseleqRRR", + + [144] = { shift = 20, mask = 1, [0] = "mtcrfRZ~", "mtocrfRZ~", }, + [19] = { shift = 20, mask = 1, [0] = "mfcrR", "mfocrfRZ", }, + [371] = { shift = 11, mask = 1023, [392] = "mftbR", [424] = "mftbuR", }, + [339] = { + shift = 11, mask = 1023, + [32] = "mferR", [256] = "mflrR", [288] = "mfctrR", [16] = "mfspefscrR", + }, + [467] = { + shift = 11, mask = 1023, + [32] = "mtxerR", [256] = "mtlrR", [288] = "mtctrR", [16] = "mtspefscrR", + }, + + [20] = "lwarxRR0R", [84] = "ldarxRR0R", + + [21] = "ldxRR0R", [53] = "lduxRRR", + [149] = "stdxRR0R", [181] = "stduxRRR", + [341] = "lwaxRR0R", [373] = "lwauxRRR", + + [23] = "lwzxRR0R", [55] = "lwzuxRRR", + [87] = "lbzxRR0R", [119] = "lbzuxRRR", + [151] = "stwxRR0R", [183] = "stwuxRRR", + [215] = "stbxRR0R", [247] = "stbuxRRR", + [279] = "lhzxRR0R", [311] = "lhzuxRRR", + [343] = "lhaxRR0R", [375] = "lhauxRRR", + [407] = "sthxRR0R", [439] = "sthuxRRR", + + [54] = "dcbst-R0R", [86] = "dcbf-R0R", + [150] = "stwcxRR0R.", [214] = "stdcxRR0R.", + [246] = "dcbtst-R0R", [278] = "dcbt-R0R", + [310] = "eciwxRR0R", [438] = "ecowxRR0R", + [470] = "dcbi-RR", + + [598] = { + shift = 21, mask = 3, + [0] = "sync", "lwsync", "ptesync", + }, + [758] = "dcba-RR", + [854] = "eieio", [982] = "icbi-R0R", [1014] = "dcbz-R0R", + + [26] = "cntlzwRR~", [58] = "cntlzdRR~", + [122] = "popcntbRR~", + [154] = "prtywRR~", [186] = "prtydRR~", + + [28] = "andRR~R.", [60] = "andcRR~R.", [124] = "nor|notRR~R=.", + [284] = "eqvRR~R.", [316] = "xorRR~R.", + [412] = "orcRR~R.", [444] = "or|mrRR~R=.", [476] = "nandRR~R.", + [508] = "cmpbRR~R", + + [512] = "mcrxrX", + + [532] = "ldbrxRR0R", [660] = "stdbrxRR0R", + + [533] = "lswxRR0R", [597] = "lswiRR0A", + [661] = "stswxRR0R", [725] = "stswiRR0A", + + [534] = "lwbrxRR0R", [662] = "stwbrxRR0R", + [790] = "lhbrxRR0R", [918] = "sthbrxRR0R", + + [535] = "lfsxFR0R", [567] = "lfsuxFRR", + [599] = "lfdxFR0R", [631] = "lfduxFRR", + [663] = "stfsxFR0R", [695] = "stfsuxFRR", + [727] = "stfdxFR0R", [759] = "stfduxFR0R", + [855] = "lfiwaxFR0R", + [983] = "stfiwxFR0R", + + [24] = "slwRR~R.", + + [27] = "sldRR~R.", [536] = "srwRR~R.", + [792] = "srawRR~R.", [824] = "srawiRR~A.", + + [794] = "sradRR~R.", [826] = "sradiRR~H.", [827] = "sradiRR~H.", + [922] = "extshRR~.", [954] = "extsbRR~.", [986] = "extswRR~.", + + [539] = "srdRR~R.", +}, +{ __index = function(t, x) + if band(x, 31) == 15 then return "iselRRRC" end + end +}) + +local map_ld = { + shift = 0, mask = 3, + [0] = "ldRRE", "lduRRE", "lwaRRE", +} + +local map_std = { + shift = 0, mask = 3, + [0] = "stdRRE", "stduRRE", +} + +local map_fps = { + shift = 5, mask = 1, + { + shift = 1, mask = 15, + [0] = false, false, "fdivsFFF.", false, + "fsubsFFF.", "faddsFFF.", "fsqrtsF-F.", false, + "fresF-F.", "fmulsFF-F.", "frsqrtesF-F.", false, + "fmsubsFFFF~.", "fmaddsFFFF~.", "fnmsubsFFFF~.", "fnmaddsFFFF~.", + } +} + +local map_fpd = { + shift = 5, mask = 1, + [0] = { + shift = 1, mask = 1023, + [0] = "fcmpuXFF", [32] = "fcmpoXFF", [64] = "mcrfsXX", + [38] = "mtfsb1A.", [70] = "mtfsb0A.", [134] = "mtfsfiA>>-A>", + [8] = "fcpsgnFFF.", [40] = "fnegF-F.", [72] = "fmrF-F.", + [136] = "fnabsF-F.", [264] = "fabsF-F.", + [12] = "frspF-F.", + [14] = "fctiwF-F.", [15] = "fctiwzF-F.", + [583] = "mffsF.", [711] = "mtfsfZF.", + [392] = "frinF-F.", [424] = "frizF-F.", + [456] = "fripF-F.", [488] = "frimF-F.", + [814] = "fctidF-F.", [815] = "fctidzF-F.", [846] = "fcfidF-F.", + }, + { + shift = 1, mask = 15, + [0] = false, false, "fdivFFF.", false, + "fsubFFF.", "faddFFF.", "fsqrtF-F.", "fselFFFF~.", + "freF-F.", "fmulFF-F.", "frsqrteF-F.", false, + "fmsubFFFF~.", "fmaddFFFF~.", "fnmsubFFFF~.", "fnmaddFFFF~.", + } +} + +local map_spe = { + shift = 0, mask = 2047, + + [512] = "evaddwRRR", [514] = "evaddiwRAR~", + [516] = "evsubwRRR~", [518] = "evsubiwRAR~", + [520] = "evabsRR", [521] = "evnegRR", + [522] = "evextsbRR", [523] = "evextshRR", [524] = "evrndwRR", + [525] = "evcntlzwRR", [526] = "evcntlswRR", + + [527] = "brincRRR", + + [529] = "evandRRR", [530] = "evandcRRR", [534] = "evxorRRR", + [535] = "evor|evmrRRR=", [536] = "evnor|evnotRRR=", + [537] = "eveqvRRR", [539] = "evorcRRR", [542] = "evnandRRR", + + [544] = "evsrwuRRR", [545] = "evsrwsRRR", + [546] = "evsrwiuRRA", [547] = "evsrwisRRA", + [548] = "evslwRRR", [550] = "evslwiRRA", + [552] = "evrlwRRR", [553] = "evsplatiRS", + [554] = "evrlwiRRA", [555] = "evsplatfiRS", + [556] = "evmergehiRRR", [557] = "evmergeloRRR", + [558] = "evmergehiloRRR", [559] = "evmergelohiRRR", + + [560] = "evcmpgtuYRR", [561] = "evcmpgtsYRR", + [562] = "evcmpltuYRR", [563] = "evcmpltsYRR", + [564] = "evcmpeqYRR", + + [632] = "evselRRR", [633] = "evselRRRW", + [634] = "evselRRRW", [635] = "evselRRRW", + [636] = "evselRRRW", [637] = "evselRRRW", + [638] = "evselRRRW", [639] = "evselRRRW", + + [640] = "evfsaddRRR", [641] = "evfssubRRR", + [644] = "evfsabsRR", [645] = "evfsnabsRR", [646] = "evfsnegRR", + [648] = "evfsmulRRR", [649] = "evfsdivRRR", + [652] = "evfscmpgtYRR", [653] = "evfscmpltYRR", [654] = "evfscmpeqYRR", + [656] = "evfscfuiR-R", [657] = "evfscfsiR-R", + [658] = "evfscfufR-R", [659] = "evfscfsfR-R", + [660] = "evfsctuiR-R", [661] = "evfsctsiR-R", + [662] = "evfsctufR-R", [663] = "evfsctsfR-R", + [664] = "evfsctuizR-R", [666] = "evfsctsizR-R", + [668] = "evfststgtYRR", [669] = "evfststltYRR", [670] = "evfststeqYRR", + + [704] = "efsaddRRR", [705] = "efssubRRR", + [708] = "efsabsRR", [709] = "efsnabsRR", [710] = "efsnegRR", + [712] = "efsmulRRR", [713] = "efsdivRRR", + [716] = "efscmpgtYRR", [717] = "efscmpltYRR", [718] = "efscmpeqYRR", + [719] = "efscfdR-R", + [720] = "efscfuiR-R", [721] = "efscfsiR-R", + [722] = "efscfufR-R", [723] = "efscfsfR-R", + [724] = "efsctuiR-R", [725] = "efsctsiR-R", + [726] = "efsctufR-R", [727] = "efsctsfR-R", + [728] = "efsctuizR-R", [730] = "efsctsizR-R", + [732] = "efststgtYRR", [733] = "efststltYRR", [734] = "efststeqYRR", + + [736] = "efdaddRRR", [737] = "efdsubRRR", + [738] = "efdcfuidR-R", [739] = "efdcfsidR-R", + [740] = "efdabsRR", [741] = "efdnabsRR", [742] = "efdnegRR", + [744] = "efdmulRRR", [745] = "efddivRRR", + [746] = "efdctuidzR-R", [747] = "efdctsidzR-R", + [748] = "efdcmpgtYRR", [749] = "efdcmpltYRR", [750] = "efdcmpeqYRR", + [751] = "efdcfsR-R", + [752] = "efdcfuiR-R", [753] = "efdcfsiR-R", + [754] = "efdcfufR-R", [755] = "efdcfsfR-R", + [756] = "efdctuiR-R", [757] = "efdctsiR-R", + [758] = "efdctufR-R", [759] = "efdctsfR-R", + [760] = "efdctuizR-R", [762] = "efdctsizR-R", + [764] = "efdtstgtYRR", [765] = "efdtstltYRR", [766] = "efdtsteqYRR", + + [768] = "evlddxRR0R", [769] = "evlddRR8", + [770] = "evldwxRR0R", [771] = "evldwRR8", + [772] = "evldhxRR0R", [773] = "evldhRR8", + [776] = "evlhhesplatxRR0R", [777] = "evlhhesplatRR2", + [780] = "evlhhousplatxRR0R", [781] = "evlhhousplatRR2", + [782] = "evlhhossplatxRR0R", [783] = "evlhhossplatRR2", + [784] = "evlwhexRR0R", [785] = "evlwheRR4", + [788] = "evlwhouxRR0R", [789] = "evlwhouRR4", + [790] = "evlwhosxRR0R", [791] = "evlwhosRR4", + [792] = "evlwwsplatxRR0R", [793] = "evlwwsplatRR4", + [796] = "evlwhsplatxRR0R", [797] = "evlwhsplatRR4", + + [800] = "evstddxRR0R", [801] = "evstddRR8", + [802] = "evstdwxRR0R", [803] = "evstdwRR8", + [804] = "evstdhxRR0R", [805] = "evstdhRR8", + [816] = "evstwhexRR0R", [817] = "evstwheRR4", + [820] = "evstwhoxRR0R", [821] = "evstwhoRR4", + [824] = "evstwwexRR0R", [825] = "evstwweRR4", + [828] = "evstwwoxRR0R", [829] = "evstwwoRR4", + + [1027] = "evmhessfRRR", [1031] = "evmhossfRRR", [1032] = "evmheumiRRR", + [1033] = "evmhesmiRRR", [1035] = "evmhesmfRRR", [1036] = "evmhoumiRRR", + [1037] = "evmhosmiRRR", [1039] = "evmhosmfRRR", [1059] = "evmhessfaRRR", + [1063] = "evmhossfaRRR", [1064] = "evmheumiaRRR", [1065] = "evmhesmiaRRR", + [1067] = "evmhesmfaRRR", [1068] = "evmhoumiaRRR", [1069] = "evmhosmiaRRR", + [1071] = "evmhosmfaRRR", [1095] = "evmwhssfRRR", [1096] = "evmwlumiRRR", + [1100] = "evmwhumiRRR", [1101] = "evmwhsmiRRR", [1103] = "evmwhsmfRRR", + [1107] = "evmwssfRRR", [1112] = "evmwumiRRR", [1113] = "evmwsmiRRR", + [1115] = "evmwsmfRRR", [1127] = "evmwhssfaRRR", [1128] = "evmwlumiaRRR", + [1132] = "evmwhumiaRRR", [1133] = "evmwhsmiaRRR", [1135] = "evmwhsmfaRRR", + [1139] = "evmwssfaRRR", [1144] = "evmwumiaRRR", [1145] = "evmwsmiaRRR", + [1147] = "evmwsmfaRRR", + + [1216] = "evaddusiaawRR", [1217] = "evaddssiaawRR", + [1218] = "evsubfusiaawRR", [1219] = "evsubfssiaawRR", + [1220] = "evmraRR", + [1222] = "evdivwsRRR", [1223] = "evdivwuRRR", + [1224] = "evaddumiaawRR", [1225] = "evaddsmiaawRR", + [1226] = "evsubfumiaawRR", [1227] = "evsubfsmiaawRR", + + [1280] = "evmheusiaawRRR", [1281] = "evmhessiaawRRR", + [1283] = "evmhessfaawRRR", [1284] = "evmhousiaawRRR", + [1285] = "evmhossiaawRRR", [1287] = "evmhossfaawRRR", + [1288] = "evmheumiaawRRR", [1289] = "evmhesmiaawRRR", + [1291] = "evmhesmfaawRRR", [1292] = "evmhoumiaawRRR", + [1293] = "evmhosmiaawRRR", [1295] = "evmhosmfaawRRR", + [1320] = "evmhegumiaaRRR", [1321] = "evmhegsmiaaRRR", + [1323] = "evmhegsmfaaRRR", [1324] = "evmhogumiaaRRR", + [1325] = "evmhogsmiaaRRR", [1327] = "evmhogsmfaaRRR", + [1344] = "evmwlusiaawRRR", [1345] = "evmwlssiaawRRR", + [1352] = "evmwlumiaawRRR", [1353] = "evmwlsmiaawRRR", + [1363] = "evmwssfaaRRR", [1368] = "evmwumiaaRRR", + [1369] = "evmwsmiaaRRR", [1371] = "evmwsmfaaRRR", + [1408] = "evmheusianwRRR", [1409] = "evmhessianwRRR", + [1411] = "evmhessfanwRRR", [1412] = "evmhousianwRRR", + [1413] = "evmhossianwRRR", [1415] = "evmhossfanwRRR", + [1416] = "evmheumianwRRR", [1417] = "evmhesmianwRRR", + [1419] = "evmhesmfanwRRR", [1420] = "evmhoumianwRRR", + [1421] = "evmhosmianwRRR", [1423] = "evmhosmfanwRRR", + [1448] = "evmhegumianRRR", [1449] = "evmhegsmianRRR", + [1451] = "evmhegsmfanRRR", [1452] = "evmhogumianRRR", + [1453] = "evmhogsmianRRR", [1455] = "evmhogsmfanRRR", + [1472] = "evmwlusianwRRR", [1473] = "evmwlssianwRRR", + [1480] = "evmwlumianwRRR", [1481] = "evmwlsmianwRRR", + [1491] = "evmwssfanRRR", [1496] = "evmwumianRRR", + [1497] = "evmwsmianRRR", [1499] = "evmwsmfanRRR", +} + +local map_pri = { + [0] = false, false, "tdiARI", "twiARI", + map_spe, false, false, "mulliRRI", + "subficRRI", false, "cmpl_iYLRU", "cmp_iYLRI", + "addicRRI", "addic.RRI", "addi|liRR0I", "addis|lisRR0I", + "b_KBJ", "sc", "bKJ", map_crops, + "rlwimiRR~AAA.", map_rlwinm, false, "rlwnmRR~RAA.", + "oriNRR~U", "orisRR~U", "xoriRR~U", "xorisRR~U", + "andi.RR~U", "andis.RR~U", map_rld, map_ext, + "lwzRRD", "lwzuRRD", "lbzRRD", "lbzuRRD", + "stwRRD", "stwuRRD", "stbRRD", "stbuRRD", + "lhzRRD", "lhzuRRD", "lhaRRD", "lhauRRD", + "sthRRD", "sthuRRD", "lmwRRD", "stmwRRD", + "lfsFRD", "lfsuFRD", "lfdFRD", "lfduFRD", + "stfsFRD", "stfsuFRD", "stfdFRD", "stfduFRD", + false, false, map_ld, map_fps, + false, false, map_std, map_fpd, +} + +------------------------------------------------------------------------------ + +local map_gpr = { + [0] = "r0", "sp", "r2", "r3", "r4", "r5", "r6", "r7", + "r8", "r9", "r10", "r11", "r12", "r13", "r14", "r15", + "r16", "r17", "r18", "r19", "r20", "r21", "r22", "r23", + "r24", "r25", "r26", "r27", "r28", "r29", "r30", "r31", +} + +local map_cond = { [0] = "lt", "gt", "eq", "so", "ge", "le", "ne", "ns", } + +-- Format a condition bit. +local function condfmt(cond) + if cond <= 3 then + return map_cond[band(cond, 3)] + else + return format("4*cr%d+%s", rshift(cond, 2), map_cond[band(cond, 3)]) + end +end + +------------------------------------------------------------------------------ + +-- Output a nicely formatted line with an opcode and operands. +local function putop(ctx, text, operands) + local pos = ctx.pos + local extra = "" + if ctx.rel then + local sym = ctx.symtab[ctx.rel] + if sym then extra = "\t->"..sym end + end + if ctx.hexdump > 0 then + ctx.out(format("%08x %s %-7s %s%s\n", + ctx.addr+pos, tohex(ctx.op), text, concat(operands, ", "), extra)) + else + ctx.out(format("%08x %-7s %s%s\n", + ctx.addr+pos, text, concat(operands, ", "), extra)) + end + ctx.pos = pos + 4 +end + +-- Fallback for unknown opcodes. +local function unknown(ctx) + return putop(ctx, ".long", { "0x"..tohex(ctx.op) }) +end + +-- Disassemble a single instruction. +local function disass_ins(ctx) + local pos = ctx.pos + local b0, b1, b2, b3 = byte(ctx.code, pos+1, pos+4) + local op = bor(lshift(b0, 24), lshift(b1, 16), lshift(b2, 8), b3) + local operands = {} + local last = nil + local rs = 21 + ctx.op = op + ctx.rel = nil + + local opat = map_pri[rshift(b0, 2)] + while type(opat) ~= "string" do + if not opat then return unknown(ctx) end + opat = opat[band(rshift(op, opat.shift), opat.mask)] + end + local name, pat = match(opat, "^([a-z0-9_.]*)(.*)") + local altname, pat2 = match(pat, "|([a-z0-9_.]*)(.*)") + if altname then pat = pat2 end + + for p in gmatch(pat, ".") do + local x = nil + if p == "R" then + x = map_gpr[band(rshift(op, rs), 31)] + rs = rs - 5 + elseif p == "F" then + x = "f"..band(rshift(op, rs), 31) + rs = rs - 5 + elseif p == "A" then + x = band(rshift(op, rs), 31) + rs = rs - 5 + elseif p == "S" then + x = arshift(lshift(op, 27-rs), 27) + rs = rs - 5 + elseif p == "I" then + x = arshift(lshift(op, 16), 16) + elseif p == "U" then + x = band(op, 0xffff) + elseif p == "D" or p == "E" then + local disp = arshift(lshift(op, 16), 16) + if p == "E" then disp = band(disp, -4) end + if last == "r0" then last = "0" end + operands[#operands] = format("%d(%s)", disp, last) + elseif p >= "2" and p <= "8" then + local disp = band(rshift(op, rs), 31) * p + if last == "r0" then last = "0" end + operands[#operands] = format("%d(%s)", disp, last) + elseif p == "H" then + x = band(rshift(op, rs), 31) + lshift(band(op, 2), 4) + rs = rs - 5 + elseif p == "M" then + x = band(rshift(op, rs), 31) + band(op, 0x20) + elseif p == "C" then + x = condfmt(band(rshift(op, rs), 31)) + rs = rs - 5 + elseif p == "B" then + local bo = rshift(op, 21) + local cond = band(rshift(op, 16), 31) + local cn = "" + rs = rs - 10 + if band(bo, 4) == 0 then + cn = band(bo, 2) == 0 and "dnz" or "dz" + if band(bo, 0x10) == 0 then + cn = cn..(band(bo, 8) == 0 and "f" or "t") + end + if band(bo, 0x10) == 0 then x = condfmt(cond) end + name = name..(band(bo, 1) == band(rshift(op, 15), 1) and "-" or "+") + elseif band(bo, 0x10) == 0 then + cn = map_cond[band(cond, 3) + (band(bo, 8) == 0 and 4 or 0)] + if cond > 3 then x = "cr"..rshift(cond, 2) end + name = name..(band(bo, 1) == band(rshift(op, 15), 1) and "-" or "+") + end + name = gsub(name, "_", cn) + elseif p == "J" then + x = arshift(lshift(op, 27-rs), 29-rs)*4 + if band(op, 2) == 0 then x = ctx.addr + pos + x end + ctx.rel = x + x = "0x"..tohex(x) + elseif p == "K" then + if band(op, 1) ~= 0 then name = name.."l" end + if band(op, 2) ~= 0 then name = name.."a" end + elseif p == "X" or p == "Y" then + x = band(rshift(op, rs+2), 7) + if x == 0 and p == "Y" then x = nil else x = "cr"..x end + rs = rs - 5 + elseif p == "W" then + x = "cr"..band(op, 7) + elseif p == "Z" then + x = band(rshift(op, rs-4), 255) + rs = rs - 10 + elseif p == ">" then + operands[#operands] = rshift(operands[#operands], 1) + elseif p == "0" then + if last == "r0" then + operands[#operands] = nil + if altname then name = altname end + end + elseif p == "L" then + name = gsub(name, "_", band(op, 0x00200000) ~= 0 and "d" or "w") + elseif p == "." then + if band(op, 1) == 1 then name = name.."." end + elseif p == "N" then + if op == 0x60000000 then name = "nop"; break end + elseif p == "~" then + local n = #operands + operands[n-1], operands[n] = operands[n], operands[n-1] + elseif p == "=" then + local n = #operands + if last == operands[n-1] then + operands[n] = nil + name = altname + end + elseif p == "%" then + local n = #operands + if last == operands[n-1] and last == operands[n-2] then + operands[n] = nil + operands[n-1] = nil + name = altname + end + elseif p == "-" then + rs = rs - 5 + else + assert(false) + end + if x then operands[#operands+1] = x; last = x end + end + + return putop(ctx, name, operands) +end + +------------------------------------------------------------------------------ + +-- Disassemble a block of code. +local function disass_block(ctx, ofs, len) + if not ofs then ofs = 0 end + local stop = len and ofs+len or #ctx.code + stop = stop - stop % 4 + ctx.pos = ofs - ofs % 4 + ctx.rel = nil + while ctx.pos < stop do disass_ins(ctx) end +end + +-- Extended API: create a disassembler context. Then call ctx:disass(ofs, len). +local function create(code, addr, out) + local ctx = {} + ctx.code = code + ctx.addr = addr or 0 + ctx.out = out or io.write + ctx.symtab = {} + ctx.disass = disass_block + ctx.hexdump = 8 + return ctx +end + +-- Simple API: disassemble code (a string) at address and output via out. +local function disass(code, addr, out) + create(code, addr, out):disass() +end + +-- Return register name for RID. +local function regname(r) + if r < 32 then return map_gpr[r] end + return "f"..(r-32) +end + +-- Public module functions. +return { + create = create, + disass = disass, + regname = regname +} + diff --git a/fluent-bit/lib/luajit-3065c9/src/jit/dis_x64.lua b/fluent-bit/lib/luajit-3065c9/src/jit/dis_x64.lua new file mode 100644 index 00000000..d076c6ae --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/jit/dis_x64.lua @@ -0,0 +1,17 @@ +---------------------------------------------------------------------------- +-- LuaJIT x64 disassembler wrapper module. +-- +-- Copyright (C) 2005-2022 Mike Pall. All rights reserved. +-- Released under the MIT license. See Copyright Notice in luajit.h +---------------------------------------------------------------------------- +-- This module just exports the 64 bit functions from the combined +-- x86/x64 disassembler module. All the interesting stuff is there. +------------------------------------------------------------------------------ + +local dis_x86 = require((string.match(..., ".*%.") or "").."dis_x86") +return { + create = dis_x86.create64, + disass = dis_x86.disass64, + regname = dis_x86.regname64 +} + diff --git a/fluent-bit/lib/luajit-3065c9/src/jit/dis_x86.lua b/fluent-bit/lib/luajit-3065c9/src/jit/dis_x86.lua new file mode 100644 index 00000000..84492fff --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/jit/dis_x86.lua @@ -0,0 +1,953 @@ +---------------------------------------------------------------------------- +-- LuaJIT x86/x64 disassembler module. +-- +-- Copyright (C) 2005-2022 Mike Pall. All rights reserved. +-- Released under the MIT license. See Copyright Notice in luajit.h +---------------------------------------------------------------------------- +-- This is a helper module used by the LuaJIT machine code dumper module. +-- +-- Sending small code snippets to an external disassembler and mixing the +-- output with our own stuff was too fragile. So I had to bite the bullet +-- and write yet another x86 disassembler. Oh well ... +-- +-- The output format is very similar to what ndisasm generates. But it has +-- been developed independently by looking at the opcode tables from the +-- Intel and AMD manuals. The supported instruction set is quite extensive +-- and reflects what a current generation Intel or AMD CPU implements in +-- 32 bit and 64 bit mode. Yes, this includes MMX, SSE, SSE2, SSE3, SSSE3, +-- SSE4.1, SSE4.2, SSE4a, AVX, AVX2 and even privileged and hypervisor +-- (VMX/SVM) instructions. +-- +-- Notes: +-- * The (useless) a16 prefix, 3DNow and pre-586 opcodes are unsupported. +-- * No attempt at optimization has been made -- it's fast enough for my needs. +------------------------------------------------------------------------------ + +local type = type +local sub, byte, format = string.sub, string.byte, string.format +local match, gmatch, gsub = string.match, string.gmatch, string.gsub +local lower, rep = string.lower, string.rep +local bit = require("bit") +local tohex = bit.tohex + +-- Map for 1st opcode byte in 32 bit mode. Ugly? Well ... read on. +local map_opc1_32 = { +--0x +[0]="addBmr","addVmr","addBrm","addVrm","addBai","addVai","push es","pop es", +"orBmr","orVmr","orBrm","orVrm","orBai","orVai","push cs","opc2*", +--1x +"adcBmr","adcVmr","adcBrm","adcVrm","adcBai","adcVai","push ss","pop ss", +"sbbBmr","sbbVmr","sbbBrm","sbbVrm","sbbBai","sbbVai","push ds","pop ds", +--2x +"andBmr","andVmr","andBrm","andVrm","andBai","andVai","es:seg","daa", +"subBmr","subVmr","subBrm","subVrm","subBai","subVai","cs:seg","das", +--3x +"xorBmr","xorVmr","xorBrm","xorVrm","xorBai","xorVai","ss:seg","aaa", +"cmpBmr","cmpVmr","cmpBrm","cmpVrm","cmpBai","cmpVai","ds:seg","aas", +--4x +"incVR","incVR","incVR","incVR","incVR","incVR","incVR","incVR", +"decVR","decVR","decVR","decVR","decVR","decVR","decVR","decVR", +--5x +"pushUR","pushUR","pushUR","pushUR","pushUR","pushUR","pushUR","pushUR", +"popUR","popUR","popUR","popUR","popUR","popUR","popUR","popUR", +--6x +"sz*pushaw,pusha","sz*popaw,popa","boundVrm","arplWmr", +"fs:seg","gs:seg","o16:","a16", +"pushUi","imulVrmi","pushBs","imulVrms", +"insb","insVS","outsb","outsVS", +--7x +"joBj","jnoBj","jbBj","jnbBj","jzBj","jnzBj","jbeBj","jaBj", +"jsBj","jnsBj","jpeBj","jpoBj","jlBj","jgeBj","jleBj","jgBj", +--8x +"arith!Bmi","arith!Vmi","arith!Bmi","arith!Vms", +"testBmr","testVmr","xchgBrm","xchgVrm", +"movBmr","movVmr","movBrm","movVrm", +"movVmg","leaVrm","movWgm","popUm", +--9x +"nop*xchgVaR|pause|xchgWaR|repne nop","xchgVaR","xchgVaR","xchgVaR", +"xchgVaR","xchgVaR","xchgVaR","xchgVaR", +"sz*cbw,cwde,cdqe","sz*cwd,cdq,cqo","call farViw","wait", +"sz*pushfw,pushf","sz*popfw,popf","sahf","lahf", +--Ax +"movBao","movVao","movBoa","movVoa", +"movsb","movsVS","cmpsb","cmpsVS", +"testBai","testVai","stosb","stosVS", +"lodsb","lodsVS","scasb","scasVS", +--Bx +"movBRi","movBRi","movBRi","movBRi","movBRi","movBRi","movBRi","movBRi", +"movVRI","movVRI","movVRI","movVRI","movVRI","movVRI","movVRI","movVRI", +--Cx +"shift!Bmu","shift!Vmu","retBw","ret","vex*3$lesVrm","vex*2$ldsVrm","movBmi","movVmi", +"enterBwu","leave","retfBw","retf","int3","intBu","into","iretVS", +--Dx +"shift!Bm1","shift!Vm1","shift!Bmc","shift!Vmc","aamBu","aadBu","salc","xlatb", +"fp*0","fp*1","fp*2","fp*3","fp*4","fp*5","fp*6","fp*7", +--Ex +"loopneBj","loopeBj","loopBj","sz*jcxzBj,jecxzBj,jrcxzBj", +"inBau","inVau","outBua","outVua", +"callVj","jmpVj","jmp farViw","jmpBj","inBad","inVad","outBda","outVda", +--Fx +"lock:","int1","repne:rep","rep:","hlt","cmc","testb!Bm","testv!Vm", +"clc","stc","cli","sti","cld","std","incb!Bm","incd!Vm", +} +assert(#map_opc1_32 == 255) + +-- Map for 1st opcode byte in 64 bit mode (overrides only). +local map_opc1_64 = setmetatable({ + [0x06]=false, [0x07]=false, [0x0e]=false, + [0x16]=false, [0x17]=false, [0x1e]=false, [0x1f]=false, + [0x27]=false, [0x2f]=false, [0x37]=false, [0x3f]=false, + [0x60]=false, [0x61]=false, [0x62]=false, [0x63]="movsxdVrDmt", [0x67]="a32:", + [0x40]="rex*", [0x41]="rex*b", [0x42]="rex*x", [0x43]="rex*xb", + [0x44]="rex*r", [0x45]="rex*rb", [0x46]="rex*rx", [0x47]="rex*rxb", + [0x48]="rex*w", [0x49]="rex*wb", [0x4a]="rex*wx", [0x4b]="rex*wxb", + [0x4c]="rex*wr", [0x4d]="rex*wrb", [0x4e]="rex*wrx", [0x4f]="rex*wrxb", + [0x82]=false, [0x9a]=false, [0xc4]="vex*3", [0xc5]="vex*2", [0xce]=false, + [0xd4]=false, [0xd5]=false, [0xd6]=false, [0xea]=false, +}, { __index = map_opc1_32 }) + +-- Map for 2nd opcode byte (0F xx). True CISC hell. Hey, I told you. +-- Prefix dependent MMX/SSE opcodes: (none)|rep|o16|repne, -|F3|66|F2 +local map_opc2 = { +--0x +[0]="sldt!Dmp","sgdt!Ump","larVrm","lslVrm",nil,"syscall","clts","sysret", +"invd","wbinvd",nil,"ud1",nil,"$prefetch!Bm","femms","3dnowMrmu", +--1x +"movupsXrm|movssXrvm|movupdXrm|movsdXrvm", +"movupsXmr|movssXmvr|movupdXmr|movsdXmvr", +"movhlpsXrm$movlpsXrm|movsldupXrm|movlpdXrm|movddupXrm", +"movlpsXmr||movlpdXmr", +"unpcklpsXrvm||unpcklpdXrvm", +"unpckhpsXrvm||unpckhpdXrvm", +"movlhpsXrm$movhpsXrm|movshdupXrm|movhpdXrm", +"movhpsXmr||movhpdXmr", +"$prefetcht!Bm","hintnopVm","hintnopVm","hintnopVm", +"hintnopVm","hintnopVm","hintnopVm","hintnopVm", +--2x +"movUmx$","movUmy$","movUxm$","movUym$","movUmz$",nil,"movUzm$",nil, +"movapsXrm||movapdXrm", +"movapsXmr||movapdXmr", +"cvtpi2psXrMm|cvtsi2ssXrvVmt|cvtpi2pdXrMm|cvtsi2sdXrvVmt", +"movntpsXmr|movntssXmr|movntpdXmr|movntsdXmr", +"cvttps2piMrXm|cvttss2siVrXm|cvttpd2piMrXm|cvttsd2siVrXm", +"cvtps2piMrXm|cvtss2siVrXm|cvtpd2piMrXm|cvtsd2siVrXm", +"ucomissXrm||ucomisdXrm", +"comissXrm||comisdXrm", +--3x +"wrmsr","rdtsc","rdmsr","rdpmc","sysenter","sysexit",nil,"getsec", +"opc3*38",nil,"opc3*3a",nil,nil,nil,nil,nil, +--4x +"cmovoVrm","cmovnoVrm","cmovbVrm","cmovnbVrm", +"cmovzVrm","cmovnzVrm","cmovbeVrm","cmovaVrm", +"cmovsVrm","cmovnsVrm","cmovpeVrm","cmovpoVrm", +"cmovlVrm","cmovgeVrm","cmovleVrm","cmovgVrm", +--5x +"movmskpsVrXm$||movmskpdVrXm$","sqrtpsXrm|sqrtssXrm|sqrtpdXrm|sqrtsdXrm", +"rsqrtpsXrm|rsqrtssXrvm","rcppsXrm|rcpssXrvm", +"andpsXrvm||andpdXrvm","andnpsXrvm||andnpdXrvm", +"orpsXrvm||orpdXrvm","xorpsXrvm||xorpdXrvm", +"addpsXrvm|addssXrvm|addpdXrvm|addsdXrvm","mulpsXrvm|mulssXrvm|mulpdXrvm|mulsdXrvm", +"cvtps2pdXrm|cvtss2sdXrvm|cvtpd2psXrm|cvtsd2ssXrvm", +"cvtdq2psXrm|cvttps2dqXrm|cvtps2dqXrm", +"subpsXrvm|subssXrvm|subpdXrvm|subsdXrvm","minpsXrvm|minssXrvm|minpdXrvm|minsdXrvm", +"divpsXrvm|divssXrvm|divpdXrvm|divsdXrvm","maxpsXrvm|maxssXrvm|maxpdXrvm|maxsdXrvm", +--6x +"punpcklbwPrvm","punpcklwdPrvm","punpckldqPrvm","packsswbPrvm", +"pcmpgtbPrvm","pcmpgtwPrvm","pcmpgtdPrvm","packuswbPrvm", +"punpckhbwPrvm","punpckhwdPrvm","punpckhdqPrvm","packssdwPrvm", +"||punpcklqdqXrvm","||punpckhqdqXrvm", +"movPrVSm","movqMrm|movdquXrm|movdqaXrm", +--7x +"pshufwMrmu|pshufhwXrmu|pshufdXrmu|pshuflwXrmu","pshiftw!Pvmu", +"pshiftd!Pvmu","pshiftq!Mvmu||pshiftdq!Xvmu", +"pcmpeqbPrvm","pcmpeqwPrvm","pcmpeqdPrvm","emms*|", +"vmreadUmr||extrqXmuu$|insertqXrmuu$","vmwriteUrm||extrqXrm$|insertqXrm$", +nil,nil, +"||haddpdXrvm|haddpsXrvm","||hsubpdXrvm|hsubpsXrvm", +"movVSmMr|movqXrm|movVSmXr","movqMmr|movdquXmr|movdqaXmr", +--8x +"joVj","jnoVj","jbVj","jnbVj","jzVj","jnzVj","jbeVj","jaVj", +"jsVj","jnsVj","jpeVj","jpoVj","jlVj","jgeVj","jleVj","jgVj", +--9x +"setoBm","setnoBm","setbBm","setnbBm","setzBm","setnzBm","setbeBm","setaBm", +"setsBm","setnsBm","setpeBm","setpoBm","setlBm","setgeBm","setleBm","setgBm", +--Ax +"push fs","pop fs","cpuid","btVmr","shldVmru","shldVmrc",nil,nil, +"push gs","pop gs","rsm","btsVmr","shrdVmru","shrdVmrc","fxsave!Dmp","imulVrm", +--Bx +"cmpxchgBmr","cmpxchgVmr","$lssVrm","btrVmr", +"$lfsVrm","$lgsVrm","movzxVrBmt","movzxVrWmt", +"|popcntVrm","ud2Dp","bt!Vmu","btcVmr", +"bsfVrm","bsrVrm|lzcntVrm|bsrWrm","movsxVrBmt","movsxVrWmt", +--Cx +"xaddBmr","xaddVmr", +"cmppsXrvmu|cmpssXrvmu|cmppdXrvmu|cmpsdXrvmu","$movntiVmr|", +"pinsrwPrvWmu","pextrwDrPmu", +"shufpsXrvmu||shufpdXrvmu","$cmpxchg!Qmp", +"bswapVR","bswapVR","bswapVR","bswapVR","bswapVR","bswapVR","bswapVR","bswapVR", +--Dx +"||addsubpdXrvm|addsubpsXrvm","psrlwPrvm","psrldPrvm","psrlqPrvm", +"paddqPrvm","pmullwPrvm", +"|movq2dqXrMm|movqXmr|movdq2qMrXm$","pmovmskbVrMm||pmovmskbVrXm", +"psubusbPrvm","psubuswPrvm","pminubPrvm","pandPrvm", +"paddusbPrvm","padduswPrvm","pmaxubPrvm","pandnPrvm", +--Ex +"pavgbPrvm","psrawPrvm","psradPrvm","pavgwPrvm", +"pmulhuwPrvm","pmulhwPrvm", +"|cvtdq2pdXrm|cvttpd2dqXrm|cvtpd2dqXrm","$movntqMmr||$movntdqXmr", +"psubsbPrvm","psubswPrvm","pminswPrvm","porPrvm", +"paddsbPrvm","paddswPrvm","pmaxswPrvm","pxorPrvm", +--Fx +"|||lddquXrm","psllwPrvm","pslldPrvm","psllqPrvm", +"pmuludqPrvm","pmaddwdPrvm","psadbwPrvm","maskmovqMrm||maskmovdquXrm$", +"psubbPrvm","psubwPrvm","psubdPrvm","psubqPrvm", +"paddbPrvm","paddwPrvm","padddPrvm","ud", +} +assert(map_opc2[255] == "ud") + +-- Map for three-byte opcodes. Can't wait for their next invention. +local map_opc3 = { +["38"] = { -- [66] 0f 38 xx +--0x +[0]="pshufbPrvm","phaddwPrvm","phadddPrvm","phaddswPrvm", +"pmaddubswPrvm","phsubwPrvm","phsubdPrvm","phsubswPrvm", +"psignbPrvm","psignwPrvm","psigndPrvm","pmulhrswPrvm", +"||permilpsXrvm","||permilpdXrvm",nil,nil, +--1x +"||pblendvbXrma",nil,nil,nil, +"||blendvpsXrma","||blendvpdXrma","||permpsXrvm","||ptestXrm", +"||broadcastssXrm","||broadcastsdXrm","||broadcastf128XrlXm",nil, +"pabsbPrm","pabswPrm","pabsdPrm",nil, +--2x +"||pmovsxbwXrm","||pmovsxbdXrm","||pmovsxbqXrm","||pmovsxwdXrm", +"||pmovsxwqXrm","||pmovsxdqXrm",nil,nil, +"||pmuldqXrvm","||pcmpeqqXrvm","||$movntdqaXrm","||packusdwXrvm", +"||maskmovpsXrvm","||maskmovpdXrvm","||maskmovpsXmvr","||maskmovpdXmvr", +--3x +"||pmovzxbwXrm","||pmovzxbdXrm","||pmovzxbqXrm","||pmovzxwdXrm", +"||pmovzxwqXrm","||pmovzxdqXrm","||permdXrvm","||pcmpgtqXrvm", +"||pminsbXrvm","||pminsdXrvm","||pminuwXrvm","||pminudXrvm", +"||pmaxsbXrvm","||pmaxsdXrvm","||pmaxuwXrvm","||pmaxudXrvm", +--4x +"||pmulddXrvm","||phminposuwXrm",nil,nil, +nil,"||psrlvVSXrvm","||psravdXrvm","||psllvVSXrvm", +--5x +[0x58] = "||pbroadcastdXrlXm",[0x59] = "||pbroadcastqXrlXm", +[0x5a] = "||broadcasti128XrlXm", +--7x +[0x78] = "||pbroadcastbXrlXm",[0x79] = "||pbroadcastwXrlXm", +--8x +[0x8c] = "||pmaskmovXrvVSm", +[0x8e] = "||pmaskmovVSmXvr", +--9x +[0x96] = "||fmaddsub132pHXrvm",[0x97] = "||fmsubadd132pHXrvm", +[0x98] = "||fmadd132pHXrvm",[0x99] = "||fmadd132sHXrvm", +[0x9a] = "||fmsub132pHXrvm",[0x9b] = "||fmsub132sHXrvm", +[0x9c] = "||fnmadd132pHXrvm",[0x9d] = "||fnmadd132sHXrvm", +[0x9e] = "||fnmsub132pHXrvm",[0x9f] = "||fnmsub132sHXrvm", +--Ax +[0xa6] = "||fmaddsub213pHXrvm",[0xa7] = "||fmsubadd213pHXrvm", +[0xa8] = "||fmadd213pHXrvm",[0xa9] = "||fmadd213sHXrvm", +[0xaa] = "||fmsub213pHXrvm",[0xab] = "||fmsub213sHXrvm", +[0xac] = "||fnmadd213pHXrvm",[0xad] = "||fnmadd213sHXrvm", +[0xae] = "||fnmsub213pHXrvm",[0xaf] = "||fnmsub213sHXrvm", +--Bx +[0xb6] = "||fmaddsub231pHXrvm",[0xb7] = "||fmsubadd231pHXrvm", +[0xb8] = "||fmadd231pHXrvm",[0xb9] = "||fmadd231sHXrvm", +[0xba] = "||fmsub231pHXrvm",[0xbb] = "||fmsub231sHXrvm", +[0xbc] = "||fnmadd231pHXrvm",[0xbd] = "||fnmadd231sHXrvm", +[0xbe] = "||fnmsub231pHXrvm",[0xbf] = "||fnmsub231sHXrvm", +--Dx +[0xdc] = "||aesencXrvm", [0xdd] = "||aesenclastXrvm", +[0xde] = "||aesdecXrvm", [0xdf] = "||aesdeclastXrvm", +--Fx +[0xf0] = "|||crc32TrBmt",[0xf1] = "|||crc32TrVmt", +[0xf7] = "| sarxVrmv| shlxVrmv| shrxVrmv", +}, + +["3a"] = { -- [66] 0f 3a xx +--0x +[0x00]="||permqXrmu","||permpdXrmu","||pblenddXrvmu",nil, +"||permilpsXrmu","||permilpdXrmu","||perm2f128Xrvmu",nil, +"||roundpsXrmu","||roundpdXrmu","||roundssXrvmu","||roundsdXrvmu", +"||blendpsXrvmu","||blendpdXrvmu","||pblendwXrvmu","palignrPrvmu", +--1x +nil,nil,nil,nil, +"||pextrbVmXru","||pextrwVmXru","||pextrVmSXru","||extractpsVmXru", +"||insertf128XrvlXmu","||extractf128XlXmYru",nil,nil, +nil,nil,nil,nil, +--2x +"||pinsrbXrvVmu","||insertpsXrvmu","||pinsrXrvVmuS",nil, +--3x +[0x38] = "||inserti128Xrvmu",[0x39] = "||extracti128XlXmYru", +--4x +[0x40] = "||dppsXrvmu", +[0x41] = "||dppdXrvmu", +[0x42] = "||mpsadbwXrvmu", +[0x44] = "||pclmulqdqXrvmu", +[0x46] = "||perm2i128Xrvmu", +[0x4a] = "||blendvpsXrvmb",[0x4b] = "||blendvpdXrvmb", +[0x4c] = "||pblendvbXrvmb", +--6x +[0x60] = "||pcmpestrmXrmu",[0x61] = "||pcmpestriXrmu", +[0x62] = "||pcmpistrmXrmu",[0x63] = "||pcmpistriXrmu", +[0xdf] = "||aeskeygenassistXrmu", +--Fx +[0xf0] = "||| rorxVrmu", +}, +} + +-- Map for VMX/SVM opcodes 0F 01 C0-FF (sgdt group with register operands). +local map_opcvm = { +[0xc1]="vmcall",[0xc2]="vmlaunch",[0xc3]="vmresume",[0xc4]="vmxoff", +[0xc8]="monitor",[0xc9]="mwait", +[0xd8]="vmrun",[0xd9]="vmmcall",[0xda]="vmload",[0xdb]="vmsave", +[0xdc]="stgi",[0xdd]="clgi",[0xde]="skinit",[0xdf]="invlpga", +[0xf8]="swapgs",[0xf9]="rdtscp", +} + +-- Map for FP opcodes. And you thought stack machines are simple? +local map_opcfp = { +-- D8-DF 00-BF: opcodes with a memory operand. +-- D8 +[0]="faddFm","fmulFm","fcomFm","fcompFm","fsubFm","fsubrFm","fdivFm","fdivrFm", +"fldFm",nil,"fstFm","fstpFm","fldenvVm","fldcwWm","fnstenvVm","fnstcwWm", +-- DA +"fiaddDm","fimulDm","ficomDm","ficompDm", +"fisubDm","fisubrDm","fidivDm","fidivrDm", +-- DB +"fildDm","fisttpDm","fistDm","fistpDm",nil,"fld twordFmp",nil,"fstp twordFmp", +-- DC +"faddGm","fmulGm","fcomGm","fcompGm","fsubGm","fsubrGm","fdivGm","fdivrGm", +-- DD +"fldGm","fisttpQm","fstGm","fstpGm","frstorDmp",nil,"fnsaveDmp","fnstswWm", +-- DE +"fiaddWm","fimulWm","ficomWm","ficompWm", +"fisubWm","fisubrWm","fidivWm","fidivrWm", +-- DF +"fildWm","fisttpWm","fistWm","fistpWm", +"fbld twordFmp","fildQm","fbstp twordFmp","fistpQm", +-- xx C0-FF: opcodes with a pseudo-register operand. +-- D8 +"faddFf","fmulFf","fcomFf","fcompFf","fsubFf","fsubrFf","fdivFf","fdivrFf", +-- D9 +"fldFf","fxchFf",{"fnop"},nil, +{"fchs","fabs",nil,nil,"ftst","fxam"}, +{"fld1","fldl2t","fldl2e","fldpi","fldlg2","fldln2","fldz"}, +{"f2xm1","fyl2x","fptan","fpatan","fxtract","fprem1","fdecstp","fincstp"}, +{"fprem","fyl2xp1","fsqrt","fsincos","frndint","fscale","fsin","fcos"}, +-- DA +"fcmovbFf","fcmoveFf","fcmovbeFf","fcmovuFf",nil,{nil,"fucompp"},nil,nil, +-- DB +"fcmovnbFf","fcmovneFf","fcmovnbeFf","fcmovnuFf", +{nil,nil,"fnclex","fninit"},"fucomiFf","fcomiFf",nil, +-- DC +"fadd toFf","fmul toFf",nil,nil, +"fsub toFf","fsubr toFf","fdivr toFf","fdiv toFf", +-- DD +"ffreeFf",nil,"fstFf","fstpFf","fucomFf","fucompFf",nil,nil, +-- DE +"faddpFf","fmulpFf",nil,{nil,"fcompp"}, +"fsubrpFf","fsubpFf","fdivrpFf","fdivpFf", +-- DF +nil,nil,nil,nil,{"fnstsw ax"},"fucomipFf","fcomipFf",nil, +} +assert(map_opcfp[126] == "fcomipFf") + +-- Map for opcode groups. The subkey is sp from the ModRM byte. +local map_opcgroup = { + arith = { "add", "or", "adc", "sbb", "and", "sub", "xor", "cmp" }, + shift = { "rol", "ror", "rcl", "rcr", "shl", "shr", "sal", "sar" }, + testb = { "testBmi", "testBmi", "not", "neg", "mul", "imul", "div", "idiv" }, + testv = { "testVmi", "testVmi", "not", "neg", "mul", "imul", "div", "idiv" }, + incb = { "inc", "dec" }, + incd = { "inc", "dec", "callUmp", "$call farDmp", + "jmpUmp", "$jmp farDmp", "pushUm" }, + sldt = { "sldt", "str", "lldt", "ltr", "verr", "verw" }, + sgdt = { "vm*$sgdt", "vm*$sidt", "$lgdt", "vm*$lidt", + "smsw", nil, "lmsw", "vm*$invlpg" }, + bt = { nil, nil, nil, nil, "bt", "bts", "btr", "btc" }, + cmpxchg = { nil, "sz*,cmpxchg8bQmp,cmpxchg16bXmp", nil, nil, + nil, nil, "vmptrld|vmxon|vmclear", "vmptrst" }, + pshiftw = { nil, nil, "psrlw", nil, "psraw", nil, "psllw" }, + pshiftd = { nil, nil, "psrld", nil, "psrad", nil, "pslld" }, + pshiftq = { nil, nil, "psrlq", nil, nil, nil, "psllq" }, + pshiftdq = { nil, nil, "psrlq", "psrldq", nil, nil, "psllq", "pslldq" }, + fxsave = { "$fxsave", "$fxrstor", "$ldmxcsr", "$stmxcsr", + nil, "lfenceDp$", "mfenceDp$", "sfenceDp$clflush" }, + prefetch = { "prefetch", "prefetchw" }, + prefetcht = { "prefetchnta", "prefetcht0", "prefetcht1", "prefetcht2" }, +} + +------------------------------------------------------------------------------ + +-- Maps for register names. +local map_regs = { + B = { "al", "cl", "dl", "bl", "ah", "ch", "dh", "bh", + "r8b", "r9b", "r10b", "r11b", "r12b", "r13b", "r14b", "r15b" }, + B64 = { "al", "cl", "dl", "bl", "spl", "bpl", "sil", "dil", + "r8b", "r9b", "r10b", "r11b", "r12b", "r13b", "r14b", "r15b" }, + W = { "ax", "cx", "dx", "bx", "sp", "bp", "si", "di", + "r8w", "r9w", "r10w", "r11w", "r12w", "r13w", "r14w", "r15w" }, + D = { "eax", "ecx", "edx", "ebx", "esp", "ebp", "esi", "edi", + "r8d", "r9d", "r10d", "r11d", "r12d", "r13d", "r14d", "r15d" }, + Q = { "rax", "rcx", "rdx", "rbx", "rsp", "rbp", "rsi", "rdi", + "r8", "r9", "r10", "r11", "r12", "r13", "r14", "r15" }, + M = { "mm0", "mm1", "mm2", "mm3", "mm4", "mm5", "mm6", "mm7", + "mm0", "mm1", "mm2", "mm3", "mm4", "mm5", "mm6", "mm7" }, -- No x64 ext! + X = { "xmm0", "xmm1", "xmm2", "xmm3", "xmm4", "xmm5", "xmm6", "xmm7", + "xmm8", "xmm9", "xmm10", "xmm11", "xmm12", "xmm13", "xmm14", "xmm15" }, + Y = { "ymm0", "ymm1", "ymm2", "ymm3", "ymm4", "ymm5", "ymm6", "ymm7", + "ymm8", "ymm9", "ymm10", "ymm11", "ymm12", "ymm13", "ymm14", "ymm15" }, +} +local map_segregs = { "es", "cs", "ss", "ds", "fs", "gs", "segr6", "segr7" } + +-- Maps for size names. +local map_sz2n = { + B = 1, W = 2, D = 4, Q = 8, M = 8, X = 16, Y = 32, +} +local map_sz2prefix = { + B = "byte", W = "word", D = "dword", + Q = "qword", + M = "qword", X = "xword", Y = "yword", + F = "dword", G = "qword", -- No need for sizes/register names for these two. +} + +------------------------------------------------------------------------------ + +-- Output a nicely formatted line with an opcode and operands. +local function putop(ctx, text, operands) + local code, pos, hex = ctx.code, ctx.pos, "" + local hmax = ctx.hexdump + if hmax > 0 then + for i=ctx.start,pos-1 do + hex = hex..format("%02X", byte(code, i, i)) + end + if #hex > hmax then hex = sub(hex, 1, hmax)..". " + else hex = hex..rep(" ", hmax-#hex+2) end + end + if operands then text = text.." "..operands end + if ctx.o16 then text = "o16 "..text; ctx.o16 = false end + if ctx.a32 then text = "a32 "..text; ctx.a32 = false end + if ctx.rep then text = ctx.rep.." "..text; ctx.rep = false end + if ctx.rex then + local t = (ctx.rexw and "w" or "")..(ctx.rexr and "r" or "").. + (ctx.rexx and "x" or "")..(ctx.rexb and "b" or "").. + (ctx.vexl and "l" or "") + if ctx.vexv and ctx.vexv ~= 0 then t = t.."v"..ctx.vexv end + if t ~= "" then text = ctx.rex.."."..t.." "..gsub(text, "^ ", "") + elseif ctx.rex == "vex" then text = gsub("v"..text, "^v ", "") end + ctx.rexw = false; ctx.rexr = false; ctx.rexx = false; ctx.rexb = false + ctx.rex = false; ctx.vexl = false; ctx.vexv = false + end + if ctx.seg then + local text2, n = gsub(text, "%[", "["..ctx.seg..":") + if n == 0 then text = ctx.seg.." "..text else text = text2 end + ctx.seg = false + end + if ctx.lock then text = "lock "..text; ctx.lock = false end + local imm = ctx.imm + if imm then + local sym = ctx.symtab[imm] + if sym then text = text.."\t->"..sym end + end + ctx.out(format("%08x %s%s\n", ctx.addr+ctx.start, hex, text)) + ctx.mrm = false + ctx.vexv = false + ctx.start = pos + ctx.imm = nil +end + +-- Clear all prefix flags. +local function clearprefixes(ctx) + ctx.o16 = false; ctx.seg = false; ctx.lock = false; ctx.rep = false + ctx.rexw = false; ctx.rexr = false; ctx.rexx = false; ctx.rexb = false + ctx.rex = false; ctx.a32 = false; ctx.vexl = false +end + +-- Fallback for incomplete opcodes at the end. +local function incomplete(ctx) + ctx.pos = ctx.stop+1 + clearprefixes(ctx) + return putop(ctx, "(incomplete)") +end + +-- Fallback for unknown opcodes. +local function unknown(ctx) + clearprefixes(ctx) + return putop(ctx, "(unknown)") +end + +-- Return an immediate of the specified size. +local function getimm(ctx, pos, n) + if pos+n-1 > ctx.stop then return incomplete(ctx) end + local code = ctx.code + if n == 1 then + local b1 = byte(code, pos, pos) + return b1 + elseif n == 2 then + local b1, b2 = byte(code, pos, pos+1) + return b1+b2*256 + else + local b1, b2, b3, b4 = byte(code, pos, pos+3) + local imm = b1+b2*256+b3*65536+b4*16777216 + ctx.imm = imm + return imm + end +end + +-- Process pattern string and generate the operands. +local function putpat(ctx, name, pat) + local operands, regs, sz, mode, sp, rm, sc, rx, sdisp + local code, pos, stop, vexl = ctx.code, ctx.pos, ctx.stop, ctx.vexl + + -- Chars used: 1DFGHIMPQRSTUVWXYabcdfgijlmoprstuvwxyz + for p in gmatch(pat, ".") do + local x = nil + if p == "V" or p == "U" then + if ctx.rexw then sz = "Q"; ctx.rexw = false + elseif ctx.o16 then sz = "W"; ctx.o16 = false + elseif p == "U" and ctx.x64 then sz = "Q" + else sz = "D" end + regs = map_regs[sz] + elseif p == "T" then + if ctx.rexw then sz = "Q"; ctx.rexw = false else sz = "D" end + regs = map_regs[sz] + elseif p == "B" then + sz = "B" + regs = ctx.rex and map_regs.B64 or map_regs.B + elseif match(p, "[WDQMXYFG]") then + sz = p + if sz == "X" and vexl then sz = "Y"; ctx.vexl = false end + regs = map_regs[sz] + elseif p == "P" then + sz = ctx.o16 and "X" or "M"; ctx.o16 = false + if sz == "X" and vexl then sz = "Y"; ctx.vexl = false end + regs = map_regs[sz] + elseif p == "H" then + name = name..(ctx.rexw and "d" or "s") + ctx.rexw = false + elseif p == "S" then + name = name..lower(sz) + elseif p == "s" then + local imm = getimm(ctx, pos, 1); if not imm then return end + x = imm <= 127 and format("+0x%02x", imm) + or format("-0x%02x", 256-imm) + pos = pos+1 + elseif p == "u" then + local imm = getimm(ctx, pos, 1); if not imm then return end + x = format("0x%02x", imm) + pos = pos+1 + elseif p == "b" then + local imm = getimm(ctx, pos, 1); if not imm then return end + x = regs[imm/16+1] + pos = pos+1 + elseif p == "w" then + local imm = getimm(ctx, pos, 2); if not imm then return end + x = format("0x%x", imm) + pos = pos+2 + elseif p == "o" then -- [offset] + if ctx.x64 then + local imm1 = getimm(ctx, pos, 4); if not imm1 then return end + local imm2 = getimm(ctx, pos+4, 4); if not imm2 then return end + x = format("[0x%08x%08x]", imm2, imm1) + pos = pos+8 + else + local imm = getimm(ctx, pos, 4); if not imm then return end + x = format("[0x%08x]", imm) + pos = pos+4 + end + elseif p == "i" or p == "I" then + local n = map_sz2n[sz] + if n == 8 and ctx.x64 and p == "I" then + local imm1 = getimm(ctx, pos, 4); if not imm1 then return end + local imm2 = getimm(ctx, pos+4, 4); if not imm2 then return end + x = format("0x%08x%08x", imm2, imm1) + else + if n == 8 then n = 4 end + local imm = getimm(ctx, pos, n); if not imm then return end + if sz == "Q" and (imm < 0 or imm > 0x7fffffff) then + imm = (0xffffffff+1)-imm + x = format(imm > 65535 and "-0x%08x" or "-0x%x", imm) + else + x = format(imm > 65535 and "0x%08x" or "0x%x", imm) + end + end + pos = pos+n + elseif p == "j" then + local n = map_sz2n[sz] + if n == 8 then n = 4 end + local imm = getimm(ctx, pos, n); if not imm then return end + if sz == "B" and imm > 127 then imm = imm-256 + elseif imm > 2147483647 then imm = imm-4294967296 end + pos = pos+n + imm = imm + pos + ctx.addr + if imm > 4294967295 and not ctx.x64 then imm = imm-4294967296 end + ctx.imm = imm + if sz == "W" then + x = format("word 0x%04x", imm%65536) + elseif ctx.x64 then + local lo = imm % 0x1000000 + x = format("0x%02x%06x", (imm-lo) / 0x1000000, lo) + else + x = "0x"..tohex(imm) + end + elseif p == "R" then + local r = byte(code, pos-1, pos-1)%8 + if ctx.rexb then r = r + 8; ctx.rexb = false end + x = regs[r+1] + elseif p == "a" then x = regs[1] + elseif p == "c" then x = "cl" + elseif p == "d" then x = "dx" + elseif p == "1" then x = "1" + else + if not mode then + mode = ctx.mrm + if not mode then + if pos > stop then return incomplete(ctx) end + mode = byte(code, pos, pos) + pos = pos+1 + end + rm = mode%8; mode = (mode-rm)/8 + sp = mode%8; mode = (mode-sp)/8 + sdisp = "" + if mode < 3 then + if rm == 4 then + if pos > stop then return incomplete(ctx) end + sc = byte(code, pos, pos) + pos = pos+1 + rm = sc%8; sc = (sc-rm)/8 + rx = sc%8; sc = (sc-rx)/8 + if ctx.rexx then rx = rx + 8; ctx.rexx = false end + if rx == 4 then rx = nil end + end + if mode > 0 or rm == 5 then + local dsz = mode + if dsz ~= 1 then dsz = 4 end + local disp = getimm(ctx, pos, dsz); if not disp then return end + if mode == 0 then rm = nil end + if rm or rx or (not sc and ctx.x64 and not ctx.a32) then + if dsz == 1 and disp > 127 then + sdisp = format("-0x%x", 256-disp) + elseif disp >= 0 and disp <= 0x7fffffff then + sdisp = format("+0x%x", disp) + else + sdisp = format("-0x%x", (0xffffffff+1)-disp) + end + else + sdisp = format(ctx.x64 and not ctx.a32 and + not (disp >= 0 and disp <= 0x7fffffff) + and "0xffffffff%08x" or "0x%08x", disp) + end + pos = pos+dsz + end + end + if rm and ctx.rexb then rm = rm + 8; ctx.rexb = false end + if ctx.rexr then sp = sp + 8; ctx.rexr = false end + end + if p == "m" then + if mode == 3 then x = regs[rm+1] + else + local aregs = ctx.a32 and map_regs.D or ctx.aregs + local srm, srx = "", "" + if rm then srm = aregs[rm+1] + elseif not sc and ctx.x64 and not ctx.a32 then srm = "rip" end + ctx.a32 = false + if rx then + if rm then srm = srm.."+" end + srx = aregs[rx+1] + if sc > 0 then srx = srx.."*"..(2^sc) end + end + x = format("[%s%s%s]", srm, srx, sdisp) + end + if mode < 3 and + (not match(pat, "[aRrgp]") or match(pat, "t")) then -- Yuck. + x = map_sz2prefix[sz].." "..x + end + elseif p == "r" then x = regs[sp+1] + elseif p == "g" then x = map_segregs[sp+1] + elseif p == "p" then -- Suppress prefix. + elseif p == "f" then x = "st"..rm + elseif p == "x" then + if sp == 0 and ctx.lock and not ctx.x64 then + x = "CR8"; ctx.lock = false + else + x = "CR"..sp + end + elseif p == "v" then + if ctx.vexv then + x = regs[ctx.vexv+1]; ctx.vexv = false + end + elseif p == "y" then x = "DR"..sp + elseif p == "z" then x = "TR"..sp + elseif p == "l" then vexl = false + elseif p == "t" then + else + error("bad pattern `"..pat.."'") + end + end + if x then operands = operands and operands..", "..x or x end + end + ctx.pos = pos + return putop(ctx, name, operands) +end + +-- Forward declaration. +local map_act + +-- Fetch and cache MRM byte. +local function getmrm(ctx) + local mrm = ctx.mrm + if not mrm then + local pos = ctx.pos + if pos > ctx.stop then return nil end + mrm = byte(ctx.code, pos, pos) + ctx.pos = pos+1 + ctx.mrm = mrm + end + return mrm +end + +-- Dispatch to handler depending on pattern. +local function dispatch(ctx, opat, patgrp) + if not opat then return unknown(ctx) end + if match(opat, "%|") then -- MMX/SSE variants depending on prefix. + local p + if ctx.rep then + p = ctx.rep=="rep" and "%|([^%|]*)" or "%|[^%|]*%|[^%|]*%|([^%|]*)" + ctx.rep = false + elseif ctx.o16 then p = "%|[^%|]*%|([^%|]*)"; ctx.o16 = false + else p = "^[^%|]*" end + opat = match(opat, p) + if not opat then return unknown(ctx) end +-- ctx.rep = false; ctx.o16 = false + --XXX fails for 66 f2 0f 38 f1 06 crc32 eax,WORD PTR [esi] + --XXX remove in branches? + end + if match(opat, "%$") then -- reg$mem variants. + local mrm = getmrm(ctx); if not mrm then return incomplete(ctx) end + opat = match(opat, mrm >= 192 and "^[^%$]*" or "%$(.*)") + if opat == "" then return unknown(ctx) end + end + if opat == "" then return unknown(ctx) end + local name, pat = match(opat, "^([a-z0-9 ]*)(.*)") + if pat == "" and patgrp then pat = patgrp end + return map_act[sub(pat, 1, 1)](ctx, name, pat) +end + +-- Get a pattern from an opcode map and dispatch to handler. +local function dispatchmap(ctx, opcmap) + local pos = ctx.pos + local opat = opcmap[byte(ctx.code, pos, pos)] + pos = pos + 1 + ctx.pos = pos + return dispatch(ctx, opat) +end + +-- Map for action codes. The key is the first char after the name. +map_act = { + -- Simple opcodes without operands. + [""] = function(ctx, name, pat) + return putop(ctx, name) + end, + + -- Operand size chars fall right through. + B = putpat, W = putpat, D = putpat, Q = putpat, + V = putpat, U = putpat, T = putpat, + M = putpat, X = putpat, P = putpat, + F = putpat, G = putpat, Y = putpat, + H = putpat, + + -- Collect prefixes. + [":"] = function(ctx, name, pat) + ctx[pat == ":" and name or sub(pat, 2)] = name + if ctx.pos - ctx.start > 5 then return unknown(ctx) end -- Limit #prefixes. + end, + + -- Chain to special handler specified by name. + ["*"] = function(ctx, name, pat) + return map_act[name](ctx, name, sub(pat, 2)) + end, + + -- Use named subtable for opcode group. + ["!"] = function(ctx, name, pat) + local mrm = getmrm(ctx); if not mrm then return incomplete(ctx) end + return dispatch(ctx, map_opcgroup[name][((mrm-(mrm%8))/8)%8+1], sub(pat, 2)) + end, + + -- o16,o32[,o64] variants. + sz = function(ctx, name, pat) + if ctx.o16 then ctx.o16 = false + else + pat = match(pat, ",(.*)") + if ctx.rexw then + local p = match(pat, ",(.*)") + if p then pat = p; ctx.rexw = false end + end + end + pat = match(pat, "^[^,]*") + return dispatch(ctx, pat) + end, + + -- Two-byte opcode dispatch. + opc2 = function(ctx, name, pat) + return dispatchmap(ctx, map_opc2) + end, + + -- Three-byte opcode dispatch. + opc3 = function(ctx, name, pat) + return dispatchmap(ctx, map_opc3[pat]) + end, + + -- VMX/SVM dispatch. + vm = function(ctx, name, pat) + return dispatch(ctx, map_opcvm[ctx.mrm]) + end, + + -- Floating point opcode dispatch. + fp = function(ctx, name, pat) + local mrm = getmrm(ctx); if not mrm then return incomplete(ctx) end + local rm = mrm%8 + local idx = pat*8 + ((mrm-rm)/8)%8 + if mrm >= 192 then idx = idx + 64 end + local opat = map_opcfp[idx] + if type(opat) == "table" then opat = opat[rm+1] end + return dispatch(ctx, opat) + end, + + -- REX prefix. + rex = function(ctx, name, pat) + if ctx.rex then return unknown(ctx) end -- Only 1 REX or VEX prefix allowed. + for p in gmatch(pat, ".") do ctx["rex"..p] = true end + ctx.rex = "rex" + end, + + -- VEX prefix. + vex = function(ctx, name, pat) + if ctx.rex then return unknown(ctx) end -- Only 1 REX or VEX prefix allowed. + ctx.rex = "vex" + local pos = ctx.pos + if ctx.mrm then + ctx.mrm = nil + pos = pos-1 + end + local b = byte(ctx.code, pos, pos) + if not b then return incomplete(ctx) end + pos = pos+1 + if b < 128 then ctx.rexr = true end + local m = 1 + if pat == "3" then + m = b%32; b = (b-m)/32 + local nb = b%2; b = (b-nb)/2 + if nb == 0 then ctx.rexb = true end + local nx = b%2 + if nx == 0 then ctx.rexx = true end + b = byte(ctx.code, pos, pos) + if not b then return incomplete(ctx) end + pos = pos+1 + if b >= 128 then ctx.rexw = true end + end + ctx.pos = pos + local map + if m == 1 then map = map_opc2 + elseif m == 2 then map = map_opc3["38"] + elseif m == 3 then map = map_opc3["3a"] + else return unknown(ctx) end + local p = b%4; b = (b-p)/4 + if p == 1 then ctx.o16 = "o16" + elseif p == 2 then ctx.rep = "rep" + elseif p == 3 then ctx.rep = "repne" end + local l = b%2; b = (b-l)/2 + if l ~= 0 then ctx.vexl = true end + ctx.vexv = (-1-b)%16 + return dispatchmap(ctx, map) + end, + + -- Special case for nop with REX prefix. + nop = function(ctx, name, pat) + return dispatch(ctx, ctx.rex and pat or "nop") + end, + + -- Special case for 0F 77. + emms = function(ctx, name, pat) + if ctx.rex ~= "vex" then + return putop(ctx, "emms") + elseif ctx.vexl then + ctx.vexl = false + return putop(ctx, "zeroall") + else + return putop(ctx, "zeroupper") + end + end, +} + +------------------------------------------------------------------------------ + +-- Disassemble a block of code. +local function disass_block(ctx, ofs, len) + if not ofs then ofs = 0 end + local stop = len and ofs+len or #ctx.code + ofs = ofs + 1 + ctx.start = ofs + ctx.pos = ofs + ctx.stop = stop + ctx.imm = nil + ctx.mrm = false + clearprefixes(ctx) + while ctx.pos <= stop do dispatchmap(ctx, ctx.map1) end + if ctx.pos ~= ctx.start then incomplete(ctx) end +end + +-- Extended API: create a disassembler context. Then call ctx:disass(ofs, len). +local function create(code, addr, out) + local ctx = {} + ctx.code = code + ctx.addr = (addr or 0) - 1 + ctx.out = out or io.write + ctx.symtab = {} + ctx.disass = disass_block + ctx.hexdump = 16 + ctx.x64 = false + ctx.map1 = map_opc1_32 + ctx.aregs = map_regs.D + return ctx +end + +local function create64(code, addr, out) + local ctx = create(code, addr, out) + ctx.x64 = true + ctx.map1 = map_opc1_64 + ctx.aregs = map_regs.Q + return ctx +end + +-- Simple API: disassemble code (a string) at address and output via out. +local function disass(code, addr, out) + create(code, addr, out):disass() +end + +local function disass64(code, addr, out) + create64(code, addr, out):disass() +end + +-- Return register name for RID. +local function regname(r) + if r < 8 then return map_regs.D[r+1] end + return map_regs.X[r-7] +end + +local function regname64(r) + if r < 16 then return map_regs.Q[r+1] end + return map_regs.X[r-15] +end + +-- Public module functions. +return { + create = create, + create64 = create64, + disass = disass, + disass64 = disass64, + regname = regname, + regname64 = regname64 +} + diff --git a/fluent-bit/lib/luajit-3065c9/src/jit/dump.lua b/fluent-bit/lib/luajit-3065c9/src/jit/dump.lua new file mode 100644 index 00000000..18e7a4b7 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/jit/dump.lua @@ -0,0 +1,726 @@ +---------------------------------------------------------------------------- +-- LuaJIT compiler dump module. +-- +-- Copyright (C) 2005-2022 Mike Pall. All rights reserved. +-- Released under the MIT license. See Copyright Notice in luajit.h +---------------------------------------------------------------------------- +-- +-- This module can be used to debug the JIT compiler itself. It dumps the +-- code representations and structures used in various compiler stages. +-- +-- Example usage: +-- +-- luajit -jdump -e "local x=0; for i=1,1e6 do x=x+i end; print(x)" +-- luajit -jdump=im -e "for i=1,1000 do for j=1,1000 do end end" | less -R +-- luajit -jdump=is myapp.lua | less -R +-- luajit -jdump=-b myapp.lua +-- luajit -jdump=+aH,myapp.html myapp.lua +-- luajit -jdump=ixT,myapp.dump myapp.lua +-- +-- The first argument specifies the dump mode. The second argument gives +-- the output file name. Default output is to stdout, unless the environment +-- variable LUAJIT_DUMPFILE is set. The file is overwritten every time the +-- module is started. +-- +-- Different features can be turned on or off with the dump mode. If the +-- mode starts with a '+', the following features are added to the default +-- set of features; a '-' removes them. Otherwise the features are replaced. +-- +-- The following dump features are available (* marks the default): +-- +-- * t Print a line for each started, ended or aborted trace (see also -jv). +-- * b Dump the traced bytecode. +-- * i Dump the IR (intermediate representation). +-- r Augment the IR with register/stack slots. +-- s Dump the snapshot map. +-- * m Dump the generated machine code. +-- x Print each taken trace exit. +-- X Print each taken trace exit and the contents of all registers. +-- a Print the IR of aborted traces, too. +-- +-- The output format can be set with the following characters: +-- +-- T Plain text output. +-- A ANSI-colored text output +-- H Colorized HTML + CSS output. +-- +-- The default output format is plain text. It's set to ANSI-colored text +-- if the COLORTERM variable is set. Note: this is independent of any output +-- redirection, which is actually considered a feature. +-- +-- You probably want to use less -R to enjoy viewing ANSI-colored text from +-- a pipe or a file. Add this to your ~/.bashrc: export LESS="-R" +-- +------------------------------------------------------------------------------ + +-- Cache some library functions and objects. +local jit = require("jit") +assert(jit.version_num == 20100, "LuaJIT core/library version mismatch") +local jutil = require("jit.util") +local vmdef = require("jit.vmdef") +local funcinfo, funcbc = jutil.funcinfo, jutil.funcbc +local traceinfo, traceir, tracek = jutil.traceinfo, jutil.traceir, jutil.tracek +local tracemc, tracesnap = jutil.tracemc, jutil.tracesnap +local traceexitstub, ircalladdr = jutil.traceexitstub, jutil.ircalladdr +local bit = require("bit") +local band, shr, tohex = bit.band, bit.rshift, bit.tohex +local sub, gsub, format = string.sub, string.gsub, string.format +local byte, rep = string.byte, string.rep +local type, tostring = type, tostring +local stdout, stderr = io.stdout, io.stderr + +-- Load other modules on-demand. +local bcline, disass + +-- Active flag, output file handle and dump mode. +local active, out, dumpmode + +------------------------------------------------------------------------------ + +local symtabmt = { __index = false } +local symtab = {} +local nexitsym = 0 + +-- Fill nested symbol table with per-trace exit stub addresses. +local function fillsymtab_tr(tr, nexit) + local t = {} + symtabmt.__index = t + if jit.arch:sub(1, 4) == "mips" then + t[traceexitstub(tr, 0)] = "exit" + return + end + for i=0,nexit-1 do + local addr = traceexitstub(tr, i) + if addr < 0 then addr = addr + 2^32 end + t[addr] = tostring(i) + end + local addr = traceexitstub(tr, nexit) + if addr then t[addr] = "stack_check" end +end + +-- Fill symbol table with trace exit stub addresses. +local function fillsymtab(tr, nexit) + local t = symtab + if nexitsym == 0 then + local maskaddr = jit.arch == "arm" and -2 + local ircall = vmdef.ircall + for i=0,#ircall do + local addr = ircalladdr(i) + if addr ~= 0 then + if maskaddr then addr = band(addr, maskaddr) end + if addr < 0 then addr = addr + 2^32 end + t[addr] = ircall[i] + end + end + end + if nexitsym == 1000000 then -- Per-trace exit stubs. + fillsymtab_tr(tr, nexit) + elseif nexit > nexitsym then -- Shared exit stubs. + for i=nexitsym,nexit-1 do + local addr = traceexitstub(i) + if addr == nil then -- Fall back to per-trace exit stubs. + fillsymtab_tr(tr, nexit) + setmetatable(symtab, symtabmt) + nexit = 1000000 + break + end + if addr < 0 then addr = addr + 2^32 end + t[addr] = tostring(i) + end + nexitsym = nexit + end + return t +end + +local function dumpwrite(s) + out:write(s) +end + +-- Disassemble machine code. +local function dump_mcode(tr) + local info = traceinfo(tr) + if not info then return end + local mcode, addr, loop = tracemc(tr) + if not mcode then return end + if not disass then disass = require("jit.dis_"..jit.arch) end + if addr < 0 then addr = addr + 2^32 end + out:write("---- TRACE ", tr, " mcode ", #mcode, "\n") + local ctx = disass.create(mcode, addr, dumpwrite) + ctx.hexdump = 0 + ctx.symtab = fillsymtab(tr, info.nexit) + if loop ~= 0 then + symtab[addr+loop] = "LOOP" + ctx:disass(0, loop) + out:write("->LOOP:\n") + ctx:disass(loop, #mcode-loop) + symtab[addr+loop] = nil + else + ctx:disass(0, #mcode) + end +end + +------------------------------------------------------------------------------ + +local irtype_text = { + [0] = "nil", + "fal", + "tru", + "lud", + "str", + "p32", + "thr", + "pro", + "fun", + "p64", + "cdt", + "tab", + "udt", + "flt", + "num", + "i8 ", + "u8 ", + "i16", + "u16", + "int", + "u32", + "i64", + "u64", + "sfp", +} + +local colortype_ansi = { + [0] = "%s", + "%s", + "%s", + "\027[36m%s\027[m", + "\027[32m%s\027[m", + "%s", + "\027[1m%s\027[m", + "%s", + "\027[1m%s\027[m", + "%s", + "\027[33m%s\027[m", + "\027[31m%s\027[m", + "\027[36m%s\027[m", + "\027[34m%s\027[m", + "\027[34m%s\027[m", + "\027[35m%s\027[m", + "\027[35m%s\027[m", + "\027[35m%s\027[m", + "\027[35m%s\027[m", + "\027[35m%s\027[m", + "\027[35m%s\027[m", + "\027[35m%s\027[m", + "\027[35m%s\027[m", + "\027[35m%s\027[m", +} + +local function colorize_text(s) + return s +end + +local function colorize_ansi(s, t, extra) + local out = format(colortype_ansi[t], s) + if extra then out = "\027[3m"..out end + return out +end + +local irtype_ansi = setmetatable({}, + { __index = function(tab, t) + local s = colorize_ansi(irtype_text[t], t); tab[t] = s; return s; end }) + +local html_escape = { ["<"] = "<", [">"] = ">", ["&"] = "&", } + +local function colorize_html(s, t, extra) + s = gsub(s, "[<>&]", html_escape) + return format('%s', + irtype_text[t], extra and " irt_extra" or "", s) +end + +local irtype_html = setmetatable({}, + { __index = function(tab, t) + local s = colorize_html(irtype_text[t], t); tab[t] = s; return s; end }) + +local header_html = [[ + +]] + +local colorize, irtype + +-- Lookup tables to convert some literals into names. +local litname = { + ["SLOAD "] = setmetatable({}, { __index = function(t, mode) + local s = "" + if band(mode, 1) ~= 0 then s = s.."P" end + if band(mode, 2) ~= 0 then s = s.."F" end + if band(mode, 4) ~= 0 then s = s.."T" end + if band(mode, 8) ~= 0 then s = s.."C" end + if band(mode, 16) ~= 0 then s = s.."R" end + if band(mode, 32) ~= 0 then s = s.."I" end + if band(mode, 64) ~= 0 then s = s.."K" end + t[mode] = s + return s + end}), + ["XLOAD "] = { [0] = "", "R", "V", "RV", "U", "RU", "VU", "RVU", }, + ["CONV "] = setmetatable({}, { __index = function(t, mode) + local s = irtype[band(mode, 31)] + s = irtype[band(shr(mode, 5), 31)].."."..s + if band(mode, 0x800) ~= 0 then s = s.." sext" end + local c = shr(mode, 12) + if c == 1 then s = s.." none" + elseif c == 2 then s = s.." index" + elseif c == 3 then s = s.." check" end + t[mode] = s + return s + end}), + ["FLOAD "] = vmdef.irfield, + ["FREF "] = vmdef.irfield, + ["FPMATH"] = vmdef.irfpm, + ["TMPREF"] = { [0] = "", "IN", "OUT", "INOUT", "", "", "OUT2", "INOUT2" }, + ["BUFHDR"] = { [0] = "RESET", "APPEND", "WRITE" }, + ["TOSTR "] = { [0] = "INT", "NUM", "CHAR" }, +} + +local function ctlsub(c) + if c == "\n" then return "\\n" + elseif c == "\r" then return "\\r" + elseif c == "\t" then return "\\t" + else return format("\\%03d", byte(c)) + end +end + +local function fmtfunc(func, pc) + local fi = funcinfo(func, pc) + if fi.loc then + return fi.loc + elseif fi.ffid then + return vmdef.ffnames[fi.ffid] + elseif fi.addr then + return format("C:%x", fi.addr) + else + return "(?)" + end +end + +local function formatk(tr, idx, sn) + local k, t, slot = tracek(tr, idx) + local tn = type(k) + local s + if tn == "number" then + if t < 12 then + s = k == 0 and "NULL" or format("[0x%08x]", k) + elseif band(sn or 0, 0x30000) ~= 0 then + s = band(sn, 0x20000) ~= 0 and "contpc" or "ftsz" + elseif k == 2^52+2^51 then + s = "bias" + else + s = format(0 < k and k < 0x1p-1026 and "%+a" or "%+.14g", k) + end + elseif tn == "string" then + s = format(#k > 20 and '"%.20s"~' or '"%s"', gsub(k, "%c", ctlsub)) + elseif tn == "function" then + s = fmtfunc(k) + elseif tn == "table" then + s = format("{%p}", k) + elseif tn == "userdata" then + if t == 12 then + s = format("userdata:%p", k) + else + s = format("[%p]", k) + if s == "[NULL]" then s = "NULL" end + end + elseif t == 21 then -- int64_t + s = sub(tostring(k), 1, -3) + if sub(s, 1, 1) ~= "-" then s = "+"..s end + elseif sn == 0x1057fff then -- SNAP(1, SNAP_FRAME | SNAP_NORESTORE, REF_NIL) + return "----" -- Special case for LJ_FR2 slot 1. + else + s = tostring(k) -- For primitives. + end + s = colorize(format("%-4s", s), t, band(sn or 0, 0x100000) ~= 0) + if slot then + s = format("%s @%d", s, slot) + end + return s +end + +local function printsnap(tr, snap) + local n = 2 + for s=0,snap[1]-1 do + local sn = snap[n] + if shr(sn, 24) == s then + n = n + 1 + local ref = band(sn, 0xffff) - 0x8000 -- REF_BIAS + if ref < 0 then + out:write(formatk(tr, ref, sn)) + elseif band(sn, 0x80000) ~= 0 then -- SNAP_SOFTFPNUM + out:write(colorize(format("%04d/%04d", ref, ref+1), 14)) + else + local m, ot, op1, op2 = traceir(tr, ref) + out:write(colorize(format("%04d", ref), band(ot, 31), band(sn, 0x100000) ~= 0)) + end + out:write(band(sn, 0x10000) == 0 and " " or "|") -- SNAP_FRAME + else + out:write("---- ") + end + end + out:write("]\n") +end + +-- Dump snapshots (not interleaved with IR). +local function dump_snap(tr) + out:write("---- TRACE ", tr, " snapshots\n") + for i=0,1000000000 do + local snap = tracesnap(tr, i) + if not snap then break end + out:write(format("#%-3d %04d [ ", i, snap[0])) + printsnap(tr, snap) + end +end + +-- Return a register name or stack slot for a rid/sp location. +local function ridsp_name(ridsp, ins) + if not disass then disass = require("jit.dis_"..jit.arch) end + local rid, slot = band(ridsp, 0xff), shr(ridsp, 8) + if rid == 253 or rid == 254 then + return (slot == 0 or slot == 255) and " {sink" or format(" {%04d", ins-slot) + end + if ridsp > 255 then return format("[%x]", slot*4) end + if rid < 128 then return disass.regname(rid) end + return "" +end + +-- Dump CALL* function ref and return optional ctype. +local function dumpcallfunc(tr, ins) + local ctype + if ins > 0 then + local m, ot, op1, op2 = traceir(tr, ins) + if band(ot, 31) == 0 then -- nil type means CARG(func, ctype). + ins = op1 + ctype = formatk(tr, op2) + end + end + if ins < 0 then + out:write(format("[0x%x](", tonumber((tracek(tr, ins))))) + else + out:write(format("%04d (", ins)) + end + return ctype +end + +-- Recursively gather CALL* args and dump them. +local function dumpcallargs(tr, ins) + if ins < 0 then + out:write(formatk(tr, ins)) + else + local m, ot, op1, op2 = traceir(tr, ins) + local oidx = 6*shr(ot, 8) + local op = sub(vmdef.irnames, oidx+1, oidx+6) + if op == "CARG " then + dumpcallargs(tr, op1) + if op2 < 0 then + out:write(" ", formatk(tr, op2)) + else + out:write(" ", format("%04d", op2)) + end + else + out:write(format("%04d", ins)) + end + end +end + +-- Dump IR and interleaved snapshots. +local function dump_ir(tr, dumpsnap, dumpreg) + local info = traceinfo(tr) + if not info then return end + local nins = info.nins + out:write("---- TRACE ", tr, " IR\n") + local irnames = vmdef.irnames + local snapref = 65536 + local snap, snapno + if dumpsnap then + snap = tracesnap(tr, 0) + snapref = snap[0] + snapno = 0 + end + for ins=1,nins do + if ins >= snapref then + if dumpreg then + out:write(format(".... SNAP #%-3d [ ", snapno)) + else + out:write(format(".... SNAP #%-3d [ ", snapno)) + end + printsnap(tr, snap) + snapno = snapno + 1 + snap = tracesnap(tr, snapno) + snapref = snap and snap[0] or 65536 + end + local m, ot, op1, op2, ridsp = traceir(tr, ins) + local oidx, t = 6*shr(ot, 8), band(ot, 31) + local op = sub(irnames, oidx+1, oidx+6) + if op == "LOOP " then + if dumpreg then + out:write(format("%04d ------------ LOOP ------------\n", ins)) + else + out:write(format("%04d ------ LOOP ------------\n", ins)) + end + elseif op ~= "NOP " and op ~= "CARG " and + (dumpreg or op ~= "RENAME") then + local rid = band(ridsp, 255) + if dumpreg then + out:write(format("%04d %-6s", ins, ridsp_name(ridsp, ins))) + else + out:write(format("%04d ", ins)) + end + out:write(format("%s%s %s %s ", + (rid == 254 or rid == 253) and "}" or + (band(ot, 128) == 0 and " " or ">"), + band(ot, 64) == 0 and " " or "+", + irtype[t], op)) + local m1, m2 = band(m, 3), band(m, 3*4) + if sub(op, 1, 4) == "CALL" then + local ctype + if m2 == 1*4 then -- op2 == IRMlit + out:write(format("%-10s (", vmdef.ircall[op2])) + else + ctype = dumpcallfunc(tr, op2) + end + if op1 ~= -1 then dumpcallargs(tr, op1) end + out:write(")") + if ctype then out:write(" ctype ", ctype) end + elseif op == "CNEW " and op2 == -1 then + out:write(formatk(tr, op1)) + elseif m1 ~= 3 then -- op1 != IRMnone + if op1 < 0 then + out:write(formatk(tr, op1)) + else + out:write(format(m1 == 0 and "%04d" or "#%-3d", op1)) + end + if m2 ~= 3*4 then -- op2 != IRMnone + if m2 == 1*4 then -- op2 == IRMlit + local litn = litname[op] + if litn and litn[op2] then + out:write(" ", litn[op2]) + elseif op == "UREFO " or op == "UREFC " then + out:write(format(" #%-3d", shr(op2, 8))) + else + out:write(format(" #%-3d", op2)) + end + elseif op2 < 0 then + out:write(" ", formatk(tr, op2)) + else + out:write(format(" %04d", op2)) + end + end + end + out:write("\n") + end + end + if snap then + if dumpreg then + out:write(format(".... SNAP #%-3d [ ", snapno)) + else + out:write(format(".... SNAP #%-3d [ ", snapno)) + end + printsnap(tr, snap) + end +end + +------------------------------------------------------------------------------ + +local recprefix = "" +local recdepth = 0 + +-- Format trace error message. +local function fmterr(err, info) + if type(err) == "number" then + if type(info) == "function" then info = fmtfunc(info) end + err = format(vmdef.traceerr[err], info) + end + return err +end + +-- Dump trace states. +local function dump_trace(what, tr, func, pc, otr, oex) + if what == "stop" or (what == "abort" and dumpmode.a) then + if dumpmode.i then dump_ir(tr, dumpmode.s, dumpmode.r and what == "stop") + elseif dumpmode.s then dump_snap(tr) end + if dumpmode.m then dump_mcode(tr) end + end + if what == "start" then + if dumpmode.H then out:write('
\n') end
+    out:write("---- TRACE ", tr, " ", what)
+    if otr then out:write(" ", otr, "/", oex == -1 and "stitch" or oex) end
+    out:write(" ", fmtfunc(func, pc), "\n")
+  elseif what == "stop" or what == "abort" then
+    out:write("---- TRACE ", tr, " ", what)
+    if what == "abort" then
+      out:write(" ", fmtfunc(func, pc), " -- ", fmterr(otr, oex), "\n")
+    else
+      local info = traceinfo(tr)
+      local link, ltype = info.link, info.linktype
+      if link == tr or link == 0 then
+	out:write(" -> ", ltype, "\n")
+      elseif ltype == "root" then
+	out:write(" -> ", link, "\n")
+      else
+	out:write(" -> ", link, " ", ltype, "\n")
+      end
+    end
+    if dumpmode.H then out:write("
\n\n") else out:write("\n") end + else + if what == "flush" then symtab, nexitsym = {}, 0 end + out:write("---- TRACE ", what, "\n\n") + end + out:flush() +end + +-- Dump recorded bytecode. +local function dump_record(tr, func, pc, depth) + if depth ~= recdepth then + recdepth = depth + recprefix = rep(" .", depth) + end + local line + if pc >= 0 then + line = bcline(func, pc, recprefix) + if dumpmode.H then line = gsub(line, "[<>&]", html_escape) end + else + line = "0000 "..recprefix.." FUNCC \n" + end + if pc <= 0 then + out:write(sub(line, 1, -2), " ; ", fmtfunc(func), "\n") + else + out:write(line) + end + if pc >= 0 and band(funcbc(func, pc), 0xff) < 16 then -- ORDER BC + out:write(bcline(func, pc+1, recprefix)) -- Write JMP for cond. + end +end + +------------------------------------------------------------------------------ + +local gpr64 = jit.arch:match("64") +local fprmips32 = jit.arch == "mips" or jit.arch == "mipsel" + +-- Dump taken trace exits. +local function dump_texit(tr, ex, ngpr, nfpr, ...) + out:write("---- TRACE ", tr, " exit ", ex, "\n") + if dumpmode.X then + local regs = {...} + if gpr64 then + for i=1,ngpr do + out:write(format(" %016x", regs[i])) + if i % 4 == 0 then out:write("\n") end + end + else + for i=1,ngpr do + out:write(" ", tohex(regs[i])) + if i % 8 == 0 then out:write("\n") end + end + end + if fprmips32 then + for i=1,nfpr,2 do + out:write(format(" %+17.14g", regs[ngpr+i])) + if i % 8 == 7 then out:write("\n") end + end + else + for i=1,nfpr do + out:write(format(" %+17.14g", regs[ngpr+i])) + if i % 4 == 0 then out:write("\n") end + end + end + end +end + +------------------------------------------------------------------------------ + +-- Detach dump handlers. +local function dumpoff() + if active then + active = false + jit.attach(dump_texit) + jit.attach(dump_record) + jit.attach(dump_trace) + if out and out ~= stdout and out ~= stderr then out:close() end + out = nil + end +end + +-- Open the output file and attach dump handlers. +local function dumpon(opt, outfile) + if active then dumpoff() end + + local term = os.getenv("TERM") + local colormode = (term and term:match("color") or os.getenv("COLORTERM")) and "A" or "T" + if opt then + opt = gsub(opt, "[TAH]", function(mode) colormode = mode; return ""; end) + end + + local m = { t=true, b=true, i=true, m=true, } + if opt and opt ~= "" then + local o = sub(opt, 1, 1) + if o ~= "+" and o ~= "-" then m = {} end + for i=1,#opt do m[sub(opt, i, i)] = (o ~= "-") end + end + dumpmode = m + + if m.t or m.b or m.i or m.s or m.m then + jit.attach(dump_trace, "trace") + end + if m.b then + jit.attach(dump_record, "record") + if not bcline then bcline = require("jit.bc").line end + end + if m.x or m.X then + jit.attach(dump_texit, "texit") + end + + if not outfile then outfile = os.getenv("LUAJIT_DUMPFILE") end + if outfile then + out = outfile == "-" and stdout or assert(io.open(outfile, "w")) + else + out = stdout + end + + m[colormode] = true + if colormode == "A" then + colorize = colorize_ansi + irtype = irtype_ansi + elseif colormode == "H" then + colorize = colorize_html + irtype = irtype_html + out:write(header_html) + else + colorize = colorize_text + irtype = irtype_text + end + + active = true +end + +-- Public module functions. +return { + on = dumpon, + off = dumpoff, + start = dumpon -- For -j command line option. +} + diff --git a/fluent-bit/lib/luajit-3065c9/src/jit/p.lua b/fluent-bit/lib/luajit-3065c9/src/jit/p.lua new file mode 100644 index 00000000..f225c312 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/jit/p.lua @@ -0,0 +1,312 @@ +---------------------------------------------------------------------------- +-- LuaJIT profiler. +-- +-- Copyright (C) 2005-2022 Mike Pall. All rights reserved. +-- Released under the MIT license. See Copyright Notice in luajit.h +---------------------------------------------------------------------------- +-- +-- This module is a simple command line interface to the built-in +-- low-overhead profiler of LuaJIT. +-- +-- The lower-level API of the profiler is accessible via the "jit.profile" +-- module or the luaJIT_profile_* C API. +-- +-- Example usage: +-- +-- luajit -jp myapp.lua +-- luajit -jp=s myapp.lua +-- luajit -jp=-s myapp.lua +-- luajit -jp=vl myapp.lua +-- luajit -jp=G,profile.txt myapp.lua +-- +-- The following dump features are available: +-- +-- f Stack dump: function name, otherwise module:line. Default mode. +-- F Stack dump: ditto, but always prepend module. +-- l Stack dump: module:line. +-- stack dump depth (callee < caller). Default: 1. +-- - Inverse stack dump depth (caller > callee). +-- s Split stack dump after first stack level. Implies abs(depth) >= 2. +-- p Show full path for module names. +-- v Show VM states. Can be combined with stack dumps, e.g. vf or fv. +-- z Show zones. Can be combined with stack dumps, e.g. zf or fz. +-- r Show raw sample counts. Default: show percentages. +-- a Annotate excerpts from source code files. +-- A Annotate complete source code files. +-- G Produce raw output suitable for graphical tools (e.g. flame graphs). +-- m Minimum sample percentage to be shown. Default: 3. +-- i Sampling interval in milliseconds. Default: 10. +-- +---------------------------------------------------------------------------- + +-- Cache some library functions and objects. +local jit = require("jit") +assert(jit.version_num == 20100, "LuaJIT core/library version mismatch") +local profile = require("jit.profile") +local vmdef = require("jit.vmdef") +local math = math +local pairs, ipairs, tonumber, floor = pairs, ipairs, tonumber, math.floor +local sort, format = table.sort, string.format +local stdout = io.stdout +local zone -- Load jit.zone module on demand. + +-- Output file handle. +local out + +------------------------------------------------------------------------------ + +local prof_ud +local prof_states, prof_split, prof_min, prof_raw, prof_fmt, prof_depth +local prof_ann, prof_count1, prof_count2, prof_samples + +local map_vmmode = { + N = "Compiled", + I = "Interpreted", + C = "C code", + G = "Garbage Collector", + J = "JIT Compiler", +} + +-- Profiler callback. +local function prof_cb(th, samples, vmmode) + prof_samples = prof_samples + samples + local key_stack, key_stack2, key_state + -- Collect keys for sample. + if prof_states then + if prof_states == "v" then + key_state = map_vmmode[vmmode] or vmmode + else + key_state = zone:get() or "(none)" + end + end + if prof_fmt then + key_stack = profile.dumpstack(th, prof_fmt, prof_depth) + key_stack = key_stack:gsub("%[builtin#(%d+)%]", function(x) + return vmdef.ffnames[tonumber(x)] + end) + if prof_split == 2 then + local k1, k2 = key_stack:match("(.-) [<>] (.*)") + if k2 then key_stack, key_stack2 = k1, k2 end + elseif prof_split == 3 then + key_stack2 = profile.dumpstack(th, "l", 1) + end + end + -- Order keys. + local k1, k2 + if prof_split == 1 then + if key_state then + k1 = key_state + if key_stack then k2 = key_stack end + end + elseif key_stack then + k1 = key_stack + if key_stack2 then k2 = key_stack2 elseif key_state then k2 = key_state end + end + -- Coalesce samples in one or two levels. + if k1 then + local t1 = prof_count1 + t1[k1] = (t1[k1] or 0) + samples + if k2 then + local t2 = prof_count2 + local t3 = t2[k1] + if not t3 then t3 = {}; t2[k1] = t3 end + t3[k2] = (t3[k2] or 0) + samples + end + end +end + +------------------------------------------------------------------------------ + +-- Show top N list. +local function prof_top(count1, count2, samples, indent) + local t, n = {}, 0 + for k in pairs(count1) do + n = n + 1 + t[n] = k + end + sort(t, function(a, b) return count1[a] > count1[b] end) + for i=1,n do + local k = t[i] + local v = count1[k] + local pct = floor(v*100/samples + 0.5) + if pct < prof_min then break end + if not prof_raw then + out:write(format("%s%2d%% %s\n", indent, pct, k)) + elseif prof_raw == "r" then + out:write(format("%s%5d %s\n", indent, v, k)) + else + out:write(format("%s %d\n", k, v)) + end + if count2 then + local r = count2[k] + if r then + prof_top(r, nil, v, (prof_split == 3 or prof_split == 1) and " -- " or + (prof_depth < 0 and " -> " or " <- ")) + end + end + end +end + +-- Annotate source code +local function prof_annotate(count1, samples) + local files = {} + local ms = 0 + for k, v in pairs(count1) do + local pct = floor(v*100/samples + 0.5) + ms = math.max(ms, v) + if pct >= prof_min then + local file, line = k:match("^(.*):(%d+)$") + if not file then file = k; line = 0 end + local fl = files[file] + if not fl then fl = {}; files[file] = fl; files[#files+1] = file end + line = tonumber(line) + fl[line] = prof_raw and v or pct + end + end + sort(files) + local fmtv, fmtn = " %3d%% | %s\n", " | %s\n" + if prof_raw then + local n = math.max(5, math.ceil(math.log10(ms))) + fmtv = "%"..n.."d | %s\n" + fmtn = (" "):rep(n).." | %s\n" + end + local ann = prof_ann + for _, file in ipairs(files) do + local f0 = file:byte() + if f0 == 40 or f0 == 91 then + out:write(format("\n====== %s ======\n[Cannot annotate non-file]\n", file)) + break + end + local fp, err = io.open(file) + if not fp then + out:write(format("====== ERROR: %s: %s\n", file, err)) + break + end + out:write(format("\n====== %s ======\n", file)) + local fl = files[file] + local n, show = 1, false + if ann ~= 0 then + for i=1,ann do + if fl[i] then show = true; out:write("@@ 1 @@\n"); break end + end + end + for line in fp:lines() do + if line:byte() == 27 then + out:write("[Cannot annotate bytecode file]\n") + break + end + local v = fl[n] + if ann ~= 0 then + local v2 = fl[n+ann] + if show then + if v2 then show = n+ann elseif v then show = n + elseif show+ann < n then show = false end + elseif v2 then + show = n+ann + out:write(format("@@ %d @@\n", n)) + end + if not show then goto next end + end + if v then + out:write(format(fmtv, v, line)) + else + out:write(format(fmtn, line)) + end + ::next:: + n = n + 1 + end + fp:close() + end +end + +------------------------------------------------------------------------------ + +-- Finish profiling and dump result. +local function prof_finish() + if prof_ud then + profile.stop() + local samples = prof_samples + if samples == 0 then + if prof_raw ~= true then out:write("[No samples collected]\n") end + return + end + if prof_ann then + prof_annotate(prof_count1, samples) + else + prof_top(prof_count1, prof_count2, samples, "") + end + prof_count1 = nil + prof_count2 = nil + prof_ud = nil + if out ~= stdout then out:close() end + end +end + +-- Start profiling. +local function prof_start(mode) + local interval = "" + mode = mode:gsub("i%d*", function(s) interval = s; return "" end) + prof_min = 3 + mode = mode:gsub("m(%d+)", function(s) prof_min = tonumber(s); return "" end) + prof_depth = 1 + mode = mode:gsub("%-?%d+", function(s) prof_depth = tonumber(s); return "" end) + local m = {} + for c in mode:gmatch(".") do m[c] = c end + prof_states = m.z or m.v + if prof_states == "z" then zone = require("jit.zone") end + local scope = m.l or m.f or m.F or (prof_states and "" or "f") + local flags = (m.p or "") + prof_raw = m.r + if m.s then + prof_split = 2 + if prof_depth == -1 or m["-"] then prof_depth = -2 + elseif prof_depth == 1 then prof_depth = 2 end + elseif mode:find("[fF].*l") then + scope = "l" + prof_split = 3 + else + prof_split = (scope == "" or mode:find("[zv].*[lfF]")) and 1 or 0 + end + prof_ann = m.A and 0 or (m.a and 3) + if prof_ann then + scope = "l" + prof_fmt = "pl" + prof_split = 0 + prof_depth = 1 + elseif m.G and scope ~= "" then + prof_fmt = flags..scope.."Z;" + prof_depth = -100 + prof_raw = true + prof_min = 0 + elseif scope == "" then + prof_fmt = false + else + local sc = prof_split == 3 and m.f or m.F or scope + prof_fmt = flags..sc..(prof_depth >= 0 and "Z < " or "Z > ") + end + prof_count1 = {} + prof_count2 = {} + prof_samples = 0 + profile.start(scope:lower()..interval, prof_cb) + prof_ud = newproxy(true) + getmetatable(prof_ud).__gc = prof_finish +end + +------------------------------------------------------------------------------ + +local function start(mode, outfile) + if not outfile then outfile = os.getenv("LUAJIT_PROFILEFILE") end + if outfile then + out = outfile == "-" and stdout or assert(io.open(outfile, "w")) + else + out = stdout + end + prof_start(mode or "f") +end + +-- Public module functions. +return { + start = start, -- For -j command line option. + stop = prof_finish +} + diff --git a/fluent-bit/lib/luajit-3065c9/src/jit/v.lua b/fluent-bit/lib/luajit-3065c9/src/jit/v.lua new file mode 100644 index 00000000..ac8b19db --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/jit/v.lua @@ -0,0 +1,170 @@ +---------------------------------------------------------------------------- +-- Verbose mode of the LuaJIT compiler. +-- +-- Copyright (C) 2005-2022 Mike Pall. All rights reserved. +-- Released under the MIT license. See Copyright Notice in luajit.h +---------------------------------------------------------------------------- +-- +-- This module shows verbose information about the progress of the +-- JIT compiler. It prints one line for each generated trace. This module +-- is useful to see which code has been compiled or where the compiler +-- punts and falls back to the interpreter. +-- +-- Example usage: +-- +-- luajit -jv -e "for i=1,1000 do for j=1,1000 do end end" +-- luajit -jv=myapp.out myapp.lua +-- +-- Default output is to stderr. To redirect the output to a file, pass a +-- filename as an argument (use '-' for stdout) or set the environment +-- variable LUAJIT_VERBOSEFILE. The file is overwritten every time the +-- module is started. +-- +-- The output from the first example should look like this: +-- +-- [TRACE 1 (command line):1 loop] +-- [TRACE 2 (1/3) (command line):1 -> 1] +-- +-- The first number in each line is the internal trace number. Next are +-- the file name ('(command line)') and the line number (':1') where the +-- trace has started. Side traces also show the parent trace number and +-- the exit number where they are attached to in parentheses ('(1/3)'). +-- An arrow at the end shows where the trace links to ('-> 1'), unless +-- it loops to itself. +-- +-- In this case the inner loop gets hot and is traced first, generating +-- a root trace. Then the last exit from the 1st trace gets hot, too, +-- and triggers generation of the 2nd trace. The side trace follows the +-- path along the outer loop and *around* the inner loop, back to its +-- start, and then links to the 1st trace. Yes, this may seem unusual, +-- if you know how traditional compilers work. Trace compilers are full +-- of surprises like this -- have fun! :-) +-- +-- Aborted traces are shown like this: +-- +-- [TRACE --- foo.lua:44 -- leaving loop in root trace at foo:lua:50] +-- +-- Don't worry -- trace aborts are quite common, even in programs which +-- can be fully compiled. The compiler may retry several times until it +-- finds a suitable trace. +-- +-- Of course this doesn't work with features that are not-yet-implemented +-- (NYI error messages). The VM simply falls back to the interpreter. This +-- may not matter at all if the particular trace is not very high up in +-- the CPU usage profile. Oh, and the interpreter is quite fast, too. +-- +-- Also check out the -jdump module, which prints all the gory details. +-- +------------------------------------------------------------------------------ + +-- Cache some library functions and objects. +local jit = require("jit") +assert(jit.version_num == 20100, "LuaJIT core/library version mismatch") +local jutil = require("jit.util") +local vmdef = require("jit.vmdef") +local funcinfo, traceinfo = jutil.funcinfo, jutil.traceinfo +local type, format = type, string.format +local stdout, stderr = io.stdout, io.stderr + +-- Active flag and output file handle. +local active, out + +------------------------------------------------------------------------------ + +local startloc, startex + +local function fmtfunc(func, pc) + local fi = funcinfo(func, pc) + if fi.loc then + return fi.loc + elseif fi.ffid then + return vmdef.ffnames[fi.ffid] + elseif fi.addr then + return format("C:%x", fi.addr) + else + return "(?)" + end +end + +-- Format trace error message. +local function fmterr(err, info) + if type(err) == "number" then + if type(info) == "function" then info = fmtfunc(info) end + err = format(vmdef.traceerr[err], info) + end + return err +end + +-- Dump trace states. +local function dump_trace(what, tr, func, pc, otr, oex) + if what == "start" then + startloc = fmtfunc(func, pc) + startex = otr and "("..otr.."/"..(oex == -1 and "stitch" or oex)..") " or "" + else + if what == "abort" then + local loc = fmtfunc(func, pc) + if loc ~= startloc then + out:write(format("[TRACE --- %s%s -- %s at %s]\n", + startex, startloc, fmterr(otr, oex), loc)) + else + out:write(format("[TRACE --- %s%s -- %s]\n", + startex, startloc, fmterr(otr, oex))) + end + elseif what == "stop" then + local info = traceinfo(tr) + local link, ltype = info.link, info.linktype + if ltype == "interpreter" then + out:write(format("[TRACE %3s %s%s -- fallback to interpreter]\n", + tr, startex, startloc)) + elseif ltype == "stitch" then + out:write(format("[TRACE %3s %s%s %s %s]\n", + tr, startex, startloc, ltype, fmtfunc(func, pc))) + elseif link == tr or link == 0 then + out:write(format("[TRACE %3s %s%s %s]\n", + tr, startex, startloc, ltype)) + elseif ltype == "root" then + out:write(format("[TRACE %3s %s%s -> %d]\n", + tr, startex, startloc, link)) + else + out:write(format("[TRACE %3s %s%s -> %d %s]\n", + tr, startex, startloc, link, ltype)) + end + else + out:write(format("[TRACE %s]\n", what)) + end + out:flush() + end +end + +------------------------------------------------------------------------------ + +-- Detach dump handlers. +local function dumpoff() + if active then + active = false + jit.attach(dump_trace) + if out and out ~= stdout and out ~= stderr then out:close() end + out = nil + end +end + +-- Open the output file and attach dump handlers. +local function dumpon(outfile) + if active then dumpoff() end + if not outfile then outfile = os.getenv("LUAJIT_VERBOSEFILE") end + if outfile then + out = outfile == "-" and stdout or assert(io.open(outfile, "w")) + else + out = stderr + end + jit.attach(dump_trace, "trace") + active = true +end + +-- Public module functions. +return { + on = dumpon, + off = dumpoff, + start = dumpon -- For -j command line option. +} + diff --git a/fluent-bit/lib/luajit-3065c9/src/jit/zone.lua b/fluent-bit/lib/luajit-3065c9/src/jit/zone.lua new file mode 100644 index 00000000..1308cb74 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/jit/zone.lua @@ -0,0 +1,45 @@ +---------------------------------------------------------------------------- +-- LuaJIT profiler zones. +-- +-- Copyright (C) 2005-2022 Mike Pall. All rights reserved. +-- Released under the MIT license. See Copyright Notice in luajit.h +---------------------------------------------------------------------------- +-- +-- This module implements a simple hierarchical zone model. +-- +-- Example usage: +-- +-- local zone = require("jit.zone") +-- zone("AI") +-- ... +-- zone("A*") +-- ... +-- print(zone:get()) --> "A*" +-- ... +-- zone() +-- ... +-- print(zone:get()) --> "AI" +-- ... +-- zone() +-- +---------------------------------------------------------------------------- + +local remove = table.remove + +return setmetatable({ + flush = function(t) + for i=#t,1,-1 do t[i] = nil end + end, + get = function(t) + return t[#t] + end +}, { + __call = function(t, zone) + if zone then + t[#t+1] = zone + else + return (assert(remove(t), "empty zone stack")) + end + end +}) + diff --git a/fluent-bit/lib/luajit-3065c9/src/lauxlib.h b/fluent-bit/lib/luajit-3065c9/src/lauxlib.h new file mode 100644 index 00000000..a44f0272 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lauxlib.h @@ -0,0 +1,161 @@ +/* +** $Id: lauxlib.h,v 1.88.1.1 2007/12/27 13:02:25 roberto Exp $ +** Auxiliary functions for building Lua libraries +** See Copyright Notice in lua.h +*/ + + +#ifndef lauxlib_h +#define lauxlib_h + + +#include +#include + +#include "lua.h" + + +/* extra error code for `luaL_load' */ +#define LUA_ERRFILE (LUA_ERRERR+1) + +typedef struct luaL_Reg { + const char *name; + lua_CFunction func; +} luaL_Reg; + +LUALIB_API void (luaL_openlib) (lua_State *L, const char *libname, + const luaL_Reg *l, int nup); +LUALIB_API void (luaL_register) (lua_State *L, const char *libname, + const luaL_Reg *l); +LUALIB_API int (luaL_getmetafield) (lua_State *L, int obj, const char *e); +LUALIB_API int (luaL_callmeta) (lua_State *L, int obj, const char *e); +LUALIB_API int (luaL_typerror) (lua_State *L, int narg, const char *tname); +LUALIB_API int (luaL_argerror) (lua_State *L, int numarg, const char *extramsg); +LUALIB_API const char *(luaL_checklstring) (lua_State *L, int numArg, + size_t *l); +LUALIB_API const char *(luaL_optlstring) (lua_State *L, int numArg, + const char *def, size_t *l); +LUALIB_API lua_Number (luaL_checknumber) (lua_State *L, int numArg); +LUALIB_API lua_Number (luaL_optnumber) (lua_State *L, int nArg, lua_Number def); + +LUALIB_API lua_Integer (luaL_checkinteger) (lua_State *L, int numArg); +LUALIB_API lua_Integer (luaL_optinteger) (lua_State *L, int nArg, + lua_Integer def); + +LUALIB_API void (luaL_checkstack) (lua_State *L, int sz, const char *msg); +LUALIB_API void (luaL_checktype) (lua_State *L, int narg, int t); +LUALIB_API void (luaL_checkany) (lua_State *L, int narg); + +LUALIB_API int (luaL_newmetatable) (lua_State *L, const char *tname); +LUALIB_API void *(luaL_checkudata) (lua_State *L, int ud, const char *tname); + +LUALIB_API void (luaL_where) (lua_State *L, int lvl); +LUALIB_API int (luaL_error) (lua_State *L, const char *fmt, ...); + +LUALIB_API int (luaL_checkoption) (lua_State *L, int narg, const char *def, + const char *const lst[]); + +/* pre-defined references */ +#define LUA_NOREF (-2) +#define LUA_REFNIL (-1) + +LUALIB_API int (luaL_ref) (lua_State *L, int t); +LUALIB_API void (luaL_unref) (lua_State *L, int t, int ref); + +LUALIB_API int (luaL_loadfile) (lua_State *L, const char *filename); +LUALIB_API int (luaL_loadbuffer) (lua_State *L, const char *buff, size_t sz, + const char *name); +LUALIB_API int (luaL_loadstring) (lua_State *L, const char *s); + +LUALIB_API lua_State *(luaL_newstate) (void); + + +LUALIB_API const char *(luaL_gsub) (lua_State *L, const char *s, const char *p, + const char *r); + +LUALIB_API const char *(luaL_findtable) (lua_State *L, int idx, + const char *fname, int szhint); + +/* From Lua 5.2. */ +LUALIB_API int luaL_fileresult(lua_State *L, int stat, const char *fname); +LUALIB_API int luaL_execresult(lua_State *L, int stat); +LUALIB_API int (luaL_loadfilex) (lua_State *L, const char *filename, + const char *mode); +LUALIB_API int (luaL_loadbufferx) (lua_State *L, const char *buff, size_t sz, + const char *name, const char *mode); +LUALIB_API void luaL_traceback (lua_State *L, lua_State *L1, const char *msg, + int level); +LUALIB_API void (luaL_setfuncs) (lua_State *L, const luaL_Reg *l, int nup); +LUALIB_API void (luaL_pushmodule) (lua_State *L, const char *modname, + int sizehint); +LUALIB_API void *(luaL_testudata) (lua_State *L, int ud, const char *tname); +LUALIB_API void (luaL_setmetatable) (lua_State *L, const char *tname); + + +/* +** =============================================================== +** some useful macros +** =============================================================== +*/ + +#define luaL_argcheck(L, cond,numarg,extramsg) \ + ((void)((cond) || luaL_argerror(L, (numarg), (extramsg)))) +#define luaL_checkstring(L,n) (luaL_checklstring(L, (n), NULL)) +#define luaL_optstring(L,n,d) (luaL_optlstring(L, (n), (d), NULL)) +#define luaL_checkint(L,n) ((int)luaL_checkinteger(L, (n))) +#define luaL_optint(L,n,d) ((int)luaL_optinteger(L, (n), (d))) +#define luaL_checklong(L,n) ((long)luaL_checkinteger(L, (n))) +#define luaL_optlong(L,n,d) ((long)luaL_optinteger(L, (n), (d))) + +#define luaL_typename(L,i) lua_typename(L, lua_type(L,(i))) + +#define luaL_dofile(L, fn) \ + (luaL_loadfile(L, fn) || lua_pcall(L, 0, LUA_MULTRET, 0)) + +#define luaL_dostring(L, s) \ + (luaL_loadstring(L, s) || lua_pcall(L, 0, LUA_MULTRET, 0)) + +#define luaL_getmetatable(L,n) (lua_getfield(L, LUA_REGISTRYINDEX, (n))) + +#define luaL_opt(L,f,n,d) (lua_isnoneornil(L,(n)) ? (d) : f(L,(n))) + +/* From Lua 5.2. */ +#define luaL_newlibtable(L, l) \ + lua_createtable(L, 0, sizeof(l)/sizeof((l)[0]) - 1) +#define luaL_newlib(L, l) (luaL_newlibtable(L, l), luaL_setfuncs(L, l, 0)) + +/* +** {====================================================== +** Generic Buffer manipulation +** ======================================================= +*/ + + + +typedef struct luaL_Buffer { + char *p; /* current position in buffer */ + int lvl; /* number of strings in the stack (level) */ + lua_State *L; + char buffer[LUAL_BUFFERSIZE]; +} luaL_Buffer; + +#define luaL_addchar(B,c) \ + ((void)((B)->p < ((B)->buffer+LUAL_BUFFERSIZE) || luaL_prepbuffer(B)), \ + (*(B)->p++ = (char)(c))) + +/* compatibility only */ +#define luaL_putchar(B,c) luaL_addchar(B,c) + +#define luaL_addsize(B,n) ((B)->p += (n)) + +LUALIB_API void (luaL_buffinit) (lua_State *L, luaL_Buffer *B); +LUALIB_API char *(luaL_prepbuffer) (luaL_Buffer *B); +LUALIB_API void (luaL_addlstring) (luaL_Buffer *B, const char *s, size_t l); +LUALIB_API void (luaL_addstring) (luaL_Buffer *B, const char *s); +LUALIB_API void (luaL_addvalue) (luaL_Buffer *B); +LUALIB_API void (luaL_pushresult) (luaL_Buffer *B); + + +/* }====================================================== */ + +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/lib_aux.c b/fluent-bit/lib/luajit-3065c9/src/lib_aux.c new file mode 100644 index 00000000..b8e56436 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lib_aux.c @@ -0,0 +1,370 @@ +/* +** Auxiliary library for the Lua/C API. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +** +** Major parts taken verbatim or adapted from the Lua interpreter. +** Copyright (C) 1994-2008 Lua.org, PUC-Rio. See Copyright Notice in lua.h +*/ + +#include +#include +#include + +#define lib_aux_c +#define LUA_LIB + +#include "lua.h" +#include "lauxlib.h" + +#include "lj_obj.h" +#include "lj_err.h" +#include "lj_state.h" +#include "lj_trace.h" +#include "lj_lib.h" + +#if LJ_TARGET_POSIX +#include +#endif + +/* -- I/O error handling -------------------------------------------------- */ + +LUALIB_API int luaL_fileresult(lua_State *L, int stat, const char *fname) +{ + if (stat) { + setboolV(L->top++, 1); + return 1; + } else { + int en = errno; /* Lua API calls may change this value. */ + setnilV(L->top++); + if (fname) + lua_pushfstring(L, "%s: %s", fname, strerror(en)); + else + lua_pushfstring(L, "%s", strerror(en)); + setintV(L->top++, en); + lj_trace_abort(G(L)); + return 3; + } +} + +LUALIB_API int luaL_execresult(lua_State *L, int stat) +{ + if (stat != -1) { +#if LJ_TARGET_POSIX + if (WIFSIGNALED(stat)) { + stat = WTERMSIG(stat); + setnilV(L->top++); + lua_pushliteral(L, "signal"); + } else { + if (WIFEXITED(stat)) + stat = WEXITSTATUS(stat); + if (stat == 0) + setboolV(L->top++, 1); + else + setnilV(L->top++); + lua_pushliteral(L, "exit"); + } +#else + if (stat == 0) + setboolV(L->top++, 1); + else + setnilV(L->top++); + lua_pushliteral(L, "exit"); +#endif + setintV(L->top++, stat); + return 3; + } + return luaL_fileresult(L, 0, NULL); +} + +/* -- Module registration ------------------------------------------------- */ + +LUALIB_API const char *luaL_findtable(lua_State *L, int idx, + const char *fname, int szhint) +{ + const char *e; + lua_pushvalue(L, idx); + do { + e = strchr(fname, '.'); + if (e == NULL) e = fname + strlen(fname); + lua_pushlstring(L, fname, (size_t)(e - fname)); + lua_rawget(L, -2); + if (lua_isnil(L, -1)) { /* no such field? */ + lua_pop(L, 1); /* remove this nil */ + lua_createtable(L, 0, (*e == '.' ? 1 : szhint)); /* new table for field */ + lua_pushlstring(L, fname, (size_t)(e - fname)); + lua_pushvalue(L, -2); + lua_settable(L, -4); /* set new table into field */ + } else if (!lua_istable(L, -1)) { /* field has a non-table value? */ + lua_pop(L, 2); /* remove table and value */ + return fname; /* return problematic part of the name */ + } + lua_remove(L, -2); /* remove previous table */ + fname = e + 1; + } while (*e == '.'); + return NULL; +} + +static int libsize(const luaL_Reg *l) +{ + int size = 0; + for (; l && l->name; l++) size++; + return size; +} + +LUALIB_API void luaL_pushmodule(lua_State *L, const char *modname, int sizehint) +{ + luaL_findtable(L, LUA_REGISTRYINDEX, "_LOADED", 16); + lua_getfield(L, -1, modname); + if (!lua_istable(L, -1)) { + lua_pop(L, 1); + if (luaL_findtable(L, LUA_GLOBALSINDEX, modname, sizehint) != NULL) + lj_err_callerv(L, LJ_ERR_BADMODN, modname); + lua_pushvalue(L, -1); + lua_setfield(L, -3, modname); /* _LOADED[modname] = new table. */ + } + lua_remove(L, -2); /* Remove _LOADED table. */ +} + +LUALIB_API void luaL_openlib(lua_State *L, const char *libname, + const luaL_Reg *l, int nup) +{ + lj_lib_checkfpu(L); + if (libname) { + luaL_pushmodule(L, libname, libsize(l)); + lua_insert(L, -(nup + 1)); /* Move module table below upvalues. */ + } + if (l) + luaL_setfuncs(L, l, nup); + else + lua_pop(L, nup); /* Remove upvalues. */ +} + +LUALIB_API void luaL_register(lua_State *L, const char *libname, + const luaL_Reg *l) +{ + luaL_openlib(L, libname, l, 0); +} + +LUALIB_API void luaL_setfuncs(lua_State *L, const luaL_Reg *l, int nup) +{ + luaL_checkstack(L, nup, "too many upvalues"); + for (; l->name; l++) { + int i; + for (i = 0; i < nup; i++) /* Copy upvalues to the top. */ + lua_pushvalue(L, -nup); + lua_pushcclosure(L, l->func, nup); + lua_setfield(L, -(nup + 2), l->name); + } + lua_pop(L, nup); /* Remove upvalues. */ +} + +LUALIB_API const char *luaL_gsub(lua_State *L, const char *s, + const char *p, const char *r) +{ + const char *wild; + size_t l = strlen(p); + luaL_Buffer b; + luaL_buffinit(L, &b); + while ((wild = strstr(s, p)) != NULL) { + luaL_addlstring(&b, s, (size_t)(wild - s)); /* push prefix */ + luaL_addstring(&b, r); /* push replacement in place of pattern */ + s = wild + l; /* continue after `p' */ + } + luaL_addstring(&b, s); /* push last suffix */ + luaL_pushresult(&b); + return lua_tostring(L, -1); +} + +/* -- Buffer handling ----------------------------------------------------- */ + +#define bufflen(B) ((size_t)((B)->p - (B)->buffer)) +#define bufffree(B) ((size_t)(LUAL_BUFFERSIZE - bufflen(B))) + +static int emptybuffer(luaL_Buffer *B) +{ + size_t l = bufflen(B); + if (l == 0) + return 0; /* put nothing on stack */ + lua_pushlstring(B->L, B->buffer, l); + B->p = B->buffer; + B->lvl++; + return 1; +} + +static void adjuststack(luaL_Buffer *B) +{ + if (B->lvl > 1) { + lua_State *L = B->L; + int toget = 1; /* number of levels to concat */ + size_t toplen = lua_strlen(L, -1); + do { + size_t l = lua_strlen(L, -(toget+1)); + if (!(B->lvl - toget + 1 >= LUA_MINSTACK/2 || toplen > l)) + break; + toplen += l; + toget++; + } while (toget < B->lvl); + lua_concat(L, toget); + B->lvl = B->lvl - toget + 1; + } +} + +LUALIB_API char *luaL_prepbuffer(luaL_Buffer *B) +{ + if (emptybuffer(B)) + adjuststack(B); + return B->buffer; +} + +LUALIB_API void luaL_addlstring(luaL_Buffer *B, const char *s, size_t l) +{ + if (l <= bufffree(B)) { + memcpy(B->p, s, l); + B->p += l; + } else { + emptybuffer(B); + lua_pushlstring(B->L, s, l); + B->lvl++; + adjuststack(B); + } +} + +LUALIB_API void luaL_addstring(luaL_Buffer *B, const char *s) +{ + luaL_addlstring(B, s, strlen(s)); +} + +LUALIB_API void luaL_pushresult(luaL_Buffer *B) +{ + emptybuffer(B); + lua_concat(B->L, B->lvl); + B->lvl = 1; +} + +LUALIB_API void luaL_addvalue(luaL_Buffer *B) +{ + lua_State *L = B->L; + size_t vl; + const char *s = lua_tolstring(L, -1, &vl); + if (vl <= bufffree(B)) { /* fit into buffer? */ + memcpy(B->p, s, vl); /* put it there */ + B->p += vl; + lua_pop(L, 1); /* remove from stack */ + } else { + if (emptybuffer(B)) + lua_insert(L, -2); /* put buffer before new value */ + B->lvl++; /* add new value into B stack */ + adjuststack(B); + } +} + +LUALIB_API void luaL_buffinit(lua_State *L, luaL_Buffer *B) +{ + B->L = L; + B->p = B->buffer; + B->lvl = 0; +} + +/* -- Reference management ------------------------------------------------ */ + +#define FREELIST_REF 0 + +/* Convert a stack index to an absolute index. */ +#define abs_index(L, i) \ + ((i) > 0 || (i) <= LUA_REGISTRYINDEX ? (i) : lua_gettop(L) + (i) + 1) + +LUALIB_API int luaL_ref(lua_State *L, int t) +{ + int ref; + t = abs_index(L, t); + if (lua_isnil(L, -1)) { + lua_pop(L, 1); /* remove from stack */ + return LUA_REFNIL; /* `nil' has a unique fixed reference */ + } + lua_rawgeti(L, t, FREELIST_REF); /* get first free element */ + ref = (int)lua_tointeger(L, -1); /* ref = t[FREELIST_REF] */ + lua_pop(L, 1); /* remove it from stack */ + if (ref != 0) { /* any free element? */ + lua_rawgeti(L, t, ref); /* remove it from list */ + lua_rawseti(L, t, FREELIST_REF); /* (t[FREELIST_REF] = t[ref]) */ + } else { /* no free elements */ + ref = (int)lua_objlen(L, t); + ref++; /* create new reference */ + } + lua_rawseti(L, t, ref); + return ref; +} + +LUALIB_API void luaL_unref(lua_State *L, int t, int ref) +{ + if (ref >= 0) { + t = abs_index(L, t); + lua_rawgeti(L, t, FREELIST_REF); + lua_rawseti(L, t, ref); /* t[ref] = t[FREELIST_REF] */ + lua_pushinteger(L, ref); + lua_rawseti(L, t, FREELIST_REF); /* t[FREELIST_REF] = ref */ + } +} + +/* -- Default allocator and panic function -------------------------------- */ + +static int panic(lua_State *L) +{ + const char *s = lua_tostring(L, -1); + fputs("PANIC: unprotected error in call to Lua API (", stderr); + fputs(s ? s : "?", stderr); + fputc(')', stderr); fputc('\n', stderr); + fflush(stderr); + return 0; +} + +#ifdef LUAJIT_USE_SYSMALLOC + +#if LJ_64 && !LJ_GC64 && !defined(LUAJIT_USE_VALGRIND) +#error "Must use builtin allocator for 64 bit target" +#endif + +static void *mem_alloc(void *ud, void *ptr, size_t osize, size_t nsize) +{ + (void)ud; + (void)osize; + if (nsize == 0) { + free(ptr); + return NULL; + } else { + return realloc(ptr, nsize); + } +} + +LUALIB_API lua_State *luaL_newstate(void) +{ + lua_State *L = lua_newstate(mem_alloc, NULL); + if (L) G(L)->panic = panic; + return L; +} + +#else + +LUALIB_API lua_State *luaL_newstate(void) +{ + lua_State *L; +#if LJ_64 && !LJ_GC64 + L = lj_state_newstate(LJ_ALLOCF_INTERNAL, NULL); +#else + L = lua_newstate(LJ_ALLOCF_INTERNAL, NULL); +#endif + if (L) G(L)->panic = panic; + return L; +} + +#if LJ_64 && !LJ_GC64 +LUA_API lua_State *lua_newstate(lua_Alloc f, void *ud) +{ + UNUSED(f); UNUSED(ud); + fputs("Must use luaL_newstate() for 64 bit target\n", stderr); + return NULL; +} +#endif + +#endif + diff --git a/fluent-bit/lib/luajit-3065c9/src/lib_base.c b/fluent-bit/lib/luajit-3065c9/src/lib_base.c new file mode 100644 index 00000000..98ec67c7 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lib_base.c @@ -0,0 +1,696 @@ +/* +** Base and coroutine library. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +** +** Major portions taken verbatim or adapted from the Lua interpreter. +** Copyright (C) 1994-2011 Lua.org, PUC-Rio. See Copyright Notice in lua.h +*/ + +#include + +#define lib_base_c +#define LUA_LIB + +#include "lua.h" +#include "lauxlib.h" +#include "lualib.h" + +#include "lj_obj.h" +#include "lj_gc.h" +#include "lj_err.h" +#include "lj_debug.h" +#include "lj_buf.h" +#include "lj_str.h" +#include "lj_tab.h" +#include "lj_meta.h" +#include "lj_state.h" +#include "lj_frame.h" +#if LJ_HASFFI +#include "lj_ctype.h" +#include "lj_cconv.h" +#endif +#include "lj_bc.h" +#include "lj_ff.h" +#include "lj_dispatch.h" +#include "lj_char.h" +#include "lj_strscan.h" +#include "lj_strfmt.h" +#include "lj_lib.h" + +/* -- Base library: checks ------------------------------------------------ */ + +#define LJLIB_MODULE_base + +LJLIB_ASM(assert) LJLIB_REC(.) +{ + lj_lib_checkany(L, 1); + if (L->top == L->base+1) + lj_err_caller(L, LJ_ERR_ASSERT); + else if (tvisstr(L->base+1) || tvisnumber(L->base+1)) + lj_err_callermsg(L, strdata(lj_lib_checkstr(L, 2))); + else + lj_err_run(L); + return FFH_UNREACHABLE; +} + +/* ORDER LJ_T */ +LJLIB_PUSH("nil") +LJLIB_PUSH("boolean") +LJLIB_PUSH(top-1) /* boolean */ +LJLIB_PUSH("userdata") +LJLIB_PUSH("string") +LJLIB_PUSH("upval") +LJLIB_PUSH("thread") +LJLIB_PUSH("proto") +LJLIB_PUSH("function") +LJLIB_PUSH("trace") +LJLIB_PUSH("cdata") +LJLIB_PUSH("table") +LJLIB_PUSH(top-9) /* userdata */ +LJLIB_PUSH("number") +LJLIB_ASM_(type) LJLIB_REC(.) +/* Recycle the lj_lib_checkany(L, 1) from assert. */ + +/* -- Base library: iterators --------------------------------------------- */ + +/* This solves a circular dependency problem -- change FF_next_N as needed. */ +LJ_STATIC_ASSERT((int)FF_next == FF_next_N); + +LJLIB_ASM(next) LJLIB_REC(.) +{ + lj_lib_checktab(L, 1); + lj_err_msg(L, LJ_ERR_NEXTIDX); + return FFH_UNREACHABLE; +} + +#if LJ_52 || LJ_HASFFI +static int ffh_pairs(lua_State *L, MMS mm) +{ + TValue *o = lj_lib_checkany(L, 1); + cTValue *mo = lj_meta_lookup(L, o, mm); + if ((LJ_52 || tviscdata(o)) && !tvisnil(mo)) { + L->top = o+1; /* Only keep one argument. */ + copyTV(L, L->base-1-LJ_FR2, mo); /* Replace callable. */ + return FFH_TAILCALL; + } else { + if (!tvistab(o)) lj_err_argt(L, 1, LUA_TTABLE); + if (LJ_FR2) { copyTV(L, o-1, o); o--; } + setfuncV(L, o-1, funcV(lj_lib_upvalue(L, 1))); + if (mm == MM_pairs) setnilV(o+1); else setintV(o+1, 0); + return FFH_RES(3); + } +} +#else +#define ffh_pairs(L, mm) (lj_lib_checktab(L, 1), FFH_UNREACHABLE) +#endif + +LJLIB_PUSH(lastcl) +LJLIB_ASM(pairs) LJLIB_REC(xpairs 0) +{ + return ffh_pairs(L, MM_pairs); +} + +LJLIB_NOREGUV LJLIB_ASM(ipairs_aux) LJLIB_REC(.) +{ + lj_lib_checktab(L, 1); + lj_lib_checkint(L, 2); + return FFH_UNREACHABLE; +} + +LJLIB_PUSH(lastcl) +LJLIB_ASM(ipairs) LJLIB_REC(xpairs 1) +{ + return ffh_pairs(L, MM_ipairs); +} + +/* -- Base library: getters and setters ----------------------------------- */ + +LJLIB_ASM_(getmetatable) LJLIB_REC(.) +/* Recycle the lj_lib_checkany(L, 1) from assert. */ + +LJLIB_ASM(setmetatable) LJLIB_REC(.) +{ + GCtab *t = lj_lib_checktab(L, 1); + GCtab *mt = lj_lib_checktabornil(L, 2); + if (!tvisnil(lj_meta_lookup(L, L->base, MM_metatable))) + lj_err_caller(L, LJ_ERR_PROTMT); + setgcref(t->metatable, obj2gco(mt)); + if (mt) { lj_gc_objbarriert(L, t, mt); } + settabV(L, L->base-1-LJ_FR2, t); + return FFH_RES(1); +} + +LJLIB_CF(getfenv) LJLIB_REC(.) +{ + GCfunc *fn; + cTValue *o = L->base; + if (!(o < L->top && tvisfunc(o))) { + int level = lj_lib_optint(L, 1, 1); + o = lj_debug_frame(L, level, &level); + if (o == NULL) + lj_err_arg(L, 1, LJ_ERR_INVLVL); + if (LJ_FR2) o--; + } + fn = &gcval(o)->fn; + settabV(L, L->top++, isluafunc(fn) ? tabref(fn->l.env) : tabref(L->env)); + return 1; +} + +LJLIB_CF(setfenv) +{ + GCfunc *fn; + GCtab *t = lj_lib_checktab(L, 2); + cTValue *o = L->base; + if (!(o < L->top && tvisfunc(o))) { + int level = lj_lib_checkint(L, 1); + if (level == 0) { + /* NOBARRIER: A thread (i.e. L) is never black. */ + setgcref(L->env, obj2gco(t)); + return 0; + } + o = lj_debug_frame(L, level, &level); + if (o == NULL) + lj_err_arg(L, 1, LJ_ERR_INVLVL); + if (LJ_FR2) o--; + } + fn = &gcval(o)->fn; + if (!isluafunc(fn)) + lj_err_caller(L, LJ_ERR_SETFENV); + setgcref(fn->l.env, obj2gco(t)); + lj_gc_objbarrier(L, obj2gco(fn), t); + setfuncV(L, L->top++, fn); + return 1; +} + +LJLIB_ASM(rawget) LJLIB_REC(.) +{ + lj_lib_checktab(L, 1); + lj_lib_checkany(L, 2); + return FFH_UNREACHABLE; +} + +LJLIB_CF(rawset) LJLIB_REC(.) +{ + lj_lib_checktab(L, 1); + lj_lib_checkany(L, 2); + L->top = 1+lj_lib_checkany(L, 3); + lua_rawset(L, 1); + return 1; +} + +LJLIB_CF(rawequal) LJLIB_REC(.) +{ + cTValue *o1 = lj_lib_checkany(L, 1); + cTValue *o2 = lj_lib_checkany(L, 2); + setboolV(L->top-1, lj_obj_equal(o1, o2)); + return 1; +} + +#if LJ_52 +LJLIB_CF(rawlen) LJLIB_REC(.) +{ + cTValue *o = L->base; + int32_t len; + if (L->top > o && tvisstr(o)) + len = (int32_t)strV(o)->len; + else + len = (int32_t)lj_tab_len(lj_lib_checktab(L, 1)); + setintV(L->top-1, len); + return 1; +} +#endif + +LJLIB_CF(unpack) +{ + GCtab *t = lj_lib_checktab(L, 1); + int32_t n, i = lj_lib_optint(L, 2, 1); + int32_t e = (L->base+3-1 < L->top && !tvisnil(L->base+3-1)) ? + lj_lib_checkint(L, 3) : (int32_t)lj_tab_len(t); + uint32_t nu; + if (i > e) return 0; + nu = (uint32_t)e - (uint32_t)i; + n = (int32_t)(nu+1); + if (nu >= LUAI_MAXCSTACK || !lua_checkstack(L, n)) + lj_err_caller(L, LJ_ERR_UNPACK); + do { + cTValue *tv = lj_tab_getint(t, i); + if (tv) { + copyTV(L, L->top++, tv); + } else { + setnilV(L->top++); + } + } while (i++ < e); + return n; +} + +LJLIB_CF(select) LJLIB_REC(.) +{ + int32_t n = (int32_t)(L->top - L->base); + if (n >= 1 && tvisstr(L->base) && *strVdata(L->base) == '#') { + setintV(L->top-1, n-1); + return 1; + } else { + int32_t i = lj_lib_checkint(L, 1); + if (i < 0) i = n + i; else if (i > n) i = n; + if (i < 1) + lj_err_arg(L, 1, LJ_ERR_IDXRNG); + return n - i; + } +} + +/* -- Base library: conversions ------------------------------------------- */ + +LJLIB_ASM(tonumber) LJLIB_REC(.) +{ + int32_t base = lj_lib_optint(L, 2, 10); + if (base == 10) { + TValue *o = lj_lib_checkany(L, 1); + if (lj_strscan_numberobj(o)) { + copyTV(L, L->base-1-LJ_FR2, o); + return FFH_RES(1); + } +#if LJ_HASFFI + if (tviscdata(o)) { + CTState *cts = ctype_cts(L); + CType *ct = lj_ctype_rawref(cts, cdataV(o)->ctypeid); + if (ctype_isenum(ct->info)) ct = ctype_child(cts, ct); + if (ctype_isnum(ct->info) || ctype_iscomplex(ct->info)) { + if (LJ_DUALNUM && ctype_isinteger_or_bool(ct->info) && + ct->size <= 4 && !(ct->size == 4 && (ct->info & CTF_UNSIGNED))) { + int32_t i; + lj_cconv_ct_tv(cts, ctype_get(cts, CTID_INT32), (uint8_t *)&i, o, 0); + setintV(L->base-1-LJ_FR2, i); + return FFH_RES(1); + } + lj_cconv_ct_tv(cts, ctype_get(cts, CTID_DOUBLE), + (uint8_t *)&(L->base-1-LJ_FR2)->n, o, 0); + return FFH_RES(1); + } + } +#endif + } else { + const char *p = strdata(lj_lib_checkstr(L, 1)); + char *ep; + unsigned int neg = 0; + unsigned long ul; + if (base < 2 || base > 36) + lj_err_arg(L, 2, LJ_ERR_BASERNG); + while (lj_char_isspace((unsigned char)(*p))) p++; + if (*p == '-') { p++; neg = 1; } else if (*p == '+') { p++; } + if (lj_char_isalnum((unsigned char)(*p))) { + ul = strtoul(p, &ep, base); + if (p != ep) { + while (lj_char_isspace((unsigned char)(*ep))) ep++; + if (*ep == '\0') { + if (LJ_DUALNUM && LJ_LIKELY(ul < 0x80000000u+neg)) { + if (neg) ul = (unsigned long)-(long)ul; + setintV(L->base-1-LJ_FR2, (int32_t)ul); + } else { + lua_Number n = (lua_Number)ul; + if (neg) n = -n; + setnumV(L->base-1-LJ_FR2, n); + } + return FFH_RES(1); + } + } + } + } + setnilV(L->base-1-LJ_FR2); + return FFH_RES(1); +} + +LJLIB_ASM(tostring) LJLIB_REC(.) +{ + TValue *o = lj_lib_checkany(L, 1); + cTValue *mo; + L->top = o+1; /* Only keep one argument. */ + if (!tvisnil(mo = lj_meta_lookup(L, o, MM_tostring))) { + copyTV(L, L->base-1-LJ_FR2, mo); /* Replace callable. */ + return FFH_TAILCALL; + } + lj_gc_check(L); + setstrV(L, L->base-1-LJ_FR2, lj_strfmt_obj(L, L->base)); + return FFH_RES(1); +} + +/* -- Base library: throw and catch errors -------------------------------- */ + +LJLIB_CF(error) +{ + int32_t level = lj_lib_optint(L, 2, 1); + lua_settop(L, 1); + if (lua_isstring(L, 1) && level > 0) { + luaL_where(L, level); + lua_pushvalue(L, 1); + lua_concat(L, 2); + } + return lua_error(L); +} + +LJLIB_ASM(pcall) LJLIB_REC(.) +{ + lj_lib_checkany(L, 1); + lj_lib_checkfunc(L, 2); /* For xpcall only. */ + return FFH_UNREACHABLE; +} +LJLIB_ASM_(xpcall) LJLIB_REC(.) + +/* -- Base library: load Lua code ----------------------------------------- */ + +static int load_aux(lua_State *L, int status, int envarg) +{ + if (status == LUA_OK) { + if (tvistab(L->base+envarg-1)) { + GCfunc *fn = funcV(L->top-1); + GCtab *t = tabV(L->base+envarg-1); + setgcref(fn->c.env, obj2gco(t)); + lj_gc_objbarrier(L, fn, t); + } + return 1; + } else { + setnilV(L->top-2); + return 2; + } +} + +LJLIB_CF(loadfile) +{ + GCstr *fname = lj_lib_optstr(L, 1); + GCstr *mode = lj_lib_optstr(L, 2); + int status; + lua_settop(L, 3); /* Ensure env arg exists. */ + status = luaL_loadfilex(L, fname ? strdata(fname) : NULL, + mode ? strdata(mode) : NULL); + return load_aux(L, status, 3); +} + +static const char *reader_func(lua_State *L, void *ud, size_t *size) +{ + UNUSED(ud); + luaL_checkstack(L, 2, "too many nested functions"); + copyTV(L, L->top++, L->base); + lua_call(L, 0, 1); /* Call user-supplied function. */ + L->top--; + if (tvisnil(L->top)) { + *size = 0; + return NULL; + } else if (tvisstr(L->top) || tvisnumber(L->top)) { + copyTV(L, L->base+4, L->top); /* Anchor string in reserved stack slot. */ + return lua_tolstring(L, 5, size); + } else { + lj_err_caller(L, LJ_ERR_RDRSTR); + return NULL; + } +} + +LJLIB_CF(load) +{ + GCstr *name = lj_lib_optstr(L, 2); + GCstr *mode = lj_lib_optstr(L, 3); + int status; + if (L->base < L->top && + (tvisstr(L->base) || tvisnumber(L->base) || tvisbuf(L->base))) { + const char *s; + MSize len; + if (tvisbuf(L->base)) { + SBufExt *sbx = bufV(L->base); + s = sbx->r; + len = sbufxlen(sbx); + if (!name) name = &G(L)->strempty; /* Buffers are not NUL-terminated. */ + } else { + GCstr *str = lj_lib_checkstr(L, 1); + s = strdata(str); + len = str->len; + } + lua_settop(L, 4); /* Ensure env arg exists. */ + status = luaL_loadbufferx(L, s, len, name ? strdata(name) : s, + mode ? strdata(mode) : NULL); + } else { + lj_lib_checkfunc(L, 1); + lua_settop(L, 5); /* Reserve a slot for the string from the reader. */ + status = lua_loadx(L, reader_func, NULL, name ? strdata(name) : "=(load)", + mode ? strdata(mode) : NULL); + } + return load_aux(L, status, 4); +} + +LJLIB_CF(loadstring) +{ + return lj_cf_load(L); +} + +LJLIB_CF(dofile) +{ + GCstr *fname = lj_lib_optstr(L, 1); + setnilV(L->top); + L->top = L->base+1; + if (luaL_loadfile(L, fname ? strdata(fname) : NULL) != LUA_OK) + lua_error(L); + lua_call(L, 0, LUA_MULTRET); + return (int)(L->top - L->base) - 1; +} + +/* -- Base library: GC control -------------------------------------------- */ + +LJLIB_CF(gcinfo) +{ + setintV(L->top++, (int32_t)(G(L)->gc.total >> 10)); + return 1; +} + +LJLIB_CF(collectgarbage) +{ + int opt = lj_lib_checkopt(L, 1, LUA_GCCOLLECT, /* ORDER LUA_GC* */ + "\4stop\7restart\7collect\5count\1\377\4step\10setpause\12setstepmul\1\377\11isrunning"); + int32_t data = lj_lib_optint(L, 2, 0); + if (opt == LUA_GCCOUNT) { + setnumV(L->top, (lua_Number)G(L)->gc.total/1024.0); + } else { + int res = lua_gc(L, opt, data); + if (opt == LUA_GCSTEP || opt == LUA_GCISRUNNING) + setboolV(L->top, res); + else + setintV(L->top, res); + } + L->top++; + return 1; +} + +/* -- Base library: miscellaneous functions ------------------------------- */ + +LJLIB_PUSH(top-2) /* Upvalue holds weak table. */ +LJLIB_CF(newproxy) +{ + lua_settop(L, 1); + lua_newuserdata(L, 0); + if (lua_toboolean(L, 1) == 0) { /* newproxy(): without metatable. */ + return 1; + } else if (lua_isboolean(L, 1)) { /* newproxy(true): with metatable. */ + lua_newtable(L); + lua_pushvalue(L, -1); + lua_pushboolean(L, 1); + lua_rawset(L, lua_upvalueindex(1)); /* Remember mt in weak table. */ + } else { /* newproxy(proxy): inherit metatable. */ + int validproxy = 0; + if (lua_getmetatable(L, 1)) { + lua_rawget(L, lua_upvalueindex(1)); + validproxy = lua_toboolean(L, -1); + lua_pop(L, 1); + } + if (!validproxy) + lj_err_arg(L, 1, LJ_ERR_NOPROXY); + lua_getmetatable(L, 1); + } + lua_setmetatable(L, 2); + return 1; +} + +LJLIB_PUSH("tostring") +LJLIB_CF(print) +{ + ptrdiff_t i, nargs = L->top - L->base; + cTValue *tv = lj_tab_getstr(tabref(L->env), strV(lj_lib_upvalue(L, 1))); + int shortcut; + if (tv && !tvisnil(tv)) { + copyTV(L, L->top++, tv); + } else { + setstrV(L, L->top++, strV(lj_lib_upvalue(L, 1))); + lua_gettable(L, LUA_GLOBALSINDEX); + tv = L->top-1; + } + shortcut = (tvisfunc(tv) && funcV(tv)->c.ffid == FF_tostring) && + !gcrefu(basemt_it(G(L), LJ_TNUMX)); + for (i = 0; i < nargs; i++) { + cTValue *o = &L->base[i]; + const char *str; + size_t size; + MSize len; + if (shortcut && (str = lj_strfmt_wstrnum(L, o, &len)) != NULL) { + size = len; + } else { + copyTV(L, L->top+1, o); + copyTV(L, L->top, L->top-1); + L->top += 2; + lua_call(L, 1, 1); + str = lua_tolstring(L, -1, &size); + if (!str) + lj_err_caller(L, LJ_ERR_PRTOSTR); + L->top--; + } + if (i) + putchar('\t'); + fwrite(str, 1, size, stdout); + } + putchar('\n'); + return 0; +} + +LJLIB_PUSH(top-3) +LJLIB_SET(_VERSION) + +#include "lj_libdef.h" + +/* -- Coroutine library --------------------------------------------------- */ + +#define LJLIB_MODULE_coroutine + +LJLIB_CF(coroutine_status) +{ + const char *s; + lua_State *co; + if (!(L->top > L->base && tvisthread(L->base))) + lj_err_arg(L, 1, LJ_ERR_NOCORO); + co = threadV(L->base); + if (co == L) s = "running"; + else if (co->status == LUA_YIELD) s = "suspended"; + else if (co->status != LUA_OK) s = "dead"; + else if (co->base > tvref(co->stack)+1+LJ_FR2) s = "normal"; + else if (co->top == co->base) s = "dead"; + else s = "suspended"; + lua_pushstring(L, s); + return 1; +} + +LJLIB_CF(coroutine_running) +{ +#if LJ_52 + int ismain = lua_pushthread(L); + setboolV(L->top++, ismain); + return 2; +#else + if (lua_pushthread(L)) + setnilV(L->top++); + return 1; +#endif +} + +LJLIB_CF(coroutine_isyieldable) +{ + setboolV(L->top++, cframe_canyield(L->cframe)); + return 1; +} + +LJLIB_CF(coroutine_create) +{ + lua_State *L1; + if (!(L->base < L->top && tvisfunc(L->base))) + lj_err_argt(L, 1, LUA_TFUNCTION); + L1 = lua_newthread(L); + setfuncV(L, L1->top++, funcV(L->base)); + return 1; +} + +LJLIB_ASM(coroutine_yield) +{ + lj_err_caller(L, LJ_ERR_CYIELD); + return FFH_UNREACHABLE; +} + +static int ffh_resume(lua_State *L, lua_State *co, int wrap) +{ + if (co->cframe != NULL || co->status > LUA_YIELD || + (co->status == LUA_OK && co->top == co->base)) { + ErrMsg em = co->cframe ? LJ_ERR_CORUN : LJ_ERR_CODEAD; + if (wrap) lj_err_caller(L, em); + setboolV(L->base-1-LJ_FR2, 0); + setstrV(L, L->base-LJ_FR2, lj_err_str(L, em)); + return FFH_RES(2); + } + lj_state_growstack(co, (MSize)(L->top - L->base)); + return FFH_RETRY; +} + +LJLIB_ASM(coroutine_resume) +{ + if (!(L->top > L->base && tvisthread(L->base))) + lj_err_arg(L, 1, LJ_ERR_NOCORO); + return ffh_resume(L, threadV(L->base), 0); +} + +LJLIB_NOREG LJLIB_ASM(coroutine_wrap_aux) +{ + return ffh_resume(L, threadV(lj_lib_upvalue(L, 1)), 1); +} + +/* Inline declarations. */ +LJ_ASMF void lj_ff_coroutine_wrap_aux(void); +#if !(LJ_TARGET_MIPS && defined(ljamalg_c)) +LJ_FUNCA_NORET void LJ_FASTCALL lj_ffh_coroutine_wrap_err(lua_State *L, + lua_State *co); +#endif + +/* Error handler, called from assembler VM. */ +void LJ_FASTCALL lj_ffh_coroutine_wrap_err(lua_State *L, lua_State *co) +{ + co->top--; copyTV(L, L->top, co->top); L->top++; + if (tvisstr(L->top-1)) + lj_err_callermsg(L, strVdata(L->top-1)); + else + lj_err_run(L); +} + +/* Forward declaration. */ +static void setpc_wrap_aux(lua_State *L, GCfunc *fn); + +LJLIB_CF(coroutine_wrap) +{ + GCfunc *fn; + lj_cf_coroutine_create(L); + fn = lj_lib_pushcc(L, lj_ffh_coroutine_wrap_aux, FF_coroutine_wrap_aux, 1); + setpc_wrap_aux(L, fn); + return 1; +} + +#include "lj_libdef.h" + +/* Fix the PC of wrap_aux. Really ugly workaround. */ +static void setpc_wrap_aux(lua_State *L, GCfunc *fn) +{ + setmref(fn->c.pc, &L2GG(L)->bcff[lj_lib_init_coroutine[1]+2]); +} + +/* ------------------------------------------------------------------------ */ + +static void newproxy_weaktable(lua_State *L) +{ + /* NOBARRIER: The table is new (marked white). */ + GCtab *t = lj_tab_new(L, 0, 1); + settabV(L, L->top++, t); + setgcref(t->metatable, obj2gco(t)); + setstrV(L, lj_tab_setstr(L, t, lj_str_newlit(L, "__mode")), + lj_str_newlit(L, "kv")); + t->nomm = (uint8_t)(~(1u<env); + settabV(L, lj_tab_setstr(L, env, lj_str_newlit(L, "_G")), env); + lua_pushliteral(L, LUA_VERSION); /* top-3. */ + newproxy_weaktable(L); /* top-2. */ + LJ_LIB_REG(L, "_G", base); + LJ_LIB_REG(L, LUA_COLIBNAME, coroutine); + return 2; +} + diff --git a/fluent-bit/lib/luajit-3065c9/src/lib_bit.c b/fluent-bit/lib/luajit-3065c9/src/lib_bit.c new file mode 100644 index 00000000..38c0f578 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lib_bit.c @@ -0,0 +1,180 @@ +/* +** Bit manipulation library. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#define lib_bit_c +#define LUA_LIB + +#include "lua.h" +#include "lauxlib.h" +#include "lualib.h" + +#include "lj_obj.h" +#include "lj_err.h" +#include "lj_buf.h" +#include "lj_strscan.h" +#include "lj_strfmt.h" +#if LJ_HASFFI +#include "lj_ctype.h" +#include "lj_cdata.h" +#include "lj_cconv.h" +#include "lj_carith.h" +#endif +#include "lj_ff.h" +#include "lj_lib.h" + +/* ------------------------------------------------------------------------ */ + +#define LJLIB_MODULE_bit + +#if LJ_HASFFI +static int bit_result64(lua_State *L, CTypeID id, uint64_t x) +{ + GCcdata *cd = lj_cdata_new_(L, id, 8); + *(uint64_t *)cdataptr(cd) = x; + setcdataV(L, L->base-1-LJ_FR2, cd); + return FFH_RES(1); +} +#else +static int32_t bit_checkbit(lua_State *L, int narg) +{ + TValue *o = L->base + narg-1; + if (!(o < L->top && lj_strscan_numberobj(o))) + lj_err_argt(L, narg, LUA_TNUMBER); + if (LJ_LIKELY(tvisint(o))) { + return intV(o); + } else { + int32_t i = lj_num2bit(numV(o)); + if (LJ_DUALNUM) setintV(o, i); + return i; + } +} +#endif + +LJLIB_ASM(bit_tobit) LJLIB_REC(bit_tobit) +{ +#if LJ_HASFFI + CTypeID id = 0; + setintV(L->base-1-LJ_FR2, (int32_t)lj_carith_check64(L, 1, &id)); + return FFH_RES(1); +#else + lj_lib_checknumber(L, 1); + return FFH_RETRY; +#endif +} + +LJLIB_ASM(bit_bnot) LJLIB_REC(bit_unary IR_BNOT) +{ +#if LJ_HASFFI + CTypeID id = 0; + uint64_t x = lj_carith_check64(L, 1, &id); + return id ? bit_result64(L, id, ~x) : FFH_RETRY; +#else + lj_lib_checknumber(L, 1); + return FFH_RETRY; +#endif +} + +LJLIB_ASM(bit_bswap) LJLIB_REC(bit_unary IR_BSWAP) +{ +#if LJ_HASFFI + CTypeID id = 0; + uint64_t x = lj_carith_check64(L, 1, &id); + return id ? bit_result64(L, id, lj_bswap64(x)) : FFH_RETRY; +#else + lj_lib_checknumber(L, 1); + return FFH_RETRY; +#endif +} + +LJLIB_ASM(bit_lshift) LJLIB_REC(bit_shift IR_BSHL) +{ +#if LJ_HASFFI + CTypeID id = 0, id2 = 0; + uint64_t x = lj_carith_check64(L, 1, &id); + int32_t sh = (int32_t)lj_carith_check64(L, 2, &id2); + if (id) { + x = lj_carith_shift64(x, sh, curr_func(L)->c.ffid - (int)FF_bit_lshift); + return bit_result64(L, id, x); + } + if (id2) setintV(L->base+1, sh); + return FFH_RETRY; +#else + lj_lib_checknumber(L, 1); + bit_checkbit(L, 2); + return FFH_RETRY; +#endif +} +LJLIB_ASM_(bit_rshift) LJLIB_REC(bit_shift IR_BSHR) +LJLIB_ASM_(bit_arshift) LJLIB_REC(bit_shift IR_BSAR) +LJLIB_ASM_(bit_rol) LJLIB_REC(bit_shift IR_BROL) +LJLIB_ASM_(bit_ror) LJLIB_REC(bit_shift IR_BROR) + +LJLIB_ASM(bit_band) LJLIB_REC(bit_nary IR_BAND) +{ +#if LJ_HASFFI + CTypeID id = 0; + TValue *o = L->base, *top = L->top; + int i = 0; + do { lj_carith_check64(L, ++i, &id); } while (++o < top); + if (id) { + CTState *cts = ctype_cts(L); + CType *ct = ctype_get(cts, id); + int op = curr_func(L)->c.ffid - (int)FF_bit_bor; + uint64_t x, y = op >= 0 ? 0 : ~(uint64_t)0; + o = L->base; + do { + lj_cconv_ct_tv(cts, ct, (uint8_t *)&x, o, 0); + if (op < 0) y &= x; else if (op == 0) y |= x; else y ^= x; + } while (++o < top); + return bit_result64(L, id, y); + } + return FFH_RETRY; +#else + int i = 0; + do { lj_lib_checknumber(L, ++i); } while (L->base+i < L->top); + return FFH_RETRY; +#endif +} +LJLIB_ASM_(bit_bor) LJLIB_REC(bit_nary IR_BOR) +LJLIB_ASM_(bit_bxor) LJLIB_REC(bit_nary IR_BXOR) + +/* ------------------------------------------------------------------------ */ + +LJLIB_CF(bit_tohex) LJLIB_REC(.) +{ +#if LJ_HASFFI + CTypeID id = 0, id2 = 0; + uint64_t b = lj_carith_check64(L, 1, &id); + int32_t n = L->base+1>=L->top ? (id ? 16 : 8) : + (int32_t)lj_carith_check64(L, 2, &id2); +#else + uint32_t b = (uint32_t)bit_checkbit(L, 1); + int32_t n = L->base+1>=L->top ? 8 : bit_checkbit(L, 2); +#endif + SBuf *sb = lj_buf_tmp_(L); + SFormat sf = (STRFMT_UINT|STRFMT_T_HEX); + if (n < 0) { n = -n; sf |= STRFMT_F_UPPER; } + sf |= ((SFormat)((n+1)&255) << STRFMT_SH_PREC); +#if LJ_HASFFI + if (n < 16) b &= ((uint64_t)1 << 4*n)-1; +#else + if (n < 8) b &= (1u << 4*n)-1; +#endif + sb = lj_strfmt_putfxint(sb, sf, b); + setstrV(L, L->top-1, lj_buf_str(L, sb)); + lj_gc_check(L); + return 1; +} + +/* ------------------------------------------------------------------------ */ + +#include "lj_libdef.h" + +LUALIB_API int luaopen_bit(lua_State *L) +{ + LJ_LIB_REG(L, LUA_BITLIBNAME, bit); + return 1; +} + diff --git a/fluent-bit/lib/luajit-3065c9/src/lib_buffer.c b/fluent-bit/lib/luajit-3065c9/src/lib_buffer.c new file mode 100644 index 00000000..e3d24504 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lib_buffer.c @@ -0,0 +1,358 @@ +/* +** Buffer library. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#define lib_buffer_c +#define LUA_LIB + +#include "lua.h" +#include "lauxlib.h" +#include "lualib.h" + +#include "lj_obj.h" + +#if LJ_HASBUFFER +#include "lj_gc.h" +#include "lj_err.h" +#include "lj_buf.h" +#include "lj_str.h" +#include "lj_tab.h" +#include "lj_udata.h" +#include "lj_meta.h" +#if LJ_HASFFI +#include "lj_ctype.h" +#include "lj_cdata.h" +#include "lj_cconv.h" +#endif +#include "lj_strfmt.h" +#include "lj_serialize.h" +#include "lj_lib.h" + +/* -- Helper functions ---------------------------------------------------- */ + +/* Check that the first argument is a string buffer. */ +static SBufExt *buffer_tobuf(lua_State *L) +{ + if (!(L->base < L->top && tvisbuf(L->base))) + lj_err_argtype(L, 1, "buffer"); + return bufV(L->base); +} + +/* Ditto, but for writers. */ +static LJ_AINLINE SBufExt *buffer_tobufw(lua_State *L) +{ + SBufExt *sbx = buffer_tobuf(L); + setsbufXL_(sbx, L); + return sbx; +} + +#define buffer_toudata(sbx) ((GCudata *)(sbx)-1) + +/* -- Buffer methods ------------------------------------------------------ */ + +#define LJLIB_MODULE_buffer_method + +LJLIB_CF(buffer_method_free) +{ + SBufExt *sbx = buffer_tobuf(L); + lj_bufx_free(L, sbx); + L->top = L->base+1; /* Chain buffer object. */ + return 1; +} + +LJLIB_CF(buffer_method_reset) LJLIB_REC(.) +{ + SBufExt *sbx = buffer_tobuf(L); + lj_bufx_reset(sbx); + L->top = L->base+1; /* Chain buffer object. */ + return 1; +} + +LJLIB_CF(buffer_method_skip) LJLIB_REC(.) +{ + SBufExt *sbx = buffer_tobuf(L); + MSize n = (MSize)lj_lib_checkintrange(L, 2, 0, LJ_MAX_BUF); + MSize len = sbufxlen(sbx); + if (n < len) { + sbx->r += n; + } else if (sbufiscow(sbx)) { + sbx->r = sbx->w; + } else { + sbx->r = sbx->w = sbx->b; + } + L->top = L->base+1; /* Chain buffer object. */ + return 1; +} + +LJLIB_CF(buffer_method_set) LJLIB_REC(.) +{ + SBufExt *sbx = buffer_tobuf(L); + GCobj *ref; + const char *p; + MSize len; +#if LJ_HASFFI + if (tviscdata(L->base+1)) { + CTState *cts = ctype_cts(L); + lj_cconv_ct_tv(cts, ctype_get(cts, CTID_P_CVOID), (uint8_t *)&p, + L->base+1, CCF_ARG(2)); + len = (MSize)lj_lib_checkintrange(L, 3, 0, LJ_MAX_BUF); + } else +#endif + { + GCstr *str = lj_lib_checkstrx(L, 2); + p = strdata(str); + len = str->len; + } + lj_bufx_free(L, sbx); + lj_bufx_set_cow(L, sbx, p, len); + ref = gcV(L->base+1); + setgcref(sbx->cowref, ref); + lj_gc_objbarrier(L, buffer_toudata(sbx), ref); + L->top = L->base+1; /* Chain buffer object. */ + return 1; +} + +LJLIB_CF(buffer_method_put) LJLIB_REC(.) +{ + SBufExt *sbx = buffer_tobufw(L); + ptrdiff_t arg, narg = L->top - L->base; + for (arg = 1; arg < narg; arg++) { + cTValue *o = &L->base[arg], *mo = NULL; + retry: + if (tvisstr(o)) { + lj_buf_putstr((SBuf *)sbx, strV(o)); + } else if (tvisint(o)) { + lj_strfmt_putint((SBuf *)sbx, intV(o)); + } else if (tvisnum(o)) { + lj_strfmt_putfnum((SBuf *)sbx, STRFMT_G14, numV(o)); + } else if (tvisbuf(o)) { + SBufExt *sbx2 = bufV(o); + if (sbx2 == sbx) lj_err_arg(L, arg+1, LJ_ERR_BUFFER_SELF); + lj_buf_putmem((SBuf *)sbx, sbx2->r, sbufxlen(sbx2)); + } else if (!mo && !tvisnil(mo = lj_meta_lookup(L, o, MM_tostring))) { + /* Call __tostring metamethod inline. */ + copyTV(L, L->top++, mo); + copyTV(L, L->top++, o); + lua_call(L, 1, 1); + o = &L->base[arg]; /* The stack may have been reallocated. */ + copyTV(L, &L->base[arg], L->top-1); + L->top = L->base + narg; + goto retry; /* Retry with the result. */ + } else { + lj_err_argtype(L, arg+1, "string/number/__tostring"); + } + /* Probably not useful to inline other __tostring MMs, e.g. FFI numbers. */ + } + L->top = L->base+1; /* Chain buffer object. */ + lj_gc_check(L); + return 1; +} + +LJLIB_CF(buffer_method_putf) LJLIB_REC(.) +{ + SBufExt *sbx = buffer_tobufw(L); + lj_strfmt_putarg(L, (SBuf *)sbx, 2, 2); + L->top = L->base+1; /* Chain buffer object. */ + lj_gc_check(L); + return 1; +} + +LJLIB_CF(buffer_method_get) LJLIB_REC(.) +{ + SBufExt *sbx = buffer_tobuf(L); + ptrdiff_t arg, narg = L->top - L->base; + if (narg == 1) { + narg++; + setnilV(L->top++); /* get() is the same as get(nil). */ + } + for (arg = 1; arg < narg; arg++) { + TValue *o = &L->base[arg]; + MSize n = tvisnil(o) ? LJ_MAX_BUF : + (MSize) lj_lib_checkintrange(L, arg+1, 0, LJ_MAX_BUF); + MSize len = sbufxlen(sbx); + if (n > len) n = len; + setstrV(L, o, lj_str_new(L, sbx->r, n)); + sbx->r += n; + } + if (sbx->r == sbx->w && !sbufiscow(sbx)) sbx->r = sbx->w = sbx->b; + lj_gc_check(L); + return narg-1; +} + +#if LJ_HASFFI +LJLIB_CF(buffer_method_putcdata) LJLIB_REC(.) +{ + SBufExt *sbx = buffer_tobufw(L); + const char *p; + MSize len; + if (tviscdata(L->base+1)) { + CTState *cts = ctype_cts(L); + lj_cconv_ct_tv(cts, ctype_get(cts, CTID_P_CVOID), (uint8_t *)&p, + L->base+1, CCF_ARG(2)); + } else { + lj_err_argtype(L, 2, "cdata"); + } + len = (MSize)lj_lib_checkintrange(L, 3, 0, LJ_MAX_BUF); + lj_buf_putmem((SBuf *)sbx, p, len); + L->top = L->base+1; /* Chain buffer object. */ + return 1; +} + +LJLIB_CF(buffer_method_reserve) LJLIB_REC(.) +{ + SBufExt *sbx = buffer_tobufw(L); + MSize sz = (MSize)lj_lib_checkintrange(L, 2, 0, LJ_MAX_BUF); + GCcdata *cd; + lj_buf_more((SBuf *)sbx, sz); + ctype_loadffi(L); + cd = lj_cdata_new_(L, CTID_P_UINT8, CTSIZE_PTR); + *(void **)cdataptr(cd) = sbx->w; + setcdataV(L, L->top++, cd); + setintV(L->top++, sbufleft(sbx)); + return 2; +} + +LJLIB_CF(buffer_method_commit) LJLIB_REC(.) +{ + SBufExt *sbx = buffer_tobuf(L); + MSize len = (MSize)lj_lib_checkintrange(L, 2, 0, LJ_MAX_BUF); + if (len > sbufleft(sbx)) lj_err_arg(L, 2, LJ_ERR_NUMRNG); + sbx->w += len; + L->top = L->base+1; /* Chain buffer object. */ + return 1; +} + +LJLIB_CF(buffer_method_ref) LJLIB_REC(.) +{ + SBufExt *sbx = buffer_tobuf(L); + GCcdata *cd; + ctype_loadffi(L); + cd = lj_cdata_new_(L, CTID_P_UINT8, CTSIZE_PTR); + *(void **)cdataptr(cd) = sbx->r; + setcdataV(L, L->top++, cd); + setintV(L->top++, sbufxlen(sbx)); + return 2; +} +#endif + +LJLIB_CF(buffer_method_encode) LJLIB_REC(.) +{ + SBufExt *sbx = buffer_tobufw(L); + cTValue *o = lj_lib_checkany(L, 2); + lj_serialize_put(sbx, o); + lj_gc_check(L); + L->top = L->base+1; /* Chain buffer object. */ + return 1; +} + +LJLIB_CF(buffer_method_decode) LJLIB_REC(.) +{ + SBufExt *sbx = buffer_tobufw(L); + setnilV(L->top++); + sbx->r = lj_serialize_get(sbx, L->top-1); + lj_gc_check(L); + return 1; +} + +LJLIB_CF(buffer_method___gc) +{ + SBufExt *sbx = buffer_tobuf(L); + lj_bufx_free(L, sbx); + return 0; +} + +LJLIB_CF(buffer_method___tostring) LJLIB_REC(.) +{ + SBufExt *sbx = buffer_tobuf(L); + setstrV(L, L->top-1, lj_str_new(L, sbx->r, sbufxlen(sbx))); + lj_gc_check(L); + return 1; +} + +LJLIB_CF(buffer_method___len) LJLIB_REC(.) +{ + SBufExt *sbx = buffer_tobuf(L); + setintV(L->top-1, (int32_t)sbufxlen(sbx)); + return 1; +} + +LJLIB_PUSH("buffer") LJLIB_SET(__metatable) +LJLIB_PUSH(top-1) LJLIB_SET(__index) + +/* -- Buffer library functions -------------------------------------------- */ + +#define LJLIB_MODULE_buffer + +LJLIB_PUSH(top-2) LJLIB_SET(!) /* Set environment. */ + +LJLIB_CF(buffer_new) +{ + MSize sz = 0; + int targ = 1; + GCtab *env, *dict_str = NULL, *dict_mt = NULL; + GCudata *ud; + SBufExt *sbx; + if (L->base < L->top && !tvistab(L->base)) { + targ = 2; + if (!tvisnil(L->base)) + sz = (MSize)lj_lib_checkintrange(L, 1, 0, LJ_MAX_BUF); + } + if (L->base+targ-1 < L->top) { + GCtab *options = lj_lib_checktab(L, targ); + cTValue *opt_dict, *opt_mt; + opt_dict = lj_tab_getstr(options, lj_str_newlit(L, "dict")); + if (opt_dict && tvistab(opt_dict)) { + dict_str = tabV(opt_dict); + lj_serialize_dict_prep_str(L, dict_str); + } + opt_mt = lj_tab_getstr(options, lj_str_newlit(L, "metatable")); + if (opt_mt && tvistab(opt_mt)) { + dict_mt = tabV(opt_mt); + lj_serialize_dict_prep_mt(L, dict_mt); + } + } + env = tabref(curr_func(L)->c.env); + ud = lj_udata_new(L, sizeof(SBufExt), env); + ud->udtype = UDTYPE_BUFFER; + /* NOBARRIER: The GCudata is new (marked white). */ + setgcref(ud->metatable, obj2gco(env)); + setudataV(L, L->top++, ud); + sbx = (SBufExt *)uddata(ud); + lj_bufx_init(L, sbx); + setgcref(sbx->dict_str, obj2gco(dict_str)); + setgcref(sbx->dict_mt, obj2gco(dict_mt)); + if (sz > 0) lj_buf_need2((SBuf *)sbx, sz); + return 1; +} + +LJLIB_CF(buffer_encode) LJLIB_REC(.) +{ + cTValue *o = lj_lib_checkany(L, 1); + setstrV(L, L->top++, lj_serialize_encode(L, o)); + lj_gc_check(L); + return 1; +} + +LJLIB_CF(buffer_decode) LJLIB_REC(.) +{ + GCstr *str = lj_lib_checkstrx(L, 1); + setnilV(L->top++); + lj_serialize_decode(L, L->top-1, str); + return 1; +} + +/* ------------------------------------------------------------------------ */ + +#include "lj_libdef.h" + +int luaopen_string_buffer(lua_State *L) +{ + LJ_LIB_REG(L, NULL, buffer_method); + lua_getfield(L, -1, "__tostring"); + lua_setfield(L, -2, "tostring"); + LJ_LIB_REG(L, NULL, buffer); + return 1; +} + +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/lib_debug.c b/fluent-bit/lib/luajit-3065c9/src/lib_debug.c new file mode 100644 index 00000000..3af7a353 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lib_debug.c @@ -0,0 +1,406 @@ +/* +** Debug library. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +** +** Major portions taken verbatim or adapted from the Lua interpreter. +** Copyright (C) 1994-2008 Lua.org, PUC-Rio. See Copyright Notice in lua.h +*/ + +#define lib_debug_c +#define LUA_LIB + +#include "lua.h" +#include "lauxlib.h" +#include "lualib.h" + +#include "lj_obj.h" +#include "lj_gc.h" +#include "lj_err.h" +#include "lj_debug.h" +#include "lj_lib.h" + +/* ------------------------------------------------------------------------ */ + +#define LJLIB_MODULE_debug + +LJLIB_CF(debug_getregistry) +{ + copyTV(L, L->top++, registry(L)); + return 1; +} + +LJLIB_CF(debug_getmetatable) LJLIB_REC(.) +{ + lj_lib_checkany(L, 1); + if (!lua_getmetatable(L, 1)) { + setnilV(L->top-1); + } + return 1; +} + +LJLIB_CF(debug_setmetatable) +{ + lj_lib_checktabornil(L, 2); + L->top = L->base+2; + lua_setmetatable(L, 1); +#if !LJ_52 + setboolV(L->top-1, 1); +#endif + return 1; +} + +LJLIB_CF(debug_getfenv) +{ + lj_lib_checkany(L, 1); + lua_getfenv(L, 1); + return 1; +} + +LJLIB_CF(debug_setfenv) +{ + lj_lib_checktab(L, 2); + L->top = L->base+2; + if (!lua_setfenv(L, 1)) + lj_err_caller(L, LJ_ERR_SETFENV); + return 1; +} + +/* ------------------------------------------------------------------------ */ + +static void settabss(lua_State *L, const char *i, const char *v) +{ + lua_pushstring(L, v); + lua_setfield(L, -2, i); +} + +static void settabsi(lua_State *L, const char *i, int v) +{ + lua_pushinteger(L, v); + lua_setfield(L, -2, i); +} + +static void settabsb(lua_State *L, const char *i, int v) +{ + lua_pushboolean(L, v); + lua_setfield(L, -2, i); +} + +static lua_State *getthread(lua_State *L, int *arg) +{ + if (L->base < L->top && tvisthread(L->base)) { + *arg = 1; + return threadV(L->base); + } else { + *arg = 0; + return L; + } +} + +static void treatstackoption(lua_State *L, lua_State *L1, const char *fname) +{ + if (L == L1) { + lua_pushvalue(L, -2); + lua_remove(L, -3); + } + else + lua_xmove(L1, L, 1); + lua_setfield(L, -2, fname); +} + +LJLIB_CF(debug_getinfo) +{ + lj_Debug ar; + int arg, opt_f = 0, opt_L = 0; + lua_State *L1 = getthread(L, &arg); + const char *options = luaL_optstring(L, arg+2, "flnSu"); + if (lua_isnumber(L, arg+1)) { + if (!lua_getstack(L1, (int)lua_tointeger(L, arg+1), (lua_Debug *)&ar)) { + setnilV(L->top-1); + return 1; + } + } else if (L->base+arg < L->top && tvisfunc(L->base+arg)) { + options = lua_pushfstring(L, ">%s", options); + setfuncV(L1, L1->top++, funcV(L->base+arg)); + } else { + lj_err_arg(L, arg+1, LJ_ERR_NOFUNCL); + } + if (!lj_debug_getinfo(L1, options, &ar, 1)) + lj_err_arg(L, arg+2, LJ_ERR_INVOPT); + lua_createtable(L, 0, 16); /* Create result table. */ + for (; *options; options++) { + switch (*options) { + case 'S': + settabss(L, "source", ar.source); + settabss(L, "short_src", ar.short_src); + settabsi(L, "linedefined", ar.linedefined); + settabsi(L, "lastlinedefined", ar.lastlinedefined); + settabss(L, "what", ar.what); + break; + case 'l': + settabsi(L, "currentline", ar.currentline); + break; + case 'u': + settabsi(L, "nups", ar.nups); + settabsi(L, "nparams", ar.nparams); + settabsb(L, "isvararg", ar.isvararg); + break; + case 'n': + settabss(L, "name", ar.name); + settabss(L, "namewhat", ar.namewhat); + break; + case 'f': opt_f = 1; break; + case 'L': opt_L = 1; break; + default: break; + } + } + if (opt_L) treatstackoption(L, L1, "activelines"); + if (opt_f) treatstackoption(L, L1, "func"); + return 1; /* Return result table. */ +} + +LJLIB_CF(debug_getlocal) +{ + int arg; + lua_State *L1 = getthread(L, &arg); + lua_Debug ar; + const char *name; + int slot = lj_lib_checkint(L, arg+2); + if (tvisfunc(L->base+arg)) { + L->top = L->base+arg+1; + lua_pushstring(L, lua_getlocal(L, NULL, slot)); + return 1; + } + if (!lua_getstack(L1, lj_lib_checkint(L, arg+1), &ar)) + lj_err_arg(L, arg+1, LJ_ERR_LVLRNG); + name = lua_getlocal(L1, &ar, slot); + if (name) { + lua_xmove(L1, L, 1); + lua_pushstring(L, name); + lua_pushvalue(L, -2); + return 2; + } else { + setnilV(L->top-1); + return 1; + } +} + +LJLIB_CF(debug_setlocal) +{ + int arg; + lua_State *L1 = getthread(L, &arg); + lua_Debug ar; + TValue *tv; + if (!lua_getstack(L1, lj_lib_checkint(L, arg+1), &ar)) + lj_err_arg(L, arg+1, LJ_ERR_LVLRNG); + tv = lj_lib_checkany(L, arg+3); + copyTV(L1, L1->top++, tv); + lua_pushstring(L, lua_setlocal(L1, &ar, lj_lib_checkint(L, arg+2))); + return 1; +} + +static int debug_getupvalue(lua_State *L, int get) +{ + int32_t n = lj_lib_checkint(L, 2); + const char *name; + lj_lib_checkfunc(L, 1); + name = get ? lua_getupvalue(L, 1, n) : lua_setupvalue(L, 1, n); + if (name) { + lua_pushstring(L, name); + if (!get) return 1; + copyTV(L, L->top, L->top-2); + L->top++; + return 2; + } + return 0; +} + +LJLIB_CF(debug_getupvalue) +{ + return debug_getupvalue(L, 1); +} + +LJLIB_CF(debug_setupvalue) +{ + lj_lib_checkany(L, 3); + return debug_getupvalue(L, 0); +} + +LJLIB_CF(debug_upvalueid) +{ + GCfunc *fn = lj_lib_checkfunc(L, 1); + int32_t n = lj_lib_checkint(L, 2) - 1; + if ((uint32_t)n >= fn->l.nupvalues) + lj_err_arg(L, 2, LJ_ERR_IDXRNG); + lua_pushlightuserdata(L, isluafunc(fn) ? (void *)gcref(fn->l.uvptr[n]) : + (void *)&fn->c.upvalue[n]); + return 1; +} + +LJLIB_CF(debug_upvaluejoin) +{ + GCfunc *fn[2]; + GCRef *p[2]; + int i; + for (i = 0; i < 2; i++) { + int32_t n; + fn[i] = lj_lib_checkfunc(L, 2*i+1); + if (!isluafunc(fn[i])) + lj_err_arg(L, 2*i+1, LJ_ERR_NOLFUNC); + n = lj_lib_checkint(L, 2*i+2) - 1; + if ((uint32_t)n >= fn[i]->l.nupvalues) + lj_err_arg(L, 2*i+2, LJ_ERR_IDXRNG); + p[i] = &fn[i]->l.uvptr[n]; + } + setgcrefr(*p[0], *p[1]); + lj_gc_objbarrier(L, fn[0], gcref(*p[1])); + return 0; +} + +#if LJ_52 +LJLIB_CF(debug_getuservalue) +{ + TValue *o = L->base; + if (o < L->top && tvisudata(o)) + settabV(L, o, tabref(udataV(o)->env)); + else + setnilV(o); + L->top = o+1; + return 1; +} + +LJLIB_CF(debug_setuservalue) +{ + TValue *o = L->base; + if (!(o < L->top && tvisudata(o))) + lj_err_argt(L, 1, LUA_TUSERDATA); + if (!(o+1 < L->top && tvistab(o+1))) + lj_err_argt(L, 2, LUA_TTABLE); + L->top = o+2; + lua_setfenv(L, 1); + return 1; +} +#endif + +/* ------------------------------------------------------------------------ */ + +#define KEY_HOOK (U64x(80000000,00000000)|'h') + +static void hookf(lua_State *L, lua_Debug *ar) +{ + static const char *const hooknames[] = + {"call", "return", "line", "count", "tail return"}; + (L->top++)->u64 = KEY_HOOK; + lua_rawget(L, LUA_REGISTRYINDEX); + if (lua_isfunction(L, -1)) { + lua_pushstring(L, hooknames[(int)ar->event]); + if (ar->currentline >= 0) + lua_pushinteger(L, ar->currentline); + else lua_pushnil(L); + lua_call(L, 2, 0); + } +} + +static int makemask(const char *smask, int count) +{ + int mask = 0; + if (strchr(smask, 'c')) mask |= LUA_MASKCALL; + if (strchr(smask, 'r')) mask |= LUA_MASKRET; + if (strchr(smask, 'l')) mask |= LUA_MASKLINE; + if (count > 0) mask |= LUA_MASKCOUNT; + return mask; +} + +static char *unmakemask(int mask, char *smask) +{ + int i = 0; + if (mask & LUA_MASKCALL) smask[i++] = 'c'; + if (mask & LUA_MASKRET) smask[i++] = 'r'; + if (mask & LUA_MASKLINE) smask[i++] = 'l'; + smask[i] = '\0'; + return smask; +} + +LJLIB_CF(debug_sethook) +{ + int arg, mask, count; + lua_Hook func; + (void)getthread(L, &arg); + if (lua_isnoneornil(L, arg+1)) { + lua_settop(L, arg+1); + func = NULL; mask = 0; count = 0; /* turn off hooks */ + } else { + const char *smask = luaL_checkstring(L, arg+2); + luaL_checktype(L, arg+1, LUA_TFUNCTION); + count = luaL_optint(L, arg+3, 0); + func = hookf; mask = makemask(smask, count); + } + (L->top++)->u64 = KEY_HOOK; + lua_pushvalue(L, arg+1); + lua_rawset(L, LUA_REGISTRYINDEX); + lua_sethook(L, func, mask, count); + return 0; +} + +LJLIB_CF(debug_gethook) +{ + char buff[5]; + int mask = lua_gethookmask(L); + lua_Hook hook = lua_gethook(L); + if (hook != NULL && hook != hookf) { /* external hook? */ + lua_pushliteral(L, "external hook"); + } else { + (L->top++)->u64 = KEY_HOOK; + lua_rawget(L, LUA_REGISTRYINDEX); /* get hook */ + } + lua_pushstring(L, unmakemask(mask, buff)); + lua_pushinteger(L, lua_gethookcount(L)); + return 3; +} + +/* ------------------------------------------------------------------------ */ + +LJLIB_CF(debug_debug) +{ + for (;;) { + char buffer[250]; + fputs("lua_debug> ", stderr); + if (fgets(buffer, sizeof(buffer), stdin) == 0 || + strcmp(buffer, "cont\n") == 0) + return 0; + if (luaL_loadbuffer(L, buffer, strlen(buffer), "=(debug command)") || + lua_pcall(L, 0, 0, 0)) { + const char *s = lua_tostring(L, -1); + fputs(s ? s : "(error object is not a string)", stderr); + fputs("\n", stderr); + } + lua_settop(L, 0); /* remove eventual returns */ + } +} + +/* ------------------------------------------------------------------------ */ + +#define LEVELS1 12 /* size of the first part of the stack */ +#define LEVELS2 10 /* size of the second part of the stack */ + +LJLIB_CF(debug_traceback) +{ + int arg; + lua_State *L1 = getthread(L, &arg); + const char *msg = lua_tostring(L, arg+1); + if (msg == NULL && L->top > L->base+arg) + L->top = L->base+arg+1; + else + luaL_traceback(L, L1, msg, lj_lib_optint(L, arg+2, (L == L1))); + return 1; +} + +/* ------------------------------------------------------------------------ */ + +#include "lj_libdef.h" + +LUALIB_API int luaopen_debug(lua_State *L) +{ + LJ_LIB_REG(L, LUA_DBLIBNAME, debug); + return 1; +} + diff --git a/fluent-bit/lib/luajit-3065c9/src/lib_ffi.c b/fluent-bit/lib/luajit-3065c9/src/lib_ffi.c new file mode 100644 index 00000000..2295cf15 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lib_ffi.c @@ -0,0 +1,870 @@ +/* +** FFI library. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#define lib_ffi_c +#define LUA_LIB + +#include + +#include "lua.h" +#include "lauxlib.h" +#include "lualib.h" + +#include "lj_obj.h" + +#if LJ_HASFFI + +#include "lj_gc.h" +#include "lj_err.h" +#include "lj_str.h" +#include "lj_tab.h" +#include "lj_meta.h" +#include "lj_ctype.h" +#include "lj_cparse.h" +#include "lj_cdata.h" +#include "lj_cconv.h" +#include "lj_carith.h" +#include "lj_ccall.h" +#include "lj_ccallback.h" +#include "lj_clib.h" +#include "lj_strfmt.h" +#include "lj_ff.h" +#include "lj_lib.h" + +/* -- C type checks ------------------------------------------------------- */ + +/* Check first argument for a C type and returns its ID. */ +static CTypeID ffi_checkctype(lua_State *L, CTState *cts, TValue *param) +{ + TValue *o = L->base; + if (!(o < L->top)) { + err_argtype: + lj_err_argtype(L, 1, "C type"); + } + if (tvisstr(o)) { /* Parse an abstract C type declaration. */ + GCstr *s = strV(o); + CPState cp; + int errcode; + cp.L = L; + cp.cts = cts; + cp.srcname = strdata(s); + cp.p = strdata(s); + cp.param = param; + cp.mode = CPARSE_MODE_ABSTRACT|CPARSE_MODE_NOIMPLICIT; + errcode = lj_cparse(&cp); + if (errcode) lj_err_throw(L, errcode); /* Propagate errors. */ + return cp.val.id; + } else { + GCcdata *cd; + if (!tviscdata(o)) goto err_argtype; + if (param && param < L->top) lj_err_arg(L, 1, LJ_ERR_FFI_NUMPARAM); + cd = cdataV(o); + return cd->ctypeid == CTID_CTYPEID ? *(CTypeID *)cdataptr(cd) : cd->ctypeid; + } +} + +/* Check argument for C data and return it. */ +static GCcdata *ffi_checkcdata(lua_State *L, int narg) +{ + TValue *o = L->base + narg-1; + if (!(o < L->top && tviscdata(o))) + lj_err_argt(L, narg, LUA_TCDATA); + return cdataV(o); +} + +/* Convert argument to C pointer. */ +static void *ffi_checkptr(lua_State *L, int narg, CTypeID id) +{ + CTState *cts = ctype_cts(L); + TValue *o = L->base + narg-1; + void *p; + if (o >= L->top) + lj_err_arg(L, narg, LJ_ERR_NOVAL); + lj_cconv_ct_tv(cts, ctype_get(cts, id), (uint8_t *)&p, o, CCF_ARG(narg)); + return p; +} + +/* Convert argument to int32_t. */ +static int32_t ffi_checkint(lua_State *L, int narg) +{ + CTState *cts = ctype_cts(L); + TValue *o = L->base + narg-1; + int32_t i; + if (o >= L->top) + lj_err_arg(L, narg, LJ_ERR_NOVAL); + lj_cconv_ct_tv(cts, ctype_get(cts, CTID_INT32), (uint8_t *)&i, o, + CCF_ARG(narg)); + return i; +} + +/* -- C type metamethods -------------------------------------------------- */ + +#define LJLIB_MODULE_ffi_meta + +/* Handle ctype __index/__newindex metamethods. */ +static int ffi_index_meta(lua_State *L, CTState *cts, CType *ct, MMS mm) +{ + CTypeID id = ctype_typeid(cts, ct); + cTValue *tv = lj_ctype_meta(cts, id, mm); + TValue *base = L->base; + if (!tv) { + const char *s; + err_index: + s = strdata(lj_ctype_repr(L, id, NULL)); + if (tvisstr(L->base+1)) { + lj_err_callerv(L, LJ_ERR_FFI_BADMEMBER, s, strVdata(L->base+1)); + } else { + const char *key = tviscdata(L->base+1) ? + strdata(lj_ctype_repr(L, cdataV(L->base+1)->ctypeid, NULL)) : + lj_typename(L->base+1); + lj_err_callerv(L, LJ_ERR_FFI_BADIDXW, s, key); + } + } + if (!tvisfunc(tv)) { + if (mm == MM_index) { + cTValue *o = lj_meta_tget(L, tv, base+1); + if (o) { + if (tvisnil(o)) goto err_index; + copyTV(L, L->top-1, o); + return 1; + } + } else { + TValue *o = lj_meta_tset(L, tv, base+1); + if (o) { + copyTV(L, o, base+2); + return 0; + } + } + copyTV(L, base, L->top); + tv = L->top-1-LJ_FR2; + } + return lj_meta_tailcall(L, tv); +} + +LJLIB_CF(ffi_meta___index) LJLIB_REC(cdata_index 0) +{ + CTState *cts = ctype_cts(L); + CTInfo qual = 0; + CType *ct; + uint8_t *p; + TValue *o = L->base; + if (!(o+1 < L->top && tviscdata(o))) /* Also checks for presence of key. */ + lj_err_argt(L, 1, LUA_TCDATA); + ct = lj_cdata_index(cts, cdataV(o), o+1, &p, &qual); + if ((qual & 1)) + return ffi_index_meta(L, cts, ct, MM_index); + if (lj_cdata_get(cts, ct, L->top-1, p)) + lj_gc_check(L); + return 1; +} + +LJLIB_CF(ffi_meta___newindex) LJLIB_REC(cdata_index 1) +{ + CTState *cts = ctype_cts(L); + CTInfo qual = 0; + CType *ct; + uint8_t *p; + TValue *o = L->base; + if (!(o+2 < L->top && tviscdata(o))) /* Also checks for key and value. */ + lj_err_argt(L, 1, LUA_TCDATA); + ct = lj_cdata_index(cts, cdataV(o), o+1, &p, &qual); + if ((qual & 1)) { + if ((qual & CTF_CONST)) + lj_err_caller(L, LJ_ERR_FFI_WRCONST); + return ffi_index_meta(L, cts, ct, MM_newindex); + } + lj_cdata_set(cts, ct, p, o+2, qual); + return 0; +} + +/* Common handler for cdata arithmetic. */ +static int ffi_arith(lua_State *L) +{ + MMS mm = (MMS)(curr_func(L)->c.ffid - (int)FF_ffi_meta___eq + (int)MM_eq); + return lj_carith_op(L, mm); +} + +/* The following functions must be in contiguous ORDER MM. */ +LJLIB_CF(ffi_meta___eq) LJLIB_REC(cdata_arith MM_eq) +{ + return ffi_arith(L); +} + +LJLIB_CF(ffi_meta___len) LJLIB_REC(cdata_arith MM_len) +{ + return ffi_arith(L); +} + +LJLIB_CF(ffi_meta___lt) LJLIB_REC(cdata_arith MM_lt) +{ + return ffi_arith(L); +} + +LJLIB_CF(ffi_meta___le) LJLIB_REC(cdata_arith MM_le) +{ + return ffi_arith(L); +} + +LJLIB_CF(ffi_meta___concat) LJLIB_REC(cdata_arith MM_concat) +{ + return ffi_arith(L); +} + +/* Forward declaration. */ +static int lj_cf_ffi_new(lua_State *L); + +LJLIB_CF(ffi_meta___call) LJLIB_REC(cdata_call) +{ + CTState *cts = ctype_cts(L); + GCcdata *cd = ffi_checkcdata(L, 1); + CTypeID id = cd->ctypeid; + CType *ct; + cTValue *tv; + MMS mm = MM_call; + if (cd->ctypeid == CTID_CTYPEID) { + id = *(CTypeID *)cdataptr(cd); + mm = MM_new; + } else { + int ret = lj_ccall_func(L, cd); + if (ret >= 0) + return ret; + } + /* Handle ctype __call/__new metamethod. */ + ct = ctype_raw(cts, id); + if (ctype_isptr(ct->info)) id = ctype_cid(ct->info); + tv = lj_ctype_meta(cts, id, mm); + if (tv) + return lj_meta_tailcall(L, tv); + else if (mm == MM_call) + lj_err_callerv(L, LJ_ERR_FFI_BADCALL, strdata(lj_ctype_repr(L, id, NULL))); + return lj_cf_ffi_new(L); +} + +LJLIB_CF(ffi_meta___add) LJLIB_REC(cdata_arith MM_add) +{ + return ffi_arith(L); +} + +LJLIB_CF(ffi_meta___sub) LJLIB_REC(cdata_arith MM_sub) +{ + return ffi_arith(L); +} + +LJLIB_CF(ffi_meta___mul) LJLIB_REC(cdata_arith MM_mul) +{ + return ffi_arith(L); +} + +LJLIB_CF(ffi_meta___div) LJLIB_REC(cdata_arith MM_div) +{ + return ffi_arith(L); +} + +LJLIB_CF(ffi_meta___mod) LJLIB_REC(cdata_arith MM_mod) +{ + return ffi_arith(L); +} + +LJLIB_CF(ffi_meta___pow) LJLIB_REC(cdata_arith MM_pow) +{ + return ffi_arith(L); +} + +LJLIB_CF(ffi_meta___unm) LJLIB_REC(cdata_arith MM_unm) +{ + return ffi_arith(L); +} +/* End of contiguous ORDER MM. */ + +LJLIB_CF(ffi_meta___tostring) +{ + GCcdata *cd = ffi_checkcdata(L, 1); + const char *msg = "cdata<%s>: %p"; + CTypeID id = cd->ctypeid; + void *p = cdataptr(cd); + if (id == CTID_CTYPEID) { + msg = "ctype<%s>"; + id = *(CTypeID *)p; + } else { + CTState *cts = ctype_cts(L); + CType *ct = ctype_raw(cts, id); + if (ctype_isref(ct->info)) { + p = *(void **)p; + ct = ctype_rawchild(cts, ct); + } + if (ctype_iscomplex(ct->info)) { + setstrV(L, L->top-1, lj_ctype_repr_complex(L, cdataptr(cd), ct->size)); + goto checkgc; + } else if (ct->size == 8 && ctype_isinteger(ct->info)) { + setstrV(L, L->top-1, lj_ctype_repr_int64(L, *(uint64_t *)cdataptr(cd), + (ct->info & CTF_UNSIGNED))); + goto checkgc; + } else if (ctype_isfunc(ct->info)) { + p = *(void **)p; + } else if (ctype_isenum(ct->info)) { + msg = "cdata<%s>: %d"; + p = (void *)(uintptr_t)*(uint32_t **)p; + } else { + if (ctype_isptr(ct->info)) { + p = cdata_getptr(p, ct->size); + ct = ctype_rawchild(cts, ct); + } + if (ctype_isstruct(ct->info) || ctype_isvector(ct->info)) { + /* Handle ctype __tostring metamethod. */ + cTValue *tv = lj_ctype_meta(cts, ctype_typeid(cts, ct), MM_tostring); + if (tv) + return lj_meta_tailcall(L, tv); + } + } + } + lj_strfmt_pushf(L, msg, strdata(lj_ctype_repr(L, id, NULL)), p); +checkgc: + lj_gc_check(L); + return 1; +} + +static int ffi_pairs(lua_State *L, MMS mm) +{ + CTState *cts = ctype_cts(L); + CTypeID id = ffi_checkcdata(L, 1)->ctypeid; + CType *ct = ctype_raw(cts, id); + cTValue *tv; + if (ctype_isptr(ct->info)) id = ctype_cid(ct->info); + tv = lj_ctype_meta(cts, id, mm); + if (!tv) + lj_err_callerv(L, LJ_ERR_FFI_BADMM, strdata(lj_ctype_repr(L, id, NULL)), + strdata(mmname_str(G(L), mm))); + return lj_meta_tailcall(L, tv); +} + +LJLIB_CF(ffi_meta___pairs) +{ + return ffi_pairs(L, MM_pairs); +} + +LJLIB_CF(ffi_meta___ipairs) +{ + return ffi_pairs(L, MM_ipairs); +} + +LJLIB_PUSH("ffi") LJLIB_SET(__metatable) + +#include "lj_libdef.h" + +/* -- C library metamethods ----------------------------------------------- */ + +#define LJLIB_MODULE_ffi_clib + +/* Index C library by a name. */ +static TValue *ffi_clib_index(lua_State *L) +{ + TValue *o = L->base; + CLibrary *cl; + if (!(o < L->top && tvisudata(o) && udataV(o)->udtype == UDTYPE_FFI_CLIB)) + lj_err_argt(L, 1, LUA_TUSERDATA); + cl = (CLibrary *)uddata(udataV(o)); + if (!(o+1 < L->top && tvisstr(o+1))) + lj_err_argt(L, 2, LUA_TSTRING); + return lj_clib_index(L, cl, strV(o+1)); +} + +LJLIB_CF(ffi_clib___index) LJLIB_REC(clib_index 1) +{ + TValue *tv = ffi_clib_index(L); + if (tviscdata(tv)) { + CTState *cts = ctype_cts(L); + GCcdata *cd = cdataV(tv); + CType *s = ctype_get(cts, cd->ctypeid); + if (ctype_isextern(s->info)) { + CTypeID sid = ctype_cid(s->info); + void *sp = *(void **)cdataptr(cd); + CType *ct = ctype_raw(cts, sid); + if (lj_cconv_tv_ct(cts, ct, sid, L->top-1, sp)) + lj_gc_check(L); + return 1; + } + } + copyTV(L, L->top-1, tv); + return 1; +} + +LJLIB_CF(ffi_clib___newindex) LJLIB_REC(clib_index 0) +{ + TValue *tv = ffi_clib_index(L); + TValue *o = L->base+2; + if (o < L->top && tviscdata(tv)) { + CTState *cts = ctype_cts(L); + GCcdata *cd = cdataV(tv); + CType *d = ctype_get(cts, cd->ctypeid); + if (ctype_isextern(d->info)) { + CTInfo qual = 0; + for (;;) { /* Skip attributes and collect qualifiers. */ + d = ctype_child(cts, d); + if (!ctype_isattrib(d->info)) break; + if (ctype_attrib(d->info) == CTA_QUAL) qual |= d->size; + } + if (!((d->info|qual) & CTF_CONST)) { + lj_cconv_ct_tv(cts, d, *(void **)cdataptr(cd), o, 0); + return 0; + } + } + } + lj_err_caller(L, LJ_ERR_FFI_WRCONST); + return 0; /* unreachable */ +} + +LJLIB_CF(ffi_clib___gc) +{ + TValue *o = L->base; + if (o < L->top && tvisudata(o) && udataV(o)->udtype == UDTYPE_FFI_CLIB) + lj_clib_unload((CLibrary *)uddata(udataV(o))); + return 0; +} + +#include "lj_libdef.h" + +/* -- Callback function metamethods --------------------------------------- */ + +#define LJLIB_MODULE_ffi_callback + +static int ffi_callback_set(lua_State *L, GCfunc *fn) +{ + GCcdata *cd = ffi_checkcdata(L, 1); + CTState *cts = ctype_cts(L); + CType *ct = ctype_raw(cts, cd->ctypeid); + if (ctype_isptr(ct->info) && (LJ_32 || ct->size == 8)) { + MSize slot = lj_ccallback_ptr2slot(cts, *(void **)cdataptr(cd)); + if (slot < cts->cb.sizeid && cts->cb.cbid[slot] != 0) { + GCtab *t = cts->miscmap; + TValue *tv = lj_tab_setint(L, t, (int32_t)slot); + if (fn) { + setfuncV(L, tv, fn); + lj_gc_anybarriert(L, t); + } else { + setnilV(tv); + cts->cb.cbid[slot] = 0; + cts->cb.topid = slot < cts->cb.topid ? slot : cts->cb.topid; + } + return 0; + } + } + lj_err_caller(L, LJ_ERR_FFI_BADCBACK); + return 0; +} + +LJLIB_CF(ffi_callback_free) +{ + return ffi_callback_set(L, NULL); +} + +LJLIB_CF(ffi_callback_set) +{ + GCfunc *fn = lj_lib_checkfunc(L, 2); + return ffi_callback_set(L, fn); +} + +LJLIB_PUSH(top-1) LJLIB_SET(__index) + +#include "lj_libdef.h" + +/* -- FFI library functions ----------------------------------------------- */ + +#define LJLIB_MODULE_ffi + +LJLIB_CF(ffi_cdef) +{ + GCstr *s = lj_lib_checkstr(L, 1); + CPState cp; + int errcode; + cp.L = L; + cp.cts = ctype_cts(L); + cp.srcname = strdata(s); + cp.p = strdata(s); + cp.param = L->base+1; + cp.mode = CPARSE_MODE_MULTI|CPARSE_MODE_DIRECT; + errcode = lj_cparse(&cp); + if (errcode) lj_err_throw(L, errcode); /* Propagate errors. */ + lj_gc_check(L); + return 0; +} + +LJLIB_CF(ffi_new) LJLIB_REC(.) +{ + CTState *cts = ctype_cts(L); + CTypeID id = ffi_checkctype(L, cts, NULL); + CType *ct = ctype_raw(cts, id); + CTSize sz; + CTInfo info = lj_ctype_info(cts, id, &sz); + TValue *o = L->base+1; + GCcdata *cd; + if ((info & CTF_VLA)) { + o++; + sz = lj_ctype_vlsize(cts, ct, (CTSize)ffi_checkint(L, 2)); + } + if (sz == CTSIZE_INVALID) + lj_err_arg(L, 1, LJ_ERR_FFI_INVSIZE); + cd = lj_cdata_newx(cts, id, sz, info); + setcdataV(L, o-1, cd); /* Anchor the uninitialized cdata. */ + lj_cconv_ct_init(cts, ct, sz, cdataptr(cd), + o, (MSize)(L->top - o)); /* Initialize cdata. */ + if (ctype_isstruct(ct->info)) { + /* Handle ctype __gc metamethod. Use the fast lookup here. */ + cTValue *tv = lj_tab_getinth(cts->miscmap, -(int32_t)id); + if (tv && tvistab(tv) && (tv = lj_meta_fast(L, tabV(tv), MM_gc))) { + GCtab *t = cts->finalizer; + if (gcref(t->metatable)) { + /* Add to finalizer table, if still enabled. */ + copyTV(L, lj_tab_set(L, t, o-1), tv); + lj_gc_anybarriert(L, t); + cd->marked |= LJ_GC_CDATA_FIN; + } + } + } + L->top = o; /* Only return the cdata itself. */ + lj_gc_check(L); + return 1; +} + +LJLIB_CF(ffi_cast) LJLIB_REC(ffi_new) +{ + CTState *cts = ctype_cts(L); + CTypeID id = ffi_checkctype(L, cts, NULL); + CType *d = ctype_raw(cts, id); + TValue *o = lj_lib_checkany(L, 2); + L->top = o+1; /* Make sure this is the last item on the stack. */ + if (!(ctype_isnum(d->info) || ctype_isptr(d->info) || ctype_isenum(d->info))) + lj_err_arg(L, 1, LJ_ERR_FFI_INVTYPE); + if (!(tviscdata(o) && cdataV(o)->ctypeid == id)) { + GCcdata *cd = lj_cdata_new(cts, id, d->size); + lj_cconv_ct_tv(cts, d, cdataptr(cd), o, CCF_CAST); + setcdataV(L, o, cd); + lj_gc_check(L); + } + return 1; +} + +LJLIB_CF(ffi_typeof) LJLIB_REC(.) +{ + CTState *cts = ctype_cts(L); + CTypeID id = ffi_checkctype(L, cts, L->base+1); + GCcdata *cd = lj_cdata_new(cts, CTID_CTYPEID, 4); + *(CTypeID *)cdataptr(cd) = id; + setcdataV(L, L->top-1, cd); + lj_gc_check(L); + return 1; +} + +/* Internal and unsupported API. */ +LJLIB_CF(ffi_typeinfo) +{ + CTState *cts = ctype_cts(L); + CTypeID id = (CTypeID)ffi_checkint(L, 1); + if (id > 0 && id < cts->top) { + CType *ct = ctype_get(cts, id); + GCtab *t; + lua_createtable(L, 0, 4); /* Increment hash size if fields are added. */ + t = tabV(L->top-1); + setintV(lj_tab_setstr(L, t, lj_str_newlit(L, "info")), (int32_t)ct->info); + if (ct->size != CTSIZE_INVALID) + setintV(lj_tab_setstr(L, t, lj_str_newlit(L, "size")), (int32_t)ct->size); + if (ct->sib) + setintV(lj_tab_setstr(L, t, lj_str_newlit(L, "sib")), (int32_t)ct->sib); + if (gcref(ct->name)) { + GCstr *s = gco2str(gcref(ct->name)); + if (isdead(G(L), obj2gco(s))) flipwhite(obj2gco(s)); + setstrV(L, lj_tab_setstr(L, t, lj_str_newlit(L, "name")), s); + } + lj_gc_check(L); + return 1; + } + return 0; +} + +LJLIB_CF(ffi_istype) LJLIB_REC(.) +{ + CTState *cts = ctype_cts(L); + CTypeID id1 = ffi_checkctype(L, cts, NULL); + TValue *o = lj_lib_checkany(L, 2); + int b = 0; + if (tviscdata(o)) { + GCcdata *cd = cdataV(o); + CTypeID id2 = cd->ctypeid == CTID_CTYPEID ? *(CTypeID *)cdataptr(cd) : + cd->ctypeid; + CType *ct1 = lj_ctype_rawref(cts, id1); + CType *ct2 = lj_ctype_rawref(cts, id2); + if (ct1 == ct2) { + b = 1; + } else if (ctype_type(ct1->info) == ctype_type(ct2->info) && + ct1->size == ct2->size) { + if (ctype_ispointer(ct1->info)) + b = lj_cconv_compatptr(cts, ct1, ct2, CCF_IGNQUAL); + else if (ctype_isnum(ct1->info) || ctype_isvoid(ct1->info)) + b = (((ct1->info ^ ct2->info) & ~(CTF_QUAL|CTF_LONG)) == 0); + } else if (ctype_isstruct(ct1->info) && ctype_isptr(ct2->info) && + ct1 == ctype_rawchild(cts, ct2)) { + b = 1; + } + } + setboolV(L->top-1, b); + setboolV(&G(L)->tmptv2, b); /* Remember for trace recorder. */ + return 1; +} + +LJLIB_CF(ffi_sizeof) LJLIB_REC(ffi_xof FF_ffi_sizeof) +{ + CTState *cts = ctype_cts(L); + CTypeID id = ffi_checkctype(L, cts, NULL); + CTSize sz; + if (LJ_UNLIKELY(tviscdata(L->base) && cdataisv(cdataV(L->base)))) { + sz = cdatavlen(cdataV(L->base)); + } else { + CType *ct = lj_ctype_rawref(cts, id); + if (ctype_isvltype(ct->info)) + sz = lj_ctype_vlsize(cts, ct, (CTSize)ffi_checkint(L, 2)); + else + sz = ctype_hassize(ct->info) ? ct->size : CTSIZE_INVALID; + if (LJ_UNLIKELY(sz == CTSIZE_INVALID)) { + setnilV(L->top-1); + return 1; + } + } + setintV(L->top-1, (int32_t)sz); + return 1; +} + +LJLIB_CF(ffi_alignof) LJLIB_REC(ffi_xof FF_ffi_alignof) +{ + CTState *cts = ctype_cts(L); + CTypeID id = ffi_checkctype(L, cts, NULL); + CTSize sz = 0; + CTInfo info = lj_ctype_info_raw(cts, id, &sz); + setintV(L->top-1, 1 << ctype_align(info)); + return 1; +} + +LJLIB_CF(ffi_offsetof) LJLIB_REC(ffi_xof FF_ffi_offsetof) +{ + CTState *cts = ctype_cts(L); + CTypeID id = ffi_checkctype(L, cts, NULL); + GCstr *name = lj_lib_checkstr(L, 2); + CType *ct = lj_ctype_rawref(cts, id); + CTSize ofs; + if (ctype_isstruct(ct->info) && ct->size != CTSIZE_INVALID) { + CType *fct = lj_ctype_getfield(cts, ct, name, &ofs); + if (fct) { + setintV(L->top-1, ofs); + if (ctype_isfield(fct->info)) { + return 1; + } else if (ctype_isbitfield(fct->info)) { + setintV(L->top++, ctype_bitpos(fct->info)); + setintV(L->top++, ctype_bitbsz(fct->info)); + return 3; + } + } + } + return 0; +} + +LJLIB_CF(ffi_errno) LJLIB_REC(.) +{ + int err = errno; + if (L->top > L->base) + errno = ffi_checkint(L, 1); + setintV(L->top++, err); + return 1; +} + +LJLIB_CF(ffi_string) LJLIB_REC(.) +{ + CTState *cts = ctype_cts(L); + TValue *o = lj_lib_checkany(L, 1); + const char *p; + size_t len; + if (o+1 < L->top && !tvisnil(o+1)) { + len = (size_t)ffi_checkint(L, 2); + lj_cconv_ct_tv(cts, ctype_get(cts, CTID_P_CVOID), (uint8_t *)&p, o, + CCF_ARG(1)); + } else { + lj_cconv_ct_tv(cts, ctype_get(cts, CTID_P_CCHAR), (uint8_t *)&p, o, + CCF_ARG(1)); + len = strlen(p); + } + L->top = o+1; /* Make sure this is the last item on the stack. */ + setstrV(L, o, lj_str_new(L, p, len)); + lj_gc_check(L); + return 1; +} + +LJLIB_CF(ffi_copy) LJLIB_REC(.) +{ + void *dp = ffi_checkptr(L, 1, CTID_P_VOID); + void *sp = ffi_checkptr(L, 2, CTID_P_CVOID); + TValue *o = L->base+1; + CTSize len; + if (tvisstr(o) && o+1 >= L->top) + len = strV(o)->len+1; /* Copy Lua string including trailing '\0'. */ + else + len = (CTSize)ffi_checkint(L, 3); + memcpy(dp, sp, len); + return 0; +} + +LJLIB_CF(ffi_fill) LJLIB_REC(.) +{ + void *dp = ffi_checkptr(L, 1, CTID_P_VOID); + CTSize len = (CTSize)ffi_checkint(L, 2); + int32_t fill = 0; + if (L->base+2 < L->top && !tvisnil(L->base+2)) fill = ffi_checkint(L, 3); + memset(dp, fill, len); + return 0; +} + +/* Test ABI string. */ +LJLIB_CF(ffi_abi) LJLIB_REC(.) +{ + GCstr *s = lj_lib_checkstr(L, 1); + int b = lj_cparse_case(s, +#if LJ_64 + "\00564bit" +#else + "\00532bit" +#endif +#if LJ_ARCH_HASFPU + "\003fpu" +#endif +#if LJ_ABI_SOFTFP + "\006softfp" +#else + "\006hardfp" +#endif +#if LJ_ABI_EABI + "\004eabi" +#endif +#if LJ_ABI_WIN + "\003win" +#endif +#if LJ_TARGET_UWP + "\003uwp" +#endif +#if LJ_LE + "\002le" +#else + "\002be" +#endif +#if LJ_GC64 + "\004gc64" +#endif + ) >= 0; + setboolV(L->top-1, b); + setboolV(&G(L)->tmptv2, b); /* Remember for trace recorder. */ + return 1; +} + +LJLIB_PUSH(top-8) LJLIB_SET(!) /* Store reference to miscmap table. */ + +LJLIB_CF(ffi_metatype) +{ + CTState *cts = ctype_cts(L); + CTypeID id = ffi_checkctype(L, cts, NULL); + GCtab *mt = lj_lib_checktab(L, 2); + GCtab *t = cts->miscmap; + CType *ct = ctype_raw(cts, id); + TValue *tv; + GCcdata *cd; + if (!(ctype_isstruct(ct->info) || ctype_iscomplex(ct->info) || + ctype_isvector(ct->info))) + lj_err_arg(L, 1, LJ_ERR_FFI_INVTYPE); + tv = lj_tab_setinth(L, t, -(int32_t)id); + if (!tvisnil(tv)) + lj_err_caller(L, LJ_ERR_PROTMT); + settabV(L, tv, mt); + lj_gc_anybarriert(L, t); + cd = lj_cdata_new(cts, CTID_CTYPEID, 4); + *(CTypeID *)cdataptr(cd) = id; + setcdataV(L, L->top-1, cd); + lj_gc_check(L); + return 1; +} + +LJLIB_PUSH(top-7) LJLIB_SET(!) /* Store reference to finalizer table. */ + +LJLIB_CF(ffi_gc) LJLIB_REC(.) +{ + GCcdata *cd = ffi_checkcdata(L, 1); + TValue *fin = lj_lib_checkany(L, 2); + CTState *cts = ctype_cts(L); + CType *ct = ctype_raw(cts, cd->ctypeid); + if (!(ctype_isptr(ct->info) || ctype_isstruct(ct->info) || + ctype_isrefarray(ct->info))) + lj_err_arg(L, 1, LJ_ERR_FFI_INVTYPE); + lj_cdata_setfin(L, cd, gcval(fin), itype(fin)); + L->top = L->base+1; /* Pass through the cdata object. */ + return 1; +} + +LJLIB_PUSH(top-5) LJLIB_SET(!) /* Store clib metatable in func environment. */ + +LJLIB_CF(ffi_load) +{ + GCstr *name = lj_lib_checkstr(L, 1); + int global = (L->base+1 < L->top && tvistruecond(L->base+1)); + lj_clib_load(L, tabref(curr_func(L)->c.env), name, global); + return 1; +} + +LJLIB_PUSH(top-4) LJLIB_SET(C) +LJLIB_PUSH(top-3) LJLIB_SET(os) +LJLIB_PUSH(top-2) LJLIB_SET(arch) + +#include "lj_libdef.h" + +/* ------------------------------------------------------------------------ */ + +/* Create special weak-keyed finalizer table. */ +static GCtab *ffi_finalizer(lua_State *L) +{ + /* NOBARRIER: The table is new (marked white). */ + GCtab *t = lj_tab_new(L, 0, 1); + settabV(L, L->top++, t); + setgcref(t->metatable, obj2gco(t)); + setstrV(L, lj_tab_setstr(L, t, lj_str_newlit(L, "__mode")), + lj_str_newlit(L, "k")); + t->nomm = (uint8_t)(~(1u<top-1); + lj_gc_anybarriert(L, t); + } +} + +LUALIB_API int luaopen_ffi(lua_State *L) +{ + CTState *cts = lj_ctype_init(L); + settabV(L, L->top++, (cts->miscmap = lj_tab_new(L, 0, 1))); + cts->finalizer = ffi_finalizer(L); + LJ_LIB_REG(L, NULL, ffi_meta); + /* NOBARRIER: basemt is a GC root. */ + setgcref(basemt_it(G(L), LJ_TCDATA), obj2gco(tabV(L->top-1))); + LJ_LIB_REG(L, NULL, ffi_clib); + LJ_LIB_REG(L, NULL, ffi_callback); + /* NOBARRIER: the key is new and lj_tab_newkey() handles the barrier. */ + settabV(L, lj_tab_setstr(L, cts->miscmap, &cts->g->strempty), tabV(L->top-1)); + L->top--; + lj_clib_default(L, tabV(L->top-1)); /* Create ffi.C default namespace. */ + lua_pushliteral(L, LJ_OS_NAME); + lua_pushliteral(L, LJ_ARCH_NAME); + LJ_LIB_REG(L, NULL, ffi); /* Note: no global "ffi" created! */ + ffi_register_module(L); + return 1; +} + +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/lib_init.c b/fluent-bit/lib/luajit-3065c9/src/lib_init.c new file mode 100644 index 00000000..35e06fe2 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lib_init.c @@ -0,0 +1,55 @@ +/* +** Library initialization. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +** +** Major parts taken verbatim from the Lua interpreter. +** Copyright (C) 1994-2008 Lua.org, PUC-Rio. See Copyright Notice in lua.h +*/ + +#define lib_init_c +#define LUA_LIB + +#include "lua.h" +#include "lauxlib.h" +#include "lualib.h" + +#include "lj_arch.h" + +static const luaL_Reg lj_lib_load[] = { + { "", luaopen_base }, + { LUA_LOADLIBNAME, luaopen_package }, + { LUA_TABLIBNAME, luaopen_table }, + { LUA_IOLIBNAME, luaopen_io }, + { LUA_OSLIBNAME, luaopen_os }, + { LUA_STRLIBNAME, luaopen_string }, + { LUA_MATHLIBNAME, luaopen_math }, + { LUA_DBLIBNAME, luaopen_debug }, + { LUA_BITLIBNAME, luaopen_bit }, + { LUA_JITLIBNAME, luaopen_jit }, + { NULL, NULL } +}; + +static const luaL_Reg lj_lib_preload[] = { +#if LJ_HASFFI + { LUA_FFILIBNAME, luaopen_ffi }, +#endif + { NULL, NULL } +}; + +LUALIB_API void luaL_openlibs(lua_State *L) +{ + const luaL_Reg *lib; + for (lib = lj_lib_load; lib->func; lib++) { + lua_pushcfunction(L, lib->func); + lua_pushstring(L, lib->name); + lua_call(L, 1, 0); + } + luaL_findtable(L, LUA_REGISTRYINDEX, "_PRELOAD", + sizeof(lj_lib_preload)/sizeof(lj_lib_preload[0])-1); + for (lib = lj_lib_preload; lib->func; lib++) { + lua_pushcfunction(L, lib->func); + lua_setfield(L, -2, lib->name); + } + lua_pop(L, 1); +} + diff --git a/fluent-bit/lib/luajit-3065c9/src/lib_io.c b/fluent-bit/lib/luajit-3065c9/src/lib_io.c new file mode 100644 index 00000000..c22faa24 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lib_io.c @@ -0,0 +1,551 @@ +/* +** I/O library. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +** +** Major portions taken verbatim or adapted from the Lua interpreter. +** Copyright (C) 1994-2011 Lua.org, PUC-Rio. See Copyright Notice in lua.h +*/ + +#include +#include + +#define lib_io_c +#define LUA_LIB + +#include "lua.h" +#include "lauxlib.h" +#include "lualib.h" + +#include "lj_obj.h" +#include "lj_gc.h" +#include "lj_err.h" +#include "lj_buf.h" +#include "lj_str.h" +#include "lj_state.h" +#include "lj_strfmt.h" +#include "lj_ff.h" +#include "lj_lib.h" + +/* Userdata payload for I/O file. */ +typedef struct IOFileUD { + FILE *fp; /* File handle. */ + uint32_t type; /* File type. */ +} IOFileUD; + +#define IOFILE_TYPE_FILE 0 /* Regular file. */ +#define IOFILE_TYPE_PIPE 1 /* Pipe. */ +#define IOFILE_TYPE_STDF 2 /* Standard file handle. */ +#define IOFILE_TYPE_MASK 3 + +#define IOFILE_FLAG_CLOSE 4 /* Close after io.lines() iterator. */ + +#define IOSTDF_UD(L, id) (&gcref(G(L)->gcroot[(id)])->ud) +#define IOSTDF_IOF(L, id) ((IOFileUD *)uddata(IOSTDF_UD(L, (id)))) + +/* -- Open/close helpers -------------------------------------------------- */ + +static IOFileUD *io_tofilep(lua_State *L) +{ + if (!(L->base < L->top && tvisudata(L->base) && + udataV(L->base)->udtype == UDTYPE_IO_FILE)) + lj_err_argtype(L, 1, "FILE*"); + return (IOFileUD *)uddata(udataV(L->base)); +} + +static IOFileUD *io_tofile(lua_State *L) +{ + IOFileUD *iof = io_tofilep(L); + if (iof->fp == NULL) + lj_err_caller(L, LJ_ERR_IOCLFL); + return iof; +} + +static IOFileUD *io_stdfile(lua_State *L, ptrdiff_t id) +{ + IOFileUD *iof = IOSTDF_IOF(L, id); + if (iof->fp == NULL) + lj_err_caller(L, LJ_ERR_IOSTDCL); + return iof; +} + +static IOFileUD *io_file_new(lua_State *L) +{ + IOFileUD *iof = (IOFileUD *)lua_newuserdata(L, sizeof(IOFileUD)); + GCudata *ud = udataV(L->top-1); + ud->udtype = UDTYPE_IO_FILE; + /* NOBARRIER: The GCudata is new (marked white). */ + setgcrefr(ud->metatable, curr_func(L)->c.env); + iof->fp = NULL; + iof->type = IOFILE_TYPE_FILE; + return iof; +} + +static IOFileUD *io_file_open(lua_State *L, const char *mode) +{ + const char *fname = strdata(lj_lib_checkstr(L, 1)); + IOFileUD *iof = io_file_new(L); + iof->fp = fopen(fname, mode); + if (iof->fp == NULL) + luaL_argerror(L, 1, lj_strfmt_pushf(L, "%s: %s", fname, strerror(errno))); + return iof; +} + +static int io_file_close(lua_State *L, IOFileUD *iof) +{ + int ok; + if ((iof->type & IOFILE_TYPE_MASK) == IOFILE_TYPE_FILE) { + ok = (fclose(iof->fp) == 0); + } else if ((iof->type & IOFILE_TYPE_MASK) == IOFILE_TYPE_PIPE) { + int stat = -1; +#if LJ_TARGET_POSIX + stat = pclose(iof->fp); +#elif LJ_TARGET_WINDOWS && !LJ_TARGET_XBOXONE && !LJ_TARGET_UWP + stat = _pclose(iof->fp); +#endif +#if LJ_52 + iof->fp = NULL; + return luaL_execresult(L, stat); +#else + ok = (stat != -1); +#endif + } else { + lj_assertL((iof->type & IOFILE_TYPE_MASK) == IOFILE_TYPE_STDF, + "close of unknown FILE* type"); + setnilV(L->top++); + lua_pushliteral(L, "cannot close standard file"); + return 2; + } + iof->fp = NULL; + return luaL_fileresult(L, ok, NULL); +} + +/* -- Read/write helpers -------------------------------------------------- */ + +static int io_file_readnum(lua_State *L, FILE *fp) +{ + lua_Number d; + if (fscanf(fp, LUA_NUMBER_SCAN, &d) == 1) { + if (LJ_DUALNUM) { + int32_t i = lj_num2int(d); + if (d == (lua_Number)i && !tvismzero((cTValue *)&d)) { + setintV(L->top++, i); + return 1; + } + } + setnumV(L->top++, d); + return 1; + } else { + setnilV(L->top++); + return 0; + } +} + +static int io_file_readline(lua_State *L, FILE *fp, MSize chop) +{ + MSize m = LUAL_BUFFERSIZE, n = 0, ok = 0; + char *buf; + for (;;) { + buf = lj_buf_tmp(L, m); + if (fgets(buf+n, m-n, fp) == NULL) break; + n += (MSize)strlen(buf+n); + ok |= n; + if (n && buf[n-1] == '\n') { n -= chop; break; } + if (n >= m - 64) m += m; + } + setstrV(L, L->top++, lj_str_new(L, buf, (size_t)n)); + lj_gc_check(L); + return (int)ok; +} + +static void io_file_readall(lua_State *L, FILE *fp) +{ + MSize m, n; + for (m = LUAL_BUFFERSIZE, n = 0; ; m += m) { + char *buf = lj_buf_tmp(L, m); + n += (MSize)fread(buf+n, 1, m-n, fp); + if (n != m) { + setstrV(L, L->top++, lj_str_new(L, buf, (size_t)n)); + lj_gc_check(L); + return; + } + } +} + +static int io_file_readlen(lua_State *L, FILE *fp, MSize m) +{ + if (m) { + char *buf = lj_buf_tmp(L, m); + MSize n = (MSize)fread(buf, 1, m, fp); + setstrV(L, L->top++, lj_str_new(L, buf, (size_t)n)); + lj_gc_check(L); + return n > 0; + } else { + int c = getc(fp); + ungetc(c, fp); + setstrV(L, L->top++, &G(L)->strempty); + return (c != EOF); + } +} + +static int io_file_read(lua_State *L, IOFileUD *iof, int start) +{ + FILE *fp = iof->fp; + int ok, n, nargs = (int)(L->top - L->base) - start; + clearerr(fp); + if (nargs == 0) { + ok = io_file_readline(L, fp, 1); + n = start+1; /* Return 1 result. */ + } else { + /* The results plus the buffers go on top of the args. */ + luaL_checkstack(L, nargs+LUA_MINSTACK, "too many arguments"); + ok = 1; + for (n = start; nargs-- && ok; n++) { + if (tvisstr(L->base+n)) { + const char *p = strVdata(L->base+n); + if (p[0] == '*') p++; + if (p[0] == 'n') + ok = io_file_readnum(L, fp); + else if ((p[0] & ~0x20) == 'L') + ok = io_file_readline(L, fp, (p[0] == 'l')); + else if (p[0] == 'a') + io_file_readall(L, fp); + else + lj_err_arg(L, n+1, LJ_ERR_INVFMT); + } else if (tvisnumber(L->base+n)) { + ok = io_file_readlen(L, fp, (MSize)lj_lib_checkint(L, n+1)); + } else { + lj_err_arg(L, n+1, LJ_ERR_INVOPT); + } + } + } + if (ferror(fp)) + return luaL_fileresult(L, 0, NULL); + if (!ok) + setnilV(L->top-1); /* Replace last result with nil. */ + return n - start; +} + +static int io_file_write(lua_State *L, IOFileUD *iof, int start) +{ + FILE *fp = iof->fp; + cTValue *tv; + int status = 1; + for (tv = L->base+start; tv < L->top; tv++) { + MSize len; + const char *p = lj_strfmt_wstrnum(L, tv, &len); + if (!p) + lj_err_argt(L, (int)(tv - L->base) + 1, LUA_TSTRING); + status = status && (fwrite(p, 1, len, fp) == len); + } + if (LJ_52 && status) { + L->top = L->base+1; + if (start == 0) + setudataV(L, L->base, IOSTDF_UD(L, GCROOT_IO_OUTPUT)); + return 1; + } + return luaL_fileresult(L, status, NULL); +} + +static int io_file_iter(lua_State *L) +{ + GCfunc *fn = curr_func(L); + IOFileUD *iof = uddata(udataV(&fn->c.upvalue[0])); + int n = fn->c.nupvalues - 1; + if (iof->fp == NULL) + lj_err_caller(L, LJ_ERR_IOCLFL); + L->top = L->base; + if (n) { /* Copy upvalues with options to stack. */ + lj_state_checkstack(L, (MSize)n); + memcpy(L->top, &fn->c.upvalue[1], n*sizeof(TValue)); + L->top += n; + } + n = io_file_read(L, iof, 0); + if (ferror(iof->fp)) + lj_err_callermsg(L, strVdata(L->top-2)); + if (tvisnil(L->base) && (iof->type & IOFILE_FLAG_CLOSE)) { + io_file_close(L, iof); /* Return values are ignored. */ + return 0; + } + return n; +} + +static int io_file_lines(lua_State *L) +{ + int n = (int)(L->top - L->base); + if (n > LJ_MAX_UPVAL) + lj_err_caller(L, LJ_ERR_UNPACK); + lua_pushcclosure(L, io_file_iter, n); + return 1; +} + +/* -- I/O file methods ---------------------------------------------------- */ + +#define LJLIB_MODULE_io_method + +LJLIB_CF(io_method_close) +{ + IOFileUD *iof; + if (L->base < L->top) { + iof = io_tofile(L); + } else { + iof = IOSTDF_IOF(L, GCROOT_IO_OUTPUT); + if (iof->fp == NULL) + lj_err_caller(L, LJ_ERR_IOCLFL); + } + return io_file_close(L, iof); +} + +LJLIB_CF(io_method_read) +{ + return io_file_read(L, io_tofile(L), 1); +} + +LJLIB_CF(io_method_write) LJLIB_REC(io_write 0) +{ + return io_file_write(L, io_tofile(L), 1); +} + +LJLIB_CF(io_method_flush) LJLIB_REC(io_flush 0) +{ + return luaL_fileresult(L, fflush(io_tofile(L)->fp) == 0, NULL); +} + +#if LJ_32 && defined(__ANDROID__) && __ANDROID_API__ < 24 +/* The Android NDK is such an unmatched marvel of engineering. */ +extern int fseeko32(FILE *, long int, int) __asm__("fseeko"); +extern long int ftello32(FILE *) __asm__("ftello"); +#define fseeko(fp, pos, whence) (fseeko32((fp), (pos), (whence))) +#define ftello(fp) (ftello32((fp))) +#endif + +LJLIB_CF(io_method_seek) +{ + FILE *fp = io_tofile(L)->fp; + int opt = lj_lib_checkopt(L, 2, 1, "\3set\3cur\3end"); + int64_t ofs = 0; + cTValue *o; + int res; + if (opt == 0) opt = SEEK_SET; + else if (opt == 1) opt = SEEK_CUR; + else if (opt == 2) opt = SEEK_END; + o = L->base+2; + if (o < L->top) { + if (tvisint(o)) + ofs = (int64_t)intV(o); + else if (tvisnum(o)) + ofs = (int64_t)numV(o); + else if (!tvisnil(o)) + lj_err_argt(L, 3, LUA_TNUMBER); + } +#if LJ_TARGET_POSIX + res = fseeko(fp, ofs, opt); +#elif _MSC_VER >= 1400 + res = _fseeki64(fp, ofs, opt); +#elif defined(__MINGW32__) + res = fseeko64(fp, ofs, opt); +#else + res = fseek(fp, (long)ofs, opt); +#endif + if (res) + return luaL_fileresult(L, 0, NULL); +#if LJ_TARGET_POSIX + ofs = ftello(fp); +#elif _MSC_VER >= 1400 + ofs = _ftelli64(fp); +#elif defined(__MINGW32__) + ofs = ftello64(fp); +#else + ofs = (int64_t)ftell(fp); +#endif + setint64V(L->top-1, ofs); + return 1; +} + +LJLIB_CF(io_method_setvbuf) +{ + FILE *fp = io_tofile(L)->fp; + int opt = lj_lib_checkopt(L, 2, -1, "\4full\4line\2no"); + size_t sz = (size_t)lj_lib_optint(L, 3, LUAL_BUFFERSIZE); + if (opt == 0) opt = _IOFBF; + else if (opt == 1) opt = _IOLBF; + else if (opt == 2) opt = _IONBF; + return luaL_fileresult(L, setvbuf(fp, NULL, opt, sz) == 0, NULL); +} + +LJLIB_CF(io_method_lines) +{ + io_tofile(L); + return io_file_lines(L); +} + +LJLIB_CF(io_method___gc) +{ + IOFileUD *iof = io_tofilep(L); + if (iof->fp != NULL && (iof->type & IOFILE_TYPE_MASK) != IOFILE_TYPE_STDF) + io_file_close(L, iof); + return 0; +} + +LJLIB_CF(io_method___tostring) +{ + IOFileUD *iof = io_tofilep(L); + if (iof->fp != NULL) + lua_pushfstring(L, "file (%p)", iof->fp); + else + lua_pushliteral(L, "file (closed)"); + return 1; +} + +LJLIB_PUSH(top-1) LJLIB_SET(__index) + +#include "lj_libdef.h" + +/* -- I/O library functions ----------------------------------------------- */ + +#define LJLIB_MODULE_io + +LJLIB_PUSH(top-2) LJLIB_SET(!) /* Set environment. */ + +LJLIB_CF(io_open) +{ + const char *fname = strdata(lj_lib_checkstr(L, 1)); + GCstr *s = lj_lib_optstr(L, 2); + const char *mode = s ? strdata(s) : "r"; + IOFileUD *iof = io_file_new(L); + iof->fp = fopen(fname, mode); + return iof->fp != NULL ? 1 : luaL_fileresult(L, 0, fname); +} + +LJLIB_CF(io_popen) +{ +#if LJ_TARGET_POSIX || (LJ_TARGET_WINDOWS && !LJ_TARGET_XBOXONE && !LJ_TARGET_UWP) + const char *fname = strdata(lj_lib_checkstr(L, 1)); + GCstr *s = lj_lib_optstr(L, 2); + const char *mode = s ? strdata(s) : "r"; + IOFileUD *iof = io_file_new(L); + iof->type = IOFILE_TYPE_PIPE; +#if LJ_TARGET_POSIX + fflush(NULL); + iof->fp = popen(fname, mode); +#else + iof->fp = _popen(fname, mode); +#endif + return iof->fp != NULL ? 1 : luaL_fileresult(L, 0, fname); +#else + return luaL_error(L, LUA_QL("popen") " not supported"); +#endif +} + +LJLIB_CF(io_tmpfile) +{ + IOFileUD *iof = io_file_new(L); +#if LJ_TARGET_PS3 || LJ_TARGET_PS4 || LJ_TARGET_PS5 || LJ_TARGET_PSVITA || LJ_TARGET_NX + iof->fp = NULL; errno = ENOSYS; +#else + iof->fp = tmpfile(); +#endif + return iof->fp != NULL ? 1 : luaL_fileresult(L, 0, NULL); +} + +LJLIB_CF(io_close) +{ + return lj_cf_io_method_close(L); +} + +LJLIB_CF(io_read) +{ + return io_file_read(L, io_stdfile(L, GCROOT_IO_INPUT), 0); +} + +LJLIB_CF(io_write) LJLIB_REC(io_write GCROOT_IO_OUTPUT) +{ + return io_file_write(L, io_stdfile(L, GCROOT_IO_OUTPUT), 0); +} + +LJLIB_CF(io_flush) LJLIB_REC(io_flush GCROOT_IO_OUTPUT) +{ + return luaL_fileresult(L, fflush(io_stdfile(L, GCROOT_IO_OUTPUT)->fp) == 0, NULL); +} + +static int io_std_getset(lua_State *L, ptrdiff_t id, const char *mode) +{ + if (L->base < L->top && !tvisnil(L->base)) { + if (tvisudata(L->base)) { + io_tofile(L); + L->top = L->base+1; + } else { + io_file_open(L, mode); + } + /* NOBARRIER: The standard I/O handles are GC roots. */ + setgcref(G(L)->gcroot[id], gcV(L->top-1)); + } else { + setudataV(L, L->top++, IOSTDF_UD(L, id)); + } + return 1; +} + +LJLIB_CF(io_input) +{ + return io_std_getset(L, GCROOT_IO_INPUT, "r"); +} + +LJLIB_CF(io_output) +{ + return io_std_getset(L, GCROOT_IO_OUTPUT, "w"); +} + +LJLIB_CF(io_lines) +{ + if (L->base == L->top) setnilV(L->top++); + if (!tvisnil(L->base)) { /* io.lines(fname) */ + IOFileUD *iof = io_file_open(L, "r"); + iof->type = IOFILE_TYPE_FILE|IOFILE_FLAG_CLOSE; + L->top--; + setudataV(L, L->base, udataV(L->top)); + } else { /* io.lines() iterates over stdin. */ + setudataV(L, L->base, IOSTDF_UD(L, GCROOT_IO_INPUT)); + } + return io_file_lines(L); +} + +LJLIB_CF(io_type) +{ + cTValue *o = lj_lib_checkany(L, 1); + if (!(tvisudata(o) && udataV(o)->udtype == UDTYPE_IO_FILE)) + setnilV(L->top++); + else if (((IOFileUD *)uddata(udataV(o)))->fp != NULL) + lua_pushliteral(L, "file"); + else + lua_pushliteral(L, "closed file"); + return 1; +} + +#include "lj_libdef.h" + +/* ------------------------------------------------------------------------ */ + +static GCobj *io_std_new(lua_State *L, FILE *fp, const char *name) +{ + IOFileUD *iof = (IOFileUD *)lua_newuserdata(L, sizeof(IOFileUD)); + GCudata *ud = udataV(L->top-1); + ud->udtype = UDTYPE_IO_FILE; + /* NOBARRIER: The GCudata is new (marked white). */ + setgcref(ud->metatable, gcV(L->top-3)); + iof->fp = fp; + iof->type = IOFILE_TYPE_STDF; + lua_setfield(L, -2, name); + return obj2gco(ud); +} + +LUALIB_API int luaopen_io(lua_State *L) +{ + LJ_LIB_REG(L, NULL, io_method); + copyTV(L, L->top, L->top-1); L->top++; + lua_setfield(L, LUA_REGISTRYINDEX, LUA_FILEHANDLE); + LJ_LIB_REG(L, LUA_IOLIBNAME, io); + setgcref(G(L)->gcroot[GCROOT_IO_INPUT], io_std_new(L, stdin, "stdin")); + setgcref(G(L)->gcroot[GCROOT_IO_OUTPUT], io_std_new(L, stdout, "stdout")); + io_std_new(L, stderr, "stderr"); + return 1; +} + diff --git a/fluent-bit/lib/luajit-3065c9/src/lib_jit.c b/fluent-bit/lib/luajit-3065c9/src/lib_jit.c new file mode 100644 index 00000000..2867d420 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lib_jit.c @@ -0,0 +1,761 @@ +/* +** JIT library. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#define lib_jit_c +#define LUA_LIB + +#include "lua.h" +#include "lauxlib.h" +#include "lualib.h" + +#include "lj_obj.h" +#include "lj_gc.h" +#include "lj_err.h" +#include "lj_debug.h" +#include "lj_str.h" +#include "lj_tab.h" +#include "lj_state.h" +#include "lj_bc.h" +#if LJ_HASFFI +#include "lj_ctype.h" +#endif +#if LJ_HASJIT +#include "lj_ir.h" +#include "lj_jit.h" +#include "lj_ircall.h" +#include "lj_iropt.h" +#include "lj_target.h" +#endif +#include "lj_trace.h" +#include "lj_dispatch.h" +#include "lj_vm.h" +#include "lj_vmevent.h" +#include "lj_lib.h" + +#include "luajit.h" + +/* -- jit.* functions ----------------------------------------------------- */ + +#define LJLIB_MODULE_jit + +static int setjitmode(lua_State *L, int mode) +{ + int idx = 0; + if (L->base == L->top || tvisnil(L->base)) { /* jit.on/off/flush([nil]) */ + mode |= LUAJIT_MODE_ENGINE; + } else { + /* jit.on/off/flush(func|proto, nil|true|false) */ + if (tvisfunc(L->base) || tvisproto(L->base)) + idx = 1; + else if (!tvistrue(L->base)) /* jit.on/off/flush(true, nil|true|false) */ + goto err; + if (L->base+1 < L->top && tvisbool(L->base+1)) + mode |= boolV(L->base+1) ? LUAJIT_MODE_ALLFUNC : LUAJIT_MODE_ALLSUBFUNC; + else + mode |= LUAJIT_MODE_FUNC; + } + if (luaJIT_setmode(L, idx, mode) != 1) { + if ((mode & LUAJIT_MODE_MASK) == LUAJIT_MODE_ENGINE) + lj_err_caller(L, LJ_ERR_NOJIT); + err: + lj_err_argt(L, 1, LUA_TFUNCTION); + } + return 0; +} + +LJLIB_CF(jit_on) +{ + return setjitmode(L, LUAJIT_MODE_ON); +} + +LJLIB_CF(jit_off) +{ + return setjitmode(L, LUAJIT_MODE_OFF); +} + +LJLIB_CF(jit_flush) +{ +#if LJ_HASJIT + if (L->base < L->top && tvisnumber(L->base)) { + int traceno = lj_lib_checkint(L, 1); + luaJIT_setmode(L, traceno, LUAJIT_MODE_FLUSH|LUAJIT_MODE_TRACE); + return 0; + } +#endif + return setjitmode(L, LUAJIT_MODE_FLUSH); +} + +#if LJ_HASJIT +/* Push a string for every flag bit that is set. */ +static void flagbits_to_strings(lua_State *L, uint32_t flags, uint32_t base, + const char *str) +{ + for (; *str; base <<= 1, str += 1+*str) + if (flags & base) + setstrV(L, L->top++, lj_str_new(L, str+1, *(uint8_t *)str)); +} +#endif + +LJLIB_CF(jit_status) +{ +#if LJ_HASJIT + jit_State *J = L2J(L); + L->top = L->base; + setboolV(L->top++, (J->flags & JIT_F_ON) ? 1 : 0); + flagbits_to_strings(L, J->flags, JIT_F_CPU, JIT_F_CPUSTRING); + flagbits_to_strings(L, J->flags, JIT_F_OPT, JIT_F_OPTSTRING); + return (int)(L->top - L->base); +#else + setboolV(L->top++, 0); + return 1; +#endif +} + +LJLIB_CF(jit_security) +{ + int idx = lj_lib_checkopt(L, 1, -1, LJ_SECURITY_MODESTRING); + setintV(L->top++, ((LJ_SECURITY_MODE >> (2*idx)) & 3)); + return 1; +} + +LJLIB_CF(jit_attach) +{ +#ifdef LUAJIT_DISABLE_VMEVENT + luaL_error(L, "vmevent API disabled"); +#else + GCfunc *fn = lj_lib_checkfunc(L, 1); + GCstr *s = lj_lib_optstr(L, 2); + luaL_findtable(L, LUA_REGISTRYINDEX, LJ_VMEVENTS_REGKEY, LJ_VMEVENTS_HSIZE); + if (s) { /* Attach to given event. */ + const uint8_t *p = (const uint8_t *)strdata(s); + uint32_t h = s->len; + while (*p) h = h ^ (lj_rol(h, 6) + *p++); + lua_pushvalue(L, 1); + lua_rawseti(L, -2, VMEVENT_HASHIDX(h)); + G(L)->vmevmask = VMEVENT_NOCACHE; /* Invalidate cache. */ + } else { /* Detach if no event given. */ + setnilV(L->top++); + while (lua_next(L, -2)) { + L->top--; + if (tvisfunc(L->top) && funcV(L->top) == fn) { + setnilV(lj_tab_set(L, tabV(L->top-2), L->top-1)); + } + } + } +#endif + return 0; +} + +LJLIB_PUSH(top-5) LJLIB_SET(os) +LJLIB_PUSH(top-4) LJLIB_SET(arch) +LJLIB_PUSH(top-3) LJLIB_SET(version_num) +LJLIB_PUSH(top-2) LJLIB_SET(version) + +#include "lj_libdef.h" + +/* -- jit.util.* functions ------------------------------------------------ */ + +#define LJLIB_MODULE_jit_util + +/* -- Reflection API for Lua functions ------------------------------------ */ + +/* Return prototype of first argument (Lua function or prototype object) */ +static GCproto *check_Lproto(lua_State *L, int nolua) +{ + TValue *o = L->base; + if (L->top > o) { + if (tvisproto(o)) { + return protoV(o); + } else if (tvisfunc(o)) { + if (isluafunc(funcV(o))) + return funcproto(funcV(o)); + else if (nolua) + return NULL; + } + } + lj_err_argt(L, 1, LUA_TFUNCTION); + return NULL; /* unreachable */ +} + +static void setintfield(lua_State *L, GCtab *t, const char *name, int32_t val) +{ + setintV(lj_tab_setstr(L, t, lj_str_newz(L, name)), val); +} + +/* local info = jit.util.funcinfo(func [,pc]) */ +LJLIB_CF(jit_util_funcinfo) +{ + GCproto *pt = check_Lproto(L, 1); + if (pt) { + BCPos pc = (BCPos)lj_lib_optint(L, 2, 0); + GCtab *t; + lua_createtable(L, 0, 16); /* Increment hash size if fields are added. */ + t = tabV(L->top-1); + setintfield(L, t, "linedefined", pt->firstline); + setintfield(L, t, "lastlinedefined", pt->firstline + pt->numline); + setintfield(L, t, "stackslots", pt->framesize); + setintfield(L, t, "params", pt->numparams); + setintfield(L, t, "bytecodes", (int32_t)pt->sizebc); + setintfield(L, t, "gcconsts", (int32_t)pt->sizekgc); + setintfield(L, t, "nconsts", (int32_t)pt->sizekn); + setintfield(L, t, "upvalues", (int32_t)pt->sizeuv); + if (pc < pt->sizebc) + setintfield(L, t, "currentline", lj_debug_line(pt, pc)); + lua_pushboolean(L, (pt->flags & PROTO_VARARG)); + lua_setfield(L, -2, "isvararg"); + lua_pushboolean(L, (pt->flags & PROTO_CHILD)); + lua_setfield(L, -2, "children"); + setstrV(L, L->top++, proto_chunkname(pt)); + lua_setfield(L, -2, "source"); + lj_debug_pushloc(L, pt, pc); + lua_setfield(L, -2, "loc"); + setprotoV(L, lj_tab_setstr(L, t, lj_str_newlit(L, "proto")), pt); + } else { + GCfunc *fn = funcV(L->base); + GCtab *t; + lua_createtable(L, 0, 4); /* Increment hash size if fields are added. */ + t = tabV(L->top-1); + if (!iscfunc(fn)) + setintfield(L, t, "ffid", fn->c.ffid); + setintptrV(lj_tab_setstr(L, t, lj_str_newlit(L, "addr")), + (intptr_t)(void *)fn->c.f); + setintfield(L, t, "upvalues", fn->c.nupvalues); + } + return 1; +} + +/* local ins, m = jit.util.funcbc(func, pc) */ +LJLIB_CF(jit_util_funcbc) +{ + GCproto *pt = check_Lproto(L, 0); + BCPos pc = (BCPos)lj_lib_checkint(L, 2); + if (pc < pt->sizebc) { + BCIns ins = proto_bc(pt)[pc]; + BCOp op = bc_op(ins); + lj_assertL(op < BC__MAX, "bad bytecode op %d", op); + setintV(L->top, ins); + setintV(L->top+1, lj_bc_mode[op]); + L->top += 2; + return 2; + } + return 0; +} + +/* local k = jit.util.funck(func, idx) */ +LJLIB_CF(jit_util_funck) +{ + GCproto *pt = check_Lproto(L, 0); + ptrdiff_t idx = (ptrdiff_t)lj_lib_checkint(L, 2); + if (idx >= 0) { + if (idx < (ptrdiff_t)pt->sizekn) { + copyTV(L, L->top-1, proto_knumtv(pt, idx)); + return 1; + } + } else { + if (~idx < (ptrdiff_t)pt->sizekgc) { + GCobj *gc = proto_kgc(pt, idx); + setgcV(L, L->top-1, gc, ~gc->gch.gct); + return 1; + } + } + return 0; +} + +/* local name = jit.util.funcuvname(func, idx) */ +LJLIB_CF(jit_util_funcuvname) +{ + GCproto *pt = check_Lproto(L, 0); + uint32_t idx = (uint32_t)lj_lib_checkint(L, 2); + if (idx < pt->sizeuv) { + setstrV(L, L->top-1, lj_str_newz(L, lj_debug_uvname(pt, idx))); + return 1; + } + return 0; +} + +/* -- Reflection API for traces ------------------------------------------- */ + +#if LJ_HASJIT + +/* Check trace argument. Must not throw for non-existent trace numbers. */ +static GCtrace *jit_checktrace(lua_State *L) +{ + TraceNo tr = (TraceNo)lj_lib_checkint(L, 1); + jit_State *J = L2J(L); + if (tr > 0 && tr < J->sizetrace) + return traceref(J, tr); + return NULL; +} + +/* Names of link types. ORDER LJ_TRLINK */ +static const char *const jit_trlinkname[] = { + "none", "root", "loop", "tail-recursion", "up-recursion", "down-recursion", + "interpreter", "return", "stitch" +}; + +/* local info = jit.util.traceinfo(tr) */ +LJLIB_CF(jit_util_traceinfo) +{ + GCtrace *T = jit_checktrace(L); + if (T) { + GCtab *t; + lua_createtable(L, 0, 8); /* Increment hash size if fields are added. */ + t = tabV(L->top-1); + setintfield(L, t, "nins", (int32_t)T->nins - REF_BIAS - 1); + setintfield(L, t, "nk", REF_BIAS - (int32_t)T->nk); + setintfield(L, t, "link", T->link); + setintfield(L, t, "nexit", T->nsnap); + setstrV(L, L->top++, lj_str_newz(L, jit_trlinkname[T->linktype])); + lua_setfield(L, -2, "linktype"); + /* There are many more fields. Add them only when needed. */ + return 1; + } + return 0; +} + +/* local m, ot, op1, op2, prev = jit.util.traceir(tr, idx) */ +LJLIB_CF(jit_util_traceir) +{ + GCtrace *T = jit_checktrace(L); + IRRef ref = (IRRef)lj_lib_checkint(L, 2) + REF_BIAS; + if (T && ref >= REF_BIAS && ref < T->nins) { + IRIns *ir = &T->ir[ref]; + int32_t m = lj_ir_mode[ir->o]; + setintV(L->top-2, m); + setintV(L->top-1, ir->ot); + setintV(L->top++, (int32_t)ir->op1 - (irm_op1(m)==IRMref ? REF_BIAS : 0)); + setintV(L->top++, (int32_t)ir->op2 - (irm_op2(m)==IRMref ? REF_BIAS : 0)); + setintV(L->top++, ir->prev); + return 5; + } + return 0; +} + +/* local k, t [, slot] = jit.util.tracek(tr, idx) */ +LJLIB_CF(jit_util_tracek) +{ + GCtrace *T = jit_checktrace(L); + IRRef ref = (IRRef)lj_lib_checkint(L, 2) + REF_BIAS; + if (T && ref >= T->nk && ref < REF_BIAS) { + IRIns *ir = &T->ir[ref]; + int32_t slot = -1; + if (ir->o == IR_KSLOT) { + slot = ir->op2; + ir = &T->ir[ir->op1]; + } +#if LJ_HASFFI + if (ir->o == IR_KINT64) ctype_loadffi(L); +#endif + lj_ir_kvalue(L, L->top-2, ir); + setintV(L->top-1, (int32_t)irt_type(ir->t)); + if (slot == -1) + return 2; + setintV(L->top++, slot); + return 3; + } + return 0; +} + +/* local snap = jit.util.tracesnap(tr, sn) */ +LJLIB_CF(jit_util_tracesnap) +{ + GCtrace *T = jit_checktrace(L); + SnapNo sn = (SnapNo)lj_lib_checkint(L, 2); + if (T && sn < T->nsnap) { + SnapShot *snap = &T->snap[sn]; + SnapEntry *map = &T->snapmap[snap->mapofs]; + MSize n, nent = snap->nent; + GCtab *t; + lua_createtable(L, nent+2, 0); + t = tabV(L->top-1); + setintV(lj_tab_setint(L, t, 0), (int32_t)snap->ref - REF_BIAS); + setintV(lj_tab_setint(L, t, 1), (int32_t)snap->nslots); + for (n = 0; n < nent; n++) + setintV(lj_tab_setint(L, t, (int32_t)(n+2)), (int32_t)map[n]); + setintV(lj_tab_setint(L, t, (int32_t)(nent+2)), (int32_t)SNAP(255, 0, 0)); + return 1; + } + return 0; +} + +/* local mcode, addr, loop = jit.util.tracemc(tr) */ +LJLIB_CF(jit_util_tracemc) +{ + GCtrace *T = jit_checktrace(L); + if (T && T->mcode != NULL) { + setstrV(L, L->top-1, lj_str_new(L, (const char *)T->mcode, T->szmcode)); + setintptrV(L->top++, (intptr_t)(void *)T->mcode); + setintV(L->top++, T->mcloop); + return 3; + } + return 0; +} + +/* local addr = jit.util.traceexitstub([tr,] exitno) */ +LJLIB_CF(jit_util_traceexitstub) +{ +#ifdef EXITSTUBS_PER_GROUP + ExitNo exitno = (ExitNo)lj_lib_checkint(L, 1); + jit_State *J = L2J(L); + if (exitno < EXITSTUBS_PER_GROUP*LJ_MAX_EXITSTUBGR) { + setintptrV(L->top-1, (intptr_t)(void *)exitstub_addr(J, exitno)); + return 1; + } +#else + if (L->top > L->base+1) { /* Don't throw for one-argument variant. */ + GCtrace *T = jit_checktrace(L); + ExitNo exitno = (ExitNo)lj_lib_checkint(L, 2); + ExitNo maxexit = T->root ? T->nsnap+1 : T->nsnap; + if (T && T->mcode != NULL && exitno < maxexit) { + setintptrV(L->top-1, (intptr_t)(void *)exitstub_trace_addr(T, exitno)); + return 1; + } + } +#endif + return 0; +} + +/* local addr = jit.util.ircalladdr(idx) */ +LJLIB_CF(jit_util_ircalladdr) +{ + uint32_t idx = (uint32_t)lj_lib_checkint(L, 1); + if (idx < IRCALL__MAX) { + setintptrV(L->top-1, (intptr_t)(void *)lj_ir_callinfo[idx].func); + return 1; + } + return 0; +} + +#endif + +#include "lj_libdef.h" + +static int luaopen_jit_util(lua_State *L) +{ + LJ_LIB_REG(L, NULL, jit_util); + return 1; +} + +/* -- jit.opt module ------------------------------------------------------ */ + +#if LJ_HASJIT + +#define LJLIB_MODULE_jit_opt + +/* Parse optimization level. */ +static int jitopt_level(jit_State *J, const char *str) +{ + if (str[0] >= '0' && str[0] <= '9' && str[1] == '\0') { + uint32_t flags; + if (str[0] == '0') flags = JIT_F_OPT_0; + else if (str[0] == '1') flags = JIT_F_OPT_1; + else if (str[0] == '2') flags = JIT_F_OPT_2; + else flags = JIT_F_OPT_3; + J->flags = (J->flags & ~JIT_F_OPT_MASK) | flags; + return 1; /* Ok. */ + } + return 0; /* No match. */ +} + +/* Parse optimization flag. */ +static int jitopt_flag(jit_State *J, const char *str) +{ + const char *lst = JIT_F_OPTSTRING; + uint32_t opt; + int set = 1; + if (str[0] == '+') { + str++; + } else if (str[0] == '-') { + str++; + set = 0; + } else if (str[0] == 'n' && str[1] == 'o') { + str += str[2] == '-' ? 3 : 2; + set = 0; + } + for (opt = JIT_F_OPT; ; opt <<= 1) { + size_t len = *(const uint8_t *)lst; + if (len == 0) + break; + if (strncmp(str, lst+1, len) == 0 && str[len] == '\0') { + if (set) J->flags |= opt; else J->flags &= ~opt; + return 1; /* Ok. */ + } + lst += 1+len; + } + return 0; /* No match. */ +} + +/* Parse optimization parameter. */ +static int jitopt_param(jit_State *J, const char *str) +{ + const char *lst = JIT_P_STRING; + int i; + for (i = 0; i < JIT_P__MAX; i++) { + size_t len = *(const uint8_t *)lst; + lj_assertJ(len != 0, "bad JIT_P_STRING"); + if (strncmp(str, lst+1, len) == 0 && str[len] == '=') { + int32_t n = 0; + const char *p = &str[len+1]; + while (*p >= '0' && *p <= '9') + n = n*10 + (*p++ - '0'); + if (*p) return 0; /* Malformed number. */ + J->param[i] = n; + if (i == JIT_P_hotloop) + lj_dispatch_init_hotcount(J2G(J)); + return 1; /* Ok. */ + } + lst += 1+len; + } + return 0; /* No match. */ +} + +/* jit.opt.start(flags...) */ +LJLIB_CF(jit_opt_start) +{ + jit_State *J = L2J(L); + int nargs = (int)(L->top - L->base); + if (nargs == 0) { + J->flags = (J->flags & ~JIT_F_OPT_MASK) | JIT_F_OPT_DEFAULT; + } else { + int i; + for (i = 1; i <= nargs; i++) { + const char *str = strdata(lj_lib_checkstr(L, i)); + if (!jitopt_level(J, str) && + !jitopt_flag(J, str) && + !jitopt_param(J, str)) + lj_err_callerv(L, LJ_ERR_JITOPT, str); + } + } + return 0; +} + +#include "lj_libdef.h" + +#endif + +/* -- jit.profile module -------------------------------------------------- */ + +#if LJ_HASPROFILE + +#define LJLIB_MODULE_jit_profile + +/* Not loaded by default, use: local profile = require("jit.profile") */ + +#define KEY_PROFILE_THREAD (U64x(80000000,00000000)|'t') +#define KEY_PROFILE_FUNC (U64x(80000000,00000000)|'f') + +static void jit_profile_callback(lua_State *L2, lua_State *L, int samples, + int vmstate) +{ + TValue key; + cTValue *tv; + key.u64 = KEY_PROFILE_FUNC; + tv = lj_tab_get(L, tabV(registry(L)), &key); + if (tvisfunc(tv)) { + char vmst = (char)vmstate; + int status; + setfuncV(L2, L2->top++, funcV(tv)); + setthreadV(L2, L2->top++, L); + setintV(L2->top++, samples); + setstrV(L2, L2->top++, lj_str_new(L2, &vmst, 1)); + status = lua_pcall(L2, 3, 0, 0); /* callback(thread, samples, vmstate) */ + if (status) { + if (G(L2)->panic) G(L2)->panic(L2); + exit(EXIT_FAILURE); + } + lj_trace_abort(G(L2)); + } +} + +/* profile.start(mode, cb) */ +LJLIB_CF(jit_profile_start) +{ + GCtab *registry = tabV(registry(L)); + GCstr *mode = lj_lib_optstr(L, 1); + GCfunc *func = lj_lib_checkfunc(L, 2); + lua_State *L2 = lua_newthread(L); /* Thread that runs profiler callback. */ + TValue key; + /* Anchor thread and function in registry. */ + key.u64 = KEY_PROFILE_THREAD; + setthreadV(L, lj_tab_set(L, registry, &key), L2); + key.u64 = KEY_PROFILE_FUNC; + setfuncV(L, lj_tab_set(L, registry, &key), func); + lj_gc_anybarriert(L, registry); + luaJIT_profile_start(L, mode ? strdata(mode) : "", + (luaJIT_profile_callback)jit_profile_callback, L2); + return 0; +} + +/* profile.stop() */ +LJLIB_CF(jit_profile_stop) +{ + GCtab *registry; + TValue key; + luaJIT_profile_stop(L); + registry = tabV(registry(L)); + key.u64 = KEY_PROFILE_THREAD; + setnilV(lj_tab_set(L, registry, &key)); + key.u64 = KEY_PROFILE_FUNC; + setnilV(lj_tab_set(L, registry, &key)); + lj_gc_anybarriert(L, registry); + return 0; +} + +/* dump = profile.dumpstack([thread,] fmt, depth) */ +LJLIB_CF(jit_profile_dumpstack) +{ + lua_State *L2 = L; + int arg = 0; + size_t len; + int depth; + GCstr *fmt; + const char *p; + if (L->top > L->base && tvisthread(L->base)) { + L2 = threadV(L->base); + arg = 1; + } + fmt = lj_lib_checkstr(L, arg+1); + depth = lj_lib_checkint(L, arg+2); + p = luaJIT_profile_dumpstack(L2, strdata(fmt), depth, &len); + lua_pushlstring(L, p, len); + return 1; +} + +#include "lj_libdef.h" + +static int luaopen_jit_profile(lua_State *L) +{ + LJ_LIB_REG(L, NULL, jit_profile); + return 1; +} + +#endif + +/* -- JIT compiler initialization ----------------------------------------- */ + +#if LJ_HASJIT +/* Default values for JIT parameters. */ +static const int32_t jit_param_default[JIT_P__MAX+1] = { +#define JIT_PARAMINIT(len, name, value) (value), +JIT_PARAMDEF(JIT_PARAMINIT) +#undef JIT_PARAMINIT + 0 +}; + +#if LJ_TARGET_ARM && LJ_TARGET_LINUX +#include +#endif + +/* Arch-dependent CPU feature detection. */ +static uint32_t jit_cpudetect(void) +{ + uint32_t flags = 0; +#if LJ_TARGET_X86ORX64 + + uint32_t vendor[4]; + uint32_t features[4]; + if (lj_vm_cpuid(0, vendor) && lj_vm_cpuid(1, features)) { + flags |= ((features[2] >> 0)&1) * JIT_F_SSE3; + flags |= ((features[2] >> 19)&1) * JIT_F_SSE4_1; + if (vendor[0] >= 7) { + uint32_t xfeatures[4]; + lj_vm_cpuid(7, xfeatures); + flags |= ((xfeatures[1] >> 8)&1) * JIT_F_BMI2; + } + } + /* Don't bother checking for SSE2 -- the VM will crash before getting here. */ + +#elif LJ_TARGET_ARM + + int ver = LJ_ARCH_VERSION; /* Compile-time ARM CPU detection. */ +#if LJ_TARGET_LINUX + if (ver < 70) { /* Runtime ARM CPU detection. */ + struct utsname ut; + uname(&ut); + if (strncmp(ut.machine, "armv", 4) == 0) { + if (ut.machine[4] >= '8') ver = 80; + else if (ut.machine[4] == '7') ver = 70; + else if (ut.machine[4] == '6') ver = 60; + } + } +#endif + flags |= ver >= 70 ? JIT_F_ARMV7 : + ver >= 61 ? JIT_F_ARMV6T2_ : + ver >= 60 ? JIT_F_ARMV6_ : 0; + flags |= LJ_ARCH_HASFPU == 0 ? 0 : ver >= 70 ? JIT_F_VFPV3 : JIT_F_VFPV2; + +#elif LJ_TARGET_ARM64 + + /* No optional CPU features to detect (for now). */ + +#elif LJ_TARGET_PPC + +#if LJ_ARCH_SQRT + flags |= JIT_F_SQRT; +#endif +#if LJ_ARCH_ROUND + flags |= JIT_F_ROUND; +#endif + +#elif LJ_TARGET_MIPS + + /* Compile-time MIPS CPU detection. */ +#if LJ_ARCH_VERSION >= 20 + flags |= JIT_F_MIPSXXR2; +#endif + /* Runtime MIPS CPU detection. */ +#if defined(__GNUC__) + if (!(flags & JIT_F_MIPSXXR2)) { + int x; +#ifdef __mips16 + x = 0; /* Runtime detection is difficult. Ensure optimal -march flags. */ +#else + /* On MIPS32R1 rotr is treated as srl. rotr r2,r2,1 -> srl r2,r2,1. */ + __asm__("li $2, 1\n\t.long 0x00221042\n\tmove %0, $2" : "=r"(x) : : "$2"); +#endif + if (x) flags |= JIT_F_MIPSXXR2; /* Either 0x80000000 (R2) or 0 (R1). */ + } +#endif + +#else +#error "Missing CPU detection for this architecture" +#endif + return flags; +} + +/* Initialize JIT compiler. */ +static void jit_init(lua_State *L) +{ + jit_State *J = L2J(L); + J->flags = jit_cpudetect() | JIT_F_ON | JIT_F_OPT_DEFAULT; + memcpy(J->param, jit_param_default, sizeof(J->param)); + lj_dispatch_update(G(L)); +} +#endif + +LUALIB_API int luaopen_jit(lua_State *L) +{ +#if LJ_HASJIT + jit_init(L); +#endif + lua_pushliteral(L, LJ_OS_NAME); + lua_pushliteral(L, LJ_ARCH_NAME); + lua_pushinteger(L, LUAJIT_VERSION_NUM); + lua_pushliteral(L, LUAJIT_VERSION); + LJ_LIB_REG(L, LUA_JITLIBNAME, jit); +#if LJ_HASPROFILE + lj_lib_prereg(L, LUA_JITLIBNAME ".profile", luaopen_jit_profile, + tabref(L->env)); +#endif +#ifndef LUAJIT_DISABLE_JITUTIL + lj_lib_prereg(L, LUA_JITLIBNAME ".util", luaopen_jit_util, tabref(L->env)); +#endif +#if LJ_HASJIT + LJ_LIB_REG(L, "jit.opt", jit_opt); +#endif + L->top -= 2; + return 1; +} + diff --git a/fluent-bit/lib/luajit-3065c9/src/lib_math.c b/fluent-bit/lib/luajit-3065c9/src/lib_math.c new file mode 100644 index 00000000..b677bbcd --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lib_math.c @@ -0,0 +1,201 @@ +/* +** Math library. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#include + +#define lib_math_c +#define LUA_LIB + +#include "lua.h" +#include "lauxlib.h" +#include "lualib.h" + +#include "lj_obj.h" +#include "lj_lib.h" +#include "lj_vm.h" +#include "lj_prng.h" + +/* ------------------------------------------------------------------------ */ + +#define LJLIB_MODULE_math + +LJLIB_ASM(math_abs) LJLIB_REC(.) +{ + lj_lib_checknumber(L, 1); + return FFH_RETRY; +} +LJLIB_ASM_(math_floor) LJLIB_REC(math_round IRFPM_FLOOR) +LJLIB_ASM_(math_ceil) LJLIB_REC(math_round IRFPM_CEIL) + +LJLIB_ASM(math_sqrt) LJLIB_REC(math_unary IRFPM_SQRT) +{ + lj_lib_checknum(L, 1); + return FFH_RETRY; +} +LJLIB_ASM_(math_log10) LJLIB_REC(math_call IRCALL_log10) +LJLIB_ASM_(math_exp) LJLIB_REC(math_call IRCALL_exp) +LJLIB_ASM_(math_sin) LJLIB_REC(math_call IRCALL_sin) +LJLIB_ASM_(math_cos) LJLIB_REC(math_call IRCALL_cos) +LJLIB_ASM_(math_tan) LJLIB_REC(math_call IRCALL_tan) +LJLIB_ASM_(math_asin) LJLIB_REC(math_call IRCALL_asin) +LJLIB_ASM_(math_acos) LJLIB_REC(math_call IRCALL_acos) +LJLIB_ASM_(math_atan) LJLIB_REC(math_call IRCALL_atan) +LJLIB_ASM_(math_sinh) LJLIB_REC(math_call IRCALL_sinh) +LJLIB_ASM_(math_cosh) LJLIB_REC(math_call IRCALL_cosh) +LJLIB_ASM_(math_tanh) LJLIB_REC(math_call IRCALL_tanh) +LJLIB_ASM_(math_frexp) +LJLIB_ASM_(math_modf) + +LJLIB_ASM(math_log) LJLIB_REC(math_log) +{ + double x = lj_lib_checknum(L, 1); + if (L->base+1 < L->top) { + double y = lj_lib_checknum(L, 2); +#ifdef LUAJIT_NO_LOG2 + x = log(x); y = 1.0 / log(y); +#else + x = lj_vm_log2(x); y = 1.0 / lj_vm_log2(y); +#endif + setnumV(L->base-1-LJ_FR2, x*y); /* Do NOT join the expression to x / y. */ + return FFH_RES(1); + } + return FFH_RETRY; +} + +LJLIB_LUA(math_deg) /* function(x) return x * 57.29577951308232 end */ +LJLIB_LUA(math_rad) /* function(x) return x * 0.017453292519943295 end */ + +LJLIB_ASM(math_atan2) LJLIB_REC(.) +{ + lj_lib_checknum(L, 1); + lj_lib_checknum(L, 2); + return FFH_RETRY; +} +LJLIB_ASM_(math_pow) LJLIB_REC(.) +LJLIB_ASM_(math_fmod) + +LJLIB_ASM(math_ldexp) LJLIB_REC(.) +{ + lj_lib_checknum(L, 1); +#if LJ_DUALNUM && !LJ_TARGET_X86ORX64 + lj_lib_checkint(L, 2); +#else + lj_lib_checknum(L, 2); +#endif + return FFH_RETRY; +} + +LJLIB_ASM(math_min) LJLIB_REC(math_minmax IR_MIN) +{ + int i = 0; + do { lj_lib_checknumber(L, ++i); } while (L->base+i < L->top); + return FFH_RETRY; +} +LJLIB_ASM_(math_max) LJLIB_REC(math_minmax IR_MAX) + +LJLIB_PUSH(3.14159265358979323846) LJLIB_SET(pi) +LJLIB_PUSH(1e310) LJLIB_SET(huge) + +/* ------------------------------------------------------------------------ */ + +/* This implements a Tausworthe PRNG with period 2^223. Based on: +** Tables of maximally-equidistributed combined LFSR generators, +** Pierre L'Ecuyer, 1991, table 3, 1st entry. +** Full-period ME-CF generator with L=64, J=4, k=223, N1=49. +*/ + +/* Union needed for bit-pattern conversion between uint64_t and double. */ +typedef union { uint64_t u64; double d; } U64double; + +/* PRNG seeding function. */ +static void random_seed(PRNGState *rs, double d) +{ + uint32_t r = 0x11090601; /* 64-k[i] as four 8 bit constants. */ + int i; + for (i = 0; i < 4; i++) { + U64double u; + uint32_t m = 1u << (r&255); + r >>= 8; + u.d = d = d * 3.14159265358979323846 + 2.7182818284590452354; + if (u.u64 < m) u.u64 += m; /* Ensure k[i] MSB of u[i] are non-zero. */ + rs->u[i] = u.u64; + } + for (i = 0; i < 10; i++) + (void)lj_prng_u64(rs); +} + +/* PRNG extract function. */ +LJLIB_PUSH(top-2) /* Upvalue holds userdata with PRNGState. */ +LJLIB_CF(math_random) LJLIB_REC(.) +{ + int n = (int)(L->top - L->base); + PRNGState *rs = (PRNGState *)(uddata(udataV(lj_lib_upvalue(L, 1)))); + U64double u; + double d; + u.u64 = lj_prng_u64d(rs); + d = u.d - 1.0; + if (n > 0) { +#if LJ_DUALNUM + int isint = 1; + double r1; + lj_lib_checknumber(L, 1); + if (tvisint(L->base)) { + r1 = (lua_Number)intV(L->base); + } else { + isint = 0; + r1 = numV(L->base); + } +#else + double r1 = lj_lib_checknum(L, 1); +#endif + if (n == 1) { + d = lj_vm_floor(d*r1) + 1.0; /* d is an int in range [1, r1] */ + } else { +#if LJ_DUALNUM + double r2; + lj_lib_checknumber(L, 2); + if (tvisint(L->base+1)) { + r2 = (lua_Number)intV(L->base+1); + } else { + isint = 0; + r2 = numV(L->base+1); + } +#else + double r2 = lj_lib_checknum(L, 2); +#endif + d = lj_vm_floor(d*(r2-r1+1.0)) + r1; /* d is an int in range [r1, r2] */ + } +#if LJ_DUALNUM + if (isint) { + setintV(L->top-1, lj_num2int(d)); + return 1; + } +#endif + } /* else: d is a double in range [0, 1] */ + setnumV(L->top++, d); + return 1; +} + +/* PRNG seed function. */ +LJLIB_PUSH(top-2) /* Upvalue holds userdata with PRNGState. */ +LJLIB_CF(math_randomseed) +{ + PRNGState *rs = (PRNGState *)(uddata(udataV(lj_lib_upvalue(L, 1)))); + random_seed(rs, lj_lib_checknum(L, 1)); + return 0; +} + +/* ------------------------------------------------------------------------ */ + +#include "lj_libdef.h" + +LUALIB_API int luaopen_math(lua_State *L) +{ + PRNGState *rs = (PRNGState *)lua_newuserdata(L, sizeof(PRNGState)); + lj_prng_seed_fixed(rs); + LJ_LIB_REG(L, LUA_MATHLIBNAME, math); + return 1; +} + diff --git a/fluent-bit/lib/luajit-3065c9/src/lib_os.c b/fluent-bit/lib/luajit-3065c9/src/lib_os.c new file mode 100644 index 00000000..6bcd0147 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lib_os.c @@ -0,0 +1,292 @@ +/* +** OS library. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +** +** Major portions taken verbatim or adapted from the Lua interpreter. +** Copyright (C) 1994-2008 Lua.org, PUC-Rio. See Copyright Notice in lua.h +*/ + +#include +#include + +#define lib_os_c +#define LUA_LIB + +#include "lua.h" +#include "lauxlib.h" +#include "lualib.h" + +#include "lj_obj.h" +#include "lj_gc.h" +#include "lj_err.h" +#include "lj_buf.h" +#include "lj_str.h" +#include "lj_lib.h" + +#if LJ_TARGET_POSIX +#include +#else +#include +#endif + +#if !LJ_TARGET_PSVITA +#include +#endif + +/* ------------------------------------------------------------------------ */ + +#define LJLIB_MODULE_os + +LJLIB_CF(os_execute) +{ +#if LJ_NO_SYSTEM +#if LJ_52 + errno = ENOSYS; + return luaL_fileresult(L, 0, NULL); +#else + lua_pushinteger(L, -1); + return 1; +#endif +#else + const char *cmd = luaL_optstring(L, 1, NULL); + int stat = system(cmd); +#if LJ_52 + if (cmd) + return luaL_execresult(L, stat); + setboolV(L->top++, 1); +#else + setintV(L->top++, stat); +#endif + return 1; +#endif +} + +LJLIB_CF(os_remove) +{ + const char *filename = luaL_checkstring(L, 1); + return luaL_fileresult(L, remove(filename) == 0, filename); +} + +LJLIB_CF(os_rename) +{ + const char *fromname = luaL_checkstring(L, 1); + const char *toname = luaL_checkstring(L, 2); + return luaL_fileresult(L, rename(fromname, toname) == 0, fromname); +} + +LJLIB_CF(os_tmpname) +{ +#if LJ_TARGET_PS3 || LJ_TARGET_PS4 || LJ_TARGET_PS5 || LJ_TARGET_PSVITA || LJ_TARGET_NX + lj_err_caller(L, LJ_ERR_OSUNIQF); + return 0; +#else +#if LJ_TARGET_POSIX + char buf[15+1]; + int fp; + strcpy(buf, "/tmp/lua_XXXXXX"); + fp = mkstemp(buf); + if (fp != -1) + close(fp); + else + lj_err_caller(L, LJ_ERR_OSUNIQF); +#else + char buf[L_tmpnam]; + if (tmpnam(buf) == NULL) + lj_err_caller(L, LJ_ERR_OSUNIQF); +#endif + lua_pushstring(L, buf); + return 1; +#endif +} + +LJLIB_CF(os_getenv) +{ +#if LJ_TARGET_CONSOLE + lua_pushnil(L); +#else + lua_pushstring(L, getenv(luaL_checkstring(L, 1))); /* if NULL push nil */ +#endif + return 1; +} + +LJLIB_CF(os_exit) +{ + int status; + if (L->base < L->top && tvisbool(L->base)) + status = boolV(L->base) ? EXIT_SUCCESS : EXIT_FAILURE; + else + status = lj_lib_optint(L, 1, EXIT_SUCCESS); + if (L->base+1 < L->top && tvistruecond(L->base+1)) + lua_close(L); + exit(status); + return 0; /* Unreachable. */ +} + +LJLIB_CF(os_clock) +{ + setnumV(L->top++, ((lua_Number)clock())*(1.0/(lua_Number)CLOCKS_PER_SEC)); + return 1; +} + +/* ------------------------------------------------------------------------ */ + +static void setfield(lua_State *L, const char *key, int value) +{ + lua_pushinteger(L, value); + lua_setfield(L, -2, key); +} + +static void setboolfield(lua_State *L, const char *key, int value) +{ + if (value < 0) /* undefined? */ + return; /* does not set field */ + lua_pushboolean(L, value); + lua_setfield(L, -2, key); +} + +static int getboolfield(lua_State *L, const char *key) +{ + int res; + lua_getfield(L, -1, key); + res = lua_isnil(L, -1) ? -1 : lua_toboolean(L, -1); + lua_pop(L, 1); + return res; +} + +static int getfield(lua_State *L, const char *key, int d) +{ + int res; + lua_getfield(L, -1, key); + if (lua_isnumber(L, -1)) { + res = (int)lua_tointeger(L, -1); + } else { + if (d < 0) + lj_err_callerv(L, LJ_ERR_OSDATEF, key); + res = d; + } + lua_pop(L, 1); + return res; +} + +LJLIB_CF(os_date) +{ + const char *s = luaL_optstring(L, 1, "%c"); + time_t t = luaL_opt(L, (time_t)luaL_checknumber, 2, time(NULL)); + struct tm *stm; +#if LJ_TARGET_POSIX + struct tm rtm; +#endif + if (*s == '!') { /* UTC? */ + s++; /* Skip '!' */ +#if LJ_TARGET_POSIX + stm = gmtime_r(&t, &rtm); +#else + stm = gmtime(&t); +#endif + } else { +#if LJ_TARGET_POSIX + stm = localtime_r(&t, &rtm); +#else + stm = localtime(&t); +#endif + } + if (stm == NULL) { /* Invalid date? */ + setnilV(L->top++); + } else if (strcmp(s, "*t") == 0) { + lua_createtable(L, 0, 9); /* 9 = number of fields */ + setfield(L, "sec", stm->tm_sec); + setfield(L, "min", stm->tm_min); + setfield(L, "hour", stm->tm_hour); + setfield(L, "day", stm->tm_mday); + setfield(L, "month", stm->tm_mon+1); + setfield(L, "year", stm->tm_year+1900); + setfield(L, "wday", stm->tm_wday+1); + setfield(L, "yday", stm->tm_yday+1); + setboolfield(L, "isdst", stm->tm_isdst); + } else if (*s) { + SBuf *sb = &G(L)->tmpbuf; + MSize sz = 0, retry = 4; + const char *q; + for (q = s; *q; q++) + sz += (*q == '%') ? 30 : 1; /* Overflow doesn't matter. */ + setsbufL(sb, L); + while (retry--) { /* Limit growth for invalid format or empty result. */ + char *buf = lj_buf_need(sb, sz); + size_t len = strftime(buf, sbufsz(sb), s, stm); + if (len) { + setstrV(L, L->top++, lj_str_new(L, buf, len)); + lj_gc_check(L); + break; + } + sz += (sz|1); + } + } else { + setstrV(L, L->top++, &G(L)->strempty); + } + return 1; +} + +LJLIB_CF(os_time) +{ + time_t t; + if (lua_isnoneornil(L, 1)) { /* called without args? */ + t = time(NULL); /* get current time */ + } else { + struct tm ts; + luaL_checktype(L, 1, LUA_TTABLE); + lua_settop(L, 1); /* make sure table is at the top */ + ts.tm_sec = getfield(L, "sec", 0); + ts.tm_min = getfield(L, "min", 0); + ts.tm_hour = getfield(L, "hour", 12); + ts.tm_mday = getfield(L, "day", -1); + ts.tm_mon = getfield(L, "month", -1) - 1; + ts.tm_year = getfield(L, "year", -1) - 1900; + ts.tm_isdst = getboolfield(L, "isdst"); + t = mktime(&ts); + } + if (t == (time_t)(-1)) + lua_pushnil(L); + else + lua_pushnumber(L, (lua_Number)t); + return 1; +} + +LJLIB_CF(os_difftime) +{ + lua_pushnumber(L, difftime((time_t)(luaL_checknumber(L, 1)), + (time_t)(luaL_optnumber(L, 2, (lua_Number)0)))); + return 1; +} + +/* ------------------------------------------------------------------------ */ + +LJLIB_CF(os_setlocale) +{ +#if LJ_TARGET_PSVITA + lua_pushliteral(L, "C"); +#else + GCstr *s = lj_lib_optstr(L, 1); + const char *str = s ? strdata(s) : NULL; + int opt = lj_lib_checkopt(L, 2, 6, + "\5ctype\7numeric\4time\7collate\10monetary\1\377\3all"); + if (opt == 0) opt = LC_CTYPE; + else if (opt == 1) opt = LC_NUMERIC; + else if (opt == 2) opt = LC_TIME; + else if (opt == 3) opt = LC_COLLATE; + else if (opt == 4) opt = LC_MONETARY; + else if (opt == 6) opt = LC_ALL; + lua_pushstring(L, setlocale(opt, str)); +#endif + return 1; +} + +/* ------------------------------------------------------------------------ */ + +#include "lj_libdef.h" + +LUALIB_API int luaopen_os(lua_State *L) +{ + LJ_LIB_REG(L, LUA_OSLIBNAME, os); + return 1; +} + diff --git a/fluent-bit/lib/luajit-3065c9/src/lib_package.c b/fluent-bit/lib/luajit-3065c9/src/lib_package.c new file mode 100644 index 00000000..1f8b0677 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lib_package.c @@ -0,0 +1,628 @@ +/* +** Package library. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +** +** Major portions taken verbatim or adapted from the Lua interpreter. +** Copyright (C) 1994-2012 Lua.org, PUC-Rio. See Copyright Notice in lua.h +*/ + +#define lib_package_c +#define LUA_LIB + +#include "lua.h" +#include "lauxlib.h" +#include "lualib.h" + +#include "lj_obj.h" +#include "lj_err.h" +#include "lj_lib.h" + +/* ------------------------------------------------------------------------ */ + +/* Error codes for ll_loadfunc. */ +#define PACKAGE_ERR_LIB 1 +#define PACKAGE_ERR_FUNC 2 +#define PACKAGE_ERR_LOAD 3 + +/* Redefined in platform specific part. */ +#define PACKAGE_LIB_FAIL "open" +#define setprogdir(L) ((void)0) + +/* Symbol name prefixes. */ +#define SYMPREFIX_CF "luaopen_%s" +#define SYMPREFIX_BC "luaJIT_BC_%s" + +#if LJ_TARGET_DLOPEN + +#include + +static void ll_unloadlib(void *lib) +{ + dlclose(lib); +} + +static void *ll_load(lua_State *L, const char *path, int gl) +{ + void *lib = dlopen(path, RTLD_NOW | (gl ? RTLD_GLOBAL : RTLD_LOCAL)); + if (lib == NULL) lua_pushstring(L, dlerror()); + return lib; +} + +static lua_CFunction ll_sym(lua_State *L, void *lib, const char *sym) +{ + lua_CFunction f = (lua_CFunction)dlsym(lib, sym); + if (f == NULL) lua_pushstring(L, dlerror()); + return f; +} + +static const char *ll_bcsym(void *lib, const char *sym) +{ +#if defined(RTLD_DEFAULT) + if (lib == NULL) lib = RTLD_DEFAULT; +#elif LJ_TARGET_OSX || LJ_TARGET_BSD + if (lib == NULL) lib = (void *)(intptr_t)-2; +#endif + return (const char *)dlsym(lib, sym); +} + +#elif LJ_TARGET_WINDOWS + +#define WIN32_LEAN_AND_MEAN +#include + +#ifndef GET_MODULE_HANDLE_EX_FLAG_FROM_ADDRESS +#define GET_MODULE_HANDLE_EX_FLAG_FROM_ADDRESS 4 +#define GET_MODULE_HANDLE_EX_FLAG_UNCHANGED_REFCOUNT 2 +BOOL WINAPI GetModuleHandleExA(DWORD, LPCSTR, HMODULE*); +#endif + +#if LJ_TARGET_UWP +void *LJ_WIN_LOADLIBA(const char *path) +{ + DWORD err = GetLastError(); + wchar_t wpath[256]; + HANDLE lib = NULL; + if (MultiByteToWideChar(CP_ACP, 0, path, -1, wpath, 256) > 0) { + lib = LoadPackagedLibrary(wpath, 0); + } + SetLastError(err); + return lib; +} +#endif + +#undef setprogdir + +static void setprogdir(lua_State *L) +{ + char buff[MAX_PATH + 1]; + char *lb; + DWORD nsize = sizeof(buff); + DWORD n = GetModuleFileNameA(NULL, buff, nsize); + if (n == 0 || n == nsize || (lb = strrchr(buff, '\\')) == NULL) { + luaL_error(L, "unable to get ModuleFileName"); + } else { + *lb = '\0'; + luaL_gsub(L, lua_tostring(L, -1), LUA_EXECDIR, buff); + lua_remove(L, -2); /* remove original string */ + } +} + +static void pusherror(lua_State *L) +{ + DWORD error = GetLastError(); +#if LJ_TARGET_XBOXONE + wchar_t wbuffer[128]; + char buffer[128*2]; + if (FormatMessageW(FORMAT_MESSAGE_IGNORE_INSERTS | FORMAT_MESSAGE_FROM_SYSTEM, + NULL, error, 0, wbuffer, sizeof(wbuffer)/sizeof(wchar_t), NULL) && + WideCharToMultiByte(CP_ACP, 0, wbuffer, 128, buffer, 128*2, NULL, NULL)) +#else + char buffer[128]; + if (FormatMessageA(FORMAT_MESSAGE_IGNORE_INSERTS | FORMAT_MESSAGE_FROM_SYSTEM, + NULL, error, 0, buffer, sizeof(buffer), NULL)) +#endif + lua_pushstring(L, buffer); + else + lua_pushfstring(L, "system error %d\n", error); +} + +static void ll_unloadlib(void *lib) +{ + FreeLibrary((HINSTANCE)lib); +} + +static void *ll_load(lua_State *L, const char *path, int gl) +{ + HINSTANCE lib = LJ_WIN_LOADLIBA(path); + if (lib == NULL) pusherror(L); + UNUSED(gl); + return lib; +} + +static lua_CFunction ll_sym(lua_State *L, void *lib, const char *sym) +{ + lua_CFunction f = (lua_CFunction)GetProcAddress((HINSTANCE)lib, sym); + if (f == NULL) pusherror(L); + return f; +} + +#if LJ_TARGET_UWP +EXTERN_C IMAGE_DOS_HEADER __ImageBase; +#endif + +static const char *ll_bcsym(void *lib, const char *sym) +{ + if (lib) { + return (const char *)GetProcAddress((HINSTANCE)lib, sym); + } else { +#if LJ_TARGET_UWP + return (const char *)GetProcAddress((HINSTANCE)&__ImageBase, sym); +#else + HINSTANCE h = GetModuleHandleA(NULL); + const char *p = (const char *)GetProcAddress(h, sym); + if (p == NULL && GetModuleHandleExA(GET_MODULE_HANDLE_EX_FLAG_FROM_ADDRESS|GET_MODULE_HANDLE_EX_FLAG_UNCHANGED_REFCOUNT, + (const char *)ll_bcsym, &h)) + p = (const char *)GetProcAddress(h, sym); + return p; +#endif + } +} + +#else + +#undef PACKAGE_LIB_FAIL +#define PACKAGE_LIB_FAIL "absent" + +#define DLMSG "dynamic libraries not enabled; no support for target OS" + +static void ll_unloadlib(void *lib) +{ + UNUSED(lib); +} + +static void *ll_load(lua_State *L, const char *path, int gl) +{ + UNUSED(path); UNUSED(gl); + lua_pushliteral(L, DLMSG); + return NULL; +} + +static lua_CFunction ll_sym(lua_State *L, void *lib, const char *sym) +{ + UNUSED(lib); UNUSED(sym); + lua_pushliteral(L, DLMSG); + return NULL; +} + +static const char *ll_bcsym(void *lib, const char *sym) +{ + UNUSED(lib); UNUSED(sym); + return NULL; +} + +#endif + +/* ------------------------------------------------------------------------ */ + +static void **ll_register(lua_State *L, const char *path) +{ + void **plib; + lua_pushfstring(L, "LOADLIB: %s", path); + lua_gettable(L, LUA_REGISTRYINDEX); /* check library in registry? */ + if (!lua_isnil(L, -1)) { /* is there an entry? */ + plib = (void **)lua_touserdata(L, -1); + } else { /* no entry yet; create one */ + lua_pop(L, 1); + plib = (void **)lua_newuserdata(L, sizeof(void *)); + *plib = NULL; + luaL_setmetatable(L, "_LOADLIB"); + lua_pushfstring(L, "LOADLIB: %s", path); + lua_pushvalue(L, -2); + lua_settable(L, LUA_REGISTRYINDEX); + } + return plib; +} + +static const char *mksymname(lua_State *L, const char *modname, + const char *prefix) +{ + const char *funcname; + const char *mark = strchr(modname, *LUA_IGMARK); + if (mark) modname = mark + 1; + funcname = luaL_gsub(L, modname, ".", "_"); + funcname = lua_pushfstring(L, prefix, funcname); + lua_remove(L, -2); /* remove 'gsub' result */ + return funcname; +} + +static int ll_loadfunc(lua_State *L, const char *path, const char *name, int r) +{ + void **reg; + if (strlen(path) >= 4096) { + lua_pushliteral(L, "path too long"); + return PACKAGE_ERR_LIB; + } + reg = ll_register(L, path); + if (*reg == NULL) *reg = ll_load(L, path, (*name == '*')); + if (*reg == NULL) { + return PACKAGE_ERR_LIB; /* Unable to load library. */ + } else if (*name == '*') { /* Only load library into global namespace. */ + lua_pushboolean(L, 1); + return 0; + } else { + const char *sym = r ? name : mksymname(L, name, SYMPREFIX_CF); + lua_CFunction f = ll_sym(L, *reg, sym); + if (f) { + lua_pushcfunction(L, f); + return 0; + } + if (!r) { + const char *bcdata = ll_bcsym(*reg, mksymname(L, name, SYMPREFIX_BC)); + lua_pop(L, 1); + if (bcdata) { + if (luaL_loadbuffer(L, bcdata, ~(size_t)0, name) != 0) + return PACKAGE_ERR_LOAD; + return 0; + } + } + return PACKAGE_ERR_FUNC; /* Unable to find function. */ + } +} + +static int lj_cf_package_loadlib(lua_State *L) +{ + const char *path = luaL_checkstring(L, 1); + const char *init = luaL_checkstring(L, 2); + int st = ll_loadfunc(L, path, init, 1); + if (st == 0) { /* no errors? */ + return 1; /* return the loaded function */ + } else { /* error; error message is on stack top */ + lua_pushnil(L); + lua_insert(L, -2); + lua_pushstring(L, (st == PACKAGE_ERR_LIB) ? PACKAGE_LIB_FAIL : "init"); + return 3; /* return nil, error message, and where */ + } +} + +static int lj_cf_package_unloadlib(lua_State *L) +{ + void **lib = (void **)luaL_checkudata(L, 1, "_LOADLIB"); + if (*lib) ll_unloadlib(*lib); + *lib = NULL; /* mark library as closed */ + return 0; +} + +/* ------------------------------------------------------------------------ */ + +static int readable(const char *filename) +{ + FILE *f = fopen(filename, "r"); /* try to open file */ + if (f == NULL) return 0; /* open failed */ + fclose(f); + return 1; +} + +static const char *pushnexttemplate(lua_State *L, const char *path) +{ + const char *l; + while (*path == *LUA_PATHSEP) path++; /* skip separators */ + if (*path == '\0') return NULL; /* no more templates */ + l = strchr(path, *LUA_PATHSEP); /* find next separator */ + if (l == NULL) l = path + strlen(path); + lua_pushlstring(L, path, (size_t)(l - path)); /* template */ + return l; +} + +static const char *searchpath (lua_State *L, const char *name, + const char *path, const char *sep, + const char *dirsep) +{ + luaL_Buffer msg; /* to build error message */ + luaL_buffinit(L, &msg); + if (*sep != '\0') /* non-empty separator? */ + name = luaL_gsub(L, name, sep, dirsep); /* replace it by 'dirsep' */ + while ((path = pushnexttemplate(L, path)) != NULL) { + const char *filename = luaL_gsub(L, lua_tostring(L, -1), + LUA_PATH_MARK, name); + lua_remove(L, -2); /* remove path template */ + if (readable(filename)) /* does file exist and is readable? */ + return filename; /* return that file name */ + lua_pushfstring(L, "\n\tno file " LUA_QS, filename); + lua_remove(L, -2); /* remove file name */ + luaL_addvalue(&msg); /* concatenate error msg. entry */ + } + luaL_pushresult(&msg); /* create error message */ + return NULL; /* not found */ +} + +static int lj_cf_package_searchpath(lua_State *L) +{ + const char *f = searchpath(L, luaL_checkstring(L, 1), + luaL_checkstring(L, 2), + luaL_optstring(L, 3, "."), + luaL_optstring(L, 4, LUA_DIRSEP)); + if (f != NULL) { + return 1; + } else { /* error message is on top of the stack */ + lua_pushnil(L); + lua_insert(L, -2); + return 2; /* return nil + error message */ + } +} + +static const char *findfile(lua_State *L, const char *name, + const char *pname) +{ + const char *path; + lua_getfield(L, LUA_ENVIRONINDEX, pname); + path = lua_tostring(L, -1); + if (path == NULL) + luaL_error(L, LUA_QL("package.%s") " must be a string", pname); + return searchpath(L, name, path, ".", LUA_DIRSEP); +} + +static void loaderror(lua_State *L, const char *filename) +{ + luaL_error(L, "error loading module " LUA_QS " from file " LUA_QS ":\n\t%s", + lua_tostring(L, 1), filename, lua_tostring(L, -1)); +} + +static int lj_cf_package_loader_lua(lua_State *L) +{ + const char *filename; + const char *name = luaL_checkstring(L, 1); + filename = findfile(L, name, "path"); + if (filename == NULL) return 1; /* library not found in this path */ + if (luaL_loadfile(L, filename) != 0) + loaderror(L, filename); + return 1; /* library loaded successfully */ +} + +static int lj_cf_package_loader_c(lua_State *L) +{ + const char *name = luaL_checkstring(L, 1); + const char *filename = findfile(L, name, "cpath"); + if (filename == NULL) return 1; /* library not found in this path */ + if (ll_loadfunc(L, filename, name, 0) != 0) + loaderror(L, filename); + return 1; /* library loaded successfully */ +} + +static int lj_cf_package_loader_croot(lua_State *L) +{ + const char *filename; + const char *name = luaL_checkstring(L, 1); + const char *p = strchr(name, '.'); + int st; + if (p == NULL) return 0; /* is root */ + lua_pushlstring(L, name, (size_t)(p - name)); + filename = findfile(L, lua_tostring(L, -1), "cpath"); + if (filename == NULL) return 1; /* root not found */ + if ((st = ll_loadfunc(L, filename, name, 0)) != 0) { + if (st != PACKAGE_ERR_FUNC) loaderror(L, filename); /* real error */ + lua_pushfstring(L, "\n\tno module " LUA_QS " in file " LUA_QS, + name, filename); + return 1; /* function not found */ + } + return 1; +} + +static int lj_cf_package_loader_preload(lua_State *L) +{ + const char *name = luaL_checkstring(L, 1); + lua_getfield(L, LUA_ENVIRONINDEX, "preload"); + if (!lua_istable(L, -1)) + luaL_error(L, LUA_QL("package.preload") " must be a table"); + lua_getfield(L, -1, name); + if (lua_isnil(L, -1)) { /* Not found? */ + const char *bcname = mksymname(L, name, SYMPREFIX_BC); + const char *bcdata = ll_bcsym(NULL, bcname); + if (bcdata == NULL || luaL_loadbuffer(L, bcdata, ~(size_t)0, name) != 0) + lua_pushfstring(L, "\n\tno field package.preload['%s']", name); + } + return 1; +} + +/* ------------------------------------------------------------------------ */ + +#define KEY_SENTINEL (U64x(80000000,00000000)|'s') + +static int lj_cf_package_require(lua_State *L) +{ + const char *name = luaL_checkstring(L, 1); + int i; + lua_settop(L, 1); /* _LOADED table will be at index 2 */ + lua_getfield(L, LUA_REGISTRYINDEX, "_LOADED"); + lua_getfield(L, 2, name); + if (lua_toboolean(L, -1)) { /* is it there? */ + if ((L->top-1)->u64 == KEY_SENTINEL) /* check loops */ + luaL_error(L, "loop or previous error loading module " LUA_QS, name); + return 1; /* package is already loaded */ + } + /* else must load it; iterate over available loaders */ + lua_getfield(L, LUA_ENVIRONINDEX, "loaders"); + if (!lua_istable(L, -1)) + luaL_error(L, LUA_QL("package.loaders") " must be a table"); + lua_pushliteral(L, ""); /* error message accumulator */ + for (i = 1; ; i++) { + lua_rawgeti(L, -2, i); /* get a loader */ + if (lua_isnil(L, -1)) + luaL_error(L, "module " LUA_QS " not found:%s", + name, lua_tostring(L, -2)); + lua_pushstring(L, name); + lua_call(L, 1, 1); /* call it */ + if (lua_isfunction(L, -1)) /* did it find module? */ + break; /* module loaded successfully */ + else if (lua_isstring(L, -1)) /* loader returned error message? */ + lua_concat(L, 2); /* accumulate it */ + else + lua_pop(L, 1); + } + (L->top++)->u64 = KEY_SENTINEL; + lua_setfield(L, 2, name); /* _LOADED[name] = sentinel */ + lua_pushstring(L, name); /* pass name as argument to module */ + lua_call(L, 1, 1); /* run loaded module */ + if (!lua_isnil(L, -1)) /* non-nil return? */ + lua_setfield(L, 2, name); /* _LOADED[name] = returned value */ + lua_getfield(L, 2, name); + if ((L->top-1)->u64 == KEY_SENTINEL) { /* module did not set a value? */ + lua_pushboolean(L, 1); /* use true as result */ + lua_pushvalue(L, -1); /* extra copy to be returned */ + lua_setfield(L, 2, name); /* _LOADED[name] = true */ + } + lj_lib_checkfpu(L); + return 1; +} + +/* ------------------------------------------------------------------------ */ + +static void setfenv(lua_State *L) +{ + lua_Debug ar; + if (lua_getstack(L, 1, &ar) == 0 || + lua_getinfo(L, "f", &ar) == 0 || /* get calling function */ + lua_iscfunction(L, -1)) + luaL_error(L, LUA_QL("module") " not called from a Lua function"); + lua_pushvalue(L, -2); + lua_setfenv(L, -2); + lua_pop(L, 1); +} + +static void dooptions(lua_State *L, int n) +{ + int i; + for (i = 2; i <= n; i++) { + lua_pushvalue(L, i); /* get option (a function) */ + lua_pushvalue(L, -2); /* module */ + lua_call(L, 1, 0); + } +} + +static void modinit(lua_State *L, const char *modname) +{ + const char *dot; + lua_pushvalue(L, -1); + lua_setfield(L, -2, "_M"); /* module._M = module */ + lua_pushstring(L, modname); + lua_setfield(L, -2, "_NAME"); + dot = strrchr(modname, '.'); /* look for last dot in module name */ + if (dot == NULL) dot = modname; else dot++; + /* set _PACKAGE as package name (full module name minus last part) */ + lua_pushlstring(L, modname, (size_t)(dot - modname)); + lua_setfield(L, -2, "_PACKAGE"); +} + +static int lj_cf_package_module(lua_State *L) +{ + const char *modname = luaL_checkstring(L, 1); + int lastarg = (int)(L->top - L->base); + luaL_pushmodule(L, modname, 1); + lua_getfield(L, -1, "_NAME"); + if (!lua_isnil(L, -1)) { /* Module already initialized? */ + lua_pop(L, 1); + } else { + lua_pop(L, 1); + modinit(L, modname); + } + lua_pushvalue(L, -1); + setfenv(L); + dooptions(L, lastarg); + return LJ_52; +} + +static int lj_cf_package_seeall(lua_State *L) +{ + luaL_checktype(L, 1, LUA_TTABLE); + if (!lua_getmetatable(L, 1)) { + lua_createtable(L, 0, 1); /* create new metatable */ + lua_pushvalue(L, -1); + lua_setmetatable(L, 1); + } + lua_pushvalue(L, LUA_GLOBALSINDEX); + lua_setfield(L, -2, "__index"); /* mt.__index = _G */ + return 0; +} + +/* ------------------------------------------------------------------------ */ + +#define AUXMARK "\1" + +static void setpath(lua_State *L, const char *fieldname, const char *envname, + const char *def, int noenv) +{ +#if LJ_TARGET_CONSOLE + const char *path = NULL; + UNUSED(envname); +#else + const char *path = getenv(envname); +#endif + if (path == NULL || noenv) { + lua_pushstring(L, def); + } else { + path = luaL_gsub(L, path, LUA_PATHSEP LUA_PATHSEP, + LUA_PATHSEP AUXMARK LUA_PATHSEP); + luaL_gsub(L, path, AUXMARK, def); + lua_remove(L, -2); + } + setprogdir(L); + lua_setfield(L, -2, fieldname); +} + +static const luaL_Reg package_lib[] = { + { "loadlib", lj_cf_package_loadlib }, + { "searchpath", lj_cf_package_searchpath }, + { "seeall", lj_cf_package_seeall }, + { NULL, NULL } +}; + +static const luaL_Reg package_global[] = { + { "module", lj_cf_package_module }, + { "require", lj_cf_package_require }, + { NULL, NULL } +}; + +static const lua_CFunction package_loaders[] = +{ + lj_cf_package_loader_preload, + lj_cf_package_loader_lua, + lj_cf_package_loader_c, + lj_cf_package_loader_croot, + NULL +}; + +LUALIB_API int luaopen_package(lua_State *L) +{ + int i; + int noenv; + luaL_newmetatable(L, "_LOADLIB"); + lj_lib_pushcf(L, lj_cf_package_unloadlib, 1); + lua_setfield(L, -2, "__gc"); + luaL_register(L, LUA_LOADLIBNAME, package_lib); + lua_copy(L, -1, LUA_ENVIRONINDEX); + lua_createtable(L, sizeof(package_loaders)/sizeof(package_loaders[0])-1, 0); + for (i = 0; package_loaders[i] != NULL; i++) { + lj_lib_pushcf(L, package_loaders[i], 1); + lua_rawseti(L, -2, i+1); + } +#if LJ_52 + lua_pushvalue(L, -1); + lua_setfield(L, -3, "searchers"); +#endif + lua_setfield(L, -2, "loaders"); + lua_getfield(L, LUA_REGISTRYINDEX, "LUA_NOENV"); + noenv = lua_toboolean(L, -1); + lua_pop(L, 1); + setpath(L, "path", LUA_PATH, LUA_PATH_DEFAULT, noenv); + setpath(L, "cpath", LUA_CPATH, LUA_CPATH_DEFAULT, noenv); + lua_pushliteral(L, LUA_PATH_CONFIG); + lua_setfield(L, -2, "config"); + luaL_findtable(L, LUA_REGISTRYINDEX, "_LOADED", 16); + lua_setfield(L, -2, "loaded"); + luaL_findtable(L, LUA_REGISTRYINDEX, "_PRELOAD", 4); + lua_setfield(L, -2, "preload"); + lua_pushvalue(L, LUA_GLOBALSINDEX); + luaL_register(L, NULL, package_global); + lua_pop(L, 1); + return 1; +} + diff --git a/fluent-bit/lib/luajit-3065c9/src/lib_string.c b/fluent-bit/lib/luajit-3065c9/src/lib_string.c new file mode 100644 index 00000000..79aeddfc --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lib_string.c @@ -0,0 +1,676 @@ +/* +** String library. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +** +** Major portions taken verbatim or adapted from the Lua interpreter. +** Copyright (C) 1994-2008 Lua.org, PUC-Rio. See Copyright Notice in lua.h +*/ + +#define lib_string_c +#define LUA_LIB + +#include "lua.h" +#include "lauxlib.h" +#include "lualib.h" + +#include "lj_obj.h" +#include "lj_gc.h" +#include "lj_err.h" +#include "lj_buf.h" +#include "lj_str.h" +#include "lj_tab.h" +#include "lj_meta.h" +#include "lj_state.h" +#include "lj_ff.h" +#include "lj_bcdump.h" +#include "lj_char.h" +#include "lj_strfmt.h" +#include "lj_lib.h" + +/* ------------------------------------------------------------------------ */ + +#define LJLIB_MODULE_string + +LJLIB_LUA(string_len) /* + function(s) + CHECK_str(s) + return #s + end +*/ + +LJLIB_ASM(string_byte) LJLIB_REC(string_range 0) +{ + GCstr *s = lj_lib_checkstr(L, 1); + int32_t len = (int32_t)s->len; + int32_t start = lj_lib_optint(L, 2, 1); + int32_t stop = lj_lib_optint(L, 3, start); + int32_t n, i; + const unsigned char *p; + if (stop < 0) stop += len+1; + if (start < 0) start += len+1; + if (start <= 0) start = 1; + if (stop > len) stop = len; + if (start > stop) return FFH_RES(0); /* Empty interval: return no results. */ + start--; + n = stop - start; + if ((uint32_t)n > LUAI_MAXCSTACK) + lj_err_caller(L, LJ_ERR_STRSLC); + lj_state_checkstack(L, (MSize)n); + p = (const unsigned char *)strdata(s) + start; + for (i = 0; i < n; i++) + setintV(L->base + i-1-LJ_FR2, p[i]); + return FFH_RES(n); +} + +LJLIB_ASM(string_char) LJLIB_REC(.) +{ + int i, nargs = (int)(L->top - L->base); + char *buf = lj_buf_tmp(L, (MSize)nargs); + for (i = 1; i <= nargs; i++) { + int32_t k = lj_lib_checkint(L, i); + if (!checku8(k)) + lj_err_arg(L, i, LJ_ERR_BADVAL); + buf[i-1] = (char)k; + } + setstrV(L, L->base-1-LJ_FR2, lj_str_new(L, buf, (size_t)nargs)); + return FFH_RES(1); +} + +LJLIB_ASM(string_sub) LJLIB_REC(string_range 1) +{ + lj_lib_checkstr(L, 1); + lj_lib_checkint(L, 2); + setintV(L->base+2, lj_lib_optint(L, 3, -1)); + return FFH_RETRY; +} + +LJLIB_CF(string_rep) LJLIB_REC(.) +{ + GCstr *s = lj_lib_checkstr(L, 1); + int32_t rep = lj_lib_checkint(L, 2); + GCstr *sep = lj_lib_optstr(L, 3); + SBuf *sb = lj_buf_tmp_(L); + if (sep && rep > 1) { + GCstr *s2 = lj_buf_cat2str(L, sep, s); + lj_buf_reset(sb); + lj_buf_putstr(sb, s); + s = s2; + rep--; + } + sb = lj_buf_putstr_rep(sb, s, rep); + setstrV(L, L->top-1, lj_buf_str(L, sb)); + lj_gc_check(L); + return 1; +} + +LJLIB_ASM(string_reverse) LJLIB_REC(string_op IRCALL_lj_buf_putstr_reverse) +{ + lj_lib_checkstr(L, 1); + return FFH_RETRY; +} +LJLIB_ASM_(string_lower) LJLIB_REC(string_op IRCALL_lj_buf_putstr_lower) +LJLIB_ASM_(string_upper) LJLIB_REC(string_op IRCALL_lj_buf_putstr_upper) + +/* ------------------------------------------------------------------------ */ + +static int writer_buf(lua_State *L, const void *p, size_t size, void *sb) +{ + lj_buf_putmem((SBuf *)sb, p, (MSize)size); + UNUSED(L); + return 0; +} + +LJLIB_CF(string_dump) +{ + GCfunc *fn = lj_lib_checkfunc(L, 1); + int strip = L->base+1 < L->top && tvistruecond(L->base+1); + SBuf *sb = lj_buf_tmp_(L); /* Assumes lj_bcwrite() doesn't use tmpbuf. */ + L->top = L->base+1; + if (!isluafunc(fn) || lj_bcwrite(L, funcproto(fn), writer_buf, sb, strip)) + lj_err_caller(L, LJ_ERR_STRDUMP); + setstrV(L, L->top-1, lj_buf_str(L, sb)); + lj_gc_check(L); + return 1; +} + +/* ------------------------------------------------------------------------ */ + +/* macro to `unsign' a character */ +#define uchar(c) ((unsigned char)(c)) + +#define CAP_UNFINISHED (-1) +#define CAP_POSITION (-2) + +typedef struct MatchState { + const char *src_init; /* init of source string */ + const char *src_end; /* end (`\0') of source string */ + lua_State *L; + int level; /* total number of captures (finished or unfinished) */ + int depth; + struct { + const char *init; + ptrdiff_t len; + } capture[LUA_MAXCAPTURES]; +} MatchState; + +#define L_ESC '%' + +static int check_capture(MatchState *ms, int l) +{ + l -= '1'; + if (l < 0 || l >= ms->level || ms->capture[l].len == CAP_UNFINISHED) + lj_err_caller(ms->L, LJ_ERR_STRCAPI); + return l; +} + +static int capture_to_close(MatchState *ms) +{ + int level = ms->level; + for (level--; level>=0; level--) + if (ms->capture[level].len == CAP_UNFINISHED) return level; + lj_err_caller(ms->L, LJ_ERR_STRPATC); + return 0; /* unreachable */ +} + +static const char *classend(MatchState *ms, const char *p) +{ + switch (*p++) { + case L_ESC: + if (*p == '\0') + lj_err_caller(ms->L, LJ_ERR_STRPATE); + return p+1; + case '[': + if (*p == '^') p++; + do { /* look for a `]' */ + if (*p == '\0') + lj_err_caller(ms->L, LJ_ERR_STRPATM); + if (*(p++) == L_ESC && *p != '\0') + p++; /* skip escapes (e.g. `%]') */ + } while (*p != ']'); + return p+1; + default: + return p; + } +} + +static const unsigned char match_class_map[32] = { + 0,LJ_CHAR_ALPHA,0,LJ_CHAR_CNTRL,LJ_CHAR_DIGIT,0,0,LJ_CHAR_GRAPH,0,0,0,0, + LJ_CHAR_LOWER,0,0,0,LJ_CHAR_PUNCT,0,0,LJ_CHAR_SPACE,0, + LJ_CHAR_UPPER,0,LJ_CHAR_ALNUM,LJ_CHAR_XDIGIT,0,0,0,0,0,0,0 +}; + +static int match_class(int c, int cl) +{ + if ((cl & 0xc0) == 0x40) { + int t = match_class_map[(cl&0x1f)]; + if (t) { + t = lj_char_isa(c, t); + return (cl & 0x20) ? t : !t; + } + if (cl == 'z') return c == 0; + if (cl == 'Z') return c != 0; + } + return (cl == c); +} + +static int matchbracketclass(int c, const char *p, const char *ec) +{ + int sig = 1; + if (*(p+1) == '^') { + sig = 0; + p++; /* skip the `^' */ + } + while (++p < ec) { + if (*p == L_ESC) { + p++; + if (match_class(c, uchar(*p))) + return sig; + } + else if ((*(p+1) == '-') && (p+2 < ec)) { + p+=2; + if (uchar(*(p-2)) <= c && c <= uchar(*p)) + return sig; + } + else if (uchar(*p) == c) return sig; + } + return !sig; +} + +static int singlematch(int c, const char *p, const char *ep) +{ + switch (*p) { + case '.': return 1; /* matches any char */ + case L_ESC: return match_class(c, uchar(*(p+1))); + case '[': return matchbracketclass(c, p, ep-1); + default: return (uchar(*p) == c); + } +} + +static const char *match(MatchState *ms, const char *s, const char *p); + +static const char *matchbalance(MatchState *ms, const char *s, const char *p) +{ + if (*p == 0 || *(p+1) == 0) + lj_err_caller(ms->L, LJ_ERR_STRPATU); + if (*s != *p) { + return NULL; + } else { + int b = *p; + int e = *(p+1); + int cont = 1; + while (++s < ms->src_end) { + if (*s == e) { + if (--cont == 0) return s+1; + } else if (*s == b) { + cont++; + } + } + } + return NULL; /* string ends out of balance */ +} + +static const char *max_expand(MatchState *ms, const char *s, + const char *p, const char *ep) +{ + ptrdiff_t i = 0; /* counts maximum expand for item */ + while ((s+i)src_end && singlematch(uchar(*(s+i)), p, ep)) + i++; + /* keeps trying to match with the maximum repetitions */ + while (i>=0) { + const char *res = match(ms, (s+i), ep+1); + if (res) return res; + i--; /* else didn't match; reduce 1 repetition to try again */ + } + return NULL; +} + +static const char *min_expand(MatchState *ms, const char *s, + const char *p, const char *ep) +{ + for (;;) { + const char *res = match(ms, s, ep+1); + if (res != NULL) + return res; + else if (ssrc_end && singlematch(uchar(*s), p, ep)) + s++; /* try with one more repetition */ + else + return NULL; + } +} + +static const char *start_capture(MatchState *ms, const char *s, + const char *p, int what) +{ + const char *res; + int level = ms->level; + if (level >= LUA_MAXCAPTURES) lj_err_caller(ms->L, LJ_ERR_STRCAPN); + ms->capture[level].init = s; + ms->capture[level].len = what; + ms->level = level+1; + if ((res=match(ms, s, p)) == NULL) /* match failed? */ + ms->level--; /* undo capture */ + return res; +} + +static const char *end_capture(MatchState *ms, const char *s, + const char *p) +{ + int l = capture_to_close(ms); + const char *res; + ms->capture[l].len = s - ms->capture[l].init; /* close capture */ + if ((res = match(ms, s, p)) == NULL) /* match failed? */ + ms->capture[l].len = CAP_UNFINISHED; /* undo capture */ + return res; +} + +static const char *match_capture(MatchState *ms, const char *s, int l) +{ + size_t len; + l = check_capture(ms, l); + len = (size_t)ms->capture[l].len; + if ((size_t)(ms->src_end-s) >= len && + memcmp(ms->capture[l].init, s, len) == 0) + return s+len; + else + return NULL; +} + +static const char *match(MatchState *ms, const char *s, const char *p) +{ + if (++ms->depth > LJ_MAX_XLEVEL) + lj_err_caller(ms->L, LJ_ERR_STRPATX); + init: /* using goto's to optimize tail recursion */ + switch (*p) { + case '(': /* start capture */ + if (*(p+1) == ')') /* position capture? */ + s = start_capture(ms, s, p+2, CAP_POSITION); + else + s = start_capture(ms, s, p+1, CAP_UNFINISHED); + break; + case ')': /* end capture */ + s = end_capture(ms, s, p+1); + break; + case L_ESC: + switch (*(p+1)) { + case 'b': /* balanced string? */ + s = matchbalance(ms, s, p+2); + if (s == NULL) break; + p+=4; + goto init; /* else s = match(ms, s, p+4); */ + case 'f': { /* frontier? */ + const char *ep; char previous; + p += 2; + if (*p != '[') + lj_err_caller(ms->L, LJ_ERR_STRPATB); + ep = classend(ms, p); /* points to what is next */ + previous = (s == ms->src_init) ? '\0' : *(s-1); + if (matchbracketclass(uchar(previous), p, ep-1) || + !matchbracketclass(uchar(*s), p, ep-1)) { s = NULL; break; } + p=ep; + goto init; /* else s = match(ms, s, ep); */ + } + default: + if (lj_char_isdigit(uchar(*(p+1)))) { /* capture results (%0-%9)? */ + s = match_capture(ms, s, uchar(*(p+1))); + if (s == NULL) break; + p+=2; + goto init; /* else s = match(ms, s, p+2) */ + } + goto dflt; /* case default */ + } + break; + case '\0': /* end of pattern */ + break; /* match succeeded */ + case '$': + /* is the `$' the last char in pattern? */ + if (*(p+1) != '\0') goto dflt; + if (s != ms->src_end) s = NULL; /* check end of string */ + break; + default: dflt: { /* it is a pattern item */ + const char *ep = classend(ms, p); /* points to what is next */ + int m = ssrc_end && singlematch(uchar(*s), p, ep); + switch (*ep) { + case '?': { /* optional */ + const char *res; + if (m && ((res=match(ms, s+1, ep+1)) != NULL)) { + s = res; + break; + } + p=ep+1; + goto init; /* else s = match(ms, s, ep+1); */ + } + case '*': /* 0 or more repetitions */ + s = max_expand(ms, s, p, ep); + break; + case '+': /* 1 or more repetitions */ + s = (m ? max_expand(ms, s+1, p, ep) : NULL); + break; + case '-': /* 0 or more repetitions (minimum) */ + s = min_expand(ms, s, p, ep); + break; + default: + if (m) { s++; p=ep; goto init; } /* else s = match(ms, s+1, ep); */ + s = NULL; + break; + } + break; + } + } + ms->depth--; + return s; +} + +static void push_onecapture(MatchState *ms, int i, const char *s, const char *e) +{ + if (i >= ms->level) { + if (i == 0) /* ms->level == 0, too */ + lua_pushlstring(ms->L, s, (size_t)(e - s)); /* add whole match */ + else + lj_err_caller(ms->L, LJ_ERR_STRCAPI); + } else { + ptrdiff_t l = ms->capture[i].len; + if (l == CAP_UNFINISHED) lj_err_caller(ms->L, LJ_ERR_STRCAPU); + if (l == CAP_POSITION) + lua_pushinteger(ms->L, ms->capture[i].init - ms->src_init + 1); + else + lua_pushlstring(ms->L, ms->capture[i].init, (size_t)l); + } +} + +static int push_captures(MatchState *ms, const char *s, const char *e) +{ + int i; + int nlevels = (ms->level == 0 && s) ? 1 : ms->level; + luaL_checkstack(ms->L, nlevels, "too many captures"); + for (i = 0; i < nlevels; i++) + push_onecapture(ms, i, s, e); + return nlevels; /* number of strings pushed */ +} + +static int str_find_aux(lua_State *L, int find) +{ + GCstr *s = lj_lib_checkstr(L, 1); + GCstr *p = lj_lib_checkstr(L, 2); + int32_t start = lj_lib_optint(L, 3, 1); + MSize st; + if (start < 0) start += (int32_t)s->len; else start--; + if (start < 0) start = 0; + st = (MSize)start; + if (st > s->len) { +#if LJ_52 + setnilV(L->top-1); + return 1; +#else + st = s->len; +#endif + } + if (find && ((L->base+3 < L->top && tvistruecond(L->base+3)) || + !lj_str_haspattern(p))) { /* Search for fixed string. */ + const char *q = lj_str_find(strdata(s)+st, strdata(p), s->len-st, p->len); + if (q) { + setintV(L->top-2, (int32_t)(q-strdata(s)) + 1); + setintV(L->top-1, (int32_t)(q-strdata(s)) + (int32_t)p->len); + return 2; + } + } else { /* Search for pattern. */ + MatchState ms; + const char *pstr = strdata(p); + const char *sstr = strdata(s) + st; + int anchor = 0; + if (*pstr == '^') { pstr++; anchor = 1; } + ms.L = L; + ms.src_init = strdata(s); + ms.src_end = strdata(s) + s->len; + do { /* Loop through string and try to match the pattern. */ + const char *q; + ms.level = ms.depth = 0; + q = match(&ms, sstr, pstr); + if (q) { + if (find) { + setintV(L->top++, (int32_t)(sstr-(strdata(s)-1))); + setintV(L->top++, (int32_t)(q-strdata(s))); + return push_captures(&ms, NULL, NULL) + 2; + } else { + return push_captures(&ms, sstr, q); + } + } + } while (sstr++ < ms.src_end && !anchor); + } + setnilV(L->top-1); /* Not found. */ + return 1; +} + +LJLIB_CF(string_find) LJLIB_REC(.) +{ + return str_find_aux(L, 1); +} + +LJLIB_CF(string_match) +{ + return str_find_aux(L, 0); +} + +LJLIB_NOREG LJLIB_CF(string_gmatch_aux) +{ + const char *p = strVdata(lj_lib_upvalue(L, 2)); + GCstr *str = strV(lj_lib_upvalue(L, 1)); + const char *s = strdata(str); + TValue *tvpos = lj_lib_upvalue(L, 3); + const char *src = s + tvpos->u32.lo; + MatchState ms; + ms.L = L; + ms.src_init = s; + ms.src_end = s + str->len; + for (; src <= ms.src_end; src++) { + const char *e; + ms.level = ms.depth = 0; + if ((e = match(&ms, src, p)) != NULL) { + int32_t pos = (int32_t)(e - s); + if (e == src) pos++; /* Ensure progress for empty match. */ + tvpos->u32.lo = (uint32_t)pos; + return push_captures(&ms, src, e); + } + } + return 0; /* not found */ +} + +LJLIB_CF(string_gmatch) +{ + lj_lib_checkstr(L, 1); + lj_lib_checkstr(L, 2); + L->top = L->base+3; + (L->top-1)->u64 = 0; + lj_lib_pushcc(L, lj_cf_string_gmatch_aux, FF_string_gmatch_aux, 3); + return 1; +} + +static void add_s(MatchState *ms, luaL_Buffer *b, const char *s, const char *e) +{ + size_t l, i; + const char *news = lua_tolstring(ms->L, 3, &l); + for (i = 0; i < l; i++) { + if (news[i] != L_ESC) { + luaL_addchar(b, news[i]); + } else { + i++; /* skip ESC */ + if (!lj_char_isdigit(uchar(news[i]))) { + luaL_addchar(b, news[i]); + } else if (news[i] == '0') { + luaL_addlstring(b, s, (size_t)(e - s)); + } else { + push_onecapture(ms, news[i] - '1', s, e); + luaL_addvalue(b); /* add capture to accumulated result */ + } + } + } +} + +static void add_value(MatchState *ms, luaL_Buffer *b, + const char *s, const char *e) +{ + lua_State *L = ms->L; + switch (lua_type(L, 3)) { + case LUA_TNUMBER: + case LUA_TSTRING: { + add_s(ms, b, s, e); + return; + } + case LUA_TFUNCTION: { + int n; + lua_pushvalue(L, 3); + n = push_captures(ms, s, e); + lua_call(L, n, 1); + break; + } + case LUA_TTABLE: { + push_onecapture(ms, 0, s, e); + lua_gettable(L, 3); + break; + } + } + if (!lua_toboolean(L, -1)) { /* nil or false? */ + lua_pop(L, 1); + lua_pushlstring(L, s, (size_t)(e - s)); /* keep original text */ + } else if (!lua_isstring(L, -1)) { + lj_err_callerv(L, LJ_ERR_STRGSRV, luaL_typename(L, -1)); + } + luaL_addvalue(b); /* add result to accumulator */ +} + +LJLIB_CF(string_gsub) +{ + size_t srcl; + const char *src = luaL_checklstring(L, 1, &srcl); + const char *p = luaL_checkstring(L, 2); + int tr = lua_type(L, 3); + int max_s = luaL_optint(L, 4, (int)(srcl+1)); + int anchor = (*p == '^') ? (p++, 1) : 0; + int n = 0; + MatchState ms; + luaL_Buffer b; + if (!(tr == LUA_TNUMBER || tr == LUA_TSTRING || + tr == LUA_TFUNCTION || tr == LUA_TTABLE)) + lj_err_arg(L, 3, LJ_ERR_NOSFT); + luaL_buffinit(L, &b); + ms.L = L; + ms.src_init = src; + ms.src_end = src+srcl; + while (n < max_s) { + const char *e; + ms.level = ms.depth = 0; + e = match(&ms, src, p); + if (e) { + n++; + add_value(&ms, &b, src, e); + } + if (e && e>src) /* non empty match? */ + src = e; /* skip it */ + else if (src < ms.src_end) + luaL_addchar(&b, *src++); + else + break; + if (anchor) + break; + } + luaL_addlstring(&b, src, (size_t)(ms.src_end-src)); + luaL_pushresult(&b); + lua_pushinteger(L, n); /* number of substitutions */ + return 2; +} + +/* ------------------------------------------------------------------------ */ + +LJLIB_CF(string_format) LJLIB_REC(.) +{ + int retry = 0; + SBuf *sb; + do { + sb = lj_buf_tmp_(L); + retry = lj_strfmt_putarg(L, sb, 1, -retry); + } while (retry > 0); + setstrV(L, L->top-1, lj_buf_str(L, sb)); + lj_gc_check(L); + return 1; +} + +/* ------------------------------------------------------------------------ */ + +#include "lj_libdef.h" + +LUALIB_API int luaopen_string(lua_State *L) +{ + GCtab *mt; + global_State *g; + LJ_LIB_REG(L, LUA_STRLIBNAME, string); + mt = lj_tab_new(L, 0, 1); + /* NOBARRIER: basemt is a GC root. */ + g = G(L); + setgcref(basemt_it(g, LJ_TSTR), obj2gco(mt)); + settabV(L, lj_tab_setstr(L, mt, mmname_str(g, MM_index)), tabV(L->top-1)); + mt->nomm = (uint8_t)(~(1u<top-1)); +#endif + return 1; +} + diff --git a/fluent-bit/lib/luajit-3065c9/src/lib_table.c b/fluent-bit/lib/luajit-3065c9/src/lib_table.c new file mode 100644 index 00000000..a723326a --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lib_table.c @@ -0,0 +1,327 @@ +/* +** Table library. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +** +** Major portions taken verbatim or adapted from the Lua interpreter. +** Copyright (C) 1994-2008 Lua.org, PUC-Rio. See Copyright Notice in lua.h +*/ + +#define lib_table_c +#define LUA_LIB + +#include "lua.h" +#include "lauxlib.h" +#include "lualib.h" + +#include "lj_obj.h" +#include "lj_gc.h" +#include "lj_err.h" +#include "lj_buf.h" +#include "lj_tab.h" +#include "lj_ff.h" +#include "lj_lib.h" + +/* ------------------------------------------------------------------------ */ + +#define LJLIB_MODULE_table + +LJLIB_LUA(table_foreachi) /* + function(t, f) + CHECK_tab(t) + CHECK_func(f) + for i=1,#t do + local r = f(i, t[i]) + if r ~= nil then return r end + end + end +*/ + +LJLIB_LUA(table_foreach) /* + function(t, f) + CHECK_tab(t) + CHECK_func(f) + for k, v in PAIRS(t) do + local r = f(k, v) + if r ~= nil then return r end + end + end +*/ + +LJLIB_LUA(table_getn) /* + function(t) + CHECK_tab(t) + return #t + end +*/ + +LJLIB_CF(table_maxn) +{ + GCtab *t = lj_lib_checktab(L, 1); + TValue *array = tvref(t->array); + Node *node; + lua_Number m = 0; + ptrdiff_t i; + for (i = (ptrdiff_t)t->asize - 1; i >= 0; i--) + if (!tvisnil(&array[i])) { + m = (lua_Number)(int32_t)i; + break; + } + node = noderef(t->node); + for (i = (ptrdiff_t)t->hmask; i >= 0; i--) + if (!tvisnil(&node[i].val) && tvisnumber(&node[i].key)) { + lua_Number n = numberVnum(&node[i].key); + if (n > m) m = n; + } + setnumV(L->top-1, m); + return 1; +} + +LJLIB_CF(table_insert) LJLIB_REC(.) +{ + GCtab *t = lj_lib_checktab(L, 1); + int32_t n, i = (int32_t)lj_tab_len(t) + 1; + int nargs = (int)((char *)L->top - (char *)L->base); + if (nargs != 2*sizeof(TValue)) { + if (nargs != 3*sizeof(TValue)) + lj_err_caller(L, LJ_ERR_TABINS); + /* NOBARRIER: This just moves existing elements around. */ + for (n = lj_lib_checkint(L, 2); i > n; i--) { + /* The set may invalidate the get pointer, so need to do it first! */ + TValue *dst = lj_tab_setint(L, t, i); + cTValue *src = lj_tab_getint(t, i-1); + if (src) { + copyTV(L, dst, src); + } else { + setnilV(dst); + } + } + i = n; + } + { + TValue *dst = lj_tab_setint(L, t, i); + copyTV(L, dst, L->top-1); /* Set new value. */ + lj_gc_barriert(L, t, dst); + } + return 0; +} + +LJLIB_LUA(table_remove) /* + function(t, pos) + CHECK_tab(t) + local len = #t + if pos == nil then + if len ~= 0 then + local old = t[len] + t[len] = nil + return old + end + else + CHECK_int(pos) + if pos >= 1 and pos <= len then + local old = t[pos] + for i=pos+1,len do + t[i-1] = t[i] + end + t[len] = nil + return old + end + end + end +*/ + +LJLIB_LUA(table_move) /* + function(a1, f, e, t, a2) + CHECK_tab(a1) + CHECK_int(f) + CHECK_int(e) + CHECK_int(t) + if a2 == nil then a2 = a1 end + CHECK_tab(a2) + if e >= f then + local d = t - f + if t > e or t <= f or a2 ~= a1 then + for i=f,e do a2[i+d] = a1[i] end + else + for i=e,f,-1 do a2[i+d] = a1[i] end + end + end + return a2 + end +*/ + +LJLIB_CF(table_concat) LJLIB_REC(.) +{ + GCtab *t = lj_lib_checktab(L, 1); + GCstr *sep = lj_lib_optstr(L, 2); + int32_t i = lj_lib_optint(L, 3, 1); + int32_t e = (L->base+3 < L->top && !tvisnil(L->base+3)) ? + lj_lib_checkint(L, 4) : (int32_t)lj_tab_len(t); + SBuf *sb = lj_buf_tmp_(L); + SBuf *sbx = lj_buf_puttab(sb, t, sep, i, e); + if (LJ_UNLIKELY(!sbx)) { /* Error: bad element type. */ + int32_t idx = (int32_t)(intptr_t)sb->w; + cTValue *o = lj_tab_getint(t, idx); + lj_err_callerv(L, LJ_ERR_TABCAT, + lj_obj_itypename[o ? itypemap(o) : ~LJ_TNIL], idx); + } + setstrV(L, L->top-1, lj_buf_str(L, sbx)); + lj_gc_check(L); + return 1; +} + +/* ------------------------------------------------------------------------ */ + +static void set2(lua_State *L, int i, int j) +{ + lua_rawseti(L, 1, i); + lua_rawseti(L, 1, j); +} + +static int sort_comp(lua_State *L, int a, int b) +{ + if (!lua_isnil(L, 2)) { /* function? */ + int res; + lua_pushvalue(L, 2); + lua_pushvalue(L, a-1); /* -1 to compensate function */ + lua_pushvalue(L, b-2); /* -2 to compensate function and `a' */ + lua_call(L, 2, 1); + res = lua_toboolean(L, -1); + lua_pop(L, 1); + return res; + } else { /* a < b? */ + return lua_lessthan(L, a, b); + } +} + +static void auxsort(lua_State *L, int l, int u) +{ + while (l < u) { /* for tail recursion */ + int i, j; + /* sort elements a[l], a[(l+u)/2] and a[u] */ + lua_rawgeti(L, 1, l); + lua_rawgeti(L, 1, u); + if (sort_comp(L, -1, -2)) /* a[u] < a[l]? */ + set2(L, l, u); /* swap a[l] - a[u] */ + else + lua_pop(L, 2); + if (u-l == 1) break; /* only 2 elements */ + i = (l+u)/2; + lua_rawgeti(L, 1, i); + lua_rawgeti(L, 1, l); + if (sort_comp(L, -2, -1)) { /* a[i]= P */ + while (lua_rawgeti(L, 1, ++i), sort_comp(L, -1, -2)) { + if (i>=u) lj_err_caller(L, LJ_ERR_TABSORT); + lua_pop(L, 1); /* remove a[i] */ + } + /* repeat --j until a[j] <= P */ + while (lua_rawgeti(L, 1, --j), sort_comp(L, -3, -1)) { + if (j<=l) lj_err_caller(L, LJ_ERR_TABSORT); + lua_pop(L, 1); /* remove a[j] */ + } + if (jbase+1)) + lj_lib_checkfunc(L, 2); + auxsort(L, 1, n); + return 0; +} + +#if LJ_52 +LJLIB_PUSH("n") +LJLIB_CF(table_pack) +{ + TValue *array, *base = L->base; + MSize i, n = (uint32_t)(L->top - base); + GCtab *t = lj_tab_new(L, n ? n+1 : 0, 1); + /* NOBARRIER: The table is new (marked white). */ + setintV(lj_tab_setstr(L, t, strV(lj_lib_upvalue(L, 1))), (int32_t)n); + for (array = tvref(t->array) + 1, i = 0; i < n; i++) + copyTV(L, &array[i], &base[i]); + settabV(L, base, t); + L->top = base+1; + lj_gc_check(L); + return 1; +} +#endif + +LJLIB_NOREG LJLIB_CF(table_new) LJLIB_REC(.) +{ + int32_t a = lj_lib_checkint(L, 1); + int32_t h = lj_lib_checkint(L, 2); + lua_createtable(L, a, h); + return 1; +} + +LJLIB_NOREG LJLIB_CF(table_clear) LJLIB_REC(.) +{ + lj_tab_clear(lj_lib_checktab(L, 1)); + return 0; +} + +static int luaopen_table_new(lua_State *L) +{ + return lj_lib_postreg(L, lj_cf_table_new, FF_table_new, "new"); +} + +static int luaopen_table_clear(lua_State *L) +{ + return lj_lib_postreg(L, lj_cf_table_clear, FF_table_clear, "clear"); +} + +/* ------------------------------------------------------------------------ */ + +#include "lj_libdef.h" + +LUALIB_API int luaopen_table(lua_State *L) +{ + LJ_LIB_REG(L, LUA_TABLIBNAME, table); +#if LJ_52 + lua_getglobal(L, "unpack"); + lua_setfield(L, -2, "unpack"); +#endif + lj_lib_prereg(L, LUA_TABLIBNAME ".new", luaopen_table_new, tabV(L->top-1)); + lj_lib_prereg(L, LUA_TABLIBNAME ".clear", luaopen_table_clear, tabV(L->top-1)); + return 1; +} + diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_alloc.c b/fluent-bit/lib/luajit-3065c9/src/lj_alloc.c new file mode 100644 index 00000000..20e60493 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_alloc.c @@ -0,0 +1,1485 @@ +/* +** Bundled memory allocator. +** +** Beware: this is a HEAVILY CUSTOMIZED version of dlmalloc. +** The original bears the following remark: +** +** This is a version (aka dlmalloc) of malloc/free/realloc written by +** Doug Lea and released to the public domain, as explained at +** https://creativecommons.org/licenses/publicdomain. +** +** * Version pre-2.8.4 Wed Mar 29 19:46:29 2006 (dl at gee) +** +** No additional copyright is claimed over the customizations. +** Please do NOT bother the original author about this version here! +** +** If you want to use dlmalloc in another project, you should get +** the original from: ftp://gee.cs.oswego.edu/pub/misc/ +** For thread-safe derivatives, take a look at: +** - ptmalloc: https://www.malloc.de/ +** - nedmalloc: https://www.nedprod.com/programs/portable/nedmalloc/ +*/ + +#define lj_alloc_c +#define LUA_CORE + +/* To get the mremap prototype. Must be defined before any system includes. */ +#if defined(__linux__) && !defined(_GNU_SOURCE) +#define _GNU_SOURCE +#endif + +#include "lj_def.h" +#include "lj_arch.h" +#include "lj_alloc.h" +#include "lj_prng.h" + +#ifndef LUAJIT_USE_SYSMALLOC + +#define MAX_SIZE_T (~(size_t)0) +#define MALLOC_ALIGNMENT ((size_t)8U) + +#define DEFAULT_GRANULARITY ((size_t)128U * (size_t)1024U) +#define DEFAULT_TRIM_THRESHOLD ((size_t)2U * (size_t)1024U * (size_t)1024U) +#define DEFAULT_MMAP_THRESHOLD ((size_t)128U * (size_t)1024U) +#define MAX_RELEASE_CHECK_RATE 255 + +/* ------------------- size_t and alignment properties -------------------- */ + +/* The byte and bit size of a size_t */ +#define SIZE_T_SIZE (sizeof(size_t)) +#define SIZE_T_BITSIZE (sizeof(size_t) << 3) + +/* Some constants coerced to size_t */ +/* Annoying but necessary to avoid errors on some platforms */ +#define SIZE_T_ZERO ((size_t)0) +#define SIZE_T_ONE ((size_t)1) +#define SIZE_T_TWO ((size_t)2) +#define TWO_SIZE_T_SIZES (SIZE_T_SIZE<<1) +#define FOUR_SIZE_T_SIZES (SIZE_T_SIZE<<2) +#define SIX_SIZE_T_SIZES (FOUR_SIZE_T_SIZES+TWO_SIZE_T_SIZES) + +/* The bit mask value corresponding to MALLOC_ALIGNMENT */ +#define CHUNK_ALIGN_MASK (MALLOC_ALIGNMENT - SIZE_T_ONE) + +/* the number of bytes to offset an address to align it */ +#define align_offset(A)\ + ((((size_t)(A) & CHUNK_ALIGN_MASK) == 0)? 0 :\ + ((MALLOC_ALIGNMENT - ((size_t)(A) & CHUNK_ALIGN_MASK)) & CHUNK_ALIGN_MASK)) + +/* -------------------------- MMAP support ------------------------------- */ + +#define MFAIL ((void *)(MAX_SIZE_T)) +#define CMFAIL ((char *)(MFAIL)) /* defined for convenience */ + +#define IS_DIRECT_BIT (SIZE_T_ONE) + + +/* Determine system-specific block allocation method. */ +#if LJ_TARGET_WINDOWS + +#define WIN32_LEAN_AND_MEAN +#include + +#define LJ_ALLOC_VIRTUALALLOC 1 + +#if LJ_64 && !LJ_GC64 +#define LJ_ALLOC_NTAVM 1 +#endif + +#else + +#include +/* If this include fails, then rebuild with: -DLUAJIT_USE_SYSMALLOC */ +#include + +#define LJ_ALLOC_MMAP 1 + +#if LJ_64 + +#define LJ_ALLOC_MMAP_PROBE 1 + +#if LJ_GC64 +#define LJ_ALLOC_MBITS 47 /* 128 TB in LJ_GC64 mode. */ +#elif LJ_TARGET_X64 && LJ_HASJIT +/* Due to limitations in the x64 compiler backend. */ +#define LJ_ALLOC_MBITS 31 /* 2 GB on x64 with !LJ_GC64. */ +#else +#define LJ_ALLOC_MBITS 32 /* 4 GB on other archs with !LJ_GC64. */ +#endif + +#endif + +#if LJ_64 && !LJ_GC64 && defined(MAP_32BIT) +#define LJ_ALLOC_MMAP32 1 +#endif + +#if LJ_TARGET_LINUX +#define LJ_ALLOC_MREMAP 1 +#endif + +#endif + + +#if LJ_ALLOC_VIRTUALALLOC + +#if LJ_ALLOC_NTAVM +/* Undocumented, but hey, that's what we all love so much about Windows. */ +typedef long (*PNTAVM)(HANDLE handle, void **addr, ULONG_PTR zbits, + size_t *size, ULONG alloctype, ULONG prot); +static PNTAVM ntavm; + +/* Number of top bits of the lower 32 bits of an address that must be zero. +** Apparently 0 gives us full 64 bit addresses and 1 gives us the lower 2GB. +*/ +#define NTAVM_ZEROBITS 1 + +static void init_mmap(void) +{ + ntavm = (PNTAVM)GetProcAddress(GetModuleHandleA("ntdll.dll"), + "NtAllocateVirtualMemory"); +} +#define INIT_MMAP() init_mmap() + +/* Win64 32 bit MMAP via NtAllocateVirtualMemory. */ +static void *mmap_plain(size_t size) +{ + DWORD olderr = GetLastError(); + void *ptr = NULL; + long st = ntavm(INVALID_HANDLE_VALUE, &ptr, NTAVM_ZEROBITS, &size, + MEM_RESERVE|MEM_COMMIT, PAGE_READWRITE); + SetLastError(olderr); + return st == 0 ? ptr : MFAIL; +} + +/* For direct MMAP, use MEM_TOP_DOWN to minimize interference */ +static void *direct_mmap(size_t size) +{ + DWORD olderr = GetLastError(); + void *ptr = NULL; + long st = ntavm(INVALID_HANDLE_VALUE, &ptr, NTAVM_ZEROBITS, &size, + MEM_RESERVE|MEM_COMMIT|MEM_TOP_DOWN, PAGE_READWRITE); + SetLastError(olderr); + return st == 0 ? ptr : MFAIL; +} + +#else + +/* Win32 MMAP via VirtualAlloc */ +static void *mmap_plain(size_t size) +{ + DWORD olderr = GetLastError(); + void *ptr = LJ_WIN_VALLOC(0, size, MEM_RESERVE|MEM_COMMIT, PAGE_READWRITE); + SetLastError(olderr); + return ptr ? ptr : MFAIL; +} + +/* For direct MMAP, use MEM_TOP_DOWN to minimize interference */ +static void *direct_mmap(size_t size) +{ + DWORD olderr = GetLastError(); + void *ptr = LJ_WIN_VALLOC(0, size, MEM_RESERVE|MEM_COMMIT|MEM_TOP_DOWN, + PAGE_READWRITE); + SetLastError(olderr); + return ptr ? ptr : MFAIL; +} + +#endif + +#define CALL_MMAP(prng, size) mmap_plain(size) +#define DIRECT_MMAP(prng, size) direct_mmap(size) + +/* This function supports releasing coalesed segments */ +static int CALL_MUNMAP(void *ptr, size_t size) +{ + DWORD olderr = GetLastError(); + MEMORY_BASIC_INFORMATION minfo; + char *cptr = (char *)ptr; + while (size) { + if (VirtualQuery(cptr, &minfo, sizeof(minfo)) == 0) + return -1; + if (minfo.BaseAddress != cptr || minfo.AllocationBase != cptr || + minfo.State != MEM_COMMIT || minfo.RegionSize > size) + return -1; + if (VirtualFree(cptr, 0, MEM_RELEASE) == 0) + return -1; + cptr += minfo.RegionSize; + size -= minfo.RegionSize; + } + SetLastError(olderr); + return 0; +} + +#elif LJ_ALLOC_MMAP + +#define MMAP_PROT (PROT_READ|PROT_WRITE) +#if !defined(MAP_ANONYMOUS) && defined(MAP_ANON) +#define MAP_ANONYMOUS MAP_ANON +#endif +#define MMAP_FLAGS (MAP_PRIVATE|MAP_ANONYMOUS) + +#if LJ_ALLOC_MMAP_PROBE + +#ifdef MAP_TRYFIXED +#define MMAP_FLAGS_PROBE (MMAP_FLAGS|MAP_TRYFIXED) +#else +#define MMAP_FLAGS_PROBE MMAP_FLAGS +#endif + +#define LJ_ALLOC_MMAP_PROBE_MAX 30 +#define LJ_ALLOC_MMAP_PROBE_LINEAR 5 + +#define LJ_ALLOC_MMAP_PROBE_LOWER ((uintptr_t)0x4000) + +static void *mmap_probe(PRNGState *rs, size_t size) +{ + /* Hint for next allocation. Doesn't need to be thread-safe. */ + static uintptr_t hint_addr = 0; + int olderr = errno; + int retry; + for (retry = 0; retry < LJ_ALLOC_MMAP_PROBE_MAX; retry++) { + void *p = mmap((void *)hint_addr, size, MMAP_PROT, MMAP_FLAGS_PROBE, -1, 0); + uintptr_t addr = (uintptr_t)p; + if ((addr >> LJ_ALLOC_MBITS) == 0 && addr >= LJ_ALLOC_MMAP_PROBE_LOWER && + ((addr + size) >> LJ_ALLOC_MBITS) == 0) { + /* We got a suitable address. Bump the hint address. */ + hint_addr = addr + size; + errno = olderr; + return p; + } + if (p != MFAIL) { + munmap(p, size); + } else if (errno == ENOMEM) { + return MFAIL; + } + if (hint_addr) { + /* First, try linear probing. */ + if (retry < LJ_ALLOC_MMAP_PROBE_LINEAR) { + hint_addr += 0x1000000; + if (((hint_addr + size) >> LJ_ALLOC_MBITS) != 0) + hint_addr = 0; + continue; + } else if (retry == LJ_ALLOC_MMAP_PROBE_LINEAR) { + /* Next, try a no-hint probe to get back an ASLR address. */ + hint_addr = 0; + continue; + } + } + /* Finally, try pseudo-random probing. */ + do { + hint_addr = lj_prng_u64(rs) & (((uintptr_t)1< + +static void init_mmap(void) +{ + struct rlimit rlim; + rlim.rlim_cur = rlim.rlim_max = 0x10000; + setrlimit(RLIMIT_DATA, &rlim); /* Ignore result. May fail later. */ +} +#define INIT_MMAP() init_mmap() + +#endif + +static int CALL_MUNMAP(void *ptr, size_t size) +{ + int olderr = errno; + int ret = munmap(ptr, size); + errno = olderr; + return ret; +} + +#if LJ_ALLOC_MREMAP +/* Need to define _GNU_SOURCE to get the mremap prototype. */ +static void *CALL_MREMAP_(void *ptr, size_t osz, size_t nsz, int flags) +{ + int olderr = errno; + ptr = mremap(ptr, osz, nsz, flags); + errno = olderr; + return ptr; +} + +#define CALL_MREMAP(addr, osz, nsz, mv) CALL_MREMAP_((addr), (osz), (nsz), (mv)) +#define CALL_MREMAP_NOMOVE 0 +#define CALL_MREMAP_MAYMOVE 1 +#if LJ_64 && (!LJ_GC64 || LJ_TARGET_ARM64) +#define CALL_MREMAP_MV CALL_MREMAP_NOMOVE +#else +#define CALL_MREMAP_MV CALL_MREMAP_MAYMOVE +#endif +#endif + +#endif + + +#ifndef INIT_MMAP +#define INIT_MMAP() ((void)0) +#endif + +#ifndef DIRECT_MMAP +#define DIRECT_MMAP(prng, s) CALL_MMAP(prng, s) +#endif + +#ifndef CALL_MREMAP +#define CALL_MREMAP(addr, osz, nsz, mv) ((void)osz, MFAIL) +#endif + +/* ----------------------- Chunk representations ------------------------ */ + +struct malloc_chunk { + size_t prev_foot; /* Size of previous chunk (if free). */ + size_t head; /* Size and inuse bits. */ + struct malloc_chunk *fd; /* double links -- used only if free. */ + struct malloc_chunk *bk; +}; + +typedef struct malloc_chunk mchunk; +typedef struct malloc_chunk *mchunkptr; +typedef struct malloc_chunk *sbinptr; /* The type of bins of chunks */ +typedef size_t bindex_t; /* Described below */ +typedef unsigned int binmap_t; /* Described below */ +typedef unsigned int flag_t; /* The type of various bit flag sets */ + +/* ------------------- Chunks sizes and alignments ----------------------- */ + +#define MCHUNK_SIZE (sizeof(mchunk)) + +#define CHUNK_OVERHEAD (SIZE_T_SIZE) + +/* Direct chunks need a second word of overhead ... */ +#define DIRECT_CHUNK_OVERHEAD (TWO_SIZE_T_SIZES) +/* ... and additional padding for fake next-chunk at foot */ +#define DIRECT_FOOT_PAD (FOUR_SIZE_T_SIZES) + +/* The smallest size we can malloc is an aligned minimal chunk */ +#define MIN_CHUNK_SIZE\ + ((MCHUNK_SIZE + CHUNK_ALIGN_MASK) & ~CHUNK_ALIGN_MASK) + +/* conversion from malloc headers to user pointers, and back */ +#define chunk2mem(p) ((void *)((char *)(p) + TWO_SIZE_T_SIZES)) +#define mem2chunk(mem) ((mchunkptr)((char *)(mem) - TWO_SIZE_T_SIZES)) +/* chunk associated with aligned address A */ +#define align_as_chunk(A) (mchunkptr)((A) + align_offset(chunk2mem(A))) + +/* Bounds on request (not chunk) sizes. */ +#define MAX_REQUEST ((~MIN_CHUNK_SIZE+1) << 2) +#define MIN_REQUEST (MIN_CHUNK_SIZE - CHUNK_OVERHEAD - SIZE_T_ONE) + +/* pad request bytes into a usable size */ +#define pad_request(req) \ + (((req) + CHUNK_OVERHEAD + CHUNK_ALIGN_MASK) & ~CHUNK_ALIGN_MASK) + +/* pad request, checking for minimum (but not maximum) */ +#define request2size(req) \ + (((req) < MIN_REQUEST)? MIN_CHUNK_SIZE : pad_request(req)) + +/* ------------------ Operations on head and foot fields ----------------- */ + +#define PINUSE_BIT (SIZE_T_ONE) +#define CINUSE_BIT (SIZE_T_TWO) +#define INUSE_BITS (PINUSE_BIT|CINUSE_BIT) + +/* Head value for fenceposts */ +#define FENCEPOST_HEAD (INUSE_BITS|SIZE_T_SIZE) + +/* extraction of fields from head words */ +#define cinuse(p) ((p)->head & CINUSE_BIT) +#define pinuse(p) ((p)->head & PINUSE_BIT) +#define chunksize(p) ((p)->head & ~(INUSE_BITS)) + +#define clear_pinuse(p) ((p)->head &= ~PINUSE_BIT) +#define clear_cinuse(p) ((p)->head &= ~CINUSE_BIT) + +/* Treat space at ptr +/- offset as a chunk */ +#define chunk_plus_offset(p, s) ((mchunkptr)(((char *)(p)) + (s))) +#define chunk_minus_offset(p, s) ((mchunkptr)(((char *)(p)) - (s))) + +/* Ptr to next or previous physical malloc_chunk. */ +#define next_chunk(p) ((mchunkptr)(((char *)(p)) + ((p)->head & ~INUSE_BITS))) +#define prev_chunk(p) ((mchunkptr)(((char *)(p)) - ((p)->prev_foot) )) + +/* extract next chunk's pinuse bit */ +#define next_pinuse(p) ((next_chunk(p)->head) & PINUSE_BIT) + +/* Get/set size at footer */ +#define get_foot(p, s) (((mchunkptr)((char *)(p) + (s)))->prev_foot) +#define set_foot(p, s) (((mchunkptr)((char *)(p) + (s)))->prev_foot = (s)) + +/* Set size, pinuse bit, and foot */ +#define set_size_and_pinuse_of_free_chunk(p, s)\ + ((p)->head = (s|PINUSE_BIT), set_foot(p, s)) + +/* Set size, pinuse bit, foot, and clear next pinuse */ +#define set_free_with_pinuse(p, s, n)\ + (clear_pinuse(n), set_size_and_pinuse_of_free_chunk(p, s)) + +#define is_direct(p)\ + (!((p)->head & PINUSE_BIT) && ((p)->prev_foot & IS_DIRECT_BIT)) + +/* Get the internal overhead associated with chunk p */ +#define overhead_for(p)\ + (is_direct(p)? DIRECT_CHUNK_OVERHEAD : CHUNK_OVERHEAD) + +/* ---------------------- Overlaid data structures ----------------------- */ + +struct malloc_tree_chunk { + /* The first four fields must be compatible with malloc_chunk */ + size_t prev_foot; + size_t head; + struct malloc_tree_chunk *fd; + struct malloc_tree_chunk *bk; + + struct malloc_tree_chunk *child[2]; + struct malloc_tree_chunk *parent; + bindex_t index; +}; + +typedef struct malloc_tree_chunk tchunk; +typedef struct malloc_tree_chunk *tchunkptr; +typedef struct malloc_tree_chunk *tbinptr; /* The type of bins of trees */ + +/* A little helper macro for trees */ +#define leftmost_child(t) ((t)->child[0] != 0? (t)->child[0] : (t)->child[1]) + +/* ----------------------------- Segments -------------------------------- */ + +struct malloc_segment { + char *base; /* base address */ + size_t size; /* allocated size */ + struct malloc_segment *next; /* ptr to next segment */ +}; + +typedef struct malloc_segment msegment; +typedef struct malloc_segment *msegmentptr; + +/* ---------------------------- malloc_state ----------------------------- */ + +/* Bin types, widths and sizes */ +#define NSMALLBINS (32U) +#define NTREEBINS (32U) +#define SMALLBIN_SHIFT (3U) +#define SMALLBIN_WIDTH (SIZE_T_ONE << SMALLBIN_SHIFT) +#define TREEBIN_SHIFT (8U) +#define MIN_LARGE_SIZE (SIZE_T_ONE << TREEBIN_SHIFT) +#define MAX_SMALL_SIZE (MIN_LARGE_SIZE - SIZE_T_ONE) +#define MAX_SMALL_REQUEST (MAX_SMALL_SIZE - CHUNK_ALIGN_MASK - CHUNK_OVERHEAD) + +struct malloc_state { + binmap_t smallmap; + binmap_t treemap; + size_t dvsize; + size_t topsize; + mchunkptr dv; + mchunkptr top; + size_t trim_check; + size_t release_checks; + mchunkptr smallbins[(NSMALLBINS+1)*2]; + tbinptr treebins[NTREEBINS]; + msegment seg; + PRNGState *prng; +}; + +typedef struct malloc_state *mstate; + +#define is_initialized(M) ((M)->top != 0) + +/* -------------------------- system alloc setup ------------------------- */ + +/* page-align a size */ +#define page_align(S)\ + (((S) + (LJ_PAGESIZE - SIZE_T_ONE)) & ~(LJ_PAGESIZE - SIZE_T_ONE)) + +/* granularity-align a size */ +#define granularity_align(S)\ + (((S) + (DEFAULT_GRANULARITY - SIZE_T_ONE))\ + & ~(DEFAULT_GRANULARITY - SIZE_T_ONE)) + +#if LJ_TARGET_WINDOWS +#define mmap_align(S) granularity_align(S) +#else +#define mmap_align(S) page_align(S) +#endif + +/* True if segment S holds address A */ +#define segment_holds(S, A)\ + ((char *)(A) >= S->base && (char *)(A) < S->base + S->size) + +/* Return segment holding given address */ +static msegmentptr segment_holding(mstate m, char *addr) +{ + msegmentptr sp = &m->seg; + for (;;) { + if (addr >= sp->base && addr < sp->base + sp->size) + return sp; + if ((sp = sp->next) == 0) + return 0; + } +} + +/* Return true if segment contains a segment link */ +static int has_segment_link(mstate m, msegmentptr ss) +{ + msegmentptr sp = &m->seg; + for (;;) { + if ((char *)sp >= ss->base && (char *)sp < ss->base + ss->size) + return 1; + if ((sp = sp->next) == 0) + return 0; + } +} + +/* + TOP_FOOT_SIZE is padding at the end of a segment, including space + that may be needed to place segment records and fenceposts when new + noncontiguous segments are added. +*/ +#define TOP_FOOT_SIZE\ + (align_offset(TWO_SIZE_T_SIZES)+pad_request(sizeof(struct malloc_segment))+MIN_CHUNK_SIZE) + +/* ---------------------------- Indexing Bins ---------------------------- */ + +#define is_small(s) (((s) >> SMALLBIN_SHIFT) < NSMALLBINS) +#define small_index(s) ((s) >> SMALLBIN_SHIFT) +#define small_index2size(i) ((i) << SMALLBIN_SHIFT) +#define MIN_SMALL_INDEX (small_index(MIN_CHUNK_SIZE)) + +/* addressing by index. See above about smallbin repositioning */ +#define smallbin_at(M, i) ((sbinptr)((char *)&((M)->smallbins[(i)<<1]))) +#define treebin_at(M,i) (&((M)->treebins[i])) + +/* assign tree index for size S to variable I */ +#define compute_tree_index(S, I)\ +{\ + unsigned int X = (unsigned int)(S >> TREEBIN_SHIFT);\ + if (X == 0) {\ + I = 0;\ + } else if (X > 0xFFFF) {\ + I = NTREEBINS-1;\ + } else {\ + unsigned int K = lj_fls(X);\ + I = (bindex_t)((K << 1) + ((S >> (K + (TREEBIN_SHIFT-1)) & 1)));\ + }\ +} + +/* Bit representing maximum resolved size in a treebin at i */ +#define bit_for_tree_index(i) \ + (i == NTREEBINS-1)? (SIZE_T_BITSIZE-1) : (((i) >> 1) + TREEBIN_SHIFT - 2) + +/* Shift placing maximum resolved bit in a treebin at i as sign bit */ +#define leftshift_for_tree_index(i) \ + ((i == NTREEBINS-1)? 0 : \ + ((SIZE_T_BITSIZE-SIZE_T_ONE) - (((i) >> 1) + TREEBIN_SHIFT - 2))) + +/* The size of the smallest chunk held in bin with index i */ +#define minsize_for_tree_index(i) \ + ((SIZE_T_ONE << (((i) >> 1) + TREEBIN_SHIFT)) | \ + (((size_t)((i) & SIZE_T_ONE)) << (((i) >> 1) + TREEBIN_SHIFT - 1))) + +/* ------------------------ Operations on bin maps ----------------------- */ + +/* bit corresponding to given index */ +#define idx2bit(i) ((binmap_t)(1) << (i)) + +/* Mark/Clear bits with given index */ +#define mark_smallmap(M,i) ((M)->smallmap |= idx2bit(i)) +#define clear_smallmap(M,i) ((M)->smallmap &= ~idx2bit(i)) +#define smallmap_is_marked(M,i) ((M)->smallmap & idx2bit(i)) + +#define mark_treemap(M,i) ((M)->treemap |= idx2bit(i)) +#define clear_treemap(M,i) ((M)->treemap &= ~idx2bit(i)) +#define treemap_is_marked(M,i) ((M)->treemap & idx2bit(i)) + +/* mask with all bits to left of least bit of x on */ +#define left_bits(x) ((x<<1) | (~(x<<1)+1)) + +/* Set cinuse bit and pinuse bit of next chunk */ +#define set_inuse(M,p,s)\ + ((p)->head = (((p)->head & PINUSE_BIT)|s|CINUSE_BIT),\ + ((mchunkptr)(((char *)(p)) + (s)))->head |= PINUSE_BIT) + +/* Set cinuse and pinuse of this chunk and pinuse of next chunk */ +#define set_inuse_and_pinuse(M,p,s)\ + ((p)->head = (s|PINUSE_BIT|CINUSE_BIT),\ + ((mchunkptr)(((char *)(p)) + (s)))->head |= PINUSE_BIT) + +/* Set size, cinuse and pinuse bit of this chunk */ +#define set_size_and_pinuse_of_inuse_chunk(M, p, s)\ + ((p)->head = (s|PINUSE_BIT|CINUSE_BIT)) + +/* ----------------------- Operations on smallbins ----------------------- */ + +/* Link a free chunk into a smallbin */ +#define insert_small_chunk(M, P, S) {\ + bindex_t I = small_index(S);\ + mchunkptr B = smallbin_at(M, I);\ + mchunkptr F = B;\ + if (!smallmap_is_marked(M, I))\ + mark_smallmap(M, I);\ + else\ + F = B->fd;\ + B->fd = P;\ + F->bk = P;\ + P->fd = F;\ + P->bk = B;\ +} + +/* Unlink a chunk from a smallbin */ +#define unlink_small_chunk(M, P, S) {\ + mchunkptr F = P->fd;\ + mchunkptr B = P->bk;\ + bindex_t I = small_index(S);\ + if (F == B) {\ + clear_smallmap(M, I);\ + } else {\ + F->bk = B;\ + B->fd = F;\ + }\ +} + +/* Unlink the first chunk from a smallbin */ +#define unlink_first_small_chunk(M, B, P, I) {\ + mchunkptr F = P->fd;\ + if (B == F) {\ + clear_smallmap(M, I);\ + } else {\ + B->fd = F;\ + F->bk = B;\ + }\ +} + +/* Replace dv node, binning the old one */ +/* Used only when dvsize known to be small */ +#define replace_dv(M, P, S) {\ + size_t DVS = M->dvsize;\ + if (DVS != 0) {\ + mchunkptr DV = M->dv;\ + insert_small_chunk(M, DV, DVS);\ + }\ + M->dvsize = S;\ + M->dv = P;\ +} + +/* ------------------------- Operations on trees ------------------------- */ + +/* Insert chunk into tree */ +#define insert_large_chunk(M, X, S) {\ + tbinptr *H;\ + bindex_t I;\ + compute_tree_index(S, I);\ + H = treebin_at(M, I);\ + X->index = I;\ + X->child[0] = X->child[1] = 0;\ + if (!treemap_is_marked(M, I)) {\ + mark_treemap(M, I);\ + *H = X;\ + X->parent = (tchunkptr)H;\ + X->fd = X->bk = X;\ + } else {\ + tchunkptr T = *H;\ + size_t K = S << leftshift_for_tree_index(I);\ + for (;;) {\ + if (chunksize(T) != S) {\ + tchunkptr *C = &(T->child[(K >> (SIZE_T_BITSIZE-SIZE_T_ONE)) & 1]);\ + K <<= 1;\ + if (*C != 0) {\ + T = *C;\ + } else {\ + *C = X;\ + X->parent = T;\ + X->fd = X->bk = X;\ + break;\ + }\ + } else {\ + tchunkptr F = T->fd;\ + T->fd = F->bk = X;\ + X->fd = F;\ + X->bk = T;\ + X->parent = 0;\ + break;\ + }\ + }\ + }\ +} + +#define unlink_large_chunk(M, X) {\ + tchunkptr XP = X->parent;\ + tchunkptr R;\ + if (X->bk != X) {\ + tchunkptr F = X->fd;\ + R = X->bk;\ + F->bk = R;\ + R->fd = F;\ + } else {\ + tchunkptr *RP;\ + if (((R = *(RP = &(X->child[1]))) != 0) ||\ + ((R = *(RP = &(X->child[0]))) != 0)) {\ + tchunkptr *CP;\ + while ((*(CP = &(R->child[1])) != 0) ||\ + (*(CP = &(R->child[0])) != 0)) {\ + R = *(RP = CP);\ + }\ + *RP = 0;\ + }\ + }\ + if (XP != 0) {\ + tbinptr *H = treebin_at(M, X->index);\ + if (X == *H) {\ + if ((*H = R) == 0) \ + clear_treemap(M, X->index);\ + } else {\ + if (XP->child[0] == X) \ + XP->child[0] = R;\ + else \ + XP->child[1] = R;\ + }\ + if (R != 0) {\ + tchunkptr C0, C1;\ + R->parent = XP;\ + if ((C0 = X->child[0]) != 0) {\ + R->child[0] = C0;\ + C0->parent = R;\ + }\ + if ((C1 = X->child[1]) != 0) {\ + R->child[1] = C1;\ + C1->parent = R;\ + }\ + }\ + }\ +} + +/* Relays to large vs small bin operations */ + +#define insert_chunk(M, P, S)\ + if (is_small(S)) { insert_small_chunk(M, P, S)\ + } else { tchunkptr TP = (tchunkptr)(P); insert_large_chunk(M, TP, S); } + +#define unlink_chunk(M, P, S)\ + if (is_small(S)) { unlink_small_chunk(M, P, S)\ + } else { tchunkptr TP = (tchunkptr)(P); unlink_large_chunk(M, TP); } + +/* ----------------------- Direct-mmapping chunks ----------------------- */ + +static void *direct_alloc(mstate m, size_t nb) +{ + size_t mmsize = mmap_align(nb + SIX_SIZE_T_SIZES + CHUNK_ALIGN_MASK); + if (LJ_LIKELY(mmsize > nb)) { /* Check for wrap around 0 */ + char *mm = (char *)(DIRECT_MMAP(m->prng, mmsize)); + if (mm != CMFAIL) { + size_t offset = align_offset(chunk2mem(mm)); + size_t psize = mmsize - offset - DIRECT_FOOT_PAD; + mchunkptr p = (mchunkptr)(mm + offset); + p->prev_foot = offset | IS_DIRECT_BIT; + p->head = psize|CINUSE_BIT; + chunk_plus_offset(p, psize)->head = FENCEPOST_HEAD; + chunk_plus_offset(p, psize+SIZE_T_SIZE)->head = 0; + return chunk2mem(p); + } + } + UNUSED(m); + return NULL; +} + +static mchunkptr direct_resize(mchunkptr oldp, size_t nb) +{ + size_t oldsize = chunksize(oldp); + if (is_small(nb)) /* Can't shrink direct regions below small size */ + return NULL; + /* Keep old chunk if big enough but not too big */ + if (oldsize >= nb + SIZE_T_SIZE && + (oldsize - nb) <= (DEFAULT_GRANULARITY >> 1)) { + return oldp; + } else { + size_t offset = oldp->prev_foot & ~IS_DIRECT_BIT; + size_t oldmmsize = oldsize + offset + DIRECT_FOOT_PAD; + size_t newmmsize = mmap_align(nb + SIX_SIZE_T_SIZES + CHUNK_ALIGN_MASK); + char *cp = (char *)CALL_MREMAP((char *)oldp - offset, + oldmmsize, newmmsize, CALL_MREMAP_MV); + if (cp != CMFAIL) { + mchunkptr newp = (mchunkptr)(cp + offset); + size_t psize = newmmsize - offset - DIRECT_FOOT_PAD; + newp->head = psize|CINUSE_BIT; + chunk_plus_offset(newp, psize)->head = FENCEPOST_HEAD; + chunk_plus_offset(newp, psize+SIZE_T_SIZE)->head = 0; + return newp; + } + } + return NULL; +} + +/* -------------------------- mspace management -------------------------- */ + +/* Initialize top chunk and its size */ +static void init_top(mstate m, mchunkptr p, size_t psize) +{ + /* Ensure alignment */ + size_t offset = align_offset(chunk2mem(p)); + p = (mchunkptr)((char *)p + offset); + psize -= offset; + + m->top = p; + m->topsize = psize; + p->head = psize | PINUSE_BIT; + /* set size of fake trailing chunk holding overhead space only once */ + chunk_plus_offset(p, psize)->head = TOP_FOOT_SIZE; + m->trim_check = DEFAULT_TRIM_THRESHOLD; /* reset on each update */ +} + +/* Initialize bins for a new mstate that is otherwise zeroed out */ +static void init_bins(mstate m) +{ + /* Establish circular links for smallbins */ + bindex_t i; + for (i = 0; i < NSMALLBINS; i++) { + sbinptr bin = smallbin_at(m,i); + bin->fd = bin->bk = bin; + } +} + +/* Allocate chunk and prepend remainder with chunk in successor base. */ +static void *prepend_alloc(mstate m, char *newbase, char *oldbase, size_t nb) +{ + mchunkptr p = align_as_chunk(newbase); + mchunkptr oldfirst = align_as_chunk(oldbase); + size_t psize = (size_t)((char *)oldfirst - (char *)p); + mchunkptr q = chunk_plus_offset(p, nb); + size_t qsize = psize - nb; + set_size_and_pinuse_of_inuse_chunk(m, p, nb); + + /* consolidate remainder with first chunk of old base */ + if (oldfirst == m->top) { + size_t tsize = m->topsize += qsize; + m->top = q; + q->head = tsize | PINUSE_BIT; + } else if (oldfirst == m->dv) { + size_t dsize = m->dvsize += qsize; + m->dv = q; + set_size_and_pinuse_of_free_chunk(q, dsize); + } else { + if (!cinuse(oldfirst)) { + size_t nsize = chunksize(oldfirst); + unlink_chunk(m, oldfirst, nsize); + oldfirst = chunk_plus_offset(oldfirst, nsize); + qsize += nsize; + } + set_free_with_pinuse(q, qsize, oldfirst); + insert_chunk(m, q, qsize); + } + + return chunk2mem(p); +} + +/* Add a segment to hold a new noncontiguous region */ +static void add_segment(mstate m, char *tbase, size_t tsize) +{ + /* Determine locations and sizes of segment, fenceposts, old top */ + char *old_top = (char *)m->top; + msegmentptr oldsp = segment_holding(m, old_top); + char *old_end = oldsp->base + oldsp->size; + size_t ssize = pad_request(sizeof(struct malloc_segment)); + char *rawsp = old_end - (ssize + FOUR_SIZE_T_SIZES + CHUNK_ALIGN_MASK); + size_t offset = align_offset(chunk2mem(rawsp)); + char *asp = rawsp + offset; + char *csp = (asp < (old_top + MIN_CHUNK_SIZE))? old_top : asp; + mchunkptr sp = (mchunkptr)csp; + msegmentptr ss = (msegmentptr)(chunk2mem(sp)); + mchunkptr tnext = chunk_plus_offset(sp, ssize); + mchunkptr p = tnext; + + /* reset top to new space */ + init_top(m, (mchunkptr)tbase, tsize - TOP_FOOT_SIZE); + + /* Set up segment record */ + set_size_and_pinuse_of_inuse_chunk(m, sp, ssize); + *ss = m->seg; /* Push current record */ + m->seg.base = tbase; + m->seg.size = tsize; + m->seg.next = ss; + + /* Insert trailing fenceposts */ + for (;;) { + mchunkptr nextp = chunk_plus_offset(p, SIZE_T_SIZE); + p->head = FENCEPOST_HEAD; + if ((char *)(&(nextp->head)) < old_end) + p = nextp; + else + break; + } + + /* Insert the rest of old top into a bin as an ordinary free chunk */ + if (csp != old_top) { + mchunkptr q = (mchunkptr)old_top; + size_t psize = (size_t)(csp - old_top); + mchunkptr tn = chunk_plus_offset(q, psize); + set_free_with_pinuse(q, psize, tn); + insert_chunk(m, q, psize); + } +} + +/* -------------------------- System allocation -------------------------- */ + +static void *alloc_sys(mstate m, size_t nb) +{ + char *tbase = CMFAIL; + size_t tsize = 0; + + /* Directly map large chunks */ + if (LJ_UNLIKELY(nb >= DEFAULT_MMAP_THRESHOLD)) { + void *mem = direct_alloc(m, nb); + if (mem != 0) + return mem; + } + + { + size_t req = nb + TOP_FOOT_SIZE + SIZE_T_ONE; + size_t rsize = granularity_align(req); + if (LJ_LIKELY(rsize > nb)) { /* Fail if wraps around zero */ + char *mp = (char *)(CALL_MMAP(m->prng, rsize)); + if (mp != CMFAIL) { + tbase = mp; + tsize = rsize; + } + } + } + + if (tbase != CMFAIL) { + msegmentptr sp = &m->seg; + /* Try to merge with an existing segment */ + while (sp != 0 && tbase != sp->base + sp->size) + sp = sp->next; + if (sp != 0 && segment_holds(sp, m->top)) { /* append */ + sp->size += tsize; + init_top(m, m->top, m->topsize + tsize); + } else { + sp = &m->seg; + while (sp != 0 && sp->base != tbase + tsize) + sp = sp->next; + if (sp != 0) { + char *oldbase = sp->base; + sp->base = tbase; + sp->size += tsize; + return prepend_alloc(m, tbase, oldbase, nb); + } else { + add_segment(m, tbase, tsize); + } + } + + if (nb < m->topsize) { /* Allocate from new or extended top space */ + size_t rsize = m->topsize -= nb; + mchunkptr p = m->top; + mchunkptr r = m->top = chunk_plus_offset(p, nb); + r->head = rsize | PINUSE_BIT; + set_size_and_pinuse_of_inuse_chunk(m, p, nb); + return chunk2mem(p); + } + } + + return NULL; +} + +/* ----------------------- system deallocation -------------------------- */ + +/* Unmap and unlink any mmapped segments that don't contain used chunks */ +static size_t release_unused_segments(mstate m) +{ + size_t released = 0; + size_t nsegs = 0; + msegmentptr pred = &m->seg; + msegmentptr sp = pred->next; + while (sp != 0) { + char *base = sp->base; + size_t size = sp->size; + msegmentptr next = sp->next; + nsegs++; + { + mchunkptr p = align_as_chunk(base); + size_t psize = chunksize(p); + /* Can unmap if first chunk holds entire segment and not pinned */ + if (!cinuse(p) && (char *)p + psize >= base + size - TOP_FOOT_SIZE) { + tchunkptr tp = (tchunkptr)p; + if (p == m->dv) { + m->dv = 0; + m->dvsize = 0; + } else { + unlink_large_chunk(m, tp); + } + if (CALL_MUNMAP(base, size) == 0) { + released += size; + /* unlink obsoleted record */ + sp = pred; + sp->next = next; + } else { /* back out if cannot unmap */ + insert_large_chunk(m, tp, psize); + } + } + } + pred = sp; + sp = next; + } + /* Reset check counter */ + m->release_checks = nsegs > MAX_RELEASE_CHECK_RATE ? + nsegs : MAX_RELEASE_CHECK_RATE; + return released; +} + +static int alloc_trim(mstate m, size_t pad) +{ + size_t released = 0; + if (pad < MAX_REQUEST && is_initialized(m)) { + pad += TOP_FOOT_SIZE; /* ensure enough room for segment overhead */ + + if (m->topsize > pad) { + /* Shrink top space in granularity-size units, keeping at least one */ + size_t unit = DEFAULT_GRANULARITY; + size_t extra = ((m->topsize - pad + (unit - SIZE_T_ONE)) / unit - + SIZE_T_ONE) * unit; + msegmentptr sp = segment_holding(m, (char *)m->top); + + if (sp->size >= extra && + !has_segment_link(m, sp)) { /* can't shrink if pinned */ + size_t newsize = sp->size - extra; + /* Prefer mremap, fall back to munmap */ + if ((CALL_MREMAP(sp->base, sp->size, newsize, CALL_MREMAP_NOMOVE) != MFAIL) || + (CALL_MUNMAP(sp->base + newsize, extra) == 0)) { + released = extra; + } + } + + if (released != 0) { + sp->size -= released; + init_top(m, m->top, m->topsize - released); + } + } + + /* Unmap any unused mmapped segments */ + released += release_unused_segments(m); + + /* On failure, disable autotrim to avoid repeated failed future calls */ + if (released == 0 && m->topsize > m->trim_check) + m->trim_check = MAX_SIZE_T; + } + + return (released != 0)? 1 : 0; +} + +/* ---------------------------- malloc support --------------------------- */ + +/* allocate a large request from the best fitting chunk in a treebin */ +static void *tmalloc_large(mstate m, size_t nb) +{ + tchunkptr v = 0; + size_t rsize = ~nb+1; /* Unsigned negation */ + tchunkptr t; + bindex_t idx; + compute_tree_index(nb, idx); + + if ((t = *treebin_at(m, idx)) != 0) { + /* Traverse tree for this bin looking for node with size == nb */ + size_t sizebits = nb << leftshift_for_tree_index(idx); + tchunkptr rst = 0; /* The deepest untaken right subtree */ + for (;;) { + tchunkptr rt; + size_t trem = chunksize(t) - nb; + if (trem < rsize) { + v = t; + if ((rsize = trem) == 0) + break; + } + rt = t->child[1]; + t = t->child[(sizebits >> (SIZE_T_BITSIZE-SIZE_T_ONE)) & 1]; + if (rt != 0 && rt != t) + rst = rt; + if (t == 0) { + t = rst; /* set t to least subtree holding sizes > nb */ + break; + } + sizebits <<= 1; + } + } + + if (t == 0 && v == 0) { /* set t to root of next non-empty treebin */ + binmap_t leftbits = left_bits(idx2bit(idx)) & m->treemap; + if (leftbits != 0) + t = *treebin_at(m, lj_ffs(leftbits)); + } + + while (t != 0) { /* find smallest of tree or subtree */ + size_t trem = chunksize(t) - nb; + if (trem < rsize) { + rsize = trem; + v = t; + } + t = leftmost_child(t); + } + + /* If dv is a better fit, return NULL so malloc will use it */ + if (v != 0 && rsize < (size_t)(m->dvsize - nb)) { + mchunkptr r = chunk_plus_offset(v, nb); + unlink_large_chunk(m, v); + if (rsize < MIN_CHUNK_SIZE) { + set_inuse_and_pinuse(m, v, (rsize + nb)); + } else { + set_size_and_pinuse_of_inuse_chunk(m, v, nb); + set_size_and_pinuse_of_free_chunk(r, rsize); + insert_chunk(m, r, rsize); + } + return chunk2mem(v); + } + return NULL; +} + +/* allocate a small request from the best fitting chunk in a treebin */ +static void *tmalloc_small(mstate m, size_t nb) +{ + tchunkptr t, v; + mchunkptr r; + size_t rsize; + bindex_t i = lj_ffs(m->treemap); + + v = t = *treebin_at(m, i); + rsize = chunksize(t) - nb; + + while ((t = leftmost_child(t)) != 0) { + size_t trem = chunksize(t) - nb; + if (trem < rsize) { + rsize = trem; + v = t; + } + } + + r = chunk_plus_offset(v, nb); + unlink_large_chunk(m, v); + if (rsize < MIN_CHUNK_SIZE) { + set_inuse_and_pinuse(m, v, (rsize + nb)); + } else { + set_size_and_pinuse_of_inuse_chunk(m, v, nb); + set_size_and_pinuse_of_free_chunk(r, rsize); + replace_dv(m, r, rsize); + } + return chunk2mem(v); +} + +/* ----------------------------------------------------------------------- */ + +void *lj_alloc_create(PRNGState *rs) +{ + size_t tsize = DEFAULT_GRANULARITY; + char *tbase; + INIT_MMAP(); + UNUSED(rs); + tbase = (char *)(CALL_MMAP(rs, tsize)); + if (tbase != CMFAIL) { + size_t msize = pad_request(sizeof(struct malloc_state)); + mchunkptr mn; + mchunkptr msp = align_as_chunk(tbase); + mstate m = (mstate)(chunk2mem(msp)); + memset(m, 0, msize); + msp->head = (msize|PINUSE_BIT|CINUSE_BIT); + m->seg.base = tbase; + m->seg.size = tsize; + m->release_checks = MAX_RELEASE_CHECK_RATE; + init_bins(m); + mn = next_chunk(mem2chunk(m)); + init_top(m, mn, (size_t)((tbase + tsize) - (char *)mn) - TOP_FOOT_SIZE); + return m; + } + return NULL; +} + +void lj_alloc_setprng(void *msp, PRNGState *rs) +{ + mstate ms = (mstate)msp; + ms->prng = rs; +} + +void lj_alloc_destroy(void *msp) +{ + mstate ms = (mstate)msp; + msegmentptr sp = &ms->seg; + while (sp != 0) { + char *base = sp->base; + size_t size = sp->size; + sp = sp->next; + CALL_MUNMAP(base, size); + } +} + +static LJ_NOINLINE void *lj_alloc_malloc(void *msp, size_t nsize) +{ + mstate ms = (mstate)msp; + void *mem; + size_t nb; + if (nsize <= MAX_SMALL_REQUEST) { + bindex_t idx; + binmap_t smallbits; + nb = (nsize < MIN_REQUEST)? MIN_CHUNK_SIZE : pad_request(nsize); + idx = small_index(nb); + smallbits = ms->smallmap >> idx; + + if ((smallbits & 0x3U) != 0) { /* Remainderless fit to a smallbin. */ + mchunkptr b, p; + idx += ~smallbits & 1; /* Uses next bin if idx empty */ + b = smallbin_at(ms, idx); + p = b->fd; + unlink_first_small_chunk(ms, b, p, idx); + set_inuse_and_pinuse(ms, p, small_index2size(idx)); + mem = chunk2mem(p); + return mem; + } else if (nb > ms->dvsize) { + if (smallbits != 0) { /* Use chunk in next nonempty smallbin */ + mchunkptr b, p, r; + size_t rsize; + binmap_t leftbits = (smallbits << idx) & left_bits(idx2bit(idx)); + bindex_t i = lj_ffs(leftbits); + b = smallbin_at(ms, i); + p = b->fd; + unlink_first_small_chunk(ms, b, p, i); + rsize = small_index2size(i) - nb; + /* Fit here cannot be remainderless if 4byte sizes */ + if (SIZE_T_SIZE != 4 && rsize < MIN_CHUNK_SIZE) { + set_inuse_and_pinuse(ms, p, small_index2size(i)); + } else { + set_size_and_pinuse_of_inuse_chunk(ms, p, nb); + r = chunk_plus_offset(p, nb); + set_size_and_pinuse_of_free_chunk(r, rsize); + replace_dv(ms, r, rsize); + } + mem = chunk2mem(p); + return mem; + } else if (ms->treemap != 0 && (mem = tmalloc_small(ms, nb)) != 0) { + return mem; + } + } + } else if (nsize >= MAX_REQUEST) { + nb = MAX_SIZE_T; /* Too big to allocate. Force failure (in sys alloc) */ + } else { + nb = pad_request(nsize); + if (ms->treemap != 0 && (mem = tmalloc_large(ms, nb)) != 0) { + return mem; + } + } + + if (nb <= ms->dvsize) { + size_t rsize = ms->dvsize - nb; + mchunkptr p = ms->dv; + if (rsize >= MIN_CHUNK_SIZE) { /* split dv */ + mchunkptr r = ms->dv = chunk_plus_offset(p, nb); + ms->dvsize = rsize; + set_size_and_pinuse_of_free_chunk(r, rsize); + set_size_and_pinuse_of_inuse_chunk(ms, p, nb); + } else { /* exhaust dv */ + size_t dvs = ms->dvsize; + ms->dvsize = 0; + ms->dv = 0; + set_inuse_and_pinuse(ms, p, dvs); + } + mem = chunk2mem(p); + return mem; + } else if (nb < ms->topsize) { /* Split top */ + size_t rsize = ms->topsize -= nb; + mchunkptr p = ms->top; + mchunkptr r = ms->top = chunk_plus_offset(p, nb); + r->head = rsize | PINUSE_BIT; + set_size_and_pinuse_of_inuse_chunk(ms, p, nb); + mem = chunk2mem(p); + return mem; + } + return alloc_sys(ms, nb); +} + +static LJ_NOINLINE void *lj_alloc_free(void *msp, void *ptr) +{ + if (ptr != 0) { + mchunkptr p = mem2chunk(ptr); + mstate fm = (mstate)msp; + size_t psize = chunksize(p); + mchunkptr next = chunk_plus_offset(p, psize); + if (!pinuse(p)) { + size_t prevsize = p->prev_foot; + if ((prevsize & IS_DIRECT_BIT) != 0) { + prevsize &= ~IS_DIRECT_BIT; + psize += prevsize + DIRECT_FOOT_PAD; + CALL_MUNMAP((char *)p - prevsize, psize); + return NULL; + } else { + mchunkptr prev = chunk_minus_offset(p, prevsize); + psize += prevsize; + p = prev; + /* consolidate backward */ + if (p != fm->dv) { + unlink_chunk(fm, p, prevsize); + } else if ((next->head & INUSE_BITS) == INUSE_BITS) { + fm->dvsize = psize; + set_free_with_pinuse(p, psize, next); + return NULL; + } + } + } + if (!cinuse(next)) { /* consolidate forward */ + if (next == fm->top) { + size_t tsize = fm->topsize += psize; + fm->top = p; + p->head = tsize | PINUSE_BIT; + if (p == fm->dv) { + fm->dv = 0; + fm->dvsize = 0; + } + if (tsize > fm->trim_check) + alloc_trim(fm, 0); + return NULL; + } else if (next == fm->dv) { + size_t dsize = fm->dvsize += psize; + fm->dv = p; + set_size_and_pinuse_of_free_chunk(p, dsize); + return NULL; + } else { + size_t nsize = chunksize(next); + psize += nsize; + unlink_chunk(fm, next, nsize); + set_size_and_pinuse_of_free_chunk(p, psize); + if (p == fm->dv) { + fm->dvsize = psize; + return NULL; + } + } + } else { + set_free_with_pinuse(p, psize, next); + } + + if (is_small(psize)) { + insert_small_chunk(fm, p, psize); + } else { + tchunkptr tp = (tchunkptr)p; + insert_large_chunk(fm, tp, psize); + if (--fm->release_checks == 0) + release_unused_segments(fm); + } + } + return NULL; +} + +static LJ_NOINLINE void *lj_alloc_realloc(void *msp, void *ptr, size_t nsize) +{ + if (nsize >= MAX_REQUEST) { + return NULL; + } else { + mstate m = (mstate)msp; + mchunkptr oldp = mem2chunk(ptr); + size_t oldsize = chunksize(oldp); + mchunkptr next = chunk_plus_offset(oldp, oldsize); + mchunkptr newp = 0; + size_t nb = request2size(nsize); + + /* Try to either shrink or extend into top. Else malloc-copy-free */ + if (is_direct(oldp)) { + newp = direct_resize(oldp, nb); /* this may return NULL. */ + } else if (oldsize >= nb) { /* already big enough */ + size_t rsize = oldsize - nb; + newp = oldp; + if (rsize >= MIN_CHUNK_SIZE) { + mchunkptr rem = chunk_plus_offset(newp, nb); + set_inuse(m, newp, nb); + set_inuse(m, rem, rsize); + lj_alloc_free(m, chunk2mem(rem)); + } + } else if (next == m->top && oldsize + m->topsize > nb) { + /* Expand into top */ + size_t newsize = oldsize + m->topsize; + size_t newtopsize = newsize - nb; + mchunkptr newtop = chunk_plus_offset(oldp, nb); + set_inuse(m, oldp, nb); + newtop->head = newtopsize |PINUSE_BIT; + m->top = newtop; + m->topsize = newtopsize; + newp = oldp; + } + + if (newp != 0) { + return chunk2mem(newp); + } else { + void *newmem = lj_alloc_malloc(m, nsize); + if (newmem != 0) { + size_t oc = oldsize - overhead_for(oldp); + memcpy(newmem, ptr, oc < nsize ? oc : nsize); + lj_alloc_free(m, ptr); + } + return newmem; + } + } +} + +void *lj_alloc_f(void *msp, void *ptr, size_t osize, size_t nsize) +{ + (void)osize; + if (nsize == 0) { + return lj_alloc_free(msp, ptr); + } else if (ptr == NULL) { + return lj_alloc_malloc(msp, nsize); + } else { + return lj_alloc_realloc(msp, ptr, nsize); + } +} + +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_alloc.h b/fluent-bit/lib/luajit-3065c9/src/lj_alloc.h new file mode 100644 index 00000000..669f50b7 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_alloc.h @@ -0,0 +1,18 @@ +/* +** Bundled memory allocator. +** Donated to the public domain. +*/ + +#ifndef _LJ_ALLOC_H +#define _LJ_ALLOC_H + +#include "lj_def.h" + +#ifndef LUAJIT_USE_SYSMALLOC +LJ_FUNC void *lj_alloc_create(PRNGState *rs); +LJ_FUNC void lj_alloc_setprng(void *msp, PRNGState *rs); +LJ_FUNC void lj_alloc_destroy(void *msp); +LJ_FUNC void *lj_alloc_f(void *msp, void *ptr, size_t osize, size_t nsize); +#endif + +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_api.c b/fluent-bit/lib/luajit-3065c9/src/lj_api.c new file mode 100644 index 00000000..d869ebf8 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_api.c @@ -0,0 +1,1313 @@ +/* +** Public Lua/C API. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +** +** Major portions taken verbatim or adapted from the Lua interpreter. +** Copyright (C) 1994-2008 Lua.org, PUC-Rio. See Copyright Notice in lua.h +*/ + +#define lj_api_c +#define LUA_CORE + +#include "lj_obj.h" +#include "lj_gc.h" +#include "lj_err.h" +#include "lj_debug.h" +#include "lj_str.h" +#include "lj_tab.h" +#include "lj_func.h" +#include "lj_udata.h" +#include "lj_meta.h" +#include "lj_state.h" +#include "lj_bc.h" +#include "lj_frame.h" +#include "lj_trace.h" +#include "lj_vm.h" +#include "lj_strscan.h" +#include "lj_strfmt.h" + +/* -- Common helper functions --------------------------------------------- */ + +#define lj_checkapi_slot(idx) \ + lj_checkapi((idx) <= (L->top - L->base), "stack slot %d out of range", (idx)) + +static TValue *index2adr(lua_State *L, int idx) +{ + if (idx > 0) { + TValue *o = L->base + (idx - 1); + return o < L->top ? o : niltv(L); + } else if (idx > LUA_REGISTRYINDEX) { + lj_checkapi(idx != 0 && -idx <= L->top - L->base, + "bad stack slot %d", idx); + return L->top + idx; + } else if (idx == LUA_GLOBALSINDEX) { + TValue *o = &G(L)->tmptv; + settabV(L, o, tabref(L->env)); + return o; + } else if (idx == LUA_REGISTRYINDEX) { + return registry(L); + } else { + GCfunc *fn = curr_func(L); + lj_checkapi(fn->c.gct == ~LJ_TFUNC && !isluafunc(fn), + "calling frame is not a C function"); + if (idx == LUA_ENVIRONINDEX) { + TValue *o = &G(L)->tmptv; + settabV(L, o, tabref(fn->c.env)); + return o; + } else { + idx = LUA_GLOBALSINDEX - idx; + return idx <= fn->c.nupvalues ? &fn->c.upvalue[idx-1] : niltv(L); + } + } +} + +static LJ_AINLINE TValue *index2adr_check(lua_State *L, int idx) +{ + TValue *o = index2adr(L, idx); + lj_checkapi(o != niltv(L), "invalid stack slot %d", idx); + return o; +} + +static TValue *index2adr_stack(lua_State *L, int idx) +{ + if (idx > 0) { + TValue *o = L->base + (idx - 1); + if (o < L->top) { + return o; + } else { + lj_checkapi(0, "invalid stack slot %d", idx); + return niltv(L); + } + return o < L->top ? o : niltv(L); + } else { + lj_checkapi(idx != 0 && -idx <= L->top - L->base, + "invalid stack slot %d", idx); + return L->top + idx; + } +} + +static GCtab *getcurrenv(lua_State *L) +{ + GCfunc *fn = curr_func(L); + return fn->c.gct == ~LJ_TFUNC ? tabref(fn->c.env) : tabref(L->env); +} + +/* -- Miscellaneous API functions ----------------------------------------- */ + +LUA_API int lua_status(lua_State *L) +{ + return L->status; +} + +LUA_API int lua_checkstack(lua_State *L, int size) +{ + if (size > LUAI_MAXCSTACK || (L->top - L->base + size) > LUAI_MAXCSTACK) { + return 0; /* Stack overflow. */ + } else if (size > 0) { + lj_state_checkstack(L, (MSize)size); + } + return 1; +} + +LUALIB_API void luaL_checkstack(lua_State *L, int size, const char *msg) +{ + if (!lua_checkstack(L, size)) + lj_err_callerv(L, LJ_ERR_STKOVM, msg); +} + +LUA_API void lua_xmove(lua_State *L, lua_State *to, int n) +{ + TValue *f, *t; + if (L == to) return; + lj_checkapi_slot(n); + lj_checkapi(G(L) == G(to), "move across global states"); + lj_state_checkstack(to, (MSize)n); + f = L->top; + t = to->top = to->top + n; + while (--n >= 0) copyTV(to, --t, --f); + L->top = f; +} + +LUA_API const lua_Number *lua_version(lua_State *L) +{ + static const lua_Number version = LUA_VERSION_NUM; + UNUSED(L); + return &version; +} + +/* -- Stack manipulation -------------------------------------------------- */ + +LUA_API int lua_gettop(lua_State *L) +{ + return (int)(L->top - L->base); +} + +LUA_API void lua_settop(lua_State *L, int idx) +{ + if (idx >= 0) { + lj_checkapi(idx <= tvref(L->maxstack) - L->base, "bad stack slot %d", idx); + if (L->base + idx > L->top) { + if (L->base + idx >= tvref(L->maxstack)) + lj_state_growstack(L, (MSize)idx - (MSize)(L->top - L->base)); + do { setnilV(L->top++); } while (L->top < L->base + idx); + } else { + L->top = L->base + idx; + } + } else { + lj_checkapi(-(idx+1) <= (L->top - L->base), "bad stack slot %d", idx); + L->top += idx+1; /* Shrinks top (idx < 0). */ + } +} + +LUA_API void lua_remove(lua_State *L, int idx) +{ + TValue *p = index2adr_stack(L, idx); + while (++p < L->top) copyTV(L, p-1, p); + L->top--; +} + +LUA_API void lua_insert(lua_State *L, int idx) +{ + TValue *q, *p = index2adr_stack(L, idx); + for (q = L->top; q > p; q--) copyTV(L, q, q-1); + copyTV(L, p, L->top); +} + +static void copy_slot(lua_State *L, TValue *f, int idx) +{ + if (idx == LUA_GLOBALSINDEX) { + lj_checkapi(tvistab(f), "stack slot %d is not a table", idx); + /* NOBARRIER: A thread (i.e. L) is never black. */ + setgcref(L->env, obj2gco(tabV(f))); + } else if (idx == LUA_ENVIRONINDEX) { + GCfunc *fn = curr_func(L); + if (fn->c.gct != ~LJ_TFUNC) + lj_err_msg(L, LJ_ERR_NOENV); + lj_checkapi(tvistab(f), "stack slot %d is not a table", idx); + setgcref(fn->c.env, obj2gco(tabV(f))); + lj_gc_barrier(L, fn, f); + } else { + TValue *o = index2adr_check(L, idx); + copyTV(L, o, f); + if (idx < LUA_GLOBALSINDEX) /* Need a barrier for upvalues. */ + lj_gc_barrier(L, curr_func(L), f); + } +} + +LUA_API void lua_replace(lua_State *L, int idx) +{ + lj_checkapi_slot(1); + copy_slot(L, L->top - 1, idx); + L->top--; +} + +LUA_API void lua_copy(lua_State *L, int fromidx, int toidx) +{ + copy_slot(L, index2adr(L, fromidx), toidx); +} + +LUA_API void lua_pushvalue(lua_State *L, int idx) +{ + copyTV(L, L->top, index2adr(L, idx)); + incr_top(L); +} + +/* -- Stack getters ------------------------------------------------------- */ + +LUA_API int lua_type(lua_State *L, int idx) +{ + cTValue *o = index2adr(L, idx); + if (tvisnumber(o)) { + return LUA_TNUMBER; +#if LJ_64 && !LJ_GC64 + } else if (tvislightud(o)) { + return LUA_TLIGHTUSERDATA; +#endif + } else if (o == niltv(L)) { + return LUA_TNONE; + } else { /* Magic internal/external tag conversion. ORDER LJ_T */ + uint32_t t = ~itype(o); +#if LJ_64 + int tt = (int)((U64x(75a06,98042110) >> 4*t) & 15u); +#else + int tt = (int)(((t < 8 ? 0x98042110u : 0x75a06u) >> 4*(t&7)) & 15u); +#endif + lj_assertL(tt != LUA_TNIL || tvisnil(o), "bad tag conversion"); + return tt; + } +} + +LUALIB_API void luaL_checktype(lua_State *L, int idx, int tt) +{ + if (lua_type(L, idx) != tt) + lj_err_argt(L, idx, tt); +} + +LUALIB_API void luaL_checkany(lua_State *L, int idx) +{ + if (index2adr(L, idx) == niltv(L)) + lj_err_arg(L, idx, LJ_ERR_NOVAL); +} + +LUA_API const char *lua_typename(lua_State *L, int t) +{ + UNUSED(L); + return lj_obj_typename[t+1]; +} + +LUA_API int lua_iscfunction(lua_State *L, int idx) +{ + cTValue *o = index2adr(L, idx); + return tvisfunc(o) && !isluafunc(funcV(o)); +} + +LUA_API int lua_isnumber(lua_State *L, int idx) +{ + cTValue *o = index2adr(L, idx); + TValue tmp; + return (tvisnumber(o) || (tvisstr(o) && lj_strscan_number(strV(o), &tmp))); +} + +LUA_API int lua_isstring(lua_State *L, int idx) +{ + cTValue *o = index2adr(L, idx); + return (tvisstr(o) || tvisnumber(o)); +} + +LUA_API int lua_isuserdata(lua_State *L, int idx) +{ + cTValue *o = index2adr(L, idx); + return (tvisudata(o) || tvislightud(o)); +} + +LUA_API int lua_rawequal(lua_State *L, int idx1, int idx2) +{ + cTValue *o1 = index2adr(L, idx1); + cTValue *o2 = index2adr(L, idx2); + return (o1 == niltv(L) || o2 == niltv(L)) ? 0 : lj_obj_equal(o1, o2); +} + +LUA_API int lua_equal(lua_State *L, int idx1, int idx2) +{ + cTValue *o1 = index2adr(L, idx1); + cTValue *o2 = index2adr(L, idx2); + if (tvisint(o1) && tvisint(o2)) { + return intV(o1) == intV(o2); + } else if (tvisnumber(o1) && tvisnumber(o2)) { + return numberVnum(o1) == numberVnum(o2); + } else if (itype(o1) != itype(o2)) { + return 0; + } else if (tvispri(o1)) { + return o1 != niltv(L) && o2 != niltv(L); +#if LJ_64 && !LJ_GC64 + } else if (tvislightud(o1)) { + return o1->u64 == o2->u64; +#endif + } else if (gcrefeq(o1->gcr, o2->gcr)) { + return 1; + } else if (!tvistabud(o1)) { + return 0; + } else { + TValue *base = lj_meta_equal(L, gcV(o1), gcV(o2), 0); + if ((uintptr_t)base <= 1) { + return (int)(uintptr_t)base; + } else { + L->top = base+2; + lj_vm_call(L, base, 1+1); + L->top -= 2+LJ_FR2; + return tvistruecond(L->top+1+LJ_FR2); + } + } +} + +LUA_API int lua_lessthan(lua_State *L, int idx1, int idx2) +{ + cTValue *o1 = index2adr(L, idx1); + cTValue *o2 = index2adr(L, idx2); + if (o1 == niltv(L) || o2 == niltv(L)) { + return 0; + } else if (tvisint(o1) && tvisint(o2)) { + return intV(o1) < intV(o2); + } else if (tvisnumber(o1) && tvisnumber(o2)) { + return numberVnum(o1) < numberVnum(o2); + } else { + TValue *base = lj_meta_comp(L, o1, o2, 0); + if ((uintptr_t)base <= 1) { + return (int)(uintptr_t)base; + } else { + L->top = base+2; + lj_vm_call(L, base, 1+1); + L->top -= 2+LJ_FR2; + return tvistruecond(L->top+1+LJ_FR2); + } + } +} + +LUA_API lua_Number lua_tonumber(lua_State *L, int idx) +{ + cTValue *o = index2adr(L, idx); + TValue tmp; + if (LJ_LIKELY(tvisnumber(o))) + return numberVnum(o); + else if (tvisstr(o) && lj_strscan_num(strV(o), &tmp)) + return numV(&tmp); + else + return 0; +} + +LUA_API lua_Number lua_tonumberx(lua_State *L, int idx, int *ok) +{ + cTValue *o = index2adr(L, idx); + TValue tmp; + if (LJ_LIKELY(tvisnumber(o))) { + if (ok) *ok = 1; + return numberVnum(o); + } else if (tvisstr(o) && lj_strscan_num(strV(o), &tmp)) { + if (ok) *ok = 1; + return numV(&tmp); + } else { + if (ok) *ok = 0; + return 0; + } +} + +LUALIB_API lua_Number luaL_checknumber(lua_State *L, int idx) +{ + cTValue *o = index2adr(L, idx); + TValue tmp; + if (LJ_LIKELY(tvisnumber(o))) + return numberVnum(o); + else if (!(tvisstr(o) && lj_strscan_num(strV(o), &tmp))) + lj_err_argt(L, idx, LUA_TNUMBER); + return numV(&tmp); +} + +LUALIB_API lua_Number luaL_optnumber(lua_State *L, int idx, lua_Number def) +{ + cTValue *o = index2adr(L, idx); + TValue tmp; + if (LJ_LIKELY(tvisnumber(o))) + return numberVnum(o); + else if (tvisnil(o)) + return def; + else if (!(tvisstr(o) && lj_strscan_num(strV(o), &tmp))) + lj_err_argt(L, idx, LUA_TNUMBER); + return numV(&tmp); +} + +LUA_API lua_Integer lua_tointeger(lua_State *L, int idx) +{ + cTValue *o = index2adr(L, idx); + TValue tmp; + lua_Number n; + if (LJ_LIKELY(tvisint(o))) { + return intV(o); + } else if (LJ_LIKELY(tvisnum(o))) { + n = numV(o); + } else { + if (!(tvisstr(o) && lj_strscan_number(strV(o), &tmp))) + return 0; + if (tvisint(&tmp)) + return intV(&tmp); + n = numV(&tmp); + } +#if LJ_64 + return (lua_Integer)n; +#else + return lj_num2int(n); +#endif +} + +LUA_API lua_Integer lua_tointegerx(lua_State *L, int idx, int *ok) +{ + cTValue *o = index2adr(L, idx); + TValue tmp; + lua_Number n; + if (LJ_LIKELY(tvisint(o))) { + if (ok) *ok = 1; + return intV(o); + } else if (LJ_LIKELY(tvisnum(o))) { + n = numV(o); + } else { + if (!(tvisstr(o) && lj_strscan_number(strV(o), &tmp))) { + if (ok) *ok = 0; + return 0; + } + if (tvisint(&tmp)) { + if (ok) *ok = 1; + return intV(&tmp); + } + n = numV(&tmp); + } + if (ok) *ok = 1; +#if LJ_64 + return (lua_Integer)n; +#else + return lj_num2int(n); +#endif +} + +LUALIB_API lua_Integer luaL_checkinteger(lua_State *L, int idx) +{ + cTValue *o = index2adr(L, idx); + TValue tmp; + lua_Number n; + if (LJ_LIKELY(tvisint(o))) { + return intV(o); + } else if (LJ_LIKELY(tvisnum(o))) { + n = numV(o); + } else { + if (!(tvisstr(o) && lj_strscan_number(strV(o), &tmp))) + lj_err_argt(L, idx, LUA_TNUMBER); + if (tvisint(&tmp)) + return (lua_Integer)intV(&tmp); + n = numV(&tmp); + } +#if LJ_64 + return (lua_Integer)n; +#else + return lj_num2int(n); +#endif +} + +LUALIB_API lua_Integer luaL_optinteger(lua_State *L, int idx, lua_Integer def) +{ + cTValue *o = index2adr(L, idx); + TValue tmp; + lua_Number n; + if (LJ_LIKELY(tvisint(o))) { + return intV(o); + } else if (LJ_LIKELY(tvisnum(o))) { + n = numV(o); + } else if (tvisnil(o)) { + return def; + } else { + if (!(tvisstr(o) && lj_strscan_number(strV(o), &tmp))) + lj_err_argt(L, idx, LUA_TNUMBER); + if (tvisint(&tmp)) + return (lua_Integer)intV(&tmp); + n = numV(&tmp); + } +#if LJ_64 + return (lua_Integer)n; +#else + return lj_num2int(n); +#endif +} + +LUA_API int lua_toboolean(lua_State *L, int idx) +{ + cTValue *o = index2adr(L, idx); + return tvistruecond(o); +} + +LUA_API const char *lua_tolstring(lua_State *L, int idx, size_t *len) +{ + TValue *o = index2adr(L, idx); + GCstr *s; + if (LJ_LIKELY(tvisstr(o))) { + s = strV(o); + } else if (tvisnumber(o)) { + lj_gc_check(L); + o = index2adr(L, idx); /* GC may move the stack. */ + s = lj_strfmt_number(L, o); + setstrV(L, o, s); + } else { + if (len != NULL) *len = 0; + return NULL; + } + if (len != NULL) *len = s->len; + return strdata(s); +} + +LUALIB_API const char *luaL_checklstring(lua_State *L, int idx, size_t *len) +{ + TValue *o = index2adr(L, idx); + GCstr *s; + if (LJ_LIKELY(tvisstr(o))) { + s = strV(o); + } else if (tvisnumber(o)) { + lj_gc_check(L); + o = index2adr(L, idx); /* GC may move the stack. */ + s = lj_strfmt_number(L, o); + setstrV(L, o, s); + } else { + lj_err_argt(L, idx, LUA_TSTRING); + } + if (len != NULL) *len = s->len; + return strdata(s); +} + +LUALIB_API const char *luaL_optlstring(lua_State *L, int idx, + const char *def, size_t *len) +{ + TValue *o = index2adr(L, idx); + GCstr *s; + if (LJ_LIKELY(tvisstr(o))) { + s = strV(o); + } else if (tvisnil(o)) { + if (len != NULL) *len = def ? strlen(def) : 0; + return def; + } else if (tvisnumber(o)) { + lj_gc_check(L); + o = index2adr(L, idx); /* GC may move the stack. */ + s = lj_strfmt_number(L, o); + setstrV(L, o, s); + } else { + lj_err_argt(L, idx, LUA_TSTRING); + } + if (len != NULL) *len = s->len; + return strdata(s); +} + +LUALIB_API int luaL_checkoption(lua_State *L, int idx, const char *def, + const char *const lst[]) +{ + ptrdiff_t i; + const char *s = lua_tolstring(L, idx, NULL); + if (s == NULL && (s = def) == NULL) + lj_err_argt(L, idx, LUA_TSTRING); + for (i = 0; lst[i]; i++) + if (strcmp(lst[i], s) == 0) + return (int)i; + lj_err_argv(L, idx, LJ_ERR_INVOPTM, s); +} + +LUA_API size_t lua_objlen(lua_State *L, int idx) +{ + TValue *o = index2adr(L, idx); + if (tvisstr(o)) { + return strV(o)->len; + } else if (tvistab(o)) { + return (size_t)lj_tab_len(tabV(o)); + } else if (tvisudata(o)) { + return udataV(o)->len; + } else if (tvisnumber(o)) { + GCstr *s = lj_strfmt_number(L, o); + setstrV(L, o, s); + return s->len; + } else { + return 0; + } +} + +LUA_API lua_CFunction lua_tocfunction(lua_State *L, int idx) +{ + cTValue *o = index2adr(L, idx); + if (tvisfunc(o)) { + BCOp op = bc_op(*mref(funcV(o)->c.pc, BCIns)); + if (op == BC_FUNCC || op == BC_FUNCCW) + return funcV(o)->c.f; + } + return NULL; +} + +LUA_API void *lua_touserdata(lua_State *L, int idx) +{ + cTValue *o = index2adr(L, idx); + if (tvisudata(o)) + return uddata(udataV(o)); + else if (tvislightud(o)) + return lightudV(G(L), o); + else + return NULL; +} + +LUA_API lua_State *lua_tothread(lua_State *L, int idx) +{ + cTValue *o = index2adr(L, idx); + return (!tvisthread(o)) ? NULL : threadV(o); +} + +LUA_API const void *lua_topointer(lua_State *L, int idx) +{ + return lj_obj_ptr(G(L), index2adr(L, idx)); +} + +/* -- Stack setters (object creation) ------------------------------------- */ + +LUA_API void lua_pushnil(lua_State *L) +{ + setnilV(L->top); + incr_top(L); +} + +LUA_API void lua_pushnumber(lua_State *L, lua_Number n) +{ + setnumV(L->top, n); + if (LJ_UNLIKELY(tvisnan(L->top))) + setnanV(L->top); /* Canonicalize injected NaNs. */ + incr_top(L); +} + +LUA_API void lua_pushinteger(lua_State *L, lua_Integer n) +{ + setintptrV(L->top, n); + incr_top(L); +} + +LUA_API void lua_pushlstring(lua_State *L, const char *str, size_t len) +{ + GCstr *s; + lj_gc_check(L); + s = lj_str_new(L, str, len); + setstrV(L, L->top, s); + incr_top(L); +} + +LUA_API void lua_pushstring(lua_State *L, const char *str) +{ + if (str == NULL) { + setnilV(L->top); + } else { + GCstr *s; + lj_gc_check(L); + s = lj_str_newz(L, str); + setstrV(L, L->top, s); + } + incr_top(L); +} + +LUA_API const char *lua_pushvfstring(lua_State *L, const char *fmt, + va_list argp) +{ + lj_gc_check(L); + return lj_strfmt_pushvf(L, fmt, argp); +} + +LUA_API const char *lua_pushfstring(lua_State *L, const char *fmt, ...) +{ + const char *ret; + va_list argp; + lj_gc_check(L); + va_start(argp, fmt); + ret = lj_strfmt_pushvf(L, fmt, argp); + va_end(argp); + return ret; +} + +LUA_API void lua_pushcclosure(lua_State *L, lua_CFunction f, int n) +{ + GCfunc *fn; + lj_gc_check(L); + lj_checkapi_slot(n); + fn = lj_func_newC(L, (MSize)n, getcurrenv(L)); + fn->c.f = f; + L->top -= n; + while (n--) + copyTV(L, &fn->c.upvalue[n], L->top+n); + setfuncV(L, L->top, fn); + lj_assertL(iswhite(obj2gco(fn)), "new GC object is not white"); + incr_top(L); +} + +LUA_API void lua_pushboolean(lua_State *L, int b) +{ + setboolV(L->top, (b != 0)); + incr_top(L); +} + +LUA_API void lua_pushlightuserdata(lua_State *L, void *p) +{ +#if LJ_64 + p = lj_lightud_intern(L, p); +#endif + setrawlightudV(L->top, p); + incr_top(L); +} + +LUA_API void lua_createtable(lua_State *L, int narray, int nrec) +{ + lj_gc_check(L); + settabV(L, L->top, lj_tab_new_ah(L, narray, nrec)); + incr_top(L); +} + +LUALIB_API int luaL_newmetatable(lua_State *L, const char *tname) +{ + GCtab *regt = tabV(registry(L)); + TValue *tv = lj_tab_setstr(L, regt, lj_str_newz(L, tname)); + if (tvisnil(tv)) { + GCtab *mt = lj_tab_new(L, 0, 1); + settabV(L, tv, mt); + settabV(L, L->top++, mt); + lj_gc_anybarriert(L, regt); + return 1; + } else { + copyTV(L, L->top++, tv); + return 0; + } +} + +LUA_API int lua_pushthread(lua_State *L) +{ + setthreadV(L, L->top, L); + incr_top(L); + return (mainthread(G(L)) == L); +} + +LUA_API lua_State *lua_newthread(lua_State *L) +{ + lua_State *L1; + lj_gc_check(L); + L1 = lj_state_new(L); + setthreadV(L, L->top, L1); + incr_top(L); + return L1; +} + +LUA_API void *lua_newuserdata(lua_State *L, size_t size) +{ + GCudata *ud; + lj_gc_check(L); + if (size > LJ_MAX_UDATA) + lj_err_msg(L, LJ_ERR_UDATAOV); + ud = lj_udata_new(L, (MSize)size, getcurrenv(L)); + setudataV(L, L->top, ud); + incr_top(L); + return uddata(ud); +} + +LUA_API void lua_concat(lua_State *L, int n) +{ + lj_checkapi_slot(n); + if (n >= 2) { + n--; + do { + TValue *top = lj_meta_cat(L, L->top-1, -n); + if (top == NULL) { + L->top -= n; + break; + } + n -= (int)(L->top - top); + L->top = top+2; + lj_vm_call(L, top, 1+1); + L->top -= 1+LJ_FR2; + copyTV(L, L->top-1, L->top+LJ_FR2); + } while (--n > 0); + } else if (n == 0) { /* Push empty string. */ + setstrV(L, L->top, &G(L)->strempty); + incr_top(L); + } + /* else n == 1: nothing to do. */ +} + +/* -- Object getters ------------------------------------------------------ */ + +LUA_API void lua_gettable(lua_State *L, int idx) +{ + cTValue *t = index2adr_check(L, idx); + cTValue *v = lj_meta_tget(L, t, L->top-1); + if (v == NULL) { + L->top += 2; + lj_vm_call(L, L->top-2, 1+1); + L->top -= 2+LJ_FR2; + v = L->top+1+LJ_FR2; + } + copyTV(L, L->top-1, v); +} + +LUA_API void lua_getfield(lua_State *L, int idx, const char *k) +{ + cTValue *v, *t = index2adr_check(L, idx); + TValue key; + setstrV(L, &key, lj_str_newz(L, k)); + v = lj_meta_tget(L, t, &key); + if (v == NULL) { + L->top += 2; + lj_vm_call(L, L->top-2, 1+1); + L->top -= 2+LJ_FR2; + v = L->top+1+LJ_FR2; + } + copyTV(L, L->top, v); + incr_top(L); +} + +LUA_API void lua_rawget(lua_State *L, int idx) +{ + cTValue *t = index2adr(L, idx); + lj_checkapi(tvistab(t), "stack slot %d is not a table", idx); + copyTV(L, L->top-1, lj_tab_get(L, tabV(t), L->top-1)); +} + +LUA_API void lua_rawgeti(lua_State *L, int idx, int n) +{ + cTValue *v, *t = index2adr(L, idx); + lj_checkapi(tvistab(t), "stack slot %d is not a table", idx); + v = lj_tab_getint(tabV(t), n); + if (v) { + copyTV(L, L->top, v); + } else { + setnilV(L->top); + } + incr_top(L); +} + +LUA_API int lua_getmetatable(lua_State *L, int idx) +{ + cTValue *o = index2adr(L, idx); + GCtab *mt = NULL; + if (tvistab(o)) + mt = tabref(tabV(o)->metatable); + else if (tvisudata(o)) + mt = tabref(udataV(o)->metatable); + else + mt = tabref(basemt_obj(G(L), o)); + if (mt == NULL) + return 0; + settabV(L, L->top, mt); + incr_top(L); + return 1; +} + +LUALIB_API int luaL_getmetafield(lua_State *L, int idx, const char *field) +{ + if (lua_getmetatable(L, idx)) { + cTValue *tv = lj_tab_getstr(tabV(L->top-1), lj_str_newz(L, field)); + if (tv && !tvisnil(tv)) { + copyTV(L, L->top-1, tv); + return 1; + } + L->top--; + } + return 0; +} + +LUA_API void lua_getfenv(lua_State *L, int idx) +{ + cTValue *o = index2adr_check(L, idx); + if (tvisfunc(o)) { + settabV(L, L->top, tabref(funcV(o)->c.env)); + } else if (tvisudata(o)) { + settabV(L, L->top, tabref(udataV(o)->env)); + } else if (tvisthread(o)) { + settabV(L, L->top, tabref(threadV(o)->env)); + } else { + setnilV(L->top); + } + incr_top(L); +} + +LUA_API int lua_next(lua_State *L, int idx) +{ + cTValue *t = index2adr(L, idx); + int more; + lj_checkapi(tvistab(t), "stack slot %d is not a table", idx); + more = lj_tab_next(tabV(t), L->top-1, L->top-1); + if (more > 0) { + incr_top(L); /* Return new key and value slot. */ + } else if (!more) { /* End of traversal. */ + L->top--; /* Remove key slot. */ + } else { + lj_err_msg(L, LJ_ERR_NEXTIDX); + } + return more; +} + +LUA_API const char *lua_getupvalue(lua_State *L, int idx, int n) +{ + TValue *val; + GCobj *o; + const char *name = lj_debug_uvnamev(index2adr(L, idx), (uint32_t)(n-1), &val, &o); + if (name) { + copyTV(L, L->top, val); + incr_top(L); + } + return name; +} + +LUA_API void *lua_upvalueid(lua_State *L, int idx, int n) +{ + GCfunc *fn = funcV(index2adr(L, idx)); + n--; + lj_checkapi((uint32_t)n < fn->l.nupvalues, "bad upvalue %d", n); + return isluafunc(fn) ? (void *)gcref(fn->l.uvptr[n]) : + (void *)&fn->c.upvalue[n]; +} + +LUA_API void lua_upvaluejoin(lua_State *L, int idx1, int n1, int idx2, int n2) +{ + GCfunc *fn1 = funcV(index2adr(L, idx1)); + GCfunc *fn2 = funcV(index2adr(L, idx2)); + n1--; n2--; + lj_checkapi(isluafunc(fn1), "stack slot %d is not a Lua function", idx1); + lj_checkapi(isluafunc(fn2), "stack slot %d is not a Lua function", idx2); + lj_checkapi((uint32_t)n1 < fn1->l.nupvalues, "bad upvalue %d", n1+1); + lj_checkapi((uint32_t)n2 < fn2->l.nupvalues, "bad upvalue %d", n2+1); + setgcrefr(fn1->l.uvptr[n1], fn2->l.uvptr[n2]); + lj_gc_objbarrier(L, fn1, gcref(fn1->l.uvptr[n1])); +} + +LUALIB_API void *luaL_testudata(lua_State *L, int idx, const char *tname) +{ + cTValue *o = index2adr(L, idx); + if (tvisudata(o)) { + GCudata *ud = udataV(o); + cTValue *tv = lj_tab_getstr(tabV(registry(L)), lj_str_newz(L, tname)); + if (tv && tvistab(tv) && tabV(tv) == tabref(ud->metatable)) + return uddata(ud); + } + return NULL; /* value is not a userdata with a metatable */ +} + +LUALIB_API void *luaL_checkudata(lua_State *L, int idx, const char *tname) +{ + void *p = luaL_testudata(L, idx, tname); + if (!p) lj_err_argtype(L, idx, tname); + return p; +} + +/* -- Object setters ------------------------------------------------------ */ + +LUA_API void lua_settable(lua_State *L, int idx) +{ + TValue *o; + cTValue *t = index2adr_check(L, idx); + lj_checkapi_slot(2); + o = lj_meta_tset(L, t, L->top-2); + if (o) { + /* NOBARRIER: lj_meta_tset ensures the table is not black. */ + L->top -= 2; + copyTV(L, o, L->top+1); + } else { + TValue *base = L->top; + copyTV(L, base+2, base-3-2*LJ_FR2); + L->top = base+3; + lj_vm_call(L, base, 0+1); + L->top -= 3+LJ_FR2; + } +} + +LUA_API void lua_setfield(lua_State *L, int idx, const char *k) +{ + TValue *o; + TValue key; + cTValue *t = index2adr_check(L, idx); + lj_checkapi_slot(1); + setstrV(L, &key, lj_str_newz(L, k)); + o = lj_meta_tset(L, t, &key); + if (o) { + /* NOBARRIER: lj_meta_tset ensures the table is not black. */ + copyTV(L, o, --L->top); + } else { + TValue *base = L->top; + copyTV(L, base+2, base-3-2*LJ_FR2); + L->top = base+3; + lj_vm_call(L, base, 0+1); + L->top -= 2+LJ_FR2; + } +} + +LUA_API void lua_rawset(lua_State *L, int idx) +{ + GCtab *t = tabV(index2adr(L, idx)); + TValue *dst, *key; + lj_checkapi_slot(2); + key = L->top-2; + dst = lj_tab_set(L, t, key); + copyTV(L, dst, key+1); + lj_gc_anybarriert(L, t); + L->top = key; +} + +LUA_API void lua_rawseti(lua_State *L, int idx, int n) +{ + GCtab *t = tabV(index2adr(L, idx)); + TValue *dst, *src; + lj_checkapi_slot(1); + dst = lj_tab_setint(L, t, n); + src = L->top-1; + copyTV(L, dst, src); + lj_gc_barriert(L, t, dst); + L->top = src; +} + +LUA_API int lua_setmetatable(lua_State *L, int idx) +{ + global_State *g; + GCtab *mt; + cTValue *o = index2adr_check(L, idx); + lj_checkapi_slot(1); + if (tvisnil(L->top-1)) { + mt = NULL; + } else { + lj_checkapi(tvistab(L->top-1), "top stack slot is not a table"); + mt = tabV(L->top-1); + } + g = G(L); + if (tvistab(o)) { + setgcref(tabV(o)->metatable, obj2gco(mt)); + if (mt) + lj_gc_objbarriert(L, tabV(o), mt); + } else if (tvisudata(o)) { + setgcref(udataV(o)->metatable, obj2gco(mt)); + if (mt) + lj_gc_objbarrier(L, udataV(o), mt); + } else { + /* Flush cache, since traces specialize to basemt. But not during __gc. */ + if (lj_trace_flushall(L)) + lj_err_caller(L, LJ_ERR_NOGCMM); + if (tvisbool(o)) { + /* NOBARRIER: basemt is a GC root. */ + setgcref(basemt_it(g, LJ_TTRUE), obj2gco(mt)); + setgcref(basemt_it(g, LJ_TFALSE), obj2gco(mt)); + } else { + /* NOBARRIER: basemt is a GC root. */ + setgcref(basemt_obj(g, o), obj2gco(mt)); + } + } + L->top--; + return 1; +} + +LUALIB_API void luaL_setmetatable(lua_State *L, const char *tname) +{ + lua_getfield(L, LUA_REGISTRYINDEX, tname); + lua_setmetatable(L, -2); +} + +LUA_API int lua_setfenv(lua_State *L, int idx) +{ + cTValue *o = index2adr_check(L, idx); + GCtab *t; + lj_checkapi_slot(1); + lj_checkapi(tvistab(L->top-1), "top stack slot is not a table"); + t = tabV(L->top-1); + if (tvisfunc(o)) { + setgcref(funcV(o)->c.env, obj2gco(t)); + } else if (tvisudata(o)) { + setgcref(udataV(o)->env, obj2gco(t)); + } else if (tvisthread(o)) { + setgcref(threadV(o)->env, obj2gco(t)); + } else { + L->top--; + return 0; + } + lj_gc_objbarrier(L, gcV(o), t); + L->top--; + return 1; +} + +LUA_API const char *lua_setupvalue(lua_State *L, int idx, int n) +{ + cTValue *f = index2adr(L, idx); + TValue *val; + GCobj *o; + const char *name; + lj_checkapi_slot(1); + name = lj_debug_uvnamev(f, (uint32_t)(n-1), &val, &o); + if (name) { + L->top--; + copyTV(L, val, L->top); + lj_gc_barrier(L, o, L->top); + } + return name; +} + +/* -- Calls --------------------------------------------------------------- */ + +#if LJ_FR2 +static TValue *api_call_base(lua_State *L, int nargs) +{ + TValue *o = L->top, *base = o - nargs; + L->top = o+1; + for (; o > base; o--) copyTV(L, o, o-1); + setnilV(o); + return o+1; +} +#else +#define api_call_base(L, nargs) (L->top - (nargs)) +#endif + +LUA_API void lua_call(lua_State *L, int nargs, int nresults) +{ + lj_checkapi(L->status == LUA_OK || L->status == LUA_ERRERR, + "thread called in wrong state %d", L->status); + lj_checkapi_slot(nargs+1); + lj_vm_call(L, api_call_base(L, nargs), nresults+1); +} + +LUA_API int lua_pcall(lua_State *L, int nargs, int nresults, int errfunc) +{ + global_State *g = G(L); + uint8_t oldh = hook_save(g); + ptrdiff_t ef; + int status; + lj_checkapi(L->status == LUA_OK || L->status == LUA_ERRERR, + "thread called in wrong state %d", L->status); + lj_checkapi_slot(nargs+1); + if (errfunc == 0) { + ef = 0; + } else { + cTValue *o = index2adr_stack(L, errfunc); + ef = savestack(L, o); + } + status = lj_vm_pcall(L, api_call_base(L, nargs), nresults+1, ef); + if (status) hook_restore(g, oldh); + return status; +} + +static TValue *cpcall(lua_State *L, lua_CFunction func, void *ud) +{ + GCfunc *fn = lj_func_newC(L, 0, getcurrenv(L)); + TValue *top = L->top; + fn->c.f = func; + setfuncV(L, top++, fn); + if (LJ_FR2) setnilV(top++); +#if LJ_64 + ud = lj_lightud_intern(L, ud); +#endif + setrawlightudV(top++, ud); + cframe_nres(L->cframe) = 1+0; /* Zero results. */ + L->top = top; + return top-1; /* Now call the newly allocated C function. */ +} + +LUA_API int lua_cpcall(lua_State *L, lua_CFunction func, void *ud) +{ + global_State *g = G(L); + uint8_t oldh = hook_save(g); + int status; + lj_checkapi(L->status == LUA_OK || L->status == LUA_ERRERR, + "thread called in wrong state %d", L->status); + status = lj_vm_cpcall(L, func, ud, cpcall); + if (status) hook_restore(g, oldh); + return status; +} + +LUALIB_API int luaL_callmeta(lua_State *L, int idx, const char *field) +{ + if (luaL_getmetafield(L, idx, field)) { + TValue *top = L->top--; + if (LJ_FR2) setnilV(top++); + copyTV(L, top++, index2adr(L, idx)); + L->top = top; + lj_vm_call(L, top-1, 1+1); + return 1; + } + return 0; +} + +/* -- Coroutine yield and resume ------------------------------------------ */ + +LUA_API int lua_isyieldable(lua_State *L) +{ + return cframe_canyield(L->cframe); +} + +LUA_API int lua_yield(lua_State *L, int nresults) +{ + void *cf = L->cframe; + global_State *g = G(L); + if (cframe_canyield(cf)) { + cf = cframe_raw(cf); + if (!hook_active(g)) { /* Regular yield: move results down if needed. */ + cTValue *f = L->top - nresults; + if (f > L->base) { + TValue *t = L->base; + while (--nresults >= 0) copyTV(L, t++, f++); + L->top = t; + } + L->cframe = NULL; + L->status = LUA_YIELD; + return -1; + } else { /* Yield from hook: add a pseudo-frame. */ + TValue *top = L->top; + hook_leave(g); + (top++)->u64 = cframe_multres(cf); + setcont(top, lj_cont_hook); + if (LJ_FR2) top++; + setframe_pc(top, cframe_pc(cf)-1); + top++; + setframe_gc(top, obj2gco(L), LJ_TTHREAD); + if (LJ_FR2) top++; + setframe_ftsz(top, ((char *)(top+1)-(char *)L->base)+FRAME_CONT); + L->top = L->base = top+1; +#if ((defined(__GNUC__) || defined(__clang__)) && (LJ_TARGET_X64 || defined(LUAJIT_UNWIND_EXTERNAL)) && !LJ_NO_UNWIND) || LJ_TARGET_WINDOWS + lj_err_throw(L, LUA_YIELD); +#else + L->cframe = NULL; + L->status = LUA_YIELD; + lj_vm_unwind_c(cf, LUA_YIELD); +#endif + } + } + lj_err_msg(L, LJ_ERR_CYIELD); + return 0; /* unreachable */ +} + +LUA_API int lua_resume(lua_State *L, int nargs) +{ + if (L->cframe == NULL && L->status <= LUA_YIELD) + return lj_vm_resume(L, + L->status == LUA_OK ? api_call_base(L, nargs) : L->top - nargs, + 0, 0); + L->top = L->base; + setstrV(L, L->top, lj_err_str(L, LJ_ERR_COSUSP)); + incr_top(L); + return LUA_ERRRUN; +} + +/* -- GC and memory management -------------------------------------------- */ + +LUA_API int lua_gc(lua_State *L, int what, int data) +{ + global_State *g = G(L); + int res = 0; + switch (what) { + case LUA_GCSTOP: + g->gc.threshold = LJ_MAX_MEM; + break; + case LUA_GCRESTART: + g->gc.threshold = data == -1 ? (g->gc.total/100)*g->gc.pause : g->gc.total; + break; + case LUA_GCCOLLECT: + lj_gc_fullgc(L); + break; + case LUA_GCCOUNT: + res = (int)(g->gc.total >> 10); + break; + case LUA_GCCOUNTB: + res = (int)(g->gc.total & 0x3ff); + break; + case LUA_GCSTEP: { + GCSize a = (GCSize)data << 10; + g->gc.threshold = (a <= g->gc.total) ? (g->gc.total - a) : 0; + while (g->gc.total >= g->gc.threshold) + if (lj_gc_step(L) > 0) { + res = 1; + break; + } + break; + } + case LUA_GCSETPAUSE: + res = (int)(g->gc.pause); + g->gc.pause = (MSize)data; + break; + case LUA_GCSETSTEPMUL: + res = (int)(g->gc.stepmul); + g->gc.stepmul = (MSize)data; + break; + case LUA_GCISRUNNING: + res = (g->gc.threshold != LJ_MAX_MEM); + break; + default: + res = -1; /* Invalid option. */ + } + return res; +} + +LUA_API lua_Alloc lua_getallocf(lua_State *L, void **ud) +{ + global_State *g = G(L); + if (ud) *ud = g->allocd; + return g->allocf; +} + +LUA_API void lua_setallocf(lua_State *L, lua_Alloc f, void *ud) +{ + global_State *g = G(L); + g->allocd = ud; + g->allocf = f; +} + diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_arch.h b/fluent-bit/lib/luajit-3065c9/src/lj_arch.h new file mode 100644 index 00000000..882c99cb --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_arch.h @@ -0,0 +1,716 @@ +/* +** Target architecture selection. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#ifndef _LJ_ARCH_H +#define _LJ_ARCH_H + +#include "lua.h" + +/* -- Target definitions -------------------------------------------------- */ + +/* Target endianess. */ +#define LUAJIT_LE 0 +#define LUAJIT_BE 1 + +/* Target architectures. */ +#define LUAJIT_ARCH_X86 1 +#define LUAJIT_ARCH_x86 1 +#define LUAJIT_ARCH_X64 2 +#define LUAJIT_ARCH_x64 2 +#define LUAJIT_ARCH_ARM 3 +#define LUAJIT_ARCH_arm 3 +#define LUAJIT_ARCH_ARM64 4 +#define LUAJIT_ARCH_arm64 4 +#define LUAJIT_ARCH_PPC 5 +#define LUAJIT_ARCH_ppc 5 +#define LUAJIT_ARCH_MIPS 6 +#define LUAJIT_ARCH_mips 6 +#define LUAJIT_ARCH_MIPS32 6 +#define LUAJIT_ARCH_mips32 6 +#define LUAJIT_ARCH_MIPS64 7 +#define LUAJIT_ARCH_mips64 7 + +/* Target OS. */ +#define LUAJIT_OS_OTHER 0 +#define LUAJIT_OS_WINDOWS 1 +#define LUAJIT_OS_LINUX 2 +#define LUAJIT_OS_OSX 3 +#define LUAJIT_OS_BSD 4 +#define LUAJIT_OS_POSIX 5 + +/* Number mode. */ +#define LJ_NUMMODE_SINGLE 0 /* Single-number mode only. */ +#define LJ_NUMMODE_SINGLE_DUAL 1 /* Default to single-number mode. */ +#define LJ_NUMMODE_DUAL 2 /* Dual-number mode only. */ +#define LJ_NUMMODE_DUAL_SINGLE 3 /* Default to dual-number mode. */ + +/* -- Target detection ---------------------------------------------------- */ + +/* Select native target if no target defined. */ +#ifndef LUAJIT_TARGET + +#if defined(__i386) || defined(__i386__) || defined(_M_IX86) +#define LUAJIT_TARGET LUAJIT_ARCH_X86 +#elif defined(__x86_64__) || defined(__x86_64) || defined(_M_X64) || defined(_M_AMD64) +#define LUAJIT_TARGET LUAJIT_ARCH_X64 +#elif defined(__arm__) || defined(__arm) || defined(__ARM__) || defined(__ARM) +#define LUAJIT_TARGET LUAJIT_ARCH_ARM +#elif defined(__aarch64__) +#define LUAJIT_TARGET LUAJIT_ARCH_ARM64 +#elif defined(__ppc__) || defined(__ppc) || defined(__PPC__) || defined(__PPC) || defined(__powerpc__) || defined(__powerpc) || defined(__POWERPC__) || defined(__POWERPC) || defined(_M_PPC) +#define LUAJIT_TARGET LUAJIT_ARCH_PPC +#elif defined(__mips64__) || defined(__mips64) || defined(__MIPS64__) || defined(__MIPS64) +#define LUAJIT_TARGET LUAJIT_ARCH_MIPS64 +#elif defined(__mips__) || defined(__mips) || defined(__MIPS__) || defined(__MIPS) +#define LUAJIT_TARGET LUAJIT_ARCH_MIPS32 +#else +#error "No support for this architecture (yet)" +#endif + +#endif + +/* Select native OS if no target OS defined. */ +#ifndef LUAJIT_OS + +#if defined(_WIN32) && !defined(_XBOX_VER) +#define LUAJIT_OS LUAJIT_OS_WINDOWS +#elif defined(__linux__) +#define LUAJIT_OS LUAJIT_OS_LINUX +#elif defined(__MACH__) && defined(__APPLE__) +#include "TargetConditionals.h" +#define LUAJIT_OS LUAJIT_OS_OSX +#elif (defined(__FreeBSD__) || defined(__FreeBSD_kernel__) || \ + defined(__NetBSD__) || defined(__OpenBSD__) || \ + defined(__DragonFly__)) && !defined(__ORBIS__) && !defined(__PROSPERO__) +#define LUAJIT_OS LUAJIT_OS_BSD +#elif (defined(__sun__) && defined(__svr4__)) +#define LJ_TARGET_SOLARIS 1 +#define LUAJIT_OS LUAJIT_OS_POSIX +#elif defined(__HAIKU__) +#define LUAJIT_OS LUAJIT_OS_POSIX +#elif defined(__CYGWIN__) +#define LJ_TARGET_CYGWIN 1 +#define LUAJIT_OS LUAJIT_OS_POSIX +#else +#define LUAJIT_OS LUAJIT_OS_OTHER +#endif + +#endif + +/* Set target OS properties. */ +#if LUAJIT_OS == LUAJIT_OS_WINDOWS +#define LJ_OS_NAME "Windows" +#elif LUAJIT_OS == LUAJIT_OS_LINUX +#define LJ_OS_NAME "Linux" +#elif LUAJIT_OS == LUAJIT_OS_OSX +#define LJ_OS_NAME "OSX" +#elif LUAJIT_OS == LUAJIT_OS_BSD +#define LJ_OS_NAME "BSD" +#elif LUAJIT_OS == LUAJIT_OS_POSIX +#define LJ_OS_NAME "POSIX" +#else +#define LJ_OS_NAME "Other" +#endif + +#define LJ_TARGET_WINDOWS (LUAJIT_OS == LUAJIT_OS_WINDOWS) +#define LJ_TARGET_LINUX (LUAJIT_OS == LUAJIT_OS_LINUX) +#define LJ_TARGET_OSX (LUAJIT_OS == LUAJIT_OS_OSX) +#define LJ_TARGET_BSD (LUAJIT_OS == LUAJIT_OS_BSD) +#define LJ_TARGET_POSIX (LUAJIT_OS > LUAJIT_OS_WINDOWS) +#define LJ_TARGET_DLOPEN LJ_TARGET_POSIX + +#if TARGET_OS_IPHONE +#define LJ_TARGET_IOS 1 +#else +#define LJ_TARGET_IOS 0 +#endif + +#ifdef __CELLOS_LV2__ +#define LJ_TARGET_PS3 1 +#define LJ_TARGET_CONSOLE 1 +#endif + +#ifdef __ORBIS__ +#define LJ_TARGET_PS4 1 +#define LJ_TARGET_CONSOLE 1 +#undef NULL +#define NULL ((void*)0) +#endif + +#ifdef __PROSPERO__ +#define LJ_TARGET_PS5 1 +#define LJ_TARGET_CONSOLE 1 +#undef NULL +#define NULL ((void*)0) +#endif + +#ifdef __psp2__ +#define LJ_TARGET_PSVITA 1 +#define LJ_TARGET_CONSOLE 1 +#endif + +#if _XBOX_VER >= 200 +#define LJ_TARGET_XBOX360 1 +#define LJ_TARGET_CONSOLE 1 +#endif + +#ifdef _DURANGO +#define LJ_TARGET_XBOXONE 1 +#define LJ_TARGET_CONSOLE 1 +#define LJ_TARGET_GC64 1 +#endif + +#ifdef __NX__ +#define LJ_TARGET_NX 1 +#define LJ_TARGET_CONSOLE 1 +#undef NULL +#define NULL ((void*)0) +#endif + +#ifdef _UWP +#define LJ_TARGET_UWP 1 +#if LUAJIT_TARGET == LUAJIT_ARCH_X64 +#define LJ_TARGET_GC64 1 +#endif +#endif + +/* -- Arch-specific settings ---------------------------------------------- */ + +/* Set target architecture properties. */ +#if LUAJIT_TARGET == LUAJIT_ARCH_X86 + +#define LJ_ARCH_NAME "x86" +#define LJ_ARCH_BITS 32 +#define LJ_ARCH_ENDIAN LUAJIT_LE +#define LJ_TARGET_X86 1 +#define LJ_TARGET_X86ORX64 1 +#define LJ_TARGET_EHRETREG 0 +#define LJ_TARGET_EHRAREG 8 +#define LJ_TARGET_MASKSHIFT 1 +#define LJ_TARGET_MASKROT 1 +#define LJ_TARGET_UNALIGNED 1 +#define LJ_ARCH_NUMMODE LJ_NUMMODE_SINGLE_DUAL + +#elif LUAJIT_TARGET == LUAJIT_ARCH_X64 + +#define LJ_ARCH_NAME "x64" +#define LJ_ARCH_BITS 64 +#define LJ_ARCH_ENDIAN LUAJIT_LE +#define LJ_TARGET_X64 1 +#define LJ_TARGET_X86ORX64 1 +#define LJ_TARGET_EHRETREG 0 +#define LJ_TARGET_EHRAREG 16 +#define LJ_TARGET_JUMPRANGE 31 /* +-2^31 = +-2GB */ +#define LJ_TARGET_MASKSHIFT 1 +#define LJ_TARGET_MASKROT 1 +#define LJ_TARGET_UNALIGNED 1 +#define LJ_ARCH_NUMMODE LJ_NUMMODE_SINGLE_DUAL +#ifndef LUAJIT_DISABLE_GC64 +#define LJ_TARGET_GC64 1 +#elif LJ_TARGET_OSX +#error "macOS requires GC64 -- don't disable it" +#endif + +#elif LUAJIT_TARGET == LUAJIT_ARCH_ARM + +#define LJ_ARCH_NAME "arm" +#define LJ_ARCH_BITS 32 +#define LJ_ARCH_ENDIAN LUAJIT_LE +#if !defined(LJ_ARCH_HASFPU) && __SOFTFP__ +#define LJ_ARCH_HASFPU 0 +#endif +#if !defined(LJ_ABI_SOFTFP) && !__ARM_PCS_VFP +#define LJ_ABI_SOFTFP 1 +#endif +#define LJ_ABI_EABI 1 +#define LJ_TARGET_ARM 1 +#define LJ_TARGET_EHRETREG 0 +#define LJ_TARGET_EHRAREG 14 +#define LJ_TARGET_JUMPRANGE 25 /* +-2^25 = +-32MB */ +#define LJ_TARGET_MASKSHIFT 0 +#define LJ_TARGET_MASKROT 1 +#define LJ_TARGET_UNIFYROT 2 /* Want only IR_BROR. */ +#define LJ_ARCH_NUMMODE LJ_NUMMODE_DUAL + +#if __ARM_ARCH == 8 || __ARM_ARCH_8__ || __ARM_ARCH_8A__ +#define LJ_ARCH_VERSION 80 +#elif __ARM_ARCH == 7 || __ARM_ARCH_7__ || __ARM_ARCH_7A__ || __ARM_ARCH_7R__ || __ARM_ARCH_7S__ || __ARM_ARCH_7VE__ +#define LJ_ARCH_VERSION 70 +#elif __ARM_ARCH_6T2__ +#define LJ_ARCH_VERSION 61 +#elif __ARM_ARCH == 6 || __ARM_ARCH_6__ || __ARM_ARCH_6J__ || __ARM_ARCH_6K__ || __ARM_ARCH_6Z__ || __ARM_ARCH_6ZK__ +#define LJ_ARCH_VERSION 60 +#else +#define LJ_ARCH_VERSION 50 +#endif + +#elif LUAJIT_TARGET == LUAJIT_ARCH_ARM64 + +#define LJ_ARCH_BITS 64 +#if defined(__AARCH64EB__) +#define LJ_ARCH_NAME "arm64be" +#define LJ_ARCH_ENDIAN LUAJIT_BE +#else +#define LJ_ARCH_NAME "arm64" +#define LJ_ARCH_ENDIAN LUAJIT_LE +#endif +#define LJ_TARGET_ARM64 1 +#define LJ_TARGET_EHRETREG 0 +#define LJ_TARGET_EHRAREG 30 +#define LJ_TARGET_JUMPRANGE 27 /* +-2^27 = +-128MB */ +#define LJ_TARGET_MASKSHIFT 1 +#define LJ_TARGET_MASKROT 1 +#define LJ_TARGET_UNIFYROT 2 /* Want only IR_BROR. */ +#define LJ_TARGET_GC64 1 +#define LJ_ARCH_NUMMODE LJ_NUMMODE_DUAL + +#define LJ_ARCH_VERSION 80 + +#elif LUAJIT_TARGET == LUAJIT_ARCH_PPC + +#ifndef LJ_ARCH_ENDIAN +#if __BYTE_ORDER__ != __ORDER_BIG_ENDIAN__ +#define LJ_ARCH_ENDIAN LUAJIT_LE +#else +#define LJ_ARCH_ENDIAN LUAJIT_BE +#endif +#endif + +#if _LP64 +#define LJ_ARCH_BITS 64 +#if LJ_ARCH_ENDIAN == LUAJIT_LE +#define LJ_ARCH_NAME "ppc64le" +#else +#define LJ_ARCH_NAME "ppc64" +#endif +#else +#define LJ_ARCH_BITS 32 +#define LJ_ARCH_NAME "ppc" + +#if !defined(LJ_ARCH_HASFPU) +#if defined(_SOFT_FLOAT) || defined(_SOFT_DOUBLE) +#define LJ_ARCH_HASFPU 0 +#else +#define LJ_ARCH_HASFPU 1 +#endif +#endif + +#if !defined(LJ_ABI_SOFTFP) +#if defined(_SOFT_FLOAT) || defined(_SOFT_DOUBLE) +#define LJ_ABI_SOFTFP 1 +#else +#define LJ_ABI_SOFTFP 0 +#endif +#endif +#endif + +#if LJ_ABI_SOFTFP +#define LJ_ARCH_NUMMODE LJ_NUMMODE_DUAL +#else +#define LJ_ARCH_NUMMODE LJ_NUMMODE_DUAL_SINGLE +#endif + +#define LJ_TARGET_PPC 1 +#define LJ_TARGET_EHRETREG 3 +#define LJ_TARGET_EHRAREG 65 +#define LJ_TARGET_JUMPRANGE 25 /* +-2^25 = +-32MB */ +#define LJ_TARGET_MASKSHIFT 0 +#define LJ_TARGET_MASKROT 1 +#define LJ_TARGET_UNIFYROT 1 /* Want only IR_BROL. */ + +#if LJ_TARGET_CONSOLE +#define LJ_ARCH_PPC32ON64 1 +#define LJ_ARCH_NOFFI 1 +#elif LJ_ARCH_BITS == 64 +#error "No support for PPC64" +#endif + +#if _ARCH_PWR7 +#define LJ_ARCH_VERSION 70 +#elif _ARCH_PWR6 +#define LJ_ARCH_VERSION 60 +#elif _ARCH_PWR5X +#define LJ_ARCH_VERSION 51 +#elif _ARCH_PWR5 +#define LJ_ARCH_VERSION 50 +#elif _ARCH_PWR4 +#define LJ_ARCH_VERSION 40 +#else +#define LJ_ARCH_VERSION 0 +#endif +#if _ARCH_PPCSQ +#define LJ_ARCH_SQRT 1 +#endif +#if _ARCH_PWR5X +#define LJ_ARCH_ROUND 1 +#endif +#if __PPU__ +#define LJ_ARCH_CELL 1 +#endif +#if LJ_TARGET_XBOX360 +#define LJ_ARCH_XENON 1 +#endif + +#elif LUAJIT_TARGET == LUAJIT_ARCH_MIPS32 || LUAJIT_TARGET == LUAJIT_ARCH_MIPS64 + +#if defined(__MIPSEL__) || defined(__MIPSEL) || defined(_MIPSEL) +#if __mips_isa_rev >= 6 +#define LJ_TARGET_MIPSR6 1 +#define LJ_TARGET_UNALIGNED 1 +#endif +#if LUAJIT_TARGET == LUAJIT_ARCH_MIPS32 +#if LJ_TARGET_MIPSR6 +#define LJ_ARCH_NAME "mips32r6el" +#else +#define LJ_ARCH_NAME "mipsel" +#endif +#else +#if LJ_TARGET_MIPSR6 +#define LJ_ARCH_NAME "mips64r6el" +#else +#define LJ_ARCH_NAME "mips64el" +#endif +#endif +#define LJ_ARCH_ENDIAN LUAJIT_LE +#else +#if LUAJIT_TARGET == LUAJIT_ARCH_MIPS32 +#if LJ_TARGET_MIPSR6 +#define LJ_ARCH_NAME "mips32r6" +#else +#define LJ_ARCH_NAME "mips" +#endif +#else +#if LJ_TARGET_MIPSR6 +#define LJ_ARCH_NAME "mips64r6" +#else +#define LJ_ARCH_NAME "mips64" +#endif +#endif +#define LJ_ARCH_ENDIAN LUAJIT_BE +#endif + +#if !defined(LJ_ARCH_HASFPU) +#ifdef __mips_soft_float +#define LJ_ARCH_HASFPU 0 +#else +#define LJ_ARCH_HASFPU 1 +#endif +#endif + +#if !defined(LJ_ABI_SOFTFP) +#ifdef __mips_soft_float +#define LJ_ABI_SOFTFP 1 +#else +#define LJ_ABI_SOFTFP 0 +#endif +#endif + +#if LUAJIT_TARGET == LUAJIT_ARCH_MIPS32 +#define LJ_ARCH_BITS 32 +#define LJ_TARGET_MIPS32 1 +#else +#define LJ_ARCH_BITS 64 +#define LJ_TARGET_MIPS64 1 +#define LJ_TARGET_GC64 1 +#endif +#define LJ_TARGET_MIPS 1 +#define LJ_TARGET_EHRETREG 4 +#define LJ_TARGET_EHRAREG 31 +#define LJ_TARGET_JUMPRANGE 27 /* 2*2^27 = 256MB-aligned region */ +#define LJ_TARGET_MASKSHIFT 1 +#define LJ_TARGET_MASKROT 1 +#define LJ_TARGET_UNIFYROT 2 /* Want only IR_BROR. */ +#define LJ_ARCH_NUMMODE LJ_NUMMODE_DUAL + +#if LJ_TARGET_MIPSR6 +#define LJ_ARCH_VERSION 60 +#elif _MIPS_ARCH_MIPS32R2 || _MIPS_ARCH_MIPS64R2 +#define LJ_ARCH_VERSION 20 +#else +#define LJ_ARCH_VERSION 10 +#endif + +#else +#error "No target architecture defined" +#endif + +/* -- Checks for requirements --------------------------------------------- */ + +/* Check for minimum required compiler versions. */ +#if defined(__GNUC__) +#if LJ_TARGET_X86 +#if (__GNUC__ < 3) || ((__GNUC__ == 3) && __GNUC_MINOR__ < 4) +#error "Need at least GCC 3.4 or newer" +#endif +#elif LJ_TARGET_X64 +#if __GNUC__ < 4 +#error "Need at least GCC 4.0 or newer" +#endif +#elif LJ_TARGET_ARM +#if (__GNUC__ < 4) || ((__GNUC__ == 4) && __GNUC_MINOR__ < 2) +#error "Need at least GCC 4.2 or newer" +#endif +#elif LJ_TARGET_ARM64 +#if __clang__ +#if ((__clang_major__ < 3) || ((__clang_major__ == 3) && __clang_minor__ < 5)) && !defined(__NX_TOOLCHAIN_MAJOR__) +#error "Need at least Clang 3.5 or newer" +#endif +#else +#if (__GNUC__ < 4) || ((__GNUC__ == 4) && __GNUC_MINOR__ < 8) +#error "Need at least GCC 4.8 or newer" +#endif +#endif +#elif !LJ_TARGET_PS3 +#if (__GNUC__ < 4) || ((__GNUC__ == 4) && __GNUC_MINOR__ < 3) +#error "Need at least GCC 4.3 or newer" +#endif +#endif +#endif + +/* Check target-specific constraints. */ +#ifndef _BUILDVM_H +#if LJ_TARGET_X64 +#if __USING_SJLJ_EXCEPTIONS__ +#error "Need a C compiler with native exception handling on x64" +#endif +#elif LJ_TARGET_ARM +#if defined(__ARMEB__) +#error "No support for big-endian ARM" +#endif +#if __ARM_ARCH_6M__ || __ARM_ARCH_7M__ || __ARM_ARCH_7EM__ +#error "No support for Cortex-M CPUs" +#endif +#if !(__ARM_EABI__ || LJ_TARGET_IOS) +#error "Only ARM EABI or iOS 3.0+ ABI is supported" +#endif +#elif LJ_TARGET_ARM64 +#if defined(_ILP32) +#error "No support for ILP32 model on ARM64" +#endif +#elif LJ_TARGET_PPC +#if defined(_LITTLE_ENDIAN) && (!defined(_BYTE_ORDER) || (_BYTE_ORDER == _LITTLE_ENDIAN)) +#error "No support for little-endian PPC32" +#endif +#if defined(__NO_FPRS__) && !defined(_SOFT_FLOAT) +#error "No support for PPC/e500 anymore (use LuaJIT 2.0)" +#endif +#elif LJ_TARGET_MIPS32 +#if !((defined(_MIPS_SIM_ABI32) && _MIPS_SIM == _MIPS_SIM_ABI32) || (defined(_ABIO32) && _MIPS_SIM == _ABIO32)) +#error "Only o32 ABI supported for MIPS32" +#endif +#if LJ_TARGET_MIPSR6 +/* Not that useful, since most available r6 CPUs are 64 bit. */ +#error "No support for MIPS32R6" +#endif +#elif LJ_TARGET_MIPS64 +#if !((defined(_MIPS_SIM_ABI64) && _MIPS_SIM == _MIPS_SIM_ABI64) || (defined(_ABI64) && _MIPS_SIM == _ABI64)) +/* MIPS32ON64 aka n32 ABI support might be desirable, but difficult. */ +#error "Only n64 ABI supported for MIPS64" +#endif +#endif +#endif + +/* -- Derived defines ----------------------------------------------------- */ + +/* Enable or disable the dual-number mode for the VM. */ +#if (LJ_ARCH_NUMMODE == LJ_NUMMODE_SINGLE && LUAJIT_NUMMODE == 2) || \ + (LJ_ARCH_NUMMODE == LJ_NUMMODE_DUAL && LUAJIT_NUMMODE == 1) +#error "No support for this number mode on this architecture" +#endif +#if LJ_ARCH_NUMMODE == LJ_NUMMODE_DUAL || \ + (LJ_ARCH_NUMMODE == LJ_NUMMODE_DUAL_SINGLE && LUAJIT_NUMMODE != 1) || \ + (LJ_ARCH_NUMMODE == LJ_NUMMODE_SINGLE_DUAL && LUAJIT_NUMMODE == 2) +#define LJ_DUALNUM 1 +#else +#define LJ_DUALNUM 0 +#endif + +#if LJ_TARGET_IOS || LJ_TARGET_CONSOLE +/* Runtime code generation is restricted on iOS. Complain to Apple, not me. */ +/* Ditto for the consoles. Complain to Sony or MS, not me. */ +#ifndef LUAJIT_ENABLE_JIT +#define LJ_OS_NOJIT 1 +#endif +#endif + +/* 64 bit GC references. */ +#if LJ_TARGET_GC64 +#define LJ_GC64 1 +#else +#define LJ_GC64 0 +#endif + +/* 2-slot frame info. */ +#if LJ_GC64 +#define LJ_FR2 1 +#else +#define LJ_FR2 0 +#endif + +/* Disable or enable the JIT compiler. */ +#if defined(LUAJIT_DISABLE_JIT) || defined(LJ_ARCH_NOJIT) || defined(LJ_OS_NOJIT) +#define LJ_HASJIT 0 +#else +#define LJ_HASJIT 1 +#endif + +/* Disable or enable the FFI extension. */ +#if defined(LUAJIT_DISABLE_FFI) || defined(LJ_ARCH_NOFFI) +#define LJ_HASFFI 0 +#else +#define LJ_HASFFI 1 +#endif + +/* Disable or enable the string buffer extension. */ +#if defined(LUAJIT_DISABLE_BUFFER) +#define LJ_HASBUFFER 0 +#else +#define LJ_HASBUFFER 1 +#endif + +#if defined(LUAJIT_DISABLE_PROFILE) +#define LJ_HASPROFILE 0 +#elif LJ_TARGET_POSIX +#define LJ_HASPROFILE 1 +#define LJ_PROFILE_SIGPROF 1 +#elif LJ_TARGET_PS3 +#define LJ_HASPROFILE 1 +#define LJ_PROFILE_PTHREAD 1 +#elif LJ_TARGET_WINDOWS || LJ_TARGET_XBOX360 +#define LJ_HASPROFILE 1 +#define LJ_PROFILE_WTHREAD 1 +#else +#define LJ_HASPROFILE 0 +#endif + +#ifndef LJ_ARCH_HASFPU +#define LJ_ARCH_HASFPU 1 +#endif +#ifndef LJ_ABI_SOFTFP +#define LJ_ABI_SOFTFP 0 +#endif +#define LJ_SOFTFP (!LJ_ARCH_HASFPU) +#define LJ_SOFTFP32 (LJ_SOFTFP && LJ_32) + +#if LJ_ARCH_ENDIAN == LUAJIT_BE +#define LJ_LE 0 +#define LJ_BE 1 +#define LJ_ENDIAN_SELECT(le, be) be +#define LJ_ENDIAN_LOHI(lo, hi) hi lo +#else +#define LJ_LE 1 +#define LJ_BE 0 +#define LJ_ENDIAN_SELECT(le, be) le +#define LJ_ENDIAN_LOHI(lo, hi) lo hi +#endif + +#if LJ_ARCH_BITS == 32 +#define LJ_32 1 +#define LJ_64 0 +#else +#define LJ_32 0 +#define LJ_64 1 +#endif + +#ifndef LJ_TARGET_UNALIGNED +#define LJ_TARGET_UNALIGNED 0 +#endif + +#ifndef LJ_PAGESIZE +#define LJ_PAGESIZE 4096 +#endif + +/* Various workarounds for embedded operating systems or weak C runtimes. */ +#if defined(__ANDROID__) || defined(__symbian__) || LJ_TARGET_XBOX360 || LJ_TARGET_WINDOWS +#define LUAJIT_NO_LOG2 +#endif +#if LJ_TARGET_CONSOLE || (LJ_TARGET_IOS && __IPHONE_OS_VERSION_MIN_REQUIRED >= __IPHONE_8_0) +#define LJ_NO_SYSTEM 1 +#endif + +#if LJ_TARGET_WINDOWS || LJ_TARGET_CYGWIN +#define LJ_ABI_WIN 1 +#else +#define LJ_ABI_WIN 0 +#endif + +#if LJ_TARGET_WINDOWS +#if LJ_TARGET_UWP +#define LJ_WIN_VALLOC VirtualAllocFromApp +#define LJ_WIN_VPROTECT VirtualProtectFromApp +extern void *LJ_WIN_LOADLIBA(const char *path); +#else +#define LJ_WIN_VALLOC VirtualAlloc +#define LJ_WIN_VPROTECT VirtualProtect +#define LJ_WIN_LOADLIBA(path) LoadLibraryExA((path), NULL, 0) +#endif +#endif + +#if defined(LUAJIT_NO_UNWIND) || __GNU_COMPACT_EH__ || defined(__symbian__) || LJ_TARGET_IOS || LJ_TARGET_PS3 || LJ_TARGET_PS4 || LJ_TARGET_PS5 +#define LJ_NO_UNWIND 1 +#endif + +#if !LJ_NO_UNWIND && !defined(LUAJIT_UNWIND_INTERNAL) && (LJ_ABI_WIN || (defined(LUAJIT_UNWIND_EXTERNAL) && (defined(__GNUC__) || defined(__clang__)))) +#define LJ_UNWIND_EXT 1 +#else +#define LJ_UNWIND_EXT 0 +#endif + +#if LJ_UNWIND_EXT && LJ_HASJIT && !LJ_TARGET_ARM && !(LJ_ABI_WIN && LJ_TARGET_X86) +#define LJ_UNWIND_JIT 1 +#else +#define LJ_UNWIND_JIT 0 +#endif + +/* Compatibility with Lua 5.1 vs. 5.2. */ +#ifdef LUAJIT_ENABLE_LUA52COMPAT +#define LJ_52 1 +#else +#define LJ_52 0 +#endif + +/* -- VM security --------------------------------------------------------- */ + +/* Don't make any changes here. Instead build with: +** make "XCFLAGS=-DLUAJIT_SECURITY_flag=value" +** +** Important note to distro maintainers: DO NOT change the defaults for a +** regular distro build -- neither upwards, nor downwards! +** These build-time configurable security flags are intended for embedders +** who may have specific needs wrt. security vs. performance. +*/ + +/* Security defaults. */ +#ifndef LUAJIT_SECURITY_PRNG +/* PRNG init: 0 = fixed/insecure, 1 = secure from OS. */ +#define LUAJIT_SECURITY_PRNG 1 +#endif + +#ifndef LUAJIT_SECURITY_STRHASH +/* String hash: 0 = sparse only, 1 = sparse + dense. */ +#define LUAJIT_SECURITY_STRHASH 1 +#endif + +#ifndef LUAJIT_SECURITY_STRID +/* String IDs: 0 = linear, 1 = reseed < 255, 2 = reseed < 15, 3 = random. */ +#define LUAJIT_SECURITY_STRID 1 +#endif + +#ifndef LUAJIT_SECURITY_MCODE +/* Machine code page protection: 0 = insecure RWX, 1 = secure RW^X. */ +#define LUAJIT_SECURITY_MCODE 1 +#endif + +#define LJ_SECURITY_MODE \ + ( 0u \ + | ((LUAJIT_SECURITY_PRNG & 3) << 0) \ + | ((LUAJIT_SECURITY_STRHASH & 3) << 2) \ + | ((LUAJIT_SECURITY_STRID & 3) << 4) \ + | ((LUAJIT_SECURITY_MCODE & 3) << 6) \ + ) +#define LJ_SECURITY_MODESTRING \ + "\004prng\007strhash\005strid\005mcode" + +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_asm.c b/fluent-bit/lib/luajit-3065c9/src/lj_asm.c new file mode 100644 index 00000000..6f5e0c45 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_asm.c @@ -0,0 +1,2571 @@ +/* +** IR assembler (SSA IR -> machine code). +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#define lj_asm_c +#define LUA_CORE + +#include "lj_obj.h" + +#if LJ_HASJIT + +#include "lj_gc.h" +#include "lj_buf.h" +#include "lj_str.h" +#include "lj_tab.h" +#include "lj_frame.h" +#if LJ_HASFFI +#include "lj_ctype.h" +#endif +#include "lj_ir.h" +#include "lj_jit.h" +#include "lj_ircall.h" +#include "lj_iropt.h" +#include "lj_mcode.h" +#include "lj_trace.h" +#include "lj_snap.h" +#include "lj_asm.h" +#include "lj_dispatch.h" +#include "lj_vm.h" +#include "lj_target.h" + +#ifdef LUA_USE_ASSERT +#include +#endif + +/* -- Assembler state and common macros ----------------------------------- */ + +/* Assembler state. */ +typedef struct ASMState { + RegCost cost[RID_MAX]; /* Reference and blended allocation cost for regs. */ + + MCode *mcp; /* Current MCode pointer (grows down). */ + MCode *mclim; /* Lower limit for MCode memory + red zone. */ +#ifdef LUA_USE_ASSERT + MCode *mcp_prev; /* Red zone overflow check. */ +#endif + + IRIns *ir; /* Copy of pointer to IR instructions/constants. */ + jit_State *J; /* JIT compiler state. */ + +#if LJ_TARGET_X86ORX64 + x86ModRM mrm; /* Fused x86 address operand. */ +#endif + + RegSet freeset; /* Set of free registers. */ + RegSet modset; /* Set of registers modified inside the loop. */ + RegSet weakset; /* Set of weakly referenced registers. */ + RegSet phiset; /* Set of PHI registers. */ + + uint32_t flags; /* Copy of JIT compiler flags. */ + int loopinv; /* Loop branch inversion (0:no, 1:yes, 2:yes+CC_P). */ + + int32_t evenspill; /* Next even spill slot. */ + int32_t oddspill; /* Next odd spill slot (or 0). */ + + IRRef curins; /* Reference of current instruction. */ + IRRef stopins; /* Stop assembly before hitting this instruction. */ + IRRef orignins; /* Original T->nins. */ + + IRRef snapref; /* Current snapshot is active after this reference. */ + IRRef snaprename; /* Rename highwater mark for snapshot check. */ + SnapNo snapno; /* Current snapshot number. */ + SnapNo loopsnapno; /* Loop snapshot number. */ + int snapalloc; /* Current snapshot needs allocation. */ + BloomFilter snapfilt1, snapfilt2; /* Filled with snapshot refs. */ + + IRRef fuseref; /* Fusion limit (loopref, 0 or FUSE_DISABLED). */ + IRRef sectref; /* Section base reference (loopref or 0). */ + IRRef loopref; /* Reference of LOOP instruction (or 0). */ + + BCReg topslot; /* Number of slots for stack check (unless 0). */ + int32_t gcsteps; /* Accumulated number of GC steps (per section). */ + + GCtrace *T; /* Trace to assemble. */ + GCtrace *parent; /* Parent trace (or NULL). */ + + MCode *mcbot; /* Bottom of reserved MCode. */ + MCode *mctop; /* Top of generated MCode. */ + MCode *mctoporig; /* Original top of generated MCode. */ + MCode *mcloop; /* Pointer to loop MCode (or NULL). */ + MCode *invmcp; /* Points to invertible loop branch (or NULL). */ + MCode *flagmcp; /* Pending opportunity to merge flag setting ins. */ + MCode *realign; /* Realign loop if not NULL. */ + +#ifdef RID_NUM_KREF + intptr_t krefk[RID_NUM_KREF]; +#endif + IRRef1 phireg[RID_MAX]; /* PHI register references. */ + uint16_t parentmap[LJ_MAX_JSLOTS]; /* Parent instruction to RegSP map. */ +} ASMState; + +#ifdef LUA_USE_ASSERT +#define lj_assertA(c, ...) lj_assertG_(J2G(as->J), (c), __VA_ARGS__) +#else +#define lj_assertA(c, ...) ((void)as) +#endif + +#define IR(ref) (&as->ir[(ref)]) + +#define ASMREF_TMP1 REF_TRUE /* Temp. register. */ +#define ASMREF_TMP2 REF_FALSE /* Temp. register. */ +#define ASMREF_L REF_NIL /* Stores register for L. */ + +/* Check for variant to invariant references. */ +#define iscrossref(as, ref) ((ref) < as->sectref) + +/* Inhibit memory op fusion from variant to invariant references. */ +#define FUSE_DISABLED (~(IRRef)0) +#define mayfuse(as, ref) ((ref) > as->fuseref) +#define neverfuse(as) (as->fuseref == FUSE_DISABLED) +#define canfuse(as, ir) (!neverfuse(as) && !irt_isphi((ir)->t)) +#define opisfusableload(o) \ + ((o) == IR_ALOAD || (o) == IR_HLOAD || (o) == IR_ULOAD || \ + (o) == IR_FLOAD || (o) == IR_XLOAD || (o) == IR_SLOAD || (o) == IR_VLOAD) + +/* Sparse limit checks using a red zone before the actual limit. */ +#define MCLIM_REDZONE 64 + +static LJ_NORET LJ_NOINLINE void asm_mclimit(ASMState *as) +{ + lj_mcode_limiterr(as->J, (size_t)(as->mctop - as->mcp + 4*MCLIM_REDZONE)); +} + +static LJ_AINLINE void checkmclim(ASMState *as) +{ +#ifdef LUA_USE_ASSERT + if (as->mcp + MCLIM_REDZONE < as->mcp_prev) { + IRIns *ir = IR(as->curins+1); + lj_assertA(0, "red zone overflow: %p IR %04d %02d %04d %04d\n", as->mcp, + as->curins+1-REF_BIAS, ir->o, ir->op1-REF_BIAS, ir->op2-REF_BIAS); + } +#endif + if (LJ_UNLIKELY(as->mcp < as->mclim)) asm_mclimit(as); +#ifdef LUA_USE_ASSERT + as->mcp_prev = as->mcp; +#endif +} + +#ifdef RID_NUM_KREF +#define ra_iskref(ref) ((ref) < RID_NUM_KREF) +#define ra_krefreg(ref) ((Reg)(RID_MIN_KREF + (Reg)(ref))) +#define ra_krefk(as, ref) (as->krefk[(ref)]) + +static LJ_AINLINE void ra_setkref(ASMState *as, Reg r, intptr_t k) +{ + IRRef ref = (IRRef)(r - RID_MIN_KREF); + as->krefk[ref] = k; + as->cost[r] = REGCOST(ref, ref); +} + +#else +#define ra_iskref(ref) 0 +#define ra_krefreg(ref) RID_MIN_GPR +#define ra_krefk(as, ref) 0 +#endif + +/* Arch-specific field offsets. */ +static const uint8_t field_ofs[IRFL__MAX+1] = { +#define FLOFS(name, ofs) (uint8_t)(ofs), +IRFLDEF(FLOFS) +#undef FLOFS + 0 +}; + +/* -- Target-specific instruction emitter --------------------------------- */ + +#if LJ_TARGET_X86ORX64 +#include "lj_emit_x86.h" +#elif LJ_TARGET_ARM +#include "lj_emit_arm.h" +#elif LJ_TARGET_ARM64 +#include "lj_emit_arm64.h" +#elif LJ_TARGET_PPC +#include "lj_emit_ppc.h" +#elif LJ_TARGET_MIPS +#include "lj_emit_mips.h" +#else +#error "Missing instruction emitter for target CPU" +#endif + +/* Generic load/store of register from/to stack slot. */ +#define emit_spload(as, ir, r, ofs) \ + emit_loadofs(as, ir, (r), RID_SP, (ofs)) +#define emit_spstore(as, ir, r, ofs) \ + emit_storeofs(as, ir, (r), RID_SP, (ofs)) + +/* -- Register allocator debugging ---------------------------------------- */ + +/* #define LUAJIT_DEBUG_RA */ + +#ifdef LUAJIT_DEBUG_RA + +#include +#include + +#define RIDNAME(name) #name, +static const char *const ra_regname[] = { + GPRDEF(RIDNAME) + FPRDEF(RIDNAME) + VRIDDEF(RIDNAME) + NULL +}; +#undef RIDNAME + +static char ra_dbg_buf[65536]; +static char *ra_dbg_p; +static char *ra_dbg_merge; +static MCode *ra_dbg_mcp; + +static void ra_dstart(void) +{ + ra_dbg_p = ra_dbg_buf; + ra_dbg_merge = NULL; + ra_dbg_mcp = NULL; +} + +static void ra_dflush(void) +{ + fwrite(ra_dbg_buf, 1, (size_t)(ra_dbg_p-ra_dbg_buf), stdout); + ra_dstart(); +} + +static void ra_dprintf(ASMState *as, const char *fmt, ...) +{ + char *p; + va_list argp; + va_start(argp, fmt); + p = ra_dbg_mcp == as->mcp ? ra_dbg_merge : ra_dbg_p; + ra_dbg_mcp = NULL; + p += sprintf(p, "%08x \e[36m%04d ", (uintptr_t)as->mcp, as->curins-REF_BIAS); + for (;;) { + const char *e = strchr(fmt, '$'); + if (e == NULL) break; + memcpy(p, fmt, (size_t)(e-fmt)); + p += e-fmt; + if (e[1] == 'r') { + Reg r = va_arg(argp, Reg) & RID_MASK; + if (r <= RID_MAX) { + const char *q; + for (q = ra_regname[r]; *q; q++) + *p++ = *q >= 'A' && *q <= 'Z' ? *q + 0x20 : *q; + } else { + *p++ = '?'; + lj_assertA(0, "bad register %d for debug format \"%s\"", r, fmt); + } + } else if (e[1] == 'f' || e[1] == 'i') { + IRRef ref; + if (e[1] == 'f') + ref = va_arg(argp, IRRef); + else + ref = va_arg(argp, IRIns *) - as->ir; + if (ref >= REF_BIAS) + p += sprintf(p, "%04d", ref - REF_BIAS); + else + p += sprintf(p, "K%03d", REF_BIAS - ref); + } else if (e[1] == 's') { + uint32_t slot = va_arg(argp, uint32_t); + p += sprintf(p, "[sp+0x%x]", sps_scale(slot)); + } else if (e[1] == 'x') { + p += sprintf(p, "%08x", va_arg(argp, int32_t)); + } else { + lj_assertA(0, "bad debug format code"); + } + fmt = e+2; + } + va_end(argp); + while (*fmt) + *p++ = *fmt++; + *p++ = '\e'; *p++ = '['; *p++ = 'm'; *p++ = '\n'; + if (p > ra_dbg_buf+sizeof(ra_dbg_buf)-256) { + fwrite(ra_dbg_buf, 1, (size_t)(p-ra_dbg_buf), stdout); + p = ra_dbg_buf; + } + ra_dbg_p = p; +} + +#define RA_DBG_START() ra_dstart() +#define RA_DBG_FLUSH() ra_dflush() +#define RA_DBG_REF() \ + do { char *_p = ra_dbg_p; ra_dprintf(as, ""); \ + ra_dbg_merge = _p; ra_dbg_mcp = as->mcp; } while (0) +#define RA_DBGX(x) ra_dprintf x + +#else +#define RA_DBG_START() ((void)0) +#define RA_DBG_FLUSH() ((void)0) +#define RA_DBG_REF() ((void)0) +#define RA_DBGX(x) ((void)0) +#endif + +/* -- Register allocator -------------------------------------------------- */ + +#define ra_free(as, r) rset_set(as->freeset, (r)) +#define ra_modified(as, r) rset_set(as->modset, (r)) +#define ra_weak(as, r) rset_set(as->weakset, (r)) +#define ra_noweak(as, r) rset_clear(as->weakset, (r)) + +#define ra_used(ir) (ra_hasreg((ir)->r) || ra_hasspill((ir)->s)) + +/* Setup register allocator. */ +static void ra_setup(ASMState *as) +{ + Reg r; + /* Initially all regs (except the stack pointer) are free for use. */ + as->freeset = RSET_INIT; + as->modset = RSET_EMPTY; + as->weakset = RSET_EMPTY; + as->phiset = RSET_EMPTY; + memset(as->phireg, 0, sizeof(as->phireg)); + for (r = RID_MIN_GPR; r < RID_MAX; r++) + as->cost[r] = REGCOST(~0u, 0u); +} + +/* Rematerialize constants. */ +static Reg ra_rematk(ASMState *as, IRRef ref) +{ + IRIns *ir; + Reg r; + if (ra_iskref(ref)) { + r = ra_krefreg(ref); + lj_assertA(!rset_test(as->freeset, r), "rematk of free reg %d", r); + ra_free(as, r); + ra_modified(as, r); +#if LJ_64 + emit_loadu64(as, r, ra_krefk(as, ref)); +#else + emit_loadi(as, r, ra_krefk(as, ref)); +#endif + return r; + } + ir = IR(ref); + r = ir->r; + lj_assertA(ra_hasreg(r), "rematk of K%03d has no reg", REF_BIAS - ref); + lj_assertA(!ra_hasspill(ir->s), + "rematk of K%03d has spill slot [%x]", REF_BIAS - ref, ir->s); + ra_free(as, r); + ra_modified(as, r); + ir->r = RID_INIT; /* Do not keep any hint. */ + RA_DBGX((as, "remat $i $r", ir, r)); +#if !LJ_SOFTFP32 + if (ir->o == IR_KNUM) { + emit_loadk64(as, r, ir); + } else +#endif + if (emit_canremat(REF_BASE) && ir->o == IR_BASE) { + ra_sethint(ir->r, RID_BASE); /* Restore BASE register hint. */ + emit_getgl(as, r, jit_base); + } else if (emit_canremat(ASMREF_L) && ir->o == IR_KPRI) { + /* REF_NIL stores ASMREF_L register. */ + lj_assertA(irt_isnil(ir->t), "rematk of bad ASMREF_L"); + emit_getgl(as, r, cur_L); +#if LJ_64 + } else if (ir->o == IR_KINT64) { + emit_loadu64(as, r, ir_kint64(ir)->u64); +#if LJ_GC64 + } else if (ir->o == IR_KGC) { + emit_loadu64(as, r, (uintptr_t)ir_kgc(ir)); + } else if (ir->o == IR_KPTR || ir->o == IR_KKPTR) { + emit_loadu64(as, r, (uintptr_t)ir_kptr(ir)); +#endif +#endif + } else { + lj_assertA(ir->o == IR_KINT || ir->o == IR_KGC || + ir->o == IR_KPTR || ir->o == IR_KKPTR || ir->o == IR_KNULL, + "rematk of bad IR op %d", ir->o); + emit_loadi(as, r, ir->i); + } + return r; +} + +/* Force a spill. Allocate a new spill slot if needed. */ +static int32_t ra_spill(ASMState *as, IRIns *ir) +{ + int32_t slot = ir->s; + lj_assertA(ir >= as->ir + REF_TRUE, + "spill of K%03d", REF_BIAS - (int)(ir - as->ir)); + if (!ra_hasspill(slot)) { + if (irt_is64(ir->t)) { + slot = as->evenspill; + as->evenspill += 2; + } else if (as->oddspill) { + slot = as->oddspill; + as->oddspill = 0; + } else { + slot = as->evenspill; + as->oddspill = slot+1; + as->evenspill += 2; + } + if (as->evenspill > 256) + lj_trace_err(as->J, LJ_TRERR_SPILLOV); + ir->s = (uint8_t)slot; + } + return sps_scale(slot); +} + +/* Release the temporarily allocated register in ASMREF_TMP1/ASMREF_TMP2. */ +static Reg ra_releasetmp(ASMState *as, IRRef ref) +{ + IRIns *ir = IR(ref); + Reg r = ir->r; + lj_assertA(ra_hasreg(r), "release of TMP%d has no reg", ref-ASMREF_TMP1+1); + lj_assertA(!ra_hasspill(ir->s), + "release of TMP%d has spill slot [%x]", ref-ASMREF_TMP1+1, ir->s); + ra_free(as, r); + ra_modified(as, r); + ir->r = RID_INIT; + return r; +} + +/* Restore a register (marked as free). Rematerialize or force a spill. */ +static Reg ra_restore(ASMState *as, IRRef ref) +{ + if (emit_canremat(ref)) { + return ra_rematk(as, ref); + } else { + IRIns *ir = IR(ref); + int32_t ofs = ra_spill(as, ir); /* Force a spill slot. */ + Reg r = ir->r; + lj_assertA(ra_hasreg(r), "restore of IR %04d has no reg", ref - REF_BIAS); + ra_sethint(ir->r, r); /* Keep hint. */ + ra_free(as, r); + if (!rset_test(as->weakset, r)) { /* Only restore non-weak references. */ + ra_modified(as, r); + RA_DBGX((as, "restore $i $r", ir, r)); + emit_spload(as, ir, r, ofs); + } + return r; + } +} + +/* Save a register to a spill slot. */ +static void ra_save(ASMState *as, IRIns *ir, Reg r) +{ + RA_DBGX((as, "save $i $r", ir, r)); + emit_spstore(as, ir, r, sps_scale(ir->s)); +} + +#define MINCOST(name) \ + if (rset_test(RSET_ALL, RID_##name) && \ + LJ_LIKELY(allow&RID2RSET(RID_##name)) && as->cost[RID_##name] < cost) \ + cost = as->cost[RID_##name]; + +/* Evict the register with the lowest cost, forcing a restore. */ +static Reg ra_evict(ASMState *as, RegSet allow) +{ + IRRef ref; + RegCost cost = ~(RegCost)0; + lj_assertA(allow != RSET_EMPTY, "evict from empty set"); + if (RID_NUM_FPR == 0 || allow < RID2RSET(RID_MAX_GPR)) { + GPRDEF(MINCOST) + } else { + FPRDEF(MINCOST) + } + ref = regcost_ref(cost); + lj_assertA(ra_iskref(ref) || (ref >= as->T->nk && ref < as->T->nins), + "evict of out-of-range IR %04d", ref - REF_BIAS); + /* Preferably pick any weak ref instead of a non-weak, non-const ref. */ + if (!irref_isk(ref) && (as->weakset & allow)) { + IRIns *ir = IR(ref); + if (!rset_test(as->weakset, ir->r)) + ref = regcost_ref(as->cost[rset_pickbot((as->weakset & allow))]); + } + return ra_restore(as, ref); +} + +/* Pick any register (marked as free). Evict on-demand. */ +static Reg ra_pick(ASMState *as, RegSet allow) +{ + RegSet pick = as->freeset & allow; + if (!pick) + return ra_evict(as, allow); + else + return rset_picktop(pick); +} + +/* Get a scratch register (marked as free). */ +static Reg ra_scratch(ASMState *as, RegSet allow) +{ + Reg r = ra_pick(as, allow); + ra_modified(as, r); + RA_DBGX((as, "scratch $r", r)); + return r; +} + +/* Evict all registers from a set (if not free). */ +static void ra_evictset(ASMState *as, RegSet drop) +{ + RegSet work; + as->modset |= drop; +#if !LJ_SOFTFP + work = (drop & ~as->freeset) & RSET_FPR; + while (work) { + Reg r = rset_pickbot(work); + ra_restore(as, regcost_ref(as->cost[r])); + rset_clear(work, r); + checkmclim(as); + } +#endif + work = (drop & ~as->freeset); + while (work) { + Reg r = rset_pickbot(work); + ra_restore(as, regcost_ref(as->cost[r])); + rset_clear(work, r); + checkmclim(as); + } +} + +/* Evict (rematerialize) all registers allocated to constants. */ +static void ra_evictk(ASMState *as) +{ + RegSet work; +#if !LJ_SOFTFP + work = ~as->freeset & RSET_FPR; + while (work) { + Reg r = rset_pickbot(work); + IRRef ref = regcost_ref(as->cost[r]); + if (emit_canremat(ref) && irref_isk(ref)) { + ra_rematk(as, ref); + checkmclim(as); + } + rset_clear(work, r); + } +#endif + work = ~as->freeset & RSET_GPR; + while (work) { + Reg r = rset_pickbot(work); + IRRef ref = regcost_ref(as->cost[r]); + if (emit_canremat(ref) && irref_isk(ref)) { + ra_rematk(as, ref); + checkmclim(as); + } + rset_clear(work, r); + } +} + +#ifdef RID_NUM_KREF +/* Allocate a register for a constant. */ +static Reg ra_allock(ASMState *as, intptr_t k, RegSet allow) +{ + /* First try to find a register which already holds the same constant. */ + RegSet pick, work = ~as->freeset & RSET_GPR; + Reg r; + while (work) { + IRRef ref; + r = rset_pickbot(work); + ref = regcost_ref(as->cost[r]); +#if LJ_64 + if (ref < ASMREF_L) { + if (ra_iskref(ref)) { + if (k == ra_krefk(as, ref)) + return r; + } else { + IRIns *ir = IR(ref); + if ((ir->o == IR_KINT64 && k == (int64_t)ir_kint64(ir)->u64) || +#if LJ_GC64 + (ir->o == IR_KINT && k == ir->i) || + (ir->o == IR_KGC && k == (intptr_t)ir_kgc(ir)) || + ((ir->o == IR_KPTR || ir->o == IR_KKPTR) && + k == (intptr_t)ir_kptr(ir)) +#else + (ir->o != IR_KINT64 && k == ir->i) +#endif + ) + return r; + } + } +#else + if (ref < ASMREF_L && + k == (ra_iskref(ref) ? ra_krefk(as, ref) : IR(ref)->i)) + return r; +#endif + rset_clear(work, r); + } + pick = as->freeset & allow; + if (pick) { + /* Constants should preferably get unmodified registers. */ + if ((pick & ~as->modset)) + pick &= ~as->modset; + r = rset_pickbot(pick); /* Reduce conflicts with inverse allocation. */ + } else { + r = ra_evict(as, allow); + } + RA_DBGX((as, "allock $x $r", k, r)); + ra_setkref(as, r, k); + rset_clear(as->freeset, r); + ra_noweak(as, r); + return r; +} + +/* Allocate a specific register for a constant. */ +static void ra_allockreg(ASMState *as, intptr_t k, Reg r) +{ + Reg kr = ra_allock(as, k, RID2RSET(r)); + if (kr != r) { + IRIns irdummy; + irdummy.t.irt = IRT_INT; + ra_scratch(as, RID2RSET(r)); + emit_movrr(as, &irdummy, r, kr); + } +} +#else +#define ra_allockreg(as, k, r) emit_loadi(as, (r), (k)) +#endif + +/* Allocate a register for ref from the allowed set of registers. +** Note: this function assumes the ref does NOT have a register yet! +** Picks an optimal register, sets the cost and marks the register as non-free. +*/ +static Reg ra_allocref(ASMState *as, IRRef ref, RegSet allow) +{ + IRIns *ir = IR(ref); + RegSet pick = as->freeset & allow; + Reg r; + lj_assertA(ra_noreg(ir->r), + "IR %04d already has reg %d", ref - REF_BIAS, ir->r); + if (pick) { + /* First check register hint from propagation or PHI. */ + if (ra_hashint(ir->r)) { + r = ra_gethint(ir->r); + if (rset_test(pick, r)) /* Use hint register if possible. */ + goto found; + /* Rematerialization is cheaper than missing a hint. */ + if (rset_test(allow, r) && emit_canremat(regcost_ref(as->cost[r]))) { + ra_rematk(as, regcost_ref(as->cost[r])); + goto found; + } + RA_DBGX((as, "hintmiss $f $r", ref, r)); + } + /* Invariants should preferably get unmodified registers. */ + if (ref < as->loopref && !irt_isphi(ir->t)) { + if ((pick & ~as->modset)) + pick &= ~as->modset; + r = rset_pickbot(pick); /* Reduce conflicts with inverse allocation. */ + } else { + /* We've got plenty of regs, so get callee-save regs if possible. */ + if (RID_NUM_GPR > 8 && (pick & ~RSET_SCRATCH)) + pick &= ~RSET_SCRATCH; + r = rset_picktop(pick); + } + } else { + r = ra_evict(as, allow); + } +found: + RA_DBGX((as, "alloc $f $r", ref, r)); + ir->r = (uint8_t)r; + rset_clear(as->freeset, r); + ra_noweak(as, r); + as->cost[r] = REGCOST_REF_T(ref, irt_t(ir->t)); + return r; +} + +/* Allocate a register on-demand. */ +static Reg ra_alloc1(ASMState *as, IRRef ref, RegSet allow) +{ + Reg r = IR(ref)->r; + /* Note: allow is ignored if the register is already allocated. */ + if (ra_noreg(r)) r = ra_allocref(as, ref, allow); + ra_noweak(as, r); + return r; +} + +/* Add a register rename to the IR. */ +static void ra_addrename(ASMState *as, Reg down, IRRef ref, SnapNo snapno) +{ + IRRef ren; + lj_ir_set(as->J, IRT(IR_RENAME, IRT_NIL), ref, snapno); + ren = tref_ref(lj_ir_emit(as->J)); + as->J->cur.ir[ren].r = (uint8_t)down; + as->J->cur.ir[ren].s = SPS_NONE; +} + +/* Rename register allocation and emit move. */ +static void ra_rename(ASMState *as, Reg down, Reg up) +{ + IRRef ref = regcost_ref(as->cost[up] = as->cost[down]); + IRIns *ir = IR(ref); + ir->r = (uint8_t)up; + as->cost[down] = 0; + lj_assertA((down < RID_MAX_GPR) == (up < RID_MAX_GPR), + "rename between GPR/FPR %d and %d", down, up); + lj_assertA(!rset_test(as->freeset, down), "rename from free reg %d", down); + lj_assertA(rset_test(as->freeset, up), "rename to non-free reg %d", up); + ra_free(as, down); /* 'down' is free ... */ + ra_modified(as, down); + rset_clear(as->freeset, up); /* ... and 'up' is now allocated. */ + ra_noweak(as, up); + RA_DBGX((as, "rename $f $r $r", regcost_ref(as->cost[up]), down, up)); + emit_movrr(as, ir, down, up); /* Backwards codegen needs inverse move. */ + if (!ra_hasspill(IR(ref)->s)) { /* Add the rename to the IR. */ + /* + ** The rename is effective at the subsequent (already emitted) exit + ** branch. This is for the current snapshot (as->snapno). Except if we + ** haven't yet allocated any refs for the snapshot (as->snapalloc == 1), + ** then it belongs to the next snapshot. + ** See also the discussion at asm_snap_checkrename(). + */ + ra_addrename(as, down, ref, as->snapno + as->snapalloc); + } +} + +/* Pick a destination register (marked as free). +** Caveat: allow is ignored if there's already a destination register. +** Use ra_destreg() to get a specific register. +*/ +static Reg ra_dest(ASMState *as, IRIns *ir, RegSet allow) +{ + Reg dest = ir->r; + if (ra_hasreg(dest)) { + ra_free(as, dest); + ra_modified(as, dest); + } else { + if (ra_hashint(dest) && rset_test((as->freeset&allow), ra_gethint(dest))) { + dest = ra_gethint(dest); + ra_modified(as, dest); + RA_DBGX((as, "dest $r", dest)); + } else { + dest = ra_scratch(as, allow); + } + ir->r = dest; + } + if (LJ_UNLIKELY(ra_hasspill(ir->s))) ra_save(as, ir, dest); + return dest; +} + +/* Force a specific destination register (marked as free). */ +static void ra_destreg(ASMState *as, IRIns *ir, Reg r) +{ + Reg dest = ra_dest(as, ir, RID2RSET(r)); + if (dest != r) { + lj_assertA(rset_test(as->freeset, r), "dest reg %d is not free", r); + ra_modified(as, r); + emit_movrr(as, ir, dest, r); + } +} + +#if LJ_TARGET_X86ORX64 +/* Propagate dest register to left reference. Emit moves as needed. +** This is a required fixup step for all 2-operand machine instructions. +*/ +static void ra_left(ASMState *as, Reg dest, IRRef lref) +{ + IRIns *ir = IR(lref); + Reg left = ir->r; + if (ra_noreg(left)) { + if (irref_isk(lref)) { + if (ir->o == IR_KNUM) { + /* FP remat needs a load except for +0. Still better than eviction. */ + if (tvispzero(ir_knum(ir)) || !(as->freeset & RSET_FPR)) { + emit_loadk64(as, dest, ir); + return; + } +#if LJ_64 + } else if (ir->o == IR_KINT64) { + emit_loadk64(as, dest, ir); + return; +#if LJ_GC64 + } else if (ir->o == IR_KGC || ir->o == IR_KPTR || ir->o == IR_KKPTR) { + emit_loadk64(as, dest, ir); + return; +#endif +#endif + } else if (ir->o != IR_KPRI) { + lj_assertA(ir->o == IR_KINT || ir->o == IR_KGC || + ir->o == IR_KPTR || ir->o == IR_KKPTR || ir->o == IR_KNULL, + "K%03d has bad IR op %d", REF_BIAS - lref, ir->o); + emit_loadi(as, dest, ir->i); + return; + } + } + if (!ra_hashint(left) && !iscrossref(as, lref)) + ra_sethint(ir->r, dest); /* Propagate register hint. */ + left = ra_allocref(as, lref, dest < RID_MAX_GPR ? RSET_GPR : RSET_FPR); + } + ra_noweak(as, left); + /* Move needed for true 3-operand instruction: y=a+b ==> y=a; y+=b. */ + if (dest != left) { + /* Use register renaming if dest is the PHI reg. */ + if (irt_isphi(ir->t) && as->phireg[dest] == lref) { + ra_modified(as, left); + ra_rename(as, left, dest); + } else { + emit_movrr(as, ir, dest, left); + } + } +} +#else +/* Similar to ra_left, except we override any hints. */ +static void ra_leftov(ASMState *as, Reg dest, IRRef lref) +{ + IRIns *ir = IR(lref); + Reg left = ir->r; + if (ra_noreg(left)) { + ra_sethint(ir->r, dest); /* Propagate register hint. */ + left = ra_allocref(as, lref, + (LJ_SOFTFP || dest < RID_MAX_GPR) ? RSET_GPR : RSET_FPR); + } + ra_noweak(as, left); + if (dest != left) { + /* Use register renaming if dest is the PHI reg. */ + if (irt_isphi(ir->t) && as->phireg[dest] == lref) { + ra_modified(as, left); + ra_rename(as, left, dest); + } else { + emit_movrr(as, ir, dest, left); + } + } +} +#endif + +/* Force a RID_RETLO/RID_RETHI destination register pair (marked as free). */ +static void ra_destpair(ASMState *as, IRIns *ir) +{ + Reg destlo = ir->r, desthi = (ir+1)->r; + IRIns *irx = (LJ_64 && !irt_is64(ir->t)) ? ir+1 : ir; + /* First spill unrelated refs blocking the destination registers. */ + if (!rset_test(as->freeset, RID_RETLO) && + destlo != RID_RETLO && desthi != RID_RETLO) + ra_restore(as, regcost_ref(as->cost[RID_RETLO])); + if (!rset_test(as->freeset, RID_RETHI) && + destlo != RID_RETHI && desthi != RID_RETHI) + ra_restore(as, regcost_ref(as->cost[RID_RETHI])); + /* Next free the destination registers (if any). */ + if (ra_hasreg(destlo)) { + ra_free(as, destlo); + ra_modified(as, destlo); + } else { + destlo = RID_RETLO; + } + if (ra_hasreg(desthi)) { + ra_free(as, desthi); + ra_modified(as, desthi); + } else { + desthi = RID_RETHI; + } + /* Check for conflicts and shuffle the registers as needed. */ + if (destlo == RID_RETHI) { + if (desthi == RID_RETLO) { +#if LJ_TARGET_X86ORX64 + *--as->mcp = XI_XCHGa + RID_RETHI; + if (LJ_64 && irt_is64(irx->t)) *--as->mcp = 0x48; +#else + emit_movrr(as, irx, RID_RETHI, RID_TMP); + emit_movrr(as, irx, RID_RETLO, RID_RETHI); + emit_movrr(as, irx, RID_TMP, RID_RETLO); +#endif + } else { + emit_movrr(as, irx, RID_RETHI, RID_RETLO); + if (desthi != RID_RETHI) emit_movrr(as, irx, desthi, RID_RETHI); + } + } else if (desthi == RID_RETLO) { + emit_movrr(as, irx, RID_RETLO, RID_RETHI); + if (destlo != RID_RETLO) emit_movrr(as, irx, destlo, RID_RETLO); + } else { + if (desthi != RID_RETHI) emit_movrr(as, irx, desthi, RID_RETHI); + if (destlo != RID_RETLO) emit_movrr(as, irx, destlo, RID_RETLO); + } + /* Restore spill slots (if any). */ + if (ra_hasspill((ir+1)->s)) ra_save(as, ir+1, RID_RETHI); + if (ra_hasspill(ir->s)) ra_save(as, ir, RID_RETLO); +} + +/* -- Snapshot handling --------- ----------------------------------------- */ + +/* Can we rematerialize a KNUM instead of forcing a spill? */ +static int asm_snap_canremat(ASMState *as) +{ + Reg r; + for (r = RID_MIN_FPR; r < RID_MAX_FPR; r++) + if (irref_isk(regcost_ref(as->cost[r]))) + return 1; + return 0; +} + +/* Check whether a sunk store corresponds to an allocation. */ +static int asm_sunk_store(ASMState *as, IRIns *ira, IRIns *irs) +{ + if (irs->s == 255) { + if (irs->o == IR_ASTORE || irs->o == IR_HSTORE || + irs->o == IR_FSTORE || irs->o == IR_XSTORE) { + IRIns *irk = IR(irs->op1); + if (irk->o == IR_AREF || irk->o == IR_HREFK) + irk = IR(irk->op1); + return (IR(irk->op1) == ira); + } + return 0; + } else { + return (ira + irs->s == irs); /* Quick check. */ + } +} + +/* Allocate register or spill slot for a ref that escapes to a snapshot. */ +static void asm_snap_alloc1(ASMState *as, IRRef ref) +{ + IRIns *ir = IR(ref); + if (!irref_isk(ref) && ir->r != RID_SUNK) { + bloomset(as->snapfilt1, ref); + bloomset(as->snapfilt2, hashrot(ref, ref + HASH_BIAS)); + if (ra_used(ir)) return; + if (ir->r == RID_SINK) { + ir->r = RID_SUNK; +#if LJ_HASFFI + if (ir->o == IR_CNEWI) { /* Allocate CNEWI value. */ + asm_snap_alloc1(as, ir->op2); + if (LJ_32 && (ir+1)->o == IR_HIOP) + asm_snap_alloc1(as, (ir+1)->op2); + } else +#endif + { /* Allocate stored values for TNEW, TDUP and CNEW. */ + IRIns *irs; + lj_assertA(ir->o == IR_TNEW || ir->o == IR_TDUP || ir->o == IR_CNEW, + "sink of IR %04d has bad op %d", ref - REF_BIAS, ir->o); + for (irs = IR(as->snapref-1); irs > ir; irs--) + if (irs->r == RID_SINK && asm_sunk_store(as, ir, irs)) { + lj_assertA(irs->o == IR_ASTORE || irs->o == IR_HSTORE || + irs->o == IR_FSTORE || irs->o == IR_XSTORE, + "sunk store IR %04d has bad op %d", + (int)(irs - as->ir) - REF_BIAS, irs->o); + asm_snap_alloc1(as, irs->op2); + if (LJ_32 && (irs+1)->o == IR_HIOP) + asm_snap_alloc1(as, (irs+1)->op2); + } + } + } else { + RegSet allow; + if (ir->o == IR_CONV && ir->op2 == IRCONV_NUM_INT) { + IRIns *irc; + for (irc = IR(as->curins); irc > ir; irc--) + if ((irc->op1 == ref || irc->op2 == ref) && + !(irc->r == RID_SINK || irc->r == RID_SUNK)) + goto nosink; /* Don't sink conversion if result is used. */ + asm_snap_alloc1(as, ir->op1); + return; + } + nosink: + allow = (!LJ_SOFTFP && irt_isfp(ir->t)) ? RSET_FPR : RSET_GPR; + if ((as->freeset & allow) || + (allow == RSET_FPR && asm_snap_canremat(as))) { + /* Get a weak register if we have a free one or can rematerialize. */ + Reg r = ra_allocref(as, ref, allow); /* Allocate a register. */ + if (!irt_isphi(ir->t)) + ra_weak(as, r); /* But mark it as weakly referenced. */ + checkmclim(as); + RA_DBGX((as, "snapreg $f $r", ref, ir->r)); + } else { + ra_spill(as, ir); /* Otherwise force a spill slot. */ + RA_DBGX((as, "snapspill $f $s", ref, ir->s)); + } + } + } +} + +/* Allocate refs escaping to a snapshot. */ +static void asm_snap_alloc(ASMState *as, int snapno) +{ + SnapShot *snap = &as->T->snap[snapno]; + SnapEntry *map = &as->T->snapmap[snap->mapofs]; + MSize n, nent = snap->nent; + as->snapfilt1 = as->snapfilt2 = 0; + for (n = 0; n < nent; n++) { + SnapEntry sn = map[n]; + IRRef ref = snap_ref(sn); + if (!irref_isk(ref)) { + asm_snap_alloc1(as, ref); + if (LJ_SOFTFP && (sn & SNAP_SOFTFPNUM)) { + lj_assertA(irt_type(IR(ref+1)->t) == IRT_SOFTFP, + "snap %d[%d] points to bad SOFTFP IR %04d", + snapno, n, ref - REF_BIAS); + asm_snap_alloc1(as, ref+1); + } + } + } +} + +/* All guards for a snapshot use the same exitno. This is currently the +** same as the snapshot number. Since the exact origin of the exit cannot +** be determined, all guards for the same snapshot must exit with the same +** RegSP mapping. +** A renamed ref which has been used in a prior guard for the same snapshot +** would cause an inconsistency. The easy way out is to force a spill slot. +*/ +static int asm_snap_checkrename(ASMState *as, IRRef ren) +{ + if (bloomtest(as->snapfilt1, ren) && + bloomtest(as->snapfilt2, hashrot(ren, ren + HASH_BIAS))) { + IRIns *ir = IR(ren); + ra_spill(as, ir); /* Register renamed, so force a spill slot. */ + RA_DBGX((as, "snaprensp $f $s", ren, ir->s)); + return 1; /* Found. */ + } + return 0; /* Not found. */ +} + +/* Prepare snapshot for next guard or throwing instruction. */ +static void asm_snap_prep(ASMState *as) +{ + if (as->snapalloc) { + /* Alloc on first invocation for each snapshot. */ + as->snapalloc = 0; + asm_snap_alloc(as, as->snapno); + as->snaprename = as->T->nins; + } else { + /* Check any renames above the highwater mark. */ + for (; as->snaprename < as->T->nins; as->snaprename++) { + IRIns *ir = &as->T->ir[as->snaprename]; + if (asm_snap_checkrename(as, ir->op1)) + ir->op2 = REF_BIAS-1; /* Kill rename. */ + } + } +} + +/* Move to previous snapshot when we cross the current snapshot ref. */ +static void asm_snap_prev(ASMState *as) +{ + if (as->curins < as->snapref) { + uintptr_t ofs = (uintptr_t)(as->mctoporig - as->mcp); + if (ofs >= 0x10000) lj_trace_err(as->J, LJ_TRERR_MCODEOV); + do { + if (as->snapno == 0) return; + as->snapno--; + as->snapref = as->T->snap[as->snapno].ref; + as->T->snap[as->snapno].mcofs = (uint16_t)ofs; /* Remember mcode ofs. */ + } while (as->curins < as->snapref); /* May have no ins inbetween. */ + as->snapalloc = 1; + } +} + +/* Fixup snapshot mcode offsetst. */ +static void asm_snap_fixup_mcofs(ASMState *as) +{ + uint32_t sz = (uint32_t)(as->mctoporig - as->mcp); + SnapShot *snap = as->T->snap; + SnapNo i; + for (i = as->T->nsnap-1; i > 0; i--) { + /* Compute offset from mcode start and store in correct snapshot. */ + snap[i].mcofs = (uint16_t)(sz - snap[i-1].mcofs); + } + snap[0].mcofs = 0; +} + +/* -- Miscellaneous helpers ----------------------------------------------- */ + +/* Calculate stack adjustment. */ +static int32_t asm_stack_adjust(ASMState *as) +{ + if (as->evenspill <= SPS_FIXED) + return 0; + return sps_scale(sps_align(as->evenspill)); +} + +/* Must match with hash*() in lj_tab.c. */ +static uint32_t ir_khash(ASMState *as, IRIns *ir) +{ + uint32_t lo, hi; + UNUSED(as); + if (irt_isstr(ir->t)) { + return ir_kstr(ir)->sid; + } else if (irt_isnum(ir->t)) { + lo = ir_knum(ir)->u32.lo; + hi = ir_knum(ir)->u32.hi << 1; + } else if (irt_ispri(ir->t)) { + lj_assertA(!irt_isnil(ir->t), "hash of nil key"); + return irt_type(ir->t)-IRT_FALSE; + } else { + lj_assertA(irt_isgcv(ir->t), "hash of bad IR type %d", irt_type(ir->t)); + lo = u32ptr(ir_kgc(ir)); +#if LJ_GC64 + hi = (uint32_t)(u64ptr(ir_kgc(ir)) >> 32) | (irt_toitype(ir->t) << 15); +#else + hi = lo + HASH_BIAS; +#endif + } + return hashrot(lo, hi); +} + +/* -- Allocations --------------------------------------------------------- */ + +static void asm_gencall(ASMState *as, const CCallInfo *ci, IRRef *args); +static void asm_setupresult(ASMState *as, IRIns *ir, const CCallInfo *ci); + +static void asm_snew(ASMState *as, IRIns *ir) +{ + const CCallInfo *ci = &lj_ir_callinfo[IRCALL_lj_str_new]; + IRRef args[3]; + asm_snap_prep(as); + args[0] = ASMREF_L; /* lua_State *L */ + args[1] = ir->op1; /* const char *str */ + args[2] = ir->op2; /* size_t len */ + as->gcsteps++; + asm_setupresult(as, ir, ci); /* GCstr * */ + asm_gencall(as, ci, args); +} + +static void asm_tnew(ASMState *as, IRIns *ir) +{ + const CCallInfo *ci = &lj_ir_callinfo[IRCALL_lj_tab_new1]; + IRRef args[2]; + asm_snap_prep(as); + args[0] = ASMREF_L; /* lua_State *L */ + args[1] = ASMREF_TMP1; /* uint32_t ahsize */ + as->gcsteps++; + asm_setupresult(as, ir, ci); /* GCtab * */ + asm_gencall(as, ci, args); + ra_allockreg(as, ir->op1 | (ir->op2 << 24), ra_releasetmp(as, ASMREF_TMP1)); +} + +static void asm_tdup(ASMState *as, IRIns *ir) +{ + const CCallInfo *ci = &lj_ir_callinfo[IRCALL_lj_tab_dup]; + IRRef args[2]; + asm_snap_prep(as); + args[0] = ASMREF_L; /* lua_State *L */ + args[1] = ir->op1; /* const GCtab *kt */ + as->gcsteps++; + asm_setupresult(as, ir, ci); /* GCtab * */ + asm_gencall(as, ci, args); +} + +static void asm_gc_check(ASMState *as); + +/* Explicit GC step. */ +static void asm_gcstep(ASMState *as, IRIns *ir) +{ + IRIns *ira; + for (ira = IR(as->stopins+1); ira < ir; ira++) + if ((ira->o == IR_TNEW || ira->o == IR_TDUP || + (LJ_HASFFI && (ira->o == IR_CNEW || ira->o == IR_CNEWI))) && + ra_used(ira)) + as->gcsteps++; + if (as->gcsteps) + asm_gc_check(as); + as->gcsteps = 0x80000000; /* Prevent implicit GC check further up. */ +} + +/* -- Buffer operations --------------------------------------------------- */ + +static void asm_tvptr(ASMState *as, Reg dest, IRRef ref, MSize mode); +#if LJ_HASBUFFER +static void asm_bufhdr_write(ASMState *as, Reg sb); +#endif + +static void asm_bufhdr(ASMState *as, IRIns *ir) +{ + Reg sb = ra_dest(as, ir, RSET_GPR); + switch (ir->op2) { + case IRBUFHDR_RESET: { + Reg tmp = ra_scratch(as, rset_exclude(RSET_GPR, sb)); + IRIns irbp; + irbp.ot = IRT(0, IRT_PTR); /* Buffer data pointer type. */ + emit_storeofs(as, &irbp, tmp, sb, offsetof(SBuf, w)); + emit_loadofs(as, &irbp, tmp, sb, offsetof(SBuf, b)); + break; + } + case IRBUFHDR_APPEND: { + /* Rematerialize const buffer pointer instead of likely spill. */ + IRIns *irp = IR(ir->op1); + if (!(ra_hasreg(irp->r) || irp == ir-1 || + (irp == ir-2 && !ra_used(ir-1)))) { + while (!(irp->o == IR_BUFHDR && irp->op2 == IRBUFHDR_RESET)) + irp = IR(irp->op1); + if (irref_isk(irp->op1)) { + ra_weak(as, ra_allocref(as, ir->op1, RSET_GPR)); + ir = irp; + } + } + break; + } +#if LJ_HASBUFFER + case IRBUFHDR_WRITE: + asm_bufhdr_write(as, sb); + break; +#endif + default: lj_assertA(0, "bad BUFHDR op2 %d", ir->op2); break; + } +#if LJ_TARGET_X86ORX64 + ra_left(as, sb, ir->op1); +#else + ra_leftov(as, sb, ir->op1); +#endif +} + +static void asm_bufput(ASMState *as, IRIns *ir) +{ + const CCallInfo *ci = &lj_ir_callinfo[IRCALL_lj_buf_putstr]; + IRRef args[3]; + IRIns *irs; + int kchar = -129; + args[0] = ir->op1; /* SBuf * */ + args[1] = ir->op2; /* GCstr * */ + irs = IR(ir->op2); + lj_assertA(irt_isstr(irs->t), + "BUFPUT of non-string IR %04d", ir->op2 - REF_BIAS); + if (irs->o == IR_KGC) { + GCstr *s = ir_kstr(irs); + if (s->len == 1) { /* Optimize put of single-char string constant. */ + kchar = (int8_t)strdata(s)[0]; /* Signed! */ + args[1] = ASMREF_TMP1; /* int, truncated to char */ + ci = &lj_ir_callinfo[IRCALL_lj_buf_putchar]; + } + } else if (mayfuse(as, ir->op2) && ra_noreg(irs->r)) { + if (irs->o == IR_TOSTR) { /* Fuse number to string conversions. */ + if (irs->op2 == IRTOSTR_NUM) { + args[1] = ASMREF_TMP1; /* TValue * */ + ci = &lj_ir_callinfo[IRCALL_lj_strfmt_putnum]; + } else { + lj_assertA(irt_isinteger(IR(irs->op1)->t), + "TOSTR of non-numeric IR %04d", irs->op1); + args[1] = irs->op1; /* int */ + if (irs->op2 == IRTOSTR_INT) + ci = &lj_ir_callinfo[IRCALL_lj_strfmt_putint]; + else + ci = &lj_ir_callinfo[IRCALL_lj_buf_putchar]; + } + } else if (irs->o == IR_SNEW) { /* Fuse string allocation. */ + args[1] = irs->op1; /* const void * */ + args[2] = irs->op2; /* MSize */ + ci = &lj_ir_callinfo[IRCALL_lj_buf_putmem]; + } + } + asm_setupresult(as, ir, ci); /* SBuf * */ + asm_gencall(as, ci, args); + if (args[1] == ASMREF_TMP1) { + Reg tmp = ra_releasetmp(as, ASMREF_TMP1); + if (kchar == -129) + asm_tvptr(as, tmp, irs->op1, IRTMPREF_IN1); + else + ra_allockreg(as, kchar, tmp); + } +} + +static void asm_bufstr(ASMState *as, IRIns *ir) +{ + const CCallInfo *ci = &lj_ir_callinfo[IRCALL_lj_buf_tostr]; + IRRef args[1]; + args[0] = ir->op1; /* SBuf *sb */ + as->gcsteps++; + asm_setupresult(as, ir, ci); /* GCstr * */ + asm_gencall(as, ci, args); +} + +/* -- Type conversions ---------------------------------------------------- */ + +static void asm_tostr(ASMState *as, IRIns *ir) +{ + const CCallInfo *ci; + IRRef args[2]; + asm_snap_prep(as); + args[0] = ASMREF_L; + as->gcsteps++; + if (ir->op2 == IRTOSTR_NUM) { + args[1] = ASMREF_TMP1; /* cTValue * */ + ci = &lj_ir_callinfo[IRCALL_lj_strfmt_num]; + } else { + args[1] = ir->op1; /* int32_t k */ + if (ir->op2 == IRTOSTR_INT) + ci = &lj_ir_callinfo[IRCALL_lj_strfmt_int]; + else + ci = &lj_ir_callinfo[IRCALL_lj_strfmt_char]; + } + asm_setupresult(as, ir, ci); /* GCstr * */ + asm_gencall(as, ci, args); + if (ir->op2 == IRTOSTR_NUM) + asm_tvptr(as, ra_releasetmp(as, ASMREF_TMP1), ir->op1, IRTMPREF_IN1); +} + +#if LJ_32 && LJ_HASFFI && !LJ_SOFTFP && !LJ_TARGET_X86 +static void asm_conv64(ASMState *as, IRIns *ir) +{ + IRType st = (IRType)((ir-1)->op2 & IRCONV_SRCMASK); + IRType dt = (((ir-1)->op2 & IRCONV_DSTMASK) >> IRCONV_DSH); + IRCallID id; + IRRef args[2]; + lj_assertA((ir-1)->o == IR_CONV && ir->o == IR_HIOP, + "not a CONV/HIOP pair at IR %04d", (int)(ir - as->ir) - REF_BIAS); + args[LJ_BE] = (ir-1)->op1; + args[LJ_LE] = ir->op1; + if (st == IRT_NUM || st == IRT_FLOAT) { + id = IRCALL_fp64_d2l + ((st == IRT_FLOAT) ? 2 : 0) + (dt - IRT_I64); + ir--; + } else { + id = IRCALL_fp64_l2d + ((dt == IRT_FLOAT) ? 2 : 0) + (st - IRT_I64); + } + { +#if LJ_TARGET_ARM && !LJ_ABI_SOFTFP + CCallInfo cim = lj_ir_callinfo[id], *ci = &cim; + cim.flags |= CCI_VARARG; /* These calls don't use the hard-float ABI! */ +#else + const CCallInfo *ci = &lj_ir_callinfo[id]; +#endif + asm_setupresult(as, ir, ci); + asm_gencall(as, ci, args); + } +} +#endif + +/* -- Memory references --------------------------------------------------- */ + +static void asm_newref(ASMState *as, IRIns *ir) +{ + const CCallInfo *ci = &lj_ir_callinfo[IRCALL_lj_tab_newkey]; + IRRef args[3]; + if (ir->r == RID_SINK) + return; + asm_snap_prep(as); + args[0] = ASMREF_L; /* lua_State *L */ + args[1] = ir->op1; /* GCtab *t */ + args[2] = ASMREF_TMP1; /* cTValue *key */ + asm_setupresult(as, ir, ci); /* TValue * */ + asm_gencall(as, ci, args); + asm_tvptr(as, ra_releasetmp(as, ASMREF_TMP1), ir->op2, IRTMPREF_IN1); +} + +static void asm_tmpref(ASMState *as, IRIns *ir) +{ + Reg r = ra_dest(as, ir, RSET_GPR); + asm_tvptr(as, r, ir->op1, ir->op2); +} + +static void asm_lref(ASMState *as, IRIns *ir) +{ + Reg r = ra_dest(as, ir, RSET_GPR); +#if LJ_TARGET_X86ORX64 + ra_left(as, r, ASMREF_L); +#else + ra_leftov(as, r, ASMREF_L); +#endif +} + +/* -- Calls --------------------------------------------------------------- */ + +/* Collect arguments from CALL* and CARG instructions. */ +static void asm_collectargs(ASMState *as, IRIns *ir, + const CCallInfo *ci, IRRef *args) +{ + uint32_t n = CCI_XNARGS(ci); + /* Account for split args. */ + lj_assertA(n <= CCI_NARGS_MAX*2, "too many args %d to collect", n); + if ((ci->flags & CCI_L)) { *args++ = ASMREF_L; n--; } + while (n-- > 1) { + ir = IR(ir->op1); + lj_assertA(ir->o == IR_CARG, "malformed CALL arg tree"); + args[n] = ir->op2 == REF_NIL ? 0 : ir->op2; + } + args[0] = ir->op1 == REF_NIL ? 0 : ir->op1; + lj_assertA(IR(ir->op1)->o != IR_CARG, "malformed CALL arg tree"); +} + +/* Reconstruct CCallInfo flags for CALLX*. */ +static uint32_t asm_callx_flags(ASMState *as, IRIns *ir) +{ + uint32_t nargs = 0; + if (ir->op1 != REF_NIL) { /* Count number of arguments first. */ + IRIns *ira = IR(ir->op1); + nargs++; + while (ira->o == IR_CARG) { nargs++; ira = IR(ira->op1); } + } +#if LJ_HASFFI + if (IR(ir->op2)->o == IR_CARG) { /* Copy calling convention info. */ + CTypeID id = (CTypeID)IR(IR(ir->op2)->op2)->i; + CType *ct = ctype_get(ctype_ctsG(J2G(as->J)), id); + nargs |= ((ct->info & CTF_VARARG) ? CCI_VARARG : 0); +#if LJ_TARGET_X86 + nargs |= (ctype_cconv(ct->info) << CCI_CC_SHIFT); +#endif + } +#endif + return (nargs | (ir->t.irt << CCI_OTSHIFT)); +} + +static void asm_callid(ASMState *as, IRIns *ir, IRCallID id) +{ + const CCallInfo *ci = &lj_ir_callinfo[id]; + IRRef args[2]; + args[0] = ir->op1; + args[1] = ir->op2; + asm_setupresult(as, ir, ci); + asm_gencall(as, ci, args); +} + +static void asm_call(ASMState *as, IRIns *ir) +{ + IRRef args[CCI_NARGS_MAX]; + const CCallInfo *ci = &lj_ir_callinfo[ir->op2]; + asm_collectargs(as, ir, ci, args); + asm_setupresult(as, ir, ci); + asm_gencall(as, ci, args); +} + +/* -- PHI and loop handling ----------------------------------------------- */ + +/* Break a PHI cycle by renaming to a free register (evict if needed). */ +static void asm_phi_break(ASMState *as, RegSet blocked, RegSet blockedby, + RegSet allow) +{ + RegSet candidates = blocked & allow; + if (candidates) { /* If this register file has candidates. */ + /* Note: the set for ra_pick cannot be empty, since each register file + ** has some registers never allocated to PHIs. + */ + Reg down, up = ra_pick(as, ~blocked & allow); /* Get a free register. */ + if (candidates & ~blockedby) /* Optimize shifts, else it's a cycle. */ + candidates = candidates & ~blockedby; + down = rset_picktop(candidates); /* Pick candidate PHI register. */ + ra_rename(as, down, up); /* And rename it to the free register. */ + } +} + +/* PHI register shuffling. +** +** The allocator tries hard to preserve PHI register assignments across +** the loop body. Most of the time this loop does nothing, since there +** are no register mismatches. +** +** If a register mismatch is detected and ... +** - the register is currently free: rename it. +** - the register is blocked by an invariant: restore/remat and rename it. +** - Otherwise the register is used by another PHI, so mark it as blocked. +** +** The renames are order-sensitive, so just retry the loop if a register +** is marked as blocked, but has been freed in the meantime. A cycle is +** detected if all of the blocked registers are allocated. To break the +** cycle rename one of them to a free register and retry. +** +** Note that PHI spill slots are kept in sync and don't need to be shuffled. +*/ +static void asm_phi_shuffle(ASMState *as) +{ + RegSet work; + + /* Find and resolve PHI register mismatches. */ + for (;;) { + RegSet blocked = RSET_EMPTY; + RegSet blockedby = RSET_EMPTY; + RegSet phiset = as->phiset; + while (phiset) { /* Check all left PHI operand registers. */ + Reg r = rset_pickbot(phiset); + IRIns *irl = IR(as->phireg[r]); + Reg left = irl->r; + if (r != left) { /* Mismatch? */ + if (!rset_test(as->freeset, r)) { /* PHI register blocked? */ + IRRef ref = regcost_ref(as->cost[r]); + /* Blocked by other PHI (w/reg)? */ + if (!ra_iskref(ref) && irt_ismarked(IR(ref)->t)) { + rset_set(blocked, r); + if (ra_hasreg(left)) + rset_set(blockedby, left); + left = RID_NONE; + } else { /* Otherwise grab register from invariant. */ + ra_restore(as, ref); + checkmclim(as); + } + } + if (ra_hasreg(left)) { + ra_rename(as, left, r); + checkmclim(as); + } + } + rset_clear(phiset, r); + } + if (!blocked) break; /* Finished. */ + if (!(as->freeset & blocked)) { /* Break cycles if none are free. */ + asm_phi_break(as, blocked, blockedby, RSET_GPR); + if (!LJ_SOFTFP) asm_phi_break(as, blocked, blockedby, RSET_FPR); + checkmclim(as); + } /* Else retry some more renames. */ + } + + /* Restore/remat invariants whose registers are modified inside the loop. */ +#if !LJ_SOFTFP + work = as->modset & ~(as->freeset | as->phiset) & RSET_FPR; + while (work) { + Reg r = rset_pickbot(work); + ra_restore(as, regcost_ref(as->cost[r])); + rset_clear(work, r); + checkmclim(as); + } +#endif + work = as->modset & ~(as->freeset | as->phiset); + while (work) { + Reg r = rset_pickbot(work); + ra_restore(as, regcost_ref(as->cost[r])); + rset_clear(work, r); + checkmclim(as); + } + + /* Allocate and save all unsaved PHI regs and clear marks. */ + work = as->phiset; + while (work) { + Reg r = rset_picktop(work); + IRRef lref = as->phireg[r]; + IRIns *ir = IR(lref); + if (ra_hasspill(ir->s)) { /* Left PHI gained a spill slot? */ + irt_clearmark(ir->t); /* Handled here, so clear marker now. */ + ra_alloc1(as, lref, RID2RSET(r)); + ra_save(as, ir, r); /* Save to spill slot inside the loop. */ + checkmclim(as); + } + rset_clear(work, r); + } +} + +/* Copy unsynced left/right PHI spill slots. Rarely needed. */ +static void asm_phi_copyspill(ASMState *as) +{ + int need = 0; + IRIns *ir; + for (ir = IR(as->orignins-1); ir->o == IR_PHI; ir--) + if (ra_hasspill(ir->s) && ra_hasspill(IR(ir->op1)->s)) + need |= irt_isfp(ir->t) ? 2 : 1; /* Unsynced spill slot? */ + if ((need & 1)) { /* Copy integer spill slots. */ +#if !LJ_TARGET_X86ORX64 + Reg r = RID_TMP; +#else + Reg r = RID_RET; + if ((as->freeset & RSET_GPR)) + r = rset_pickbot((as->freeset & RSET_GPR)); + else + emit_spload(as, IR(regcost_ref(as->cost[r])), r, SPOFS_TMP); +#endif + for (ir = IR(as->orignins-1); ir->o == IR_PHI; ir--) { + if (ra_hasspill(ir->s)) { + IRIns *irl = IR(ir->op1); + if (ra_hasspill(irl->s) && !irt_isfp(ir->t)) { + emit_spstore(as, irl, r, sps_scale(irl->s)); + emit_spload(as, ir, r, sps_scale(ir->s)); + checkmclim(as); + } + } + } +#if LJ_TARGET_X86ORX64 + if (!rset_test(as->freeset, r)) + emit_spstore(as, IR(regcost_ref(as->cost[r])), r, SPOFS_TMP); +#endif + } +#if !LJ_SOFTFP + if ((need & 2)) { /* Copy FP spill slots. */ +#if LJ_TARGET_X86 + Reg r = RID_XMM0; +#else + Reg r = RID_FPRET; +#endif + if ((as->freeset & RSET_FPR)) + r = rset_pickbot((as->freeset & RSET_FPR)); + if (!rset_test(as->freeset, r)) + emit_spload(as, IR(regcost_ref(as->cost[r])), r, SPOFS_TMP); + for (ir = IR(as->orignins-1); ir->o == IR_PHI; ir--) { + if (ra_hasspill(ir->s)) { + IRIns *irl = IR(ir->op1); + if (ra_hasspill(irl->s) && irt_isfp(ir->t)) { + emit_spstore(as, irl, r, sps_scale(irl->s)); + emit_spload(as, ir, r, sps_scale(ir->s)); + checkmclim(as); + } + } + } + if (!rset_test(as->freeset, r)) + emit_spstore(as, IR(regcost_ref(as->cost[r])), r, SPOFS_TMP); + } +#endif +} + +/* Emit renames for left PHIs which are only spilled outside the loop. */ +static void asm_phi_fixup(ASMState *as) +{ + RegSet work = as->phiset; + while (work) { + Reg r = rset_picktop(work); + IRRef lref = as->phireg[r]; + IRIns *ir = IR(lref); + if (irt_ismarked(ir->t)) { + irt_clearmark(ir->t); + /* Left PHI gained a spill slot before the loop? */ + if (ra_hasspill(ir->s)) { + ra_addrename(as, r, lref, as->loopsnapno); + } + } + rset_clear(work, r); + } +} + +/* Setup right PHI reference. */ +static void asm_phi(ASMState *as, IRIns *ir) +{ + RegSet allow = ((!LJ_SOFTFP && irt_isfp(ir->t)) ? RSET_FPR : RSET_GPR) & + ~as->phiset; + RegSet afree = (as->freeset & allow); + IRIns *irl = IR(ir->op1); + IRIns *irr = IR(ir->op2); + if (ir->r == RID_SINK) /* Sink PHI. */ + return; + /* Spill slot shuffling is not implemented yet (but rarely needed). */ + if (ra_hasspill(irl->s) || ra_hasspill(irr->s)) + lj_trace_err(as->J, LJ_TRERR_NYIPHI); + /* Leave at least one register free for non-PHIs (and PHI cycle breaking). */ + if ((afree & (afree-1))) { /* Two or more free registers? */ + Reg r; + if (ra_noreg(irr->r)) { /* Get a register for the right PHI. */ + r = ra_allocref(as, ir->op2, allow); + } else { /* Duplicate right PHI, need a copy (rare). */ + r = ra_scratch(as, allow); + emit_movrr(as, irr, r, irr->r); + } + ir->r = (uint8_t)r; + rset_set(as->phiset, r); + as->phireg[r] = (IRRef1)ir->op1; + irt_setmark(irl->t); /* Marks left PHIs _with_ register. */ + if (ra_noreg(irl->r)) + ra_sethint(irl->r, r); /* Set register hint for left PHI. */ + } else { /* Otherwise allocate a spill slot. */ + /* This is overly restrictive, but it triggers only on synthetic code. */ + if (ra_hasreg(irl->r) || ra_hasreg(irr->r)) + lj_trace_err(as->J, LJ_TRERR_NYIPHI); + ra_spill(as, ir); + irr->s = ir->s; /* Set right PHI spill slot. Sync left slot later. */ + } +} + +static void asm_loop_fixup(ASMState *as); + +/* Middle part of a loop. */ +static void asm_loop(ASMState *as) +{ + MCode *mcspill; + /* LOOP is a guard, so the snapno is up to date. */ + as->loopsnapno = as->snapno; + if (as->gcsteps) + asm_gc_check(as); + /* LOOP marks the transition from the variant to the invariant part. */ + as->flagmcp = as->invmcp = NULL; + as->sectref = 0; + if (!neverfuse(as)) as->fuseref = 0; + asm_phi_shuffle(as); + mcspill = as->mcp; + asm_phi_copyspill(as); + asm_loop_fixup(as); + as->mcloop = as->mcp; + RA_DBGX((as, "===== LOOP =====")); + if (!as->realign) RA_DBG_FLUSH(); + if (as->mcp != mcspill) + emit_jmp(as, mcspill); +} + +/* -- Target-specific assembler ------------------------------------------- */ + +#if LJ_TARGET_X86ORX64 +#include "lj_asm_x86.h" +#elif LJ_TARGET_ARM +#include "lj_asm_arm.h" +#elif LJ_TARGET_ARM64 +#include "lj_asm_arm64.h" +#elif LJ_TARGET_PPC +#include "lj_asm_ppc.h" +#elif LJ_TARGET_MIPS +#include "lj_asm_mips.h" +#else +#error "Missing assembler for target CPU" +#endif + +/* -- Common instruction helpers ------------------------------------------ */ + +#if !LJ_SOFTFP32 +#if !LJ_TARGET_X86ORX64 +#define asm_ldexp(as, ir) asm_callid(as, ir, IRCALL_ldexp) +#endif + +static void asm_pow(ASMState *as, IRIns *ir) +{ +#if LJ_64 && LJ_HASFFI + if (!irt_isnum(ir->t)) + asm_callid(as, ir, irt_isi64(ir->t) ? IRCALL_lj_carith_powi64 : + IRCALL_lj_carith_powu64); + else +#endif + asm_callid(as, ir, IRCALL_pow); +} + +static void asm_div(ASMState *as, IRIns *ir) +{ +#if LJ_64 && LJ_HASFFI + if (!irt_isnum(ir->t)) + asm_callid(as, ir, irt_isi64(ir->t) ? IRCALL_lj_carith_divi64 : + IRCALL_lj_carith_divu64); + else +#endif + asm_fpdiv(as, ir); +} +#endif + +static void asm_mod(ASMState *as, IRIns *ir) +{ +#if LJ_64 && LJ_HASFFI + if (!irt_isint(ir->t)) + asm_callid(as, ir, irt_isi64(ir->t) ? IRCALL_lj_carith_modi64 : + IRCALL_lj_carith_modu64); + else +#endif + asm_callid(as, ir, IRCALL_lj_vm_modi); +} + +static void asm_fuseequal(ASMState *as, IRIns *ir) +{ + /* Fuse HREF + EQ/NE. */ + if ((ir-1)->o == IR_HREF && ir->op1 == as->curins-1) { + as->curins--; + asm_href(as, ir-1, (IROp)ir->o); + } else { + asm_equal(as, ir); + } +} + +static void asm_alen(ASMState *as, IRIns *ir) +{ + asm_callid(as, ir, ir->op2 == REF_NIL ? IRCALL_lj_tab_len : + IRCALL_lj_tab_len_hint); +} + +/* -- Instruction dispatch ------------------------------------------------ */ + +/* Assemble a single instruction. */ +static void asm_ir(ASMState *as, IRIns *ir) +{ + switch ((IROp)ir->o) { + /* Miscellaneous ops. */ + case IR_LOOP: asm_loop(as); break; + case IR_NOP: case IR_XBAR: + lj_assertA(!ra_used(ir), + "IR %04d not unused", (int)(ir - as->ir) - REF_BIAS); + break; + case IR_USE: + ra_alloc1(as, ir->op1, irt_isfp(ir->t) ? RSET_FPR : RSET_GPR); break; + case IR_PHI: asm_phi(as, ir); break; + case IR_HIOP: asm_hiop(as, ir); break; + case IR_GCSTEP: asm_gcstep(as, ir); break; + case IR_PROF: asm_prof(as, ir); break; + + /* Guarded assertions. */ + case IR_LT: case IR_GE: case IR_LE: case IR_GT: + case IR_ULT: case IR_UGE: case IR_ULE: case IR_UGT: + case IR_ABC: + asm_comp(as, ir); + break; + case IR_EQ: case IR_NE: asm_fuseequal(as, ir); break; + + case IR_RETF: asm_retf(as, ir); break; + + /* Bit ops. */ + case IR_BNOT: asm_bnot(as, ir); break; + case IR_BSWAP: asm_bswap(as, ir); break; + case IR_BAND: asm_band(as, ir); break; + case IR_BOR: asm_bor(as, ir); break; + case IR_BXOR: asm_bxor(as, ir); break; + case IR_BSHL: asm_bshl(as, ir); break; + case IR_BSHR: asm_bshr(as, ir); break; + case IR_BSAR: asm_bsar(as, ir); break; + case IR_BROL: asm_brol(as, ir); break; + case IR_BROR: asm_bror(as, ir); break; + + /* Arithmetic ops. */ + case IR_ADD: asm_add(as, ir); break; + case IR_SUB: asm_sub(as, ir); break; + case IR_MUL: asm_mul(as, ir); break; + case IR_MOD: asm_mod(as, ir); break; + case IR_NEG: asm_neg(as, ir); break; +#if LJ_SOFTFP32 + case IR_DIV: case IR_POW: case IR_ABS: + case IR_LDEXP: case IR_FPMATH: case IR_TOBIT: + /* Unused for LJ_SOFTFP32. */ + lj_assertA(0, "IR %04d with unused op %d", + (int)(ir - as->ir) - REF_BIAS, ir->o); + break; +#else + case IR_DIV: asm_div(as, ir); break; + case IR_POW: asm_pow(as, ir); break; + case IR_ABS: asm_abs(as, ir); break; + case IR_LDEXP: asm_ldexp(as, ir); break; + case IR_FPMATH: asm_fpmath(as, ir); break; + case IR_TOBIT: asm_tobit(as, ir); break; +#endif + case IR_MIN: asm_min(as, ir); break; + case IR_MAX: asm_max(as, ir); break; + + /* Overflow-checking arithmetic ops. */ + case IR_ADDOV: asm_addov(as, ir); break; + case IR_SUBOV: asm_subov(as, ir); break; + case IR_MULOV: asm_mulov(as, ir); break; + + /* Memory references. */ + case IR_AREF: asm_aref(as, ir); break; + case IR_HREF: asm_href(as, ir, 0); break; + case IR_HREFK: asm_hrefk(as, ir); break; + case IR_NEWREF: asm_newref(as, ir); break; + case IR_UREFO: case IR_UREFC: asm_uref(as, ir); break; + case IR_FREF: asm_fref(as, ir); break; + case IR_TMPREF: asm_tmpref(as, ir); break; + case IR_STRREF: asm_strref(as, ir); break; + case IR_LREF: asm_lref(as, ir); break; + + /* Loads and stores. */ + case IR_ALOAD: case IR_HLOAD: case IR_ULOAD: case IR_VLOAD: + asm_ahuvload(as, ir); + break; + case IR_FLOAD: asm_fload(as, ir); break; + case IR_XLOAD: asm_xload(as, ir); break; + case IR_SLOAD: asm_sload(as, ir); break; + case IR_ALEN: asm_alen(as, ir); break; + + case IR_ASTORE: case IR_HSTORE: case IR_USTORE: asm_ahustore(as, ir); break; + case IR_FSTORE: asm_fstore(as, ir); break; + case IR_XSTORE: asm_xstore(as, ir); break; + + /* Allocations. */ + case IR_SNEW: case IR_XSNEW: asm_snew(as, ir); break; + case IR_TNEW: asm_tnew(as, ir); break; + case IR_TDUP: asm_tdup(as, ir); break; + case IR_CNEW: case IR_CNEWI: +#if LJ_HASFFI + asm_cnew(as, ir); +#else + lj_assertA(0, "IR %04d with unused op %d", + (int)(ir - as->ir) - REF_BIAS, ir->o); +#endif + break; + + /* Buffer operations. */ + case IR_BUFHDR: asm_bufhdr(as, ir); break; + case IR_BUFPUT: asm_bufput(as, ir); break; + case IR_BUFSTR: asm_bufstr(as, ir); break; + + /* Write barriers. */ + case IR_TBAR: asm_tbar(as, ir); break; + case IR_OBAR: asm_obar(as, ir); break; + + /* Type conversions. */ + case IR_CONV: asm_conv(as, ir); break; + case IR_TOSTR: asm_tostr(as, ir); break; + case IR_STRTO: asm_strto(as, ir); break; + + /* Calls. */ + case IR_CALLA: + as->gcsteps++; + /* fallthrough */ + case IR_CALLN: case IR_CALLL: case IR_CALLS: asm_call(as, ir); break; + case IR_CALLXS: asm_callx(as, ir); break; + case IR_CARG: break; + + default: + setintV(&as->J->errinfo, ir->o); + lj_trace_err_info(as->J, LJ_TRERR_NYIIR); + break; + } +} + +/* -- Head of trace ------------------------------------------------------- */ + +/* Head of a root trace. */ +static void asm_head_root(ASMState *as) +{ + int32_t spadj; + asm_head_root_base(as); + emit_setvmstate(as, (int32_t)as->T->traceno); + spadj = asm_stack_adjust(as); + as->T->spadjust = (uint16_t)spadj; + emit_spsub(as, spadj); + /* Root traces assume a checked stack for the starting proto. */ + as->T->topslot = gcref(as->T->startpt)->pt.framesize; +} + +/* Head of a side trace. +** +** The current simplistic algorithm requires that all slots inherited +** from the parent are live in a register between pass 2 and pass 3. This +** avoids the complexity of stack slot shuffling. But of course this may +** overflow the register set in some cases and cause the dreaded error: +** "NYI: register coalescing too complex". A refined algorithm is needed. +*/ +static void asm_head_side(ASMState *as) +{ + IRRef1 sloadins[RID_MAX]; + RegSet allow = RSET_ALL; /* Inverse of all coalesced registers. */ + RegSet live = RSET_EMPTY; /* Live parent registers. */ + IRIns *irp = &as->parent->ir[REF_BASE]; /* Parent base. */ + int32_t spadj, spdelta; + int pass2 = 0; + int pass3 = 0; + IRRef i; + + if (as->snapno && as->topslot > as->parent->topslot) { + /* Force snap #0 alloc to prevent register overwrite in stack check. */ + asm_snap_alloc(as, 0); + } + allow = asm_head_side_base(as, irp, allow); + + /* Scan all parent SLOADs and collect register dependencies. */ + for (i = as->stopins; i > REF_BASE; i--) { + IRIns *ir = IR(i); + RegSP rs; + lj_assertA((ir->o == IR_SLOAD && (ir->op2 & IRSLOAD_PARENT)) || + (LJ_SOFTFP && ir->o == IR_HIOP) || ir->o == IR_PVAL, + "IR %04d has bad parent op %d", + (int)(ir - as->ir) - REF_BIAS, ir->o); + rs = as->parentmap[i - REF_FIRST]; + if (ra_hasreg(ir->r)) { + rset_clear(allow, ir->r); + if (ra_hasspill(ir->s)) { + ra_save(as, ir, ir->r); + checkmclim(as); + } + } else if (ra_hasspill(ir->s)) { + irt_setmark(ir->t); + pass2 = 1; + } + if (ir->r == rs) { /* Coalesce matching registers right now. */ + ra_free(as, ir->r); + } else if (ra_hasspill(regsp_spill(rs))) { + if (ra_hasreg(ir->r)) + pass3 = 1; + } else if (ra_used(ir)) { + sloadins[rs] = (IRRef1)i; + rset_set(live, rs); /* Block live parent register. */ + } + } + + /* Calculate stack frame adjustment. */ + spadj = asm_stack_adjust(as); + spdelta = spadj - (int32_t)as->parent->spadjust; + if (spdelta < 0) { /* Don't shrink the stack frame. */ + spadj = (int32_t)as->parent->spadjust; + spdelta = 0; + } + as->T->spadjust = (uint16_t)spadj; + + /* Reload spilled target registers. */ + if (pass2) { + for (i = as->stopins; i > REF_BASE; i--) { + IRIns *ir = IR(i); + if (irt_ismarked(ir->t)) { + RegSet mask; + Reg r; + RegSP rs; + irt_clearmark(ir->t); + rs = as->parentmap[i - REF_FIRST]; + if (!ra_hasspill(regsp_spill(rs))) + ra_sethint(ir->r, rs); /* Hint may be gone, set it again. */ + else if (sps_scale(regsp_spill(rs))+spdelta == sps_scale(ir->s)) + continue; /* Same spill slot, do nothing. */ + mask = ((!LJ_SOFTFP && irt_isfp(ir->t)) ? RSET_FPR : RSET_GPR) & allow; + if (mask == RSET_EMPTY) + lj_trace_err(as->J, LJ_TRERR_NYICOAL); + r = ra_allocref(as, i, mask); + ra_save(as, ir, r); + rset_clear(allow, r); + if (r == rs) { /* Coalesce matching registers right now. */ + ra_free(as, r); + rset_clear(live, r); + } else if (ra_hasspill(regsp_spill(rs))) { + pass3 = 1; + } + checkmclim(as); + } + } + } + + /* Store trace number and adjust stack frame relative to the parent. */ + emit_setvmstate(as, (int32_t)as->T->traceno); + emit_spsub(as, spdelta); + +#if !LJ_TARGET_X86ORX64 + /* Restore BASE register from parent spill slot. */ + if (ra_hasspill(irp->s)) + emit_spload(as, IR(REF_BASE), IR(REF_BASE)->r, sps_scale(irp->s)); +#endif + + /* Restore target registers from parent spill slots. */ + if (pass3) { + RegSet work = ~as->freeset & RSET_ALL; + while (work) { + Reg r = rset_pickbot(work); + IRRef ref = regcost_ref(as->cost[r]); + RegSP rs = as->parentmap[ref - REF_FIRST]; + rset_clear(work, r); + if (ra_hasspill(regsp_spill(rs))) { + int32_t ofs = sps_scale(regsp_spill(rs)); + ra_free(as, r); + emit_spload(as, IR(ref), r, ofs); + checkmclim(as); + } + } + } + + /* Shuffle registers to match up target regs with parent regs. */ + for (;;) { + RegSet work; + + /* Repeatedly coalesce free live registers by moving to their target. */ + while ((work = as->freeset & live) != RSET_EMPTY) { + Reg rp = rset_pickbot(work); + IRIns *ir = IR(sloadins[rp]); + rset_clear(live, rp); + rset_clear(allow, rp); + ra_free(as, ir->r); + emit_movrr(as, ir, ir->r, rp); + checkmclim(as); + } + + /* We're done if no live registers remain. */ + if (live == RSET_EMPTY) + break; + + /* Break cycles by renaming one target to a temp. register. */ + if (live & RSET_GPR) { + RegSet tmpset = as->freeset & ~live & allow & RSET_GPR; + if (tmpset == RSET_EMPTY) + lj_trace_err(as->J, LJ_TRERR_NYICOAL); + ra_rename(as, rset_pickbot(live & RSET_GPR), rset_pickbot(tmpset)); + } + if (!LJ_SOFTFP && (live & RSET_FPR)) { + RegSet tmpset = as->freeset & ~live & allow & RSET_FPR; + if (tmpset == RSET_EMPTY) + lj_trace_err(as->J, LJ_TRERR_NYICOAL); + ra_rename(as, rset_pickbot(live & RSET_FPR), rset_pickbot(tmpset)); + } + checkmclim(as); + /* Continue with coalescing to fix up the broken cycle(s). */ + } + + /* Inherit top stack slot already checked by parent trace. */ + as->T->topslot = as->parent->topslot; + if (as->topslot > as->T->topslot) { /* Need to check for higher slot? */ +#ifdef EXITSTATE_CHECKEXIT + /* Highest exit + 1 indicates stack check. */ + ExitNo exitno = as->T->nsnap; +#else + /* Reuse the parent exit in the context of the parent trace. */ + ExitNo exitno = as->J->exitno; +#endif + as->T->topslot = (uint8_t)as->topslot; /* Remember for child traces. */ + asm_stack_check(as, as->topslot, irp, allow & RSET_GPR, exitno); + } +} + +/* -- Tail of trace ------------------------------------------------------- */ + +/* Get base slot for a snapshot. */ +static BCReg asm_baseslot(ASMState *as, SnapShot *snap, int *gotframe) +{ + SnapEntry *map = &as->T->snapmap[snap->mapofs]; + MSize n; + for (n = snap->nent; n > 0; n--) { + SnapEntry sn = map[n-1]; + if ((sn & SNAP_FRAME)) { + *gotframe = 1; + return snap_slot(sn) - LJ_FR2; + } + } + return 0; +} + +/* Link to another trace. */ +static void asm_tail_link(ASMState *as) +{ + SnapNo snapno = as->T->nsnap-1; /* Last snapshot. */ + SnapShot *snap = &as->T->snap[snapno]; + int gotframe = 0; + BCReg baseslot = asm_baseslot(as, snap, &gotframe); + + as->topslot = snap->topslot; + checkmclim(as); + ra_allocref(as, REF_BASE, RID2RSET(RID_BASE)); + + if (as->T->link == 0) { + /* Setup fixed registers for exit to interpreter. */ + const BCIns *pc = snap_pc(&as->T->snapmap[snap->mapofs + snap->nent]); + int32_t mres; + if (bc_op(*pc) == BC_JLOOP) { /* NYI: find a better way to do this. */ + BCIns *retpc = &traceref(as->J, bc_d(*pc))->startins; + if (bc_isret(bc_op(*retpc))) + pc = retpc; + } +#if LJ_GC64 + emit_loadu64(as, RID_LPC, u64ptr(pc)); +#else + ra_allockreg(as, i32ptr(J2GG(as->J)->dispatch), RID_DISPATCH); + ra_allockreg(as, i32ptr(pc), RID_LPC); +#endif + mres = (int32_t)(snap->nslots - baseslot - LJ_FR2); + switch (bc_op(*pc)) { + case BC_CALLM: case BC_CALLMT: + mres -= (int32_t)(1 + LJ_FR2 + bc_a(*pc) + bc_c(*pc)); break; + case BC_RETM: mres -= (int32_t)(bc_a(*pc) + bc_d(*pc)); break; + case BC_TSETM: mres -= (int32_t)bc_a(*pc); break; + default: if (bc_op(*pc) < BC_FUNCF) mres = 0; break; + } + ra_allockreg(as, mres, RID_RET); /* Return MULTRES or 0. */ + } else if (baseslot) { + /* Save modified BASE for linking to trace with higher start frame. */ + emit_setgl(as, RID_BASE, jit_base); + } + emit_addptr(as, RID_BASE, 8*(int32_t)baseslot); + + if (as->J->ktrace) { /* Patch ktrace slot with the final GCtrace pointer. */ + setgcref(IR(as->J->ktrace)[LJ_GC64].gcr, obj2gco(as->J->curfinal)); + IR(as->J->ktrace)->o = IR_KGC; + } + + /* Sync the interpreter state with the on-trace state. */ + asm_stack_restore(as, snap); + + /* Root traces that add frames need to check the stack at the end. */ + if (!as->parent && gotframe) + asm_stack_check(as, as->topslot, NULL, as->freeset & RSET_GPR, snapno); +} + +/* -- Trace setup --------------------------------------------------------- */ + +/* Clear reg/sp for all instructions and add register hints. */ +static void asm_setup_regsp(ASMState *as) +{ + GCtrace *T = as->T; + int sink = T->sinktags; + IRRef nins = T->nins; + IRIns *ir, *lastir; + int inloop; +#if LJ_TARGET_ARM + uint32_t rload = 0xa6402a64; +#endif + + ra_setup(as); +#if LJ_TARGET_ARM64 + ra_setkref(as, RID_GL, (intptr_t)J2G(as->J)); +#endif + + /* Clear reg/sp for constants. */ + for (ir = IR(T->nk), lastir = IR(REF_BASE); ir < lastir; ir++) { + ir->prev = REGSP_INIT; + if (irt_is64(ir->t) && ir->o != IR_KNULL) { +#if LJ_GC64 + /* The false-positive of irt_is64() for ASMREF_L (REF_NIL) is OK here. */ + ir->i = 0; /* Will become non-zero only for RIP-relative addresses. */ +#else + /* Make life easier for backends by putting address of constant in i. */ + ir->i = (int32_t)(intptr_t)(ir+1); +#endif + ir++; + } + } + + /* REF_BASE is used for implicit references to the BASE register. */ + lastir->prev = REGSP_HINT(RID_BASE); + + as->snaprename = nins; + as->snapref = nins; + as->snapno = T->nsnap; + as->snapalloc = 0; + + as->stopins = REF_BASE; + as->orignins = nins; + as->curins = nins; + + /* Setup register hints for parent link instructions. */ + ir = IR(REF_FIRST); + if (as->parent) { + uint16_t *p; + lastir = lj_snap_regspmap(as->J, as->parent, as->J->exitno, ir); + if (lastir - ir > LJ_MAX_JSLOTS) + lj_trace_err(as->J, LJ_TRERR_NYICOAL); + as->stopins = (IRRef)((lastir-1) - as->ir); + for (p = as->parentmap; ir < lastir; ir++) { + RegSP rs = ir->prev; + *p++ = (uint16_t)rs; /* Copy original parent RegSP to parentmap. */ + if (!ra_hasspill(regsp_spill(rs))) + ir->prev = (uint16_t)REGSP_HINT(regsp_reg(rs)); + else + ir->prev = REGSP_INIT; + } + } + + inloop = 0; + as->evenspill = SPS_FIRST; + for (lastir = IR(nins); ir < lastir; ir++) { + if (sink) { + if (ir->r == RID_SINK) + continue; + if (ir->r == RID_SUNK) { /* Revert after ASM restart. */ + ir->r = RID_SINK; + continue; + } + } + switch (ir->o) { + case IR_LOOP: + inloop = 1; + break; +#if LJ_TARGET_ARM + case IR_SLOAD: + if (!((ir->op2 & IRSLOAD_TYPECHECK) || (ir+1)->o == IR_HIOP)) + break; + /* fallthrough */ + case IR_ALOAD: case IR_HLOAD: case IR_ULOAD: case IR_VLOAD: + if (!LJ_SOFTFP && irt_isnum(ir->t)) break; + ir->prev = (uint16_t)REGSP_HINT((rload & 15)); + rload = lj_ror(rload, 4); + continue; + case IR_TMPREF: + if ((ir->op2 & IRTMPREF_OUT2) && as->evenspill < 4) + as->evenspill = 4; /* TMPREF OUT2 needs two TValues on the stack. */ + break; +#endif + case IR_CALLXS: { + CCallInfo ci; + ci.flags = asm_callx_flags(as, ir); + ir->prev = asm_setup_call_slots(as, ir, &ci); + if (inloop) + as->modset |= RSET_SCRATCH; + continue; + } + case IR_CALLL: + /* lj_vm_next needs two TValues on the stack. */ +#if LJ_TARGET_X64 && LJ_ABI_WIN + if (ir->op2 == IRCALL_lj_vm_next && as->evenspill < SPS_FIRST + 4) + as->evenspill = SPS_FIRST + 4; +#else + if (SPS_FIRST < 4 && ir->op2 == IRCALL_lj_vm_next && as->evenspill < 4) + as->evenspill = 4; +#endif + /* fallthrough */ + case IR_CALLN: case IR_CALLA: case IR_CALLS: { + const CCallInfo *ci = &lj_ir_callinfo[ir->op2]; + ir->prev = asm_setup_call_slots(as, ir, ci); + if (inloop) + as->modset |= (ci->flags & CCI_NOFPRCLOBBER) ? + (RSET_SCRATCH & ~RSET_FPR) : RSET_SCRATCH; + continue; + } + case IR_HIOP: + switch ((ir-1)->o) { +#if LJ_SOFTFP && LJ_TARGET_ARM + case IR_SLOAD: case IR_ALOAD: case IR_HLOAD: case IR_ULOAD: case IR_VLOAD: + if (ra_hashint((ir-1)->r)) { + ir->prev = (ir-1)->prev + 1; + continue; + } + break; +#endif +#if !LJ_SOFTFP && LJ_NEED_FP64 && LJ_32 && LJ_HASFFI + case IR_CONV: + if (irt_isfp((ir-1)->t)) { + ir->prev = REGSP_HINT(RID_FPRET); + continue; + } +#endif + /* fallthrough */ + case IR_CALLN: case IR_CALLL: case IR_CALLS: case IR_CALLXS: +#if LJ_SOFTFP + case IR_MIN: case IR_MAX: +#endif + (ir-1)->prev = REGSP_HINT(RID_RETLO); + ir->prev = REGSP_HINT(RID_RETHI); + continue; + default: + break; + } + break; +#if LJ_SOFTFP + case IR_MIN: case IR_MAX: + if ((ir+1)->o != IR_HIOP) break; +#endif + /* fallthrough */ + /* C calls evict all scratch regs and return results in RID_RET. */ + case IR_SNEW: case IR_XSNEW: case IR_NEWREF: case IR_BUFPUT: + if (REGARG_NUMGPR < 3 && as->evenspill < 3) + as->evenspill = 3; /* lj_str_new and lj_tab_newkey need 3 args. */ +#if LJ_TARGET_X86 && LJ_HASFFI + if (0) { + case IR_CNEW: + if (ir->op2 != REF_NIL && as->evenspill < 4) + as->evenspill = 4; /* lj_cdata_newv needs 4 args. */ + } + /* fallthrough */ +#else + /* fallthrough */ + case IR_CNEW: +#endif + /* fallthrough */ + case IR_TNEW: case IR_TDUP: case IR_CNEWI: case IR_TOSTR: + case IR_BUFSTR: + ir->prev = REGSP_HINT(RID_RET); + if (inloop) + as->modset = RSET_SCRATCH; + continue; + case IR_STRTO: case IR_OBAR: + if (inloop) + as->modset = RSET_SCRATCH; + break; +#if !LJ_SOFTFP +#if !LJ_TARGET_X86ORX64 + case IR_LDEXP: +#endif +#endif + /* fallthrough */ + case IR_POW: + if (!LJ_SOFTFP && irt_isnum(ir->t)) { + if (inloop) + as->modset |= RSET_SCRATCH; +#if LJ_TARGET_X86 + if (irt_isnum(IR(ir->op2)->t)) { + if (as->evenspill < 4) /* Leave room to call pow(). */ + as->evenspill = 4; + } + break; +#else + ir->prev = REGSP_HINT(RID_FPRET); + continue; +#endif + } + /* fallthrough */ /* for integer POW */ + case IR_DIV: case IR_MOD: + if ((LJ_64 && LJ_SOFTFP) || !irt_isnum(ir->t)) { + ir->prev = REGSP_HINT(RID_RET); + if (inloop) + as->modset |= (RSET_SCRATCH & RSET_GPR); + continue; + } + break; +#if LJ_64 && LJ_SOFTFP + case IR_ADD: case IR_SUB: case IR_MUL: + if (irt_isnum(ir->t)) { + ir->prev = REGSP_HINT(RID_RET); + if (inloop) + as->modset |= (RSET_SCRATCH & RSET_GPR); + continue; + } + break; +#endif + case IR_FPMATH: +#if LJ_TARGET_X86ORX64 + if (ir->op2 <= IRFPM_TRUNC) { + if (!(as->flags & JIT_F_SSE4_1)) { + ir->prev = REGSP_HINT(RID_XMM0); + if (inloop) + as->modset |= RSET_RANGE(RID_XMM0, RID_XMM3+1)|RID2RSET(RID_EAX); + continue; + } + break; + } +#endif + if (inloop) + as->modset |= RSET_SCRATCH; +#if LJ_TARGET_X86 + break; +#else + ir->prev = REGSP_HINT(RID_FPRET); + continue; +#endif +#if LJ_TARGET_X86ORX64 + /* Non-constant shift counts need to be in RID_ECX on x86/x64. */ + case IR_BSHL: case IR_BSHR: case IR_BSAR: + if ((as->flags & JIT_F_BMI2)) /* Except if BMI2 is available. */ + break; + /* fallthrough */ + case IR_BROL: case IR_BROR: + if (!irref_isk(ir->op2) && !ra_hashint(IR(ir->op2)->r)) { + IR(ir->op2)->r = REGSP_HINT(RID_ECX); + if (inloop) + rset_set(as->modset, RID_ECX); + } + break; +#endif + /* Do not propagate hints across type conversions or loads. */ + case IR_TOBIT: + case IR_XLOAD: +#if !LJ_TARGET_ARM + case IR_ALOAD: case IR_HLOAD: case IR_ULOAD: case IR_VLOAD: +#endif + break; + case IR_CONV: + if (irt_isfp(ir->t) || (ir->op2 & IRCONV_SRCMASK) == IRT_NUM || + (ir->op2 & IRCONV_SRCMASK) == IRT_FLOAT) + break; + /* fallthrough */ + default: + /* Propagate hints across likely 'op reg, imm' or 'op reg'. */ + if (irref_isk(ir->op2) && !irref_isk(ir->op1) && + ra_hashint(regsp_reg(IR(ir->op1)->prev))) { + ir->prev = IR(ir->op1)->prev; + continue; + } + break; + } + ir->prev = REGSP_INIT; + } + if ((as->evenspill & 1)) + as->oddspill = as->evenspill++; + else + as->oddspill = 0; +} + +/* -- Assembler core ------------------------------------------------------ */ + +/* Assemble a trace. */ +void lj_asm_trace(jit_State *J, GCtrace *T) +{ + ASMState as_; + ASMState *as = &as_; + + /* Remove nops/renames left over from ASM restart due to LJ_TRERR_MCODELM. */ + { + IRRef nins = T->nins; + IRIns *ir = &T->ir[nins-1]; + if (ir->o == IR_NOP || ir->o == IR_RENAME) { + do { ir--; nins--; } while (ir->o == IR_NOP || ir->o == IR_RENAME); + T->nins = nins; + } + } + + /* Ensure an initialized instruction beyond the last one for HIOP checks. */ + /* This also allows one RENAME to be added without reallocating curfinal. */ + as->orignins = lj_ir_nextins(J); + lj_ir_nop(&J->cur.ir[as->orignins]); + + /* Setup initial state. Copy some fields to reduce indirections. */ + as->J = J; + as->T = T; + J->curfinal = lj_trace_alloc(J->L, T); /* This copies the IR, too. */ + as->flags = J->flags; + as->loopref = J->loopref; + as->realign = NULL; + as->loopinv = 0; + as->parent = J->parent ? traceref(J, J->parent) : NULL; + + /* Reserve MCode memory. */ + as->mctop = as->mctoporig = lj_mcode_reserve(J, &as->mcbot); + as->mcp = as->mctop; + as->mclim = as->mcbot + MCLIM_REDZONE; + asm_setup_target(as); + + /* + ** This is a loop, because the MCode may have to be (re-)assembled + ** multiple times: + ** + ** 1. as->realign is set (and the assembly aborted), if the arch-specific + ** backend wants the MCode to be aligned differently. + ** + ** This is currently only the case on x86/x64, where small loops get + ** an aligned loop body plus a short branch. Not much effort is wasted, + ** because the abort happens very quickly and only once. + ** + ** 2. The IR is immovable, since the MCode embeds pointers to various + ** constants inside the IR. But RENAMEs may need to be added to the IR + ** during assembly, which might grow and reallocate the IR. We check + ** at the end if the IR (in J->cur.ir) has actually grown, resize the + ** copy (in J->curfinal.ir) and try again. + ** + ** 95% of all traces have zero RENAMEs, 3% have one RENAME, 1.5% have + ** 2 RENAMEs and only 0.5% have more than that. That's why we opt to + ** always have one spare slot in the IR (see above), which means we + ** have to redo the assembly for only ~2% of all traces. + ** + ** Very, very rarely, this needs to be done repeatedly, since the + ** location of constants inside the IR (actually, reachability from + ** a global pointer) may affect register allocation and thus the + ** number of RENAMEs. + */ + for (;;) { + as->mcp = as->mctop; +#ifdef LUA_USE_ASSERT + as->mcp_prev = as->mcp; +#endif + as->ir = J->curfinal->ir; /* Use the copied IR. */ + as->curins = J->cur.nins = as->orignins; + + RA_DBG_START(); + RA_DBGX((as, "===== STOP =====")); + + /* General trace setup. Emit tail of trace. */ + asm_tail_prep(as); + as->mcloop = NULL; + as->flagmcp = NULL; + as->topslot = 0; + as->gcsteps = 0; + as->sectref = as->loopref; + as->fuseref = (as->flags & JIT_F_OPT_FUSE) ? as->loopref : FUSE_DISABLED; + asm_setup_regsp(as); + if (!as->loopref) + asm_tail_link(as); + + /* Assemble a trace in linear backwards order. */ + for (as->curins--; as->curins > as->stopins; as->curins--) { + IRIns *ir = IR(as->curins); + /* 64 bit types handled by SPLIT for 32 bit archs. */ + lj_assertA(!(LJ_32 && irt_isint64(ir->t)), + "IR %04d has unsplit 64 bit type", + (int)(ir - as->ir) - REF_BIAS); + asm_snap_prev(as); + if (!ra_used(ir) && !ir_sideeff(ir) && (as->flags & JIT_F_OPT_DCE)) + continue; /* Dead-code elimination can be soooo easy. */ + if (irt_isguard(ir->t)) + asm_snap_prep(as); + RA_DBG_REF(); + checkmclim(as); + asm_ir(as, ir); + } + + if (as->realign && J->curfinal->nins >= T->nins) + continue; /* Retry in case only the MCode needs to be realigned. */ + + /* Emit head of trace. */ + RA_DBG_REF(); + checkmclim(as); + if (as->gcsteps > 0) { + as->curins = as->T->snap[0].ref; + asm_snap_prep(as); /* The GC check is a guard. */ + asm_gc_check(as); + as->curins = as->stopins; + } + ra_evictk(as); + if (as->parent) + asm_head_side(as); + else + asm_head_root(as); + asm_phi_fixup(as); + + if (J->curfinal->nins >= T->nins) { /* IR didn't grow? */ + lj_assertA(J->curfinal->nk == T->nk, "unexpected IR constant growth"); + memcpy(J->curfinal->ir + as->orignins, T->ir + as->orignins, + (T->nins - as->orignins) * sizeof(IRIns)); /* Copy RENAMEs. */ + T->nins = J->curfinal->nins; + /* Fill mcofs of any unprocessed snapshots. */ + as->curins = REF_FIRST; + asm_snap_prev(as); + break; /* Done. */ + } + + /* Otherwise try again with a bigger IR. */ + lj_trace_free(J2G(J), J->curfinal); + J->curfinal = NULL; /* In case lj_trace_alloc() OOMs. */ + J->curfinal = lj_trace_alloc(J->L, T); + as->realign = NULL; + } + + RA_DBGX((as, "===== START ====")); + RA_DBG_FLUSH(); + if (as->freeset != RSET_ALL) + lj_trace_err(as->J, LJ_TRERR_BADRA); /* Ouch! Should never happen. */ + + /* Set trace entry point before fixing up tail to allow link to self. */ + T->mcode = as->mcp; + T->mcloop = as->mcloop ? (MSize)((char *)as->mcloop - (char *)as->mcp) : 0; + if (as->loopref) + asm_loop_tail_fixup(as); + else + asm_tail_fixup(as, T->link); /* Note: this may change as->mctop! */ + T->szmcode = (MSize)((char *)as->mctop - (char *)as->mcp); + asm_snap_fixup_mcofs(as); +#if LJ_TARGET_MCODE_FIXUP + asm_mcode_fixup(T->mcode, T->szmcode); +#endif + lj_mcode_sync(T->mcode, as->mctoporig); +} + +#undef IR + +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_asm.h b/fluent-bit/lib/luajit-3065c9/src/lj_asm.h new file mode 100644 index 00000000..f0a4f2d0 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_asm.h @@ -0,0 +1,17 @@ +/* +** IR assembler (SSA IR -> machine code). +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#ifndef _LJ_ASM_H +#define _LJ_ASM_H + +#include "lj_jit.h" + +#if LJ_HASJIT +LJ_FUNC void lj_asm_trace(jit_State *J, GCtrace *T); +LJ_FUNC void lj_asm_patchexit(jit_State *J, GCtrace *T, ExitNo exitno, + MCode *target); +#endif + +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_asm_arm.h b/fluent-bit/lib/luajit-3065c9/src/lj_asm_arm.h new file mode 100644 index 00000000..326330f4 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_asm_arm.h @@ -0,0 +1,2286 @@ +/* +** ARM IR assembler (SSA IR -> machine code). +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +/* -- Register allocator extensions --------------------------------------- */ + +/* Allocate a register with a hint. */ +static Reg ra_hintalloc(ASMState *as, IRRef ref, Reg hint, RegSet allow) +{ + Reg r = IR(ref)->r; + if (ra_noreg(r)) { + if (!ra_hashint(r) && !iscrossref(as, ref)) + ra_sethint(IR(ref)->r, hint); /* Propagate register hint. */ + r = ra_allocref(as, ref, allow); + } + ra_noweak(as, r); + return r; +} + +/* Allocate a scratch register pair. */ +static Reg ra_scratchpair(ASMState *as, RegSet allow) +{ + RegSet pick1 = as->freeset & allow; + RegSet pick2 = pick1 & (pick1 >> 1) & RSET_GPREVEN; + Reg r; + if (pick2) { + r = rset_picktop(pick2); + } else { + RegSet pick = pick1 & (allow >> 1) & RSET_GPREVEN; + if (pick) { + r = rset_picktop(pick); + ra_restore(as, regcost_ref(as->cost[r+1])); + } else { + pick = pick1 & (allow << 1) & RSET_GPRODD; + if (pick) { + r = ra_restore(as, regcost_ref(as->cost[rset_picktop(pick)-1])); + } else { + r = ra_evict(as, allow & (allow >> 1) & RSET_GPREVEN); + ra_restore(as, regcost_ref(as->cost[r+1])); + } + } + } + lj_assertA(rset_test(RSET_GPREVEN, r), "odd reg %d", r); + ra_modified(as, r); + ra_modified(as, r+1); + RA_DBGX((as, "scratchpair $r $r", r, r+1)); + return r; +} + +#if !LJ_SOFTFP +/* Allocate two source registers for three-operand instructions. */ +static Reg ra_alloc2(ASMState *as, IRIns *ir, RegSet allow) +{ + IRIns *irl = IR(ir->op1), *irr = IR(ir->op2); + Reg left = irl->r, right = irr->r; + if (ra_hasreg(left)) { + ra_noweak(as, left); + if (ra_noreg(right)) + right = ra_allocref(as, ir->op2, rset_exclude(allow, left)); + else + ra_noweak(as, right); + } else if (ra_hasreg(right)) { + ra_noweak(as, right); + left = ra_allocref(as, ir->op1, rset_exclude(allow, right)); + } else if (ra_hashint(right)) { + right = ra_allocref(as, ir->op2, allow); + left = ra_alloc1(as, ir->op1, rset_exclude(allow, right)); + } else { + left = ra_allocref(as, ir->op1, allow); + right = ra_alloc1(as, ir->op2, rset_exclude(allow, left)); + } + return left | (right << 8); +} +#endif + +/* -- Guard handling ------------------------------------------------------ */ + +/* Generate an exit stub group at the bottom of the reserved MCode memory. */ +static MCode *asm_exitstub_gen(ASMState *as, ExitNo group) +{ + MCode *mxp = as->mcbot; + int i; + if (mxp + 4*4+4*EXITSTUBS_PER_GROUP >= as->mctop) + asm_mclimit(as); + /* str lr, [sp]; bl ->vm_exit_handler; .long DISPATCH_address, group. */ + *mxp++ = ARMI_STR|ARMI_LS_P|ARMI_LS_U|ARMF_D(RID_LR)|ARMF_N(RID_SP); + *mxp = ARMI_BL|((((MCode *)(void *)lj_vm_exit_handler-mxp)-2)&0x00ffffffu); + mxp++; + *mxp++ = (MCode)i32ptr(J2GG(as->J)->dispatch); /* DISPATCH address */ + *mxp++ = group*EXITSTUBS_PER_GROUP; + for (i = 0; i < EXITSTUBS_PER_GROUP; i++) + *mxp++ = ARMI_B|((-6-i)&0x00ffffffu); + lj_mcode_sync(as->mcbot, mxp); + lj_mcode_commitbot(as->J, mxp); + as->mcbot = mxp; + as->mclim = as->mcbot + MCLIM_REDZONE; + return mxp - EXITSTUBS_PER_GROUP; +} + +/* Setup all needed exit stubs. */ +static void asm_exitstub_setup(ASMState *as, ExitNo nexits) +{ + ExitNo i; + if (nexits >= EXITSTUBS_PER_GROUP*LJ_MAX_EXITSTUBGR) + lj_trace_err(as->J, LJ_TRERR_SNAPOV); + for (i = 0; i < (nexits+EXITSTUBS_PER_GROUP-1)/EXITSTUBS_PER_GROUP; i++) + if (as->J->exitstubgroup[i] == NULL) + as->J->exitstubgroup[i] = asm_exitstub_gen(as, i); +} + +/* Emit conditional branch to exit for guard. */ +static void asm_guardcc(ASMState *as, ARMCC cc) +{ + MCode *target = exitstub_addr(as->J, as->snapno); + MCode *p = as->mcp; + if (LJ_UNLIKELY(p == as->invmcp)) { + as->loopinv = 1; + *p = ARMI_BL | ((target-p-2) & 0x00ffffffu); + emit_branch(as, ARMF_CC(ARMI_B, cc^1), p+1); + return; + } + emit_branch(as, ARMF_CC(ARMI_BL, cc), target); +} + +/* -- Operand fusion ------------------------------------------------------ */ + +/* Limit linear search to this distance. Avoids O(n^2) behavior. */ +#define CONFLICT_SEARCH_LIM 31 + +/* Check if there's no conflicting instruction between curins and ref. */ +static int noconflict(ASMState *as, IRRef ref, IROp conflict) +{ + IRIns *ir = as->ir; + IRRef i = as->curins; + if (i > ref + CONFLICT_SEARCH_LIM) + return 0; /* Give up, ref is too far away. */ + while (--i > ref) + if (ir[i].o == conflict) + return 0; /* Conflict found. */ + return 1; /* Ok, no conflict. */ +} + +/* Fuse the array base of colocated arrays. */ +static int32_t asm_fuseabase(ASMState *as, IRRef ref) +{ + IRIns *ir = IR(ref); + if (ir->o == IR_TNEW && ir->op1 <= LJ_MAX_COLOSIZE && + !neverfuse(as) && noconflict(as, ref, IR_NEWREF)) + return (int32_t)sizeof(GCtab); + return 0; +} + +/* Fuse array/hash/upvalue reference into register+offset operand. */ +static Reg asm_fuseahuref(ASMState *as, IRRef ref, int32_t *ofsp, RegSet allow, + int lim) +{ + IRIns *ir = IR(ref); + if (ra_noreg(ir->r)) { + if (ir->o == IR_AREF) { + if (mayfuse(as, ref)) { + if (irref_isk(ir->op2)) { + IRRef tab = IR(ir->op1)->op1; + int32_t ofs = asm_fuseabase(as, tab); + IRRef refa = ofs ? tab : ir->op1; + ofs += 8*IR(ir->op2)->i; + if (ofs > -lim && ofs < lim) { + *ofsp = ofs; + return ra_alloc1(as, refa, allow); + } + } + } + } else if (ir->o == IR_HREFK) { + if (mayfuse(as, ref)) { + int32_t ofs = (int32_t)(IR(ir->op2)->op2 * sizeof(Node)); + if (ofs < lim) { + *ofsp = ofs; + return ra_alloc1(as, ir->op1, allow); + } + } + } else if (ir->o == IR_UREFC) { + if (irref_isk(ir->op1)) { + GCfunc *fn = ir_kfunc(IR(ir->op1)); + int32_t ofs = i32ptr(&gcref(fn->l.uvptr[(ir->op2 >> 8)])->uv.tv); + *ofsp = (ofs & 255); /* Mask out less bits to allow LDRD. */ + return ra_allock(as, (ofs & ~255), allow); + } + } else if (ir->o == IR_TMPREF) { + *ofsp = 0; + return RID_SP; + } + } + *ofsp = 0; + return ra_alloc1(as, ref, allow); +} + +/* Fuse m operand into arithmetic/logic instructions. */ +static uint32_t asm_fuseopm(ASMState *as, ARMIns ai, IRRef ref, RegSet allow) +{ + IRIns *ir = IR(ref); + if (ra_hasreg(ir->r)) { + ra_noweak(as, ir->r); + return ARMF_M(ir->r); + } else if (irref_isk(ref)) { + uint32_t k = emit_isk12(ai, ir->i); + if (k) + return k; + } else if (mayfuse(as, ref)) { + if (ir->o >= IR_BSHL && ir->o <= IR_BROR) { + Reg m = ra_alloc1(as, ir->op1, allow); + ARMShift sh = ir->o == IR_BSHL ? ARMSH_LSL : + ir->o == IR_BSHR ? ARMSH_LSR : + ir->o == IR_BSAR ? ARMSH_ASR : ARMSH_ROR; + if (irref_isk(ir->op2)) { + return m | ARMF_SH(sh, (IR(ir->op2)->i & 31)); + } else { + Reg s = ra_alloc1(as, ir->op2, rset_exclude(allow, m)); + return m | ARMF_RSH(sh, s); + } + } else if (ir->o == IR_ADD && ir->op1 == ir->op2) { + Reg m = ra_alloc1(as, ir->op1, allow); + return m | ARMF_SH(ARMSH_LSL, 1); + } + } + return ra_allocref(as, ref, allow); +} + +/* Fuse shifts into loads/stores. Only bother with BSHL 2 => lsl #2. */ +static IRRef asm_fuselsl2(ASMState *as, IRRef ref) +{ + IRIns *ir = IR(ref); + if (ra_noreg(ir->r) && mayfuse(as, ref) && ir->o == IR_BSHL && + irref_isk(ir->op2) && IR(ir->op2)->i == 2) + return ir->op1; + return 0; /* No fusion. */ +} + +/* Fuse XLOAD/XSTORE reference into load/store operand. */ +static void asm_fusexref(ASMState *as, ARMIns ai, Reg rd, IRRef ref, + RegSet allow, int32_t ofs) +{ + IRIns *ir = IR(ref); + Reg base; + if (ra_noreg(ir->r) && canfuse(as, ir)) { + int32_t lim = (!LJ_SOFTFP && (ai & 0x08000000)) ? 1024 : + (ai & 0x04000000) ? 4096 : 256; + if (ir->o == IR_ADD) { + int32_t ofs2; + if (irref_isk(ir->op2) && + (ofs2 = ofs + IR(ir->op2)->i) > -lim && ofs2 < lim && + (!(!LJ_SOFTFP && (ai & 0x08000000)) || !(ofs2 & 3))) { + ofs = ofs2; + ref = ir->op1; + } else if (ofs == 0 && !(!LJ_SOFTFP && (ai & 0x08000000))) { + IRRef lref = ir->op1, rref = ir->op2; + Reg rn, rm; + if ((ai & 0x04000000)) { + IRRef sref = asm_fuselsl2(as, rref); + if (sref) { + rref = sref; + ai |= ARMF_SH(ARMSH_LSL, 2); + } else if ((sref = asm_fuselsl2(as, lref)) != 0) { + lref = rref; + rref = sref; + ai |= ARMF_SH(ARMSH_LSL, 2); + } + } + rn = ra_alloc1(as, lref, allow); + rm = ra_alloc1(as, rref, rset_exclude(allow, rn)); + if ((ai & 0x04000000)) ai |= ARMI_LS_R; + emit_dnm(as, ai|ARMI_LS_P|ARMI_LS_U, rd, rn, rm); + return; + } + } else if (ir->o == IR_STRREF && !(!LJ_SOFTFP && (ai & 0x08000000))) { + lj_assertA(ofs == 0, "bad usage"); + ofs = (int32_t)sizeof(GCstr); + if (irref_isk(ir->op2)) { + ofs += IR(ir->op2)->i; + ref = ir->op1; + } else if (irref_isk(ir->op1)) { + ofs += IR(ir->op1)->i; + ref = ir->op2; + } else { + /* NYI: Fuse ADD with constant. */ + Reg rn = ra_alloc1(as, ir->op1, allow); + uint32_t m = asm_fuseopm(as, 0, ir->op2, rset_exclude(allow, rn)); + if ((ai & 0x04000000)) + emit_lso(as, ai, rd, rd, ofs); + else + emit_lsox(as, ai, rd, rd, ofs); + emit_dn(as, ARMI_ADD^m, rd, rn); + return; + } + if (ofs <= -lim || ofs >= lim) { + Reg rn = ra_alloc1(as, ref, allow); + Reg rm = ra_allock(as, ofs, rset_exclude(allow, rn)); + if ((ai & 0x04000000)) ai |= ARMI_LS_R; + emit_dnm(as, ai|ARMI_LS_P|ARMI_LS_U, rd, rn, rm); + return; + } + } + } + base = ra_alloc1(as, ref, allow); +#if !LJ_SOFTFP + if ((ai & 0x08000000)) + emit_vlso(as, ai, rd, base, ofs); + else +#endif + if ((ai & 0x04000000)) + emit_lso(as, ai, rd, base, ofs); + else + emit_lsox(as, ai, rd, base, ofs); +} + +#if !LJ_SOFTFP +/* Fuse to multiply-add/sub instruction. */ +static int asm_fusemadd(ASMState *as, IRIns *ir, ARMIns ai, ARMIns air) +{ + IRRef lref = ir->op1, rref = ir->op2; + IRIns *irm; + if (lref != rref && + ((mayfuse(as, lref) && (irm = IR(lref), irm->o == IR_MUL) && + ra_noreg(irm->r)) || + (mayfuse(as, rref) && (irm = IR(rref), irm->o == IR_MUL) && + (rref = lref, ai = air, ra_noreg(irm->r))))) { + Reg dest = ra_dest(as, ir, RSET_FPR); + Reg add = ra_hintalloc(as, rref, dest, RSET_FPR); + Reg right, left = ra_alloc2(as, irm, + rset_exclude(rset_exclude(RSET_FPR, dest), add)); + right = (left >> 8); left &= 255; + emit_dnm(as, ai, (dest & 15), (left & 15), (right & 15)); + if (dest != add) emit_dm(as, ARMI_VMOV_D, (dest & 15), (add & 15)); + return 1; + } + return 0; +} +#endif + +/* -- Calls --------------------------------------------------------------- */ + +/* Generate a call to a C function. */ +static void asm_gencall(ASMState *as, const CCallInfo *ci, IRRef *args) +{ + uint32_t n, nargs = CCI_XNARGS(ci); + int32_t ofs = 0; +#if LJ_SOFTFP + Reg gpr = REGARG_FIRSTGPR; +#else + Reg gpr, fpr = REGARG_FIRSTFPR, fprodd = 0; +#endif + if ((void *)ci->func) + emit_call(as, (void *)ci->func); +#if !LJ_SOFTFP + for (gpr = REGARG_FIRSTGPR; gpr <= REGARG_LASTGPR; gpr++) + as->cost[gpr] = REGCOST(~0u, ASMREF_L); + gpr = REGARG_FIRSTGPR; +#endif + for (n = 0; n < nargs; n++) { /* Setup args. */ + IRRef ref = args[n]; + IRIns *ir = IR(ref); +#if !LJ_SOFTFP + if (ref && irt_isfp(ir->t)) { + RegSet of = as->freeset; + Reg src; + if (!LJ_ABI_SOFTFP && !(ci->flags & CCI_VARARG)) { + if (irt_isnum(ir->t)) { + if (fpr <= REGARG_LASTFPR) { + ra_leftov(as, fpr, ref); + fpr++; + continue; + } + } else if (fprodd) { /* Ick. */ + src = ra_alloc1(as, ref, RSET_FPR); + emit_dm(as, ARMI_VMOV_S, (fprodd & 15), (src & 15) | 0x00400000); + fprodd = 0; + continue; + } else if (fpr <= REGARG_LASTFPR) { + ra_leftov(as, fpr, ref); + fprodd = fpr++; + continue; + } + /* Workaround to protect argument GPRs from being used for remat. */ + as->freeset &= ~RSET_RANGE(REGARG_FIRSTGPR, REGARG_LASTGPR+1); + src = ra_alloc1(as, ref, RSET_FPR); /* May alloc GPR to remat FPR. */ + as->freeset |= (of & RSET_RANGE(REGARG_FIRSTGPR, REGARG_LASTGPR+1)); + fprodd = 0; + goto stackfp; + } + /* Workaround to protect argument GPRs from being used for remat. */ + as->freeset &= ~RSET_RANGE(REGARG_FIRSTGPR, REGARG_LASTGPR+1); + src = ra_alloc1(as, ref, RSET_FPR); /* May alloc GPR to remat FPR. */ + as->freeset |= (of & RSET_RANGE(REGARG_FIRSTGPR, REGARG_LASTGPR+1)); + if (irt_isnum(ir->t)) gpr = (gpr+1) & ~1u; + if (gpr <= REGARG_LASTGPR) { + lj_assertA(rset_test(as->freeset, gpr), + "reg %d not free", gpr); /* Must have been evicted. */ + if (irt_isnum(ir->t)) { + lj_assertA(rset_test(as->freeset, gpr+1), + "reg %d not free", gpr+1); /* Ditto. */ + emit_dnm(as, ARMI_VMOV_RR_D, gpr, gpr+1, (src & 15)); + gpr += 2; + } else { + emit_dn(as, ARMI_VMOV_R_S, gpr, (src & 15)); + gpr++; + } + } else { + stackfp: + if (irt_isnum(ir->t)) ofs = (ofs + 4) & ~4; + emit_spstore(as, ir, src, ofs); + ofs += irt_isnum(ir->t) ? 8 : 4; + } + } else +#endif + { + if (gpr <= REGARG_LASTGPR) { + lj_assertA(rset_test(as->freeset, gpr), + "reg %d not free", gpr); /* Must have been evicted. */ + if (ref) ra_leftov(as, gpr, ref); + gpr++; + } else { + if (ref) { + Reg r = ra_alloc1(as, ref, RSET_GPR); + emit_spstore(as, ir, r, ofs); + } + ofs += 4; + } + } + } +} + +/* Setup result reg/sp for call. Evict scratch regs. */ +static void asm_setupresult(ASMState *as, IRIns *ir, const CCallInfo *ci) +{ + RegSet drop = RSET_SCRATCH; + int hiop = ((ir+1)->o == IR_HIOP && !irt_isnil((ir+1)->t)); + if (ra_hasreg(ir->r)) + rset_clear(drop, ir->r); /* Dest reg handled below. */ + if (hiop && ra_hasreg((ir+1)->r)) + rset_clear(drop, (ir+1)->r); /* Dest reg handled below. */ + ra_evictset(as, drop); /* Evictions must be performed first. */ + if (ra_used(ir)) { + lj_assertA(!irt_ispri(ir->t), "PRI dest"); + if (!LJ_SOFTFP && irt_isfp(ir->t)) { + if (LJ_ABI_SOFTFP || (ci->flags & (CCI_CASTU64|CCI_VARARG))) { + Reg dest = (ra_dest(as, ir, RSET_FPR) & 15); + if (irt_isnum(ir->t)) + emit_dnm(as, ARMI_VMOV_D_RR, RID_RETLO, RID_RETHI, dest); + else + emit_dn(as, ARMI_VMOV_S_R, RID_RET, dest); + } else { + ra_destreg(as, ir, RID_FPRET); + } + } else if (hiop) { + ra_destpair(as, ir); + } else { + ra_destreg(as, ir, RID_RET); + } + } + UNUSED(ci); +} + +static void asm_callx(ASMState *as, IRIns *ir) +{ + IRRef args[CCI_NARGS_MAX*2]; + CCallInfo ci; + IRRef func; + IRIns *irf; + ci.flags = asm_callx_flags(as, ir); + asm_collectargs(as, ir, &ci, args); + asm_setupresult(as, ir, &ci); + func = ir->op2; irf = IR(func); + if (irf->o == IR_CARG) { func = irf->op1; irf = IR(func); } + if (irref_isk(func)) { /* Call to constant address. */ + ci.func = (ASMFunction)(void *)(irf->i); + } else { /* Need a non-argument register for indirect calls. */ + Reg freg = ra_alloc1(as, func, RSET_RANGE(RID_R4, RID_R12+1)); + emit_m(as, ARMI_BLXr, freg); + ci.func = (ASMFunction)(void *)0; + } + asm_gencall(as, &ci, args); +} + +/* -- Returns ------------------------------------------------------------- */ + +/* Return to lower frame. Guard that it goes to the right spot. */ +static void asm_retf(ASMState *as, IRIns *ir) +{ + Reg base = ra_alloc1(as, REF_BASE, RSET_GPR); + void *pc = ir_kptr(IR(ir->op2)); + int32_t delta = 1+LJ_FR2+bc_a(*((const BCIns *)pc - 1)); + as->topslot -= (BCReg)delta; + if ((int32_t)as->topslot < 0) as->topslot = 0; + irt_setmark(IR(REF_BASE)->t); /* Children must not coalesce with BASE reg. */ + /* Need to force a spill on REF_BASE now to update the stack slot. */ + emit_lso(as, ARMI_STR, base, RID_SP, ra_spill(as, IR(REF_BASE))); + emit_setgl(as, base, jit_base); + emit_addptr(as, base, -8*delta); + asm_guardcc(as, CC_NE); + emit_nm(as, ARMI_CMP, RID_TMP, + ra_allock(as, i32ptr(pc), rset_exclude(RSET_GPR, base))); + emit_lso(as, ARMI_LDR, RID_TMP, base, -4); +} + +/* -- Buffer operations --------------------------------------------------- */ + +#if LJ_HASBUFFER +static void asm_bufhdr_write(ASMState *as, Reg sb) +{ + Reg tmp = ra_scratch(as, rset_exclude(RSET_GPR, sb)); + IRIns irgc; + int32_t addr = i32ptr((void *)&J2G(as->J)->cur_L); + irgc.ot = IRT(0, IRT_PGC); /* GC type. */ + emit_storeofs(as, &irgc, RID_TMP, sb, offsetof(SBuf, L)); + if ((as->flags & JIT_F_ARMV6T2)) { + emit_dnm(as, ARMI_BFI, RID_TMP, lj_fls(SBUF_MASK_FLAG), tmp); + } else { + emit_dnm(as, ARMI_ORR, RID_TMP, RID_TMP, tmp); + emit_dn(as, ARMI_AND|ARMI_K12|SBUF_MASK_FLAG, tmp, tmp); + } + emit_lso(as, ARMI_LDR, RID_TMP, + ra_allock(as, (addr & ~4095), + rset_exclude(rset_exclude(RSET_GPR, sb), tmp)), + (addr & 4095)); + emit_loadofs(as, &irgc, tmp, sb, offsetof(SBuf, L)); +} +#endif + +/* -- Type conversions ---------------------------------------------------- */ + +#if !LJ_SOFTFP +static void asm_tointg(ASMState *as, IRIns *ir, Reg left) +{ + Reg tmp = ra_scratch(as, rset_exclude(RSET_FPR, left)); + Reg dest = ra_dest(as, ir, RSET_GPR); + asm_guardcc(as, CC_NE); + emit_d(as, ARMI_VMRS, 0); + emit_dm(as, ARMI_VCMP_D, (tmp & 15), (left & 15)); + emit_dm(as, ARMI_VCVT_F64_S32, (tmp & 15), (tmp & 15)); + emit_dn(as, ARMI_VMOV_R_S, dest, (tmp & 15)); + emit_dm(as, ARMI_VCVT_S32_F64, (tmp & 15), (left & 15)); +} + +static void asm_tobit(ASMState *as, IRIns *ir) +{ + RegSet allow = RSET_FPR; + Reg left = ra_alloc1(as, ir->op1, allow); + Reg right = ra_alloc1(as, ir->op2, rset_clear(allow, left)); + Reg tmp = ra_scratch(as, rset_clear(allow, right)); + Reg dest = ra_dest(as, ir, RSET_GPR); + emit_dn(as, ARMI_VMOV_R_S, dest, (tmp & 15)); + emit_dnm(as, ARMI_VADD_D, (tmp & 15), (left & 15), (right & 15)); +} +#endif + +static void asm_conv(ASMState *as, IRIns *ir) +{ + IRType st = (IRType)(ir->op2 & IRCONV_SRCMASK); +#if !LJ_SOFTFP + int stfp = (st == IRT_NUM || st == IRT_FLOAT); +#endif + IRRef lref = ir->op1; + /* 64 bit integer conversions are handled by SPLIT. */ + lj_assertA(!irt_isint64(ir->t) && !(st == IRT_I64 || st == IRT_U64), + "IR %04d has unsplit 64 bit type", + (int)(ir - as->ir) - REF_BIAS); +#if LJ_SOFTFP + /* FP conversions are handled by SPLIT. */ + lj_assertA(!irt_isfp(ir->t) && !(st == IRT_NUM || st == IRT_FLOAT), + "IR %04d has FP type", + (int)(ir - as->ir) - REF_BIAS); + /* Can't check for same types: SPLIT uses CONV int.int + BXOR for sfp NEG. */ +#else + lj_assertA(irt_type(ir->t) != st, "inconsistent types for CONV"); + if (irt_isfp(ir->t)) { + Reg dest = ra_dest(as, ir, RSET_FPR); + if (stfp) { /* FP to FP conversion. */ + emit_dm(as, st == IRT_NUM ? ARMI_VCVT_F32_F64 : ARMI_VCVT_F64_F32, + (dest & 15), (ra_alloc1(as, lref, RSET_FPR) & 15)); + } else { /* Integer to FP conversion. */ + Reg left = ra_alloc1(as, lref, RSET_GPR); + ARMIns ai = irt_isfloat(ir->t) ? + (st == IRT_INT ? ARMI_VCVT_F32_S32 : ARMI_VCVT_F32_U32) : + (st == IRT_INT ? ARMI_VCVT_F64_S32 : ARMI_VCVT_F64_U32); + emit_dm(as, ai, (dest & 15), (dest & 15)); + emit_dn(as, ARMI_VMOV_S_R, left, (dest & 15)); + } + } else if (stfp) { /* FP to integer conversion. */ + if (irt_isguard(ir->t)) { + /* Checked conversions are only supported from number to int. */ + lj_assertA(irt_isint(ir->t) && st == IRT_NUM, + "bad type for checked CONV"); + asm_tointg(as, ir, ra_alloc1(as, lref, RSET_FPR)); + } else { + Reg left = ra_alloc1(as, lref, RSET_FPR); + Reg tmp = ra_scratch(as, rset_exclude(RSET_FPR, left)); + Reg dest = ra_dest(as, ir, RSET_GPR); + ARMIns ai; + emit_dn(as, ARMI_VMOV_R_S, dest, (tmp & 15)); + ai = irt_isint(ir->t) ? + (st == IRT_NUM ? ARMI_VCVT_S32_F64 : ARMI_VCVT_S32_F32) : + (st == IRT_NUM ? ARMI_VCVT_U32_F64 : ARMI_VCVT_U32_F32); + emit_dm(as, ai, (tmp & 15), (left & 15)); + } + } else +#endif + { + Reg dest = ra_dest(as, ir, RSET_GPR); + if (st >= IRT_I8 && st <= IRT_U16) { /* Extend to 32 bit integer. */ + Reg left = ra_alloc1(as, lref, RSET_GPR); + lj_assertA(irt_isint(ir->t) || irt_isu32(ir->t), "bad type for CONV EXT"); + if ((as->flags & JIT_F_ARMV6)) { + ARMIns ai = st == IRT_I8 ? ARMI_SXTB : + st == IRT_U8 ? ARMI_UXTB : + st == IRT_I16 ? ARMI_SXTH : ARMI_UXTH; + emit_dm(as, ai, dest, left); + } else if (st == IRT_U8) { + emit_dn(as, ARMI_AND|ARMI_K12|255, dest, left); + } else { + uint32_t shift = st == IRT_I8 ? 24 : 16; + ARMShift sh = st == IRT_U16 ? ARMSH_LSR : ARMSH_ASR; + emit_dm(as, ARMI_MOV|ARMF_SH(sh, shift), dest, RID_TMP); + emit_dm(as, ARMI_MOV|ARMF_SH(ARMSH_LSL, shift), RID_TMP, left); + } + } else { /* Handle 32/32 bit no-op (cast). */ + ra_leftov(as, dest, lref); /* Do nothing, but may need to move regs. */ + } + } +} + +static void asm_strto(ASMState *as, IRIns *ir) +{ + const CCallInfo *ci = &lj_ir_callinfo[IRCALL_lj_strscan_num]; + IRRef args[2]; + Reg rlo = 0, rhi = 0, tmp; + int destused = ra_used(ir); + int32_t ofs = 0; + ra_evictset(as, RSET_SCRATCH); +#if LJ_SOFTFP + if (destused) { + if (ra_hasspill(ir->s) && ra_hasspill((ir+1)->s) && + (ir->s & 1) == 0 && ir->s + 1 == (ir+1)->s) { + int i; + for (i = 0; i < 2; i++) { + Reg r = (ir+i)->r; + if (ra_hasreg(r)) { + ra_free(as, r); + ra_modified(as, r); + emit_spload(as, ir+i, r, sps_scale((ir+i)->s)); + } + } + ofs = sps_scale(ir->s); + destused = 0; + } else { + rhi = ra_dest(as, ir+1, RSET_GPR); + rlo = ra_dest(as, ir, rset_exclude(RSET_GPR, rhi)); + } + } + asm_guardcc(as, CC_EQ); + if (destused) { + emit_lso(as, ARMI_LDR, rhi, RID_SP, 4); + emit_lso(as, ARMI_LDR, rlo, RID_SP, 0); + } +#else + UNUSED(rhi); + if (destused) { + if (ra_hasspill(ir->s)) { + ofs = sps_scale(ir->s); + destused = 0; + if (ra_hasreg(ir->r)) { + ra_free(as, ir->r); + ra_modified(as, ir->r); + emit_spload(as, ir, ir->r, ofs); + } + } else { + rlo = ra_dest(as, ir, RSET_FPR); + } + } + asm_guardcc(as, CC_EQ); + if (destused) + emit_vlso(as, ARMI_VLDR_D, rlo, RID_SP, 0); +#endif + emit_n(as, ARMI_CMP|ARMI_K12|0, RID_RET); /* Test return status. */ + args[0] = ir->op1; /* GCstr *str */ + args[1] = ASMREF_TMP1; /* TValue *n */ + asm_gencall(as, ci, args); + tmp = ra_releasetmp(as, ASMREF_TMP1); + if (ofs == 0) + emit_dm(as, ARMI_MOV, tmp, RID_SP); + else + emit_opk(as, ARMI_ADD, tmp, RID_SP, ofs, RSET_GPR); +} + +/* -- Memory references --------------------------------------------------- */ + +/* Get pointer to TValue. */ +static void asm_tvptr(ASMState *as, Reg dest, IRRef ref, MSize mode) +{ + if ((mode & IRTMPREF_IN1)) { + IRIns *ir = IR(ref); + if (irt_isnum(ir->t)) { + if ((mode & IRTMPREF_OUT1)) { +#if LJ_SOFTFP + lj_assertA(irref_isk(ref), "unsplit FP op"); + emit_dm(as, ARMI_MOV, dest, RID_SP); + emit_lso(as, ARMI_STR, + ra_allock(as, (int32_t)ir_knum(ir)->u32.lo, RSET_GPR), + RID_SP, 0); + emit_lso(as, ARMI_STR, + ra_allock(as, (int32_t)ir_knum(ir)->u32.hi, RSET_GPR), + RID_SP, 4); +#else + Reg src = ra_alloc1(as, ref, RSET_FPR); + emit_dm(as, ARMI_MOV, dest, RID_SP); + emit_vlso(as, ARMI_VSTR_D, src, RID_SP, 0); +#endif + } else if (irref_isk(ref)) { + /* Use the number constant itself as a TValue. */ + ra_allockreg(as, i32ptr(ir_knum(ir)), dest); + } else { +#if LJ_SOFTFP + lj_assertA(0, "unsplit FP op"); +#else + /* Otherwise force a spill and use the spill slot. */ + emit_opk(as, ARMI_ADD, dest, RID_SP, ra_spill(as, ir), RSET_GPR); +#endif + } + } else { + /* Otherwise use [sp] and [sp+4] to hold the TValue. + ** This assumes the following call has max. 4 args. + */ + Reg type; + emit_dm(as, ARMI_MOV, dest, RID_SP); + if (!irt_ispri(ir->t)) { + Reg src = ra_alloc1(as, ref, RSET_GPR); + emit_lso(as, ARMI_STR, src, RID_SP, 0); + } + if (LJ_SOFTFP && (ir+1)->o == IR_HIOP && !irt_isnil((ir+1)->t)) + type = ra_alloc1(as, ref+1, RSET_GPR); + else + type = ra_allock(as, irt_toitype(ir->t), RSET_GPR); + emit_lso(as, ARMI_STR, type, RID_SP, 4); + } + } else { + emit_dm(as, ARMI_MOV, dest, RID_SP); + } +} + +static void asm_aref(ASMState *as, IRIns *ir) +{ + Reg dest = ra_dest(as, ir, RSET_GPR); + Reg idx, base; + if (irref_isk(ir->op2)) { + IRRef tab = IR(ir->op1)->op1; + int32_t ofs = asm_fuseabase(as, tab); + IRRef refa = ofs ? tab : ir->op1; + uint32_t k = emit_isk12(ARMI_ADD, ofs + 8*IR(ir->op2)->i); + if (k) { + base = ra_alloc1(as, refa, RSET_GPR); + emit_dn(as, ARMI_ADD^k, dest, base); + return; + } + } + base = ra_alloc1(as, ir->op1, RSET_GPR); + idx = ra_alloc1(as, ir->op2, rset_exclude(RSET_GPR, base)); + emit_dnm(as, ARMI_ADD|ARMF_SH(ARMSH_LSL, 3), dest, base, idx); +} + +/* Inlined hash lookup. Specialized for key type and for const keys. +** The equivalent C code is: +** Node *n = hashkey(t, key); +** do { +** if (lj_obj_equal(&n->key, key)) return &n->val; +** } while ((n = nextnode(n))); +** return niltv(L); +*/ +static void asm_href(ASMState *as, IRIns *ir, IROp merge) +{ + RegSet allow = RSET_GPR; + int destused = ra_used(ir); + Reg dest = ra_dest(as, ir, allow); + Reg tab = ra_alloc1(as, ir->op1, rset_clear(allow, dest)); + Reg key = 0, keyhi = 0, keynumhi = RID_NONE, tmp = RID_TMP; + IRRef refkey = ir->op2; + IRIns *irkey = IR(refkey); + IRType1 kt = irkey->t; + int32_t k = 0, khi = emit_isk12(ARMI_CMP, irt_toitype(kt)); + uint32_t khash; + MCLabel l_end, l_loop; + rset_clear(allow, tab); + if (!irref_isk(refkey) || irt_isstr(kt)) { +#if LJ_SOFTFP + key = ra_alloc1(as, refkey, allow); + rset_clear(allow, key); + if (irkey[1].o == IR_HIOP) { + if (ra_hasreg((irkey+1)->r)) { + keynumhi = (irkey+1)->r; + keyhi = RID_TMP; + ra_noweak(as, keynumhi); + } else { + keyhi = keynumhi = ra_allocref(as, refkey+1, allow); + } + rset_clear(allow, keynumhi); + khi = 0; + } +#else + if (irt_isnum(kt)) { + key = ra_scratch(as, allow); + rset_clear(allow, key); + keyhi = keynumhi = ra_scratch(as, allow); + rset_clear(allow, keyhi); + khi = 0; + } else { + key = ra_alloc1(as, refkey, allow); + rset_clear(allow, key); + } +#endif + } else if (irt_isnum(kt)) { + int32_t val = (int32_t)ir_knum(irkey)->u32.lo; + k = emit_isk12(ARMI_CMP, val); + if (!k) { + key = ra_allock(as, val, allow); + rset_clear(allow, key); + } + val = (int32_t)ir_knum(irkey)->u32.hi; + khi = emit_isk12(ARMI_CMP, val); + if (!khi) { + keyhi = ra_allock(as, val, allow); + rset_clear(allow, keyhi); + } + } else if (!irt_ispri(kt)) { + k = emit_isk12(ARMI_CMP, irkey->i); + if (!k) { + key = ra_alloc1(as, refkey, allow); + rset_clear(allow, key); + } + } + if (!irt_ispri(kt)) + tmp = ra_scratchpair(as, allow); + + /* Key not found in chain: jump to exit (if merged) or load niltv. */ + l_end = emit_label(as); + as->invmcp = NULL; + if (merge == IR_NE) + asm_guardcc(as, CC_AL); + else if (destused) + emit_loada(as, dest, niltvg(J2G(as->J))); + + /* Follow hash chain until the end. */ + l_loop = --as->mcp; + emit_n(as, ARMI_CMP|ARMI_K12|0, dest); + emit_lso(as, ARMI_LDR, dest, dest, (int32_t)offsetof(Node, next)); + + /* Type and value comparison. */ + if (merge == IR_EQ) + asm_guardcc(as, CC_EQ); + else + emit_branch(as, ARMF_CC(ARMI_B, CC_EQ), l_end); + if (!irt_ispri(kt)) { + emit_nm(as, ARMF_CC(ARMI_CMP, CC_EQ)^k, tmp, key); + emit_nm(as, ARMI_CMP^khi, tmp+1, keyhi); + emit_lsox(as, ARMI_LDRD, tmp, dest, (int32_t)offsetof(Node, key)); + } else { + emit_n(as, ARMI_CMP^khi, tmp); + emit_lso(as, ARMI_LDR, tmp, dest, (int32_t)offsetof(Node, key.it)); + } + *l_loop = ARMF_CC(ARMI_B, CC_NE) | ((as->mcp-l_loop-2) & 0x00ffffffu); + + /* Load main position relative to tab->node into dest. */ + khash = irref_isk(refkey) ? ir_khash(as, irkey) : 1; + if (khash == 0) { + emit_lso(as, ARMI_LDR, dest, tab, (int32_t)offsetof(GCtab, node)); + } else { + emit_dnm(as, ARMI_ADD|ARMF_SH(ARMSH_LSL, 3), dest, dest, tmp); + emit_dnm(as, ARMI_ADD|ARMF_SH(ARMSH_LSL, 1), tmp, tmp, tmp); + if (irt_isstr(kt)) { /* Fetch of str->sid is cheaper than ra_allock. */ + emit_dnm(as, ARMI_AND, tmp, tmp+1, RID_TMP); + emit_lso(as, ARMI_LDR, dest, tab, (int32_t)offsetof(GCtab, node)); + emit_lso(as, ARMI_LDR, tmp+1, key, (int32_t)offsetof(GCstr, sid)); + emit_lso(as, ARMI_LDR, RID_TMP, tab, (int32_t)offsetof(GCtab, hmask)); + } else if (irref_isk(refkey)) { + emit_opk(as, ARMI_AND, tmp, RID_TMP, (int32_t)khash, + rset_exclude(rset_exclude(RSET_GPR, tab), dest)); + emit_lso(as, ARMI_LDR, dest, tab, (int32_t)offsetof(GCtab, node)); + emit_lso(as, ARMI_LDR, RID_TMP, tab, (int32_t)offsetof(GCtab, hmask)); + } else { /* Must match with hash*() in lj_tab.c. */ + if (ra_hasreg(keynumhi)) { /* Canonicalize +-0.0 to 0.0. */ + if (keyhi == RID_TMP) + emit_dm(as, ARMF_CC(ARMI_MOV, CC_NE), keyhi, keynumhi); + emit_d(as, ARMF_CC(ARMI_MOV, CC_EQ)|ARMI_K12|0, keyhi); + } + emit_dnm(as, ARMI_AND, tmp, tmp, RID_TMP); + emit_dnm(as, ARMI_SUB|ARMF_SH(ARMSH_ROR, 32-HASH_ROT3), tmp, tmp, tmp+1); + emit_lso(as, ARMI_LDR, dest, tab, (int32_t)offsetof(GCtab, node)); + emit_dnm(as, ARMI_EOR|ARMF_SH(ARMSH_ROR, 32-((HASH_ROT2+HASH_ROT1)&31)), + tmp, tmp+1, tmp); + emit_lso(as, ARMI_LDR, RID_TMP, tab, (int32_t)offsetof(GCtab, hmask)); + emit_dnm(as, ARMI_SUB|ARMF_SH(ARMSH_ROR, 32-HASH_ROT1), tmp+1, tmp+1, tmp); + if (ra_hasreg(keynumhi)) { + emit_dnm(as, ARMI_EOR, tmp+1, tmp, key); + emit_dnm(as, ARMI_ORR|ARMI_S, RID_TMP, tmp, key); /* Test for +-0.0. */ + emit_dnm(as, ARMI_ADD, tmp, keynumhi, keynumhi); +#if !LJ_SOFTFP + emit_dnm(as, ARMI_VMOV_RR_D, key, keynumhi, + (ra_alloc1(as, refkey, RSET_FPR) & 15)); +#endif + } else { + emit_dnm(as, ARMI_EOR, tmp+1, tmp, key); + emit_opk(as, ARMI_ADD, tmp, key, (int32_t)HASH_BIAS, + rset_exclude(rset_exclude(RSET_GPR, tab), key)); + } + } + } +} + +static void asm_hrefk(ASMState *as, IRIns *ir) +{ + IRIns *kslot = IR(ir->op2); + IRIns *irkey = IR(kslot->op1); + int32_t ofs = (int32_t)(kslot->op2 * sizeof(Node)); + int32_t kofs = ofs + (int32_t)offsetof(Node, key); + Reg dest = (ra_used(ir) || ofs > 4095) ? ra_dest(as, ir, RSET_GPR) : RID_NONE; + Reg node = ra_alloc1(as, ir->op1, RSET_GPR); + Reg key = RID_NONE, type = RID_TMP, idx = node; + RegSet allow = rset_exclude(RSET_GPR, node); + lj_assertA(ofs % sizeof(Node) == 0, "unaligned HREFK slot"); + if (ofs > 4095) { + idx = dest; + rset_clear(allow, dest); + kofs = (int32_t)offsetof(Node, key); + } else if (ra_hasreg(dest)) { + emit_opk(as, ARMI_ADD, dest, node, ofs, allow); + } + asm_guardcc(as, CC_NE); + if (!irt_ispri(irkey->t)) { + RegSet even = (as->freeset & allow); + even = even & (even >> 1) & RSET_GPREVEN; + if (even) { + key = ra_scratch(as, even); + if (rset_test(as->freeset, key+1)) { + type = key+1; + ra_modified(as, type); + } + } else { + key = ra_scratch(as, allow); + } + rset_clear(allow, key); + } + rset_clear(allow, type); + if (irt_isnum(irkey->t)) { + emit_opk(as, ARMF_CC(ARMI_CMP, CC_EQ), 0, type, + (int32_t)ir_knum(irkey)->u32.hi, allow); + emit_opk(as, ARMI_CMP, 0, key, + (int32_t)ir_knum(irkey)->u32.lo, allow); + } else { + if (ra_hasreg(key)) + emit_opk(as, ARMF_CC(ARMI_CMP, CC_EQ), 0, key, irkey->i, allow); + emit_n(as, ARMI_CMN|ARMI_K12|-irt_toitype(irkey->t), type); + } + emit_lso(as, ARMI_LDR, type, idx, kofs+4); + if (ra_hasreg(key)) emit_lso(as, ARMI_LDR, key, idx, kofs); + if (ofs > 4095) + emit_opk(as, ARMI_ADD, dest, node, ofs, RSET_GPR); +} + +static void asm_uref(ASMState *as, IRIns *ir) +{ + Reg dest = ra_dest(as, ir, RSET_GPR); + if (irref_isk(ir->op1)) { + GCfunc *fn = ir_kfunc(IR(ir->op1)); + MRef *v = &gcref(fn->l.uvptr[(ir->op2 >> 8)])->uv.v; + emit_lsptr(as, ARMI_LDR, dest, v); + } else { + Reg uv = ra_scratch(as, RSET_GPR); + Reg func = ra_alloc1(as, ir->op1, RSET_GPR); + if (ir->o == IR_UREFC) { + asm_guardcc(as, CC_NE); + emit_n(as, ARMI_CMP|ARMI_K12|1, RID_TMP); + emit_opk(as, ARMI_ADD, dest, uv, + (int32_t)offsetof(GCupval, tv), RSET_GPR); + emit_lso(as, ARMI_LDRB, RID_TMP, uv, (int32_t)offsetof(GCupval, closed)); + } else { + emit_lso(as, ARMI_LDR, dest, uv, (int32_t)offsetof(GCupval, v)); + } + emit_lso(as, ARMI_LDR, uv, func, + (int32_t)offsetof(GCfuncL, uvptr) + 4*(int32_t)(ir->op2 >> 8)); + } +} + +static void asm_fref(ASMState *as, IRIns *ir) +{ + UNUSED(as); UNUSED(ir); + lj_assertA(!ra_used(ir), "unfused FREF"); +} + +static void asm_strref(ASMState *as, IRIns *ir) +{ + Reg dest = ra_dest(as, ir, RSET_GPR); + IRRef ref = ir->op2, refk = ir->op1; + Reg r; + if (irref_isk(ref)) { + IRRef tmp = refk; refk = ref; ref = tmp; + } else if (!irref_isk(refk)) { + uint32_t k, m = ARMI_K12|sizeof(GCstr); + Reg right, left = ra_alloc1(as, ir->op1, RSET_GPR); + IRIns *irr = IR(ir->op2); + if (ra_hasreg(irr->r)) { + ra_noweak(as, irr->r); + right = irr->r; + } else if (mayfuse(as, irr->op2) && + irr->o == IR_ADD && irref_isk(irr->op2) && + (k = emit_isk12(ARMI_ADD, + (int32_t)sizeof(GCstr) + IR(irr->op2)->i))) { + m = k; + right = ra_alloc1(as, irr->op1, rset_exclude(RSET_GPR, left)); + } else { + right = ra_allocref(as, ir->op2, rset_exclude(RSET_GPR, left)); + } + emit_dn(as, ARMI_ADD^m, dest, dest); + emit_dnm(as, ARMI_ADD, dest, left, right); + return; + } + r = ra_alloc1(as, ref, RSET_GPR); + emit_opk(as, ARMI_ADD, dest, r, + sizeof(GCstr) + IR(refk)->i, rset_exclude(RSET_GPR, r)); +} + +/* -- Loads and stores ---------------------------------------------------- */ + +static ARMIns asm_fxloadins(ASMState *as, IRIns *ir) +{ + UNUSED(as); + switch (irt_type(ir->t)) { + case IRT_I8: return ARMI_LDRSB; + case IRT_U8: return ARMI_LDRB; + case IRT_I16: return ARMI_LDRSH; + case IRT_U16: return ARMI_LDRH; + case IRT_NUM: lj_assertA(!LJ_SOFTFP, "unsplit FP op"); return ARMI_VLDR_D; + case IRT_FLOAT: if (!LJ_SOFTFP) return ARMI_VLDR_S; /* fallthrough */ + default: return ARMI_LDR; + } +} + +static ARMIns asm_fxstoreins(ASMState *as, IRIns *ir) +{ + UNUSED(as); + switch (irt_type(ir->t)) { + case IRT_I8: case IRT_U8: return ARMI_STRB; + case IRT_I16: case IRT_U16: return ARMI_STRH; + case IRT_NUM: lj_assertA(!LJ_SOFTFP, "unsplit FP op"); return ARMI_VSTR_D; + case IRT_FLOAT: if (!LJ_SOFTFP) return ARMI_VSTR_S; /* fallthrough */ + default: return ARMI_STR; + } +} + +static void asm_fload(ASMState *as, IRIns *ir) +{ + Reg dest = ra_dest(as, ir, RSET_GPR); + ARMIns ai = asm_fxloadins(as, ir); + Reg idx; + int32_t ofs; + if (ir->op1 == REF_NIL) { /* FLOAD from GG_State with offset. */ + idx = ra_allock(as, (int32_t)(ir->op2<<2) + (int32_t)J2GG(as->J), RSET_GPR); + ofs = 0; + } else { + idx = ra_alloc1(as, ir->op1, RSET_GPR); + if (ir->op2 == IRFL_TAB_ARRAY) { + ofs = asm_fuseabase(as, ir->op1); + if (ofs) { /* Turn the t->array load into an add for colocated arrays. */ + emit_dn(as, ARMI_ADD|ARMI_K12|ofs, dest, idx); + return; + } + } + ofs = field_ofs[ir->op2]; + } + if ((ai & 0x04000000)) + emit_lso(as, ai, dest, idx, ofs); + else + emit_lsox(as, ai, dest, idx, ofs); +} + +static void asm_fstore(ASMState *as, IRIns *ir) +{ + if (ir->r != RID_SINK) { + Reg src = ra_alloc1(as, ir->op2, RSET_GPR); + IRIns *irf = IR(ir->op1); + Reg idx = ra_alloc1(as, irf->op1, rset_exclude(RSET_GPR, src)); + int32_t ofs = field_ofs[irf->op2]; + ARMIns ai = asm_fxstoreins(as, ir); + if ((ai & 0x04000000)) + emit_lso(as, ai, src, idx, ofs); + else + emit_lsox(as, ai, src, idx, ofs); + } +} + +static void asm_xload(ASMState *as, IRIns *ir) +{ + Reg dest = ra_dest(as, ir, + (!LJ_SOFTFP && irt_isfp(ir->t)) ? RSET_FPR : RSET_GPR); + lj_assertA(!(ir->op2 & IRXLOAD_UNALIGNED), "unaligned XLOAD"); + asm_fusexref(as, asm_fxloadins(as, ir), dest, ir->op1, RSET_GPR, 0); +} + +static void asm_xstore_(ASMState *as, IRIns *ir, int32_t ofs) +{ + if (ir->r != RID_SINK) { + Reg src = ra_alloc1(as, ir->op2, + (!LJ_SOFTFP && irt_isfp(ir->t)) ? RSET_FPR : RSET_GPR); + asm_fusexref(as, asm_fxstoreins(as, ir), src, ir->op1, + rset_exclude(RSET_GPR, src), ofs); + } +} + +#define asm_xstore(as, ir) asm_xstore_(as, ir, 0) + +static void asm_ahuvload(ASMState *as, IRIns *ir) +{ + int hiop = (LJ_SOFTFP && (ir+1)->o == IR_HIOP); + IRType t = hiop ? IRT_NUM : irt_type(ir->t); + Reg dest = RID_NONE, type = RID_NONE, idx; + RegSet allow = RSET_GPR; + int32_t ofs = 0; + if (hiop && ra_used(ir+1)) { + type = ra_dest(as, ir+1, allow); + rset_clear(allow, type); + } + if (ra_used(ir)) { + lj_assertA((LJ_SOFTFP ? 0 : irt_isnum(ir->t)) || + irt_isint(ir->t) || irt_isaddr(ir->t), + "bad load type %d", irt_type(ir->t)); + dest = ra_dest(as, ir, (!LJ_SOFTFP && t == IRT_NUM) ? RSET_FPR : allow); + rset_clear(allow, dest); + } + idx = asm_fuseahuref(as, ir->op1, &ofs, allow, + (!LJ_SOFTFP && t == IRT_NUM) ? 1024 : 4096); + if (ir->o == IR_VLOAD) ofs += 8 * ir->op2; + if (!hiop || type == RID_NONE) { + rset_clear(allow, idx); + if (ofs < 256 && ra_hasreg(dest) && (dest & 1) == 0 && + rset_test((as->freeset & allow), dest+1)) { + type = dest+1; + ra_modified(as, type); + } else { + type = RID_TMP; + } + } + asm_guardcc(as, t == IRT_NUM ? CC_HS : CC_NE); + emit_n(as, ARMI_CMN|ARMI_K12|-irt_toitype_(t), type); + if (ra_hasreg(dest)) { +#if !LJ_SOFTFP + if (t == IRT_NUM) + emit_vlso(as, ARMI_VLDR_D, dest, idx, ofs); + else +#endif + emit_lso(as, ARMI_LDR, dest, idx, ofs); + } + emit_lso(as, ARMI_LDR, type, idx, ofs+4); +} + +static void asm_ahustore(ASMState *as, IRIns *ir) +{ + if (ir->r != RID_SINK) { + RegSet allow = RSET_GPR; + Reg idx, src = RID_NONE, type = RID_NONE; + int32_t ofs = 0; +#if !LJ_SOFTFP + if (irt_isnum(ir->t)) { + src = ra_alloc1(as, ir->op2, RSET_FPR); + idx = asm_fuseahuref(as, ir->op1, &ofs, allow, 1024); + emit_vlso(as, ARMI_VSTR_D, src, idx, ofs); + } else +#endif + { + int hiop = (LJ_SOFTFP && (ir+1)->o == IR_HIOP); + if (!irt_ispri(ir->t)) { + src = ra_alloc1(as, ir->op2, allow); + rset_clear(allow, src); + } + if (hiop) + type = ra_alloc1(as, (ir+1)->op2, allow); + else + type = ra_allock(as, (int32_t)irt_toitype(ir->t), allow); + idx = asm_fuseahuref(as, ir->op1, &ofs, rset_exclude(allow, type), 4096); + if (ra_hasreg(src)) emit_lso(as, ARMI_STR, src, idx, ofs); + emit_lso(as, ARMI_STR, type, idx, ofs+4); + } + } +} + +static void asm_sload(ASMState *as, IRIns *ir) +{ + int32_t ofs = 8*((int32_t)ir->op1-1) + ((ir->op2 & IRSLOAD_FRAME) ? 4 : 0); + int hiop = (LJ_SOFTFP && (ir+1)->o == IR_HIOP); + IRType t = hiop ? IRT_NUM : irt_type(ir->t); + Reg dest = RID_NONE, type = RID_NONE, base; + RegSet allow = RSET_GPR; + lj_assertA(!(ir->op2 & IRSLOAD_PARENT), + "bad parent SLOAD"); /* Handled by asm_head_side(). */ + lj_assertA(irt_isguard(ir->t) || !(ir->op2 & IRSLOAD_TYPECHECK), + "inconsistent SLOAD variant"); +#if LJ_SOFTFP + lj_assertA(!(ir->op2 & IRSLOAD_CONVERT), + "unsplit SLOAD convert"); /* Handled by LJ_SOFTFP SPLIT. */ + if (hiop && ra_used(ir+1)) { + type = ra_dest(as, ir+1, allow); + rset_clear(allow, type); + } +#else + if ((ir->op2 & IRSLOAD_CONVERT) && irt_isguard(ir->t) && t == IRT_INT) { + dest = ra_scratch(as, RSET_FPR); + asm_tointg(as, ir, dest); + t = IRT_NUM; /* Continue with a regular number type check. */ + } else +#endif + if (ra_used(ir)) { + Reg tmp = RID_NONE; + if ((ir->op2 & IRSLOAD_CONVERT)) + tmp = ra_scratch(as, t == IRT_INT ? RSET_FPR : RSET_GPR); + lj_assertA((LJ_SOFTFP ? 0 : irt_isnum(ir->t)) || + irt_isint(ir->t) || irt_isaddr(ir->t), + "bad SLOAD type %d", irt_type(ir->t)); + dest = ra_dest(as, ir, (!LJ_SOFTFP && t == IRT_NUM) ? RSET_FPR : allow); + rset_clear(allow, dest); + base = ra_alloc1(as, REF_BASE, allow); + if ((ir->op2 & IRSLOAD_CONVERT)) { + if (t == IRT_INT) { + emit_dn(as, ARMI_VMOV_R_S, dest, (tmp & 15)); + emit_dm(as, ARMI_VCVT_S32_F64, (tmp & 15), (tmp & 15)); + t = IRT_NUM; /* Check for original type. */ + } else { + emit_dm(as, ARMI_VCVT_F64_S32, (dest & 15), (dest & 15)); + emit_dn(as, ARMI_VMOV_S_R, tmp, (dest & 15)); + t = IRT_INT; /* Check for original type. */ + } + dest = tmp; + } + goto dotypecheck; + } + base = ra_alloc1(as, REF_BASE, allow); +dotypecheck: + rset_clear(allow, base); + if ((ir->op2 & IRSLOAD_TYPECHECK)) { + if (ra_noreg(type)) { + if (ofs < 256 && ra_hasreg(dest) && (dest & 1) == 0 && + rset_test((as->freeset & allow), dest+1)) { + type = dest+1; + ra_modified(as, type); + } else { + type = RID_TMP; + } + } + asm_guardcc(as, t == IRT_NUM ? CC_HS : CC_NE); + if ((ir->op2 & IRSLOAD_KEYINDEX)) { + emit_n(as, ARMI_CMN|ARMI_K12|1, type); + emit_dn(as, ARMI_EOR^emit_isk12(ARMI_EOR, ~LJ_KEYINDEX), type, type); + } else { + emit_n(as, ARMI_CMN|ARMI_K12|-irt_toitype_(t), type); + } + } + if (ra_hasreg(dest)) { +#if !LJ_SOFTFP + if (t == IRT_NUM) { + if (ofs < 1024) { + emit_vlso(as, ARMI_VLDR_D, dest, base, ofs); + } else { + if (ra_hasreg(type)) emit_lso(as, ARMI_LDR, type, base, ofs+4); + emit_vlso(as, ARMI_VLDR_D, dest, RID_TMP, 0); + emit_opk(as, ARMI_ADD, RID_TMP, base, ofs, allow); + return; + } + } else +#endif + emit_lso(as, ARMI_LDR, dest, base, ofs); + } + if (ra_hasreg(type)) emit_lso(as, ARMI_LDR, type, base, ofs+4); +} + +/* -- Allocations --------------------------------------------------------- */ + +#if LJ_HASFFI +static void asm_cnew(ASMState *as, IRIns *ir) +{ + CTState *cts = ctype_ctsG(J2G(as->J)); + CTypeID id = (CTypeID)IR(ir->op1)->i; + CTSize sz; + CTInfo info = lj_ctype_info(cts, id, &sz); + const CCallInfo *ci = &lj_ir_callinfo[IRCALL_lj_mem_newgco]; + IRRef args[4]; + RegSet allow = (RSET_GPR & ~RSET_SCRATCH); + RegSet drop = RSET_SCRATCH; + lj_assertA(sz != CTSIZE_INVALID || (ir->o == IR_CNEW && ir->op2 != REF_NIL), + "bad CNEW/CNEWI operands"); + + as->gcsteps++; + if (ra_hasreg(ir->r)) + rset_clear(drop, ir->r); /* Dest reg handled below. */ + ra_evictset(as, drop); + if (ra_used(ir)) + ra_destreg(as, ir, RID_RET); /* GCcdata * */ + + /* Initialize immutable cdata object. */ + if (ir->o == IR_CNEWI) { + int32_t ofs = sizeof(GCcdata); + lj_assertA(sz == 4 || sz == 8, "bad CNEWI size %d", sz); + if (sz == 8) { + ofs += 4; ir++; + lj_assertA(ir->o == IR_HIOP, "expected HIOP for CNEWI"); + } + for (;;) { + Reg r = ra_alloc1(as, ir->op2, allow); + emit_lso(as, ARMI_STR, r, RID_RET, ofs); + rset_clear(allow, r); + if (ofs == sizeof(GCcdata)) break; + ofs -= 4; ir--; + } + } else if (ir->op2 != REF_NIL) { /* Create VLA/VLS/aligned cdata. */ + ci = &lj_ir_callinfo[IRCALL_lj_cdata_newv]; + args[0] = ASMREF_L; /* lua_State *L */ + args[1] = ir->op1; /* CTypeID id */ + args[2] = ir->op2; /* CTSize sz */ + args[3] = ASMREF_TMP1; /* CTSize align */ + asm_gencall(as, ci, args); + emit_loadi(as, ra_releasetmp(as, ASMREF_TMP1), (int32_t)ctype_align(info)); + return; + } + + /* Initialize gct and ctypeid. lj_mem_newgco() already sets marked. */ + { + uint32_t k = emit_isk12(ARMI_MOV, id); + Reg r = k ? RID_R1 : ra_allock(as, id, allow); + emit_lso(as, ARMI_STRB, RID_TMP, RID_RET, offsetof(GCcdata, gct)); + emit_lsox(as, ARMI_STRH, r, RID_RET, offsetof(GCcdata, ctypeid)); + emit_d(as, ARMI_MOV|ARMI_K12|~LJ_TCDATA, RID_TMP); + if (k) emit_d(as, ARMI_MOV^k, RID_R1); + } + args[0] = ASMREF_L; /* lua_State *L */ + args[1] = ASMREF_TMP1; /* MSize size */ + asm_gencall(as, ci, args); + ra_allockreg(as, (int32_t)(sz+sizeof(GCcdata)), + ra_releasetmp(as, ASMREF_TMP1)); +} +#endif + +/* -- Write barriers ------------------------------------------------------ */ + +static void asm_tbar(ASMState *as, IRIns *ir) +{ + Reg tab = ra_alloc1(as, ir->op1, RSET_GPR); + Reg link = ra_scratch(as, rset_exclude(RSET_GPR, tab)); + Reg gr = ra_allock(as, i32ptr(J2G(as->J)), + rset_exclude(rset_exclude(RSET_GPR, tab), link)); + Reg mark = RID_TMP; + MCLabel l_end = emit_label(as); + emit_lso(as, ARMI_STR, link, tab, (int32_t)offsetof(GCtab, gclist)); + emit_lso(as, ARMI_STRB, mark, tab, (int32_t)offsetof(GCtab, marked)); + emit_lso(as, ARMI_STR, tab, gr, + (int32_t)offsetof(global_State, gc.grayagain)); + emit_dn(as, ARMI_BIC|ARMI_K12|LJ_GC_BLACK, mark, mark); + emit_lso(as, ARMI_LDR, link, gr, + (int32_t)offsetof(global_State, gc.grayagain)); + emit_branch(as, ARMF_CC(ARMI_B, CC_EQ), l_end); + emit_n(as, ARMI_TST|ARMI_K12|LJ_GC_BLACK, mark); + emit_lso(as, ARMI_LDRB, mark, tab, (int32_t)offsetof(GCtab, marked)); +} + +static void asm_obar(ASMState *as, IRIns *ir) +{ + const CCallInfo *ci = &lj_ir_callinfo[IRCALL_lj_gc_barrieruv]; + IRRef args[2]; + MCLabel l_end; + Reg obj, val, tmp; + /* No need for other object barriers (yet). */ + lj_assertA(IR(ir->op1)->o == IR_UREFC, "bad OBAR type"); + ra_evictset(as, RSET_SCRATCH); + l_end = emit_label(as); + args[0] = ASMREF_TMP1; /* global_State *g */ + args[1] = ir->op1; /* TValue *tv */ + asm_gencall(as, ci, args); + if ((l_end[-1] >> 28) == CC_AL) + l_end[-1] = ARMF_CC(l_end[-1], CC_NE); + else + emit_branch(as, ARMF_CC(ARMI_B, CC_EQ), l_end); + ra_allockreg(as, i32ptr(J2G(as->J)), ra_releasetmp(as, ASMREF_TMP1)); + obj = IR(ir->op1)->r; + tmp = ra_scratch(as, rset_exclude(RSET_GPR, obj)); + emit_n(as, ARMF_CC(ARMI_TST, CC_NE)|ARMI_K12|LJ_GC_BLACK, tmp); + emit_n(as, ARMI_TST|ARMI_K12|LJ_GC_WHITES, RID_TMP); + val = ra_alloc1(as, ir->op2, rset_exclude(RSET_GPR, obj)); + emit_lso(as, ARMI_LDRB, tmp, obj, + (int32_t)offsetof(GCupval, marked)-(int32_t)offsetof(GCupval, tv)); + emit_lso(as, ARMI_LDRB, RID_TMP, val, (int32_t)offsetof(GChead, marked)); +} + +/* -- Arithmetic and logic operations ------------------------------------- */ + +#if !LJ_SOFTFP +static void asm_fparith(ASMState *as, IRIns *ir, ARMIns ai) +{ + Reg dest = ra_dest(as, ir, RSET_FPR); + Reg right, left = ra_alloc2(as, ir, RSET_FPR); + right = (left >> 8); left &= 255; + emit_dnm(as, ai, (dest & 15), (left & 15), (right & 15)); +} + +static void asm_fpunary(ASMState *as, IRIns *ir, ARMIns ai) +{ + Reg dest = ra_dest(as, ir, RSET_FPR); + Reg left = ra_hintalloc(as, ir->op1, dest, RSET_FPR); + emit_dm(as, ai, (dest & 15), (left & 15)); +} + +static void asm_callround(ASMState *as, IRIns *ir, int id) +{ + /* The modified regs must match with the *.dasc implementation. */ + RegSet drop = RID2RSET(RID_R0)|RID2RSET(RID_R1)|RID2RSET(RID_R2)| + RID2RSET(RID_R3)|RID2RSET(RID_R12); + RegSet of; + Reg dest, src; + ra_evictset(as, drop); + dest = ra_dest(as, ir, RSET_FPR); + emit_dnm(as, ARMI_VMOV_D_RR, RID_RETLO, RID_RETHI, (dest & 15)); + emit_call(as, id == IRFPM_FLOOR ? (void *)lj_vm_floor_sf : + id == IRFPM_CEIL ? (void *)lj_vm_ceil_sf : + (void *)lj_vm_trunc_sf); + /* Workaround to protect argument GPRs from being used for remat. */ + of = as->freeset; + as->freeset &= ~RSET_RANGE(RID_R0, RID_R1+1); + as->cost[RID_R0] = as->cost[RID_R1] = REGCOST(~0u, ASMREF_L); + src = ra_alloc1(as, ir->op1, RSET_FPR); /* May alloc GPR to remat FPR. */ + as->freeset |= (of & RSET_RANGE(RID_R0, RID_R1+1)); + emit_dnm(as, ARMI_VMOV_RR_D, RID_R0, RID_R1, (src & 15)); +} + +static void asm_fpmath(ASMState *as, IRIns *ir) +{ + if (ir->op2 <= IRFPM_TRUNC) + asm_callround(as, ir, ir->op2); + else if (ir->op2 == IRFPM_SQRT) + asm_fpunary(as, ir, ARMI_VSQRT_D); + else + asm_callid(as, ir, IRCALL_lj_vm_floor + ir->op2); +} +#endif + +static int asm_swapops(ASMState *as, IRRef lref, IRRef rref) +{ + IRIns *ir; + if (irref_isk(rref)) + return 0; /* Don't swap constants to the left. */ + if (irref_isk(lref)) + return 1; /* But swap constants to the right. */ + ir = IR(rref); + if ((ir->o >= IR_BSHL && ir->o <= IR_BROR) || + (ir->o == IR_ADD && ir->op1 == ir->op2)) + return 0; /* Don't swap fusable operands to the left. */ + ir = IR(lref); + if ((ir->o >= IR_BSHL && ir->o <= IR_BROR) || + (ir->o == IR_ADD && ir->op1 == ir->op2)) + return 1; /* But swap fusable operands to the right. */ + return 0; /* Otherwise don't swap. */ +} + +static void asm_intop(ASMState *as, IRIns *ir, ARMIns ai) +{ + IRRef lref = ir->op1, rref = ir->op2; + Reg left, dest = ra_dest(as, ir, RSET_GPR); + uint32_t m; + if (asm_swapops(as, lref, rref)) { + IRRef tmp = lref; lref = rref; rref = tmp; + if ((ai & ~ARMI_S) == ARMI_SUB || (ai & ~ARMI_S) == ARMI_SBC) + ai ^= (ARMI_SUB^ARMI_RSB); + } + left = ra_hintalloc(as, lref, dest, RSET_GPR); + m = asm_fuseopm(as, ai, rref, rset_exclude(RSET_GPR, left)); + if (irt_isguard(ir->t)) { /* For IR_ADDOV etc. */ + asm_guardcc(as, CC_VS); + ai |= ARMI_S; + } + emit_dn(as, ai^m, dest, left); +} + +/* Try to drop cmp r, #0. */ +static ARMIns asm_drop_cmp0(ASMState *as, ARMIns ai) +{ + if (as->flagmcp == as->mcp) { + uint32_t cc = (as->mcp[1] >> 28); + as->flagmcp = NULL; + if (cc <= CC_NE) { + as->mcp++; + ai |= ARMI_S; + } else if (cc == CC_GE) { + *++as->mcp ^= ((CC_GE^CC_PL) << 28); + ai |= ARMI_S; + } else if (cc == CC_LT) { + *++as->mcp ^= ((CC_LT^CC_MI) << 28); + ai |= ARMI_S; + } /* else: other conds don't work in general. */ + } + return ai; +} + +static void asm_intop_s(ASMState *as, IRIns *ir, ARMIns ai) +{ + asm_intop(as, ir, asm_drop_cmp0(as, ai)); +} + +static void asm_intneg(ASMState *as, IRIns *ir, ARMIns ai) +{ + Reg dest = ra_dest(as, ir, RSET_GPR); + Reg left = ra_hintalloc(as, ir->op1, dest, RSET_GPR); + emit_dn(as, ai|ARMI_K12|0, dest, left); +} + +/* NYI: use add/shift for MUL(OV) with constants. FOLD only does 2^k. */ +static void asm_intmul(ASMState *as, IRIns *ir) +{ + Reg dest = ra_dest(as, ir, RSET_GPR); + Reg left = ra_alloc1(as, ir->op1, rset_exclude(RSET_GPR, dest)); + Reg right = ra_alloc1(as, ir->op2, rset_exclude(RSET_GPR, left)); + Reg tmp = RID_NONE; + /* ARMv5 restriction: dest != left and dest_hi != left. */ + if (dest == left && left != right) { left = right; right = dest; } + if (irt_isguard(ir->t)) { /* IR_MULOV */ + if (!(as->flags & JIT_F_ARMV6) && dest == left) + tmp = left = ra_scratch(as, rset_exclude(RSET_GPR, left)); + asm_guardcc(as, CC_NE); + emit_nm(as, ARMI_TEQ|ARMF_SH(ARMSH_ASR, 31), RID_TMP, dest); + emit_dnm(as, ARMI_SMULL|ARMF_S(right), dest, RID_TMP, left); + } else { + if (!(as->flags & JIT_F_ARMV6) && dest == left) tmp = left = RID_TMP; + emit_nm(as, ARMI_MUL|ARMF_S(right), dest, left); + } + /* Only need this for the dest == left == right case. */ + if (ra_hasreg(tmp)) emit_dm(as, ARMI_MOV, tmp, right); +} + +static void asm_add(ASMState *as, IRIns *ir) +{ +#if !LJ_SOFTFP + if (irt_isnum(ir->t)) { + if (!asm_fusemadd(as, ir, ARMI_VMLA_D, ARMI_VMLA_D)) + asm_fparith(as, ir, ARMI_VADD_D); + return; + } +#endif + asm_intop_s(as, ir, ARMI_ADD); +} + +static void asm_sub(ASMState *as, IRIns *ir) +{ +#if !LJ_SOFTFP + if (irt_isnum(ir->t)) { + if (!asm_fusemadd(as, ir, ARMI_VNMLS_D, ARMI_VMLS_D)) + asm_fparith(as, ir, ARMI_VSUB_D); + return; + } +#endif + asm_intop_s(as, ir, ARMI_SUB); +} + +static void asm_mul(ASMState *as, IRIns *ir) +{ +#if !LJ_SOFTFP + if (irt_isnum(ir->t)) { + asm_fparith(as, ir, ARMI_VMUL_D); + return; + } +#endif + asm_intmul(as, ir); +} + +#define asm_addov(as, ir) asm_add(as, ir) +#define asm_subov(as, ir) asm_sub(as, ir) +#define asm_mulov(as, ir) asm_mul(as, ir) + +#if !LJ_SOFTFP +#define asm_fpdiv(as, ir) asm_fparith(as, ir, ARMI_VDIV_D) +#define asm_abs(as, ir) asm_fpunary(as, ir, ARMI_VABS_D) +#endif + +static void asm_neg(ASMState *as, IRIns *ir) +{ +#if !LJ_SOFTFP + if (irt_isnum(ir->t)) { + asm_fpunary(as, ir, ARMI_VNEG_D); + return; + } +#endif + asm_intneg(as, ir, ARMI_RSB); +} + +static void asm_bitop(ASMState *as, IRIns *ir, ARMIns ai) +{ + ai = asm_drop_cmp0(as, ai); + if (ir->op2 == 0) { + Reg dest = ra_dest(as, ir, RSET_GPR); + uint32_t m = asm_fuseopm(as, ai, ir->op1, RSET_GPR); + emit_d(as, ai^m, dest); + } else { + /* NYI: Turn BAND !k12 into uxtb, uxth or bfc or shl+shr. */ + asm_intop(as, ir, ai); + } +} + +#define asm_bnot(as, ir) asm_bitop(as, ir, ARMI_MVN) + +static void asm_bswap(ASMState *as, IRIns *ir) +{ + Reg dest = ra_dest(as, ir, RSET_GPR); + Reg left = ra_alloc1(as, ir->op1, RSET_GPR); + if ((as->flags & JIT_F_ARMV6)) { + emit_dm(as, ARMI_REV, dest, left); + } else { + Reg tmp2 = dest; + if (tmp2 == left) + tmp2 = ra_scratch(as, rset_exclude(rset_exclude(RSET_GPR, dest), left)); + emit_dnm(as, ARMI_EOR|ARMF_SH(ARMSH_LSR, 8), dest, tmp2, RID_TMP); + emit_dm(as, ARMI_MOV|ARMF_SH(ARMSH_ROR, 8), tmp2, left); + emit_dn(as, ARMI_BIC|ARMI_K12|256*8|255, RID_TMP, RID_TMP); + emit_dnm(as, ARMI_EOR|ARMF_SH(ARMSH_ROR, 16), RID_TMP, left, left); + } +} + +#define asm_band(as, ir) asm_bitop(as, ir, ARMI_AND) +#define asm_bor(as, ir) asm_bitop(as, ir, ARMI_ORR) +#define asm_bxor(as, ir) asm_bitop(as, ir, ARMI_EOR) + +static void asm_bitshift(ASMState *as, IRIns *ir, ARMShift sh) +{ + if (irref_isk(ir->op2)) { /* Constant shifts. */ + /* NYI: Turn SHL+SHR or BAND+SHR into uxtb, uxth or ubfx. */ + /* NYI: Turn SHL+ASR into sxtb, sxth or sbfx. */ + Reg dest = ra_dest(as, ir, RSET_GPR); + Reg left = ra_alloc1(as, ir->op1, RSET_GPR); + int32_t shift = (IR(ir->op2)->i & 31); + emit_dm(as, ARMI_MOV|ARMF_SH(sh, shift), dest, left); + } else { + Reg dest = ra_dest(as, ir, RSET_GPR); + Reg left = ra_alloc1(as, ir->op1, RSET_GPR); + Reg right = ra_alloc1(as, ir->op2, rset_exclude(RSET_GPR, left)); + emit_dm(as, ARMI_MOV|ARMF_RSH(sh, right), dest, left); + } +} + +#define asm_bshl(as, ir) asm_bitshift(as, ir, ARMSH_LSL) +#define asm_bshr(as, ir) asm_bitshift(as, ir, ARMSH_LSR) +#define asm_bsar(as, ir) asm_bitshift(as, ir, ARMSH_ASR) +#define asm_bror(as, ir) asm_bitshift(as, ir, ARMSH_ROR) +#define asm_brol(as, ir) lj_assertA(0, "unexpected BROL") + +static void asm_intmin_max(ASMState *as, IRIns *ir, int cc) +{ + uint32_t kcmp = 0, kmov = 0; + Reg dest = ra_dest(as, ir, RSET_GPR); + Reg left = ra_hintalloc(as, ir->op1, dest, RSET_GPR); + Reg right = 0; + if (irref_isk(ir->op2)) { + kcmp = emit_isk12(ARMI_CMP, IR(ir->op2)->i); + if (kcmp) kmov = emit_isk12(ARMI_MOV, IR(ir->op2)->i); + } + if (!kmov) { + kcmp = 0; + right = ra_alloc1(as, ir->op2, rset_exclude(RSET_GPR, left)); + } + if (kmov || dest != right) { + emit_dm(as, ARMF_CC(ARMI_MOV, cc)^kmov, dest, right); + cc ^= 1; /* Must use opposite conditions for paired moves. */ + } else { + cc ^= (CC_LT^CC_GT); /* Otherwise may swap CC_LT <-> CC_GT. */ + } + if (dest != left) emit_dm(as, ARMF_CC(ARMI_MOV, cc), dest, left); + emit_nm(as, ARMI_CMP^kcmp, left, right); +} + +#if LJ_SOFTFP +static void asm_sfpmin_max(ASMState *as, IRIns *ir, int cc) +{ + const CCallInfo *ci = &lj_ir_callinfo[IRCALL_softfp_cmp]; + RegSet drop = RSET_SCRATCH; + Reg r; + IRRef args[4]; + args[0] = ir->op1; args[1] = (ir+1)->op1; + args[2] = ir->op2; args[3] = (ir+1)->op2; + /* __aeabi_cdcmple preserves r0-r3. */ + if (ra_hasreg(ir->r)) rset_clear(drop, ir->r); + if (ra_hasreg((ir+1)->r)) rset_clear(drop, (ir+1)->r); + if (!rset_test(as->freeset, RID_R2) && + regcost_ref(as->cost[RID_R2]) == args[2]) rset_clear(drop, RID_R2); + if (!rset_test(as->freeset, RID_R3) && + regcost_ref(as->cost[RID_R3]) == args[3]) rset_clear(drop, RID_R3); + ra_evictset(as, drop); + ra_destpair(as, ir); + emit_dm(as, ARMF_CC(ARMI_MOV, cc), RID_RETHI, RID_R3); + emit_dm(as, ARMF_CC(ARMI_MOV, cc), RID_RETLO, RID_R2); + emit_call(as, (void *)ci->func); + for (r = RID_R0; r <= RID_R3; r++) + ra_leftov(as, r, args[r-RID_R0]); +} +#else +static void asm_fpmin_max(ASMState *as, IRIns *ir, int cc) +{ + Reg dest = (ra_dest(as, ir, RSET_FPR) & 15); + Reg right, left = ra_alloc2(as, ir, RSET_FPR); + right = ((left >> 8) & 15); left &= 15; + if (dest != left) emit_dm(as, ARMF_CC(ARMI_VMOV_D, cc^1), dest, left); + if (dest != right) emit_dm(as, ARMF_CC(ARMI_VMOV_D, cc), dest, right); + emit_d(as, ARMI_VMRS, 0); + emit_dm(as, ARMI_VCMP_D, left, right); +} +#endif + +static void asm_min_max(ASMState *as, IRIns *ir, int cc, int fcc) +{ +#if LJ_SOFTFP + UNUSED(fcc); +#else + if (irt_isnum(ir->t)) + asm_fpmin_max(as, ir, fcc); + else +#endif + asm_intmin_max(as, ir, cc); +} + +#define asm_min(as, ir) asm_min_max(as, ir, CC_GT, CC_PL) +#define asm_max(as, ir) asm_min_max(as, ir, CC_LT, CC_LE) + +/* -- Comparisons --------------------------------------------------------- */ + +/* Map of comparisons to flags. ORDER IR. */ +static const uint8_t asm_compmap[IR_ABC+1] = { + /* op FP swp int cc FP cc */ + /* LT */ CC_GE + (CC_HS << 4), + /* GE x */ CC_LT + (CC_HI << 4), + /* LE */ CC_GT + (CC_HI << 4), + /* GT x */ CC_LE + (CC_HS << 4), + /* ULT x */ CC_HS + (CC_LS << 4), + /* UGE */ CC_LO + (CC_LO << 4), + /* ULE x */ CC_HI + (CC_LO << 4), + /* UGT */ CC_LS + (CC_LS << 4), + /* EQ */ CC_NE + (CC_NE << 4), + /* NE */ CC_EQ + (CC_EQ << 4), + /* ABC */ CC_LS + (CC_LS << 4) /* Same as UGT. */ +}; + +#if LJ_SOFTFP +/* FP comparisons. */ +static void asm_sfpcomp(ASMState *as, IRIns *ir) +{ + const CCallInfo *ci = &lj_ir_callinfo[IRCALL_softfp_cmp]; + RegSet drop = RSET_SCRATCH; + Reg r; + IRRef args[4]; + int swp = (((ir->o ^ (ir->o >> 2)) & ~(ir->o >> 3) & 1) << 1); + args[swp^0] = ir->op1; args[swp^1] = (ir+1)->op1; + args[swp^2] = ir->op2; args[swp^3] = (ir+1)->op2; + /* __aeabi_cdcmple preserves r0-r3. This helps to reduce spills. */ + for (r = RID_R0; r <= RID_R3; r++) + if (!rset_test(as->freeset, r) && + regcost_ref(as->cost[r]) == args[r-RID_R0]) rset_clear(drop, r); + ra_evictset(as, drop); + asm_guardcc(as, (asm_compmap[ir->o] >> 4)); + emit_call(as, (void *)ci->func); + for (r = RID_R0; r <= RID_R3; r++) + ra_leftov(as, r, args[r-RID_R0]); +} +#else +/* FP comparisons. */ +static void asm_fpcomp(ASMState *as, IRIns *ir) +{ + Reg left, right; + ARMIns ai; + int swp = ((ir->o ^ (ir->o >> 2)) & ~(ir->o >> 3) & 1); + if (!swp && irref_isk(ir->op2) && ir_knum(IR(ir->op2))->u64 == 0) { + left = (ra_alloc1(as, ir->op1, RSET_FPR) & 15); + right = 0; + ai = ARMI_VCMPZ_D; + } else { + left = ra_alloc2(as, ir, RSET_FPR); + if (swp) { + right = (left & 15); left = ((left >> 8) & 15); + } else { + right = ((left >> 8) & 15); left &= 15; + } + ai = ARMI_VCMP_D; + } + asm_guardcc(as, (asm_compmap[ir->o] >> 4)); + emit_d(as, ARMI_VMRS, 0); + emit_dm(as, ai, left, right); +} +#endif + +/* Integer comparisons. */ +static void asm_intcomp(ASMState *as, IRIns *ir) +{ + ARMCC cc = (asm_compmap[ir->o] & 15); + IRRef lref = ir->op1, rref = ir->op2; + Reg left; + uint32_t m; + int cmpprev0 = 0; + lj_assertA(irt_isint(ir->t) || irt_isu32(ir->t) || irt_isaddr(ir->t), + "bad comparison data type %d", irt_type(ir->t)); + if (asm_swapops(as, lref, rref)) { + Reg tmp = lref; lref = rref; rref = tmp; + if (cc >= CC_GE) cc ^= 7; /* LT <-> GT, LE <-> GE */ + else if (cc > CC_NE) cc ^= 11; /* LO <-> HI, LS <-> HS */ + } + if (irref_isk(rref) && IR(rref)->i == 0) { + IRIns *irl = IR(lref); + cmpprev0 = (irl+1 == ir); + /* Combine comp(BAND(left, right), 0) into tst left, right. */ + if (cmpprev0 && irl->o == IR_BAND && !ra_used(irl)) { + IRRef blref = irl->op1, brref = irl->op2; + uint32_t m2 = 0; + Reg bleft; + if (asm_swapops(as, blref, brref)) { + Reg tmp = blref; blref = brref; brref = tmp; + } + if (irref_isk(brref)) { + m2 = emit_isk12(ARMI_AND, IR(brref)->i); + if ((m2 & (ARMI_AND^ARMI_BIC))) + goto notst; /* Not beneficial if we miss a constant operand. */ + } + if (cc == CC_GE) cc = CC_PL; + else if (cc == CC_LT) cc = CC_MI; + else if (cc > CC_NE) goto notst; /* Other conds don't work with tst. */ + bleft = ra_alloc1(as, blref, RSET_GPR); + if (!m2) m2 = asm_fuseopm(as, 0, brref, rset_exclude(RSET_GPR, bleft)); + asm_guardcc(as, cc); + emit_n(as, ARMI_TST^m2, bleft); + return; + } + } +notst: + left = ra_alloc1(as, lref, RSET_GPR); + m = asm_fuseopm(as, ARMI_CMP, rref, rset_exclude(RSET_GPR, left)); + asm_guardcc(as, cc); + emit_n(as, ARMI_CMP^m, left); + /* Signed comparison with zero and referencing previous ins? */ + if (cmpprev0 && (cc <= CC_NE || cc >= CC_GE)) + as->flagmcp = as->mcp; /* Allow elimination of the compare. */ +} + +static void asm_comp(ASMState *as, IRIns *ir) +{ +#if !LJ_SOFTFP + if (irt_isnum(ir->t)) + asm_fpcomp(as, ir); + else +#endif + asm_intcomp(as, ir); +} + +#define asm_equal(as, ir) asm_comp(as, ir) + +#if LJ_HASFFI +/* 64 bit integer comparisons. */ +static void asm_int64comp(ASMState *as, IRIns *ir) +{ + int signedcomp = (ir->o <= IR_GT); + ARMCC cclo, cchi; + Reg leftlo, lefthi; + uint32_t mlo, mhi; + RegSet allow = RSET_GPR, oldfree; + + /* Always use unsigned comparison for loword. */ + cclo = asm_compmap[ir->o + (signedcomp ? 4 : 0)] & 15; + leftlo = ra_alloc1(as, ir->op1, allow); + oldfree = as->freeset; + mlo = asm_fuseopm(as, ARMI_CMP, ir->op2, rset_clear(allow, leftlo)); + allow &= ~(oldfree & ~as->freeset); /* Update for allocs of asm_fuseopm. */ + + /* Use signed or unsigned comparison for hiword. */ + cchi = asm_compmap[ir->o] & 15; + lefthi = ra_alloc1(as, (ir+1)->op1, allow); + mhi = asm_fuseopm(as, ARMI_CMP, (ir+1)->op2, rset_clear(allow, lefthi)); + + /* All register allocations must be performed _before_ this point. */ + if (signedcomp) { + MCLabel l_around = emit_label(as); + asm_guardcc(as, cclo); + emit_n(as, ARMI_CMP^mlo, leftlo); + emit_branch(as, ARMF_CC(ARMI_B, CC_NE), l_around); + if (cchi == CC_GE || cchi == CC_LE) cchi ^= 6; /* GE -> GT, LE -> LT */ + asm_guardcc(as, cchi); + } else { + asm_guardcc(as, cclo); + emit_n(as, ARMF_CC(ARMI_CMP, CC_EQ)^mlo, leftlo); + } + emit_n(as, ARMI_CMP^mhi, lefthi); +} +#endif + +/* -- Split register ops -------------------------------------------------- */ + +/* Hiword op of a split 32/32 bit op. Previous op is the loword op. */ +static void asm_hiop(ASMState *as, IRIns *ir) +{ + /* HIOP is marked as a store because it needs its own DCE logic. */ + int uselo = ra_used(ir-1), usehi = ra_used(ir); /* Loword/hiword used? */ + if (LJ_UNLIKELY(!(as->flags & JIT_F_OPT_DCE))) uselo = usehi = 1; +#if LJ_HASFFI || LJ_SOFTFP + if ((ir-1)->o <= IR_NE) { /* 64 bit integer or FP comparisons. ORDER IR. */ + as->curins--; /* Always skip the loword comparison. */ +#if LJ_SOFTFP + if (!irt_isint(ir->t)) { + asm_sfpcomp(as, ir-1); + return; + } +#endif +#if LJ_HASFFI + asm_int64comp(as, ir-1); +#endif + return; +#if LJ_SOFTFP + } else if ((ir-1)->o == IR_MIN || (ir-1)->o == IR_MAX) { + as->curins--; /* Always skip the loword min/max. */ + if (uselo || usehi) + asm_sfpmin_max(as, ir-1, (ir-1)->o == IR_MIN ? CC_PL : CC_LE); + return; +#elif LJ_HASFFI + } else if ((ir-1)->o == IR_CONV) { + as->curins--; /* Always skip the CONV. */ + if (usehi || uselo) + asm_conv64(as, ir); + return; +#endif + } else if ((ir-1)->o == IR_XSTORE) { + if ((ir-1)->r != RID_SINK) + asm_xstore_(as, ir, 4); + return; + } +#endif + if (!usehi) return; /* Skip unused hiword op for all remaining ops. */ + switch ((ir-1)->o) { +#if LJ_HASFFI + case IR_ADD: + as->curins--; + asm_intop(as, ir, ARMI_ADC); + asm_intop(as, ir-1, ARMI_ADD|ARMI_S); + break; + case IR_SUB: + as->curins--; + asm_intop(as, ir, ARMI_SBC); + asm_intop(as, ir-1, ARMI_SUB|ARMI_S); + break; + case IR_NEG: + as->curins--; + asm_intneg(as, ir, ARMI_RSC); + asm_intneg(as, ir-1, ARMI_RSB|ARMI_S); + break; + case IR_CNEWI: + /* Nothing to do here. Handled by lo op itself. */ + break; +#endif +#if LJ_SOFTFP + case IR_SLOAD: case IR_ALOAD: case IR_HLOAD: case IR_ULOAD: case IR_VLOAD: + case IR_STRTO: + if (!uselo) + ra_allocref(as, ir->op1, RSET_GPR); /* Mark lo op as used. */ + break; + case IR_ASTORE: case IR_HSTORE: case IR_USTORE: case IR_TOSTR: case IR_TMPREF: + /* Nothing to do here. Handled by lo op itself. */ + break; +#endif + case IR_CALLN: case IR_CALLL: case IR_CALLS: case IR_CALLXS: + if (!uselo) + ra_allocref(as, ir->op1, RID2RSET(RID_RETLO)); /* Mark lo op as used. */ + break; + default: lj_assertA(0, "bad HIOP for op %d", (ir-1)->o); break; + } +} + +/* -- Profiling ----------------------------------------------------------- */ + +static void asm_prof(ASMState *as, IRIns *ir) +{ + UNUSED(ir); + asm_guardcc(as, CC_NE); + emit_n(as, ARMI_TST|ARMI_K12|HOOK_PROFILE, RID_TMP); + emit_lsptr(as, ARMI_LDRB, RID_TMP, (void *)&J2G(as->J)->hookmask); +} + +/* -- Stack handling ------------------------------------------------------ */ + +/* Check Lua stack size for overflow. Use exit handler as fallback. */ +static void asm_stack_check(ASMState *as, BCReg topslot, + IRIns *irp, RegSet allow, ExitNo exitno) +{ + Reg pbase; + uint32_t k; + if (irp) { + if (!ra_hasspill(irp->s)) { + pbase = irp->r; + lj_assertA(ra_hasreg(pbase), "base reg lost"); + } else if (allow) { + pbase = rset_pickbot(allow); + } else { + pbase = RID_RET; + emit_lso(as, ARMI_LDR, RID_RET, RID_SP, 0); /* Restore temp. register. */ + } + } else { + pbase = RID_BASE; + } + emit_branch(as, ARMF_CC(ARMI_BL, CC_LS), exitstub_addr(as->J, exitno)); + k = emit_isk12(0, (int32_t)(8*topslot)); + lj_assertA(k, "slot offset %d does not fit in K12", 8*topslot); + emit_n(as, ARMI_CMP^k, RID_TMP); + emit_dnm(as, ARMI_SUB, RID_TMP, RID_TMP, pbase); + emit_lso(as, ARMI_LDR, RID_TMP, RID_TMP, + (int32_t)offsetof(lua_State, maxstack)); + if (irp) { /* Must not spill arbitrary registers in head of side trace. */ + int32_t i = i32ptr(&J2G(as->J)->cur_L); + if (ra_hasspill(irp->s)) + emit_lso(as, ARMI_LDR, pbase, RID_SP, sps_scale(irp->s)); + emit_lso(as, ARMI_LDR, RID_TMP, RID_TMP, (i & 4095)); + if (ra_hasspill(irp->s) && !allow) + emit_lso(as, ARMI_STR, RID_RET, RID_SP, 0); /* Save temp. register. */ + emit_loadi(as, RID_TMP, (i & ~4095)); + } else { + emit_getgl(as, RID_TMP, cur_L); + } +} + +/* Restore Lua stack from on-trace state. */ +static void asm_stack_restore(ASMState *as, SnapShot *snap) +{ + SnapEntry *map = &as->T->snapmap[snap->mapofs]; + SnapEntry *flinks = &as->T->snapmap[snap_nextofs(as->T, snap)-1]; + MSize n, nent = snap->nent; + /* Store the value of all modified slots to the Lua stack. */ + for (n = 0; n < nent; n++) { + SnapEntry sn = map[n]; + BCReg s = snap_slot(sn); + int32_t ofs = 8*((int32_t)s-1); + IRRef ref = snap_ref(sn); + IRIns *ir = IR(ref); + if ((sn & SNAP_NORESTORE)) + continue; + if (irt_isnum(ir->t)) { +#if LJ_SOFTFP + RegSet odd = rset_exclude(RSET_GPRODD, RID_BASE); + Reg tmp; + /* LJ_SOFTFP: must be a number constant. */ + lj_assertA(irref_isk(ref), "unsplit FP op"); + tmp = ra_allock(as, (int32_t)ir_knum(ir)->u32.lo, + rset_exclude(RSET_GPREVEN, RID_BASE)); + emit_lso(as, ARMI_STR, tmp, RID_BASE, ofs); + if (rset_test(as->freeset, tmp+1)) odd = RID2RSET(tmp+1); + tmp = ra_allock(as, (int32_t)ir_knum(ir)->u32.hi, odd); + emit_lso(as, ARMI_STR, tmp, RID_BASE, ofs+4); +#else + Reg src = ra_alloc1(as, ref, RSET_FPR); + emit_vlso(as, ARMI_VSTR_D, src, RID_BASE, ofs); +#endif + } else { + RegSet odd = rset_exclude(RSET_GPRODD, RID_BASE); + Reg type; + lj_assertA(irt_ispri(ir->t) || irt_isaddr(ir->t) || irt_isinteger(ir->t), + "restore of IR type %d", irt_type(ir->t)); + if (!irt_ispri(ir->t)) { + Reg src = ra_alloc1(as, ref, rset_exclude(RSET_GPREVEN, RID_BASE)); + emit_lso(as, ARMI_STR, src, RID_BASE, ofs); + if (rset_test(as->freeset, src+1)) odd = RID2RSET(src+1); + } + if ((sn & (SNAP_CONT|SNAP_FRAME))) { + if (s == 0) continue; /* Do not overwrite link to previous frame. */ + type = ra_allock(as, (int32_t)(*flinks--), odd); +#if LJ_SOFTFP + } else if ((sn & SNAP_SOFTFPNUM)) { + type = ra_alloc1(as, ref+1, rset_exclude(RSET_GPRODD, RID_BASE)); +#endif + } else if ((sn & SNAP_KEYINDEX)) { + type = ra_allock(as, (int32_t)LJ_KEYINDEX, odd); + } else { + type = ra_allock(as, (int32_t)irt_toitype(ir->t), odd); + } + emit_lso(as, ARMI_STR, type, RID_BASE, ofs+4); + } + checkmclim(as); + } + lj_assertA(map + nent == flinks, "inconsistent frames in snapshot"); +} + +/* -- GC handling --------------------------------------------------------- */ + +/* Marker to prevent patching the GC check exit. */ +#define ARM_NOPATCH_GC_CHECK (ARMI_BIC|ARMI_K12) + +/* Check GC threshold and do one or more GC steps. */ +static void asm_gc_check(ASMState *as) +{ + const CCallInfo *ci = &lj_ir_callinfo[IRCALL_lj_gc_step_jit]; + IRRef args[2]; + MCLabel l_end; + Reg tmp1, tmp2; + ra_evictset(as, RSET_SCRATCH); + l_end = emit_label(as); + /* Exit trace if in GCSatomic or GCSfinalize. Avoids syncing GC objects. */ + asm_guardcc(as, CC_NE); /* Assumes asm_snap_prep() already done. */ + *--as->mcp = ARM_NOPATCH_GC_CHECK; + emit_n(as, ARMI_CMP|ARMI_K12|0, RID_RET); + args[0] = ASMREF_TMP1; /* global_State *g */ + args[1] = ASMREF_TMP2; /* MSize steps */ + asm_gencall(as, ci, args); + tmp1 = ra_releasetmp(as, ASMREF_TMP1); + tmp2 = ra_releasetmp(as, ASMREF_TMP2); + emit_loadi(as, tmp2, as->gcsteps); + /* Jump around GC step if GC total < GC threshold. */ + emit_branch(as, ARMF_CC(ARMI_B, CC_LS), l_end); + emit_nm(as, ARMI_CMP, RID_TMP, tmp2); + emit_lso(as, ARMI_LDR, tmp2, tmp1, + (int32_t)offsetof(global_State, gc.threshold)); + emit_lso(as, ARMI_LDR, RID_TMP, tmp1, + (int32_t)offsetof(global_State, gc.total)); + ra_allockreg(as, i32ptr(J2G(as->J)), tmp1); + as->gcsteps = 0; + checkmclim(as); +} + +/* -- Loop handling ------------------------------------------------------- */ + +/* Fixup the loop branch. */ +static void asm_loop_fixup(ASMState *as) +{ + MCode *p = as->mctop; + MCode *target = as->mcp; + if (as->loopinv) { /* Inverted loop branch? */ + /* asm_guardcc already inverted the bcc and patched the final bl. */ + p[-2] |= ((uint32_t)(target-p) & 0x00ffffffu); + } else { + p[-1] = ARMI_B | ((uint32_t)((target-p)-1) & 0x00ffffffu); + } +} + +/* Fixup the tail of the loop. */ +static void asm_loop_tail_fixup(ASMState *as) +{ + UNUSED(as); /* Nothing to do. */ +} + +/* -- Head of trace ------------------------------------------------------- */ + +/* Reload L register from g->cur_L. */ +static void asm_head_lreg(ASMState *as) +{ + IRIns *ir = IR(ASMREF_L); + if (ra_used(ir)) { + Reg r = ra_dest(as, ir, RSET_GPR); + emit_getgl(as, r, cur_L); + ra_evictk(as); + } +} + +/* Coalesce BASE register for a root trace. */ +static void asm_head_root_base(ASMState *as) +{ + IRIns *ir; + asm_head_lreg(as); + ir = IR(REF_BASE); + if (ra_hasreg(ir->r) && (rset_test(as->modset, ir->r) || irt_ismarked(ir->t))) + ra_spill(as, ir); + ra_destreg(as, ir, RID_BASE); +} + +/* Coalesce BASE register for a side trace. */ +static RegSet asm_head_side_base(ASMState *as, IRIns *irp, RegSet allow) +{ + IRIns *ir; + asm_head_lreg(as); + ir = IR(REF_BASE); + if (ra_hasreg(ir->r) && (rset_test(as->modset, ir->r) || irt_ismarked(ir->t))) + ra_spill(as, ir); + if (ra_hasspill(irp->s)) { + rset_clear(allow, ra_dest(as, ir, allow)); + } else { + Reg r = irp->r; + lj_assertA(ra_hasreg(r), "base reg lost"); + rset_clear(allow, r); + if (r != ir->r && !rset_test(as->freeset, r)) + ra_restore(as, regcost_ref(as->cost[r])); + ra_destreg(as, ir, r); + } + return allow; +} + +/* -- Tail of trace ------------------------------------------------------- */ + +/* Fixup the tail code. */ +static void asm_tail_fixup(ASMState *as, TraceNo lnk) +{ + MCode *p = as->mctop; + MCode *target; + int32_t spadj = as->T->spadjust; + if (spadj == 0) { + as->mctop = --p; + } else { + /* Patch stack adjustment. */ + uint32_t k = emit_isk12(ARMI_ADD, spadj); + lj_assertA(k, "stack adjustment %d does not fit in K12", spadj); + p[-2] = (ARMI_ADD^k) | ARMF_D(RID_SP) | ARMF_N(RID_SP); + } + /* Patch exit branch. */ + target = lnk ? traceref(as->J, lnk)->mcode : (MCode *)lj_vm_exit_interp; + p[-1] = ARMI_B|(((target-p)-1)&0x00ffffffu); +} + +/* Prepare tail of code. */ +static void asm_tail_prep(ASMState *as) +{ + MCode *p = as->mctop - 1; /* Leave room for exit branch. */ + if (as->loopref) { + as->invmcp = as->mcp = p; + } else { + as->mcp = p-1; /* Leave room for stack pointer adjustment. */ + as->invmcp = NULL; + } + *p = 0; /* Prevent load/store merging. */ +} + +/* -- Trace setup --------------------------------------------------------- */ + +/* Ensure there are enough stack slots for call arguments. */ +static Reg asm_setup_call_slots(ASMState *as, IRIns *ir, const CCallInfo *ci) +{ + IRRef args[CCI_NARGS_MAX*2]; + uint32_t i, nargs = CCI_XNARGS(ci); + int nslots = 0, ngpr = REGARG_NUMGPR, nfpr = REGARG_NUMFPR, fprodd = 0; + asm_collectargs(as, ir, ci, args); + for (i = 0; i < nargs; i++) { + if (!LJ_SOFTFP && args[i] && irt_isfp(IR(args[i])->t)) { + if (!LJ_ABI_SOFTFP && !(ci->flags & CCI_VARARG)) { + if (irt_isnum(IR(args[i])->t)) { + if (nfpr > 0) nfpr--; + else fprodd = 0, nslots = (nslots + 3) & ~1; + } else { + if (fprodd) fprodd--; + else if (nfpr > 0) fprodd = 1, nfpr--; + else nslots++; + } + } else if (irt_isnum(IR(args[i])->t)) { + ngpr &= ~1; + if (ngpr > 0) ngpr -= 2; else nslots += 2; + } else { + if (ngpr > 0) ngpr--; else nslots++; + } + } else { + if (ngpr > 0) ngpr--; else nslots++; + } + } + if (nslots > as->evenspill) /* Leave room for args in stack slots. */ + as->evenspill = nslots; + return REGSP_HINT(RID_RET); +} + +static void asm_setup_target(ASMState *as) +{ + /* May need extra exit for asm_stack_check on side traces. */ + asm_exitstub_setup(as, as->T->nsnap + (as->parent ? 1 : 0)); +} + +/* -- Trace patching ------------------------------------------------------ */ + +/* Patch exit jumps of existing machine code to a new target. */ +void lj_asm_patchexit(jit_State *J, GCtrace *T, ExitNo exitno, MCode *target) +{ + MCode *p = T->mcode; + MCode *pe = (MCode *)((char *)p + T->szmcode); + MCode *cstart = NULL, *cend = p; + MCode *mcarea = lj_mcode_patch(J, p, 0); + MCode *px = exitstub_addr(J, exitno) - 2; + for (; p < pe; p++) { + /* Look for bl_cc exitstub, replace with b_cc target. */ + uint32_t ins = *p; + if ((ins & 0x0f000000u) == 0x0b000000u && ins < 0xf0000000u && + ((ins ^ (px-p)) & 0x00ffffffu) == 0 && + p[-1] != ARM_NOPATCH_GC_CHECK) { + *p = (ins & 0xfe000000u) | (((target-p)-2) & 0x00ffffffu); + cend = p+1; + if (!cstart) cstart = p; + } + } + lj_assertJ(cstart != NULL, "exit stub %d not found", exitno); + lj_mcode_sync(cstart, cend); + lj_mcode_patch(J, mcarea, 1); +} + diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_asm_arm64.h b/fluent-bit/lib/luajit-3065c9/src/lj_asm_arm64.h new file mode 100644 index 00000000..1f44d023 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_asm_arm64.h @@ -0,0 +1,2070 @@ +/* +** ARM64 IR assembler (SSA IR -> machine code). +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +** +** Contributed by Djordje Kovacevic and Stefan Pejic from RT-RK.com. +** Sponsored by Cisco Systems, Inc. +*/ + +/* -- Register allocator extensions --------------------------------------- */ + +/* Allocate a register with a hint. */ +static Reg ra_hintalloc(ASMState *as, IRRef ref, Reg hint, RegSet allow) +{ + Reg r = IR(ref)->r; + if (ra_noreg(r)) { + if (!ra_hashint(r) && !iscrossref(as, ref)) + ra_sethint(IR(ref)->r, hint); /* Propagate register hint. */ + r = ra_allocref(as, ref, allow); + } + ra_noweak(as, r); + return r; +} + +/* Allocate two source registers for three-operand instructions. */ +static Reg ra_alloc2(ASMState *as, IRIns *ir, RegSet allow) +{ + IRIns *irl = IR(ir->op1), *irr = IR(ir->op2); + Reg left = irl->r, right = irr->r; + if (ra_hasreg(left)) { + ra_noweak(as, left); + if (ra_noreg(right)) + right = ra_allocref(as, ir->op2, rset_exclude(allow, left)); + else + ra_noweak(as, right); + } else if (ra_hasreg(right)) { + ra_noweak(as, right); + left = ra_allocref(as, ir->op1, rset_exclude(allow, right)); + } else if (ra_hashint(right)) { + right = ra_allocref(as, ir->op2, allow); + left = ra_alloc1(as, ir->op1, rset_exclude(allow, right)); + } else { + left = ra_allocref(as, ir->op1, allow); + right = ra_alloc1(as, ir->op2, rset_exclude(allow, left)); + } + return left | (right << 8); +} + +/* -- Guard handling ------------------------------------------------------ */ + +/* Setup all needed exit stubs. */ +static void asm_exitstub_setup(ASMState *as, ExitNo nexits) +{ + ExitNo i; + MCode *mxp = as->mctop; + if (mxp - (nexits + 3 + MCLIM_REDZONE) < as->mclim) + asm_mclimit(as); + /* 1: str lr,[sp]; bl ->vm_exit_handler; movz w0,traceno; bl <1; bl <1; ... */ + for (i = nexits-1; (int32_t)i >= 0; i--) + *--mxp = A64I_LE(A64I_BL | A64F_S26(-3-i)); + *--mxp = A64I_LE(A64I_MOVZw | A64F_U16(as->T->traceno)); + mxp--; + *mxp = A64I_LE(A64I_BL | A64F_S26(((MCode *)(void *)lj_vm_exit_handler-mxp))); + *--mxp = A64I_LE(A64I_STRx | A64F_D(RID_LR) | A64F_N(RID_SP)); + as->mctop = mxp; +} + +static MCode *asm_exitstub_addr(ASMState *as, ExitNo exitno) +{ + /* Keep this in-sync with exitstub_trace_addr(). */ + return as->mctop + exitno + 3; +} + +/* Emit conditional branch to exit for guard. */ +static void asm_guardcc(ASMState *as, A64CC cc) +{ + MCode *target = asm_exitstub_addr(as, as->snapno); + MCode *p = as->mcp; + if (LJ_UNLIKELY(p == as->invmcp)) { + as->loopinv = 1; + *p = A64I_B | A64F_S26(target-p); + emit_cond_branch(as, cc^1, p-1); + return; + } + emit_cond_branch(as, cc, target); +} + +/* Emit test and branch instruction to exit for guard. */ +static void asm_guardtnb(ASMState *as, A64Ins ai, Reg r, uint32_t bit) +{ + MCode *target = asm_exitstub_addr(as, as->snapno); + MCode *p = as->mcp; + if (LJ_UNLIKELY(p == as->invmcp)) { + as->loopinv = 1; + *p = A64I_B | A64F_S26(target-p); + emit_tnb(as, ai^0x01000000u, r, bit, p-1); + return; + } + emit_tnb(as, ai, r, bit, target); +} + +/* Emit compare and branch instruction to exit for guard. */ +static void asm_guardcnb(ASMState *as, A64Ins ai, Reg r) +{ + MCode *target = asm_exitstub_addr(as, as->snapno); + MCode *p = as->mcp; + if (LJ_UNLIKELY(p == as->invmcp)) { + as->loopinv = 1; + *p = A64I_B | A64F_S26(target-p); + emit_cnb(as, ai^0x01000000u, r, p-1); + return; + } + emit_cnb(as, ai, r, target); +} + +/* -- Operand fusion ------------------------------------------------------ */ + +/* Limit linear search to this distance. Avoids O(n^2) behavior. */ +#define CONFLICT_SEARCH_LIM 31 + +static int asm_isk32(ASMState *as, IRRef ref, int32_t *k) +{ + if (irref_isk(ref)) { + IRIns *ir = IR(ref); + if (ir->o == IR_KNULL || !irt_is64(ir->t)) { + *k = ir->i; + return 1; + } else if (checki32((int64_t)ir_k64(ir)->u64)) { + *k = (int32_t)ir_k64(ir)->u64; + return 1; + } + } + return 0; +} + +/* Check if there's no conflicting instruction between curins and ref. */ +static int noconflict(ASMState *as, IRRef ref, IROp conflict) +{ + IRIns *ir = as->ir; + IRRef i = as->curins; + if (i > ref + CONFLICT_SEARCH_LIM) + return 0; /* Give up, ref is too far away. */ + while (--i > ref) + if (ir[i].o == conflict) + return 0; /* Conflict found. */ + return 1; /* Ok, no conflict. */ +} + +/* Fuse the array base of colocated arrays. */ +static int32_t asm_fuseabase(ASMState *as, IRRef ref) +{ + IRIns *ir = IR(ref); + if (ir->o == IR_TNEW && ir->op1 <= LJ_MAX_COLOSIZE && + !neverfuse(as) && noconflict(as, ref, IR_NEWREF)) + return (int32_t)sizeof(GCtab); + return 0; +} + +#define FUSE_REG 0x40000000 + +/* Fuse array/hash/upvalue reference into register+offset operand. */ +static Reg asm_fuseahuref(ASMState *as, IRRef ref, int32_t *ofsp, RegSet allow, + A64Ins ins) +{ + IRIns *ir = IR(ref); + if (ra_noreg(ir->r)) { + if (ir->o == IR_AREF) { + if (mayfuse(as, ref)) { + if (irref_isk(ir->op2)) { + IRRef tab = IR(ir->op1)->op1; + int32_t ofs = asm_fuseabase(as, tab); + IRRef refa = ofs ? tab : ir->op1; + ofs += 8*IR(ir->op2)->i; + if (emit_checkofs(ins, ofs)) { + *ofsp = ofs; + return ra_alloc1(as, refa, allow); + } + } else { + Reg base = ra_alloc1(as, ir->op1, allow); + *ofsp = FUSE_REG|ra_alloc1(as, ir->op2, rset_exclude(allow, base)); + return base; + } + } + } else if (ir->o == IR_HREFK) { + if (mayfuse(as, ref)) { + int32_t ofs = (int32_t)(IR(ir->op2)->op2 * sizeof(Node)); + if (emit_checkofs(ins, ofs)) { + *ofsp = ofs; + return ra_alloc1(as, ir->op1, allow); + } + } + } else if (ir->o == IR_UREFC) { + if (irref_isk(ir->op1)) { + GCfunc *fn = ir_kfunc(IR(ir->op1)); + GCupval *uv = &gcref(fn->l.uvptr[(ir->op2 >> 8)])->uv; + int64_t ofs = glofs(as, &uv->tv); + if (emit_checkofs(ins, ofs)) { + *ofsp = (int32_t)ofs; + return RID_GL; + } + } + } else if (ir->o == IR_TMPREF) { + *ofsp = (int32_t)glofs(as, &J2G(as->J)->tmptv); + return RID_GL; + } + } + *ofsp = 0; + return ra_alloc1(as, ref, allow); +} + +/* Fuse m operand into arithmetic/logic instructions. */ +static uint32_t asm_fuseopm(ASMState *as, A64Ins ai, IRRef ref, RegSet allow) +{ + IRIns *ir = IR(ref); + if (ra_hasreg(ir->r)) { + ra_noweak(as, ir->r); + return A64F_M(ir->r); + } else if (irref_isk(ref)) { + uint32_t m; + int64_t k = get_k64val(as, ref); + if ((ai & 0x1f000000) == 0x0a000000) + m = emit_isk13(k, irt_is64(ir->t)); + else + m = emit_isk12(k); + if (m) + return m; + } else if (mayfuse(as, ref)) { + if ((ir->o >= IR_BSHL && ir->o <= IR_BSAR && irref_isk(ir->op2)) || + (ir->o == IR_ADD && ir->op1 == ir->op2)) { + A64Shift sh = ir->o == IR_BSHR ? A64SH_LSR : + ir->o == IR_BSAR ? A64SH_ASR : A64SH_LSL; + int shift = ir->o == IR_ADD ? 1 : + (IR(ir->op2)->i & (irt_is64(ir->t) ? 63 : 31)); + IRIns *irl = IR(ir->op1); + if (sh == A64SH_LSL && + irl->o == IR_CONV && + irl->op2 == ((IRT_I64<op1, allow); + return A64F_M(m) | A64F_EXSH(A64EX_SXTW, shift); + } else { + Reg m = ra_alloc1(as, ir->op1, allow); + return A64F_M(m) | A64F_SH(sh, shift); + } + } else if (ir->o == IR_CONV && + ir->op2 == ((IRT_I64<op1, allow); + return A64F_M(m) | A64F_EX(A64EX_SXTW); + } + } + return A64F_M(ra_allocref(as, ref, allow)); +} + +/* Fuse XLOAD/XSTORE reference into load/store operand. */ +static void asm_fusexref(ASMState *as, A64Ins ai, Reg rd, IRRef ref, + RegSet allow) +{ + IRIns *ir = IR(ref); + Reg base; + int32_t ofs = 0; + if (ra_noreg(ir->r) && canfuse(as, ir)) { + if (ir->o == IR_ADD) { + if (asm_isk32(as, ir->op2, &ofs) && emit_checkofs(ai, ofs)) { + ref = ir->op1; + } else { + Reg rn, rm; + IRRef lref = ir->op1, rref = ir->op2; + IRIns *irl = IR(lref); + if (mayfuse(as, irl->op1)) { + unsigned int shift = 4; + if (irl->o == IR_BSHL && irref_isk(irl->op2)) { + shift = (IR(irl->op2)->i & 63); + } else if (irl->o == IR_ADD && irl->op1 == irl->op2) { + shift = 1; + } + if ((ai >> 30) == shift) { + lref = irl->op1; + irl = IR(lref); + ai |= A64I_LS_SH; + } + } + if (irl->o == IR_CONV && + irl->op2 == ((IRT_I64<op1; + ai |= A64I_LS_SXTWx; + } else { + ai |= A64I_LS_LSLx; + } + rm = ra_alloc1(as, lref, allow); + rn = ra_alloc1(as, rref, rset_exclude(allow, rm)); + emit_dnm(as, (ai^A64I_LS_R), (rd & 31), rn, rm); + return; + } + } else if (ir->o == IR_STRREF) { + if (asm_isk32(as, ir->op2, &ofs)) { + ref = ir->op1; + } else if (asm_isk32(as, ir->op1, &ofs)) { + ref = ir->op2; + } else { + Reg refk = irref_isk(ir->op1) ? ir->op1 : ir->op2; + Reg refv = irref_isk(ir->op1) ? ir->op2 : ir->op1; + Reg rn = ra_alloc1(as, refv, allow); + IRIns *irr = IR(refk); + uint32_t m; + if (irr+1 == ir && !ra_used(irr) && + irr->o == IR_ADD && irref_isk(irr->op2)) { + ofs = sizeof(GCstr) + IR(irr->op2)->i; + if (emit_checkofs(ai, ofs)) { + Reg rm = ra_alloc1(as, irr->op1, rset_exclude(allow, rn)); + m = A64F_M(rm) | A64F_EX(A64EX_SXTW); + goto skipopm; + } + } + m = asm_fuseopm(as, 0, refk, rset_exclude(allow, rn)); + ofs = sizeof(GCstr); + skipopm: + emit_lso(as, ai, rd, rd, ofs); + emit_dn(as, A64I_ADDx^m, rd, rn); + return; + } + ofs += sizeof(GCstr); + if (!emit_checkofs(ai, ofs)) { + Reg rn = ra_alloc1(as, ref, allow); + Reg rm = ra_allock(as, ofs, rset_exclude(allow, rn)); + emit_dnm(as, (ai^A64I_LS_R)|A64I_LS_UXTWx, rd, rn, rm); + return; + } + } + } + base = ra_alloc1(as, ref, allow); + emit_lso(as, ai, (rd & 31), base, ofs); +} + +/* Fuse FP multiply-add/sub. */ +static int asm_fusemadd(ASMState *as, IRIns *ir, A64Ins ai, A64Ins air) +{ + IRRef lref = ir->op1, rref = ir->op2; + IRIns *irm; + if (lref != rref && + ((mayfuse(as, lref) && (irm = IR(lref), irm->o == IR_MUL) && + ra_noreg(irm->r)) || + (mayfuse(as, rref) && (irm = IR(rref), irm->o == IR_MUL) && + (rref = lref, ai = air, ra_noreg(irm->r))))) { + Reg dest = ra_dest(as, ir, RSET_FPR); + Reg add = ra_hintalloc(as, rref, dest, RSET_FPR); + Reg left = ra_alloc2(as, irm, + rset_exclude(rset_exclude(RSET_FPR, dest), add)); + Reg right = (left >> 8); left &= 255; + emit_dnma(as, ai, (dest & 31), (left & 31), (right & 31), (add & 31)); + return 1; + } + return 0; +} + +/* Fuse BAND + BSHL/BSHR into UBFM. */ +static int asm_fuseandshift(ASMState *as, IRIns *ir) +{ + IRIns *irl = IR(ir->op1); + lj_assertA(ir->o == IR_BAND, "bad usage"); + if (canfuse(as, irl) && irref_isk(ir->op2)) { + uint64_t mask = get_k64val(as, ir->op2); + if (irref_isk(irl->op2) && (irl->o == IR_BSHR || irl->o == IR_BSHL)) { + int32_t shmask = irt_is64(irl->t) ? 63 : 31; + int32_t shift = (IR(irl->op2)->i & shmask); + int32_t imms = shift; + if (irl->o == IR_BSHL) { + mask >>= shift; + shift = (shmask-shift+1) & shmask; + imms = 0; + } + if (mask && !((mask+1) & mask)) { /* Contiguous 1-bits at the bottom. */ + Reg dest = ra_dest(as, ir, RSET_GPR); + Reg left = ra_alloc1(as, irl->op1, RSET_GPR); + A64Ins ai = shmask == 63 ? A64I_UBFMx : A64I_UBFMw; + imms += 63 - emit_clz64(mask); + if (imms > shmask) imms = shmask; + emit_dn(as, ai | A64F_IMMS(imms) | A64F_IMMR(shift), dest, left); + return 1; + } + } + } + return 0; +} + +/* Fuse BOR(BSHL, BSHR) into EXTR/ROR. */ +static int asm_fuseorshift(ASMState *as, IRIns *ir) +{ + IRIns *irl = IR(ir->op1), *irr = IR(ir->op2); + lj_assertA(ir->o == IR_BOR, "bad usage"); + if (canfuse(as, irl) && canfuse(as, irr) && + ((irl->o == IR_BSHR && irr->o == IR_BSHL) || + (irl->o == IR_BSHL && irr->o == IR_BSHR))) { + if (irref_isk(irl->op2) && irref_isk(irr->op2)) { + IRRef lref = irl->op1, rref = irr->op1; + uint32_t lshift = IR(irl->op2)->i, rshift = IR(irr->op2)->i; + if (irl->o == IR_BSHR) { /* BSHR needs to be the right operand. */ + uint32_t tmp2; + IRRef tmp1 = lref; lref = rref; rref = tmp1; + tmp2 = lshift; lshift = rshift; rshift = tmp2; + } + if (rshift + lshift == (irt_is64(ir->t) ? 64 : 32)) { + A64Ins ai = irt_is64(ir->t) ? A64I_EXTRx : A64I_EXTRw; + Reg dest = ra_dest(as, ir, RSET_GPR); + Reg left = ra_alloc1(as, lref, RSET_GPR); + Reg right = ra_alloc1(as, rref, rset_exclude(RSET_GPR, left)); + emit_dnm(as, ai | A64F_IMMS(rshift), dest, left, right); + return 1; + } + } + } + return 0; +} + +/* -- Calls --------------------------------------------------------------- */ + +/* Generate a call to a C function. */ +static void asm_gencall(ASMState *as, const CCallInfo *ci, IRRef *args) +{ + uint32_t n, nargs = CCI_XNARGS(ci); + int32_t ofs = 0; + Reg gpr, fpr = REGARG_FIRSTFPR; + if ((void *)ci->func) + emit_call(as, (void *)ci->func); + for (gpr = REGARG_FIRSTGPR; gpr <= REGARG_LASTGPR; gpr++) + as->cost[gpr] = REGCOST(~0u, ASMREF_L); + gpr = REGARG_FIRSTGPR; + for (n = 0; n < nargs; n++) { /* Setup args. */ + IRRef ref = args[n]; + IRIns *ir = IR(ref); + if (ref) { + if (irt_isfp(ir->t)) { + if (fpr <= REGARG_LASTFPR) { + lj_assertA(rset_test(as->freeset, fpr), + "reg %d not free", fpr); /* Must have been evicted. */ + ra_leftov(as, fpr, ref); + fpr++; + } else { + Reg r = ra_alloc1(as, ref, RSET_FPR); + emit_spstore(as, ir, r, ofs + ((LJ_BE && !irt_isnum(ir->t)) ? 4 : 0)); + ofs += 8; + } + } else { + if (gpr <= REGARG_LASTGPR) { + lj_assertA(rset_test(as->freeset, gpr), + "reg %d not free", gpr); /* Must have been evicted. */ + ra_leftov(as, gpr, ref); + gpr++; + } else { + Reg r = ra_alloc1(as, ref, RSET_GPR); + emit_spstore(as, ir, r, ofs + ((LJ_BE && !irt_is64(ir->t)) ? 4 : 0)); + ofs += 8; + } + } + } + } +} + +/* Setup result reg/sp for call. Evict scratch regs. */ +static void asm_setupresult(ASMState *as, IRIns *ir, const CCallInfo *ci) +{ + RegSet drop = RSET_SCRATCH; + int hiop = ((ir+1)->o == IR_HIOP && !irt_isnil((ir+1)->t)); + if (ra_hasreg(ir->r)) + rset_clear(drop, ir->r); /* Dest reg handled below. */ + if (hiop && ra_hasreg((ir+1)->r)) + rset_clear(drop, (ir+1)->r); /* Dest reg handled below. */ + ra_evictset(as, drop); /* Evictions must be performed first. */ + if (ra_used(ir)) { + lj_assertA(!irt_ispri(ir->t), "PRI dest"); + if (irt_isfp(ir->t)) { + if (ci->flags & CCI_CASTU64) { + Reg dest = ra_dest(as, ir, RSET_FPR) & 31; + emit_dn(as, irt_isnum(ir->t) ? A64I_FMOV_D_R : A64I_FMOV_S_R, + dest, RID_RET); + } else { + ra_destreg(as, ir, RID_FPRET); + } + } else if (hiop) { + ra_destpair(as, ir); + } else { + ra_destreg(as, ir, RID_RET); + } + } + UNUSED(ci); +} + +static void asm_callx(ASMState *as, IRIns *ir) +{ + IRRef args[CCI_NARGS_MAX*2]; + CCallInfo ci; + IRRef func; + IRIns *irf; + ci.flags = asm_callx_flags(as, ir); + asm_collectargs(as, ir, &ci, args); + asm_setupresult(as, ir, &ci); + func = ir->op2; irf = IR(func); + if (irf->o == IR_CARG) { func = irf->op1; irf = IR(func); } + if (irref_isk(func)) { /* Call to constant address. */ + ci.func = (ASMFunction)(ir_k64(irf)->u64); + } else { /* Need a non-argument register for indirect calls. */ + Reg freg = ra_alloc1(as, func, RSET_RANGE(RID_X8, RID_MAX_GPR)-RSET_FIXED); + emit_n(as, A64I_BLR, freg); + ci.func = (ASMFunction)(void *)0; + } + asm_gencall(as, &ci, args); +} + +/* -- Returns ------------------------------------------------------------- */ + +/* Return to lower frame. Guard that it goes to the right spot. */ +static void asm_retf(ASMState *as, IRIns *ir) +{ + Reg base = ra_alloc1(as, REF_BASE, RSET_GPR); + void *pc = ir_kptr(IR(ir->op2)); + int32_t delta = 1+LJ_FR2+bc_a(*((const BCIns *)pc - 1)); + as->topslot -= (BCReg)delta; + if ((int32_t)as->topslot < 0) as->topslot = 0; + irt_setmark(IR(REF_BASE)->t); /* Children must not coalesce with BASE reg. */ + /* Need to force a spill on REF_BASE now to update the stack slot. */ + emit_lso(as, A64I_STRx, base, RID_SP, ra_spill(as, IR(REF_BASE))); + emit_setgl(as, base, jit_base); + emit_addptr(as, base, -8*delta); + asm_guardcc(as, CC_NE); + emit_nm(as, A64I_CMPx, RID_TMP, + ra_allock(as, i64ptr(pc), rset_exclude(RSET_GPR, base))); + emit_lso(as, A64I_LDRx, RID_TMP, base, -8); +} + +/* -- Buffer operations --------------------------------------------------- */ + +#if LJ_HASBUFFER +static void asm_bufhdr_write(ASMState *as, Reg sb) +{ + Reg tmp = ra_scratch(as, rset_exclude(RSET_GPR, sb)); + IRIns irgc; + irgc.ot = IRT(0, IRT_PGC); /* GC type. */ + emit_storeofs(as, &irgc, RID_TMP, sb, offsetof(SBuf, L)); + emit_dn(as, A64I_BFMx | A64F_IMMS(lj_fls(SBUF_MASK_FLAG)) | A64F_IMMR(0), RID_TMP, tmp); + emit_getgl(as, RID_TMP, cur_L); + emit_loadofs(as, &irgc, tmp, sb, offsetof(SBuf, L)); +} +#endif + +/* -- Type conversions ---------------------------------------------------- */ + +static void asm_tointg(ASMState *as, IRIns *ir, Reg left) +{ + Reg tmp = ra_scratch(as, rset_exclude(RSET_FPR, left)); + Reg dest = ra_dest(as, ir, RSET_GPR); + asm_guardcc(as, CC_NE); + emit_nm(as, A64I_FCMPd, (tmp & 31), (left & 31)); + emit_dn(as, A64I_FCVT_F64_S32, (tmp & 31), dest); + emit_dn(as, A64I_FCVT_S32_F64, dest, (left & 31)); +} + +static void asm_tobit(ASMState *as, IRIns *ir) +{ + RegSet allow = RSET_FPR; + Reg left = ra_alloc1(as, ir->op1, allow); + Reg right = ra_alloc1(as, ir->op2, rset_clear(allow, left)); + Reg tmp = ra_scratch(as, rset_clear(allow, right)); + Reg dest = ra_dest(as, ir, RSET_GPR); + emit_dn(as, A64I_FMOV_R_S, dest, (tmp & 31)); + emit_dnm(as, A64I_FADDd, (tmp & 31), (left & 31), (right & 31)); +} + +static void asm_conv(ASMState *as, IRIns *ir) +{ + IRType st = (IRType)(ir->op2 & IRCONV_SRCMASK); + int st64 = (st == IRT_I64 || st == IRT_U64 || st == IRT_P64); + int stfp = (st == IRT_NUM || st == IRT_FLOAT); + IRRef lref = ir->op1; + lj_assertA(irt_type(ir->t) != st, "inconsistent types for CONV"); + if (irt_isfp(ir->t)) { + Reg dest = ra_dest(as, ir, RSET_FPR); + if (stfp) { /* FP to FP conversion. */ + emit_dn(as, st == IRT_NUM ? A64I_FCVT_F32_F64 : A64I_FCVT_F64_F32, + (dest & 31), (ra_alloc1(as, lref, RSET_FPR) & 31)); + } else { /* Integer to FP conversion. */ + Reg left = ra_alloc1(as, lref, RSET_GPR); + A64Ins ai = irt_isfloat(ir->t) ? + (((IRT_IS64 >> st) & 1) ? + (st == IRT_I64 ? A64I_FCVT_F32_S64 : A64I_FCVT_F32_U64) : + (st == IRT_INT ? A64I_FCVT_F32_S32 : A64I_FCVT_F32_U32)) : + (((IRT_IS64 >> st) & 1) ? + (st == IRT_I64 ? A64I_FCVT_F64_S64 : A64I_FCVT_F64_U64) : + (st == IRT_INT ? A64I_FCVT_F64_S32 : A64I_FCVT_F64_U32)); + emit_dn(as, ai, (dest & 31), left); + } + } else if (stfp) { /* FP to integer conversion. */ + if (irt_isguard(ir->t)) { + /* Checked conversions are only supported from number to int. */ + lj_assertA(irt_isint(ir->t) && st == IRT_NUM, + "bad type for checked CONV"); + asm_tointg(as, ir, ra_alloc1(as, lref, RSET_FPR)); + } else { + Reg left = ra_alloc1(as, lref, RSET_FPR); + Reg dest = ra_dest(as, ir, RSET_GPR); + A64Ins ai = irt_is64(ir->t) ? + (st == IRT_NUM ? + (irt_isi64(ir->t) ? A64I_FCVT_S64_F64 : A64I_FCVT_U64_F64) : + (irt_isi64(ir->t) ? A64I_FCVT_S64_F32 : A64I_FCVT_U64_F32)) : + (st == IRT_NUM ? + (irt_isint(ir->t) ? A64I_FCVT_S32_F64 : A64I_FCVT_U32_F64) : + (irt_isint(ir->t) ? A64I_FCVT_S32_F32 : A64I_FCVT_U32_F32)); + emit_dn(as, ai, dest, (left & 31)); + } + } else if (st >= IRT_I8 && st <= IRT_U16) { /* Extend to 32 bit integer. */ + Reg dest = ra_dest(as, ir, RSET_GPR); + Reg left = ra_alloc1(as, lref, RSET_GPR); + A64Ins ai = st == IRT_I8 ? A64I_SXTBw : + st == IRT_U8 ? A64I_UXTBw : + st == IRT_I16 ? A64I_SXTHw : A64I_UXTHw; + lj_assertA(irt_isint(ir->t) || irt_isu32(ir->t), "bad type for CONV EXT"); + emit_dn(as, ai, dest, left); + } else { + Reg dest = ra_dest(as, ir, RSET_GPR); + if (irt_is64(ir->t)) { + if (st64 || !(ir->op2 & IRCONV_SEXT)) { + /* 64/64 bit no-op (cast) or 32 to 64 bit zero extension. */ + ra_leftov(as, dest, lref); /* Do nothing, but may need to move regs. */ + } else { /* 32 to 64 bit sign extension. */ + Reg left = ra_alloc1(as, lref, RSET_GPR); + emit_dn(as, A64I_SXTW, dest, left); + } + } else { + if (st64 && !(ir->op2 & IRCONV_NONE)) { + /* This is either a 32 bit reg/reg mov which zeroes the hiword + ** or a load of the loword from a 64 bit address. + */ + Reg left = ra_alloc1(as, lref, RSET_GPR); + emit_dm(as, A64I_MOVw, dest, left); + } else { /* 32/32 bit no-op (cast). */ + ra_leftov(as, dest, lref); /* Do nothing, but may need to move regs. */ + } + } + } +} + +static void asm_strto(ASMState *as, IRIns *ir) +{ + const CCallInfo *ci = &lj_ir_callinfo[IRCALL_lj_strscan_num]; + IRRef args[2]; + Reg dest = 0, tmp; + int destused = ra_used(ir); + int32_t ofs = 0; + ra_evictset(as, RSET_SCRATCH); + if (destused) { + if (ra_hasspill(ir->s)) { + ofs = sps_scale(ir->s); + destused = 0; + if (ra_hasreg(ir->r)) { + ra_free(as, ir->r); + ra_modified(as, ir->r); + emit_spload(as, ir, ir->r, ofs); + } + } else { + dest = ra_dest(as, ir, RSET_FPR); + } + } + if (destused) + emit_lso(as, A64I_LDRd, (dest & 31), RID_SP, 0); + asm_guardcnb(as, A64I_CBZ, RID_RET); + args[0] = ir->op1; /* GCstr *str */ + args[1] = ASMREF_TMP1; /* TValue *n */ + asm_gencall(as, ci, args); + tmp = ra_releasetmp(as, ASMREF_TMP1); + emit_opk(as, A64I_ADDx, tmp, RID_SP, ofs, RSET_GPR); +} + +/* -- Memory references --------------------------------------------------- */ + +/* Store tagged value for ref at base+ofs. */ +static void asm_tvstore64(ASMState *as, Reg base, int32_t ofs, IRRef ref) +{ + RegSet allow = rset_exclude(RSET_GPR, base); + IRIns *ir = IR(ref); + lj_assertA(irt_ispri(ir->t) || irt_isaddr(ir->t) || irt_isinteger(ir->t), + "store of IR type %d", irt_type(ir->t)); + if (irref_isk(ref)) { + TValue k; + lj_ir_kvalue(as->J->L, &k, ir); + emit_lso(as, A64I_STRx, ra_allock(as, k.u64, allow), base, ofs); + } else { + Reg src = ra_alloc1(as, ref, allow); + rset_clear(allow, src); + if (irt_isinteger(ir->t)) { + Reg type = ra_allock(as, (int64_t)irt_toitype(ir->t) << 47, allow); + emit_lso(as, A64I_STRx, RID_TMP, base, ofs); + emit_dnm(as, A64I_ADDx | A64F_EX(A64EX_UXTW), RID_TMP, type, src); + } else { + Reg type = ra_allock(as, (int32_t)irt_toitype(ir->t), allow); + emit_lso(as, A64I_STRx, RID_TMP, base, ofs); + emit_dnm(as, A64I_ADDx | A64F_SH(A64SH_LSL, 47), RID_TMP, src, type); + } + } +} + +/* Get pointer to TValue. */ +static void asm_tvptr(ASMState *as, Reg dest, IRRef ref, MSize mode) +{ + if ((mode & IRTMPREF_IN1)) { + IRIns *ir = IR(ref); + if (irt_isnum(ir->t)) { + if (irref_isk(ref) && !(mode & IRTMPREF_OUT1)) { + /* Use the number constant itself as a TValue. */ + ra_allockreg(as, i64ptr(ir_knum(ir)), dest); + return; + } + emit_lso(as, A64I_STRd, (ra_alloc1(as, ref, RSET_FPR) & 31), dest, 0); + } else { + asm_tvstore64(as, dest, 0, ref); + } + } + /* g->tmptv holds the TValue(s). */ + emit_dn(as, A64I_ADDx^emit_isk12(glofs(as, &J2G(as->J)->tmptv)), dest, RID_GL); +} + +static void asm_aref(ASMState *as, IRIns *ir) +{ + Reg dest = ra_dest(as, ir, RSET_GPR); + Reg idx, base; + if (irref_isk(ir->op2)) { + IRRef tab = IR(ir->op1)->op1; + int32_t ofs = asm_fuseabase(as, tab); + IRRef refa = ofs ? tab : ir->op1; + uint32_t k = emit_isk12(ofs + 8*IR(ir->op2)->i); + if (k) { + base = ra_alloc1(as, refa, RSET_GPR); + emit_dn(as, A64I_ADDx^k, dest, base); + return; + } + } + base = ra_alloc1(as, ir->op1, RSET_GPR); + idx = ra_alloc1(as, ir->op2, rset_exclude(RSET_GPR, base)); + emit_dnm(as, A64I_ADDx | A64F_EXSH(A64EX_UXTW, 3), dest, base, idx); +} + +/* Inlined hash lookup. Specialized for key type and for const keys. +** The equivalent C code is: +** Node *n = hashkey(t, key); +** do { +** if (lj_obj_equal(&n->key, key)) return &n->val; +** } while ((n = nextnode(n))); +** return niltv(L); +*/ +static void asm_href(ASMState *as, IRIns *ir, IROp merge) +{ + RegSet allow = RSET_GPR; + int destused = ra_used(ir); + Reg dest = ra_dest(as, ir, allow); + Reg tab = ra_alloc1(as, ir->op1, rset_clear(allow, dest)); + Reg key = 0, tmp = RID_TMP; + Reg ftmp = RID_NONE, type = RID_NONE, scr = RID_NONE, tisnum = RID_NONE; + IRRef refkey = ir->op2; + IRIns *irkey = IR(refkey); + int isk = irref_isk(ir->op2); + IRType1 kt = irkey->t; + uint32_t k = 0; + uint32_t khash; + MCLabel l_end, l_loop, l_next; + rset_clear(allow, tab); + + if (!isk) { + key = ra_alloc1(as, ir->op2, irt_isnum(kt) ? RSET_FPR : allow); + rset_clear(allow, key); + if (!irt_isstr(kt)) { + tmp = ra_scratch(as, allow); + rset_clear(allow, tmp); + } + } else if (irt_isnum(kt)) { + int64_t val = (int64_t)ir_knum(irkey)->u64; + if (!(k = emit_isk12(val))) { + key = ra_allock(as, val, allow); + rset_clear(allow, key); + } + } else if (!irt_ispri(kt)) { + if (!(k = emit_isk12(irkey->i))) { + key = ra_alloc1(as, refkey, allow); + rset_clear(allow, key); + } + } + + /* Allocate constants early. */ + if (irt_isnum(kt)) { + if (!isk) { + tisnum = ra_allock(as, LJ_TISNUM << 15, allow); + ftmp = ra_scratch(as, rset_exclude(RSET_FPR, key)); + rset_clear(allow, tisnum); + } + } else if (irt_isaddr(kt)) { + if (isk) { + int64_t kk = ((int64_t)irt_toitype(kt) << 47) | irkey[1].tv.u64; + scr = ra_allock(as, kk, allow); + } else { + scr = ra_scratch(as, allow); + } + rset_clear(allow, scr); + } else { + lj_assertA(irt_ispri(kt) && !irt_isnil(kt), "bad HREF key type"); + type = ra_allock(as, ~((int64_t)~irt_toitype(kt) << 47), allow); + scr = ra_scratch(as, rset_clear(allow, type)); + rset_clear(allow, scr); + } + + /* Key not found in chain: jump to exit (if merged) or load niltv. */ + l_end = emit_label(as); + as->invmcp = NULL; + if (merge == IR_NE) + asm_guardcc(as, CC_AL); + else if (destused) + emit_loada(as, dest, niltvg(J2G(as->J))); + + /* Follow hash chain until the end. */ + l_loop = --as->mcp; + emit_n(as, A64I_CMPx^A64I_K12^0, dest); + emit_lso(as, A64I_LDRx, dest, dest, offsetof(Node, next)); + l_next = emit_label(as); + + /* Type and value comparison. */ + if (merge == IR_EQ) + asm_guardcc(as, CC_EQ); + else + emit_cond_branch(as, CC_EQ, l_end); + + if (irt_isnum(kt)) { + if (isk) { + /* Assumes -0.0 is already canonicalized to +0.0. */ + if (k) + emit_n(as, A64I_CMPx^k, tmp); + else + emit_nm(as, A64I_CMPx, key, tmp); + emit_lso(as, A64I_LDRx, tmp, dest, offsetof(Node, key.u64)); + } else { + emit_nm(as, A64I_FCMPd, key, ftmp); + emit_dn(as, A64I_FMOV_D_R, (ftmp & 31), (tmp & 31)); + emit_cond_branch(as, CC_LO, l_next); + emit_nm(as, A64I_CMPx | A64F_SH(A64SH_LSR, 32), tisnum, tmp); + emit_lso(as, A64I_LDRx, tmp, dest, offsetof(Node, key.n)); + } + } else if (irt_isaddr(kt)) { + if (isk) { + emit_nm(as, A64I_CMPx, scr, tmp); + emit_lso(as, A64I_LDRx, tmp, dest, offsetof(Node, key.u64)); + } else { + emit_nm(as, A64I_CMPx, tmp, scr); + emit_lso(as, A64I_LDRx, scr, dest, offsetof(Node, key.u64)); + } + } else { + emit_nm(as, A64I_CMPx, scr, type); + emit_lso(as, A64I_LDRx, scr, dest, offsetof(Node, key)); + } + + *l_loop = A64I_BCC | A64F_S19(as->mcp - l_loop) | CC_NE; + if (!isk && irt_isaddr(kt)) { + type = ra_allock(as, (int32_t)irt_toitype(kt), allow); + emit_dnm(as, A64I_ADDx | A64F_SH(A64SH_LSL, 47), tmp, key, type); + rset_clear(allow, type); + } + /* Load main position relative to tab->node into dest. */ + khash = isk ? ir_khash(as, irkey) : 1; + if (khash == 0) { + emit_lso(as, A64I_LDRx, dest, tab, offsetof(GCtab, node)); + } else { + emit_dnm(as, A64I_ADDx | A64F_SH(A64SH_LSL, 3), dest, tmp, dest); + emit_dnm(as, A64I_ADDx | A64F_SH(A64SH_LSL, 1), dest, dest, dest); + emit_lso(as, A64I_LDRx, tmp, tab, offsetof(GCtab, node)); + if (isk) { + Reg tmphash = ra_allock(as, khash, allow); + emit_dnm(as, A64I_ANDw, dest, dest, tmphash); + emit_lso(as, A64I_LDRw, dest, tab, offsetof(GCtab, hmask)); + } else if (irt_isstr(kt)) { + /* Fetch of str->sid is cheaper than ra_allock. */ + emit_dnm(as, A64I_ANDw, dest, dest, tmp); + emit_lso(as, A64I_LDRw, tmp, key, offsetof(GCstr, sid)); + emit_lso(as, A64I_LDRw, dest, tab, offsetof(GCtab, hmask)); + } else { /* Must match with hash*() in lj_tab.c. */ + emit_dnm(as, A64I_ANDw, dest, dest, tmp); + emit_lso(as, A64I_LDRw, tmp, tab, offsetof(GCtab, hmask)); + emit_dnm(as, A64I_SUBw, dest, dest, tmp); + emit_dnm(as, A64I_EXTRw | (A64F_IMMS(32-HASH_ROT3)), tmp, tmp, tmp); + emit_dnm(as, A64I_EORw, dest, dest, tmp); + emit_dnm(as, A64I_EXTRw | (A64F_IMMS(32-HASH_ROT2)), dest, dest, dest); + emit_dnm(as, A64I_SUBw, tmp, tmp, dest); + emit_dnm(as, A64I_EXTRw | (A64F_IMMS(32-HASH_ROT1)), dest, dest, dest); + emit_dnm(as, A64I_EORw, tmp, tmp, dest); + if (irt_isnum(kt)) { + emit_dnm(as, A64I_ADDw, dest, dest, dest); + emit_dn(as, A64I_LSRx | A64F_IMMR(32)|A64F_IMMS(32), dest, dest); + emit_dm(as, A64I_MOVw, tmp, dest); + emit_dn(as, A64I_FMOV_R_D, dest, (key & 31)); + } else { + checkmclim(as); + emit_dm(as, A64I_MOVw, tmp, key); + emit_dnm(as, A64I_EORw, dest, dest, + ra_allock(as, irt_toitype(kt) << 15, allow)); + emit_dn(as, A64I_LSRx | A64F_IMMR(32)|A64F_IMMS(32), dest, dest); + emit_dm(as, A64I_MOVx, dest, key); + } + } + } +} + +static void asm_hrefk(ASMState *as, IRIns *ir) +{ + IRIns *kslot = IR(ir->op2); + IRIns *irkey = IR(kslot->op1); + int32_t ofs = (int32_t)(kslot->op2 * sizeof(Node)); + int32_t kofs = ofs + (int32_t)offsetof(Node, key); + int bigofs = !emit_checkofs(A64I_LDRx, ofs); + Reg dest = (ra_used(ir) || bigofs) ? ra_dest(as, ir, RSET_GPR) : RID_NONE; + Reg node = ra_alloc1(as, ir->op1, RSET_GPR); + Reg key, idx = node; + RegSet allow = rset_exclude(RSET_GPR, node); + uint64_t k; + lj_assertA(ofs % sizeof(Node) == 0, "unaligned HREFK slot"); + if (bigofs) { + idx = dest; + rset_clear(allow, dest); + kofs = (int32_t)offsetof(Node, key); + } else if (ra_hasreg(dest)) { + emit_opk(as, A64I_ADDx, dest, node, ofs, allow); + } + asm_guardcc(as, CC_NE); + if (irt_ispri(irkey->t)) { + k = ~((int64_t)~irt_toitype(irkey->t) << 47); + } else if (irt_isnum(irkey->t)) { + k = ir_knum(irkey)->u64; + } else { + k = ((uint64_t)irt_toitype(irkey->t) << 47) | (uint64_t)ir_kgc(irkey); + } + key = ra_scratch(as, allow); + emit_nm(as, A64I_CMPx, key, ra_allock(as, k, rset_exclude(allow, key))); + emit_lso(as, A64I_LDRx, key, idx, kofs); + if (bigofs) + emit_opk(as, A64I_ADDx, dest, node, ofs, RSET_GPR); +} + +static void asm_uref(ASMState *as, IRIns *ir) +{ + Reg dest = ra_dest(as, ir, RSET_GPR); + if (irref_isk(ir->op1)) { + GCfunc *fn = ir_kfunc(IR(ir->op1)); + MRef *v = &gcref(fn->l.uvptr[(ir->op2 >> 8)])->uv.v; + emit_lsptr(as, A64I_LDRx, dest, v); + } else { + Reg uv = ra_scratch(as, RSET_GPR); + Reg func = ra_alloc1(as, ir->op1, RSET_GPR); + if (ir->o == IR_UREFC) { + asm_guardcc(as, CC_NE); + emit_n(as, (A64I_CMPx^A64I_K12) | A64F_U12(1), RID_TMP); + emit_opk(as, A64I_ADDx, dest, uv, + (int32_t)offsetof(GCupval, tv), RSET_GPR); + emit_lso(as, A64I_LDRB, RID_TMP, uv, (int32_t)offsetof(GCupval, closed)); + } else { + emit_lso(as, A64I_LDRx, dest, uv, (int32_t)offsetof(GCupval, v)); + } + emit_lso(as, A64I_LDRx, uv, func, + (int32_t)offsetof(GCfuncL, uvptr) + 8*(int32_t)(ir->op2 >> 8)); + } +} + +static void asm_fref(ASMState *as, IRIns *ir) +{ + UNUSED(as); UNUSED(ir); + lj_assertA(!ra_used(ir), "unfused FREF"); +} + +static void asm_strref(ASMState *as, IRIns *ir) +{ + RegSet allow = RSET_GPR; + Reg dest = ra_dest(as, ir, allow); + Reg base = ra_alloc1(as, ir->op1, allow); + IRIns *irr = IR(ir->op2); + int32_t ofs = sizeof(GCstr); + uint32_t m; + rset_clear(allow, base); + if (irref_isk(ir->op2) && (m = emit_isk12(ofs + irr->i))) { + emit_dn(as, A64I_ADDx^m, dest, base); + } else { + emit_dn(as, (A64I_ADDx^A64I_K12) | A64F_U12(ofs), dest, dest); + emit_dnm(as, A64I_ADDx, dest, base, ra_alloc1(as, ir->op2, allow)); + } +} + +/* -- Loads and stores ---------------------------------------------------- */ + +static A64Ins asm_fxloadins(IRIns *ir) +{ + switch (irt_type(ir->t)) { + case IRT_I8: return A64I_LDRB ^ A64I_LS_S; + case IRT_U8: return A64I_LDRB; + case IRT_I16: return A64I_LDRH ^ A64I_LS_S; + case IRT_U16: return A64I_LDRH; + case IRT_NUM: return A64I_LDRd; + case IRT_FLOAT: return A64I_LDRs; + default: return irt_is64(ir->t) ? A64I_LDRx : A64I_LDRw; + } +} + +static A64Ins asm_fxstoreins(IRIns *ir) +{ + switch (irt_type(ir->t)) { + case IRT_I8: case IRT_U8: return A64I_STRB; + case IRT_I16: case IRT_U16: return A64I_STRH; + case IRT_NUM: return A64I_STRd; + case IRT_FLOAT: return A64I_STRs; + default: return irt_is64(ir->t) ? A64I_STRx : A64I_STRw; + } +} + +static void asm_fload(ASMState *as, IRIns *ir) +{ + Reg dest = ra_dest(as, ir, RSET_GPR); + Reg idx; + A64Ins ai = asm_fxloadins(ir); + int32_t ofs; + if (ir->op1 == REF_NIL) { /* FLOAD from GG_State with offset. */ + idx = RID_GL; + ofs = (ir->op2 << 2) - GG_OFS(g); + } else { + idx = ra_alloc1(as, ir->op1, RSET_GPR); + if (ir->op2 == IRFL_TAB_ARRAY) { + ofs = asm_fuseabase(as, ir->op1); + if (ofs) { /* Turn the t->array load into an add for colocated arrays. */ + emit_dn(as, (A64I_ADDx^A64I_K12) | A64F_U12(ofs), dest, idx); + return; + } + } + ofs = field_ofs[ir->op2]; + } + emit_lso(as, ai, (dest & 31), idx, ofs); +} + +static void asm_fstore(ASMState *as, IRIns *ir) +{ + if (ir->r != RID_SINK) { + Reg src = ra_alloc1(as, ir->op2, RSET_GPR); + IRIns *irf = IR(ir->op1); + Reg idx = ra_alloc1(as, irf->op1, rset_exclude(RSET_GPR, src)); + int32_t ofs = field_ofs[irf->op2]; + emit_lso(as, asm_fxstoreins(ir), (src & 31), idx, ofs); + } +} + +static void asm_xload(ASMState *as, IRIns *ir) +{ + Reg dest = ra_dest(as, ir, irt_isfp(ir->t) ? RSET_FPR : RSET_GPR); + lj_assertA(!(ir->op2 & IRXLOAD_UNALIGNED), "unaligned XLOAD"); + asm_fusexref(as, asm_fxloadins(ir), dest, ir->op1, RSET_GPR); +} + +static void asm_xstore(ASMState *as, IRIns *ir) +{ + if (ir->r != RID_SINK) { + Reg src = ra_alloc1(as, ir->op2, irt_isfp(ir->t) ? RSET_FPR : RSET_GPR); + asm_fusexref(as, asm_fxstoreins(ir), src, ir->op1, + rset_exclude(RSET_GPR, src)); + } +} + +static void asm_ahuvload(ASMState *as, IRIns *ir) +{ + Reg idx, tmp, type; + int32_t ofs = 0; + RegSet gpr = RSET_GPR, allow = irt_isnum(ir->t) ? RSET_FPR : RSET_GPR; + lj_assertA(irt_isnum(ir->t) || irt_ispri(ir->t) || irt_isaddr(ir->t) || + irt_isint(ir->t), + "bad load type %d", irt_type(ir->t)); + if (ra_used(ir)) { + Reg dest = ra_dest(as, ir, allow); + tmp = irt_isnum(ir->t) ? ra_scratch(as, rset_clear(gpr, dest)) : dest; + if (irt_isaddr(ir->t)) { + emit_dn(as, A64I_ANDx^emit_isk13(LJ_GCVMASK, 1), dest, dest); + } else if (irt_isnum(ir->t)) { + emit_dn(as, A64I_FMOV_D_R, (dest & 31), tmp); + } else if (irt_isint(ir->t)) { + emit_dm(as, A64I_MOVw, dest, dest); + } + } else { + tmp = ra_scratch(as, gpr); + } + type = ra_scratch(as, rset_clear(gpr, tmp)); + idx = asm_fuseahuref(as, ir->op1, &ofs, rset_clear(gpr, type), A64I_LDRx); + if (ir->o == IR_VLOAD) ofs += 8 * ir->op2; + /* Always do the type check, even if the load result is unused. */ + asm_guardcc(as, irt_isnum(ir->t) ? CC_LS : CC_NE); + if (irt_type(ir->t) >= IRT_NUM) { + lj_assertA(irt_isinteger(ir->t) || irt_isnum(ir->t), + "bad load type %d", irt_type(ir->t)); + emit_nm(as, A64I_CMPx | A64F_SH(A64SH_LSR, 32), + ra_allock(as, LJ_TISNUM << 15, rset_exclude(gpr, idx)), tmp); + } else if (irt_isaddr(ir->t)) { + emit_n(as, (A64I_CMNx^A64I_K12) | A64F_U12(-irt_toitype(ir->t)), type); + emit_dn(as, A64I_ASRx | A64F_IMMR(47), type, tmp); + } else if (irt_isnil(ir->t)) { + emit_n(as, (A64I_CMNx^A64I_K12) | A64F_U12(1), tmp); + } else { + emit_nm(as, A64I_CMPx | A64F_SH(A64SH_LSR, 32), + ra_allock(as, (irt_toitype(ir->t) << 15) | 0x7fff, gpr), tmp); + } + if (ofs & FUSE_REG) + emit_dnm(as, (A64I_LDRx^A64I_LS_R)|A64I_LS_UXTWx|A64I_LS_SH, tmp, idx, (ofs & 31)); + else + emit_lso(as, A64I_LDRx, tmp, idx, ofs); +} + +static void asm_ahustore(ASMState *as, IRIns *ir) +{ + if (ir->r != RID_SINK) { + RegSet allow = RSET_GPR; + Reg idx, src = RID_NONE, tmp = RID_TMP, type = RID_NONE; + int32_t ofs = 0; + if (irt_isnum(ir->t)) { + src = ra_alloc1(as, ir->op2, RSET_FPR); + idx = asm_fuseahuref(as, ir->op1, &ofs, allow, A64I_STRd); + if (ofs & FUSE_REG) + emit_dnm(as, (A64I_STRd^A64I_LS_R)|A64I_LS_UXTWx|A64I_LS_SH, (src & 31), idx, (ofs &31)); + else + emit_lso(as, A64I_STRd, (src & 31), idx, ofs); + } else { + if (!irt_ispri(ir->t)) { + src = ra_alloc1(as, ir->op2, allow); + rset_clear(allow, src); + if (irt_isinteger(ir->t)) + type = ra_allock(as, (uint64_t)(int32_t)LJ_TISNUM << 47, allow); + else + type = ra_allock(as, irt_toitype(ir->t), allow); + } else { + tmp = type = ra_allock(as, ~((int64_t)~irt_toitype(ir->t)<<47), allow); + } + idx = asm_fuseahuref(as, ir->op1, &ofs, rset_exclude(allow, type), + A64I_STRx); + if (ofs & FUSE_REG) + emit_dnm(as, (A64I_STRx^A64I_LS_R)|A64I_LS_UXTWx|A64I_LS_SH, tmp, idx, (ofs & 31)); + else + emit_lso(as, A64I_STRx, tmp, idx, ofs); + if (ra_hasreg(src)) { + if (irt_isinteger(ir->t)) { + emit_dnm(as, A64I_ADDx | A64F_EX(A64EX_UXTW), tmp, type, src); + } else { + emit_dnm(as, A64I_ADDx | A64F_SH(A64SH_LSL, 47), tmp, src, type); + } + } + } + } +} + +static void asm_sload(ASMState *as, IRIns *ir) +{ + int32_t ofs = 8*((int32_t)ir->op1-2); + IRType1 t = ir->t; + Reg dest = RID_NONE, base; + RegSet allow = RSET_GPR; + lj_assertA(!(ir->op2 & IRSLOAD_PARENT), + "bad parent SLOAD"); /* Handled by asm_head_side(). */ + lj_assertA(irt_isguard(t) || !(ir->op2 & IRSLOAD_TYPECHECK), + "inconsistent SLOAD variant"); + if ((ir->op2 & IRSLOAD_CONVERT) && irt_isguard(t) && irt_isint(t)) { + dest = ra_scratch(as, RSET_FPR); + asm_tointg(as, ir, dest); + t.irt = IRT_NUM; /* Continue with a regular number type check. */ + } else if (ra_used(ir)) { + Reg tmp = RID_NONE; + if ((ir->op2 & IRSLOAD_CONVERT)) + tmp = ra_scratch(as, irt_isint(t) ? RSET_FPR : RSET_GPR); + lj_assertA((irt_isnum(t)) || irt_isint(t) || irt_isaddr(t), + "bad SLOAD type %d", irt_type(t)); + dest = ra_dest(as, ir, irt_isnum(t) ? RSET_FPR : allow); + base = ra_alloc1(as, REF_BASE, rset_clear(allow, dest)); + if (irt_isaddr(t)) { + emit_dn(as, A64I_ANDx^emit_isk13(LJ_GCVMASK, 1), dest, dest); + } else if ((ir->op2 & IRSLOAD_CONVERT)) { + if (irt_isint(t)) { + emit_dn(as, A64I_FCVT_S32_F64, dest, (tmp & 31)); + /* If value is already loaded for type check, move it to FPR. */ + if ((ir->op2 & IRSLOAD_TYPECHECK)) + emit_dn(as, A64I_FMOV_D_R, (tmp & 31), dest); + else + dest = tmp; + t.irt = IRT_NUM; /* Check for original type. */ + } else { + emit_dn(as, A64I_FCVT_F64_S32, (dest & 31), tmp); + dest = tmp; + t.irt = IRT_INT; /* Check for original type. */ + } + } else if (irt_isint(t) && (ir->op2 & IRSLOAD_TYPECHECK)) { + emit_dm(as, A64I_MOVw, dest, dest); + } + goto dotypecheck; + } + base = ra_alloc1(as, REF_BASE, allow); +dotypecheck: + rset_clear(allow, base); + if ((ir->op2 & IRSLOAD_TYPECHECK)) { + Reg tmp; + if (ra_hasreg(dest) && rset_test(RSET_GPR, dest)) { + tmp = dest; + } else { + tmp = ra_scratch(as, allow); + rset_clear(allow, tmp); + } + if (irt_isnum(t) && !(ir->op2 & IRSLOAD_CONVERT)) + emit_dn(as, A64I_FMOV_D_R, (dest & 31), tmp); + /* Need type check, even if the load result is unused. */ + asm_guardcc(as, irt_isnum(t) ? CC_LS : CC_NE); + if (irt_type(t) >= IRT_NUM) { + lj_assertA(irt_isinteger(t) || irt_isnum(t), + "bad SLOAD type %d", irt_type(t)); + emit_nm(as, A64I_CMPx | A64F_SH(A64SH_LSR, 32), + ra_allock(as, (ir->op2 & IRSLOAD_KEYINDEX) ? LJ_KEYINDEX : (LJ_TISNUM << 15), allow), tmp); + } else if (irt_isnil(t)) { + emit_n(as, (A64I_CMNx^A64I_K12) | A64F_U12(1), tmp); + } else if (irt_ispri(t)) { + emit_nm(as, A64I_CMPx, + ra_allock(as, ~((int64_t)~irt_toitype(t) << 47) , allow), tmp); + } else { + Reg type = ra_scratch(as, allow); + emit_n(as, (A64I_CMNx^A64I_K12) | A64F_U12(-irt_toitype(t)), type); + emit_dn(as, A64I_ASRx | A64F_IMMR(47), type, tmp); + } + emit_lso(as, A64I_LDRx, tmp, base, ofs); + return; + } + if (ra_hasreg(dest)) { + emit_lso(as, irt_isnum(t) ? A64I_LDRd : + (irt_isint(t) ? A64I_LDRw : A64I_LDRx), (dest & 31), base, + ofs ^ ((LJ_BE && irt_isint(t) ? 4 : 0))); + } +} + +/* -- Allocations --------------------------------------------------------- */ + +#if LJ_HASFFI +static void asm_cnew(ASMState *as, IRIns *ir) +{ + CTState *cts = ctype_ctsG(J2G(as->J)); + CTypeID id = (CTypeID)IR(ir->op1)->i; + CTSize sz; + CTInfo info = lj_ctype_info(cts, id, &sz); + const CCallInfo *ci = &lj_ir_callinfo[IRCALL_lj_mem_newgco]; + IRRef args[4]; + RegSet allow = (RSET_GPR & ~RSET_SCRATCH); + lj_assertA(sz != CTSIZE_INVALID || (ir->o == IR_CNEW && ir->op2 != REF_NIL), + "bad CNEW/CNEWI operands"); + + as->gcsteps++; + asm_setupresult(as, ir, ci); /* GCcdata * */ + /* Initialize immutable cdata object. */ + if (ir->o == IR_CNEWI) { + int32_t ofs = sizeof(GCcdata); + Reg r = ra_alloc1(as, ir->op2, allow); + lj_assertA(sz == 4 || sz == 8, "bad CNEWI size %d", sz); + emit_lso(as, sz == 8 ? A64I_STRx : A64I_STRw, r, RID_RET, ofs); + } else if (ir->op2 != REF_NIL) { /* Create VLA/VLS/aligned cdata. */ + ci = &lj_ir_callinfo[IRCALL_lj_cdata_newv]; + args[0] = ASMREF_L; /* lua_State *L */ + args[1] = ir->op1; /* CTypeID id */ + args[2] = ir->op2; /* CTSize sz */ + args[3] = ASMREF_TMP1; /* CTSize align */ + asm_gencall(as, ci, args); + emit_loadi(as, ra_releasetmp(as, ASMREF_TMP1), (int32_t)ctype_align(info)); + return; + } + + /* Initialize gct and ctypeid. lj_mem_newgco() already sets marked. */ + { + Reg r = (id < 65536) ? RID_X1 : ra_allock(as, id, allow); + emit_lso(as, A64I_STRB, RID_TMP, RID_RET, offsetof(GCcdata, gct)); + emit_lso(as, A64I_STRH, r, RID_RET, offsetof(GCcdata, ctypeid)); + emit_d(as, A64I_MOVZw | A64F_U16(~LJ_TCDATA), RID_TMP); + if (id < 65536) emit_d(as, A64I_MOVZw | A64F_U16(id), RID_X1); + } + args[0] = ASMREF_L; /* lua_State *L */ + args[1] = ASMREF_TMP1; /* MSize size */ + asm_gencall(as, ci, args); + ra_allockreg(as, (int32_t)(sz+sizeof(GCcdata)), + ra_releasetmp(as, ASMREF_TMP1)); +} +#endif + +/* -- Write barriers ------------------------------------------------------ */ + +static void asm_tbar(ASMState *as, IRIns *ir) +{ + Reg tab = ra_alloc1(as, ir->op1, RSET_GPR); + Reg link = ra_scratch(as, rset_exclude(RSET_GPR, tab)); + Reg mark = RID_TMP; + MCLabel l_end = emit_label(as); + emit_lso(as, A64I_STRx, link, tab, (int32_t)offsetof(GCtab, gclist)); + emit_lso(as, A64I_STRB, mark, tab, (int32_t)offsetof(GCtab, marked)); + emit_setgl(as, tab, gc.grayagain); + emit_dn(as, A64I_ANDw^emit_isk13(~LJ_GC_BLACK, 0), mark, mark); + emit_getgl(as, link, gc.grayagain); + emit_cond_branch(as, CC_EQ, l_end); + emit_n(as, A64I_TSTw^emit_isk13(LJ_GC_BLACK, 0), mark); + emit_lso(as, A64I_LDRB, mark, tab, (int32_t)offsetof(GCtab, marked)); +} + +static void asm_obar(ASMState *as, IRIns *ir) +{ + const CCallInfo *ci = &lj_ir_callinfo[IRCALL_lj_gc_barrieruv]; + IRRef args[2]; + MCLabel l_end; + RegSet allow = RSET_GPR; + Reg obj, val, tmp; + /* No need for other object barriers (yet). */ + lj_assertA(IR(ir->op1)->o == IR_UREFC, "bad OBAR type"); + ra_evictset(as, RSET_SCRATCH); + l_end = emit_label(as); + args[0] = ASMREF_TMP1; /* global_State *g */ + args[1] = ir->op1; /* TValue *tv */ + asm_gencall(as, ci, args); + emit_dm(as, A64I_MOVx, ra_releasetmp(as, ASMREF_TMP1), RID_GL); + obj = IR(ir->op1)->r; + tmp = ra_scratch(as, rset_exclude(allow, obj)); + emit_cond_branch(as, CC_EQ, l_end); + emit_n(as, A64I_TSTw^emit_isk13(LJ_GC_BLACK, 0), tmp); + emit_cond_branch(as, CC_EQ, l_end); + emit_n(as, A64I_TSTw^emit_isk13(LJ_GC_WHITES, 0), RID_TMP); + val = ra_alloc1(as, ir->op2, rset_exclude(RSET_GPR, obj)); + emit_lso(as, A64I_LDRB, tmp, obj, + (int32_t)offsetof(GCupval, marked)-(int32_t)offsetof(GCupval, tv)); + emit_lso(as, A64I_LDRB, RID_TMP, val, (int32_t)offsetof(GChead, marked)); +} + +/* -- Arithmetic and logic operations ------------------------------------- */ + +static void asm_fparith(ASMState *as, IRIns *ir, A64Ins ai) +{ + Reg dest = ra_dest(as, ir, RSET_FPR); + Reg right, left = ra_alloc2(as, ir, RSET_FPR); + right = (left >> 8); left &= 255; + emit_dnm(as, ai, (dest & 31), (left & 31), (right & 31)); +} + +static void asm_fpunary(ASMState *as, IRIns *ir, A64Ins ai) +{ + Reg dest = ra_dest(as, ir, RSET_FPR); + Reg left = ra_hintalloc(as, ir->op1, dest, RSET_FPR); + emit_dn(as, ai, (dest & 31), (left & 31)); +} + +static void asm_fpmath(ASMState *as, IRIns *ir) +{ + IRFPMathOp fpm = (IRFPMathOp)ir->op2; + if (fpm == IRFPM_SQRT) { + asm_fpunary(as, ir, A64I_FSQRTd); + } else if (fpm <= IRFPM_TRUNC) { + asm_fpunary(as, ir, fpm == IRFPM_FLOOR ? A64I_FRINTMd : + fpm == IRFPM_CEIL ? A64I_FRINTPd : A64I_FRINTZd); + } else { + asm_callid(as, ir, IRCALL_lj_vm_floor + fpm); + } +} + +static int asm_swapops(ASMState *as, IRRef lref, IRRef rref) +{ + IRIns *ir; + if (irref_isk(rref)) + return 0; /* Don't swap constants to the left. */ + if (irref_isk(lref)) + return 1; /* But swap constants to the right. */ + ir = IR(rref); + if ((ir->o >= IR_BSHL && ir->o <= IR_BSAR) || + (ir->o == IR_ADD && ir->op1 == ir->op2) || + (ir->o == IR_CONV && ir->op2 == ((IRT_I64<o >= IR_BSHL && ir->o <= IR_BSAR) || + (ir->o == IR_ADD && ir->op1 == ir->op2) || + (ir->o == IR_CONV && ir->op2 == ((IRT_I64<op1, rref = ir->op2; + Reg left, dest = ra_dest(as, ir, RSET_GPR); + uint32_t m; + if ((ai & ~A64I_S) != A64I_SUBw && asm_swapops(as, lref, rref)) { + IRRef tmp = lref; lref = rref; rref = tmp; + } + left = ra_hintalloc(as, lref, dest, RSET_GPR); + if (irt_is64(ir->t)) ai |= A64I_X; + m = asm_fuseopm(as, ai, rref, rset_exclude(RSET_GPR, left)); + if (irt_isguard(ir->t)) { /* For IR_ADDOV etc. */ + asm_guardcc(as, CC_VS); + ai |= A64I_S; + } + emit_dn(as, ai^m, dest, left); +} + +static void asm_intop_s(ASMState *as, IRIns *ir, A64Ins ai) +{ + if (as->flagmcp == as->mcp) { /* Drop cmp r, #0. */ + as->flagmcp = NULL; + as->mcp++; + ai |= A64I_S; + } + asm_intop(as, ir, ai); +} + +static void asm_intneg(ASMState *as, IRIns *ir) +{ + Reg dest = ra_dest(as, ir, RSET_GPR); + Reg left = ra_hintalloc(as, ir->op1, dest, RSET_GPR); + emit_dm(as, irt_is64(ir->t) ? A64I_NEGx : A64I_NEGw, dest, left); +} + +/* NYI: use add/shift for MUL(OV) with constants. FOLD only does 2^k. */ +static void asm_intmul(ASMState *as, IRIns *ir) +{ + Reg dest = ra_dest(as, ir, RSET_GPR); + Reg left = ra_alloc1(as, ir->op1, rset_exclude(RSET_GPR, dest)); + Reg right = ra_alloc1(as, ir->op2, rset_exclude(RSET_GPR, left)); + if (irt_isguard(ir->t)) { /* IR_MULOV */ + asm_guardcc(as, CC_NE); + emit_dm(as, A64I_MOVw, dest, dest); /* Zero-extend. */ + emit_nm(as, A64I_CMPw | A64F_SH(A64SH_ASR, 31), RID_TMP, dest); + emit_dn(as, A64I_ASRx | A64F_IMMR(32), RID_TMP, dest); + emit_dnm(as, A64I_SMULL, dest, right, left); + } else { + emit_dnm(as, irt_is64(ir->t) ? A64I_MULx : A64I_MULw, dest, left, right); + } +} + +static void asm_add(ASMState *as, IRIns *ir) +{ + if (irt_isnum(ir->t)) { + if (!asm_fusemadd(as, ir, A64I_FMADDd, A64I_FMADDd)) + asm_fparith(as, ir, A64I_FADDd); + return; + } + asm_intop_s(as, ir, A64I_ADDw); +} + +static void asm_sub(ASMState *as, IRIns *ir) +{ + if (irt_isnum(ir->t)) { + if (!asm_fusemadd(as, ir, A64I_FNMSUBd, A64I_FMSUBd)) + asm_fparith(as, ir, A64I_FSUBd); + return; + } + asm_intop_s(as, ir, A64I_SUBw); +} + +static void asm_mul(ASMState *as, IRIns *ir) +{ + if (irt_isnum(ir->t)) { + asm_fparith(as, ir, A64I_FMULd); + return; + } + asm_intmul(as, ir); +} + +#define asm_addov(as, ir) asm_add(as, ir) +#define asm_subov(as, ir) asm_sub(as, ir) +#define asm_mulov(as, ir) asm_mul(as, ir) + +#define asm_fpdiv(as, ir) asm_fparith(as, ir, A64I_FDIVd) +#define asm_abs(as, ir) asm_fpunary(as, ir, A64I_FABS) + +static void asm_neg(ASMState *as, IRIns *ir) +{ + if (irt_isnum(ir->t)) { + asm_fpunary(as, ir, A64I_FNEGd); + return; + } + asm_intneg(as, ir); +} + +static void asm_band(ASMState *as, IRIns *ir) +{ + A64Ins ai = A64I_ANDw; + if (asm_fuseandshift(as, ir)) + return; + if (as->flagmcp == as->mcp) { + /* Try to drop cmp r, #0. */ + as->flagmcp = NULL; + as->mcp++; + ai = A64I_ANDSw; + } + asm_intop(as, ir, ai); +} + +static void asm_borbxor(ASMState *as, IRIns *ir, A64Ins ai) +{ + IRRef lref = ir->op1, rref = ir->op2; + IRIns *irl = IR(lref), *irr = IR(rref); + if ((canfuse(as, irl) && irl->o == IR_BNOT && !irref_isk(rref)) || + (canfuse(as, irr) && irr->o == IR_BNOT && !irref_isk(lref))) { + Reg left, dest = ra_dest(as, ir, RSET_GPR); + uint32_t m; + if (irl->o == IR_BNOT) { + IRRef tmp = lref; lref = rref; rref = tmp; + } + left = ra_alloc1(as, lref, RSET_GPR); + ai |= A64I_ON; + if (irt_is64(ir->t)) ai |= A64I_X; + m = asm_fuseopm(as, ai, IR(rref)->op1, rset_exclude(RSET_GPR, left)); + emit_dn(as, ai^m, dest, left); + } else { + asm_intop(as, ir, ai); + } +} + +static void asm_bor(ASMState *as, IRIns *ir) +{ + if (asm_fuseorshift(as, ir)) + return; + asm_borbxor(as, ir, A64I_ORRw); +} + +#define asm_bxor(as, ir) asm_borbxor(as, ir, A64I_EORw) + +static void asm_bnot(ASMState *as, IRIns *ir) +{ + A64Ins ai = A64I_MVNw; + Reg dest = ra_dest(as, ir, RSET_GPR); + uint32_t m = asm_fuseopm(as, ai, ir->op1, RSET_GPR); + if (irt_is64(ir->t)) ai |= A64I_X; + emit_d(as, ai^m, dest); +} + +static void asm_bswap(ASMState *as, IRIns *ir) +{ + Reg dest = ra_dest(as, ir, RSET_GPR); + Reg left = ra_alloc1(as, ir->op1, RSET_GPR); + emit_dn(as, irt_is64(ir->t) ? A64I_REVx : A64I_REVw, dest, left); +} + +static void asm_bitshift(ASMState *as, IRIns *ir, A64Ins ai, A64Shift sh) +{ + int32_t shmask = irt_is64(ir->t) ? 63 : 31; + if (irref_isk(ir->op2)) { /* Constant shifts. */ + Reg left, dest = ra_dest(as, ir, RSET_GPR); + int32_t shift = (IR(ir->op2)->i & shmask); + IRIns *irl = IR(ir->op1); + if (shmask == 63) ai += A64I_UBFMx - A64I_UBFMw; + + /* Fuse BSHL + BSHR/BSAR into UBFM/SBFM aka UBFX/SBFX/UBFIZ/SBFIZ. */ + if ((sh == A64SH_LSR || sh == A64SH_ASR) && canfuse(as, irl)) { + if (irl->o == IR_BSHL && irref_isk(irl->op2)) { + int32_t shift2 = (IR(irl->op2)->i & shmask); + shift = ((shift - shift2) & shmask); + shmask -= shift2; + ir = irl; + } + } + + left = ra_alloc1(as, ir->op1, RSET_GPR); + switch (sh) { + case A64SH_LSL: + emit_dn(as, ai | A64F_IMMS(shmask-shift) | + A64F_IMMR((shmask-shift+1)&shmask), dest, left); + break; + case A64SH_LSR: case A64SH_ASR: + emit_dn(as, ai | A64F_IMMS(shmask) | A64F_IMMR(shift), dest, left); + break; + case A64SH_ROR: + emit_dnm(as, ai | A64F_IMMS(shift), dest, left, left); + break; + } + } else { /* Variable-length shifts. */ + Reg dest = ra_dest(as, ir, RSET_GPR); + Reg left = ra_alloc1(as, ir->op1, RSET_GPR); + Reg right = ra_alloc1(as, ir->op2, rset_exclude(RSET_GPR, left)); + emit_dnm(as, (shmask == 63 ? A64I_SHRx : A64I_SHRw) | A64F_BSH(sh), dest, left, right); + } +} + +#define asm_bshl(as, ir) asm_bitshift(as, ir, A64I_UBFMw, A64SH_LSL) +#define asm_bshr(as, ir) asm_bitshift(as, ir, A64I_UBFMw, A64SH_LSR) +#define asm_bsar(as, ir) asm_bitshift(as, ir, A64I_SBFMw, A64SH_ASR) +#define asm_bror(as, ir) asm_bitshift(as, ir, A64I_EXTRw, A64SH_ROR) +#define asm_brol(as, ir) lj_assertA(0, "unexpected BROL") + +static void asm_intmin_max(ASMState *as, IRIns *ir, A64CC cc) +{ + Reg dest = ra_dest(as, ir, RSET_GPR); + Reg left = ra_hintalloc(as, ir->op1, dest, RSET_GPR); + Reg right = ra_alloc1(as, ir->op2, rset_exclude(RSET_GPR, left)); + emit_dnm(as, A64I_CSELw|A64F_CC(cc), dest, left, right); + emit_nm(as, A64I_CMPw, left, right); +} + +static void asm_fpmin_max(ASMState *as, IRIns *ir, A64CC fcc) +{ + Reg dest = (ra_dest(as, ir, RSET_FPR) & 31); + Reg right, left = ra_alloc2(as, ir, RSET_FPR); + right = ((left >> 8) & 31); left &= 31; + emit_dnm(as, A64I_FCSELd | A64F_CC(fcc), dest, right, left); + emit_nm(as, A64I_FCMPd, left, right); +} + +static void asm_min_max(ASMState *as, IRIns *ir, A64CC cc, A64CC fcc) +{ + if (irt_isnum(ir->t)) + asm_fpmin_max(as, ir, fcc); + else + asm_intmin_max(as, ir, cc); +} + +#define asm_min(as, ir) asm_min_max(as, ir, CC_LT, CC_PL) +#define asm_max(as, ir) asm_min_max(as, ir, CC_GT, CC_LE) + +/* -- Comparisons --------------------------------------------------------- */ + +/* Map of comparisons to flags. ORDER IR. */ +static const uint8_t asm_compmap[IR_ABC+1] = { + /* op FP swp int cc FP cc */ + /* LT */ CC_GE + (CC_HS << 4), + /* GE x */ CC_LT + (CC_HI << 4), + /* LE */ CC_GT + (CC_HI << 4), + /* GT x */ CC_LE + (CC_HS << 4), + /* ULT x */ CC_HS + (CC_LS << 4), + /* UGE */ CC_LO + (CC_LO << 4), + /* ULE x */ CC_HI + (CC_LO << 4), + /* UGT */ CC_LS + (CC_LS << 4), + /* EQ */ CC_NE + (CC_NE << 4), + /* NE */ CC_EQ + (CC_EQ << 4), + /* ABC */ CC_LS + (CC_LS << 4) /* Same as UGT. */ +}; + +/* FP comparisons. */ +static void asm_fpcomp(ASMState *as, IRIns *ir) +{ + Reg left, right; + A64Ins ai; + int swp = ((ir->o ^ (ir->o >> 2)) & ~(ir->o >> 3) & 1); + if (!swp && irref_isk(ir->op2) && ir_knum(IR(ir->op2))->u64 == 0) { + left = (ra_alloc1(as, ir->op1, RSET_FPR) & 31); + right = 0; + ai = A64I_FCMPZd; + } else { + left = ra_alloc2(as, ir, RSET_FPR); + if (swp) { + right = (left & 31); left = ((left >> 8) & 31); + } else { + right = ((left >> 8) & 31); left &= 31; + } + ai = A64I_FCMPd; + } + asm_guardcc(as, (asm_compmap[ir->o] >> 4)); + emit_nm(as, ai, left, right); +} + +/* Integer comparisons. */ +static void asm_intcomp(ASMState *as, IRIns *ir) +{ + A64CC oldcc, cc = (asm_compmap[ir->o] & 15); + A64Ins ai = irt_is64(ir->t) ? A64I_CMPx : A64I_CMPw; + IRRef lref = ir->op1, rref = ir->op2; + Reg left; + uint32_t m; + int cmpprev0 = 0; + lj_assertA(irt_is64(ir->t) || irt_isint(ir->t) || + irt_isu32(ir->t) || irt_isaddr(ir->t) || irt_isu8(ir->t), + "bad comparison data type %d", irt_type(ir->t)); + if (asm_swapops(as, lref, rref)) { + IRRef tmp = lref; lref = rref; rref = tmp; + if (cc >= CC_GE) cc ^= 7; /* LT <-> GT, LE <-> GE */ + else if (cc > CC_NE) cc ^= 11; /* LO <-> HI, LS <-> HS */ + } + oldcc = cc; + if (irref_isk(rref) && get_k64val(as, rref) == 0) { + IRIns *irl = IR(lref); + if (cc == CC_GE) cc = CC_PL; + else if (cc == CC_LT) cc = CC_MI; + else if (cc > CC_NE) goto nocombine; /* Other conds don't work with tst. */ + cmpprev0 = (irl+1 == ir); + /* Combine and-cmp-bcc into tbz/tbnz or and-cmp into tst. */ + if (cmpprev0 && irl->o == IR_BAND && !ra_used(irl)) { + IRRef blref = irl->op1, brref = irl->op2; + uint32_t m2 = 0; + Reg bleft; + if (asm_swapops(as, blref, brref)) { + Reg tmp = blref; blref = brref; brref = tmp; + } + if (irref_isk(brref)) { + uint64_t k = get_k64val(as, brref); + if (k && !(k & (k-1)) && (cc == CC_EQ || cc == CC_NE)) { + asm_guardtnb(as, cc == CC_EQ ? A64I_TBZ : A64I_TBNZ, + ra_alloc1(as, blref, RSET_GPR), emit_ctz64(k)); + return; + } + m2 = emit_isk13(k, irt_is64(irl->t)); + } + bleft = ra_alloc1(as, blref, RSET_GPR); + ai = (irt_is64(irl->t) ? A64I_TSTx : A64I_TSTw); + if (!m2) + m2 = asm_fuseopm(as, ai, brref, rset_exclude(RSET_GPR, bleft)); + asm_guardcc(as, cc); + emit_n(as, ai^m2, bleft); + return; + } + if (cc == CC_EQ || cc == CC_NE) { + /* Combine cmp-bcc into cbz/cbnz. */ + ai = cc == CC_EQ ? A64I_CBZ : A64I_CBNZ; + if (irt_is64(ir->t)) ai |= A64I_X; + asm_guardcnb(as, ai, ra_alloc1(as, lref, RSET_GPR)); + return; + } + } +nocombine: + left = ra_alloc1(as, lref, RSET_GPR); + m = asm_fuseopm(as, ai, rref, rset_exclude(RSET_GPR, left)); + asm_guardcc(as, cc); + emit_n(as, ai^m, left); + /* Signed comparison with zero and referencing previous ins? */ + if (cmpprev0 && (oldcc <= CC_NE || oldcc >= CC_GE)) + as->flagmcp = as->mcp; /* Allow elimination of the compare. */ +} + +static void asm_comp(ASMState *as, IRIns *ir) +{ + if (irt_isnum(ir->t)) + asm_fpcomp(as, ir); + else + asm_intcomp(as, ir); +} + +#define asm_equal(as, ir) asm_comp(as, ir) + +/* -- Split register ops -------------------------------------------------- */ + +/* Hiword op of a split 64/64 bit op. Previous op is the loword op. */ +static void asm_hiop(ASMState *as, IRIns *ir) +{ + /* HIOP is marked as a store because it needs its own DCE logic. */ + int uselo = ra_used(ir-1), usehi = ra_used(ir); /* Loword/hiword used? */ + if (LJ_UNLIKELY(!(as->flags & JIT_F_OPT_DCE))) uselo = usehi = 1; + if (!usehi) return; /* Skip unused hiword op for all remaining ops. */ + switch ((ir-1)->o) { + case IR_CALLN: + case IR_CALLL: + case IR_CALLS: + case IR_CALLXS: + if (!uselo) + ra_allocref(as, ir->op1, RID2RSET(RID_RETLO)); /* Mark lo op as used. */ + break; + default: lj_assertA(0, "bad HIOP for op %d", (ir-1)->o); break; + } +} + +/* -- Profiling ----------------------------------------------------------- */ + +static void asm_prof(ASMState *as, IRIns *ir) +{ + uint32_t k = emit_isk13(HOOK_PROFILE, 0); + lj_assertA(k != 0, "HOOK_PROFILE does not fit in K13"); + UNUSED(ir); + asm_guardcc(as, CC_NE); + emit_n(as, A64I_TSTw^k, RID_TMP); + emit_lsptr(as, A64I_LDRB, RID_TMP, (void *)&J2G(as->J)->hookmask); +} + +/* -- Stack handling ------------------------------------------------------ */ + +/* Check Lua stack size for overflow. Use exit handler as fallback. */ +static void asm_stack_check(ASMState *as, BCReg topslot, + IRIns *irp, RegSet allow, ExitNo exitno) +{ + Reg pbase; + uint32_t k; + if (irp) { + if (!ra_hasspill(irp->s)) { + pbase = irp->r; + lj_assertA(ra_hasreg(pbase), "base reg lost"); + } else if (allow) { + pbase = rset_pickbot(allow); + } else { + pbase = RID_RET; + emit_lso(as, A64I_LDRx, RID_RET, RID_SP, 0); /* Restore temp register. */ + } + } else { + pbase = RID_BASE; + } + emit_cond_branch(as, CC_LS, asm_exitstub_addr(as, exitno)); + k = emit_isk12((8*topslot)); + lj_assertA(k, "slot offset %d does not fit in K12", 8*topslot); + emit_n(as, A64I_CMPx^k, RID_TMP); + emit_dnm(as, A64I_SUBx, RID_TMP, RID_TMP, pbase); + emit_lso(as, A64I_LDRx, RID_TMP, RID_TMP, + (int32_t)offsetof(lua_State, maxstack)); + if (irp) { /* Must not spill arbitrary registers in head of side trace. */ + if (ra_hasspill(irp->s)) + emit_lso(as, A64I_LDRx, pbase, RID_SP, sps_scale(irp->s)); + emit_lso(as, A64I_LDRx, RID_TMP, RID_GL, glofs(as, &J2G(as->J)->cur_L)); + if (ra_hasspill(irp->s) && !allow) + emit_lso(as, A64I_STRx, RID_RET, RID_SP, 0); /* Save temp register. */ + } else { + emit_getgl(as, RID_TMP, cur_L); + } +} + +/* Restore Lua stack from on-trace state. */ +static void asm_stack_restore(ASMState *as, SnapShot *snap) +{ + SnapEntry *map = &as->T->snapmap[snap->mapofs]; +#ifdef LUA_USE_ASSERT + SnapEntry *flinks = &as->T->snapmap[snap_nextofs(as->T, snap)-1-LJ_FR2]; +#endif + MSize n, nent = snap->nent; + /* Store the value of all modified slots to the Lua stack. */ + for (n = 0; n < nent; n++) { + SnapEntry sn = map[n]; + BCReg s = snap_slot(sn); + int32_t ofs = 8*((int32_t)s-1-LJ_FR2); + IRRef ref = snap_ref(sn); + IRIns *ir = IR(ref); + if ((sn & SNAP_NORESTORE)) + continue; + if ((sn & SNAP_KEYINDEX)) { + RegSet allow = rset_exclude(RSET_GPR, RID_BASE); + Reg r = irref_isk(ref) ? ra_allock(as, ir->i, allow) : + ra_alloc1(as, ref, allow); + rset_clear(allow, r); + emit_lso(as, A64I_STRw, r, RID_BASE, ofs); + emit_lso(as, A64I_STRw, ra_allock(as, LJ_KEYINDEX, allow), RID_BASE, ofs+4); + } else if (irt_isnum(ir->t)) { + Reg src = ra_alloc1(as, ref, RSET_FPR); + emit_lso(as, A64I_STRd, (src & 31), RID_BASE, ofs); + } else { + asm_tvstore64(as, RID_BASE, ofs, ref); + } + checkmclim(as); + } + lj_assertA(map + nent == flinks, "inconsistent frames in snapshot"); +} + +/* -- GC handling --------------------------------------------------------- */ + +/* Marker to prevent patching the GC check exit. */ +#define ARM64_NOPATCH_GC_CHECK \ + (A64I_ORRx|A64F_D(RID_TMP)|A64F_M(RID_TMP)|A64F_N(RID_TMP)) + +/* Check GC threshold and do one or more GC steps. */ +static void asm_gc_check(ASMState *as) +{ + const CCallInfo *ci = &lj_ir_callinfo[IRCALL_lj_gc_step_jit]; + IRRef args[2]; + MCLabel l_end; + Reg tmp2; + ra_evictset(as, RSET_SCRATCH); + l_end = emit_label(as); + /* Exit trace if in GCSatomic or GCSfinalize. Avoids syncing GC objects. */ + asm_guardcnb(as, A64I_CBNZ, RID_RET); /* Assumes asm_snap_prep() is done. */ + *--as->mcp = ARM64_NOPATCH_GC_CHECK; + args[0] = ASMREF_TMP1; /* global_State *g */ + args[1] = ASMREF_TMP2; /* MSize steps */ + asm_gencall(as, ci, args); + emit_dm(as, A64I_MOVx, ra_releasetmp(as, ASMREF_TMP1), RID_GL); + tmp2 = ra_releasetmp(as, ASMREF_TMP2); + emit_loadi(as, tmp2, as->gcsteps); + /* Jump around GC step if GC total < GC threshold. */ + emit_cond_branch(as, CC_LS, l_end); + emit_nm(as, A64I_CMPx, RID_TMP, tmp2); + emit_getgl(as, tmp2, gc.threshold); + emit_getgl(as, RID_TMP, gc.total); + as->gcsteps = 0; + checkmclim(as); +} + +/* -- Loop handling ------------------------------------------------------- */ + +/* Fixup the loop branch. */ +static void asm_loop_fixup(ASMState *as) +{ + MCode *p = as->mctop; + MCode *target = as->mcp; + if (as->loopinv) { /* Inverted loop branch? */ + uint32_t mask = (p[-2] & 0x7e000000) == 0x36000000 ? 0x3fffu : 0x7ffffu; + ptrdiff_t delta = target - (p - 2); + /* asm_guard* already inverted the bcc/tnb/cnb and patched the final b. */ + p[-2] |= ((uint32_t)delta & mask) << 5; + } else { + ptrdiff_t delta = target - (p - 1); + p[-1] = A64I_B | A64F_S26(delta); + } +} + +/* Fixup the tail of the loop. */ +static void asm_loop_tail_fixup(ASMState *as) +{ + UNUSED(as); /* Nothing to do. */ +} + +/* -- Head of trace ------------------------------------------------------- */ + +/* Reload L register from g->cur_L. */ +static void asm_head_lreg(ASMState *as) +{ + IRIns *ir = IR(ASMREF_L); + if (ra_used(ir)) { + Reg r = ra_dest(as, ir, RSET_GPR); + emit_getgl(as, r, cur_L); + ra_evictk(as); + } +} + +/* Coalesce BASE register for a root trace. */ +static void asm_head_root_base(ASMState *as) +{ + IRIns *ir; + asm_head_lreg(as); + ir = IR(REF_BASE); + if (ra_hasreg(ir->r) && (rset_test(as->modset, ir->r) || irt_ismarked(ir->t))) + ra_spill(as, ir); + ra_destreg(as, ir, RID_BASE); +} + +/* Coalesce BASE register for a side trace. */ +static RegSet asm_head_side_base(ASMState *as, IRIns *irp, RegSet allow) +{ + IRIns *ir; + asm_head_lreg(as); + ir = IR(REF_BASE); + if (ra_hasreg(ir->r) && (rset_test(as->modset, ir->r) || irt_ismarked(ir->t))) + ra_spill(as, ir); + if (ra_hasspill(irp->s)) { + rset_clear(allow, ra_dest(as, ir, allow)); + } else { + Reg r = irp->r; + lj_assertA(ra_hasreg(r), "base reg lost"); + rset_clear(allow, r); + if (r != ir->r && !rset_test(as->freeset, r)) + ra_restore(as, regcost_ref(as->cost[r])); + ra_destreg(as, ir, r); + } + return allow; +} + +/* -- Tail of trace ------------------------------------------------------- */ + +/* Fixup the tail code. */ +static void asm_tail_fixup(ASMState *as, TraceNo lnk) +{ + MCode *p = as->mctop; + MCode *target; + /* Undo the sp adjustment in BC_JLOOP when exiting to the interpreter. */ + int32_t spadj = as->T->spadjust + (lnk ? 0 : sps_scale(SPS_FIXED)); + if (spadj == 0) { + *--p = A64I_LE(A64I_NOP); + as->mctop = p; + } else { + /* Patch stack adjustment. */ + uint32_t k = emit_isk12(spadj); + lj_assertA(k, "stack adjustment %d does not fit in K12", spadj); + p[-2] = (A64I_ADDx^k) | A64F_D(RID_SP) | A64F_N(RID_SP); + } + /* Patch exit branch. */ + target = lnk ? traceref(as->J, lnk)->mcode : (MCode *)lj_vm_exit_interp; + p[-1] = A64I_B | A64F_S26((target-p)+1); +} + +/* Prepare tail of code. */ +static void asm_tail_prep(ASMState *as) +{ + MCode *p = as->mctop - 1; /* Leave room for exit branch. */ + if (as->loopref) { + as->invmcp = as->mcp = p; + } else { + as->mcp = p-1; /* Leave room for stack pointer adjustment. */ + as->invmcp = NULL; + } + *p = 0; /* Prevent load/store merging. */ +} + +/* -- Trace setup --------------------------------------------------------- */ + +/* Ensure there are enough stack slots for call arguments. */ +static Reg asm_setup_call_slots(ASMState *as, IRIns *ir, const CCallInfo *ci) +{ + IRRef args[CCI_NARGS_MAX*2]; + uint32_t i, nargs = CCI_XNARGS(ci); + int nslots = 0, ngpr = REGARG_NUMGPR, nfpr = REGARG_NUMFPR; + asm_collectargs(as, ir, ci, args); + for (i = 0; i < nargs; i++) { + if (args[i] && irt_isfp(IR(args[i])->t)) { + if (nfpr > 0) nfpr--; else nslots += 2; + } else { + if (ngpr > 0) ngpr--; else nslots += 2; + } + } + if (nslots > as->evenspill) /* Leave room for args in stack slots. */ + as->evenspill = nslots; + return REGSP_HINT(RID_RET); +} + +static void asm_setup_target(ASMState *as) +{ + /* May need extra exit for asm_stack_check on side traces. */ + asm_exitstub_setup(as, as->T->nsnap + (as->parent ? 1 : 0)); +} + +#if LJ_BE +/* ARM64 instructions are always little-endian. Swap for ARM64BE. */ +static void asm_mcode_fixup(MCode *mcode, MSize size) +{ + MCode *pe = (MCode *)((char *)mcode + size); + while (mcode < pe) { + MCode ins = *mcode; + *mcode++ = lj_bswap(ins); + } +} +#define LJ_TARGET_MCODE_FIXUP 1 +#endif + +/* -- Trace patching ------------------------------------------------------ */ + +/* Patch exit jumps of existing machine code to a new target. */ +void lj_asm_patchexit(jit_State *J, GCtrace *T, ExitNo exitno, MCode *target) +{ + MCode *p = T->mcode; + MCode *pe = (MCode *)((char *)p + T->szmcode); + MCode *cstart = NULL; + MCode *mcarea = lj_mcode_patch(J, p, 0); + MCode *px = exitstub_trace_addr(T, exitno); + int patchlong = 1; + /* Note: this assumes a trace exit is only ever patched once. */ + for (; p < pe; p++) { + /* Look for exitstub branch, replace with branch to target. */ + ptrdiff_t delta = target - p; + MCode ins = A64I_LE(*p); + if ((ins & 0xff000000u) == 0x54000000u && + ((ins ^ ((px-p)<<5)) & 0x00ffffe0u) == 0) { + /* Patch bcc, if within range. */ + if (A64F_S_OK(delta, 19)) { + *p = A64I_LE((ins & 0xff00001fu) | A64F_S19(delta)); + if (!cstart) cstart = p; + } + } else if ((ins & 0xfc000000u) == 0x14000000u && + ((ins ^ (px-p)) & 0x03ffffffu) == 0) { + /* Patch b. */ + lj_assertJ(A64F_S_OK(delta, 26), "branch target out of range"); + *p = A64I_LE((ins & 0xfc000000u) | A64F_S26(delta)); + if (!cstart) cstart = p; + } else if ((ins & 0x7e000000u) == 0x34000000u && + ((ins ^ ((px-p)<<5)) & 0x00ffffe0u) == 0) { + /* Patch cbz/cbnz, if within range. */ + if (p[-1] == ARM64_NOPATCH_GC_CHECK) { + patchlong = 0; + } else if (A64F_S_OK(delta, 19)) { + *p = A64I_LE((ins & 0xff00001fu) | A64F_S19(delta)); + if (!cstart) cstart = p; + } + } else if ((ins & 0x7e000000u) == 0x36000000u && + ((ins ^ ((px-p)<<5)) & 0x0007ffe0u) == 0) { + /* Patch tbz/tbnz, if within range. */ + if (A64F_S_OK(delta, 14)) { + *p = A64I_LE((ins & 0xfff8001fu) | A64F_S14(delta)); + if (!cstart) cstart = p; + } + } + } + /* Always patch long-range branch in exit stub itself. Except, if we can't. */ + if (patchlong) { + ptrdiff_t delta = target - px; + lj_assertJ(A64F_S_OK(delta, 26), "branch target out of range"); + *px = A64I_B | A64F_S26(delta); + if (!cstart) cstart = px; + } + if (cstart) lj_mcode_sync(cstart, px+1); + lj_mcode_patch(J, mcarea, 1); +} + diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_asm_mips.h b/fluent-bit/lib/luajit-3065c9/src/lj_asm_mips.h new file mode 100644 index 00000000..1686b40f --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_asm_mips.h @@ -0,0 +1,2808 @@ +/* +** MIPS IR assembler (SSA IR -> machine code). +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +/* -- Register allocator extensions --------------------------------------- */ + +/* Allocate a register with a hint. */ +static Reg ra_hintalloc(ASMState *as, IRRef ref, Reg hint, RegSet allow) +{ + Reg r = IR(ref)->r; + if (ra_noreg(r)) { + if (!ra_hashint(r) && !iscrossref(as, ref)) + ra_sethint(IR(ref)->r, hint); /* Propagate register hint. */ + r = ra_allocref(as, ref, allow); + } + ra_noweak(as, r); + return r; +} + +/* Allocate a register or RID_ZERO. */ +static Reg ra_alloc1z(ASMState *as, IRRef ref, RegSet allow) +{ + Reg r = IR(ref)->r; + if (ra_noreg(r)) { + if (!(allow & RSET_FPR) && irref_isk(ref) && get_kval(as, ref) == 0) + return RID_ZERO; + r = ra_allocref(as, ref, allow); + } else { + ra_noweak(as, r); + } + return r; +} + +/* Allocate two source registers for three-operand instructions. */ +static Reg ra_alloc2(ASMState *as, IRIns *ir, RegSet allow) +{ + IRIns *irl = IR(ir->op1), *irr = IR(ir->op2); + Reg left = irl->r, right = irr->r; + if (ra_hasreg(left)) { + ra_noweak(as, left); + if (ra_noreg(right)) + right = ra_alloc1z(as, ir->op2, rset_exclude(allow, left)); + else + ra_noweak(as, right); + } else if (ra_hasreg(right)) { + ra_noweak(as, right); + left = ra_alloc1z(as, ir->op1, rset_exclude(allow, right)); + } else if (ra_hashint(right)) { + right = ra_alloc1z(as, ir->op2, allow); + left = ra_alloc1z(as, ir->op1, rset_exclude(allow, right)); + } else { + left = ra_alloc1z(as, ir->op1, allow); + right = ra_alloc1z(as, ir->op2, rset_exclude(allow, left)); + } + return left | (right << 8); +} + +/* -- Guard handling ------------------------------------------------------ */ + +/* Need some spare long-range jump slots, for out-of-range branches. */ +#define MIPS_SPAREJUMP 4 + +/* Setup spare long-range jump slots per mcarea. */ +static void asm_sparejump_setup(ASMState *as) +{ + MCode *mxp = as->mctop; + if ((char *)mxp == (char *)as->J->mcarea + as->J->szmcarea) { + mxp -= MIPS_SPAREJUMP*2; + lj_assertA(MIPSI_NOP == 0, "bad NOP"); + memset(mxp, 0, MIPS_SPAREJUMP*2*sizeof(MCode)); + as->mctop = mxp; + } +} + +static MCode *asm_sparejump_use(MCode *mcarea, MCode tjump) +{ + MCode *mxp = (MCode *)((char *)mcarea + ((MCLink *)mcarea)->size); + int slot = MIPS_SPAREJUMP; + while (slot--) { + mxp -= 2; + if (*mxp == tjump) { + return mxp; + } else if (*mxp == MIPSI_NOP) { + *mxp = tjump; + return mxp; + } + } + return NULL; +} + +/* Setup exit stub after the end of each trace. */ +static void asm_exitstub_setup(ASMState *as) +{ + MCode *mxp = as->mctop; + /* sw TMP, 0(sp); j ->vm_exit_handler; li TMP, traceno */ + *--mxp = MIPSI_LI|MIPSF_T(RID_TMP)|as->T->traceno; + *--mxp = MIPSI_J|((((uintptr_t)(void *)lj_vm_exit_handler)>>2)&0x03ffffffu); + lj_assertA(((uintptr_t)mxp ^ (uintptr_t)(void *)lj_vm_exit_handler)>>28 == 0, + "branch target out of range"); + *--mxp = MIPSI_SW|MIPSF_T(RID_TMP)|MIPSF_S(RID_SP)|0; + as->mctop = mxp; +} + +/* Keep this in-sync with exitstub_trace_addr(). */ +#define asm_exitstub_addr(as) ((as)->mctop) + +/* Emit conditional branch to exit for guard. */ +static void asm_guard(ASMState *as, MIPSIns mi, Reg rs, Reg rt) +{ + MCode *target = asm_exitstub_addr(as); + MCode *p = as->mcp; + if (LJ_UNLIKELY(p == as->invmcp)) { + as->invmcp = NULL; + as->loopinv = 1; + as->mcp = p+1; +#if !LJ_TARGET_MIPSR6 + mi = mi ^ ((mi>>28) == 1 ? 0x04000000u : 0x00010000u); /* Invert cond. */ +#else + mi = mi ^ ((mi>>28) == 1 ? 0x04000000u : + (mi>>28) == 4 ? 0x00800000u : 0x00010000u); /* Invert cond. */ +#endif + target = p; /* Patch target later in asm_loop_fixup. */ + } + emit_ti(as, MIPSI_LI, RID_TMP, as->snapno); + emit_branch(as, mi, rs, rt, target); +} + +/* -- Operand fusion ------------------------------------------------------ */ + +/* Limit linear search to this distance. Avoids O(n^2) behavior. */ +#define CONFLICT_SEARCH_LIM 31 + +/* Check if there's no conflicting instruction between curins and ref. */ +static int noconflict(ASMState *as, IRRef ref, IROp conflict) +{ + IRIns *ir = as->ir; + IRRef i = as->curins; + if (i > ref + CONFLICT_SEARCH_LIM) + return 0; /* Give up, ref is too far away. */ + while (--i > ref) + if (ir[i].o == conflict) + return 0; /* Conflict found. */ + return 1; /* Ok, no conflict. */ +} + +/* Fuse the array base of colocated arrays. */ +static int32_t asm_fuseabase(ASMState *as, IRRef ref) +{ + IRIns *ir = IR(ref); + if (ir->o == IR_TNEW && ir->op1 <= LJ_MAX_COLOSIZE && + !neverfuse(as) && noconflict(as, ref, IR_NEWREF)) + return (int32_t)sizeof(GCtab); + return 0; +} + +/* Fuse array/hash/upvalue reference into register+offset operand. */ +static Reg asm_fuseahuref(ASMState *as, IRRef ref, int32_t *ofsp, RegSet allow) +{ + IRIns *ir = IR(ref); + if (ra_noreg(ir->r)) { + if (ir->o == IR_AREF) { + if (mayfuse(as, ref)) { + if (irref_isk(ir->op2)) { + IRRef tab = IR(ir->op1)->op1; + int32_t ofs = asm_fuseabase(as, tab); + IRRef refa = ofs ? tab : ir->op1; + ofs += 8*IR(ir->op2)->i; + if (checki16(ofs)) { + *ofsp = ofs; + return ra_alloc1(as, refa, allow); + } + } + } + } else if (ir->o == IR_HREFK) { + if (mayfuse(as, ref)) { + int32_t ofs = (int32_t)(IR(ir->op2)->op2 * sizeof(Node)); + if (checki16(ofs)) { + *ofsp = ofs; + return ra_alloc1(as, ir->op1, allow); + } + } + } else if (ir->o == IR_UREFC) { + if (irref_isk(ir->op1)) { + GCfunc *fn = ir_kfunc(IR(ir->op1)); + intptr_t ofs = (intptr_t)&gcref(fn->l.uvptr[(ir->op2 >> 8)])->uv.tv; + intptr_t jgl = (intptr_t)J2G(as->J); + if ((uintptr_t)(ofs-jgl) < 65536) { + *ofsp = ofs-jgl-32768; + return RID_JGL; + } else { + *ofsp = (int16_t)ofs; + return ra_allock(as, ofs-(int16_t)ofs, allow); + } + } + } else if (ir->o == IR_TMPREF) { + *ofsp = (int32_t)(offsetof(global_State, tmptv)-32768); + return RID_JGL; + } + } + *ofsp = 0; + return ra_alloc1(as, ref, allow); +} + +/* Fuse XLOAD/XSTORE reference into load/store operand. */ +static void asm_fusexref(ASMState *as, MIPSIns mi, Reg rt, IRRef ref, + RegSet allow, int32_t ofs) +{ + IRIns *ir = IR(ref); + Reg base; + if (ra_noreg(ir->r) && canfuse(as, ir)) { + if (ir->o == IR_ADD) { + intptr_t ofs2; + if (irref_isk(ir->op2) && (ofs2 = ofs + get_kval(as, ir->op2), + checki16(ofs2))) { + ref = ir->op1; + ofs = (int32_t)ofs2; + } + } else if (ir->o == IR_STRREF) { + intptr_t ofs2 = 65536; + lj_assertA(ofs == 0, "bad usage"); + ofs = (int32_t)sizeof(GCstr); + if (irref_isk(ir->op2)) { + ofs2 = ofs + get_kval(as, ir->op2); + ref = ir->op1; + } else if (irref_isk(ir->op1)) { + ofs2 = ofs + get_kval(as, ir->op1); + ref = ir->op2; + } + if (!checki16(ofs2)) { + /* NYI: Fuse ADD with constant. */ + Reg right, left = ra_alloc2(as, ir, allow); + right = (left >> 8); left &= 255; + emit_hsi(as, mi, rt, RID_TMP, ofs); + emit_dst(as, MIPSI_AADDU, RID_TMP, left, right); + return; + } + ofs = ofs2; + } + } + base = ra_alloc1(as, ref, allow); + emit_hsi(as, mi, rt, base, ofs); +} + +/* -- Calls --------------------------------------------------------------- */ + +/* Generate a call to a C function. */ +static void asm_gencall(ASMState *as, const CCallInfo *ci, IRRef *args) +{ + uint32_t n, nargs = CCI_XNARGS(ci); + int32_t ofs = LJ_32 ? 16 : 0; +#if LJ_SOFTFP + Reg gpr = REGARG_FIRSTGPR; +#else + Reg gpr, fpr = REGARG_FIRSTFPR; +#endif + if ((void *)ci->func) + emit_call(as, (void *)ci->func, 1); +#if !LJ_SOFTFP + for (gpr = REGARG_FIRSTGPR; gpr <= REGARG_LASTGPR; gpr++) + as->cost[gpr] = REGCOST(~0u, ASMREF_L); + gpr = REGARG_FIRSTGPR; +#endif + for (n = 0; n < nargs; n++) { /* Setup args. */ + IRRef ref = args[n]; + if (ref) { + IRIns *ir = IR(ref); +#if !LJ_SOFTFP + if (irt_isfp(ir->t) && fpr <= REGARG_LASTFPR && + !(ci->flags & CCI_VARARG)) { + lj_assertA(rset_test(as->freeset, fpr), + "reg %d not free", fpr); /* Already evicted. */ + ra_leftov(as, fpr, ref); + fpr += LJ_32 ? 2 : 1; + gpr += (LJ_32 && irt_isnum(ir->t)) ? 2 : 1; + } else +#endif + { +#if LJ_32 && !LJ_SOFTFP + fpr = REGARG_LASTFPR+1; +#endif + if (LJ_32 && irt_isnum(ir->t)) gpr = (gpr+1) & ~1; + if (gpr <= REGARG_LASTGPR) { + lj_assertA(rset_test(as->freeset, gpr), + "reg %d not free", gpr); /* Already evicted. */ +#if !LJ_SOFTFP + if (irt_isfp(ir->t)) { + RegSet of = as->freeset; + Reg r; + /* Workaround to protect argument GPRs from being used for remat. */ + as->freeset &= ~RSET_RANGE(REGARG_FIRSTGPR, REGARG_LASTGPR+1); + r = ra_alloc1(as, ref, RSET_FPR); + as->freeset |= (of & RSET_RANGE(REGARG_FIRSTGPR, REGARG_LASTGPR+1)); + if (irt_isnum(ir->t)) { +#if LJ_32 + emit_tg(as, MIPSI_MFC1, gpr+(LJ_BE?0:1), r+1); + emit_tg(as, MIPSI_MFC1, gpr+(LJ_BE?1:0), r); + lj_assertA(rset_test(as->freeset, gpr+1), + "reg %d not free", gpr+1); /* Already evicted. */ + gpr += 2; +#else + emit_tg(as, MIPSI_DMFC1, gpr, r); + gpr++; fpr++; +#endif + } else if (irt_isfloat(ir->t)) { + emit_tg(as, MIPSI_MFC1, gpr, r); + gpr++; +#if LJ_64 + fpr++; +#endif + } + } else +#endif + { + ra_leftov(as, gpr, ref); + gpr++; +#if LJ_64 && !LJ_SOFTFP + fpr++; +#endif + } + } else { + Reg r = ra_alloc1z(as, ref, !LJ_SOFTFP && irt_isfp(ir->t) ? RSET_FPR : RSET_GPR); +#if LJ_32 + if (irt_isnum(ir->t)) ofs = (ofs + 4) & ~4; + emit_spstore(as, ir, r, ofs); + ofs += irt_isnum(ir->t) ? 8 : 4; +#else + emit_spstore(as, ir, r, ofs + ((LJ_BE && !irt_isfp(ir->t) && !irt_is64(ir->t)) ? 4 : 0)); + ofs += 8; +#endif + } + } + } else { +#if !LJ_SOFTFP + fpr = REGARG_LASTFPR+1; +#endif + if (gpr <= REGARG_LASTGPR) { + gpr++; +#if LJ_64 && !LJ_SOFTFP + fpr++; +#endif + } else { + ofs += LJ_32 ? 4 : 8; + } + } + checkmclim(as); + } +} + +/* Setup result reg/sp for call. Evict scratch regs. */ +static void asm_setupresult(ASMState *as, IRIns *ir, const CCallInfo *ci) +{ + RegSet drop = RSET_SCRATCH; + int hiop = ((ir+1)->o == IR_HIOP && !irt_isnil((ir+1)->t)); +#if !LJ_SOFTFP + if ((ci->flags & CCI_NOFPRCLOBBER)) + drop &= ~RSET_FPR; +#endif + if (ra_hasreg(ir->r)) + rset_clear(drop, ir->r); /* Dest reg handled below. */ + if (hiop && ra_hasreg((ir+1)->r)) + rset_clear(drop, (ir+1)->r); /* Dest reg handled below. */ + ra_evictset(as, drop); /* Evictions must be performed first. */ + if (ra_used(ir)) { + lj_assertA(!irt_ispri(ir->t), "PRI dest"); + if (!LJ_SOFTFP && irt_isfp(ir->t)) { + if ((ci->flags & CCI_CASTU64)) { + int32_t ofs = sps_scale(ir->s); + Reg dest = ir->r; + if (ra_hasreg(dest)) { + ra_free(as, dest); + ra_modified(as, dest); +#if LJ_32 + emit_tg(as, MIPSI_MTC1, RID_RETHI, dest+1); + emit_tg(as, MIPSI_MTC1, RID_RETLO, dest); +#else + emit_tg(as, MIPSI_DMTC1, RID_RET, dest); +#endif + } + if (ofs) { +#if LJ_32 + emit_tsi(as, MIPSI_SW, RID_RETLO, RID_SP, ofs+(LJ_BE?4:0)); + emit_tsi(as, MIPSI_SW, RID_RETHI, RID_SP, ofs+(LJ_BE?0:4)); +#else + emit_tsi(as, MIPSI_SD, RID_RET, RID_SP, ofs); +#endif + } + } else { + ra_destreg(as, ir, RID_FPRET); + } + } else if (hiop) { + ra_destpair(as, ir); + } else { + ra_destreg(as, ir, RID_RET); + } + } +} + +static void asm_callx(ASMState *as, IRIns *ir) +{ + IRRef args[CCI_NARGS_MAX*2]; + CCallInfo ci; + IRRef func; + IRIns *irf; + ci.flags = asm_callx_flags(as, ir); + asm_collectargs(as, ir, &ci, args); + asm_setupresult(as, ir, &ci); + func = ir->op2; irf = IR(func); + if (irf->o == IR_CARG) { func = irf->op1; irf = IR(func); } + if (irref_isk(func)) { /* Call to constant address. */ + ci.func = (ASMFunction)(void *)get_kval(as, func); + } else { /* Need specific register for indirect calls. */ + Reg r = ra_alloc1(as, func, RID2RSET(RID_CFUNCADDR)); + MCode *p = as->mcp; + if (r == RID_CFUNCADDR) + *--p = MIPSI_NOP; + else + *--p = MIPSI_MOVE | MIPSF_D(RID_CFUNCADDR) | MIPSF_S(r); + *--p = MIPSI_JALR | MIPSF_S(r); + as->mcp = p; + ci.func = (ASMFunction)(void *)0; + } + asm_gencall(as, &ci, args); +} + +#if !LJ_SOFTFP +static void asm_callround(ASMState *as, IRIns *ir, IRCallID id) +{ + /* The modified regs must match with the *.dasc implementation. */ + RegSet drop = RID2RSET(RID_R1)|RID2RSET(RID_R12)|RID2RSET(RID_FPRET)| + RID2RSET(RID_F2)|RID2RSET(RID_F4)|RID2RSET(REGARG_FIRSTFPR) +#if LJ_TARGET_MIPSR6 + |RID2RSET(RID_F21) +#endif + ; + if (ra_hasreg(ir->r)) rset_clear(drop, ir->r); + ra_evictset(as, drop); + ra_destreg(as, ir, RID_FPRET); + emit_call(as, (void *)lj_ir_callinfo[id].func, 0); + ra_leftov(as, REGARG_FIRSTFPR, ir->op1); +} +#endif + +/* -- Returns ------------------------------------------------------------- */ + +/* Return to lower frame. Guard that it goes to the right spot. */ +static void asm_retf(ASMState *as, IRIns *ir) +{ + Reg base = ra_alloc1(as, REF_BASE, RSET_GPR); + void *pc = ir_kptr(IR(ir->op2)); + int32_t delta = 1+LJ_FR2+bc_a(*((const BCIns *)pc - 1)); + as->topslot -= (BCReg)delta; + if ((int32_t)as->topslot < 0) as->topslot = 0; + irt_setmark(IR(REF_BASE)->t); /* Children must not coalesce with BASE reg. */ + emit_setgl(as, base, jit_base); + emit_addptr(as, base, -8*delta); + asm_guard(as, MIPSI_BNE, RID_TMP, + ra_allock(as, igcptr(pc), rset_exclude(RSET_GPR, base))); + emit_tsi(as, MIPSI_AL, RID_TMP, base, -8); +} + +/* -- Buffer operations --------------------------------------------------- */ + +#if LJ_HASBUFFER +static void asm_bufhdr_write(ASMState *as, Reg sb) +{ + Reg tmp = ra_scratch(as, rset_exclude(RSET_GPR, sb)); + IRIns irgc; + irgc.ot = IRT(0, IRT_PGC); /* GC type. */ + emit_storeofs(as, &irgc, RID_TMP, sb, offsetof(SBuf, L)); + if ((as->flags & JIT_F_MIPSXXR2)) { + emit_tsml(as, LJ_64 ? MIPSI_DINS : MIPSI_INS, RID_TMP, tmp, + lj_fls(SBUF_MASK_FLAG), 0); + } else { + emit_dst(as, MIPSI_OR, RID_TMP, RID_TMP, tmp); + emit_tsi(as, MIPSI_ANDI, tmp, tmp, SBUF_MASK_FLAG); + } + emit_getgl(as, RID_TMP, cur_L); + emit_loadofs(as, &irgc, tmp, sb, offsetof(SBuf, L)); +} +#endif + +/* -- Type conversions ---------------------------------------------------- */ + +#if !LJ_SOFTFP +static void asm_tointg(ASMState *as, IRIns *ir, Reg left) +{ + Reg tmp = ra_scratch(as, rset_exclude(RSET_FPR, left)); + Reg dest = ra_dest(as, ir, RSET_GPR); +#if !LJ_TARGET_MIPSR6 + asm_guard(as, MIPSI_BC1F, 0, 0); + emit_fgh(as, MIPSI_C_EQ_D, 0, tmp, left); +#else + asm_guard(as, MIPSI_BC1EQZ, 0, (tmp&31)); + emit_fgh(as, MIPSI_CMP_EQ_D, tmp, tmp, left); +#endif + emit_fg(as, MIPSI_CVT_D_W, tmp, tmp); + emit_tg(as, MIPSI_MFC1, dest, tmp); + emit_fg(as, MIPSI_CVT_W_D, tmp, left); +} + +static void asm_tobit(ASMState *as, IRIns *ir) +{ + RegSet allow = RSET_FPR; + Reg dest = ra_dest(as, ir, RSET_GPR); + Reg left = ra_alloc1(as, ir->op1, allow); + Reg right = ra_alloc1(as, ir->op2, rset_clear(allow, left)); + Reg tmp = ra_scratch(as, rset_clear(allow, right)); + emit_tg(as, MIPSI_MFC1, dest, tmp); + emit_fgh(as, MIPSI_ADD_D, tmp, left, right); +} +#elif LJ_64 /* && LJ_SOFTFP */ +static void asm_tointg(ASMState *as, IRIns *ir, Reg r) +{ + /* The modified regs must match with the *.dasc implementation. */ + RegSet drop = RID2RSET(REGARG_FIRSTGPR)|RID2RSET(RID_RET)|RID2RSET(RID_RET+1)| + RID2RSET(RID_R1)|RID2RSET(RID_R12); + if (ra_hasreg(ir->r)) rset_clear(drop, ir->r); + ra_evictset(as, drop); + /* Return values are in RID_RET (converted value) and RID_RET+1 (status). */ + ra_destreg(as, ir, RID_RET); + asm_guard(as, MIPSI_BNE, RID_RET+1, RID_ZERO); + emit_call(as, (void *)lj_ir_callinfo[IRCALL_lj_vm_tointg].func, 0); + if (r == RID_NONE) + ra_leftov(as, REGARG_FIRSTGPR, ir->op1); + else if (r != REGARG_FIRSTGPR) + emit_move(as, REGARG_FIRSTGPR, r); +} + +static void asm_tobit(ASMState *as, IRIns *ir) +{ + Reg dest = ra_dest(as, ir, RSET_GPR); + emit_dta(as, MIPSI_SLL, dest, dest, 0); + asm_callid(as, ir, IRCALL_lj_vm_tobit); +} +#endif + +static void asm_conv(ASMState *as, IRIns *ir) +{ + IRType st = (IRType)(ir->op2 & IRCONV_SRCMASK); +#if !LJ_SOFTFP32 + int stfp = (st == IRT_NUM || st == IRT_FLOAT); +#endif +#if LJ_64 + int st64 = (st == IRT_I64 || st == IRT_U64 || st == IRT_P64); +#endif + IRRef lref = ir->op1; +#if LJ_32 + /* 64 bit integer conversions are handled by SPLIT. */ + lj_assertA(!(irt_isint64(ir->t) || (st == IRT_I64 || st == IRT_U64)), + "IR %04d has unsplit 64 bit type", + (int)(ir - as->ir) - REF_BIAS); +#endif +#if LJ_SOFTFP32 + /* FP conversions are handled by SPLIT. */ + lj_assertA(!irt_isfp(ir->t) && !(st == IRT_NUM || st == IRT_FLOAT), + "IR %04d has FP type", + (int)(ir - as->ir) - REF_BIAS); + /* Can't check for same types: SPLIT uses CONV int.int + BXOR for sfp NEG. */ +#else + lj_assertA(irt_type(ir->t) != st, "inconsistent types for CONV"); +#if !LJ_SOFTFP + if (irt_isfp(ir->t)) { + Reg dest = ra_dest(as, ir, RSET_FPR); + if (stfp) { /* FP to FP conversion. */ + emit_fg(as, st == IRT_NUM ? MIPSI_CVT_S_D : MIPSI_CVT_D_S, + dest, ra_alloc1(as, lref, RSET_FPR)); + } else if (st == IRT_U32) { /* U32 to FP conversion. */ + /* y = (x ^ 0x8000000) + 2147483648.0 */ + Reg left = ra_alloc1(as, lref, RSET_GPR); + Reg tmp = ra_scratch(as, rset_exclude(RSET_FPR, dest)); + if (irt_isfloat(ir->t)) + emit_fg(as, MIPSI_CVT_S_D, dest, dest); + /* Must perform arithmetic with doubles to keep the precision. */ + emit_fgh(as, MIPSI_ADD_D, dest, dest, tmp); + emit_fg(as, MIPSI_CVT_D_W, dest, dest); + emit_lsptr(as, MIPSI_LDC1, (tmp & 31), + (void *)&as->J->k64[LJ_K64_2P31], RSET_GPR); + emit_tg(as, MIPSI_MTC1, RID_TMP, dest); + emit_dst(as, MIPSI_XOR, RID_TMP, RID_TMP, left); + emit_ti(as, MIPSI_LUI, RID_TMP, 0x8000); +#if LJ_64 + } else if(st == IRT_U64) { /* U64 to FP conversion. */ + /* if (x >= 1u<<63) y = (double)(int64_t)(x&(1u<<63)-1) + pow(2.0, 63) */ + Reg left = ra_alloc1(as, lref, RSET_GPR); + Reg tmp = ra_scratch(as, rset_exclude(RSET_FPR, dest)); + MCLabel l_end = emit_label(as); + if (irt_isfloat(ir->t)) { + emit_fgh(as, MIPSI_ADD_S, dest, dest, tmp); + emit_lsptr(as, MIPSI_LWC1, (tmp & 31), (void *)&as->J->k32[LJ_K32_2P63], + rset_exclude(RSET_GPR, left)); + emit_fg(as, MIPSI_CVT_S_L, dest, dest); + } else { + emit_fgh(as, MIPSI_ADD_D, dest, dest, tmp); + emit_lsptr(as, MIPSI_LDC1, (tmp & 31), (void *)&as->J->k64[LJ_K64_2P63], + rset_exclude(RSET_GPR, left)); + emit_fg(as, MIPSI_CVT_D_L, dest, dest); + } + emit_branch(as, MIPSI_BGEZ, left, RID_ZERO, l_end); + emit_tg(as, MIPSI_DMTC1, RID_TMP, dest); + emit_tsml(as, MIPSI_DEXTM, RID_TMP, left, 30, 0); +#endif + } else { /* Integer to FP conversion. */ + Reg left = ra_alloc1(as, lref, RSET_GPR); +#if LJ_32 + emit_fg(as, irt_isfloat(ir->t) ? MIPSI_CVT_S_W : MIPSI_CVT_D_W, + dest, dest); + emit_tg(as, MIPSI_MTC1, left, dest); +#else + MIPSIns mi = irt_isfloat(ir->t) ? + (st64 ? MIPSI_CVT_S_L : MIPSI_CVT_S_W) : + (st64 ? MIPSI_CVT_D_L : MIPSI_CVT_D_W); + emit_fg(as, mi, dest, dest); + emit_tg(as, st64 ? MIPSI_DMTC1 : MIPSI_MTC1, left, dest); +#endif + } + } else if (stfp) { /* FP to integer conversion. */ + if (irt_isguard(ir->t)) { + /* Checked conversions are only supported from number to int. */ + lj_assertA(irt_isint(ir->t) && st == IRT_NUM, + "bad type for checked CONV"); + asm_tointg(as, ir, ra_alloc1(as, lref, RSET_FPR)); + } else { + Reg dest = ra_dest(as, ir, RSET_GPR); + Reg left = ra_alloc1(as, lref, RSET_FPR); + Reg tmp = ra_scratch(as, rset_exclude(RSET_FPR, left)); + if (irt_isu32(ir->t)) { /* FP to U32 conversion. */ + /* y = (int)floor(x - 2147483648.0) ^ 0x80000000 */ + emit_dst(as, MIPSI_XOR, dest, dest, RID_TMP); + emit_ti(as, MIPSI_LUI, RID_TMP, 0x8000); + emit_tg(as, MIPSI_MFC1, dest, tmp); + emit_fg(as, st == IRT_FLOAT ? MIPSI_FLOOR_W_S : MIPSI_FLOOR_W_D, + tmp, tmp); + emit_fgh(as, st == IRT_FLOAT ? MIPSI_SUB_S : MIPSI_SUB_D, + tmp, left, tmp); + if (st == IRT_FLOAT) + emit_lsptr(as, MIPSI_LWC1, (tmp & 31), + (void *)&as->J->k32[LJ_K32_2P31], RSET_GPR); + else + emit_lsptr(as, MIPSI_LDC1, (tmp & 31), + (void *)&as->J->k64[LJ_K64_2P31], RSET_GPR); +#if LJ_64 + } else if (irt_isu64(ir->t)) { /* FP to U64 conversion. */ + MCLabel l_end; + emit_tg(as, MIPSI_DMFC1, dest, tmp); + l_end = emit_label(as); + /* For inputs >= 2^63 add -2^64 and convert again. */ + if (st == IRT_NUM) { + emit_fg(as, MIPSI_TRUNC_L_D, tmp, tmp); + emit_fgh(as, MIPSI_ADD_D, tmp, left, tmp); + emit_lsptr(as, MIPSI_LDC1, (tmp & 31), + (void *)&as->J->k64[LJ_K64_M2P64], + rset_exclude(RSET_GPR, dest)); + emit_fg(as, MIPSI_TRUNC_L_D, tmp, left); /* Delay slot. */ +#if !LJ_TARGET_MIPSR6 + emit_branch(as, MIPSI_BC1T, 0, 0, l_end); + emit_fgh(as, MIPSI_C_OLT_D, 0, left, tmp); +#else + emit_branch(as, MIPSI_BC1NEZ, 0, (left&31), l_end); + emit_fgh(as, MIPSI_CMP_LT_D, left, left, tmp); +#endif + emit_lsptr(as, MIPSI_LDC1, (tmp & 31), + (void *)&as->J->k64[LJ_K64_2P63], + rset_exclude(RSET_GPR, dest)); + } else { + emit_fg(as, MIPSI_TRUNC_L_S, tmp, tmp); + emit_fgh(as, MIPSI_ADD_S, tmp, left, tmp); + emit_lsptr(as, MIPSI_LWC1, (tmp & 31), + (void *)&as->J->k32[LJ_K32_M2P64], + rset_exclude(RSET_GPR, dest)); + emit_fg(as, MIPSI_TRUNC_L_S, tmp, left); /* Delay slot. */ +#if !LJ_TARGET_MIPSR6 + emit_branch(as, MIPSI_BC1T, 0, 0, l_end); + emit_fgh(as, MIPSI_C_OLT_S, 0, left, tmp); +#else + emit_branch(as, MIPSI_BC1NEZ, 0, (left&31), l_end); + emit_fgh(as, MIPSI_CMP_LT_S, left, left, tmp); +#endif + emit_lsptr(as, MIPSI_LWC1, (tmp & 31), + (void *)&as->J->k32[LJ_K32_2P63], + rset_exclude(RSET_GPR, dest)); + } +#endif + } else { +#if LJ_32 + emit_tg(as, MIPSI_MFC1, dest, tmp); + emit_fg(as, st == IRT_FLOAT ? MIPSI_TRUNC_W_S : MIPSI_TRUNC_W_D, + tmp, left); +#else + MIPSIns mi = irt_is64(ir->t) ? + (st == IRT_NUM ? MIPSI_TRUNC_L_D : MIPSI_TRUNC_L_S) : + (st == IRT_NUM ? MIPSI_TRUNC_W_D : MIPSI_TRUNC_W_S); + emit_tg(as, irt_is64(ir->t) ? MIPSI_DMFC1 : MIPSI_MFC1, dest, left); + emit_fg(as, mi, left, left); +#endif + } + } + } else +#else + if (irt_isfp(ir->t)) { +#if LJ_64 && LJ_HASFFI + if (stfp) { /* FP to FP conversion. */ + asm_callid(as, ir, irt_isnum(ir->t) ? IRCALL_softfp_f2d : + IRCALL_softfp_d2f); + } else { /* Integer to FP conversion. */ + IRCallID cid = ((IRT_IS64 >> st) & 1) ? + (irt_isnum(ir->t) ? + (st == IRT_I64 ? IRCALL_fp64_l2d : IRCALL_fp64_ul2d) : + (st == IRT_I64 ? IRCALL_fp64_l2f : IRCALL_fp64_ul2f)) : + (irt_isnum(ir->t) ? + (st == IRT_INT ? IRCALL_softfp_i2d : IRCALL_softfp_ui2d) : + (st == IRT_INT ? IRCALL_softfp_i2f : IRCALL_softfp_ui2f)); + asm_callid(as, ir, cid); + } +#else + asm_callid(as, ir, IRCALL_softfp_i2d); +#endif + } else if (stfp) { /* FP to integer conversion. */ + if (irt_isguard(ir->t)) { + /* Checked conversions are only supported from number to int. */ + lj_assertA(irt_isint(ir->t) && st == IRT_NUM, + "bad type for checked CONV"); + asm_tointg(as, ir, RID_NONE); + } else { + IRCallID cid = irt_is64(ir->t) ? + ((st == IRT_NUM) ? + (irt_isi64(ir->t) ? IRCALL_fp64_d2l : IRCALL_fp64_d2ul) : + (irt_isi64(ir->t) ? IRCALL_fp64_f2l : IRCALL_fp64_f2ul)) : + ((st == IRT_NUM) ? + (irt_isint(ir->t) ? IRCALL_softfp_d2i : IRCALL_softfp_d2ui) : + (irt_isint(ir->t) ? IRCALL_softfp_f2i : IRCALL_softfp_f2ui)); + asm_callid(as, ir, cid); + } + } else +#endif +#endif + { + Reg dest = ra_dest(as, ir, RSET_GPR); + if (st >= IRT_I8 && st <= IRT_U16) { /* Extend to 32 bit integer. */ + Reg left = ra_alloc1(as, ir->op1, RSET_GPR); + lj_assertA(irt_isint(ir->t) || irt_isu32(ir->t), "bad type for CONV EXT"); + if ((ir->op2 & IRCONV_SEXT)) { + if (LJ_64 || (as->flags & JIT_F_MIPSXXR2)) { + emit_dst(as, st == IRT_I8 ? MIPSI_SEB : MIPSI_SEH, dest, 0, left); + } else { + uint32_t shift = st == IRT_I8 ? 24 : 16; + emit_dta(as, MIPSI_SRA, dest, dest, shift); + emit_dta(as, MIPSI_SLL, dest, left, shift); + } + } else { + emit_tsi(as, MIPSI_ANDI, dest, left, + (int32_t)(st == IRT_U8 ? 0xff : 0xffff)); + } + } else { /* 32/64 bit integer conversions. */ +#if LJ_32 + /* Only need to handle 32/32 bit no-op (cast) on 32 bit archs. */ + ra_leftov(as, dest, lref); /* Do nothing, but may need to move regs. */ +#else + if (irt_is64(ir->t)) { + if (st64) { + /* 64/64 bit no-op (cast)*/ + ra_leftov(as, dest, lref); + } else { + Reg left = ra_alloc1(as, lref, RSET_GPR); + if ((ir->op2 & IRCONV_SEXT)) { /* 32 to 64 bit sign extension. */ + emit_dta(as, MIPSI_SLL, dest, left, 0); + } else { /* 32 to 64 bit zero extension. */ + emit_tsml(as, MIPSI_DEXT, dest, left, 31, 0); + } + } + } else { + if (st64 && !(ir->op2 & IRCONV_NONE)) { + /* This is either a 32 bit reg/reg mov which zeroes the hiword + ** or a load of the loword from a 64 bit address. + */ + Reg left = ra_alloc1(as, lref, RSET_GPR); + emit_tsml(as, MIPSI_DEXT, dest, left, 31, 0); + } else { /* 32/32 bit no-op (cast). */ + /* Do nothing, but may need to move regs. */ + ra_leftov(as, dest, lref); + } + } +#endif + } + } +} + +static void asm_strto(ASMState *as, IRIns *ir) +{ + const CCallInfo *ci = &lj_ir_callinfo[IRCALL_lj_strscan_num]; + IRRef args[2]; + int32_t ofs = 0; +#if LJ_SOFTFP32 + ra_evictset(as, RSET_SCRATCH); + if (ra_used(ir)) { + if (ra_hasspill(ir->s) && ra_hasspill((ir+1)->s) && + (ir->s & 1) == LJ_BE && (ir->s ^ 1) == (ir+1)->s) { + int i; + for (i = 0; i < 2; i++) { + Reg r = (ir+i)->r; + if (ra_hasreg(r)) { + ra_free(as, r); + ra_modified(as, r); + emit_spload(as, ir+i, r, sps_scale((ir+i)->s)); + } + } + ofs = sps_scale(ir->s & ~1); + } else { + Reg rhi = ra_dest(as, ir+1, RSET_GPR); + Reg rlo = ra_dest(as, ir, rset_exclude(RSET_GPR, rhi)); + emit_tsi(as, MIPSI_LW, rhi, RID_SP, ofs+(LJ_BE?0:4)); + emit_tsi(as, MIPSI_LW, rlo, RID_SP, ofs+(LJ_BE?4:0)); + } + } +#else + RegSet drop = RSET_SCRATCH; + if (ra_hasreg(ir->r)) rset_set(drop, ir->r); /* Spill dest reg (if any). */ + ra_evictset(as, drop); + ofs = sps_scale(ir->s); +#endif + asm_guard(as, MIPSI_BEQ, RID_RET, RID_ZERO); /* Test return status. */ + args[0] = ir->op1; /* GCstr *str */ + args[1] = ASMREF_TMP1; /* TValue *n */ + asm_gencall(as, ci, args); + /* Store the result to the spill slot or temp slots. */ + emit_tsi(as, MIPSI_AADDIU, ra_releasetmp(as, ASMREF_TMP1), + RID_SP, ofs); +} + +/* -- Memory references --------------------------------------------------- */ + +#if LJ_64 +/* Store tagged value for ref at base+ofs. */ +static void asm_tvstore64(ASMState *as, Reg base, int32_t ofs, IRRef ref) +{ + RegSet allow = rset_exclude(RSET_GPR, base); + IRIns *ir = IR(ref); + lj_assertA(irt_ispri(ir->t) || irt_isaddr(ir->t) || irt_isinteger(ir->t), + "store of IR type %d", irt_type(ir->t)); + if (irref_isk(ref)) { + TValue k; + lj_ir_kvalue(as->J->L, &k, ir); + emit_tsi(as, MIPSI_SD, ra_allock(as, (int64_t)k.u64, allow), base, ofs); + } else { + Reg src = ra_alloc1(as, ref, allow); + Reg type = ra_allock(as, (int64_t)irt_toitype(ir->t) << 47, + rset_exclude(allow, src)); + emit_tsi(as, MIPSI_SD, RID_TMP, base, ofs); + if (irt_isinteger(ir->t)) { + emit_dst(as, MIPSI_DADDU, RID_TMP, RID_TMP, type); + emit_tsml(as, MIPSI_DEXT, RID_TMP, src, 31, 0); + } else { + emit_dst(as, MIPSI_DADDU, RID_TMP, src, type); + } + } +} +#endif + +/* Get pointer to TValue. */ +static void asm_tvptr(ASMState *as, Reg dest, IRRef ref, MSize mode) +{ + int32_t tmpofs = (int32_t)(offsetof(global_State, tmptv)-32768); + if ((mode & IRTMPREF_IN1)) { + IRIns *ir = IR(ref); + if (irt_isnum(ir->t)) { + if ((mode & IRTMPREF_OUT1)) { +#if LJ_SOFTFP + emit_tsi(as, MIPSI_AADDIU, dest, RID_JGL, tmpofs); +#if LJ_64 + emit_setgl(as, ra_alloc1(as, ref, RSET_GPR), tmptv.u64); +#else + lj_assertA(irref_isk(ref), "unsplit FP op"); + emit_setgl(as, + ra_allock(as, (int32_t)ir_knum(ir)->u32.lo, RSET_GPR), + tmptv.u32.lo); + emit_setgl(as, + ra_allock(as, (int32_t)ir_knum(ir)->u32.hi, RSET_GPR), + tmptv.u32.hi); +#endif +#else + Reg src = ra_alloc1(as, ref, RSET_FPR); + emit_tsi(as, MIPSI_AADDIU, dest, RID_JGL, tmpofs); + emit_tsi(as, MIPSI_SDC1, (src & 31), RID_JGL, tmpofs); +#endif + } else if (irref_isk(ref)) { + /* Use the number constant itself as a TValue. */ + ra_allockreg(as, igcptr(ir_knum(ir)), dest); + } else { +#if LJ_SOFTFP32 + lj_assertA(0, "unsplit FP op"); +#else + /* Otherwise force a spill and use the spill slot. */ + emit_tsi(as, MIPSI_AADDIU, dest, RID_SP, ra_spill(as, ir)); +#endif + } + } else { + /* Otherwise use g->tmptv to hold the TValue. */ +#if LJ_32 + Reg type; + emit_tsi(as, MIPSI_ADDIU, dest, RID_JGL, tmpofs); + if (!irt_ispri(ir->t)) { + Reg src = ra_alloc1(as, ref, RSET_GPR); + emit_setgl(as, src, tmptv.gcr); + } + if (LJ_SOFTFP && (ir+1)->o == IR_HIOP && !irt_isnil((ir+1)->t)) + type = ra_alloc1(as, ref+1, RSET_GPR); + else + type = ra_allock(as, (int32_t)irt_toitype(ir->t), RSET_GPR); + emit_setgl(as, type, tmptv.it); +#else + asm_tvstore64(as, dest, 0, ref); + emit_tsi(as, MIPSI_DADDIU, dest, RID_JGL, tmpofs); +#endif + } + } else { + emit_tsi(as, MIPSI_AADDIU, dest, RID_JGL, tmpofs); + } +} + +static void asm_aref(ASMState *as, IRIns *ir) +{ + Reg dest = ra_dest(as, ir, RSET_GPR); + Reg idx, base; + if (irref_isk(ir->op2)) { + IRRef tab = IR(ir->op1)->op1; + int32_t ofs = asm_fuseabase(as, tab); + IRRef refa = ofs ? tab : ir->op1; + ofs += 8*IR(ir->op2)->i; + if (checki16(ofs)) { + base = ra_alloc1(as, refa, RSET_GPR); + emit_tsi(as, MIPSI_AADDIU, dest, base, ofs); + return; + } + } + base = ra_alloc1(as, ir->op1, RSET_GPR); + idx = ra_alloc1(as, ir->op2, rset_exclude(RSET_GPR, base)); +#if !LJ_TARGET_MIPSR6 + emit_dst(as, MIPSI_AADDU, dest, RID_TMP, base); + emit_dta(as, MIPSI_SLL, RID_TMP, idx, 3); +#else + emit_dst(as, MIPSI_ALSA | MIPSF_A(3-1), dest, idx, base); +#endif +} + +/* Inlined hash lookup. Specialized for key type and for const keys. +** The equivalent C code is: +** Node *n = hashkey(t, key); +** do { +** if (lj_obj_equal(&n->key, key)) return &n->val; +** } while ((n = nextnode(n))); +** return niltv(L); +*/ +static void asm_href(ASMState *as, IRIns *ir, IROp merge) +{ + RegSet allow = RSET_GPR; + int destused = ra_used(ir); + Reg dest = ra_dest(as, ir, allow); + Reg tab = ra_alloc1(as, ir->op1, rset_clear(allow, dest)); + Reg key = RID_NONE, type = RID_NONE, tmpnum = RID_NONE, tmp1 = RID_TMP, tmp2; +#if LJ_64 + Reg cmp64 = RID_NONE; +#endif + IRRef refkey = ir->op2; + IRIns *irkey = IR(refkey); + int isk = irref_isk(refkey); + IRType1 kt = irkey->t; + uint32_t khash; + MCLabel l_end, l_loop, l_next; + + rset_clear(allow, tab); + if (!LJ_SOFTFP && irt_isnum(kt)) { + key = ra_alloc1(as, refkey, RSET_FPR); + tmpnum = ra_scratch(as, rset_exclude(RSET_FPR, key)); + } else { + if (!irt_ispri(kt)) { + key = ra_alloc1(as, refkey, allow); + rset_clear(allow, key); + } +#if LJ_32 + if (LJ_SOFTFP && irkey[1].o == IR_HIOP) { + if (ra_hasreg((irkey+1)->r)) { + type = tmpnum = (irkey+1)->r; + tmp1 = ra_scratch(as, allow); + rset_clear(allow, tmp1); + ra_noweak(as, tmpnum); + } else { + type = tmpnum = ra_allocref(as, refkey+1, allow); + } + rset_clear(allow, tmpnum); + } else { + type = ra_allock(as, (int32_t)irt_toitype(kt), allow); + rset_clear(allow, type); + } +#endif + } + tmp2 = ra_scratch(as, allow); + rset_clear(allow, tmp2); +#if LJ_64 + if (LJ_SOFTFP || !irt_isnum(kt)) { + /* Allocate cmp64 register used for 64-bit comparisons */ + if (LJ_SOFTFP && irt_isnum(kt)) { + cmp64 = key; + } else if (!isk && irt_isaddr(kt)) { + cmp64 = tmp2; + } else { + int64_t k; + if (isk && irt_isaddr(kt)) { + k = ((int64_t)irt_toitype(kt) << 47) | irkey[1].tv.u64; + } else { + lj_assertA(irt_ispri(kt) && !irt_isnil(kt), "bad HREF key type"); + k = ~((int64_t)~irt_toitype(kt) << 47); + } + cmp64 = ra_allock(as, k, allow); + rset_clear(allow, cmp64); + } + } +#endif + + /* Key not found in chain: jump to exit (if merged) or load niltv. */ + l_end = emit_label(as); + as->invmcp = NULL; + if (merge == IR_NE) + asm_guard(as, MIPSI_B, RID_ZERO, RID_ZERO); + else if (destused) + emit_loada(as, dest, niltvg(J2G(as->J))); + /* Follow hash chain until the end. */ + emit_move(as, dest, tmp1); + l_loop = --as->mcp; + emit_tsi(as, MIPSI_AL, tmp1, dest, (int32_t)offsetof(Node, next)); + l_next = emit_label(as); + + /* Type and value comparison. */ + if (merge == IR_EQ) { /* Must match asm_guard(). */ + emit_ti(as, MIPSI_LI, RID_TMP, as->snapno); + l_end = asm_exitstub_addr(as); + } + if (!LJ_SOFTFP && irt_isnum(kt)) { +#if !LJ_TARGET_MIPSR6 + emit_branch(as, MIPSI_BC1T, 0, 0, l_end); + emit_fgh(as, MIPSI_C_EQ_D, 0, tmpnum, key); +#else + emit_branch(as, MIPSI_BC1NEZ, 0, (tmpnum&31), l_end); + emit_fgh(as, MIPSI_CMP_EQ_D, tmpnum, tmpnum, key); +#endif + *--as->mcp = MIPSI_NOP; /* Avoid NaN comparison overhead. */ + emit_branch(as, MIPSI_BEQ, tmp1, RID_ZERO, l_next); + emit_tsi(as, MIPSI_SLTIU, tmp1, tmp1, (int32_t)LJ_TISNUM); +#if LJ_32 + emit_hsi(as, MIPSI_LDC1, tmpnum, dest, (int32_t)offsetof(Node, key.n)); + } else { + if (irt_ispri(kt)) { + emit_branch(as, MIPSI_BEQ, tmp1, type, l_end); + } else { + emit_branch(as, MIPSI_BEQ, tmp2, key, l_end); + emit_tsi(as, MIPSI_LW, tmp2, dest, (int32_t)offsetof(Node, key.gcr)); + emit_branch(as, MIPSI_BNE, tmp1, type, l_next); + } + } + emit_tsi(as, MIPSI_LW, tmp1, dest, (int32_t)offsetof(Node, key.it)); + *l_loop = MIPSI_BNE | MIPSF_S(tmp1) | ((as->mcp-l_loop-1) & 0xffffu); +#else + emit_dta(as, MIPSI_DSRA32, tmp1, tmp1, 15); + emit_tg(as, MIPSI_DMTC1, tmp1, tmpnum); + emit_tsi(as, MIPSI_LD, tmp1, dest, (int32_t)offsetof(Node, key.u64)); + } else { + emit_branch(as, MIPSI_BEQ, tmp1, cmp64, l_end); + emit_tsi(as, MIPSI_LD, tmp1, dest, (int32_t)offsetof(Node, key.u64)); + } + *l_loop = MIPSI_BNE | MIPSF_S(tmp1) | ((as->mcp-l_loop-1) & 0xffffu); + if (!isk && irt_isaddr(kt)) { + type = ra_allock(as, (int64_t)irt_toitype(kt) << 47, allow); + emit_dst(as, MIPSI_DADDU, tmp2, key, type); + rset_clear(allow, type); + } +#endif + + /* Load main position relative to tab->node into dest. */ + khash = isk ? ir_khash(as, irkey) : 1; + if (khash == 0) { + emit_tsi(as, MIPSI_AL, dest, tab, (int32_t)offsetof(GCtab, node)); + } else { + Reg tmphash = tmp1; + if (isk) + tmphash = ra_allock(as, khash, allow); + emit_dst(as, MIPSI_AADDU, dest, dest, tmp1); + lj_assertA(sizeof(Node) == 24, "bad Node size"); + emit_dst(as, MIPSI_SUBU, tmp1, tmp2, tmp1); + emit_dta(as, MIPSI_SLL, tmp1, tmp1, 3); + emit_dta(as, MIPSI_SLL, tmp2, tmp1, 5); + emit_dst(as, MIPSI_AND, tmp1, tmp2, tmphash); + emit_tsi(as, MIPSI_AL, dest, tab, (int32_t)offsetof(GCtab, node)); + emit_tsi(as, MIPSI_LW, tmp2, tab, (int32_t)offsetof(GCtab, hmask)); + if (isk) { + /* Nothing to do. */ + } else if (irt_isstr(kt)) { + emit_tsi(as, MIPSI_LW, tmp1, key, (int32_t)offsetof(GCstr, sid)); + } else { /* Must match with hash*() in lj_tab.c. */ + emit_dst(as, MIPSI_SUBU, tmp1, tmp1, tmp2); + emit_rotr(as, tmp2, tmp2, dest, (-HASH_ROT3)&31); + emit_dst(as, MIPSI_XOR, tmp1, tmp1, tmp2); + emit_rotr(as, tmp1, tmp1, dest, (-HASH_ROT2-HASH_ROT1)&31); + emit_dst(as, MIPSI_SUBU, tmp2, tmp2, dest); +#if LJ_32 + if (LJ_SOFTFP ? (irkey[1].o == IR_HIOP) : irt_isnum(kt)) { + emit_dst(as, MIPSI_XOR, tmp2, tmp2, tmp1); + if ((as->flags & JIT_F_MIPSXXR2)) { + emit_dta(as, MIPSI_ROTR, dest, tmp1, (-HASH_ROT1)&31); + } else { + emit_dst(as, MIPSI_OR, dest, dest, tmp1); + emit_dta(as, MIPSI_SLL, tmp1, tmp1, HASH_ROT1); + emit_dta(as, MIPSI_SRL, dest, tmp1, (-HASH_ROT1)&31); + } + emit_dst(as, MIPSI_ADDU, tmp1, tmp1, tmp1); +#if LJ_SOFTFP + emit_ds(as, MIPSI_MOVE, tmp1, type); + emit_ds(as, MIPSI_MOVE, tmp2, key); +#else + emit_tg(as, MIPSI_MFC1, tmp2, key); + emit_tg(as, MIPSI_MFC1, tmp1, key+1); +#endif + } else { + emit_dst(as, MIPSI_XOR, tmp2, key, tmp1); + emit_rotr(as, dest, tmp1, tmp2, (-HASH_ROT1)&31); + emit_dst(as, MIPSI_ADDU, tmp1, key, ra_allock(as, HASH_BIAS, allow)); + } +#else + emit_dst(as, MIPSI_XOR, tmp2, tmp2, tmp1); + emit_dta(as, MIPSI_ROTR, dest, tmp1, (-HASH_ROT1)&31); + if (irt_isnum(kt)) { + emit_dst(as, MIPSI_ADDU, tmp1, tmp1, tmp1); + emit_dta(as, MIPSI_DSRA32, tmp1, LJ_SOFTFP ? key : tmp1, 0); + emit_dta(as, MIPSI_SLL, tmp2, LJ_SOFTFP ? key : tmp1, 0); +#if !LJ_SOFTFP + emit_tg(as, MIPSI_DMFC1, tmp1, key); +#endif + } else { + checkmclim(as); + emit_dta(as, MIPSI_DSRA32, tmp1, tmp1, 0); + emit_dta(as, MIPSI_SLL, tmp2, key, 0); + emit_dst(as, MIPSI_DADDU, tmp1, key, type); + } +#endif + } + } +} + +static void asm_hrefk(ASMState *as, IRIns *ir) +{ + IRIns *kslot = IR(ir->op2); + IRIns *irkey = IR(kslot->op1); + int32_t ofs = (int32_t)(kslot->op2 * sizeof(Node)); + int32_t kofs = ofs + (int32_t)offsetof(Node, key); + Reg dest = (ra_used(ir)||ofs > 32736) ? ra_dest(as, ir, RSET_GPR) : RID_NONE; + Reg node = ra_alloc1(as, ir->op1, RSET_GPR); + RegSet allow = rset_exclude(RSET_GPR, node); + Reg idx = node; +#if LJ_32 + Reg key = RID_NONE, type = RID_TMP; + int32_t lo, hi; +#else + Reg key = ra_scratch(as, allow); + int64_t k; +#endif + lj_assertA(ofs % sizeof(Node) == 0, "unaligned HREFK slot"); + if (ofs > 32736) { + idx = dest; + rset_clear(allow, dest); + kofs = (int32_t)offsetof(Node, key); + } else if (ra_hasreg(dest)) { + emit_tsi(as, MIPSI_AADDIU, dest, node, ofs); + } +#if LJ_32 + if (!irt_ispri(irkey->t)) { + key = ra_scratch(as, allow); + rset_clear(allow, key); + } + if (irt_isnum(irkey->t)) { + lo = (int32_t)ir_knum(irkey)->u32.lo; + hi = (int32_t)ir_knum(irkey)->u32.hi; + } else { + lo = irkey->i; + hi = irt_toitype(irkey->t); + if (!ra_hasreg(key)) + goto nolo; + } + asm_guard(as, MIPSI_BNE, key, lo ? ra_allock(as, lo, allow) : RID_ZERO); +nolo: + asm_guard(as, MIPSI_BNE, type, hi ? ra_allock(as, hi, allow) : RID_ZERO); + if (ra_hasreg(key)) emit_tsi(as, MIPSI_LW, key, idx, kofs+(LJ_BE?4:0)); + emit_tsi(as, MIPSI_LW, type, idx, kofs+(LJ_BE?0:4)); +#else + if (irt_ispri(irkey->t)) { + lj_assertA(!irt_isnil(irkey->t), "bad HREFK key type"); + k = ~((int64_t)~irt_toitype(irkey->t) << 47); + } else if (irt_isnum(irkey->t)) { + k = (int64_t)ir_knum(irkey)->u64; + } else { + k = ((int64_t)irt_toitype(irkey->t) << 47) | (int64_t)ir_kgc(irkey); + } + asm_guard(as, MIPSI_BNE, key, ra_allock(as, k, allow)); + emit_tsi(as, MIPSI_LD, key, idx, kofs); +#endif + if (ofs > 32736) + emit_tsi(as, MIPSI_AADDU, dest, node, ra_allock(as, ofs, allow)); +} + +static void asm_uref(ASMState *as, IRIns *ir) +{ + Reg dest = ra_dest(as, ir, RSET_GPR); + if (irref_isk(ir->op1)) { + GCfunc *fn = ir_kfunc(IR(ir->op1)); + MRef *v = &gcref(fn->l.uvptr[(ir->op2 >> 8)])->uv.v; + emit_lsptr(as, MIPSI_AL, dest, v, RSET_GPR); + } else { + Reg uv = ra_scratch(as, RSET_GPR); + Reg func = ra_alloc1(as, ir->op1, RSET_GPR); + if (ir->o == IR_UREFC) { + asm_guard(as, MIPSI_BEQ, RID_TMP, RID_ZERO); + emit_tsi(as, MIPSI_AADDIU, dest, uv, (int32_t)offsetof(GCupval, tv)); + emit_tsi(as, MIPSI_LBU, RID_TMP, uv, (int32_t)offsetof(GCupval, closed)); + } else { + emit_tsi(as, MIPSI_AL, dest, uv, (int32_t)offsetof(GCupval, v)); + } + emit_tsi(as, MIPSI_AL, uv, func, (int32_t)offsetof(GCfuncL, uvptr) + + (int32_t)sizeof(MRef) * (int32_t)(ir->op2 >> 8)); + } +} + +static void asm_fref(ASMState *as, IRIns *ir) +{ + UNUSED(as); UNUSED(ir); + lj_assertA(!ra_used(ir), "unfused FREF"); +} + +static void asm_strref(ASMState *as, IRIns *ir) +{ +#if LJ_32 + Reg dest = ra_dest(as, ir, RSET_GPR); + IRRef ref = ir->op2, refk = ir->op1; + int32_t ofs = (int32_t)sizeof(GCstr); + Reg r; + if (irref_isk(ref)) { + IRRef tmp = refk; refk = ref; ref = tmp; + } else if (!irref_isk(refk)) { + Reg right, left = ra_alloc1(as, ir->op1, RSET_GPR); + IRIns *irr = IR(ir->op2); + if (ra_hasreg(irr->r)) { + ra_noweak(as, irr->r); + right = irr->r; + } else if (mayfuse(as, irr->op2) && + irr->o == IR_ADD && irref_isk(irr->op2) && + checki16(ofs + IR(irr->op2)->i)) { + ofs += IR(irr->op2)->i; + right = ra_alloc1(as, irr->op1, rset_exclude(RSET_GPR, left)); + } else { + right = ra_allocref(as, ir->op2, rset_exclude(RSET_GPR, left)); + } + emit_tsi(as, MIPSI_ADDIU, dest, dest, ofs); + emit_dst(as, MIPSI_ADDU, dest, left, right); + return; + } + r = ra_alloc1(as, ref, RSET_GPR); + ofs += IR(refk)->i; + if (checki16(ofs)) + emit_tsi(as, MIPSI_ADDIU, dest, r, ofs); + else + emit_dst(as, MIPSI_ADDU, dest, r, + ra_allock(as, ofs, rset_exclude(RSET_GPR, r))); +#else + RegSet allow = RSET_GPR; + Reg dest = ra_dest(as, ir, allow); + Reg base = ra_alloc1(as, ir->op1, allow); + IRIns *irr = IR(ir->op2); + int32_t ofs = sizeof(GCstr); + rset_clear(allow, base); + if (irref_isk(ir->op2) && checki16(ofs + irr->i)) { + emit_tsi(as, MIPSI_DADDIU, dest, base, ofs + irr->i); + } else { + emit_tsi(as, MIPSI_DADDIU, dest, dest, ofs); + emit_dst(as, MIPSI_DADDU, dest, base, ra_alloc1(as, ir->op2, allow)); + } +#endif +} + +/* -- Loads and stores ---------------------------------------------------- */ + +static MIPSIns asm_fxloadins(ASMState *as, IRIns *ir) +{ + UNUSED(as); + switch (irt_type(ir->t)) { + case IRT_I8: return MIPSI_LB; + case IRT_U8: return MIPSI_LBU; + case IRT_I16: return MIPSI_LH; + case IRT_U16: return MIPSI_LHU; + case IRT_NUM: + lj_assertA(!LJ_SOFTFP32, "unsplit FP op"); + if (!LJ_SOFTFP) return MIPSI_LDC1; + /* fallthrough */ + case IRT_FLOAT: if (!LJ_SOFTFP) return MIPSI_LWC1; + /* fallthrough */ + default: return (LJ_64 && irt_is64(ir->t)) ? MIPSI_LD : MIPSI_LW; + } +} + +static MIPSIns asm_fxstoreins(ASMState *as, IRIns *ir) +{ + UNUSED(as); + switch (irt_type(ir->t)) { + case IRT_I8: case IRT_U8: return MIPSI_SB; + case IRT_I16: case IRT_U16: return MIPSI_SH; + case IRT_NUM: + lj_assertA(!LJ_SOFTFP32, "unsplit FP op"); + if (!LJ_SOFTFP) return MIPSI_SDC1; + /* fallthrough */ + case IRT_FLOAT: if (!LJ_SOFTFP) return MIPSI_SWC1; + /* fallthrough */ + default: return (LJ_64 && irt_is64(ir->t)) ? MIPSI_SD : MIPSI_SW; + } +} + +static void asm_fload(ASMState *as, IRIns *ir) +{ + Reg dest = ra_dest(as, ir, RSET_GPR); + MIPSIns mi = asm_fxloadins(as, ir); + Reg idx; + int32_t ofs; + if (ir->op1 == REF_NIL) { /* FLOAD from GG_State with offset. */ + idx = RID_JGL; + ofs = (ir->op2 << 2) - 32768 - GG_OFS(g); + } else { + idx = ra_alloc1(as, ir->op1, RSET_GPR); + if (ir->op2 == IRFL_TAB_ARRAY) { + ofs = asm_fuseabase(as, ir->op1); + if (ofs) { /* Turn the t->array load into an add for colocated arrays. */ + emit_tsi(as, MIPSI_AADDIU, dest, idx, ofs); + return; + } + } + ofs = field_ofs[ir->op2]; + } + lj_assertA(!irt_isfp(ir->t), "bad FP FLOAD"); + emit_tsi(as, mi, dest, idx, ofs); +} + +static void asm_fstore(ASMState *as, IRIns *ir) +{ + if (ir->r != RID_SINK) { + Reg src = ra_alloc1z(as, ir->op2, RSET_GPR); + IRIns *irf = IR(ir->op1); + Reg idx = ra_alloc1(as, irf->op1, rset_exclude(RSET_GPR, src)); + int32_t ofs = field_ofs[irf->op2]; + MIPSIns mi = asm_fxstoreins(as, ir); + lj_assertA(!irt_isfp(ir->t), "bad FP FSTORE"); + emit_tsi(as, mi, src, idx, ofs); + } +} + +static void asm_xload(ASMState *as, IRIns *ir) +{ + Reg dest = ra_dest(as, ir, + (!LJ_SOFTFP && irt_isfp(ir->t)) ? RSET_FPR : RSET_GPR); + lj_assertA(LJ_TARGET_UNALIGNED || !(ir->op2 & IRXLOAD_UNALIGNED), + "unaligned XLOAD"); + asm_fusexref(as, asm_fxloadins(as, ir), dest, ir->op1, RSET_GPR, 0); +} + +static void asm_xstore_(ASMState *as, IRIns *ir, int32_t ofs) +{ + if (ir->r != RID_SINK) { + Reg src = ra_alloc1z(as, ir->op2, + (!LJ_SOFTFP && irt_isfp(ir->t)) ? RSET_FPR : RSET_GPR); + asm_fusexref(as, asm_fxstoreins(as, ir), src, ir->op1, + rset_exclude(RSET_GPR, src), ofs); + } +} + +#define asm_xstore(as, ir) asm_xstore_(as, ir, 0) + +static void asm_ahuvload(ASMState *as, IRIns *ir) +{ + int hiop = (LJ_SOFTFP32 && (ir+1)->o == IR_HIOP); + Reg dest = RID_NONE, type = RID_TMP, idx; + RegSet allow = RSET_GPR; + int32_t ofs = 0; + IRType1 t = ir->t; + if (hiop) { + t.irt = IRT_NUM; + if (ra_used(ir+1)) { + type = ra_dest(as, ir+1, allow); + rset_clear(allow, type); + } + } + if (ra_used(ir)) { + lj_assertA((LJ_SOFTFP32 ? 0 : irt_isnum(ir->t)) || + irt_isint(ir->t) || irt_isaddr(ir->t), + "bad load type %d", irt_type(ir->t)); + dest = ra_dest(as, ir, (!LJ_SOFTFP && irt_isnum(t)) ? RSET_FPR : allow); + rset_clear(allow, dest); +#if LJ_64 + if (irt_isaddr(t)) + emit_tsml(as, MIPSI_DEXTM, dest, dest, 14, 0); + else if (irt_isint(t)) + emit_dta(as, MIPSI_SLL, dest, dest, 0); +#endif + } + idx = asm_fuseahuref(as, ir->op1, &ofs, allow); + if (ir->o == IR_VLOAD) ofs += 8 * ir->op2; + rset_clear(allow, idx); + if (irt_isnum(t)) { + asm_guard(as, MIPSI_BEQ, RID_TMP, RID_ZERO); + emit_tsi(as, MIPSI_SLTIU, RID_TMP, type, (int32_t)LJ_TISNUM); + } else { + asm_guard(as, MIPSI_BNE, type, + ra_allock(as, (int32_t)irt_toitype(t), allow)); + } +#if LJ_32 + if (ra_hasreg(dest)) { + if (!LJ_SOFTFP && irt_isnum(t)) + emit_hsi(as, MIPSI_LDC1, dest, idx, ofs); + else + emit_tsi(as, MIPSI_LW, dest, idx, ofs+(LJ_BE?4:0)); + } + emit_tsi(as, MIPSI_LW, type, idx, ofs+(LJ_BE?0:4)); +#else + if (ra_hasreg(dest)) { + if (!LJ_SOFTFP && irt_isnum(t)) { + emit_hsi(as, MIPSI_LDC1, dest, idx, ofs); + dest = type; + } + } else { + dest = type; + } + emit_dta(as, MIPSI_DSRA32, type, dest, 15); + emit_tsi(as, MIPSI_LD, dest, idx, ofs); +#endif +} + +static void asm_ahustore(ASMState *as, IRIns *ir) +{ + RegSet allow = RSET_GPR; + Reg idx, src = RID_NONE, type = RID_NONE; + int32_t ofs = 0; + if (ir->r == RID_SINK) + return; + if (!LJ_SOFTFP32 && irt_isnum(ir->t)) { + src = ra_alloc1(as, ir->op2, LJ_SOFTFP ? RSET_GPR : RSET_FPR); + idx = asm_fuseahuref(as, ir->op1, &ofs, allow); + emit_hsi(as, LJ_SOFTFP ? MIPSI_SD : MIPSI_SDC1, src, idx, ofs); + } else { +#if LJ_32 + if (!irt_ispri(ir->t)) { + src = ra_alloc1(as, ir->op2, allow); + rset_clear(allow, src); + } + if (LJ_SOFTFP && (ir+1)->o == IR_HIOP) + type = ra_alloc1(as, (ir+1)->op2, allow); + else + type = ra_allock(as, (int32_t)irt_toitype(ir->t), allow); + rset_clear(allow, type); + idx = asm_fuseahuref(as, ir->op1, &ofs, allow); + if (ra_hasreg(src)) + emit_tsi(as, MIPSI_SW, src, idx, ofs+(LJ_BE?4:0)); + emit_tsi(as, MIPSI_SW, type, idx, ofs+(LJ_BE?0:4)); +#else + Reg tmp = RID_TMP; + if (irt_ispri(ir->t)) { + tmp = ra_allock(as, ~((int64_t)~irt_toitype(ir->t) << 47), allow); + rset_clear(allow, tmp); + } else { + src = ra_alloc1(as, ir->op2, allow); + rset_clear(allow, src); + type = ra_allock(as, (int64_t)irt_toitype(ir->t) << 47, allow); + rset_clear(allow, type); + } + idx = asm_fuseahuref(as, ir->op1, &ofs, allow); + emit_tsi(as, MIPSI_SD, tmp, idx, ofs); + if (ra_hasreg(src)) { + if (irt_isinteger(ir->t)) { + emit_dst(as, MIPSI_DADDU, tmp, tmp, type); + emit_tsml(as, MIPSI_DEXT, tmp, src, 31, 0); + } else { + emit_dst(as, MIPSI_DADDU, tmp, src, type); + } + } +#endif + } +} + +static void asm_sload(ASMState *as, IRIns *ir) +{ + Reg dest = RID_NONE, type = RID_NONE, base; + RegSet allow = RSET_GPR; + IRType1 t = ir->t; +#if LJ_32 + int32_t ofs = 8*((int32_t)ir->op1-1) + ((ir->op2 & IRSLOAD_FRAME) ? 4 : 0); + int hiop = (LJ_SOFTFP32 && (ir+1)->o == IR_HIOP); + if (hiop) + t.irt = IRT_NUM; +#else + int32_t ofs = 8*((int32_t)ir->op1-2); +#endif + lj_assertA(!(ir->op2 & IRSLOAD_PARENT), + "bad parent SLOAD"); /* Handled by asm_head_side(). */ + lj_assertA(irt_isguard(ir->t) || !(ir->op2 & IRSLOAD_TYPECHECK), + "inconsistent SLOAD variant"); +#if LJ_SOFTFP32 + lj_assertA(!(ir->op2 & IRSLOAD_CONVERT), + "unsplit SLOAD convert"); /* Handled by LJ_SOFTFP SPLIT. */ + if (hiop && ra_used(ir+1)) { + type = ra_dest(as, ir+1, allow); + rset_clear(allow, type); + } +#else + if ((ir->op2 & IRSLOAD_CONVERT) && irt_isguard(t) && irt_isint(t)) { + dest = ra_scratch(as, LJ_SOFTFP ? allow : RSET_FPR); + asm_tointg(as, ir, dest); + t.irt = IRT_NUM; /* Continue with a regular number type check. */ + } else +#endif + if (ra_used(ir)) { + lj_assertA((LJ_SOFTFP32 ? 0 : irt_isnum(ir->t)) || + irt_isint(ir->t) || irt_isaddr(ir->t), + "bad SLOAD type %d", irt_type(ir->t)); + dest = ra_dest(as, ir, (!LJ_SOFTFP && irt_isnum(t)) ? RSET_FPR : allow); + rset_clear(allow, dest); + base = ra_alloc1(as, REF_BASE, allow); + rset_clear(allow, base); + if (!LJ_SOFTFP32 && (ir->op2 & IRSLOAD_CONVERT)) { + if (irt_isint(t)) { + Reg tmp = ra_scratch(as, LJ_SOFTFP ? RSET_GPR : RSET_FPR); +#if LJ_SOFTFP + ra_evictset(as, rset_exclude(RSET_SCRATCH, dest)); + ra_destreg(as, ir, RID_RET); + emit_call(as, (void *)lj_ir_callinfo[IRCALL_softfp_d2i].func, 0); + if (tmp != REGARG_FIRSTGPR) + emit_move(as, REGARG_FIRSTGPR, tmp); +#else + emit_tg(as, MIPSI_MFC1, dest, tmp); + emit_fg(as, MIPSI_TRUNC_W_D, tmp, tmp); +#endif + dest = tmp; + t.irt = IRT_NUM; /* Check for original type. */ + } else { + Reg tmp = ra_scratch(as, RSET_GPR); +#if LJ_SOFTFP + ra_evictset(as, rset_exclude(RSET_SCRATCH, dest)); + ra_destreg(as, ir, RID_RET); + emit_call(as, (void *)lj_ir_callinfo[IRCALL_softfp_i2d].func, 0); + emit_dta(as, MIPSI_SLL, REGARG_FIRSTGPR, tmp, 0); +#else + emit_fg(as, MIPSI_CVT_D_W, dest, dest); + emit_tg(as, MIPSI_MTC1, tmp, dest); +#endif + dest = tmp; + t.irt = IRT_INT; /* Check for original type. */ + } + } +#if LJ_64 + else if (irt_isaddr(t)) { + /* Clear type from pointers. */ + emit_tsml(as, MIPSI_DEXTM, dest, dest, 14, 0); + } else if (irt_isint(t) && (ir->op2 & IRSLOAD_TYPECHECK)) { + /* Sign-extend integers. */ + emit_dta(as, MIPSI_SLL, dest, dest, 0); + } +#endif + goto dotypecheck; + } + base = ra_alloc1(as, REF_BASE, allow); + rset_clear(allow, base); +dotypecheck: +#if LJ_32 + if ((ir->op2 & IRSLOAD_TYPECHECK)) { + if (ra_noreg(type)) + type = RID_TMP; + if (irt_isnum(t)) { + asm_guard(as, MIPSI_BEQ, RID_TMP, RID_ZERO); + emit_tsi(as, MIPSI_SLTIU, RID_TMP, type, (int32_t)LJ_TISNUM); + } else { + Reg ktype = ra_allock(as, (ir->op2 & IRSLOAD_KEYINDEX) ? LJ_KEYINDEX : irt_toitype(t), allow); + asm_guard(as, MIPSI_BNE, type, ktype); + } + } + if (ra_hasreg(dest)) { + if (!LJ_SOFTFP && irt_isnum(t)) + emit_hsi(as, MIPSI_LDC1, dest, base, ofs); + else + emit_tsi(as, MIPSI_LW, dest, base, ofs ^ (LJ_BE?4:0)); + } + if (ra_hasreg(type)) + emit_tsi(as, MIPSI_LW, type, base, ofs ^ (LJ_BE?0:4)); +#else + if ((ir->op2 & IRSLOAD_TYPECHECK)) { + type = dest < RID_MAX_GPR ? dest : RID_TMP; + if (irt_ispri(t)) { + asm_guard(as, MIPSI_BNE, type, + ra_allock(as, ~((int64_t)~irt_toitype(t) << 47) , allow)); + } else if ((ir->op2 & IRSLOAD_KEYINDEX)) { + asm_guard(as, MIPSI_BNE, RID_TMP, + ra_allock(as, (int32_t)LJ_KEYINDEX, allow)); + emit_dta(as, MIPSI_DSRA32, RID_TMP, type, 0); + } else { + if (irt_isnum(t)) { + asm_guard(as, MIPSI_BEQ, RID_TMP, RID_ZERO); + emit_tsi(as, MIPSI_SLTIU, RID_TMP, RID_TMP, (int32_t)LJ_TISNUM); + if (!LJ_SOFTFP && ra_hasreg(dest)) + emit_hsi(as, MIPSI_LDC1, dest, base, ofs); + } else { + asm_guard(as, MIPSI_BNE, RID_TMP, + ra_allock(as, (int32_t)irt_toitype(t), allow)); + } + emit_dta(as, MIPSI_DSRA32, RID_TMP, type, 15); + } + emit_tsi(as, MIPSI_LD, type, base, ofs); + } else if (ra_hasreg(dest)) { + if (!LJ_SOFTFP && irt_isnum(t)) + emit_hsi(as, MIPSI_LDC1, dest, base, ofs); + else + emit_tsi(as, irt_isint(t) ? MIPSI_LW : MIPSI_LD, dest, base, + ofs ^ ((LJ_BE && irt_isint(t)) ? 4 : 0)); + } +#endif +} + +/* -- Allocations --------------------------------------------------------- */ + +#if LJ_HASFFI +static void asm_cnew(ASMState *as, IRIns *ir) +{ + CTState *cts = ctype_ctsG(J2G(as->J)); + CTypeID id = (CTypeID)IR(ir->op1)->i; + CTSize sz; + CTInfo info = lj_ctype_info(cts, id, &sz); + const CCallInfo *ci = &lj_ir_callinfo[IRCALL_lj_mem_newgco]; + IRRef args[4]; + RegSet drop = RSET_SCRATCH; + lj_assertA(sz != CTSIZE_INVALID || (ir->o == IR_CNEW && ir->op2 != REF_NIL), + "bad CNEW/CNEWI operands"); + + as->gcsteps++; + if (ra_hasreg(ir->r)) + rset_clear(drop, ir->r); /* Dest reg handled below. */ + ra_evictset(as, drop); + if (ra_used(ir)) + ra_destreg(as, ir, RID_RET); /* GCcdata * */ + + /* Initialize immutable cdata object. */ + if (ir->o == IR_CNEWI) { + RegSet allow = (RSET_GPR & ~RSET_SCRATCH); +#if LJ_32 + int32_t ofs = sizeof(GCcdata); + if (sz == 8) { + ofs += 4; + lj_assertA((ir+1)->o == IR_HIOP, "expected HIOP for CNEWI"); + if (LJ_LE) ir++; + } + for (;;) { + Reg r = ra_alloc1z(as, ir->op2, allow); + emit_tsi(as, MIPSI_SW, r, RID_RET, ofs); + rset_clear(allow, r); + if (ofs == sizeof(GCcdata)) break; + ofs -= 4; if (LJ_BE) ir++; else ir--; + } +#else + emit_tsi(as, sz == 8 ? MIPSI_SD : MIPSI_SW, ra_alloc1(as, ir->op2, allow), + RID_RET, sizeof(GCcdata)); +#endif + lj_assertA(sz == 4 || sz == 8, "bad CNEWI size %d", sz); + } else if (ir->op2 != REF_NIL) { /* Create VLA/VLS/aligned cdata. */ + ci = &lj_ir_callinfo[IRCALL_lj_cdata_newv]; + args[0] = ASMREF_L; /* lua_State *L */ + args[1] = ir->op1; /* CTypeID id */ + args[2] = ir->op2; /* CTSize sz */ + args[3] = ASMREF_TMP1; /* CTSize align */ + asm_gencall(as, ci, args); + emit_loadi(as, ra_releasetmp(as, ASMREF_TMP1), (int32_t)ctype_align(info)); + return; + } + + /* Initialize gct and ctypeid. lj_mem_newgco() already sets marked. */ + emit_tsi(as, MIPSI_SB, RID_RET+1, RID_RET, offsetof(GCcdata, gct)); + emit_tsi(as, MIPSI_SH, RID_TMP, RID_RET, offsetof(GCcdata, ctypeid)); + emit_ti(as, MIPSI_LI, RID_RET+1, ~LJ_TCDATA); + emit_ti(as, MIPSI_LI, RID_TMP, id); /* Lower 16 bit used. Sign-ext ok. */ + args[0] = ASMREF_L; /* lua_State *L */ + args[1] = ASMREF_TMP1; /* MSize size */ + asm_gencall(as, ci, args); + ra_allockreg(as, (int32_t)(sz+sizeof(GCcdata)), + ra_releasetmp(as, ASMREF_TMP1)); +} +#endif + +/* -- Write barriers ------------------------------------------------------ */ + +static void asm_tbar(ASMState *as, IRIns *ir) +{ + Reg tab = ra_alloc1(as, ir->op1, RSET_GPR); + Reg mark = ra_scratch(as, rset_exclude(RSET_GPR, tab)); + Reg link = RID_TMP; + MCLabel l_end = emit_label(as); + emit_tsi(as, MIPSI_AS, link, tab, (int32_t)offsetof(GCtab, gclist)); + emit_tsi(as, MIPSI_SB, mark, tab, (int32_t)offsetof(GCtab, marked)); + emit_setgl(as, tab, gc.grayagain); + emit_getgl(as, link, gc.grayagain); + emit_dst(as, MIPSI_XOR, mark, mark, RID_TMP); /* Clear black bit. */ + emit_branch(as, MIPSI_BEQ, RID_TMP, RID_ZERO, l_end); + emit_tsi(as, MIPSI_ANDI, RID_TMP, mark, LJ_GC_BLACK); + emit_tsi(as, MIPSI_LBU, mark, tab, (int32_t)offsetof(GCtab, marked)); +} + +static void asm_obar(ASMState *as, IRIns *ir) +{ + const CCallInfo *ci = &lj_ir_callinfo[IRCALL_lj_gc_barrieruv]; + IRRef args[2]; + MCLabel l_end; + Reg obj, val, tmp; + /* No need for other object barriers (yet). */ + lj_assertA(IR(ir->op1)->o == IR_UREFC, "bad OBAR type"); + ra_evictset(as, RSET_SCRATCH); + l_end = emit_label(as); + args[0] = ASMREF_TMP1; /* global_State *g */ + args[1] = ir->op1; /* TValue *tv */ + asm_gencall(as, ci, args); + emit_tsi(as, MIPSI_AADDIU, ra_releasetmp(as, ASMREF_TMP1), RID_JGL, -32768); + obj = IR(ir->op1)->r; + tmp = ra_scratch(as, rset_exclude(RSET_GPR, obj)); + emit_branch(as, MIPSI_BEQ, RID_TMP, RID_ZERO, l_end); + emit_tsi(as, MIPSI_ANDI, tmp, tmp, LJ_GC_BLACK); + emit_branch(as, MIPSI_BEQ, RID_TMP, RID_ZERO, l_end); + emit_tsi(as, MIPSI_ANDI, RID_TMP, RID_TMP, LJ_GC_WHITES); + val = ra_alloc1(as, ir->op2, rset_exclude(RSET_GPR, obj)); + emit_tsi(as, MIPSI_LBU, tmp, obj, + (int32_t)offsetof(GCupval, marked)-(int32_t)offsetof(GCupval, tv)); + emit_tsi(as, MIPSI_LBU, RID_TMP, val, (int32_t)offsetof(GChead, marked)); +} + +/* -- Arithmetic and logic operations ------------------------------------- */ + +#if !LJ_SOFTFP +static void asm_fparith(ASMState *as, IRIns *ir, MIPSIns mi) +{ + Reg dest = ra_dest(as, ir, RSET_FPR); + Reg right, left = ra_alloc2(as, ir, RSET_FPR); + right = (left >> 8); left &= 255; + emit_fgh(as, mi, dest, left, right); +} + +static void asm_fpunary(ASMState *as, IRIns *ir, MIPSIns mi) +{ + Reg dest = ra_dest(as, ir, RSET_FPR); + Reg left = ra_hintalloc(as, ir->op1, dest, RSET_FPR); + emit_fg(as, mi, dest, left); +} +#endif + +#if !LJ_SOFTFP32 +static void asm_fpmath(ASMState *as, IRIns *ir) +{ +#if !LJ_SOFTFP + if (ir->op2 <= IRFPM_TRUNC) + asm_callround(as, ir, IRCALL_lj_vm_floor + ir->op2); + else if (ir->op2 == IRFPM_SQRT) + asm_fpunary(as, ir, MIPSI_SQRT_D); + else +#endif + asm_callid(as, ir, IRCALL_lj_vm_floor + ir->op2); +} +#endif + +#if !LJ_SOFTFP +#define asm_fpadd(as, ir) asm_fparith(as, ir, MIPSI_ADD_D) +#define asm_fpsub(as, ir) asm_fparith(as, ir, MIPSI_SUB_D) +#define asm_fpmul(as, ir) asm_fparith(as, ir, MIPSI_MUL_D) +#elif LJ_64 /* && LJ_SOFTFP */ +#define asm_fpadd(as, ir) asm_callid(as, ir, IRCALL_softfp_add) +#define asm_fpsub(as, ir) asm_callid(as, ir, IRCALL_softfp_sub) +#define asm_fpmul(as, ir) asm_callid(as, ir, IRCALL_softfp_mul) +#endif + +static void asm_add(ASMState *as, IRIns *ir) +{ + IRType1 t = ir->t; +#if !LJ_SOFTFP32 + if (irt_isnum(t)) { + asm_fpadd(as, ir); + } else +#endif + { + /* TODO MIPSR6: Fuse ADD(BSHL(a,1-4),b) or ADD(ADD(a,a),b) to MIPSI_ALSA. */ + Reg dest = ra_dest(as, ir, RSET_GPR); + Reg right, left = ra_hintalloc(as, ir->op1, dest, RSET_GPR); + if (irref_isk(ir->op2)) { + intptr_t k = get_kval(as, ir->op2); + if (checki16(k)) { + emit_tsi(as, (LJ_64 && irt_is64(t)) ? MIPSI_DADDIU : MIPSI_ADDIU, dest, + left, k); + return; + } + } + right = ra_alloc1(as, ir->op2, rset_exclude(RSET_GPR, left)); + emit_dst(as, (LJ_64 && irt_is64(t)) ? MIPSI_DADDU : MIPSI_ADDU, dest, + left, right); + } +} + +static void asm_sub(ASMState *as, IRIns *ir) +{ +#if !LJ_SOFTFP32 + if (irt_isnum(ir->t)) { + asm_fpsub(as, ir); + } else +#endif + { + Reg dest = ra_dest(as, ir, RSET_GPR); + Reg right, left = ra_alloc2(as, ir, RSET_GPR); + right = (left >> 8); left &= 255; + emit_dst(as, (LJ_64 && irt_is64(ir->t)) ? MIPSI_DSUBU : MIPSI_SUBU, dest, + left, right); + } +} + +static void asm_mul(ASMState *as, IRIns *ir) +{ +#if !LJ_SOFTFP32 + if (irt_isnum(ir->t)) { + asm_fpmul(as, ir); + } else +#endif + { + Reg dest = ra_dest(as, ir, RSET_GPR); + Reg right, left = ra_alloc2(as, ir, RSET_GPR); + right = (left >> 8); left &= 255; + if (LJ_64 && irt_is64(ir->t)) { +#if !LJ_TARGET_MIPSR6 + emit_dst(as, MIPSI_MFLO, dest, 0, 0); + emit_dst(as, MIPSI_DMULT, 0, left, right); +#else + emit_dst(as, MIPSI_DMUL, dest, left, right); +#endif + } else { + emit_dst(as, MIPSI_MUL, dest, left, right); + } + } +} + +#if !LJ_SOFTFP32 +static void asm_fpdiv(ASMState *as, IRIns *ir) +{ +#if !LJ_SOFTFP + asm_fparith(as, ir, MIPSI_DIV_D); +#else + asm_callid(as, ir, IRCALL_softfp_div); +#endif +} +#endif + +static void asm_neg(ASMState *as, IRIns *ir) +{ +#if !LJ_SOFTFP + if (irt_isnum(ir->t)) { + asm_fpunary(as, ir, MIPSI_NEG_D); + } else +#elif LJ_64 /* && LJ_SOFTFP */ + if (irt_isnum(ir->t)) { + Reg dest = ra_dest(as, ir, RSET_GPR); + Reg left = ra_hintalloc(as, ir->op1, dest, RSET_GPR); + emit_dst(as, MIPSI_XOR, dest, left, + ra_allock(as, 0x8000000000000000ll, rset_exclude(RSET_GPR, dest))); + } else +#endif + { + Reg dest = ra_dest(as, ir, RSET_GPR); + Reg left = ra_hintalloc(as, ir->op1, dest, RSET_GPR); + emit_dst(as, (LJ_64 && irt_is64(ir->t)) ? MIPSI_DSUBU : MIPSI_SUBU, dest, + RID_ZERO, left); + } +} + +#if !LJ_SOFTFP +#define asm_abs(as, ir) asm_fpunary(as, ir, MIPSI_ABS_D) +#elif LJ_64 /* && LJ_SOFTFP */ +static void asm_abs(ASMState *as, IRIns *ir) +{ + Reg dest = ra_dest(as, ir, RSET_GPR); + Reg left = ra_alloc1(as, ir->op1, RSET_GPR); + emit_tsml(as, MIPSI_DEXTM, dest, left, 30, 0); +} +#endif + +static void asm_arithov(ASMState *as, IRIns *ir) +{ + /* TODO MIPSR6: bovc/bnvc. Caveat: no delay slot to load RID_TMP. */ + Reg right, left, tmp, dest = ra_dest(as, ir, RSET_GPR); + lj_assertA(!irt_is64(ir->t), "bad usage"); + if (irref_isk(ir->op2)) { + int k = IR(ir->op2)->i; + if (ir->o == IR_SUBOV) k = -k; + if (checki16(k)) { /* (dest < left) == (k >= 0 ? 1 : 0) */ + left = ra_alloc1(as, ir->op1, RSET_GPR); + asm_guard(as, k >= 0 ? MIPSI_BNE : MIPSI_BEQ, RID_TMP, RID_ZERO); + emit_dst(as, MIPSI_SLT, RID_TMP, dest, dest == left ? RID_TMP : left); + emit_tsi(as, MIPSI_ADDIU, dest, left, k); + if (dest == left) emit_move(as, RID_TMP, left); + return; + } + } + left = ra_alloc2(as, ir, RSET_GPR); + right = (left >> 8); left &= 255; + tmp = ra_scratch(as, rset_exclude(rset_exclude(rset_exclude(RSET_GPR, left), + right), dest)); + asm_guard(as, MIPSI_BLTZ, RID_TMP, 0); + emit_dst(as, MIPSI_AND, RID_TMP, RID_TMP, tmp); + if (ir->o == IR_ADDOV) { /* ((dest^left) & (dest^right)) < 0 */ + emit_dst(as, MIPSI_XOR, RID_TMP, dest, dest == right ? RID_TMP : right); + } else { /* ((dest^left) & (dest^~right)) < 0 */ + emit_dst(as, MIPSI_XOR, RID_TMP, RID_TMP, dest); + emit_dst(as, MIPSI_NOR, RID_TMP, dest == right ? RID_TMP : right, RID_ZERO); + } + emit_dst(as, MIPSI_XOR, tmp, dest, dest == left ? RID_TMP : left); + emit_dst(as, ir->o == IR_ADDOV ? MIPSI_ADDU : MIPSI_SUBU, dest, left, right); + if (dest == left || dest == right) + emit_move(as, RID_TMP, dest == left ? left : right); +} + +#define asm_addov(as, ir) asm_arithov(as, ir) +#define asm_subov(as, ir) asm_arithov(as, ir) + +static void asm_mulov(ASMState *as, IRIns *ir) +{ + Reg dest = ra_dest(as, ir, RSET_GPR); + Reg tmp, right, left = ra_alloc2(as, ir, RSET_GPR); + right = (left >> 8); left &= 255; + tmp = ra_scratch(as, rset_exclude(rset_exclude(rset_exclude(RSET_GPR, left), + right), dest)); + asm_guard(as, MIPSI_BNE, RID_TMP, tmp); + emit_dta(as, MIPSI_SRA, RID_TMP, dest, 31); +#if !LJ_TARGET_MIPSR6 + emit_dst(as, MIPSI_MFHI, tmp, 0, 0); + emit_dst(as, MIPSI_MFLO, dest, 0, 0); + emit_dst(as, MIPSI_MULT, 0, left, right); +#else + emit_dst(as, MIPSI_MUL, dest, left, right); + emit_dst(as, MIPSI_MUH, tmp, left, right); +#endif +} + +#if LJ_32 && LJ_HASFFI +static void asm_add64(ASMState *as, IRIns *ir) +{ + Reg dest = ra_dest(as, ir, RSET_GPR); + Reg right, left = ra_alloc1(as, ir->op1, RSET_GPR); + if (irref_isk(ir->op2)) { + int32_t k = IR(ir->op2)->i; + if (k == 0) { + emit_dst(as, MIPSI_ADDU, dest, left, RID_TMP); + goto loarith; + } else if (checki16(k)) { + emit_dst(as, MIPSI_ADDU, dest, dest, RID_TMP); + emit_tsi(as, MIPSI_ADDIU, dest, left, k); + goto loarith; + } + } + emit_dst(as, MIPSI_ADDU, dest, dest, RID_TMP); + right = ra_alloc1(as, ir->op2, rset_exclude(RSET_GPR, left)); + emit_dst(as, MIPSI_ADDU, dest, left, right); +loarith: + ir--; + dest = ra_dest(as, ir, RSET_GPR); + left = ra_alloc1(as, ir->op1, RSET_GPR); + if (irref_isk(ir->op2)) { + int32_t k = IR(ir->op2)->i; + if (k == 0) { + if (dest != left) + emit_move(as, dest, left); + return; + } else if (checki16(k)) { + if (dest == left) { + Reg tmp = ra_scratch(as, rset_exclude(RSET_GPR, left)); + emit_move(as, dest, tmp); + dest = tmp; + } + emit_dst(as, MIPSI_SLTU, RID_TMP, dest, left); + emit_tsi(as, MIPSI_ADDIU, dest, left, k); + return; + } + } + right = ra_alloc1(as, ir->op2, rset_exclude(RSET_GPR, left)); + if (dest == left && dest == right) { + Reg tmp = ra_scratch(as, rset_exclude(rset_exclude(RSET_GPR, left), right)); + emit_move(as, dest, tmp); + dest = tmp; + } + emit_dst(as, MIPSI_SLTU, RID_TMP, dest, dest == left ? right : left); + emit_dst(as, MIPSI_ADDU, dest, left, right); +} + +static void asm_sub64(ASMState *as, IRIns *ir) +{ + Reg dest = ra_dest(as, ir, RSET_GPR); + Reg right, left = ra_alloc2(as, ir, RSET_GPR); + right = (left >> 8); left &= 255; + emit_dst(as, MIPSI_SUBU, dest, dest, RID_TMP); + emit_dst(as, MIPSI_SUBU, dest, left, right); + ir--; + dest = ra_dest(as, ir, RSET_GPR); + left = ra_alloc2(as, ir, RSET_GPR); + right = (left >> 8); left &= 255; + if (dest == left) { + Reg tmp = ra_scratch(as, rset_exclude(rset_exclude(RSET_GPR, left), right)); + emit_move(as, dest, tmp); + dest = tmp; + } + emit_dst(as, MIPSI_SLTU, RID_TMP, left, dest); + emit_dst(as, MIPSI_SUBU, dest, left, right); +} + +static void asm_neg64(ASMState *as, IRIns *ir) +{ + Reg dest = ra_dest(as, ir, RSET_GPR); + Reg left = ra_alloc1(as, ir->op1, RSET_GPR); + emit_dst(as, MIPSI_SUBU, dest, dest, RID_TMP); + emit_dst(as, MIPSI_SUBU, dest, RID_ZERO, left); + ir--; + dest = ra_dest(as, ir, RSET_GPR); + left = ra_alloc1(as, ir->op1, RSET_GPR); + emit_dst(as, MIPSI_SLTU, RID_TMP, RID_ZERO, dest); + emit_dst(as, MIPSI_SUBU, dest, RID_ZERO, left); +} +#endif + +static void asm_bnot(ASMState *as, IRIns *ir) +{ + Reg left, right, dest = ra_dest(as, ir, RSET_GPR); + IRIns *irl = IR(ir->op1); + if (mayfuse(as, ir->op1) && irl->o == IR_BOR) { + left = ra_alloc2(as, irl, RSET_GPR); + right = (left >> 8); left &= 255; + } else { + left = ra_hintalloc(as, ir->op1, dest, RSET_GPR); + right = RID_ZERO; + } + emit_dst(as, MIPSI_NOR, dest, left, right); +} + +static void asm_bswap(ASMState *as, IRIns *ir) +{ + Reg dest = ra_dest(as, ir, RSET_GPR); + Reg left = ra_alloc1(as, ir->op1, RSET_GPR); +#if LJ_32 + if ((as->flags & JIT_F_MIPSXXR2)) { + emit_dta(as, MIPSI_ROTR, dest, RID_TMP, 16); + emit_dst(as, MIPSI_WSBH, RID_TMP, 0, left); + } else { + Reg tmp = ra_scratch(as, rset_exclude(rset_exclude(RSET_GPR, left), dest)); + emit_dst(as, MIPSI_OR, dest, dest, tmp); + emit_dst(as, MIPSI_OR, dest, dest, RID_TMP); + emit_tsi(as, MIPSI_ANDI, dest, dest, 0xff00); + emit_dta(as, MIPSI_SLL, RID_TMP, RID_TMP, 8); + emit_dta(as, MIPSI_SRL, dest, left, 8); + emit_tsi(as, MIPSI_ANDI, RID_TMP, left, 0xff00); + emit_dst(as, MIPSI_OR, tmp, tmp, RID_TMP); + emit_dta(as, MIPSI_SRL, tmp, left, 24); + emit_dta(as, MIPSI_SLL, RID_TMP, left, 24); + } +#else + if (irt_is64(ir->t)) { + emit_dst(as, MIPSI_DSHD, dest, 0, RID_TMP); + emit_dst(as, MIPSI_DSBH, RID_TMP, 0, left); + } else { + emit_dta(as, MIPSI_ROTR, dest, RID_TMP, 16); + emit_dst(as, MIPSI_WSBH, RID_TMP, 0, left); + } +#endif +} + +static void asm_bitop(ASMState *as, IRIns *ir, MIPSIns mi, MIPSIns mik) +{ + Reg dest = ra_dest(as, ir, RSET_GPR); + Reg right, left = ra_hintalloc(as, ir->op1, dest, RSET_GPR); + if (irref_isk(ir->op2)) { + intptr_t k = get_kval(as, ir->op2); + if (checku16(k)) { + emit_tsi(as, mik, dest, left, k); + return; + } + } + right = ra_alloc1(as, ir->op2, rset_exclude(RSET_GPR, left)); + emit_dst(as, mi, dest, left, right); +} + +#define asm_band(as, ir) asm_bitop(as, ir, MIPSI_AND, MIPSI_ANDI) +#define asm_bor(as, ir) asm_bitop(as, ir, MIPSI_OR, MIPSI_ORI) +#define asm_bxor(as, ir) asm_bitop(as, ir, MIPSI_XOR, MIPSI_XORI) + +static void asm_bitshift(ASMState *as, IRIns *ir, MIPSIns mi, MIPSIns mik) +{ + Reg dest = ra_dest(as, ir, RSET_GPR); + if (irref_isk(ir->op2)) { /* Constant shifts. */ + uint32_t shift = (uint32_t)IR(ir->op2)->i; + if (LJ_64 && irt_is64(ir->t)) mik |= (shift & 32) ? MIPSI_D32 : MIPSI_D; + emit_dta(as, mik, dest, ra_hintalloc(as, ir->op1, dest, RSET_GPR), + (shift & 31)); + } else { + Reg right, left = ra_alloc2(as, ir, RSET_GPR); + right = (left >> 8); left &= 255; + if (LJ_64 && irt_is64(ir->t)) mi |= MIPSI_DV; + emit_dst(as, mi, dest, right, left); /* Shift amount is in rs. */ + } +} + +#define asm_bshl(as, ir) asm_bitshift(as, ir, MIPSI_SLLV, MIPSI_SLL) +#define asm_bshr(as, ir) asm_bitshift(as, ir, MIPSI_SRLV, MIPSI_SRL) +#define asm_bsar(as, ir) asm_bitshift(as, ir, MIPSI_SRAV, MIPSI_SRA) +#define asm_brol(as, ir) lj_assertA(0, "unexpected BROL") + +static void asm_bror(ASMState *as, IRIns *ir) +{ + if (LJ_64 || (as->flags & JIT_F_MIPSXXR2)) { + asm_bitshift(as, ir, MIPSI_ROTRV, MIPSI_ROTR); + } else { + Reg dest = ra_dest(as, ir, RSET_GPR); + if (irref_isk(ir->op2)) { /* Constant shifts. */ + uint32_t shift = (uint32_t)(IR(ir->op2)->i & 31); + Reg left = ra_hintalloc(as, ir->op1, dest, RSET_GPR); + emit_rotr(as, dest, left, RID_TMP, shift); + } else { + Reg right, left = ra_alloc2(as, ir, RSET_GPR); + right = (left >> 8); left &= 255; + emit_dst(as, MIPSI_OR, dest, dest, RID_TMP); + emit_dst(as, MIPSI_SRLV, dest, right, left); + emit_dst(as, MIPSI_SLLV, RID_TMP, RID_TMP, left); + emit_dst(as, MIPSI_SUBU, RID_TMP, ra_allock(as, 32, RSET_GPR), right); + } + } +} + +#if LJ_SOFTFP +static void asm_sfpmin_max(ASMState *as, IRIns *ir) +{ + CCallInfo ci = lj_ir_callinfo[(IROp)ir->o == IR_MIN ? IRCALL_lj_vm_sfmin : IRCALL_lj_vm_sfmax]; +#if LJ_64 + IRRef args[2]; + args[0] = ir->op1; + args[1] = ir->op2; +#else + IRRef args[4]; + args[0^LJ_BE] = ir->op1; + args[1^LJ_BE] = (ir+1)->op1; + args[2^LJ_BE] = ir->op2; + args[3^LJ_BE] = (ir+1)->op2; +#endif + asm_setupresult(as, ir, &ci); + emit_call(as, (void *)ci.func, 0); + ci.func = NULL; + asm_gencall(as, &ci, args); +} +#endif + +static void asm_min_max(ASMState *as, IRIns *ir, int ismax) +{ + if (!LJ_SOFTFP32 && irt_isnum(ir->t)) { +#if LJ_SOFTFP + asm_sfpmin_max(as, ir); +#else + Reg dest = ra_dest(as, ir, RSET_FPR); + Reg right, left = ra_alloc2(as, ir, RSET_FPR); + right = (left >> 8); left &= 255; +#if !LJ_TARGET_MIPSR6 + if (dest == left) { + emit_fg(as, MIPSI_MOVF_D, dest, right); + } else { + emit_fg(as, MIPSI_MOVT_D, dest, left); + if (dest != right) emit_fg(as, MIPSI_MOV_D, dest, right); + } + emit_fgh(as, MIPSI_C_OLT_D, 0, ismax ? right : left, ismax ? left : right); +#else + emit_fgh(as, ismax ? MIPSI_MAX_D : MIPSI_MIN_D, dest, left, right); +#endif +#endif + } else { + Reg dest = ra_dest(as, ir, RSET_GPR); + Reg right, left = ra_alloc2(as, ir, RSET_GPR); + right = (left >> 8); left &= 255; + if (left == right) { + if (dest != left) emit_move(as, dest, left); + } else { +#if !LJ_TARGET_MIPSR6 + if (dest == left) { + emit_dst(as, MIPSI_MOVN, dest, right, RID_TMP); + } else { + emit_dst(as, MIPSI_MOVZ, dest, left, RID_TMP); + if (dest != right) emit_move(as, dest, right); + } +#else + emit_dst(as, MIPSI_OR, dest, dest, RID_TMP); + if (dest != right) { + emit_dst(as, MIPSI_SELNEZ, RID_TMP, right, RID_TMP); + emit_dst(as, MIPSI_SELEQZ, dest, left, RID_TMP); + } else { + emit_dst(as, MIPSI_SELEQZ, RID_TMP, left, RID_TMP); + emit_dst(as, MIPSI_SELNEZ, dest, right, RID_TMP); + } +#endif + emit_dst(as, MIPSI_SLT, RID_TMP, + ismax ? left : right, ismax ? right : left); + } + } +} + +#define asm_min(as, ir) asm_min_max(as, ir, 0) +#define asm_max(as, ir) asm_min_max(as, ir, 1) + +/* -- Comparisons --------------------------------------------------------- */ + +#if LJ_SOFTFP +/* SFP comparisons. */ +static void asm_sfpcomp(ASMState *as, IRIns *ir) +{ + const CCallInfo *ci = &lj_ir_callinfo[IRCALL_softfp_cmp]; + RegSet drop = RSET_SCRATCH; + Reg r; +#if LJ_64 + IRRef args[2]; + args[0] = ir->op1; + args[1] = ir->op2; +#else + IRRef args[4]; + args[LJ_LE ? 0 : 1] = ir->op1; args[LJ_LE ? 1 : 0] = (ir+1)->op1; + args[LJ_LE ? 2 : 3] = ir->op2; args[LJ_LE ? 3 : 2] = (ir+1)->op2; +#endif + + for (r = REGARG_FIRSTGPR; r <= REGARG_FIRSTGPR+(LJ_64?1:3); r++) { + if (!rset_test(as->freeset, r) && + regcost_ref(as->cost[r]) == args[r-REGARG_FIRSTGPR]) + rset_clear(drop, r); + } + ra_evictset(as, drop); + + asm_setupresult(as, ir, ci); + + switch ((IROp)ir->o) { + case IR_LT: + asm_guard(as, MIPSI_BGEZ, RID_RET, 0); + break; + case IR_ULT: + asm_guard(as, MIPSI_BEQ, RID_RET, RID_TMP); + emit_loadi(as, RID_TMP, 1); + asm_guard(as, MIPSI_BEQ, RID_RET, RID_ZERO); + break; + case IR_GE: + asm_guard(as, MIPSI_BEQ, RID_RET, RID_TMP); + emit_loadi(as, RID_TMP, 2); + asm_guard(as, MIPSI_BLTZ, RID_RET, 0); + break; + case IR_LE: + asm_guard(as, MIPSI_BGTZ, RID_RET, 0); + break; + case IR_GT: + asm_guard(as, MIPSI_BEQ, RID_RET, RID_TMP); + emit_loadi(as, RID_TMP, 2); + asm_guard(as, MIPSI_BLEZ, RID_RET, 0); + break; + case IR_UGE: + asm_guard(as, MIPSI_BLTZ, RID_RET, 0); + break; + case IR_ULE: + asm_guard(as, MIPSI_BEQ, RID_RET, RID_TMP); + emit_loadi(as, RID_TMP, 1); + break; + case IR_UGT: case IR_ABC: + asm_guard(as, MIPSI_BLEZ, RID_RET, 0); + break; + case IR_EQ: case IR_NE: + asm_guard(as, (ir->o & 1) ? MIPSI_BEQ : MIPSI_BNE, RID_RET, RID_ZERO); + default: + break; + } + asm_gencall(as, ci, args); +} +#endif + +static void asm_comp(ASMState *as, IRIns *ir) +{ + /* ORDER IR: LT GE LE GT ULT UGE ULE UGT. */ + IROp op = ir->o; + if (!LJ_SOFTFP32 && irt_isnum(ir->t)) { +#if LJ_SOFTFP + asm_sfpcomp(as, ir); +#else +#if !LJ_TARGET_MIPSR6 + Reg right, left = ra_alloc2(as, ir, RSET_FPR); + right = (left >> 8); left &= 255; + asm_guard(as, (op&1) ? MIPSI_BC1T : MIPSI_BC1F, 0, 0); + emit_fgh(as, MIPSI_C_OLT_D + ((op&3) ^ ((op>>2)&1)), 0, left, right); +#else + Reg tmp, right, left = ra_alloc2(as, ir, RSET_FPR); + right = (left >> 8); left &= 255; + tmp = ra_scratch(as, rset_exclude(rset_exclude(RSET_FPR, left), right)); + asm_guard(as, (op&1) ? MIPSI_BC1NEZ : MIPSI_BC1EQZ, 0, (tmp&31)); + emit_fgh(as, MIPSI_CMP_LT_D + ((op&3) ^ ((op>>2)&1)), tmp, left, right); +#endif +#endif + } else { + Reg right, left = ra_alloc1(as, ir->op1, RSET_GPR); + if (op == IR_ABC) op = IR_UGT; + if ((op&4) == 0 && irref_isk(ir->op2) && get_kval(as, ir->op2) == 0) { + MIPSIns mi = (op&2) ? ((op&1) ? MIPSI_BLEZ : MIPSI_BGTZ) : + ((op&1) ? MIPSI_BLTZ : MIPSI_BGEZ); + asm_guard(as, mi, left, 0); + } else { + if (irref_isk(ir->op2)) { + intptr_t k = get_kval(as, ir->op2); + if ((op&2)) k++; + if (checki16(k)) { + asm_guard(as, (op&1) ? MIPSI_BNE : MIPSI_BEQ, RID_TMP, RID_ZERO); + emit_tsi(as, (op&4) ? MIPSI_SLTIU : MIPSI_SLTI, + RID_TMP, left, k); + return; + } + } + right = ra_alloc1(as, ir->op2, rset_exclude(RSET_GPR, left)); + asm_guard(as, ((op^(op>>1))&1) ? MIPSI_BNE : MIPSI_BEQ, RID_TMP, RID_ZERO); + emit_dst(as, (op&4) ? MIPSI_SLTU : MIPSI_SLT, + RID_TMP, (op&2) ? right : left, (op&2) ? left : right); + } + } +} + +static void asm_equal(ASMState *as, IRIns *ir) +{ + Reg right, left = ra_alloc2(as, ir, (!LJ_SOFTFP && irt_isnum(ir->t)) ? + RSET_FPR : RSET_GPR); + right = (left >> 8); left &= 255; + if (!LJ_SOFTFP32 && irt_isnum(ir->t)) { +#if LJ_SOFTFP + asm_sfpcomp(as, ir); +#elif !LJ_TARGET_MIPSR6 + asm_guard(as, (ir->o & 1) ? MIPSI_BC1T : MIPSI_BC1F, 0, 0); + emit_fgh(as, MIPSI_C_EQ_D, 0, left, right); +#else + Reg tmp = ra_scratch(as, rset_exclude(rset_exclude(RSET_FPR, left), right)); + asm_guard(as, (ir->o & 1) ? MIPSI_BC1NEZ : MIPSI_BC1EQZ, 0, (tmp&31)); + emit_fgh(as, MIPSI_CMP_EQ_D, tmp, left, right); +#endif + } else { + asm_guard(as, (ir->o & 1) ? MIPSI_BEQ : MIPSI_BNE, left, right); + } +} + +#if LJ_32 && LJ_HASFFI +/* 64 bit integer comparisons. */ +static void asm_comp64(ASMState *as, IRIns *ir) +{ + /* ORDER IR: LT GE LE GT ULT UGE ULE UGT. */ + IROp op = (ir-1)->o; + MCLabel l_end; + Reg rightlo, leftlo, righthi, lefthi = ra_alloc2(as, ir, RSET_GPR); + righthi = (lefthi >> 8); lefthi &= 255; + leftlo = ra_alloc2(as, ir-1, + rset_exclude(rset_exclude(RSET_GPR, lefthi), righthi)); + rightlo = (leftlo >> 8); leftlo &= 255; + asm_guard(as, ((op^(op>>1))&1) ? MIPSI_BNE : MIPSI_BEQ, RID_TMP, RID_ZERO); + l_end = emit_label(as); + if (lefthi != righthi) + emit_dst(as, (op&4) ? MIPSI_SLTU : MIPSI_SLT, RID_TMP, + (op&2) ? righthi : lefthi, (op&2) ? lefthi : righthi); + emit_dst(as, MIPSI_SLTU, RID_TMP, + (op&2) ? rightlo : leftlo, (op&2) ? leftlo : rightlo); + if (lefthi != righthi) + emit_branch(as, MIPSI_BEQ, lefthi, righthi, l_end); +} + +static void asm_comp64eq(ASMState *as, IRIns *ir) +{ + Reg tmp, right, left = ra_alloc2(as, ir, RSET_GPR); + right = (left >> 8); left &= 255; + asm_guard(as, ((ir-1)->o & 1) ? MIPSI_BEQ : MIPSI_BNE, RID_TMP, RID_ZERO); + tmp = ra_scratch(as, rset_exclude(rset_exclude(RSET_GPR, left), right)); + emit_dst(as, MIPSI_OR, RID_TMP, RID_TMP, tmp); + emit_dst(as, MIPSI_XOR, tmp, left, right); + left = ra_alloc2(as, ir-1, RSET_GPR); + right = (left >> 8); left &= 255; + emit_dst(as, MIPSI_XOR, RID_TMP, left, right); +} +#endif + +/* -- Split register ops -------------------------------------------------- */ + +/* Hiword op of a split 32/32 or 64/64 bit op. Previous op is the loword op. */ +static void asm_hiop(ASMState *as, IRIns *ir) +{ + /* HIOP is marked as a store because it needs its own DCE logic. */ + int uselo = ra_used(ir-1), usehi = ra_used(ir); /* Loword/hiword used? */ + if (LJ_UNLIKELY(!(as->flags & JIT_F_OPT_DCE))) uselo = usehi = 1; +#if LJ_32 && (LJ_HASFFI || LJ_SOFTFP) + if ((ir-1)->o == IR_CONV) { /* Conversions to/from 64 bit. */ + as->curins--; /* Always skip the CONV. */ +#if LJ_HASFFI && !LJ_SOFTFP + if (usehi || uselo) + asm_conv64(as, ir); + return; +#endif + } else if ((ir-1)->o < IR_EQ) { /* 64 bit integer comparisons. ORDER IR. */ + as->curins--; /* Always skip the loword comparison. */ +#if LJ_SOFTFP + if (!irt_isint(ir->t)) { + asm_sfpcomp(as, ir-1); + return; + } +#endif +#if LJ_HASFFI + asm_comp64(as, ir); +#endif + return; + } else if ((ir-1)->o <= IR_NE) { /* 64 bit integer comparisons. ORDER IR. */ + as->curins--; /* Always skip the loword comparison. */ +#if LJ_SOFTFP + if (!irt_isint(ir->t)) { + asm_sfpcomp(as, ir-1); + return; + } +#endif +#if LJ_HASFFI + asm_comp64eq(as, ir); +#endif + return; +#if LJ_SOFTFP + } else if ((ir-1)->o == IR_MIN || (ir-1)->o == IR_MAX) { + as->curins--; /* Always skip the loword min/max. */ + if (uselo || usehi) + asm_sfpmin_max(as, ir-1); + return; +#endif + } else if ((ir-1)->o == IR_XSTORE) { + as->curins--; /* Handle both stores here. */ + if ((ir-1)->r != RID_SINK) { + asm_xstore_(as, ir, LJ_LE ? 4 : 0); + asm_xstore_(as, ir-1, LJ_LE ? 0 : 4); + } + return; + } +#endif + if (!usehi) return; /* Skip unused hiword op for all remaining ops. */ + switch ((ir-1)->o) { +#if LJ_32 && LJ_HASFFI + case IR_ADD: as->curins--; asm_add64(as, ir); break; + case IR_SUB: as->curins--; asm_sub64(as, ir); break; + case IR_NEG: as->curins--; asm_neg64(as, ir); break; + case IR_CNEWI: + /* Nothing to do here. Handled by lo op itself. */ + break; +#endif +#if LJ_32 && LJ_SOFTFP + case IR_SLOAD: case IR_ALOAD: case IR_HLOAD: case IR_ULOAD: case IR_VLOAD: + case IR_STRTO: + if (!uselo) + ra_allocref(as, ir->op1, RSET_GPR); /* Mark lo op as used. */ + break; + case IR_ASTORE: case IR_HSTORE: case IR_USTORE: case IR_TOSTR: case IR_TMPREF: + /* Nothing to do here. Handled by lo op itself. */ + break; +#endif + case IR_CALLN: case IR_CALLL: case IR_CALLS: case IR_CALLXS: + if (!uselo) + ra_allocref(as, ir->op1, RID2RSET(RID_RETLO)); /* Mark lo op as used. */ + break; + default: lj_assertA(0, "bad HIOP for op %d", (ir-1)->o); break; + } +} + +/* -- Profiling ----------------------------------------------------------- */ + +static void asm_prof(ASMState *as, IRIns *ir) +{ + UNUSED(ir); + asm_guard(as, MIPSI_BNE, RID_TMP, RID_ZERO); + emit_tsi(as, MIPSI_ANDI, RID_TMP, RID_TMP, HOOK_PROFILE); + emit_lsglptr(as, MIPSI_LBU, RID_TMP, + (int32_t)offsetof(global_State, hookmask)); +} + +/* -- Stack handling ------------------------------------------------------ */ + +/* Check Lua stack size for overflow. Use exit handler as fallback. */ +static void asm_stack_check(ASMState *as, BCReg topslot, + IRIns *irp, RegSet allow, ExitNo exitno) +{ + /* Try to get an unused temp. register, otherwise spill/restore RID_RET*. */ + Reg tmp, pbase = irp ? (ra_hasreg(irp->r) ? irp->r : RID_TMP) : RID_BASE; + ExitNo oldsnap = as->snapno; + rset_clear(allow, pbase); +#if LJ_32 + tmp = allow ? rset_pickbot(allow) : + (pbase == RID_RETHI ? RID_RETLO : RID_RETHI); +#else + tmp = allow ? rset_pickbot(allow) : RID_RET; +#endif + as->snapno = exitno; + asm_guard(as, MIPSI_BNE, RID_TMP, RID_ZERO); + as->snapno = oldsnap; + if (allow == RSET_EMPTY) /* Restore temp. register. */ + emit_tsi(as, MIPSI_AL, tmp, RID_SP, 0); + else + ra_modified(as, tmp); + emit_tsi(as, MIPSI_SLTIU, RID_TMP, RID_TMP, (int32_t)(8*topslot)); + emit_dst(as, MIPSI_ASUBU, RID_TMP, tmp, pbase); + emit_tsi(as, MIPSI_AL, tmp, tmp, offsetof(lua_State, maxstack)); + if (pbase == RID_TMP) + emit_getgl(as, RID_TMP, jit_base); + emit_getgl(as, tmp, cur_L); + if (allow == RSET_EMPTY) /* Spill temp. register. */ + emit_tsi(as, MIPSI_AS, tmp, RID_SP, 0); +} + +/* Restore Lua stack from on-trace state. */ +static void asm_stack_restore(ASMState *as, SnapShot *snap) +{ + SnapEntry *map = &as->T->snapmap[snap->mapofs]; +#if LJ_32 || defined(LUA_USE_ASSERT) + SnapEntry *flinks = &as->T->snapmap[snap_nextofs(as->T, snap)-1-LJ_FR2]; +#endif + MSize n, nent = snap->nent; + /* Store the value of all modified slots to the Lua stack. */ + for (n = 0; n < nent; n++) { + SnapEntry sn = map[n]; + BCReg s = snap_slot(sn); + int32_t ofs = 8*((int32_t)s-1-LJ_FR2); + IRRef ref = snap_ref(sn); + IRIns *ir = IR(ref); + if ((sn & SNAP_NORESTORE)) + continue; + if (irt_isnum(ir->t)) { +#if LJ_SOFTFP32 + Reg tmp; + RegSet allow = rset_exclude(RSET_GPR, RID_BASE); + /* LJ_SOFTFP: must be a number constant. */ + lj_assertA(irref_isk(ref), "unsplit FP op"); + tmp = ra_allock(as, (int32_t)ir_knum(ir)->u32.lo, allow); + emit_tsi(as, MIPSI_SW, tmp, RID_BASE, ofs+(LJ_BE?4:0)); + if (rset_test(as->freeset, tmp+1)) allow = RID2RSET(tmp+1); + tmp = ra_allock(as, (int32_t)ir_knum(ir)->u32.hi, allow); + emit_tsi(as, MIPSI_SW, tmp, RID_BASE, ofs+(LJ_BE?0:4)); +#elif LJ_SOFTFP /* && LJ_64 */ + Reg src = ra_alloc1(as, ref, rset_exclude(RSET_GPR, RID_BASE)); + emit_tsi(as, MIPSI_SD, src, RID_BASE, ofs); +#else + Reg src = ra_alloc1(as, ref, RSET_FPR); + emit_hsi(as, MIPSI_SDC1, src, RID_BASE, ofs); +#endif + } else { +#if LJ_32 + RegSet allow = rset_exclude(RSET_GPR, RID_BASE); + Reg type; + lj_assertA(irt_ispri(ir->t) || irt_isaddr(ir->t) || irt_isinteger(ir->t), + "restore of IR type %d", irt_type(ir->t)); + if (!irt_ispri(ir->t)) { + Reg src = ra_alloc1(as, ref, allow); + rset_clear(allow, src); + emit_tsi(as, MIPSI_SW, src, RID_BASE, ofs+(LJ_BE?4:0)); + } + if ((sn & (SNAP_CONT|SNAP_FRAME))) { + if (s == 0) continue; /* Do not overwrite link to previous frame. */ + type = ra_allock(as, (int32_t)(*flinks--), allow); +#if LJ_SOFTFP + } else if ((sn & SNAP_SOFTFPNUM)) { + type = ra_alloc1(as, ref+1, rset_exclude(RSET_GPR, RID_BASE)); +#endif + } else if ((sn & SNAP_KEYINDEX)) { + type = ra_allock(as, (int32_t)LJ_KEYINDEX, allow); + } else { + type = ra_allock(as, (int32_t)irt_toitype(ir->t), allow); + } + emit_tsi(as, MIPSI_SW, type, RID_BASE, ofs+(LJ_BE?0:4)); +#else + if ((sn & SNAP_KEYINDEX)) { + RegSet allow = rset_exclude(RSET_GPR, RID_BASE); + int64_t kki = (int64_t)LJ_KEYINDEX << 32; + if (irref_isk(ref)) { + emit_tsi(as, MIPSI_SD, + ra_allock(as, kki | (int64_t)(uint32_t)ir->i, allow), + RID_BASE, ofs); + } else { + Reg src = ra_alloc1(as, ref, allow); + Reg rki = ra_allock(as, kki, rset_exclude(allow, src)); + emit_tsi(as, MIPSI_SD, RID_TMP, RID_BASE, ofs); + emit_dst(as, MIPSI_DADDU, RID_TMP, src, rki); + } + } else { + asm_tvstore64(as, RID_BASE, ofs, ref); + } +#endif + } + checkmclim(as); + } + lj_assertA(map + nent == flinks, "inconsistent frames in snapshot"); +} + +/* -- GC handling --------------------------------------------------------- */ + +/* Marker to prevent patching the GC check exit. */ +#define MIPS_NOPATCH_GC_CHECK MIPSI_OR + +/* Check GC threshold and do one or more GC steps. */ +static void asm_gc_check(ASMState *as) +{ + const CCallInfo *ci = &lj_ir_callinfo[IRCALL_lj_gc_step_jit]; + IRRef args[2]; + MCLabel l_end; + Reg tmp; + ra_evictset(as, RSET_SCRATCH); + l_end = emit_label(as); + /* Exit trace if in GCSatomic or GCSfinalize. Avoids syncing GC objects. */ + /* Assumes asm_snap_prep() already done. */ + asm_guard(as, MIPSI_BNE, RID_RET, RID_ZERO); + args[0] = ASMREF_TMP1; /* global_State *g */ + args[1] = ASMREF_TMP2; /* MSize steps */ + asm_gencall(as, ci, args); + l_end[-3] = MIPS_NOPATCH_GC_CHECK; /* Replace the nop after the call. */ + emit_tsi(as, MIPSI_AADDIU, ra_releasetmp(as, ASMREF_TMP1), RID_JGL, -32768); + tmp = ra_releasetmp(as, ASMREF_TMP2); + emit_loadi(as, tmp, as->gcsteps); + /* Jump around GC step if GC total < GC threshold. */ + emit_branch(as, MIPSI_BNE, RID_TMP, RID_ZERO, l_end); + emit_dst(as, MIPSI_SLTU, RID_TMP, RID_TMP, tmp); + emit_getgl(as, tmp, gc.threshold); + emit_getgl(as, RID_TMP, gc.total); + as->gcsteps = 0; + checkmclim(as); +} + +/* -- Loop handling ------------------------------------------------------- */ + +/* Fixup the loop branch. */ +static void asm_loop_fixup(ASMState *as) +{ + MCode *p = as->mctop; + MCode *target = as->mcp; + p[-1] = MIPSI_NOP; + if (as->loopinv) { /* Inverted loop branch? */ + /* asm_guard already inverted the cond branch. Only patch the target. */ + p[-3] |= ((target-p+2) & 0x0000ffffu); + } else { + p[-2] = MIPSI_J|(((uintptr_t)target>>2)&0x03ffffffu); + } +} + +/* Fixup the tail of the loop. */ +static void asm_loop_tail_fixup(ASMState *as) +{ + if (as->loopinv) as->mctop--; +} + +/* -- Head of trace ------------------------------------------------------- */ + +/* Coalesce BASE register for a root trace. */ +static void asm_head_root_base(ASMState *as) +{ + IRIns *ir = IR(REF_BASE); + Reg r = ir->r; + if (ra_hasreg(r)) { + ra_free(as, r); + if (rset_test(as->modset, r) || irt_ismarked(ir->t)) + ir->r = RID_INIT; /* No inheritance for modified BASE register. */ + if (r != RID_BASE) + emit_move(as, r, RID_BASE); + } +} + +/* Coalesce BASE register for a side trace. */ +static RegSet asm_head_side_base(ASMState *as, IRIns *irp, RegSet allow) +{ + IRIns *ir = IR(REF_BASE); + Reg r = ir->r; + if (ra_hasreg(r)) { + ra_free(as, r); + if (rset_test(as->modset, r) || irt_ismarked(ir->t)) + ir->r = RID_INIT; /* No inheritance for modified BASE register. */ + if (irp->r == r) { + rset_clear(allow, r); /* Mark same BASE register as coalesced. */ + } else if (ra_hasreg(irp->r) && rset_test(as->freeset, irp->r)) { + rset_clear(allow, irp->r); + emit_move(as, r, irp->r); /* Move from coalesced parent reg. */ + } else { + emit_getgl(as, r, jit_base); /* Otherwise reload BASE. */ + } + } + return allow; +} + +/* -- Tail of trace ------------------------------------------------------- */ + +/* Fixup the tail code. */ +static void asm_tail_fixup(ASMState *as, TraceNo lnk) +{ + MCode *target = lnk ? traceref(as->J,lnk)->mcode : (MCode *)lj_vm_exit_interp; + int32_t spadj = as->T->spadjust; + MCode *p = as->mctop-1; + *p = spadj ? (MIPSI_AADDIU|MIPSF_T(RID_SP)|MIPSF_S(RID_SP)|spadj) : MIPSI_NOP; + p[-1] = MIPSI_J|(((uintptr_t)target>>2)&0x03ffffffu); +} + +/* Prepare tail of code. */ +static void asm_tail_prep(ASMState *as) +{ + as->mcp = as->mctop-2; /* Leave room for branch plus nop or stack adj. */ + as->invmcp = as->loopref ? as->mcp : NULL; +} + +/* -- Trace setup --------------------------------------------------------- */ + +/* Ensure there are enough stack slots for call arguments. */ +static Reg asm_setup_call_slots(ASMState *as, IRIns *ir, const CCallInfo *ci) +{ + IRRef args[CCI_NARGS_MAX*2]; + uint32_t i, nargs = CCI_XNARGS(ci); +#if LJ_32 + int nslots = 4, ngpr = REGARG_NUMGPR, nfpr = REGARG_NUMFPR; +#else + int nslots = 0, ngpr = REGARG_NUMGPR; +#endif + asm_collectargs(as, ir, ci, args); + for (i = 0; i < nargs; i++) { +#if LJ_32 + if (!LJ_SOFTFP && args[i] && irt_isfp(IR(args[i])->t) && + nfpr > 0 && !(ci->flags & CCI_VARARG)) { + nfpr--; + ngpr -= irt_isnum(IR(args[i])->t) ? 2 : 1; + } else if (!LJ_SOFTFP && args[i] && irt_isnum(IR(args[i])->t)) { + nfpr = 0; + ngpr = ngpr & ~1; + if (ngpr > 0) ngpr -= 2; else nslots = (nslots+3) & ~1; + } else { + nfpr = 0; + if (ngpr > 0) ngpr--; else nslots++; + } +#else + if (ngpr > 0) ngpr--; else nslots += 2; +#endif + } + if (nslots > as->evenspill) /* Leave room for args in stack slots. */ + as->evenspill = nslots; + return irt_isfp(ir->t) ? REGSP_HINT(RID_FPRET) : REGSP_HINT(RID_RET); +} + +static void asm_setup_target(ASMState *as) +{ + asm_sparejump_setup(as); + asm_exitstub_setup(as); +} + +/* -- Trace patching ------------------------------------------------------ */ + +/* Patch exit jumps of existing machine code to a new target. */ +void lj_asm_patchexit(jit_State *J, GCtrace *T, ExitNo exitno, MCode *target) +{ + MCode *p = T->mcode; + MCode *pe = (MCode *)((char *)p + T->szmcode); + MCode *px = exitstub_trace_addr(T, exitno); + MCode *cstart = NULL, *cstop = NULL; + MCode *mcarea = lj_mcode_patch(J, p, 0); + MCode exitload = MIPSI_LI | MIPSF_T(RID_TMP) | exitno; + MCode tjump = MIPSI_J|(((uintptr_t)target>>2)&0x03ffffffu); + for (p++; p < pe; p++) { + if (*p == exitload) { /* Look for load of exit number. */ + /* Look for exitstub branch. Yes, this covers all used branch variants. */ + if (((p[-1] ^ (px-p)) & 0xffffu) == 0 && + ((p[-1] & 0xf0000000u) == MIPSI_BEQ || + (p[-1] & 0xfc1e0000u) == MIPSI_BLTZ || +#if !LJ_TARGET_MIPSR6 + (p[-1] & 0xffe00000u) == MIPSI_BC1F +#else + (p[-1] & 0xff600000u) == MIPSI_BC1EQZ +#endif + ) && p[-2] != MIPS_NOPATCH_GC_CHECK) { + ptrdiff_t delta = target - p; + if (((delta + 0x8000) >> 16) == 0) { /* Patch in-range branch. */ + patchbranch: + p[-1] = (p[-1] & 0xffff0000u) | (delta & 0xffffu); + *p = MIPSI_NOP; /* Replace the load of the exit number. */ + cstop = p+1; + if (!cstart) cstart = p-1; + } else { /* Branch out of range. Use spare jump slot in mcarea. */ + MCode *mcjump = asm_sparejump_use(mcarea, tjump); + if (mcjump) { + lj_mcode_sync(mcjump, mcjump+1); + delta = mcjump - p; + if (((delta + 0x8000) >> 16) == 0) { + goto patchbranch; + } else { + lj_assertJ(0, "spare jump out of range: -Osizemcode too big"); + } + } + /* Ignore jump slot overflow. Child trace is simply not attached. */ + } + } else if (p+1 == pe) { + /* Patch NOP after code for inverted loop branch. Use of J is ok. */ + lj_assertJ(p[1] == MIPSI_NOP, "expected NOP"); + p[1] = tjump; + *p = MIPSI_NOP; /* Replace the load of the exit number. */ + cstop = p+2; + if (!cstart) cstart = p+1; + } + } + } + if (cstart) lj_mcode_sync(cstart, cstop); + lj_mcode_patch(J, mcarea, 1); +} + diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_asm_ppc.h b/fluent-bit/lib/luajit-3065c9/src/lj_asm_ppc.h new file mode 100644 index 00000000..546b8e5d --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_asm_ppc.h @@ -0,0 +1,2325 @@ +/* +** PPC IR assembler (SSA IR -> machine code). +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +/* -- Register allocator extensions --------------------------------------- */ + +/* Allocate a register with a hint. */ +static Reg ra_hintalloc(ASMState *as, IRRef ref, Reg hint, RegSet allow) +{ + Reg r = IR(ref)->r; + if (ra_noreg(r)) { + if (!ra_hashint(r) && !iscrossref(as, ref)) + ra_sethint(IR(ref)->r, hint); /* Propagate register hint. */ + r = ra_allocref(as, ref, allow); + } + ra_noweak(as, r); + return r; +} + +/* Allocate two source registers for three-operand instructions. */ +static Reg ra_alloc2(ASMState *as, IRIns *ir, RegSet allow) +{ + IRIns *irl = IR(ir->op1), *irr = IR(ir->op2); + Reg left = irl->r, right = irr->r; + if (ra_hasreg(left)) { + ra_noweak(as, left); + if (ra_noreg(right)) + right = ra_allocref(as, ir->op2, rset_exclude(allow, left)); + else + ra_noweak(as, right); + } else if (ra_hasreg(right)) { + ra_noweak(as, right); + left = ra_allocref(as, ir->op1, rset_exclude(allow, right)); + } else if (ra_hashint(right)) { + right = ra_allocref(as, ir->op2, allow); + left = ra_alloc1(as, ir->op1, rset_exclude(allow, right)); + } else { + left = ra_allocref(as, ir->op1, allow); + right = ra_alloc1(as, ir->op2, rset_exclude(allow, left)); + } + return left | (right << 8); +} + +/* -- Guard handling ------------------------------------------------------ */ + +/* Setup exit stubs after the end of each trace. */ +static void asm_exitstub_setup(ASMState *as, ExitNo nexits) +{ + ExitNo i; + MCode *mxp = as->mctop; + if (mxp - (nexits + 3 + MCLIM_REDZONE) < as->mclim) + asm_mclimit(as); + /* 1: mflr r0; bl ->vm_exit_handler; li r0, traceno; bl <1; bl <1; ... */ + for (i = nexits-1; (int32_t)i >= 0; i--) + *--mxp = PPCI_BL|(((-3-i)&0x00ffffffu)<<2); + *--mxp = PPCI_LI|PPCF_T(RID_TMP)|as->T->traceno; /* Read by exit handler. */ + mxp--; + *mxp = PPCI_BL|((((MCode *)(void *)lj_vm_exit_handler-mxp)&0x00ffffffu)<<2); + *--mxp = PPCI_MFLR|PPCF_T(RID_TMP); + as->mctop = mxp; +} + +static MCode *asm_exitstub_addr(ASMState *as, ExitNo exitno) +{ + /* Keep this in-sync with exitstub_trace_addr(). */ + return as->mctop + exitno + 3; +} + +/* Emit conditional branch to exit for guard. */ +static void asm_guardcc(ASMState *as, PPCCC cc) +{ + MCode *target = asm_exitstub_addr(as, as->snapno); + MCode *p = as->mcp; + if (LJ_UNLIKELY(p == as->invmcp)) { + as->loopinv = 1; + *p = PPCI_B | (((target-p) & 0x00ffffffu) << 2); + emit_condbranch(as, PPCI_BC, cc^4, p); + return; + } + emit_condbranch(as, PPCI_BC, cc, target); +} + +/* -- Operand fusion ------------------------------------------------------ */ + +/* Limit linear search to this distance. Avoids O(n^2) behavior. */ +#define CONFLICT_SEARCH_LIM 31 + +/* Check if there's no conflicting instruction between curins and ref. */ +static int noconflict(ASMState *as, IRRef ref, IROp conflict) +{ + IRIns *ir = as->ir; + IRRef i = as->curins; + if (i > ref + CONFLICT_SEARCH_LIM) + return 0; /* Give up, ref is too far away. */ + while (--i > ref) + if (ir[i].o == conflict) + return 0; /* Conflict found. */ + return 1; /* Ok, no conflict. */ +} + +/* Fuse the array base of colocated arrays. */ +static int32_t asm_fuseabase(ASMState *as, IRRef ref) +{ + IRIns *ir = IR(ref); + if (ir->o == IR_TNEW && ir->op1 <= LJ_MAX_COLOSIZE && + !neverfuse(as) && noconflict(as, ref, IR_NEWREF)) + return (int32_t)sizeof(GCtab); + return 0; +} + +/* Indicates load/store indexed is ok. */ +#define AHUREF_LSX ((int32_t)0x80000000) + +/* Fuse array/hash/upvalue reference into register+offset operand. */ +static Reg asm_fuseahuref(ASMState *as, IRRef ref, int32_t *ofsp, RegSet allow) +{ + IRIns *ir = IR(ref); + if (ra_noreg(ir->r)) { + if (ir->o == IR_AREF) { + if (mayfuse(as, ref)) { + if (irref_isk(ir->op2)) { + IRRef tab = IR(ir->op1)->op1; + int32_t ofs = asm_fuseabase(as, tab); + IRRef refa = ofs ? tab : ir->op1; + ofs += 8*IR(ir->op2)->i; + if (checki16(ofs)) { + *ofsp = ofs; + return ra_alloc1(as, refa, allow); + } + } + if (*ofsp == AHUREF_LSX) { + Reg base = ra_alloc1(as, ir->op1, allow); + Reg idx = ra_alloc1(as, ir->op2, rset_exclude(RSET_GPR, base)); + return base | (idx << 8); + } + } + } else if (ir->o == IR_HREFK) { + if (mayfuse(as, ref)) { + int32_t ofs = (int32_t)(IR(ir->op2)->op2 * sizeof(Node)); + if (checki16(ofs)) { + *ofsp = ofs; + return ra_alloc1(as, ir->op1, allow); + } + } + } else if (ir->o == IR_UREFC) { + if (irref_isk(ir->op1)) { + GCfunc *fn = ir_kfunc(IR(ir->op1)); + int32_t ofs = i32ptr(&gcref(fn->l.uvptr[(ir->op2 >> 8)])->uv.tv); + int32_t jgl = (intptr_t)J2G(as->J); + if ((uint32_t)(ofs-jgl) < 65536) { + *ofsp = ofs-jgl-32768; + return RID_JGL; + } else { + *ofsp = (int16_t)ofs; + return ra_allock(as, ofs-(int16_t)ofs, allow); + } + } + } else if (ir->o == IR_TMPREF) { + *ofsp = (int32_t)(offsetof(global_State, tmptv)-32768); + return RID_JGL; + } + } + *ofsp = 0; + return ra_alloc1(as, ref, allow); +} + +/* Fuse XLOAD/XSTORE reference into load/store operand. */ +static void asm_fusexref(ASMState *as, PPCIns pi, Reg rt, IRRef ref, + RegSet allow, int32_t ofs) +{ + IRIns *ir = IR(ref); + Reg base; + if (ra_noreg(ir->r) && canfuse(as, ir)) { + if (ir->o == IR_ADD) { + int32_t ofs2; + if (irref_isk(ir->op2) && (ofs2 = ofs + IR(ir->op2)->i, checki16(ofs2))) { + ofs = ofs2; + ref = ir->op1; + } else if (ofs == 0) { + Reg right, left = ra_alloc2(as, ir, allow); + right = (left >> 8); left &= 255; + emit_fab(as, PPCI_LWZX | ((pi >> 20) & 0x780), rt, left, right); + return; + } + } else if (ir->o == IR_STRREF) { + lj_assertA(ofs == 0, "bad usage"); + ofs = (int32_t)sizeof(GCstr); + if (irref_isk(ir->op2)) { + ofs += IR(ir->op2)->i; + ref = ir->op1; + } else if (irref_isk(ir->op1)) { + ofs += IR(ir->op1)->i; + ref = ir->op2; + } else { + /* NYI: Fuse ADD with constant. */ + Reg tmp, right, left = ra_alloc2(as, ir, allow); + right = (left >> 8); left &= 255; + tmp = ra_scratch(as, rset_exclude(rset_exclude(allow, left), right)); + emit_fai(as, pi, rt, tmp, ofs); + emit_tab(as, PPCI_ADD, tmp, left, right); + return; + } + if (!checki16(ofs)) { + Reg left = ra_alloc1(as, ref, allow); + Reg right = ra_allock(as, ofs, rset_exclude(allow, left)); + emit_fab(as, PPCI_LWZX | ((pi >> 20) & 0x780), rt, left, right); + return; + } + } + } + base = ra_alloc1(as, ref, allow); + emit_fai(as, pi, rt, base, ofs); +} + +/* Fuse XLOAD/XSTORE reference into indexed-only load/store operand. */ +static void asm_fusexrefx(ASMState *as, PPCIns pi, Reg rt, IRRef ref, + RegSet allow) +{ + IRIns *ira = IR(ref); + Reg right, left; + if (canfuse(as, ira) && ira->o == IR_ADD && ra_noreg(ira->r)) { + left = ra_alloc2(as, ira, allow); + right = (left >> 8); left &= 255; + } else { + right = ra_alloc1(as, ref, allow); + left = RID_R0; + } + emit_tab(as, pi, rt, left, right); +} + +#if !LJ_SOFTFP +/* Fuse to multiply-add/sub instruction. */ +static int asm_fusemadd(ASMState *as, IRIns *ir, PPCIns pi, PPCIns pir) +{ + IRRef lref = ir->op1, rref = ir->op2; + IRIns *irm; + if (lref != rref && + ((mayfuse(as, lref) && (irm = IR(lref), irm->o == IR_MUL) && + ra_noreg(irm->r)) || + (mayfuse(as, rref) && (irm = IR(rref), irm->o == IR_MUL) && + (rref = lref, pi = pir, ra_noreg(irm->r))))) { + Reg dest = ra_dest(as, ir, RSET_FPR); + Reg add = ra_alloc1(as, rref, RSET_FPR); + Reg right, left = ra_alloc2(as, irm, rset_exclude(RSET_FPR, add)); + right = (left >> 8); left &= 255; + emit_facb(as, pi, dest, left, right, add); + return 1; + } + return 0; +} +#endif + +/* -- Calls --------------------------------------------------------------- */ + +/* Generate a call to a C function. */ +static void asm_gencall(ASMState *as, const CCallInfo *ci, IRRef *args) +{ + uint32_t n, nargs = CCI_XNARGS(ci); + int32_t ofs = 8; + Reg gpr = REGARG_FIRSTGPR; +#if !LJ_SOFTFP + Reg fpr = REGARG_FIRSTFPR; +#endif + if ((void *)ci->func) + emit_call(as, (void *)ci->func); + for (n = 0; n < nargs; n++) { /* Setup args. */ + IRRef ref = args[n]; + if (ref) { + IRIns *ir = IR(ref); +#if !LJ_SOFTFP + if (irt_isfp(ir->t)) { + if (fpr <= REGARG_LASTFPR) { + lj_assertA(rset_test(as->freeset, fpr), + "reg %d not free", fpr); /* Already evicted. */ + ra_leftov(as, fpr, ref); + fpr++; + } else { + Reg r = ra_alloc1(as, ref, RSET_FPR); + if (irt_isnum(ir->t)) ofs = (ofs + 4) & ~4; + emit_spstore(as, ir, r, ofs); + ofs += irt_isnum(ir->t) ? 8 : 4; + } + } else +#endif + { + if (gpr <= REGARG_LASTGPR) { + lj_assertA(rset_test(as->freeset, gpr), + "reg %d not free", gpr); /* Already evicted. */ + ra_leftov(as, gpr, ref); + gpr++; + } else { + Reg r = ra_alloc1(as, ref, RSET_GPR); + emit_spstore(as, ir, r, ofs); + ofs += 4; + } + } + } else { + if (gpr <= REGARG_LASTGPR) + gpr++; + else + ofs += 4; + } + checkmclim(as); + } +#if !LJ_SOFTFP + if ((ci->flags & CCI_VARARG)) /* Vararg calls need to know about FPR use. */ + emit_tab(as, fpr == REGARG_FIRSTFPR ? PPCI_CRXOR : PPCI_CREQV, 6, 6, 6); +#endif +} + +/* Setup result reg/sp for call. Evict scratch regs. */ +static void asm_setupresult(ASMState *as, IRIns *ir, const CCallInfo *ci) +{ + RegSet drop = RSET_SCRATCH; + int hiop = ((ir+1)->o == IR_HIOP && !irt_isnil((ir+1)->t)); +#if !LJ_SOFTFP + if ((ci->flags & CCI_NOFPRCLOBBER)) + drop &= ~RSET_FPR; +#endif + if (ra_hasreg(ir->r)) + rset_clear(drop, ir->r); /* Dest reg handled below. */ + if (hiop && ra_hasreg((ir+1)->r)) + rset_clear(drop, (ir+1)->r); /* Dest reg handled below. */ + ra_evictset(as, drop); /* Evictions must be performed first. */ + if (ra_used(ir)) { + lj_assertA(!irt_ispri(ir->t), "PRI dest"); + if (!LJ_SOFTFP && irt_isfp(ir->t)) { + if ((ci->flags & CCI_CASTU64)) { + /* Use spill slot or temp slots. */ + int32_t ofs = ir->s ? sps_scale(ir->s) : SPOFS_TMP; + Reg dest = ir->r; + if (ra_hasreg(dest)) { + ra_free(as, dest); + ra_modified(as, dest); + emit_fai(as, PPCI_LFD, dest, RID_SP, ofs); + } + emit_tai(as, PPCI_STW, RID_RETHI, RID_SP, ofs); + emit_tai(as, PPCI_STW, RID_RETLO, RID_SP, ofs+4); + } else { + ra_destreg(as, ir, RID_FPRET); + } + } else if (hiop) { + ra_destpair(as, ir); + } else { + ra_destreg(as, ir, RID_RET); + } + } +} + +static void asm_callx(ASMState *as, IRIns *ir) +{ + IRRef args[CCI_NARGS_MAX*2]; + CCallInfo ci; + IRRef func; + IRIns *irf; + ci.flags = asm_callx_flags(as, ir); + asm_collectargs(as, ir, &ci, args); + asm_setupresult(as, ir, &ci); + func = ir->op2; irf = IR(func); + if (irf->o == IR_CARG) { func = irf->op1; irf = IR(func); } + if (irref_isk(func)) { /* Call to constant address. */ + ci.func = (ASMFunction)(void *)(intptr_t)(irf->i); + } else { /* Need a non-argument register for indirect calls. */ + RegSet allow = RSET_GPR & ~RSET_RANGE(RID_R0, REGARG_LASTGPR+1); + Reg freg = ra_alloc1(as, func, allow); + *--as->mcp = PPCI_BCTRL; + *--as->mcp = PPCI_MTCTR | PPCF_T(freg); + ci.func = (ASMFunction)(void *)0; + } + asm_gencall(as, &ci, args); +} + +/* -- Returns ------------------------------------------------------------- */ + +/* Return to lower frame. Guard that it goes to the right spot. */ +static void asm_retf(ASMState *as, IRIns *ir) +{ + Reg base = ra_alloc1(as, REF_BASE, RSET_GPR); + void *pc = ir_kptr(IR(ir->op2)); + int32_t delta = 1+LJ_FR2+bc_a(*((const BCIns *)pc - 1)); + as->topslot -= (BCReg)delta; + if ((int32_t)as->topslot < 0) as->topslot = 0; + irt_setmark(IR(REF_BASE)->t); /* Children must not coalesce with BASE reg. */ + emit_setgl(as, base, jit_base); + emit_addptr(as, base, -8*delta); + asm_guardcc(as, CC_NE); + emit_ab(as, PPCI_CMPW, RID_TMP, + ra_allock(as, i32ptr(pc), rset_exclude(RSET_GPR, base))); + emit_tai(as, PPCI_LWZ, RID_TMP, base, -8); +} + +/* -- Buffer operations --------------------------------------------------- */ + +#if LJ_HASBUFFER +static void asm_bufhdr_write(ASMState *as, Reg sb) +{ + Reg tmp = ra_scratch(as, rset_exclude(RSET_GPR, sb)); + IRIns irgc; + irgc.ot = IRT(0, IRT_PGC); /* GC type. */ + emit_storeofs(as, &irgc, RID_TMP, sb, offsetof(SBuf, L)); + emit_rot(as, PPCI_RLWIMI, RID_TMP, tmp, 0, 31-lj_fls(SBUF_MASK_FLAG), 31); + emit_getgl(as, RID_TMP, cur_L); + emit_loadofs(as, &irgc, tmp, sb, offsetof(SBuf, L)); +} +#endif + +/* -- Type conversions ---------------------------------------------------- */ + +#if !LJ_SOFTFP +static void asm_tointg(ASMState *as, IRIns *ir, Reg left) +{ + RegSet allow = RSET_FPR; + Reg tmp = ra_scratch(as, rset_clear(allow, left)); + Reg fbias = ra_scratch(as, rset_clear(allow, tmp)); + Reg dest = ra_dest(as, ir, RSET_GPR); + Reg hibias = ra_allock(as, 0x43300000, rset_exclude(RSET_GPR, dest)); + asm_guardcc(as, CC_NE); + emit_fab(as, PPCI_FCMPU, 0, tmp, left); + emit_fab(as, PPCI_FSUB, tmp, tmp, fbias); + emit_fai(as, PPCI_LFD, tmp, RID_SP, SPOFS_TMP); + emit_tai(as, PPCI_STW, RID_TMP, RID_SP, SPOFS_TMPLO); + emit_tai(as, PPCI_STW, hibias, RID_SP, SPOFS_TMPHI); + emit_asi(as, PPCI_XORIS, RID_TMP, dest, 0x8000); + emit_tai(as, PPCI_LWZ, dest, RID_SP, SPOFS_TMPLO); + emit_lsptr(as, PPCI_LFS, (fbias & 31), + (void *)&as->J->k32[LJ_K32_2P52_2P31], RSET_GPR); + emit_fai(as, PPCI_STFD, tmp, RID_SP, SPOFS_TMP); + emit_fb(as, PPCI_FCTIWZ, tmp, left); +} + +static void asm_tobit(ASMState *as, IRIns *ir) +{ + RegSet allow = RSET_FPR; + Reg dest = ra_dest(as, ir, RSET_GPR); + Reg left = ra_alloc1(as, ir->op1, allow); + Reg right = ra_alloc1(as, ir->op2, rset_clear(allow, left)); + Reg tmp = ra_scratch(as, rset_clear(allow, right)); + emit_tai(as, PPCI_LWZ, dest, RID_SP, SPOFS_TMPLO); + emit_fai(as, PPCI_STFD, tmp, RID_SP, SPOFS_TMP); + emit_fab(as, PPCI_FADD, tmp, left, right); +} +#endif + +static void asm_conv(ASMState *as, IRIns *ir) +{ + IRType st = (IRType)(ir->op2 & IRCONV_SRCMASK); +#if !LJ_SOFTFP + int stfp = (st == IRT_NUM || st == IRT_FLOAT); +#endif + IRRef lref = ir->op1; + /* 64 bit integer conversions are handled by SPLIT. */ + lj_assertA(!(irt_isint64(ir->t) || (st == IRT_I64 || st == IRT_U64)), + "IR %04d has unsplit 64 bit type", + (int)(ir - as->ir) - REF_BIAS); +#if LJ_SOFTFP + /* FP conversions are handled by SPLIT. */ + lj_assertA(!irt_isfp(ir->t) && !(st == IRT_NUM || st == IRT_FLOAT), + "IR %04d has FP type", + (int)(ir - as->ir) - REF_BIAS); + /* Can't check for same types: SPLIT uses CONV int.int + BXOR for sfp NEG. */ +#else + lj_assertA(irt_type(ir->t) != st, "inconsistent types for CONV"); + if (irt_isfp(ir->t)) { + Reg dest = ra_dest(as, ir, RSET_FPR); + if (stfp) { /* FP to FP conversion. */ + if (st == IRT_NUM) /* double -> float conversion. */ + emit_fb(as, PPCI_FRSP, dest, ra_alloc1(as, lref, RSET_FPR)); + else /* float -> double conversion is a no-op on PPC. */ + ra_leftov(as, dest, lref); /* Do nothing, but may need to move regs. */ + } else { /* Integer to FP conversion. */ + /* IRT_INT: Flip hibit, bias with 2^52, subtract 2^52+2^31. */ + /* IRT_U32: Bias with 2^52, subtract 2^52. */ + RegSet allow = RSET_GPR; + Reg left = ra_alloc1(as, lref, allow); + Reg hibias = ra_allock(as, 0x43300000, rset_clear(allow, left)); + Reg fbias = ra_scratch(as, rset_exclude(RSET_FPR, dest)); + if (irt_isfloat(ir->t)) emit_fb(as, PPCI_FRSP, dest, dest); + emit_fab(as, PPCI_FSUB, dest, dest, fbias); + emit_fai(as, PPCI_LFD, dest, RID_SP, SPOFS_TMP); + emit_lsptr(as, PPCI_LFS, (fbias & 31), + &as->J->k32[st == IRT_U32 ? LJ_K32_2P52 : LJ_K32_2P52_2P31], + rset_clear(allow, hibias)); + emit_tai(as, PPCI_STW, st == IRT_U32 ? left : RID_TMP, + RID_SP, SPOFS_TMPLO); + emit_tai(as, PPCI_STW, hibias, RID_SP, SPOFS_TMPHI); + if (st != IRT_U32) emit_asi(as, PPCI_XORIS, RID_TMP, left, 0x8000); + } + } else if (stfp) { /* FP to integer conversion. */ + if (irt_isguard(ir->t)) { + /* Checked conversions are only supported from number to int. */ + lj_assertA(irt_isint(ir->t) && st == IRT_NUM, + "bad type for checked CONV"); + asm_tointg(as, ir, ra_alloc1(as, lref, RSET_FPR)); + } else { + Reg dest = ra_dest(as, ir, RSET_GPR); + Reg left = ra_alloc1(as, lref, RSET_FPR); + Reg tmp = ra_scratch(as, rset_exclude(RSET_FPR, left)); + if (irt_isu32(ir->t)) { + /* Convert both x and x-2^31 to int and merge results. */ + Reg tmpi = ra_scratch(as, rset_exclude(RSET_GPR, dest)); + emit_asb(as, PPCI_OR, dest, dest, tmpi); /* Select with mask idiom. */ + emit_asb(as, PPCI_AND, tmpi, tmpi, RID_TMP); + emit_asb(as, PPCI_ANDC, dest, dest, RID_TMP); + emit_tai(as, PPCI_LWZ, tmpi, RID_SP, SPOFS_TMPLO); /* tmp = (int)(x) */ + emit_tai(as, PPCI_ADDIS, dest, dest, 0x8000); /* dest += 2^31 */ + emit_asb(as, PPCI_SRAWI, RID_TMP, dest, 31); /* mask = -(dest < 0) */ + emit_fai(as, PPCI_STFD, tmp, RID_SP, SPOFS_TMP); + emit_tai(as, PPCI_LWZ, dest, + RID_SP, SPOFS_TMPLO); /* dest = (int)(x-2^31) */ + emit_fb(as, PPCI_FCTIWZ, tmp, left); + emit_fai(as, PPCI_STFD, tmp, RID_SP, SPOFS_TMP); + emit_fb(as, PPCI_FCTIWZ, tmp, tmp); + emit_fab(as, PPCI_FSUB, tmp, left, tmp); + emit_lsptr(as, PPCI_LFS, (tmp & 31), + (void *)&as->J->k32[LJ_K32_2P31], RSET_GPR); + } else { + emit_tai(as, PPCI_LWZ, dest, RID_SP, SPOFS_TMPLO); + emit_fai(as, PPCI_STFD, tmp, RID_SP, SPOFS_TMP); + emit_fb(as, PPCI_FCTIWZ, tmp, left); + } + } + } else +#endif + { + Reg dest = ra_dest(as, ir, RSET_GPR); + if (st >= IRT_I8 && st <= IRT_U16) { /* Extend to 32 bit integer. */ + Reg left = ra_alloc1(as, ir->op1, RSET_GPR); + lj_assertA(irt_isint(ir->t) || irt_isu32(ir->t), "bad type for CONV EXT"); + if ((ir->op2 & IRCONV_SEXT)) + emit_as(as, st == IRT_I8 ? PPCI_EXTSB : PPCI_EXTSH, dest, left); + else + emit_rot(as, PPCI_RLWINM, dest, left, 0, st == IRT_U8 ? 24 : 16, 31); + } else { /* 32/64 bit integer conversions. */ + /* Only need to handle 32/32 bit no-op (cast) on 32 bit archs. */ + ra_leftov(as, dest, lref); /* Do nothing, but may need to move regs. */ + } + } +} + +static void asm_strto(ASMState *as, IRIns *ir) +{ + const CCallInfo *ci = &lj_ir_callinfo[IRCALL_lj_strscan_num]; + IRRef args[2]; + int32_t ofs = SPOFS_TMP; +#if LJ_SOFTFP + ra_evictset(as, RSET_SCRATCH); + if (ra_used(ir)) { + if (ra_hasspill(ir->s) && ra_hasspill((ir+1)->s) && + (ir->s & 1) == LJ_BE && (ir->s ^ 1) == (ir+1)->s) { + int i; + for (i = 0; i < 2; i++) { + Reg r = (ir+i)->r; + if (ra_hasreg(r)) { + ra_free(as, r); + ra_modified(as, r); + emit_spload(as, ir+i, r, sps_scale((ir+i)->s)); + } + } + ofs = sps_scale(ir->s & ~1); + } else { + Reg rhi = ra_dest(as, ir+1, RSET_GPR); + Reg rlo = ra_dest(as, ir, rset_exclude(RSET_GPR, rhi)); + emit_tai(as, PPCI_LWZ, rhi, RID_SP, ofs); + emit_tai(as, PPCI_LWZ, rlo, RID_SP, ofs+4); + } + } +#else + RegSet drop = RSET_SCRATCH; + if (ra_hasreg(ir->r)) rset_set(drop, ir->r); /* Spill dest reg (if any). */ + ra_evictset(as, drop); + if (ir->s) ofs = sps_scale(ir->s); +#endif + asm_guardcc(as, CC_EQ); + emit_ai(as, PPCI_CMPWI, RID_RET, 0); /* Test return status. */ + args[0] = ir->op1; /* GCstr *str */ + args[1] = ASMREF_TMP1; /* TValue *n */ + asm_gencall(as, ci, args); + /* Store the result to the spill slot or temp slots. */ + emit_tai(as, PPCI_ADDI, ra_releasetmp(as, ASMREF_TMP1), RID_SP, ofs); +} + +/* -- Memory references --------------------------------------------------- */ + +/* Get pointer to TValue. */ +static void asm_tvptr(ASMState *as, Reg dest, IRRef ref, MSize mode) +{ + int32_t tmpofs = (int32_t)(offsetof(global_State, tmptv)-32768); + if ((mode & IRTMPREF_IN1)) { + IRIns *ir = IR(ref); + if (irt_isnum(ir->t)) { + if ((mode & IRTMPREF_OUT1)) { +#if LJ_SOFTFP + lj_assertA(irref_isk(ref), "unsplit FP op"); + emit_tai(as, PPCI_ADDI, dest, RID_JGL, tmpofs); + emit_setgl(as, + ra_allock(as, (int32_t)ir_knum(ir)->u32.lo, RSET_GPR), + tmptv.u32.lo); + emit_setgl(as, + ra_allock(as, (int32_t)ir_knum(ir)->u32.hi, RSET_GPR), + tmptv.u32.hi); +#else + Reg src = ra_alloc1(as, ref, RSET_FPR); + emit_tai(as, PPCI_ADDI, dest, RID_JGL, tmpofs); + emit_fai(as, PPCI_STFD, src, RID_JGL, tmpofs); +#endif + } else if (irref_isk(ref)) { + /* Use the number constant itself as a TValue. */ + ra_allockreg(as, i32ptr(ir_knum(ir)), dest); + } else { +#if LJ_SOFTFP + lj_assertA(0, "unsplit FP op"); +#else + /* Otherwise force a spill and use the spill slot. */ + emit_tai(as, PPCI_ADDI, dest, RID_SP, ra_spill(as, ir)); +#endif + } + } else { + /* Otherwise use g->tmptv to hold the TValue. */ + Reg type; + emit_tai(as, PPCI_ADDI, dest, RID_JGL, tmpofs); + if (!irt_ispri(ir->t)) { + Reg src = ra_alloc1(as, ref, RSET_GPR); + emit_setgl(as, src, tmptv.gcr); + } + if (LJ_SOFTFP && (ir+1)->o == IR_HIOP && !irt_isnil((ir+1)->t)) + type = ra_alloc1(as, ref+1, RSET_GPR); + else + type = ra_allock(as, irt_toitype(ir->t), RSET_GPR); + emit_setgl(as, type, tmptv.it); + } + } else { + emit_tai(as, PPCI_ADDI, dest, RID_JGL, tmpofs); + } +} + +static void asm_aref(ASMState *as, IRIns *ir) +{ + Reg dest = ra_dest(as, ir, RSET_GPR); + Reg idx, base; + if (irref_isk(ir->op2)) { + IRRef tab = IR(ir->op1)->op1; + int32_t ofs = asm_fuseabase(as, tab); + IRRef refa = ofs ? tab : ir->op1; + ofs += 8*IR(ir->op2)->i; + if (checki16(ofs)) { + base = ra_alloc1(as, refa, RSET_GPR); + emit_tai(as, PPCI_ADDI, dest, base, ofs); + return; + } + } + base = ra_alloc1(as, ir->op1, RSET_GPR); + idx = ra_alloc1(as, ir->op2, rset_exclude(RSET_GPR, base)); + emit_tab(as, PPCI_ADD, dest, RID_TMP, base); + emit_slwi(as, RID_TMP, idx, 3); +} + +/* Inlined hash lookup. Specialized for key type and for const keys. +** The equivalent C code is: +** Node *n = hashkey(t, key); +** do { +** if (lj_obj_equal(&n->key, key)) return &n->val; +** } while ((n = nextnode(n))); +** return niltv(L); +*/ +static void asm_href(ASMState *as, IRIns *ir, IROp merge) +{ + RegSet allow = RSET_GPR; + int destused = ra_used(ir); + Reg dest = ra_dest(as, ir, allow); + Reg tab = ra_alloc1(as, ir->op1, rset_clear(allow, dest)); + Reg key = RID_NONE, tmp1 = RID_TMP, tmp2; + Reg tisnum = RID_NONE, tmpnum = RID_NONE; + IRRef refkey = ir->op2; + IRIns *irkey = IR(refkey); + int isk = irref_isk(refkey); + IRType1 kt = irkey->t; + uint32_t khash; + MCLabel l_end, l_loop, l_next; + + rset_clear(allow, tab); +#if LJ_SOFTFP + if (!isk) { + key = ra_alloc1(as, refkey, allow); + rset_clear(allow, key); + if (irkey[1].o == IR_HIOP) { + if (ra_hasreg((irkey+1)->r)) { + tmpnum = (irkey+1)->r; + ra_noweak(as, tmpnum); + } else { + tmpnum = ra_allocref(as, refkey+1, allow); + } + rset_clear(allow, tmpnum); + } + } +#else + if (irt_isnum(kt)) { + key = ra_alloc1(as, refkey, RSET_FPR); + tmpnum = ra_scratch(as, rset_exclude(RSET_FPR, key)); + tisnum = ra_allock(as, (int32_t)LJ_TISNUM, allow); + rset_clear(allow, tisnum); + } else if (!irt_ispri(kt)) { + key = ra_alloc1(as, refkey, allow); + rset_clear(allow, key); + } +#endif + tmp2 = ra_scratch(as, allow); + rset_clear(allow, tmp2); + + /* Key not found in chain: jump to exit (if merged) or load niltv. */ + l_end = emit_label(as); + as->invmcp = NULL; + if (merge == IR_NE) + asm_guardcc(as, CC_EQ); + else if (destused) + emit_loada(as, dest, niltvg(J2G(as->J))); + + /* Follow hash chain until the end. */ + l_loop = --as->mcp; + emit_ai(as, PPCI_CMPWI, dest, 0); + emit_tai(as, PPCI_LWZ, dest, dest, (int32_t)offsetof(Node, next)); + l_next = emit_label(as); + + /* Type and value comparison. */ + if (merge == IR_EQ) + asm_guardcc(as, CC_EQ); + else + emit_condbranch(as, PPCI_BC|PPCF_Y, CC_EQ, l_end); + if (!LJ_SOFTFP && irt_isnum(kt)) { + emit_fab(as, PPCI_FCMPU, 0, tmpnum, key); + emit_condbranch(as, PPCI_BC, CC_GE, l_next); + emit_ab(as, PPCI_CMPLW, tmp1, tisnum); + emit_fai(as, PPCI_LFD, tmpnum, dest, (int32_t)offsetof(Node, key.n)); + } else { + if (!irt_ispri(kt)) { + emit_ab(as, PPCI_CMPW, tmp2, key); + emit_condbranch(as, PPCI_BC, CC_NE, l_next); + } + if (LJ_SOFTFP && ra_hasreg(tmpnum)) + emit_ab(as, PPCI_CMPW, tmp1, tmpnum); + else + emit_ai(as, PPCI_CMPWI, tmp1, irt_toitype(irkey->t)); + if (!irt_ispri(kt)) + emit_tai(as, PPCI_LWZ, tmp2, dest, (int32_t)offsetof(Node, key.gcr)); + } + emit_tai(as, PPCI_LWZ, tmp1, dest, (int32_t)offsetof(Node, key.it)); + *l_loop = PPCI_BC | PPCF_Y | PPCF_CC(CC_NE) | + (((char *)as->mcp-(char *)l_loop) & 0xffffu); + + /* Load main position relative to tab->node into dest. */ + khash = isk ? ir_khash(as, irkey) : 1; + if (khash == 0) { + emit_tai(as, PPCI_LWZ, dest, tab, (int32_t)offsetof(GCtab, node)); + } else { + Reg tmphash = tmp1; + if (isk) + tmphash = ra_allock(as, khash, allow); + emit_tab(as, PPCI_ADD, dest, dest, tmp1); + emit_tai(as, PPCI_MULLI, tmp1, tmp1, sizeof(Node)); + emit_asb(as, PPCI_AND, tmp1, tmp2, tmphash); + emit_tai(as, PPCI_LWZ, dest, tab, (int32_t)offsetof(GCtab, node)); + emit_tai(as, PPCI_LWZ, tmp2, tab, (int32_t)offsetof(GCtab, hmask)); + if (isk) { + /* Nothing to do. */ + } else if (irt_isstr(kt)) { + emit_tai(as, PPCI_LWZ, tmp1, key, (int32_t)offsetof(GCstr, sid)); + } else { /* Must match with hash*() in lj_tab.c. */ + emit_tab(as, PPCI_SUBF, tmp1, tmp2, tmp1); + emit_rotlwi(as, tmp2, tmp2, HASH_ROT3); + emit_asb(as, PPCI_XOR, tmp1, tmp1, tmp2); + emit_rotlwi(as, tmp1, tmp1, (HASH_ROT2+HASH_ROT1)&31); + emit_tab(as, PPCI_SUBF, tmp2, dest, tmp2); + if (LJ_SOFTFP ? (irkey[1].o == IR_HIOP) : irt_isnum(kt)) { +#if LJ_SOFTFP + emit_asb(as, PPCI_XOR, tmp2, key, tmp1); + emit_rotlwi(as, dest, tmp1, HASH_ROT1); + emit_tab(as, PPCI_ADD, tmp1, tmpnum, tmpnum); +#else + int32_t ofs = ra_spill(as, irkey); + emit_asb(as, PPCI_XOR, tmp2, tmp2, tmp1); + emit_rotlwi(as, dest, tmp1, HASH_ROT1); + emit_tab(as, PPCI_ADD, tmp1, tmp1, tmp1); + emit_tai(as, PPCI_LWZ, tmp2, RID_SP, ofs+4); + emit_tai(as, PPCI_LWZ, tmp1, RID_SP, ofs); +#endif + } else { + emit_asb(as, PPCI_XOR, tmp2, key, tmp1); + emit_rotlwi(as, dest, tmp1, HASH_ROT1); + emit_tai(as, PPCI_ADDI, tmp1, tmp2, HASH_BIAS); + emit_tai(as, PPCI_ADDIS, tmp2, key, (HASH_BIAS + 32768)>>16); + } + } + } +} + +static void asm_hrefk(ASMState *as, IRIns *ir) +{ + IRIns *kslot = IR(ir->op2); + IRIns *irkey = IR(kslot->op1); + int32_t ofs = (int32_t)(kslot->op2 * sizeof(Node)); + int32_t kofs = ofs + (int32_t)offsetof(Node, key); + Reg dest = (ra_used(ir)||ofs > 32736) ? ra_dest(as, ir, RSET_GPR) : RID_NONE; + Reg node = ra_alloc1(as, ir->op1, RSET_GPR); + Reg key = RID_NONE, type = RID_TMP, idx = node; + RegSet allow = rset_exclude(RSET_GPR, node); + lj_assertA(ofs % sizeof(Node) == 0, "unaligned HREFK slot"); + if (ofs > 32736) { + idx = dest; + rset_clear(allow, dest); + kofs = (int32_t)offsetof(Node, key); + } else if (ra_hasreg(dest)) { + emit_tai(as, PPCI_ADDI, dest, node, ofs); + } + asm_guardcc(as, CC_NE); + if (!irt_ispri(irkey->t)) { + key = ra_scratch(as, allow); + rset_clear(allow, key); + } + rset_clear(allow, type); + if (irt_isnum(irkey->t)) { + emit_cmpi(as, key, (int32_t)ir_knum(irkey)->u32.lo); + asm_guardcc(as, CC_NE); + emit_cmpi(as, type, (int32_t)ir_knum(irkey)->u32.hi); + } else { + if (ra_hasreg(key)) { + emit_cmpi(as, key, irkey->i); /* May use RID_TMP, i.e. type. */ + asm_guardcc(as, CC_NE); + } + emit_ai(as, PPCI_CMPWI, type, irt_toitype(irkey->t)); + } + if (ra_hasreg(key)) emit_tai(as, PPCI_LWZ, key, idx, kofs+4); + emit_tai(as, PPCI_LWZ, type, idx, kofs); + if (ofs > 32736) { + emit_tai(as, PPCI_ADDIS, dest, dest, (ofs + 32768) >> 16); + emit_tai(as, PPCI_ADDI, dest, node, ofs); + } +} + +static void asm_uref(ASMState *as, IRIns *ir) +{ + Reg dest = ra_dest(as, ir, RSET_GPR); + if (irref_isk(ir->op1)) { + GCfunc *fn = ir_kfunc(IR(ir->op1)); + MRef *v = &gcref(fn->l.uvptr[(ir->op2 >> 8)])->uv.v; + emit_lsptr(as, PPCI_LWZ, dest, v, RSET_GPR); + } else { + Reg uv = ra_scratch(as, RSET_GPR); + Reg func = ra_alloc1(as, ir->op1, RSET_GPR); + if (ir->o == IR_UREFC) { + asm_guardcc(as, CC_NE); + emit_ai(as, PPCI_CMPWI, RID_TMP, 1); + emit_tai(as, PPCI_ADDI, dest, uv, (int32_t)offsetof(GCupval, tv)); + emit_tai(as, PPCI_LBZ, RID_TMP, uv, (int32_t)offsetof(GCupval, closed)); + } else { + emit_tai(as, PPCI_LWZ, dest, uv, (int32_t)offsetof(GCupval, v)); + } + emit_tai(as, PPCI_LWZ, uv, func, + (int32_t)offsetof(GCfuncL, uvptr) + 4*(int32_t)(ir->op2 >> 8)); + } +} + +static void asm_fref(ASMState *as, IRIns *ir) +{ + UNUSED(as); UNUSED(ir); + lj_assertA(!ra_used(ir), "unfused FREF"); +} + +static void asm_strref(ASMState *as, IRIns *ir) +{ + Reg dest = ra_dest(as, ir, RSET_GPR); + IRRef ref = ir->op2, refk = ir->op1; + int32_t ofs = (int32_t)sizeof(GCstr); + Reg r; + if (irref_isk(ref)) { + IRRef tmp = refk; refk = ref; ref = tmp; + } else if (!irref_isk(refk)) { + Reg right, left = ra_alloc1(as, ir->op1, RSET_GPR); + IRIns *irr = IR(ir->op2); + if (ra_hasreg(irr->r)) { + ra_noweak(as, irr->r); + right = irr->r; + } else if (mayfuse(as, irr->op2) && + irr->o == IR_ADD && irref_isk(irr->op2) && + checki16(ofs + IR(irr->op2)->i)) { + ofs += IR(irr->op2)->i; + right = ra_alloc1(as, irr->op1, rset_exclude(RSET_GPR, left)); + } else { + right = ra_allocref(as, ir->op2, rset_exclude(RSET_GPR, left)); + } + emit_tai(as, PPCI_ADDI, dest, dest, ofs); + emit_tab(as, PPCI_ADD, dest, left, right); + return; + } + r = ra_alloc1(as, ref, RSET_GPR); + ofs += IR(refk)->i; + if (checki16(ofs)) + emit_tai(as, PPCI_ADDI, dest, r, ofs); + else + emit_tab(as, PPCI_ADD, dest, r, + ra_allock(as, ofs, rset_exclude(RSET_GPR, r))); +} + +/* -- Loads and stores ---------------------------------------------------- */ + +static PPCIns asm_fxloadins(ASMState *as, IRIns *ir) +{ + UNUSED(as); + switch (irt_type(ir->t)) { + case IRT_I8: return PPCI_LBZ; /* Needs sign-extension. */ + case IRT_U8: return PPCI_LBZ; + case IRT_I16: return PPCI_LHA; + case IRT_U16: return PPCI_LHZ; + case IRT_NUM: lj_assertA(!LJ_SOFTFP, "unsplit FP op"); return PPCI_LFD; + case IRT_FLOAT: if (!LJ_SOFTFP) return PPCI_LFS; + default: return PPCI_LWZ; + } +} + +static PPCIns asm_fxstoreins(ASMState *as, IRIns *ir) +{ + UNUSED(as); + switch (irt_type(ir->t)) { + case IRT_I8: case IRT_U8: return PPCI_STB; + case IRT_I16: case IRT_U16: return PPCI_STH; + case IRT_NUM: lj_assertA(!LJ_SOFTFP, "unsplit FP op"); return PPCI_STFD; + case IRT_FLOAT: if (!LJ_SOFTFP) return PPCI_STFS; + default: return PPCI_STW; + } +} + +static void asm_fload(ASMState *as, IRIns *ir) +{ + Reg dest = ra_dest(as, ir, RSET_GPR); + PPCIns pi = asm_fxloadins(as, ir); + Reg idx; + int32_t ofs; + if (ir->op1 == REF_NIL) { /* FLOAD from GG_State with offset. */ + idx = RID_JGL; + ofs = (ir->op2 << 2) - 32768 - GG_OFS(g); + } else { + idx = ra_alloc1(as, ir->op1, RSET_GPR); + if (ir->op2 == IRFL_TAB_ARRAY) { + ofs = asm_fuseabase(as, ir->op1); + if (ofs) { /* Turn the t->array load into an add for colocated arrays. */ + emit_tai(as, PPCI_ADDI, dest, idx, ofs); + return; + } + } + ofs = field_ofs[ir->op2]; + } + lj_assertA(!irt_isi8(ir->t), "unsupported FLOAD I8"); + emit_tai(as, pi, dest, idx, ofs); +} + +static void asm_fstore(ASMState *as, IRIns *ir) +{ + if (ir->r != RID_SINK) { + Reg src = ra_alloc1(as, ir->op2, RSET_GPR); + IRIns *irf = IR(ir->op1); + Reg idx = ra_alloc1(as, irf->op1, rset_exclude(RSET_GPR, src)); + int32_t ofs = field_ofs[irf->op2]; + PPCIns pi = asm_fxstoreins(as, ir); + emit_tai(as, pi, src, idx, ofs); + } +} + +static void asm_xload(ASMState *as, IRIns *ir) +{ + Reg dest = ra_dest(as, ir, + (!LJ_SOFTFP && irt_isfp(ir->t)) ? RSET_FPR : RSET_GPR); + lj_assertA(!(ir->op2 & IRXLOAD_UNALIGNED), "unaligned XLOAD"); + if (irt_isi8(ir->t)) + emit_as(as, PPCI_EXTSB, dest, dest); + asm_fusexref(as, asm_fxloadins(as, ir), dest, ir->op1, RSET_GPR, 0); +} + +static void asm_xstore_(ASMState *as, IRIns *ir, int32_t ofs) +{ + IRIns *irb; + if (ir->r == RID_SINK) + return; + if (ofs == 0 && mayfuse(as, ir->op2) && (irb = IR(ir->op2))->o == IR_BSWAP && + ra_noreg(irb->r) && (irt_isint(ir->t) || irt_isu32(ir->t))) { + /* Fuse BSWAP with XSTORE to stwbrx. */ + Reg src = ra_alloc1(as, irb->op1, RSET_GPR); + asm_fusexrefx(as, PPCI_STWBRX, src, ir->op1, rset_exclude(RSET_GPR, src)); + } else { + Reg src = ra_alloc1(as, ir->op2, + (!LJ_SOFTFP && irt_isfp(ir->t)) ? RSET_FPR : RSET_GPR); + asm_fusexref(as, asm_fxstoreins(as, ir), src, ir->op1, + rset_exclude(RSET_GPR, src), ofs); + } +} + +#define asm_xstore(as, ir) asm_xstore_(as, ir, 0) + +static void asm_ahuvload(ASMState *as, IRIns *ir) +{ + IRType1 t = ir->t; + Reg dest = RID_NONE, type = RID_TMP, tmp = RID_TMP, idx; + RegSet allow = RSET_GPR; + int32_t ofs = AHUREF_LSX; + if (LJ_SOFTFP && (ir+1)->o == IR_HIOP) { + t.irt = IRT_NUM; + if (ra_used(ir+1)) { + type = ra_dest(as, ir+1, allow); + rset_clear(allow, type); + } + ofs = 0; + } + if (ra_used(ir)) { + lj_assertA((LJ_SOFTFP ? 0 : irt_isnum(ir->t)) || + irt_isint(ir->t) || irt_isaddr(ir->t), + "bad load type %d", irt_type(ir->t)); + if (LJ_SOFTFP || !irt_isnum(t)) ofs = 0; + dest = ra_dest(as, ir, (!LJ_SOFTFP && irt_isnum(t)) ? RSET_FPR : allow); + rset_clear(allow, dest); + } + idx = asm_fuseahuref(as, ir->op1, &ofs, allow); + if (ir->o == IR_VLOAD) { + ofs = ofs != AHUREF_LSX ? ofs + 8 * ir->op2 : + ir->op2 ? 8 * ir->op2 : AHUREF_LSX; + } + if (irt_isnum(t)) { + Reg tisnum = ra_allock(as, (int32_t)LJ_TISNUM, rset_exclude(allow, idx)); + asm_guardcc(as, CC_GE); + emit_ab(as, PPCI_CMPLW, type, tisnum); + if (ra_hasreg(dest)) { + if (!LJ_SOFTFP && ofs == AHUREF_LSX) { + tmp = ra_scratch(as, rset_exclude(rset_exclude(RSET_GPR, + (idx&255)), (idx>>8))); + emit_fab(as, PPCI_LFDX, dest, (idx&255), tmp); + } else { + emit_fai(as, LJ_SOFTFP ? PPCI_LWZ : PPCI_LFD, dest, idx, + ofs+4*LJ_SOFTFP); + } + } + } else { + asm_guardcc(as, CC_NE); + emit_ai(as, PPCI_CMPWI, type, irt_toitype(t)); + if (ra_hasreg(dest)) emit_tai(as, PPCI_LWZ, dest, idx, ofs+4); + } + if (ofs == AHUREF_LSX) { + emit_tab(as, PPCI_LWZX, type, (idx&255), tmp); + emit_slwi(as, tmp, (idx>>8), 3); + } else { + emit_tai(as, PPCI_LWZ, type, idx, ofs); + } +} + +static void asm_ahustore(ASMState *as, IRIns *ir) +{ + RegSet allow = RSET_GPR; + Reg idx, src = RID_NONE, type = RID_NONE; + int32_t ofs = AHUREF_LSX; + if (ir->r == RID_SINK) + return; + if (!LJ_SOFTFP && irt_isnum(ir->t)) { + src = ra_alloc1(as, ir->op2, RSET_FPR); + } else { + if (!irt_ispri(ir->t)) { + src = ra_alloc1(as, ir->op2, allow); + rset_clear(allow, src); + ofs = 0; + } + if (LJ_SOFTFP && (ir+1)->o == IR_HIOP) + type = ra_alloc1(as, (ir+1)->op2, allow); + else + type = ra_allock(as, (int32_t)irt_toitype(ir->t), allow); + rset_clear(allow, type); + } + idx = asm_fuseahuref(as, ir->op1, &ofs, allow); + if (!LJ_SOFTFP && irt_isnum(ir->t)) { + if (ofs == AHUREF_LSX) { + emit_fab(as, PPCI_STFDX, src, (idx&255), RID_TMP); + emit_slwi(as, RID_TMP, (idx>>8), 3); + } else { + emit_fai(as, PPCI_STFD, src, idx, ofs); + } + } else { + if (ra_hasreg(src)) + emit_tai(as, PPCI_STW, src, idx, ofs+4); + if (ofs == AHUREF_LSX) { + emit_tab(as, PPCI_STWX, type, (idx&255), RID_TMP); + emit_slwi(as, RID_TMP, (idx>>8), 3); + } else { + emit_tai(as, PPCI_STW, type, idx, ofs); + } + } +} + +static void asm_sload(ASMState *as, IRIns *ir) +{ + int32_t ofs = 8*((int32_t)ir->op1-1) + ((ir->op2 & IRSLOAD_FRAME) ? 0 : 4); + IRType1 t = ir->t; + Reg dest = RID_NONE, type = RID_NONE, base; + RegSet allow = RSET_GPR; + int hiop = (LJ_SOFTFP && (ir+1)->o == IR_HIOP); + if (hiop) + t.irt = IRT_NUM; + lj_assertA(!(ir->op2 & IRSLOAD_PARENT), + "bad parent SLOAD"); /* Handled by asm_head_side(). */ + lj_assertA(irt_isguard(ir->t) || !(ir->op2 & IRSLOAD_TYPECHECK), + "inconsistent SLOAD variant"); + lj_assertA(LJ_DUALNUM || + !irt_isint(t) || + (ir->op2 & (IRSLOAD_CONVERT|IRSLOAD_FRAME|IRSLOAD_KEYINDEX)), + "bad SLOAD type"); +#if LJ_SOFTFP + lj_assertA(!(ir->op2 & IRSLOAD_CONVERT), + "unsplit SLOAD convert"); /* Handled by LJ_SOFTFP SPLIT. */ + if (hiop && ra_used(ir+1)) { + type = ra_dest(as, ir+1, allow); + rset_clear(allow, type); + } +#else + if ((ir->op2 & IRSLOAD_CONVERT) && irt_isguard(t) && irt_isint(t)) { + dest = ra_scratch(as, RSET_FPR); + asm_tointg(as, ir, dest); + t.irt = IRT_NUM; /* Continue with a regular number type check. */ + } else +#endif + if (ra_used(ir)) { + lj_assertA(irt_isnum(t) || irt_isint(t) || irt_isaddr(t), + "bad SLOAD type %d", irt_type(ir->t)); + dest = ra_dest(as, ir, (!LJ_SOFTFP && irt_isnum(t)) ? RSET_FPR : allow); + rset_clear(allow, dest); + base = ra_alloc1(as, REF_BASE, allow); + rset_clear(allow, base); + if (!LJ_SOFTFP && (ir->op2 & IRSLOAD_CONVERT)) { + if (irt_isint(t)) { + emit_tai(as, PPCI_LWZ, dest, RID_SP, SPOFS_TMPLO); + dest = ra_scratch(as, RSET_FPR); + emit_fai(as, PPCI_STFD, dest, RID_SP, SPOFS_TMP); + emit_fb(as, PPCI_FCTIWZ, dest, dest); + t.irt = IRT_NUM; /* Check for original type. */ + } else { + Reg tmp = ra_scratch(as, allow); + Reg hibias = ra_allock(as, 0x43300000, rset_clear(allow, tmp)); + Reg fbias = ra_scratch(as, rset_exclude(RSET_FPR, dest)); + emit_fab(as, PPCI_FSUB, dest, dest, fbias); + emit_fai(as, PPCI_LFD, dest, RID_SP, SPOFS_TMP); + emit_lsptr(as, PPCI_LFS, (fbias & 31), + (void *)&as->J->k32[LJ_K32_2P52_2P31], + rset_clear(allow, hibias)); + emit_tai(as, PPCI_STW, tmp, RID_SP, SPOFS_TMPLO); + emit_tai(as, PPCI_STW, hibias, RID_SP, SPOFS_TMPHI); + emit_asi(as, PPCI_XORIS, tmp, tmp, 0x8000); + dest = tmp; + t.irt = IRT_INT; /* Check for original type. */ + } + } + goto dotypecheck; + } + base = ra_alloc1(as, REF_BASE, allow); + rset_clear(allow, base); +dotypecheck: + if (irt_isnum(t)) { + if ((ir->op2 & IRSLOAD_TYPECHECK)) { + Reg tisnum = ra_allock(as, (int32_t)LJ_TISNUM, allow); + asm_guardcc(as, CC_GE); +#if !LJ_SOFTFP + type = RID_TMP; +#endif + emit_ab(as, PPCI_CMPLW, type, tisnum); + } + if (ra_hasreg(dest)) emit_fai(as, LJ_SOFTFP ? PPCI_LWZ : PPCI_LFD, dest, + base, ofs-(LJ_SOFTFP?0:4)); + } else { + if ((ir->op2 & IRSLOAD_TYPECHECK)) { + asm_guardcc(as, CC_NE); + if ((ir->op2 & IRSLOAD_KEYINDEX)) { + emit_ai(as, PPCI_CMPWI, RID_TMP, (LJ_KEYINDEX & 0xffff)); + emit_asi(as, PPCI_XORIS, RID_TMP, RID_TMP, (LJ_KEYINDEX >> 16)); + } else { + emit_ai(as, PPCI_CMPWI, RID_TMP, irt_toitype(t)); + } + type = RID_TMP; + } + if (ra_hasreg(dest)) emit_tai(as, PPCI_LWZ, dest, base, ofs); + } + if (ra_hasreg(type)) emit_tai(as, PPCI_LWZ, type, base, ofs-4); +} + +/* -- Allocations --------------------------------------------------------- */ + +#if LJ_HASFFI +static void asm_cnew(ASMState *as, IRIns *ir) +{ + CTState *cts = ctype_ctsG(J2G(as->J)); + CTypeID id = (CTypeID)IR(ir->op1)->i; + CTSize sz; + CTInfo info = lj_ctype_info(cts, id, &sz); + const CCallInfo *ci = &lj_ir_callinfo[IRCALL_lj_mem_newgco]; + IRRef args[4]; + RegSet drop = RSET_SCRATCH; + lj_assertA(sz != CTSIZE_INVALID || (ir->o == IR_CNEW && ir->op2 != REF_NIL), + "bad CNEW/CNEWI operands"); + + as->gcsteps++; + if (ra_hasreg(ir->r)) + rset_clear(drop, ir->r); /* Dest reg handled below. */ + ra_evictset(as, drop); + if (ra_used(ir)) + ra_destreg(as, ir, RID_RET); /* GCcdata * */ + + /* Initialize immutable cdata object. */ + if (ir->o == IR_CNEWI) { + RegSet allow = (RSET_GPR & ~RSET_SCRATCH); + int32_t ofs = sizeof(GCcdata); + lj_assertA(sz == 4 || sz == 8, "bad CNEWI size %d", sz); + if (sz == 8) { + ofs += 4; + lj_assertA((ir+1)->o == IR_HIOP, "expected HIOP for CNEWI"); + } + for (;;) { + Reg r = ra_alloc1(as, ir->op2, allow); + emit_tai(as, PPCI_STW, r, RID_RET, ofs); + rset_clear(allow, r); + if (ofs == sizeof(GCcdata)) break; + ofs -= 4; ir++; + } + } else if (ir->op2 != REF_NIL) { /* Create VLA/VLS/aligned cdata. */ + ci = &lj_ir_callinfo[IRCALL_lj_cdata_newv]; + args[0] = ASMREF_L; /* lua_State *L */ + args[1] = ir->op1; /* CTypeID id */ + args[2] = ir->op2; /* CTSize sz */ + args[3] = ASMREF_TMP1; /* CTSize align */ + asm_gencall(as, ci, args); + emit_loadi(as, ra_releasetmp(as, ASMREF_TMP1), (int32_t)ctype_align(info)); + return; + } + + /* Initialize gct and ctypeid. lj_mem_newgco() already sets marked. */ + emit_tai(as, PPCI_STB, RID_RET+1, RID_RET, offsetof(GCcdata, gct)); + emit_tai(as, PPCI_STH, RID_TMP, RID_RET, offsetof(GCcdata, ctypeid)); + emit_ti(as, PPCI_LI, RID_RET+1, ~LJ_TCDATA); + emit_ti(as, PPCI_LI, RID_TMP, id); /* Lower 16 bit used. Sign-ext ok. */ + args[0] = ASMREF_L; /* lua_State *L */ + args[1] = ASMREF_TMP1; /* MSize size */ + asm_gencall(as, ci, args); + ra_allockreg(as, (int32_t)(sz+sizeof(GCcdata)), + ra_releasetmp(as, ASMREF_TMP1)); +} +#endif + +/* -- Write barriers ------------------------------------------------------ */ + +static void asm_tbar(ASMState *as, IRIns *ir) +{ + Reg tab = ra_alloc1(as, ir->op1, RSET_GPR); + Reg mark = ra_scratch(as, rset_exclude(RSET_GPR, tab)); + Reg link = RID_TMP; + MCLabel l_end = emit_label(as); + emit_tai(as, PPCI_STW, link, tab, (int32_t)offsetof(GCtab, gclist)); + emit_tai(as, PPCI_STB, mark, tab, (int32_t)offsetof(GCtab, marked)); + emit_setgl(as, tab, gc.grayagain); + lj_assertA(LJ_GC_BLACK == 0x04, "bad LJ_GC_BLACK"); + emit_rot(as, PPCI_RLWINM, mark, mark, 0, 30, 28); /* Clear black bit. */ + emit_getgl(as, link, gc.grayagain); + emit_condbranch(as, PPCI_BC|PPCF_Y, CC_EQ, l_end); + emit_asi(as, PPCI_ANDIDOT, RID_TMP, mark, LJ_GC_BLACK); + emit_tai(as, PPCI_LBZ, mark, tab, (int32_t)offsetof(GCtab, marked)); +} + +static void asm_obar(ASMState *as, IRIns *ir) +{ + const CCallInfo *ci = &lj_ir_callinfo[IRCALL_lj_gc_barrieruv]; + IRRef args[2]; + MCLabel l_end; + Reg obj, val, tmp; + /* No need for other object barriers (yet). */ + lj_assertA(IR(ir->op1)->o == IR_UREFC, "bad OBAR type"); + ra_evictset(as, RSET_SCRATCH); + l_end = emit_label(as); + args[0] = ASMREF_TMP1; /* global_State *g */ + args[1] = ir->op1; /* TValue *tv */ + asm_gencall(as, ci, args); + emit_tai(as, PPCI_ADDI, ra_releasetmp(as, ASMREF_TMP1), RID_JGL, -32768); + obj = IR(ir->op1)->r; + tmp = ra_scratch(as, rset_exclude(RSET_GPR, obj)); + emit_condbranch(as, PPCI_BC|PPCF_Y, CC_EQ, l_end); + emit_asi(as, PPCI_ANDIDOT, tmp, tmp, LJ_GC_BLACK); + emit_condbranch(as, PPCI_BC, CC_EQ, l_end); + emit_asi(as, PPCI_ANDIDOT, RID_TMP, RID_TMP, LJ_GC_WHITES); + val = ra_alloc1(as, ir->op2, rset_exclude(RSET_GPR, obj)); + emit_tai(as, PPCI_LBZ, tmp, obj, + (int32_t)offsetof(GCupval, marked)-(int32_t)offsetof(GCupval, tv)); + emit_tai(as, PPCI_LBZ, RID_TMP, val, (int32_t)offsetof(GChead, marked)); +} + +/* -- Arithmetic and logic operations ------------------------------------- */ + +#if !LJ_SOFTFP +static void asm_fparith(ASMState *as, IRIns *ir, PPCIns pi) +{ + Reg dest = ra_dest(as, ir, RSET_FPR); + Reg right, left = ra_alloc2(as, ir, RSET_FPR); + right = (left >> 8); left &= 255; + if (pi == PPCI_FMUL) + emit_fac(as, pi, dest, left, right); + else + emit_fab(as, pi, dest, left, right); +} + +static void asm_fpunary(ASMState *as, IRIns *ir, PPCIns pi) +{ + Reg dest = ra_dest(as, ir, RSET_FPR); + Reg left = ra_hintalloc(as, ir->op1, dest, RSET_FPR); + emit_fb(as, pi, dest, left); +} + +static void asm_fpmath(ASMState *as, IRIns *ir) +{ + if (ir->op2 == IRFPM_SQRT && (as->flags & JIT_F_SQRT)) + asm_fpunary(as, ir, PPCI_FSQRT); + else + asm_callid(as, ir, IRCALL_lj_vm_floor + ir->op2); +} +#endif + +static void asm_add(ASMState *as, IRIns *ir) +{ +#if !LJ_SOFTFP + if (irt_isnum(ir->t)) { + if (!asm_fusemadd(as, ir, PPCI_FMADD, PPCI_FMADD)) + asm_fparith(as, ir, PPCI_FADD); + } else +#endif + { + Reg dest = ra_dest(as, ir, RSET_GPR); + Reg right, left = ra_hintalloc(as, ir->op1, dest, RSET_GPR); + PPCIns pi; + if (irref_isk(ir->op2)) { + int32_t k = IR(ir->op2)->i; + if (checki16(k)) { + pi = PPCI_ADDI; + /* May fail due to spills/restores above, but simplifies the logic. */ + if (as->flagmcp == as->mcp) { + as->flagmcp = NULL; + as->mcp++; + pi = PPCI_ADDICDOT; + } + emit_tai(as, pi, dest, left, k); + return; + } else if ((k & 0xffff) == 0) { + emit_tai(as, PPCI_ADDIS, dest, left, (k >> 16)); + return; + } else if (!as->sectref) { + emit_tai(as, PPCI_ADDIS, dest, dest, (k + 32768) >> 16); + emit_tai(as, PPCI_ADDI, dest, left, k); + return; + } + } + pi = PPCI_ADD; + /* May fail due to spills/restores above, but simplifies the logic. */ + if (as->flagmcp == as->mcp) { + as->flagmcp = NULL; + as->mcp++; + pi |= PPCF_DOT; + } + right = ra_alloc1(as, ir->op2, rset_exclude(RSET_GPR, left)); + emit_tab(as, pi, dest, left, right); + } +} + +static void asm_sub(ASMState *as, IRIns *ir) +{ +#if !LJ_SOFTFP + if (irt_isnum(ir->t)) { + if (!asm_fusemadd(as, ir, PPCI_FMSUB, PPCI_FNMSUB)) + asm_fparith(as, ir, PPCI_FSUB); + } else +#endif + { + PPCIns pi = PPCI_SUBF; + Reg dest = ra_dest(as, ir, RSET_GPR); + Reg left, right; + if (irref_isk(ir->op1)) { + int32_t k = IR(ir->op1)->i; + if (checki16(k)) { + right = ra_alloc1(as, ir->op2, RSET_GPR); + emit_tai(as, PPCI_SUBFIC, dest, right, k); + return; + } + } + /* May fail due to spills/restores above, but simplifies the logic. */ + if (as->flagmcp == as->mcp) { + as->flagmcp = NULL; + as->mcp++; + pi |= PPCF_DOT; + } + left = ra_hintalloc(as, ir->op1, dest, RSET_GPR); + right = ra_alloc1(as, ir->op2, rset_exclude(RSET_GPR, left)); + emit_tab(as, pi, dest, right, left); /* Subtract right _from_ left. */ + } +} + +static void asm_mul(ASMState *as, IRIns *ir) +{ +#if !LJ_SOFTFP + if (irt_isnum(ir->t)) { + asm_fparith(as, ir, PPCI_FMUL); + } else +#endif + { + PPCIns pi = PPCI_MULLW; + Reg dest = ra_dest(as, ir, RSET_GPR); + Reg right, left = ra_hintalloc(as, ir->op1, dest, RSET_GPR); + if (irref_isk(ir->op2)) { + int32_t k = IR(ir->op2)->i; + if (checki16(k)) { + emit_tai(as, PPCI_MULLI, dest, left, k); + return; + } + } + /* May fail due to spills/restores above, but simplifies the logic. */ + if (as->flagmcp == as->mcp) { + as->flagmcp = NULL; + as->mcp++; + pi |= PPCF_DOT; + } + right = ra_alloc1(as, ir->op2, rset_exclude(RSET_GPR, left)); + emit_tab(as, pi, dest, left, right); + } +} + +#define asm_fpdiv(as, ir) asm_fparith(as, ir, PPCI_FDIV) + +static void asm_neg(ASMState *as, IRIns *ir) +{ +#if !LJ_SOFTFP + if (irt_isnum(ir->t)) { + asm_fpunary(as, ir, PPCI_FNEG); + } else +#endif + { + Reg dest, left; + PPCIns pi = PPCI_NEG; + if (as->flagmcp == as->mcp) { + as->flagmcp = NULL; + as->mcp++; + pi |= PPCF_DOT; + } + dest = ra_dest(as, ir, RSET_GPR); + left = ra_hintalloc(as, ir->op1, dest, RSET_GPR); + emit_tab(as, pi, dest, left, 0); + } +} + +#define asm_abs(as, ir) asm_fpunary(as, ir, PPCI_FABS) + +static void asm_arithov(ASMState *as, IRIns *ir, PPCIns pi) +{ + Reg dest, left, right; + if (as->flagmcp == as->mcp) { + as->flagmcp = NULL; + as->mcp++; + } + asm_guardcc(as, CC_SO); + dest = ra_dest(as, ir, RSET_GPR); + left = ra_alloc2(as, ir, RSET_GPR); + right = (left >> 8); left &= 255; + if (pi == PPCI_SUBFO) { Reg tmp = left; left = right; right = tmp; } + emit_tab(as, pi|PPCF_DOT, dest, left, right); +} + +#define asm_addov(as, ir) asm_arithov(as, ir, PPCI_ADDO) +#define asm_subov(as, ir) asm_arithov(as, ir, PPCI_SUBFO) +#define asm_mulov(as, ir) asm_arithov(as, ir, PPCI_MULLWO) + +#if LJ_HASFFI +static void asm_add64(ASMState *as, IRIns *ir) +{ + Reg dest = ra_dest(as, ir, RSET_GPR); + Reg right, left = ra_alloc1(as, ir->op1, RSET_GPR); + PPCIns pi = PPCI_ADDE; + if (irref_isk(ir->op2)) { + int32_t k = IR(ir->op2)->i; + if (k == 0) + pi = PPCI_ADDZE; + else if (k == -1) + pi = PPCI_ADDME; + else + goto needright; + right = 0; + } else { + needright: + right = ra_alloc1(as, ir->op2, rset_exclude(RSET_GPR, left)); + } + emit_tab(as, pi, dest, left, right); + ir--; + dest = ra_dest(as, ir, RSET_GPR); + left = ra_alloc1(as, ir->op1, RSET_GPR); + if (irref_isk(ir->op2)) { + int32_t k = IR(ir->op2)->i; + if (checki16(k)) { + emit_tai(as, PPCI_ADDIC, dest, left, k); + return; + } + } + right = ra_alloc1(as, ir->op2, rset_exclude(RSET_GPR, left)); + emit_tab(as, PPCI_ADDC, dest, left, right); +} + +static void asm_sub64(ASMState *as, IRIns *ir) +{ + Reg dest = ra_dest(as, ir, RSET_GPR); + Reg left, right = ra_alloc1(as, ir->op2, RSET_GPR); + PPCIns pi = PPCI_SUBFE; + if (irref_isk(ir->op1)) { + int32_t k = IR(ir->op1)->i; + if (k == 0) + pi = PPCI_SUBFZE; + else if (k == -1) + pi = PPCI_SUBFME; + else + goto needleft; + left = 0; + } else { + needleft: + left = ra_alloc1(as, ir->op1, rset_exclude(RSET_GPR, right)); + } + emit_tab(as, pi, dest, right, left); /* Subtract right _from_ left. */ + ir--; + dest = ra_dest(as, ir, RSET_GPR); + right = ra_alloc1(as, ir->op2, RSET_GPR); + if (irref_isk(ir->op1)) { + int32_t k = IR(ir->op1)->i; + if (checki16(k)) { + emit_tai(as, PPCI_SUBFIC, dest, right, k); + return; + } + } + left = ra_alloc1(as, ir->op1, rset_exclude(RSET_GPR, right)); + emit_tab(as, PPCI_SUBFC, dest, right, left); +} + +static void asm_neg64(ASMState *as, IRIns *ir) +{ + Reg dest = ra_dest(as, ir, RSET_GPR); + Reg left = ra_alloc1(as, ir->op1, RSET_GPR); + emit_tab(as, PPCI_SUBFZE, dest, left, 0); + ir--; + dest = ra_dest(as, ir, RSET_GPR); + left = ra_alloc1(as, ir->op1, RSET_GPR); + emit_tai(as, PPCI_SUBFIC, dest, left, 0); +} +#endif + +static void asm_bnot(ASMState *as, IRIns *ir) +{ + Reg dest, left, right; + PPCIns pi = PPCI_NOR; + if (as->flagmcp == as->mcp) { + as->flagmcp = NULL; + as->mcp++; + pi |= PPCF_DOT; + } + dest = ra_dest(as, ir, RSET_GPR); + if (mayfuse(as, ir->op1)) { + IRIns *irl = IR(ir->op1); + if (irl->o == IR_BAND) + pi ^= (PPCI_NOR ^ PPCI_NAND); + else if (irl->o == IR_BXOR) + pi ^= (PPCI_NOR ^ PPCI_EQV); + else if (irl->o != IR_BOR) + goto nofuse; + left = ra_hintalloc(as, irl->op1, dest, RSET_GPR); + right = ra_alloc1(as, irl->op2, rset_exclude(RSET_GPR, left)); + } else { +nofuse: + left = right = ra_hintalloc(as, ir->op1, dest, RSET_GPR); + } + emit_asb(as, pi, dest, left, right); +} + +static void asm_bswap(ASMState *as, IRIns *ir) +{ + Reg dest = ra_dest(as, ir, RSET_GPR); + IRIns *irx; + if (mayfuse(as, ir->op1) && (irx = IR(ir->op1))->o == IR_XLOAD && + ra_noreg(irx->r) && (irt_isint(irx->t) || irt_isu32(irx->t))) { + /* Fuse BSWAP with XLOAD to lwbrx. */ + asm_fusexrefx(as, PPCI_LWBRX, dest, irx->op1, RSET_GPR); + } else { + Reg left = ra_alloc1(as, ir->op1, RSET_GPR); + Reg tmp = dest; + if (tmp == left) { + tmp = RID_TMP; + emit_mr(as, dest, RID_TMP); + } + emit_rot(as, PPCI_RLWIMI, tmp, left, 24, 16, 23); + emit_rot(as, PPCI_RLWIMI, tmp, left, 24, 0, 7); + emit_rotlwi(as, tmp, left, 8); + } +} + +/* Fuse BAND with contiguous bitmask and a shift to rlwinm. */ +static void asm_fuseandsh(ASMState *as, PPCIns pi, int32_t mask, IRRef ref) +{ + IRIns *ir; + Reg left; + if (mayfuse(as, ref) && (ir = IR(ref), ra_noreg(ir->r)) && + irref_isk(ir->op2) && ir->o >= IR_BSHL && ir->o <= IR_BROR) { + int32_t sh = (IR(ir->op2)->i & 31); + switch (ir->o) { + case IR_BSHL: + if ((mask & ((1u<>sh))) goto nofuse; + sh = ((32-sh)&31); + break; + case IR_BROL: + break; + default: + goto nofuse; + } + left = ra_alloc1(as, ir->op1, RSET_GPR); + *--as->mcp = pi | PPCF_T(left) | PPCF_B(sh); + return; + } +nofuse: + left = ra_alloc1(as, ref, RSET_GPR); + *--as->mcp = pi | PPCF_T(left); +} + +static void asm_band(ASMState *as, IRIns *ir) +{ + Reg dest, left, right; + IRRef lref = ir->op1; + PPCIns dot = 0; + IRRef op2; + if (as->flagmcp == as->mcp) { + as->flagmcp = NULL; + as->mcp++; + dot = PPCF_DOT; + } + dest = ra_dest(as, ir, RSET_GPR); + if (irref_isk(ir->op2)) { + int32_t k = IR(ir->op2)->i; + if (k) { + /* First check for a contiguous bitmask as used by rlwinm. */ + uint32_t s1 = lj_ffs((uint32_t)k); + uint32_t k1 = ((uint32_t)k >> s1); + if ((k1 & (k1+1)) == 0) { + asm_fuseandsh(as, PPCI_RLWINM|dot | PPCF_A(dest) | + PPCF_MB(31-lj_fls((uint32_t)k)) | PPCF_ME(31-s1), + k, lref); + return; + } + if (~(uint32_t)k) { + uint32_t s2 = lj_ffs(~(uint32_t)k); + uint32_t k2 = (~(uint32_t)k >> s2); + if ((k2 & (k2+1)) == 0) { + asm_fuseandsh(as, PPCI_RLWINM|dot | PPCF_A(dest) | + PPCF_MB(32-s2) | PPCF_ME(30-lj_fls(~(uint32_t)k)), + k, lref); + return; + } + } + } + if (checku16(k)) { + left = ra_alloc1(as, lref, RSET_GPR); + emit_asi(as, PPCI_ANDIDOT, dest, left, k); + return; + } else if ((k & 0xffff) == 0) { + left = ra_alloc1(as, lref, RSET_GPR); + emit_asi(as, PPCI_ANDISDOT, dest, left, (k >> 16)); + return; + } + } + op2 = ir->op2; + if (mayfuse(as, op2) && IR(op2)->o == IR_BNOT && ra_noreg(IR(op2)->r)) { + dot ^= (PPCI_AND ^ PPCI_ANDC); + op2 = IR(op2)->op1; + } + left = ra_hintalloc(as, lref, dest, RSET_GPR); + right = ra_alloc1(as, op2, rset_exclude(RSET_GPR, left)); + emit_asb(as, PPCI_AND ^ dot, dest, left, right); +} + +static void asm_bitop(ASMState *as, IRIns *ir, PPCIns pi, PPCIns pik) +{ + Reg dest = ra_dest(as, ir, RSET_GPR); + Reg right, left = ra_hintalloc(as, ir->op1, dest, RSET_GPR); + if (irref_isk(ir->op2)) { + int32_t k = IR(ir->op2)->i; + Reg tmp = left; + if ((checku16(k) || (k & 0xffff) == 0) || (tmp = dest, !as->sectref)) { + if (!checku16(k)) { + emit_asi(as, pik ^ (PPCI_ORI ^ PPCI_ORIS), dest, tmp, (k >> 16)); + if ((k & 0xffff) == 0) return; + } + emit_asi(as, pik, dest, left, k); + return; + } + } + /* May fail due to spills/restores above, but simplifies the logic. */ + if (as->flagmcp == as->mcp) { + as->flagmcp = NULL; + as->mcp++; + pi |= PPCF_DOT; + } + right = ra_alloc1(as, ir->op2, rset_exclude(RSET_GPR, left)); + emit_asb(as, pi, dest, left, right); +} + +#define asm_bor(as, ir) asm_bitop(as, ir, PPCI_OR, PPCI_ORI) +#define asm_bxor(as, ir) asm_bitop(as, ir, PPCI_XOR, PPCI_XORI) + +static void asm_bitshift(ASMState *as, IRIns *ir, PPCIns pi, PPCIns pik) +{ + Reg dest, left; + Reg dot = 0; + if (as->flagmcp == as->mcp) { + as->flagmcp = NULL; + as->mcp++; + dot = PPCF_DOT; + } + dest = ra_dest(as, ir, RSET_GPR); + left = ra_alloc1(as, ir->op1, RSET_GPR); + if (irref_isk(ir->op2)) { /* Constant shifts. */ + int32_t shift = (IR(ir->op2)->i & 31); + if (pik == 0) /* SLWI */ + emit_rot(as, PPCI_RLWINM|dot, dest, left, shift, 0, 31-shift); + else if (pik == 1) /* SRWI */ + emit_rot(as, PPCI_RLWINM|dot, dest, left, (32-shift)&31, shift, 31); + else + emit_asb(as, pik|dot, dest, left, shift); + } else { + Reg right = ra_alloc1(as, ir->op2, rset_exclude(RSET_GPR, left)); + emit_asb(as, pi|dot, dest, left, right); + } +} + +#define asm_bshl(as, ir) asm_bitshift(as, ir, PPCI_SLW, 0) +#define asm_bshr(as, ir) asm_bitshift(as, ir, PPCI_SRW, 1) +#define asm_bsar(as, ir) asm_bitshift(as, ir, PPCI_SRAW, PPCI_SRAWI) +#define asm_brol(as, ir) \ + asm_bitshift(as, ir, PPCI_RLWNM|PPCF_MB(0)|PPCF_ME(31), \ + PPCI_RLWINM|PPCF_MB(0)|PPCF_ME(31)) +#define asm_bror(as, ir) lj_assertA(0, "unexpected BROR") + +#if LJ_SOFTFP +static void asm_sfpmin_max(ASMState *as, IRIns *ir) +{ + CCallInfo ci = lj_ir_callinfo[IRCALL_softfp_cmp]; + IRRef args[4]; + MCLabel l_right, l_end; + Reg desthi = ra_dest(as, ir, RSET_GPR), destlo = ra_dest(as, ir+1, RSET_GPR); + Reg righthi, lefthi = ra_alloc2(as, ir, RSET_GPR); + Reg rightlo, leftlo = ra_alloc2(as, ir+1, RSET_GPR); + PPCCC cond = (IROp)ir->o == IR_MIN ? CC_EQ : CC_NE; + righthi = (lefthi >> 8); lefthi &= 255; + rightlo = (leftlo >> 8); leftlo &= 255; + args[0^LJ_BE] = ir->op1; args[1^LJ_BE] = (ir+1)->op1; + args[2^LJ_BE] = ir->op2; args[3^LJ_BE] = (ir+1)->op2; + l_end = emit_label(as); + if (desthi != righthi) emit_mr(as, desthi, righthi); + if (destlo != rightlo) emit_mr(as, destlo, rightlo); + l_right = emit_label(as); + if (l_end != l_right) emit_jmp(as, l_end); + if (desthi != lefthi) emit_mr(as, desthi, lefthi); + if (destlo != leftlo) emit_mr(as, destlo, leftlo); + if (l_right == as->mcp+1) { + cond ^= 4; l_right = l_end; ++as->mcp; + } + emit_condbranch(as, PPCI_BC, cond, l_right); + ra_evictset(as, RSET_SCRATCH); + emit_cmpi(as, RID_RET, 1); + asm_gencall(as, &ci, args); +} +#endif + +static void asm_min_max(ASMState *as, IRIns *ir, int ismax) +{ + if (!LJ_SOFTFP && irt_isnum(ir->t)) { + Reg dest = ra_dest(as, ir, RSET_FPR); + Reg tmp = dest; + Reg right, left = ra_alloc2(as, ir, RSET_FPR); + right = (left >> 8); left &= 255; + if (tmp == left || tmp == right) + tmp = ra_scratch(as, rset_exclude(rset_exclude(rset_exclude(RSET_FPR, + dest), left), right)); + emit_facb(as, PPCI_FSEL, dest, tmp, left, right); + emit_fab(as, PPCI_FSUB, tmp, ismax ? left : right, ismax ? right : left); + } else { + Reg dest = ra_dest(as, ir, RSET_GPR); + Reg tmp1 = RID_TMP, tmp2 = dest; + Reg right, left = ra_alloc2(as, ir, RSET_GPR); + right = (left >> 8); left &= 255; + if (tmp2 == left || tmp2 == right) + tmp2 = ra_scratch(as, rset_exclude(rset_exclude(rset_exclude(RSET_GPR, + dest), left), right)); + emit_tab(as, PPCI_ADD, dest, tmp2, right); + emit_asb(as, ismax ? PPCI_ANDC : PPCI_AND, tmp2, tmp2, tmp1); + emit_tab(as, PPCI_SUBFE, tmp1, tmp1, tmp1); + emit_tab(as, PPCI_SUBFC, tmp2, tmp2, tmp1); + emit_asi(as, PPCI_XORIS, tmp2, right, 0x8000); + emit_asi(as, PPCI_XORIS, tmp1, left, 0x8000); + } +} + +#define asm_min(as, ir) asm_min_max(as, ir, 0) +#define asm_max(as, ir) asm_min_max(as, ir, 1) + +/* -- Comparisons --------------------------------------------------------- */ + +#define CC_UNSIGNED 0x08 /* Unsigned integer comparison. */ +#define CC_TWO 0x80 /* Check two flags for FP comparison. */ + +/* Map of comparisons to flags. ORDER IR. */ +static const uint8_t asm_compmap[IR_ABC+1] = { + /* op int cc FP cc */ + /* LT */ CC_GE + (CC_GE<<4), + /* GE */ CC_LT + (CC_LE<<4) + CC_TWO, + /* LE */ CC_GT + (CC_GE<<4) + CC_TWO, + /* GT */ CC_LE + (CC_LE<<4), + /* ULT */ CC_GE + CC_UNSIGNED + (CC_GT<<4) + CC_TWO, + /* UGE */ CC_LT + CC_UNSIGNED + (CC_LT<<4), + /* ULE */ CC_GT + CC_UNSIGNED + (CC_GT<<4), + /* UGT */ CC_LE + CC_UNSIGNED + (CC_LT<<4) + CC_TWO, + /* EQ */ CC_NE + (CC_NE<<4), + /* NE */ CC_EQ + (CC_EQ<<4), + /* ABC */ CC_LE + CC_UNSIGNED + (CC_LT<<4) + CC_TWO /* Same as UGT. */ +}; + +static void asm_intcomp_(ASMState *as, IRRef lref, IRRef rref, Reg cr, PPCCC cc) +{ + Reg right, left = ra_alloc1(as, lref, RSET_GPR); + if (irref_isk(rref)) { + int32_t k = IR(rref)->i; + if ((cc & CC_UNSIGNED) == 0) { /* Signed comparison with constant. */ + if (checki16(k)) { + emit_tai(as, PPCI_CMPWI, cr, left, k); + /* Signed comparison with zero and referencing previous ins? */ + if (k == 0 && lref == as->curins-1) + as->flagmcp = as->mcp; /* Allow elimination of the compare. */ + return; + } else if ((cc & 3) == (CC_EQ & 3)) { /* Use CMPLWI for EQ or NE. */ + if (checku16(k)) { + emit_tai(as, PPCI_CMPLWI, cr, left, k); + return; + } else if (!as->sectref && ra_noreg(IR(rref)->r)) { + emit_tai(as, PPCI_CMPLWI, cr, RID_TMP, k); + emit_asi(as, PPCI_XORIS, RID_TMP, left, (k >> 16)); + return; + } + } + } else { /* Unsigned comparison with constant. */ + if (checku16(k)) { + emit_tai(as, PPCI_CMPLWI, cr, left, k); + return; + } + } + } + right = ra_alloc1(as, rref, rset_exclude(RSET_GPR, left)); + emit_tab(as, (cc & CC_UNSIGNED) ? PPCI_CMPLW : PPCI_CMPW, cr, left, right); +} + +static void asm_comp(ASMState *as, IRIns *ir) +{ + PPCCC cc = asm_compmap[ir->o]; + if (!LJ_SOFTFP && irt_isnum(ir->t)) { + Reg right, left = ra_alloc2(as, ir, RSET_FPR); + right = (left >> 8); left &= 255; + asm_guardcc(as, (cc >> 4)); + if ((cc & CC_TWO)) + emit_tab(as, PPCI_CROR, ((cc>>4)&3), ((cc>>4)&3), (CC_EQ&3)); + emit_fab(as, PPCI_FCMPU, 0, left, right); + } else { + IRRef lref = ir->op1, rref = ir->op2; + if (irref_isk(lref) && !irref_isk(rref)) { + /* Swap constants to the right (only for ABC). */ + IRRef tmp = lref; lref = rref; rref = tmp; + if ((cc & 2) == 0) cc ^= 1; /* LT <-> GT, LE <-> GE */ + } + asm_guardcc(as, cc); + asm_intcomp_(as, lref, rref, 0, cc); + } +} + +#define asm_equal(as, ir) asm_comp(as, ir) + +#if LJ_SOFTFP +/* SFP comparisons. */ +static void asm_sfpcomp(ASMState *as, IRIns *ir) +{ + const CCallInfo *ci = &lj_ir_callinfo[IRCALL_softfp_cmp]; + RegSet drop = RSET_SCRATCH; + Reg r; + IRRef args[4]; + args[0^LJ_BE] = ir->op1; args[1^LJ_BE] = (ir+1)->op1; + args[2^LJ_BE] = ir->op2; args[3^LJ_BE] = (ir+1)->op2; + + for (r = REGARG_FIRSTGPR; r <= REGARG_FIRSTGPR+3; r++) { + if (!rset_test(as->freeset, r) && + regcost_ref(as->cost[r]) == args[r-REGARG_FIRSTGPR]) + rset_clear(drop, r); + } + ra_evictset(as, drop); + asm_setupresult(as, ir, ci); + switch ((IROp)ir->o) { + case IR_ULT: + asm_guardcc(as, CC_EQ); + emit_ai(as, PPCI_CMPWI, RID_RET, 0); + case IR_ULE: + asm_guardcc(as, CC_EQ); + emit_ai(as, PPCI_CMPWI, RID_RET, 1); + break; + case IR_GE: case IR_GT: + asm_guardcc(as, CC_EQ); + emit_ai(as, PPCI_CMPWI, RID_RET, 2); + default: + asm_guardcc(as, (asm_compmap[ir->o] & 0xf)); + emit_ai(as, PPCI_CMPWI, RID_RET, 0); + break; + } + asm_gencall(as, ci, args); +} +#endif + +#if LJ_HASFFI +/* 64 bit integer comparisons. */ +static void asm_comp64(ASMState *as, IRIns *ir) +{ + PPCCC cc = asm_compmap[(ir-1)->o]; + if ((cc&3) == (CC_EQ&3)) { + asm_guardcc(as, cc); + emit_tab(as, (cc&4) ? PPCI_CRAND : PPCI_CROR, + (CC_EQ&3), (CC_EQ&3), 4+(CC_EQ&3)); + } else { + asm_guardcc(as, CC_EQ); + emit_tab(as, PPCI_CROR, (CC_EQ&3), (CC_EQ&3), ((cc^~(cc>>2))&1)); + emit_tab(as, (cc&4) ? PPCI_CRAND : PPCI_CRANDC, + (CC_EQ&3), (CC_EQ&3), 4+(cc&3)); + } + /* Loword comparison sets cr1 and is unsigned, except for equality. */ + asm_intcomp_(as, (ir-1)->op1, (ir-1)->op2, 4, + cc | ((cc&3) == (CC_EQ&3) ? 0 : CC_UNSIGNED)); + /* Hiword comparison sets cr0. */ + asm_intcomp_(as, ir->op1, ir->op2, 0, cc); + as->flagmcp = NULL; /* Doesn't work here. */ +} +#endif + +/* -- Split register ops -------------------------------------------------- */ + +/* Hiword op of a split 32/32 bit op. Previous op is be the loword op. */ +static void asm_hiop(ASMState *as, IRIns *ir) +{ + /* HIOP is marked as a store because it needs its own DCE logic. */ + int uselo = ra_used(ir-1), usehi = ra_used(ir); /* Loword/hiword used? */ + if (LJ_UNLIKELY(!(as->flags & JIT_F_OPT_DCE))) uselo = usehi = 1; +#if LJ_HASFFI || LJ_SOFTFP + if ((ir-1)->o == IR_CONV) { /* Conversions to/from 64 bit. */ + as->curins--; /* Always skip the CONV. */ +#if LJ_HASFFI && !LJ_SOFTFP + if (usehi || uselo) + asm_conv64(as, ir); + return; +#endif + } else if ((ir-1)->o <= IR_NE) { /* 64 bit integer comparisons. ORDER IR. */ + as->curins--; /* Always skip the loword comparison. */ +#if LJ_SOFTFP + if (!irt_isint(ir->t)) { + asm_sfpcomp(as, ir-1); + return; + } +#endif +#if LJ_HASFFI + asm_comp64(as, ir); +#endif + return; +#if LJ_SOFTFP + } else if ((ir-1)->o == IR_MIN || (ir-1)->o == IR_MAX) { + as->curins--; /* Always skip the loword min/max. */ + if (uselo || usehi) + asm_sfpmin_max(as, ir-1); + return; +#endif + } else if ((ir-1)->o == IR_XSTORE) { + as->curins--; /* Handle both stores here. */ + if ((ir-1)->r != RID_SINK) { + asm_xstore_(as, ir, 0); + asm_xstore_(as, ir-1, 4); + } + return; + } +#endif + if (!usehi) return; /* Skip unused hiword op for all remaining ops. */ + switch ((ir-1)->o) { +#if LJ_HASFFI + case IR_ADD: as->curins--; asm_add64(as, ir); break; + case IR_SUB: as->curins--; asm_sub64(as, ir); break; + case IR_NEG: as->curins--; asm_neg64(as, ir); break; + case IR_CNEWI: + /* Nothing to do here. Handled by lo op itself. */ + break; +#endif +#if LJ_SOFTFP + case IR_SLOAD: case IR_ALOAD: case IR_HLOAD: case IR_ULOAD: case IR_VLOAD: + case IR_STRTO: + if (!uselo) + ra_allocref(as, ir->op1, RSET_GPR); /* Mark lo op as used. */ + break; + case IR_ASTORE: case IR_HSTORE: case IR_USTORE: case IR_TOSTR: case IR_TMPREF: + /* Nothing to do here. Handled by lo op itself. */ + break; +#endif + case IR_CALLN: case IR_CALLL: case IR_CALLS: case IR_CALLXS: + if (!uselo) + ra_allocref(as, ir->op1, RID2RSET(RID_RETLO)); /* Mark lo op as used. */ + break; + default: lj_assertA(0, "bad HIOP for op %d", (ir-1)->o); break; + } +} + +/* -- Profiling ----------------------------------------------------------- */ + +static void asm_prof(ASMState *as, IRIns *ir) +{ + UNUSED(ir); + asm_guardcc(as, CC_NE); + emit_asi(as, PPCI_ANDIDOT, RID_TMP, RID_TMP, HOOK_PROFILE); + emit_lsglptr(as, PPCI_LBZ, RID_TMP, + (int32_t)offsetof(global_State, hookmask)); +} + +/* -- Stack handling ------------------------------------------------------ */ + +/* Check Lua stack size for overflow. Use exit handler as fallback. */ +static void asm_stack_check(ASMState *as, BCReg topslot, + IRIns *irp, RegSet allow, ExitNo exitno) +{ + /* Try to get an unused temp. register, otherwise spill/restore RID_RET*. */ + Reg tmp, pbase = irp ? (ra_hasreg(irp->r) ? irp->r : RID_TMP) : RID_BASE; + rset_clear(allow, pbase); + tmp = allow ? rset_pickbot(allow) : + (pbase == RID_RETHI ? RID_RETLO : RID_RETHI); + emit_condbranch(as, PPCI_BC, CC_LT, asm_exitstub_addr(as, exitno)); + if (allow == RSET_EMPTY) /* Restore temp. register. */ + emit_tai(as, PPCI_LWZ, tmp, RID_SP, SPOFS_TMPW); + else + ra_modified(as, tmp); + emit_ai(as, PPCI_CMPLWI, RID_TMP, (int32_t)(8*topslot)); + emit_tab(as, PPCI_SUBF, RID_TMP, pbase, tmp); + emit_tai(as, PPCI_LWZ, tmp, tmp, offsetof(lua_State, maxstack)); + if (pbase == RID_TMP) + emit_getgl(as, RID_TMP, jit_base); + emit_getgl(as, tmp, cur_L); + if (allow == RSET_EMPTY) /* Spill temp. register. */ + emit_tai(as, PPCI_STW, tmp, RID_SP, SPOFS_TMPW); +} + +/* Restore Lua stack from on-trace state. */ +static void asm_stack_restore(ASMState *as, SnapShot *snap) +{ + SnapEntry *map = &as->T->snapmap[snap->mapofs]; + SnapEntry *flinks = &as->T->snapmap[snap_nextofs(as->T, snap)-1]; + MSize n, nent = snap->nent; + /* Store the value of all modified slots to the Lua stack. */ + for (n = 0; n < nent; n++) { + SnapEntry sn = map[n]; + BCReg s = snap_slot(sn); + int32_t ofs = 8*((int32_t)s-1); + IRRef ref = snap_ref(sn); + IRIns *ir = IR(ref); + if ((sn & SNAP_NORESTORE)) + continue; + if (irt_isnum(ir->t)) { +#if LJ_SOFTFP + Reg tmp; + RegSet allow = rset_exclude(RSET_GPR, RID_BASE); + /* LJ_SOFTFP: must be a number constant. */ + lj_assertA(irref_isk(ref), "unsplit FP op"); + tmp = ra_allock(as, (int32_t)ir_knum(ir)->u32.lo, allow); + emit_tai(as, PPCI_STW, tmp, RID_BASE, ofs+(LJ_BE?4:0)); + if (rset_test(as->freeset, tmp+1)) allow = RID2RSET(tmp+1); + tmp = ra_allock(as, (int32_t)ir_knum(ir)->u32.hi, allow); + emit_tai(as, PPCI_STW, tmp, RID_BASE, ofs+(LJ_BE?0:4)); +#else + Reg src = ra_alloc1(as, ref, RSET_FPR); + emit_fai(as, PPCI_STFD, src, RID_BASE, ofs); +#endif + } else { + Reg type; + RegSet allow = rset_exclude(RSET_GPR, RID_BASE); + lj_assertA(irt_ispri(ir->t) || irt_isaddr(ir->t) || irt_isinteger(ir->t), + "restore of IR type %d", irt_type(ir->t)); + if (!irt_ispri(ir->t)) { + Reg src = ra_alloc1(as, ref, allow); + rset_clear(allow, src); + emit_tai(as, PPCI_STW, src, RID_BASE, ofs+4); + } + if ((sn & (SNAP_CONT|SNAP_FRAME))) { + if (s == 0) continue; /* Do not overwrite link to previous frame. */ + type = ra_allock(as, (int32_t)(*flinks--), allow); +#if LJ_SOFTFP + } else if ((sn & SNAP_SOFTFPNUM)) { + type = ra_alloc1(as, ref+1, rset_exclude(RSET_GPR, RID_BASE)); +#endif + } else if ((sn & SNAP_KEYINDEX)) { + type = ra_allock(as, (int32_t)LJ_KEYINDEX, allow); + } else { + type = ra_allock(as, (int32_t)irt_toitype(ir->t), allow); + } + emit_tai(as, PPCI_STW, type, RID_BASE, ofs); + } + checkmclim(as); + } + lj_assertA(map + nent == flinks, "inconsistent frames in snapshot"); +} + +/* -- GC handling --------------------------------------------------------- */ + +/* Marker to prevent patching the GC check exit. */ +#define PPC_NOPATCH_GC_CHECK PPCI_ORIS + +/* Check GC threshold and do one or more GC steps. */ +static void asm_gc_check(ASMState *as) +{ + const CCallInfo *ci = &lj_ir_callinfo[IRCALL_lj_gc_step_jit]; + IRRef args[2]; + MCLabel l_end; + Reg tmp; + ra_evictset(as, RSET_SCRATCH); + l_end = emit_label(as); + /* Exit trace if in GCSatomic or GCSfinalize. Avoids syncing GC objects. */ + asm_guardcc(as, CC_NE); /* Assumes asm_snap_prep() already done. */ + *--as->mcp = PPC_NOPATCH_GC_CHECK; + emit_ai(as, PPCI_CMPWI, RID_RET, 0); + args[0] = ASMREF_TMP1; /* global_State *g */ + args[1] = ASMREF_TMP2; /* MSize steps */ + asm_gencall(as, ci, args); + emit_tai(as, PPCI_ADDI, ra_releasetmp(as, ASMREF_TMP1), RID_JGL, -32768); + tmp = ra_releasetmp(as, ASMREF_TMP2); + emit_loadi(as, tmp, as->gcsteps); + /* Jump around GC step if GC total < GC threshold. */ + emit_condbranch(as, PPCI_BC|PPCF_Y, CC_LT, l_end); + emit_ab(as, PPCI_CMPLW, RID_TMP, tmp); + emit_getgl(as, tmp, gc.threshold); + emit_getgl(as, RID_TMP, gc.total); + as->gcsteps = 0; + checkmclim(as); +} + +/* -- Loop handling ------------------------------------------------------- */ + +/* Fixup the loop branch. */ +static void asm_loop_fixup(ASMState *as) +{ + MCode *p = as->mctop; + MCode *target = as->mcp; + if (as->loopinv) { /* Inverted loop branch? */ + /* asm_guardcc already inverted the cond branch and patched the final b. */ + p[-2] = (p[-2] & (0xffff0000u & ~PPCF_Y)) | (((target-p+2) & 0x3fffu) << 2); + } else { + p[-1] = PPCI_B|(((target-p+1)&0x00ffffffu)<<2); + } +} + +/* Fixup the tail of the loop. */ +static void asm_loop_tail_fixup(ASMState *as) +{ + UNUSED(as); /* Nothing to do. */ +} + +/* -- Head of trace ------------------------------------------------------- */ + +/* Coalesce BASE register for a root trace. */ +static void asm_head_root_base(ASMState *as) +{ + IRIns *ir = IR(REF_BASE); + Reg r = ir->r; + if (ra_hasreg(r)) { + ra_free(as, r); + if (rset_test(as->modset, r) || irt_ismarked(ir->t)) + ir->r = RID_INIT; /* No inheritance for modified BASE register. */ + if (r != RID_BASE) + emit_mr(as, r, RID_BASE); + } +} + +/* Coalesce BASE register for a side trace. */ +static RegSet asm_head_side_base(ASMState *as, IRIns *irp, RegSet allow) +{ + IRIns *ir = IR(REF_BASE); + Reg r = ir->r; + if (ra_hasreg(r)) { + ra_free(as, r); + if (rset_test(as->modset, r) || irt_ismarked(ir->t)) + ir->r = RID_INIT; /* No inheritance for modified BASE register. */ + if (irp->r == r) { + rset_clear(allow, r); /* Mark same BASE register as coalesced. */ + } else if (ra_hasreg(irp->r) && rset_test(as->freeset, irp->r)) { + rset_clear(allow, irp->r); + emit_mr(as, r, irp->r); /* Move from coalesced parent reg. */ + } else { + emit_getgl(as, r, jit_base); /* Otherwise reload BASE. */ + } + } + return allow; +} + +/* -- Tail of trace ------------------------------------------------------- */ + +/* Fixup the tail code. */ +static void asm_tail_fixup(ASMState *as, TraceNo lnk) +{ + MCode *p = as->mctop; + MCode *target; + int32_t spadj = as->T->spadjust; + if (spadj == 0) { + *--p = PPCI_NOP; + *--p = PPCI_NOP; + as->mctop = p; + } else { + /* Patch stack adjustment. */ + lj_assertA(checki16(CFRAME_SIZE+spadj), "stack adjustment out of range"); + p[-3] = PPCI_ADDI | PPCF_T(RID_TMP) | PPCF_A(RID_SP) | (CFRAME_SIZE+spadj); + p[-2] = PPCI_STWU | PPCF_T(RID_TMP) | PPCF_A(RID_SP) | spadj; + } + /* Patch exit branch. */ + target = lnk ? traceref(as->J, lnk)->mcode : (MCode *)lj_vm_exit_interp; + p[-1] = PPCI_B|(((target-p+1)&0x00ffffffu)<<2); +} + +/* Prepare tail of code. */ +static void asm_tail_prep(ASMState *as) +{ + MCode *p = as->mctop - 1; /* Leave room for exit branch. */ + if (as->loopref) { + as->invmcp = as->mcp = p; + } else { + as->mcp = p-2; /* Leave room for stack pointer adjustment. */ + as->invmcp = NULL; + } +} + +/* -- Trace setup --------------------------------------------------------- */ + +/* Ensure there are enough stack slots for call arguments. */ +static Reg asm_setup_call_slots(ASMState *as, IRIns *ir, const CCallInfo *ci) +{ + IRRef args[CCI_NARGS_MAX*2]; + uint32_t i, nargs = CCI_XNARGS(ci); + int nslots = 2, ngpr = REGARG_NUMGPR, nfpr = REGARG_NUMFPR; + asm_collectargs(as, ir, ci, args); + for (i = 0; i < nargs; i++) + if (!LJ_SOFTFP && args[i] && irt_isfp(IR(args[i])->t)) { + if (nfpr > 0) nfpr--; else nslots = (nslots+3) & ~1; + } else { + if (ngpr > 0) ngpr--; else nslots++; + } + if (nslots > as->evenspill) /* Leave room for args in stack slots. */ + as->evenspill = nslots; + return (!LJ_SOFTFP && irt_isfp(ir->t)) ? REGSP_HINT(RID_FPRET) : + REGSP_HINT(RID_RET); +} + +static void asm_setup_target(ASMState *as) +{ + asm_exitstub_setup(as, as->T->nsnap + (as->parent ? 1 : 0)); +} + +/* -- Trace patching ------------------------------------------------------ */ + +/* Patch exit jumps of existing machine code to a new target. */ +void lj_asm_patchexit(jit_State *J, GCtrace *T, ExitNo exitno, MCode *target) +{ + MCode *p = T->mcode; + MCode *pe = (MCode *)((char *)p + T->szmcode); + MCode *px = exitstub_trace_addr(T, exitno); + MCode *cstart = NULL; + MCode *mcarea = lj_mcode_patch(J, p, 0); + int clearso = 0, patchlong = 1; + for (; p < pe; p++) { + /* Look for exitstub branch, try to replace with branch to target. */ + uint32_t ins = *p; + if ((ins & 0xfc000000u) == 0x40000000u && + ((ins ^ ((char *)px-(char *)p)) & 0xffffu) == 0) { + ptrdiff_t delta = (char *)target - (char *)p; + if (((ins >> 16) & 3) == (CC_SO&3)) { + clearso = sizeof(MCode); + delta -= sizeof(MCode); + } + /* Many, but not all short-range branches can be patched directly. */ + if (p[-1] == PPC_NOPATCH_GC_CHECK) { + patchlong = 0; + } else if (((delta + 0x8000) >> 16) == 0) { + *p = (ins & 0xffdf0000u) | ((uint32_t)delta & 0xffffu) | + ((delta & 0x8000) * (PPCF_Y/0x8000)); + if (!cstart) cstart = p; + } + } else if ((ins & 0xfc000000u) == PPCI_B && + ((ins ^ ((char *)px-(char *)p)) & 0x03ffffffu) == 0) { + ptrdiff_t delta = (char *)target - (char *)p; + lj_assertJ(((delta + 0x02000000) >> 26) == 0, + "branch target out of range"); + *p = PPCI_B | ((uint32_t)delta & 0x03ffffffu); + if (!cstart) cstart = p; + } + } + /* Always patch long-range branch in exit stub itself. Except, if we can't. */ + if (patchlong) { + ptrdiff_t delta = (char *)target - (char *)px - clearso; + lj_assertJ(((delta + 0x02000000) >> 26) == 0, + "branch target out of range"); + *px = PPCI_B | ((uint32_t)delta & 0x03ffffffu); + } + if (!cstart) cstart = px; + lj_mcode_sync(cstart, px+1); + if (clearso) { /* Extend the current trace. Ugly workaround. */ + MCode *pp = J->cur.mcode; + J->cur.szmcode += sizeof(MCode); + *--pp = PPCI_MCRXR; /* Clear SO flag. */ + J->cur.mcode = pp; + lj_mcode_sync(pp, pp+1); + } + lj_mcode_patch(J, mcarea, 1); +} + diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_asm_x86.h b/fluent-bit/lib/luajit-3065c9/src/lj_asm_x86.h new file mode 100644 index 00000000..4465efa2 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_asm_x86.h @@ -0,0 +1,3124 @@ +/* +** x86/x64 IR assembler (SSA IR -> machine code). +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +/* -- Guard handling ------------------------------------------------------ */ + +/* Generate an exit stub group at the bottom of the reserved MCode memory. */ +static MCode *asm_exitstub_gen(ASMState *as, ExitNo group) +{ + ExitNo i, groupofs = (group*EXITSTUBS_PER_GROUP) & 0xff; + MCode *mxp = as->mcbot; + MCode *mxpstart = mxp; + if (mxp + (2+2)*EXITSTUBS_PER_GROUP+8+5 >= as->mctop) + asm_mclimit(as); + /* Push low byte of exitno for each exit stub. */ + *mxp++ = XI_PUSHi8; *mxp++ = (MCode)groupofs; + for (i = 1; i < EXITSTUBS_PER_GROUP; i++) { + *mxp++ = XI_JMPs; *mxp++ = (MCode)((2+2)*(EXITSTUBS_PER_GROUP - i) - 2); + *mxp++ = XI_PUSHi8; *mxp++ = (MCode)(groupofs + i); + } + /* Push the high byte of the exitno for each exit stub group. */ + *mxp++ = XI_PUSHi8; *mxp++ = (MCode)((group*EXITSTUBS_PER_GROUP)>>8); +#if !LJ_GC64 + /* Store DISPATCH at original stack slot 0. Account for the two push ops. */ + *mxp++ = XI_MOVmi; + *mxp++ = MODRM(XM_OFS8, 0, RID_ESP); + *mxp++ = MODRM(XM_SCALE1, RID_ESP, RID_ESP); + *mxp++ = 2*sizeof(void *); + *(int32_t *)mxp = ptr2addr(J2GG(as->J)->dispatch); mxp += 4; +#endif + /* Jump to exit handler which fills in the ExitState. */ + *mxp++ = XI_JMP; mxp += 4; + *((int32_t *)(mxp-4)) = jmprel(as->J, mxp, (MCode *)(void *)lj_vm_exit_handler); + /* Commit the code for this group (even if assembly fails later on). */ + lj_mcode_commitbot(as->J, mxp); + as->mcbot = mxp; + as->mclim = as->mcbot + MCLIM_REDZONE; + return mxpstart; +} + +/* Setup all needed exit stubs. */ +static void asm_exitstub_setup(ASMState *as, ExitNo nexits) +{ + ExitNo i; + if (nexits >= EXITSTUBS_PER_GROUP*LJ_MAX_EXITSTUBGR) + lj_trace_err(as->J, LJ_TRERR_SNAPOV); + for (i = 0; i < (nexits+EXITSTUBS_PER_GROUP-1)/EXITSTUBS_PER_GROUP; i++) + if (as->J->exitstubgroup[i] == NULL) + as->J->exitstubgroup[i] = asm_exitstub_gen(as, i); +} + +/* Emit conditional branch to exit for guard. +** It's important to emit this *after* all registers have been allocated, +** because rematerializations may invalidate the flags. +*/ +static void asm_guardcc(ASMState *as, int cc) +{ + MCode *target = exitstub_addr(as->J, as->snapno); + MCode *p = as->mcp; + if (LJ_UNLIKELY(p == as->invmcp)) { + as->loopinv = 1; + *(int32_t *)(p+1) = jmprel(as->J, p+5, target); + target = p; + cc ^= 1; + if (as->realign) { + if (LJ_GC64 && LJ_UNLIKELY(as->mrm.base == RID_RIP)) + as->mrm.ofs += 2; /* Fixup RIP offset for pending fused load. */ + emit_sjcc(as, cc, target); + return; + } + } + if (LJ_GC64 && LJ_UNLIKELY(as->mrm.base == RID_RIP)) + as->mrm.ofs += 6; /* Fixup RIP offset for pending fused load. */ + emit_jcc(as, cc, target); +} + +/* -- Memory operand fusion ----------------------------------------------- */ + +/* Limit linear search to this distance. Avoids O(n^2) behavior. */ +#define CONFLICT_SEARCH_LIM 31 + +/* Check if a reference is a signed 32 bit constant. */ +static int asm_isk32(ASMState *as, IRRef ref, int32_t *k) +{ + if (irref_isk(ref)) { + IRIns *ir = IR(ref); +#if LJ_GC64 + if (ir->o == IR_KNULL || !irt_is64(ir->t)) { + *k = ir->i; + return 1; + } else if (checki32((int64_t)ir_k64(ir)->u64)) { + *k = (int32_t)ir_k64(ir)->u64; + return 1; + } +#else + if (ir->o != IR_KINT64) { + *k = ir->i; + return 1; + } else if (checki32((int64_t)ir_kint64(ir)->u64)) { + *k = (int32_t)ir_kint64(ir)->u64; + return 1; + } +#endif + } + return 0; +} + +/* Check if there's no conflicting instruction between curins and ref. +** Also avoid fusing loads if there are multiple references. +*/ +static int noconflict(ASMState *as, IRRef ref, IROp conflict, int noload) +{ + IRIns *ir = as->ir; + IRRef i = as->curins; + if (i > ref + CONFLICT_SEARCH_LIM) + return 0; /* Give up, ref is too far away. */ + while (--i > ref) { + if (ir[i].o == conflict) + return 0; /* Conflict found. */ + else if (!noload && (ir[i].op1 == ref || ir[i].op2 == ref)) + return 0; + } + return 1; /* Ok, no conflict. */ +} + +/* Fuse array base into memory operand. */ +static IRRef asm_fuseabase(ASMState *as, IRRef ref) +{ + IRIns *irb = IR(ref); + as->mrm.ofs = 0; + if (irb->o == IR_FLOAD) { + IRIns *ira = IR(irb->op1); + lj_assertA(irb->op2 == IRFL_TAB_ARRAY, "expected FLOAD TAB_ARRAY"); + /* We can avoid the FLOAD of t->array for colocated arrays. */ + if (ira->o == IR_TNEW && ira->op1 <= LJ_MAX_COLOSIZE && + !neverfuse(as) && noconflict(as, irb->op1, IR_NEWREF, 1)) { + as->mrm.ofs = (int32_t)sizeof(GCtab); /* Ofs to colocated array. */ + return irb->op1; /* Table obj. */ + } + } else if (irb->o == IR_ADD && irref_isk(irb->op2)) { + /* Fuse base offset (vararg load). */ + as->mrm.ofs = IR(irb->op2)->i; + return irb->op1; + } + return ref; /* Otherwise use the given array base. */ +} + +/* Fuse array reference into memory operand. */ +static void asm_fusearef(ASMState *as, IRIns *ir, RegSet allow) +{ + IRIns *irx; + lj_assertA(ir->o == IR_AREF, "expected AREF"); + as->mrm.base = (uint8_t)ra_alloc1(as, asm_fuseabase(as, ir->op1), allow); + irx = IR(ir->op2); + if (irref_isk(ir->op2)) { + as->mrm.ofs += 8*irx->i; + as->mrm.idx = RID_NONE; + } else { + rset_clear(allow, as->mrm.base); + as->mrm.scale = XM_SCALE8; + /* Fuse a constant ADD (e.g. t[i+1]) into the offset. + ** Doesn't help much without ABCelim, but reduces register pressure. + */ + if (!LJ_64 && /* Has bad effects with negative index on x64. */ + mayfuse(as, ir->op2) && ra_noreg(irx->r) && + irx->o == IR_ADD && irref_isk(irx->op2)) { + as->mrm.ofs += 8*IR(irx->op2)->i; + as->mrm.idx = (uint8_t)ra_alloc1(as, irx->op1, allow); + } else { + as->mrm.idx = (uint8_t)ra_alloc1(as, ir->op2, allow); + } + } +} + +/* Fuse array/hash/upvalue reference into memory operand. +** Caveat: this may allocate GPRs for the base/idx registers. Be sure to +** pass the final allow mask, excluding any GPRs used for other inputs. +** In particular: 2-operand GPR instructions need to call ra_dest() first! +*/ +static void asm_fuseahuref(ASMState *as, IRRef ref, RegSet allow) +{ + IRIns *ir = IR(ref); + if (ra_noreg(ir->r)) { + switch ((IROp)ir->o) { + case IR_AREF: + if (mayfuse(as, ref)) { + asm_fusearef(as, ir, allow); + return; + } + break; + case IR_HREFK: + if (mayfuse(as, ref)) { + as->mrm.base = (uint8_t)ra_alloc1(as, ir->op1, allow); + as->mrm.ofs = (int32_t)(IR(ir->op2)->op2 * sizeof(Node)); + as->mrm.idx = RID_NONE; + return; + } + break; + case IR_UREFC: + if (irref_isk(ir->op1)) { + GCfunc *fn = ir_kfunc(IR(ir->op1)); + GCupval *uv = &gcref(fn->l.uvptr[(ir->op2 >> 8)])->uv; +#if LJ_GC64 + int64_t ofs = dispofs(as, &uv->tv); + if (checki32(ofs) && checki32(ofs+4)) { + as->mrm.ofs = (int32_t)ofs; + as->mrm.base = RID_DISPATCH; + as->mrm.idx = RID_NONE; + return; + } +#else + as->mrm.ofs = ptr2addr(&uv->tv); + as->mrm.base = as->mrm.idx = RID_NONE; + return; +#endif + } + break; + case IR_TMPREF: +#if LJ_GC64 + as->mrm.ofs = (int32_t)dispofs(as, &J2G(as->J)->tmptv); + as->mrm.base = RID_DISPATCH; + as->mrm.idx = RID_NONE; +#else + as->mrm.ofs = igcptr(&J2G(as->J)->tmptv); + as->mrm.base = as->mrm.idx = RID_NONE; +#endif + return; + default: + break; + } + } + as->mrm.base = (uint8_t)ra_alloc1(as, ref, allow); + as->mrm.ofs = 0; + as->mrm.idx = RID_NONE; +} + +/* Fuse FLOAD/FREF reference into memory operand. */ +static void asm_fusefref(ASMState *as, IRIns *ir, RegSet allow) +{ + lj_assertA(ir->o == IR_FLOAD || ir->o == IR_FREF, + "bad IR op %d", ir->o); + as->mrm.idx = RID_NONE; + if (ir->op1 == REF_NIL) { /* FLOAD from GG_State with offset. */ +#if LJ_GC64 + as->mrm.ofs = (int32_t)(ir->op2 << 2) - GG_OFS(dispatch); + as->mrm.base = RID_DISPATCH; +#else + as->mrm.ofs = (int32_t)(ir->op2 << 2) + ptr2addr(J2GG(as->J)); + as->mrm.base = RID_NONE; +#endif + return; + } + as->mrm.ofs = field_ofs[ir->op2]; + if (irref_isk(ir->op1)) { + IRIns *op1 = IR(ir->op1); +#if LJ_GC64 + if (ir->op1 == REF_NIL) { + as->mrm.ofs -= GG_OFS(dispatch); + as->mrm.base = RID_DISPATCH; + return; + } else if (op1->o == IR_KPTR || op1->o == IR_KKPTR) { + intptr_t ofs = dispofs(as, ir_kptr(op1)); + if (checki32(as->mrm.ofs + ofs)) { + as->mrm.ofs += (int32_t)ofs; + as->mrm.base = RID_DISPATCH; + return; + } + } +#else + as->mrm.ofs += op1->i; + as->mrm.base = RID_NONE; + return; +#endif + } + as->mrm.base = (uint8_t)ra_alloc1(as, ir->op1, allow); +} + +/* Fuse string reference into memory operand. */ +static void asm_fusestrref(ASMState *as, IRIns *ir, RegSet allow) +{ + IRIns *irr; + lj_assertA(ir->o == IR_STRREF, "bad IR op %d", ir->o); + as->mrm.base = as->mrm.idx = RID_NONE; + as->mrm.scale = XM_SCALE1; + as->mrm.ofs = sizeof(GCstr); + if (!LJ_GC64 && irref_isk(ir->op1)) { + as->mrm.ofs += IR(ir->op1)->i; + } else { + Reg r = ra_alloc1(as, ir->op1, allow); + rset_clear(allow, r); + as->mrm.base = (uint8_t)r; + } + irr = IR(ir->op2); + if (irref_isk(ir->op2)) { + as->mrm.ofs += irr->i; + } else { + Reg r; + /* Fuse a constant add into the offset, e.g. string.sub(s, i+10). */ + if (!LJ_64 && /* Has bad effects with negative index on x64. */ + mayfuse(as, ir->op2) && irr->o == IR_ADD && irref_isk(irr->op2)) { + as->mrm.ofs += IR(irr->op2)->i; + r = ra_alloc1(as, irr->op1, allow); + } else { + r = ra_alloc1(as, ir->op2, allow); + } + if (as->mrm.base == RID_NONE) + as->mrm.base = (uint8_t)r; + else + as->mrm.idx = (uint8_t)r; + } +} + +static void asm_fusexref(ASMState *as, IRRef ref, RegSet allow) +{ + IRIns *ir = IR(ref); + as->mrm.idx = RID_NONE; + if (ir->o == IR_KPTR || ir->o == IR_KKPTR) { +#if LJ_GC64 + intptr_t ofs = dispofs(as, ir_kptr(ir)); + if (checki32(ofs)) { + as->mrm.ofs = (int32_t)ofs; + as->mrm.base = RID_DISPATCH; + return; + } + } if (0) { +#else + as->mrm.ofs = ir->i; + as->mrm.base = RID_NONE; + } else if (ir->o == IR_STRREF) { + asm_fusestrref(as, ir, allow); +#endif + } else { + as->mrm.ofs = 0; + if (canfuse(as, ir) && ir->o == IR_ADD && ra_noreg(ir->r)) { + /* Gather (base+idx*sz)+ofs as emitted by cdata ptr/array indexing. */ + IRIns *irx; + IRRef idx; + Reg r; + if (asm_isk32(as, ir->op2, &as->mrm.ofs)) { /* Recognize x+ofs. */ + ref = ir->op1; + ir = IR(ref); + if (!(ir->o == IR_ADD && canfuse(as, ir) && ra_noreg(ir->r))) + goto noadd; + } + as->mrm.scale = XM_SCALE1; + idx = ir->op1; + ref = ir->op2; + irx = IR(idx); + if (!(irx->o == IR_BSHL || irx->o == IR_ADD)) { /* Try other operand. */ + idx = ir->op2; + ref = ir->op1; + irx = IR(idx); + } + if (canfuse(as, irx) && ra_noreg(irx->r)) { + if (irx->o == IR_BSHL && irref_isk(irx->op2) && IR(irx->op2)->i <= 3) { + /* Recognize idx<op1; + as->mrm.scale = (uint8_t)(IR(irx->op2)->i << 6); + } else if (irx->o == IR_ADD && irx->op1 == irx->op2) { + /* FOLD does idx*2 ==> idx<<1 ==> idx+idx. */ + idx = irx->op1; + as->mrm.scale = XM_SCALE2; + } + } + r = ra_alloc1(as, idx, allow); + rset_clear(allow, r); + as->mrm.idx = (uint8_t)r; + } + noadd: + as->mrm.base = (uint8_t)ra_alloc1(as, ref, allow); + } +} + +/* Fuse load of 64 bit IR constant into memory operand. */ +static Reg asm_fuseloadk64(ASMState *as, IRIns *ir) +{ + const uint64_t *k = &ir_k64(ir)->u64; + if (!LJ_GC64 || checki32((intptr_t)k)) { + as->mrm.ofs = ptr2addr(k); + as->mrm.base = RID_NONE; +#if LJ_GC64 + } else if (checki32(dispofs(as, k))) { + as->mrm.ofs = (int32_t)dispofs(as, k); + as->mrm.base = RID_DISPATCH; + } else if (checki32(mcpofs(as, k)) && checki32(mcpofs(as, k+1)) && + checki32(mctopofs(as, k)) && checki32(mctopofs(as, k+1))) { + as->mrm.ofs = (int32_t)mcpofs(as, k); + as->mrm.base = RID_RIP; + } else { /* Intern 64 bit constant at bottom of mcode. */ + if (ir->i) { + lj_assertA(*k == *(uint64_t*)(as->mctop - ir->i), + "bad interned 64 bit constant"); + } else { + while ((uintptr_t)as->mcbot & 7) *as->mcbot++ = XI_INT3; + *(uint64_t*)as->mcbot = *k; + ir->i = (int32_t)(as->mctop - as->mcbot); + as->mcbot += 8; + as->mclim = as->mcbot + MCLIM_REDZONE; + lj_mcode_commitbot(as->J, as->mcbot); + } + as->mrm.ofs = (int32_t)mcpofs(as, as->mctop - ir->i); + as->mrm.base = RID_RIP; +#endif + } + as->mrm.idx = RID_NONE; + return RID_MRM; +} + +/* Fuse load into memory operand. +** +** Important caveat: this may emit RIP-relative loads! So don't place any +** code emitters between this function and the use of its result. +** The only permitted exception is asm_guardcc(). +*/ +static Reg asm_fuseload(ASMState *as, IRRef ref, RegSet allow) +{ + IRIns *ir = IR(ref); + if (ra_hasreg(ir->r)) { + if (allow != RSET_EMPTY) { /* Fast path. */ + ra_noweak(as, ir->r); + return ir->r; + } + fusespill: + /* Force a spill if only memory operands are allowed (asm_x87load). */ + as->mrm.base = RID_ESP; + as->mrm.ofs = ra_spill(as, ir); + as->mrm.idx = RID_NONE; + return RID_MRM; + } + if (ir->o == IR_KNUM) { + RegSet avail = as->freeset & ~as->modset & RSET_FPR; + lj_assertA(allow != RSET_EMPTY, "no register allowed"); + if (!(avail & (avail-1))) /* Fuse if less than two regs available. */ + return asm_fuseloadk64(as, ir); + } else if (ref == REF_BASE || ir->o == IR_KINT64) { + RegSet avail = as->freeset & ~as->modset & RSET_GPR; + lj_assertA(allow != RSET_EMPTY, "no register allowed"); + if (!(avail & (avail-1))) { /* Fuse if less than two regs available. */ + if (ref == REF_BASE) { +#if LJ_GC64 + as->mrm.ofs = (int32_t)dispofs(as, &J2G(as->J)->jit_base); + as->mrm.base = RID_DISPATCH; +#else + as->mrm.ofs = ptr2addr(&J2G(as->J)->jit_base); + as->mrm.base = RID_NONE; +#endif + as->mrm.idx = RID_NONE; + return RID_MRM; + } else { + return asm_fuseloadk64(as, ir); + } + } + } else if (mayfuse(as, ref)) { + RegSet xallow = (allow & RSET_GPR) ? allow : RSET_GPR; + if (ir->o == IR_SLOAD) { + if (!(ir->op2 & (IRSLOAD_PARENT|IRSLOAD_CONVERT)) && + noconflict(as, ref, IR_RETF, 0) && + !(LJ_GC64 && irt_isaddr(ir->t))) { + as->mrm.base = (uint8_t)ra_alloc1(as, REF_BASE, xallow); + as->mrm.ofs = 8*((int32_t)ir->op1-1-LJ_FR2) + + (!LJ_FR2 && (ir->op2 & IRSLOAD_FRAME) ? 4 : 0); + as->mrm.idx = RID_NONE; + return RID_MRM; + } + } else if (ir->o == IR_FLOAD) { + /* Generic fusion is only ok for 32 bit operand (but see asm_comp). */ + if ((irt_isint(ir->t) || irt_isu32(ir->t) || irt_isaddr(ir->t)) && + noconflict(as, ref, IR_FSTORE, 0)) { + asm_fusefref(as, ir, xallow); + return RID_MRM; + } + } else if (ir->o == IR_ALOAD || ir->o == IR_HLOAD || ir->o == IR_ULOAD) { + if (noconflict(as, ref, ir->o + IRDELTA_L2S, 0) && + !(LJ_GC64 && irt_isaddr(ir->t))) { + asm_fuseahuref(as, ir->op1, xallow); + return RID_MRM; + } + } else if (ir->o == IR_XLOAD) { + /* Generic fusion is not ok for 8/16 bit operands (but see asm_comp). + ** Fusing unaligned memory operands is ok on x86 (except for SIMD types). + */ + if ((!irt_typerange(ir->t, IRT_I8, IRT_U16)) && + noconflict(as, ref, IR_XSTORE, 0)) { + asm_fusexref(as, ir->op1, xallow); + return RID_MRM; + } + } else if (ir->o == IR_VLOAD && !(LJ_GC64 && irt_isaddr(ir->t))) { + asm_fuseahuref(as, ir->op1, xallow); + as->mrm.ofs += 8 * ir->op2; + return RID_MRM; + } + } + if (ir->o == IR_FLOAD && ir->op1 == REF_NIL) { + asm_fusefref(as, ir, RSET_EMPTY); + return RID_MRM; + } + if (!(as->freeset & allow) && !emit_canremat(ref) && + (allow == RSET_EMPTY || ra_hasspill(ir->s) || iscrossref(as, ref))) + goto fusespill; + return ra_allocref(as, ref, allow); +} + +#if LJ_64 +/* Don't fuse a 32 bit load into a 64 bit operation. */ +static Reg asm_fuseloadm(ASMState *as, IRRef ref, RegSet allow, int is64) +{ + if (is64 && !irt_is64(IR(ref)->t)) + return ra_alloc1(as, ref, allow); + return asm_fuseload(as, ref, allow); +} +#else +#define asm_fuseloadm(as, ref, allow, is64) asm_fuseload(as, (ref), (allow)) +#endif + +/* -- Calls --------------------------------------------------------------- */ + +/* Count the required number of stack slots for a call. */ +static int asm_count_call_slots(ASMState *as, const CCallInfo *ci, IRRef *args) +{ + uint32_t i, nargs = CCI_XNARGS(ci); + int nslots = 0; +#if LJ_64 + if (LJ_ABI_WIN) { + nslots = (int)(nargs*2); /* Only matters for more than four args. */ + } else { + int ngpr = REGARG_NUMGPR, nfpr = REGARG_NUMFPR; + for (i = 0; i < nargs; i++) + if (args[i] && irt_isfp(IR(args[i])->t)) { + if (nfpr > 0) nfpr--; else nslots += 2; + } else { + if (ngpr > 0) ngpr--; else nslots += 2; + } + } +#else + int ngpr = 0; + if ((ci->flags & CCI_CC_MASK) == CCI_CC_FASTCALL) + ngpr = 2; + else if ((ci->flags & CCI_CC_MASK) == CCI_CC_THISCALL) + ngpr = 1; + for (i = 0; i < nargs; i++) + if (args[i] && irt_isfp(IR(args[i])->t)) { + nslots += irt_isnum(IR(args[i])->t) ? 2 : 1; + } else { + if (ngpr > 0) ngpr--; else nslots++; + } +#endif + return nslots; +} + +/* Generate a call to a C function. */ +static void asm_gencall(ASMState *as, const CCallInfo *ci, IRRef *args) +{ + uint32_t n, nargs = CCI_XNARGS(ci); + int32_t ofs = STACKARG_OFS; +#if LJ_64 + uint32_t gprs = REGARG_GPRS; + Reg fpr = REGARG_FIRSTFPR; +#if !LJ_ABI_WIN + MCode *patchnfpr = NULL; +#endif +#else + uint32_t gprs = 0; + if ((ci->flags & CCI_CC_MASK) != CCI_CC_CDECL) { + if ((ci->flags & CCI_CC_MASK) == CCI_CC_THISCALL) + gprs = (REGARG_GPRS & 31); + else if ((ci->flags & CCI_CC_MASK) == CCI_CC_FASTCALL) + gprs = REGARG_GPRS; + } +#endif + if ((void *)ci->func) + emit_call(as, ci->func); +#if LJ_64 + if ((ci->flags & CCI_VARARG)) { /* Special handling for vararg calls. */ +#if LJ_ABI_WIN + for (n = 0; n < 4 && n < nargs; n++) { + IRIns *ir = IR(args[n]); + if (irt_isfp(ir->t)) /* Duplicate FPRs in GPRs. */ + emit_rr(as, XO_MOVDto, (irt_isnum(ir->t) ? REX_64 : 0) | (fpr+n), + ((gprs >> (n*5)) & 31)); /* Either MOVD or MOVQ. */ + } +#else + patchnfpr = --as->mcp; /* Indicate number of used FPRs in register al. */ + *--as->mcp = XI_MOVrib | RID_EAX; +#endif + } +#endif + for (n = 0; n < nargs; n++) { /* Setup args. */ + IRRef ref = args[n]; + IRIns *ir = IR(ref); + Reg r; +#if LJ_64 && LJ_ABI_WIN + /* Windows/x64 argument registers are strictly positional. */ + r = irt_isfp(ir->t) ? (fpr <= REGARG_LASTFPR ? fpr : 0) : (gprs & 31); + fpr++; gprs >>= 5; +#elif LJ_64 + /* POSIX/x64 argument registers are used in order of appearance. */ + if (irt_isfp(ir->t)) { + r = fpr <= REGARG_LASTFPR ? fpr++ : 0; + } else { + r = gprs & 31; gprs >>= 5; + } +#else + if (ref && irt_isfp(ir->t)) { + r = 0; + } else { + r = gprs & 31; gprs >>= 5; + if (!ref) continue; + } +#endif + if (r) { /* Argument is in a register. */ + if (r < RID_MAX_GPR && ref < ASMREF_TMP1) { +#if LJ_64 + if (LJ_GC64 ? !(ir->o == IR_KINT || ir->o == IR_KNULL) : ir->o == IR_KINT64) + emit_loadu64(as, r, ir_k64(ir)->u64); + else +#endif + emit_loadi(as, r, ir->i); + } else { + /* Must have been evicted. */ + lj_assertA(rset_test(as->freeset, r), "reg %d not free", r); + if (ra_hasreg(ir->r)) { + ra_noweak(as, ir->r); + emit_movrr(as, ir, r, ir->r); + } else { + ra_allocref(as, ref, RID2RSET(r)); + } + } + } else if (irt_isfp(ir->t)) { /* FP argument is on stack. */ + lj_assertA(!(irt_isfloat(ir->t) && irref_isk(ref)), + "unexpected float constant"); + if (LJ_32 && (ofs & 4) && irref_isk(ref)) { + /* Split stores for unaligned FP consts. */ + emit_movmroi(as, RID_ESP, ofs, (int32_t)ir_knum(ir)->u32.lo); + emit_movmroi(as, RID_ESP, ofs+4, (int32_t)ir_knum(ir)->u32.hi); + } else { + r = ra_alloc1(as, ref, RSET_FPR); + emit_rmro(as, irt_isnum(ir->t) ? XO_MOVSDto : XO_MOVSSto, + r, RID_ESP, ofs); + } + ofs += (LJ_32 && irt_isfloat(ir->t)) ? 4 : 8; + } else { /* Non-FP argument is on stack. */ + if (LJ_32 && ref < ASMREF_TMP1) { + emit_movmroi(as, RID_ESP, ofs, ir->i); + } else { + r = ra_alloc1(as, ref, RSET_GPR); + emit_movtomro(as, REX_64 + r, RID_ESP, ofs); + } + ofs += sizeof(intptr_t); + } + checkmclim(as); + } +#if LJ_64 && !LJ_ABI_WIN + if (patchnfpr) *patchnfpr = fpr - REGARG_FIRSTFPR; +#endif +} + +/* Setup result reg/sp for call. Evict scratch regs. */ +static void asm_setupresult(ASMState *as, IRIns *ir, const CCallInfo *ci) +{ + RegSet drop = RSET_SCRATCH; + int hiop = ((ir+1)->o == IR_HIOP && !irt_isnil((ir+1)->t)); + if ((ci->flags & CCI_NOFPRCLOBBER)) + drop &= ~RSET_FPR; + if (ra_hasreg(ir->r)) + rset_clear(drop, ir->r); /* Dest reg handled below. */ + if (hiop && ra_hasreg((ir+1)->r)) + rset_clear(drop, (ir+1)->r); /* Dest reg handled below. */ + ra_evictset(as, drop); /* Evictions must be performed first. */ + if (ra_used(ir)) { + if (irt_isfp(ir->t)) { + int32_t ofs = sps_scale(ir->s); /* Use spill slot or temp slots. */ +#if LJ_64 + if ((ci->flags & CCI_CASTU64)) { + Reg dest = ir->r; + if (ra_hasreg(dest)) { + ra_free(as, dest); + ra_modified(as, dest); + emit_rr(as, XO_MOVD, dest|REX_64, RID_RET); /* Really MOVQ. */ + } + if (ofs) emit_movtomro(as, RID_RET|REX_64, RID_ESP, ofs); + } else { + ra_destreg(as, ir, RID_FPRET); + } +#else + /* Number result is in x87 st0 for x86 calling convention. */ + Reg dest = ir->r; + if (ra_hasreg(dest)) { + ra_free(as, dest); + ra_modified(as, dest); + emit_rmro(as, irt_isnum(ir->t) ? XO_MOVSD : XO_MOVSS, + dest, RID_ESP, ofs); + } + if ((ci->flags & CCI_CASTU64)) { + emit_movtomro(as, RID_RETLO, RID_ESP, ofs); + emit_movtomro(as, RID_RETHI, RID_ESP, ofs+4); + } else { + emit_rmro(as, irt_isnum(ir->t) ? XO_FSTPq : XO_FSTPd, + irt_isnum(ir->t) ? XOg_FSTPq : XOg_FSTPd, RID_ESP, ofs); + } +#endif + } else if (hiop) { + ra_destpair(as, ir); + } else { + lj_assertA(!irt_ispri(ir->t), "PRI dest"); + ra_destreg(as, ir, RID_RET); + } + } else if (LJ_32 && irt_isfp(ir->t) && !(ci->flags & CCI_CASTU64)) { + emit_x87op(as, XI_FPOP); /* Pop unused result from x87 st0. */ + } +} + +/* Return a constant function pointer or NULL for indirect calls. */ +static void *asm_callx_func(ASMState *as, IRIns *irf, IRRef func) +{ +#if LJ_32 + UNUSED(as); + if (irref_isk(func)) + return (void *)irf->i; +#else + if (irref_isk(func)) { + MCode *p; + if (irf->o == IR_KINT64) + p = (MCode *)(void *)ir_k64(irf)->u64; + else + p = (MCode *)(void *)(uintptr_t)(uint32_t)irf->i; + if (p - as->mcp == (int32_t)(p - as->mcp)) + return p; /* Call target is still in +-2GB range. */ + /* Avoid the indirect case of emit_call(). Try to hoist func addr. */ + } +#endif + return NULL; +} + +static void asm_callx(ASMState *as, IRIns *ir) +{ + IRRef args[CCI_NARGS_MAX*2]; + CCallInfo ci; + IRRef func; + IRIns *irf; + int32_t spadj = 0; + ci.flags = asm_callx_flags(as, ir); + asm_collectargs(as, ir, &ci, args); + asm_setupresult(as, ir, &ci); +#if LJ_32 + /* Have to readjust stack after non-cdecl calls due to callee cleanup. */ + if ((ci.flags & CCI_CC_MASK) != CCI_CC_CDECL) + spadj = 4 * asm_count_call_slots(as, &ci, args); +#endif + func = ir->op2; irf = IR(func); + if (irf->o == IR_CARG) { func = irf->op1; irf = IR(func); } + ci.func = (ASMFunction)asm_callx_func(as, irf, func); + if (!(void *)ci.func) { + /* Use a (hoistable) non-scratch register for indirect calls. */ + RegSet allow = (RSET_GPR & ~RSET_SCRATCH); + Reg r = ra_alloc1(as, func, allow); + if (LJ_32) emit_spsub(as, spadj); /* Above code may cause restores! */ + emit_rr(as, XO_GROUP5, XOg_CALL, r); + } else if (LJ_32) { + emit_spsub(as, spadj); + } + asm_gencall(as, &ci, args); +} + +/* -- Returns ------------------------------------------------------------- */ + +/* Return to lower frame. Guard that it goes to the right spot. */ +static void asm_retf(ASMState *as, IRIns *ir) +{ + Reg base = ra_alloc1(as, REF_BASE, RSET_GPR); +#if LJ_FR2 + Reg rpc = ra_scratch(as, rset_exclude(RSET_GPR, base)); +#endif + void *pc = ir_kptr(IR(ir->op2)); + int32_t delta = 1+LJ_FR2+bc_a(*((const BCIns *)pc - 1)); + as->topslot -= (BCReg)delta; + if ((int32_t)as->topslot < 0) as->topslot = 0; + irt_setmark(IR(REF_BASE)->t); /* Children must not coalesce with BASE reg. */ + emit_setgl(as, base, jit_base); + emit_addptr(as, base, -8*delta); + asm_guardcc(as, CC_NE); +#if LJ_FR2 + emit_rmro(as, XO_CMP, rpc|REX_GC64, base, -8); + emit_loadu64(as, rpc, u64ptr(pc)); +#else + emit_gmroi(as, XG_ARITHi(XOg_CMP), base, -4, ptr2addr(pc)); +#endif +} + +/* -- Buffer operations --------------------------------------------------- */ + +#if LJ_HASBUFFER +static void asm_bufhdr_write(ASMState *as, Reg sb) +{ + Reg tmp = ra_scratch(as, rset_exclude(RSET_GPR, sb)); + IRIns irgc; + irgc.ot = IRT(0, IRT_PGC); /* GC type. */ + emit_storeofs(as, &irgc, tmp, sb, offsetof(SBuf, L)); + emit_opgl(as, XO_ARITH(XOg_OR), tmp|REX_GC64, cur_L); + emit_gri(as, XG_ARITHi(XOg_AND), tmp, SBUF_MASK_FLAG); + emit_loadofs(as, &irgc, tmp, sb, offsetof(SBuf, L)); +} +#endif + +/* -- Type conversions ---------------------------------------------------- */ + +static void asm_tointg(ASMState *as, IRIns *ir, Reg left) +{ + Reg tmp = ra_scratch(as, rset_exclude(RSET_FPR, left)); + Reg dest = ra_dest(as, ir, RSET_GPR); + asm_guardcc(as, CC_P); + asm_guardcc(as, CC_NE); + emit_rr(as, XO_UCOMISD, left, tmp); + emit_rr(as, XO_CVTSI2SD, tmp, dest); + emit_rr(as, XO_XORPS, tmp, tmp); /* Avoid partial register stall. */ + emit_rr(as, XO_CVTTSD2SI, dest, left); + /* Can't fuse since left is needed twice. */ +} + +static void asm_tobit(ASMState *as, IRIns *ir) +{ + Reg dest = ra_dest(as, ir, RSET_GPR); + Reg tmp = ra_noreg(IR(ir->op1)->r) ? + ra_alloc1(as, ir->op1, RSET_FPR) : + ra_scratch(as, RSET_FPR); + Reg right; + emit_rr(as, XO_MOVDto, tmp, dest); + right = asm_fuseload(as, ir->op2, rset_exclude(RSET_FPR, tmp)); + emit_mrm(as, XO_ADDSD, tmp, right); + ra_left(as, tmp, ir->op1); +} + +static void asm_conv(ASMState *as, IRIns *ir) +{ + IRType st = (IRType)(ir->op2 & IRCONV_SRCMASK); + int st64 = (st == IRT_I64 || st == IRT_U64 || (LJ_64 && st == IRT_P64)); + int stfp = (st == IRT_NUM || st == IRT_FLOAT); + IRRef lref = ir->op1; + lj_assertA(irt_type(ir->t) != st, "inconsistent types for CONV"); + lj_assertA(!(LJ_32 && (irt_isint64(ir->t) || st64)), + "IR %04d has unsplit 64 bit type", + (int)(ir - as->ir) - REF_BIAS); + if (irt_isfp(ir->t)) { + Reg dest = ra_dest(as, ir, RSET_FPR); + if (stfp) { /* FP to FP conversion. */ + Reg left = asm_fuseload(as, lref, RSET_FPR); + emit_mrm(as, st == IRT_NUM ? XO_CVTSD2SS : XO_CVTSS2SD, dest, left); + if (left == dest) return; /* Avoid the XO_XORPS. */ + } else if (LJ_32 && st == IRT_U32) { /* U32 to FP conversion on x86. */ + /* number = (2^52+2^51 .. u32) - (2^52+2^51) */ + cTValue *k = &as->J->k64[LJ_K64_TOBIT]; + Reg bias = ra_scratch(as, rset_exclude(RSET_FPR, dest)); + if (irt_isfloat(ir->t)) + emit_rr(as, XO_CVTSD2SS, dest, dest); + emit_rr(as, XO_SUBSD, dest, bias); /* Subtract 2^52+2^51 bias. */ + emit_rr(as, XO_XORPS, dest, bias); /* Merge bias and integer. */ + emit_rma(as, XO_MOVSD, bias, k); + emit_mrm(as, XO_MOVD, dest, asm_fuseload(as, lref, RSET_GPR)); + return; + } else { /* Integer to FP conversion. */ + Reg left = (LJ_64 && (st == IRT_U32 || st == IRT_U64)) ? + ra_alloc1(as, lref, RSET_GPR) : + asm_fuseloadm(as, lref, RSET_GPR, st64); + if (LJ_64 && st == IRT_U64) { + MCLabel l_end = emit_label(as); + cTValue *k = &as->J->k64[LJ_K64_2P64]; + emit_rma(as, XO_ADDSD, dest, k); /* Add 2^64 to compensate. */ + emit_sjcc(as, CC_NS, l_end); + emit_rr(as, XO_TEST, left|REX_64, left); /* Check if u64 >= 2^63. */ + } + emit_mrm(as, irt_isnum(ir->t) ? XO_CVTSI2SD : XO_CVTSI2SS, + dest|((LJ_64 && (st64 || st == IRT_U32)) ? REX_64 : 0), left); + } + emit_rr(as, XO_XORPS, dest, dest); /* Avoid partial register stall. */ + } else if (stfp) { /* FP to integer conversion. */ + if (irt_isguard(ir->t)) { + /* Checked conversions are only supported from number to int. */ + lj_assertA(irt_isint(ir->t) && st == IRT_NUM, + "bad type for checked CONV"); + asm_tointg(as, ir, ra_alloc1(as, lref, RSET_FPR)); + } else { + Reg dest = ra_dest(as, ir, RSET_GPR); + x86Op op = st == IRT_NUM ? XO_CVTTSD2SI : XO_CVTTSS2SI; + if (LJ_64 ? irt_isu64(ir->t) : irt_isu32(ir->t)) { + /* LJ_64: For inputs >= 2^63 add -2^64, convert again. */ + /* LJ_32: For inputs >= 2^31 add -2^31, convert again and add 2^31. */ + Reg tmp = ra_noreg(IR(lref)->r) ? ra_alloc1(as, lref, RSET_FPR) : + ra_scratch(as, RSET_FPR); + MCLabel l_end = emit_label(as); + if (LJ_32) + emit_gri(as, XG_ARITHi(XOg_ADD), dest, (int32_t)0x80000000); + emit_rr(as, op, dest|REX_64, tmp); + if (st == IRT_NUM) + emit_rma(as, XO_ADDSD, tmp, &as->J->k64[LJ_K64_M2P64_31]); + else + emit_rma(as, XO_ADDSS, tmp, &as->J->k32[LJ_K32_M2P64_31]); + emit_sjcc(as, CC_NS, l_end); + emit_rr(as, XO_TEST, dest|REX_64, dest); /* Check if dest negative. */ + emit_rr(as, op, dest|REX_64, tmp); + ra_left(as, tmp, lref); + } else { + if (LJ_64 && irt_isu32(ir->t)) + emit_rr(as, XO_MOV, dest, dest); /* Zero hiword. */ + emit_mrm(as, op, + dest|((LJ_64 && + (irt_is64(ir->t) || irt_isu32(ir->t))) ? REX_64 : 0), + asm_fuseload(as, lref, RSET_FPR)); + } + } + } else if (st >= IRT_I8 && st <= IRT_U16) { /* Extend to 32 bit integer. */ + Reg left, dest = ra_dest(as, ir, RSET_GPR); + RegSet allow = RSET_GPR; + x86Op op; + lj_assertA(irt_isint(ir->t) || irt_isu32(ir->t), "bad type for CONV EXT"); + if (st == IRT_I8) { + op = XO_MOVSXb; allow = RSET_GPR8; dest |= FORCE_REX; + } else if (st == IRT_U8) { + op = XO_MOVZXb; allow = RSET_GPR8; dest |= FORCE_REX; + } else if (st == IRT_I16) { + op = XO_MOVSXw; + } else { + op = XO_MOVZXw; + } + left = asm_fuseload(as, lref, allow); + /* Add extra MOV if source is already in wrong register. */ + if (!LJ_64 && left != RID_MRM && !rset_test(allow, left)) { + Reg tmp = ra_scratch(as, allow); + emit_rr(as, op, dest, tmp); + emit_rr(as, XO_MOV, tmp, left); + } else { + emit_mrm(as, op, dest, left); + } + } else { /* 32/64 bit integer conversions. */ + if (LJ_32) { /* Only need to handle 32/32 bit no-op (cast) on x86. */ + Reg dest = ra_dest(as, ir, RSET_GPR); + ra_left(as, dest, lref); /* Do nothing, but may need to move regs. */ + } else if (irt_is64(ir->t)) { + Reg dest = ra_dest(as, ir, RSET_GPR); + if (st64 || !(ir->op2 & IRCONV_SEXT)) { + /* 64/64 bit no-op (cast) or 32 to 64 bit zero extension. */ + ra_left(as, dest, lref); /* Do nothing, but may need to move regs. */ + } else { /* 32 to 64 bit sign extension. */ + Reg left = asm_fuseload(as, lref, RSET_GPR); + emit_mrm(as, XO_MOVSXd, dest|REX_64, left); + } + } else { + Reg dest = ra_dest(as, ir, RSET_GPR); + if (st64 && !(ir->op2 & IRCONV_NONE)) { + Reg left = asm_fuseload(as, lref, RSET_GPR); + /* This is either a 32 bit reg/reg mov which zeroes the hiword + ** or a load of the loword from a 64 bit address. + */ + emit_mrm(as, XO_MOV, dest, left); + } else { /* 32/32 bit no-op (cast). */ + ra_left(as, dest, lref); /* Do nothing, but may need to move regs. */ + } + } + } +} + +#if LJ_32 && LJ_HASFFI +/* No SSE conversions to/from 64 bit on x86, so resort to ugly x87 code. */ + +/* 64 bit integer to FP conversion in 32 bit mode. */ +static void asm_conv_fp_int64(ASMState *as, IRIns *ir) +{ + Reg hi = ra_alloc1(as, ir->op1, RSET_GPR); + Reg lo = ra_alloc1(as, (ir-1)->op1, rset_exclude(RSET_GPR, hi)); + int32_t ofs = sps_scale(ir->s); /* Use spill slot or temp slots. */ + Reg dest = ir->r; + if (ra_hasreg(dest)) { + ra_free(as, dest); + ra_modified(as, dest); + emit_rmro(as, irt_isnum(ir->t) ? XO_MOVSD : XO_MOVSS, dest, RID_ESP, ofs); + } + emit_rmro(as, irt_isnum(ir->t) ? XO_FSTPq : XO_FSTPd, + irt_isnum(ir->t) ? XOg_FSTPq : XOg_FSTPd, RID_ESP, ofs); + if (((ir-1)->op2 & IRCONV_SRCMASK) == IRT_U64) { + /* For inputs in [2^63,2^64-1] add 2^64 to compensate. */ + MCLabel l_end = emit_label(as); + emit_rma(as, XO_FADDq, XOg_FADDq, &as->J->k64[LJ_K64_2P64]); + emit_sjcc(as, CC_NS, l_end); + emit_rr(as, XO_TEST, hi, hi); /* Check if u64 >= 2^63. */ + } else { + lj_assertA(((ir-1)->op2 & IRCONV_SRCMASK) == IRT_I64, "bad type for CONV"); + } + emit_rmro(as, XO_FILDq, XOg_FILDq, RID_ESP, 0); + /* NYI: Avoid narrow-to-wide store-to-load forwarding stall. */ + emit_rmro(as, XO_MOVto, hi, RID_ESP, 4); + emit_rmro(as, XO_MOVto, lo, RID_ESP, 0); +} + +/* FP to 64 bit integer conversion in 32 bit mode. */ +static void asm_conv_int64_fp(ASMState *as, IRIns *ir) +{ + IRType st = (IRType)((ir-1)->op2 & IRCONV_SRCMASK); + IRType dt = (((ir-1)->op2 & IRCONV_DSTMASK) >> IRCONV_DSH); + Reg lo, hi; + lj_assertA(st == IRT_NUM || st == IRT_FLOAT, "bad type for CONV"); + lj_assertA(dt == IRT_I64 || dt == IRT_U64, "bad type for CONV"); + hi = ra_dest(as, ir, RSET_GPR); + lo = ra_dest(as, ir-1, rset_exclude(RSET_GPR, hi)); + if (ra_used(ir-1)) emit_rmro(as, XO_MOV, lo, RID_ESP, 0); + /* NYI: Avoid wide-to-narrow store-to-load forwarding stall. */ + if (!(as->flags & JIT_F_SSE3)) { /* Set FPU rounding mode to default. */ + emit_rmro(as, XO_FLDCW, XOg_FLDCW, RID_ESP, 4); + emit_rmro(as, XO_MOVto, lo, RID_ESP, 4); + emit_gri(as, XG_ARITHi(XOg_AND), lo, 0xf3ff); + } + if (dt == IRT_U64) { + /* For inputs in [2^63,2^64-1] add -2^64 and convert again. */ + MCLabel l_pop, l_end = emit_label(as); + emit_x87op(as, XI_FPOP); + l_pop = emit_label(as); + emit_sjmp(as, l_end); + emit_rmro(as, XO_MOV, hi, RID_ESP, 4); + if ((as->flags & JIT_F_SSE3)) + emit_rmro(as, XO_FISTTPq, XOg_FISTTPq, RID_ESP, 0); + else + emit_rmro(as, XO_FISTPq, XOg_FISTPq, RID_ESP, 0); + emit_rma(as, XO_FADDq, XOg_FADDq, &as->J->k64[LJ_K64_M2P64]); + emit_sjcc(as, CC_NS, l_pop); + emit_rr(as, XO_TEST, hi, hi); /* Check if out-of-range (2^63). */ + } + emit_rmro(as, XO_MOV, hi, RID_ESP, 4); + if ((as->flags & JIT_F_SSE3)) { /* Truncation is easy with SSE3. */ + emit_rmro(as, XO_FISTTPq, XOg_FISTTPq, RID_ESP, 0); + } else { /* Otherwise set FPU rounding mode to truncate before the store. */ + emit_rmro(as, XO_FISTPq, XOg_FISTPq, RID_ESP, 0); + emit_rmro(as, XO_FLDCW, XOg_FLDCW, RID_ESP, 0); + emit_rmro(as, XO_MOVtow, lo, RID_ESP, 0); + emit_rmro(as, XO_ARITHw(XOg_OR), lo, RID_ESP, 0); + emit_loadi(as, lo, 0xc00); + emit_rmro(as, XO_FNSTCW, XOg_FNSTCW, RID_ESP, 0); + } + if (dt == IRT_U64) + emit_x87op(as, XI_FDUP); + emit_mrm(as, st == IRT_NUM ? XO_FLDq : XO_FLDd, + st == IRT_NUM ? XOg_FLDq: XOg_FLDd, + asm_fuseload(as, ir->op1, RSET_EMPTY)); +} + +static void asm_conv64(ASMState *as, IRIns *ir) +{ + if (irt_isfp(ir->t)) + asm_conv_fp_int64(as, ir); + else + asm_conv_int64_fp(as, ir); +} +#endif + +static void asm_strto(ASMState *as, IRIns *ir) +{ + /* Force a spill slot for the destination register (if any). */ + const CCallInfo *ci = &lj_ir_callinfo[IRCALL_lj_strscan_num]; + IRRef args[2]; + RegSet drop = RSET_SCRATCH; + if ((drop & RSET_FPR) != RSET_FPR && ra_hasreg(ir->r)) + rset_set(drop, ir->r); /* WIN64 doesn't spill all FPRs. */ + ra_evictset(as, drop); + asm_guardcc(as, CC_E); + emit_rr(as, XO_TEST, RID_RET, RID_RET); /* Test return status. */ + args[0] = ir->op1; /* GCstr *str */ + args[1] = ASMREF_TMP1; /* TValue *n */ + asm_gencall(as, ci, args); + /* Store the result to the spill slot or temp slots. */ + emit_rmro(as, XO_LEA, ra_releasetmp(as, ASMREF_TMP1)|REX_64, + RID_ESP, sps_scale(ir->s)); +} + +/* -- Memory references --------------------------------------------------- */ + +/* Get pointer to TValue. */ +static void asm_tvptr(ASMState *as, Reg dest, IRRef ref, MSize mode) +{ + if ((mode & IRTMPREF_IN1)) { + IRIns *ir = IR(ref); + if (irt_isnum(ir->t)) { + if (irref_isk(ref) && !(mode & IRTMPREF_OUT1)) { + /* Use the number constant itself as a TValue. */ + emit_loada(as, dest, ir_knum(ir)); + return; + } + emit_rmro(as, XO_MOVSDto, ra_alloc1(as, ref, RSET_FPR), dest, 0); + } else { +#if LJ_GC64 + if (irref_isk(ref)) { + TValue k; + lj_ir_kvalue(as->J->L, &k, ir); + emit_movmroi(as, dest, 4, k.u32.hi); + emit_movmroi(as, dest, 0, k.u32.lo); + } else { + /* TODO: 64 bit store + 32 bit load-modify-store is suboptimal. */ + Reg src = ra_alloc1(as, ref, rset_exclude(RSET_GPR, dest)); + if (irt_is64(ir->t)) { + emit_u32(as, irt_toitype(ir->t) << 15); + emit_rmro(as, XO_ARITHi, XOg_OR, dest, 4); + } else { + emit_movmroi(as, dest, 4, (irt_toitype(ir->t) << 15)); + } + emit_movtomro(as, REX_64IR(ir, src), dest, 0); + } +#else + if (!irref_isk(ref)) { + Reg src = ra_alloc1(as, ref, rset_exclude(RSET_GPR, dest)); + emit_movtomro(as, REX_64IR(ir, src), dest, 0); + } else if (!irt_ispri(ir->t)) { + emit_movmroi(as, dest, 0, ir->i); + } + if (!(LJ_64 && irt_islightud(ir->t))) + emit_movmroi(as, dest, 4, irt_toitype(ir->t)); +#endif + } + } + emit_loada(as, dest, &J2G(as->J)->tmptv); /* g->tmptv holds the TValue(s). */ +} + +static void asm_aref(ASMState *as, IRIns *ir) +{ + Reg dest = ra_dest(as, ir, RSET_GPR); + asm_fusearef(as, ir, RSET_GPR); + if (!(as->mrm.idx == RID_NONE && as->mrm.ofs == 0)) + emit_mrm(as, XO_LEA, dest|REX_GC64, RID_MRM); + else if (as->mrm.base != dest) + emit_rr(as, XO_MOV, dest|REX_GC64, as->mrm.base); +} + +/* Inlined hash lookup. Specialized for key type and for const keys. +** The equivalent C code is: +** Node *n = hashkey(t, key); +** do { +** if (lj_obj_equal(&n->key, key)) return &n->val; +** } while ((n = nextnode(n))); +** return niltv(L); +*/ +static void asm_href(ASMState *as, IRIns *ir, IROp merge) +{ + RegSet allow = RSET_GPR; + int destused = ra_used(ir); + Reg dest = ra_dest(as, ir, allow); + Reg tab = ra_alloc1(as, ir->op1, rset_clear(allow, dest)); + Reg key = RID_NONE, tmp = RID_NONE; + IRIns *irkey = IR(ir->op2); + int isk = irref_isk(ir->op2); + IRType1 kt = irkey->t; + uint32_t khash; + MCLabel l_end, l_loop, l_next; + + if (!isk) { + rset_clear(allow, tab); + key = ra_alloc1(as, ir->op2, irt_isnum(kt) ? RSET_FPR : allow); + if (LJ_GC64 || !irt_isstr(kt)) + tmp = ra_scratch(as, rset_exclude(allow, key)); + } + + /* Key not found in chain: jump to exit (if merged) or load niltv. */ + l_end = emit_label(as); + if (merge == IR_NE) + asm_guardcc(as, CC_E); /* XI_JMP is not found by lj_asm_patchexit. */ + else if (destused) + emit_loada(as, dest, niltvg(J2G(as->J))); + + /* Follow hash chain until the end. */ + l_loop = emit_sjcc_label(as, CC_NZ); + emit_rr(as, XO_TEST, dest|REX_GC64, dest); + emit_rmro(as, XO_MOV, dest|REX_GC64, dest, offsetof(Node, next)); + l_next = emit_label(as); + + /* Type and value comparison. */ + if (merge == IR_EQ) + asm_guardcc(as, CC_E); + else + emit_sjcc(as, CC_E, l_end); + if (irt_isnum(kt)) { + if (isk) { + /* Assumes -0.0 is already canonicalized to +0.0. */ + emit_gmroi(as, XG_ARITHi(XOg_CMP), dest, offsetof(Node, key.u32.lo), + (int32_t)ir_knum(irkey)->u32.lo); + emit_sjcc(as, CC_NE, l_next); + emit_gmroi(as, XG_ARITHi(XOg_CMP), dest, offsetof(Node, key.u32.hi), + (int32_t)ir_knum(irkey)->u32.hi); + } else { + emit_sjcc(as, CC_P, l_next); + emit_rmro(as, XO_UCOMISD, key, dest, offsetof(Node, key.n)); + emit_sjcc(as, CC_AE, l_next); + /* The type check avoids NaN penalties and complaints from Valgrind. */ +#if LJ_64 && !LJ_GC64 + emit_u32(as, LJ_TISNUM); + emit_rmro(as, XO_ARITHi, XOg_CMP, dest, offsetof(Node, key.it)); +#else + emit_i8(as, LJ_TISNUM); + emit_rmro(as, XO_ARITHi8, XOg_CMP, dest, offsetof(Node, key.it)); +#endif + } +#if LJ_64 && !LJ_GC64 + } else if (irt_islightud(kt)) { + emit_rmro(as, XO_CMP, key|REX_64, dest, offsetof(Node, key.u64)); +#endif +#if LJ_GC64 + } else if (irt_isaddr(kt)) { + if (isk) { + TValue k; + k.u64 = ((uint64_t)irt_toitype(irkey->t) << 47) | irkey[1].tv.u64; + emit_gmroi(as, XG_ARITHi(XOg_CMP), dest, offsetof(Node, key.u32.lo), + k.u32.lo); + emit_sjcc(as, CC_NE, l_next); + emit_gmroi(as, XG_ARITHi(XOg_CMP), dest, offsetof(Node, key.u32.hi), + k.u32.hi); + } else { + emit_rmro(as, XO_CMP, tmp|REX_64, dest, offsetof(Node, key.u64)); + } + } else { + lj_assertA(irt_ispri(kt) && !irt_isnil(kt), "bad HREF key type"); + emit_u32(as, (irt_toitype(kt)<<15)|0x7fff); + emit_rmro(as, XO_ARITHi, XOg_CMP, dest, offsetof(Node, key.it)); +#else + } else { + if (!irt_ispri(kt)) { + lj_assertA(irt_isaddr(kt), "bad HREF key type"); + if (isk) + emit_gmroi(as, XG_ARITHi(XOg_CMP), dest, offsetof(Node, key.gcr), + ptr2addr(ir_kgc(irkey))); + else + emit_rmro(as, XO_CMP, key, dest, offsetof(Node, key.gcr)); + emit_sjcc(as, CC_NE, l_next); + } + lj_assertA(!irt_isnil(kt), "bad HREF key type"); + emit_i8(as, irt_toitype(kt)); + emit_rmro(as, XO_ARITHi8, XOg_CMP, dest, offsetof(Node, key.it)); +#endif + } + emit_sfixup(as, l_loop); + checkmclim(as); +#if LJ_GC64 + if (!isk && irt_isaddr(kt)) { + emit_rr(as, XO_OR, tmp|REX_64, key); + emit_loadu64(as, tmp, (uint64_t)irt_toitype(kt) << 47); + } +#endif + + /* Load main position relative to tab->node into dest. */ + khash = isk ? ir_khash(as, irkey) : 1; + if (khash == 0) { + emit_rmro(as, XO_MOV, dest|REX_GC64, tab, offsetof(GCtab, node)); + } else { + emit_rmro(as, XO_ARITH(XOg_ADD), dest|REX_GC64, tab, offsetof(GCtab,node)); + emit_shifti(as, XOg_SHL, dest, 3); + emit_rmrxo(as, XO_LEA, dest, dest, dest, XM_SCALE2, 0); + if (isk) { + emit_gri(as, XG_ARITHi(XOg_AND), dest, (int32_t)khash); + emit_rmro(as, XO_MOV, dest, tab, offsetof(GCtab, hmask)); + } else if (irt_isstr(kt)) { + emit_rmro(as, XO_ARITH(XOg_AND), dest, key, offsetof(GCstr, sid)); + emit_rmro(as, XO_MOV, dest, tab, offsetof(GCtab, hmask)); + } else { /* Must match with hashrot() in lj_tab.c. */ + emit_rmro(as, XO_ARITH(XOg_AND), dest, tab, offsetof(GCtab, hmask)); + emit_rr(as, XO_ARITH(XOg_SUB), dest, tmp); + emit_shifti(as, XOg_ROL, tmp, HASH_ROT3); + emit_rr(as, XO_ARITH(XOg_XOR), dest, tmp); + emit_shifti(as, XOg_ROL, dest, HASH_ROT2); + emit_rr(as, XO_ARITH(XOg_SUB), tmp, dest); + emit_shifti(as, XOg_ROL, dest, HASH_ROT1); + emit_rr(as, XO_ARITH(XOg_XOR), tmp, dest); + if (irt_isnum(kt)) { + emit_rr(as, XO_ARITH(XOg_ADD), dest, dest); +#if LJ_64 + emit_shifti(as, XOg_SHR|REX_64, dest, 32); + emit_rr(as, XO_MOV, tmp, dest); + emit_rr(as, XO_MOVDto, key|REX_64, dest); +#else + emit_rmro(as, XO_MOV, dest, RID_ESP, ra_spill(as, irkey)+4); + emit_rr(as, XO_MOVDto, key, tmp); +#endif + } else { + emit_rr(as, XO_MOV, tmp, key); +#if LJ_GC64 + checkmclim(as); + emit_gri(as, XG_ARITHi(XOg_XOR), dest, irt_toitype(kt) << 15); + if ((as->flags & JIT_F_BMI2)) { + emit_i8(as, 32); + emit_mrm(as, XV_RORX|VEX_64, dest, key); + } else { + emit_shifti(as, XOg_SHR|REX_64, dest, 32); + emit_rr(as, XO_MOV, dest|REX_64, key|REX_64); + } +#else + emit_rmro(as, XO_LEA, dest, key, HASH_BIAS); +#endif + } + } + } +} + +static void asm_hrefk(ASMState *as, IRIns *ir) +{ + IRIns *kslot = IR(ir->op2); + IRIns *irkey = IR(kslot->op1); + int32_t ofs = (int32_t)(kslot->op2 * sizeof(Node)); + Reg dest = ra_used(ir) ? ra_dest(as, ir, RSET_GPR) : RID_NONE; + Reg node = ra_alloc1(as, ir->op1, RSET_GPR); +#if !LJ_64 + MCLabel l_exit; +#endif + lj_assertA(ofs % sizeof(Node) == 0, "unaligned HREFK slot"); + if (ra_hasreg(dest)) { + if (ofs != 0) { + if (dest == node) + emit_gri(as, XG_ARITHi(XOg_ADD), dest|REX_GC64, ofs); + else + emit_rmro(as, XO_LEA, dest|REX_GC64, node, ofs); + } else if (dest != node) { + emit_rr(as, XO_MOV, dest|REX_GC64, node); + } + } + asm_guardcc(as, CC_NE); +#if LJ_64 + if (!irt_ispri(irkey->t)) { + Reg key = ra_scratch(as, rset_exclude(RSET_GPR, node)); + emit_rmro(as, XO_CMP, key|REX_64, node, + ofs + (int32_t)offsetof(Node, key.u64)); + lj_assertA(irt_isnum(irkey->t) || irt_isgcv(irkey->t), + "bad HREFK key type"); + /* Assumes -0.0 is already canonicalized to +0.0. */ + emit_loadu64(as, key, irt_isnum(irkey->t) ? ir_knum(irkey)->u64 : +#if LJ_GC64 + ((uint64_t)irt_toitype(irkey->t) << 47) | + (uint64_t)ir_kgc(irkey)); +#else + ((uint64_t)irt_toitype(irkey->t) << 32) | + (uint64_t)(uint32_t)ptr2addr(ir_kgc(irkey))); +#endif + } else { + lj_assertA(!irt_isnil(irkey->t), "bad HREFK key type"); +#if LJ_GC64 + emit_i32(as, (irt_toitype(irkey->t)<<15)|0x7fff); + emit_rmro(as, XO_ARITHi, XOg_CMP, node, + ofs + (int32_t)offsetof(Node, key.it)); +#else + emit_i8(as, irt_toitype(irkey->t)); + emit_rmro(as, XO_ARITHi8, XOg_CMP, node, + ofs + (int32_t)offsetof(Node, key.it)); +#endif + } +#else + l_exit = emit_label(as); + if (irt_isnum(irkey->t)) { + /* Assumes -0.0 is already canonicalized to +0.0. */ + emit_gmroi(as, XG_ARITHi(XOg_CMP), node, + ofs + (int32_t)offsetof(Node, key.u32.lo), + (int32_t)ir_knum(irkey)->u32.lo); + emit_sjcc(as, CC_NE, l_exit); + emit_gmroi(as, XG_ARITHi(XOg_CMP), node, + ofs + (int32_t)offsetof(Node, key.u32.hi), + (int32_t)ir_knum(irkey)->u32.hi); + } else { + if (!irt_ispri(irkey->t)) { + lj_assertA(irt_isgcv(irkey->t), "bad HREFK key type"); + emit_gmroi(as, XG_ARITHi(XOg_CMP), node, + ofs + (int32_t)offsetof(Node, key.gcr), + ptr2addr(ir_kgc(irkey))); + emit_sjcc(as, CC_NE, l_exit); + } + lj_assertA(!irt_isnil(irkey->t), "bad HREFK key type"); + emit_i8(as, irt_toitype(irkey->t)); + emit_rmro(as, XO_ARITHi8, XOg_CMP, node, + ofs + (int32_t)offsetof(Node, key.it)); + } +#endif +} + +static void asm_uref(ASMState *as, IRIns *ir) +{ + Reg dest = ra_dest(as, ir, RSET_GPR); + if (irref_isk(ir->op1)) { + GCfunc *fn = ir_kfunc(IR(ir->op1)); + MRef *v = &gcref(fn->l.uvptr[(ir->op2 >> 8)])->uv.v; + emit_rma(as, XO_MOV, dest|REX_GC64, v); + } else { + Reg uv = ra_scratch(as, RSET_GPR); + Reg func = ra_alloc1(as, ir->op1, RSET_GPR); + if (ir->o == IR_UREFC) { + emit_rmro(as, XO_LEA, dest|REX_GC64, uv, offsetof(GCupval, tv)); + asm_guardcc(as, CC_NE); + emit_i8(as, 1); + emit_rmro(as, XO_ARITHib, XOg_CMP, uv, offsetof(GCupval, closed)); + } else { + emit_rmro(as, XO_MOV, dest|REX_GC64, uv, offsetof(GCupval, v)); + } + emit_rmro(as, XO_MOV, uv|REX_GC64, func, + (int32_t)offsetof(GCfuncL, uvptr) + + (int32_t)sizeof(MRef) * (int32_t)(ir->op2 >> 8)); + } +} + +static void asm_fref(ASMState *as, IRIns *ir) +{ + Reg dest = ra_dest(as, ir, RSET_GPR); + asm_fusefref(as, ir, RSET_GPR); + emit_mrm(as, XO_LEA, dest, RID_MRM); +} + +static void asm_strref(ASMState *as, IRIns *ir) +{ + Reg dest = ra_dest(as, ir, RSET_GPR); + asm_fusestrref(as, ir, RSET_GPR); + if (as->mrm.base == RID_NONE) + emit_loadi(as, dest, as->mrm.ofs); + else if (as->mrm.base == dest && as->mrm.idx == RID_NONE) + emit_gri(as, XG_ARITHi(XOg_ADD), dest|REX_GC64, as->mrm.ofs); + else + emit_mrm(as, XO_LEA, dest|REX_GC64, RID_MRM); +} + +/* -- Loads and stores ---------------------------------------------------- */ + +static void asm_fxload(ASMState *as, IRIns *ir) +{ + Reg dest = ra_dest(as, ir, irt_isfp(ir->t) ? RSET_FPR : RSET_GPR); + x86Op xo; + if (ir->o == IR_FLOAD) + asm_fusefref(as, ir, RSET_GPR); + else + asm_fusexref(as, ir->op1, RSET_GPR); + /* ir->op2 is ignored -- unaligned loads are ok on x86. */ + switch (irt_type(ir->t)) { + case IRT_I8: xo = XO_MOVSXb; break; + case IRT_U8: xo = XO_MOVZXb; break; + case IRT_I16: xo = XO_MOVSXw; break; + case IRT_U16: xo = XO_MOVZXw; break; + case IRT_NUM: xo = XO_MOVSD; break; + case IRT_FLOAT: xo = XO_MOVSS; break; + default: + if (LJ_64 && irt_is64(ir->t)) + dest |= REX_64; + else + lj_assertA(irt_isint(ir->t) || irt_isu32(ir->t) || irt_isaddr(ir->t), + "unsplit 64 bit load"); + xo = XO_MOV; + break; + } + emit_mrm(as, xo, dest, RID_MRM); +} + +#define asm_fload(as, ir) asm_fxload(as, ir) +#define asm_xload(as, ir) asm_fxload(as, ir) + +static void asm_fxstore(ASMState *as, IRIns *ir) +{ + RegSet allow = RSET_GPR; + Reg src = RID_NONE, osrc = RID_NONE; + int32_t k = 0; + if (ir->r == RID_SINK) + return; + /* The IRT_I16/IRT_U16 stores should never be simplified for constant + ** values since mov word [mem], imm16 has a length-changing prefix. + */ + if (irt_isi16(ir->t) || irt_isu16(ir->t) || irt_isfp(ir->t) || + !asm_isk32(as, ir->op2, &k)) { + RegSet allow8 = irt_isfp(ir->t) ? RSET_FPR : + (irt_isi8(ir->t) || irt_isu8(ir->t)) ? RSET_GPR8 : RSET_GPR; + src = osrc = ra_alloc1(as, ir->op2, allow8); + if (!LJ_64 && !rset_test(allow8, src)) { /* Already in wrong register. */ + rset_clear(allow, osrc); + src = ra_scratch(as, allow8); + } + rset_clear(allow, src); + } + if (ir->o == IR_FSTORE) { + asm_fusefref(as, IR(ir->op1), allow); + } else { + asm_fusexref(as, ir->op1, allow); + if (LJ_32 && ir->o == IR_HIOP) as->mrm.ofs += 4; + } + if (ra_hasreg(src)) { + x86Op xo; + switch (irt_type(ir->t)) { + case IRT_I8: case IRT_U8: xo = XO_MOVtob; src |= FORCE_REX; break; + case IRT_I16: case IRT_U16: xo = XO_MOVtow; break; + case IRT_NUM: xo = XO_MOVSDto; break; + case IRT_FLOAT: xo = XO_MOVSSto; break; +#if LJ_64 && !LJ_GC64 + case IRT_LIGHTUD: + /* NYI: mask 64 bit lightuserdata. */ + lj_assertA(0, "store of lightuserdata"); +#endif + default: + if (LJ_64 && irt_is64(ir->t)) + src |= REX_64; + else + lj_assertA(irt_isint(ir->t) || irt_isu32(ir->t) || irt_isaddr(ir->t), + "unsplit 64 bit store"); + xo = XO_MOVto; + break; + } + emit_mrm(as, xo, src, RID_MRM); + if (!LJ_64 && src != osrc) { + ra_noweak(as, osrc); + emit_rr(as, XO_MOV, src, osrc); + } + } else { + if (irt_isi8(ir->t) || irt_isu8(ir->t)) { + emit_i8(as, k); + emit_mrm(as, XO_MOVmib, 0, RID_MRM); + } else { + lj_assertA(irt_is64(ir->t) || irt_isint(ir->t) || irt_isu32(ir->t) || + irt_isaddr(ir->t), "bad store type"); + emit_i32(as, k); + emit_mrm(as, XO_MOVmi, REX_64IR(ir, 0), RID_MRM); + } + } +} + +#define asm_fstore(as, ir) asm_fxstore(as, ir) +#define asm_xstore(as, ir) asm_fxstore(as, ir) + +#if LJ_64 && !LJ_GC64 +static Reg asm_load_lightud64(ASMState *as, IRIns *ir, int typecheck) +{ + if (ra_used(ir) || typecheck) { + Reg dest = ra_dest(as, ir, RSET_GPR); + if (typecheck) { + Reg tmp = ra_scratch(as, rset_exclude(RSET_GPR, dest)); + asm_guardcc(as, CC_NE); + emit_i8(as, -2); + emit_rr(as, XO_ARITHi8, XOg_CMP, tmp); + emit_shifti(as, XOg_SAR|REX_64, tmp, 47); + emit_rr(as, XO_MOV, tmp|REX_64, dest); + } + return dest; + } else { + return RID_NONE; + } +} +#endif + +static void asm_ahuvload(ASMState *as, IRIns *ir) +{ +#if LJ_GC64 + Reg tmp = RID_NONE; +#endif + lj_assertA(irt_isnum(ir->t) || irt_ispri(ir->t) || irt_isaddr(ir->t) || + (LJ_DUALNUM && irt_isint(ir->t)), + "bad load type %d", irt_type(ir->t)); +#if LJ_64 && !LJ_GC64 + if (irt_islightud(ir->t)) { + Reg dest = asm_load_lightud64(as, ir, 1); + if (ra_hasreg(dest)) { + asm_fuseahuref(as, ir->op1, RSET_GPR); + if (ir->o == IR_VLOAD) as->mrm.ofs += 8 * ir->op2; + emit_mrm(as, XO_MOV, dest|REX_64, RID_MRM); + } + return; + } else +#endif + if (ra_used(ir)) { + RegSet allow = irt_isnum(ir->t) ? RSET_FPR : RSET_GPR; + Reg dest = ra_dest(as, ir, allow); + asm_fuseahuref(as, ir->op1, RSET_GPR); + if (ir->o == IR_VLOAD) as->mrm.ofs += 8 * ir->op2; +#if LJ_GC64 + if (irt_isaddr(ir->t)) { + emit_shifti(as, XOg_SHR|REX_64, dest, 17); + asm_guardcc(as, CC_NE); + emit_i8(as, irt_toitype(ir->t)); + emit_rr(as, XO_ARITHi8, XOg_CMP, dest); + emit_i8(as, XI_O16); + if ((as->flags & JIT_F_BMI2)) { + emit_i8(as, 47); + emit_mrm(as, XV_RORX|VEX_64, dest, RID_MRM); + } else { + emit_shifti(as, XOg_ROR|REX_64, dest, 47); + emit_mrm(as, XO_MOV, dest|REX_64, RID_MRM); + } + return; + } else +#endif + emit_mrm(as, dest < RID_MAX_GPR ? XO_MOV : XO_MOVSD, dest, RID_MRM); + } else { + RegSet gpr = RSET_GPR; +#if LJ_GC64 + if (irt_isaddr(ir->t)) { + tmp = ra_scratch(as, RSET_GPR); + gpr = rset_exclude(gpr, tmp); + } +#endif + asm_fuseahuref(as, ir->op1, gpr); + if (ir->o == IR_VLOAD) as->mrm.ofs += 8 * ir->op2; + } + /* Always do the type check, even if the load result is unused. */ + as->mrm.ofs += 4; + asm_guardcc(as, irt_isnum(ir->t) ? CC_AE : CC_NE); + if (LJ_64 && irt_type(ir->t) >= IRT_NUM) { + lj_assertA(irt_isinteger(ir->t) || irt_isnum(ir->t), + "bad load type %d", irt_type(ir->t)); +#if LJ_GC64 + emit_u32(as, LJ_TISNUM << 15); +#else + emit_u32(as, LJ_TISNUM); +#endif + emit_mrm(as, XO_ARITHi, XOg_CMP, RID_MRM); +#if LJ_GC64 + } else if (irt_isaddr(ir->t)) { + as->mrm.ofs -= 4; + emit_i8(as, irt_toitype(ir->t)); + emit_mrm(as, XO_ARITHi8, XOg_CMP, tmp); + emit_shifti(as, XOg_SAR|REX_64, tmp, 47); + emit_mrm(as, XO_MOV, tmp|REX_64, RID_MRM); + } else if (irt_isnil(ir->t)) { + as->mrm.ofs -= 4; + emit_i8(as, -1); + emit_mrm(as, XO_ARITHi8, XOg_CMP|REX_64, RID_MRM); + } else { + emit_u32(as, (irt_toitype(ir->t) << 15) | 0x7fff); + emit_mrm(as, XO_ARITHi, XOg_CMP, RID_MRM); +#else + } else { + emit_i8(as, irt_toitype(ir->t)); + emit_mrm(as, XO_ARITHi8, XOg_CMP, RID_MRM); +#endif + } +} + +static void asm_ahustore(ASMState *as, IRIns *ir) +{ + if (ir->r == RID_SINK) + return; + if (irt_isnum(ir->t)) { + Reg src = ra_alloc1(as, ir->op2, RSET_FPR); + asm_fuseahuref(as, ir->op1, RSET_GPR); + emit_mrm(as, XO_MOVSDto, src, RID_MRM); +#if LJ_64 && !LJ_GC64 + } else if (irt_islightud(ir->t)) { + Reg src = ra_alloc1(as, ir->op2, RSET_GPR); + asm_fuseahuref(as, ir->op1, rset_exclude(RSET_GPR, src)); + emit_mrm(as, XO_MOVto, src|REX_64, RID_MRM); +#endif +#if LJ_GC64 + } else if (irref_isk(ir->op2)) { + TValue k; + lj_ir_kvalue(as->J->L, &k, IR(ir->op2)); + asm_fuseahuref(as, ir->op1, RSET_GPR); + if (tvisnil(&k)) { + emit_i32(as, -1); + emit_mrm(as, XO_MOVmi, REX_64, RID_MRM); + } else { + emit_u32(as, k.u32.lo); + emit_mrm(as, XO_MOVmi, 0, RID_MRM); + as->mrm.ofs += 4; + emit_u32(as, k.u32.hi); + emit_mrm(as, XO_MOVmi, 0, RID_MRM); + } +#endif + } else { + IRIns *irr = IR(ir->op2); + RegSet allow = RSET_GPR; + Reg src = RID_NONE; + if (!irref_isk(ir->op2)) { + src = ra_alloc1(as, ir->op2, allow); + rset_clear(allow, src); + } + asm_fuseahuref(as, ir->op1, allow); + if (ra_hasreg(src)) { +#if LJ_GC64 + if (!(LJ_DUALNUM && irt_isinteger(ir->t))) { + /* TODO: 64 bit store + 32 bit load-modify-store is suboptimal. */ + as->mrm.ofs += 4; + emit_u32(as, irt_toitype(ir->t) << 15); + emit_mrm(as, XO_ARITHi, XOg_OR, RID_MRM); + as->mrm.ofs -= 4; + emit_mrm(as, XO_MOVto, src|REX_64, RID_MRM); + return; + } +#endif + emit_mrm(as, XO_MOVto, src, RID_MRM); + } else if (!irt_ispri(irr->t)) { + lj_assertA(irt_isaddr(ir->t) || (LJ_DUALNUM && irt_isinteger(ir->t)), + "bad store type"); + emit_i32(as, irr->i); + emit_mrm(as, XO_MOVmi, 0, RID_MRM); + } + as->mrm.ofs += 4; +#if LJ_GC64 + lj_assertA(LJ_DUALNUM && irt_isinteger(ir->t), "bad store type"); + emit_i32(as, LJ_TNUMX << 15); +#else + emit_i32(as, (int32_t)irt_toitype(ir->t)); +#endif + emit_mrm(as, XO_MOVmi, 0, RID_MRM); + } +} + +static void asm_sload(ASMState *as, IRIns *ir) +{ + int32_t ofs = 8*((int32_t)ir->op1-1-LJ_FR2) + + (!LJ_FR2 && (ir->op2 & IRSLOAD_FRAME) ? 4 : 0); + IRType1 t = ir->t; + Reg base; + lj_assertA(!(ir->op2 & IRSLOAD_PARENT), + "bad parent SLOAD"); /* Handled by asm_head_side(). */ + lj_assertA(irt_isguard(t) || !(ir->op2 & IRSLOAD_TYPECHECK), + "inconsistent SLOAD variant"); + lj_assertA(LJ_DUALNUM || + !irt_isint(t) || + (ir->op2 & (IRSLOAD_CONVERT|IRSLOAD_FRAME|IRSLOAD_KEYINDEX)), + "bad SLOAD type"); + if ((ir->op2 & IRSLOAD_CONVERT) && irt_isguard(t) && irt_isint(t)) { + Reg left = ra_scratch(as, RSET_FPR); + asm_tointg(as, ir, left); /* Frees dest reg. Do this before base alloc. */ + base = ra_alloc1(as, REF_BASE, RSET_GPR); + emit_rmro(as, XO_MOVSD, left, base, ofs); + t.irt = IRT_NUM; /* Continue with a regular number type check. */ +#if LJ_64 && !LJ_GC64 + } else if (irt_islightud(t)) { + Reg dest = asm_load_lightud64(as, ir, (ir->op2 & IRSLOAD_TYPECHECK)); + if (ra_hasreg(dest)) { + base = ra_alloc1(as, REF_BASE, RSET_GPR); + emit_rmro(as, XO_MOV, dest|REX_64, base, ofs); + } + return; +#endif + } else if (ra_used(ir)) { + RegSet allow = irt_isnum(t) ? RSET_FPR : RSET_GPR; + Reg dest = ra_dest(as, ir, allow); + base = ra_alloc1(as, REF_BASE, RSET_GPR); + lj_assertA(irt_isnum(t) || irt_isint(t) || irt_isaddr(t), + "bad SLOAD type %d", irt_type(t)); + if ((ir->op2 & IRSLOAD_CONVERT)) { + t.irt = irt_isint(t) ? IRT_NUM : IRT_INT; /* Check for original type. */ + emit_rmro(as, irt_isint(t) ? XO_CVTSI2SD : XO_CVTTSD2SI, dest, base, ofs); + } else { +#if LJ_GC64 + if (irt_isaddr(t)) { + /* LJ_GC64 type check + tag removal without BMI2 and with BMI2: + ** + ** mov r64, [addr] rorx r64, [addr], 47 + ** ror r64, 47 + ** cmp r16, itype cmp r16, itype + ** jne ->exit jne ->exit + ** shr r64, 16 shr r64, 16 + */ + emit_shifti(as, XOg_SHR|REX_64, dest, 17); + if ((ir->op2 & IRSLOAD_TYPECHECK)) { + asm_guardcc(as, CC_NE); + emit_i8(as, irt_toitype(t)); + emit_rr(as, XO_ARITHi8, XOg_CMP, dest); + emit_i8(as, XI_O16); + } + if ((as->flags & JIT_F_BMI2)) { + emit_i8(as, 47); + emit_rmro(as, XV_RORX|VEX_64, dest, base, ofs); + } else { + if ((ir->op2 & IRSLOAD_TYPECHECK)) + emit_shifti(as, XOg_ROR|REX_64, dest, 47); + else + emit_shifti(as, XOg_SHL|REX_64, dest, 17); + emit_rmro(as, XO_MOV, dest|REX_64, base, ofs); + } + return; + } else +#endif + emit_rmro(as, irt_isnum(t) ? XO_MOVSD : XO_MOV, dest, base, ofs); + } + } else { + if (!(ir->op2 & IRSLOAD_TYPECHECK)) + return; /* No type check: avoid base alloc. */ + base = ra_alloc1(as, REF_BASE, RSET_GPR); + } + if ((ir->op2 & IRSLOAD_TYPECHECK)) { + /* Need type check, even if the load result is unused. */ + asm_guardcc(as, irt_isnum(t) ? CC_AE : CC_NE); + if ((LJ_64 && irt_type(t) >= IRT_NUM) || (ir->op2 & IRSLOAD_KEYINDEX)) { + lj_assertA(irt_isinteger(t) || irt_isnum(t), + "bad SLOAD type %d", irt_type(t)); + emit_u32(as, (ir->op2 & IRSLOAD_KEYINDEX) ? LJ_KEYINDEX : + LJ_GC64 ? (LJ_TISNUM << 15) : LJ_TISNUM); + emit_rmro(as, XO_ARITHi, XOg_CMP, base, ofs+4); +#if LJ_GC64 + } else if (irt_isnil(t)) { + /* LJ_GC64 type check for nil: + ** + ** cmp qword [addr], -1 + ** jne ->exit + */ + emit_i8(as, -1); + emit_rmro(as, XO_ARITHi8, XOg_CMP|REX_64, base, ofs); + } else if (irt_ispri(t)) { + emit_u32(as, (irt_toitype(t) << 15) | 0x7fff); + emit_rmro(as, XO_ARITHi, XOg_CMP, base, ofs+4); + } else { + /* LJ_GC64 type check only: + ** + ** mov r64, [addr] + ** sar r64, 47 + ** cmp r32, itype + ** jne ->exit + */ + Reg tmp = ra_scratch(as, rset_exclude(RSET_GPR, base)); + emit_i8(as, irt_toitype(t)); + emit_rr(as, XO_ARITHi8, XOg_CMP, tmp); + emit_shifti(as, XOg_SAR|REX_64, tmp, 47); + emit_rmro(as, XO_MOV, tmp|REX_64, base, ofs); +#else + } else { + emit_i8(as, irt_toitype(t)); + emit_rmro(as, XO_ARITHi8, XOg_CMP, base, ofs+4); +#endif + } + } +} + +/* -- Allocations --------------------------------------------------------- */ + +#if LJ_HASFFI +static void asm_cnew(ASMState *as, IRIns *ir) +{ + CTState *cts = ctype_ctsG(J2G(as->J)); + CTypeID id = (CTypeID)IR(ir->op1)->i; + CTSize sz; + CTInfo info = lj_ctype_info(cts, id, &sz); + const CCallInfo *ci = &lj_ir_callinfo[IRCALL_lj_mem_newgco]; + IRRef args[4]; + lj_assertA(sz != CTSIZE_INVALID || (ir->o == IR_CNEW && ir->op2 != REF_NIL), + "bad CNEW/CNEWI operands"); + + as->gcsteps++; + asm_setupresult(as, ir, ci); /* GCcdata * */ + + /* Initialize immutable cdata object. */ + if (ir->o == IR_CNEWI) { + RegSet allow = (RSET_GPR & ~RSET_SCRATCH); +#if LJ_64 + Reg r64 = sz == 8 ? REX_64 : 0; + if (irref_isk(ir->op2)) { + IRIns *irk = IR(ir->op2); + uint64_t k = (irk->o == IR_KINT64 || + (LJ_GC64 && (irk->o == IR_KPTR || irk->o == IR_KKPTR))) ? + ir_k64(irk)->u64 : (uint64_t)(uint32_t)irk->i; + if (sz == 4 || checki32((int64_t)k)) { + emit_i32(as, (int32_t)k); + emit_rmro(as, XO_MOVmi, r64, RID_RET, sizeof(GCcdata)); + } else { + emit_movtomro(as, RID_ECX + r64, RID_RET, sizeof(GCcdata)); + emit_loadu64(as, RID_ECX, k); + } + } else { + Reg r = ra_alloc1(as, ir->op2, allow); + emit_movtomro(as, r + r64, RID_RET, sizeof(GCcdata)); + } +#else + int32_t ofs = sizeof(GCcdata); + if (sz == 8) { + ofs += 4; ir++; + lj_assertA(ir->o == IR_HIOP, "missing CNEWI HIOP"); + } + do { + if (irref_isk(ir->op2)) { + emit_movmroi(as, RID_RET, ofs, IR(ir->op2)->i); + } else { + Reg r = ra_alloc1(as, ir->op2, allow); + emit_movtomro(as, r, RID_RET, ofs); + rset_clear(allow, r); + } + if (ofs == sizeof(GCcdata)) break; + ofs -= 4; ir--; + } while (1); +#endif + lj_assertA(sz == 4 || sz == 8, "bad CNEWI size %d", sz); + } else if (ir->op2 != REF_NIL) { /* Create VLA/VLS/aligned cdata. */ + ci = &lj_ir_callinfo[IRCALL_lj_cdata_newv]; + args[0] = ASMREF_L; /* lua_State *L */ + args[1] = ir->op1; /* CTypeID id */ + args[2] = ir->op2; /* CTSize sz */ + args[3] = ASMREF_TMP1; /* CTSize align */ + asm_gencall(as, ci, args); + emit_loadi(as, ra_releasetmp(as, ASMREF_TMP1), (int32_t)ctype_align(info)); + return; + } + + /* Combine initialization of marked, gct and ctypeid. */ + emit_movtomro(as, RID_ECX, RID_RET, offsetof(GCcdata, marked)); + emit_gri(as, XG_ARITHi(XOg_OR), RID_ECX, + (int32_t)((~LJ_TCDATA<<8)+(id<<16))); + emit_gri(as, XG_ARITHi(XOg_AND), RID_ECX, LJ_GC_WHITES); + emit_opgl(as, XO_MOVZXb, RID_ECX, gc.currentwhite); + + args[0] = ASMREF_L; /* lua_State *L */ + args[1] = ASMREF_TMP1; /* MSize size */ + asm_gencall(as, ci, args); + emit_loadi(as, ra_releasetmp(as, ASMREF_TMP1), (int32_t)(sz+sizeof(GCcdata))); +} +#endif + +/* -- Write barriers ------------------------------------------------------ */ + +static void asm_tbar(ASMState *as, IRIns *ir) +{ + Reg tab = ra_alloc1(as, ir->op1, RSET_GPR); + Reg tmp = ra_scratch(as, rset_exclude(RSET_GPR, tab)); + MCLabel l_end = emit_label(as); + emit_movtomro(as, tmp|REX_GC64, tab, offsetof(GCtab, gclist)); + emit_setgl(as, tab, gc.grayagain); + emit_getgl(as, tmp, gc.grayagain); + emit_i8(as, ~LJ_GC_BLACK); + emit_rmro(as, XO_ARITHib, XOg_AND, tab, offsetof(GCtab, marked)); + emit_sjcc(as, CC_Z, l_end); + emit_i8(as, LJ_GC_BLACK); + emit_rmro(as, XO_GROUP3b, XOg_TEST, tab, offsetof(GCtab, marked)); +} + +static void asm_obar(ASMState *as, IRIns *ir) +{ + const CCallInfo *ci = &lj_ir_callinfo[IRCALL_lj_gc_barrieruv]; + IRRef args[2]; + MCLabel l_end; + Reg obj; + /* No need for other object barriers (yet). */ + lj_assertA(IR(ir->op1)->o == IR_UREFC, "bad OBAR type"); + ra_evictset(as, RSET_SCRATCH); + l_end = emit_label(as); + args[0] = ASMREF_TMP1; /* global_State *g */ + args[1] = ir->op1; /* TValue *tv */ + asm_gencall(as, ci, args); + emit_loada(as, ra_releasetmp(as, ASMREF_TMP1), J2G(as->J)); + obj = IR(ir->op1)->r; + emit_sjcc(as, CC_Z, l_end); + emit_i8(as, LJ_GC_WHITES); + if (irref_isk(ir->op2)) { + GCobj *vp = ir_kgc(IR(ir->op2)); + emit_rma(as, XO_GROUP3b, XOg_TEST, &vp->gch.marked); + } else { + Reg val = ra_alloc1(as, ir->op2, rset_exclude(RSET_SCRATCH&RSET_GPR, obj)); + emit_rmro(as, XO_GROUP3b, XOg_TEST, val, (int32_t)offsetof(GChead, marked)); + } + emit_sjcc(as, CC_Z, l_end); + emit_i8(as, LJ_GC_BLACK); + emit_rmro(as, XO_GROUP3b, XOg_TEST, obj, + (int32_t)offsetof(GCupval, marked)-(int32_t)offsetof(GCupval, tv)); +} + +/* -- FP/int arithmetic and logic operations ------------------------------ */ + +/* Load reference onto x87 stack. Force a spill to memory if needed. */ +static void asm_x87load(ASMState *as, IRRef ref) +{ + IRIns *ir = IR(ref); + if (ir->o == IR_KNUM) { + cTValue *tv = ir_knum(ir); + if (tvispzero(tv)) /* Use fldz only for +0. */ + emit_x87op(as, XI_FLDZ); + else if (tvispone(tv)) + emit_x87op(as, XI_FLD1); + else + emit_rma(as, XO_FLDq, XOg_FLDq, tv); + } else if (ir->o == IR_CONV && ir->op2 == IRCONV_NUM_INT && !ra_used(ir) && + !irref_isk(ir->op1) && mayfuse(as, ir->op1)) { + IRIns *iri = IR(ir->op1); + emit_rmro(as, XO_FILDd, XOg_FILDd, RID_ESP, ra_spill(as, iri)); + } else { + emit_mrm(as, XO_FLDq, XOg_FLDq, asm_fuseload(as, ref, RSET_EMPTY)); + } +} + +static void asm_fpmath(ASMState *as, IRIns *ir) +{ + IRFPMathOp fpm = (IRFPMathOp)ir->op2; + if (fpm == IRFPM_SQRT) { + Reg dest = ra_dest(as, ir, RSET_FPR); + Reg left = asm_fuseload(as, ir->op1, RSET_FPR); + emit_mrm(as, XO_SQRTSD, dest, left); + } else if (fpm <= IRFPM_TRUNC) { + if (as->flags & JIT_F_SSE4_1) { /* SSE4.1 has a rounding instruction. */ + Reg dest = ra_dest(as, ir, RSET_FPR); + Reg left = asm_fuseload(as, ir->op1, RSET_FPR); + /* ROUNDSD has a 4-byte opcode which doesn't fit in x86Op. + ** Let's pretend it's a 3-byte opcode, and compensate afterwards. + ** This is atrocious, but the alternatives are much worse. + */ + /* Round down/up/trunc == 1001/1010/1011. */ + emit_i8(as, 0x09 + fpm); + emit_mrm(as, XO_ROUNDSD, dest, left); + if (LJ_64 && as->mcp[1] != (MCode)(XO_ROUNDSD >> 16)) { + as->mcp[0] = as->mcp[1]; as->mcp[1] = 0x0f; /* Swap 0F and REX. */ + } + *--as->mcp = 0x66; /* 1st byte of ROUNDSD opcode. */ + } else { /* Call helper functions for SSE2 variant. */ + /* The modified regs must match with the *.dasc implementation. */ + RegSet drop = RSET_RANGE(RID_XMM0, RID_XMM3+1)|RID2RSET(RID_EAX); + if (ra_hasreg(ir->r)) + rset_clear(drop, ir->r); /* Dest reg handled below. */ + ra_evictset(as, drop); + ra_destreg(as, ir, RID_XMM0); + emit_call(as, fpm == IRFPM_FLOOR ? lj_vm_floor_sse : + fpm == IRFPM_CEIL ? lj_vm_ceil_sse : lj_vm_trunc_sse); + ra_left(as, RID_XMM0, ir->op1); + } + } else { + asm_callid(as, ir, IRCALL_lj_vm_floor + fpm); + } +} + +static void asm_ldexp(ASMState *as, IRIns *ir) +{ + int32_t ofs = sps_scale(ir->s); /* Use spill slot or temp slots. */ + Reg dest = ir->r; + if (ra_hasreg(dest)) { + ra_free(as, dest); + ra_modified(as, dest); + emit_rmro(as, XO_MOVSD, dest, RID_ESP, ofs); + } + emit_rmro(as, XO_FSTPq, XOg_FSTPq, RID_ESP, ofs); + emit_x87op(as, XI_FPOP1); + emit_x87op(as, XI_FSCALE); + asm_x87load(as, ir->op1); + asm_x87load(as, ir->op2); +} + +static int asm_swapops(ASMState *as, IRIns *ir) +{ + IRIns *irl = IR(ir->op1); + IRIns *irr = IR(ir->op2); + lj_assertA(ra_noreg(irr->r), "bad usage"); + if (!irm_iscomm(lj_ir_mode[ir->o])) + return 0; /* Can't swap non-commutative operations. */ + if (irref_isk(ir->op2)) + return 0; /* Don't swap constants to the left. */ + if (ra_hasreg(irl->r)) + return 1; /* Swap if left already has a register. */ + if (ra_samehint(ir->r, irr->r)) + return 1; /* Swap if dest and right have matching hints. */ + if (as->curins > as->loopref) { /* In variant part? */ + if (ir->op2 < as->loopref && !irt_isphi(irr->t)) + return 0; /* Keep invariants on the right. */ + if (ir->op1 < as->loopref && !irt_isphi(irl->t)) + return 1; /* Swap invariants to the right. */ + } + if (opisfusableload(irl->o)) + return 1; /* Swap fusable loads to the right. */ + return 0; /* Otherwise don't swap. */ +} + +static void asm_fparith(ASMState *as, IRIns *ir, x86Op xo) +{ + IRRef lref = ir->op1; + IRRef rref = ir->op2; + RegSet allow = RSET_FPR; + Reg dest; + Reg right = IR(rref)->r; + if (ra_hasreg(right)) { + rset_clear(allow, right); + ra_noweak(as, right); + } + dest = ra_dest(as, ir, allow); + if (lref == rref) { + right = dest; + } else if (ra_noreg(right)) { + if (asm_swapops(as, ir)) { + IRRef tmp = lref; lref = rref; rref = tmp; + } + right = asm_fuseload(as, rref, rset_clear(allow, dest)); + } + emit_mrm(as, xo, dest, right); + ra_left(as, dest, lref); +} + +static void asm_intarith(ASMState *as, IRIns *ir, x86Arith xa) +{ + IRRef lref = ir->op1; + IRRef rref = ir->op2; + RegSet allow = RSET_GPR; + Reg dest, right; + int32_t k = 0; + if (as->flagmcp == as->mcp) { /* Drop test r,r instruction. */ + MCode *p = as->mcp + ((LJ_64 && *as->mcp < XI_TESTb) ? 3 : 2); + MCode *q = p[0] == 0x0f ? p+1 : p; + if ((*q & 15) < 14) { + if ((*q & 15) >= 12) *q -= 4; /* L <->S, NL <-> NS */ + as->flagmcp = NULL; + as->mcp = p; + } /* else: cannot transform LE/NLE to cc without use of OF. */ + } + right = IR(rref)->r; + if (ra_hasreg(right)) { + rset_clear(allow, right); + ra_noweak(as, right); + } + dest = ra_dest(as, ir, allow); + if (lref == rref) { + right = dest; + } else if (ra_noreg(right) && !asm_isk32(as, rref, &k)) { + if (asm_swapops(as, ir)) { + IRRef tmp = lref; lref = rref; rref = tmp; + } + right = asm_fuseloadm(as, rref, rset_clear(allow, dest), irt_is64(ir->t)); + } + if (irt_isguard(ir->t)) /* For IR_ADDOV etc. */ + asm_guardcc(as, CC_O); + if (xa != XOg_X_IMUL) { + if (ra_hasreg(right)) + emit_mrm(as, XO_ARITH(xa), REX_64IR(ir, dest), right); + else + emit_gri(as, XG_ARITHi(xa), REX_64IR(ir, dest), k); + } else if (ra_hasreg(right)) { /* IMUL r, mrm. */ + emit_mrm(as, XO_IMUL, REX_64IR(ir, dest), right); + } else { /* IMUL r, r, k. */ + /* NYI: use lea/shl/add/sub (FOLD only does 2^k) depending on CPU. */ + Reg left = asm_fuseloadm(as, lref, RSET_GPR, irt_is64(ir->t)); + x86Op xo; + if (checki8(k)) { emit_i8(as, k); xo = XO_IMULi8; + } else { emit_i32(as, k); xo = XO_IMULi; } + emit_mrm(as, xo, REX_64IR(ir, dest), left); + return; + } + ra_left(as, dest, lref); +} + +/* LEA is really a 4-operand ADD with an independent destination register, +** up to two source registers and an immediate. One register can be scaled +** by 1, 2, 4 or 8. This can be used to avoid moves or to fuse several +** instructions. +** +** Currently only a few common cases are supported: +** - 3-operand ADD: y = a+b; y = a+k with a and b already allocated +** - Left ADD fusion: y = (a+b)+k; y = (a+k)+b +** - Right ADD fusion: y = a+(b+k) +** The ommited variants have already been reduced by FOLD. +** +** There are more fusion opportunities, like gathering shifts or joining +** common references. But these are probably not worth the trouble, since +** array indexing is not decomposed and already makes use of all fields +** of the ModRM operand. +*/ +static int asm_lea(ASMState *as, IRIns *ir) +{ + IRIns *irl = IR(ir->op1); + IRIns *irr = IR(ir->op2); + RegSet allow = RSET_GPR; + Reg dest; + as->mrm.base = as->mrm.idx = RID_NONE; + as->mrm.scale = XM_SCALE1; + as->mrm.ofs = 0; + if (ra_hasreg(irl->r)) { + rset_clear(allow, irl->r); + ra_noweak(as, irl->r); + as->mrm.base = irl->r; + if (irref_isk(ir->op2) || ra_hasreg(irr->r)) { + /* The PHI renaming logic does a better job in some cases. */ + if (ra_hasreg(ir->r) && + ((irt_isphi(irl->t) && as->phireg[ir->r] == ir->op1) || + (irt_isphi(irr->t) && as->phireg[ir->r] == ir->op2))) + return 0; + if (irref_isk(ir->op2)) { + as->mrm.ofs = irr->i; + } else { + rset_clear(allow, irr->r); + ra_noweak(as, irr->r); + as->mrm.idx = irr->r; + } + } else if (irr->o == IR_ADD && mayfuse(as, ir->op2) && + irref_isk(irr->op2)) { + Reg idx = ra_alloc1(as, irr->op1, allow); + rset_clear(allow, idx); + as->mrm.idx = (uint8_t)idx; + as->mrm.ofs = IR(irr->op2)->i; + } else { + return 0; + } + } else if (ir->op1 != ir->op2 && irl->o == IR_ADD && mayfuse(as, ir->op1) && + (irref_isk(ir->op2) || irref_isk(irl->op2))) { + Reg idx, base = ra_alloc1(as, irl->op1, allow); + rset_clear(allow, base); + as->mrm.base = (uint8_t)base; + if (irref_isk(ir->op2)) { + as->mrm.ofs = irr->i; + idx = ra_alloc1(as, irl->op2, allow); + } else { + as->mrm.ofs = IR(irl->op2)->i; + idx = ra_alloc1(as, ir->op2, allow); + } + rset_clear(allow, idx); + as->mrm.idx = (uint8_t)idx; + } else { + return 0; + } + dest = ra_dest(as, ir, allow); + emit_mrm(as, XO_LEA, dest, RID_MRM); + return 1; /* Success. */ +} + +static void asm_add(ASMState *as, IRIns *ir) +{ + if (irt_isnum(ir->t)) + asm_fparith(as, ir, XO_ADDSD); + else if (as->flagmcp == as->mcp || irt_is64(ir->t) || !asm_lea(as, ir)) + asm_intarith(as, ir, XOg_ADD); +} + +static void asm_sub(ASMState *as, IRIns *ir) +{ + if (irt_isnum(ir->t)) + asm_fparith(as, ir, XO_SUBSD); + else /* Note: no need for LEA trick here. i-k is encoded as i+(-k). */ + asm_intarith(as, ir, XOg_SUB); +} + +static void asm_mul(ASMState *as, IRIns *ir) +{ + if (irt_isnum(ir->t)) + asm_fparith(as, ir, XO_MULSD); + else + asm_intarith(as, ir, XOg_X_IMUL); +} + +#define asm_fpdiv(as, ir) asm_fparith(as, ir, XO_DIVSD) + +static void asm_neg_not(ASMState *as, IRIns *ir, x86Group3 xg) +{ + Reg dest = ra_dest(as, ir, RSET_GPR); + emit_rr(as, XO_GROUP3, REX_64IR(ir, xg), dest); + ra_left(as, dest, ir->op1); +} + +static void asm_neg(ASMState *as, IRIns *ir) +{ + if (irt_isnum(ir->t)) + asm_fparith(as, ir, XO_XORPS); + else + asm_neg_not(as, ir, XOg_NEG); +} + +#define asm_abs(as, ir) asm_fparith(as, ir, XO_ANDPS) + +static void asm_intmin_max(ASMState *as, IRIns *ir, int cc) +{ + Reg right, dest = ra_dest(as, ir, RSET_GPR); + IRRef lref = ir->op1, rref = ir->op2; + if (irref_isk(rref)) { lref = rref; rref = ir->op1; } + right = ra_alloc1(as, rref, rset_exclude(RSET_GPR, dest)); + emit_rr(as, XO_CMOV + (cc<<24), REX_64IR(ir, dest), right); + emit_rr(as, XO_CMP, REX_64IR(ir, dest), right); + ra_left(as, dest, lref); +} + +static void asm_min(ASMState *as, IRIns *ir) +{ + if (irt_isnum(ir->t)) + asm_fparith(as, ir, XO_MINSD); + else + asm_intmin_max(as, ir, CC_G); +} + +static void asm_max(ASMState *as, IRIns *ir) +{ + if (irt_isnum(ir->t)) + asm_fparith(as, ir, XO_MAXSD); + else + asm_intmin_max(as, ir, CC_L); +} + +/* Note: don't use LEA for overflow-checking arithmetic! */ +#define asm_addov(as, ir) asm_intarith(as, ir, XOg_ADD) +#define asm_subov(as, ir) asm_intarith(as, ir, XOg_SUB) +#define asm_mulov(as, ir) asm_intarith(as, ir, XOg_X_IMUL) + +#define asm_bnot(as, ir) asm_neg_not(as, ir, XOg_NOT) + +static void asm_bswap(ASMState *as, IRIns *ir) +{ + Reg dest = ra_dest(as, ir, RSET_GPR); + as->mcp = emit_op(XO_BSWAP + ((dest&7) << 24), + REX_64IR(ir, 0), dest, 0, as->mcp, 1); + ra_left(as, dest, ir->op1); +} + +#define asm_band(as, ir) asm_intarith(as, ir, XOg_AND) +#define asm_bor(as, ir) asm_intarith(as, ir, XOg_OR) +#define asm_bxor(as, ir) asm_intarith(as, ir, XOg_XOR) + +static void asm_bitshift(ASMState *as, IRIns *ir, x86Shift xs, x86Op xv) +{ + IRRef rref = ir->op2; + IRIns *irr = IR(rref); + Reg dest; + if (irref_isk(rref)) { /* Constant shifts. */ + int shift; + dest = ra_dest(as, ir, RSET_GPR); + shift = irr->i & (irt_is64(ir->t) ? 63 : 31); + if (!xv && shift && (as->flags & JIT_F_BMI2)) { + Reg left = asm_fuseloadm(as, ir->op1, RSET_GPR, irt_is64(ir->t)); + if (left != dest) { /* BMI2 rotate right by constant. */ + emit_i8(as, xs == XOg_ROL ? -shift : shift); + emit_mrm(as, VEX_64IR(ir, XV_RORX), dest, left); + return; + } + } + switch (shift) { + case 0: break; + case 1: emit_rr(as, XO_SHIFT1, REX_64IR(ir, xs), dest); break; + default: emit_shifti(as, REX_64IR(ir, xs), dest, shift); break; + } + } else if ((as->flags & JIT_F_BMI2) && xv) { /* BMI2 variable shifts. */ + Reg left, right; + dest = ra_dest(as, ir, RSET_GPR); + right = ra_alloc1(as, rref, RSET_GPR); + left = asm_fuseloadm(as, ir->op1, rset_exclude(RSET_GPR, right), + irt_is64(ir->t)); + emit_mrm(as, VEX_64IR(ir, xv) ^ (right << 19), dest, left); + return; + } else { /* Variable shifts implicitly use register cl (i.e. ecx). */ + Reg right; + dest = ra_dest(as, ir, rset_exclude(RSET_GPR, RID_ECX)); + if (dest == RID_ECX) { + dest = ra_scratch(as, rset_exclude(RSET_GPR, RID_ECX)); + emit_rr(as, XO_MOV, REX_64IR(ir, RID_ECX), dest); + } + right = irr->r; + if (ra_noreg(right)) + right = ra_allocref(as, rref, RID2RSET(RID_ECX)); + else if (right != RID_ECX) + ra_scratch(as, RID2RSET(RID_ECX)); + emit_rr(as, XO_SHIFTcl, REX_64IR(ir, xs), dest); + ra_noweak(as, right); + if (right != RID_ECX) + emit_rr(as, XO_MOV, RID_ECX, right); + } + ra_left(as, dest, ir->op1); + /* + ** Note: avoid using the flags resulting from a shift or rotate! + ** All of them cause a partial flag stall, except for r,1 shifts + ** (but not rotates). And a shift count of 0 leaves the flags unmodified. + */ +} + +#define asm_bshl(as, ir) asm_bitshift(as, ir, XOg_SHL, XV_SHLX) +#define asm_bshr(as, ir) asm_bitshift(as, ir, XOg_SHR, XV_SHRX) +#define asm_bsar(as, ir) asm_bitshift(as, ir, XOg_SAR, XV_SARX) +#define asm_brol(as, ir) asm_bitshift(as, ir, XOg_ROL, 0) +#define asm_bror(as, ir) asm_bitshift(as, ir, XOg_ROR, 0) + +/* -- Comparisons --------------------------------------------------------- */ + +/* Virtual flags for unordered FP comparisons. */ +#define VCC_U 0x1000 /* Unordered. */ +#define VCC_P 0x2000 /* Needs extra CC_P branch. */ +#define VCC_S 0x4000 /* Swap avoids CC_P branch. */ +#define VCC_PS (VCC_P|VCC_S) + +/* Map of comparisons to flags. ORDER IR. */ +#define COMPFLAGS(ci, cin, cu, cf) ((ci)+((cu)<<4)+((cin)<<8)+(cf)) +static const uint16_t asm_compmap[IR_ABC+1] = { + /* signed non-eq unsigned flags */ + /* LT */ COMPFLAGS(CC_GE, CC_G, CC_AE, VCC_PS), + /* GE */ COMPFLAGS(CC_L, CC_L, CC_B, 0), + /* LE */ COMPFLAGS(CC_G, CC_G, CC_A, VCC_PS), + /* GT */ COMPFLAGS(CC_LE, CC_L, CC_BE, 0), + /* ULT */ COMPFLAGS(CC_AE, CC_A, CC_AE, VCC_U), + /* UGE */ COMPFLAGS(CC_B, CC_B, CC_B, VCC_U|VCC_PS), + /* ULE */ COMPFLAGS(CC_A, CC_A, CC_A, VCC_U), + /* UGT */ COMPFLAGS(CC_BE, CC_B, CC_BE, VCC_U|VCC_PS), + /* EQ */ COMPFLAGS(CC_NE, CC_NE, CC_NE, VCC_P), + /* NE */ COMPFLAGS(CC_E, CC_E, CC_E, VCC_U|VCC_P), + /* ABC */ COMPFLAGS(CC_BE, CC_B, CC_BE, VCC_U|VCC_PS) /* Same as UGT. */ +}; + +/* FP and integer comparisons. */ +static void asm_comp(ASMState *as, IRIns *ir) +{ + uint32_t cc = asm_compmap[ir->o]; + if (irt_isnum(ir->t)) { + IRRef lref = ir->op1; + IRRef rref = ir->op2; + Reg left, right; + MCLabel l_around; + /* + ** An extra CC_P branch is required to preserve ordered/unordered + ** semantics for FP comparisons. This can be avoided by swapping + ** the operands and inverting the condition (except for EQ and UNE). + ** So always try to swap if possible. + ** + ** Another option would be to swap operands to achieve better memory + ** operand fusion. But it's unlikely that this outweighs the cost + ** of the extra branches. + */ + if (cc & VCC_S) { /* Swap? */ + IRRef tmp = lref; lref = rref; rref = tmp; + cc ^= (VCC_PS|(5<<4)); /* A <-> B, AE <-> BE, PS <-> none */ + } + left = ra_alloc1(as, lref, RSET_FPR); + l_around = emit_label(as); + asm_guardcc(as, cc >> 4); + if (cc & VCC_P) { /* Extra CC_P branch required? */ + if (!(cc & VCC_U)) { + asm_guardcc(as, CC_P); /* Branch to exit for ordered comparisons. */ + } else if (l_around != as->invmcp) { + emit_sjcc(as, CC_P, l_around); /* Branch around for unordered. */ + } else { + /* Patched to mcloop by asm_loop_fixup. */ + as->loopinv = 2; + if (as->realign) + emit_sjcc(as, CC_P, as->mcp); + else + emit_jcc(as, CC_P, as->mcp); + } + } + right = asm_fuseload(as, rref, rset_exclude(RSET_FPR, left)); + emit_mrm(as, XO_UCOMISD, left, right); + } else { + IRRef lref = ir->op1, rref = ir->op2; + IROp leftop = (IROp)(IR(lref)->o); + Reg r64 = REX_64IR(ir, 0); + int32_t imm = 0; + lj_assertA(irt_is64(ir->t) || irt_isint(ir->t) || + irt_isu32(ir->t) || irt_isaddr(ir->t) || irt_isu8(ir->t), + "bad comparison data type %d", irt_type(ir->t)); + /* Swap constants (only for ABC) and fusable loads to the right. */ + if (irref_isk(lref) || (!irref_isk(rref) && opisfusableload(leftop))) { + if ((cc & 0xc) == 0xc) cc ^= 0x53; /* L <-> G, LE <-> GE */ + else if ((cc & 0xa) == 0x2) cc ^= 0x55; /* A <-> B, AE <-> BE */ + lref = ir->op2; rref = ir->op1; + } + if (asm_isk32(as, rref, &imm)) { + IRIns *irl = IR(lref); + /* Check wether we can use test ins. Not for unsigned, since CF=0. */ + int usetest = (imm == 0 && (cc & 0xa) != 0x2); + if (usetest && irl->o == IR_BAND && irl+1 == ir && !ra_used(irl)) { + /* Combine comp(BAND(ref, r/imm), 0) into test mrm, r/imm. */ + Reg right, left = RID_NONE; + RegSet allow = RSET_GPR; + if (!asm_isk32(as, irl->op2, &imm)) { + left = ra_alloc1(as, irl->op2, allow); + rset_clear(allow, left); + } else { /* Try to Fuse IRT_I8/IRT_U8 loads, too. See below. */ + IRIns *irll = IR(irl->op1); + if (opisfusableload((IROp)irll->o) && + (irt_isi8(irll->t) || irt_isu8(irll->t))) { + IRType1 origt = irll->t; /* Temporarily flip types. */ + irll->t.irt = (irll->t.irt & ~IRT_TYPE) | IRT_INT; + as->curins--; /* Skip to BAND to avoid failing in noconflict(). */ + right = asm_fuseload(as, irl->op1, RSET_GPR); + as->curins++; + irll->t = origt; + if (right != RID_MRM) goto test_nofuse; + /* Fusion succeeded, emit test byte mrm, imm8. */ + asm_guardcc(as, cc); + emit_i8(as, (imm & 0xff)); + emit_mrm(as, XO_GROUP3b, XOg_TEST, RID_MRM); + return; + } + } + as->curins--; /* Skip to BAND to avoid failing in noconflict(). */ + right = asm_fuseloadm(as, irl->op1, allow, r64); + as->curins++; /* Undo the above. */ + test_nofuse: + asm_guardcc(as, cc); + if (ra_noreg(left)) { + emit_i32(as, imm); + emit_mrm(as, XO_GROUP3, r64 + XOg_TEST, right); + } else { + emit_mrm(as, XO_TEST, r64 + left, right); + } + } else { + Reg left; + if (opisfusableload((IROp)irl->o) && + ((irt_isu8(irl->t) && checku8(imm)) || + ((irt_isi8(irl->t) || irt_isi16(irl->t)) && checki8(imm)) || + (irt_isu16(irl->t) && checku16(imm) && checki8((int16_t)imm)))) { + /* Only the IRT_INT case is fused by asm_fuseload. + ** The IRT_I8/IRT_U8 loads and some IRT_I16/IRT_U16 loads + ** are handled here. + ** Note that cmp word [mem], imm16 should not be generated, + ** since it has a length-changing prefix. Compares of a word + ** against a sign-extended imm8 are ok, however. + */ + IRType1 origt = irl->t; /* Temporarily flip types. */ + irl->t.irt = (irl->t.irt & ~IRT_TYPE) | IRT_INT; + left = asm_fuseload(as, lref, RSET_GPR); + irl->t = origt; + if (left == RID_MRM) { /* Fusion succeeded? */ + if (irt_isu8(irl->t) || irt_isu16(irl->t)) + cc >>= 4; /* Need unsigned compare. */ + asm_guardcc(as, cc); + emit_i8(as, imm); + emit_mrm(as, (irt_isi8(origt) || irt_isu8(origt)) ? + XO_ARITHib : XO_ARITHiw8, r64 + XOg_CMP, RID_MRM); + return; + } /* Otherwise handle register case as usual. */ + } else { + left = asm_fuseloadm(as, lref, + irt_isu8(ir->t) ? RSET_GPR8 : RSET_GPR, r64); + } + asm_guardcc(as, cc); + if (usetest && left != RID_MRM) { + /* Use test r,r instead of cmp r,0. */ + x86Op xo = XO_TEST; + if (irt_isu8(ir->t)) { + lj_assertA(ir->o == IR_EQ || ir->o == IR_NE, "bad usage"); + xo = XO_TESTb; + if (!rset_test(RSET_RANGE(RID_EAX, RID_EBX+1), left)) { + if (LJ_64) { + left |= FORCE_REX; + } else { + emit_i32(as, 0xff); + emit_mrm(as, XO_GROUP3, XOg_TEST, left); + return; + } + } + } + emit_rr(as, xo, r64 + left, left); + if (irl+1 == ir) /* Referencing previous ins? */ + as->flagmcp = as->mcp; /* Set flag to drop test r,r if possible. */ + } else { + emit_gmrmi(as, XG_ARITHi(XOg_CMP), r64 + left, imm); + } + } + } else { + Reg left = ra_alloc1(as, lref, RSET_GPR); + Reg right = asm_fuseloadm(as, rref, rset_exclude(RSET_GPR, left), r64); + asm_guardcc(as, cc); + emit_mrm(as, XO_CMP, r64 + left, right); + } + } +} + +#define asm_equal(as, ir) asm_comp(as, ir) + +#if LJ_32 && LJ_HASFFI +/* 64 bit integer comparisons in 32 bit mode. */ +static void asm_comp_int64(ASMState *as, IRIns *ir) +{ + uint32_t cc = asm_compmap[(ir-1)->o]; + RegSet allow = RSET_GPR; + Reg lefthi = RID_NONE, leftlo = RID_NONE; + Reg righthi = RID_NONE, rightlo = RID_NONE; + MCLabel l_around; + x86ModRM mrm; + + as->curins--; /* Skip loword ins. Avoids failing in noconflict(), too. */ + + /* Allocate/fuse hiword operands. */ + if (irref_isk(ir->op2)) { + lefthi = asm_fuseload(as, ir->op1, allow); + } else { + lefthi = ra_alloc1(as, ir->op1, allow); + rset_clear(allow, lefthi); + righthi = asm_fuseload(as, ir->op2, allow); + if (righthi == RID_MRM) { + if (as->mrm.base != RID_NONE) rset_clear(allow, as->mrm.base); + if (as->mrm.idx != RID_NONE) rset_clear(allow, as->mrm.idx); + } else { + rset_clear(allow, righthi); + } + } + mrm = as->mrm; /* Save state for hiword instruction. */ + + /* Allocate/fuse loword operands. */ + if (irref_isk((ir-1)->op2)) { + leftlo = asm_fuseload(as, (ir-1)->op1, allow); + } else { + leftlo = ra_alloc1(as, (ir-1)->op1, allow); + rset_clear(allow, leftlo); + rightlo = asm_fuseload(as, (ir-1)->op2, allow); + } + + /* All register allocations must be performed _before_ this point. */ + l_around = emit_label(as); + as->invmcp = as->flagmcp = NULL; /* Cannot use these optimizations. */ + + /* Loword comparison and branch. */ + asm_guardcc(as, cc >> 4); /* Always use unsigned compare for loword. */ + if (ra_noreg(rightlo)) { + int32_t imm = IR((ir-1)->op2)->i; + if (imm == 0 && ((cc >> 4) & 0xa) != 0x2 && leftlo != RID_MRM) + emit_rr(as, XO_TEST, leftlo, leftlo); + else + emit_gmrmi(as, XG_ARITHi(XOg_CMP), leftlo, imm); + } else { + emit_mrm(as, XO_CMP, leftlo, rightlo); + } + + /* Hiword comparison and branches. */ + if ((cc & 15) != CC_NE) + emit_sjcc(as, CC_NE, l_around); /* Hiword unequal: skip loword compare. */ + if ((cc & 15) != CC_E) + asm_guardcc(as, cc >> 8); /* Hiword compare without equality check. */ + as->mrm = mrm; /* Restore state. */ + if (ra_noreg(righthi)) { + int32_t imm = IR(ir->op2)->i; + if (imm == 0 && (cc & 0xa) != 0x2 && lefthi != RID_MRM) + emit_rr(as, XO_TEST, lefthi, lefthi); + else + emit_gmrmi(as, XG_ARITHi(XOg_CMP), lefthi, imm); + } else { + emit_mrm(as, XO_CMP, lefthi, righthi); + } +} +#endif + +/* -- Split register ops -------------------------------------------------- */ + +/* Hiword op of a split 32/32 or 64/64 bit op. Previous op is the loword op. */ +static void asm_hiop(ASMState *as, IRIns *ir) +{ + /* HIOP is marked as a store because it needs its own DCE logic. */ + int uselo = ra_used(ir-1), usehi = ra_used(ir); /* Loword/hiword used? */ + if (LJ_UNLIKELY(!(as->flags & JIT_F_OPT_DCE))) uselo = usehi = 1; +#if LJ_32 && LJ_HASFFI + if ((ir-1)->o == IR_CONV) { /* Conversions to/from 64 bit. */ + as->curins--; /* Always skip the CONV. */ + if (usehi || uselo) + asm_conv64(as, ir); + return; + } else if ((ir-1)->o <= IR_NE) { /* 64 bit integer comparisons. ORDER IR. */ + asm_comp_int64(as, ir); + return; + } else if ((ir-1)->o == IR_XSTORE) { + if ((ir-1)->r != RID_SINK) + asm_fxstore(as, ir); + return; + } +#endif + if (!usehi) return; /* Skip unused hiword op for all remaining ops. */ + switch ((ir-1)->o) { +#if LJ_32 && LJ_HASFFI + case IR_ADD: + as->flagmcp = NULL; + as->curins--; + asm_intarith(as, ir, XOg_ADC); + asm_intarith(as, ir-1, XOg_ADD); + break; + case IR_SUB: + as->flagmcp = NULL; + as->curins--; + asm_intarith(as, ir, XOg_SBB); + asm_intarith(as, ir-1, XOg_SUB); + break; + case IR_NEG: { + Reg dest = ra_dest(as, ir, RSET_GPR); + emit_rr(as, XO_GROUP3, XOg_NEG, dest); + emit_i8(as, 0); + emit_rr(as, XO_ARITHi8, XOg_ADC, dest); + ra_left(as, dest, ir->op1); + as->curins--; + asm_neg_not(as, ir-1, XOg_NEG); + break; + } + case IR_CNEWI: + /* Nothing to do here. Handled by CNEWI itself. */ + break; +#endif + case IR_CALLN: case IR_CALLL: case IR_CALLS: case IR_CALLXS: + if (!uselo) + ra_allocref(as, ir->op1, RID2RSET(RID_RETLO)); /* Mark lo op as used. */ + break; + default: lj_assertA(0, "bad HIOP for op %d", (ir-1)->o); break; + } +} + +/* -- Profiling ----------------------------------------------------------- */ + +static void asm_prof(ASMState *as, IRIns *ir) +{ + UNUSED(ir); + asm_guardcc(as, CC_NE); + emit_i8(as, HOOK_PROFILE); + emit_rma(as, XO_GROUP3b, XOg_TEST, &J2G(as->J)->hookmask); +} + +/* -- Stack handling ------------------------------------------------------ */ + +/* Check Lua stack size for overflow. Use exit handler as fallback. */ +static void asm_stack_check(ASMState *as, BCReg topslot, + IRIns *irp, RegSet allow, ExitNo exitno) +{ + /* Try to get an unused temp. register, otherwise spill/restore eax. */ + Reg pbase = irp ? irp->r : RID_BASE; + Reg r = allow ? rset_pickbot(allow) : RID_EAX; + emit_jcc(as, CC_B, exitstub_addr(as->J, exitno)); + if (allow == RSET_EMPTY) /* Restore temp. register. */ + emit_rmro(as, XO_MOV, r|REX_64, RID_ESP, 0); + else + ra_modified(as, r); + emit_gri(as, XG_ARITHi(XOg_CMP), r|REX_GC64, (int32_t)(8*topslot)); + if (ra_hasreg(pbase) && pbase != r) + emit_rr(as, XO_ARITH(XOg_SUB), r|REX_GC64, pbase); + else +#if LJ_GC64 + emit_rmro(as, XO_ARITH(XOg_SUB), r|REX_64, RID_DISPATCH, + (int32_t)dispofs(as, &J2G(as->J)->jit_base)); +#else + emit_rmro(as, XO_ARITH(XOg_SUB), r, RID_NONE, + ptr2addr(&J2G(as->J)->jit_base)); +#endif + emit_rmro(as, XO_MOV, r|REX_GC64, r, offsetof(lua_State, maxstack)); + emit_getgl(as, r, cur_L); + if (allow == RSET_EMPTY) /* Spill temp. register. */ + emit_rmro(as, XO_MOVto, r|REX_64, RID_ESP, 0); +} + +/* Restore Lua stack from on-trace state. */ +static void asm_stack_restore(ASMState *as, SnapShot *snap) +{ + SnapEntry *map = &as->T->snapmap[snap->mapofs]; +#if !LJ_FR2 || defined(LUA_USE_ASSERT) + SnapEntry *flinks = &as->T->snapmap[snap_nextofs(as->T, snap)-1-LJ_FR2]; +#endif + MSize n, nent = snap->nent; + /* Store the value of all modified slots to the Lua stack. */ + for (n = 0; n < nent; n++) { + SnapEntry sn = map[n]; + BCReg s = snap_slot(sn); + int32_t ofs = 8*((int32_t)s-1-LJ_FR2); + IRRef ref = snap_ref(sn); + IRIns *ir = IR(ref); + if ((sn & SNAP_NORESTORE)) + continue; + if ((sn & SNAP_KEYINDEX)) { + emit_movmroi(as, RID_BASE, ofs+4, LJ_KEYINDEX); + if (irref_isk(ref)) { + emit_movmroi(as, RID_BASE, ofs, ir->i); + } else { + Reg src = ra_alloc1(as, ref, rset_exclude(RSET_GPR, RID_BASE)); + emit_movtomro(as, src, RID_BASE, ofs); + } + } else if (irt_isnum(ir->t)) { + Reg src = ra_alloc1(as, ref, RSET_FPR); + emit_rmro(as, XO_MOVSDto, src, RID_BASE, ofs); + } else { + lj_assertA(irt_ispri(ir->t) || irt_isaddr(ir->t) || + (LJ_DUALNUM && irt_isinteger(ir->t)), + "restore of IR type %d", irt_type(ir->t)); + if (!irref_isk(ref)) { + Reg src = ra_alloc1(as, ref, rset_exclude(RSET_GPR, RID_BASE)); +#if LJ_GC64 + if (irt_is64(ir->t)) { + /* TODO: 64 bit store + 32 bit load-modify-store is suboptimal. */ + emit_u32(as, irt_toitype(ir->t) << 15); + emit_rmro(as, XO_ARITHi, XOg_OR, RID_BASE, ofs+4); + } else if (LJ_DUALNUM && irt_isinteger(ir->t)) { + emit_movmroi(as, RID_BASE, ofs+4, LJ_TISNUM << 15); + } else { + emit_movmroi(as, RID_BASE, ofs+4, (irt_toitype(ir->t)<<15)|0x7fff); + } +#endif + emit_movtomro(as, REX_64IR(ir, src), RID_BASE, ofs); +#if LJ_GC64 + } else { + TValue k; + lj_ir_kvalue(as->J->L, &k, ir); + if (tvisnil(&k)) { + emit_i32(as, -1); + emit_rmro(as, XO_MOVmi, REX_64, RID_BASE, ofs); + } else { + emit_movmroi(as, RID_BASE, ofs+4, k.u32.hi); + emit_movmroi(as, RID_BASE, ofs, k.u32.lo); + } +#else + } else if (!irt_ispri(ir->t)) { + emit_movmroi(as, RID_BASE, ofs, ir->i); +#endif + } + if ((sn & (SNAP_CONT|SNAP_FRAME))) { +#if !LJ_FR2 + if (s != 0) /* Do not overwrite link to previous frame. */ + emit_movmroi(as, RID_BASE, ofs+4, (int32_t)(*flinks--)); +#endif +#if !LJ_GC64 + } else { + if (!(LJ_64 && irt_islightud(ir->t))) + emit_movmroi(as, RID_BASE, ofs+4, irt_toitype(ir->t)); +#endif + } + } + checkmclim(as); + } + lj_assertA(map + nent == flinks, "inconsistent frames in snapshot"); +} + +/* -- GC handling --------------------------------------------------------- */ + +/* Check GC threshold and do one or more GC steps. */ +static void asm_gc_check(ASMState *as) +{ + const CCallInfo *ci = &lj_ir_callinfo[IRCALL_lj_gc_step_jit]; + IRRef args[2]; + MCLabel l_end; + Reg tmp; + ra_evictset(as, RSET_SCRATCH); + l_end = emit_label(as); + /* Exit trace if in GCSatomic or GCSfinalize. Avoids syncing GC objects. */ + asm_guardcc(as, CC_NE); /* Assumes asm_snap_prep() already done. */ + emit_rr(as, XO_TEST, RID_RET, RID_RET); + args[0] = ASMREF_TMP1; /* global_State *g */ + args[1] = ASMREF_TMP2; /* MSize steps */ + asm_gencall(as, ci, args); + tmp = ra_releasetmp(as, ASMREF_TMP1); +#if LJ_GC64 + emit_rmro(as, XO_LEA, tmp|REX_64, RID_DISPATCH, GG_DISP2G); +#else + emit_loada(as, tmp, J2G(as->J)); +#endif + emit_loadi(as, ra_releasetmp(as, ASMREF_TMP2), as->gcsteps); + /* Jump around GC step if GC total < GC threshold. */ + emit_sjcc(as, CC_B, l_end); + emit_opgl(as, XO_ARITH(XOg_CMP), tmp|REX_GC64, gc.threshold); + emit_getgl(as, tmp, gc.total); + as->gcsteps = 0; + checkmclim(as); +} + +/* -- Loop handling ------------------------------------------------------- */ + +/* Fixup the loop branch. */ +static void asm_loop_fixup(ASMState *as) +{ + MCode *p = as->mctop; + MCode *target = as->mcp; + if (as->realign) { /* Realigned loops use short jumps. */ + as->realign = NULL; /* Stop another retry. */ + lj_assertA(((intptr_t)target & 15) == 0, "loop realign failed"); + if (as->loopinv) { /* Inverted loop branch? */ + p -= 5; + p[0] = XI_JMP; + lj_assertA(target - p >= -128, "loop realign failed"); + p[-1] = (MCode)(target - p); /* Patch sjcc. */ + if (as->loopinv == 2) + p[-3] = (MCode)(target - p + 2); /* Patch opt. short jp. */ + } else { + lj_assertA(target - p >= -128, "loop realign failed"); + p[-1] = (MCode)(int8_t)(target - p); /* Patch short jmp. */ + p[-2] = XI_JMPs; + } + } else { + MCode *newloop; + p[-5] = XI_JMP; + if (as->loopinv) { /* Inverted loop branch? */ + /* asm_guardcc already inverted the jcc and patched the jmp. */ + p -= 5; + newloop = target+4; + *(int32_t *)(p-4) = (int32_t)(target - p); /* Patch jcc. */ + if (as->loopinv == 2) { + *(int32_t *)(p-10) = (int32_t)(target - p + 6); /* Patch opt. jp. */ + newloop = target+8; + } + } else { /* Otherwise just patch jmp. */ + *(int32_t *)(p-4) = (int32_t)(target - p); + newloop = target+3; + } + /* Realign small loops and shorten the loop branch. */ + if (newloop >= p - 128) { + as->realign = newloop; /* Force a retry and remember alignment. */ + as->curins = as->stopins; /* Abort asm_trace now. */ + as->T->nins = as->orignins; /* Remove any added renames. */ + } + } +} + +/* Fixup the tail of the loop. */ +static void asm_loop_tail_fixup(ASMState *as) +{ + UNUSED(as); /* Nothing to do. */ +} + +/* -- Head of trace ------------------------------------------------------- */ + +/* Coalesce BASE register for a root trace. */ +static void asm_head_root_base(ASMState *as) +{ + IRIns *ir = IR(REF_BASE); + Reg r = ir->r; + if (ra_hasreg(r)) { + ra_free(as, r); + if (rset_test(as->modset, r) || irt_ismarked(ir->t)) + ir->r = RID_INIT; /* No inheritance for modified BASE register. */ + if (r != RID_BASE) + emit_rr(as, XO_MOV, r|REX_GC64, RID_BASE); + } +} + +/* Coalesce or reload BASE register for a side trace. */ +static RegSet asm_head_side_base(ASMState *as, IRIns *irp, RegSet allow) +{ + IRIns *ir = IR(REF_BASE); + Reg r = ir->r; + if (ra_hasreg(r)) { + ra_free(as, r); + if (rset_test(as->modset, r) || irt_ismarked(ir->t)) + ir->r = RID_INIT; /* No inheritance for modified BASE register. */ + if (irp->r == r) { + rset_clear(allow, r); /* Mark same BASE register as coalesced. */ + } else if (ra_hasreg(irp->r) && rset_test(as->freeset, irp->r)) { + /* Move from coalesced parent reg. */ + rset_clear(allow, irp->r); + emit_rr(as, XO_MOV, r|REX_GC64, irp->r); + } else { + emit_getgl(as, r, jit_base); /* Otherwise reload BASE. */ + } + } + return allow; +} + +/* -- Tail of trace ------------------------------------------------------- */ + +/* Fixup the tail code. */ +static void asm_tail_fixup(ASMState *as, TraceNo lnk) +{ + /* Note: don't use as->mcp swap + emit_*: emit_op overwrites more bytes. */ + MCode *p = as->mctop; + MCode *target, *q; + int32_t spadj = as->T->spadjust; + if (spadj == 0) { + p -= LJ_64 ? 7 : 6; + } else { + MCode *p1; + /* Patch stack adjustment. */ + if (checki8(spadj)) { + p -= 3; + p1 = p-6; + *p1 = (MCode)spadj; + } else { + p1 = p-9; + *(int32_t *)p1 = spadj; + } +#if LJ_64 + p1[-3] = 0x48; +#endif + p1[-2] = (MCode)(checki8(spadj) ? XI_ARITHi8 : XI_ARITHi); + p1[-1] = MODRM(XM_REG, XOg_ADD, RID_ESP); + } + /* Patch exit branch. */ + target = lnk ? traceref(as->J, lnk)->mcode : (MCode *)lj_vm_exit_interp; + *(int32_t *)(p-4) = jmprel(as->J, p, target); + p[-5] = XI_JMP; + /* Drop unused mcode tail. Fill with NOPs to make the prefetcher happy. */ + for (q = as->mctop-1; q >= p; q--) + *q = XI_NOP; + as->mctop = p; +} + +/* Prepare tail of code. */ +static void asm_tail_prep(ASMState *as) +{ + MCode *p = as->mctop; + /* Realign and leave room for backwards loop branch or exit branch. */ + if (as->realign) { + int i = ((int)(intptr_t)as->realign) & 15; + /* Fill unused mcode tail with NOPs to make the prefetcher happy. */ + while (i-- > 0) + *--p = XI_NOP; + as->mctop = p; + p -= (as->loopinv ? 5 : 2); /* Space for short/near jmp. */ + } else { + p -= 5; /* Space for exit branch (near jmp). */ + } + if (as->loopref) { + as->invmcp = as->mcp = p; + } else { + /* Leave room for ESP adjustment: add esp, imm or lea esp, [esp+imm] */ + as->mcp = p - (LJ_64 ? 7 : 6); + as->invmcp = NULL; + } +} + +/* -- Trace setup --------------------------------------------------------- */ + +/* Ensure there are enough stack slots for call arguments. */ +static Reg asm_setup_call_slots(ASMState *as, IRIns *ir, const CCallInfo *ci) +{ + IRRef args[CCI_NARGS_MAX*2]; + int nslots; + asm_collectargs(as, ir, ci, args); + nslots = asm_count_call_slots(as, ci, args); + if (nslots > as->evenspill) /* Leave room for args in stack slots. */ + as->evenspill = nslots; +#if LJ_64 + return irt_isfp(ir->t) ? REGSP_HINT(RID_FPRET) : REGSP_HINT(RID_RET); +#else + return irt_isfp(ir->t) ? REGSP_INIT : REGSP_HINT(RID_RET); +#endif +} + +/* Target-specific setup. */ +static void asm_setup_target(ASMState *as) +{ + asm_exitstub_setup(as, as->T->nsnap); + as->mrm.base = 0; +} + +/* -- Trace patching ------------------------------------------------------ */ + +static const uint8_t map_op1[256] = { +0x92,0x92,0x92,0x92,0x52,0x45,0x51,0x51,0x92,0x92,0x92,0x92,0x52,0x45,0x51,0x20, +0x92,0x92,0x92,0x92,0x52,0x45,0x51,0x51,0x92,0x92,0x92,0x92,0x52,0x45,0x51,0x51, +0x92,0x92,0x92,0x92,0x52,0x45,0x10,0x51,0x92,0x92,0x92,0x92,0x52,0x45,0x10,0x51, +0x92,0x92,0x92,0x92,0x52,0x45,0x10,0x51,0x92,0x92,0x92,0x92,0x52,0x45,0x10,0x51, +#if LJ_64 +0x10,0x10,0x10,0x10,0x10,0x10,0x10,0x10,0x14,0x14,0x14,0x14,0x14,0x14,0x14,0x14, +#else +0x51,0x51,0x51,0x51,0x51,0x51,0x51,0x51,0x51,0x51,0x51,0x51,0x51,0x51,0x51,0x51, +#endif +0x51,0x51,0x51,0x51,0x51,0x51,0x51,0x51,0x51,0x51,0x51,0x51,0x51,0x51,0x51,0x51, +0x51,0x51,0x92,0x92,0x10,0x10,0x12,0x11,0x45,0x86,0x52,0x93,0x51,0x51,0x51,0x51, +0x52,0x52,0x52,0x52,0x52,0x52,0x52,0x52,0x52,0x52,0x52,0x52,0x52,0x52,0x52,0x52, +0x93,0x86,0x93,0x93,0x92,0x92,0x92,0x92,0x92,0x92,0x92,0x92,0x92,0x92,0x92,0x92, +0x51,0x51,0x51,0x51,0x51,0x51,0x51,0x51,0x51,0x51,0x47,0x51,0x51,0x51,0x51,0x51, +#if LJ_64 +0x59,0x59,0x59,0x59,0x51,0x51,0x51,0x51,0x52,0x45,0x51,0x51,0x51,0x51,0x51,0x51, +#else +0x55,0x55,0x55,0x55,0x51,0x51,0x51,0x51,0x52,0x45,0x51,0x51,0x51,0x51,0x51,0x51, +#endif +0x52,0x52,0x52,0x52,0x52,0x52,0x52,0x52,0x05,0x05,0x05,0x05,0x05,0x05,0x05,0x05, +0x93,0x93,0x53,0x51,0x70,0x71,0x93,0x86,0x54,0x51,0x53,0x51,0x51,0x52,0x51,0x51, +0x92,0x92,0x92,0x92,0x52,0x52,0x51,0x51,0x92,0x92,0x92,0x92,0x92,0x92,0x92,0x92, +0x52,0x52,0x52,0x52,0x52,0x52,0x52,0x52,0x45,0x45,0x47,0x52,0x51,0x51,0x51,0x51, +0x10,0x51,0x10,0x10,0x51,0x51,0x63,0x66,0x51,0x51,0x51,0x51,0x51,0x51,0x92,0x92 +}; + +static const uint8_t map_op2[256] = { +0x93,0x93,0x93,0x93,0x52,0x52,0x52,0x52,0x52,0x52,0x51,0x52,0x51,0x93,0x52,0x94, +0x93,0x93,0x93,0x93,0x93,0x93,0x93,0x93,0x93,0x93,0x93,0x93,0x93,0x93,0x93,0x93, +0x53,0x53,0x53,0x53,0x53,0x53,0x53,0x53,0x93,0x93,0x93,0x93,0x93,0x93,0x93,0x93, +0x52,0x52,0x52,0x52,0x52,0x52,0x52,0x52,0x34,0x51,0x35,0x51,0x51,0x51,0x51,0x51, +0x93,0x93,0x93,0x93,0x93,0x93,0x93,0x93,0x93,0x93,0x93,0x93,0x93,0x93,0x93,0x93, +0x53,0x93,0x93,0x93,0x93,0x93,0x93,0x93,0x93,0x93,0x93,0x93,0x93,0x93,0x93,0x93, +0x93,0x93,0x93,0x93,0x93,0x93,0x93,0x93,0x93,0x93,0x93,0x93,0x93,0x93,0x93,0x93, +0x94,0x54,0x54,0x54,0x93,0x93,0x93,0x52,0x93,0x93,0x93,0x93,0x93,0x93,0x93,0x93, +0x46,0x46,0x46,0x46,0x46,0x46,0x46,0x46,0x46,0x46,0x46,0x46,0x46,0x46,0x46,0x46, +0x93,0x93,0x93,0x93,0x93,0x93,0x93,0x93,0x93,0x93,0x93,0x93,0x93,0x93,0x93,0x93, +0x52,0x52,0x52,0x93,0x94,0x93,0x51,0x51,0x52,0x52,0x52,0x93,0x94,0x93,0x93,0x93, +0x93,0x93,0x93,0x93,0x93,0x93,0x93,0x93,0x93,0x93,0x94,0x93,0x93,0x93,0x93,0x93, +0x93,0x93,0x94,0x93,0x94,0x94,0x94,0x93,0x52,0x52,0x52,0x52,0x52,0x52,0x52,0x52, +0x93,0x93,0x93,0x93,0x93,0x93,0x93,0x93,0x93,0x93,0x93,0x93,0x93,0x93,0x93,0x93, +0x93,0x93,0x93,0x93,0x93,0x93,0x93,0x93,0x93,0x93,0x93,0x93,0x93,0x93,0x93,0x93, +0x93,0x93,0x93,0x93,0x93,0x93,0x93,0x93,0x93,0x93,0x93,0x93,0x93,0x93,0x93,0x52 +}; + +static uint32_t asm_x86_inslen(const uint8_t* p) +{ + uint32_t result = 0; + uint32_t prefixes = 0; + uint32_t x = map_op1[*p]; + for (;;) { + switch (x >> 4) { + case 0: return result + x + (prefixes & 4); + case 1: prefixes |= x; x = map_op1[*++p]; result++; break; + case 2: x = map_op2[*++p]; break; + case 3: p++; goto mrm; + case 4: result -= (prefixes & 2); /* fallthrough */ + case 5: return result + (x & 15); + case 6: /* Group 3. */ + if (p[1] & 0x38) x = 2; + else if ((prefixes & 2) && (x == 0x66)) x = 4; + goto mrm; + case 7: /* VEX c4/c5. */ + if (LJ_32 && p[1] < 0xc0) { + x = 2; + goto mrm; + } + if (x == 0x70) { + x = *++p & 0x1f; + result++; + if (x >= 2) { + p += 2; + result += 2; + goto mrm; + } + } + p++; + result++; + x = map_op2[*++p]; + break; + case 8: result -= (prefixes & 2); /* fallthrough */ + case 9: mrm: /* ModR/M and possibly SIB. */ + result += (x & 15); + x = *++p; + switch (x >> 6) { + case 0: if ((x & 7) == 5) return result + 4; break; + case 1: result++; break; + case 2: result += 4; break; + case 3: return result; + } + if ((x & 7) == 4) { + result++; + if (x < 0x40 && (p[1] & 7) == 5) result += 4; + } + return result; + } + } +} + +/* Patch exit jumps of existing machine code to a new target. */ +void lj_asm_patchexit(jit_State *J, GCtrace *T, ExitNo exitno, MCode *target) +{ + MCode *p = T->mcode; + MCode *mcarea = lj_mcode_patch(J, p, 0); + MSize len = T->szmcode; + MCode *px = exitstub_addr(J, exitno) - 6; + MCode *pe = p+len-6; + MCode *pgc = NULL; +#if LJ_GC64 + uint32_t statei = (uint32_t)(GG_OFS(g.vmstate) - GG_OFS(dispatch)); +#else + uint32_t statei = u32ptr(&J2G(J)->vmstate); +#endif + if (len > 5 && p[len-5] == XI_JMP && p+len-6 + *(int32_t *)(p+len-4) == px) + *(int32_t *)(p+len-4) = jmprel(J, p+len, target); + /* Do not patch parent exit for a stack check. Skip beyond vmstate update. */ + for (; p < pe; p += asm_x86_inslen(p)) { + intptr_t ofs = LJ_GC64 ? (p[0] & 0xf0) == 0x40 : LJ_64; + if (*(uint32_t *)(p+2+ofs) == statei && p[ofs+LJ_GC64-LJ_64] == XI_MOVmi) + break; + } + lj_assertJ(p < pe, "instruction length decoder failed"); + for (; p < pe; p += asm_x86_inslen(p)) { + if ((*(uint16_t *)p & 0xf0ff) == 0x800f && p + *(int32_t *)(p+2) == px && + p != pgc) { + *(int32_t *)(p+2) = jmprel(J, p+6, target); + } else if (*p == XI_CALL && + (void *)(p+5+*(int32_t *)(p+1)) == (void *)lj_gc_step_jit) { + pgc = p+7; /* Do not patch GC check exit. */ + } + } + lj_mcode_sync(T->mcode, T->mcode + T->szmcode); + lj_mcode_patch(J, mcarea, 1); +} + diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_assert.c b/fluent-bit/lib/luajit-3065c9/src/lj_assert.c new file mode 100644 index 00000000..4b713b2b --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_assert.c @@ -0,0 +1,28 @@ +/* +** Internal assertions. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#define lj_assert_c +#define LUA_CORE + +#if defined(LUA_USE_ASSERT) || defined(LUA_USE_APICHECK) + +#include + +#include "lj_obj.h" + +void lj_assert_fail(global_State *g, const char *file, int line, + const char *func, const char *fmt, ...) +{ + va_list argp; + va_start(argp, fmt); + fprintf(stderr, "LuaJIT ASSERT %s:%d: %s: ", file, line, func); + vfprintf(stderr, fmt, argp); + fputc('\n', stderr); + va_end(argp); + UNUSED(g); /* May be NULL. TODO: optionally dump state. */ + abort(); +} + +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_bc.c b/fluent-bit/lib/luajit-3065c9/src/lj_bc.c new file mode 100644 index 00000000..b692cb54 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_bc.c @@ -0,0 +1,14 @@ +/* +** Bytecode instruction modes. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#define lj_bc_c +#define LUA_CORE + +#include "lj_obj.h" +#include "lj_bc.h" + +/* Bytecode offsets and bytecode instruction modes. */ +#include "lj_bcdef.h" + diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_bc.h b/fluent-bit/lib/luajit-3065c9/src/lj_bc.h new file mode 100644 index 00000000..02356e5b --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_bc.h @@ -0,0 +1,265 @@ +/* +** Bytecode instruction format. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#ifndef _LJ_BC_H +#define _LJ_BC_H + +#include "lj_def.h" +#include "lj_arch.h" + +/* Bytecode instruction format, 32 bit wide, fields of 8 or 16 bit: +** +** +----+----+----+----+ +** | B | C | A | OP | Format ABC +** +----+----+----+----+ +** | D | A | OP | Format AD +** +-------------------- +** MSB LSB +** +** In-memory instructions are always stored in host byte order. +*/ + +/* Operand ranges and related constants. */ +#define BCMAX_A 0xff +#define BCMAX_B 0xff +#define BCMAX_C 0xff +#define BCMAX_D 0xffff +#define BCBIAS_J 0x8000 +#define NO_REG BCMAX_A +#define NO_JMP (~(BCPos)0) + +/* Macros to get instruction fields. */ +#define bc_op(i) ((BCOp)((i)&0xff)) +#define bc_a(i) ((BCReg)(((i)>>8)&0xff)) +#define bc_b(i) ((BCReg)((i)>>24)) +#define bc_c(i) ((BCReg)(((i)>>16)&0xff)) +#define bc_d(i) ((BCReg)((i)>>16)) +#define bc_j(i) ((ptrdiff_t)bc_d(i)-BCBIAS_J) + +/* Macros to set instruction fields. */ +#define setbc_byte(p, x, ofs) \ + ((uint8_t *)(p))[LJ_ENDIAN_SELECT(ofs, 3-ofs)] = (uint8_t)(x) +#define setbc_op(p, x) setbc_byte(p, (x), 0) +#define setbc_a(p, x) setbc_byte(p, (x), 1) +#define setbc_b(p, x) setbc_byte(p, (x), 3) +#define setbc_c(p, x) setbc_byte(p, (x), 2) +#define setbc_d(p, x) \ + ((uint16_t *)(p))[LJ_ENDIAN_SELECT(1, 0)] = (uint16_t)(x) +#define setbc_j(p, x) setbc_d(p, (BCPos)((int32_t)(x)+BCBIAS_J)) + +/* Macros to compose instructions. */ +#define BCINS_ABC(o, a, b, c) \ + (((BCIns)(o))|((BCIns)(a)<<8)|((BCIns)(b)<<24)|((BCIns)(c)<<16)) +#define BCINS_AD(o, a, d) \ + (((BCIns)(o))|((BCIns)(a)<<8)|((BCIns)(d)<<16)) +#define BCINS_AJ(o, a, j) BCINS_AD(o, a, (BCPos)((int32_t)(j)+BCBIAS_J)) + +/* Bytecode instruction definition. Order matters, see below. +** +** (name, filler, Amode, Bmode, Cmode or Dmode, metamethod) +** +** The opcode name suffixes specify the type for RB/RC or RD: +** V = variable slot +** S = string const +** N = number const +** P = primitive type (~itype) +** B = unsigned byte literal +** M = multiple args/results +*/ +#define BCDEF(_) \ + /* Comparison ops. ORDER OPR. */ \ + _(ISLT, var, ___, var, lt) \ + _(ISGE, var, ___, var, lt) \ + _(ISLE, var, ___, var, le) \ + _(ISGT, var, ___, var, le) \ + \ + _(ISEQV, var, ___, var, eq) \ + _(ISNEV, var, ___, var, eq) \ + _(ISEQS, var, ___, str, eq) \ + _(ISNES, var, ___, str, eq) \ + _(ISEQN, var, ___, num, eq) \ + _(ISNEN, var, ___, num, eq) \ + _(ISEQP, var, ___, pri, eq) \ + _(ISNEP, var, ___, pri, eq) \ + \ + /* Unary test and copy ops. */ \ + _(ISTC, dst, ___, var, ___) \ + _(ISFC, dst, ___, var, ___) \ + _(IST, ___, ___, var, ___) \ + _(ISF, ___, ___, var, ___) \ + _(ISTYPE, var, ___, lit, ___) \ + _(ISNUM, var, ___, lit, ___) \ + \ + /* Unary ops. */ \ + _(MOV, dst, ___, var, ___) \ + _(NOT, dst, ___, var, ___) \ + _(UNM, dst, ___, var, unm) \ + _(LEN, dst, ___, var, len) \ + \ + /* Binary ops. ORDER OPR. VV last, POW must be next. */ \ + _(ADDVN, dst, var, num, add) \ + _(SUBVN, dst, var, num, sub) \ + _(MULVN, dst, var, num, mul) \ + _(DIVVN, dst, var, num, div) \ + _(MODVN, dst, var, num, mod) \ + \ + _(ADDNV, dst, var, num, add) \ + _(SUBNV, dst, var, num, sub) \ + _(MULNV, dst, var, num, mul) \ + _(DIVNV, dst, var, num, div) \ + _(MODNV, dst, var, num, mod) \ + \ + _(ADDVV, dst, var, var, add) \ + _(SUBVV, dst, var, var, sub) \ + _(MULVV, dst, var, var, mul) \ + _(DIVVV, dst, var, var, div) \ + _(MODVV, dst, var, var, mod) \ + \ + _(POW, dst, var, var, pow) \ + _(CAT, dst, rbase, rbase, concat) \ + \ + /* Constant ops. */ \ + _(KSTR, dst, ___, str, ___) \ + _(KCDATA, dst, ___, cdata, ___) \ + _(KSHORT, dst, ___, lits, ___) \ + _(KNUM, dst, ___, num, ___) \ + _(KPRI, dst, ___, pri, ___) \ + _(KNIL, base, ___, base, ___) \ + \ + /* Upvalue and function ops. */ \ + _(UGET, dst, ___, uv, ___) \ + _(USETV, uv, ___, var, ___) \ + _(USETS, uv, ___, str, ___) \ + _(USETN, uv, ___, num, ___) \ + _(USETP, uv, ___, pri, ___) \ + _(UCLO, rbase, ___, jump, ___) \ + _(FNEW, dst, ___, func, gc) \ + \ + /* Table ops. */ \ + _(TNEW, dst, ___, lit, gc) \ + _(TDUP, dst, ___, tab, gc) \ + _(GGET, dst, ___, str, index) \ + _(GSET, var, ___, str, newindex) \ + _(TGETV, dst, var, var, index) \ + _(TGETS, dst, var, str, index) \ + _(TGETB, dst, var, lit, index) \ + _(TGETR, dst, var, var, index) \ + _(TSETV, var, var, var, newindex) \ + _(TSETS, var, var, str, newindex) \ + _(TSETB, var, var, lit, newindex) \ + _(TSETM, base, ___, num, newindex) \ + _(TSETR, var, var, var, newindex) \ + \ + /* Calls and vararg handling. T = tail call. */ \ + _(CALLM, base, lit, lit, call) \ + _(CALL, base, lit, lit, call) \ + _(CALLMT, base, ___, lit, call) \ + _(CALLT, base, ___, lit, call) \ + _(ITERC, base, lit, lit, call) \ + _(ITERN, base, lit, lit, call) \ + _(VARG, base, lit, lit, ___) \ + _(ISNEXT, base, ___, jump, ___) \ + \ + /* Returns. */ \ + _(RETM, base, ___, lit, ___) \ + _(RET, rbase, ___, lit, ___) \ + _(RET0, rbase, ___, lit, ___) \ + _(RET1, rbase, ___, lit, ___) \ + \ + /* Loops and branches. I/J = interp/JIT, I/C/L = init/call/loop. */ \ + _(FORI, base, ___, jump, ___) \ + _(JFORI, base, ___, jump, ___) \ + \ + _(FORL, base, ___, jump, ___) \ + _(IFORL, base, ___, jump, ___) \ + _(JFORL, base, ___, lit, ___) \ + \ + _(ITERL, base, ___, jump, ___) \ + _(IITERL, base, ___, jump, ___) \ + _(JITERL, base, ___, lit, ___) \ + \ + _(LOOP, rbase, ___, jump, ___) \ + _(ILOOP, rbase, ___, jump, ___) \ + _(JLOOP, rbase, ___, lit, ___) \ + \ + _(JMP, rbase, ___, jump, ___) \ + \ + /* Function headers. I/J = interp/JIT, F/V/C = fixarg/vararg/C func. */ \ + _(FUNCF, rbase, ___, ___, ___) \ + _(IFUNCF, rbase, ___, ___, ___) \ + _(JFUNCF, rbase, ___, lit, ___) \ + _(FUNCV, rbase, ___, ___, ___) \ + _(IFUNCV, rbase, ___, ___, ___) \ + _(JFUNCV, rbase, ___, lit, ___) \ + _(FUNCC, rbase, ___, ___, ___) \ + _(FUNCCW, rbase, ___, ___, ___) + +/* Bytecode opcode numbers. */ +typedef enum { +#define BCENUM(name, ma, mb, mc, mt) BC_##name, +BCDEF(BCENUM) +#undef BCENUM + BC__MAX +} BCOp; + +LJ_STATIC_ASSERT((int)BC_ISEQV+1 == (int)BC_ISNEV); +LJ_STATIC_ASSERT(((int)BC_ISEQV^1) == (int)BC_ISNEV); +LJ_STATIC_ASSERT(((int)BC_ISEQS^1) == (int)BC_ISNES); +LJ_STATIC_ASSERT(((int)BC_ISEQN^1) == (int)BC_ISNEN); +LJ_STATIC_ASSERT(((int)BC_ISEQP^1) == (int)BC_ISNEP); +LJ_STATIC_ASSERT(((int)BC_ISLT^1) == (int)BC_ISGE); +LJ_STATIC_ASSERT(((int)BC_ISLE^1) == (int)BC_ISGT); +LJ_STATIC_ASSERT(((int)BC_ISLT^3) == (int)BC_ISGT); +LJ_STATIC_ASSERT((int)BC_IST-(int)BC_ISTC == (int)BC_ISF-(int)BC_ISFC); +LJ_STATIC_ASSERT((int)BC_CALLT-(int)BC_CALL == (int)BC_CALLMT-(int)BC_CALLM); +LJ_STATIC_ASSERT((int)BC_CALLMT + 1 == (int)BC_CALLT); +LJ_STATIC_ASSERT((int)BC_RETM + 1 == (int)BC_RET); +LJ_STATIC_ASSERT((int)BC_FORL + 1 == (int)BC_IFORL); +LJ_STATIC_ASSERT((int)BC_FORL + 2 == (int)BC_JFORL); +LJ_STATIC_ASSERT((int)BC_ITERL + 1 == (int)BC_IITERL); +LJ_STATIC_ASSERT((int)BC_ITERL + 2 == (int)BC_JITERL); +LJ_STATIC_ASSERT((int)BC_LOOP + 1 == (int)BC_ILOOP); +LJ_STATIC_ASSERT((int)BC_LOOP + 2 == (int)BC_JLOOP); +LJ_STATIC_ASSERT((int)BC_FUNCF + 1 == (int)BC_IFUNCF); +LJ_STATIC_ASSERT((int)BC_FUNCF + 2 == (int)BC_JFUNCF); +LJ_STATIC_ASSERT((int)BC_FUNCV + 1 == (int)BC_IFUNCV); +LJ_STATIC_ASSERT((int)BC_FUNCV + 2 == (int)BC_JFUNCV); + +/* This solves a circular dependency problem, change as needed. */ +#define FF_next_N 4 + +/* Stack slots used by FORI/FORL, relative to operand A. */ +enum { + FORL_IDX, FORL_STOP, FORL_STEP, FORL_EXT +}; + +/* Bytecode operand modes. ORDER BCMode */ +typedef enum { + BCMnone, BCMdst, BCMbase, BCMvar, BCMrbase, BCMuv, /* Mode A must be <= 7 */ + BCMlit, BCMlits, BCMpri, BCMnum, BCMstr, BCMtab, BCMfunc, BCMjump, BCMcdata, + BCM_max +} BCMode; +#define BCM___ BCMnone + +#define bcmode_a(op) ((BCMode)(lj_bc_mode[op] & 7)) +#define bcmode_b(op) ((BCMode)((lj_bc_mode[op]>>3) & 15)) +#define bcmode_c(op) ((BCMode)((lj_bc_mode[op]>>7) & 15)) +#define bcmode_d(op) bcmode_c(op) +#define bcmode_hasd(op) ((lj_bc_mode[op] & (15<<3)) == (BCMnone<<3)) +#define bcmode_mm(op) ((MMS)(lj_bc_mode[op]>>11)) + +#define BCMODE(name, ma, mb, mc, mm) \ + (BCM##ma|(BCM##mb<<3)|(BCM##mc<<7)|(MM_##mm<<11)), +#define BCMODE_FF 0 + +static LJ_AINLINE int bc_isret(BCOp op) +{ + return (op == BC_RETM || op == BC_RET || op == BC_RET0 || op == BC_RET1); +} + +LJ_DATA const uint16_t lj_bc_mode[]; +LJ_DATA const uint16_t lj_bc_ofs[]; + +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_bcdump.h b/fluent-bit/lib/luajit-3065c9/src/lj_bcdump.h new file mode 100644 index 00000000..69da16e9 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_bcdump.h @@ -0,0 +1,68 @@ +/* +** Bytecode dump definitions. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#ifndef _LJ_BCDUMP_H +#define _LJ_BCDUMP_H + +#include "lj_obj.h" +#include "lj_lex.h" + +/* -- Bytecode dump format ------------------------------------------------ */ + +/* +** dump = header proto+ 0U +** header = ESC 'L' 'J' versionB flagsU [namelenU nameB*] +** proto = lengthU pdata +** pdata = phead bcinsW* uvdataH* kgc* knum* [debugB*] +** phead = flagsB numparamsB framesizeB numuvB numkgcU numknU numbcU +** [debuglenU [firstlineU numlineU]] +** kgc = kgctypeU { ktab | (loU hiU) | (rloU rhiU iloU ihiU) | strB* } +** knum = intU0 | (loU1 hiU) +** ktab = narrayU nhashU karray* khash* +** karray = ktabk +** khash = ktabk ktabk +** ktabk = ktabtypeU { intU | (loU hiU) | strB* } +** +** B = 8 bit, H = 16 bit, W = 32 bit, U = ULEB128 of W, U0/U1 = ULEB128 of W+1 +*/ + +/* Bytecode dump header. */ +#define BCDUMP_HEAD1 0x1b +#define BCDUMP_HEAD2 0x4c +#define BCDUMP_HEAD3 0x4a + +/* If you perform *any* kind of private modifications to the bytecode itself +** or to the dump format, you *must* set BCDUMP_VERSION to 0x80 or higher. +*/ +#define BCDUMP_VERSION 2 + +/* Compatibility flags. */ +#define BCDUMP_F_BE 0x01 +#define BCDUMP_F_STRIP 0x02 +#define BCDUMP_F_FFI 0x04 +#define BCDUMP_F_FR2 0x08 + +#define BCDUMP_F_KNOWN (BCDUMP_F_FR2*2-1) + +/* Type codes for the GC constants of a prototype. Plus length for strings. */ +enum { + BCDUMP_KGC_CHILD, BCDUMP_KGC_TAB, BCDUMP_KGC_I64, BCDUMP_KGC_U64, + BCDUMP_KGC_COMPLEX, BCDUMP_KGC_STR +}; + +/* Type codes for the keys/values of a constant table. */ +enum { + BCDUMP_KTAB_NIL, BCDUMP_KTAB_FALSE, BCDUMP_KTAB_TRUE, + BCDUMP_KTAB_INT, BCDUMP_KTAB_NUM, BCDUMP_KTAB_STR +}; + +/* -- Bytecode reader/writer ---------------------------------------------- */ + +LJ_FUNC int lj_bcwrite(lua_State *L, GCproto *pt, lua_Writer writer, + void *data, int strip); +LJ_FUNC GCproto *lj_bcread_proto(LexState *ls); +LJ_FUNC GCproto *lj_bcread(LexState *ls); + +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_bcread.c b/fluent-bit/lib/luajit-3065c9/src/lj_bcread.c new file mode 100644 index 00000000..2ce05707 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_bcread.c @@ -0,0 +1,453 @@ +/* +** Bytecode reader. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#define lj_bcread_c +#define LUA_CORE + +#include "lj_obj.h" +#include "lj_gc.h" +#include "lj_err.h" +#include "lj_buf.h" +#include "lj_str.h" +#include "lj_tab.h" +#include "lj_bc.h" +#if LJ_HASFFI +#include "lj_ctype.h" +#include "lj_cdata.h" +#include "lualib.h" +#endif +#include "lj_lex.h" +#include "lj_bcdump.h" +#include "lj_state.h" +#include "lj_strfmt.h" + +/* Reuse some lexer fields for our own purposes. */ +#define bcread_flags(ls) ls->level +#define bcread_swap(ls) \ + ((bcread_flags(ls) & BCDUMP_F_BE) != LJ_BE*BCDUMP_F_BE) +#define bcread_oldtop(L, ls) restorestack(L, ls->lastline) +#define bcread_savetop(L, ls, top) \ + ls->lastline = (BCLine)savestack(L, (top)) + +/* -- Input buffer handling ----------------------------------------------- */ + +/* Throw reader error. */ +static LJ_NOINLINE void bcread_error(LexState *ls, ErrMsg em) +{ + lua_State *L = ls->L; + const char *name = ls->chunkarg; + if (*name == BCDUMP_HEAD1) name = "(binary)"; + else if (*name == '@' || *name == '=') name++; + lj_strfmt_pushf(L, "%s: %s", name, err2msg(em)); + lj_err_throw(L, LUA_ERRSYNTAX); +} + +/* Refill buffer. */ +static LJ_NOINLINE void bcread_fill(LexState *ls, MSize len, int need) +{ + lj_assertLS(len != 0, "empty refill"); + if (len > LJ_MAX_BUF || ls->c < 0) + bcread_error(ls, LJ_ERR_BCBAD); + do { + const char *buf; + size_t sz; + char *p = ls->sb.b; + MSize n = (MSize)(ls->pe - ls->p); + if (n) { /* Copy remainder to buffer. */ + if (sbuflen(&ls->sb)) { /* Move down in buffer. */ + lj_assertLS(ls->pe == ls->sb.w, "bad buffer pointer"); + if (ls->p != p) memmove(p, ls->p, n); + } else { /* Copy from buffer provided by reader. */ + p = lj_buf_need(&ls->sb, len); + memcpy(p, ls->p, n); + } + ls->p = p; + ls->pe = p + n; + } + ls->sb.w = p + n; + buf = ls->rfunc(ls->L, ls->rdata, &sz); /* Get more data from reader. */ + if (buf == NULL || sz == 0) { /* EOF? */ + if (need) bcread_error(ls, LJ_ERR_BCBAD); + ls->c = -1; /* Only bad if we get called again. */ + break; + } + if (sz >= LJ_MAX_BUF - n) lj_err_mem(ls->L); + if (n) { /* Append to buffer. */ + n += (MSize)sz; + p = lj_buf_need(&ls->sb, n < len ? len : n); + memcpy(ls->sb.w, buf, sz); + ls->sb.w = p + n; + ls->p = p; + ls->pe = p + n; + } else { /* Return buffer provided by reader. */ + ls->p = buf; + ls->pe = buf + sz; + } + } while ((MSize)(ls->pe - ls->p) < len); +} + +/* Need a certain number of bytes. */ +static LJ_AINLINE void bcread_need(LexState *ls, MSize len) +{ + if (LJ_UNLIKELY((MSize)(ls->pe - ls->p) < len)) + bcread_fill(ls, len, 1); +} + +/* Want to read up to a certain number of bytes, but may need less. */ +static LJ_AINLINE void bcread_want(LexState *ls, MSize len) +{ + if (LJ_UNLIKELY((MSize)(ls->pe - ls->p) < len)) + bcread_fill(ls, len, 0); +} + +/* Return memory block from buffer. */ +static LJ_AINLINE uint8_t *bcread_mem(LexState *ls, MSize len) +{ + uint8_t *p = (uint8_t *)ls->p; + ls->p += len; + lj_assertLS(ls->p <= ls->pe, "buffer read overflow"); + return p; +} + +/* Copy memory block from buffer. */ +static void bcread_block(LexState *ls, void *q, MSize len) +{ + memcpy(q, bcread_mem(ls, len), len); +} + +/* Read byte from buffer. */ +static LJ_AINLINE uint32_t bcread_byte(LexState *ls) +{ + lj_assertLS(ls->p < ls->pe, "buffer read overflow"); + return (uint32_t)(uint8_t)*ls->p++; +} + +/* Read ULEB128 value from buffer. */ +static LJ_AINLINE uint32_t bcread_uleb128(LexState *ls) +{ + uint32_t v = lj_buf_ruleb128(&ls->p); + lj_assertLS(ls->p <= ls->pe, "buffer read overflow"); + return v; +} + +/* Read top 32 bits of 33 bit ULEB128 value from buffer. */ +static uint32_t bcread_uleb128_33(LexState *ls) +{ + const uint8_t *p = (const uint8_t *)ls->p; + uint32_t v = (*p++ >> 1); + if (LJ_UNLIKELY(v >= 0x40)) { + int sh = -1; + v &= 0x3f; + do { + v |= ((*p & 0x7f) << (sh += 7)); + } while (*p++ >= 0x80); + } + ls->p = (char *)p; + lj_assertLS(ls->p <= ls->pe, "buffer read overflow"); + return v; +} + +/* -- Bytecode reader ----------------------------------------------------- */ + +/* Read debug info of a prototype. */ +static void bcread_dbg(LexState *ls, GCproto *pt, MSize sizedbg) +{ + void *lineinfo = (void *)proto_lineinfo(pt); + bcread_block(ls, lineinfo, sizedbg); + /* Swap lineinfo if the endianess differs. */ + if (bcread_swap(ls) && pt->numline >= 256) { + MSize i, n = pt->sizebc-1; + if (pt->numline < 65536) { + uint16_t *p = (uint16_t *)lineinfo; + for (i = 0; i < n; i++) p[i] = (uint16_t)((p[i] >> 8)|(p[i] << 8)); + } else { + uint32_t *p = (uint32_t *)lineinfo; + for (i = 0; i < n; i++) p[i] = lj_bswap(p[i]); + } + } +} + +/* Find pointer to varinfo. */ +static const void *bcread_varinfo(GCproto *pt) +{ + const uint8_t *p = proto_uvinfo(pt); + MSize n = pt->sizeuv; + if (n) while (*p++ || --n) ; + return p; +} + +/* Read a single constant key/value of a template table. */ +static void bcread_ktabk(LexState *ls, TValue *o) +{ + MSize tp = bcread_uleb128(ls); + if (tp >= BCDUMP_KTAB_STR) { + MSize len = tp - BCDUMP_KTAB_STR; + const char *p = (const char *)bcread_mem(ls, len); + setstrV(ls->L, o, lj_str_new(ls->L, p, len)); + } else if (tp == BCDUMP_KTAB_INT) { + setintV(o, (int32_t)bcread_uleb128(ls)); + } else if (tp == BCDUMP_KTAB_NUM) { + o->u32.lo = bcread_uleb128(ls); + o->u32.hi = bcread_uleb128(ls); + } else { + lj_assertLS(tp <= BCDUMP_KTAB_TRUE, "bad constant type %d", tp); + setpriV(o, ~tp); + } +} + +/* Read a template table. */ +static GCtab *bcread_ktab(LexState *ls) +{ + MSize narray = bcread_uleb128(ls); + MSize nhash = bcread_uleb128(ls); + GCtab *t = lj_tab_new(ls->L, narray, hsize2hbits(nhash)); + if (narray) { /* Read array entries. */ + MSize i; + TValue *o = tvref(t->array); + for (i = 0; i < narray; i++, o++) + bcread_ktabk(ls, o); + } + if (nhash) { /* Read hash entries. */ + MSize i; + for (i = 0; i < nhash; i++) { + TValue key; + bcread_ktabk(ls, &key); + lj_assertLS(!tvisnil(&key), "nil key"); + bcread_ktabk(ls, lj_tab_set(ls->L, t, &key)); + } + } + return t; +} + +/* Read GC constants of a prototype. */ +static void bcread_kgc(LexState *ls, GCproto *pt, MSize sizekgc) +{ + MSize i; + GCRef *kr = mref(pt->k, GCRef) - (ptrdiff_t)sizekgc; + for (i = 0; i < sizekgc; i++, kr++) { + MSize tp = bcread_uleb128(ls); + if (tp >= BCDUMP_KGC_STR) { + MSize len = tp - BCDUMP_KGC_STR; + const char *p = (const char *)bcread_mem(ls, len); + setgcref(*kr, obj2gco(lj_str_new(ls->L, p, len))); + } else if (tp == BCDUMP_KGC_TAB) { + setgcref(*kr, obj2gco(bcread_ktab(ls))); +#if LJ_HASFFI + } else if (tp != BCDUMP_KGC_CHILD) { + CTypeID id = tp == BCDUMP_KGC_COMPLEX ? CTID_COMPLEX_DOUBLE : + tp == BCDUMP_KGC_I64 ? CTID_INT64 : CTID_UINT64; + CTSize sz = tp == BCDUMP_KGC_COMPLEX ? 16 : 8; + GCcdata *cd = lj_cdata_new_(ls->L, id, sz); + TValue *p = (TValue *)cdataptr(cd); + setgcref(*kr, obj2gco(cd)); + p[0].u32.lo = bcread_uleb128(ls); + p[0].u32.hi = bcread_uleb128(ls); + if (tp == BCDUMP_KGC_COMPLEX) { + p[1].u32.lo = bcread_uleb128(ls); + p[1].u32.hi = bcread_uleb128(ls); + } +#endif + } else { + lua_State *L = ls->L; + lj_assertLS(tp == BCDUMP_KGC_CHILD, "bad constant type %d", tp); + if (L->top <= bcread_oldtop(L, ls)) /* Stack underflow? */ + bcread_error(ls, LJ_ERR_BCBAD); + L->top--; + setgcref(*kr, obj2gco(protoV(L->top))); + } + } +} + +/* Read number constants of a prototype. */ +static void bcread_knum(LexState *ls, GCproto *pt, MSize sizekn) +{ + MSize i; + TValue *o = mref(pt->k, TValue); + for (i = 0; i < sizekn; i++, o++) { + int isnum = (ls->p[0] & 1); + uint32_t lo = bcread_uleb128_33(ls); + if (isnum) { + o->u32.lo = lo; + o->u32.hi = bcread_uleb128(ls); + } else { + setintV(o, lo); + } + } +} + +/* Read bytecode instructions. */ +static void bcread_bytecode(LexState *ls, GCproto *pt, MSize sizebc) +{ + BCIns *bc = proto_bc(pt); + bc[0] = BCINS_AD((pt->flags & PROTO_VARARG) ? BC_FUNCV : BC_FUNCF, + pt->framesize, 0); + bcread_block(ls, bc+1, (sizebc-1)*(MSize)sizeof(BCIns)); + /* Swap bytecode instructions if the endianess differs. */ + if (bcread_swap(ls)) { + MSize i; + for (i = 1; i < sizebc; i++) bc[i] = lj_bswap(bc[i]); + } +} + +/* Read upvalue refs. */ +static void bcread_uv(LexState *ls, GCproto *pt, MSize sizeuv) +{ + if (sizeuv) { + uint16_t *uv = proto_uv(pt); + bcread_block(ls, uv, sizeuv*2); + /* Swap upvalue refs if the endianess differs. */ + if (bcread_swap(ls)) { + MSize i; + for (i = 0; i < sizeuv; i++) + uv[i] = (uint16_t)((uv[i] >> 8)|(uv[i] << 8)); + } + } +} + +/* Read a prototype. */ +GCproto *lj_bcread_proto(LexState *ls) +{ + GCproto *pt; + MSize framesize, numparams, flags, sizeuv, sizekgc, sizekn, sizebc, sizept; + MSize ofsk, ofsuv, ofsdbg; + MSize sizedbg = 0; + BCLine firstline = 0, numline = 0; + + /* Read prototype header. */ + flags = bcread_byte(ls); + numparams = bcread_byte(ls); + framesize = bcread_byte(ls); + sizeuv = bcread_byte(ls); + sizekgc = bcread_uleb128(ls); + sizekn = bcread_uleb128(ls); + sizebc = bcread_uleb128(ls) + 1; + if (!(bcread_flags(ls) & BCDUMP_F_STRIP)) { + sizedbg = bcread_uleb128(ls); + if (sizedbg) { + firstline = bcread_uleb128(ls); + numline = bcread_uleb128(ls); + } + } + + /* Calculate total size of prototype including all colocated arrays. */ + sizept = (MSize)sizeof(GCproto) + + sizebc*(MSize)sizeof(BCIns) + + sizekgc*(MSize)sizeof(GCRef); + sizept = (sizept + (MSize)sizeof(TValue)-1) & ~((MSize)sizeof(TValue)-1); + ofsk = sizept; sizept += sizekn*(MSize)sizeof(TValue); + ofsuv = sizept; sizept += ((sizeuv+1)&~1)*2; + ofsdbg = sizept; sizept += sizedbg; + + /* Allocate prototype object and initialize its fields. */ + pt = (GCproto *)lj_mem_newgco(ls->L, (MSize)sizept); + pt->gct = ~LJ_TPROTO; + pt->numparams = (uint8_t)numparams; + pt->framesize = (uint8_t)framesize; + pt->sizebc = sizebc; + setmref(pt->k, (char *)pt + ofsk); + setmref(pt->uv, (char *)pt + ofsuv); + pt->sizekgc = 0; /* Set to zero until fully initialized. */ + pt->sizekn = sizekn; + pt->sizept = sizept; + pt->sizeuv = (uint8_t)sizeuv; + pt->flags = (uint8_t)flags; + pt->trace = 0; + setgcref(pt->chunkname, obj2gco(ls->chunkname)); + + /* Close potentially uninitialized gap between bc and kgc. */ + *(uint32_t *)((char *)pt + ofsk - sizeof(GCRef)*(sizekgc+1)) = 0; + + /* Read bytecode instructions and upvalue refs. */ + bcread_bytecode(ls, pt, sizebc); + bcread_uv(ls, pt, sizeuv); + + /* Read constants. */ + bcread_kgc(ls, pt, sizekgc); + pt->sizekgc = sizekgc; + bcread_knum(ls, pt, sizekn); + + /* Read and initialize debug info. */ + pt->firstline = firstline; + pt->numline = numline; + if (sizedbg) { + MSize sizeli = (sizebc-1) << (numline < 256 ? 0 : numline < 65536 ? 1 : 2); + setmref(pt->lineinfo, (char *)pt + ofsdbg); + setmref(pt->uvinfo, (char *)pt + ofsdbg + sizeli); + bcread_dbg(ls, pt, sizedbg); + setmref(pt->varinfo, bcread_varinfo(pt)); + } else { + setmref(pt->lineinfo, NULL); + setmref(pt->uvinfo, NULL); + setmref(pt->varinfo, NULL); + } + return pt; +} + +/* Read and check header of bytecode dump. */ +static int bcread_header(LexState *ls) +{ + uint32_t flags; + bcread_want(ls, 3+5+5); + if (bcread_byte(ls) != BCDUMP_HEAD2 || + bcread_byte(ls) != BCDUMP_HEAD3 || + bcread_byte(ls) != BCDUMP_VERSION) return 0; + bcread_flags(ls) = flags = bcread_uleb128(ls); + if ((flags & ~(BCDUMP_F_KNOWN)) != 0) return 0; + if ((flags & BCDUMP_F_FR2) != LJ_FR2*BCDUMP_F_FR2) return 0; + if ((flags & BCDUMP_F_FFI)) { +#if LJ_HASFFI + lua_State *L = ls->L; + ctype_loadffi(L); +#else + return 0; +#endif + } + if ((flags & BCDUMP_F_STRIP)) { + ls->chunkname = lj_str_newz(ls->L, ls->chunkarg); + } else { + MSize len = bcread_uleb128(ls); + bcread_need(ls, len); + ls->chunkname = lj_str_new(ls->L, (const char *)bcread_mem(ls, len), len); + } + return 1; /* Ok. */ +} + +/* Read a bytecode dump. */ +GCproto *lj_bcread(LexState *ls) +{ + lua_State *L = ls->L; + lj_assertLS(ls->c == BCDUMP_HEAD1, "bad bytecode header"); + bcread_savetop(L, ls, L->top); + lj_buf_reset(&ls->sb); + /* Check for a valid bytecode dump header. */ + if (!bcread_header(ls)) + bcread_error(ls, LJ_ERR_BCFMT); + for (;;) { /* Process all prototypes in the bytecode dump. */ + GCproto *pt; + MSize len; + const char *startp; + /* Read length. */ + if (ls->p < ls->pe && ls->p[0] == 0) { /* Shortcut EOF. */ + ls->p++; + break; + } + bcread_want(ls, 5); + len = bcread_uleb128(ls); + if (!len) break; /* EOF */ + bcread_need(ls, len); + startp = ls->p; + pt = lj_bcread_proto(ls); + if (ls->p != startp + len) + bcread_error(ls, LJ_ERR_BCBAD); + setprotoV(L, L->top, pt); + incr_top(L); + } + if ((ls->pe != ls->p && !ls->endmark) || L->top-1 != bcread_oldtop(L, ls)) + bcread_error(ls, LJ_ERR_BCBAD); + /* Pop off last prototype. */ + L->top--; + return protoV(L->top); +} + diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_bcwrite.c b/fluent-bit/lib/luajit-3065c9/src/lj_bcwrite.c new file mode 100644 index 00000000..2c70ff47 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_bcwrite.c @@ -0,0 +1,372 @@ +/* +** Bytecode writer. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#define lj_bcwrite_c +#define LUA_CORE + +#include "lj_obj.h" +#include "lj_gc.h" +#include "lj_buf.h" +#include "lj_bc.h" +#if LJ_HASFFI +#include "lj_ctype.h" +#endif +#if LJ_HASJIT +#include "lj_dispatch.h" +#include "lj_jit.h" +#endif +#include "lj_strfmt.h" +#include "lj_bcdump.h" +#include "lj_vm.h" + +/* Context for bytecode writer. */ +typedef struct BCWriteCtx { + SBuf sb; /* Output buffer. */ + GCproto *pt; /* Root prototype. */ + lua_Writer wfunc; /* Writer callback. */ + void *wdata; /* Writer callback data. */ + int strip; /* Strip debug info. */ + int status; /* Status from writer callback. */ +#ifdef LUA_USE_ASSERT + global_State *g; +#endif +} BCWriteCtx; + +#ifdef LUA_USE_ASSERT +#define lj_assertBCW(c, ...) lj_assertG_(ctx->g, (c), __VA_ARGS__) +#else +#define lj_assertBCW(c, ...) ((void)ctx) +#endif + +/* -- Bytecode writer ----------------------------------------------------- */ + +/* Write a single constant key/value of a template table. */ +static void bcwrite_ktabk(BCWriteCtx *ctx, cTValue *o, int narrow) +{ + char *p = lj_buf_more(&ctx->sb, 1+10); + if (tvisstr(o)) { + const GCstr *str = strV(o); + MSize len = str->len; + p = lj_buf_more(&ctx->sb, 5+len); + p = lj_strfmt_wuleb128(p, BCDUMP_KTAB_STR+len); + p = lj_buf_wmem(p, strdata(str), len); + } else if (tvisint(o)) { + *p++ = BCDUMP_KTAB_INT; + p = lj_strfmt_wuleb128(p, intV(o)); + } else if (tvisnum(o)) { + if (!LJ_DUALNUM && narrow) { /* Narrow number constants to integers. */ + lua_Number num = numV(o); + int32_t k = lj_num2int(num); + if (num == (lua_Number)k) { /* -0 is never a constant. */ + *p++ = BCDUMP_KTAB_INT; + p = lj_strfmt_wuleb128(p, k); + ctx->sb.w = p; + return; + } + } + *p++ = BCDUMP_KTAB_NUM; + p = lj_strfmt_wuleb128(p, o->u32.lo); + p = lj_strfmt_wuleb128(p, o->u32.hi); + } else { + lj_assertBCW(tvispri(o), "unhandled type %d", itype(o)); + *p++ = BCDUMP_KTAB_NIL+~itype(o); + } + ctx->sb.w = p; +} + +/* Write a template table. */ +static void bcwrite_ktab(BCWriteCtx *ctx, char *p, const GCtab *t) +{ + MSize narray = 0, nhash = 0; + if (t->asize > 0) { /* Determine max. length of array part. */ + ptrdiff_t i; + TValue *array = tvref(t->array); + for (i = (ptrdiff_t)t->asize-1; i >= 0; i--) + if (!tvisnil(&array[i])) + break; + narray = (MSize)(i+1); + } + if (t->hmask > 0) { /* Count number of used hash slots. */ + MSize i, hmask = t->hmask; + Node *node = noderef(t->node); + for (i = 0; i <= hmask; i++) + nhash += !tvisnil(&node[i].val); + } + /* Write number of array slots and hash slots. */ + p = lj_strfmt_wuleb128(p, narray); + p = lj_strfmt_wuleb128(p, nhash); + ctx->sb.w = p; + if (narray) { /* Write array entries (may contain nil). */ + MSize i; + TValue *o = tvref(t->array); + for (i = 0; i < narray; i++, o++) + bcwrite_ktabk(ctx, o, 1); + } + if (nhash) { /* Write hash entries. */ + MSize i = nhash; + Node *node = noderef(t->node) + t->hmask; + for (;; node--) + if (!tvisnil(&node->val)) { + bcwrite_ktabk(ctx, &node->key, 0); + bcwrite_ktabk(ctx, &node->val, 1); + if (--i == 0) break; + } + } +} + +/* Write GC constants of a prototype. */ +static void bcwrite_kgc(BCWriteCtx *ctx, GCproto *pt) +{ + MSize i, sizekgc = pt->sizekgc; + GCRef *kr = mref(pt->k, GCRef) - (ptrdiff_t)sizekgc; + for (i = 0; i < sizekgc; i++, kr++) { + GCobj *o = gcref(*kr); + MSize tp, need = 1; + char *p; + /* Determine constant type and needed size. */ + if (o->gch.gct == ~LJ_TSTR) { + tp = BCDUMP_KGC_STR + gco2str(o)->len; + need = 5+gco2str(o)->len; + } else if (o->gch.gct == ~LJ_TPROTO) { + lj_assertBCW((pt->flags & PROTO_CHILD), "prototype has unexpected child"); + tp = BCDUMP_KGC_CHILD; +#if LJ_HASFFI + } else if (o->gch.gct == ~LJ_TCDATA) { + CTypeID id = gco2cd(o)->ctypeid; + need = 1+4*5; + if (id == CTID_INT64) { + tp = BCDUMP_KGC_I64; + } else if (id == CTID_UINT64) { + tp = BCDUMP_KGC_U64; + } else { + lj_assertBCW(id == CTID_COMPLEX_DOUBLE, + "bad cdata constant CTID %d", id); + tp = BCDUMP_KGC_COMPLEX; + } +#endif + } else { + lj_assertBCW(o->gch.gct == ~LJ_TTAB, + "bad constant GC type %d", o->gch.gct); + tp = BCDUMP_KGC_TAB; + need = 1+2*5; + } + /* Write constant type. */ + p = lj_buf_more(&ctx->sb, need); + p = lj_strfmt_wuleb128(p, tp); + /* Write constant data (if any). */ + if (tp >= BCDUMP_KGC_STR) { + p = lj_buf_wmem(p, strdata(gco2str(o)), gco2str(o)->len); + } else if (tp == BCDUMP_KGC_TAB) { + bcwrite_ktab(ctx, p, gco2tab(o)); + continue; +#if LJ_HASFFI + } else if (tp != BCDUMP_KGC_CHILD) { + cTValue *q = (TValue *)cdataptr(gco2cd(o)); + p = lj_strfmt_wuleb128(p, q[0].u32.lo); + p = lj_strfmt_wuleb128(p, q[0].u32.hi); + if (tp == BCDUMP_KGC_COMPLEX) { + p = lj_strfmt_wuleb128(p, q[1].u32.lo); + p = lj_strfmt_wuleb128(p, q[1].u32.hi); + } +#endif + } + ctx->sb.w = p; + } +} + +/* Write number constants of a prototype. */ +static void bcwrite_knum(BCWriteCtx *ctx, GCproto *pt) +{ + MSize i, sizekn = pt->sizekn; + cTValue *o = mref(pt->k, TValue); + char *p = lj_buf_more(&ctx->sb, 10*sizekn); + for (i = 0; i < sizekn; i++, o++) { + int32_t k; + if (tvisint(o)) { + k = intV(o); + goto save_int; + } else { + /* Write a 33 bit ULEB128 for the int (lsb=0) or loword (lsb=1). */ + if (!LJ_DUALNUM) { /* Narrow number constants to integers. */ + lua_Number num = numV(o); + k = lj_num2int(num); + if (num == (lua_Number)k) { /* -0 is never a constant. */ + save_int: + p = lj_strfmt_wuleb128(p, 2*(uint32_t)k | ((uint32_t)k&0x80000000u)); + if (k < 0) + p[-1] = (p[-1] & 7) | ((k>>27) & 0x18); + continue; + } + } + p = lj_strfmt_wuleb128(p, 1+(2*o->u32.lo | (o->u32.lo & 0x80000000u))); + if (o->u32.lo >= 0x80000000u) + p[-1] = (p[-1] & 7) | ((o->u32.lo>>27) & 0x18); + p = lj_strfmt_wuleb128(p, o->u32.hi); + } + } + ctx->sb.w = p; +} + +/* Write bytecode instructions. */ +static char *bcwrite_bytecode(BCWriteCtx *ctx, char *p, GCproto *pt) +{ + MSize nbc = pt->sizebc-1; /* Omit the [JI]FUNC* header. */ +#if LJ_HASJIT + uint8_t *q = (uint8_t *)p; +#endif + p = lj_buf_wmem(p, proto_bc(pt)+1, nbc*(MSize)sizeof(BCIns)); + UNUSED(ctx); +#if LJ_HASJIT + /* Unpatch modified bytecode containing ILOOP/JLOOP etc. */ + if ((pt->flags & PROTO_ILOOP) || pt->trace) { + jit_State *J = L2J(sbufL(&ctx->sb)); + MSize i; + for (i = 0; i < nbc; i++, q += sizeof(BCIns)) { + BCOp op = (BCOp)q[LJ_ENDIAN_SELECT(0, 3)]; + if (op == BC_IFORL || op == BC_IITERL || op == BC_ILOOP || + op == BC_JFORI) { + q[LJ_ENDIAN_SELECT(0, 3)] = (uint8_t)(op-BC_IFORL+BC_FORL); + } else if (op == BC_JFORL || op == BC_JITERL || op == BC_JLOOP) { + BCReg rd = q[LJ_ENDIAN_SELECT(2, 1)] + (q[LJ_ENDIAN_SELECT(3, 0)] << 8); + memcpy(q, &traceref(J, rd)->startins, 4); + } + } + } +#endif + return p; +} + +/* Write prototype. */ +static void bcwrite_proto(BCWriteCtx *ctx, GCproto *pt) +{ + MSize sizedbg = 0; + char *p; + + /* Recursively write children of prototype. */ + if ((pt->flags & PROTO_CHILD)) { + ptrdiff_t i, n = pt->sizekgc; + GCRef *kr = mref(pt->k, GCRef) - 1; + for (i = 0; i < n; i++, kr--) { + GCobj *o = gcref(*kr); + if (o->gch.gct == ~LJ_TPROTO) + bcwrite_proto(ctx, gco2pt(o)); + } + } + + /* Start writing the prototype info to a buffer. */ + p = lj_buf_need(&ctx->sb, + 5+4+6*5+(pt->sizebc-1)*(MSize)sizeof(BCIns)+pt->sizeuv*2); + p += 5; /* Leave room for final size. */ + + /* Write prototype header. */ + *p++ = (pt->flags & (PROTO_CHILD|PROTO_VARARG|PROTO_FFI)); + *p++ = pt->numparams; + *p++ = pt->framesize; + *p++ = pt->sizeuv; + p = lj_strfmt_wuleb128(p, pt->sizekgc); + p = lj_strfmt_wuleb128(p, pt->sizekn); + p = lj_strfmt_wuleb128(p, pt->sizebc-1); + if (!ctx->strip) { + if (proto_lineinfo(pt)) + sizedbg = pt->sizept - (MSize)((char *)proto_lineinfo(pt) - (char *)pt); + p = lj_strfmt_wuleb128(p, sizedbg); + if (sizedbg) { + p = lj_strfmt_wuleb128(p, pt->firstline); + p = lj_strfmt_wuleb128(p, pt->numline); + } + } + + /* Write bytecode instructions and upvalue refs. */ + p = bcwrite_bytecode(ctx, p, pt); + p = lj_buf_wmem(p, proto_uv(pt), pt->sizeuv*2); + ctx->sb.w = p; + + /* Write constants. */ + bcwrite_kgc(ctx, pt); + bcwrite_knum(ctx, pt); + + /* Write debug info, if not stripped. */ + if (sizedbg) { + p = lj_buf_more(&ctx->sb, sizedbg); + p = lj_buf_wmem(p, proto_lineinfo(pt), sizedbg); + ctx->sb.w = p; + } + + /* Pass buffer to writer function. */ + if (ctx->status == 0) { + MSize n = sbuflen(&ctx->sb) - 5; + MSize nn = (lj_fls(n)+8)*9 >> 6; + char *q = ctx->sb.b + (5 - nn); + p = lj_strfmt_wuleb128(q, n); /* Fill in final size. */ + lj_assertBCW(p == ctx->sb.b + 5, "bad ULEB128 write"); + ctx->status = ctx->wfunc(sbufL(&ctx->sb), q, nn+n, ctx->wdata); + } +} + +/* Write header of bytecode dump. */ +static void bcwrite_header(BCWriteCtx *ctx) +{ + GCstr *chunkname = proto_chunkname(ctx->pt); + const char *name = strdata(chunkname); + MSize len = chunkname->len; + char *p = lj_buf_need(&ctx->sb, 5+5+len); + *p++ = BCDUMP_HEAD1; + *p++ = BCDUMP_HEAD2; + *p++ = BCDUMP_HEAD3; + *p++ = BCDUMP_VERSION; + *p++ = (ctx->strip ? BCDUMP_F_STRIP : 0) + + LJ_BE*BCDUMP_F_BE + + ((ctx->pt->flags & PROTO_FFI) ? BCDUMP_F_FFI : 0) + + LJ_FR2*BCDUMP_F_FR2; + if (!ctx->strip) { + p = lj_strfmt_wuleb128(p, len); + p = lj_buf_wmem(p, name, len); + } + ctx->status = ctx->wfunc(sbufL(&ctx->sb), ctx->sb.b, + (MSize)(p - ctx->sb.b), ctx->wdata); +} + +/* Write footer of bytecode dump. */ +static void bcwrite_footer(BCWriteCtx *ctx) +{ + if (ctx->status == 0) { + uint8_t zero = 0; + ctx->status = ctx->wfunc(sbufL(&ctx->sb), &zero, 1, ctx->wdata); + } +} + +/* Protected callback for bytecode writer. */ +static TValue *cpwriter(lua_State *L, lua_CFunction dummy, void *ud) +{ + BCWriteCtx *ctx = (BCWriteCtx *)ud; + UNUSED(L); UNUSED(dummy); + lj_buf_need(&ctx->sb, 1024); /* Avoids resize for most prototypes. */ + bcwrite_header(ctx); + bcwrite_proto(ctx, ctx->pt); + bcwrite_footer(ctx); + return NULL; +} + +/* Write bytecode for a prototype. */ +int lj_bcwrite(lua_State *L, GCproto *pt, lua_Writer writer, void *data, + int strip) +{ + BCWriteCtx ctx; + int status; + ctx.pt = pt; + ctx.wfunc = writer; + ctx.wdata = data; + ctx.strip = strip; + ctx.status = 0; +#ifdef LUA_USE_ASSERT + ctx.g = G(L); +#endif + lj_buf_init(L, &ctx.sb); + status = lj_vm_cpcall(L, NULL, &ctx, cpwriter); + if (status == 0) status = ctx.status; + lj_buf_free(G(sbufL(&ctx.sb)), &ctx.sb); + return status; +} + diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_buf.c b/fluent-bit/lib/luajit-3065c9/src/lj_buf.c new file mode 100644 index 00000000..cf268af2 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_buf.c @@ -0,0 +1,305 @@ +/* +** Buffer handling. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#define lj_buf_c +#define LUA_CORE + +#include "lj_obj.h" +#include "lj_gc.h" +#include "lj_err.h" +#include "lj_buf.h" +#include "lj_str.h" +#include "lj_tab.h" +#include "lj_strfmt.h" + +/* -- Buffer management --------------------------------------------------- */ + +static void buf_grow(SBuf *sb, MSize sz) +{ + MSize osz = sbufsz(sb), len = sbuflen(sb), nsz = osz; + char *b; + GCSize flag; + if (nsz < LJ_MIN_SBUF) nsz = LJ_MIN_SBUF; + while (nsz < sz) nsz += nsz; + flag = sbufflag(sb); + if ((flag & SBUF_FLAG_COW)) { /* Copy-on-write semantics. */ + lj_assertG_(G(sbufL(sb)), sb->w == sb->e, "bad SBuf COW"); + b = (char *)lj_mem_new(sbufL(sb), nsz); + setsbufflag(sb, flag & ~(GCSize)SBUF_FLAG_COW); + setgcrefnull(sbufX(sb)->cowref); + memcpy(b, sb->b, osz); + } else { + b = (char *)lj_mem_realloc(sbufL(sb), sb->b, osz, nsz); + } + if ((flag & SBUF_FLAG_EXT)) { + sbufX(sb)->r = sbufX(sb)->r - sb->b + b; /* Adjust read pointer, too. */ + } + /* Adjust buffer pointers. */ + sb->b = b; + sb->w = b + len; + sb->e = b + nsz; + if ((flag & SBUF_FLAG_BORROW)) { /* Adjust borrowed buffer pointers. */ + SBuf *bsb = mref(sbufX(sb)->bsb, SBuf); + bsb->b = b; + bsb->w = b + len; + bsb->e = b + nsz; + } +} + +LJ_NOINLINE char *LJ_FASTCALL lj_buf_need2(SBuf *sb, MSize sz) +{ + lj_assertG_(G(sbufL(sb)), sz > sbufsz(sb), "SBuf overflow"); + if (LJ_UNLIKELY(sz > LJ_MAX_BUF)) + lj_err_mem(sbufL(sb)); + buf_grow(sb, sz); + return sb->b; +} + +LJ_NOINLINE char *LJ_FASTCALL lj_buf_more2(SBuf *sb, MSize sz) +{ + if (sbufisext(sb)) { + SBufExt *sbx = (SBufExt *)sb; + MSize len = sbufxlen(sbx); + if (LJ_UNLIKELY(sz > LJ_MAX_BUF || len + sz > LJ_MAX_BUF)) + lj_err_mem(sbufL(sbx)); + if (len + sz > sbufsz(sbx)) { /* Must grow. */ + buf_grow((SBuf *)sbx, len + sz); + } else if (sbufiscow(sb) || sbufxslack(sbx) < (sbufsz(sbx) >> 3)) { + /* Also grow to avoid excessive compactions, if slack < size/8. */ + buf_grow((SBuf *)sbx, sbuflen(sbx) + sz); /* Not sbufxlen! */ + return sbx->w; + } + if (sbx->r != sbx->b) { /* Compact by moving down. */ + memmove(sbx->b, sbx->r, len); + sbx->r = sbx->b; + sbx->w = sbx->b + len; + lj_assertG_(G(sbufL(sbx)), len + sz <= sbufsz(sbx), "bad SBuf compact"); + } + } else { + MSize len = sbuflen(sb); + lj_assertG_(G(sbufL(sb)), sz > sbufleft(sb), "SBuf overflow"); + if (LJ_UNLIKELY(sz > LJ_MAX_BUF || len + sz > LJ_MAX_BUF)) + lj_err_mem(sbufL(sb)); + buf_grow(sb, len + sz); + } + return sb->w; +} + +void LJ_FASTCALL lj_buf_shrink(lua_State *L, SBuf *sb) +{ + char *b = sb->b; + MSize osz = (MSize)(sb->e - b); + if (osz > 2*LJ_MIN_SBUF) { + MSize n = (MSize)(sb->w - b); + b = lj_mem_realloc(L, b, osz, (osz >> 1)); + sb->b = b; + sb->w = b + n; + sb->e = b + (osz >> 1); + } + lj_assertG_(G(sbufL(sb)), !sbufisext(sb), "YAGNI shrink SBufExt"); +} + +char * LJ_FASTCALL lj_buf_tmp(lua_State *L, MSize sz) +{ + SBuf *sb = &G(L)->tmpbuf; + setsbufL(sb, L); + return lj_buf_need(sb, sz); +} + +#if LJ_HASBUFFER && LJ_HASJIT +void lj_bufx_set(SBufExt *sbx, const char *p, MSize len, GCobj *ref) +{ + lua_State *L = sbufL(sbx); + lj_bufx_free(L, sbx); + lj_bufx_set_cow(L, sbx, p, len); + setgcref(sbx->cowref, ref); + lj_gc_objbarrier(L, (GCudata *)sbx - 1, ref); +} + +#if LJ_HASFFI +MSize LJ_FASTCALL lj_bufx_more(SBufExt *sbx, MSize sz) +{ + lj_buf_more((SBuf *)sbx, sz); + return sbufleft(sbx); +} +#endif +#endif + +/* -- Low-level buffer put operations ------------------------------------- */ + +SBuf *lj_buf_putmem(SBuf *sb, const void *q, MSize len) +{ + char *w = lj_buf_more(sb, len); + w = lj_buf_wmem(w, q, len); + sb->w = w; + return sb; +} + +#if LJ_HASJIT || LJ_HASFFI +static LJ_NOINLINE SBuf * LJ_FASTCALL lj_buf_putchar2(SBuf *sb, int c) +{ + char *w = lj_buf_more2(sb, 1); + *w++ = (char)c; + sb->w = w; + return sb; +} + +SBuf * LJ_FASTCALL lj_buf_putchar(SBuf *sb, int c) +{ + char *w = sb->w; + if (LJ_LIKELY(w < sb->e)) { + *w++ = (char)c; + sb->w = w; + return sb; + } + return lj_buf_putchar2(sb, c); +} +#endif + +SBuf * LJ_FASTCALL lj_buf_putstr(SBuf *sb, GCstr *s) +{ + MSize len = s->len; + char *w = lj_buf_more(sb, len); + w = lj_buf_wmem(w, strdata(s), len); + sb->w = w; + return sb; +} + +/* -- High-level buffer put operations ------------------------------------ */ + +SBuf * LJ_FASTCALL lj_buf_putstr_reverse(SBuf *sb, GCstr *s) +{ + MSize len = s->len; + char *w = lj_buf_more(sb, len), *e = w+len; + const char *q = strdata(s)+len-1; + while (w < e) + *w++ = *q--; + sb->w = w; + return sb; +} + +SBuf * LJ_FASTCALL lj_buf_putstr_lower(SBuf *sb, GCstr *s) +{ + MSize len = s->len; + char *w = lj_buf_more(sb, len), *e = w+len; + const char *q = strdata(s); + for (; w < e; w++, q++) { + uint32_t c = *(unsigned char *)q; +#if LJ_TARGET_PPC + *w = c + ((c >= 'A' && c <= 'Z') << 5); +#else + if (c >= 'A' && c <= 'Z') c += 0x20; + *w = c; +#endif + } + sb->w = w; + return sb; +} + +SBuf * LJ_FASTCALL lj_buf_putstr_upper(SBuf *sb, GCstr *s) +{ + MSize len = s->len; + char *w = lj_buf_more(sb, len), *e = w+len; + const char *q = strdata(s); + for (; w < e; w++, q++) { + uint32_t c = *(unsigned char *)q; +#if LJ_TARGET_PPC + *w = c - ((c >= 'a' && c <= 'z') << 5); +#else + if (c >= 'a' && c <= 'z') c -= 0x20; + *w = c; +#endif + } + sb->w = w; + return sb; +} + +SBuf *lj_buf_putstr_rep(SBuf *sb, GCstr *s, int32_t rep) +{ + MSize len = s->len; + if (rep > 0 && len) { + uint64_t tlen = (uint64_t)rep * len; + char *w; + if (LJ_UNLIKELY(tlen > LJ_MAX_STR)) + lj_err_mem(sbufL(sb)); + w = lj_buf_more(sb, (MSize)tlen); + if (len == 1) { /* Optimize a common case. */ + uint32_t c = strdata(s)[0]; + do { *w++ = c; } while (--rep > 0); + } else { + const char *e = strdata(s) + len; + do { + const char *q = strdata(s); + do { *w++ = *q++; } while (q < e); + } while (--rep > 0); + } + sb->w = w; + } + return sb; +} + +SBuf *lj_buf_puttab(SBuf *sb, GCtab *t, GCstr *sep, int32_t i, int32_t e) +{ + MSize seplen = sep ? sep->len : 0; + if (i <= e) { + for (;;) { + cTValue *o = lj_tab_getint(t, i); + char *w; + if (!o) { + badtype: /* Error: bad element type. */ + sb->w = (char *)(intptr_t)i; /* Store failing index. */ + return NULL; + } else if (tvisstr(o)) { + MSize len = strV(o)->len; + w = lj_buf_wmem(lj_buf_more(sb, len + seplen), strVdata(o), len); + } else if (tvisint(o)) { + w = lj_strfmt_wint(lj_buf_more(sb, STRFMT_MAXBUF_INT+seplen), intV(o)); + } else if (tvisnum(o)) { + w = lj_buf_more(lj_strfmt_putfnum(sb, STRFMT_G14, numV(o)), seplen); + } else { + goto badtype; + } + if (i++ == e) { + sb->w = w; + break; + } + if (seplen) w = lj_buf_wmem(w, strdata(sep), seplen); + sb->w = w; + } + } + return sb; +} + +/* -- Miscellaneous buffer operations ------------------------------------- */ + +GCstr * LJ_FASTCALL lj_buf_tostr(SBuf *sb) +{ + return lj_str_new(sbufL(sb), sb->b, sbuflen(sb)); +} + +/* Concatenate two strings. */ +GCstr *lj_buf_cat2str(lua_State *L, GCstr *s1, GCstr *s2) +{ + MSize len1 = s1->len, len2 = s2->len; + char *buf = lj_buf_tmp(L, len1 + len2); + memcpy(buf, strdata(s1), len1); + memcpy(buf+len1, strdata(s2), len2); + return lj_str_new(L, buf, len1 + len2); +} + +/* Read ULEB128 from buffer. */ +uint32_t LJ_FASTCALL lj_buf_ruleb128(const char **pp) +{ + const uint8_t *w = (const uint8_t *)*pp; + uint32_t v = *w++; + if (LJ_UNLIKELY(v >= 0x80)) { + int sh = 0; + v &= 0x7f; + do { v |= ((*w & 0x7f) << (sh += 7)); } while (*w++ >= 0x80); + } + *pp = (const char *)w; + return v; +} + diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_buf.h b/fluent-bit/lib/luajit-3065c9/src/lj_buf.h new file mode 100644 index 00000000..76114201 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_buf.h @@ -0,0 +1,198 @@ +/* +** Buffer handling. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#ifndef _LJ_BUF_H +#define _LJ_BUF_H + +#include "lj_obj.h" +#include "lj_gc.h" +#include "lj_str.h" + +/* Resizable string buffers. */ + +/* The SBuf struct definition is in lj_obj.h: +** char *w; Write pointer. +** char *e; End pointer. +** char *b; Base pointer. +** MRef L; lua_State, used for buffer resizing. Extension bits in 3 LSB. +*/ + +/* Extended string buffer. */ +typedef struct SBufExt { + SBufHeader; + union { + GCRef cowref; /* Copy-on-write object reference. */ + MRef bsb; /* Borrowed string buffer. */ + }; + char *r; /* Read pointer. */ + GCRef dict_str; /* Serialization string dictionary table. */ + GCRef dict_mt; /* Serialization metatable dictionary table. */ + int depth; /* Remaining recursion depth. */ +} SBufExt; + +#define sbufsz(sb) ((MSize)((sb)->e - (sb)->b)) +#define sbuflen(sb) ((MSize)((sb)->w - (sb)->b)) +#define sbufleft(sb) ((MSize)((sb)->e - (sb)->w)) +#define sbufxlen(sbx) ((MSize)((sbx)->w - (sbx)->r)) +#define sbufxslack(sbx) ((MSize)((sbx)->r - (sbx)->b)) + +#define SBUF_MASK_FLAG (7) +#define SBUF_MASK_L (~(GCSize)SBUF_MASK_FLAG) +#define SBUF_FLAG_EXT 1 /* Extended string buffer. */ +#define SBUF_FLAG_COW 2 /* Copy-on-write buffer. */ +#define SBUF_FLAG_BORROW 4 /* Borrowed string buffer. */ + +#define sbufL(sb) \ + ((lua_State *)(void *)(uintptr_t)(mrefu((sb)->L) & SBUF_MASK_L)) +#define setsbufL(sb, l) (setmref((sb)->L, (l))) +#define setsbufXL(sb, l, flag) \ + (setmrefu((sb)->L, (GCSize)(uintptr_t)(void *)(l) + (flag))) +#define setsbufXL_(sb, l) \ + (setmrefu((sb)->L, (GCSize)(uintptr_t)(void *)(l) | (mrefu((sb)->L) & SBUF_MASK_FLAG))) + +#define sbufflag(sb) (mrefu((sb)->L)) +#define sbufisext(sb) (sbufflag((sb)) & SBUF_FLAG_EXT) +#define sbufiscow(sb) (sbufflag((sb)) & SBUF_FLAG_COW) +#define sbufisborrow(sb) (sbufflag((sb)) & SBUF_FLAG_BORROW) +#define sbufiscoworborrow(sb) (sbufflag((sb)) & (SBUF_FLAG_COW|SBUF_FLAG_BORROW)) +#define sbufX(sb) \ + (lj_assertG_(G(sbufL(sb)), sbufisext(sb), "not an SBufExt"), (SBufExt *)(sb)) +#define setsbufflag(sb, flag) (setmrefu((sb)->L, (flag))) + +#define tvisbuf(o) \ + (LJ_HASBUFFER && tvisudata(o) && udataV(o)->udtype == UDTYPE_BUFFER) +#define bufV(o) check_exp(tvisbuf(o), ((SBufExt *)uddata(udataV(o)))) + +/* Buffer management */ +LJ_FUNC char *LJ_FASTCALL lj_buf_need2(SBuf *sb, MSize sz); +LJ_FUNC char *LJ_FASTCALL lj_buf_more2(SBuf *sb, MSize sz); +LJ_FUNC void LJ_FASTCALL lj_buf_shrink(lua_State *L, SBuf *sb); +LJ_FUNC char * LJ_FASTCALL lj_buf_tmp(lua_State *L, MSize sz); + +static LJ_AINLINE void lj_buf_init(lua_State *L, SBuf *sb) +{ + setsbufL(sb, L); + sb->w = sb->e = sb->b = NULL; +} + +static LJ_AINLINE void lj_buf_reset(SBuf *sb) +{ + sb->w = sb->b; +} + +static LJ_AINLINE SBuf *lj_buf_tmp_(lua_State *L) +{ + SBuf *sb = &G(L)->tmpbuf; + setsbufL(sb, L); + lj_buf_reset(sb); + return sb; +} + +static LJ_AINLINE void lj_buf_free(global_State *g, SBuf *sb) +{ + lj_assertG(!sbufisext(sb), "bad free of SBufExt"); + lj_mem_free(g, sb->b, sbufsz(sb)); +} + +static LJ_AINLINE char *lj_buf_need(SBuf *sb, MSize sz) +{ + if (LJ_UNLIKELY(sz > sbufsz(sb))) + return lj_buf_need2(sb, sz); + return sb->b; +} + +static LJ_AINLINE char *lj_buf_more(SBuf *sb, MSize sz) +{ + if (LJ_UNLIKELY(sz > sbufleft(sb))) + return lj_buf_more2(sb, sz); + return sb->w; +} + +/* Extended buffer management */ +static LJ_AINLINE void lj_bufx_init(lua_State *L, SBufExt *sbx) +{ + memset(sbx, 0, sizeof(SBufExt)); + setsbufXL(sbx, L, SBUF_FLAG_EXT); +} + +static LJ_AINLINE void lj_bufx_set_borrow(lua_State *L, SBufExt *sbx, SBuf *sb) +{ + setsbufXL(sbx, L, SBUF_FLAG_EXT | SBUF_FLAG_BORROW); + setmref(sbx->bsb, sb); + sbx->r = sbx->w = sbx->b = sb->b; + sbx->e = sb->e; +} + +static LJ_AINLINE void lj_bufx_set_cow(lua_State *L, SBufExt *sbx, + const char *p, MSize len) +{ + setsbufXL(sbx, L, SBUF_FLAG_EXT | SBUF_FLAG_COW); + sbx->r = sbx->b = (char *)p; + sbx->w = sbx->e = (char *)p + len; +} + +static LJ_AINLINE void lj_bufx_reset(SBufExt *sbx) +{ + if (sbufiscow(sbx)) { + setmrefu(sbx->L, (mrefu(sbx->L) & ~(GCSize)SBUF_FLAG_COW)); + setgcrefnull(sbx->cowref); + sbx->b = sbx->e = NULL; + } + sbx->r = sbx->w = sbx->b; +} + +static LJ_AINLINE void lj_bufx_free(lua_State *L, SBufExt *sbx) +{ + if (!sbufiscoworborrow(sbx)) lj_mem_free(G(L), sbx->b, sbufsz(sbx)); + setsbufXL(sbx, L, SBUF_FLAG_EXT); + setgcrefnull(sbx->cowref); + sbx->r = sbx->w = sbx->b = sbx->e = NULL; +} + +#if LJ_HASBUFFER && LJ_HASJIT +LJ_FUNC void lj_bufx_set(SBufExt *sbx, const char *p, MSize len, GCobj *o); +#if LJ_HASFFI +LJ_FUNC MSize LJ_FASTCALL lj_bufx_more(SBufExt *sbx, MSize sz); +#endif +#endif + +/* Low-level buffer put operations */ +LJ_FUNC SBuf *lj_buf_putmem(SBuf *sb, const void *q, MSize len); +#if LJ_HASJIT || LJ_HASFFI +LJ_FUNC SBuf * LJ_FASTCALL lj_buf_putchar(SBuf *sb, int c); +#endif +LJ_FUNC SBuf * LJ_FASTCALL lj_buf_putstr(SBuf *sb, GCstr *s); + +static LJ_AINLINE char *lj_buf_wmem(char *p, const void *q, MSize len) +{ + return (char *)memcpy(p, q, len) + len; +} + +static LJ_AINLINE void lj_buf_putb(SBuf *sb, int c) +{ + char *w = lj_buf_more(sb, 1); + *w++ = (char)c; + sb->w = w; +} + +/* High-level buffer put operations */ +LJ_FUNCA SBuf * LJ_FASTCALL lj_buf_putstr_reverse(SBuf *sb, GCstr *s); +LJ_FUNCA SBuf * LJ_FASTCALL lj_buf_putstr_lower(SBuf *sb, GCstr *s); +LJ_FUNCA SBuf * LJ_FASTCALL lj_buf_putstr_upper(SBuf *sb, GCstr *s); +LJ_FUNC SBuf *lj_buf_putstr_rep(SBuf *sb, GCstr *s, int32_t rep); +LJ_FUNC SBuf *lj_buf_puttab(SBuf *sb, GCtab *t, GCstr *sep, + int32_t i, int32_t e); + +/* Miscellaneous buffer operations */ +LJ_FUNCA GCstr * LJ_FASTCALL lj_buf_tostr(SBuf *sb); +LJ_FUNC GCstr *lj_buf_cat2str(lua_State *L, GCstr *s1, GCstr *s2); +LJ_FUNC uint32_t LJ_FASTCALL lj_buf_ruleb128(const char **pp); + +static LJ_AINLINE GCstr *lj_buf_str(lua_State *L, SBuf *sb) +{ + return lj_str_new(L, sb->b, sbuflen(sb)); +} + +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_carith.c b/fluent-bit/lib/luajit-3065c9/src/lj_carith.c new file mode 100644 index 00000000..1a2a058f --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_carith.c @@ -0,0 +1,432 @@ +/* +** C data arithmetic. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#include "lj_obj.h" + +#if LJ_HASFFI + +#include "lj_gc.h" +#include "lj_err.h" +#include "lj_tab.h" +#include "lj_meta.h" +#include "lj_ir.h" +#include "lj_ctype.h" +#include "lj_cconv.h" +#include "lj_cdata.h" +#include "lj_carith.h" +#include "lj_strscan.h" + +/* -- C data arithmetic --------------------------------------------------- */ + +/* Binary operands of an operator converted to ctypes. */ +typedef struct CDArith { + uint8_t *p[2]; + CType *ct[2]; +} CDArith; + +/* Check arguments for arithmetic metamethods. */ +static int carith_checkarg(lua_State *L, CTState *cts, CDArith *ca) +{ + TValue *o = L->base; + int ok = 1; + MSize i; + if (o+1 >= L->top) + lj_err_argt(L, 1, LUA_TCDATA); + for (i = 0; i < 2; i++, o++) { + if (tviscdata(o)) { + GCcdata *cd = cdataV(o); + CTypeID id = (CTypeID)cd->ctypeid; + CType *ct = ctype_raw(cts, id); + uint8_t *p = (uint8_t *)cdataptr(cd); + if (ctype_isptr(ct->info)) { + p = (uint8_t *)cdata_getptr(p, ct->size); + if (ctype_isref(ct->info)) ct = ctype_rawchild(cts, ct); + } else if (ctype_isfunc(ct->info)) { + p = (uint8_t *)*(void **)p; + ct = ctype_get(cts, + lj_ctype_intern(cts, CTINFO(CT_PTR, CTALIGN_PTR|id), CTSIZE_PTR)); + } + if (ctype_isenum(ct->info)) ct = ctype_child(cts, ct); + ca->ct[i] = ct; + ca->p[i] = p; + } else if (tvisint(o)) { + ca->ct[i] = ctype_get(cts, CTID_INT32); + ca->p[i] = (uint8_t *)&o->i; + } else if (tvisnum(o)) { + ca->ct[i] = ctype_get(cts, CTID_DOUBLE); + ca->p[i] = (uint8_t *)&o->n; + } else if (tvisnil(o)) { + ca->ct[i] = ctype_get(cts, CTID_P_VOID); + ca->p[i] = (uint8_t *)0; + } else if (tvisstr(o)) { + TValue *o2 = i == 0 ? o+1 : o-1; + CType *ct = ctype_raw(cts, cdataV(o2)->ctypeid); + ca->ct[i] = NULL; + ca->p[i] = (uint8_t *)strVdata(o); + ok = 0; + if (ctype_isenum(ct->info)) { + CTSize ofs; + CType *cct = lj_ctype_getfield(cts, ct, strV(o), &ofs); + if (cct && ctype_isconstval(cct->info)) { + ca->ct[i] = ctype_child(cts, cct); + ca->p[i] = (uint8_t *)&cct->size; /* Assumes ct does not grow. */ + ok = 1; + } else { + ca->ct[1-i] = ct; /* Use enum to improve error message. */ + ca->p[1-i] = NULL; + break; + } + } + } else { + ca->ct[i] = NULL; + ca->p[i] = (void *)(intptr_t)1; /* To make it unequal. */ + ok = 0; + } + } + return ok; +} + +/* Pointer arithmetic. */ +static int carith_ptr(lua_State *L, CTState *cts, CDArith *ca, MMS mm) +{ + CType *ctp = ca->ct[0]; + uint8_t *pp = ca->p[0]; + ptrdiff_t idx; + CTSize sz; + CTypeID id; + GCcdata *cd; + if (ctype_isptr(ctp->info) || ctype_isrefarray(ctp->info)) { + if ((mm == MM_sub || mm == MM_eq || mm == MM_lt || mm == MM_le) && + (ctype_isptr(ca->ct[1]->info) || ctype_isrefarray(ca->ct[1]->info))) { + uint8_t *pp2 = ca->p[1]; + if (mm == MM_eq) { /* Pointer equality. Incompatible pointers are ok. */ + setboolV(L->top-1, (pp == pp2)); + return 1; + } + if (!lj_cconv_compatptr(cts, ctp, ca->ct[1], CCF_IGNQUAL)) + return 0; + if (mm == MM_sub) { /* Pointer difference. */ + intptr_t diff; + sz = lj_ctype_size(cts, ctype_cid(ctp->info)); /* Element size. */ + if (sz == 0 || sz == CTSIZE_INVALID) + return 0; + diff = ((intptr_t)pp - (intptr_t)pp2) / (int32_t)sz; + /* All valid pointer differences on x64 are in (-2^47, +2^47), + ** which fits into a double without loss of precision. + */ + setintptrV(L->top-1, (int32_t)diff); + return 1; + } else if (mm == MM_lt) { /* Pointer comparison (unsigned). */ + setboolV(L->top-1, ((uintptr_t)pp < (uintptr_t)pp2)); + return 1; + } else { + lj_assertL(mm == MM_le, "bad metamethod %d", mm); + setboolV(L->top-1, ((uintptr_t)pp <= (uintptr_t)pp2)); + return 1; + } + } + if (!((mm == MM_add || mm == MM_sub) && ctype_isnum(ca->ct[1]->info))) + return 0; + lj_cconv_ct_ct(cts, ctype_get(cts, CTID_INT_PSZ), ca->ct[1], + (uint8_t *)&idx, ca->p[1], 0); + if (mm == MM_sub) idx = -idx; + } else if (mm == MM_add && ctype_isnum(ctp->info) && + (ctype_isptr(ca->ct[1]->info) || ctype_isrefarray(ca->ct[1]->info))) { + /* Swap pointer and index. */ + ctp = ca->ct[1]; pp = ca->p[1]; + lj_cconv_ct_ct(cts, ctype_get(cts, CTID_INT_PSZ), ca->ct[0], + (uint8_t *)&idx, ca->p[0], 0); + } else { + return 0; + } + sz = lj_ctype_size(cts, ctype_cid(ctp->info)); /* Element size. */ + if (sz == CTSIZE_INVALID) + return 0; + pp += idx*(int32_t)sz; /* Compute pointer + index. */ + id = lj_ctype_intern(cts, CTINFO(CT_PTR, CTALIGN_PTR|ctype_cid(ctp->info)), + CTSIZE_PTR); + cd = lj_cdata_new(cts, id, CTSIZE_PTR); + *(uint8_t **)cdataptr(cd) = pp; + setcdataV(L, L->top-1, cd); + lj_gc_check(L); + return 1; +} + +/* 64 bit integer arithmetic. */ +static int carith_int64(lua_State *L, CTState *cts, CDArith *ca, MMS mm) +{ + if (ctype_isnum(ca->ct[0]->info) && ca->ct[0]->size <= 8 && + ctype_isnum(ca->ct[1]->info) && ca->ct[1]->size <= 8) { + CTypeID id = (((ca->ct[0]->info & CTF_UNSIGNED) && ca->ct[0]->size == 8) || + ((ca->ct[1]->info & CTF_UNSIGNED) && ca->ct[1]->size == 8)) ? + CTID_UINT64 : CTID_INT64; + CType *ct = ctype_get(cts, id); + GCcdata *cd; + uint64_t u0, u1, *up; + lj_cconv_ct_ct(cts, ct, ca->ct[0], (uint8_t *)&u0, ca->p[0], 0); + if (mm != MM_unm) + lj_cconv_ct_ct(cts, ct, ca->ct[1], (uint8_t *)&u1, ca->p[1], 0); + switch (mm) { + case MM_eq: + setboolV(L->top-1, (u0 == u1)); + return 1; + case MM_lt: + setboolV(L->top-1, + id == CTID_INT64 ? ((int64_t)u0 < (int64_t)u1) : (u0 < u1)); + return 1; + case MM_le: + setboolV(L->top-1, + id == CTID_INT64 ? ((int64_t)u0 <= (int64_t)u1) : (u0 <= u1)); + return 1; + default: break; + } + cd = lj_cdata_new(cts, id, 8); + up = (uint64_t *)cdataptr(cd); + setcdataV(L, L->top-1, cd); + switch (mm) { + case MM_add: *up = u0 + u1; break; + case MM_sub: *up = u0 - u1; break; + case MM_mul: *up = u0 * u1; break; + case MM_div: + if (id == CTID_INT64) + *up = (uint64_t)lj_carith_divi64((int64_t)u0, (int64_t)u1); + else + *up = lj_carith_divu64(u0, u1); + break; + case MM_mod: + if (id == CTID_INT64) + *up = (uint64_t)lj_carith_modi64((int64_t)u0, (int64_t)u1); + else + *up = lj_carith_modu64(u0, u1); + break; + case MM_pow: + if (id == CTID_INT64) + *up = (uint64_t)lj_carith_powi64((int64_t)u0, (int64_t)u1); + else + *up = lj_carith_powu64(u0, u1); + break; + case MM_unm: *up = (uint64_t)-(int64_t)u0; break; + default: + lj_assertL(0, "bad metamethod %d", mm); + break; + } + lj_gc_check(L); + return 1; + } + return 0; +} + +/* Handle ctype arithmetic metamethods. */ +static int lj_carith_meta(lua_State *L, CTState *cts, CDArith *ca, MMS mm) +{ + cTValue *tv = NULL; + if (tviscdata(L->base)) { + CTypeID id = cdataV(L->base)->ctypeid; + CType *ct = ctype_raw(cts, id); + if (ctype_isptr(ct->info)) id = ctype_cid(ct->info); + tv = lj_ctype_meta(cts, id, mm); + } + if (!tv && L->base+1 < L->top && tviscdata(L->base+1)) { + CTypeID id = cdataV(L->base+1)->ctypeid; + CType *ct = ctype_raw(cts, id); + if (ctype_isptr(ct->info)) id = ctype_cid(ct->info); + tv = lj_ctype_meta(cts, id, mm); + } + if (!tv) { + const char *repr[2]; + int i, isenum = -1, isstr = -1; + if (mm == MM_eq) { /* Equality checks never raise an error. */ + int eq = ca->p[0] == ca->p[1]; + setboolV(L->top-1, eq); + setboolV(&G(L)->tmptv2, eq); /* Remember for trace recorder. */ + return 1; + } + for (i = 0; i < 2; i++) { + if (ca->ct[i] && tviscdata(L->base+i)) { + if (ctype_isenum(ca->ct[i]->info)) isenum = i; + repr[i] = strdata(lj_ctype_repr(L, ctype_typeid(cts, ca->ct[i]), NULL)); + } else { + if (tvisstr(&L->base[i])) isstr = i; + repr[i] = lj_typename(&L->base[i]); + } + } + if ((isenum ^ isstr) == 1) + lj_err_callerv(L, LJ_ERR_FFI_BADCONV, repr[isstr], repr[isenum]); + lj_err_callerv(L, mm == MM_len ? LJ_ERR_FFI_BADLEN : + mm == MM_concat ? LJ_ERR_FFI_BADCONCAT : + mm < MM_add ? LJ_ERR_FFI_BADCOMP : LJ_ERR_FFI_BADARITH, + repr[0], repr[1]); + } + return lj_meta_tailcall(L, tv); +} + +/* Arithmetic operators for cdata. */ +int lj_carith_op(lua_State *L, MMS mm) +{ + CTState *cts = ctype_cts(L); + CDArith ca; + if (carith_checkarg(L, cts, &ca) && mm != MM_len && mm != MM_concat) { + if (carith_int64(L, cts, &ca, mm) || carith_ptr(L, cts, &ca, mm)) { + copyTV(L, &G(L)->tmptv2, L->top-1); /* Remember for trace recorder. */ + return 1; + } + } + return lj_carith_meta(L, cts, &ca, mm); +} + +/* -- 64 bit bit operations helpers --------------------------------------- */ + +#if LJ_64 +#define B64DEF(name) \ + static LJ_AINLINE uint64_t lj_carith_##name(uint64_t x, int32_t sh) +#else +/* Not inlined on 32 bit archs, since some of these are quite lengthy. */ +#define B64DEF(name) \ + uint64_t LJ_NOINLINE lj_carith_##name(uint64_t x, int32_t sh) +#endif + +B64DEF(shl64) { return x << (sh&63); } +B64DEF(shr64) { return x >> (sh&63); } +B64DEF(sar64) { return (uint64_t)((int64_t)x >> (sh&63)); } +B64DEF(rol64) { return lj_rol(x, (sh&63)); } +B64DEF(ror64) { return lj_ror(x, (sh&63)); } + +#undef B64DEF + +uint64_t lj_carith_shift64(uint64_t x, int32_t sh, int op) +{ + switch (op) { + case IR_BSHL-IR_BSHL: x = lj_carith_shl64(x, sh); break; + case IR_BSHR-IR_BSHL: x = lj_carith_shr64(x, sh); break; + case IR_BSAR-IR_BSHL: x = lj_carith_sar64(x, sh); break; + case IR_BROL-IR_BSHL: x = lj_carith_rol64(x, sh); break; + case IR_BROR-IR_BSHL: x = lj_carith_ror64(x, sh); break; + default: + lj_assertX(0, "bad shift op %d", op); + break; + } + return x; +} + +/* Equivalent to lj_lib_checkbit(), but handles cdata. */ +uint64_t lj_carith_check64(lua_State *L, int narg, CTypeID *id) +{ + TValue *o = L->base + narg-1; + if (o >= L->top) { + err: + lj_err_argt(L, narg, LUA_TNUMBER); + } else if (LJ_LIKELY(tvisnumber(o))) { + /* Handled below. */ + } else if (tviscdata(o)) { + CTState *cts = ctype_cts(L); + uint8_t *sp = (uint8_t *)cdataptr(cdataV(o)); + CTypeID sid = cdataV(o)->ctypeid; + CType *s = ctype_get(cts, sid); + uint64_t x; + if (ctype_isref(s->info)) { + sp = *(void **)sp; + sid = ctype_cid(s->info); + } + s = ctype_raw(cts, sid); + if (ctype_isenum(s->info)) s = ctype_child(cts, s); + if ((s->info & (CTMASK_NUM|CTF_BOOL|CTF_FP|CTF_UNSIGNED)) == + CTINFO(CT_NUM, CTF_UNSIGNED) && s->size == 8) + *id = CTID_UINT64; /* Use uint64_t, since it has the highest rank. */ + else if (!*id) + *id = CTID_INT64; /* Use int64_t, unless already set. */ + lj_cconv_ct_ct(cts, ctype_get(cts, *id), s, + (uint8_t *)&x, sp, CCF_ARG(narg)); + return x; + } else if (!(tvisstr(o) && lj_strscan_number(strV(o), o))) { + goto err; + } + if (LJ_LIKELY(tvisint(o))) { + return (uint32_t)intV(o); + } else { + int32_t i = lj_num2bit(numV(o)); + if (LJ_DUALNUM) setintV(o, i); + return (uint32_t)i; + } +} + +/* -- 64 bit integer arithmetic helpers ----------------------------------- */ + +#if LJ_32 && LJ_HASJIT +/* Signed/unsigned 64 bit multiplication. */ +int64_t lj_carith_mul64(int64_t a, int64_t b) +{ + return a * b; +} +#endif + +/* Unsigned 64 bit division. */ +uint64_t lj_carith_divu64(uint64_t a, uint64_t b) +{ + if (b == 0) return U64x(80000000,00000000); + return a / b; +} + +/* Signed 64 bit division. */ +int64_t lj_carith_divi64(int64_t a, int64_t b) +{ + if (b == 0 || (a == (int64_t)U64x(80000000,00000000) && b == -1)) + return U64x(80000000,00000000); + return a / b; +} + +/* Unsigned 64 bit modulo. */ +uint64_t lj_carith_modu64(uint64_t a, uint64_t b) +{ + if (b == 0) return U64x(80000000,00000000); + return a % b; +} + +/* Signed 64 bit modulo. */ +int64_t lj_carith_modi64(int64_t a, int64_t b) +{ + if (b == 0) return U64x(80000000,00000000); + if (a == (int64_t)U64x(80000000,00000000) && b == -1) return 0; + return a % b; +} + +/* Unsigned 64 bit x^k. */ +uint64_t lj_carith_powu64(uint64_t x, uint64_t k) +{ + uint64_t y; + if (k == 0) + return 1; + for (; (k & 1) == 0; k >>= 1) x *= x; + y = x; + if ((k >>= 1) != 0) { + for (;;) { + x *= x; + if (k == 1) break; + if (k & 1) y *= x; + k >>= 1; + } + y *= x; + } + return y; +} + +/* Signed 64 bit x^k. */ +int64_t lj_carith_powi64(int64_t x, int64_t k) +{ + if (k == 0) + return 1; + if (k < 0) { + if (x == 0) + return U64x(7fffffff,ffffffff); + else if (x == 1) + return 1; + else if (x == -1) + return (k & 1) ? -1 : 1; + else + return 0; + } + return (int64_t)lj_carith_powu64((uint64_t)x, (uint64_t)k); +} + +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_carith.h b/fluent-bit/lib/luajit-3065c9/src/lj_carith.h new file mode 100644 index 00000000..9d6b1dc9 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_carith.h @@ -0,0 +1,37 @@ +/* +** C data arithmetic. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#ifndef _LJ_CARITH_H +#define _LJ_CARITH_H + +#include "lj_obj.h" + +#if LJ_HASFFI + +LJ_FUNC int lj_carith_op(lua_State *L, MMS mm); + +#if LJ_32 +LJ_FUNC uint64_t lj_carith_shl64(uint64_t x, int32_t sh); +LJ_FUNC uint64_t lj_carith_shr64(uint64_t x, int32_t sh); +LJ_FUNC uint64_t lj_carith_sar64(uint64_t x, int32_t sh); +LJ_FUNC uint64_t lj_carith_rol64(uint64_t x, int32_t sh); +LJ_FUNC uint64_t lj_carith_ror64(uint64_t x, int32_t sh); +#endif +LJ_FUNC uint64_t lj_carith_shift64(uint64_t x, int32_t sh, int op); +LJ_FUNC uint64_t lj_carith_check64(lua_State *L, int narg, CTypeID *id); + +#if LJ_32 && LJ_HASJIT +LJ_FUNC int64_t lj_carith_mul64(int64_t x, int64_t k); +#endif +LJ_FUNC uint64_t lj_carith_divu64(uint64_t a, uint64_t b); +LJ_FUNC int64_t lj_carith_divi64(int64_t a, int64_t b); +LJ_FUNC uint64_t lj_carith_modu64(uint64_t a, uint64_t b); +LJ_FUNC int64_t lj_carith_modi64(int64_t a, int64_t b); +LJ_FUNC uint64_t lj_carith_powu64(uint64_t x, uint64_t k); +LJ_FUNC int64_t lj_carith_powi64(int64_t x, int64_t k); + +#endif + +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_ccall.c b/fluent-bit/lib/luajit-3065c9/src/lj_ccall.c new file mode 100644 index 00000000..25f54dee --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_ccall.c @@ -0,0 +1,1189 @@ +/* +** FFI C call handling. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#include "lj_obj.h" + +#if LJ_HASFFI + +#include "lj_gc.h" +#include "lj_err.h" +#include "lj_tab.h" +#include "lj_ctype.h" +#include "lj_cconv.h" +#include "lj_cdata.h" +#include "lj_ccall.h" +#include "lj_trace.h" + +/* Target-specific handling of register arguments. */ +#if LJ_TARGET_X86 +/* -- x86 calling conventions --------------------------------------------- */ + +#if LJ_ABI_WIN + +#define CCALL_HANDLE_STRUCTRET \ + /* Return structs bigger than 8 by reference (on stack only). */ \ + cc->retref = (sz > 8); \ + if (cc->retref) cc->stack[nsp++] = (GPRArg)dp; + +#define CCALL_HANDLE_COMPLEXRET CCALL_HANDLE_STRUCTRET + +#else + +#if LJ_TARGET_OSX + +#define CCALL_HANDLE_STRUCTRET \ + /* Return structs of size 1, 2, 4 or 8 in registers. */ \ + cc->retref = !(sz == 1 || sz == 2 || sz == 4 || sz == 8); \ + if (cc->retref) { \ + if (ngpr < maxgpr) \ + cc->gpr[ngpr++] = (GPRArg)dp; \ + else \ + cc->stack[nsp++] = (GPRArg)dp; \ + } else { /* Struct with single FP field ends up in FPR. */ \ + cc->resx87 = ccall_classify_struct(cts, ctr); \ + } + +#define CCALL_HANDLE_STRUCTRET2 \ + if (cc->resx87) sp = (uint8_t *)&cc->fpr[0]; \ + memcpy(dp, sp, ctr->size); + +#else + +#define CCALL_HANDLE_STRUCTRET \ + cc->retref = 1; /* Return all structs by reference (in reg or on stack). */ \ + if (ngpr < maxgpr) \ + cc->gpr[ngpr++] = (GPRArg)dp; \ + else \ + cc->stack[nsp++] = (GPRArg)dp; + +#endif + +#define CCALL_HANDLE_COMPLEXRET \ + /* Return complex float in GPRs and complex double by reference. */ \ + cc->retref = (sz > 8); \ + if (cc->retref) { \ + if (ngpr < maxgpr) \ + cc->gpr[ngpr++] = (GPRArg)dp; \ + else \ + cc->stack[nsp++] = (GPRArg)dp; \ + } + +#endif + +#define CCALL_HANDLE_COMPLEXRET2 \ + if (!cc->retref) \ + *(int64_t *)dp = *(int64_t *)sp; /* Copy complex float from GPRs. */ + +#define CCALL_HANDLE_STRUCTARG \ + ngpr = maxgpr; /* Pass all structs by value on the stack. */ + +#define CCALL_HANDLE_COMPLEXARG \ + isfp = 1; /* Pass complex by value on stack. */ + +#define CCALL_HANDLE_REGARG \ + if (!isfp) { /* Only non-FP values may be passed in registers. */ \ + if (n > 1) { /* Anything > 32 bit is passed on the stack. */ \ + if (!LJ_ABI_WIN) ngpr = maxgpr; /* Prevent reordering. */ \ + } else if (ngpr + 1 <= maxgpr) { \ + dp = &cc->gpr[ngpr]; \ + ngpr += n; \ + goto done; \ + } \ + } + +#elif LJ_TARGET_X64 && LJ_ABI_WIN +/* -- Windows/x64 calling conventions ------------------------------------- */ + +#define CCALL_HANDLE_STRUCTRET \ + /* Return structs of size 1, 2, 4 or 8 in a GPR. */ \ + cc->retref = !(sz == 1 || sz == 2 || sz == 4 || sz == 8); \ + if (cc->retref) cc->gpr[ngpr++] = (GPRArg)dp; + +#define CCALL_HANDLE_COMPLEXRET CCALL_HANDLE_STRUCTRET + +#define CCALL_HANDLE_COMPLEXRET2 \ + if (!cc->retref) \ + *(int64_t *)dp = *(int64_t *)sp; /* Copy complex float from GPRs. */ + +#define CCALL_HANDLE_STRUCTARG \ + /* Pass structs of size 1, 2, 4 or 8 in a GPR by value. */ \ + if (!(sz == 1 || sz == 2 || sz == 4 || sz == 8)) { \ + rp = cdataptr(lj_cdata_new(cts, did, sz)); \ + sz = CTSIZE_PTR; /* Pass all other structs by reference. */ \ + } + +#define CCALL_HANDLE_COMPLEXARG \ + /* Pass complex float in a GPR and complex double by reference. */ \ + if (sz != 2*sizeof(float)) { \ + rp = cdataptr(lj_cdata_new(cts, did, sz)); \ + sz = CTSIZE_PTR; \ + } + +/* Windows/x64 argument registers are strictly positional (use ngpr). */ +#define CCALL_HANDLE_REGARG \ + if (isfp) { \ + if (ngpr < maxgpr) { dp = &cc->fpr[ngpr++]; nfpr = ngpr; goto done; } \ + } else { \ + if (ngpr < maxgpr) { dp = &cc->gpr[ngpr++]; goto done; } \ + } + +#elif LJ_TARGET_X64 +/* -- POSIX/x64 calling conventions --------------------------------------- */ + +#define CCALL_HANDLE_STRUCTRET \ + int rcl[2]; rcl[0] = rcl[1] = 0; \ + if (ccall_classify_struct(cts, ctr, rcl, 0)) { \ + cc->retref = 1; /* Return struct by reference. */ \ + cc->gpr[ngpr++] = (GPRArg)dp; \ + } else { \ + cc->retref = 0; /* Return small structs in registers. */ \ + } + +#define CCALL_HANDLE_STRUCTRET2 \ + int rcl[2]; rcl[0] = rcl[1] = 0; \ + ccall_classify_struct(cts, ctr, rcl, 0); \ + ccall_struct_ret(cc, rcl, dp, ctr->size); + +#define CCALL_HANDLE_COMPLEXRET \ + /* Complex values are returned in one or two FPRs. */ \ + cc->retref = 0; + +#define CCALL_HANDLE_COMPLEXRET2 \ + if (ctr->size == 2*sizeof(float)) { /* Copy complex float from FPR. */ \ + *(int64_t *)dp = cc->fpr[0].l[0]; \ + } else { /* Copy non-contiguous complex double from FPRs. */ \ + ((int64_t *)dp)[0] = cc->fpr[0].l[0]; \ + ((int64_t *)dp)[1] = cc->fpr[1].l[0]; \ + } + +#define CCALL_HANDLE_STRUCTARG \ + int rcl[2]; rcl[0] = rcl[1] = 0; \ + if (!ccall_classify_struct(cts, d, rcl, 0)) { \ + cc->nsp = nsp; cc->ngpr = ngpr; cc->nfpr = nfpr; \ + if (ccall_struct_arg(cc, cts, d, rcl, o, narg)) goto err_nyi; \ + nsp = cc->nsp; ngpr = cc->ngpr; nfpr = cc->nfpr; \ + continue; \ + } /* Pass all other structs by value on stack. */ + +#define CCALL_HANDLE_COMPLEXARG \ + isfp = 2; /* Pass complex in FPRs or on stack. Needs postprocessing. */ + +#define CCALL_HANDLE_REGARG \ + if (isfp) { /* Try to pass argument in FPRs. */ \ + int n2 = ctype_isvector(d->info) ? 1 : n; \ + if (nfpr + n2 <= CCALL_NARG_FPR) { \ + dp = &cc->fpr[nfpr]; \ + nfpr += n2; \ + goto done; \ + } \ + } else { /* Try to pass argument in GPRs. */ \ + /* Note that reordering is explicitly allowed in the x64 ABI. */ \ + if (n <= 2 && ngpr + n <= maxgpr) { \ + dp = &cc->gpr[ngpr]; \ + ngpr += n; \ + goto done; \ + } \ + } + +#elif LJ_TARGET_ARM +/* -- ARM calling conventions --------------------------------------------- */ + +#if LJ_ABI_SOFTFP + +#define CCALL_HANDLE_STRUCTRET \ + /* Return structs of size <= 4 in a GPR. */ \ + cc->retref = !(sz <= 4); \ + if (cc->retref) cc->gpr[ngpr++] = (GPRArg)dp; + +#define CCALL_HANDLE_COMPLEXRET \ + cc->retref = 1; /* Return all complex values by reference. */ \ + cc->gpr[ngpr++] = (GPRArg)dp; + +#define CCALL_HANDLE_COMPLEXRET2 \ + UNUSED(dp); /* Nothing to do. */ + +#define CCALL_HANDLE_STRUCTARG \ + /* Pass all structs by value in registers and/or on the stack. */ + +#define CCALL_HANDLE_COMPLEXARG \ + /* Pass complex by value in 2 or 4 GPRs. */ + +#define CCALL_HANDLE_REGARG_FP1 +#define CCALL_HANDLE_REGARG_FP2 + +#else + +#define CCALL_HANDLE_STRUCTRET \ + cc->retref = !ccall_classify_struct(cts, ctr, ct); \ + if (cc->retref) cc->gpr[ngpr++] = (GPRArg)dp; + +#define CCALL_HANDLE_STRUCTRET2 \ + if (ccall_classify_struct(cts, ctr, ct) > 1) sp = (uint8_t *)&cc->fpr[0]; \ + memcpy(dp, sp, ctr->size); + +#define CCALL_HANDLE_COMPLEXRET \ + if (!(ct->info & CTF_VARARG)) cc->retref = 0; /* Return complex in FPRs. */ + +#define CCALL_HANDLE_COMPLEXRET2 \ + if (!(ct->info & CTF_VARARG)) memcpy(dp, &cc->fpr[0], ctr->size); + +#define CCALL_HANDLE_STRUCTARG \ + isfp = (ccall_classify_struct(cts, d, ct) > 1); + /* Pass all structs by value in registers and/or on the stack. */ + +#define CCALL_HANDLE_COMPLEXARG \ + isfp = 1; /* Pass complex by value in FPRs or on stack. */ + +#define CCALL_HANDLE_REGARG_FP1 \ + if (isfp && !(ct->info & CTF_VARARG)) { \ + if ((d->info & CTF_ALIGN) > CTALIGN_PTR) { \ + if (nfpr + (n >> 1) <= CCALL_NARG_FPR) { \ + dp = &cc->fpr[nfpr]; \ + nfpr += (n >> 1); \ + goto done; \ + } \ + } else { \ + if (sz > 1 && fprodd != nfpr) fprodd = 0; \ + if (fprodd) { \ + if (2*nfpr+n <= 2*CCALL_NARG_FPR+1) { \ + dp = (void *)&cc->fpr[fprodd-1].f[1]; \ + nfpr += (n >> 1); \ + if ((n & 1)) fprodd = 0; else fprodd = nfpr-1; \ + goto done; \ + } \ + } else { \ + if (2*nfpr+n <= 2*CCALL_NARG_FPR) { \ + dp = (void *)&cc->fpr[nfpr]; \ + nfpr += (n >> 1); \ + if ((n & 1)) fprodd = ++nfpr; else fprodd = 0; \ + goto done; \ + } \ + } \ + } \ + fprodd = 0; /* No reordering after the first FP value is on stack. */ \ + } else { + +#define CCALL_HANDLE_REGARG_FP2 } + +#endif + +#define CCALL_HANDLE_REGARG \ + CCALL_HANDLE_REGARG_FP1 \ + if ((d->info & CTF_ALIGN) > CTALIGN_PTR) { \ + if (ngpr < maxgpr) \ + ngpr = (ngpr + 1u) & ~1u; /* Align to regpair. */ \ + } \ + if (ngpr < maxgpr) { \ + dp = &cc->gpr[ngpr]; \ + if (ngpr + n > maxgpr) { \ + nsp += ngpr + n - maxgpr; /* Assumes contiguous gpr/stack fields. */ \ + if (nsp > CCALL_MAXSTACK) goto err_nyi; /* Too many arguments. */ \ + ngpr = maxgpr; \ + } else { \ + ngpr += n; \ + } \ + goto done; \ + } CCALL_HANDLE_REGARG_FP2 + +#define CCALL_HANDLE_RET \ + if ((ct->info & CTF_VARARG)) sp = (uint8_t *)&cc->gpr[0]; + +#elif LJ_TARGET_ARM64 +/* -- ARM64 calling conventions ------------------------------------------- */ + +#define CCALL_HANDLE_STRUCTRET \ + cc->retref = !ccall_classify_struct(cts, ctr); \ + if (cc->retref) cc->retp = dp; + +#define CCALL_HANDLE_STRUCTRET2 \ + unsigned int cl = ccall_classify_struct(cts, ctr); \ + if ((cl & 4)) { /* Combine float HFA from separate registers. */ \ + CTSize i = (cl >> 8) - 1; \ + do { ((uint32_t *)dp)[i] = cc->fpr[i].lo; } while (i--); \ + } else { \ + if (cl > 1) sp = (uint8_t *)&cc->fpr[0]; \ + memcpy(dp, sp, ctr->size); \ + } + +#define CCALL_HANDLE_COMPLEXRET \ + /* Complex values are returned in one or two FPRs. */ \ + cc->retref = 0; + +#define CCALL_HANDLE_COMPLEXRET2 \ + if (ctr->size == 2*sizeof(float)) { /* Copy complex float from FPRs. */ \ + ((float *)dp)[0] = cc->fpr[0].f; \ + ((float *)dp)[1] = cc->fpr[1].f; \ + } else { /* Copy complex double from FPRs. */ \ + ((double *)dp)[0] = cc->fpr[0].d; \ + ((double *)dp)[1] = cc->fpr[1].d; \ + } + +#define CCALL_HANDLE_STRUCTARG \ + unsigned int cl = ccall_classify_struct(cts, d); \ + if (cl == 0) { /* Pass struct by reference. */ \ + rp = cdataptr(lj_cdata_new(cts, did, sz)); \ + sz = CTSIZE_PTR; \ + } else if (cl > 1) { /* Pass struct in FPRs or on stack. */ \ + isfp = (cl & 4) ? 2 : 1; \ + } /* else: Pass struct in GPRs or on stack. */ + +#define CCALL_HANDLE_COMPLEXARG \ + /* Pass complex by value in separate (!) FPRs or on stack. */ \ + isfp = sz == 2*sizeof(float) ? 2 : 1; + +#define CCALL_HANDLE_REGARG \ + if (LJ_TARGET_OSX && isva) { \ + /* IOS: All variadic arguments are on the stack. */ \ + } else if (isfp) { /* Try to pass argument in FPRs. */ \ + int n2 = ctype_isvector(d->info) ? 1 : \ + isfp == 1 ? n : (d->size >> (4-isfp)); \ + if (nfpr + n2 <= CCALL_NARG_FPR) { \ + dp = &cc->fpr[nfpr]; \ + nfpr += n2; \ + goto done; \ + } else { \ + nfpr = CCALL_NARG_FPR; /* Prevent reordering. */ \ + if (LJ_TARGET_OSX && d->size < 8) goto err_nyi; \ + } \ + } else { /* Try to pass argument in GPRs. */ \ + if (!LJ_TARGET_OSX && (d->info & CTF_ALIGN) > CTALIGN_PTR) \ + ngpr = (ngpr + 1u) & ~1u; /* Align to regpair. */ \ + if (ngpr + n <= maxgpr) { \ + dp = &cc->gpr[ngpr]; \ + ngpr += n; \ + goto done; \ + } else { \ + ngpr = maxgpr; /* Prevent reordering. */ \ + if (LJ_TARGET_OSX && d->size < 8) goto err_nyi; \ + } \ + } + +#if LJ_BE +#define CCALL_HANDLE_RET \ + if (ctype_isfp(ctr->info) && ctr->size == sizeof(float)) \ + sp = (uint8_t *)&cc->fpr[0].f; +#endif + + +#elif LJ_TARGET_PPC +/* -- PPC calling conventions --------------------------------------------- */ + +#define CCALL_HANDLE_STRUCTRET \ + cc->retref = 1; /* Return all structs by reference. */ \ + cc->gpr[ngpr++] = (GPRArg)dp; + +#define CCALL_HANDLE_COMPLEXRET \ + /* Complex values are returned in 2 or 4 GPRs. */ \ + cc->retref = 0; + +#define CCALL_HANDLE_COMPLEXRET2 \ + memcpy(dp, sp, ctr->size); /* Copy complex from GPRs. */ + +#define CCALL_HANDLE_STRUCTARG \ + rp = cdataptr(lj_cdata_new(cts, did, sz)); \ + sz = CTSIZE_PTR; /* Pass all structs by reference. */ + +#define CCALL_HANDLE_COMPLEXARG \ + /* Pass complex by value in 2 or 4 GPRs. */ + +#define CCALL_HANDLE_GPR \ + /* Try to pass argument in GPRs. */ \ + if (n > 1) { \ + /* int64_t or complex (float). */ \ + lj_assertL(n == 2 || n == 4, "bad GPR size %d", n); \ + if (ctype_isinteger(d->info) || ctype_isfp(d->info)) \ + ngpr = (ngpr + 1u) & ~1u; /* Align int64_t to regpair. */ \ + else if (ngpr + n > maxgpr) \ + ngpr = maxgpr; /* Prevent reordering. */ \ + } \ + if (ngpr + n <= maxgpr) { \ + dp = &cc->gpr[ngpr]; \ + ngpr += n; \ + goto done; \ + } \ + +#if LJ_ABI_SOFTFP +#define CCALL_HANDLE_REGARG CCALL_HANDLE_GPR +#else +#define CCALL_HANDLE_REGARG \ + if (isfp) { /* Try to pass argument in FPRs. */ \ + if (nfpr + 1 <= CCALL_NARG_FPR) { \ + dp = &cc->fpr[nfpr]; \ + nfpr += 1; \ + d = ctype_get(cts, CTID_DOUBLE); /* FPRs always hold doubles. */ \ + goto done; \ + } \ + } else { \ + CCALL_HANDLE_GPR \ + } +#endif + +#if !LJ_ABI_SOFTFP +#define CCALL_HANDLE_RET \ + if (ctype_isfp(ctr->info) && ctr->size == sizeof(float)) \ + ctr = ctype_get(cts, CTID_DOUBLE); /* FPRs always hold doubles. */ +#endif + +#elif LJ_TARGET_MIPS32 +/* -- MIPS o32 calling conventions ---------------------------------------- */ + +#define CCALL_HANDLE_STRUCTRET \ + cc->retref = 1; /* Return all structs by reference. */ \ + cc->gpr[ngpr++] = (GPRArg)dp; + +#define CCALL_HANDLE_COMPLEXRET \ + /* Complex values are returned in 1 or 2 FPRs. */ \ + cc->retref = 0; + +#if LJ_ABI_SOFTFP +#define CCALL_HANDLE_COMPLEXRET2 \ + if (ctr->size == 2*sizeof(float)) { /* Copy complex float from GPRs. */ \ + ((intptr_t *)dp)[0] = cc->gpr[0]; \ + ((intptr_t *)dp)[1] = cc->gpr[1]; \ + } else { /* Copy complex double from GPRs. */ \ + ((intptr_t *)dp)[0] = cc->gpr[0]; \ + ((intptr_t *)dp)[1] = cc->gpr[1]; \ + ((intptr_t *)dp)[2] = cc->gpr[2]; \ + ((intptr_t *)dp)[3] = cc->gpr[3]; \ + } +#else +#define CCALL_HANDLE_COMPLEXRET2 \ + if (ctr->size == 2*sizeof(float)) { /* Copy complex float from FPRs. */ \ + ((float *)dp)[0] = cc->fpr[0].f; \ + ((float *)dp)[1] = cc->fpr[1].f; \ + } else { /* Copy complex double from FPRs. */ \ + ((double *)dp)[0] = cc->fpr[0].d; \ + ((double *)dp)[1] = cc->fpr[1].d; \ + } +#endif + +#define CCALL_HANDLE_STRUCTARG \ + /* Pass all structs by value in registers and/or on the stack. */ + +#define CCALL_HANDLE_COMPLEXARG \ + /* Pass complex by value in 2 or 4 GPRs. */ + +#define CCALL_HANDLE_GPR \ + if ((d->info & CTF_ALIGN) > CTALIGN_PTR) \ + ngpr = (ngpr + 1u) & ~1u; /* Align to regpair. */ \ + if (ngpr < maxgpr) { \ + dp = &cc->gpr[ngpr]; \ + if (ngpr + n > maxgpr) { \ + nsp += ngpr + n - maxgpr; /* Assumes contiguous gpr/stack fields. */ \ + if (nsp > CCALL_MAXSTACK) goto err_nyi; /* Too many arguments. */ \ + ngpr = maxgpr; \ + } else { \ + ngpr += n; \ + } \ + goto done; \ + } + +#if !LJ_ABI_SOFTFP /* MIPS32 hard-float */ +#define CCALL_HANDLE_REGARG \ + if (isfp && nfpr < CCALL_NARG_FPR && !(ct->info & CTF_VARARG)) { \ + /* Try to pass argument in FPRs. */ \ + dp = n == 1 ? (void *)&cc->fpr[nfpr].f : (void *)&cc->fpr[nfpr].d; \ + nfpr++; ngpr += n; \ + goto done; \ + } else { /* Try to pass argument in GPRs. */ \ + nfpr = CCALL_NARG_FPR; \ + CCALL_HANDLE_GPR \ + } +#else /* MIPS32 soft-float */ +#define CCALL_HANDLE_REGARG CCALL_HANDLE_GPR +#endif + +#if !LJ_ABI_SOFTFP +/* On MIPS64 soft-float, position of float return values is endian-dependant. */ +#define CCALL_HANDLE_RET \ + if (ctype_isfp(ctr->info) && ctr->size == sizeof(float)) \ + sp = (uint8_t *)&cc->fpr[0].f; +#endif + +#elif LJ_TARGET_MIPS64 +/* -- MIPS n64 calling conventions ---------------------------------------- */ + +#define CCALL_HANDLE_STRUCTRET \ + cc->retref = !(sz <= 16); \ + if (cc->retref) cc->gpr[ngpr++] = (GPRArg)dp; + +#define CCALL_HANDLE_STRUCTRET2 \ + ccall_copy_struct(cc, ctr, dp, sp, ccall_classify_struct(cts, ctr, ct)); + +#define CCALL_HANDLE_COMPLEXRET \ + /* Complex values are returned in 1 or 2 FPRs. */ \ + cc->retref = 0; + +#if LJ_ABI_SOFTFP /* MIPS64 soft-float */ + +#define CCALL_HANDLE_COMPLEXRET2 \ + if (ctr->size == 2*sizeof(float)) { /* Copy complex float from GPRs. */ \ + ((intptr_t *)dp)[0] = cc->gpr[0]; \ + } else { /* Copy complex double from GPRs. */ \ + ((intptr_t *)dp)[0] = cc->gpr[0]; \ + ((intptr_t *)dp)[1] = cc->gpr[1]; \ + } + +#define CCALL_HANDLE_COMPLEXARG \ + /* Pass complex by value in 2 or 4 GPRs. */ + +/* Position of soft-float 'float' return value depends on endianess. */ +#define CCALL_HANDLE_RET \ + if (ctype_isfp(ctr->info) && ctr->size == sizeof(float)) \ + sp = (uint8_t *)cc->gpr + LJ_ENDIAN_SELECT(0, 4); + +#else /* MIPS64 hard-float */ + +#define CCALL_HANDLE_COMPLEXRET2 \ + if (ctr->size == 2*sizeof(float)) { /* Copy complex float from FPRs. */ \ + ((float *)dp)[0] = cc->fpr[0].f; \ + ((float *)dp)[1] = cc->fpr[1].f; \ + } else { /* Copy complex double from FPRs. */ \ + ((double *)dp)[0] = cc->fpr[0].d; \ + ((double *)dp)[1] = cc->fpr[1].d; \ + } + +#define CCALL_HANDLE_COMPLEXARG \ + if (sz == 2*sizeof(float)) { \ + isfp = 2; \ + if (ngpr < maxgpr) \ + sz *= 2; \ + } + +#define CCALL_HANDLE_RET \ + if (ctype_isfp(ctr->info) && ctr->size == sizeof(float)) \ + sp = (uint8_t *)&cc->fpr[0].f; + +#endif + +#define CCALL_HANDLE_STRUCTARG \ + /* Pass all structs by value in registers and/or on the stack. */ + +#define CCALL_HANDLE_REGARG \ + if (ngpr < maxgpr) { \ + dp = &cc->gpr[ngpr]; \ + if (ngpr + n > maxgpr) { \ + nsp += ngpr + n - maxgpr; /* Assumes contiguous gpr/stack fields. */ \ + if (nsp > CCALL_MAXSTACK) goto err_nyi; /* Too many arguments. */ \ + ngpr = maxgpr; \ + } else { \ + ngpr += n; \ + } \ + goto done; \ + } + +#else +#error "Missing calling convention definitions for this architecture" +#endif + +#ifndef CCALL_HANDLE_STRUCTRET2 +#define CCALL_HANDLE_STRUCTRET2 \ + memcpy(dp, sp, ctr->size); /* Copy struct return value from GPRs. */ +#endif + +/* -- x86 OSX ABI struct classification ----------------------------------- */ + +#if LJ_TARGET_X86 && LJ_TARGET_OSX + +/* Check for struct with single FP field. */ +static int ccall_classify_struct(CTState *cts, CType *ct) +{ + CTSize sz = ct->size; + if (!(sz == sizeof(float) || sz == sizeof(double))) return 0; + if ((ct->info & CTF_UNION)) return 0; + while (ct->sib) { + ct = ctype_get(cts, ct->sib); + if (ctype_isfield(ct->info)) { + CType *sct = ctype_rawchild(cts, ct); + if (ctype_isfp(sct->info)) { + if (sct->size == sz) + return (sz >> 2); /* Return 1 for float or 2 for double. */ + } else if (ctype_isstruct(sct->info)) { + if (sct->size) + return ccall_classify_struct(cts, sct); + } else { + break; + } + } else if (ctype_isbitfield(ct->info)) { + break; + } else if (ctype_isxattrib(ct->info, CTA_SUBTYPE)) { + CType *sct = ctype_rawchild(cts, ct); + if (sct->size) + return ccall_classify_struct(cts, sct); + } + } + return 0; +} + +#endif + +/* -- x64 struct classification ------------------------------------------- */ + +#if LJ_TARGET_X64 && !LJ_ABI_WIN + +/* Register classes for x64 struct classification. */ +#define CCALL_RCL_INT 1 +#define CCALL_RCL_SSE 2 +#define CCALL_RCL_MEM 4 +/* NYI: classify vectors. */ + +static int ccall_classify_struct(CTState *cts, CType *ct, int *rcl, CTSize ofs); + +/* Classify a C type. */ +static void ccall_classify_ct(CTState *cts, CType *ct, int *rcl, CTSize ofs) +{ + if (ctype_isarray(ct->info)) { + CType *cct = ctype_rawchild(cts, ct); + CTSize eofs, esz = cct->size, asz = ct->size; + for (eofs = 0; eofs < asz; eofs += esz) + ccall_classify_ct(cts, cct, rcl, ofs+eofs); + } else if (ctype_isstruct(ct->info)) { + ccall_classify_struct(cts, ct, rcl, ofs); + } else { + int cl = ctype_isfp(ct->info) ? CCALL_RCL_SSE : CCALL_RCL_INT; + lj_assertCTS(ctype_hassize(ct->info), + "classify ctype %08x without size", ct->info); + if ((ofs & (ct->size-1))) cl = CCALL_RCL_MEM; /* Unaligned. */ + rcl[(ofs >= 8)] |= cl; + } +} + +/* Recursively classify a struct based on its fields. */ +static int ccall_classify_struct(CTState *cts, CType *ct, int *rcl, CTSize ofs) +{ + if (ct->size > 16) return CCALL_RCL_MEM; /* Too big, gets memory class. */ + while (ct->sib) { + CTSize fofs; + ct = ctype_get(cts, ct->sib); + fofs = ofs+ct->size; + if (ctype_isfield(ct->info)) + ccall_classify_ct(cts, ctype_rawchild(cts, ct), rcl, fofs); + else if (ctype_isbitfield(ct->info)) + rcl[(fofs >= 8)] |= CCALL_RCL_INT; /* NYI: unaligned bitfields? */ + else if (ctype_isxattrib(ct->info, CTA_SUBTYPE)) + ccall_classify_struct(cts, ctype_rawchild(cts, ct), rcl, fofs); + } + return ((rcl[0]|rcl[1]) & CCALL_RCL_MEM); /* Memory class? */ +} + +/* Try to split up a small struct into registers. */ +static int ccall_struct_reg(CCallState *cc, CTState *cts, GPRArg *dp, int *rcl) +{ + MSize ngpr = cc->ngpr, nfpr = cc->nfpr; + uint32_t i; + UNUSED(cts); + for (i = 0; i < 2; i++) { + lj_assertCTS(!(rcl[i] & CCALL_RCL_MEM), "pass mem struct in reg"); + if ((rcl[i] & CCALL_RCL_INT)) { /* Integer class takes precedence. */ + if (ngpr >= CCALL_NARG_GPR) return 1; /* Register overflow. */ + cc->gpr[ngpr++] = dp[i]; + } else if ((rcl[i] & CCALL_RCL_SSE)) { + if (nfpr >= CCALL_NARG_FPR) return 1; /* Register overflow. */ + cc->fpr[nfpr++].l[0] = dp[i]; + } + } + cc->ngpr = ngpr; cc->nfpr = nfpr; + return 0; /* Ok. */ +} + +/* Pass a small struct argument. */ +static int ccall_struct_arg(CCallState *cc, CTState *cts, CType *d, int *rcl, + TValue *o, int narg) +{ + GPRArg dp[2]; + dp[0] = dp[1] = 0; + /* Convert to temp. struct. */ + lj_cconv_ct_tv(cts, d, (uint8_t *)dp, o, CCF_ARG(narg)); + if (ccall_struct_reg(cc, cts, dp, rcl)) { + /* Register overflow? Pass on stack. */ + MSize nsp = cc->nsp, n = rcl[1] ? 2 : 1; + if (nsp + n > CCALL_MAXSTACK) return 1; /* Too many arguments. */ + cc->nsp = nsp + n; + memcpy(&cc->stack[nsp], dp, n*CTSIZE_PTR); + } + return 0; /* Ok. */ +} + +/* Combine returned small struct. */ +static void ccall_struct_ret(CCallState *cc, int *rcl, uint8_t *dp, CTSize sz) +{ + GPRArg sp[2]; + MSize ngpr = 0, nfpr = 0; + uint32_t i; + for (i = 0; i < 2; i++) { + if ((rcl[i] & CCALL_RCL_INT)) { /* Integer class takes precedence. */ + sp[i] = cc->gpr[ngpr++]; + } else if ((rcl[i] & CCALL_RCL_SSE)) { + sp[i] = cc->fpr[nfpr++].l[0]; + } + } + memcpy(dp, sp, sz); +} +#endif + +/* -- ARM hard-float ABI struct classification ---------------------------- */ + +#if LJ_TARGET_ARM && !LJ_ABI_SOFTFP + +/* Classify a struct based on its fields. */ +static unsigned int ccall_classify_struct(CTState *cts, CType *ct, CType *ctf) +{ + CTSize sz = ct->size; + unsigned int r = 0, n = 0, isu = (ct->info & CTF_UNION); + if ((ctf->info & CTF_VARARG)) goto noth; + while (ct->sib) { + CType *sct; + ct = ctype_get(cts, ct->sib); + if (ctype_isfield(ct->info)) { + sct = ctype_rawchild(cts, ct); + if (ctype_isfp(sct->info)) { + r |= sct->size; + if (!isu) n++; else if (n == 0) n = 1; + } else if (ctype_iscomplex(sct->info)) { + r |= (sct->size >> 1); + if (!isu) n += 2; else if (n < 2) n = 2; + } else if (ctype_isstruct(sct->info)) { + goto substruct; + } else { + goto noth; + } + } else if (ctype_isbitfield(ct->info)) { + goto noth; + } else if (ctype_isxattrib(ct->info, CTA_SUBTYPE)) { + sct = ctype_rawchild(cts, ct); + substruct: + if (sct->size > 0) { + unsigned int s = ccall_classify_struct(cts, sct, ctf); + if (s <= 1) goto noth; + r |= (s & 255); + if (!isu) n += (s >> 8); else if (n < (s >>8)) n = (s >> 8); + } + } + } + if ((r == 4 || r == 8) && n <= 4) + return r + (n << 8); +noth: /* Not a homogeneous float/double aggregate. */ + return (sz <= 4); /* Return structs of size <= 4 in a GPR. */ +} + +#endif + +/* -- ARM64 ABI struct classification ------------------------------------- */ + +#if LJ_TARGET_ARM64 + +/* Classify a struct based on its fields. */ +static unsigned int ccall_classify_struct(CTState *cts, CType *ct) +{ + CTSize sz = ct->size; + unsigned int r = 0, n = 0, isu = (ct->info & CTF_UNION); + while (ct->sib) { + CType *sct; + ct = ctype_get(cts, ct->sib); + if (ctype_isfield(ct->info)) { + sct = ctype_rawchild(cts, ct); + if (ctype_isfp(sct->info)) { + r |= sct->size; + if (!isu) n++; else if (n == 0) n = 1; + } else if (ctype_iscomplex(sct->info)) { + r |= (sct->size >> 1); + if (!isu) n += 2; else if (n < 2) n = 2; + } else if (ctype_isstruct(sct->info)) { + goto substruct; + } else { + goto noth; + } + } else if (ctype_isbitfield(ct->info)) { + goto noth; + } else if (ctype_isxattrib(ct->info, CTA_SUBTYPE)) { + sct = ctype_rawchild(cts, ct); + substruct: + if (sct->size > 0) { + unsigned int s = ccall_classify_struct(cts, sct); + if (s <= 1) goto noth; + r |= (s & 255); + if (!isu) n += (s >> 8); else if (n < (s >>8)) n = (s >> 8); + } + } + } + if ((r == 4 || r == 8) && n <= 4) + return r + (n << 8); +noth: /* Not a homogeneous float/double aggregate. */ + return (sz <= 16); /* Return structs of size <= 16 in GPRs. */ +} + +#endif + +/* -- MIPS64 ABI struct classification ---------------------------- */ + +#if LJ_TARGET_MIPS64 + +#define FTYPE_FLOAT 1 +#define FTYPE_DOUBLE 2 + +/* Classify FP fields (max. 2) and their types. */ +static unsigned int ccall_classify_struct(CTState *cts, CType *ct, CType *ctf) +{ + int n = 0, ft = 0; + if ((ctf->info & CTF_VARARG) || (ct->info & CTF_UNION)) + goto noth; + while (ct->sib) { + CType *sct; + ct = ctype_get(cts, ct->sib); + if (n == 2) { + goto noth; + } else if (ctype_isfield(ct->info)) { + sct = ctype_rawchild(cts, ct); + if (ctype_isfp(sct->info)) { + ft |= (sct->size == 4 ? FTYPE_FLOAT : FTYPE_DOUBLE) << 2*n; + n++; + } else { + goto noth; + } + } else if (ctype_isbitfield(ct->info) || + ctype_isxattrib(ct->info, CTA_SUBTYPE)) { + goto noth; + } + } + if (n <= 2) + return ft; +noth: /* Not a homogeneous float/double aggregate. */ + return 0; /* Struct is in GPRs. */ +} + +static void ccall_copy_struct(CCallState *cc, CType *ctr, void *dp, void *sp, + int ft) +{ + if (LJ_ABI_SOFTFP ? ft : + ((ft & 3) == FTYPE_FLOAT || (ft >> 2) == FTYPE_FLOAT)) { + int i, ofs = 0; + for (i = 0; ft != 0; i++, ft >>= 2) { + if ((ft & 3) == FTYPE_FLOAT) { +#if LJ_ABI_SOFTFP + /* The 2nd FP struct result is in CARG1 (gpr[2]) and not CRET2. */ + memcpy((uint8_t *)dp + ofs, + (uint8_t *)&cc->gpr[2*i] + LJ_ENDIAN_SELECT(0, 4), 4); +#else + *(float *)((uint8_t *)dp + ofs) = cc->fpr[i].f; +#endif + ofs += 4; + } else { + ofs = (ofs + 7) & ~7; /* 64 bit alignment. */ +#if LJ_ABI_SOFTFP + *(intptr_t *)((uint8_t *)dp + ofs) = cc->gpr[2*i]; +#else + *(double *)((uint8_t *)dp + ofs) = cc->fpr[i].d; +#endif + ofs += 8; + } + } + } else { +#if !LJ_ABI_SOFTFP + if (ft) sp = (uint8_t *)&cc->fpr[0]; +#endif + memcpy(dp, sp, ctr->size); + } +} + +#endif + +/* -- Common C call handling ---------------------------------------------- */ + +/* Infer the destination CTypeID for a vararg argument. */ +CTypeID lj_ccall_ctid_vararg(CTState *cts, cTValue *o) +{ + if (tvisnumber(o)) { + return CTID_DOUBLE; + } else if (tviscdata(o)) { + CTypeID id = cdataV(o)->ctypeid; + CType *s = ctype_get(cts, id); + if (ctype_isrefarray(s->info)) { + return lj_ctype_intern(cts, + CTINFO(CT_PTR, CTALIGN_PTR|ctype_cid(s->info)), CTSIZE_PTR); + } else if (ctype_isstruct(s->info) || ctype_isfunc(s->info)) { + /* NYI: how to pass a struct by value in a vararg argument? */ + return lj_ctype_intern(cts, CTINFO(CT_PTR, CTALIGN_PTR|id), CTSIZE_PTR); + } else if (ctype_isfp(s->info) && s->size == sizeof(float)) { + return CTID_DOUBLE; + } else { + return id; + } + } else if (tvisstr(o)) { + return CTID_P_CCHAR; + } else if (tvisbool(o)) { + return CTID_BOOL; + } else { + return CTID_P_VOID; + } +} + +/* Setup arguments for C call. */ +static int ccall_set_args(lua_State *L, CTState *cts, CType *ct, + CCallState *cc) +{ + int gcsteps = 0; + TValue *o, *top = L->top; + CTypeID fid; + CType *ctr; + MSize maxgpr, ngpr = 0, nsp = 0, narg; +#if CCALL_NARG_FPR + MSize nfpr = 0; +#if LJ_TARGET_ARM + MSize fprodd = 0; +#endif +#endif + + /* Clear unused regs to get some determinism in case of misdeclaration. */ + memset(cc->gpr, 0, sizeof(cc->gpr)); +#if CCALL_NUM_FPR + memset(cc->fpr, 0, sizeof(cc->fpr)); +#endif + +#if LJ_TARGET_X86 + /* x86 has several different calling conventions. */ + cc->resx87 = 0; + switch (ctype_cconv(ct->info)) { + case CTCC_FASTCALL: maxgpr = 2; break; + case CTCC_THISCALL: maxgpr = 1; break; + default: maxgpr = 0; break; + } +#else + maxgpr = CCALL_NARG_GPR; +#endif + + /* Perform required setup for some result types. */ + ctr = ctype_rawchild(cts, ct); + if (ctype_isvector(ctr->info)) { + if (!(CCALL_VECTOR_REG && (ctr->size == 8 || ctr->size == 16))) + goto err_nyi; + } else if (ctype_iscomplex(ctr->info) || ctype_isstruct(ctr->info)) { + /* Preallocate cdata object and anchor it after arguments. */ + CTSize sz = ctr->size; + GCcdata *cd = lj_cdata_new(cts, ctype_cid(ct->info), sz); + void *dp = cdataptr(cd); + setcdataV(L, L->top++, cd); + if (ctype_isstruct(ctr->info)) { + CCALL_HANDLE_STRUCTRET + } else { + CCALL_HANDLE_COMPLEXRET + } +#if LJ_TARGET_X86 + } else if (ctype_isfp(ctr->info)) { + cc->resx87 = ctr->size == sizeof(float) ? 1 : 2; +#endif + } + + /* Skip initial attributes. */ + fid = ct->sib; + while (fid) { + CType *ctf = ctype_get(cts, fid); + if (!ctype_isattrib(ctf->info)) break; + fid = ctf->sib; + } + + /* Walk through all passed arguments. */ + for (o = L->base+1, narg = 1; o < top; o++, narg++) { + CTypeID did; + CType *d; + CTSize sz; + MSize n, isfp = 0, isva = 0; + void *dp, *rp = NULL; + + if (fid) { /* Get argument type from field. */ + CType *ctf = ctype_get(cts, fid); + fid = ctf->sib; + lj_assertL(ctype_isfield(ctf->info), "field expected"); + did = ctype_cid(ctf->info); + } else { + if (!(ct->info & CTF_VARARG)) + lj_err_caller(L, LJ_ERR_FFI_NUMARG); /* Too many arguments. */ + did = lj_ccall_ctid_vararg(cts, o); /* Infer vararg type. */ + isva = 1; + } + d = ctype_raw(cts, did); + sz = d->size; + + /* Find out how (by value/ref) and where (GPR/FPR) to pass an argument. */ + if (ctype_isnum(d->info)) { + if (sz > 8) goto err_nyi; + if ((d->info & CTF_FP)) + isfp = 1; + } else if (ctype_isvector(d->info)) { + if (CCALL_VECTOR_REG && (sz == 8 || sz == 16)) + isfp = 1; + else + goto err_nyi; + } else if (ctype_isstruct(d->info)) { + CCALL_HANDLE_STRUCTARG + } else if (ctype_iscomplex(d->info)) { + CCALL_HANDLE_COMPLEXARG + } else { + sz = CTSIZE_PTR; + } + sz = (sz + CTSIZE_PTR-1) & ~(CTSIZE_PTR-1); + n = sz / CTSIZE_PTR; /* Number of GPRs or stack slots needed. */ + + CCALL_HANDLE_REGARG /* Handle register arguments. */ + + /* Otherwise pass argument on stack. */ + if (CCALL_ALIGN_STACKARG && !rp && (d->info & CTF_ALIGN) > CTALIGN_PTR) { + MSize align = (1u << ctype_align(d->info-CTALIGN_PTR)) -1; + nsp = (nsp + align) & ~align; /* Align argument on stack. */ + } + if (nsp + n > CCALL_MAXSTACK) { /* Too many arguments. */ + err_nyi: + lj_err_caller(L, LJ_ERR_FFI_NYICALL); + } + dp = &cc->stack[nsp]; + nsp += n; + isva = 0; + + done: + if (rp) { /* Pass by reference. */ + gcsteps++; + *(void **)dp = rp; + dp = rp; + } + lj_cconv_ct_tv(cts, d, (uint8_t *)dp, o, CCF_ARG(narg)); + /* Extend passed integers to 32 bits at least. */ + if (ctype_isinteger_or_bool(d->info) && d->size < 4) { + if (d->info & CTF_UNSIGNED) + *(uint32_t *)dp = d->size == 1 ? (uint32_t)*(uint8_t *)dp : + (uint32_t)*(uint16_t *)dp; + else + *(int32_t *)dp = d->size == 1 ? (int32_t)*(int8_t *)dp : + (int32_t)*(int16_t *)dp; + } +#if LJ_TARGET_ARM64 && LJ_BE + if (isfp && d->size == sizeof(float)) + ((float *)dp)[1] = ((float *)dp)[0]; /* Floats occupy high slot. */ +#endif +#if LJ_TARGET_MIPS64 || (LJ_TARGET_ARM64 && LJ_BE) + if ((ctype_isinteger_or_bool(d->info) || ctype_isenum(d->info) +#if LJ_TARGET_MIPS64 + || (isfp && nsp == 0) +#endif + ) && d->size <= 4) { + *(int64_t *)dp = (int64_t)*(int32_t *)dp; /* Sign-extend to 64 bit. */ + } +#endif +#if LJ_TARGET_X64 && LJ_ABI_WIN + if (isva) { /* Windows/x64 mirrors varargs in both register sets. */ + if (nfpr == ngpr) + cc->gpr[ngpr-1] = cc->fpr[ngpr-1].l[0]; + else + cc->fpr[ngpr-1].l[0] = cc->gpr[ngpr-1]; + } +#else + UNUSED(isva); +#endif +#if LJ_TARGET_X64 && !LJ_ABI_WIN + if (isfp == 2 && n == 2 && (uint8_t *)dp == (uint8_t *)&cc->fpr[nfpr-2]) { + cc->fpr[nfpr-1].d[0] = cc->fpr[nfpr-2].d[1]; /* Split complex double. */ + cc->fpr[nfpr-2].d[1] = 0; + } +#elif LJ_TARGET_ARM64 || (LJ_TARGET_MIPS64 && !LJ_ABI_SOFTFP) + if (isfp == 2 && (uint8_t *)dp < (uint8_t *)cc->stack) { + /* Split float HFA or complex float into separate registers. */ + CTSize i = (sz >> 2) - 1; + do { ((uint64_t *)dp)[i] = ((uint32_t *)dp)[i]; } while (i--); + } +#else + UNUSED(isfp); +#endif + } + if (fid) lj_err_caller(L, LJ_ERR_FFI_NUMARG); /* Too few arguments. */ + +#if LJ_TARGET_X64 || (LJ_TARGET_PPC && !LJ_ABI_SOFTFP) + cc->nfpr = nfpr; /* Required for vararg functions. */ +#endif + cc->nsp = nsp; + cc->spadj = (CCALL_SPS_FREE + CCALL_SPS_EXTRA)*CTSIZE_PTR; + if (nsp > CCALL_SPS_FREE) + cc->spadj += (((nsp-CCALL_SPS_FREE)*CTSIZE_PTR + 15u) & ~15u); + return gcsteps; +} + +/* Get results from C call. */ +static int ccall_get_results(lua_State *L, CTState *cts, CType *ct, + CCallState *cc, int *ret) +{ + CType *ctr = ctype_rawchild(cts, ct); + uint8_t *sp = (uint8_t *)&cc->gpr[0]; + if (ctype_isvoid(ctr->info)) { + *ret = 0; /* Zero results. */ + return 0; /* No additional GC step. */ + } + *ret = 1; /* One result. */ + if (ctype_isstruct(ctr->info)) { + /* Return cdata object which is already on top of stack. */ + if (!cc->retref) { + void *dp = cdataptr(cdataV(L->top-1)); /* Use preallocated object. */ + CCALL_HANDLE_STRUCTRET2 + } + return 1; /* One GC step. */ + } + if (ctype_iscomplex(ctr->info)) { + /* Return cdata object which is already on top of stack. */ + void *dp = cdataptr(cdataV(L->top-1)); /* Use preallocated object. */ + CCALL_HANDLE_COMPLEXRET2 + return 1; /* One GC step. */ + } + if (LJ_BE && ctr->size < CTSIZE_PTR && + (ctype_isinteger_or_bool(ctr->info) || ctype_isenum(ctr->info))) + sp += (CTSIZE_PTR - ctr->size); +#if CCALL_NUM_FPR + if (ctype_isfp(ctr->info) || ctype_isvector(ctr->info)) + sp = (uint8_t *)&cc->fpr[0]; +#endif +#ifdef CCALL_HANDLE_RET + CCALL_HANDLE_RET +#endif + /* No reference types end up here, so there's no need for the CTypeID. */ + lj_assertL(!(ctype_isrefarray(ctr->info) || ctype_isstruct(ctr->info)), + "unexpected reference ctype"); + return lj_cconv_tv_ct(cts, ctr, 0, L->top-1, sp); +} + +/* Call C function. */ +int lj_ccall_func(lua_State *L, GCcdata *cd) +{ + CTState *cts = ctype_cts(L); + CType *ct = ctype_raw(cts, cd->ctypeid); + CTSize sz = CTSIZE_PTR; + if (ctype_isptr(ct->info)) { + sz = ct->size; + ct = ctype_rawchild(cts, ct); + } + if (ctype_isfunc(ct->info)) { + CCallState cc; + int gcsteps, ret; + cc.func = (void (*)(void))cdata_getptr(cdataptr(cd), sz); + gcsteps = ccall_set_args(L, cts, ct, &cc); + ct = (CType *)((intptr_t)ct-(intptr_t)cts->tab); + cts->cb.slot = ~0u; + lj_vm_ffi_call(&cc); + if (cts->cb.slot != ~0u) { /* Blacklist function that called a callback. */ + TValue tv; + tv.u64 = ((uintptr_t)(void *)cc.func >> 2) | U64x(800000000, 00000000); + setboolV(lj_tab_set(L, cts->miscmap, &tv), 1); + } + ct = (CType *)((intptr_t)ct+(intptr_t)cts->tab); /* May be reallocated. */ + gcsteps += ccall_get_results(L, cts, ct, &cc, &ret); +#if LJ_TARGET_X86 && LJ_ABI_WIN + /* Automatically detect __stdcall and fix up C function declaration. */ + if (cc.spadj && ctype_cconv(ct->info) == CTCC_CDECL) { + CTF_INSERT(ct->info, CCONV, CTCC_STDCALL); + lj_trace_abort(G(L)); + } +#endif + while (gcsteps-- > 0) + lj_gc_check(L); + return ret; + } + return -1; /* Not a function. */ +} + +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_ccall.h b/fluent-bit/lib/luajit-3065c9/src/lj_ccall.h new file mode 100644 index 00000000..0b3c5244 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_ccall.h @@ -0,0 +1,194 @@ +/* +** FFI C call handling. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#ifndef _LJ_CCALL_H +#define _LJ_CCALL_H + +#include "lj_obj.h" +#include "lj_ctype.h" + +#if LJ_HASFFI + +/* -- C calling conventions ----------------------------------------------- */ + +#if LJ_TARGET_X86ORX64 + +#if LJ_TARGET_X86 +#define CCALL_NARG_GPR 2 /* For fastcall arguments. */ +#define CCALL_NARG_FPR 0 +#define CCALL_NRET_GPR 2 +#define CCALL_NRET_FPR 1 /* For FP results on x87 stack. */ +#define CCALL_ALIGN_STACKARG 0 /* Don't align argument on stack. */ +#elif LJ_ABI_WIN +#define CCALL_NARG_GPR 4 +#define CCALL_NARG_FPR 4 +#define CCALL_NRET_GPR 1 +#define CCALL_NRET_FPR 1 +#define CCALL_SPS_EXTRA 4 +#else +#define CCALL_NARG_GPR 6 +#define CCALL_NARG_FPR 8 +#define CCALL_NRET_GPR 2 +#define CCALL_NRET_FPR 2 +#define CCALL_VECTOR_REG 1 /* Pass vectors in registers. */ +#endif + +#define CCALL_SPS_FREE 1 +#define CCALL_ALIGN_CALLSTATE 16 + +typedef LJ_ALIGN(16) union FPRArg { + double d[2]; + float f[4]; + uint8_t b[16]; + uint16_t s[8]; + int i[4]; + int64_t l[2]; +} FPRArg; + +typedef intptr_t GPRArg; + +#elif LJ_TARGET_ARM + +#define CCALL_NARG_GPR 4 +#define CCALL_NRET_GPR 2 /* For softfp double. */ +#if LJ_ABI_SOFTFP +#define CCALL_NARG_FPR 0 +#define CCALL_NRET_FPR 0 +#else +#define CCALL_NARG_FPR 8 +#define CCALL_NRET_FPR 4 +#endif +#define CCALL_SPS_FREE 0 + +typedef intptr_t GPRArg; +typedef union FPRArg { + double d; + float f[2]; +} FPRArg; + +#elif LJ_TARGET_ARM64 + +#define CCALL_NARG_GPR 8 +#define CCALL_NRET_GPR 2 +#define CCALL_NARG_FPR 8 +#define CCALL_NRET_FPR 4 +#define CCALL_SPS_FREE 0 + +typedef intptr_t GPRArg; +typedef union FPRArg { + double d; + struct { LJ_ENDIAN_LOHI(float f; , float g;) }; + struct { LJ_ENDIAN_LOHI(uint32_t lo; , uint32_t hi;) }; +} FPRArg; + +#elif LJ_TARGET_PPC + +#define CCALL_NARG_GPR 8 +#define CCALL_NARG_FPR (LJ_ABI_SOFTFP ? 0 : 8) +#define CCALL_NRET_GPR 4 /* For complex double. */ +#define CCALL_NRET_FPR (LJ_ABI_SOFTFP ? 0 : 1) +#define CCALL_SPS_EXTRA 4 +#define CCALL_SPS_FREE 0 + +typedef intptr_t GPRArg; +typedef double FPRArg; + +#elif LJ_TARGET_MIPS32 + +#define CCALL_NARG_GPR 4 +#define CCALL_NARG_FPR (LJ_ABI_SOFTFP ? 0 : 2) +#define CCALL_NRET_GPR (LJ_ABI_SOFTFP ? 4 : 2) +#define CCALL_NRET_FPR (LJ_ABI_SOFTFP ? 0 : 2) +#define CCALL_SPS_EXTRA 7 +#define CCALL_SPS_FREE 1 + +typedef intptr_t GPRArg; +typedef union FPRArg { + double d; + struct { LJ_ENDIAN_LOHI(float f; , float g;) }; +} FPRArg; + +#elif LJ_TARGET_MIPS64 + +/* FP args are positional and overlay the GPR array. */ +#define CCALL_NARG_GPR 8 +#define CCALL_NARG_FPR 0 +#define CCALL_NRET_GPR 2 +#define CCALL_NRET_FPR (LJ_ABI_SOFTFP ? 0 : 2) +#define CCALL_SPS_EXTRA 3 +#define CCALL_SPS_FREE 1 + +typedef intptr_t GPRArg; +typedef union FPRArg { + double d; + struct { LJ_ENDIAN_LOHI(float f; , float g;) }; +} FPRArg; + +#else +#error "Missing calling convention definitions for this architecture" +#endif + +#ifndef CCALL_SPS_EXTRA +#define CCALL_SPS_EXTRA 0 +#endif +#ifndef CCALL_VECTOR_REG +#define CCALL_VECTOR_REG 0 +#endif +#ifndef CCALL_ALIGN_STACKARG +#define CCALL_ALIGN_STACKARG 1 +#endif +#ifndef CCALL_ALIGN_CALLSTATE +#define CCALL_ALIGN_CALLSTATE 8 +#endif + +#define CCALL_NUM_GPR \ + (CCALL_NARG_GPR > CCALL_NRET_GPR ? CCALL_NARG_GPR : CCALL_NRET_GPR) +#define CCALL_NUM_FPR \ + (CCALL_NARG_FPR > CCALL_NRET_FPR ? CCALL_NARG_FPR : CCALL_NRET_FPR) + +/* Check against constants in lj_ctype.h. */ +LJ_STATIC_ASSERT(CCALL_NUM_GPR <= CCALL_MAX_GPR); +LJ_STATIC_ASSERT(CCALL_NUM_FPR <= CCALL_MAX_FPR); + +#define CCALL_MAXSTACK 32 + +/* -- C call state -------------------------------------------------------- */ + +typedef LJ_ALIGN(CCALL_ALIGN_CALLSTATE) struct CCallState { + void (*func)(void); /* Pointer to called function. */ + uint32_t spadj; /* Stack pointer adjustment. */ + uint8_t nsp; /* Number of stack slots. */ + uint8_t retref; /* Return value by reference. */ +#if LJ_TARGET_X64 + uint8_t ngpr; /* Number of arguments in GPRs. */ + uint8_t nfpr; /* Number of arguments in FPRs. */ +#elif LJ_TARGET_X86 + uint8_t resx87; /* Result on x87 stack: 1:float, 2:double. */ +#elif LJ_TARGET_ARM64 + void *retp; /* Aggregate return pointer in x8. */ +#elif LJ_TARGET_PPC + uint8_t nfpr; /* Number of arguments in FPRs. */ +#endif +#if LJ_32 + int32_t align1; +#endif +#if CCALL_NUM_FPR + FPRArg fpr[CCALL_NUM_FPR]; /* Arguments/results in FPRs. */ +#endif + GPRArg gpr[CCALL_NUM_GPR]; /* Arguments/results in GPRs. */ + GPRArg stack[CCALL_MAXSTACK]; /* Stack slots. */ +} CCallState; + +/* -- C call handling ----------------------------------------------------- */ + +/* Really belongs to lj_vm.h. */ +LJ_ASMF void LJ_FASTCALL lj_vm_ffi_call(CCallState *cc); + +LJ_FUNC CTypeID lj_ccall_ctid_vararg(CTState *cts, cTValue *o); +LJ_FUNC int lj_ccall_func(lua_State *L, GCcdata *cd); + +#endif + +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_ccallback.c b/fluent-bit/lib/luajit-3065c9/src/lj_ccallback.c new file mode 100644 index 00000000..43e44305 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_ccallback.c @@ -0,0 +1,796 @@ +/* +** FFI C callback handling. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#include "lj_obj.h" + +#if LJ_HASFFI + +#include "lj_gc.h" +#include "lj_err.h" +#include "lj_tab.h" +#include "lj_state.h" +#include "lj_frame.h" +#include "lj_ctype.h" +#include "lj_cconv.h" +#include "lj_ccall.h" +#include "lj_ccallback.h" +#include "lj_target.h" +#include "lj_mcode.h" +#include "lj_trace.h" +#include "lj_vm.h" + +/* -- Target-specific handling of callback slots -------------------------- */ + +#define CALLBACK_MCODE_SIZE (LJ_PAGESIZE * LJ_NUM_CBPAGE) + +#if LJ_OS_NOJIT + +/* Callbacks disabled. */ +#define CALLBACK_SLOT2OFS(slot) (0*(slot)) +#define CALLBACK_OFS2SLOT(ofs) (0*(ofs)) +#define CALLBACK_MAX_SLOT 0 + +#elif LJ_TARGET_X86ORX64 + +#define CALLBACK_MCODE_HEAD (LJ_64 ? 8 : 0) +#define CALLBACK_MCODE_GROUP (-2+1+2+(LJ_GC64 ? 10 : 5)+(LJ_64 ? 6 : 5)) + +#define CALLBACK_SLOT2OFS(slot) \ + (CALLBACK_MCODE_HEAD + CALLBACK_MCODE_GROUP*((slot)/32) + 4*(slot)) + +static MSize CALLBACK_OFS2SLOT(MSize ofs) +{ + MSize group; + ofs -= CALLBACK_MCODE_HEAD; + group = ofs / (32*4 + CALLBACK_MCODE_GROUP); + return (ofs % (32*4 + CALLBACK_MCODE_GROUP))/4 + group*32; +} + +#define CALLBACK_MAX_SLOT \ + (((CALLBACK_MCODE_SIZE-CALLBACK_MCODE_HEAD)/(CALLBACK_MCODE_GROUP+4*32))*32) + +#elif LJ_TARGET_ARM + +#define CALLBACK_MCODE_HEAD 32 + +#elif LJ_TARGET_ARM64 + +#define CALLBACK_MCODE_HEAD 32 + +#elif LJ_TARGET_PPC + +#define CALLBACK_MCODE_HEAD 24 + +#elif LJ_TARGET_MIPS32 + +#define CALLBACK_MCODE_HEAD 20 + +#elif LJ_TARGET_MIPS64 + +#define CALLBACK_MCODE_HEAD 52 + +#else + +/* Missing support for this architecture. */ +#define CALLBACK_SLOT2OFS(slot) (0*(slot)) +#define CALLBACK_OFS2SLOT(ofs) (0*(ofs)) +#define CALLBACK_MAX_SLOT 0 + +#endif + +#ifndef CALLBACK_SLOT2OFS +#define CALLBACK_SLOT2OFS(slot) (CALLBACK_MCODE_HEAD + 8*(slot)) +#define CALLBACK_OFS2SLOT(ofs) (((ofs)-CALLBACK_MCODE_HEAD)/8) +#define CALLBACK_MAX_SLOT (CALLBACK_OFS2SLOT(CALLBACK_MCODE_SIZE)) +#endif + +/* Convert callback slot number to callback function pointer. */ +static void *callback_slot2ptr(CTState *cts, MSize slot) +{ + return (uint8_t *)cts->cb.mcode + CALLBACK_SLOT2OFS(slot); +} + +/* Convert callback function pointer to slot number. */ +MSize lj_ccallback_ptr2slot(CTState *cts, void *p) +{ + uintptr_t ofs = (uintptr_t)((uint8_t *)p -(uint8_t *)cts->cb.mcode); + if (ofs < CALLBACK_MCODE_SIZE) { + MSize slot = CALLBACK_OFS2SLOT((MSize)ofs); + if (CALLBACK_SLOT2OFS(slot) == (MSize)ofs) + return slot; + } + return ~0u; /* Not a known callback function pointer. */ +} + +/* Initialize machine code for callback function pointers. */ +#if LJ_OS_NOJIT +/* Disabled callback support. */ +#define callback_mcode_init(g, p) (p) +#elif LJ_TARGET_X86ORX64 +static void *callback_mcode_init(global_State *g, uint8_t *page) +{ + uint8_t *p = page; + uint8_t *target = (uint8_t *)(void *)lj_vm_ffi_callback; + MSize slot; +#if LJ_64 + *(void **)p = target; p += 8; +#endif + for (slot = 0; slot < CALLBACK_MAX_SLOT; slot++) { + /* mov al, slot; jmp group */ + *p++ = XI_MOVrib | RID_EAX; *p++ = (uint8_t)slot; + if ((slot & 31) == 31 || slot == CALLBACK_MAX_SLOT-1) { + /* push ebp/rbp; mov ah, slot>>8; mov ebp, &g. */ + *p++ = XI_PUSH + RID_EBP; + *p++ = XI_MOVrib | (RID_EAX+4); *p++ = (uint8_t)(slot >> 8); +#if LJ_GC64 + *p++ = 0x48; *p++ = XI_MOVri | RID_EBP; + *(uint64_t *)p = (uint64_t)(g); p += 8; +#else + *p++ = XI_MOVri | RID_EBP; + *(int32_t *)p = i32ptr(g); p += 4; +#endif +#if LJ_64 + /* jmp [rip-pageofs] where lj_vm_ffi_callback is stored. */ + *p++ = XI_GROUP5; *p++ = XM_OFS0 + (XOg_JMP<<3) + RID_EBP; + *(int32_t *)p = (int32_t)(page-(p+4)); p += 4; +#else + /* jmp lj_vm_ffi_callback. */ + *p++ = XI_JMP; *(int32_t *)p = target-(p+4); p += 4; +#endif + } else { + *p++ = XI_JMPs; *p++ = (uint8_t)((2+2)*(31-(slot&31)) - 2); + } + } + return p; +} +#elif LJ_TARGET_ARM +static void *callback_mcode_init(global_State *g, uint32_t *page) +{ + uint32_t *p = page; + void *target = (void *)lj_vm_ffi_callback; + MSize slot; + /* This must match with the saveregs macro in buildvm_arm.dasc. */ + *p++ = ARMI_SUB|ARMF_D(RID_R12)|ARMF_N(RID_R12)|ARMF_M(RID_PC); + *p++ = ARMI_PUSH|ARMF_N(RID_SP)|RSET_RANGE(RID_R4,RID_R11+1)|RID2RSET(RID_LR); + *p++ = ARMI_SUB|ARMI_K12|ARMF_D(RID_R12)|ARMF_N(RID_R12)|CALLBACK_MCODE_HEAD; + *p++ = ARMI_STR|ARMI_LS_P|ARMI_LS_W|ARMF_D(RID_R12)|ARMF_N(RID_SP)|(CFRAME_SIZE-4*9); + *p++ = ARMI_LDR|ARMI_LS_P|ARMI_LS_U|ARMF_D(RID_R12)|ARMF_N(RID_PC); + *p++ = ARMI_LDR|ARMI_LS_P|ARMI_LS_U|ARMF_D(RID_PC)|ARMF_N(RID_PC); + *p++ = u32ptr(g); + *p++ = u32ptr(target); + for (slot = 0; slot < CALLBACK_MAX_SLOT; slot++) { + *p++ = ARMI_MOV|ARMF_D(RID_R12)|ARMF_M(RID_PC); + *p = ARMI_B | ((page-p-2) & 0x00ffffffu); + p++; + } + return p; +} +#elif LJ_TARGET_ARM64 +static void *callback_mcode_init(global_State *g, uint32_t *page) +{ + uint32_t *p = page; + void *target = (void *)lj_vm_ffi_callback; + MSize slot; + *p++ = A64I_LE(A64I_LDRLx | A64F_D(RID_X11) | A64F_S19(4)); + *p++ = A64I_LE(A64I_LDRLx | A64F_D(RID_X10) | A64F_S19(5)); + *p++ = A64I_LE(A64I_BR | A64F_N(RID_X11)); + *p++ = A64I_LE(A64I_NOP); + ((void **)p)[0] = target; + ((void **)p)[1] = g; + p += 4; + for (slot = 0; slot < CALLBACK_MAX_SLOT; slot++) { + *p++ = A64I_LE(A64I_MOVZw | A64F_D(RID_X9) | A64F_U16(slot)); + *p = A64I_LE(A64I_B | A64F_S26((page-p) & 0x03ffffffu)); + p++; + } + return p; +} +#elif LJ_TARGET_PPC +static void *callback_mcode_init(global_State *g, uint32_t *page) +{ + uint32_t *p = page; + void *target = (void *)lj_vm_ffi_callback; + MSize slot; + *p++ = PPCI_LIS | PPCF_T(RID_TMP) | (u32ptr(target) >> 16); + *p++ = PPCI_LIS | PPCF_T(RID_R12) | (u32ptr(g) >> 16); + *p++ = PPCI_ORI | PPCF_A(RID_TMP)|PPCF_T(RID_TMP) | (u32ptr(target) & 0xffff); + *p++ = PPCI_ORI | PPCF_A(RID_R12)|PPCF_T(RID_R12) | (u32ptr(g) & 0xffff); + *p++ = PPCI_MTCTR | PPCF_T(RID_TMP); + *p++ = PPCI_BCTR; + for (slot = 0; slot < CALLBACK_MAX_SLOT; slot++) { + *p++ = PPCI_LI | PPCF_T(RID_R11) | slot; + *p = PPCI_B | (((page-p) & 0x00ffffffu) << 2); + p++; + } + return p; +} +#elif LJ_TARGET_MIPS +static void *callback_mcode_init(global_State *g, uint32_t *page) +{ + uint32_t *p = page; + uintptr_t target = (uintptr_t)(void *)lj_vm_ffi_callback; + uintptr_t ug = (uintptr_t)(void *)g; + MSize slot; +#if LJ_TARGET_MIPS32 + *p++ = MIPSI_LUI | MIPSF_T(RID_R3) | (target >> 16); + *p++ = MIPSI_LUI | MIPSF_T(RID_R2) | (ug >> 16); +#else + *p++ = MIPSI_LUI | MIPSF_T(RID_R3) | (target >> 48); + *p++ = MIPSI_LUI | MIPSF_T(RID_R2) | (ug >> 48); + *p++ = MIPSI_ORI | MIPSF_T(RID_R3)|MIPSF_S(RID_R3) | ((target >> 32) & 0xffff); + *p++ = MIPSI_ORI | MIPSF_T(RID_R2)|MIPSF_S(RID_R2) | ((ug >> 32) & 0xffff); + *p++ = MIPSI_DSLL | MIPSF_D(RID_R3)|MIPSF_T(RID_R3) | MIPSF_A(16); + *p++ = MIPSI_DSLL | MIPSF_D(RID_R2)|MIPSF_T(RID_R2) | MIPSF_A(16); + *p++ = MIPSI_ORI | MIPSF_T(RID_R3)|MIPSF_S(RID_R3) | ((target >> 16) & 0xffff); + *p++ = MIPSI_ORI | MIPSF_T(RID_R2)|MIPSF_S(RID_R2) | ((ug >> 16) & 0xffff); + *p++ = MIPSI_DSLL | MIPSF_D(RID_R3)|MIPSF_T(RID_R3) | MIPSF_A(16); + *p++ = MIPSI_DSLL | MIPSF_D(RID_R2)|MIPSF_T(RID_R2) | MIPSF_A(16); +#endif + *p++ = MIPSI_ORI | MIPSF_T(RID_R3)|MIPSF_S(RID_R3) | (target & 0xffff); + *p++ = MIPSI_JR | MIPSF_S(RID_R3); + *p++ = MIPSI_ORI | MIPSF_T(RID_R2)|MIPSF_S(RID_R2) | (ug & 0xffff); + for (slot = 0; slot < CALLBACK_MAX_SLOT; slot++) { + *p = MIPSI_B | ((page-p-1) & 0x0000ffffu); + p++; + *p++ = MIPSI_LI | MIPSF_T(RID_R1) | slot; + } + return p; +} +#else +/* Missing support for this architecture. */ +#define callback_mcode_init(g, p) (p) +#endif + +/* -- Machine code management --------------------------------------------- */ + +#if LJ_TARGET_WINDOWS + +#define WIN32_LEAN_AND_MEAN +#include + +#elif LJ_TARGET_POSIX + +#include +#ifndef MAP_ANONYMOUS +#define MAP_ANONYMOUS MAP_ANON +#endif +#ifdef PROT_MPROTECT +#define CCPROT_CREATE (PROT_MPROTECT(PROT_EXEC)) +#else +#define CCPROT_CREATE 0 +#endif + +#endif + +/* Allocate and initialize area for callback function pointers. */ +static void callback_mcode_new(CTState *cts) +{ + size_t sz = (size_t)CALLBACK_MCODE_SIZE; + void *p, *pe; + if (CALLBACK_MAX_SLOT == 0) + lj_err_caller(cts->L, LJ_ERR_FFI_CBACKOV); +#if LJ_TARGET_WINDOWS + p = LJ_WIN_VALLOC(NULL, sz, MEM_RESERVE|MEM_COMMIT, PAGE_READWRITE); + if (!p) + lj_err_caller(cts->L, LJ_ERR_FFI_CBACKOV); +#elif LJ_TARGET_POSIX + p = mmap(NULL, sz, (PROT_READ|PROT_WRITE|CCPROT_CREATE), MAP_PRIVATE|MAP_ANONYMOUS, + -1, 0); + if (p == MAP_FAILED) + lj_err_caller(cts->L, LJ_ERR_FFI_CBACKOV); +#else + /* Fallback allocator. Fails if memory is not executable by default. */ + p = lj_mem_new(cts->L, sz); +#endif + cts->cb.mcode = p; + pe = callback_mcode_init(cts->g, p); + UNUSED(pe); + lj_assertCTS((size_t)((char *)pe - (char *)p) <= sz, + "miscalculated CALLBACK_MAX_SLOT"); + lj_mcode_sync(p, (char *)p + sz); +#if LJ_TARGET_WINDOWS + { + DWORD oprot; + LJ_WIN_VPROTECT(p, sz, PAGE_EXECUTE_READ, &oprot); + } +#elif LJ_TARGET_POSIX + mprotect(p, sz, (PROT_READ|PROT_EXEC)); +#endif +} + +/* Free area for callback function pointers. */ +void lj_ccallback_mcode_free(CTState *cts) +{ + size_t sz = (size_t)CALLBACK_MCODE_SIZE; + void *p = cts->cb.mcode; + if (p == NULL) return; +#if LJ_TARGET_WINDOWS + VirtualFree(p, 0, MEM_RELEASE); + UNUSED(sz); +#elif LJ_TARGET_POSIX + munmap(p, sz); +#else + lj_mem_free(cts->g, p, sz); +#endif +} + +/* -- C callback entry ---------------------------------------------------- */ + +/* Target-specific handling of register arguments. Similar to lj_ccall.c. */ +#if LJ_TARGET_X86 + +#define CALLBACK_HANDLE_REGARG \ + if (!isfp) { /* Only non-FP values may be passed in registers. */ \ + if (n > 1) { /* Anything > 32 bit is passed on the stack. */ \ + if (!LJ_ABI_WIN) ngpr = maxgpr; /* Prevent reordering. */ \ + } else if (ngpr + 1 <= maxgpr) { \ + sp = &cts->cb.gpr[ngpr]; \ + ngpr += n; \ + goto done; \ + } \ + } + +#elif LJ_TARGET_X64 && LJ_ABI_WIN + +/* Windows/x64 argument registers are strictly positional (use ngpr). */ +#define CALLBACK_HANDLE_REGARG \ + if (isfp) { \ + if (ngpr < maxgpr) { sp = &cts->cb.fpr[ngpr++]; UNUSED(nfpr); goto done; } \ + } else { \ + if (ngpr < maxgpr) { sp = &cts->cb.gpr[ngpr++]; goto done; } \ + } + +#elif LJ_TARGET_X64 + +#define CALLBACK_HANDLE_REGARG \ + if (isfp) { \ + if (nfpr + n <= CCALL_NARG_FPR) { \ + sp = &cts->cb.fpr[nfpr]; \ + nfpr += n; \ + goto done; \ + } \ + } else { \ + if (ngpr + n <= maxgpr) { \ + sp = &cts->cb.gpr[ngpr]; \ + ngpr += n; \ + goto done; \ + } \ + } + +#elif LJ_TARGET_ARM + +#if LJ_ABI_SOFTFP + +#define CALLBACK_HANDLE_REGARG_FP1 UNUSED(isfp); +#define CALLBACK_HANDLE_REGARG_FP2 + +#else + +#define CALLBACK_HANDLE_REGARG_FP1 \ + if (isfp) { \ + if (n == 1) { \ + if (fprodd) { \ + sp = &cts->cb.fpr[fprodd-1]; \ + fprodd = 0; \ + goto done; \ + } else if (nfpr + 1 <= CCALL_NARG_FPR) { \ + sp = &cts->cb.fpr[nfpr++]; \ + fprodd = nfpr; \ + goto done; \ + } \ + } else { \ + if (nfpr + 1 <= CCALL_NARG_FPR) { \ + sp = &cts->cb.fpr[nfpr++]; \ + goto done; \ + } \ + } \ + fprodd = 0; /* No reordering after the first FP value is on stack. */ \ + } else { + +#define CALLBACK_HANDLE_REGARG_FP2 } + +#endif + +#define CALLBACK_HANDLE_REGARG \ + CALLBACK_HANDLE_REGARG_FP1 \ + if (n > 1) ngpr = (ngpr + 1u) & ~1u; /* Align to regpair. */ \ + if (ngpr + n <= maxgpr) { \ + sp = &cts->cb.gpr[ngpr]; \ + ngpr += n; \ + goto done; \ + } CALLBACK_HANDLE_REGARG_FP2 + +#elif LJ_TARGET_ARM64 + +#define CALLBACK_HANDLE_REGARG \ + if (isfp) { \ + if (nfpr + n <= CCALL_NARG_FPR) { \ + sp = &cts->cb.fpr[nfpr]; \ + nfpr += n; \ + goto done; \ + } else { \ + nfpr = CCALL_NARG_FPR; /* Prevent reordering. */ \ + } \ + } else { \ + if (!LJ_TARGET_OSX && n > 1) \ + ngpr = (ngpr + 1u) & ~1u; /* Align to regpair. */ \ + if (ngpr + n <= maxgpr) { \ + sp = &cts->cb.gpr[ngpr]; \ + ngpr += n; \ + goto done; \ + } else { \ + ngpr = CCALL_NARG_GPR; /* Prevent reordering. */ \ + } \ + } + +#elif LJ_TARGET_PPC + +#define CALLBACK_HANDLE_GPR \ + if (n > 1) { \ + lj_assertCTS(((LJ_ABI_SOFTFP && ctype_isnum(cta->info)) || /* double. */ \ + ctype_isinteger(cta->info)) && n == 2, /* int64_t. */ \ + "bad GPR type"); \ + ngpr = (ngpr + 1u) & ~1u; /* Align int64_t to regpair. */ \ + } \ + if (ngpr + n <= maxgpr) { \ + sp = &cts->cb.gpr[ngpr]; \ + ngpr += n; \ + goto done; \ + } + +#if LJ_ABI_SOFTFP +#define CALLBACK_HANDLE_REGARG \ + CALLBACK_HANDLE_GPR \ + UNUSED(isfp); +#else +#define CALLBACK_HANDLE_REGARG \ + if (isfp) { \ + if (nfpr + 1 <= CCALL_NARG_FPR) { \ + sp = &cts->cb.fpr[nfpr++]; \ + cta = ctype_get(cts, CTID_DOUBLE); /* FPRs always hold doubles. */ \ + goto done; \ + } \ + } else { /* Try to pass argument in GPRs. */ \ + CALLBACK_HANDLE_GPR \ + } +#endif + +#if !LJ_ABI_SOFTFP +#define CALLBACK_HANDLE_RET \ + if (ctype_isfp(ctr->info) && ctr->size == sizeof(float)) \ + *(double *)dp = *(float *)dp; /* FPRs always hold doubles. */ +#endif + +#elif LJ_TARGET_MIPS32 + +#define CALLBACK_HANDLE_GPR \ + if (n > 1) ngpr = (ngpr + 1u) & ~1u; /* Align to regpair. */ \ + if (ngpr + n <= maxgpr) { \ + sp = &cts->cb.gpr[ngpr]; \ + ngpr += n; \ + goto done; \ + } + +#if !LJ_ABI_SOFTFP /* MIPS32 hard-float */ +#define CALLBACK_HANDLE_REGARG \ + if (isfp && nfpr < CCALL_NARG_FPR) { /* Try to pass argument in FPRs. */ \ + sp = (void *)((uint8_t *)&cts->cb.fpr[nfpr] + ((LJ_BE && n==1) ? 4 : 0)); \ + nfpr++; ngpr += n; \ + goto done; \ + } else { /* Try to pass argument in GPRs. */ \ + nfpr = CCALL_NARG_FPR; \ + CALLBACK_HANDLE_GPR \ + } +#else /* MIPS32 soft-float */ +#define CALLBACK_HANDLE_REGARG \ + CALLBACK_HANDLE_GPR \ + UNUSED(isfp); +#endif + +#define CALLBACK_HANDLE_RET \ + if (ctype_isfp(ctr->info) && ctr->size == sizeof(float)) \ + ((float *)dp)[1] = *(float *)dp; + +#elif LJ_TARGET_MIPS64 + +#if !LJ_ABI_SOFTFP /* MIPS64 hard-float */ +#define CALLBACK_HANDLE_REGARG \ + if (ngpr + n <= maxgpr) { \ + sp = isfp ? (void*) &cts->cb.fpr[ngpr] : (void*) &cts->cb.gpr[ngpr]; \ + ngpr += n; \ + goto done; \ + } +#else /* MIPS64 soft-float */ +#define CALLBACK_HANDLE_REGARG \ + if (ngpr + n <= maxgpr) { \ + UNUSED(isfp); \ + sp = (void*) &cts->cb.gpr[ngpr]; \ + ngpr += n; \ + goto done; \ + } +#endif + +#define CALLBACK_HANDLE_RET \ + if (ctype_isfp(ctr->info) && ctr->size == sizeof(float)) \ + ((float *)dp)[1] = *(float *)dp; + +#else +#error "Missing calling convention definitions for this architecture" +#endif + +/* Convert and push callback arguments to Lua stack. */ +static void callback_conv_args(CTState *cts, lua_State *L) +{ + TValue *o = L->top; + intptr_t *stack = cts->cb.stack; + MSize slot = cts->cb.slot; + CTypeID id = 0, rid, fid; + int gcsteps = 0; + CType *ct; + GCfunc *fn; + int fntp; + MSize ngpr = 0, nsp = 0, maxgpr = CCALL_NARG_GPR; +#if CCALL_NARG_FPR + MSize nfpr = 0; +#if LJ_TARGET_ARM + MSize fprodd = 0; +#endif +#endif + + if (slot < cts->cb.sizeid && (id = cts->cb.cbid[slot]) != 0) { + ct = ctype_get(cts, id); + rid = ctype_cid(ct->info); /* Return type. x86: +(spadj<<16). */ + fn = funcV(lj_tab_getint(cts->miscmap, (int32_t)slot)); + fntp = LJ_TFUNC; + } else { /* Must set up frame first, before throwing the error. */ + ct = NULL; + rid = 0; + fn = (GCfunc *)L; + fntp = LJ_TTHREAD; + } + /* Continuation returns from callback. */ + if (LJ_FR2) { + (o++)->u64 = LJ_CONT_FFI_CALLBACK; + (o++)->u64 = rid; + } else { + o->u32.lo = LJ_CONT_FFI_CALLBACK; + o->u32.hi = rid; + o++; + } + setframe_gc(o, obj2gco(fn), fntp); + if (LJ_FR2) o++; + setframe_ftsz(o, ((char *)(o+1) - (char *)L->base) + FRAME_CONT); + L->top = L->base = ++o; + if (!ct) + lj_err_caller(cts->L, LJ_ERR_FFI_BADCBACK); + if (isluafunc(fn)) + setcframe_pc(L->cframe, proto_bc(funcproto(fn))+1); + lj_state_checkstack(L, LUA_MINSTACK); /* May throw. */ + o = L->base; /* Might have been reallocated. */ + +#if LJ_TARGET_X86 + /* x86 has several different calling conventions. */ + switch (ctype_cconv(ct->info)) { + case CTCC_FASTCALL: maxgpr = 2; break; + case CTCC_THISCALL: maxgpr = 1; break; + default: maxgpr = 0; break; + } +#endif + + fid = ct->sib; + while (fid) { + CType *ctf = ctype_get(cts, fid); + if (!ctype_isattrib(ctf->info)) { + CType *cta; + void *sp; + CTSize sz; + int isfp; + MSize n; + lj_assertCTS(ctype_isfield(ctf->info), "field expected"); + cta = ctype_rawchild(cts, ctf); + isfp = ctype_isfp(cta->info); + sz = (cta->size + CTSIZE_PTR-1) & ~(CTSIZE_PTR-1); + n = sz / CTSIZE_PTR; /* Number of GPRs or stack slots needed. */ + + CALLBACK_HANDLE_REGARG /* Handle register arguments. */ + + /* Otherwise pass argument on stack. */ + if (CCALL_ALIGN_STACKARG && LJ_32 && sz == 8) + nsp = (nsp + 1) & ~1u; /* Align 64 bit argument on stack. */ + sp = &stack[nsp]; + nsp += n; + + done: + if (LJ_BE && cta->size < CTSIZE_PTR +#if LJ_TARGET_MIPS64 + && !(isfp && nsp) +#endif + ) + sp = (void *)((uint8_t *)sp + CTSIZE_PTR-cta->size); + gcsteps += lj_cconv_tv_ct(cts, cta, 0, o++, sp); + } + fid = ctf->sib; + } + L->top = o; +#if LJ_TARGET_X86 + /* Store stack adjustment for returns from non-cdecl callbacks. */ + if (ctype_cconv(ct->info) != CTCC_CDECL) { +#if LJ_FR2 + (L->base-3)->u64 |= (nsp << (16+2)); +#else + (L->base-2)->u32.hi |= (nsp << (16+2)); +#endif + } +#endif + while (gcsteps-- > 0) + lj_gc_check(L); +} + +/* Convert Lua object to callback result. */ +static void callback_conv_result(CTState *cts, lua_State *L, TValue *o) +{ +#if LJ_FR2 + CType *ctr = ctype_raw(cts, (uint16_t)(L->base-3)->u64); +#else + CType *ctr = ctype_raw(cts, (uint16_t)(L->base-2)->u32.hi); +#endif +#if LJ_TARGET_X86 + cts->cb.gpr[2] = 0; +#endif + if (!ctype_isvoid(ctr->info)) { + uint8_t *dp = (uint8_t *)&cts->cb.gpr[0]; +#if CCALL_NUM_FPR + if (ctype_isfp(ctr->info)) + dp = (uint8_t *)&cts->cb.fpr[0]; +#endif +#if LJ_TARGET_ARM64 && LJ_BE + if (ctype_isfp(ctr->info) && ctr->size == sizeof(float)) + dp = (uint8_t *)&cts->cb.fpr[0].f[1]; +#endif + lj_cconv_ct_tv(cts, ctr, dp, o, 0); +#ifdef CALLBACK_HANDLE_RET + CALLBACK_HANDLE_RET +#endif + /* Extend returned integers to (at least) 32 bits. */ + if (ctype_isinteger_or_bool(ctr->info) && ctr->size < 4) { + if (ctr->info & CTF_UNSIGNED) + *(uint32_t *)dp = ctr->size == 1 ? (uint32_t)*(uint8_t *)dp : + (uint32_t)*(uint16_t *)dp; + else + *(int32_t *)dp = ctr->size == 1 ? (int32_t)*(int8_t *)dp : + (int32_t)*(int16_t *)dp; + } +#if LJ_TARGET_MIPS64 || (LJ_TARGET_ARM64 && LJ_BE) + /* Always sign-extend results to 64 bits. Even a soft-fp 'float'. */ + if (ctr->size <= 4 && + (LJ_ABI_SOFTFP || ctype_isinteger_or_bool(ctr->info))) + *(int64_t *)dp = (int64_t)*(int32_t *)dp; +#endif +#if LJ_TARGET_X86 + if (ctype_isfp(ctr->info)) + cts->cb.gpr[2] = ctr->size == sizeof(float) ? 1 : 2; +#endif + } +} + +/* Enter callback. */ +lua_State * LJ_FASTCALL lj_ccallback_enter(CTState *cts, void *cf) +{ + lua_State *L = cts->L; + global_State *g = cts->g; + lj_assertG(L != NULL, "uninitialized cts->L in callback"); + if (tvref(g->jit_base)) { + setstrV(L, L->top++, lj_err_str(L, LJ_ERR_FFI_BADCBACK)); + if (g->panic) g->panic(L); + exit(EXIT_FAILURE); + } + lj_trace_abort(g); /* Never record across callback. */ + /* Setup C frame. */ + cframe_prev(cf) = L->cframe; + setcframe_L(cf, L); + cframe_errfunc(cf) = -1; + cframe_nres(cf) = 0; + L->cframe = cf; + callback_conv_args(cts, L); + return L; /* Now call the function on this stack. */ +} + +/* Leave callback. */ +void LJ_FASTCALL lj_ccallback_leave(CTState *cts, TValue *o) +{ + lua_State *L = cts->L; + GCfunc *fn; + TValue *obase = L->base; + L->base = L->top; /* Keep continuation frame for throwing errors. */ + if (o >= L->base) { + /* PC of RET* is lost. Point to last line for result conv. errors. */ + fn = curr_func(L); + if (isluafunc(fn)) { + GCproto *pt = funcproto(fn); + setcframe_pc(L->cframe, proto_bc(pt)+pt->sizebc+1); + } + } + callback_conv_result(cts, L, o); + /* Finally drop C frame and continuation frame. */ + L->top -= 2+2*LJ_FR2; + L->base = obase; + L->cframe = cframe_prev(L->cframe); + cts->cb.slot = 0; /* Blacklist C function that called the callback. */ +} + +/* -- C callback management ----------------------------------------------- */ + +/* Get an unused slot in the callback slot table. */ +static MSize callback_slot_new(CTState *cts, CType *ct) +{ + CTypeID id = ctype_typeid(cts, ct); + CTypeID1 *cbid = cts->cb.cbid; + MSize top; + for (top = cts->cb.topid; top < cts->cb.sizeid; top++) + if (LJ_LIKELY(cbid[top] == 0)) + goto found; +#if CALLBACK_MAX_SLOT + if (top >= CALLBACK_MAX_SLOT) +#endif + lj_err_caller(cts->L, LJ_ERR_FFI_CBACKOV); + if (!cts->cb.mcode) + callback_mcode_new(cts); + lj_mem_growvec(cts->L, cbid, cts->cb.sizeid, CALLBACK_MAX_SLOT, CTypeID1); + cts->cb.cbid = cbid; + memset(cbid+top, 0, (cts->cb.sizeid-top)*sizeof(CTypeID1)); +found: + cbid[top] = id; + cts->cb.topid = top+1; + return top; +} + +/* Check for function pointer and supported argument/result types. */ +static CType *callback_checkfunc(CTState *cts, CType *ct) +{ + int narg = 0; + if (!ctype_isptr(ct->info) || (LJ_64 && ct->size != CTSIZE_PTR)) + return NULL; + ct = ctype_rawchild(cts, ct); + if (ctype_isfunc(ct->info)) { + CType *ctr = ctype_rawchild(cts, ct); + CTypeID fid = ct->sib; + if (!(ctype_isvoid(ctr->info) || ctype_isenum(ctr->info) || + ctype_isptr(ctr->info) || (ctype_isnum(ctr->info) && ctr->size <= 8))) + return NULL; + if ((ct->info & CTF_VARARG)) + return NULL; + while (fid) { + CType *ctf = ctype_get(cts, fid); + if (!ctype_isattrib(ctf->info)) { + CType *cta; + lj_assertCTS(ctype_isfield(ctf->info), "field expected"); + cta = ctype_rawchild(cts, ctf); + if (!(ctype_isenum(cta->info) || ctype_isptr(cta->info) || + (ctype_isnum(cta->info) && cta->size <= 8)) || + ++narg >= LUA_MINSTACK-3) + return NULL; + } + fid = ctf->sib; + } + return ct; + } + return NULL; +} + +/* Create a new callback and return the callback function pointer. */ +void *lj_ccallback_new(CTState *cts, CType *ct, GCfunc *fn) +{ + ct = callback_checkfunc(cts, ct); + if (ct) { + MSize slot = callback_slot_new(cts, ct); + GCtab *t = cts->miscmap; + setfuncV(cts->L, lj_tab_setint(cts->L, t, (int32_t)slot), fn); + lj_gc_anybarriert(cts->L, t); + return callback_slot2ptr(cts, slot); + } + return NULL; /* Bad conversion. */ +} + +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_ccallback.h b/fluent-bit/lib/luajit-3065c9/src/lj_ccallback.h new file mode 100644 index 00000000..8a2c31df --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_ccallback.h @@ -0,0 +1,25 @@ +/* +** FFI C callback handling. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#ifndef _LJ_CCALLBACK_H +#define _LJ_CCALLBACK_H + +#include "lj_obj.h" +#include "lj_ctype.h" + +#if LJ_HASFFI + +/* Really belongs to lj_vm.h. */ +LJ_ASMF void lj_vm_ffi_callback(void); + +LJ_FUNC MSize lj_ccallback_ptr2slot(CTState *cts, void *p); +LJ_FUNCA lua_State * LJ_FASTCALL lj_ccallback_enter(CTState *cts, void *cf); +LJ_FUNCA void LJ_FASTCALL lj_ccallback_leave(CTState *cts, TValue *o); +LJ_FUNC void *lj_ccallback_new(CTState *cts, CType *ct, GCfunc *fn); +LJ_FUNC void lj_ccallback_mcode_free(CTState *cts); + +#endif + +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_cconv.c b/fluent-bit/lib/luajit-3065c9/src/lj_cconv.c new file mode 100644 index 00000000..3bbfd3f1 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_cconv.c @@ -0,0 +1,770 @@ +/* +** C type conversions. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#include "lj_obj.h" + +#if LJ_HASFFI + +#include "lj_err.h" +#include "lj_buf.h" +#include "lj_tab.h" +#include "lj_ctype.h" +#include "lj_cdata.h" +#include "lj_cconv.h" +#include "lj_ccallback.h" + +/* -- Conversion errors --------------------------------------------------- */ + +/* Bad conversion. */ +LJ_NORET static void cconv_err_conv(CTState *cts, CType *d, CType *s, + CTInfo flags) +{ + const char *dst = strdata(lj_ctype_repr(cts->L, ctype_typeid(cts, d), NULL)); + const char *src; + if ((flags & CCF_FROMTV)) + src = lj_obj_typename[1+(ctype_isnum(s->info) ? LUA_TNUMBER : + ctype_isarray(s->info) ? LUA_TSTRING : LUA_TNIL)]; + else + src = strdata(lj_ctype_repr(cts->L, ctype_typeid(cts, s), NULL)); + if (CCF_GETARG(flags)) + lj_err_argv(cts->L, CCF_GETARG(flags), LJ_ERR_FFI_BADCONV, src, dst); + else + lj_err_callerv(cts->L, LJ_ERR_FFI_BADCONV, src, dst); +} + +/* Bad conversion from TValue. */ +LJ_NORET static void cconv_err_convtv(CTState *cts, CType *d, TValue *o, + CTInfo flags) +{ + const char *dst = strdata(lj_ctype_repr(cts->L, ctype_typeid(cts, d), NULL)); + const char *src = lj_typename(o); + if (CCF_GETARG(flags)) + lj_err_argv(cts->L, CCF_GETARG(flags), LJ_ERR_FFI_BADCONV, src, dst); + else + lj_err_callerv(cts->L, LJ_ERR_FFI_BADCONV, src, dst); +} + +/* Initializer overflow. */ +LJ_NORET static void cconv_err_initov(CTState *cts, CType *d) +{ + const char *dst = strdata(lj_ctype_repr(cts->L, ctype_typeid(cts, d), NULL)); + lj_err_callerv(cts->L, LJ_ERR_FFI_INITOV, dst); +} + +/* -- C type compatibility checks ----------------------------------------- */ + +/* Get raw type and qualifiers for a child type. Resolves enums, too. */ +static CType *cconv_childqual(CTState *cts, CType *ct, CTInfo *qual) +{ + ct = ctype_child(cts, ct); + for (;;) { + if (ctype_isattrib(ct->info)) { + if (ctype_attrib(ct->info) == CTA_QUAL) *qual |= ct->size; + } else if (!ctype_isenum(ct->info)) { + break; + } + ct = ctype_child(cts, ct); + } + *qual |= (ct->info & CTF_QUAL); + return ct; +} + +/* Check for compatible types when converting to a pointer. +** Note: these checks are more relaxed than what C99 mandates. +*/ +int lj_cconv_compatptr(CTState *cts, CType *d, CType *s, CTInfo flags) +{ + if (!((flags & CCF_CAST) || d == s)) { + CTInfo dqual = 0, squal = 0; + d = cconv_childqual(cts, d, &dqual); + if (!ctype_isstruct(s->info)) + s = cconv_childqual(cts, s, &squal); + if ((flags & CCF_SAME)) { + if (dqual != squal) + return 0; /* Different qualifiers. */ + } else if (!(flags & CCF_IGNQUAL)) { + if ((dqual & squal) != squal) + return 0; /* Discarded qualifiers. */ + if (ctype_isvoid(d->info) || ctype_isvoid(s->info)) + return 1; /* Converting to/from void * is always ok. */ + } + if (ctype_type(d->info) != ctype_type(s->info) || + d->size != s->size) + return 0; /* Different type or different size. */ + if (ctype_isnum(d->info)) { + if (((d->info ^ s->info) & (CTF_BOOL|CTF_FP))) + return 0; /* Different numeric types. */ + } else if (ctype_ispointer(d->info)) { + /* Check child types for compatibility. */ + return lj_cconv_compatptr(cts, d, s, flags|CCF_SAME); + } else if (ctype_isstruct(d->info)) { + if (d != s) + return 0; /* Must be exact same type for struct/union. */ + } else if (ctype_isfunc(d->info)) { + /* NYI: structural equality of functions. */ + } + } + return 1; /* Types are compatible. */ +} + +/* -- C type to C type conversion ----------------------------------------- */ + +/* Convert C type to C type. Caveat: expects to get the raw CType! +** +** Note: This is only used by the interpreter and not optimized at all. +** The JIT compiler will do a much better job specializing for each case. +*/ +void lj_cconv_ct_ct(CTState *cts, CType *d, CType *s, + uint8_t *dp, uint8_t *sp, CTInfo flags) +{ + CTSize dsize = d->size, ssize = s->size; + CTInfo dinfo = d->info, sinfo = s->info; + void *tmpptr; + + lj_assertCTS(!ctype_isenum(dinfo) && !ctype_isenum(sinfo), + "unresolved enum"); + lj_assertCTS(!ctype_isattrib(dinfo) && !ctype_isattrib(sinfo), + "unstripped attribute"); + + if (ctype_type(dinfo) > CT_MAYCONVERT || ctype_type(sinfo) > CT_MAYCONVERT) + goto err_conv; + + /* Some basic sanity checks. */ + lj_assertCTS(!ctype_isnum(dinfo) || dsize > 0, "bad size for number type"); + lj_assertCTS(!ctype_isnum(sinfo) || ssize > 0, "bad size for number type"); + lj_assertCTS(!ctype_isbool(dinfo) || dsize == 1 || dsize == 4, + "bad size for bool type"); + lj_assertCTS(!ctype_isbool(sinfo) || ssize == 1 || ssize == 4, + "bad size for bool type"); + lj_assertCTS(!ctype_isinteger(dinfo) || (1u< ssize) { /* Zero-extend or sign-extend LSB. */ +#if LJ_LE + uint8_t fill = (!(sinfo & CTF_UNSIGNED) && (sp[ssize-1]&0x80)) ? 0xff : 0; + memcpy(dp, sp, ssize); + memset(dp + ssize, fill, dsize-ssize); +#else + uint8_t fill = (!(sinfo & CTF_UNSIGNED) && (sp[0]&0x80)) ? 0xff : 0; + memset(dp, fill, dsize-ssize); + memcpy(dp + (dsize-ssize), sp, ssize); +#endif + } else { /* Copy LSB. */ +#if LJ_LE + memcpy(dp, sp, dsize); +#else + memcpy(dp, sp + (ssize-dsize), dsize); +#endif + } + break; + case CCX(I, F): { + double n; /* Always convert via double. */ + conv_I_F: + /* Convert source to double. */ + if (ssize == sizeof(double)) n = *(double *)sp; + else if (ssize == sizeof(float)) n = (double)*(float *)sp; + else goto err_conv; /* NYI: long double. */ + /* Then convert double to integer. */ + /* The conversion must exactly match the semantics of JIT-compiled code! */ + if (dsize < 4 || (dsize == 4 && !(dinfo & CTF_UNSIGNED))) { + int32_t i = (int32_t)n; + if (dsize == 4) *(int32_t *)dp = i; + else if (dsize == 2) *(int16_t *)dp = (int16_t)i; + else *(int8_t *)dp = (int8_t)i; + } else if (dsize == 4) { + *(uint32_t *)dp = (uint32_t)n; + } else if (dsize == 8) { + if (!(dinfo & CTF_UNSIGNED)) + *(int64_t *)dp = (int64_t)n; + else + *(uint64_t *)dp = lj_num2u64(n); + } else { + goto err_conv; /* NYI: conversion to >64 bit integers. */ + } + break; + } + case CCX(I, C): + s = ctype_child(cts, s); + sinfo = s->info; + ssize = s->size; + goto conv_I_F; /* Just convert re. */ + case CCX(I, P): + if (!(flags & CCF_CAST)) goto err_conv; + sinfo = CTINFO(CT_NUM, CTF_UNSIGNED); + goto conv_I_I; + case CCX(I, A): + if (!(flags & CCF_CAST)) goto err_conv; + sinfo = CTINFO(CT_NUM, CTF_UNSIGNED); + ssize = CTSIZE_PTR; + tmpptr = sp; + sp = (uint8_t *)&tmpptr; + goto conv_I_I; + + /* Destination is a floating-point number. */ + case CCX(F, B): + case CCX(F, I): { + double n; /* Always convert via double. */ + conv_F_I: + /* First convert source to double. */ + /* The conversion must exactly match the semantics of JIT-compiled code! */ + if (ssize < 4 || (ssize == 4 && !(sinfo & CTF_UNSIGNED))) { + int32_t i; + if (ssize == 4) { + i = *(int32_t *)sp; + } else if (!(sinfo & CTF_UNSIGNED)) { + if (ssize == 2) i = *(int16_t *)sp; + else i = *(int8_t *)sp; + } else { + if (ssize == 2) i = *(uint16_t *)sp; + else i = *(uint8_t *)sp; + } + n = (double)i; + } else if (ssize == 4) { + n = (double)*(uint32_t *)sp; + } else if (ssize == 8) { + if (!(sinfo & CTF_UNSIGNED)) n = (double)*(int64_t *)sp; + else n = (double)*(uint64_t *)sp; + } else { + goto err_conv; /* NYI: conversion from >64 bit integers. */ + } + /* Convert double to destination. */ + if (dsize == sizeof(double)) *(double *)dp = n; + else if (dsize == sizeof(float)) *(float *)dp = (float)n; + else goto err_conv; /* NYI: long double. */ + break; + } + case CCX(F, F): { + double n; /* Always convert via double. */ + conv_F_F: + if (ssize == dsize) goto copyval; + /* Convert source to double. */ + if (ssize == sizeof(double)) n = *(double *)sp; + else if (ssize == sizeof(float)) n = (double)*(float *)sp; + else goto err_conv; /* NYI: long double. */ + /* Convert double to destination. */ + if (dsize == sizeof(double)) *(double *)dp = n; + else if (dsize == sizeof(float)) *(float *)dp = (float)n; + else goto err_conv; /* NYI: long double. */ + break; + } + case CCX(F, C): + s = ctype_child(cts, s); + sinfo = s->info; + ssize = s->size; + goto conv_F_F; /* Ignore im, and convert from re. */ + + /* Destination is a complex number. */ + case CCX(C, I): + d = ctype_child(cts, d); + dinfo = d->info; + dsize = d->size; + memset(dp + dsize, 0, dsize); /* Clear im. */ + goto conv_F_I; /* Convert to re. */ + case CCX(C, F): + d = ctype_child(cts, d); + dinfo = d->info; + dsize = d->size; + memset(dp + dsize, 0, dsize); /* Clear im. */ + goto conv_F_F; /* Convert to re. */ + + case CCX(C, C): + if (dsize != ssize) { /* Different types: convert re/im separately. */ + CType *dc = ctype_child(cts, d); + CType *sc = ctype_child(cts, s); + lj_cconv_ct_ct(cts, dc, sc, dp, sp, flags); + lj_cconv_ct_ct(cts, dc, sc, dp + dc->size, sp + sc->size, flags); + return; + } + goto copyval; /* Otherwise this is easy. */ + + /* Destination is a vector. */ + case CCX(V, I): + case CCX(V, F): + case CCX(V, C): { + CType *dc = ctype_child(cts, d); + CTSize esize; + /* First convert the scalar to the first element. */ + lj_cconv_ct_ct(cts, dc, s, dp, sp, flags); + /* Then replicate it to the other elements (splat). */ + for (sp = dp, esize = dc->size; dsize > esize; dsize -= esize) { + dp += esize; + memcpy(dp, sp, esize); + } + break; + } + + case CCX(V, V): + /* Copy same-sized vectors, even for different lengths/element-types. */ + if (dsize != ssize) goto err_conv; + goto copyval; + + /* Destination is a pointer. */ + case CCX(P, I): + if (!(flags & CCF_CAST)) goto err_conv; + dinfo = CTINFO(CT_NUM, CTF_UNSIGNED); + goto conv_I_I; + + case CCX(P, F): + if (!(flags & CCF_CAST) || !(flags & CCF_FROMTV)) goto err_conv; + /* The signed conversion is cheaper. x64 really has 47 bit pointers. */ + dinfo = CTINFO(CT_NUM, (LJ_64 && dsize == 8) ? 0 : CTF_UNSIGNED); + goto conv_I_F; + + case CCX(P, P): + if (!lj_cconv_compatptr(cts, d, s, flags)) goto err_conv; + cdata_setptr(dp, dsize, cdata_getptr(sp, ssize)); + break; + + case CCX(P, A): + case CCX(P, S): + if (!lj_cconv_compatptr(cts, d, s, flags)) goto err_conv; + cdata_setptr(dp, dsize, sp); + break; + + /* Destination is an array. */ + case CCX(A, A): + if ((flags & CCF_CAST) || (d->info & CTF_VLA) || dsize != ssize || + d->size == CTSIZE_INVALID || !lj_cconv_compatptr(cts, d, s, flags)) + goto err_conv; + goto copyval; + + /* Destination is a struct/union. */ + case CCX(S, S): + if ((flags & CCF_CAST) || (d->info & CTF_VLA) || d != s) + goto err_conv; /* Must be exact same type. */ +copyval: /* Copy value. */ + lj_assertCTS(dsize == ssize, "value copy with different sizes"); + memcpy(dp, sp, dsize); + break; + + default: + err_conv: + cconv_err_conv(cts, d, s, flags); + } +} + +/* -- C type to TValue conversion ----------------------------------------- */ + +/* Convert C type to TValue. Caveat: expects to get the raw CType! */ +int lj_cconv_tv_ct(CTState *cts, CType *s, CTypeID sid, + TValue *o, uint8_t *sp) +{ + CTInfo sinfo = s->info; + if (ctype_isnum(sinfo)) { + if (!ctype_isbool(sinfo)) { + if (ctype_isinteger(sinfo) && s->size > 4) goto copyval; + if (LJ_DUALNUM && ctype_isinteger(sinfo)) { + int32_t i; + lj_cconv_ct_ct(cts, ctype_get(cts, CTID_INT32), s, + (uint8_t *)&i, sp, 0); + if ((sinfo & CTF_UNSIGNED) && i < 0) + setnumV(o, (lua_Number)(uint32_t)i); + else + setintV(o, i); + } else { + lj_cconv_ct_ct(cts, ctype_get(cts, CTID_DOUBLE), s, + (uint8_t *)&o->n, sp, 0); + /* Numbers are NOT canonicalized here! Beware of uninitialized data. */ + lj_assertCTS(tvisnum(o), "non-canonical NaN passed"); + } + } else { + uint32_t b = s->size == 1 ? (*sp != 0) : (*(int *)sp != 0); + setboolV(o, b); + setboolV(&cts->g->tmptv2, b); /* Remember for trace recorder. */ + } + return 0; + } else if (ctype_isrefarray(sinfo) || ctype_isstruct(sinfo)) { + /* Create reference. */ + setcdataV(cts->L, o, lj_cdata_newref(cts, sp, sid)); + return 1; /* Need GC step. */ + } else { + GCcdata *cd; + CTSize sz; + copyval: /* Copy value. */ + sz = s->size; + lj_assertCTS(sz != CTSIZE_INVALID, "value copy with invalid size"); + /* Attributes are stripped, qualifiers are kept (but mostly ignored). */ + cd = lj_cdata_new(cts, ctype_typeid(cts, s), sz); + setcdataV(cts->L, o, cd); + memcpy(cdataptr(cd), sp, sz); + return 1; /* Need GC step. */ + } +} + +/* Convert bitfield to TValue. */ +int lj_cconv_tv_bf(CTState *cts, CType *s, TValue *o, uint8_t *sp) +{ + CTInfo info = s->info; + CTSize pos, bsz; + uint32_t val; + lj_assertCTS(ctype_isbitfield(info), "bitfield expected"); + /* NYI: packed bitfields may cause misaligned reads. */ + switch (ctype_bitcsz(info)) { + case 4: val = *(uint32_t *)sp; break; + case 2: val = *(uint16_t *)sp; break; + case 1: val = *(uint8_t *)sp; break; + default: + lj_assertCTS(0, "bad bitfield container size %d", ctype_bitcsz(info)); + val = 0; + break; + } + /* Check if a packed bitfield crosses a container boundary. */ + pos = ctype_bitpos(info); + bsz = ctype_bitbsz(info); + lj_assertCTS(pos < 8*ctype_bitcsz(info), "bad bitfield position"); + lj_assertCTS(bsz > 0 && bsz <= 8*ctype_bitcsz(info), "bad bitfield size"); + if (pos + bsz > 8*ctype_bitcsz(info)) + lj_err_caller(cts->L, LJ_ERR_FFI_NYIPACKBIT); + if (!(info & CTF_BOOL)) { + CTSize shift = 32 - bsz; + if (!(info & CTF_UNSIGNED)) { + setintV(o, (int32_t)(val << (shift-pos)) >> shift); + } else { + val = (val << (shift-pos)) >> shift; + if (!LJ_DUALNUM || (int32_t)val < 0) + setnumV(o, (lua_Number)(uint32_t)val); + else + setintV(o, (int32_t)val); + } + } else { + uint32_t b = (val >> pos) & 1; + lj_assertCTS(bsz == 1, "bad bool bitfield size"); + setboolV(o, b); + setboolV(&cts->g->tmptv2, b); /* Remember for trace recorder. */ + } + return 0; /* No GC step needed. */ +} + +/* -- TValue to C type conversion ----------------------------------------- */ + +/* Convert table to array. */ +static void cconv_array_tab(CTState *cts, CType *d, + uint8_t *dp, GCtab *t, CTInfo flags) +{ + int32_t i; + CType *dc = ctype_rawchild(cts, d); /* Array element type. */ + CTSize size = d->size, esize = dc->size, ofs = 0; + for (i = 0; ; i++) { + TValue *tv = (TValue *)lj_tab_getint(t, i); + if (!tv || tvisnil(tv)) { + if (i == 0) continue; /* Try again for 1-based tables. */ + break; /* Stop at first nil. */ + } + if (ofs >= size) + cconv_err_initov(cts, d); + lj_cconv_ct_tv(cts, dc, dp + ofs, tv, flags); + ofs += esize; + } + if (size != CTSIZE_INVALID) { /* Only fill up arrays with known size. */ + if (ofs == esize) { /* Replicate a single element. */ + for (; ofs < size; ofs += esize) memcpy(dp + ofs, dp, esize); + } else { /* Otherwise fill the remainder with zero. */ + memset(dp + ofs, 0, size - ofs); + } + } +} + +/* Convert table to sub-struct/union. */ +static void cconv_substruct_tab(CTState *cts, CType *d, uint8_t *dp, + GCtab *t, int32_t *ip, CTInfo flags) +{ + CTypeID id = d->sib; + while (id) { + CType *df = ctype_get(cts, id); + id = df->sib; + if (ctype_isfield(df->info) || ctype_isbitfield(df->info)) { + TValue *tv; + int32_t i = *ip, iz = i; + if (!gcref(df->name)) continue; /* Ignore unnamed fields. */ + if (i >= 0) { + retry: + tv = (TValue *)lj_tab_getint(t, i); + if (!tv || tvisnil(tv)) { + if (i == 0) { i = 1; goto retry; } /* 1-based tables. */ + if (iz == 0) { *ip = i = -1; goto tryname; } /* Init named fields. */ + break; /* Stop at first nil. */ + } + *ip = i + 1; + } else { + tryname: + tv = (TValue *)lj_tab_getstr(t, gco2str(gcref(df->name))); + if (!tv || tvisnil(tv)) continue; + } + if (ctype_isfield(df->info)) + lj_cconv_ct_tv(cts, ctype_rawchild(cts, df), dp+df->size, tv, flags); + else + lj_cconv_bf_tv(cts, df, dp+df->size, tv); + if ((d->info & CTF_UNION)) break; + } else if (ctype_isxattrib(df->info, CTA_SUBTYPE)) { + cconv_substruct_tab(cts, ctype_rawchild(cts, df), + dp+df->size, t, ip, flags); + } /* Ignore all other entries in the chain. */ + } +} + +/* Convert table to struct/union. */ +static void cconv_struct_tab(CTState *cts, CType *d, + uint8_t *dp, GCtab *t, CTInfo flags) +{ + int32_t i = 0; + memset(dp, 0, d->size); /* Much simpler to clear the struct first. */ + cconv_substruct_tab(cts, d, dp, t, &i, flags); +} + +/* Convert TValue to C type. Caveat: expects to get the raw CType! */ +void lj_cconv_ct_tv(CTState *cts, CType *d, + uint8_t *dp, TValue *o, CTInfo flags) +{ + CTypeID sid = CTID_P_VOID; + CType *s; + void *tmpptr; + uint8_t tmpbool, *sp = (uint8_t *)&tmpptr; + if (LJ_LIKELY(tvisint(o))) { + sp = (uint8_t *)&o->i; + sid = CTID_INT32; + flags |= CCF_FROMTV; + } else if (LJ_LIKELY(tvisnum(o))) { + sp = (uint8_t *)&o->n; + sid = CTID_DOUBLE; + flags |= CCF_FROMTV; + } else if (tviscdata(o)) { + sp = cdataptr(cdataV(o)); + sid = cdataV(o)->ctypeid; + s = ctype_get(cts, sid); + if (ctype_isref(s->info)) { /* Resolve reference for value. */ + lj_assertCTS(s->size == CTSIZE_PTR, "ref is not pointer-sized"); + sp = *(void **)sp; + sid = ctype_cid(s->info); + } + s = ctype_raw(cts, sid); + if (ctype_isfunc(s->info)) { + CTypeID did = ctype_typeid(cts, d); + sid = lj_ctype_intern(cts, CTINFO(CT_PTR, CTALIGN_PTR|sid), CTSIZE_PTR); + d = ctype_get(cts, did); /* cts->tab may have been reallocated. */ + } else { + if (ctype_isenum(s->info)) s = ctype_child(cts, s); + goto doconv; + } + } else if (tvisstr(o)) { + GCstr *str = strV(o); + if (ctype_isenum(d->info)) { /* Match string against enum constant. */ + CTSize ofs; + CType *cct = lj_ctype_getfield(cts, d, str, &ofs); + if (!cct || !ctype_isconstval(cct->info)) + goto err_conv; + lj_assertCTS(d->size == 4, "only 32 bit enum supported"); /* NYI */ + sp = (uint8_t *)&cct->size; + sid = ctype_cid(cct->info); + } else if (ctype_isrefarray(d->info)) { /* Copy string to array. */ + CType *dc = ctype_rawchild(cts, d); + CTSize sz = str->len+1; + if (!ctype_isinteger(dc->info) || dc->size != 1) + goto err_conv; + if (d->size != 0 && d->size < sz) + sz = d->size; + memcpy(dp, strdata(str), sz); + return; + } else { /* Otherwise pass it as a const char[]. */ + sp = (uint8_t *)strdata(str); + sid = CTID_A_CCHAR; + flags |= CCF_FROMTV; + } + } else if (tvistab(o)) { + if (ctype_isarray(d->info)) { + cconv_array_tab(cts, d, dp, tabV(o), flags); + return; + } else if (ctype_isstruct(d->info)) { + cconv_struct_tab(cts, d, dp, tabV(o), flags); + return; + } else { + goto err_conv; + } + } else if (tvisbool(o)) { + tmpbool = boolV(o); + sp = &tmpbool; + sid = CTID_BOOL; + } else if (tvisnil(o)) { + tmpptr = (void *)0; + flags |= CCF_FROMTV; + } else if (tvisudata(o)) { + GCudata *ud = udataV(o); + tmpptr = uddata(ud); + if (ud->udtype == UDTYPE_IO_FILE) + tmpptr = *(void **)tmpptr; + else if (ud->udtype == UDTYPE_BUFFER) + tmpptr = ((SBufExt *)tmpptr)->r; + } else if (tvislightud(o)) { + tmpptr = lightudV(cts->g, o); + } else if (tvisfunc(o)) { + void *p = lj_ccallback_new(cts, d, funcV(o)); + if (p) { + *(void **)dp = p; + return; + } + goto err_conv; + } else { + err_conv: + cconv_err_convtv(cts, d, o, flags); + } + s = ctype_get(cts, sid); +doconv: + if (ctype_isenum(d->info)) d = ctype_child(cts, d); + lj_cconv_ct_ct(cts, d, s, dp, sp, flags); +} + +/* Convert TValue to bitfield. */ +void lj_cconv_bf_tv(CTState *cts, CType *d, uint8_t *dp, TValue *o) +{ + CTInfo info = d->info; + CTSize pos, bsz; + uint32_t val, mask; + lj_assertCTS(ctype_isbitfield(info), "bitfield expected"); + if ((info & CTF_BOOL)) { + uint8_t tmpbool; + lj_assertCTS(ctype_bitbsz(info) == 1, "bad bool bitfield size"); + lj_cconv_ct_tv(cts, ctype_get(cts, CTID_BOOL), &tmpbool, o, 0); + val = tmpbool; + } else { + CTypeID did = (info & CTF_UNSIGNED) ? CTID_UINT32 : CTID_INT32; + lj_cconv_ct_tv(cts, ctype_get(cts, did), (uint8_t *)&val, o, 0); + } + pos = ctype_bitpos(info); + bsz = ctype_bitbsz(info); + lj_assertCTS(pos < 8*ctype_bitcsz(info), "bad bitfield position"); + lj_assertCTS(bsz > 0 && bsz <= 8*ctype_bitcsz(info), "bad bitfield size"); + /* Check if a packed bitfield crosses a container boundary. */ + if (pos + bsz > 8*ctype_bitcsz(info)) + lj_err_caller(cts->L, LJ_ERR_FFI_NYIPACKBIT); + mask = ((1u << bsz) - 1u) << pos; + val = (val << pos) & mask; + /* NYI: packed bitfields may cause misaligned reads/writes. */ + switch (ctype_bitcsz(info)) { + case 4: *(uint32_t *)dp = (*(uint32_t *)dp & ~mask) | (uint32_t)val; break; + case 2: *(uint16_t *)dp = (*(uint16_t *)dp & ~mask) | (uint16_t)val; break; + case 1: *(uint8_t *)dp = (*(uint8_t *)dp & ~mask) | (uint8_t)val; break; + default: + lj_assertCTS(0, "bad bitfield container size %d", ctype_bitcsz(info)); + break; + } +} + +/* -- Initialize C type with TValues -------------------------------------- */ + +/* Initialize an array with TValues. */ +static void cconv_array_init(CTState *cts, CType *d, CTSize sz, uint8_t *dp, + TValue *o, MSize len) +{ + CType *dc = ctype_rawchild(cts, d); /* Array element type. */ + CTSize ofs, esize = dc->size; + MSize i; + if (len*esize > sz) + cconv_err_initov(cts, d); + for (i = 0, ofs = 0; i < len; i++, ofs += esize) + lj_cconv_ct_tv(cts, dc, dp + ofs, o + i, 0); + if (ofs == esize) { /* Replicate a single element. */ + for (; ofs < sz; ofs += esize) memcpy(dp + ofs, dp, esize); + } else { /* Otherwise fill the remainder with zero. */ + memset(dp + ofs, 0, sz - ofs); + } +} + +/* Initialize a sub-struct/union with TValues. */ +static void cconv_substruct_init(CTState *cts, CType *d, uint8_t *dp, + TValue *o, MSize len, MSize *ip) +{ + CTypeID id = d->sib; + while (id) { + CType *df = ctype_get(cts, id); + id = df->sib; + if (ctype_isfield(df->info) || ctype_isbitfield(df->info)) { + MSize i = *ip; + if (!gcref(df->name)) continue; /* Ignore unnamed fields. */ + if (i >= len) break; + *ip = i + 1; + if (ctype_isfield(df->info)) + lj_cconv_ct_tv(cts, ctype_rawchild(cts, df), dp+df->size, o + i, 0); + else + lj_cconv_bf_tv(cts, df, dp+df->size, o + i); + if ((d->info & CTF_UNION)) break; + } else if (ctype_isxattrib(df->info, CTA_SUBTYPE)) { + cconv_substruct_init(cts, ctype_rawchild(cts, df), + dp+df->size, o, len, ip); + if ((d->info & CTF_UNION)) break; + } /* Ignore all other entries in the chain. */ + } +} + +/* Initialize a struct/union with TValues. */ +static void cconv_struct_init(CTState *cts, CType *d, CTSize sz, uint8_t *dp, + TValue *o, MSize len) +{ + MSize i = 0; + memset(dp, 0, sz); /* Much simpler to clear the struct first. */ + cconv_substruct_init(cts, d, dp, o, len, &i); + if (i < len) + cconv_err_initov(cts, d); +} + +/* Check whether to use a multi-value initializer. +** This is true if an aggregate is to be initialized with a value. +** Valarrays are treated as values here so ct_tv handles (V|C, I|F). +*/ +int lj_cconv_multi_init(CTState *cts, CType *d, TValue *o) +{ + if (!(ctype_isrefarray(d->info) || ctype_isstruct(d->info))) + return 0; /* Destination is not an aggregate. */ + if (tvistab(o) || (tvisstr(o) && !ctype_isstruct(d->info))) + return 0; /* Initializer is not a value. */ + if (tviscdata(o) && lj_ctype_rawref(cts, cdataV(o)->ctypeid) == d) + return 0; /* Source and destination are identical aggregates. */ + return 1; /* Otherwise the initializer is a value. */ +} + +/* Initialize C type with TValues. Caveat: expects to get the raw CType! */ +void lj_cconv_ct_init(CTState *cts, CType *d, CTSize sz, + uint8_t *dp, TValue *o, MSize len) +{ + if (len == 0) + memset(dp, 0, sz); + else if (len == 1 && !lj_cconv_multi_init(cts, d, o)) + lj_cconv_ct_tv(cts, d, dp, o, 0); + else if (ctype_isarray(d->info)) /* Also handles valarray init with len>1. */ + cconv_array_init(cts, d, sz, dp, o, len); + else if (ctype_isstruct(d->info)) + cconv_struct_init(cts, d, sz, dp, o, len); + else + cconv_err_initov(cts, d); +} + +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_cconv.h b/fluent-bit/lib/luajit-3065c9/src/lj_cconv.h new file mode 100644 index 00000000..45b0ca1e --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_cconv.h @@ -0,0 +1,71 @@ +/* +** C type conversions. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#ifndef _LJ_CCONV_H +#define _LJ_CCONV_H + +#include "lj_obj.h" +#include "lj_ctype.h" + +#if LJ_HASFFI + +/* Compressed C type index. ORDER CCX. */ +enum { + CCX_B, /* Bool. */ + CCX_I, /* Integer. */ + CCX_F, /* Floating-point number. */ + CCX_C, /* Complex. */ + CCX_V, /* Vector. */ + CCX_P, /* Pointer. */ + CCX_A, /* Refarray. */ + CCX_S /* Struct/union. */ +}; + +/* Convert C type info to compressed C type index. ORDER CT. ORDER CCX. */ +static LJ_AINLINE uint32_t cconv_idx(CTInfo info) +{ + uint32_t idx = ((info >> 26) & 15u); /* Dispatch bits. */ + lj_assertX(ctype_type(info) <= CT_MAYCONVERT, + "cannot convert ctype %08x", info); +#if LJ_64 + idx = ((uint32_t)(U64x(f436fff5,fff7f021) >> 4*idx) & 15u); +#else + idx = (((idx < 8 ? 0xfff7f021u : 0xf436fff5) >> 4*(idx & 7u)) & 15u); +#endif + lj_assertX(idx < 8, "cannot convert ctype %08x", info); + return idx; +} + +#define cconv_idx2(dinfo, sinfo) \ + ((cconv_idx((dinfo)) << 3) + cconv_idx((sinfo))) + +#define CCX(dst, src) ((CCX_##dst << 3) + CCX_##src) + +/* Conversion flags. */ +#define CCF_CAST 0x00000001u +#define CCF_FROMTV 0x00000002u +#define CCF_SAME 0x00000004u +#define CCF_IGNQUAL 0x00000008u + +#define CCF_ARG_SHIFT 8 +#define CCF_ARG(n) ((n) << CCF_ARG_SHIFT) +#define CCF_GETARG(f) ((f) >> CCF_ARG_SHIFT) + +LJ_FUNC int lj_cconv_compatptr(CTState *cts, CType *d, CType *s, CTInfo flags); +LJ_FUNC void lj_cconv_ct_ct(CTState *cts, CType *d, CType *s, + uint8_t *dp, uint8_t *sp, CTInfo flags); +LJ_FUNC int lj_cconv_tv_ct(CTState *cts, CType *s, CTypeID sid, + TValue *o, uint8_t *sp); +LJ_FUNC int lj_cconv_tv_bf(CTState *cts, CType *s, TValue *o, uint8_t *sp); +LJ_FUNC void lj_cconv_ct_tv(CTState *cts, CType *d, + uint8_t *dp, TValue *o, CTInfo flags); +LJ_FUNC void lj_cconv_bf_tv(CTState *cts, CType *d, uint8_t *dp, TValue *o); +LJ_FUNC int lj_cconv_multi_init(CTState *cts, CType *d, TValue *o); +LJ_FUNC void lj_cconv_ct_init(CTState *cts, CType *d, CTSize sz, + uint8_t *dp, TValue *o, MSize len); + +#endif + +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_cdata.c b/fluent-bit/lib/luajit-3065c9/src/lj_cdata.c new file mode 100644 index 00000000..01a74f5d --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_cdata.c @@ -0,0 +1,304 @@ +/* +** C data management. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#include "lj_obj.h" + +#if LJ_HASFFI + +#include "lj_gc.h" +#include "lj_err.h" +#include "lj_tab.h" +#include "lj_ctype.h" +#include "lj_cconv.h" +#include "lj_cdata.h" + +/* -- C data allocation --------------------------------------------------- */ + +/* Allocate a new C data object holding a reference to another object. */ +GCcdata *lj_cdata_newref(CTState *cts, const void *p, CTypeID id) +{ + CTypeID refid = lj_ctype_intern(cts, CTINFO_REF(id), CTSIZE_PTR); + GCcdata *cd = lj_cdata_new(cts, refid, CTSIZE_PTR); + *(const void **)cdataptr(cd) = p; + return cd; +} + +/* Allocate variable-sized or specially aligned C data object. */ +GCcdata *lj_cdata_newv(lua_State *L, CTypeID id, CTSize sz, CTSize align) +{ + global_State *g; + MSize extra = sizeof(GCcdataVar) + sizeof(GCcdata) + + (align > CT_MEMALIGN ? (1u<offset = (uint16_t)((char *)cd - p); + cdatav(cd)->extra = extra; + cdatav(cd)->len = sz; + g = G(L); + setgcrefr(cd->nextgc, g->gc.root); + setgcref(g->gc.root, obj2gco(cd)); + newwhite(g, obj2gco(cd)); + cd->marked |= 0x80; + cd->gct = ~LJ_TCDATA; + cd->ctypeid = id; + return cd; +} + +/* Allocate arbitrary C data object. */ +GCcdata *lj_cdata_newx(CTState *cts, CTypeID id, CTSize sz, CTInfo info) +{ + if (!(info & CTF_VLA) && ctype_align(info) <= CT_MEMALIGN) + return lj_cdata_new(cts, id, sz); + else + return lj_cdata_newv(cts->L, id, sz, ctype_align(info)); +} + +/* Free a C data object. */ +void LJ_FASTCALL lj_cdata_free(global_State *g, GCcdata *cd) +{ + if (LJ_UNLIKELY(cd->marked & LJ_GC_CDATA_FIN)) { + GCobj *root; + makewhite(g, obj2gco(cd)); + markfinalized(obj2gco(cd)); + if ((root = gcref(g->gc.mmudata)) != NULL) { + setgcrefr(cd->nextgc, root->gch.nextgc); + setgcref(root->gch.nextgc, obj2gco(cd)); + setgcref(g->gc.mmudata, obj2gco(cd)); + } else { + setgcref(cd->nextgc, obj2gco(cd)); + setgcref(g->gc.mmudata, obj2gco(cd)); + } + } else if (LJ_LIKELY(!cdataisv(cd))) { + CType *ct = ctype_raw(ctype_ctsG(g), cd->ctypeid); + CTSize sz = ctype_hassize(ct->info) ? ct->size : CTSIZE_PTR; + lj_assertG(ctype_hassize(ct->info) || ctype_isfunc(ct->info) || + ctype_isextern(ct->info), "free of ctype without a size"); + lj_mem_free(g, cd, sizeof(GCcdata) + sz); + } else { + lj_mem_free(g, memcdatav(cd), sizecdatav(cd)); + } +} + +void lj_cdata_setfin(lua_State *L, GCcdata *cd, GCobj *obj, uint32_t it) +{ + GCtab *t = ctype_ctsG(G(L))->finalizer; + if (gcref(t->metatable)) { + /* Add cdata to finalizer table, if still enabled. */ + TValue *tv, tmp; + setcdataV(L, &tmp, cd); + lj_gc_anybarriert(L, t); + tv = lj_tab_set(L, t, &tmp); + if (it == LJ_TNIL) { + setnilV(tv); + cd->marked &= ~LJ_GC_CDATA_FIN; + } else { + setgcV(L, tv, obj, it); + cd->marked |= LJ_GC_CDATA_FIN; + } + } +} + +/* -- C data indexing ----------------------------------------------------- */ + +/* Index C data by a TValue. Return CType and pointer. */ +CType *lj_cdata_index(CTState *cts, GCcdata *cd, cTValue *key, uint8_t **pp, + CTInfo *qual) +{ + uint8_t *p = (uint8_t *)cdataptr(cd); + CType *ct = ctype_get(cts, cd->ctypeid); + ptrdiff_t idx; + + /* Resolve reference for cdata object. */ + if (ctype_isref(ct->info)) { + lj_assertCTS(ct->size == CTSIZE_PTR, "ref is not pointer-sized"); + p = *(uint8_t **)p; + ct = ctype_child(cts, ct); + } + +collect_attrib: + /* Skip attributes and collect qualifiers. */ + while (ctype_isattrib(ct->info)) { + if (ctype_attrib(ct->info) == CTA_QUAL) *qual |= ct->size; + ct = ctype_child(cts, ct); + } + /* Interning rejects refs to refs. */ + lj_assertCTS(!ctype_isref(ct->info), "bad ref of ref"); + + if (tvisint(key)) { + idx = (ptrdiff_t)intV(key); + goto integer_key; + } else if (tvisnum(key)) { /* Numeric key. */ +#ifdef _MSC_VER + /* Workaround for MSVC bug. */ + volatile +#endif + lua_Number n = numV(key); + idx = LJ_64 ? (ptrdiff_t)n : (ptrdiff_t)lj_num2int(n); + integer_key: + if (ctype_ispointer(ct->info)) { + CTSize sz = lj_ctype_size(cts, ctype_cid(ct->info)); /* Element size. */ + if (sz == CTSIZE_INVALID) + lj_err_caller(cts->L, LJ_ERR_FFI_INVSIZE); + if (ctype_isptr(ct->info)) { + p = (uint8_t *)cdata_getptr(p, ct->size); + } else if ((ct->info & (CTF_VECTOR|CTF_COMPLEX))) { + if ((ct->info & CTF_COMPLEX)) idx &= 1; + *qual |= CTF_CONST; /* Valarray elements are constant. */ + } + *pp = p + idx*(int32_t)sz; + return ct; + } + } else if (tviscdata(key)) { /* Integer cdata key. */ + GCcdata *cdk = cdataV(key); + CType *ctk = ctype_raw(cts, cdk->ctypeid); + if (ctype_isenum(ctk->info)) ctk = ctype_child(cts, ctk); + if (ctype_isinteger(ctk->info)) { + lj_cconv_ct_ct(cts, ctype_get(cts, CTID_INT_PSZ), ctk, + (uint8_t *)&idx, cdataptr(cdk), 0); + goto integer_key; + } + } else if (tvisstr(key)) { /* String key. */ + GCstr *name = strV(key); + if (ctype_isstruct(ct->info)) { + CTSize ofs; + CType *fct = lj_ctype_getfieldq(cts, ct, name, &ofs, qual); + if (fct) { + *pp = p + ofs; + return fct; + } + } else if (ctype_iscomplex(ct->info)) { + if (name->len == 2) { + *qual |= CTF_CONST; /* Complex fields are constant. */ + if (strdata(name)[0] == 'r' && strdata(name)[1] == 'e') { + *pp = p; + return ct; + } else if (strdata(name)[0] == 'i' && strdata(name)[1] == 'm') { + *pp = p + (ct->size >> 1); + return ct; + } + } + } else if (cd->ctypeid == CTID_CTYPEID) { + /* Allow indexing a (pointer to) struct constructor to get constants. */ + CType *sct = ctype_raw(cts, *(CTypeID *)p); + if (ctype_isptr(sct->info)) + sct = ctype_rawchild(cts, sct); + if (ctype_isstruct(sct->info)) { + CTSize ofs; + CType *fct = lj_ctype_getfield(cts, sct, name, &ofs); + if (fct && ctype_isconstval(fct->info)) + return fct; + } + ct = sct; /* Allow resolving metamethods for constructors, too. */ + } + } + if (ctype_isptr(ct->info)) { /* Automatically perform '->'. */ + if (ctype_isstruct(ctype_rawchild(cts, ct)->info)) { + p = (uint8_t *)cdata_getptr(p, ct->size); + ct = ctype_child(cts, ct); + goto collect_attrib; + } + } + *qual |= 1; /* Lookup failed. */ + return ct; /* But return the resolved raw type. */ +} + +/* -- C data getters ------------------------------------------------------ */ + +/* Get constant value and convert to TValue. */ +static void cdata_getconst(CTState *cts, TValue *o, CType *ct) +{ + CType *ctt = ctype_child(cts, ct); + lj_assertCTS(ctype_isinteger(ctt->info) && ctt->size <= 4, + "only 32 bit const supported"); /* NYI */ + /* Constants are already zero-extended/sign-extended to 32 bits. */ + if ((ctt->info & CTF_UNSIGNED) && (int32_t)ct->size < 0) + setnumV(o, (lua_Number)(uint32_t)ct->size); + else + setintV(o, (int32_t)ct->size); +} + +/* Get C data value and convert to TValue. */ +int lj_cdata_get(CTState *cts, CType *s, TValue *o, uint8_t *sp) +{ + CTypeID sid; + + if (ctype_isconstval(s->info)) { + cdata_getconst(cts, o, s); + return 0; /* No GC step needed. */ + } else if (ctype_isbitfield(s->info)) { + return lj_cconv_tv_bf(cts, s, o, sp); + } + + /* Get child type of pointer/array/field. */ + lj_assertCTS(ctype_ispointer(s->info) || ctype_isfield(s->info), + "pointer or field expected"); + sid = ctype_cid(s->info); + s = ctype_get(cts, sid); + + /* Resolve reference for field. */ + if (ctype_isref(s->info)) { + lj_assertCTS(s->size == CTSIZE_PTR, "ref is not pointer-sized"); + sp = *(uint8_t **)sp; + sid = ctype_cid(s->info); + s = ctype_get(cts, sid); + } + + /* Skip attributes. */ + while (ctype_isattrib(s->info)) + s = ctype_child(cts, s); + + return lj_cconv_tv_ct(cts, s, sid, o, sp); +} + +/* -- C data setters ------------------------------------------------------ */ + +/* Convert TValue and set C data value. */ +void lj_cdata_set(CTState *cts, CType *d, uint8_t *dp, TValue *o, CTInfo qual) +{ + if (ctype_isconstval(d->info)) { + goto err_const; + } else if (ctype_isbitfield(d->info)) { + if (((d->info|qual) & CTF_CONST)) goto err_const; + lj_cconv_bf_tv(cts, d, dp, o); + return; + } + + /* Get child type of pointer/array/field. */ + lj_assertCTS(ctype_ispointer(d->info) || ctype_isfield(d->info), + "pointer or field expected"); + d = ctype_child(cts, d); + + /* Resolve reference for field. */ + if (ctype_isref(d->info)) { + lj_assertCTS(d->size == CTSIZE_PTR, "ref is not pointer-sized"); + dp = *(uint8_t **)dp; + d = ctype_child(cts, d); + } + + /* Skip attributes and collect qualifiers. */ + for (;;) { + if (ctype_isattrib(d->info)) { + if (ctype_attrib(d->info) == CTA_QUAL) qual |= d->size; + } else { + break; + } + d = ctype_child(cts, d); + } + + lj_assertCTS(ctype_hassize(d->info), "store to ctype without size"); + lj_assertCTS(!ctype_isvoid(d->info), "store to void type"); + + if (((d->info|qual) & CTF_CONST)) { + err_const: + lj_err_caller(cts->L, LJ_ERR_FFI_WRCONST); + } + + lj_cconv_ct_tv(cts, d, dp, o, 0); +} + +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_cdata.h b/fluent-bit/lib/luajit-3065c9/src/lj_cdata.h new file mode 100644 index 00000000..de52e8aa --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_cdata.h @@ -0,0 +1,79 @@ +/* +** C data management. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#ifndef _LJ_CDATA_H +#define _LJ_CDATA_H + +#include "lj_obj.h" +#include "lj_gc.h" +#include "lj_ctype.h" + +#if LJ_HASFFI + +/* Get C data pointer. */ +static LJ_AINLINE void *cdata_getptr(void *p, CTSize sz) +{ + if (LJ_64 && sz == 4) { /* Support 32 bit pointers on 64 bit targets. */ + return ((void *)(uintptr_t)*(uint32_t *)p); + } else { + lj_assertX(sz == CTSIZE_PTR, "bad pointer size %d", sz); + return *(void **)p; + } +} + +/* Set C data pointer. */ +static LJ_AINLINE void cdata_setptr(void *p, CTSize sz, const void *v) +{ + if (LJ_64 && sz == 4) { /* Support 32 bit pointers on 64 bit targets. */ + *(uint32_t *)p = (uint32_t)(uintptr_t)v; + } else { + lj_assertX(sz == CTSIZE_PTR, "bad pointer size %d", sz); + *(void **)p = (void *)v; + } +} + +/* Allocate fixed-size C data object. */ +static LJ_AINLINE GCcdata *lj_cdata_new(CTState *cts, CTypeID id, CTSize sz) +{ + GCcdata *cd; +#ifdef LUA_USE_ASSERT + CType *ct = ctype_raw(cts, id); + lj_assertCTS((ctype_hassize(ct->info) ? ct->size : CTSIZE_PTR) == sz, + "inconsistent size of fixed-size cdata alloc"); +#endif + cd = (GCcdata *)lj_mem_newgco(cts->L, sizeof(GCcdata) + sz); + cd->gct = ~LJ_TCDATA; + cd->ctypeid = ctype_check(cts, id); + return cd; +} + +/* Variant which works without a valid CTState. */ +static LJ_AINLINE GCcdata *lj_cdata_new_(lua_State *L, CTypeID id, CTSize sz) +{ + GCcdata *cd = (GCcdata *)lj_mem_newgco(L, sizeof(GCcdata) + sz); + cd->gct = ~LJ_TCDATA; + cd->ctypeid = id; + return cd; +} + +LJ_FUNC GCcdata *lj_cdata_newref(CTState *cts, const void *pp, CTypeID id); +LJ_FUNC GCcdata *lj_cdata_newv(lua_State *L, CTypeID id, CTSize sz, + CTSize align); +LJ_FUNC GCcdata *lj_cdata_newx(CTState *cts, CTypeID id, CTSize sz, + CTInfo info); + +LJ_FUNC void LJ_FASTCALL lj_cdata_free(global_State *g, GCcdata *cd); +LJ_FUNC void lj_cdata_setfin(lua_State *L, GCcdata *cd, GCobj *obj, + uint32_t it); + +LJ_FUNC CType *lj_cdata_index(CTState *cts, GCcdata *cd, cTValue *key, + uint8_t **pp, CTInfo *qual); +LJ_FUNC int lj_cdata_get(CTState *cts, CType *s, TValue *o, uint8_t *sp); +LJ_FUNC void lj_cdata_set(CTState *cts, CType *d, uint8_t *dp, TValue *o, + CTInfo qual); + +#endif + +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_char.c b/fluent-bit/lib/luajit-3065c9/src/lj_char.c new file mode 100644 index 00000000..11f23efe --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_char.c @@ -0,0 +1,43 @@ +/* +** Character types. +** Donated to the public domain. +** +** This is intended to replace the problematic libc single-byte NLS functions. +** These just don't make sense anymore with UTF-8 locales becoming the norm +** on POSIX systems. It never worked too well on Windows systems since hardly +** anyone bothered to call setlocale(). +** +** This table is hardcoded for ASCII. Identifiers include the characters +** 128-255, too. This allows for the use of all non-ASCII chars as identifiers +** in the lexer. This is a broad definition, but works well in practice +** for both UTF-8 locales and most single-byte locales (such as ISO-8859-*). +** +** If you really need proper character types for UTF-8 strings, please use +** an add-on library such as slnunicode: http://luaforge.net/projects/sln/ +*/ + +#define lj_char_c +#define LUA_CORE + +#include "lj_char.h" + +LJ_DATADEF const uint8_t lj_char_bits[257] = { + 0, + 1, 1, 1, 1, 1, 1, 1, 1, 1, 3, 3, 3, 3, 3, 1, 1, + 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, + 2, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, + 152,152,152,152,152,152,152,152,152,152, 4, 4, 4, 4, 4, 4, + 4,176,176,176,176,176,176,160,160,160,160,160,160,160,160,160, + 160,160,160,160,160,160,160,160,160,160,160, 4, 4, 4, 4,132, + 4,208,208,208,208,208,208,192,192,192,192,192,192,192,192,192, + 192,192,192,192,192,192,192,192,192,192,192, 4, 4, 4, 4, 1, + 128,128,128,128,128,128,128,128,128,128,128,128,128,128,128,128, + 128,128,128,128,128,128,128,128,128,128,128,128,128,128,128,128, + 128,128,128,128,128,128,128,128,128,128,128,128,128,128,128,128, + 128,128,128,128,128,128,128,128,128,128,128,128,128,128,128,128, + 128,128,128,128,128,128,128,128,128,128,128,128,128,128,128,128, + 128,128,128,128,128,128,128,128,128,128,128,128,128,128,128,128, + 128,128,128,128,128,128,128,128,128,128,128,128,128,128,128,128, + 128,128,128,128,128,128,128,128,128,128,128,128,128,128,128,128 +}; + diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_char.h b/fluent-bit/lib/luajit-3065c9/src/lj_char.h new file mode 100644 index 00000000..c3c86d34 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_char.h @@ -0,0 +1,42 @@ +/* +** Character types. +** Donated to the public domain. +*/ + +#ifndef _LJ_CHAR_H +#define _LJ_CHAR_H + +#include "lj_def.h" + +#define LJ_CHAR_CNTRL 0x01 +#define LJ_CHAR_SPACE 0x02 +#define LJ_CHAR_PUNCT 0x04 +#define LJ_CHAR_DIGIT 0x08 +#define LJ_CHAR_XDIGIT 0x10 +#define LJ_CHAR_UPPER 0x20 +#define LJ_CHAR_LOWER 0x40 +#define LJ_CHAR_IDENT 0x80 +#define LJ_CHAR_ALPHA (LJ_CHAR_LOWER|LJ_CHAR_UPPER) +#define LJ_CHAR_ALNUM (LJ_CHAR_ALPHA|LJ_CHAR_DIGIT) +#define LJ_CHAR_GRAPH (LJ_CHAR_ALNUM|LJ_CHAR_PUNCT) + +/* Only pass -1 or 0..255 to these macros. Never pass a signed char! */ +#define lj_char_isa(c, t) ((lj_char_bits+1)[(c)] & t) +#define lj_char_iscntrl(c) lj_char_isa((c), LJ_CHAR_CNTRL) +#define lj_char_isspace(c) lj_char_isa((c), LJ_CHAR_SPACE) +#define lj_char_ispunct(c) lj_char_isa((c), LJ_CHAR_PUNCT) +#define lj_char_isdigit(c) lj_char_isa((c), LJ_CHAR_DIGIT) +#define lj_char_isxdigit(c) lj_char_isa((c), LJ_CHAR_XDIGIT) +#define lj_char_isupper(c) lj_char_isa((c), LJ_CHAR_UPPER) +#define lj_char_islower(c) lj_char_isa((c), LJ_CHAR_LOWER) +#define lj_char_isident(c) lj_char_isa((c), LJ_CHAR_IDENT) +#define lj_char_isalpha(c) lj_char_isa((c), LJ_CHAR_ALPHA) +#define lj_char_isalnum(c) lj_char_isa((c), LJ_CHAR_ALNUM) +#define lj_char_isgraph(c) lj_char_isa((c), LJ_CHAR_GRAPH) + +#define lj_char_toupper(c) ((c) - (lj_char_islower(c) >> 1)) +#define lj_char_tolower(c) ((c) + lj_char_isupper(c)) + +LJ_DATA const uint8_t lj_char_bits[257]; + +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_clib.c b/fluent-bit/lib/luajit-3065c9/src/lj_clib.c new file mode 100644 index 00000000..57669a14 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_clib.c @@ -0,0 +1,434 @@ +/* +** FFI C library loader. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#include "lj_obj.h" + +#if LJ_HASFFI + +#include "lj_gc.h" +#include "lj_err.h" +#include "lj_tab.h" +#include "lj_str.h" +#include "lj_udata.h" +#include "lj_ctype.h" +#include "lj_cconv.h" +#include "lj_cdata.h" +#include "lj_clib.h" +#include "lj_strfmt.h" + +/* -- OS-specific functions ----------------------------------------------- */ + +#if LJ_TARGET_DLOPEN + +#include +#include + +#if defined(RTLD_DEFAULT) +#define CLIB_DEFHANDLE RTLD_DEFAULT +#elif LJ_TARGET_OSX || LJ_TARGET_BSD +#define CLIB_DEFHANDLE ((void *)(intptr_t)-2) +#else +#define CLIB_DEFHANDLE NULL +#endif + +LJ_NORET LJ_NOINLINE static void clib_error_(lua_State *L) +{ + lj_err_callermsg(L, dlerror()); +} + +#define clib_error(L, fmt, name) clib_error_(L) + +#if LJ_TARGET_CYGWIN +#define CLIB_SOPREFIX "cyg" +#else +#define CLIB_SOPREFIX "lib" +#endif + +#if LJ_TARGET_OSX +#define CLIB_SOEXT "%s.dylib" +#elif LJ_TARGET_CYGWIN +#define CLIB_SOEXT "%s.dll" +#else +#define CLIB_SOEXT "%s.so" +#endif + +static const char *clib_extname(lua_State *L, const char *name) +{ + if (!strchr(name, '/') +#if LJ_TARGET_CYGWIN + && !strchr(name, '\\') +#endif + ) { + if (!strchr(name, '.')) { + name = lj_strfmt_pushf(L, CLIB_SOEXT, name); + L->top--; +#if LJ_TARGET_CYGWIN + } else { + return name; +#endif + } + if (!(name[0] == CLIB_SOPREFIX[0] && name[1] == CLIB_SOPREFIX[1] && + name[2] == CLIB_SOPREFIX[2])) { + name = lj_strfmt_pushf(L, CLIB_SOPREFIX "%s", name); + L->top--; + } + } + return name; +} + +/* Check for a recognized ld script line. */ +static const char *clib_check_lds(lua_State *L, const char *buf) +{ + char *p, *e; + if ((!strncmp(buf, "GROUP", 5) || !strncmp(buf, "INPUT", 5)) && + (p = strchr(buf, '('))) { + while (*++p == ' ') ; + for (e = p; *e && *e != ' ' && *e != ')'; e++) ; + return strdata(lj_str_new(L, p, e-p)); + } + return NULL; +} + +/* Quick and dirty solution to resolve shared library name from ld script. */ +static const char *clib_resolve_lds(lua_State *L, const char *name) +{ + FILE *fp = fopen(name, "r"); + const char *p = NULL; + if (fp) { + char buf[256]; + if (fgets(buf, sizeof(buf), fp)) { + if (!strncmp(buf, "/* GNU ld script", 16)) { /* ld script magic? */ + while (fgets(buf, sizeof(buf), fp)) { /* Check all lines. */ + p = clib_check_lds(L, buf); + if (p) break; + } + } else { /* Otherwise check only the first line. */ + p = clib_check_lds(L, buf); + } + } + fclose(fp); + } + return p; +} + +static void *clib_loadlib(lua_State *L, const char *name, int global) +{ + void *h = dlopen(clib_extname(L, name), + RTLD_LAZY | (global?RTLD_GLOBAL:RTLD_LOCAL)); + if (!h) { + const char *e, *err = dlerror(); + if (err && *err == '/' && (e = strchr(err, ':')) && + (name = clib_resolve_lds(L, strdata(lj_str_new(L, err, e-err))))) { + h = dlopen(name, RTLD_LAZY | (global?RTLD_GLOBAL:RTLD_LOCAL)); + if (h) return h; + err = dlerror(); + } + if (!err) err = "dlopen failed"; + lj_err_callermsg(L, err); + } + return h; +} + +static void clib_unloadlib(CLibrary *cl) +{ + if (cl->handle && cl->handle != CLIB_DEFHANDLE) + dlclose(cl->handle); +} + +static void *clib_getsym(CLibrary *cl, const char *name) +{ + void *p = dlsym(cl->handle, name); + return p; +} + +#elif LJ_TARGET_WINDOWS + +#define WIN32_LEAN_AND_MEAN +#include + +#ifndef GET_MODULE_HANDLE_EX_FLAG_FROM_ADDRESS +#define GET_MODULE_HANDLE_EX_FLAG_FROM_ADDRESS 4 +#define GET_MODULE_HANDLE_EX_FLAG_UNCHANGED_REFCOUNT 2 +BOOL WINAPI GetModuleHandleExA(DWORD, LPCSTR, HMODULE*); +#endif + +#define CLIB_DEFHANDLE ((void *)-1) + +/* Default libraries. */ +enum { + CLIB_HANDLE_EXE, +#if !LJ_TARGET_UWP + CLIB_HANDLE_DLL, + CLIB_HANDLE_CRT, + CLIB_HANDLE_KERNEL32, + CLIB_HANDLE_USER32, + CLIB_HANDLE_GDI32, +#endif + CLIB_HANDLE_MAX +}; + +static void *clib_def_handle[CLIB_HANDLE_MAX]; + +LJ_NORET LJ_NOINLINE static void clib_error(lua_State *L, const char *fmt, + const char *name) +{ + DWORD err = GetLastError(); +#if LJ_TARGET_XBOXONE + wchar_t wbuf[128]; + char buf[128*2]; + if (!FormatMessageW(FORMAT_MESSAGE_IGNORE_INSERTS|FORMAT_MESSAGE_FROM_SYSTEM, + NULL, err, 0, wbuf, sizeof(wbuf)/sizeof(wchar_t), NULL) || + !WideCharToMultiByte(CP_ACP, 0, wbuf, 128, buf, 128*2, NULL, NULL)) +#else + char buf[128]; + if (!FormatMessageA(FORMAT_MESSAGE_IGNORE_INSERTS|FORMAT_MESSAGE_FROM_SYSTEM, + NULL, err, 0, buf, sizeof(buf), NULL)) +#endif + buf[0] = '\0'; + lj_err_callermsg(L, lj_strfmt_pushf(L, fmt, name, buf)); +} + +static int clib_needext(const char *s) +{ + while (*s) { + if (*s == '/' || *s == '\\' || *s == '.') return 0; + s++; + } + return 1; +} + +static const char *clib_extname(lua_State *L, const char *name) +{ + if (clib_needext(name)) { + name = lj_strfmt_pushf(L, "%s.dll", name); + L->top--; + } + return name; +} + +static void *clib_loadlib(lua_State *L, const char *name, int global) +{ + DWORD oldwerr = GetLastError(); + void *h = LJ_WIN_LOADLIBA(clib_extname(L, name)); + if (!h) clib_error(L, "cannot load module " LUA_QS ": %s", name); + SetLastError(oldwerr); + UNUSED(global); + return h; +} + +static void clib_unloadlib(CLibrary *cl) +{ + if (cl->handle == CLIB_DEFHANDLE) { +#if !LJ_TARGET_UWP + MSize i; + for (i = CLIB_HANDLE_KERNEL32; i < CLIB_HANDLE_MAX; i++) { + void *h = clib_def_handle[i]; + if (h) { + clib_def_handle[i] = NULL; + FreeLibrary((HINSTANCE)h); + } + } +#endif + } else if (cl->handle) { + FreeLibrary((HINSTANCE)cl->handle); + } +} + +#if LJ_TARGET_UWP +EXTERN_C IMAGE_DOS_HEADER __ImageBase; +#endif + +static void *clib_getsym(CLibrary *cl, const char *name) +{ + void *p = NULL; + if (cl->handle == CLIB_DEFHANDLE) { /* Search default libraries. */ + MSize i; + for (i = 0; i < CLIB_HANDLE_MAX; i++) { + HINSTANCE h = (HINSTANCE)clib_def_handle[i]; + if (!(void *)h) { /* Resolve default library handles (once). */ +#if LJ_TARGET_UWP + h = (HINSTANCE)&__ImageBase; +#else + switch (i) { + case CLIB_HANDLE_EXE: GetModuleHandleExA(GET_MODULE_HANDLE_EX_FLAG_UNCHANGED_REFCOUNT, NULL, &h); break; + case CLIB_HANDLE_DLL: + GetModuleHandleExA(GET_MODULE_HANDLE_EX_FLAG_FROM_ADDRESS|GET_MODULE_HANDLE_EX_FLAG_UNCHANGED_REFCOUNT, + (const char *)clib_def_handle, &h); + break; + case CLIB_HANDLE_CRT: + GetModuleHandleExA(GET_MODULE_HANDLE_EX_FLAG_FROM_ADDRESS|GET_MODULE_HANDLE_EX_FLAG_UNCHANGED_REFCOUNT, + (const char *)&_fmode, &h); + break; + case CLIB_HANDLE_KERNEL32: h = LJ_WIN_LOADLIBA("kernel32.dll"); break; + case CLIB_HANDLE_USER32: h = LJ_WIN_LOADLIBA("user32.dll"); break; + case CLIB_HANDLE_GDI32: h = LJ_WIN_LOADLIBA("gdi32.dll"); break; + } + if (!h) continue; +#endif + clib_def_handle[i] = (void *)h; + } + p = (void *)GetProcAddress(h, name); + if (p) break; + } + } else { + p = (void *)GetProcAddress((HINSTANCE)cl->handle, name); + } + return p; +} + +#else + +#define CLIB_DEFHANDLE NULL + +LJ_NORET LJ_NOINLINE static void clib_error(lua_State *L, const char *fmt, + const char *name) +{ + lj_err_callermsg(L, lj_strfmt_pushf(L, fmt, name, "no support for this OS")); +} + +static void *clib_loadlib(lua_State *L, const char *name, int global) +{ + lj_err_callermsg(L, "no support for loading dynamic libraries for this OS"); + UNUSED(name); UNUSED(global); + return NULL; +} + +static void clib_unloadlib(CLibrary *cl) +{ + UNUSED(cl); +} + +static void *clib_getsym(CLibrary *cl, const char *name) +{ + UNUSED(cl); UNUSED(name); + return NULL; +} + +#endif + +/* -- C library indexing -------------------------------------------------- */ + +#if LJ_TARGET_X86 && LJ_ABI_WIN +/* Compute argument size for fastcall/stdcall functions. */ +static CTSize clib_func_argsize(CTState *cts, CType *ct) +{ + CTSize n = 0; + while (ct->sib) { + CType *d; + ct = ctype_get(cts, ct->sib); + if (ctype_isfield(ct->info)) { + d = ctype_rawchild(cts, ct); + n += ((d->size + 3) & ~3); + } + } + return n; +} +#endif + +/* Get redirected or mangled external symbol. */ +static const char *clib_extsym(CTState *cts, CType *ct, GCstr *name) +{ + if (ct->sib) { + CType *ctf = ctype_get(cts, ct->sib); + if (ctype_isxattrib(ctf->info, CTA_REDIR)) + return strdata(gco2str(gcref(ctf->name))); + } + return strdata(name); +} + +/* Index a C library by name. */ +TValue *lj_clib_index(lua_State *L, CLibrary *cl, GCstr *name) +{ + TValue *tv = lj_tab_setstr(L, cl->cache, name); + if (LJ_UNLIKELY(tvisnil(tv))) { + CTState *cts = ctype_cts(L); + CType *ct; + CTypeID id = lj_ctype_getname(cts, &ct, name, CLNS_INDEX); + if (!id) + lj_err_callerv(L, LJ_ERR_FFI_NODECL, strdata(name)); + if (ctype_isconstval(ct->info)) { + CType *ctt = ctype_child(cts, ct); + lj_assertCTS(ctype_isinteger(ctt->info) && ctt->size <= 4, + "only 32 bit const supported"); /* NYI */ + if ((ctt->info & CTF_UNSIGNED) && (int32_t)ct->size < 0) + setnumV(tv, (lua_Number)(uint32_t)ct->size); + else + setintV(tv, (int32_t)ct->size); + } else { + const char *sym = clib_extsym(cts, ct, name); +#if LJ_TARGET_WINDOWS + DWORD oldwerr = GetLastError(); +#endif + void *p = clib_getsym(cl, sym); + GCcdata *cd; + lj_assertCTS(ctype_isfunc(ct->info) || ctype_isextern(ct->info), + "unexpected ctype %08x in clib", ct->info); +#if LJ_TARGET_X86 && LJ_ABI_WIN + /* Retry with decorated name for fastcall/stdcall functions. */ + if (!p && ctype_isfunc(ct->info)) { + CTInfo cconv = ctype_cconv(ct->info); + if (cconv == CTCC_FASTCALL || cconv == CTCC_STDCALL) { + CTSize sz = clib_func_argsize(cts, ct); + const char *symd = lj_strfmt_pushf(L, + cconv == CTCC_FASTCALL ? "@%s@%d" : "_%s@%d", + sym, sz); + L->top--; + p = clib_getsym(cl, symd); + } + } +#endif + if (!p) + clib_error(L, "cannot resolve symbol " LUA_QS ": %s", sym); +#if LJ_TARGET_WINDOWS + SetLastError(oldwerr); +#endif + cd = lj_cdata_new(cts, id, CTSIZE_PTR); + *(void **)cdataptr(cd) = p; + setcdataV(L, tv, cd); + lj_gc_anybarriert(L, cl->cache); + } + } + return tv; +} + +/* -- C library management ------------------------------------------------ */ + +/* Create a new CLibrary object and push it on the stack. */ +static CLibrary *clib_new(lua_State *L, GCtab *mt) +{ + GCtab *t = lj_tab_new(L, 0, 0); + GCudata *ud = lj_udata_new(L, sizeof(CLibrary), t); + CLibrary *cl = (CLibrary *)uddata(ud); + cl->cache = t; + ud->udtype = UDTYPE_FFI_CLIB; + /* NOBARRIER: The GCudata is new (marked white). */ + setgcref(ud->metatable, obj2gco(mt)); + setudataV(L, L->top++, ud); + return cl; +} + +/* Load a C library. */ +void lj_clib_load(lua_State *L, GCtab *mt, GCstr *name, int global) +{ + void *handle = clib_loadlib(L, strdata(name), global); + CLibrary *cl = clib_new(L, mt); + cl->handle = handle; +} + +/* Unload a C library. */ +void lj_clib_unload(CLibrary *cl) +{ + clib_unloadlib(cl); + cl->handle = NULL; +} + +/* Create the default C library object. */ +void lj_clib_default(lua_State *L, GCtab *mt) +{ + CLibrary *cl = clib_new(L, mt); + cl->handle = CLIB_DEFHANDLE; +} + +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_clib.h b/fluent-bit/lib/luajit-3065c9/src/lj_clib.h new file mode 100644 index 00000000..4429486e --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_clib.h @@ -0,0 +1,29 @@ +/* +** FFI C library loader. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#ifndef _LJ_CLIB_H +#define _LJ_CLIB_H + +#include "lj_obj.h" + +#if LJ_HASFFI + +/* Namespace for C library indexing. */ +#define CLNS_INDEX ((1u<env. */ +} CLibrary; + +LJ_FUNC TValue *lj_clib_index(lua_State *L, CLibrary *cl, GCstr *name); +LJ_FUNC void lj_clib_load(lua_State *L, GCtab *mt, GCstr *name, int global); +LJ_FUNC void lj_clib_unload(CLibrary *cl); +LJ_FUNC void lj_clib_default(lua_State *L, GCtab *mt); + +#endif + +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_cparse.c b/fluent-bit/lib/luajit-3065c9/src/lj_cparse.c new file mode 100644 index 00000000..7fd83997 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_cparse.c @@ -0,0 +1,1927 @@ +/* +** C declaration parser. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#include "lj_obj.h" + +#if LJ_HASFFI + +#include "lj_gc.h" +#include "lj_err.h" +#include "lj_buf.h" +#include "lj_ctype.h" +#include "lj_cparse.h" +#include "lj_frame.h" +#include "lj_vm.h" +#include "lj_char.h" +#include "lj_strscan.h" +#include "lj_strfmt.h" + +/* +** Important note: this is NOT a validating C parser! This is a minimal +** C declaration parser, solely for use by the LuaJIT FFI. +** +** It ought to return correct results for properly formed C declarations, +** but it may accept some invalid declarations, too (and return nonsense). +** Also, it shows rather generic error messages to avoid unnecessary bloat. +** If in doubt, please check the input against your favorite C compiler. +*/ + +#ifdef LUA_USE_ASSERT +#define lj_assertCP(c, ...) (lj_assertG_(G(cp->L), (c), __VA_ARGS__)) +#else +#define lj_assertCP(c, ...) ((void)cp) +#endif + +/* -- Miscellaneous ------------------------------------------------------- */ + +/* Match string against a C literal. */ +#define cp_str_is(str, k) \ + ((str)->len == sizeof(k)-1 && !memcmp(strdata(str), k, sizeof(k)-1)) + +/* Check string against a linear list of matches. */ +int lj_cparse_case(GCstr *str, const char *match) +{ + MSize len; + int n; + for (n = 0; (len = (MSize)*match++); n++, match += len) { + if (str->len == len && !memcmp(match, strdata(str), len)) + return n; + } + return -1; +} + +/* -- C lexer ------------------------------------------------------------- */ + +/* C lexer token names. */ +static const char *const ctoknames[] = { +#define CTOKSTR(name, str) str, +CTOKDEF(CTOKSTR) +#undef CTOKSTR + NULL +}; + +/* Forward declaration. */ +LJ_NORET static void cp_err(CPState *cp, ErrMsg em); + +static const char *cp_tok2str(CPState *cp, CPToken tok) +{ + lj_assertCP(tok < CTOK_FIRSTDECL, "bad CPToken %d", tok); + if (tok > CTOK_OFS) + return ctoknames[tok-CTOK_OFS-1]; + else if (!lj_char_iscntrl(tok)) + return lj_strfmt_pushf(cp->L, "%c", tok); + else + return lj_strfmt_pushf(cp->L, "char(%d)", tok); +} + +/* End-of-line? */ +static LJ_AINLINE int cp_iseol(CPChar c) +{ + return (c == '\n' || c == '\r'); +} + +/* Peek next raw character. */ +static LJ_AINLINE CPChar cp_rawpeek(CPState *cp) +{ + return (CPChar)(uint8_t)(*cp->p); +} + +static LJ_NOINLINE CPChar cp_get_bs(CPState *cp); + +/* Get next character. */ +static LJ_AINLINE CPChar cp_get(CPState *cp) +{ + cp->c = (CPChar)(uint8_t)(*cp->p++); + if (LJ_LIKELY(cp->c != '\\')) return cp->c; + return cp_get_bs(cp); +} + +/* Transparently skip backslash-escaped line breaks. */ +static LJ_NOINLINE CPChar cp_get_bs(CPState *cp) +{ + CPChar c2, c = cp_rawpeek(cp); + if (!cp_iseol(c)) return cp->c; + cp->p++; + c2 = cp_rawpeek(cp); + if (cp_iseol(c2) && c2 != c) cp->p++; + cp->linenumber++; + return cp_get(cp); +} + +/* Save character in buffer. */ +static LJ_AINLINE void cp_save(CPState *cp, CPChar c) +{ + lj_buf_putb(&cp->sb, c); +} + +/* Skip line break. Handles "\n", "\r", "\r\n" or "\n\r". */ +static void cp_newline(CPState *cp) +{ + CPChar c = cp_rawpeek(cp); + if (cp_iseol(c) && c != cp->c) cp->p++; + cp->linenumber++; +} + +LJ_NORET static void cp_errmsg(CPState *cp, CPToken tok, ErrMsg em, ...) +{ + const char *msg, *tokstr; + lua_State *L; + va_list argp; + if (tok == 0) { + tokstr = NULL; + } else if (tok == CTOK_IDENT || tok == CTOK_INTEGER || tok == CTOK_STRING || + tok >= CTOK_FIRSTDECL) { + if (cp->sb.w == cp->sb.b) cp_save(cp, '$'); + cp_save(cp, '\0'); + tokstr = cp->sb.b; + } else { + tokstr = cp_tok2str(cp, tok); + } + L = cp->L; + va_start(argp, em); + msg = lj_strfmt_pushvf(L, err2msg(em), argp); + va_end(argp); + if (tokstr) + msg = lj_strfmt_pushf(L, err2msg(LJ_ERR_XNEAR), msg, tokstr); + if (cp->linenumber > 1) + msg = lj_strfmt_pushf(L, "%s at line %d", msg, cp->linenumber); + lj_err_callermsg(L, msg); +} + +LJ_NORET LJ_NOINLINE static void cp_err_token(CPState *cp, CPToken tok) +{ + cp_errmsg(cp, cp->tok, LJ_ERR_XTOKEN, cp_tok2str(cp, tok)); +} + +LJ_NORET LJ_NOINLINE static void cp_err_badidx(CPState *cp, CType *ct) +{ + GCstr *s = lj_ctype_repr(cp->cts->L, ctype_typeid(cp->cts, ct), NULL); + cp_errmsg(cp, 0, LJ_ERR_FFI_BADIDX, strdata(s)); +} + +LJ_NORET LJ_NOINLINE static void cp_err(CPState *cp, ErrMsg em) +{ + cp_errmsg(cp, 0, em); +} + +/* -- Main lexical scanner ------------------------------------------------ */ + +/* Parse number literal. Only handles int32_t/uint32_t right now. */ +static CPToken cp_number(CPState *cp) +{ + StrScanFmt fmt; + TValue o; + do { cp_save(cp, cp->c); } while (lj_char_isident(cp_get(cp))); + cp_save(cp, '\0'); + fmt = lj_strscan_scan((const uint8_t *)(cp->sb.b), sbuflen(&cp->sb)-1, + &o, STRSCAN_OPT_C); + if (fmt == STRSCAN_INT) cp->val.id = CTID_INT32; + else if (fmt == STRSCAN_U32) cp->val.id = CTID_UINT32; + else if (!(cp->mode & CPARSE_MODE_SKIP)) + cp_errmsg(cp, CTOK_INTEGER, LJ_ERR_XNUMBER); + cp->val.u32 = (uint32_t)o.i; + return CTOK_INTEGER; +} + +/* Parse identifier or keyword. */ +static CPToken cp_ident(CPState *cp) +{ + do { cp_save(cp, cp->c); } while (lj_char_isident(cp_get(cp))); + cp->str = lj_buf_str(cp->L, &cp->sb); + cp->val.id = lj_ctype_getname(cp->cts, &cp->ct, cp->str, cp->tmask); + if (ctype_type(cp->ct->info) == CT_KW) + return ctype_cid(cp->ct->info); + return CTOK_IDENT; +} + +/* Parse parameter. */ +static CPToken cp_param(CPState *cp) +{ + CPChar c = cp_get(cp); + TValue *o = cp->param; + if (lj_char_isident(c) || c == '$') /* Reserve $xyz for future extensions. */ + cp_errmsg(cp, c, LJ_ERR_XSYNTAX); + if (!o || o >= cp->L->top) + cp_err(cp, LJ_ERR_FFI_NUMPARAM); + cp->param = o+1; + if (tvisstr(o)) { + cp->str = strV(o); + cp->val.id = 0; + cp->ct = &cp->cts->tab[0]; + return CTOK_IDENT; + } else if (tvisnumber(o)) { + cp->val.i32 = numberVint(o); + cp->val.id = CTID_INT32; + return CTOK_INTEGER; + } else { + GCcdata *cd; + if (!tviscdata(o)) + lj_err_argtype(cp->L, (int)(o-cp->L->base)+1, "type parameter"); + cd = cdataV(o); + if (cd->ctypeid == CTID_CTYPEID) + cp->val.id = *(CTypeID *)cdataptr(cd); + else + cp->val.id = cd->ctypeid; + return '$'; + } +} + +/* Parse string or character constant. */ +static CPToken cp_string(CPState *cp) +{ + CPChar delim = cp->c; + cp_get(cp); + while (cp->c != delim) { + CPChar c = cp->c; + if (c == '\0') cp_errmsg(cp, CTOK_EOF, LJ_ERR_XSTR); + if (c == '\\') { + c = cp_get(cp); + switch (c) { + case '\0': cp_errmsg(cp, CTOK_EOF, LJ_ERR_XSTR); break; + case 'a': c = '\a'; break; + case 'b': c = '\b'; break; + case 'f': c = '\f'; break; + case 'n': c = '\n'; break; + case 'r': c = '\r'; break; + case 't': c = '\t'; break; + case 'v': c = '\v'; break; + case 'e': c = 27; break; + case 'x': + c = 0; + while (lj_char_isxdigit(cp_get(cp))) + c = (c<<4) + (lj_char_isdigit(cp->c) ? cp->c-'0' : (cp->c&15)+9); + cp_save(cp, (c & 0xff)); + continue; + default: + if (lj_char_isdigit(c)) { + c -= '0'; + if (lj_char_isdigit(cp_get(cp))) { + c = c*8 + (cp->c - '0'); + if (lj_char_isdigit(cp_get(cp))) { + c = c*8 + (cp->c - '0'); + cp_get(cp); + } + } + cp_save(cp, (c & 0xff)); + continue; + } + break; + } + } + cp_save(cp, c); + cp_get(cp); + } + cp_get(cp); + if (delim == '"') { + cp->str = lj_buf_str(cp->L, &cp->sb); + return CTOK_STRING; + } else { + if (sbuflen(&cp->sb) != 1) cp_err_token(cp, '\''); + cp->val.i32 = (int32_t)(char)*cp->sb.b; + cp->val.id = CTID_INT32; + return CTOK_INTEGER; + } +} + +/* Skip C comment. */ +static void cp_comment_c(CPState *cp) +{ + do { + if (cp_get(cp) == '*') { + do { + if (cp_get(cp) == '/') { cp_get(cp); return; } + } while (cp->c == '*'); + } + if (cp_iseol(cp->c)) cp_newline(cp); + } while (cp->c != '\0'); +} + +/* Skip C++ comment. */ +static void cp_comment_cpp(CPState *cp) +{ + while (!cp_iseol(cp_get(cp)) && cp->c != '\0') + ; +} + +/* Lexical scanner for C. Only a minimal subset is implemented. */ +static CPToken cp_next_(CPState *cp) +{ + lj_buf_reset(&cp->sb); + for (;;) { + if (lj_char_isident(cp->c)) + return lj_char_isdigit(cp->c) ? cp_number(cp) : cp_ident(cp); + switch (cp->c) { + case '\n': case '\r': cp_newline(cp); /* fallthrough. */ + case ' ': case '\t': case '\v': case '\f': cp_get(cp); break; + case '"': case '\'': return cp_string(cp); + case '/': + if (cp_get(cp) == '*') cp_comment_c(cp); + else if (cp->c == '/') cp_comment_cpp(cp); + else return '/'; + break; + case '|': + if (cp_get(cp) != '|') return '|'; + cp_get(cp); return CTOK_OROR; + case '&': + if (cp_get(cp) != '&') return '&'; + cp_get(cp); return CTOK_ANDAND; + case '=': + if (cp_get(cp) != '=') return '='; + cp_get(cp); return CTOK_EQ; + case '!': + if (cp_get(cp) != '=') return '!'; + cp_get(cp); return CTOK_NE; + case '<': + if (cp_get(cp) == '=') { cp_get(cp); return CTOK_LE; } + else if (cp->c == '<') { cp_get(cp); return CTOK_SHL; } + return '<'; + case '>': + if (cp_get(cp) == '=') { cp_get(cp); return CTOK_GE; } + else if (cp->c == '>') { cp_get(cp); return CTOK_SHR; } + return '>'; + case '-': + if (cp_get(cp) != '>') return '-'; + cp_get(cp); return CTOK_DEREF; + case '$': + return cp_param(cp); + case '\0': return CTOK_EOF; + default: { CPToken c = cp->c; cp_get(cp); return c; } + } + } +} + +static LJ_NOINLINE CPToken cp_next(CPState *cp) +{ + return (cp->tok = cp_next_(cp)); +} + +/* -- C parser ------------------------------------------------------------ */ + +/* Namespaces for resolving identifiers. */ +#define CPNS_DEFAULT \ + ((1u<linenumber = 1; + cp->depth = 0; + cp->curpack = 0; + cp->packstack[0] = 255; + lj_buf_init(cp->L, &cp->sb); + lj_assertCP(cp->p != NULL, "uninitialized cp->p"); + cp_get(cp); /* Read-ahead first char. */ + cp->tok = 0; + cp->tmask = CPNS_DEFAULT; + cp_next(cp); /* Read-ahead first token. */ +} + +/* Cleanup C parser state. */ +static void cp_cleanup(CPState *cp) +{ + global_State *g = G(cp->L); + lj_buf_free(g, &cp->sb); +} + +/* Check and consume optional token. */ +static int cp_opt(CPState *cp, CPToken tok) +{ + if (cp->tok == tok) { cp_next(cp); return 1; } + return 0; +} + +/* Check and consume token. */ +static void cp_check(CPState *cp, CPToken tok) +{ + if (cp->tok != tok) cp_err_token(cp, tok); + cp_next(cp); +} + +/* Check if the next token may start a type declaration. */ +static int cp_istypedecl(CPState *cp) +{ + if (cp->tok >= CTOK_FIRSTDECL && cp->tok <= CTOK_LASTDECL) return 1; + if (cp->tok == CTOK_IDENT && ctype_istypedef(cp->ct->info)) return 1; + if (cp->tok == '$') return 1; + return 0; +} + +/* -- Constant expression evaluator --------------------------------------- */ + +/* Forward declarations. */ +static void cp_expr_unary(CPState *cp, CPValue *k); +static void cp_expr_sub(CPState *cp, CPValue *k, int pri); + +/* Please note that type handling is very weak here. Most ops simply +** assume integer operands. Accessors are only needed to compute types and +** return synthetic values. The only purpose of the expression evaluator +** is to compute the values of constant expressions one would typically +** find in C header files. And again: this is NOT a validating C parser! +*/ + +/* Parse comma separated expression and return last result. */ +static void cp_expr_comma(CPState *cp, CPValue *k) +{ + do { cp_expr_sub(cp, k, 0); } while (cp_opt(cp, ',')); +} + +/* Parse sizeof/alignof operator. */ +static void cp_expr_sizeof(CPState *cp, CPValue *k, int wantsz) +{ + CTSize sz; + CTInfo info; + if (cp_opt(cp, '(')) { + if (cp_istypedecl(cp)) + k->id = cp_decl_abstract(cp); + else + cp_expr_comma(cp, k); + cp_check(cp, ')'); + } else { + cp_expr_unary(cp, k); + } + info = lj_ctype_info_raw(cp->cts, k->id, &sz); + if (wantsz) { + if (sz != CTSIZE_INVALID) + k->u32 = sz; + else if (k->id != CTID_A_CCHAR) /* Special case for sizeof("string"). */ + cp_err(cp, LJ_ERR_FFI_INVSIZE); + } else { + k->u32 = 1u << ctype_align(info); + } + k->id = CTID_UINT32; /* Really size_t. */ +} + +/* Parse prefix operators. */ +static void cp_expr_prefix(CPState *cp, CPValue *k) +{ + if (cp->tok == CTOK_INTEGER) { + *k = cp->val; cp_next(cp); + } else if (cp_opt(cp, '+')) { + cp_expr_unary(cp, k); /* Nothing to do (well, integer promotion). */ + } else if (cp_opt(cp, '-')) { + cp_expr_unary(cp, k); k->i32 = -k->i32; + } else if (cp_opt(cp, '~')) { + cp_expr_unary(cp, k); k->i32 = ~k->i32; + } else if (cp_opt(cp, '!')) { + cp_expr_unary(cp, k); k->i32 = !k->i32; k->id = CTID_INT32; + } else if (cp_opt(cp, '(')) { + if (cp_istypedecl(cp)) { /* Cast operator. */ + CTypeID id = cp_decl_abstract(cp); + cp_check(cp, ')'); + cp_expr_unary(cp, k); + k->id = id; /* No conversion performed. */ + } else { /* Sub-expression. */ + cp_expr_comma(cp, k); + cp_check(cp, ')'); + } + } else if (cp_opt(cp, '*')) { /* Indirection. */ + CType *ct; + cp_expr_unary(cp, k); + ct = lj_ctype_rawref(cp->cts, k->id); + if (!ctype_ispointer(ct->info)) + cp_err_badidx(cp, ct); + k->u32 = 0; k->id = ctype_cid(ct->info); + } else if (cp_opt(cp, '&')) { /* Address operator. */ + cp_expr_unary(cp, k); + k->id = lj_ctype_intern(cp->cts, CTINFO(CT_PTR, CTALIGN_PTR+k->id), + CTSIZE_PTR); + } else if (cp_opt(cp, CTOK_SIZEOF)) { + cp_expr_sizeof(cp, k, 1); + } else if (cp_opt(cp, CTOK_ALIGNOF)) { + cp_expr_sizeof(cp, k, 0); + } else if (cp->tok == CTOK_IDENT) { + if (ctype_type(cp->ct->info) == CT_CONSTVAL) { + k->u32 = cp->ct->size; k->id = ctype_cid(cp->ct->info); + } else if (ctype_type(cp->ct->info) == CT_EXTERN) { + k->u32 = cp->val.id; k->id = ctype_cid(cp->ct->info); + } else if (ctype_type(cp->ct->info) == CT_FUNC) { + k->u32 = cp->val.id; k->id = cp->val.id; + } else { + goto err_expr; + } + cp_next(cp); + } else if (cp->tok == CTOK_STRING) { + CTSize sz = cp->str->len; + while (cp_next(cp) == CTOK_STRING) + sz += cp->str->len; + k->u32 = sz + 1; + k->id = CTID_A_CCHAR; + } else { + err_expr: + cp_errmsg(cp, cp->tok, LJ_ERR_XSYMBOL); + } +} + +/* Parse postfix operators. */ +static void cp_expr_postfix(CPState *cp, CPValue *k) +{ + for (;;) { + CType *ct; + if (cp_opt(cp, '[')) { /* Array/pointer index. */ + CPValue k2; + cp_expr_comma(cp, &k2); + ct = lj_ctype_rawref(cp->cts, k->id); + if (!ctype_ispointer(ct->info)) { + ct = lj_ctype_rawref(cp->cts, k2.id); + if (!ctype_ispointer(ct->info)) + cp_err_badidx(cp, ct); + } + cp_check(cp, ']'); + k->u32 = 0; + } else if (cp->tok == '.' || cp->tok == CTOK_DEREF) { /* Struct deref. */ + CTSize ofs; + CType *fct; + ct = lj_ctype_rawref(cp->cts, k->id); + if (cp->tok == CTOK_DEREF) { + if (!ctype_ispointer(ct->info)) + cp_err_badidx(cp, ct); + ct = lj_ctype_rawref(cp->cts, ctype_cid(ct->info)); + } + cp_next(cp); + if (cp->tok != CTOK_IDENT) cp_err_token(cp, CTOK_IDENT); + if (!ctype_isstruct(ct->info) || ct->size == CTSIZE_INVALID || + !(fct = lj_ctype_getfield(cp->cts, ct, cp->str, &ofs)) || + ctype_isbitfield(fct->info)) { + GCstr *s = lj_ctype_repr(cp->cts->L, ctype_typeid(cp->cts, ct), NULL); + cp_errmsg(cp, 0, LJ_ERR_FFI_BADMEMBER, strdata(s), strdata(cp->str)); + } + ct = fct; + k->u32 = ctype_isconstval(ct->info) ? ct->size : 0; + cp_next(cp); + } else { + return; + } + k->id = ctype_cid(ct->info); + } +} + +/* Parse infix operators. */ +static void cp_expr_infix(CPState *cp, CPValue *k, int pri) +{ + CPValue k2; + k2.u32 = 0; k2.id = 0; /* Silence the compiler. */ + for (;;) { + switch (pri) { + case 0: + if (cp_opt(cp, '?')) { + CPValue k3; + cp_expr_comma(cp, &k2); /* Right-associative. */ + cp_check(cp, ':'); + cp_expr_sub(cp, &k3, 0); + k->u32 = k->u32 ? k2.u32 : k3.u32; + k->id = k2.id > k3.id ? k2.id : k3.id; + continue; + } + /* fallthrough */ + case 1: + if (cp_opt(cp, CTOK_OROR)) { + cp_expr_sub(cp, &k2, 2); k->i32 = k->u32 || k2.u32; k->id = CTID_INT32; + continue; + } + /* fallthrough */ + case 2: + if (cp_opt(cp, CTOK_ANDAND)) { + cp_expr_sub(cp, &k2, 3); k->i32 = k->u32 && k2.u32; k->id = CTID_INT32; + continue; + } + /* fallthrough */ + case 3: + if (cp_opt(cp, '|')) { + cp_expr_sub(cp, &k2, 4); k->u32 = k->u32 | k2.u32; goto arith_result; + } + /* fallthrough */ + case 4: + if (cp_opt(cp, '^')) { + cp_expr_sub(cp, &k2, 5); k->u32 = k->u32 ^ k2.u32; goto arith_result; + } + /* fallthrough */ + case 5: + if (cp_opt(cp, '&')) { + cp_expr_sub(cp, &k2, 6); k->u32 = k->u32 & k2.u32; goto arith_result; + } + /* fallthrough */ + case 6: + if (cp_opt(cp, CTOK_EQ)) { + cp_expr_sub(cp, &k2, 7); k->i32 = k->u32 == k2.u32; k->id = CTID_INT32; + continue; + } else if (cp_opt(cp, CTOK_NE)) { + cp_expr_sub(cp, &k2, 7); k->i32 = k->u32 != k2.u32; k->id = CTID_INT32; + continue; + } + /* fallthrough */ + case 7: + if (cp_opt(cp, '<')) { + cp_expr_sub(cp, &k2, 8); + if (k->id == CTID_INT32 && k2.id == CTID_INT32) + k->i32 = k->i32 < k2.i32; + else + k->i32 = k->u32 < k2.u32; + k->id = CTID_INT32; + continue; + } else if (cp_opt(cp, '>')) { + cp_expr_sub(cp, &k2, 8); + if (k->id == CTID_INT32 && k2.id == CTID_INT32) + k->i32 = k->i32 > k2.i32; + else + k->i32 = k->u32 > k2.u32; + k->id = CTID_INT32; + continue; + } else if (cp_opt(cp, CTOK_LE)) { + cp_expr_sub(cp, &k2, 8); + if (k->id == CTID_INT32 && k2.id == CTID_INT32) + k->i32 = k->i32 <= k2.i32; + else + k->i32 = k->u32 <= k2.u32; + k->id = CTID_INT32; + continue; + } else if (cp_opt(cp, CTOK_GE)) { + cp_expr_sub(cp, &k2, 8); + if (k->id == CTID_INT32 && k2.id == CTID_INT32) + k->i32 = k->i32 >= k2.i32; + else + k->i32 = k->u32 >= k2.u32; + k->id = CTID_INT32; + continue; + } + /* fallthrough */ + case 8: + if (cp_opt(cp, CTOK_SHL)) { + cp_expr_sub(cp, &k2, 9); k->u32 = k->u32 << k2.u32; + continue; + } else if (cp_opt(cp, CTOK_SHR)) { + cp_expr_sub(cp, &k2, 9); + if (k->id == CTID_INT32) + k->i32 = k->i32 >> k2.i32; + else + k->u32 = k->u32 >> k2.u32; + continue; + } + /* fallthrough */ + case 9: + if (cp_opt(cp, '+')) { + cp_expr_sub(cp, &k2, 10); k->u32 = k->u32 + k2.u32; + arith_result: + if (k2.id > k->id) k->id = k2.id; /* Trivial promotion to unsigned. */ + continue; + } else if (cp_opt(cp, '-')) { + cp_expr_sub(cp, &k2, 10); k->u32 = k->u32 - k2.u32; goto arith_result; + } + /* fallthrough */ + case 10: + if (cp_opt(cp, '*')) { + cp_expr_unary(cp, &k2); k->u32 = k->u32 * k2.u32; goto arith_result; + } else if (cp_opt(cp, '/')) { + cp_expr_unary(cp, &k2); + if (k2.id > k->id) k->id = k2.id; /* Trivial promotion to unsigned. */ + if (k2.u32 == 0 || + (k->id == CTID_INT32 && k->u32 == 0x80000000u && k2.i32 == -1)) + cp_err(cp, LJ_ERR_BADVAL); + if (k->id == CTID_INT32) + k->i32 = k->i32 / k2.i32; + else + k->u32 = k->u32 / k2.u32; + continue; + } else if (cp_opt(cp, '%')) { + cp_expr_unary(cp, &k2); + if (k2.id > k->id) k->id = k2.id; /* Trivial promotion to unsigned. */ + if (k2.u32 == 0 || + (k->id == CTID_INT32 && k->u32 == 0x80000000u && k2.i32 == -1)) + cp_err(cp, LJ_ERR_BADVAL); + if (k->id == CTID_INT32) + k->i32 = k->i32 % k2.i32; + else + k->u32 = k->u32 % k2.u32; + continue; + } + default: + return; + } + } +} + +/* Parse and evaluate unary expression. */ +static void cp_expr_unary(CPState *cp, CPValue *k) +{ + if (++cp->depth > CPARSE_MAX_DECLDEPTH) cp_err(cp, LJ_ERR_XLEVELS); + cp_expr_prefix(cp, k); + cp_expr_postfix(cp, k); + cp->depth--; +} + +/* Parse and evaluate sub-expression. */ +static void cp_expr_sub(CPState *cp, CPValue *k, int pri) +{ + cp_expr_unary(cp, k); + cp_expr_infix(cp, k, pri); +} + +/* Parse constant integer expression. */ +static void cp_expr_kint(CPState *cp, CPValue *k) +{ + CType *ct; + cp_expr_sub(cp, k, 0); + ct = ctype_raw(cp->cts, k->id); + if (!ctype_isinteger(ct->info)) cp_err(cp, LJ_ERR_BADVAL); +} + +/* Parse (non-negative) size expression. */ +static CTSize cp_expr_ksize(CPState *cp) +{ + CPValue k; + cp_expr_kint(cp, &k); + if (k.u32 >= 0x80000000u) cp_err(cp, LJ_ERR_FFI_INVSIZE); + return k.u32; +} + +/* -- Type declaration stack management ----------------------------------- */ + +/* Add declaration element behind the insertion position. */ +static CPDeclIdx cp_add(CPDecl *decl, CTInfo info, CTSize size) +{ + CPDeclIdx top = decl->top; + if (top >= CPARSE_MAX_DECLSTACK) cp_err(decl->cp, LJ_ERR_XLEVELS); + decl->stack[top].info = info; + decl->stack[top].size = size; + decl->stack[top].sib = 0; + setgcrefnull(decl->stack[top].name); + decl->stack[top].next = decl->stack[decl->pos].next; + decl->stack[decl->pos].next = (CTypeID1)top; + decl->top = top+1; + return top; +} + +/* Push declaration element before the insertion position. */ +static CPDeclIdx cp_push(CPDecl *decl, CTInfo info, CTSize size) +{ + return (decl->pos = cp_add(decl, info, size)); +} + +/* Push or merge attributes. */ +static void cp_push_attributes(CPDecl *decl) +{ + CType *ct = &decl->stack[decl->pos]; + if (ctype_isfunc(ct->info)) { /* Ok to modify in-place. */ +#if LJ_TARGET_X86 + if ((decl->fattr & CTFP_CCONV)) + ct->info = (ct->info & (CTMASK_NUM|CTF_VARARG|CTMASK_CID)) + + (decl->fattr & ~CTMASK_CID); +#endif + } else { + if ((decl->attr & CTFP_ALIGNED) && !(decl->mode & CPARSE_MODE_FIELD)) + cp_push(decl, CTINFO(CT_ATTRIB, CTATTRIB(CTA_ALIGN)), + ctype_align(decl->attr)); + } +} + +/* Push unrolled type to declaration stack and merge qualifiers. */ +static void cp_push_type(CPDecl *decl, CTypeID id) +{ + CType *ct = ctype_get(decl->cp->cts, id); + CTInfo info = ct->info; + CTSize size = ct->size; + switch (ctype_type(info)) { + case CT_STRUCT: case CT_ENUM: + cp_push(decl, CTINFO(CT_TYPEDEF, id), 0); /* Don't copy unique types. */ + if ((decl->attr & CTF_QUAL)) { /* Push unmerged qualifiers. */ + cp_push(decl, CTINFO(CT_ATTRIB, CTATTRIB(CTA_QUAL)), + (decl->attr & CTF_QUAL)); + decl->attr &= ~CTF_QUAL; + } + break; + case CT_ATTRIB: + if (ctype_isxattrib(info, CTA_QUAL)) + decl->attr &= ~size; /* Remove redundant qualifiers. */ + cp_push_type(decl, ctype_cid(info)); /* Unroll. */ + cp_push(decl, info & ~CTMASK_CID, size); /* Copy type. */ + break; + case CT_ARRAY: + if ((ct->info & (CTF_VECTOR|CTF_COMPLEX))) { + info |= (decl->attr & CTF_QUAL); + decl->attr &= ~CTF_QUAL; + } + cp_push_type(decl, ctype_cid(info)); /* Unroll. */ + cp_push(decl, info & ~CTMASK_CID, size); /* Copy type. */ + decl->stack[decl->pos].sib = 1; /* Mark as already checked and sized. */ + /* Note: this is not copied to the ct->sib in the C type table. */ + break; + case CT_FUNC: + /* Copy type, link parameters (shared). */ + decl->stack[cp_push(decl, info, size)].sib = ct->sib; + break; + default: + /* Copy type, merge common qualifiers. */ + cp_push(decl, info|(decl->attr & CTF_QUAL), size); + decl->attr &= ~CTF_QUAL; + break; + } +} + +/* Consume the declaration element chain and intern the C type. */ +static CTypeID cp_decl_intern(CPState *cp, CPDecl *decl) +{ + CTypeID id = 0; + CPDeclIdx idx = 0; + CTSize csize = CTSIZE_INVALID; + CTSize cinfo = 0; + do { + CType *ct = &decl->stack[idx]; + CTInfo info = ct->info; + CTInfo size = ct->size; + /* The cid is already part of info for copies of pointers/functions. */ + idx = ct->next; + if (ctype_istypedef(info)) { + lj_assertCP(id == 0, "typedef not at toplevel"); + id = ctype_cid(info); + /* Always refetch info/size, since struct/enum may have been completed. */ + cinfo = ctype_get(cp->cts, id)->info; + csize = ctype_get(cp->cts, id)->size; + lj_assertCP(ctype_isstruct(cinfo) || ctype_isenum(cinfo), + "typedef of bad type"); + } else if (ctype_isfunc(info)) { /* Intern function. */ + CType *fct; + CTypeID fid; + CTypeID sib; + if (id) { + CType *refct = ctype_raw(cp->cts, id); + /* Reject function or refarray return types. */ + if (ctype_isfunc(refct->info) || ctype_isrefarray(refct->info)) + cp_err(cp, LJ_ERR_FFI_INVTYPE); + } + /* No intervening attributes allowed, skip forward. */ + while (idx) { + CType *ctn = &decl->stack[idx]; + if (!ctype_isattrib(ctn->info)) break; + idx = ctn->next; /* Skip attribute. */ + } + sib = ct->sib; /* Next line may reallocate the C type table. */ + fid = lj_ctype_new(cp->cts, &fct); + csize = CTSIZE_INVALID; + fct->info = cinfo = info + id; + fct->size = size; + fct->sib = sib; + id = fid; + } else if (ctype_isattrib(info)) { + if (ctype_isxattrib(info, CTA_QUAL)) + cinfo |= size; + else if (ctype_isxattrib(info, CTA_ALIGN)) + CTF_INSERT(cinfo, ALIGN, size); + id = lj_ctype_intern(cp->cts, info+id, size); + /* Inherit csize/cinfo from original type. */ + } else { + if (ctype_isnum(info)) { /* Handle mode/vector-size attributes. */ + lj_assertCP(id == 0, "number not at toplevel"); + if (!(info & CTF_BOOL)) { + CTSize msize = ctype_msizeP(decl->attr); + CTSize vsize = ctype_vsizeP(decl->attr); + if (msize && (!(info & CTF_FP) || (msize == 4 || msize == 8))) { + CTSize malign = lj_fls(msize); + if (malign > 4) malign = 4; /* Limit alignment. */ + CTF_INSERT(info, ALIGN, malign); + size = msize; /* Override size via mode. */ + } + if (vsize) { /* Vector size set? */ + CTSize esize = lj_fls(size); + if (vsize >= esize) { + /* Intern the element type first. */ + id = lj_ctype_intern(cp->cts, info, size); + /* Then create a vector (array) with vsize alignment. */ + size = (1u << vsize); + if (vsize > 4) vsize = 4; /* Limit alignment. */ + if (ctype_align(info) > vsize) vsize = ctype_align(info); + info = CTINFO(CT_ARRAY, (info & CTF_QUAL) + CTF_VECTOR + + CTALIGN(vsize)); + } + } + } + } else if (ctype_isptr(info)) { + /* Reject pointer/ref to ref. */ + if (id && ctype_isref(ctype_raw(cp->cts, id)->info)) + cp_err(cp, LJ_ERR_FFI_INVTYPE); + if (ctype_isref(info)) { + info &= ~CTF_VOLATILE; /* Refs are always const, never volatile. */ + /* No intervening attributes allowed, skip forward. */ + while (idx) { + CType *ctn = &decl->stack[idx]; + if (!ctype_isattrib(ctn->info)) break; + idx = ctn->next; /* Skip attribute. */ + } + } + } else if (ctype_isarray(info)) { /* Check for valid array size etc. */ + if (ct->sib == 0) { /* Only check/size arrays not copied by unroll. */ + if (ctype_isref(cinfo)) /* Reject arrays of refs. */ + cp_err(cp, LJ_ERR_FFI_INVTYPE); + /* Reject VLS or unknown-sized types. */ + if (ctype_isvltype(cinfo) || csize == CTSIZE_INVALID) + cp_err(cp, LJ_ERR_FFI_INVSIZE); + /* a[] and a[?] keep their invalid size. */ + if (size != CTSIZE_INVALID) { + uint64_t xsz = (uint64_t)size * csize; + if (xsz >= 0x80000000u) cp_err(cp, LJ_ERR_FFI_INVSIZE); + size = (CTSize)xsz; + } + } + if ((cinfo & CTF_ALIGN) > (info & CTF_ALIGN)) /* Find max. align. */ + info = (info & ~CTF_ALIGN) | (cinfo & CTF_ALIGN); + info |= (cinfo & CTF_QUAL); /* Inherit qual. */ + } else { + lj_assertCP(ctype_isvoid(info), "bad ctype %08x", info); + } + csize = size; + cinfo = info+id; + id = lj_ctype_intern(cp->cts, info+id, size); + } + } while (idx); + return id; +} + +/* -- C declaration parser ------------------------------------------------ */ + +/* Reset declaration state to declaration specifier. */ +static void cp_decl_reset(CPDecl *decl) +{ + decl->pos = decl->specpos; + decl->top = decl->specpos+1; + decl->stack[decl->specpos].next = 0; + decl->attr = decl->specattr; + decl->fattr = decl->specfattr; + decl->name = NULL; + decl->redir = NULL; +} + +/* Parse constant initializer. */ +/* NYI: FP constants and strings as initializers. */ +static CTypeID cp_decl_constinit(CPState *cp, CType **ctp, CTypeID ctypeid) +{ + CType *ctt = ctype_get(cp->cts, ctypeid); + CTInfo info; + CTSize size; + CPValue k; + CTypeID constid; + while (ctype_isattrib(ctt->info)) { /* Skip attributes. */ + ctypeid = ctype_cid(ctt->info); /* Update ID, too. */ + ctt = ctype_get(cp->cts, ctypeid); + } + info = ctt->info; + size = ctt->size; + if (!ctype_isinteger(info) || !(info & CTF_CONST) || size > 4) + cp_err(cp, LJ_ERR_FFI_INVTYPE); + cp_check(cp, '='); + cp_expr_sub(cp, &k, 0); + constid = lj_ctype_new(cp->cts, ctp); + (*ctp)->info = CTINFO(CT_CONSTVAL, CTF_CONST|ctypeid); + k.u32 <<= 8*(4-size); + if ((info & CTF_UNSIGNED)) + k.u32 >>= 8*(4-size); + else + k.u32 = (uint32_t)((int32_t)k.u32 >> 8*(4-size)); + (*ctp)->size = k.u32; + return constid; +} + +/* Parse size in parentheses as part of attribute. */ +static CTSize cp_decl_sizeattr(CPState *cp) +{ + CTSize sz; + uint32_t oldtmask = cp->tmask; + cp->tmask = CPNS_DEFAULT; /* Required for expression evaluator. */ + cp_check(cp, '('); + sz = cp_expr_ksize(cp); + cp->tmask = oldtmask; + cp_check(cp, ')'); + return sz; +} + +/* Parse alignment attribute. */ +static void cp_decl_align(CPState *cp, CPDecl *decl) +{ + CTSize al = 4; /* Unspecified alignment is 16 bytes. */ + if (cp->tok == '(') { + al = cp_decl_sizeattr(cp); + al = al ? lj_fls(al) : 0; + } + CTF_INSERT(decl->attr, ALIGN, al); + decl->attr |= CTFP_ALIGNED; +} + +/* Parse GCC asm("name") redirect. */ +static void cp_decl_asm(CPState *cp, CPDecl *decl) +{ + UNUSED(decl); + cp_next(cp); + cp_check(cp, '('); + if (cp->tok == CTOK_STRING) { + GCstr *str = cp->str; + while (cp_next(cp) == CTOK_STRING) { + lj_strfmt_pushf(cp->L, "%s%s", strdata(str), strdata(cp->str)); + cp->L->top--; + str = strV(cp->L->top); + } + decl->redir = str; + } + cp_check(cp, ')'); +} + +/* Parse GCC __attribute__((mode(...))). */ +static void cp_decl_mode(CPState *cp, CPDecl *decl) +{ + cp_check(cp, '('); + if (cp->tok == CTOK_IDENT) { + const char *s = strdata(cp->str); + CTSize sz = 0, vlen = 0; + if (s[0] == '_' && s[1] == '_') s += 2; + if (*s == 'V') { + s++; + vlen = *s++ - '0'; + if (*s >= '0' && *s <= '9') + vlen = vlen*10 + (*s++ - '0'); + } + switch (*s++) { + case 'Q': sz = 1; break; + case 'H': sz = 2; break; + case 'S': sz = 4; break; + case 'D': sz = 8; break; + case 'T': sz = 16; break; + case 'O': sz = 32; break; + default: goto bad_size; + } + if (*s == 'I' || *s == 'F') { + CTF_INSERT(decl->attr, MSIZEP, sz); + if (vlen) CTF_INSERT(decl->attr, VSIZEP, lj_fls(vlen*sz)); + } + bad_size: + cp_next(cp); + } + cp_check(cp, ')'); +} + +/* Parse GCC __attribute__((...)). */ +static void cp_decl_gccattribute(CPState *cp, CPDecl *decl) +{ + cp_next(cp); + cp_check(cp, '('); + cp_check(cp, '('); + while (cp->tok != ')') { + if (cp->tok == CTOK_IDENT) { + GCstr *attrstr = cp->str; + cp_next(cp); + switch (lj_cparse_case(attrstr, + "\007aligned" "\013__aligned__" + "\006packed" "\012__packed__" + "\004mode" "\010__mode__" + "\013vector_size" "\017__vector_size__" +#if LJ_TARGET_X86 + "\007regparm" "\013__regparm__" + "\005cdecl" "\011__cdecl__" + "\010thiscall" "\014__thiscall__" + "\010fastcall" "\014__fastcall__" + "\007stdcall" "\013__stdcall__" + "\012sseregparm" "\016__sseregparm__" +#endif + )) { + case 0: case 1: /* aligned */ + cp_decl_align(cp, decl); + break; + case 2: case 3: /* packed */ + decl->attr |= CTFP_PACKED; + break; + case 4: case 5: /* mode */ + cp_decl_mode(cp, decl); + break; + case 6: case 7: /* vector_size */ + { + CTSize vsize = cp_decl_sizeattr(cp); + if (vsize) CTF_INSERT(decl->attr, VSIZEP, lj_fls(vsize)); + } + break; +#if LJ_TARGET_X86 + case 8: case 9: /* regparm */ + CTF_INSERT(decl->fattr, REGPARM, cp_decl_sizeattr(cp)); + decl->fattr |= CTFP_CCONV; + break; + case 10: case 11: /* cdecl */ + CTF_INSERT(decl->fattr, CCONV, CTCC_CDECL); + decl->fattr |= CTFP_CCONV; + break; + case 12: case 13: /* thiscall */ + CTF_INSERT(decl->fattr, CCONV, CTCC_THISCALL); + decl->fattr |= CTFP_CCONV; + break; + case 14: case 15: /* fastcall */ + CTF_INSERT(decl->fattr, CCONV, CTCC_FASTCALL); + decl->fattr |= CTFP_CCONV; + break; + case 16: case 17: /* stdcall */ + CTF_INSERT(decl->fattr, CCONV, CTCC_STDCALL); + decl->fattr |= CTFP_CCONV; + break; + case 18: case 19: /* sseregparm */ + decl->fattr |= CTF_SSEREGPARM; + decl->fattr |= CTFP_CCONV; + break; +#endif + default: /* Skip all other attributes. */ + goto skip_attr; + } + } else if (cp->tok >= CTOK_FIRSTDECL) { /* For __attribute((const)) etc. */ + cp_next(cp); + skip_attr: + if (cp_opt(cp, '(')) { + while (cp->tok != ')' && cp->tok != CTOK_EOF) cp_next(cp); + cp_check(cp, ')'); + } + } else { + break; + } + if (!cp_opt(cp, ',')) break; + } + cp_check(cp, ')'); + cp_check(cp, ')'); +} + +/* Parse MSVC __declspec(...). */ +static void cp_decl_msvcattribute(CPState *cp, CPDecl *decl) +{ + cp_next(cp); + cp_check(cp, '('); + while (cp->tok == CTOK_IDENT) { + GCstr *attrstr = cp->str; + cp_next(cp); + if (cp_str_is(attrstr, "align")) { + cp_decl_align(cp, decl); + } else { /* Ignore all other attributes. */ + if (cp_opt(cp, '(')) { + while (cp->tok != ')' && cp->tok != CTOK_EOF) cp_next(cp); + cp_check(cp, ')'); + } + } + } + cp_check(cp, ')'); +} + +/* Parse declaration attributes (and common qualifiers). */ +static void cp_decl_attributes(CPState *cp, CPDecl *decl) +{ + for (;;) { + switch (cp->tok) { + case CTOK_CONST: decl->attr |= CTF_CONST; break; + case CTOK_VOLATILE: decl->attr |= CTF_VOLATILE; break; + case CTOK_RESTRICT: break; /* Ignore. */ + case CTOK_EXTENSION: break; /* Ignore. */ + case CTOK_ATTRIBUTE: cp_decl_gccattribute(cp, decl); continue; + case CTOK_ASM: cp_decl_asm(cp, decl); continue; + case CTOK_DECLSPEC: cp_decl_msvcattribute(cp, decl); continue; + case CTOK_CCDECL: +#if LJ_TARGET_X86 + CTF_INSERT(decl->fattr, CCONV, cp->ct->size); + decl->fattr |= CTFP_CCONV; +#endif + break; + case CTOK_PTRSZ: +#if LJ_64 + CTF_INSERT(decl->attr, MSIZEP, cp->ct->size); +#endif + break; + default: return; + } + cp_next(cp); + } +} + +/* Parse struct/union/enum name. */ +static CTypeID cp_struct_name(CPState *cp, CPDecl *sdecl, CTInfo info) +{ + CTypeID sid; + CType *ct; + cp->tmask = CPNS_STRUCT; + cp_next(cp); + cp_decl_attributes(cp, sdecl); + cp->tmask = CPNS_DEFAULT; + if (cp->tok != '{') { + if (cp->tok != CTOK_IDENT) cp_err_token(cp, CTOK_IDENT); + if (cp->val.id) { /* Name of existing struct/union/enum. */ + sid = cp->val.id; + ct = cp->ct; + if ((ct->info ^ info) & (CTMASK_NUM|CTF_UNION)) /* Wrong type. */ + cp_errmsg(cp, 0, LJ_ERR_FFI_REDEF, strdata(gco2str(gcref(ct->name)))); + } else { /* Create named, incomplete struct/union/enum. */ + if ((cp->mode & CPARSE_MODE_NOIMPLICIT)) + cp_errmsg(cp, 0, LJ_ERR_FFI_BADTAG, strdata(cp->str)); + sid = lj_ctype_new(cp->cts, &ct); + ct->info = info; + ct->size = CTSIZE_INVALID; + ctype_setname(ct, cp->str); + lj_ctype_addname(cp->cts, ct, sid); + } + cp_next(cp); + } else { /* Create anonymous, incomplete struct/union/enum. */ + sid = lj_ctype_new(cp->cts, &ct); + ct->info = info; + ct->size = CTSIZE_INVALID; + } + if (cp->tok == '{') { + if (ct->size != CTSIZE_INVALID || ct->sib) + cp_errmsg(cp, 0, LJ_ERR_FFI_REDEF, strdata(gco2str(gcref(ct->name)))); + ct->sib = 1; /* Indicate the type is currently being defined. */ + } + return sid; +} + +/* Determine field alignment. */ +static CTSize cp_field_align(CPState *cp, CType *ct, CTInfo info) +{ + CTSize align = ctype_align(info); + UNUSED(cp); UNUSED(ct); +#if (LJ_TARGET_X86 && !LJ_ABI_WIN) || (LJ_TARGET_ARM && __APPLE__) + /* The SYSV i386 and iOS ABIs limit alignment of non-vector fields to 2^2. */ + if (align > 2 && !(info & CTFP_ALIGNED)) { + if (ctype_isarray(info) && !(info & CTF_VECTOR)) { + do { + ct = ctype_rawchild(cp->cts, ct); + info = ct->info; + } while (ctype_isarray(info) && !(info & CTF_VECTOR)); + } + if (ctype_isnum(info) || ctype_isenum(info)) + align = 2; + } +#endif + return align; +} + +/* Layout struct/union fields. */ +static void cp_struct_layout(CPState *cp, CTypeID sid, CTInfo sattr) +{ + CTSize bofs = 0, bmaxofs = 0; /* Bit offset and max. bit offset. */ + CTSize maxalign = ctype_align(sattr); + CType *sct = ctype_get(cp->cts, sid); + CTInfo sinfo = sct->info; + CTypeID fieldid = sct->sib; + while (fieldid) { + CType *ct = ctype_get(cp->cts, fieldid); + CTInfo attr = ct->size; /* Field declaration attributes (temp.). */ + + if (ctype_isfield(ct->info) || + (ctype_isxattrib(ct->info, CTA_SUBTYPE) && attr)) { + CTSize align, amask; /* Alignment (pow2) and alignment mask (bits). */ + CTSize sz; + CTInfo info = lj_ctype_info(cp->cts, ctype_cid(ct->info), &sz); + CTSize bsz, csz = 8*sz; /* Field size and container size (in bits). */ + sinfo |= (info & (CTF_QUAL|CTF_VLA)); /* Merge pseudo-qualifiers. */ + + /* Check for size overflow and determine alignment. */ + if (sz >= 0x20000000u || bofs + csz < bofs || (info & CTF_VLA)) { + if (!(sz == CTSIZE_INVALID && ctype_isarray(info) && + !(sinfo & CTF_UNION))) + cp_err(cp, LJ_ERR_FFI_INVSIZE); + csz = sz = 0; /* Treat a[] and a[?] as zero-sized. */ + } + align = cp_field_align(cp, ct, info); + if (((attr|sattr) & CTFP_PACKED) || + ((attr & CTFP_ALIGNED) && ctype_align(attr) > align)) + align = ctype_align(attr); + if (cp->packstack[cp->curpack] < align) + align = cp->packstack[cp->curpack]; + if (align > maxalign) maxalign = align; + amask = (8u << align) - 1; + + bsz = ctype_bitcsz(ct->info); /* Bitfield size (temp.). */ + if (bsz == CTBSZ_FIELD || !ctype_isfield(ct->info)) { + bsz = csz; /* Regular fields or subtypes always fill the container. */ + bofs = (bofs + amask) & ~amask; /* Start new aligned field. */ + ct->size = (bofs >> 3); /* Store field offset. */ + } else { /* Bitfield. */ + if (bsz == 0 || (attr & CTFP_ALIGNED) || + (!((attr|sattr) & CTFP_PACKED) && (bofs & amask) + bsz > csz)) + bofs = (bofs + amask) & ~amask; /* Start new aligned field. */ + + /* Prefer regular field over bitfield. */ + if (bsz == csz && (bofs & amask) == 0) { + ct->info = CTINFO(CT_FIELD, ctype_cid(ct->info)); + ct->size = (bofs >> 3); /* Store field offset. */ + } else { + ct->info = CTINFO(CT_BITFIELD, + (info & (CTF_QUAL|CTF_UNSIGNED|CTF_BOOL)) + + (csz << (CTSHIFT_BITCSZ-3)) + (bsz << CTSHIFT_BITBSZ)); +#if LJ_BE + ct->info += ((csz - (bofs & (csz-1)) - bsz) << CTSHIFT_BITPOS); +#else + ct->info += ((bofs & (csz-1)) << CTSHIFT_BITPOS); +#endif + ct->size = ((bofs & ~(csz-1)) >> 3); /* Store container offset. */ + } + } + + /* Determine next offset or max. offset. */ + if ((sinfo & CTF_UNION)) { + if (bsz > bmaxofs) bmaxofs = bsz; + } else { + bofs += bsz; + } + } /* All other fields in the chain are already set up. */ + + fieldid = ct->sib; + } + + /* Complete struct/union. */ + sct->info = sinfo + CTALIGN(maxalign); + bofs = (sinfo & CTF_UNION) ? bmaxofs : bofs; + maxalign = (8u << maxalign) - 1; + sct->size = (((bofs + maxalign) & ~maxalign) >> 3); +} + +/* Parse struct/union declaration. */ +static CTypeID cp_decl_struct(CPState *cp, CPDecl *sdecl, CTInfo sinfo) +{ + CTypeID sid = cp_struct_name(cp, sdecl, sinfo); + if (cp_opt(cp, '{')) { /* Struct/union definition. */ + CTypeID lastid = sid; + int lastdecl = 0; + while (cp->tok != '}') { + CPDecl decl; + CPscl scl = cp_decl_spec(cp, &decl, CDF_STATIC); + decl.mode = scl ? CPARSE_MODE_DIRECT : + CPARSE_MODE_DIRECT|CPARSE_MODE_ABSTRACT|CPARSE_MODE_FIELD; + + for (;;) { + CTypeID ctypeid; + + if (lastdecl) cp_err_token(cp, '}'); + + /* Parse field declarator. */ + decl.bits = CTSIZE_INVALID; + cp_declarator(cp, &decl); + ctypeid = cp_decl_intern(cp, &decl); + + if ((scl & CDF_STATIC)) { /* Static constant in struct namespace. */ + CType *ct; + CTypeID fieldid = cp_decl_constinit(cp, &ct, ctypeid); + ctype_get(cp->cts, lastid)->sib = fieldid; + lastid = fieldid; + ctype_setname(ct, decl.name); + } else { + CTSize bsz = CTBSZ_FIELD; /* Temp. for layout phase. */ + CType *ct; + CTypeID fieldid = lj_ctype_new(cp->cts, &ct); /* Do this first. */ + CType *tct = ctype_raw(cp->cts, ctypeid); + + if (decl.bits == CTSIZE_INVALID) { /* Regular field. */ + if (ctype_isarray(tct->info) && tct->size == CTSIZE_INVALID) + lastdecl = 1; /* a[] or a[?] must be the last declared field. */ + + /* Accept transparent struct/union/enum. */ + if (!decl.name) { + if (!((ctype_isstruct(tct->info) && !(tct->info & CTF_VLA)) || + ctype_isenum(tct->info))) + cp_err_token(cp, CTOK_IDENT); + ct->info = CTINFO(CT_ATTRIB, CTATTRIB(CTA_SUBTYPE) + ctypeid); + ct->size = ctype_isstruct(tct->info) ? + (decl.attr|0x80000000u) : 0; /* For layout phase. */ + goto add_field; + } + } else { /* Bitfield. */ + bsz = decl.bits; + if (!ctype_isinteger_or_bool(tct->info) || + (bsz == 0 && decl.name) || 8*tct->size > CTBSZ_MAX || + bsz > ((tct->info & CTF_BOOL) ? 1 : 8*tct->size)) + cp_errmsg(cp, ':', LJ_ERR_BADVAL); + } + + /* Create temporary field for layout phase. */ + ct->info = CTINFO(CT_FIELD, ctypeid + (bsz << CTSHIFT_BITCSZ)); + ct->size = decl.attr; + if (decl.name) ctype_setname(ct, decl.name); + + add_field: + ctype_get(cp->cts, lastid)->sib = fieldid; + lastid = fieldid; + } + if (!cp_opt(cp, ',')) break; + cp_decl_reset(&decl); + } + cp_check(cp, ';'); + } + cp_check(cp, '}'); + ctype_get(cp->cts, lastid)->sib = 0; /* Drop sib = 1 for empty structs. */ + cp_decl_attributes(cp, sdecl); /* Layout phase needs postfix attributes. */ + cp_struct_layout(cp, sid, sdecl->attr); + } + return sid; +} + +/* Parse enum declaration. */ +static CTypeID cp_decl_enum(CPState *cp, CPDecl *sdecl) +{ + CTypeID eid = cp_struct_name(cp, sdecl, CTINFO(CT_ENUM, CTID_VOID)); + CTInfo einfo = CTINFO(CT_ENUM, CTALIGN(2) + CTID_UINT32); + CTSize esize = 4; /* Only 32 bit enums are supported. */ + if (cp_opt(cp, '{')) { /* Enum definition. */ + CPValue k; + CTypeID lastid = eid; + k.u32 = 0; + k.id = CTID_INT32; + do { + GCstr *name = cp->str; + if (cp->tok != CTOK_IDENT) cp_err_token(cp, CTOK_IDENT); + if (cp->val.id) cp_errmsg(cp, 0, LJ_ERR_FFI_REDEF, strdata(name)); + cp_next(cp); + if (cp_opt(cp, '=')) { + cp_expr_kint(cp, &k); + if (k.id == CTID_UINT32) { + /* C99 says that enum constants are always (signed) integers. + ** But since unsigned constants like 0x80000000 are quite common, + ** those are left as uint32_t. + */ + if (k.i32 >= 0) k.id = CTID_INT32; + } else { + /* OTOH it's common practice and even mandated by some ABIs + ** that the enum type itself is unsigned, unless there are any + ** negative constants. + */ + k.id = CTID_INT32; + if (k.i32 < 0) einfo = CTINFO(CT_ENUM, CTALIGN(2) + CTID_INT32); + } + } + /* Add named enum constant. */ + { + CType *ct; + CTypeID constid = lj_ctype_new(cp->cts, &ct); + ctype_get(cp->cts, lastid)->sib = constid; + lastid = constid; + ctype_setname(ct, name); + ct->info = CTINFO(CT_CONSTVAL, CTF_CONST|k.id); + ct->size = k.u32++; + if (k.u32 == 0x80000000u) k.id = CTID_UINT32; + lj_ctype_addname(cp->cts, ct, constid); + } + if (!cp_opt(cp, ',')) break; + } while (cp->tok != '}'); /* Trailing ',' is ok. */ + cp_check(cp, '}'); + /* Complete enum. */ + ctype_get(cp->cts, eid)->info = einfo; + ctype_get(cp->cts, eid)->size = esize; + } + return eid; +} + +/* Parse declaration specifiers. */ +static CPscl cp_decl_spec(CPState *cp, CPDecl *decl, CPscl scl) +{ + uint32_t cds = 0, sz = 0; + CTypeID tdef = 0; + + decl->cp = cp; + decl->mode = cp->mode; + decl->name = NULL; + decl->redir = NULL; + decl->attr = 0; + decl->fattr = 0; + decl->pos = decl->top = 0; + decl->stack[0].next = 0; + + for (;;) { /* Parse basic types. */ + cp_decl_attributes(cp, decl); + if (cp->tok >= CTOK_FIRSTDECL && cp->tok <= CTOK_LASTDECLFLAG) { + uint32_t cbit; + if (cp->ct->size) { + if (sz) goto end_decl; + sz = cp->ct->size; + } + cbit = (1u << (cp->tok - CTOK_FIRSTDECL)); + cds = cds | cbit | ((cbit & cds & CDF_LONG) << 1); + if (cp->tok >= CTOK_FIRSTSCL) { + if (!(scl & cbit)) cp_errmsg(cp, cp->tok, LJ_ERR_FFI_BADSCL); + } else if (tdef) { + goto end_decl; + } + cp_next(cp); + continue; + } + if (sz || tdef || + (cds & (CDF_SHORT|CDF_LONG|CDF_SIGNED|CDF_UNSIGNED|CDF_COMPLEX))) + break; + switch (cp->tok) { + case CTOK_STRUCT: + tdef = cp_decl_struct(cp, decl, CTINFO(CT_STRUCT, 0)); + continue; + case CTOK_UNION: + tdef = cp_decl_struct(cp, decl, CTINFO(CT_STRUCT, CTF_UNION)); + continue; + case CTOK_ENUM: + tdef = cp_decl_enum(cp, decl); + continue; + case CTOK_IDENT: + if (ctype_istypedef(cp->ct->info)) { + tdef = ctype_cid(cp->ct->info); /* Get typedef. */ + cp_next(cp); + continue; + } + break; + case '$': + tdef = cp->val.id; + cp_next(cp); + continue; + default: + break; + } + break; + } +end_decl: + + if ((cds & CDF_COMPLEX)) /* Use predefined complex types. */ + tdef = sz == 4 ? CTID_COMPLEX_FLOAT : CTID_COMPLEX_DOUBLE; + + if (tdef) { + cp_push_type(decl, tdef); + } else if ((cds & CDF_VOID)) { + cp_push(decl, CTINFO(CT_VOID, (decl->attr & CTF_QUAL)), CTSIZE_INVALID); + decl->attr &= ~CTF_QUAL; + } else { + /* Determine type info and size. */ + CTInfo info = CTINFO(CT_NUM, (cds & CDF_UNSIGNED) ? CTF_UNSIGNED : 0); + if ((cds & CDF_BOOL)) { + if ((cds & ~(CDF_SCL|CDF_BOOL|CDF_INT|CDF_SIGNED|CDF_UNSIGNED))) + cp_errmsg(cp, 0, LJ_ERR_FFI_INVTYPE); + info |= CTF_BOOL; + if (!(cds & CDF_SIGNED)) info |= CTF_UNSIGNED; + if (!sz) { + sz = 1; + } + } else if ((cds & CDF_FP)) { + info = CTINFO(CT_NUM, CTF_FP); + if ((cds & CDF_LONG)) sz = sizeof(long double); + } else if ((cds & CDF_CHAR)) { + if ((cds & (CDF_CHAR|CDF_SIGNED|CDF_UNSIGNED)) == CDF_CHAR) + info |= CTF_UCHAR; /* Handle platforms where char is unsigned. */ + } else if ((cds & CDF_SHORT)) { + sz = sizeof(short); + } else if ((cds & CDF_LONGLONG)) { + sz = 8; + } else if ((cds & CDF_LONG)) { + info |= CTF_LONG; + sz = sizeof(long); + } else if (!sz) { + if (!(cds & (CDF_SIGNED|CDF_UNSIGNED))) + cp_errmsg(cp, cp->tok, LJ_ERR_FFI_DECLSPEC); + sz = sizeof(int); + } + lj_assertCP(sz != 0, "basic ctype with zero size"); + info += CTALIGN(lj_fls(sz)); /* Use natural alignment. */ + info += (decl->attr & CTF_QUAL); /* Merge qualifiers. */ + cp_push(decl, info, sz); + decl->attr &= ~CTF_QUAL; + } + decl->specpos = decl->pos; + decl->specattr = decl->attr; + decl->specfattr = decl->fattr; + return (cds & CDF_SCL); /* Return storage class. */ +} + +/* Parse array declaration. */ +static void cp_decl_array(CPState *cp, CPDecl *decl) +{ + CTInfo info = CTINFO(CT_ARRAY, 0); + CTSize nelem = CTSIZE_INVALID; /* Default size for a[] or a[?]. */ + cp_decl_attributes(cp, decl); + if (cp_opt(cp, '?')) + info |= CTF_VLA; /* Create variable-length array a[?]. */ + else if (cp->tok != ']') + nelem = cp_expr_ksize(cp); + cp_check(cp, ']'); + cp_add(decl, info, nelem); +} + +/* Parse function declaration. */ +static void cp_decl_func(CPState *cp, CPDecl *fdecl) +{ + CTSize nargs = 0; + CTInfo info = CTINFO(CT_FUNC, 0); + CTypeID lastid = 0, anchor = 0; + if (cp->tok != ')') { + do { + CPDecl decl; + CTypeID ctypeid, fieldid; + CType *ct; + if (cp_opt(cp, '.')) { /* Vararg function. */ + cp_check(cp, '.'); /* Workaround for the minimalistic lexer. */ + cp_check(cp, '.'); + info |= CTF_VARARG; + break; + } + cp_decl_spec(cp, &decl, CDF_REGISTER); + decl.mode = CPARSE_MODE_DIRECT|CPARSE_MODE_ABSTRACT; + cp_declarator(cp, &decl); + ctypeid = cp_decl_intern(cp, &decl); + ct = ctype_raw(cp->cts, ctypeid); + if (ctype_isvoid(ct->info)) + break; + else if (ctype_isrefarray(ct->info)) + ctypeid = lj_ctype_intern(cp->cts, + CTINFO(CT_PTR, CTALIGN_PTR|ctype_cid(ct->info)), CTSIZE_PTR); + else if (ctype_isfunc(ct->info)) + ctypeid = lj_ctype_intern(cp->cts, + CTINFO(CT_PTR, CTALIGN_PTR|ctypeid), CTSIZE_PTR); + /* Add new parameter. */ + fieldid = lj_ctype_new(cp->cts, &ct); + if (anchor) + ctype_get(cp->cts, lastid)->sib = fieldid; + else + anchor = fieldid; + lastid = fieldid; + if (decl.name) ctype_setname(ct, decl.name); + ct->info = CTINFO(CT_FIELD, ctypeid); + ct->size = nargs++; + } while (cp_opt(cp, ',')); + } + cp_check(cp, ')'); + if (cp_opt(cp, '{')) { /* Skip function definition. */ + int level = 1; + cp->mode |= CPARSE_MODE_SKIP; + for (;;) { + if (cp->tok == '{') level++; + else if (cp->tok == '}' && --level == 0) break; + else if (cp->tok == CTOK_EOF) cp_err_token(cp, '}'); + cp_next(cp); + } + cp->mode &= ~CPARSE_MODE_SKIP; + cp->tok = ';'; /* Ok for cp_decl_multi(), error in cp_decl_single(). */ + } + info |= (fdecl->fattr & ~CTMASK_CID); + fdecl->fattr = 0; + fdecl->stack[cp_add(fdecl, info, nargs)].sib = anchor; +} + +/* Parse declarator. */ +static void cp_declarator(CPState *cp, CPDecl *decl) +{ + if (++cp->depth > CPARSE_MAX_DECLDEPTH) cp_err(cp, LJ_ERR_XLEVELS); + + for (;;) { /* Head of declarator. */ + if (cp_opt(cp, '*')) { /* Pointer. */ + CTSize sz; + CTInfo info; + cp_decl_attributes(cp, decl); + sz = CTSIZE_PTR; + info = CTINFO(CT_PTR, CTALIGN_PTR); +#if LJ_64 + if (ctype_msizeP(decl->attr) == 4) { + sz = 4; + info = CTINFO(CT_PTR, CTALIGN(2)); + } +#endif + info += (decl->attr & (CTF_QUAL|CTF_REF)); + decl->attr &= ~(CTF_QUAL|(CTMASK_MSIZEP<attr &= ~(CTF_QUAL|(CTMASK_MSIZEP<mode & CPARSE_MODE_ABSTRACT) && + (cp->tok == ')' || cp_istypedecl(cp))) goto func_decl; + pos = decl->pos; + cp_declarator(cp, decl); + cp_check(cp, ')'); + decl->pos = pos; + } else if (cp->tok == CTOK_IDENT) { /* Direct declarator. */ + if (!(decl->mode & CPARSE_MODE_DIRECT)) cp_err_token(cp, CTOK_EOF); + decl->name = cp->str; + decl->nameid = cp->val.id; + cp_next(cp); + } else { /* Abstract declarator. */ + if (!(decl->mode & CPARSE_MODE_ABSTRACT)) cp_err_token(cp, CTOK_IDENT); + } + + for (;;) { /* Tail of declarator. */ + if (cp_opt(cp, '[')) { /* Array. */ + cp_decl_array(cp, decl); + } else if (cp_opt(cp, '(')) { /* Function. */ + func_decl: + cp_decl_func(cp, decl); + } else { + break; + } + } + + if ((decl->mode & CPARSE_MODE_FIELD) && cp_opt(cp, ':')) /* Field width. */ + decl->bits = cp_expr_ksize(cp); + + /* Process postfix attributes. */ + cp_decl_attributes(cp, decl); + cp_push_attributes(decl); + + cp->depth--; +} + +/* Parse an abstract type declaration and return it's C type ID. */ +static CTypeID cp_decl_abstract(CPState *cp) +{ + CPDecl decl; + cp_decl_spec(cp, &decl, 0); + decl.mode = CPARSE_MODE_ABSTRACT; + cp_declarator(cp, &decl); + return cp_decl_intern(cp, &decl); +} + +/* Handle pragmas. */ +static void cp_pragma(CPState *cp, BCLine pragmaline) +{ + cp_next(cp); + if (cp->tok == CTOK_IDENT && cp_str_is(cp->str, "pack")) { + cp_next(cp); + cp_check(cp, '('); + if (cp->tok == CTOK_IDENT) { + if (cp_str_is(cp->str, "push")) { + if (cp->curpack < CPARSE_MAX_PACKSTACK) { + cp->packstack[cp->curpack+1] = cp->packstack[cp->curpack]; + cp->curpack++; + } + } else if (cp_str_is(cp->str, "pop")) { + if (cp->curpack > 0) cp->curpack--; + } else { + cp_errmsg(cp, cp->tok, LJ_ERR_XSYMBOL); + } + cp_next(cp); + if (!cp_opt(cp, ',')) goto end_pack; + } + if (cp->tok == CTOK_INTEGER) { + cp->packstack[cp->curpack] = cp->val.u32 ? lj_fls(cp->val.u32) : 0; + cp_next(cp); + } else { + cp->packstack[cp->curpack] = 255; + } + end_pack: + cp_check(cp, ')'); + } else { /* Ignore all other pragmas. */ + while (cp->tok != CTOK_EOF && cp->linenumber == pragmaline) + cp_next(cp); + } +} + +/* Handle line number. */ +static void cp_line(CPState *cp, BCLine hashline) +{ + BCLine newline = cp->val.u32; + /* TODO: Handle file name and include it in error messages. */ + while (cp->tok != CTOK_EOF && cp->linenumber == hashline) + cp_next(cp); + cp->linenumber = newline; +} + +/* Parse multiple C declarations of types or extern identifiers. */ +static void cp_decl_multi(CPState *cp) +{ + int first = 1; + while (cp->tok != CTOK_EOF) { + CPDecl decl; + CPscl scl; + if (cp_opt(cp, ';')) { /* Skip empty statements. */ + first = 0; + continue; + } + if (cp->tok == '#') { /* Workaround, since we have no preprocessor, yet. */ + BCLine hashline = cp->linenumber; + CPToken tok = cp_next(cp); + if (tok == CTOK_INTEGER) { + cp_line(cp, hashline); + continue; + } else if (tok == CTOK_IDENT && cp_str_is(cp->str, "line")) { + if (cp_next(cp) != CTOK_INTEGER) cp_err_token(cp, tok); + cp_line(cp, hashline); + continue; + } else if (tok == CTOK_IDENT && cp_str_is(cp->str, "pragma")) { + cp_pragma(cp, hashline); + continue; + } else { + cp_errmsg(cp, cp->tok, LJ_ERR_XSYMBOL); + } + } + scl = cp_decl_spec(cp, &decl, CDF_TYPEDEF|CDF_EXTERN|CDF_STATIC); + if ((cp->tok == ';' || cp->tok == CTOK_EOF) && + ctype_istypedef(decl.stack[0].info)) { + CTInfo info = ctype_rawchild(cp->cts, &decl.stack[0])->info; + if (ctype_isstruct(info) || ctype_isenum(info)) + goto decl_end; /* Accept empty declaration of struct/union/enum. */ + } + for (;;) { + CTypeID ctypeid; + cp_declarator(cp, &decl); + ctypeid = cp_decl_intern(cp, &decl); + if (decl.name && !decl.nameid) { /* NYI: redeclarations are ignored. */ + CType *ct; + CTypeID id; + if ((scl & CDF_TYPEDEF)) { /* Create new typedef. */ + id = lj_ctype_new(cp->cts, &ct); + ct->info = CTINFO(CT_TYPEDEF, ctypeid); + goto noredir; + } else if (ctype_isfunc(ctype_get(cp->cts, ctypeid)->info)) { + /* Treat both static and extern function declarations as extern. */ + ct = ctype_get(cp->cts, ctypeid); + /* We always get new anonymous functions (typedefs are copied). */ + lj_assertCP(gcref(ct->name) == NULL, "unexpected named function"); + id = ctypeid; /* Just name it. */ + } else if ((scl & CDF_STATIC)) { /* Accept static constants. */ + id = cp_decl_constinit(cp, &ct, ctypeid); + goto noredir; + } else { /* External references have extern or no storage class. */ + id = lj_ctype_new(cp->cts, &ct); + ct->info = CTINFO(CT_EXTERN, ctypeid); + } + if (decl.redir) { /* Add attribute for redirected symbol name. */ + CType *cta; + CTypeID aid = lj_ctype_new(cp->cts, &cta); + ct = ctype_get(cp->cts, id); /* Table may have been reallocated. */ + cta->info = CTINFO(CT_ATTRIB, CTATTRIB(CTA_REDIR)); + cta->sib = ct->sib; + ct->sib = aid; + ctype_setname(cta, decl.redir); + } + noredir: + ctype_setname(ct, decl.name); + lj_ctype_addname(cp->cts, ct, id); + } + if (!cp_opt(cp, ',')) break; + cp_decl_reset(&decl); + } + decl_end: + if (cp->tok == CTOK_EOF && first) break; /* May omit ';' for 1 decl. */ + first = 0; + cp_check(cp, ';'); + } +} + +/* Parse a single C type declaration. */ +static void cp_decl_single(CPState *cp) +{ + CPDecl decl; + cp_decl_spec(cp, &decl, 0); + cp_declarator(cp, &decl); + cp->val.id = cp_decl_intern(cp, &decl); + if (cp->tok != CTOK_EOF) cp_err_token(cp, CTOK_EOF); +} + +/* ------------------------------------------------------------------------ */ + +/* Protected callback for C parser. */ +static TValue *cpcparser(lua_State *L, lua_CFunction dummy, void *ud) +{ + CPState *cp = (CPState *)ud; + UNUSED(dummy); + cframe_errfunc(L->cframe) = -1; /* Inherit error function. */ + cp_init(cp); + if ((cp->mode & CPARSE_MODE_MULTI)) + cp_decl_multi(cp); + else + cp_decl_single(cp); + if (cp->param && cp->param != cp->L->top) + cp_err(cp, LJ_ERR_FFI_NUMPARAM); + lj_assertCP(cp->depth == 0, "unbalanced cparser declaration depth"); + return NULL; +} + +/* C parser. */ +int lj_cparse(CPState *cp) +{ + LJ_CTYPE_SAVE(cp->cts); + int errcode = lj_vm_cpcall(cp->L, NULL, cp, cpcparser); + if (errcode) + LJ_CTYPE_RESTORE(cp->cts); + cp_cleanup(cp); + return errcode; +} + +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_cparse.h b/fluent-bit/lib/luajit-3065c9/src/lj_cparse.h new file mode 100644 index 00000000..c0f61edc --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_cparse.h @@ -0,0 +1,67 @@ +/* +** C declaration parser. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#ifndef _LJ_CPARSE_H +#define _LJ_CPARSE_H + +#include "lj_obj.h" +#include "lj_ctype.h" + +#if LJ_HASFFI + +/* C parser limits. */ +#define CPARSE_MAX_BUF 32768 /* Max. token buffer size. */ +#define CPARSE_MAX_DECLSTACK 100 /* Max. declaration stack depth. */ +#define CPARSE_MAX_DECLDEPTH 20 /* Max. recursive declaration depth. */ +#define CPARSE_MAX_PACKSTACK 7 /* Max. pack pragma stack depth. */ + +/* Flags for C parser mode. */ +#define CPARSE_MODE_MULTI 1 /* Process multiple declarations. */ +#define CPARSE_MODE_ABSTRACT 2 /* Accept abstract declarators. */ +#define CPARSE_MODE_DIRECT 4 /* Accept direct declarators. */ +#define CPARSE_MODE_FIELD 8 /* Accept field width in bits, too. */ +#define CPARSE_MODE_NOIMPLICIT 16 /* Reject implicit declarations. */ +#define CPARSE_MODE_SKIP 32 /* Skip definitions, ignore errors. */ + +typedef int CPChar; /* C parser character. Unsigned ext. from char. */ +typedef int CPToken; /* C parser token. */ + +/* C parser internal value representation. */ +typedef struct CPValue { + union { + int32_t i32; /* Value for CTID_INT32. */ + uint32_t u32; /* Value for CTID_UINT32. */ + }; + CTypeID id; /* C Type ID of the value. */ +} CPValue; + +/* C parser state. */ +typedef struct CPState { + CPChar c; /* Current character. */ + CPToken tok; /* Current token. */ + CPValue val; /* Token value. */ + GCstr *str; /* Interned string of identifier/keyword. */ + CType *ct; /* C type table entry. */ + const char *p; /* Current position in input buffer. */ + SBuf sb; /* String buffer for tokens. */ + lua_State *L; /* Lua state. */ + CTState *cts; /* C type state. */ + TValue *param; /* C type parameters. */ + const char *srcname; /* Current source name. */ + BCLine linenumber; /* Input line counter. */ + int depth; /* Recursive declaration depth. */ + uint32_t tmask; /* Type mask for next identifier. */ + uint32_t mode; /* C parser mode. */ + uint8_t packstack[CPARSE_MAX_PACKSTACK]; /* Stack for pack pragmas. */ + uint8_t curpack; /* Current position in pack pragma stack. */ +} CPState; + +LJ_FUNC int lj_cparse(CPState *cp); + +LJ_FUNC int lj_cparse_case(GCstr *str, const char *match); + +#endif + +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_crecord.c b/fluent-bit/lib/luajit-3065c9/src/lj_crecord.c new file mode 100644 index 00000000..bc21d859 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_crecord.c @@ -0,0 +1,1944 @@ +/* +** Trace recorder for C data operations. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#define lj_ffrecord_c +#define LUA_CORE + +#include "lj_obj.h" + +#if LJ_HASJIT && LJ_HASFFI + +#include "lj_err.h" +#include "lj_tab.h" +#include "lj_frame.h" +#include "lj_ctype.h" +#include "lj_cdata.h" +#include "lj_cparse.h" +#include "lj_cconv.h" +#include "lj_carith.h" +#include "lj_clib.h" +#include "lj_ccall.h" +#include "lj_ff.h" +#include "lj_ir.h" +#include "lj_jit.h" +#include "lj_ircall.h" +#include "lj_iropt.h" +#include "lj_trace.h" +#include "lj_record.h" +#include "lj_ffrecord.h" +#include "lj_snap.h" +#include "lj_crecord.h" +#include "lj_dispatch.h" +#include "lj_strfmt.h" + +/* Some local macros to save typing. Undef'd at the end. */ +#define IR(ref) (&J->cur.ir[(ref)]) + +/* Pass IR on to next optimization in chain (FOLD). */ +#define emitir(ot, a, b) (lj_ir_set(J, (ot), (a), (b)), lj_opt_fold(J)) + +#define emitconv(a, dt, st, flags) \ + emitir(IRT(IR_CONV, (dt)), (a), (st)|((dt) << 5)|(flags)) + +/* -- C type checks ------------------------------------------------------- */ + +static GCcdata *argv2cdata(jit_State *J, TRef tr, cTValue *o) +{ + GCcdata *cd; + TRef trtypeid; + if (!tref_iscdata(tr)) + lj_trace_err(J, LJ_TRERR_BADTYPE); + cd = cdataV(o); + /* Specialize to the CTypeID. */ + trtypeid = emitir(IRT(IR_FLOAD, IRT_U16), tr, IRFL_CDATA_CTYPEID); + emitir(IRTG(IR_EQ, IRT_INT), trtypeid, lj_ir_kint(J, (int32_t)cd->ctypeid)); + return cd; +} + +/* Specialize to the CTypeID held by a cdata constructor. */ +static CTypeID crec_constructor(jit_State *J, GCcdata *cd, TRef tr) +{ + CTypeID id; + lj_assertJ(tref_iscdata(tr) && cd->ctypeid == CTID_CTYPEID, + "expected CTypeID cdata"); + id = *(CTypeID *)cdataptr(cd); + tr = emitir(IRT(IR_FLOAD, IRT_INT), tr, IRFL_CDATA_INT); + emitir(IRTG(IR_EQ, IRT_INT), tr, lj_ir_kint(J, (int32_t)id)); + return id; +} + +static CTypeID argv2ctype(jit_State *J, TRef tr, cTValue *o) +{ + if (tref_isstr(tr)) { + GCstr *s = strV(o); + CPState cp; + CTypeID oldtop; + /* Specialize to the string containing the C type declaration. */ + emitir(IRTG(IR_EQ, IRT_STR), tr, lj_ir_kstr(J, s)); + cp.L = J->L; + cp.cts = ctype_cts(J->L); + oldtop = cp.cts->top; + cp.srcname = strdata(s); + cp.p = strdata(s); + cp.param = NULL; + cp.mode = CPARSE_MODE_ABSTRACT|CPARSE_MODE_NOIMPLICIT; + if (lj_cparse(&cp) || cp.cts->top > oldtop) /* Avoid new struct defs. */ + lj_trace_err(J, LJ_TRERR_BADTYPE); + return cp.val.id; + } else { + GCcdata *cd = argv2cdata(J, tr, o); + return cd->ctypeid == CTID_CTYPEID ? crec_constructor(J, cd, tr) : + cd->ctypeid; + } +} + +/* Convert CType to IRType (if possible). */ +static IRType crec_ct2irt(CTState *cts, CType *ct) +{ + if (ctype_isenum(ct->info)) ct = ctype_child(cts, ct); + if (LJ_LIKELY(ctype_isnum(ct->info))) { + if ((ct->info & CTF_FP)) { + if (ct->size == sizeof(double)) + return IRT_NUM; + else if (ct->size == sizeof(float)) + return IRT_FLOAT; + } else { + uint32_t b = lj_fls(ct->size); + if (b <= 3) + return IRT_I8 + 2*b + ((ct->info & CTF_UNSIGNED) ? 1 : 0); + } + } else if (ctype_isptr(ct->info)) { + return (LJ_64 && ct->size == 8) ? IRT_P64 : IRT_P32; + } else if (ctype_iscomplex(ct->info)) { + if (ct->size == 2*sizeof(double)) + return IRT_NUM; + else if (ct->size == 2*sizeof(float)) + return IRT_FLOAT; + } + return IRT_CDATA; +} + +/* -- Optimized memory fill and copy -------------------------------------- */ + +/* Maximum length and unroll of inlined copy/fill. */ +#define CREC_COPY_MAXUNROLL 16 +#define CREC_COPY_MAXLEN 128 + +#define CREC_FILL_MAXUNROLL 16 + +/* Number of windowed registers used for optimized memory copy. */ +#if LJ_TARGET_X86 +#define CREC_COPY_REGWIN 2 +#elif LJ_TARGET_PPC || LJ_TARGET_MIPS +#define CREC_COPY_REGWIN 8 +#else +#define CREC_COPY_REGWIN 4 +#endif + +/* List of memory offsets for copy/fill. */ +typedef struct CRecMemList { + CTSize ofs; /* Offset in bytes. */ + IRType tp; /* Type of load/store. */ + TRef trofs; /* TRef of interned offset. */ + TRef trval; /* TRef of load value. */ +} CRecMemList; + +/* Generate copy list for element-wise struct copy. */ +static MSize crec_copy_struct(CRecMemList *ml, CTState *cts, CType *ct) +{ + CTypeID fid = ct->sib; + MSize mlp = 0; + while (fid) { + CType *df = ctype_get(cts, fid); + fid = df->sib; + if (ctype_isfield(df->info)) { + CType *cct; + IRType tp; + if (!gcref(df->name)) continue; /* Ignore unnamed fields. */ + cct = ctype_rawchild(cts, df); /* Field type. */ + tp = crec_ct2irt(cts, cct); + if (tp == IRT_CDATA) return 0; /* NYI: aggregates. */ + if (mlp >= CREC_COPY_MAXUNROLL) return 0; + ml[mlp].ofs = df->size; + ml[mlp].tp = tp; + mlp++; + if (ctype_iscomplex(cct->info)) { + if (mlp >= CREC_COPY_MAXUNROLL) return 0; + ml[mlp].ofs = df->size + (cct->size >> 1); + ml[mlp].tp = tp; + mlp++; + } + } else if (!ctype_isconstval(df->info)) { + /* NYI: bitfields and sub-structures. */ + return 0; + } + } + return mlp; +} + +/* Generate unrolled copy list, from highest to lowest step size/alignment. */ +static MSize crec_copy_unroll(CRecMemList *ml, CTSize len, CTSize step, + IRType tp) +{ + CTSize ofs = 0; + MSize mlp = 0; + if (tp == IRT_CDATA) tp = IRT_U8 + 2*lj_fls(step); + do { + while (ofs + step <= len) { + if (mlp >= CREC_COPY_MAXUNROLL) return 0; + ml[mlp].ofs = ofs; + ml[mlp].tp = tp; + mlp++; + ofs += step; + } + step >>= 1; + tp -= 2; + } while (ofs < len); + return mlp; +} + +/* +** Emit copy list with windowed loads/stores. +** LJ_TARGET_UNALIGNED: may emit unaligned loads/stores (not marked as such). +*/ +static void crec_copy_emit(jit_State *J, CRecMemList *ml, MSize mlp, + TRef trdst, TRef trsrc) +{ + MSize i, j, rwin = 0; + for (i = 0, j = 0; i < mlp; ) { + TRef trofs = lj_ir_kintp(J, ml[i].ofs); + TRef trsptr = emitir(IRT(IR_ADD, IRT_PTR), trsrc, trofs); + ml[i].trval = emitir(IRT(IR_XLOAD, ml[i].tp), trsptr, 0); + ml[i].trofs = trofs; + i++; + rwin += (LJ_SOFTFP32 && ml[i].tp == IRT_NUM) ? 2 : 1; + if (rwin >= CREC_COPY_REGWIN || i >= mlp) { /* Flush buffered stores. */ + rwin = 0; + for ( ; j < i; j++) { + TRef trdptr = emitir(IRT(IR_ADD, IRT_PTR), trdst, ml[j].trofs); + emitir(IRT(IR_XSTORE, ml[j].tp), trdptr, ml[j].trval); + } + } + } +} + +/* Optimized memory copy. */ +static void crec_copy(jit_State *J, TRef trdst, TRef trsrc, TRef trlen, + CType *ct) +{ + if (tref_isk(trlen)) { /* Length must be constant. */ + CRecMemList ml[CREC_COPY_MAXUNROLL]; + MSize mlp = 0; + CTSize step = 1, len = (CTSize)IR(tref_ref(trlen))->i; + IRType tp = IRT_CDATA; + int needxbar = 0; + if (len == 0) return; /* Shortcut. */ + if (len > CREC_COPY_MAXLEN) goto fallback; + if (ct) { + CTState *cts = ctype_ctsG(J2G(J)); + lj_assertJ(ctype_isarray(ct->info) || ctype_isstruct(ct->info), + "copy of non-aggregate"); + if (ctype_isarray(ct->info)) { + CType *cct = ctype_rawchild(cts, ct); + tp = crec_ct2irt(cts, cct); + if (tp == IRT_CDATA) goto rawcopy; + step = lj_ir_type_size[tp]; + lj_assertJ((len & (step-1)) == 0, "copy of fractional size"); + } else if ((ct->info & CTF_UNION)) { + step = (1u << ctype_align(ct->info)); + goto rawcopy; + } else { + mlp = crec_copy_struct(ml, cts, ct); + goto emitcopy; + } + } else { + rawcopy: + needxbar = 1; + if (LJ_TARGET_UNALIGNED || step >= CTSIZE_PTR) + step = CTSIZE_PTR; + } + mlp = crec_copy_unroll(ml, len, step, tp); + emitcopy: + if (mlp) { + crec_copy_emit(J, ml, mlp, trdst, trsrc); + if (needxbar) + emitir(IRT(IR_XBAR, IRT_NIL), 0, 0); + return; + } + } +fallback: + /* Call memcpy. Always needs a barrier to disable alias analysis. */ + lj_ir_call(J, IRCALL_memcpy, trdst, trsrc, trlen); + emitir(IRT(IR_XBAR, IRT_NIL), 0, 0); +} + +/* Generate unrolled fill list, from highest to lowest step size/alignment. */ +static MSize crec_fill_unroll(CRecMemList *ml, CTSize len, CTSize step) +{ + CTSize ofs = 0; + MSize mlp = 0; + IRType tp = IRT_U8 + 2*lj_fls(step); + do { + while (ofs + step <= len) { + if (mlp >= CREC_COPY_MAXUNROLL) return 0; + ml[mlp].ofs = ofs; + ml[mlp].tp = tp; + mlp++; + ofs += step; + } + step >>= 1; + tp -= 2; + } while (ofs < len); + return mlp; +} + +/* +** Emit stores for fill list. +** LJ_TARGET_UNALIGNED: may emit unaligned stores (not marked as such). +*/ +static void crec_fill_emit(jit_State *J, CRecMemList *ml, MSize mlp, + TRef trdst, TRef trfill) +{ + MSize i; + for (i = 0; i < mlp; i++) { + TRef trofs = lj_ir_kintp(J, ml[i].ofs); + TRef trdptr = emitir(IRT(IR_ADD, IRT_PTR), trdst, trofs); + emitir(IRT(IR_XSTORE, ml[i].tp), trdptr, trfill); + } +} + +/* Optimized memory fill. */ +static void crec_fill(jit_State *J, TRef trdst, TRef trlen, TRef trfill, + CTSize step) +{ + if (tref_isk(trlen)) { /* Length must be constant. */ + CRecMemList ml[CREC_FILL_MAXUNROLL]; + MSize mlp; + CTSize len = (CTSize)IR(tref_ref(trlen))->i; + if (len == 0) return; /* Shortcut. */ + if (LJ_TARGET_UNALIGNED || step >= CTSIZE_PTR) + step = CTSIZE_PTR; + if (step * CREC_FILL_MAXUNROLL < len) goto fallback; + mlp = crec_fill_unroll(ml, len, step); + if (!mlp) goto fallback; + if (tref_isk(trfill) || ml[0].tp != IRT_U8) + trfill = emitconv(trfill, IRT_INT, IRT_U8, 0); + if (ml[0].tp != IRT_U8) { /* Scatter U8 to U16/U32/U64. */ + if (CTSIZE_PTR == 8 && ml[0].tp == IRT_U64) { + if (tref_isk(trfill)) /* Pointless on x64 with zero-extended regs. */ + trfill = emitconv(trfill, IRT_U64, IRT_U32, 0); + trfill = emitir(IRT(IR_MUL, IRT_U64), trfill, + lj_ir_kint64(J, U64x(01010101,01010101))); + } else { + trfill = emitir(IRTI(IR_MUL), trfill, + lj_ir_kint(J, ml[0].tp == IRT_U16 ? 0x0101 : 0x01010101)); + } + } + crec_fill_emit(J, ml, mlp, trdst, trfill); + } else { +fallback: + /* Call memset. Always needs a barrier to disable alias analysis. */ + lj_ir_call(J, IRCALL_memset, trdst, trfill, trlen); /* Note: arg order! */ + } + emitir(IRT(IR_XBAR, IRT_NIL), 0, 0); +} + +/* -- Convert C type to C type -------------------------------------------- */ + +/* +** This code mirrors the code in lj_cconv.c. It performs the same steps +** for the trace recorder that lj_cconv.c does for the interpreter. +** +** One major difference is that we can get away with much fewer checks +** here. E.g. checks for casts, constness or correct types can often be +** omitted, even if they might fail. The interpreter subsequently throws +** an error, which aborts the trace. +** +** All operations are specialized to their C types, so the on-trace +** outcome must be the same as the outcome in the interpreter. If the +** interpreter doesn't throw an error, then the trace is correct, too. +** Care must be taken not to generate invalid (temporary) IR or to +** trigger asserts. +*/ + +/* Determine whether a passed number or cdata number is non-zero. */ +static int crec_isnonzero(CType *s, void *p) +{ + if (p == (void *)0) + return 0; + if (p == (void *)1) + return 1; + if ((s->info & CTF_FP)) { + if (s->size == sizeof(float)) + return (*(float *)p != 0); + else + return (*(double *)p != 0); + } else { + if (s->size == 1) + return (*(uint8_t *)p != 0); + else if (s->size == 2) + return (*(uint16_t *)p != 0); + else if (s->size == 4) + return (*(uint32_t *)p != 0); + else + return (*(uint64_t *)p != 0); + } +} + +static TRef crec_ct_ct(jit_State *J, CType *d, CType *s, TRef dp, TRef sp, + void *svisnz) +{ + IRType dt = crec_ct2irt(ctype_ctsG(J2G(J)), d); + IRType st = crec_ct2irt(ctype_ctsG(J2G(J)), s); + CTSize dsize = d->size, ssize = s->size; + CTInfo dinfo = d->info, sinfo = s->info; + + if (ctype_type(dinfo) > CT_MAYCONVERT || ctype_type(sinfo) > CT_MAYCONVERT) + goto err_conv; + + /* + ** Note: Unlike lj_cconv_ct_ct(), sp holds the _value_ of pointers and + ** numbers up to 8 bytes. Otherwise sp holds a pointer. + */ + + switch (cconv_idx2(dinfo, sinfo)) { + /* Destination is a bool. */ + case CCX(B, B): + goto xstore; /* Source operand is already normalized. */ + case CCX(B, I): + case CCX(B, F): + if (st != IRT_CDATA) { + /* Specialize to the result of a comparison against 0. */ + TRef zero = (st == IRT_NUM || st == IRT_FLOAT) ? lj_ir_knum(J, 0) : + (st == IRT_I64 || st == IRT_U64) ? lj_ir_kint64(J, 0) : + lj_ir_kint(J, 0); + int isnz = crec_isnonzero(s, svisnz); + emitir(IRTG(isnz ? IR_NE : IR_EQ, st), sp, zero); + sp = lj_ir_kint(J, isnz); + goto xstore; + } + goto err_nyi; + + /* Destination is an integer. */ + case CCX(I, B): + case CCX(I, I): + conv_I_I: + if (dt == IRT_CDATA || st == IRT_CDATA) goto err_nyi; + /* Extend 32 to 64 bit integer. */ + if (dsize == 8 && ssize < 8 && !(LJ_64 && (sinfo & CTF_UNSIGNED))) + sp = emitconv(sp, dt, ssize < 4 ? IRT_INT : st, + (sinfo & CTF_UNSIGNED) ? 0 : IRCONV_SEXT); + else if (dsize < 8 && ssize == 8) /* Truncate from 64 bit integer. */ + sp = emitconv(sp, dsize < 4 ? IRT_INT : dt, st, 0); + else if (st == IRT_INT) + sp = lj_opt_narrow_toint(J, sp); + xstore: + if (dt == IRT_I64 || dt == IRT_U64) lj_needsplit(J); + if (dp == 0) return sp; + emitir(IRT(IR_XSTORE, dt), dp, sp); + break; + case CCX(I, C): + sp = emitir(IRT(IR_XLOAD, st), sp, 0); /* Load re. */ + /* fallthrough */ + case CCX(I, F): + if (dt == IRT_CDATA || st == IRT_CDATA) goto err_nyi; + sp = emitconv(sp, dsize < 4 ? IRT_INT : dt, st, IRCONV_ANY); + goto xstore; + case CCX(I, P): + case CCX(I, A): + sinfo = CTINFO(CT_NUM, CTF_UNSIGNED); + ssize = CTSIZE_PTR; + st = IRT_UINTP; + if (((dsize ^ ssize) & 8) == 0) { /* Must insert no-op type conversion. */ + sp = emitconv(sp, dsize < 4 ? IRT_INT : dt, IRT_PTR, 0); + goto xstore; + } + goto conv_I_I; + + /* Destination is a floating-point number. */ + case CCX(F, B): + case CCX(F, I): + conv_F_I: + if (dt == IRT_CDATA || st == IRT_CDATA) goto err_nyi; + sp = emitconv(sp, dt, ssize < 4 ? IRT_INT : st, 0); + goto xstore; + case CCX(F, C): + sp = emitir(IRT(IR_XLOAD, st), sp, 0); /* Load re. */ + /* fallthrough */ + case CCX(F, F): + conv_F_F: + if (dt == IRT_CDATA || st == IRT_CDATA) goto err_nyi; + if (dt != st) sp = emitconv(sp, dt, st, 0); + goto xstore; + + /* Destination is a complex number. */ + case CCX(C, I): + case CCX(C, F): + { /* Clear im. */ + TRef ptr = emitir(IRT(IR_ADD, IRT_PTR), dp, lj_ir_kintp(J, (dsize >> 1))); + emitir(IRT(IR_XSTORE, dt), ptr, lj_ir_knum(J, 0)); + } + /* Convert to re. */ + if ((sinfo & CTF_FP)) goto conv_F_F; else goto conv_F_I; + + case CCX(C, C): + if (dt == IRT_CDATA || st == IRT_CDATA) goto err_nyi; + { + TRef re, im, ptr; + re = emitir(IRT(IR_XLOAD, st), sp, 0); + ptr = emitir(IRT(IR_ADD, IRT_PTR), sp, lj_ir_kintp(J, (ssize >> 1))); + im = emitir(IRT(IR_XLOAD, st), ptr, 0); + if (dt != st) { + re = emitconv(re, dt, st, 0); + im = emitconv(im, dt, st, 0); + } + emitir(IRT(IR_XSTORE, dt), dp, re); + ptr = emitir(IRT(IR_ADD, IRT_PTR), dp, lj_ir_kintp(J, (dsize >> 1))); + emitir(IRT(IR_XSTORE, dt), ptr, im); + } + break; + + /* Destination is a vector. */ + case CCX(V, I): + case CCX(V, F): + case CCX(V, C): + case CCX(V, V): + goto err_nyi; + + /* Destination is a pointer. */ + case CCX(P, P): + case CCX(P, A): + case CCX(P, S): + /* There are only 32 bit pointers/addresses on 32 bit machines. + ** Also ok on x64, since all 32 bit ops clear the upper part of the reg. + */ + goto xstore; + case CCX(P, I): + if (st == IRT_CDATA) goto err_nyi; + if (!LJ_64 && ssize == 8) /* Truncate from 64 bit integer. */ + sp = emitconv(sp, IRT_U32, st, 0); + goto xstore; + case CCX(P, F): + if (st == IRT_CDATA) goto err_nyi; + /* The signed conversion is cheaper. x64 really has 47 bit pointers. */ + sp = emitconv(sp, (LJ_64 && dsize == 8) ? IRT_I64 : IRT_U32, + st, IRCONV_ANY); + goto xstore; + + /* Destination is an array. */ + case CCX(A, A): + /* Destination is a struct/union. */ + case CCX(S, S): + if (dp == 0) goto err_conv; + crec_copy(J, dp, sp, lj_ir_kint(J, dsize), d); + break; + + default: + err_conv: + err_nyi: + lj_trace_err(J, LJ_TRERR_NYICONV); + break; + } + return 0; +} + +/* -- Convert C type to TValue (load) ------------------------------------- */ + +static TRef crec_tv_ct(jit_State *J, CType *s, CTypeID sid, TRef sp) +{ + CTState *cts = ctype_ctsG(J2G(J)); + IRType t = crec_ct2irt(cts, s); + CTInfo sinfo = s->info; + if (ctype_isnum(sinfo)) { + TRef tr; + if (t == IRT_CDATA) + goto err_nyi; /* NYI: copyval of >64 bit integers. */ + tr = emitir(IRT(IR_XLOAD, t), sp, 0); + if (t == IRT_FLOAT || t == IRT_U32) { /* Keep uint32_t/float as numbers. */ + return emitconv(tr, IRT_NUM, t, 0); + } else if (t == IRT_I64 || t == IRT_U64) { /* Box 64 bit integer. */ + sp = tr; + lj_needsplit(J); + } else if ((sinfo & CTF_BOOL)) { + /* Assume not equal to zero. Fixup and emit pending guard later. */ + lj_ir_set(J, IRTGI(IR_NE), tr, lj_ir_kint(J, 0)); + J->postproc = LJ_POST_FIXGUARD; + return TREF_TRUE; + } else { + return tr; + } + } else if (ctype_isptr(sinfo) || ctype_isenum(sinfo)) { + sp = emitir(IRT(IR_XLOAD, t), sp, 0); /* Box pointers and enums. */ + } else if (ctype_isrefarray(sinfo) || ctype_isstruct(sinfo)) { + cts->L = J->L; + sid = lj_ctype_intern(cts, CTINFO_REF(sid), CTSIZE_PTR); /* Create ref. */ + } else if (ctype_iscomplex(sinfo)) { /* Unbox/box complex. */ + ptrdiff_t esz = (ptrdiff_t)(s->size >> 1); + TRef ptr, tr1, tr2, dp; + dp = emitir(IRTG(IR_CNEW, IRT_CDATA), lj_ir_kint(J, sid), TREF_NIL); + tr1 = emitir(IRT(IR_XLOAD, t), sp, 0); + ptr = emitir(IRT(IR_ADD, IRT_PTR), sp, lj_ir_kintp(J, esz)); + tr2 = emitir(IRT(IR_XLOAD, t), ptr, 0); + ptr = emitir(IRT(IR_ADD, IRT_PTR), dp, lj_ir_kintp(J, sizeof(GCcdata))); + emitir(IRT(IR_XSTORE, t), ptr, tr1); + ptr = emitir(IRT(IR_ADD, IRT_PTR), dp, lj_ir_kintp(J, sizeof(GCcdata)+esz)); + emitir(IRT(IR_XSTORE, t), ptr, tr2); + return dp; + } else { + /* NYI: copyval of vectors. */ + err_nyi: + lj_trace_err(J, LJ_TRERR_NYICONV); + } + /* Box pointer, ref, enum or 64 bit integer. */ + return emitir(IRTG(IR_CNEWI, IRT_CDATA), lj_ir_kint(J, sid), sp); +} + +/* -- Convert TValue to C type (store) ------------------------------------ */ + +static TRef crec_ct_tv(jit_State *J, CType *d, TRef dp, TRef sp, cTValue *sval) +{ + CTState *cts = ctype_ctsG(J2G(J)); + CTypeID sid = CTID_P_VOID; + void *svisnz = 0; + CType *s; + if (LJ_LIKELY(tref_isinteger(sp))) { + sid = CTID_INT32; + svisnz = (void *)(intptr_t)(tvisint(sval)?(intV(sval)!=0):!tviszero(sval)); + } else if (tref_isnum(sp)) { + sid = CTID_DOUBLE; + svisnz = (void *)(intptr_t)(tvisint(sval)?(intV(sval)!=0):!tviszero(sval)); + } else if (tref_isbool(sp)) { + sp = lj_ir_kint(J, tref_istrue(sp) ? 1 : 0); + sid = CTID_BOOL; + } else if (tref_isnil(sp)) { + sp = lj_ir_kptr(J, NULL); + } else if (tref_isudata(sp)) { + GCudata *ud = udataV(sval); + if (ud->udtype == UDTYPE_IO_FILE || ud->udtype == UDTYPE_BUFFER) { + TRef tr = emitir(IRT(IR_FLOAD, IRT_U8), sp, IRFL_UDATA_UDTYPE); + emitir(IRTGI(IR_EQ), tr, lj_ir_kint(J, ud->udtype)); + sp = emitir(IRT(IR_FLOAD, IRT_PTR), sp, + ud->udtype == UDTYPE_IO_FILE ? IRFL_UDATA_FILE : + IRFL_SBUF_R); + } else { + sp = emitir(IRT(IR_ADD, IRT_PTR), sp, lj_ir_kintp(J, sizeof(GCudata))); + } + } else if (tref_isstr(sp)) { + if (ctype_isenum(d->info)) { /* Match string against enum constant. */ + GCstr *str = strV(sval); + CTSize ofs; + CType *cct = lj_ctype_getfield(cts, d, str, &ofs); + /* Specialize to the name of the enum constant. */ + emitir(IRTG(IR_EQ, IRT_STR), sp, lj_ir_kstr(J, str)); + if (cct && ctype_isconstval(cct->info)) { + lj_assertJ(ctype_child(cts, cct)->size == 4, + "only 32 bit const supported"); /* NYI */ + svisnz = (void *)(intptr_t)(ofs != 0); + sp = lj_ir_kint(J, (int32_t)ofs); + sid = ctype_cid(cct->info); + } /* else: interpreter will throw. */ + } else if (ctype_isrefarray(d->info)) { /* Copy string to array. */ + lj_trace_err(J, LJ_TRERR_BADTYPE); /* NYI */ + } else { /* Otherwise pass the string data as a const char[]. */ + /* Don't use STRREF. It folds with SNEW, which loses the trailing NUL. */ + sp = emitir(IRT(IR_ADD, IRT_PTR), sp, lj_ir_kintp(J, sizeof(GCstr))); + sid = CTID_A_CCHAR; + } + } else if (tref_islightud(sp)) { +#if LJ_64 + lj_trace_err(J, LJ_TRERR_NYICONV); +#endif + } else { /* NYI: tref_istab(sp). */ + IRType t; + sid = argv2cdata(J, sp, sval)->ctypeid; + s = ctype_raw(cts, sid); + svisnz = cdataptr(cdataV(sval)); + if (ctype_isfunc(s->info)) { + sid = lj_ctype_intern(cts, CTINFO(CT_PTR, CTALIGN_PTR|sid), CTSIZE_PTR); + s = ctype_get(cts, sid); + t = IRT_PTR; + } else { + t = crec_ct2irt(cts, s); + } + if (ctype_isptr(s->info)) { + sp = emitir(IRT(IR_FLOAD, t), sp, IRFL_CDATA_PTR); + if (ctype_isref(s->info)) { + svisnz = *(void **)svisnz; + s = ctype_rawchild(cts, s); + if (ctype_isenum(s->info)) s = ctype_child(cts, s); + t = crec_ct2irt(cts, s); + } else { + goto doconv; + } + } else if (t == IRT_I64 || t == IRT_U64) { + sp = emitir(IRT(IR_FLOAD, t), sp, IRFL_CDATA_INT64); + lj_needsplit(J); + goto doconv; + } else if (t == IRT_INT || t == IRT_U32) { + if (ctype_isenum(s->info)) s = ctype_child(cts, s); + sp = emitir(IRT(IR_FLOAD, t), sp, IRFL_CDATA_INT); + goto doconv; + } else { + sp = emitir(IRT(IR_ADD, IRT_PTR), sp, lj_ir_kintp(J, sizeof(GCcdata))); + } + if (ctype_isnum(s->info) && t != IRT_CDATA) + sp = emitir(IRT(IR_XLOAD, t), sp, 0); /* Load number value. */ + goto doconv; + } + s = ctype_get(cts, sid); +doconv: + if (ctype_isenum(d->info)) d = ctype_child(cts, d); + return crec_ct_ct(J, d, s, dp, sp, svisnz); +} + +/* -- C data metamethods -------------------------------------------------- */ + +/* This would be rather difficult in FOLD, so do it here: +** (base+k)+(idx*sz)+ofs ==> (base+idx*sz)+(ofs+k) +** (base+(idx+k)*sz)+ofs ==> (base+idx*sz)+(ofs+k*sz) +*/ +static TRef crec_reassoc_ofs(jit_State *J, TRef tr, ptrdiff_t *ofsp, MSize sz) +{ + IRIns *ir = IR(tref_ref(tr)); + if (LJ_LIKELY(J->flags & JIT_F_OPT_FOLD) && irref_isk(ir->op2) && + (ir->o == IR_ADD || ir->o == IR_ADDOV || ir->o == IR_SUBOV)) { + IRIns *irk = IR(ir->op2); + ptrdiff_t k; + if (LJ_64 && irk->o == IR_KINT64) + k = (ptrdiff_t)ir_kint64(irk)->u64 * sz; + else + k = (ptrdiff_t)irk->i * sz; + if (ir->o == IR_SUBOV) *ofsp -= k; else *ofsp += k; + tr = ir->op1; /* Not a TRef, but the caller doesn't care. */ + } + return tr; +} + +/* Tailcall to function. */ +static void crec_tailcall(jit_State *J, RecordFFData *rd, cTValue *tv) +{ + TRef kfunc = lj_ir_kfunc(J, funcV(tv)); +#if LJ_FR2 + J->base[-2] = kfunc; + J->base[-1] = TREF_FRAME; +#else + J->base[-1] = kfunc | TREF_FRAME; +#endif + rd->nres = -1; /* Pending tailcall. */ +} + +/* Record ctype __index/__newindex metamethods. */ +static void crec_index_meta(jit_State *J, CTState *cts, CType *ct, + RecordFFData *rd) +{ + CTypeID id = ctype_typeid(cts, ct); + cTValue *tv = lj_ctype_meta(cts, id, rd->data ? MM_newindex : MM_index); + if (!tv) + lj_trace_err(J, LJ_TRERR_BADTYPE); + if (tvisfunc(tv)) { + crec_tailcall(J, rd, tv); + } else if (rd->data == 0 && tvistab(tv) && tref_isstr(J->base[1])) { + /* Specialize to result of __index lookup. */ + cTValue *o = lj_tab_get(J->L, tabV(tv), &rd->argv[1]); + J->base[0] = lj_record_constify(J, o); + if (!J->base[0]) + lj_trace_err(J, LJ_TRERR_BADTYPE); + /* Always specialize to the key. */ + emitir(IRTG(IR_EQ, IRT_STR), J->base[1], lj_ir_kstr(J, strV(&rd->argv[1]))); + } else { + /* NYI: resolving of non-function metamethods. */ + /* NYI: non-string keys for __index table. */ + /* NYI: stores to __newindex table. */ + lj_trace_err(J, LJ_TRERR_BADTYPE); + } +} + +/* Record bitfield load/store. */ +static void crec_index_bf(jit_State *J, RecordFFData *rd, TRef ptr, CTInfo info) +{ + IRType t = IRT_I8 + 2*lj_fls(ctype_bitcsz(info)) + ((info&CTF_UNSIGNED)?1:0); + TRef tr = emitir(IRT(IR_XLOAD, t), ptr, 0); + CTSize pos = ctype_bitpos(info), bsz = ctype_bitbsz(info), shift = 32 - bsz; + lj_assertJ(t <= IRT_U32, "only 32 bit bitfields supported"); /* NYI */ + if (rd->data == 0) { /* __index metamethod. */ + if ((info & CTF_BOOL)) { + tr = emitir(IRTI(IR_BAND), tr, lj_ir_kint(J, (int32_t)((1u << pos)))); + /* Assume not equal to zero. Fixup and emit pending guard later. */ + lj_ir_set(J, IRTGI(IR_NE), tr, lj_ir_kint(J, 0)); + J->postproc = LJ_POST_FIXGUARD; + tr = TREF_TRUE; + } else if (!(info & CTF_UNSIGNED)) { + tr = emitir(IRTI(IR_BSHL), tr, lj_ir_kint(J, shift - pos)); + tr = emitir(IRTI(IR_BSAR), tr, lj_ir_kint(J, shift)); + } else { + lj_assertJ(bsz < 32, "unexpected full bitfield index"); + tr = emitir(IRTI(IR_BSHR), tr, lj_ir_kint(J, pos)); + tr = emitir(IRTI(IR_BAND), tr, lj_ir_kint(J, (int32_t)((1u << bsz)-1))); + /* We can omit the U32 to NUM conversion, since bsz < 32. */ + } + J->base[0] = tr; + } else { /* __newindex metamethod. */ + CTState *cts = ctype_ctsG(J2G(J)); + CType *ct = ctype_get(cts, + (info & CTF_BOOL) ? CTID_BOOL : + (info & CTF_UNSIGNED) ? CTID_UINT32 : CTID_INT32); + int32_t mask = (int32_t)(((1u << bsz)-1) << pos); + TRef sp = crec_ct_tv(J, ct, 0, J->base[2], &rd->argv[2]); + sp = emitir(IRTI(IR_BSHL), sp, lj_ir_kint(J, pos)); + /* Use of the target type avoids forwarding conversions. */ + sp = emitir(IRT(IR_BAND, t), sp, lj_ir_kint(J, mask)); + tr = emitir(IRT(IR_BAND, t), tr, lj_ir_kint(J, (int32_t)~mask)); + tr = emitir(IRT(IR_BOR, t), tr, sp); + emitir(IRT(IR_XSTORE, t), ptr, tr); + rd->nres = 0; + J->needsnap = 1; + } +} + +void LJ_FASTCALL recff_cdata_index(jit_State *J, RecordFFData *rd) +{ + TRef idx, ptr = J->base[0]; + ptrdiff_t ofs = sizeof(GCcdata); + GCcdata *cd = argv2cdata(J, ptr, &rd->argv[0]); + CTState *cts = ctype_ctsG(J2G(J)); + CType *ct = ctype_raw(cts, cd->ctypeid); + CTypeID sid = 0; + + /* Resolve pointer or reference for cdata object. */ + if (ctype_isptr(ct->info)) { + IRType t = (LJ_64 && ct->size == 8) ? IRT_P64 : IRT_P32; + if (ctype_isref(ct->info)) ct = ctype_rawchild(cts, ct); + ptr = emitir(IRT(IR_FLOAD, t), ptr, IRFL_CDATA_PTR); + ofs = 0; + ptr = crec_reassoc_ofs(J, ptr, &ofs, 1); + } + +again: + idx = J->base[1]; + if (tref_isnumber(idx)) { + idx = lj_opt_narrow_cindex(J, idx); + if (ctype_ispointer(ct->info)) { + CTSize sz; + integer_key: + if ((ct->info & CTF_COMPLEX)) + idx = emitir(IRT(IR_BAND, IRT_INTP), idx, lj_ir_kintp(J, 1)); + sz = lj_ctype_size(cts, (sid = ctype_cid(ct->info))); + idx = crec_reassoc_ofs(J, idx, &ofs, sz); +#if LJ_TARGET_ARM || LJ_TARGET_PPC + /* Hoist base add to allow fusion of index/shift into operands. */ + if (LJ_LIKELY(J->flags & JIT_F_OPT_LOOP) && ofs +#if LJ_TARGET_ARM + && (sz == 1 || sz == 4) +#endif + ) { + ptr = emitir(IRT(IR_ADD, IRT_PTR), ptr, lj_ir_kintp(J, ofs)); + ofs = 0; + } +#endif + idx = emitir(IRT(IR_MUL, IRT_INTP), idx, lj_ir_kintp(J, sz)); + ptr = emitir(IRT(IR_ADD, IRT_PTR), idx, ptr); + } + } else if (tref_iscdata(idx)) { + GCcdata *cdk = cdataV(&rd->argv[1]); + CType *ctk = ctype_raw(cts, cdk->ctypeid); + IRType t = crec_ct2irt(cts, ctk); + if (ctype_ispointer(ct->info) && t >= IRT_I8 && t <= IRT_U64) { + if (ctk->size == 8) { + idx = emitir(IRT(IR_FLOAD, t), idx, IRFL_CDATA_INT64); + } else if (ctk->size == 4) { + idx = emitir(IRT(IR_FLOAD, t), idx, IRFL_CDATA_INT); + } else { + idx = emitir(IRT(IR_ADD, IRT_PTR), idx, + lj_ir_kintp(J, sizeof(GCcdata))); + idx = emitir(IRT(IR_XLOAD, t), idx, 0); + } + if (LJ_64 && ctk->size < sizeof(intptr_t) && !(ctk->info & CTF_UNSIGNED)) + idx = emitconv(idx, IRT_INTP, IRT_INT, IRCONV_SEXT); + if (!LJ_64 && ctk->size > sizeof(intptr_t)) { + idx = emitconv(idx, IRT_INTP, t, 0); + lj_needsplit(J); + } + goto integer_key; + } + } else if (tref_isstr(idx)) { + GCstr *name = strV(&rd->argv[1]); + if (cd && cd->ctypeid == CTID_CTYPEID) + ct = ctype_raw(cts, crec_constructor(J, cd, ptr)); + if (ctype_isstruct(ct->info)) { + CTSize fofs; + CType *fct; + fct = lj_ctype_getfield(cts, ct, name, &fofs); + if (fct) { + ofs += (ptrdiff_t)fofs; + /* Always specialize to the field name. */ + emitir(IRTG(IR_EQ, IRT_STR), idx, lj_ir_kstr(J, name)); + if (ctype_isconstval(fct->info)) { + if (fct->size >= 0x80000000u && + (ctype_child(cts, fct)->info & CTF_UNSIGNED)) { + J->base[0] = lj_ir_knum(J, (lua_Number)(uint32_t)fct->size); + return; + } + J->base[0] = lj_ir_kint(J, (int32_t)fct->size); + return; /* Interpreter will throw for newindex. */ + } else if (ctype_isbitfield(fct->info)) { + if (ofs) + ptr = emitir(IRT(IR_ADD, IRT_PTR), ptr, lj_ir_kintp(J, ofs)); + crec_index_bf(J, rd, ptr, fct->info); + return; + } else { + lj_assertJ(ctype_isfield(fct->info), "field expected"); + sid = ctype_cid(fct->info); + } + } + } else if (ctype_iscomplex(ct->info)) { + if (name->len == 2 && + ((strdata(name)[0] == 'r' && strdata(name)[1] == 'e') || + (strdata(name)[0] == 'i' && strdata(name)[1] == 'm'))) { + /* Always specialize to the field name. */ + emitir(IRTG(IR_EQ, IRT_STR), idx, lj_ir_kstr(J, name)); + if (strdata(name)[0] == 'i') ofs += (ct->size >> 1); + sid = ctype_cid(ct->info); + } + } + } + if (!sid) { + if (ctype_isptr(ct->info)) { /* Automatically perform '->'. */ + CType *cct = ctype_rawchild(cts, ct); + if (ctype_isstruct(cct->info)) { + ct = cct; + cd = NULL; + if (tref_isstr(idx)) goto again; + } + } + crec_index_meta(J, cts, ct, rd); + return; + } + + if (ofs) + ptr = emitir(IRT(IR_ADD, IRT_PTR), ptr, lj_ir_kintp(J, ofs)); + + /* Resolve reference for field. */ + ct = ctype_get(cts, sid); + if (ctype_isref(ct->info)) { + ptr = emitir(IRT(IR_XLOAD, IRT_PTR), ptr, 0); + sid = ctype_cid(ct->info); + ct = ctype_get(cts, sid); + } + + while (ctype_isattrib(ct->info)) + ct = ctype_child(cts, ct); /* Skip attributes. */ + + if (rd->data == 0) { /* __index metamethod. */ + J->base[0] = crec_tv_ct(J, ct, sid, ptr); + } else { /* __newindex metamethod. */ + rd->nres = 0; + J->needsnap = 1; + crec_ct_tv(J, ct, ptr, J->base[2], &rd->argv[2]); + } +} + +/* Record setting a finalizer. */ +static void crec_finalizer(jit_State *J, TRef trcd, TRef trfin, cTValue *fin) +{ + if (tvisgcv(fin)) { + if (!trfin) trfin = lj_ir_kptr(J, gcval(fin)); + } else if (tvisnil(fin)) { + trfin = lj_ir_kptr(J, NULL); + } else { + lj_trace_err(J, LJ_TRERR_BADTYPE); + } + lj_ir_call(J, IRCALL_lj_cdata_setfin, trcd, + trfin, lj_ir_kint(J, (int32_t)itype(fin))); + J->needsnap = 1; +} + +/* Record cdata allocation. */ +static void crec_alloc(jit_State *J, RecordFFData *rd, CTypeID id) +{ + CTState *cts = ctype_ctsG(J2G(J)); + CTSize sz; + CTInfo info = lj_ctype_info(cts, id, &sz); + CType *d = ctype_raw(cts, id); + TRef trcd, trid = lj_ir_kint(J, id); + cTValue *fin; + /* Use special instruction to box pointer or 32/64 bit integer. */ + if (ctype_isptr(info) || (ctype_isinteger(info) && (sz == 4 || sz == 8))) { + TRef sp = J->base[1] ? crec_ct_tv(J, d, 0, J->base[1], &rd->argv[1]) : + ctype_isptr(info) ? lj_ir_kptr(J, NULL) : + sz == 4 ? lj_ir_kint(J, 0) : + (lj_needsplit(J), lj_ir_kint64(J, 0)); + J->base[0] = emitir(IRTG(IR_CNEWI, IRT_CDATA), trid, sp); + return; + } else { + TRef trsz = TREF_NIL; + if ((info & CTF_VLA)) { /* Calculate VLA/VLS size at runtime. */ + CTSize sz0, sz1; + if (!J->base[1] || J->base[2]) + lj_trace_err(J, LJ_TRERR_NYICONV); /* NYI: init VLA/VLS. */ + trsz = crec_ct_tv(J, ctype_get(cts, CTID_INT32), 0, + J->base[1], &rd->argv[1]); + sz0 = lj_ctype_vlsize(cts, d, 0); + sz1 = lj_ctype_vlsize(cts, d, 1); + trsz = emitir(IRTGI(IR_MULOV), trsz, lj_ir_kint(J, (int32_t)(sz1-sz0))); + trsz = emitir(IRTGI(IR_ADDOV), trsz, lj_ir_kint(J, (int32_t)sz0)); + J->base[1] = 0; /* Simplify logic below. */ + } else if (ctype_align(info) > CT_MEMALIGN) { + trsz = lj_ir_kint(J, sz); + } + trcd = emitir(IRTG(IR_CNEW, IRT_CDATA), trid, trsz); + if (sz > 128 || (info & CTF_VLA)) { + TRef dp; + CTSize align; + special: /* Only handle bulk zero-fill for large/VLA/VLS types. */ + if (J->base[1]) + lj_trace_err(J, LJ_TRERR_NYICONV); /* NYI: init large/VLA/VLS types. */ + dp = emitir(IRT(IR_ADD, IRT_PTR), trcd, lj_ir_kintp(J, sizeof(GCcdata))); + if (trsz == TREF_NIL) trsz = lj_ir_kint(J, sz); + align = ctype_align(info); + if (align < CT_MEMALIGN) align = CT_MEMALIGN; + crec_fill(J, dp, trsz, lj_ir_kint(J, 0), (1u << align)); + } else if (J->base[1] && !J->base[2] && + !lj_cconv_multi_init(cts, d, &rd->argv[1])) { + goto single_init; + } else if (ctype_isarray(d->info)) { + CType *dc = ctype_rawchild(cts, d); /* Array element type. */ + CTSize ofs, esize = dc->size; + TRef sp = 0; + TValue tv; + TValue *sval = &tv; + MSize i; + tv.u64 = 0; + if (!(ctype_isnum(dc->info) || ctype_isptr(dc->info)) || + esize * CREC_FILL_MAXUNROLL < sz) + goto special; + for (i = 1, ofs = 0; ofs < sz; ofs += esize) { + TRef dp = emitir(IRT(IR_ADD, IRT_PTR), trcd, + lj_ir_kintp(J, ofs + sizeof(GCcdata))); + if (J->base[i]) { + sp = J->base[i]; + sval = &rd->argv[i]; + i++; + } else if (i != 2) { + sp = ctype_isnum(dc->info) ? lj_ir_kint(J, 0) : TREF_NIL; + } + crec_ct_tv(J, dc, dp, sp, sval); + } + } else if (ctype_isstruct(d->info)) { + CTypeID fid; + MSize i = 1; + if (!J->base[1]) { /* Handle zero-fill of struct-of-NYI. */ + fid = d->sib; + while (fid) { + CType *df = ctype_get(cts, fid); + fid = df->sib; + if (ctype_isfield(df->info)) { + CType *dc; + if (!gcref(df->name)) continue; /* Ignore unnamed fields. */ + dc = ctype_rawchild(cts, df); /* Field type. */ + if (!(ctype_isnum(dc->info) || ctype_isptr(dc->info) || + ctype_isenum(dc->info))) + goto special; + } else if (!ctype_isconstval(df->info)) { + goto special; + } + } + } + fid = d->sib; + while (fid) { + CType *df = ctype_get(cts, fid); + fid = df->sib; + if (ctype_isfield(df->info)) { + CType *dc; + TRef sp, dp; + TValue tv; + TValue *sval = &tv; + setintV(&tv, 0); + if (!gcref(df->name)) continue; /* Ignore unnamed fields. */ + dc = ctype_rawchild(cts, df); /* Field type. */ + if (!(ctype_isnum(dc->info) || ctype_isptr(dc->info) || + ctype_isenum(dc->info))) + lj_trace_err(J, LJ_TRERR_NYICONV); /* NYI: init aggregates. */ + if (J->base[i]) { + sp = J->base[i]; + sval = &rd->argv[i]; + i++; + } else { + sp = ctype_isptr(dc->info) ? TREF_NIL : lj_ir_kint(J, 0); + } + dp = emitir(IRT(IR_ADD, IRT_PTR), trcd, + lj_ir_kintp(J, df->size + sizeof(GCcdata))); + crec_ct_tv(J, dc, dp, sp, sval); + if ((d->info & CTF_UNION)) { + if (d->size != dc->size) /* NYI: partial init of union. */ + lj_trace_err(J, LJ_TRERR_NYICONV); + break; + } + } else if (!ctype_isconstval(df->info)) { + /* NYI: init bitfields and sub-structures. */ + lj_trace_err(J, LJ_TRERR_NYICONV); + } + } + } else { + TRef dp; + single_init: + dp = emitir(IRT(IR_ADD, IRT_PTR), trcd, lj_ir_kintp(J, sizeof(GCcdata))); + if (J->base[1]) { + crec_ct_tv(J, d, dp, J->base[1], &rd->argv[1]); + } else { + TValue tv; + tv.u64 = 0; + crec_ct_tv(J, d, dp, lj_ir_kint(J, 0), &tv); + } + } + } + J->base[0] = trcd; + /* Handle __gc metamethod. */ + fin = lj_ctype_meta(cts, id, MM_gc); + if (fin) + crec_finalizer(J, trcd, 0, fin); +} + +/* Record argument conversions. */ +static TRef crec_call_args(jit_State *J, RecordFFData *rd, + CTState *cts, CType *ct) +{ + TRef args[CCI_NARGS_MAX]; + CTypeID fid; + MSize i, n; + TRef tr, *base; + cTValue *o; +#if LJ_TARGET_X86 +#if LJ_ABI_WIN + TRef *arg0 = NULL, *arg1 = NULL; +#endif + int ngpr = 0; + if (ctype_cconv(ct->info) == CTCC_THISCALL) + ngpr = 1; + else if (ctype_cconv(ct->info) == CTCC_FASTCALL) + ngpr = 2; +#endif + + /* Skip initial attributes. */ + fid = ct->sib; + while (fid) { + CType *ctf = ctype_get(cts, fid); + if (!ctype_isattrib(ctf->info)) break; + fid = ctf->sib; + } + args[0] = TREF_NIL; + for (n = 0, base = J->base+1, o = rd->argv+1; *base; n++, base++, o++) { + CTypeID did; + CType *d; + + if (n >= CCI_NARGS_MAX) + lj_trace_err(J, LJ_TRERR_NYICALL); + + if (fid) { /* Get argument type from field. */ + CType *ctf = ctype_get(cts, fid); + fid = ctf->sib; + lj_assertJ(ctype_isfield(ctf->info), "field expected"); + did = ctype_cid(ctf->info); + } else { + if (!(ct->info & CTF_VARARG)) + lj_trace_err(J, LJ_TRERR_NYICALL); /* Too many arguments. */ + did = lj_ccall_ctid_vararg(cts, o); /* Infer vararg type. */ + } + d = ctype_raw(cts, did); + if (!(ctype_isnum(d->info) || ctype_isptr(d->info) || + ctype_isenum(d->info))) + lj_trace_err(J, LJ_TRERR_NYICALL); + tr = crec_ct_tv(J, d, 0, *base, o); + if (ctype_isinteger_or_bool(d->info)) { + if (d->size < 4) { + if ((d->info & CTF_UNSIGNED)) + tr = emitconv(tr, IRT_INT, d->size==1 ? IRT_U8 : IRT_U16, 0); + else + tr = emitconv(tr, IRT_INT, d->size==1 ? IRT_I8 : IRT_I16,IRCONV_SEXT); + } + } else if (LJ_SOFTFP32 && ctype_isfp(d->info) && d->size > 4) { + lj_needsplit(J); + } +#if LJ_TARGET_X86 + /* 64 bit args must not end up in registers for fastcall/thiscall. */ +#if LJ_ABI_WIN + if (!ctype_isfp(d->info)) { + /* Sigh, the Windows/x86 ABI allows reordering across 64 bit args. */ + if (tref_typerange(tr, IRT_I64, IRT_U64)) { + if (ngpr) { + arg0 = &args[n]; args[n++] = TREF_NIL; ngpr--; + if (ngpr) { + arg1 = &args[n]; args[n++] = TREF_NIL; ngpr--; + } + } + } else { + if (arg0) { *arg0 = tr; arg0 = NULL; n--; continue; } + if (arg1) { *arg1 = tr; arg1 = NULL; n--; continue; } + if (ngpr) ngpr--; + } + } +#else + if (!ctype_isfp(d->info) && ngpr) { + if (tref_typerange(tr, IRT_I64, IRT_U64)) { + /* No reordering for other x86 ABIs. Simply add alignment args. */ + do { args[n++] = TREF_NIL; } while (--ngpr); + } else { + ngpr--; + } + } +#endif +#endif + args[n] = tr; + } + tr = args[0]; + for (i = 1; i < n; i++) + tr = emitir(IRT(IR_CARG, IRT_NIL), tr, args[i]); + return tr; +} + +/* Create a snapshot for the caller, simulating a 'false' return value. */ +static void crec_snap_caller(jit_State *J) +{ + lua_State *L = J->L; + TValue *base = L->base, *top = L->top; + const BCIns *pc = J->pc; + TRef ftr = J->base[-1-LJ_FR2]; + ptrdiff_t delta; + if (!frame_islua(base-1) || J->framedepth <= 0) + lj_trace_err(J, LJ_TRERR_NYICALL); + J->pc = frame_pc(base-1); delta = 1+LJ_FR2+bc_a(J->pc[-1]); + L->top = base; L->base = base - delta; + J->base[-1-LJ_FR2] = TREF_FALSE; + J->base -= delta; J->baseslot -= (BCReg)delta; + J->maxslot = (BCReg)delta-LJ_FR2; J->framedepth--; + lj_snap_add(J); + L->base = base; L->top = top; + J->framedepth++; J->maxslot = 1; + J->base += delta; J->baseslot += (BCReg)delta; + J->base[-1-LJ_FR2] = ftr; J->pc = pc; +} + +/* Record function call. */ +static int crec_call(jit_State *J, RecordFFData *rd, GCcdata *cd) +{ + CTState *cts = ctype_ctsG(J2G(J)); + CType *ct = ctype_raw(cts, cd->ctypeid); + IRType tp = IRT_PTR; + if (ctype_isptr(ct->info)) { + tp = (LJ_64 && ct->size == 8) ? IRT_P64 : IRT_P32; + ct = ctype_rawchild(cts, ct); + } + if (ctype_isfunc(ct->info)) { + TRef func = emitir(IRT(IR_FLOAD, tp), J->base[0], IRFL_CDATA_PTR); + CType *ctr = ctype_rawchild(cts, ct); + IRType t = crec_ct2irt(cts, ctr); + TRef tr; + TValue tv; + /* Check for blacklisted C functions that might call a callback. */ + tv.u64 = ((uintptr_t)cdata_getptr(cdataptr(cd), (LJ_64 && tp == IRT_P64) ? 8 : 4) >> 2) | U64x(800000000, 00000000); + if (tvistrue(lj_tab_get(J->L, cts->miscmap, &tv))) + lj_trace_err(J, LJ_TRERR_BLACKL); + if (ctype_isvoid(ctr->info)) { + t = IRT_NIL; + rd->nres = 0; + } else if (!(ctype_isnum(ctr->info) || ctype_isptr(ctr->info) || + ctype_isenum(ctr->info)) || t == IRT_CDATA) { + lj_trace_err(J, LJ_TRERR_NYICALL); + } + if ((ct->info & CTF_VARARG) +#if LJ_TARGET_X86 + || ctype_cconv(ct->info) != CTCC_CDECL +#endif + ) + func = emitir(IRT(IR_CARG, IRT_NIL), func, + lj_ir_kint(J, ctype_typeid(cts, ct))); + tr = emitir(IRT(IR_CALLXS, t), crec_call_args(J, rd, cts, ct), func); + if (ctype_isbool(ctr->info)) { + if (frame_islua(J->L->base-1) && bc_b(frame_pc(J->L->base-1)[-1]) == 1) { + /* Don't check result if ignored. */ + tr = TREF_NIL; + } else { + crec_snap_caller(J); +#if LJ_TARGET_X86ORX64 + /* Note: only the x86/x64 backend supports U8 and only for EQ(tr, 0). */ + lj_ir_set(J, IRTG(IR_NE, IRT_U8), tr, lj_ir_kint(J, 0)); +#else + lj_ir_set(J, IRTGI(IR_NE), tr, lj_ir_kint(J, 0)); +#endif + J->postproc = LJ_POST_FIXGUARDSNAP; + tr = TREF_TRUE; + } + } else if (t == IRT_PTR || (LJ_64 && t == IRT_P32) || + t == IRT_I64 || t == IRT_U64 || ctype_isenum(ctr->info)) { + TRef trid = lj_ir_kint(J, ctype_cid(ct->info)); + tr = emitir(IRTG(IR_CNEWI, IRT_CDATA), trid, tr); + if (t == IRT_I64 || t == IRT_U64) lj_needsplit(J); + } else if (t == IRT_FLOAT || t == IRT_U32) { + tr = emitconv(tr, IRT_NUM, t, 0); + } else if (t == IRT_I8 || t == IRT_I16) { + tr = emitconv(tr, IRT_INT, t, IRCONV_SEXT); + } else if (t == IRT_U8 || t == IRT_U16) { + tr = emitconv(tr, IRT_INT, t, 0); + } + J->base[0] = tr; + J->needsnap = 1; + return 1; + } + return 0; +} + +void LJ_FASTCALL recff_cdata_call(jit_State *J, RecordFFData *rd) +{ + CTState *cts = ctype_ctsG(J2G(J)); + GCcdata *cd = argv2cdata(J, J->base[0], &rd->argv[0]); + CTypeID id = cd->ctypeid; + CType *ct; + cTValue *tv; + MMS mm = MM_call; + if (id == CTID_CTYPEID) { + id = crec_constructor(J, cd, J->base[0]); + mm = MM_new; + } else if (crec_call(J, rd, cd)) { + return; + } + /* Record ctype __call/__new metamethod. */ + ct = ctype_raw(cts, id); + tv = lj_ctype_meta(cts, ctype_isptr(ct->info) ? ctype_cid(ct->info) : id, mm); + if (tv) { + if (tvisfunc(tv)) { + crec_tailcall(J, rd, tv); + return; + } + } else if (mm == MM_new) { + crec_alloc(J, rd, id); + return; + } + /* No metamethod or NYI: non-function metamethods. */ + lj_trace_err(J, LJ_TRERR_BADTYPE); +} + +static TRef crec_arith_int64(jit_State *J, TRef *sp, CType **s, MMS mm) +{ + if (sp[0] && sp[1] && ctype_isnum(s[0]->info) && ctype_isnum(s[1]->info)) { + IRType dt; + CTypeID id; + TRef tr; + MSize i; + IROp op; + lj_needsplit(J); + if (((s[0]->info & CTF_UNSIGNED) && s[0]->size == 8) || + ((s[1]->info & CTF_UNSIGNED) && s[1]->size == 8)) { + dt = IRT_U64; id = CTID_UINT64; + } else { + dt = IRT_I64; id = CTID_INT64; + if (mm < MM_add && + !((s[0]->info | s[1]->info) & CTF_FP) && + s[0]->size == 4 && s[1]->size == 4) { /* Try to narrow comparison. */ + if (!((s[0]->info ^ s[1]->info) & CTF_UNSIGNED) || + (tref_isk(sp[1]) && IR(tref_ref(sp[1]))->i >= 0)) { + dt = (s[0]->info & CTF_UNSIGNED) ? IRT_U32 : IRT_INT; + goto comp; + } else if (tref_isk(sp[0]) && IR(tref_ref(sp[0]))->i >= 0) { + dt = (s[1]->info & CTF_UNSIGNED) ? IRT_U32 : IRT_INT; + goto comp; + } + } + } + for (i = 0; i < 2; i++) { + IRType st = tref_type(sp[i]); + if (st == IRT_NUM || st == IRT_FLOAT) + sp[i] = emitconv(sp[i], dt, st, IRCONV_ANY); + else if (!(st == IRT_I64 || st == IRT_U64)) + sp[i] = emitconv(sp[i], dt, IRT_INT, + (s[i]->info & CTF_UNSIGNED) ? 0 : IRCONV_SEXT); + } + if (mm < MM_add) { + comp: + /* Assume true comparison. Fixup and emit pending guard later. */ + if (mm == MM_eq) { + op = IR_EQ; + } else { + op = mm == MM_lt ? IR_LT : IR_LE; + if (dt == IRT_U32 || dt == IRT_U64) + op += (IR_ULT-IR_LT); + } + lj_ir_set(J, IRTG(op, dt), sp[0], sp[1]); + J->postproc = LJ_POST_FIXGUARD; + return TREF_TRUE; + } else { + tr = emitir(IRT(mm+(int)IR_ADD-(int)MM_add, dt), sp[0], sp[1]); + } + return emitir(IRTG(IR_CNEWI, IRT_CDATA), lj_ir_kint(J, id), tr); + } + return 0; +} + +static TRef crec_arith_ptr(jit_State *J, TRef *sp, CType **s, MMS mm) +{ + CTState *cts = ctype_ctsG(J2G(J)); + CType *ctp = s[0]; + if (!(sp[0] && sp[1])) return 0; + if (ctype_isptr(ctp->info) || ctype_isrefarray(ctp->info)) { + if ((mm == MM_sub || mm == MM_eq || mm == MM_lt || mm == MM_le) && + (ctype_isptr(s[1]->info) || ctype_isrefarray(s[1]->info))) { + if (mm == MM_sub) { /* Pointer difference. */ + TRef tr; + CTSize sz = lj_ctype_size(cts, ctype_cid(ctp->info)); + if (sz == 0 || (sz & (sz-1)) != 0) + return 0; /* NYI: integer division. */ + tr = emitir(IRT(IR_SUB, IRT_INTP), sp[0], sp[1]); + tr = emitir(IRT(IR_BSAR, IRT_INTP), tr, lj_ir_kint(J, lj_fls(sz))); +#if LJ_64 + tr = emitconv(tr, IRT_NUM, IRT_INTP, 0); +#endif + return tr; + } else { /* Pointer comparison (unsigned). */ + /* Assume true comparison. Fixup and emit pending guard later. */ + IROp op = mm == MM_eq ? IR_EQ : mm == MM_lt ? IR_ULT : IR_ULE; + lj_ir_set(J, IRTG(op, IRT_PTR), sp[0], sp[1]); + J->postproc = LJ_POST_FIXGUARD; + return TREF_TRUE; + } + } + if (!((mm == MM_add || mm == MM_sub) && ctype_isnum(s[1]->info))) + return 0; + } else if (mm == MM_add && ctype_isnum(ctp->info) && + (ctype_isptr(s[1]->info) || ctype_isrefarray(s[1]->info))) { + TRef tr = sp[0]; sp[0] = sp[1]; sp[1] = tr; /* Swap pointer and index. */ + ctp = s[1]; + } else { + return 0; + } + { + TRef tr = sp[1]; + IRType t = tref_type(tr); + CTSize sz = lj_ctype_size(cts, ctype_cid(ctp->info)); + CTypeID id; +#if LJ_64 + if (t == IRT_NUM || t == IRT_FLOAT) + tr = emitconv(tr, IRT_INTP, t, IRCONV_ANY); + else if (!(t == IRT_I64 || t == IRT_U64)) + tr = emitconv(tr, IRT_INTP, IRT_INT, + ((t - IRT_I8) & 1) ? 0 : IRCONV_SEXT); +#else + if (!tref_typerange(sp[1], IRT_I8, IRT_U32)) { + tr = emitconv(tr, IRT_INTP, t, + (t == IRT_NUM || t == IRT_FLOAT) ? IRCONV_ANY : 0); + } +#endif + tr = emitir(IRT(IR_MUL, IRT_INTP), tr, lj_ir_kintp(J, sz)); + tr = emitir(IRT(mm+(int)IR_ADD-(int)MM_add, IRT_PTR), sp[0], tr); + id = lj_ctype_intern(cts, CTINFO(CT_PTR, CTALIGN_PTR|ctype_cid(ctp->info)), + CTSIZE_PTR); + return emitir(IRTG(IR_CNEWI, IRT_CDATA), lj_ir_kint(J, id), tr); + } +} + +/* Record ctype arithmetic metamethods. */ +static TRef crec_arith_meta(jit_State *J, TRef *sp, CType **s, CTState *cts, + RecordFFData *rd) +{ + cTValue *tv = NULL; + if (J->base[0]) { + if (tviscdata(&rd->argv[0])) { + CTypeID id = argv2cdata(J, J->base[0], &rd->argv[0])->ctypeid; + CType *ct = ctype_raw(cts, id); + if (ctype_isptr(ct->info)) id = ctype_cid(ct->info); + tv = lj_ctype_meta(cts, id, (MMS)rd->data); + } + if (!tv && J->base[1] && tviscdata(&rd->argv[1])) { + CTypeID id = argv2cdata(J, J->base[1], &rd->argv[1])->ctypeid; + CType *ct = ctype_raw(cts, id); + if (ctype_isptr(ct->info)) id = ctype_cid(ct->info); + tv = lj_ctype_meta(cts, id, (MMS)rd->data); + } + } + if (tv) { + if (tvisfunc(tv)) { + crec_tailcall(J, rd, tv); + return 0; + } /* NYI: non-function metamethods. */ + } else if ((MMS)rd->data == MM_eq) { /* Fallback cdata pointer comparison. */ + if (sp[0] && sp[1] && ctype_isnum(s[0]->info) == ctype_isnum(s[1]->info)) { + /* Assume true comparison. Fixup and emit pending guard later. */ + lj_ir_set(J, IRTG(IR_EQ, IRT_PTR), sp[0], sp[1]); + J->postproc = LJ_POST_FIXGUARD; + return TREF_TRUE; + } else { + return TREF_FALSE; + } + } + lj_trace_err(J, LJ_TRERR_BADTYPE); + return 0; +} + +void LJ_FASTCALL recff_cdata_arith(jit_State *J, RecordFFData *rd) +{ + CTState *cts = ctype_ctsG(J2G(J)); + TRef sp[2]; + CType *s[2]; + MSize i; + for (i = 0; i < 2; i++) { + TRef tr = J->base[i]; + CType *ct = ctype_get(cts, CTID_DOUBLE); + if (!tr) { + lj_trace_err(J, LJ_TRERR_BADTYPE); + } else if (tref_iscdata(tr)) { + CTypeID id = argv2cdata(J, tr, &rd->argv[i])->ctypeid; + IRType t; + ct = ctype_raw(cts, id); + t = crec_ct2irt(cts, ct); + if (ctype_isptr(ct->info)) { /* Resolve pointer or reference. */ + tr = emitir(IRT(IR_FLOAD, t), tr, IRFL_CDATA_PTR); + if (ctype_isref(ct->info)) { + ct = ctype_rawchild(cts, ct); + t = crec_ct2irt(cts, ct); + } + } else if (t == IRT_I64 || t == IRT_U64) { + tr = emitir(IRT(IR_FLOAD, t), tr, IRFL_CDATA_INT64); + lj_needsplit(J); + goto ok; + } else if (t == IRT_INT || t == IRT_U32) { + tr = emitir(IRT(IR_FLOAD, t), tr, IRFL_CDATA_INT); + if (ctype_isenum(ct->info)) ct = ctype_child(cts, ct); + goto ok; + } else if (ctype_isfunc(ct->info)) { + tr = emitir(IRT(IR_FLOAD, IRT_PTR), tr, IRFL_CDATA_PTR); + ct = ctype_get(cts, + lj_ctype_intern(cts, CTINFO(CT_PTR, CTALIGN_PTR|id), CTSIZE_PTR)); + goto ok; + } else { + tr = emitir(IRT(IR_ADD, IRT_PTR), tr, lj_ir_kintp(J, sizeof(GCcdata))); + } + if (ctype_isenum(ct->info)) ct = ctype_child(cts, ct); + if (ctype_isnum(ct->info)) { + if (t == IRT_CDATA) { + tr = 0; + } else { + if (t == IRT_I64 || t == IRT_U64) lj_needsplit(J); + tr = emitir(IRT(IR_XLOAD, t), tr, 0); + } + } + } else if (tref_isnil(tr)) { + tr = lj_ir_kptr(J, NULL); + ct = ctype_get(cts, CTID_P_VOID); + } else if (tref_isinteger(tr)) { + ct = ctype_get(cts, CTID_INT32); + } else if (tref_isstr(tr)) { + TRef tr2 = J->base[1-i]; + CTypeID id = argv2cdata(J, tr2, &rd->argv[1-i])->ctypeid; + ct = ctype_raw(cts, id); + if (ctype_isenum(ct->info)) { /* Match string against enum constant. */ + GCstr *str = strV(&rd->argv[i]); + CTSize ofs; + CType *cct = lj_ctype_getfield(cts, ct, str, &ofs); + if (cct && ctype_isconstval(cct->info)) { + /* Specialize to the name of the enum constant. */ + emitir(IRTG(IR_EQ, IRT_STR), tr, lj_ir_kstr(J, str)); + ct = ctype_child(cts, cct); + tr = lj_ir_kint(J, (int32_t)ofs); + } else { /* Interpreter will throw or return false. */ + ct = ctype_get(cts, CTID_P_VOID); + } + } else if (ctype_isptr(ct->info)) { + tr = emitir(IRT(IR_ADD, IRT_PTR), tr, lj_ir_kintp(J, sizeof(GCstr))); + } else { + ct = ctype_get(cts, CTID_P_VOID); + } + } else if (!tref_isnum(tr)) { + tr = 0; + ct = ctype_get(cts, CTID_P_VOID); + } + ok: + s[i] = ct; + sp[i] = tr; + } + { + TRef tr; + MMS mm = (MMS)rd->data; + if ((mm == MM_len || mm == MM_concat || + (!(tr = crec_arith_int64(J, sp, s, mm)) && + !(tr = crec_arith_ptr(J, sp, s, mm)))) && + !(tr = crec_arith_meta(J, sp, s, cts, rd))) + return; + J->base[0] = tr; + /* Fixup cdata comparisons, too. Avoids some cdata escapes. */ + if (J->postproc == LJ_POST_FIXGUARD && frame_iscont(J->L->base-1) && + !irt_isguard(J->guardemit)) { + const BCIns *pc = frame_contpc(J->L->base-1) - 1; + if (bc_op(*pc) <= BC_ISNEP) { + J2G(J)->tmptv.u64 = (uint64_t)(uintptr_t)pc; + J->postproc = LJ_POST_FIXCOMP; + } + } + } +} + +/* -- C library namespace metamethods ------------------------------------- */ + +void LJ_FASTCALL recff_clib_index(jit_State *J, RecordFFData *rd) +{ + CTState *cts = ctype_ctsG(J2G(J)); + if (tref_isudata(J->base[0]) && tref_isstr(J->base[1]) && + udataV(&rd->argv[0])->udtype == UDTYPE_FFI_CLIB) { + CLibrary *cl = (CLibrary *)uddata(udataV(&rd->argv[0])); + GCstr *name = strV(&rd->argv[1]); + CType *ct; + CTypeID id = lj_ctype_getname(cts, &ct, name, CLNS_INDEX); + cTValue *tv = lj_tab_getstr(cl->cache, name); + rd->nres = rd->data; + if (id && tv && !tvisnil(tv)) { + /* Specialize to the symbol name and make the result a constant. */ + emitir(IRTG(IR_EQ, IRT_STR), J->base[1], lj_ir_kstr(J, name)); + if (ctype_isconstval(ct->info)) { + if (ct->size >= 0x80000000u && + (ctype_child(cts, ct)->info & CTF_UNSIGNED)) + J->base[0] = lj_ir_knum(J, (lua_Number)(uint32_t)ct->size); + else + J->base[0] = lj_ir_kint(J, (int32_t)ct->size); + } else if (ctype_isextern(ct->info)) { + CTypeID sid = ctype_cid(ct->info); + void *sp = *(void **)cdataptr(cdataV(tv)); + TRef ptr; + ct = ctype_raw(cts, sid); + if (LJ_64 && !checkptr32(sp)) + ptr = lj_ir_kintp(J, (uintptr_t)sp); + else + ptr = lj_ir_kptr(J, sp); + if (rd->data) { + J->base[0] = crec_tv_ct(J, ct, sid, ptr); + } else { + J->needsnap = 1; + crec_ct_tv(J, ct, ptr, J->base[2], &rd->argv[2]); + } + } else { + J->base[0] = lj_ir_kgc(J, obj2gco(cdataV(tv)), IRT_CDATA); + } + } else { + lj_trace_err(J, LJ_TRERR_NOCACHE); + } + } /* else: interpreter will throw. */ +} + +/* -- FFI library functions ----------------------------------------------- */ + +static TRef crec_toint(jit_State *J, CTState *cts, TRef sp, TValue *sval) +{ + return crec_ct_tv(J, ctype_get(cts, CTID_INT32), 0, sp, sval); +} + +void LJ_FASTCALL recff_ffi_new(jit_State *J, RecordFFData *rd) +{ + crec_alloc(J, rd, argv2ctype(J, J->base[0], &rd->argv[0])); +} + +void LJ_FASTCALL recff_ffi_errno(jit_State *J, RecordFFData *rd) +{ + UNUSED(rd); + if (J->base[0]) + lj_trace_err(J, LJ_TRERR_NYICALL); + J->base[0] = lj_ir_call(J, IRCALL_lj_vm_errno); +} + +void LJ_FASTCALL recff_ffi_string(jit_State *J, RecordFFData *rd) +{ + CTState *cts = ctype_ctsG(J2G(J)); + TRef tr = J->base[0]; + if (tr) { + TRef trlen = J->base[1]; + if (!tref_isnil(trlen)) { + trlen = crec_toint(J, cts, trlen, &rd->argv[1]); + tr = crec_ct_tv(J, ctype_get(cts, CTID_P_CVOID), 0, tr, &rd->argv[0]); + } else { + tr = crec_ct_tv(J, ctype_get(cts, CTID_P_CCHAR), 0, tr, &rd->argv[0]); + trlen = lj_ir_call(J, IRCALL_strlen, tr); + } + J->base[0] = emitir(IRT(IR_XSNEW, IRT_STR), tr, trlen); + } /* else: interpreter will throw. */ +} + +void LJ_FASTCALL recff_ffi_copy(jit_State *J, RecordFFData *rd) +{ + CTState *cts = ctype_ctsG(J2G(J)); + TRef trdst = J->base[0], trsrc = J->base[1], trlen = J->base[2]; + if (trdst && trsrc && (trlen || tref_isstr(trsrc))) { + trdst = crec_ct_tv(J, ctype_get(cts, CTID_P_VOID), 0, trdst, &rd->argv[0]); + trsrc = crec_ct_tv(J, ctype_get(cts, CTID_P_CVOID), 0, trsrc, &rd->argv[1]); + if (trlen) { + trlen = crec_toint(J, cts, trlen, &rd->argv[2]); + } else { + trlen = emitir(IRTI(IR_FLOAD), J->base[1], IRFL_STR_LEN); + trlen = emitir(IRTI(IR_ADD), trlen, lj_ir_kint(J, 1)); + } + rd->nres = 0; + crec_copy(J, trdst, trsrc, trlen, NULL); + } /* else: interpreter will throw. */ +} + +void LJ_FASTCALL recff_ffi_fill(jit_State *J, RecordFFData *rd) +{ + CTState *cts = ctype_ctsG(J2G(J)); + TRef trdst = J->base[0], trlen = J->base[1], trfill = J->base[2]; + if (trdst && trlen) { + CTSize step = 1; + if (tviscdata(&rd->argv[0])) { /* Get alignment of original destination. */ + CTSize sz; + CType *ct = ctype_raw(cts, cdataV(&rd->argv[0])->ctypeid); + if (ctype_isptr(ct->info)) + ct = ctype_rawchild(cts, ct); + step = (1u<argv[0]); + trlen = crec_toint(J, cts, trlen, &rd->argv[1]); + if (trfill) + trfill = crec_toint(J, cts, trfill, &rd->argv[2]); + else + trfill = lj_ir_kint(J, 0); + rd->nres = 0; + crec_fill(J, trdst, trlen, trfill, step); + } /* else: interpreter will throw. */ +} + +void LJ_FASTCALL recff_ffi_typeof(jit_State *J, RecordFFData *rd) +{ + if (tref_iscdata(J->base[0])) { + TRef trid = lj_ir_kint(J, argv2ctype(J, J->base[0], &rd->argv[0])); + J->base[0] = emitir(IRTG(IR_CNEWI, IRT_CDATA), + lj_ir_kint(J, CTID_CTYPEID), trid); + } else { + setfuncV(J->L, &J->errinfo, J->fn); + lj_trace_err_info(J, LJ_TRERR_NYIFFU); + } +} + +void LJ_FASTCALL recff_ffi_istype(jit_State *J, RecordFFData *rd) +{ + argv2ctype(J, J->base[0], &rd->argv[0]); + if (tref_iscdata(J->base[1])) { + argv2ctype(J, J->base[1], &rd->argv[1]); + J->postproc = LJ_POST_FIXBOOL; + J->base[0] = TREF_TRUE; + } else { + J->base[0] = TREF_FALSE; + } +} + +void LJ_FASTCALL recff_ffi_abi(jit_State *J, RecordFFData *rd) +{ + if (tref_isstr(J->base[0])) { + /* Specialize to the ABI string to make the boolean result a constant. */ + emitir(IRTG(IR_EQ, IRT_STR), J->base[0], lj_ir_kstr(J, strV(&rd->argv[0]))); + J->postproc = LJ_POST_FIXBOOL; + J->base[0] = TREF_TRUE; + } else { + lj_trace_err(J, LJ_TRERR_BADTYPE); + } +} + +/* Record ffi.sizeof(), ffi.alignof(), ffi.offsetof(). */ +void LJ_FASTCALL recff_ffi_xof(jit_State *J, RecordFFData *rd) +{ + CTypeID id = argv2ctype(J, J->base[0], &rd->argv[0]); + if (rd->data == FF_ffi_sizeof) { + CType *ct = lj_ctype_rawref(ctype_ctsG(J2G(J)), id); + if (ctype_isvltype(ct->info)) + lj_trace_err(J, LJ_TRERR_BADTYPE); + } else if (rd->data == FF_ffi_offsetof) { /* Specialize to the field name. */ + if (!tref_isstr(J->base[1])) + lj_trace_err(J, LJ_TRERR_BADTYPE); + emitir(IRTG(IR_EQ, IRT_STR), J->base[1], lj_ir_kstr(J, strV(&rd->argv[1]))); + rd->nres = 3; /* Just in case. */ + } + J->postproc = LJ_POST_FIXCONST; + J->base[0] = J->base[1] = J->base[2] = TREF_NIL; +} + +void LJ_FASTCALL recff_ffi_gc(jit_State *J, RecordFFData *rd) +{ + argv2cdata(J, J->base[0], &rd->argv[0]); + if (!J->base[1]) + lj_trace_err(J, LJ_TRERR_BADTYPE); + crec_finalizer(J, J->base[0], J->base[1], &rd->argv[1]); +} + +/* -- 64 bit bit.* library functions -------------------------------------- */ + +/* Determine bit operation type from argument type. */ +static CTypeID crec_bit64_type(CTState *cts, cTValue *tv) +{ + if (tviscdata(tv)) { + CType *ct = lj_ctype_rawref(cts, cdataV(tv)->ctypeid); + if (ctype_isenum(ct->info)) ct = ctype_child(cts, ct); + if ((ct->info & (CTMASK_NUM|CTF_BOOL|CTF_FP|CTF_UNSIGNED)) == + CTINFO(CT_NUM, CTF_UNSIGNED) && ct->size == 8) + return CTID_UINT64; /* Use uint64_t, since it has the highest rank. */ + return CTID_INT64; /* Otherwise use int64_t. */ + } + return 0; /* Use regular 32 bit ops. */ +} + +void LJ_FASTCALL recff_bit64_tobit(jit_State *J, RecordFFData *rd) +{ + CTState *cts = ctype_ctsG(J2G(J)); + TRef tr = crec_ct_tv(J, ctype_get(cts, CTID_INT64), 0, + J->base[0], &rd->argv[0]); + if (!tref_isinteger(tr)) + tr = emitconv(tr, IRT_INT, tref_type(tr), 0); + J->base[0] = tr; +} + +int LJ_FASTCALL recff_bit64_unary(jit_State *J, RecordFFData *rd) +{ + CTState *cts = ctype_ctsG(J2G(J)); + CTypeID id = crec_bit64_type(cts, &rd->argv[0]); + if (id) { + TRef tr = crec_ct_tv(J, ctype_get(cts, id), 0, J->base[0], &rd->argv[0]); + tr = emitir(IRT(rd->data, id-CTID_INT64+IRT_I64), tr, 0); + J->base[0] = emitir(IRTG(IR_CNEWI, IRT_CDATA), lj_ir_kint(J, id), tr); + return 1; + } + return 0; +} + +int LJ_FASTCALL recff_bit64_nary(jit_State *J, RecordFFData *rd) +{ + CTState *cts = ctype_ctsG(J2G(J)); + CTypeID id = 0; + MSize i; + for (i = 0; J->base[i] != 0; i++) { + CTypeID aid = crec_bit64_type(cts, &rd->argv[i]); + if (id < aid) id = aid; /* Determine highest type rank of all arguments. */ + } + if (id) { + CType *ct = ctype_get(cts, id); + uint32_t ot = IRT(rd->data, id-CTID_INT64+IRT_I64); + TRef tr = crec_ct_tv(J, ct, 0, J->base[0], &rd->argv[0]); + for (i = 1; J->base[i] != 0; i++) { + TRef tr2 = crec_ct_tv(J, ct, 0, J->base[i], &rd->argv[i]); + tr = emitir(ot, tr, tr2); + } + J->base[0] = emitir(IRTG(IR_CNEWI, IRT_CDATA), lj_ir_kint(J, id), tr); + return 1; + } + return 0; +} + +int LJ_FASTCALL recff_bit64_shift(jit_State *J, RecordFFData *rd) +{ + CTState *cts = ctype_ctsG(J2G(J)); + CTypeID id; + TRef tsh = 0; + if (J->base[0] && tref_iscdata(J->base[1])) { + tsh = crec_ct_tv(J, ctype_get(cts, CTID_INT64), 0, + J->base[1], &rd->argv[1]); + if (!tref_isinteger(tsh)) + tsh = emitconv(tsh, IRT_INT, tref_type(tsh), 0); + J->base[1] = tsh; + } + id = crec_bit64_type(cts, &rd->argv[0]); + if (id) { + TRef tr = crec_ct_tv(J, ctype_get(cts, id), 0, J->base[0], &rd->argv[0]); + uint32_t op = rd->data; + if (!tsh) tsh = lj_opt_narrow_tobit(J, J->base[1]); + if (!(op < IR_BROL ? LJ_TARGET_MASKSHIFT : LJ_TARGET_MASKROT) && + !tref_isk(tsh)) + tsh = emitir(IRTI(IR_BAND), tsh, lj_ir_kint(J, 63)); +#ifdef LJ_TARGET_UNIFYROT + if (op == (LJ_TARGET_UNIFYROT == 1 ? IR_BROR : IR_BROL)) { + op = LJ_TARGET_UNIFYROT == 1 ? IR_BROL : IR_BROR; + tsh = emitir(IRTI(IR_NEG), tsh, tsh); + } +#endif + tr = emitir(IRT(op, id-CTID_INT64+IRT_I64), tr, tsh); + J->base[0] = emitir(IRTG(IR_CNEWI, IRT_CDATA), lj_ir_kint(J, id), tr); + return 1; + } + return 0; +} + +TRef recff_bit64_tohex(jit_State *J, RecordFFData *rd, TRef hdr) +{ + CTState *cts = ctype_ctsG(J2G(J)); + CTypeID id = crec_bit64_type(cts, &rd->argv[0]); + TRef tr, trsf = J->base[1]; + SFormat sf = (STRFMT_UINT|STRFMT_T_HEX); + int32_t n; + if (trsf) { + CTypeID id2 = 0; + n = (int32_t)lj_carith_check64(J->L, 2, &id2); + if (id2) + trsf = crec_ct_tv(J, ctype_get(cts, CTID_INT32), 0, trsf, &rd->argv[1]); + else + trsf = lj_opt_narrow_tobit(J, trsf); + emitir(IRTGI(IR_EQ), trsf, lj_ir_kint(J, n)); /* Specialize to n. */ + } else { + n = id ? 16 : 8; + } + if (n < 0) { n = -n; sf |= STRFMT_F_UPPER; } + sf |= ((SFormat)((n+1)&255) << STRFMT_SH_PREC); + if (id) { + tr = crec_ct_tv(J, ctype_get(cts, id), 0, J->base[0], &rd->argv[0]); + if (n < 16) + tr = emitir(IRT(IR_BAND, IRT_U64), tr, + lj_ir_kint64(J, ((uint64_t)1 << 4*n)-1)); + } else { + tr = lj_opt_narrow_tobit(J, J->base[0]); + if (n < 8) + tr = emitir(IRTI(IR_BAND), tr, lj_ir_kint(J, (int32_t)((1u << 4*n)-1))); + tr = emitconv(tr, IRT_U64, IRT_INT, 0); /* No sign-extension. */ + lj_needsplit(J); + } + return lj_ir_call(J, IRCALL_lj_strfmt_putfxint, hdr, lj_ir_kint(J, sf), tr); +} + +/* -- Miscellaneous library functions ------------------------------------- */ + +void LJ_FASTCALL lj_crecord_tonumber(jit_State *J, RecordFFData *rd) +{ + CTState *cts = ctype_ctsG(J2G(J)); + CType *d, *ct = lj_ctype_rawref(cts, cdataV(&rd->argv[0])->ctypeid); + if (ctype_isenum(ct->info)) ct = ctype_child(cts, ct); + if (ctype_isnum(ct->info) || ctype_iscomplex(ct->info)) { + if (ctype_isinteger_or_bool(ct->info) && ct->size <= 4 && + !(ct->size == 4 && (ct->info & CTF_UNSIGNED))) + d = ctype_get(cts, CTID_INT32); + else + d = ctype_get(cts, CTID_DOUBLE); + J->base[0] = crec_ct_tv(J, d, 0, J->base[0], &rd->argv[0]); + } else { + /* Specialize to the ctype that couldn't be converted. */ + argv2cdata(J, J->base[0], &rd->argv[0]); + J->base[0] = TREF_NIL; + } +} + +TRef lj_crecord_loadiu64(jit_State *J, TRef tr, cTValue *o) +{ + CTypeID id = argv2cdata(J, tr, o)->ctypeid; + if (!(id == CTID_INT64 || id == CTID_UINT64)) + lj_trace_err(J, LJ_TRERR_BADTYPE); + lj_needsplit(J); + return emitir(IRT(IR_FLOAD, id == CTID_INT64 ? IRT_I64 : IRT_U64), tr, + IRFL_CDATA_INT64); +} + +#if LJ_HASBUFFER +TRef lj_crecord_topcvoid(jit_State *J, TRef tr, cTValue *o) +{ + CTState *cts = ctype_ctsG(J2G(J)); + if (!tref_iscdata(tr)) lj_trace_err(J, LJ_TRERR_BADTYPE); + return crec_ct_tv(J, ctype_get(cts, CTID_P_CVOID), 0, tr, o); +} + +TRef lj_crecord_topuint8(jit_State *J, TRef tr) +{ + return emitir(IRTG(IR_CNEWI, IRT_CDATA), lj_ir_kint(J, CTID_P_UINT8), tr); +} +#endif + +#undef IR +#undef emitir +#undef emitconv + +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_crecord.h b/fluent-bit/lib/luajit-3065c9/src/lj_crecord.h new file mode 100644 index 00000000..2c8cf05c --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_crecord.h @@ -0,0 +1,43 @@ +/* +** Trace recorder for C data operations. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#ifndef _LJ_CRECORD_H +#define _LJ_CRECORD_H + +#include "lj_obj.h" +#include "lj_jit.h" +#include "lj_ffrecord.h" + +#if LJ_HASJIT && LJ_HASFFI +LJ_FUNC void LJ_FASTCALL recff_cdata_index(jit_State *J, RecordFFData *rd); +LJ_FUNC void LJ_FASTCALL recff_cdata_call(jit_State *J, RecordFFData *rd); +LJ_FUNC void LJ_FASTCALL recff_cdata_arith(jit_State *J, RecordFFData *rd); +LJ_FUNC void LJ_FASTCALL recff_clib_index(jit_State *J, RecordFFData *rd); +LJ_FUNC void LJ_FASTCALL recff_ffi_new(jit_State *J, RecordFFData *rd); +LJ_FUNC void LJ_FASTCALL recff_ffi_errno(jit_State *J, RecordFFData *rd); +LJ_FUNC void LJ_FASTCALL recff_ffi_string(jit_State *J, RecordFFData *rd); +LJ_FUNC void LJ_FASTCALL recff_ffi_copy(jit_State *J, RecordFFData *rd); +LJ_FUNC void LJ_FASTCALL recff_ffi_fill(jit_State *J, RecordFFData *rd); +LJ_FUNC void LJ_FASTCALL recff_ffi_typeof(jit_State *J, RecordFFData *rd); +LJ_FUNC void LJ_FASTCALL recff_ffi_istype(jit_State *J, RecordFFData *rd); +LJ_FUNC void LJ_FASTCALL recff_ffi_abi(jit_State *J, RecordFFData *rd); +LJ_FUNC void LJ_FASTCALL recff_ffi_xof(jit_State *J, RecordFFData *rd); +LJ_FUNC void LJ_FASTCALL recff_ffi_gc(jit_State *J, RecordFFData *rd); + +LJ_FUNC void LJ_FASTCALL recff_bit64_tobit(jit_State *J, RecordFFData *rd); +LJ_FUNC int LJ_FASTCALL recff_bit64_unary(jit_State *J, RecordFFData *rd); +LJ_FUNC int LJ_FASTCALL recff_bit64_nary(jit_State *J, RecordFFData *rd); +LJ_FUNC int LJ_FASTCALL recff_bit64_shift(jit_State *J, RecordFFData *rd); +LJ_FUNC TRef recff_bit64_tohex(jit_State *J, RecordFFData *rd, TRef hdr); + +LJ_FUNC void LJ_FASTCALL lj_crecord_tonumber(jit_State *J, RecordFFData *rd); +LJ_FUNC TRef lj_crecord_loadiu64(jit_State *J, TRef tr, cTValue *o); +#if LJ_HASBUFFER +LJ_FUNC TRef lj_crecord_topcvoid(jit_State *J, TRef tr, cTValue *o); +LJ_FUNC TRef lj_crecord_topuint8(jit_State *J, TRef tr); +#endif +#endif + +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_ctype.c b/fluent-bit/lib/luajit-3065c9/src/lj_ctype.c new file mode 100644 index 00000000..204be034 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_ctype.c @@ -0,0 +1,646 @@ +/* +** C type management. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#include "lj_obj.h" + +#if LJ_HASFFI + +#include "lj_gc.h" +#include "lj_err.h" +#include "lj_str.h" +#include "lj_tab.h" +#include "lj_strfmt.h" +#include "lj_ctype.h" +#include "lj_ccallback.h" +#include "lj_buf.h" + +/* -- C type definitions -------------------------------------------------- */ + +/* Predefined typedefs. */ +#define CTTDDEF(_) \ + /* Vararg handling. */ \ + _("va_list", P_VOID) \ + _("__builtin_va_list", P_VOID) \ + _("__gnuc_va_list", P_VOID) \ + /* From stddef.h. */ \ + _("ptrdiff_t", INT_PSZ) \ + _("size_t", UINT_PSZ) \ + _("wchar_t", WCHAR) \ + /* Subset of stdint.h. */ \ + _("int8_t", INT8) \ + _("int16_t", INT16) \ + _("int32_t", INT32) \ + _("int64_t", INT64) \ + _("uint8_t", UINT8) \ + _("uint16_t", UINT16) \ + _("uint32_t", UINT32) \ + _("uint64_t", UINT64) \ + _("intptr_t", INT_PSZ) \ + _("uintptr_t", UINT_PSZ) \ + /* From POSIX. */ \ + _("ssize_t", INT_PSZ) \ + /* End of typedef list. */ + +/* Keywords (only the ones we actually care for). */ +#define CTKWDEF(_) \ + /* Type specifiers. */ \ + _("void", -1, CTOK_VOID) \ + _("_Bool", 0, CTOK_BOOL) \ + _("bool", 1, CTOK_BOOL) \ + _("char", 1, CTOK_CHAR) \ + _("int", 4, CTOK_INT) \ + _("__int8", 1, CTOK_INT) \ + _("__int16", 2, CTOK_INT) \ + _("__int32", 4, CTOK_INT) \ + _("__int64", 8, CTOK_INT) \ + _("float", 4, CTOK_FP) \ + _("double", 8, CTOK_FP) \ + _("long", 0, CTOK_LONG) \ + _("short", 0, CTOK_SHORT) \ + _("_Complex", 0, CTOK_COMPLEX) \ + _("complex", 0, CTOK_COMPLEX) \ + _("__complex", 0, CTOK_COMPLEX) \ + _("__complex__", 0, CTOK_COMPLEX) \ + _("signed", 0, CTOK_SIGNED) \ + _("__signed", 0, CTOK_SIGNED) \ + _("__signed__", 0, CTOK_SIGNED) \ + _("unsigned", 0, CTOK_UNSIGNED) \ + /* Type qualifiers. */ \ + _("const", 0, CTOK_CONST) \ + _("__const", 0, CTOK_CONST) \ + _("__const__", 0, CTOK_CONST) \ + _("volatile", 0, CTOK_VOLATILE) \ + _("__volatile", 0, CTOK_VOLATILE) \ + _("__volatile__", 0, CTOK_VOLATILE) \ + _("restrict", 0, CTOK_RESTRICT) \ + _("__restrict", 0, CTOK_RESTRICT) \ + _("__restrict__", 0, CTOK_RESTRICT) \ + _("inline", 0, CTOK_INLINE) \ + _("__inline", 0, CTOK_INLINE) \ + _("__inline__", 0, CTOK_INLINE) \ + /* Storage class specifiers. */ \ + _("typedef", 0, CTOK_TYPEDEF) \ + _("extern", 0, CTOK_EXTERN) \ + _("static", 0, CTOK_STATIC) \ + _("auto", 0, CTOK_AUTO) \ + _("register", 0, CTOK_REGISTER) \ + /* GCC Attributes. */ \ + _("__extension__", 0, CTOK_EXTENSION) \ + _("__attribute", 0, CTOK_ATTRIBUTE) \ + _("__attribute__", 0, CTOK_ATTRIBUTE) \ + _("asm", 0, CTOK_ASM) \ + _("__asm", 0, CTOK_ASM) \ + _("__asm__", 0, CTOK_ASM) \ + /* MSVC Attributes. */ \ + _("__declspec", 0, CTOK_DECLSPEC) \ + _("__cdecl", CTCC_CDECL, CTOK_CCDECL) \ + _("__thiscall", CTCC_THISCALL, CTOK_CCDECL) \ + _("__fastcall", CTCC_FASTCALL, CTOK_CCDECL) \ + _("__stdcall", CTCC_STDCALL, CTOK_CCDECL) \ + _("__ptr32", 4, CTOK_PTRSZ) \ + _("__ptr64", 8, CTOK_PTRSZ) \ + /* Other type specifiers. */ \ + _("struct", 0, CTOK_STRUCT) \ + _("union", 0, CTOK_UNION) \ + _("enum", 0, CTOK_ENUM) \ + /* Operators. */ \ + _("sizeof", 0, CTOK_SIZEOF) \ + _("__alignof", 0, CTOK_ALIGNOF) \ + _("__alignof__", 0, CTOK_ALIGNOF) \ + /* End of keyword list. */ + +/* Type info for predefined types. Size merged in. */ +static CTInfo lj_ctype_typeinfo[] = { +#define CTTYINFODEF(id, sz, ct, info) CTINFO((ct),(((sz)&0x3fu)<<10)+(info)), +#define CTTDINFODEF(name, id) CTINFO(CT_TYPEDEF, CTID_##id), +#define CTKWINFODEF(name, sz, kw) CTINFO(CT_KW,(((sz)&0x3fu)<<10)+(kw)), +CTTYDEF(CTTYINFODEF) +CTTDDEF(CTTDINFODEF) +CTKWDEF(CTKWINFODEF) +#undef CTTYINFODEF +#undef CTTDINFODEF +#undef CTKWINFODEF + 0 +}; + +/* Predefined type names collected in a single string. */ +static const char * const lj_ctype_typenames = +#define CTTDNAMEDEF(name, id) name "\0" +#define CTKWNAMEDEF(name, sz, cds) name "\0" +CTTDDEF(CTTDNAMEDEF) +CTKWDEF(CTKWNAMEDEF) +#undef CTTDNAMEDEF +#undef CTKWNAMEDEF +; + +#define CTTYPEINFO_NUM (sizeof(lj_ctype_typeinfo)/sizeof(CTInfo)-1) +#ifdef LUAJIT_CTYPE_CHECK_ANCHOR +#define CTTYPETAB_MIN CTTYPEINFO_NUM +#else +#define CTTYPETAB_MIN 128 +#endif + +/* -- C type interning ---------------------------------------------------- */ + +#define ct_hashtype(info, size) (hashrot(info, size) & CTHASH_MASK) +#define ct_hashname(name) \ + (hashrot(u32ptr(name), u32ptr(name) + HASH_BIAS) & CTHASH_MASK) + +/* Create new type element. */ +CTypeID lj_ctype_new(CTState *cts, CType **ctp) +{ + CTypeID id = cts->top; + CType *ct; + lj_assertCTS(cts->L, "uninitialized cts->L"); + if (LJ_UNLIKELY(id >= cts->sizetab)) { + if (id >= CTID_MAX) lj_err_msg(cts->L, LJ_ERR_TABOV); +#ifdef LUAJIT_CTYPE_CHECK_ANCHOR + ct = lj_mem_newvec(cts->L, id+1, CType); + memcpy(ct, cts->tab, id*sizeof(CType)); + memset(cts->tab, 0, id*sizeof(CType)); + lj_mem_freevec(cts->g, cts->tab, cts->sizetab, CType); + cts->tab = ct; + cts->sizetab = id+1; +#else + lj_mem_growvec(cts->L, cts->tab, cts->sizetab, CTID_MAX, CType); +#endif + } + cts->top = id+1; + *ctp = ct = &cts->tab[id]; + ct->info = 0; + ct->size = 0; + ct->sib = 0; + ct->next = 0; + setgcrefnull(ct->name); + return id; +} + +/* Intern a type element. */ +CTypeID lj_ctype_intern(CTState *cts, CTInfo info, CTSize size) +{ + uint32_t h = ct_hashtype(info, size); + CTypeID id = cts->hash[h]; + lj_assertCTS(cts->L, "uninitialized cts->L"); + while (id) { + CType *ct = ctype_get(cts, id); + if (ct->info == info && ct->size == size) + return id; + id = ct->next; + } + id = cts->top; + if (LJ_UNLIKELY(id >= cts->sizetab)) { + if (id >= CTID_MAX) lj_err_msg(cts->L, LJ_ERR_TABOV); + lj_mem_growvec(cts->L, cts->tab, cts->sizetab, CTID_MAX, CType); + } + cts->top = id+1; + cts->tab[id].info = info; + cts->tab[id].size = size; + cts->tab[id].sib = 0; + cts->tab[id].next = cts->hash[h]; + setgcrefnull(cts->tab[id].name); + cts->hash[h] = (CTypeID1)id; + return id; +} + +/* Add type element to hash table. */ +static void ctype_addtype(CTState *cts, CType *ct, CTypeID id) +{ + uint32_t h = ct_hashtype(ct->info, ct->size); + ct->next = cts->hash[h]; + cts->hash[h] = (CTypeID1)id; +} + +/* Add named element to hash table. */ +void lj_ctype_addname(CTState *cts, CType *ct, CTypeID id) +{ + uint32_t h = ct_hashname(gcref(ct->name)); + ct->next = cts->hash[h]; + cts->hash[h] = (CTypeID1)id; +} + +/* Get a C type by name, matching the type mask. */ +CTypeID lj_ctype_getname(CTState *cts, CType **ctp, GCstr *name, uint32_t tmask) +{ + CTypeID id = cts->hash[ct_hashname(name)]; + while (id) { + CType *ct = ctype_get(cts, id); + if (gcref(ct->name) == obj2gco(name) && + ((tmask >> ctype_type(ct->info)) & 1)) { + *ctp = ct; + return id; + } + id = ct->next; + } + *ctp = &cts->tab[0]; /* Simplify caller logic. ctype_get() would assert. */ + return 0; +} + +/* Get a struct/union/enum/function field by name. */ +CType *lj_ctype_getfieldq(CTState *cts, CType *ct, GCstr *name, CTSize *ofs, + CTInfo *qual) +{ + while (ct->sib) { + ct = ctype_get(cts, ct->sib); + if (gcref(ct->name) == obj2gco(name)) { + *ofs = ct->size; + return ct; + } + if (ctype_isxattrib(ct->info, CTA_SUBTYPE)) { + CType *fct, *cct = ctype_child(cts, ct); + CTInfo q = 0; + while (ctype_isattrib(cct->info)) { + if (ctype_attrib(cct->info) == CTA_QUAL) q |= cct->size; + cct = ctype_child(cts, cct); + } + fct = lj_ctype_getfieldq(cts, cct, name, ofs, qual); + if (fct) { + if (qual) *qual |= q; + *ofs += ct->size; + return fct; + } + } + } + return NULL; /* Not found. */ +} + +/* -- C type information -------------------------------------------------- */ + +/* Follow references and get raw type for a C type ID. */ +CType *lj_ctype_rawref(CTState *cts, CTypeID id) +{ + CType *ct = ctype_get(cts, id); + while (ctype_isattrib(ct->info) || ctype_isref(ct->info)) + ct = ctype_child(cts, ct); + return ct; +} + +/* Get size for a C type ID. Does NOT support VLA/VLS. */ +CTSize lj_ctype_size(CTState *cts, CTypeID id) +{ + CType *ct = ctype_raw(cts, id); + return ctype_hassize(ct->info) ? ct->size : CTSIZE_INVALID; +} + +/* Get size for a variable-length C type. Does NOT support other C types. */ +CTSize lj_ctype_vlsize(CTState *cts, CType *ct, CTSize nelem) +{ + uint64_t xsz = 0; + if (ctype_isstruct(ct->info)) { + CTypeID arrid = 0, fid = ct->sib; + xsz = ct->size; /* Add the struct size. */ + while (fid) { + CType *ctf = ctype_get(cts, fid); + if (ctype_type(ctf->info) == CT_FIELD) + arrid = ctype_cid(ctf->info); /* Remember last field of VLS. */ + fid = ctf->sib; + } + ct = ctype_raw(cts, arrid); + } + lj_assertCTS(ctype_isvlarray(ct->info), "VLA expected"); + ct = ctype_rawchild(cts, ct); /* Get array element. */ + lj_assertCTS(ctype_hassize(ct->info), "bad VLA without size"); + /* Calculate actual size of VLA and check for overflow. */ + xsz += (uint64_t)ct->size * nelem; + return xsz < 0x80000000u ? (CTSize)xsz : CTSIZE_INVALID; +} + +/* Get type, qualifiers, size and alignment for a C type ID. */ +CTInfo lj_ctype_info(CTState *cts, CTypeID id, CTSize *szp) +{ + CTInfo qual = 0; + CType *ct = ctype_get(cts, id); + for (;;) { + CTInfo info = ct->info; + if (ctype_isenum(info)) { + /* Follow child. Need to look at its attributes, too. */ + } else if (ctype_isattrib(info)) { + if (ctype_isxattrib(info, CTA_QUAL)) + qual |= ct->size; + else if (ctype_isxattrib(info, CTA_ALIGN) && !(qual & CTFP_ALIGNED)) + qual |= CTFP_ALIGNED + CTALIGN(ct->size); + } else { + if (!(qual & CTFP_ALIGNED)) qual |= (info & CTF_ALIGN); + qual |= (info & ~(CTF_ALIGN|CTMASK_CID)); + lj_assertCTS(ctype_hassize(info) || ctype_isfunc(info), + "ctype without size"); + *szp = ctype_isfunc(info) ? CTSIZE_INVALID : ct->size; + break; + } + ct = ctype_get(cts, ctype_cid(info)); + } + return qual; +} + +/* Ditto, but follow a reference. */ +CTInfo lj_ctype_info_raw(CTState *cts, CTypeID id, CTSize *szp) +{ + CType *ct = ctype_get(cts, id); + if (ctype_isref(ct->info)) id = ctype_cid(ct->info); + return lj_ctype_info(cts, id, szp); +} + +/* Get ctype metamethod. */ +cTValue *lj_ctype_meta(CTState *cts, CTypeID id, MMS mm) +{ + CType *ct = ctype_get(cts, id); + cTValue *tv; + while (ctype_isattrib(ct->info) || ctype_isref(ct->info)) { + id = ctype_cid(ct->info); + ct = ctype_get(cts, id); + } + if (ctype_isptr(ct->info) && + ctype_isfunc(ctype_get(cts, ctype_cid(ct->info))->info)) + tv = lj_tab_getstr(cts->miscmap, &cts->g->strempty); + else + tv = lj_tab_getinth(cts->miscmap, -(int32_t)id); + if (tv && tvistab(tv) && + (tv = lj_tab_getstr(tabV(tv), mmname_str(cts->g, mm))) && !tvisnil(tv)) + return tv; + return NULL; +} + +/* -- C type representation ----------------------------------------------- */ + +/* Fixed max. length of a C type representation. */ +#define CTREPR_MAX 512 + +typedef struct CTRepr { + char *pb, *pe; + CTState *cts; + lua_State *L; + int needsp; + int ok; + char buf[CTREPR_MAX]; +} CTRepr; + +/* Prepend string. */ +static void ctype_prepstr(CTRepr *ctr, const char *str, MSize len) +{ + char *p = ctr->pb; + if (ctr->buf + len+1 > p) { ctr->ok = 0; return; } + if (ctr->needsp) *--p = ' '; + ctr->needsp = 1; + p -= len; + while (len-- > 0) p[len] = str[len]; + ctr->pb = p; +} + +#define ctype_preplit(ctr, str) ctype_prepstr((ctr), "" str, sizeof(str)-1) + +/* Prepend char. */ +static void ctype_prepc(CTRepr *ctr, int c) +{ + if (ctr->buf >= ctr->pb) { ctr->ok = 0; return; } + *--ctr->pb = c; +} + +/* Prepend number. */ +static void ctype_prepnum(CTRepr *ctr, uint32_t n) +{ + char *p = ctr->pb; + if (ctr->buf + 10+1 > p) { ctr->ok = 0; return; } + do { *--p = (char)('0' + n % 10); } while (n /= 10); + ctr->pb = p; + ctr->needsp = 0; +} + +/* Append char. */ +static void ctype_appc(CTRepr *ctr, int c) +{ + if (ctr->pe >= ctr->buf + CTREPR_MAX) { ctr->ok = 0; return; } + *ctr->pe++ = c; +} + +/* Append number. */ +static void ctype_appnum(CTRepr *ctr, uint32_t n) +{ + char buf[10]; + char *p = buf+sizeof(buf); + char *q = ctr->pe; + if (q > ctr->buf + CTREPR_MAX - 10) { ctr->ok = 0; return; } + do { *--p = (char)('0' + n % 10); } while (n /= 10); + do { *q++ = *p++; } while (p < buf+sizeof(buf)); + ctr->pe = q; +} + +/* Prepend qualifiers. */ +static void ctype_prepqual(CTRepr *ctr, CTInfo info) +{ + if ((info & CTF_VOLATILE)) ctype_preplit(ctr, "volatile"); + if ((info & CTF_CONST)) ctype_preplit(ctr, "const"); +} + +/* Prepend named type. */ +static void ctype_preptype(CTRepr *ctr, CType *ct, CTInfo qual, const char *t) +{ + if (gcref(ct->name)) { + GCstr *str = gco2str(gcref(ct->name)); + ctype_prepstr(ctr, strdata(str), str->len); + } else { + if (ctr->needsp) ctype_prepc(ctr, ' '); + ctype_prepnum(ctr, ctype_typeid(ctr->cts, ct)); + ctr->needsp = 1; + } + ctype_prepstr(ctr, t, (MSize)strlen(t)); + ctype_prepqual(ctr, qual); +} + +static void ctype_repr(CTRepr *ctr, CTypeID id) +{ + CType *ct = ctype_get(ctr->cts, id); + CTInfo qual = 0; + int ptrto = 0; + for (;;) { + CTInfo info = ct->info; + CTSize size = ct->size; + switch (ctype_type(info)) { + case CT_NUM: + if ((info & CTF_BOOL)) { + ctype_preplit(ctr, "bool"); + } else if ((info & CTF_FP)) { + if (size == sizeof(double)) ctype_preplit(ctr, "double"); + else if (size == sizeof(float)) ctype_preplit(ctr, "float"); + else ctype_preplit(ctr, "long double"); + } else if (size == 1) { + if (!((info ^ CTF_UCHAR) & CTF_UNSIGNED)) ctype_preplit(ctr, "char"); + else if (CTF_UCHAR) ctype_preplit(ctr, "signed char"); + else ctype_preplit(ctr, "unsigned char"); + } else if (size < 8) { + if (size == 4) ctype_preplit(ctr, "int"); + else ctype_preplit(ctr, "short"); + if ((info & CTF_UNSIGNED)) ctype_preplit(ctr, "unsigned"); + } else { + ctype_preplit(ctr, "_t"); + ctype_prepnum(ctr, size*8); + ctype_preplit(ctr, "int"); + if ((info & CTF_UNSIGNED)) ctype_prepc(ctr, 'u'); + } + ctype_prepqual(ctr, (qual|info)); + return; + case CT_VOID: + ctype_preplit(ctr, "void"); + ctype_prepqual(ctr, (qual|info)); + return; + case CT_STRUCT: + ctype_preptype(ctr, ct, qual, (info & CTF_UNION) ? "union" : "struct"); + return; + case CT_ENUM: + if (id == CTID_CTYPEID) { + ctype_preplit(ctr, "ctype"); + return; + } + ctype_preptype(ctr, ct, qual, "enum"); + return; + case CT_ATTRIB: + if (ctype_attrib(info) == CTA_QUAL) qual |= size; + break; + case CT_PTR: + if ((info & CTF_REF)) { + ctype_prepc(ctr, '&'); + } else { + ctype_prepqual(ctr, (qual|info)); + if (LJ_64 && size == 4) ctype_preplit(ctr, "__ptr32"); + ctype_prepc(ctr, '*'); + } + qual = 0; + ptrto = 1; + ctr->needsp = 1; + break; + case CT_ARRAY: + if (ctype_isrefarray(info)) { + ctr->needsp = 1; + if (ptrto) { ptrto = 0; ctype_prepc(ctr, '('); ctype_appc(ctr, ')'); } + ctype_appc(ctr, '['); + if (size != CTSIZE_INVALID) { + CTSize csize = ctype_child(ctr->cts, ct)->size; + ctype_appnum(ctr, csize ? size/csize : 0); + } else if ((info & CTF_VLA)) { + ctype_appc(ctr, '?'); + } + ctype_appc(ctr, ']'); + } else if ((info & CTF_COMPLEX)) { + if (size == 2*sizeof(float)) ctype_preplit(ctr, "float"); + ctype_preplit(ctr, "complex"); + return; + } else { + ctype_preplit(ctr, ")))"); + ctype_prepnum(ctr, size); + ctype_preplit(ctr, "__attribute__((vector_size("); + } + break; + case CT_FUNC: + ctr->needsp = 1; + if (ptrto) { ptrto = 0; ctype_prepc(ctr, '('); ctype_appc(ctr, ')'); } + ctype_appc(ctr, '('); + ctype_appc(ctr, ')'); + break; + default: + lj_assertG_(ctr->cts->g, 0, "bad ctype %08x", info); + break; + } + ct = ctype_get(ctr->cts, ctype_cid(info)); + } +} + +/* Return a printable representation of a C type. */ +GCstr *lj_ctype_repr(lua_State *L, CTypeID id, GCstr *name) +{ + global_State *g = G(L); + CTRepr ctr; + ctr.pb = ctr.pe = &ctr.buf[CTREPR_MAX/2]; + ctr.cts = ctype_ctsG(g); + ctr.L = L; + ctr.ok = 1; + ctr.needsp = 0; + if (name) ctype_prepstr(&ctr, strdata(name), name->len); + ctype_repr(&ctr, id); + if (LJ_UNLIKELY(!ctr.ok)) return lj_str_newlit(L, "?"); + return lj_str_new(L, ctr.pb, ctr.pe - ctr.pb); +} + +/* Convert int64_t/uint64_t to string with 'LL' or 'ULL' suffix. */ +GCstr *lj_ctype_repr_int64(lua_State *L, uint64_t n, int isunsigned) +{ + char buf[1+20+3]; + char *p = buf+sizeof(buf); + int sign = 0; + *--p = 'L'; *--p = 'L'; + if (isunsigned) { + *--p = 'U'; + } else if ((int64_t)n < 0) { + n = (uint64_t)-(int64_t)n; + sign = 1; + } + do { *--p = (char)('0' + n % 10); } while (n /= 10); + if (sign) *--p = '-'; + return lj_str_new(L, p, (size_t)(buf+sizeof(buf)-p)); +} + +/* Convert complex to string with 'i' or 'I' suffix. */ +GCstr *lj_ctype_repr_complex(lua_State *L, void *sp, CTSize size) +{ + SBuf *sb = lj_buf_tmp_(L); + TValue re, im; + if (size == 2*sizeof(double)) { + re.n = *(double *)sp; im.n = ((double *)sp)[1]; + } else { + re.n = (double)*(float *)sp; im.n = (double)((float *)sp)[1]; + } + lj_strfmt_putfnum(sb, STRFMT_G14, re.n); + if (!(im.u32.hi & 0x80000000u) || im.n != im.n) lj_buf_putchar(sb, '+'); + lj_strfmt_putfnum(sb, STRFMT_G14, im.n); + lj_buf_putchar(sb, sb->w[-1] >= 'a' ? 'I' : 'i'); + return lj_buf_str(L, sb); +} + +/* -- C type state -------------------------------------------------------- */ + +/* Initialize C type table and state. */ +CTState *lj_ctype_init(lua_State *L) +{ + CTState *cts = lj_mem_newt(L, sizeof(CTState), CTState); + CType *ct = lj_mem_newvec(L, CTTYPETAB_MIN, CType); + const char *name = lj_ctype_typenames; + CTypeID id; + memset(cts, 0, sizeof(CTState)); + cts->tab = ct; + cts->sizetab = CTTYPETAB_MIN; + cts->top = CTTYPEINFO_NUM; + cts->L = NULL; + cts->g = G(L); + for (id = 0; id < CTTYPEINFO_NUM; id++, ct++) { + CTInfo info = lj_ctype_typeinfo[id]; + ct->size = (CTSize)((int32_t)(info << 16) >> 26); + ct->info = info & 0xffff03ffu; + ct->sib = 0; + if (ctype_type(info) == CT_KW || ctype_istypedef(info)) { + size_t len = strlen(name); + GCstr *str = lj_str_new(L, name, len); + ctype_setname(ct, str); + name += len+1; + lj_ctype_addname(cts, ct, id); + } else { + setgcrefnull(ct->name); + ct->next = 0; + if (!ctype_isenum(info)) ctype_addtype(cts, ct, id); + } + } + setmref(G(L)->ctype_state, cts); + return cts; +} + +/* Free C type table and state. */ +void lj_ctype_freestate(global_State *g) +{ + CTState *cts = ctype_ctsG(g); + if (cts) { + lj_ccallback_mcode_free(cts); + lj_mem_freevec(g, cts->tab, cts->sizetab, CType); + lj_mem_freevec(g, cts->cb.cbid, cts->cb.sizeid, CTypeID1); + lj_mem_freet(g, cts); + } +} + +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_ctype.h b/fluent-bit/lib/luajit-3065c9/src/lj_ctype.h new file mode 100644 index 00000000..3dbcdbfb --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_ctype.h @@ -0,0 +1,481 @@ +/* +** C type management. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#ifndef _LJ_CTYPE_H +#define _LJ_CTYPE_H + +#include "lj_obj.h" +#include "lj_gc.h" + +#if LJ_HASFFI + +/* -- C type definitions -------------------------------------------------- */ + +/* C type numbers. Highest 4 bits of C type info. ORDER CT. */ +enum { + /* Externally visible types. */ + CT_NUM, /* Integer or floating-point numbers. */ + CT_STRUCT, /* Struct or union. */ + CT_PTR, /* Pointer or reference. */ + CT_ARRAY, /* Array or complex type. */ + CT_MAYCONVERT = CT_ARRAY, + CT_VOID, /* Void type. */ + CT_ENUM, /* Enumeration. */ + CT_HASSIZE = CT_ENUM, /* Last type where ct->size holds the actual size. */ + CT_FUNC, /* Function. */ + CT_TYPEDEF, /* Typedef. */ + CT_ATTRIB, /* Miscellaneous attributes. */ + /* Internal element types. */ + CT_FIELD, /* Struct/union field or function parameter. */ + CT_BITFIELD, /* Struct/union bitfield. */ + CT_CONSTVAL, /* Constant value. */ + CT_EXTERN, /* External reference. */ + CT_KW /* Keyword. */ +}; + +LJ_STATIC_ASSERT(((int)CT_PTR & (int)CT_ARRAY) == CT_PTR); +LJ_STATIC_ASSERT(((int)CT_STRUCT & (int)CT_ARRAY) == CT_STRUCT); + +/* +** ---------- info ------------ +** |type flags... A cid | size | sib | next | name | +** +----------------------------+--------+-------+-------+-------+-- +** |NUM BFcvUL.. A | size | | type | | +** |STRUCT ..cvU..V A | size | field | name? | name? | +** |PTR ..cvR... A cid | size | | type | | +** |ARRAY VCcv...V A cid | size | | type | | +** |VOID ..cv.... A | size | | type | | +** |ENUM A cid | size | const | name? | name? | +** |FUNC ....VS.. cc cid | nargs | field | name? | name? | +** |TYPEDEF cid | | | name | name | +** |ATTRIB attrnum cid | attr | sib? | type? | | +** |FIELD cid | offset | field | | name? | +** |BITFIELD B.cvU csz bsz pos | offset | field | | name? | +** |CONSTVAL c cid | value | const | name | name | +** |EXTERN cid | | sib? | name | name | +** |KW tok | size | | name | name | +** +----------------------------+--------+-------+-------+-------+-- +** ^^ ^^--- bits used for C type conversion dispatch +*/ + +/* C type info flags. TFFArrrr */ +#define CTF_BOOL 0x08000000u /* Boolean: NUM, BITFIELD. */ +#define CTF_FP 0x04000000u /* Floating-point: NUM. */ +#define CTF_CONST 0x02000000u /* Const qualifier. */ +#define CTF_VOLATILE 0x01000000u /* Volatile qualifier. */ +#define CTF_UNSIGNED 0x00800000u /* Unsigned: NUM, BITFIELD. */ +#define CTF_LONG 0x00400000u /* Long: NUM. */ +#define CTF_VLA 0x00100000u /* Variable-length: ARRAY, STRUCT. */ +#define CTF_REF 0x00800000u /* Reference: PTR. */ +#define CTF_VECTOR 0x08000000u /* Vector: ARRAY. */ +#define CTF_COMPLEX 0x04000000u /* Complex: ARRAY. */ +#define CTF_UNION 0x00800000u /* Union: STRUCT. */ +#define CTF_VARARG 0x00800000u /* Vararg: FUNC. */ +#define CTF_SSEREGPARM 0x00400000u /* SSE register parameters: FUNC. */ + +#define CTF_QUAL (CTF_CONST|CTF_VOLATILE) +#define CTF_ALIGN (CTMASK_ALIGN< 0 ? CTF_UNSIGNED : 0) + +/* Flags used in parser. .F.Ammvf cp->attr */ +#define CTFP_ALIGNED 0x00000001u /* cp->attr + ALIGN */ +#define CTFP_PACKED 0x00000002u /* cp->attr */ +/* ...C...f cp->fattr */ +#define CTFP_CCONV 0x00000001u /* cp->fattr + CCONV/[SSE]REGPARM */ + +/* C type info bitfields. */ +#define CTMASK_CID 0x0000ffffu /* Max. 65536 type IDs. */ +#define CTMASK_NUM 0xf0000000u /* Max. 16 type numbers. */ +#define CTSHIFT_NUM 28 +#define CTMASK_ALIGN 15 /* Max. alignment is 2^15. */ +#define CTSHIFT_ALIGN 16 +#define CTMASK_ATTRIB 255 /* Max. 256 attributes. */ +#define CTSHIFT_ATTRIB 16 +#define CTMASK_CCONV 3 /* Max. 4 calling conventions. */ +#define CTSHIFT_CCONV 16 +#define CTMASK_REGPARM 3 /* Max. 0-3 regparms. */ +#define CTSHIFT_REGPARM 18 +/* Bitfields only used in parser. */ +#define CTMASK_VSIZEP 15 /* Max. vector size is 2^15. */ +#define CTSHIFT_VSIZEP 4 +#define CTMASK_MSIZEP 255 /* Max. type size (via mode) is 128. */ +#define CTSHIFT_MSIZEP 8 + +/* Info bits for BITFIELD. Max. size of bitfield is 64 bits. */ +#define CTBSZ_MAX 32 /* Max. size of bitfield is 32 bit. */ +#define CTBSZ_FIELD 127 /* Temp. marker for regular field. */ +#define CTMASK_BITPOS 127 +#define CTMASK_BITBSZ 127 +#define CTMASK_BITCSZ 127 +#define CTSHIFT_BITPOS 0 +#define CTSHIFT_BITBSZ 8 +#define CTSHIFT_BITCSZ 16 + +#define CTF_INSERT(info, field, val) \ + info = (info & ~(CTMASK_##field<> CTSHIFT_NUM) +#define ctype_cid(info) ((CTypeID)((info) & CTMASK_CID)) +#define ctype_align(info) (((info) >> CTSHIFT_ALIGN) & CTMASK_ALIGN) +#define ctype_attrib(info) (((info) >> CTSHIFT_ATTRIB) & CTMASK_ATTRIB) +#define ctype_bitpos(info) (((info) >> CTSHIFT_BITPOS) & CTMASK_BITPOS) +#define ctype_bitbsz(info) (((info) >> CTSHIFT_BITBSZ) & CTMASK_BITBSZ) +#define ctype_bitcsz(info) (((info) >> CTSHIFT_BITCSZ) & CTMASK_BITCSZ) +#define ctype_vsizeP(info) (((info) >> CTSHIFT_VSIZEP) & CTMASK_VSIZEP) +#define ctype_msizeP(info) (((info) >> CTSHIFT_MSIZEP) & CTMASK_MSIZEP) +#define ctype_cconv(info) (((info) >> CTSHIFT_CCONV) & CTMASK_CCONV) + +/* Simple type checks. */ +#define ctype_isnum(info) (ctype_type((info)) == CT_NUM) +#define ctype_isvoid(info) (ctype_type((info)) == CT_VOID) +#define ctype_isptr(info) (ctype_type((info)) == CT_PTR) +#define ctype_isarray(info) (ctype_type((info)) == CT_ARRAY) +#define ctype_isstruct(info) (ctype_type((info)) == CT_STRUCT) +#define ctype_isfunc(info) (ctype_type((info)) == CT_FUNC) +#define ctype_isenum(info) (ctype_type((info)) == CT_ENUM) +#define ctype_istypedef(info) (ctype_type((info)) == CT_TYPEDEF) +#define ctype_isattrib(info) (ctype_type((info)) == CT_ATTRIB) +#define ctype_isfield(info) (ctype_type((info)) == CT_FIELD) +#define ctype_isbitfield(info) (ctype_type((info)) == CT_BITFIELD) +#define ctype_isconstval(info) (ctype_type((info)) == CT_CONSTVAL) +#define ctype_isextern(info) (ctype_type((info)) == CT_EXTERN) +#define ctype_hassize(info) (ctype_type((info)) <= CT_HASSIZE) + +/* Combined type and flag checks. */ +#define ctype_isinteger(info) \ + (((info) & (CTMASK_NUM|CTF_BOOL|CTF_FP)) == CTINFO(CT_NUM, 0)) +#define ctype_isinteger_or_bool(info) \ + (((info) & (CTMASK_NUM|CTF_FP)) == CTINFO(CT_NUM, 0)) +#define ctype_isbool(info) \ + (((info) & (CTMASK_NUM|CTF_BOOL)) == CTINFO(CT_NUM, CTF_BOOL)) +#define ctype_isfp(info) \ + (((info) & (CTMASK_NUM|CTF_FP)) == CTINFO(CT_NUM, CTF_FP)) + +#define ctype_ispointer(info) \ + ((ctype_type(info) >> 1) == (CT_PTR >> 1)) /* Pointer or array. */ +#define ctype_isref(info) \ + (((info) & (CTMASK_NUM|CTF_REF)) == CTINFO(CT_PTR, CTF_REF)) + +#define ctype_isrefarray(info) \ + (((info) & (CTMASK_NUM|CTF_VECTOR|CTF_COMPLEX)) == CTINFO(CT_ARRAY, 0)) +#define ctype_isvector(info) \ + (((info) & (CTMASK_NUM|CTF_VECTOR)) == CTINFO(CT_ARRAY, CTF_VECTOR)) +#define ctype_iscomplex(info) \ + (((info) & (CTMASK_NUM|CTF_COMPLEX)) == CTINFO(CT_ARRAY, CTF_COMPLEX)) + +#define ctype_isvltype(info) \ + (((info) & ((CTMASK_NUM|CTF_VLA) - (2u<g, (c), __VA_ARGS__)) +#else +#define lj_assertCTS(c, ...) ((void)cts) +#endif + +/* -- Predefined types ---------------------------------------------------- */ + +/* Target-dependent types. */ +#if LJ_TARGET_PPC +#define CTTYDEFP(_) \ + _(LINT32, 4, CT_NUM, CTF_LONG|CTALIGN(2)) +#else +#define CTTYDEFP(_) +#endif + +/* Common types. */ +#define CTTYDEF(_) \ + _(NONE, 0, CT_ATTRIB, CTATTRIB(CTA_BAD)) \ + _(VOID, -1, CT_VOID, CTALIGN(0)) \ + _(CVOID, -1, CT_VOID, CTF_CONST|CTALIGN(0)) \ + _(BOOL, 1, CT_NUM, CTF_BOOL|CTF_UNSIGNED|CTALIGN(0)) \ + _(CCHAR, 1, CT_NUM, CTF_CONST|CTF_UCHAR|CTALIGN(0)) \ + _(INT8, 1, CT_NUM, CTALIGN(0)) \ + _(UINT8, 1, CT_NUM, CTF_UNSIGNED|CTALIGN(0)) \ + _(INT16, 2, CT_NUM, CTALIGN(1)) \ + _(UINT16, 2, CT_NUM, CTF_UNSIGNED|CTALIGN(1)) \ + _(INT32, 4, CT_NUM, CTALIGN(2)) \ + _(UINT32, 4, CT_NUM, CTF_UNSIGNED|CTALIGN(2)) \ + _(INT64, 8, CT_NUM, CTF_LONG|CTALIGN(3)) \ + _(UINT64, 8, CT_NUM, CTF_UNSIGNED|CTF_LONG|CTALIGN(3)) \ + _(FLOAT, 4, CT_NUM, CTF_FP|CTALIGN(2)) \ + _(DOUBLE, 8, CT_NUM, CTF_FP|CTALIGN(3)) \ + _(COMPLEX_FLOAT, 8, CT_ARRAY, CTF_COMPLEX|CTALIGN(2)|CTID_FLOAT) \ + _(COMPLEX_DOUBLE, 16, CT_ARRAY, CTF_COMPLEX|CTALIGN(3)|CTID_DOUBLE) \ + _(P_VOID, CTSIZE_PTR, CT_PTR, CTALIGN_PTR|CTID_VOID) \ + _(P_CVOID, CTSIZE_PTR, CT_PTR, CTALIGN_PTR|CTID_CVOID) \ + _(P_CCHAR, CTSIZE_PTR, CT_PTR, CTALIGN_PTR|CTID_CCHAR) \ + _(P_UINT8, CTSIZE_PTR, CT_PTR, CTALIGN_PTR|CTID_UINT8) \ + _(A_CCHAR, -1, CT_ARRAY, CTF_CONST|CTALIGN(0)|CTID_CCHAR) \ + _(CTYPEID, 4, CT_ENUM, CTALIGN(2)|CTID_INT32) \ + CTTYDEFP(_) \ + /* End of type list. */ + +/* Public predefined type IDs. */ +enum { +#define CTTYIDDEF(id, sz, ct, info) CTID_##id, +CTTYDEF(CTTYIDDEF) +#undef CTTYIDDEF + /* Predefined typedefs and keywords follow. */ + CTID_MAX = 65536 +}; + +/* Target-dependent type IDs. */ +#if LJ_64 +#define CTID_INT_PSZ CTID_INT64 +#define CTID_UINT_PSZ CTID_UINT64 +#else +#define CTID_INT_PSZ CTID_INT32 +#define CTID_UINT_PSZ CTID_UINT32 +#endif + +#if LJ_ABI_WIN +#define CTID_WCHAR CTID_UINT16 +#elif LJ_TARGET_PPC +#define CTID_WCHAR CTID_LINT32 +#else +#define CTID_WCHAR CTID_INT32 +#endif + +/* -- C tokens and keywords ----------------------------------------------- */ + +/* C lexer keywords. */ +#define CTOKDEF(_) \ + _(IDENT, "") _(STRING, "") \ + _(INTEGER, "") _(EOF, "") \ + _(OROR, "||") _(ANDAND, "&&") _(EQ, "==") _(NE, "!=") \ + _(LE, "<=") _(GE, ">=") _(SHL, "<<") _(SHR, ">>") _(DEREF, "->") + +/* Simple declaration specifiers. */ +#define CDSDEF(_) \ + _(VOID) _(BOOL) _(CHAR) _(INT) _(FP) \ + _(LONG) _(LONGLONG) _(SHORT) _(COMPLEX) _(SIGNED) _(UNSIGNED) \ + _(CONST) _(VOLATILE) _(RESTRICT) _(INLINE) \ + _(TYPEDEF) _(EXTERN) _(STATIC) _(AUTO) _(REGISTER) + +/* C keywords. */ +#define CKWDEF(_) \ + CDSDEF(_) _(EXTENSION) _(ASM) _(ATTRIBUTE) \ + _(DECLSPEC) _(CCDECL) _(PTRSZ) \ + _(STRUCT) _(UNION) _(ENUM) \ + _(SIZEOF) _(ALIGNOF) + +/* C token numbers. */ +enum { + CTOK_OFS = 255, +#define CTOKNUM(name, sym) CTOK_##name, +#define CKWNUM(name) CTOK_##name, +CTOKDEF(CTOKNUM) +CKWDEF(CKWNUM) +#undef CTOKNUM +#undef CKWNUM + CTOK_FIRSTDECL = CTOK_VOID, + CTOK_FIRSTSCL = CTOK_TYPEDEF, + CTOK_LASTDECLFLAG = CTOK_REGISTER, + CTOK_LASTDECL = CTOK_ENUM +}; + +/* Declaration specifier flags. */ +enum { +#define CDSFLAG(name) CDF_##name = (1u << (CTOK_##name - CTOK_FIRSTDECL)), +CDSDEF(CDSFLAG) +#undef CDSFLAG + CDF__END +}; + +#define CDF_SCL (CDF_TYPEDEF|CDF_EXTERN|CDF_STATIC|CDF_AUTO|CDF_REGISTER) + +/* -- C type management --------------------------------------------------- */ + +#define ctype_ctsG(g) (mref((g)->ctype_state, CTState)) + +/* Get C type state. */ +static LJ_AINLINE CTState *ctype_cts(lua_State *L) +{ + CTState *cts = ctype_ctsG(G(L)); + cts->L = L; /* Save L for errors and allocations. */ + return cts; +} + +/* Load FFI library on-demand. */ +#define ctype_loadffi(L) \ + do { \ + if (!ctype_ctsG(G(L))) { \ + ptrdiff_t oldtop = (char *)L->top - mref(L->stack, char); \ + luaopen_ffi(L); \ + L->top = (TValue *)(mref(L->stack, char) + oldtop); \ + } \ + } while (0) + +/* Save and restore state of C type table. */ +#define LJ_CTYPE_SAVE(cts) CTState savects_ = *(cts) +#define LJ_CTYPE_RESTORE(cts) \ + ((cts)->top = savects_.top, \ + memcpy((cts)->hash, savects_.hash, sizeof(savects_.hash))) + +/* Check C type ID for validity when assertions are enabled. */ +static LJ_AINLINE CTypeID ctype_check(CTState *cts, CTypeID id) +{ + UNUSED(cts); + lj_assertCTS(id > 0 && id < cts->top, "bad CTID %d", id); + return id; +} + +/* Get C type for C type ID. */ +static LJ_AINLINE CType *ctype_get(CTState *cts, CTypeID id) +{ + return &cts->tab[ctype_check(cts, id)]; +} + +/* Get C type ID for a C type. */ +#define ctype_typeid(cts, ct) ((CTypeID)((ct) - (cts)->tab)) + +/* Get child C type. */ +static LJ_AINLINE CType *ctype_child(CTState *cts, CType *ct) +{ + lj_assertCTS(!(ctype_isvoid(ct->info) || ctype_isstruct(ct->info) || + ctype_isbitfield(ct->info)), + "ctype %08x has no children", ct->info); + return ctype_get(cts, ctype_cid(ct->info)); +} + +/* Get raw type for a C type ID. */ +static LJ_AINLINE CType *ctype_raw(CTState *cts, CTypeID id) +{ + CType *ct = ctype_get(cts, id); + while (ctype_isattrib(ct->info)) ct = ctype_child(cts, ct); + return ct; +} + +/* Get raw type of the child of a C type. */ +static LJ_AINLINE CType *ctype_rawchild(CTState *cts, CType *ct) +{ + do { ct = ctype_child(cts, ct); } while (ctype_isattrib(ct->info)); + return ct; +} + +/* Set the name of a C type table element. */ +static LJ_AINLINE void ctype_setname(CType *ct, GCstr *s) +{ + /* NOBARRIER: mark string as fixed -- the C type table is never collected. */ + fixstring(s); + setgcref(ct->name, obj2gco(s)); +} + +LJ_FUNC CTypeID lj_ctype_new(CTState *cts, CType **ctp); +LJ_FUNC CTypeID lj_ctype_intern(CTState *cts, CTInfo info, CTSize size); +LJ_FUNC void lj_ctype_addname(CTState *cts, CType *ct, CTypeID id); +LJ_FUNC CTypeID lj_ctype_getname(CTState *cts, CType **ctp, GCstr *name, + uint32_t tmask); +LJ_FUNC CType *lj_ctype_getfieldq(CTState *cts, CType *ct, GCstr *name, + CTSize *ofs, CTInfo *qual); +#define lj_ctype_getfield(cts, ct, name, ofs) \ + lj_ctype_getfieldq((cts), (ct), (name), (ofs), NULL) +LJ_FUNC CType *lj_ctype_rawref(CTState *cts, CTypeID id); +LJ_FUNC CTSize lj_ctype_size(CTState *cts, CTypeID id); +LJ_FUNC CTSize lj_ctype_vlsize(CTState *cts, CType *ct, CTSize nelem); +LJ_FUNC CTInfo lj_ctype_info(CTState *cts, CTypeID id, CTSize *szp); +LJ_FUNC CTInfo lj_ctype_info_raw(CTState *cts, CTypeID id, CTSize *szp); +LJ_FUNC cTValue *lj_ctype_meta(CTState *cts, CTypeID id, MMS mm); +LJ_FUNC GCstr *lj_ctype_repr(lua_State *L, CTypeID id, GCstr *name); +LJ_FUNC GCstr *lj_ctype_repr_int64(lua_State *L, uint64_t n, int isunsigned); +LJ_FUNC GCstr *lj_ctype_repr_complex(lua_State *L, void *sp, CTSize size); +LJ_FUNC CTState *lj_ctype_init(lua_State *L); +LJ_FUNC void lj_ctype_freestate(global_State *g); + +#endif + +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_debug.c b/fluent-bit/lib/luajit-3065c9/src/lj_debug.c new file mode 100644 index 00000000..112f5358 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_debug.c @@ -0,0 +1,705 @@ +/* +** Debugging and introspection. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#define lj_debug_c +#define LUA_CORE + +#include "lj_obj.h" +#include "lj_err.h" +#include "lj_debug.h" +#include "lj_buf.h" +#include "lj_tab.h" +#include "lj_state.h" +#include "lj_frame.h" +#include "lj_bc.h" +#include "lj_strfmt.h" +#if LJ_HASJIT +#include "lj_jit.h" +#endif + +/* -- Frames -------------------------------------------------------------- */ + +/* Get frame corresponding to a level. */ +cTValue *lj_debug_frame(lua_State *L, int level, int *size) +{ + cTValue *frame, *nextframe, *bot = tvref(L->stack)+LJ_FR2; + /* Traverse frames backwards. */ + for (nextframe = frame = L->base-1; frame > bot; ) { + if (frame_gc(frame) == obj2gco(L)) + level++; /* Skip dummy frames. See lj_err_optype_call(). */ + if (level-- == 0) { + *size = (int)(nextframe - frame); + return frame; /* Level found. */ + } + nextframe = frame; + if (frame_islua(frame)) { + frame = frame_prevl(frame); + } else { + if (frame_isvarg(frame)) + level++; /* Skip vararg pseudo-frame. */ + frame = frame_prevd(frame); + } + } + *size = level; + return NULL; /* Level not found. */ +} + +/* Invalid bytecode position. */ +#define NO_BCPOS (~(BCPos)0) + +/* Return bytecode position for function/frame or NO_BCPOS. */ +static BCPos debug_framepc(lua_State *L, GCfunc *fn, cTValue *nextframe) +{ + const BCIns *ins; + GCproto *pt; + BCPos pos; + lj_assertL(fn->c.gct == ~LJ_TFUNC || fn->c.gct == ~LJ_TTHREAD, + "function or frame expected"); + if (!isluafunc(fn)) { /* Cannot derive a PC for non-Lua functions. */ + return NO_BCPOS; + } else if (nextframe == NULL) { /* Lua function on top. */ + void *cf = cframe_raw(L->cframe); + if (cf == NULL || (char *)cframe_pc(cf) == (char *)cframe_L(cf)) + return NO_BCPOS; + ins = cframe_pc(cf); /* Only happens during error/hook handling. */ + } else { + if (frame_islua(nextframe)) { + ins = frame_pc(nextframe); + } else if (frame_iscont(nextframe)) { + ins = frame_contpc(nextframe); + } else { + /* Lua function below errfunc/gc/hook: find cframe to get the PC. */ + void *cf = cframe_raw(L->cframe); + TValue *f = L->base-1; + for (;;) { + if (cf == NULL) + return NO_BCPOS; + while (cframe_nres(cf) < 0) { + if (f >= restorestack(L, -cframe_nres(cf))) + break; + cf = cframe_raw(cframe_prev(cf)); + if (cf == NULL) + return NO_BCPOS; + } + if (f < nextframe) + break; + if (frame_islua(f)) { + f = frame_prevl(f); + } else { + if (frame_isc(f) || (frame_iscont(f) && frame_iscont_fficb(f))) + cf = cframe_raw(cframe_prev(cf)); + f = frame_prevd(f); + } + } + ins = cframe_pc(cf); + if (!ins) return NO_BCPOS; + } + } + pt = funcproto(fn); + pos = proto_bcpos(pt, ins) - 1; +#if LJ_HASJIT + if (pos > pt->sizebc) { /* Undo the effects of lj_trace_exit for JLOOP. */ + GCtrace *T = (GCtrace *)((char *)(ins-1) - offsetof(GCtrace, startins)); + lj_assertL(bc_isret(bc_op(ins[-1])), "return bytecode expected"); + pos = proto_bcpos(pt, mref(T->startpc, const BCIns)); + } +#endif + return pos; +} + +/* -- Line numbers -------------------------------------------------------- */ + +/* Get line number for a bytecode position. */ +BCLine LJ_FASTCALL lj_debug_line(GCproto *pt, BCPos pc) +{ + const void *lineinfo = proto_lineinfo(pt); + if (pc <= pt->sizebc && lineinfo) { + BCLine first = pt->firstline; + if (pc == pt->sizebc) return first + pt->numline; + if (pc-- == 0) return first; + if (pt->numline < 256) + return first + (BCLine)((const uint8_t *)lineinfo)[pc]; + else if (pt->numline < 65536) + return first + (BCLine)((const uint16_t *)lineinfo)[pc]; + else + return first + (BCLine)((const uint32_t *)lineinfo)[pc]; + } + return 0; +} + +/* Get line number for function/frame. */ +static BCLine debug_frameline(lua_State *L, GCfunc *fn, cTValue *nextframe) +{ + BCPos pc = debug_framepc(L, fn, nextframe); + if (pc != NO_BCPOS) { + GCproto *pt = funcproto(fn); + lj_assertL(pc <= pt->sizebc, "PC out of range"); + return lj_debug_line(pt, pc); + } + return -1; +} + +/* -- Variable names ------------------------------------------------------ */ + +/* Get name of a local variable from slot number and PC. */ +static const char *debug_varname(const GCproto *pt, BCPos pc, BCReg slot) +{ + const char *p = (const char *)proto_varinfo(pt); + if (p) { + BCPos lastpc = 0; + for (;;) { + const char *name = p; + uint32_t vn = *(const uint8_t *)p; + BCPos startpc, endpc; + if (vn < VARNAME__MAX) { + if (vn == VARNAME_END) break; /* End of varinfo. */ + } else { + do { p++; } while (*(const uint8_t *)p); /* Skip over variable name. */ + } + p++; + lastpc = startpc = lastpc + lj_buf_ruleb128(&p); + if (startpc > pc) break; + endpc = startpc + lj_buf_ruleb128(&p); + if (pc < endpc && slot-- == 0) { + if (vn < VARNAME__MAX) { +#define VARNAMESTR(name, str) str "\0" + name = VARNAMEDEF(VARNAMESTR); +#undef VARNAMESTR + if (--vn) while (*name++ || --vn) ; + } + return name; + } + } + } + return NULL; +} + +/* Get name of local variable from 1-based slot number and function/frame. */ +static TValue *debug_localname(lua_State *L, const lua_Debug *ar, + const char **name, BCReg slot1) +{ + uint32_t offset = (uint32_t)ar->i_ci & 0xffff; + uint32_t size = (uint32_t)ar->i_ci >> 16; + TValue *frame = tvref(L->stack) + offset; + TValue *nextframe = size ? frame + size : NULL; + GCfunc *fn = frame_func(frame); + BCPos pc = debug_framepc(L, fn, nextframe); + if (!nextframe) nextframe = L->top+LJ_FR2; + if ((int)slot1 < 0) { /* Negative slot number is for varargs. */ + if (pc != NO_BCPOS) { + GCproto *pt = funcproto(fn); + if ((pt->flags & PROTO_VARARG)) { + slot1 = pt->numparams + (BCReg)(-(int)slot1); + if (frame_isvarg(frame)) { /* Vararg frame has been set up? (pc!=0) */ + nextframe = frame; + frame = frame_prevd(frame); + } + if (frame + slot1+LJ_FR2 < nextframe) { + *name = "(*vararg)"; + return frame+slot1; + } + } + } + return NULL; + } + if (pc != NO_BCPOS && + (*name = debug_varname(funcproto(fn), pc, slot1-1)) != NULL) + ; + else if (slot1 > 0 && frame + slot1+LJ_FR2 < nextframe) + *name = "(*temporary)"; + return frame+slot1; +} + +/* Get name of upvalue. */ +const char *lj_debug_uvname(GCproto *pt, uint32_t idx) +{ + const uint8_t *p = proto_uvinfo(pt); + lj_assertX(idx < pt->sizeuv, "bad upvalue index"); + if (!p) return ""; + if (idx) while (*p++ || --idx) ; + return (const char *)p; +} + +/* Get name and value of upvalue. */ +const char *lj_debug_uvnamev(cTValue *o, uint32_t idx, TValue **tvp, GCobj **op) +{ + if (tvisfunc(o)) { + GCfunc *fn = funcV(o); + if (isluafunc(fn)) { + GCproto *pt = funcproto(fn); + if (idx < pt->sizeuv) { + GCobj *uvo = gcref(fn->l.uvptr[idx]); + *tvp = uvval(&uvo->uv); + *op = uvo; + return lj_debug_uvname(pt, idx); + } + } else { + if (idx < fn->c.nupvalues) { + *tvp = &fn->c.upvalue[idx]; + *op = obj2gco(fn); + return ""; + } + } + } + return NULL; +} + +/* Deduce name of an object from slot number and PC. */ +const char *lj_debug_slotname(GCproto *pt, const BCIns *ip, BCReg slot, + const char **name) +{ + const char *lname; +restart: + lname = debug_varname(pt, proto_bcpos(pt, ip), slot); + if (lname != NULL) { *name = lname; return "local"; } + while (--ip > proto_bc(pt)) { + BCIns ins = *ip; + BCOp op = bc_op(ins); + BCReg ra = bc_a(ins); + if (bcmode_a(op) == BCMbase) { + if (slot >= ra && (op != BC_KNIL || slot <= bc_d(ins))) + return NULL; + } else if (bcmode_a(op) == BCMdst && ra == slot) { + switch (bc_op(ins)) { + case BC_MOV: + if (ra == slot) { slot = bc_d(ins); goto restart; } + break; + case BC_GGET: + *name = strdata(gco2str(proto_kgc(pt, ~(ptrdiff_t)bc_d(ins)))); + return "global"; + case BC_TGETS: + *name = strdata(gco2str(proto_kgc(pt, ~(ptrdiff_t)bc_c(ins)))); + if (ip > proto_bc(pt)) { + BCIns insp = ip[-1]; + if (bc_op(insp) == BC_MOV && bc_a(insp) == ra+1+LJ_FR2 && + bc_d(insp) == bc_b(ins)) + return "method"; + } + return "field"; + case BC_UGET: + *name = lj_debug_uvname(pt, bc_d(ins)); + return "upvalue"; + default: + return NULL; + } + } + } + return NULL; +} + +/* Deduce function name from caller of a frame. */ +const char *lj_debug_funcname(lua_State *L, cTValue *frame, const char **name) +{ + cTValue *pframe; + GCfunc *fn; + BCPos pc; + if (frame <= tvref(L->stack)+LJ_FR2) + return NULL; + if (frame_isvarg(frame)) + frame = frame_prevd(frame); + pframe = frame_prev(frame); + fn = frame_func(pframe); + pc = debug_framepc(L, fn, frame); + if (pc != NO_BCPOS) { + GCproto *pt = funcproto(fn); + const BCIns *ip = &proto_bc(pt)[check_exp(pc < pt->sizebc, pc)]; + MMS mm = bcmode_mm(bc_op(*ip)); + if (mm == MM_call) { + BCReg slot = bc_a(*ip); + if (bc_op(*ip) == BC_ITERC) slot -= 3; + return lj_debug_slotname(pt, ip, slot, name); + } else if (mm != MM__MAX) { + *name = strdata(mmname_str(G(L), mm)); + return "metamethod"; + } + } + return NULL; +} + +/* -- Source code locations ----------------------------------------------- */ + +/* Generate shortened source name. */ +void lj_debug_shortname(char *out, GCstr *str, BCLine line) +{ + const char *src = strdata(str); + if (*src == '=') { + strncpy(out, src+1, LUA_IDSIZE); /* Remove first char. */ + out[LUA_IDSIZE-1] = '\0'; /* Ensures null termination. */ + } else if (*src == '@') { /* Output "source", or "...source". */ + size_t len = str->len-1; + src++; /* Skip the `@' */ + if (len >= LUA_IDSIZE) { + src += len-(LUA_IDSIZE-4); /* Get last part of file name. */ + *out++ = '.'; *out++ = '.'; *out++ = '.'; + } + strcpy(out, src); + } else { /* Output [string "string"] or [builtin:name]. */ + size_t len; /* Length, up to first control char. */ + for (len = 0; len < LUA_IDSIZE-12; len++) + if (((const unsigned char *)src)[len] < ' ') break; + strcpy(out, line == ~(BCLine)0 ? "[builtin:" : "[string \""); out += 9; + if (src[len] != '\0') { /* Must truncate? */ + if (len > LUA_IDSIZE-15) len = LUA_IDSIZE-15; + strncpy(out, src, len); out += len; + strcpy(out, "..."); out += 3; + } else { + strcpy(out, src); out += len; + } + strcpy(out, line == ~(BCLine)0 ? "]" : "\"]"); + } +} + +/* Add current location of a frame to error message. */ +void lj_debug_addloc(lua_State *L, const char *msg, + cTValue *frame, cTValue *nextframe) +{ + if (frame) { + GCfunc *fn = frame_func(frame); + if (isluafunc(fn)) { + BCLine line = debug_frameline(L, fn, nextframe); + if (line >= 0) { + GCproto *pt = funcproto(fn); + char buf[LUA_IDSIZE]; + lj_debug_shortname(buf, proto_chunkname(pt), pt->firstline); + lj_strfmt_pushf(L, "%s:%d: %s", buf, line, msg); + return; + } + } + } + lj_strfmt_pushf(L, "%s", msg); +} + +/* Push location string for a bytecode position to Lua stack. */ +void lj_debug_pushloc(lua_State *L, GCproto *pt, BCPos pc) +{ + GCstr *name = proto_chunkname(pt); + const char *s = strdata(name); + MSize i, len = name->len; + BCLine line = lj_debug_line(pt, pc); + if (pt->firstline == ~(BCLine)0) { + lj_strfmt_pushf(L, "builtin:%s", s); + } else if (*s == '@') { + s++; len--; + for (i = len; i > 0; i--) + if (s[i] == '/' || s[i] == '\\') { + s += i+1; + break; + } + lj_strfmt_pushf(L, "%s:%d", s, line); + } else if (len > 40) { + lj_strfmt_pushf(L, "%p:%d", pt, line); + } else if (*s == '=') { + lj_strfmt_pushf(L, "%s:%d", s+1, line); + } else { + lj_strfmt_pushf(L, "\"%s\":%d", s, line); + } +} + +/* -- Public debug API ---------------------------------------------------- */ + +/* lua_getupvalue() and lua_setupvalue() are in lj_api.c. */ + +LUA_API const char *lua_getlocal(lua_State *L, const lua_Debug *ar, int n) +{ + const char *name = NULL; + if (ar) { + TValue *o = debug_localname(L, ar, &name, (BCReg)n); + if (name) { + copyTV(L, L->top, o); + incr_top(L); + } + } else if (tvisfunc(L->top-1) && isluafunc(funcV(L->top-1))) { + name = debug_varname(funcproto(funcV(L->top-1)), 0, (BCReg)n-1); + } + return name; +} + +LUA_API const char *lua_setlocal(lua_State *L, const lua_Debug *ar, int n) +{ + const char *name = NULL; + TValue *o = debug_localname(L, ar, &name, (BCReg)n); + if (name) + copyTV(L, o, L->top-1); + L->top--; + return name; +} + +int lj_debug_getinfo(lua_State *L, const char *what, lj_Debug *ar, int ext) +{ + int opt_f = 0, opt_L = 0; + TValue *frame = NULL; + TValue *nextframe = NULL; + GCfunc *fn; + if (*what == '>') { + TValue *func = L->top - 1; + if (!tvisfunc(func)) return 0; + fn = funcV(func); + L->top--; + what++; + } else { + uint32_t offset = (uint32_t)ar->i_ci & 0xffff; + uint32_t size = (uint32_t)ar->i_ci >> 16; + lj_assertL(offset != 0, "bad frame offset"); + frame = tvref(L->stack) + offset; + if (size) nextframe = frame + size; + lj_assertL(frame <= tvref(L->maxstack) && + (!nextframe || nextframe <= tvref(L->maxstack)), + "broken frame chain"); + fn = frame_func(frame); + lj_assertL(fn->c.gct == ~LJ_TFUNC, "bad frame function"); + } + for (; *what; what++) { + if (*what == 'S') { + if (isluafunc(fn)) { + GCproto *pt = funcproto(fn); + BCLine firstline = pt->firstline; + GCstr *name = proto_chunkname(pt); + ar->source = strdata(name); + lj_debug_shortname(ar->short_src, name, pt->firstline); + ar->linedefined = (int)firstline; + ar->lastlinedefined = (int)(firstline + pt->numline); + ar->what = (firstline || !pt->numline) ? "Lua" : "main"; + } else { + ar->source = "=[C]"; + ar->short_src[0] = '['; + ar->short_src[1] = 'C'; + ar->short_src[2] = ']'; + ar->short_src[3] = '\0'; + ar->linedefined = -1; + ar->lastlinedefined = -1; + ar->what = "C"; + } + } else if (*what == 'l') { + ar->currentline = frame ? debug_frameline(L, fn, nextframe) : -1; + } else if (*what == 'u') { + ar->nups = fn->c.nupvalues; + if (ext) { + if (isluafunc(fn)) { + GCproto *pt = funcproto(fn); + ar->nparams = pt->numparams; + ar->isvararg = !!(pt->flags & PROTO_VARARG); + } else { + ar->nparams = 0; + ar->isvararg = 1; + } + } + } else if (*what == 'n') { + ar->namewhat = frame ? lj_debug_funcname(L, frame, &ar->name) : NULL; + if (ar->namewhat == NULL) { + ar->namewhat = ""; + ar->name = NULL; + } + } else if (*what == 'f') { + opt_f = 1; + } else if (*what == 'L') { + opt_L = 1; + } else { + return 0; /* Bad option. */ + } + } + if (opt_f) { + setfuncV(L, L->top, fn); + incr_top(L); + } + if (opt_L) { + if (isluafunc(fn)) { + GCtab *t = lj_tab_new(L, 0, 0); + GCproto *pt = funcproto(fn); + const void *lineinfo = proto_lineinfo(pt); + if (lineinfo) { + BCLine first = pt->firstline; + int sz = pt->numline < 256 ? 1 : pt->numline < 65536 ? 2 : 4; + MSize i, szl = pt->sizebc-1; + for (i = 0; i < szl; i++) { + BCLine line = first + + (sz == 1 ? (BCLine)((const uint8_t *)lineinfo)[i] : + sz == 2 ? (BCLine)((const uint16_t *)lineinfo)[i] : + (BCLine)((const uint32_t *)lineinfo)[i]); + setboolV(lj_tab_setint(L, t, line), 1); + } + } + settabV(L, L->top, t); + } else { + setnilV(L->top); + } + incr_top(L); + } + return 1; /* Ok. */ +} + +LUA_API int lua_getinfo(lua_State *L, const char *what, lua_Debug *ar) +{ + return lj_debug_getinfo(L, what, (lj_Debug *)ar, 0); +} + +LUA_API int lua_getstack(lua_State *L, int level, lua_Debug *ar) +{ + int size; + cTValue *frame = lj_debug_frame(L, level, &size); + if (frame) { + ar->i_ci = (size << 16) + (int)(frame - tvref(L->stack)); + return 1; + } else { + ar->i_ci = level - size; + return 0; + } +} + +#if LJ_HASPROFILE +/* Put the chunkname into a buffer. */ +static int debug_putchunkname(SBuf *sb, GCproto *pt, int pathstrip) +{ + GCstr *name = proto_chunkname(pt); + const char *p = strdata(name); + if (pt->firstline == ~(BCLine)0) { + lj_buf_putmem(sb, "[builtin:", 9); + lj_buf_putstr(sb, name); + lj_buf_putb(sb, ']'); + return 0; + } + if (*p == '=' || *p == '@') { + MSize len = name->len-1; + p++; + if (pathstrip) { + int i; + for (i = len-1; i >= 0; i--) + if (p[i] == '/' || p[i] == '\\') { + len -= i+1; + p = p+i+1; + break; + } + } + lj_buf_putmem(sb, p, len); + } else { + lj_buf_putmem(sb, "[string]", 8); + } + return 1; +} + +/* Put a compact stack dump into a buffer. */ +void lj_debug_dumpstack(lua_State *L, SBuf *sb, const char *fmt, int depth) +{ + int level = 0, dir = 1, pathstrip = 1; + MSize lastlen = 0; + if (depth < 0) { level = ~depth; depth = dir = -1; } /* Reverse frames. */ + while (level != depth) { /* Loop through all frame. */ + int size; + cTValue *frame = lj_debug_frame(L, level, &size); + if (frame) { + cTValue *nextframe = size ? frame+size : NULL; + GCfunc *fn = frame_func(frame); + const uint8_t *p = (const uint8_t *)fmt; + int c; + while ((c = *p++)) { + switch (c) { + case 'p': /* Preserve full path. */ + pathstrip = 0; + break; + case 'F': case 'f': { /* Dump function name. */ + const char *name; + const char *what = lj_debug_funcname(L, frame, &name); + if (what) { + if (c == 'F' && isluafunc(fn)) { /* Dump module:name for 'F'. */ + GCproto *pt = funcproto(fn); + if (pt->firstline != ~(BCLine)0) { /* Not a bytecode builtin. */ + debug_putchunkname(sb, pt, pathstrip); + lj_buf_putb(sb, ':'); + } + } + lj_buf_putmem(sb, name, (MSize)strlen(name)); + break; + } /* else: can't derive a name, dump module:line. */ + } + /* fallthrough */ + case 'l': /* Dump module:line. */ + if (isluafunc(fn)) { + GCproto *pt = funcproto(fn); + if (debug_putchunkname(sb, pt, pathstrip)) { + /* Regular Lua function. */ + BCLine line = c == 'l' ? debug_frameline(L, fn, nextframe) : + pt->firstline; + lj_buf_putb(sb, ':'); + lj_strfmt_putint(sb, line >= 0 ? line : pt->firstline); + } + } else if (isffunc(fn)) { /* Dump numbered builtins. */ + lj_buf_putmem(sb, "[builtin#", 9); + lj_strfmt_putint(sb, fn->c.ffid); + lj_buf_putb(sb, ']'); + } else { /* Dump C function address. */ + lj_buf_putb(sb, '@'); + lj_strfmt_putptr(sb, fn->c.f); + } + break; + case 'Z': /* Zap trailing separator. */ + lastlen = sbuflen(sb); + break; + default: + lj_buf_putb(sb, c); + break; + } + } + } else if (dir == 1) { + break; + } else { + level -= size; /* Reverse frame order: quickly skip missing level. */ + } + level += dir; + } + if (lastlen) + sb->w = sb->b + lastlen; /* Zap trailing separator. */ +} +#endif + +/* Number of frames for the leading and trailing part of a traceback. */ +#define TRACEBACK_LEVELS1 12 +#define TRACEBACK_LEVELS2 10 + +LUALIB_API void luaL_traceback (lua_State *L, lua_State *L1, const char *msg, + int level) +{ + int top = (int)(L->top - L->base); + int lim = TRACEBACK_LEVELS1; + lua_Debug ar; + if (msg) lua_pushfstring(L, "%s\n", msg); + lua_pushliteral(L, "stack traceback:"); + while (lua_getstack(L1, level++, &ar)) { + GCfunc *fn; + if (level > lim) { + if (!lua_getstack(L1, level + TRACEBACK_LEVELS2, &ar)) { + level--; + } else { + lua_pushliteral(L, "\n\t..."); + lua_getstack(L1, -10, &ar); + level = ar.i_ci - TRACEBACK_LEVELS2; + } + lim = 2147483647; + continue; + } + lua_getinfo(L1, "Snlf", &ar); + fn = funcV(L1->top-1); L1->top--; + if (isffunc(fn) && !*ar.namewhat) + lua_pushfstring(L, "\n\t[builtin#%d]:", fn->c.ffid); + else + lua_pushfstring(L, "\n\t%s:", ar.short_src); + if (ar.currentline > 0) + lua_pushfstring(L, "%d:", ar.currentline); + if (*ar.namewhat) { + lua_pushfstring(L, " in function " LUA_QS, ar.name); + } else { + if (*ar.what == 'm') { + lua_pushliteral(L, " in main chunk"); + } else if (*ar.what == 'C') { + lua_pushfstring(L, " at %p", fn->c.f); + } else { + lua_pushfstring(L, " in function <%s:%d>", + ar.short_src, ar.linedefined); + } + } + if ((int)(L->top - L->base) - top >= 15) + lua_concat(L, (int)(L->top - L->base) - top); + } + lua_concat(L, (int)(L->top - L->base) - top); +} + diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_debug.h b/fluent-bit/lib/luajit-3065c9/src/lj_debug.h new file mode 100644 index 00000000..28127ae9 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_debug.h @@ -0,0 +1,66 @@ +/* +** Debugging and introspection. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#ifndef _LJ_DEBUG_H +#define _LJ_DEBUG_H + +#include "lj_obj.h" + +typedef struct lj_Debug { + /* Common fields. Must be in the same order as in lua.h. */ + int event; + const char *name; + const char *namewhat; + const char *what; + const char *source; + int currentline; + int nups; + int linedefined; + int lastlinedefined; + char short_src[LUA_IDSIZE]; + int i_ci; + /* Extended fields. Only valid if lj_debug_getinfo() is called with ext = 1.*/ + int nparams; + int isvararg; +} lj_Debug; + +LJ_FUNC cTValue *lj_debug_frame(lua_State *L, int level, int *size); +LJ_FUNC BCLine LJ_FASTCALL lj_debug_line(GCproto *pt, BCPos pc); +LJ_FUNC const char *lj_debug_uvname(GCproto *pt, uint32_t idx); +LJ_FUNC const char *lj_debug_uvnamev(cTValue *o, uint32_t idx, TValue **tvp, + GCobj **op); +LJ_FUNC const char *lj_debug_slotname(GCproto *pt, const BCIns *pc, + BCReg slot, const char **name); +LJ_FUNC const char *lj_debug_funcname(lua_State *L, cTValue *frame, + const char **name); +LJ_FUNC void lj_debug_shortname(char *out, GCstr *str, BCLine line); +LJ_FUNC void lj_debug_addloc(lua_State *L, const char *msg, + cTValue *frame, cTValue *nextframe); +LJ_FUNC void lj_debug_pushloc(lua_State *L, GCproto *pt, BCPos pc); +LJ_FUNC int lj_debug_getinfo(lua_State *L, const char *what, lj_Debug *ar, + int ext); +#if LJ_HASPROFILE +LJ_FUNC void lj_debug_dumpstack(lua_State *L, SBuf *sb, const char *fmt, + int depth); +#endif + +/* Fixed internal variable names. */ +#define VARNAMEDEF(_) \ + _(FOR_IDX, "(for index)") \ + _(FOR_STOP, "(for limit)") \ + _(FOR_STEP, "(for step)") \ + _(FOR_GEN, "(for generator)") \ + _(FOR_STATE, "(for state)") \ + _(FOR_CTL, "(for control)") + +enum { + VARNAME_END, +#define VARNAMEENUM(name, str) VARNAME_##name, + VARNAMEDEF(VARNAMEENUM) +#undef VARNAMEENUM + VARNAME__MAX +}; + +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_def.h b/fluent-bit/lib/luajit-3065c9/src/lj_def.h new file mode 100644 index 00000000..b61297aa --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_def.h @@ -0,0 +1,381 @@ +/* +** LuaJIT common internal definitions. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#ifndef _LJ_DEF_H +#define _LJ_DEF_H + +#include "lua.h" + +#if defined(_MSC_VER) && (_MSC_VER < 1700) +/* Old MSVC is stuck in the last century and doesn't have C99's stdint.h. */ +typedef __int8 int8_t; +typedef __int16 int16_t; +typedef __int32 int32_t; +typedef __int64 int64_t; +typedef unsigned __int8 uint8_t; +typedef unsigned __int16 uint16_t; +typedef unsigned __int32 uint32_t; +typedef unsigned __int64 uint64_t; +#ifdef _WIN64 +typedef __int64 intptr_t; +typedef unsigned __int64 uintptr_t; +#else +typedef __int32 intptr_t; +typedef unsigned __int32 uintptr_t; +#endif +#elif defined(__symbian__) +/* Cough. */ +typedef signed char int8_t; +typedef short int int16_t; +typedef int int32_t; +typedef long long int64_t; +typedef unsigned char uint8_t; +typedef unsigned short int uint16_t; +typedef unsigned int uint32_t; +typedef unsigned long long uint64_t; +typedef int intptr_t; +typedef unsigned int uintptr_t; +#else +#include +#endif + +/* Needed everywhere. */ +#include +#include + +/* Various VM limits. */ +#define LJ_MAX_MEM32 0x7fffff00 /* Max. 32 bit memory allocation. */ +#define LJ_MAX_MEM64 ((uint64_t)1<<47) /* Max. 64 bit memory allocation. */ +/* Max. total memory allocation. */ +#define LJ_MAX_MEM (LJ_GC64 ? LJ_MAX_MEM64 : LJ_MAX_MEM32) +#define LJ_MAX_ALLOC LJ_MAX_MEM /* Max. individual allocation length. */ +#define LJ_MAX_STR LJ_MAX_MEM32 /* Max. string length. */ +#define LJ_MAX_BUF LJ_MAX_MEM32 /* Max. buffer length. */ +#define LJ_MAX_UDATA LJ_MAX_MEM32 /* Max. userdata length. */ + +#define LJ_MAX_STRTAB (1<<26) /* Max. string table size. */ +#define LJ_MAX_HBITS 26 /* Max. hash bits. */ +#define LJ_MAX_ABITS 28 /* Max. bits of array key. */ +#define LJ_MAX_ASIZE ((1<<(LJ_MAX_ABITS-1))+1) /* Max. array part size. */ +#define LJ_MAX_COLOSIZE 16 /* Max. elems for colocated array. */ + +#define LJ_MAX_LINE LJ_MAX_MEM32 /* Max. source code line number. */ +#define LJ_MAX_XLEVEL 200 /* Max. syntactic nesting level. */ +#define LJ_MAX_BCINS (1<<26) /* Max. # of bytecode instructions. */ +#define LJ_MAX_SLOTS 250 /* Max. # of slots in a Lua func. */ +#define LJ_MAX_LOCVAR 200 /* Max. # of local variables. */ +#define LJ_MAX_UPVAL 60 /* Max. # of upvalues. */ + +#define LJ_MAX_IDXCHAIN 100 /* __index/__newindex chain limit. */ +#define LJ_STACK_EXTRA (5+2*LJ_FR2) /* Extra stack space (metamethods). */ + +#define LJ_NUM_CBPAGE 1 /* Number of FFI callback pages. */ + +/* Minimum table/buffer sizes. */ +#define LJ_MIN_GLOBAL 6 /* Min. global table size (hbits). */ +#define LJ_MIN_REGISTRY 2 /* Min. registry size (hbits). */ +#define LJ_MIN_STRTAB 256 /* Min. string table size (pow2). */ +#define LJ_MIN_SBUF 32 /* Min. string buffer length. */ +#define LJ_MIN_VECSZ 8 /* Min. size for growable vectors. */ +#define LJ_MIN_IRSZ 32 /* Min. size for growable IR. */ + +/* JIT compiler limits. */ +#define LJ_MAX_JSLOTS 250 /* Max. # of stack slots for a trace. */ +#define LJ_MAX_PHI 64 /* Max. # of PHIs for a loop. */ +#define LJ_MAX_EXITSTUBGR 16 /* Max. # of exit stub groups. */ + +/* Various macros. */ +#ifndef UNUSED +#define UNUSED(x) ((void)(x)) /* to avoid warnings */ +#endif + +#define U64x(hi, lo) (((uint64_t)0x##hi << 32) + (uint64_t)0x##lo) +#define i32ptr(p) ((int32_t)(intptr_t)(void *)(p)) +#define u32ptr(p) ((uint32_t)(intptr_t)(void *)(p)) +#define i64ptr(p) ((int64_t)(intptr_t)(void *)(p)) +#define u64ptr(p) ((uint64_t)(intptr_t)(void *)(p)) +#define igcptr(p) (LJ_GC64 ? i64ptr(p) : i32ptr(p)) + +#define checki8(x) ((x) == (int32_t)(int8_t)(x)) +#define checku8(x) ((x) == (int32_t)(uint8_t)(x)) +#define checki16(x) ((x) == (int32_t)(int16_t)(x)) +#define checku16(x) ((x) == (int32_t)(uint16_t)(x)) +#define checki32(x) ((x) == (int32_t)(x)) +#define checku32(x) ((x) == (uint32_t)(x)) +#define checkptr31(x) (((uint64_t)(uintptr_t)(x) >> 31) == 0) +#define checkptr32(x) ((uintptr_t)(x) == (uint32_t)(uintptr_t)(x)) +#define checkptr47(x) (((uint64_t)(uintptr_t)(x) >> 47) == 0) +#define checkptrGC(x) (LJ_GC64 ? checkptr47((x)) : LJ_64 ? checkptr31((x)) :1) + +/* Every half-decent C compiler transforms this into a rotate instruction. */ +#define lj_rol(x, n) (((x)<<(n)) | ((x)>>(-(int)(n)&(8*sizeof(x)-1)))) +#define lj_ror(x, n) (((x)<<(-(int)(n)&(8*sizeof(x)-1))) | ((x)>>(n))) + +/* A really naive Bloom filter. But sufficient for our needs. */ +typedef uintptr_t BloomFilter; +#define BLOOM_MASK (8*sizeof(BloomFilter) - 1) +#define bloombit(x) ((uintptr_t)1 << ((x) & BLOOM_MASK)) +#define bloomset(b, x) ((b) |= bloombit((x))) +#define bloomtest(b, x) ((b) & bloombit((x))) + +#if defined(__GNUC__) || defined(__clang__) || defined(__psp2__) + +#define LJ_NORET __attribute__((noreturn)) +#define LJ_ALIGN(n) __attribute__((aligned(n))) +#define LJ_INLINE inline +#define LJ_AINLINE inline __attribute__((always_inline)) +#define LJ_NOINLINE __attribute__((noinline)) + +#if defined(__ELF__) || defined(__MACH__) || defined(__psp2__) +#if !((defined(__sun__) && defined(__svr4__)) || defined(__CELLOS_LV2__)) +#define LJ_NOAPI extern __attribute__((visibility("hidden"))) +#endif +#endif + +/* Note: it's only beneficial to use fastcall on x86 and then only for up to +** two non-FP args. The amalgamated compile covers all LJ_FUNC cases. Only +** indirect calls and related tail-called C functions are marked as fastcall. +*/ +#if defined(__i386__) +#define LJ_FASTCALL __attribute__((fastcall)) +#endif + +#define LJ_LIKELY(x) __builtin_expect(!!(x), 1) +#define LJ_UNLIKELY(x) __builtin_expect(!!(x), 0) + +#define lj_ffs(x) ((uint32_t)__builtin_ctz(x)) +/* Don't ask ... */ +#if defined(__INTEL_COMPILER) && (defined(__i386__) || defined(__x86_64__)) +static LJ_AINLINE uint32_t lj_fls(uint32_t x) +{ + uint32_t r; __asm__("bsrl %1, %0" : "=r" (r) : "rm" (x) : "cc"); return r; +} +#else +#define lj_fls(x) ((uint32_t)(__builtin_clz(x)^31)) +#endif + +#if defined(__arm__) +static LJ_AINLINE uint32_t lj_bswap(uint32_t x) +{ +#if defined(__psp2__) + return __builtin_rev(x); +#else + uint32_t r; +#if __ARM_ARCH_6__ || __ARM_ARCH_6J__ || __ARM_ARCH_6T2__ || __ARM_ARCH_6Z__ ||\ + __ARM_ARCH_6ZK__ || __ARM_ARCH_7__ || __ARM_ARCH_7A__ || __ARM_ARCH_7R__ + __asm__("rev %0, %1" : "=r" (r) : "r" (x)); + return r; +#else +#ifdef __thumb__ + r = x ^ lj_ror(x, 16); +#else + __asm__("eor %0, %1, %1, ror #16" : "=r" (r) : "r" (x)); +#endif + return ((r & 0xff00ffffu) >> 8) ^ lj_ror(x, 8); +#endif +#endif +} + +static LJ_AINLINE uint64_t lj_bswap64(uint64_t x) +{ + return ((uint64_t)lj_bswap((uint32_t)x)<<32) | lj_bswap((uint32_t)(x>>32)); +} +#elif (__GNUC__ > 4) || (__GNUC__ == 4 && __GNUC_MINOR__ >= 3) || __clang__ +static LJ_AINLINE uint32_t lj_bswap(uint32_t x) +{ + return (uint32_t)__builtin_bswap32((int32_t)x); +} + +static LJ_AINLINE uint64_t lj_bswap64(uint64_t x) +{ + return (uint64_t)__builtin_bswap64((int64_t)x); +} +#elif defined(__i386__) || defined(__x86_64__) +static LJ_AINLINE uint32_t lj_bswap(uint32_t x) +{ + uint32_t r; __asm__("bswap %0" : "=r" (r) : "0" (x)); return r; +} + +#if defined(__i386__) +static LJ_AINLINE uint64_t lj_bswap64(uint64_t x) +{ + return ((uint64_t)lj_bswap((uint32_t)x)<<32) | lj_bswap((uint32_t)(x>>32)); +} +#else +static LJ_AINLINE uint64_t lj_bswap64(uint64_t x) +{ + uint64_t r; __asm__("bswap %0" : "=r" (r) : "0" (x)); return r; +} +#endif +#else +static LJ_AINLINE uint32_t lj_bswap(uint32_t x) +{ + return (x << 24) | ((x & 0xff00) << 8) | ((x >> 8) & 0xff00) | (x >> 24); +} + +static LJ_AINLINE uint64_t lj_bswap64(uint64_t x) +{ + return (uint64_t)lj_bswap((uint32_t)(x >> 32)) | + ((uint64_t)lj_bswap((uint32_t)x) << 32); +} +#endif + +typedef union __attribute__((packed)) Unaligned16 { + uint16_t u; + uint8_t b[2]; +} Unaligned16; + +typedef union __attribute__((packed)) Unaligned32 { + uint32_t u; + uint8_t b[4]; +} Unaligned32; + +/* Unaligned load of uint16_t. */ +static LJ_AINLINE uint16_t lj_getu16(const void *p) +{ + return ((const Unaligned16 *)p)->u; +} + +/* Unaligned load of uint32_t. */ +static LJ_AINLINE uint32_t lj_getu32(const void *p) +{ + return ((const Unaligned32 *)p)->u; +} + +#elif defined(_MSC_VER) + +#define LJ_NORET __declspec(noreturn) +#define LJ_ALIGN(n) __declspec(align(n)) +#define LJ_INLINE __inline +#define LJ_AINLINE __forceinline +#define LJ_NOINLINE __declspec(noinline) +#if defined(_M_IX86) +#define LJ_FASTCALL __fastcall +#endif + +#ifdef _M_PPC +unsigned int _CountLeadingZeros(long); +#pragma intrinsic(_CountLeadingZeros) +static LJ_AINLINE uint32_t lj_fls(uint32_t x) +{ + return _CountLeadingZeros(x) ^ 31; +} +#else +unsigned char _BitScanForward(unsigned long *, unsigned long); +unsigned char _BitScanReverse(unsigned long *, unsigned long); +#pragma intrinsic(_BitScanForward) +#pragma intrinsic(_BitScanReverse) + +static LJ_AINLINE uint32_t lj_ffs(uint32_t x) +{ + unsigned long r; _BitScanForward(&r, x); return (uint32_t)r; +} + +static LJ_AINLINE uint32_t lj_fls(uint32_t x) +{ + unsigned long r; _BitScanReverse(&r, x); return (uint32_t)r; +} +#endif + +unsigned long _byteswap_ulong(unsigned long); +uint64_t _byteswap_uint64(uint64_t); +#define lj_bswap(x) (_byteswap_ulong((x))) +#define lj_bswap64(x) (_byteswap_uint64((x))) + +#if defined(_M_PPC) && defined(LUAJIT_NO_UNALIGNED) +/* +** Replacement for unaligned loads on Xbox 360. Disabled by default since it's +** usually more costly than the occasional stall when crossing a cache-line. +*/ +static LJ_AINLINE uint16_t lj_getu16(const void *v) +{ + const uint8_t *p = (const uint8_t *)v; + return (uint16_t)((p[0]<<8) | p[1]); +} +static LJ_AINLINE uint32_t lj_getu32(const void *v) +{ + const uint8_t *p = (const uint8_t *)v; + return (uint32_t)((p[0]<<24) | (p[1]<<16) | (p[2]<<8) | p[3]); +} +#else +/* Unaligned loads are generally ok on x86/x64. */ +#define lj_getu16(p) (*(uint16_t *)(p)) +#define lj_getu32(p) (*(uint32_t *)(p)) +#endif + +#else +#error "missing defines for your compiler" +#endif + +/* Optional defines. */ +#ifndef LJ_FASTCALL +#define LJ_FASTCALL +#endif +#ifndef LJ_NORET +#define LJ_NORET +#endif +#ifndef LJ_NOAPI +#define LJ_NOAPI extern +#endif +#ifndef LJ_LIKELY +#define LJ_LIKELY(x) (x) +#define LJ_UNLIKELY(x) (x) +#endif + +/* Attributes for internal functions. */ +#define LJ_DATA LJ_NOAPI +#define LJ_DATADEF +#define LJ_ASMF LJ_NOAPI +#define LJ_FUNCA LJ_NOAPI +#if defined(ljamalg_c) +#define LJ_FUNC static +#else +#define LJ_FUNC LJ_NOAPI +#endif +#define LJ_FUNC_NORET LJ_FUNC LJ_NORET +#define LJ_FUNCA_NORET LJ_FUNCA LJ_NORET +#define LJ_ASMF_NORET LJ_ASMF LJ_NORET + +/* Internal assertions. */ +#if defined(LUA_USE_ASSERT) || defined(LUA_USE_APICHECK) +#define lj_assert_check(g, c, ...) \ + ((c) ? (void)0 : \ + (lj_assert_fail((g), __FILE__, __LINE__, __func__, __VA_ARGS__), 0)) +#define lj_checkapi(c, ...) lj_assert_check(G(L), (c), __VA_ARGS__) +#else +#define lj_checkapi(c, ...) ((void)L) +#endif + +#ifdef LUA_USE_ASSERT +#define lj_assertG_(g, c, ...) lj_assert_check((g), (c), __VA_ARGS__) +#define lj_assertG(c, ...) lj_assert_check(g, (c), __VA_ARGS__) +#define lj_assertL(c, ...) lj_assert_check(G(L), (c), __VA_ARGS__) +#define lj_assertX(c, ...) lj_assert_check(NULL, (c), __VA_ARGS__) +#define check_exp(c, e) (lj_assertX((c), #c), (e)) +#else +#define lj_assertG_(g, c, ...) ((void)0) +#define lj_assertG(c, ...) ((void)g) +#define lj_assertL(c, ...) ((void)L) +#define lj_assertX(c, ...) ((void)0) +#define check_exp(c, e) (e) +#endif + +/* Static assertions. */ +#define LJ_ASSERT_NAME2(name, line) name ## line +#define LJ_ASSERT_NAME(line) LJ_ASSERT_NAME2(lj_assert_, line) +#ifdef __COUNTER__ +#define LJ_STATIC_ASSERT(cond) \ + extern void LJ_ASSERT_NAME(__COUNTER__)(int STATIC_ASSERTION_FAILED[(cond)?1:-1]) +#else +#define LJ_STATIC_ASSERT(cond) \ + extern void LJ_ASSERT_NAME(__LINE__)(int STATIC_ASSERTION_FAILED[(cond)?1:-1]) +#endif + +/* PRNG state. Need this here, details in lj_prng.h. */ +typedef struct PRNGState { + uint64_t u[4]; +} PRNGState; + +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_dispatch.c b/fluent-bit/lib/luajit-3065c9/src/lj_dispatch.c new file mode 100644 index 00000000..ded382aa --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_dispatch.c @@ -0,0 +1,559 @@ +/* +** Instruction dispatch handling. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#define lj_dispatch_c +#define LUA_CORE + +#include "lj_obj.h" +#include "lj_err.h" +#include "lj_buf.h" +#include "lj_func.h" +#include "lj_str.h" +#include "lj_tab.h" +#include "lj_meta.h" +#include "lj_debug.h" +#include "lj_state.h" +#include "lj_frame.h" +#include "lj_bc.h" +#include "lj_ff.h" +#include "lj_strfmt.h" +#if LJ_HASJIT +#include "lj_jit.h" +#endif +#if LJ_HASFFI +#include "lj_ccallback.h" +#endif +#include "lj_trace.h" +#include "lj_dispatch.h" +#if LJ_HASPROFILE +#include "lj_profile.h" +#endif +#include "lj_vm.h" +#include "luajit.h" + +/* Bump GG_NUM_ASMFF in lj_dispatch.h as needed. Ugly. */ +LJ_STATIC_ASSERT(GG_NUM_ASMFF == FF_NUM_ASMFUNC); + +/* -- Dispatch table management ------------------------------------------- */ + +#if LJ_TARGET_MIPS +#include +LJ_FUNCA_NORET void LJ_FASTCALL lj_ffh_coroutine_wrap_err(lua_State *L, + lua_State *co); +#if !LJ_HASJIT +#define lj_dispatch_stitch lj_dispatch_ins +#endif +#if !LJ_HASPROFILE +#define lj_dispatch_profile lj_dispatch_ins +#endif + +#define GOTFUNC(name) (ASMFunction)name, +static const ASMFunction dispatch_got[] = { + GOTDEF(GOTFUNC) +}; +#undef GOTFUNC +#endif + +/* Initialize instruction dispatch table and hot counters. */ +void lj_dispatch_init(GG_State *GG) +{ + uint32_t i; + ASMFunction *disp = GG->dispatch; + for (i = 0; i < GG_LEN_SDISP; i++) + disp[GG_LEN_DDISP+i] = disp[i] = makeasmfunc(lj_bc_ofs[i]); + for (i = GG_LEN_SDISP; i < GG_LEN_DDISP; i++) + disp[i] = makeasmfunc(lj_bc_ofs[i]); + /* The JIT engine is off by default. luaopen_jit() turns it on. */ + disp[BC_FORL] = disp[BC_IFORL]; + disp[BC_ITERL] = disp[BC_IITERL]; + /* Workaround for stable v2.1 bytecode. TODO: Replace with BC_IITERN. */ + disp[BC_ITERN] = &lj_vm_IITERN; + disp[BC_LOOP] = disp[BC_ILOOP]; + disp[BC_FUNCF] = disp[BC_IFUNCF]; + disp[BC_FUNCV] = disp[BC_IFUNCV]; + GG->g.bc_cfunc_ext = GG->g.bc_cfunc_int = BCINS_AD(BC_FUNCC, LUA_MINSTACK, 0); + for (i = 0; i < GG_NUM_ASMFF; i++) + GG->bcff[i] = BCINS_AD(BC__MAX+i, 0, 0); +#if LJ_TARGET_MIPS + memcpy(GG->got, dispatch_got, LJ_GOT__MAX*sizeof(ASMFunction *)); +#endif +} + +#if LJ_HASJIT +/* Initialize hotcount table. */ +void lj_dispatch_init_hotcount(global_State *g) +{ + int32_t hotloop = G2J(g)->param[JIT_P_hotloop]; + HotCount start = (HotCount)(hotloop*HOTCOUNT_LOOP - 1); + HotCount *hotcount = G2GG(g)->hotcount; + uint32_t i; + for (i = 0; i < HOTCOUNT_SIZE; i++) + hotcount[i] = start; +} +#endif + +/* Internal dispatch mode bits. */ +#define DISPMODE_CALL 0x01 /* Override call dispatch. */ +#define DISPMODE_RET 0x02 /* Override return dispatch. */ +#define DISPMODE_INS 0x04 /* Override instruction dispatch. */ +#define DISPMODE_JIT 0x10 /* JIT compiler on. */ +#define DISPMODE_REC 0x20 /* Recording active. */ +#define DISPMODE_PROF 0x40 /* Profiling active. */ + +/* Update dispatch table depending on various flags. */ +void lj_dispatch_update(global_State *g) +{ + uint8_t oldmode = g->dispatchmode; + uint8_t mode = 0; +#if LJ_HASJIT + mode |= (G2J(g)->flags & JIT_F_ON) ? DISPMODE_JIT : 0; + mode |= G2J(g)->state != LJ_TRACE_IDLE ? + (DISPMODE_REC|DISPMODE_INS|DISPMODE_CALL) : 0; +#endif +#if LJ_HASPROFILE + mode |= (g->hookmask & HOOK_PROFILE) ? (DISPMODE_PROF|DISPMODE_INS) : 0; +#endif + mode |= (g->hookmask & (LUA_MASKLINE|LUA_MASKCOUNT)) ? DISPMODE_INS : 0; + mode |= (g->hookmask & LUA_MASKCALL) ? DISPMODE_CALL : 0; + mode |= (g->hookmask & LUA_MASKRET) ? DISPMODE_RET : 0; + if (oldmode != mode) { /* Mode changed? */ + ASMFunction *disp = G2GG(g)->dispatch; + ASMFunction f_forl, f_iterl, f_itern, f_loop, f_funcf, f_funcv; + g->dispatchmode = mode; + + /* Hotcount if JIT is on, but not while recording. */ + if ((mode & (DISPMODE_JIT|DISPMODE_REC)) == DISPMODE_JIT) { + f_forl = makeasmfunc(lj_bc_ofs[BC_FORL]); + f_iterl = makeasmfunc(lj_bc_ofs[BC_ITERL]); + f_itern = makeasmfunc(lj_bc_ofs[BC_ITERN]); + f_loop = makeasmfunc(lj_bc_ofs[BC_LOOP]); + f_funcf = makeasmfunc(lj_bc_ofs[BC_FUNCF]); + f_funcv = makeasmfunc(lj_bc_ofs[BC_FUNCV]); + } else { /* Otherwise use the non-hotcounting instructions. */ + f_forl = disp[GG_LEN_DDISP+BC_IFORL]; + f_iterl = disp[GG_LEN_DDISP+BC_IITERL]; + f_itern = &lj_vm_IITERN; + f_loop = disp[GG_LEN_DDISP+BC_ILOOP]; + f_funcf = makeasmfunc(lj_bc_ofs[BC_IFUNCF]); + f_funcv = makeasmfunc(lj_bc_ofs[BC_IFUNCV]); + } + /* Init static counting instruction dispatch first (may be copied below). */ + disp[GG_LEN_DDISP+BC_FORL] = f_forl; + disp[GG_LEN_DDISP+BC_ITERL] = f_iterl; + disp[GG_LEN_DDISP+BC_ITERN] = f_itern; + disp[GG_LEN_DDISP+BC_LOOP] = f_loop; + + /* Set dynamic instruction dispatch. */ + if ((oldmode ^ mode) & (DISPMODE_PROF|DISPMODE_REC|DISPMODE_INS)) { + /* Need to update the whole table. */ + if (!(mode & DISPMODE_INS)) { /* No ins dispatch? */ + /* Copy static dispatch table to dynamic dispatch table. */ + memcpy(&disp[0], &disp[GG_LEN_DDISP], GG_LEN_SDISP*sizeof(ASMFunction)); + /* Overwrite with dynamic return dispatch. */ + if ((mode & DISPMODE_RET)) { + disp[BC_RETM] = lj_vm_rethook; + disp[BC_RET] = lj_vm_rethook; + disp[BC_RET0] = lj_vm_rethook; + disp[BC_RET1] = lj_vm_rethook; + } + } else { + /* The recording dispatch also checks for hooks. */ + ASMFunction f = (mode & DISPMODE_PROF) ? lj_vm_profhook : + (mode & DISPMODE_REC) ? lj_vm_record : lj_vm_inshook; + uint32_t i; + for (i = 0; i < GG_LEN_SDISP; i++) + disp[i] = f; + } + } else if (!(mode & DISPMODE_INS)) { + /* Otherwise set dynamic counting ins. */ + disp[BC_FORL] = f_forl; + disp[BC_ITERL] = f_iterl; + disp[BC_ITERN] = f_itern; + disp[BC_LOOP] = f_loop; + /* Set dynamic return dispatch. */ + if ((mode & DISPMODE_RET)) { + disp[BC_RETM] = lj_vm_rethook; + disp[BC_RET] = lj_vm_rethook; + disp[BC_RET0] = lj_vm_rethook; + disp[BC_RET1] = lj_vm_rethook; + } else { + disp[BC_RETM] = disp[GG_LEN_DDISP+BC_RETM]; + disp[BC_RET] = disp[GG_LEN_DDISP+BC_RET]; + disp[BC_RET0] = disp[GG_LEN_DDISP+BC_RET0]; + disp[BC_RET1] = disp[GG_LEN_DDISP+BC_RET1]; + } + } + + /* Set dynamic call dispatch. */ + if ((oldmode ^ mode) & DISPMODE_CALL) { /* Update the whole table? */ + uint32_t i; + if ((mode & DISPMODE_CALL) == 0) { /* No call hooks? */ + for (i = GG_LEN_SDISP; i < GG_LEN_DDISP; i++) + disp[i] = makeasmfunc(lj_bc_ofs[i]); + } else { + for (i = GG_LEN_SDISP; i < GG_LEN_DDISP; i++) + disp[i] = lj_vm_callhook; + } + } + if (!(mode & DISPMODE_CALL)) { /* Overwrite dynamic counting ins. */ + disp[BC_FUNCF] = f_funcf; + disp[BC_FUNCV] = f_funcv; + } + +#if LJ_HASJIT + /* Reset hotcounts for JIT off to on transition. */ + if ((mode & DISPMODE_JIT) && !(oldmode & DISPMODE_JIT)) + lj_dispatch_init_hotcount(g); +#endif + } +} + +/* -- JIT mode setting ---------------------------------------------------- */ + +#if LJ_HASJIT +/* Set JIT mode for a single prototype. */ +static void setptmode(global_State *g, GCproto *pt, int mode) +{ + if ((mode & LUAJIT_MODE_ON)) { /* (Re-)enable JIT compilation. */ + pt->flags &= ~PROTO_NOJIT; + lj_trace_reenableproto(pt); /* Unpatch all ILOOP etc. bytecodes. */ + } else { /* Flush and/or disable JIT compilation. */ + if (!(mode & LUAJIT_MODE_FLUSH)) + pt->flags |= PROTO_NOJIT; + lj_trace_flushproto(g, pt); /* Flush all traces of prototype. */ + } +} + +/* Recursively set the JIT mode for all children of a prototype. */ +static void setptmode_all(global_State *g, GCproto *pt, int mode) +{ + ptrdiff_t i; + if (!(pt->flags & PROTO_CHILD)) return; + for (i = -(ptrdiff_t)pt->sizekgc; i < 0; i++) { + GCobj *o = proto_kgc(pt, i); + if (o->gch.gct == ~LJ_TPROTO) { + setptmode(g, gco2pt(o), mode); + setptmode_all(g, gco2pt(o), mode); + } + } +} +#endif + +/* Public API function: control the JIT engine. */ +int luaJIT_setmode(lua_State *L, int idx, int mode) +{ + global_State *g = G(L); + int mm = mode & LUAJIT_MODE_MASK; + lj_trace_abort(g); /* Abort recording on any state change. */ + /* Avoid pulling the rug from under our own feet. */ + if ((g->hookmask & HOOK_GC)) + lj_err_caller(L, LJ_ERR_NOGCMM); + switch (mm) { +#if LJ_HASJIT + case LUAJIT_MODE_ENGINE: + if ((mode & LUAJIT_MODE_FLUSH)) { + lj_trace_flushall(L); + } else { + if (!(mode & LUAJIT_MODE_ON)) + G2J(g)->flags &= ~(uint32_t)JIT_F_ON; + else + G2J(g)->flags |= (uint32_t)JIT_F_ON; + lj_dispatch_update(g); + } + break; + case LUAJIT_MODE_FUNC: + case LUAJIT_MODE_ALLFUNC: + case LUAJIT_MODE_ALLSUBFUNC: { + cTValue *tv = idx == 0 ? frame_prev(L->base-1)-LJ_FR2 : + idx > 0 ? L->base + (idx-1) : L->top + idx; + GCproto *pt; + if ((idx == 0 || tvisfunc(tv)) && isluafunc(&gcval(tv)->fn)) + pt = funcproto(&gcval(tv)->fn); /* Cannot use funcV() for frame slot. */ + else if (tvisproto(tv)) + pt = protoV(tv); + else + return 0; /* Failed. */ + if (mm != LUAJIT_MODE_ALLSUBFUNC) + setptmode(g, pt, mode); + if (mm != LUAJIT_MODE_FUNC) + setptmode_all(g, pt, mode); + break; + } + case LUAJIT_MODE_TRACE: + if (!(mode & LUAJIT_MODE_FLUSH)) + return 0; /* Failed. */ + lj_trace_flush(G2J(g), idx); + break; +#else + case LUAJIT_MODE_ENGINE: + case LUAJIT_MODE_FUNC: + case LUAJIT_MODE_ALLFUNC: + case LUAJIT_MODE_ALLSUBFUNC: + UNUSED(idx); + if ((mode & LUAJIT_MODE_ON)) + return 0; /* Failed. */ + break; +#endif + case LUAJIT_MODE_WRAPCFUNC: + if ((mode & LUAJIT_MODE_ON)) { + if (idx != 0) { + cTValue *tv = idx > 0 ? L->base + (idx-1) : L->top + idx; + if (tvislightud(tv)) + g->wrapf = (lua_CFunction)lightudV(g, tv); + else + return 0; /* Failed. */ + } else { + return 0; /* Failed. */ + } + g->bc_cfunc_ext = BCINS_AD(BC_FUNCCW, 0, 0); + } else { + g->bc_cfunc_ext = BCINS_AD(BC_FUNCC, 0, 0); + } + break; + default: + return 0; /* Failed. */ + } + return 1; /* OK. */ +} + +/* Enforce (dynamic) linker error for version mismatches. See luajit.c. */ +LUA_API void LUAJIT_VERSION_SYM(void) +{ +} + +/* -- Hooks --------------------------------------------------------------- */ + +/* This function can be called asynchronously (e.g. during a signal). */ +LUA_API int lua_sethook(lua_State *L, lua_Hook func, int mask, int count) +{ + global_State *g = G(L); + mask &= HOOK_EVENTMASK; + if (func == NULL || mask == 0) { mask = 0; func = NULL; } /* Consistency. */ + g->hookf = func; + g->hookcount = g->hookcstart = (int32_t)count; + g->hookmask = (uint8_t)((g->hookmask & ~HOOK_EVENTMASK) | mask); + lj_trace_abort(g); /* Abort recording on any hook change. */ + lj_dispatch_update(g); + return 1; +} + +LUA_API lua_Hook lua_gethook(lua_State *L) +{ + return G(L)->hookf; +} + +LUA_API int lua_gethookmask(lua_State *L) +{ + return G(L)->hookmask & HOOK_EVENTMASK; +} + +LUA_API int lua_gethookcount(lua_State *L) +{ + return (int)G(L)->hookcstart; +} + +/* Call a hook. */ +static void callhook(lua_State *L, int event, BCLine line) +{ + global_State *g = G(L); + lua_Hook hookf = g->hookf; + if (hookf && !hook_active(g)) { + lua_Debug ar; + lj_trace_abort(g); /* Abort recording on any hook call. */ + ar.event = event; + ar.currentline = line; + /* Top frame, nextframe = NULL. */ + ar.i_ci = (int)((L->base-1) - tvref(L->stack)); + lj_state_checkstack(L, 1+LUA_MINSTACK); +#if LJ_HASPROFILE && !LJ_PROFILE_SIGPROF + lj_profile_hook_enter(g); +#else + hook_enter(g); +#endif + hookf(L, &ar); + lj_assertG(hook_active(g), "active hook flag removed"); + setgcref(g->cur_L, obj2gco(L)); +#if LJ_HASPROFILE && !LJ_PROFILE_SIGPROF + lj_profile_hook_leave(g); +#else + hook_leave(g); +#endif + } +} + +/* -- Dispatch callbacks -------------------------------------------------- */ + +/* Calculate number of used stack slots in the current frame. */ +static BCReg cur_topslot(GCproto *pt, const BCIns *pc, uint32_t nres) +{ + BCIns ins = pc[-1]; + if (bc_op(ins) == BC_UCLO) + ins = pc[bc_j(ins)]; + switch (bc_op(ins)) { + case BC_CALLM: case BC_CALLMT: return bc_a(ins) + bc_c(ins) + nres-1+1+LJ_FR2; + case BC_RETM: return bc_a(ins) + bc_d(ins) + nres-1; + case BC_TSETM: return bc_a(ins) + nres-1; + default: return pt->framesize; + } +} + +/* Instruction dispatch. Used by instr/line/return hooks or when recording. */ +void LJ_FASTCALL lj_dispatch_ins(lua_State *L, const BCIns *pc) +{ + ERRNO_SAVE + GCfunc *fn = curr_func(L); + GCproto *pt = funcproto(fn); + void *cf = cframe_raw(L->cframe); + const BCIns *oldpc = cframe_pc(cf); + global_State *g = G(L); + BCReg slots; + setcframe_pc(cf, pc); + slots = cur_topslot(pt, pc, cframe_multres_n(cf)); + L->top = L->base + slots; /* Fix top. */ +#if LJ_HASJIT + { + jit_State *J = G2J(g); + if (J->state != LJ_TRACE_IDLE) { +#ifdef LUA_USE_ASSERT + ptrdiff_t delta = L->top - L->base; +#endif + J->L = L; + lj_trace_ins(J, pc-1); /* The interpreter bytecode PC is offset by 1. */ + lj_assertG(L->top - L->base == delta, + "unbalanced stack after tracing of instruction"); + } + } +#endif + if ((g->hookmask & LUA_MASKCOUNT) && g->hookcount == 0) { + g->hookcount = g->hookcstart; + callhook(L, LUA_HOOKCOUNT, -1); + L->top = L->base + slots; /* Fix top again. */ + } + if ((g->hookmask & LUA_MASKLINE)) { + BCPos npc = proto_bcpos(pt, pc) - 1; + BCPos opc = proto_bcpos(pt, oldpc) - 1; + BCLine line = lj_debug_line(pt, npc); + if (pc <= oldpc || opc >= pt->sizebc || line != lj_debug_line(pt, opc)) { + callhook(L, LUA_HOOKLINE, line); + L->top = L->base + slots; /* Fix top again. */ + } + } + if ((g->hookmask & LUA_MASKRET) && bc_isret(bc_op(pc[-1]))) + callhook(L, LUA_HOOKRET, -1); + ERRNO_RESTORE +} + +/* Initialize call. Ensure stack space and return # of missing parameters. */ +static int call_init(lua_State *L, GCfunc *fn) +{ + if (isluafunc(fn)) { + GCproto *pt = funcproto(fn); + int numparams = pt->numparams; + int gotparams = (int)(L->top - L->base); + int need = pt->framesize; + if ((pt->flags & PROTO_VARARG)) need += 1+gotparams; + lj_state_checkstack(L, (MSize)need); + numparams -= gotparams; + return numparams >= 0 ? numparams : 0; + } else { + lj_state_checkstack(L, LUA_MINSTACK); + return 0; + } +} + +/* Call dispatch. Used by call hooks, hot calls or when recording. */ +ASMFunction LJ_FASTCALL lj_dispatch_call(lua_State *L, const BCIns *pc) +{ + ERRNO_SAVE + GCfunc *fn = curr_func(L); + BCOp op; + global_State *g = G(L); +#if LJ_HASJIT + jit_State *J = G2J(g); +#endif + int missing = call_init(L, fn); +#if LJ_HASJIT + J->L = L; + if ((uintptr_t)pc & 1) { /* Marker for hot call. */ +#ifdef LUA_USE_ASSERT + ptrdiff_t delta = L->top - L->base; +#endif + pc = (const BCIns *)((uintptr_t)pc & ~(uintptr_t)1); + lj_trace_hot(J, pc); + lj_assertG(L->top - L->base == delta, + "unbalanced stack after hot call"); + goto out; + } else if (J->state != LJ_TRACE_IDLE && + !(g->hookmask & (HOOK_GC|HOOK_VMEVENT))) { +#ifdef LUA_USE_ASSERT + ptrdiff_t delta = L->top - L->base; +#endif + /* Record the FUNC* bytecodes, too. */ + lj_trace_ins(J, pc-1); /* The interpreter bytecode PC is offset by 1. */ + lj_assertG(L->top - L->base == delta, + "unbalanced stack after hot instruction"); + } +#endif + if ((g->hookmask & LUA_MASKCALL)) { + int i; + for (i = 0; i < missing; i++) /* Add missing parameters. */ + setnilV(L->top++); + callhook(L, LUA_HOOKCALL, -1); + /* Preserve modifications of missing parameters by lua_setlocal(). */ + while (missing-- > 0 && tvisnil(L->top - 1)) + L->top--; + } +#if LJ_HASJIT +out: +#endif + op = bc_op(pc[-1]); /* Get FUNC* op. */ +#if LJ_HASJIT + /* Use the non-hotcounting variants if JIT is off or while recording. */ + if ((!(J->flags & JIT_F_ON) || J->state != LJ_TRACE_IDLE) && + (op == BC_FUNCF || op == BC_FUNCV)) + op = (BCOp)((int)op+(int)BC_IFUNCF-(int)BC_FUNCF); +#endif + ERRNO_RESTORE + return makeasmfunc(lj_bc_ofs[op]); /* Return static dispatch target. */ +} + +#if LJ_HASJIT +/* Stitch a new trace. */ +void LJ_FASTCALL lj_dispatch_stitch(jit_State *J, const BCIns *pc) +{ + ERRNO_SAVE + lua_State *L = J->L; + void *cf = cframe_raw(L->cframe); + const BCIns *oldpc = cframe_pc(cf); + setcframe_pc(cf, pc); + /* Before dispatch, have to bias PC by 1. */ + L->top = L->base + cur_topslot(curr_proto(L), pc+1, cframe_multres_n(cf)); + lj_trace_stitch(J, pc-1); /* Point to the CALL instruction. */ + setcframe_pc(cf, oldpc); + ERRNO_RESTORE +} +#endif + +#if LJ_HASPROFILE +/* Profile dispatch. */ +void LJ_FASTCALL lj_dispatch_profile(lua_State *L, const BCIns *pc) +{ + ERRNO_SAVE + GCfunc *fn = curr_func(L); + GCproto *pt = funcproto(fn); + void *cf = cframe_raw(L->cframe); + const BCIns *oldpc = cframe_pc(cf); + global_State *g; + setcframe_pc(cf, pc); + L->top = L->base + cur_topslot(pt, pc, cframe_multres_n(cf)); + lj_profile_interpreter(L); + setcframe_pc(cf, oldpc); + g = G(L); + setgcref(g->cur_L, obj2gco(L)); + setvmstate(g, INTERP); + ERRNO_RESTORE +} +#endif + diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_dispatch.h b/fluent-bit/lib/luajit-3065c9/src/lj_dispatch.h new file mode 100644 index 00000000..52762eea --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_dispatch.h @@ -0,0 +1,164 @@ +/* +** Instruction dispatch handling. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#ifndef _LJ_DISPATCH_H +#define _LJ_DISPATCH_H + +#include "lj_obj.h" +#include "lj_bc.h" +#if LJ_HASJIT +#include "lj_jit.h" +#endif + +#if LJ_TARGET_MIPS +/* Need our own global offset table for the dreaded MIPS calling conventions. */ + +#ifndef _LJ_VM_H +LJ_ASMF int32_t LJ_FASTCALL lj_vm_modi(int32_t a, int32_t b); +#endif + +#if LJ_SOFTFP +#ifndef _LJ_IRCALL_H +extern double __adddf3(double a, double b); +extern double __subdf3(double a, double b); +extern double __muldf3(double a, double b); +extern double __divdf3(double a, double b); +#endif +#define SFGOTDEF(_) _(sqrt) _(__adddf3) _(__subdf3) _(__muldf3) _(__divdf3) +#else +#define SFGOTDEF(_) +#endif +#if LJ_HASJIT +#define JITGOTDEF(_) _(lj_err_trace) _(lj_trace_exit) _(lj_trace_hot) +#else +#define JITGOTDEF(_) +#endif +#if LJ_HASFFI +#define FFIGOTDEF(_) \ + _(lj_meta_equal_cd) _(lj_ccallback_enter) _(lj_ccallback_leave) +#else +#define FFIGOTDEF(_) +#endif +#define GOTDEF(_) \ + _(floor) _(ceil) _(trunc) _(log) _(log10) _(exp) _(sin) _(cos) _(tan) \ + _(asin) _(acos) _(atan) _(sinh) _(cosh) _(tanh) _(frexp) _(modf) _(atan2) \ + _(pow) _(fmod) _(ldexp) _(lj_vm_modi) \ + _(lj_dispatch_call) _(lj_dispatch_ins) _(lj_dispatch_stitch) \ + _(lj_dispatch_profile) _(lj_err_throw) \ + _(lj_ffh_coroutine_wrap_err) _(lj_func_closeuv) _(lj_func_newL_gc) \ + _(lj_gc_barrieruv) _(lj_gc_step) _(lj_gc_step_fixtop) _(lj_meta_arith) \ + _(lj_meta_call) _(lj_meta_cat) _(lj_meta_comp) _(lj_meta_equal) \ + _(lj_meta_for) _(lj_meta_istype) _(lj_meta_len) _(lj_meta_tget) \ + _(lj_meta_tset) _(lj_state_growstack) _(lj_strfmt_number) \ + _(lj_str_new) _(lj_tab_dup) _(lj_tab_get) _(lj_tab_getinth) _(lj_tab_len) \ + _(lj_tab_new) _(lj_tab_newkey) _(lj_tab_next) _(lj_tab_reasize) \ + _(lj_tab_setinth) _(lj_buf_putstr_reverse) _(lj_buf_putstr_lower) \ + _(lj_buf_putstr_upper) _(lj_buf_tostr) \ + JITGOTDEF(_) FFIGOTDEF(_) SFGOTDEF(_) + +enum { +#define GOTENUM(name) LJ_GOT_##name, +GOTDEF(GOTENUM) +#undef GOTENUM + LJ_GOT__MAX +}; +#endif + +/* Type of hot counter. Must match the code in the assembler VM. */ +/* 16 bits are sufficient. Only 0.0015% overhead with maximum slot penalty. */ +typedef uint16_t HotCount; + +/* Number of hot counter hash table entries (must be a power of two). */ +#define HOTCOUNT_SIZE 64 +#define HOTCOUNT_PCMASK ((HOTCOUNT_SIZE-1)*sizeof(HotCount)) + +/* Hotcount decrements. */ +#define HOTCOUNT_LOOP 2 +#define HOTCOUNT_CALL 1 + +/* This solves a circular dependency problem -- bump as needed. Sigh. */ +#define GG_NUM_ASMFF 57 + +#define GG_LEN_DDISP (BC__MAX + GG_NUM_ASMFF) +#define GG_LEN_SDISP BC_FUNCF +#define GG_LEN_DISP (GG_LEN_DDISP + GG_LEN_SDISP) + +/* Global state, main thread and extra fields are allocated together. */ +typedef struct GG_State { + lua_State L; /* Main thread. */ + global_State g; /* Global state. */ +#if LJ_TARGET_ARM && !LJ_TARGET_NX + /* Make g reachable via K12 encoded DISPATCH-relative addressing. */ + uint8_t align1[(16-sizeof(global_State))&15]; +#endif +#if LJ_TARGET_MIPS + ASMFunction got[LJ_GOT__MAX]; /* Global offset table. */ +#endif +#if LJ_HASJIT + jit_State J; /* JIT state. */ + HotCount hotcount[HOTCOUNT_SIZE]; /* Hot counters. */ +#if LJ_TARGET_ARM && !LJ_TARGET_NX + /* Ditto for J. */ + uint8_t align2[(16-sizeof(jit_State)-sizeof(HotCount)*HOTCOUNT_SIZE)&15]; +#endif +#endif + ASMFunction dispatch[GG_LEN_DISP]; /* Instruction dispatch tables. */ + BCIns bcff[GG_NUM_ASMFF]; /* Bytecode for ASM fast functions. */ +} GG_State; + +#define GG_OFS(field) ((int)offsetof(GG_State, field)) +#define G2GG(gl) ((GG_State *)((char *)(gl) - GG_OFS(g))) +#define J2GG(j) ((GG_State *)((char *)(j) - GG_OFS(J))) +#define L2GG(L) (G2GG(G(L))) +#define J2G(J) (&J2GG(J)->g) +#define G2J(gl) (&G2GG(gl)->J) +#define L2J(L) (&L2GG(L)->J) +#define GG_G2J (GG_OFS(J) - GG_OFS(g)) +#define GG_G2DISP (GG_OFS(dispatch) - GG_OFS(g)) +#define GG_DISP2G (GG_OFS(g) - GG_OFS(dispatch)) +#define GG_DISP2J (GG_OFS(J) - GG_OFS(dispatch)) +#define GG_DISP2HOT (GG_OFS(hotcount) - GG_OFS(dispatch)) +#define GG_DISP2STATIC (GG_LEN_DDISP*(int)sizeof(ASMFunction)) + +#define hotcount_get(gg, pc) \ + (gg)->hotcount[(u32ptr(pc)>>2) & (HOTCOUNT_SIZE-1)] +#define hotcount_set(gg, pc, val) \ + (hotcount_get((gg), (pc)) = (HotCount)(val)) + +/* Dispatch table management. */ +LJ_FUNC void lj_dispatch_init(GG_State *GG); +#if LJ_HASJIT +LJ_FUNC void lj_dispatch_init_hotcount(global_State *g); +#endif +LJ_FUNC void lj_dispatch_update(global_State *g); + +/* Instruction dispatch callback for hooks or when recording. */ +LJ_FUNCA void LJ_FASTCALL lj_dispatch_ins(lua_State *L, const BCIns *pc); +LJ_FUNCA ASMFunction LJ_FASTCALL lj_dispatch_call(lua_State *L, const BCIns*pc); +#if LJ_HASJIT +LJ_FUNCA void LJ_FASTCALL lj_dispatch_stitch(jit_State *J, const BCIns *pc); +#endif +#if LJ_HASPROFILE +LJ_FUNCA void LJ_FASTCALL lj_dispatch_profile(lua_State *L, const BCIns *pc); +#endif + +#if LJ_HASFFI && !defined(_BUILDVM_H) +/* Save/restore errno and GetLastError() around hooks, exits and recording. */ +#include +#if LJ_TARGET_WINDOWS +#define WIN32_LEAN_AND_MEAN +#include +#define ERRNO_SAVE int olderr = errno; DWORD oldwerr = GetLastError(); +#define ERRNO_RESTORE errno = olderr; SetLastError(oldwerr); +#else +#define ERRNO_SAVE int olderr = errno; +#define ERRNO_RESTORE errno = olderr; +#endif +#else +#define ERRNO_SAVE +#define ERRNO_RESTORE +#endif + +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_emit_arm.h b/fluent-bit/lib/luajit-3065c9/src/lj_emit_arm.h new file mode 100644 index 00000000..cfb174f4 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_emit_arm.h @@ -0,0 +1,361 @@ +/* +** ARM instruction emitter. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +/* -- Constant encoding --------------------------------------------------- */ + +static uint8_t emit_invai[16] = { + /* AND */ (ARMI_AND^ARMI_BIC) >> 21, + /* EOR */ 0, + /* SUB */ (ARMI_SUB^ARMI_ADD) >> 21, + /* RSB */ 0, + /* ADD */ (ARMI_ADD^ARMI_SUB) >> 21, + /* ADC */ (ARMI_ADC^ARMI_SBC) >> 21, + /* SBC */ (ARMI_SBC^ARMI_ADC) >> 21, + /* RSC */ 0, + /* TST */ 0, + /* TEQ */ 0, + /* CMP */ (ARMI_CMP^ARMI_CMN) >> 21, + /* CMN */ (ARMI_CMN^ARMI_CMP) >> 21, + /* ORR */ 0, + /* MOV */ (ARMI_MOV^ARMI_MVN) >> 21, + /* BIC */ (ARMI_BIC^ARMI_AND) >> 21, + /* MVN */ (ARMI_MVN^ARMI_MOV) >> 21 +}; + +/* Encode constant in K12 format for data processing instructions. */ +static uint32_t emit_isk12(ARMIns ai, int32_t n) +{ + uint32_t invai, i, m = (uint32_t)n; + /* K12: unsigned 8 bit value, rotated in steps of two bits. */ + for (i = 0; i < 4096; i += 256, m = lj_rol(m, 2)) + if (m <= 255) return ARMI_K12|m|i; + /* Otherwise try negation/complement with the inverse instruction. */ + invai = emit_invai[((ai >> 21) & 15)]; + if (!invai) return 0; /* Failed. No inverse instruction. */ + m = ~(uint32_t)n; + if (invai == ((ARMI_SUB^ARMI_ADD) >> 21) || + invai == (ARMI_CMP^ARMI_CMN) >> 21) m++; + for (i = 0; i < 4096; i += 256, m = lj_rol(m, 2)) + if (m <= 255) return ARMI_K12|(invai<<21)|m|i; + return 0; /* Failed. */ +} + +/* -- Emit basic instructions --------------------------------------------- */ + +static void emit_dnm(ASMState *as, ARMIns ai, Reg rd, Reg rn, Reg rm) +{ + *--as->mcp = ai | ARMF_D(rd) | ARMF_N(rn) | ARMF_M(rm); +} + +static void emit_dm(ASMState *as, ARMIns ai, Reg rd, Reg rm) +{ + *--as->mcp = ai | ARMF_D(rd) | ARMF_M(rm); +} + +static void emit_dn(ASMState *as, ARMIns ai, Reg rd, Reg rn) +{ + *--as->mcp = ai | ARMF_D(rd) | ARMF_N(rn); +} + +static void emit_nm(ASMState *as, ARMIns ai, Reg rn, Reg rm) +{ + *--as->mcp = ai | ARMF_N(rn) | ARMF_M(rm); +} + +static void emit_d(ASMState *as, ARMIns ai, Reg rd) +{ + *--as->mcp = ai | ARMF_D(rd); +} + +static void emit_n(ASMState *as, ARMIns ai, Reg rn) +{ + *--as->mcp = ai | ARMF_N(rn); +} + +static void emit_m(ASMState *as, ARMIns ai, Reg rm) +{ + *--as->mcp = ai | ARMF_M(rm); +} + +static void emit_lsox(ASMState *as, ARMIns ai, Reg rd, Reg rn, int32_t ofs) +{ + lj_assertA(ofs >= -255 && ofs <= 255, + "load/store offset %d out of range", ofs); + if (ofs < 0) ofs = -ofs; else ai |= ARMI_LS_U; + *--as->mcp = ai | ARMI_LS_P | ARMI_LSX_I | ARMF_D(rd) | ARMF_N(rn) | + ((ofs & 0xf0) << 4) | (ofs & 0x0f); +} + +static void emit_lso(ASMState *as, ARMIns ai, Reg rd, Reg rn, int32_t ofs) +{ + lj_assertA(ofs >= -4095 && ofs <= 4095, + "load/store offset %d out of range", ofs); + /* Combine LDR/STR pairs to LDRD/STRD. */ + if (*as->mcp == (ai|ARMI_LS_P|ARMI_LS_U|ARMF_D(rd^1)|ARMF_N(rn)|(ofs^4)) && + (ai & ~(ARMI_LDR^ARMI_STR)) == ARMI_STR && rd != rn && + (uint32_t)ofs <= 252 && !(ofs & 3) && !((rd ^ (ofs >>2)) & 1) && + as->mcp != as->mcloop) { + as->mcp++; + emit_lsox(as, ai == ARMI_LDR ? ARMI_LDRD : ARMI_STRD, rd&~1, rn, ofs&~4); + return; + } + if (ofs < 0) ofs = -ofs; else ai |= ARMI_LS_U; + *--as->mcp = ai | ARMI_LS_P | ARMF_D(rd) | ARMF_N(rn) | ofs; +} + +#if !LJ_SOFTFP +static void emit_vlso(ASMState *as, ARMIns ai, Reg rd, Reg rn, int32_t ofs) +{ + lj_assertA(ofs >= -1020 && ofs <= 1020 && (ofs&3) == 0, + "load/store offset %d out of range", ofs); + if (ofs < 0) ofs = -ofs; else ai |= ARMI_LS_U; + *--as->mcp = ai | ARMI_LS_P | ARMF_D(rd & 15) | ARMF_N(rn) | (ofs >> 2); +} +#endif + +/* -- Emit loads/stores --------------------------------------------------- */ + +/* Prefer spills of BASE/L. */ +#define emit_canremat(ref) ((ref) < ASMREF_L) + +/* Try to find a one step delta relative to another constant. */ +static int emit_kdelta1(ASMState *as, Reg d, int32_t i) +{ + RegSet work = ~as->freeset & RSET_GPR; + while (work) { + Reg r = rset_picktop(work); + IRRef ref = regcost_ref(as->cost[r]); + lj_assertA(r != d, "dest reg not free"); + if (emit_canremat(ref)) { + int32_t delta = i - (ra_iskref(ref) ? ra_krefk(as, ref) : IR(ref)->i); + uint32_t k = emit_isk12(ARMI_ADD, delta); + if (k) { + if (k == ARMI_K12) + emit_dm(as, ARMI_MOV, d, r); + else + emit_dn(as, ARMI_ADD^k, d, r); + return 1; + } + } + rset_clear(work, r); + } + return 0; /* Failed. */ +} + +/* Try to find a two step delta relative to another constant. */ +static int emit_kdelta2(ASMState *as, Reg rd, int32_t i) +{ + RegSet work = ~as->freeset & RSET_GPR; + while (work) { + Reg r = rset_picktop(work); + IRRef ref = regcost_ref(as->cost[r]); + lj_assertA(r != rd, "dest reg %d not free", rd); + if (emit_canremat(ref)) { + int32_t other = ra_iskref(ref) ? ra_krefk(as, ref) : IR(ref)->i; + if (other) { + int32_t delta = i - other; + uint32_t sh, inv = 0, k2, k; + if (delta < 0) { delta = -delta; inv = ARMI_ADD^ARMI_SUB; } + sh = lj_ffs(delta) & ~1; + k2 = emit_isk12(0, delta & (255 << sh)); + k = emit_isk12(0, delta & ~(255 << sh)); + if (k) { + emit_dn(as, ARMI_ADD^k2^inv, rd, rd); + emit_dn(as, ARMI_ADD^k^inv, rd, r); + return 1; + } + } + } + rset_clear(work, r); + } + return 0; /* Failed. */ +} + +/* Load a 32 bit constant into a GPR. */ +static void emit_loadi(ASMState *as, Reg rd, int32_t i) +{ + uint32_t k = emit_isk12(ARMI_MOV, i); + lj_assertA(rset_test(as->freeset, rd) || rd == RID_TMP, + "dest reg %d not free", rd); + if (k) { + /* Standard K12 constant. */ + emit_d(as, ARMI_MOV^k, rd); + } else if ((as->flags & JIT_F_ARMV6T2) && (uint32_t)i < 0x00010000u) { + /* 16 bit loword constant for ARMv6T2. */ + emit_d(as, ARMI_MOVW|(i & 0x0fff)|((i & 0xf000)<<4), rd); + } else if (emit_kdelta1(as, rd, i)) { + /* One step delta relative to another constant. */ + } else if ((as->flags & JIT_F_ARMV6T2)) { + /* 32 bit hiword/loword constant for ARMv6T2. */ + emit_d(as, ARMI_MOVT|((i>>16) & 0x0fff)|(((i>>16) & 0xf000)<<4), rd); + emit_d(as, ARMI_MOVW|(i & 0x0fff)|((i & 0xf000)<<4), rd); + } else if (emit_kdelta2(as, rd, i)) { + /* Two step delta relative to another constant. */ + } else { + /* Otherwise construct the constant with up to 4 instructions. */ + /* NYI: use mvn+bic, use pc-relative loads. */ + for (;;) { + uint32_t sh = lj_ffs(i) & ~1; + int32_t m = i & (255 << sh); + i &= ~(255 << sh); + if (i == 0) { + emit_d(as, ARMI_MOV ^ emit_isk12(0, m), rd); + break; + } + emit_dn(as, ARMI_ORR ^ emit_isk12(0, m), rd, rd); + } + } +} + +#define emit_loada(as, rd, addr) emit_loadi(as, (rd), i32ptr((addr))) + +static Reg ra_allock(ASMState *as, intptr_t k, RegSet allow); + +/* Get/set from constant pointer. */ +static void emit_lsptr(ASMState *as, ARMIns ai, Reg r, void *p) +{ + int32_t i = i32ptr(p); + emit_lso(as, ai, r, ra_allock(as, (i & ~4095), rset_exclude(RSET_GPR, r)), + (i & 4095)); +} + +#if !LJ_SOFTFP +/* Load a number constant into an FPR. */ +static void emit_loadk64(ASMState *as, Reg r, IRIns *ir) +{ + cTValue *tv = ir_knum(ir); + int32_t i; + if ((as->flags & JIT_F_VFPV3) && !tv->u32.lo) { + uint32_t hi = tv->u32.hi; + uint32_t b = ((hi >> 22) & 0x1ff); + if (!(hi & 0xffff) && (b == 0x100 || b == 0x0ff)) { + *--as->mcp = ARMI_VMOVI_D | ARMF_D(r & 15) | + ((tv->u32.hi >> 12) & 0x00080000) | + ((tv->u32.hi >> 4) & 0x00070000) | + ((tv->u32.hi >> 16) & 0x0000000f); + return; + } + } + i = i32ptr(tv); + emit_vlso(as, ARMI_VLDR_D, r, + ra_allock(as, (i & ~1020), RSET_GPR), (i & 1020)); +} +#endif + +/* Get/set global_State fields. */ +#define emit_getgl(as, r, field) \ + emit_lsptr(as, ARMI_LDR, (r), (void *)&J2G(as->J)->field) +#define emit_setgl(as, r, field) \ + emit_lsptr(as, ARMI_STR, (r), (void *)&J2G(as->J)->field) + +/* Trace number is determined from pc of exit instruction. */ +#define emit_setvmstate(as, i) UNUSED(i) + +/* -- Emit control-flow instructions -------------------------------------- */ + +/* Label for internal jumps. */ +typedef MCode *MCLabel; + +/* Return label pointing to current PC. */ +#define emit_label(as) ((as)->mcp) + +static void emit_branch(ASMState *as, ARMIns ai, MCode *target) +{ + MCode *p = as->mcp; + ptrdiff_t delta = (target - p) - 1; + lj_assertA(((delta + 0x00800000) >> 24) == 0, "branch target out of range"); + *--p = ai | ((uint32_t)delta & 0x00ffffffu); + as->mcp = p; +} + +#define emit_jmp(as, target) emit_branch(as, ARMI_B, (target)) + +static void emit_call(ASMState *as, void *target) +{ + MCode *p = --as->mcp; + ptrdiff_t delta = ((char *)target - (char *)p) - 8; + if ((((delta>>2) + 0x00800000) >> 24) == 0) { + if ((delta & 1)) + *p = ARMI_BLX | ((uint32_t)(delta>>2) & 0x00ffffffu) | ((delta&2) << 23); + else + *p = ARMI_BL | ((uint32_t)(delta>>2) & 0x00ffffffu); + } else { /* Target out of range: need indirect call. But don't use R0-R3. */ + Reg r = ra_allock(as, i32ptr(target), RSET_RANGE(RID_R4, RID_R12+1)); + *p = ARMI_BLXr | ARMF_M(r); + } +} + +/* -- Emit generic operations --------------------------------------------- */ + +/* Generic move between two regs. */ +static void emit_movrr(ASMState *as, IRIns *ir, Reg dst, Reg src) +{ +#if LJ_SOFTFP + lj_assertA(!irt_isnum(ir->t), "unexpected FP op"); UNUSED(ir); +#else + if (dst >= RID_MAX_GPR) { + emit_dm(as, irt_isnum(ir->t) ? ARMI_VMOV_D : ARMI_VMOV_S, + (dst & 15), (src & 15)); + return; + } +#endif + if (as->mcp != as->mcloop) { /* Swap early registers for loads/stores. */ + MCode ins = *as->mcp, swp = (src^dst); + if ((ins & 0x0c000000) == 0x04000000 && (ins & 0x02000010) != 0x02000010) { + if (!((ins ^ (dst << 16)) & 0x000f0000)) + *as->mcp = ins ^ (swp << 16); /* Swap N in load/store. */ + if (!(ins & 0x00100000) && !((ins ^ (dst << 12)) & 0x0000f000)) + *as->mcp = ins ^ (swp << 12); /* Swap D in store. */ + } + } + emit_dm(as, ARMI_MOV, dst, src); +} + +/* Generic load of register with base and (small) offset address. */ +static void emit_loadofs(ASMState *as, IRIns *ir, Reg r, Reg base, int32_t ofs) +{ +#if LJ_SOFTFP + lj_assertA(!irt_isnum(ir->t), "unexpected FP op"); UNUSED(ir); +#else + if (r >= RID_MAX_GPR) + emit_vlso(as, irt_isnum(ir->t) ? ARMI_VLDR_D : ARMI_VLDR_S, r, base, ofs); + else +#endif + emit_lso(as, ARMI_LDR, r, base, ofs); +} + +/* Generic store of register with base and (small) offset address. */ +static void emit_storeofs(ASMState *as, IRIns *ir, Reg r, Reg base, int32_t ofs) +{ +#if LJ_SOFTFP + lj_assertA(!irt_isnum(ir->t), "unexpected FP op"); UNUSED(ir); +#else + if (r >= RID_MAX_GPR) + emit_vlso(as, irt_isnum(ir->t) ? ARMI_VSTR_D : ARMI_VSTR_S, r, base, ofs); + else +#endif + emit_lso(as, ARMI_STR, r, base, ofs); +} + +/* Emit an arithmetic/logic operation with a constant operand. */ +static void emit_opk(ASMState *as, ARMIns ai, Reg dest, Reg src, + int32_t i, RegSet allow) +{ + uint32_t k = emit_isk12(ai, i); + if (k) + emit_dn(as, ai^k, dest, src); + else + emit_dnm(as, ai, dest, src, ra_allock(as, i, allow)); +} + +/* Add offset to pointer. */ +static void emit_addptr(ASMState *as, Reg r, int32_t ofs) +{ + if (ofs) + emit_opk(as, ARMI_ADD, r, r, ofs, rset_exclude(RSET_GPR, r)); +} + +#define emit_spsub(as, ofs) emit_addptr(as, RID_SP, -(ofs)) + diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_emit_arm64.h b/fluent-bit/lib/luajit-3065c9/src/lj_emit_arm64.h new file mode 100644 index 00000000..c4b4c147 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_emit_arm64.h @@ -0,0 +1,424 @@ +/* +** ARM64 instruction emitter. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +** +** Contributed by Djordje Kovacevic and Stefan Pejic from RT-RK.com. +** Sponsored by Cisco Systems, Inc. +*/ + +/* -- Constant encoding --------------------------------------------------- */ + +static uint64_t get_k64val(ASMState *as, IRRef ref) +{ + IRIns *ir = IR(ref); + if (ir->o == IR_KINT64) { + return ir_kint64(ir)->u64; + } else if (ir->o == IR_KGC) { + return (uint64_t)ir_kgc(ir); + } else if (ir->o == IR_KPTR || ir->o == IR_KKPTR) { + return (uint64_t)ir_kptr(ir); + } else { + lj_assertA(ir->o == IR_KINT || ir->o == IR_KNULL, + "bad 64 bit const IR op %d", ir->o); + return ir->i; /* Sign-extended. */ + } +} + +/* Encode constant in K12 format for data processing instructions. */ +static uint32_t emit_isk12(int64_t n) +{ + uint64_t k = (n < 0) ? -n : n; + uint32_t m = (n < 0) ? 0x40000000 : 0; + if (k < 0x1000) { + return A64I_K12|m|A64F_U12(k); + } else if ((k & 0xfff000) == k) { + return A64I_K12|m|0x400000|A64F_U12(k>>12); + } + return 0; +} + +#define emit_clz64(n) __builtin_clzll(n) +#define emit_ctz64(n) __builtin_ctzll(n) + +/* Encode constant in K13 format for logical data processing instructions. */ +static uint32_t emit_isk13(uint64_t n, int is64) +{ + int inv = 0, w = 128, lz, tz; + if (n & 1) { n = ~n; w = 64; inv = 1; } /* Avoid wrap-around of ones. */ + if (!n) return 0; /* Neither all-zero nor all-ones are allowed. */ + do { /* Find the repeat width. */ + if (is64 && (uint32_t)(n^(n>>32))) break; + n = (uint32_t)n; + if (!n) return 0; /* Ditto when passing n=0xffffffff and is64=0. */ + w = 32; if ((n^(n>>16)) & 0xffff) break; + n = n & 0xffff; w = 16; if ((n^(n>>8)) & 0xff) break; + n = n & 0xff; w = 8; if ((n^(n>>4)) & 0xf) break; + n = n & 0xf; w = 4; if ((n^(n>>2)) & 0x3) break; + n = n & 0x3; w = 2; + } while (0); + lz = emit_clz64(n); + tz = emit_ctz64(n); + if ((int64_t)(n << lz) >> (lz+tz) != -1ll) return 0; /* Non-contiguous? */ + if (inv) + return A64I_K13 | (((lz-w) & 127) << 16) | (((lz+tz-w-1) & 63) << 10); + else + return A64I_K13 | ((w-tz) << 16) | (((63-lz-tz-w-w) & 63) << 10); +} + +static uint32_t emit_isfpk64(uint64_t n) +{ + uint64_t etop9 = ((n >> 54) & 0x1ff); + if ((n << 16) == 0 && (etop9 == 0x100 || etop9 == 0x0ff)) { + return (uint32_t)(((n >> 48) & 0x7f) | ((n >> 56) & 0x80)); + } + return ~0u; +} + +/* -- Emit basic instructions --------------------------------------------- */ + +static void emit_dnma(ASMState *as, A64Ins ai, Reg rd, Reg rn, Reg rm, Reg ra) +{ + *--as->mcp = ai | A64F_D(rd) | A64F_N(rn) | A64F_M(rm) | A64F_A(ra); +} + +static void emit_dnm(ASMState *as, A64Ins ai, Reg rd, Reg rn, Reg rm) +{ + *--as->mcp = ai | A64F_D(rd) | A64F_N(rn) | A64F_M(rm); +} + +static void emit_dm(ASMState *as, A64Ins ai, Reg rd, Reg rm) +{ + *--as->mcp = ai | A64F_D(rd) | A64F_M(rm); +} + +static void emit_dn(ASMState *as, A64Ins ai, Reg rd, Reg rn) +{ + *--as->mcp = ai | A64F_D(rd) | A64F_N(rn); +} + +static void emit_nm(ASMState *as, A64Ins ai, Reg rn, Reg rm) +{ + *--as->mcp = ai | A64F_N(rn) | A64F_M(rm); +} + +static void emit_d(ASMState *as, A64Ins ai, Reg rd) +{ + *--as->mcp = ai | A64F_D(rd); +} + +static void emit_n(ASMState *as, A64Ins ai, Reg rn) +{ + *--as->mcp = ai | A64F_N(rn); +} + +static int emit_checkofs(A64Ins ai, int64_t ofs) +{ + int scale = (ai >> 30) & 3; + if (ofs < 0 || (ofs & ((1<= -256 && ofs <= 255) ? -1 : 0; + } else { + return (ofs < (4096<> 30) & 3; + lj_assertA(ot, "load/store offset %d out of range", ofs); + /* Combine LDR/STR pairs to LDP/STP. */ + if ((sc == 2 || sc == 3) && + (!(ai & 0x400000) || rd != rn) && + as->mcp != as->mcloop) { + uint32_t prev = *as->mcp & ~A64F_D(31); + int ofsm = ofs - (1<>sc)) || + prev == ((ai^A64I_LS_U) | A64F_N(rn) | A64F_S9(ofsm&0x1ff))) { + aip = (A64F_A(rd) | A64F_D(*as->mcp & 31)); + } else if (prev == (ai | A64F_N(rn) | A64F_U12(ofsp>>sc)) || + prev == ((ai^A64I_LS_U) | A64F_N(rn) | A64F_S9(ofsp&0x1ff))) { + aip = (A64F_D(rd) | A64F_A(*as->mcp & 31)); + ofsm = ofs; + } else { + goto nopair; + } + if (ofsm >= (int)((unsigned int)-64<mcp = aip | A64F_N(rn) | ((ofsm >> sc) << 15) | + (ai ^ ((ai == A64I_LDRx || ai == A64I_STRx) ? 0x50000000 : 0x90000000)); + return; + } + } +nopair: + if (ot == 1) + *--as->mcp = ai | A64F_D(rd) | A64F_N(rn) | A64F_U12(ofs >> sc); + else + *--as->mcp = (ai^A64I_LS_U) | A64F_D(rd) | A64F_N(rn) | A64F_S9(ofs & 0x1ff); +} + +/* -- Emit loads/stores --------------------------------------------------- */ + +/* Prefer rematerialization of BASE/L from global_State over spills. */ +#define emit_canremat(ref) ((ref) <= ASMREF_L) + +/* Try to find an N-step delta relative to other consts with N < lim. */ +static int emit_kdelta(ASMState *as, Reg rd, uint64_t k, int lim) +{ + RegSet work = (~as->freeset & RSET_GPR) | RID2RSET(RID_GL); + if (lim <= 1) return 0; /* Can't beat that. */ + while (work) { + Reg r = rset_picktop(work); + IRRef ref = regcost_ref(as->cost[r]); + lj_assertA(r != rd, "dest reg %d not free", rd); + if (ref < REF_TRUE) { + uint64_t kx = ra_iskref(ref) ? (uint64_t)ra_krefk(as, ref) : + get_k64val(as, ref); + int64_t delta = (int64_t)(k - kx); + if (delta == 0) { + emit_dm(as, A64I_MOVx, rd, r); + return 1; + } else { + uint32_t k12 = emit_isk12(delta < 0 ? -delta : delta); + if (k12) { + emit_dn(as, (delta < 0 ? A64I_SUBx : A64I_ADDx)^k12, rd, r); + return 1; + } + /* Do other ops or multi-step deltas pay off? Probably not. + ** E.g. XOR rarely helps with pointer consts. + */ + } + } + rset_clear(work, r); + } + return 0; /* Failed. */ +} + +static void emit_loadk(ASMState *as, Reg rd, uint64_t u64, int is64) +{ + int i, zeros = 0, ones = 0, neg; + if (!is64) u64 = (int64_t)(int32_t)u64; /* Sign-extend. */ + /* Count homogeneous 16 bit fragments. */ + for (i = 0; i < 4; i++) { + uint64_t frag = (u64 >> i*16) & 0xffff; + zeros += (frag == 0); + ones += (frag == 0xffff); + } + neg = ones > zeros; /* Use MOVN if it pays off. */ + if ((neg ? ones : zeros) < 3) { /* Need 2+ ins. Try shorter K13 encoding. */ + uint32_t k13 = emit_isk13(u64, is64); + if (k13) { + emit_dn(as, (is64|A64I_ORRw)^k13, rd, RID_ZERO); + return; + } + } + if (!emit_kdelta(as, rd, u64, 4 - (neg ? ones : zeros))) { + int shift = 0, lshift = 0; + uint64_t n64 = neg ? ~u64 : u64; + if (n64 != 0) { + /* Find first/last fragment to be filled. */ + shift = (63-emit_clz64(n64)) & ~15; + lshift = emit_ctz64(n64) & ~15; + } + /* MOVK requires the original value (u64). */ + while (shift > lshift) { + uint32_t u16 = (u64 >> shift) & 0xffff; + /* Skip fragments that are correctly filled by MOVN/MOVZ. */ + if (u16 != (neg ? 0xffff : 0)) + emit_d(as, is64 | A64I_MOVKw | A64F_U16(u16) | A64F_LSL16(shift), rd); + shift -= 16; + } + /* But MOVN needs an inverted value (n64). */ + emit_d(as, (neg ? A64I_MOVNx : A64I_MOVZx) | + A64F_U16((n64 >> lshift) & 0xffff) | A64F_LSL16(lshift), rd); + } +} + +/* Load a 32 bit constant into a GPR. */ +#define emit_loadi(as, rd, i) emit_loadk(as, rd, i, 0) + +/* Load a 64 bit constant into a GPR. */ +#define emit_loadu64(as, rd, i) emit_loadk(as, rd, i, A64I_X) + +#define emit_loada(as, r, addr) emit_loadu64(as, (r), (uintptr_t)(addr)) + +#define glofs(as, k) \ + ((intptr_t)((uintptr_t)(k) - (uintptr_t)&J2GG(as->J)->g)) +#define mcpofs(as, k) \ + ((intptr_t)((uintptr_t)(k) - (uintptr_t)(as->mcp - 1))) +#define checkmcpofs(as, k) \ + (A64F_S_OK(mcpofs(as, k)>>2, 19)) + +static Reg ra_allock(ASMState *as, intptr_t k, RegSet allow); + +/* Get/set from constant pointer. */ +static void emit_lsptr(ASMState *as, A64Ins ai, Reg r, void *p) +{ + /* First, check if ip + offset is in range. */ + if ((ai & 0x00400000) && checkmcpofs(as, p)) { + emit_d(as, A64I_LDRLx | A64F_S19(mcpofs(as, p)>>2), r); + } else { + Reg base = RID_GL; /* Next, try GL + offset. */ + int64_t ofs = glofs(as, p); + if (!emit_checkofs(ai, ofs)) { /* Else split up into base reg + offset. */ + int64_t i64 = i64ptr(p); + base = ra_allock(as, (i64 & ~0x7fffull), rset_exclude(RSET_GPR, r)); + ofs = i64 & 0x7fffull; + } + emit_lso(as, ai, r, base, ofs); + } +} + +/* Load 64 bit IR constant into register. */ +static void emit_loadk64(ASMState *as, Reg r, IRIns *ir) +{ + const uint64_t *k = &ir_k64(ir)->u64; + int64_t ofs; + if (r >= RID_MAX_GPR) { + uint32_t fpk = emit_isfpk64(*k); + if (fpk != ~0u) { + emit_d(as, A64I_FMOV_DI | A64F_FP8(fpk), (r & 31)); + return; + } + } + ofs = glofs(as, k); + if (emit_checkofs(A64I_LDRx, ofs)) { + emit_lso(as, r >= RID_MAX_GPR ? A64I_LDRd : A64I_LDRx, + (r & 31), RID_GL, ofs); + } else { + if (r >= RID_MAX_GPR) { + emit_dn(as, A64I_FMOV_D_R, (r & 31), RID_TMP); + r = RID_TMP; + } + if (checkmcpofs(as, k)) + emit_d(as, A64I_LDRLx | A64F_S19(mcpofs(as, k)>>2), r); + else + emit_loadu64(as, r, *k); + } +} + +/* Get/set global_State fields. */ +#define emit_getgl(as, r, field) \ + emit_lsptr(as, A64I_LDRx, (r), (void *)&J2G(as->J)->field) +#define emit_setgl(as, r, field) \ + emit_lsptr(as, A64I_STRx, (r), (void *)&J2G(as->J)->field) + +/* Trace number is determined from pc of exit instruction. */ +#define emit_setvmstate(as, i) UNUSED(i) + +/* -- Emit control-flow instructions -------------------------------------- */ + +/* Label for internal jumps. */ +typedef MCode *MCLabel; + +/* Return label pointing to current PC. */ +#define emit_label(as) ((as)->mcp) + +static void emit_cond_branch(ASMState *as, A64CC cond, MCode *target) +{ + MCode *p = --as->mcp; + ptrdiff_t delta = target - p; + lj_assertA(A64F_S_OK(delta, 19), "branch target out of range"); + *p = A64I_BCC | A64F_S19(delta) | cond; +} + +static void emit_branch(ASMState *as, A64Ins ai, MCode *target) +{ + MCode *p = --as->mcp; + ptrdiff_t delta = target - p; + lj_assertA(A64F_S_OK(delta, 26), "branch target out of range"); + *p = ai | A64F_S26(delta); +} + +static void emit_tnb(ASMState *as, A64Ins ai, Reg r, uint32_t bit, MCode *target) +{ + MCode *p = --as->mcp; + ptrdiff_t delta = target - p; + lj_assertA(bit < 63, "bit number out of range"); + lj_assertA(A64F_S_OK(delta, 14), "branch target out of range"); + if (bit > 31) ai |= A64I_X; + *p = ai | A64F_BIT(bit & 31) | A64F_S14(delta) | r; +} + +static void emit_cnb(ASMState *as, A64Ins ai, Reg r, MCode *target) +{ + MCode *p = --as->mcp; + ptrdiff_t delta = target - p; + lj_assertA(A64F_S_OK(delta, 19), "branch target out of range"); + *p = ai | A64F_S19(delta) | r; +} + +#define emit_jmp(as, target) emit_branch(as, A64I_B, (target)) + +static void emit_call(ASMState *as, void *target) +{ + MCode *p = --as->mcp; + ptrdiff_t delta = (char *)target - (char *)p; + if (A64F_S_OK(delta>>2, 26)) { + *p = A64I_BL | A64F_S26(delta>>2); + } else { /* Target out of range: need indirect call. But don't use R0-R7. */ + Reg r = ra_allock(as, i64ptr(target), + RSET_RANGE(RID_X8, RID_MAX_GPR)-RSET_FIXED); + *p = A64I_BLR | A64F_N(r); + } +} + +/* -- Emit generic operations --------------------------------------------- */ + +/* Generic move between two regs. */ +static void emit_movrr(ASMState *as, IRIns *ir, Reg dst, Reg src) +{ + if (dst >= RID_MAX_GPR) { + emit_dn(as, irt_isnum(ir->t) ? A64I_FMOV_D : A64I_FMOV_S, + (dst & 31), (src & 31)); + return; + } + if (as->mcp != as->mcloop) { /* Swap early registers for loads/stores. */ + MCode ins = *as->mcp, swp = (src^dst); + if ((ins & 0xbf800000) == 0xb9000000) { + if (!((ins ^ (dst << 5)) & 0x000003e0)) + *as->mcp = ins ^ (swp << 5); /* Swap N in load/store. */ + if (!(ins & 0x00400000) && !((ins ^ dst) & 0x0000001f)) + *as->mcp = ins ^ swp; /* Swap D in store. */ + } + } + emit_dm(as, A64I_MOVx, dst, src); +} + +/* Generic load of register with base and (small) offset address. */ +static void emit_loadofs(ASMState *as, IRIns *ir, Reg r, Reg base, int32_t ofs) +{ + if (r >= RID_MAX_GPR) + emit_lso(as, irt_isnum(ir->t) ? A64I_LDRd : A64I_LDRs, (r & 31), base, ofs); + else + emit_lso(as, irt_is64(ir->t) ? A64I_LDRx : A64I_LDRw, r, base, ofs); +} + +/* Generic store of register with base and (small) offset address. */ +static void emit_storeofs(ASMState *as, IRIns *ir, Reg r, Reg base, int32_t ofs) +{ + if (r >= RID_MAX_GPR) + emit_lso(as, irt_isnum(ir->t) ? A64I_STRd : A64I_STRs, (r & 31), base, ofs); + else + emit_lso(as, irt_is64(ir->t) ? A64I_STRx : A64I_STRw, r, base, ofs); +} + +/* Emit an arithmetic operation with a constant operand. */ +static void emit_opk(ASMState *as, A64Ins ai, Reg dest, Reg src, + int32_t i, RegSet allow) +{ + uint32_t k = emit_isk12(i); + if (k) + emit_dn(as, ai^k, dest, src); + else + emit_dnm(as, ai, dest, src, ra_allock(as, i, allow)); +} + +/* Add offset to pointer. */ +static void emit_addptr(ASMState *as, Reg r, int32_t ofs) +{ + if (ofs) + emit_opk(as, ofs < 0 ? A64I_SUBx : A64I_ADDx, r, r, + ofs < 0 ? -ofs : ofs, rset_exclude(RSET_GPR, r)); +} + +#define emit_spsub(as, ofs) emit_addptr(as, RID_SP, -(ofs)) + diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_emit_mips.h b/fluent-bit/lib/luajit-3065c9/src/lj_emit_mips.h new file mode 100644 index 00000000..0cea5479 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_emit_mips.h @@ -0,0 +1,310 @@ +/* +** MIPS instruction emitter. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#if LJ_64 +static intptr_t get_k64val(ASMState *as, IRRef ref) +{ + IRIns *ir = IR(ref); + if (ir->o == IR_KINT64) { + return (intptr_t)ir_kint64(ir)->u64; + } else if (ir->o == IR_KGC) { + return (intptr_t)ir_kgc(ir); + } else if (ir->o == IR_KPTR || ir->o == IR_KKPTR) { + return (intptr_t)ir_kptr(ir); + } else if (LJ_SOFTFP && ir->o == IR_KNUM) { + return (intptr_t)ir_knum(ir)->u64; + } else { + lj_assertA(ir->o == IR_KINT || ir->o == IR_KNULL, + "bad 64 bit const IR op %d", ir->o); + return ir->i; /* Sign-extended. */ + } +} +#endif + +#if LJ_64 +#define get_kval(as, ref) get_k64val(as, ref) +#else +#define get_kval(as, ref) (IR((ref))->i) +#endif + +/* -- Emit basic instructions --------------------------------------------- */ + +static void emit_dst(ASMState *as, MIPSIns mi, Reg rd, Reg rs, Reg rt) +{ + *--as->mcp = mi | MIPSF_D(rd) | MIPSF_S(rs) | MIPSF_T(rt); +} + +static void emit_dta(ASMState *as, MIPSIns mi, Reg rd, Reg rt, uint32_t a) +{ + *--as->mcp = mi | MIPSF_D(rd) | MIPSF_T(rt) | MIPSF_A(a); +} + +#define emit_ds(as, mi, rd, rs) emit_dst(as, (mi), (rd), (rs), 0) +#define emit_tg(as, mi, rt, rg) emit_dst(as, (mi), (rg)&31, 0, (rt)) + +static void emit_tsi(ASMState *as, MIPSIns mi, Reg rt, Reg rs, int32_t i) +{ + *--as->mcp = mi | MIPSF_T(rt) | MIPSF_S(rs) | (i & 0xffff); +} + +#define emit_ti(as, mi, rt, i) emit_tsi(as, (mi), (rt), 0, (i)) +#define emit_hsi(as, mi, rh, rs, i) emit_tsi(as, (mi), (rh) & 31, (rs), (i)) + +static void emit_fgh(ASMState *as, MIPSIns mi, Reg rf, Reg rg, Reg rh) +{ + *--as->mcp = mi | MIPSF_F(rf&31) | MIPSF_G(rg&31) | MIPSF_H(rh&31); +} + +#define emit_fg(as, mi, rf, rg) emit_fgh(as, (mi), (rf), (rg), 0) + +static void emit_rotr(ASMState *as, Reg dest, Reg src, Reg tmp, uint32_t shift) +{ + if (LJ_64 || (as->flags & JIT_F_MIPSXXR2)) { + emit_dta(as, MIPSI_ROTR, dest, src, shift); + } else { + emit_dst(as, MIPSI_OR, dest, dest, tmp); + emit_dta(as, MIPSI_SLL, dest, src, (-shift)&31); + emit_dta(as, MIPSI_SRL, tmp, src, shift); + } +} + +#if LJ_64 || LJ_HASBUFFER +static void emit_tsml(ASMState *as, MIPSIns mi, Reg rt, Reg rs, uint32_t msb, + uint32_t lsb) +{ + *--as->mcp = mi | MIPSF_T(rt) | MIPSF_S(rs) | MIPSF_M(msb) | MIPSF_L(lsb); +} +#endif + +/* -- Emit loads/stores --------------------------------------------------- */ + +/* Prefer rematerialization of BASE/L from global_State over spills. */ +#define emit_canremat(ref) ((ref) <= REF_BASE) + +/* Try to find a one step delta relative to another constant. */ +static int emit_kdelta1(ASMState *as, Reg rd, intptr_t i) +{ + RegSet work = ~as->freeset & RSET_GPR; + while (work) { + Reg r = rset_picktop(work); + IRRef ref = regcost_ref(as->cost[r]); + lj_assertA(r != rd, "dest reg %d not free", rd); + if (ref < ASMREF_L) { + intptr_t delta = (intptr_t)((uintptr_t)i - + (uintptr_t)(ra_iskref(ref) ? ra_krefk(as, ref) : get_kval(as, ref))); + if (checki16(delta)) { + emit_tsi(as, MIPSI_AADDIU, rd, r, delta); + return 1; + } + } + rset_clear(work, r); + } + return 0; /* Failed. */ +} + +/* Load a 32 bit constant into a GPR. */ +static void emit_loadi(ASMState *as, Reg r, int32_t i) +{ + if (checki16(i)) { + emit_ti(as, MIPSI_LI, r, i); + } else { + if ((i & 0xffff)) { + intptr_t jgl = (intptr_t)(void *)J2G(as->J); + if ((uintptr_t)(i-jgl) < 65536) { + emit_tsi(as, MIPSI_ADDIU, r, RID_JGL, i-jgl-32768); + return; + } else if (emit_kdelta1(as, r, i)) { + return; + } else if ((i >> 16) == 0) { + emit_tsi(as, MIPSI_ORI, r, RID_ZERO, i); + return; + } + emit_tsi(as, MIPSI_ORI, r, r, i); + } + emit_ti(as, MIPSI_LUI, r, (i >> 16)); + } +} + +#if LJ_64 +/* Load a 64 bit constant into a GPR. */ +static void emit_loadu64(ASMState *as, Reg r, uint64_t u64) +{ + if (checki32((int64_t)u64)) { + emit_loadi(as, r, (int32_t)u64); + } else { + uint64_t delta = u64 - (uint64_t)(void *)J2G(as->J); + if (delta < 65536) { + emit_tsi(as, MIPSI_DADDIU, r, RID_JGL, (int32_t)(delta-32768)); + } else if (emit_kdelta1(as, r, (intptr_t)u64)) { + return; + } else { + /* TODO MIPSR6: Use DAHI & DATI. Caveat: sign-extension. */ + if ((u64 & 0xffff)) { + emit_tsi(as, MIPSI_ORI, r, r, u64 & 0xffff); + } + if (((u64 >> 16) & 0xffff)) { + emit_dta(as, MIPSI_DSLL, r, r, 16); + emit_tsi(as, MIPSI_ORI, r, r, (u64 >> 16) & 0xffff); + emit_dta(as, MIPSI_DSLL, r, r, 16); + } else { + emit_dta(as, MIPSI_DSLL32, r, r, 0); + } + emit_loadi(as, r, (int32_t)(u64 >> 32)); + } + /* TODO: There are probably more optimization opportunities. */ + } +} + +#define emit_loada(as, r, addr) emit_loadu64(as, (r), u64ptr((addr))) +#else +#define emit_loada(as, r, addr) emit_loadi(as, (r), i32ptr((addr))) +#endif + +static Reg ra_allock(ASMState *as, intptr_t k, RegSet allow); +static void ra_allockreg(ASMState *as, intptr_t k, Reg r); + +/* Get/set from constant pointer. */ +static void emit_lsptr(ASMState *as, MIPSIns mi, Reg r, void *p, RegSet allow) +{ + intptr_t jgl = (intptr_t)(J2G(as->J)); + intptr_t i = (intptr_t)(p); + Reg base; + if ((uint32_t)(i-jgl) < 65536) { + i = i-jgl-32768; + base = RID_JGL; + } else { + base = ra_allock(as, i-(int16_t)i, allow); + } + emit_tsi(as, mi, r, base, i); +} + +#if LJ_64 +static void emit_loadk64(ASMState *as, Reg r, IRIns *ir) +{ + const uint64_t *k = &ir_k64(ir)->u64; + Reg r64 = r; + if (rset_test(RSET_FPR, r)) { + r64 = RID_TMP; + emit_tg(as, MIPSI_DMTC1, r64, r); + } + if ((uint32_t)((intptr_t)k-(intptr_t)J2G(as->J)) < 65536) + emit_lsptr(as, MIPSI_LD, r64, (void *)k, 0); + else + emit_loadu64(as, r64, *k); +} +#else +#define emit_loadk64(as, r, ir) \ + emit_lsptr(as, MIPSI_LDC1, ((r) & 31), (void *)&ir_knum((ir))->u64, RSET_GPR) +#endif + +/* Get/set global_State fields. */ +static void emit_lsglptr(ASMState *as, MIPSIns mi, Reg r, int32_t ofs) +{ + emit_tsi(as, mi, r, RID_JGL, ofs-32768); +} + +#define emit_getgl(as, r, field) \ + emit_lsglptr(as, MIPSI_AL, (r), (int32_t)offsetof(global_State, field)) +#define emit_setgl(as, r, field) \ + emit_lsglptr(as, MIPSI_AS, (r), (int32_t)offsetof(global_State, field)) + +/* Trace number is determined from per-trace exit stubs. */ +#define emit_setvmstate(as, i) UNUSED(i) + +/* -- Emit control-flow instructions -------------------------------------- */ + +/* Label for internal jumps. */ +typedef MCode *MCLabel; + +/* Return label pointing to current PC. */ +#define emit_label(as) ((as)->mcp) + +static void emit_branch(ASMState *as, MIPSIns mi, Reg rs, Reg rt, MCode *target) +{ + MCode *p = as->mcp; + ptrdiff_t delta = target - p; + lj_assertA(((delta + 0x8000) >> 16) == 0, "branch target out of range"); + *--p = mi | MIPSF_S(rs) | MIPSF_T(rt) | ((uint32_t)delta & 0xffffu); + as->mcp = p; +} + +static void emit_jmp(ASMState *as, MCode *target) +{ + *--as->mcp = MIPSI_NOP; + emit_branch(as, MIPSI_B, RID_ZERO, RID_ZERO, (target)); +} + +static void emit_call(ASMState *as, void *target, int needcfa) +{ + MCode *p = as->mcp; +#if LJ_TARGET_MIPSR6 + ptrdiff_t delta = (char *)target - (char *)p; + if ((((delta>>2) + 0x02000000) >> 26) == 0) { /* Try compact call first. */ + *--p = MIPSI_BALC | (((uintptr_t)delta >>2) & 0x03ffffffu); + as->mcp = p; + return; + } +#endif + *--p = MIPSI_NOP; /* Delay slot. */ + if ((((uintptr_t)target ^ (uintptr_t)p) >> 28) == 0) { +#if !LJ_TARGET_MIPSR6 + *--p = (((uintptr_t)target & 1) ? MIPSI_JALX : MIPSI_JAL) | + (((uintptr_t)target >>2) & 0x03ffffffu); +#else + *--p = MIPSI_JAL | (((uintptr_t)target >>2) & 0x03ffffffu); +#endif + } else { /* Target out of range: need indirect call. */ + *--p = MIPSI_JALR | MIPSF_S(RID_CFUNCADDR); + needcfa = 1; + } + as->mcp = p; + if (needcfa) ra_allockreg(as, (intptr_t)target, RID_CFUNCADDR); +} + +/* -- Emit generic operations --------------------------------------------- */ + +#define emit_move(as, dst, src) \ + emit_ds(as, MIPSI_MOVE, (dst), (src)) + +/* Generic move between two regs. */ +static void emit_movrr(ASMState *as, IRIns *ir, Reg dst, Reg src) +{ + if (dst < RID_MAX_GPR) + emit_move(as, dst, src); + else + emit_fg(as, irt_isnum(ir->t) ? MIPSI_MOV_D : MIPSI_MOV_S, dst, src); +} + +/* Generic load of register with base and (small) offset address. */ +static void emit_loadofs(ASMState *as, IRIns *ir, Reg r, Reg base, int32_t ofs) +{ + if (r < RID_MAX_GPR) + emit_tsi(as, irt_is64(ir->t) ? MIPSI_LD : MIPSI_LW, r, base, ofs); + else + emit_tsi(as, irt_isnum(ir->t) ? MIPSI_LDC1 : MIPSI_LWC1, + (r & 31), base, ofs); +} + +/* Generic store of register with base and (small) offset address. */ +static void emit_storeofs(ASMState *as, IRIns *ir, Reg r, Reg base, int32_t ofs) +{ + if (r < RID_MAX_GPR) + emit_tsi(as, irt_is64(ir->t) ? MIPSI_SD : MIPSI_SW, r, base, ofs); + else + emit_tsi(as, irt_isnum(ir->t) ? MIPSI_SDC1 : MIPSI_SWC1, + (r&31), base, ofs); +} + +/* Add offset to pointer. */ +static void emit_addptr(ASMState *as, Reg r, int32_t ofs) +{ + if (ofs) { + lj_assertA(checki16(ofs), "offset %d out of range", ofs); + emit_tsi(as, MIPSI_AADDIU, r, r, ofs); + } +} + +#define emit_spsub(as, ofs) emit_addptr(as, RID_SP, -(ofs)) + diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_emit_ppc.h b/fluent-bit/lib/luajit-3065c9/src/lj_emit_ppc.h new file mode 100644 index 00000000..86760e78 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_emit_ppc.h @@ -0,0 +1,238 @@ +/* +** PPC instruction emitter. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +/* -- Emit basic instructions --------------------------------------------- */ + +static void emit_tab(ASMState *as, PPCIns pi, Reg rt, Reg ra, Reg rb) +{ + *--as->mcp = pi | PPCF_T(rt) | PPCF_A(ra) | PPCF_B(rb); +} + +#define emit_asb(as, pi, ra, rs, rb) emit_tab(as, (pi), (rs), (ra), (rb)) +#define emit_as(as, pi, ra, rs) emit_tab(as, (pi), (rs), (ra), 0) +#define emit_ab(as, pi, ra, rb) emit_tab(as, (pi), 0, (ra), (rb)) + +static void emit_tai(ASMState *as, PPCIns pi, Reg rt, Reg ra, int32_t i) +{ + *--as->mcp = pi | PPCF_T(rt) | PPCF_A(ra) | (i & 0xffff); +} + +#define emit_ti(as, pi, rt, i) emit_tai(as, (pi), (rt), 0, (i)) +#define emit_ai(as, pi, ra, i) emit_tai(as, (pi), 0, (ra), (i)) +#define emit_asi(as, pi, ra, rs, i) emit_tai(as, (pi), (rs), (ra), (i)) + +#define emit_fab(as, pi, rf, ra, rb) \ + emit_tab(as, (pi), (rf)&31, (ra)&31, (rb)&31) +#define emit_fb(as, pi, rf, rb) emit_tab(as, (pi), (rf)&31, 0, (rb)&31) +#define emit_fac(as, pi, rf, ra, rc) \ + emit_tab(as, (pi) | PPCF_C((rc) & 31), (rf)&31, (ra)&31, 0) +#define emit_facb(as, pi, rf, ra, rc, rb) \ + emit_tab(as, (pi) | PPCF_C((rc) & 31), (rf)&31, (ra)&31, (rb)&31) +#define emit_fai(as, pi, rf, ra, i) emit_tai(as, (pi), (rf)&31, (ra), (i)) + +static void emit_rot(ASMState *as, PPCIns pi, Reg ra, Reg rs, + int32_t n, int32_t b, int32_t e) +{ + *--as->mcp = pi | PPCF_T(rs) | PPCF_A(ra) | PPCF_B(n) | + PPCF_MB(b) | PPCF_ME(e); +} + +static void emit_slwi(ASMState *as, Reg ra, Reg rs, int32_t n) +{ + lj_assertA(n >= 0 && n < 32, "shift out or range"); + emit_rot(as, PPCI_RLWINM, ra, rs, n, 0, 31-n); +} + +static void emit_rotlwi(ASMState *as, Reg ra, Reg rs, int32_t n) +{ + lj_assertA(n >= 0 && n < 32, "shift out or range"); + emit_rot(as, PPCI_RLWINM, ra, rs, n, 0, 31); +} + +/* -- Emit loads/stores --------------------------------------------------- */ + +/* Prefer rematerialization of BASE/L from global_State over spills. */ +#define emit_canremat(ref) ((ref) <= REF_BASE) + +/* Try to find a one step delta relative to another constant. */ +static int emit_kdelta1(ASMState *as, Reg rd, int32_t i) +{ + RegSet work = ~as->freeset & RSET_GPR; + while (work) { + Reg r = rset_picktop(work); + IRRef ref = regcost_ref(as->cost[r]); + lj_assertA(r != rd, "dest reg %d not free", rd); + if (ref < ASMREF_L) { + int32_t delta = i - (ra_iskref(ref) ? ra_krefk(as, ref) : IR(ref)->i); + if (checki16(delta)) { + emit_tai(as, PPCI_ADDI, rd, r, delta); + return 1; + } + } + rset_clear(work, r); + } + return 0; /* Failed. */ +} + +/* Load a 32 bit constant into a GPR. */ +static void emit_loadi(ASMState *as, Reg r, int32_t i) +{ + if (checki16(i)) { + emit_ti(as, PPCI_LI, r, i); + } else { + if ((i & 0xffff)) { + int32_t jgl = i32ptr(J2G(as->J)); + if ((uint32_t)(i-jgl) < 65536) { + emit_tai(as, PPCI_ADDI, r, RID_JGL, i-jgl-32768); + return; + } else if (emit_kdelta1(as, r, i)) { + return; + } + emit_asi(as, PPCI_ORI, r, r, i); + } + emit_ti(as, PPCI_LIS, r, (i >> 16)); + } +} + +#define emit_loada(as, r, addr) emit_loadi(as, (r), i32ptr((addr))) + +static Reg ra_allock(ASMState *as, intptr_t k, RegSet allow); + +/* Get/set from constant pointer. */ +static void emit_lsptr(ASMState *as, PPCIns pi, Reg r, void *p, RegSet allow) +{ + int32_t jgl = i32ptr(J2G(as->J)); + int32_t i = i32ptr(p); + Reg base; + if ((uint32_t)(i-jgl) < 65536) { + i = i-jgl-32768; + base = RID_JGL; + } else { + base = ra_allock(as, i-(int16_t)i, allow); + } + emit_tai(as, pi, r, base, i); +} + +#define emit_loadk64(as, r, ir) \ + emit_lsptr(as, PPCI_LFD, ((r) & 31), (void *)&ir_knum((ir))->u64, RSET_GPR) + +/* Get/set global_State fields. */ +static void emit_lsglptr(ASMState *as, PPCIns pi, Reg r, int32_t ofs) +{ + emit_tai(as, pi, r, RID_JGL, ofs-32768); +} + +#define emit_getgl(as, r, field) \ + emit_lsglptr(as, PPCI_LWZ, (r), (int32_t)offsetof(global_State, field)) +#define emit_setgl(as, r, field) \ + emit_lsglptr(as, PPCI_STW, (r), (int32_t)offsetof(global_State, field)) + +/* Trace number is determined from per-trace exit stubs. */ +#define emit_setvmstate(as, i) UNUSED(i) + +/* -- Emit control-flow instructions -------------------------------------- */ + +/* Label for internal jumps. */ +typedef MCode *MCLabel; + +/* Return label pointing to current PC. */ +#define emit_label(as) ((as)->mcp) + +static void emit_condbranch(ASMState *as, PPCIns pi, PPCCC cc, MCode *target) +{ + MCode *p = --as->mcp; + ptrdiff_t delta = (char *)target - (char *)p; + lj_assertA(((delta + 0x8000) >> 16) == 0, "branch target out of range"); + pi ^= (delta & 0x8000) * (PPCF_Y/0x8000); + *p = pi | PPCF_CC(cc) | ((uint32_t)delta & 0xffffu); +} + +static void emit_jmp(ASMState *as, MCode *target) +{ + MCode *p = --as->mcp; + ptrdiff_t delta = (char *)target - (char *)p; + *p = PPCI_B | (delta & 0x03fffffcu); +} + +static void emit_call(ASMState *as, void *target) +{ + MCode *p = --as->mcp; + ptrdiff_t delta = (char *)target - (char *)p; + if ((((delta>>2) + 0x00800000) >> 24) == 0) { + *p = PPCI_BL | (delta & 0x03fffffcu); + } else { /* Target out of range: need indirect call. Don't use arg reg. */ + RegSet allow = RSET_GPR & ~RSET_RANGE(RID_R0, REGARG_LASTGPR+1); + Reg r = ra_allock(as, i32ptr(target), allow); + *p = PPCI_BCTRL; + p[-1] = PPCI_MTCTR | PPCF_T(r); + as->mcp = p-1; + } +} + +/* -- Emit generic operations --------------------------------------------- */ + +#define emit_mr(as, dst, src) \ + emit_asb(as, PPCI_MR, (dst), (src), (src)) + +/* Generic move between two regs. */ +static void emit_movrr(ASMState *as, IRIns *ir, Reg dst, Reg src) +{ + UNUSED(ir); + if (dst < RID_MAX_GPR) + emit_mr(as, dst, src); + else + emit_fb(as, PPCI_FMR, dst, src); +} + +/* Generic load of register with base and (small) offset address. */ +static void emit_loadofs(ASMState *as, IRIns *ir, Reg r, Reg base, int32_t ofs) +{ + if (r < RID_MAX_GPR) + emit_tai(as, PPCI_LWZ, r, base, ofs); + else + emit_fai(as, irt_isnum(ir->t) ? PPCI_LFD : PPCI_LFS, r, base, ofs); +} + +/* Generic store of register with base and (small) offset address. */ +static void emit_storeofs(ASMState *as, IRIns *ir, Reg r, Reg base, int32_t ofs) +{ + if (r < RID_MAX_GPR) + emit_tai(as, PPCI_STW, r, base, ofs); + else + emit_fai(as, irt_isnum(ir->t) ? PPCI_STFD : PPCI_STFS, r, base, ofs); +} + +/* Emit a compare (for equality) with a constant operand. */ +static void emit_cmpi(ASMState *as, Reg r, int32_t k) +{ + if (checki16(k)) { + emit_ai(as, PPCI_CMPWI, r, k); + } else if (checku16(k)) { + emit_ai(as, PPCI_CMPLWI, r, k); + } else { + emit_ai(as, PPCI_CMPLWI, RID_TMP, k); + emit_asi(as, PPCI_XORIS, RID_TMP, r, (k >> 16)); + } +} + +/* Add offset to pointer. */ +static void emit_addptr(ASMState *as, Reg r, int32_t ofs) +{ + if (ofs) { + emit_tai(as, PPCI_ADDI, r, r, ofs); + if (!checki16(ofs)) + emit_tai(as, PPCI_ADDIS, r, r, (ofs + 32768) >> 16); + } +} + +static void emit_spsub(ASMState *as, int32_t ofs) +{ + if (ofs) { + emit_tai(as, PPCI_STWU, RID_TMP, RID_SP, -ofs); + emit_tai(as, PPCI_ADDI, RID_TMP, RID_SP, + CFRAME_SIZE + (as->parent ? as->parent->spadjust : 0)); + } +} + diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_emit_x86.h b/fluent-bit/lib/luajit-3065c9/src/lj_emit_x86.h new file mode 100644 index 00000000..3d3beda3 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_emit_x86.h @@ -0,0 +1,572 @@ +/* +** x86/x64 instruction emitter. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +/* -- Emit basic instructions --------------------------------------------- */ + +#define MODRM(mode, r1, r2) ((MCode)((mode)+(((r1)&7)<<3)+((r2)&7))) + +#if LJ_64 +#define REXRB(p, rr, rb) \ + { MCode rex = 0x40 + (((rr)>>1)&4) + (((rb)>>3)&1); \ + if (rex != 0x40) *--(p) = rex; } +#define FORCE_REX 0x200 +#define REX_64 (FORCE_REX|0x080000) +#define VEX_64 0x800000 +#else +#define REXRB(p, rr, rb) ((void)0) +#define FORCE_REX 0 +#define REX_64 0 +#define VEX_64 0 +#endif +#if LJ_GC64 +#define REX_GC64 REX_64 +#else +#define REX_GC64 0 +#endif + +#define emit_i8(as, i) (*--as->mcp = (MCode)(i)) +#define emit_i32(as, i) (*(int32_t *)(as->mcp-4) = (i), as->mcp -= 4) +#define emit_u32(as, u) (*(uint32_t *)(as->mcp-4) = (u), as->mcp -= 4) + +#define emit_x87op(as, xo) \ + (*(uint16_t *)(as->mcp-2) = (uint16_t)(xo), as->mcp -= 2) + +/* op */ +static LJ_AINLINE MCode *emit_op(x86Op xo, Reg rr, Reg rb, Reg rx, + MCode *p, int delta) +{ + int n = (int8_t)xo; + if (n == -60) { /* VEX-encoded instruction */ +#if LJ_64 + xo ^= (((rr>>1)&4)+((rx>>2)&2)+((rb>>3)&1))<<13; +#endif + *(uint32_t *)(p+delta-5) = (uint32_t)xo; + return p+delta-5; + } +#if defined(__GNUC__) || defined(__clang__) + if (__builtin_constant_p(xo) && n == -2) + p[delta-2] = (MCode)(xo >> 24); + else if (__builtin_constant_p(xo) && n == -3) + *(uint16_t *)(p+delta-3) = (uint16_t)(xo >> 16); + else +#endif + *(uint32_t *)(p+delta-5) = (uint32_t)xo; + p += n + delta; +#if LJ_64 + { + uint32_t rex = 0x40 + ((rr>>1)&(4+(FORCE_REX>>1)))+((rx>>2)&2)+((rb>>3)&1); + if (rex != 0x40) { + rex |= (rr >> 16); + if (n == -4) { *p = (MCode)rex; rex = (MCode)(xo >> 8); } + else if ((xo & 0xffffff) == 0x6600fd) { *p = (MCode)rex; rex = 0x66; } + *--p = (MCode)rex; + } + } +#else + UNUSED(rr); UNUSED(rb); UNUSED(rx); +#endif + return p; +} + +/* op + modrm */ +#define emit_opm(xo, mode, rr, rb, p, delta) \ + (p[(delta)-1] = MODRM((mode), (rr), (rb)), \ + emit_op((xo), (rr), (rb), 0, (p), (delta))) + +/* op + modrm + sib */ +#define emit_opmx(xo, mode, scale, rr, rb, rx, p) \ + (p[-1] = MODRM((scale), (rx), (rb)), \ + p[-2] = MODRM((mode), (rr), RID_ESP), \ + emit_op((xo), (rr), (rb), (rx), (p), -1)) + +/* op r1, r2 */ +static void emit_rr(ASMState *as, x86Op xo, Reg r1, Reg r2) +{ + MCode *p = as->mcp; + as->mcp = emit_opm(xo, XM_REG, r1, r2, p, 0); +} + +#if LJ_64 && defined(LUA_USE_ASSERT) +/* [addr] is sign-extended in x64 and must be in lower 2G (not 4G). */ +static int32_t ptr2addr(const void *p) +{ + lj_assertX((uintptr_t)p < (uintptr_t)0x80000000, "pointer outside 2G range"); + return i32ptr(p); +} +#else +#define ptr2addr(p) (i32ptr((p))) +#endif + +/* op r, [base+ofs] */ +static void emit_rmro(ASMState *as, x86Op xo, Reg rr, Reg rb, int32_t ofs) +{ + MCode *p = as->mcp; + x86Mode mode; + if (ra_hasreg(rb)) { + if (LJ_GC64 && rb == RID_RIP) { + mode = XM_OFS0; + p -= 4; + *(int32_t *)p = ofs; + } else if (ofs == 0 && (rb&7) != RID_EBP) { + mode = XM_OFS0; + } else if (checki8(ofs)) { + *--p = (MCode)ofs; + mode = XM_OFS8; + } else { + p -= 4; + *(int32_t *)p = ofs; + mode = XM_OFS32; + } + if ((rb&7) == RID_ESP) + *--p = MODRM(XM_SCALE1, RID_ESP, RID_ESP); + } else { + *(int32_t *)(p-4) = ofs; +#if LJ_64 + p[-5] = MODRM(XM_SCALE1, RID_ESP, RID_EBP); + p -= 5; + rb = RID_ESP; +#else + p -= 4; + rb = RID_EBP; +#endif + mode = XM_OFS0; + } + as->mcp = emit_opm(xo, mode, rr, rb, p, 0); +} + +/* op r, [base+idx*scale+ofs] */ +static void emit_rmrxo(ASMState *as, x86Op xo, Reg rr, Reg rb, Reg rx, + x86Mode scale, int32_t ofs) +{ + MCode *p = as->mcp; + x86Mode mode; + if (ofs == 0 && (rb&7) != RID_EBP) { + mode = XM_OFS0; + } else if (checki8(ofs)) { + mode = XM_OFS8; + *--p = (MCode)ofs; + } else { + mode = XM_OFS32; + p -= 4; + *(int32_t *)p = ofs; + } + as->mcp = emit_opmx(xo, mode, scale, rr, rb, rx, p); +} + +/* op r, i */ +static void emit_gri(ASMState *as, x86Group xg, Reg rb, int32_t i) +{ + MCode *p = as->mcp; + x86Op xo; + if (checki8(i)) { + *--p = (MCode)i; + xo = XG_TOXOi8(xg); + } else { + p -= 4; + *(int32_t *)p = i; + xo = XG_TOXOi(xg); + } + as->mcp = emit_opm(xo, XM_REG, (Reg)(xg & 7) | (rb & REX_64), rb, p, 0); +} + +/* op [base+ofs], i */ +static void emit_gmroi(ASMState *as, x86Group xg, Reg rb, int32_t ofs, + int32_t i) +{ + x86Op xo; + if (checki8(i)) { + emit_i8(as, i); + xo = XG_TOXOi8(xg); + } else { + emit_i32(as, i); + xo = XG_TOXOi(xg); + } + emit_rmro(as, xo, (Reg)(xg & 7), rb, ofs); +} + +#define emit_shifti(as, xg, r, i) \ + (emit_i8(as, (i)), emit_rr(as, XO_SHIFTi, (Reg)(xg), (r))) + +/* op r, rm/mrm */ +static void emit_mrm(ASMState *as, x86Op xo, Reg rr, Reg rb) +{ + MCode *p = as->mcp; + x86Mode mode = XM_REG; + if (rb == RID_MRM) { + rb = as->mrm.base; + if (rb == RID_NONE) { + rb = RID_EBP; + mode = XM_OFS0; + p -= 4; + *(int32_t *)p = as->mrm.ofs; + if (as->mrm.idx != RID_NONE) + goto mrmidx; +#if LJ_64 + *--p = MODRM(XM_SCALE1, RID_ESP, RID_EBP); + rb = RID_ESP; +#endif + } else if (LJ_GC64 && rb == RID_RIP) { + lj_assertA(as->mrm.idx == RID_NONE, "RIP-rel mrm cannot have index"); + mode = XM_OFS0; + p -= 4; + *(int32_t *)p = as->mrm.ofs; + } else { + if (as->mrm.ofs == 0 && (rb&7) != RID_EBP) { + mode = XM_OFS0; + } else if (checki8(as->mrm.ofs)) { + *--p = (MCode)as->mrm.ofs; + mode = XM_OFS8; + } else { + p -= 4; + *(int32_t *)p = as->mrm.ofs; + mode = XM_OFS32; + } + if (as->mrm.idx != RID_NONE) { + mrmidx: + as->mcp = emit_opmx(xo, mode, as->mrm.scale, rr, rb, as->mrm.idx, p); + return; + } + if ((rb&7) == RID_ESP) + *--p = MODRM(XM_SCALE1, RID_ESP, RID_ESP); + } + } + as->mcp = emit_opm(xo, mode, rr, rb, p, 0); +} + +/* op rm/mrm, i */ +static void emit_gmrmi(ASMState *as, x86Group xg, Reg rb, int32_t i) +{ + x86Op xo; + if (checki8(i)) { + emit_i8(as, i); + xo = XG_TOXOi8(xg); + } else { + emit_i32(as, i); + xo = XG_TOXOi(xg); + } + emit_mrm(as, xo, (Reg)(xg & 7) | (rb & REX_64), (rb & ~REX_64)); +} + +/* -- Emit loads/stores --------------------------------------------------- */ + +/* mov [base+ofs], i */ +static void emit_movmroi(ASMState *as, Reg base, int32_t ofs, int32_t i) +{ + emit_i32(as, i); + emit_rmro(as, XO_MOVmi, 0, base, ofs); +} + +/* mov [base+ofs], r */ +#define emit_movtomro(as, r, base, ofs) \ + emit_rmro(as, XO_MOVto, (r), (base), (ofs)) + +/* Get/set global_State fields. */ +#define emit_opgl(as, xo, r, field) \ + emit_rma(as, (xo), (r), (void *)&J2G(as->J)->field) +#define emit_getgl(as, r, field) emit_opgl(as, XO_MOV, (r)|REX_GC64, field) +#define emit_setgl(as, r, field) emit_opgl(as, XO_MOVto, (r)|REX_GC64, field) + +#define emit_setvmstate(as, i) \ + (emit_i32(as, i), emit_opgl(as, XO_MOVmi, 0, vmstate)) + +/* mov r, i / xor r, r */ +static void emit_loadi(ASMState *as, Reg r, int32_t i) +{ + /* XOR r,r is shorter, but modifies the flags. This is bad for HIOP/jcc. */ + if (i == 0 && !(LJ_32 && (IR(as->curins)->o == IR_HIOP || + (as->curins+1 < as->T->nins && + IR(as->curins+1)->o == IR_HIOP))) && + !((*as->mcp == 0x0f && (as->mcp[1] & 0xf0) == XI_JCCn) || + (*as->mcp & 0xf0) == XI_JCCs)) { + emit_rr(as, XO_ARITH(XOg_XOR), r, r); + } else { + MCode *p = as->mcp; + *(int32_t *)(p-4) = i; + p[-5] = (MCode)(XI_MOVri+(r&7)); + p -= 5; + REXRB(p, 0, r); + as->mcp = p; + } +} + +#if LJ_GC64 +#define dispofs(as, k) \ + ((intptr_t)((uintptr_t)(k) - (uintptr_t)J2GG(as->J)->dispatch)) +#define mcpofs(as, k) \ + ((intptr_t)((uintptr_t)(k) - (uintptr_t)as->mcp)) +#define mctopofs(as, k) \ + ((intptr_t)((uintptr_t)(k) - (uintptr_t)as->mctop)) +/* mov r, addr */ +#define emit_loada(as, r, addr) \ + emit_loadu64(as, (r), (uintptr_t)(addr)) +#else +/* mov r, addr */ +#define emit_loada(as, r, addr) \ + emit_loadi(as, (r), ptr2addr((addr))) +#endif + +#if LJ_64 +/* mov r, imm64 or shorter 32 bit extended load. */ +static void emit_loadu64(ASMState *as, Reg r, uint64_t u64) +{ + if (checku32(u64)) { /* 32 bit load clears upper 32 bits. */ + emit_loadi(as, r, (int32_t)u64); + } else if (checki32((int64_t)u64)) { /* Sign-extended 32 bit load. */ + MCode *p = as->mcp; + *(int32_t *)(p-4) = (int32_t)u64; + as->mcp = emit_opm(XO_MOVmi, XM_REG, REX_64, r, p, -4); +#if LJ_GC64 + } else if (checki32(dispofs(as, u64))) { + emit_rmro(as, XO_LEA, r|REX_64, RID_DISPATCH, (int32_t)dispofs(as, u64)); + } else if (checki32(mcpofs(as, u64)) && checki32(mctopofs(as, u64))) { + /* Since as->realign assumes the code size doesn't change, check + ** RIP-relative addressing reachability for both as->mcp and as->mctop. + */ + emit_rmro(as, XO_LEA, r|REX_64, RID_RIP, (int32_t)mcpofs(as, u64)); +#endif + } else { /* Full-size 64 bit load. */ + MCode *p = as->mcp; + *(uint64_t *)(p-8) = u64; + p[-9] = (MCode)(XI_MOVri+(r&7)); + p[-10] = 0x48 + ((r>>3)&1); + p -= 10; + as->mcp = p; + } +} +#endif + +/* op r, [addr] */ +static void emit_rma(ASMState *as, x86Op xo, Reg rr, const void *addr) +{ +#if LJ_GC64 + if (checki32(dispofs(as, addr))) { + emit_rmro(as, xo, rr, RID_DISPATCH, (int32_t)dispofs(as, addr)); + } else if (checki32(mcpofs(as, addr)) && checki32(mctopofs(as, addr))) { + emit_rmro(as, xo, rr, RID_RIP, (int32_t)mcpofs(as, addr)); + } else if (!checki32((intptr_t)addr)) { + Reg ra = (rr & 15); + if (xo != XO_MOV) { + /* We can't allocate a register here. Use and restore DISPATCH. Ugly. */ + uint64_t dispaddr = (uintptr_t)J2GG(as->J)->dispatch; + uint8_t i8 = xo == XO_GROUP3b ? *as->mcp++ : 0; + ra = RID_DISPATCH; + if (checku32(dispaddr)) { + emit_loadi(as, ra, (int32_t)dispaddr); + } else { /* Full-size 64 bit load. */ + MCode *p = as->mcp; + *(uint64_t *)(p-8) = dispaddr; + p[-9] = (MCode)(XI_MOVri+(ra&7)); + p[-10] = 0x48 + ((ra>>3)&1); + p -= 10; + as->mcp = p; + } + if (xo == XO_GROUP3b) emit_i8(as, i8); + } + emit_rmro(as, xo, rr, ra, 0); + emit_loadu64(as, ra, (uintptr_t)addr); + } else +#endif + { + MCode *p = as->mcp; + *(int32_t *)(p-4) = ptr2addr(addr); +#if LJ_64 + p[-5] = MODRM(XM_SCALE1, RID_ESP, RID_EBP); + as->mcp = emit_opm(xo, XM_OFS0, rr, RID_ESP, p, -5); +#else + as->mcp = emit_opm(xo, XM_OFS0, rr, RID_EBP, p, -4); +#endif + } +} + +/* Load 64 bit IR constant into register. */ +static void emit_loadk64(ASMState *as, Reg r, IRIns *ir) +{ + Reg r64; + x86Op xo; + const uint64_t *k = &ir_k64(ir)->u64; + if (rset_test(RSET_FPR, r)) { + r64 = r; + xo = XO_MOVSD; + } else { + r64 = r | REX_64; + xo = XO_MOV; + } + if (*k == 0) { + emit_rr(as, rset_test(RSET_FPR, r) ? XO_XORPS : XO_ARITH(XOg_XOR), r, r); +#if LJ_GC64 + } else if (checki32((intptr_t)k) || checki32(dispofs(as, k)) || + (checki32(mcpofs(as, k)) && checki32(mctopofs(as, k)))) { + emit_rma(as, xo, r64, k); + } else { + if (ir->i) { + lj_assertA(*k == *(uint64_t*)(as->mctop - ir->i), + "bad interned 64 bit constant"); + } else if (as->curins <= as->stopins && rset_test(RSET_GPR, r)) { + emit_loadu64(as, r, *k); + return; + } else { + /* If all else fails, add the FP constant at the MCode area bottom. */ + while ((uintptr_t)as->mcbot & 7) *as->mcbot++ = XI_INT3; + *(uint64_t *)as->mcbot = *k; + ir->i = (int32_t)(as->mctop - as->mcbot); + as->mcbot += 8; + as->mclim = as->mcbot + MCLIM_REDZONE; + lj_mcode_commitbot(as->J, as->mcbot); + } + emit_rmro(as, xo, r64, RID_RIP, (int32_t)mcpofs(as, as->mctop - ir->i)); +#else + } else { + emit_rma(as, xo, r64, k); +#endif + } +} + +/* -- Emit control-flow instructions -------------------------------------- */ + +/* Label for short jumps. */ +typedef MCode *MCLabel; + +#if LJ_32 && LJ_HASFFI +/* jmp short target */ +static void emit_sjmp(ASMState *as, MCLabel target) +{ + MCode *p = as->mcp; + ptrdiff_t delta = target - p; + lj_assertA(delta == (int8_t)delta, "short jump target out of range"); + p[-1] = (MCode)(int8_t)delta; + p[-2] = XI_JMPs; + as->mcp = p - 2; +} +#endif + +/* jcc short target */ +static void emit_sjcc(ASMState *as, int cc, MCLabel target) +{ + MCode *p = as->mcp; + ptrdiff_t delta = target - p; + lj_assertA(delta == (int8_t)delta, "short jump target out of range"); + p[-1] = (MCode)(int8_t)delta; + p[-2] = (MCode)(XI_JCCs+(cc&15)); + as->mcp = p - 2; +} + +/* jcc short (pending target) */ +static MCLabel emit_sjcc_label(ASMState *as, int cc) +{ + MCode *p = as->mcp; + p[-1] = 0; + p[-2] = (MCode)(XI_JCCs+(cc&15)); + as->mcp = p - 2; + return p; +} + +/* Fixup jcc short target. */ +static void emit_sfixup(ASMState *as, MCLabel source) +{ + source[-1] = (MCode)(as->mcp-source); +} + +/* Return label pointing to current PC. */ +#define emit_label(as) ((as)->mcp) + +/* Compute relative 32 bit offset for jump and call instructions. */ +static LJ_AINLINE int32_t jmprel(jit_State *J, MCode *p, MCode *target) +{ + ptrdiff_t delta = target - p; + UNUSED(J); + lj_assertJ(delta == (int32_t)delta, "jump target out of range"); + return (int32_t)delta; +} + +/* jcc target */ +static void emit_jcc(ASMState *as, int cc, MCode *target) +{ + MCode *p = as->mcp; + *(int32_t *)(p-4) = jmprel(as->J, p, target); + p[-5] = (MCode)(XI_JCCn+(cc&15)); + p[-6] = 0x0f; + as->mcp = p - 6; +} + +/* jmp target */ +static void emit_jmp(ASMState *as, MCode *target) +{ + MCode *p = as->mcp; + *(int32_t *)(p-4) = jmprel(as->J, p, target); + p[-5] = XI_JMP; + as->mcp = p - 5; +} + +/* call target */ +static void emit_call_(ASMState *as, MCode *target) +{ + MCode *p = as->mcp; +#if LJ_64 + if (target-p != (int32_t)(target-p)) { + /* Assumes RID_RET is never an argument to calls and always clobbered. */ + emit_rr(as, XO_GROUP5, XOg_CALL, RID_RET); + emit_loadu64(as, RID_RET, (uint64_t)target); + return; + } +#endif + *(int32_t *)(p-4) = jmprel(as->J, p, target); + p[-5] = XI_CALL; + as->mcp = p - 5; +} + +#define emit_call(as, f) emit_call_(as, (MCode *)(void *)(f)) + +/* -- Emit generic operations --------------------------------------------- */ + +/* Use 64 bit operations to handle 64 bit IR types. */ +#if LJ_64 +#define REX_64IR(ir, r) ((r) + (irt_is64((ir)->t) ? REX_64 : 0)) +#define VEX_64IR(ir, r) ((r) + (irt_is64((ir)->t) ? VEX_64 : 0)) +#else +#define REX_64IR(ir, r) (r) +#define VEX_64IR(ir, r) (r) +#endif + +/* Generic move between two regs. */ +static void emit_movrr(ASMState *as, IRIns *ir, Reg dst, Reg src) +{ + UNUSED(ir); + if (dst < RID_MAX_GPR) + emit_rr(as, XO_MOV, REX_64IR(ir, dst), src); + else + emit_rr(as, XO_MOVAPS, dst, src); +} + +/* Generic load of register with base and (small) offset address. */ +static void emit_loadofs(ASMState *as, IRIns *ir, Reg r, Reg base, int32_t ofs) +{ + if (r < RID_MAX_GPR) + emit_rmro(as, XO_MOV, REX_64IR(ir, r), base, ofs); + else + emit_rmro(as, irt_isnum(ir->t) ? XO_MOVSD : XO_MOVSS, r, base, ofs); +} + +/* Generic store of register with base and (small) offset address. */ +static void emit_storeofs(ASMState *as, IRIns *ir, Reg r, Reg base, int32_t ofs) +{ + if (r < RID_MAX_GPR) + emit_rmro(as, XO_MOVto, REX_64IR(ir, r), base, ofs); + else + emit_rmro(as, irt_isnum(ir->t) ? XO_MOVSDto : XO_MOVSSto, r, base, ofs); +} + +/* Add offset to pointer. */ +static void emit_addptr(ASMState *as, Reg r, int32_t ofs) +{ + if (ofs) { + emit_gri(as, XG_ARITHi(XOg_ADD), r|REX_GC64, ofs); + } +} + +#define emit_spsub(as, ofs) emit_addptr(as, RID_ESP|REX_64, -(ofs)) + +/* Prefer rematerialization of BASE/L from global_State over spills. */ +#define emit_canremat(ref) ((ref) <= REF_BASE) + diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_err.c b/fluent-bit/lib/luajit-3065c9/src/lj_err.c new file mode 100644 index 00000000..563c7706 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_err.c @@ -0,0 +1,1097 @@ +/* +** Error handling. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#define lj_err_c +#define LUA_CORE + +#include "lj_obj.h" +#include "lj_err.h" +#include "lj_debug.h" +#include "lj_str.h" +#include "lj_func.h" +#include "lj_state.h" +#include "lj_frame.h" +#include "lj_ff.h" +#include "lj_trace.h" +#include "lj_vm.h" +#include "lj_strfmt.h" + +/* +** LuaJIT can either use internal or external frame unwinding: +** +** - Internal frame unwinding (INT) is free-standing and doesn't require +** any OS or library support. +** +** - External frame unwinding (EXT) uses the system-provided unwind handler. +** +** Pros and Cons: +** +** - EXT requires unwind tables for *all* functions on the C stack between +** the pcall/catch and the error/throw. C modules used by Lua code can +** throw errors, so these need to have unwind tables, too. Transitively +** this applies to all system libraries used by C modules -- at least +** when they have callbacks which may throw an error. +** +** - INT is faster when actually throwing errors, but this happens rarely. +** Setting up error handlers is zero-cost in any case. +** +** - INT needs to save *all* callee-saved registers when entering the +** interpreter. EXT only needs to save those actually used inside the +** interpreter. JIT-compiled code may need to save some more. +** +** - EXT provides full interoperability with C++ exceptions. You can throw +** Lua errors or C++ exceptions through a mix of Lua frames and C++ frames. +** C++ destructors are called as needed. C++ exceptions caught by pcall +** are converted to the string "C++ exception". Lua errors can be caught +** with catch (...) in C++. +** +** - INT has only limited support for automatically catching C++ exceptions +** on POSIX systems using DWARF2 stack unwinding. Other systems may use +** the wrapper function feature. Lua errors thrown through C++ frames +** cannot be caught by C++ code and C++ destructors are not run. +** +** - EXT can handle errors from internal helper functions that are called +** from JIT-compiled code (except for Windows/x86 and 32 bit ARM). +** INT has no choice but to call the panic handler, if this happens. +** Note: this is mainly relevant for out-of-memory errors. +** +** EXT is the default on all systems where the toolchain produces unwind +** tables by default (*). This is hard-coded and/or detected in src/Makefile. +** You can thwart the detection with: TARGET_XCFLAGS=-DLUAJIT_UNWIND_INTERNAL +** +** INT is the default on all other systems. +** +** EXT can be manually enabled for toolchains that are able to produce +** conforming unwind tables: +** "TARGET_XCFLAGS=-funwind-tables -DLUAJIT_UNWIND_EXTERNAL" +** As explained above, *all* C code used directly or indirectly by LuaJIT +** must be compiled with -funwind-tables (or -fexceptions). C++ code must +** *not* be compiled with -fno-exceptions. +** +** If you're unsure whether error handling inside the VM works correctly, +** try running this and check whether it prints "OK": +** +** luajit -e "print(select(2, load('OK')):match('OK'))" +** +** (*) Originally, toolchains only generated unwind tables for C++ code. For +** interoperability reasons, this can be manually enabled for plain C code, +** too (with -funwind-tables). With the introduction of the x64 architecture, +** the corresponding POSIX and Windows ABIs mandated unwind tables for all +** code. Over the following years most desktop and server platforms have +** enabled unwind tables by default on all architectures. OTOH mobile and +** embedded platforms do not consistently mandate unwind tables. +*/ + +/* -- Error messages ------------------------------------------------------ */ + +/* Error message strings. */ +LJ_DATADEF const char *lj_err_allmsg = +#define ERRDEF(name, msg) msg "\0" +#include "lj_errmsg.h" +; + +/* -- Internal frame unwinding -------------------------------------------- */ + +/* Unwind Lua stack and move error message to new top. */ +LJ_NOINLINE static void unwindstack(lua_State *L, TValue *top) +{ + lj_func_closeuv(L, top); + if (top < L->top-1) { + copyTV(L, top, L->top-1); + L->top = top+1; + } + lj_state_relimitstack(L); +} + +/* Unwind until stop frame. Optionally cleanup frames. */ +static void *err_unwind(lua_State *L, void *stopcf, int errcode) +{ + TValue *frame = L->base-1; + void *cf = L->cframe; + while (cf) { + int32_t nres = cframe_nres(cframe_raw(cf)); + if (nres < 0) { /* C frame without Lua frame? */ + TValue *top = restorestack(L, -nres); + if (frame < top) { /* Frame reached? */ + if (errcode) { + L->base = frame+1; + L->cframe = cframe_prev(cf); + unwindstack(L, top); + } + return cf; + } + } + if (frame <= tvref(L->stack)+LJ_FR2) + break; + switch (frame_typep(frame)) { + case FRAME_LUA: /* Lua frame. */ + case FRAME_LUAP: + frame = frame_prevl(frame); + break; + case FRAME_C: /* C frame. */ + unwind_c: +#if LJ_UNWIND_EXT + if (errcode) { + L->base = frame_prevd(frame) + 1; + L->cframe = cframe_prev(cf); + unwindstack(L, frame - LJ_FR2); + } else if (cf != stopcf) { + cf = cframe_prev(cf); + frame = frame_prevd(frame); + break; + } + return NULL; /* Continue unwinding. */ +#else + UNUSED(stopcf); + cf = cframe_prev(cf); + frame = frame_prevd(frame); + break; +#endif + case FRAME_CP: /* Protected C frame. */ + if (cframe_canyield(cf)) { /* Resume? */ + if (errcode) { + hook_leave(G(L)); /* Assumes nobody uses coroutines inside hooks. */ + L->cframe = NULL; + L->status = (uint8_t)errcode; + } + return cf; + } + if (errcode) { + L->base = frame_prevd(frame) + 1; + L->cframe = cframe_prev(cf); + unwindstack(L, frame - LJ_FR2); + } + return cf; + case FRAME_CONT: /* Continuation frame. */ + if (frame_iscont_fficb(frame)) + goto unwind_c; + /* fallthrough */ + case FRAME_VARG: /* Vararg frame. */ + frame = frame_prevd(frame); + break; + case FRAME_PCALL: /* FF pcall() frame. */ + case FRAME_PCALLH: /* FF pcall() frame inside hook. */ + if (errcode) { + if (errcode == LUA_YIELD) { + frame = frame_prevd(frame); + break; + } + if (frame_typep(frame) == FRAME_PCALL) + hook_leave(G(L)); + L->base = frame_prevd(frame) + 1; + L->cframe = cf; + unwindstack(L, L->base); + } + return (void *)((intptr_t)cf | CFRAME_UNWIND_FF); + } + } + /* No C frame. */ + if (errcode) { + L->base = tvref(L->stack)+1+LJ_FR2; + L->cframe = NULL; + unwindstack(L, L->base); + if (G(L)->panic) + G(L)->panic(L); + exit(EXIT_FAILURE); + } + return L; /* Anything non-NULL will do. */ +} + +/* -- External frame unwinding -------------------------------------------- */ + +#if LJ_ABI_WIN + +/* +** Someone in Redmond owes me several days of my life. A lot of this is +** undocumented or just plain wrong on MSDN. Some of it can be gathered +** from 3rd party docs or must be found by trial-and-error. They really +** don't want you to write your own language-specific exception handler +** or to interact gracefully with MSVC. :-( +** +** Apparently MSVC doesn't call C++ destructors for foreign exceptions +** unless you compile your C++ code with /EHa. Unfortunately this means +** catch (...) also catches things like access violations. The use of +** _set_se_translator doesn't really help, because it requires /EHa, too. +*/ + +#define WIN32_LEAN_AND_MEAN +#include + +#if LJ_TARGET_X86 +typedef void *UndocumentedDispatcherContext; /* Unused on x86. */ +#else +/* Taken from: http://www.nynaeve.net/?p=99 */ +typedef struct UndocumentedDispatcherContext { + ULONG64 ControlPc; + ULONG64 ImageBase; + PRUNTIME_FUNCTION FunctionEntry; + ULONG64 EstablisherFrame; + ULONG64 TargetIp; + PCONTEXT ContextRecord; + void (*LanguageHandler)(void); + PVOID HandlerData; + PUNWIND_HISTORY_TABLE HistoryTable; + ULONG ScopeIndex; + ULONG Fill0; +} UndocumentedDispatcherContext; +#endif + +/* Another wild guess. */ +extern void __DestructExceptionObject(EXCEPTION_RECORD *rec, int nothrow); + +#if LJ_TARGET_X64 && defined(MINGW_SDK_INIT) +/* Workaround for broken MinGW64 declaration. */ +VOID RtlUnwindEx_FIXED(PVOID,PVOID,PVOID,PVOID,PVOID,PVOID) asm("RtlUnwindEx"); +#define RtlUnwindEx RtlUnwindEx_FIXED +#endif + +#define LJ_MSVC_EXCODE ((DWORD)0xe06d7363) +#define LJ_GCC_EXCODE ((DWORD)0x20474343) + +#define LJ_EXCODE ((DWORD)0xe24c4a00) +#define LJ_EXCODE_MAKE(c) (LJ_EXCODE | (DWORD)(c)) +#define LJ_EXCODE_CHECK(cl) (((cl) ^ LJ_EXCODE) <= 0xff) +#define LJ_EXCODE_ERRCODE(cl) ((int)((cl) & 0xff)) + +/* Windows exception handler for interpreter frame. */ +LJ_FUNCA int lj_err_unwind_win(EXCEPTION_RECORD *rec, + void *f, CONTEXT *ctx, UndocumentedDispatcherContext *dispatch) +{ +#if LJ_TARGET_X86 + void *cf = (char *)f - CFRAME_OFS_SEH; +#else + void *cf = f; +#endif + lua_State *L = cframe_L(cf); + int errcode = LJ_EXCODE_CHECK(rec->ExceptionCode) ? + LJ_EXCODE_ERRCODE(rec->ExceptionCode) : LUA_ERRRUN; + if ((rec->ExceptionFlags & 6)) { /* EH_UNWINDING|EH_EXIT_UNWIND */ + /* Unwind internal frames. */ + err_unwind(L, cf, errcode); + } else { + void *cf2 = err_unwind(L, cf, 0); + if (cf2) { /* We catch it, so start unwinding the upper frames. */ + if (rec->ExceptionCode == LJ_MSVC_EXCODE || + rec->ExceptionCode == LJ_GCC_EXCODE) { +#if !LJ_TARGET_CYGWIN + __DestructExceptionObject(rec, 1); +#endif + setstrV(L, L->top++, lj_err_str(L, LJ_ERR_ERRCPP)); + } else if (!LJ_EXCODE_CHECK(rec->ExceptionCode)) { + /* Don't catch access violations etc. */ + return 1; /* ExceptionContinueSearch */ + } +#if LJ_TARGET_X86 + UNUSED(ctx); + UNUSED(dispatch); + /* Call all handlers for all lower C frames (including ourselves) again + ** with EH_UNWINDING set. Then call the specified function, passing cf + ** and errcode. + */ + lj_vm_rtlunwind(cf, (void *)rec, + (cframe_unwind_ff(cf2) && errcode != LUA_YIELD) ? + (void *)lj_vm_unwind_ff : (void *)lj_vm_unwind_c, errcode); + /* lj_vm_rtlunwind does not return. */ +#else + /* Unwind the stack and call all handlers for all lower C frames + ** (including ourselves) again with EH_UNWINDING set. Then set + ** stack pointer = cf, result = errcode and jump to the specified target. + */ + RtlUnwindEx(cf, (void *)((cframe_unwind_ff(cf2) && errcode != LUA_YIELD) ? + lj_vm_unwind_ff_eh : + lj_vm_unwind_c_eh), + rec, (void *)(uintptr_t)errcode, ctx, dispatch->HistoryTable); + /* RtlUnwindEx should never return. */ +#endif + } + } + return 1; /* ExceptionContinueSearch */ +} + +#if LJ_UNWIND_JIT + +#if LJ_TARGET_X64 +#define CONTEXT_REG_PC Rip +#elif LJ_TARGET_ARM64 +#define CONTEXT_REG_PC Pc +#else +#error "NYI: Windows arch-specific unwinder for JIT-compiled code" +#endif + +/* Windows unwinder for JIT-compiled code. */ +static void err_unwind_win_jit(global_State *g, int errcode) +{ + CONTEXT ctx; + UNWIND_HISTORY_TABLE hist; + + memset(&hist, 0, sizeof(hist)); + RtlCaptureContext(&ctx); + while (1) { + uintptr_t frame, base, addr = ctx.CONTEXT_REG_PC; + void *hdata; + PRUNTIME_FUNCTION func = RtlLookupFunctionEntry(addr, &base, &hist); + if (!func) { /* Found frame without .pdata: must be JIT-compiled code. */ + ExitNo exitno; + uintptr_t stub = lj_trace_unwind(G2J(g), addr - sizeof(MCode), &exitno); + if (stub) { /* Jump to side exit to unwind the trace. */ + ctx.CONTEXT_REG_PC = stub; + G2J(g)->exitcode = errcode; + RtlRestoreContext(&ctx, NULL); /* Does not return. */ + } + break; + } + RtlVirtualUnwind(UNW_FLAG_NHANDLER, base, addr, func, + &ctx, &hdata, &frame, NULL); + if (!addr) break; + } + /* Unwinding failed, if we end up here. */ +} +#endif + +/* Raise Windows exception. */ +static void err_raise_ext(global_State *g, int errcode) +{ +#if LJ_UNWIND_JIT + if (tvref(g->jit_base)) { + err_unwind_win_jit(g, errcode); + return; /* Unwinding failed. */ + } +#elif LJ_HASJIT + /* Cannot catch on-trace errors for Windows/x86 SEH. Unwind to interpreter. */ + setmref(g->jit_base, NULL); +#endif + UNUSED(g); + RaiseException(LJ_EXCODE_MAKE(errcode), 1 /* EH_NONCONTINUABLE */, 0, NULL); +} + +#elif !LJ_NO_UNWIND && (defined(__GNUC__) || defined(__clang__)) + +/* +** We have to use our own definitions instead of the mandatory (!) unwind.h, +** since various OS, distros and compilers mess up the header installation. +*/ + +typedef struct _Unwind_Context _Unwind_Context; + +#define _URC_OK 0 +#define _URC_FATAL_PHASE2_ERROR 2 +#define _URC_FATAL_PHASE1_ERROR 3 +#define _URC_HANDLER_FOUND 6 +#define _URC_INSTALL_CONTEXT 7 +#define _URC_CONTINUE_UNWIND 8 +#define _URC_FAILURE 9 + +#define LJ_UEXCLASS 0x4c55414a49543200ULL /* LUAJIT2\0 */ +#define LJ_UEXCLASS_MAKE(c) (LJ_UEXCLASS | (uint64_t)(c)) +#define LJ_UEXCLASS_CHECK(cl) (((cl) ^ LJ_UEXCLASS) <= 0xff) +#define LJ_UEXCLASS_ERRCODE(cl) ((int)((cl) & 0xff)) + +#if !LJ_TARGET_ARM + +typedef struct _Unwind_Exception +{ + uint64_t exclass; + void (*excleanup)(int, struct _Unwind_Exception *); + uintptr_t p1, p2; +} __attribute__((__aligned__)) _Unwind_Exception; +#define UNWIND_EXCEPTION_TYPE _Unwind_Exception + +extern uintptr_t _Unwind_GetCFA(_Unwind_Context *); +extern void _Unwind_SetGR(_Unwind_Context *, int, uintptr_t); +extern uintptr_t _Unwind_GetIP(_Unwind_Context *); +extern void _Unwind_SetIP(_Unwind_Context *, uintptr_t); +extern void _Unwind_DeleteException(_Unwind_Exception *); +extern int _Unwind_RaiseException(_Unwind_Exception *); + +#define _UA_SEARCH_PHASE 1 +#define _UA_CLEANUP_PHASE 2 +#define _UA_HANDLER_FRAME 4 +#define _UA_FORCE_UNWIND 8 + +/* DWARF2 personality handler referenced from interpreter .eh_frame. */ +LJ_FUNCA int lj_err_unwind_dwarf(int version, int actions, + uint64_t uexclass, _Unwind_Exception *uex, _Unwind_Context *ctx) +{ + void *cf; + lua_State *L; + if (version != 1) + return _URC_FATAL_PHASE1_ERROR; + cf = (void *)_Unwind_GetCFA(ctx); + L = cframe_L(cf); + if ((actions & _UA_SEARCH_PHASE)) { +#if LJ_UNWIND_EXT + if (err_unwind(L, cf, 0) == NULL) + return _URC_CONTINUE_UNWIND; +#endif + if (!LJ_UEXCLASS_CHECK(uexclass)) { + setstrV(L, L->top++, lj_err_str(L, LJ_ERR_ERRCPP)); + } + return _URC_HANDLER_FOUND; + } + if ((actions & _UA_CLEANUP_PHASE)) { + int errcode; + if (LJ_UEXCLASS_CHECK(uexclass)) { + errcode = LJ_UEXCLASS_ERRCODE(uexclass); + } else { + if ((actions & _UA_HANDLER_FRAME)) + _Unwind_DeleteException(uex); + errcode = LUA_ERRRUN; + } +#if LJ_UNWIND_EXT + cf = err_unwind(L, cf, errcode); + if ((actions & _UA_FORCE_UNWIND)) { + return _URC_CONTINUE_UNWIND; + } else if (cf) { + _Unwind_SetGR(ctx, LJ_TARGET_EHRETREG, errcode); + _Unwind_SetIP(ctx, (uintptr_t)(cframe_unwind_ff(cf) ? + lj_vm_unwind_ff_eh : + lj_vm_unwind_c_eh)); + return _URC_INSTALL_CONTEXT; + } +#if LJ_TARGET_X86ORX64 + else if ((actions & _UA_HANDLER_FRAME)) { + /* Workaround for ancient libgcc bug. Still present in RHEL 5.5. :-/ + ** Real fix: http://gcc.gnu.org/viewcvs/trunk/gcc/unwind-dw2.c?r1=121165&r2=124837&pathrev=153877&diff_format=h + */ + _Unwind_SetGR(ctx, LJ_TARGET_EHRETREG, errcode); + _Unwind_SetIP(ctx, (uintptr_t)lj_vm_unwind_rethrow); + return _URC_INSTALL_CONTEXT; + } +#endif +#else + /* This is not the proper way to escape from the unwinder. We get away with + ** it on non-x64 because the interpreter restores all callee-saved regs. + */ + lj_err_throw(L, errcode); +#if LJ_TARGET_X64 +#error "Broken build system -- only use the provided Makefiles!" +#endif +#endif + } + return _URC_CONTINUE_UNWIND; +} + +#if LJ_UNWIND_EXT && defined(LUA_USE_ASSERT) +struct dwarf_eh_bases { void *tbase, *dbase, *func; }; +extern const void *_Unwind_Find_FDE(void *pc, struct dwarf_eh_bases *bases); + +/* Verify that external error handling actually has a chance to work. */ +void lj_err_verify(void) +{ +#if !LJ_TARGET_OSX + /* Check disabled on MacOS due to brilliant software engineering at Apple. */ + struct dwarf_eh_bases ehb; + lj_assertX(_Unwind_Find_FDE((void *)lj_err_throw, &ehb), "broken build: external frame unwinding enabled, but missing -funwind-tables"); +#endif + /* Check disabled, because of broken Fedora/ARM64. See #722. + lj_assertX(_Unwind_Find_FDE((void *)_Unwind_RaiseException, &ehb), "broken build: external frame unwinding enabled, but system libraries have no unwind tables"); + */ +} +#endif + +#if LJ_UNWIND_JIT +/* DWARF2 personality handler for JIT-compiled code. */ +static int err_unwind_jit(int version, int actions, + uint64_t uexclass, _Unwind_Exception *uex, _Unwind_Context *ctx) +{ + /* NYI: FFI C++ exception interoperability. */ + if (version != 1 || !LJ_UEXCLASS_CHECK(uexclass)) + return _URC_FATAL_PHASE1_ERROR; + if ((actions & _UA_SEARCH_PHASE)) { + return _URC_HANDLER_FOUND; + } + if ((actions & _UA_CLEANUP_PHASE)) { + global_State *g = *(global_State **)(uex+1); + ExitNo exitno; + uintptr_t addr = _Unwind_GetIP(ctx); /* Return address _after_ call. */ + uintptr_t stub = lj_trace_unwind(G2J(g), addr - sizeof(MCode), &exitno); + lj_assertG(tvref(g->jit_base), "unexpected throw across mcode frame"); + if (stub) { /* Jump to side exit to unwind the trace. */ + G2J(g)->exitcode = LJ_UEXCLASS_ERRCODE(uexclass); +#ifdef LJ_TARGET_MIPS + _Unwind_SetGR(ctx, 4, stub); + _Unwind_SetGR(ctx, 5, exitno); + _Unwind_SetIP(ctx, (uintptr_t)(void *)lj_vm_unwind_stub); +#else + _Unwind_SetIP(ctx, stub); +#endif + return _URC_INSTALL_CONTEXT; + } + return _URC_FATAL_PHASE2_ERROR; + } + return _URC_FATAL_PHASE1_ERROR; +} + +/* DWARF2 template frame info for JIT-compiled code. +** +** After copying the template to the start of the mcode segment, +** the frame handler function and the code size is patched. +** The frame handler always installs a new context to jump to the exit, +** so don't bother to add any unwind opcodes. +*/ +static const uint8_t err_frame_jit_template[] = { +#if LJ_BE + 0,0,0, +#endif + LJ_64 ? 0x1c : 0x14, /* CIE length. */ +#if LJ_LE + 0,0,0, +#endif + 0,0,0,0, 1, 'z','P','R',0, /* CIE mark, CIE version, augmentation. */ + 1, LJ_64 ? 0x78 : 0x7c, LJ_TARGET_EHRAREG, /* Code/data align, RA. */ +#if LJ_64 + 10, 0, 0,0,0,0,0,0,0,0, 0x1b, /* Aug. data ABS handler, PCREL|SDATA4 code. */ + 0,0,0,0,0, /* Alignment. */ +#else + 6, 0, 0,0,0,0, 0x1b, /* Aug. data ABS handler, PCREL|SDATA4 code. */ + 0, /* Alignment. */ +#endif +#if LJ_BE + 0,0,0, +#endif + LJ_64 ? 0x14 : 0x10, /* FDE length. */ + 0,0,0, + LJ_64 ? 0x24 : 0x1c, /* CIE offset. */ + 0,0,0, + LJ_64 ? 0x14 : 0x10, /* Code offset. After Final FDE. */ +#if LJ_LE + 0,0,0, +#endif + 0,0,0,0, 0, 0,0,0, /* Code size, augmentation length, alignment. */ +#if LJ_64 + 0,0,0,0, /* Alignment. */ +#endif + 0,0,0,0 /* Final FDE. */ +}; + +#define ERR_FRAME_JIT_OFS_HANDLER 0x12 +#define ERR_FRAME_JIT_OFS_FDE (LJ_64 ? 0x20 : 0x18) +#define ERR_FRAME_JIT_OFS_CODE_SIZE (LJ_64 ? 0x2c : 0x24) +#if LJ_TARGET_OSX +#define ERR_FRAME_JIT_OFS_REGISTER ERR_FRAME_JIT_OFS_FDE +#else +#define ERR_FRAME_JIT_OFS_REGISTER 0 +#endif + +extern void __register_frame(const void *); +extern void __deregister_frame(const void *); + +uint8_t *lj_err_register_mcode(void *base, size_t sz, uint8_t *info) +{ + void **handler; + memcpy(info, err_frame_jit_template, sizeof(err_frame_jit_template)); + handler = (void *)err_unwind_jit; + memcpy(info + ERR_FRAME_JIT_OFS_HANDLER, &handler, sizeof(handler)); + *(uint32_t *)(info + ERR_FRAME_JIT_OFS_CODE_SIZE) = + (uint32_t)(sz - sizeof(err_frame_jit_template) - (info - (uint8_t *)base)); + __register_frame(info + ERR_FRAME_JIT_OFS_REGISTER); +#ifdef LUA_USE_ASSERT + { + struct dwarf_eh_bases ehb; + lj_assertX(_Unwind_Find_FDE(info + sizeof(err_frame_jit_template)+1, &ehb), + "bad JIT unwind table registration"); + } +#endif + return info + sizeof(err_frame_jit_template); +} + +void lj_err_deregister_mcode(void *base, size_t sz, uint8_t *info) +{ + UNUSED(base); UNUSED(sz); + __deregister_frame(info + ERR_FRAME_JIT_OFS_REGISTER); +} +#endif + +#else /* LJ_TARGET_ARM */ + +#define _US_VIRTUAL_UNWIND_FRAME 0 +#define _US_UNWIND_FRAME_STARTING 1 +#define _US_ACTION_MASK 3 +#define _US_FORCE_UNWIND 8 + +typedef struct _Unwind_Control_Block _Unwind_Control_Block; +#define UNWIND_EXCEPTION_TYPE _Unwind_Control_Block + +struct _Unwind_Control_Block { + uint64_t exclass; + uint32_t misc[20]; +}; + +extern int _Unwind_RaiseException(_Unwind_Control_Block *); +extern int __gnu_unwind_frame(_Unwind_Control_Block *, _Unwind_Context *); +extern int _Unwind_VRS_Set(_Unwind_Context *, int, uint32_t, int, void *); +extern int _Unwind_VRS_Get(_Unwind_Context *, int, uint32_t, int, void *); + +static inline uint32_t _Unwind_GetGR(_Unwind_Context *ctx, int r) +{ + uint32_t v; + _Unwind_VRS_Get(ctx, 0, r, 0, &v); + return v; +} + +static inline void _Unwind_SetGR(_Unwind_Context *ctx, int r, uint32_t v) +{ + _Unwind_VRS_Set(ctx, 0, r, 0, &v); +} + +extern void lj_vm_unwind_ext(void); + +/* ARM unwinder personality handler referenced from interpreter .ARM.extab. */ +LJ_FUNCA int lj_err_unwind_arm(int state, _Unwind_Control_Block *ucb, + _Unwind_Context *ctx) +{ + void *cf = (void *)_Unwind_GetGR(ctx, 13); + lua_State *L = cframe_L(cf); + int errcode; + + switch ((state & _US_ACTION_MASK)) { + case _US_VIRTUAL_UNWIND_FRAME: + if ((state & _US_FORCE_UNWIND)) break; + return _URC_HANDLER_FOUND; + case _US_UNWIND_FRAME_STARTING: + if (LJ_UEXCLASS_CHECK(ucb->exclass)) { + errcode = LJ_UEXCLASS_ERRCODE(ucb->exclass); + } else { + errcode = LUA_ERRRUN; + setstrV(L, L->top++, lj_err_str(L, LJ_ERR_ERRCPP)); + } + cf = err_unwind(L, cf, errcode); + if ((state & _US_FORCE_UNWIND) || cf == NULL) break; + _Unwind_SetGR(ctx, 15, (uint32_t)lj_vm_unwind_ext); + _Unwind_SetGR(ctx, 0, (uint32_t)ucb); + _Unwind_SetGR(ctx, 1, (uint32_t)errcode); + _Unwind_SetGR(ctx, 2, cframe_unwind_ff(cf) ? + (uint32_t)lj_vm_unwind_ff_eh : + (uint32_t)lj_vm_unwind_c_eh); + return _URC_INSTALL_CONTEXT; + default: + return _URC_FAILURE; + } + if (__gnu_unwind_frame(ucb, ctx) != _URC_OK) + return _URC_FAILURE; +#ifdef LUA_USE_ASSERT + /* We should never get here unless this is a forced unwind aka backtrace. */ + if (_Unwind_GetGR(ctx, 0) == 0xff33aa77) { + _Unwind_SetGR(ctx, 0, 0xff33aa88); + } +#endif + return _URC_CONTINUE_UNWIND; +} + +#if LJ_UNWIND_EXT && defined(LUA_USE_ASSERT) +typedef int (*_Unwind_Trace_Fn)(_Unwind_Context *, void *); +extern int _Unwind_Backtrace(_Unwind_Trace_Fn, void *); + +static int err_verify_bt(_Unwind_Context *ctx, int *got) +{ + if (_Unwind_GetGR(ctx, 0) == 0xff33aa88) { *got = 2; } + else if (*got == 0) { *got = 1; _Unwind_SetGR(ctx, 0, 0xff33aa77); } + return _URC_OK; +} + +/* Verify that external error handling actually has a chance to work. */ +void lj_err_verify(void) +{ + int got = 0; + _Unwind_Backtrace((_Unwind_Trace_Fn)err_verify_bt, &got); + lj_assertX(got == 2, "broken build: external frame unwinding enabled, but missing -funwind-tables"); +} +#endif + +/* +** Note: LJ_UNWIND_JIT is not implemented for 32 bit ARM. +** +** The quirky ARM unwind API doesn't have __register_frame(). +** A potential workaround might involve _Unwind_Backtrace. +** But most 32 bit ARM targets don't qualify for LJ_UNWIND_EXT, anyway, +** since they are built without unwind tables by default. +*/ + +#endif /* LJ_TARGET_ARM */ + + +#if LJ_UNWIND_EXT +static __thread struct { + UNWIND_EXCEPTION_TYPE ex; + global_State *g; +} static_uex; + +/* Raise external exception. */ +static void err_raise_ext(global_State *g, int errcode) +{ + memset(&static_uex, 0, sizeof(static_uex)); + static_uex.ex.exclass = LJ_UEXCLASS_MAKE(errcode); + static_uex.g = g; + _Unwind_RaiseException(&static_uex.ex); +} + +#endif + +#endif + +/* -- Error handling ------------------------------------------------------ */ + +/* Throw error. Find catch frame, unwind stack and continue. */ +LJ_NOINLINE void LJ_FASTCALL lj_err_throw(lua_State *L, int errcode) +{ + global_State *g = G(L); + lj_trace_abort(g); + L->status = LUA_OK; +#if LJ_UNWIND_EXT + err_raise_ext(g, errcode); + /* + ** A return from this function signals a corrupt C stack that cannot be + ** unwound. We have no choice but to call the panic function and exit. + ** + ** Usually this is caused by a C function without unwind information. + ** This may happen if you've manually enabled LUAJIT_UNWIND_EXTERNAL + ** and forgot to recompile *every* non-C++ file with -funwind-tables. + */ + if (G(L)->panic) + G(L)->panic(L); +#else +#if LJ_HASJIT + setmref(g->jit_base, NULL); +#endif + { + void *cf = err_unwind(L, NULL, errcode); + if (cframe_unwind_ff(cf)) + lj_vm_unwind_ff(cframe_raw(cf)); + else + lj_vm_unwind_c(cframe_raw(cf), errcode); + } +#endif + exit(EXIT_FAILURE); +} + +/* Return string object for error message. */ +LJ_NOINLINE GCstr *lj_err_str(lua_State *L, ErrMsg em) +{ + return lj_str_newz(L, err2msg(em)); +} + +/* Out-of-memory error. */ +LJ_NOINLINE void lj_err_mem(lua_State *L) +{ + if (L->status == LUA_ERRERR+1) /* Don't touch the stack during lua_open. */ + lj_vm_unwind_c(L->cframe, LUA_ERRMEM); + setstrV(L, L->top++, lj_err_str(L, LJ_ERR_ERRMEM)); + lj_err_throw(L, LUA_ERRMEM); +} + +/* Find error function for runtime errors. Requires an extra stack traversal. */ +static ptrdiff_t finderrfunc(lua_State *L) +{ + cTValue *frame = L->base-1, *bot = tvref(L->stack)+LJ_FR2; + void *cf = L->cframe; + while (frame > bot && cf) { + while (cframe_nres(cframe_raw(cf)) < 0) { /* cframe without frame? */ + if (frame >= restorestack(L, -cframe_nres(cf))) + break; + if (cframe_errfunc(cf) >= 0) /* Error handler not inherited (-1)? */ + return cframe_errfunc(cf); + cf = cframe_prev(cf); /* Else unwind cframe and continue searching. */ + if (cf == NULL) + return 0; + } + switch (frame_typep(frame)) { + case FRAME_LUA: + case FRAME_LUAP: + frame = frame_prevl(frame); + break; + case FRAME_C: + cf = cframe_prev(cf); + /* fallthrough */ + case FRAME_VARG: + frame = frame_prevd(frame); + break; + case FRAME_CONT: + if (frame_iscont_fficb(frame)) + cf = cframe_prev(cf); + frame = frame_prevd(frame); + break; + case FRAME_CP: + if (cframe_canyield(cf)) return 0; + if (cframe_errfunc(cf) >= 0) + return cframe_errfunc(cf); + cf = cframe_prev(cf); + frame = frame_prevd(frame); + break; + case FRAME_PCALL: + case FRAME_PCALLH: + if (frame_func(frame_prevd(frame))->c.ffid == FF_xpcall) + return savestack(L, frame_prevd(frame)+1); /* xpcall's errorfunc. */ + return 0; + default: + lj_assertL(0, "bad frame type"); + return 0; + } + } + return 0; +} + +/* Runtime error. */ +LJ_NOINLINE void LJ_FASTCALL lj_err_run(lua_State *L) +{ + ptrdiff_t ef = (LJ_HASJIT && tvref(G(L)->jit_base)) ? 0 : finderrfunc(L); + if (ef) { + TValue *errfunc = restorestack(L, ef); + TValue *top = L->top; + lj_trace_abort(G(L)); + if (!tvisfunc(errfunc) || L->status == LUA_ERRERR) { + setstrV(L, top-1, lj_err_str(L, LJ_ERR_ERRERR)); + lj_err_throw(L, LUA_ERRERR); + } + L->status = LUA_ERRERR; + copyTV(L, top+LJ_FR2, top-1); + copyTV(L, top-1, errfunc); + if (LJ_FR2) setnilV(top++); + L->top = top+1; + lj_vm_call(L, top, 1+1); /* Stack: |errfunc|msg| -> |msg| */ + } + lj_err_throw(L, LUA_ERRRUN); +} + +#if LJ_HASJIT +LJ_NOINLINE void LJ_FASTCALL lj_err_trace(lua_State *L, int errcode) +{ + if (errcode == LUA_ERRRUN) + lj_err_run(L); + else + lj_err_throw(L, errcode); +} +#endif + +/* Formatted runtime error message. */ +LJ_NORET LJ_NOINLINE static void err_msgv(lua_State *L, ErrMsg em, ...) +{ + const char *msg; + va_list argp; + va_start(argp, em); + if (curr_funcisL(L)) L->top = curr_topL(L); + msg = lj_strfmt_pushvf(L, err2msg(em), argp); + va_end(argp); + lj_debug_addloc(L, msg, L->base-1, NULL); + lj_err_run(L); +} + +/* Non-vararg variant for better calling conventions. */ +LJ_NOINLINE void lj_err_msg(lua_State *L, ErrMsg em) +{ + err_msgv(L, em); +} + +/* Lexer error. */ +LJ_NOINLINE void lj_err_lex(lua_State *L, GCstr *src, const char *tok, + BCLine line, ErrMsg em, va_list argp) +{ + char buff[LUA_IDSIZE]; + const char *msg; + lj_debug_shortname(buff, src, line); + msg = lj_strfmt_pushvf(L, err2msg(em), argp); + msg = lj_strfmt_pushf(L, "%s:%d: %s", buff, line, msg); + if (tok) + lj_strfmt_pushf(L, err2msg(LJ_ERR_XNEAR), msg, tok); + lj_err_throw(L, LUA_ERRSYNTAX); +} + +/* Typecheck error for operands. */ +LJ_NOINLINE void lj_err_optype(lua_State *L, cTValue *o, ErrMsg opm) +{ + const char *tname = lj_typename(o); + const char *opname = err2msg(opm); + if (curr_funcisL(L)) { + GCproto *pt = curr_proto(L); + const BCIns *pc = cframe_Lpc(L) - 1; + const char *oname = NULL; + const char *kind = lj_debug_slotname(pt, pc, (BCReg)(o-L->base), &oname); + if (kind) + err_msgv(L, LJ_ERR_BADOPRT, opname, kind, oname, tname); + } + err_msgv(L, LJ_ERR_BADOPRV, opname, tname); +} + +/* Typecheck error for ordered comparisons. */ +LJ_NOINLINE void lj_err_comp(lua_State *L, cTValue *o1, cTValue *o2) +{ + const char *t1 = lj_typename(o1); + const char *t2 = lj_typename(o2); + err_msgv(L, t1 == t2 ? LJ_ERR_BADCMPV : LJ_ERR_BADCMPT, t1, t2); + /* This assumes the two "boolean" entries are commoned by the C compiler. */ +} + +/* Typecheck error for __call. */ +LJ_NOINLINE void lj_err_optype_call(lua_State *L, TValue *o) +{ + /* Gross hack if lua_[p]call or pcall/xpcall fail for a non-callable object: + ** L->base still points to the caller. So add a dummy frame with L instead + ** of a function. See lua_getstack(). + */ + const BCIns *pc = cframe_Lpc(L); + if (((ptrdiff_t)pc & FRAME_TYPE) != FRAME_LUA) { + const char *tname = lj_typename(o); + setframe_gc(o, obj2gco(L), LJ_TTHREAD); + if (LJ_FR2) o++; + setframe_pc(o, pc); + L->top = L->base = o+1; + err_msgv(L, LJ_ERR_BADCALL, tname); + } + lj_err_optype(L, o, LJ_ERR_OPCALL); +} + +/* Error in context of caller. */ +LJ_NOINLINE void lj_err_callermsg(lua_State *L, const char *msg) +{ + TValue *frame = NULL, *pframe = NULL; + if (!(LJ_HASJIT && tvref(G(L)->jit_base))) { + frame = L->base-1; + if (frame_islua(frame)) { + pframe = frame_prevl(frame); + } else if (frame_iscont(frame)) { + if (frame_iscont_fficb(frame)) { + pframe = frame; + frame = NULL; + } else { + pframe = frame_prevd(frame); +#if LJ_HASFFI + /* Remove frame for FFI metamethods. */ + if (frame_func(frame)->c.ffid >= FF_ffi_meta___index && + frame_func(frame)->c.ffid <= FF_ffi_meta___tostring) { + L->base = pframe+1; + L->top = frame; + setcframe_pc(cframe_raw(L->cframe), frame_contpc(frame)); + } +#endif + } + } + } + lj_debug_addloc(L, msg, pframe, frame); + lj_err_run(L); +} + +/* Formatted error in context of caller. */ +LJ_NOINLINE void lj_err_callerv(lua_State *L, ErrMsg em, ...) +{ + const char *msg; + va_list argp; + va_start(argp, em); + msg = lj_strfmt_pushvf(L, err2msg(em), argp); + va_end(argp); + lj_err_callermsg(L, msg); +} + +/* Error in context of caller. */ +LJ_NOINLINE void lj_err_caller(lua_State *L, ErrMsg em) +{ + lj_err_callermsg(L, err2msg(em)); +} + +/* Argument error message. */ +LJ_NORET LJ_NOINLINE static void err_argmsg(lua_State *L, int narg, + const char *msg) +{ + const char *fname = "?"; + const char *ftype = lj_debug_funcname(L, L->base - 1, &fname); + if (narg < 0 && narg > LUA_REGISTRYINDEX) + narg = (int)(L->top - L->base) + narg + 1; + if (ftype && ftype[3] == 'h' && --narg == 0) /* Check for "method". */ + msg = lj_strfmt_pushf(L, err2msg(LJ_ERR_BADSELF), fname, msg); + else + msg = lj_strfmt_pushf(L, err2msg(LJ_ERR_BADARG), narg, fname, msg); + lj_err_callermsg(L, msg); +} + +/* Formatted argument error. */ +LJ_NOINLINE void lj_err_argv(lua_State *L, int narg, ErrMsg em, ...) +{ + const char *msg; + va_list argp; + va_start(argp, em); + msg = lj_strfmt_pushvf(L, err2msg(em), argp); + va_end(argp); + err_argmsg(L, narg, msg); +} + +/* Argument error. */ +LJ_NOINLINE void lj_err_arg(lua_State *L, int narg, ErrMsg em) +{ + err_argmsg(L, narg, err2msg(em)); +} + +/* Typecheck error for arguments. */ +LJ_NOINLINE void lj_err_argtype(lua_State *L, int narg, const char *xname) +{ + const char *tname, *msg; + if (narg <= LUA_REGISTRYINDEX) { + if (narg >= LUA_GLOBALSINDEX) { + tname = lj_obj_itypename[~LJ_TTAB]; + } else { + GCfunc *fn = curr_func(L); + int idx = LUA_GLOBALSINDEX - narg; + if (idx <= fn->c.nupvalues) + tname = lj_typename(&fn->c.upvalue[idx-1]); + else + tname = lj_obj_typename[0]; + } + } else { + TValue *o = narg < 0 ? L->top + narg : L->base + narg-1; + tname = o < L->top ? lj_typename(o) : lj_obj_typename[0]; + } + msg = lj_strfmt_pushf(L, err2msg(LJ_ERR_BADTYPE), xname, tname); + err_argmsg(L, narg, msg); +} + +/* Typecheck error for arguments. */ +LJ_NOINLINE void lj_err_argt(lua_State *L, int narg, int tt) +{ + lj_err_argtype(L, narg, lj_obj_typename[tt+1]); +} + +/* -- Public error handling API ------------------------------------------- */ + +LUA_API lua_CFunction lua_atpanic(lua_State *L, lua_CFunction panicf) +{ + lua_CFunction old = G(L)->panic; + G(L)->panic = panicf; + return old; +} + +/* Forwarders for the public API (C calling convention and no LJ_NORET). */ +LUA_API int lua_error(lua_State *L) +{ + lj_err_run(L); + return 0; /* unreachable */ +} + +LUALIB_API int luaL_argerror(lua_State *L, int narg, const char *msg) +{ + err_argmsg(L, narg, msg); + return 0; /* unreachable */ +} + +LUALIB_API int luaL_typerror(lua_State *L, int narg, const char *xname) +{ + lj_err_argtype(L, narg, xname); + return 0; /* unreachable */ +} + +LUALIB_API void luaL_where(lua_State *L, int level) +{ + int size; + cTValue *frame = lj_debug_frame(L, level, &size); + lj_debug_addloc(L, "", frame, size ? frame+size : NULL); +} + +LUALIB_API int luaL_error(lua_State *L, const char *fmt, ...) +{ + const char *msg; + va_list argp; + va_start(argp, fmt); + msg = lj_strfmt_pushvf(L, fmt, argp); + va_end(argp); + lj_err_callermsg(L, msg); + return 0; /* unreachable */ +} + diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_err.h b/fluent-bit/lib/luajit-3065c9/src/lj_err.h new file mode 100644 index 00000000..bd4de9ae --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_err.h @@ -0,0 +1,58 @@ +/* +** Error handling. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#ifndef _LJ_ERR_H +#define _LJ_ERR_H + +#include + +#include "lj_obj.h" + +typedef enum { +#define ERRDEF(name, msg) \ + LJ_ERR_##name, LJ_ERR_##name##_ = LJ_ERR_##name + sizeof(msg)-1, +#include "lj_errmsg.h" + LJ_ERR__MAX +} ErrMsg; + +LJ_DATA const char *lj_err_allmsg; +#define err2msg(em) (lj_err_allmsg+(int)(em)) + +LJ_FUNC GCstr *lj_err_str(lua_State *L, ErrMsg em); +LJ_FUNCA_NORET void LJ_FASTCALL lj_err_throw(lua_State *L, int errcode); +LJ_FUNC_NORET void lj_err_mem(lua_State *L); +LJ_FUNC_NORET void LJ_FASTCALL lj_err_run(lua_State *L); +#if LJ_HASJIT +LJ_FUNCA_NORET void LJ_FASTCALL lj_err_trace(lua_State *L, int errcode); +#endif +LJ_FUNC_NORET void lj_err_msg(lua_State *L, ErrMsg em); +LJ_FUNC_NORET void lj_err_lex(lua_State *L, GCstr *src, const char *tok, + BCLine line, ErrMsg em, va_list argp); +LJ_FUNC_NORET void lj_err_optype(lua_State *L, cTValue *o, ErrMsg opm); +LJ_FUNC_NORET void lj_err_comp(lua_State *L, cTValue *o1, cTValue *o2); +LJ_FUNC_NORET void lj_err_optype_call(lua_State *L, TValue *o); +LJ_FUNC_NORET void lj_err_callermsg(lua_State *L, const char *msg); +LJ_FUNC_NORET void lj_err_callerv(lua_State *L, ErrMsg em, ...); +LJ_FUNC_NORET void lj_err_caller(lua_State *L, ErrMsg em); +LJ_FUNC_NORET void lj_err_arg(lua_State *L, int narg, ErrMsg em); +LJ_FUNC_NORET void lj_err_argv(lua_State *L, int narg, ErrMsg em, ...); +LJ_FUNC_NORET void lj_err_argtype(lua_State *L, int narg, const char *xname); +LJ_FUNC_NORET void lj_err_argt(lua_State *L, int narg, int tt); + +#if LJ_UNWIND_JIT && !LJ_ABI_WIN +LJ_FUNC uint8_t *lj_err_register_mcode(void *base, size_t sz, uint8_t *info); +LJ_FUNC void lj_err_deregister_mcode(void *base, size_t sz, uint8_t *info); +#else +#define lj_err_register_mcode(base, sz, info) (info) +#define lj_err_deregister_mcode(base, sz, info) UNUSED(base) +#endif + +#if LJ_UNWIND_EXT && !LJ_ABI_WIN && defined(LUA_USE_ASSERT) +LJ_FUNC void lj_err_verify(void); +#else +#define lj_err_verify() ((void)0) +#endif + +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_errmsg.h b/fluent-bit/lib/luajit-3065c9/src/lj_errmsg.h new file mode 100644 index 00000000..2e5c776a --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_errmsg.h @@ -0,0 +1,200 @@ +/* +** VM error messages. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +/* This file may be included multiple times with different ERRDEF macros. */ + +/* Basic error handling. */ +ERRDEF(ERRMEM, "not enough memory") +ERRDEF(ERRERR, "error in error handling") +ERRDEF(ERRCPP, "C++ exception") + +/* Allocations. */ +ERRDEF(STROV, "string length overflow") +ERRDEF(UDATAOV, "userdata length overflow") +ERRDEF(STKOV, "stack overflow") +ERRDEF(STKOVM, "stack overflow (%s)") +ERRDEF(TABOV, "table overflow") + +/* Table indexing. */ +ERRDEF(NANIDX, "table index is NaN") +ERRDEF(NILIDX, "table index is nil") +ERRDEF(NEXTIDX, "invalid key to " LUA_QL("next")) + +/* Metamethod resolving. */ +ERRDEF(BADCALL, "attempt to call a %s value") +ERRDEF(BADOPRT, "attempt to %s %s " LUA_QS " (a %s value)") +ERRDEF(BADOPRV, "attempt to %s a %s value") +ERRDEF(BADCMPT, "attempt to compare %s with %s") +ERRDEF(BADCMPV, "attempt to compare two %s values") +ERRDEF(GETLOOP, "loop in gettable") +ERRDEF(SETLOOP, "loop in settable") +ERRDEF(OPCALL, "call") +ERRDEF(OPINDEX, "index") +ERRDEF(OPARITH, "perform arithmetic on") +ERRDEF(OPCAT, "concatenate") +ERRDEF(OPLEN, "get length of") + +/* Type checks. */ +ERRDEF(BADSELF, "calling " LUA_QS " on bad self (%s)") +ERRDEF(BADARG, "bad argument #%d to " LUA_QS " (%s)") +ERRDEF(BADTYPE, "%s expected, got %s") +ERRDEF(BADVAL, "invalid value") +ERRDEF(NOVAL, "value expected") +ERRDEF(NOCORO, "coroutine expected") +ERRDEF(NOTABN, "nil or table expected") +ERRDEF(NOLFUNC, "Lua function expected") +ERRDEF(NOFUNCL, "function or level expected") +ERRDEF(NOSFT, "string/function/table expected") +ERRDEF(NOPROXY, "boolean or proxy expected") +ERRDEF(FORINIT, LUA_QL("for") " initial value must be a number") +ERRDEF(FORLIM, LUA_QL("for") " limit must be a number") +ERRDEF(FORSTEP, LUA_QL("for") " step must be a number") + +/* C API checks. */ +ERRDEF(NOENV, "no calling environment") +ERRDEF(CYIELD, "attempt to yield across C-call boundary") +ERRDEF(BADLU, "bad light userdata pointer") +ERRDEF(NOGCMM, "bad action while in __gc metamethod") +#if LJ_TARGET_WINDOWS +ERRDEF(BADFPU, "bad FPU precision (use D3DCREATE_FPU_PRESERVE with DirectX)") +#endif + +/* Standard library function errors. */ +ERRDEF(ASSERT, "assertion failed!") +ERRDEF(PROTMT, "cannot change a protected metatable") +ERRDEF(UNPACK, "too many results to unpack") +ERRDEF(RDRSTR, "reader function must return a string") +ERRDEF(PRTOSTR, LUA_QL("tostring") " must return a string to " LUA_QL("print")) +ERRDEF(NUMRNG, "number out of range") +ERRDEF(IDXRNG, "index out of range") +ERRDEF(BASERNG, "base out of range") +ERRDEF(LVLRNG, "level out of range") +ERRDEF(INVLVL, "invalid level") +ERRDEF(INVOPT, "invalid option") +ERRDEF(INVOPTM, "invalid option " LUA_QS) +ERRDEF(INVFMT, "invalid format") +ERRDEF(SETFENV, LUA_QL("setfenv") " cannot change environment of given object") +ERRDEF(CORUN, "cannot resume running coroutine") +ERRDEF(CODEAD, "cannot resume dead coroutine") +ERRDEF(COSUSP, "cannot resume non-suspended coroutine") +ERRDEF(TABINS, "wrong number of arguments to " LUA_QL("insert")) +ERRDEF(TABCAT, "invalid value (%s) at index %d in table for " LUA_QL("concat")) +ERRDEF(TABSORT, "invalid order function for sorting") +ERRDEF(IOCLFL, "attempt to use a closed file") +ERRDEF(IOSTDCL, "standard file is closed") +ERRDEF(OSUNIQF, "unable to generate a unique filename") +ERRDEF(OSDATEF, "field " LUA_QS " missing in date table") +ERRDEF(STRDUMP, "unable to dump given function") +ERRDEF(STRSLC, "string slice too long") +ERRDEF(STRPATB, "missing " LUA_QL("[") " after " LUA_QL("%f") " in pattern") +ERRDEF(STRPATC, "invalid pattern capture") +ERRDEF(STRPATE, "malformed pattern (ends with " LUA_QL("%") ")") +ERRDEF(STRPATM, "malformed pattern (missing " LUA_QL("]") ")") +ERRDEF(STRPATU, "unbalanced pattern") +ERRDEF(STRPATX, "pattern too complex") +ERRDEF(STRCAPI, "invalid capture index") +ERRDEF(STRCAPN, "too many captures") +ERRDEF(STRCAPU, "unfinished capture") +ERRDEF(STRFMT, "invalid option " LUA_QS " to " LUA_QL("format")) +ERRDEF(STRGSRV, "invalid replacement value (a %s)") +ERRDEF(BADMODN, "name conflict for module " LUA_QS) +#if LJ_HASJIT +ERRDEF(JITPROT, "runtime code generation failed, restricted kernel?") +ERRDEF(NOJIT, "JIT compiler disabled") +#elif defined(LJ_ARCH_NOJIT) +ERRDEF(NOJIT, "no JIT compiler for this architecture (yet)") +#else +ERRDEF(NOJIT, "JIT compiler permanently disabled by build option") +#endif +ERRDEF(JITOPT, "unknown or malformed optimization flag " LUA_QS) + +/* Lexer/parser errors. */ +ERRDEF(XMODE, "attempt to load chunk with wrong mode") +ERRDEF(XNEAR, "%s near " LUA_QS) +ERRDEF(XLINES, "chunk has too many lines") +ERRDEF(XLEVELS, "chunk has too many syntax levels") +ERRDEF(XNUMBER, "malformed number") +ERRDEF(XLSTR, "unfinished long string") +ERRDEF(XLCOM, "unfinished long comment") +ERRDEF(XSTR, "unfinished string") +ERRDEF(XESC, "invalid escape sequence") +ERRDEF(XLDELIM, "invalid long string delimiter") +ERRDEF(XTOKEN, LUA_QS " expected") +ERRDEF(XJUMP, "control structure too long") +ERRDEF(XSLOTS, "function or expression too complex") +ERRDEF(XLIMC, "chunk has more than %d local variables") +ERRDEF(XLIMM, "main function has more than %d %s") +ERRDEF(XLIMF, "function at line %d has more than %d %s") +ERRDEF(XMATCH, LUA_QS " expected (to close " LUA_QS " at line %d)") +ERRDEF(XFIXUP, "function too long for return fixup") +ERRDEF(XPARAM, " or " LUA_QL("...") " expected") +#if !LJ_52 +ERRDEF(XAMBIG, "ambiguous syntax (function call x new statement)") +#endif +ERRDEF(XFUNARG, "function arguments expected") +ERRDEF(XSYMBOL, "unexpected symbol") +ERRDEF(XDOTS, "cannot use " LUA_QL("...") " outside a vararg function") +ERRDEF(XSYNTAX, "syntax error") +ERRDEF(XFOR, LUA_QL("=") " or " LUA_QL("in") " expected") +ERRDEF(XBREAK, "no loop to break") +ERRDEF(XLUNDEF, "undefined label " LUA_QS) +ERRDEF(XLDUP, "duplicate label " LUA_QS) +ERRDEF(XGSCOPE, " jumps into the scope of local " LUA_QS) + +/* Bytecode reader errors. */ +ERRDEF(BCFMT, "cannot load incompatible bytecode") +ERRDEF(BCBAD, "cannot load malformed bytecode") + +#if LJ_HASFFI +/* FFI errors. */ +ERRDEF(FFI_INVTYPE, "invalid C type") +ERRDEF(FFI_INVSIZE, "size of C type is unknown or too large") +ERRDEF(FFI_BADSCL, "bad storage class") +ERRDEF(FFI_DECLSPEC, "declaration specifier expected") +ERRDEF(FFI_BADTAG, "undeclared or implicit tag " LUA_QS) +ERRDEF(FFI_REDEF, "attempt to redefine " LUA_QS) +ERRDEF(FFI_NUMPARAM, "wrong number of type parameters") +ERRDEF(FFI_INITOV, "too many initializers for " LUA_QS) +ERRDEF(FFI_BADCONV, "cannot convert " LUA_QS " to " LUA_QS) +ERRDEF(FFI_BADLEN, "attempt to get length of " LUA_QS) +ERRDEF(FFI_BADCONCAT, "attempt to concatenate " LUA_QS " and " LUA_QS) +ERRDEF(FFI_BADARITH, "attempt to perform arithmetic on " LUA_QS " and " LUA_QS) +ERRDEF(FFI_BADCOMP, "attempt to compare " LUA_QS " with " LUA_QS) +ERRDEF(FFI_BADCALL, LUA_QS " is not callable") +ERRDEF(FFI_NUMARG, "wrong number of arguments for function call") +ERRDEF(FFI_BADMEMBER, LUA_QS " has no member named " LUA_QS) +ERRDEF(FFI_BADIDX, LUA_QS " cannot be indexed") +ERRDEF(FFI_BADIDXW, LUA_QS " cannot be indexed with " LUA_QS) +ERRDEF(FFI_BADMM, LUA_QS " has no " LUA_QS " metamethod") +ERRDEF(FFI_WRCONST, "attempt to write to constant location") +ERRDEF(FFI_NODECL, "missing declaration for symbol " LUA_QS) +ERRDEF(FFI_BADCBACK, "bad callback") +#if LJ_OS_NOJIT +ERRDEF(FFI_CBACKOV, "no support for callbacks on this OS") +#else +ERRDEF(FFI_CBACKOV, "too many callbacks") +#endif +ERRDEF(FFI_NYIPACKBIT, "NYI: packed bit fields") +ERRDEF(FFI_NYICALL, "NYI: cannot call this C function (yet)") +#endif + +#if LJ_HASBUFFER +/* String buffer errors. */ +ERRDEF(BUFFER_SELF, "cannot put buffer into itself") +ERRDEF(BUFFER_BADOPT, "bad options table") +ERRDEF(BUFFER_BADENC, "cannot serialize " LUA_QS) +ERRDEF(BUFFER_BADDEC, "cannot deserialize tag 0x%02x") +ERRDEF(BUFFER_BADDICTX, "cannot deserialize dictionary index %d") +ERRDEF(BUFFER_DEPTH, "too deep to serialize") +ERRDEF(BUFFER_DUPKEY, "duplicate table key") +ERRDEF(BUFFER_EOB, "unexpected end of buffer") +ERRDEF(BUFFER_LEFTOV, "left-over data in buffer") +#endif + +#undef ERRDEF + +/* Detecting unused error messages: + awk -F, '/^ERRDEF/ { gsub(/ERRDEF./, ""); printf "grep -q LJ_ERR_%s *.[ch] || echo %s\n", $1, $1}' lj_errmsg.h | sh +*/ diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_ff.h b/fluent-bit/lib/luajit-3065c9/src/lj_ff.h new file mode 100644 index 00000000..d00c32fc --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_ff.h @@ -0,0 +1,18 @@ +/* +** Fast function IDs. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#ifndef _LJ_FF_H +#define _LJ_FF_H + +/* Fast function ID. */ +typedef enum { + FF_LUA_ = FF_LUA, /* Lua function (must be 0). */ + FF_C_ = FF_C, /* Regular C function (must be 1). */ +#define FFDEF(name) FF_##name, +#include "lj_ffdef.h" + FF__MAX +} FastFunc; + +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_ffrecord.c b/fluent-bit/lib/luajit-3065c9/src/lj_ffrecord.c new file mode 100644 index 00000000..60c1d84f --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_ffrecord.c @@ -0,0 +1,1574 @@ +/* +** Fast function call recorder. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#define lj_ffrecord_c +#define LUA_CORE + +#include "lj_obj.h" + +#if LJ_HASJIT + +#include "lj_err.h" +#include "lj_buf.h" +#include "lj_str.h" +#include "lj_tab.h" +#include "lj_frame.h" +#include "lj_bc.h" +#include "lj_ff.h" +#include "lj_ir.h" +#include "lj_jit.h" +#include "lj_ircall.h" +#include "lj_iropt.h" +#include "lj_trace.h" +#include "lj_record.h" +#include "lj_ffrecord.h" +#include "lj_crecord.h" +#include "lj_dispatch.h" +#include "lj_vm.h" +#include "lj_strscan.h" +#include "lj_strfmt.h" +#include "lj_serialize.h" + +/* Some local macros to save typing. Undef'd at the end. */ +#define IR(ref) (&J->cur.ir[(ref)]) + +/* Pass IR on to next optimization in chain (FOLD). */ +#define emitir(ot, a, b) (lj_ir_set(J, (ot), (a), (b)), lj_opt_fold(J)) + +/* -- Fast function recording handlers ------------------------------------ */ + +/* Conventions for fast function call handlers: +** +** The argument slots start at J->base[0]. All of them are guaranteed to be +** valid and type-specialized references. J->base[J->maxslot] is set to 0 +** as a sentinel. The runtime argument values start at rd->argv[0]. +** +** In general fast functions should check for presence of all of their +** arguments and for the correct argument types. Some simplifications +** are allowed if the interpreter throws instead. But even if recording +** is aborted, the generated IR must be consistent (no zero-refs). +** +** The number of results in rd->nres is set to 1. Handlers that return +** a different number of results need to override it. A negative value +** prevents return processing (e.g. for pending calls). +** +** Results need to be stored starting at J->base[0]. Return processing +** moves them to the right slots later. +** +** The per-ffid auxiliary data is the value of the 2nd part of the +** LJLIB_REC() annotation. This allows handling similar functionality +** in a common handler. +*/ + +/* Type of handler to record a fast function. */ +typedef void (LJ_FASTCALL *RecordFunc)(jit_State *J, RecordFFData *rd); + +/* Get runtime value of int argument. */ +static int32_t argv2int(jit_State *J, TValue *o) +{ + if (!lj_strscan_numberobj(o)) + lj_trace_err(J, LJ_TRERR_BADTYPE); + return tvisint(o) ? intV(o) : lj_num2int(numV(o)); +} + +/* Get runtime value of string argument. */ +static GCstr *argv2str(jit_State *J, TValue *o) +{ + if (LJ_LIKELY(tvisstr(o))) { + return strV(o); + } else { + GCstr *s; + if (!tvisnumber(o)) + lj_trace_err(J, LJ_TRERR_BADTYPE); + s = lj_strfmt_number(J->L, o); + setstrV(J->L, o, s); + return s; + } +} + +/* Return number of results wanted by caller. */ +static ptrdiff_t results_wanted(jit_State *J) +{ + TValue *frame = J->L->base-1; + if (frame_islua(frame)) + return (ptrdiff_t)bc_b(frame_pc(frame)[-1]) - 1; + else + return -1; +} + +/* Trace stitching: add continuation below frame to start a new trace. */ +static void recff_stitch(jit_State *J) +{ + ASMFunction cont = lj_cont_stitch; + lua_State *L = J->L; + TValue *base = L->base; + BCReg nslot = J->maxslot + 1 + LJ_FR2; + TValue *nframe = base + 1 + LJ_FR2; + const BCIns *pc = frame_pc(base-1); + TValue *pframe = frame_prevl(base-1); + + /* Check for this now. Throwing in lj_record_stop messes up the stack. */ + if (J->cur.nsnap >= (MSize)J->param[JIT_P_maxsnap]) + lj_trace_err(J, LJ_TRERR_SNAPOV); + + /* Move func + args up in Lua stack and insert continuation. */ + memmove(&base[1], &base[-1-LJ_FR2], sizeof(TValue)*nslot); + setframe_ftsz(nframe, ((char *)nframe - (char *)pframe) + FRAME_CONT); + setcont(base-LJ_FR2, cont); + setframe_pc(base, pc); + setnilV(base-1-LJ_FR2); /* Incorrect, but rec_check_slots() won't run anymore. */ + L->base += 2 + LJ_FR2; + L->top += 2 + LJ_FR2; + + /* Ditto for the IR. */ + memmove(&J->base[1], &J->base[-1-LJ_FR2], sizeof(TRef)*nslot); +#if LJ_FR2 + J->base[2] = TREF_FRAME; + J->base[-1] = lj_ir_k64(J, IR_KNUM, u64ptr(contptr(cont))); + J->base[0] = lj_ir_k64(J, IR_KNUM, u64ptr(pc)) | TREF_CONT; +#else + J->base[0] = lj_ir_kptr(J, contptr(cont)) | TREF_CONT; +#endif + J->ktrace = tref_ref((J->base[-1-LJ_FR2] = lj_ir_ktrace(J))); + J->base += 2 + LJ_FR2; + J->baseslot += 2 + LJ_FR2; + J->framedepth++; + + lj_record_stop(J, LJ_TRLINK_STITCH, 0); + + /* Undo Lua stack changes. */ + memmove(&base[-1-LJ_FR2], &base[1], sizeof(TValue)*nslot); + setframe_pc(base-1, pc); + L->base -= 2 + LJ_FR2; + L->top -= 2 + LJ_FR2; +} + +/* Fallback handler for fast functions that are not recorded (yet). */ +static void LJ_FASTCALL recff_nyi(jit_State *J, RecordFFData *rd) +{ + if (J->cur.nins < (IRRef)J->param[JIT_P_minstitch] + REF_BASE) { + lj_trace_err_info(J, LJ_TRERR_TRACEUV); + } else { + /* Can only stitch from Lua call. */ + if (J->framedepth && frame_islua(J->L->base-1)) { + BCOp op = bc_op(*frame_pc(J->L->base-1)); + /* Stitched trace cannot start with *M op with variable # of args. */ + if (!(op == BC_CALLM || op == BC_CALLMT || + op == BC_RETM || op == BC_TSETM)) { + switch (J->fn->c.ffid) { + case FF_error: + case FF_debug_sethook: + case FF_jit_flush: + break; /* Don't stitch across special builtins. */ + default: + recff_stitch(J); /* Use trace stitching. */ + rd->nres = -1; + return; + } + } + } + /* Otherwise stop trace and return to interpreter. */ + lj_record_stop(J, LJ_TRLINK_RETURN, 0); + rd->nres = -1; + } +} + +/* Fallback handler for unsupported variants of fast functions. */ +#define recff_nyiu recff_nyi + +/* Must stop the trace for classic C functions with arbitrary side-effects. */ +#define recff_c recff_nyi + +/* Emit BUFHDR for the global temporary buffer. */ +static TRef recff_bufhdr(jit_State *J) +{ + return emitir(IRT(IR_BUFHDR, IRT_PGC), + lj_ir_kptr(J, &J2G(J)->tmpbuf), IRBUFHDR_RESET); +} + +/* Emit TMPREF. */ +static TRef recff_tmpref(jit_State *J, TRef tr, int mode) +{ + if (!LJ_DUALNUM && tref_isinteger(tr)) + tr = emitir(IRTN(IR_CONV), tr, IRCONV_NUM_INT); + return emitir(IRT(IR_TMPREF, IRT_PGC), tr, mode); +} + +/* -- Base library fast functions ----------------------------------------- */ + +static void LJ_FASTCALL recff_assert(jit_State *J, RecordFFData *rd) +{ + /* Arguments already specialized. The interpreter throws for nil/false. */ + rd->nres = J->maxslot; /* Pass through all arguments. */ +} + +static void LJ_FASTCALL recff_type(jit_State *J, RecordFFData *rd) +{ + /* Arguments already specialized. Result is a constant string. Neat, huh? */ + uint32_t t; + if (tvisnumber(&rd->argv[0])) + t = ~LJ_TNUMX; + else if (LJ_64 && !LJ_GC64 && tvislightud(&rd->argv[0])) + t = ~LJ_TLIGHTUD; + else + t = ~itype(&rd->argv[0]); + J->base[0] = lj_ir_kstr(J, strV(&J->fn->c.upvalue[t])); + UNUSED(rd); +} + +static void LJ_FASTCALL recff_getmetatable(jit_State *J, RecordFFData *rd) +{ + TRef tr = J->base[0]; + if (tr) { + RecordIndex ix; + ix.tab = tr; + copyTV(J->L, &ix.tabv, &rd->argv[0]); + if (lj_record_mm_lookup(J, &ix, MM_metatable)) + J->base[0] = ix.mobj; + else + J->base[0] = ix.mt; + } /* else: Interpreter will throw. */ +} + +static void LJ_FASTCALL recff_setmetatable(jit_State *J, RecordFFData *rd) +{ + TRef tr = J->base[0]; + TRef mt = J->base[1]; + if (tref_istab(tr) && (tref_istab(mt) || (mt && tref_isnil(mt)))) { + TRef fref, mtref; + RecordIndex ix; + ix.tab = tr; + copyTV(J->L, &ix.tabv, &rd->argv[0]); + lj_record_mm_lookup(J, &ix, MM_metatable); /* Guard for no __metatable. */ + fref = emitir(IRT(IR_FREF, IRT_PGC), tr, IRFL_TAB_META); + mtref = tref_isnil(mt) ? lj_ir_knull(J, IRT_TAB) : mt; + emitir(IRT(IR_FSTORE, IRT_TAB), fref, mtref); + if (!tref_isnil(mt)) + emitir(IRT(IR_TBAR, IRT_TAB), tr, 0); + J->base[0] = tr; + J->needsnap = 1; + } /* else: Interpreter will throw. */ +} + +static void LJ_FASTCALL recff_rawget(jit_State *J, RecordFFData *rd) +{ + RecordIndex ix; + ix.tab = J->base[0]; ix.key = J->base[1]; + if (tref_istab(ix.tab) && ix.key) { + ix.val = 0; ix.idxchain = 0; + settabV(J->L, &ix.tabv, tabV(&rd->argv[0])); + copyTV(J->L, &ix.keyv, &rd->argv[1]); + J->base[0] = lj_record_idx(J, &ix); + } /* else: Interpreter will throw. */ +} + +static void LJ_FASTCALL recff_rawset(jit_State *J, RecordFFData *rd) +{ + RecordIndex ix; + ix.tab = J->base[0]; ix.key = J->base[1]; ix.val = J->base[2]; + if (tref_istab(ix.tab) && ix.key && ix.val) { + ix.idxchain = 0; + settabV(J->L, &ix.tabv, tabV(&rd->argv[0])); + copyTV(J->L, &ix.keyv, &rd->argv[1]); + copyTV(J->L, &ix.valv, &rd->argv[2]); + lj_record_idx(J, &ix); + /* Pass through table at J->base[0] as result. */ + } /* else: Interpreter will throw. */ +} + +static void LJ_FASTCALL recff_rawequal(jit_State *J, RecordFFData *rd) +{ + TRef tra = J->base[0]; + TRef trb = J->base[1]; + if (tra && trb) { + int diff = lj_record_objcmp(J, tra, trb, &rd->argv[0], &rd->argv[1]); + J->base[0] = diff ? TREF_FALSE : TREF_TRUE; + } /* else: Interpreter will throw. */ +} + +#if LJ_52 +static void LJ_FASTCALL recff_rawlen(jit_State *J, RecordFFData *rd) +{ + TRef tr = J->base[0]; + if (tref_isstr(tr)) + J->base[0] = emitir(IRTI(IR_FLOAD), tr, IRFL_STR_LEN); + else if (tref_istab(tr)) + J->base[0] = emitir(IRTI(IR_ALEN), tr, TREF_NIL); + /* else: Interpreter will throw. */ + UNUSED(rd); +} +#endif + +/* Determine mode of select() call. */ +int32_t lj_ffrecord_select_mode(jit_State *J, TRef tr, TValue *tv) +{ + if (tref_isstr(tr) && *strVdata(tv) == '#') { /* select('#', ...) */ + if (strV(tv)->len == 1) { + emitir(IRTG(IR_EQ, IRT_STR), tr, lj_ir_kstr(J, strV(tv))); + } else { + TRef trptr = emitir(IRT(IR_STRREF, IRT_PGC), tr, lj_ir_kint(J, 0)); + TRef trchar = emitir(IRT(IR_XLOAD, IRT_U8), trptr, IRXLOAD_READONLY); + emitir(IRTGI(IR_EQ), trchar, lj_ir_kint(J, '#')); + } + return 0; + } else { /* select(n, ...) */ + int32_t start = argv2int(J, tv); + if (start == 0) lj_trace_err(J, LJ_TRERR_BADTYPE); /* A bit misleading. */ + return start; + } +} + +static void LJ_FASTCALL recff_select(jit_State *J, RecordFFData *rd) +{ + TRef tr = J->base[0]; + if (tr) { + ptrdiff_t start = lj_ffrecord_select_mode(J, tr, &rd->argv[0]); + if (start == 0) { /* select('#', ...) */ + J->base[0] = lj_ir_kint(J, J->maxslot - 1); + } else if (tref_isk(tr)) { /* select(k, ...) */ + ptrdiff_t n = (ptrdiff_t)J->maxslot; + if (start < 0) start += n; + else if (start > n) start = n; + if (start >= 1) { + ptrdiff_t i; + rd->nres = n - start; + for (i = 0; i < n - start; i++) + J->base[i] = J->base[start+i]; + } /* else: Interpreter will throw. */ + } else { + recff_nyiu(J, rd); + return; + } + } /* else: Interpreter will throw. */ +} + +static void LJ_FASTCALL recff_tonumber(jit_State *J, RecordFFData *rd) +{ + TRef tr = J->base[0]; + TRef base = J->base[1]; + if (tr && !tref_isnil(base)) { + base = lj_opt_narrow_toint(J, base); + if (!tref_isk(base) || IR(tref_ref(base))->i != 10) { + recff_nyiu(J, rd); + return; + } + } + if (tref_isnumber_str(tr)) { + if (tref_isstr(tr)) { + TValue tmp; + if (!lj_strscan_num(strV(&rd->argv[0]), &tmp)) { + recff_nyiu(J, rd); /* Would need an inverted STRTO for this case. */ + return; + } + tr = emitir(IRTG(IR_STRTO, IRT_NUM), tr, 0); + } +#if LJ_HASFFI + } else if (tref_iscdata(tr)) { + lj_crecord_tonumber(J, rd); + return; +#endif + } else { + tr = TREF_NIL; + } + J->base[0] = tr; + UNUSED(rd); +} + +static TValue *recff_metacall_cp(lua_State *L, lua_CFunction dummy, void *ud) +{ + jit_State *J = (jit_State *)ud; + lj_record_tailcall(J, 0, 1); + UNUSED(L); UNUSED(dummy); + return NULL; +} + +static int recff_metacall(jit_State *J, RecordFFData *rd, MMS mm) +{ + RecordIndex ix; + ix.tab = J->base[0]; + copyTV(J->L, &ix.tabv, &rd->argv[0]); + if (lj_record_mm_lookup(J, &ix, mm)) { /* Has metamethod? */ + int errcode; + TValue argv0; + /* Temporarily insert metamethod below object. */ + J->base[1+LJ_FR2] = J->base[0]; + J->base[0] = ix.mobj; + copyTV(J->L, &argv0, &rd->argv[0]); + copyTV(J->L, &rd->argv[1+LJ_FR2], &rd->argv[0]); + copyTV(J->L, &rd->argv[0], &ix.mobjv); + /* Need to protect lj_record_tailcall because it may throw. */ + errcode = lj_vm_cpcall(J->L, NULL, J, recff_metacall_cp); + /* Always undo Lua stack changes to avoid confusing the interpreter. */ + copyTV(J->L, &rd->argv[0], &argv0); + if (errcode) + lj_err_throw(J->L, errcode); /* Propagate errors. */ + rd->nres = -1; /* Pending call. */ + return 1; /* Tailcalled to metamethod. */ + } + return 0; +} + +static void LJ_FASTCALL recff_tostring(jit_State *J, RecordFFData *rd) +{ + TRef tr = J->base[0]; + if (tref_isstr(tr)) { + /* Ignore __tostring in the string base metatable. */ + /* Pass on result in J->base[0]. */ + } else if (tr && !recff_metacall(J, rd, MM_tostring)) { + if (tref_isnumber(tr)) { + J->base[0] = emitir(IRT(IR_TOSTR, IRT_STR), tr, + tref_isnum(tr) ? IRTOSTR_NUM : IRTOSTR_INT); + } else if (tref_ispri(tr)) { + J->base[0] = lj_ir_kstr(J, lj_strfmt_obj(J->L, &rd->argv[0])); + } else { + recff_nyiu(J, rd); + return; + } + } +} + +static void LJ_FASTCALL recff_ipairs_aux(jit_State *J, RecordFFData *rd) +{ + RecordIndex ix; + ix.tab = J->base[0]; + if (tref_istab(ix.tab)) { + if (!tvisnumber(&rd->argv[1])) /* No support for string coercion. */ + lj_trace_err(J, LJ_TRERR_BADTYPE); + setintV(&ix.keyv, numberVint(&rd->argv[1])+1); + settabV(J->L, &ix.tabv, tabV(&rd->argv[0])); + ix.val = 0; ix.idxchain = 0; + ix.key = lj_opt_narrow_toint(J, J->base[1]); + J->base[0] = ix.key = emitir(IRTI(IR_ADD), ix.key, lj_ir_kint(J, 1)); + J->base[1] = lj_record_idx(J, &ix); + rd->nres = tref_isnil(J->base[1]) ? 0 : 2; + } /* else: Interpreter will throw. */ +} + +static void LJ_FASTCALL recff_xpairs(jit_State *J, RecordFFData *rd) +{ + TRef tr = J->base[0]; + if (!((LJ_52 || (LJ_HASFFI && tref_iscdata(tr))) && + recff_metacall(J, rd, MM_pairs + rd->data))) { + if (tref_istab(tr)) { + J->base[0] = lj_ir_kfunc(J, funcV(&J->fn->c.upvalue[0])); + J->base[1] = tr; + J->base[2] = rd->data ? lj_ir_kint(J, 0) : TREF_NIL; + rd->nres = 3; + } /* else: Interpreter will throw. */ + } +} + +static void LJ_FASTCALL recff_pcall(jit_State *J, RecordFFData *rd) +{ + if (J->maxslot >= 1) { +#if LJ_FR2 + /* Shift function arguments up. */ + memmove(J->base + 1, J->base, sizeof(TRef) * J->maxslot); +#endif + lj_record_call(J, 0, J->maxslot - 1); + rd->nres = -1; /* Pending call. */ + J->needsnap = 1; /* Start catching on-trace errors. */ + } /* else: Interpreter will throw. */ +} + +static TValue *recff_xpcall_cp(lua_State *L, lua_CFunction dummy, void *ud) +{ + jit_State *J = (jit_State *)ud; + lj_record_call(J, 1, J->maxslot - 2); + UNUSED(L); UNUSED(dummy); + return NULL; +} + +static void LJ_FASTCALL recff_xpcall(jit_State *J, RecordFFData *rd) +{ + if (J->maxslot >= 2) { + TValue argv0, argv1; + TRef tmp; + int errcode; + /* Swap function and traceback. */ + tmp = J->base[0]; J->base[0] = J->base[1]; J->base[1] = tmp; + copyTV(J->L, &argv0, &rd->argv[0]); + copyTV(J->L, &argv1, &rd->argv[1]); + copyTV(J->L, &rd->argv[0], &argv1); + copyTV(J->L, &rd->argv[1], &argv0); +#if LJ_FR2 + /* Shift function arguments up. */ + memmove(J->base + 2, J->base + 1, sizeof(TRef) * (J->maxslot-1)); +#endif + /* Need to protect lj_record_call because it may throw. */ + errcode = lj_vm_cpcall(J->L, NULL, J, recff_xpcall_cp); + /* Always undo Lua stack swap to avoid confusing the interpreter. */ + copyTV(J->L, &rd->argv[0], &argv0); + copyTV(J->L, &rd->argv[1], &argv1); + if (errcode) + lj_err_throw(J->L, errcode); /* Propagate errors. */ + rd->nres = -1; /* Pending call. */ + J->needsnap = 1; /* Start catching on-trace errors. */ + } /* else: Interpreter will throw. */ +} + +static void LJ_FASTCALL recff_getfenv(jit_State *J, RecordFFData *rd) +{ + TRef tr = J->base[0]; + /* Only support getfenv(0) for now. */ + if (tref_isint(tr) && tref_isk(tr) && IR(tref_ref(tr))->i == 0) { + TRef trl = emitir(IRT(IR_LREF, IRT_THREAD), 0, 0); + J->base[0] = emitir(IRT(IR_FLOAD, IRT_TAB), trl, IRFL_THREAD_ENV); + return; + } + recff_nyiu(J, rd); +} + +static void LJ_FASTCALL recff_next(jit_State *J, RecordFFData *rd) +{ +#if LJ_BE + /* YAGNI: Disabled on big-endian due to issues with lj_vm_next, + ** IR_HIOP, RID_RETLO/RID_RETHI and ra_destpair. + */ + recff_nyi(J, rd); +#else + TRef tab = J->base[0]; + if (tref_istab(tab)) { + RecordIndex ix; + cTValue *keyv; + ix.tab = tab; + if (tref_isnil(J->base[1])) { /* Shortcut for start of traversal. */ + ix.key = lj_ir_kint(J, 0); + keyv = niltvg(J2G(J)); + } else { + TRef tmp = recff_tmpref(J, J->base[1], IRTMPREF_IN1); + ix.key = lj_ir_call(J, IRCALL_lj_tab_keyindex, tab, tmp); + keyv = &rd->argv[1]; + } + copyTV(J->L, &ix.tabv, &rd->argv[0]); + ix.keyv.u32.lo = lj_tab_keyindex(tabV(&ix.tabv), keyv); + /* Omit the value, if not used by the caller. */ + ix.idxchain = (J->framedepth && frame_islua(J->L->base-1) && + bc_b(frame_pc(J->L->base-1)[-1])-1 < 2); + ix.mobj = 0; /* We don't need the next index. */ + rd->nres = lj_record_next(J, &ix); + J->base[0] = ix.key; + J->base[1] = ix.val; + } /* else: Interpreter will throw. */ +#endif +} + +/* -- Math library fast functions ----------------------------------------- */ + +static void LJ_FASTCALL recff_math_abs(jit_State *J, RecordFFData *rd) +{ + TRef tr = lj_ir_tonum(J, J->base[0]); + J->base[0] = emitir(IRTN(IR_ABS), tr, lj_ir_ksimd(J, LJ_KSIMD_ABS)); + UNUSED(rd); +} + +/* Record rounding functions math.floor and math.ceil. */ +static void LJ_FASTCALL recff_math_round(jit_State *J, RecordFFData *rd) +{ + TRef tr = J->base[0]; + if (!tref_isinteger(tr)) { /* Pass through integers unmodified. */ + tr = emitir(IRTN(IR_FPMATH), lj_ir_tonum(J, tr), rd->data); + /* Result is integral (or NaN/Inf), but may not fit an int32_t. */ + if (LJ_DUALNUM) { /* Try to narrow using a guarded conversion to int. */ + lua_Number n = lj_vm_foldfpm(numberVnum(&rd->argv[0]), rd->data); + if (n == (lua_Number)lj_num2int(n)) + tr = emitir(IRTGI(IR_CONV), tr, IRCONV_INT_NUM|IRCONV_CHECK); + } + J->base[0] = tr; + } +} + +/* Record unary math.* functions, mapped to IR_FPMATH opcode. */ +static void LJ_FASTCALL recff_math_unary(jit_State *J, RecordFFData *rd) +{ + J->base[0] = emitir(IRTN(IR_FPMATH), lj_ir_tonum(J, J->base[0]), rd->data); +} + +/* Record math.log. */ +static void LJ_FASTCALL recff_math_log(jit_State *J, RecordFFData *rd) +{ + TRef tr = lj_ir_tonum(J, J->base[0]); + if (J->base[1]) { +#ifdef LUAJIT_NO_LOG2 + uint32_t fpm = IRFPM_LOG; +#else + uint32_t fpm = IRFPM_LOG2; +#endif + TRef trb = lj_ir_tonum(J, J->base[1]); + tr = emitir(IRTN(IR_FPMATH), tr, fpm); + trb = emitir(IRTN(IR_FPMATH), trb, fpm); + trb = emitir(IRTN(IR_DIV), lj_ir_knum_one(J), trb); + tr = emitir(IRTN(IR_MUL), tr, trb); + } else { + tr = emitir(IRTN(IR_FPMATH), tr, IRFPM_LOG); + } + J->base[0] = tr; + UNUSED(rd); +} + +/* Record math.atan2. */ +static void LJ_FASTCALL recff_math_atan2(jit_State *J, RecordFFData *rd) +{ + TRef tr = lj_ir_tonum(J, J->base[0]); + TRef tr2 = lj_ir_tonum(J, J->base[1]); + J->base[0] = lj_ir_call(J, IRCALL_atan2, tr, tr2); + UNUSED(rd); +} + +/* Record math.ldexp. */ +static void LJ_FASTCALL recff_math_ldexp(jit_State *J, RecordFFData *rd) +{ + TRef tr = lj_ir_tonum(J, J->base[0]); +#if LJ_TARGET_X86ORX64 + TRef tr2 = lj_ir_tonum(J, J->base[1]); +#else + TRef tr2 = lj_opt_narrow_toint(J, J->base[1]); +#endif + J->base[0] = emitir(IRTN(IR_LDEXP), tr, tr2); + UNUSED(rd); +} + +static void LJ_FASTCALL recff_math_call(jit_State *J, RecordFFData *rd) +{ + TRef tr = lj_ir_tonum(J, J->base[0]); + J->base[0] = emitir(IRTN(IR_CALLN), tr, rd->data); +} + +static void LJ_FASTCALL recff_math_pow(jit_State *J, RecordFFData *rd) +{ + J->base[0] = lj_opt_narrow_arith(J, J->base[0], J->base[1], + &rd->argv[0], &rd->argv[1], IR_POW); + UNUSED(rd); +} + +static void LJ_FASTCALL recff_math_minmax(jit_State *J, RecordFFData *rd) +{ + TRef tr = lj_ir_tonumber(J, J->base[0]); + uint32_t op = rd->data; + BCReg i; + for (i = 1; J->base[i] != 0; i++) { + TRef tr2 = lj_ir_tonumber(J, J->base[i]); + IRType t = IRT_INT; + if (!(tref_isinteger(tr) && tref_isinteger(tr2))) { + if (tref_isinteger(tr)) tr = emitir(IRTN(IR_CONV), tr, IRCONV_NUM_INT); + if (tref_isinteger(tr2)) tr2 = emitir(IRTN(IR_CONV), tr2, IRCONV_NUM_INT); + t = IRT_NUM; + } + tr = emitir(IRT(op, t), tr, tr2); + } + J->base[0] = tr; +} + +static void LJ_FASTCALL recff_math_random(jit_State *J, RecordFFData *rd) +{ + GCudata *ud = udataV(&J->fn->c.upvalue[0]); + TRef tr, one; + lj_ir_kgc(J, obj2gco(ud), IRT_UDATA); /* Prevent collection. */ + tr = lj_ir_call(J, IRCALL_lj_prng_u64d, lj_ir_kptr(J, uddata(ud))); + one = lj_ir_knum_one(J); + tr = emitir(IRTN(IR_SUB), tr, one); + if (J->base[0]) { + TRef tr1 = lj_ir_tonum(J, J->base[0]); + if (J->base[1]) { /* d = floor(d*(r2-r1+1.0)) + r1 */ + TRef tr2 = lj_ir_tonum(J, J->base[1]); + tr2 = emitir(IRTN(IR_SUB), tr2, tr1); + tr2 = emitir(IRTN(IR_ADD), tr2, one); + tr = emitir(IRTN(IR_MUL), tr, tr2); + tr = emitir(IRTN(IR_FPMATH), tr, IRFPM_FLOOR); + tr = emitir(IRTN(IR_ADD), tr, tr1); + } else { /* d = floor(d*r1) + 1.0 */ + tr = emitir(IRTN(IR_MUL), tr, tr1); + tr = emitir(IRTN(IR_FPMATH), tr, IRFPM_FLOOR); + tr = emitir(IRTN(IR_ADD), tr, one); + } + } + J->base[0] = tr; + UNUSED(rd); +} + +/* -- Bit library fast functions ------------------------------------------ */ + +/* Record bit.tobit. */ +static void LJ_FASTCALL recff_bit_tobit(jit_State *J, RecordFFData *rd) +{ + TRef tr = J->base[0]; +#if LJ_HASFFI + if (tref_iscdata(tr)) { recff_bit64_tobit(J, rd); return; } +#endif + J->base[0] = lj_opt_narrow_tobit(J, tr); + UNUSED(rd); +} + +/* Record unary bit.bnot, bit.bswap. */ +static void LJ_FASTCALL recff_bit_unary(jit_State *J, RecordFFData *rd) +{ +#if LJ_HASFFI + if (recff_bit64_unary(J, rd)) + return; +#endif + J->base[0] = emitir(IRTI(rd->data), lj_opt_narrow_tobit(J, J->base[0]), 0); +} + +/* Record N-ary bit.band, bit.bor, bit.bxor. */ +static void LJ_FASTCALL recff_bit_nary(jit_State *J, RecordFFData *rd) +{ +#if LJ_HASFFI + if (recff_bit64_nary(J, rd)) + return; +#endif + { + TRef tr = lj_opt_narrow_tobit(J, J->base[0]); + uint32_t ot = IRTI(rd->data); + BCReg i; + for (i = 1; J->base[i] != 0; i++) + tr = emitir(ot, tr, lj_opt_narrow_tobit(J, J->base[i])); + J->base[0] = tr; + } +} + +/* Record bit shifts. */ +static void LJ_FASTCALL recff_bit_shift(jit_State *J, RecordFFData *rd) +{ +#if LJ_HASFFI + if (recff_bit64_shift(J, rd)) + return; +#endif + { + TRef tr = lj_opt_narrow_tobit(J, J->base[0]); + TRef tsh = lj_opt_narrow_tobit(J, J->base[1]); + IROp op = (IROp)rd->data; + if (!(op < IR_BROL ? LJ_TARGET_MASKSHIFT : LJ_TARGET_MASKROT) && + !tref_isk(tsh)) + tsh = emitir(IRTI(IR_BAND), tsh, lj_ir_kint(J, 31)); +#ifdef LJ_TARGET_UNIFYROT + if (op == (LJ_TARGET_UNIFYROT == 1 ? IR_BROR : IR_BROL)) { + op = LJ_TARGET_UNIFYROT == 1 ? IR_BROL : IR_BROR; + tsh = emitir(IRTI(IR_NEG), tsh, tsh); + } +#endif + J->base[0] = emitir(IRTI(op), tr, tsh); + } +} + +static void LJ_FASTCALL recff_bit_tohex(jit_State *J, RecordFFData *rd) +{ +#if LJ_HASFFI + TRef hdr = recff_bufhdr(J); + TRef tr = recff_bit64_tohex(J, rd, hdr); + J->base[0] = emitir(IRTG(IR_BUFSTR, IRT_STR), tr, hdr); +#else + recff_nyiu(J, rd); /* Don't bother working around this NYI. */ +#endif +} + +/* -- String library fast functions --------------------------------------- */ + +/* Specialize to relative starting position for string. */ +static TRef recff_string_start(jit_State *J, GCstr *s, int32_t *st, TRef tr, + TRef trlen, TRef tr0) +{ + int32_t start = *st; + if (start < 0) { + emitir(IRTGI(IR_LT), tr, tr0); + tr = emitir(IRTI(IR_ADD), trlen, tr); + start = start + (int32_t)s->len; + emitir(start < 0 ? IRTGI(IR_LT) : IRTGI(IR_GE), tr, tr0); + if (start < 0) { + tr = tr0; + start = 0; + } + } else if (start == 0) { + emitir(IRTGI(IR_EQ), tr, tr0); + tr = tr0; + } else { + tr = emitir(IRTI(IR_ADD), tr, lj_ir_kint(J, -1)); + emitir(IRTGI(IR_GE), tr, tr0); + start--; + } + *st = start; + return tr; +} + +/* Handle string.byte (rd->data = 0) and string.sub (rd->data = 1). */ +static void LJ_FASTCALL recff_string_range(jit_State *J, RecordFFData *rd) +{ + TRef trstr = lj_ir_tostr(J, J->base[0]); + TRef trlen = emitir(IRTI(IR_FLOAD), trstr, IRFL_STR_LEN); + TRef tr0 = lj_ir_kint(J, 0); + TRef trstart, trend; + GCstr *str = argv2str(J, &rd->argv[0]); + int32_t start, end; + if (rd->data) { /* string.sub(str, start [,end]) */ + start = argv2int(J, &rd->argv[1]); + trstart = lj_opt_narrow_toint(J, J->base[1]); + trend = J->base[2]; + if (tref_isnil(trend)) { + trend = lj_ir_kint(J, -1); + end = -1; + } else { + trend = lj_opt_narrow_toint(J, trend); + end = argv2int(J, &rd->argv[2]); + } + } else { /* string.byte(str, [,start [,end]]) */ + if (tref_isnil(J->base[1])) { + start = 1; + trstart = lj_ir_kint(J, 1); + } else { + start = argv2int(J, &rd->argv[1]); + trstart = lj_opt_narrow_toint(J, J->base[1]); + } + if (J->base[1] && !tref_isnil(J->base[2])) { + trend = lj_opt_narrow_toint(J, J->base[2]); + end = argv2int(J, &rd->argv[2]); + } else { + trend = trstart; + end = start; + } + } + if (end < 0) { + emitir(IRTGI(IR_LT), trend, tr0); + trend = emitir(IRTI(IR_ADD), emitir(IRTI(IR_ADD), trlen, trend), + lj_ir_kint(J, 1)); + end = end+(int32_t)str->len+1; + } else if ((MSize)end <= str->len) { + emitir(IRTGI(IR_ULE), trend, trlen); + } else { + emitir(IRTGI(IR_UGT), trend, trlen); + end = (int32_t)str->len; + trend = trlen; + } + trstart = recff_string_start(J, str, &start, trstart, trlen, tr0); + if (rd->data) { /* Return string.sub result. */ + if (end - start >= 0) { + /* Also handle empty range here, to avoid extra traces. */ + TRef trptr, trslen = emitir(IRTI(IR_SUB), trend, trstart); + emitir(IRTGI(IR_GE), trslen, tr0); + trptr = emitir(IRT(IR_STRREF, IRT_PGC), trstr, trstart); + J->base[0] = emitir(IRT(IR_SNEW, IRT_STR), trptr, trslen); + } else { /* Range underflow: return empty string. */ + emitir(IRTGI(IR_LT), trend, trstart); + J->base[0] = lj_ir_kstr(J, &J2G(J)->strempty); + } + } else { /* Return string.byte result(s). */ + ptrdiff_t i, len = end - start; + if (len > 0) { + TRef trslen = emitir(IRTI(IR_SUB), trend, trstart); + emitir(IRTGI(IR_EQ), trslen, lj_ir_kint(J, (int32_t)len)); + if (J->baseslot + len > LJ_MAX_JSLOTS) + lj_trace_err_info(J, LJ_TRERR_STACKOV); + rd->nres = len; + for (i = 0; i < len; i++) { + TRef tmp = emitir(IRTI(IR_ADD), trstart, lj_ir_kint(J, (int32_t)i)); + tmp = emitir(IRT(IR_STRREF, IRT_PGC), trstr, tmp); + J->base[i] = emitir(IRT(IR_XLOAD, IRT_U8), tmp, IRXLOAD_READONLY); + } + } else { /* Empty range or range underflow: return no results. */ + emitir(IRTGI(IR_LE), trend, trstart); + rd->nres = 0; + } + } +} + +static void LJ_FASTCALL recff_string_char(jit_State *J, RecordFFData *rd) +{ + TRef k255 = lj_ir_kint(J, 255); + BCReg i; + for (i = 0; J->base[i] != 0; i++) { /* Convert char values to strings. */ + TRef tr = lj_opt_narrow_toint(J, J->base[i]); + emitir(IRTGI(IR_ULE), tr, k255); + J->base[i] = emitir(IRT(IR_TOSTR, IRT_STR), tr, IRTOSTR_CHAR); + } + if (i > 1) { /* Concatenate the strings, if there's more than one. */ + TRef hdr = recff_bufhdr(J), tr = hdr; + for (i = 0; J->base[i] != 0; i++) + tr = emitir(IRTG(IR_BUFPUT, IRT_PGC), tr, J->base[i]); + J->base[0] = emitir(IRTG(IR_BUFSTR, IRT_STR), tr, hdr); + } else if (i == 0) { + J->base[0] = lj_ir_kstr(J, &J2G(J)->strempty); + } + UNUSED(rd); +} + +static void LJ_FASTCALL recff_string_rep(jit_State *J, RecordFFData *rd) +{ + TRef str = lj_ir_tostr(J, J->base[0]); + TRef rep = lj_opt_narrow_toint(J, J->base[1]); + TRef hdr, tr, str2 = 0; + if (!tref_isnil(J->base[2])) { + TRef sep = lj_ir_tostr(J, J->base[2]); + int32_t vrep = argv2int(J, &rd->argv[1]); + emitir(IRTGI(vrep > 1 ? IR_GT : IR_LE), rep, lj_ir_kint(J, 1)); + if (vrep > 1) { + TRef hdr2 = recff_bufhdr(J); + TRef tr2 = emitir(IRTG(IR_BUFPUT, IRT_PGC), hdr2, sep); + tr2 = emitir(IRTG(IR_BUFPUT, IRT_PGC), tr2, str); + str2 = emitir(IRTG(IR_BUFSTR, IRT_STR), tr2, hdr2); + } + } + tr = hdr = recff_bufhdr(J); + if (str2) { + tr = emitir(IRTG(IR_BUFPUT, IRT_PGC), tr, str); + str = str2; + rep = emitir(IRTI(IR_ADD), rep, lj_ir_kint(J, -1)); + } + tr = lj_ir_call(J, IRCALL_lj_buf_putstr_rep, tr, str, rep); + J->base[0] = emitir(IRTG(IR_BUFSTR, IRT_STR), tr, hdr); +} + +static void LJ_FASTCALL recff_string_op(jit_State *J, RecordFFData *rd) +{ + TRef str = lj_ir_tostr(J, J->base[0]); + TRef hdr = recff_bufhdr(J); + TRef tr = lj_ir_call(J, rd->data, hdr, str); + J->base[0] = emitir(IRTG(IR_BUFSTR, IRT_STR), tr, hdr); +} + +static void LJ_FASTCALL recff_string_find(jit_State *J, RecordFFData *rd) +{ + TRef trstr = lj_ir_tostr(J, J->base[0]); + TRef trpat = lj_ir_tostr(J, J->base[1]); + TRef trlen = emitir(IRTI(IR_FLOAD), trstr, IRFL_STR_LEN); + TRef tr0 = lj_ir_kint(J, 0); + TRef trstart; + GCstr *str = argv2str(J, &rd->argv[0]); + GCstr *pat = argv2str(J, &rd->argv[1]); + int32_t start; + J->needsnap = 1; + if (tref_isnil(J->base[2])) { + trstart = lj_ir_kint(J, 1); + start = 1; + } else { + trstart = lj_opt_narrow_toint(J, J->base[2]); + start = argv2int(J, &rd->argv[2]); + } + trstart = recff_string_start(J, str, &start, trstart, trlen, tr0); + if ((MSize)start <= str->len) { + emitir(IRTGI(IR_ULE), trstart, trlen); + } else { + emitir(IRTGI(IR_UGT), trstart, trlen); +#if LJ_52 + J->base[0] = TREF_NIL; + return; +#else + trstart = trlen; + start = str->len; +#endif + } + /* Fixed arg or no pattern matching chars? (Specialized to pattern string.) */ + if ((J->base[2] && tref_istruecond(J->base[3])) || + (emitir(IRTG(IR_EQ, IRT_STR), trpat, lj_ir_kstr(J, pat)), + !lj_str_haspattern(pat))) { /* Search for fixed string. */ + TRef trsptr = emitir(IRT(IR_STRREF, IRT_PGC), trstr, trstart); + TRef trpptr = emitir(IRT(IR_STRREF, IRT_PGC), trpat, tr0); + TRef trslen = emitir(IRTI(IR_SUB), trlen, trstart); + TRef trplen = emitir(IRTI(IR_FLOAD), trpat, IRFL_STR_LEN); + TRef tr = lj_ir_call(J, IRCALL_lj_str_find, trsptr, trpptr, trslen, trplen); + TRef trp0 = lj_ir_kkptr(J, NULL); + if (lj_str_find(strdata(str)+(MSize)start, strdata(pat), + str->len-(MSize)start, pat->len)) { + TRef pos; + emitir(IRTG(IR_NE, IRT_PGC), tr, trp0); + /* Recompute offset. trsptr may not point into trstr after folding. */ + pos = emitir(IRTI(IR_ADD), emitir(IRTI(IR_SUB), tr, trsptr), trstart); + J->base[0] = emitir(IRTI(IR_ADD), pos, lj_ir_kint(J, 1)); + J->base[1] = emitir(IRTI(IR_ADD), pos, trplen); + rd->nres = 2; + } else { + emitir(IRTG(IR_EQ, IRT_PGC), tr, trp0); + J->base[0] = TREF_NIL; + } + } else { /* Search for pattern. */ + recff_nyiu(J, rd); + return; + } +} + +static void recff_format(jit_State *J, RecordFFData *rd, TRef hdr, int sbufx) +{ + ptrdiff_t arg = sbufx; + TRef tr = hdr, trfmt = lj_ir_tostr(J, J->base[arg]); + GCstr *fmt = argv2str(J, &rd->argv[arg]); + FormatState fs; + SFormat sf; + /* Specialize to the format string. */ + emitir(IRTG(IR_EQ, IRT_STR), trfmt, lj_ir_kstr(J, fmt)); + lj_strfmt_init(&fs, strdata(fmt), fmt->len); + while ((sf = lj_strfmt_parse(&fs)) != STRFMT_EOF) { /* Parse format. */ + TRef tra = sf == STRFMT_LIT ? 0 : J->base[++arg]; + TRef trsf = lj_ir_kint(J, (int32_t)sf); + IRCallID id; + switch (STRFMT_TYPE(sf)) { + case STRFMT_LIT: + tr = emitir(IRTG(IR_BUFPUT, IRT_PGC), tr, + lj_ir_kstr(J, lj_str_new(J->L, fs.str, fs.len))); + break; + case STRFMT_INT: + id = IRCALL_lj_strfmt_putfnum_int; + handle_int: + if (!tref_isinteger(tra)) { +#if LJ_HASFFI + if (tref_iscdata(tra)) { + tra = lj_crecord_loadiu64(J, tra, &rd->argv[arg]); + tr = lj_ir_call(J, IRCALL_lj_strfmt_putfxint, tr, trsf, tra); + break; + } +#endif + goto handle_num; + } + if (sf == STRFMT_INT) { /* Shortcut for plain %d. */ + tr = emitir(IRTG(IR_BUFPUT, IRT_PGC), tr, + emitir(IRT(IR_TOSTR, IRT_STR), tra, IRTOSTR_INT)); + } else { +#if LJ_HASFFI + tra = emitir(IRT(IR_CONV, IRT_U64), tra, + (IRT_INT|(IRT_U64<<5)|IRCONV_SEXT)); + tr = lj_ir_call(J, IRCALL_lj_strfmt_putfxint, tr, trsf, tra); + lj_needsplit(J); +#else + recff_nyiu(J, rd); /* Don't bother working around this NYI. */ + return; +#endif + } + break; + case STRFMT_UINT: + id = IRCALL_lj_strfmt_putfnum_uint; + goto handle_int; + case STRFMT_NUM: + id = IRCALL_lj_strfmt_putfnum; + handle_num: + tra = lj_ir_tonum(J, tra); + tr = lj_ir_call(J, id, tr, trsf, tra); + if (LJ_SOFTFP32) lj_needsplit(J); + break; + case STRFMT_STR: + if (!tref_isstr(tra)) { + recff_nyiu(J, rd); /* NYI: __tostring and non-string types for %s. */ + /* NYI: also buffers. */ + return; + } + if (sf == STRFMT_STR) /* Shortcut for plain %s. */ + tr = emitir(IRTG(IR_BUFPUT, IRT_PGC), tr, tra); + else if ((sf & STRFMT_T_QUOTED)) + tr = lj_ir_call(J, IRCALL_lj_strfmt_putquoted, tr, tra); + else + tr = lj_ir_call(J, IRCALL_lj_strfmt_putfstr, tr, trsf, tra); + break; + case STRFMT_CHAR: + tra = lj_opt_narrow_toint(J, tra); + if (sf == STRFMT_CHAR) /* Shortcut for plain %c. */ + tr = emitir(IRTG(IR_BUFPUT, IRT_PGC), tr, + emitir(IRT(IR_TOSTR, IRT_STR), tra, IRTOSTR_CHAR)); + else + tr = lj_ir_call(J, IRCALL_lj_strfmt_putfchar, tr, trsf, tra); + break; + case STRFMT_PTR: /* NYI */ + case STRFMT_ERR: + default: + recff_nyiu(J, rd); + return; + } + } + if (sbufx) { + emitir(IRT(IR_USE, IRT_NIL), tr, 0); + } else { + J->base[0] = emitir(IRTG(IR_BUFSTR, IRT_STR), tr, hdr); + } +} + +static void LJ_FASTCALL recff_string_format(jit_State *J, RecordFFData *rd) +{ + recff_format(J, rd, recff_bufhdr(J), 0); +} + +/* -- Buffer library fast functions --------------------------------------- */ + +#if LJ_HASBUFFER + +static LJ_AINLINE TRef recff_sbufx_get_L(jit_State *J, TRef ud) +{ + return emitir(IRT(IR_FLOAD, IRT_PGC), ud, IRFL_SBUF_L); +} + +static LJ_AINLINE void recff_sbufx_set_L(jit_State *J, TRef ud, TRef val) +{ + TRef fref = emitir(IRT(IR_FREF, IRT_PGC), ud, IRFL_SBUF_L); + emitir(IRT(IR_FSTORE, IRT_PGC), fref, val); +} + +static LJ_AINLINE TRef recff_sbufx_get_ptr(jit_State *J, TRef ud, IRFieldID fl) +{ + return emitir(IRT(IR_FLOAD, IRT_PTR), ud, fl); +} + +static LJ_AINLINE void recff_sbufx_set_ptr(jit_State *J, TRef ud, IRFieldID fl, TRef val) +{ + TRef fref = emitir(IRT(IR_FREF, IRT_PTR), ud, fl); + emitir(IRT(IR_FSTORE, IRT_PTR), fref, val); +} + +static LJ_AINLINE TRef recff_sbufx_len(jit_State *J, TRef trr, TRef trw) +{ + TRef len = emitir(IRT(IR_SUB, IRT_INTP), trw, trr); + if (LJ_64) + len = emitir(IRTI(IR_CONV), len, (IRT_INT<<5)|IRT_INTP|IRCONV_NONE); + return len; +} + +/* Emit typecheck for string buffer. */ +static TRef recff_sbufx_check(jit_State *J, RecordFFData *rd, int arg) +{ + TRef trtype, ud = J->base[arg]; + if (!tvisbuf(&rd->argv[arg])) lj_trace_err(J, LJ_TRERR_BADTYPE); + trtype = emitir(IRT(IR_FLOAD, IRT_U8), ud, IRFL_UDATA_UDTYPE); + emitir(IRTGI(IR_EQ), trtype, lj_ir_kint(J, UDTYPE_BUFFER)); + J->needsnap = 1; + return ud; +} + +/* Emit BUFHDR for write to extended string buffer. */ +static TRef recff_sbufx_write(jit_State *J, TRef ud) +{ + TRef trbuf = emitir(IRT(IR_ADD, IRT_PGC), ud, lj_ir_kint(J, sizeof(GCudata))); + return emitir(IRT(IR_BUFHDR, IRT_PGC), trbuf, IRBUFHDR_WRITE); +} + +/* Check for integer in range for the buffer API. */ +static TRef recff_sbufx_checkint(jit_State *J, RecordFFData *rd, int arg) +{ + TRef tr = J->base[arg]; + TRef trlim = lj_ir_kint(J, LJ_MAX_BUF); + if (tref_isinteger(tr)) { + emitir(IRTGI(IR_ULE), tr, trlim); + } else if (tref_isnum(tr)) { + tr = emitir(IRTI(IR_CONV), tr, IRCONV_INT_NUM|IRCONV_ANY); + emitir(IRTGI(IR_ULE), tr, trlim); +#if LJ_HASFFI + } else if (tref_iscdata(tr)) { + tr = lj_crecord_loadiu64(J, tr, &rd->argv[arg]); + emitir(IRTG(IR_ULE, IRT_U64), tr, lj_ir_kint64(J, LJ_MAX_BUF)); + tr = emitir(IRTI(IR_CONV), tr, (IRT_INT<<5)|IRT_I64|IRCONV_NONE); +#else + UNUSED(rd); +#endif + } else { + lj_trace_err(J, LJ_TRERR_BADTYPE); + } + return tr; +} + +static void LJ_FASTCALL recff_buffer_method_reset(jit_State *J, RecordFFData *rd) +{ + TRef ud = recff_sbufx_check(J, rd, 0); + SBufExt *sbx = bufV(&rd->argv[0]); + int iscow = (int)sbufiscow(sbx); + TRef trl = recff_sbufx_get_L(J, ud); + TRef trcow = emitir(IRT(IR_BAND, IRT_IGC), trl, lj_ir_kint(J, SBUF_FLAG_COW)); + TRef zero = lj_ir_kint(J, 0); + emitir(IRTG(iscow ? IR_NE : IR_EQ, IRT_IGC), trcow, zero); + if (iscow) { + trl = emitir(IRT(IR_BXOR, IRT_IGC), trl, + LJ_GC64 ? lj_ir_kint64(J, SBUF_FLAG_COW) : + lj_ir_kint(J, SBUF_FLAG_COW)); + recff_sbufx_set_ptr(J, ud, IRFL_SBUF_W, zero); + recff_sbufx_set_ptr(J, ud, IRFL_SBUF_E, zero); + recff_sbufx_set_ptr(J, ud, IRFL_SBUF_B, zero); + recff_sbufx_set_L(J, ud, trl); + emitir(IRT(IR_FSTORE, IRT_PGC), + emitir(IRT(IR_FREF, IRT_PGC), ud, IRFL_SBUF_REF), zero); + recff_sbufx_set_ptr(J, ud, IRFL_SBUF_R, zero); + } else { + TRef trb = recff_sbufx_get_ptr(J, ud, IRFL_SBUF_B); + recff_sbufx_set_ptr(J, ud, IRFL_SBUF_W, trb); + recff_sbufx_set_ptr(J, ud, IRFL_SBUF_R, trb); + } +} + +static void LJ_FASTCALL recff_buffer_method_skip(jit_State *J, RecordFFData *rd) +{ + TRef ud = recff_sbufx_check(J, rd, 0); + TRef trr = recff_sbufx_get_ptr(J, ud, IRFL_SBUF_R); + TRef trw = recff_sbufx_get_ptr(J, ud, IRFL_SBUF_W); + TRef len = recff_sbufx_len(J, trr, trw); + TRef trn = recff_sbufx_checkint(J, rd, 1); + len = emitir(IRTI(IR_MIN), len, trn); + trr = emitir(IRT(IR_ADD, IRT_PTR), trr, len); + recff_sbufx_set_ptr(J, ud, IRFL_SBUF_R, trr); +} + +static void LJ_FASTCALL recff_buffer_method_set(jit_State *J, RecordFFData *rd) +{ + TRef ud = recff_sbufx_check(J, rd, 0); + TRef trbuf = recff_sbufx_write(J, ud); + TRef tr = J->base[1]; + if (tref_isstr(tr)) { + TRef trp = emitir(IRT(IR_STRREF, IRT_PGC), tr, lj_ir_kint(J, 0)); + TRef len = emitir(IRTI(IR_FLOAD), tr, IRFL_STR_LEN); + lj_ir_call(J, IRCALL_lj_bufx_set, trbuf, trp, len, tr); +#if LJ_HASFFI + } else if (tref_iscdata(tr)) { + TRef trp = lj_crecord_topcvoid(J, tr, &rd->argv[1]); + TRef len = recff_sbufx_checkint(J, rd, 2); + lj_ir_call(J, IRCALL_lj_bufx_set, trbuf, trp, len, tr); +#endif + } /* else: Interpreter will throw. */ +} + +static void LJ_FASTCALL recff_buffer_method_put(jit_State *J, RecordFFData *rd) +{ + TRef ud = recff_sbufx_check(J, rd, 0); + TRef trbuf = recff_sbufx_write(J, ud); + TRef tr; + ptrdiff_t arg; + if (!J->base[1]) return; + for (arg = 1; (tr = J->base[arg]); arg++) { + if (tref_isudata(tr)) { + TRef ud2 = recff_sbufx_check(J, rd, arg); + emitir(IRTG(IR_NE, IRT_PGC), ud, ud2); + } + } + for (arg = 1; (tr = J->base[arg]); arg++) { + if (tref_isstr(tr)) { + trbuf = emitir(IRTG(IR_BUFPUT, IRT_PGC), trbuf, tr); + } else if (tref_isnumber(tr)) { + trbuf = emitir(IRTG(IR_BUFPUT, IRT_PGC), trbuf, + emitir(IRT(IR_TOSTR, IRT_STR), tr, + tref_isnum(tr) ? IRTOSTR_NUM : IRTOSTR_INT)); + } else if (tref_isudata(tr)) { + TRef trr = recff_sbufx_get_ptr(J, tr, IRFL_SBUF_R); + TRef trw = recff_sbufx_get_ptr(J, tr, IRFL_SBUF_W); + TRef len = recff_sbufx_len(J, trr, trw); + trbuf = lj_ir_call(J, IRCALL_lj_buf_putmem, trbuf, trr, len); + } else { + recff_nyiu(J, rd); + } + } + emitir(IRT(IR_USE, IRT_NIL), trbuf, 0); +} + +static void LJ_FASTCALL recff_buffer_method_putf(jit_State *J, RecordFFData *rd) +{ + TRef ud = recff_sbufx_check(J, rd, 0); + TRef trbuf = recff_sbufx_write(J, ud); + recff_format(J, rd, trbuf, 1); +} + +static void LJ_FASTCALL recff_buffer_method_get(jit_State *J, RecordFFData *rd) +{ + TRef ud = recff_sbufx_check(J, rd, 0); + TRef trr = recff_sbufx_get_ptr(J, ud, IRFL_SBUF_R); + TRef trw = recff_sbufx_get_ptr(J, ud, IRFL_SBUF_W); + TRef tr; + ptrdiff_t arg; + if (!J->base[1]) { J->base[1] = TREF_NIL; J->base[2] = 0; } + for (arg = 0; (tr = J->base[arg+1]); arg++) { + if (!tref_isnil(tr)) { + J->base[arg+1] = recff_sbufx_checkint(J, rd, arg+1); + } + } + for (arg = 0; (tr = J->base[arg+1]); arg++) { + TRef len = recff_sbufx_len(J, trr, trw); + if (tref_isnil(tr)) { + J->base[arg] = emitir(IRT(IR_XSNEW, IRT_STR), trr, len); + trr = trw; + } else { + TRef tru; + len = emitir(IRTI(IR_MIN), len, tr); + tru = emitir(IRT(IR_ADD, IRT_PTR), trr, len); + J->base[arg] = emitir(IRT(IR_XSNEW, IRT_STR), trr, len); + trr = tru; /* Doing the ADD before the SNEW generates better code. */ + } + recff_sbufx_set_ptr(J, ud, IRFL_SBUF_R, trr); + } + rd->nres = arg; +} + +static void LJ_FASTCALL recff_buffer_method___tostring(jit_State *J, RecordFFData *rd) +{ + TRef ud = recff_sbufx_check(J, rd, 0); + TRef trr = recff_sbufx_get_ptr(J, ud, IRFL_SBUF_R); + TRef trw = recff_sbufx_get_ptr(J, ud, IRFL_SBUF_W); + J->base[0] = emitir(IRT(IR_XSNEW, IRT_STR), trr, recff_sbufx_len(J, trr, trw)); +} + +static void LJ_FASTCALL recff_buffer_method___len(jit_State *J, RecordFFData *rd) +{ + TRef ud = recff_sbufx_check(J, rd, 0); + TRef trr = recff_sbufx_get_ptr(J, ud, IRFL_SBUF_R); + TRef trw = recff_sbufx_get_ptr(J, ud, IRFL_SBUF_W); + J->base[0] = recff_sbufx_len(J, trr, trw); +} + +#if LJ_HASFFI +static void LJ_FASTCALL recff_buffer_method_putcdata(jit_State *J, RecordFFData *rd) +{ + TRef ud = recff_sbufx_check(J, rd, 0); + TRef trbuf = recff_sbufx_write(J, ud); + TRef tr = lj_crecord_topcvoid(J, J->base[1], &rd->argv[1]); + TRef len = recff_sbufx_checkint(J, rd, 2); + trbuf = lj_ir_call(J, IRCALL_lj_buf_putmem, trbuf, tr, len); + emitir(IRT(IR_USE, IRT_NIL), trbuf, 0); +} + +static void LJ_FASTCALL recff_buffer_method_reserve(jit_State *J, RecordFFData *rd) +{ + TRef ud = recff_sbufx_check(J, rd, 0); + TRef trbuf = recff_sbufx_write(J, ud); + TRef trsz = recff_sbufx_checkint(J, rd, 1); + J->base[1] = lj_ir_call(J, IRCALL_lj_bufx_more, trbuf, trsz); + J->base[0] = lj_crecord_topuint8(J, recff_sbufx_get_ptr(J, ud, IRFL_SBUF_W)); + rd->nres = 2; +} + +static void LJ_FASTCALL recff_buffer_method_commit(jit_State *J, RecordFFData *rd) +{ + TRef ud = recff_sbufx_check(J, rd, 0); + TRef len = recff_sbufx_checkint(J, rd, 1); + TRef trw = recff_sbufx_get_ptr(J, ud, IRFL_SBUF_W); + TRef tre = recff_sbufx_get_ptr(J, ud, IRFL_SBUF_E); + TRef left = emitir(IRT(IR_SUB, IRT_INTP), tre, trw); + if (LJ_64) + left = emitir(IRTI(IR_CONV), left, (IRT_INT<<5)|IRT_INTP|IRCONV_NONE); + emitir(IRTGI(IR_ULE), len, left); + trw = emitir(IRT(IR_ADD, IRT_PTR), trw, len); + recff_sbufx_set_ptr(J, ud, IRFL_SBUF_W, trw); +} + +static void LJ_FASTCALL recff_buffer_method_ref(jit_State *J, RecordFFData *rd) +{ + TRef ud = recff_sbufx_check(J, rd, 0); + TRef trr = recff_sbufx_get_ptr(J, ud, IRFL_SBUF_R); + TRef trw = recff_sbufx_get_ptr(J, ud, IRFL_SBUF_W); + J->base[0] = lj_crecord_topuint8(J, trr); + J->base[1] = recff_sbufx_len(J, trr, trw); + rd->nres = 2; +} +#endif + +static void LJ_FASTCALL recff_buffer_method_encode(jit_State *J, RecordFFData *rd) +{ + TRef ud = recff_sbufx_check(J, rd, 0); + TRef trbuf = recff_sbufx_write(J, ud); + TRef tmp = recff_tmpref(J, J->base[1], IRTMPREF_IN1); + lj_ir_call(J, IRCALL_lj_serialize_put, trbuf, tmp); + /* No IR_USE needed, since the call is a store. */ +} + +static void LJ_FASTCALL recff_buffer_method_decode(jit_State *J, RecordFFData *rd) +{ + TRef ud = recff_sbufx_check(J, rd, 0); + TRef trbuf = recff_sbufx_write(J, ud); + TRef tmp = recff_tmpref(J, TREF_NIL, IRTMPREF_OUT1); + TRef trr = lj_ir_call(J, IRCALL_lj_serialize_get, trbuf, tmp); + IRType t = (IRType)lj_serialize_peektype(bufV(&rd->argv[0])); + /* No IR_USE needed, since the call is a store. */ + J->base[0] = lj_record_vload(J, tmp, 0, t); + /* The sbx->r store must be after the VLOAD type check, in case it fails. */ + recff_sbufx_set_ptr(J, ud, IRFL_SBUF_R, trr); +} + +static void LJ_FASTCALL recff_buffer_encode(jit_State *J, RecordFFData *rd) +{ + TRef tmp = recff_tmpref(J, J->base[0], IRTMPREF_IN1); + J->base[0] = lj_ir_call(J, IRCALL_lj_serialize_encode, tmp); + /* IR_USE needed for IR_CALLA, because the encoder may throw non-OOM. */ + emitir(IRT(IR_USE, IRT_NIL), J->base[0], 0); + UNUSED(rd); +} + +static void LJ_FASTCALL recff_buffer_decode(jit_State *J, RecordFFData *rd) +{ + if (tvisstr(&rd->argv[0])) { + GCstr *str = strV(&rd->argv[0]); + SBufExt sbx; + IRType t; + TRef tmp = recff_tmpref(J, TREF_NIL, IRTMPREF_OUT1); + TRef tr = lj_ir_call(J, IRCALL_lj_serialize_decode, tmp, J->base[0]); + /* IR_USE needed for IR_CALLA, because the decoder may throw non-OOM. + ** That's why IRCALL_lj_serialize_decode needs a fake INT result. + */ + emitir(IRT(IR_USE, IRT_NIL), tr, 0); + memset(&sbx, 0, sizeof(SBufExt)); + lj_bufx_set_cow(J->L, &sbx, strdata(str), str->len); + t = (IRType)lj_serialize_peektype(&sbx); + J->base[0] = lj_record_vload(J, tmp, 0, t); + } /* else: Interpreter will throw. */ +} + +#endif + +/* -- Table library fast functions ---------------------------------------- */ + +static void LJ_FASTCALL recff_table_insert(jit_State *J, RecordFFData *rd) +{ + RecordIndex ix; + ix.tab = J->base[0]; + ix.val = J->base[1]; + rd->nres = 0; + if (tref_istab(ix.tab) && ix.val) { + if (!J->base[2]) { /* Simple push: t[#t+1] = v */ + TRef trlen = emitir(IRTI(IR_ALEN), ix.tab, TREF_NIL); + GCtab *t = tabV(&rd->argv[0]); + ix.key = emitir(IRTI(IR_ADD), trlen, lj_ir_kint(J, 1)); + settabV(J->L, &ix.tabv, t); + setintV(&ix.keyv, lj_tab_len(t) + 1); + ix.idxchain = 0; + lj_record_idx(J, &ix); /* Set new value. */ + } else { /* Complex case: insert in the middle. */ + recff_nyiu(J, rd); + return; + } + } /* else: Interpreter will throw. */ +} + +static void LJ_FASTCALL recff_table_concat(jit_State *J, RecordFFData *rd) +{ + TRef tab = J->base[0]; + if (tref_istab(tab)) { + TRef sep = !tref_isnil(J->base[1]) ? + lj_ir_tostr(J, J->base[1]) : lj_ir_knull(J, IRT_STR); + TRef tri = (J->base[1] && !tref_isnil(J->base[2])) ? + lj_opt_narrow_toint(J, J->base[2]) : lj_ir_kint(J, 1); + TRef tre = (J->base[1] && J->base[2] && !tref_isnil(J->base[3])) ? + lj_opt_narrow_toint(J, J->base[3]) : + emitir(IRTI(IR_ALEN), tab, TREF_NIL); + TRef hdr = recff_bufhdr(J); + TRef tr = lj_ir_call(J, IRCALL_lj_buf_puttab, hdr, tab, sep, tri, tre); + emitir(IRTG(IR_NE, IRT_PTR), tr, lj_ir_kptr(J, NULL)); + J->base[0] = emitir(IRTG(IR_BUFSTR, IRT_STR), tr, hdr); + } /* else: Interpreter will throw. */ + UNUSED(rd); +} + +static void LJ_FASTCALL recff_table_new(jit_State *J, RecordFFData *rd) +{ + TRef tra = lj_opt_narrow_toint(J, J->base[0]); + TRef trh = lj_opt_narrow_toint(J, J->base[1]); + J->base[0] = lj_ir_call(J, IRCALL_lj_tab_new_ah, tra, trh); + UNUSED(rd); +} + +static void LJ_FASTCALL recff_table_clear(jit_State *J, RecordFFData *rd) +{ + TRef tr = J->base[0]; + if (tref_istab(tr)) { + rd->nres = 0; + lj_ir_call(J, IRCALL_lj_tab_clear, tr); + J->needsnap = 1; + } /* else: Interpreter will throw. */ +} + +/* -- I/O library fast functions ------------------------------------------ */ + +/* Get FILE* for I/O function. Any I/O error aborts recording, so there's +** no need to encode the alternate cases for any of the guards. +*/ +static TRef recff_io_fp(jit_State *J, TRef *udp, int32_t id) +{ + TRef tr, ud, fp; + if (id) { /* io.func() */ + ud = lj_ir_ggfload(J, IRT_UDATA, GG_OFS(g.gcroot[id])); + } else { /* fp:method() */ + ud = J->base[0]; + if (!tref_isudata(ud)) + lj_trace_err(J, LJ_TRERR_BADTYPE); + tr = emitir(IRT(IR_FLOAD, IRT_U8), ud, IRFL_UDATA_UDTYPE); + emitir(IRTGI(IR_EQ), tr, lj_ir_kint(J, UDTYPE_IO_FILE)); + } + *udp = ud; + fp = emitir(IRT(IR_FLOAD, IRT_PTR), ud, IRFL_UDATA_FILE); + emitir(IRTG(IR_NE, IRT_PTR), fp, lj_ir_knull(J, IRT_PTR)); + return fp; +} + +static void LJ_FASTCALL recff_io_write(jit_State *J, RecordFFData *rd) +{ + TRef ud, fp = recff_io_fp(J, &ud, rd->data); + TRef zero = lj_ir_kint(J, 0); + TRef one = lj_ir_kint(J, 1); + ptrdiff_t i = rd->data == 0 ? 1 : 0; + for (; J->base[i]; i++) { + TRef str = lj_ir_tostr(J, J->base[i]); + TRef buf = emitir(IRT(IR_STRREF, IRT_PGC), str, zero); + TRef len = emitir(IRTI(IR_FLOAD), str, IRFL_STR_LEN); + if (tref_isk(len) && IR(tref_ref(len))->i == 1) { + IRIns *irs = IR(tref_ref(str)); + TRef tr = (irs->o == IR_TOSTR && irs->op2 == IRTOSTR_CHAR) ? + irs->op1 : + emitir(IRT(IR_XLOAD, IRT_U8), buf, IRXLOAD_READONLY); + tr = lj_ir_call(J, IRCALL_fputc, tr, fp); + if (results_wanted(J) != 0) /* Check result only if not ignored. */ + emitir(IRTGI(IR_NE), tr, lj_ir_kint(J, -1)); + } else { + TRef tr = lj_ir_call(J, IRCALL_fwrite, buf, one, len, fp); + if (results_wanted(J) != 0) /* Check result only if not ignored. */ + emitir(IRTGI(IR_EQ), tr, len); + } + } + J->base[0] = LJ_52 ? ud : TREF_TRUE; +} + +static void LJ_FASTCALL recff_io_flush(jit_State *J, RecordFFData *rd) +{ + TRef ud, fp = recff_io_fp(J, &ud, rd->data); + TRef tr = lj_ir_call(J, IRCALL_fflush, fp); + if (results_wanted(J) != 0) /* Check result only if not ignored. */ + emitir(IRTGI(IR_EQ), tr, lj_ir_kint(J, 0)); + J->base[0] = TREF_TRUE; +} + +/* -- Debug library fast functions ---------------------------------------- */ + +static void LJ_FASTCALL recff_debug_getmetatable(jit_State *J, RecordFFData *rd) +{ + GCtab *mt; + TRef mtref; + TRef tr = J->base[0]; + if (tref_istab(tr)) { + mt = tabref(tabV(&rd->argv[0])->metatable); + mtref = emitir(IRT(IR_FLOAD, IRT_TAB), tr, IRFL_TAB_META); + } else if (tref_isudata(tr)) { + mt = tabref(udataV(&rd->argv[0])->metatable); + mtref = emitir(IRT(IR_FLOAD, IRT_TAB), tr, IRFL_UDATA_META); + } else { + mt = tabref(basemt_obj(J2G(J), &rd->argv[0])); + J->base[0] = mt ? lj_ir_ktab(J, mt) : TREF_NIL; + return; + } + emitir(IRTG(mt ? IR_NE : IR_EQ, IRT_TAB), mtref, lj_ir_knull(J, IRT_TAB)); + J->base[0] = mt ? mtref : TREF_NIL; +} + +/* -- Record calls to fast functions -------------------------------------- */ + +#include "lj_recdef.h" + +static uint32_t recdef_lookup(GCfunc *fn) +{ + if (fn->c.ffid < sizeof(recff_idmap)/sizeof(recff_idmap[0])) + return recff_idmap[fn->c.ffid]; + else + return 0; +} + +/* Record entry to a fast function or C function. */ +void lj_ffrecord_func(jit_State *J) +{ + RecordFFData rd; + uint32_t m = recdef_lookup(J->fn); + rd.data = m & 0xff; + rd.nres = 1; /* Default is one result. */ + rd.argv = J->L->base; + J->base[J->maxslot] = 0; /* Mark end of arguments. */ + (recff_func[m >> 8])(J, &rd); /* Call recff_* handler. */ + if (rd.nres >= 0) { + if (J->postproc == LJ_POST_NONE) J->postproc = LJ_POST_FFRETRY; + lj_record_ret(J, 0, rd.nres); + } +} + +#undef IR +#undef emitir + +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_ffrecord.h b/fluent-bit/lib/luajit-3065c9/src/lj_ffrecord.h new file mode 100644 index 00000000..0acb8ed5 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_ffrecord.h @@ -0,0 +1,24 @@ +/* +** Fast function call recorder. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#ifndef _LJ_FFRECORD_H +#define _LJ_FFRECORD_H + +#include "lj_obj.h" +#include "lj_jit.h" + +#if LJ_HASJIT +/* Data used by handlers to record a fast function. */ +typedef struct RecordFFData { + TValue *argv; /* Runtime argument values. */ + ptrdiff_t nres; /* Number of returned results (defaults to 1). */ + uint32_t data; /* Per-ffid auxiliary data (opcode, literal etc.). */ +} RecordFFData; + +LJ_FUNC int32_t lj_ffrecord_select_mode(jit_State *J, TRef tr, TValue *tv); +LJ_FUNC void lj_ffrecord_func(jit_State *J); +#endif + +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_frame.h b/fluent-bit/lib/luajit-3065c9/src/lj_frame.h new file mode 100644 index 00000000..aa1dc11a --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_frame.h @@ -0,0 +1,297 @@ +/* +** Stack frames. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#ifndef _LJ_FRAME_H +#define _LJ_FRAME_H + +#include "lj_obj.h" +#include "lj_bc.h" + +/* -- Lua stack frame ----------------------------------------------------- */ + +/* Frame type markers in LSB of PC (4-byte aligned) or delta (8-byte aligned: +** +** PC 00 Lua frame +** delta 001 C frame +** delta 010 Continuation frame +** delta 011 Lua vararg frame +** delta 101 cpcall() frame +** delta 110 ff pcall() frame +** delta 111 ff pcall() frame with active hook +*/ +enum { + FRAME_LUA, FRAME_C, FRAME_CONT, FRAME_VARG, + FRAME_LUAP, FRAME_CP, FRAME_PCALL, FRAME_PCALLH +}; +#define FRAME_TYPE 3 +#define FRAME_P 4 +#define FRAME_TYPEP (FRAME_TYPE|FRAME_P) + +/* Macros to access and modify Lua frames. */ +#if LJ_FR2 +/* Two-slot frame info, required for 64 bit PC/GCRef: +** +** base-2 base-1 | base base+1 ... +** [func PC/delta/ft] | [slots ...] +** ^-- frame | ^-- base ^-- top +** +** Continuation frames: +** +** base-4 base-3 base-2 base-1 | base base+1 ... +** [cont PC ] [func PC/delta/ft] | [slots ...] +** ^-- frame | ^-- base ^-- top +*/ +#define frame_gc(f) (gcval((f)-1)) +#define frame_ftsz(f) ((ptrdiff_t)(f)->ftsz) +#define frame_pc(f) ((const BCIns *)frame_ftsz(f)) +#define setframe_gc(f, p, tp) (setgcVraw((f), (p), (tp))) +#define setframe_ftsz(f, sz) ((f)->ftsz = (sz)) +#define setframe_pc(f, pc) ((f)->ftsz = (int64_t)(intptr_t)(pc)) +#else +/* One-slot frame info, sufficient for 32 bit PC/GCRef: +** +** base-1 | base base+1 ... +** lo hi | +** [func | PC/delta/ft] | [slots ...] +** ^-- frame | ^-- base ^-- top +** +** Continuation frames: +** +** base-2 base-1 | base base+1 ... +** lo hi lo hi | +** [cont | PC] [func | PC/delta/ft] | [slots ...] +** ^-- frame | ^-- base ^-- top +*/ +#define frame_gc(f) (gcref((f)->fr.func)) +#define frame_ftsz(f) ((ptrdiff_t)(f)->fr.tp.ftsz) +#define frame_pc(f) (mref((f)->fr.tp.pcr, const BCIns)) +#define setframe_gc(f, p, tp) (setgcref((f)->fr.func, (p)), UNUSED(tp)) +#define setframe_ftsz(f, sz) ((f)->fr.tp.ftsz = (int32_t)(sz)) +#define setframe_pc(f, pc) (setmref((f)->fr.tp.pcr, (pc))) +#endif + +#define frame_type(f) (frame_ftsz(f) & FRAME_TYPE) +#define frame_typep(f) (frame_ftsz(f) & FRAME_TYPEP) +#define frame_islua(f) (frame_type(f) == FRAME_LUA) +#define frame_isc(f) (frame_type(f) == FRAME_C) +#define frame_iscont(f) (frame_typep(f) == FRAME_CONT) +#define frame_isvarg(f) (frame_typep(f) == FRAME_VARG) +#define frame_ispcall(f) ((frame_ftsz(f) & 6) == FRAME_PCALL) + +#define frame_func(f) (&frame_gc(f)->fn) +#define frame_delta(f) (frame_ftsz(f) >> 3) +#define frame_sized(f) (frame_ftsz(f) & ~FRAME_TYPEP) + +enum { LJ_CONT_TAILCALL, LJ_CONT_FFI_CALLBACK }; /* Special continuations. */ + +#if LJ_FR2 +#define frame_contpc(f) (frame_pc((f)-2)) +#define frame_contv(f) (((f)-3)->u64) +#else +#define frame_contpc(f) (frame_pc((f)-1)) +#define frame_contv(f) (((f)-1)->u32.lo) +#endif +#if LJ_FR2 +#define frame_contf(f) ((ASMFunction)(uintptr_t)((f)-3)->u64) +#elif LJ_64 +#define frame_contf(f) \ + ((ASMFunction)(void *)((intptr_t)lj_vm_asm_begin + \ + (intptr_t)(int32_t)((f)-1)->u32.lo)) +#else +#define frame_contf(f) ((ASMFunction)gcrefp(((f)-1)->gcr, void)) +#endif +#define frame_iscont_fficb(f) \ + (LJ_HASFFI && frame_contv(f) == LJ_CONT_FFI_CALLBACK) + +#define frame_prevl(f) ((f) - (1+LJ_FR2+bc_a(frame_pc(f)[-1]))) +#define frame_prevd(f) ((TValue *)((char *)(f) - frame_sized(f))) +#define frame_prev(f) (frame_islua(f)?frame_prevl(f):frame_prevd(f)) +/* Note: this macro does not skip over FRAME_VARG. */ + +/* -- C stack frame ------------------------------------------------------- */ + +/* Macros to access and modify the C stack frame chain. */ + +/* These definitions must match with the arch-specific *.dasc files. */ +#if LJ_TARGET_X86 +#if LJ_ABI_WIN +#define CFRAME_OFS_ERRF (19*4) +#define CFRAME_OFS_NRES (18*4) +#define CFRAME_OFS_PREV (17*4) +#define CFRAME_OFS_L (16*4) +#define CFRAME_OFS_SEH (9*4) +#define CFRAME_OFS_PC (6*4) +#define CFRAME_OFS_MULTRES (5*4) +#define CFRAME_SIZE (16*4) +#define CFRAME_SHIFT_MULTRES 0 +#else +#define CFRAME_OFS_ERRF (15*4) +#define CFRAME_OFS_NRES (14*4) +#define CFRAME_OFS_PREV (13*4) +#define CFRAME_OFS_L (12*4) +#define CFRAME_OFS_PC (6*4) +#define CFRAME_OFS_MULTRES (5*4) +#define CFRAME_SIZE (12*4) +#define CFRAME_SHIFT_MULTRES 0 +#endif +#elif LJ_TARGET_X64 +#if LJ_ABI_WIN +#define CFRAME_OFS_PREV (13*8) +#if LJ_GC64 +#define CFRAME_OFS_PC (12*8) +#define CFRAME_OFS_L (11*8) +#define CFRAME_OFS_ERRF (21*4) +#define CFRAME_OFS_NRES (20*4) +#define CFRAME_OFS_MULTRES (8*4) +#else +#define CFRAME_OFS_PC (25*4) +#define CFRAME_OFS_L (24*4) +#define CFRAME_OFS_ERRF (23*4) +#define CFRAME_OFS_NRES (22*4) +#define CFRAME_OFS_MULTRES (21*4) +#endif +#define CFRAME_SIZE (10*8) +#define CFRAME_SIZE_JIT (CFRAME_SIZE + 9*16 + 4*8) +#define CFRAME_SHIFT_MULTRES 0 +#else +#define CFRAME_OFS_PREV (4*8) +#if LJ_GC64 +#define CFRAME_OFS_PC (3*8) +#define CFRAME_OFS_L (2*8) +#define CFRAME_OFS_ERRF (3*4) +#define CFRAME_OFS_NRES (2*4) +#define CFRAME_OFS_MULTRES (0*4) +#else +#define CFRAME_OFS_PC (7*4) +#define CFRAME_OFS_L (6*4) +#define CFRAME_OFS_ERRF (5*4) +#define CFRAME_OFS_NRES (4*4) +#define CFRAME_OFS_MULTRES (1*4) +#endif +#if LJ_NO_UNWIND +#define CFRAME_SIZE (12*8) +#else +#define CFRAME_SIZE (10*8) +#endif +#define CFRAME_SIZE_JIT (CFRAME_SIZE + 16) +#define CFRAME_SHIFT_MULTRES 0 +#endif +#elif LJ_TARGET_ARM +#define CFRAME_OFS_ERRF 24 +#define CFRAME_OFS_NRES 20 +#define CFRAME_OFS_PREV 16 +#define CFRAME_OFS_L 12 +#define CFRAME_OFS_PC 8 +#define CFRAME_OFS_MULTRES 4 +#if LJ_ARCH_HASFPU +#define CFRAME_SIZE 128 +#else +#define CFRAME_SIZE 64 +#endif +#define CFRAME_SHIFT_MULTRES 3 +#elif LJ_TARGET_ARM64 +#define CFRAME_OFS_ERRF 36 +#define CFRAME_OFS_NRES 40 +#define CFRAME_OFS_PREV 0 +#define CFRAME_OFS_L 16 +#define CFRAME_OFS_PC 8 +#define CFRAME_OFS_MULTRES 32 +#define CFRAME_SIZE 208 +#define CFRAME_SHIFT_MULTRES 3 +#elif LJ_TARGET_PPC +#if LJ_TARGET_XBOX360 +#define CFRAME_OFS_ERRF 424 +#define CFRAME_OFS_NRES 420 +#define CFRAME_OFS_PREV 400 +#define CFRAME_OFS_L 416 +#define CFRAME_OFS_PC 412 +#define CFRAME_OFS_MULTRES 408 +#define CFRAME_SIZE 384 +#define CFRAME_SHIFT_MULTRES 3 +#elif LJ_ARCH_PPC32ON64 +#define CFRAME_OFS_ERRF 472 +#define CFRAME_OFS_NRES 468 +#define CFRAME_OFS_PREV 448 +#define CFRAME_OFS_L 464 +#define CFRAME_OFS_PC 460 +#define CFRAME_OFS_MULTRES 456 +#define CFRAME_SIZE 400 +#define CFRAME_SHIFT_MULTRES 3 +#else +#define CFRAME_OFS_ERRF 48 +#define CFRAME_OFS_NRES 44 +#define CFRAME_OFS_PREV 40 +#define CFRAME_OFS_L 36 +#define CFRAME_OFS_PC 32 +#define CFRAME_OFS_MULTRES 28 +#define CFRAME_SIZE (LJ_ARCH_HASFPU ? 272 : 128) +#define CFRAME_SHIFT_MULTRES 3 +#endif +#elif LJ_TARGET_MIPS32 +#if LJ_ARCH_HASFPU +#define CFRAME_OFS_ERRF 124 +#define CFRAME_OFS_NRES 120 +#define CFRAME_OFS_PREV 116 +#define CFRAME_OFS_L 112 +#define CFRAME_SIZE 112 +#else +#define CFRAME_OFS_ERRF 76 +#define CFRAME_OFS_NRES 72 +#define CFRAME_OFS_PREV 68 +#define CFRAME_OFS_L 64 +#define CFRAME_SIZE 64 +#endif +#define CFRAME_OFS_PC 20 +#define CFRAME_OFS_MULTRES 16 +#define CFRAME_SHIFT_MULTRES 3 +#elif LJ_TARGET_MIPS64 +#if LJ_ARCH_HASFPU +#define CFRAME_OFS_ERRF 188 +#define CFRAME_OFS_NRES 184 +#define CFRAME_OFS_PREV 176 +#define CFRAME_OFS_L 168 +#define CFRAME_OFS_PC 160 +#define CFRAME_SIZE 192 +#else +#define CFRAME_OFS_ERRF 124 +#define CFRAME_OFS_NRES 120 +#define CFRAME_OFS_PREV 112 +#define CFRAME_OFS_L 104 +#define CFRAME_OFS_PC 96 +#define CFRAME_SIZE 128 +#endif +#define CFRAME_OFS_MULTRES 0 +#define CFRAME_SHIFT_MULTRES 3 +#else +#error "Missing CFRAME_* definitions for this architecture" +#endif + +#ifndef CFRAME_SIZE_JIT +#define CFRAME_SIZE_JIT CFRAME_SIZE +#endif + +#define CFRAME_RESUME 1 +#define CFRAME_UNWIND_FF 2 /* Only used in unwinder. */ +#define CFRAME_RAWMASK (~(intptr_t)(CFRAME_RESUME|CFRAME_UNWIND_FF)) + +#define cframe_errfunc(cf) (*(int32_t *)(((char *)(cf))+CFRAME_OFS_ERRF)) +#define cframe_nres(cf) (*(int32_t *)(((char *)(cf))+CFRAME_OFS_NRES)) +#define cframe_prev(cf) (*(void **)(((char *)(cf))+CFRAME_OFS_PREV)) +#define cframe_multres(cf) (*(uint32_t *)(((char *)(cf))+CFRAME_OFS_MULTRES)) +#define cframe_multres_n(cf) (cframe_multres((cf)) >> CFRAME_SHIFT_MULTRES) +#define cframe_L(cf) \ + (&gcref(*(GCRef *)(((char *)(cf))+CFRAME_OFS_L))->th) +#define cframe_pc(cf) \ + (mref(*(MRef *)(((char *)(cf))+CFRAME_OFS_PC), const BCIns)) +#define setcframe_L(cf, L) \ + (setmref(*(MRef *)(((char *)(cf))+CFRAME_OFS_L), (L))) +#define setcframe_pc(cf, pc) \ + (setmref(*(MRef *)(((char *)(cf))+CFRAME_OFS_PC), (pc))) +#define cframe_canyield(cf) ((intptr_t)(cf) & CFRAME_RESUME) +#define cframe_unwind_ff(cf) ((intptr_t)(cf) & CFRAME_UNWIND_FF) +#define cframe_raw(cf) ((void *)((intptr_t)(cf) & CFRAME_RAWMASK)) +#define cframe_Lpc(L) cframe_pc(cframe_raw(L->cframe)) + +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_func.c b/fluent-bit/lib/luajit-3065c9/src/lj_func.c new file mode 100644 index 00000000..9795a771 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_func.c @@ -0,0 +1,191 @@ +/* +** Function handling (prototypes, functions and upvalues). +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +** +** Portions taken verbatim or adapted from the Lua interpreter. +** Copyright (C) 1994-2008 Lua.org, PUC-Rio. See Copyright Notice in lua.h +*/ + +#define lj_func_c +#define LUA_CORE + +#include "lj_obj.h" +#include "lj_gc.h" +#include "lj_func.h" +#include "lj_trace.h" +#include "lj_vm.h" + +/* -- Prototypes ---------------------------------------------------------- */ + +void LJ_FASTCALL lj_func_freeproto(global_State *g, GCproto *pt) +{ + lj_mem_free(g, pt, pt->sizept); +} + +/* -- Upvalues ------------------------------------------------------------ */ + +static void unlinkuv(global_State *g, GCupval *uv) +{ + UNUSED(g); + lj_assertG(uvprev(uvnext(uv)) == uv && uvnext(uvprev(uv)) == uv, + "broken upvalue chain"); + setgcrefr(uvnext(uv)->prev, uv->prev); + setgcrefr(uvprev(uv)->next, uv->next); +} + +/* Find existing open upvalue for a stack slot or create a new one. */ +static GCupval *func_finduv(lua_State *L, TValue *slot) +{ + global_State *g = G(L); + GCRef *pp = &L->openupval; + GCupval *p; + GCupval *uv; + /* Search the sorted list of open upvalues. */ + while (gcref(*pp) != NULL && uvval((p = gco2uv(gcref(*pp)))) >= slot) { + lj_assertG(!p->closed && uvval(p) != &p->tv, "closed upvalue in chain"); + if (uvval(p) == slot) { /* Found open upvalue pointing to same slot? */ + if (isdead(g, obj2gco(p))) /* Resurrect it, if it's dead. */ + flipwhite(obj2gco(p)); + return p; + } + pp = &p->nextgc; + } + /* No matching upvalue found. Create a new one. */ + uv = lj_mem_newt(L, sizeof(GCupval), GCupval); + newwhite(g, uv); + uv->gct = ~LJ_TUPVAL; + uv->closed = 0; /* Still open. */ + setmref(uv->v, slot); /* Pointing to the stack slot. */ + /* NOBARRIER: The GCupval is new (marked white) and open. */ + setgcrefr(uv->nextgc, *pp); /* Insert into sorted list of open upvalues. */ + setgcref(*pp, obj2gco(uv)); + setgcref(uv->prev, obj2gco(&g->uvhead)); /* Insert into GC list, too. */ + setgcrefr(uv->next, g->uvhead.next); + setgcref(uvnext(uv)->prev, obj2gco(uv)); + setgcref(g->uvhead.next, obj2gco(uv)); + lj_assertG(uvprev(uvnext(uv)) == uv && uvnext(uvprev(uv)) == uv, + "broken upvalue chain"); + return uv; +} + +/* Create an empty and closed upvalue. */ +static GCupval *func_emptyuv(lua_State *L) +{ + GCupval *uv = (GCupval *)lj_mem_newgco(L, sizeof(GCupval)); + uv->gct = ~LJ_TUPVAL; + uv->closed = 1; + setnilV(&uv->tv); + setmref(uv->v, &uv->tv); + return uv; +} + +/* Close all open upvalues pointing to some stack level or above. */ +void LJ_FASTCALL lj_func_closeuv(lua_State *L, TValue *level) +{ + GCupval *uv; + global_State *g = G(L); + while (gcref(L->openupval) != NULL && + uvval((uv = gco2uv(gcref(L->openupval)))) >= level) { + GCobj *o = obj2gco(uv); + lj_assertG(!isblack(o), "bad black upvalue"); + lj_assertG(!uv->closed && uvval(uv) != &uv->tv, "closed upvalue in chain"); + setgcrefr(L->openupval, uv->nextgc); /* No longer in open list. */ + if (isdead(g, o)) { + lj_func_freeuv(g, uv); + } else { + unlinkuv(g, uv); + lj_gc_closeuv(g, uv); + } + } +} + +void LJ_FASTCALL lj_func_freeuv(global_State *g, GCupval *uv) +{ + if (!uv->closed) + unlinkuv(g, uv); + lj_mem_freet(g, uv); +} + +/* -- Functions (closures) ------------------------------------------------ */ + +GCfunc *lj_func_newC(lua_State *L, MSize nelems, GCtab *env) +{ + GCfunc *fn = (GCfunc *)lj_mem_newgco(L, sizeCfunc(nelems)); + fn->c.gct = ~LJ_TFUNC; + fn->c.ffid = FF_C; + fn->c.nupvalues = (uint8_t)nelems; + /* NOBARRIER: The GCfunc is new (marked white). */ + setmref(fn->c.pc, &G(L)->bc_cfunc_ext); + setgcref(fn->c.env, obj2gco(env)); + return fn; +} + +static GCfunc *func_newL(lua_State *L, GCproto *pt, GCtab *env) +{ + uint32_t count; + GCfunc *fn = (GCfunc *)lj_mem_newgco(L, sizeLfunc((MSize)pt->sizeuv)); + fn->l.gct = ~LJ_TFUNC; + fn->l.ffid = FF_LUA; + fn->l.nupvalues = 0; /* Set to zero until upvalues are initialized. */ + /* NOBARRIER: Really a setgcref. But the GCfunc is new (marked white). */ + setmref(fn->l.pc, proto_bc(pt)); + setgcref(fn->l.env, obj2gco(env)); + /* Saturating 3 bit counter (0..7) for created closures. */ + count = (uint32_t)pt->flags + PROTO_CLCOUNT; + pt->flags = (uint8_t)(count - ((count >> PROTO_CLC_BITS) & PROTO_CLCOUNT)); + return fn; +} + +/* Create a new Lua function with empty upvalues. */ +GCfunc *lj_func_newL_empty(lua_State *L, GCproto *pt, GCtab *env) +{ + GCfunc *fn = func_newL(L, pt, env); + MSize i, nuv = pt->sizeuv; + /* NOBARRIER: The GCfunc is new (marked white). */ + for (i = 0; i < nuv; i++) { + GCupval *uv = func_emptyuv(L); + int32_t v = proto_uv(pt)[i]; + uv->immutable = ((v / PROTO_UV_IMMUTABLE) & 1); + uv->dhash = (uint32_t)(uintptr_t)pt ^ (v << 24); + setgcref(fn->l.uvptr[i], obj2gco(uv)); + } + fn->l.nupvalues = (uint8_t)nuv; + return fn; +} + +/* Do a GC check and create a new Lua function with inherited upvalues. */ +GCfunc *lj_func_newL_gc(lua_State *L, GCproto *pt, GCfuncL *parent) +{ + GCfunc *fn; + GCRef *puv; + MSize i, nuv; + TValue *base; + lj_gc_check_fixtop(L); + fn = func_newL(L, pt, tabref(parent->env)); + /* NOBARRIER: The GCfunc is new (marked white). */ + puv = parent->uvptr; + nuv = pt->sizeuv; + base = L->base; + for (i = 0; i < nuv; i++) { + uint32_t v = proto_uv(pt)[i]; + GCupval *uv; + if ((v & PROTO_UV_LOCAL)) { + uv = func_finduv(L, base + (v & 0xff)); + uv->immutable = ((v / PROTO_UV_IMMUTABLE) & 1); + uv->dhash = (uint32_t)(uintptr_t)mref(parent->pc, char) ^ (v << 24); + } else { + uv = &gcref(puv[v])->uv; + } + setgcref(fn->l.uvptr[i], obj2gco(uv)); + } + fn->l.nupvalues = (uint8_t)nuv; + return fn; +} + +void LJ_FASTCALL lj_func_free(global_State *g, GCfunc *fn) +{ + MSize size = isluafunc(fn) ? sizeLfunc((MSize)fn->l.nupvalues) : + sizeCfunc((MSize)fn->c.nupvalues); + lj_mem_free(g, fn, size); +} + diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_func.h b/fluent-bit/lib/luajit-3065c9/src/lj_func.h new file mode 100644 index 00000000..44df4deb --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_func.h @@ -0,0 +1,24 @@ +/* +** Function handling (prototypes, functions and upvalues). +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#ifndef _LJ_FUNC_H +#define _LJ_FUNC_H + +#include "lj_obj.h" + +/* Prototypes. */ +LJ_FUNC void LJ_FASTCALL lj_func_freeproto(global_State *g, GCproto *pt); + +/* Upvalues. */ +LJ_FUNCA void LJ_FASTCALL lj_func_closeuv(lua_State *L, TValue *level); +LJ_FUNC void LJ_FASTCALL lj_func_freeuv(global_State *g, GCupval *uv); + +/* Functions (closures). */ +LJ_FUNC GCfunc *lj_func_newC(lua_State *L, MSize nelems, GCtab *env); +LJ_FUNC GCfunc *lj_func_newL_empty(lua_State *L, GCproto *pt, GCtab *env); +LJ_FUNCA GCfunc *lj_func_newL_gc(lua_State *L, GCproto *pt, GCfuncL *parent); +LJ_FUNC void LJ_FASTCALL lj_func_free(global_State *g, GCfunc *c); + +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_gc.c b/fluent-bit/lib/luajit-3065c9/src/lj_gc.c new file mode 100644 index 00000000..b35a0d44 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_gc.c @@ -0,0 +1,906 @@ +/* +** Garbage collector. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +** +** Major portions taken verbatim or adapted from the Lua interpreter. +** Copyright (C) 1994-2008 Lua.org, PUC-Rio. See Copyright Notice in lua.h +*/ + +#define lj_gc_c +#define LUA_CORE + +#include "lj_obj.h" +#include "lj_gc.h" +#include "lj_err.h" +#include "lj_buf.h" +#include "lj_str.h" +#include "lj_tab.h" +#include "lj_func.h" +#include "lj_udata.h" +#include "lj_meta.h" +#include "lj_state.h" +#include "lj_frame.h" +#if LJ_HASFFI +#include "lj_ctype.h" +#include "lj_cdata.h" +#endif +#include "lj_trace.h" +#include "lj_dispatch.h" +#include "lj_vm.h" + +#define GCSTEPSIZE 1024u +#define GCSWEEPMAX 40 +#define GCSWEEPCOST 10 +#define GCFINALIZECOST 100 + +/* Macros to set GCobj colors and flags. */ +#define white2gray(x) ((x)->gch.marked &= (uint8_t)~LJ_GC_WHITES) +#define gray2black(x) ((x)->gch.marked |= LJ_GC_BLACK) +#define isfinalized(u) ((u)->marked & LJ_GC_FINALIZED) + +/* -- Mark phase ---------------------------------------------------------- */ + +/* Mark a TValue (if needed). */ +#define gc_marktv(g, tv) \ + { lj_assertG(!tvisgcv(tv) || (~itype(tv) == gcval(tv)->gch.gct), \ + "TValue and GC type mismatch"); \ + if (tviswhite(tv)) gc_mark(g, gcV(tv)); } + +/* Mark a GCobj (if needed). */ +#define gc_markobj(g, o) \ + { if (iswhite(obj2gco(o))) gc_mark(g, obj2gco(o)); } + +/* Mark a string object. */ +#define gc_mark_str(s) ((s)->marked &= (uint8_t)~LJ_GC_WHITES) + +/* Mark a white GCobj. */ +static void gc_mark(global_State *g, GCobj *o) +{ + int gct = o->gch.gct; + lj_assertG(iswhite(o), "mark of non-white object"); + lj_assertG(!isdead(g, o), "mark of dead object"); + white2gray(o); + if (LJ_UNLIKELY(gct == ~LJ_TUDATA)) { + GCtab *mt = tabref(gco2ud(o)->metatable); + gray2black(o); /* Userdata are never gray. */ + if (mt) gc_markobj(g, mt); + gc_markobj(g, tabref(gco2ud(o)->env)); + if (LJ_HASBUFFER && gco2ud(o)->udtype == UDTYPE_BUFFER) { + SBufExt *sbx = (SBufExt *)uddata(gco2ud(o)); + if (sbufiscow(sbx) && gcref(sbx->cowref)) + gc_markobj(g, gcref(sbx->cowref)); + if (gcref(sbx->dict_str)) + gc_markobj(g, gcref(sbx->dict_str)); + if (gcref(sbx->dict_mt)) + gc_markobj(g, gcref(sbx->dict_mt)); + } + } else if (LJ_UNLIKELY(gct == ~LJ_TUPVAL)) { + GCupval *uv = gco2uv(o); + gc_marktv(g, uvval(uv)); + if (uv->closed) + gray2black(o); /* Closed upvalues are never gray. */ + } else if (gct != ~LJ_TSTR && gct != ~LJ_TCDATA) { + lj_assertG(gct == ~LJ_TFUNC || gct == ~LJ_TTAB || + gct == ~LJ_TTHREAD || gct == ~LJ_TPROTO || gct == ~LJ_TTRACE, + "bad GC type %d", gct); + setgcrefr(o->gch.gclist, g->gc.gray); + setgcref(g->gc.gray, o); + } +} + +/* Mark GC roots. */ +static void gc_mark_gcroot(global_State *g) +{ + ptrdiff_t i; + for (i = 0; i < GCROOT_MAX; i++) + if (gcref(g->gcroot[i]) != NULL) + gc_markobj(g, gcref(g->gcroot[i])); +} + +/* Start a GC cycle and mark the root set. */ +static void gc_mark_start(global_State *g) +{ + setgcrefnull(g->gc.gray); + setgcrefnull(g->gc.grayagain); + setgcrefnull(g->gc.weak); + gc_markobj(g, mainthread(g)); + gc_markobj(g, tabref(mainthread(g)->env)); + gc_marktv(g, &g->registrytv); + gc_mark_gcroot(g); + g->gc.state = GCSpropagate; +} + +/* Mark open upvalues. */ +static void gc_mark_uv(global_State *g) +{ + GCupval *uv; + for (uv = uvnext(&g->uvhead); uv != &g->uvhead; uv = uvnext(uv)) { + lj_assertG(uvprev(uvnext(uv)) == uv && uvnext(uvprev(uv)) == uv, + "broken upvalue chain"); + if (isgray(obj2gco(uv))) + gc_marktv(g, uvval(uv)); + } +} + +/* Mark userdata in mmudata list. */ +static void gc_mark_mmudata(global_State *g) +{ + GCobj *root = gcref(g->gc.mmudata); + GCobj *u = root; + if (u) { + do { + u = gcnext(u); + makewhite(g, u); /* Could be from previous GC. */ + gc_mark(g, u); + } while (u != root); + } +} + +/* Separate userdata objects to be finalized to mmudata list. */ +size_t lj_gc_separateudata(global_State *g, int all) +{ + size_t m = 0; + GCRef *p = &mainthread(g)->nextgc; + GCobj *o; + while ((o = gcref(*p)) != NULL) { + if (!(iswhite(o) || all) || isfinalized(gco2ud(o))) { + p = &o->gch.nextgc; /* Nothing to do. */ + } else if (!lj_meta_fastg(g, tabref(gco2ud(o)->metatable), MM_gc)) { + markfinalized(o); /* Done, as there's no __gc metamethod. */ + p = &o->gch.nextgc; + } else { /* Otherwise move userdata to be finalized to mmudata list. */ + m += sizeudata(gco2ud(o)); + markfinalized(o); + *p = o->gch.nextgc; + if (gcref(g->gc.mmudata)) { /* Link to end of mmudata list. */ + GCobj *root = gcref(g->gc.mmudata); + setgcrefr(o->gch.nextgc, root->gch.nextgc); + setgcref(root->gch.nextgc, o); + setgcref(g->gc.mmudata, o); + } else { /* Create circular list. */ + setgcref(o->gch.nextgc, o); + setgcref(g->gc.mmudata, o); + } + } + } + return m; +} + +/* -- Propagation phase --------------------------------------------------- */ + +/* Traverse a table. */ +static int gc_traverse_tab(global_State *g, GCtab *t) +{ + int weak = 0; + cTValue *mode; + GCtab *mt = tabref(t->metatable); + if (mt) + gc_markobj(g, mt); + mode = lj_meta_fastg(g, mt, MM_mode); + if (mode && tvisstr(mode)) { /* Valid __mode field? */ + const char *modestr = strVdata(mode); + int c; + while ((c = *modestr++)) { + if (c == 'k') weak |= LJ_GC_WEAKKEY; + else if (c == 'v') weak |= LJ_GC_WEAKVAL; + } + if (weak) { /* Weak tables are cleared in the atomic phase. */ +#if LJ_HASFFI + CTState *cts = ctype_ctsG(g); + if (cts && cts->finalizer == t) { + weak = (int)(~0u & ~LJ_GC_WEAKVAL); + } else +#endif + { + t->marked = (uint8_t)((t->marked & ~LJ_GC_WEAK) | weak); + setgcrefr(t->gclist, g->gc.weak); + setgcref(g->gc.weak, obj2gco(t)); + } + } + } + if (weak == LJ_GC_WEAK) /* Nothing to mark if both keys/values are weak. */ + return 1; + if (!(weak & LJ_GC_WEAKVAL)) { /* Mark array part. */ + MSize i, asize = t->asize; + for (i = 0; i < asize; i++) + gc_marktv(g, arrayslot(t, i)); + } + if (t->hmask > 0) { /* Mark hash part. */ + Node *node = noderef(t->node); + MSize i, hmask = t->hmask; + for (i = 0; i <= hmask; i++) { + Node *n = &node[i]; + if (!tvisnil(&n->val)) { /* Mark non-empty slot. */ + lj_assertG(!tvisnil(&n->key), "mark of nil key in non-empty slot"); + if (!(weak & LJ_GC_WEAKKEY)) gc_marktv(g, &n->key); + if (!(weak & LJ_GC_WEAKVAL)) gc_marktv(g, &n->val); + } + } + } + return weak; +} + +/* Traverse a function. */ +static void gc_traverse_func(global_State *g, GCfunc *fn) +{ + gc_markobj(g, tabref(fn->c.env)); + if (isluafunc(fn)) { + uint32_t i; + lj_assertG(fn->l.nupvalues <= funcproto(fn)->sizeuv, + "function upvalues out of range"); + gc_markobj(g, funcproto(fn)); + for (i = 0; i < fn->l.nupvalues; i++) /* Mark Lua function upvalues. */ + gc_markobj(g, &gcref(fn->l.uvptr[i])->uv); + } else { + uint32_t i; + for (i = 0; i < fn->c.nupvalues; i++) /* Mark C function upvalues. */ + gc_marktv(g, &fn->c.upvalue[i]); + } +} + +#if LJ_HASJIT +/* Mark a trace. */ +static void gc_marktrace(global_State *g, TraceNo traceno) +{ + GCobj *o = obj2gco(traceref(G2J(g), traceno)); + lj_assertG(traceno != G2J(g)->cur.traceno, "active trace escaped"); + if (iswhite(o)) { + white2gray(o); + setgcrefr(o->gch.gclist, g->gc.gray); + setgcref(g->gc.gray, o); + } +} + +/* Traverse a trace. */ +static void gc_traverse_trace(global_State *g, GCtrace *T) +{ + IRRef ref; + if (T->traceno == 0) return; + for (ref = T->nk; ref < REF_TRUE; ref++) { + IRIns *ir = &T->ir[ref]; + if (ir->o == IR_KGC) + gc_markobj(g, ir_kgc(ir)); + if (irt_is64(ir->t) && ir->o != IR_KNULL) + ref++; + } + if (T->link) gc_marktrace(g, T->link); + if (T->nextroot) gc_marktrace(g, T->nextroot); + if (T->nextside) gc_marktrace(g, T->nextside); + gc_markobj(g, gcref(T->startpt)); +} + +/* The current trace is a GC root while not anchored in the prototype (yet). */ +#define gc_traverse_curtrace(g) gc_traverse_trace(g, &G2J(g)->cur) +#else +#define gc_traverse_curtrace(g) UNUSED(g) +#endif + +/* Traverse a prototype. */ +static void gc_traverse_proto(global_State *g, GCproto *pt) +{ + ptrdiff_t i; + gc_mark_str(proto_chunkname(pt)); + for (i = -(ptrdiff_t)pt->sizekgc; i < 0; i++) /* Mark collectable consts. */ + gc_markobj(g, proto_kgc(pt, i)); +#if LJ_HASJIT + if (pt->trace) gc_marktrace(g, pt->trace); +#endif +} + +/* Traverse the frame structure of a stack. */ +static MSize gc_traverse_frames(global_State *g, lua_State *th) +{ + TValue *frame, *top = th->top-1, *bot = tvref(th->stack); + /* Note: extra vararg frame not skipped, marks function twice (harmless). */ + for (frame = th->base-1; frame > bot+LJ_FR2; frame = frame_prev(frame)) { + GCfunc *fn = frame_func(frame); + TValue *ftop = frame; + if (isluafunc(fn)) ftop += funcproto(fn)->framesize; + if (ftop > top) top = ftop; + if (!LJ_FR2) gc_markobj(g, fn); /* Need to mark hidden function (or L). */ + } + top++; /* Correct bias of -1 (frame == base-1). */ + if (top > tvref(th->maxstack)) top = tvref(th->maxstack); + return (MSize)(top - bot); /* Return minimum needed stack size. */ +} + +/* Traverse a thread object. */ +static void gc_traverse_thread(global_State *g, lua_State *th) +{ + TValue *o, *top = th->top; + for (o = tvref(th->stack)+1+LJ_FR2; o < top; o++) + gc_marktv(g, o); + if (g->gc.state == GCSatomic) { + top = tvref(th->stack) + th->stacksize; + for (; o < top; o++) /* Clear unmarked slots. */ + setnilV(o); + } + gc_markobj(g, tabref(th->env)); + lj_state_shrinkstack(th, gc_traverse_frames(g, th)); +} + +/* Propagate one gray object. Traverse it and turn it black. */ +static size_t propagatemark(global_State *g) +{ + GCobj *o = gcref(g->gc.gray); + int gct = o->gch.gct; + lj_assertG(isgray(o), "propagation of non-gray object"); + gray2black(o); + setgcrefr(g->gc.gray, o->gch.gclist); /* Remove from gray list. */ + if (LJ_LIKELY(gct == ~LJ_TTAB)) { + GCtab *t = gco2tab(o); + if (gc_traverse_tab(g, t) > 0) + black2gray(o); /* Keep weak tables gray. */ + return sizeof(GCtab) + sizeof(TValue) * t->asize + + (t->hmask ? sizeof(Node) * (t->hmask + 1) : 0); + } else if (LJ_LIKELY(gct == ~LJ_TFUNC)) { + GCfunc *fn = gco2func(o); + gc_traverse_func(g, fn); + return isluafunc(fn) ? sizeLfunc((MSize)fn->l.nupvalues) : + sizeCfunc((MSize)fn->c.nupvalues); + } else if (LJ_LIKELY(gct == ~LJ_TPROTO)) { + GCproto *pt = gco2pt(o); + gc_traverse_proto(g, pt); + return pt->sizept; + } else if (LJ_LIKELY(gct == ~LJ_TTHREAD)) { + lua_State *th = gco2th(o); + setgcrefr(th->gclist, g->gc.grayagain); + setgcref(g->gc.grayagain, o); + black2gray(o); /* Threads are never black. */ + gc_traverse_thread(g, th); + return sizeof(lua_State) + sizeof(TValue) * th->stacksize; + } else { +#if LJ_HASJIT + GCtrace *T = gco2trace(o); + gc_traverse_trace(g, T); + return ((sizeof(GCtrace)+7)&~7) + (T->nins-T->nk)*sizeof(IRIns) + + T->nsnap*sizeof(SnapShot) + T->nsnapmap*sizeof(SnapEntry); +#else + lj_assertG(0, "bad GC type %d", gct); + return 0; +#endif + } +} + +/* Propagate all gray objects. */ +static size_t gc_propagate_gray(global_State *g) +{ + size_t m = 0; + while (gcref(g->gc.gray) != NULL) + m += propagatemark(g); + return m; +} + +/* -- Sweep phase --------------------------------------------------------- */ + +/* Type of GC free functions. */ +typedef void (LJ_FASTCALL *GCFreeFunc)(global_State *g, GCobj *o); + +/* GC free functions for LJ_TSTR .. LJ_TUDATA. ORDER LJ_T */ +static const GCFreeFunc gc_freefunc[] = { + (GCFreeFunc)lj_str_free, + (GCFreeFunc)lj_func_freeuv, + (GCFreeFunc)lj_state_free, + (GCFreeFunc)lj_func_freeproto, + (GCFreeFunc)lj_func_free, +#if LJ_HASJIT + (GCFreeFunc)lj_trace_free, +#else + (GCFreeFunc)0, +#endif +#if LJ_HASFFI + (GCFreeFunc)lj_cdata_free, +#else + (GCFreeFunc)0, +#endif + (GCFreeFunc)lj_tab_free, + (GCFreeFunc)lj_udata_free +}; + +/* Full sweep of a GC list. */ +#define gc_fullsweep(g, p) gc_sweep(g, (p), ~(uint32_t)0) + +/* Partial sweep of a GC list. */ +static GCRef *gc_sweep(global_State *g, GCRef *p, uint32_t lim) +{ + /* Mask with other white and LJ_GC_FIXED. Or LJ_GC_SFIXED on shutdown. */ + int ow = otherwhite(g); + GCobj *o; + while ((o = gcref(*p)) != NULL && lim-- > 0) { + if (o->gch.gct == ~LJ_TTHREAD) /* Need to sweep open upvalues, too. */ + gc_fullsweep(g, &gco2th(o)->openupval); + if (((o->gch.marked ^ LJ_GC_WHITES) & ow)) { /* Black or current white? */ + lj_assertG(!isdead(g, o) || (o->gch.marked & LJ_GC_FIXED), + "sweep of undead object"); + makewhite(g, o); /* Value is alive, change to the current white. */ + p = &o->gch.nextgc; + } else { /* Otherwise value is dead, free it. */ + lj_assertG(isdead(g, o) || ow == LJ_GC_SFIXED, + "sweep of unlive object"); + setgcrefr(*p, o->gch.nextgc); + if (o == gcref(g->gc.root)) + setgcrefr(g->gc.root, o->gch.nextgc); /* Adjust list anchor. */ + gc_freefunc[o->gch.gct - ~LJ_TSTR](g, o); + } + } + return p; +} + +/* Sweep one string interning table chain. Preserves hashalg bit. */ +static void gc_sweepstr(global_State *g, GCRef *chain) +{ + /* Mask with other white and LJ_GC_FIXED. Or LJ_GC_SFIXED on shutdown. */ + int ow = otherwhite(g); + uintptr_t u = gcrefu(*chain); + GCRef q; + GCRef *p = &q; + GCobj *o; + setgcrefp(q, (u & ~(uintptr_t)1)); + while ((o = gcref(*p)) != NULL) { + if (((o->gch.marked ^ LJ_GC_WHITES) & ow)) { /* Black or current white? */ + lj_assertG(!isdead(g, o) || (o->gch.marked & LJ_GC_FIXED), + "sweep of undead string"); + makewhite(g, o); /* String is alive, change to the current white. */ + p = &o->gch.nextgc; + } else { /* Otherwise string is dead, free it. */ + lj_assertG(isdead(g, o) || ow == LJ_GC_SFIXED, + "sweep of unlive string"); + setgcrefr(*p, o->gch.nextgc); + lj_str_free(g, gco2str(o)); + } + } + setgcrefp(*chain, (gcrefu(q) | (u & 1))); +} + +/* Check whether we can clear a key or a value slot from a table. */ +static int gc_mayclear(cTValue *o, int val) +{ + if (tvisgcv(o)) { /* Only collectable objects can be weak references. */ + if (tvisstr(o)) { /* But strings cannot be used as weak references. */ + gc_mark_str(strV(o)); /* And need to be marked. */ + return 0; + } + if (iswhite(gcV(o))) + return 1; /* Object is about to be collected. */ + if (tvisudata(o) && val && isfinalized(udataV(o))) + return 1; /* Finalized userdata is dropped only from values. */ + } + return 0; /* Cannot clear. */ +} + +/* Clear collected entries from weak tables. */ +static void gc_clearweak(global_State *g, GCobj *o) +{ + UNUSED(g); + while (o) { + GCtab *t = gco2tab(o); + lj_assertG((t->marked & LJ_GC_WEAK), "clear of non-weak table"); + if ((t->marked & LJ_GC_WEAKVAL)) { + MSize i, asize = t->asize; + for (i = 0; i < asize; i++) { + /* Clear array slot when value is about to be collected. */ + TValue *tv = arrayslot(t, i); + if (gc_mayclear(tv, 1)) + setnilV(tv); + } + } + if (t->hmask > 0) { + Node *node = noderef(t->node); + MSize i, hmask = t->hmask; + for (i = 0; i <= hmask; i++) { + Node *n = &node[i]; + /* Clear hash slot when key or value is about to be collected. */ + if (!tvisnil(&n->val) && (gc_mayclear(&n->key, 0) || + gc_mayclear(&n->val, 1))) + setnilV(&n->val); + } + } + o = gcref(t->gclist); + } +} + +/* Call a userdata or cdata finalizer. */ +static void gc_call_finalizer(global_State *g, lua_State *L, + cTValue *mo, GCobj *o) +{ + /* Save and restore lots of state around the __gc callback. */ + uint8_t oldh = hook_save(g); + GCSize oldt = g->gc.threshold; + int errcode; + TValue *top; + lj_trace_abort(g); + hook_entergc(g); /* Disable hooks and new traces during __gc. */ + if (LJ_HASPROFILE && (oldh & HOOK_PROFILE)) lj_dispatch_update(g); + g->gc.threshold = LJ_MAX_MEM; /* Prevent GC steps. */ + top = L->top; + copyTV(L, top++, mo); + if (LJ_FR2) setnilV(top++); + setgcV(L, top, o, ~o->gch.gct); + L->top = top+1; + errcode = lj_vm_pcall(L, top, 1+0, -1); /* Stack: |mo|o| -> | */ + hook_restore(g, oldh); + if (LJ_HASPROFILE && (oldh & HOOK_PROFILE)) lj_dispatch_update(g); + g->gc.threshold = oldt; /* Restore GC threshold. */ + if (errcode) + lj_err_throw(L, errcode); /* Propagate errors. */ +} + +/* Finalize one userdata or cdata object from the mmudata list. */ +static void gc_finalize(lua_State *L) +{ + global_State *g = G(L); + GCobj *o = gcnext(gcref(g->gc.mmudata)); + cTValue *mo; + lj_assertG(tvref(g->jit_base) == NULL, "finalizer called on trace"); + /* Unchain from list of userdata to be finalized. */ + if (o == gcref(g->gc.mmudata)) + setgcrefnull(g->gc.mmudata); + else + setgcrefr(gcref(g->gc.mmudata)->gch.nextgc, o->gch.nextgc); +#if LJ_HASFFI + if (o->gch.gct == ~LJ_TCDATA) { + TValue tmp, *tv; + /* Add cdata back to the GC list and make it white. */ + setgcrefr(o->gch.nextgc, g->gc.root); + setgcref(g->gc.root, o); + makewhite(g, o); + o->gch.marked &= (uint8_t)~LJ_GC_CDATA_FIN; + /* Resolve finalizer. */ + setcdataV(L, &tmp, gco2cd(o)); + tv = lj_tab_set(L, ctype_ctsG(g)->finalizer, &tmp); + if (!tvisnil(tv)) { + g->gc.nocdatafin = 0; + copyTV(L, &tmp, tv); + setnilV(tv); /* Clear entry in finalizer table. */ + gc_call_finalizer(g, L, &tmp, o); + } + return; + } +#endif + /* Add userdata back to the main userdata list and make it white. */ + setgcrefr(o->gch.nextgc, mainthread(g)->nextgc); + setgcref(mainthread(g)->nextgc, o); + makewhite(g, o); + /* Resolve the __gc metamethod. */ + mo = lj_meta_fastg(g, tabref(gco2ud(o)->metatable), MM_gc); + if (mo) + gc_call_finalizer(g, L, mo, o); +} + +/* Finalize all userdata objects from mmudata list. */ +void lj_gc_finalize_udata(lua_State *L) +{ + while (gcref(G(L)->gc.mmudata) != NULL) + gc_finalize(L); +} + +#if LJ_HASFFI +/* Finalize all cdata objects from finalizer table. */ +void lj_gc_finalize_cdata(lua_State *L) +{ + global_State *g = G(L); + CTState *cts = ctype_ctsG(g); + if (cts) { + GCtab *t = cts->finalizer; + Node *node = noderef(t->node); + ptrdiff_t i; + setgcrefnull(t->metatable); /* Mark finalizer table as disabled. */ + for (i = (ptrdiff_t)t->hmask; i >= 0; i--) + if (!tvisnil(&node[i].val) && tviscdata(&node[i].key)) { + GCobj *o = gcV(&node[i].key); + TValue tmp; + makewhite(g, o); + o->gch.marked &= (uint8_t)~LJ_GC_CDATA_FIN; + copyTV(L, &tmp, &node[i].val); + setnilV(&node[i].val); + gc_call_finalizer(g, L, &tmp, o); + } + } +} +#endif + +/* Free all remaining GC objects. */ +void lj_gc_freeall(global_State *g) +{ + MSize i, strmask; + /* Free everything, except super-fixed objects (the main thread). */ + g->gc.currentwhite = LJ_GC_WHITES | LJ_GC_SFIXED; + gc_fullsweep(g, &g->gc.root); + strmask = g->str.mask; + for (i = 0; i <= strmask; i++) /* Free all string hash chains. */ + gc_sweepstr(g, &g->str.tab[i]); +} + +/* -- Collector ----------------------------------------------------------- */ + +/* Atomic part of the GC cycle, transitioning from mark to sweep phase. */ +static void atomic(global_State *g, lua_State *L) +{ + size_t udsize; + + gc_mark_uv(g); /* Need to remark open upvalues (the thread may be dead). */ + gc_propagate_gray(g); /* Propagate any left-overs. */ + + setgcrefr(g->gc.gray, g->gc.weak); /* Empty the list of weak tables. */ + setgcrefnull(g->gc.weak); + lj_assertG(!iswhite(obj2gco(mainthread(g))), "main thread turned white"); + gc_markobj(g, L); /* Mark running thread. */ + gc_traverse_curtrace(g); /* Traverse current trace. */ + gc_mark_gcroot(g); /* Mark GC roots (again). */ + gc_propagate_gray(g); /* Propagate all of the above. */ + + setgcrefr(g->gc.gray, g->gc.grayagain); /* Empty the 2nd chance list. */ + setgcrefnull(g->gc.grayagain); + gc_propagate_gray(g); /* Propagate it. */ + + udsize = lj_gc_separateudata(g, 0); /* Separate userdata to be finalized. */ + gc_mark_mmudata(g); /* Mark them. */ + udsize += gc_propagate_gray(g); /* And propagate the marks. */ + + /* All marking done, clear weak tables. */ + gc_clearweak(g, gcref(g->gc.weak)); + + lj_buf_shrink(L, &g->tmpbuf); /* Shrink temp buffer. */ + + /* Prepare for sweep phase. */ + g->gc.currentwhite = (uint8_t)otherwhite(g); /* Flip current white. */ + g->strempty.marked = g->gc.currentwhite; + setmref(g->gc.sweep, &g->gc.root); + g->gc.estimate = g->gc.total - (GCSize)udsize; /* Initial estimate. */ +} + +/* GC state machine. Returns a cost estimate for each step performed. */ +static size_t gc_onestep(lua_State *L) +{ + global_State *g = G(L); + switch (g->gc.state) { + case GCSpause: + gc_mark_start(g); /* Start a new GC cycle by marking all GC roots. */ + return 0; + case GCSpropagate: + if (gcref(g->gc.gray) != NULL) + return propagatemark(g); /* Propagate one gray object. */ + g->gc.state = GCSatomic; /* End of mark phase. */ + return 0; + case GCSatomic: + if (tvref(g->jit_base)) /* Don't run atomic phase on trace. */ + return LJ_MAX_MEM; + atomic(g, L); + g->gc.state = GCSsweepstring; /* Start of sweep phase. */ + g->gc.sweepstr = 0; + return 0; + case GCSsweepstring: { + GCSize old = g->gc.total; + gc_sweepstr(g, &g->str.tab[g->gc.sweepstr++]); /* Sweep one chain. */ + if (g->gc.sweepstr > g->str.mask) + g->gc.state = GCSsweep; /* All string hash chains sweeped. */ + lj_assertG(old >= g->gc.total, "sweep increased memory"); + g->gc.estimate -= old - g->gc.total; + return GCSWEEPCOST; + } + case GCSsweep: { + GCSize old = g->gc.total; + setmref(g->gc.sweep, gc_sweep(g, mref(g->gc.sweep, GCRef), GCSWEEPMAX)); + lj_assertG(old >= g->gc.total, "sweep increased memory"); + g->gc.estimate -= old - g->gc.total; + if (gcref(*mref(g->gc.sweep, GCRef)) == NULL) { + if (g->str.num <= (g->str.mask >> 2) && g->str.mask > LJ_MIN_STRTAB*2-1) + lj_str_resize(L, g->str.mask >> 1); /* Shrink string table. */ + if (gcref(g->gc.mmudata)) { /* Need any finalizations? */ + g->gc.state = GCSfinalize; +#if LJ_HASFFI + g->gc.nocdatafin = 1; +#endif + } else { /* Otherwise skip this phase to help the JIT. */ + g->gc.state = GCSpause; /* End of GC cycle. */ + g->gc.debt = 0; + } + } + return GCSWEEPMAX*GCSWEEPCOST; + } + case GCSfinalize: + if (gcref(g->gc.mmudata) != NULL) { + if (tvref(g->jit_base)) /* Don't call finalizers on trace. */ + return LJ_MAX_MEM; + gc_finalize(L); /* Finalize one userdata object. */ + if (g->gc.estimate > GCFINALIZECOST) + g->gc.estimate -= GCFINALIZECOST; + return GCFINALIZECOST; + } +#if LJ_HASFFI + if (!g->gc.nocdatafin) lj_tab_rehash(L, ctype_ctsG(g)->finalizer); +#endif + g->gc.state = GCSpause; /* End of GC cycle. */ + g->gc.debt = 0; + return 0; + default: + lj_assertG(0, "bad GC state"); + return 0; + } +} + +/* Perform a limited amount of incremental GC steps. */ +int LJ_FASTCALL lj_gc_step(lua_State *L) +{ + global_State *g = G(L); + GCSize lim; + int32_t ostate = g->vmstate; + setvmstate(g, GC); + lim = (GCSTEPSIZE/100) * g->gc.stepmul; + if (lim == 0) + lim = LJ_MAX_MEM; + if (g->gc.total > g->gc.threshold) + g->gc.debt += g->gc.total - g->gc.threshold; + do { + lim -= (GCSize)gc_onestep(L); + if (g->gc.state == GCSpause) { + g->gc.threshold = (g->gc.estimate/100) * g->gc.pause; + g->vmstate = ostate; + return 1; /* Finished a GC cycle. */ + } + } while (sizeof(lim) == 8 ? ((int64_t)lim > 0) : ((int32_t)lim > 0)); + if (g->gc.debt < GCSTEPSIZE) { + g->gc.threshold = g->gc.total + GCSTEPSIZE; + g->vmstate = ostate; + return -1; + } else { + g->gc.debt -= GCSTEPSIZE; + g->gc.threshold = g->gc.total; + g->vmstate = ostate; + return 0; + } +} + +/* Ditto, but fix the stack top first. */ +void LJ_FASTCALL lj_gc_step_fixtop(lua_State *L) +{ + if (curr_funcisL(L)) L->top = curr_topL(L); + lj_gc_step(L); +} + +#if LJ_HASJIT +/* Perform multiple GC steps. Called from JIT-compiled code. */ +int LJ_FASTCALL lj_gc_step_jit(global_State *g, MSize steps) +{ + lua_State *L = gco2th(gcref(g->cur_L)); + L->base = tvref(G(L)->jit_base); + L->top = curr_topL(L); + while (steps-- > 0 && lj_gc_step(L) == 0) + ; + /* Return 1 to force a trace exit. */ + return (G(L)->gc.state == GCSatomic || G(L)->gc.state == GCSfinalize); +} +#endif + +/* Perform a full GC cycle. */ +void lj_gc_fullgc(lua_State *L) +{ + global_State *g = G(L); + int32_t ostate = g->vmstate; + setvmstate(g, GC); + if (g->gc.state <= GCSatomic) { /* Caught somewhere in the middle. */ + setmref(g->gc.sweep, &g->gc.root); /* Sweep everything (preserving it). */ + setgcrefnull(g->gc.gray); /* Reset lists from partial propagation. */ + setgcrefnull(g->gc.grayagain); + setgcrefnull(g->gc.weak); + g->gc.state = GCSsweepstring; /* Fast forward to the sweep phase. */ + g->gc.sweepstr = 0; + } + while (g->gc.state == GCSsweepstring || g->gc.state == GCSsweep) + gc_onestep(L); /* Finish sweep. */ + lj_assertG(g->gc.state == GCSfinalize || g->gc.state == GCSpause, + "bad GC state"); + /* Now perform a full GC. */ + g->gc.state = GCSpause; + do { gc_onestep(L); } while (g->gc.state != GCSpause); + g->gc.threshold = (g->gc.estimate/100) * g->gc.pause; + g->vmstate = ostate; +} + +/* -- Write barriers ------------------------------------------------------ */ + +/* Move the GC propagation frontier forward. */ +void lj_gc_barrierf(global_State *g, GCobj *o, GCobj *v) +{ + lj_assertG(isblack(o) && iswhite(v) && !isdead(g, v) && !isdead(g, o), + "bad object states for forward barrier"); + lj_assertG(g->gc.state != GCSfinalize && g->gc.state != GCSpause, + "bad GC state"); + lj_assertG(o->gch.gct != ~LJ_TTAB, "barrier object is not a table"); + /* Preserve invariant during propagation. Otherwise it doesn't matter. */ + if (g->gc.state == GCSpropagate || g->gc.state == GCSatomic) + gc_mark(g, v); /* Move frontier forward. */ + else + makewhite(g, o); /* Make it white to avoid the following barrier. */ +} + +/* Specialized barrier for closed upvalue. Pass &uv->tv. */ +void LJ_FASTCALL lj_gc_barrieruv(global_State *g, TValue *tv) +{ +#define TV2MARKED(x) \ + (*((uint8_t *)(x) - offsetof(GCupval, tv) + offsetof(GCupval, marked))) + if (g->gc.state == GCSpropagate || g->gc.state == GCSatomic) + gc_mark(g, gcV(tv)); + else + TV2MARKED(tv) = (TV2MARKED(tv) & (uint8_t)~LJ_GC_COLORS) | curwhite(g); +#undef TV2MARKED +} + +/* Close upvalue. Also needs a write barrier. */ +void lj_gc_closeuv(global_State *g, GCupval *uv) +{ + GCobj *o = obj2gco(uv); + /* Copy stack slot to upvalue itself and point to the copy. */ + copyTV(mainthread(g), &uv->tv, uvval(uv)); + setmref(uv->v, &uv->tv); + uv->closed = 1; + setgcrefr(o->gch.nextgc, g->gc.root); + setgcref(g->gc.root, o); + if (isgray(o)) { /* A closed upvalue is never gray, so fix this. */ + if (g->gc.state == GCSpropagate || g->gc.state == GCSatomic) { + gray2black(o); /* Make it black and preserve invariant. */ + if (tviswhite(&uv->tv)) + lj_gc_barrierf(g, o, gcV(&uv->tv)); + } else { + makewhite(g, o); /* Make it white, i.e. sweep the upvalue. */ + lj_assertG(g->gc.state != GCSfinalize && g->gc.state != GCSpause, + "bad GC state"); + } + } +} + +#if LJ_HASJIT +/* Mark a trace if it's saved during the propagation phase. */ +void lj_gc_barriertrace(global_State *g, uint32_t traceno) +{ + if (g->gc.state == GCSpropagate || g->gc.state == GCSatomic) + gc_marktrace(g, traceno); +} +#endif + +/* -- Allocator ----------------------------------------------------------- */ + +/* Call pluggable memory allocator to allocate or resize a fragment. */ +void *lj_mem_realloc(lua_State *L, void *p, GCSize osz, GCSize nsz) +{ + global_State *g = G(L); + lj_assertG((osz == 0) == (p == NULL), "realloc API violation"); + p = g->allocf(g->allocd, p, osz, nsz); + if (p == NULL && nsz > 0) + lj_err_mem(L); + lj_assertG((nsz == 0) == (p == NULL), "allocf API violation"); + lj_assertG(checkptrGC(p), + "allocated memory address %p outside required range", p); + g->gc.total = (g->gc.total - osz) + nsz; + return p; +} + +/* Allocate new GC object and link it to the root set. */ +void * LJ_FASTCALL lj_mem_newgco(lua_State *L, GCSize size) +{ + global_State *g = G(L); + GCobj *o = (GCobj *)g->allocf(g->allocd, NULL, 0, size); + if (o == NULL) + lj_err_mem(L); + lj_assertG(checkptrGC(o), + "allocated memory address %p outside required range", o); + g->gc.total += size; + setgcrefr(o->gch.nextgc, g->gc.root); + setgcref(g->gc.root, o); + newwhite(g, o); + return o; +} + +/* Resize growable vector. */ +void *lj_mem_grow(lua_State *L, void *p, MSize *szp, MSize lim, MSize esz) +{ + MSize sz = (*szp) << 1; + if (sz < LJ_MIN_VECSZ) + sz = LJ_MIN_VECSZ; + if (sz > lim) + sz = lim; + p = lj_mem_realloc(L, p, (*szp)*esz, sz*esz); + *szp = sz; + return p; +} + diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_gc.h b/fluent-bit/lib/luajit-3065c9/src/lj_gc.h new file mode 100644 index 00000000..0df7dee6 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_gc.h @@ -0,0 +1,136 @@ +/* +** Garbage collector. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#ifndef _LJ_GC_H +#define _LJ_GC_H + +#include "lj_obj.h" + +/* Garbage collector states. Order matters. */ +enum { + GCSpause, GCSpropagate, GCSatomic, GCSsweepstring, GCSsweep, GCSfinalize +}; + +/* Bitmasks for marked field of GCobj. */ +#define LJ_GC_WHITE0 0x01 +#define LJ_GC_WHITE1 0x02 +#define LJ_GC_BLACK 0x04 +#define LJ_GC_FINALIZED 0x08 +#define LJ_GC_WEAKKEY 0x08 +#define LJ_GC_WEAKVAL 0x10 +#define LJ_GC_CDATA_FIN 0x10 +#define LJ_GC_FIXED 0x20 +#define LJ_GC_SFIXED 0x40 + +#define LJ_GC_WHITES (LJ_GC_WHITE0 | LJ_GC_WHITE1) +#define LJ_GC_COLORS (LJ_GC_WHITES | LJ_GC_BLACK) +#define LJ_GC_WEAK (LJ_GC_WEAKKEY | LJ_GC_WEAKVAL) + +/* Macros to test and set GCobj colors. */ +#define iswhite(x) ((x)->gch.marked & LJ_GC_WHITES) +#define isblack(x) ((x)->gch.marked & LJ_GC_BLACK) +#define isgray(x) (!((x)->gch.marked & (LJ_GC_BLACK|LJ_GC_WHITES))) +#define tviswhite(x) (tvisgcv(x) && iswhite(gcV(x))) +#define otherwhite(g) (g->gc.currentwhite ^ LJ_GC_WHITES) +#define isdead(g, v) ((v)->gch.marked & otherwhite(g) & LJ_GC_WHITES) + +#define curwhite(g) ((g)->gc.currentwhite & LJ_GC_WHITES) +#define newwhite(g, x) (obj2gco(x)->gch.marked = (uint8_t)curwhite(g)) +#define makewhite(g, x) \ + ((x)->gch.marked = ((x)->gch.marked & (uint8_t)~LJ_GC_COLORS) | curwhite(g)) +#define flipwhite(x) ((x)->gch.marked ^= LJ_GC_WHITES) +#define black2gray(x) ((x)->gch.marked &= (uint8_t)~LJ_GC_BLACK) +#define fixstring(s) ((s)->marked |= LJ_GC_FIXED) +#define markfinalized(x) ((x)->gch.marked |= LJ_GC_FINALIZED) + +/* Collector. */ +LJ_FUNC size_t lj_gc_separateudata(global_State *g, int all); +LJ_FUNC void lj_gc_finalize_udata(lua_State *L); +#if LJ_HASFFI +LJ_FUNC void lj_gc_finalize_cdata(lua_State *L); +#else +#define lj_gc_finalize_cdata(L) UNUSED(L) +#endif +LJ_FUNC void lj_gc_freeall(global_State *g); +LJ_FUNCA int LJ_FASTCALL lj_gc_step(lua_State *L); +LJ_FUNCA void LJ_FASTCALL lj_gc_step_fixtop(lua_State *L); +#if LJ_HASJIT +LJ_FUNC int LJ_FASTCALL lj_gc_step_jit(global_State *g, MSize steps); +#endif +LJ_FUNC void lj_gc_fullgc(lua_State *L); + +/* GC check: drive collector forward if the GC threshold has been reached. */ +#define lj_gc_check(L) \ + { if (LJ_UNLIKELY(G(L)->gc.total >= G(L)->gc.threshold)) \ + lj_gc_step(L); } +#define lj_gc_check_fixtop(L) \ + { if (LJ_UNLIKELY(G(L)->gc.total >= G(L)->gc.threshold)) \ + lj_gc_step_fixtop(L); } + +/* Write barriers. */ +LJ_FUNC void lj_gc_barrierf(global_State *g, GCobj *o, GCobj *v); +LJ_FUNCA void LJ_FASTCALL lj_gc_barrieruv(global_State *g, TValue *tv); +LJ_FUNC void lj_gc_closeuv(global_State *g, GCupval *uv); +#if LJ_HASJIT +LJ_FUNC void lj_gc_barriertrace(global_State *g, uint32_t traceno); +#endif + +/* Move the GC propagation frontier back for tables (make it gray again). */ +static LJ_AINLINE void lj_gc_barrierback(global_State *g, GCtab *t) +{ + GCobj *o = obj2gco(t); + lj_assertG(isblack(o) && !isdead(g, o), + "bad object states for backward barrier"); + lj_assertG(g->gc.state != GCSfinalize && g->gc.state != GCSpause, + "bad GC state"); + black2gray(o); + setgcrefr(t->gclist, g->gc.grayagain); + setgcref(g->gc.grayagain, o); +} + +/* Barrier for stores to table objects. TValue and GCobj variant. */ +#define lj_gc_anybarriert(L, t) \ + { if (LJ_UNLIKELY(isblack(obj2gco(t)))) lj_gc_barrierback(G(L), (t)); } +#define lj_gc_barriert(L, t, tv) \ + { if (tviswhite(tv) && isblack(obj2gco(t))) \ + lj_gc_barrierback(G(L), (t)); } +#define lj_gc_objbarriert(L, t, o) \ + { if (iswhite(obj2gco(o)) && isblack(obj2gco(t))) \ + lj_gc_barrierback(G(L), (t)); } + +/* Barrier for stores to any other object. TValue and GCobj variant. */ +#define lj_gc_barrier(L, p, tv) \ + { if (tviswhite(tv) && isblack(obj2gco(p))) \ + lj_gc_barrierf(G(L), obj2gco(p), gcV(tv)); } +#define lj_gc_objbarrier(L, p, o) \ + { if (iswhite(obj2gco(o)) && isblack(obj2gco(p))) \ + lj_gc_barrierf(G(L), obj2gco(p), obj2gco(o)); } + +/* Allocator. */ +LJ_FUNC void *lj_mem_realloc(lua_State *L, void *p, GCSize osz, GCSize nsz); +LJ_FUNC void * LJ_FASTCALL lj_mem_newgco(lua_State *L, GCSize size); +LJ_FUNC void *lj_mem_grow(lua_State *L, void *p, + MSize *szp, MSize lim, MSize esz); + +#define lj_mem_new(L, s) lj_mem_realloc(L, NULL, 0, (s)) + +static LJ_AINLINE void lj_mem_free(global_State *g, void *p, size_t osize) +{ + g->gc.total -= (GCSize)osize; + g->allocf(g->allocd, p, osize, 0); +} + +#define lj_mem_newvec(L, n, t) ((t *)lj_mem_new(L, (GCSize)((n)*sizeof(t)))) +#define lj_mem_reallocvec(L, p, on, n, t) \ + ((p) = (t *)lj_mem_realloc(L, p, (on)*sizeof(t), (GCSize)((n)*sizeof(t)))) +#define lj_mem_growvec(L, p, n, m, t) \ + ((p) = (t *)lj_mem_grow(L, (p), &(n), (m), (MSize)sizeof(t))) +#define lj_mem_freevec(g, p, n, t) lj_mem_free(g, (p), (n)*sizeof(t)) + +#define lj_mem_newobj(L, t) ((t *)lj_mem_newgco(L, sizeof(t))) +#define lj_mem_newt(L, s, t) ((t *)lj_mem_new(L, (s))) +#define lj_mem_freet(g, p) lj_mem_free(g, (p), sizeof(*(p))) + +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_gdbjit.c b/fluent-bit/lib/luajit-3065c9/src/lj_gdbjit.c new file mode 100644 index 00000000..c50d0d4c --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_gdbjit.c @@ -0,0 +1,818 @@ +/* +** Client for the GDB JIT API. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#define lj_gdbjit_c +#define LUA_CORE + +#include "lj_obj.h" + +#if LJ_HASJIT + +#include "lj_gc.h" +#include "lj_err.h" +#include "lj_debug.h" +#include "lj_frame.h" +#include "lj_buf.h" +#include "lj_strfmt.h" +#include "lj_jit.h" +#include "lj_dispatch.h" + +/* This is not compiled in by default. +** Enable with -DLUAJIT_USE_GDBJIT in the Makefile and recompile everything. +*/ +#ifdef LUAJIT_USE_GDBJIT + +/* The GDB JIT API allows JIT compilers to pass debug information about +** JIT-compiled code back to GDB. You need at least GDB 7.0 or higher +** to see it in action. +** +** This is a passive API, so it works even when not running under GDB +** or when attaching to an already running process. Alas, this implies +** enabling it always has a non-negligible overhead -- do not use in +** release mode! +** +** The LuaJIT GDB JIT client is rather minimal at the moment. It gives +** each trace a symbol name and adds a source location and frame unwind +** information. Obviously LuaJIT itself and any embedding C application +** should be compiled with debug symbols, too (see the Makefile). +** +** Traces are named TRACE_1, TRACE_2, ... these correspond to the trace +** numbers from -jv or -jdump. Use "break TRACE_1" or "tbreak TRACE_1" etc. +** to set breakpoints on specific traces (even ahead of their creation). +** +** The source location for each trace allows listing the corresponding +** source lines with the GDB command "list" (but only if the Lua source +** has been loaded from a file). Currently this is always set to the +** location where the trace has been started. +** +** Frame unwind information can be inspected with the GDB command +** "info frame". This also allows proper backtraces across JIT-compiled +** code with the GDB command "bt". +** +** You probably want to add the following settings to a .gdbinit file +** (or add them to ~/.gdbinit): +** set disassembly-flavor intel +** set breakpoint pending on +** +** Here's a sample GDB session: +** ------------------------------------------------------------------------ + +$ cat >x.lua +for outer=1,100 do + for inner=1,100 do end +end +^D + +$ luajit -jv x.lua +[TRACE 1 x.lua:2] +[TRACE 2 (1/3) x.lua:1 -> 1] + +$ gdb --quiet --args luajit x.lua +(gdb) tbreak TRACE_1 +Function "TRACE_1" not defined. +Temporary breakpoint 1 (TRACE_1) pending. +(gdb) run +Starting program: luajit x.lua + +Temporary breakpoint 1, TRACE_1 () at x.lua:2 +2 for inner=1,100 do end +(gdb) list +1 for outer=1,100 do +2 for inner=1,100 do end +3 end +(gdb) bt +#0 TRACE_1 () at x.lua:2 +#1 0x08053690 in lua_pcall [...] +[...] +#7 0x0806ff90 in main [...] +(gdb) disass TRACE_1 +Dump of assembler code for function TRACE_1: +0xf7fd9fba : mov DWORD PTR ds:0xf7e0e2a0,0x1 +0xf7fd9fc4 : movsd xmm7,QWORD PTR [edx+0x20] +[...] +0xf7fd9ff8 : jmp 0xf7fd2014 +End of assembler dump. +(gdb) tbreak TRACE_2 +Function "TRACE_2" not defined. +Temporary breakpoint 2 (TRACE_2) pending. +(gdb) cont +Continuing. + +Temporary breakpoint 2, TRACE_2 () at x.lua:1 +1 for outer=1,100 do +(gdb) info frame +Stack level 0, frame at 0xffffd7c0: + eip = 0xf7fd9f60 in TRACE_2 (x.lua:1); saved eip 0x8053690 + called by frame at 0xffffd7e0 + source language unknown. + Arglist at 0xffffd78c, args: + Locals at 0xffffd78c, Previous frame's sp is 0xffffd7c0 + Saved registers: + ebx at 0xffffd7ac, ebp at 0xffffd7b8, esi at 0xffffd7b0, edi at 0xffffd7b4, + eip at 0xffffd7bc +(gdb) + +** ------------------------------------------------------------------------ +*/ + +/* -- GDB JIT API --------------------------------------------------------- */ + +/* GDB JIT actions. */ +enum { + GDBJIT_NOACTION = 0, + GDBJIT_REGISTER, + GDBJIT_UNREGISTER +}; + +/* GDB JIT entry. */ +typedef struct GDBJITentry { + struct GDBJITentry *next_entry; + struct GDBJITentry *prev_entry; + const char *symfile_addr; + uint64_t symfile_size; +} GDBJITentry; + +/* GDB JIT descriptor. */ +typedef struct GDBJITdesc { + uint32_t version; + uint32_t action_flag; + GDBJITentry *relevant_entry; + GDBJITentry *first_entry; +} GDBJITdesc; + +GDBJITdesc __jit_debug_descriptor = { + 1, GDBJIT_NOACTION, NULL, NULL +}; + +/* GDB sets a breakpoint at this function. */ +void LJ_NOINLINE __jit_debug_register_code() +{ + __asm__ __volatile__(""); +}; + +/* -- In-memory ELF object definitions ------------------------------------ */ + +/* ELF definitions. */ +typedef struct ELFheader { + uint8_t emagic[4]; + uint8_t eclass; + uint8_t eendian; + uint8_t eversion; + uint8_t eosabi; + uint8_t eabiversion; + uint8_t epad[7]; + uint16_t type; + uint16_t machine; + uint32_t version; + uintptr_t entry; + uintptr_t phofs; + uintptr_t shofs; + uint32_t flags; + uint16_t ehsize; + uint16_t phentsize; + uint16_t phnum; + uint16_t shentsize; + uint16_t shnum; + uint16_t shstridx; +} ELFheader; + +typedef struct ELFsectheader { + uint32_t name; + uint32_t type; + uintptr_t flags; + uintptr_t addr; + uintptr_t ofs; + uintptr_t size; + uint32_t link; + uint32_t info; + uintptr_t align; + uintptr_t entsize; +} ELFsectheader; + +#define ELFSECT_IDX_ABS 0xfff1 + +enum { + ELFSECT_TYPE_PROGBITS = 1, + ELFSECT_TYPE_SYMTAB = 2, + ELFSECT_TYPE_STRTAB = 3, + ELFSECT_TYPE_NOBITS = 8 +}; + +#define ELFSECT_FLAGS_WRITE 1 +#define ELFSECT_FLAGS_ALLOC 2 +#define ELFSECT_FLAGS_EXEC 4 + +typedef struct ELFsymbol { +#if LJ_64 + uint32_t name; + uint8_t info; + uint8_t other; + uint16_t sectidx; + uintptr_t value; + uint64_t size; +#else + uint32_t name; + uintptr_t value; + uint32_t size; + uint8_t info; + uint8_t other; + uint16_t sectidx; +#endif +} ELFsymbol; + +enum { + ELFSYM_TYPE_FUNC = 2, + ELFSYM_TYPE_FILE = 4, + ELFSYM_BIND_LOCAL = 0 << 4, + ELFSYM_BIND_GLOBAL = 1 << 4, +}; + +/* DWARF definitions. */ +#define DW_CIE_VERSION 1 + +enum { + DW_CFA_nop = 0x0, + DW_CFA_offset_extended = 0x5, + DW_CFA_def_cfa = 0xc, + DW_CFA_def_cfa_offset = 0xe, + DW_CFA_offset_extended_sf = 0x11, + DW_CFA_advance_loc = 0x40, + DW_CFA_offset = 0x80 +}; + +enum { + DW_EH_PE_udata4 = 3, + DW_EH_PE_textrel = 0x20 +}; + +enum { + DW_TAG_compile_unit = 0x11 +}; + +enum { + DW_children_no = 0, + DW_children_yes = 1 +}; + +enum { + DW_AT_name = 0x03, + DW_AT_stmt_list = 0x10, + DW_AT_low_pc = 0x11, + DW_AT_high_pc = 0x12 +}; + +enum { + DW_FORM_addr = 0x01, + DW_FORM_data4 = 0x06, + DW_FORM_string = 0x08 +}; + +enum { + DW_LNS_extended_op = 0, + DW_LNS_copy = 1, + DW_LNS_advance_pc = 2, + DW_LNS_advance_line = 3 +}; + +enum { + DW_LNE_end_sequence = 1, + DW_LNE_set_address = 2 +}; + +enum { +#if LJ_TARGET_X86 + DW_REG_AX, DW_REG_CX, DW_REG_DX, DW_REG_BX, + DW_REG_SP, DW_REG_BP, DW_REG_SI, DW_REG_DI, + DW_REG_RA, +#elif LJ_TARGET_X64 + /* Yes, the order is strange, but correct. */ + DW_REG_AX, DW_REG_DX, DW_REG_CX, DW_REG_BX, + DW_REG_SI, DW_REG_DI, DW_REG_BP, DW_REG_SP, + DW_REG_8, DW_REG_9, DW_REG_10, DW_REG_11, + DW_REG_12, DW_REG_13, DW_REG_14, DW_REG_15, + DW_REG_RA, +#elif LJ_TARGET_ARM + DW_REG_SP = 13, + DW_REG_RA = 14, +#elif LJ_TARGET_ARM64 + DW_REG_SP = 31, + DW_REG_RA = 30, +#elif LJ_TARGET_PPC + DW_REG_SP = 1, + DW_REG_RA = 65, + DW_REG_CR = 70, +#elif LJ_TARGET_MIPS + DW_REG_SP = 29, + DW_REG_RA = 31, +#else +#error "Unsupported target architecture" +#endif +}; + +/* Minimal list of sections for the in-memory ELF object. */ +enum { + GDBJIT_SECT_NULL, + GDBJIT_SECT_text, + GDBJIT_SECT_eh_frame, + GDBJIT_SECT_shstrtab, + GDBJIT_SECT_strtab, + GDBJIT_SECT_symtab, + GDBJIT_SECT_debug_info, + GDBJIT_SECT_debug_abbrev, + GDBJIT_SECT_debug_line, + GDBJIT_SECT__MAX +}; + +enum { + GDBJIT_SYM_UNDEF, + GDBJIT_SYM_FILE, + GDBJIT_SYM_FUNC, + GDBJIT_SYM__MAX +}; + +/* In-memory ELF object. */ +typedef struct GDBJITobj { + ELFheader hdr; /* ELF header. */ + ELFsectheader sect[GDBJIT_SECT__MAX]; /* ELF sections. */ + ELFsymbol sym[GDBJIT_SYM__MAX]; /* ELF symbol table. */ + uint8_t space[4096]; /* Space for various section data. */ +} GDBJITobj; + +/* Combined structure for GDB JIT entry and ELF object. */ +typedef struct GDBJITentryobj { + GDBJITentry entry; + size_t sz; + GDBJITobj obj; +} GDBJITentryobj; + +/* Template for in-memory ELF header. */ +static const ELFheader elfhdr_template = { + .emagic = { 0x7f, 'E', 'L', 'F' }, + .eclass = LJ_64 ? 2 : 1, + .eendian = LJ_ENDIAN_SELECT(1, 2), + .eversion = 1, +#if LJ_TARGET_LINUX + .eosabi = 0, /* Nope, it's not 3. */ +#elif defined(__FreeBSD__) + .eosabi = 9, +#elif defined(__NetBSD__) + .eosabi = 2, +#elif defined(__OpenBSD__) + .eosabi = 12, +#elif defined(__DragonFly__) + .eosabi = 0, +#elif LJ_TARGET_SOLARIS + .eosabi = 6, +#else + .eosabi = 0, +#endif + .eabiversion = 0, + .epad = { 0, 0, 0, 0, 0, 0, 0 }, + .type = 1, +#if LJ_TARGET_X86 + .machine = 3, +#elif LJ_TARGET_X64 + .machine = 62, +#elif LJ_TARGET_ARM + .machine = 40, +#elif LJ_TARGET_ARM64 + .machine = 183, +#elif LJ_TARGET_PPC + .machine = 20, +#elif LJ_TARGET_MIPS + .machine = 8, +#else +#error "Unsupported target architecture" +#endif + .version = 1, + .entry = 0, + .phofs = 0, + .shofs = offsetof(GDBJITobj, sect), + .flags = 0, + .ehsize = sizeof(ELFheader), + .phentsize = 0, + .phnum = 0, + .shentsize = sizeof(ELFsectheader), + .shnum = GDBJIT_SECT__MAX, + .shstridx = GDBJIT_SECT_shstrtab +}; + +/* -- In-memory ELF object generation ------------------------------------- */ + +/* Context for generating the ELF object for the GDB JIT API. */ +typedef struct GDBJITctx { + uint8_t *p; /* Pointer to next address in obj.space. */ + uint8_t *startp; /* Pointer to start address in obj.space. */ + GCtrace *T; /* Generate symbols for this trace. */ + uintptr_t mcaddr; /* Machine code address. */ + MSize szmcode; /* Size of machine code. */ + MSize spadjp; /* Stack adjustment for parent trace or interpreter. */ + MSize spadj; /* Stack adjustment for trace itself. */ + BCLine lineno; /* Starting line number. */ + const char *filename; /* Starting file name. */ + size_t objsize; /* Final size of ELF object. */ + GDBJITobj obj; /* In-memory ELF object. */ +} GDBJITctx; + +/* Add a zero-terminated string. */ +static uint32_t gdbjit_strz(GDBJITctx *ctx, const char *str) +{ + uint8_t *p = ctx->p; + uint32_t ofs = (uint32_t)(p - ctx->startp); + do { + *p++ = (uint8_t)*str; + } while (*str++); + ctx->p = p; + return ofs; +} + +/* Append a decimal number. */ +static void gdbjit_catnum(GDBJITctx *ctx, uint32_t n) +{ + if (n >= 10) { uint32_t m = n / 10; n = n % 10; gdbjit_catnum(ctx, m); } + *ctx->p++ = '0' + n; +} + +/* Add a SLEB128 value. */ +static void gdbjit_sleb128(GDBJITctx *ctx, int32_t v) +{ + uint8_t *p = ctx->p; + for (; (uint32_t)(v+0x40) >= 0x80; v >>= 7) + *p++ = (uint8_t)((v & 0x7f) | 0x80); + *p++ = (uint8_t)(v & 0x7f); + ctx->p = p; +} + +/* Shortcuts to generate DWARF structures. */ +#define DB(x) (*p++ = (x)) +#define DI8(x) (*(int8_t *)p = (x), p++) +#define DU16(x) (*(uint16_t *)p = (x), p += 2) +#define DU32(x) (*(uint32_t *)p = (x), p += 4) +#define DADDR(x) (*(uintptr_t *)p = (x), p += sizeof(uintptr_t)) +#define DUV(x) (p = (uint8_t *)lj_strfmt_wuleb128((char *)p, (x))) +#define DSV(x) (ctx->p = p, gdbjit_sleb128(ctx, (x)), p = ctx->p) +#define DSTR(str) (ctx->p = p, gdbjit_strz(ctx, (str)), p = ctx->p) +#define DALIGNNOP(s) while ((uintptr_t)p & ((s)-1)) *p++ = DW_CFA_nop +#define DSECT(name, stmt) \ + { uint32_t *szp_##name = (uint32_t *)p; p += 4; stmt \ + *szp_##name = (uint32_t)((p-(uint8_t *)szp_##name)-4); } \ + +/* Initialize ELF section headers. */ +static void LJ_FASTCALL gdbjit_secthdr(GDBJITctx *ctx) +{ + ELFsectheader *sect; + + *ctx->p++ = '\0'; /* Empty string at start of string table. */ + +#define SECTDEF(id, tp, al) \ + sect = &ctx->obj.sect[GDBJIT_SECT_##id]; \ + sect->name = gdbjit_strz(ctx, "." #id); \ + sect->type = ELFSECT_TYPE_##tp; \ + sect->align = (al) + + SECTDEF(text, NOBITS, 16); + sect->flags = ELFSECT_FLAGS_ALLOC|ELFSECT_FLAGS_EXEC; + sect->addr = ctx->mcaddr; + sect->ofs = 0; + sect->size = ctx->szmcode; + + SECTDEF(eh_frame, PROGBITS, sizeof(uintptr_t)); + sect->flags = ELFSECT_FLAGS_ALLOC; + + SECTDEF(shstrtab, STRTAB, 1); + SECTDEF(strtab, STRTAB, 1); + + SECTDEF(symtab, SYMTAB, sizeof(uintptr_t)); + sect->ofs = offsetof(GDBJITobj, sym); + sect->size = sizeof(ctx->obj.sym); + sect->link = GDBJIT_SECT_strtab; + sect->entsize = sizeof(ELFsymbol); + sect->info = GDBJIT_SYM_FUNC; + + SECTDEF(debug_info, PROGBITS, 1); + SECTDEF(debug_abbrev, PROGBITS, 1); + SECTDEF(debug_line, PROGBITS, 1); + +#undef SECTDEF +} + +/* Initialize symbol table. */ +static void LJ_FASTCALL gdbjit_symtab(GDBJITctx *ctx) +{ + ELFsymbol *sym; + + *ctx->p++ = '\0'; /* Empty string at start of string table. */ + + sym = &ctx->obj.sym[GDBJIT_SYM_FILE]; + sym->name = gdbjit_strz(ctx, "JIT mcode"); + sym->sectidx = ELFSECT_IDX_ABS; + sym->info = ELFSYM_TYPE_FILE|ELFSYM_BIND_LOCAL; + + sym = &ctx->obj.sym[GDBJIT_SYM_FUNC]; + sym->name = gdbjit_strz(ctx, "TRACE_"); ctx->p--; + gdbjit_catnum(ctx, ctx->T->traceno); *ctx->p++ = '\0'; + sym->sectidx = GDBJIT_SECT_text; + sym->value = 0; + sym->size = ctx->szmcode; + sym->info = ELFSYM_TYPE_FUNC|ELFSYM_BIND_GLOBAL; +} + +/* Initialize .eh_frame section. */ +static void LJ_FASTCALL gdbjit_ehframe(GDBJITctx *ctx) +{ + uint8_t *p = ctx->p; + uint8_t *framep = p; + + /* Emit DWARF EH CIE. */ + DSECT(CIE, + DU32(0); /* Offset to CIE itself. */ + DB(DW_CIE_VERSION); + DSTR("zR"); /* Augmentation. */ + DUV(1); /* Code alignment factor. */ + DSV(-(int32_t)sizeof(uintptr_t)); /* Data alignment factor. */ + DB(DW_REG_RA); /* Return address register. */ + DB(1); DB(DW_EH_PE_textrel|DW_EH_PE_udata4); /* Augmentation data. */ + DB(DW_CFA_def_cfa); DUV(DW_REG_SP); DUV(sizeof(uintptr_t)); +#if LJ_TARGET_PPC + DB(DW_CFA_offset_extended_sf); DB(DW_REG_RA); DSV(-1); +#else + DB(DW_CFA_offset|DW_REG_RA); DUV(1); +#endif + DALIGNNOP(sizeof(uintptr_t)); + ) + + /* Emit DWARF EH FDE. */ + DSECT(FDE, + DU32((uint32_t)(p-framep)); /* Offset to CIE. */ + DU32(0); /* Machine code offset relative to .text. */ + DU32(ctx->szmcode); /* Machine code length. */ + DB(0); /* Augmentation data. */ + /* Registers saved in CFRAME. */ +#if LJ_TARGET_X86 + DB(DW_CFA_offset|DW_REG_BP); DUV(2); + DB(DW_CFA_offset|DW_REG_DI); DUV(3); + DB(DW_CFA_offset|DW_REG_SI); DUV(4); + DB(DW_CFA_offset|DW_REG_BX); DUV(5); +#elif LJ_TARGET_X64 + DB(DW_CFA_offset|DW_REG_BP); DUV(2); + DB(DW_CFA_offset|DW_REG_BX); DUV(3); + DB(DW_CFA_offset|DW_REG_15); DUV(4); + DB(DW_CFA_offset|DW_REG_14); DUV(5); + /* Extra registers saved for JIT-compiled code. */ + DB(DW_CFA_offset|DW_REG_13); DUV(LJ_GC64 ? 10 : 9); + DB(DW_CFA_offset|DW_REG_12); DUV(LJ_GC64 ? 11 : 10); +#elif LJ_TARGET_ARM + { + int i; + for (i = 11; i >= 4; i--) { DB(DW_CFA_offset|i); DUV(2+(11-i)); } + } +#elif LJ_TARGET_ARM64 + { + int i; + DB(DW_CFA_offset|31); DUV(2); + for (i = 28; i >= 19; i--) { DB(DW_CFA_offset|i); DUV(3+(28-i)); } + for (i = 15; i >= 8; i--) { DB(DW_CFA_offset|32|i); DUV(28-i); } + } +#elif LJ_TARGET_PPC + { + int i; + DB(DW_CFA_offset_extended); DB(DW_REG_CR); DUV(55); + for (i = 14; i <= 31; i++) { + DB(DW_CFA_offset|i); DUV(37+(31-i)); + DB(DW_CFA_offset|32|i); DUV(2+2*(31-i)); + } + } +#elif LJ_TARGET_MIPS + { + int i; + DB(DW_CFA_offset|30); DUV(2); + for (i = 23; i >= 16; i--) { DB(DW_CFA_offset|i); DUV(26-i); } + for (i = 30; i >= 20; i -= 2) { DB(DW_CFA_offset|32|i); DUV(42-i); } + } +#else +#error "Unsupported target architecture" +#endif + if (ctx->spadjp != ctx->spadj) { /* Parent/interpreter stack frame size. */ + DB(DW_CFA_def_cfa_offset); DUV(ctx->spadjp); + DB(DW_CFA_advance_loc|1); /* Only an approximation. */ + } + DB(DW_CFA_def_cfa_offset); DUV(ctx->spadj); /* Trace stack frame size. */ + DALIGNNOP(sizeof(uintptr_t)); + ) + + ctx->p = p; +} + +/* Initialize .debug_info section. */ +static void LJ_FASTCALL gdbjit_debuginfo(GDBJITctx *ctx) +{ + uint8_t *p = ctx->p; + + DSECT(info, + DU16(2); /* DWARF version. */ + DU32(0); /* Abbrev offset. */ + DB(sizeof(uintptr_t)); /* Pointer size. */ + + DUV(1); /* Abbrev #1: DW_TAG_compile_unit. */ + DSTR(ctx->filename); /* DW_AT_name. */ + DADDR(ctx->mcaddr); /* DW_AT_low_pc. */ + DADDR(ctx->mcaddr + ctx->szmcode); /* DW_AT_high_pc. */ + DU32(0); /* DW_AT_stmt_list. */ + ) + + ctx->p = p; +} + +/* Initialize .debug_abbrev section. */ +static void LJ_FASTCALL gdbjit_debugabbrev(GDBJITctx *ctx) +{ + uint8_t *p = ctx->p; + + /* Abbrev #1: DW_TAG_compile_unit. */ + DUV(1); DUV(DW_TAG_compile_unit); + DB(DW_children_no); + DUV(DW_AT_name); DUV(DW_FORM_string); + DUV(DW_AT_low_pc); DUV(DW_FORM_addr); + DUV(DW_AT_high_pc); DUV(DW_FORM_addr); + DUV(DW_AT_stmt_list); DUV(DW_FORM_data4); + DB(0); DB(0); + + ctx->p = p; +} + +#define DLNE(op, s) (DB(DW_LNS_extended_op), DUV(1+(s)), DB((op))) + +/* Initialize .debug_line section. */ +static void LJ_FASTCALL gdbjit_debugline(GDBJITctx *ctx) +{ + uint8_t *p = ctx->p; + + DSECT(line, + DU16(2); /* DWARF version. */ + DSECT(header, + DB(1); /* Minimum instruction length. */ + DB(1); /* is_stmt. */ + DI8(0); /* Line base for special opcodes. */ + DB(2); /* Line range for special opcodes. */ + DB(3+1); /* Opcode base at DW_LNS_advance_line+1. */ + DB(0); DB(1); DB(1); /* Standard opcode lengths. */ + /* Directory table. */ + DB(0); + /* File name table. */ + DSTR(ctx->filename); DUV(0); DUV(0); DUV(0); + DB(0); + ) + + DLNE(DW_LNE_set_address, sizeof(uintptr_t)); DADDR(ctx->mcaddr); + if (ctx->lineno) { + DB(DW_LNS_advance_line); DSV(ctx->lineno-1); + } + DB(DW_LNS_copy); + DB(DW_LNS_advance_pc); DUV(ctx->szmcode); + DLNE(DW_LNE_end_sequence, 0); + ) + + ctx->p = p; +} + +#undef DLNE + +/* Undef shortcuts. */ +#undef DB +#undef DI8 +#undef DU16 +#undef DU32 +#undef DADDR +#undef DUV +#undef DSV +#undef DSTR +#undef DALIGNNOP +#undef DSECT + +/* Type of a section initializer callback. */ +typedef void (LJ_FASTCALL *GDBJITinitf)(GDBJITctx *ctx); + +/* Call section initializer and set the section offset and size. */ +static void gdbjit_initsect(GDBJITctx *ctx, int sect, GDBJITinitf initf) +{ + ctx->startp = ctx->p; + ctx->obj.sect[sect].ofs = (uintptr_t)((char *)ctx->p - (char *)&ctx->obj); + initf(ctx); + ctx->obj.sect[sect].size = (uintptr_t)(ctx->p - ctx->startp); +} + +#define SECTALIGN(p, a) \ + ((p) = (uint8_t *)(((uintptr_t)(p) + ((a)-1)) & ~(uintptr_t)((a)-1))) + +/* Build in-memory ELF object. */ +static void gdbjit_buildobj(GDBJITctx *ctx) +{ + GDBJITobj *obj = &ctx->obj; + /* Fill in ELF header and clear structures. */ + memcpy(&obj->hdr, &elfhdr_template, sizeof(ELFheader)); + memset(&obj->sect, 0, sizeof(ELFsectheader)*GDBJIT_SECT__MAX); + memset(&obj->sym, 0, sizeof(ELFsymbol)*GDBJIT_SYM__MAX); + /* Initialize sections. */ + ctx->p = obj->space; + gdbjit_initsect(ctx, GDBJIT_SECT_shstrtab, gdbjit_secthdr); + gdbjit_initsect(ctx, GDBJIT_SECT_strtab, gdbjit_symtab); + gdbjit_initsect(ctx, GDBJIT_SECT_debug_info, gdbjit_debuginfo); + gdbjit_initsect(ctx, GDBJIT_SECT_debug_abbrev, gdbjit_debugabbrev); + gdbjit_initsect(ctx, GDBJIT_SECT_debug_line, gdbjit_debugline); + SECTALIGN(ctx->p, sizeof(uintptr_t)); + gdbjit_initsect(ctx, GDBJIT_SECT_eh_frame, gdbjit_ehframe); + ctx->objsize = (size_t)((char *)ctx->p - (char *)obj); + lj_assertX(ctx->objsize < sizeof(GDBJITobj), "GDBJITobj overflow"); +} + +#undef SECTALIGN + +/* -- Interface to GDB JIT API -------------------------------------------- */ + +static int gdbjit_lock; + +static void gdbjit_lock_acquire() +{ + while (__sync_lock_test_and_set(&gdbjit_lock, 1)) { + /* Just spin; futexes or pthreads aren't worth the portability cost. */ + } +} + +static void gdbjit_lock_release() +{ + __sync_lock_release(&gdbjit_lock); +} + +/* Add new entry to GDB JIT symbol chain. */ +static void gdbjit_newentry(lua_State *L, GDBJITctx *ctx) +{ + /* Allocate memory for GDB JIT entry and ELF object. */ + MSize sz = (MSize)(sizeof(GDBJITentryobj) - sizeof(GDBJITobj) + ctx->objsize); + GDBJITentryobj *eo = lj_mem_newt(L, sz, GDBJITentryobj); + memcpy(&eo->obj, &ctx->obj, ctx->objsize); /* Copy ELF object. */ + eo->sz = sz; + ctx->T->gdbjit_entry = (void *)eo; + /* Link new entry to chain and register it. */ + eo->entry.prev_entry = NULL; + gdbjit_lock_acquire(); + eo->entry.next_entry = __jit_debug_descriptor.first_entry; + if (eo->entry.next_entry) + eo->entry.next_entry->prev_entry = &eo->entry; + eo->entry.symfile_addr = (const char *)&eo->obj; + eo->entry.symfile_size = ctx->objsize; + __jit_debug_descriptor.first_entry = &eo->entry; + __jit_debug_descriptor.relevant_entry = &eo->entry; + __jit_debug_descriptor.action_flag = GDBJIT_REGISTER; + __jit_debug_register_code(); + gdbjit_lock_release(); +} + +/* Add debug info for newly compiled trace and notify GDB. */ +void lj_gdbjit_addtrace(jit_State *J, GCtrace *T) +{ + GDBJITctx ctx; + GCproto *pt = &gcref(T->startpt)->pt; + TraceNo parent = T->ir[REF_BASE].op1; + const BCIns *startpc = mref(T->startpc, const BCIns); + ctx.T = T; + ctx.mcaddr = (uintptr_t)T->mcode; + ctx.szmcode = T->szmcode; + ctx.spadjp = CFRAME_SIZE_JIT + + (MSize)(parent ? traceref(J, parent)->spadjust : 0); + ctx.spadj = CFRAME_SIZE_JIT + T->spadjust; + lj_assertJ(startpc >= proto_bc(pt) && startpc < proto_bc(pt) + pt->sizebc, + "start PC out of range"); + ctx.lineno = lj_debug_line(pt, proto_bcpos(pt, startpc)); + ctx.filename = proto_chunknamestr(pt); + if (*ctx.filename == '@' || *ctx.filename == '=') + ctx.filename++; + else + ctx.filename = "(string)"; + gdbjit_buildobj(&ctx); + gdbjit_newentry(J->L, &ctx); +} + +/* Delete debug info for trace and notify GDB. */ +void lj_gdbjit_deltrace(jit_State *J, GCtrace *T) +{ + GDBJITentryobj *eo = (GDBJITentryobj *)T->gdbjit_entry; + if (eo) { + gdbjit_lock_acquire(); + if (eo->entry.prev_entry) + eo->entry.prev_entry->next_entry = eo->entry.next_entry; + else + __jit_debug_descriptor.first_entry = eo->entry.next_entry; + if (eo->entry.next_entry) + eo->entry.next_entry->prev_entry = eo->entry.prev_entry; + __jit_debug_descriptor.relevant_entry = &eo->entry; + __jit_debug_descriptor.action_flag = GDBJIT_UNREGISTER; + __jit_debug_register_code(); + gdbjit_lock_release(); + lj_mem_free(J2G(J), eo, eo->sz); + } +} + +#endif +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_gdbjit.h b/fluent-bit/lib/luajit-3065c9/src/lj_gdbjit.h new file mode 100644 index 00000000..f531be61 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_gdbjit.h @@ -0,0 +1,22 @@ +/* +** Client for the GDB JIT API. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#ifndef _LJ_GDBJIT_H +#define _LJ_GDBJIT_H + +#include "lj_obj.h" +#include "lj_jit.h" + +#if LJ_HASJIT && defined(LUAJIT_USE_GDBJIT) + +LJ_FUNC void lj_gdbjit_addtrace(jit_State *J, GCtrace *T); +LJ_FUNC void lj_gdbjit_deltrace(jit_State *J, GCtrace *T); + +#else +#define lj_gdbjit_addtrace(J, T) UNUSED(T) +#define lj_gdbjit_deltrace(J, T) UNUSED(T) +#endif + +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_ir.c b/fluent-bit/lib/luajit-3065c9/src/lj_ir.c new file mode 100644 index 00000000..65901510 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_ir.c @@ -0,0 +1,500 @@ +/* +** SSA IR (Intermediate Representation) emitter. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#define lj_ir_c +#define LUA_CORE + +/* For pointers to libc/libm functions. */ +#include +#include + +#include "lj_obj.h" + +#if LJ_HASJIT + +#include "lj_gc.h" +#include "lj_buf.h" +#include "lj_str.h" +#include "lj_tab.h" +#include "lj_ir.h" +#include "lj_jit.h" +#include "lj_ircall.h" +#include "lj_iropt.h" +#include "lj_trace.h" +#if LJ_HASFFI +#include "lj_ctype.h" +#include "lj_cdata.h" +#include "lj_carith.h" +#endif +#include "lj_vm.h" +#include "lj_strscan.h" +#include "lj_serialize.h" +#include "lj_strfmt.h" +#include "lj_prng.h" + +/* Some local macros to save typing. Undef'd at the end. */ +#define IR(ref) (&J->cur.ir[(ref)]) +#define fins (&J->fold.ins) + +/* Pass IR on to next optimization in chain (FOLD). */ +#define emitir(ot, a, b) (lj_ir_set(J, (ot), (a), (b)), lj_opt_fold(J)) + +/* -- IR tables ----------------------------------------------------------- */ + +/* IR instruction modes. */ +LJ_DATADEF const uint8_t lj_ir_mode[IR__MAX+1] = { +IRDEF(IRMODE) + 0 +}; + +/* IR type sizes. */ +LJ_DATADEF const uint8_t lj_ir_type_size[IRT__MAX+1] = { +#define IRTSIZE(name, size) size, +IRTDEF(IRTSIZE) +#undef IRTSIZE + 0 +}; + +/* C call info for CALL* instructions. */ +LJ_DATADEF const CCallInfo lj_ir_callinfo[] = { +#define IRCALLCI(cond, name, nargs, kind, type, flags) \ + { (ASMFunction)IRCALLCOND_##cond(name), \ + (nargs)|(CCI_CALL_##kind)|(IRT_##type<irbuf + J->irbotlim; + MSize szins = J->irtoplim - J->irbotlim; + if (szins) { + baseir = (IRIns *)lj_mem_realloc(J->L, baseir, szins*sizeof(IRIns), + 2*szins*sizeof(IRIns)); + J->irtoplim = J->irbotlim + 2*szins; + } else { + baseir = (IRIns *)lj_mem_realloc(J->L, NULL, 0, LJ_MIN_IRSZ*sizeof(IRIns)); + J->irbotlim = REF_BASE - LJ_MIN_IRSZ/4; + J->irtoplim = J->irbotlim + LJ_MIN_IRSZ; + } + J->cur.ir = J->irbuf = baseir - J->irbotlim; +} + +/* Grow IR buffer at the bottom or shift it up. */ +static void lj_ir_growbot(jit_State *J) +{ + IRIns *baseir = J->irbuf + J->irbotlim; + MSize szins = J->irtoplim - J->irbotlim; + lj_assertJ(szins != 0, "zero IR size"); + lj_assertJ(J->cur.nk == J->irbotlim || J->cur.nk-1 == J->irbotlim, + "unexpected IR growth"); + if (J->cur.nins + (szins >> 1) < J->irtoplim) { + /* More than half of the buffer is free on top: shift up by a quarter. */ + MSize ofs = szins >> 2; + memmove(baseir + ofs, baseir, (J->cur.nins - J->irbotlim)*sizeof(IRIns)); + J->irbotlim -= ofs; + J->irtoplim -= ofs; + J->cur.ir = J->irbuf = baseir - J->irbotlim; + } else { + /* Double the buffer size, but split the growth amongst top/bottom. */ + IRIns *newbase = lj_mem_newt(J->L, 2*szins*sizeof(IRIns), IRIns); + MSize ofs = szins >= 256 ? 128 : (szins >> 1); /* Limit bottom growth. */ + memcpy(newbase + ofs, baseir, (J->cur.nins - J->irbotlim)*sizeof(IRIns)); + lj_mem_free(G(J->L), baseir, szins*sizeof(IRIns)); + J->irbotlim -= ofs; + J->irtoplim = J->irbotlim + 2*szins; + J->cur.ir = J->irbuf = newbase - J->irbotlim; + } +} + +/* Emit IR without any optimizations. */ +TRef LJ_FASTCALL lj_ir_emit(jit_State *J) +{ + IRRef ref = lj_ir_nextins(J); + IRIns *ir = IR(ref); + IROp op = fins->o; + ir->prev = J->chain[op]; + J->chain[op] = (IRRef1)ref; + ir->o = op; + ir->op1 = fins->op1; + ir->op2 = fins->op2; + J->guardemit.irt |= fins->t.irt; + return TREF(ref, irt_t((ir->t = fins->t))); +} + +/* Emit call to a C function. */ +TRef lj_ir_call(jit_State *J, IRCallID id, ...) +{ + const CCallInfo *ci = &lj_ir_callinfo[id]; + uint32_t n = CCI_NARGS(ci); + TRef tr = TREF_NIL; + va_list argp; + va_start(argp, id); + if ((ci->flags & CCI_L)) n--; + if (n > 0) + tr = va_arg(argp, IRRef); + while (n-- > 1) + tr = emitir(IRT(IR_CARG, IRT_NIL), tr, va_arg(argp, IRRef)); + va_end(argp); + if (CCI_OP(ci) == IR_CALLS) + J->needsnap = 1; /* Need snapshot after call with side effect. */ + return emitir(CCI_OPTYPE(ci), tr, id); +} + +/* Load field of type t from GG_State + offset. Must be 32 bit aligned. */ +TRef lj_ir_ggfload(jit_State *J, IRType t, uintptr_t ofs) +{ + lj_assertJ((ofs & 3) == 0, "unaligned GG_State field offset"); + ofs >>= 2; + lj_assertJ(ofs >= IRFL__MAX && ofs <= 0x3ff, + "GG_State field offset breaks 10 bit FOLD key limit"); + lj_ir_set(J, IRT(IR_FLOAD, t), REF_NIL, ofs); + return lj_opt_fold(J); +} + +/* -- Interning of constants ---------------------------------------------- */ + +/* +** IR instructions for constants are kept between J->cur.nk >= ref < REF_BIAS. +** They are chained like all other instructions, but grow downwards. +** The are interned (like strings in the VM) to facilitate reference +** comparisons. The same constant must get the same reference. +*/ + +/* Get ref of next IR constant and optionally grow IR. +** Note: this may invalidate all IRIns *! +*/ +static LJ_AINLINE IRRef ir_nextk(jit_State *J) +{ + IRRef ref = J->cur.nk; + if (LJ_UNLIKELY(ref <= J->irbotlim)) lj_ir_growbot(J); + J->cur.nk = --ref; + return ref; +} + +/* Get ref of next 64 bit IR constant and optionally grow IR. +** Note: this may invalidate all IRIns *! +*/ +static LJ_AINLINE IRRef ir_nextk64(jit_State *J) +{ + IRRef ref = J->cur.nk - 2; + lj_assertJ(J->state != LJ_TRACE_ASM, "bad JIT state"); + if (LJ_UNLIKELY(ref < J->irbotlim)) lj_ir_growbot(J); + J->cur.nk = ref; + return ref; +} + +#if LJ_GC64 +#define ir_nextkgc ir_nextk64 +#else +#define ir_nextkgc ir_nextk +#endif + +/* Intern int32_t constant. */ +TRef LJ_FASTCALL lj_ir_kint(jit_State *J, int32_t k) +{ + IRIns *ir, *cir = J->cur.ir; + IRRef ref; + for (ref = J->chain[IR_KINT]; ref; ref = cir[ref].prev) + if (cir[ref].i == k) + goto found; + ref = ir_nextk(J); + ir = IR(ref); + ir->i = k; + ir->t.irt = IRT_INT; + ir->o = IR_KINT; + ir->prev = J->chain[IR_KINT]; + J->chain[IR_KINT] = (IRRef1)ref; +found: + return TREF(ref, IRT_INT); +} + +/* Intern 64 bit constant, given by its 64 bit pattern. */ +TRef lj_ir_k64(jit_State *J, IROp op, uint64_t u64) +{ + IRIns *ir, *cir = J->cur.ir; + IRRef ref; + IRType t = op == IR_KNUM ? IRT_NUM : IRT_I64; + for (ref = J->chain[op]; ref; ref = cir[ref].prev) + if (ir_k64(&cir[ref])->u64 == u64) + goto found; + ref = ir_nextk64(J); + ir = IR(ref); + ir[1].tv.u64 = u64; + ir->t.irt = t; + ir->o = op; + ir->op12 = 0; + ir->prev = J->chain[op]; + J->chain[op] = (IRRef1)ref; +found: + return TREF(ref, t); +} + +/* Intern FP constant, given by its 64 bit pattern. */ +TRef lj_ir_knum_u64(jit_State *J, uint64_t u64) +{ + return lj_ir_k64(J, IR_KNUM, u64); +} + +/* Intern 64 bit integer constant. */ +TRef lj_ir_kint64(jit_State *J, uint64_t u64) +{ + return lj_ir_k64(J, IR_KINT64, u64); +} + +/* Check whether a number is int and return it. -0 is NOT considered an int. */ +static int numistrueint(lua_Number n, int32_t *kp) +{ + int32_t k = lj_num2int(n); + if (n == (lua_Number)k) { + if (kp) *kp = k; + if (k == 0) { /* Special check for -0. */ + TValue tv; + setnumV(&tv, n); + if (tv.u32.hi != 0) + return 0; + } + return 1; + } + return 0; +} + +/* Intern number as int32_t constant if possible, otherwise as FP constant. */ +TRef lj_ir_knumint(jit_State *J, lua_Number n) +{ + int32_t k; + if (numistrueint(n, &k)) + return lj_ir_kint(J, k); + else + return lj_ir_knum(J, n); +} + +/* Intern GC object "constant". */ +TRef lj_ir_kgc(jit_State *J, GCobj *o, IRType t) +{ + IRIns *ir, *cir = J->cur.ir; + IRRef ref; + lj_assertJ(!isdead(J2G(J), o), "interning of dead GC object"); + for (ref = J->chain[IR_KGC]; ref; ref = cir[ref].prev) + if (ir_kgc(&cir[ref]) == o) + goto found; + ref = ir_nextkgc(J); + ir = IR(ref); + /* NOBARRIER: Current trace is a GC root. */ + ir->op12 = 0; + setgcref(ir[LJ_GC64].gcr, o); + ir->t.irt = (uint8_t)t; + ir->o = IR_KGC; + ir->prev = J->chain[IR_KGC]; + J->chain[IR_KGC] = (IRRef1)ref; +found: + return TREF(ref, t); +} + +/* Allocate GCtrace constant placeholder (no interning). */ +TRef lj_ir_ktrace(jit_State *J) +{ + IRRef ref = ir_nextkgc(J); + IRIns *ir = IR(ref); + lj_assertJ(irt_toitype_(IRT_P64) == LJ_TTRACE, "mismatched type mapping"); + ir->t.irt = IRT_P64; + ir->o = LJ_GC64 ? IR_KNUM : IR_KNULL; /* Not IR_KGC yet, but same size. */ + ir->op12 = 0; + ir->prev = 0; + return TREF(ref, IRT_P64); +} + +/* Intern pointer constant. */ +TRef lj_ir_kptr_(jit_State *J, IROp op, void *ptr) +{ + IRIns *ir, *cir = J->cur.ir; + IRRef ref; +#if LJ_64 && !LJ_GC64 + lj_assertJ((void *)(uintptr_t)u32ptr(ptr) == ptr, "out-of-range GC pointer"); +#endif + for (ref = J->chain[op]; ref; ref = cir[ref].prev) + if (ir_kptr(&cir[ref]) == ptr) + goto found; +#if LJ_GC64 + ref = ir_nextk64(J); +#else + ref = ir_nextk(J); +#endif + ir = IR(ref); + ir->op12 = 0; + setmref(ir[LJ_GC64].ptr, ptr); + ir->t.irt = IRT_PGC; + ir->o = op; + ir->prev = J->chain[op]; + J->chain[op] = (IRRef1)ref; +found: + return TREF(ref, IRT_PGC); +} + +/* Intern typed NULL constant. */ +TRef lj_ir_knull(jit_State *J, IRType t) +{ + IRIns *ir, *cir = J->cur.ir; + IRRef ref; + for (ref = J->chain[IR_KNULL]; ref; ref = cir[ref].prev) + if (irt_t(cir[ref].t) == t) + goto found; + ref = ir_nextk(J); + ir = IR(ref); + ir->i = 0; + ir->t.irt = (uint8_t)t; + ir->o = IR_KNULL; + ir->prev = J->chain[IR_KNULL]; + J->chain[IR_KNULL] = (IRRef1)ref; +found: + return TREF(ref, t); +} + +/* Intern key slot. */ +TRef lj_ir_kslot(jit_State *J, TRef key, IRRef slot) +{ + IRIns *ir, *cir = J->cur.ir; + IRRef2 op12 = IRREF2((IRRef1)key, (IRRef1)slot); + IRRef ref; + /* Const part is not touched by CSE/DCE, so 0-65535 is ok for IRMlit here. */ + lj_assertJ(tref_isk(key) && slot == (IRRef)(IRRef1)slot, + "out-of-range key/slot"); + for (ref = J->chain[IR_KSLOT]; ref; ref = cir[ref].prev) + if (cir[ref].op12 == op12) + goto found; + ref = ir_nextk(J); + ir = IR(ref); + ir->op12 = op12; + ir->t.irt = IRT_P32; + ir->o = IR_KSLOT; + ir->prev = J->chain[IR_KSLOT]; + J->chain[IR_KSLOT] = (IRRef1)ref; +found: + return TREF(ref, IRT_P32); +} + +/* -- Access to IR constants ---------------------------------------------- */ + +/* Copy value of IR constant. */ +void lj_ir_kvalue(lua_State *L, TValue *tv, const IRIns *ir) +{ + UNUSED(L); + lj_assertL(ir->o != IR_KSLOT, "unexpected KSLOT"); /* Common mistake. */ + switch (ir->o) { + case IR_KPRI: setpriV(tv, irt_toitype(ir->t)); break; + case IR_KINT: setintV(tv, ir->i); break; + case IR_KGC: setgcV(L, tv, ir_kgc(ir), irt_toitype(ir->t)); break; + case IR_KPTR: case IR_KKPTR: + setnumV(tv, (lua_Number)(uintptr_t)ir_kptr(ir)); + break; + case IR_KNULL: setintV(tv, 0); break; + case IR_KNUM: setnumV(tv, ir_knum(ir)->n); break; +#if LJ_HASFFI + case IR_KINT64: { + GCcdata *cd = lj_cdata_new_(L, CTID_INT64, 8); + *(uint64_t *)cdataptr(cd) = ir_kint64(ir)->u64; + setcdataV(L, tv, cd); + break; + } +#endif + default: lj_assertL(0, "bad IR constant op %d", ir->o); break; + } +} + +/* -- Convert IR operand types -------------------------------------------- */ + +/* Convert from string to number. */ +TRef LJ_FASTCALL lj_ir_tonumber(jit_State *J, TRef tr) +{ + if (!tref_isnumber(tr)) { + if (tref_isstr(tr)) + tr = emitir(IRTG(IR_STRTO, IRT_NUM), tr, 0); + else + lj_trace_err(J, LJ_TRERR_BADTYPE); + } + return tr; +} + +/* Convert from integer or string to number. */ +TRef LJ_FASTCALL lj_ir_tonum(jit_State *J, TRef tr) +{ + if (!tref_isnum(tr)) { + if (tref_isinteger(tr)) + tr = emitir(IRTN(IR_CONV), tr, IRCONV_NUM_INT); + else if (tref_isstr(tr)) + tr = emitir(IRTG(IR_STRTO, IRT_NUM), tr, 0); + else + lj_trace_err(J, LJ_TRERR_BADTYPE); + } + return tr; +} + +/* Convert from integer or number to string. */ +TRef LJ_FASTCALL lj_ir_tostr(jit_State *J, TRef tr) +{ + if (!tref_isstr(tr)) { + if (!tref_isnumber(tr)) + lj_trace_err(J, LJ_TRERR_BADTYPE); + tr = emitir(IRT(IR_TOSTR, IRT_STR), tr, + tref_isnum(tr) ? IRTOSTR_NUM : IRTOSTR_INT); + } + return tr; +} + +/* -- Miscellaneous IR ops ------------------------------------------------ */ + +/* Evaluate numeric comparison. */ +int lj_ir_numcmp(lua_Number a, lua_Number b, IROp op) +{ + switch (op) { + case IR_EQ: return (a == b); + case IR_NE: return (a != b); + case IR_LT: return (a < b); + case IR_GE: return (a >= b); + case IR_LE: return (a <= b); + case IR_GT: return (a > b); + case IR_ULT: return !(a >= b); + case IR_UGE: return !(a < b); + case IR_ULE: return !(a > b); + case IR_UGT: return !(a <= b); + default: lj_assertX(0, "bad IR op %d", op); return 0; + } +} + +/* Evaluate string comparison. */ +int lj_ir_strcmp(GCstr *a, GCstr *b, IROp op) +{ + int res = lj_str_cmp(a, b); + switch (op) { + case IR_LT: return (res < 0); + case IR_GE: return (res >= 0); + case IR_LE: return (res <= 0); + case IR_GT: return (res > 0); + default: lj_assertX(0, "bad IR op %d", op); return 0; + } +} + +/* Rollback IR to previous state. */ +void lj_ir_rollback(jit_State *J, IRRef ref) +{ + IRRef nins = J->cur.nins; + while (nins > ref) { + IRIns *ir; + nins--; + ir = IR(nins); + J->chain[ir->o] = ir->prev; + } + J->cur.nins = nins; +} + +#undef IR +#undef fins +#undef emitir + +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_ir.h b/fluent-bit/lib/luajit-3065c9/src/lj_ir.h new file mode 100644 index 00000000..ed492e93 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_ir.h @@ -0,0 +1,614 @@ +/* +** SSA IR (Intermediate Representation) format. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#ifndef _LJ_IR_H +#define _LJ_IR_H + +#include "lj_obj.h" + +/* -- IR instructions ----------------------------------------------------- */ + +/* IR instruction definition. Order matters, see below. ORDER IR */ +#define IRDEF(_) \ + /* Guarded assertions. */ \ + /* Must be properly aligned to flip opposites (^1) and (un)ordered (^4). */ \ + _(LT, N , ref, ref) \ + _(GE, N , ref, ref) \ + _(LE, N , ref, ref) \ + _(GT, N , ref, ref) \ + \ + _(ULT, N , ref, ref) \ + _(UGE, N , ref, ref) \ + _(ULE, N , ref, ref) \ + _(UGT, N , ref, ref) \ + \ + _(EQ, C , ref, ref) \ + _(NE, C , ref, ref) \ + \ + _(ABC, N , ref, ref) \ + _(RETF, S , ref, ref) \ + \ + /* Miscellaneous ops. */ \ + _(NOP, N , ___, ___) \ + _(BASE, N , lit, lit) \ + _(PVAL, N , lit, ___) \ + _(GCSTEP, S , ___, ___) \ + _(HIOP, S , ref, ref) \ + _(LOOP, S , ___, ___) \ + _(USE, S , ref, ___) \ + _(PHI, S , ref, ref) \ + _(RENAME, S , ref, lit) \ + _(PROF, S , ___, ___) \ + \ + /* Constants. */ \ + _(KPRI, N , ___, ___) \ + _(KINT, N , cst, ___) \ + _(KGC, N , cst, ___) \ + _(KPTR, N , cst, ___) \ + _(KKPTR, N , cst, ___) \ + _(KNULL, N , cst, ___) \ + _(KNUM, N , cst, ___) \ + _(KINT64, N , cst, ___) \ + _(KSLOT, N , ref, lit) \ + \ + /* Bit ops. */ \ + _(BNOT, N , ref, ___) \ + _(BSWAP, N , ref, ___) \ + _(BAND, C , ref, ref) \ + _(BOR, C , ref, ref) \ + _(BXOR, C , ref, ref) \ + _(BSHL, N , ref, ref) \ + _(BSHR, N , ref, ref) \ + _(BSAR, N , ref, ref) \ + _(BROL, N , ref, ref) \ + _(BROR, N , ref, ref) \ + \ + /* Arithmetic ops. ORDER ARITH */ \ + _(ADD, C , ref, ref) \ + _(SUB, N , ref, ref) \ + _(MUL, C , ref, ref) \ + _(DIV, N , ref, ref) \ + _(MOD, N , ref, ref) \ + _(POW, N , ref, ref) \ + _(NEG, N , ref, ref) \ + \ + _(ABS, N , ref, ref) \ + _(LDEXP, N , ref, ref) \ + _(MIN, C , ref, ref) \ + _(MAX, C , ref, ref) \ + _(FPMATH, N , ref, lit) \ + \ + /* Overflow-checking arithmetic ops. */ \ + _(ADDOV, CW, ref, ref) \ + _(SUBOV, NW, ref, ref) \ + _(MULOV, CW, ref, ref) \ + \ + /* Memory ops. A = array, H = hash, U = upvalue, F = field, S = stack. */ \ + \ + /* Memory references. */ \ + _(AREF, R , ref, ref) \ + _(HREFK, R , ref, ref) \ + _(HREF, L , ref, ref) \ + _(NEWREF, S , ref, ref) \ + _(UREFO, LW, ref, lit) \ + _(UREFC, LW, ref, lit) \ + _(FREF, R , ref, lit) \ + _(TMPREF, S , ref, lit) \ + _(STRREF, N , ref, ref) \ + _(LREF, L , ___, ___) \ + \ + /* Loads and Stores. These must be in the same order. */ \ + _(ALOAD, L , ref, ___) \ + _(HLOAD, L , ref, ___) \ + _(ULOAD, L , ref, ___) \ + _(FLOAD, L , ref, lit) \ + _(XLOAD, L , ref, lit) \ + _(SLOAD, L , lit, lit) \ + _(VLOAD, L , ref, lit) \ + _(ALEN, L , ref, ref) \ + \ + _(ASTORE, S , ref, ref) \ + _(HSTORE, S , ref, ref) \ + _(USTORE, S , ref, ref) \ + _(FSTORE, S , ref, ref) \ + _(XSTORE, S , ref, ref) \ + \ + /* Allocations. */ \ + _(SNEW, N , ref, ref) /* CSE is ok, not marked as A. */ \ + _(XSNEW, A , ref, ref) \ + _(TNEW, AW, lit, lit) \ + _(TDUP, AW, ref, ___) \ + _(CNEW, AW, ref, ref) \ + _(CNEWI, NW, ref, ref) /* CSE is ok, not marked as A. */ \ + \ + /* Buffer operations. */ \ + _(BUFHDR, L , ref, lit) \ + _(BUFPUT, LW, ref, ref) \ + _(BUFSTR, AW, ref, ref) \ + \ + /* Barriers. */ \ + _(TBAR, S , ref, ___) \ + _(OBAR, S , ref, ref) \ + _(XBAR, S , ___, ___) \ + \ + /* Type conversions. */ \ + _(CONV, N , ref, lit) \ + _(TOBIT, N , ref, ref) \ + _(TOSTR, N , ref, lit) \ + _(STRTO, N , ref, ___) \ + \ + /* Calls. */ \ + _(CALLN, NW, ref, lit) \ + _(CALLA, AW, ref, lit) \ + _(CALLL, LW, ref, lit) \ + _(CALLS, S , ref, lit) \ + _(CALLXS, S , ref, ref) \ + _(CARG, N , ref, ref) \ + \ + /* End of list. */ + +/* IR opcodes (max. 256). */ +typedef enum { +#define IRENUM(name, m, m1, m2) IR_##name, +IRDEF(IRENUM) +#undef IRENUM + IR__MAX +} IROp; + +/* Stored opcode. */ +typedef uint8_t IROp1; + +LJ_STATIC_ASSERT(((int)IR_EQ^1) == (int)IR_NE); +LJ_STATIC_ASSERT(((int)IR_LT^1) == (int)IR_GE); +LJ_STATIC_ASSERT(((int)IR_LE^1) == (int)IR_GT); +LJ_STATIC_ASSERT(((int)IR_LT^3) == (int)IR_GT); +LJ_STATIC_ASSERT(((int)IR_LT^4) == (int)IR_ULT); + +/* Delta between xLOAD and xSTORE. */ +#define IRDELTA_L2S ((int)IR_ASTORE - (int)IR_ALOAD) + +LJ_STATIC_ASSERT((int)IR_HLOAD + IRDELTA_L2S == (int)IR_HSTORE); +LJ_STATIC_ASSERT((int)IR_ULOAD + IRDELTA_L2S == (int)IR_USTORE); +LJ_STATIC_ASSERT((int)IR_FLOAD + IRDELTA_L2S == (int)IR_FSTORE); +LJ_STATIC_ASSERT((int)IR_XLOAD + IRDELTA_L2S == (int)IR_XSTORE); + +/* -- Named IR literals --------------------------------------------------- */ + +/* FPMATH sub-functions. ORDER FPM. */ +#define IRFPMDEF(_) \ + _(FLOOR) _(CEIL) _(TRUNC) /* Must be first and in this order. */ \ + _(SQRT) _(LOG) _(LOG2) \ + _(OTHER) + +typedef enum { +#define FPMENUM(name) IRFPM_##name, +IRFPMDEF(FPMENUM) +#undef FPMENUM + IRFPM__MAX +} IRFPMathOp; + +/* FLOAD fields. */ +#define IRFLDEF(_) \ + _(STR_LEN, offsetof(GCstr, len)) \ + _(FUNC_ENV, offsetof(GCfunc, l.env)) \ + _(FUNC_PC, offsetof(GCfunc, l.pc)) \ + _(FUNC_FFID, offsetof(GCfunc, l.ffid)) \ + _(THREAD_ENV, offsetof(lua_State, env)) \ + _(TAB_META, offsetof(GCtab, metatable)) \ + _(TAB_ARRAY, offsetof(GCtab, array)) \ + _(TAB_NODE, offsetof(GCtab, node)) \ + _(TAB_ASIZE, offsetof(GCtab, asize)) \ + _(TAB_HMASK, offsetof(GCtab, hmask)) \ + _(TAB_NOMM, offsetof(GCtab, nomm)) \ + _(UDATA_META, offsetof(GCudata, metatable)) \ + _(UDATA_UDTYPE, offsetof(GCudata, udtype)) \ + _(UDATA_FILE, sizeof(GCudata)) \ + _(SBUF_W, sizeof(GCudata) + offsetof(SBufExt, w)) \ + _(SBUF_E, sizeof(GCudata) + offsetof(SBufExt, e)) \ + _(SBUF_B, sizeof(GCudata) + offsetof(SBufExt, b)) \ + _(SBUF_L, sizeof(GCudata) + offsetof(SBufExt, L)) \ + _(SBUF_REF, sizeof(GCudata) + offsetof(SBufExt, cowref)) \ + _(SBUF_R, sizeof(GCudata) + offsetof(SBufExt, r)) \ + _(CDATA_CTYPEID, offsetof(GCcdata, ctypeid)) \ + _(CDATA_PTR, sizeof(GCcdata)) \ + _(CDATA_INT, sizeof(GCcdata)) \ + _(CDATA_INT64, sizeof(GCcdata)) \ + _(CDATA_INT64_4, sizeof(GCcdata) + 4) + +typedef enum { +#define FLENUM(name, ofs) IRFL_##name, +IRFLDEF(FLENUM) +#undef FLENUM + IRFL__MAX +} IRFieldID; + +/* TMPREF mode bits, stored in op2. */ +#define IRTMPREF_IN1 0x01 /* First input value. */ +#define IRTMPREF_OUT1 0x02 /* First output value. */ +#define IRTMPREF_OUT2 0x04 /* Second output value. */ + +/* SLOAD mode bits, stored in op2. */ +#define IRSLOAD_PARENT 0x01 /* Coalesce with parent trace. */ +#define IRSLOAD_FRAME 0x02 /* Load 32 bits of ftsz. */ +#define IRSLOAD_TYPECHECK 0x04 /* Needs type check. */ +#define IRSLOAD_CONVERT 0x08 /* Number to integer conversion. */ +#define IRSLOAD_READONLY 0x10 /* Read-only, omit slot store. */ +#define IRSLOAD_INHERIT 0x20 /* Inherited by exits/side traces. */ +#define IRSLOAD_KEYINDEX 0x40 /* Table traversal key index. */ + +/* XLOAD mode bits, stored in op2. */ +#define IRXLOAD_READONLY 0x01 /* Load from read-only data. */ +#define IRXLOAD_VOLATILE 0x02 /* Load from volatile data. */ +#define IRXLOAD_UNALIGNED 0x04 /* Unaligned load. */ + +/* BUFHDR mode, stored in op2. */ +#define IRBUFHDR_RESET 0 /* Reset buffer. */ +#define IRBUFHDR_APPEND 1 /* Append to buffer. */ +#define IRBUFHDR_WRITE 2 /* Write to string buffer. */ + +/* CONV mode, stored in op2. */ +#define IRCONV_SRCMASK 0x001f /* Source IRType. */ +#define IRCONV_DSTMASK 0x03e0 /* Dest. IRType (also in ir->t). */ +#define IRCONV_DSH 5 +#define IRCONV_NUM_INT ((IRT_NUM<>2)&3)) +#define irm_iscomm(m) ((m) & IRM_C) +#define irm_kind(m) ((m) & IRM_S) + +#define IRMODE(name, m, m1, m2) (((IRM##m1)|((IRM##m2)<<2)|(IRM_##m))^IRM_W), + +LJ_DATA const uint8_t lj_ir_mode[IR__MAX+1]; + +/* -- IR instruction types ------------------------------------------------ */ + +#define IRTSIZE_PGC (LJ_GC64 ? 8 : 4) + +/* Map of itypes to non-negative numbers and their sizes. ORDER LJ_T. +** LJ_TUPVAL/LJ_TTRACE never appear in a TValue. Use these itypes for +** IRT_P32 and IRT_P64, which never escape the IR. +** The various integers are only used in the IR and can only escape to +** a TValue after implicit or explicit conversion. Their types must be +** contiguous and next to IRT_NUM (see the typerange macros below). +*/ +#define IRTDEF(_) \ + _(NIL, 4) _(FALSE, 4) _(TRUE, 4) _(LIGHTUD, LJ_64 ? 8 : 4) \ + _(STR, IRTSIZE_PGC) _(P32, 4) _(THREAD, IRTSIZE_PGC) _(PROTO, IRTSIZE_PGC) \ + _(FUNC, IRTSIZE_PGC) _(P64, 8) _(CDATA, IRTSIZE_PGC) _(TAB, IRTSIZE_PGC) \ + _(UDATA, IRTSIZE_PGC) \ + _(FLOAT, 4) _(NUM, 8) _(I8, 1) _(U8, 1) _(I16, 2) _(U16, 2) \ + _(INT, 4) _(U32, 4) _(I64, 8) _(U64, 8) \ + _(SOFTFP, 4) /* There is room for 8 more types. */ + +/* IR result type and flags (8 bit). */ +typedef enum { +#define IRTENUM(name, size) IRT_##name, +IRTDEF(IRTENUM) +#undef IRTENUM + IRT__MAX, + + /* Native pointer type and the corresponding integer type. */ + IRT_PTR = LJ_64 ? IRT_P64 : IRT_P32, + IRT_PGC = LJ_GC64 ? IRT_P64 : IRT_P32, + IRT_IGC = LJ_GC64 ? IRT_I64 : IRT_INT, + IRT_INTP = LJ_64 ? IRT_I64 : IRT_INT, + IRT_UINTP = LJ_64 ? IRT_U64 : IRT_U32, + + /* Additional flags. */ + IRT_MARK = 0x20, /* Marker for misc. purposes. */ + IRT_ISPHI = 0x40, /* Instruction is left or right PHI operand. */ + IRT_GUARD = 0x80, /* Instruction is a guard. */ + + /* Masks. */ + IRT_TYPE = 0x1f, + IRT_T = 0xff +} IRType; + +#define irtype_ispri(irt) ((uint32_t)(irt) <= IRT_TRUE) + +/* Stored IRType. */ +typedef struct IRType1 { uint8_t irt; } IRType1; + +#define IRT(o, t) ((uint32_t)(((o)<<8) | (t))) +#define IRTI(o) (IRT((o), IRT_INT)) +#define IRTN(o) (IRT((o), IRT_NUM)) +#define IRTG(o, t) (IRT((o), IRT_GUARD|(t))) +#define IRTGI(o) (IRT((o), IRT_GUARD|IRT_INT)) + +#define irt_t(t) ((IRType)(t).irt) +#define irt_type(t) ((IRType)((t).irt & IRT_TYPE)) +#define irt_sametype(t1, t2) ((((t1).irt ^ (t2).irt) & IRT_TYPE) == 0) +#define irt_typerange(t, first, last) \ + ((uint32_t)((t).irt & IRT_TYPE) - (uint32_t)(first) <= (uint32_t)(last-first)) + +#define irt_isnil(t) (irt_type(t) == IRT_NIL) +#define irt_ispri(t) ((uint32_t)irt_type(t) <= IRT_TRUE) +#define irt_islightud(t) (irt_type(t) == IRT_LIGHTUD) +#define irt_isstr(t) (irt_type(t) == IRT_STR) +#define irt_istab(t) (irt_type(t) == IRT_TAB) +#define irt_iscdata(t) (irt_type(t) == IRT_CDATA) +#define irt_isfloat(t) (irt_type(t) == IRT_FLOAT) +#define irt_isnum(t) (irt_type(t) == IRT_NUM) +#define irt_isint(t) (irt_type(t) == IRT_INT) +#define irt_isi8(t) (irt_type(t) == IRT_I8) +#define irt_isu8(t) (irt_type(t) == IRT_U8) +#define irt_isi16(t) (irt_type(t) == IRT_I16) +#define irt_isu16(t) (irt_type(t) == IRT_U16) +#define irt_isu32(t) (irt_type(t) == IRT_U32) +#define irt_isi64(t) (irt_type(t) == IRT_I64) +#define irt_isu64(t) (irt_type(t) == IRT_U64) + +#define irt_isfp(t) (irt_isnum(t) || irt_isfloat(t)) +#define irt_isinteger(t) (irt_typerange((t), IRT_I8, IRT_INT)) +#define irt_isgcv(t) (irt_typerange((t), IRT_STR, IRT_UDATA)) +#define irt_isaddr(t) (irt_typerange((t), IRT_LIGHTUD, IRT_UDATA)) +#define irt_isint64(t) (irt_typerange((t), IRT_I64, IRT_U64)) + +#if LJ_GC64 +/* Include IRT_NIL, so IR(ASMREF_L) (aka REF_NIL) is considered 64 bit. */ +#define IRT_IS64 \ + ((1u<> irt_type(t)) & 1) +#define irt_is64orfp(t) (((IRT_IS64|(1u<>irt_type(t)) & 1) + +#define irt_size(t) (lj_ir_type_size[irt_t((t))]) + +LJ_DATA const uint8_t lj_ir_type_size[]; + +static LJ_AINLINE IRType itype2irt(const TValue *tv) +{ + if (tvisint(tv)) + return IRT_INT; + else if (tvisnum(tv)) + return IRT_NUM; +#if LJ_64 && !LJ_GC64 + else if (tvislightud(tv)) + return IRT_LIGHTUD; +#endif + else + return (IRType)~itype(tv); +} + +static LJ_AINLINE uint32_t irt_toitype_(IRType t) +{ + lj_assertX(!LJ_64 || LJ_GC64 || t != IRT_LIGHTUD, + "no plain type tag for lightuserdata"); + if (LJ_DUALNUM && t > IRT_NUM) { + return LJ_TISNUM; + } else { + lj_assertX(t <= IRT_NUM, "no plain type tag for IR type %d", t); + return ~(uint32_t)t; + } +} + +#define irt_toitype(t) irt_toitype_(irt_type((t))) + +#define irt_isguard(t) ((t).irt & IRT_GUARD) +#define irt_ismarked(t) ((t).irt & IRT_MARK) +#define irt_setmark(t) ((t).irt |= IRT_MARK) +#define irt_clearmark(t) ((t).irt &= ~IRT_MARK) +#define irt_isphi(t) ((t).irt & IRT_ISPHI) +#define irt_setphi(t) ((t).irt |= IRT_ISPHI) +#define irt_clearphi(t) ((t).irt &= ~IRT_ISPHI) + +/* Stored combined IR opcode and type. */ +typedef uint16_t IROpT; + +/* -- IR references ------------------------------------------------------- */ + +/* IR references. */ +typedef uint16_t IRRef1; /* One stored reference. */ +typedef uint32_t IRRef2; /* Two stored references. */ +typedef uint32_t IRRef; /* Used to pass around references. */ + +/* Fixed references. */ +enum { + REF_BIAS = 0x8000, + REF_TRUE = REF_BIAS-3, + REF_FALSE = REF_BIAS-2, + REF_NIL = REF_BIAS-1, /* \--- Constants grow downwards. */ + REF_BASE = REF_BIAS, /* /--- IR grows upwards. */ + REF_FIRST = REF_BIAS+1, + REF_DROP = 0xffff +}; + +/* Note: IRMlit operands must be < REF_BIAS, too! +** This allows for fast and uniform manipulation of all operands +** without looking up the operand mode in lj_ir_mode: +** - CSE calculates the maximum reference of two operands. +** This must work with mixed reference/literal operands, too. +** - DCE marking only checks for operand >= REF_BIAS. +** - LOOP needs to substitute reference operands. +** Constant references and literals must not be modified. +*/ + +#define IRREF2(lo, hi) ((IRRef2)(lo) | ((IRRef2)(hi) << 16)) + +#define irref_isk(ref) ((ref) < REF_BIAS) + +/* Tagged IR references (32 bit). +** +** +-------+-------+---------------+ +** | irt | flags | ref | +** +-------+-------+---------------+ +** +** The tag holds a copy of the IRType and speeds up IR type checks. +*/ +typedef uint32_t TRef; + +#define TREF_REFMASK 0x0000ffff +#define TREF_FRAME 0x00010000 +#define TREF_CONT 0x00020000 +#define TREF_KEYINDEX 0x00100000 + +#define TREF(ref, t) ((TRef)((ref) + ((t)<<24))) + +#define tref_ref(tr) ((IRRef1)(tr)) +#define tref_t(tr) ((IRType)((tr)>>24)) +#define tref_type(tr) ((IRType)(((tr)>>24) & IRT_TYPE)) +#define tref_typerange(tr, first, last) \ + ((((tr)>>24) & IRT_TYPE) - (TRef)(first) <= (TRef)(last-first)) + +#define tref_istype(tr, t) (((tr) & (IRT_TYPE<<24)) == ((t)<<24)) +#define tref_isnil(tr) (tref_istype((tr), IRT_NIL)) +#define tref_isfalse(tr) (tref_istype((tr), IRT_FALSE)) +#define tref_istrue(tr) (tref_istype((tr), IRT_TRUE)) +#define tref_islightud(tr) (tref_istype((tr), IRT_LIGHTUD)) +#define tref_isstr(tr) (tref_istype((tr), IRT_STR)) +#define tref_isfunc(tr) (tref_istype((tr), IRT_FUNC)) +#define tref_iscdata(tr) (tref_istype((tr), IRT_CDATA)) +#define tref_istab(tr) (tref_istype((tr), IRT_TAB)) +#define tref_isudata(tr) (tref_istype((tr), IRT_UDATA)) +#define tref_isnum(tr) (tref_istype((tr), IRT_NUM)) +#define tref_isint(tr) (tref_istype((tr), IRT_INT)) + +#define tref_isbool(tr) (tref_typerange((tr), IRT_FALSE, IRT_TRUE)) +#define tref_ispri(tr) (tref_typerange((tr), IRT_NIL, IRT_TRUE)) +#define tref_istruecond(tr) (!tref_typerange((tr), IRT_NIL, IRT_FALSE)) +#define tref_isinteger(tr) (tref_typerange((tr), IRT_I8, IRT_INT)) +#define tref_isnumber(tr) (tref_typerange((tr), IRT_NUM, IRT_INT)) +#define tref_isnumber_str(tr) (tref_isnumber((tr)) || tref_isstr((tr))) +#define tref_isgcv(tr) (tref_typerange((tr), IRT_STR, IRT_UDATA)) + +#define tref_isk(tr) (irref_isk(tref_ref((tr)))) +#define tref_isk2(tr1, tr2) (irref_isk(tref_ref((tr1) | (tr2)))) + +#define TREF_PRI(t) (TREF(REF_NIL-(t), (t))) +#define TREF_NIL (TREF_PRI(IRT_NIL)) +#define TREF_FALSE (TREF_PRI(IRT_FALSE)) +#define TREF_TRUE (TREF_PRI(IRT_TRUE)) + +/* -- IR format ----------------------------------------------------------- */ + +/* IR instruction format (64 bit). +** +** 16 16 8 8 8 8 +** +-------+-------+---+---+---+---+ +** | op1 | op2 | t | o | r | s | +** +-------+-------+---+---+---+---+ +** | op12/i/gco32 | ot | prev | (alternative fields in union) +** +-------+-------+---+---+---+---+ +** | TValue/gco64 | (2nd IR slot for 64 bit constants) +** +---------------+-------+-------+ +** 32 16 16 +** +** prev is only valid prior to register allocation and then reused for r + s. +*/ + +typedef union IRIns { + struct { + LJ_ENDIAN_LOHI( + IRRef1 op1; /* IR operand 1. */ + , IRRef1 op2; /* IR operand 2. */ + ) + IROpT ot; /* IR opcode and type (overlaps t and o). */ + IRRef1 prev; /* Previous ins in same chain (overlaps r and s). */ + }; + struct { + IRRef2 op12; /* IR operand 1 and 2 (overlaps op1 and op2). */ + LJ_ENDIAN_LOHI( + IRType1 t; /* IR type. */ + , IROp1 o; /* IR opcode. */ + ) + LJ_ENDIAN_LOHI( + uint8_t r; /* Register allocation (overlaps prev). */ + , uint8_t s; /* Spill slot allocation (overlaps prev). */ + ) + }; + int32_t i; /* 32 bit signed integer literal (overlaps op12). */ + GCRef gcr; /* GCobj constant (overlaps op12 or entire slot). */ + MRef ptr; /* Pointer constant (overlaps op12 or entire slot). */ + TValue tv; /* TValue constant (overlaps entire slot). */ +} IRIns; + +#define ir_isk64(ir) \ + ((ir)->o == IR_KNUM || (ir)->o == IR_KINT64 || \ + (LJ_GC64 && \ + ((ir)->o == IR_KGC || (ir)->o == IR_KPTR || (ir)->o == IR_KKPTR))) + +#define ir_kgc(ir) check_exp((ir)->o == IR_KGC, gcref((ir)[LJ_GC64].gcr)) +#define ir_kstr(ir) (gco2str(ir_kgc((ir)))) +#define ir_ktab(ir) (gco2tab(ir_kgc((ir)))) +#define ir_kfunc(ir) (gco2func(ir_kgc((ir)))) +#define ir_kcdata(ir) (gco2cd(ir_kgc((ir)))) +#define ir_knum(ir) check_exp((ir)->o == IR_KNUM, &(ir)[1].tv) +#define ir_kint64(ir) check_exp((ir)->o == IR_KINT64, &(ir)[1].tv) +#define ir_k64(ir) check_exp(ir_isk64(ir), &(ir)[1].tv) +#define ir_kptr(ir) \ + check_exp((ir)->o == IR_KPTR || (ir)->o == IR_KKPTR, \ + mref((ir)[LJ_GC64].ptr, void)) + +/* A store or any other op with a non-weak guard has a side-effect. */ +static LJ_AINLINE int ir_sideeff(IRIns *ir) +{ + return (((ir->t.irt | ~IRT_GUARD) & lj_ir_mode[ir->o]) >= IRM_S); +} + +LJ_STATIC_ASSERT((int)IRT_GUARD == (int)IRM_W); + +/* Replace IR instruction with NOP. */ +static LJ_AINLINE void lj_ir_nop(IRIns *ir) +{ + ir->ot = IRT(IR_NOP, IRT_NIL); + ir->op1 = ir->op2 = 0; + ir->prev = 0; +} + +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_ircall.h b/fluent-bit/lib/luajit-3065c9/src/lj_ircall.h new file mode 100644 index 00000000..67fb58ae --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_ircall.h @@ -0,0 +1,383 @@ +/* +** IR CALL* instruction definitions. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#ifndef _LJ_IRCALL_H +#define _LJ_IRCALL_H + +#include "lj_obj.h" +#include "lj_ir.h" +#include "lj_jit.h" + +/* C call info for CALL* instructions. */ +typedef struct CCallInfo { + ASMFunction func; /* Function pointer. */ + uint32_t flags; /* Number of arguments and flags. */ +} CCallInfo; + +#define CCI_NARGS(ci) ((ci)->flags & 0xff) /* # of args. */ +#define CCI_NARGS_MAX 32 /* Max. # of args. */ + +#define CCI_OTSHIFT 16 +#define CCI_OPTYPE(ci) ((ci)->flags >> CCI_OTSHIFT) /* Get op/type. */ +#define CCI_TYPE(ci) (((ci)->flags>>CCI_OTSHIFT) & IRT_TYPE) +#define CCI_OPSHIFT 24 +#define CCI_OP(ci) ((ci)->flags >> CCI_OPSHIFT) /* Get op. */ + +#define CCI_CALL_N (IR_CALLN << CCI_OPSHIFT) +#define CCI_CALL_A (IR_CALLA << CCI_OPSHIFT) +#define CCI_CALL_L (IR_CALLL << CCI_OPSHIFT) +#define CCI_CALL_S (IR_CALLS << CCI_OPSHIFT) +#define CCI_CALL_FN (CCI_CALL_N|CCI_CC_FASTCALL) +#define CCI_CALL_FA (CCI_CALL_A|CCI_CC_FASTCALL) +#define CCI_CALL_FL (CCI_CALL_L|CCI_CC_FASTCALL) +#define CCI_CALL_FS (CCI_CALL_S|CCI_CC_FASTCALL) + +/* C call info flags. */ +#define CCI_T (IRT_GUARD << CCI_OTSHIFT) /* May throw. */ +#define CCI_L 0x0100 /* Implicit L arg. */ +#define CCI_CASTU64 0x0200 /* Cast u64 result to number. */ +#define CCI_NOFPRCLOBBER 0x0400 /* Does not clobber any FPRs. */ +#define CCI_VARARG 0x0800 /* Vararg function. */ + +#define CCI_CC_MASK 0x3000 /* Calling convention mask. */ +#define CCI_CC_SHIFT 12 +/* ORDER CC */ +#define CCI_CC_CDECL 0x0000 /* Default cdecl calling convention. */ +#define CCI_CC_THISCALL 0x1000 /* Thiscall calling convention. */ +#define CCI_CC_FASTCALL 0x2000 /* Fastcall calling convention. */ +#define CCI_CC_STDCALL 0x3000 /* Stdcall calling convention. */ + +/* Extra args for SOFTFP, SPLIT 64 bit. */ +#define CCI_XARGS_SHIFT 14 +#define CCI_XARGS(ci) (((ci)->flags >> CCI_XARGS_SHIFT) & 3) +#define CCI_XA (1u << CCI_XARGS_SHIFT) + +#if LJ_SOFTFP32 || (LJ_32 && LJ_HASFFI) +#define CCI_XNARGS(ci) (CCI_NARGS((ci)) + CCI_XARGS((ci))) +#else +#define CCI_XNARGS(ci) CCI_NARGS((ci)) +#endif + +/* Helpers for conditional function definitions. */ +#define IRCALLCOND_ANY(x) x + +#if LJ_TARGET_X86ORX64 +#define IRCALLCOND_FPMATH(x) NULL +#else +#define IRCALLCOND_FPMATH(x) x +#endif + +#if LJ_SOFTFP +#define IRCALLCOND_SOFTFP(x) x +#if LJ_HASFFI +#define IRCALLCOND_SOFTFP_FFI(x) x +#else +#define IRCALLCOND_SOFTFP_FFI(x) NULL +#endif +#else +#define IRCALLCOND_SOFTFP(x) NULL +#define IRCALLCOND_SOFTFP_FFI(x) NULL +#endif + +#if LJ_SOFTFP && LJ_TARGET_MIPS +#define IRCALLCOND_SOFTFP_MIPS(x) x +#else +#define IRCALLCOND_SOFTFP_MIPS(x) NULL +#endif + +#if LJ_SOFTFP && LJ_TARGET_MIPS64 +#define IRCALLCOND_SOFTFP_MIPS64(x) x +#else +#define IRCALLCOND_SOFTFP_MIPS64(x) NULL +#endif + +#define LJ_NEED_FP64 (LJ_TARGET_ARM || LJ_TARGET_PPC || LJ_TARGET_MIPS) + +#if LJ_HASFFI && (LJ_SOFTFP || LJ_NEED_FP64) +#define IRCALLCOND_FP64_FFI(x) x +#else +#define IRCALLCOND_FP64_FFI(x) NULL +#endif + +#if LJ_HASFFI +#define IRCALLCOND_FFI(x) x +#if LJ_32 +#define IRCALLCOND_FFI32(x) x +#else +#define IRCALLCOND_FFI32(x) NULL +#endif +#else +#define IRCALLCOND_FFI(x) NULL +#define IRCALLCOND_FFI32(x) NULL +#endif + +#if LJ_HASBUFFER +#define IRCALLCOND_BUFFER(x) x +#else +#define IRCALLCOND_BUFFER(x) NULL +#endif + +#if LJ_HASBUFFER && LJ_HASFFI +#define IRCALLCOND_BUFFFI(x) x +#else +#define IRCALLCOND_BUFFFI(x) NULL +#endif + +#if LJ_SOFTFP +#define XA_FP CCI_XA +#define XA2_FP (CCI_XA+CCI_XA) +#else +#define XA_FP 0 +#define XA2_FP 0 +#endif + +#if LJ_SOFTFP32 +#define XA_FP32 CCI_XA +#define XA2_FP32 (CCI_XA+CCI_XA) +#else +#define XA_FP32 0 +#define XA2_FP32 0 +#endif + +#if LJ_32 +#define XA_64 CCI_XA +#define XA2_64 (CCI_XA+CCI_XA) +#else +#define XA_64 0 +#define XA2_64 0 +#endif + +/* Function definitions for CALL* instructions. */ +#define IRCALLDEF(_) \ + _(ANY, lj_str_cmp, 2, FN, INT, CCI_NOFPRCLOBBER) \ + _(ANY, lj_str_find, 4, N, PGC, 0) \ + _(ANY, lj_str_new, 3, S, STR, CCI_L|CCI_T) \ + _(ANY, lj_strscan_num, 2, FN, INT, 0) \ + _(ANY, lj_strfmt_int, 2, FN, STR, CCI_L|CCI_T) \ + _(ANY, lj_strfmt_num, 2, FN, STR, CCI_L|CCI_T) \ + _(ANY, lj_strfmt_char, 2, FN, STR, CCI_L|CCI_T) \ + _(ANY, lj_strfmt_putint, 2, FL, PGC, CCI_T) \ + _(ANY, lj_strfmt_putnum, 2, FL, PGC, CCI_T) \ + _(ANY, lj_strfmt_putquoted, 2, FL, PGC, CCI_T) \ + _(ANY, lj_strfmt_putfxint, 3, L, PGC, XA_64|CCI_T) \ + _(ANY, lj_strfmt_putfnum_int, 3, L, PGC, XA_FP|CCI_T) \ + _(ANY, lj_strfmt_putfnum_uint, 3, L, PGC, XA_FP|CCI_T) \ + _(ANY, lj_strfmt_putfnum, 3, L, PGC, XA_FP|CCI_T) \ + _(ANY, lj_strfmt_putfstr, 3, L, PGC, CCI_T) \ + _(ANY, lj_strfmt_putfchar, 3, L, PGC, CCI_T) \ + _(ANY, lj_buf_putmem, 3, S, PGC, CCI_T) \ + _(ANY, lj_buf_putstr, 2, FL, PGC, CCI_T) \ + _(ANY, lj_buf_putchar, 2, FL, PGC, CCI_T) \ + _(ANY, lj_buf_putstr_reverse, 2, FL, PGC, CCI_T) \ + _(ANY, lj_buf_putstr_lower, 2, FL, PGC, CCI_T) \ + _(ANY, lj_buf_putstr_upper, 2, FL, PGC, CCI_T) \ + _(ANY, lj_buf_putstr_rep, 3, L, PGC, CCI_T) \ + _(ANY, lj_buf_puttab, 5, L, PGC, CCI_T) \ + _(BUFFER, lj_bufx_set, 4, S, NIL, 0) \ + _(BUFFFI, lj_bufx_more, 2, FS, INT, CCI_T) \ + _(BUFFER, lj_serialize_put, 2, FS, PGC, CCI_T) \ + _(BUFFER, lj_serialize_get, 2, FS, PTR, CCI_T) \ + _(BUFFER, lj_serialize_encode, 2, FA, STR, CCI_L|CCI_T) \ + _(BUFFER, lj_serialize_decode, 3, A, INT, CCI_L|CCI_T) \ + _(ANY, lj_buf_tostr, 1, FL, STR, CCI_T) \ + _(ANY, lj_tab_new_ah, 3, A, TAB, CCI_L|CCI_T) \ + _(ANY, lj_tab_new1, 2, FA, TAB, CCI_L|CCI_T) \ + _(ANY, lj_tab_dup, 2, FA, TAB, CCI_L|CCI_T) \ + _(ANY, lj_tab_clear, 1, FS, NIL, 0) \ + _(ANY, lj_tab_newkey, 3, S, PGC, CCI_L|CCI_T) \ + _(ANY, lj_tab_keyindex, 2, FL, INT, 0) \ + _(ANY, lj_vm_next, 2, FL, PTR, 0) \ + _(ANY, lj_tab_len, 1, FL, INT, 0) \ + _(ANY, lj_tab_len_hint, 2, FL, INT, 0) \ + _(ANY, lj_gc_step_jit, 2, FS, NIL, CCI_L) \ + _(ANY, lj_gc_barrieruv, 2, FS, NIL, 0) \ + _(ANY, lj_mem_newgco, 2, FA, PGC, CCI_L|CCI_T) \ + _(ANY, lj_prng_u64d, 1, FS, NUM, CCI_CASTU64) \ + _(ANY, lj_vm_modi, 2, FN, INT, 0) \ + _(ANY, log10, 1, N, NUM, XA_FP) \ + _(ANY, exp, 1, N, NUM, XA_FP) \ + _(ANY, sin, 1, N, NUM, XA_FP) \ + _(ANY, cos, 1, N, NUM, XA_FP) \ + _(ANY, tan, 1, N, NUM, XA_FP) \ + _(ANY, asin, 1, N, NUM, XA_FP) \ + _(ANY, acos, 1, N, NUM, XA_FP) \ + _(ANY, atan, 1, N, NUM, XA_FP) \ + _(ANY, sinh, 1, N, NUM, XA_FP) \ + _(ANY, cosh, 1, N, NUM, XA_FP) \ + _(ANY, tanh, 1, N, NUM, XA_FP) \ + _(ANY, fputc, 2, S, INT, 0) \ + _(ANY, fwrite, 4, S, INT, 0) \ + _(ANY, fflush, 1, S, INT, 0) \ + /* ORDER FPM */ \ + _(FPMATH, lj_vm_floor, 1, N, NUM, XA_FP) \ + _(FPMATH, lj_vm_ceil, 1, N, NUM, XA_FP) \ + _(FPMATH, lj_vm_trunc, 1, N, NUM, XA_FP) \ + _(FPMATH, sqrt, 1, N, NUM, XA_FP) \ + _(ANY, log, 1, N, NUM, XA_FP) \ + _(ANY, lj_vm_log2, 1, N, NUM, XA_FP) \ + _(ANY, pow, 2, N, NUM, XA2_FP) \ + _(ANY, atan2, 2, N, NUM, XA2_FP) \ + _(ANY, ldexp, 2, N, NUM, XA_FP) \ + _(SOFTFP, lj_vm_tobit, 1, N, INT, XA_FP32) \ + _(SOFTFP, softfp_add, 2, N, NUM, XA2_FP32) \ + _(SOFTFP, softfp_sub, 2, N, NUM, XA2_FP32) \ + _(SOFTFP, softfp_mul, 2, N, NUM, XA2_FP32) \ + _(SOFTFP, softfp_div, 2, N, NUM, XA2_FP32) \ + _(SOFTFP, softfp_cmp, 2, N, NIL, XA2_FP32) \ + _(SOFTFP, softfp_i2d, 1, N, NUM, 0) \ + _(SOFTFP, softfp_d2i, 1, N, INT, XA_FP32) \ + _(SOFTFP_MIPS, lj_vm_sfmin, 2, N, NUM, XA2_FP32) \ + _(SOFTFP_MIPS, lj_vm_sfmax, 2, N, NUM, XA2_FP32) \ + _(SOFTFP_MIPS64, lj_vm_tointg, 1, N, INT, 0) \ + _(SOFTFP_FFI, softfp_ui2d, 1, N, NUM, 0) \ + _(SOFTFP_FFI, softfp_f2d, 1, N, NUM, 0) \ + _(SOFTFP_FFI, softfp_d2ui, 1, N, INT, XA_FP32) \ + _(SOFTFP_FFI, softfp_d2f, 1, N, FLOAT, XA_FP32) \ + _(SOFTFP_FFI, softfp_i2f, 1, N, FLOAT, 0) \ + _(SOFTFP_FFI, softfp_ui2f, 1, N, FLOAT, 0) \ + _(SOFTFP_FFI, softfp_f2i, 1, N, INT, 0) \ + _(SOFTFP_FFI, softfp_f2ui, 1, N, INT, 0) \ + _(FP64_FFI, fp64_l2d, 1, N, NUM, XA_64) \ + _(FP64_FFI, fp64_ul2d, 1, N, NUM, XA_64) \ + _(FP64_FFI, fp64_l2f, 1, N, FLOAT, XA_64) \ + _(FP64_FFI, fp64_ul2f, 1, N, FLOAT, XA_64) \ + _(FP64_FFI, fp64_d2l, 1, N, I64, XA_FP) \ + _(FP64_FFI, fp64_d2ul, 1, N, U64, XA_FP) \ + _(FP64_FFI, fp64_f2l, 1, N, I64, 0) \ + _(FP64_FFI, fp64_f2ul, 1, N, U64, 0) \ + _(FFI, lj_carith_divi64, 2, N, I64, XA2_64|CCI_NOFPRCLOBBER) \ + _(FFI, lj_carith_divu64, 2, N, U64, XA2_64|CCI_NOFPRCLOBBER) \ + _(FFI, lj_carith_modi64, 2, N, I64, XA2_64|CCI_NOFPRCLOBBER) \ + _(FFI, lj_carith_modu64, 2, N, U64, XA2_64|CCI_NOFPRCLOBBER) \ + _(FFI, lj_carith_powi64, 2, N, I64, XA2_64|CCI_NOFPRCLOBBER) \ + _(FFI, lj_carith_powu64, 2, N, U64, XA2_64|CCI_NOFPRCLOBBER) \ + _(FFI, lj_cdata_newv, 4, S, CDATA, CCI_L) \ + _(FFI, lj_cdata_setfin, 4, S, NIL, CCI_L) \ + _(FFI, strlen, 1, L, INTP, 0) \ + _(FFI, memcpy, 3, S, PTR, 0) \ + _(FFI, memset, 3, S, PTR, 0) \ + _(FFI, lj_vm_errno, 0, S, INT, CCI_NOFPRCLOBBER) \ + _(FFI32, lj_carith_mul64, 2, N, I64, XA2_64|CCI_NOFPRCLOBBER) \ + _(FFI32, lj_carith_shl64, 2, N, U64, XA_64|CCI_NOFPRCLOBBER) \ + _(FFI32, lj_carith_shr64, 2, N, U64, XA_64|CCI_NOFPRCLOBBER) \ + _(FFI32, lj_carith_sar64, 2, N, U64, XA_64|CCI_NOFPRCLOBBER) \ + _(FFI32, lj_carith_rol64, 2, N, U64, XA_64|CCI_NOFPRCLOBBER) \ + _(FFI32, lj_carith_ror64, 2, N, U64, XA_64|CCI_NOFPRCLOBBER) \ + \ + /* End of list. */ + +typedef enum { +#define IRCALLENUM(cond, name, nargs, kind, type, flags) IRCALL_##name, +IRCALLDEF(IRCALLENUM) +#undef IRCALLENUM + IRCALL__MAX +} IRCallID; + +LJ_FUNC TRef lj_ir_call(jit_State *J, IRCallID id, ...); + +LJ_DATA const CCallInfo lj_ir_callinfo[IRCALL__MAX+1]; + +/* Soft-float declarations. */ +#if LJ_SOFTFP +#if LJ_TARGET_ARM +#define softfp_add __aeabi_dadd +#define softfp_sub __aeabi_dsub +#define softfp_mul __aeabi_dmul +#define softfp_div __aeabi_ddiv +#define softfp_cmp __aeabi_cdcmple +#define softfp_i2d __aeabi_i2d +#define softfp_d2i __aeabi_d2iz +#define softfp_ui2d __aeabi_ui2d +#define softfp_f2d __aeabi_f2d +#define softfp_d2ui __aeabi_d2uiz +#define softfp_d2f __aeabi_d2f +#define softfp_i2f __aeabi_i2f +#define softfp_ui2f __aeabi_ui2f +#define softfp_f2i __aeabi_f2iz +#define softfp_f2ui __aeabi_f2uiz +#define fp64_l2d __aeabi_l2d +#define fp64_ul2d __aeabi_ul2d +#define fp64_l2f __aeabi_l2f +#define fp64_ul2f __aeabi_ul2f +#if LJ_TARGET_IOS +#define fp64_d2l __fixdfdi +#define fp64_d2ul __fixunsdfdi +#define fp64_f2l __fixsfdi +#define fp64_f2ul __fixunssfdi +#else +#define fp64_d2l __aeabi_d2lz +#define fp64_d2ul __aeabi_d2ulz +#define fp64_f2l __aeabi_f2lz +#define fp64_f2ul __aeabi_f2ulz +#endif +#elif LJ_TARGET_MIPS || LJ_TARGET_PPC +#define softfp_add __adddf3 +#define softfp_sub __subdf3 +#define softfp_mul __muldf3 +#define softfp_div __divdf3 +#define softfp_cmp __ledf2 +#define softfp_i2d __floatsidf +#define softfp_d2i __fixdfsi +#define softfp_ui2d __floatunsidf +#define softfp_f2d __extendsfdf2 +#define softfp_d2ui __fixunsdfsi +#define softfp_d2f __truncdfsf2 +#define softfp_i2f __floatsisf +#define softfp_ui2f __floatunsisf +#define softfp_f2i __fixsfsi +#define softfp_f2ui __fixunssfsi +#else +#error "Missing soft-float definitions for target architecture" +#endif +extern double softfp_add(double a, double b); +extern double softfp_sub(double a, double b); +extern double softfp_mul(double a, double b); +extern double softfp_div(double a, double b); +extern void softfp_cmp(double a, double b); +extern double softfp_i2d(int32_t a); +extern int32_t softfp_d2i(double a); +#if LJ_HASFFI +extern double softfp_ui2d(uint32_t a); +extern double softfp_f2d(float a); +extern uint32_t softfp_d2ui(double a); +extern float softfp_d2f(double a); +extern float softfp_i2f(int32_t a); +extern float softfp_ui2f(uint32_t a); +extern int32_t softfp_f2i(float a); +extern uint32_t softfp_f2ui(float a); +#endif +#if LJ_TARGET_MIPS +extern double lj_vm_sfmin(double a, double b); +extern double lj_vm_sfmax(double a, double b); +#endif +#endif + +#if LJ_HASFFI && LJ_NEED_FP64 && !(LJ_TARGET_ARM && LJ_SOFTFP) +#if defined(__GNUC__) || defined(__clang__) +#define fp64_l2d __floatdidf +#define fp64_ul2d __floatundidf +#define fp64_l2f __floatdisf +#define fp64_ul2f __floatundisf +#define fp64_d2l __fixdfdi +#define fp64_d2ul __fixunsdfdi +#define fp64_f2l __fixsfdi +#define fp64_f2ul __fixunssfdi +#else +#error "Missing fp64 helper definitions for this compiler" +#endif +#endif + +#if LJ_HASFFI && (LJ_SOFTFP || LJ_NEED_FP64) +extern double fp64_l2d(int64_t a); +extern double fp64_ul2d(uint64_t a); +extern float fp64_l2f(int64_t a); +extern float fp64_ul2f(uint64_t a); +extern int64_t fp64_d2l(double a); +extern uint64_t fp64_d2ul(double a); +extern int64_t fp64_f2l(float a); +extern uint64_t fp64_f2ul(float a); +#endif + +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_iropt.h b/fluent-bit/lib/luajit-3065c9/src/lj_iropt.h new file mode 100644 index 00000000..d239f173 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_iropt.h @@ -0,0 +1,162 @@ +/* +** Common header for IR emitter and optimizations. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#ifndef _LJ_IROPT_H +#define _LJ_IROPT_H + +#include + +#include "lj_obj.h" +#include "lj_jit.h" + +#if LJ_HASJIT +/* IR emitter. */ +LJ_FUNC void LJ_FASTCALL lj_ir_growtop(jit_State *J); +LJ_FUNC TRef LJ_FASTCALL lj_ir_emit(jit_State *J); + +/* Save current IR in J->fold.ins, but do not emit it (yet). */ +static LJ_AINLINE void lj_ir_set_(jit_State *J, uint16_t ot, IRRef1 a, IRRef1 b) +{ + J->fold.ins.ot = ot; J->fold.ins.op1 = a; J->fold.ins.op2 = b; +} + +#define lj_ir_set(J, ot, a, b) \ + lj_ir_set_(J, (uint16_t)(ot), (IRRef1)(a), (IRRef1)(b)) + +/* Get ref of next IR instruction and optionally grow IR. +** Note: this may invalidate all IRIns*! +*/ +static LJ_AINLINE IRRef lj_ir_nextins(jit_State *J) +{ + IRRef ref = J->cur.nins; + if (LJ_UNLIKELY(ref >= J->irtoplim)) lj_ir_growtop(J); + J->cur.nins = ref + 1; + return ref; +} + +LJ_FUNC TRef lj_ir_ggfload(jit_State *J, IRType t, uintptr_t ofs); + +/* Interning of constants. */ +LJ_FUNC TRef LJ_FASTCALL lj_ir_kint(jit_State *J, int32_t k); +LJ_FUNC TRef lj_ir_k64(jit_State *J, IROp op, uint64_t u64); +LJ_FUNC TRef lj_ir_knum_u64(jit_State *J, uint64_t u64); +LJ_FUNC TRef lj_ir_knumint(jit_State *J, lua_Number n); +LJ_FUNC TRef lj_ir_kint64(jit_State *J, uint64_t u64); +LJ_FUNC TRef lj_ir_kgc(jit_State *J, GCobj *o, IRType t); +LJ_FUNC TRef lj_ir_kptr_(jit_State *J, IROp op, void *ptr); +LJ_FUNC TRef lj_ir_knull(jit_State *J, IRType t); +LJ_FUNC TRef lj_ir_kslot(jit_State *J, TRef key, IRRef slot); +LJ_FUNC TRef lj_ir_ktrace(jit_State *J); + +#if LJ_64 +#define lj_ir_kintp(J, k) lj_ir_kint64(J, (uint64_t)(k)) +#else +#define lj_ir_kintp(J, k) lj_ir_kint(J, (int32_t)(k)) +#endif + +static LJ_AINLINE TRef lj_ir_knum(jit_State *J, lua_Number n) +{ + TValue tv; + tv.n = n; + return lj_ir_knum_u64(J, tv.u64); +} + +#define lj_ir_kstr(J, str) lj_ir_kgc(J, obj2gco((str)), IRT_STR) +#define lj_ir_ktab(J, tab) lj_ir_kgc(J, obj2gco((tab)), IRT_TAB) +#define lj_ir_kfunc(J, func) lj_ir_kgc(J, obj2gco((func)), IRT_FUNC) +#define lj_ir_kptr(J, ptr) lj_ir_kptr_(J, IR_KPTR, (ptr)) +#define lj_ir_kkptr(J, ptr) lj_ir_kptr_(J, IR_KKPTR, (ptr)) + +/* Special FP constants. */ +#define lj_ir_knum_zero(J) lj_ir_knum_u64(J, U64x(00000000,00000000)) +#define lj_ir_knum_one(J) lj_ir_knum_u64(J, U64x(3ff00000,00000000)) +#define lj_ir_knum_tobit(J) lj_ir_knum_u64(J, U64x(43380000,00000000)) + +/* Special 128 bit SIMD constants. */ +#define lj_ir_ksimd(J, idx) \ + lj_ir_ggfload(J, IRT_NUM, (uintptr_t)LJ_KSIMD(J, idx) - (uintptr_t)J2GG(J)) + +/* Access to constants. */ +LJ_FUNC void lj_ir_kvalue(lua_State *L, TValue *tv, const IRIns *ir); + +/* Convert IR operand types. */ +LJ_FUNC TRef LJ_FASTCALL lj_ir_tonumber(jit_State *J, TRef tr); +LJ_FUNC TRef LJ_FASTCALL lj_ir_tonum(jit_State *J, TRef tr); +LJ_FUNC TRef LJ_FASTCALL lj_ir_tostr(jit_State *J, TRef tr); + +/* Miscellaneous IR ops. */ +LJ_FUNC int lj_ir_numcmp(lua_Number a, lua_Number b, IROp op); +LJ_FUNC int lj_ir_strcmp(GCstr *a, GCstr *b, IROp op); +LJ_FUNC void lj_ir_rollback(jit_State *J, IRRef ref); + +/* Emit IR instructions with on-the-fly optimizations. */ +LJ_FUNC TRef LJ_FASTCALL lj_opt_fold(jit_State *J); +LJ_FUNC TRef LJ_FASTCALL lj_opt_cse(jit_State *J); +LJ_FUNC TRef LJ_FASTCALL lj_opt_cselim(jit_State *J, IRRef lim); + +/* Special return values for the fold functions. */ +enum { + NEXTFOLD, /* Couldn't fold, pass on. */ + RETRYFOLD, /* Retry fold with modified fins. */ + KINTFOLD, /* Return ref for int constant in fins->i. */ + FAILFOLD, /* Guard would always fail. */ + DROPFOLD, /* Guard eliminated. */ + MAX_FOLD +}; + +#define INTFOLD(k) ((J->fold.ins.i = (k)), (TRef)KINTFOLD) +#define INT64FOLD(k) (lj_ir_kint64(J, (k))) +#define CONDFOLD(cond) ((TRef)FAILFOLD + (TRef)(cond)) +#define LEFTFOLD (J->fold.ins.op1) +#define RIGHTFOLD (J->fold.ins.op2) +#define CSEFOLD (lj_opt_cse(J)) +#define EMITFOLD (lj_ir_emit(J)) + +/* Load/store forwarding. */ +LJ_FUNC TRef LJ_FASTCALL lj_opt_fwd_aload(jit_State *J); +LJ_FUNC TRef LJ_FASTCALL lj_opt_fwd_hload(jit_State *J); +LJ_FUNC TRef LJ_FASTCALL lj_opt_fwd_uload(jit_State *J); +LJ_FUNC TRef LJ_FASTCALL lj_opt_fwd_fload(jit_State *J); +LJ_FUNC TRef LJ_FASTCALL lj_opt_fwd_xload(jit_State *J); +LJ_FUNC TRef LJ_FASTCALL lj_opt_fwd_alen(jit_State *J); +LJ_FUNC TRef LJ_FASTCALL lj_opt_fwd_hrefk(jit_State *J); +LJ_FUNC int LJ_FASTCALL lj_opt_fwd_href_nokey(jit_State *J); +LJ_FUNC int LJ_FASTCALL lj_opt_fwd_tptr(jit_State *J, IRRef lim); +LJ_FUNC int LJ_FASTCALL lj_opt_fwd_sbuf(jit_State *J, IRRef lim); +LJ_FUNC int lj_opt_fwd_wasnonnil(jit_State *J, IROpT loadop, IRRef xref); + +/* Dead-store elimination. */ +LJ_FUNC TRef LJ_FASTCALL lj_opt_dse_ahstore(jit_State *J); +LJ_FUNC TRef LJ_FASTCALL lj_opt_dse_ustore(jit_State *J); +LJ_FUNC TRef LJ_FASTCALL lj_opt_dse_fstore(jit_State *J); +LJ_FUNC TRef LJ_FASTCALL lj_opt_dse_xstore(jit_State *J); + +/* Narrowing. */ +LJ_FUNC TRef LJ_FASTCALL lj_opt_narrow_convert(jit_State *J); +LJ_FUNC TRef LJ_FASTCALL lj_opt_narrow_index(jit_State *J, TRef key); +LJ_FUNC TRef LJ_FASTCALL lj_opt_narrow_toint(jit_State *J, TRef tr); +LJ_FUNC TRef LJ_FASTCALL lj_opt_narrow_tobit(jit_State *J, TRef tr); +#if LJ_HASFFI +LJ_FUNC TRef LJ_FASTCALL lj_opt_narrow_cindex(jit_State *J, TRef key); +#endif +LJ_FUNC TRef lj_opt_narrow_arith(jit_State *J, TRef rb, TRef rc, + TValue *vb, TValue *vc, IROp op); +LJ_FUNC TRef lj_opt_narrow_unm(jit_State *J, TRef rc, TValue *vc); +LJ_FUNC TRef lj_opt_narrow_mod(jit_State *J, TRef rb, TRef rc, TValue *vb, TValue *vc); +LJ_FUNC IRType lj_opt_narrow_forl(jit_State *J, cTValue *forbase); + +/* Optimization passes. */ +LJ_FUNC void lj_opt_dce(jit_State *J); +LJ_FUNC int lj_opt_loop(jit_State *J); +#if LJ_SOFTFP32 || (LJ_32 && LJ_HASFFI) +LJ_FUNC void lj_opt_split(jit_State *J); +#else +#define lj_opt_split(J) UNUSED(J) +#endif +LJ_FUNC void lj_opt_sink(jit_State *J); + +#endif + +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_jit.h b/fluent-bit/lib/luajit-3065c9/src/lj_jit.h new file mode 100644 index 00000000..32b3861a --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_jit.h @@ -0,0 +1,528 @@ +/* +** Common definitions for the JIT compiler. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#ifndef _LJ_JIT_H +#define _LJ_JIT_H + +#include "lj_obj.h" +#if LJ_HASJIT +#include "lj_ir.h" + +/* -- JIT engine flags ---------------------------------------------------- */ + +/* General JIT engine flags. 4 bits. */ +#define JIT_F_ON 0x00000001 + +/* CPU-specific JIT engine flags. 12 bits. Flags and strings must match. */ +#define JIT_F_CPU 0x00000010 + +#if LJ_TARGET_X86ORX64 + +#define JIT_F_SSE3 (JIT_F_CPU << 0) +#define JIT_F_SSE4_1 (JIT_F_CPU << 1) +#define JIT_F_BMI2 (JIT_F_CPU << 2) + + +#define JIT_F_CPUSTRING "\4SSE3\6SSE4.1\4BMI2" + +#elif LJ_TARGET_ARM + +#define JIT_F_ARMV6_ (JIT_F_CPU << 0) +#define JIT_F_ARMV6T2_ (JIT_F_CPU << 1) +#define JIT_F_ARMV7 (JIT_F_CPU << 2) +#define JIT_F_ARMV8 (JIT_F_CPU << 3) +#define JIT_F_VFPV2 (JIT_F_CPU << 4) +#define JIT_F_VFPV3 (JIT_F_CPU << 5) + +#define JIT_F_ARMV6 (JIT_F_ARMV6_|JIT_F_ARMV6T2_|JIT_F_ARMV7|JIT_F_ARMV8) +#define JIT_F_ARMV6T2 (JIT_F_ARMV6T2_|JIT_F_ARMV7|JIT_F_ARMV8) +#define JIT_F_VFP (JIT_F_VFPV2|JIT_F_VFPV3) + +#define JIT_F_CPUSTRING "\5ARMv6\7ARMv6T2\5ARMv7\5ARMv8\5VFPv2\5VFPv3" + +#elif LJ_TARGET_PPC + +#define JIT_F_SQRT (JIT_F_CPU << 0) +#define JIT_F_ROUND (JIT_F_CPU << 1) + +#define JIT_F_CPUSTRING "\4SQRT\5ROUND" + +#elif LJ_TARGET_MIPS + +#define JIT_F_MIPSXXR2 (JIT_F_CPU << 0) + +#if LJ_TARGET_MIPS32 +#if LJ_TARGET_MIPSR6 +#define JIT_F_CPUSTRING "\010MIPS32R6" +#else +#define JIT_F_CPUSTRING "\010MIPS32R2" +#endif +#else +#if LJ_TARGET_MIPSR6 +#define JIT_F_CPUSTRING "\010MIPS64R6" +#else +#define JIT_F_CPUSTRING "\010MIPS64R2" +#endif +#endif + +#else + +#define JIT_F_CPUSTRING "" + +#endif + +/* Optimization flags. 12 bits. */ +#define JIT_F_OPT 0x00010000 +#define JIT_F_OPT_MASK 0x0fff0000 + +#define JIT_F_OPT_FOLD (JIT_F_OPT << 0) +#define JIT_F_OPT_CSE (JIT_F_OPT << 1) +#define JIT_F_OPT_DCE (JIT_F_OPT << 2) +#define JIT_F_OPT_FWD (JIT_F_OPT << 3) +#define JIT_F_OPT_DSE (JIT_F_OPT << 4) +#define JIT_F_OPT_NARROW (JIT_F_OPT << 5) +#define JIT_F_OPT_LOOP (JIT_F_OPT << 6) +#define JIT_F_OPT_ABC (JIT_F_OPT << 7) +#define JIT_F_OPT_SINK (JIT_F_OPT << 8) +#define JIT_F_OPT_FUSE (JIT_F_OPT << 9) + +/* Optimizations names for -O. Must match the order above. */ +#define JIT_F_OPTSTRING \ + "\4fold\3cse\3dce\3fwd\3dse\6narrow\4loop\3abc\4sink\4fuse" + +/* Optimization levels set a fixed combination of flags. */ +#define JIT_F_OPT_0 0 +#define JIT_F_OPT_1 (JIT_F_OPT_FOLD|JIT_F_OPT_CSE|JIT_F_OPT_DCE) +#define JIT_F_OPT_2 (JIT_F_OPT_1|JIT_F_OPT_NARROW|JIT_F_OPT_LOOP) +#define JIT_F_OPT_3 (JIT_F_OPT_2|\ + JIT_F_OPT_FWD|JIT_F_OPT_DSE|JIT_F_OPT_ABC|JIT_F_OPT_SINK|JIT_F_OPT_FUSE) +#define JIT_F_OPT_DEFAULT JIT_F_OPT_3 + +/* -- JIT engine parameters ----------------------------------------------- */ + +#if LJ_TARGET_WINDOWS || LJ_64 +/* See: http://blogs.msdn.com/oldnewthing/archive/2003/10/08/55239.aspx */ +#define JIT_P_sizemcode_DEFAULT 64 +#else +/* Could go as low as 4K, but the mmap() overhead would be rather high. */ +#define JIT_P_sizemcode_DEFAULT 32 +#endif + +/* Optimization parameters and their defaults. Length is a char in octal! */ +#define JIT_PARAMDEF(_) \ + _(\010, maxtrace, 1000) /* Max. # of traces in cache. */ \ + _(\011, maxrecord, 4000) /* Max. # of recorded IR instructions. */ \ + _(\012, maxirconst, 500) /* Max. # of IR constants of a trace. */ \ + _(\007, maxside, 100) /* Max. # of side traces of a root trace. */ \ + _(\007, maxsnap, 500) /* Max. # of snapshots for a trace. */ \ + _(\011, minstitch, 0) /* Min. # of IR ins for a stitched trace. */ \ + \ + _(\007, hotloop, 56) /* # of iter. to detect a hot loop/call. */ \ + _(\007, hotexit, 10) /* # of taken exits to start a side trace. */ \ + _(\007, tryside, 4) /* # of attempts to compile a side trace. */ \ + \ + _(\012, instunroll, 4) /* Max. unroll for instable loops. */ \ + _(\012, loopunroll, 15) /* Max. unroll for loop ops in side traces. */ \ + _(\012, callunroll, 3) /* Max. unroll for recursive calls. */ \ + _(\011, recunroll, 2) /* Min. unroll for true recursion. */ \ + \ + /* Size of each machine code area (in KBytes). */ \ + _(\011, sizemcode, JIT_P_sizemcode_DEFAULT) \ + /* Max. total size of all machine code areas (in KBytes). */ \ + _(\010, maxmcode, 512) \ + /* End of list. */ + +enum { +#define JIT_PARAMENUM(len, name, value) JIT_P_##name, +JIT_PARAMDEF(JIT_PARAMENUM) +#undef JIT_PARAMENUM + JIT_P__MAX +}; + +#define JIT_PARAMSTR(len, name, value) #len #name +#define JIT_P_STRING JIT_PARAMDEF(JIT_PARAMSTR) + +/* -- JIT engine data structures ------------------------------------------ */ + +/* Trace compiler state. */ +typedef enum { + LJ_TRACE_IDLE, /* Trace compiler idle. */ + LJ_TRACE_ACTIVE = 0x10, + LJ_TRACE_RECORD, /* Bytecode recording active. */ + LJ_TRACE_RECORD_1ST, /* Record 1st instruction, too. */ + LJ_TRACE_START, /* New trace started. */ + LJ_TRACE_END, /* End of trace. */ + LJ_TRACE_ASM, /* Assemble trace. */ + LJ_TRACE_ERR /* Trace aborted with error. */ +} TraceState; + +/* Post-processing action. */ +typedef enum { + LJ_POST_NONE, /* No action. */ + LJ_POST_FIXCOMP, /* Fixup comparison and emit pending guard. */ + LJ_POST_FIXGUARD, /* Fixup and emit pending guard. */ + LJ_POST_FIXGUARDSNAP, /* Fixup and emit pending guard and snapshot. */ + LJ_POST_FIXBOOL, /* Fixup boolean result. */ + LJ_POST_FIXCONST, /* Fixup constant results. */ + LJ_POST_FFRETRY /* Suppress recording of retried fast functions. */ +} PostProc; + +/* Machine code type. */ +#if LJ_TARGET_X86ORX64 +typedef uint8_t MCode; +#else +typedef uint32_t MCode; +#endif + +/* Linked list of MCode areas. */ +typedef struct MCLink { + MCode *next; /* Next area. */ + size_t size; /* Size of current area. */ +} MCLink; + +/* Stack snapshot header. */ +typedef struct SnapShot { + uint32_t mapofs; /* Offset into snapshot map. */ + IRRef1 ref; /* First IR ref for this snapshot. */ + uint16_t mcofs; /* Offset into machine code in MCode units. */ + uint8_t nslots; /* Number of valid slots. */ + uint8_t topslot; /* Maximum frame extent. */ + uint8_t nent; /* Number of compressed entries. */ + uint8_t count; /* Count of taken exits for this snapshot. */ +} SnapShot; + +#define SNAPCOUNT_DONE 255 /* Already compiled and linked a side trace. */ + +/* Compressed snapshot entry. */ +typedef uint32_t SnapEntry; + +#define SNAP_FRAME 0x010000 /* Frame slot. */ +#define SNAP_CONT 0x020000 /* Continuation slot. */ +#define SNAP_NORESTORE 0x040000 /* No need to restore slot. */ +#define SNAP_SOFTFPNUM 0x080000 /* Soft-float number. */ +#define SNAP_KEYINDEX 0x100000 /* Traversal key index. */ +LJ_STATIC_ASSERT(SNAP_FRAME == TREF_FRAME); +LJ_STATIC_ASSERT(SNAP_CONT == TREF_CONT); +LJ_STATIC_ASSERT(SNAP_KEYINDEX == TREF_KEYINDEX); + +#define SNAP(slot, flags, ref) (((SnapEntry)(slot) << 24) + (flags) + (ref)) +#define SNAP_TR(slot, tr) \ + (((SnapEntry)(slot) << 24) + \ + ((tr) & (TREF_KEYINDEX|TREF_CONT|TREF_FRAME|TREF_REFMASK))) +#if !LJ_FR2 +#define SNAP_MKPC(pc) ((SnapEntry)u32ptr(pc)) +#endif +#define SNAP_MKFTSZ(ftsz) ((SnapEntry)(ftsz)) +#define snap_ref(sn) ((sn) & 0xffff) +#define snap_slot(sn) ((BCReg)((sn) >> 24)) +#define snap_isframe(sn) ((sn) & SNAP_FRAME) +#define snap_setref(sn, ref) (((sn) & (0xffff0000&~SNAP_NORESTORE)) | (ref)) + +static LJ_AINLINE const BCIns *snap_pc(SnapEntry *sn) +{ +#if LJ_FR2 + uint64_t pcbase; + memcpy(&pcbase, sn, sizeof(uint64_t)); + return (const BCIns *)(pcbase >> 8); +#else + return (const BCIns *)(uintptr_t)*sn; +#endif +} + +/* Snapshot and exit numbers. */ +typedef uint32_t SnapNo; +typedef uint32_t ExitNo; + +/* Trace number. */ +typedef uint32_t TraceNo; /* Used to pass around trace numbers. */ +typedef uint16_t TraceNo1; /* Stored trace number. */ + +/* Type of link. ORDER LJ_TRLINK */ +typedef enum { + LJ_TRLINK_NONE, /* Incomplete trace. No link, yet. */ + LJ_TRLINK_ROOT, /* Link to other root trace. */ + LJ_TRLINK_LOOP, /* Loop to same trace. */ + LJ_TRLINK_TAILREC, /* Tail-recursion. */ + LJ_TRLINK_UPREC, /* Up-recursion. */ + LJ_TRLINK_DOWNREC, /* Down-recursion. */ + LJ_TRLINK_INTERP, /* Fallback to interpreter. */ + LJ_TRLINK_RETURN, /* Return to interpreter. */ + LJ_TRLINK_STITCH /* Trace stitching. */ +} TraceLink; + +/* Trace object. */ +typedef struct GCtrace { + GCHeader; + uint16_t nsnap; /* Number of snapshots. */ + IRRef nins; /* Next IR instruction. Biased with REF_BIAS. */ +#if LJ_GC64 + uint32_t unused_gc64; +#endif + GCRef gclist; + IRIns *ir; /* IR instructions/constants. Biased with REF_BIAS. */ + IRRef nk; /* Lowest IR constant. Biased with REF_BIAS. */ + uint32_t nsnapmap; /* Number of snapshot map elements. */ + SnapShot *snap; /* Snapshot array. */ + SnapEntry *snapmap; /* Snapshot map. */ + GCRef startpt; /* Starting prototype. */ + MRef startpc; /* Bytecode PC of starting instruction. */ + BCIns startins; /* Original bytecode of starting instruction. */ + MSize szmcode; /* Size of machine code. */ + MCode *mcode; /* Start of machine code. */ + MSize mcloop; /* Offset of loop start in machine code. */ + uint16_t nchild; /* Number of child traces (root trace only). */ + uint16_t spadjust; /* Stack pointer adjustment (offset in bytes). */ + TraceNo1 traceno; /* Trace number. */ + TraceNo1 link; /* Linked trace (or self for loops). */ + TraceNo1 root; /* Root trace of side trace (or 0 for root traces). */ + TraceNo1 nextroot; /* Next root trace for same prototype. */ + TraceNo1 nextside; /* Next side trace of same root trace. */ + uint8_t sinktags; /* Trace has SINK tags. */ + uint8_t topslot; /* Top stack slot already checked to be allocated. */ + uint8_t linktype; /* Type of link. */ + uint8_t unused1; +#ifdef LUAJIT_USE_GDBJIT + void *gdbjit_entry; /* GDB JIT entry. */ +#endif +} GCtrace; + +#define gco2trace(o) check_exp((o)->gch.gct == ~LJ_TTRACE, (GCtrace *)(o)) +#define traceref(J, n) \ + check_exp((n)>0 && (MSize)(n)sizetrace, (GCtrace *)gcref(J->trace[(n)])) + +LJ_STATIC_ASSERT(offsetof(GChead, gclist) == offsetof(GCtrace, gclist)); + +static LJ_AINLINE MSize snap_nextofs(GCtrace *T, SnapShot *snap) +{ + if (snap+1 == &T->snap[T->nsnap]) + return T->nsnapmap; + else + return (snap+1)->mapofs; +} + +/* Round-robin penalty cache for bytecodes leading to aborted traces. */ +typedef struct HotPenalty { + MRef pc; /* Starting bytecode PC. */ + uint16_t val; /* Penalty value, i.e. hotcount start. */ + uint16_t reason; /* Abort reason (really TraceErr). */ +} HotPenalty; + +#define PENALTY_SLOTS 64 /* Penalty cache slot. Must be a power of 2. */ +#define PENALTY_MIN (36*2) /* Minimum penalty value. */ +#define PENALTY_MAX 60000 /* Maximum penalty value. */ +#define PENALTY_RNDBITS 4 /* # of random bits to add to penalty value. */ + +/* Round-robin backpropagation cache for narrowing conversions. */ +typedef struct BPropEntry { + IRRef1 key; /* Key: original reference. */ + IRRef1 val; /* Value: reference after conversion. */ + IRRef mode; /* Mode for this entry (currently IRCONV_*). */ +} BPropEntry; + +/* Number of slots for the backpropagation cache. Must be a power of 2. */ +#define BPROP_SLOTS 16 + +/* Scalar evolution analysis cache. */ +typedef struct ScEvEntry { + MRef pc; /* Bytecode PC of FORI. */ + IRRef1 idx; /* Index reference. */ + IRRef1 start; /* Constant start reference. */ + IRRef1 stop; /* Constant stop reference. */ + IRRef1 step; /* Constant step reference. */ + IRType1 t; /* Scalar type. */ + uint8_t dir; /* Direction. 1: +, 0: -. */ +} ScEvEntry; + +/* Reverse bytecode map (IRRef -> PC). Only for selected instructions. */ +typedef struct RBCHashEntry { + MRef pc; /* Bytecode PC. */ + GCRef pt; /* Prototype. */ + IRRef ref; /* IR reference. */ +} RBCHashEntry; + +/* Number of slots in the reverse bytecode hash table. Must be a power of 2. */ +#define RBCHASH_SLOTS 8 + +/* 128 bit SIMD constants. */ +enum { + LJ_KSIMD_ABS, + LJ_KSIMD_NEG, + LJ_KSIMD__MAX +}; + +enum { +#if LJ_TARGET_X86ORX64 + LJ_K64_TOBIT, /* 2^52 + 2^51 */ + LJ_K64_2P64, /* 2^64 */ + LJ_K64_M2P64, /* -2^64 */ +#if LJ_32 + LJ_K64_M2P64_31, /* -2^64 or -2^31 */ +#else + LJ_K64_M2P64_31 = LJ_K64_M2P64, +#endif +#endif +#if LJ_TARGET_MIPS + LJ_K64_2P31, /* 2^31 */ +#if LJ_64 + LJ_K64_2P63, /* 2^63 */ + LJ_K64_M2P64, /* -2^64 */ +#endif +#endif + LJ_K64__MAX, +}; +#define LJ_K64__USED (LJ_TARGET_X86ORX64 || LJ_TARGET_MIPS) + +enum { +#if LJ_TARGET_X86ORX64 + LJ_K32_M2P64_31, /* -2^64 or -2^31 */ +#endif +#if LJ_TARGET_PPC + LJ_K32_2P52_2P31, /* 2^52 + 2^31 */ + LJ_K32_2P52, /* 2^52 */ +#endif +#if LJ_TARGET_PPC || LJ_TARGET_MIPS + LJ_K32_2P31, /* 2^31 */ +#endif +#if LJ_TARGET_MIPS64 + LJ_K32_2P63, /* 2^63 */ + LJ_K32_M2P64, /* -2^64 */ +#endif + LJ_K32__MAX +}; +#define LJ_K32__USED (LJ_TARGET_X86ORX64 || LJ_TARGET_PPC || LJ_TARGET_MIPS) + +/* Get 16 byte aligned pointer to SIMD constant. */ +#define LJ_KSIMD(J, n) \ + ((TValue *)(((intptr_t)&J->ksimd[2*(n)] + 15) & ~(intptr_t)15)) + +/* Set/reset flag to activate the SPLIT pass for the current trace. */ +#if LJ_SOFTFP32 || (LJ_32 && LJ_HASFFI) +#define lj_needsplit(J) (J->needsplit = 1) +#define lj_resetsplit(J) (J->needsplit = 0) +#else +#define lj_needsplit(J) UNUSED(J) +#define lj_resetsplit(J) UNUSED(J) +#endif + +/* Fold state is used to fold instructions on-the-fly. */ +typedef struct FoldState { + IRIns ins; /* Currently emitted instruction. */ + IRIns left[2]; /* Instruction referenced by left operand. */ + IRIns right[2]; /* Instruction referenced by right operand. */ +} FoldState; + +/* JIT compiler state. */ +typedef struct jit_State { + GCtrace cur; /* Current trace. */ + GCtrace *curfinal; /* Final address of current trace (set during asm). */ + + lua_State *L; /* Current Lua state. */ + const BCIns *pc; /* Current PC. */ + GCfunc *fn; /* Current function. */ + GCproto *pt; /* Current prototype. */ + TRef *base; /* Current frame base, points into J->slots. */ + + uint32_t flags; /* JIT engine flags. */ + BCReg maxslot; /* Relative to baseslot. */ + BCReg baseslot; /* Current frame base, offset into J->slots. */ + + uint8_t mergesnap; /* Allowed to merge with next snapshot. */ + uint8_t needsnap; /* Need snapshot before recording next bytecode. */ + IRType1 guardemit; /* Accumulated IRT_GUARD for emitted instructions. */ + uint8_t bcskip; /* Number of bytecode instructions to skip. */ + + FoldState fold; /* Fold state. */ + + const BCIns *bc_min; /* Start of allowed bytecode range for root trace. */ + MSize bc_extent; /* Extent of the range. */ + + TraceState state; /* Trace compiler state. */ + + int32_t instunroll; /* Unroll counter for instable loops. */ + int32_t loopunroll; /* Unroll counter for loop ops in side traces. */ + int32_t tailcalled; /* Number of successive tailcalls. */ + int32_t framedepth; /* Current frame depth. */ + int32_t retdepth; /* Return frame depth (count of RETF). */ + +#if LJ_K32__USED + uint32_t k32[LJ_K32__MAX]; /* Common 4 byte constants used by backends. */ +#endif + TValue ksimd[LJ_KSIMD__MAX*2+1]; /* 16 byte aligned SIMD constants. */ +#if LJ_K64__USED + TValue k64[LJ_K64__MAX]; /* Common 8 byte constants. */ +#endif + + IRIns *irbuf; /* Temp. IR instruction buffer. Biased with REF_BIAS. */ + IRRef irtoplim; /* Upper limit of instuction buffer (biased). */ + IRRef irbotlim; /* Lower limit of instuction buffer (biased). */ + IRRef loopref; /* Last loop reference or ref of final LOOP (or 0). */ + + MSize sizesnap; /* Size of temp. snapshot buffer. */ + SnapShot *snapbuf; /* Temp. snapshot buffer. */ + SnapEntry *snapmapbuf; /* Temp. snapshot map buffer. */ + MSize sizesnapmap; /* Size of temp. snapshot map buffer. */ + + PostProc postproc; /* Required post-processing after execution. */ +#if LJ_SOFTFP32 || (LJ_32 && LJ_HASFFI) + uint8_t needsplit; /* Need SPLIT pass. */ +#endif + uint8_t retryrec; /* Retry recording. */ + + GCRef *trace; /* Array of traces. */ + TraceNo freetrace; /* Start of scan for next free trace. */ + MSize sizetrace; /* Size of trace array. */ + IRRef1 ktrace; /* Reference to KGC with GCtrace. */ + + IRRef1 chain[IR__MAX]; /* IR instruction skip-list chain anchors. */ + TRef slot[LJ_MAX_JSLOTS+LJ_STACK_EXTRA]; /* Stack slot map. */ + + int32_t param[JIT_P__MAX]; /* JIT engine parameters. */ + + MCode *exitstubgroup[LJ_MAX_EXITSTUBGR]; /* Exit stub group addresses. */ + + HotPenalty penalty[PENALTY_SLOTS]; /* Penalty slots. */ + uint32_t penaltyslot; /* Round-robin index into penalty slots. */ + +#ifdef LUAJIT_ENABLE_TABLE_BUMP + RBCHashEntry rbchash[RBCHASH_SLOTS]; /* Reverse bytecode map. */ +#endif + + BPropEntry bpropcache[BPROP_SLOTS]; /* Backpropagation cache slots. */ + uint32_t bpropslot; /* Round-robin index into bpropcache slots. */ + + ScEvEntry scev; /* Scalar evolution analysis cache slots. */ + + const BCIns *startpc; /* Bytecode PC of starting instruction. */ + TraceNo parent; /* Parent of current side trace (0 for root traces). */ + ExitNo exitno; /* Exit number in parent of current side trace. */ + int exitcode; /* Exit code from unwound trace. */ + + BCIns *patchpc; /* PC for pending re-patch. */ + BCIns patchins; /* Instruction for pending re-patch. */ + + int mcprot; /* Protection of current mcode area. */ + MCode *mcarea; /* Base of current mcode area. */ + MCode *mctop; /* Top of current mcode area. */ + MCode *mcbot; /* Bottom of current mcode area. */ + size_t szmcarea; /* Size of current mcode area. */ + size_t szallmcarea; /* Total size of all allocated mcode areas. */ + + TValue errinfo; /* Additional info element for trace errors. */ + +#if LJ_HASPROFILE + GCproto *prev_pt; /* Previous prototype. */ + BCLine prev_line; /* Previous line. */ + int prof_mode; /* Profiling mode: 0, 'f', 'l'. */ +#endif +} jit_State; + +#ifdef LUA_USE_ASSERT +#define lj_assertJ(c, ...) lj_assertG_(J2G(J), (c), __VA_ARGS__) +#else +#define lj_assertJ(c, ...) ((void)J) +#endif +#endif + +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_lex.c b/fluent-bit/lib/luajit-3065c9/src/lj_lex.c new file mode 100644 index 00000000..463a87ce --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_lex.c @@ -0,0 +1,514 @@ +/* +** Lexical analyzer. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +** +** Major portions taken verbatim or adapted from the Lua interpreter. +** Copyright (C) 1994-2008 Lua.org, PUC-Rio. See Copyright Notice in lua.h +*/ + +#define lj_lex_c +#define LUA_CORE + +#include "lj_obj.h" +#include "lj_gc.h" +#include "lj_err.h" +#include "lj_buf.h" +#include "lj_str.h" +#if LJ_HASFFI +#include "lj_tab.h" +#include "lj_ctype.h" +#include "lj_cdata.h" +#include "lualib.h" +#endif +#include "lj_state.h" +#include "lj_lex.h" +#include "lj_parse.h" +#include "lj_char.h" +#include "lj_strscan.h" +#include "lj_strfmt.h" + +/* Lua lexer token names. */ +static const char *const tokennames[] = { +#define TKSTR1(name) #name, +#define TKSTR2(name, sym) #sym, +TKDEF(TKSTR1, TKSTR2) +#undef TKSTR1 +#undef TKSTR2 + NULL +}; + +/* -- Buffer handling ----------------------------------------------------- */ + +#define LEX_EOF (-1) +#define lex_iseol(ls) (ls->c == '\n' || ls->c == '\r') + +/* Get more input from reader. */ +static LJ_NOINLINE LexChar lex_more(LexState *ls) +{ + size_t sz; + const char *p = ls->rfunc(ls->L, ls->rdata, &sz); + if (p == NULL || sz == 0) return LEX_EOF; + if (sz >= LJ_MAX_BUF) { + if (sz != ~(size_t)0) lj_err_mem(ls->L); + sz = ~(uintptr_t)0 - (uintptr_t)p; + if (sz >= LJ_MAX_BUF) sz = LJ_MAX_BUF-1; + ls->endmark = 1; + } + ls->pe = p + sz; + ls->p = p + 1; + return (LexChar)(uint8_t)p[0]; +} + +/* Get next character. */ +static LJ_AINLINE LexChar lex_next(LexState *ls) +{ + return (ls->c = ls->p < ls->pe ? (LexChar)(uint8_t)*ls->p++ : lex_more(ls)); +} + +/* Save character. */ +static LJ_AINLINE void lex_save(LexState *ls, LexChar c) +{ + lj_buf_putb(&ls->sb, c); +} + +/* Save previous character and get next character. */ +static LJ_AINLINE LexChar lex_savenext(LexState *ls) +{ + lex_save(ls, ls->c); + return lex_next(ls); +} + +/* Skip line break. Handles "\n", "\r", "\r\n" or "\n\r". */ +static void lex_newline(LexState *ls) +{ + LexChar old = ls->c; + lj_assertLS(lex_iseol(ls), "bad usage"); + lex_next(ls); /* Skip "\n" or "\r". */ + if (lex_iseol(ls) && ls->c != old) lex_next(ls); /* Skip "\n\r" or "\r\n". */ + if (++ls->linenumber >= LJ_MAX_LINE) + lj_lex_error(ls, ls->tok, LJ_ERR_XLINES); +} + +/* -- Scanner for terminals ----------------------------------------------- */ + +/* Parse a number literal. */ +static void lex_number(LexState *ls, TValue *tv) +{ + StrScanFmt fmt; + LexChar c, xp = 'e'; + lj_assertLS(lj_char_isdigit(ls->c), "bad usage"); + if ((c = ls->c) == '0' && (lex_savenext(ls) | 0x20) == 'x') + xp = 'p'; + while (lj_char_isident(ls->c) || ls->c == '.' || + ((ls->c == '-' || ls->c == '+') && (c | 0x20) == xp)) { + c = ls->c; + lex_savenext(ls); + } + lex_save(ls, '\0'); + fmt = lj_strscan_scan((const uint8_t *)ls->sb.b, sbuflen(&ls->sb)-1, tv, + (LJ_DUALNUM ? STRSCAN_OPT_TOINT : STRSCAN_OPT_TONUM) | + (LJ_HASFFI ? (STRSCAN_OPT_LL|STRSCAN_OPT_IMAG) : 0)); + if (LJ_DUALNUM && fmt == STRSCAN_INT) { + setitype(tv, LJ_TISNUM); + } else if (fmt == STRSCAN_NUM) { + /* Already in correct format. */ +#if LJ_HASFFI + } else if (fmt != STRSCAN_ERROR) { + lua_State *L = ls->L; + GCcdata *cd; + lj_assertLS(fmt == STRSCAN_I64 || fmt == STRSCAN_U64 || fmt == STRSCAN_IMAG, + "unexpected number format %d", fmt); + ctype_loadffi(L); + if (fmt == STRSCAN_IMAG) { + cd = lj_cdata_new_(L, CTID_COMPLEX_DOUBLE, 2*sizeof(double)); + ((double *)cdataptr(cd))[0] = 0; + ((double *)cdataptr(cd))[1] = numV(tv); + } else { + cd = lj_cdata_new_(L, fmt==STRSCAN_I64 ? CTID_INT64 : CTID_UINT64, 8); + *(uint64_t *)cdataptr(cd) = tv->u64; + } + lj_parse_keepcdata(ls, tv, cd); +#endif + } else { + lj_assertLS(fmt == STRSCAN_ERROR, + "unexpected number format %d", fmt); + lj_lex_error(ls, TK_number, LJ_ERR_XNUMBER); + } +} + +/* Skip equal signs for "[=...=[" and "]=...=]" and return their count. */ +static int lex_skipeq(LexState *ls) +{ + int count = 0; + LexChar s = ls->c; + lj_assertLS(s == '[' || s == ']', "bad usage"); + while (lex_savenext(ls) == '=' && count < 0x20000000) + count++; + return (ls->c == s) ? count : (-count) - 1; +} + +/* Parse a long string or long comment (tv set to NULL). */ +static void lex_longstring(LexState *ls, TValue *tv, int sep) +{ + lex_savenext(ls); /* Skip second '['. */ + if (lex_iseol(ls)) /* Skip initial newline. */ + lex_newline(ls); + for (;;) { + switch (ls->c) { + case LEX_EOF: + lj_lex_error(ls, TK_eof, tv ? LJ_ERR_XLSTR : LJ_ERR_XLCOM); + break; + case ']': + if (lex_skipeq(ls) == sep) { + lex_savenext(ls); /* Skip second ']'. */ + goto endloop; + } + break; + case '\n': + case '\r': + lex_save(ls, '\n'); + lex_newline(ls); + if (!tv) lj_buf_reset(&ls->sb); /* Don't waste space for comments. */ + break; + default: + lex_savenext(ls); + break; + } + } endloop: + if (tv) { + GCstr *str = lj_parse_keepstr(ls, ls->sb.b + (2 + (MSize)sep), + sbuflen(&ls->sb) - 2*(2 + (MSize)sep)); + setstrV(ls->L, tv, str); + } +} + +/* Parse a string. */ +static void lex_string(LexState *ls, TValue *tv) +{ + LexChar delim = ls->c; /* Delimiter is '\'' or '"'. */ + lex_savenext(ls); + while (ls->c != delim) { + switch (ls->c) { + case LEX_EOF: + lj_lex_error(ls, TK_eof, LJ_ERR_XSTR); + continue; + case '\n': + case '\r': + lj_lex_error(ls, TK_string, LJ_ERR_XSTR); + continue; + case '\\': { + LexChar c = lex_next(ls); /* Skip the '\\'. */ + switch (c) { + case 'a': c = '\a'; break; + case 'b': c = '\b'; break; + case 'f': c = '\f'; break; + case 'n': c = '\n'; break; + case 'r': c = '\r'; break; + case 't': c = '\t'; break; + case 'v': c = '\v'; break; + case 'x': /* Hexadecimal escape '\xXX'. */ + c = (lex_next(ls) & 15u) << 4; + if (!lj_char_isdigit(ls->c)) { + if (!lj_char_isxdigit(ls->c)) goto err_xesc; + c += 9 << 4; + } + c += (lex_next(ls) & 15u); + if (!lj_char_isdigit(ls->c)) { + if (!lj_char_isxdigit(ls->c)) goto err_xesc; + c += 9; + } + break; + case 'u': /* Unicode escape '\u{XX...}'. */ + if (lex_next(ls) != '{') goto err_xesc; + lex_next(ls); + c = 0; + do { + c = (c << 4) | (ls->c & 15u); + if (!lj_char_isdigit(ls->c)) { + if (!lj_char_isxdigit(ls->c)) goto err_xesc; + c += 9; + } + if (c >= 0x110000) goto err_xesc; /* Out of Unicode range. */ + } while (lex_next(ls) != '}'); + if (c < 0x800) { + if (c < 0x80) break; + lex_save(ls, 0xc0 | (c >> 6)); + } else { + if (c >= 0x10000) { + lex_save(ls, 0xf0 | (c >> 18)); + lex_save(ls, 0x80 | ((c >> 12) & 0x3f)); + } else { + if (c >= 0xd800 && c < 0xe000) goto err_xesc; /* No surrogates. */ + lex_save(ls, 0xe0 | (c >> 12)); + } + lex_save(ls, 0x80 | ((c >> 6) & 0x3f)); + } + c = 0x80 | (c & 0x3f); + break; + case 'z': /* Skip whitespace. */ + lex_next(ls); + while (lj_char_isspace(ls->c)) + if (lex_iseol(ls)) lex_newline(ls); else lex_next(ls); + continue; + case '\n': case '\r': lex_save(ls, '\n'); lex_newline(ls); continue; + case '\\': case '\"': case '\'': break; + case LEX_EOF: continue; + default: + if (!lj_char_isdigit(c)) + goto err_xesc; + c -= '0'; /* Decimal escape '\ddd'. */ + if (lj_char_isdigit(lex_next(ls))) { + c = c*10 + (ls->c - '0'); + if (lj_char_isdigit(lex_next(ls))) { + c = c*10 + (ls->c - '0'); + if (c > 255) { + err_xesc: + lj_lex_error(ls, TK_string, LJ_ERR_XESC); + } + lex_next(ls); + } + } + lex_save(ls, c); + continue; + } + lex_save(ls, c); + lex_next(ls); + continue; + } + default: + lex_savenext(ls); + break; + } + } + lex_savenext(ls); /* Skip trailing delimiter. */ + setstrV(ls->L, tv, + lj_parse_keepstr(ls, ls->sb.b+1, sbuflen(&ls->sb)-2)); +} + +/* -- Main lexical scanner ------------------------------------------------ */ + +/* Get next lexical token. */ +static LexToken lex_scan(LexState *ls, TValue *tv) +{ + lj_buf_reset(&ls->sb); + for (;;) { + if (lj_char_isident(ls->c)) { + GCstr *s; + if (lj_char_isdigit(ls->c)) { /* Numeric literal. */ + lex_number(ls, tv); + return TK_number; + } + /* Identifier or reserved word. */ + do { + lex_savenext(ls); + } while (lj_char_isident(ls->c)); + s = lj_parse_keepstr(ls, ls->sb.b, sbuflen(&ls->sb)); + setstrV(ls->L, tv, s); + if (s->reserved > 0) /* Reserved word? */ + return TK_OFS + s->reserved; + return TK_name; + } + switch (ls->c) { + case '\n': + case '\r': + lex_newline(ls); + continue; + case ' ': + case '\t': + case '\v': + case '\f': + lex_next(ls); + continue; + case '-': + lex_next(ls); + if (ls->c != '-') return '-'; + lex_next(ls); + if (ls->c == '[') { /* Long comment "--[=*[...]=*]". */ + int sep = lex_skipeq(ls); + lj_buf_reset(&ls->sb); /* `lex_skipeq' may dirty the buffer */ + if (sep >= 0) { + lex_longstring(ls, NULL, sep); + lj_buf_reset(&ls->sb); + continue; + } + } + /* Short comment "--.*\n". */ + while (!lex_iseol(ls) && ls->c != LEX_EOF) + lex_next(ls); + continue; + case '[': { + int sep = lex_skipeq(ls); + if (sep >= 0) { + lex_longstring(ls, tv, sep); + return TK_string; + } else if (sep == -1) { + return '['; + } else { + lj_lex_error(ls, TK_string, LJ_ERR_XLDELIM); + continue; + } + } + case '=': + lex_next(ls); + if (ls->c != '=') return '='; else { lex_next(ls); return TK_eq; } + case '<': + lex_next(ls); + if (ls->c != '=') return '<'; else { lex_next(ls); return TK_le; } + case '>': + lex_next(ls); + if (ls->c != '=') return '>'; else { lex_next(ls); return TK_ge; } + case '~': + lex_next(ls); + if (ls->c != '=') return '~'; else { lex_next(ls); return TK_ne; } + case ':': + lex_next(ls); + if (ls->c != ':') return ':'; else { lex_next(ls); return TK_label; } + case '"': + case '\'': + lex_string(ls, tv); + return TK_string; + case '.': + if (lex_savenext(ls) == '.') { + lex_next(ls); + if (ls->c == '.') { + lex_next(ls); + return TK_dots; /* ... */ + } + return TK_concat; /* .. */ + } else if (!lj_char_isdigit(ls->c)) { + return '.'; + } else { + lex_number(ls, tv); + return TK_number; + } + case LEX_EOF: + return TK_eof; + default: { + LexChar c = ls->c; + lex_next(ls); + return c; /* Single-char tokens (+ - / ...). */ + } + } + } +} + +/* -- Lexer API ----------------------------------------------------------- */ + +/* Setup lexer state. */ +int lj_lex_setup(lua_State *L, LexState *ls) +{ + int header = 0; + ls->L = L; + ls->fs = NULL; + ls->pe = ls->p = NULL; + ls->vstack = NULL; + ls->sizevstack = 0; + ls->vtop = 0; + ls->bcstack = NULL; + ls->sizebcstack = 0; + ls->tok = 0; + ls->lookahead = TK_eof; /* No look-ahead token. */ + ls->linenumber = 1; + ls->lastline = 1; + ls->endmark = 0; + lex_next(ls); /* Read-ahead first char. */ + if (ls->c == 0xef && ls->p + 2 <= ls->pe && (uint8_t)ls->p[0] == 0xbb && + (uint8_t)ls->p[1] == 0xbf) { /* Skip UTF-8 BOM (if buffered). */ + ls->p += 2; + lex_next(ls); + header = 1; + } + if (ls->c == '#') { /* Skip POSIX #! header line. */ + do { + lex_next(ls); + if (ls->c == LEX_EOF) return 0; + } while (!lex_iseol(ls)); + lex_newline(ls); + header = 1; + } + if (ls->c == LUA_SIGNATURE[0]) { /* Bytecode dump. */ + if (header) { + /* + ** Loading bytecode with an extra header is disabled for security + ** reasons. This may circumvent the usual check for bytecode vs. + ** Lua code by looking at the first char. Since this is a potential + ** security violation no attempt is made to echo the chunkname either. + */ + setstrV(L, L->top++, lj_err_str(L, LJ_ERR_BCBAD)); + lj_err_throw(L, LUA_ERRSYNTAX); + } + return 1; + } + return 0; +} + +/* Cleanup lexer state. */ +void lj_lex_cleanup(lua_State *L, LexState *ls) +{ + global_State *g = G(L); + lj_mem_freevec(g, ls->bcstack, ls->sizebcstack, BCInsLine); + lj_mem_freevec(g, ls->vstack, ls->sizevstack, VarInfo); + lj_buf_free(g, &ls->sb); +} + +/* Return next lexical token. */ +void lj_lex_next(LexState *ls) +{ + ls->lastline = ls->linenumber; + if (LJ_LIKELY(ls->lookahead == TK_eof)) { /* No lookahead token? */ + ls->tok = lex_scan(ls, &ls->tokval); /* Get next token. */ + } else { /* Otherwise return lookahead token. */ + ls->tok = ls->lookahead; + ls->lookahead = TK_eof; + ls->tokval = ls->lookaheadval; + } +} + +/* Look ahead for the next token. */ +LexToken lj_lex_lookahead(LexState *ls) +{ + lj_assertLS(ls->lookahead == TK_eof, "double lookahead"); + ls->lookahead = lex_scan(ls, &ls->lookaheadval); + return ls->lookahead; +} + +/* Convert token to string. */ +const char *lj_lex_token2str(LexState *ls, LexToken tok) +{ + if (tok > TK_OFS) + return tokennames[tok-TK_OFS-1]; + else if (!lj_char_iscntrl(tok)) + return lj_strfmt_pushf(ls->L, "%c", tok); + else + return lj_strfmt_pushf(ls->L, "char(%d)", tok); +} + +/* Lexer error. */ +void lj_lex_error(LexState *ls, LexToken tok, ErrMsg em, ...) +{ + const char *tokstr; + va_list argp; + if (tok == 0) { + tokstr = NULL; + } else if (tok == TK_name || tok == TK_string || tok == TK_number) { + lex_save(ls, '\0'); + tokstr = ls->sb.b; + } else { + tokstr = lj_lex_token2str(ls, tok); + } + va_start(argp, em); + lj_err_lex(ls->L, ls->chunkname, tokstr, ls->linenumber, em, argp); + va_end(argp); +} + +/* Initialize strings for reserved words. */ +void lj_lex_init(lua_State *L) +{ + uint32_t i; + for (i = 0; i < TK_RESERVED; i++) { + GCstr *s = lj_str_newz(L, tokennames[i]); + fixstring(s); /* Reserved words are never collected. */ + s->reserved = (uint8_t)(i+1); + } +} + diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_lex.h b/fluent-bit/lib/luajit-3065c9/src/lj_lex.h new file mode 100644 index 00000000..cb5b5769 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_lex.h @@ -0,0 +1,93 @@ +/* +** Lexical analyzer. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#ifndef _LJ_LEX_H +#define _LJ_LEX_H + +#include + +#include "lj_obj.h" +#include "lj_err.h" + +/* Lua lexer tokens. */ +#define TKDEF(_, __) \ + _(and) _(break) _(do) _(else) _(elseif) _(end) _(false) \ + _(for) _(function) _(goto) _(if) _(in) _(local) _(nil) _(not) _(or) \ + _(repeat) _(return) _(then) _(true) _(until) _(while) \ + __(concat, ..) __(dots, ...) __(eq, ==) __(ge, >=) __(le, <=) __(ne, ~=) \ + __(label, ::) __(number, ) __(name, ) __(string, ) \ + __(eof, ) + +enum { + TK_OFS = 256, +#define TKENUM1(name) TK_##name, +#define TKENUM2(name, sym) TK_##name, +TKDEF(TKENUM1, TKENUM2) +#undef TKENUM1 +#undef TKENUM2 + TK_RESERVED = TK_while - TK_OFS +}; + +typedef int LexChar; /* Lexical character. Unsigned ext. from char. */ +typedef int LexToken; /* Lexical token. */ + +/* Combined bytecode ins/line. Only used during bytecode generation. */ +typedef struct BCInsLine { + BCIns ins; /* Bytecode instruction. */ + BCLine line; /* Line number for this bytecode. */ +} BCInsLine; + +/* Info for local variables. Only used during bytecode generation. */ +typedef struct VarInfo { + GCRef name; /* Local variable name or goto/label name. */ + BCPos startpc; /* First point where the local variable is active. */ + BCPos endpc; /* First point where the local variable is dead. */ + uint8_t slot; /* Variable slot. */ + uint8_t info; /* Variable/goto/label info. */ +} VarInfo; + +/* Lua lexer state. */ +typedef struct LexState { + struct FuncState *fs; /* Current FuncState. Defined in lj_parse.c. */ + struct lua_State *L; /* Lua state. */ + TValue tokval; /* Current token value. */ + TValue lookaheadval; /* Lookahead token value. */ + const char *p; /* Current position in input buffer. */ + const char *pe; /* End of input buffer. */ + LexChar c; /* Current character. */ + LexToken tok; /* Current token. */ + LexToken lookahead; /* Lookahead token. */ + SBuf sb; /* String buffer for tokens. */ + lua_Reader rfunc; /* Reader callback. */ + void *rdata; /* Reader callback data. */ + BCLine linenumber; /* Input line counter. */ + BCLine lastline; /* Line of last token. */ + GCstr *chunkname; /* Current chunk name (interned string). */ + const char *chunkarg; /* Chunk name argument. */ + const char *mode; /* Allow loading bytecode (b) and/or source text (t). */ + VarInfo *vstack; /* Stack for names and extents of local variables. */ + MSize sizevstack; /* Size of variable stack. */ + MSize vtop; /* Top of variable stack. */ + BCInsLine *bcstack; /* Stack for bytecode instructions/line numbers. */ + MSize sizebcstack; /* Size of bytecode stack. */ + uint32_t level; /* Syntactical nesting level. */ + int endmark; /* Trust bytecode end marker, even if not at EOF. */ +} LexState; + +LJ_FUNC int lj_lex_setup(lua_State *L, LexState *ls); +LJ_FUNC void lj_lex_cleanup(lua_State *L, LexState *ls); +LJ_FUNC void lj_lex_next(LexState *ls); +LJ_FUNC LexToken lj_lex_lookahead(LexState *ls); +LJ_FUNC const char *lj_lex_token2str(LexState *ls, LexToken tok); +LJ_FUNC_NORET void lj_lex_error(LexState *ls, LexToken tok, ErrMsg em, ...); +LJ_FUNC void lj_lex_init(lua_State *L); + +#ifdef LUA_USE_ASSERT +#define lj_assertLS(c, ...) (lj_assertG_(G(ls->L), (c), __VA_ARGS__)) +#else +#define lj_assertLS(c, ...) ((void)ls) +#endif + +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_lib.c b/fluent-bit/lib/luajit-3065c9/src/lj_lib.c new file mode 100644 index 00000000..82a9e256 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_lib.c @@ -0,0 +1,359 @@ +/* +** Library function support. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#define lj_lib_c +#define LUA_CORE + +#include "lauxlib.h" + +#include "lj_obj.h" +#include "lj_gc.h" +#include "lj_err.h" +#include "lj_str.h" +#include "lj_tab.h" +#include "lj_func.h" +#include "lj_bc.h" +#include "lj_dispatch.h" +#if LJ_HASFFI +#include "lj_ctype.h" +#endif +#include "lj_vm.h" +#include "lj_strscan.h" +#include "lj_strfmt.h" +#include "lj_lex.h" +#include "lj_bcdump.h" +#include "lj_lib.h" + +/* -- Library initialization ---------------------------------------------- */ + +static GCtab *lib_create_table(lua_State *L, const char *libname, int hsize) +{ + if (libname) { + luaL_findtable(L, LUA_REGISTRYINDEX, "_LOADED", 16); + lua_getfield(L, -1, libname); + if (!tvistab(L->top-1)) { + L->top--; + if (luaL_findtable(L, LUA_GLOBALSINDEX, libname, hsize) != NULL) + lj_err_callerv(L, LJ_ERR_BADMODN, libname); + settabV(L, L->top, tabV(L->top-1)); + L->top++; + lua_setfield(L, -3, libname); /* _LOADED[libname] = new table */ + } + L->top--; + settabV(L, L->top-1, tabV(L->top)); + } else { + lua_createtable(L, 0, hsize); + } + return tabV(L->top-1); +} + +static const uint8_t *lib_read_lfunc(lua_State *L, const uint8_t *p, GCtab *tab) +{ + int len = *p++; + GCstr *name = lj_str_new(L, (const char *)p, len); + LexState ls; + GCproto *pt; + GCfunc *fn; + memset(&ls, 0, sizeof(ls)); + ls.L = L; + ls.p = (const char *)(p+len); + ls.pe = (const char *)~(uintptr_t)0; + ls.c = -1; + ls.level = (BCDUMP_F_STRIP|(LJ_BE*BCDUMP_F_BE)); + ls.chunkname = name; + pt = lj_bcread_proto(&ls); + pt->firstline = ~(BCLine)0; + fn = lj_func_newL_empty(L, pt, tabref(L->env)); + /* NOBARRIER: See below for common barrier. */ + setfuncV(L, lj_tab_setstr(L, tab, name), fn); + return (const uint8_t *)ls.p; +} + +void lj_lib_register(lua_State *L, const char *libname, + const uint8_t *p, const lua_CFunction *cf) +{ + GCtab *env = tabref(L->env); + GCfunc *ofn = NULL; + int ffid = *p++; + BCIns *bcff = &L2GG(L)->bcff[*p++]; + GCtab *tab = lib_create_table(L, libname, *p++); + ptrdiff_t tpos = L->top - L->base; + + /* Avoid barriers further down. */ + lj_gc_anybarriert(L, tab); + tab->nomm = 0; + + for (;;) { + uint32_t tag = *p++; + MSize len = tag & LIBINIT_LENMASK; + tag &= LIBINIT_TAGMASK; + if (tag != LIBINIT_STRING) { + const char *name; + MSize nuv = (MSize)(L->top - L->base - tpos); + GCfunc *fn = lj_func_newC(L, nuv, env); + if (nuv) { + L->top = L->base + tpos; + memcpy(fn->c.upvalue, L->top, sizeof(TValue)*nuv); + } + fn->c.ffid = (uint8_t)(ffid++); + name = (const char *)p; + p += len; + if (tag == LIBINIT_CF) + setmref(fn->c.pc, &G(L)->bc_cfunc_int); + else + setmref(fn->c.pc, bcff++); + if (tag == LIBINIT_ASM_) + fn->c.f = ofn->c.f; /* Copy handler from previous function. */ + else + fn->c.f = *cf++; /* Get cf or handler from C function table. */ + if (len) { + /* NOBARRIER: See above for common barrier. */ + setfuncV(L, lj_tab_setstr(L, tab, lj_str_new(L, name, len)), fn); + } + ofn = fn; + } else { + switch (tag | len) { + case LIBINIT_LUA: + p = lib_read_lfunc(L, p, tab); + break; + case LIBINIT_SET: + L->top -= 2; + if (tvisstr(L->top+1) && strV(L->top+1)->len == 0) + env = tabV(L->top); + else /* NOBARRIER: See above for common barrier. */ + copyTV(L, lj_tab_set(L, tab, L->top+1), L->top); + break; + case LIBINIT_NUMBER: + memcpy(&L->top->n, p, sizeof(double)); + L->top++; + p += sizeof(double); + break; + case LIBINIT_COPY: + copyTV(L, L->top, L->top - *p++); + L->top++; + break; + case LIBINIT_LASTCL: + setfuncV(L, L->top++, ofn); + break; + case LIBINIT_FFID: + ffid++; + break; + case LIBINIT_END: + return; + default: + setstrV(L, L->top++, lj_str_new(L, (const char *)p, len)); + p += len; + break; + } + } + } +} + +/* Push internal function on the stack. */ +GCfunc *lj_lib_pushcc(lua_State *L, lua_CFunction f, int id, int n) +{ + GCfunc *fn; + lua_pushcclosure(L, f, n); + fn = funcV(L->top-1); + fn->c.ffid = (uint8_t)id; + setmref(fn->c.pc, &G(L)->bc_cfunc_int); + return fn; +} + +void lj_lib_prereg(lua_State *L, const char *name, lua_CFunction f, GCtab *env) +{ + luaL_findtable(L, LUA_REGISTRYINDEX, "_PRELOAD", 4); + lua_pushcfunction(L, f); + /* NOBARRIER: The function is new (marked white). */ + setgcref(funcV(L->top-1)->c.env, obj2gco(env)); + lua_setfield(L, -2, name); + L->top--; +} + +int lj_lib_postreg(lua_State *L, lua_CFunction cf, int id, const char *name) +{ + GCfunc *fn = lj_lib_pushcf(L, cf, id); + GCtab *t = tabref(curr_func(L)->c.env); /* Reference to parent table. */ + setfuncV(L, lj_tab_setstr(L, t, lj_str_newz(L, name)), fn); + lj_gc_anybarriert(L, t); + setfuncV(L, L->top++, fn); + return 1; +} + +/* -- Type checks --------------------------------------------------------- */ + +TValue *lj_lib_checkany(lua_State *L, int narg) +{ + TValue *o = L->base + narg-1; + if (o >= L->top) + lj_err_arg(L, narg, LJ_ERR_NOVAL); + return o; +} + +GCstr *lj_lib_checkstr(lua_State *L, int narg) +{ + TValue *o = L->base + narg-1; + if (o < L->top) { + if (LJ_LIKELY(tvisstr(o))) { + return strV(o); + } else if (tvisnumber(o)) { + GCstr *s = lj_strfmt_number(L, o); + setstrV(L, o, s); + return s; + } + } + lj_err_argt(L, narg, LUA_TSTRING); + return NULL; /* unreachable */ +} + +GCstr *lj_lib_optstr(lua_State *L, int narg) +{ + TValue *o = L->base + narg-1; + return (o < L->top && !tvisnil(o)) ? lj_lib_checkstr(L, narg) : NULL; +} + +#if LJ_DUALNUM +void lj_lib_checknumber(lua_State *L, int narg) +{ + TValue *o = L->base + narg-1; + if (!(o < L->top && lj_strscan_numberobj(o))) + lj_err_argt(L, narg, LUA_TNUMBER); +} +#endif + +lua_Number lj_lib_checknum(lua_State *L, int narg) +{ + TValue *o = L->base + narg-1; + if (!(o < L->top && + (tvisnumber(o) || (tvisstr(o) && lj_strscan_num(strV(o), o))))) + lj_err_argt(L, narg, LUA_TNUMBER); + if (LJ_UNLIKELY(tvisint(o))) { + lua_Number n = (lua_Number)intV(o); + setnumV(o, n); + return n; + } else { + return numV(o); + } +} + +int32_t lj_lib_checkint(lua_State *L, int narg) +{ + TValue *o = L->base + narg-1; + if (!(o < L->top && lj_strscan_numberobj(o))) + lj_err_argt(L, narg, LUA_TNUMBER); + if (LJ_LIKELY(tvisint(o))) { + return intV(o); + } else { + int32_t i = lj_num2int(numV(o)); + if (LJ_DUALNUM) setintV(o, i); + return i; + } +} + +int32_t lj_lib_optint(lua_State *L, int narg, int32_t def) +{ + TValue *o = L->base + narg-1; + return (o < L->top && !tvisnil(o)) ? lj_lib_checkint(L, narg) : def; +} + +GCfunc *lj_lib_checkfunc(lua_State *L, int narg) +{ + TValue *o = L->base + narg-1; + if (!(o < L->top && tvisfunc(o))) + lj_err_argt(L, narg, LUA_TFUNCTION); + return funcV(o); +} + +GCtab *lj_lib_checktab(lua_State *L, int narg) +{ + TValue *o = L->base + narg-1; + if (!(o < L->top && tvistab(o))) + lj_err_argt(L, narg, LUA_TTABLE); + return tabV(o); +} + +GCtab *lj_lib_checktabornil(lua_State *L, int narg) +{ + TValue *o = L->base + narg-1; + if (o < L->top) { + if (tvistab(o)) + return tabV(o); + else if (tvisnil(o)) + return NULL; + } + lj_err_arg(L, narg, LJ_ERR_NOTABN); + return NULL; /* unreachable */ +} + +int lj_lib_checkopt(lua_State *L, int narg, int def, const char *lst) +{ + GCstr *s = def >= 0 ? lj_lib_optstr(L, narg) : lj_lib_checkstr(L, narg); + if (s) { + const char *opt = strdata(s); + MSize len = s->len; + int i; + for (i = 0; *(const uint8_t *)lst; i++) { + if (*(const uint8_t *)lst == len && memcmp(opt, lst+1, len) == 0) + return i; + lst += 1+*(const uint8_t *)lst; + } + lj_err_argv(L, narg, LJ_ERR_INVOPTM, opt); + } + return def; +} + +/* -- Strict type checks -------------------------------------------------- */ + +/* The following type checks do not coerce between strings and numbers. +** And they handle plain int64_t/uint64_t FFI numbers, too. +*/ + +#if LJ_HASBUFFER +GCstr *lj_lib_checkstrx(lua_State *L, int narg) +{ + TValue *o = L->base + narg-1; + if (!(o < L->top && tvisstr(o))) lj_err_argt(L, narg, LUA_TSTRING); + return strV(o); +} + +int32_t lj_lib_checkintrange(lua_State *L, int narg, int32_t a, int32_t b) +{ + TValue *o = L->base + narg-1; + lj_assertL(b >= 0, "expected range must be non-negative"); + if (o < L->top) { + if (LJ_LIKELY(tvisint(o))) { + int32_t i = intV(o); + if (i >= a && i <= b) return i; + } else if (LJ_LIKELY(tvisnum(o))) { + /* For performance reasons, this doesn't check for integerness or + ** integer overflow. Overflow detection still works, since all FPUs + ** return either MININT or MAXINT, which is then out of range. + */ + int32_t i = (int32_t)numV(o); + if (i >= a && i <= b) return i; +#if LJ_HASFFI + } else if (tviscdata(o)) { + GCcdata *cd = cdataV(o); + if (cd->ctypeid == CTID_INT64) { + int64_t i = *(int64_t *)cdataptr(cd); + if (i >= (int64_t)a && i <= (int64_t)b) return (int32_t)i; + } else if (cd->ctypeid == CTID_UINT64) { + uint64_t i = *(uint64_t *)cdataptr(cd); + if ((a < 0 || i >= (uint64_t)a) && i <= (uint64_t)b) return (int32_t)i; + } else { + goto badtype; + } +#endif + } else { + goto badtype; + } + lj_err_arg(L, narg, LJ_ERR_NUMRNG); + } +badtype: + lj_err_argt(L, narg, LUA_TNUMBER); + return 0; /* unreachable */ +} +#endif + diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_lib.h b/fluent-bit/lib/luajit-3065c9/src/lj_lib.h new file mode 100644 index 00000000..a18f52bf --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_lib.h @@ -0,0 +1,116 @@ +/* +** Library function support. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#ifndef _LJ_LIB_H +#define _LJ_LIB_H + +#include "lj_obj.h" + +/* +** A fallback handler is called by the assembler VM if the fast path fails: +** +** - too few arguments: unrecoverable. +** - wrong argument type: recoverable, if coercion succeeds. +** - bad argument value: unrecoverable. +** - stack overflow: recoverable, if stack reallocation succeeds. +** - extra handling: recoverable. +** +** The unrecoverable cases throw an error with lj_err_arg(), lj_err_argtype(), +** lj_err_caller() or lj_err_callermsg(). +** The recoverable cases return 0 or the number of results + 1. +** The assembler VM retries the fast path only if 0 is returned. +** This time the fallback must not be called again or it gets stuck in a loop. +*/ + +/* Return values from fallback handler. */ +#define FFH_RETRY 0 +#define FFH_UNREACHABLE FFH_RETRY +#define FFH_RES(n) ((n)+1) +#define FFH_TAILCALL (-1) + +LJ_FUNC TValue *lj_lib_checkany(lua_State *L, int narg); +LJ_FUNC GCstr *lj_lib_checkstr(lua_State *L, int narg); +LJ_FUNC GCstr *lj_lib_optstr(lua_State *L, int narg); +#if LJ_DUALNUM +LJ_FUNC void lj_lib_checknumber(lua_State *L, int narg); +#else +#define lj_lib_checknumber(L, narg) lj_lib_checknum((L), (narg)) +#endif +LJ_FUNC lua_Number lj_lib_checknum(lua_State *L, int narg); +LJ_FUNC int32_t lj_lib_checkint(lua_State *L, int narg); +LJ_FUNC int32_t lj_lib_optint(lua_State *L, int narg, int32_t def); +LJ_FUNC GCfunc *lj_lib_checkfunc(lua_State *L, int narg); +LJ_FUNC GCtab *lj_lib_checktab(lua_State *L, int narg); +LJ_FUNC GCtab *lj_lib_checktabornil(lua_State *L, int narg); +LJ_FUNC int lj_lib_checkopt(lua_State *L, int narg, int def, const char *lst); + +#if LJ_HASBUFFER +LJ_FUNC GCstr *lj_lib_checkstrx(lua_State *L, int narg); +LJ_FUNC int32_t lj_lib_checkintrange(lua_State *L, int narg, + int32_t a, int32_t b); +#endif + +/* Avoid including lj_frame.h. */ +#if LJ_GC64 +#define lj_lib_upvalue(L, n) \ + (&gcval(L->base-2)->fn.c.upvalue[(n)-1]) +#elif LJ_FR2 +#define lj_lib_upvalue(L, n) \ + (&gcref((L->base-2)->gcr)->fn.c.upvalue[(n)-1]) +#else +#define lj_lib_upvalue(L, n) \ + (&gcref((L->base-1)->fr.func)->fn.c.upvalue[(n)-1]) +#endif + +#if LJ_TARGET_WINDOWS +#define lj_lib_checkfpu(L) \ + do { setnumV(L->top++, (lua_Number)1437217655); \ + if (lua_tointeger(L, -1) != 1437217655) lj_err_caller(L, LJ_ERR_BADFPU); \ + L->top--; } while (0) +#else +#define lj_lib_checkfpu(L) UNUSED(L) +#endif + +LJ_FUNC GCfunc *lj_lib_pushcc(lua_State *L, lua_CFunction f, int id, int n); +#define lj_lib_pushcf(L, fn, id) (lj_lib_pushcc(L, (fn), (id), 0)) + +/* Library function declarations. Scanned by buildvm. */ +#define LJLIB_CF(name) static int lj_cf_##name(lua_State *L) +#define LJLIB_ASM(name) static int lj_ffh_##name(lua_State *L) +#define LJLIB_ASM_(name) +#define LJLIB_LUA(name) +#define LJLIB_SET(name) +#define LJLIB_PUSH(arg) +#define LJLIB_REC(handler) +#define LJLIB_NOREGUV +#define LJLIB_NOREG + +#define LJ_LIB_REG(L, regname, name) \ + lj_lib_register(L, regname, lj_lib_init_##name, lj_lib_cf_##name) + +LJ_FUNC void lj_lib_register(lua_State *L, const char *libname, + const uint8_t *init, const lua_CFunction *cf); +LJ_FUNC void lj_lib_prereg(lua_State *L, const char *name, lua_CFunction f, + GCtab *env); +LJ_FUNC int lj_lib_postreg(lua_State *L, lua_CFunction cf, int id, + const char *name); + +/* Library init data tags. */ +#define LIBINIT_LENMASK 0x3f +#define LIBINIT_TAGMASK 0xc0 +#define LIBINIT_CF 0x00 +#define LIBINIT_ASM 0x40 +#define LIBINIT_ASM_ 0x80 +#define LIBINIT_STRING 0xc0 +#define LIBINIT_MAXSTR 0x38 +#define LIBINIT_LUA 0xf9 +#define LIBINIT_SET 0xfa +#define LIBINIT_NUMBER 0xfb +#define LIBINIT_COPY 0xfc +#define LIBINIT_LASTCL 0xfd +#define LIBINIT_FFID 0xfe +#define LIBINIT_END 0xff + +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_load.c b/fluent-bit/lib/luajit-3065c9/src/lj_load.c new file mode 100644 index 00000000..0aab4884 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_load.c @@ -0,0 +1,168 @@ +/* +** Load and dump code. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#include +#include + +#define lj_load_c +#define LUA_CORE + +#include "lua.h" +#include "lauxlib.h" + +#include "lj_obj.h" +#include "lj_gc.h" +#include "lj_err.h" +#include "lj_buf.h" +#include "lj_func.h" +#include "lj_frame.h" +#include "lj_vm.h" +#include "lj_lex.h" +#include "lj_bcdump.h" +#include "lj_parse.h" + +/* -- Load Lua source code and bytecode ----------------------------------- */ + +static TValue *cpparser(lua_State *L, lua_CFunction dummy, void *ud) +{ + LexState *ls = (LexState *)ud; + GCproto *pt; + GCfunc *fn; + int bc; + UNUSED(dummy); + cframe_errfunc(L->cframe) = -1; /* Inherit error function. */ + bc = lj_lex_setup(L, ls); + if (ls->mode && !strchr(ls->mode, bc ? 'b' : 't')) { + setstrV(L, L->top++, lj_err_str(L, LJ_ERR_XMODE)); + lj_err_throw(L, LUA_ERRSYNTAX); + } + pt = bc ? lj_bcread(ls) : lj_parse(ls); + fn = lj_func_newL_empty(L, pt, tabref(L->env)); + /* Don't combine above/below into one statement. */ + setfuncV(L, L->top++, fn); + return NULL; +} + +LUA_API int lua_loadx(lua_State *L, lua_Reader reader, void *data, + const char *chunkname, const char *mode) +{ + LexState ls; + int status; + ls.rfunc = reader; + ls.rdata = data; + ls.chunkarg = chunkname ? chunkname : "?"; + ls.mode = mode; + lj_buf_init(L, &ls.sb); + status = lj_vm_cpcall(L, NULL, &ls, cpparser); + lj_lex_cleanup(L, &ls); + lj_gc_check(L); + return status; +} + +LUA_API int lua_load(lua_State *L, lua_Reader reader, void *data, + const char *chunkname) +{ + return lua_loadx(L, reader, data, chunkname, NULL); +} + +typedef struct FileReaderCtx { + FILE *fp; + char buf[LUAL_BUFFERSIZE]; +} FileReaderCtx; + +static const char *reader_file(lua_State *L, void *ud, size_t *size) +{ + FileReaderCtx *ctx = (FileReaderCtx *)ud; + UNUSED(L); + if (feof(ctx->fp)) return NULL; + *size = fread(ctx->buf, 1, sizeof(ctx->buf), ctx->fp); + return *size > 0 ? ctx->buf : NULL; +} + +LUALIB_API int luaL_loadfilex(lua_State *L, const char *filename, + const char *mode) +{ + FileReaderCtx ctx; + int status; + const char *chunkname; + if (filename) { + ctx.fp = fopen(filename, "rb"); + if (ctx.fp == NULL) { + lua_pushfstring(L, "cannot open %s: %s", filename, strerror(errno)); + return LUA_ERRFILE; + } + chunkname = lua_pushfstring(L, "@%s", filename); + } else { + ctx.fp = stdin; + chunkname = "=stdin"; + } + status = lua_loadx(L, reader_file, &ctx, chunkname, mode); + if (ferror(ctx.fp)) { + L->top -= filename ? 2 : 1; + lua_pushfstring(L, "cannot read %s: %s", chunkname+1, strerror(errno)); + if (filename) + fclose(ctx.fp); + return LUA_ERRFILE; + } + if (filename) { + L->top--; + copyTV(L, L->top-1, L->top); + fclose(ctx.fp); + } + return status; +} + +LUALIB_API int luaL_loadfile(lua_State *L, const char *filename) +{ + return luaL_loadfilex(L, filename, NULL); +} + +typedef struct StringReaderCtx { + const char *str; + size_t size; +} StringReaderCtx; + +static const char *reader_string(lua_State *L, void *ud, size_t *size) +{ + StringReaderCtx *ctx = (StringReaderCtx *)ud; + UNUSED(L); + if (ctx->size == 0) return NULL; + *size = ctx->size; + ctx->size = 0; + return ctx->str; +} + +LUALIB_API int luaL_loadbufferx(lua_State *L, const char *buf, size_t size, + const char *name, const char *mode) +{ + StringReaderCtx ctx; + ctx.str = buf; + ctx.size = size; + return lua_loadx(L, reader_string, &ctx, name, mode); +} + +LUALIB_API int luaL_loadbuffer(lua_State *L, const char *buf, size_t size, + const char *name) +{ + return luaL_loadbufferx(L, buf, size, name, NULL); +} + +LUALIB_API int luaL_loadstring(lua_State *L, const char *s) +{ + return luaL_loadbuffer(L, s, strlen(s), s); +} + +/* -- Dump bytecode ------------------------------------------------------- */ + +LUA_API int lua_dump(lua_State *L, lua_Writer writer, void *data) +{ + cTValue *o = L->top-1; + lj_checkapi(L->top > L->base, "top slot empty"); + if (tvisfunc(o) && isluafunc(funcV(o))) + return lj_bcwrite(L, funcproto(funcV(o)), writer, data, 0); + else + return 1; +} + diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_mcode.c b/fluent-bit/lib/luajit-3065c9/src/lj_mcode.c new file mode 100644 index 00000000..163aada4 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_mcode.c @@ -0,0 +1,374 @@ +/* +** Machine code management. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#define lj_mcode_c +#define LUA_CORE + +#include "lj_obj.h" +#if LJ_HASJIT +#include "lj_gc.h" +#include "lj_err.h" +#include "lj_jit.h" +#include "lj_mcode.h" +#include "lj_trace.h" +#include "lj_dispatch.h" +#include "lj_prng.h" +#endif +#if LJ_HASJIT || LJ_HASFFI +#include "lj_vm.h" +#endif + +/* -- OS-specific functions ----------------------------------------------- */ + +#if LJ_HASJIT || LJ_HASFFI + +/* Define this if you want to run LuaJIT with Valgrind. */ +#ifdef LUAJIT_USE_VALGRIND +#include +#endif + +#if LJ_TARGET_IOS +void sys_icache_invalidate(void *start, size_t len); +#endif + +/* Synchronize data/instruction cache. */ +void lj_mcode_sync(void *start, void *end) +{ +#ifdef LUAJIT_USE_VALGRIND + VALGRIND_DISCARD_TRANSLATIONS(start, (char *)end-(char *)start); +#endif +#if LJ_TARGET_X86ORX64 + UNUSED(start); UNUSED(end); +#elif LJ_TARGET_IOS + sys_icache_invalidate(start, (char *)end-(char *)start); +#elif LJ_TARGET_PPC + lj_vm_cachesync(start, end); +#elif defined(__GNUC__) || defined(__clang__) + __clear_cache(start, end); +#else +#error "Missing builtin to flush instruction cache" +#endif +} + +#endif + +#if LJ_HASJIT + +#if LJ_TARGET_WINDOWS + +#define WIN32_LEAN_AND_MEAN +#include + +#define MCPROT_RW PAGE_READWRITE +#define MCPROT_RX PAGE_EXECUTE_READ +#define MCPROT_RWX PAGE_EXECUTE_READWRITE + +static void *mcode_alloc_at(jit_State *J, uintptr_t hint, size_t sz, DWORD prot) +{ + void *p = LJ_WIN_VALLOC((void *)hint, sz, + MEM_RESERVE|MEM_COMMIT|MEM_TOP_DOWN, prot); + if (!p && !hint) + lj_trace_err(J, LJ_TRERR_MCODEAL); + return p; +} + +static void mcode_free(jit_State *J, void *p, size_t sz) +{ + UNUSED(J); UNUSED(sz); + VirtualFree(p, 0, MEM_RELEASE); +} + +static int mcode_setprot(void *p, size_t sz, DWORD prot) +{ + DWORD oprot; + return !LJ_WIN_VPROTECT(p, sz, prot, &oprot); +} + +#elif LJ_TARGET_POSIX + +#include + +#ifndef MAP_ANONYMOUS +#define MAP_ANONYMOUS MAP_ANON +#endif + +#define MCPROT_RW (PROT_READ|PROT_WRITE) +#define MCPROT_RX (PROT_READ|PROT_EXEC) +#define MCPROT_RWX (PROT_READ|PROT_WRITE|PROT_EXEC) +#ifdef PROT_MPROTECT +#define MCPROT_CREATE (PROT_MPROTECT(MCPROT_RWX)) +#else +#define MCPROT_CREATE 0 +#endif + +static void *mcode_alloc_at(jit_State *J, uintptr_t hint, size_t sz, int prot) +{ + void *p = mmap((void *)hint, sz, prot|MCPROT_CREATE, MAP_PRIVATE|MAP_ANONYMOUS, -1, 0); + if (p == MAP_FAILED) { + if (!hint) lj_trace_err(J, LJ_TRERR_MCODEAL); + p = NULL; + } + return p; +} + +static void mcode_free(jit_State *J, void *p, size_t sz) +{ + UNUSED(J); + munmap(p, sz); +} + +static int mcode_setprot(void *p, size_t sz, int prot) +{ + return mprotect(p, sz, prot); +} + +#else + +#error "Missing OS support for explicit placement of executable memory" + +#endif + +/* -- MCode area protection ----------------------------------------------- */ + +#if LUAJIT_SECURITY_MCODE == 0 + +/* Define this ONLY if page protection twiddling becomes a bottleneck. +** +** It's generally considered to be a potential security risk to have +** pages with simultaneous write *and* execute access in a process. +** +** Do not even think about using this mode for server processes or +** apps handling untrusted external data. +** +** The security risk is not in LuaJIT itself -- but if an adversary finds +** any *other* flaw in your C application logic, then any RWX memory pages +** simplify writing an exploit considerably. +*/ +#define MCPROT_GEN MCPROT_RWX +#define MCPROT_RUN MCPROT_RWX + +static void mcode_protect(jit_State *J, int prot) +{ + UNUSED(J); UNUSED(prot); UNUSED(mcode_setprot); +} + +#else + +/* This is the default behaviour and much safer: +** +** Most of the time the memory pages holding machine code are executable, +** but NONE of them is writable. +** +** The current memory area is marked read-write (but NOT executable) only +** during the short time window while the assembler generates machine code. +*/ +#define MCPROT_GEN MCPROT_RW +#define MCPROT_RUN MCPROT_RX + +/* Protection twiddling failed. Probably due to kernel security. */ +static LJ_NORET LJ_NOINLINE void mcode_protfail(jit_State *J) +{ + lua_CFunction panic = J2G(J)->panic; + if (panic) { + lua_State *L = J->L; + setstrV(L, L->top++, lj_err_str(L, LJ_ERR_JITPROT)); + panic(L); + } + exit(EXIT_FAILURE); +} + +/* Change protection of MCode area. */ +static void mcode_protect(jit_State *J, int prot) +{ + if (J->mcprot != prot) { + if (LJ_UNLIKELY(mcode_setprot(J->mcarea, J->szmcarea, prot))) + mcode_protfail(J); + J->mcprot = prot; + } +} + +#endif + +/* -- MCode area allocation ----------------------------------------------- */ + +#if LJ_64 +#define mcode_validptr(p) (p) +#else +#define mcode_validptr(p) ((p) && (uintptr_t)(p) < 0xffff0000) +#endif + +#ifdef LJ_TARGET_JUMPRANGE + +/* Get memory within relative jump distance of our code in 64 bit mode. */ +static void *mcode_alloc(jit_State *J, size_t sz) +{ + /* Target an address in the static assembler code (64K aligned). + ** Try addresses within a distance of target-range/2+1MB..target+range/2-1MB. + ** Use half the jump range so every address in the range can reach any other. + */ +#if LJ_TARGET_MIPS + /* Use the middle of the 256MB-aligned region. */ + uintptr_t target = ((uintptr_t)(void *)lj_vm_exit_handler & + ~(uintptr_t)0x0fffffffu) + 0x08000000u; +#else + uintptr_t target = (uintptr_t)(void *)lj_vm_exit_handler & ~(uintptr_t)0xffff; +#endif + const uintptr_t range = (1u << (LJ_TARGET_JUMPRANGE-1)) - (1u << 21); + /* First try a contiguous area below the last one. */ + uintptr_t hint = J->mcarea ? (uintptr_t)J->mcarea - sz : 0; + int i; + /* Limit probing iterations, depending on the available pool size. */ + for (i = 0; i < LJ_TARGET_JUMPRANGE; i++) { + if (mcode_validptr(hint)) { + void *p = mcode_alloc_at(J, hint, sz, MCPROT_GEN); + + if (mcode_validptr(p) && + ((uintptr_t)p + sz - target < range || target - (uintptr_t)p < range)) + return p; + if (p) mcode_free(J, p, sz); /* Free badly placed area. */ + } + /* Next try probing 64K-aligned pseudo-random addresses. */ + do { + hint = lj_prng_u64(&J2G(J)->prng) & ((1u<mcarea; + size_t sz = (size_t)J->param[JIT_P_sizemcode] << 10; + sz = (sz + LJ_PAGESIZE-1) & ~(size_t)(LJ_PAGESIZE - 1); + J->mcarea = (MCode *)mcode_alloc(J, sz); + J->szmcarea = sz; + J->mcprot = MCPROT_GEN; + J->mctop = (MCode *)((char *)J->mcarea + J->szmcarea); + J->mcbot = (MCode *)((char *)J->mcarea + sizeof(MCLink)); + ((MCLink *)J->mcarea)->next = oldarea; + ((MCLink *)J->mcarea)->size = sz; + J->szallmcarea += sz; + J->mcbot = (MCode *)lj_err_register_mcode(J->mcarea, sz, (uint8_t *)J->mcbot); +} + +/* Free all MCode areas. */ +void lj_mcode_free(jit_State *J) +{ + MCode *mc = J->mcarea; + J->mcarea = NULL; + J->szallmcarea = 0; + while (mc) { + MCode *next = ((MCLink *)mc)->next; + size_t sz = ((MCLink *)mc)->size; + lj_err_deregister_mcode(mc, sz, (uint8_t *)mc + sizeof(MCLink)); + mcode_free(J, mc, sz); + mc = next; + } +} + +/* -- MCode transactions -------------------------------------------------- */ + +/* Reserve the remainder of the current MCode area. */ +MCode *lj_mcode_reserve(jit_State *J, MCode **lim) +{ + if (!J->mcarea) + mcode_allocarea(J); + else + mcode_protect(J, MCPROT_GEN); + *lim = J->mcbot; + return J->mctop; +} + +/* Commit the top part of the current MCode area. */ +void lj_mcode_commit(jit_State *J, MCode *top) +{ + J->mctop = top; + mcode_protect(J, MCPROT_RUN); +} + +/* Abort the reservation. */ +void lj_mcode_abort(jit_State *J) +{ + if (J->mcarea) + mcode_protect(J, MCPROT_RUN); +} + +/* Set/reset protection to allow patching of MCode areas. */ +MCode *lj_mcode_patch(jit_State *J, MCode *ptr, int finish) +{ + if (finish) { +#if LUAJIT_SECURITY_MCODE + if (J->mcarea == ptr) + mcode_protect(J, MCPROT_RUN); + else if (LJ_UNLIKELY(mcode_setprot(ptr, ((MCLink *)ptr)->size, MCPROT_RUN))) + mcode_protfail(J); +#endif + return NULL; + } else { + MCode *mc = J->mcarea; + /* Try current area first to use the protection cache. */ + if (ptr >= mc && ptr < (MCode *)((char *)mc + J->szmcarea)) { +#if LUAJIT_SECURITY_MCODE + mcode_protect(J, MCPROT_GEN); +#endif + return mc; + } + /* Otherwise search through the list of MCode areas. */ + for (;;) { + mc = ((MCLink *)mc)->next; + lj_assertJ(mc != NULL, "broken MCode area chain"); + if (ptr >= mc && ptr < (MCode *)((char *)mc + ((MCLink *)mc)->size)) { +#if LUAJIT_SECURITY_MCODE + if (LJ_UNLIKELY(mcode_setprot(mc, ((MCLink *)mc)->size, MCPROT_GEN))) + mcode_protfail(J); +#endif + return mc; + } + } + } +} + +/* Limit of MCode reservation reached. */ +void lj_mcode_limiterr(jit_State *J, size_t need) +{ + size_t sizemcode, maxmcode; + lj_mcode_abort(J); + sizemcode = (size_t)J->param[JIT_P_sizemcode] << 10; + sizemcode = (sizemcode + LJ_PAGESIZE-1) & ~(size_t)(LJ_PAGESIZE - 1); + maxmcode = (size_t)J->param[JIT_P_maxmcode] << 10; + if ((size_t)need > sizemcode) + lj_trace_err(J, LJ_TRERR_MCODEOV); /* Too long for any area. */ + if (J->szallmcarea + sizemcode > maxmcode) + lj_trace_err(J, LJ_TRERR_MCODEAL); + mcode_allocarea(J); + lj_trace_err(J, LJ_TRERR_MCODELM); /* Retry with new area. */ +} + +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_mcode.h b/fluent-bit/lib/luajit-3065c9/src/lj_mcode.h new file mode 100644 index 00000000..be35925f --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_mcode.h @@ -0,0 +1,30 @@ +/* +** Machine code management. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#ifndef _LJ_MCODE_H +#define _LJ_MCODE_H + +#include "lj_obj.h" + +#if LJ_HASJIT || LJ_HASFFI +LJ_FUNC void lj_mcode_sync(void *start, void *end); +#endif + +#if LJ_HASJIT + +#include "lj_jit.h" + +LJ_FUNC void lj_mcode_free(jit_State *J); +LJ_FUNC MCode *lj_mcode_reserve(jit_State *J, MCode **lim); +LJ_FUNC void lj_mcode_commit(jit_State *J, MCode *m); +LJ_FUNC void lj_mcode_abort(jit_State *J); +LJ_FUNC MCode *lj_mcode_patch(jit_State *J, MCode *ptr, int finish); +LJ_FUNC_NORET void lj_mcode_limiterr(jit_State *J, size_t need); + +#define lj_mcode_commitbot(J, m) (J->mcbot = (m)) + +#endif + +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_meta.c b/fluent-bit/lib/luajit-3065c9/src/lj_meta.c new file mode 100644 index 00000000..5324c666 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_meta.c @@ -0,0 +1,482 @@ +/* +** Metamethod handling. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +** +** Portions taken verbatim or adapted from the Lua interpreter. +** Copyright (C) 1994-2008 Lua.org, PUC-Rio. See Copyright Notice in lua.h +*/ + +#define lj_meta_c +#define LUA_CORE + +#include "lj_obj.h" +#include "lj_gc.h" +#include "lj_err.h" +#include "lj_buf.h" +#include "lj_str.h" +#include "lj_tab.h" +#include "lj_meta.h" +#include "lj_frame.h" +#include "lj_bc.h" +#include "lj_vm.h" +#include "lj_strscan.h" +#include "lj_strfmt.h" +#include "lj_lib.h" + +/* -- Metamethod handling ------------------------------------------------- */ + +/* String interning of metamethod names for fast indexing. */ +void lj_meta_init(lua_State *L) +{ +#define MMNAME(name) "__" #name + const char *metanames = MMDEF(MMNAME); +#undef MMNAME + global_State *g = G(L); + const char *p, *q; + uint32_t mm; + for (mm = 0, p = metanames; *p; mm++, p = q) { + GCstr *s; + for (q = p+2; *q && *q != '_'; q++) ; + s = lj_str_new(L, p, (size_t)(q-p)); + /* NOBARRIER: g->gcroot[] is a GC root. */ + setgcref(g->gcroot[GCROOT_MMNAME+mm], obj2gco(s)); + } +} + +/* Negative caching of a few fast metamethods. See the lj_meta_fast() macro. */ +cTValue *lj_meta_cache(GCtab *mt, MMS mm, GCstr *name) +{ + cTValue *mo = lj_tab_getstr(mt, name); + lj_assertX(mm <= MM_FAST, "bad metamethod %d", mm); + if (!mo || tvisnil(mo)) { /* No metamethod? */ + mt->nomm |= (uint8_t)(1u<metatable); + else if (tvisudata(o)) + mt = tabref(udataV(o)->metatable); + else + mt = tabref(basemt_obj(G(L), o)); + if (mt) { + cTValue *mo = lj_tab_getstr(mt, mmname_str(G(L), mm)); + if (mo) + return mo; + } + return niltv(L); +} + +#if LJ_HASFFI +/* Tailcall from C function. */ +int lj_meta_tailcall(lua_State *L, cTValue *tv) +{ + TValue *base = L->base; + TValue *top = L->top; + const BCIns *pc = frame_pc(base-1); /* Preserve old PC from frame. */ + copyTV(L, base-1-LJ_FR2, tv); /* Replace frame with new object. */ + if (LJ_FR2) + (top++)->u64 = LJ_CONT_TAILCALL; + else + top->u32.lo = LJ_CONT_TAILCALL; + setframe_pc(top++, pc); + setframe_gc(top, obj2gco(L), LJ_TTHREAD); /* Dummy frame object. */ + if (LJ_FR2) top++; + setframe_ftsz(top, ((char *)(top+1) - (char *)base) + FRAME_CONT); + L->base = L->top = top+1; + /* + ** before: [old_mo|PC] [... ...] + ** ^base ^top + ** after: [new_mo|itype] [... ...] [NULL|PC] [dummy|delta] + ** ^base/top + ** tailcall: [new_mo|PC] [... ...] + ** ^base ^top + */ + return 0; +} +#endif + +/* Setup call to metamethod to be run by Assembler VM. */ +static TValue *mmcall(lua_State *L, ASMFunction cont, cTValue *mo, + cTValue *a, cTValue *b) +{ + /* + ** |-- framesize -> top top+1 top+2 top+3 + ** before: [func slots ...] + ** mm setup: [func slots ...] [cont|?] [mo|tmtype] [a] [b] + ** in asm: [func slots ...] [cont|PC] [mo|delta] [a] [b] + ** ^-- func base ^-- mm base + ** after mm: [func slots ...] [result] + ** ^-- copy to base[PC_RA] --/ for lj_cont_ra + ** istruecond + branch for lj_cont_cond* + ** ignore for lj_cont_nop + ** next PC: [func slots ...] + */ + TValue *top = L->top; + if (curr_funcisL(L)) top = curr_topL(L); + setcont(top++, cont); /* Assembler VM stores PC in upper word or FR2. */ + if (LJ_FR2) setnilV(top++); + copyTV(L, top++, mo); /* Store metamethod and two arguments. */ + if (LJ_FR2) setnilV(top++); + copyTV(L, top, a); + copyTV(L, top+1, b); + return top; /* Return new base. */ +} + +/* -- C helpers for some instructions, called from assembler VM ----------- */ + +/* Helper for TGET*. __index chain and metamethod. */ +cTValue *lj_meta_tget(lua_State *L, cTValue *o, cTValue *k) +{ + int loop; + for (loop = 0; loop < LJ_MAX_IDXCHAIN; loop++) { + cTValue *mo; + if (LJ_LIKELY(tvistab(o))) { + GCtab *t = tabV(o); + cTValue *tv = lj_tab_get(L, t, k); + if (!tvisnil(tv) || + !(mo = lj_meta_fast(L, tabref(t->metatable), MM_index))) + return tv; + } else if (tvisnil(mo = lj_meta_lookup(L, o, MM_index))) { + lj_err_optype(L, o, LJ_ERR_OPINDEX); + return NULL; /* unreachable */ + } + if (tvisfunc(mo)) { + L->top = mmcall(L, lj_cont_ra, mo, o, k); + return NULL; /* Trigger metamethod call. */ + } + o = mo; + } + lj_err_msg(L, LJ_ERR_GETLOOP); + return NULL; /* unreachable */ +} + +/* Helper for TSET*. __newindex chain and metamethod. */ +TValue *lj_meta_tset(lua_State *L, cTValue *o, cTValue *k) +{ + TValue tmp; + int loop; + for (loop = 0; loop < LJ_MAX_IDXCHAIN; loop++) { + cTValue *mo; + if (LJ_LIKELY(tvistab(o))) { + GCtab *t = tabV(o); + cTValue *tv = lj_tab_get(L, t, k); + if (LJ_LIKELY(!tvisnil(tv))) { + t->nomm = 0; /* Invalidate negative metamethod cache. */ + lj_gc_anybarriert(L, t); + return (TValue *)tv; + } else if (!(mo = lj_meta_fast(L, tabref(t->metatable), MM_newindex))) { + t->nomm = 0; /* Invalidate negative metamethod cache. */ + lj_gc_anybarriert(L, t); + if (tv != niltv(L)) + return (TValue *)tv; + if (tvisnil(k)) lj_err_msg(L, LJ_ERR_NILIDX); + else if (tvisint(k)) { setnumV(&tmp, (lua_Number)intV(k)); k = &tmp; } + else if (tvisnum(k) && tvisnan(k)) lj_err_msg(L, LJ_ERR_NANIDX); + return lj_tab_newkey(L, t, k); + } + } else if (tvisnil(mo = lj_meta_lookup(L, o, MM_newindex))) { + lj_err_optype(L, o, LJ_ERR_OPINDEX); + return NULL; /* unreachable */ + } + if (tvisfunc(mo)) { + L->top = mmcall(L, lj_cont_nop, mo, o, k); + /* L->top+2 = v filled in by caller. */ + return NULL; /* Trigger metamethod call. */ + } + copyTV(L, &tmp, mo); + o = &tmp; + } + lj_err_msg(L, LJ_ERR_SETLOOP); + return NULL; /* unreachable */ +} + +static cTValue *str2num(cTValue *o, TValue *n) +{ + if (tvisnum(o)) + return o; + else if (tvisint(o)) + return (setnumV(n, (lua_Number)intV(o)), n); + else if (tvisstr(o) && lj_strscan_num(strV(o), n)) + return n; + else + return NULL; +} + +/* Helper for arithmetic instructions. Coercion, metamethod. */ +TValue *lj_meta_arith(lua_State *L, TValue *ra, cTValue *rb, cTValue *rc, + BCReg op) +{ + MMS mm = bcmode_mm(op); + TValue tempb, tempc; + cTValue *b, *c; + if ((b = str2num(rb, &tempb)) != NULL && + (c = str2num(rc, &tempc)) != NULL) { /* Try coercion first. */ + setnumV(ra, lj_vm_foldarith(numV(b), numV(c), (int)mm-MM_add)); + return NULL; + } else { + cTValue *mo = lj_meta_lookup(L, rb, mm); + if (tvisnil(mo)) { + mo = lj_meta_lookup(L, rc, mm); + if (tvisnil(mo)) { + if (str2num(rb, &tempb) == NULL) rc = rb; + lj_err_optype(L, rc, LJ_ERR_OPARITH); + return NULL; /* unreachable */ + } + } + return mmcall(L, lj_cont_ra, mo, rb, rc); + } +} + +/* Helper for CAT. Coercion, iterative concat, __concat metamethod. */ +TValue *lj_meta_cat(lua_State *L, TValue *top, int left) +{ + int fromc = 0; + if (left < 0) { left = -left; fromc = 1; } + do { + if (!(tvisstr(top) || tvisnumber(top) || tvisbuf(top)) || + !(tvisstr(top-1) || tvisnumber(top-1) || tvisbuf(top-1))) { + cTValue *mo = lj_meta_lookup(L, top-1, MM_concat); + if (tvisnil(mo)) { + mo = lj_meta_lookup(L, top, MM_concat); + if (tvisnil(mo)) { + if (tvisstr(top-1) || tvisnumber(top-1)) top++; + lj_err_optype(L, top-1, LJ_ERR_OPCAT); + return NULL; /* unreachable */ + } + } + /* One of the top two elements is not a string, call __cat metamethod: + ** + ** before: [...][CAT stack .........................] + ** top-1 top top+1 top+2 + ** pick two: [...][CAT stack ...] [o1] [o2] + ** setup mm: [...][CAT stack ...] [cont|?] [mo|tmtype] [o1] [o2] + ** in asm: [...][CAT stack ...] [cont|PC] [mo|delta] [o1] [o2] + ** ^-- func base ^-- mm base + ** after mm: [...][CAT stack ...] <--push-- [result] + ** next step: [...][CAT stack .............] + */ + copyTV(L, top+2*LJ_FR2+2, top); /* Carefully ordered stack copies! */ + copyTV(L, top+2*LJ_FR2+1, top-1); + copyTV(L, top+LJ_FR2, mo); + setcont(top-1, lj_cont_cat); + if (LJ_FR2) { setnilV(top); setnilV(top+2); top += 2; } + return top+1; /* Trigger metamethod call. */ + } else { + /* Pick as many strings as possible from the top and concatenate them: + ** + ** before: [...][CAT stack ...........................] + ** pick str: [...][CAT stack ...] [...... strings ......] + ** concat: [...][CAT stack ...] [result] + ** next step: [...][CAT stack ............] + */ + TValue *e, *o = top; + uint64_t tlen = tvisstr(o) ? strV(o)->len : + tvisbuf(o) ? sbufxlen(bufV(o)) : STRFMT_MAXBUF_NUM; + SBuf *sb; + do { + o--; tlen += tvisstr(o) ? strV(o)->len : + tvisbuf(o) ? sbufxlen(bufV(o)) : STRFMT_MAXBUF_NUM; + } while (--left > 0 && (tvisstr(o-1) || tvisnumber(o-1))); + if (tlen >= LJ_MAX_STR) lj_err_msg(L, LJ_ERR_STROV); + sb = lj_buf_tmp_(L); + lj_buf_more(sb, (MSize)tlen); + for (e = top, top = o; o <= e; o++) { + if (tvisstr(o)) { + GCstr *s = strV(o); + MSize len = s->len; + lj_buf_putmem(sb, strdata(s), len); + } else if (tvisbuf(o)) { + SBufExt *sbx = bufV(o); + lj_buf_putmem(sb, sbx->r, sbufxlen(sbx)); + } else if (tvisint(o)) { + lj_strfmt_putint(sb, intV(o)); + } else { + lj_strfmt_putfnum(sb, STRFMT_G14, numV(o)); + } + } + setstrV(L, top, lj_buf_str(L, sb)); + } + } while (left >= 1); + if (LJ_UNLIKELY(G(L)->gc.total >= G(L)->gc.threshold)) { + if (!fromc) L->top = curr_topL(L); + lj_gc_step(L); + } + return NULL; +} + +/* Helper for LEN. __len metamethod. */ +TValue * LJ_FASTCALL lj_meta_len(lua_State *L, cTValue *o) +{ + cTValue *mo = lj_meta_lookup(L, o, MM_len); + if (tvisnil(mo)) { + if (LJ_52 && tvistab(o)) + tabref(tabV(o)->metatable)->nomm |= (uint8_t)(1u<gch.metatable), MM_eq); + if (mo) { + TValue *top; + uint32_t it; + if (tabref(o1->gch.metatable) != tabref(o2->gch.metatable)) { + cTValue *mo2 = lj_meta_fast(L, tabref(o2->gch.metatable), MM_eq); + if (mo2 == NULL || !lj_obj_equal(mo, mo2)) + return (TValue *)(intptr_t)ne; + } + top = curr_top(L); + setcont(top++, ne ? lj_cont_condf : lj_cont_condt); + if (LJ_FR2) setnilV(top++); + copyTV(L, top++, mo); + if (LJ_FR2) setnilV(top++); + it = ~(uint32_t)o1->gch.gct; + setgcV(L, top, o1, it); + setgcV(L, top+1, o2, it); + return top; /* Trigger metamethod call. */ + } + return (TValue *)(intptr_t)ne; +} + +#if LJ_HASFFI +TValue * LJ_FASTCALL lj_meta_equal_cd(lua_State *L, BCIns ins) +{ + ASMFunction cont = (bc_op(ins) & 1) ? lj_cont_condf : lj_cont_condt; + int op = (int)bc_op(ins) & ~1; + TValue tv; + cTValue *mo, *o2, *o1 = &L->base[bc_a(ins)]; + cTValue *o1mm = o1; + if (op == BC_ISEQV) { + o2 = &L->base[bc_d(ins)]; + if (!tviscdata(o1mm)) o1mm = o2; + } else if (op == BC_ISEQS) { + setstrV(L, &tv, gco2str(proto_kgc(curr_proto(L), ~(ptrdiff_t)bc_d(ins)))); + o2 = &tv; + } else if (op == BC_ISEQN) { + o2 = &mref(curr_proto(L)->k, cTValue)[bc_d(ins)]; + } else { + lj_assertL(op == BC_ISEQP, "bad bytecode op %d", op); + setpriV(&tv, ~bc_d(ins)); + o2 = &tv; + } + mo = lj_meta_lookup(L, o1mm, MM_eq); + if (LJ_LIKELY(!tvisnil(mo))) + return mmcall(L, cont, mo, o1, o2); + else + return (TValue *)(intptr_t)(bc_op(ins) & 1); +} +#endif + +/* Helper for ordered comparisons. String compare, __lt/__le metamethods. */ +TValue *lj_meta_comp(lua_State *L, cTValue *o1, cTValue *o2, int op) +{ + if (LJ_HASFFI && (tviscdata(o1) || tviscdata(o2))) { + ASMFunction cont = (op & 1) ? lj_cont_condf : lj_cont_condt; + MMS mm = (op & 2) ? MM_le : MM_lt; + cTValue *mo = lj_meta_lookup(L, tviscdata(o1) ? o1 : o2, mm); + if (LJ_UNLIKELY(tvisnil(mo))) goto err; + return mmcall(L, cont, mo, o1, o2); + } else if (LJ_52 || itype(o1) == itype(o2)) { + /* Never called with two numbers. */ + if (tvisstr(o1) && tvisstr(o2)) { + int32_t res = lj_str_cmp(strV(o1), strV(o2)); + return (TValue *)(intptr_t)(((op&2) ? res <= 0 : res < 0) ^ (op&1)); + } else { + trymt: + while (1) { + ASMFunction cont = (op & 1) ? lj_cont_condf : lj_cont_condt; + MMS mm = (op & 2) ? MM_le : MM_lt; + cTValue *mo = lj_meta_lookup(L, o1, mm); +#if LJ_52 + if (tvisnil(mo) && tvisnil((mo = lj_meta_lookup(L, o2, mm)))) +#else + cTValue *mo2 = lj_meta_lookup(L, o2, mm); + if (tvisnil(mo) || !lj_obj_equal(mo, mo2)) +#endif + { + if (op & 2) { /* MM_le not found: retry with MM_lt. */ + cTValue *ot = o1; o1 = o2; o2 = ot; /* Swap operands. */ + op ^= 3; /* Use LT and flip condition. */ + continue; + } + goto err; + } + return mmcall(L, cont, mo, o1, o2); + } + } + } else if (tvisbool(o1) && tvisbool(o2)) { + goto trymt; + } else { + err: + lj_err_comp(L, o1, o2); + return NULL; + } +} + +/* Helper for ISTYPE and ISNUM. Implicit coercion or error. */ +void lj_meta_istype(lua_State *L, BCReg ra, BCReg tp) +{ + L->top = curr_topL(L); + ra++; tp--; + lj_assertL(LJ_DUALNUM || tp != ~LJ_TNUMX, "bad type for ISTYPE"); + if (LJ_DUALNUM && tp == ~LJ_TNUMX) lj_lib_checkint(L, ra); + else if (tp == ~LJ_TNUMX+1) lj_lib_checknum(L, ra); + else if (tp == ~LJ_TSTR) lj_lib_checkstr(L, ra); + else lj_err_argtype(L, ra, lj_obj_itypename[tp]); +} + +/* Helper for calls. __call metamethod. */ +void lj_meta_call(lua_State *L, TValue *func, TValue *top) +{ + cTValue *mo = lj_meta_lookup(L, func, MM_call); + TValue *p; + if (!tvisfunc(mo)) + lj_err_optype_call(L, func); + for (p = top; p > func+2*LJ_FR2; p--) copyTV(L, p, p-1); + if (LJ_FR2) copyTV(L, func+2, func); + copyTV(L, func, mo); +} + +/* Helper for FORI. Coercion. */ +void LJ_FASTCALL lj_meta_for(lua_State *L, TValue *o) +{ + if (!lj_strscan_numberobj(o)) lj_err_msg(L, LJ_ERR_FORINIT); + if (!lj_strscan_numberobj(o+1)) lj_err_msg(L, LJ_ERR_FORLIM); + if (!lj_strscan_numberobj(o+2)) lj_err_msg(L, LJ_ERR_FORSTEP); + if (LJ_DUALNUM) { + /* Ensure all slots are integers or all slots are numbers. */ + int32_t k[3]; + int nint = 0; + ptrdiff_t i; + for (i = 0; i <= 2; i++) { + if (tvisint(o+i)) { + k[i] = intV(o+i); nint++; + } else { + k[i] = lj_num2int(numV(o+i)); nint += ((lua_Number)k[i] == numV(o+i)); + } + } + if (nint == 3) { /* Narrow to integers. */ + setintV(o, k[0]); + setintV(o+1, k[1]); + setintV(o+2, k[2]); + } else if (nint != 0) { /* Widen to numbers. */ + if (tvisint(o)) setnumV(o, (lua_Number)intV(o)); + if (tvisint(o+1)) setnumV(o+1, (lua_Number)intV(o+1)); + if (tvisint(o+2)) setnumV(o+2, (lua_Number)intV(o+2)); + } + } +} + diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_meta.h b/fluent-bit/lib/luajit-3065c9/src/lj_meta.h new file mode 100644 index 00000000..3a6eaac2 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_meta.h @@ -0,0 +1,38 @@ +/* +** Metamethod handling. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#ifndef _LJ_META_H +#define _LJ_META_H + +#include "lj_obj.h" + +/* Metamethod handling */ +LJ_FUNC void lj_meta_init(lua_State *L); +LJ_FUNC cTValue *lj_meta_cache(GCtab *mt, MMS mm, GCstr *name); +LJ_FUNC cTValue *lj_meta_lookup(lua_State *L, cTValue *o, MMS mm); +#if LJ_HASFFI +LJ_FUNC int lj_meta_tailcall(lua_State *L, cTValue *tv); +#endif + +#define lj_meta_fastg(g, mt, mm) \ + ((mt) == NULL ? NULL : ((mt)->nomm & (1u<<(mm))) ? NULL : \ + lj_meta_cache(mt, mm, mmname_str(g, mm))) +#define lj_meta_fast(L, mt, mm) lj_meta_fastg(G(L), mt, mm) + +/* C helpers for some instructions, called from assembler VM. */ +LJ_FUNCA cTValue *lj_meta_tget(lua_State *L, cTValue *o, cTValue *k); +LJ_FUNCA TValue *lj_meta_tset(lua_State *L, cTValue *o, cTValue *k); +LJ_FUNCA TValue *lj_meta_arith(lua_State *L, TValue *ra, cTValue *rb, + cTValue *rc, BCReg op); +LJ_FUNCA TValue *lj_meta_cat(lua_State *L, TValue *top, int left); +LJ_FUNCA TValue * LJ_FASTCALL lj_meta_len(lua_State *L, cTValue *o); +LJ_FUNCA TValue *lj_meta_equal(lua_State *L, GCobj *o1, GCobj *o2, int ne); +LJ_FUNCA TValue * LJ_FASTCALL lj_meta_equal_cd(lua_State *L, BCIns ins); +LJ_FUNCA TValue *lj_meta_comp(lua_State *L, cTValue *o1, cTValue *o2, int op); +LJ_FUNCA void lj_meta_istype(lua_State *L, BCReg ra, BCReg tp); +LJ_FUNCA void lj_meta_call(lua_State *L, TValue *func, TValue *top); +LJ_FUNCA void LJ_FASTCALL lj_meta_for(lua_State *L, TValue *o); + +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_obj.c b/fluent-bit/lib/luajit-3065c9/src/lj_obj.c new file mode 100644 index 00000000..65cbe1a1 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_obj.c @@ -0,0 +1,51 @@ +/* +** Miscellaneous object handling. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#define lj_obj_c +#define LUA_CORE + +#include "lj_obj.h" + +/* Object type names. */ +LJ_DATADEF const char *const lj_obj_typename[] = { /* ORDER LUA_T */ + "no value", "nil", "boolean", "userdata", "number", "string", + "table", "function", "userdata", "thread", "proto", "cdata" +}; + +LJ_DATADEF const char *const lj_obj_itypename[] = { /* ORDER LJ_T */ + "nil", "boolean", "boolean", "userdata", "string", "upval", "thread", + "proto", "function", "trace", "cdata", "table", "userdata", "number" +}; + +/* Compare two objects without calling metamethods. */ +int LJ_FASTCALL lj_obj_equal(cTValue *o1, cTValue *o2) +{ + if (itype(o1) == itype(o2)) { + if (tvispri(o1)) + return 1; + if (!tvisnum(o1)) + return gcrefeq(o1->gcr, o2->gcr); + } else if (!tvisnumber(o1) || !tvisnumber(o2)) { + return 0; + } + return numberVnum(o1) == numberVnum(o2); +} + +/* Return pointer to object or its object data. */ +const void * LJ_FASTCALL lj_obj_ptr(global_State *g, cTValue *o) +{ + UNUSED(g); + if (tvisudata(o)) + return uddata(udataV(o)); + else if (tvislightud(o)) + return lightudV(g, o); + else if (LJ_HASFFI && tviscdata(o)) + return cdataptr(cdataV(o)); + else if (tvisgcv(o)) + return gcV(o); + else + return NULL; +} + diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_obj.h b/fluent-bit/lib/luajit-3065c9/src/lj_obj.h new file mode 100644 index 00000000..67e41181 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_obj.h @@ -0,0 +1,1045 @@ +/* +** LuaJIT VM tags, values and objects. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +** +** Portions taken verbatim or adapted from the Lua interpreter. +** Copyright (C) 1994-2008 Lua.org, PUC-Rio. See Copyright Notice in lua.h +*/ + +#ifndef _LJ_OBJ_H +#define _LJ_OBJ_H + +#include "lua.h" +#include "lj_def.h" +#include "lj_arch.h" + +/* -- Memory references --------------------------------------------------- */ + +/* Memory and GC object sizes. */ +typedef uint32_t MSize; +#if LJ_GC64 +typedef uint64_t GCSize; +#else +typedef uint32_t GCSize; +#endif + +/* Memory reference */ +typedef struct MRef { +#if LJ_GC64 + uint64_t ptr64; /* True 64 bit pointer. */ +#else + uint32_t ptr32; /* Pseudo 32 bit pointer. */ +#endif +} MRef; + +#if LJ_GC64 +#define mref(r, t) ((t *)(void *)(r).ptr64) +#define mrefu(r) ((r).ptr64) + +#define setmref(r, p) ((r).ptr64 = (uint64_t)(void *)(p)) +#define setmrefu(r, u) ((r).ptr64 = (uint64_t)(u)) +#define setmrefr(r, v) ((r).ptr64 = (v).ptr64) +#else +#define mref(r, t) ((t *)(void *)(uintptr_t)(r).ptr32) +#define mrefu(r) ((r).ptr32) + +#define setmref(r, p) ((r).ptr32 = (uint32_t)(uintptr_t)(void *)(p)) +#define setmrefu(r, u) ((r).ptr32 = (uint32_t)(u)) +#define setmrefr(r, v) ((r).ptr32 = (v).ptr32) +#endif + +/* -- GC object references ------------------------------------------------ */ + +/* GCobj reference */ +typedef struct GCRef { +#if LJ_GC64 + uint64_t gcptr64; /* True 64 bit pointer. */ +#else + uint32_t gcptr32; /* Pseudo 32 bit pointer. */ +#endif +} GCRef; + +/* Common GC header for all collectable objects. */ +#define GCHeader GCRef nextgc; uint8_t marked; uint8_t gct +/* This occupies 6 bytes, so use the next 2 bytes for non-32 bit fields. */ + +#if LJ_GC64 +#define gcref(r) ((GCobj *)(r).gcptr64) +#define gcrefp(r, t) ((t *)(void *)(r).gcptr64) +#define gcrefu(r) ((r).gcptr64) +#define gcrefeq(r1, r2) ((r1).gcptr64 == (r2).gcptr64) + +#define setgcref(r, gc) ((r).gcptr64 = (uint64_t)&(gc)->gch) +#define setgcreft(r, gc, it) \ + (r).gcptr64 = (uint64_t)&(gc)->gch | (((uint64_t)(it)) << 47) +#define setgcrefp(r, p) ((r).gcptr64 = (uint64_t)(p)) +#define setgcrefnull(r) ((r).gcptr64 = 0) +#define setgcrefr(r, v) ((r).gcptr64 = (v).gcptr64) +#else +#define gcref(r) ((GCobj *)(uintptr_t)(r).gcptr32) +#define gcrefp(r, t) ((t *)(void *)(uintptr_t)(r).gcptr32) +#define gcrefu(r) ((r).gcptr32) +#define gcrefeq(r1, r2) ((r1).gcptr32 == (r2).gcptr32) + +#define setgcref(r, gc) ((r).gcptr32 = (uint32_t)(uintptr_t)&(gc)->gch) +#define setgcrefp(r, p) ((r).gcptr32 = (uint32_t)(uintptr_t)(p)) +#define setgcrefnull(r) ((r).gcptr32 = 0) +#define setgcrefr(r, v) ((r).gcptr32 = (v).gcptr32) +#endif + +#define gcnext(gc) (gcref((gc)->gch.nextgc)) + +/* IMPORTANT NOTE: +** +** All uses of the setgcref* macros MUST be accompanied with a write barrier. +** +** This is to ensure the integrity of the incremental GC. The invariant +** to preserve is that a black object never points to a white object. +** I.e. never store a white object into a field of a black object. +** +** It's ok to LEAVE OUT the write barrier ONLY in the following cases: +** - The source is not a GC object (NULL). +** - The target is a GC root. I.e. everything in global_State. +** - The target is a lua_State field (threads are never black). +** - The target is a stack slot, see setgcV et al. +** - The target is an open upvalue, i.e. pointing to a stack slot. +** - The target is a newly created object (i.e. marked white). But make +** sure nothing invokes the GC inbetween. +** - The target and the source are the same object (self-reference). +** - The target already contains the object (e.g. moving elements around). +** +** The most common case is a store to a stack slot. All other cases where +** a barrier has been omitted are annotated with a NOBARRIER comment. +** +** The same logic applies for stores to table slots (array part or hash +** part). ALL uses of lj_tab_set* require a barrier for the stored value +** *and* the stored key, based on the above rules. In practice this means +** a barrier is needed if *either* of the key or value are a GC object. +** +** It's ok to LEAVE OUT the write barrier in the following special cases: +** - The stored value is nil. The key doesn't matter because it's either +** not resurrected or lj_tab_newkey() will take care of the key barrier. +** - The key doesn't matter if the *previously* stored value is guaranteed +** to be non-nil (because the key is kept alive in the table). +** - The key doesn't matter if it's guaranteed not to be part of the table, +** since lj_tab_newkey() takes care of the key barrier. This applies +** trivially to new tables, but watch out for resurrected keys. Storing +** a nil value leaves the key in the table! +** +** In case of doubt use lj_gc_anybarriert() as it's rather cheap. It's used +** by the interpreter for all table stores. +** +** Note: In contrast to Lua's GC, LuaJIT's GC does *not* specially mark +** dead keys in tables. The reference is left in, but it's guaranteed to +** be never dereferenced as long as the value is nil. It's ok if the key is +** freed or if any object subsequently gets the same address. +** +** Not destroying dead keys helps to keep key hash slots stable. This avoids +** specialization back-off for HREFK when a value flips between nil and +** non-nil and the GC gets in the way. It also allows safely hoisting +** HREF/HREFK across GC steps. Dead keys are only removed if a table is +** resized (i.e. by NEWREF) and xREF must not be CSEd across a resize. +** +** The trade-off is that a write barrier for tables must take the key into +** account, too. Implicitly resurrecting the key by storing a non-nil value +** may invalidate the incremental GC invariant. +*/ + +/* -- Common type definitions --------------------------------------------- */ + +/* Types for handling bytecodes. Need this here, details in lj_bc.h. */ +typedef uint32_t BCIns; /* Bytecode instruction. */ +typedef uint32_t BCPos; /* Bytecode position. */ +typedef uint32_t BCReg; /* Bytecode register. */ +typedef int32_t BCLine; /* Bytecode line number. */ + +/* Internal assembler functions. Never call these directly from C. */ +typedef void (*ASMFunction)(void); + +/* Resizable string buffer. Need this here, details in lj_buf.h. */ +#define SBufHeader char *w, *e, *b; MRef L +typedef struct SBuf { + SBufHeader; +} SBuf; + +/* -- Tags and values ----------------------------------------------------- */ + +/* Frame link. */ +typedef union { + int32_t ftsz; /* Frame type and size of previous frame. */ + MRef pcr; /* Or PC for Lua frames. */ +} FrameLink; + +/* Tagged value. */ +typedef LJ_ALIGN(8) union TValue { + uint64_t u64; /* 64 bit pattern overlaps number. */ + lua_Number n; /* Number object overlaps split tag/value object. */ +#if LJ_GC64 + GCRef gcr; /* GCobj reference with tag. */ + int64_t it64; + struct { + LJ_ENDIAN_LOHI( + int32_t i; /* Integer value. */ + , uint32_t it; /* Internal object tag. Must overlap MSW of number. */ + ) + }; +#else + struct { + LJ_ENDIAN_LOHI( + union { + GCRef gcr; /* GCobj reference (if any). */ + int32_t i; /* Integer value. */ + }; + , uint32_t it; /* Internal object tag. Must overlap MSW of number. */ + ) + }; +#endif +#if LJ_FR2 + int64_t ftsz; /* Frame type and size of previous frame, or PC. */ +#else + struct { + LJ_ENDIAN_LOHI( + GCRef func; /* Function for next frame (or dummy L). */ + , FrameLink tp; /* Link to previous frame. */ + ) + } fr; +#endif + struct { + LJ_ENDIAN_LOHI( + uint32_t lo; /* Lower 32 bits of number. */ + , uint32_t hi; /* Upper 32 bits of number. */ + ) + } u32; +} TValue; + +typedef const TValue cTValue; + +#define tvref(r) (mref(r, TValue)) + +/* More external and GCobj tags for internal objects. */ +#define LAST_TT LUA_TTHREAD +#define LUA_TPROTO (LAST_TT+1) +#define LUA_TCDATA (LAST_TT+2) + +/* Internal object tags. +** +** Format for 32 bit GC references (!LJ_GC64): +** +** Internal tags overlap the MSW of a number object (must be a double). +** Interpreted as a double these are special NaNs. The FPU only generates +** one type of NaN (0xfff8_0000_0000_0000). So MSWs > 0xfff80000 are available +** for use as internal tags. Small negative numbers are used to shorten the +** encoding of type comparisons (reg/mem against sign-ext. 8 bit immediate). +** +** ---MSW---.---LSW--- +** primitive types | itype | | +** lightuserdata | itype | void * | (32 bit platforms) +** lightuserdata |ffff|seg| ofs | (64 bit platforms) +** GC objects | itype | GCRef | +** int (LJ_DUALNUM)| itype | int | +** number -------double------ +** +** Format for 64 bit GC references (LJ_GC64): +** +** The upper 13 bits must be 1 (0xfff8...) for a special NaN. The next +** 4 bits hold the internal tag. The lowest 47 bits either hold a pointer, +** a zero-extended 32 bit integer or all bits set to 1 for primitive types. +** +** ------MSW------.------LSW------ +** primitive types |1..1|itype|1..................1| +** GC objects |1..1|itype|-------GCRef--------| +** lightuserdata |1..1|itype|seg|------ofs-------| +** int (LJ_DUALNUM) |1..1|itype|0..0|-----int-------| +** number ------------double------------- +** +** ORDER LJ_T +** Primitive types nil/false/true must be first, lightuserdata next. +** GC objects are at the end, table/userdata must be lowest. +** Also check lj_ir.h for similar ordering constraints. +*/ +#define LJ_TNIL (~0u) +#define LJ_TFALSE (~1u) +#define LJ_TTRUE (~2u) +#define LJ_TLIGHTUD (~3u) +#define LJ_TSTR (~4u) +#define LJ_TUPVAL (~5u) +#define LJ_TTHREAD (~6u) +#define LJ_TPROTO (~7u) +#define LJ_TFUNC (~8u) +#define LJ_TTRACE (~9u) +#define LJ_TCDATA (~10u) +#define LJ_TTAB (~11u) +#define LJ_TUDATA (~12u) +/* This is just the canonical number type used in some places. */ +#define LJ_TNUMX (~13u) + +/* Integers have itype == LJ_TISNUM doubles have itype < LJ_TISNUM */ +#if LJ_64 && !LJ_GC64 +#define LJ_TISNUM 0xfffeffffu +#else +#define LJ_TISNUM LJ_TNUMX +#endif +#define LJ_TISTRUECOND LJ_TFALSE +#define LJ_TISPRI LJ_TTRUE +#define LJ_TISGCV (LJ_TSTR+1) +#define LJ_TISTABUD LJ_TTAB + +/* Type marker for slot holding a traversal index. Must be lightuserdata. */ +#define LJ_KEYINDEX 0xfffe7fffu + +#if LJ_GC64 +#define LJ_GCVMASK (((uint64_t)1 << 47) - 1) +#endif + +#if LJ_64 +/* To stay within 47 bits, lightuserdata is segmented. */ +#define LJ_LIGHTUD_BITS_SEG 8 +#define LJ_LIGHTUD_BITS_LO (47 - LJ_LIGHTUD_BITS_SEG) +#endif + +/* -- String object ------------------------------------------------------- */ + +typedef uint32_t StrHash; /* String hash value. */ +typedef uint32_t StrID; /* String ID. */ + +/* String object header. String payload follows. */ +typedef struct GCstr { + GCHeader; + uint8_t reserved; /* Used by lexer for fast lookup of reserved words. */ + uint8_t hashalg; /* Hash algorithm. */ + StrID sid; /* Interned string ID. */ + StrHash hash; /* Hash of string. */ + MSize len; /* Size of string. */ +} GCstr; + +#define strref(r) (&gcref((r))->str) +#define strdata(s) ((const char *)((s)+1)) +#define strdatawr(s) ((char *)((s)+1)) +#define strVdata(o) strdata(strV(o)) + +/* -- Userdata object ----------------------------------------------------- */ + +/* Userdata object. Payload follows. */ +typedef struct GCudata { + GCHeader; + uint8_t udtype; /* Userdata type. */ + uint8_t unused2; + GCRef env; /* Should be at same offset in GCfunc. */ + MSize len; /* Size of payload. */ + GCRef metatable; /* Must be at same offset in GCtab. */ + uint32_t align1; /* To force 8 byte alignment of the payload. */ +} GCudata; + +/* Userdata types. */ +enum { + UDTYPE_USERDATA, /* Regular userdata. */ + UDTYPE_IO_FILE, /* I/O library FILE. */ + UDTYPE_FFI_CLIB, /* FFI C library namespace. */ + UDTYPE_BUFFER, /* String buffer. */ + UDTYPE__MAX +}; + +#define uddata(u) ((void *)((u)+1)) +#define sizeudata(u) (sizeof(struct GCudata)+(u)->len) + +/* -- C data object ------------------------------------------------------- */ + +/* C data object. Payload follows. */ +typedef struct GCcdata { + GCHeader; + uint16_t ctypeid; /* C type ID. */ +} GCcdata; + +/* Prepended to variable-sized or realigned C data objects. */ +typedef struct GCcdataVar { + uint16_t offset; /* Offset to allocated memory (relative to GCcdata). */ + uint16_t extra; /* Extra space allocated (incl. GCcdata + GCcdatav). */ + MSize len; /* Size of payload. */ +} GCcdataVar; + +#define cdataptr(cd) ((void *)((cd)+1)) +#define cdataisv(cd) ((cd)->marked & 0x80) +#define cdatav(cd) ((GCcdataVar *)((char *)(cd) - sizeof(GCcdataVar))) +#define cdatavlen(cd) check_exp(cdataisv(cd), cdatav(cd)->len) +#define sizecdatav(cd) (cdatavlen(cd) + cdatav(cd)->extra) +#define memcdatav(cd) ((void *)((char *)(cd) - cdatav(cd)->offset)) + +/* -- Prototype object ---------------------------------------------------- */ + +#define SCALE_NUM_GCO ((int32_t)sizeof(lua_Number)/sizeof(GCRef)) +#define round_nkgc(n) (((n) + SCALE_NUM_GCO-1) & ~(SCALE_NUM_GCO-1)) + +typedef struct GCproto { + GCHeader; + uint8_t numparams; /* Number of parameters. */ + uint8_t framesize; /* Fixed frame size. */ + MSize sizebc; /* Number of bytecode instructions. */ +#if LJ_GC64 + uint32_t unused_gc64; +#endif + GCRef gclist; + MRef k; /* Split constant array (points to the middle). */ + MRef uv; /* Upvalue list. local slot|0x8000 or parent uv idx. */ + MSize sizekgc; /* Number of collectable constants. */ + MSize sizekn; /* Number of lua_Number constants. */ + MSize sizept; /* Total size including colocated arrays. */ + uint8_t sizeuv; /* Number of upvalues. */ + uint8_t flags; /* Miscellaneous flags (see below). */ + uint16_t trace; /* Anchor for chain of root traces. */ + /* ------ The following fields are for debugging/tracebacks only ------ */ + GCRef chunkname; /* Name of the chunk this function was defined in. */ + BCLine firstline; /* First line of the function definition. */ + BCLine numline; /* Number of lines for the function definition. */ + MRef lineinfo; /* Compressed map from bytecode ins. to source line. */ + MRef uvinfo; /* Upvalue names. */ + MRef varinfo; /* Names and compressed extents of local variables. */ +} GCproto; + +/* Flags for prototype. */ +#define PROTO_CHILD 0x01 /* Has child prototypes. */ +#define PROTO_VARARG 0x02 /* Vararg function. */ +#define PROTO_FFI 0x04 /* Uses BC_KCDATA for FFI datatypes. */ +#define PROTO_NOJIT 0x08 /* JIT disabled for this function. */ +#define PROTO_ILOOP 0x10 /* Patched bytecode with ILOOP etc. */ +/* Only used during parsing. */ +#define PROTO_HAS_RETURN 0x20 /* Already emitted a return. */ +#define PROTO_FIXUP_RETURN 0x40 /* Need to fixup emitted returns. */ +/* Top bits used for counting created closures. */ +#define PROTO_CLCOUNT 0x20 /* Base of saturating 3 bit counter. */ +#define PROTO_CLC_BITS 3 +#define PROTO_CLC_POLY (3*PROTO_CLCOUNT) /* Polymorphic threshold. */ + +#define PROTO_UV_LOCAL 0x8000 /* Upvalue for local slot. */ +#define PROTO_UV_IMMUTABLE 0x4000 /* Immutable upvalue. */ + +#define proto_kgc(pt, idx) \ + check_exp((uintptr_t)(intptr_t)(idx) >= (uintptr_t)-(intptr_t)(pt)->sizekgc, \ + gcref(mref((pt)->k, GCRef)[(idx)])) +#define proto_knumtv(pt, idx) \ + check_exp((uintptr_t)(idx) < (pt)->sizekn, &mref((pt)->k, TValue)[(idx)]) +#define proto_bc(pt) ((BCIns *)((char *)(pt) + sizeof(GCproto))) +#define proto_bcpos(pt, pc) ((BCPos)((pc) - proto_bc(pt))) +#define proto_uv(pt) (mref((pt)->uv, uint16_t)) + +#define proto_chunkname(pt) (strref((pt)->chunkname)) +#define proto_chunknamestr(pt) (strdata(proto_chunkname((pt)))) +#define proto_lineinfo(pt) (mref((pt)->lineinfo, const void)) +#define proto_uvinfo(pt) (mref((pt)->uvinfo, const uint8_t)) +#define proto_varinfo(pt) (mref((pt)->varinfo, const uint8_t)) + +/* -- Upvalue object ------------------------------------------------------ */ + +typedef struct GCupval { + GCHeader; + uint8_t closed; /* Set if closed (i.e. uv->v == &uv->u.value). */ + uint8_t immutable; /* Immutable value. */ + union { + TValue tv; /* If closed: the value itself. */ + struct { /* If open: double linked list, anchored at thread. */ + GCRef prev; + GCRef next; + }; + }; + MRef v; /* Points to stack slot (open) or above (closed). */ + uint32_t dhash; /* Disambiguation hash: dh1 != dh2 => cannot alias. */ +} GCupval; + +#define uvprev(uv_) (&gcref((uv_)->prev)->uv) +#define uvnext(uv_) (&gcref((uv_)->next)->uv) +#define uvval(uv_) (mref((uv_)->v, TValue)) + +/* -- Function object (closures) ------------------------------------------ */ + +/* Common header for functions. env should be at same offset in GCudata. */ +#define GCfuncHeader \ + GCHeader; uint8_t ffid; uint8_t nupvalues; \ + GCRef env; GCRef gclist; MRef pc + +typedef struct GCfuncC { + GCfuncHeader; + lua_CFunction f; /* C function to be called. */ + TValue upvalue[1]; /* Array of upvalues (TValue). */ +} GCfuncC; + +typedef struct GCfuncL { + GCfuncHeader; + GCRef uvptr[1]; /* Array of _pointers_ to upvalue objects (GCupval). */ +} GCfuncL; + +typedef union GCfunc { + GCfuncC c; + GCfuncL l; +} GCfunc; + +#define FF_LUA 0 +#define FF_C 1 +#define isluafunc(fn) ((fn)->c.ffid == FF_LUA) +#define iscfunc(fn) ((fn)->c.ffid == FF_C) +#define isffunc(fn) ((fn)->c.ffid > FF_C) +#define funcproto(fn) \ + check_exp(isluafunc(fn), (GCproto *)(mref((fn)->l.pc, char)-sizeof(GCproto))) +#define sizeCfunc(n) (sizeof(GCfuncC)-sizeof(TValue)+sizeof(TValue)*(n)) +#define sizeLfunc(n) (sizeof(GCfuncL)-sizeof(GCRef)+sizeof(GCRef)*(n)) + +/* -- Table object -------------------------------------------------------- */ + +/* Hash node. */ +typedef struct Node { + TValue val; /* Value object. Must be first field. */ + TValue key; /* Key object. */ + MRef next; /* Hash chain. */ +#if !LJ_GC64 + MRef freetop; /* Top of free elements (stored in t->node[0]). */ +#endif +} Node; + +LJ_STATIC_ASSERT(offsetof(Node, val) == 0); + +typedef struct GCtab { + GCHeader; + uint8_t nomm; /* Negative cache for fast metamethods. */ + int8_t colo; /* Array colocation. */ + MRef array; /* Array part. */ + GCRef gclist; + GCRef metatable; /* Must be at same offset in GCudata. */ + MRef node; /* Hash part. */ + uint32_t asize; /* Size of array part (keys [0, asize-1]). */ + uint32_t hmask; /* Hash part mask (size of hash part - 1). */ +#if LJ_GC64 + MRef freetop; /* Top of free elements. */ +#endif +} GCtab; + +#define sizetabcolo(n) ((n)*sizeof(TValue) + sizeof(GCtab)) +#define tabref(r) ((GCtab *)gcref((r))) +#define noderef(r) (mref((r), Node)) +#define nextnode(n) (mref((n)->next, Node)) +#if LJ_GC64 +#define getfreetop(t, n) (noderef((t)->freetop)) +#define setfreetop(t, n, v) (setmref((t)->freetop, (v))) +#else +#define getfreetop(t, n) (noderef((n)->freetop)) +#define setfreetop(t, n, v) (setmref((n)->freetop, (v))) +#endif + +/* -- State objects ------------------------------------------------------- */ + +/* VM states. */ +enum { + LJ_VMST_INTERP, /* Interpreter. */ + LJ_VMST_C, /* C function. */ + LJ_VMST_GC, /* Garbage collector. */ + LJ_VMST_EXIT, /* Trace exit handler. */ + LJ_VMST_RECORD, /* Trace recorder. */ + LJ_VMST_OPT, /* Optimizer. */ + LJ_VMST_ASM, /* Assembler. */ + LJ_VMST__MAX +}; + +#define setvmstate(g, st) ((g)->vmstate = ~LJ_VMST_##st) + +/* Metamethods. ORDER MM */ +#ifdef LJ_HASFFI +#define MMDEF_FFI(_) _(new) +#else +#define MMDEF_FFI(_) +#endif + +#if LJ_52 || LJ_HASFFI +#define MMDEF_PAIRS(_) _(pairs) _(ipairs) +#else +#define MMDEF_PAIRS(_) +#define MM_pairs 255 +#define MM_ipairs 255 +#endif + +#define MMDEF(_) \ + _(index) _(newindex) _(gc) _(mode) _(eq) _(len) \ + /* Only the above (fast) metamethods are negative cached (max. 8). */ \ + _(lt) _(le) _(concat) _(call) \ + /* The following must be in ORDER ARITH. */ \ + _(add) _(sub) _(mul) _(div) _(mod) _(pow) _(unm) \ + /* The following are used in the standard libraries. */ \ + _(metatable) _(tostring) MMDEF_FFI(_) MMDEF_PAIRS(_) + +typedef enum { +#define MMENUM(name) MM_##name, +MMDEF(MMENUM) +#undef MMENUM + MM__MAX, + MM____ = MM__MAX, + MM_FAST = MM_len +} MMS; + +/* GC root IDs. */ +typedef enum { + GCROOT_MMNAME, /* Metamethod names. */ + GCROOT_MMNAME_LAST = GCROOT_MMNAME + MM__MAX-1, + GCROOT_BASEMT, /* Metatables for base types. */ + GCROOT_BASEMT_NUM = GCROOT_BASEMT + ~LJ_TNUMX, + GCROOT_IO_INPUT, /* Userdata for default I/O input file. */ + GCROOT_IO_OUTPUT, /* Userdata for default I/O output file. */ + GCROOT_MAX +} GCRootID; + +#define basemt_it(g, it) ((g)->gcroot[GCROOT_BASEMT+~(it)]) +#define basemt_obj(g, o) ((g)->gcroot[GCROOT_BASEMT+itypemap(o)]) +#define mmname_str(g, mm) (strref((g)->gcroot[GCROOT_MMNAME+(mm)])) + +/* Garbage collector state. */ +typedef struct GCState { + GCSize total; /* Memory currently allocated. */ + GCSize threshold; /* Memory threshold. */ + uint8_t currentwhite; /* Current white color. */ + uint8_t state; /* GC state. */ + uint8_t nocdatafin; /* No cdata finalizer called. */ +#if LJ_64 + uint8_t lightudnum; /* Number of lightuserdata segments - 1. */ +#else + uint8_t unused1; +#endif + MSize sweepstr; /* Sweep position in string table. */ + GCRef root; /* List of all collectable objects. */ + MRef sweep; /* Sweep position in root list. */ + GCRef gray; /* List of gray objects. */ + GCRef grayagain; /* List of objects for atomic traversal. */ + GCRef weak; /* List of weak tables (to be cleared). */ + GCRef mmudata; /* List of userdata (to be finalized). */ + GCSize debt; /* Debt (how much GC is behind schedule). */ + GCSize estimate; /* Estimate of memory actually in use. */ + MSize stepmul; /* Incremental GC step granularity. */ + MSize pause; /* Pause between successive GC cycles. */ +#if LJ_64 + MRef lightudseg; /* Upper bits of lightuserdata segments. */ +#endif +} GCState; + +/* String interning state. */ +typedef struct StrInternState { + GCRef *tab; /* String hash table anchors. */ + MSize mask; /* String hash mask (size of hash table - 1). */ + MSize num; /* Number of strings in hash table. */ + StrID id; /* Next string ID. */ + uint8_t idreseed; /* String ID reseed counter. */ + uint8_t second; /* String interning table uses secondary hashing. */ + uint8_t unused1; + uint8_t unused2; + LJ_ALIGN(8) uint64_t seed; /* Random string seed. */ +} StrInternState; + +/* Global state, shared by all threads of a Lua universe. */ +typedef struct global_State { + lua_Alloc allocf; /* Memory allocator. */ + void *allocd; /* Memory allocator data. */ + GCState gc; /* Garbage collector. */ + GCstr strempty; /* Empty string. */ + uint8_t stremptyz; /* Zero terminator of empty string. */ + uint8_t hookmask; /* Hook mask. */ + uint8_t dispatchmode; /* Dispatch mode. */ + uint8_t vmevmask; /* VM event mask. */ + StrInternState str; /* String interning. */ + volatile int32_t vmstate; /* VM state or current JIT code trace number. */ + GCRef mainthref; /* Link to main thread. */ + SBuf tmpbuf; /* Temporary string buffer. */ + TValue tmptv, tmptv2; /* Temporary TValues. */ + Node nilnode; /* Fallback 1-element hash part (nil key and value). */ + TValue registrytv; /* Anchor for registry. */ + GCupval uvhead; /* Head of double-linked list of all open upvalues. */ + int32_t hookcount; /* Instruction hook countdown. */ + int32_t hookcstart; /* Start count for instruction hook counter. */ + lua_Hook hookf; /* Hook function. */ + lua_CFunction wrapf; /* Wrapper for C function calls. */ + lua_CFunction panic; /* Called as a last resort for errors. */ + BCIns bc_cfunc_int; /* Bytecode for internal C function calls. */ + BCIns bc_cfunc_ext; /* Bytecode for external C function calls. */ + GCRef cur_L; /* Currently executing lua_State. */ + MRef jit_base; /* Current JIT code L->base or NULL. */ + MRef ctype_state; /* Pointer to C type state. */ + PRNGState prng; /* Global PRNG state. */ + GCRef gcroot[GCROOT_MAX]; /* GC roots. */ +} global_State; + +#define mainthread(g) (&gcref(g->mainthref)->th) +#define niltv(L) \ + check_exp(tvisnil(&G(L)->nilnode.val), &G(L)->nilnode.val) +#define niltvg(g) \ + check_exp(tvisnil(&(g)->nilnode.val), &(g)->nilnode.val) + +/* Hook management. Hook event masks are defined in lua.h. */ +#define HOOK_EVENTMASK 0x0f +#define HOOK_ACTIVE 0x10 +#define HOOK_ACTIVE_SHIFT 4 +#define HOOK_VMEVENT 0x20 +#define HOOK_GC 0x40 +#define HOOK_PROFILE 0x80 +#define hook_active(g) ((g)->hookmask & HOOK_ACTIVE) +#define hook_enter(g) ((g)->hookmask |= HOOK_ACTIVE) +#define hook_entergc(g) \ + ((g)->hookmask = ((g)->hookmask | (HOOK_ACTIVE|HOOK_GC)) & ~HOOK_PROFILE) +#define hook_vmevent(g) ((g)->hookmask |= (HOOK_ACTIVE|HOOK_VMEVENT)) +#define hook_leave(g) ((g)->hookmask &= ~HOOK_ACTIVE) +#define hook_save(g) ((g)->hookmask & ~HOOK_EVENTMASK) +#define hook_restore(g, h) \ + ((g)->hookmask = ((g)->hookmask & HOOK_EVENTMASK) | (h)) + +/* Per-thread state object. */ +struct lua_State { + GCHeader; + uint8_t dummy_ffid; /* Fake FF_C for curr_funcisL() on dummy frames. */ + uint8_t status; /* Thread status. */ + MRef glref; /* Link to global state. */ + GCRef gclist; /* GC chain. */ + TValue *base; /* Base of currently executing function. */ + TValue *top; /* First free slot in the stack. */ + MRef maxstack; /* Last free slot in the stack. */ + MRef stack; /* Stack base. */ + GCRef openupval; /* List of open upvalues in the stack. */ + GCRef env; /* Thread environment (table of globals). */ + void *cframe; /* End of C stack frame chain. */ + MSize stacksize; /* True stack size (incl. LJ_STACK_EXTRA). */ +}; + +#define G(L) (mref(L->glref, global_State)) +#define registry(L) (&G(L)->registrytv) + +/* Macros to access the currently executing (Lua) function. */ +#if LJ_GC64 +#define curr_func(L) (&gcval(L->base-2)->fn) +#elif LJ_FR2 +#define curr_func(L) (&gcref((L->base-2)->gcr)->fn) +#else +#define curr_func(L) (&gcref((L->base-1)->fr.func)->fn) +#endif +#define curr_funcisL(L) (isluafunc(curr_func(L))) +#define curr_proto(L) (funcproto(curr_func(L))) +#define curr_topL(L) (L->base + curr_proto(L)->framesize) +#define curr_top(L) (curr_funcisL(L) ? curr_topL(L) : L->top) + +#if defined(LUA_USE_ASSERT) || defined(LUA_USE_APICHECK) +LJ_FUNC_NORET void lj_assert_fail(global_State *g, const char *file, int line, + const char *func, const char *fmt, ...); +#endif + +/* -- GC object definition and conversions -------------------------------- */ + +/* GC header for generic access to common fields of GC objects. */ +typedef struct GChead { + GCHeader; + uint8_t unused1; + uint8_t unused2; + GCRef env; + GCRef gclist; + GCRef metatable; +} GChead; + +/* The env field SHOULD be at the same offset for all GC objects. */ +LJ_STATIC_ASSERT(offsetof(GChead, env) == offsetof(GCfuncL, env)); +LJ_STATIC_ASSERT(offsetof(GChead, env) == offsetof(GCudata, env)); + +/* The metatable field MUST be at the same offset for all GC objects. */ +LJ_STATIC_ASSERT(offsetof(GChead, metatable) == offsetof(GCtab, metatable)); +LJ_STATIC_ASSERT(offsetof(GChead, metatable) == offsetof(GCudata, metatable)); + +/* The gclist field MUST be at the same offset for all GC objects. */ +LJ_STATIC_ASSERT(offsetof(GChead, gclist) == offsetof(lua_State, gclist)); +LJ_STATIC_ASSERT(offsetof(GChead, gclist) == offsetof(GCproto, gclist)); +LJ_STATIC_ASSERT(offsetof(GChead, gclist) == offsetof(GCfuncL, gclist)); +LJ_STATIC_ASSERT(offsetof(GChead, gclist) == offsetof(GCtab, gclist)); + +typedef union GCobj { + GChead gch; + GCstr str; + GCupval uv; + lua_State th; + GCproto pt; + GCfunc fn; + GCcdata cd; + GCtab tab; + GCudata ud; +} GCobj; + +/* Macros to convert a GCobj pointer into a specific value. */ +#define gco2str(o) check_exp((o)->gch.gct == ~LJ_TSTR, &(o)->str) +#define gco2uv(o) check_exp((o)->gch.gct == ~LJ_TUPVAL, &(o)->uv) +#define gco2th(o) check_exp((o)->gch.gct == ~LJ_TTHREAD, &(o)->th) +#define gco2pt(o) check_exp((o)->gch.gct == ~LJ_TPROTO, &(o)->pt) +#define gco2func(o) check_exp((o)->gch.gct == ~LJ_TFUNC, &(o)->fn) +#define gco2cd(o) check_exp((o)->gch.gct == ~LJ_TCDATA, &(o)->cd) +#define gco2tab(o) check_exp((o)->gch.gct == ~LJ_TTAB, &(o)->tab) +#define gco2ud(o) check_exp((o)->gch.gct == ~LJ_TUDATA, &(o)->ud) + +/* Macro to convert any collectable object into a GCobj pointer. */ +#define obj2gco(v) ((GCobj *)(v)) + +/* -- TValue getters/setters ---------------------------------------------- */ + +/* Macros to test types. */ +#if LJ_GC64 +#define itype(o) ((uint32_t)((o)->it64 >> 47)) +#define tvisnil(o) ((o)->it64 == -1) +#else +#define itype(o) ((o)->it) +#define tvisnil(o) (itype(o) == LJ_TNIL) +#endif +#define tvisfalse(o) (itype(o) == LJ_TFALSE) +#define tvistrue(o) (itype(o) == LJ_TTRUE) +#define tvisbool(o) (tvisfalse(o) || tvistrue(o)) +#if LJ_64 && !LJ_GC64 +#define tvislightud(o) (((int32_t)itype(o) >> 15) == -2) +#else +#define tvislightud(o) (itype(o) == LJ_TLIGHTUD) +#endif +#define tvisstr(o) (itype(o) == LJ_TSTR) +#define tvisfunc(o) (itype(o) == LJ_TFUNC) +#define tvisthread(o) (itype(o) == LJ_TTHREAD) +#define tvisproto(o) (itype(o) == LJ_TPROTO) +#define tviscdata(o) (itype(o) == LJ_TCDATA) +#define tvistab(o) (itype(o) == LJ_TTAB) +#define tvisudata(o) (itype(o) == LJ_TUDATA) +#define tvisnumber(o) (itype(o) <= LJ_TISNUM) +#define tvisint(o) (LJ_DUALNUM && itype(o) == LJ_TISNUM) +#define tvisnum(o) (itype(o) < LJ_TISNUM) + +#define tvistruecond(o) (itype(o) < LJ_TISTRUECOND) +#define tvispri(o) (itype(o) >= LJ_TISPRI) +#define tvistabud(o) (itype(o) <= LJ_TISTABUD) /* && !tvisnum() */ +#define tvisgcv(o) ((itype(o) - LJ_TISGCV) > (LJ_TNUMX - LJ_TISGCV)) + +/* Special macros to test numbers for NaN, +0, -0, +1 and raw equality. */ +#define tvisnan(o) ((o)->n != (o)->n) +#if LJ_64 +#define tviszero(o) (((o)->u64 << 1) == 0) +#else +#define tviszero(o) (((o)->u32.lo | ((o)->u32.hi << 1)) == 0) +#endif +#define tvispzero(o) ((o)->u64 == 0) +#define tvismzero(o) ((o)->u64 == U64x(80000000,00000000)) +#define tvispone(o) ((o)->u64 == U64x(3ff00000,00000000)) +#define rawnumequal(o1, o2) ((o1)->u64 == (o2)->u64) + +/* Macros to convert type ids. */ +#if LJ_64 && !LJ_GC64 +#define itypemap(o) \ + (tvisnumber(o) ? ~LJ_TNUMX : tvislightud(o) ? ~LJ_TLIGHTUD : ~itype(o)) +#else +#define itypemap(o) (tvisnumber(o) ? ~LJ_TNUMX : ~itype(o)) +#endif + +/* Macros to get tagged values. */ +#if LJ_GC64 +#define gcval(o) ((GCobj *)(gcrefu((o)->gcr) & LJ_GCVMASK)) +#else +#define gcval(o) (gcref((o)->gcr)) +#endif +#define boolV(o) check_exp(tvisbool(o), (LJ_TFALSE - itype(o))) +#if LJ_64 +#define lightudseg(u) \ + (((u) >> LJ_LIGHTUD_BITS_LO) & ((1 << LJ_LIGHTUD_BITS_SEG)-1)) +#define lightudlo(u) \ + ((u) & (((uint64_t)1 << LJ_LIGHTUD_BITS_LO) - 1)) +#define lightudup(p) \ + ((uint32_t)(((p) >> LJ_LIGHTUD_BITS_LO) << (LJ_LIGHTUD_BITS_LO-32))) +static LJ_AINLINE void *lightudV(global_State *g, cTValue *o) +{ + uint64_t u = o->u64; + uint64_t seg = lightudseg(u); + uint32_t *segmap = mref(g->gc.lightudseg, uint32_t); + lj_assertG(tvislightud(o), "lightuserdata expected"); + if (seg == (1 << LJ_LIGHTUD_BITS_SEG)-1) return NULL; + lj_assertG(seg <= g->gc.lightudnum, "bad lightuserdata segment %d", seg); + return (void *)(((uint64_t)segmap[seg] << 32) | lightudlo(u)); +} +#else +#define lightudV(g, o) check_exp(tvislightud(o), gcrefp((o)->gcr, void)) +#endif +#define gcV(o) check_exp(tvisgcv(o), gcval(o)) +#define strV(o) check_exp(tvisstr(o), &gcval(o)->str) +#define funcV(o) check_exp(tvisfunc(o), &gcval(o)->fn) +#define threadV(o) check_exp(tvisthread(o), &gcval(o)->th) +#define protoV(o) check_exp(tvisproto(o), &gcval(o)->pt) +#define cdataV(o) check_exp(tviscdata(o), &gcval(o)->cd) +#define tabV(o) check_exp(tvistab(o), &gcval(o)->tab) +#define udataV(o) check_exp(tvisudata(o), &gcval(o)->ud) +#define numV(o) check_exp(tvisnum(o), (o)->n) +#define intV(o) check_exp(tvisint(o), (int32_t)(o)->i) + +/* Macros to set tagged values. */ +#if LJ_GC64 +#define setitype(o, i) ((o)->it = ((i) << 15)) +#define setnilV(o) ((o)->it64 = -1) +#define setpriV(o, x) ((o)->it64 = (int64_t)~((uint64_t)~(x)<<47)) +#define setboolV(o, x) ((o)->it64 = (int64_t)~((uint64_t)((x)+1)<<47)) +#else +#define setitype(o, i) ((o)->it = (i)) +#define setnilV(o) ((o)->it = LJ_TNIL) +#define setboolV(o, x) ((o)->it = LJ_TFALSE-(uint32_t)(x)) +#define setpriV(o, i) (setitype((o), (i))) +#endif + +static LJ_AINLINE void setrawlightudV(TValue *o, void *p) +{ +#if LJ_GC64 + o->u64 = (uint64_t)p | (((uint64_t)LJ_TLIGHTUD) << 47); +#elif LJ_64 + o->u64 = (uint64_t)p | (((uint64_t)0xffff) << 48); +#else + setgcrefp(o->gcr, p); setitype(o, LJ_TLIGHTUD); +#endif +} + +#if LJ_FR2 || LJ_32 +#define contptr(f) ((void *)(f)) +#define setcont(o, f) ((o)->u64 = (uint64_t)(uintptr_t)contptr(f)) +#else +#define contptr(f) \ + ((void *)(uintptr_t)(uint32_t)((intptr_t)(f) - (intptr_t)lj_vm_asm_begin)) +#define setcont(o, f) \ + ((o)->u64 = (uint64_t)(void *)(f) - (uint64_t)lj_vm_asm_begin) +#endif + +static LJ_AINLINE void checklivetv(lua_State *L, TValue *o, const char *msg) +{ + UNUSED(L); UNUSED(o); UNUSED(msg); +#if LUA_USE_ASSERT + if (tvisgcv(o)) { + lj_assertL(~itype(o) == gcval(o)->gch.gct, + "mismatch of TValue type %d vs GC type %d", + ~itype(o), gcval(o)->gch.gct); + /* Copy of isdead check from lj_gc.h to avoid circular include. */ + lj_assertL(!(gcval(o)->gch.marked & (G(L)->gc.currentwhite ^ 3) & 3), msg); + } +#endif +} + +static LJ_AINLINE void setgcVraw(TValue *o, GCobj *v, uint32_t itype) +{ +#if LJ_GC64 + setgcreft(o->gcr, v, itype); +#else + setgcref(o->gcr, v); setitype(o, itype); +#endif +} + +static LJ_AINLINE void setgcV(lua_State *L, TValue *o, GCobj *v, uint32_t it) +{ + setgcVraw(o, v, it); + checklivetv(L, o, "store to dead GC object"); +} + +#define define_setV(name, type, tag) \ +static LJ_AINLINE void name(lua_State *L, TValue *o, const type *v) \ +{ \ + setgcV(L, o, obj2gco(v), tag); \ +} +define_setV(setstrV, GCstr, LJ_TSTR) +define_setV(setthreadV, lua_State, LJ_TTHREAD) +define_setV(setprotoV, GCproto, LJ_TPROTO) +define_setV(setfuncV, GCfunc, LJ_TFUNC) +define_setV(setcdataV, GCcdata, LJ_TCDATA) +define_setV(settabV, GCtab, LJ_TTAB) +define_setV(setudataV, GCudata, LJ_TUDATA) + +#define setnumV(o, x) ((o)->n = (x)) +#define setnanV(o) ((o)->u64 = U64x(fff80000,00000000)) +#define setpinfV(o) ((o)->u64 = U64x(7ff00000,00000000)) +#define setminfV(o) ((o)->u64 = U64x(fff00000,00000000)) + +static LJ_AINLINE void setintV(TValue *o, int32_t i) +{ +#if LJ_DUALNUM + o->i = (uint32_t)i; setitype(o, LJ_TISNUM); +#else + o->n = (lua_Number)i; +#endif +} + +static LJ_AINLINE void setint64V(TValue *o, int64_t i) +{ + if (LJ_DUALNUM && LJ_LIKELY(i == (int64_t)(int32_t)i)) + setintV(o, (int32_t)i); + else + setnumV(o, (lua_Number)i); +} + +#if LJ_64 +#define setintptrV(o, i) setint64V((o), (i)) +#else +#define setintptrV(o, i) setintV((o), (i)) +#endif + +/* Copy tagged values. */ +static LJ_AINLINE void copyTV(lua_State *L, TValue *o1, const TValue *o2) +{ + *o1 = *o2; + checklivetv(L, o1, "copy of dead GC object"); +} + +/* -- Number to integer conversion ---------------------------------------- */ + +#if LJ_SOFTFP +LJ_ASMF int32_t lj_vm_tobit(double x); +#if LJ_TARGET_MIPS64 +LJ_ASMF int32_t lj_vm_tointg(double x); +#endif +#endif + +static LJ_AINLINE int32_t lj_num2bit(lua_Number n) +{ +#if LJ_SOFTFP + return lj_vm_tobit(n); +#else + TValue o; + o.n = n + 6755399441055744.0; /* 2^52 + 2^51 */ + return (int32_t)o.u32.lo; +#endif +} + +#define lj_num2int(n) ((int32_t)(n)) + +/* +** This must match the JIT backend behavior. In particular for archs +** that don't have a common hardware instruction for this conversion. +** Note that signed FP to unsigned int conversions have an undefined +** result and should never be relied upon in portable FFI code. +** See also: C99 or C11 standard, 6.3.1.4, footnote of (1). +*/ +static LJ_AINLINE uint64_t lj_num2u64(lua_Number n) +{ +#if LJ_TARGET_X86ORX64 || LJ_TARGET_MIPS + int64_t i = (int64_t)n; + if (i < 0) i = (int64_t)(n - 18446744073709551616.0); + return (uint64_t)i; +#else + return (uint64_t)n; +#endif +} + +static LJ_AINLINE int32_t numberVint(cTValue *o) +{ + if (LJ_LIKELY(tvisint(o))) + return intV(o); + else + return lj_num2int(numV(o)); +} + +static LJ_AINLINE lua_Number numberVnum(cTValue *o) +{ + if (LJ_UNLIKELY(tvisint(o))) + return (lua_Number)intV(o); + else + return numV(o); +} + +/* -- Miscellaneous object handling --------------------------------------- */ + +/* Names and maps for internal and external object tags. */ +LJ_DATA const char *const lj_obj_typename[1+LUA_TCDATA+1]; +LJ_DATA const char *const lj_obj_itypename[~LJ_TNUMX+1]; + +#define lj_typename(o) (lj_obj_itypename[itypemap(o)]) + +/* Compare two objects without calling metamethods. */ +LJ_FUNC int LJ_FASTCALL lj_obj_equal(cTValue *o1, cTValue *o2); +LJ_FUNC const void * LJ_FASTCALL lj_obj_ptr(global_State *g, cTValue *o); + +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_opt_dce.c b/fluent-bit/lib/luajit-3065c9/src/lj_opt_dce.c new file mode 100644 index 00000000..cff54a8b --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_opt_dce.c @@ -0,0 +1,75 @@ +/* +** DCE: Dead Code Elimination. Pre-LOOP only -- ASM already performs DCE. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#define lj_opt_dce_c +#define LUA_CORE + +#include "lj_obj.h" + +#if LJ_HASJIT + +#include "lj_ir.h" +#include "lj_jit.h" +#include "lj_iropt.h" + +/* Some local macros to save typing. Undef'd at the end. */ +#define IR(ref) (&J->cur.ir[(ref)]) + +/* Scan through all snapshots and mark all referenced instructions. */ +static void dce_marksnap(jit_State *J) +{ + SnapNo i, nsnap = J->cur.nsnap; + for (i = 0; i < nsnap; i++) { + SnapShot *snap = &J->cur.snap[i]; + SnapEntry *map = &J->cur.snapmap[snap->mapofs]; + MSize n, nent = snap->nent; + for (n = 0; n < nent; n++) { + IRRef ref = snap_ref(map[n]); + if (ref >= REF_FIRST) + irt_setmark(IR(ref)->t); + } + } +} + +/* Backwards propagate marks. Replace unused instructions with NOPs. */ +static void dce_propagate(jit_State *J) +{ + IRRef1 *pchain[IR__MAX]; + IRRef ins; + uint32_t i; + for (i = 0; i < IR__MAX; i++) pchain[i] = &J->chain[i]; + for (ins = J->cur.nins-1; ins >= REF_FIRST; ins--) { + IRIns *ir = IR(ins); + if (irt_ismarked(ir->t)) { + irt_clearmark(ir->t); + pchain[ir->o] = &ir->prev; + } else if (!ir_sideeff(ir)) { + *pchain[ir->o] = ir->prev; /* Reroute original instruction chain. */ + lj_ir_nop(ir); + continue; + } + if (ir->op1 >= REF_FIRST) irt_setmark(IR(ir->op1)->t); + if (ir->op2 >= REF_FIRST) irt_setmark(IR(ir->op2)->t); + } +} + +/* Dead Code Elimination. +** +** First backpropagate marks for all used instructions. Then replace +** the unused ones with a NOP. Note that compressing the IR to eliminate +** the NOPs does not pay off. +*/ +void lj_opt_dce(jit_State *J) +{ + if ((J->flags & JIT_F_OPT_DCE)) { + dce_marksnap(J); + dce_propagate(J); + memset(J->bpropcache, 0, sizeof(J->bpropcache)); /* Invalidate cache. */ + } +} + +#undef IR + +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_opt_fold.c b/fluent-bit/lib/luajit-3065c9/src/lj_opt_fold.c new file mode 100644 index 00000000..7ef09a1f --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_opt_fold.c @@ -0,0 +1,2602 @@ +/* +** FOLD: Constant Folding, Algebraic Simplifications and Reassociation. +** ABCelim: Array Bounds Check Elimination. +** CSE: Common-Subexpression Elimination. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#define lj_opt_fold_c +#define LUA_CORE + +#include + +#include "lj_obj.h" + +#if LJ_HASJIT + +#include "lj_buf.h" +#include "lj_str.h" +#include "lj_tab.h" +#include "lj_ir.h" +#include "lj_jit.h" +#include "lj_ircall.h" +#include "lj_iropt.h" +#include "lj_trace.h" +#if LJ_HASFFI +#include "lj_ctype.h" +#include "lj_carith.h" +#endif +#include "lj_vm.h" +#include "lj_strscan.h" +#include "lj_strfmt.h" + +/* Here's a short description how the FOLD engine processes instructions: +** +** The FOLD engine receives a single instruction stored in fins (J->fold.ins). +** The instruction and its operands are used to select matching fold rules. +** These are applied iteratively until a fixed point is reached. +** +** The 8 bit opcode of the instruction itself plus the opcodes of the +** two instructions referenced by its operands form a 24 bit key +** 'ins left right' (unused operands -> 0, literals -> lowest 8 bits). +** +** This key is used for partial matching against the fold rules. The +** left/right operand fields of the key are successively masked with +** the 'any' wildcard, from most specific to least specific: +** +** ins left right +** ins any right +** ins left any +** ins any any +** +** The masked key is used to lookup a matching fold rule in a semi-perfect +** hash table. If a matching rule is found, the related fold function is run. +** Multiple rules can share the same fold function. A fold rule may return +** one of several special values: +** +** - NEXTFOLD means no folding was applied, because an additional test +** inside the fold function failed. Matching continues against less +** specific fold rules. Finally the instruction is passed on to CSE. +** +** - RETRYFOLD means the instruction was modified in-place. Folding is +** retried as if this instruction had just been received. +** +** All other return values are terminal actions -- no further folding is +** applied: +** +** - INTFOLD(i) returns a reference to the integer constant i. +** +** - LEFTFOLD and RIGHTFOLD return the left/right operand reference +** without emitting an instruction. +** +** - CSEFOLD and EMITFOLD pass the instruction directly to CSE or emit +** it without passing through any further optimizations. +** +** - FAILFOLD, DROPFOLD and CONDFOLD only apply to instructions which have +** no result (e.g. guarded assertions): FAILFOLD means the guard would +** always fail, i.e. the current trace is pointless. DROPFOLD means +** the guard is always true and has been eliminated. CONDFOLD is a +** shortcut for FAILFOLD + cond (i.e. drop if true, otherwise fail). +** +** - Any other return value is interpreted as an IRRef or TRef. This +** can be a reference to an existing or a newly created instruction. +** Only the least-significant 16 bits (IRRef1) are used to form a TRef +** which is finally returned to the caller. +** +** The FOLD engine receives instructions both from the trace recorder and +** substituted instructions from LOOP unrolling. This means all types +** of instructions may end up here, even though the recorder bypasses +** FOLD in some cases. Thus all loads, stores and allocations must have +** an any/any rule to avoid being passed on to CSE. +** +** Carefully read the following requirements before adding or modifying +** any fold rules: +** +** Requirement #1: All fold rules must preserve their destination type. +** +** Consistently use INTFOLD() (KINT result) or lj_ir_knum() (KNUM result). +** Never use lj_ir_knumint() which can have either a KINT or KNUM result. +** +** Requirement #2: Fold rules should not create *new* instructions which +** reference operands *across* PHIs. +** +** E.g. a RETRYFOLD with 'fins->op1 = fleft->op1' is invalid if the +** left operand is a PHI. Then fleft->op1 would point across the PHI +** frontier to an invariant instruction. Adding a PHI for this instruction +** would be counterproductive. The solution is to add a barrier which +** prevents folding across PHIs, i.e. 'PHIBARRIER(fleft)' in this case. +** The only exception is for recurrences with high latencies like +** repeated int->num->int conversions. +** +** One could relax this condition a bit if the referenced instruction is +** a PHI, too. But this often leads to worse code due to excessive +** register shuffling. +** +** Note: returning *existing* instructions (e.g. LEFTFOLD) is ok, though. +** Even returning fleft->op1 would be ok, because a new PHI will added, +** if needed. But again, this leads to excessive register shuffling and +** should be avoided. +** +** Requirement #3: The set of all fold rules must be monotonic to guarantee +** termination. +** +** The goal is optimization, so one primarily wants to add strength-reducing +** rules. This means eliminating an instruction or replacing an instruction +** with one or more simpler instructions. Don't add fold rules which point +** into the other direction. +** +** Some rules (like commutativity) do not directly reduce the strength of +** an instruction, but enable other fold rules (e.g. by moving constants +** to the right operand). These rules must be made unidirectional to avoid +** cycles. +** +** Rule of thumb: the trace recorder expands the IR and FOLD shrinks it. +*/ + +/* Some local macros to save typing. Undef'd at the end. */ +#define IR(ref) (&J->cur.ir[(ref)]) +#define fins (&J->fold.ins) +#define fleft (J->fold.left) +#define fright (J->fold.right) +#define knumleft (ir_knum(fleft)->n) +#define knumright (ir_knum(fright)->n) + +/* Pass IR on to next optimization in chain (FOLD). */ +#define emitir(ot, a, b) (lj_ir_set(J, (ot), (a), (b)), lj_opt_fold(J)) + +/* Fold function type. Fastcall on x86 significantly reduces their size. */ +typedef IRRef (LJ_FASTCALL *FoldFunc)(jit_State *J); + +/* Macros for the fold specs, so buildvm can recognize them. */ +#define LJFOLD(x) +#define LJFOLDX(x) +#define LJFOLDF(name) static TRef LJ_FASTCALL fold_##name(jit_State *J) +/* Note: They must be at the start of a line or buildvm ignores them! */ + +/* Barrier to prevent using operands across PHIs. */ +#define PHIBARRIER(ir) if (irt_isphi((ir)->t)) return NEXTFOLD + +/* Barrier to prevent folding across a GC step. +** GC steps can only happen at the head of a trace and at LOOP. +** And the GC is only driven forward if there's at least one allocation. +*/ +#define gcstep_barrier(J, ref) \ + ((ref) < J->chain[IR_LOOP] && \ + (J->chain[IR_SNEW] || J->chain[IR_XSNEW] || \ + J->chain[IR_TNEW] || J->chain[IR_TDUP] || \ + J->chain[IR_CNEW] || J->chain[IR_CNEWI] || \ + J->chain[IR_BUFSTR] || J->chain[IR_TOSTR] || J->chain[IR_CALLA])) + +/* -- Constant folding for FP numbers ------------------------------------- */ + +LJFOLD(ADD KNUM KNUM) +LJFOLD(SUB KNUM KNUM) +LJFOLD(MUL KNUM KNUM) +LJFOLD(DIV KNUM KNUM) +LJFOLD(LDEXP KNUM KNUM) +LJFOLD(MIN KNUM KNUM) +LJFOLD(MAX KNUM KNUM) +LJFOLDF(kfold_numarith) +{ + lua_Number a = knumleft; + lua_Number b = knumright; + lua_Number y = lj_vm_foldarith(a, b, fins->o - IR_ADD); + return lj_ir_knum(J, y); +} + +LJFOLD(NEG KNUM FLOAD) +LJFOLD(ABS KNUM FLOAD) +LJFOLDF(kfold_numabsneg) +{ + lua_Number a = knumleft; + lua_Number y = lj_vm_foldarith(a, a, fins->o - IR_ADD); + return lj_ir_knum(J, y); +} + +LJFOLD(LDEXP KNUM KINT) +LJFOLDF(kfold_ldexp) +{ +#if LJ_TARGET_X86ORX64 + UNUSED(J); + return NEXTFOLD; +#else + return lj_ir_knum(J, ldexp(knumleft, fright->i)); +#endif +} + +LJFOLD(FPMATH KNUM any) +LJFOLDF(kfold_fpmath) +{ + lua_Number a = knumleft; + lua_Number y = lj_vm_foldfpm(a, fins->op2); + return lj_ir_knum(J, y); +} + +LJFOLD(CALLN KNUM any) +LJFOLDF(kfold_fpcall1) +{ + const CCallInfo *ci = &lj_ir_callinfo[fins->op2]; + if (CCI_TYPE(ci) == IRT_NUM) { + double y = ((double (*)(double))ci->func)(knumleft); + return lj_ir_knum(J, y); + } + return NEXTFOLD; +} + +LJFOLD(CALLN CARG IRCALL_atan2) +LJFOLDF(kfold_fpcall2) +{ + if (irref_isk(fleft->op1) && irref_isk(fleft->op2)) { + const CCallInfo *ci = &lj_ir_callinfo[fins->op2]; + double a = ir_knum(IR(fleft->op1))->n; + double b = ir_knum(IR(fleft->op2))->n; + double y = ((double (*)(double, double))ci->func)(a, b); + return lj_ir_knum(J, y); + } + return NEXTFOLD; +} + +LJFOLD(POW KNUM KNUM) +LJFOLDF(kfold_numpow) +{ + return lj_ir_knum(J, lj_vm_foldarith(knumleft, knumright, IR_POW - IR_ADD)); +} + +/* Must not use kfold_kref for numbers (could be NaN). */ +LJFOLD(EQ KNUM KNUM) +LJFOLD(NE KNUM KNUM) +LJFOLD(LT KNUM KNUM) +LJFOLD(GE KNUM KNUM) +LJFOLD(LE KNUM KNUM) +LJFOLD(GT KNUM KNUM) +LJFOLD(ULT KNUM KNUM) +LJFOLD(UGE KNUM KNUM) +LJFOLD(ULE KNUM KNUM) +LJFOLD(UGT KNUM KNUM) +LJFOLDF(kfold_numcomp) +{ + return CONDFOLD(lj_ir_numcmp(knumleft, knumright, (IROp)fins->o)); +} + +/* -- Constant folding for 32 bit integers -------------------------------- */ + +static int32_t kfold_intop(int32_t k1, int32_t k2, IROp op) +{ + switch (op) { + case IR_ADD: k1 += k2; break; + case IR_SUB: k1 -= k2; break; + case IR_MUL: k1 *= k2; break; + case IR_MOD: k1 = lj_vm_modi(k1, k2); break; + case IR_NEG: k1 = -k1; break; + case IR_BAND: k1 &= k2; break; + case IR_BOR: k1 |= k2; break; + case IR_BXOR: k1 ^= k2; break; + case IR_BSHL: k1 <<= (k2 & 31); break; + case IR_BSHR: k1 = (int32_t)((uint32_t)k1 >> (k2 & 31)); break; + case IR_BSAR: k1 >>= (k2 & 31); break; + case IR_BROL: k1 = (int32_t)lj_rol((uint32_t)k1, (k2 & 31)); break; + case IR_BROR: k1 = (int32_t)lj_ror((uint32_t)k1, (k2 & 31)); break; + case IR_MIN: k1 = k1 < k2 ? k1 : k2; break; + case IR_MAX: k1 = k1 > k2 ? k1 : k2; break; + default: lj_assertX(0, "bad IR op %d", op); break; + } + return k1; +} + +LJFOLD(ADD KINT KINT) +LJFOLD(SUB KINT KINT) +LJFOLD(MUL KINT KINT) +LJFOLD(MOD KINT KINT) +LJFOLD(NEG KINT KINT) +LJFOLD(BAND KINT KINT) +LJFOLD(BOR KINT KINT) +LJFOLD(BXOR KINT KINT) +LJFOLD(BSHL KINT KINT) +LJFOLD(BSHR KINT KINT) +LJFOLD(BSAR KINT KINT) +LJFOLD(BROL KINT KINT) +LJFOLD(BROR KINT KINT) +LJFOLD(MIN KINT KINT) +LJFOLD(MAX KINT KINT) +LJFOLDF(kfold_intarith) +{ + return INTFOLD(kfold_intop(fleft->i, fright->i, (IROp)fins->o)); +} + +LJFOLD(ADDOV KINT KINT) +LJFOLD(SUBOV KINT KINT) +LJFOLD(MULOV KINT KINT) +LJFOLDF(kfold_intovarith) +{ + lua_Number n = lj_vm_foldarith((lua_Number)fleft->i, (lua_Number)fright->i, + fins->o - IR_ADDOV); + int32_t k = lj_num2int(n); + if (n != (lua_Number)k) + return FAILFOLD; + return INTFOLD(k); +} + +LJFOLD(BNOT KINT) +LJFOLDF(kfold_bnot) +{ + return INTFOLD(~fleft->i); +} + +LJFOLD(BSWAP KINT) +LJFOLDF(kfold_bswap) +{ + return INTFOLD((int32_t)lj_bswap((uint32_t)fleft->i)); +} + +LJFOLD(LT KINT KINT) +LJFOLD(GE KINT KINT) +LJFOLD(LE KINT KINT) +LJFOLD(GT KINT KINT) +LJFOLD(ULT KINT KINT) +LJFOLD(UGE KINT KINT) +LJFOLD(ULE KINT KINT) +LJFOLD(UGT KINT KINT) +LJFOLD(ABC KINT KINT) +LJFOLDF(kfold_intcomp) +{ + int32_t a = fleft->i, b = fright->i; + switch ((IROp)fins->o) { + case IR_LT: return CONDFOLD(a < b); + case IR_GE: return CONDFOLD(a >= b); + case IR_LE: return CONDFOLD(a <= b); + case IR_GT: return CONDFOLD(a > b); + case IR_ULT: return CONDFOLD((uint32_t)a < (uint32_t)b); + case IR_UGE: return CONDFOLD((uint32_t)a >= (uint32_t)b); + case IR_ULE: return CONDFOLD((uint32_t)a <= (uint32_t)b); + case IR_ABC: + case IR_UGT: return CONDFOLD((uint32_t)a > (uint32_t)b); + default: lj_assertJ(0, "bad IR op %d", fins->o); return FAILFOLD; + } +} + +LJFOLD(UGE any KINT) +LJFOLDF(kfold_intcomp0) +{ + if (fright->i == 0) + return DROPFOLD; + return NEXTFOLD; +} + +/* -- Constant folding for 64 bit integers -------------------------------- */ + +static uint64_t kfold_int64arith(jit_State *J, uint64_t k1, uint64_t k2, + IROp op) +{ + UNUSED(J); +#if LJ_HASFFI + switch (op) { + case IR_ADD: k1 += k2; break; + case IR_SUB: k1 -= k2; break; + case IR_MUL: k1 *= k2; break; + case IR_BAND: k1 &= k2; break; + case IR_BOR: k1 |= k2; break; + case IR_BXOR: k1 ^= k2; break; + case IR_BSHL: k1 <<= (k2 & 63); break; + case IR_BSHR: k1 = (int32_t)((uint32_t)k1 >> (k2 & 63)); break; + case IR_BSAR: k1 >>= (k2 & 63); break; + case IR_BROL: k1 = (int32_t)lj_rol((uint32_t)k1, (k2 & 63)); break; + case IR_BROR: k1 = (int32_t)lj_ror((uint32_t)k1, (k2 & 63)); break; + default: lj_assertJ(0, "bad IR op %d", op); break; + } +#else + UNUSED(k2); UNUSED(op); + lj_assertJ(0, "FFI IR op without FFI"); +#endif + return k1; +} + +LJFOLD(ADD KINT64 KINT64) +LJFOLD(SUB KINT64 KINT64) +LJFOLD(MUL KINT64 KINT64) +LJFOLD(BAND KINT64 KINT64) +LJFOLD(BOR KINT64 KINT64) +LJFOLD(BXOR KINT64 KINT64) +LJFOLDF(kfold_int64arith) +{ + return INT64FOLD(kfold_int64arith(J, ir_k64(fleft)->u64, + ir_k64(fright)->u64, (IROp)fins->o)); +} + +LJFOLD(DIV KINT64 KINT64) +LJFOLD(MOD KINT64 KINT64) +LJFOLD(POW KINT64 KINT64) +LJFOLDF(kfold_int64arith2) +{ +#if LJ_HASFFI + uint64_t k1 = ir_k64(fleft)->u64, k2 = ir_k64(fright)->u64; + if (irt_isi64(fins->t)) { + k1 = fins->o == IR_DIV ? lj_carith_divi64((int64_t)k1, (int64_t)k2) : + fins->o == IR_MOD ? lj_carith_modi64((int64_t)k1, (int64_t)k2) : + lj_carith_powi64((int64_t)k1, (int64_t)k2); + } else { + k1 = fins->o == IR_DIV ? lj_carith_divu64(k1, k2) : + fins->o == IR_MOD ? lj_carith_modu64(k1, k2) : + lj_carith_powu64(k1, k2); + } + return INT64FOLD(k1); +#else + UNUSED(J); lj_assertJ(0, "FFI IR op without FFI"); return FAILFOLD; +#endif +} + +LJFOLD(BSHL KINT64 KINT) +LJFOLD(BSHR KINT64 KINT) +LJFOLD(BSAR KINT64 KINT) +LJFOLD(BROL KINT64 KINT) +LJFOLD(BROR KINT64 KINT) +LJFOLDF(kfold_int64shift) +{ +#if LJ_HASFFI + uint64_t k = ir_k64(fleft)->u64; + int32_t sh = (fright->i & 63); + return INT64FOLD(lj_carith_shift64(k, sh, fins->o - IR_BSHL)); +#else + UNUSED(J); lj_assertJ(0, "FFI IR op without FFI"); return FAILFOLD; +#endif +} + +LJFOLD(BNOT KINT64) +LJFOLDF(kfold_bnot64) +{ +#if LJ_HASFFI + return INT64FOLD(~ir_k64(fleft)->u64); +#else + UNUSED(J); lj_assertJ(0, "FFI IR op without FFI"); return FAILFOLD; +#endif +} + +LJFOLD(BSWAP KINT64) +LJFOLDF(kfold_bswap64) +{ +#if LJ_HASFFI + return INT64FOLD(lj_bswap64(ir_k64(fleft)->u64)); +#else + UNUSED(J); lj_assertJ(0, "FFI IR op without FFI"); return FAILFOLD; +#endif +} + +LJFOLD(LT KINT64 KINT64) +LJFOLD(GE KINT64 KINT64) +LJFOLD(LE KINT64 KINT64) +LJFOLD(GT KINT64 KINT64) +LJFOLD(ULT KINT64 KINT64) +LJFOLD(UGE KINT64 KINT64) +LJFOLD(ULE KINT64 KINT64) +LJFOLD(UGT KINT64 KINT64) +LJFOLDF(kfold_int64comp) +{ +#if LJ_HASFFI + uint64_t a = ir_k64(fleft)->u64, b = ir_k64(fright)->u64; + switch ((IROp)fins->o) { + case IR_LT: return CONDFOLD((int64_t)a < (int64_t)b); + case IR_GE: return CONDFOLD((int64_t)a >= (int64_t)b); + case IR_LE: return CONDFOLD((int64_t)a <= (int64_t)b); + case IR_GT: return CONDFOLD((int64_t)a > (int64_t)b); + case IR_ULT: return CONDFOLD(a < b); + case IR_UGE: return CONDFOLD(a >= b); + case IR_ULE: return CONDFOLD(a <= b); + case IR_UGT: return CONDFOLD(a > b); + default: lj_assertJ(0, "bad IR op %d", fins->o); return FAILFOLD; + } +#else + UNUSED(J); lj_assertJ(0, "FFI IR op without FFI"); return FAILFOLD; +#endif +} + +LJFOLD(UGE any KINT64) +LJFOLDF(kfold_int64comp0) +{ +#if LJ_HASFFI + if (ir_k64(fright)->u64 == 0) + return DROPFOLD; + return NEXTFOLD; +#else + UNUSED(J); lj_assertJ(0, "FFI IR op without FFI"); return FAILFOLD; +#endif +} + +/* -- Constant folding for strings ---------------------------------------- */ + +LJFOLD(SNEW KKPTR KINT) +LJFOLDF(kfold_snew_kptr) +{ + GCstr *s = lj_str_new(J->L, (const char *)ir_kptr(fleft), (size_t)fright->i); + return lj_ir_kstr(J, s); +} + +LJFOLD(SNEW any KINT) +LJFOLD(XSNEW any KINT) +LJFOLDF(kfold_snew_empty) +{ + if (fright->i == 0) + return lj_ir_kstr(J, &J2G(J)->strempty); + return NEXTFOLD; +} + +LJFOLD(STRREF KGC KINT) +LJFOLDF(kfold_strref) +{ + GCstr *str = ir_kstr(fleft); + lj_assertJ((MSize)fright->i <= str->len, "bad string ref"); + return lj_ir_kkptr(J, (char *)strdata(str) + fright->i); +} + +LJFOLD(STRREF SNEW any) +LJFOLDF(kfold_strref_snew) +{ + PHIBARRIER(fleft); + if (irref_isk(fins->op2) && fright->i == 0) { + return fleft->op1; /* strref(snew(ptr, len), 0) ==> ptr */ + } else { + /* Reassociate: strref(snew(strref(str, a), len), b) ==> strref(str, a+b) */ + IRIns *ir = IR(fleft->op1); + if (ir->o == IR_STRREF) { + IRRef1 str = ir->op1; /* IRIns * is not valid across emitir. */ + PHIBARRIER(ir); + fins->op2 = emitir(IRTI(IR_ADD), ir->op2, fins->op2); /* Clobbers fins! */ + fins->op1 = str; + fins->ot = IRT(IR_STRREF, IRT_PGC); + return RETRYFOLD; + } + } + return NEXTFOLD; +} + +LJFOLD(CALLN CARG IRCALL_lj_str_cmp) +LJFOLDF(kfold_strcmp) +{ + if (irref_isk(fleft->op1) && irref_isk(fleft->op2)) { + GCstr *a = ir_kstr(IR(fleft->op1)); + GCstr *b = ir_kstr(IR(fleft->op2)); + return INTFOLD(lj_str_cmp(a, b)); + } + return NEXTFOLD; +} + +/* -- Constant folding and forwarding for buffers ------------------------- */ + +/* +** Buffer ops perform stores, but their effect is limited to the buffer +** itself. Also, buffer ops are chained: a use of an op implies a use of +** all other ops up the chain. Conversely, if an op is unused, all ops +** up the chain can go unsed. This largely eliminates the need to treat +** them as stores. +** +** Alas, treating them as normal (IRM_N) ops doesn't work, because they +** cannot be CSEd in isolation. CSE for IRM_N is implicitly done in LOOP +** or if FOLD is disabled. +** +** The compromise is to declare them as loads, emit them like stores and +** CSE whole chains manually when the BUFSTR is to be emitted. Any chain +** fragments left over from CSE are eliminated by DCE. +** +** The string buffer methods emit a USE instead of a BUFSTR to keep the +** chain alive. +*/ + +LJFOLD(BUFHDR any any) +LJFOLDF(bufhdr_merge) +{ + return fins->op2 == IRBUFHDR_WRITE ? CSEFOLD : EMITFOLD; +} + +LJFOLD(BUFPUT any BUFSTR) +LJFOLDF(bufput_bufstr) +{ + if ((J->flags & JIT_F_OPT_FWD)) { + IRRef hdr = fright->op2; + /* New buffer, no other buffer op inbetween and same buffer? */ + if (fleft->o == IR_BUFHDR && fleft->op2 == IRBUFHDR_RESET && + fleft->prev == hdr && + fleft->op1 == IR(hdr)->op1 && + !(irt_isphi(fright->t) && IR(hdr)->prev) && + (!LJ_HASBUFFER || J->chain[IR_CALLA] < hdr)) { + IRRef ref = fins->op1; + IR(ref)->op2 = IRBUFHDR_APPEND; /* Modify BUFHDR. */ + IR(ref)->op1 = fright->op1; + return ref; + } + /* Replay puts to global temporary buffer. */ + if (IR(hdr)->op2 == IRBUFHDR_RESET && !irt_isphi(fright->t)) { + IRIns *ir = IR(fright->op1); + /* For now only handle single string.reverse .lower .upper .rep. */ + if (ir->o == IR_CALLL && + ir->op2 >= IRCALL_lj_buf_putstr_reverse && + ir->op2 <= IRCALL_lj_buf_putstr_rep) { + IRIns *carg1 = IR(ir->op1); + if (ir->op2 == IRCALL_lj_buf_putstr_rep) { + IRIns *carg2 = IR(carg1->op1); + if (carg2->op1 == hdr) { + return lj_ir_call(J, ir->op2, fins->op1, carg2->op2, carg1->op2); + } + } else if (carg1->op1 == hdr) { + return lj_ir_call(J, ir->op2, fins->op1, carg1->op2); + } + } + } + } + return EMITFOLD; /* Always emit, CSE later. */ +} + +LJFOLD(BUFPUT any any) +LJFOLDF(bufput_kgc) +{ + if (LJ_LIKELY(J->flags & JIT_F_OPT_FOLD) && fright->o == IR_KGC) { + GCstr *s2 = ir_kstr(fright); + if (s2->len == 0) { /* Empty string? */ + return LEFTFOLD; + } else { + if (fleft->o == IR_BUFPUT && irref_isk(fleft->op2) && + !irt_isphi(fleft->t)) { /* Join two constant string puts in a row. */ + GCstr *s1 = ir_kstr(IR(fleft->op2)); + IRRef kref = lj_ir_kstr(J, lj_buf_cat2str(J->L, s1, s2)); + /* lj_ir_kstr() may realloc the IR and invalidates any IRIns *. */ + IR(fins->op1)->op2 = kref; /* Modify previous BUFPUT. */ + return fins->op1; + } + } + } + return EMITFOLD; /* Always emit, CSE later. */ +} + +LJFOLD(BUFSTR any any) +LJFOLDF(bufstr_kfold_cse) +{ + lj_assertJ(fleft->o == IR_BUFHDR || fleft->o == IR_BUFPUT || + fleft->o == IR_CALLL, + "bad buffer constructor IR op %d", fleft->o); + if (LJ_LIKELY(J->flags & JIT_F_OPT_FOLD)) { + if (fleft->o == IR_BUFHDR) { /* No put operations? */ + if (fleft->op2 == IRBUFHDR_RESET) /* Empty buffer? */ + return lj_ir_kstr(J, &J2G(J)->strempty); + fins->op1 = fleft->op1; + fins->op2 = fleft->prev; /* Relies on checks in bufput_append. */ + return CSEFOLD; + } else if (fleft->o == IR_BUFPUT) { + IRIns *irb = IR(fleft->op1); + if (irb->o == IR_BUFHDR && irb->op2 == IRBUFHDR_RESET) + return fleft->op2; /* Shortcut for a single put operation. */ + } + } + /* Try to CSE the whole chain. */ + if (LJ_LIKELY(J->flags & JIT_F_OPT_CSE)) { + IRRef ref = J->chain[IR_BUFSTR]; + while (ref) { + IRIns *irs = IR(ref), *ira = fleft, *irb = IR(irs->op1); + while (ira->o == irb->o && ira->op2 == irb->op2) { + lj_assertJ(ira->o == IR_BUFHDR || ira->o == IR_BUFPUT || + ira->o == IR_CALLL || ira->o == IR_CARG, + "bad buffer constructor IR op %d", ira->o); + if (ira->o == IR_BUFHDR && ira->op2 == IRBUFHDR_RESET) + return ref; /* CSE succeeded. */ + if (ira->o == IR_CALLL && ira->op2 == IRCALL_lj_buf_puttab) + break; + ira = IR(ira->op1); + irb = IR(irb->op1); + } + ref = irs->prev; + } + } + return EMITFOLD; /* No CSE possible. */ +} + +LJFOLD(CALLL CARG IRCALL_lj_buf_putstr_reverse) +LJFOLD(CALLL CARG IRCALL_lj_buf_putstr_upper) +LJFOLD(CALLL CARG IRCALL_lj_buf_putstr_lower) +LJFOLD(CALLL CARG IRCALL_lj_strfmt_putquoted) +LJFOLDF(bufput_kfold_op) +{ + if (irref_isk(fleft->op2)) { + const CCallInfo *ci = &lj_ir_callinfo[fins->op2]; + SBuf *sb = lj_buf_tmp_(J->L); + sb = ((SBuf * (LJ_FASTCALL *)(SBuf *, GCstr *))ci->func)(sb, + ir_kstr(IR(fleft->op2))); + fins->o = IR_BUFPUT; + fins->op1 = fleft->op1; + fins->op2 = lj_ir_kstr(J, lj_buf_tostr(sb)); + return RETRYFOLD; + } + return EMITFOLD; /* Always emit, CSE later. */ +} + +LJFOLD(CALLL CARG IRCALL_lj_buf_putstr_rep) +LJFOLDF(bufput_kfold_rep) +{ + if (irref_isk(fleft->op2)) { + IRIns *irc = IR(fleft->op1); + if (irref_isk(irc->op2)) { + SBuf *sb = lj_buf_tmp_(J->L); + sb = lj_buf_putstr_rep(sb, ir_kstr(IR(irc->op2)), IR(fleft->op2)->i); + fins->o = IR_BUFPUT; + fins->op1 = irc->op1; + fins->op2 = lj_ir_kstr(J, lj_buf_tostr(sb)); + return RETRYFOLD; + } + } + return EMITFOLD; /* Always emit, CSE later. */ +} + +LJFOLD(CALLL CARG IRCALL_lj_strfmt_putfxint) +LJFOLD(CALLL CARG IRCALL_lj_strfmt_putfnum_int) +LJFOLD(CALLL CARG IRCALL_lj_strfmt_putfnum_uint) +LJFOLD(CALLL CARG IRCALL_lj_strfmt_putfnum) +LJFOLD(CALLL CARG IRCALL_lj_strfmt_putfstr) +LJFOLD(CALLL CARG IRCALL_lj_strfmt_putfchar) +LJFOLDF(bufput_kfold_fmt) +{ + IRIns *irc = IR(fleft->op1); + lj_assertJ(irref_isk(irc->op2), "SFormat must be const"); + if (irref_isk(fleft->op2)) { + SFormat sf = (SFormat)IR(irc->op2)->i; + IRIns *ira = IR(fleft->op2); + SBuf *sb = lj_buf_tmp_(J->L); + switch (fins->op2) { + case IRCALL_lj_strfmt_putfxint: + sb = lj_strfmt_putfxint(sb, sf, ir_k64(ira)->u64); + break; + case IRCALL_lj_strfmt_putfstr: + sb = lj_strfmt_putfstr(sb, sf, ir_kstr(ira)); + break; + case IRCALL_lj_strfmt_putfchar: + sb = lj_strfmt_putfchar(sb, sf, ira->i); + break; + case IRCALL_lj_strfmt_putfnum_int: + case IRCALL_lj_strfmt_putfnum_uint: + case IRCALL_lj_strfmt_putfnum: + default: { + const CCallInfo *ci = &lj_ir_callinfo[fins->op2]; + sb = ((SBuf * (*)(SBuf *, SFormat, lua_Number))ci->func)(sb, sf, + ir_knum(ira)->n); + break; + } + } + fins->o = IR_BUFPUT; + fins->op1 = irc->op1; + fins->op2 = lj_ir_kstr(J, lj_buf_tostr(sb)); + return RETRYFOLD; + } + return EMITFOLD; /* Always emit, CSE later. */ +} + +/* -- Constant folding of pointer arithmetic ------------------------------ */ + +LJFOLD(ADD KGC KINT) +LJFOLD(ADD KGC KINT64) +LJFOLDF(kfold_add_kgc) +{ + GCobj *o = ir_kgc(fleft); +#if LJ_64 + ptrdiff_t ofs = (ptrdiff_t)ir_kint64(fright)->u64; +#else + ptrdiff_t ofs = fright->i; +#endif +#if LJ_HASFFI + if (irt_iscdata(fleft->t)) { + CType *ct = ctype_raw(ctype_ctsG(J2G(J)), gco2cd(o)->ctypeid); + if (ctype_isnum(ct->info) || ctype_isenum(ct->info) || + ctype_isptr(ct->info) || ctype_isfunc(ct->info) || + ctype_iscomplex(ct->info) || ctype_isvector(ct->info)) + return lj_ir_kkptr(J, (char *)o + ofs); + } +#endif + return lj_ir_kptr(J, (char *)o + ofs); +} + +LJFOLD(ADD KPTR KINT) +LJFOLD(ADD KPTR KINT64) +LJFOLD(ADD KKPTR KINT) +LJFOLD(ADD KKPTR KINT64) +LJFOLDF(kfold_add_kptr) +{ + void *p = ir_kptr(fleft); +#if LJ_64 + ptrdiff_t ofs = (ptrdiff_t)ir_kint64(fright)->u64; +#else + ptrdiff_t ofs = fright->i; +#endif + return lj_ir_kptr_(J, fleft->o, (char *)p + ofs); +} + +LJFOLD(ADD any KGC) +LJFOLD(ADD any KPTR) +LJFOLD(ADD any KKPTR) +LJFOLDF(kfold_add_kright) +{ + if (fleft->o == IR_KINT || fleft->o == IR_KINT64) { + IRRef1 tmp = fins->op1; fins->op1 = fins->op2; fins->op2 = tmp; + return RETRYFOLD; + } + return NEXTFOLD; +} + +/* -- Constant folding of conversions ------------------------------------- */ + +LJFOLD(TOBIT KNUM KNUM) +LJFOLDF(kfold_tobit) +{ + return INTFOLD(lj_num2bit(knumleft)); +} + +LJFOLD(CONV KINT IRCONV_NUM_INT) +LJFOLDF(kfold_conv_kint_num) +{ + return lj_ir_knum(J, (lua_Number)fleft->i); +} + +LJFOLD(CONV KINT IRCONV_NUM_U32) +LJFOLDF(kfold_conv_kintu32_num) +{ + return lj_ir_knum(J, (lua_Number)(uint32_t)fleft->i); +} + +LJFOLD(CONV KINT IRCONV_INT_I8) +LJFOLD(CONV KINT IRCONV_INT_U8) +LJFOLD(CONV KINT IRCONV_INT_I16) +LJFOLD(CONV KINT IRCONV_INT_U16) +LJFOLDF(kfold_conv_kint_ext) +{ + int32_t k = fleft->i; + if ((fins->op2 & IRCONV_SRCMASK) == IRT_I8) k = (int8_t)k; + else if ((fins->op2 & IRCONV_SRCMASK) == IRT_U8) k = (uint8_t)k; + else if ((fins->op2 & IRCONV_SRCMASK) == IRT_I16) k = (int16_t)k; + else k = (uint16_t)k; + return INTFOLD(k); +} + +LJFOLD(CONV KINT IRCONV_I64_INT) +LJFOLD(CONV KINT IRCONV_U64_INT) +LJFOLD(CONV KINT IRCONV_I64_U32) +LJFOLD(CONV KINT IRCONV_U64_U32) +LJFOLDF(kfold_conv_kint_i64) +{ + if ((fins->op2 & IRCONV_SEXT)) + return INT64FOLD((uint64_t)(int64_t)fleft->i); + else + return INT64FOLD((uint64_t)(int64_t)(uint32_t)fleft->i); +} + +LJFOLD(CONV KINT64 IRCONV_NUM_I64) +LJFOLDF(kfold_conv_kint64_num_i64) +{ + return lj_ir_knum(J, (lua_Number)(int64_t)ir_kint64(fleft)->u64); +} + +LJFOLD(CONV KINT64 IRCONV_NUM_U64) +LJFOLDF(kfold_conv_kint64_num_u64) +{ + return lj_ir_knum(J, (lua_Number)ir_kint64(fleft)->u64); +} + +LJFOLD(CONV KINT64 IRCONV_INT_I64) +LJFOLD(CONV KINT64 IRCONV_U32_I64) +LJFOLDF(kfold_conv_kint64_int_i64) +{ + return INTFOLD((int32_t)ir_kint64(fleft)->u64); +} + +LJFOLD(CONV KNUM IRCONV_INT_NUM) +LJFOLDF(kfold_conv_knum_int_num) +{ + lua_Number n = knumleft; + int32_t k = lj_num2int(n); + if (irt_isguard(fins->t) && n != (lua_Number)k) { + /* We're about to create a guard which always fails, like CONV +1.5. + ** Some pathological loops cause this during LICM, e.g.: + ** local x,k,t = 0,1.5,{1,[1.5]=2} + ** for i=1,200 do x = x+ t[k]; k = k == 1 and 1.5 or 1 end + ** assert(x == 300) + */ + return FAILFOLD; + } + return INTFOLD(k); +} + +LJFOLD(CONV KNUM IRCONV_U32_NUM) +LJFOLDF(kfold_conv_knum_u32_num) +{ +#ifdef _MSC_VER + { /* Workaround for MSVC bug. */ + volatile uint32_t u = (uint32_t)knumleft; + return INTFOLD((int32_t)u); + } +#else + return INTFOLD((int32_t)(uint32_t)knumleft); +#endif +} + +LJFOLD(CONV KNUM IRCONV_I64_NUM) +LJFOLDF(kfold_conv_knum_i64_num) +{ + return INT64FOLD((uint64_t)(int64_t)knumleft); +} + +LJFOLD(CONV KNUM IRCONV_U64_NUM) +LJFOLDF(kfold_conv_knum_u64_num) +{ + return INT64FOLD(lj_num2u64(knumleft)); +} + +LJFOLD(TOSTR KNUM any) +LJFOLDF(kfold_tostr_knum) +{ + return lj_ir_kstr(J, lj_strfmt_num(J->L, ir_knum(fleft))); +} + +LJFOLD(TOSTR KINT any) +LJFOLDF(kfold_tostr_kint) +{ + return lj_ir_kstr(J, fins->op2 == IRTOSTR_INT ? + lj_strfmt_int(J->L, fleft->i) : + lj_strfmt_char(J->L, fleft->i)); +} + +LJFOLD(STRTO KGC) +LJFOLDF(kfold_strto) +{ + TValue n; + if (lj_strscan_num(ir_kstr(fleft), &n)) + return lj_ir_knum(J, numV(&n)); + return FAILFOLD; +} + +/* -- Constant folding of equality checks --------------------------------- */ + +/* Don't constant-fold away FLOAD checks against KNULL. */ +LJFOLD(EQ FLOAD KNULL) +LJFOLD(NE FLOAD KNULL) +LJFOLDX(lj_opt_cse) + +/* But fold all other KNULL compares, since only KNULL is equal to KNULL. */ +LJFOLD(EQ any KNULL) +LJFOLD(NE any KNULL) +LJFOLD(EQ KNULL any) +LJFOLD(NE KNULL any) +LJFOLD(EQ KINT KINT) /* Constants are unique, so same refs <==> same value. */ +LJFOLD(NE KINT KINT) +LJFOLD(EQ KINT64 KINT64) +LJFOLD(NE KINT64 KINT64) +LJFOLD(EQ KGC KGC) +LJFOLD(NE KGC KGC) +LJFOLDF(kfold_kref) +{ + return CONDFOLD((fins->op1 == fins->op2) ^ (fins->o == IR_NE)); +} + +/* -- Algebraic shortcuts ------------------------------------------------- */ + +LJFOLD(FPMATH FPMATH IRFPM_FLOOR) +LJFOLD(FPMATH FPMATH IRFPM_CEIL) +LJFOLD(FPMATH FPMATH IRFPM_TRUNC) +LJFOLDF(shortcut_round) +{ + IRFPMathOp op = (IRFPMathOp)fleft->op2; + if (op == IRFPM_FLOOR || op == IRFPM_CEIL || op == IRFPM_TRUNC) + return LEFTFOLD; /* round(round_left(x)) = round_left(x) */ + return NEXTFOLD; +} + +LJFOLD(ABS ABS FLOAD) +LJFOLDF(shortcut_left) +{ + return LEFTFOLD; /* f(g(x)) ==> g(x) */ +} + +LJFOLD(ABS NEG FLOAD) +LJFOLDF(shortcut_dropleft) +{ + PHIBARRIER(fleft); + fins->op1 = fleft->op1; /* abs(neg(x)) ==> abs(x) */ + return RETRYFOLD; +} + +/* Note: no safe shortcuts with STRTO and TOSTR ("1e2" ==> +100 ==> "100"). */ +LJFOLD(NEG NEG any) +LJFOLD(BNOT BNOT) +LJFOLD(BSWAP BSWAP) +LJFOLDF(shortcut_leftleft) +{ + PHIBARRIER(fleft); /* See above. Fold would be ok, but not beneficial. */ + return fleft->op1; /* f(g(x)) ==> x */ +} + +/* -- FP algebraic simplifications ---------------------------------------- */ + +/* FP arithmetic is tricky -- there's not much to simplify. +** Please note the following common pitfalls before sending "improvements": +** x+0 ==> x is INVALID for x=-0 +** 0-x ==> -x is INVALID for x=+0 +** x*0 ==> 0 is INVALID for x=-0, x=+-Inf or x=NaN +*/ + +LJFOLD(ADD NEG any) +LJFOLDF(simplify_numadd_negx) +{ + PHIBARRIER(fleft); + fins->o = IR_SUB; /* (-a) + b ==> b - a */ + fins->op1 = fins->op2; + fins->op2 = fleft->op1; + return RETRYFOLD; +} + +LJFOLD(ADD any NEG) +LJFOLDF(simplify_numadd_xneg) +{ + PHIBARRIER(fright); + fins->o = IR_SUB; /* a + (-b) ==> a - b */ + fins->op2 = fright->op1; + return RETRYFOLD; +} + +LJFOLD(SUB any KNUM) +LJFOLDF(simplify_numsub_k) +{ + if (ir_knum(fright)->u64 == 0) /* x - (+0) ==> x */ + return LEFTFOLD; + return NEXTFOLD; +} + +LJFOLD(SUB NEG KNUM) +LJFOLDF(simplify_numsub_negk) +{ + PHIBARRIER(fleft); + fins->op2 = fleft->op1; /* (-x) - k ==> (-k) - x */ + fins->op1 = (IRRef1)lj_ir_knum(J, -knumright); + return RETRYFOLD; +} + +LJFOLD(SUB any NEG) +LJFOLDF(simplify_numsub_xneg) +{ + PHIBARRIER(fright); + fins->o = IR_ADD; /* a - (-b) ==> a + b */ + fins->op2 = fright->op1; + return RETRYFOLD; +} + +LJFOLD(MUL any KNUM) +LJFOLD(DIV any KNUM) +LJFOLDF(simplify_nummuldiv_k) +{ + lua_Number n = knumright; + if (n == 1.0) { /* x o 1 ==> x */ + return LEFTFOLD; + } else if (n == -1.0) { /* x o -1 ==> -x */ + IRRef op1 = fins->op1; + fins->op2 = (IRRef1)lj_ir_ksimd(J, LJ_KSIMD_NEG); /* Modifies fins. */ + fins->op1 = op1; + fins->o = IR_NEG; + return RETRYFOLD; + } else if (fins->o == IR_MUL && n == 2.0) { /* x * 2 ==> x + x */ + fins->o = IR_ADD; + fins->op2 = fins->op1; + return RETRYFOLD; + } else if (fins->o == IR_DIV) { /* x / 2^k ==> x * 2^-k */ + uint64_t u = ir_knum(fright)->u64; + uint32_t ex = ((uint32_t)(u >> 52) & 0x7ff); + if ((u & U64x(000fffff,ffffffff)) == 0 && ex - 1 < 0x7fd) { + u = (u & ((uint64_t)1 << 63)) | ((uint64_t)(0x7fe - ex) << 52); + fins->o = IR_MUL; /* Multiply by exact reciprocal. */ + fins->op2 = lj_ir_knum_u64(J, u); + return RETRYFOLD; + } + } + return NEXTFOLD; +} + +LJFOLD(MUL NEG KNUM) +LJFOLD(DIV NEG KNUM) +LJFOLDF(simplify_nummuldiv_negk) +{ + PHIBARRIER(fleft); + fins->op1 = fleft->op1; /* (-a) o k ==> a o (-k) */ + fins->op2 = (IRRef1)lj_ir_knum(J, -knumright); + return RETRYFOLD; +} + +LJFOLD(MUL NEG NEG) +LJFOLD(DIV NEG NEG) +LJFOLDF(simplify_nummuldiv_negneg) +{ + PHIBARRIER(fleft); + PHIBARRIER(fright); + fins->op1 = fleft->op1; /* (-a) o (-b) ==> a o b */ + fins->op2 = fright->op1; + return RETRYFOLD; +} + +LJFOLD(POW any KNUM) +LJFOLDF(simplify_numpow_k) +{ + if (knumright == 0.0) /* x ^ 0 ==> 1 */ + return lj_ir_knum_one(J); /* Result must be a number, not an int. */ + else if (knumright == 1.0) /* x ^ 1 ==> x */ + return LEFTFOLD; + else if (knumright == 2.0) /* x ^ 2 ==> x * x */ + return emitir(IRTN(IR_MUL), fins->op1, fins->op1); + else + return NEXTFOLD; +} + +/* -- Simplify conversions ------------------------------------------------ */ + +LJFOLD(CONV CONV IRCONV_NUM_INT) /* _NUM */ +LJFOLDF(shortcut_conv_num_int) +{ + PHIBARRIER(fleft); + /* Only safe with a guarded conversion to int. */ + if ((fleft->op2 & IRCONV_SRCMASK) == IRT_NUM && irt_isguard(fleft->t)) + return fleft->op1; /* f(g(x)) ==> x */ + return NEXTFOLD; +} + +LJFOLD(CONV CONV IRCONV_INT_NUM) /* _INT */ +LJFOLD(CONV CONV IRCONV_U32_NUM) /* _U32*/ +LJFOLDF(simplify_conv_int_num) +{ + /* Fold even across PHI to avoid expensive num->int conversions in loop. */ + if ((fleft->op2 & IRCONV_SRCMASK) == + ((fins->op2 & IRCONV_DSTMASK) >> IRCONV_DSH)) + return fleft->op1; + return NEXTFOLD; +} + +LJFOLD(CONV CONV IRCONV_I64_NUM) /* _INT or _U32 */ +LJFOLD(CONV CONV IRCONV_U64_NUM) /* _INT or _U32 */ +LJFOLDF(simplify_conv_i64_num) +{ + PHIBARRIER(fleft); + if ((fleft->op2 & IRCONV_SRCMASK) == IRT_INT) { + /* Reduce to a sign-extension. */ + fins->op1 = fleft->op1; + fins->op2 = ((IRT_I64<<5)|IRT_INT|IRCONV_SEXT); + return RETRYFOLD; + } else if ((fleft->op2 & IRCONV_SRCMASK) == IRT_U32) { +#if LJ_TARGET_X64 + return fleft->op1; +#else + /* Reduce to a zero-extension. */ + fins->op1 = fleft->op1; + fins->op2 = (IRT_I64<<5)|IRT_U32; + return RETRYFOLD; +#endif + } + return NEXTFOLD; +} + +LJFOLD(CONV CONV IRCONV_INT_I64) /* _INT or _U32 */ +LJFOLD(CONV CONV IRCONV_INT_U64) /* _INT or _U32 */ +LJFOLD(CONV CONV IRCONV_U32_I64) /* _INT or _U32 */ +LJFOLD(CONV CONV IRCONV_U32_U64) /* _INT or _U32 */ +LJFOLDF(simplify_conv_int_i64) +{ + int src; + PHIBARRIER(fleft); + src = (fleft->op2 & IRCONV_SRCMASK); + if (src == IRT_INT || src == IRT_U32) { + if (src == ((fins->op2 & IRCONV_DSTMASK) >> IRCONV_DSH)) { + return fleft->op1; + } else { + fins->op2 = ((fins->op2 & IRCONV_DSTMASK) | src); + fins->op1 = fleft->op1; + return RETRYFOLD; + } + } + return NEXTFOLD; +} + +LJFOLD(CONV CONV IRCONV_FLOAT_NUM) /* _FLOAT */ +LJFOLDF(simplify_conv_flt_num) +{ + PHIBARRIER(fleft); + if ((fleft->op2 & IRCONV_SRCMASK) == IRT_FLOAT) + return fleft->op1; + return NEXTFOLD; +} + +/* Shortcut TOBIT + IRT_NUM <- IRT_INT/IRT_U32 conversion. */ +LJFOLD(TOBIT CONV KNUM) +LJFOLDF(simplify_tobit_conv) +{ + /* Fold even across PHI to avoid expensive num->int conversions in loop. */ + if ((fleft->op2 & IRCONV_SRCMASK) == IRT_INT) { + lj_assertJ(irt_isnum(fleft->t), "expected TOBIT number arg"); + return fleft->op1; + } else if ((fleft->op2 & IRCONV_SRCMASK) == IRT_U32) { + lj_assertJ(irt_isnum(fleft->t), "expected TOBIT number arg"); + fins->o = IR_CONV; + fins->op1 = fleft->op1; + fins->op2 = (IRT_INT<<5)|IRT_U32; + return RETRYFOLD; + } + return NEXTFOLD; +} + +/* Shortcut floor/ceil/round + IRT_NUM <- IRT_INT/IRT_U32 conversion. */ +LJFOLD(FPMATH CONV IRFPM_FLOOR) +LJFOLD(FPMATH CONV IRFPM_CEIL) +LJFOLD(FPMATH CONV IRFPM_TRUNC) +LJFOLDF(simplify_floor_conv) +{ + if ((fleft->op2 & IRCONV_SRCMASK) == IRT_INT || + (fleft->op2 & IRCONV_SRCMASK) == IRT_U32) + return LEFTFOLD; + return NEXTFOLD; +} + +/* Strength reduction of widening. */ +LJFOLD(CONV any IRCONV_I64_INT) +LJFOLD(CONV any IRCONV_U64_INT) +LJFOLDF(simplify_conv_sext) +{ + IRRef ref = fins->op1; + int64_t ofs = 0; + if (!(fins->op2 & IRCONV_SEXT)) + return NEXTFOLD; + PHIBARRIER(fleft); + if (fleft->o == IR_XLOAD && (irt_isu8(fleft->t) || irt_isu16(fleft->t))) + goto ok_reduce; + if (fleft->o == IR_ADD && irref_isk(fleft->op2)) { + ofs = (int64_t)IR(fleft->op2)->i; + ref = fleft->op1; + } + /* Use scalar evolution analysis results to strength-reduce sign-extension. */ + if (ref == J->scev.idx) { + IRRef lo = J->scev.dir ? J->scev.start : J->scev.stop; + lj_assertJ(irt_isint(J->scev.t), "only int SCEV supported"); + if (lo && IR(lo)->o == IR_KINT && IR(lo)->i + ofs >= 0) { + ok_reduce: +#if LJ_TARGET_X64 + /* Eliminate widening. All 32 bit ops do an implicit zero-extension. */ + return LEFTFOLD; +#else + /* Reduce to a (cheaper) zero-extension. */ + fins->op2 &= ~IRCONV_SEXT; + return RETRYFOLD; +#endif + } + } + return NEXTFOLD; +} + +/* Strength reduction of narrowing. */ +LJFOLD(CONV ADD IRCONV_INT_I64) +LJFOLD(CONV SUB IRCONV_INT_I64) +LJFOLD(CONV MUL IRCONV_INT_I64) +LJFOLD(CONV ADD IRCONV_INT_U64) +LJFOLD(CONV SUB IRCONV_INT_U64) +LJFOLD(CONV MUL IRCONV_INT_U64) +LJFOLD(CONV ADD IRCONV_U32_I64) +LJFOLD(CONV SUB IRCONV_U32_I64) +LJFOLD(CONV MUL IRCONV_U32_I64) +LJFOLD(CONV ADD IRCONV_U32_U64) +LJFOLD(CONV SUB IRCONV_U32_U64) +LJFOLD(CONV MUL IRCONV_U32_U64) +LJFOLDF(simplify_conv_narrow) +{ +#if LJ_64 + UNUSED(J); + return NEXTFOLD; +#else + IROp op = (IROp)fleft->o; + IRType t = irt_type(fins->t); + IRRef op1 = fleft->op1, op2 = fleft->op2, mode = fins->op2; + PHIBARRIER(fleft); + op1 = emitir(IRT(IR_CONV, t), op1, mode); + op2 = emitir(IRT(IR_CONV, t), op2, mode); + fins->ot = IRT(op, t); + fins->op1 = op1; + fins->op2 = op2; + return RETRYFOLD; +#endif +} + +/* Special CSE rule for CONV. */ +LJFOLD(CONV any any) +LJFOLDF(cse_conv) +{ + if (LJ_LIKELY(J->flags & JIT_F_OPT_CSE)) { + IRRef op1 = fins->op1, op2 = (fins->op2 & IRCONV_MODEMASK); + uint8_t guard = irt_isguard(fins->t); + IRRef ref = J->chain[IR_CONV]; + while (ref > op1) { + IRIns *ir = IR(ref); + /* Commoning with stronger checks is ok. */ + if (ir->op1 == op1 && (ir->op2 & IRCONV_MODEMASK) == op2 && + irt_isguard(ir->t) >= guard) + return ref; + ref = ir->prev; + } + } + return EMITFOLD; /* No fallthrough to regular CSE. */ +} + +/* FP conversion narrowing. */ +LJFOLD(TOBIT ADD KNUM) +LJFOLD(TOBIT SUB KNUM) +LJFOLD(CONV ADD IRCONV_INT_NUM) +LJFOLD(CONV SUB IRCONV_INT_NUM) +LJFOLD(CONV ADD IRCONV_I64_NUM) +LJFOLD(CONV SUB IRCONV_I64_NUM) +LJFOLDF(narrow_convert) +{ + PHIBARRIER(fleft); + /* Narrowing ignores PHIs and repeating it inside the loop is not useful. */ + if (J->chain[IR_LOOP]) + return NEXTFOLD; + lj_assertJ(fins->o != IR_CONV || (fins->op2&IRCONV_CONVMASK) != IRCONV_TOBIT, + "unexpected CONV TOBIT"); + return lj_opt_narrow_convert(J); +} + +/* -- Integer algebraic simplifications ----------------------------------- */ + +LJFOLD(ADD any KINT) +LJFOLD(ADDOV any KINT) +LJFOLD(SUBOV any KINT) +LJFOLDF(simplify_intadd_k) +{ + if (fright->i == 0) /* i o 0 ==> i */ + return LEFTFOLD; + return NEXTFOLD; +} + +LJFOLD(MULOV any KINT) +LJFOLDF(simplify_intmul_k) +{ + if (fright->i == 0) /* i * 0 ==> 0 */ + return RIGHTFOLD; + if (fright->i == 1) /* i * 1 ==> i */ + return LEFTFOLD; + if (fright->i == 2) { /* i * 2 ==> i + i */ + fins->o = IR_ADDOV; + fins->op2 = fins->op1; + return RETRYFOLD; + } + return NEXTFOLD; +} + +LJFOLD(SUB any KINT) +LJFOLDF(simplify_intsub_k) +{ + if (fright->i == 0) /* i - 0 ==> i */ + return LEFTFOLD; + fins->o = IR_ADD; /* i - k ==> i + (-k) */ + fins->op2 = (IRRef1)lj_ir_kint(J, -fright->i); /* Overflow for -2^31 ok. */ + return RETRYFOLD; +} + +LJFOLD(SUB KINT any) +LJFOLD(SUB KINT64 any) +LJFOLDF(simplify_intsub_kleft) +{ + if (fleft->o == IR_KINT ? (fleft->i == 0) : (ir_kint64(fleft)->u64 == 0)) { + fins->o = IR_NEG; /* 0 - i ==> -i */ + fins->op1 = fins->op2; + return RETRYFOLD; + } + return NEXTFOLD; +} + +LJFOLD(ADD any KINT64) +LJFOLDF(simplify_intadd_k64) +{ + if (ir_kint64(fright)->u64 == 0) /* i + 0 ==> i */ + return LEFTFOLD; + return NEXTFOLD; +} + +LJFOLD(SUB any KINT64) +LJFOLDF(simplify_intsub_k64) +{ + uint64_t k = ir_kint64(fright)->u64; + if (k == 0) /* i - 0 ==> i */ + return LEFTFOLD; + fins->o = IR_ADD; /* i - k ==> i + (-k) */ + fins->op2 = (IRRef1)lj_ir_kint64(J, (uint64_t)-(int64_t)k); + return RETRYFOLD; +} + +static TRef simplify_intmul_k(jit_State *J, int32_t k) +{ + /* Note: many more simplifications are possible, e.g. 2^k1 +- 2^k2. + ** But this is mainly intended for simple address arithmetic. + ** Also it's easier for the backend to optimize the original multiplies. + */ + if (k == 0) { /* i * 0 ==> 0 */ + return RIGHTFOLD; + } else if (k == 1) { /* i * 1 ==> i */ + return LEFTFOLD; + } else if ((k & (k-1)) == 0) { /* i * 2^k ==> i << k */ + fins->o = IR_BSHL; + fins->op2 = lj_ir_kint(J, lj_fls((uint32_t)k)); + return RETRYFOLD; + } + return NEXTFOLD; +} + +LJFOLD(MUL any KINT) +LJFOLDF(simplify_intmul_k32) +{ + if (fright->i >= 0) + return simplify_intmul_k(J, fright->i); + return NEXTFOLD; +} + +LJFOLD(MUL any KINT64) +LJFOLDF(simplify_intmul_k64) +{ +#if LJ_HASFFI + if (ir_kint64(fright)->u64 < 0x80000000u) + return simplify_intmul_k(J, (int32_t)ir_kint64(fright)->u64); + return NEXTFOLD; +#else + UNUSED(J); lj_assertJ(0, "FFI IR op without FFI"); return FAILFOLD; +#endif +} + +LJFOLD(MOD any KINT) +LJFOLDF(simplify_intmod_k) +{ + int32_t k = fright->i; + lj_assertJ(k != 0, "integer mod 0"); + if (k > 0 && (k & (k-1)) == 0) { /* i % (2^k) ==> i & (2^k-1) */ + fins->o = IR_BAND; + fins->op2 = lj_ir_kint(J, k-1); + return RETRYFOLD; + } + return NEXTFOLD; +} + +LJFOLD(MOD KINT any) +LJFOLDF(simplify_intmod_kleft) +{ + if (fleft->i == 0) + return INTFOLD(0); + return NEXTFOLD; +} + +LJFOLD(SUB any any) +LJFOLD(SUBOV any any) +LJFOLDF(simplify_intsub) +{ + if (fins->op1 == fins->op2 && !irt_isnum(fins->t)) /* i - i ==> 0 */ + return irt_is64(fins->t) ? INT64FOLD(0) : INTFOLD(0); + return NEXTFOLD; +} + +LJFOLD(SUB ADD any) +LJFOLDF(simplify_intsubadd_leftcancel) +{ + if (!irt_isnum(fins->t)) { + PHIBARRIER(fleft); + if (fins->op2 == fleft->op1) /* (i + j) - i ==> j */ + return fleft->op2; + if (fins->op2 == fleft->op2) /* (i + j) - j ==> i */ + return fleft->op1; + } + return NEXTFOLD; +} + +LJFOLD(SUB SUB any) +LJFOLDF(simplify_intsubsub_leftcancel) +{ + if (!irt_isnum(fins->t)) { + PHIBARRIER(fleft); + if (fins->op2 == fleft->op1) { /* (i - j) - i ==> 0 - j */ + fins->op1 = (IRRef1)lj_ir_kint(J, 0); + fins->op2 = fleft->op2; + return RETRYFOLD; + } + } + return NEXTFOLD; +} + +LJFOLD(SUB any SUB) +LJFOLDF(simplify_intsubsub_rightcancel) +{ + if (!irt_isnum(fins->t)) { + PHIBARRIER(fright); + if (fins->op1 == fright->op1) /* i - (i - j) ==> j */ + return fright->op2; + } + return NEXTFOLD; +} + +LJFOLD(SUB any ADD) +LJFOLDF(simplify_intsubadd_rightcancel) +{ + if (!irt_isnum(fins->t)) { + PHIBARRIER(fright); + if (fins->op1 == fright->op1) { /* i - (i + j) ==> 0 - j */ + fins->op2 = fright->op2; + fins->op1 = (IRRef1)lj_ir_kint(J, 0); + return RETRYFOLD; + } + if (fins->op1 == fright->op2) { /* i - (j + i) ==> 0 - j */ + fins->op2 = fright->op1; + fins->op1 = (IRRef1)lj_ir_kint(J, 0); + return RETRYFOLD; + } + } + return NEXTFOLD; +} + +LJFOLD(SUB ADD ADD) +LJFOLDF(simplify_intsubaddadd_cancel) +{ + if (!irt_isnum(fins->t)) { + PHIBARRIER(fleft); + PHIBARRIER(fright); + if (fleft->op1 == fright->op1) { /* (i + j1) - (i + j2) ==> j1 - j2 */ + fins->op1 = fleft->op2; + fins->op2 = fright->op2; + return RETRYFOLD; + } + if (fleft->op1 == fright->op2) { /* (i + j1) - (j2 + i) ==> j1 - j2 */ + fins->op1 = fleft->op2; + fins->op2 = fright->op1; + return RETRYFOLD; + } + if (fleft->op2 == fright->op1) { /* (j1 + i) - (i + j2) ==> j1 - j2 */ + fins->op1 = fleft->op1; + fins->op2 = fright->op2; + return RETRYFOLD; + } + if (fleft->op2 == fright->op2) { /* (j1 + i) - (j2 + i) ==> j1 - j2 */ + fins->op1 = fleft->op1; + fins->op2 = fright->op1; + return RETRYFOLD; + } + } + return NEXTFOLD; +} + +LJFOLD(BAND any KINT) +LJFOLD(BAND any KINT64) +LJFOLDF(simplify_band_k) +{ + int64_t k = fright->o == IR_KINT ? (int64_t)fright->i : + (int64_t)ir_k64(fright)->u64; + if (k == 0) /* i & 0 ==> 0 */ + return RIGHTFOLD; + if (k == -1) /* i & -1 ==> i */ + return LEFTFOLD; + return NEXTFOLD; +} + +LJFOLD(BOR any KINT) +LJFOLD(BOR any KINT64) +LJFOLDF(simplify_bor_k) +{ + int64_t k = fright->o == IR_KINT ? (int64_t)fright->i : + (int64_t)ir_k64(fright)->u64; + if (k == 0) /* i | 0 ==> i */ + return LEFTFOLD; + if (k == -1) /* i | -1 ==> -1 */ + return RIGHTFOLD; + return NEXTFOLD; +} + +LJFOLD(BXOR any KINT) +LJFOLD(BXOR any KINT64) +LJFOLDF(simplify_bxor_k) +{ + int64_t k = fright->o == IR_KINT ? (int64_t)fright->i : + (int64_t)ir_k64(fright)->u64; + if (k == 0) /* i xor 0 ==> i */ + return LEFTFOLD; + if (k == -1) { /* i xor -1 ==> ~i */ + fins->o = IR_BNOT; + fins->op2 = 0; + return RETRYFOLD; + } + return NEXTFOLD; +} + +LJFOLD(BSHL any KINT) +LJFOLD(BSHR any KINT) +LJFOLD(BSAR any KINT) +LJFOLD(BROL any KINT) +LJFOLD(BROR any KINT) +LJFOLDF(simplify_shift_ik) +{ + int32_t mask = irt_is64(fins->t) ? 63 : 31; + int32_t k = (fright->i & mask); + if (k == 0) /* i o 0 ==> i */ + return LEFTFOLD; + if (k == 1 && fins->o == IR_BSHL) { /* i << 1 ==> i + i */ + fins->o = IR_ADD; + fins->op2 = fins->op1; + return RETRYFOLD; + } + if (k != fright->i) { /* i o k ==> i o (k & mask) */ + fins->op2 = (IRRef1)lj_ir_kint(J, k); + return RETRYFOLD; + } +#ifndef LJ_TARGET_UNIFYROT + if (fins->o == IR_BROR) { /* bror(i, k) ==> brol(i, (-k)&mask) */ + fins->o = IR_BROL; + fins->op2 = (IRRef1)lj_ir_kint(J, (-k)&mask); + return RETRYFOLD; + } +#endif + return NEXTFOLD; +} + +LJFOLD(BSHL any BAND) +LJFOLD(BSHR any BAND) +LJFOLD(BSAR any BAND) +LJFOLD(BROL any BAND) +LJFOLD(BROR any BAND) +LJFOLDF(simplify_shift_andk) +{ + IRIns *irk = IR(fright->op2); + PHIBARRIER(fright); + if ((fins->o < IR_BROL ? LJ_TARGET_MASKSHIFT : LJ_TARGET_MASKROT) && + irk->o == IR_KINT) { /* i o (j & mask) ==> i o j */ + int32_t mask = irt_is64(fins->t) ? 63 : 31; + int32_t k = irk->i & mask; + if (k == mask) { + fins->op2 = fright->op1; + return RETRYFOLD; + } + } + return NEXTFOLD; +} + +LJFOLD(BSHL KINT any) +LJFOLD(BSHR KINT any) +LJFOLD(BSHL KINT64 any) +LJFOLD(BSHR KINT64 any) +LJFOLDF(simplify_shift1_ki) +{ + int64_t k = fleft->o == IR_KINT ? (int64_t)fleft->i : + (int64_t)ir_k64(fleft)->u64; + if (k == 0) /* 0 o i ==> 0 */ + return LEFTFOLD; + return NEXTFOLD; +} + +LJFOLD(BSAR KINT any) +LJFOLD(BROL KINT any) +LJFOLD(BROR KINT any) +LJFOLD(BSAR KINT64 any) +LJFOLD(BROL KINT64 any) +LJFOLD(BROR KINT64 any) +LJFOLDF(simplify_shift2_ki) +{ + int64_t k = fleft->o == IR_KINT ? (int64_t)fleft->i : + (int64_t)ir_k64(fleft)->u64; + if (k == 0 || k == -1) /* 0 o i ==> 0; -1 o i ==> -1 */ + return LEFTFOLD; + return NEXTFOLD; +} + +LJFOLD(BSHL BAND KINT) +LJFOLD(BSHR BAND KINT) +LJFOLD(BROL BAND KINT) +LJFOLD(BROR BAND KINT) +LJFOLDF(simplify_shiftk_andk) +{ + IRIns *irk = IR(fleft->op2); + PHIBARRIER(fleft); + if (irk->o == IR_KINT) { /* (i & k1) o k2 ==> (i o k2) & (k1 o k2) */ + int32_t k = kfold_intop(irk->i, fright->i, (IROp)fins->o); + fins->op1 = fleft->op1; + fins->op1 = (IRRef1)lj_opt_fold(J); + fins->op2 = (IRRef1)lj_ir_kint(J, k); + fins->ot = IRTI(IR_BAND); + return RETRYFOLD; + } else if (irk->o == IR_KINT64) { + uint64_t k = kfold_int64arith(J, ir_k64(irk)->u64, fright->i, + (IROp)fins->o); + IROpT ot = fleft->ot; + fins->op1 = fleft->op1; + fins->op1 = (IRRef1)lj_opt_fold(J); + fins->op2 = (IRRef1)lj_ir_kint64(J, k); + fins->ot = ot; + return RETRYFOLD; + } + return NEXTFOLD; +} + +LJFOLD(BAND BSHL KINT) +LJFOLD(BAND BSHR KINT) +LJFOLDF(simplify_andk_shiftk) +{ + IRIns *irk = IR(fleft->op2); + if (irk->o == IR_KINT && + kfold_intop(-1, irk->i, (IROp)fleft->o) == fright->i) + return LEFTFOLD; /* (i o k1) & k2 ==> i, if (-1 o k1) == k2 */ + return NEXTFOLD; +} + +LJFOLD(BAND BOR KINT) +LJFOLD(BOR BAND KINT) +LJFOLDF(simplify_andor_k) +{ + IRIns *irk = IR(fleft->op2); + PHIBARRIER(fleft); + if (irk->o == IR_KINT) { + int32_t k = kfold_intop(irk->i, fright->i, (IROp)fins->o); + /* (i | k1) & k2 ==> i & k2, if (k1 & k2) == 0. */ + /* (i & k1) | k2 ==> i | k2, if (k1 | k2) == -1. */ + if (k == (fins->o == IR_BAND ? 0 : -1)) { + fins->op1 = fleft->op1; + return RETRYFOLD; + } + } + return NEXTFOLD; +} + +LJFOLD(BAND BOR KINT64) +LJFOLD(BOR BAND KINT64) +LJFOLDF(simplify_andor_k64) +{ +#if LJ_HASFFI + IRIns *irk = IR(fleft->op2); + PHIBARRIER(fleft); + if (irk->o == IR_KINT64) { + uint64_t k = kfold_int64arith(J, ir_k64(irk)->u64, ir_k64(fright)->u64, + (IROp)fins->o); + /* (i | k1) & k2 ==> i & k2, if (k1 & k2) == 0. */ + /* (i & k1) | k2 ==> i | k2, if (k1 | k2) == -1. */ + if (k == (fins->o == IR_BAND ? (uint64_t)0 : ~(uint64_t)0)) { + fins->op1 = fleft->op1; + return RETRYFOLD; + } + } + return NEXTFOLD; +#else + UNUSED(J); lj_assertJ(0, "FFI IR op without FFI"); return FAILFOLD; +#endif +} + +/* -- Reassociation ------------------------------------------------------- */ + +LJFOLD(ADD ADD KINT) +LJFOLD(MUL MUL KINT) +LJFOLD(BAND BAND KINT) +LJFOLD(BOR BOR KINT) +LJFOLD(BXOR BXOR KINT) +LJFOLDF(reassoc_intarith_k) +{ + IRIns *irk = IR(fleft->op2); + if (irk->o == IR_KINT) { + int32_t k = kfold_intop(irk->i, fright->i, (IROp)fins->o); + if (k == irk->i) /* (i o k1) o k2 ==> i o k1, if (k1 o k2) == k1. */ + return LEFTFOLD; + PHIBARRIER(fleft); + fins->op1 = fleft->op1; + fins->op2 = (IRRef1)lj_ir_kint(J, k); + return RETRYFOLD; /* (i o k1) o k2 ==> i o (k1 o k2) */ + } + return NEXTFOLD; +} + +LJFOLD(ADD ADD KINT64) +LJFOLD(MUL MUL KINT64) +LJFOLD(BAND BAND KINT64) +LJFOLD(BOR BOR KINT64) +LJFOLD(BXOR BXOR KINT64) +LJFOLDF(reassoc_intarith_k64) +{ +#if LJ_HASFFI + IRIns *irk = IR(fleft->op2); + if (irk->o == IR_KINT64) { + uint64_t k = kfold_int64arith(J, ir_k64(irk)->u64, ir_k64(fright)->u64, + (IROp)fins->o); + PHIBARRIER(fleft); + fins->op1 = fleft->op1; + fins->op2 = (IRRef1)lj_ir_kint64(J, k); + return RETRYFOLD; /* (i o k1) o k2 ==> i o (k1 o k2) */ + } + return NEXTFOLD; +#else + UNUSED(J); lj_assertJ(0, "FFI IR op without FFI"); return FAILFOLD; +#endif +} + +LJFOLD(BAND BAND any) +LJFOLD(BOR BOR any) +LJFOLDF(reassoc_dup) +{ + if (fins->op2 == fleft->op1 || fins->op2 == fleft->op2) + return LEFTFOLD; /* (a o b) o a ==> a o b; (a o b) o b ==> a o b */ + return NEXTFOLD; +} + +LJFOLD(MIN MIN any) +LJFOLD(MAX MAX any) +LJFOLDF(reassoc_dup_minmax) +{ + if (fins->op2 == fleft->op2) + return LEFTFOLD; /* (a o b) o b ==> a o b */ + return NEXTFOLD; +} + +LJFOLD(BXOR BXOR any) +LJFOLDF(reassoc_bxor) +{ + PHIBARRIER(fleft); + if (fins->op2 == fleft->op1) /* (a xor b) xor a ==> b */ + return fleft->op2; + if (fins->op2 == fleft->op2) /* (a xor b) xor b ==> a */ + return fleft->op1; + return NEXTFOLD; +} + +LJFOLD(BSHL BSHL KINT) +LJFOLD(BSHR BSHR KINT) +LJFOLD(BSAR BSAR KINT) +LJFOLD(BROL BROL KINT) +LJFOLD(BROR BROR KINT) +LJFOLDF(reassoc_shift) +{ + IRIns *irk = IR(fleft->op2); + PHIBARRIER(fleft); /* The (shift any KINT) rule covers k2 == 0 and more. */ + if (irk->o == IR_KINT) { /* (i o k1) o k2 ==> i o (k1 + k2) */ + int32_t mask = irt_is64(fins->t) ? 63 : 31; + int32_t k = (irk->i & mask) + (fright->i & mask); + if (k > mask) { /* Combined shift too wide? */ + if (fins->o == IR_BSHL || fins->o == IR_BSHR) + return mask == 31 ? INTFOLD(0) : INT64FOLD(0); + else if (fins->o == IR_BSAR) + k = mask; + else + k &= mask; + } + fins->op1 = fleft->op1; + fins->op2 = (IRRef1)lj_ir_kint(J, k); + return RETRYFOLD; + } + return NEXTFOLD; +} + +LJFOLD(MIN MIN KINT) +LJFOLD(MAX MAX KINT) +LJFOLDF(reassoc_minmax_k) +{ + IRIns *irk = IR(fleft->op2); + if (irk->o == IR_KINT) { + int32_t a = irk->i; + int32_t y = kfold_intop(a, fright->i, fins->o); + if (a == y) /* (x o k1) o k2 ==> x o k1, if (k1 o k2) == k1. */ + return LEFTFOLD; + PHIBARRIER(fleft); + fins->op1 = fleft->op1; + fins->op2 = (IRRef1)lj_ir_kint(J, y); + return RETRYFOLD; /* (x o k1) o k2 ==> x o (k1 o k2) */ + } + return NEXTFOLD; +} + +/* -- Array bounds check elimination -------------------------------------- */ + +/* Eliminate ABC across PHIs to handle t[i-1] forwarding case. +** ABC(asize, (i+k)+(-k)) ==> ABC(asize, i), but only if it already exists. +** Could be generalized to (i+k1)+k2 ==> i+(k1+k2), but needs better disambig. +*/ +LJFOLD(ABC any ADD) +LJFOLDF(abc_fwd) +{ + if (LJ_LIKELY(J->flags & JIT_F_OPT_ABC)) { + if (irref_isk(fright->op2)) { + IRIns *add2 = IR(fright->op1); + if (add2->o == IR_ADD && irref_isk(add2->op2) && + IR(fright->op2)->i == -IR(add2->op2)->i) { + IRRef ref = J->chain[IR_ABC]; + IRRef lim = add2->op1; + if (fins->op1 > lim) lim = fins->op1; + while (ref > lim) { + IRIns *ir = IR(ref); + if (ir->op1 == fins->op1 && ir->op2 == add2->op1) + return DROPFOLD; + ref = ir->prev; + } + } + } + } + return NEXTFOLD; +} + +/* Eliminate ABC for constants. +** ABC(asize, k1), ABC(asize k2) ==> ABC(asize, max(k1, k2)) +** Drop second ABC if k2 is lower. Otherwise patch first ABC with k2. +*/ +LJFOLD(ABC any KINT) +LJFOLDF(abc_k) +{ + PHIBARRIER(fleft); + if (LJ_LIKELY(J->flags & JIT_F_OPT_ABC)) { + IRRef ref = J->chain[IR_ABC]; + IRRef asize = fins->op1; + while (ref > asize) { + IRIns *ir = IR(ref); + if (ir->op1 == asize && irref_isk(ir->op2)) { + uint32_t k = (uint32_t)IR(ir->op2)->i; + if ((uint32_t)fright->i > k) + ir->op2 = fins->op2; + return DROPFOLD; + } + ref = ir->prev; + } + return EMITFOLD; /* Already performed CSE. */ + } + return NEXTFOLD; +} + +/* Eliminate invariant ABC inside loop. */ +LJFOLD(ABC any any) +LJFOLDF(abc_invar) +{ + /* Invariant ABC marked as PTR. Drop if op1 is invariant, too. */ + if (!irt_isint(fins->t) && fins->op1 < J->chain[IR_LOOP] && + !irt_isphi(IR(fins->op1)->t)) + return DROPFOLD; + return NEXTFOLD; +} + +/* -- Commutativity ------------------------------------------------------- */ + +/* The refs of commutative ops are canonicalized. Lower refs go to the right. +** Rationale behind this: +** - It (also) moves constants to the right. +** - It reduces the number of FOLD rules (e.g. (BOR any KINT) suffices). +** - It helps CSE to find more matches. +** - The assembler generates better code with constants at the right. +*/ + +LJFOLD(ADD any any) +LJFOLD(MUL any any) +LJFOLD(ADDOV any any) +LJFOLD(MULOV any any) +LJFOLDF(comm_swap) +{ + if (fins->op1 < fins->op2) { /* Move lower ref to the right. */ + IRRef1 tmp = fins->op1; + fins->op1 = fins->op2; + fins->op2 = tmp; + return RETRYFOLD; + } + return NEXTFOLD; +} + +LJFOLD(EQ any any) +LJFOLD(NE any any) +LJFOLDF(comm_equal) +{ + /* For non-numbers only: x == x ==> drop; x ~= x ==> fail */ + if (fins->op1 == fins->op2 && !irt_isnum(fins->t)) + return CONDFOLD(fins->o == IR_EQ); + return fold_comm_swap(J); +} + +LJFOLD(LT any any) +LJFOLD(GE any any) +LJFOLD(LE any any) +LJFOLD(GT any any) +LJFOLD(ULT any any) +LJFOLD(UGE any any) +LJFOLD(ULE any any) +LJFOLD(UGT any any) +LJFOLDF(comm_comp) +{ + /* For non-numbers only: x <=> x ==> drop; x <> x ==> fail */ + if (fins->op1 == fins->op2 && !irt_isnum(fins->t)) + return CONDFOLD((fins->o ^ (fins->o >> 1)) & 1); + if (fins->op1 < fins->op2) { /* Move lower ref to the right. */ + IRRef1 tmp = fins->op1; + fins->op1 = fins->op2; + fins->op2 = tmp; + fins->o ^= 3; /* GT <-> LT, GE <-> LE, does not affect U */ + return RETRYFOLD; + } + return NEXTFOLD; +} + +LJFOLD(BAND any any) +LJFOLD(BOR any any) +LJFOLDF(comm_dup) +{ + if (fins->op1 == fins->op2) /* x o x ==> x */ + return LEFTFOLD; + return fold_comm_swap(J); +} + +LJFOLD(MIN any any) +LJFOLD(MAX any any) +LJFOLDF(comm_dup_minmax) +{ + if (fins->op1 == fins->op2) /* x o x ==> x */ + return LEFTFOLD; + return NEXTFOLD; +} + +LJFOLD(BXOR any any) +LJFOLDF(comm_bxor) +{ + if (fins->op1 == fins->op2) /* i xor i ==> 0 */ + return irt_is64(fins->t) ? INT64FOLD(0) : INTFOLD(0); + return fold_comm_swap(J); +} + +/* -- Simplification of compound expressions ------------------------------ */ + +static TRef kfold_xload(jit_State *J, IRIns *ir, const void *p) +{ + int32_t k; + switch (irt_type(ir->t)) { + case IRT_NUM: return lj_ir_knum_u64(J, *(uint64_t *)p); + case IRT_I8: k = (int32_t)*(int8_t *)p; break; + case IRT_U8: k = (int32_t)*(uint8_t *)p; break; + case IRT_I16: k = (int32_t)(int16_t)lj_getu16(p); break; + case IRT_U16: k = (int32_t)(uint16_t)lj_getu16(p); break; + case IRT_INT: case IRT_U32: k = (int32_t)lj_getu32(p); break; + case IRT_I64: case IRT_U64: return lj_ir_kint64(J, *(uint64_t *)p); + default: return 0; + } + return lj_ir_kint(J, k); +} + +/* Turn: string.sub(str, a, b) == kstr +** into: string.byte(str, a) == string.byte(kstr, 1) etc. +** Note: this creates unaligned XLOADs on x86/x64. +*/ +LJFOLD(EQ SNEW KGC) +LJFOLD(NE SNEW KGC) +LJFOLDF(merge_eqne_snew_kgc) +{ + GCstr *kstr = ir_kstr(fright); + int32_t len = (int32_t)kstr->len; + lj_assertJ(irt_isstr(fins->t), "bad equality IR type"); + +#if LJ_TARGET_UNALIGNED +#define FOLD_SNEW_MAX_LEN 4 /* Handle string lengths 0, 1, 2, 3, 4. */ +#define FOLD_SNEW_TYPE8 IRT_I8 /* Creates shorter immediates. */ +#else +#define FOLD_SNEW_MAX_LEN 1 /* Handle string lengths 0 or 1. */ +#define FOLD_SNEW_TYPE8 IRT_U8 /* Prefer unsigned loads. */ +#endif + + PHIBARRIER(fleft); + if (len <= FOLD_SNEW_MAX_LEN) { + IROp op = (IROp)fins->o; + IRRef strref = fleft->op1; + if (IR(strref)->o != IR_STRREF) + return NEXTFOLD; + if (op == IR_EQ) { + emitir(IRTGI(IR_EQ), fleft->op2, lj_ir_kint(J, len)); + /* Caveat: fins/fleft/fright is no longer valid after emitir. */ + } else { + /* NE is not expanded since this would need an OR of two conds. */ + if (!irref_isk(fleft->op2)) /* Only handle the constant length case. */ + return NEXTFOLD; + if (IR(fleft->op2)->i != len) + return DROPFOLD; + } + if (len > 0) { + /* A 4 byte load for length 3 is ok -- all strings have an extra NUL. */ + uint16_t ot = (uint16_t)(len == 1 ? IRT(IR_XLOAD, FOLD_SNEW_TYPE8) : + len == 2 ? IRT(IR_XLOAD, IRT_U16) : + IRTI(IR_XLOAD)); + TRef tmp = emitir(ot, strref, + IRXLOAD_READONLY | (len > 1 ? IRXLOAD_UNALIGNED : 0)); + TRef val = kfold_xload(J, IR(tref_ref(tmp)), strdata(kstr)); + if (len == 3) + tmp = emitir(IRTI(IR_BAND), tmp, + lj_ir_kint(J, LJ_ENDIAN_SELECT(0x00ffffff, 0xffffff00))); + fins->op1 = (IRRef1)tmp; + fins->op2 = (IRRef1)val; + fins->ot = (IROpT)IRTGI(op); + return RETRYFOLD; + } else { + return DROPFOLD; + } + } + return NEXTFOLD; +} + +/* -- Loads --------------------------------------------------------------- */ + +/* Loads cannot be folded or passed on to CSE in general. +** Alias analysis is needed to check for forwarding opportunities. +** +** Caveat: *all* loads must be listed here or they end up at CSE! +*/ + +LJFOLD(ALOAD any) +LJFOLDX(lj_opt_fwd_aload) + +/* From HREF fwd (see below). Must eliminate, not supported by fwd/backend. */ +LJFOLD(HLOAD KKPTR) +LJFOLDF(kfold_hload_kkptr) +{ + UNUSED(J); + lj_assertJ(ir_kptr(fleft) == niltvg(J2G(J)), "expected niltv"); + return TREF_NIL; +} + +LJFOLD(HLOAD any) +LJFOLDX(lj_opt_fwd_hload) + +LJFOLD(ULOAD any) +LJFOLDX(lj_opt_fwd_uload) + +LJFOLD(ALEN any any) +LJFOLDX(lj_opt_fwd_alen) + +/* Upvalue refs are really loads, but there are no corresponding stores. +** So CSE is ok for them, except for UREFO across a GC step (see below). +** If the referenced function is const, its upvalue addresses are const, too. +** This can be used to improve CSE by looking for the same address, +** even if the upvalues originate from a different function. +*/ +LJFOLD(UREFO KGC any) +LJFOLD(UREFC KGC any) +LJFOLDF(cse_uref) +{ + if (LJ_LIKELY(J->flags & JIT_F_OPT_CSE)) { + IRRef ref = J->chain[fins->o]; + GCfunc *fn = ir_kfunc(fleft); + GCupval *uv = gco2uv(gcref(fn->l.uvptr[(fins->op2 >> 8)])); + while (ref > 0) { + IRIns *ir = IR(ref); + if (irref_isk(ir->op1)) { + GCfunc *fn2 = ir_kfunc(IR(ir->op1)); + if (gco2uv(gcref(fn2->l.uvptr[(ir->op2 >> 8)])) == uv) { + if (fins->o == IR_UREFO && gcstep_barrier(J, ref)) + break; + return ref; + } + } + ref = ir->prev; + } + } + return EMITFOLD; +} + +LJFOLD(HREFK any any) +LJFOLDX(lj_opt_fwd_hrefk) + +LJFOLD(HREF TNEW any) +LJFOLDF(fwd_href_tnew) +{ + if (lj_opt_fwd_href_nokey(J)) + return lj_ir_kkptr(J, niltvg(J2G(J))); + return NEXTFOLD; +} + +LJFOLD(HREF TDUP KPRI) +LJFOLD(HREF TDUP KGC) +LJFOLD(HREF TDUP KNUM) +LJFOLDF(fwd_href_tdup) +{ + TValue keyv; + lj_ir_kvalue(J->L, &keyv, fright); + if (lj_tab_get(J->L, ir_ktab(IR(fleft->op1)), &keyv) == niltvg(J2G(J)) && + lj_opt_fwd_href_nokey(J)) + return lj_ir_kkptr(J, niltvg(J2G(J))); + return NEXTFOLD; +} + +/* We can safely FOLD/CSE array/hash refs and field loads, since there +** are no corresponding stores. But we need to check for any NEWREF with +** an aliased table, as it may invalidate all of the pointers and fields. +** Only HREF needs the NEWREF check -- AREF and HREFK already depend on +** FLOADs. And NEWREF itself is treated like a store (see below). +** LREF is constant (per trace) since coroutine switches are not inlined. +*/ +LJFOLD(FLOAD TNEW IRFL_TAB_ASIZE) +LJFOLDF(fload_tab_tnew_asize) +{ + if (LJ_LIKELY(J->flags & JIT_F_OPT_FOLD) && lj_opt_fwd_tptr(J, fins->op1)) + return INTFOLD(fleft->op1); + return NEXTFOLD; +} + +LJFOLD(FLOAD TNEW IRFL_TAB_HMASK) +LJFOLDF(fload_tab_tnew_hmask) +{ + if (LJ_LIKELY(J->flags & JIT_F_OPT_FOLD) && lj_opt_fwd_tptr(J, fins->op1)) + return INTFOLD((1 << fleft->op2)-1); + return NEXTFOLD; +} + +LJFOLD(FLOAD TDUP IRFL_TAB_ASIZE) +LJFOLDF(fload_tab_tdup_asize) +{ + if (LJ_LIKELY(J->flags & JIT_F_OPT_FOLD) && lj_opt_fwd_tptr(J, fins->op1)) + return INTFOLD((int32_t)ir_ktab(IR(fleft->op1))->asize); + return NEXTFOLD; +} + +LJFOLD(FLOAD TDUP IRFL_TAB_HMASK) +LJFOLDF(fload_tab_tdup_hmask) +{ + if (LJ_LIKELY(J->flags & JIT_F_OPT_FOLD) && lj_opt_fwd_tptr(J, fins->op1)) + return INTFOLD((int32_t)ir_ktab(IR(fleft->op1))->hmask); + return NEXTFOLD; +} + +LJFOLD(HREF any any) +LJFOLD(FLOAD any IRFL_TAB_ARRAY) +LJFOLD(FLOAD any IRFL_TAB_NODE) +LJFOLD(FLOAD any IRFL_TAB_ASIZE) +LJFOLD(FLOAD any IRFL_TAB_HMASK) +LJFOLDF(fload_tab_ah) +{ + TRef tr = lj_opt_cse(J); + return lj_opt_fwd_tptr(J, tref_ref(tr)) ? tr : EMITFOLD; +} + +/* Strings are immutable, so we can safely FOLD/CSE the related FLOAD. */ +LJFOLD(FLOAD KGC IRFL_STR_LEN) +LJFOLDF(fload_str_len_kgc) +{ + if (LJ_LIKELY(J->flags & JIT_F_OPT_FOLD)) + return INTFOLD((int32_t)ir_kstr(fleft)->len); + return NEXTFOLD; +} + +LJFOLD(FLOAD SNEW IRFL_STR_LEN) +LJFOLDF(fload_str_len_snew) +{ + if (LJ_LIKELY(J->flags & JIT_F_OPT_FOLD)) { + PHIBARRIER(fleft); + return fleft->op2; + } + return NEXTFOLD; +} + +LJFOLD(FLOAD TOSTR IRFL_STR_LEN) +LJFOLDF(fload_str_len_tostr) +{ + if (LJ_LIKELY(J->flags & JIT_F_OPT_FOLD) && fleft->op2 == IRTOSTR_CHAR) + return INTFOLD(1); + return NEXTFOLD; +} + +LJFOLD(FLOAD any IRFL_SBUF_W) +LJFOLD(FLOAD any IRFL_SBUF_E) +LJFOLD(FLOAD any IRFL_SBUF_B) +LJFOLD(FLOAD any IRFL_SBUF_L) +LJFOLD(FLOAD any IRFL_SBUF_REF) +LJFOLD(FLOAD any IRFL_SBUF_R) +LJFOLDF(fload_sbuf) +{ + TRef tr = lj_opt_fwd_fload(J); + return lj_opt_fwd_sbuf(J, tref_ref(tr)) ? tr : EMITFOLD; +} + +/* The fast function ID of function objects is immutable. */ +LJFOLD(FLOAD KGC IRFL_FUNC_FFID) +LJFOLDF(fload_func_ffid_kgc) +{ + if (LJ_LIKELY(J->flags & JIT_F_OPT_FOLD)) + return INTFOLD((int32_t)ir_kfunc(fleft)->c.ffid); + return NEXTFOLD; +} + +/* The C type ID of cdata objects is immutable. */ +LJFOLD(FLOAD KGC IRFL_CDATA_CTYPEID) +LJFOLDF(fload_cdata_typeid_kgc) +{ + if (LJ_LIKELY(J->flags & JIT_F_OPT_FOLD)) + return INTFOLD((int32_t)ir_kcdata(fleft)->ctypeid); + return NEXTFOLD; +} + +/* Get the contents of immutable cdata objects. */ +LJFOLD(FLOAD KGC IRFL_CDATA_PTR) +LJFOLD(FLOAD KGC IRFL_CDATA_INT) +LJFOLD(FLOAD KGC IRFL_CDATA_INT64) +LJFOLDF(fload_cdata_int64_kgc) +{ + if (LJ_LIKELY(J->flags & JIT_F_OPT_FOLD)) { + void *p = cdataptr(ir_kcdata(fleft)); + if (irt_is64(fins->t)) + return INT64FOLD(*(uint64_t *)p); + else + return INTFOLD(*(int32_t *)p); + } + return NEXTFOLD; +} + +LJFOLD(FLOAD CNEW IRFL_CDATA_CTYPEID) +LJFOLD(FLOAD CNEWI IRFL_CDATA_CTYPEID) +LJFOLDF(fload_cdata_typeid_cnew) +{ + if (LJ_LIKELY(J->flags & JIT_F_OPT_FOLD)) + return fleft->op1; /* No PHI barrier needed. CNEW/CNEWI op1 is const. */ + return NEXTFOLD; +} + +/* Pointer, int and int64 cdata objects are immutable. */ +LJFOLD(FLOAD CNEWI IRFL_CDATA_PTR) +LJFOLD(FLOAD CNEWI IRFL_CDATA_INT) +LJFOLD(FLOAD CNEWI IRFL_CDATA_INT64) +LJFOLDF(fload_cdata_ptr_int64_cnew) +{ + if (LJ_LIKELY(J->flags & JIT_F_OPT_FOLD)) + return fleft->op2; /* Fold even across PHI to avoid allocations. */ + return NEXTFOLD; +} + +LJFOLD(FLOAD any IRFL_STR_LEN) +LJFOLD(FLOAD any IRFL_FUNC_ENV) +LJFOLD(FLOAD any IRFL_THREAD_ENV) +LJFOLD(FLOAD any IRFL_CDATA_CTYPEID) +LJFOLD(FLOAD any IRFL_CDATA_PTR) +LJFOLD(FLOAD any IRFL_CDATA_INT) +LJFOLD(FLOAD any IRFL_CDATA_INT64) +LJFOLD(VLOAD any any) /* Vararg loads have no corresponding stores. */ +LJFOLDX(lj_opt_cse) + +/* All other field loads need alias analysis. */ +LJFOLD(FLOAD any any) +LJFOLDX(lj_opt_fwd_fload) + +/* This is for LOOP only. Recording handles SLOADs internally. */ +LJFOLD(SLOAD any any) +LJFOLDF(fwd_sload) +{ + if ((fins->op2 & IRSLOAD_FRAME)) { + TRef tr = lj_opt_cse(J); + return tref_ref(tr) < J->chain[IR_RETF] ? EMITFOLD : tr; + } else { + lj_assertJ(J->slot[fins->op1] != 0, "uninitialized slot accessed"); + return J->slot[fins->op1]; + } +} + +/* Only fold for KKPTR. The pointer _and_ the contents must be const. */ +LJFOLD(XLOAD KKPTR any) +LJFOLDF(xload_kptr) +{ + TRef tr = kfold_xload(J, fins, ir_kptr(fleft)); + return tr ? tr : NEXTFOLD; +} + +LJFOLD(XLOAD any any) +LJFOLDX(lj_opt_fwd_xload) + +/* -- Frame handling ------------------------------------------------------ */ + +/* Prevent CSE of a REF_BASE operand across IR_RETF. */ +LJFOLD(SUB any BASE) +LJFOLD(SUB BASE any) +LJFOLD(EQ any BASE) +LJFOLDF(fold_base) +{ + return lj_opt_cselim(J, J->chain[IR_RETF]); +} + +/* -- Write barriers ------------------------------------------------------ */ + +/* Write barriers are amenable to CSE, but not across any incremental +** GC steps. +** +** The same logic applies to open upvalue references, because a stack +** may be resized during a GC step (not the current stack, but maybe that +** of a coroutine). +*/ +LJFOLD(TBAR any) +LJFOLD(OBAR any any) +LJFOLD(UREFO any any) +LJFOLDF(barrier_tab) +{ + TRef tr = lj_opt_cse(J); + if (gcstep_barrier(J, tref_ref(tr))) /* CSE across GC step? */ + return EMITFOLD; /* Raw emit. Assumes fins is left intact by CSE. */ + return tr; +} + +LJFOLD(TBAR TNEW) +LJFOLD(TBAR TDUP) +LJFOLDF(barrier_tnew_tdup) +{ + /* New tables are always white and never need a barrier. */ + if (fins->op1 < J->chain[IR_LOOP]) /* Except across a GC step. */ + return NEXTFOLD; + return DROPFOLD; +} + +/* -- Profiling ----------------------------------------------------------- */ + +LJFOLD(PROF any any) +LJFOLDF(prof) +{ + IRRef ref = J->chain[IR_PROF]; + if (ref+1 == J->cur.nins) /* Drop neighbouring IR_PROF. */ + return ref; + return EMITFOLD; +} + +/* -- Stores and allocations ---------------------------------------------- */ + +/* Stores and allocations cannot be folded or passed on to CSE in general. +** But some stores can be eliminated with dead-store elimination (DSE). +** +** Caveat: *all* stores and allocs must be listed here or they end up at CSE! +*/ + +LJFOLD(ASTORE any any) +LJFOLD(HSTORE any any) +LJFOLDX(lj_opt_dse_ahstore) + +LJFOLD(USTORE any any) +LJFOLDX(lj_opt_dse_ustore) + +LJFOLD(FSTORE any any) +LJFOLDX(lj_opt_dse_fstore) + +LJFOLD(XSTORE any any) +LJFOLDX(lj_opt_dse_xstore) + +LJFOLD(NEWREF any any) /* Treated like a store. */ +LJFOLD(TMPREF any any) +LJFOLD(CALLA any any) +LJFOLD(CALLL any any) /* Safeguard fallback. */ +LJFOLD(CALLS any any) +LJFOLD(CALLXS any any) +LJFOLD(XBAR) +LJFOLD(RETF any any) /* Modifies BASE. */ +LJFOLD(TNEW any any) +LJFOLD(TDUP any) +LJFOLD(CNEW any any) +LJFOLD(XSNEW any any) +LJFOLDX(lj_ir_emit) + +/* ------------------------------------------------------------------------ */ + +/* Every entry in the generated hash table is a 32 bit pattern: +** +** xxxxxxxx iiiiiii lllllll rrrrrrrrrr +** +** xxxxxxxx = 8 bit index into fold function table +** iiiiiii = 7 bit folded instruction opcode +** lllllll = 7 bit left instruction opcode +** rrrrrrrrrr = 8 bit right instruction opcode or 10 bits from literal field +*/ + +#include "lj_folddef.h" + +/* ------------------------------------------------------------------------ */ + +/* Fold IR instruction. */ +TRef LJ_FASTCALL lj_opt_fold(jit_State *J) +{ + uint32_t key, any; + IRRef ref; + + if (LJ_UNLIKELY((J->flags & JIT_F_OPT_MASK) != JIT_F_OPT_DEFAULT)) { + lj_assertJ(((JIT_F_OPT_FOLD|JIT_F_OPT_FWD|JIT_F_OPT_CSE|JIT_F_OPT_DSE) | + JIT_F_OPT_DEFAULT) == JIT_F_OPT_DEFAULT, + "bad JIT_F_OPT_DEFAULT"); + /* Folding disabled? Chain to CSE, but not for loads/stores/allocs. */ + if (!(J->flags & JIT_F_OPT_FOLD) && irm_kind(lj_ir_mode[fins->o]) == IRM_N) + return lj_opt_cse(J); + + /* No FOLD, forwarding or CSE? Emit raw IR for loads, except for SLOAD. */ + if ((J->flags & (JIT_F_OPT_FOLD|JIT_F_OPT_FWD|JIT_F_OPT_CSE)) != + (JIT_F_OPT_FOLD|JIT_F_OPT_FWD|JIT_F_OPT_CSE) && + irm_kind(lj_ir_mode[fins->o]) == IRM_L && fins->o != IR_SLOAD) + return lj_ir_emit(J); + + /* No FOLD or DSE? Emit raw IR for stores. */ + if ((J->flags & (JIT_F_OPT_FOLD|JIT_F_OPT_DSE)) != + (JIT_F_OPT_FOLD|JIT_F_OPT_DSE) && + irm_kind(lj_ir_mode[fins->o]) == IRM_S) + return lj_ir_emit(J); + } + + /* Fold engine start/retry point. */ +retry: + /* Construct key from opcode and operand opcodes (unless literal/none). */ + key = ((uint32_t)fins->o << 17); + if (fins->op1 >= J->cur.nk) { + key += (uint32_t)IR(fins->op1)->o << 10; + *fleft = *IR(fins->op1); + if (fins->op1 < REF_TRUE) + fleft[1] = IR(fins->op1)[1]; + } + if (fins->op2 >= J->cur.nk) { + key += (uint32_t)IR(fins->op2)->o; + *fright = *IR(fins->op2); + if (fins->op2 < REF_TRUE) + fright[1] = IR(fins->op2)[1]; + } else { + key += (fins->op2 & 0x3ffu); /* Literal mask. Must include IRCONV_*MASK. */ + } + + /* Check for a match in order from most specific to least specific. */ + any = 0; + for (;;) { + uint32_t k = key | (any & 0x1ffff); + uint32_t h = fold_hashkey(k); + uint32_t fh = fold_hash[h]; /* Lookup key in semi-perfect hash table. */ + if ((fh & 0xffffff) == k || (fh = fold_hash[h+1], (fh & 0xffffff) == k)) { + ref = (IRRef)tref_ref(fold_func[fh >> 24](J)); + if (ref != NEXTFOLD) + break; + } + if (any == 0xfffff) /* Exhausted folding. Pass on to CSE. */ + return lj_opt_cse(J); + any = (any | (any >> 10)) ^ 0xffc00; + } + + /* Return value processing, ordered by frequency. */ + if (LJ_LIKELY(ref >= MAX_FOLD)) + return TREF(ref, irt_t(IR(ref)->t)); + if (ref == RETRYFOLD) + goto retry; + if (ref == KINTFOLD) + return lj_ir_kint(J, fins->i); + if (ref == FAILFOLD) + lj_trace_err(J, LJ_TRERR_GFAIL); + lj_assertJ(ref == DROPFOLD, "bad fold result"); + return REF_DROP; +} + +/* -- Common-Subexpression Elimination ------------------------------------ */ + +/* CSE an IR instruction. This is very fast due to the skip-list chains. */ +TRef LJ_FASTCALL lj_opt_cse(jit_State *J) +{ + /* Avoid narrow to wide store-to-load forwarding stall */ + IRRef2 op12 = (IRRef2)fins->op1 + ((IRRef2)fins->op2 << 16); + IROp op = fins->o; + if (LJ_LIKELY(J->flags & JIT_F_OPT_CSE)) { + /* Limited search for same operands in per-opcode chain. */ + IRRef ref = J->chain[op]; + IRRef lim = fins->op1; + if (fins->op2 > lim) lim = fins->op2; /* Relies on lit < REF_BIAS. */ + while (ref > lim) { + if (IR(ref)->op12 == op12) + return TREF(ref, irt_t(IR(ref)->t)); /* Common subexpression found. */ + ref = IR(ref)->prev; + } + } + /* Otherwise emit IR (inlined for speed). */ + { + IRRef ref = lj_ir_nextins(J); + IRIns *ir = IR(ref); + ir->prev = J->chain[op]; + ir->op12 = op12; + J->chain[op] = (IRRef1)ref; + ir->o = fins->o; + J->guardemit.irt |= fins->t.irt; + return TREF(ref, irt_t((ir->t = fins->t))); + } +} + +/* CSE with explicit search limit. */ +TRef LJ_FASTCALL lj_opt_cselim(jit_State *J, IRRef lim) +{ + IRRef ref = J->chain[fins->o]; + IRRef2 op12 = (IRRef2)fins->op1 + ((IRRef2)fins->op2 << 16); + while (ref > lim) { + if (IR(ref)->op12 == op12) + return ref; + ref = IR(ref)->prev; + } + return lj_ir_emit(J); +} + +/* ------------------------------------------------------------------------ */ + +#undef IR +#undef fins +#undef fleft +#undef fright +#undef knumleft +#undef knumright +#undef emitir + +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_opt_loop.c b/fluent-bit/lib/luajit-3065c9/src/lj_opt_loop.c new file mode 100644 index 00000000..ee3ee049 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_opt_loop.c @@ -0,0 +1,453 @@ +/* +** LOOP: Loop Optimizations. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#define lj_opt_loop_c +#define LUA_CORE + +#include "lj_obj.h" + +#if LJ_HASJIT + +#include "lj_err.h" +#include "lj_buf.h" +#include "lj_ir.h" +#include "lj_jit.h" +#include "lj_iropt.h" +#include "lj_trace.h" +#include "lj_snap.h" +#include "lj_vm.h" + +/* Loop optimization: +** +** Traditional Loop-Invariant Code Motion (LICM) splits the instructions +** of a loop into invariant and variant instructions. The invariant +** instructions are hoisted out of the loop and only the variant +** instructions remain inside the loop body. +** +** Unfortunately LICM is mostly useless for compiling dynamic languages. +** The IR has many guards and most of the subsequent instructions are +** control-dependent on them. The first non-hoistable guard would +** effectively prevent hoisting of all subsequent instructions. +** +** That's why we use a special form of unrolling using copy-substitution, +** combined with redundancy elimination: +** +** The recorded instruction stream is re-emitted to the compiler pipeline +** with substituted operands. The substitution table is filled with the +** refs returned by re-emitting each instruction. This can be done +** on-the-fly, because the IR is in strict SSA form, where every ref is +** defined before its use. +** +** This aproach generates two code sections, separated by the LOOP +** instruction: +** +** 1. The recorded instructions form a kind of pre-roll for the loop. It +** contains a mix of invariant and variant instructions and performs +** exactly one loop iteration (but not necessarily the 1st iteration). +** +** 2. The loop body contains only the variant instructions and performs +** all remaining loop iterations. +** +** On first sight that looks like a waste of space, because the variant +** instructions are present twice. But the key insight is that the +** pre-roll honors the control-dependencies for *both* the pre-roll itself +** *and* the loop body! +** +** It also means one doesn't have to explicitly model control-dependencies +** (which, BTW, wouldn't help LICM much). And it's much easier to +** integrate sparse snapshotting with this approach. +** +** One of the nicest aspects of this approach is that all of the +** optimizations of the compiler pipeline (FOLD, CSE, FWD, etc.) can be +** reused with only minor restrictions (e.g. one should not fold +** instructions across loop-carried dependencies). +** +** But in general all optimizations can be applied which only need to look +** backwards into the generated instruction stream. At any point in time +** during the copy-substitution process this contains both a static loop +** iteration (the pre-roll) and a dynamic one (from the to-be-copied +** instruction up to the end of the partial loop body). +** +** Since control-dependencies are implicitly kept, CSE also applies to all +** kinds of guards. The major advantage is that all invariant guards can +** be hoisted, too. +** +** Load/store forwarding works across loop iterations, too. This is +** important if loop-carried dependencies are kept in upvalues or tables. +** E.g. 'self.idx = self.idx + 1' deep down in some OO-style method may +** become a forwarded loop-recurrence after inlining. +** +** Since the IR is in SSA form, loop-carried dependencies have to be +** modeled with PHI instructions. The potential candidates for PHIs are +** collected on-the-fly during copy-substitution. After eliminating the +** redundant ones, PHI instructions are emitted *below* the loop body. +** +** Note that this departure from traditional SSA form doesn't change the +** semantics of the PHI instructions themselves. But it greatly simplifies +** on-the-fly generation of the IR and the machine code. +*/ + +/* Some local macros to save typing. Undef'd at the end. */ +#define IR(ref) (&J->cur.ir[(ref)]) + +/* Pass IR on to next optimization in chain (FOLD). */ +#define emitir(ot, a, b) (lj_ir_set(J, (ot), (a), (b)), lj_opt_fold(J)) + +/* Emit raw IR without passing through optimizations. */ +#define emitir_raw(ot, a, b) (lj_ir_set(J, (ot), (a), (b)), lj_ir_emit(J)) + +/* -- PHI elimination ----------------------------------------------------- */ + +/* Emit or eliminate collected PHIs. */ +static void loop_emit_phi(jit_State *J, IRRef1 *subst, IRRef1 *phi, IRRef nphi, + SnapNo onsnap) +{ + int passx = 0; + IRRef i, j, nslots; + IRRef invar = J->chain[IR_LOOP]; + /* Pass #1: mark redundant and potentially redundant PHIs. */ + for (i = 0, j = 0; i < nphi; i++) { + IRRef lref = phi[i]; + IRRef rref = subst[lref]; + if (lref == rref || rref == REF_DROP) { /* Invariants are redundant. */ + irt_clearphi(IR(lref)->t); + } else { + phi[j++] = (IRRef1)lref; + if (!(IR(rref)->op1 == lref || IR(rref)->op2 == lref)) { + /* Quick check for simple recurrences failed, need pass2. */ + irt_setmark(IR(lref)->t); + passx = 1; + } + } + } + nphi = j; + /* Pass #2: traverse variant part and clear marks of non-redundant PHIs. */ + if (passx) { + SnapNo s; + for (i = J->cur.nins-1; i > invar; i--) { + IRIns *ir = IR(i); + if (!irref_isk(ir->op2)) irt_clearmark(IR(ir->op2)->t); + if (!irref_isk(ir->op1)) { + irt_clearmark(IR(ir->op1)->t); + if (ir->op1 < invar && + ir->o >= IR_CALLN && ir->o <= IR_CARG) { /* ORDER IR */ + ir = IR(ir->op1); + while (ir->o == IR_CARG) { + if (!irref_isk(ir->op2)) irt_clearmark(IR(ir->op2)->t); + if (irref_isk(ir->op1)) break; + ir = IR(ir->op1); + irt_clearmark(ir->t); + } + } + } + } + for (s = J->cur.nsnap-1; s >= onsnap; s--) { + SnapShot *snap = &J->cur.snap[s]; + SnapEntry *map = &J->cur.snapmap[snap->mapofs]; + MSize n, nent = snap->nent; + for (n = 0; n < nent; n++) { + IRRef ref = snap_ref(map[n]); + if (!irref_isk(ref)) irt_clearmark(IR(ref)->t); + } + } + } + /* Pass #3: add PHIs for variant slots without a corresponding SLOAD. */ + nslots = J->baseslot+J->maxslot; + for (i = 1; i < nslots; i++) { + IRRef ref = tref_ref(J->slot[i]); + while (!irref_isk(ref) && ref != subst[ref]) { + IRIns *ir = IR(ref); + irt_clearmark(ir->t); /* Unmark potential uses, too. */ + if (irt_isphi(ir->t) || irt_ispri(ir->t)) + break; + irt_setphi(ir->t); + if (nphi >= LJ_MAX_PHI) + lj_trace_err(J, LJ_TRERR_PHIOV); + phi[nphi++] = (IRRef1)ref; + ref = subst[ref]; + if (ref > invar) + break; + } + } + /* Pass #4: propagate non-redundant PHIs. */ + while (passx) { + passx = 0; + for (i = 0; i < nphi; i++) { + IRRef lref = phi[i]; + IRIns *ir = IR(lref); + if (!irt_ismarked(ir->t)) { /* Propagate only from unmarked PHIs. */ + IRIns *irr = IR(subst[lref]); + if (irt_ismarked(irr->t)) { /* Right ref points to other PHI? */ + irt_clearmark(irr->t); /* Mark that PHI as non-redundant. */ + passx = 1; /* Retry. */ + } + } + } + } + /* Pass #5: emit PHI instructions or eliminate PHIs. */ + for (i = 0; i < nphi; i++) { + IRRef lref = phi[i]; + IRIns *ir = IR(lref); + if (!irt_ismarked(ir->t)) { /* Emit PHI if not marked. */ + IRRef rref = subst[lref]; + if (rref > invar) + irt_setphi(IR(rref)->t); + emitir_raw(IRT(IR_PHI, irt_type(ir->t)), lref, rref); + } else { /* Otherwise eliminate PHI. */ + irt_clearmark(ir->t); + irt_clearphi(ir->t); + } + } +} + +/* -- Loop unrolling using copy-substitution ------------------------------ */ + +/* Copy-substitute snapshot. */ +static void loop_subst_snap(jit_State *J, SnapShot *osnap, + SnapEntry *loopmap, IRRef1 *subst) +{ + SnapEntry *nmap, *omap = &J->cur.snapmap[osnap->mapofs]; + SnapEntry *nextmap = &J->cur.snapmap[snap_nextofs(&J->cur, osnap)]; + MSize nmapofs; + MSize on, ln, nn, onent = osnap->nent; + BCReg nslots = osnap->nslots; + SnapShot *snap = &J->cur.snap[J->cur.nsnap]; + if (irt_isguard(J->guardemit)) { /* Guard inbetween? */ + nmapofs = J->cur.nsnapmap; + J->cur.nsnap++; /* Add new snapshot. */ + } else { /* Otherwise overwrite previous snapshot. */ + snap--; + nmapofs = snap->mapofs; + } + J->guardemit.irt = 0; + /* Setup new snapshot. */ + snap->mapofs = (uint32_t)nmapofs; + snap->ref = (IRRef1)J->cur.nins; + snap->mcofs = 0; + snap->nslots = nslots; + snap->topslot = osnap->topslot; + snap->count = 0; + nmap = &J->cur.snapmap[nmapofs]; + /* Substitute snapshot slots. */ + on = ln = nn = 0; + while (on < onent) { + SnapEntry osn = omap[on], lsn = loopmap[ln]; + if (snap_slot(lsn) < snap_slot(osn)) { /* Copy slot from loop map. */ + nmap[nn++] = lsn; + ln++; + } else { /* Copy substituted slot from snapshot map. */ + if (snap_slot(lsn) == snap_slot(osn)) ln++; /* Shadowed loop slot. */ + if (!irref_isk(snap_ref(osn))) + osn = snap_setref(osn, subst[snap_ref(osn)]); + nmap[nn++] = osn; + on++; + } + } + while (snap_slot(loopmap[ln]) < nslots) /* Copy remaining loop slots. */ + nmap[nn++] = loopmap[ln++]; + snap->nent = (uint8_t)nn; + omap += onent; + nmap += nn; + while (omap < nextmap) /* Copy PC + frame links. */ + *nmap++ = *omap++; + J->cur.nsnapmap = (uint32_t)(nmap - J->cur.snapmap); +} + +typedef struct LoopState { + jit_State *J; + IRRef1 *subst; + MSize sizesubst; +} LoopState; + +/* Unroll loop. */ +static void loop_unroll(LoopState *lps) +{ + jit_State *J = lps->J; + IRRef1 phi[LJ_MAX_PHI]; + uint32_t nphi = 0; + IRRef1 *subst; + SnapNo onsnap; + SnapShot *osnap, *loopsnap; + SnapEntry *loopmap, *psentinel; + IRRef ins, invar; + + /* Allocate substitution table. + ** Only non-constant refs in [REF_BIAS,invar) are valid indexes. + */ + invar = J->cur.nins; + lps->sizesubst = invar - REF_BIAS; + lps->subst = lj_mem_newvec(J->L, lps->sizesubst, IRRef1); + subst = lps->subst - REF_BIAS; + subst[REF_BASE] = REF_BASE; + + /* LOOP separates the pre-roll from the loop body. */ + emitir_raw(IRTG(IR_LOOP, IRT_NIL), 0, 0); + + /* Grow snapshot buffer and map for copy-substituted snapshots. + ** Need up to twice the number of snapshots minus #0 and loop snapshot. + ** Need up to twice the number of entries plus fallback substitutions + ** from the loop snapshot entries for each new snapshot. + ** Caveat: both calls may reallocate J->cur.snap and J->cur.snapmap! + */ + onsnap = J->cur.nsnap; + lj_snap_grow_buf(J, 2*onsnap-2); + lj_snap_grow_map(J, J->cur.nsnapmap*2+(onsnap-2)*J->cur.snap[onsnap-1].nent); + + /* The loop snapshot is used for fallback substitutions. */ + loopsnap = &J->cur.snap[onsnap-1]; + loopmap = &J->cur.snapmap[loopsnap->mapofs]; + /* The PC of snapshot #0 and the loop snapshot must match. */ + psentinel = &loopmap[loopsnap->nent]; + lj_assertJ(*psentinel == J->cur.snapmap[J->cur.snap[0].nent], + "mismatched PC for loop snapshot"); + *psentinel = SNAP(255, 0, 0); /* Replace PC with temporary sentinel. */ + + /* Start substitution with snapshot #1 (#0 is empty for root traces). */ + osnap = &J->cur.snap[1]; + + /* Copy and substitute all recorded instructions and snapshots. */ + for (ins = REF_FIRST; ins < invar; ins++) { + IRIns *ir; + IRRef op1, op2; + + if (ins >= osnap->ref) /* Instruction belongs to next snapshot? */ + loop_subst_snap(J, osnap++, loopmap, subst); /* Copy-substitute it. */ + + /* Substitute instruction operands. */ + ir = IR(ins); + op1 = ir->op1; + if (!irref_isk(op1)) op1 = subst[op1]; + op2 = ir->op2; + if (!irref_isk(op2)) op2 = subst[op2]; + if (irm_kind(lj_ir_mode[ir->o]) == IRM_N && + op1 == ir->op1 && op2 == ir->op2) { /* Regular invariant ins? */ + subst[ins] = (IRRef1)ins; /* Shortcut. */ + } else { + /* Re-emit substituted instruction to the FOLD/CSE/etc. pipeline. */ + IRType1 t = ir->t; /* Get this first, since emitir may invalidate ir. */ + IRRef ref = tref_ref(emitir(ir->ot & ~IRT_ISPHI, op1, op2)); + subst[ins] = (IRRef1)ref; + if (ref != ins) { + IRIns *irr = IR(ref); + if (ref < invar) { /* Loop-carried dependency? */ + /* Potential PHI? */ + if (!irref_isk(ref) && !irt_isphi(irr->t) && !irt_ispri(irr->t)) { + irt_setphi(irr->t); + if (nphi >= LJ_MAX_PHI) + lj_trace_err(J, LJ_TRERR_PHIOV); + phi[nphi++] = (IRRef1)ref; + } + /* Check all loop-carried dependencies for type instability. */ + if (!irt_sametype(t, irr->t)) { + if (irt_isinteger(t) && irt_isinteger(irr->t)) + continue; + else if (irt_isnum(t) && irt_isinteger(irr->t)) /* Fix int->num. */ + ref = tref_ref(emitir(IRTN(IR_CONV), ref, IRCONV_NUM_INT)); + else if (irt_isnum(irr->t) && irt_isinteger(t)) /* Fix num->int. */ + ref = tref_ref(emitir(IRTGI(IR_CONV), ref, + IRCONV_INT_NUM|IRCONV_CHECK)); + else + lj_trace_err(J, LJ_TRERR_TYPEINS); + subst[ins] = (IRRef1)ref; + irr = IR(ref); + goto phiconv; + } + } else if (ref != REF_DROP && ref > invar && + ((irr->o == IR_CONV && irr->op1 < invar) || + (irr->o == IR_ALEN && irr->op2 < invar && + irr->op2 != REF_NIL))) { + /* May need an extra PHI for a CONV or ALEN hint. */ + ref = irr->o == IR_CONV ? irr->op1 : irr->op2; + irr = IR(ref); + phiconv: + if (ref < invar && !irref_isk(ref) && !irt_isphi(irr->t)) { + irt_setphi(irr->t); + if (nphi >= LJ_MAX_PHI) + lj_trace_err(J, LJ_TRERR_PHIOV); + phi[nphi++] = (IRRef1)ref; + } + } + } + } + } + if (!irt_isguard(J->guardemit)) /* Drop redundant snapshot. */ + J->cur.nsnapmap = (uint32_t)J->cur.snap[--J->cur.nsnap].mapofs; + lj_assertJ(J->cur.nsnapmap <= J->sizesnapmap, "bad snapshot map index"); + *psentinel = J->cur.snapmap[J->cur.snap[0].nent]; /* Restore PC. */ + + loop_emit_phi(J, subst, phi, nphi, onsnap); +} + +/* Undo any partial changes made by the loop optimization. */ +static void loop_undo(jit_State *J, IRRef ins, SnapNo nsnap, MSize nsnapmap) +{ + ptrdiff_t i; + SnapShot *snap = &J->cur.snap[nsnap-1]; + SnapEntry *map = J->cur.snapmap; + map[snap->mapofs + snap->nent] = map[J->cur.snap[0].nent]; /* Restore PC. */ + J->cur.nsnapmap = (uint32_t)nsnapmap; + J->cur.nsnap = nsnap; + J->guardemit.irt = 0; + lj_ir_rollback(J, ins); + for (i = 0; i < BPROP_SLOTS; i++) { /* Remove backprop. cache entries. */ + BPropEntry *bp = &J->bpropcache[i]; + if (bp->val >= ins) + bp->key = 0; + } + for (ins--; ins >= REF_FIRST; ins--) { /* Remove flags. */ + IRIns *ir = IR(ins); + irt_clearphi(ir->t); + irt_clearmark(ir->t); + } +} + +/* Protected callback for loop optimization. */ +static TValue *cploop_opt(lua_State *L, lua_CFunction dummy, void *ud) +{ + UNUSED(L); UNUSED(dummy); + loop_unroll((LoopState *)ud); + return NULL; +} + +/* Loop optimization. */ +int lj_opt_loop(jit_State *J) +{ + IRRef nins = J->cur.nins; + SnapNo nsnap = J->cur.nsnap; + MSize nsnapmap = J->cur.nsnapmap; + LoopState lps; + int errcode; + lps.J = J; + lps.subst = NULL; + lps.sizesubst = 0; + errcode = lj_vm_cpcall(J->L, NULL, &lps, cploop_opt); + lj_mem_freevec(J2G(J), lps.subst, lps.sizesubst, IRRef1); + if (LJ_UNLIKELY(errcode)) { + lua_State *L = J->L; + if (errcode == LUA_ERRRUN && tvisnumber(L->top-1)) { /* Trace error? */ + int32_t e = numberVint(L->top-1); + switch ((TraceError)e) { + case LJ_TRERR_TYPEINS: /* Type instability. */ + case LJ_TRERR_GFAIL: /* Guard would always fail. */ + /* Unrolling via recording fixes many cases, e.g. a flipped boolean. */ + if (--J->instunroll < 0) /* But do not unroll forever. */ + break; + L->top--; /* Remove error object. */ + loop_undo(J, nins, nsnap, nsnapmap); + return 1; /* Loop optimization failed, continue recording. */ + default: + break; + } + } + lj_err_throw(L, errcode); /* Propagate all other errors. */ + } + return 0; /* Loop optimization is ok. */ +} + +#undef IR +#undef emitir +#undef emitir_raw + +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_opt_mem.c b/fluent-bit/lib/luajit-3065c9/src/lj_opt_mem.c new file mode 100644 index 00000000..09de2f05 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_opt_mem.c @@ -0,0 +1,979 @@ +/* +** Memory access optimizations. +** AA: Alias Analysis using high-level semantic disambiguation. +** FWD: Load Forwarding (L2L) + Store Forwarding (S2L). +** DSE: Dead-Store Elimination. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#define lj_opt_mem_c +#define LUA_CORE + +#include "lj_obj.h" + +#if LJ_HASJIT + +#include "lj_tab.h" +#include "lj_ir.h" +#include "lj_jit.h" +#include "lj_iropt.h" +#include "lj_ircall.h" +#include "lj_dispatch.h" + +/* Some local macros to save typing. Undef'd at the end. */ +#define IR(ref) (&J->cur.ir[(ref)]) +#define fins (&J->fold.ins) +#define fleft (J->fold.left) +#define fright (J->fold.right) + +/* +** Caveat #1: return value is not always a TRef -- only use with tref_ref(). +** Caveat #2: FWD relies on active CSE for xREF operands -- see lj_opt_fold(). +*/ + +/* Return values from alias analysis. */ +typedef enum { + ALIAS_NO, /* The two refs CANNOT alias (exact). */ + ALIAS_MAY, /* The two refs MAY alias (inexact). */ + ALIAS_MUST /* The two refs MUST alias (exact). */ +} AliasRet; + +/* -- ALOAD/HLOAD forwarding and ASTORE/HSTORE elimination ---------------- */ + +/* Simplified escape analysis: check for intervening stores. */ +static AliasRet aa_escape(jit_State *J, IRIns *ir, IRIns *stop) +{ + IRRef ref = (IRRef)(ir - J->cur.ir); /* The ref that might be stored. */ + for (ir++; ir < stop; ir++) + if (ir->op2 == ref && + (ir->o == IR_ASTORE || ir->o == IR_HSTORE || + ir->o == IR_USTORE || ir->o == IR_FSTORE)) + return ALIAS_MAY; /* Reference was stored and might alias. */ + return ALIAS_NO; /* Reference was not stored. */ +} + +/* Alias analysis for two different table references. */ +static AliasRet aa_table(jit_State *J, IRRef ta, IRRef tb) +{ + IRIns *taba = IR(ta), *tabb = IR(tb); + int newa, newb; + lj_assertJ(ta != tb, "bad usage"); + lj_assertJ(irt_istab(taba->t) && irt_istab(tabb->t), "bad usage"); + /* Disambiguate new allocations. */ + newa = (taba->o == IR_TNEW || taba->o == IR_TDUP); + newb = (tabb->o == IR_TNEW || tabb->o == IR_TDUP); + if (newa && newb) + return ALIAS_NO; /* Two different allocations never alias. */ + if (newb) { /* At least one allocation? */ + IRIns *tmp = taba; taba = tabb; tabb = tmp; + } else if (!newa) { + return ALIAS_MAY; /* Anything else: we just don't know. */ + } + return aa_escape(J, taba, tabb); +} + +/* Check whether there's no aliasing table.clear. */ +static int fwd_aa_tab_clear(jit_State *J, IRRef lim, IRRef ta) +{ + IRRef ref = J->chain[IR_CALLS]; + while (ref > lim) { + IRIns *calls = IR(ref); + if (calls->op2 == IRCALL_lj_tab_clear && + (ta == calls->op1 || aa_table(J, ta, calls->op1) != ALIAS_NO)) + return 0; /* Conflict. */ + ref = calls->prev; + } + return 1; /* No conflict. Can safely FOLD/CSE. */ +} + +/* Check whether there's no aliasing NEWREF/table.clear for the left operand. */ +int LJ_FASTCALL lj_opt_fwd_tptr(jit_State *J, IRRef lim) +{ + IRRef ta = fins->op1; + IRRef ref = J->chain[IR_NEWREF]; + while (ref > lim) { + IRIns *newref = IR(ref); + if (ta == newref->op1 || aa_table(J, ta, newref->op1) != ALIAS_NO) + return 0; /* Conflict. */ + ref = newref->prev; + } + return fwd_aa_tab_clear(J, lim, ta); +} + +/* Alias analysis for array and hash access using key-based disambiguation. */ +static AliasRet aa_ahref(jit_State *J, IRIns *refa, IRIns *refb) +{ + IRRef ka = refa->op2; + IRRef kb = refb->op2; + IRIns *keya, *keyb; + IRRef ta, tb; + if (refa == refb) + return ALIAS_MUST; /* Shortcut for same refs. */ + keya = IR(ka); + if (keya->o == IR_KSLOT) { ka = keya->op1; keya = IR(ka); } + keyb = IR(kb); + if (keyb->o == IR_KSLOT) { kb = keyb->op1; keyb = IR(kb); } + ta = (refa->o==IR_HREFK || refa->o==IR_AREF) ? IR(refa->op1)->op1 : refa->op1; + tb = (refb->o==IR_HREFK || refb->o==IR_AREF) ? IR(refb->op1)->op1 : refb->op1; + if (ka == kb) { + /* Same key. Check for same table with different ref (NEWREF vs. HREF). */ + if (ta == tb) + return ALIAS_MUST; /* Same key, same table. */ + else + return aa_table(J, ta, tb); /* Same key, possibly different table. */ + } + if (irref_isk(ka) && irref_isk(kb)) + return ALIAS_NO; /* Different constant keys. */ + if (refa->o == IR_AREF) { + /* Disambiguate array references based on index arithmetic. */ + int32_t ofsa = 0, ofsb = 0; + IRRef basea = ka, baseb = kb; + lj_assertJ(refb->o == IR_AREF, "expected AREF"); + /* Gather base and offset from t[base] or t[base+-ofs]. */ + if (keya->o == IR_ADD && irref_isk(keya->op2)) { + basea = keya->op1; + ofsa = IR(keya->op2)->i; + if (basea == kb && ofsa != 0) + return ALIAS_NO; /* t[base+-ofs] vs. t[base]. */ + } + if (keyb->o == IR_ADD && irref_isk(keyb->op2)) { + baseb = keyb->op1; + ofsb = IR(keyb->op2)->i; + if (ka == baseb && ofsb != 0) + return ALIAS_NO; /* t[base] vs. t[base+-ofs]. */ + } + if (basea == baseb && ofsa != ofsb) + return ALIAS_NO; /* t[base+-o1] vs. t[base+-o2] and o1 != o2. */ + } else { + /* Disambiguate hash references based on the type of their keys. */ + lj_assertJ((refa->o==IR_HREF || refa->o==IR_HREFK || refa->o==IR_NEWREF) && + (refb->o==IR_HREF || refb->o==IR_HREFK || refb->o==IR_NEWREF), + "bad xREF IR op %d or %d", refa->o, refb->o); + if (!irt_sametype(keya->t, keyb->t)) + return ALIAS_NO; /* Different key types. */ + } + if (ta == tb) + return ALIAS_MAY; /* Same table, cannot disambiguate keys. */ + else + return aa_table(J, ta, tb); /* Try to disambiguate tables. */ +} + +/* Array and hash load forwarding. */ +static TRef fwd_ahload(jit_State *J, IRRef xref) +{ + IRIns *xr = IR(xref); + IRRef lim = xref; /* Search limit. */ + IRRef ref; + + /* Search for conflicting stores. */ + ref = J->chain[fins->o+IRDELTA_L2S]; + while (ref > xref) { + IRIns *store = IR(ref); + switch (aa_ahref(J, xr, IR(store->op1))) { + case ALIAS_NO: break; /* Continue searching. */ + case ALIAS_MAY: lim = ref; goto cselim; /* Limit search for load. */ + case ALIAS_MUST: return store->op2; /* Store forwarding. */ + } + ref = store->prev; + } + + /* No conflicting store (yet): const-fold loads from allocations. */ + { + IRIns *ir = (xr->o == IR_HREFK || xr->o == IR_AREF) ? IR(xr->op1) : xr; + IRRef tab = ir->op1; + ir = IR(tab); + if ((ir->o == IR_TNEW || (ir->o == IR_TDUP && irref_isk(xr->op2))) && + fwd_aa_tab_clear(J, tab, tab)) { + /* A NEWREF with a number key may end up pointing to the array part. + ** But it's referenced from HSTORE and not found in the ASTORE chain. + ** For now simply consider this a conflict without forwarding anything. + */ + if (xr->o == IR_AREF) { + IRRef ref2 = J->chain[IR_NEWREF]; + while (ref2 > tab) { + IRIns *newref = IR(ref2); + if (irt_isnum(IR(newref->op2)->t)) + goto cselim; + ref2 = newref->prev; + } + } + /* NEWREF inhibits CSE for HREF, and dependent FLOADs from HREFK/AREF. + ** But the above search for conflicting stores was limited by xref. + ** So continue searching, limited by the TNEW/TDUP. Store forwarding + ** is ok, too. A conflict does NOT limit the search for a matching load. + */ + while (ref > tab) { + IRIns *store = IR(ref); + switch (aa_ahref(J, xr, IR(store->op1))) { + case ALIAS_NO: break; /* Continue searching. */ + case ALIAS_MAY: goto cselim; /* Conflicting store. */ + case ALIAS_MUST: return store->op2; /* Store forwarding. */ + } + ref = store->prev; + } + if (ir->o == IR_TNEW && !irt_isnil(fins->t)) + return 0; /* Type instability in loop-carried dependency. */ + if (irt_ispri(fins->t)) { + return TREF_PRI(irt_type(fins->t)); + } else if (irt_isnum(fins->t) || (LJ_DUALNUM && irt_isint(fins->t)) || + irt_isstr(fins->t)) { + TValue keyv; + cTValue *tv; + IRIns *key = IR(xr->op2); + if (key->o == IR_KSLOT) key = IR(key->op1); + lj_ir_kvalue(J->L, &keyv, key); + tv = lj_tab_get(J->L, ir_ktab(IR(ir->op1)), &keyv); + lj_assertJ(itype2irt(tv) == irt_type(fins->t), + "mismatched type in constant table"); + if (irt_isnum(fins->t)) + return lj_ir_knum_u64(J, tv->u64); + else if (LJ_DUALNUM && irt_isint(fins->t)) + return lj_ir_kint(J, intV(tv)); + else + return lj_ir_kstr(J, strV(tv)); + } + /* Othwerwise: don't intern as a constant. */ + } + } + +cselim: + /* Try to find a matching load. Below the conflicting store, if any. */ + ref = J->chain[fins->o]; + while (ref > lim) { + IRIns *load = IR(ref); + if (load->op1 == xref) + return ref; /* Load forwarding. */ + ref = load->prev; + } + return 0; /* Conflict or no match. */ +} + +/* Reassociate ALOAD across PHIs to handle t[i-1] forwarding case. */ +static TRef fwd_aload_reassoc(jit_State *J) +{ + IRIns *irx = IR(fins->op1); + IRIns *key = IR(irx->op2); + if (key->o == IR_ADD && irref_isk(key->op2)) { + IRIns *add2 = IR(key->op1); + if (add2->o == IR_ADD && irref_isk(add2->op2) && + IR(key->op2)->i == -IR(add2->op2)->i) { + IRRef ref = J->chain[IR_AREF]; + IRRef lim = add2->op1; + if (irx->op1 > lim) lim = irx->op1; + while (ref > lim) { + IRIns *ir = IR(ref); + if (ir->op1 == irx->op1 && ir->op2 == add2->op1) + return fwd_ahload(J, ref); + ref = ir->prev; + } + } + } + return 0; +} + +/* ALOAD forwarding. */ +TRef LJ_FASTCALL lj_opt_fwd_aload(jit_State *J) +{ + IRRef ref; + if ((ref = fwd_ahload(J, fins->op1)) || + (ref = fwd_aload_reassoc(J))) + return ref; + return EMITFOLD; +} + +/* HLOAD forwarding. */ +TRef LJ_FASTCALL lj_opt_fwd_hload(jit_State *J) +{ + IRRef ref = fwd_ahload(J, fins->op1); + if (ref) + return ref; + return EMITFOLD; +} + +/* HREFK forwarding. */ +TRef LJ_FASTCALL lj_opt_fwd_hrefk(jit_State *J) +{ + IRRef tab = fleft->op1; + IRRef ref = J->chain[IR_NEWREF]; + while (ref > tab) { + IRIns *newref = IR(ref); + if (tab == newref->op1) { + if (fright->op1 == newref->op2 && fwd_aa_tab_clear(J, ref, tab)) + return ref; /* Forward from NEWREF. */ + else + goto docse; + } else if (aa_table(J, tab, newref->op1) != ALIAS_NO) { + goto docse; + } + ref = newref->prev; + } + /* No conflicting NEWREF: key location unchanged for HREFK of TDUP. */ + if (IR(tab)->o == IR_TDUP && fwd_aa_tab_clear(J, tab, tab)) + fins->t.irt &= ~IRT_GUARD; /* Drop HREFK guard. */ +docse: + return CSEFOLD; +} + +/* Check whether HREF of TNEW/TDUP can be folded to niltv. */ +int LJ_FASTCALL lj_opt_fwd_href_nokey(jit_State *J) +{ + IRRef lim = fins->op1; /* Search limit. */ + IRRef ref; + + /* The key for an ASTORE may end up in the hash part after a NEWREF. */ + if (irt_isnum(fright->t) && J->chain[IR_NEWREF] > lim) { + ref = J->chain[IR_ASTORE]; + while (ref > lim) { + if (ref < J->chain[IR_NEWREF]) + return 0; /* Conflict. */ + ref = IR(ref)->prev; + } + } + + /* Search for conflicting stores. */ + ref = J->chain[IR_HSTORE]; + while (ref > lim) { + IRIns *store = IR(ref); + if (aa_ahref(J, fins, IR(store->op1)) != ALIAS_NO) + return 0; /* Conflict. */ + ref = store->prev; + } + + return 1; /* No conflict. Can fold to niltv. */ +} + +/* ASTORE/HSTORE elimination. */ +TRef LJ_FASTCALL lj_opt_dse_ahstore(jit_State *J) +{ + IRRef xref = fins->op1; /* xREF reference. */ + IRRef val = fins->op2; /* Stored value reference. */ + IRIns *xr = IR(xref); + IRRef1 *refp = &J->chain[fins->o]; + IRRef ref = *refp; + while (ref > xref) { /* Search for redundant or conflicting stores. */ + IRIns *store = IR(ref); + switch (aa_ahref(J, xr, IR(store->op1))) { + case ALIAS_NO: + break; /* Continue searching. */ + case ALIAS_MAY: /* Store to MAYBE the same location. */ + if (store->op2 != val) /* Conflict if the value is different. */ + goto doemit; + break; /* Otherwise continue searching. */ + case ALIAS_MUST: /* Store to the same location. */ + if (store->op2 == val) /* Same value: drop the new store. */ + return DROPFOLD; + /* Different value: try to eliminate the redundant store. */ + if (ref > J->chain[IR_LOOP]) { /* Quick check to avoid crossing LOOP. */ + IRIns *ir; + /* Check for any intervening guards (includes conflicting loads). + ** Note that lj_tab_keyindex and lj_vm_next don't need guards, + ** since they are followed by at least one guarded VLOAD. + */ + for (ir = IR(J->cur.nins-1); ir > store; ir--) + if (irt_isguard(ir->t) || ir->o == IR_ALEN) + goto doemit; /* No elimination possible. */ + /* Remove redundant store from chain and replace with NOP. */ + *refp = store->prev; + lj_ir_nop(store); + /* Now emit the new store instead. */ + } + goto doemit; + } + ref = *(refp = &store->prev); + } +doemit: + return EMITFOLD; /* Otherwise we have a conflict or simply no match. */ +} + +/* ALEN forwarding. */ +TRef LJ_FASTCALL lj_opt_fwd_alen(jit_State *J) +{ + IRRef tab = fins->op1; /* Table reference. */ + IRRef lim = tab; /* Search limit. */ + IRRef ref; + + /* Search for conflicting HSTORE with numeric key. */ + ref = J->chain[IR_HSTORE]; + while (ref > lim) { + IRIns *store = IR(ref); + IRIns *href = IR(store->op1); + IRIns *key = IR(href->op2); + if (irt_isnum(key->o == IR_KSLOT ? IR(key->op1)->t : key->t)) { + lim = ref; /* Conflicting store found, limits search for ALEN. */ + break; + } + ref = store->prev; + } + + /* Try to find a matching ALEN. */ + ref = J->chain[IR_ALEN]; + while (ref > lim) { + /* CSE for ALEN only depends on the table, not the hint. */ + if (IR(ref)->op1 == tab) { + IRRef sref; + + /* Search for aliasing table.clear. */ + if (!fwd_aa_tab_clear(J, ref, tab)) + break; + + /* Search for hint-forwarding or conflicting store. */ + sref = J->chain[IR_ASTORE]; + while (sref > ref) { + IRIns *store = IR(sref); + IRIns *aref = IR(store->op1); + IRIns *fref = IR(aref->op1); + if (tab == fref->op1) { /* ASTORE to the same table. */ + /* Detect t[#t+1] = x idiom for push. */ + IRIns *idx = IR(aref->op2); + if (!irt_isnil(store->t) && + idx->o == IR_ADD && idx->op1 == ref && + IR(idx->op2)->o == IR_KINT && IR(idx->op2)->i == 1) { + /* Note: this requires an extra PHI check in loop unroll. */ + fins->op2 = aref->op2; /* Set ALEN hint. */ + } + goto doemit; /* Conflicting store, possibly giving a hint. */ + } else if (aa_table(J, tab, fref->op1) != ALIAS_NO) { + goto doemit; /* Conflicting store. */ + } + sref = store->prev; + } + + return ref; /* Plain ALEN forwarding. */ + } + ref = IR(ref)->prev; + } +doemit: + return EMITFOLD; +} + +/* -- ULOAD forwarding ---------------------------------------------------- */ + +/* The current alias analysis for upvalues is very simplistic. It only +** disambiguates between the unique upvalues of the same function. +** This is good enough for now, since most upvalues are read-only. +** +** A more precise analysis would be feasible with the help of the parser: +** generate a unique key for every upvalue, even across all prototypes. +** Lacking a realistic use-case, it's unclear whether this is beneficial. +*/ +static AliasRet aa_uref(IRIns *refa, IRIns *refb) +{ + if (refa->o != refb->o) + return ALIAS_NO; /* Different UREFx type. */ + if (refa->op1 == refb->op1) { /* Same function. */ + if (refa->op2 == refb->op2) + return ALIAS_MUST; /* Same function, same upvalue idx. */ + else + return ALIAS_NO; /* Same function, different upvalue idx. */ + } else { /* Different functions, check disambiguation hash values. */ + if (((refa->op2 ^ refb->op2) & 0xff)) + return ALIAS_NO; /* Upvalues with different hash values cannot alias. */ + else + return ALIAS_MAY; /* No conclusion can be drawn for same hash value. */ + } +} + +/* ULOAD forwarding. */ +TRef LJ_FASTCALL lj_opt_fwd_uload(jit_State *J) +{ + IRRef uref = fins->op1; + IRRef lim = REF_BASE; /* Search limit. */ + IRIns *xr = IR(uref); + IRRef ref; + + /* Search for conflicting stores. */ + ref = J->chain[IR_USTORE]; + while (ref > lim) { + IRIns *store = IR(ref); + switch (aa_uref(xr, IR(store->op1))) { + case ALIAS_NO: break; /* Continue searching. */ + case ALIAS_MAY: lim = ref; goto cselim; /* Limit search for load. */ + case ALIAS_MUST: return store->op2; /* Store forwarding. */ + } + ref = store->prev; + } + +cselim: + /* Try to find a matching load. Below the conflicting store, if any. */ + ref = J->chain[IR_ULOAD]; + while (ref > lim) { + IRIns *ir = IR(ref); + if (ir->op1 == uref || + (IR(ir->op1)->op12 == IR(uref)->op12 && IR(ir->op1)->o == IR(uref)->o)) + return ref; /* Match for identical or equal UREFx (non-CSEable UREFO). */ + ref = ir->prev; + } + return lj_ir_emit(J); +} + +/* USTORE elimination. */ +TRef LJ_FASTCALL lj_opt_dse_ustore(jit_State *J) +{ + IRRef xref = fins->op1; /* xREF reference. */ + IRRef val = fins->op2; /* Stored value reference. */ + IRIns *xr = IR(xref); + IRRef1 *refp = &J->chain[IR_USTORE]; + IRRef ref = *refp; + while (ref > xref) { /* Search for redundant or conflicting stores. */ + IRIns *store = IR(ref); + switch (aa_uref(xr, IR(store->op1))) { + case ALIAS_NO: + break; /* Continue searching. */ + case ALIAS_MAY: /* Store to MAYBE the same location. */ + if (store->op2 != val) /* Conflict if the value is different. */ + goto doemit; + break; /* Otherwise continue searching. */ + case ALIAS_MUST: /* Store to the same location. */ + if (store->op2 == val) /* Same value: drop the new store. */ + return DROPFOLD; + /* Different value: try to eliminate the redundant store. */ + if (ref > J->chain[IR_LOOP]) { /* Quick check to avoid crossing LOOP. */ + IRIns *ir; + /* Check for any intervening guards (includes conflicting loads). */ + for (ir = IR(J->cur.nins-1); ir > store; ir--) + if (irt_isguard(ir->t)) + goto doemit; /* No elimination possible. */ + /* Remove redundant store from chain and replace with NOP. */ + *refp = store->prev; + lj_ir_nop(store); + if (ref+1 < J->cur.nins && + store[1].o == IR_OBAR && store[1].op1 == xref) { + IRRef1 *bp = &J->chain[IR_OBAR]; + IRIns *obar; + for (obar = IR(*bp); *bp > ref+1; obar = IR(*bp)) + bp = &obar->prev; + /* Remove OBAR, too. */ + *bp = obar->prev; + lj_ir_nop(obar); + } + /* Now emit the new store instead. */ + } + goto doemit; + } + ref = *(refp = &store->prev); + } +doemit: + return EMITFOLD; /* Otherwise we have a conflict or simply no match. */ +} + +/* -- FLOAD forwarding and FSTORE elimination ----------------------------- */ + +/* Alias analysis for field access. +** Field loads are cheap and field stores are rare. +** Simple disambiguation based on field types is good enough. +*/ +static AliasRet aa_fref(jit_State *J, IRIns *refa, IRIns *refb) +{ + if (refa->op2 != refb->op2) + return ALIAS_NO; /* Different fields. */ + if (refa->op1 == refb->op1) + return ALIAS_MUST; /* Same field, same object. */ + else if (refa->op2 >= IRFL_TAB_META && refa->op2 <= IRFL_TAB_NOMM) + return aa_table(J, refa->op1, refb->op1); /* Disambiguate tables. */ + else + return ALIAS_MAY; /* Same field, possibly different object. */ +} + +/* Only the loads for mutable fields end up here (see FOLD). */ +TRef LJ_FASTCALL lj_opt_fwd_fload(jit_State *J) +{ + IRRef oref = fins->op1; /* Object reference. */ + IRRef fid = fins->op2; /* Field ID. */ + IRRef lim = oref; /* Search limit. */ + IRRef ref; + + /* Search for conflicting stores. */ + ref = J->chain[IR_FSTORE]; + while (ref > oref) { + IRIns *store = IR(ref); + switch (aa_fref(J, fins, IR(store->op1))) { + case ALIAS_NO: break; /* Continue searching. */ + case ALIAS_MAY: lim = ref; goto cselim; /* Limit search for load. */ + case ALIAS_MUST: return store->op2; /* Store forwarding. */ + } + ref = store->prev; + } + + /* No conflicting store: const-fold field loads from allocations. */ + if (fid == IRFL_TAB_META) { + IRIns *ir = IR(oref); + if (ir->o == IR_TNEW || ir->o == IR_TDUP) + return lj_ir_knull(J, IRT_TAB); + } + +cselim: + /* Try to find a matching load. Below the conflicting store, if any. */ + return lj_opt_cselim(J, lim); +} + +/* FSTORE elimination. */ +TRef LJ_FASTCALL lj_opt_dse_fstore(jit_State *J) +{ + IRRef fref = fins->op1; /* FREF reference. */ + IRRef val = fins->op2; /* Stored value reference. */ + IRIns *xr = IR(fref); + IRRef1 *refp = &J->chain[IR_FSTORE]; + IRRef ref = *refp; + while (ref > fref) { /* Search for redundant or conflicting stores. */ + IRIns *store = IR(ref); + switch (aa_fref(J, xr, IR(store->op1))) { + case ALIAS_NO: + break; /* Continue searching. */ + case ALIAS_MAY: + if (store->op2 != val) /* Conflict if the value is different. */ + goto doemit; + break; /* Otherwise continue searching. */ + case ALIAS_MUST: + if (store->op2 == val && + !(xr->op2 >= IRFL_SBUF_W && xr->op2 <= IRFL_SBUF_R)) + return DROPFOLD; /* Same value: drop the new store. */ + /* Different value: try to eliminate the redundant store. */ + if (ref > J->chain[IR_LOOP]) { /* Quick check to avoid crossing LOOP. */ + IRIns *ir; + /* Check for any intervening guards or conflicting loads. */ + for (ir = IR(J->cur.nins-1); ir > store; ir--) + if (irt_isguard(ir->t) || (ir->o == IR_FLOAD && ir->op2 == xr->op2)) + goto doemit; /* No elimination possible. */ + /* Remove redundant store from chain and replace with NOP. */ + *refp = store->prev; + lj_ir_nop(store); + /* Now emit the new store instead. */ + } + goto doemit; + } + ref = *(refp = &store->prev); + } +doemit: + return EMITFOLD; /* Otherwise we have a conflict or simply no match. */ +} + +/* Check whether there's no aliasing buffer op between IRFL_SBUF_*. */ +int LJ_FASTCALL lj_opt_fwd_sbuf(jit_State *J, IRRef lim) +{ + IRRef ref; + if (J->chain[IR_BUFPUT] > lim) + return 0; /* Conflict. */ + ref = J->chain[IR_CALLS]; + while (ref > lim) { + IRIns *ir = IR(ref); + if (ir->op2 >= IRCALL_lj_strfmt_putint && ir->op2 < IRCALL_lj_buf_tostr) + return 0; /* Conflict. */ + ref = ir->prev; + } + ref = J->chain[IR_CALLL]; + while (ref > lim) { + IRIns *ir = IR(ref); + if (ir->op2 >= IRCALL_lj_strfmt_putint && ir->op2 < IRCALL_lj_buf_tostr) + return 0; /* Conflict. */ + ref = ir->prev; + } + return 1; /* No conflict. Can safely FOLD/CSE. */ +} + +/* -- XLOAD forwarding and XSTORE elimination ----------------------------- */ + +/* Find cdata allocation for a reference (if any). */ +static IRIns *aa_findcnew(jit_State *J, IRIns *ir) +{ + while (ir->o == IR_ADD) { + if (!irref_isk(ir->op1)) { + IRIns *ir1 = aa_findcnew(J, IR(ir->op1)); /* Left-recursion. */ + if (ir1) return ir1; + } + if (irref_isk(ir->op2)) return NULL; + ir = IR(ir->op2); /* Flatten right-recursion. */ + } + return ir->o == IR_CNEW ? ir : NULL; +} + +/* Alias analysis for two cdata allocations. */ +static AliasRet aa_cnew(jit_State *J, IRIns *refa, IRIns *refb) +{ + IRIns *cnewa = aa_findcnew(J, refa); + IRIns *cnewb = aa_findcnew(J, refb); + if (cnewa == cnewb) + return ALIAS_MAY; /* Same allocation or neither is an allocation. */ + if (cnewa && cnewb) + return ALIAS_NO; /* Two different allocations never alias. */ + if (cnewb) { cnewa = cnewb; refb = refa; } + return aa_escape(J, cnewa, refb); +} + +/* Alias analysis for XLOAD/XSTORE. */ +static AliasRet aa_xref(jit_State *J, IRIns *refa, IRIns *xa, IRIns *xb) +{ + ptrdiff_t ofsa = 0, ofsb = 0; + IRIns *refb = IR(xb->op1); + IRIns *basea = refa, *baseb = refb; + if (refa == refb && irt_sametype(xa->t, xb->t)) + return ALIAS_MUST; /* Shortcut for same refs with identical type. */ + /* Offset-based disambiguation. */ + if (refa->o == IR_ADD && irref_isk(refa->op2)) { + IRIns *irk = IR(refa->op2); + basea = IR(refa->op1); + ofsa = (LJ_64 && irk->o == IR_KINT64) ? (ptrdiff_t)ir_k64(irk)->u64 : + (ptrdiff_t)irk->i; + } + if (refb->o == IR_ADD && irref_isk(refb->op2)) { + IRIns *irk = IR(refb->op2); + baseb = IR(refb->op1); + ofsb = (LJ_64 && irk->o == IR_KINT64) ? (ptrdiff_t)ir_k64(irk)->u64 : + (ptrdiff_t)irk->i; + } + /* Treat constified pointers like base vs. base+offset. */ + if (basea->o == IR_KPTR && baseb->o == IR_KPTR) { + ofsb += (char *)ir_kptr(baseb) - (char *)ir_kptr(basea); + baseb = basea; + } + /* This implements (very) strict aliasing rules. + ** Different types do NOT alias, except for differences in signedness. + ** Type punning through unions is allowed (but forces a reload). + */ + if (basea == baseb) { + ptrdiff_t sza = irt_size(xa->t), szb = irt_size(xb->t); + if (ofsa == ofsb) { + if (sza == szb && irt_isfp(xa->t) == irt_isfp(xb->t)) + return ALIAS_MUST; /* Same-sized, same-kind. May need to convert. */ + } else if (ofsa + sza <= ofsb || ofsb + szb <= ofsa) { + return ALIAS_NO; /* Non-overlapping base+-o1 vs. base+-o2. */ + } + /* NYI: extract, extend or reinterpret bits (int <-> fp). */ + return ALIAS_MAY; /* Overlapping or type punning: force reload. */ + } + if (!irt_sametype(xa->t, xb->t) && + !(irt_typerange(xa->t, IRT_I8, IRT_U64) && + ((xa->t.irt - IRT_I8) ^ (xb->t.irt - IRT_I8)) == 1)) + return ALIAS_NO; + /* NYI: structural disambiguation. */ + return aa_cnew(J, basea, baseb); /* Try to disambiguate allocations. */ +} + +/* Return CSEd reference or 0. Caveat: swaps lower ref to the right! */ +static IRRef reassoc_trycse(jit_State *J, IROp op, IRRef op1, IRRef op2) +{ + IRRef ref = J->chain[op]; + IRRef lim = op1; + if (op2 > lim) { lim = op2; op2 = op1; op1 = lim; } + while (ref > lim) { + IRIns *ir = IR(ref); + if (ir->op1 == op1 && ir->op2 == op2) + return ref; + ref = ir->prev; + } + return 0; +} + +/* Reassociate index references. */ +static IRRef reassoc_xref(jit_State *J, IRIns *ir) +{ + ptrdiff_t ofs = 0; + if (ir->o == IR_ADD && irref_isk(ir->op2)) { /* Get constant offset. */ + IRIns *irk = IR(ir->op2); + ofs = (LJ_64 && irk->o == IR_KINT64) ? (ptrdiff_t)ir_k64(irk)->u64 : + (ptrdiff_t)irk->i; + ir = IR(ir->op1); + } + if (ir->o == IR_ADD) { /* Add of base + index. */ + /* Index ref > base ref for loop-carried dependences. Only check op1. */ + IRIns *ir2, *ir1 = IR(ir->op1); + int32_t shift = 0; + IRRef idxref; + /* Determine index shifts. Don't bother with IR_MUL here. */ + if (ir1->o == IR_BSHL && irref_isk(ir1->op2)) + shift = IR(ir1->op2)->i; + else if (ir1->o == IR_ADD && ir1->op1 == ir1->op2) + shift = 1; + else + ir1 = ir; + ir2 = IR(ir1->op1); + /* A non-reassociated add. Must be a loop-carried dependence. */ + if (ir2->o == IR_ADD && irt_isint(ir2->t) && irref_isk(ir2->op2)) + ofs += (ptrdiff_t)IR(ir2->op2)->i << shift; + else + return 0; + idxref = ir2->op1; + /* Try to CSE the reassociated chain. Give up if not found. */ + if (ir1 != ir && + !(idxref = reassoc_trycse(J, ir1->o, idxref, + ir1->o == IR_BSHL ? ir1->op2 : idxref))) + return 0; + if (!(idxref = reassoc_trycse(J, IR_ADD, idxref, ir->op2))) + return 0; + if (ofs != 0) { + IRRef refk = tref_ref(lj_ir_kintp(J, ofs)); + if (!(idxref = reassoc_trycse(J, IR_ADD, idxref, refk))) + return 0; + } + return idxref; /* Success, found a reassociated index reference. Phew. */ + } + return 0; /* Failure. */ +} + +/* XLOAD forwarding. */ +TRef LJ_FASTCALL lj_opt_fwd_xload(jit_State *J) +{ + IRRef xref = fins->op1; + IRIns *xr = IR(xref); + IRRef lim = xref; /* Search limit. */ + IRRef ref; + + if ((fins->op2 & IRXLOAD_READONLY)) + goto cselim; + if ((fins->op2 & IRXLOAD_VOLATILE)) + goto doemit; + + /* Search for conflicting stores. */ + ref = J->chain[IR_XSTORE]; +retry: + if (J->chain[IR_CALLXS] > lim) lim = J->chain[IR_CALLXS]; + if (J->chain[IR_XBAR] > lim) lim = J->chain[IR_XBAR]; + while (ref > lim) { + IRIns *store = IR(ref); + switch (aa_xref(J, xr, fins, store)) { + case ALIAS_NO: break; /* Continue searching. */ + case ALIAS_MAY: lim = ref; goto cselim; /* Limit search for load. */ + case ALIAS_MUST: + /* Emit conversion if the loaded type doesn't match the forwarded type. */ + if (!irt_sametype(fins->t, IR(store->op2)->t)) { + IRType dt = irt_type(fins->t), st = irt_type(IR(store->op2)->t); + if (dt == IRT_I8 || dt == IRT_I16) { /* Trunc + sign-extend. */ + st = dt | IRCONV_SEXT; + dt = IRT_INT; + } else if (dt == IRT_U8 || dt == IRT_U16) { /* Trunc + zero-extend. */ + st = dt; + dt = IRT_INT; + } + fins->ot = IRT(IR_CONV, dt); + fins->op1 = store->op2; + fins->op2 = (dt<<5)|st; + return RETRYFOLD; + } + return store->op2; /* Store forwarding. */ + } + ref = store->prev; + } + +cselim: + /* Try to find a matching load. Below the conflicting store, if any. */ + ref = J->chain[IR_XLOAD]; + while (ref > lim) { + /* CSE for XLOAD depends on the type, but not on the IRXLOAD_* flags. */ + if (IR(ref)->op1 == xref && irt_sametype(IR(ref)->t, fins->t)) + return ref; + ref = IR(ref)->prev; + } + + /* Reassociate XLOAD across PHIs to handle a[i-1] forwarding case. */ + if (!(fins->op2 & IRXLOAD_READONLY) && J->chain[IR_LOOP] && + xref == fins->op1 && (xref = reassoc_xref(J, xr)) != 0) { + ref = J->chain[IR_XSTORE]; + while (ref > lim) /* Skip stores that have already been checked. */ + ref = IR(ref)->prev; + lim = xref; + xr = IR(xref); + goto retry; /* Retry with the reassociated reference. */ + } +doemit: + return EMITFOLD; +} + +/* XSTORE elimination. */ +TRef LJ_FASTCALL lj_opt_dse_xstore(jit_State *J) +{ + IRRef xref = fins->op1; + IRIns *xr = IR(xref); + IRRef lim = xref; /* Search limit. */ + IRRef val = fins->op2; /* Stored value reference. */ + IRRef1 *refp = &J->chain[IR_XSTORE]; + IRRef ref = *refp; + if (J->chain[IR_CALLXS] > lim) lim = J->chain[IR_CALLXS]; + if (J->chain[IR_XBAR] > lim) lim = J->chain[IR_XBAR]; + if (J->chain[IR_XSNEW] > lim) lim = J->chain[IR_XSNEW]; + while (ref > lim) { /* Search for redundant or conflicting stores. */ + IRIns *store = IR(ref); + switch (aa_xref(J, xr, fins, store)) { + case ALIAS_NO: + break; /* Continue searching. */ + case ALIAS_MAY: + if (store->op2 != val) /* Conflict if the value is different. */ + goto doemit; + break; /* Otherwise continue searching. */ + case ALIAS_MUST: + if (store->op2 == val) /* Same value: drop the new store. */ + return DROPFOLD; + /* Different value: try to eliminate the redundant store. */ + if (ref > J->chain[IR_LOOP]) { /* Quick check to avoid crossing LOOP. */ + IRIns *ir; + /* Check for any intervening guards or any XLOADs (no AA performed). */ + for (ir = IR(J->cur.nins-1); ir > store; ir--) + if (irt_isguard(ir->t) || ir->o == IR_XLOAD) + goto doemit; /* No elimination possible. */ + /* Remove redundant store from chain and replace with NOP. */ + *refp = store->prev; + lj_ir_nop(store); + /* Now emit the new store instead. */ + } + goto doemit; + } + ref = *(refp = &store->prev); + } +doemit: + return EMITFOLD; /* Otherwise we have a conflict or simply no match. */ +} + +/* -- ASTORE/HSTORE previous type analysis -------------------------------- */ + +/* Check whether the previous value for a table store is non-nil. +** This can be derived either from a previous store or from a previous +** load (because all loads from tables perform a type check). +** +** The result of the analysis can be used to avoid the metatable check +** and the guard against HREF returning niltv. Both of these are cheap, +** so let's not spend too much effort on the analysis. +** +** A result of 1 is exact: previous value CANNOT be nil. +** A result of 0 is inexact: previous value MAY be nil. +*/ +int lj_opt_fwd_wasnonnil(jit_State *J, IROpT loadop, IRRef xref) +{ + /* First check stores. */ + IRRef ref = J->chain[loadop+IRDELTA_L2S]; + while (ref > xref) { + IRIns *store = IR(ref); + if (store->op1 == xref) { /* Same xREF. */ + /* A nil store MAY alias, but a non-nil store MUST alias. */ + return !irt_isnil(store->t); + } else if (irt_isnil(store->t)) { /* Must check any nil store. */ + IRRef skref = IR(store->op1)->op2; + IRRef xkref = IR(xref)->op2; + /* Same key type MAY alias. Need ALOAD check due to multiple int types. */ + if (loadop == IR_ALOAD || irt_sametype(IR(skref)->t, IR(xkref)->t)) { + if (skref == xkref || !irref_isk(skref) || !irref_isk(xkref)) + return 0; /* A nil store with same const key or var key MAY alias. */ + /* Different const keys CANNOT alias. */ + } /* Different key types CANNOT alias. */ + } /* Other non-nil stores MAY alias. */ + ref = store->prev; + } + + /* Check loads since nothing could be derived from stores. */ + ref = J->chain[loadop]; + while (ref > xref) { + IRIns *load = IR(ref); + if (load->op1 == xref) { /* Same xREF. */ + /* A nil load MAY alias, but a non-nil load MUST alias. */ + return !irt_isnil(load->t); + } /* Other non-nil loads MAY alias. */ + ref = load->prev; + } + return 0; /* Nothing derived at all, previous value MAY be nil. */ +} + +/* ------------------------------------------------------------------------ */ + +#undef IR +#undef fins +#undef fleft +#undef fright + +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_opt_narrow.c b/fluent-bit/lib/luajit-3065c9/src/lj_opt_narrow.c new file mode 100644 index 00000000..586f1bc7 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_opt_narrow.c @@ -0,0 +1,622 @@ +/* +** NARROW: Narrowing of numbers to integers (double to int32_t). +** STRIPOV: Stripping of overflow checks. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#define lj_opt_narrow_c +#define LUA_CORE + +#include "lj_obj.h" + +#if LJ_HASJIT + +#include "lj_bc.h" +#include "lj_ir.h" +#include "lj_jit.h" +#include "lj_iropt.h" +#include "lj_trace.h" +#include "lj_vm.h" +#include "lj_strscan.h" + +/* Rationale for narrowing optimizations: +** +** Lua has only a single number type and this is a FP double by default. +** Narrowing doubles to integers does not pay off for the interpreter on a +** current-generation x86/x64 machine. Most FP operations need the same +** amount of execution resources as their integer counterparts, except +** with slightly longer latencies. Longer latencies are a non-issue for +** the interpreter, since they are usually hidden by other overhead. +** +** The total CPU execution bandwidth is the sum of the bandwidth of the FP +** and the integer units, because they execute in parallel. The FP units +** have an equal or higher bandwidth than the integer units. Not using +** them means losing execution bandwidth. Moving work away from them to +** the already quite busy integer units is a losing proposition. +** +** The situation for JIT-compiled code is a bit different: the higher code +** density makes the extra latencies much more visible. Tight loops expose +** the latencies for updating the induction variables. Array indexing +** requires narrowing conversions with high latencies and additional +** guards (to check that the index is really an integer). And many common +** optimizations only work on integers. +** +** One solution would be speculative, eager narrowing of all number loads. +** This causes many problems, like losing -0 or the need to resolve type +** mismatches between traces. It also effectively forces the integer type +** to have overflow-checking semantics. This impedes many basic +** optimizations and requires adding overflow checks to all integer +** arithmetic operations (whereas FP arithmetics can do without). +** +** Always replacing an FP op with an integer op plus an overflow check is +** counter-productive on a current-generation super-scalar CPU. Although +** the overflow check branches are highly predictable, they will clog the +** execution port for the branch unit and tie up reorder buffers. This is +** turning a pure data-flow dependency into a different data-flow +** dependency (with slightly lower latency) *plus* a control dependency. +** In general, you don't want to do this since latencies due to data-flow +** dependencies can be well hidden by out-of-order execution. +** +** A better solution is to keep all numbers as FP values and only narrow +** when it's beneficial to do so. LuaJIT uses predictive narrowing for +** induction variables and demand-driven narrowing for index expressions, +** integer arguments and bit operations. Additionally it can eliminate or +** hoist most of the resulting overflow checks. Regular arithmetic +** computations are never narrowed to integers. +** +** The integer type in the IR has convenient wrap-around semantics and +** ignores overflow. Extra operations have been added for +** overflow-checking arithmetic (ADDOV/SUBOV) instead of an extra type. +** Apart from reducing overall complexity of the compiler, this also +** nicely solves the problem where you want to apply algebraic +** simplifications to ADD, but not to ADDOV. And the x86/x64 assembler can +** use lea instead of an add for integer ADD, but not for ADDOV (lea does +** not affect the flags, but it helps to avoid register moves). +** +** +** All of the above has to be reconsidered for architectures with slow FP +** operations or without a hardware FPU. The dual-number mode of LuaJIT +** addresses this issue. Arithmetic operations are performed on integers +** as far as possible and overflow checks are added as needed. +** +** This implies that narrowing for integer arguments and bit operations +** should also strip overflow checks, e.g. replace ADDOV with ADD. The +** original overflow guards are weak and can be eliminated by DCE, if +** there's no other use. +** +** A slight twist is that it's usually beneficial to use overflow-checked +** integer arithmetics if all inputs are already integers. This is the only +** change that affects the single-number mode, too. +*/ + +/* Some local macros to save typing. Undef'd at the end. */ +#define IR(ref) (&J->cur.ir[(ref)]) +#define fins (&J->fold.ins) + +/* Pass IR on to next optimization in chain (FOLD). */ +#define emitir(ot, a, b) (lj_ir_set(J, (ot), (a), (b)), lj_opt_fold(J)) + +#define emitir_raw(ot, a, b) (lj_ir_set(J, (ot), (a), (b)), lj_ir_emit(J)) + +/* -- Elimination of narrowing type conversions --------------------------- */ + +/* Narrowing of index expressions and bit operations is demand-driven. The +** trace recorder emits a narrowing type conversion (CONV.int.num or TOBIT) +** in all of these cases (e.g. array indexing or string indexing). FOLD +** already takes care of eliminating simple redundant conversions like +** CONV.int.num(CONV.num.int(x)) ==> x. +** +** But the surrounding code is FP-heavy and arithmetic operations are +** performed on FP numbers (for the single-number mode). Consider a common +** example such as 'x=t[i+1]', with 'i' already an integer (due to induction +** variable narrowing). The index expression would be recorded as +** CONV.int.num(ADD(CONV.num.int(i), 1)) +** which is clearly suboptimal. +** +** One can do better by recursively backpropagating the narrowing type +** conversion across FP arithmetic operations. This turns FP ops into +** their corresponding integer counterparts. Depending on the semantics of +** the conversion they also need to check for overflow. Currently only ADD +** and SUB are supported. +** +** The above example can be rewritten as +** ADDOV(CONV.int.num(CONV.num.int(i)), 1) +** and then into ADDOV(i, 1) after folding of the conversions. The original +** FP ops remain in the IR and are eliminated by DCE since all references to +** them are gone. +** +** [In dual-number mode the trace recorder already emits ADDOV etc., but +** this can be further reduced. See below.] +** +** Special care has to be taken to avoid narrowing across an operation +** which is potentially operating on non-integral operands. One obvious +** case is when an expression contains a non-integral constant, but ends +** up as an integer index at runtime (like t[x+1.5] with x=0.5). +** +** Operations with two non-constant operands illustrate a similar problem +** (like t[a+b] with a=1.5 and b=2.5). Backpropagation has to stop there, +** unless it can be proven that either operand is integral (e.g. by CSEing +** a previous conversion). As a not-so-obvious corollary this logic also +** applies for a whole expression tree (e.g. t[(a+1)+(b+1)]). +** +** Correctness of the transformation is guaranteed by avoiding to expand +** the tree by adding more conversions than the one we would need to emit +** if not backpropagating. TOBIT employs a more optimistic rule, because +** the conversion has special semantics, designed to make the life of the +** compiler writer easier. ;-) +** +** Using on-the-fly backpropagation of an expression tree doesn't work +** because it's unknown whether the transform is correct until the end. +** This either requires IR rollback and cache invalidation for every +** subtree or a two-pass algorithm. The former didn't work out too well, +** so the code now combines a recursive collector with a stack-based +** emitter. +** +** [A recursive backpropagation algorithm with backtracking, employing +** skip-list lookup and round-robin caching, emitting stack operations +** on-the-fly for a stack-based interpreter -- and all of that in a meager +** kilobyte? Yep, compilers are a great treasure chest. Throw away your +** textbooks and read the codebase of a compiler today!] +** +** There's another optimization opportunity for array indexing: it's +** always accompanied by an array bounds-check. The outermost overflow +** check may be delegated to the ABC operation. This works because ABC is +** an unsigned comparison and wrap-around due to overflow creates negative +** numbers. +** +** But this optimization is only valid for constants that cannot overflow +** an int32_t into the range of valid array indexes [0..2^27+1). A check +** for +-2^30 is safe since -2^31 - 2^30 wraps to 2^30 and 2^31-1 + 2^30 +** wraps to -2^30-1. +** +** It's also good enough in practice, since e.g. t[i+1] or t[i-10] are +** quite common. So the above example finally ends up as ADD(i, 1)! +** +** Later on, the assembler is able to fuse the whole array reference and +** the ADD into the memory operands of loads and other instructions. This +** is why LuaJIT is able to generate very pretty (and fast) machine code +** for array indexing. And that, my dear, concludes another story about +** one of the hidden secrets of LuaJIT ... +*/ + +/* Maximum backpropagation depth and maximum stack size. */ +#define NARROW_MAX_BACKPROP 100 +#define NARROW_MAX_STACK 256 + +/* The stack machine has a 32 bit instruction format: [IROpT | IRRef1] +** The lower 16 bits hold a reference (or 0). The upper 16 bits hold +** the IR opcode + type or one of the following special opcodes: +*/ +enum { + NARROW_REF, /* Push ref. */ + NARROW_CONV, /* Push conversion of ref. */ + NARROW_SEXT, /* Push sign-extension of ref. */ + NARROW_INT /* Push KINT ref. The next code holds an int32_t. */ +}; + +typedef uint32_t NarrowIns; + +#define NARROWINS(op, ref) (((op) << 16) + (ref)) +#define narrow_op(ins) ((IROpT)((ins) >> 16)) +#define narrow_ref(ins) ((IRRef1)(ins)) + +/* Context used for narrowing of type conversions. */ +typedef struct NarrowConv { + jit_State *J; /* JIT compiler state. */ + NarrowIns *sp; /* Current stack pointer. */ + NarrowIns *maxsp; /* Maximum stack pointer minus redzone. */ + IRRef mode; /* Conversion mode (IRCONV_*). */ + IRType t; /* Destination type: IRT_INT or IRT_I64. */ + NarrowIns stack[NARROW_MAX_STACK]; /* Stack holding stack-machine code. */ +} NarrowConv; + +/* Lookup a reference in the backpropagation cache. */ +static BPropEntry *narrow_bpc_get(jit_State *J, IRRef1 key, IRRef mode) +{ + ptrdiff_t i; + for (i = 0; i < BPROP_SLOTS; i++) { + BPropEntry *bp = &J->bpropcache[i]; + /* Stronger checks are ok, too. */ + if (bp->key == key && bp->mode >= mode && + ((bp->mode ^ mode) & IRCONV_MODEMASK) == 0) + return bp; + } + return NULL; +} + +/* Add an entry to the backpropagation cache. */ +static void narrow_bpc_set(jit_State *J, IRRef1 key, IRRef1 val, IRRef mode) +{ + uint32_t slot = J->bpropslot; + BPropEntry *bp = &J->bpropcache[slot]; + J->bpropslot = (slot + 1) & (BPROP_SLOTS-1); + bp->key = key; + bp->val = val; + bp->mode = mode; +} + +/* Backpropagate overflow stripping. */ +static void narrow_stripov_backprop(NarrowConv *nc, IRRef ref, int depth) +{ + jit_State *J = nc->J; + IRIns *ir = IR(ref); + if (ir->o == IR_ADDOV || ir->o == IR_SUBOV || + (ir->o == IR_MULOV && (nc->mode & IRCONV_CONVMASK) == IRCONV_ANY)) { + BPropEntry *bp = narrow_bpc_get(nc->J, ref, IRCONV_TOBIT); + if (bp) { + ref = bp->val; + } else if (++depth < NARROW_MAX_BACKPROP && nc->sp < nc->maxsp) { + NarrowIns *savesp = nc->sp; + narrow_stripov_backprop(nc, ir->op1, depth); + if (nc->sp < nc->maxsp) { + narrow_stripov_backprop(nc, ir->op2, depth); + if (nc->sp < nc->maxsp) { + *nc->sp++ = NARROWINS(IRT(ir->o - IR_ADDOV + IR_ADD, IRT_INT), ref); + return; + } + } + nc->sp = savesp; /* Path too deep, need to backtrack. */ + } + } + *nc->sp++ = NARROWINS(NARROW_REF, ref); +} + +/* Backpropagate narrowing conversion. Return number of needed conversions. */ +static int narrow_conv_backprop(NarrowConv *nc, IRRef ref, int depth) +{ + jit_State *J = nc->J; + IRIns *ir = IR(ref); + IRRef cref; + + if (nc->sp >= nc->maxsp) return 10; /* Path too deep. */ + + /* Check the easy cases first. */ + if (ir->o == IR_CONV && (ir->op2 & IRCONV_SRCMASK) == IRT_INT) { + if ((nc->mode & IRCONV_CONVMASK) <= IRCONV_ANY) + narrow_stripov_backprop(nc, ir->op1, depth+1); + else + *nc->sp++ = NARROWINS(NARROW_REF, ir->op1); /* Undo conversion. */ + if (nc->t == IRT_I64) + *nc->sp++ = NARROWINS(NARROW_SEXT, 0); /* Sign-extend integer. */ + return 0; + } else if (ir->o == IR_KNUM) { /* Narrow FP constant. */ + lua_Number n = ir_knum(ir)->n; + if ((nc->mode & IRCONV_CONVMASK) == IRCONV_TOBIT) { + /* Allows a wider range of constants. */ + int64_t k64 = (int64_t)n; + if (n == (lua_Number)k64) { /* Only if const doesn't lose precision. */ + *nc->sp++ = NARROWINS(NARROW_INT, 0); + *nc->sp++ = (NarrowIns)k64; /* But always truncate to 32 bits. */ + return 0; + } + } else { + int32_t k = lj_num2int(n); + /* Only if constant is a small integer. */ + if (checki16(k) && n == (lua_Number)k) { + *nc->sp++ = NARROWINS(NARROW_INT, 0); + *nc->sp++ = (NarrowIns)k; + return 0; + } + } + return 10; /* Never narrow other FP constants (this is rare). */ + } + + /* Try to CSE the conversion. Stronger checks are ok, too. */ + cref = J->chain[fins->o]; + while (cref > ref) { + IRIns *cr = IR(cref); + if (cr->op1 == ref && + (fins->o == IR_TOBIT || + ((cr->op2 & IRCONV_MODEMASK) == (nc->mode & IRCONV_MODEMASK) && + irt_isguard(cr->t) >= irt_isguard(fins->t)))) { + *nc->sp++ = NARROWINS(NARROW_REF, cref); + return 0; /* Already there, no additional conversion needed. */ + } + cref = cr->prev; + } + + /* Backpropagate across ADD/SUB. */ + if (ir->o == IR_ADD || ir->o == IR_SUB) { + /* Try cache lookup first. */ + IRRef mode = nc->mode; + BPropEntry *bp; + /* Inner conversions need a stronger check. */ + if ((mode & IRCONV_CONVMASK) == IRCONV_INDEX && depth > 0) + mode += IRCONV_CHECK-IRCONV_INDEX; + bp = narrow_bpc_get(nc->J, (IRRef1)ref, mode); + if (bp) { + *nc->sp++ = NARROWINS(NARROW_REF, bp->val); + return 0; + } else if (nc->t == IRT_I64) { + /* Try sign-extending from an existing (checked) conversion to int. */ + mode = (IRT_INT<<5)|IRT_NUM|IRCONV_INDEX; + bp = narrow_bpc_get(nc->J, (IRRef1)ref, mode); + if (bp) { + *nc->sp++ = NARROWINS(NARROW_REF, bp->val); + *nc->sp++ = NARROWINS(NARROW_SEXT, 0); + return 0; + } + } + if (++depth < NARROW_MAX_BACKPROP && nc->sp < nc->maxsp) { + NarrowIns *savesp = nc->sp; + int count = narrow_conv_backprop(nc, ir->op1, depth); + count += narrow_conv_backprop(nc, ir->op2, depth); + if (count <= 1) { /* Limit total number of conversions. */ + *nc->sp++ = NARROWINS(IRT(ir->o, nc->t), ref); + return count; + } + nc->sp = savesp; /* Too many conversions, need to backtrack. */ + } + } + + /* Otherwise add a conversion. */ + *nc->sp++ = NARROWINS(NARROW_CONV, ref); + return 1; +} + +/* Emit the conversions collected during backpropagation. */ +static IRRef narrow_conv_emit(jit_State *J, NarrowConv *nc) +{ + /* The fins fields must be saved now -- emitir() overwrites them. */ + IROpT guardot = irt_isguard(fins->t) ? IRTG(IR_ADDOV-IR_ADD, 0) : 0; + IROpT convot = fins->ot; + IRRef1 convop2 = fins->op2; + NarrowIns *next = nc->stack; /* List of instructions from backpropagation. */ + NarrowIns *last = nc->sp; + NarrowIns *sp = nc->stack; /* Recycle the stack to store operands. */ + while (next < last) { /* Simple stack machine to process the ins. list. */ + NarrowIns ref = *next++; + IROpT op = narrow_op(ref); + if (op == NARROW_REF) { + *sp++ = ref; + } else if (op == NARROW_CONV) { + *sp++ = emitir_raw(convot, ref, convop2); /* Raw emit avoids a loop. */ + } else if (op == NARROW_SEXT) { + lj_assertJ(sp >= nc->stack+1, "stack underflow"); + sp[-1] = emitir(IRT(IR_CONV, IRT_I64), sp[-1], + (IRT_I64<<5)|IRT_INT|IRCONV_SEXT); + } else if (op == NARROW_INT) { + lj_assertJ(next < last, "missing arg to NARROW_INT"); + *sp++ = nc->t == IRT_I64 ? + lj_ir_kint64(J, (int64_t)(int32_t)*next++) : + lj_ir_kint(J, *next++); + } else { /* Regular IROpT. Pops two operands and pushes one result. */ + IRRef mode = nc->mode; + lj_assertJ(sp >= nc->stack+2, "stack underflow"); + sp--; + /* Omit some overflow checks for array indexing. See comments above. */ + if ((mode & IRCONV_CONVMASK) == IRCONV_INDEX) { + if (next == last && irref_isk(narrow_ref(sp[0])) && + (uint32_t)IR(narrow_ref(sp[0]))->i + 0x40000000u < 0x80000000u) + guardot = 0; + else /* Otherwise cache a stronger check. */ + mode += IRCONV_CHECK-IRCONV_INDEX; + } + sp[-1] = emitir(op+guardot, sp[-1], sp[0]); + /* Add to cache. */ + if (narrow_ref(ref)) + narrow_bpc_set(J, narrow_ref(ref), narrow_ref(sp[-1]), mode); + } + } + lj_assertJ(sp == nc->stack+1, "stack misalignment"); + return nc->stack[0]; +} + +/* Narrow a type conversion of an arithmetic operation. */ +TRef LJ_FASTCALL lj_opt_narrow_convert(jit_State *J) +{ + if ((J->flags & JIT_F_OPT_NARROW)) { + NarrowConv nc; + nc.J = J; + nc.sp = nc.stack; + nc.maxsp = &nc.stack[NARROW_MAX_STACK-4]; + nc.t = irt_type(fins->t); + if (fins->o == IR_TOBIT) { + nc.mode = IRCONV_TOBIT; /* Used only in the backpropagation cache. */ + } else { + nc.mode = fins->op2; + } + if (narrow_conv_backprop(&nc, fins->op1, 0) <= 1) + return narrow_conv_emit(J, &nc); + } + return NEXTFOLD; +} + +/* -- Narrowing of implicit conversions ----------------------------------- */ + +/* Recursively strip overflow checks. */ +static TRef narrow_stripov(jit_State *J, TRef tr, int lastop, IRRef mode) +{ + IRRef ref = tref_ref(tr); + IRIns *ir = IR(ref); + int op = ir->o; + if (op >= IR_ADDOV && op <= lastop) { + BPropEntry *bp = narrow_bpc_get(J, ref, mode); + if (bp) { + return TREF(bp->val, irt_t(IR(bp->val)->t)); + } else { + IRRef op1 = ir->op1, op2 = ir->op2; /* The IR may be reallocated. */ + op1 = narrow_stripov(J, op1, lastop, mode); + op2 = narrow_stripov(J, op2, lastop, mode); + tr = emitir(IRT(op - IR_ADDOV + IR_ADD, + ((mode & IRCONV_DSTMASK) >> IRCONV_DSH)), op1, op2); + narrow_bpc_set(J, ref, tref_ref(tr), mode); + } + } else if (LJ_64 && (mode & IRCONV_SEXT) && !irt_is64(ir->t)) { + tr = emitir(IRT(IR_CONV, IRT_INTP), tr, mode); + } + return tr; +} + +/* Narrow array index. */ +TRef LJ_FASTCALL lj_opt_narrow_index(jit_State *J, TRef tr) +{ + IRIns *ir; + lj_assertJ(tref_isnumber(tr), "expected number type"); + if (tref_isnum(tr)) /* Conversion may be narrowed, too. See above. */ + return emitir(IRTGI(IR_CONV), tr, IRCONV_INT_NUM|IRCONV_INDEX); + /* Omit some overflow checks for array indexing. See comments above. */ + ir = IR(tref_ref(tr)); + if ((ir->o == IR_ADDOV || ir->o == IR_SUBOV) && irref_isk(ir->op2) && + (uint32_t)IR(ir->op2)->i + 0x40000000u < 0x80000000u) + return emitir(IRTI(ir->o - IR_ADDOV + IR_ADD), ir->op1, ir->op2); + return tr; +} + +/* Narrow conversion to integer operand (overflow undefined). */ +TRef LJ_FASTCALL lj_opt_narrow_toint(jit_State *J, TRef tr) +{ + if (tref_isstr(tr)) + tr = emitir(IRTG(IR_STRTO, IRT_NUM), tr, 0); + if (tref_isnum(tr)) /* Conversion may be narrowed, too. See above. */ + return emitir(IRTI(IR_CONV), tr, IRCONV_INT_NUM|IRCONV_ANY); + if (!tref_isinteger(tr)) + lj_trace_err(J, LJ_TRERR_BADTYPE); + /* + ** Undefined overflow semantics allow stripping of ADDOV, SUBOV and MULOV. + ** Use IRCONV_TOBIT for the cache entries, since the semantics are the same. + */ + return narrow_stripov(J, tr, IR_MULOV, (IRT_INT<<5)|IRT_INT|IRCONV_TOBIT); +} + +/* Narrow conversion to bitop operand (overflow wrapped). */ +TRef LJ_FASTCALL lj_opt_narrow_tobit(jit_State *J, TRef tr) +{ + if (tref_isstr(tr)) + tr = emitir(IRTG(IR_STRTO, IRT_NUM), tr, 0); + if (tref_isnum(tr)) /* Conversion may be narrowed, too. See above. */ + return emitir(IRTI(IR_TOBIT), tr, lj_ir_knum_tobit(J)); + if (!tref_isinteger(tr)) + lj_trace_err(J, LJ_TRERR_BADTYPE); + /* + ** Wrapped overflow semantics allow stripping of ADDOV and SUBOV. + ** MULOV cannot be stripped due to precision widening. + */ + return narrow_stripov(J, tr, IR_SUBOV, (IRT_INT<<5)|IRT_INT|IRCONV_TOBIT); +} + +#if LJ_HASFFI +/* Narrow C array index (overflow undefined). */ +TRef LJ_FASTCALL lj_opt_narrow_cindex(jit_State *J, TRef tr) +{ + lj_assertJ(tref_isnumber(tr), "expected number type"); + if (tref_isnum(tr)) + return emitir(IRT(IR_CONV, IRT_INTP), tr, (IRT_INTP<<5)|IRT_NUM|IRCONV_ANY); + /* Undefined overflow semantics allow stripping of ADDOV, SUBOV and MULOV. */ + return narrow_stripov(J, tr, IR_MULOV, + LJ_64 ? ((IRT_INTP<<5)|IRT_INT|IRCONV_SEXT) : + ((IRT_INTP<<5)|IRT_INT|IRCONV_TOBIT)); +} +#endif + +/* -- Narrowing of arithmetic operators ----------------------------------- */ + +/* Check whether a number fits into an int32_t (-0 is ok, too). */ +static int numisint(lua_Number n) +{ + return (n == (lua_Number)lj_num2int(n)); +} + +/* Convert string to number. Error out for non-numeric string values. */ +static TRef conv_str_tonum(jit_State *J, TRef tr, TValue *o) +{ + if (tref_isstr(tr)) { + tr = emitir(IRTG(IR_STRTO, IRT_NUM), tr, 0); + /* Would need an inverted STRTO for this rare and useless case. */ + if (!lj_strscan_num(strV(o), o)) /* Convert in-place. Value used below. */ + lj_trace_err(J, LJ_TRERR_BADTYPE); /* Punt if non-numeric. */ + } + return tr; +} + +/* Narrowing of arithmetic operations. */ +TRef lj_opt_narrow_arith(jit_State *J, TRef rb, TRef rc, + TValue *vb, TValue *vc, IROp op) +{ + rb = conv_str_tonum(J, rb, vb); + rc = conv_str_tonum(J, rc, vc); + /* Must not narrow MUL in non-DUALNUM variant, because it loses -0. */ + if ((op >= IR_ADD && op <= (LJ_DUALNUM ? IR_MUL : IR_SUB)) && + tref_isinteger(rb) && tref_isinteger(rc) && + numisint(lj_vm_foldarith(numberVnum(vb), numberVnum(vc), + (int)op - (int)IR_ADD))) + return emitir(IRTGI((int)op - (int)IR_ADD + (int)IR_ADDOV), rb, rc); + if (!tref_isnum(rb)) rb = emitir(IRTN(IR_CONV), rb, IRCONV_NUM_INT); + if (!tref_isnum(rc)) rc = emitir(IRTN(IR_CONV), rc, IRCONV_NUM_INT); + return emitir(IRTN(op), rb, rc); +} + +/* Narrowing of unary minus operator. */ +TRef lj_opt_narrow_unm(jit_State *J, TRef rc, TValue *vc) +{ + rc = conv_str_tonum(J, rc, vc); + if (tref_isinteger(rc)) { + uint32_t k = (uint32_t)numberVint(vc); + if ((LJ_DUALNUM || k != 0) && k != 0x80000000u) { + TRef zero = lj_ir_kint(J, 0); + if (!LJ_DUALNUM) + emitir(IRTGI(IR_NE), rc, zero); + return emitir(IRTGI(IR_SUBOV), zero, rc); + } + rc = emitir(IRTN(IR_CONV), rc, IRCONV_NUM_INT); + } + return emitir(IRTN(IR_NEG), rc, lj_ir_ksimd(J, LJ_KSIMD_NEG)); +} + +/* Narrowing of modulo operator. */ +TRef lj_opt_narrow_mod(jit_State *J, TRef rb, TRef rc, TValue *vb, TValue *vc) +{ + TRef tmp; + rb = conv_str_tonum(J, rb, vb); + rc = conv_str_tonum(J, rc, vc); + if ((LJ_DUALNUM || (J->flags & JIT_F_OPT_NARROW)) && + tref_isinteger(rb) && tref_isinteger(rc) && + (tvisint(vc) ? intV(vc) != 0 : !tviszero(vc))) { + emitir(IRTGI(IR_NE), rc, lj_ir_kint(J, 0)); + return emitir(IRTI(IR_MOD), rb, rc); + } + /* b % c ==> b - floor(b/c)*c */ + rb = lj_ir_tonum(J, rb); + rc = lj_ir_tonum(J, rc); + tmp = emitir(IRTN(IR_DIV), rb, rc); + tmp = emitir(IRTN(IR_FPMATH), tmp, IRFPM_FLOOR); + tmp = emitir(IRTN(IR_MUL), tmp, rc); + return emitir(IRTN(IR_SUB), rb, tmp); +} + +/* -- Predictive narrowing of induction variables ------------------------- */ + +/* Narrow a single runtime value. */ +static int narrow_forl(jit_State *J, cTValue *o) +{ + if (tvisint(o)) return 1; + if (LJ_DUALNUM || (J->flags & JIT_F_OPT_NARROW)) return numisint(numV(o)); + return 0; +} + +/* Narrow the FORL index type by looking at the runtime values. */ +IRType lj_opt_narrow_forl(jit_State *J, cTValue *tv) +{ + lj_assertJ(tvisnumber(&tv[FORL_IDX]) && + tvisnumber(&tv[FORL_STOP]) && + tvisnumber(&tv[FORL_STEP]), + "expected number types"); + /* Narrow only if the runtime values of start/stop/step are all integers. */ + if (narrow_forl(J, &tv[FORL_IDX]) && + narrow_forl(J, &tv[FORL_STOP]) && + narrow_forl(J, &tv[FORL_STEP])) { + /* And if the loop index can't possibly overflow. */ + lua_Number step = numberVnum(&tv[FORL_STEP]); + lua_Number sum = numberVnum(&tv[FORL_STOP]) + step; + if (0 <= step ? (sum <= 2147483647.0) : (sum >= -2147483648.0)) + return IRT_INT; + } + return IRT_NUM; +} + +#undef IR +#undef fins +#undef emitir +#undef emitir_raw + +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_opt_sink.c b/fluent-bit/lib/luajit-3065c9/src/lj_opt_sink.c new file mode 100644 index 00000000..4b9008be --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_opt_sink.c @@ -0,0 +1,258 @@ +/* +** SINK: Allocation Sinking and Store Sinking. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#define lj_opt_sink_c +#define LUA_CORE + +#include "lj_obj.h" + +#if LJ_HASJIT + +#include "lj_ir.h" +#include "lj_jit.h" +#include "lj_iropt.h" +#include "lj_target.h" + +/* Some local macros to save typing. Undef'd at the end. */ +#define IR(ref) (&J->cur.ir[(ref)]) + +/* Check whether the store ref points to an eligible allocation. */ +static IRIns *sink_checkalloc(jit_State *J, IRIns *irs) +{ + IRIns *ir = IR(irs->op1); + if (!irref_isk(ir->op2)) + return NULL; /* Non-constant key. */ + if (ir->o == IR_HREFK || ir->o == IR_AREF) + ir = IR(ir->op1); + else if (!(ir->o == IR_HREF || ir->o == IR_NEWREF || + ir->o == IR_FREF || ir->o == IR_ADD)) + return NULL; /* Unhandled reference type (for XSTORE). */ + ir = IR(ir->op1); + if (!(ir->o == IR_TNEW || ir->o == IR_TDUP || ir->o == IR_CNEW)) + return NULL; /* Not an allocation. */ + return ir; /* Return allocation. */ +} + +/* Recursively check whether a value depends on a PHI. */ +static int sink_phidep(jit_State *J, IRRef ref, int *workp) +{ + IRIns *ir = IR(ref); + if (!*workp) return 1; /* Give up and pretend it does. */ + (*workp)--; + if (irt_isphi(ir->t)) return 1; + if (ir->op1 >= REF_FIRST && sink_phidep(J, ir->op1, workp)) return 1; + if (ir->op2 >= REF_FIRST && sink_phidep(J, ir->op2, workp)) return 1; + return 0; +} + +/* Check whether a value is a sinkable PHI or loop-invariant. */ +static int sink_checkphi(jit_State *J, IRIns *ira, IRRef ref) +{ + if (ref >= REF_FIRST) { + IRIns *ir = IR(ref); + if (irt_isphi(ir->t) || (ir->o == IR_CONV && ir->op2 == IRCONV_NUM_INT && + irt_isphi(IR(ir->op1)->t))) { + ira->prev++; + return 1; /* Sinkable PHI. */ + } + /* Otherwise the value must be loop-invariant. */ + if (ref < J->loopref) { + /* Check for PHI dependencies, but give up after reasonable effort. */ + int work = 64; + return !sink_phidep(J, ref, &work); + } else { + return 0; /* Loop-variant. */ + } + } + return 1; /* Constant (non-PHI). */ +} + +/* Mark non-sinkable allocations using single-pass backward propagation. +** +** Roots for the marking process are: +** - Some PHIs or snapshots (see below). +** - Non-PHI, non-constant values stored to PHI allocations. +** - All guards. +** - Any remaining loads not eliminated by store-to-load forwarding. +** - Stores with non-constant keys. +** - All stored values. +*/ +static void sink_mark_ins(jit_State *J) +{ + IRIns *ir, *irlast = IR(J->cur.nins-1); + for (ir = irlast ; ; ir--) { + switch (ir->o) { + case IR_BASE: + return; /* Finished. */ + case IR_ALOAD: case IR_HLOAD: case IR_XLOAD: case IR_TBAR: case IR_ALEN: + irt_setmark(IR(ir->op1)->t); /* Mark ref for remaining loads. */ + break; + case IR_FLOAD: + if (irt_ismarked(ir->t) || ir->op2 == IRFL_TAB_META) + irt_setmark(IR(ir->op1)->t); /* Mark table for remaining loads. */ + break; + case IR_ASTORE: case IR_HSTORE: case IR_FSTORE: case IR_XSTORE: { + IRIns *ira = sink_checkalloc(J, ir); + if (!ira || (irt_isphi(ira->t) && !sink_checkphi(J, ira, ir->op2))) + irt_setmark(IR(ir->op1)->t); /* Mark ineligible ref. */ + irt_setmark(IR(ir->op2)->t); /* Mark stored value. */ + break; + } +#if LJ_HASFFI + case IR_CNEWI: + if (irt_isphi(ir->t) && + (!sink_checkphi(J, ir, ir->op2) || + (LJ_32 && ir+1 < irlast && (ir+1)->o == IR_HIOP && + !sink_checkphi(J, ir, (ir+1)->op2)))) + irt_setmark(ir->t); /* Mark ineligible allocation. */ +#endif + /* fallthrough */ + case IR_USTORE: + irt_setmark(IR(ir->op2)->t); /* Mark stored value. */ + break; +#if LJ_HASFFI + case IR_CALLXS: +#endif + case IR_CALLS: + irt_setmark(IR(ir->op1)->t); /* Mark (potentially) stored values. */ + break; + case IR_PHI: { + IRIns *irl = IR(ir->op1), *irr = IR(ir->op2); + irl->prev = irr->prev = 0; /* Clear PHI value counts. */ + if (irl->o == irr->o && + (irl->o == IR_TNEW || irl->o == IR_TDUP || + (LJ_HASFFI && (irl->o == IR_CNEW || irl->o == IR_CNEWI)))) + break; + irt_setmark(irl->t); + irt_setmark(irr->t); + break; + } + default: + if (irt_ismarked(ir->t) || irt_isguard(ir->t)) { /* Propagate mark. */ + if (ir->op1 >= REF_FIRST) irt_setmark(IR(ir->op1)->t); + if (ir->op2 >= REF_FIRST) irt_setmark(IR(ir->op2)->t); + } + break; + } + } +} + +/* Mark all instructions referenced by a snapshot. */ +static void sink_mark_snap(jit_State *J, SnapShot *snap) +{ + SnapEntry *map = &J->cur.snapmap[snap->mapofs]; + MSize n, nent = snap->nent; + for (n = 0; n < nent; n++) { + IRRef ref = snap_ref(map[n]); + if (!irref_isk(ref)) + irt_setmark(IR(ref)->t); + } +} + +/* Iteratively remark PHI refs with differing marks or PHI value counts. */ +static void sink_remark_phi(jit_State *J) +{ + IRIns *ir; + int remark; + do { + remark = 0; + for (ir = IR(J->cur.nins-1); ir->o == IR_PHI; ir--) { + IRIns *irl = IR(ir->op1), *irr = IR(ir->op2); + if (!((irl->t.irt ^ irr->t.irt) & IRT_MARK) && irl->prev == irr->prev) + continue; + remark |= (~(irl->t.irt & irr->t.irt) & IRT_MARK); + irt_setmark(IR(ir->op1)->t); + irt_setmark(IR(ir->op2)->t); + } + } while (remark); +} + +/* Sweep instructions and tag sunken allocations and stores. */ +static void sink_sweep_ins(jit_State *J) +{ + IRIns *ir, *irbase = IR(REF_BASE); + for (ir = IR(J->cur.nins-1) ; ir >= irbase; ir--) { + switch (ir->o) { + case IR_ASTORE: case IR_HSTORE: case IR_FSTORE: case IR_XSTORE: { + IRIns *ira = sink_checkalloc(J, ir); + if (ira && !irt_ismarked(ira->t)) { + int delta = (int)(ir - ira); + ir->prev = REGSP(RID_SINK, delta > 255 ? 255 : delta); + } else { + ir->prev = REGSP_INIT; + } + break; + } + case IR_NEWREF: + if (!irt_ismarked(IR(ir->op1)->t)) { + ir->prev = REGSP(RID_SINK, 0); + } else { + irt_clearmark(ir->t); + ir->prev = REGSP_INIT; + } + break; +#if LJ_HASFFI + case IR_CNEW: case IR_CNEWI: +#endif + case IR_TNEW: case IR_TDUP: + if (!irt_ismarked(ir->t)) { + ir->t.irt &= ~IRT_GUARD; + ir->prev = REGSP(RID_SINK, 0); + J->cur.sinktags = 1; /* Signal present SINK tags to assembler. */ + } else { + irt_clearmark(ir->t); + ir->prev = REGSP_INIT; + } + break; + case IR_PHI: { + IRIns *ira = IR(ir->op2); + if (!irt_ismarked(ira->t) && + (ira->o == IR_TNEW || ira->o == IR_TDUP || + (LJ_HASFFI && (ira->o == IR_CNEW || ira->o == IR_CNEWI)))) { + ir->prev = REGSP(RID_SINK, 0); + } else { + ir->prev = REGSP_INIT; + } + break; + } + default: + irt_clearmark(ir->t); + ir->prev = REGSP_INIT; + break; + } + } + for (ir = IR(J->cur.nk); ir < irbase; ir++) { + irt_clearmark(ir->t); + ir->prev = REGSP_INIT; + /* The false-positive of irt_is64() for ASMREF_L (REF_NIL) is OK here. */ + if (irt_is64(ir->t) && ir->o != IR_KNULL) + ir++; + } +} + +/* Allocation sinking and store sinking. +** +** 1. Mark all non-sinkable allocations. +** 2. Then sink all remaining allocations and the related stores. +*/ +void lj_opt_sink(jit_State *J) +{ + const uint32_t need = (JIT_F_OPT_SINK|JIT_F_OPT_FWD| + JIT_F_OPT_DCE|JIT_F_OPT_CSE|JIT_F_OPT_FOLD); + if ((J->flags & need) == need && + (J->chain[IR_TNEW] || J->chain[IR_TDUP] || + (LJ_HASFFI && (J->chain[IR_CNEW] || J->chain[IR_CNEWI])))) { + if (!J->loopref) + sink_mark_snap(J, &J->cur.snap[J->cur.nsnap-1]); + sink_mark_ins(J); + if (J->loopref) + sink_remark_phi(J); + sink_sweep_ins(J); + } +} + +#undef IR + +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_opt_split.c b/fluent-bit/lib/luajit-3065c9/src/lj_opt_split.c new file mode 100644 index 00000000..506b9814 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_opt_split.c @@ -0,0 +1,848 @@ +/* +** SPLIT: Split 64 bit IR instructions into 32 bit IR instructions. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#define lj_opt_split_c +#define LUA_CORE + +#include "lj_obj.h" + +#if LJ_HASJIT && (LJ_SOFTFP32 || (LJ_32 && LJ_HASFFI)) + +#include "lj_err.h" +#include "lj_buf.h" +#include "lj_ir.h" +#include "lj_jit.h" +#include "lj_ircall.h" +#include "lj_iropt.h" +#include "lj_dispatch.h" +#include "lj_vm.h" + +/* SPLIT pass: +** +** This pass splits up 64 bit IR instructions into multiple 32 bit IR +** instructions. It's only active for soft-float targets or for 32 bit CPUs +** which lack native 64 bit integer operations (the FFI is currently the +** only emitter for 64 bit integer instructions). +** +** Splitting the IR in a separate pass keeps each 32 bit IR assembler +** backend simple. Only a small amount of extra functionality needs to be +** implemented. This is much easier than adding support for allocating +** register pairs to each backend (believe me, I tried). A few simple, but +** important optimizations can be performed by the SPLIT pass, which would +** be tedious to do in the backend. +** +** The basic idea is to replace each 64 bit IR instruction with its 32 bit +** equivalent plus an extra HIOP instruction. The splitted IR is not passed +** through FOLD or any other optimizations, so each HIOP is guaranteed to +** immediately follow it's counterpart. The actual functionality of HIOP is +** inferred from the previous instruction. +** +** The operands of HIOP hold the hiword input references. The output of HIOP +** is the hiword output reference, which is also used to hold the hiword +** register or spill slot information. The register allocator treats this +** instruction independently of any other instruction, which improves code +** quality compared to using fixed register pairs. +** +** It's easier to split up some instructions into two regular 32 bit +** instructions. E.g. XLOAD is split up into two XLOADs with two different +** addresses. Obviously 64 bit constants need to be split up into two 32 bit +** constants, too. Some hiword instructions can be entirely omitted, e.g. +** when zero-extending a 32 bit value to 64 bits. 64 bit arguments for calls +** are split up into two 32 bit arguments each. +** +** On soft-float targets, floating-point instructions are directly converted +** to soft-float calls by the SPLIT pass (except for comparisons and MIN/MAX). +** HIOP for number results has the type IRT_SOFTFP ("sfp" in -jdump). +** +** Here's the IR and x64 machine code for 'x.b = x.a + 1' for a struct with +** two int64_t fields: +** +** 0100 p32 ADD base +8 +** 0101 i64 XLOAD 0100 +** 0102 i64 ADD 0101 +1 +** 0103 p32 ADD base +16 +** 0104 i64 XSTORE 0103 0102 +** +** mov rax, [esi+0x8] +** add rax, +0x01 +** mov [esi+0x10], rax +** +** Here's the transformed IR and the x86 machine code after the SPLIT pass: +** +** 0100 p32 ADD base +8 +** 0101 int XLOAD 0100 +** 0102 p32 ADD base +12 +** 0103 int XLOAD 0102 +** 0104 int ADD 0101 +1 +** 0105 int HIOP 0103 +0 +** 0106 p32 ADD base +16 +** 0107 int XSTORE 0106 0104 +** 0108 int HIOP 0106 0105 +** +** mov eax, [esi+0x8] +** mov ecx, [esi+0xc] +** add eax, +0x01 +** adc ecx, +0x00 +** mov [esi+0x10], eax +** mov [esi+0x14], ecx +** +** You may notice the reassociated hiword address computation, which is +** later fused into the mov operands by the assembler. +*/ + +/* Some local macros to save typing. Undef'd at the end. */ +#define IR(ref) (&J->cur.ir[(ref)]) + +/* Directly emit the transformed IR without updating chains etc. */ +static IRRef split_emit(jit_State *J, uint16_t ot, IRRef1 op1, IRRef1 op2) +{ + IRRef nref = lj_ir_nextins(J); + IRIns *ir = IR(nref); + ir->ot = ot; + ir->op1 = op1; + ir->op2 = op2; + return nref; +} + +#if LJ_SOFTFP +/* Emit a (checked) number to integer conversion. */ +static IRRef split_num2int(jit_State *J, IRRef lo, IRRef hi, int check) +{ + IRRef tmp, res; +#if LJ_LE + tmp = split_emit(J, IRT(IR_CARG, IRT_NIL), lo, hi); +#else + tmp = split_emit(J, IRT(IR_CARG, IRT_NIL), hi, lo); +#endif + res = split_emit(J, IRTI(IR_CALLN), tmp, IRCALL_softfp_d2i); + if (check) { + tmp = split_emit(J, IRTI(IR_CALLN), res, IRCALL_softfp_i2d); + split_emit(J, IRT(IR_HIOP, IRT_SOFTFP), tmp, tmp); + split_emit(J, IRTGI(IR_EQ), tmp, lo); + split_emit(J, IRTG(IR_HIOP, IRT_SOFTFP), tmp+1, hi); + } + return res; +} + +/* Emit a CALLN with one split 64 bit argument. */ +static IRRef split_call_l(jit_State *J, IRRef1 *hisubst, IRIns *oir, + IRIns *ir, IRCallID id) +{ + IRRef tmp, op1 = ir->op1; + J->cur.nins--; +#if LJ_LE + tmp = split_emit(J, IRT(IR_CARG, IRT_NIL), oir[op1].prev, hisubst[op1]); +#else + tmp = split_emit(J, IRT(IR_CARG, IRT_NIL), hisubst[op1], oir[op1].prev); +#endif + ir->prev = tmp = split_emit(J, IRTI(IR_CALLN), tmp, id); + return split_emit(J, IRT(IR_HIOP, IRT_SOFTFP), tmp, tmp); +} +#endif + +/* Emit a CALLN with one split 64 bit argument and a 32 bit argument. */ +static IRRef split_call_li(jit_State *J, IRRef1 *hisubst, IRIns *oir, + IRIns *ir, IRCallID id) +{ + IRRef tmp, op1 = ir->op1, op2 = ir->op2; + J->cur.nins--; +#if LJ_LE + tmp = split_emit(J, IRT(IR_CARG, IRT_NIL), oir[op1].prev, hisubst[op1]); +#else + tmp = split_emit(J, IRT(IR_CARG, IRT_NIL), hisubst[op1], oir[op1].prev); +#endif + tmp = split_emit(J, IRT(IR_CARG, IRT_NIL), tmp, oir[op2].prev); + ir->prev = tmp = split_emit(J, IRTI(IR_CALLN), tmp, id); + return split_emit(J, IRT(IR_HIOP, IRT_SOFTFP), tmp, tmp); +} + +/* Emit a CALLN with two split 64 bit arguments. */ +static IRRef split_call_ll(jit_State *J, IRRef1 *hisubst, IRIns *oir, + IRIns *ir, IRCallID id) +{ + IRRef tmp, op1 = ir->op1, op2 = ir->op2; + J->cur.nins--; +#if LJ_LE + tmp = split_emit(J, IRT(IR_CARG, IRT_NIL), oir[op1].prev, hisubst[op1]); + tmp = split_emit(J, IRT(IR_CARG, IRT_NIL), tmp, oir[op2].prev); + tmp = split_emit(J, IRT(IR_CARG, IRT_NIL), tmp, hisubst[op2]); +#else + tmp = split_emit(J, IRT(IR_CARG, IRT_NIL), hisubst[op1], oir[op1].prev); + tmp = split_emit(J, IRT(IR_CARG, IRT_NIL), tmp, hisubst[op2]); + tmp = split_emit(J, IRT(IR_CARG, IRT_NIL), tmp, oir[op2].prev); +#endif + ir->prev = tmp = split_emit(J, IRTI(IR_CALLN), tmp, id); + return split_emit(J, + IRT(IR_HIOP, (LJ_SOFTFP && irt_isnum(ir->t)) ? IRT_SOFTFP : IRT_INT), + tmp, tmp); +} + +/* Get a pointer to the other 32 bit word (LE: hiword, BE: loword). */ +static IRRef split_ptr(jit_State *J, IRIns *oir, IRRef ref) +{ + IRRef nref = oir[ref].prev; + IRIns *ir = IR(nref); + int32_t ofs = 4; + if (ir->o == IR_KPTR) + return lj_ir_kptr(J, (char *)ir_kptr(ir) + ofs); + if (ir->o == IR_ADD && irref_isk(ir->op2) && !irt_isphi(oir[ref].t)) { + /* Reassociate address. */ + ofs += IR(ir->op2)->i; + nref = ir->op1; + if (ofs == 0) return nref; + } + return split_emit(J, IRT(IR_ADD, IRT_PTR), nref, lj_ir_kint(J, ofs)); +} + +#if LJ_HASFFI +static IRRef split_bitshift(jit_State *J, IRRef1 *hisubst, + IRIns *oir, IRIns *nir, IRIns *ir) +{ + IROp op = ir->o; + IRRef kref = nir->op2; + if (irref_isk(kref)) { /* Optimize constant shifts. */ + int32_t k = (IR(kref)->i & 63); + IRRef lo = nir->op1, hi = hisubst[ir->op1]; + if (op == IR_BROL || op == IR_BROR) { + if (op == IR_BROR) k = (-k & 63); + if (k >= 32) { IRRef t = lo; lo = hi; hi = t; k -= 32; } + if (k == 0) { + passthrough: + J->cur.nins--; + ir->prev = lo; + return hi; + } else { + TRef k1, k2; + IRRef t1, t2, t3, t4; + J->cur.nins--; + k1 = lj_ir_kint(J, k); + k2 = lj_ir_kint(J, (-k & 31)); + t1 = split_emit(J, IRTI(IR_BSHL), lo, k1); + t2 = split_emit(J, IRTI(IR_BSHL), hi, k1); + t3 = split_emit(J, IRTI(IR_BSHR), lo, k2); + t4 = split_emit(J, IRTI(IR_BSHR), hi, k2); + ir->prev = split_emit(J, IRTI(IR_BOR), t1, t4); + return split_emit(J, IRTI(IR_BOR), t2, t3); + } + } else if (k == 0) { + goto passthrough; + } else if (k < 32) { + if (op == IR_BSHL) { + IRRef t1 = split_emit(J, IRTI(IR_BSHL), hi, kref); + IRRef t2 = split_emit(J, IRTI(IR_BSHR), lo, lj_ir_kint(J, (-k&31))); + return split_emit(J, IRTI(IR_BOR), t1, t2); + } else { + IRRef t1 = ir->prev, t2; + lj_assertJ(op == IR_BSHR || op == IR_BSAR, "bad usage"); + nir->o = IR_BSHR; + t2 = split_emit(J, IRTI(IR_BSHL), hi, lj_ir_kint(J, (-k&31))); + ir->prev = split_emit(J, IRTI(IR_BOR), t1, t2); + return split_emit(J, IRTI(op), hi, kref); + } + } else { + if (op == IR_BSHL) { + if (k == 32) + J->cur.nins--; + else + lo = ir->prev; + ir->prev = lj_ir_kint(J, 0); + return lo; + } else { + lj_assertJ(op == IR_BSHR || op == IR_BSAR, "bad usage"); + if (k == 32) { + J->cur.nins--; + ir->prev = hi; + } else { + nir->op1 = hi; + } + if (op == IR_BSHR) + return lj_ir_kint(J, 0); + else + return split_emit(J, IRTI(IR_BSAR), hi, lj_ir_kint(J, 31)); + } + } + } + return split_call_li(J, hisubst, oir, ir, + op - IR_BSHL + IRCALL_lj_carith_shl64); +} + +static IRRef split_bitop(jit_State *J, IRRef1 *hisubst, + IRIns *nir, IRIns *ir) +{ + IROp op = ir->o; + IRRef hi, kref = nir->op2; + if (irref_isk(kref)) { /* Optimize bit operations with lo constant. */ + int32_t k = IR(kref)->i; + if (k == 0 || k == -1) { + if (op == IR_BAND) k = ~k; + if (k == 0) { + J->cur.nins--; + ir->prev = nir->op1; + } else if (op == IR_BXOR) { + nir->o = IR_BNOT; + nir->op2 = 0; + } else { + J->cur.nins--; + ir->prev = kref; + } + } + } + hi = hisubst[ir->op1]; + kref = hisubst[ir->op2]; + if (irref_isk(kref)) { /* Optimize bit operations with hi constant. */ + int32_t k = IR(kref)->i; + if (k == 0 || k == -1) { + if (op == IR_BAND) k = ~k; + if (k == 0) { + return hi; + } else if (op == IR_BXOR) { + return split_emit(J, IRTI(IR_BNOT), hi, 0); + } else { + return kref; + } + } + } + return split_emit(J, IRTI(op), hi, kref); +} +#endif + +/* Substitute references of a snapshot. */ +static void split_subst_snap(jit_State *J, SnapShot *snap, IRIns *oir) +{ + SnapEntry *map = &J->cur.snapmap[snap->mapofs]; + MSize n, nent = snap->nent; + for (n = 0; n < nent; n++) { + SnapEntry sn = map[n]; + IRIns *ir = &oir[snap_ref(sn)]; + if (!(LJ_SOFTFP && (sn & SNAP_SOFTFPNUM) && irref_isk(snap_ref(sn)))) + map[n] = ((sn & 0xffff0000) | ir->prev); + } +} + +/* Transform the old IR to the new IR. */ +static void split_ir(jit_State *J) +{ + IRRef nins = J->cur.nins, nk = J->cur.nk; + MSize irlen = nins - nk; + MSize need = (irlen+1)*(sizeof(IRIns) + sizeof(IRRef1)); + IRIns *oir = (IRIns *)lj_buf_tmp(J->L, need); + IRRef1 *hisubst; + IRRef ref, snref; + SnapShot *snap; + + /* Copy old IR to buffer. */ + memcpy(oir, IR(nk), irlen*sizeof(IRIns)); + /* Bias hiword substitution table and old IR. Loword kept in field prev. */ + hisubst = (IRRef1 *)&oir[irlen] - nk; + oir -= nk; + + /* Remove all IR instructions, but retain IR constants. */ + J->cur.nins = REF_FIRST; + J->loopref = 0; + + /* Process constants and fixed references. */ + for (ref = nk; ref <= REF_BASE; ref++) { + IRIns *ir = &oir[ref]; + if ((LJ_SOFTFP && ir->o == IR_KNUM) || ir->o == IR_KINT64) { + /* Split up 64 bit constant. */ + TValue tv = *ir_k64(ir); + ir->prev = lj_ir_kint(J, (int32_t)tv.u32.lo); + hisubst[ref] = lj_ir_kint(J, (int32_t)tv.u32.hi); + } else { + ir->prev = ref; /* Identity substitution for loword. */ + hisubst[ref] = 0; + } + if (irt_is64(ir->t) && ir->o != IR_KNULL) + ref++; + } + + /* Process old IR instructions. */ + snap = J->cur.snap; + snref = snap->ref; + for (ref = REF_FIRST; ref < nins; ref++) { + IRIns *ir = &oir[ref]; + IRRef nref = lj_ir_nextins(J); + IRIns *nir = IR(nref); + IRRef hi = 0; + + if (ref >= snref) { + snap->ref = nref; + split_subst_snap(J, snap++, oir); + snref = snap < &J->cur.snap[J->cur.nsnap] ? snap->ref : ~(IRRef)0; + } + + /* Copy-substitute old instruction to new instruction. */ + nir->op1 = ir->op1 < nk ? ir->op1 : oir[ir->op1].prev; + nir->op2 = ir->op2 < nk ? ir->op2 : oir[ir->op2].prev; + ir->prev = nref; /* Loword substitution. */ + nir->o = ir->o; + nir->t.irt = ir->t.irt & ~(IRT_MARK|IRT_ISPHI); + hisubst[ref] = 0; + + /* Split 64 bit instructions. */ +#if LJ_SOFTFP + if (irt_isnum(ir->t)) { + nir->t.irt = IRT_INT | (nir->t.irt & IRT_GUARD); /* Turn into INT op. */ + /* Note: hi ref = lo ref + 1! Required for SNAP_SOFTFPNUM logic. */ + switch (ir->o) { + case IR_ADD: + hi = split_call_ll(J, hisubst, oir, ir, IRCALL_softfp_add); + break; + case IR_SUB: + hi = split_call_ll(J, hisubst, oir, ir, IRCALL_softfp_sub); + break; + case IR_MUL: + hi = split_call_ll(J, hisubst, oir, ir, IRCALL_softfp_mul); + break; + case IR_DIV: + hi = split_call_ll(J, hisubst, oir, ir, IRCALL_softfp_div); + break; + case IR_POW: + hi = split_call_ll(J, hisubst, oir, ir, IRCALL_pow); + break; + case IR_FPMATH: + hi = split_call_l(J, hisubst, oir, ir, IRCALL_lj_vm_floor + ir->op2); + break; + case IR_LDEXP: + hi = split_call_li(J, hisubst, oir, ir, IRCALL_ldexp); + break; + case IR_NEG: case IR_ABS: + nir->o = IR_CONV; /* Pass through loword. */ + nir->op2 = (IRT_INT << 5) | IRT_INT; + hi = split_emit(J, IRT(ir->o == IR_NEG ? IR_BXOR : IR_BAND, IRT_SOFTFP), + hisubst[ir->op1], + lj_ir_kint(J, (int32_t)(0x7fffffffu + (ir->o == IR_NEG)))); + break; + case IR_SLOAD: + if ((nir->op2 & IRSLOAD_CONVERT)) { /* Convert from int to number. */ + nir->op2 &= ~IRSLOAD_CONVERT; + ir->prev = nref = split_emit(J, IRTI(IR_CALLN), nref, + IRCALL_softfp_i2d); + hi = split_emit(J, IRT(IR_HIOP, IRT_SOFTFP), nref, nref); + break; + } + /* fallthrough */ + case IR_ALOAD: case IR_HLOAD: case IR_ULOAD: case IR_VLOAD: + case IR_STRTO: + hi = split_emit(J, IRT(IR_HIOP, IRT_SOFTFP), nref, nref); + break; + case IR_FLOAD: + lj_assertJ(ir->op1 == REF_NIL, "expected FLOAD from GG_State"); + hi = lj_ir_kint(J, *(int32_t*)((char*)J2GG(J) + ir->op2 + LJ_LE*4)); + nir->op2 += LJ_BE*4; + break; + case IR_XLOAD: { + IRIns inslo = *nir; /* Save/undo the emit of the lo XLOAD. */ + J->cur.nins--; + hi = split_ptr(J, oir, ir->op1); /* Insert the hiref ADD. */ +#if LJ_BE + hi = split_emit(J, IRT(IR_XLOAD, IRT_INT), hi, ir->op2); + inslo.t.irt = IRT_SOFTFP | (inslo.t.irt & IRT_GUARD); +#endif + nref = lj_ir_nextins(J); + nir = IR(nref); + *nir = inslo; /* Re-emit lo XLOAD. */ +#if LJ_LE + hi = split_emit(J, IRT(IR_XLOAD, IRT_SOFTFP), hi, ir->op2); + ir->prev = nref; +#else + ir->prev = hi; hi = nref; +#endif + break; + } + case IR_ASTORE: case IR_HSTORE: case IR_USTORE: case IR_XSTORE: + split_emit(J, IRT(IR_HIOP, IRT_SOFTFP), nir->op1, hisubst[ir->op2]); + break; + case IR_CONV: { /* Conversion to number. Others handled below. */ + IRType st = (IRType)(ir->op2 & IRCONV_SRCMASK); + UNUSED(st); +#if LJ_32 && LJ_HASFFI + if (st == IRT_I64 || st == IRT_U64) { + hi = split_call_l(J, hisubst, oir, ir, + st == IRT_I64 ? IRCALL_fp64_l2d : IRCALL_fp64_ul2d); + break; + } +#endif + lj_assertJ(st == IRT_INT || + (LJ_32 && LJ_HASFFI && (st == IRT_U32 || st == IRT_FLOAT)), + "bad source type for CONV"); + nir->o = IR_CALLN; +#if LJ_32 && LJ_HASFFI + nir->op2 = st == IRT_INT ? IRCALL_softfp_i2d : + st == IRT_FLOAT ? IRCALL_softfp_f2d : + IRCALL_softfp_ui2d; +#else + nir->op2 = IRCALL_softfp_i2d; +#endif + hi = split_emit(J, IRT(IR_HIOP, IRT_SOFTFP), nref, nref); + break; + } + case IR_CALLN: + case IR_CALLL: + case IR_CALLS: + case IR_CALLXS: + goto split_call; + case IR_PHI: + if (nir->op1 == nir->op2) + J->cur.nins--; /* Drop useless PHIs. */ + if (hisubst[ir->op1] != hisubst[ir->op2]) + split_emit(J, IRT(IR_PHI, IRT_SOFTFP), + hisubst[ir->op1], hisubst[ir->op2]); + break; + case IR_HIOP: + J->cur.nins--; /* Drop joining HIOP. */ + ir->prev = nir->op1; + hi = nir->op2; + break; + default: + lj_assertJ(ir->o <= IR_NE || ir->o == IR_MIN || ir->o == IR_MAX, + "bad IR op %d", ir->o); + hi = split_emit(J, IRTG(IR_HIOP, IRT_SOFTFP), + hisubst[ir->op1], hisubst[ir->op2]); + break; + } + } else +#endif +#if LJ_32 && LJ_HASFFI + if (irt_isint64(ir->t)) { + IRRef hiref = hisubst[ir->op1]; + nir->t.irt = IRT_INT | (nir->t.irt & IRT_GUARD); /* Turn into INT op. */ + switch (ir->o) { + case IR_ADD: + case IR_SUB: + /* Use plain op for hiword if loword cannot produce a carry/borrow. */ + if (irref_isk(nir->op2) && IR(nir->op2)->i == 0) { + ir->prev = nir->op1; /* Pass through loword. */ + nir->op1 = hiref; nir->op2 = hisubst[ir->op2]; + hi = nref; + break; + } + /* fallthrough */ + case IR_NEG: + hi = split_emit(J, IRTI(IR_HIOP), hiref, hisubst[ir->op2]); + break; + case IR_MUL: + hi = split_call_ll(J, hisubst, oir, ir, IRCALL_lj_carith_mul64); + break; + case IR_DIV: + hi = split_call_ll(J, hisubst, oir, ir, + irt_isi64(ir->t) ? IRCALL_lj_carith_divi64 : + IRCALL_lj_carith_divu64); + break; + case IR_MOD: + hi = split_call_ll(J, hisubst, oir, ir, + irt_isi64(ir->t) ? IRCALL_lj_carith_modi64 : + IRCALL_lj_carith_modu64); + break; + case IR_POW: + hi = split_call_ll(J, hisubst, oir, ir, + irt_isi64(ir->t) ? IRCALL_lj_carith_powi64 : + IRCALL_lj_carith_powu64); + break; + case IR_BNOT: + hi = split_emit(J, IRTI(IR_BNOT), hiref, 0); + break; + case IR_BSWAP: + ir->prev = split_emit(J, IRTI(IR_BSWAP), hiref, 0); + hi = nref; + break; + case IR_BAND: case IR_BOR: case IR_BXOR: + hi = split_bitop(J, hisubst, nir, ir); + break; + case IR_BSHL: case IR_BSHR: case IR_BSAR: case IR_BROL: case IR_BROR: + hi = split_bitshift(J, hisubst, oir, nir, ir); + break; + case IR_FLOAD: + lj_assertJ(ir->op2 == IRFL_CDATA_INT64, "only INT64 supported"); + hi = split_emit(J, IRTI(IR_FLOAD), nir->op1, IRFL_CDATA_INT64_4); +#if LJ_BE + ir->prev = hi; hi = nref; +#endif + break; + case IR_XLOAD: + hi = split_emit(J, IRTI(IR_XLOAD), split_ptr(J, oir, ir->op1), ir->op2); +#if LJ_BE + ir->prev = hi; hi = nref; +#endif + break; + case IR_XSTORE: + split_emit(J, IRTI(IR_HIOP), nir->op1, hisubst[ir->op2]); + break; + case IR_CONV: { /* Conversion to 64 bit integer. Others handled below. */ + IRType st = (IRType)(ir->op2 & IRCONV_SRCMASK); +#if LJ_SOFTFP + if (st == IRT_NUM) { /* NUM to 64 bit int conv. */ + hi = split_call_l(J, hisubst, oir, ir, + irt_isi64(ir->t) ? IRCALL_fp64_d2l : IRCALL_fp64_d2ul); + } else if (st == IRT_FLOAT) { /* FLOAT to 64 bit int conv. */ + nir->o = IR_CALLN; + nir->op2 = irt_isi64(ir->t) ? IRCALL_fp64_f2l : IRCALL_fp64_f2ul; + hi = split_emit(J, IRTI(IR_HIOP), nref, nref); + } +#else + if (st == IRT_NUM || st == IRT_FLOAT) { /* FP to 64 bit int conv. */ + hi = split_emit(J, IRTI(IR_HIOP), nir->op1, nref); + } +#endif + else if (st == IRT_I64 || st == IRT_U64) { /* 64/64 bit cast. */ + /* Drop cast, since assembler doesn't care. But fwd both parts. */ + hi = hiref; + goto fwdlo; + } else if ((ir->op2 & IRCONV_SEXT)) { /* Sign-extend to 64 bit. */ + IRRef k31 = lj_ir_kint(J, 31); + nir = IR(nref); /* May have been reallocated. */ + ir->prev = nir->op1; /* Pass through loword. */ + nir->o = IR_BSAR; /* hi = bsar(lo, 31). */ + nir->op2 = k31; + hi = nref; + } else { /* Zero-extend to 64 bit. */ + hi = lj_ir_kint(J, 0); + goto fwdlo; + } + break; + } + case IR_CALLXS: + goto split_call; + case IR_PHI: { + IRRef hiref2; + if ((irref_isk(nir->op1) && irref_isk(nir->op2)) || + nir->op1 == nir->op2) + J->cur.nins--; /* Drop useless PHIs. */ + hiref2 = hisubst[ir->op2]; + if (!((irref_isk(hiref) && irref_isk(hiref2)) || hiref == hiref2)) + split_emit(J, IRTI(IR_PHI), hiref, hiref2); + break; + } + case IR_HIOP: + J->cur.nins--; /* Drop joining HIOP. */ + ir->prev = nir->op1; + hi = nir->op2; + break; + default: + lj_assertJ(ir->o <= IR_NE, "bad IR op %d", ir->o); /* Comparisons. */ + split_emit(J, IRTGI(IR_HIOP), hiref, hisubst[ir->op2]); + break; + } + } else +#endif +#if LJ_SOFTFP + if (ir->o == IR_SLOAD) { + if ((nir->op2 & IRSLOAD_CONVERT)) { /* Convert from number to int. */ + nir->op2 &= ~IRSLOAD_CONVERT; + if (!(nir->op2 & IRSLOAD_TYPECHECK)) + nir->t.irt = IRT_INT; /* Drop guard. */ + split_emit(J, IRT(IR_HIOP, IRT_SOFTFP), nref, nref); + ir->prev = split_num2int(J, nref, nref+1, irt_isguard(ir->t)); + } + } else if (ir->o == IR_TOBIT) { + IRRef tmp, op1 = ir->op1; + J->cur.nins--; +#if LJ_LE + tmp = split_emit(J, IRT(IR_CARG, IRT_NIL), oir[op1].prev, hisubst[op1]); +#else + tmp = split_emit(J, IRT(IR_CARG, IRT_NIL), hisubst[op1], oir[op1].prev); +#endif + ir->prev = split_emit(J, IRTI(IR_CALLN), tmp, IRCALL_lj_vm_tobit); + } else if (ir->o == IR_TOSTR || ir->o == IR_TMPREF) { + if (hisubst[ir->op1]) { + if (irref_isk(ir->op1)) + nir->op1 = ir->op1; + else + split_emit(J, IRT(IR_HIOP, IRT_NIL), hisubst[ir->op1], nref); + } + } else if (ir->o == IR_HREF || ir->o == IR_NEWREF) { + if (irref_isk(ir->op2) && hisubst[ir->op2]) + nir->op2 = ir->op2; + } else +#endif + if (ir->o == IR_CONV) { /* See above, too. */ + IRType st = (IRType)(ir->op2 & IRCONV_SRCMASK); +#if LJ_32 && LJ_HASFFI + if (st == IRT_I64 || st == IRT_U64) { /* Conversion from 64 bit int. */ +#if LJ_SOFTFP + if (irt_isfloat(ir->t)) { + split_call_l(J, hisubst, oir, ir, + st == IRT_I64 ? IRCALL_fp64_l2f : IRCALL_fp64_ul2f); + J->cur.nins--; /* Drop unused HIOP. */ + } +#else + if (irt_isfp(ir->t)) { /* 64 bit integer to FP conversion. */ + ir->prev = split_emit(J, IRT(IR_HIOP, irt_type(ir->t)), + hisubst[ir->op1], nref); + } +#endif + else { /* Truncate to lower 32 bits. */ + fwdlo: + ir->prev = nir->op1; /* Forward loword. */ + /* Replace with NOP to avoid messing up the snapshot logic. */ + nir->ot = IRT(IR_NOP, IRT_NIL); + nir->op1 = nir->op2 = 0; + } + } +#endif +#if LJ_SOFTFP && LJ_32 && LJ_HASFFI + else if (irt_isfloat(ir->t)) { + if (st == IRT_NUM) { + split_call_l(J, hisubst, oir, ir, IRCALL_softfp_d2f); + J->cur.nins--; /* Drop unused HIOP. */ + } else { + nir->o = IR_CALLN; + nir->op2 = st == IRT_INT ? IRCALL_softfp_i2f : IRCALL_softfp_ui2f; + } + } else if (st == IRT_FLOAT) { + nir->o = IR_CALLN; + nir->op2 = irt_isint(ir->t) ? IRCALL_softfp_f2i : IRCALL_softfp_f2ui; + } else +#endif +#if LJ_SOFTFP + if (st == IRT_NUM || (LJ_32 && LJ_HASFFI && st == IRT_FLOAT)) { + if (irt_isguard(ir->t)) { + lj_assertJ(st == IRT_NUM && irt_isint(ir->t), "bad CONV types"); + J->cur.nins--; + ir->prev = split_num2int(J, nir->op1, hisubst[ir->op1], 1); + } else { + split_call_l(J, hisubst, oir, ir, +#if LJ_32 && LJ_HASFFI + st == IRT_NUM ? + (irt_isint(ir->t) ? IRCALL_softfp_d2i : IRCALL_softfp_d2ui) : + (irt_isint(ir->t) ? IRCALL_softfp_f2i : IRCALL_softfp_f2ui) +#else + IRCALL_softfp_d2i +#endif + ); + J->cur.nins--; /* Drop unused HIOP. */ + } + } +#endif + } else if (ir->o == IR_CALLXS) { + IRRef hiref; + split_call: + hiref = hisubst[ir->op1]; + if (hiref) { + IROpT ot = nir->ot; + IRRef op2 = nir->op2; + nir->ot = IRT(IR_CARG, IRT_NIL); +#if LJ_LE + nir->op2 = hiref; +#else + nir->op2 = nir->op1; nir->op1 = hiref; +#endif + ir->prev = nref = split_emit(J, ot, nref, op2); + } + if (LJ_SOFTFP ? irt_is64(ir->t) : irt_isint64(ir->t)) + hi = split_emit(J, + IRT(IR_HIOP, (LJ_SOFTFP && irt_isnum(ir->t)) ? IRT_SOFTFP : IRT_INT), + nref, nref); + } else if (ir->o == IR_CARG) { + IRRef hiref = hisubst[ir->op1]; + if (hiref) { + IRRef op2 = nir->op2; +#if LJ_LE + nir->op2 = hiref; +#else + nir->op2 = nir->op1; nir->op1 = hiref; +#endif + ir->prev = nref = split_emit(J, IRT(IR_CARG, IRT_NIL), nref, op2); + nir = IR(nref); + } + hiref = hisubst[ir->op2]; + if (hiref) { +#if !LJ_TARGET_X86 + int carg = 0; + IRIns *cir; + for (cir = IR(nir->op1); cir->o == IR_CARG; cir = IR(cir->op1)) + carg++; + if ((carg & 1) == 0) { /* Align 64 bit arguments. */ + IRRef op2 = nir->op2; + nir->op2 = REF_NIL; + nref = split_emit(J, IRT(IR_CARG, IRT_NIL), nref, op2); + nir = IR(nref); + } +#endif +#if LJ_BE + { IRRef tmp = nir->op2; nir->op2 = hiref; hiref = tmp; } +#endif + ir->prev = split_emit(J, IRT(IR_CARG, IRT_NIL), nref, hiref); + } + } else if (ir->o == IR_CNEWI) { + if (hisubst[ir->op2]) + split_emit(J, IRT(IR_HIOP, IRT_NIL), nref, hisubst[ir->op2]); + } else if (ir->o == IR_LOOP) { + J->loopref = nref; /* Needed by assembler. */ + } + hisubst[ref] = hi; /* Store hiword substitution. */ + } + if (snref == nins) { /* Substitution for last snapshot. */ + snap->ref = J->cur.nins; + split_subst_snap(J, snap, oir); + } + + /* Add PHI marks. */ + for (ref = J->cur.nins-1; ref >= REF_FIRST; ref--) { + IRIns *ir = IR(ref); + if (ir->o != IR_PHI) break; + if (!irref_isk(ir->op1)) irt_setphi(IR(ir->op1)->t); + if (ir->op2 > J->loopref) irt_setphi(IR(ir->op2)->t); + } +} + +/* Protected callback for split pass. */ +static TValue *cpsplit(lua_State *L, lua_CFunction dummy, void *ud) +{ + jit_State *J = (jit_State *)ud; + split_ir(J); + UNUSED(L); UNUSED(dummy); + return NULL; +} + +#if defined(LUA_USE_ASSERT) || LJ_SOFTFP +/* Slow, but sure way to check whether a SPLIT pass is needed. */ +static int split_needsplit(jit_State *J) +{ + IRIns *ir, *irend; + IRRef ref; + for (ir = IR(REF_FIRST), irend = IR(J->cur.nins); ir < irend; ir++) + if (LJ_SOFTFP ? irt_is64orfp(ir->t) : irt_isint64(ir->t)) + return 1; + if (LJ_SOFTFP) { + for (ref = J->chain[IR_SLOAD]; ref; ref = IR(ref)->prev) + if ((IR(ref)->op2 & IRSLOAD_CONVERT)) + return 1; + if (J->chain[IR_TOBIT]) + return 1; + } + for (ref = J->chain[IR_CONV]; ref; ref = IR(ref)->prev) { + IRType st = (IR(ref)->op2 & IRCONV_SRCMASK); + if ((LJ_SOFTFP && (st == IRT_NUM || st == IRT_FLOAT)) || + st == IRT_I64 || st == IRT_U64) + return 1; + } + return 0; /* Nope. */ +} +#endif + +/* SPLIT pass. */ +void lj_opt_split(jit_State *J) +{ +#if LJ_SOFTFP + if (!J->needsplit) + J->needsplit = split_needsplit(J); +#else + lj_assertJ(J->needsplit >= split_needsplit(J), "bad SPLIT state"); +#endif + if (J->needsplit) { + int errcode = lj_vm_cpcall(J->L, NULL, J, cpsplit); + if (errcode) { + /* Completely reset the trace to avoid inconsistent dump on abort. */ + J->cur.nins = J->cur.nk = REF_BASE; + J->cur.nsnap = 0; + lj_err_throw(J->L, errcode); /* Propagate errors. */ + } + } +} + +#undef IR + +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_parse.c b/fluent-bit/lib/luajit-3065c9/src/lj_parse.c new file mode 100644 index 00000000..9ddf60ed --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_parse.c @@ -0,0 +1,2747 @@ +/* +** Lua parser (source code -> bytecode). +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +** +** Major portions taken verbatim or adapted from the Lua interpreter. +** Copyright (C) 1994-2008 Lua.org, PUC-Rio. See Copyright Notice in lua.h +*/ + +#define lj_parse_c +#define LUA_CORE + +#include "lj_obj.h" +#include "lj_gc.h" +#include "lj_err.h" +#include "lj_debug.h" +#include "lj_buf.h" +#include "lj_str.h" +#include "lj_tab.h" +#include "lj_func.h" +#include "lj_state.h" +#include "lj_bc.h" +#if LJ_HASFFI +#include "lj_ctype.h" +#endif +#include "lj_strfmt.h" +#include "lj_lex.h" +#include "lj_parse.h" +#include "lj_vm.h" +#include "lj_vmevent.h" + +/* -- Parser structures and definitions ----------------------------------- */ + +/* Expression kinds. */ +typedef enum { + /* Constant expressions must be first and in this order: */ + VKNIL, + VKFALSE, + VKTRUE, + VKSTR, /* sval = string value */ + VKNUM, /* nval = number value */ + VKLAST = VKNUM, + VKCDATA, /* nval = cdata value, not treated as a constant expression */ + /* Non-constant expressions follow: */ + VLOCAL, /* info = local register, aux = vstack index */ + VUPVAL, /* info = upvalue index, aux = vstack index */ + VGLOBAL, /* sval = string value */ + VINDEXED, /* info = table register, aux = index reg/byte/string const */ + VJMP, /* info = instruction PC */ + VRELOCABLE, /* info = instruction PC */ + VNONRELOC, /* info = result register */ + VCALL, /* info = instruction PC, aux = base */ + VVOID +} ExpKind; + +/* Expression descriptor. */ +typedef struct ExpDesc { + union { + struct { + uint32_t info; /* Primary info. */ + uint32_t aux; /* Secondary info. */ + } s; + TValue nval; /* Number value. */ + GCstr *sval; /* String value. */ + } u; + ExpKind k; + BCPos t; /* True condition jump list. */ + BCPos f; /* False condition jump list. */ +} ExpDesc; + +/* Macros for expressions. */ +#define expr_hasjump(e) ((e)->t != (e)->f) + +#define expr_isk(e) ((e)->k <= VKLAST) +#define expr_isk_nojump(e) (expr_isk(e) && !expr_hasjump(e)) +#define expr_isnumk(e) ((e)->k == VKNUM) +#define expr_isnumk_nojump(e) (expr_isnumk(e) && !expr_hasjump(e)) +#define expr_isstrk(e) ((e)->k == VKSTR) + +#define expr_numtv(e) check_exp(expr_isnumk((e)), &(e)->u.nval) +#define expr_numberV(e) numberVnum(expr_numtv((e))) + +/* Initialize expression. */ +static LJ_AINLINE void expr_init(ExpDesc *e, ExpKind k, uint32_t info) +{ + e->k = k; + e->u.s.info = info; + e->f = e->t = NO_JMP; +} + +/* Check number constant for +-0. */ +static int expr_numiszero(ExpDesc *e) +{ + TValue *o = expr_numtv(e); + return tvisint(o) ? (intV(o) == 0) : tviszero(o); +} + +/* Per-function linked list of scope blocks. */ +typedef struct FuncScope { + struct FuncScope *prev; /* Link to outer scope. */ + MSize vstart; /* Start of block-local variables. */ + uint8_t nactvar; /* Number of active vars outside the scope. */ + uint8_t flags; /* Scope flags. */ +} FuncScope; + +#define FSCOPE_LOOP 0x01 /* Scope is a (breakable) loop. */ +#define FSCOPE_BREAK 0x02 /* Break used in scope. */ +#define FSCOPE_GOLA 0x04 /* Goto or label used in scope. */ +#define FSCOPE_UPVAL 0x08 /* Upvalue in scope. */ +#define FSCOPE_NOCLOSE 0x10 /* Do not close upvalues. */ + +#define NAME_BREAK ((GCstr *)(uintptr_t)1) + +/* Index into variable stack. */ +typedef uint16_t VarIndex; +#define LJ_MAX_VSTACK (65536 - LJ_MAX_UPVAL) + +/* Variable/goto/label info. */ +#define VSTACK_VAR_RW 0x01 /* R/W variable. */ +#define VSTACK_GOTO 0x02 /* Pending goto. */ +#define VSTACK_LABEL 0x04 /* Label. */ + +/* Per-function state. */ +typedef struct FuncState { + GCtab *kt; /* Hash table for constants. */ + LexState *ls; /* Lexer state. */ + lua_State *L; /* Lua state. */ + FuncScope *bl; /* Current scope. */ + struct FuncState *prev; /* Enclosing function. */ + BCPos pc; /* Next bytecode position. */ + BCPos lasttarget; /* Bytecode position of last jump target. */ + BCPos jpc; /* Pending jump list to next bytecode. */ + BCReg freereg; /* First free register. */ + BCReg nactvar; /* Number of active local variables. */ + BCReg nkn, nkgc; /* Number of lua_Number/GCobj constants */ + BCLine linedefined; /* First line of the function definition. */ + BCInsLine *bcbase; /* Base of bytecode stack. */ + BCPos bclim; /* Limit of bytecode stack. */ + MSize vbase; /* Base of variable stack for this function. */ + uint8_t flags; /* Prototype flags. */ + uint8_t numparams; /* Number of parameters. */ + uint8_t framesize; /* Fixed frame size. */ + uint8_t nuv; /* Number of upvalues */ + VarIndex varmap[LJ_MAX_LOCVAR]; /* Map from register to variable idx. */ + VarIndex uvmap[LJ_MAX_UPVAL]; /* Map from upvalue to variable idx. */ + VarIndex uvtmp[LJ_MAX_UPVAL]; /* Temporary upvalue map. */ +} FuncState; + +/* Binary and unary operators. ORDER OPR */ +typedef enum BinOpr { + OPR_ADD, OPR_SUB, OPR_MUL, OPR_DIV, OPR_MOD, OPR_POW, /* ORDER ARITH */ + OPR_CONCAT, + OPR_NE, OPR_EQ, + OPR_LT, OPR_GE, OPR_LE, OPR_GT, + OPR_AND, OPR_OR, + OPR_NOBINOPR +} BinOpr; + +LJ_STATIC_ASSERT((int)BC_ISGE-(int)BC_ISLT == (int)OPR_GE-(int)OPR_LT); +LJ_STATIC_ASSERT((int)BC_ISLE-(int)BC_ISLT == (int)OPR_LE-(int)OPR_LT); +LJ_STATIC_ASSERT((int)BC_ISGT-(int)BC_ISLT == (int)OPR_GT-(int)OPR_LT); +LJ_STATIC_ASSERT((int)BC_SUBVV-(int)BC_ADDVV == (int)OPR_SUB-(int)OPR_ADD); +LJ_STATIC_ASSERT((int)BC_MULVV-(int)BC_ADDVV == (int)OPR_MUL-(int)OPR_ADD); +LJ_STATIC_ASSERT((int)BC_DIVVV-(int)BC_ADDVV == (int)OPR_DIV-(int)OPR_ADD); +LJ_STATIC_ASSERT((int)BC_MODVV-(int)BC_ADDVV == (int)OPR_MOD-(int)OPR_ADD); + +#ifdef LUA_USE_ASSERT +#define lj_assertFS(c, ...) (lj_assertG_(G(fs->L), (c), __VA_ARGS__)) +#else +#define lj_assertFS(c, ...) ((void)fs) +#endif + +/* -- Error handling ------------------------------------------------------ */ + +LJ_NORET LJ_NOINLINE static void err_syntax(LexState *ls, ErrMsg em) +{ + lj_lex_error(ls, ls->tok, em); +} + +LJ_NORET LJ_NOINLINE static void err_token(LexState *ls, LexToken tok) +{ + lj_lex_error(ls, ls->tok, LJ_ERR_XTOKEN, lj_lex_token2str(ls, tok)); +} + +LJ_NORET static void err_limit(FuncState *fs, uint32_t limit, const char *what) +{ + if (fs->linedefined == 0) + lj_lex_error(fs->ls, 0, LJ_ERR_XLIMM, limit, what); + else + lj_lex_error(fs->ls, 0, LJ_ERR_XLIMF, fs->linedefined, limit, what); +} + +#define checklimit(fs, v, l, m) if ((v) >= (l)) err_limit(fs, l, m) +#define checklimitgt(fs, v, l, m) if ((v) > (l)) err_limit(fs, l, m) +#define checkcond(ls, c, em) { if (!(c)) err_syntax(ls, em); } + +/* -- Management of constants --------------------------------------------- */ + +/* Return bytecode encoding for primitive constant. */ +#define const_pri(e) check_exp((e)->k <= VKTRUE, (e)->k) + +#define tvhaskslot(o) ((o)->u32.hi == 0) +#define tvkslot(o) ((o)->u32.lo) + +/* Add a number constant. */ +static BCReg const_num(FuncState *fs, ExpDesc *e) +{ + lua_State *L = fs->L; + TValue *o; + lj_assertFS(expr_isnumk(e), "bad usage"); + o = lj_tab_set(L, fs->kt, &e->u.nval); + if (tvhaskslot(o)) + return tvkslot(o); + o->u64 = fs->nkn; + return fs->nkn++; +} + +/* Add a GC object constant. */ +static BCReg const_gc(FuncState *fs, GCobj *gc, uint32_t itype) +{ + lua_State *L = fs->L; + TValue key, *o; + setgcV(L, &key, gc, itype); + /* NOBARRIER: the key is new or kept alive. */ + o = lj_tab_set(L, fs->kt, &key); + if (tvhaskslot(o)) + return tvkslot(o); + o->u64 = fs->nkgc; + return fs->nkgc++; +} + +/* Add a string constant. */ +static BCReg const_str(FuncState *fs, ExpDesc *e) +{ + lj_assertFS(expr_isstrk(e) || e->k == VGLOBAL, "bad usage"); + return const_gc(fs, obj2gco(e->u.sval), LJ_TSTR); +} + +/* Anchor string constant to avoid GC. */ +GCstr *lj_parse_keepstr(LexState *ls, const char *str, size_t len) +{ + /* NOBARRIER: the key is new or kept alive. */ + lua_State *L = ls->L; + GCstr *s = lj_str_new(L, str, len); + TValue *tv = lj_tab_setstr(L, ls->fs->kt, s); + if (tvisnil(tv)) setboolV(tv, 1); + lj_gc_check(L); + return s; +} + +#if LJ_HASFFI +/* Anchor cdata to avoid GC. */ +void lj_parse_keepcdata(LexState *ls, TValue *tv, GCcdata *cd) +{ + /* NOBARRIER: the key is new or kept alive. */ + lua_State *L = ls->L; + setcdataV(L, tv, cd); + setboolV(lj_tab_set(L, ls->fs->kt, tv), 1); +} +#endif + +/* -- Jump list handling -------------------------------------------------- */ + +/* Get next element in jump list. */ +static BCPos jmp_next(FuncState *fs, BCPos pc) +{ + ptrdiff_t delta = bc_j(fs->bcbase[pc].ins); + if ((BCPos)delta == NO_JMP) + return NO_JMP; + else + return (BCPos)(((ptrdiff_t)pc+1)+delta); +} + +/* Check if any of the instructions on the jump list produce no value. */ +static int jmp_novalue(FuncState *fs, BCPos list) +{ + for (; list != NO_JMP; list = jmp_next(fs, list)) { + BCIns p = fs->bcbase[list >= 1 ? list-1 : list].ins; + if (!(bc_op(p) == BC_ISTC || bc_op(p) == BC_ISFC || bc_a(p) == NO_REG)) + return 1; + } + return 0; +} + +/* Patch register of test instructions. */ +static int jmp_patchtestreg(FuncState *fs, BCPos pc, BCReg reg) +{ + BCInsLine *ilp = &fs->bcbase[pc >= 1 ? pc-1 : pc]; + BCOp op = bc_op(ilp->ins); + if (op == BC_ISTC || op == BC_ISFC) { + if (reg != NO_REG && reg != bc_d(ilp->ins)) { + setbc_a(&ilp->ins, reg); + } else { /* Nothing to store or already in the right register. */ + setbc_op(&ilp->ins, op+(BC_IST-BC_ISTC)); + setbc_a(&ilp->ins, 0); + } + } else if (bc_a(ilp->ins) == NO_REG) { + if (reg == NO_REG) { + ilp->ins = BCINS_AJ(BC_JMP, bc_a(fs->bcbase[pc].ins), 0); + } else { + setbc_a(&ilp->ins, reg); + if (reg >= bc_a(ilp[1].ins)) + setbc_a(&ilp[1].ins, reg+1); + } + } else { + return 0; /* Cannot patch other instructions. */ + } + return 1; +} + +/* Drop values for all instructions on jump list. */ +static void jmp_dropval(FuncState *fs, BCPos list) +{ + for (; list != NO_JMP; list = jmp_next(fs, list)) + jmp_patchtestreg(fs, list, NO_REG); +} + +/* Patch jump instruction to target. */ +static void jmp_patchins(FuncState *fs, BCPos pc, BCPos dest) +{ + BCIns *jmp = &fs->bcbase[pc].ins; + BCPos offset = dest-(pc+1)+BCBIAS_J; + lj_assertFS(dest != NO_JMP, "uninitialized jump target"); + if (offset > BCMAX_D) + err_syntax(fs->ls, LJ_ERR_XJUMP); + setbc_d(jmp, offset); +} + +/* Append to jump list. */ +static void jmp_append(FuncState *fs, BCPos *l1, BCPos l2) +{ + if (l2 == NO_JMP) { + return; + } else if (*l1 == NO_JMP) { + *l1 = l2; + } else { + BCPos list = *l1; + BCPos next; + while ((next = jmp_next(fs, list)) != NO_JMP) /* Find last element. */ + list = next; + jmp_patchins(fs, list, l2); + } +} + +/* Patch jump list and preserve produced values. */ +static void jmp_patchval(FuncState *fs, BCPos list, BCPos vtarget, + BCReg reg, BCPos dtarget) +{ + while (list != NO_JMP) { + BCPos next = jmp_next(fs, list); + if (jmp_patchtestreg(fs, list, reg)) + jmp_patchins(fs, list, vtarget); /* Jump to target with value. */ + else + jmp_patchins(fs, list, dtarget); /* Jump to default target. */ + list = next; + } +} + +/* Jump to following instruction. Append to list of pending jumps. */ +static void jmp_tohere(FuncState *fs, BCPos list) +{ + fs->lasttarget = fs->pc; + jmp_append(fs, &fs->jpc, list); +} + +/* Patch jump list to target. */ +static void jmp_patch(FuncState *fs, BCPos list, BCPos target) +{ + if (target == fs->pc) { + jmp_tohere(fs, list); + } else { + lj_assertFS(target < fs->pc, "bad jump target"); + jmp_patchval(fs, list, target, NO_REG, target); + } +} + +/* -- Bytecode register allocator ----------------------------------------- */ + +/* Bump frame size. */ +static void bcreg_bump(FuncState *fs, BCReg n) +{ + BCReg sz = fs->freereg + n; + if (sz > fs->framesize) { + if (sz >= LJ_MAX_SLOTS) + err_syntax(fs->ls, LJ_ERR_XSLOTS); + fs->framesize = (uint8_t)sz; + } +} + +/* Reserve registers. */ +static void bcreg_reserve(FuncState *fs, BCReg n) +{ + bcreg_bump(fs, n); + fs->freereg += n; +} + +/* Free register. */ +static void bcreg_free(FuncState *fs, BCReg reg) +{ + if (reg >= fs->nactvar) { + fs->freereg--; + lj_assertFS(reg == fs->freereg, "bad regfree"); + } +} + +/* Free register for expression. */ +static void expr_free(FuncState *fs, ExpDesc *e) +{ + if (e->k == VNONRELOC) + bcreg_free(fs, e->u.s.info); +} + +/* -- Bytecode emitter ---------------------------------------------------- */ + +/* Emit bytecode instruction. */ +static BCPos bcemit_INS(FuncState *fs, BCIns ins) +{ + BCPos pc = fs->pc; + LexState *ls = fs->ls; + jmp_patchval(fs, fs->jpc, pc, NO_REG, pc); + fs->jpc = NO_JMP; + if (LJ_UNLIKELY(pc >= fs->bclim)) { + ptrdiff_t base = fs->bcbase - ls->bcstack; + checklimit(fs, ls->sizebcstack, LJ_MAX_BCINS, "bytecode instructions"); + lj_mem_growvec(fs->L, ls->bcstack, ls->sizebcstack, LJ_MAX_BCINS,BCInsLine); + fs->bclim = (BCPos)(ls->sizebcstack - base); + fs->bcbase = ls->bcstack + base; + } + fs->bcbase[pc].ins = ins; + fs->bcbase[pc].line = ls->lastline; + fs->pc = pc+1; + return pc; +} + +#define bcemit_ABC(fs, o, a, b, c) bcemit_INS(fs, BCINS_ABC(o, a, b, c)) +#define bcemit_AD(fs, o, a, d) bcemit_INS(fs, BCINS_AD(o, a, d)) +#define bcemit_AJ(fs, o, a, j) bcemit_INS(fs, BCINS_AJ(o, a, j)) + +#define bcptr(fs, e) (&(fs)->bcbase[(e)->u.s.info].ins) + +/* -- Bytecode emitter for expressions ------------------------------------ */ + +/* Discharge non-constant expression to any register. */ +static void expr_discharge(FuncState *fs, ExpDesc *e) +{ + BCIns ins; + if (e->k == VUPVAL) { + ins = BCINS_AD(BC_UGET, 0, e->u.s.info); + } else if (e->k == VGLOBAL) { + ins = BCINS_AD(BC_GGET, 0, const_str(fs, e)); + } else if (e->k == VINDEXED) { + BCReg rc = e->u.s.aux; + if ((int32_t)rc < 0) { + ins = BCINS_ABC(BC_TGETS, 0, e->u.s.info, ~rc); + } else if (rc > BCMAX_C) { + ins = BCINS_ABC(BC_TGETB, 0, e->u.s.info, rc-(BCMAX_C+1)); + } else { + bcreg_free(fs, rc); + ins = BCINS_ABC(BC_TGETV, 0, e->u.s.info, rc); + } + bcreg_free(fs, e->u.s.info); + } else if (e->k == VCALL) { + e->u.s.info = e->u.s.aux; + e->k = VNONRELOC; + return; + } else if (e->k == VLOCAL) { + e->k = VNONRELOC; + return; + } else { + return; + } + e->u.s.info = bcemit_INS(fs, ins); + e->k = VRELOCABLE; +} + +/* Emit bytecode to set a range of registers to nil. */ +static void bcemit_nil(FuncState *fs, BCReg from, BCReg n) +{ + if (fs->pc > fs->lasttarget) { /* No jumps to current position? */ + BCIns *ip = &fs->bcbase[fs->pc-1].ins; + BCReg pto, pfrom = bc_a(*ip); + switch (bc_op(*ip)) { /* Try to merge with the previous instruction. */ + case BC_KPRI: + if (bc_d(*ip) != ~LJ_TNIL) break; + if (from == pfrom) { + if (n == 1) return; + } else if (from == pfrom+1) { + from = pfrom; + n++; + } else { + break; + } + *ip = BCINS_AD(BC_KNIL, from, from+n-1); /* Replace KPRI. */ + return; + case BC_KNIL: + pto = bc_d(*ip); + if (pfrom <= from && from <= pto+1) { /* Can we connect both ranges? */ + if (from+n-1 > pto) + setbc_d(ip, from+n-1); /* Patch previous instruction range. */ + return; + } + break; + default: + break; + } + } + /* Emit new instruction or replace old instruction. */ + bcemit_INS(fs, n == 1 ? BCINS_AD(BC_KPRI, from, VKNIL) : + BCINS_AD(BC_KNIL, from, from+n-1)); +} + +/* Discharge an expression to a specific register. Ignore branches. */ +static void expr_toreg_nobranch(FuncState *fs, ExpDesc *e, BCReg reg) +{ + BCIns ins; + expr_discharge(fs, e); + if (e->k == VKSTR) { + ins = BCINS_AD(BC_KSTR, reg, const_str(fs, e)); + } else if (e->k == VKNUM) { +#if LJ_DUALNUM + cTValue *tv = expr_numtv(e); + if (tvisint(tv) && checki16(intV(tv))) + ins = BCINS_AD(BC_KSHORT, reg, (BCReg)(uint16_t)intV(tv)); + else +#else + lua_Number n = expr_numberV(e); + int32_t k = lj_num2int(n); + if (checki16(k) && n == (lua_Number)k) + ins = BCINS_AD(BC_KSHORT, reg, (BCReg)(uint16_t)k); + else +#endif + ins = BCINS_AD(BC_KNUM, reg, const_num(fs, e)); +#if LJ_HASFFI + } else if (e->k == VKCDATA) { + fs->flags |= PROTO_FFI; + ins = BCINS_AD(BC_KCDATA, reg, + const_gc(fs, obj2gco(cdataV(&e->u.nval)), LJ_TCDATA)); +#endif + } else if (e->k == VRELOCABLE) { + setbc_a(bcptr(fs, e), reg); + goto noins; + } else if (e->k == VNONRELOC) { + if (reg == e->u.s.info) + goto noins; + ins = BCINS_AD(BC_MOV, reg, e->u.s.info); + } else if (e->k == VKNIL) { + bcemit_nil(fs, reg, 1); + goto noins; + } else if (e->k <= VKTRUE) { + ins = BCINS_AD(BC_KPRI, reg, const_pri(e)); + } else { + lj_assertFS(e->k == VVOID || e->k == VJMP, "bad expr type %d", e->k); + return; + } + bcemit_INS(fs, ins); +noins: + e->u.s.info = reg; + e->k = VNONRELOC; +} + +/* Forward declaration. */ +static BCPos bcemit_jmp(FuncState *fs); + +/* Discharge an expression to a specific register. */ +static void expr_toreg(FuncState *fs, ExpDesc *e, BCReg reg) +{ + expr_toreg_nobranch(fs, e, reg); + if (e->k == VJMP) + jmp_append(fs, &e->t, e->u.s.info); /* Add it to the true jump list. */ + if (expr_hasjump(e)) { /* Discharge expression with branches. */ + BCPos jend, jfalse = NO_JMP, jtrue = NO_JMP; + if (jmp_novalue(fs, e->t) || jmp_novalue(fs, e->f)) { + BCPos jval = (e->k == VJMP) ? NO_JMP : bcemit_jmp(fs); + jfalse = bcemit_AD(fs, BC_KPRI, reg, VKFALSE); + bcemit_AJ(fs, BC_JMP, fs->freereg, 1); + jtrue = bcemit_AD(fs, BC_KPRI, reg, VKTRUE); + jmp_tohere(fs, jval); + } + jend = fs->pc; + fs->lasttarget = jend; + jmp_patchval(fs, e->f, jend, reg, jfalse); + jmp_patchval(fs, e->t, jend, reg, jtrue); + } + e->f = e->t = NO_JMP; + e->u.s.info = reg; + e->k = VNONRELOC; +} + +/* Discharge an expression to the next free register. */ +static void expr_tonextreg(FuncState *fs, ExpDesc *e) +{ + expr_discharge(fs, e); + expr_free(fs, e); + bcreg_reserve(fs, 1); + expr_toreg(fs, e, fs->freereg - 1); +} + +/* Discharge an expression to any register. */ +static BCReg expr_toanyreg(FuncState *fs, ExpDesc *e) +{ + expr_discharge(fs, e); + if (e->k == VNONRELOC) { + if (!expr_hasjump(e)) return e->u.s.info; /* Already in a register. */ + if (e->u.s.info >= fs->nactvar) { + expr_toreg(fs, e, e->u.s.info); /* Discharge to temp. register. */ + return e->u.s.info; + } + } + expr_tonextreg(fs, e); /* Discharge to next register. */ + return e->u.s.info; +} + +/* Partially discharge expression to a value. */ +static void expr_toval(FuncState *fs, ExpDesc *e) +{ + if (expr_hasjump(e)) + expr_toanyreg(fs, e); + else + expr_discharge(fs, e); +} + +/* Emit store for LHS expression. */ +static void bcemit_store(FuncState *fs, ExpDesc *var, ExpDesc *e) +{ + BCIns ins; + if (var->k == VLOCAL) { + fs->ls->vstack[var->u.s.aux].info |= VSTACK_VAR_RW; + expr_free(fs, e); + expr_toreg(fs, e, var->u.s.info); + return; + } else if (var->k == VUPVAL) { + fs->ls->vstack[var->u.s.aux].info |= VSTACK_VAR_RW; + expr_toval(fs, e); + if (e->k <= VKTRUE) + ins = BCINS_AD(BC_USETP, var->u.s.info, const_pri(e)); + else if (e->k == VKSTR) + ins = BCINS_AD(BC_USETS, var->u.s.info, const_str(fs, e)); + else if (e->k == VKNUM) + ins = BCINS_AD(BC_USETN, var->u.s.info, const_num(fs, e)); + else + ins = BCINS_AD(BC_USETV, var->u.s.info, expr_toanyreg(fs, e)); + } else if (var->k == VGLOBAL) { + BCReg ra = expr_toanyreg(fs, e); + ins = BCINS_AD(BC_GSET, ra, const_str(fs, var)); + } else { + BCReg ra, rc; + lj_assertFS(var->k == VINDEXED, "bad expr type %d", var->k); + ra = expr_toanyreg(fs, e); + rc = var->u.s.aux; + if ((int32_t)rc < 0) { + ins = BCINS_ABC(BC_TSETS, ra, var->u.s.info, ~rc); + } else if (rc > BCMAX_C) { + ins = BCINS_ABC(BC_TSETB, ra, var->u.s.info, rc-(BCMAX_C+1)); + } else { +#ifdef LUA_USE_ASSERT + /* Free late alloced key reg to avoid assert on free of value reg. */ + /* This can only happen when called from expr_table(). */ + if (e->k == VNONRELOC && ra >= fs->nactvar && rc >= ra) + bcreg_free(fs, rc); +#endif + ins = BCINS_ABC(BC_TSETV, ra, var->u.s.info, rc); + } + } + bcemit_INS(fs, ins); + expr_free(fs, e); +} + +/* Emit method lookup expression. */ +static void bcemit_method(FuncState *fs, ExpDesc *e, ExpDesc *key) +{ + BCReg idx, func, obj = expr_toanyreg(fs, e); + expr_free(fs, e); + func = fs->freereg; + bcemit_AD(fs, BC_MOV, func+1+LJ_FR2, obj); /* Copy object to 1st argument. */ + lj_assertFS(expr_isstrk(key), "bad usage"); + idx = const_str(fs, key); + if (idx <= BCMAX_C) { + bcreg_reserve(fs, 2+LJ_FR2); + bcemit_ABC(fs, BC_TGETS, func, obj, idx); + } else { + bcreg_reserve(fs, 3+LJ_FR2); + bcemit_AD(fs, BC_KSTR, func+2+LJ_FR2, idx); + bcemit_ABC(fs, BC_TGETV, func, obj, func+2+LJ_FR2); + fs->freereg--; + } + e->u.s.info = func; + e->k = VNONRELOC; +} + +/* -- Bytecode emitter for branches --------------------------------------- */ + +/* Emit unconditional branch. */ +static BCPos bcemit_jmp(FuncState *fs) +{ + BCPos jpc = fs->jpc; + BCPos j = fs->pc - 1; + BCIns *ip = &fs->bcbase[j].ins; + fs->jpc = NO_JMP; + if ((int32_t)j >= (int32_t)fs->lasttarget && bc_op(*ip) == BC_UCLO) { + setbc_j(ip, NO_JMP); + fs->lasttarget = j+1; + } else { + j = bcemit_AJ(fs, BC_JMP, fs->freereg, NO_JMP); + } + jmp_append(fs, &j, jpc); + return j; +} + +/* Invert branch condition of bytecode instruction. */ +static void invertcond(FuncState *fs, ExpDesc *e) +{ + BCIns *ip = &fs->bcbase[e->u.s.info - 1].ins; + setbc_op(ip, bc_op(*ip)^1); +} + +/* Emit conditional branch. */ +static BCPos bcemit_branch(FuncState *fs, ExpDesc *e, int cond) +{ + BCPos pc; + if (e->k == VRELOCABLE) { + BCIns *ip = bcptr(fs, e); + if (bc_op(*ip) == BC_NOT) { + *ip = BCINS_AD(cond ? BC_ISF : BC_IST, 0, bc_d(*ip)); + return bcemit_jmp(fs); + } + } + if (e->k != VNONRELOC) { + bcreg_reserve(fs, 1); + expr_toreg_nobranch(fs, e, fs->freereg-1); + } + bcemit_AD(fs, cond ? BC_ISTC : BC_ISFC, NO_REG, e->u.s.info); + pc = bcemit_jmp(fs); + expr_free(fs, e); + return pc; +} + +/* Emit branch on true condition. */ +static void bcemit_branch_t(FuncState *fs, ExpDesc *e) +{ + BCPos pc; + expr_discharge(fs, e); + if (e->k == VKSTR || e->k == VKNUM || e->k == VKTRUE) + pc = NO_JMP; /* Never jump. */ + else if (e->k == VJMP) + invertcond(fs, e), pc = e->u.s.info; + else if (e->k == VKFALSE || e->k == VKNIL) + expr_toreg_nobranch(fs, e, NO_REG), pc = bcemit_jmp(fs); + else + pc = bcemit_branch(fs, e, 0); + jmp_append(fs, &e->f, pc); + jmp_tohere(fs, e->t); + e->t = NO_JMP; +} + +/* Emit branch on false condition. */ +static void bcemit_branch_f(FuncState *fs, ExpDesc *e) +{ + BCPos pc; + expr_discharge(fs, e); + if (e->k == VKNIL || e->k == VKFALSE) + pc = NO_JMP; /* Never jump. */ + else if (e->k == VJMP) + pc = e->u.s.info; + else if (e->k == VKSTR || e->k == VKNUM || e->k == VKTRUE) + expr_toreg_nobranch(fs, e, NO_REG), pc = bcemit_jmp(fs); + else + pc = bcemit_branch(fs, e, 1); + jmp_append(fs, &e->t, pc); + jmp_tohere(fs, e->f); + e->f = NO_JMP; +} + +/* -- Bytecode emitter for operators -------------------------------------- */ + +/* Try constant-folding of arithmetic operators. */ +static int foldarith(BinOpr opr, ExpDesc *e1, ExpDesc *e2) +{ + TValue o; + lua_Number n; + if (!expr_isnumk_nojump(e1) || !expr_isnumk_nojump(e2)) return 0; + n = lj_vm_foldarith(expr_numberV(e1), expr_numberV(e2), (int)opr-OPR_ADD); + setnumV(&o, n); + if (tvisnan(&o) || tvismzero(&o)) return 0; /* Avoid NaN and -0 as consts. */ + if (LJ_DUALNUM) { + int32_t k = lj_num2int(n); + if ((lua_Number)k == n) { + setintV(&e1->u.nval, k); + return 1; + } + } + setnumV(&e1->u.nval, n); + return 1; +} + +/* Emit arithmetic operator. */ +static void bcemit_arith(FuncState *fs, BinOpr opr, ExpDesc *e1, ExpDesc *e2) +{ + BCReg rb, rc, t; + uint32_t op; + if (foldarith(opr, e1, e2)) + return; + if (opr == OPR_POW) { + op = BC_POW; + rc = expr_toanyreg(fs, e2); + rb = expr_toanyreg(fs, e1); + } else { + op = opr-OPR_ADD+BC_ADDVV; + /* Must discharge 2nd operand first since VINDEXED might free regs. */ + expr_toval(fs, e2); + if (expr_isnumk(e2) && (rc = const_num(fs, e2)) <= BCMAX_C) + op -= BC_ADDVV-BC_ADDVN; + else + rc = expr_toanyreg(fs, e2); + /* 1st operand discharged by bcemit_binop_left, but need KNUM/KSHORT. */ + lj_assertFS(expr_isnumk(e1) || e1->k == VNONRELOC, + "bad expr type %d", e1->k); + expr_toval(fs, e1); + /* Avoid two consts to satisfy bytecode constraints. */ + if (expr_isnumk(e1) && !expr_isnumk(e2) && + (t = const_num(fs, e1)) <= BCMAX_B) { + rb = rc; rc = t; op -= BC_ADDVV-BC_ADDNV; + } else { + rb = expr_toanyreg(fs, e1); + } + } + /* Using expr_free might cause asserts if the order is wrong. */ + if (e1->k == VNONRELOC && e1->u.s.info >= fs->nactvar) fs->freereg--; + if (e2->k == VNONRELOC && e2->u.s.info >= fs->nactvar) fs->freereg--; + e1->u.s.info = bcemit_ABC(fs, op, 0, rb, rc); + e1->k = VRELOCABLE; +} + +/* Emit comparison operator. */ +static void bcemit_comp(FuncState *fs, BinOpr opr, ExpDesc *e1, ExpDesc *e2) +{ + ExpDesc *eret = e1; + BCIns ins; + expr_toval(fs, e1); + if (opr == OPR_EQ || opr == OPR_NE) { + BCOp op = opr == OPR_EQ ? BC_ISEQV : BC_ISNEV; + BCReg ra; + if (expr_isk(e1)) { e1 = e2; e2 = eret; } /* Need constant in 2nd arg. */ + ra = expr_toanyreg(fs, e1); /* First arg must be in a reg. */ + expr_toval(fs, e2); + switch (e2->k) { + case VKNIL: case VKFALSE: case VKTRUE: + ins = BCINS_AD(op+(BC_ISEQP-BC_ISEQV), ra, const_pri(e2)); + break; + case VKSTR: + ins = BCINS_AD(op+(BC_ISEQS-BC_ISEQV), ra, const_str(fs, e2)); + break; + case VKNUM: + ins = BCINS_AD(op+(BC_ISEQN-BC_ISEQV), ra, const_num(fs, e2)); + break; + default: + ins = BCINS_AD(op, ra, expr_toanyreg(fs, e2)); + break; + } + } else { + uint32_t op = opr-OPR_LT+BC_ISLT; + BCReg ra, rd; + if ((op-BC_ISLT) & 1) { /* GT -> LT, GE -> LE */ + e1 = e2; e2 = eret; /* Swap operands. */ + op = ((op-BC_ISLT)^3)+BC_ISLT; + expr_toval(fs, e1); + ra = expr_toanyreg(fs, e1); + rd = expr_toanyreg(fs, e2); + } else { + rd = expr_toanyreg(fs, e2); + ra = expr_toanyreg(fs, e1); + } + ins = BCINS_AD(op, ra, rd); + } + /* Using expr_free might cause asserts if the order is wrong. */ + if (e1->k == VNONRELOC && e1->u.s.info >= fs->nactvar) fs->freereg--; + if (e2->k == VNONRELOC && e2->u.s.info >= fs->nactvar) fs->freereg--; + bcemit_INS(fs, ins); + eret->u.s.info = bcemit_jmp(fs); + eret->k = VJMP; +} + +/* Fixup left side of binary operator. */ +static void bcemit_binop_left(FuncState *fs, BinOpr op, ExpDesc *e) +{ + if (op == OPR_AND) { + bcemit_branch_t(fs, e); + } else if (op == OPR_OR) { + bcemit_branch_f(fs, e); + } else if (op == OPR_CONCAT) { + expr_tonextreg(fs, e); + } else if (op == OPR_EQ || op == OPR_NE) { + if (!expr_isk_nojump(e)) expr_toanyreg(fs, e); + } else { + if (!expr_isnumk_nojump(e)) expr_toanyreg(fs, e); + } +} + +/* Emit binary operator. */ +static void bcemit_binop(FuncState *fs, BinOpr op, ExpDesc *e1, ExpDesc *e2) +{ + if (op <= OPR_POW) { + bcemit_arith(fs, op, e1, e2); + } else if (op == OPR_AND) { + lj_assertFS(e1->t == NO_JMP, "jump list not closed"); + expr_discharge(fs, e2); + jmp_append(fs, &e2->f, e1->f); + *e1 = *e2; + } else if (op == OPR_OR) { + lj_assertFS(e1->f == NO_JMP, "jump list not closed"); + expr_discharge(fs, e2); + jmp_append(fs, &e2->t, e1->t); + *e1 = *e2; + } else if (op == OPR_CONCAT) { + expr_toval(fs, e2); + if (e2->k == VRELOCABLE && bc_op(*bcptr(fs, e2)) == BC_CAT) { + lj_assertFS(e1->u.s.info == bc_b(*bcptr(fs, e2))-1, + "bad CAT stack layout"); + expr_free(fs, e1); + setbc_b(bcptr(fs, e2), e1->u.s.info); + e1->u.s.info = e2->u.s.info; + } else { + expr_tonextreg(fs, e2); + expr_free(fs, e2); + expr_free(fs, e1); + e1->u.s.info = bcemit_ABC(fs, BC_CAT, 0, e1->u.s.info, e2->u.s.info); + } + e1->k = VRELOCABLE; + } else { + lj_assertFS(op == OPR_NE || op == OPR_EQ || + op == OPR_LT || op == OPR_GE || op == OPR_LE || op == OPR_GT, + "bad binop %d", op); + bcemit_comp(fs, op, e1, e2); + } +} + +/* Emit unary operator. */ +static void bcemit_unop(FuncState *fs, BCOp op, ExpDesc *e) +{ + if (op == BC_NOT) { + /* Swap true and false lists. */ + { BCPos temp = e->f; e->f = e->t; e->t = temp; } + jmp_dropval(fs, e->f); + jmp_dropval(fs, e->t); + expr_discharge(fs, e); + if (e->k == VKNIL || e->k == VKFALSE) { + e->k = VKTRUE; + return; + } else if (expr_isk(e) || (LJ_HASFFI && e->k == VKCDATA)) { + e->k = VKFALSE; + return; + } else if (e->k == VJMP) { + invertcond(fs, e); + return; + } else if (e->k == VRELOCABLE) { + bcreg_reserve(fs, 1); + setbc_a(bcptr(fs, e), fs->freereg-1); + e->u.s.info = fs->freereg-1; + e->k = VNONRELOC; + } else { + lj_assertFS(e->k == VNONRELOC, "bad expr type %d", e->k); + } + } else { + lj_assertFS(op == BC_UNM || op == BC_LEN, "bad unop %d", op); + if (op == BC_UNM && !expr_hasjump(e)) { /* Constant-fold negations. */ +#if LJ_HASFFI + if (e->k == VKCDATA) { /* Fold in-place since cdata is not interned. */ + GCcdata *cd = cdataV(&e->u.nval); + int64_t *p = (int64_t *)cdataptr(cd); + if (cd->ctypeid == CTID_COMPLEX_DOUBLE) + p[1] ^= (int64_t)U64x(80000000,00000000); + else + *p = -*p; + return; + } else +#endif + if (expr_isnumk(e) && !expr_numiszero(e)) { /* Avoid folding to -0. */ + TValue *o = expr_numtv(e); + if (tvisint(o)) { + int32_t k = intV(o); + if (k == -k) + setnumV(o, -(lua_Number)k); + else + setintV(o, -k); + return; + } else { + o->u64 ^= U64x(80000000,00000000); + return; + } + } + } + expr_toanyreg(fs, e); + } + expr_free(fs, e); + e->u.s.info = bcemit_AD(fs, op, 0, e->u.s.info); + e->k = VRELOCABLE; +} + +/* -- Lexer support ------------------------------------------------------- */ + +/* Check and consume optional token. */ +static int lex_opt(LexState *ls, LexToken tok) +{ + if (ls->tok == tok) { + lj_lex_next(ls); + return 1; + } + return 0; +} + +/* Check and consume token. */ +static void lex_check(LexState *ls, LexToken tok) +{ + if (ls->tok != tok) + err_token(ls, tok); + lj_lex_next(ls); +} + +/* Check for matching token. */ +static void lex_match(LexState *ls, LexToken what, LexToken who, BCLine line) +{ + if (!lex_opt(ls, what)) { + if (line == ls->linenumber) { + err_token(ls, what); + } else { + const char *swhat = lj_lex_token2str(ls, what); + const char *swho = lj_lex_token2str(ls, who); + lj_lex_error(ls, ls->tok, LJ_ERR_XMATCH, swhat, swho, line); + } + } +} + +/* Check for string token. */ +static GCstr *lex_str(LexState *ls) +{ + GCstr *s; + if (ls->tok != TK_name && (LJ_52 || ls->tok != TK_goto)) + err_token(ls, TK_name); + s = strV(&ls->tokval); + lj_lex_next(ls); + return s; +} + +/* -- Variable handling --------------------------------------------------- */ + +#define var_get(ls, fs, i) ((ls)->vstack[(fs)->varmap[(i)]]) + +/* Define a new local variable. */ +static void var_new(LexState *ls, BCReg n, GCstr *name) +{ + FuncState *fs = ls->fs; + MSize vtop = ls->vtop; + checklimit(fs, fs->nactvar+n, LJ_MAX_LOCVAR, "local variables"); + if (LJ_UNLIKELY(vtop >= ls->sizevstack)) { + if (ls->sizevstack >= LJ_MAX_VSTACK) + lj_lex_error(ls, 0, LJ_ERR_XLIMC, LJ_MAX_VSTACK); + lj_mem_growvec(ls->L, ls->vstack, ls->sizevstack, LJ_MAX_VSTACK, VarInfo); + } + lj_assertFS((uintptr_t)name < VARNAME__MAX || + lj_tab_getstr(fs->kt, name) != NULL, + "unanchored variable name"); + /* NOBARRIER: name is anchored in fs->kt and ls->vstack is not a GCobj. */ + setgcref(ls->vstack[vtop].name, obj2gco(name)); + fs->varmap[fs->nactvar+n] = (uint16_t)vtop; + ls->vtop = vtop+1; +} + +#define var_new_lit(ls, n, v) \ + var_new(ls, (n), lj_parse_keepstr(ls, "" v, sizeof(v)-1)) + +#define var_new_fixed(ls, n, vn) \ + var_new(ls, (n), (GCstr *)(uintptr_t)(vn)) + +/* Add local variables. */ +static void var_add(LexState *ls, BCReg nvars) +{ + FuncState *fs = ls->fs; + BCReg nactvar = fs->nactvar; + while (nvars--) { + VarInfo *v = &var_get(ls, fs, nactvar); + v->startpc = fs->pc; + v->slot = nactvar++; + v->info = 0; + } + fs->nactvar = nactvar; +} + +/* Remove local variables. */ +static void var_remove(LexState *ls, BCReg tolevel) +{ + FuncState *fs = ls->fs; + while (fs->nactvar > tolevel) + var_get(ls, fs, --fs->nactvar).endpc = fs->pc; +} + +/* Lookup local variable name. */ +static BCReg var_lookup_local(FuncState *fs, GCstr *n) +{ + int i; + for (i = fs->nactvar-1; i >= 0; i--) { + if (n == strref(var_get(fs->ls, fs, i).name)) + return (BCReg)i; + } + return (BCReg)-1; /* Not found. */ +} + +/* Lookup or add upvalue index. */ +static MSize var_lookup_uv(FuncState *fs, MSize vidx, ExpDesc *e) +{ + MSize i, n = fs->nuv; + for (i = 0; i < n; i++) + if (fs->uvmap[i] == vidx) + return i; /* Already exists. */ + /* Otherwise create a new one. */ + checklimit(fs, fs->nuv, LJ_MAX_UPVAL, "upvalues"); + lj_assertFS(e->k == VLOCAL || e->k == VUPVAL, "bad expr type %d", e->k); + fs->uvmap[n] = (uint16_t)vidx; + fs->uvtmp[n] = (uint16_t)(e->k == VLOCAL ? vidx : LJ_MAX_VSTACK+e->u.s.info); + fs->nuv = n+1; + return n; +} + +/* Forward declaration. */ +static void fscope_uvmark(FuncState *fs, BCReg level); + +/* Recursively lookup variables in enclosing functions. */ +static MSize var_lookup_(FuncState *fs, GCstr *name, ExpDesc *e, int first) +{ + if (fs) { + BCReg reg = var_lookup_local(fs, name); + if ((int32_t)reg >= 0) { /* Local in this function? */ + expr_init(e, VLOCAL, reg); + if (!first) + fscope_uvmark(fs, reg); /* Scope now has an upvalue. */ + return (MSize)(e->u.s.aux = (uint32_t)fs->varmap[reg]); + } else { + MSize vidx = var_lookup_(fs->prev, name, e, 0); /* Var in outer func? */ + if ((int32_t)vidx >= 0) { /* Yes, make it an upvalue here. */ + e->u.s.info = (uint8_t)var_lookup_uv(fs, vidx, e); + e->k = VUPVAL; + return vidx; + } + } + } else { /* Not found in any function, must be a global. */ + expr_init(e, VGLOBAL, 0); + e->u.sval = name; + } + return (MSize)-1; /* Global. */ +} + +/* Lookup variable name. */ +#define var_lookup(ls, e) \ + var_lookup_((ls)->fs, lex_str(ls), (e), 1) + +/* -- Goto an label handling ---------------------------------------------- */ + +/* Add a new goto or label. */ +static MSize gola_new(LexState *ls, GCstr *name, uint8_t info, BCPos pc) +{ + FuncState *fs = ls->fs; + MSize vtop = ls->vtop; + if (LJ_UNLIKELY(vtop >= ls->sizevstack)) { + if (ls->sizevstack >= LJ_MAX_VSTACK) + lj_lex_error(ls, 0, LJ_ERR_XLIMC, LJ_MAX_VSTACK); + lj_mem_growvec(ls->L, ls->vstack, ls->sizevstack, LJ_MAX_VSTACK, VarInfo); + } + lj_assertFS(name == NAME_BREAK || lj_tab_getstr(fs->kt, name) != NULL, + "unanchored label name"); + /* NOBARRIER: name is anchored in fs->kt and ls->vstack is not a GCobj. */ + setgcref(ls->vstack[vtop].name, obj2gco(name)); + ls->vstack[vtop].startpc = pc; + ls->vstack[vtop].slot = (uint8_t)fs->nactvar; + ls->vstack[vtop].info = info; + ls->vtop = vtop+1; + return vtop; +} + +#define gola_isgoto(v) ((v)->info & VSTACK_GOTO) +#define gola_islabel(v) ((v)->info & VSTACK_LABEL) +#define gola_isgotolabel(v) ((v)->info & (VSTACK_GOTO|VSTACK_LABEL)) + +/* Patch goto to jump to label. */ +static void gola_patch(LexState *ls, VarInfo *vg, VarInfo *vl) +{ + FuncState *fs = ls->fs; + BCPos pc = vg->startpc; + setgcrefnull(vg->name); /* Invalidate pending goto. */ + setbc_a(&fs->bcbase[pc].ins, vl->slot); + jmp_patch(fs, pc, vl->startpc); +} + +/* Patch goto to close upvalues. */ +static void gola_close(LexState *ls, VarInfo *vg) +{ + FuncState *fs = ls->fs; + BCPos pc = vg->startpc; + BCIns *ip = &fs->bcbase[pc].ins; + lj_assertFS(gola_isgoto(vg), "expected goto"); + lj_assertFS(bc_op(*ip) == BC_JMP || bc_op(*ip) == BC_UCLO, + "bad bytecode op %d", bc_op(*ip)); + setbc_a(ip, vg->slot); + if (bc_op(*ip) == BC_JMP) { + BCPos next = jmp_next(fs, pc); + if (next != NO_JMP) jmp_patch(fs, next, pc); /* Jump to UCLO. */ + setbc_op(ip, BC_UCLO); /* Turn into UCLO. */ + setbc_j(ip, NO_JMP); + } +} + +/* Resolve pending forward gotos for label. */ +static void gola_resolve(LexState *ls, FuncScope *bl, MSize idx) +{ + VarInfo *vg = ls->vstack + bl->vstart; + VarInfo *vl = ls->vstack + idx; + for (; vg < vl; vg++) + if (gcrefeq(vg->name, vl->name) && gola_isgoto(vg)) { + if (vg->slot < vl->slot) { + GCstr *name = strref(var_get(ls, ls->fs, vg->slot).name); + lj_assertLS((uintptr_t)name >= VARNAME__MAX, "expected goto name"); + ls->linenumber = ls->fs->bcbase[vg->startpc].line; + lj_assertLS(strref(vg->name) != NAME_BREAK, "unexpected break"); + lj_lex_error(ls, 0, LJ_ERR_XGSCOPE, + strdata(strref(vg->name)), strdata(name)); + } + gola_patch(ls, vg, vl); + } +} + +/* Fixup remaining gotos and labels for scope. */ +static void gola_fixup(LexState *ls, FuncScope *bl) +{ + VarInfo *v = ls->vstack + bl->vstart; + VarInfo *ve = ls->vstack + ls->vtop; + for (; v < ve; v++) { + GCstr *name = strref(v->name); + if (name != NULL) { /* Only consider remaining valid gotos/labels. */ + if (gola_islabel(v)) { + VarInfo *vg; + setgcrefnull(v->name); /* Invalidate label that goes out of scope. */ + for (vg = v+1; vg < ve; vg++) /* Resolve pending backward gotos. */ + if (strref(vg->name) == name && gola_isgoto(vg)) { + if ((bl->flags&FSCOPE_UPVAL) && vg->slot > v->slot) + gola_close(ls, vg); + gola_patch(ls, vg, v); + } + } else if (gola_isgoto(v)) { + if (bl->prev) { /* Propagate goto or break to outer scope. */ + bl->prev->flags |= name == NAME_BREAK ? FSCOPE_BREAK : FSCOPE_GOLA; + v->slot = bl->nactvar; + if ((bl->flags & FSCOPE_UPVAL)) + gola_close(ls, v); + } else { /* No outer scope: undefined goto label or no loop. */ + ls->linenumber = ls->fs->bcbase[v->startpc].line; + if (name == NAME_BREAK) + lj_lex_error(ls, 0, LJ_ERR_XBREAK); + else + lj_lex_error(ls, 0, LJ_ERR_XLUNDEF, strdata(name)); + } + } + } + } +} + +/* Find existing label. */ +static VarInfo *gola_findlabel(LexState *ls, GCstr *name) +{ + VarInfo *v = ls->vstack + ls->fs->bl->vstart; + VarInfo *ve = ls->vstack + ls->vtop; + for (; v < ve; v++) + if (strref(v->name) == name && gola_islabel(v)) + return v; + return NULL; +} + +/* -- Scope handling ------------------------------------------------------ */ + +/* Begin a scope. */ +static void fscope_begin(FuncState *fs, FuncScope *bl, int flags) +{ + bl->nactvar = (uint8_t)fs->nactvar; + bl->flags = flags; + bl->vstart = fs->ls->vtop; + bl->prev = fs->bl; + fs->bl = bl; + lj_assertFS(fs->freereg == fs->nactvar, "bad regalloc"); +} + +/* End a scope. */ +static void fscope_end(FuncState *fs) +{ + FuncScope *bl = fs->bl; + LexState *ls = fs->ls; + fs->bl = bl->prev; + var_remove(ls, bl->nactvar); + fs->freereg = fs->nactvar; + lj_assertFS(bl->nactvar == fs->nactvar, "bad regalloc"); + if ((bl->flags & (FSCOPE_UPVAL|FSCOPE_NOCLOSE)) == FSCOPE_UPVAL) + bcemit_AJ(fs, BC_UCLO, bl->nactvar, 0); + if ((bl->flags & FSCOPE_BREAK)) { + if ((bl->flags & FSCOPE_LOOP)) { + MSize idx = gola_new(ls, NAME_BREAK, VSTACK_LABEL, fs->pc); + ls->vtop = idx; /* Drop break label immediately. */ + gola_resolve(ls, bl, idx); + } else { /* Need the fixup step to propagate the breaks. */ + gola_fixup(ls, bl); + return; + } + } + if ((bl->flags & FSCOPE_GOLA)) { + gola_fixup(ls, bl); + } +} + +/* Mark scope as having an upvalue. */ +static void fscope_uvmark(FuncState *fs, BCReg level) +{ + FuncScope *bl; + for (bl = fs->bl; bl && bl->nactvar > level; bl = bl->prev) + ; + if (bl) + bl->flags |= FSCOPE_UPVAL; +} + +/* -- Function state management ------------------------------------------- */ + +/* Fixup bytecode for prototype. */ +static void fs_fixup_bc(FuncState *fs, GCproto *pt, BCIns *bc, MSize n) +{ + BCInsLine *base = fs->bcbase; + MSize i; + pt->sizebc = n; + bc[0] = BCINS_AD((fs->flags & PROTO_VARARG) ? BC_FUNCV : BC_FUNCF, + fs->framesize, 0); + for (i = 1; i < n; i++) + bc[i] = base[i].ins; +} + +/* Fixup upvalues for child prototype, step #2. */ +static void fs_fixup_uv2(FuncState *fs, GCproto *pt) +{ + VarInfo *vstack = fs->ls->vstack; + uint16_t *uv = proto_uv(pt); + MSize i, n = pt->sizeuv; + for (i = 0; i < n; i++) { + VarIndex vidx = uv[i]; + if (vidx >= LJ_MAX_VSTACK) + uv[i] = vidx - LJ_MAX_VSTACK; + else if ((vstack[vidx].info & VSTACK_VAR_RW)) + uv[i] = vstack[vidx].slot | PROTO_UV_LOCAL; + else + uv[i] = vstack[vidx].slot | PROTO_UV_LOCAL | PROTO_UV_IMMUTABLE; + } +} + +/* Fixup constants for prototype. */ +static void fs_fixup_k(FuncState *fs, GCproto *pt, void *kptr) +{ + GCtab *kt; + TValue *array; + Node *node; + MSize i, hmask; + checklimitgt(fs, fs->nkn, BCMAX_D+1, "constants"); + checklimitgt(fs, fs->nkgc, BCMAX_D+1, "constants"); + setmref(pt->k, kptr); + pt->sizekn = fs->nkn; + pt->sizekgc = fs->nkgc; + kt = fs->kt; + array = tvref(kt->array); + for (i = 0; i < kt->asize; i++) + if (tvhaskslot(&array[i])) { + TValue *tv = &((TValue *)kptr)[tvkslot(&array[i])]; + if (LJ_DUALNUM) + setintV(tv, (int32_t)i); + else + setnumV(tv, (lua_Number)i); + } + node = noderef(kt->node); + hmask = kt->hmask; + for (i = 0; i <= hmask; i++) { + Node *n = &node[i]; + if (tvhaskslot(&n->val)) { + ptrdiff_t kidx = (ptrdiff_t)tvkslot(&n->val); + lj_assertFS(!tvisint(&n->key), "unexpected integer key"); + if (tvisnum(&n->key)) { + TValue *tv = &((TValue *)kptr)[kidx]; + if (LJ_DUALNUM) { + lua_Number nn = numV(&n->key); + int32_t k = lj_num2int(nn); + lj_assertFS(!tvismzero(&n->key), "unexpected -0 key"); + if ((lua_Number)k == nn) + setintV(tv, k); + else + *tv = n->key; + } else { + *tv = n->key; + } + } else { + GCobj *o = gcV(&n->key); + setgcref(((GCRef *)kptr)[~kidx], o); + lj_gc_objbarrier(fs->L, pt, o); + if (tvisproto(&n->key)) + fs_fixup_uv2(fs, gco2pt(o)); + } + } + } +} + +/* Fixup upvalues for prototype, step #1. */ +static void fs_fixup_uv1(FuncState *fs, GCproto *pt, uint16_t *uv) +{ + setmref(pt->uv, uv); + pt->sizeuv = fs->nuv; + memcpy(uv, fs->uvtmp, fs->nuv*sizeof(VarIndex)); +} + +#ifndef LUAJIT_DISABLE_DEBUGINFO +/* Prepare lineinfo for prototype. */ +static size_t fs_prep_line(FuncState *fs, BCLine numline) +{ + return (fs->pc-1) << (numline < 256 ? 0 : numline < 65536 ? 1 : 2); +} + +/* Fixup lineinfo for prototype. */ +static void fs_fixup_line(FuncState *fs, GCproto *pt, + void *lineinfo, BCLine numline) +{ + BCInsLine *base = fs->bcbase + 1; + BCLine first = fs->linedefined; + MSize i = 0, n = fs->pc-1; + pt->firstline = fs->linedefined; + pt->numline = numline; + setmref(pt->lineinfo, lineinfo); + if (LJ_LIKELY(numline < 256)) { + uint8_t *li = (uint8_t *)lineinfo; + do { + BCLine delta = base[i].line - first; + lj_assertFS(delta >= 0 && delta < 256, "bad line delta"); + li[i] = (uint8_t)delta; + } while (++i < n); + } else if (LJ_LIKELY(numline < 65536)) { + uint16_t *li = (uint16_t *)lineinfo; + do { + BCLine delta = base[i].line - first; + lj_assertFS(delta >= 0 && delta < 65536, "bad line delta"); + li[i] = (uint16_t)delta; + } while (++i < n); + } else { + uint32_t *li = (uint32_t *)lineinfo; + do { + BCLine delta = base[i].line - first; + lj_assertFS(delta >= 0, "bad line delta"); + li[i] = (uint32_t)delta; + } while (++i < n); + } +} + +/* Prepare variable info for prototype. */ +static size_t fs_prep_var(LexState *ls, FuncState *fs, size_t *ofsvar) +{ + VarInfo *vs =ls->vstack, *ve; + MSize i, n; + BCPos lastpc; + lj_buf_reset(&ls->sb); /* Copy to temp. string buffer. */ + /* Store upvalue names. */ + for (i = 0, n = fs->nuv; i < n; i++) { + GCstr *s = strref(vs[fs->uvmap[i]].name); + MSize len = s->len+1; + char *p = lj_buf_more(&ls->sb, len); + p = lj_buf_wmem(p, strdata(s), len); + ls->sb.w = p; + } + *ofsvar = sbuflen(&ls->sb); + lastpc = 0; + /* Store local variable names and compressed ranges. */ + for (ve = vs + ls->vtop, vs += fs->vbase; vs < ve; vs++) { + if (!gola_isgotolabel(vs)) { + GCstr *s = strref(vs->name); + BCPos startpc; + char *p; + if ((uintptr_t)s < VARNAME__MAX) { + p = lj_buf_more(&ls->sb, 1 + 2*5); + *p++ = (char)(uintptr_t)s; + } else { + MSize len = s->len+1; + p = lj_buf_more(&ls->sb, len + 2*5); + p = lj_buf_wmem(p, strdata(s), len); + } + startpc = vs->startpc; + p = lj_strfmt_wuleb128(p, startpc-lastpc); + p = lj_strfmt_wuleb128(p, vs->endpc-startpc); + ls->sb.w = p; + lastpc = startpc; + } + } + lj_buf_putb(&ls->sb, '\0'); /* Terminator for varinfo. */ + return sbuflen(&ls->sb); +} + +/* Fixup variable info for prototype. */ +static void fs_fixup_var(LexState *ls, GCproto *pt, uint8_t *p, size_t ofsvar) +{ + setmref(pt->uvinfo, p); + setmref(pt->varinfo, (char *)p + ofsvar); + memcpy(p, ls->sb.b, sbuflen(&ls->sb)); /* Copy from temp. buffer. */ +} +#else + +/* Initialize with empty debug info, if disabled. */ +#define fs_prep_line(fs, numline) (UNUSED(numline), 0) +#define fs_fixup_line(fs, pt, li, numline) \ + pt->firstline = pt->numline = 0, setmref((pt)->lineinfo, NULL) +#define fs_prep_var(ls, fs, ofsvar) (UNUSED(ofsvar), 0) +#define fs_fixup_var(ls, pt, p, ofsvar) \ + setmref((pt)->uvinfo, NULL), setmref((pt)->varinfo, NULL) + +#endif + +/* Check if bytecode op returns. */ +static int bcopisret(BCOp op) +{ + switch (op) { + case BC_CALLMT: case BC_CALLT: + case BC_RETM: case BC_RET: case BC_RET0: case BC_RET1: + return 1; + default: + return 0; + } +} + +/* Fixup return instruction for prototype. */ +static void fs_fixup_ret(FuncState *fs) +{ + BCPos lastpc = fs->pc; + if (lastpc <= fs->lasttarget || !bcopisret(bc_op(fs->bcbase[lastpc-1].ins))) { + if ((fs->bl->flags & FSCOPE_UPVAL)) + bcemit_AJ(fs, BC_UCLO, 0, 0); + bcemit_AD(fs, BC_RET0, 0, 1); /* Need final return. */ + } + fs->bl->flags |= FSCOPE_NOCLOSE; /* Handled above. */ + fscope_end(fs); + lj_assertFS(fs->bl == NULL, "bad scope nesting"); + /* May need to fixup returns encoded before first function was created. */ + if (fs->flags & PROTO_FIXUP_RETURN) { + BCPos pc; + for (pc = 1; pc < lastpc; pc++) { + BCIns ins = fs->bcbase[pc].ins; + BCPos offset; + switch (bc_op(ins)) { + case BC_CALLMT: case BC_CALLT: + case BC_RETM: case BC_RET: case BC_RET0: case BC_RET1: + offset = bcemit_INS(fs, ins); /* Copy original instruction. */ + fs->bcbase[offset].line = fs->bcbase[pc].line; + offset = offset-(pc+1)+BCBIAS_J; + if (offset > BCMAX_D) + err_syntax(fs->ls, LJ_ERR_XFIXUP); + /* Replace with UCLO plus branch. */ + fs->bcbase[pc].ins = BCINS_AD(BC_UCLO, 0, offset); + break; + case BC_FNEW: + return; /* We're done. */ + default: + break; + } + } + } +} + +/* Finish a FuncState and return the new prototype. */ +static GCproto *fs_finish(LexState *ls, BCLine line) +{ + lua_State *L = ls->L; + FuncState *fs = ls->fs; + BCLine numline = line - fs->linedefined; + size_t sizept, ofsk, ofsuv, ofsli, ofsdbg, ofsvar; + GCproto *pt; + + /* Apply final fixups. */ + fs_fixup_ret(fs); + + /* Calculate total size of prototype including all colocated arrays. */ + sizept = sizeof(GCproto) + fs->pc*sizeof(BCIns) + fs->nkgc*sizeof(GCRef); + sizept = (sizept + sizeof(TValue)-1) & ~(sizeof(TValue)-1); + ofsk = sizept; sizept += fs->nkn*sizeof(TValue); + ofsuv = sizept; sizept += ((fs->nuv+1)&~1)*2; + ofsli = sizept; sizept += fs_prep_line(fs, numline); + ofsdbg = sizept; sizept += fs_prep_var(ls, fs, &ofsvar); + + /* Allocate prototype and initialize its fields. */ + pt = (GCproto *)lj_mem_newgco(L, (MSize)sizept); + pt->gct = ~LJ_TPROTO; + pt->sizept = (MSize)sizept; + pt->trace = 0; + pt->flags = (uint8_t)(fs->flags & ~(PROTO_HAS_RETURN|PROTO_FIXUP_RETURN)); + pt->numparams = fs->numparams; + pt->framesize = fs->framesize; + setgcref(pt->chunkname, obj2gco(ls->chunkname)); + + /* Close potentially uninitialized gap between bc and kgc. */ + *(uint32_t *)((char *)pt + ofsk - sizeof(GCRef)*(fs->nkgc+1)) = 0; + fs_fixup_bc(fs, pt, (BCIns *)((char *)pt + sizeof(GCproto)), fs->pc); + fs_fixup_k(fs, pt, (void *)((char *)pt + ofsk)); + fs_fixup_uv1(fs, pt, (uint16_t *)((char *)pt + ofsuv)); + fs_fixup_line(fs, pt, (void *)((char *)pt + ofsli), numline); + fs_fixup_var(ls, pt, (uint8_t *)((char *)pt + ofsdbg), ofsvar); + + lj_vmevent_send(L, BC, + setprotoV(L, L->top++, pt); + ); + + L->top--; /* Pop table of constants. */ + ls->vtop = fs->vbase; /* Reset variable stack. */ + ls->fs = fs->prev; + lj_assertL(ls->fs != NULL || ls->tok == TK_eof, "bad parser state"); + return pt; +} + +/* Initialize a new FuncState. */ +static void fs_init(LexState *ls, FuncState *fs) +{ + lua_State *L = ls->L; + fs->prev = ls->fs; ls->fs = fs; /* Append to list. */ + fs->ls = ls; + fs->vbase = ls->vtop; + fs->L = L; + fs->pc = 0; + fs->lasttarget = 0; + fs->jpc = NO_JMP; + fs->freereg = 0; + fs->nkgc = 0; + fs->nkn = 0; + fs->nactvar = 0; + fs->nuv = 0; + fs->bl = NULL; + fs->flags = 0; + fs->framesize = 1; /* Minimum frame size. */ + fs->kt = lj_tab_new(L, 0, 0); + /* Anchor table of constants in stack to avoid being collected. */ + settabV(L, L->top, fs->kt); + incr_top(L); +} + +/* -- Expressions --------------------------------------------------------- */ + +/* Forward declaration. */ +static void expr(LexState *ls, ExpDesc *v); + +/* Return string expression. */ +static void expr_str(LexState *ls, ExpDesc *e) +{ + expr_init(e, VKSTR, 0); + e->u.sval = lex_str(ls); +} + +/* Return index expression. */ +static void expr_index(FuncState *fs, ExpDesc *t, ExpDesc *e) +{ + /* Already called: expr_toval(fs, e). */ + t->k = VINDEXED; + if (expr_isnumk(e)) { +#if LJ_DUALNUM + if (tvisint(expr_numtv(e))) { + int32_t k = intV(expr_numtv(e)); + if (checku8(k)) { + t->u.s.aux = BCMAX_C+1+(uint32_t)k; /* 256..511: const byte key */ + return; + } + } +#else + lua_Number n = expr_numberV(e); + int32_t k = lj_num2int(n); + if (checku8(k) && n == (lua_Number)k) { + t->u.s.aux = BCMAX_C+1+(uint32_t)k; /* 256..511: const byte key */ + return; + } +#endif + } else if (expr_isstrk(e)) { + BCReg idx = const_str(fs, e); + if (idx <= BCMAX_C) { + t->u.s.aux = ~idx; /* -256..-1: const string key */ + return; + } + } + t->u.s.aux = expr_toanyreg(fs, e); /* 0..255: register */ +} + +/* Parse index expression with named field. */ +static void expr_field(LexState *ls, ExpDesc *v) +{ + FuncState *fs = ls->fs; + ExpDesc key; + expr_toanyreg(fs, v); + lj_lex_next(ls); /* Skip dot or colon. */ + expr_str(ls, &key); + expr_index(fs, v, &key); +} + +/* Parse index expression with brackets. */ +static void expr_bracket(LexState *ls, ExpDesc *v) +{ + lj_lex_next(ls); /* Skip '['. */ + expr(ls, v); + expr_toval(ls->fs, v); + lex_check(ls, ']'); +} + +/* Get value of constant expression. */ +static void expr_kvalue(FuncState *fs, TValue *v, ExpDesc *e) +{ + UNUSED(fs); + if (e->k <= VKTRUE) { + setpriV(v, ~(uint32_t)e->k); + } else if (e->k == VKSTR) { + setgcVraw(v, obj2gco(e->u.sval), LJ_TSTR); + } else { + lj_assertFS(tvisnumber(expr_numtv(e)), "bad number constant"); + *v = *expr_numtv(e); + } +} + +/* Parse table constructor expression. */ +static void expr_table(LexState *ls, ExpDesc *e) +{ + FuncState *fs = ls->fs; + BCLine line = ls->linenumber; + GCtab *t = NULL; + int vcall = 0, needarr = 0, fixt = 0; + uint32_t narr = 1; /* First array index. */ + uint32_t nhash = 0; /* Number of hash entries. */ + BCReg freg = fs->freereg; + BCPos pc = bcemit_AD(fs, BC_TNEW, freg, 0); + expr_init(e, VNONRELOC, freg); + bcreg_reserve(fs, 1); + freg++; + lex_check(ls, '{'); + while (ls->tok != '}') { + ExpDesc key, val; + vcall = 0; + if (ls->tok == '[') { + expr_bracket(ls, &key); /* Already calls expr_toval. */ + if (!expr_isk(&key)) expr_index(fs, e, &key); + if (expr_isnumk(&key) && expr_numiszero(&key)) needarr = 1; else nhash++; + lex_check(ls, '='); + } else if ((ls->tok == TK_name || (!LJ_52 && ls->tok == TK_goto)) && + lj_lex_lookahead(ls) == '=') { + expr_str(ls, &key); + lex_check(ls, '='); + nhash++; + } else { + expr_init(&key, VKNUM, 0); + setintV(&key.u.nval, (int)narr); + narr++; + needarr = vcall = 1; + } + expr(ls, &val); + if (expr_isk(&key) && key.k != VKNIL && + (key.k == VKSTR || expr_isk_nojump(&val))) { + TValue k, *v; + if (!t) { /* Create template table on demand. */ + BCReg kidx; + t = lj_tab_new(fs->L, needarr ? narr : 0, hsize2hbits(nhash)); + kidx = const_gc(fs, obj2gco(t), LJ_TTAB); + fs->bcbase[pc].ins = BCINS_AD(BC_TDUP, freg-1, kidx); + } + vcall = 0; + expr_kvalue(fs, &k, &key); + v = lj_tab_set(fs->L, t, &k); + lj_gc_anybarriert(fs->L, t); + if (expr_isk_nojump(&val)) { /* Add const key/value to template table. */ + expr_kvalue(fs, v, &val); + } else { /* Otherwise create dummy string key (avoids lj_tab_newkey). */ + settabV(fs->L, v, t); /* Preserve key with table itself as value. */ + fixt = 1; /* Fix this later, after all resizes. */ + goto nonconst; + } + } else { + nonconst: + if (val.k != VCALL) { expr_toanyreg(fs, &val); vcall = 0; } + if (expr_isk(&key)) expr_index(fs, e, &key); + bcemit_store(fs, e, &val); + } + fs->freereg = freg; + if (!lex_opt(ls, ',') && !lex_opt(ls, ';')) break; + } + lex_match(ls, '}', '{', line); + if (vcall) { + BCInsLine *ilp = &fs->bcbase[fs->pc-1]; + ExpDesc en; + lj_assertFS(bc_a(ilp->ins) == freg && + bc_op(ilp->ins) == (narr > 256 ? BC_TSETV : BC_TSETB), + "bad CALL code generation"); + expr_init(&en, VKNUM, 0); + en.u.nval.u32.lo = narr-1; + en.u.nval.u32.hi = 0x43300000; /* Biased integer to avoid denormals. */ + if (narr > 256) { fs->pc--; ilp--; } + ilp->ins = BCINS_AD(BC_TSETM, freg, const_num(fs, &en)); + setbc_b(&ilp[-1].ins, 0); + } + if (pc == fs->pc-1) { /* Make expr relocable if possible. */ + e->u.s.info = pc; + fs->freereg--; + e->k = VRELOCABLE; + } else { + e->k = VNONRELOC; /* May have been changed by expr_index. */ + } + if (!t) { /* Construct TNEW RD: hhhhhaaaaaaaaaaa. */ + BCIns *ip = &fs->bcbase[pc].ins; + if (!needarr) narr = 0; + else if (narr < 3) narr = 3; + else if (narr > 0x7ff) narr = 0x7ff; + setbc_d(ip, narr|(hsize2hbits(nhash)<<11)); + } else { + if (needarr && t->asize < narr) + lj_tab_reasize(fs->L, t, narr-1); + if (fixt) { /* Fix value for dummy keys in template table. */ + Node *node = noderef(t->node); + uint32_t i, hmask = t->hmask; + for (i = 0; i <= hmask; i++) { + Node *n = &node[i]; + if (tvistab(&n->val)) { + lj_assertFS(tabV(&n->val) == t, "bad dummy key in template table"); + setnilV(&n->val); /* Turn value into nil. */ + } + } + } + lj_gc_check(fs->L); + } +} + +/* Parse function parameters. */ +static BCReg parse_params(LexState *ls, int needself) +{ + FuncState *fs = ls->fs; + BCReg nparams = 0; + lex_check(ls, '('); + if (needself) + var_new_lit(ls, nparams++, "self"); + if (ls->tok != ')') { + do { + if (ls->tok == TK_name || (!LJ_52 && ls->tok == TK_goto)) { + var_new(ls, nparams++, lex_str(ls)); + } else if (ls->tok == TK_dots) { + lj_lex_next(ls); + fs->flags |= PROTO_VARARG; + break; + } else { + err_syntax(ls, LJ_ERR_XPARAM); + } + } while (lex_opt(ls, ',')); + } + var_add(ls, nparams); + lj_assertFS(fs->nactvar == nparams, "bad regalloc"); + bcreg_reserve(fs, nparams); + lex_check(ls, ')'); + return nparams; +} + +/* Forward declaration. */ +static void parse_chunk(LexState *ls); + +/* Parse body of a function. */ +static void parse_body(LexState *ls, ExpDesc *e, int needself, BCLine line) +{ + FuncState fs, *pfs = ls->fs; + FuncScope bl; + GCproto *pt; + ptrdiff_t oldbase = pfs->bcbase - ls->bcstack; + fs_init(ls, &fs); + fscope_begin(&fs, &bl, 0); + fs.linedefined = line; + fs.numparams = (uint8_t)parse_params(ls, needself); + fs.bcbase = pfs->bcbase + pfs->pc; + fs.bclim = pfs->bclim - pfs->pc; + bcemit_AD(&fs, BC_FUNCF, 0, 0); /* Placeholder. */ + parse_chunk(ls); + if (ls->tok != TK_end) lex_match(ls, TK_end, TK_function, line); + pt = fs_finish(ls, (ls->lastline = ls->linenumber)); + pfs->bcbase = ls->bcstack + oldbase; /* May have been reallocated. */ + pfs->bclim = (BCPos)(ls->sizebcstack - oldbase); + /* Store new prototype in the constant array of the parent. */ + expr_init(e, VRELOCABLE, + bcemit_AD(pfs, BC_FNEW, 0, const_gc(pfs, obj2gco(pt), LJ_TPROTO))); +#if LJ_HASFFI + pfs->flags |= (fs.flags & PROTO_FFI); +#endif + if (!(pfs->flags & PROTO_CHILD)) { + if (pfs->flags & PROTO_HAS_RETURN) + pfs->flags |= PROTO_FIXUP_RETURN; + pfs->flags |= PROTO_CHILD; + } + lj_lex_next(ls); +} + +/* Parse expression list. Last expression is left open. */ +static BCReg expr_list(LexState *ls, ExpDesc *v) +{ + BCReg n = 1; + expr(ls, v); + while (lex_opt(ls, ',')) { + expr_tonextreg(ls->fs, v); + expr(ls, v); + n++; + } + return n; +} + +/* Parse function argument list. */ +static void parse_args(LexState *ls, ExpDesc *e) +{ + FuncState *fs = ls->fs; + ExpDesc args; + BCIns ins; + BCReg base; + BCLine line = ls->linenumber; + if (ls->tok == '(') { +#if !LJ_52 + if (line != ls->lastline) + err_syntax(ls, LJ_ERR_XAMBIG); +#endif + lj_lex_next(ls); + if (ls->tok == ')') { /* f(). */ + args.k = VVOID; + } else { + expr_list(ls, &args); + if (args.k == VCALL) /* f(a, b, g()) or f(a, b, ...). */ + setbc_b(bcptr(fs, &args), 0); /* Pass on multiple results. */ + } + lex_match(ls, ')', '(', line); + } else if (ls->tok == '{') { + expr_table(ls, &args); + } else if (ls->tok == TK_string) { + expr_init(&args, VKSTR, 0); + args.u.sval = strV(&ls->tokval); + lj_lex_next(ls); + } else { + err_syntax(ls, LJ_ERR_XFUNARG); + return; /* Silence compiler. */ + } + lj_assertFS(e->k == VNONRELOC, "bad expr type %d", e->k); + base = e->u.s.info; /* Base register for call. */ + if (args.k == VCALL) { + ins = BCINS_ABC(BC_CALLM, base, 2, args.u.s.aux - base - 1 - LJ_FR2); + } else { + if (args.k != VVOID) + expr_tonextreg(fs, &args); + ins = BCINS_ABC(BC_CALL, base, 2, fs->freereg - base - LJ_FR2); + } + expr_init(e, VCALL, bcemit_INS(fs, ins)); + e->u.s.aux = base; + fs->bcbase[fs->pc - 1].line = line; + fs->freereg = base+1; /* Leave one result by default. */ +} + +/* Parse primary expression. */ +static void expr_primary(LexState *ls, ExpDesc *v) +{ + FuncState *fs = ls->fs; + /* Parse prefix expression. */ + if (ls->tok == '(') { + BCLine line = ls->linenumber; + lj_lex_next(ls); + expr(ls, v); + lex_match(ls, ')', '(', line); + expr_discharge(ls->fs, v); + } else if (ls->tok == TK_name || (!LJ_52 && ls->tok == TK_goto)) { + var_lookup(ls, v); + } else { + err_syntax(ls, LJ_ERR_XSYMBOL); + } + for (;;) { /* Parse multiple expression suffixes. */ + if (ls->tok == '.') { + expr_field(ls, v); + } else if (ls->tok == '[') { + ExpDesc key; + expr_toanyreg(fs, v); + expr_bracket(ls, &key); + expr_index(fs, v, &key); + } else if (ls->tok == ':') { + ExpDesc key; + lj_lex_next(ls); + expr_str(ls, &key); + bcemit_method(fs, v, &key); + parse_args(ls, v); + } else if (ls->tok == '(' || ls->tok == TK_string || ls->tok == '{') { + expr_tonextreg(fs, v); + if (LJ_FR2) bcreg_reserve(fs, 1); + parse_args(ls, v); + } else { + break; + } + } +} + +/* Parse simple expression. */ +static void expr_simple(LexState *ls, ExpDesc *v) +{ + switch (ls->tok) { + case TK_number: + expr_init(v, (LJ_HASFFI && tviscdata(&ls->tokval)) ? VKCDATA : VKNUM, 0); + copyTV(ls->L, &v->u.nval, &ls->tokval); + break; + case TK_string: + expr_init(v, VKSTR, 0); + v->u.sval = strV(&ls->tokval); + break; + case TK_nil: + expr_init(v, VKNIL, 0); + break; + case TK_true: + expr_init(v, VKTRUE, 0); + break; + case TK_false: + expr_init(v, VKFALSE, 0); + break; + case TK_dots: { /* Vararg. */ + FuncState *fs = ls->fs; + BCReg base; + checkcond(ls, fs->flags & PROTO_VARARG, LJ_ERR_XDOTS); + bcreg_reserve(fs, 1); + base = fs->freereg-1; + expr_init(v, VCALL, bcemit_ABC(fs, BC_VARG, base, 2, fs->numparams)); + v->u.s.aux = base; + break; + } + case '{': /* Table constructor. */ + expr_table(ls, v); + return; + case TK_function: + lj_lex_next(ls); + parse_body(ls, v, 0, ls->linenumber); + return; + default: + expr_primary(ls, v); + return; + } + lj_lex_next(ls); +} + +/* Manage syntactic levels to avoid blowing up the stack. */ +static void synlevel_begin(LexState *ls) +{ + if (++ls->level >= LJ_MAX_XLEVEL) + lj_lex_error(ls, 0, LJ_ERR_XLEVELS); +} + +#define synlevel_end(ls) ((ls)->level--) + +/* Convert token to binary operator. */ +static BinOpr token2binop(LexToken tok) +{ + switch (tok) { + case '+': return OPR_ADD; + case '-': return OPR_SUB; + case '*': return OPR_MUL; + case '/': return OPR_DIV; + case '%': return OPR_MOD; + case '^': return OPR_POW; + case TK_concat: return OPR_CONCAT; + case TK_ne: return OPR_NE; + case TK_eq: return OPR_EQ; + case '<': return OPR_LT; + case TK_le: return OPR_LE; + case '>': return OPR_GT; + case TK_ge: return OPR_GE; + case TK_and: return OPR_AND; + case TK_or: return OPR_OR; + default: return OPR_NOBINOPR; + } +} + +/* Priorities for each binary operator. ORDER OPR. */ +static const struct { + uint8_t left; /* Left priority. */ + uint8_t right; /* Right priority. */ +} priority[] = { + {6,6}, {6,6}, {7,7}, {7,7}, {7,7}, /* ADD SUB MUL DIV MOD */ + {10,9}, {5,4}, /* POW CONCAT (right associative) */ + {3,3}, {3,3}, /* EQ NE */ + {3,3}, {3,3}, {3,3}, {3,3}, /* LT GE GT LE */ + {2,2}, {1,1} /* AND OR */ +}; + +#define UNARY_PRIORITY 8 /* Priority for unary operators. */ + +/* Forward declaration. */ +static BinOpr expr_binop(LexState *ls, ExpDesc *v, uint32_t limit); + +/* Parse unary expression. */ +static void expr_unop(LexState *ls, ExpDesc *v) +{ + BCOp op; + if (ls->tok == TK_not) { + op = BC_NOT; + } else if (ls->tok == '-') { + op = BC_UNM; + } else if (ls->tok == '#') { + op = BC_LEN; + } else { + expr_simple(ls, v); + return; + } + lj_lex_next(ls); + expr_binop(ls, v, UNARY_PRIORITY); + bcemit_unop(ls->fs, op, v); +} + +/* Parse binary expressions with priority higher than the limit. */ +static BinOpr expr_binop(LexState *ls, ExpDesc *v, uint32_t limit) +{ + BinOpr op; + synlevel_begin(ls); + expr_unop(ls, v); + op = token2binop(ls->tok); + while (op != OPR_NOBINOPR && priority[op].left > limit) { + ExpDesc v2; + BinOpr nextop; + lj_lex_next(ls); + bcemit_binop_left(ls->fs, op, v); + /* Parse binary expression with higher priority. */ + nextop = expr_binop(ls, &v2, priority[op].right); + bcemit_binop(ls->fs, op, v, &v2); + op = nextop; + } + synlevel_end(ls); + return op; /* Return unconsumed binary operator (if any). */ +} + +/* Parse expression. */ +static void expr(LexState *ls, ExpDesc *v) +{ + expr_binop(ls, v, 0); /* Priority 0: parse whole expression. */ +} + +/* Assign expression to the next register. */ +static void expr_next(LexState *ls) +{ + ExpDesc e; + expr(ls, &e); + expr_tonextreg(ls->fs, &e); +} + +/* Parse conditional expression. */ +static BCPos expr_cond(LexState *ls) +{ + ExpDesc v; + expr(ls, &v); + if (v.k == VKNIL) v.k = VKFALSE; + bcemit_branch_t(ls->fs, &v); + return v.f; +} + +/* -- Assignments --------------------------------------------------------- */ + +/* List of LHS variables. */ +typedef struct LHSVarList { + ExpDesc v; /* LHS variable. */ + struct LHSVarList *prev; /* Link to previous LHS variable. */ +} LHSVarList; + +/* Eliminate write-after-read hazards for local variable assignment. */ +static void assign_hazard(LexState *ls, LHSVarList *lh, const ExpDesc *v) +{ + FuncState *fs = ls->fs; + BCReg reg = v->u.s.info; /* Check against this variable. */ + BCReg tmp = fs->freereg; /* Rename to this temp. register (if needed). */ + int hazard = 0; + for (; lh; lh = lh->prev) { + if (lh->v.k == VINDEXED) { + if (lh->v.u.s.info == reg) { /* t[i], t = 1, 2 */ + hazard = 1; + lh->v.u.s.info = tmp; + } + if (lh->v.u.s.aux == reg) { /* t[i], i = 1, 2 */ + hazard = 1; + lh->v.u.s.aux = tmp; + } + } + } + if (hazard) { + bcemit_AD(fs, BC_MOV, tmp, reg); /* Rename conflicting variable. */ + bcreg_reserve(fs, 1); + } +} + +/* Adjust LHS/RHS of an assignment. */ +static void assign_adjust(LexState *ls, BCReg nvars, BCReg nexps, ExpDesc *e) +{ + FuncState *fs = ls->fs; + int32_t extra = (int32_t)nvars - (int32_t)nexps; + if (e->k == VCALL) { + extra++; /* Compensate for the VCALL itself. */ + if (extra < 0) extra = 0; + setbc_b(bcptr(fs, e), extra+1); /* Fixup call results. */ + if (extra > 1) bcreg_reserve(fs, (BCReg)extra-1); + } else { + if (e->k != VVOID) + expr_tonextreg(fs, e); /* Close last expression. */ + if (extra > 0) { /* Leftover LHS are set to nil. */ + BCReg reg = fs->freereg; + bcreg_reserve(fs, (BCReg)extra); + bcemit_nil(fs, reg, (BCReg)extra); + } + } + if (nexps > nvars) + ls->fs->freereg -= nexps - nvars; /* Drop leftover regs. */ +} + +/* Recursively parse assignment statement. */ +static void parse_assignment(LexState *ls, LHSVarList *lh, BCReg nvars) +{ + ExpDesc e; + checkcond(ls, VLOCAL <= lh->v.k && lh->v.k <= VINDEXED, LJ_ERR_XSYNTAX); + if (lex_opt(ls, ',')) { /* Collect LHS list and recurse upwards. */ + LHSVarList vl; + vl.prev = lh; + expr_primary(ls, &vl.v); + if (vl.v.k == VLOCAL) + assign_hazard(ls, lh, &vl.v); + checklimit(ls->fs, ls->level + nvars, LJ_MAX_XLEVEL, "variable names"); + parse_assignment(ls, &vl, nvars+1); + } else { /* Parse RHS. */ + BCReg nexps; + lex_check(ls, '='); + nexps = expr_list(ls, &e); + if (nexps == nvars) { + if (e.k == VCALL) { + if (bc_op(*bcptr(ls->fs, &e)) == BC_VARG) { /* Vararg assignment. */ + ls->fs->freereg--; + e.k = VRELOCABLE; + } else { /* Multiple call results. */ + e.u.s.info = e.u.s.aux; /* Base of call is not relocatable. */ + e.k = VNONRELOC; + } + } + bcemit_store(ls->fs, &lh->v, &e); + return; + } + assign_adjust(ls, nvars, nexps, &e); + } + /* Assign RHS to LHS and recurse downwards. */ + expr_init(&e, VNONRELOC, ls->fs->freereg-1); + bcemit_store(ls->fs, &lh->v, &e); +} + +/* Parse call statement or assignment. */ +static void parse_call_assign(LexState *ls) +{ + FuncState *fs = ls->fs; + LHSVarList vl; + expr_primary(ls, &vl.v); + if (vl.v.k == VCALL) { /* Function call statement. */ + setbc_b(bcptr(fs, &vl.v), 1); /* No results. */ + } else { /* Start of an assignment. */ + vl.prev = NULL; + parse_assignment(ls, &vl, 1); + } +} + +/* Parse 'local' statement. */ +static void parse_local(LexState *ls) +{ + if (lex_opt(ls, TK_function)) { /* Local function declaration. */ + ExpDesc v, b; + FuncState *fs = ls->fs; + var_new(ls, 0, lex_str(ls)); + expr_init(&v, VLOCAL, fs->freereg); + v.u.s.aux = fs->varmap[fs->freereg]; + bcreg_reserve(fs, 1); + var_add(ls, 1); + parse_body(ls, &b, 0, ls->linenumber); + /* bcemit_store(fs, &v, &b) without setting VSTACK_VAR_RW. */ + expr_free(fs, &b); + expr_toreg(fs, &b, v.u.s.info); + /* The upvalue is in scope, but the local is only valid after the store. */ + var_get(ls, fs, fs->nactvar - 1).startpc = fs->pc; + } else { /* Local variable declaration. */ + ExpDesc e; + BCReg nexps, nvars = 0; + do { /* Collect LHS. */ + var_new(ls, nvars++, lex_str(ls)); + } while (lex_opt(ls, ',')); + if (lex_opt(ls, '=')) { /* Optional RHS. */ + nexps = expr_list(ls, &e); + } else { /* Or implicitly set to nil. */ + e.k = VVOID; + nexps = 0; + } + assign_adjust(ls, nvars, nexps, &e); + var_add(ls, nvars); + } +} + +/* Parse 'function' statement. */ +static void parse_func(LexState *ls, BCLine line) +{ + FuncState *fs; + ExpDesc v, b; + int needself = 0; + lj_lex_next(ls); /* Skip 'function'. */ + /* Parse function name. */ + var_lookup(ls, &v); + while (ls->tok == '.') /* Multiple dot-separated fields. */ + expr_field(ls, &v); + if (ls->tok == ':') { /* Optional colon to signify method call. */ + needself = 1; + expr_field(ls, &v); + } + parse_body(ls, &b, needself, line); + fs = ls->fs; + bcemit_store(fs, &v, &b); + fs->bcbase[fs->pc - 1].line = line; /* Set line for the store. */ +} + +/* -- Control transfer statements ----------------------------------------- */ + +/* Check for end of block. */ +static int parse_isend(LexToken tok) +{ + switch (tok) { + case TK_else: case TK_elseif: case TK_end: case TK_until: case TK_eof: + return 1; + default: + return 0; + } +} + +/* Parse 'return' statement. */ +static void parse_return(LexState *ls) +{ + BCIns ins; + FuncState *fs = ls->fs; + lj_lex_next(ls); /* Skip 'return'. */ + fs->flags |= PROTO_HAS_RETURN; + if (parse_isend(ls->tok) || ls->tok == ';') { /* Bare return. */ + ins = BCINS_AD(BC_RET0, 0, 1); + } else { /* Return with one or more values. */ + ExpDesc e; /* Receives the _last_ expression in the list. */ + BCReg nret = expr_list(ls, &e); + if (nret == 1) { /* Return one result. */ + if (e.k == VCALL) { /* Check for tail call. */ + BCIns *ip = bcptr(fs, &e); + /* It doesn't pay off to add BC_VARGT just for 'return ...'. */ + if (bc_op(*ip) == BC_VARG) goto notailcall; + fs->pc--; + ins = BCINS_AD(bc_op(*ip)-BC_CALL+BC_CALLT, bc_a(*ip), bc_c(*ip)); + } else { /* Can return the result from any register. */ + ins = BCINS_AD(BC_RET1, expr_toanyreg(fs, &e), 2); + } + } else { + if (e.k == VCALL) { /* Append all results from a call. */ + notailcall: + setbc_b(bcptr(fs, &e), 0); + ins = BCINS_AD(BC_RETM, fs->nactvar, e.u.s.aux - fs->nactvar); + } else { + expr_tonextreg(fs, &e); /* Force contiguous registers. */ + ins = BCINS_AD(BC_RET, fs->nactvar, nret+1); + } + } + } + if (fs->flags & PROTO_CHILD) + bcemit_AJ(fs, BC_UCLO, 0, 0); /* May need to close upvalues first. */ + bcemit_INS(fs, ins); +} + +/* Parse 'break' statement. */ +static void parse_break(LexState *ls) +{ + ls->fs->bl->flags |= FSCOPE_BREAK; + gola_new(ls, NAME_BREAK, VSTACK_GOTO, bcemit_jmp(ls->fs)); +} + +/* Parse 'goto' statement. */ +static void parse_goto(LexState *ls) +{ + FuncState *fs = ls->fs; + GCstr *name = lex_str(ls); + VarInfo *vl = gola_findlabel(ls, name); + if (vl) /* Treat backwards goto within same scope like a loop. */ + bcemit_AJ(fs, BC_LOOP, vl->slot, -1); /* No BC range check. */ + fs->bl->flags |= FSCOPE_GOLA; + gola_new(ls, name, VSTACK_GOTO, bcemit_jmp(fs)); +} + +/* Parse label. */ +static void parse_label(LexState *ls) +{ + FuncState *fs = ls->fs; + GCstr *name; + MSize idx; + fs->lasttarget = fs->pc; + fs->bl->flags |= FSCOPE_GOLA; + lj_lex_next(ls); /* Skip '::'. */ + name = lex_str(ls); + if (gola_findlabel(ls, name)) + lj_lex_error(ls, 0, LJ_ERR_XLDUP, strdata(name)); + idx = gola_new(ls, name, VSTACK_LABEL, fs->pc); + lex_check(ls, TK_label); + /* Recursively parse trailing statements: labels and ';' (Lua 5.2 only). */ + for (;;) { + if (ls->tok == TK_label) { + synlevel_begin(ls); + parse_label(ls); + synlevel_end(ls); + } else if (LJ_52 && ls->tok == ';') { + lj_lex_next(ls); + } else { + break; + } + } + /* Trailing label is considered to be outside of scope. */ + if (parse_isend(ls->tok) && ls->tok != TK_until) + ls->vstack[idx].slot = fs->bl->nactvar; + gola_resolve(ls, fs->bl, idx); +} + +/* -- Blocks, loops and conditional statements ---------------------------- */ + +/* Parse a block. */ +static void parse_block(LexState *ls) +{ + FuncState *fs = ls->fs; + FuncScope bl; + fscope_begin(fs, &bl, 0); + parse_chunk(ls); + fscope_end(fs); +} + +/* Parse 'while' statement. */ +static void parse_while(LexState *ls, BCLine line) +{ + FuncState *fs = ls->fs; + BCPos start, loop, condexit; + FuncScope bl; + lj_lex_next(ls); /* Skip 'while'. */ + start = fs->lasttarget = fs->pc; + condexit = expr_cond(ls); + fscope_begin(fs, &bl, FSCOPE_LOOP); + lex_check(ls, TK_do); + loop = bcemit_AD(fs, BC_LOOP, fs->nactvar, 0); + parse_block(ls); + jmp_patch(fs, bcemit_jmp(fs), start); + lex_match(ls, TK_end, TK_while, line); + fscope_end(fs); + jmp_tohere(fs, condexit); + jmp_patchins(fs, loop, fs->pc); +} + +/* Parse 'repeat' statement. */ +static void parse_repeat(LexState *ls, BCLine line) +{ + FuncState *fs = ls->fs; + BCPos loop = fs->lasttarget = fs->pc; + BCPos condexit; + FuncScope bl1, bl2; + fscope_begin(fs, &bl1, FSCOPE_LOOP); /* Breakable loop scope. */ + fscope_begin(fs, &bl2, 0); /* Inner scope. */ + lj_lex_next(ls); /* Skip 'repeat'. */ + bcemit_AD(fs, BC_LOOP, fs->nactvar, 0); + parse_chunk(ls); + lex_match(ls, TK_until, TK_repeat, line); + condexit = expr_cond(ls); /* Parse condition (still inside inner scope). */ + if (!(bl2.flags & FSCOPE_UPVAL)) { /* No upvalues? Just end inner scope. */ + fscope_end(fs); + } else { /* Otherwise generate: cond: UCLO+JMP out, !cond: UCLO+JMP loop. */ + parse_break(ls); /* Break from loop and close upvalues. */ + jmp_tohere(fs, condexit); + fscope_end(fs); /* End inner scope and close upvalues. */ + condexit = bcemit_jmp(fs); + } + jmp_patch(fs, condexit, loop); /* Jump backwards if !cond. */ + jmp_patchins(fs, loop, fs->pc); + fscope_end(fs); /* End loop scope. */ +} + +/* Parse numeric 'for'. */ +static void parse_for_num(LexState *ls, GCstr *varname, BCLine line) +{ + FuncState *fs = ls->fs; + BCReg base = fs->freereg; + FuncScope bl; + BCPos loop, loopend; + /* Hidden control variables. */ + var_new_fixed(ls, FORL_IDX, VARNAME_FOR_IDX); + var_new_fixed(ls, FORL_STOP, VARNAME_FOR_STOP); + var_new_fixed(ls, FORL_STEP, VARNAME_FOR_STEP); + /* Visible copy of index variable. */ + var_new(ls, FORL_EXT, varname); + lex_check(ls, '='); + expr_next(ls); + lex_check(ls, ','); + expr_next(ls); + if (lex_opt(ls, ',')) { + expr_next(ls); + } else { + bcemit_AD(fs, BC_KSHORT, fs->freereg, 1); /* Default step is 1. */ + bcreg_reserve(fs, 1); + } + var_add(ls, 3); /* Hidden control variables. */ + lex_check(ls, TK_do); + loop = bcemit_AJ(fs, BC_FORI, base, NO_JMP); + fscope_begin(fs, &bl, 0); /* Scope for visible variables. */ + var_add(ls, 1); + bcreg_reserve(fs, 1); + parse_block(ls); + fscope_end(fs); + /* Perform loop inversion. Loop control instructions are at the end. */ + loopend = bcemit_AJ(fs, BC_FORL, base, NO_JMP); + fs->bcbase[loopend].line = line; /* Fix line for control ins. */ + jmp_patchins(fs, loopend, loop+1); + jmp_patchins(fs, loop, fs->pc); +} + +/* Try to predict whether the iterator is next() and specialize the bytecode. +** Detecting next() and pairs() by name is simplistic, but quite effective. +** The interpreter backs off if the check for the closure fails at runtime. +*/ +static int predict_next(LexState *ls, FuncState *fs, BCPos pc) +{ + BCIns ins = fs->bcbase[pc].ins; + GCstr *name; + cTValue *o; + switch (bc_op(ins)) { + case BC_MOV: + name = gco2str(gcref(var_get(ls, fs, bc_d(ins)).name)); + break; + case BC_UGET: + name = gco2str(gcref(ls->vstack[fs->uvmap[bc_d(ins)]].name)); + break; + case BC_GGET: + /* There's no inverse index (yet), so lookup the strings. */ + o = lj_tab_getstr(fs->kt, lj_str_newlit(ls->L, "pairs")); + if (o && tvhaskslot(o) && tvkslot(o) == bc_d(ins)) + return 1; + o = lj_tab_getstr(fs->kt, lj_str_newlit(ls->L, "next")); + if (o && tvhaskslot(o) && tvkslot(o) == bc_d(ins)) + return 1; + return 0; + default: + return 0; + } + return (name->len == 5 && !strcmp(strdata(name), "pairs")) || + (name->len == 4 && !strcmp(strdata(name), "next")); +} + +/* Parse 'for' iterator. */ +static void parse_for_iter(LexState *ls, GCstr *indexname) +{ + FuncState *fs = ls->fs; + ExpDesc e; + BCReg nvars = 0; + BCLine line; + BCReg base = fs->freereg + 3; + BCPos loop, loopend, exprpc = fs->pc; + FuncScope bl; + int isnext; + /* Hidden control variables. */ + var_new_fixed(ls, nvars++, VARNAME_FOR_GEN); + var_new_fixed(ls, nvars++, VARNAME_FOR_STATE); + var_new_fixed(ls, nvars++, VARNAME_FOR_CTL); + /* Visible variables returned from iterator. */ + var_new(ls, nvars++, indexname); + while (lex_opt(ls, ',')) + var_new(ls, nvars++, lex_str(ls)); + lex_check(ls, TK_in); + line = ls->linenumber; + assign_adjust(ls, 3, expr_list(ls, &e), &e); + /* The iterator needs another 3 [4] slots (func [pc] | state ctl). */ + bcreg_bump(fs, 3+LJ_FR2); + isnext = (nvars <= 5 && predict_next(ls, fs, exprpc)); + var_add(ls, 3); /* Hidden control variables. */ + lex_check(ls, TK_do); + loop = bcemit_AJ(fs, isnext ? BC_ISNEXT : BC_JMP, base, NO_JMP); + fscope_begin(fs, &bl, 0); /* Scope for visible variables. */ + var_add(ls, nvars-3); + bcreg_reserve(fs, nvars-3); + parse_block(ls); + fscope_end(fs); + /* Perform loop inversion. Loop control instructions are at the end. */ + jmp_patchins(fs, loop, fs->pc); + bcemit_ABC(fs, isnext ? BC_ITERN : BC_ITERC, base, nvars-3+1, 2+1); + loopend = bcemit_AJ(fs, BC_ITERL, base, NO_JMP); + fs->bcbase[loopend-1].line = line; /* Fix line for control ins. */ + fs->bcbase[loopend].line = line; + jmp_patchins(fs, loopend, loop+1); +} + +/* Parse 'for' statement. */ +static void parse_for(LexState *ls, BCLine line) +{ + FuncState *fs = ls->fs; + GCstr *varname; + FuncScope bl; + fscope_begin(fs, &bl, FSCOPE_LOOP); + lj_lex_next(ls); /* Skip 'for'. */ + varname = lex_str(ls); /* Get first variable name. */ + if (ls->tok == '=') + parse_for_num(ls, varname, line); + else if (ls->tok == ',' || ls->tok == TK_in) + parse_for_iter(ls, varname); + else + err_syntax(ls, LJ_ERR_XFOR); + lex_match(ls, TK_end, TK_for, line); + fscope_end(fs); /* Resolve break list. */ +} + +/* Parse condition and 'then' block. */ +static BCPos parse_then(LexState *ls) +{ + BCPos condexit; + lj_lex_next(ls); /* Skip 'if' or 'elseif'. */ + condexit = expr_cond(ls); + lex_check(ls, TK_then); + parse_block(ls); + return condexit; +} + +/* Parse 'if' statement. */ +static void parse_if(LexState *ls, BCLine line) +{ + FuncState *fs = ls->fs; + BCPos flist; + BCPos escapelist = NO_JMP; + flist = parse_then(ls); + while (ls->tok == TK_elseif) { /* Parse multiple 'elseif' blocks. */ + jmp_append(fs, &escapelist, bcemit_jmp(fs)); + jmp_tohere(fs, flist); + flist = parse_then(ls); + } + if (ls->tok == TK_else) { /* Parse optional 'else' block. */ + jmp_append(fs, &escapelist, bcemit_jmp(fs)); + jmp_tohere(fs, flist); + lj_lex_next(ls); /* Skip 'else'. */ + parse_block(ls); + } else { + jmp_append(fs, &escapelist, flist); + } + jmp_tohere(fs, escapelist); + lex_match(ls, TK_end, TK_if, line); +} + +/* -- Parse statements ---------------------------------------------------- */ + +/* Parse a statement. Returns 1 if it must be the last one in a chunk. */ +static int parse_stmt(LexState *ls) +{ + BCLine line = ls->linenumber; + switch (ls->tok) { + case TK_if: + parse_if(ls, line); + break; + case TK_while: + parse_while(ls, line); + break; + case TK_do: + lj_lex_next(ls); + parse_block(ls); + lex_match(ls, TK_end, TK_do, line); + break; + case TK_for: + parse_for(ls, line); + break; + case TK_repeat: + parse_repeat(ls, line); + break; + case TK_function: + parse_func(ls, line); + break; + case TK_local: + lj_lex_next(ls); + parse_local(ls); + break; + case TK_return: + parse_return(ls); + return 1; /* Must be last. */ + case TK_break: + lj_lex_next(ls); + parse_break(ls); + return !LJ_52; /* Must be last in Lua 5.1. */ +#if LJ_52 + case ';': + lj_lex_next(ls); + break; +#endif + case TK_label: + parse_label(ls); + break; + case TK_goto: + if (LJ_52 || lj_lex_lookahead(ls) == TK_name) { + lj_lex_next(ls); + parse_goto(ls); + break; + } + /* fallthrough */ + default: + parse_call_assign(ls); + break; + } + return 0; +} + +/* A chunk is a list of statements optionally separated by semicolons. */ +static void parse_chunk(LexState *ls) +{ + int islast = 0; + synlevel_begin(ls); + while (!islast && !parse_isend(ls->tok)) { + islast = parse_stmt(ls); + lex_opt(ls, ';'); + lj_assertLS(ls->fs->framesize >= ls->fs->freereg && + ls->fs->freereg >= ls->fs->nactvar, + "bad regalloc"); + ls->fs->freereg = ls->fs->nactvar; /* Free registers after each stmt. */ + } + synlevel_end(ls); +} + +/* Entry point of bytecode parser. */ +GCproto *lj_parse(LexState *ls) +{ + FuncState fs; + FuncScope bl; + GCproto *pt; + lua_State *L = ls->L; +#ifdef LUAJIT_DISABLE_DEBUGINFO + ls->chunkname = lj_str_newlit(L, "="); +#else + ls->chunkname = lj_str_newz(L, ls->chunkarg); +#endif + setstrV(L, L->top, ls->chunkname); /* Anchor chunkname string. */ + incr_top(L); + ls->level = 0; + fs_init(ls, &fs); + fs.linedefined = 0; + fs.numparams = 0; + fs.bcbase = NULL; + fs.bclim = 0; + fs.flags |= PROTO_VARARG; /* Main chunk is always a vararg func. */ + fscope_begin(&fs, &bl, 0); + bcemit_AD(&fs, BC_FUNCV, 0, 0); /* Placeholder. */ + lj_lex_next(ls); /* Read-ahead first token. */ + parse_chunk(ls); + if (ls->tok != TK_eof) + err_token(ls, TK_eof); + pt = fs_finish(ls, ls->linenumber); + L->top--; /* Drop chunkname. */ + lj_assertL(fs.prev == NULL && ls->fs == NULL, "mismatched frame nesting"); + lj_assertL(pt->sizeuv == 0, "toplevel proto has upvalues"); + return pt; +} + diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_parse.h b/fluent-bit/lib/luajit-3065c9/src/lj_parse.h new file mode 100644 index 00000000..4206f00e --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_parse.h @@ -0,0 +1,18 @@ +/* +** Lua parser (source code -> bytecode). +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#ifndef _LJ_PARSE_H +#define _LJ_PARSE_H + +#include "lj_obj.h" +#include "lj_lex.h" + +LJ_FUNC GCproto *lj_parse(LexState *ls); +LJ_FUNC GCstr *lj_parse_keepstr(LexState *ls, const char *str, size_t l); +#if LJ_HASFFI +LJ_FUNC void lj_parse_keepcdata(LexState *ls, TValue *tv, GCcdata *cd); +#endif + +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_prng.c b/fluent-bit/lib/luajit-3065c9/src/lj_prng.c new file mode 100644 index 00000000..9e57505e --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_prng.c @@ -0,0 +1,259 @@ +/* +** Pseudo-random number generation. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#define lj_prng_c +#define LUA_CORE + +/* To get the syscall prototype. */ +#if defined(__linux__) && !defined(_GNU_SOURCE) +#define _GNU_SOURCE +#endif + +#include "lj_def.h" +#include "lj_arch.h" +#include "lj_prng.h" + +/* -- PRNG step function -------------------------------------------------- */ + +/* This implements a Tausworthe PRNG with period 2^223. Based on: +** Tables of maximally-equidistributed combined LFSR generators, +** Pierre L'Ecuyer, 1991, table 3, 1st entry. +** Full-period ME-CF generator with L=64, J=4, k=223, N1=49. +** +** Important note: This PRNG is NOT suitable for cryptographic use! +** +** But it works fine for math.random(), which has an API that's not +** suitable for cryptography, anyway. +** +** When used as a securely seeded global PRNG, it substantially raises +** the difficulty for various attacks on the VM. +*/ + +/* Update generator i and compute a running xor of all states. */ +#define TW223_GEN(rs, z, r, i, k, q, s) \ + z = rs->u[i]; \ + z = (((z<> (k-s)) ^ ((z&((uint64_t)(int64_t)-1 << (64-k)))<u[i] = z; + +#define TW223_STEP(rs, z, r) \ + TW223_GEN(rs, z, r, 0, 63, 31, 18) \ + TW223_GEN(rs, z, r, 1, 58, 19, 28) \ + TW223_GEN(rs, z, r, 2, 55, 24, 7) \ + TW223_GEN(rs, z, r, 3, 47, 21, 8) + +/* PRNG step function with uint64_t result. */ +LJ_NOINLINE uint64_t LJ_FASTCALL lj_prng_u64(PRNGState *rs) +{ + uint64_t z, r = 0; + TW223_STEP(rs, z, r) + return r; +} + +/* PRNG step function with double in uint64_t result. */ +LJ_NOINLINE uint64_t LJ_FASTCALL lj_prng_u64d(PRNGState *rs) +{ + uint64_t z, r = 0; + TW223_STEP(rs, z, r) + /* Returns a double bit pattern in the range 1.0 <= d < 2.0. */ + return (r & U64x(000fffff,ffffffff)) | U64x(3ff00000,00000000); +} + +/* Condition seed: ensure k[i] MSB of u[i] are non-zero. */ +static LJ_AINLINE void lj_prng_condition(PRNGState *rs) +{ + if (rs->u[0] < (1u << 1)) rs->u[0] += (1u << 1); + if (rs->u[1] < (1u << 6)) rs->u[1] += (1u << 6); + if (rs->u[2] < (1u << 9)) rs->u[2] += (1u << 9); + if (rs->u[3] < (1u << 17)) rs->u[3] += (1u << 17); +} + +/* -- PRNG seeding from OS ------------------------------------------------ */ + +#if LUAJIT_SECURITY_PRNG == 0 + +/* Nothing to define. */ + +#elif LJ_TARGET_XBOX360 + +extern int XNetRandom(void *buf, unsigned int len); + +#elif LJ_TARGET_PS3 + +extern int sys_get_random_number(void *buf, uint64_t len); + +#elif LJ_TARGET_PS4 || LJ_TARGET_PS5 || LJ_TARGET_PSVITA + +extern int sceRandomGetRandomNumber(void *buf, size_t len); + +#elif LJ_TARGET_NX + +#include + +#elif LJ_TARGET_WINDOWS || LJ_TARGET_XBOXONE + +#define WIN32_LEAN_AND_MEAN +#include + +#if LJ_TARGET_UWP || LJ_TARGET_XBOXONE +/* Must use BCryptGenRandom. */ +#include +#pragma comment(lib, "bcrypt.lib") +#else +/* If you wonder about this mess, then search online for RtlGenRandom. */ +typedef BOOLEAN (WINAPI *PRGR)(void *buf, ULONG len); +static PRGR libfunc_rgr; +#endif + +#elif LJ_TARGET_POSIX + +#if LJ_TARGET_LINUX +/* Avoid a dependency on glibc 2.25+ and use the getrandom syscall instead. */ +#include +#else + +#if LJ_TARGET_OSX && !LJ_TARGET_IOS +/* +** In their infinite wisdom Apple decided to disallow getentropy() in the +** iOS App Store. Even though the call is common to all BSD-ish OS, it's +** recommended by Apple in their own security-related docs, and, to top +** off the foolery, /dev/urandom is handled by the same kernel code, +** yet accessing it is actually permitted (but less efficient). +*/ +#include +#if __MAC_OS_X_VERSION_MIN_REQUIRED >= 101200 +#define LJ_TARGET_HAS_GETENTROPY 1 +#endif +#elif (LJ_TARGET_BSD && !defined(__NetBSD__)) || LJ_TARGET_SOLARIS || LJ_TARGET_CYGWIN +#define LJ_TARGET_HAS_GETENTROPY 1 +#endif + +#if LJ_TARGET_HAS_GETENTROPY +extern int getentropy(void *buf, size_t len) +#ifdef __ELF__ + __attribute__((weak)) +#endif +; +#endif + +#endif + +/* For the /dev/urandom fallback. */ +#include +#include + +#endif + +#if LUAJIT_SECURITY_PRNG == 0 + +/* If you really don't care about security, then define +** LUAJIT_SECURITY_PRNG=0. This yields a predictable seed +** and provides NO SECURITY against various attacks on the VM. +** +** BTW: This is NOT the way to get predictable table iteration, +** predictable trace generation, predictable bytecode generation, etc. +*/ +int LJ_FASTCALL lj_prng_seed_secure(PRNGState *rs) +{ + lj_prng_seed_fixed(rs); /* The fixed seed is already conditioned. */ + return 1; +} + +#else + +/* Securely seed PRNG from system entropy. Returns 0 on failure. */ +int LJ_FASTCALL lj_prng_seed_secure(PRNGState *rs) +{ +#if LJ_TARGET_XBOX360 + + if (XNetRandom(rs->u, (unsigned int)sizeof(rs->u)) == 0) + goto ok; + +#elif LJ_TARGET_PS3 + + if (sys_get_random_number(rs->u, sizeof(rs->u)) == 0) + goto ok; + +#elif LJ_TARGET_PS4 || LJ_TARGET_PS5 || LJ_TARGET_PSVITA + + if (sceRandomGetRandomNumber(rs->u, sizeof(rs->u)) == 0) + goto ok; + +#elif LJ_TARGET_NX + + if (getentropy(rs->u, sizeof(rs->u)) == 0) + goto ok; + +#elif LJ_TARGET_UWP || LJ_TARGET_XBOXONE + + if (BCryptGenRandom(NULL, (PUCHAR)(rs->u), (ULONG)sizeof(rs->u), + BCRYPT_USE_SYSTEM_PREFERRED_RNG) >= 0) + goto ok; + +#elif LJ_TARGET_WINDOWS + + /* Keep the library loaded in case multiple VMs are started. */ + if (!libfunc_rgr) { + HMODULE lib = LJ_WIN_LOADLIBA("advapi32.dll"); + if (!lib) return 0; + libfunc_rgr = (PRGR)GetProcAddress(lib, "SystemFunction036"); + if (!libfunc_rgr) return 0; + } + if (libfunc_rgr(rs->u, (ULONG)sizeof(rs->u))) + goto ok; + +#elif LJ_TARGET_POSIX + +#if LJ_TARGET_LINUX && defined(SYS_getrandom) + + if (syscall(SYS_getrandom, rs->u, sizeof(rs->u), 0) == (long)sizeof(rs->u)) + goto ok; + +#elif LJ_TARGET_HAS_GETENTROPY + +#ifdef __ELF__ + if (&getentropy && getentropy(rs->u, sizeof(rs->u)) == 0) + goto ok; +#else + if (getentropy(rs->u, sizeof(rs->u)) == 0) + goto ok; +#endif + +#endif + + /* Fallback to /dev/urandom. This may fail if the device is not + ** existent or accessible in a chroot or container, or if the process + ** or the OS ran out of file descriptors. + */ + { + int fd = open("/dev/urandom", O_RDONLY|O_CLOEXEC); + if (fd != -1) { + ssize_t n = read(fd, rs->u, sizeof(rs->u)); + (void)close(fd); + if (n == (ssize_t)sizeof(rs->u)) + goto ok; + } + } + +#else + + /* Add an elif above for your OS with a secure PRNG seed. + ** Note that fiddling around with rand(), getpid(), time() or coercing + ** ASLR to yield a few bits of randomness is not helpful. + ** If you don't want any security, then don't pretend you have any + ** and simply define LUAJIT_SECURITY_PRNG=0 for the build. + */ +#error "Missing secure PRNG seed for this OS" + +#endif + return 0; /* Fail. */ + +ok: + lj_prng_condition(rs); + (void)lj_prng_u64(rs); + return 1; /* Success. */ +} + +#endif + diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_prng.h b/fluent-bit/lib/luajit-3065c9/src/lj_prng.h new file mode 100644 index 00000000..bdc958ab --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_prng.h @@ -0,0 +1,24 @@ +/* +** Pseudo-random number generation. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#ifndef _LJ_PRNG_H +#define _LJ_PRNG_H + +#include "lj_def.h" + +LJ_FUNC int LJ_FASTCALL lj_prng_seed_secure(PRNGState *rs); +LJ_FUNC uint64_t LJ_FASTCALL lj_prng_u64(PRNGState *rs); +LJ_FUNC uint64_t LJ_FASTCALL lj_prng_u64d(PRNGState *rs); + +/* This is just the precomputed result of lib_math.c:random_seed(rs, 0.0). */ +static LJ_AINLINE void lj_prng_seed_fixed(PRNGState *rs) +{ + rs->u[0] = U64x(a0d27757,0a345b8c); + rs->u[1] = U64x(764a296c,5d4aa64f); + rs->u[2] = U64x(51220704,070adeaa); + rs->u[3] = U64x(2a2717b5,a7b7b927); +} + +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_profile.c b/fluent-bit/lib/luajit-3065c9/src/lj_profile.c new file mode 100644 index 00000000..f0af91cb --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_profile.c @@ -0,0 +1,367 @@ +/* +** Low-overhead profiling. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#define lj_profile_c +#define LUA_CORE + +#include "lj_obj.h" + +#if LJ_HASPROFILE + +#include "lj_buf.h" +#include "lj_frame.h" +#include "lj_debug.h" +#include "lj_dispatch.h" +#if LJ_HASJIT +#include "lj_jit.h" +#include "lj_trace.h" +#endif +#include "lj_profile.h" + +#include "luajit.h" + +#if LJ_PROFILE_SIGPROF + +#include +#include +#define profile_lock(ps) UNUSED(ps) +#define profile_unlock(ps) UNUSED(ps) + +#elif LJ_PROFILE_PTHREAD + +#include +#include +#if LJ_TARGET_PS3 +#include +#endif +#define profile_lock(ps) pthread_mutex_lock(&ps->lock) +#define profile_unlock(ps) pthread_mutex_unlock(&ps->lock) + +#elif LJ_PROFILE_WTHREAD + +#define WIN32_LEAN_AND_MEAN +#if LJ_TARGET_XBOX360 +#include +#include +#else +#include +#endif +typedef unsigned int (WINAPI *WMM_TPFUNC)(unsigned int); +#define profile_lock(ps) EnterCriticalSection(&ps->lock) +#define profile_unlock(ps) LeaveCriticalSection(&ps->lock) + +#endif + +/* Profiler state. */ +typedef struct ProfileState { + global_State *g; /* VM state that started the profiler. */ + luaJIT_profile_callback cb; /* Profiler callback. */ + void *data; /* Profiler callback data. */ + SBuf sb; /* String buffer for stack dumps. */ + int interval; /* Sample interval in milliseconds. */ + int samples; /* Number of samples for next callback. */ + int vmstate; /* VM state when profile timer triggered. */ +#if LJ_PROFILE_SIGPROF + struct sigaction oldsa; /* Previous SIGPROF state. */ +#elif LJ_PROFILE_PTHREAD + pthread_mutex_t lock; /* g->hookmask update lock. */ + pthread_t thread; /* Timer thread. */ + int abort; /* Abort timer thread. */ +#elif LJ_PROFILE_WTHREAD +#if LJ_TARGET_WINDOWS + HINSTANCE wmm; /* WinMM library handle. */ + WMM_TPFUNC wmm_tbp; /* WinMM timeBeginPeriod function. */ + WMM_TPFUNC wmm_tep; /* WinMM timeEndPeriod function. */ +#endif + CRITICAL_SECTION lock; /* g->hookmask update lock. */ + HANDLE thread; /* Timer thread. */ + int abort; /* Abort timer thread. */ +#endif +} ProfileState; + +/* Sadly, we have to use a static profiler state. +** +** The SIGPROF variant needs a static pointer to the global state, anyway. +** And it would be hard to extend for multiple threads. You can still use +** multiple VMs in multiple threads, but only profile one at a time. +*/ +static ProfileState profile_state; + +/* Default sample interval in milliseconds. */ +#define LJ_PROFILE_INTERVAL_DEFAULT 10 + +/* -- Profiler/hook interaction ------------------------------------------- */ + +#if !LJ_PROFILE_SIGPROF +void LJ_FASTCALL lj_profile_hook_enter(global_State *g) +{ + ProfileState *ps = &profile_state; + if (ps->g) { + profile_lock(ps); + hook_enter(g); + profile_unlock(ps); + } else { + hook_enter(g); + } +} + +void LJ_FASTCALL lj_profile_hook_leave(global_State *g) +{ + ProfileState *ps = &profile_state; + if (ps->g) { + profile_lock(ps); + hook_leave(g); + profile_unlock(ps); + } else { + hook_leave(g); + } +} +#endif + +/* -- Profile callbacks --------------------------------------------------- */ + +/* Callback from profile hook (HOOK_PROFILE already cleared). */ +void LJ_FASTCALL lj_profile_interpreter(lua_State *L) +{ + ProfileState *ps = &profile_state; + global_State *g = G(L); + uint8_t mask; + profile_lock(ps); + mask = (g->hookmask & ~HOOK_PROFILE); + if (!(mask & HOOK_VMEVENT)) { + int samples = ps->samples; + ps->samples = 0; + g->hookmask = HOOK_VMEVENT; + lj_dispatch_update(g); + profile_unlock(ps); + ps->cb(ps->data, L, samples, ps->vmstate); /* Invoke user callback. */ + profile_lock(ps); + mask |= (g->hookmask & HOOK_PROFILE); + } + g->hookmask = mask; + lj_dispatch_update(g); + profile_unlock(ps); +} + +/* Trigger profile hook. Asynchronous call from OS-specific profile timer. */ +static void profile_trigger(ProfileState *ps) +{ + global_State *g = ps->g; + uint8_t mask; + profile_lock(ps); + ps->samples++; /* Always increment number of samples. */ + mask = g->hookmask; + if (!(mask & (HOOK_PROFILE|HOOK_VMEVENT|HOOK_GC))) { /* Set profile hook. */ + int st = g->vmstate; + ps->vmstate = st >= 0 ? 'N' : + st == ~LJ_VMST_INTERP ? 'I' : + st == ~LJ_VMST_C ? 'C' : + st == ~LJ_VMST_GC ? 'G' : 'J'; + g->hookmask = (mask | HOOK_PROFILE); + lj_dispatch_update(g); + } + profile_unlock(ps); +} + +/* -- OS-specific profile timer handling ---------------------------------- */ + +#if LJ_PROFILE_SIGPROF + +/* SIGPROF handler. */ +static void profile_signal(int sig) +{ + UNUSED(sig); + profile_trigger(&profile_state); +} + +/* Start profiling timer. */ +static void profile_timer_start(ProfileState *ps) +{ + int interval = ps->interval; + struct itimerval tm; + struct sigaction sa; + tm.it_value.tv_sec = tm.it_interval.tv_sec = interval / 1000; + tm.it_value.tv_usec = tm.it_interval.tv_usec = (interval % 1000) * 1000; + setitimer(ITIMER_PROF, &tm, NULL); + sa.sa_flags = SA_RESTART; + sa.sa_handler = profile_signal; + sigemptyset(&sa.sa_mask); + sigaction(SIGPROF, &sa, &ps->oldsa); +} + +/* Stop profiling timer. */ +static void profile_timer_stop(ProfileState *ps) +{ + struct itimerval tm; + tm.it_value.tv_sec = tm.it_interval.tv_sec = 0; + tm.it_value.tv_usec = tm.it_interval.tv_usec = 0; + setitimer(ITIMER_PROF, &tm, NULL); + sigaction(SIGPROF, &ps->oldsa, NULL); +} + +#elif LJ_PROFILE_PTHREAD + +/* POSIX timer thread. */ +static void *profile_thread(ProfileState *ps) +{ + int interval = ps->interval; +#if !LJ_TARGET_PS3 + struct timespec ts; + ts.tv_sec = interval / 1000; + ts.tv_nsec = (interval % 1000) * 1000000; +#endif + while (1) { +#if LJ_TARGET_PS3 + sys_timer_usleep(interval * 1000); +#else + nanosleep(&ts, NULL); +#endif + if (ps->abort) break; + profile_trigger(ps); + } + return NULL; +} + +/* Start profiling timer thread. */ +static void profile_timer_start(ProfileState *ps) +{ + pthread_mutex_init(&ps->lock, 0); + ps->abort = 0; + pthread_create(&ps->thread, NULL, (void *(*)(void *))profile_thread, ps); +} + +/* Stop profiling timer thread. */ +static void profile_timer_stop(ProfileState *ps) +{ + ps->abort = 1; + pthread_join(ps->thread, NULL); + pthread_mutex_destroy(&ps->lock); +} + +#elif LJ_PROFILE_WTHREAD + +/* Windows timer thread. */ +static DWORD WINAPI profile_thread(void *psx) +{ + ProfileState *ps = (ProfileState *)psx; + int interval = ps->interval; +#if LJ_TARGET_WINDOWS && !LJ_TARGET_UWP + ps->wmm_tbp(interval); +#endif + while (1) { + Sleep(interval); + if (ps->abort) break; + profile_trigger(ps); + } +#if LJ_TARGET_WINDOWS && !LJ_TARGET_UWP + ps->wmm_tep(interval); +#endif + return 0; +} + +/* Start profiling timer thread. */ +static void profile_timer_start(ProfileState *ps) +{ +#if LJ_TARGET_WINDOWS && !LJ_TARGET_UWP + if (!ps->wmm) { /* Load WinMM library on-demand. */ + ps->wmm = LJ_WIN_LOADLIBA("winmm.dll"); + if (ps->wmm) { + ps->wmm_tbp = (WMM_TPFUNC)GetProcAddress(ps->wmm, "timeBeginPeriod"); + ps->wmm_tep = (WMM_TPFUNC)GetProcAddress(ps->wmm, "timeEndPeriod"); + if (!ps->wmm_tbp || !ps->wmm_tep) { + ps->wmm = NULL; + return; + } + } + } +#endif + InitializeCriticalSection(&ps->lock); + ps->abort = 0; + ps->thread = CreateThread(NULL, 0, profile_thread, ps, 0, NULL); +} + +/* Stop profiling timer thread. */ +static void profile_timer_stop(ProfileState *ps) +{ + ps->abort = 1; + WaitForSingleObject(ps->thread, INFINITE); + DeleteCriticalSection(&ps->lock); +} + +#endif + +/* -- Public profiling API ------------------------------------------------ */ + +/* Start profiling. */ +LUA_API void luaJIT_profile_start(lua_State *L, const char *mode, + luaJIT_profile_callback cb, void *data) +{ + ProfileState *ps = &profile_state; + int interval = LJ_PROFILE_INTERVAL_DEFAULT; + while (*mode) { + int m = *mode++; + switch (m) { + case 'i': + interval = 0; + while (*mode >= '0' && *mode <= '9') + interval = interval * 10 + (*mode++ - '0'); + if (interval <= 0) interval = 1; + break; +#if LJ_HASJIT + case 'l': case 'f': + L2J(L)->prof_mode = m; + lj_trace_flushall(L); + break; +#endif + default: /* Ignore unknown mode chars. */ + break; + } + } + if (ps->g) { + luaJIT_profile_stop(L); + if (ps->g) return; /* Profiler in use by another VM. */ + } + ps->g = G(L); + ps->interval = interval; + ps->cb = cb; + ps->data = data; + ps->samples = 0; + lj_buf_init(L, &ps->sb); + profile_timer_start(ps); +} + +/* Stop profiling. */ +LUA_API void luaJIT_profile_stop(lua_State *L) +{ + ProfileState *ps = &profile_state; + global_State *g = ps->g; + if (G(L) == g) { /* Only stop profiler if started by this VM. */ + profile_timer_stop(ps); + g->hookmask &= ~HOOK_PROFILE; + lj_dispatch_update(g); +#if LJ_HASJIT + G2J(g)->prof_mode = 0; + lj_trace_flushall(L); +#endif + lj_buf_free(g, &ps->sb); + ps->sb.w = ps->sb.e = NULL; + ps->g = NULL; + } +} + +/* Return a compact stack dump. */ +LUA_API const char *luaJIT_profile_dumpstack(lua_State *L, const char *fmt, + int depth, size_t *len) +{ + ProfileState *ps = &profile_state; + SBuf *sb = &ps->sb; + setsbufL(sb, L); + lj_buf_reset(sb); + lj_debug_dumpstack(L, sb, fmt, depth); + *len = (size_t)sbuflen(sb); + return sb->b; +} + +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_profile.h b/fluent-bit/lib/luajit-3065c9/src/lj_profile.h new file mode 100644 index 00000000..3969f8e8 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_profile.h @@ -0,0 +1,21 @@ +/* +** Low-overhead profiling. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#ifndef _LJ_PROFILE_H +#define _LJ_PROFILE_H + +#include "lj_obj.h" + +#if LJ_HASPROFILE + +LJ_FUNC void LJ_FASTCALL lj_profile_interpreter(lua_State *L); +#if !LJ_PROFILE_SIGPROF +LJ_FUNC void LJ_FASTCALL lj_profile_hook_enter(global_State *g); +LJ_FUNC void LJ_FASTCALL lj_profile_hook_leave(global_State *g); +#endif + +#endif + +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_record.c b/fluent-bit/lib/luajit-3065c9/src/lj_record.c new file mode 100644 index 00000000..92bdbfc9 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_record.c @@ -0,0 +1,2837 @@ +/* +** Trace recorder (bytecode -> SSA IR). +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#define lj_record_c +#define LUA_CORE + +#include "lj_obj.h" + +#if LJ_HASJIT + +#include "lj_err.h" +#include "lj_str.h" +#include "lj_tab.h" +#include "lj_meta.h" +#include "lj_frame.h" +#if LJ_HASFFI +#include "lj_ctype.h" +#endif +#include "lj_bc.h" +#include "lj_ff.h" +#if LJ_HASPROFILE +#include "lj_debug.h" +#endif +#include "lj_ir.h" +#include "lj_jit.h" +#include "lj_ircall.h" +#include "lj_iropt.h" +#include "lj_trace.h" +#include "lj_record.h" +#include "lj_ffrecord.h" +#include "lj_snap.h" +#include "lj_dispatch.h" +#include "lj_vm.h" +#include "lj_prng.h" + +/* Some local macros to save typing. Undef'd at the end. */ +#define IR(ref) (&J->cur.ir[(ref)]) + +/* Pass IR on to next optimization in chain (FOLD). */ +#define emitir(ot, a, b) (lj_ir_set(J, (ot), (a), (b)), lj_opt_fold(J)) + +/* Emit raw IR without passing through optimizations. */ +#define emitir_raw(ot, a, b) (lj_ir_set(J, (ot), (a), (b)), lj_ir_emit(J)) + +/* -- Sanity checks ------------------------------------------------------- */ + +#ifdef LUA_USE_ASSERT +/* Sanity check the whole IR -- sloooow. */ +static void rec_check_ir(jit_State *J) +{ + IRRef i, nins = J->cur.nins, nk = J->cur.nk; + lj_assertJ(nk <= REF_BIAS && nins >= REF_BIAS && nins < 65536, + "inconsistent IR layout"); + for (i = nk; i < nins; i++) { + IRIns *ir = IR(i); + uint32_t mode = lj_ir_mode[ir->o]; + IRRef op1 = ir->op1; + IRRef op2 = ir->op2; + const char *err = NULL; + switch (irm_op1(mode)) { + case IRMnone: + if (op1 != 0) err = "IRMnone op1 used"; + break; + case IRMref: + if (op1 < nk || (i >= REF_BIAS ? op1 >= i : op1 <= i)) + err = "IRMref op1 out of range"; + break; + case IRMlit: break; + case IRMcst: + if (i >= REF_BIAS) { err = "constant in IR range"; break; } + if (irt_is64(ir->t) && ir->o != IR_KNULL) + i++; + continue; + } + switch (irm_op2(mode)) { + case IRMnone: + if (op2) err = "IRMnone op2 used"; + break; + case IRMref: + if (op2 < nk || (i >= REF_BIAS ? op2 >= i : op2 <= i)) + err = "IRMref op2 out of range"; + break; + case IRMlit: break; + case IRMcst: err = "IRMcst op2"; break; + } + if (!err && ir->prev) { + if (ir->prev < nk || (i >= REF_BIAS ? ir->prev >= i : ir->prev <= i)) + err = "chain out of range"; + else if (ir->o != IR_NOP && IR(ir->prev)->o != ir->o) + err = "chain to different op"; + } + lj_assertJ(!err, "bad IR %04d op %d(%04d,%04d): %s", + i-REF_BIAS, + ir->o, + irm_op1(mode) == IRMref ? op1-REF_BIAS : op1, + irm_op2(mode) == IRMref ? op2-REF_BIAS : op2, + err); + } +} + +/* Compare stack slots and frames of the recorder and the VM. */ +static void rec_check_slots(jit_State *J) +{ + BCReg s, nslots = J->baseslot + J->maxslot; + int32_t depth = 0; + cTValue *base = J->L->base - J->baseslot; + lj_assertJ(J->baseslot >= 1+LJ_FR2, "bad baseslot"); + lj_assertJ(J->baseslot == 1+LJ_FR2 || (J->slot[J->baseslot-1] & TREF_FRAME), + "baseslot does not point to frame"); + lj_assertJ(nslots <= LJ_MAX_JSLOTS, "slot overflow"); + for (s = 0; s < nslots; s++) { + TRef tr = J->slot[s]; + if (tr) { + cTValue *tv = &base[s]; + IRRef ref = tref_ref(tr); + IRIns *ir = NULL; /* Silence compiler. */ + if (!LJ_FR2 || ref || !(tr & (TREF_FRAME | TREF_CONT))) { + lj_assertJ(ref >= J->cur.nk && ref < J->cur.nins, + "slot %d ref %04d out of range", s, ref - REF_BIAS); + ir = IR(ref); + lj_assertJ(irt_t(ir->t) == tref_t(tr), "slot %d IR type mismatch", s); + } + if (s == 0) { + lj_assertJ(tref_isfunc(tr), "frame slot 0 is not a function"); +#if LJ_FR2 + } else if (s == 1) { + lj_assertJ((tr & ~TREF_FRAME) == 0, "bad frame slot 1"); +#endif + } else if ((tr & TREF_FRAME)) { + GCfunc *fn = gco2func(frame_gc(tv)); + BCReg delta = (BCReg)(tv - frame_prev(tv)); +#if LJ_FR2 + lj_assertJ(!ref || ir_knum(ir)->u64 == tv->u64, + "frame slot %d PC mismatch", s); + tr = J->slot[s-1]; + ir = IR(tref_ref(tr)); +#endif + lj_assertJ(tref_isfunc(tr), + "frame slot %d is not a function", s-LJ_FR2); + lj_assertJ(!tref_isk(tr) || fn == ir_kfunc(ir), + "frame slot %d function mismatch", s-LJ_FR2); + lj_assertJ(s > delta + LJ_FR2 ? (J->slot[s-delta] & TREF_FRAME) + : (s == delta + LJ_FR2), + "frame slot %d broken chain", s-LJ_FR2); + depth++; + } else if ((tr & TREF_CONT)) { +#if LJ_FR2 + lj_assertJ(!ref || ir_knum(ir)->u64 == tv->u64, + "cont slot %d continuation mismatch", s); +#else + lj_assertJ(ir_kptr(ir) == gcrefp(tv->gcr, void), + "cont slot %d continuation mismatch", s); +#endif + lj_assertJ((J->slot[s+1+LJ_FR2] & TREF_FRAME), + "cont slot %d not followed by frame", s); + depth++; + } else if ((tr & TREF_KEYINDEX)) { + lj_assertJ(tref_isint(tr), "keyindex slot %d bad type %d", + s, tref_type(tr)); + } else { + /* Number repr. may differ, but other types must be the same. */ + lj_assertJ(tvisnumber(tv) ? tref_isnumber(tr) : + itype2irt(tv) == tref_type(tr), + "slot %d type mismatch: stack type %d vs IR type %d", + s, itypemap(tv), tref_type(tr)); + if (tref_isk(tr)) { /* Compare constants. */ + TValue tvk; + lj_ir_kvalue(J->L, &tvk, ir); + lj_assertJ((tvisnum(&tvk) && tvisnan(&tvk)) ? + (tvisnum(tv) && tvisnan(tv)) : + lj_obj_equal(tv, &tvk), + "slot %d const mismatch: stack %016llx vs IR %016llx", + s, tv->u64, tvk.u64); + } + } + } + } + lj_assertJ(J->framedepth == depth, + "frame depth mismatch %d vs %d", J->framedepth, depth); +} +#endif + +/* -- Type handling and specialization ------------------------------------ */ + +/* Note: these functions return tagged references (TRef). */ + +/* Specialize a slot to a specific type. Note: slot can be negative! */ +static TRef sloadt(jit_State *J, int32_t slot, IRType t, int mode) +{ + /* Caller may set IRT_GUARD in t. */ + TRef ref = emitir_raw(IRT(IR_SLOAD, t), (int32_t)J->baseslot+slot, mode); + J->base[slot] = ref; + return ref; +} + +/* Specialize a slot to the runtime type. Note: slot can be negative! */ +static TRef sload(jit_State *J, int32_t slot) +{ + IRType t = itype2irt(&J->L->base[slot]); + TRef ref = emitir_raw(IRTG(IR_SLOAD, t), (int32_t)J->baseslot+slot, + IRSLOAD_TYPECHECK); + if (irtype_ispri(t)) ref = TREF_PRI(t); /* Canonicalize primitive refs. */ + J->base[slot] = ref; + return ref; +} + +/* Get TRef from slot. Load slot and specialize if not done already. */ +#define getslot(J, s) (J->base[(s)] ? J->base[(s)] : sload(J, (int32_t)(s))) + +/* Get TRef for current function. */ +static TRef getcurrf(jit_State *J) +{ + if (J->base[-1-LJ_FR2]) + return J->base[-1-LJ_FR2]; + /* Non-base frame functions ought to be loaded already. */ + lj_assertJ(J->baseslot == 1+LJ_FR2, "bad baseslot"); + return sloadt(J, -1-LJ_FR2, IRT_FUNC, IRSLOAD_READONLY); +} + +/* Compare for raw object equality. +** Returns 0 if the objects are the same. +** Returns 1 if they are different, but the same type. +** Returns 2 for two different types. +** Comparisons between primitives always return 1 -- no caller cares about it. +*/ +int lj_record_objcmp(jit_State *J, TRef a, TRef b, cTValue *av, cTValue *bv) +{ + int diff = !lj_obj_equal(av, bv); + if (!tref_isk2(a, b)) { /* Shortcut, also handles primitives. */ + IRType ta = tref_isinteger(a) ? IRT_INT : tref_type(a); + IRType tb = tref_isinteger(b) ? IRT_INT : tref_type(b); + if (ta != tb) { + /* Widen mixed number/int comparisons to number/number comparison. */ + if (ta == IRT_INT && tb == IRT_NUM) { + a = emitir(IRTN(IR_CONV), a, IRCONV_NUM_INT); + ta = IRT_NUM; + } else if (ta == IRT_NUM && tb == IRT_INT) { + b = emitir(IRTN(IR_CONV), b, IRCONV_NUM_INT); + } else { + return 2; /* Two different types are never equal. */ + } + } + emitir(IRTG(diff ? IR_NE : IR_EQ, ta), a, b); + } + return diff; +} + +/* Constify a value. Returns 0 for non-representable object types. */ +TRef lj_record_constify(jit_State *J, cTValue *o) +{ + if (tvisgcv(o)) + return lj_ir_kgc(J, gcV(o), itype2irt(o)); + else if (tvisint(o)) + return lj_ir_kint(J, intV(o)); + else if (tvisnum(o)) + return lj_ir_knumint(J, numV(o)); + else if (tvisbool(o)) + return TREF_PRI(itype2irt(o)); + else + return 0; /* Can't represent lightuserdata (pointless). */ +} + +/* Emit a VLOAD with the correct type. */ +TRef lj_record_vload(jit_State *J, TRef ref, MSize idx, IRType t) +{ + TRef tr = emitir(IRTG(IR_VLOAD, t), ref, idx); + if (irtype_ispri(t)) tr = TREF_PRI(t); /* Canonicalize primitives. */ + return tr; +} + +/* -- Record loop ops ----------------------------------------------------- */ + +/* Loop event. */ +typedef enum { + LOOPEV_LEAVE, /* Loop is left or not entered. */ + LOOPEV_ENTERLO, /* Loop is entered with a low iteration count left. */ + LOOPEV_ENTER /* Loop is entered. */ +} LoopEvent; + +/* Canonicalize slots: convert integers to numbers. */ +static void canonicalize_slots(jit_State *J) +{ + BCReg s; + if (LJ_DUALNUM) return; + for (s = J->baseslot+J->maxslot-1; s >= 1; s--) { + TRef tr = J->slot[s]; + if (tref_isinteger(tr) && !(tr & TREF_KEYINDEX)) { + IRIns *ir = IR(tref_ref(tr)); + if (!(ir->o == IR_SLOAD && (ir->op2 & (IRSLOAD_READONLY)))) + J->slot[s] = emitir(IRTN(IR_CONV), tr, IRCONV_NUM_INT); + } + } +} + +/* Stop recording. */ +void lj_record_stop(jit_State *J, TraceLink linktype, TraceNo lnk) +{ +#ifdef LUAJIT_ENABLE_TABLE_BUMP + if (J->retryrec) + lj_trace_err(J, LJ_TRERR_RETRY); +#endif + lj_trace_end(J); + J->cur.linktype = (uint8_t)linktype; + J->cur.link = (uint16_t)lnk; + /* Looping back at the same stack level? */ + if (lnk == J->cur.traceno && J->framedepth + J->retdepth == 0) { + if ((J->flags & JIT_F_OPT_LOOP)) /* Shall we try to create a loop? */ + goto nocanon; /* Do not canonicalize or we lose the narrowing. */ + if (J->cur.root) /* Otherwise ensure we always link to the root trace. */ + J->cur.link = J->cur.root; + } + canonicalize_slots(J); +nocanon: + /* Note: all loop ops must set J->pc to the following instruction! */ + lj_snap_add(J); /* Add loop snapshot. */ + J->needsnap = 0; + J->mergesnap = 1; /* In case recording continues. */ +} + +/* Search bytecode backwards for a int/num constant slot initializer. */ +static TRef find_kinit(jit_State *J, const BCIns *endpc, BCReg slot, IRType t) +{ + /* This algorithm is rather simplistic and assumes quite a bit about + ** how the bytecode is generated. It works fine for FORI initializers, + ** but it won't necessarily work in other cases (e.g. iterator arguments). + ** It doesn't do anything fancy, either (like backpropagating MOVs). + */ + const BCIns *pc, *startpc = proto_bc(J->pt); + for (pc = endpc-1; pc > startpc; pc--) { + BCIns ins = *pc; + BCOp op = bc_op(ins); + /* First try to find the last instruction that stores to this slot. */ + if (bcmode_a(op) == BCMbase && bc_a(ins) <= slot) { + return 0; /* Multiple results, e.g. from a CALL or KNIL. */ + } else if (bcmode_a(op) == BCMdst && bc_a(ins) == slot) { + if (op == BC_KSHORT || op == BC_KNUM) { /* Found const. initializer. */ + /* Now try to verify there's no forward jump across it. */ + const BCIns *kpc = pc; + for (; pc > startpc; pc--) + if (bc_op(*pc) == BC_JMP) { + const BCIns *target = pc+bc_j(*pc)+1; + if (target > kpc && target <= endpc) + return 0; /* Conditional assignment. */ + } + if (op == BC_KSHORT) { + int32_t k = (int32_t)(int16_t)bc_d(ins); + return t == IRT_INT ? lj_ir_kint(J, k) : lj_ir_knum(J, (lua_Number)k); + } else { + cTValue *tv = proto_knumtv(J->pt, bc_d(ins)); + if (t == IRT_INT) { + int32_t k = numberVint(tv); + if (tvisint(tv) || numV(tv) == (lua_Number)k) /* -0 is ok here. */ + return lj_ir_kint(J, k); + return 0; /* Type mismatch. */ + } else { + return lj_ir_knum(J, numberVnum(tv)); + } + } + } + return 0; /* Non-constant initializer. */ + } + } + return 0; /* No assignment to this slot found? */ +} + +/* Load and optionally convert a FORI argument from a slot. */ +static TRef fori_load(jit_State *J, BCReg slot, IRType t, int mode) +{ + int conv = (tvisint(&J->L->base[slot]) != (t==IRT_INT)) ? IRSLOAD_CONVERT : 0; + return sloadt(J, (int32_t)slot, + t + (((mode & IRSLOAD_TYPECHECK) || + (conv && t == IRT_INT && !(mode >> 16))) ? + IRT_GUARD : 0), + mode + conv); +} + +/* Peek before FORI to find a const initializer. Otherwise load from slot. */ +static TRef fori_arg(jit_State *J, const BCIns *fori, BCReg slot, + IRType t, int mode) +{ + TRef tr = J->base[slot]; + if (!tr) { + tr = find_kinit(J, fori, slot, t); + if (!tr) + tr = fori_load(J, slot, t, mode); + } + return tr; +} + +/* Return the direction of the FOR loop iterator. +** It's important to exactly reproduce the semantics of the interpreter. +*/ +static int rec_for_direction(cTValue *o) +{ + return (tvisint(o) ? intV(o) : (int32_t)o->u32.hi) >= 0; +} + +/* Simulate the runtime behavior of the FOR loop iterator. */ +static LoopEvent rec_for_iter(IROp *op, cTValue *o, int isforl) +{ + lua_Number stopv = numberVnum(&o[FORL_STOP]); + lua_Number idxv = numberVnum(&o[FORL_IDX]); + lua_Number stepv = numberVnum(&o[FORL_STEP]); + if (isforl) + idxv += stepv; + if (rec_for_direction(&o[FORL_STEP])) { + if (idxv <= stopv) { + *op = IR_LE; + return idxv + 2*stepv > stopv ? LOOPEV_ENTERLO : LOOPEV_ENTER; + } + *op = IR_GT; return LOOPEV_LEAVE; + } else { + if (stopv <= idxv) { + *op = IR_GE; + return idxv + 2*stepv < stopv ? LOOPEV_ENTERLO : LOOPEV_ENTER; + } + *op = IR_LT; return LOOPEV_LEAVE; + } +} + +/* Record checks for FOR loop overflow and step direction. */ +static void rec_for_check(jit_State *J, IRType t, int dir, + TRef stop, TRef step, int init) +{ + if (!tref_isk(step)) { + /* Non-constant step: need a guard for the direction. */ + TRef zero = (t == IRT_INT) ? lj_ir_kint(J, 0) : lj_ir_knum_zero(J); + emitir(IRTG(dir ? IR_GE : IR_LT, t), step, zero); + /* Add hoistable overflow checks for a narrowed FORL index. */ + if (init && t == IRT_INT) { + if (tref_isk(stop)) { + /* Constant stop: optimize check away or to a range check for step. */ + int32_t k = IR(tref_ref(stop))->i; + if (dir) { + if (k > 0) + emitir(IRTGI(IR_LE), step, lj_ir_kint(J, (int32_t)0x7fffffff-k)); + } else { + if (k < 0) + emitir(IRTGI(IR_GE), step, lj_ir_kint(J, (int32_t)0x80000000-k)); + } + } else { + /* Stop+step variable: need full overflow check. */ + TRef tr = emitir(IRTGI(IR_ADDOV), step, stop); + emitir(IRTI(IR_USE), tr, 0); /* ADDOV is weak. Avoid dead result. */ + } + } + } else if (init && t == IRT_INT && !tref_isk(stop)) { + /* Constant step: optimize overflow check to a range check for stop. */ + int32_t k = IR(tref_ref(step))->i; + k = (int32_t)(dir ? 0x7fffffff : 0x80000000) - k; + emitir(IRTGI(dir ? IR_LE : IR_GE), stop, lj_ir_kint(J, k)); + } +} + +/* Record a FORL instruction. */ +static void rec_for_loop(jit_State *J, const BCIns *fori, ScEvEntry *scev, + int init) +{ + BCReg ra = bc_a(*fori); + cTValue *tv = &J->L->base[ra]; + TRef idx = J->base[ra+FORL_IDX]; + IRType t = idx ? tref_type(idx) : + (init || LJ_DUALNUM) ? lj_opt_narrow_forl(J, tv) : IRT_NUM; + int mode = IRSLOAD_INHERIT + + ((!LJ_DUALNUM || tvisint(tv) == (t == IRT_INT)) ? IRSLOAD_READONLY : 0); + TRef stop = fori_arg(J, fori, ra+FORL_STOP, t, mode); + TRef step = fori_arg(J, fori, ra+FORL_STEP, t, mode); + int tc, dir = rec_for_direction(&tv[FORL_STEP]); + lj_assertJ(bc_op(*fori) == BC_FORI || bc_op(*fori) == BC_JFORI, + "bad bytecode %d instead of FORI/JFORI", bc_op(*fori)); + scev->t.irt = t; + scev->dir = dir; + scev->stop = tref_ref(stop); + scev->step = tref_ref(step); + rec_for_check(J, t, dir, stop, step, init); + scev->start = tref_ref(find_kinit(J, fori, ra+FORL_IDX, IRT_INT)); + tc = (LJ_DUALNUM && + !(scev->start && irref_isk(scev->stop) && irref_isk(scev->step) && + tvisint(&tv[FORL_IDX]) == (t == IRT_INT))) ? + IRSLOAD_TYPECHECK : 0; + if (tc) { + J->base[ra+FORL_STOP] = stop; + J->base[ra+FORL_STEP] = step; + } + if (!idx) + idx = fori_load(J, ra+FORL_IDX, t, + IRSLOAD_INHERIT + tc + (J->scev.start << 16)); + if (!init) + J->base[ra+FORL_IDX] = idx = emitir(IRT(IR_ADD, t), idx, step); + J->base[ra+FORL_EXT] = idx; + scev->idx = tref_ref(idx); + setmref(scev->pc, fori); + J->maxslot = ra+FORL_EXT+1; +} + +/* Record FORL/JFORL or FORI/JFORI. */ +static LoopEvent rec_for(jit_State *J, const BCIns *fori, int isforl) +{ + BCReg ra = bc_a(*fori); + TValue *tv = &J->L->base[ra]; + TRef *tr = &J->base[ra]; + IROp op; + LoopEvent ev; + TRef stop; + IRType t; + if (isforl) { /* Handle FORL/JFORL opcodes. */ + TRef idx = tr[FORL_IDX]; + if (mref(J->scev.pc, const BCIns) == fori && tref_ref(idx) == J->scev.idx) { + t = J->scev.t.irt; + stop = J->scev.stop; + idx = emitir(IRT(IR_ADD, t), idx, J->scev.step); + tr[FORL_EXT] = tr[FORL_IDX] = idx; + } else { + ScEvEntry scev; + rec_for_loop(J, fori, &scev, 0); + t = scev.t.irt; + stop = scev.stop; + } + } else { /* Handle FORI/JFORI opcodes. */ + BCReg i; + lj_meta_for(J->L, tv); + t = (LJ_DUALNUM || tref_isint(tr[FORL_IDX])) ? lj_opt_narrow_forl(J, tv) : + IRT_NUM; + for (i = FORL_IDX; i <= FORL_STEP; i++) { + if (!tr[i]) sload(J, ra+i); + lj_assertJ(tref_isnumber_str(tr[i]), "bad FORI argument type"); + if (tref_isstr(tr[i])) + tr[i] = emitir(IRTG(IR_STRTO, IRT_NUM), tr[i], 0); + if (t == IRT_INT) { + if (!tref_isinteger(tr[i])) + tr[i] = emitir(IRTGI(IR_CONV), tr[i], IRCONV_INT_NUM|IRCONV_CHECK); + } else { + if (!tref_isnum(tr[i])) + tr[i] = emitir(IRTN(IR_CONV), tr[i], IRCONV_NUM_INT); + } + } + tr[FORL_EXT] = tr[FORL_IDX]; + stop = tr[FORL_STOP]; + rec_for_check(J, t, rec_for_direction(&tv[FORL_STEP]), + stop, tr[FORL_STEP], 1); + } + + ev = rec_for_iter(&op, tv, isforl); + if (ev == LOOPEV_LEAVE) { + J->maxslot = ra+FORL_EXT+1; + J->pc = fori+1; + } else { + J->maxslot = ra; + J->pc = fori+bc_j(*fori)+1; + } + lj_snap_add(J); + + emitir(IRTG(op, t), tr[FORL_IDX], stop); + + if (ev == LOOPEV_LEAVE) { + J->maxslot = ra; + J->pc = fori+bc_j(*fori)+1; + } else { + J->maxslot = ra+FORL_EXT+1; + J->pc = fori+1; + } + J->needsnap = 1; + return ev; +} + +/* Record ITERL/JITERL. */ +static LoopEvent rec_iterl(jit_State *J, const BCIns iterins) +{ + BCReg ra = bc_a(iterins); + if (!tref_isnil(getslot(J, ra))) { /* Looping back? */ + J->base[ra-1] = J->base[ra]; /* Copy result of ITERC to control var. */ + J->maxslot = ra-1+bc_b(J->pc[-1]); + J->pc += bc_j(iterins)+1; + return LOOPEV_ENTER; + } else { + J->maxslot = ra-3; + J->pc++; + return LOOPEV_LEAVE; + } +} + +/* Record LOOP/JLOOP. Now, that was easy. */ +static LoopEvent rec_loop(jit_State *J, BCReg ra, int skip) +{ + if (ra < J->maxslot) J->maxslot = ra; + J->pc += skip; + return LOOPEV_ENTER; +} + +/* Check if a loop repeatedly failed to trace because it didn't loop back. */ +static int innerloopleft(jit_State *J, const BCIns *pc) +{ + ptrdiff_t i; + for (i = 0; i < PENALTY_SLOTS; i++) + if (mref(J->penalty[i].pc, const BCIns) == pc) { + if ((J->penalty[i].reason == LJ_TRERR_LLEAVE || + J->penalty[i].reason == LJ_TRERR_LINNER) && + J->penalty[i].val >= 2*PENALTY_MIN) + return 1; + break; + } + return 0; +} + +/* Handle the case when an interpreted loop op is hit. */ +static void rec_loop_interp(jit_State *J, const BCIns *pc, LoopEvent ev) +{ + if (J->parent == 0 && J->exitno == 0) { + if (pc == J->startpc && J->framedepth + J->retdepth == 0) { + if (bc_op(J->cur.startins) == BC_ITERN) return; /* See rec_itern(). */ + /* Same loop? */ + if (ev == LOOPEV_LEAVE) /* Must loop back to form a root trace. */ + lj_trace_err(J, LJ_TRERR_LLEAVE); + lj_record_stop(J, LJ_TRLINK_LOOP, J->cur.traceno); /* Looping trace. */ + } else if (ev != LOOPEV_LEAVE) { /* Entering inner loop? */ + /* It's usually better to abort here and wait until the inner loop + ** is traced. But if the inner loop repeatedly didn't loop back, + ** this indicates a low trip count. In this case try unrolling + ** an inner loop even in a root trace. But it's better to be a bit + ** more conservative here and only do it for very short loops. + */ + if (bc_j(*pc) != -1 && !innerloopleft(J, pc)) + lj_trace_err(J, LJ_TRERR_LINNER); /* Root trace hit an inner loop. */ + if ((ev != LOOPEV_ENTERLO && + J->loopref && J->cur.nins - J->loopref > 24) || --J->loopunroll < 0) + lj_trace_err(J, LJ_TRERR_LUNROLL); /* Limit loop unrolling. */ + J->loopref = J->cur.nins; + } + } else if (ev != LOOPEV_LEAVE) { /* Side trace enters an inner loop. */ + J->loopref = J->cur.nins; + if (--J->loopunroll < 0) + lj_trace_err(J, LJ_TRERR_LUNROLL); /* Limit loop unrolling. */ + } /* Side trace continues across a loop that's left or not entered. */ +} + +/* Handle the case when an already compiled loop op is hit. */ +static void rec_loop_jit(jit_State *J, TraceNo lnk, LoopEvent ev) +{ + if (J->parent == 0 && J->exitno == 0) { /* Root trace hit an inner loop. */ + /* Better let the inner loop spawn a side trace back here. */ + lj_trace_err(J, LJ_TRERR_LINNER); + } else if (ev != LOOPEV_LEAVE) { /* Side trace enters a compiled loop. */ + J->instunroll = 0; /* Cannot continue across a compiled loop op. */ + if (J->pc == J->startpc && J->framedepth + J->retdepth == 0) + lj_record_stop(J, LJ_TRLINK_LOOP, J->cur.traceno); /* Form extra loop. */ + else + lj_record_stop(J, LJ_TRLINK_ROOT, lnk); /* Link to the loop. */ + } /* Side trace continues across a loop that's left or not entered. */ +} + +/* Record ITERN. */ +static LoopEvent rec_itern(jit_State *J, BCReg ra, BCReg rb) +{ +#if LJ_BE + /* YAGNI: Disabled on big-endian due to issues with lj_vm_next, + ** IR_HIOP, RID_RETLO/RID_RETHI and ra_destpair. + */ + UNUSED(ra); UNUSED(rb); + setintV(&J->errinfo, (int32_t)BC_ITERN); + lj_trace_err_info(J, LJ_TRERR_NYIBC); +#else + RecordIndex ix; + /* Since ITERN is recorded at the start, we need our own loop detection. */ + if (J->pc == J->startpc && + J->framedepth + J->retdepth == 0 && J->parent == 0 && J->exitno == 0) { + IRRef ref = REF_FIRST + LJ_HASPROFILE; +#ifdef LUAJIT_ENABLE_CHECKHOOK + ref += 3; +#endif + if (J->cur.nins > ref || + (LJ_HASPROFILE && J->cur.nins == ref && J->cur.ir[ref-1].o != IR_PROF)) { + J->instunroll = 0; /* Cannot continue unrolling across an ITERN. */ + lj_record_stop(J, LJ_TRLINK_LOOP, J->cur.traceno); /* Looping trace. */ + return LOOPEV_ENTER; + } + } + J->maxslot = ra; + lj_snap_add(J); /* Required to make JLOOP the first ins in a side-trace. */ + ix.tab = getslot(J, ra-2); + ix.key = J->base[ra-1] ? J->base[ra-1] : + sloadt(J, (int32_t)(ra-1), IRT_GUARD|IRT_INT, + IRSLOAD_TYPECHECK|IRSLOAD_KEYINDEX); + copyTV(J->L, &ix.tabv, &J->L->base[ra-2]); + copyTV(J->L, &ix.keyv, &J->L->base[ra-1]); + ix.idxchain = (rb < 3); /* Omit value type check, if unused. */ + ix.mobj = 1; /* We need the next index, too. */ + J->maxslot = ra + lj_record_next(J, &ix); + J->needsnap = 1; + if (!tref_isnil(ix.key)) { /* Looping back? */ + J->base[ra-1] = ix.mobj | TREF_KEYINDEX; /* Control var has next index. */ + J->base[ra] = ix.key; + J->base[ra+1] = ix.val; + J->pc += bc_j(J->pc[1])+2; + return LOOPEV_ENTER; + } else { + J->maxslot = ra-3; + J->pc += 2; + return LOOPEV_LEAVE; + } +#endif +} + +/* Record ISNEXT. */ +static void rec_isnext(jit_State *J, BCReg ra) +{ + cTValue *b = &J->L->base[ra-3]; + if (tvisfunc(b) && funcV(b)->c.ffid == FF_next && + tvistab(b+1) && tvisnil(b+2)) { + /* These checks are folded away for a compiled pairs(). */ + TRef func = getslot(J, ra-3); + TRef trid = emitir(IRT(IR_FLOAD, IRT_U8), func, IRFL_FUNC_FFID); + emitir(IRTGI(IR_EQ), trid, lj_ir_kint(J, FF_next)); + (void)getslot(J, ra-2); /* Type check for table. */ + (void)getslot(J, ra-1); /* Type check for nil key. */ + J->base[ra-1] = lj_ir_kint(J, 0) | TREF_KEYINDEX; + J->maxslot = ra; + } else { /* Abort trace. Interpreter will despecialize bytecode. */ + lj_trace_err(J, LJ_TRERR_RECERR); + } +} + +/* -- Record profiler hook checks ----------------------------------------- */ + +#if LJ_HASPROFILE + +/* Need to insert profiler hook check? */ +static int rec_profile_need(jit_State *J, GCproto *pt, const BCIns *pc) +{ + GCproto *ppt; + lj_assertJ(J->prof_mode == 'f' || J->prof_mode == 'l', + "bad profiler mode %c", J->prof_mode); + if (!pt) + return 0; + ppt = J->prev_pt; + J->prev_pt = pt; + if (pt != ppt && ppt) { + J->prev_line = -1; + return 1; + } + if (J->prof_mode == 'l') { + BCLine line = lj_debug_line(pt, proto_bcpos(pt, pc)); + BCLine pline = J->prev_line; + J->prev_line = line; + if (pline != line) + return 1; + } + return 0; +} + +static void rec_profile_ins(jit_State *J, const BCIns *pc) +{ + if (J->prof_mode && rec_profile_need(J, J->pt, pc)) { + emitir(IRTG(IR_PROF, IRT_NIL), 0, 0); + lj_snap_add(J); + } +} + +static void rec_profile_ret(jit_State *J) +{ + if (J->prof_mode == 'f') { + emitir(IRTG(IR_PROF, IRT_NIL), 0, 0); + J->prev_pt = NULL; + lj_snap_add(J); + } +} + +#endif + +/* -- Record calls and returns -------------------------------------------- */ + +/* Specialize to the runtime value of the called function or its prototype. */ +static TRef rec_call_specialize(jit_State *J, GCfunc *fn, TRef tr) +{ + TRef kfunc; + if (isluafunc(fn)) { + GCproto *pt = funcproto(fn); + /* Too many closures created? Probably not a monomorphic function. */ + if (pt->flags >= PROTO_CLC_POLY) { /* Specialize to prototype instead. */ + TRef trpt = emitir(IRT(IR_FLOAD, IRT_PGC), tr, IRFL_FUNC_PC); + emitir(IRTG(IR_EQ, IRT_PGC), trpt, lj_ir_kptr(J, proto_bc(pt))); + (void)lj_ir_kgc(J, obj2gco(pt), IRT_PROTO); /* Prevent GC of proto. */ + return tr; + } + } else { + /* Don't specialize to non-monomorphic builtins. */ + switch (fn->c.ffid) { + case FF_coroutine_wrap_aux: + case FF_string_gmatch_aux: + /* NYI: io_file_iter doesn't have an ffid, yet. */ + { /* Specialize to the ffid. */ + TRef trid = emitir(IRT(IR_FLOAD, IRT_U8), tr, IRFL_FUNC_FFID); + emitir(IRTGI(IR_EQ), trid, lj_ir_kint(J, fn->c.ffid)); + } + return tr; + default: + /* NYI: don't specialize to non-monomorphic C functions. */ + break; + } + } + /* Otherwise specialize to the function (closure) value itself. */ + kfunc = lj_ir_kfunc(J, fn); + emitir(IRTG(IR_EQ, IRT_FUNC), tr, kfunc); + return kfunc; +} + +/* Record call setup. */ +static void rec_call_setup(jit_State *J, BCReg func, ptrdiff_t nargs) +{ + RecordIndex ix; + TValue *functv = &J->L->base[func]; + TRef kfunc, *fbase = &J->base[func]; + ptrdiff_t i; + (void)getslot(J, func); /* Ensure func has a reference. */ + for (i = 1; i <= nargs; i++) + (void)getslot(J, func+LJ_FR2+i); /* Ensure all args have a reference. */ + if (!tref_isfunc(fbase[0])) { /* Resolve __call metamethod. */ + ix.tab = fbase[0]; + copyTV(J->L, &ix.tabv, functv); + if (!lj_record_mm_lookup(J, &ix, MM_call) || !tref_isfunc(ix.mobj)) + lj_trace_err(J, LJ_TRERR_NOMM); + for (i = ++nargs; i > LJ_FR2; i--) /* Shift arguments up. */ + fbase[i+LJ_FR2] = fbase[i+LJ_FR2-1]; +#if LJ_FR2 + fbase[2] = fbase[0]; +#endif + fbase[0] = ix.mobj; /* Replace function. */ + functv = &ix.mobjv; + } + kfunc = rec_call_specialize(J, funcV(functv), fbase[0]); +#if LJ_FR2 + fbase[0] = kfunc; + fbase[1] = TREF_FRAME; +#else + fbase[0] = kfunc | TREF_FRAME; +#endif + J->maxslot = (BCReg)nargs; +} + +/* Record call. */ +void lj_record_call(jit_State *J, BCReg func, ptrdiff_t nargs) +{ + rec_call_setup(J, func, nargs); + /* Bump frame. */ + J->framedepth++; + J->base += func+1+LJ_FR2; + J->baseslot += func+1+LJ_FR2; + if (J->baseslot + J->maxslot >= LJ_MAX_JSLOTS) + lj_trace_err(J, LJ_TRERR_STACKOV); +} + +/* Record tail call. */ +void lj_record_tailcall(jit_State *J, BCReg func, ptrdiff_t nargs) +{ + rec_call_setup(J, func, nargs); + if (frame_isvarg(J->L->base - 1)) { + BCReg cbase = (BCReg)frame_delta(J->L->base - 1); + if (--J->framedepth < 0) + lj_trace_err(J, LJ_TRERR_NYIRETL); + J->baseslot -= (BCReg)cbase; + J->base -= cbase; + func += cbase; + } + /* Move func + args down. */ + if (LJ_FR2 && J->baseslot == 2) + J->base[func+1] = TREF_FRAME; + memmove(&J->base[-1-LJ_FR2], &J->base[func], sizeof(TRef)*(J->maxslot+1+LJ_FR2)); + /* Note: the new TREF_FRAME is now at J->base[-1] (even for slot #0). */ + /* Tailcalls can form a loop, so count towards the loop unroll limit. */ + if (++J->tailcalled > J->loopunroll) + lj_trace_err(J, LJ_TRERR_LUNROLL); +} + +/* Check unroll limits for down-recursion. */ +static int check_downrec_unroll(jit_State *J, GCproto *pt) +{ + IRRef ptref; + for (ptref = J->chain[IR_KGC]; ptref; ptref = IR(ptref)->prev) + if (ir_kgc(IR(ptref)) == obj2gco(pt)) { + int count = 0; + IRRef ref; + for (ref = J->chain[IR_RETF]; ref; ref = IR(ref)->prev) + if (IR(ref)->op1 == ptref) + count++; + if (count) { + if (J->pc == J->startpc) { + if (count + J->tailcalled > J->param[JIT_P_recunroll]) + return 1; + } else { + lj_trace_err(J, LJ_TRERR_DOWNREC); + } + } + } + return 0; +} + +static TRef rec_cat(jit_State *J, BCReg baseslot, BCReg topslot); + +/* Record return. */ +void lj_record_ret(jit_State *J, BCReg rbase, ptrdiff_t gotresults) +{ + TValue *frame = J->L->base - 1; + ptrdiff_t i; + for (i = 0; i < gotresults; i++) + (void)getslot(J, rbase+i); /* Ensure all results have a reference. */ + while (frame_ispcall(frame)) { /* Immediately resolve pcall() returns. */ + BCReg cbase = (BCReg)frame_delta(frame); + if (--J->framedepth <= 0) + lj_trace_err(J, LJ_TRERR_NYIRETL); + lj_assertJ(J->baseslot > 1+LJ_FR2, "bad baseslot for return"); + gotresults++; + rbase += cbase; + J->baseslot -= (BCReg)cbase; + J->base -= cbase; + J->base[--rbase] = TREF_TRUE; /* Prepend true to results. */ + frame = frame_prevd(frame); + J->needsnap = 1; /* Stop catching on-trace errors. */ + } + /* Return to lower frame via interpreter for unhandled cases. */ + if (J->framedepth == 0 && J->pt && bc_isret(bc_op(*J->pc)) && + (!frame_islua(frame) || + (J->parent == 0 && J->exitno == 0 && + !bc_isret(bc_op(J->cur.startins))))) { + /* NYI: specialize to frame type and return directly, not via RET*. */ + for (i = 0; i < (ptrdiff_t)rbase; i++) + J->base[i] = 0; /* Purge dead slots. */ + J->maxslot = rbase + (BCReg)gotresults; + lj_record_stop(J, LJ_TRLINK_RETURN, 0); /* Return to interpreter. */ + return; + } + if (frame_isvarg(frame)) { + BCReg cbase = (BCReg)frame_delta(frame); + if (--J->framedepth < 0) /* NYI: return of vararg func to lower frame. */ + lj_trace_err(J, LJ_TRERR_NYIRETL); + lj_assertJ(J->baseslot > 1+LJ_FR2, "bad baseslot for return"); + rbase += cbase; + J->baseslot -= (BCReg)cbase; + J->base -= cbase; + frame = frame_prevd(frame); + } + if (frame_islua(frame)) { /* Return to Lua frame. */ + BCIns callins = *(frame_pc(frame)-1); + ptrdiff_t nresults = bc_b(callins) ? (ptrdiff_t)bc_b(callins)-1 :gotresults; + BCReg cbase = bc_a(callins); + GCproto *pt = funcproto(frame_func(frame - (cbase+1+LJ_FR2))); + if ((pt->flags & PROTO_NOJIT)) + lj_trace_err(J, LJ_TRERR_CJITOFF); + if (J->framedepth == 0 && J->pt && frame == J->L->base - 1) { + if (check_downrec_unroll(J, pt)) { + J->maxslot = (BCReg)(rbase + gotresults); + lj_snap_purge(J); + lj_record_stop(J, LJ_TRLINK_DOWNREC, J->cur.traceno); /* Down-rec. */ + return; + } + lj_snap_add(J); + } + for (i = 0; i < nresults; i++) /* Adjust results. */ + J->base[i-1-LJ_FR2] = i < gotresults ? J->base[rbase+i] : TREF_NIL; + J->maxslot = cbase+(BCReg)nresults; + if (J->framedepth > 0) { /* Return to a frame that is part of the trace. */ + J->framedepth--; + lj_assertJ(J->baseslot > cbase+1+LJ_FR2, "bad baseslot for return"); + J->baseslot -= cbase+1+LJ_FR2; + J->base -= cbase+1+LJ_FR2; + } else if (J->parent == 0 && J->exitno == 0 && + !bc_isret(bc_op(J->cur.startins))) { + /* Return to lower frame would leave the loop in a root trace. */ + lj_trace_err(J, LJ_TRERR_LLEAVE); + } else if (J->needsnap) { /* Tailcalled to ff with side-effects. */ + lj_trace_err(J, LJ_TRERR_NYIRETL); /* No way to insert snapshot here. */ + } else { /* Return to lower frame. Guard for the target we return to. */ + TRef trpt = lj_ir_kgc(J, obj2gco(pt), IRT_PROTO); + TRef trpc = lj_ir_kptr(J, (void *)frame_pc(frame)); + emitir(IRTG(IR_RETF, IRT_PGC), trpt, trpc); + J->retdepth++; + J->needsnap = 1; + lj_assertJ(J->baseslot == 1+LJ_FR2, "bad baseslot for return"); + /* Shift result slots up and clear the slots of the new frame below. */ + memmove(J->base + cbase, J->base-1-LJ_FR2, sizeof(TRef)*nresults); + memset(J->base-1-LJ_FR2, 0, sizeof(TRef)*(cbase+1+LJ_FR2)); + } + } else if (frame_iscont(frame)) { /* Return to continuation frame. */ + ASMFunction cont = frame_contf(frame); + BCReg cbase = (BCReg)frame_delta(frame); + if ((J->framedepth -= 2) < 0) + lj_trace_err(J, LJ_TRERR_NYIRETL); + J->baseslot -= (BCReg)cbase; + J->base -= cbase; + J->maxslot = cbase-(2<base[dst] = gotresults ? J->base[cbase+rbase] : TREF_NIL; + if (dst >= J->maxslot) { + J->maxslot = dst+1; + } + } else if (cont == lj_cont_nop) { + /* Nothing to do here. */ + } else if (cont == lj_cont_cat) { + BCReg bslot = bc_b(*(frame_contpc(frame)-1)); + TRef tr = gotresults ? J->base[cbase+rbase] : TREF_NIL; + if (bslot != J->maxslot) { /* Concatenate the remainder. */ + TValue *b = J->L->base, save; /* Simulate lower frame and result. */ + /* Can't handle MM_concat + CALLT + fast func side-effects. */ + if (J->postproc != LJ_POST_NONE) + lj_trace_err(J, LJ_TRERR_NYIRETL); + J->base[J->maxslot] = tr; + copyTV(J->L, &save, b-(2<L, b-(2<L->base = b - cbase; + tr = rec_cat(J, bslot, cbase-(2<L->base + cbase; /* Undo. */ + J->L->base = b; + copyTV(J->L, b-(2<base[dst] = tr; + if (dst >= J->maxslot) { + J->maxslot = dst+1; + } + } /* Otherwise continue with another __concat call. */ + } else { + /* Result type already specialized. */ + lj_assertJ(cont == lj_cont_condf || cont == lj_cont_condt, + "bad continuation type"); + } + } else { + lj_trace_err(J, LJ_TRERR_NYIRETL); /* NYI: handle return to C frame. */ + } + lj_assertJ(J->baseslot >= 1+LJ_FR2, "bad baseslot for return"); +} + +/* -- Metamethod handling ------------------------------------------------- */ + +/* Prepare to record call to metamethod. */ +static BCReg rec_mm_prep(jit_State *J, ASMFunction cont) +{ + BCReg s, top = cont == lj_cont_cat ? J->maxslot : curr_proto(J->L)->framesize; +#if LJ_FR2 + J->base[top] = lj_ir_k64(J, IR_KNUM, u64ptr(contptr(cont))); + J->base[top+1] = TREF_CONT; +#else + J->base[top] = lj_ir_kptr(J, contptr(cont)) | TREF_CONT; +#endif + J->framedepth++; + for (s = J->maxslot; s < top; s++) + J->base[s] = 0; /* Clear frame gap to avoid resurrecting previous refs. */ + return top+1+LJ_FR2; +} + +/* Record metamethod lookup. */ +int lj_record_mm_lookup(jit_State *J, RecordIndex *ix, MMS mm) +{ + RecordIndex mix; + GCtab *mt; + if (tref_istab(ix->tab)) { + mt = tabref(tabV(&ix->tabv)->metatable); + mix.tab = emitir(IRT(IR_FLOAD, IRT_TAB), ix->tab, IRFL_TAB_META); + } else if (tref_isudata(ix->tab)) { + int udtype = udataV(&ix->tabv)->udtype; + mt = tabref(udataV(&ix->tabv)->metatable); + /* The metatables of special userdata objects are treated as immutable. */ + if (udtype != UDTYPE_USERDATA) { + cTValue *mo; + if (LJ_HASFFI && udtype == UDTYPE_FFI_CLIB) { + /* Specialize to the C library namespace object. */ + emitir(IRTG(IR_EQ, IRT_PGC), ix->tab, lj_ir_kptr(J, udataV(&ix->tabv))); + } else { + /* Specialize to the type of userdata. */ + TRef tr = emitir(IRT(IR_FLOAD, IRT_U8), ix->tab, IRFL_UDATA_UDTYPE); + emitir(IRTGI(IR_EQ), tr, lj_ir_kint(J, udtype)); + } + immutable_mt: + mo = lj_tab_getstr(mt, mmname_str(J2G(J), mm)); + if (!mo || tvisnil(mo)) + return 0; /* No metamethod. */ + /* Treat metamethod or index table as immutable, too. */ + if (!(tvisfunc(mo) || tvistab(mo))) + lj_trace_err(J, LJ_TRERR_BADTYPE); + copyTV(J->L, &ix->mobjv, mo); + ix->mobj = lj_ir_kgc(J, gcV(mo), tvisfunc(mo) ? IRT_FUNC : IRT_TAB); + ix->mtv = mt; + ix->mt = TREF_NIL; /* Dummy value for comparison semantics. */ + return 1; /* Got metamethod or index table. */ + } + mix.tab = emitir(IRT(IR_FLOAD, IRT_TAB), ix->tab, IRFL_UDATA_META); + } else { + /* Specialize to base metatable. Must flush mcode in lua_setmetatable(). */ + mt = tabref(basemt_obj(J2G(J), &ix->tabv)); + if (mt == NULL) { + ix->mt = TREF_NIL; + return 0; /* No metamethod. */ + } + /* The cdata metatable is treated as immutable. */ + if (LJ_HASFFI && tref_iscdata(ix->tab)) goto immutable_mt; + ix->mt = mix.tab = lj_ir_ggfload(J, IRT_TAB, + GG_OFS(g.gcroot[GCROOT_BASEMT+itypemap(&ix->tabv)])); + goto nocheck; + } + ix->mt = mt ? mix.tab : TREF_NIL; + emitir(IRTG(mt ? IR_NE : IR_EQ, IRT_TAB), mix.tab, lj_ir_knull(J, IRT_TAB)); +nocheck: + if (mt) { + GCstr *mmstr = mmname_str(J2G(J), mm); + cTValue *mo = lj_tab_getstr(mt, mmstr); + if (mo && !tvisnil(mo)) + copyTV(J->L, &ix->mobjv, mo); + ix->mtv = mt; + settabV(J->L, &mix.tabv, mt); + setstrV(J->L, &mix.keyv, mmstr); + mix.key = lj_ir_kstr(J, mmstr); + mix.val = 0; + mix.idxchain = 0; + ix->mobj = lj_record_idx(J, &mix); + return !tref_isnil(ix->mobj); /* 1 if metamethod found, 0 if not. */ + } + return 0; /* No metamethod. */ +} + +/* Record call to arithmetic metamethod. */ +static TRef rec_mm_arith(jit_State *J, RecordIndex *ix, MMS mm) +{ + /* Set up metamethod call first to save ix->tab and ix->tabv. */ + BCReg func = rec_mm_prep(J, mm == MM_concat ? lj_cont_cat : lj_cont_ra); + TRef *base = J->base + func; + TValue *basev = J->L->base + func; + base[1+LJ_FR2] = ix->tab; base[2+LJ_FR2] = ix->key; + copyTV(J->L, basev+1+LJ_FR2, &ix->tabv); + copyTV(J->L, basev+2+LJ_FR2, &ix->keyv); + if (!lj_record_mm_lookup(J, ix, mm)) { /* Lookup mm on 1st operand. */ + if (mm != MM_unm) { + ix->tab = ix->key; + copyTV(J->L, &ix->tabv, &ix->keyv); + if (lj_record_mm_lookup(J, ix, mm)) /* Lookup mm on 2nd operand. */ + goto ok; + } + lj_trace_err(J, LJ_TRERR_NOMM); + } +ok: + base[0] = ix->mobj; +#if LJ_FR2 + base[1] = 0; +#endif + copyTV(J->L, basev+0, &ix->mobjv); + lj_record_call(J, func, 2); + return 0; /* No result yet. */ +} + +/* Record call to __len metamethod. */ +static TRef rec_mm_len(jit_State *J, TRef tr, TValue *tv) +{ + RecordIndex ix; + ix.tab = tr; + copyTV(J->L, &ix.tabv, tv); + if (lj_record_mm_lookup(J, &ix, MM_len)) { + BCReg func = rec_mm_prep(J, lj_cont_ra); + TRef *base = J->base + func; + TValue *basev = J->L->base + func; + base[0] = ix.mobj; copyTV(J->L, basev+0, &ix.mobjv); + base += LJ_FR2; + basev += LJ_FR2; + base[1] = tr; copyTV(J->L, basev+1, tv); +#if LJ_52 + base[2] = tr; copyTV(J->L, basev+2, tv); +#else + base[2] = TREF_NIL; setnilV(basev+2); +#endif + lj_record_call(J, func, 2); + } else { + if (LJ_52 && tref_istab(tr)) + return emitir(IRTI(IR_ALEN), tr, TREF_NIL); + lj_trace_err(J, LJ_TRERR_NOMM); + } + return 0; /* No result yet. */ +} + +/* Call a comparison metamethod. */ +static void rec_mm_callcomp(jit_State *J, RecordIndex *ix, int op) +{ + BCReg func = rec_mm_prep(J, (op&1) ? lj_cont_condf : lj_cont_condt); + TRef *base = J->base + func + LJ_FR2; + TValue *tv = J->L->base + func + LJ_FR2; + base[-LJ_FR2] = ix->mobj; base[1] = ix->val; base[2] = ix->key; + copyTV(J->L, tv-LJ_FR2, &ix->mobjv); + copyTV(J->L, tv+1, &ix->valv); + copyTV(J->L, tv+2, &ix->keyv); + lj_record_call(J, func, 2); +} + +/* Record call to equality comparison metamethod (for tab and udata only). */ +static void rec_mm_equal(jit_State *J, RecordIndex *ix, int op) +{ + ix->tab = ix->val; + copyTV(J->L, &ix->tabv, &ix->valv); + if (lj_record_mm_lookup(J, ix, MM_eq)) { /* Lookup mm on 1st operand. */ + cTValue *bv; + TRef mo1 = ix->mobj; + TValue mo1v; + copyTV(J->L, &mo1v, &ix->mobjv); + /* Avoid the 2nd lookup and the objcmp if the metatables are equal. */ + bv = &ix->keyv; + if (tvistab(bv) && tabref(tabV(bv)->metatable) == ix->mtv) { + TRef mt2 = emitir(IRT(IR_FLOAD, IRT_TAB), ix->key, IRFL_TAB_META); + emitir(IRTG(IR_EQ, IRT_TAB), mt2, ix->mt); + } else if (tvisudata(bv) && tabref(udataV(bv)->metatable) == ix->mtv) { + TRef mt2 = emitir(IRT(IR_FLOAD, IRT_TAB), ix->key, IRFL_UDATA_META); + emitir(IRTG(IR_EQ, IRT_TAB), mt2, ix->mt); + } else { /* Lookup metamethod on 2nd operand and compare both. */ + ix->tab = ix->key; + copyTV(J->L, &ix->tabv, bv); + if (!lj_record_mm_lookup(J, ix, MM_eq) || + lj_record_objcmp(J, mo1, ix->mobj, &mo1v, &ix->mobjv)) + return; + } + rec_mm_callcomp(J, ix, op); + } +} + +/* Record call to ordered comparison metamethods (for arbitrary objects). */ +static void rec_mm_comp(jit_State *J, RecordIndex *ix, int op) +{ + ix->tab = ix->val; + copyTV(J->L, &ix->tabv, &ix->valv); + while (1) { + MMS mm = (op & 2) ? MM_le : MM_lt; /* Try __le + __lt or only __lt. */ +#if LJ_52 + if (!lj_record_mm_lookup(J, ix, mm)) { /* Lookup mm on 1st operand. */ + ix->tab = ix->key; + copyTV(J->L, &ix->tabv, &ix->keyv); + if (!lj_record_mm_lookup(J, ix, mm)) /* Lookup mm on 2nd operand. */ + goto nomatch; + } + rec_mm_callcomp(J, ix, op); + return; +#else + if (lj_record_mm_lookup(J, ix, mm)) { /* Lookup mm on 1st operand. */ + cTValue *bv; + TRef mo1 = ix->mobj; + TValue mo1v; + copyTV(J->L, &mo1v, &ix->mobjv); + /* Avoid the 2nd lookup and the objcmp if the metatables are equal. */ + bv = &ix->keyv; + if (tvistab(bv) && tabref(tabV(bv)->metatable) == ix->mtv) { + TRef mt2 = emitir(IRT(IR_FLOAD, IRT_TAB), ix->key, IRFL_TAB_META); + emitir(IRTG(IR_EQ, IRT_TAB), mt2, ix->mt); + } else if (tvisudata(bv) && tabref(udataV(bv)->metatable) == ix->mtv) { + TRef mt2 = emitir(IRT(IR_FLOAD, IRT_TAB), ix->key, IRFL_UDATA_META); + emitir(IRTG(IR_EQ, IRT_TAB), mt2, ix->mt); + } else { /* Lookup metamethod on 2nd operand and compare both. */ + ix->tab = ix->key; + copyTV(J->L, &ix->tabv, bv); + if (!lj_record_mm_lookup(J, ix, mm) || + lj_record_objcmp(J, mo1, ix->mobj, &mo1v, &ix->mobjv)) + goto nomatch; + } + rec_mm_callcomp(J, ix, op); + return; + } +#endif + nomatch: + /* Lookup failed. Retry with __lt and swapped operands. */ + if (!(op & 2)) break; /* Already at __lt. Interpreter will throw. */ + ix->tab = ix->key; ix->key = ix->val; ix->val = ix->tab; + copyTV(J->L, &ix->tabv, &ix->keyv); + copyTV(J->L, &ix->keyv, &ix->valv); + copyTV(J->L, &ix->valv, &ix->tabv); + op ^= 3; + } +} + +#if LJ_HASFFI +/* Setup call to cdata comparison metamethod. */ +static void rec_mm_comp_cdata(jit_State *J, RecordIndex *ix, int op, MMS mm) +{ + lj_snap_add(J); + if (tref_iscdata(ix->val)) { + ix->tab = ix->val; + copyTV(J->L, &ix->tabv, &ix->valv); + } else { + lj_assertJ(tref_iscdata(ix->key), "cdata expected"); + ix->tab = ix->key; + copyTV(J->L, &ix->tabv, &ix->keyv); + } + lj_record_mm_lookup(J, ix, mm); + rec_mm_callcomp(J, ix, op); +} +#endif + +/* -- Indexed access ------------------------------------------------------ */ + +#ifdef LUAJIT_ENABLE_TABLE_BUMP +/* Bump table allocations in bytecode when they grow during recording. */ +static void rec_idx_bump(jit_State *J, RecordIndex *ix) +{ + RBCHashEntry *rbc = &J->rbchash[(ix->tab & (RBCHASH_SLOTS-1))]; + if (tref_ref(ix->tab) == rbc->ref) { + const BCIns *pc = mref(rbc->pc, const BCIns); + GCtab *tb = tabV(&ix->tabv); + uint32_t nhbits; + IRIns *ir; + if (!tvisnil(&ix->keyv)) + (void)lj_tab_set(J->L, tb, &ix->keyv); /* Grow table right now. */ + nhbits = tb->hmask > 0 ? lj_fls(tb->hmask)+1 : 0; + ir = IR(tref_ref(ix->tab)); + if (ir->o == IR_TNEW) { + uint32_t ah = bc_d(*pc); + uint32_t asize = ah & 0x7ff, hbits = ah >> 11; + if (nhbits > hbits) hbits = nhbits; + if (tb->asize > asize) { + asize = tb->asize <= 0x7ff ? tb->asize : 0x7ff; + } + if ((asize | (hbits<<11)) != ah) { /* Has the size changed? */ + /* Patch bytecode, but continue recording (for more patching). */ + setbc_d(pc, (asize | (hbits<<11))); + /* Patching TNEW operands is only safe if the trace is aborted. */ + ir->op1 = asize; ir->op2 = hbits; + J->retryrec = 1; /* Abort the trace at the end of recording. */ + } + } else if (ir->o == IR_TDUP) { + GCtab *tpl = gco2tab(proto_kgc(&gcref(rbc->pt)->pt, ~(ptrdiff_t)bc_d(*pc))); + /* Grow template table, but preserve keys with nil values. */ + if ((tb->asize > tpl->asize && (1u << nhbits)-1 == tpl->hmask) || + (tb->asize == tpl->asize && (1u << nhbits)-1 > tpl->hmask)) { + Node *node = noderef(tpl->node); + uint32_t i, hmask = tpl->hmask, asize; + TValue *array; + for (i = 0; i <= hmask; i++) { + if (!tvisnil(&node[i].key) && tvisnil(&node[i].val)) + settabV(J->L, &node[i].val, tpl); + } + if (!tvisnil(&ix->keyv) && tref_isk(ix->key)) { + TValue *o = lj_tab_set(J->L, tpl, &ix->keyv); + if (tvisnil(o)) settabV(J->L, o, tpl); + } + lj_tab_resize(J->L, tpl, tb->asize, nhbits); + node = noderef(tpl->node); + hmask = tpl->hmask; + for (i = 0; i <= hmask; i++) { + /* This is safe, since template tables only hold immutable values. */ + if (tvistab(&node[i].val)) + setnilV(&node[i].val); + } + /* The shape of the table may have changed. Clean up array part, too. */ + asize = tpl->asize; + array = tvref(tpl->array); + for (i = 0; i < asize; i++) { + if (tvistab(&array[i])) + setnilV(&array[i]); + } + J->retryrec = 1; /* Abort the trace at the end of recording. */ + } + } + } +} +#endif + +/* Record bounds-check. */ +static void rec_idx_abc(jit_State *J, TRef asizeref, TRef ikey, uint32_t asize) +{ + /* Try to emit invariant bounds checks. */ + if ((J->flags & (JIT_F_OPT_LOOP|JIT_F_OPT_ABC)) == + (JIT_F_OPT_LOOP|JIT_F_OPT_ABC)) { + IRRef ref = tref_ref(ikey); + IRIns *ir = IR(ref); + int32_t ofs = 0; + IRRef ofsref = 0; + /* Handle constant offsets. */ + if (ir->o == IR_ADD && irref_isk(ir->op2)) { + ofsref = ir->op2; + ofs = IR(ofsref)->i; + ref = ir->op1; + ir = IR(ref); + } + /* Got scalar evolution analysis results for this reference? */ + if (ref == J->scev.idx) { + int32_t stop; + lj_assertJ(irt_isint(J->scev.t) && ir->o == IR_SLOAD, + "only int SCEV supported"); + stop = numberVint(&(J->L->base - J->baseslot)[ir->op1 + FORL_STOP]); + /* Runtime value for stop of loop is within bounds? */ + if ((uint64_t)stop + ofs < (uint64_t)asize) { + /* Emit invariant bounds check for stop. */ + emitir(IRTG(IR_ABC, IRT_P32), asizeref, ofs == 0 ? J->scev.stop : + emitir(IRTI(IR_ADD), J->scev.stop, ofsref)); + /* Emit invariant bounds check for start, if not const or negative. */ + if (!(J->scev.dir && J->scev.start && + (int64_t)IR(J->scev.start)->i + ofs >= 0)) + emitir(IRTG(IR_ABC, IRT_P32), asizeref, ikey); + return; + } + } + } + emitir(IRTGI(IR_ABC), asizeref, ikey); /* Emit regular bounds check. */ +} + +/* Record indexed key lookup. */ +static TRef rec_idx_key(jit_State *J, RecordIndex *ix, IRRef *rbref, + IRType1 *rbguard) +{ + TRef key; + GCtab *t = tabV(&ix->tabv); + ix->oldv = lj_tab_get(J->L, t, &ix->keyv); /* Lookup previous value. */ + *rbref = 0; + rbguard->irt = 0; + + /* Integer keys are looked up in the array part first. */ + key = ix->key; + if (tref_isnumber(key)) { + int32_t k = numberVint(&ix->keyv); + if (!tvisint(&ix->keyv) && numV(&ix->keyv) != (lua_Number)k) + k = LJ_MAX_ASIZE; + if ((MSize)k < LJ_MAX_ASIZE) { /* Potential array key? */ + TRef ikey = lj_opt_narrow_index(J, key); + TRef asizeref = emitir(IRTI(IR_FLOAD), ix->tab, IRFL_TAB_ASIZE); + if ((MSize)k < t->asize) { /* Currently an array key? */ + TRef arrayref; + rec_idx_abc(J, asizeref, ikey, t->asize); + arrayref = emitir(IRT(IR_FLOAD, IRT_PGC), ix->tab, IRFL_TAB_ARRAY); + return emitir(IRT(IR_AREF, IRT_PGC), arrayref, ikey); + } else { /* Currently not in array (may be an array extension)? */ + emitir(IRTGI(IR_ULE), asizeref, ikey); /* Inv. bounds check. */ + if (k == 0 && tref_isk(key)) + key = lj_ir_knum_zero(J); /* Canonicalize 0 or +-0.0 to +0.0. */ + /* And continue with the hash lookup. */ + } + } else if (!tref_isk(key)) { + /* We can rule out const numbers which failed the integerness test + ** above. But all other numbers are potential array keys. + */ + if (t->asize == 0) { /* True sparse tables have an empty array part. */ + /* Guard that the array part stays empty. */ + TRef tmp = emitir(IRTI(IR_FLOAD), ix->tab, IRFL_TAB_ASIZE); + emitir(IRTGI(IR_EQ), tmp, lj_ir_kint(J, 0)); + } else { + lj_trace_err(J, LJ_TRERR_NYITMIX); + } + } + } + + /* Otherwise the key is located in the hash part. */ + if (t->hmask == 0) { /* Shortcut for empty hash part. */ + /* Guard that the hash part stays empty. */ + TRef tmp = emitir(IRTI(IR_FLOAD), ix->tab, IRFL_TAB_HMASK); + emitir(IRTGI(IR_EQ), tmp, lj_ir_kint(J, 0)); + return lj_ir_kkptr(J, niltvg(J2G(J))); + } + if (tref_isinteger(key)) /* Hash keys are based on numbers, not ints. */ + key = emitir(IRTN(IR_CONV), key, IRCONV_NUM_INT); + if (tref_isk(key)) { + /* Optimize lookup of constant hash keys. */ + GCSize hslot = (GCSize)((char *)ix->oldv-(char *)&noderef(t->node)[0].val); + if (hslot <= t->hmask*(GCSize)sizeof(Node) && + hslot <= 65535*(GCSize)sizeof(Node)) { + TRef node, kslot, hm; + *rbref = J->cur.nins; /* Mark possible rollback point. */ + *rbguard = J->guardemit; + hm = emitir(IRTI(IR_FLOAD), ix->tab, IRFL_TAB_HMASK); + emitir(IRTGI(IR_EQ), hm, lj_ir_kint(J, (int32_t)t->hmask)); + node = emitir(IRT(IR_FLOAD, IRT_PGC), ix->tab, IRFL_TAB_NODE); + kslot = lj_ir_kslot(J, key, (IRRef)(hslot / sizeof(Node))); + return emitir(IRTG(IR_HREFK, IRT_PGC), node, kslot); + } + } + /* Fall back to a regular hash lookup. */ + return emitir(IRT(IR_HREF, IRT_PGC), ix->tab, key); +} + +/* Determine whether a key is NOT one of the fast metamethod names. */ +static int nommstr(jit_State *J, TRef key) +{ + if (tref_isstr(key)) { + if (tref_isk(key)) { + GCstr *str = ir_kstr(IR(tref_ref(key))); + uint32_t mm; + for (mm = 0; mm <= MM_FAST; mm++) + if (mmname_str(J2G(J), mm) == str) + return 0; /* MUST be one the fast metamethod names. */ + } else { + return 0; /* Variable string key MAY be a metamethod name. */ + } + } + return 1; /* CANNOT be a metamethod name. */ +} + +/* Record indexed load/store. */ +TRef lj_record_idx(jit_State *J, RecordIndex *ix) +{ + TRef xref; + IROp xrefop, loadop; + IRRef rbref; + IRType1 rbguard; + cTValue *oldv; + + while (!tref_istab(ix->tab)) { /* Handle non-table lookup. */ + /* Never call raw lj_record_idx() on non-table. */ + lj_assertJ(ix->idxchain != 0, "bad usage"); + if (!lj_record_mm_lookup(J, ix, ix->val ? MM_newindex : MM_index)) + lj_trace_err(J, LJ_TRERR_NOMM); + handlemm: + if (tref_isfunc(ix->mobj)) { /* Handle metamethod call. */ + BCReg func = rec_mm_prep(J, ix->val ? lj_cont_nop : lj_cont_ra); + TRef *base = J->base + func + LJ_FR2; + TValue *tv = J->L->base + func + LJ_FR2; + base[-LJ_FR2] = ix->mobj; base[1] = ix->tab; base[2] = ix->key; + setfuncV(J->L, tv-LJ_FR2, funcV(&ix->mobjv)); + copyTV(J->L, tv+1, &ix->tabv); + copyTV(J->L, tv+2, &ix->keyv); + if (ix->val) { + base[3] = ix->val; + copyTV(J->L, tv+3, &ix->valv); + lj_record_call(J, func, 3); /* mobj(tab, key, val) */ + return 0; + } else { + lj_record_call(J, func, 2); /* res = mobj(tab, key) */ + return 0; /* No result yet. */ + } + } +#if LJ_HASBUFFER + /* The index table of buffer objects is treated as immutable. */ + if (ix->mt == TREF_NIL && !ix->val && + tref_isudata(ix->tab) && udataV(&ix->tabv)->udtype == UDTYPE_BUFFER && + tref_istab(ix->mobj) && tref_isstr(ix->key) && tref_isk(ix->key)) { + cTValue *val = lj_tab_getstr(tabV(&ix->mobjv), strV(&ix->keyv)); + TRef tr = lj_record_constify(J, val); + if (tr) return tr; /* Specialize to the value, i.e. a method. */ + } +#endif + /* Otherwise retry lookup with metaobject. */ + ix->tab = ix->mobj; + copyTV(J->L, &ix->tabv, &ix->mobjv); + if (--ix->idxchain == 0) + lj_trace_err(J, LJ_TRERR_IDXLOOP); + } + + /* First catch nil and NaN keys for tables. */ + if (tvisnil(&ix->keyv) || (tvisnum(&ix->keyv) && tvisnan(&ix->keyv))) { + if (ix->val) /* Better fail early. */ + lj_trace_err(J, LJ_TRERR_STORENN); + if (tref_isk(ix->key)) { + if (ix->idxchain && lj_record_mm_lookup(J, ix, MM_index)) + goto handlemm; + return TREF_NIL; + } + } + + /* Record the key lookup. */ + xref = rec_idx_key(J, ix, &rbref, &rbguard); + xrefop = IR(tref_ref(xref))->o; + loadop = xrefop == IR_AREF ? IR_ALOAD : IR_HLOAD; + /* The lj_meta_tset() inconsistency is gone, but better play safe. */ + oldv = xrefop == IR_KKPTR ? (cTValue *)ir_kptr(IR(tref_ref(xref))) : ix->oldv; + + if (ix->val == 0) { /* Indexed load */ + IRType t = itype2irt(oldv); + TRef res; + if (oldv == niltvg(J2G(J))) { + emitir(IRTG(IR_EQ, IRT_PGC), xref, lj_ir_kkptr(J, niltvg(J2G(J)))); + res = TREF_NIL; + } else { + res = emitir(IRTG(loadop, t), xref, 0); + } + if (tref_ref(res) < rbref) { /* HREFK + load forwarded? */ + lj_ir_rollback(J, rbref); /* Rollback to eliminate hmask guard. */ + J->guardemit = rbguard; + } + if (t == IRT_NIL && ix->idxchain && lj_record_mm_lookup(J, ix, MM_index)) + goto handlemm; + if (irtype_ispri(t)) res = TREF_PRI(t); /* Canonicalize primitives. */ + return res; + } else { /* Indexed store. */ + GCtab *mt = tabref(tabV(&ix->tabv)->metatable); + int keybarrier = tref_isgcv(ix->key) && !tref_isnil(ix->val); + if (tref_ref(xref) < rbref) { /* HREFK forwarded? */ + lj_ir_rollback(J, rbref); /* Rollback to eliminate hmask guard. */ + J->guardemit = rbguard; + } + if (tvisnil(oldv)) { /* Previous value was nil? */ + /* Need to duplicate the hasmm check for the early guards. */ + int hasmm = 0; + if (ix->idxchain && mt) { + cTValue *mo = lj_tab_getstr(mt, mmname_str(J2G(J), MM_newindex)); + hasmm = mo && !tvisnil(mo); + } + if (hasmm) + emitir(IRTG(loadop, IRT_NIL), xref, 0); /* Guard for nil value. */ + else if (xrefop == IR_HREF) + emitir(IRTG(oldv == niltvg(J2G(J)) ? IR_EQ : IR_NE, IRT_PGC), + xref, lj_ir_kkptr(J, niltvg(J2G(J)))); + if (ix->idxchain && lj_record_mm_lookup(J, ix, MM_newindex)) { + lj_assertJ(hasmm, "inconsistent metamethod handling"); + goto handlemm; + } + lj_assertJ(!hasmm, "inconsistent metamethod handling"); + if (oldv == niltvg(J2G(J))) { /* Need to insert a new key. */ + TRef key = ix->key; + if (tref_isinteger(key)) /* NEWREF needs a TValue as a key. */ + key = emitir(IRTN(IR_CONV), key, IRCONV_NUM_INT); + xref = emitir(IRT(IR_NEWREF, IRT_PGC), ix->tab, key); + keybarrier = 0; /* NEWREF already takes care of the key barrier. */ +#ifdef LUAJIT_ENABLE_TABLE_BUMP + if ((J->flags & JIT_F_OPT_SINK)) /* Avoid a separate flag. */ + rec_idx_bump(J, ix); +#endif + } + } else if (!lj_opt_fwd_wasnonnil(J, loadop, tref_ref(xref))) { + /* Cannot derive that the previous value was non-nil, must do checks. */ + if (xrefop == IR_HREF) /* Guard against store to niltv. */ + emitir(IRTG(IR_NE, IRT_PGC), xref, lj_ir_kkptr(J, niltvg(J2G(J)))); + if (ix->idxchain) { /* Metamethod lookup required? */ + /* A check for NULL metatable is cheaper (hoistable) than a load. */ + if (!mt) { + TRef mtref = emitir(IRT(IR_FLOAD, IRT_TAB), ix->tab, IRFL_TAB_META); + emitir(IRTG(IR_EQ, IRT_TAB), mtref, lj_ir_knull(J, IRT_TAB)); + } else { + IRType t = itype2irt(oldv); + emitir(IRTG(loadop, t), xref, 0); /* Guard for non-nil value. */ + } + } + } else { + keybarrier = 0; /* Previous non-nil value kept the key alive. */ + } + /* Convert int to number before storing. */ + if (!LJ_DUALNUM && tref_isinteger(ix->val)) + ix->val = emitir(IRTN(IR_CONV), ix->val, IRCONV_NUM_INT); + emitir(IRT(loadop+IRDELTA_L2S, tref_type(ix->val)), xref, ix->val); + if (keybarrier || tref_isgcv(ix->val)) + emitir(IRT(IR_TBAR, IRT_NIL), ix->tab, 0); + /* Invalidate neg. metamethod cache for stores with certain string keys. */ + if (!nommstr(J, ix->key)) { + TRef fref = emitir(IRT(IR_FREF, IRT_PGC), ix->tab, IRFL_TAB_NOMM); + emitir(IRT(IR_FSTORE, IRT_U8), fref, lj_ir_kint(J, 0)); + } + J->needsnap = 1; + return 0; + } +} + +/* Determine result type of table traversal. */ +static IRType rec_next_types(GCtab *t, uint32_t idx) +{ + for (; idx < t->asize; idx++) { + cTValue *a = arrayslot(t, idx); + if (LJ_LIKELY(!tvisnil(a))) + return (LJ_DUALNUM ? IRT_INT : IRT_NUM) + (itype2irt(a) << 8); + } + idx -= t->asize; + for (; idx <= t->hmask; idx++) { + Node *n = &noderef(t->node)[idx]; + if (!tvisnil(&n->val)) + return itype2irt(&n->key) + (itype2irt(&n->val) << 8); + } + return IRT_NIL + (IRT_NIL << 8); +} + +/* Record a table traversal step aka next(). */ +int lj_record_next(jit_State *J, RecordIndex *ix) +{ + IRType t, tkey, tval; + TRef trvk; + t = rec_next_types(tabV(&ix->tabv), ix->keyv.u32.lo); + tkey = (t & 0xff); tval = (t >> 8); + trvk = lj_ir_call(J, IRCALL_lj_vm_next, ix->tab, ix->key); + if (ix->mobj || tkey == IRT_NIL) { + TRef idx = emitir(IRTI(IR_HIOP), trvk, trvk); + /* Always check for invalid key from next() for nil result. */ + if (!ix->mobj) emitir(IRTGI(IR_NE), idx, lj_ir_kint(J, -1)); + ix->mobj = idx; + } + ix->key = lj_record_vload(J, trvk, 1, tkey); + if (tkey == IRT_NIL || ix->idxchain) { /* Omit value type check. */ + ix->val = TREF_NIL; + return 1; + } else { /* Need value. */ + ix->val = lj_record_vload(J, trvk, 0, tval); + return 2; + } +} + +static void rec_tsetm(jit_State *J, BCReg ra, BCReg rn, int32_t i) +{ + RecordIndex ix; + cTValue *basev = J->L->base; + GCtab *t = tabV(&basev[ra-1]); + settabV(J->L, &ix.tabv, t); + ix.tab = getslot(J, ra-1); + ix.idxchain = 0; +#ifdef LUAJIT_ENABLE_TABLE_BUMP + if ((J->flags & JIT_F_OPT_SINK)) { + if (t->asize < i+rn-ra) + lj_tab_reasize(J->L, t, i+rn-ra); + setnilV(&ix.keyv); + rec_idx_bump(J, &ix); + } +#endif + for (; ra < rn; i++, ra++) { + setintV(&ix.keyv, i); + ix.key = lj_ir_kint(J, i); + copyTV(J->L, &ix.valv, &basev[ra]); + ix.val = getslot(J, ra); + lj_record_idx(J, &ix); + } +} + +/* -- Upvalue access ------------------------------------------------------ */ + +/* Check whether upvalue is immutable and ok to constify. */ +static int rec_upvalue_constify(jit_State *J, GCupval *uvp) +{ + if (uvp->immutable) { + cTValue *o = uvval(uvp); + /* Don't constify objects that may retain large amounts of memory. */ +#if LJ_HASFFI + if (tviscdata(o)) { + GCcdata *cd = cdataV(o); + if (!cdataisv(cd) && !(cd->marked & LJ_GC_CDATA_FIN)) { + CType *ct = ctype_raw(ctype_ctsG(J2G(J)), cd->ctypeid); + if (!ctype_hassize(ct->info) || ct->size <= 16) + return 1; + } + return 0; + } +#else + UNUSED(J); +#endif + if (!(tvistab(o) || tvisudata(o) || tvisthread(o))) + return 1; + } + return 0; +} + +/* Record upvalue load/store. */ +static TRef rec_upvalue(jit_State *J, uint32_t uv, TRef val) +{ + GCupval *uvp = &gcref(J->fn->l.uvptr[uv])->uv; + TRef fn = getcurrf(J); + IRRef uref; + int needbarrier = 0; + if (rec_upvalue_constify(J, uvp)) { /* Try to constify immutable upvalue. */ + TRef tr, kfunc; + lj_assertJ(val == 0, "bad usage"); + if (!tref_isk(fn)) { /* Late specialization of current function. */ + if (J->pt->flags >= PROTO_CLC_POLY) + goto noconstify; + kfunc = lj_ir_kfunc(J, J->fn); + emitir(IRTG(IR_EQ, IRT_FUNC), fn, kfunc); +#if LJ_FR2 + J->base[-2] = kfunc; +#else + J->base[-1] = kfunc | TREF_FRAME; +#endif + fn = kfunc; + } + tr = lj_record_constify(J, uvval(uvp)); + if (tr) + return tr; + } +noconstify: + /* Note: this effectively limits LJ_MAX_UPVAL to 127. */ + uv = (uv << 8) | (hashrot(uvp->dhash, uvp->dhash + HASH_BIAS) & 0xff); + if (!uvp->closed) { + uref = tref_ref(emitir(IRTG(IR_UREFO, IRT_PGC), fn, uv)); + /* In current stack? */ + if (uvval(uvp) >= tvref(J->L->stack) && + uvval(uvp) < tvref(J->L->maxstack)) { + int32_t slot = (int32_t)(uvval(uvp) - (J->L->base - J->baseslot)); + if (slot >= 0) { /* Aliases an SSA slot? */ + emitir(IRTG(IR_EQ, IRT_PGC), + REF_BASE, + emitir(IRT(IR_ADD, IRT_PGC), uref, + lj_ir_kint(J, (slot - 1 - LJ_FR2) * -8))); + slot -= (int32_t)J->baseslot; /* Note: slot number may be negative! */ + if (val == 0) { + return getslot(J, slot); + } else { + J->base[slot] = val; + if (slot >= (int32_t)J->maxslot) J->maxslot = (BCReg)(slot+1); + return 0; + } + } + } + emitir(IRTG(IR_UGT, IRT_PGC), + emitir(IRT(IR_SUB, IRT_PGC), uref, REF_BASE), + lj_ir_kint(J, (J->baseslot + J->maxslot) * 8)); + } else { + needbarrier = 1; + uref = tref_ref(emitir(IRTG(IR_UREFC, IRT_PGC), fn, uv)); + } + if (val == 0) { /* Upvalue load */ + IRType t = itype2irt(uvval(uvp)); + TRef res = emitir(IRTG(IR_ULOAD, t), uref, 0); + if (irtype_ispri(t)) res = TREF_PRI(t); /* Canonicalize primitive refs. */ + return res; + } else { /* Upvalue store. */ + /* Convert int to number before storing. */ + if (!LJ_DUALNUM && tref_isinteger(val)) + val = emitir(IRTN(IR_CONV), val, IRCONV_NUM_INT); + emitir(IRT(IR_USTORE, tref_type(val)), uref, val); + if (needbarrier && tref_isgcv(val)) + emitir(IRT(IR_OBAR, IRT_NIL), uref, val); + J->needsnap = 1; + return 0; + } +} + +/* -- Record calls to Lua functions --------------------------------------- */ + +/* Check unroll limits for calls. */ +static void check_call_unroll(jit_State *J, TraceNo lnk) +{ + cTValue *frame = J->L->base - 1; + void *pc = mref(frame_func(frame)->l.pc, void); + int32_t depth = J->framedepth; + int32_t count = 0; + if ((J->pt->flags & PROTO_VARARG)) depth--; /* Vararg frame still missing. */ + for (; depth > 0; depth--) { /* Count frames with same prototype. */ + if (frame_iscont(frame)) depth--; + frame = frame_prev(frame); + if (mref(frame_func(frame)->l.pc, void) == pc) + count++; + } + if (J->pc == J->startpc) { + if (count + J->tailcalled > J->param[JIT_P_recunroll]) { + J->pc++; + if (J->framedepth + J->retdepth == 0) + lj_record_stop(J, LJ_TRLINK_TAILREC, J->cur.traceno); /* Tail-rec. */ + else + lj_record_stop(J, LJ_TRLINK_UPREC, J->cur.traceno); /* Up-recursion. */ + } + } else { + if (count > J->param[JIT_P_callunroll]) { + if (lnk) { /* Possible tail- or up-recursion. */ + lj_trace_flush(J, lnk); /* Flush trace that only returns. */ + /* Set a small, pseudo-random hotcount for a quick retry of JFUNC*. */ + hotcount_set(J2GG(J), J->pc+1, lj_prng_u64(&J2G(J)->prng) & 15u); + } + lj_trace_err(J, LJ_TRERR_CUNROLL); + } + } +} + +/* Record Lua function setup. */ +static void rec_func_setup(jit_State *J) +{ + GCproto *pt = J->pt; + BCReg s, numparams = pt->numparams; + if ((pt->flags & PROTO_NOJIT)) + lj_trace_err(J, LJ_TRERR_CJITOFF); + if (J->baseslot + pt->framesize >= LJ_MAX_JSLOTS) + lj_trace_err(J, LJ_TRERR_STACKOV); + /* Fill up missing parameters with nil. */ + for (s = J->maxslot; s < numparams; s++) + J->base[s] = TREF_NIL; + /* The remaining slots should never be read before they are written. */ + J->maxslot = numparams; +} + +/* Record Lua vararg function setup. */ +static void rec_func_vararg(jit_State *J) +{ + GCproto *pt = J->pt; + BCReg s, fixargs, vframe = J->maxslot+1+LJ_FR2; + lj_assertJ((pt->flags & PROTO_VARARG), "FUNCV in non-vararg function"); + if (J->baseslot + vframe + pt->framesize >= LJ_MAX_JSLOTS) + lj_trace_err(J, LJ_TRERR_STACKOV); + J->base[vframe-1-LJ_FR2] = J->base[-1-LJ_FR2]; /* Copy function up. */ +#if LJ_FR2 + J->base[vframe-1] = TREF_FRAME; +#endif + /* Copy fixarg slots up and set their original slots to nil. */ + fixargs = pt->numparams < J->maxslot ? pt->numparams : J->maxslot; + for (s = 0; s < fixargs; s++) { + J->base[vframe+s] = J->base[s]; + J->base[s] = TREF_NIL; + } + J->maxslot = fixargs; + J->framedepth++; + J->base += vframe; + J->baseslot += vframe; +} + +/* Record entry to a Lua function. */ +static void rec_func_lua(jit_State *J) +{ + rec_func_setup(J); + check_call_unroll(J, 0); +} + +/* Record entry to an already compiled function. */ +static void rec_func_jit(jit_State *J, TraceNo lnk) +{ + GCtrace *T; + rec_func_setup(J); + T = traceref(J, lnk); + if (T->linktype == LJ_TRLINK_RETURN) { /* Trace returns to interpreter? */ + check_call_unroll(J, lnk); + /* Temporarily unpatch JFUNC* to continue recording across function. */ + J->patchins = *J->pc; + J->patchpc = (BCIns *)J->pc; + *J->patchpc = T->startins; + return; + } + J->instunroll = 0; /* Cannot continue across a compiled function. */ + if (J->pc == J->startpc && J->framedepth + J->retdepth == 0) + lj_record_stop(J, LJ_TRLINK_TAILREC, J->cur.traceno); /* Extra tail-rec. */ + else + lj_record_stop(J, LJ_TRLINK_ROOT, lnk); /* Link to the function. */ +} + +/* -- Vararg handling ----------------------------------------------------- */ + +/* Detect y = select(x, ...) idiom. */ +static int select_detect(jit_State *J) +{ + BCIns ins = J->pc[1]; + if (bc_op(ins) == BC_CALLM && bc_b(ins) == 2 && bc_c(ins) == 1) { + cTValue *func = &J->L->base[bc_a(ins)]; + if (tvisfunc(func) && funcV(func)->c.ffid == FF_select) { + TRef kfunc = lj_ir_kfunc(J, funcV(func)); + emitir(IRTG(IR_EQ, IRT_FUNC), getslot(J, bc_a(ins)), kfunc); + return 1; + } + } + return 0; +} + +/* Record vararg instruction. */ +static void rec_varg(jit_State *J, BCReg dst, ptrdiff_t nresults) +{ + int32_t numparams = J->pt->numparams; + ptrdiff_t nvararg = frame_delta(J->L->base-1) - numparams - 1 - LJ_FR2; + lj_assertJ(frame_isvarg(J->L->base-1), "VARG in non-vararg frame"); + if (LJ_FR2 && dst > J->maxslot) + J->base[dst-1] = 0; /* Prevent resurrection of unrelated slot. */ + if (J->framedepth > 0) { /* Simple case: varargs defined on-trace. */ + ptrdiff_t i; + if (nvararg < 0) nvararg = 0; + if (nresults == -1) { + nresults = nvararg; + J->maxslot = dst + (BCReg)nvararg; + } else if (dst + nresults > J->maxslot) { + J->maxslot = dst + (BCReg)nresults; + } + for (i = 0; i < nresults; i++) + J->base[dst+i] = i < nvararg ? getslot(J, i - nvararg - 1 - LJ_FR2) : TREF_NIL; + } else { /* Unknown number of varargs passed to trace. */ + TRef fr = emitir(IRTI(IR_SLOAD), LJ_FR2, IRSLOAD_READONLY|IRSLOAD_FRAME); + int32_t frofs = 8*(1+LJ_FR2+numparams)+FRAME_VARG; + if (nresults >= 0) { /* Known fixed number of results. */ + ptrdiff_t i; + if (nvararg > 0) { + ptrdiff_t nload = nvararg >= nresults ? nresults : nvararg; + TRef vbase; + if (nvararg >= nresults) + emitir(IRTGI(IR_GE), fr, lj_ir_kint(J, frofs+8*(int32_t)nresults)); + else + emitir(IRTGI(IR_EQ), fr, + lj_ir_kint(J, (int32_t)frame_ftsz(J->L->base-1))); + vbase = emitir(IRT(IR_SUB, IRT_IGC), REF_BASE, fr); + vbase = emitir(IRT(IR_ADD, IRT_PGC), vbase, lj_ir_kint(J, frofs-8*(1+LJ_FR2))); + for (i = 0; i < nload; i++) { + IRType t = itype2irt(&J->L->base[i-1-LJ_FR2-nvararg]); + J->base[dst+i] = lj_record_vload(J, vbase, i, t); + } + } else { + emitir(IRTGI(IR_LE), fr, lj_ir_kint(J, frofs)); + nvararg = 0; + } + for (i = nvararg; i < nresults; i++) + J->base[dst+i] = TREF_NIL; + if (dst + (BCReg)nresults > J->maxslot) + J->maxslot = dst + (BCReg)nresults; + } else if (select_detect(J)) { /* y = select(x, ...) */ + TRef tridx = J->base[dst-1]; + TRef tr = TREF_NIL; + ptrdiff_t idx = lj_ffrecord_select_mode(J, tridx, &J->L->base[dst-1]); + if (idx < 0) goto nyivarg; + if (idx != 0 && !tref_isinteger(tridx)) + tridx = emitir(IRTGI(IR_CONV), tridx, IRCONV_INT_NUM|IRCONV_INDEX); + if (idx != 0 && tref_isk(tridx)) { + emitir(IRTGI(idx <= nvararg ? IR_GE : IR_LT), + fr, lj_ir_kint(J, frofs+8*(int32_t)idx)); + frofs -= 8; /* Bias for 1-based index. */ + } else if (idx <= nvararg) { /* Compute size. */ + TRef tmp = emitir(IRTI(IR_ADD), fr, lj_ir_kint(J, -frofs)); + if (numparams) + emitir(IRTGI(IR_GE), tmp, lj_ir_kint(J, 0)); + tr = emitir(IRTI(IR_BSHR), tmp, lj_ir_kint(J, 3)); + if (idx != 0) { + tridx = emitir(IRTI(IR_ADD), tridx, lj_ir_kint(J, -1)); + rec_idx_abc(J, tr, tridx, (uint32_t)nvararg); + } + } else { + TRef tmp = lj_ir_kint(J, frofs); + if (idx != 0) { + TRef tmp2 = emitir(IRTI(IR_BSHL), tridx, lj_ir_kint(J, 3)); + tmp = emitir(IRTI(IR_ADD), tmp2, tmp); + } else { + tr = lj_ir_kint(J, 0); + } + emitir(IRTGI(IR_LT), fr, tmp); + } + if (idx != 0 && idx <= nvararg) { + IRType t; + TRef aref, vbase = emitir(IRT(IR_SUB, IRT_IGC), REF_BASE, fr); + vbase = emitir(IRT(IR_ADD, IRT_PGC), vbase, + lj_ir_kint(J, frofs-(8<L->base[idx-2-LJ_FR2-nvararg]); + aref = emitir(IRT(IR_AREF, IRT_PGC), vbase, tridx); + tr = lj_record_vload(J, aref, 0, t); + } + J->base[dst-2-LJ_FR2] = tr; + J->maxslot = dst-1-LJ_FR2; + J->bcskip = 2; /* Skip CALLM + select. */ + } else { + nyivarg: + setintV(&J->errinfo, BC_VARG); + lj_trace_err_info(J, LJ_TRERR_NYIBC); + } + } + if (J->baseslot + J->maxslot >= LJ_MAX_JSLOTS) + lj_trace_err(J, LJ_TRERR_STACKOV); +} + +/* -- Record allocations -------------------------------------------------- */ + +static TRef rec_tnew(jit_State *J, uint32_t ah) +{ + uint32_t asize = ah & 0x7ff; + uint32_t hbits = ah >> 11; + TRef tr; + if (asize == 0x7ff) asize = 0x801; + tr = emitir(IRTG(IR_TNEW, IRT_TAB), asize, hbits); +#ifdef LUAJIT_ENABLE_TABLE_BUMP + J->rbchash[(tr & (RBCHASH_SLOTS-1))].ref = tref_ref(tr); + setmref(J->rbchash[(tr & (RBCHASH_SLOTS-1))].pc, J->pc); + setgcref(J->rbchash[(tr & (RBCHASH_SLOTS-1))].pt, obj2gco(J->pt)); +#endif + return tr; +} + +/* -- Concatenation ------------------------------------------------------- */ + +static TRef rec_cat(jit_State *J, BCReg baseslot, BCReg topslot) +{ + TRef *top = &J->base[topslot]; + TValue savetv[5+LJ_FR2]; + BCReg s; + RecordIndex ix; + lj_assertJ(baseslot < topslot, "bad CAT arg"); + for (s = baseslot; s <= topslot; s++) + (void)getslot(J, s); /* Ensure all arguments have a reference. */ + if (tref_isnumber_str(top[0]) && tref_isnumber_str(top[-1])) { + TRef tr, hdr, *trp, *xbase, *base = &J->base[baseslot]; + /* First convert numbers to strings. */ + for (trp = top; trp >= base; trp--) { + if (tref_isnumber(*trp)) + *trp = emitir(IRT(IR_TOSTR, IRT_STR), *trp, + tref_isnum(*trp) ? IRTOSTR_NUM : IRTOSTR_INT); + else if (!tref_isstr(*trp)) + break; + } + xbase = ++trp; + tr = hdr = emitir(IRT(IR_BUFHDR, IRT_PGC), + lj_ir_kptr(J, &J2G(J)->tmpbuf), IRBUFHDR_RESET); + do { + tr = emitir(IRTG(IR_BUFPUT, IRT_PGC), tr, *trp++); + } while (trp <= top); + tr = emitir(IRTG(IR_BUFSTR, IRT_STR), tr, hdr); + J->maxslot = (BCReg)(xbase - J->base); + if (xbase == base) return tr; /* Return simple concatenation result. */ + /* Pass partial result. */ + topslot = J->maxslot--; + *xbase = tr; + top = xbase; + setstrV(J->L, &ix.keyv, &J2G(J)->strempty); /* Simulate string result. */ + } else { + J->maxslot = topslot-1; + copyTV(J->L, &ix.keyv, &J->L->base[topslot]); + } + copyTV(J->L, &ix.tabv, &J->L->base[topslot-1]); + ix.tab = top[-1]; + ix.key = top[0]; + memcpy(savetv, &J->L->base[topslot-1], sizeof(savetv)); /* Save slots. */ + rec_mm_arith(J, &ix, MM_concat); /* Call __concat metamethod. */ + memcpy(&J->L->base[topslot-1], savetv, sizeof(savetv)); /* Restore slots. */ + return 0; /* No result yet. */ +} + +/* -- Record bytecode ops ------------------------------------------------- */ + +/* Prepare for comparison. */ +static void rec_comp_prep(jit_State *J) +{ + /* Prevent merging with snapshot #0 (GC exit) since we fixup the PC. */ + if (J->cur.nsnap == 1 && J->cur.snap[0].ref == J->cur.nins) + emitir_raw(IRT(IR_NOP, IRT_NIL), 0, 0); + lj_snap_add(J); +} + +/* Fixup comparison. */ +static void rec_comp_fixup(jit_State *J, const BCIns *pc, int cond) +{ + BCIns jmpins = pc[1]; + const BCIns *npc = pc + 2 + (cond ? bc_j(jmpins) : 0); + SnapShot *snap = &J->cur.snap[J->cur.nsnap-1]; + /* Set PC to opposite target to avoid re-recording the comp. in side trace. */ +#if LJ_FR2 + SnapEntry *flink = &J->cur.snapmap[snap->mapofs + snap->nent]; + uint64_t pcbase; + memcpy(&pcbase, flink, sizeof(uint64_t)); + pcbase = (pcbase & 0xff) | (u64ptr(npc) << 8); + memcpy(flink, &pcbase, sizeof(uint64_t)); +#else + J->cur.snapmap[snap->mapofs + snap->nent] = SNAP_MKPC(npc); +#endif + J->needsnap = 1; + if (bc_a(jmpins) < J->maxslot) J->maxslot = bc_a(jmpins); + lj_snap_shrink(J); /* Shrink last snapshot if possible. */ +} + +/* Record the next bytecode instruction (_before_ it's executed). */ +void lj_record_ins(jit_State *J) +{ + cTValue *lbase; + RecordIndex ix; + const BCIns *pc; + BCIns ins; + BCOp op; + TRef ra, rb, rc; + + /* Perform post-processing action before recording the next instruction. */ + if (LJ_UNLIKELY(J->postproc != LJ_POST_NONE)) { + switch (J->postproc) { + case LJ_POST_FIXCOMP: /* Fixup comparison. */ + pc = (const BCIns *)(uintptr_t)J2G(J)->tmptv.u64; + rec_comp_fixup(J, pc, (!tvistruecond(&J2G(J)->tmptv2) ^ (bc_op(*pc)&1))); + /* fallthrough */ + case LJ_POST_FIXGUARD: /* Fixup and emit pending guard. */ + case LJ_POST_FIXGUARDSNAP: /* Fixup and emit pending guard and snapshot. */ + if (!tvistruecond(&J2G(J)->tmptv2)) { + J->fold.ins.o ^= 1; /* Flip guard to opposite. */ + if (J->postproc == LJ_POST_FIXGUARDSNAP) { + SnapShot *snap = &J->cur.snap[J->cur.nsnap-1]; + J->cur.snapmap[snap->mapofs+snap->nent-1]--; /* False -> true. */ + } + } + lj_opt_fold(J); /* Emit pending guard. */ + /* fallthrough */ + case LJ_POST_FIXBOOL: + if (!tvistruecond(&J2G(J)->tmptv2)) { + BCReg s; + TValue *tv = J->L->base; + for (s = 0; s < J->maxslot; s++) /* Fixup stack slot (if any). */ + if (J->base[s] == TREF_TRUE && tvisfalse(&tv[s])) { + J->base[s] = TREF_FALSE; + break; + } + } + break; + case LJ_POST_FIXCONST: + { + BCReg s; + TValue *tv = J->L->base; + for (s = 0; s < J->maxslot; s++) /* Constify stack slots (if any). */ + if (J->base[s] == TREF_NIL && !tvisnil(&tv[s])) + J->base[s] = lj_record_constify(J, &tv[s]); + } + break; + case LJ_POST_FFRETRY: /* Suppress recording of retried fast function. */ + if (bc_op(*J->pc) >= BC__MAX) + return; + break; + default: lj_assertJ(0, "bad post-processing mode"); break; + } + J->postproc = LJ_POST_NONE; + } + + /* Need snapshot before recording next bytecode (e.g. after a store). */ + if (J->needsnap) { + J->needsnap = 0; + if (J->pt) lj_snap_purge(J); + lj_snap_add(J); + J->mergesnap = 1; + } + + /* Skip some bytecodes. */ + if (LJ_UNLIKELY(J->bcskip > 0)) { + J->bcskip--; + return; + } + + /* Record only closed loops for root traces. */ + pc = J->pc; + if (J->framedepth == 0 && + (MSize)((char *)pc - (char *)J->bc_min) >= J->bc_extent) + lj_trace_err(J, LJ_TRERR_LLEAVE); + +#ifdef LUA_USE_ASSERT + rec_check_slots(J); + rec_check_ir(J); +#endif + +#if LJ_HASPROFILE + rec_profile_ins(J, pc); +#endif + + /* Keep a copy of the runtime values of var/num/str operands. */ +#define rav (&ix.valv) +#define rbv (&ix.tabv) +#define rcv (&ix.keyv) + + lbase = J->L->base; + ins = *pc; + op = bc_op(ins); + ra = bc_a(ins); + ix.val = 0; + switch (bcmode_a(op)) { + case BCMvar: + copyTV(J->L, rav, &lbase[ra]); ix.val = ra = getslot(J, ra); break; + default: break; /* Handled later. */ + } + rb = bc_b(ins); + rc = bc_c(ins); + switch (bcmode_b(op)) { + case BCMnone: rb = 0; rc = bc_d(ins); break; /* Upgrade rc to 'rd'. */ + case BCMvar: + copyTV(J->L, rbv, &lbase[rb]); ix.tab = rb = getslot(J, rb); break; + default: break; /* Handled later. */ + } + switch (bcmode_c(op)) { + case BCMvar: + copyTV(J->L, rcv, &lbase[rc]); ix.key = rc = getslot(J, rc); break; + case BCMpri: setpriV(rcv, ~rc); ix.key = rc = TREF_PRI(IRT_NIL+rc); break; + case BCMnum: { cTValue *tv = proto_knumtv(J->pt, rc); + copyTV(J->L, rcv, tv); ix.key = rc = tvisint(tv) ? lj_ir_kint(J, intV(tv)) : + tv->u32.hi == LJ_KEYINDEX ? (lj_ir_kint(J, 0) | TREF_KEYINDEX) : + lj_ir_knumint(J, numV(tv)); } break; + case BCMstr: { GCstr *s = gco2str(proto_kgc(J->pt, ~(ptrdiff_t)rc)); + setstrV(J->L, rcv, s); ix.key = rc = lj_ir_kstr(J, s); } break; + default: break; /* Handled later. */ + } + + switch (op) { + + /* -- Comparison ops ---------------------------------------------------- */ + + case BC_ISLT: case BC_ISGE: case BC_ISLE: case BC_ISGT: +#if LJ_HASFFI + if (tref_iscdata(ra) || tref_iscdata(rc)) { + rec_mm_comp_cdata(J, &ix, op, ((int)op & 2) ? MM_le : MM_lt); + break; + } +#endif + /* Emit nothing for two numeric or string consts. */ + if (!(tref_isk2(ra,rc) && tref_isnumber_str(ra) && tref_isnumber_str(rc))) { + IRType ta = tref_isinteger(ra) ? IRT_INT : tref_type(ra); + IRType tc = tref_isinteger(rc) ? IRT_INT : tref_type(rc); + int irop; + if (ta != tc) { + /* Widen mixed number/int comparisons to number/number comparison. */ + if (ta == IRT_INT && tc == IRT_NUM) { + ra = emitir(IRTN(IR_CONV), ra, IRCONV_NUM_INT); + ta = IRT_NUM; + } else if (ta == IRT_NUM && tc == IRT_INT) { + rc = emitir(IRTN(IR_CONV), rc, IRCONV_NUM_INT); + } else if (LJ_52) { + ta = IRT_NIL; /* Force metamethod for different types. */ + } else if (!((ta == IRT_FALSE || ta == IRT_TRUE) && + (tc == IRT_FALSE || tc == IRT_TRUE))) { + break; /* Interpreter will throw for two different types. */ + } + } + rec_comp_prep(J); + irop = (int)op - (int)BC_ISLT + (int)IR_LT; + if (ta == IRT_NUM) { + if ((irop & 1)) irop ^= 4; /* ISGE/ISGT are unordered. */ + if (!lj_ir_numcmp(numberVnum(rav), numberVnum(rcv), (IROp)irop)) + irop ^= 5; + } else if (ta == IRT_INT) { + if (!lj_ir_numcmp(numberVnum(rav), numberVnum(rcv), (IROp)irop)) + irop ^= 1; + } else if (ta == IRT_STR) { + if (!lj_ir_strcmp(strV(rav), strV(rcv), (IROp)irop)) irop ^= 1; + ra = lj_ir_call(J, IRCALL_lj_str_cmp, ra, rc); + rc = lj_ir_kint(J, 0); + ta = IRT_INT; + } else { + rec_mm_comp(J, &ix, (int)op); + break; + } + emitir(IRTG(irop, ta), ra, rc); + rec_comp_fixup(J, J->pc, ((int)op ^ irop) & 1); + } + break; + + case BC_ISEQV: case BC_ISNEV: + case BC_ISEQS: case BC_ISNES: + case BC_ISEQN: case BC_ISNEN: + case BC_ISEQP: case BC_ISNEP: +#if LJ_HASFFI + if (tref_iscdata(ra) || tref_iscdata(rc)) { + rec_mm_comp_cdata(J, &ix, op, MM_eq); + break; + } +#endif + /* Emit nothing for two non-table, non-udata consts. */ + if (!(tref_isk2(ra, rc) && !(tref_istab(ra) || tref_isudata(ra)))) { + int diff; + rec_comp_prep(J); + diff = lj_record_objcmp(J, ra, rc, rav, rcv); + if (diff == 2 || !(tref_istab(ra) || tref_isudata(ra))) + rec_comp_fixup(J, J->pc, ((int)op & 1) == !diff); + else if (diff == 1) /* Only check __eq if different, but same type. */ + rec_mm_equal(J, &ix, (int)op); + } + break; + + /* -- Unary test and copy ops ------------------------------------------- */ + + case BC_ISTC: case BC_ISFC: + if ((op & 1) == tref_istruecond(rc)) + rc = 0; /* Don't store if condition is not true. */ + /* fallthrough */ + case BC_IST: case BC_ISF: /* Type specialization suffices. */ + if (bc_a(pc[1]) < J->maxslot) + J->maxslot = bc_a(pc[1]); /* Shrink used slots. */ + break; + + case BC_ISTYPE: case BC_ISNUM: + /* These coercions need to correspond with lj_meta_istype(). */ + if (LJ_DUALNUM && rc == ~LJ_TNUMX+1) + ra = lj_opt_narrow_toint(J, ra); + else if (rc == ~LJ_TNUMX+2) + ra = lj_ir_tonum(J, ra); + else if (rc == ~LJ_TSTR+1) + ra = lj_ir_tostr(J, ra); + /* else: type specialization suffices. */ + J->base[bc_a(ins)] = ra; + break; + + /* -- Unary ops --------------------------------------------------------- */ + + case BC_NOT: + /* Type specialization already forces const result. */ + rc = tref_istruecond(rc) ? TREF_FALSE : TREF_TRUE; + break; + + case BC_LEN: + if (tref_isstr(rc)) + rc = emitir(IRTI(IR_FLOAD), rc, IRFL_STR_LEN); + else if (!LJ_52 && tref_istab(rc)) + rc = emitir(IRTI(IR_ALEN), rc, TREF_NIL); + else + rc = rec_mm_len(J, rc, rcv); + break; + + /* -- Arithmetic ops ---------------------------------------------------- */ + + case BC_UNM: + if (tref_isnumber_str(rc)) { + rc = lj_opt_narrow_unm(J, rc, rcv); + } else { + ix.tab = rc; + copyTV(J->L, &ix.tabv, rcv); + rc = rec_mm_arith(J, &ix, MM_unm); + } + break; + + case BC_ADDNV: case BC_SUBNV: case BC_MULNV: case BC_DIVNV: case BC_MODNV: + /* Swap rb/rc and rbv/rcv. rav is temp. */ + ix.tab = rc; ix.key = rc = rb; rb = ix.tab; + copyTV(J->L, rav, rbv); + copyTV(J->L, rbv, rcv); + copyTV(J->L, rcv, rav); + if (op == BC_MODNV) + goto recmod; + /* fallthrough */ + case BC_ADDVN: case BC_SUBVN: case BC_MULVN: case BC_DIVVN: + case BC_ADDVV: case BC_SUBVV: case BC_MULVV: case BC_DIVVV: { + MMS mm = bcmode_mm(op); + if (tref_isnumber_str(rb) && tref_isnumber_str(rc)) + rc = lj_opt_narrow_arith(J, rb, rc, rbv, rcv, + (int)mm - (int)MM_add + (int)IR_ADD); + else + rc = rec_mm_arith(J, &ix, mm); + break; + } + + case BC_MODVN: case BC_MODVV: + recmod: + if (tref_isnumber_str(rb) && tref_isnumber_str(rc)) + rc = lj_opt_narrow_mod(J, rb, rc, rbv, rcv); + else + rc = rec_mm_arith(J, &ix, MM_mod); + break; + + case BC_POW: + if (tref_isnumber_str(rb) && tref_isnumber_str(rc)) + rc = lj_opt_narrow_arith(J, rb, rc, rbv, rcv, IR_POW); + else + rc = rec_mm_arith(J, &ix, MM_pow); + break; + + /* -- Miscellaneous ops ------------------------------------------------- */ + + case BC_CAT: + rc = rec_cat(J, rb, rc); + break; + + /* -- Constant and move ops --------------------------------------------- */ + + case BC_MOV: + /* Clear gap of method call to avoid resurrecting previous refs. */ + if (ra > J->maxslot) { +#if LJ_FR2 + memset(J->base + J->maxslot, 0, (ra - J->maxslot) * sizeof(TRef)); +#else + J->base[ra-1] = 0; +#endif + } + break; + case BC_KSTR: case BC_KNUM: case BC_KPRI: + break; + case BC_KSHORT: + rc = lj_ir_kint(J, (int32_t)(int16_t)rc); + break; + case BC_KNIL: + if (LJ_FR2 && ra > J->maxslot) + J->base[ra-1] = 0; + while (ra <= rc) + J->base[ra++] = TREF_NIL; + if (rc >= J->maxslot) J->maxslot = rc+1; + break; +#if LJ_HASFFI + case BC_KCDATA: + rc = lj_ir_kgc(J, proto_kgc(J->pt, ~(ptrdiff_t)rc), IRT_CDATA); + break; +#endif + + /* -- Upvalue and function ops ------------------------------------------ */ + + case BC_UGET: + rc = rec_upvalue(J, rc, 0); + break; + case BC_USETV: case BC_USETS: case BC_USETN: case BC_USETP: + rec_upvalue(J, ra, rc); + break; + + /* -- Table ops --------------------------------------------------------- */ + + case BC_GGET: case BC_GSET: + settabV(J->L, &ix.tabv, tabref(J->fn->l.env)); + ix.tab = emitir(IRT(IR_FLOAD, IRT_TAB), getcurrf(J), IRFL_FUNC_ENV); + ix.idxchain = LJ_MAX_IDXCHAIN; + rc = lj_record_idx(J, &ix); + break; + + case BC_TGETB: case BC_TSETB: + setintV(&ix.keyv, (int32_t)rc); + ix.key = lj_ir_kint(J, (int32_t)rc); + /* fallthrough */ + case BC_TGETV: case BC_TGETS: case BC_TSETV: case BC_TSETS: + ix.idxchain = LJ_MAX_IDXCHAIN; + rc = lj_record_idx(J, &ix); + break; + case BC_TGETR: case BC_TSETR: + ix.idxchain = 0; + rc = lj_record_idx(J, &ix); + break; + + case BC_TSETM: + rec_tsetm(J, ra, (BCReg)(J->L->top - J->L->base), (int32_t)rcv->u32.lo); + break; + + case BC_TNEW: + rc = rec_tnew(J, rc); + break; + case BC_TDUP: + rc = emitir(IRTG(IR_TDUP, IRT_TAB), + lj_ir_ktab(J, gco2tab(proto_kgc(J->pt, ~(ptrdiff_t)rc))), 0); +#ifdef LUAJIT_ENABLE_TABLE_BUMP + J->rbchash[(rc & (RBCHASH_SLOTS-1))].ref = tref_ref(rc); + setmref(J->rbchash[(rc & (RBCHASH_SLOTS-1))].pc, pc); + setgcref(J->rbchash[(rc & (RBCHASH_SLOTS-1))].pt, obj2gco(J->pt)); +#endif + break; + + /* -- Calls and vararg handling ----------------------------------------- */ + + case BC_ITERC: + J->base[ra] = getslot(J, ra-3); + J->base[ra+1+LJ_FR2] = getslot(J, ra-2); + J->base[ra+2+LJ_FR2] = getslot(J, ra-1); + { /* Do the actual copy now because lj_record_call needs the values. */ + TValue *b = &J->L->base[ra]; + copyTV(J->L, b, b-3); + copyTV(J->L, b+1+LJ_FR2, b-2); + copyTV(J->L, b+2+LJ_FR2, b-1); + } + lj_record_call(J, ra, (ptrdiff_t)rc-1); + break; + + /* L->top is set to L->base+ra+rc+NARGS-1+1. See lj_dispatch_ins(). */ + case BC_CALLM: + rc = (BCReg)(J->L->top - J->L->base) - ra - LJ_FR2; + /* fallthrough */ + case BC_CALL: + lj_record_call(J, ra, (ptrdiff_t)rc-1); + break; + + case BC_CALLMT: + rc = (BCReg)(J->L->top - J->L->base) - ra - LJ_FR2; + /* fallthrough */ + case BC_CALLT: + lj_record_tailcall(J, ra, (ptrdiff_t)rc-1); + break; + + case BC_VARG: + rec_varg(J, ra, (ptrdiff_t)rb-1); + break; + + /* -- Returns ----------------------------------------------------------- */ + + case BC_RETM: + /* L->top is set to L->base+ra+rc+NRESULTS-1, see lj_dispatch_ins(). */ + rc = (BCReg)(J->L->top - J->L->base) - ra + 1; + /* fallthrough */ + case BC_RET: case BC_RET0: case BC_RET1: +#if LJ_HASPROFILE + rec_profile_ret(J); +#endif + lj_record_ret(J, ra, (ptrdiff_t)rc-1); + break; + + /* -- Loops and branches ------------------------------------------------ */ + + case BC_FORI: + if (rec_for(J, pc, 0) != LOOPEV_LEAVE) + J->loopref = J->cur.nins; + break; + case BC_JFORI: + lj_assertJ(bc_op(pc[(ptrdiff_t)rc-BCBIAS_J]) == BC_JFORL, + "JFORI does not point to JFORL"); + if (rec_for(J, pc, 0) != LOOPEV_LEAVE) /* Link to existing loop. */ + lj_record_stop(J, LJ_TRLINK_ROOT, bc_d(pc[(ptrdiff_t)rc-BCBIAS_J])); + /* Continue tracing if the loop is not entered. */ + break; + + case BC_FORL: + rec_loop_interp(J, pc, rec_for(J, pc+((ptrdiff_t)rc-BCBIAS_J), 1)); + break; + case BC_ITERL: + rec_loop_interp(J, pc, rec_iterl(J, *pc)); + break; + case BC_ITERN: + rec_loop_interp(J, pc, rec_itern(J, ra, rb)); + break; + case BC_LOOP: + rec_loop_interp(J, pc, rec_loop(J, ra, 1)); + break; + + case BC_JFORL: + rec_loop_jit(J, rc, rec_for(J, pc+bc_j(traceref(J, rc)->startins), 1)); + break; + case BC_JITERL: + rec_loop_jit(J, rc, rec_iterl(J, traceref(J, rc)->startins)); + break; + case BC_JLOOP: + rec_loop_jit(J, rc, rec_loop(J, ra, + !bc_isret(bc_op(traceref(J, rc)->startins)))); + break; + + case BC_IFORL: + case BC_IITERL: + case BC_ILOOP: + case BC_IFUNCF: + case BC_IFUNCV: + lj_trace_err(J, LJ_TRERR_BLACKL); + break; + + case BC_JMP: + if (ra < J->maxslot) + J->maxslot = ra; /* Shrink used slots. */ + break; + + case BC_ISNEXT: + rec_isnext(J, ra); + break; + + /* -- Function headers -------------------------------------------------- */ + + case BC_FUNCF: + rec_func_lua(J); + break; + case BC_JFUNCF: + rec_func_jit(J, rc); + break; + + case BC_FUNCV: + rec_func_vararg(J); + rec_func_lua(J); + break; + case BC_JFUNCV: + /* Cannot happen. No hotcall counting for varag funcs. */ + lj_assertJ(0, "unsupported vararg hotcall"); + break; + + case BC_FUNCC: + case BC_FUNCCW: + lj_ffrecord_func(J); + break; + + default: + if (op >= BC__MAX) { + lj_ffrecord_func(J); + break; + } + /* fallthrough */ + case BC_UCLO: + case BC_FNEW: + setintV(&J->errinfo, (int32_t)op); + lj_trace_err_info(J, LJ_TRERR_NYIBC); + break; + } + + /* rc == 0 if we have no result yet, e.g. pending __index metamethod call. */ + if (bcmode_a(op) == BCMdst && rc) { + J->base[ra] = rc; + if (ra >= J->maxslot) { +#if LJ_FR2 + if (ra > J->maxslot) J->base[ra-1] = 0; +#endif + J->maxslot = ra+1; + } + } + +#undef rav +#undef rbv +#undef rcv + + /* Limit the number of recorded IR instructions and constants. */ + if (J->cur.nins > REF_FIRST+(IRRef)J->param[JIT_P_maxrecord] || + J->cur.nk < REF_BIAS-(IRRef)J->param[JIT_P_maxirconst]) + lj_trace_err(J, LJ_TRERR_TRACEOV); +} + +/* -- Recording setup ----------------------------------------------------- */ + +/* Setup recording for a root trace started by a hot loop. */ +static const BCIns *rec_setup_root(jit_State *J) +{ + /* Determine the next PC and the bytecode range for the loop. */ + const BCIns *pcj, *pc = J->pc; + BCIns ins = *pc; + BCReg ra = bc_a(ins); + switch (bc_op(ins)) { + case BC_FORL: + J->bc_extent = (MSize)(-bc_j(ins))*sizeof(BCIns); + pc += 1+bc_j(ins); + J->bc_min = pc; + break; + case BC_ITERL: + if (bc_op(pc[-1]) == BC_JLOOP) + lj_trace_err(J, LJ_TRERR_LINNER); + lj_assertJ(bc_op(pc[-1]) == BC_ITERC, "no ITERC before ITERL"); + J->maxslot = ra + bc_b(pc[-1]) - 1; + J->bc_extent = (MSize)(-bc_j(ins))*sizeof(BCIns); + pc += 1+bc_j(ins); + lj_assertJ(bc_op(pc[-1]) == BC_JMP, "ITERL does not point to JMP+1"); + J->bc_min = pc; + break; + case BC_ITERN: + lj_assertJ(bc_op(pc[1]) == BC_ITERL, "no ITERL after ITERN"); + J->maxslot = ra; + J->bc_extent = (MSize)(-bc_j(pc[1]))*sizeof(BCIns); + J->bc_min = pc+2 + bc_j(pc[1]); + J->state = LJ_TRACE_RECORD_1ST; /* Record the first ITERN, too. */ + break; + case BC_LOOP: + /* Only check BC range for real loops, but not for "repeat until true". */ + pcj = pc + bc_j(ins); + ins = *pcj; + if (bc_op(ins) == BC_JMP && bc_j(ins) < 0) { + J->bc_min = pcj+1 + bc_j(ins); + J->bc_extent = (MSize)(-bc_j(ins))*sizeof(BCIns); + } + J->maxslot = ra; + pc++; + break; + case BC_RET: + case BC_RET0: + case BC_RET1: + /* No bytecode range check for down-recursive root traces. */ + J->maxslot = ra + bc_d(ins) - 1; + break; + case BC_FUNCF: + /* No bytecode range check for root traces started by a hot call. */ + J->maxslot = J->pt->numparams; + pc++; + break; + case BC_CALLM: + case BC_CALL: + case BC_ITERC: + /* No bytecode range check for stitched traces. */ + pc++; + break; + default: + lj_assertJ(0, "bad root trace start bytecode %d", bc_op(ins)); + break; + } + return pc; +} + +/* Setup for recording a new trace. */ +void lj_record_setup(jit_State *J) +{ + uint32_t i; + + /* Initialize state related to current trace. */ + memset(J->slot, 0, sizeof(J->slot)); + memset(J->chain, 0, sizeof(J->chain)); +#ifdef LUAJIT_ENABLE_TABLE_BUMP + memset(J->rbchash, 0, sizeof(J->rbchash)); +#endif + memset(J->bpropcache, 0, sizeof(J->bpropcache)); + J->scev.idx = REF_NIL; + setmref(J->scev.pc, NULL); + + J->baseslot = 1+LJ_FR2; /* Invoking function is at base[-1-LJ_FR2]. */ + J->base = J->slot + J->baseslot; + J->maxslot = 0; + J->framedepth = 0; + J->retdepth = 0; + + J->instunroll = J->param[JIT_P_instunroll]; + J->loopunroll = J->param[JIT_P_loopunroll]; + J->tailcalled = 0; + J->loopref = 0; + + J->bc_min = NULL; /* Means no limit. */ + J->bc_extent = ~(MSize)0; + + /* Emit instructions for fixed references. Also triggers initial IR alloc. */ + emitir_raw(IRT(IR_BASE, IRT_PGC), J->parent, J->exitno); + for (i = 0; i <= 2; i++) { + IRIns *ir = IR(REF_NIL-i); + ir->i = 0; + ir->t.irt = (uint8_t)(IRT_NIL+i); + ir->o = IR_KPRI; + ir->prev = 0; + } + J->cur.nk = REF_TRUE; + + J->startpc = J->pc; + setmref(J->cur.startpc, J->pc); + if (J->parent) { /* Side trace. */ + GCtrace *T = traceref(J, J->parent); + TraceNo root = T->root ? T->root : J->parent; + J->cur.root = (uint16_t)root; + J->cur.startins = BCINS_AD(BC_JMP, 0, 0); + /* Check whether we could at least potentially form an extra loop. */ + if (J->exitno == 0 && T->snap[0].nent == 0) { + /* We can narrow a FORL for some side traces, too. */ + if (J->pc > proto_bc(J->pt) && bc_op(J->pc[-1]) == BC_JFORI && + bc_d(J->pc[bc_j(J->pc[-1])-1]) == root) { + lj_snap_add(J); + rec_for_loop(J, J->pc-1, &J->scev, 1); + goto sidecheck; + } + } else { + J->startpc = NULL; /* Prevent forming an extra loop. */ + } + lj_snap_replay(J, T); + sidecheck: + if ((traceref(J, J->cur.root)->nchild >= J->param[JIT_P_maxside] || + T->snap[J->exitno].count >= J->param[JIT_P_hotexit] + + J->param[JIT_P_tryside])) { + if (bc_op(*J->pc) == BC_JLOOP) { + BCIns startins = traceref(J, bc_d(*J->pc))->startins; + if (bc_op(startins) == BC_ITERN) + rec_itern(J, bc_a(startins), bc_b(startins)); + } + lj_record_stop(J, LJ_TRLINK_INTERP, 0); + } + } else { /* Root trace. */ + J->cur.root = 0; + J->cur.startins = *J->pc; + J->pc = rec_setup_root(J); + /* Note: the loop instruction itself is recorded at the end and not + ** at the start! So snapshot #0 needs to point to the *next* instruction. + ** The one exception is BC_ITERN, which sets LJ_TRACE_RECORD_1ST. + */ + lj_snap_add(J); + if (bc_op(J->cur.startins) == BC_FORL) + rec_for_loop(J, J->pc-1, &J->scev, 1); + else if (bc_op(J->cur.startins) == BC_ITERC) + J->startpc = NULL; + if (1 + J->pt->framesize >= LJ_MAX_JSLOTS) + lj_trace_err(J, LJ_TRERR_STACKOV); + } +#if LJ_HASPROFILE + J->prev_pt = NULL; + J->prev_line = -1; +#endif +#ifdef LUAJIT_ENABLE_CHECKHOOK + /* Regularly check for instruction/line hooks from compiled code and + ** exit to the interpreter if the hooks are set. + ** + ** This is a compile-time option and disabled by default, since the + ** hook checks may be quite expensive in tight loops. + ** + ** Note this is only useful if hooks are *not* set most of the time. + ** Use this only if you want to *asynchronously* interrupt the execution. + ** + ** You can set the instruction hook via lua_sethook() with a count of 1 + ** from a signal handler or another native thread. Please have a look + ** at the first few functions in luajit.c for an example (Ctrl-C handler). + */ + { + TRef tr = emitir(IRT(IR_XLOAD, IRT_U8), + lj_ir_kptr(J, &J2G(J)->hookmask), IRXLOAD_VOLATILE); + tr = emitir(IRTI(IR_BAND), tr, lj_ir_kint(J, (LUA_MASKLINE|LUA_MASKCOUNT))); + emitir(IRTGI(IR_EQ), tr, lj_ir_kint(J, 0)); + } +#endif +} + +#undef IR +#undef emitir_raw +#undef emitir + +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_record.h b/fluent-bit/lib/luajit-3065c9/src/lj_record.h new file mode 100644 index 00000000..ab2f4c8d --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_record.h @@ -0,0 +1,47 @@ +/* +** Trace recorder (bytecode -> SSA IR). +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#ifndef _LJ_RECORD_H +#define _LJ_RECORD_H + +#include "lj_obj.h" +#include "lj_jit.h" + +#if LJ_HASJIT +/* Context for recording an indexed load/store. */ +typedef struct RecordIndex { + TValue tabv; /* Runtime value of table (or indexed object). */ + TValue keyv; /* Runtime value of key. */ + TValue valv; /* Runtime value of stored value. */ + TValue mobjv; /* Runtime value of metamethod object. */ + GCtab *mtv; /* Runtime value of metatable object. */ + cTValue *oldv; /* Runtime value of previously stored value. */ + TRef tab; /* Table (or indexed object) reference. */ + TRef key; /* Key reference. */ + TRef val; /* Value reference for a store or 0 for a load. */ + TRef mt; /* Metatable reference. */ + TRef mobj; /* Metamethod object reference. */ + int idxchain; /* Index indirections left or 0 for raw lookup. */ +} RecordIndex; + +LJ_FUNC int lj_record_objcmp(jit_State *J, TRef a, TRef b, + cTValue *av, cTValue *bv); +LJ_FUNC void lj_record_stop(jit_State *J, TraceLink linktype, TraceNo lnk); +LJ_FUNC TRef lj_record_constify(jit_State *J, cTValue *o); +LJ_FUNC TRef lj_record_vload(jit_State *J, TRef ref, MSize idx, IRType t); + +LJ_FUNC void lj_record_call(jit_State *J, BCReg func, ptrdiff_t nargs); +LJ_FUNC void lj_record_tailcall(jit_State *J, BCReg func, ptrdiff_t nargs); +LJ_FUNC void lj_record_ret(jit_State *J, BCReg rbase, ptrdiff_t gotresults); + +LJ_FUNC int lj_record_mm_lookup(jit_State *J, RecordIndex *ix, MMS mm); +LJ_FUNC TRef lj_record_idx(jit_State *J, RecordIndex *ix); +LJ_FUNC int lj_record_next(jit_State *J, RecordIndex *ix); + +LJ_FUNC void lj_record_ins(jit_State *J); +LJ_FUNC void lj_record_setup(jit_State *J); +#endif + +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_serialize.c b/fluent-bit/lib/luajit-3065c9/src/lj_serialize.c new file mode 100644 index 00000000..f7e51828 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_serialize.c @@ -0,0 +1,539 @@ +/* +** Object de/serialization. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#define lj_serialize_c +#define LUA_CORE + +#include "lj_obj.h" + +#if LJ_HASBUFFER +#include "lj_err.h" +#include "lj_buf.h" +#include "lj_str.h" +#include "lj_tab.h" +#include "lj_udata.h" +#if LJ_HASFFI +#include "lj_ctype.h" +#include "lj_cdata.h" +#endif +#if LJ_HASJIT +#include "lj_ir.h" +#endif +#include "lj_serialize.h" + +/* Tags for internal serialization format. */ +enum { + SER_TAG_NIL, /* 0x00 */ + SER_TAG_FALSE, + SER_TAG_TRUE, + SER_TAG_NULL, + SER_TAG_LIGHTUD32, + SER_TAG_LIGHTUD64, + SER_TAG_INT, + SER_TAG_NUM, + SER_TAG_TAB, /* 0x08 */ + SER_TAG_DICT_MT = SER_TAG_TAB+6, + SER_TAG_DICT_STR, + SER_TAG_INT64, /* 0x10 */ + SER_TAG_UINT64, + SER_TAG_COMPLEX, + SER_TAG_0x13, + SER_TAG_0x14, + SER_TAG_0x15, + SER_TAG_0x16, + SER_TAG_0x17, + SER_TAG_0x18, /* 0x18 */ + SER_TAG_0x19, + SER_TAG_0x1a, + SER_TAG_0x1b, + SER_TAG_0x1c, + SER_TAG_0x1d, + SER_TAG_0x1e, + SER_TAG_0x1f, + SER_TAG_STR, /* 0x20 + str->len */ +}; +LJ_STATIC_ASSERT((SER_TAG_TAB & 7) == 0); + +/* -- Helper functions ---------------------------------------------------- */ + +static LJ_AINLINE char *serialize_more(char *w, SBufExt *sbx, MSize sz) +{ + if (LJ_UNLIKELY(sz > (MSize)(sbx->e - w))) { + sbx->w = w; + w = lj_buf_more2((SBuf *)sbx, sz); + } + return w; +} + +/* Write U124 to buffer. */ +static LJ_NOINLINE char *serialize_wu124_(char *w, uint32_t v) +{ + if (v < 0x1fe0) { + v -= 0xe0; + *w++ = (char)(0xe0 | (v >> 8)); *w++ = (char)v; + } else { + *w++ = (char)0xff; +#if LJ_BE + v = lj_bswap(v); +#endif + memcpy(w, &v, 4); w += 4; + } + return w; +} + +static LJ_AINLINE char *serialize_wu124(char *w, uint32_t v) +{ + if (LJ_LIKELY(v < 0xe0)) { + *w++ = (char)v; + return w; + } else { + return serialize_wu124_(w, v); + } +} + +static LJ_NOINLINE char *serialize_ru124_(char *r, char *w, uint32_t *pv) +{ + uint32_t v = *pv; + if (v != 0xff) { + if (r >= w) return NULL; + v = ((v & 0x1f) << 8) + *(uint8_t *)r + 0xe0; r++; + } else { + if (r + 4 > w) return NULL; + v = lj_getu32(r); r += 4; +#if LJ_BE + v = lj_bswap(v); +#endif + } + *pv = v; + return r; +} + +static LJ_AINLINE char *serialize_ru124(char *r, char *w, uint32_t *pv) +{ + if (LJ_LIKELY(r < w)) { + uint32_t v = *(uint8_t *)r; r++; + *pv = v; + if (LJ_UNLIKELY(v >= 0xe0)) { + r = serialize_ru124_(r, w, pv); + } + return r; + } + return NULL; +} + +/* Prepare string dictionary for use (once). */ +void LJ_FASTCALL lj_serialize_dict_prep_str(lua_State *L, GCtab *dict) +{ + if (!dict->hmask) { /* No hash part means not prepared, yet. */ + MSize i, len = lj_tab_len(dict); + if (!len) return; + lj_tab_resize(L, dict, dict->asize, hsize2hbits(len)); + for (i = 1; i <= len && i < dict->asize; i++) { + cTValue *o = arrayslot(dict, i); + if (tvisstr(o)) { + if (!lj_tab_getstr(dict, strV(o))) { /* Ignore dups. */ + lj_tab_newkey(L, dict, o)->u64 = (uint64_t)(i-1); + } + } else if (!tvisfalse(o)) { + lj_err_caller(L, LJ_ERR_BUFFER_BADOPT); + } + } + } +} + +/* Prepare metatable dictionary for use (once). */ +void LJ_FASTCALL lj_serialize_dict_prep_mt(lua_State *L, GCtab *dict) +{ + if (!dict->hmask) { /* No hash part means not prepared, yet. */ + MSize i, len = lj_tab_len(dict); + if (!len) return; + lj_tab_resize(L, dict, dict->asize, hsize2hbits(len)); + for (i = 1; i <= len && i < dict->asize; i++) { + cTValue *o = arrayslot(dict, i); + if (tvistab(o)) { + if (tvisnil(lj_tab_get(L, dict, o))) { /* Ignore dups. */ + lj_tab_newkey(L, dict, o)->u64 = (uint64_t)(i-1); + } + } else if (!tvisfalse(o)) { + lj_err_caller(L, LJ_ERR_BUFFER_BADOPT); + } + } + } +} + +/* -- Internal serializer ------------------------------------------------- */ + +/* Put serialized object into buffer. */ +static char *serialize_put(char *w, SBufExt *sbx, cTValue *o) +{ + if (LJ_LIKELY(tvisstr(o))) { + const GCstr *str = strV(o); + MSize len = str->len; + w = serialize_more(w, sbx, 5+len); + w = serialize_wu124(w, SER_TAG_STR + len); + w = lj_buf_wmem(w, strdata(str), len); + } else if (tvisint(o)) { + uint32_t x = LJ_BE ? lj_bswap((uint32_t)intV(o)) : (uint32_t)intV(o); + w = serialize_more(w, sbx, 1+4); + *w++ = SER_TAG_INT; memcpy(w, &x, 4); w += 4; + } else if (tvisnum(o)) { + uint64_t x = LJ_BE ? lj_bswap64(o->u64) : o->u64; + w = serialize_more(w, sbx, 1+sizeof(lua_Number)); + *w++ = SER_TAG_NUM; memcpy(w, &x, 8); w += 8; + } else if (tvispri(o)) { + w = serialize_more(w, sbx, 1); + *w++ = (char)(SER_TAG_NIL + ~itype(o)); + } else if (tvistab(o)) { + const GCtab *t = tabV(o); + uint32_t narray = 0, nhash = 0, one = 2; + if (sbx->depth <= 0) lj_err_caller(sbufL(sbx), LJ_ERR_BUFFER_DEPTH); + sbx->depth--; + if (t->asize > 0) { /* Determine max. length of array part. */ + ptrdiff_t i; + TValue *array = tvref(t->array); + for (i = (ptrdiff_t)t->asize-1; i >= 0; i--) + if (!tvisnil(&array[i])) + break; + narray = (uint32_t)(i+1); + if (narray && tvisnil(&array[0])) one = 4; + } + if (t->hmask > 0) { /* Count number of used hash slots. */ + uint32_t i, hmask = t->hmask; + Node *node = noderef(t->node); + for (i = 0; i <= hmask; i++) + nhash += !tvisnil(&node[i].val); + } + /* Write metatable index. */ + if (LJ_UNLIKELY(tabref(sbx->dict_mt)) && tabref(t->metatable)) { + TValue mto; + Node *n; + settabV(sbufL(sbx), &mto, tabref(t->metatable)); + n = hashgcref(tabref(sbx->dict_mt), mto.gcr); + do { + if (n->key.u64 == mto.u64) { + uint32_t idx = n->val.u32.lo; + w = serialize_more(w, sbx, 1+5); + *w++ = SER_TAG_DICT_MT; + w = serialize_wu124(w, idx); + break; + } + } while ((n = nextnode(n))); + } + /* Write number of array slots and hash slots. */ + w = serialize_more(w, sbx, 1+2*5); + *w++ = (char)(SER_TAG_TAB + (nhash ? 1 : 0) + (narray ? one : 0)); + if (narray) w = serialize_wu124(w, narray); + if (nhash) w = serialize_wu124(w, nhash); + if (narray) { /* Write array entries. */ + cTValue *oa = tvref(t->array) + (one >> 2); + cTValue *oe = tvref(t->array) + narray; + while (oa < oe) w = serialize_put(w, sbx, oa++); + } + if (nhash) { /* Write hash entries. */ + const Node *node = noderef(t->node) + t->hmask; + GCtab *dict_str = tabref(sbx->dict_str); + if (LJ_UNLIKELY(dict_str)) { + for (;; node--) + if (!tvisnil(&node->val)) { + if (LJ_LIKELY(tvisstr(&node->key))) { + /* Inlined lj_tab_getstr is 30% faster. */ + const GCstr *str = strV(&node->key); + Node *n = hashstr(dict_str, str); + do { + if (tvisstr(&n->key) && strV(&n->key) == str) { + uint32_t idx = n->val.u32.lo; + w = serialize_more(w, sbx, 1+5); + *w++ = SER_TAG_DICT_STR; + w = serialize_wu124(w, idx); + break; + } + n = nextnode(n); + if (!n) { + MSize len = str->len; + w = serialize_more(w, sbx, 5+len); + w = serialize_wu124(w, SER_TAG_STR + len); + w = lj_buf_wmem(w, strdata(str), len); + break; + } + } while (1); + } else { + w = serialize_put(w, sbx, &node->key); + } + w = serialize_put(w, sbx, &node->val); + if (--nhash == 0) break; + } + } else { + for (;; node--) + if (!tvisnil(&node->val)) { + w = serialize_put(w, sbx, &node->key); + w = serialize_put(w, sbx, &node->val); + if (--nhash == 0) break; + } + } + } + sbx->depth++; +#if LJ_HASFFI + } else if (tviscdata(o)) { + CTState *cts = ctype_cts(sbufL(sbx)); + CType *s = ctype_raw(cts, cdataV(o)->ctypeid); + uint8_t *sp = cdataptr(cdataV(o)); + if (ctype_isinteger(s->info) && s->size == 8) { + w = serialize_more(w, sbx, 1+8); + *w++ = (s->info & CTF_UNSIGNED) ? SER_TAG_UINT64 : SER_TAG_INT64; +#if LJ_BE + { uint64_t u = lj_bswap64(*(uint64_t *)sp); memcpy(w, &u, 8); } +#else + memcpy(w, sp, 8); +#endif + w += 8; + } else if (ctype_iscomplex(s->info) && s->size == 16) { + w = serialize_more(w, sbx, 1+16); + *w++ = SER_TAG_COMPLEX; +#if LJ_BE + { /* Only swap the doubles. The re/im order stays the same. */ + uint64_t u = lj_bswap64(((uint64_t *)sp)[0]); memcpy(w, &u, 8); + u = lj_bswap64(((uint64_t *)sp)[1]); memcpy(w+8, &u, 8); + } +#else + memcpy(w, sp, 16); +#endif + w += 16; + } else { + goto badenc; /* NYI other cdata */ + } +#endif + } else if (tvislightud(o)) { + uintptr_t ud = (uintptr_t)lightudV(G(sbufL(sbx)), o); + w = serialize_more(w, sbx, 1+sizeof(ud)); + if (ud == 0) { + *w++ = SER_TAG_NULL; + } else if (LJ_32 || checku32(ud)) { +#if LJ_BE && LJ_64 + ud = lj_bswap64(ud); +#elif LJ_BE + ud = lj_bswap(ud); +#endif + *w++ = SER_TAG_LIGHTUD32; memcpy(w, &ud, 4); w += 4; +#if LJ_64 + } else { +#if LJ_BE + ud = lj_bswap64(ud); +#endif + *w++ = SER_TAG_LIGHTUD64; memcpy(w, &ud, 8); w += 8; +#endif + } + } else { + /* NYI userdata */ +#if LJ_HASFFI + badenc: +#endif + lj_err_callerv(sbufL(sbx), LJ_ERR_BUFFER_BADENC, lj_typename(o)); + } + return w; +} + +/* Get serialized object from buffer. */ +static char *serialize_get(char *r, SBufExt *sbx, TValue *o) +{ + char *w = sbx->w; + uint32_t tp; + r = serialize_ru124(r, w, &tp); if (LJ_UNLIKELY(!r)) goto eob; + if (LJ_LIKELY(tp >= SER_TAG_STR)) { + uint32_t len = tp - SER_TAG_STR; + if (LJ_UNLIKELY(len > (uint32_t)(w - r))) goto eob; + setstrV(sbufL(sbx), o, lj_str_new(sbufL(sbx), r, len)); + r += len; + } else if (tp == SER_TAG_INT) { + if (LJ_UNLIKELY(r + 4 > w)) goto eob; + setintV(o, (int32_t)(LJ_BE ? lj_bswap(lj_getu32(r)) : lj_getu32(r))); + r += 4; + } else if (tp == SER_TAG_NUM) { + if (LJ_UNLIKELY(r + 8 > w)) goto eob; + memcpy(o, r, 8); r += 8; +#if LJ_BE + o->u64 = lj_bswap64(o->u64); +#endif + if (!tvisnum(o)) setnanV(o); /* Fix non-canonical NaNs. */ + } else if (tp <= SER_TAG_TRUE) { + setpriV(o, ~tp); + } else if (tp == SER_TAG_DICT_STR) { + GCtab *dict_str; + uint32_t idx; + r = serialize_ru124(r, w, &idx); if (LJ_UNLIKELY(!r)) goto eob; + idx++; + dict_str = tabref(sbx->dict_str); + if (dict_str && idx < dict_str->asize && tvisstr(arrayslot(dict_str, idx))) + copyTV(sbufL(sbx), o, arrayslot(dict_str, idx)); + else + lj_err_callerv(sbufL(sbx), LJ_ERR_BUFFER_BADDICTX, idx); + } else if (tp >= SER_TAG_TAB && tp <= SER_TAG_DICT_MT) { + uint32_t narray = 0, nhash = 0; + GCtab *t, *mt = NULL; + if (sbx->depth <= 0) lj_err_caller(sbufL(sbx), LJ_ERR_BUFFER_DEPTH); + sbx->depth--; + if (tp == SER_TAG_DICT_MT) { + GCtab *dict_mt; + uint32_t idx; + r = serialize_ru124(r, w, &idx); if (LJ_UNLIKELY(!r)) goto eob; + idx++; + dict_mt = tabref(sbx->dict_mt); + if (dict_mt && idx < dict_mt->asize && tvistab(arrayslot(dict_mt, idx))) + mt = tabV(arrayslot(dict_mt, idx)); + else + lj_err_callerv(sbufL(sbx), LJ_ERR_BUFFER_BADDICTX, idx); + r = serialize_ru124(r, w, &tp); if (LJ_UNLIKELY(!r)) goto eob; + if (!(tp >= SER_TAG_TAB && tp < SER_TAG_DICT_MT)) goto badtag; + } + if (tp >= SER_TAG_TAB+2) { + r = serialize_ru124(r, w, &narray); if (LJ_UNLIKELY(!r)) goto eob; + } + if ((tp & 1)) { + r = serialize_ru124(r, w, &nhash); if (LJ_UNLIKELY(!r)) goto eob; + } + t = lj_tab_new(sbufL(sbx), narray, hsize2hbits(nhash)); + /* NOBARRIER: The table is new (marked white). */ + setgcref(t->metatable, obj2gco(mt)); + settabV(sbufL(sbx), o, t); + if (narray) { + TValue *oa = tvref(t->array) + (tp >= SER_TAG_TAB+4); + TValue *oe = tvref(t->array) + narray; + while (oa < oe) r = serialize_get(r, sbx, oa++); + } + if (nhash) { + do { + TValue k, *v; + r = serialize_get(r, sbx, &k); + v = lj_tab_set(sbufL(sbx), t, &k); + if (LJ_UNLIKELY(!tvisnil(v))) + lj_err_caller(sbufL(sbx), LJ_ERR_BUFFER_DUPKEY); + r = serialize_get(r, sbx, v); + } while (--nhash); + } + sbx->depth++; +#if LJ_HASFFI + } else if (tp >= SER_TAG_INT64 && tp <= SER_TAG_COMPLEX) { + uint32_t sz = tp == SER_TAG_COMPLEX ? 16 : 8; + GCcdata *cd; + if (LJ_UNLIKELY(r + sz > w)) goto eob; + if (LJ_UNLIKELY(!ctype_ctsG(G(sbufL(sbx))))) goto badtag; + cd = lj_cdata_new_(sbufL(sbx), + tp == SER_TAG_INT64 ? CTID_INT64 : + tp == SER_TAG_UINT64 ? CTID_UINT64 : CTID_COMPLEX_DOUBLE, + sz); + memcpy(cdataptr(cd), r, sz); r += sz; +#if LJ_BE + *(uint64_t *)cdataptr(cd) = lj_bswap64(*(uint64_t *)cdataptr(cd)); + if (sz == 16) + ((uint64_t *)cdataptr(cd))[1] = lj_bswap64(((uint64_t *)cdataptr(cd))[1]); +#endif + if (sz == 16) { /* Fix non-canonical NaNs. */ + TValue *cdo = (TValue *)cdataptr(cd); + if (!tvisnum(&cdo[0])) setnanV(&cdo[0]); + if (!tvisnum(&cdo[1])) setnanV(&cdo[1]); + } + setcdataV(sbufL(sbx), o, cd); +#endif + } else if (tp <= (LJ_64 ? SER_TAG_LIGHTUD64 : SER_TAG_LIGHTUD32)) { + uintptr_t ud = 0; + if (tp == SER_TAG_LIGHTUD32) { + if (LJ_UNLIKELY(r + 4 > w)) goto eob; + ud = (uintptr_t)(LJ_BE ? lj_bswap(lj_getu32(r)) : lj_getu32(r)); + r += 4; + } +#if LJ_64 + else if (tp == SER_TAG_LIGHTUD64) { + if (LJ_UNLIKELY(r + 8 > w)) goto eob; + memcpy(&ud, r, 8); r += 8; +#if LJ_BE + ud = lj_bswap64(ud); +#endif + } + setrawlightudV(o, lj_lightud_intern(sbufL(sbx), (void *)ud)); +#else + setrawlightudV(o, (void *)ud); +#endif + } else { +badtag: + lj_err_callerv(sbufL(sbx), LJ_ERR_BUFFER_BADDEC, tp); + } + return r; +eob: + lj_err_caller(sbufL(sbx), LJ_ERR_BUFFER_EOB); + return NULL; +} + +/* -- External serialization API ------------------------------------------ */ + +/* Encode to buffer. */ +SBufExt * LJ_FASTCALL lj_serialize_put(SBufExt *sbx, cTValue *o) +{ + sbx->depth = LJ_SERIALIZE_DEPTH; + sbx->w = serialize_put(sbx->w, sbx, o); + return sbx; +} + +/* Decode from buffer. */ +char * LJ_FASTCALL lj_serialize_get(SBufExt *sbx, TValue *o) +{ + sbx->depth = LJ_SERIALIZE_DEPTH; + return serialize_get(sbx->r, sbx, o); +} + +/* Stand-alone encoding, borrowing from global temporary buffer. */ +GCstr * LJ_FASTCALL lj_serialize_encode(lua_State *L, cTValue *o) +{ + SBufExt sbx; + char *w; + memset(&sbx, 0, sizeof(SBufExt)); + lj_bufx_set_borrow(L, &sbx, &G(L)->tmpbuf); + sbx.depth = LJ_SERIALIZE_DEPTH; + w = serialize_put(sbx.w, &sbx, o); + return lj_str_new(L, sbx.b, (size_t)(w - sbx.b)); +} + +/* Stand-alone decoding, copy-on-write from string. */ +void lj_serialize_decode(lua_State *L, TValue *o, GCstr *str) +{ + SBufExt sbx; + char *r; + memset(&sbx, 0, sizeof(SBufExt)); + lj_bufx_set_cow(L, &sbx, strdata(str), str->len); + /* No need to set sbx.cowref here. */ + sbx.depth = LJ_SERIALIZE_DEPTH; + r = serialize_get(sbx.r, &sbx, o); + if (r != sbx.w) lj_err_caller(L, LJ_ERR_BUFFER_LEFTOV); +} + +#if LJ_HASJIT +/* Peek into buffer to find the result IRType for specialization purposes. */ +LJ_FUNC MSize LJ_FASTCALL lj_serialize_peektype(SBufExt *sbx) +{ + uint32_t tp; + if (serialize_ru124(sbx->r, sbx->w, &tp)) { + /* This must match the handling of all tags in the decoder above. */ + switch (tp) { + case SER_TAG_NIL: return IRT_NIL; + case SER_TAG_FALSE: return IRT_FALSE; + case SER_TAG_TRUE: return IRT_TRUE; + case SER_TAG_NULL: case SER_TAG_LIGHTUD32: case SER_TAG_LIGHTUD64: + return IRT_LIGHTUD; + case SER_TAG_INT: return LJ_DUALNUM ? IRT_INT : IRT_NUM; + case SER_TAG_NUM: return IRT_NUM; + case SER_TAG_TAB: case SER_TAG_TAB+1: case SER_TAG_TAB+2: + case SER_TAG_TAB+3: case SER_TAG_TAB+4: case SER_TAG_TAB+5: + case SER_TAG_DICT_MT: + return IRT_TAB; + case SER_TAG_INT64: case SER_TAG_UINT64: case SER_TAG_COMPLEX: + return IRT_CDATA; + case SER_TAG_DICT_STR: + default: + return IRT_STR; + } + } + return IRT_NIL; /* Will fail on actual decode. */ +} +#endif + +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_serialize.h b/fluent-bit/lib/luajit-3065c9/src/lj_serialize.h new file mode 100644 index 00000000..d3f4275a --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_serialize.h @@ -0,0 +1,28 @@ +/* +** Object de/serialization. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#ifndef _LJ_SERIALIZE_H +#define _LJ_SERIALIZE_H + +#include "lj_obj.h" +#include "lj_buf.h" + +#if LJ_HASBUFFER + +#define LJ_SERIALIZE_DEPTH 100 /* Default depth. */ + +LJ_FUNC void LJ_FASTCALL lj_serialize_dict_prep_str(lua_State *L, GCtab *dict); +LJ_FUNC void LJ_FASTCALL lj_serialize_dict_prep_mt(lua_State *L, GCtab *dict); +LJ_FUNC SBufExt * LJ_FASTCALL lj_serialize_put(SBufExt *sbx, cTValue *o); +LJ_FUNC char * LJ_FASTCALL lj_serialize_get(SBufExt *sbx, TValue *o); +LJ_FUNC GCstr * LJ_FASTCALL lj_serialize_encode(lua_State *L, cTValue *o); +LJ_FUNC void lj_serialize_decode(lua_State *L, TValue *o, GCstr *str); +#if LJ_HASJIT +LJ_FUNC MSize LJ_FASTCALL lj_serialize_peektype(SBufExt *sbx); +#endif + +#endif + +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_snap.c b/fluent-bit/lib/luajit-3065c9/src/lj_snap.c new file mode 100644 index 00000000..4140fdb7 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_snap.c @@ -0,0 +1,996 @@ +/* +** Snapshot handling. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#define lj_snap_c +#define LUA_CORE + +#include "lj_obj.h" + +#if LJ_HASJIT + +#include "lj_gc.h" +#include "lj_tab.h" +#include "lj_state.h" +#include "lj_frame.h" +#include "lj_bc.h" +#include "lj_ir.h" +#include "lj_jit.h" +#include "lj_iropt.h" +#include "lj_trace.h" +#include "lj_snap.h" +#include "lj_target.h" +#if LJ_HASFFI +#include "lj_ctype.h" +#include "lj_cdata.h" +#endif + +/* Pass IR on to next optimization in chain (FOLD). */ +#define emitir(ot, a, b) (lj_ir_set(J, (ot), (a), (b)), lj_opt_fold(J)) + +/* Emit raw IR without passing through optimizations. */ +#define emitir_raw(ot, a, b) (lj_ir_set(J, (ot), (a), (b)), lj_ir_emit(J)) + +/* -- Snapshot buffer allocation ------------------------------------------ */ + +/* Grow snapshot buffer. */ +void lj_snap_grow_buf_(jit_State *J, MSize need) +{ + MSize maxsnap = (MSize)J->param[JIT_P_maxsnap]; + if (need > maxsnap) + lj_trace_err(J, LJ_TRERR_SNAPOV); + lj_mem_growvec(J->L, J->snapbuf, J->sizesnap, maxsnap, SnapShot); + J->cur.snap = J->snapbuf; +} + +/* Grow snapshot map buffer. */ +void lj_snap_grow_map_(jit_State *J, MSize need) +{ + if (need < 2*J->sizesnapmap) + need = 2*J->sizesnapmap; + else if (need < 64) + need = 64; + J->snapmapbuf = (SnapEntry *)lj_mem_realloc(J->L, J->snapmapbuf, + J->sizesnapmap*sizeof(SnapEntry), need*sizeof(SnapEntry)); + J->cur.snapmap = J->snapmapbuf; + J->sizesnapmap = need; +} + +/* -- Snapshot generation ------------------------------------------------- */ + +/* Add all modified slots to the snapshot. */ +static MSize snapshot_slots(jit_State *J, SnapEntry *map, BCReg nslots) +{ + IRRef retf = J->chain[IR_RETF]; /* Limits SLOAD restore elimination. */ + BCReg s; + MSize n = 0; + for (s = 0; s < nslots; s++) { + TRef tr = J->slot[s]; + IRRef ref = tref_ref(tr); +#if LJ_FR2 + if (s == 1) { /* Ignore slot 1 in LJ_FR2 mode, except if tailcalled. */ + if ((tr & TREF_FRAME)) + map[n++] = SNAP(1, SNAP_FRAME | SNAP_NORESTORE, REF_NIL); + continue; + } + if ((tr & (TREF_FRAME | TREF_CONT)) && !ref) { + cTValue *base = J->L->base - J->baseslot; + tr = J->slot[s] = (tr & 0xff0000) | lj_ir_k64(J, IR_KNUM, base[s].u64); + ref = tref_ref(tr); + } +#endif + if (ref) { + SnapEntry sn = SNAP_TR(s, tr); + IRIns *ir = &J->cur.ir[ref]; + if ((LJ_FR2 || !(sn & (SNAP_CONT|SNAP_FRAME))) && + ir->o == IR_SLOAD && ir->op1 == s && ref > retf) { + /* + ** No need to snapshot unmodified non-inherited slots. + ** But always snapshot the function below a frame in LJ_FR2 mode. + */ + if (!(ir->op2 & IRSLOAD_INHERIT) && + (!LJ_FR2 || s == 0 || s+1 == nslots || + !(J->slot[s+1] & (TREF_CONT|TREF_FRAME)))) + continue; + /* No need to restore readonly slots and unmodified non-parent slots. */ + if (!(LJ_DUALNUM && (ir->op2 & IRSLOAD_CONVERT)) && + (ir->op2 & (IRSLOAD_READONLY|IRSLOAD_PARENT)) != IRSLOAD_PARENT) + sn |= SNAP_NORESTORE; + } + if (LJ_SOFTFP32 && irt_isnum(ir->t)) + sn |= SNAP_SOFTFPNUM; + map[n++] = sn; + } + } + return n; +} + +/* Add frame links at the end of the snapshot. */ +static MSize snapshot_framelinks(jit_State *J, SnapEntry *map, uint8_t *topslot) +{ + cTValue *frame = J->L->base - 1; + cTValue *lim = J->L->base - J->baseslot + LJ_FR2; + GCfunc *fn = frame_func(frame); + cTValue *ftop = isluafunc(fn) ? (frame+funcproto(fn)->framesize) : J->L->top; +#if LJ_FR2 + uint64_t pcbase = (u64ptr(J->pc) << 8) | (J->baseslot - 2); + lj_assertJ(2 <= J->baseslot && J->baseslot <= 257, "bad baseslot"); + memcpy(map, &pcbase, sizeof(uint64_t)); +#else + MSize f = 0; + map[f++] = SNAP_MKPC(J->pc); /* The current PC is always the first entry. */ +#endif + lj_assertJ(!J->pt || + (J->pc >= proto_bc(J->pt) && + J->pc < proto_bc(J->pt) + J->pt->sizebc), "bad snapshot PC"); + while (frame > lim) { /* Backwards traversal of all frames above base. */ + if (frame_islua(frame)) { +#if !LJ_FR2 + map[f++] = SNAP_MKPC(frame_pc(frame)); +#endif + frame = frame_prevl(frame); + } else if (frame_iscont(frame)) { +#if !LJ_FR2 + map[f++] = SNAP_MKFTSZ(frame_ftsz(frame)); + map[f++] = SNAP_MKPC(frame_contpc(frame)); +#endif + frame = frame_prevd(frame); + } else { + lj_assertJ(!frame_isc(frame), "broken frame chain"); +#if !LJ_FR2 + map[f++] = SNAP_MKFTSZ(frame_ftsz(frame)); +#endif + frame = frame_prevd(frame); + continue; + } + if (frame + funcproto(frame_func(frame))->framesize > ftop) + ftop = frame + funcproto(frame_func(frame))->framesize; + } + *topslot = (uint8_t)(ftop - lim); +#if LJ_FR2 + lj_assertJ(sizeof(SnapEntry) * 2 == sizeof(uint64_t), "bad SnapEntry def"); + return 2; +#else + lj_assertJ(f == (MSize)(1 + J->framedepth), "miscalculated snapshot size"); + return f; +#endif +} + +/* Take a snapshot of the current stack. */ +static void snapshot_stack(jit_State *J, SnapShot *snap, MSize nsnapmap) +{ + BCReg nslots = J->baseslot + J->maxslot; + MSize nent; + SnapEntry *p; + /* Conservative estimate. */ + lj_snap_grow_map(J, nsnapmap + nslots + (MSize)(LJ_FR2?2:J->framedepth+1)); + p = &J->cur.snapmap[nsnapmap]; + nent = snapshot_slots(J, p, nslots); + snap->nent = (uint8_t)nent; + nent += snapshot_framelinks(J, p + nent, &snap->topslot); + snap->mapofs = (uint32_t)nsnapmap; + snap->ref = (IRRef1)J->cur.nins; + snap->mcofs = 0; + snap->nslots = (uint8_t)nslots; + snap->count = 0; + J->cur.nsnapmap = (uint32_t)(nsnapmap + nent); +} + +/* Add or merge a snapshot. */ +void lj_snap_add(jit_State *J) +{ + MSize nsnap = J->cur.nsnap; + MSize nsnapmap = J->cur.nsnapmap; + /* Merge if no ins. inbetween or if requested and no guard inbetween. */ + if ((nsnap > 0 && J->cur.snap[nsnap-1].ref == J->cur.nins) || + (J->mergesnap && !irt_isguard(J->guardemit))) { + if (nsnap == 1) { /* But preserve snap #0 PC. */ + emitir_raw(IRT(IR_NOP, IRT_NIL), 0, 0); + goto nomerge; + } + nsnapmap = J->cur.snap[--nsnap].mapofs; + } else { + nomerge: + lj_snap_grow_buf(J, nsnap+1); + J->cur.nsnap = (uint16_t)(nsnap+1); + } + J->mergesnap = 0; + J->guardemit.irt = 0; + snapshot_stack(J, &J->cur.snap[nsnap], nsnapmap); +} + +/* -- Snapshot modification ----------------------------------------------- */ + +#define SNAP_USEDEF_SLOTS (LJ_MAX_JSLOTS+LJ_STACK_EXTRA) + +/* Find unused slots with reaching-definitions bytecode data-flow analysis. */ +static BCReg snap_usedef(jit_State *J, uint8_t *udf, + const BCIns *pc, BCReg maxslot) +{ + BCReg s; + GCobj *o; + + if (maxslot == 0) return 0; +#ifdef LUAJIT_USE_VALGRIND + /* Avoid errors for harmless reads beyond maxslot. */ + memset(udf, 1, SNAP_USEDEF_SLOTS); +#else + memset(udf, 1, maxslot); +#endif + + /* Treat open upvalues as used. */ + o = gcref(J->L->openupval); + while (o) { + if (uvval(gco2uv(o)) < J->L->base) break; + udf[uvval(gco2uv(o)) - J->L->base] = 0; + o = gcref(o->gch.nextgc); + } + +#define USE_SLOT(s) udf[(s)] &= ~1 +#define DEF_SLOT(s) udf[(s)] *= 3 + + /* Scan through following bytecode and check for uses/defs. */ + lj_assertJ(pc >= proto_bc(J->pt) && pc < proto_bc(J->pt) + J->pt->sizebc, + "snapshot PC out of range"); + for (;;) { + BCIns ins = *pc++; + BCOp op = bc_op(ins); + switch (bcmode_b(op)) { + case BCMvar: USE_SLOT(bc_b(ins)); break; + default: break; + } + switch (bcmode_c(op)) { + case BCMvar: USE_SLOT(bc_c(ins)); break; + case BCMrbase: + lj_assertJ(op == BC_CAT, "unhandled op %d with RC rbase", op); + for (s = bc_b(ins); s <= bc_c(ins); s++) USE_SLOT(s); + for (; s < maxslot; s++) DEF_SLOT(s); + break; + case BCMjump: + handle_jump: { + BCReg minslot = bc_a(ins); + if (op >= BC_FORI && op <= BC_JFORL) minslot += FORL_EXT; + else if (op >= BC_ITERL && op <= BC_JITERL) minslot += bc_b(pc[-2])-1; + else if (op == BC_UCLO) { + ptrdiff_t delta = bc_j(ins); + if (delta < 0) return maxslot; /* Prevent loop. */ + pc += delta; + break; + } + for (s = minslot; s < maxslot; s++) DEF_SLOT(s); + return minslot < maxslot ? minslot : maxslot; + } + case BCMlit: + if (op == BC_JFORL || op == BC_JITERL || op == BC_JLOOP) { + goto handle_jump; + } else if (bc_isret(op)) { + BCReg top = op == BC_RETM ? maxslot : (bc_a(ins) + bc_d(ins)-1); + for (s = 0; s < bc_a(ins); s++) DEF_SLOT(s); + for (; s < top; s++) USE_SLOT(s); + for (; s < maxslot; s++) DEF_SLOT(s); + return 0; + } + break; + case BCMfunc: return maxslot; /* NYI: will abort, anyway. */ + default: break; + } + switch (bcmode_a(op)) { + case BCMvar: USE_SLOT(bc_a(ins)); break; + case BCMdst: + if (!(op == BC_ISTC || op == BC_ISFC)) DEF_SLOT(bc_a(ins)); + break; + case BCMbase: + if (op >= BC_CALLM && op <= BC_ITERN) { + BCReg top = (op == BC_CALLM || op == BC_CALLMT || bc_c(ins) == 0) ? + maxslot : (bc_a(ins) + bc_c(ins)+LJ_FR2); + if (LJ_FR2) DEF_SLOT(bc_a(ins)+1); + s = bc_a(ins) - ((op == BC_ITERC || op == BC_ITERN) ? 3 : 0); + for (; s < top; s++) USE_SLOT(s); + for (; s < maxslot; s++) DEF_SLOT(s); + if (op == BC_CALLT || op == BC_CALLMT) { + for (s = 0; s < bc_a(ins); s++) DEF_SLOT(s); + return 0; + } + } else if (op == BC_VARG) { + return maxslot; /* NYI: punt. */ + } else if (op == BC_KNIL) { + for (s = bc_a(ins); s <= bc_d(ins); s++) DEF_SLOT(s); + } else if (op == BC_TSETM) { + for (s = bc_a(ins)-1; s < maxslot; s++) USE_SLOT(s); + } + break; + default: break; + } + lj_assertJ(pc >= proto_bc(J->pt) && pc < proto_bc(J->pt) + J->pt->sizebc, + "use/def analysis PC out of range"); + } + +#undef USE_SLOT +#undef DEF_SLOT + + return 0; /* unreachable */ +} + +/* Mark slots used by upvalues of child prototypes as used. */ +static void snap_useuv(GCproto *pt, uint8_t *udf) +{ + /* This is a coarse check, because it's difficult to correlate the lifetime + ** of slots and closures. But the number of false positives is quite low. + ** A false positive may cause a slot not to be purged, which is just + ** a missed optimization. + */ + if ((pt->flags & PROTO_CHILD)) { + ptrdiff_t i, j, n = pt->sizekgc; + GCRef *kr = mref(pt->k, GCRef) - 1; + for (i = 0; i < n; i++, kr--) { + GCobj *o = gcref(*kr); + if (o->gch.gct == ~LJ_TPROTO) { + for (j = 0; j < gco2pt(o)->sizeuv; j++) { + uint32_t v = proto_uv(gco2pt(o))[j]; + if ((v & PROTO_UV_LOCAL)) { + udf[(v & 0xff)] = 0; + } + } + } + } + } +} + +/* Purge dead slots before the next snapshot. */ +void lj_snap_purge(jit_State *J) +{ + uint8_t udf[SNAP_USEDEF_SLOTS]; + BCReg s, maxslot = J->maxslot; + if (bc_op(*J->pc) == BC_FUNCV && maxslot > J->pt->numparams) + maxslot = J->pt->numparams; + s = snap_usedef(J, udf, J->pc, maxslot); + if (s < maxslot) { + snap_useuv(J->pt, udf); + for (; s < maxslot; s++) + if (udf[s] != 0) + J->base[s] = 0; /* Purge dead slots. */ + } +} + +/* Shrink last snapshot. */ +void lj_snap_shrink(jit_State *J) +{ + SnapShot *snap = &J->cur.snap[J->cur.nsnap-1]; + SnapEntry *map = &J->cur.snapmap[snap->mapofs]; + MSize n, m, nlim, nent = snap->nent; + uint8_t udf[SNAP_USEDEF_SLOTS]; + BCReg maxslot = J->maxslot; + BCReg baseslot = J->baseslot; + BCReg minslot = snap_usedef(J, udf, snap_pc(&map[nent]), maxslot); + if (minslot < maxslot) snap_useuv(J->pt, udf); + maxslot += baseslot; + minslot += baseslot; + snap->nslots = (uint8_t)maxslot; + for (n = m = 0; n < nent; n++) { /* Remove unused slots from snapshot. */ + BCReg s = snap_slot(map[n]); + if (s < minslot || (s < maxslot && udf[s-baseslot] == 0)) + map[m++] = map[n]; /* Only copy used slots. */ + } + snap->nent = (uint8_t)m; + nlim = J->cur.nsnapmap - snap->mapofs - 1; + while (n <= nlim) map[m++] = map[n++]; /* Move PC + frame links down. */ + J->cur.nsnapmap = (uint32_t)(snap->mapofs + m); /* Free up space in map. */ +} + +/* -- Snapshot access ----------------------------------------------------- */ + +/* Initialize a Bloom Filter with all renamed refs. +** There are very few renames (often none), so the filter has +** very few bits set. This makes it suitable for negative filtering. +*/ +static BloomFilter snap_renamefilter(GCtrace *T, SnapNo lim) +{ + BloomFilter rfilt = 0; + IRIns *ir; + for (ir = &T->ir[T->nins-1]; ir->o == IR_RENAME; ir--) + if (ir->op2 <= lim) + bloomset(rfilt, ir->op1); + return rfilt; +} + +/* Process matching renames to find the original RegSP. */ +static RegSP snap_renameref(GCtrace *T, SnapNo lim, IRRef ref, RegSP rs) +{ + IRIns *ir; + for (ir = &T->ir[T->nins-1]; ir->o == IR_RENAME; ir--) + if (ir->op1 == ref && ir->op2 <= lim) + rs = ir->prev; + return rs; +} + +/* Copy RegSP from parent snapshot to the parent links of the IR. */ +IRIns *lj_snap_regspmap(jit_State *J, GCtrace *T, SnapNo snapno, IRIns *ir) +{ + SnapShot *snap = &T->snap[snapno]; + SnapEntry *map = &T->snapmap[snap->mapofs]; + BloomFilter rfilt = snap_renamefilter(T, snapno); + MSize n = 0; + IRRef ref = 0; + UNUSED(J); + for ( ; ; ir++) { + uint32_t rs; + if (ir->o == IR_SLOAD) { + if (!(ir->op2 & IRSLOAD_PARENT)) break; + for ( ; ; n++) { + lj_assertJ(n < snap->nent, "slot %d not found in snapshot", ir->op1); + if (snap_slot(map[n]) == ir->op1) { + ref = snap_ref(map[n++]); + break; + } + } + } else if (LJ_SOFTFP32 && ir->o == IR_HIOP) { + ref++; + } else if (ir->o == IR_PVAL) { + ref = ir->op1 + REF_BIAS; + } else { + break; + } + rs = T->ir[ref].prev; + if (bloomtest(rfilt, ref)) + rs = snap_renameref(T, snapno, ref, rs); + ir->prev = (uint16_t)rs; + lj_assertJ(regsp_used(rs), "unused IR %04d in snapshot", ref - REF_BIAS); + } + return ir; +} + +/* -- Snapshot replay ----------------------------------------------------- */ + +/* Replay constant from parent trace. */ +static TRef snap_replay_const(jit_State *J, IRIns *ir) +{ + /* Only have to deal with constants that can occur in stack slots. */ + switch ((IROp)ir->o) { + case IR_KPRI: return TREF_PRI(irt_type(ir->t)); + case IR_KINT: return lj_ir_kint(J, ir->i); + case IR_KGC: return lj_ir_kgc(J, ir_kgc(ir), irt_t(ir->t)); + case IR_KNUM: case IR_KINT64: + return lj_ir_k64(J, (IROp)ir->o, ir_k64(ir)->u64); + case IR_KPTR: return lj_ir_kptr(J, ir_kptr(ir)); /* Continuation. */ + default: lj_assertJ(0, "bad IR constant op %d", ir->o); return TREF_NIL; + } +} + +/* De-duplicate parent reference. */ +static TRef snap_dedup(jit_State *J, SnapEntry *map, MSize nmax, IRRef ref) +{ + MSize j; + for (j = 0; j < nmax; j++) + if (snap_ref(map[j]) == ref) + return J->slot[snap_slot(map[j])] & ~(SNAP_KEYINDEX|SNAP_CONT|SNAP_FRAME); + return 0; +} + +/* Emit parent reference with de-duplication. */ +static TRef snap_pref(jit_State *J, GCtrace *T, SnapEntry *map, MSize nmax, + BloomFilter seen, IRRef ref) +{ + IRIns *ir = &T->ir[ref]; + TRef tr; + if (irref_isk(ref)) + tr = snap_replay_const(J, ir); + else if (!regsp_used(ir->prev)) + tr = 0; + else if (!bloomtest(seen, ref) || (tr = snap_dedup(J, map, nmax, ref)) == 0) + tr = emitir(IRT(IR_PVAL, irt_type(ir->t)), ref - REF_BIAS, 0); + return tr; +} + +/* Check whether a sunk store corresponds to an allocation. Slow path. */ +static int snap_sunk_store2(GCtrace *T, IRIns *ira, IRIns *irs) +{ + if (irs->o == IR_ASTORE || irs->o == IR_HSTORE || + irs->o == IR_FSTORE || irs->o == IR_XSTORE) { + IRIns *irk = &T->ir[irs->op1]; + if (irk->o == IR_AREF || irk->o == IR_HREFK) + irk = &T->ir[irk->op1]; + return (&T->ir[irk->op1] == ira); + } + return 0; +} + +/* Check whether a sunk store corresponds to an allocation. Fast path. */ +static LJ_AINLINE int snap_sunk_store(GCtrace *T, IRIns *ira, IRIns *irs) +{ + if (irs->s != 255) + return (ira + irs->s == irs); /* Fast check. */ + return snap_sunk_store2(T, ira, irs); +} + +/* Replay snapshot state to setup side trace. */ +void lj_snap_replay(jit_State *J, GCtrace *T) +{ + SnapShot *snap = &T->snap[J->exitno]; + SnapEntry *map = &T->snapmap[snap->mapofs]; + MSize n, nent = snap->nent; + BloomFilter seen = 0; + int pass23 = 0; + J->framedepth = 0; + /* Emit IR for slots inherited from parent snapshot. */ + for (n = 0; n < nent; n++) { + SnapEntry sn = map[n]; + BCReg s = snap_slot(sn); + IRRef ref = snap_ref(sn); + IRIns *ir = &T->ir[ref]; + TRef tr; + /* The bloom filter avoids O(nent^2) overhead for de-duping slots. */ + if (bloomtest(seen, ref) && (tr = snap_dedup(J, map, n, ref)) != 0) + goto setslot; + bloomset(seen, ref); + if (irref_isk(ref)) { + /* See special treatment of LJ_FR2 slot 1 in snapshot_slots() above. */ + if (LJ_FR2 && (sn == SNAP(1, SNAP_FRAME | SNAP_NORESTORE, REF_NIL))) + tr = 0; + else + tr = snap_replay_const(J, ir); + } else if (!regsp_used(ir->prev)) { + pass23 = 1; + lj_assertJ(s != 0, "unused slot 0 in snapshot"); + tr = s; + } else { + IRType t = irt_type(ir->t); + uint32_t mode = IRSLOAD_INHERIT|IRSLOAD_PARENT; + if (LJ_SOFTFP32 && (sn & SNAP_SOFTFPNUM)) t = IRT_NUM; + if (ir->o == IR_SLOAD) mode |= (ir->op2 & IRSLOAD_READONLY); + if ((sn & SNAP_KEYINDEX)) mode |= IRSLOAD_KEYINDEX; + tr = emitir_raw(IRT(IR_SLOAD, t), s, mode); + } + setslot: + /* Same as TREF_* flags. */ + J->slot[s] = tr | (sn&(SNAP_KEYINDEX|SNAP_CONT|SNAP_FRAME)); + J->framedepth += ((sn & (SNAP_CONT|SNAP_FRAME)) && (s != LJ_FR2)); + if ((sn & SNAP_FRAME)) + J->baseslot = s+1; + } + if (pass23) { + IRIns *irlast = &T->ir[snap->ref]; + pass23 = 0; + /* Emit dependent PVALs. */ + for (n = 0; n < nent; n++) { + SnapEntry sn = map[n]; + IRRef refp = snap_ref(sn); + IRIns *ir = &T->ir[refp]; + if (regsp_reg(ir->r) == RID_SUNK) { + if (J->slot[snap_slot(sn)] != snap_slot(sn)) continue; + pass23 = 1; + lj_assertJ(ir->o == IR_TNEW || ir->o == IR_TDUP || + ir->o == IR_CNEW || ir->o == IR_CNEWI, + "sunk parent IR %04d has bad op %d", refp - REF_BIAS, ir->o); + if (ir->op1 >= T->nk) snap_pref(J, T, map, nent, seen, ir->op1); + if (ir->op2 >= T->nk) snap_pref(J, T, map, nent, seen, ir->op2); + if (LJ_HASFFI && ir->o == IR_CNEWI) { + if (LJ_32 && refp+1 < T->nins && (ir+1)->o == IR_HIOP) + snap_pref(J, T, map, nent, seen, (ir+1)->op2); + } else { + IRIns *irs; + for (irs = ir+1; irs < irlast; irs++) + if (irs->r == RID_SINK && snap_sunk_store(T, ir, irs)) { + if (snap_pref(J, T, map, nent, seen, irs->op2) == 0) + snap_pref(J, T, map, nent, seen, T->ir[irs->op2].op1); + else if ((LJ_SOFTFP32 || (LJ_32 && LJ_HASFFI)) && + irs+1 < irlast && (irs+1)->o == IR_HIOP) + snap_pref(J, T, map, nent, seen, (irs+1)->op2); + } + } + } else if (!irref_isk(refp) && !regsp_used(ir->prev)) { + lj_assertJ(ir->o == IR_CONV && ir->op2 == IRCONV_NUM_INT, + "sunk parent IR %04d has bad op %d", refp - REF_BIAS, ir->o); + J->slot[snap_slot(sn)] = snap_pref(J, T, map, nent, seen, ir->op1); + } + } + /* Replay sunk instructions. */ + for (n = 0; pass23 && n < nent; n++) { + SnapEntry sn = map[n]; + IRRef refp = snap_ref(sn); + IRIns *ir = &T->ir[refp]; + if (regsp_reg(ir->r) == RID_SUNK) { + TRef op1, op2; + if (J->slot[snap_slot(sn)] != snap_slot(sn)) { /* De-dup allocs. */ + J->slot[snap_slot(sn)] = J->slot[J->slot[snap_slot(sn)]]; + continue; + } + op1 = ir->op1; + if (op1 >= T->nk) op1 = snap_pref(J, T, map, nent, seen, op1); + op2 = ir->op2; + if (op2 >= T->nk) op2 = snap_pref(J, T, map, nent, seen, op2); + if (LJ_HASFFI && ir->o == IR_CNEWI) { + if (LJ_32 && refp+1 < T->nins && (ir+1)->o == IR_HIOP) { + lj_needsplit(J); /* Emit joining HIOP. */ + op2 = emitir_raw(IRT(IR_HIOP, IRT_I64), op2, + snap_pref(J, T, map, nent, seen, (ir+1)->op2)); + } + J->slot[snap_slot(sn)] = emitir(ir->ot & ~(IRT_MARK|IRT_ISPHI), op1, op2); + } else { + IRIns *irs; + TRef tr = emitir(ir->ot, op1, op2); + J->slot[snap_slot(sn)] = tr; + for (irs = ir+1; irs < irlast; irs++) + if (irs->r == RID_SINK && snap_sunk_store(T, ir, irs)) { + IRIns *irr = &T->ir[irs->op1]; + TRef val, key = irr->op2, tmp = tr; + if (irr->o != IR_FREF) { + IRIns *irk = &T->ir[key]; + if (irr->o == IR_HREFK) + key = lj_ir_kslot(J, snap_replay_const(J, &T->ir[irk->op1]), + irk->op2); + else + key = snap_replay_const(J, irk); + if (irr->o == IR_HREFK || irr->o == IR_AREF) { + IRIns *irf = &T->ir[irr->op1]; + tmp = emitir(irf->ot, tmp, irf->op2); + } + } + tmp = emitir(irr->ot, tmp, key); + val = snap_pref(J, T, map, nent, seen, irs->op2); + if (val == 0) { + IRIns *irc = &T->ir[irs->op2]; + lj_assertJ(irc->o == IR_CONV && irc->op2 == IRCONV_NUM_INT, + "sunk store for parent IR %04d with bad op %d", + refp - REF_BIAS, irc->o); + val = snap_pref(J, T, map, nent, seen, irc->op1); + val = emitir(IRTN(IR_CONV), val, IRCONV_NUM_INT); + } else if ((LJ_SOFTFP32 || (LJ_32 && LJ_HASFFI)) && + irs+1 < irlast && (irs+1)->o == IR_HIOP) { + IRType t = IRT_I64; + if (LJ_SOFTFP32 && irt_type((irs+1)->t) == IRT_SOFTFP) + t = IRT_NUM; + lj_needsplit(J); + if (irref_isk(irs->op2) && irref_isk((irs+1)->op2)) { + uint64_t k = (uint32_t)T->ir[irs->op2].i + + ((uint64_t)T->ir[(irs+1)->op2].i << 32); + val = lj_ir_k64(J, t == IRT_I64 ? IR_KINT64 : IR_KNUM, k); + } else { + val = emitir_raw(IRT(IR_HIOP, t), val, + snap_pref(J, T, map, nent, seen, (irs+1)->op2)); + } + tmp = emitir(IRT(irs->o, t), tmp, val); + continue; + } + tmp = emitir(irs->ot, tmp, val); + } else if (LJ_HASFFI && irs->o == IR_XBAR && ir->o == IR_CNEW) { + emitir(IRT(IR_XBAR, IRT_NIL), 0, 0); + } + } + } + } + } + J->base = J->slot + J->baseslot; + J->maxslot = snap->nslots - J->baseslot; + lj_snap_add(J); + if (pass23) /* Need explicit GC step _after_ initial snapshot. */ + emitir_raw(IRTG(IR_GCSTEP, IRT_NIL), 0, 0); +} + +/* -- Snapshot restore ---------------------------------------------------- */ + +static void snap_unsink(jit_State *J, GCtrace *T, ExitState *ex, + SnapNo snapno, BloomFilter rfilt, + IRIns *ir, TValue *o); + +/* Restore a value from the trace exit state. */ +static void snap_restoreval(jit_State *J, GCtrace *T, ExitState *ex, + SnapNo snapno, BloomFilter rfilt, + IRRef ref, TValue *o) +{ + IRIns *ir = &T->ir[ref]; + IRType1 t = ir->t; + RegSP rs = ir->prev; + if (irref_isk(ref)) { /* Restore constant slot. */ + if (ir->o == IR_KPTR) { + o->u64 = (uint64_t)(uintptr_t)ir_kptr(ir); + } else { + lj_assertJ(!(ir->o == IR_KKPTR || ir->o == IR_KNULL), + "restore of const from IR %04d with bad op %d", + ref - REF_BIAS, ir->o); + lj_ir_kvalue(J->L, o, ir); + } + return; + } + if (LJ_UNLIKELY(bloomtest(rfilt, ref))) + rs = snap_renameref(T, snapno, ref, rs); + if (ra_hasspill(regsp_spill(rs))) { /* Restore from spill slot. */ + int32_t *sps = &ex->spill[regsp_spill(rs)]; + if (irt_isinteger(t)) { + setintV(o, *sps); +#if !LJ_SOFTFP32 + } else if (irt_isnum(t)) { + o->u64 = *(uint64_t *)sps; +#endif +#if LJ_64 && !LJ_GC64 + } else if (irt_islightud(t)) { + /* 64 bit lightuserdata which may escape already has the tag bits. */ + o->u64 = *(uint64_t *)sps; +#endif + } else { + lj_assertJ(!irt_ispri(t), "PRI ref with spill slot"); + setgcV(J->L, o, (GCobj *)(uintptr_t)*(GCSize *)sps, irt_toitype(t)); + } + } else { /* Restore from register. */ + Reg r = regsp_reg(rs); + if (ra_noreg(r)) { + lj_assertJ(ir->o == IR_CONV && ir->op2 == IRCONV_NUM_INT, + "restore from IR %04d has no reg", ref - REF_BIAS); + snap_restoreval(J, T, ex, snapno, rfilt, ir->op1, o); + if (LJ_DUALNUM) setnumV(o, (lua_Number)intV(o)); + return; + } else if (irt_isinteger(t)) { + setintV(o, (int32_t)ex->gpr[r-RID_MIN_GPR]); +#if !LJ_SOFTFP + } else if (irt_isnum(t)) { + setnumV(o, ex->fpr[r-RID_MIN_FPR]); +#elif LJ_64 /* && LJ_SOFTFP */ + } else if (irt_isnum(t)) { + o->u64 = ex->gpr[r-RID_MIN_GPR]; +#endif +#if LJ_64 && !LJ_GC64 + } else if (irt_is64(t)) { + /* 64 bit values that already have the tag bits. */ + o->u64 = ex->gpr[r-RID_MIN_GPR]; +#endif + } else if (irt_ispri(t)) { + setpriV(o, irt_toitype(t)); + } else { + setgcV(J->L, o, (GCobj *)ex->gpr[r-RID_MIN_GPR], irt_toitype(t)); + } + } +} + +#if LJ_HASFFI +/* Restore raw data from the trace exit state. */ +static void snap_restoredata(jit_State *J, GCtrace *T, ExitState *ex, + SnapNo snapno, BloomFilter rfilt, + IRRef ref, void *dst, CTSize sz) +{ + IRIns *ir = &T->ir[ref]; + RegSP rs = ir->prev; + int32_t *src; + uint64_t tmp; + UNUSED(J); + if (irref_isk(ref)) { + if (ir_isk64(ir)) { + src = (int32_t *)&ir[1]; + } else if (sz == 8) { + tmp = (uint64_t)(uint32_t)ir->i; + src = (int32_t *)&tmp; + } else { + src = &ir->i; + } + } else { + if (LJ_UNLIKELY(bloomtest(rfilt, ref))) + rs = snap_renameref(T, snapno, ref, rs); + if (ra_hasspill(regsp_spill(rs))) { + src = &ex->spill[regsp_spill(rs)]; + if (sz == 8 && !irt_is64(ir->t)) { + tmp = (uint64_t)(uint32_t)*src; + src = (int32_t *)&tmp; + } + } else { + Reg r = regsp_reg(rs); + if (ra_noreg(r)) { + /* Note: this assumes CNEWI is never used for SOFTFP split numbers. */ + lj_assertJ(sz == 8 && ir->o == IR_CONV && ir->op2 == IRCONV_NUM_INT, + "restore from IR %04d has no reg", ref - REF_BIAS); + snap_restoredata(J, T, ex, snapno, rfilt, ir->op1, dst, 4); + *(lua_Number *)dst = (lua_Number)*(int32_t *)dst; + return; + } + src = (int32_t *)&ex->gpr[r-RID_MIN_GPR]; +#if !LJ_SOFTFP + if (r >= RID_MAX_GPR) { + src = (int32_t *)&ex->fpr[r-RID_MIN_FPR]; +#if LJ_TARGET_PPC + if (sz == 4) { /* PPC FPRs are always doubles. */ + *(float *)dst = (float)*(double *)src; + return; + } +#else + if (LJ_BE && sz == 4) src++; +#endif + } else +#endif + if (LJ_64 && LJ_BE && sz == 4) src++; + } + } + lj_assertJ(sz == 1 || sz == 2 || sz == 4 || sz == 8, + "restore from IR %04d with bad size %d", ref - REF_BIAS, sz); + if (sz == 4) *(int32_t *)dst = *src; + else if (sz == 8) *(int64_t *)dst = *(int64_t *)src; + else if (sz == 1) *(int8_t *)dst = (int8_t)*src; + else *(int16_t *)dst = (int16_t)*src; +} +#endif + +/* Unsink allocation from the trace exit state. Unsink sunk stores. */ +static void snap_unsink(jit_State *J, GCtrace *T, ExitState *ex, + SnapNo snapno, BloomFilter rfilt, + IRIns *ir, TValue *o) +{ + lj_assertJ(ir->o == IR_TNEW || ir->o == IR_TDUP || + ir->o == IR_CNEW || ir->o == IR_CNEWI, + "sunk allocation with bad op %d", ir->o); +#if LJ_HASFFI + if (ir->o == IR_CNEW || ir->o == IR_CNEWI) { + CTState *cts = ctype_cts(J->L); + CTypeID id = (CTypeID)T->ir[ir->op1].i; + CTSize sz; + CTInfo info = lj_ctype_info(cts, id, &sz); + GCcdata *cd = lj_cdata_newx(cts, id, sz, info); + setcdataV(J->L, o, cd); + if (ir->o == IR_CNEWI) { + uint8_t *p = (uint8_t *)cdataptr(cd); + lj_assertJ(sz == 4 || sz == 8, "sunk cdata with bad size %d", sz); + if (LJ_32 && sz == 8 && ir+1 < T->ir + T->nins && (ir+1)->o == IR_HIOP) { + snap_restoredata(J, T, ex, snapno, rfilt, (ir+1)->op2, + LJ_LE ? p+4 : p, 4); + if (LJ_BE) p += 4; + sz = 4; + } + snap_restoredata(J, T, ex, snapno, rfilt, ir->op2, p, sz); + } else { + IRIns *irs, *irlast = &T->ir[T->snap[snapno].ref]; + for (irs = ir+1; irs < irlast; irs++) + if (irs->r == RID_SINK && snap_sunk_store(T, ir, irs)) { + IRIns *iro = &T->ir[T->ir[irs->op1].op2]; + uint8_t *p = (uint8_t *)cd; + CTSize szs; + lj_assertJ(irs->o == IR_XSTORE, "sunk store with bad op %d", irs->o); + lj_assertJ(T->ir[irs->op1].o == IR_ADD, + "sunk store with bad add op %d", T->ir[irs->op1].o); + lj_assertJ(iro->o == IR_KINT || iro->o == IR_KINT64, + "sunk store with bad const offset op %d", iro->o); + if (irt_is64(irs->t)) szs = 8; + else if (irt_isi8(irs->t) || irt_isu8(irs->t)) szs = 1; + else if (irt_isi16(irs->t) || irt_isu16(irs->t)) szs = 2; + else szs = 4; + if (LJ_64 && iro->o == IR_KINT64) + p += (int64_t)ir_k64(iro)->u64; + else + p += iro->i; + lj_assertJ(p >= (uint8_t *)cdataptr(cd) && + p + szs <= (uint8_t *)cdataptr(cd) + sz, + "sunk store with offset out of range"); + if (LJ_32 && irs+1 < T->ir + T->nins && (irs+1)->o == IR_HIOP) { + lj_assertJ(szs == 4, "sunk store with bad size %d", szs); + snap_restoredata(J, T, ex, snapno, rfilt, (irs+1)->op2, + LJ_LE ? p+4 : p, 4); + if (LJ_BE) p += 4; + } + snap_restoredata(J, T, ex, snapno, rfilt, irs->op2, p, szs); + } + } + } else +#endif + { + IRIns *irs, *irlast; + GCtab *t = ir->o == IR_TNEW ? lj_tab_new(J->L, ir->op1, ir->op2) : + lj_tab_dup(J->L, ir_ktab(&T->ir[ir->op1])); + settabV(J->L, o, t); + irlast = &T->ir[T->snap[snapno].ref]; + for (irs = ir+1; irs < irlast; irs++) + if (irs->r == RID_SINK && snap_sunk_store(T, ir, irs)) { + IRIns *irk = &T->ir[irs->op1]; + TValue tmp, *val; + lj_assertJ(irs->o == IR_ASTORE || irs->o == IR_HSTORE || + irs->o == IR_FSTORE, + "sunk store with bad op %d", irs->o); + if (irk->o == IR_FREF) { + lj_assertJ(irk->op2 == IRFL_TAB_META, + "sunk store with bad field %d", irk->op2); + snap_restoreval(J, T, ex, snapno, rfilt, irs->op2, &tmp); + /* NOBARRIER: The table is new (marked white). */ + setgcref(t->metatable, obj2gco(tabV(&tmp))); + } else { + irk = &T->ir[irk->op2]; + if (irk->o == IR_KSLOT) irk = &T->ir[irk->op1]; + lj_ir_kvalue(J->L, &tmp, irk); + val = lj_tab_set(J->L, t, &tmp); + /* NOBARRIER: The table is new (marked white). */ + snap_restoreval(J, T, ex, snapno, rfilt, irs->op2, val); + if (LJ_SOFTFP32 && irs+1 < T->ir + T->nins && (irs+1)->o == IR_HIOP) { + snap_restoreval(J, T, ex, snapno, rfilt, (irs+1)->op2, &tmp); + val->u32.hi = tmp.u32.lo; + } + } + } + } +} + +/* Restore interpreter state from exit state with the help of a snapshot. */ +const BCIns *lj_snap_restore(jit_State *J, void *exptr) +{ + ExitState *ex = (ExitState *)exptr; + SnapNo snapno = J->exitno; /* For now, snapno == exitno. */ + GCtrace *T = traceref(J, J->parent); + SnapShot *snap = &T->snap[snapno]; + MSize n, nent = snap->nent; + SnapEntry *map = &T->snapmap[snap->mapofs]; +#if !LJ_FR2 || defined(LUA_USE_ASSERT) + SnapEntry *flinks = &T->snapmap[snap_nextofs(T, snap)-1-LJ_FR2]; +#endif +#if !LJ_FR2 + ptrdiff_t ftsz0; +#endif + TValue *frame; + BloomFilter rfilt = snap_renamefilter(T, snapno); + const BCIns *pc = snap_pc(&map[nent]); + lua_State *L = J->L; + + /* Set interpreter PC to the next PC to get correct error messages. */ + setcframe_pc(cframe_raw(L->cframe), pc+1); + + /* Make sure the stack is big enough for the slots from the snapshot. */ + if (LJ_UNLIKELY(L->base + snap->topslot >= tvref(L->maxstack))) { + L->top = curr_topL(L); + lj_state_growstack(L, snap->topslot - curr_proto(L)->framesize); + } + + /* Fill stack slots with data from the registers and spill slots. */ + frame = L->base-1-LJ_FR2; +#if !LJ_FR2 + ftsz0 = frame_ftsz(frame); /* Preserve link to previous frame in slot #0. */ +#endif + for (n = 0; n < nent; n++) { + SnapEntry sn = map[n]; + if (!(sn & SNAP_NORESTORE)) { + TValue *o = &frame[snap_slot(sn)]; + IRRef ref = snap_ref(sn); + IRIns *ir = &T->ir[ref]; + if (ir->r == RID_SUNK) { + MSize j; + for (j = 0; j < n; j++) + if (snap_ref(map[j]) == ref) { /* De-duplicate sunk allocations. */ + copyTV(L, o, &frame[snap_slot(map[j])]); + goto dupslot; + } + snap_unsink(J, T, ex, snapno, rfilt, ir, o); + dupslot: + continue; + } + snap_restoreval(J, T, ex, snapno, rfilt, ref, o); + if (LJ_SOFTFP32 && (sn & SNAP_SOFTFPNUM) && tvisint(o)) { + TValue tmp; + snap_restoreval(J, T, ex, snapno, rfilt, ref+1, &tmp); + o->u32.hi = tmp.u32.lo; +#if !LJ_FR2 + } else if ((sn & (SNAP_CONT|SNAP_FRAME))) { + /* Overwrite tag with frame link. */ + setframe_ftsz(o, snap_slot(sn) != 0 ? (int32_t)*flinks-- : ftsz0); + L->base = o+1; +#endif + } else if ((sn & SNAP_KEYINDEX)) { + /* A IRT_INT key index slot is restored as a number. Undo this. */ + o->u32.lo = (uint32_t)(LJ_DUALNUM ? intV(o) : lj_num2int(numV(o))); + o->u32.hi = LJ_KEYINDEX; + } + } + } +#if LJ_FR2 + L->base += (map[nent+LJ_BE] & 0xff); +#endif + lj_assertJ(map + nent == flinks, "inconsistent frames in snapshot"); + + /* Compute current stack top. */ + switch (bc_op(*pc)) { + default: + if (bc_op(*pc) < BC_FUNCF) { + L->top = curr_topL(L); + break; + } + /* fallthrough */ + case BC_CALLM: case BC_CALLMT: case BC_RETM: case BC_TSETM: + L->top = frame + snap->nslots; + break; + } + return pc; +} + +#undef emitir_raw +#undef emitir + +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_snap.h b/fluent-bit/lib/luajit-3065c9/src/lj_snap.h new file mode 100644 index 00000000..b7dabed8 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_snap.h @@ -0,0 +1,35 @@ +/* +** Snapshot handling. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#ifndef _LJ_SNAP_H +#define _LJ_SNAP_H + +#include "lj_obj.h" +#include "lj_jit.h" + +#if LJ_HASJIT +LJ_FUNC void lj_snap_add(jit_State *J); +LJ_FUNC void lj_snap_purge(jit_State *J); +LJ_FUNC void lj_snap_shrink(jit_State *J); +LJ_FUNC IRIns *lj_snap_regspmap(jit_State *J, GCtrace *T, SnapNo snapno, + IRIns *ir); +LJ_FUNC void lj_snap_replay(jit_State *J, GCtrace *T); +LJ_FUNC const BCIns *lj_snap_restore(jit_State *J, void *exptr); +LJ_FUNC void lj_snap_grow_buf_(jit_State *J, MSize need); +LJ_FUNC void lj_snap_grow_map_(jit_State *J, MSize need); + +static LJ_AINLINE void lj_snap_grow_buf(jit_State *J, MSize need) +{ + if (LJ_UNLIKELY(need > J->sizesnap)) lj_snap_grow_buf_(J, need); +} + +static LJ_AINLINE void lj_snap_grow_map(jit_State *J, MSize need) +{ + if (LJ_UNLIKELY(need > J->sizesnapmap)) lj_snap_grow_map_(J, need); +} + +#endif + +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_state.c b/fluent-bit/lib/luajit-3065c9/src/lj_state.c new file mode 100644 index 00000000..0b9c46ba --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_state.c @@ -0,0 +1,335 @@ +/* +** State and stack handling. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +** +** Portions taken verbatim or adapted from the Lua interpreter. +** Copyright (C) 1994-2008 Lua.org, PUC-Rio. See Copyright Notice in lua.h +*/ + +#define lj_state_c +#define LUA_CORE + +#include "lj_obj.h" +#include "lj_gc.h" +#include "lj_err.h" +#include "lj_buf.h" +#include "lj_str.h" +#include "lj_tab.h" +#include "lj_func.h" +#include "lj_meta.h" +#include "lj_state.h" +#include "lj_frame.h" +#if LJ_HASFFI +#include "lj_ctype.h" +#endif +#include "lj_trace.h" +#include "lj_dispatch.h" +#include "lj_vm.h" +#include "lj_prng.h" +#include "lj_lex.h" +#include "lj_alloc.h" +#include "luajit.h" + +/* -- Stack handling ------------------------------------------------------ */ + +/* Stack sizes. */ +#define LJ_STACK_MIN LUA_MINSTACK /* Min. stack size. */ +#define LJ_STACK_MAX LUAI_MAXSTACK /* Max. stack size. */ +#define LJ_STACK_START (2*LJ_STACK_MIN) /* Starting stack size. */ +#define LJ_STACK_MAXEX (LJ_STACK_MAX + 1 + LJ_STACK_EXTRA) + +/* Explanation of LJ_STACK_EXTRA: +** +** Calls to metamethods store their arguments beyond the current top +** without checking for the stack limit. This avoids stack resizes which +** would invalidate passed TValue pointers. The stack check is performed +** later by the function header. This can safely resize the stack or raise +** an error. Thus we need some extra slots beyond the current stack limit. +** +** Most metamethods need 4 slots above top (cont, mobj, arg1, arg2) plus +** one extra slot if mobj is not a function. Only lj_meta_tset needs 5 +** slots above top, but then mobj is always a function. So we can get by +** with 5 extra slots. +** LJ_FR2: We need 2 more slots for the frame PC and the continuation PC. +*/ + +/* Resize stack slots and adjust pointers in state. */ +static void resizestack(lua_State *L, MSize n) +{ + TValue *st, *oldst = tvref(L->stack); + ptrdiff_t delta; + MSize oldsize = L->stacksize; + MSize realsize = n + 1 + LJ_STACK_EXTRA; + GCobj *up; + lj_assertL((MSize)(tvref(L->maxstack)-oldst) == L->stacksize-LJ_STACK_EXTRA-1, + "inconsistent stack size"); + st = (TValue *)lj_mem_realloc(L, tvref(L->stack), + (MSize)(oldsize*sizeof(TValue)), + (MSize)(realsize*sizeof(TValue))); + setmref(L->stack, st); + delta = (char *)st - (char *)oldst; + setmref(L->maxstack, st + n); + while (oldsize < realsize) /* Clear new slots. */ + setnilV(st + oldsize++); + L->stacksize = realsize; + if ((size_t)(mref(G(L)->jit_base, char) - (char *)oldst) < oldsize) + setmref(G(L)->jit_base, mref(G(L)->jit_base, char) + delta); + L->base = (TValue *)((char *)L->base + delta); + L->top = (TValue *)((char *)L->top + delta); + for (up = gcref(L->openupval); up != NULL; up = gcnext(up)) + setmref(gco2uv(up)->v, (TValue *)((char *)uvval(gco2uv(up)) + delta)); +} + +/* Relimit stack after error, in case the limit was overdrawn. */ +void lj_state_relimitstack(lua_State *L) +{ + if (L->stacksize > LJ_STACK_MAXEX && L->top-tvref(L->stack) < LJ_STACK_MAX-1) + resizestack(L, LJ_STACK_MAX); +} + +/* Try to shrink the stack (called from GC). */ +void lj_state_shrinkstack(lua_State *L, MSize used) +{ + if (L->stacksize > LJ_STACK_MAXEX) + return; /* Avoid stack shrinking while handling stack overflow. */ + if (4*used < L->stacksize && + 2*(LJ_STACK_START+LJ_STACK_EXTRA) < L->stacksize && + /* Don't shrink stack of live trace. */ + (tvref(G(L)->jit_base) == NULL || obj2gco(L) != gcref(G(L)->cur_L))) + resizestack(L, L->stacksize >> 1); +} + +/* Try to grow stack. */ +void LJ_FASTCALL lj_state_growstack(lua_State *L, MSize need) +{ + MSize n; + if (L->stacksize > LJ_STACK_MAXEX) /* Overflow while handling overflow? */ + lj_err_throw(L, LUA_ERRERR); + n = L->stacksize + need; + if (n > LJ_STACK_MAX) { + n += 2*LUA_MINSTACK; + } else if (n < 2*L->stacksize) { + n = 2*L->stacksize; + if (n >= LJ_STACK_MAX) + n = LJ_STACK_MAX; + } + resizestack(L, n); + if (L->stacksize > LJ_STACK_MAXEX) + lj_err_msg(L, LJ_ERR_STKOV); +} + +void LJ_FASTCALL lj_state_growstack1(lua_State *L) +{ + lj_state_growstack(L, 1); +} + +/* Allocate basic stack for new state. */ +static void stack_init(lua_State *L1, lua_State *L) +{ + TValue *stend, *st = lj_mem_newvec(L, LJ_STACK_START+LJ_STACK_EXTRA, TValue); + setmref(L1->stack, st); + L1->stacksize = LJ_STACK_START + LJ_STACK_EXTRA; + stend = st + L1->stacksize; + setmref(L1->maxstack, stend - LJ_STACK_EXTRA - 1); + setthreadV(L1, st++, L1); /* Needed for curr_funcisL() on empty stack. */ + if (LJ_FR2) setnilV(st++); + L1->base = L1->top = st; + while (st < stend) /* Clear new slots. */ + setnilV(st++); +} + +/* -- State handling ------------------------------------------------------ */ + +/* Open parts that may cause memory-allocation errors. */ +static TValue *cpluaopen(lua_State *L, lua_CFunction dummy, void *ud) +{ + global_State *g = G(L); + UNUSED(dummy); + UNUSED(ud); + stack_init(L, L); + /* NOBARRIER: State initialization, all objects are white. */ + setgcref(L->env, obj2gco(lj_tab_new(L, 0, LJ_MIN_GLOBAL))); + settabV(L, registry(L), lj_tab_new(L, 0, LJ_MIN_REGISTRY)); + lj_str_init(L); + lj_meta_init(L); + lj_lex_init(L); + fixstring(lj_err_str(L, LJ_ERR_ERRMEM)); /* Preallocate memory error msg. */ + g->gc.threshold = 4*g->gc.total; + lj_trace_initstate(g); + lj_err_verify(); + return NULL; +} + +static void close_state(lua_State *L) +{ + global_State *g = G(L); + lj_func_closeuv(L, tvref(L->stack)); + lj_gc_freeall(g); + lj_assertG(gcref(g->gc.root) == obj2gco(L), + "main thread is not first GC object"); + lj_assertG(g->str.num == 0, "leaked %d strings", g->str.num); + lj_trace_freestate(g); +#if LJ_HASFFI + lj_ctype_freestate(g); +#endif + lj_str_freetab(g); + lj_buf_free(g, &g->tmpbuf); + lj_mem_freevec(g, tvref(L->stack), L->stacksize, TValue); +#if LJ_64 + if (mref(g->gc.lightudseg, uint32_t)) { + MSize segnum = g->gc.lightudnum ? (2 << lj_fls(g->gc.lightudnum)) : 2; + lj_mem_freevec(g, mref(g->gc.lightudseg, uint32_t), segnum, uint32_t); + } +#endif + lj_assertG(g->gc.total == sizeof(GG_State), + "memory leak of %lld bytes", + (long long)(g->gc.total - sizeof(GG_State))); +#ifndef LUAJIT_USE_SYSMALLOC + if (g->allocf == lj_alloc_f) + lj_alloc_destroy(g->allocd); + else +#endif + g->allocf(g->allocd, G2GG(g), sizeof(GG_State), 0); +} + +#if LJ_64 && !LJ_GC64 && !(defined(LUAJIT_USE_VALGRIND) && defined(LUAJIT_USE_SYSMALLOC)) +lua_State *lj_state_newstate(lua_Alloc allocf, void *allocd) +#else +LUA_API lua_State *lua_newstate(lua_Alloc allocf, void *allocd) +#endif +{ + PRNGState prng; + GG_State *GG; + lua_State *L; + global_State *g; + /* We need the PRNG for the memory allocator, so initialize this first. */ + if (!lj_prng_seed_secure(&prng)) { + lj_assertX(0, "secure PRNG seeding failed"); + /* Can only return NULL here, so this errors with "not enough memory". */ + return NULL; + } +#ifndef LUAJIT_USE_SYSMALLOC + if (allocf == LJ_ALLOCF_INTERNAL) { + allocd = lj_alloc_create(&prng); + if (!allocd) return NULL; + allocf = lj_alloc_f; + } +#endif + GG = (GG_State *)allocf(allocd, NULL, 0, sizeof(GG_State)); + if (GG == NULL || !checkptrGC(GG)) return NULL; + memset(GG, 0, sizeof(GG_State)); + L = &GG->L; + g = &GG->g; + L->gct = ~LJ_TTHREAD; + L->marked = LJ_GC_WHITE0 | LJ_GC_FIXED | LJ_GC_SFIXED; /* Prevent free. */ + L->dummy_ffid = FF_C; + setmref(L->glref, g); + g->gc.currentwhite = LJ_GC_WHITE0 | LJ_GC_FIXED; + g->strempty.marked = LJ_GC_WHITE0; + g->strempty.gct = ~LJ_TSTR; + g->allocf = allocf; + g->allocd = allocd; + g->prng = prng; +#ifndef LUAJIT_USE_SYSMALLOC + if (allocf == lj_alloc_f) { + lj_alloc_setprng(allocd, &g->prng); + } +#endif + setgcref(g->mainthref, obj2gco(L)); + setgcref(g->uvhead.prev, obj2gco(&g->uvhead)); + setgcref(g->uvhead.next, obj2gco(&g->uvhead)); + g->str.mask = ~(MSize)0; + setnilV(registry(L)); + setnilV(&g->nilnode.val); + setnilV(&g->nilnode.key); +#if !LJ_GC64 + setmref(g->nilnode.freetop, &g->nilnode); +#endif + lj_buf_init(NULL, &g->tmpbuf); + g->gc.state = GCSpause; + setgcref(g->gc.root, obj2gco(L)); + setmref(g->gc.sweep, &g->gc.root); + g->gc.total = sizeof(GG_State); + g->gc.pause = LUAI_GCPAUSE; + g->gc.stepmul = LUAI_GCMUL; + lj_dispatch_init((GG_State *)L); + L->status = LUA_ERRERR+1; /* Avoid touching the stack upon memory error. */ + if (lj_vm_cpcall(L, NULL, NULL, cpluaopen) != 0) { + /* Memory allocation error: free partial state. */ + close_state(L); + return NULL; + } + L->status = LUA_OK; + return L; +} + +static TValue *cpfinalize(lua_State *L, lua_CFunction dummy, void *ud) +{ + UNUSED(dummy); + UNUSED(ud); + lj_gc_finalize_cdata(L); + lj_gc_finalize_udata(L); + /* Frame pop omitted. */ + return NULL; +} + +LUA_API void lua_close(lua_State *L) +{ + global_State *g = G(L); + int i; + L = mainthread(g); /* Only the main thread can be closed. */ +#if LJ_HASPROFILE + luaJIT_profile_stop(L); +#endif + setgcrefnull(g->cur_L); + lj_func_closeuv(L, tvref(L->stack)); + lj_gc_separateudata(g, 1); /* Separate udata which have GC metamethods. */ +#if LJ_HASJIT + G2J(g)->flags &= ~JIT_F_ON; + G2J(g)->state = LJ_TRACE_IDLE; + lj_dispatch_update(g); +#endif + for (i = 0;;) { + hook_enter(g); + L->status = LUA_OK; + L->base = L->top = tvref(L->stack) + 1 + LJ_FR2; + L->cframe = NULL; + if (lj_vm_cpcall(L, NULL, NULL, cpfinalize) == LUA_OK) { + if (++i >= 10) break; + lj_gc_separateudata(g, 1); /* Separate udata again. */ + if (gcref(g->gc.mmudata) == NULL) /* Until nothing is left to do. */ + break; + } + } + close_state(L); +} + +lua_State *lj_state_new(lua_State *L) +{ + lua_State *L1 = lj_mem_newobj(L, lua_State); + L1->gct = ~LJ_TTHREAD; + L1->dummy_ffid = FF_C; + L1->status = LUA_OK; + L1->stacksize = 0; + setmref(L1->stack, NULL); + L1->cframe = NULL; + /* NOBARRIER: The lua_State is new (marked white). */ + setgcrefnull(L1->openupval); + setmrefr(L1->glref, L->glref); + setgcrefr(L1->env, L->env); + stack_init(L1, L); /* init stack */ + lj_assertL(iswhite(obj2gco(L1)), "new thread object is not white"); + return L1; +} + +void LJ_FASTCALL lj_state_free(global_State *g, lua_State *L) +{ + lj_assertG(L != mainthread(g), "free of main thread"); + if (obj2gco(L) == gcref(g->cur_L)) + setgcrefnull(g->cur_L); + lj_func_closeuv(L, tvref(L->stack)); + lj_assertG(gcref(L->openupval) == NULL, "stale open upvalues"); + lj_mem_freevec(g, tvref(L->stack), L->stacksize, TValue); + lj_mem_freet(g, L); +} + diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_state.h b/fluent-bit/lib/luajit-3065c9/src/lj_state.h new file mode 100644 index 00000000..d22b7a6f --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_state.h @@ -0,0 +1,37 @@ +/* +** State and stack handling. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#ifndef _LJ_STATE_H +#define _LJ_STATE_H + +#include "lj_obj.h" + +#define incr_top(L) \ + (++L->top >= tvref(L->maxstack) && (lj_state_growstack1(L), 0)) + +#define savestack(L, p) ((char *)(p) - mref(L->stack, char)) +#define restorestack(L, n) ((TValue *)(mref(L->stack, char) + (n))) + +LJ_FUNC void lj_state_relimitstack(lua_State *L); +LJ_FUNC void lj_state_shrinkstack(lua_State *L, MSize used); +LJ_FUNCA void LJ_FASTCALL lj_state_growstack(lua_State *L, MSize need); +LJ_FUNC void LJ_FASTCALL lj_state_growstack1(lua_State *L); + +static LJ_AINLINE void lj_state_checkstack(lua_State *L, MSize need) +{ + if ((mref(L->maxstack, char) - (char *)L->top) <= + (ptrdiff_t)need*(ptrdiff_t)sizeof(TValue)) + lj_state_growstack(L, need); +} + +LJ_FUNC lua_State *lj_state_new(lua_State *L); +LJ_FUNC void LJ_FASTCALL lj_state_free(global_State *g, lua_State *L); +#if LJ_64 && !LJ_GC64 && !(defined(LUAJIT_USE_VALGRIND) && defined(LUAJIT_USE_SYSMALLOC)) +LJ_FUNC lua_State *lj_state_newstate(lua_Alloc f, void *ud); +#endif + +#define LJ_ALLOCF_INTERNAL ((lua_Alloc)(void *)(uintptr_t)(1237<<4)) + +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_str.c b/fluent-bit/lib/luajit-3065c9/src/lj_str.c new file mode 100644 index 00000000..a5282da6 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_str.c @@ -0,0 +1,370 @@ +/* +** String handling. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#define lj_str_c +#define LUA_CORE + +#include "lj_obj.h" +#include "lj_gc.h" +#include "lj_err.h" +#include "lj_str.h" +#include "lj_char.h" +#include "lj_prng.h" + +/* -- String helpers ------------------------------------------------------ */ + +/* Ordered compare of strings. Assumes string data is 4-byte aligned. */ +int32_t LJ_FASTCALL lj_str_cmp(GCstr *a, GCstr *b) +{ + MSize i, n = a->len > b->len ? b->len : a->len; + for (i = 0; i < n; i += 4) { + /* Note: innocuous access up to end of string + 3. */ + uint32_t va = *(const uint32_t *)(strdata(a)+i); + uint32_t vb = *(const uint32_t *)(strdata(b)+i); + if (va != vb) { +#if LJ_LE + va = lj_bswap(va); vb = lj_bswap(vb); +#endif + i -= n; + if ((int32_t)i >= -3) { + va >>= 32+(i<<3); vb >>= 32+(i<<3); + if (va == vb) break; + } + return va < vb ? -1 : 1; + } + } + return (int32_t)(a->len - b->len); +} + +/* Find fixed string p inside string s. */ +const char *lj_str_find(const char *s, const char *p, MSize slen, MSize plen) +{ + if (plen <= slen) { + if (plen == 0) { + return s; + } else { + int c = *(const uint8_t *)p++; + plen--; slen -= plen; + while (slen) { + const char *q = (const char *)memchr(s, c, slen); + if (!q) break; + if (memcmp(q+1, p, plen) == 0) return q; + q++; slen -= (MSize)(q-s); s = q; + } + } + } + return NULL; +} + +/* Check whether a string has a pattern matching character. */ +int lj_str_haspattern(GCstr *s) +{ + const char *p = strdata(s), *q = p + s->len; + while (p < q) { + int c = *(const uint8_t *)p++; + if (lj_char_ispunct(c) && strchr("^$*+?.([%-", c)) + return 1; /* Found a pattern matching char. */ + } + return 0; /* No pattern matching chars found. */ +} + +/* -- String hashing ------------------------------------------------------ */ + +/* Keyed sparse ARX string hash. Constant time. */ +static StrHash hash_sparse(uint64_t seed, const char *str, MSize len) +{ + /* Constants taken from lookup3 hash by Bob Jenkins. */ + StrHash a, b, h = len ^ (StrHash)seed; + if (len >= 4) { /* Caveat: unaligned access! */ + a = lj_getu32(str); + h ^= lj_getu32(str+len-4); + b = lj_getu32(str+(len>>1)-2); + h ^= b; h -= lj_rol(b, 14); + b += lj_getu32(str+(len>>2)-1); + } else { + a = *(const uint8_t *)str; + h ^= *(const uint8_t *)(str+len-1); + b = *(const uint8_t *)(str+(len>>1)); + h ^= b; h -= lj_rol(b, 14); + } + a ^= h; a -= lj_rol(h, 11); + b ^= a; b -= lj_rol(a, 25); + h ^= b; h -= lj_rol(b, 16); + return h; +} + +#if LUAJIT_SECURITY_STRHASH +/* Keyed dense ARX string hash. Linear time. */ +static LJ_NOINLINE StrHash hash_dense(uint64_t seed, StrHash h, + const char *str, MSize len) +{ + StrHash b = lj_bswap(lj_rol(h ^ (StrHash)(seed >> 32), 4)); + if (len > 12) { + StrHash a = (StrHash)seed; + const char *pe = str+len-12, *p = pe, *q = str; + do { + a += lj_getu32(p); + b += lj_getu32(p+4); + h += lj_getu32(p+8); + p = q; q += 12; + h ^= b; h -= lj_rol(b, 14); + a ^= h; a -= lj_rol(h, 11); + b ^= a; b -= lj_rol(a, 25); + } while (p < pe); + h ^= b; h -= lj_rol(b, 16); + a ^= h; a -= lj_rol(h, 4); + b ^= a; b -= lj_rol(a, 14); + } + return b; +} +#endif + +/* -- String interning ---------------------------------------------------- */ + +#define LJ_STR_MAXCOLL 32 + +/* Resize the string interning hash table (grow and shrink). */ +void lj_str_resize(lua_State *L, MSize newmask) +{ + global_State *g = G(L); + GCRef *newtab, *oldtab = g->str.tab; + MSize i; + + /* No resizing during GC traversal or if already too big. */ + if (g->gc.state == GCSsweepstring || newmask >= LJ_MAX_STRTAB-1) + return; + + newtab = lj_mem_newvec(L, newmask+1, GCRef); + memset(newtab, 0, (newmask+1)*sizeof(GCRef)); + +#if LUAJIT_SECURITY_STRHASH + /* Check which chains need secondary hashes. */ + if (g->str.second) { + int newsecond = 0; + /* Compute primary chain lengths. */ + for (i = g->str.mask; i != ~(MSize)0; i--) { + GCobj *o = (GCobj *)(gcrefu(oldtab[i]) & ~(uintptr_t)1); + while (o) { + GCstr *s = gco2str(o); + MSize hash = s->hashalg ? hash_sparse(g->str.seed, strdata(s), s->len) : + s->hash; + hash &= newmask; + setgcrefp(newtab[hash], gcrefu(newtab[hash]) + 1); + o = gcnext(o); + } + } + /* Mark secondary chains. */ + for (i = newmask; i != ~(MSize)0; i--) { + int secondary = gcrefu(newtab[i]) > LJ_STR_MAXCOLL; + newsecond |= secondary; + setgcrefp(newtab[i], secondary); + } + g->str.second = newsecond; + } +#endif + + /* Reinsert all strings from the old table into the new table. */ + for (i = g->str.mask; i != ~(MSize)0; i--) { + GCobj *o = (GCobj *)(gcrefu(oldtab[i]) & ~(uintptr_t)1); + while (o) { + GCobj *next = gcnext(o); + GCstr *s = gco2str(o); + MSize hash = s->hash; +#if LUAJIT_SECURITY_STRHASH + uintptr_t u; + if (LJ_LIKELY(!s->hashalg)) { /* String hashed with primary hash. */ + hash &= newmask; + u = gcrefu(newtab[hash]); + if (LJ_UNLIKELY(u & 1)) { /* Switch string to secondary hash. */ + s->hash = hash = hash_dense(g->str.seed, s->hash, strdata(s), s->len); + s->hashalg = 1; + hash &= newmask; + u = gcrefu(newtab[hash]); + } + } else { /* String hashed with secondary hash. */ + MSize shash = hash_sparse(g->str.seed, strdata(s), s->len); + u = gcrefu(newtab[shash & newmask]); + if (u & 1) { + hash &= newmask; + u = gcrefu(newtab[hash]); + } else { /* Revert string back to primary hash. */ + s->hash = shash; + s->hashalg = 0; + hash = (shash & newmask); + } + } + /* NOBARRIER: The string table is a GC root. */ + setgcrefp(o->gch.nextgc, (u & ~(uintptr_t)1)); + setgcrefp(newtab[hash], ((uintptr_t)o | (u & 1))); +#else + hash &= newmask; + /* NOBARRIER: The string table is a GC root. */ + setgcrefr(o->gch.nextgc, newtab[hash]); + setgcref(newtab[hash], o); +#endif + o = next; + } + } + + /* Free old table and replace with new table. */ + lj_str_freetab(g); + g->str.tab = newtab; + g->str.mask = newmask; +} + +#if LUAJIT_SECURITY_STRHASH +/* Rehash and rechain all strings in a chain. */ +static LJ_NOINLINE GCstr *lj_str_rehash_chain(lua_State *L, StrHash hashc, + const char *str, MSize len) +{ + global_State *g = G(L); + int ow = g->gc.state == GCSsweepstring ? otherwhite(g) : 0; /* Sweeping? */ + GCRef *strtab = g->str.tab; + MSize strmask = g->str.mask; + GCobj *o = gcref(strtab[hashc & strmask]); + setgcrefp(strtab[hashc & strmask], (void *)((uintptr_t)1)); + g->str.second = 1; + while (o) { + uintptr_t u; + GCobj *next = gcnext(o); + GCstr *s = gco2str(o); + StrHash hash; + if (ow) { /* Must sweep while rechaining. */ + if (((o->gch.marked ^ LJ_GC_WHITES) & ow)) { /* String alive? */ + lj_assertG(!isdead(g, o) || (o->gch.marked & LJ_GC_FIXED), + "sweep of undead string"); + makewhite(g, o); + } else { /* Free dead string. */ + lj_assertG(isdead(g, o) || ow == LJ_GC_SFIXED, + "sweep of unlive string"); + lj_str_free(g, s); + o = next; + continue; + } + } + hash = s->hash; + if (!s->hashalg) { /* Rehash with secondary hash. */ + hash = hash_dense(g->str.seed, hash, strdata(s), s->len); + s->hash = hash; + s->hashalg = 1; + } + /* Rechain. */ + hash &= strmask; + u = gcrefu(strtab[hash]); + setgcrefp(o->gch.nextgc, (u & ~(uintptr_t)1)); + setgcrefp(strtab[hash], ((uintptr_t)o | (u & 1))); + o = next; + } + /* Try to insert the pending string again. */ + return lj_str_new(L, str, len); +} +#endif + +/* Reseed String ID from PRNG after random interval < 2^bits. */ +#if LUAJIT_SECURITY_STRID == 1 +#define STRID_RESEED_INTERVAL 8 +#elif LUAJIT_SECURITY_STRID == 2 +#define STRID_RESEED_INTERVAL 4 +#elif LUAJIT_SECURITY_STRID >= 3 +#define STRID_RESEED_INTERVAL 0 +#endif + +/* Allocate a new string and add to string interning table. */ +static GCstr *lj_str_alloc(lua_State *L, const char *str, MSize len, + StrHash hash, int hashalg) +{ + GCstr *s = lj_mem_newt(L, lj_str_size(len), GCstr); + global_State *g = G(L); + uintptr_t u; + newwhite(g, s); + s->gct = ~LJ_TSTR; + s->len = len; + s->hash = hash; +#ifndef STRID_RESEED_INTERVAL + s->sid = g->str.id++; +#elif STRID_RESEED_INTERVAL + if (!g->str.idreseed--) { + uint64_t r = lj_prng_u64(&g->prng); + g->str.id = (StrID)r; + g->str.idreseed = (uint8_t)(r >> (64 - STRID_RESEED_INTERVAL)); + } + s->sid = g->str.id++; +#else + s->sid = (StrID)lj_prng_u64(&g->prng); +#endif + s->reserved = 0; + s->hashalg = (uint8_t)hashalg; + /* Clear last 4 bytes of allocated memory. Implies zero-termination, too. */ + *(uint32_t *)(strdatawr(s)+(len & ~(MSize)3)) = 0; + memcpy(strdatawr(s), str, len); + /* Add to string hash table. */ + hash &= g->str.mask; + u = gcrefu(g->str.tab[hash]); + setgcrefp(s->nextgc, (u & ~(uintptr_t)1)); + /* NOBARRIER: The string table is a GC root. */ + setgcrefp(g->str.tab[hash], ((uintptr_t)s | (u & 1))); + if (g->str.num++ > g->str.mask) /* Allow a 100% load factor. */ + lj_str_resize(L, (g->str.mask<<1)+1); /* Grow string table. */ + return s; /* Return newly interned string. */ +} + +/* Intern a string and return string object. */ +GCstr *lj_str_new(lua_State *L, const char *str, size_t lenx) +{ + global_State *g = G(L); + if (lenx-1 < LJ_MAX_STR-1) { + MSize len = (MSize)lenx; + StrHash hash = hash_sparse(g->str.seed, str, len); + MSize coll = 0; + int hashalg = 0; + /* Check if the string has already been interned. */ + GCobj *o = gcref(g->str.tab[hash & g->str.mask]); +#if LUAJIT_SECURITY_STRHASH + if (LJ_UNLIKELY((uintptr_t)o & 1)) { /* Secondary hash for this chain? */ + hashalg = 1; + hash = hash_dense(g->str.seed, hash, str, len); + o = (GCobj *)(gcrefu(g->str.tab[hash & g->str.mask]) & ~(uintptr_t)1); + } +#endif + while (o != NULL) { + GCstr *sx = gco2str(o); + if (sx->hash == hash && sx->len == len) { + if (memcmp(str, strdata(sx), len) == 0) { + if (isdead(g, o)) flipwhite(o); /* Resurrect if dead. */ + return sx; /* Return existing string. */ + } + coll++; + } + coll++; + o = gcnext(o); + } +#if LUAJIT_SECURITY_STRHASH + /* Rehash chain if there are too many collisions. */ + if (LJ_UNLIKELY(coll > LJ_STR_MAXCOLL) && !hashalg) { + return lj_str_rehash_chain(L, hash, str, len); + } +#endif + /* Otherwise allocate a new string. */ + return lj_str_alloc(L, str, len, hash, hashalg); + } else { + if (lenx) + lj_err_msg(L, LJ_ERR_STROV); + return &g->strempty; + } +} + +void LJ_FASTCALL lj_str_free(global_State *g, GCstr *s) +{ + g->str.num--; + lj_mem_free(g, s, lj_str_size(s->len)); +} + +void LJ_FASTCALL lj_str_init(lua_State *L) +{ + global_State *g = G(L); + g->str.seed = lj_prng_u64(&g->prng); + lj_str_resize(L, LJ_MIN_STRTAB-1); +} + diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_str.h b/fluent-bit/lib/luajit-3065c9/src/lj_str.h new file mode 100644 index 00000000..28edb5a5 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_str.h @@ -0,0 +1,31 @@ +/* +** String handling. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#ifndef _LJ_STR_H +#define _LJ_STR_H + +#include + +#include "lj_obj.h" + +/* String helpers. */ +LJ_FUNC int32_t LJ_FASTCALL lj_str_cmp(GCstr *a, GCstr *b); +LJ_FUNC const char *lj_str_find(const char *s, const char *f, + MSize slen, MSize flen); +LJ_FUNC int lj_str_haspattern(GCstr *s); + +/* String interning. */ +LJ_FUNC void lj_str_resize(lua_State *L, MSize newmask); +LJ_FUNCA GCstr *lj_str_new(lua_State *L, const char *str, size_t len); +LJ_FUNC void LJ_FASTCALL lj_str_free(global_State *g, GCstr *s); +LJ_FUNC void LJ_FASTCALL lj_str_init(lua_State *L); +#define lj_str_freetab(g) \ + (lj_mem_freevec(g, g->str.tab, g->str.mask+1, GCRef)) + +#define lj_str_newz(L, s) (lj_str_new(L, s, strlen(s))) +#define lj_str_newlit(L, s) (lj_str_new(L, "" s, sizeof(s)-1)) +#define lj_str_size(len) (sizeof(GCstr) + (((len)+4) & ~(MSize)3)) + +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_strfmt.c b/fluent-bit/lib/luajit-3065c9/src/lj_strfmt.c new file mode 100644 index 00000000..5c808290 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_strfmt.c @@ -0,0 +1,606 @@ +/* +** String formatting. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#include + +#define lj_strfmt_c +#define LUA_CORE + +#include "lj_obj.h" +#include "lj_err.h" +#include "lj_buf.h" +#include "lj_str.h" +#include "lj_meta.h" +#include "lj_state.h" +#include "lj_char.h" +#include "lj_strfmt.h" +#if LJ_HASFFI +#include "lj_ctype.h" +#endif +#include "lj_lib.h" + +/* -- Format parser ------------------------------------------------------- */ + +static const uint8_t strfmt_map[('x'-'A')+1] = { + STRFMT_A,0,0,0,STRFMT_E,STRFMT_F,STRFMT_G,0,0,0,0,0,0, + 0,0,0,0,0,0,0,0,0,0,STRFMT_X,0,0, + 0,0,0,0,0,0, + STRFMT_A,0,STRFMT_C,STRFMT_D,STRFMT_E,STRFMT_F,STRFMT_G,0,STRFMT_I,0,0,0,0, + 0,STRFMT_O,STRFMT_P,STRFMT_Q,0,STRFMT_S,0,STRFMT_U,0,0,STRFMT_X +}; + +SFormat LJ_FASTCALL lj_strfmt_parse(FormatState *fs) +{ + const uint8_t *p = fs->p, *e = fs->e; + fs->str = (const char *)p; + for (; p < e; p++) { + if (*p == '%') { /* Escape char? */ + if (p[1] == '%') { /* '%%'? */ + fs->p = ++p+1; + goto retlit; + } else { + SFormat sf = 0; + uint32_t c; + if (p != (const uint8_t *)fs->str) + break; + for (p++; (uint32_t)*p - ' ' <= (uint32_t)('0' - ' '); p++) { + /* Parse flags. */ + if (*p == '-') sf |= STRFMT_F_LEFT; + else if (*p == '+') sf |= STRFMT_F_PLUS; + else if (*p == '0') sf |= STRFMT_F_ZERO; + else if (*p == ' ') sf |= STRFMT_F_SPACE; + else if (*p == '#') sf |= STRFMT_F_ALT; + else break; + } + if ((uint32_t)*p - '0' < 10) { /* Parse width. */ + uint32_t width = (uint32_t)*p++ - '0'; + if ((uint32_t)*p - '0' < 10) + width = (uint32_t)*p++ - '0' + width*10; + sf |= (width << STRFMT_SH_WIDTH); + } + if (*p == '.') { /* Parse precision. */ + uint32_t prec = 0; + p++; + if ((uint32_t)*p - '0' < 10) { + prec = (uint32_t)*p++ - '0'; + if ((uint32_t)*p - '0' < 10) + prec = (uint32_t)*p++ - '0' + prec*10; + } + sf |= ((prec+1) << STRFMT_SH_PREC); + } + /* Parse conversion. */ + c = (uint32_t)*p - 'A'; + if (LJ_LIKELY(c <= (uint32_t)('x' - 'A'))) { + uint32_t sx = strfmt_map[c]; + if (sx) { + fs->p = p+1; + return (sf | sx | ((c & 0x20) ? 0 : STRFMT_F_UPPER)); + } + } + /* Return error location. */ + if (*p >= 32) p++; + fs->len = (MSize)(p - (const uint8_t *)fs->str); + fs->p = fs->e; + return STRFMT_ERR; + } + } + } + fs->p = p; +retlit: + fs->len = (MSize)(p - (const uint8_t *)fs->str); + return fs->len ? STRFMT_LIT : STRFMT_EOF; +} + +/* -- Raw conversions ----------------------------------------------------- */ + +#define WINT_R(x, sh, sc) \ + { uint32_t d = (x*(((1<>sh; x -= d*sc; *p++ = (char)('0'+d); } + +/* Write integer to buffer. */ +char * LJ_FASTCALL lj_strfmt_wint(char *p, int32_t k) +{ + uint32_t u = (uint32_t)k; + if (k < 0) { u = (uint32_t)-k; *p++ = '-'; } + if (u < 10000) { + if (u < 10) goto dig1; + if (u < 100) goto dig2; + if (u < 1000) goto dig3; + } else { + uint32_t v = u / 10000; u -= v * 10000; + if (v < 10000) { + if (v < 10) goto dig5; + if (v < 100) goto dig6; + if (v < 1000) goto dig7; + } else { + uint32_t w = v / 10000; v -= w * 10000; + if (w >= 10) WINT_R(w, 10, 10) + *p++ = (char)('0'+w); + } + WINT_R(v, 23, 1000) + dig7: WINT_R(v, 12, 100) + dig6: WINT_R(v, 10, 10) + dig5: *p++ = (char)('0'+v); + } + WINT_R(u, 23, 1000) + dig3: WINT_R(u, 12, 100) + dig2: WINT_R(u, 10, 10) + dig1: *p++ = (char)('0'+u); + return p; +} +#undef WINT_R + +/* Write pointer to buffer. */ +char * LJ_FASTCALL lj_strfmt_wptr(char *p, const void *v) +{ + ptrdiff_t x = (ptrdiff_t)v; + MSize i, n = STRFMT_MAXBUF_PTR; + if (x == 0) { + *p++ = 'N'; *p++ = 'U'; *p++ = 'L'; *p++ = 'L'; + return p; + } +#if LJ_64 + /* Shorten output for 64 bit pointers. */ + n = 2+2*4+((x >> 32) ? 2+2*(lj_fls((uint32_t)(x >> 32))>>3) : 0); +#endif + p[0] = '0'; + p[1] = 'x'; + for (i = n-1; i >= 2; i--, x >>= 4) + p[i] = "0123456789abcdef"[(x & 15)]; + return p+n; +} + +/* Write ULEB128 to buffer. */ +char * LJ_FASTCALL lj_strfmt_wuleb128(char *p, uint32_t v) +{ + for (; v >= 0x80; v >>= 7) + *p++ = (char)((v & 0x7f) | 0x80); + *p++ = (char)v; + return p; +} + +/* Return string or write number to tmp buffer and return pointer to start. */ +const char *lj_strfmt_wstrnum(lua_State *L, cTValue *o, MSize *lenp) +{ + SBuf *sb; + if (tvisstr(o)) { + *lenp = strV(o)->len; + return strVdata(o); + } else if (tvisbuf(o)) { + SBufExt *sbx = bufV(o); + *lenp = sbufxlen(sbx); + return sbx->r; + } else if (tvisint(o)) { + sb = lj_strfmt_putint(lj_buf_tmp_(L), intV(o)); + } else if (tvisnum(o)) { + sb = lj_strfmt_putfnum(lj_buf_tmp_(L), STRFMT_G14, o->n); + } else { + return NULL; + } + *lenp = sbuflen(sb); + return sb->b; +} + +/* -- Unformatted conversions to buffer ----------------------------------- */ + +/* Add integer to buffer. */ +SBuf * LJ_FASTCALL lj_strfmt_putint(SBuf *sb, int32_t k) +{ + sb->w = lj_strfmt_wint(lj_buf_more(sb, STRFMT_MAXBUF_INT), k); + return sb; +} + +#if LJ_HASJIT +/* Add number to buffer. */ +SBuf * LJ_FASTCALL lj_strfmt_putnum(SBuf *sb, cTValue *o) +{ + return lj_strfmt_putfnum(sb, STRFMT_G14, o->n); +} +#endif + +SBuf * LJ_FASTCALL lj_strfmt_putptr(SBuf *sb, const void *v) +{ + sb->w = lj_strfmt_wptr(lj_buf_more(sb, STRFMT_MAXBUF_PTR), v); + return sb; +} + +/* Add quoted string to buffer. */ +static SBuf *strfmt_putquotedlen(SBuf *sb, const char *s, MSize len) +{ + lj_buf_putb(sb, '"'); + while (len--) { + uint32_t c = (uint32_t)(uint8_t)*s++; + char *w = lj_buf_more(sb, 4); + if (c == '"' || c == '\\' || c == '\n') { + *w++ = '\\'; + } else if (lj_char_iscntrl(c)) { /* This can only be 0-31 or 127. */ + uint32_t d; + *w++ = '\\'; + if (c >= 100 || lj_char_isdigit((uint8_t)*s)) { + *w++ = (char)('0'+(c >= 100)); if (c >= 100) c -= 100; + goto tens; + } else if (c >= 10) { + tens: + d = (c * 205) >> 11; c -= d * 10; *w++ = (char)('0'+d); + } + c += '0'; + } + *w++ = (char)c; + sb->w = w; + } + lj_buf_putb(sb, '"'); + return sb; +} + +#if LJ_HASJIT +SBuf * LJ_FASTCALL lj_strfmt_putquoted(SBuf *sb, GCstr *str) +{ + return strfmt_putquotedlen(sb, strdata(str), str->len); +} +#endif + +/* -- Formatted conversions to buffer ------------------------------------- */ + +/* Add formatted char to buffer. */ +SBuf *lj_strfmt_putfchar(SBuf *sb, SFormat sf, int32_t c) +{ + MSize width = STRFMT_WIDTH(sf); + char *w = lj_buf_more(sb, width > 1 ? width : 1); + if ((sf & STRFMT_F_LEFT)) *w++ = (char)c; + while (width-- > 1) *w++ = ' '; + if (!(sf & STRFMT_F_LEFT)) *w++ = (char)c; + sb->w = w; + return sb; +} + +/* Add formatted string to buffer. */ +static SBuf *strfmt_putfstrlen(SBuf *sb, SFormat sf, const char *s, MSize len) +{ + MSize width = STRFMT_WIDTH(sf); + char *w; + if (len > STRFMT_PREC(sf)) len = STRFMT_PREC(sf); + w = lj_buf_more(sb, width > len ? width : len); + if ((sf & STRFMT_F_LEFT)) w = lj_buf_wmem(w, s, len); + while (width-- > len) *w++ = ' '; + if (!(sf & STRFMT_F_LEFT)) w = lj_buf_wmem(w, s, len); + sb->w = w; + return sb; +} + +#if LJ_HASJIT +SBuf *lj_strfmt_putfstr(SBuf *sb, SFormat sf, GCstr *str) +{ + return strfmt_putfstrlen(sb, sf, strdata(str), str->len); +} +#endif + +/* Add formatted signed/unsigned integer to buffer. */ +SBuf *lj_strfmt_putfxint(SBuf *sb, SFormat sf, uint64_t k) +{ + char buf[STRFMT_MAXBUF_XINT], *q = buf + sizeof(buf), *w; +#ifdef LUA_USE_ASSERT + char *ws; +#endif + MSize prefix = 0, len, prec, pprec, width, need; + + /* Figure out signed prefixes. */ + if (STRFMT_TYPE(sf) == STRFMT_INT) { + if ((int64_t)k < 0) { + k = (uint64_t)-(int64_t)k; + prefix = 256 + '-'; + } else if ((sf & STRFMT_F_PLUS)) { + prefix = 256 + '+'; + } else if ((sf & STRFMT_F_SPACE)) { + prefix = 256 + ' '; + } + } + + /* Convert number and store to fixed-size buffer in reverse order. */ + prec = STRFMT_PREC(sf); + if ((int32_t)prec >= 0) sf &= ~STRFMT_F_ZERO; + if (k == 0) { /* Special-case zero argument. */ + if (prec != 0 || + (sf & (STRFMT_T_OCT|STRFMT_F_ALT)) == (STRFMT_T_OCT|STRFMT_F_ALT)) + *--q = '0'; + } else if (!(sf & (STRFMT_T_HEX|STRFMT_T_OCT))) { /* Decimal. */ + uint32_t k2; + while ((k >> 32)) { *--q = (char)('0' + k % 10); k /= 10; } + k2 = (uint32_t)k; + do { *--q = (char)('0' + k2 % 10); k2 /= 10; } while (k2); + } else if ((sf & STRFMT_T_HEX)) { /* Hex. */ + const char *hexdig = (sf & STRFMT_F_UPPER) ? "0123456789ABCDEF" : + "0123456789abcdef"; + do { *--q = hexdig[(k & 15)]; k >>= 4; } while (k); + if ((sf & STRFMT_F_ALT)) prefix = 512 + ((sf & STRFMT_F_UPPER) ? 'X' : 'x'); + } else { /* Octal. */ + do { *--q = (char)('0' + (uint32_t)(k & 7)); k >>= 3; } while (k); + if ((sf & STRFMT_F_ALT)) *--q = '0'; + } + + /* Calculate sizes. */ + len = (MSize)(buf + sizeof(buf) - q); + if ((int32_t)len >= (int32_t)prec) prec = len; + width = STRFMT_WIDTH(sf); + pprec = prec + (prefix >> 8); + need = width > pprec ? width : pprec; + w = lj_buf_more(sb, need); +#ifdef LUA_USE_ASSERT + ws = w; +#endif + + /* Format number with leading/trailing whitespace and zeros. */ + if ((sf & (STRFMT_F_LEFT|STRFMT_F_ZERO)) == 0) + while (width-- > pprec) *w++ = ' '; + if (prefix) { + if ((char)prefix >= 'X') *w++ = '0'; + *w++ = (char)prefix; + } + if ((sf & (STRFMT_F_LEFT|STRFMT_F_ZERO)) == STRFMT_F_ZERO) + while (width-- > pprec) *w++ = '0'; + while (prec-- > len) *w++ = '0'; + while (q < buf + sizeof(buf)) *w++ = *q++; /* Add number itself. */ + if ((sf & STRFMT_F_LEFT)) + while (width-- > pprec) *w++ = ' '; + + lj_assertX(need == (MSize)(w - ws), "miscalculated format size"); + sb->w = w; + return sb; +} + +/* Add number formatted as signed integer to buffer. */ +SBuf *lj_strfmt_putfnum_int(SBuf *sb, SFormat sf, lua_Number n) +{ + int64_t k = (int64_t)n; + if (checki32(k) && sf == STRFMT_INT) + return lj_strfmt_putint(sb, (int32_t)k); /* Shortcut for plain %d. */ + else + return lj_strfmt_putfxint(sb, sf, (uint64_t)k); +} + +/* Add number formatted as unsigned integer to buffer. */ +SBuf *lj_strfmt_putfnum_uint(SBuf *sb, SFormat sf, lua_Number n) +{ + int64_t k; + if (n >= 9223372036854775808.0) + k = (int64_t)(n - 18446744073709551616.0); + else + k = (int64_t)n; + return lj_strfmt_putfxint(sb, sf, (uint64_t)k); +} + +/* Format stack arguments to buffer. */ +int lj_strfmt_putarg(lua_State *L, SBuf *sb, int arg, int retry) +{ + int narg = (int)(L->top - L->base); + GCstr *fmt = lj_lib_checkstr(L, arg); + FormatState fs; + SFormat sf; + lj_strfmt_init(&fs, strdata(fmt), fmt->len); + while ((sf = lj_strfmt_parse(&fs)) != STRFMT_EOF) { + if (sf == STRFMT_LIT) { + lj_buf_putmem(sb, fs.str, fs.len); + } else if (sf == STRFMT_ERR) { + lj_err_callerv(L, LJ_ERR_STRFMT, + strdata(lj_str_new(L, fs.str, fs.len))); + } else { + TValue *o = &L->base[arg++]; + if (arg > narg) + lj_err_arg(L, arg, LJ_ERR_NOVAL); + switch (STRFMT_TYPE(sf)) { + case STRFMT_INT: + if (tvisint(o)) { + int32_t k = intV(o); + if (sf == STRFMT_INT) + lj_strfmt_putint(sb, k); /* Shortcut for plain %d. */ + else + lj_strfmt_putfxint(sb, sf, k); + break; + } +#if LJ_HASFFI + if (tviscdata(o)) { + GCcdata *cd = cdataV(o); + if (cd->ctypeid == CTID_INT64 || cd->ctypeid == CTID_UINT64) { + lj_strfmt_putfxint(sb, sf, *(uint64_t *)cdataptr(cd)); + break; + } + } +#endif + lj_strfmt_putfnum_int(sb, sf, lj_lib_checknum(L, arg)); + break; + case STRFMT_UINT: + if (tvisint(o)) { + lj_strfmt_putfxint(sb, sf, intV(o)); + break; + } +#if LJ_HASFFI + if (tviscdata(o)) { + GCcdata *cd = cdataV(o); + if (cd->ctypeid == CTID_INT64 || cd->ctypeid == CTID_UINT64) { + lj_strfmt_putfxint(sb, sf, *(uint64_t *)cdataptr(cd)); + break; + } + } +#endif + lj_strfmt_putfnum_uint(sb, sf, lj_lib_checknum(L, arg)); + break; + case STRFMT_NUM: + lj_strfmt_putfnum(sb, sf, lj_lib_checknum(L, arg)); + break; + case STRFMT_STR: { + MSize len; + const char *s; + cTValue *mo; + if (LJ_UNLIKELY(!tvisstr(o) && !tvisbuf(o)) && retry >= 0 && + !tvisnil(mo = lj_meta_lookup(L, o, MM_tostring))) { + /* Call __tostring metamethod once. */ + copyTV(L, L->top++, mo); + copyTV(L, L->top++, o); + lua_call(L, 1, 1); + o = &L->base[arg-1]; /* Stack may have been reallocated. */ + copyTV(L, o, --L->top); /* Replace inline for retry. */ + if (retry < 2) { /* Global buffer may have been overwritten. */ + retry = 1; + break; + } + } + if (LJ_LIKELY(tvisstr(o))) { + len = strV(o)->len; + s = strVdata(o); +#if LJ_HASBUFFER + } else if (tvisbuf(o)) { + SBufExt *sbx = bufV(o); + if (sbx == (SBufExt *)sb) lj_err_arg(L, arg+1, LJ_ERR_BUFFER_SELF); + len = sbufxlen(sbx); + s = sbx->r; +#endif + } else { + GCstr *str = lj_strfmt_obj(L, o); + len = str->len; + s = strdata(str); + } + if ((sf & STRFMT_T_QUOTED)) + strfmt_putquotedlen(sb, s, len); /* No formatting. */ + else + strfmt_putfstrlen(sb, sf, s, len); + break; + } + case STRFMT_CHAR: + lj_strfmt_putfchar(sb, sf, lj_lib_checkint(L, arg)); + break; + case STRFMT_PTR: /* No formatting. */ + lj_strfmt_putptr(sb, lj_obj_ptr(G(L), o)); + break; + default: + lj_assertL(0, "bad string format type"); + break; + } + } + } + return retry; +} + +/* -- Conversions to strings ---------------------------------------------- */ + +/* Convert integer to string. */ +GCstr * LJ_FASTCALL lj_strfmt_int(lua_State *L, int32_t k) +{ + char buf[STRFMT_MAXBUF_INT]; + MSize len = (MSize)(lj_strfmt_wint(buf, k) - buf); + return lj_str_new(L, buf, len); +} + +/* Convert integer or number to string. */ +GCstr * LJ_FASTCALL lj_strfmt_number(lua_State *L, cTValue *o) +{ + return tvisint(o) ? lj_strfmt_int(L, intV(o)) : lj_strfmt_num(L, o); +} + +#if LJ_HASJIT +/* Convert char value to string. */ +GCstr * LJ_FASTCALL lj_strfmt_char(lua_State *L, int c) +{ + char buf[1]; + buf[0] = c; + return lj_str_new(L, buf, 1); +} +#endif + +/* Raw conversion of object to string. */ +GCstr * LJ_FASTCALL lj_strfmt_obj(lua_State *L, cTValue *o) +{ + if (tvisstr(o)) { + return strV(o); + } else if (tvisnumber(o)) { + return lj_strfmt_number(L, o); + } else if (tvisnil(o)) { + return lj_str_newlit(L, "nil"); + } else if (tvisfalse(o)) { + return lj_str_newlit(L, "false"); + } else if (tvistrue(o)) { + return lj_str_newlit(L, "true"); + } else { + char buf[8+2+2+16], *p = buf; + p = lj_buf_wmem(p, lj_typename(o), (MSize)strlen(lj_typename(o))); + *p++ = ':'; *p++ = ' '; + if (tvisfunc(o) && isffunc(funcV(o))) { + p = lj_buf_wmem(p, "builtin#", 8); + p = lj_strfmt_wint(p, funcV(o)->c.ffid); + } else { + p = lj_strfmt_wptr(p, lj_obj_ptr(G(L), o)); + } + return lj_str_new(L, buf, (size_t)(p - buf)); + } +} + +/* -- Internal string formatting ------------------------------------------ */ + +/* +** These functions are only used for lua_pushfstring(), lua_pushvfstring() +** and for internal string formatting (e.g. error messages). Caveat: unlike +** string.format(), only a limited subset of formats and flags are supported! +** +** LuaJIT has support for a couple more formats than Lua 5.1/5.2: +** - %d %u %o %x with full formatting, 32 bit integers only. +** - %f and other FP formats are really %.14g. +** - %s %c %p without formatting. +*/ + +/* Push formatted message as a string object to Lua stack. va_list variant. */ +const char *lj_strfmt_pushvf(lua_State *L, const char *fmt, va_list argp) +{ + SBuf *sb = lj_buf_tmp_(L); + FormatState fs; + SFormat sf; + GCstr *str; + lj_strfmt_init(&fs, fmt, (MSize)strlen(fmt)); + while ((sf = lj_strfmt_parse(&fs)) != STRFMT_EOF) { + switch (STRFMT_TYPE(sf)) { + case STRFMT_LIT: + lj_buf_putmem(sb, fs.str, fs.len); + break; + case STRFMT_INT: + lj_strfmt_putfxint(sb, sf, va_arg(argp, int32_t)); + break; + case STRFMT_UINT: + lj_strfmt_putfxint(sb, sf, va_arg(argp, uint32_t)); + break; + case STRFMT_NUM: + lj_strfmt_putfnum(sb, STRFMT_G14, va_arg(argp, lua_Number)); + break; + case STRFMT_STR: { + const char *s = va_arg(argp, char *); + if (s == NULL) s = "(null)"; + lj_buf_putmem(sb, s, (MSize)strlen(s)); + break; + } + case STRFMT_CHAR: + lj_buf_putb(sb, va_arg(argp, int)); + break; + case STRFMT_PTR: + lj_strfmt_putptr(sb, va_arg(argp, void *)); + break; + case STRFMT_ERR: + default: + lj_buf_putb(sb, '?'); + lj_assertL(0, "bad string format near offset %d", fs.len); + break; + } + } + str = lj_buf_str(L, sb); + setstrV(L, L->top, str); + incr_top(L); + return strdata(str); +} + +/* Push formatted message as a string object to Lua stack. Vararg variant. */ +const char *lj_strfmt_pushf(lua_State *L, const char *fmt, ...) +{ + const char *msg; + va_list argp; + va_start(argp, fmt); + msg = lj_strfmt_pushvf(L, fmt, argp); + va_end(argp); + return msg; +} + diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_strfmt.h b/fluent-bit/lib/luajit-3065c9/src/lj_strfmt.h new file mode 100644 index 00000000..a4529604 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_strfmt.h @@ -0,0 +1,131 @@ +/* +** String formatting. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#ifndef _LJ_STRFMT_H +#define _LJ_STRFMT_H + +#include "lj_obj.h" + +typedef uint32_t SFormat; /* Format indicator. */ + +/* Format parser state. */ +typedef struct FormatState { + const uint8_t *p; /* Current format string pointer. */ + const uint8_t *e; /* End of format string. */ + const char *str; /* Returned literal string. */ + MSize len; /* Size of literal string. */ +} FormatState; + +/* Format types (max. 16). */ +typedef enum FormatType { + STRFMT_EOF, STRFMT_ERR, STRFMT_LIT, + STRFMT_INT, STRFMT_UINT, STRFMT_NUM, STRFMT_STR, STRFMT_CHAR, STRFMT_PTR +} FormatType; + +/* Format subtypes (bits are reused). */ +#define STRFMT_T_HEX 0x0010 /* STRFMT_UINT */ +#define STRFMT_T_OCT 0x0020 /* STRFMT_UINT */ +#define STRFMT_T_FP_A 0x0000 /* STRFMT_NUM */ +#define STRFMT_T_FP_E 0x0010 /* STRFMT_NUM */ +#define STRFMT_T_FP_F 0x0020 /* STRFMT_NUM */ +#define STRFMT_T_FP_G 0x0030 /* STRFMT_NUM */ +#define STRFMT_T_QUOTED 0x0010 /* STRFMT_STR */ + +/* Format flags. */ +#define STRFMT_F_LEFT 0x0100 +#define STRFMT_F_PLUS 0x0200 +#define STRFMT_F_ZERO 0x0400 +#define STRFMT_F_SPACE 0x0800 +#define STRFMT_F_ALT 0x1000 +#define STRFMT_F_UPPER 0x2000 + +/* Format indicator fields. */ +#define STRFMT_SH_WIDTH 16 +#define STRFMT_SH_PREC 24 + +#define STRFMT_TYPE(sf) ((FormatType)((sf) & 15)) +#define STRFMT_WIDTH(sf) (((sf) >> STRFMT_SH_WIDTH) & 255u) +#define STRFMT_PREC(sf) ((((sf) >> STRFMT_SH_PREC) & 255u) - 1u) +#define STRFMT_FP(sf) (((sf) >> 4) & 3) + +/* Formats for conversion characters. */ +#define STRFMT_A (STRFMT_NUM|STRFMT_T_FP_A) +#define STRFMT_C (STRFMT_CHAR) +#define STRFMT_D (STRFMT_INT) +#define STRFMT_E (STRFMT_NUM|STRFMT_T_FP_E) +#define STRFMT_F (STRFMT_NUM|STRFMT_T_FP_F) +#define STRFMT_G (STRFMT_NUM|STRFMT_T_FP_G) +#define STRFMT_I STRFMT_D +#define STRFMT_O (STRFMT_UINT|STRFMT_T_OCT) +#define STRFMT_P (STRFMT_PTR) +#define STRFMT_Q (STRFMT_STR|STRFMT_T_QUOTED) +#define STRFMT_S (STRFMT_STR) +#define STRFMT_U (STRFMT_UINT) +#define STRFMT_X (STRFMT_UINT|STRFMT_T_HEX) +#define STRFMT_G14 (STRFMT_G | ((14+1) << STRFMT_SH_PREC)) + +/* Maximum buffer sizes for conversions. */ +#define STRFMT_MAXBUF_XINT (1+22) /* '0' prefix + uint64_t in octal. */ +#define STRFMT_MAXBUF_INT (1+10) /* Sign + int32_t in decimal. */ +#define STRFMT_MAXBUF_NUM 32 /* Must correspond with STRFMT_G14. */ +#define STRFMT_MAXBUF_PTR (2+2*sizeof(ptrdiff_t)) /* "0x" + hex ptr. */ + +/* Format parser. */ +LJ_FUNC SFormat LJ_FASTCALL lj_strfmt_parse(FormatState *fs); + +static LJ_AINLINE void lj_strfmt_init(FormatState *fs, const char *p, MSize len) +{ + fs->p = (const uint8_t *)p; + fs->e = (const uint8_t *)p + len; + /* Must be NUL-terminated. May have NULs inside, too. */ + lj_assertX(*fs->e == 0, "format not NUL-terminated"); +} + +/* Raw conversions. */ +LJ_FUNC char * LJ_FASTCALL lj_strfmt_wint(char *p, int32_t k); +LJ_FUNC char * LJ_FASTCALL lj_strfmt_wptr(char *p, const void *v); +LJ_FUNC char * LJ_FASTCALL lj_strfmt_wuleb128(char *p, uint32_t v); +LJ_FUNC const char *lj_strfmt_wstrnum(lua_State *L, cTValue *o, MSize *lenp); + +/* Unformatted conversions to buffer. */ +LJ_FUNC SBuf * LJ_FASTCALL lj_strfmt_putint(SBuf *sb, int32_t k); +#if LJ_HASJIT +LJ_FUNC SBuf * LJ_FASTCALL lj_strfmt_putnum(SBuf *sb, cTValue *o); +#endif +LJ_FUNC SBuf * LJ_FASTCALL lj_strfmt_putptr(SBuf *sb, const void *v); +#if LJ_HASJIT +LJ_FUNC SBuf * LJ_FASTCALL lj_strfmt_putquoted(SBuf *sb, GCstr *str); +#endif + +/* Formatted conversions to buffer. */ +LJ_FUNC SBuf *lj_strfmt_putfxint(SBuf *sb, SFormat sf, uint64_t k); +LJ_FUNC SBuf *lj_strfmt_putfnum_int(SBuf *sb, SFormat sf, lua_Number n); +LJ_FUNC SBuf *lj_strfmt_putfnum_uint(SBuf *sb, SFormat sf, lua_Number n); +LJ_FUNC SBuf *lj_strfmt_putfnum(SBuf *sb, SFormat, lua_Number n); +LJ_FUNC SBuf *lj_strfmt_putfchar(SBuf *sb, SFormat, int32_t c); +#if LJ_HASJIT +LJ_FUNC SBuf *lj_strfmt_putfstr(SBuf *sb, SFormat, GCstr *str); +#endif +LJ_FUNC int lj_strfmt_putarg(lua_State *L, SBuf *sb, int arg, int retry); + +/* Conversions to strings. */ +LJ_FUNC GCstr * LJ_FASTCALL lj_strfmt_int(lua_State *L, int32_t k); +LJ_FUNCA GCstr * LJ_FASTCALL lj_strfmt_num(lua_State *L, cTValue *o); +LJ_FUNCA GCstr * LJ_FASTCALL lj_strfmt_number(lua_State *L, cTValue *o); +#if LJ_HASJIT +LJ_FUNC GCstr * LJ_FASTCALL lj_strfmt_char(lua_State *L, int c); +#endif +LJ_FUNC GCstr * LJ_FASTCALL lj_strfmt_obj(lua_State *L, cTValue *o); + +/* Internal string formatting. */ +LJ_FUNC const char *lj_strfmt_pushvf(lua_State *L, const char *fmt, + va_list argp); +LJ_FUNC const char *lj_strfmt_pushf(lua_State *L, const char *fmt, ...) +#if defined(__GNUC__) || defined(__clang__) + __attribute__ ((format (printf, 2, 3))) +#endif + ; + +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_strfmt_num.c b/fluent-bit/lib/luajit-3065c9/src/lj_strfmt_num.c new file mode 100644 index 00000000..3c60695c --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_strfmt_num.c @@ -0,0 +1,592 @@ +/* +** String formatting for floating-point numbers. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +** Contributed by Peter Cawley. +*/ + +#include + +#define lj_strfmt_num_c +#define LUA_CORE + +#include "lj_obj.h" +#include "lj_buf.h" +#include "lj_str.h" +#include "lj_strfmt.h" + +/* -- Precomputed tables -------------------------------------------------- */ + +/* Rescale factors to push the exponent of a number towards zero. */ +#define RESCALE_EXPONENTS(P, N) \ + P(308), P(289), P(270), P(250), P(231), P(212), P(193), P(173), P(154), \ + P(135), P(115), P(96), P(77), P(58), P(38), P(0), P(0), P(0), N(39), N(58), \ + N(77), N(96), N(116), N(135), N(154), N(174), N(193), N(212), N(231), \ + N(251), N(270), N(289) + +#define ONE_E_P(X) 1e+0 ## X +#define ONE_E_N(X) 1e-0 ## X +static const int16_t rescale_e[] = { RESCALE_EXPONENTS(-, +) }; +static const double rescale_n[] = { RESCALE_EXPONENTS(ONE_E_P, ONE_E_N) }; +#undef ONE_E_N +#undef ONE_E_P + +/* +** For p in range -70 through 57, this table encodes pairs (m, e) such that +** 4*2^p <= (uint8_t)m*10^e, and is the smallest value for which this holds. +*/ +static const int8_t four_ulp_m_e[] = { + 34, -21, 68, -21, 14, -20, 28, -20, 55, -20, 2, -19, 3, -19, 5, -19, 9, -19, + -82, -18, 35, -18, 7, -17, -117, -17, 28, -17, 56, -17, 112, -16, -33, -16, + 45, -16, 89, -16, -78, -15, 36, -15, 72, -15, -113, -14, 29, -14, 57, -14, + 114, -13, -28, -13, 46, -13, 91, -12, -74, -12, 37, -12, 73, -12, 15, -11, 3, + -11, 59, -11, 2, -10, 3, -10, 5, -10, 1, -9, -69, -9, 38, -9, 75, -9, 15, -7, + 3, -7, 6, -7, 12, -6, -17, -7, 48, -7, 96, -7, -65, -6, 39, -6, 77, -6, -103, + -5, 31, -5, 62, -5, 123, -4, -11, -4, 49, -4, 98, -4, -60, -3, 4, -2, 79, -3, + 16, -2, 32, -2, 63, -2, 2, -1, 25, 0, 5, 1, 1, 2, 2, 2, 4, 2, 8, 2, 16, 2, + 32, 2, 64, 2, -128, 2, 26, 2, 52, 2, 103, 3, -51, 3, 41, 4, 82, 4, -92, 4, + 33, 4, 66, 4, -124, 5, 27, 5, 53, 5, 105, 6, 21, 6, 42, 6, 84, 6, 17, 7, 34, + 7, 68, 7, 2, 8, 3, 8, 6, 8, 108, 9, -41, 9, 43, 10, 86, 9, -84, 10, 35, 10, + 69, 10, -118, 11, 28, 11, 55, 12, 11, 13, 22, 13, 44, 13, 88, 13, -80, 13, + 36, 13, 71, 13, -115, 14, 29, 14, 57, 14, 113, 15, -30, 15, 46, 15, 91, 15, + 19, 16, 37, 16, 73, 16, 2, 17, 3, 17, 6, 17 +}; + +/* min(2^32-1, 10^e-1) for e in range 0 through 10 */ +static uint32_t ndigits_dec_threshold[] = { + 0, 9U, 99U, 999U, 9999U, 99999U, 999999U, + 9999999U, 99999999U, 999999999U, 0xffffffffU +}; + +/* -- Helper functions ---------------------------------------------------- */ + +/* Compute the number of digits in the decimal representation of x. */ +static MSize ndigits_dec(uint32_t x) +{ + MSize t = ((lj_fls(x | 1) * 77) >> 8) + 1; /* 2^8/77 is roughly log2(10) */ + return t + (x > ndigits_dec_threshold[t]); +} + +#define WINT_R(x, sh, sc) \ + { uint32_t d = (x*(((1<>sh; x -= d*sc; *p++ = (char)('0'+d); } + +/* Write 9-digit unsigned integer to buffer. */ +static char *lj_strfmt_wuint9(char *p, uint32_t u) +{ + uint32_t v = u / 10000, w; + u -= v * 10000; + w = v / 10000; + v -= w * 10000; + *p++ = (char)('0'+w); + WINT_R(v, 23, 1000) + WINT_R(v, 12, 100) + WINT_R(v, 10, 10) + *p++ = (char)('0'+v); + WINT_R(u, 23, 1000) + WINT_R(u, 12, 100) + WINT_R(u, 10, 10) + *p++ = (char)('0'+u); + return p; +} +#undef WINT_R + +/* -- Extended precision arithmetic --------------------------------------- */ + +/* +** The "nd" format is a fixed-precision decimal representation for numbers. It +** consists of up to 64 uint32_t values, with each uint32_t storing a value +** in the range [0, 1e9). A number in "nd" format consists of three variables: +** +** uint32_t nd[64]; +** uint32_t ndlo; +** uint32_t ndhi; +** +** The integral part of the number is stored in nd[0 ... ndhi], the value of +** which is sum{i in [0, ndhi] | nd[i] * 10^(9*i)}. If the fractional part of +** the number is zero, ndlo is zero. Otherwise, the fractional part is stored +** in nd[ndlo ... 63], the value of which is taken to be +** sum{i in [ndlo, 63] | nd[i] * 10^(9*(i-64))}. +** +** If the array part had 128 elements rather than 64, then every double would +** have an exact representation in "nd" format. With 64 elements, all integral +** doubles have an exact representation, and all non-integral doubles have +** enough digits to make both %.99e and %.99f do the right thing. +*/ + +#if LJ_64 +#define ND_MUL2K_MAX_SHIFT 29 +#define ND_MUL2K_DIV1E9(val) ((uint32_t)((val) / 1000000000)) +#else +#define ND_MUL2K_MAX_SHIFT 11 +#define ND_MUL2K_DIV1E9(val) ((uint32_t)((val) >> 9) / 1953125) +#endif + +/* Multiply nd by 2^k and add carry_in (ndlo is assumed to be zero). */ +static uint32_t nd_mul2k(uint32_t* nd, uint32_t ndhi, uint32_t k, + uint32_t carry_in, SFormat sf) +{ + uint32_t i, ndlo = 0, start = 1; + /* Performance hacks. */ + if (k > ND_MUL2K_MAX_SHIFT*2 && STRFMT_FP(sf) != STRFMT_FP(STRFMT_T_FP_F)) { + start = ndhi - (STRFMT_PREC(sf) + 17) / 8; + } + /* Real logic. */ + while (k >= ND_MUL2K_MAX_SHIFT) { + for (i = ndlo; i <= ndhi; i++) { + uint64_t val = ((uint64_t)nd[i] << ND_MUL2K_MAX_SHIFT) | carry_in; + carry_in = ND_MUL2K_DIV1E9(val); + nd[i] = (uint32_t)val - carry_in * 1000000000; + } + if (carry_in) { + nd[++ndhi] = carry_in; carry_in = 0; + if (start++ == ndlo) ++ndlo; + } + k -= ND_MUL2K_MAX_SHIFT; + } + if (k) { + for (i = ndlo; i <= ndhi; i++) { + uint64_t val = ((uint64_t)nd[i] << k) | carry_in; + carry_in = ND_MUL2K_DIV1E9(val); + nd[i] = (uint32_t)val - carry_in * 1000000000; + } + if (carry_in) nd[++ndhi] = carry_in; + } + return ndhi; +} + +/* Divide nd by 2^k (ndlo is assumed to be zero). */ +static uint32_t nd_div2k(uint32_t* nd, uint32_t ndhi, uint32_t k, SFormat sf) +{ + uint32_t ndlo = 0, stop1 = ~0, stop2 = ~0; + /* Performance hacks. */ + if (!ndhi) { + if (!nd[0]) { + return 0; + } else { + uint32_t s = lj_ffs(nd[0]); + if (s >= k) { nd[0] >>= k; return 0; } + nd[0] >>= s; k -= s; + } + } + if (k > 18) { + if (STRFMT_FP(sf) == STRFMT_FP(STRFMT_T_FP_F)) { + stop1 = 63 - (int32_t)STRFMT_PREC(sf) / 9; + } else { + int32_t floorlog2 = ndhi * 29 + lj_fls(nd[ndhi]) - k; + int32_t floorlog10 = (int32_t)(floorlog2 * 0.30102999566398114); + stop1 = 62 + (floorlog10 - (int32_t)STRFMT_PREC(sf)) / 9; + stop2 = 61 + ndhi - (int32_t)STRFMT_PREC(sf) / 8; + } + } + /* Real logic. */ + while (k >= 9) { + uint32_t i = ndhi, carry = 0; + for (;;) { + uint32_t val = nd[i]; + nd[i] = (val >> 9) + carry; + carry = (val & 0x1ff) * 1953125; + if (i == ndlo) break; + i = (i - 1) & 0x3f; + } + if (ndlo != stop1 && ndlo != stop2) { + if (carry) { ndlo = (ndlo - 1) & 0x3f; nd[ndlo] = carry; } + if (!nd[ndhi]) { ndhi = (ndhi - 1) & 0x3f; stop2--; } + } else if (!nd[ndhi]) { + if (ndhi != ndlo) { ndhi = (ndhi - 1) & 0x3f; stop2--; } + else return ndlo; + } + k -= 9; + } + if (k) { + uint32_t mask = (1U << k) - 1, mul = 1000000000 >> k, i = ndhi, carry = 0; + for (;;) { + uint32_t val = nd[i]; + nd[i] = (val >> k) + carry; + carry = (val & mask) * mul; + if (i == ndlo) break; + i = (i - 1) & 0x3f; + } + if (carry) { ndlo = (ndlo - 1) & 0x3f; nd[ndlo] = carry; } + } + return ndlo; +} + +/* Add m*10^e to nd (assumes ndlo <= e/9 <= ndhi and 0 <= m <= 9). */ +static uint32_t nd_add_m10e(uint32_t* nd, uint32_t ndhi, uint8_t m, int32_t e) +{ + uint32_t i, carry; + if (e >= 0) { + i = (uint32_t)e/9; + carry = m * (ndigits_dec_threshold[e - (int32_t)i*9] + 1); + } else { + int32_t f = (e-8)/9; + i = (uint32_t)(64 + f); + carry = m * (ndigits_dec_threshold[e - f*9] + 1); + } + for (;;) { + uint32_t val = nd[i] + carry; + if (LJ_UNLIKELY(val >= 1000000000)) { + val -= 1000000000; + nd[i] = val; + if (LJ_UNLIKELY(i == ndhi)) { + ndhi = (ndhi + 1) & 0x3f; + nd[ndhi] = 1; + break; + } + carry = 1; + i = (i + 1) & 0x3f; + } else { + nd[i] = val; + break; + } + } + return ndhi; +} + +/* Test whether two "nd" values are equal in their most significant digits. */ +static int nd_similar(uint32_t* nd, uint32_t ndhi, uint32_t* ref, MSize hilen, + MSize prec) +{ + char nd9[9], ref9[9]; + if (hilen <= prec) { + if (LJ_UNLIKELY(nd[ndhi] != *ref)) return 0; + prec -= hilen; ref--; ndhi = (ndhi - 1) & 0x3f; + if (prec >= 9) { + if (LJ_UNLIKELY(nd[ndhi] != *ref)) return 0; + prec -= 9; ref--; ndhi = (ndhi - 1) & 0x3f; + } + } else { + prec -= hilen - 9; + } + lj_assertX(prec < 9, "bad precision %d", prec); + lj_strfmt_wuint9(nd9, nd[ndhi]); + lj_strfmt_wuint9(ref9, *ref); + return !memcmp(nd9, ref9, prec) && (nd9[prec] < '5') == (ref9[prec] < '5'); +} + +/* -- Formatted conversions to buffer ------------------------------------- */ + +/* Write formatted floating-point number to either sb or p. */ +static char *lj_strfmt_wfnum(SBuf *sb, SFormat sf, lua_Number n, char *p) +{ + MSize width = STRFMT_WIDTH(sf), prec = STRFMT_PREC(sf), len; + TValue t; + t.n = n; + if (LJ_UNLIKELY((t.u32.hi << 1) >= 0xffe00000)) { + /* Handle non-finite values uniformly for %a, %e, %f, %g. */ + int prefix = 0, ch = (sf & STRFMT_F_UPPER) ? 0x202020 : 0; + if (((t.u32.hi & 0x000fffff) | t.u32.lo) != 0) { + ch ^= ('n' << 16) | ('a' << 8) | 'n'; + if ((sf & STRFMT_F_SPACE)) prefix = ' '; + } else { + ch ^= ('i' << 16) | ('n' << 8) | 'f'; + if ((t.u32.hi & 0x80000000)) prefix = '-'; + else if ((sf & STRFMT_F_PLUS)) prefix = '+'; + else if ((sf & STRFMT_F_SPACE)) prefix = ' '; + } + len = 3 + (prefix != 0); + if (!p) p = lj_buf_more(sb, width > len ? width : len); + if (!(sf & STRFMT_F_LEFT)) while (width-- > len) *p++ = ' '; + if (prefix) *p++ = prefix; + *p++ = (char)(ch >> 16); *p++ = (char)(ch >> 8); *p++ = (char)ch; + } else if (STRFMT_FP(sf) == STRFMT_FP(STRFMT_T_FP_A)) { + /* %a */ + const char *hexdig = (sf & STRFMT_F_UPPER) ? "0123456789ABCDEFPX" + : "0123456789abcdefpx"; + int32_t e = (t.u32.hi >> 20) & 0x7ff; + char prefix = 0, eprefix = '+'; + if (t.u32.hi & 0x80000000) prefix = '-'; + else if ((sf & STRFMT_F_PLUS)) prefix = '+'; + else if ((sf & STRFMT_F_SPACE)) prefix = ' '; + t.u32.hi &= 0xfffff; + if (e) { + t.u32.hi |= 0x100000; + e -= 1023; + } else if (t.u32.lo | t.u32.hi) { + /* Non-zero denormal - normalise it. */ + uint32_t shift = t.u32.hi ? 20-lj_fls(t.u32.hi) : 52-lj_fls(t.u32.lo); + e = -1022 - shift; + t.u64 <<= shift; + } + /* abs(n) == t.u64 * 2^(e - 52) */ + /* If n != 0, bit 52 of t.u64 is set, and is the highest set bit. */ + if ((int32_t)prec < 0) { + /* Default precision: use smallest precision giving exact result. */ + prec = t.u32.lo ? 13-lj_ffs(t.u32.lo)/4 : 5-lj_ffs(t.u32.hi|0x100000)/4; + } else if (prec < 13) { + /* Precision is sufficiently low as to maybe require rounding. */ + t.u64 += (((uint64_t)1) << (51 - prec*4)); + } + if (e < 0) { + eprefix = '-'; + e = -e; + } + len = 5 + ndigits_dec((uint32_t)e) + prec + (prefix != 0) + + ((prec | (sf & STRFMT_F_ALT)) != 0); + if (!p) p = lj_buf_more(sb, width > len ? width : len); + if (!(sf & (STRFMT_F_LEFT | STRFMT_F_ZERO))) { + while (width-- > len) *p++ = ' '; + } + if (prefix) *p++ = prefix; + *p++ = '0'; + *p++ = hexdig[17]; /* x or X */ + if ((sf & (STRFMT_F_LEFT | STRFMT_F_ZERO)) == STRFMT_F_ZERO) { + while (width-- > len) *p++ = '0'; + } + *p++ = '0' + (t.u32.hi >> 20); /* Usually '1', sometimes '0' or '2'. */ + if ((prec | (sf & STRFMT_F_ALT))) { + /* Emit fractional part. */ + char *q = p + 1 + prec; + *p = '.'; + if (prec < 13) t.u64 >>= (52 - prec*4); + else while (prec > 13) p[prec--] = '0'; + while (prec) { p[prec--] = hexdig[t.u64 & 15]; t.u64 >>= 4; } + p = q; + } + *p++ = hexdig[16]; /* p or P */ + *p++ = eprefix; /* + or - */ + p = lj_strfmt_wint(p, e); + } else { + /* %e or %f or %g - begin by converting n to "nd" format. */ + uint32_t nd[64]; + uint32_t ndhi = 0, ndlo, i; + int32_t e = (t.u32.hi >> 20) & 0x7ff, ndebias = 0; + char prefix = 0, *q; + if (t.u32.hi & 0x80000000) prefix = '-'; + else if ((sf & STRFMT_F_PLUS)) prefix = '+'; + else if ((sf & STRFMT_F_SPACE)) prefix = ' '; + prec += ((int32_t)prec >> 31) & 7; /* Default precision is 6. */ + if (STRFMT_FP(sf) == STRFMT_FP(STRFMT_T_FP_G)) { + /* %g - decrement precision if non-zero (to make it like %e). */ + prec--; + prec ^= (uint32_t)((int32_t)prec >> 31); + } + if ((sf & STRFMT_T_FP_E) && prec < 14 && n != 0) { + /* Precision is sufficiently low that rescaling will probably work. */ + if ((ndebias = rescale_e[e >> 6])) { + t.n = n * rescale_n[e >> 6]; + if (LJ_UNLIKELY(!e)) t.n *= 1e10, ndebias -= 10; + t.u64 -= 2; /* Convert 2ulp below (later we convert 2ulp above). */ + nd[0] = 0x100000 | (t.u32.hi & 0xfffff); + e = ((t.u32.hi >> 20) & 0x7ff) - 1075 - (ND_MUL2K_MAX_SHIFT < 29); + goto load_t_lo; rescale_failed: + t.n = n; + e = (t.u32.hi >> 20) & 0x7ff; + ndebias = ndhi = 0; + } + } + nd[0] = t.u32.hi & 0xfffff; + if (e == 0) e++; else nd[0] |= 0x100000; + e -= 1043; + if (t.u32.lo) { + e -= 32 + (ND_MUL2K_MAX_SHIFT < 29); load_t_lo: +#if ND_MUL2K_MAX_SHIFT >= 29 + nd[0] = (nd[0] << 3) | (t.u32.lo >> 29); + ndhi = nd_mul2k(nd, ndhi, 29, t.u32.lo & 0x1fffffff, sf); +#elif ND_MUL2K_MAX_SHIFT >= 11 + ndhi = nd_mul2k(nd, ndhi, 11, t.u32.lo >> 21, sf); + ndhi = nd_mul2k(nd, ndhi, 11, (t.u32.lo >> 10) & 0x7ff, sf); + ndhi = nd_mul2k(nd, ndhi, 11, (t.u32.lo << 1) & 0x7ff, sf); +#else +#error "ND_MUL2K_MAX_SHIFT too small" +#endif + } + if (e >= 0) { + ndhi = nd_mul2k(nd, ndhi, (uint32_t)e, 0, sf); + ndlo = 0; + } else { + ndlo = nd_div2k(nd, ndhi, (uint32_t)-e, sf); + if (ndhi && !nd[ndhi]) ndhi--; + } + /* abs(n) == nd * 10^ndebias (for slightly loose interpretation of ==) */ + if ((sf & STRFMT_T_FP_E)) { + /* %e or %g - assume %e and start by calculating nd's exponent (nde). */ + char eprefix = '+'; + int32_t nde = -1; + MSize hilen; + if (ndlo && !nd[ndhi]) { + ndhi = 64; do {} while (!nd[--ndhi]); + nde -= 64 * 9; + } + hilen = ndigits_dec(nd[ndhi]); + nde += ndhi * 9 + hilen; + if (ndebias) { + /* + ** Rescaling was performed, but this introduced some error, and might + ** have pushed us across a rounding boundary. We check whether this + ** error affected the result by introducing even more error (2ulp in + ** either direction), and seeing whether a rounding boundary was + ** crossed. Having already converted the -2ulp case, we save off its + ** most significant digits, convert the +2ulp case, and compare them. + */ + int32_t eidx = e + 70 + (ND_MUL2K_MAX_SHIFT < 29) + + (t.u32.lo >= 0xfffffffe && !(~t.u32.hi << 12)); + const int8_t *m_e = four_ulp_m_e + eidx * 2; + lj_assertG_(G(sbufL(sb)), 0 <= eidx && eidx < 128, "bad eidx %d", eidx); + nd[33] = nd[ndhi]; + nd[32] = nd[(ndhi - 1) & 0x3f]; + nd[31] = nd[(ndhi - 2) & 0x3f]; + nd_add_m10e(nd, ndhi, (uint8_t)*m_e, m_e[1]); + if (LJ_UNLIKELY(!nd_similar(nd, ndhi, nd + 33, hilen, prec + 1))) { + goto rescale_failed; + } + } + if ((int32_t)(prec - nde) < (0x3f & -(int32_t)ndlo) * 9) { + /* Precision is sufficiently low as to maybe require rounding. */ + ndhi = nd_add_m10e(nd, ndhi, 5, nde - prec - 1); + nde += (hilen != ndigits_dec(nd[ndhi])); + } + nde += ndebias; + if ((sf & STRFMT_T_FP_F)) { + /* %g */ + if ((int32_t)prec >= nde && nde >= -4) { + if (nde < 0) ndhi = 0; + prec -= nde; + goto g_format_like_f; + } else if (!(sf & STRFMT_F_ALT) && prec && width > 5) { + /* Decrease precision in order to strip trailing zeroes. */ + char tail[9]; + uint32_t maxprec = hilen - 1 + ((ndhi - ndlo) & 0x3f) * 9; + if (prec >= maxprec) prec = maxprec; + else ndlo = (ndhi - (((int32_t)(prec - hilen) + 9) / 9)) & 0x3f; + i = prec - hilen - (((ndhi - ndlo) & 0x3f) * 9) + 10; + lj_strfmt_wuint9(tail, nd[ndlo]); + while (prec && tail[--i] == '0') { + prec--; + if (!i) { + if (ndlo == ndhi) { prec = 0; break; } + lj_strfmt_wuint9(tail, nd[++ndlo]); + i = 9; + } + } + } + } + if (nde < 0) { + /* Make nde non-negative. */ + eprefix = '-'; + nde = -nde; + } + len = 3 + prec + (prefix != 0) + ndigits_dec((uint32_t)nde) + (nde < 10) + + ((prec | (sf & STRFMT_F_ALT)) != 0); + if (!p) p = lj_buf_more(sb, (width > len ? width : len) + 5); + if (!(sf & (STRFMT_F_LEFT | STRFMT_F_ZERO))) { + while (width-- > len) *p++ = ' '; + } + if (prefix) *p++ = prefix; + if ((sf & (STRFMT_F_LEFT | STRFMT_F_ZERO)) == STRFMT_F_ZERO) { + while (width-- > len) *p++ = '0'; + } + q = lj_strfmt_wint(p + 1, nd[ndhi]); + p[0] = p[1]; /* Put leading digit in the correct place. */ + if ((prec | (sf & STRFMT_F_ALT))) { + /* Emit fractional part. */ + p[1] = '.'; p += 2; + prec -= (MSize)(q - p); p = q; /* Account for digits already emitted. */ + /* Then emit chunks of 9 digits (this may emit 8 digits too many). */ + for (i = ndhi; (int32_t)prec > 0 && i != ndlo; prec -= 9) { + i = (i - 1) & 0x3f; + p = lj_strfmt_wuint9(p, nd[i]); + } + if ((sf & STRFMT_T_FP_F) && !(sf & STRFMT_F_ALT)) { + /* %g (and not %#g) - strip trailing zeroes. */ + p += (int32_t)prec & ((int32_t)prec >> 31); + while (p[-1] == '0') p--; + if (p[-1] == '.') p--; + } else { + /* %e (or %#g) - emit trailing zeroes. */ + while ((int32_t)prec > 0) { *p++ = '0'; prec--; } + p += (int32_t)prec; + } + } else { + p++; + } + *p++ = (sf & STRFMT_F_UPPER) ? 'E' : 'e'; + *p++ = eprefix; /* + or - */ + if (nde < 10) *p++ = '0'; /* Always at least two digits of exponent. */ + p = lj_strfmt_wint(p, nde); + } else { + /* %f (or, shortly, %g in %f style) */ + if (prec < (MSize)(0x3f & -(int32_t)ndlo) * 9) { + /* Precision is sufficiently low as to maybe require rounding. */ + ndhi = nd_add_m10e(nd, ndhi, 5, 0 - prec - 1); + } + g_format_like_f: + if ((sf & STRFMT_T_FP_E) && !(sf & STRFMT_F_ALT) && prec && width) { + /* Decrease precision in order to strip trailing zeroes. */ + if (ndlo) { + /* nd has a fractional part; we need to look at its digits. */ + char tail[9]; + uint32_t maxprec = (64 - ndlo) * 9; + if (prec >= maxprec) prec = maxprec; + else ndlo = 64 - (prec + 8) / 9; + i = prec - ((63 - ndlo) * 9); + lj_strfmt_wuint9(tail, nd[ndlo]); + while (prec && tail[--i] == '0') { + prec--; + if (!i) { + if (ndlo == 63) { prec = 0; break; } + lj_strfmt_wuint9(tail, nd[++ndlo]); + i = 9; + } + } + } else { + /* nd has no fractional part, so precision goes straight to zero. */ + prec = 0; + } + } + len = ndhi * 9 + ndigits_dec(nd[ndhi]) + prec + (prefix != 0) + + ((prec | (sf & STRFMT_F_ALT)) != 0); + if (!p) p = lj_buf_more(sb, (width > len ? width : len) + 8); + if (!(sf & (STRFMT_F_LEFT | STRFMT_F_ZERO))) { + while (width-- > len) *p++ = ' '; + } + if (prefix) *p++ = prefix; + if ((sf & (STRFMT_F_LEFT | STRFMT_F_ZERO)) == STRFMT_F_ZERO) { + while (width-- > len) *p++ = '0'; + } + /* Emit integer part. */ + p = lj_strfmt_wint(p, nd[ndhi]); + i = ndhi; + while (i) p = lj_strfmt_wuint9(p, nd[--i]); + if ((prec | (sf & STRFMT_F_ALT))) { + /* Emit fractional part. */ + *p++ = '.'; + /* Emit chunks of 9 digits (this may emit 8 digits too many). */ + while ((int32_t)prec > 0 && i != ndlo) { + i = (i - 1) & 0x3f; + p = lj_strfmt_wuint9(p, nd[i]); + prec -= 9; + } + if ((sf & STRFMT_T_FP_E) && !(sf & STRFMT_F_ALT)) { + /* %g (and not %#g) - strip trailing zeroes. */ + p += (int32_t)prec & ((int32_t)prec >> 31); + while (p[-1] == '0') p--; + if (p[-1] == '.') p--; + } else { + /* %f (or %#g) - emit trailing zeroes. */ + while ((int32_t)prec > 0) { *p++ = '0'; prec--; } + p += (int32_t)prec; + } + } + } + } + if ((sf & STRFMT_F_LEFT)) while (width-- > len) *p++ = ' '; + return p; +} + +/* Add formatted floating-point number to buffer. */ +SBuf *lj_strfmt_putfnum(SBuf *sb, SFormat sf, lua_Number n) +{ + sb->w = lj_strfmt_wfnum(sb, sf, n, NULL); + return sb; +} + +/* -- Conversions to strings ---------------------------------------------- */ + +/* Convert number to string. */ +GCstr * LJ_FASTCALL lj_strfmt_num(lua_State *L, cTValue *o) +{ + char buf[STRFMT_MAXBUF_NUM]; + MSize len = (MSize)(lj_strfmt_wfnum(NULL, STRFMT_G14, o->n, buf) - buf); + return lj_str_new(L, buf, len); +} + diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_strscan.c b/fluent-bit/lib/luajit-3065c9/src/lj_strscan.c new file mode 100644 index 00000000..1d1c1c74 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_strscan.c @@ -0,0 +1,558 @@ +/* +** String scanning. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#include + +#define lj_strscan_c +#define LUA_CORE + +#include "lj_obj.h" +#include "lj_char.h" +#include "lj_strscan.h" + +/* -- Scanning numbers ---------------------------------------------------- */ + +/* +** Rationale for the builtin string to number conversion library: +** +** It removes a dependency on libc's strtod(), which is a true portability +** nightmare. Mainly due to the plethora of supported OS and toolchain +** combinations. Sadly, the various implementations +** a) are often buggy, incomplete (no hex floats) and/or imprecise, +** b) sometimes crash or hang on certain inputs, +** c) return non-standard NaNs that need to be filtered out, and +** d) fail if the locale-specific decimal separator is not a dot, +** which can only be fixed with atrocious workarounds. +** +** Also, most of the strtod() implementations are hopelessly bloated, +** which is not just an I-cache hog, but a problem for static linkage +** on embedded systems, too. +** +** OTOH the builtin conversion function is very compact. Even though it +** does a lot more, like parsing long longs, octal or imaginary numbers +** and returning the result in different formats: +** a) It needs less than 3 KB (!) of machine code (on x64 with -Os), +** b) it doesn't perform any dynamic allocation and, +** c) it needs only around 600 bytes of stack space. +** +** The builtin function is faster than strtod() for typical inputs, e.g. +** "123", "1.5" or "1e6". Arguably, it's slower for very large exponents, +** which are not very common (this could be fixed, if needed). +** +** And most importantly, the builtin function is equally precise on all +** platforms. It correctly converts and rounds any input to a double. +** If this is not the case, please send a bug report -- but PLEASE verify +** that the implementation you're comparing to is not the culprit! +** +** The implementation quickly pre-scans the entire string first and +** handles simple integers on-the-fly. Otherwise, it dispatches to the +** base-specific parser. Hex and octal is straightforward. +** +** Decimal to binary conversion uses a fixed-length circular buffer in +** base 100. Some simple cases are handled directly. For other cases, the +** number in the buffer is up-scaled or down-scaled until the integer part +** is in the proper range. Then the integer part is rounded and converted +** to a double which is finally rescaled to the result. Denormals need +** special treatment to prevent incorrect 'double rounding'. +*/ + +/* Definitions for circular decimal digit buffer (base 100 = 2 digits/byte). */ +#define STRSCAN_DIG 1024 +#define STRSCAN_MAXDIG 800 /* 772 + extra are sufficient. */ +#define STRSCAN_DDIG (STRSCAN_DIG/2) +#define STRSCAN_DMASK (STRSCAN_DDIG-1) +#define STRSCAN_MAXEXP (1 << 20) + +/* Helpers for circular buffer. */ +#define DNEXT(a) (((a)+1) & STRSCAN_DMASK) +#define DPREV(a) (((a)-1) & STRSCAN_DMASK) +#define DLEN(lo, hi) ((int32_t)(((lo)-(hi)) & STRSCAN_DMASK)) + +#define casecmp(c, k) (((c) | 0x20) == k) + +/* Final conversion to double. */ +static void strscan_double(uint64_t x, TValue *o, int32_t ex2, int32_t neg) +{ + double n; + + /* Avoid double rounding for denormals. */ + if (LJ_UNLIKELY(ex2 <= -1075 && x != 0)) { + /* NYI: all of this generates way too much code on 32 bit CPUs. */ +#if (defined(__GNUC__) || defined(__clang__)) && LJ_64 + int32_t b = (int32_t)(__builtin_clzll(x)^63); +#else + int32_t b = (x>>32) ? 32+(int32_t)lj_fls((uint32_t)(x>>32)) : + (int32_t)lj_fls((uint32_t)x); +#endif + if ((int32_t)b + ex2 <= -1023 && (int32_t)b + ex2 >= -1075) { + uint64_t rb = (uint64_t)1 << (-1075-ex2); + if ((x & rb) && ((x & (rb+rb+rb-1)))) x += rb+rb; + x = (x & ~(rb+rb-1)); + } + } + + /* Convert to double using a signed int64_t conversion, then rescale. */ + lj_assertX((int64_t)x >= 0, "bad double conversion"); + n = (double)(int64_t)x; + if (neg) n = -n; + if (ex2) n = ldexp(n, ex2); + o->n = n; +} + +/* Parse hexadecimal number. */ +static StrScanFmt strscan_hex(const uint8_t *p, TValue *o, + StrScanFmt fmt, uint32_t opt, + int32_t ex2, int32_t neg, uint32_t dig) +{ + uint64_t x = 0; + uint32_t i; + + /* Scan hex digits. */ + for (i = dig > 16 ? 16 : dig ; i; i--, p++) { + uint32_t d = (*p != '.' ? *p : *++p); if (d > '9') d += 9; + x = (x << 4) + (d & 15); + } + + /* Summarize rounding-effect of excess digits. */ + for (i = 16; i < dig; i++, p++) + x |= ((*p != '.' ? *p : *++p) != '0'), ex2 += 4; + + /* Format-specific handling. */ + switch (fmt) { + case STRSCAN_INT: + if (!(opt & STRSCAN_OPT_TONUM) && x < 0x80000000u+neg && + !(x == 0 && neg)) { + o->i = neg ? -(int32_t)x : (int32_t)x; + return STRSCAN_INT; /* Fast path for 32 bit integers. */ + } + if (!(opt & STRSCAN_OPT_C)) { fmt = STRSCAN_NUM; break; } + /* fallthrough */ + case STRSCAN_U32: + if (dig > 8) return STRSCAN_ERROR; + o->i = neg ? -(int32_t)x : (int32_t)x; + return STRSCAN_U32; + case STRSCAN_I64: + case STRSCAN_U64: + if (dig > 16) return STRSCAN_ERROR; + o->u64 = neg ? (uint64_t)-(int64_t)x : x; + return fmt; + default: + break; + } + + /* Reduce range, then convert to double. */ + if ((x & U64x(c0000000,0000000))) { x = (x >> 2) | (x & 3); ex2 += 2; } + strscan_double(x, o, ex2, neg); + return fmt; +} + +/* Parse octal number. */ +static StrScanFmt strscan_oct(const uint8_t *p, TValue *o, + StrScanFmt fmt, int32_t neg, uint32_t dig) +{ + uint64_t x = 0; + + /* Scan octal digits. */ + if (dig > 22 || (dig == 22 && *p > '1')) return STRSCAN_ERROR; + while (dig-- > 0) { + if (!(*p >= '0' && *p <= '7')) return STRSCAN_ERROR; + x = (x << 3) + (*p++ & 7); + } + + /* Format-specific handling. */ + switch (fmt) { + case STRSCAN_INT: + if (x >= 0x80000000u+neg) fmt = STRSCAN_U32; + /* fallthrough */ + case STRSCAN_U32: + if ((x >> 32)) return STRSCAN_ERROR; + o->i = neg ? -(int32_t)x : (int32_t)x; + break; + default: + case STRSCAN_I64: + case STRSCAN_U64: + o->u64 = neg ? (uint64_t)-(int64_t)x : x; + break; + } + return fmt; +} + +/* Parse decimal number. */ +static StrScanFmt strscan_dec(const uint8_t *p, TValue *o, + StrScanFmt fmt, uint32_t opt, + int32_t ex10, int32_t neg, uint32_t dig) +{ + uint8_t xi[STRSCAN_DDIG], *xip = xi; + + if (dig) { + uint32_t i = dig; + if (i > STRSCAN_MAXDIG) { + ex10 += (int32_t)(i - STRSCAN_MAXDIG); + i = STRSCAN_MAXDIG; + } + /* Scan unaligned leading digit. */ + if (((ex10^i) & 1)) + *xip++ = ((*p != '.' ? *p : *++p) & 15), i--, p++; + /* Scan aligned double-digits. */ + for ( ; i > 1; i -= 2) { + uint32_t d = 10 * ((*p != '.' ? *p : *++p) & 15); p++; + *xip++ = d + ((*p != '.' ? *p : *++p) & 15); p++; + } + /* Scan and realign trailing digit. */ + if (i) *xip++ = 10 * ((*p != '.' ? *p : *++p) & 15), ex10--, dig++, p++; + + /* Summarize rounding-effect of excess digits. */ + if (dig > STRSCAN_MAXDIG) { + do { + if ((*p != '.' ? *p : *++p) != '0') { xip[-1] |= 1; break; } + p++; + } while (--dig > STRSCAN_MAXDIG); + dig = STRSCAN_MAXDIG; + } else { /* Simplify exponent. */ + while (ex10 > 0 && dig <= 18) *xip++ = 0, ex10 -= 2, dig += 2; + } + } else { /* Only got zeros. */ + ex10 = 0; + xi[0] = 0; + } + + /* Fast path for numbers in integer format (but handles e.g. 1e6, too). */ + if (dig <= 20 && ex10 == 0) { + uint8_t *xis; + uint64_t x = xi[0]; + double n; + for (xis = xi+1; xis < xip; xis++) x = x * 100 + *xis; + if (!(dig == 20 && (xi[0] > 18 || (int64_t)x >= 0))) { /* No overflow? */ + /* Format-specific handling. */ + switch (fmt) { + case STRSCAN_INT: + if (!(opt & STRSCAN_OPT_TONUM) && x < 0x80000000u+neg) { + o->i = neg ? -(int32_t)x : (int32_t)x; + return STRSCAN_INT; /* Fast path for 32 bit integers. */ + } + if (!(opt & STRSCAN_OPT_C)) { fmt = STRSCAN_NUM; goto plainnumber; } + /* fallthrough */ + case STRSCAN_U32: + if ((x >> 32) != 0) return STRSCAN_ERROR; + o->i = neg ? -(int32_t)x : (int32_t)x; + return STRSCAN_U32; + case STRSCAN_I64: + case STRSCAN_U64: + o->u64 = neg ? (uint64_t)-(int64_t)x : x; + return fmt; + default: + plainnumber: /* Fast path for plain numbers < 2^63. */ + if ((int64_t)x < 0) break; + n = (double)(int64_t)x; + if (neg) n = -n; + o->n = n; + return fmt; + } + } + } + + /* Slow non-integer path. */ + if (fmt == STRSCAN_INT) { + if ((opt & STRSCAN_OPT_C)) return STRSCAN_ERROR; + fmt = STRSCAN_NUM; + } else if (fmt > STRSCAN_INT) { + return STRSCAN_ERROR; + } + { + uint32_t hi = 0, lo = (uint32_t)(xip-xi); + int32_t ex2 = 0, idig = (int32_t)lo + (ex10 >> 1); + + lj_assertX(lo > 0 && (ex10 & 1) == 0, "bad lo %d ex10 %d", lo, ex10); + + /* Handle simple overflow/underflow. */ + if (idig > 310/2) { if (neg) setminfV(o); else setpinfV(o); return fmt; } + else if (idig < -326/2) { o->n = neg ? -0.0 : 0.0; return fmt; } + + /* Scale up until we have at least 17 or 18 integer part digits. */ + while (idig < 9 && idig < DLEN(lo, hi)) { + uint32_t i, cy = 0; + ex2 -= 6; + for (i = DPREV(lo); ; i = DPREV(i)) { + uint32_t d = (xi[i] << 6) + cy; + cy = (((d >> 2) * 5243) >> 17); d = d - cy * 100; /* Div/mod 100. */ + xi[i] = (uint8_t)d; + if (i == hi) break; + if (d == 0 && i == DPREV(lo)) lo = i; + } + if (cy) { + hi = DPREV(hi); + if (xi[DPREV(lo)] == 0) lo = DPREV(lo); + else if (hi == lo) { lo = DPREV(lo); xi[DPREV(lo)] |= xi[lo]; } + xi[hi] = (uint8_t)cy; idig++; + } + } + + /* Scale down until no more than 17 or 18 integer part digits remain. */ + while (idig > 9) { + uint32_t i = hi, cy = 0; + ex2 += 6; + do { + cy += xi[i]; + xi[i] = (cy >> 6); + cy = 100 * (cy & 0x3f); + if (xi[i] == 0 && i == hi) hi = DNEXT(hi), idig--; + i = DNEXT(i); + } while (i != lo); + while (cy) { + if (hi == lo) { xi[DPREV(lo)] |= 1; break; } + xi[lo] = (cy >> 6); lo = DNEXT(lo); + cy = 100 * (cy & 0x3f); + } + } + + /* Collect integer part digits and convert to rescaled double. */ + { + uint64_t x = xi[hi]; + uint32_t i; + for (i = DNEXT(hi); --idig > 0 && i != lo; i = DNEXT(i)) + x = x * 100 + xi[i]; + if (i == lo) { + while (--idig >= 0) x = x * 100; + } else { /* Gather round bit from remaining digits. */ + x <<= 1; ex2--; + do { + if (xi[i]) { x |= 1; break; } + i = DNEXT(i); + } while (i != lo); + } + strscan_double(x, o, ex2, neg); + } + } + return fmt; +} + +/* Parse binary number. */ +static StrScanFmt strscan_bin(const uint8_t *p, TValue *o, + StrScanFmt fmt, uint32_t opt, + int32_t ex2, int32_t neg, uint32_t dig) +{ + uint64_t x = 0; + uint32_t i; + + if (ex2 || dig > 64) return STRSCAN_ERROR; + + /* Scan binary digits. */ + for (i = dig; i; i--, p++) { + if ((*p & ~1) != '0') return STRSCAN_ERROR; + x = (x << 1) | (*p & 1); + } + + /* Format-specific handling. */ + switch (fmt) { + case STRSCAN_INT: + if (!(opt & STRSCAN_OPT_TONUM) && x < 0x80000000u+neg) { + o->i = neg ? -(int32_t)x : (int32_t)x; + return STRSCAN_INT; /* Fast path for 32 bit integers. */ + } + if (!(opt & STRSCAN_OPT_C)) { fmt = STRSCAN_NUM; break; } + /* fallthrough */ + case STRSCAN_U32: + if (dig > 32) return STRSCAN_ERROR; + o->i = neg ? -(int32_t)x : (int32_t)x; + return STRSCAN_U32; + case STRSCAN_I64: + case STRSCAN_U64: + o->u64 = neg ? (uint64_t)-(int64_t)x : x; + return fmt; + default: + break; + } + + /* Reduce range, then convert to double. */ + if ((x & U64x(c0000000,0000000))) { x = (x >> 2) | (x & 3); ex2 += 2; } + strscan_double(x, o, ex2, neg); + return fmt; +} + +/* Scan string containing a number. Returns format. Returns value in o. */ +StrScanFmt lj_strscan_scan(const uint8_t *p, MSize len, TValue *o, + uint32_t opt) +{ + int32_t neg = 0; + const uint8_t *pe = p + len; + + /* Remove leading space, parse sign and non-numbers. */ + if (LJ_UNLIKELY(!lj_char_isdigit(*p))) { + while (lj_char_isspace(*p)) p++; + if (*p == '+' || *p == '-') neg = (*p++ == '-'); + if (LJ_UNLIKELY(*p >= 'A')) { /* Parse "inf", "infinity" or "nan". */ + TValue tmp; + setnanV(&tmp); + if (casecmp(p[0],'i') && casecmp(p[1],'n') && casecmp(p[2],'f')) { + if (neg) setminfV(&tmp); else setpinfV(&tmp); + p += 3; + if (casecmp(p[0],'i') && casecmp(p[1],'n') && casecmp(p[2],'i') && + casecmp(p[3],'t') && casecmp(p[4],'y')) p += 5; + } else if (casecmp(p[0],'n') && casecmp(p[1],'a') && casecmp(p[2],'n')) { + p += 3; + } + while (lj_char_isspace(*p)) p++; + if (*p || p < pe) return STRSCAN_ERROR; + o->u64 = tmp.u64; + return STRSCAN_NUM; + } + } + + /* Parse regular number. */ + { + StrScanFmt fmt = STRSCAN_INT; + int cmask = LJ_CHAR_DIGIT; + int base = (opt & STRSCAN_OPT_C) && *p == '0' ? 0 : 10; + const uint8_t *sp, *dp = NULL; + uint32_t dig = 0, hasdig = 0, x = 0; + int32_t ex = 0; + + /* Determine base and skip leading zeros. */ + if (LJ_UNLIKELY(*p <= '0')) { + if (*p == '0') { + if (casecmp(p[1], 'x')) + base = 16, cmask = LJ_CHAR_XDIGIT, p += 2; + else if (casecmp(p[1], 'b')) + base = 2, cmask = LJ_CHAR_DIGIT, p += 2; + } + for ( ; ; p++) { + if (*p == '0') { + hasdig = 1; + } else if (*p == '.') { + if (dp) return STRSCAN_ERROR; + dp = p; + } else { + break; + } + } + } + + /* Preliminary digit and decimal point scan. */ + for (sp = p; ; p++) { + if (LJ_LIKELY(lj_char_isa(*p, cmask))) { + x = x * 10 + (*p & 15); /* For fast path below. */ + dig++; + } else if (*p == '.') { + if (dp) return STRSCAN_ERROR; + dp = p; + } else { + break; + } + } + if (!(hasdig | dig)) return STRSCAN_ERROR; + + /* Handle decimal point. */ + if (dp) { + if (base == 2) return STRSCAN_ERROR; + fmt = STRSCAN_NUM; + if (dig) { + ex = (int32_t)(dp-(p-1)); dp = p-1; + while (ex < 0 && *dp-- == '0') ex++, dig--; /* Skip trailing zeros. */ + if (ex <= -STRSCAN_MAXEXP) return STRSCAN_ERROR; + if (base == 16) ex *= 4; + } + } + + /* Parse exponent. */ + if (base >= 10 && casecmp(*p, (uint32_t)(base == 16 ? 'p' : 'e'))) { + uint32_t xx; + int negx = 0; + fmt = STRSCAN_NUM; p++; + if (*p == '+' || *p == '-') negx = (*p++ == '-'); + if (!lj_char_isdigit(*p)) return STRSCAN_ERROR; + xx = (*p++ & 15); + while (lj_char_isdigit(*p)) { + xx = xx * 10 + (*p & 15); + if (xx >= STRSCAN_MAXEXP) return STRSCAN_ERROR; + p++; + } + ex += negx ? -(int32_t)xx : (int32_t)xx; + } + + /* Parse suffix. */ + if (*p) { + /* I (IMAG), U (U32), LL (I64), ULL/LLU (U64), L (long), UL/LU (ulong). */ + /* NYI: f (float). Not needed until cp_number() handles non-integers. */ + if (casecmp(*p, 'i')) { + if (!(opt & STRSCAN_OPT_IMAG)) return STRSCAN_ERROR; + p++; fmt = STRSCAN_IMAG; + } else if (fmt == STRSCAN_INT) { + if (casecmp(*p, 'u')) p++, fmt = STRSCAN_U32; + if (casecmp(*p, 'l')) { + p++; + if (casecmp(*p, 'l')) p++, fmt += STRSCAN_I64 - STRSCAN_INT; + else if (!(opt & STRSCAN_OPT_C)) return STRSCAN_ERROR; + else if (sizeof(long) == 8) fmt += STRSCAN_I64 - STRSCAN_INT; + } + if (casecmp(*p, 'u') && (fmt == STRSCAN_INT || fmt == STRSCAN_I64)) + p++, fmt += STRSCAN_U32 - STRSCAN_INT; + if ((fmt == STRSCAN_U32 && !(opt & STRSCAN_OPT_C)) || + (fmt >= STRSCAN_I64 && !(opt & STRSCAN_OPT_LL))) + return STRSCAN_ERROR; + } + while (lj_char_isspace(*p)) p++; + if (*p) return STRSCAN_ERROR; + } + if (p < pe) return STRSCAN_ERROR; + + /* Fast path for decimal 32 bit integers. */ + if (fmt == STRSCAN_INT && base == 10 && + (dig < 10 || (dig == 10 && *sp <= '2' && x < 0x80000000u+neg))) { + if ((opt & STRSCAN_OPT_TONUM)) { + o->n = neg ? -(double)x : (double)x; + return STRSCAN_NUM; + } else if (x == 0 && neg) { + o->n = -0.0; + return STRSCAN_NUM; + } else { + o->i = neg ? -(int32_t)x : (int32_t)x; + return STRSCAN_INT; + } + } + + /* Dispatch to base-specific parser. */ + if (base == 0 && !(fmt == STRSCAN_NUM || fmt == STRSCAN_IMAG)) + return strscan_oct(sp, o, fmt, neg, dig); + if (base == 16) + fmt = strscan_hex(sp, o, fmt, opt, ex, neg, dig); + else if (base == 2) + fmt = strscan_bin(sp, o, fmt, opt, ex, neg, dig); + else + fmt = strscan_dec(sp, o, fmt, opt, ex, neg, dig); + + /* Try to convert number to integer, if requested. */ + if (fmt == STRSCAN_NUM && (opt & STRSCAN_OPT_TOINT) && !tvismzero(o)) { + double n = o->n; + int32_t i = lj_num2int(n); + if (n == (lua_Number)i) { o->i = i; return STRSCAN_INT; } + } + return fmt; + } +} + +int LJ_FASTCALL lj_strscan_num(GCstr *str, TValue *o) +{ + StrScanFmt fmt = lj_strscan_scan((const uint8_t *)strdata(str), str->len, o, + STRSCAN_OPT_TONUM); + lj_assertX(fmt == STRSCAN_ERROR || fmt == STRSCAN_NUM, "bad scan format"); + return (fmt != STRSCAN_ERROR); +} + +#if LJ_DUALNUM +int LJ_FASTCALL lj_strscan_number(GCstr *str, TValue *o) +{ + StrScanFmt fmt = lj_strscan_scan((const uint8_t *)strdata(str), str->len, o, + STRSCAN_OPT_TOINT); + lj_assertX(fmt == STRSCAN_ERROR || fmt == STRSCAN_NUM || fmt == STRSCAN_INT, + "bad scan format"); + if (fmt == STRSCAN_INT) setitype(o, LJ_TISNUM); + return (fmt != STRSCAN_ERROR); +} +#endif + +#undef DNEXT +#undef DPREV +#undef DLEN + diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_strscan.h b/fluent-bit/lib/luajit-3065c9/src/lj_strscan.h new file mode 100644 index 00000000..8ed31542 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_strscan.h @@ -0,0 +1,40 @@ +/* +** String scanning. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#ifndef _LJ_STRSCAN_H +#define _LJ_STRSCAN_H + +#include "lj_obj.h" + +/* Options for accepted/returned formats. */ +#define STRSCAN_OPT_TOINT 0x01 /* Convert to int32_t, if possible. */ +#define STRSCAN_OPT_TONUM 0x02 /* Always convert to double. */ +#define STRSCAN_OPT_IMAG 0x04 +#define STRSCAN_OPT_LL 0x08 +#define STRSCAN_OPT_C 0x10 + +/* Returned format. */ +typedef enum { + STRSCAN_ERROR, + STRSCAN_NUM, STRSCAN_IMAG, + STRSCAN_INT, STRSCAN_U32, STRSCAN_I64, STRSCAN_U64, +} StrScanFmt; + +LJ_FUNC StrScanFmt lj_strscan_scan(const uint8_t *p, MSize len, TValue *o, + uint32_t opt); +LJ_FUNC int LJ_FASTCALL lj_strscan_num(GCstr *str, TValue *o); +#if LJ_DUALNUM +LJ_FUNC int LJ_FASTCALL lj_strscan_number(GCstr *str, TValue *o); +#else +#define lj_strscan_number(s, o) lj_strscan_num((s), (o)) +#endif + +/* Check for number or convert string to number/int in-place (!). */ +static LJ_AINLINE int lj_strscan_numberobj(TValue *o) +{ + return tvisnumber(o) || (tvisstr(o) && lj_strscan_number(strV(o), o)); +} + +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_tab.c b/fluent-bit/lib/luajit-3065c9/src/lj_tab.c new file mode 100644 index 00000000..c3609b38 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_tab.c @@ -0,0 +1,693 @@ +/* +** Table handling. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +** +** Major portions taken verbatim or adapted from the Lua interpreter. +** Copyright (C) 1994-2008 Lua.org, PUC-Rio. See Copyright Notice in lua.h +*/ + +#define lj_tab_c +#define LUA_CORE + +#include "lj_obj.h" +#include "lj_gc.h" +#include "lj_err.h" +#include "lj_tab.h" + +/* -- Object hashing ------------------------------------------------------ */ + +/* Hash an arbitrary key and return its anchor position in the hash table. */ +static Node *hashkey(const GCtab *t, cTValue *key) +{ + lj_assertX(!tvisint(key), "attempt to hash integer"); + if (tvisstr(key)) + return hashstr(t, strV(key)); + else if (tvisnum(key)) + return hashnum(t, key); + else if (tvisbool(key)) + return hashmask(t, boolV(key)); + else + return hashgcref(t, key->gcr); + /* Only hash 32 bits of lightuserdata on a 64 bit CPU. Good enough? */ +} + +/* -- Table creation and destruction -------------------------------------- */ + +/* Create new hash part for table. */ +static LJ_AINLINE void newhpart(lua_State *L, GCtab *t, uint32_t hbits) +{ + uint32_t hsize; + Node *node; + lj_assertL(hbits != 0, "zero hash size"); + if (hbits > LJ_MAX_HBITS) + lj_err_msg(L, LJ_ERR_TABOV); + hsize = 1u << hbits; + node = lj_mem_newvec(L, hsize, Node); + setmref(t->node, node); + setfreetop(t, node, &node[hsize]); + t->hmask = hsize-1; +} + +/* +** Q: Why all of these copies of t->hmask, t->node etc. to local variables? +** A: Because alias analysis for C is _really_ tough. +** Even state-of-the-art C compilers won't produce good code without this. +*/ + +/* Clear hash part of table. */ +static LJ_AINLINE void clearhpart(GCtab *t) +{ + uint32_t i, hmask = t->hmask; + Node *node = noderef(t->node); + lj_assertX(t->hmask != 0, "empty hash part"); + for (i = 0; i <= hmask; i++) { + Node *n = &node[i]; + setmref(n->next, NULL); + setnilV(&n->key); + setnilV(&n->val); + } +} + +/* Clear array part of table. */ +static LJ_AINLINE void clearapart(GCtab *t) +{ + uint32_t i, asize = t->asize; + TValue *array = tvref(t->array); + for (i = 0; i < asize; i++) + setnilV(&array[i]); +} + +/* Create a new table. Note: the slots are not initialized (yet). */ +static GCtab *newtab(lua_State *L, uint32_t asize, uint32_t hbits) +{ + GCtab *t; + /* First try to colocate the array part. */ + if (LJ_MAX_COLOSIZE != 0 && asize > 0 && asize <= LJ_MAX_COLOSIZE) { + Node *nilnode; + lj_assertL((sizeof(GCtab) & 7) == 0, "bad GCtab size"); + t = (GCtab *)lj_mem_newgco(L, sizetabcolo(asize)); + t->gct = ~LJ_TTAB; + t->nomm = (uint8_t)~0; + t->colo = (int8_t)asize; + setmref(t->array, (TValue *)((char *)t + sizeof(GCtab))); + setgcrefnull(t->metatable); + t->asize = asize; + t->hmask = 0; + nilnode = &G(L)->nilnode; + setmref(t->node, nilnode); +#if LJ_GC64 + setmref(t->freetop, nilnode); +#endif + } else { /* Otherwise separately allocate the array part. */ + Node *nilnode; + t = lj_mem_newobj(L, GCtab); + t->gct = ~LJ_TTAB; + t->nomm = (uint8_t)~0; + t->colo = 0; + setmref(t->array, NULL); + setgcrefnull(t->metatable); + t->asize = 0; /* In case the array allocation fails. */ + t->hmask = 0; + nilnode = &G(L)->nilnode; + setmref(t->node, nilnode); +#if LJ_GC64 + setmref(t->freetop, nilnode); +#endif + if (asize > 0) { + if (asize > LJ_MAX_ASIZE) + lj_err_msg(L, LJ_ERR_TABOV); + setmref(t->array, lj_mem_newvec(L, asize, TValue)); + t->asize = asize; + } + } + if (hbits) + newhpart(L, t, hbits); + return t; +} + +/* Create a new table. +** +** IMPORTANT NOTE: The API differs from lua_createtable()! +** +** The array size is non-inclusive. E.g. asize=128 creates array slots +** for 0..127, but not for 128. If you need slots 1..128, pass asize=129 +** (slot 0 is wasted in this case). +** +** The hash size is given in hash bits. hbits=0 means no hash part. +** hbits=1 creates 2 hash slots, hbits=2 creates 4 hash slots and so on. +*/ +GCtab *lj_tab_new(lua_State *L, uint32_t asize, uint32_t hbits) +{ + GCtab *t = newtab(L, asize, hbits); + clearapart(t); + if (t->hmask > 0) clearhpart(t); + return t; +} + +/* The API of this function conforms to lua_createtable(). */ +GCtab *lj_tab_new_ah(lua_State *L, int32_t a, int32_t h) +{ + return lj_tab_new(L, (uint32_t)(a > 0 ? a+1 : 0), hsize2hbits(h)); +} + +#if LJ_HASJIT +GCtab * LJ_FASTCALL lj_tab_new1(lua_State *L, uint32_t ahsize) +{ + GCtab *t = newtab(L, ahsize & 0xffffff, ahsize >> 24); + clearapart(t); + if (t->hmask > 0) clearhpart(t); + return t; +} +#endif + +/* Duplicate a table. */ +GCtab * LJ_FASTCALL lj_tab_dup(lua_State *L, const GCtab *kt) +{ + GCtab *t; + uint32_t asize, hmask; + t = newtab(L, kt->asize, kt->hmask > 0 ? lj_fls(kt->hmask)+1 : 0); + lj_assertL(kt->asize == t->asize && kt->hmask == t->hmask, + "mismatched size of table and template"); + t->nomm = 0; /* Keys with metamethod names may be present. */ + asize = kt->asize; + if (asize > 0) { + TValue *array = tvref(t->array); + TValue *karray = tvref(kt->array); + if (asize < 64) { /* An inlined loop beats memcpy for < 512 bytes. */ + uint32_t i; + for (i = 0; i < asize; i++) + copyTV(L, &array[i], &karray[i]); + } else { + memcpy(array, karray, asize*sizeof(TValue)); + } + } + hmask = kt->hmask; + if (hmask > 0) { + uint32_t i; + Node *node = noderef(t->node); + Node *knode = noderef(kt->node); + ptrdiff_t d = (char *)node - (char *)knode; + setfreetop(t, node, (Node *)((char *)getfreetop(kt, knode) + d)); + for (i = 0; i <= hmask; i++) { + Node *kn = &knode[i]; + Node *n = &node[i]; + Node *next = nextnode(kn); + /* Don't use copyTV here, since it asserts on a copy of a dead key. */ + n->val = kn->val; n->key = kn->key; + setmref(n->next, next == NULL? next : (Node *)((char *)next + d)); + } + } + return t; +} + +/* Clear a table. */ +void LJ_FASTCALL lj_tab_clear(GCtab *t) +{ + clearapart(t); + if (t->hmask > 0) { + Node *node = noderef(t->node); + setfreetop(t, node, &node[t->hmask+1]); + clearhpart(t); + } +} + +/* Free a table. */ +void LJ_FASTCALL lj_tab_free(global_State *g, GCtab *t) +{ + if (t->hmask > 0) + lj_mem_freevec(g, noderef(t->node), t->hmask+1, Node); + if (t->asize > 0 && LJ_MAX_COLOSIZE != 0 && t->colo <= 0) + lj_mem_freevec(g, tvref(t->array), t->asize, TValue); + if (LJ_MAX_COLOSIZE != 0 && t->colo) + lj_mem_free(g, t, sizetabcolo((uint32_t)t->colo & 0x7f)); + else + lj_mem_freet(g, t); +} + +/* -- Table resizing ------------------------------------------------------ */ + +/* Resize a table to fit the new array/hash part sizes. */ +void lj_tab_resize(lua_State *L, GCtab *t, uint32_t asize, uint32_t hbits) +{ + Node *oldnode = noderef(t->node); + uint32_t oldasize = t->asize; + uint32_t oldhmask = t->hmask; + if (asize > oldasize) { /* Array part grows? */ + TValue *array; + uint32_t i; + if (asize > LJ_MAX_ASIZE) + lj_err_msg(L, LJ_ERR_TABOV); + if (LJ_MAX_COLOSIZE != 0 && t->colo > 0) { + /* A colocated array must be separated and copied. */ + TValue *oarray = tvref(t->array); + array = lj_mem_newvec(L, asize, TValue); + t->colo = (int8_t)(t->colo | 0x80); /* Mark as separated (colo < 0). */ + for (i = 0; i < oldasize; i++) + copyTV(L, &array[i], &oarray[i]); + } else { + array = (TValue *)lj_mem_realloc(L, tvref(t->array), + oldasize*sizeof(TValue), asize*sizeof(TValue)); + } + setmref(t->array, array); + t->asize = asize; + for (i = oldasize; i < asize; i++) /* Clear newly allocated slots. */ + setnilV(&array[i]); + } + /* Create new (empty) hash part. */ + if (hbits) { + newhpart(L, t, hbits); + clearhpart(t); + } else { + global_State *g = G(L); + setmref(t->node, &g->nilnode); +#if LJ_GC64 + setmref(t->freetop, &g->nilnode); +#endif + t->hmask = 0; + } + if (asize < oldasize) { /* Array part shrinks? */ + TValue *array = tvref(t->array); + uint32_t i; + t->asize = asize; /* Note: This 'shrinks' even colocated arrays. */ + for (i = asize; i < oldasize; i++) /* Reinsert old array values. */ + if (!tvisnil(&array[i])) + copyTV(L, lj_tab_setinth(L, t, (int32_t)i), &array[i]); + /* Physically shrink only separated arrays. */ + if (LJ_MAX_COLOSIZE != 0 && t->colo <= 0) + setmref(t->array, lj_mem_realloc(L, array, + oldasize*sizeof(TValue), asize*sizeof(TValue))); + } + if (oldhmask > 0) { /* Reinsert pairs from old hash part. */ + global_State *g; + uint32_t i; + for (i = 0; i <= oldhmask; i++) { + Node *n = &oldnode[i]; + if (!tvisnil(&n->val)) + copyTV(L, lj_tab_set(L, t, &n->key), &n->val); + } + g = G(L); + lj_mem_freevec(g, oldnode, oldhmask+1, Node); + } +} + +static uint32_t countint(cTValue *key, uint32_t *bins) +{ + lj_assertX(!tvisint(key), "bad integer key"); + if (tvisnum(key)) { + lua_Number nk = numV(key); + int32_t k = lj_num2int(nk); + if ((uint32_t)k < LJ_MAX_ASIZE && nk == (lua_Number)k) { + bins[(k > 2 ? lj_fls((uint32_t)(k-1)) : 0)]++; + return 1; + } + } + return 0; +} + +static uint32_t countarray(const GCtab *t, uint32_t *bins) +{ + uint32_t na, b, i; + if (t->asize == 0) return 0; + for (na = i = b = 0; b < LJ_MAX_ABITS; b++) { + uint32_t n, top = 2u << b; + TValue *array; + if (top >= t->asize) { + top = t->asize-1; + if (i > top) + break; + } + array = tvref(t->array); + for (n = 0; i <= top; i++) + if (!tvisnil(&array[i])) + n++; + bins[b] += n; + na += n; + } + return na; +} + +static uint32_t counthash(const GCtab *t, uint32_t *bins, uint32_t *narray) +{ + uint32_t total, na, i, hmask = t->hmask; + Node *node = noderef(t->node); + for (total = na = 0, i = 0; i <= hmask; i++) { + Node *n = &node[i]; + if (!tvisnil(&n->val)) { + na += countint(&n->key, bins); + total++; + } + } + *narray += na; + return total; +} + +static uint32_t bestasize(uint32_t bins[], uint32_t *narray) +{ + uint32_t b, sum, na = 0, sz = 0, nn = *narray; + for (b = 0, sum = 0; 2*nn > (1u< 0 && 2*(sum += bins[b]) > (1u<hmask > 0 ? lj_fls(t->hmask)+1 : 0); +} + +/* -- Table getters ------------------------------------------------------- */ + +cTValue * LJ_FASTCALL lj_tab_getinth(GCtab *t, int32_t key) +{ + TValue k; + Node *n; + k.n = (lua_Number)key; + n = hashnum(t, &k); + do { + if (tvisnum(&n->key) && n->key.n == k.n) + return &n->val; + } while ((n = nextnode(n))); + return NULL; +} + +cTValue *lj_tab_getstr(GCtab *t, const GCstr *key) +{ + Node *n = hashstr(t, key); + do { + if (tvisstr(&n->key) && strV(&n->key) == key) + return &n->val; + } while ((n = nextnode(n))); + return NULL; +} + +cTValue *lj_tab_get(lua_State *L, GCtab *t, cTValue *key) +{ + if (tvisstr(key)) { + cTValue *tv = lj_tab_getstr(t, strV(key)); + if (tv) + return tv; + } else if (tvisint(key)) { + cTValue *tv = lj_tab_getint(t, intV(key)); + if (tv) + return tv; + } else if (tvisnum(key)) { + lua_Number nk = numV(key); + int32_t k = lj_num2int(nk); + if (nk == (lua_Number)k) { + cTValue *tv = lj_tab_getint(t, k); + if (tv) + return tv; + } else { + goto genlookup; /* Else use the generic lookup. */ + } + } else if (!tvisnil(key)) { + Node *n; + genlookup: + n = hashkey(t, key); + do { + if (lj_obj_equal(&n->key, key)) + return &n->val; + } while ((n = nextnode(n))); + } + return niltv(L); +} + +/* -- Table setters ------------------------------------------------------- */ + +/* Insert new key. Use Brent's variation to optimize the chain length. */ +TValue *lj_tab_newkey(lua_State *L, GCtab *t, cTValue *key) +{ + Node *n = hashkey(t, key); + if (!tvisnil(&n->val) || t->hmask == 0) { + Node *nodebase = noderef(t->node); + Node *collide, *freenode = getfreetop(t, nodebase); + lj_assertL(freenode >= nodebase && freenode <= nodebase+t->hmask+1, + "bad freenode"); + do { + if (freenode == nodebase) { /* No free node found? */ + rehashtab(L, t, key); /* Rehash table. */ + return lj_tab_set(L, t, key); /* Retry key insertion. */ + } + } while (!tvisnil(&(--freenode)->key)); + setfreetop(t, nodebase, freenode); + lj_assertL(freenode != &G(L)->nilnode, "store to fallback hash"); + collide = hashkey(t, &n->key); + if (collide != n) { /* Colliding node not the main node? */ + while (noderef(collide->next) != n) /* Find predecessor. */ + collide = nextnode(collide); + setmref(collide->next, freenode); /* Relink chain. */ + /* Copy colliding node into free node and free main node. */ + freenode->val = n->val; + freenode->key = n->key; + freenode->next = n->next; + setmref(n->next, NULL); + setnilV(&n->val); + /* Rechain pseudo-resurrected string keys with colliding hashes. */ + while (nextnode(freenode)) { + Node *nn = nextnode(freenode); + if (!tvisnil(&nn->val) && hashkey(t, &nn->key) == n) { + freenode->next = nn->next; + nn->next = n->next; + setmref(n->next, nn); + /* + ** Rechaining a resurrected string key creates a new dilemma: + ** Another string key may have originally been resurrected via + ** _any_ of the previous nodes as a chain anchor. Including + ** a node that had to be moved, which makes them unreachable. + ** It's not feasible to check for all previous nodes, so rechain + ** any string key that's currently in a non-main positions. + */ + while ((nn = nextnode(freenode))) { + if (!tvisnil(&nn->val)) { + Node *mn = hashkey(t, &nn->key); + if (mn != freenode && mn != nn) { + freenode->next = nn->next; + nn->next = mn->next; + setmref(mn->next, nn); + } else { + freenode = nn; + } + } else { + freenode = nn; + } + } + break; + } else { + freenode = nn; + } + } + } else { /* Otherwise use free node. */ + setmrefr(freenode->next, n->next); /* Insert into chain. */ + setmref(n->next, freenode); + n = freenode; + } + } + n->key.u64 = key->u64; + if (LJ_UNLIKELY(tvismzero(&n->key))) + n->key.u64 = 0; + lj_gc_anybarriert(L, t); + lj_assertL(tvisnil(&n->val), "new hash slot is not empty"); + return &n->val; +} + +TValue *lj_tab_setinth(lua_State *L, GCtab *t, int32_t key) +{ + TValue k; + Node *n; + k.n = (lua_Number)key; + n = hashnum(t, &k); + do { + if (tvisnum(&n->key) && n->key.n == k.n) + return &n->val; + } while ((n = nextnode(n))); + return lj_tab_newkey(L, t, &k); +} + +TValue *lj_tab_setstr(lua_State *L, GCtab *t, const GCstr *key) +{ + TValue k; + Node *n = hashstr(t, key); + do { + if (tvisstr(&n->key) && strV(&n->key) == key) + return &n->val; + } while ((n = nextnode(n))); + setstrV(L, &k, key); + return lj_tab_newkey(L, t, &k); +} + +TValue *lj_tab_set(lua_State *L, GCtab *t, cTValue *key) +{ + Node *n; + t->nomm = 0; /* Invalidate negative metamethod cache. */ + if (tvisstr(key)) { + return lj_tab_setstr(L, t, strV(key)); + } else if (tvisint(key)) { + return lj_tab_setint(L, t, intV(key)); + } else if (tvisnum(key)) { + lua_Number nk = numV(key); + int32_t k = lj_num2int(nk); + if (nk == (lua_Number)k) + return lj_tab_setint(L, t, k); + if (tvisnan(key)) + lj_err_msg(L, LJ_ERR_NANIDX); + /* Else use the generic lookup. */ + } else if (tvisnil(key)) { + lj_err_msg(L, LJ_ERR_NILIDX); + } + n = hashkey(t, key); + do { + if (lj_obj_equal(&n->key, key)) + return &n->val; + } while ((n = nextnode(n))); + return lj_tab_newkey(L, t, key); +} + +/* -- Table traversal ----------------------------------------------------- */ + +/* Table traversal indexes: +** +** Array key index: [0 .. t->asize-1] +** Hash key index: [t->asize .. t->asize+t->hmask] +** Invalid key: ~0 +*/ + +/* Get the successor traversal index of a key. */ +uint32_t LJ_FASTCALL lj_tab_keyindex(GCtab *t, cTValue *key) +{ + TValue tmp; + if (tvisint(key)) { + int32_t k = intV(key); + if ((uint32_t)k < t->asize) + return (uint32_t)k + 1; + setnumV(&tmp, (lua_Number)k); + key = &tmp; + } else if (tvisnum(key)) { + lua_Number nk = numV(key); + int32_t k = lj_num2int(nk); + if ((uint32_t)k < t->asize && nk == (lua_Number)k) + return (uint32_t)k + 1; + } + if (!tvisnil(key)) { + Node *n = hashkey(t, key); + do { + if (lj_obj_equal(&n->key, key)) + return t->asize + (uint32_t)((n+1) - noderef(t->node)); + } while ((n = nextnode(n))); + if (key->u32.hi == LJ_KEYINDEX) /* Despecialized ITERN while running. */ + return key->u32.lo; + return ~0u; /* Invalid key to next. */ + } + return 0; /* A nil key starts the traversal. */ +} + +/* Get the next key/value pair of a table traversal. */ +int lj_tab_next(GCtab *t, cTValue *key, TValue *o) +{ + uint32_t idx = lj_tab_keyindex(t, key); /* Find successor index of key. */ + /* First traverse the array part. */ + for (; idx < t->asize; idx++) { + cTValue *a = arrayslot(t, idx); + if (LJ_LIKELY(!tvisnil(a))) { + setintV(o, idx); + o[1] = *a; + return 1; + } + } + idx -= t->asize; + /* Then traverse the hash part. */ + for (; idx <= t->hmask; idx++) { + Node *n = &noderef(t->node)[idx]; + if (!tvisnil(&n->val)) { + o[0] = n->key; + o[1] = n->val; + return 1; + } + } + return (int32_t)idx < 0 ? -1 : 0; /* Invalid key or end of traversal. */ +} + +/* -- Table length calculation -------------------------------------------- */ + +/* Compute table length. Slow path with mixed array/hash lookups. */ +LJ_NOINLINE static MSize tab_len_slow(GCtab *t, size_t hi) +{ + cTValue *tv; + size_t lo = hi; + hi++; + /* Widening search for an upper bound. */ + while ((tv = lj_tab_getint(t, (int32_t)hi)) && !tvisnil(tv)) { + lo = hi; + hi += hi; + if (hi > (size_t)(INT_MAX-2)) { /* Punt and do a linear search. */ + lo = 1; + while ((tv = lj_tab_getint(t, (int32_t)lo)) && !tvisnil(tv)) lo++; + return (MSize)(lo - 1); + } + } + /* Binary search to find a non-nil to nil transition. */ + while (hi - lo > 1) { + size_t mid = (lo+hi) >> 1; + cTValue *tvb = lj_tab_getint(t, (int32_t)mid); + if (tvb && !tvisnil(tvb)) lo = mid; else hi = mid; + } + return (MSize)lo; +} + +/* Compute table length. Fast path. */ +MSize LJ_FASTCALL lj_tab_len(GCtab *t) +{ + size_t hi = (size_t)t->asize; + if (hi) hi--; + /* In a growing array the last array element is very likely nil. */ + if (hi > 0 && LJ_LIKELY(tvisnil(arrayslot(t, hi)))) { + /* Binary search to find a non-nil to nil transition in the array. */ + size_t lo = 0; + while (hi - lo > 1) { + size_t mid = (lo+hi) >> 1; + if (tvisnil(arrayslot(t, mid))) hi = mid; else lo = mid; + } + return (MSize)lo; + } + /* Without a hash part, there's an implicit nil after the last element. */ + return t->hmask ? tab_len_slow(t, hi) : (MSize)hi; +} + +#if LJ_HASJIT +/* Verify hinted table length or compute it. */ +MSize LJ_FASTCALL lj_tab_len_hint(GCtab *t, size_t hint) +{ + size_t asize = (size_t)t->asize; + cTValue *tv = arrayslot(t, hint); + if (LJ_LIKELY(hint+1 < asize)) { + if (LJ_LIKELY(!tvisnil(tv) && tvisnil(tv+1))) return (MSize)hint; + } else if (hint+1 <= asize && LJ_LIKELY(t->hmask == 0) && !tvisnil(tv)) { + return (MSize)hint; + } + return lj_tab_len(t); +} +#endif + diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_tab.h b/fluent-bit/lib/luajit-3065c9/src/lj_tab.h new file mode 100644 index 00000000..2a3f76bf --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_tab.h @@ -0,0 +1,96 @@ +/* +** Table handling. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#ifndef _LJ_TAB_H +#define _LJ_TAB_H + +#include "lj_obj.h" + +/* Hash constants. Tuned using a brute force search. */ +#define HASH_BIAS (-0x04c11db7) +#define HASH_ROT1 14 +#define HASH_ROT2 5 +#define HASH_ROT3 13 + +/* Scramble the bits of numbers and pointers. */ +static LJ_AINLINE uint32_t hashrot(uint32_t lo, uint32_t hi) +{ +#if LJ_TARGET_X86ORX64 + /* Prefer variant that compiles well for a 2-operand CPU. */ + lo ^= hi; hi = lj_rol(hi, HASH_ROT1); + lo -= hi; hi = lj_rol(hi, HASH_ROT2); + hi ^= lo; hi -= lj_rol(lo, HASH_ROT3); +#else + lo ^= hi; + lo = lo - lj_rol(hi, HASH_ROT1); + hi = lo ^ lj_rol(hi, HASH_ROT1 + HASH_ROT2); + hi = hi - lj_rol(lo, HASH_ROT3); +#endif + return hi; +} + +/* Hash values are masked with the table hash mask and used as an index. */ +static LJ_AINLINE Node *hashmask(const GCtab *t, uint32_t hash) +{ + Node *n = noderef(t->node); + return &n[hash & t->hmask]; +} + +/* String IDs are generated when a string is interned. */ +#define hashstr(t, s) hashmask(t, (s)->sid) + +#define hashlohi(t, lo, hi) hashmask((t), hashrot((lo), (hi))) +#define hashnum(t, o) hashlohi((t), (o)->u32.lo, ((o)->u32.hi << 1)) +#if LJ_GC64 +#define hashgcref(t, r) \ + hashlohi((t), (uint32_t)gcrefu(r), (uint32_t)(gcrefu(r) >> 32)) +#else +#define hashgcref(t, r) hashlohi((t), gcrefu(r), gcrefu(r) + HASH_BIAS) +#endif + +#define hsize2hbits(s) ((s) ? ((s)==1 ? 1 : 1+lj_fls((uint32_t)((s)-1))) : 0) + +LJ_FUNCA GCtab *lj_tab_new(lua_State *L, uint32_t asize, uint32_t hbits); +LJ_FUNC GCtab *lj_tab_new_ah(lua_State *L, int32_t a, int32_t h); +#if LJ_HASJIT +LJ_FUNC GCtab * LJ_FASTCALL lj_tab_new1(lua_State *L, uint32_t ahsize); +#endif +LJ_FUNCA GCtab * LJ_FASTCALL lj_tab_dup(lua_State *L, const GCtab *kt); +LJ_FUNC void LJ_FASTCALL lj_tab_clear(GCtab *t); +LJ_FUNC void LJ_FASTCALL lj_tab_free(global_State *g, GCtab *t); +#if LJ_HASFFI +LJ_FUNC void lj_tab_rehash(lua_State *L, GCtab *t); +#endif +LJ_FUNC void lj_tab_resize(lua_State *L, GCtab *t, uint32_t asize, uint32_t hbits); +LJ_FUNCA void lj_tab_reasize(lua_State *L, GCtab *t, uint32_t nasize); + +/* Caveat: all getters except lj_tab_get() can return NULL! */ + +LJ_FUNCA cTValue * LJ_FASTCALL lj_tab_getinth(GCtab *t, int32_t key); +LJ_FUNC cTValue *lj_tab_getstr(GCtab *t, const GCstr *key); +LJ_FUNCA cTValue *lj_tab_get(lua_State *L, GCtab *t, cTValue *key); + +/* Caveat: all setters require a write barrier for the stored value. */ + +LJ_FUNCA TValue *lj_tab_newkey(lua_State *L, GCtab *t, cTValue *key); +LJ_FUNCA TValue *lj_tab_setinth(lua_State *L, GCtab *t, int32_t key); +LJ_FUNC TValue *lj_tab_setstr(lua_State *L, GCtab *t, const GCstr *key); +LJ_FUNC TValue *lj_tab_set(lua_State *L, GCtab *t, cTValue *key); + +#define inarray(t, key) ((MSize)(key) < (MSize)(t)->asize) +#define arrayslot(t, i) (&tvref((t)->array)[(i)]) +#define lj_tab_getint(t, key) \ + (inarray((t), (key)) ? arrayslot((t), (key)) : lj_tab_getinth((t), (key))) +#define lj_tab_setint(L, t, key) \ + (inarray((t), (key)) ? arrayslot((t), (key)) : lj_tab_setinth(L, (t), (key))) + +LJ_FUNC uint32_t LJ_FASTCALL lj_tab_keyindex(GCtab *t, cTValue *key); +LJ_FUNCA int lj_tab_next(GCtab *t, cTValue *key, TValue *o); +LJ_FUNCA MSize LJ_FASTCALL lj_tab_len(GCtab *t); +#if LJ_HASJIT +LJ_FUNC MSize LJ_FASTCALL lj_tab_len_hint(GCtab *t, size_t hint); +#endif + +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_target.h b/fluent-bit/lib/luajit-3065c9/src/lj_target.h new file mode 100644 index 00000000..19716928 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_target.h @@ -0,0 +1,165 @@ +/* +** Definitions for target CPU. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#ifndef _LJ_TARGET_H +#define _LJ_TARGET_H + +#include "lj_def.h" +#include "lj_arch.h" + +/* -- Registers and spill slots ------------------------------------------- */ + +/* Register type (uint8_t in ir->r). */ +typedef uint32_t Reg; + +/* The hi-bit is NOT set for an allocated register. This means the value +** can be directly used without masking. The hi-bit is set for a register +** allocation hint or for RID_INIT, RID_SINK or RID_SUNK. +*/ +#define RID_NONE 0x80 +#define RID_MASK 0x7f +#define RID_INIT (RID_NONE|RID_MASK) +#define RID_SINK (RID_INIT-1) +#define RID_SUNK (RID_INIT-2) + +#define ra_noreg(r) ((r) & RID_NONE) +#define ra_hasreg(r) (!((r) & RID_NONE)) + +/* The ra_hashint() macro assumes a previous test for ra_noreg(). */ +#define ra_hashint(r) ((r) < RID_SUNK) +#define ra_gethint(r) ((Reg)((r) & RID_MASK)) +#define ra_sethint(rr, r) rr = (uint8_t)((r)|RID_NONE) +#define ra_samehint(r1, r2) (ra_gethint((r1)^(r2)) == 0) + +/* Spill slot 0 means no spill slot has been allocated. */ +#define SPS_NONE 0 + +#define ra_hasspill(s) ((s) != SPS_NONE) + +/* Combined register and spill slot (uint16_t in ir->prev). */ +typedef uint32_t RegSP; + +#define REGSP(r, s) ((r) + ((s) << 8)) +#define REGSP_HINT(r) ((r)|RID_NONE) +#define REGSP_INIT REGSP(RID_INIT, 0) + +#define regsp_reg(rs) ((rs) & 255) +#define regsp_spill(rs) ((rs) >> 8) +#define regsp_used(rs) \ + (((rs) & ~REGSP(RID_MASK, 0)) != REGSP(RID_NONE, 0)) + +/* -- Register sets ------------------------------------------------------- */ + +/* Bitset for registers. 32 registers suffice for most architectures. +** Note that one set holds bits for both GPRs and FPRs. +*/ +#if LJ_TARGET_PPC || LJ_TARGET_MIPS || LJ_TARGET_ARM64 +typedef uint64_t RegSet; +#else +typedef uint32_t RegSet; +#endif + +#define RID2RSET(r) (((RegSet)1) << (r)) +#define RSET_EMPTY ((RegSet)0) +#define RSET_RANGE(lo, hi) ((RID2RSET((hi)-(lo))-1) << (lo)) + +#define rset_test(rs, r) ((int)((rs) >> (r)) & 1) +#define rset_set(rs, r) (rs |= RID2RSET(r)) +#define rset_clear(rs, r) (rs &= ~RID2RSET(r)) +#define rset_exclude(rs, r) (rs & ~RID2RSET(r)) +#if LJ_TARGET_PPC || LJ_TARGET_MIPS || LJ_TARGET_ARM64 +#define rset_picktop(rs) ((Reg)(__builtin_clzll(rs)^63)) +#define rset_pickbot(rs) ((Reg)__builtin_ctzll(rs)) +#else +#define rset_picktop(rs) ((Reg)lj_fls(rs)) +#define rset_pickbot(rs) ((Reg)lj_ffs(rs)) +#endif + +/* -- Register allocation cost -------------------------------------------- */ + +/* The register allocation heuristic keeps track of the cost for allocating +** a specific register: +** +** A free register (obviously) has a cost of 0 and a 1-bit in the free mask. +** +** An already allocated register has the (non-zero) IR reference in the lowest +** bits and the result of a blended cost-model in the higher bits. +** +** The allocator first checks the free mask for a hit. Otherwise an (unrolled) +** linear search for the minimum cost is used. The search doesn't need to +** keep track of the position of the minimum, which makes it very fast. +** The lowest bits of the minimum cost show the desired IR reference whose +** register is the one to evict. +** +** Without the cost-model this degenerates to the standard heuristics for +** (reverse) linear-scan register allocation. Since code generation is done +** in reverse, a live interval extends from the last use to the first def. +** For an SSA IR the IR reference is the first (and only) def and thus +** trivially marks the end of the interval. The LSRA heuristics says to pick +** the register whose live interval has the furthest extent, i.e. the lowest +** IR reference in our case. +** +** A cost-model should take into account other factors, like spill-cost and +** restore- or rematerialization-cost, which depend on the kind of instruction. +** E.g. constants have zero spill costs, variant instructions have higher +** costs than invariants and PHIs should preferably never be spilled. +** +** Here's a first cut at simple, but effective blended cost-model for R-LSRA: +** - Due to careful design of the IR, constants already have lower IR +** references than invariants and invariants have lower IR references +** than variants. +** - The cost in the upper 16 bits is the sum of the IR reference and a +** weighted score. The score currently only takes into account whether +** the IRT_ISPHI bit is set in the instruction type. +** - The PHI weight is the minimum distance (in IR instructions) a PHI +** reference has to be further apart from a non-PHI reference to be spilled. +** - It should be a power of two (for speed) and must be between 2 and 32768. +** Good values for the PHI weight seem to be between 40 and 150. +** - Further study is required. +*/ +#define REGCOST_PHI_WEIGHT 64 + +/* Cost for allocating a specific register. */ +typedef uint32_t RegCost; + +/* Note: assumes 16 bit IRRef1. */ +#define REGCOST(cost, ref) ((RegCost)(ref) + ((RegCost)(cost) << 16)) +#define regcost_ref(rc) ((IRRef1)(rc)) + +#define REGCOST_T(t) \ + ((RegCost)((t)&IRT_ISPHI) * (((RegCost)(REGCOST_PHI_WEIGHT)<<16)/IRT_ISPHI)) +#define REGCOST_REF_T(ref, t) (REGCOST((ref), (ref)) + REGCOST_T((t))) + +/* -- Target-specific definitions ----------------------------------------- */ + +#if LJ_TARGET_X86ORX64 +#include "lj_target_x86.h" +#elif LJ_TARGET_ARM +#include "lj_target_arm.h" +#elif LJ_TARGET_ARM64 +#include "lj_target_arm64.h" +#elif LJ_TARGET_PPC +#include "lj_target_ppc.h" +#elif LJ_TARGET_MIPS +#include "lj_target_mips.h" +#else +#error "Missing include for target CPU" +#endif + +#ifdef EXITSTUBS_PER_GROUP +/* Return the address of an exit stub. */ +static LJ_AINLINE char *exitstub_addr_(char **group, uint32_t exitno) +{ + lj_assertX(group[exitno / EXITSTUBS_PER_GROUP] != NULL, + "exit stub group for exit %d uninitialized", exitno); + return (char *)group[exitno / EXITSTUBS_PER_GROUP] + + EXITSTUB_SPACING*(exitno % EXITSTUBS_PER_GROUP); +} +/* Avoid dependence on lj_jit.h if only including lj_target.h. */ +#define exitstub_addr(J, exitno) \ + ((MCode *)exitstub_addr_((char **)((J)->exitstubgroup), (exitno))) +#endif + +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_target_arm.h b/fluent-bit/lib/luajit-3065c9/src/lj_target_arm.h new file mode 100644 index 00000000..48f487a5 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_target_arm.h @@ -0,0 +1,271 @@ +/* +** Definitions for ARM CPUs. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#ifndef _LJ_TARGET_ARM_H +#define _LJ_TARGET_ARM_H + +/* -- Registers IDs ------------------------------------------------------- */ + +#define GPRDEF(_) \ + _(R0) _(R1) _(R2) _(R3) _(R4) _(R5) _(R6) _(R7) \ + _(R8) _(R9) _(R10) _(R11) _(R12) _(SP) _(LR) _(PC) +#if LJ_SOFTFP +#define FPRDEF(_) +#else +#define FPRDEF(_) \ + _(D0) _(D1) _(D2) _(D3) _(D4) _(D5) _(D6) _(D7) \ + _(D8) _(D9) _(D10) _(D11) _(D12) _(D13) _(D14) _(D15) +#endif +#define VRIDDEF(_) + +#define RIDENUM(name) RID_##name, + +enum { + GPRDEF(RIDENUM) /* General-purpose registers (GPRs). */ + FPRDEF(RIDENUM) /* Floating-point registers (FPRs). */ + RID_MAX, + RID_TMP = RID_LR, + + /* Calling conventions. */ + RID_RET = RID_R0, + RID_RETLO = RID_R0, + RID_RETHI = RID_R1, +#if LJ_SOFTFP + RID_FPRET = RID_R0, +#else + RID_FPRET = RID_D0, +#endif + + /* These definitions must match with the *.dasc file(s): */ + RID_BASE = RID_R9, /* Interpreter BASE. */ + RID_LPC = RID_R6, /* Interpreter PC. */ + RID_DISPATCH = RID_R7, /* Interpreter DISPATCH table. */ + RID_LREG = RID_R8, /* Interpreter L. */ + + /* Register ranges [min, max) and number of registers. */ + RID_MIN_GPR = RID_R0, + RID_MAX_GPR = RID_PC+1, + RID_MIN_FPR = RID_MAX_GPR, +#if LJ_SOFTFP + RID_MAX_FPR = RID_MIN_FPR, +#else + RID_MAX_FPR = RID_D15+1, +#endif + RID_NUM_GPR = RID_MAX_GPR - RID_MIN_GPR, + RID_NUM_FPR = RID_MAX_FPR - RID_MIN_FPR +}; + +#define RID_NUM_KREF RID_NUM_GPR +#define RID_MIN_KREF RID_R0 + +/* -- Register sets ------------------------------------------------------- */ + +/* Make use of all registers, except sp, lr and pc. */ +#define RSET_GPR (RSET_RANGE(RID_MIN_GPR, RID_R12+1)) +#define RSET_GPREVEN \ + (RID2RSET(RID_R0)|RID2RSET(RID_R2)|RID2RSET(RID_R4)|RID2RSET(RID_R6)| \ + RID2RSET(RID_R8)|RID2RSET(RID_R10)) +#define RSET_GPRODD \ + (RID2RSET(RID_R1)|RID2RSET(RID_R3)|RID2RSET(RID_R5)|RID2RSET(RID_R7)| \ + RID2RSET(RID_R9)|RID2RSET(RID_R11)) +#if LJ_SOFTFP +#define RSET_FPR 0 +#else +#define RSET_FPR (RSET_RANGE(RID_MIN_FPR, RID_MAX_FPR)) +#endif +#define RSET_ALL (RSET_GPR|RSET_FPR) +#define RSET_INIT RSET_ALL + +/* ABI-specific register sets. lr is an implicit scratch register. */ +#define RSET_SCRATCH_GPR_ (RSET_RANGE(RID_R0, RID_R3+1)|RID2RSET(RID_R12)) +#ifdef __APPLE__ +#define RSET_SCRATCH_GPR (RSET_SCRATCH_GPR_|RID2RSET(RID_R9)) +#else +#define RSET_SCRATCH_GPR RSET_SCRATCH_GPR_ +#endif +#if LJ_SOFTFP +#define RSET_SCRATCH_FPR 0 +#else +#define RSET_SCRATCH_FPR (RSET_RANGE(RID_D0, RID_D7+1)) +#endif +#define RSET_SCRATCH (RSET_SCRATCH_GPR|RSET_SCRATCH_FPR) +#define REGARG_FIRSTGPR RID_R0 +#define REGARG_LASTGPR RID_R3 +#define REGARG_NUMGPR 4 +#if LJ_ABI_SOFTFP +#define REGARG_FIRSTFPR 0 +#define REGARG_LASTFPR 0 +#define REGARG_NUMFPR 0 +#else +#define REGARG_FIRSTFPR RID_D0 +#define REGARG_LASTFPR RID_D7 +#define REGARG_NUMFPR 8 +#endif + +/* -- Spill slots --------------------------------------------------------- */ + +/* Spill slots are 32 bit wide. An even/odd pair is used for FPRs. +** +** SPS_FIXED: Available fixed spill slots in interpreter frame. +** This definition must match with the *.dasc file(s). +** +** SPS_FIRST: First spill slot for general use. Reserve min. two 32 bit slots. +*/ +#define SPS_FIXED 2 +#define SPS_FIRST 2 + +#define SPOFS_TMP 0 + +#define sps_scale(slot) (4 * (int32_t)(slot)) +#define sps_align(slot) (((slot) - SPS_FIXED + 1) & ~1) + +/* -- Exit state ---------------------------------------------------------- */ + +/* This definition must match with the *.dasc file(s). */ +typedef struct { +#if !LJ_SOFTFP + lua_Number fpr[RID_NUM_FPR]; /* Floating-point registers. */ +#endif + int32_t gpr[RID_NUM_GPR]; /* General-purpose registers. */ + int32_t spill[256]; /* Spill slots. */ +} ExitState; + +/* PC after instruction that caused an exit. Used to find the trace number. */ +#define EXITSTATE_PCREG RID_PC +/* Highest exit + 1 indicates stack check. */ +#define EXITSTATE_CHECKEXIT 1 + +#define EXITSTUB_SPACING 4 +#define EXITSTUBS_PER_GROUP 32 + +/* -- Instructions -------------------------------------------------------- */ + +/* Instruction fields. */ +#define ARMF_CC(ai, cc) (((ai) ^ ARMI_CCAL) | ((cc) << 28)) +#define ARMF_N(r) ((r) << 16) +#define ARMF_D(r) ((r) << 12) +#define ARMF_S(r) ((r) << 8) +#define ARMF_M(r) (r) +#define ARMF_SH(sh, n) (((sh) << 5) | ((n) << 7)) +#define ARMF_RSH(sh, r) (0x10 | ((sh) << 5) | ARMF_S(r)) + +typedef enum ARMIns { + ARMI_CCAL = 0xe0000000, + ARMI_S = 0x000100000, + ARMI_K12 = 0x02000000, + ARMI_KNEG = 0x00200000, + ARMI_LS_W = 0x00200000, + ARMI_LS_U = 0x00800000, + ARMI_LS_P = 0x01000000, + ARMI_LS_R = 0x02000000, + ARMI_LSX_I = 0x00400000, + + ARMI_AND = 0xe0000000, + ARMI_EOR = 0xe0200000, + ARMI_SUB = 0xe0400000, + ARMI_RSB = 0xe0600000, + ARMI_ADD = 0xe0800000, + ARMI_ADC = 0xe0a00000, + ARMI_SBC = 0xe0c00000, + ARMI_RSC = 0xe0e00000, + ARMI_TST = 0xe1100000, + ARMI_TEQ = 0xe1300000, + ARMI_CMP = 0xe1500000, + ARMI_CMN = 0xe1700000, + ARMI_ORR = 0xe1800000, + ARMI_MOV = 0xe1a00000, + ARMI_BIC = 0xe1c00000, + ARMI_MVN = 0xe1e00000, + + ARMI_NOP = 0xe1a00000, + + ARMI_MUL = 0xe0000090, + ARMI_SMULL = 0xe0c00090, + + ARMI_LDR = 0xe4100000, + ARMI_LDRB = 0xe4500000, + ARMI_LDRH = 0xe01000b0, + ARMI_LDRSB = 0xe01000d0, + ARMI_LDRSH = 0xe01000f0, + ARMI_LDRD = 0xe00000d0, + ARMI_STR = 0xe4000000, + ARMI_STRB = 0xe4400000, + ARMI_STRH = 0xe00000b0, + ARMI_STRD = 0xe00000f0, + ARMI_PUSH = 0xe92d0000, + + ARMI_B = 0xea000000, + ARMI_BL = 0xeb000000, + ARMI_BLX = 0xfa000000, + ARMI_BLXr = 0xe12fff30, + + /* ARMv6 */ + ARMI_REV = 0xe6bf0f30, + ARMI_SXTB = 0xe6af0070, + ARMI_SXTH = 0xe6bf0070, + ARMI_UXTB = 0xe6ef0070, + ARMI_UXTH = 0xe6ff0070, + + /* ARMv6T2 */ + ARMI_MOVW = 0xe3000000, + ARMI_MOVT = 0xe3400000, + ARMI_BFI = 0xe7c00010, + + /* VFP */ + ARMI_VMOV_D = 0xeeb00b40, + ARMI_VMOV_S = 0xeeb00a40, + ARMI_VMOVI_D = 0xeeb00b00, + + ARMI_VMOV_R_S = 0xee100a10, + ARMI_VMOV_S_R = 0xee000a10, + ARMI_VMOV_RR_D = 0xec500b10, + ARMI_VMOV_D_RR = 0xec400b10, + + ARMI_VADD_D = 0xee300b00, + ARMI_VSUB_D = 0xee300b40, + ARMI_VMUL_D = 0xee200b00, + ARMI_VMLA_D = 0xee000b00, + ARMI_VMLS_D = 0xee000b40, + ARMI_VNMLS_D = 0xee100b00, + ARMI_VDIV_D = 0xee800b00, + + ARMI_VABS_D = 0xeeb00bc0, + ARMI_VNEG_D = 0xeeb10b40, + ARMI_VSQRT_D = 0xeeb10bc0, + + ARMI_VCMP_D = 0xeeb40b40, + ARMI_VCMPZ_D = 0xeeb50b40, + + ARMI_VMRS = 0xeef1fa10, + + ARMI_VCVT_S32_F32 = 0xeebd0ac0, + ARMI_VCVT_S32_F64 = 0xeebd0bc0, + ARMI_VCVT_U32_F32 = 0xeebc0ac0, + ARMI_VCVT_U32_F64 = 0xeebc0bc0, + ARMI_VCVT_F32_S32 = 0xeeb80ac0, + ARMI_VCVT_F64_S32 = 0xeeb80bc0, + ARMI_VCVT_F32_U32 = 0xeeb80a40, + ARMI_VCVT_F64_U32 = 0xeeb80b40, + ARMI_VCVT_F32_F64 = 0xeeb70bc0, + ARMI_VCVT_F64_F32 = 0xeeb70ac0, + + ARMI_VLDR_S = 0xed100a00, + ARMI_VLDR_D = 0xed100b00, + ARMI_VSTR_S = 0xed000a00, + ARMI_VSTR_D = 0xed000b00, +} ARMIns; + +typedef enum ARMShift { + ARMSH_LSL, ARMSH_LSR, ARMSH_ASR, ARMSH_ROR +} ARMShift; + +/* ARM condition codes. */ +typedef enum ARMCC { + CC_EQ, CC_NE, CC_CS, CC_CC, CC_MI, CC_PL, CC_VS, CC_VC, + CC_HI, CC_LS, CC_GE, CC_LT, CC_GT, CC_LE, CC_AL, + CC_HS = CC_CS, CC_LO = CC_CC +} ARMCC; + +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_target_arm64.h b/fluent-bit/lib/luajit-3065c9/src/lj_target_arm64.h new file mode 100644 index 00000000..d45af2e4 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_target_arm64.h @@ -0,0 +1,336 @@ +/* +** Definitions for ARM64 CPUs. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#ifndef _LJ_TARGET_ARM64_H +#define _LJ_TARGET_ARM64_H + +/* -- Registers IDs ------------------------------------------------------- */ + +#define GPRDEF(_) \ + _(X0) _(X1) _(X2) _(X3) _(X4) _(X5) _(X6) _(X7) \ + _(X8) _(X9) _(X10) _(X11) _(X12) _(X13) _(X14) _(X15) \ + _(X16) _(X17) _(X18) _(X19) _(X20) _(X21) _(X22) _(X23) \ + _(X24) _(X25) _(X26) _(X27) _(X28) _(FP) _(LR) _(SP) +#define FPRDEF(_) \ + _(D0) _(D1) _(D2) _(D3) _(D4) _(D5) _(D6) _(D7) \ + _(D8) _(D9) _(D10) _(D11) _(D12) _(D13) _(D14) _(D15) \ + _(D16) _(D17) _(D18) _(D19) _(D20) _(D21) _(D22) _(D23) \ + _(D24) _(D25) _(D26) _(D27) _(D28) _(D29) _(D30) _(D31) +#define VRIDDEF(_) + +#define RIDENUM(name) RID_##name, + +enum { + GPRDEF(RIDENUM) /* General-purpose registers (GPRs). */ + FPRDEF(RIDENUM) /* Floating-point registers (FPRs). */ + RID_MAX, + RID_TMP = RID_LR, + RID_ZERO = RID_SP, + + /* Calling conventions. */ + RID_RET = RID_X0, + RID_RETLO = RID_X0, + RID_RETHI = RID_X1, + RID_FPRET = RID_D0, + + /* These definitions must match with the *.dasc file(s): */ + RID_BASE = RID_X19, /* Interpreter BASE. */ + RID_LPC = RID_X21, /* Interpreter PC. */ + RID_GL = RID_X22, /* Interpreter GL. */ + RID_LREG = RID_X23, /* Interpreter L. */ + + /* Register ranges [min, max) and number of registers. */ + RID_MIN_GPR = RID_X0, + RID_MAX_GPR = RID_SP+1, + RID_MIN_FPR = RID_MAX_GPR, + RID_MAX_FPR = RID_D31+1, + RID_NUM_GPR = RID_MAX_GPR - RID_MIN_GPR, + RID_NUM_FPR = RID_MAX_FPR - RID_MIN_FPR +}; + +#define RID_NUM_KREF RID_NUM_GPR +#define RID_MIN_KREF RID_X0 + +/* -- Register sets ------------------------------------------------------- */ + +/* Make use of all registers, except for x18, fp, lr and sp. */ +#define RSET_FIXED \ + (RID2RSET(RID_X18)|RID2RSET(RID_FP)|RID2RSET(RID_LR)|RID2RSET(RID_SP)|\ + RID2RSET(RID_GL)) +#define RSET_GPR (RSET_RANGE(RID_MIN_GPR, RID_MAX_GPR) - RSET_FIXED) +#define RSET_FPR RSET_RANGE(RID_MIN_FPR, RID_MAX_FPR) +#define RSET_ALL (RSET_GPR|RSET_FPR) +#define RSET_INIT RSET_ALL + +/* lr is an implicit scratch register. */ +#define RSET_SCRATCH_GPR (RSET_RANGE(RID_X0, RID_X17+1)) +#define RSET_SCRATCH_FPR \ + (RSET_RANGE(RID_D0, RID_D7+1)|RSET_RANGE(RID_D16, RID_D31+1)) +#define RSET_SCRATCH (RSET_SCRATCH_GPR|RSET_SCRATCH_FPR) +#define REGARG_FIRSTGPR RID_X0 +#define REGARG_LASTGPR RID_X7 +#define REGARG_NUMGPR 8 +#define REGARG_FIRSTFPR RID_D0 +#define REGARG_LASTFPR RID_D7 +#define REGARG_NUMFPR 8 + +/* -- Spill slots --------------------------------------------------------- */ + +/* Spill slots are 32 bit wide. An even/odd pair is used for FPRs. +** +** SPS_FIXED: Available fixed spill slots in interpreter frame. +** This definition must match with the vm_arm64.dasc file. +** Pre-allocate some slots to avoid sp adjust in every root trace. +** +** SPS_FIRST: First spill slot for general use. Reserve min. two 32 bit slots. +*/ +#define SPS_FIXED 4 +#define SPS_FIRST 2 + +#define SPOFS_TMP 0 + +#define sps_scale(slot) (4 * (int32_t)(slot)) +#define sps_align(slot) (((slot) - SPS_FIXED + 3) & ~3) + +/* -- Exit state ---------------------------------------------------------- */ + +/* This definition must match with the *.dasc file(s). */ +typedef struct { + lua_Number fpr[RID_NUM_FPR]; /* Floating-point registers. */ + intptr_t gpr[RID_NUM_GPR]; /* General-purpose registers. */ + int32_t spill[256]; /* Spill slots. */ +} ExitState; + +/* Highest exit + 1 indicates stack check. */ +#define EXITSTATE_CHECKEXIT 1 + +/* Return the address of a per-trace exit stub. */ +static LJ_AINLINE uint32_t *exitstub_trace_addr_(uint32_t *p, uint32_t exitno) +{ + while (*p == (LJ_LE ? 0xd503201f : 0x1f2003d5)) p++; /* Skip A64I_NOP. */ + return p + 3 + exitno; +} +/* Avoid dependence on lj_jit.h if only including lj_target.h. */ +#define exitstub_trace_addr(T, exitno) \ + exitstub_trace_addr_((MCode *)((char *)(T)->mcode + (T)->szmcode), (exitno)) + +/* -- Instructions -------------------------------------------------------- */ + +/* ARM64 instructions are always little-endian. Swap for ARM64BE. */ +#if LJ_BE +#define A64I_LE(x) (lj_bswap(x)) +#else +#define A64I_LE(x) (x) +#endif + +/* Instruction fields. */ +#define A64F_D(r) (r) +#define A64F_N(r) ((r) << 5) +#define A64F_A(r) ((r) << 10) +#define A64F_M(r) ((r) << 16) +#define A64F_IMMS(x) ((x) << 10) +#define A64F_IMMR(x) ((x) << 16) +#define A64F_U16(x) ((x) << 5) +#define A64F_U12(x) ((x) << 10) +#define A64F_S26(x) (((uint32_t)(x) & 0x03ffffffu)) +#define A64F_S19(x) (((uint32_t)(x) & 0x7ffffu) << 5) +#define A64F_S14(x) (((uint32_t)(x) & 0x3fffu) << 5) +#define A64F_S9(x) ((x) << 12) +#define A64F_BIT(x) ((x) << 19) +#define A64F_SH(sh, x) (((sh) << 22) | ((x) << 10)) +#define A64F_EX(ex) (A64I_EX | ((ex) << 13)) +#define A64F_EXSH(ex,x) (A64I_EX | ((ex) << 13) | ((x) << 10)) +#define A64F_FP8(x) ((x) << 13) +#define A64F_CC(cc) ((cc) << 12) +#define A64F_LSL16(x) (((x) / 16) << 21) +#define A64F_BSH(sh) ((sh) << 10) + +/* Check for valid field range. */ +#define A64F_S_OK(x, b) ((((x) + (1 << (b-1))) >> (b)) == 0) + +typedef enum A64Ins { + A64I_S = 0x20000000, + A64I_X = 0x80000000, + A64I_EX = 0x00200000, + A64I_ON = 0x00200000, + A64I_K12 = 0x1a000000, + A64I_K13 = 0x18000000, + A64I_LS_U = 0x01000000, + A64I_LS_S = 0x00800000, + A64I_LS_R = 0x01200800, + A64I_LS_SH = 0x00001000, + A64I_LS_UXTWx = 0x00004000, + A64I_LS_SXTWx = 0x0000c000, + A64I_LS_SXTXx = 0x0000e000, + A64I_LS_LSLx = 0x00006000, + + A64I_ADDw = 0x0b000000, + A64I_ADDx = 0x8b000000, + A64I_ADDSw = 0x2b000000, + A64I_ADDSx = 0xab000000, + A64I_NEGw = 0x4b0003e0, + A64I_NEGx = 0xcb0003e0, + A64I_SUBw = 0x4b000000, + A64I_SUBx = 0xcb000000, + A64I_SUBSw = 0x6b000000, + A64I_SUBSx = 0xeb000000, + + A64I_MULw = 0x1b007c00, + A64I_MULx = 0x9b007c00, + A64I_SMULL = 0x9b207c00, + + A64I_ANDw = 0x0a000000, + A64I_ANDx = 0x8a000000, + A64I_ANDSw = 0x6a000000, + A64I_ANDSx = 0xea000000, + A64I_EORw = 0x4a000000, + A64I_EORx = 0xca000000, + A64I_ORRw = 0x2a000000, + A64I_ORRx = 0xaa000000, + A64I_TSTw = 0x6a00001f, + A64I_TSTx = 0xea00001f, + + A64I_CMPw = 0x6b00001f, + A64I_CMPx = 0xeb00001f, + A64I_CMNw = 0x2b00001f, + A64I_CMNx = 0xab00001f, + A64I_CCMPw = 0x7a400000, + A64I_CCMPx = 0xfa400000, + A64I_CSELw = 0x1a800000, + A64I_CSELx = 0x9a800000, + + A64I_ASRw = 0x13007c00, + A64I_ASRx = 0x9340fc00, + A64I_LSLx = 0xd3400000, + A64I_LSRx = 0xd340fc00, + A64I_SHRw = 0x1ac02000, + A64I_SHRx = 0x9ac02000, /* lsl/lsr/asr/ror x0, x0, x0 */ + A64I_REVw = 0x5ac00800, + A64I_REVx = 0xdac00c00, + + A64I_EXTRw = 0x13800000, + A64I_EXTRx = 0x93c00000, + A64I_BFMw = 0x33000000, + A64I_BFMx = 0xb3400000, + A64I_SBFMw = 0x13000000, + A64I_SBFMx = 0x93400000, + A64I_SXTBw = 0x13001c00, + A64I_SXTHw = 0x13003c00, + A64I_SXTW = 0x93407c00, + A64I_UBFMw = 0x53000000, + A64I_UBFMx = 0xd3400000, + A64I_UXTBw = 0x53001c00, + A64I_UXTHw = 0x53003c00, + + A64I_MOVw = 0x2a0003e0, + A64I_MOVx = 0xaa0003e0, + A64I_MVNw = 0x2a2003e0, + A64I_MVNx = 0xaa2003e0, + A64I_MOVKw = 0x72800000, + A64I_MOVKx = 0xf2800000, + A64I_MOVZw = 0x52800000, + A64I_MOVZx = 0xd2800000, + A64I_MOVNw = 0x12800000, + A64I_MOVNx = 0x92800000, + + A64I_LDRB = 0x39400000, + A64I_LDRH = 0x79400000, + A64I_LDRw = 0xb9400000, + A64I_LDRx = 0xf9400000, + A64I_LDRLw = 0x18000000, + A64I_LDRLx = 0x58000000, + A64I_STRB = 0x39000000, + A64I_STRH = 0x79000000, + A64I_STRw = 0xb9000000, + A64I_STRx = 0xf9000000, + A64I_STPw = 0x29000000, + A64I_STPx = 0xa9000000, + A64I_LDPw = 0x29400000, + A64I_LDPx = 0xa9400000, + + A64I_B = 0x14000000, + A64I_BCC = 0x54000000, + A64I_BL = 0x94000000, + A64I_BR = 0xd61f0000, + A64I_BLR = 0xd63f0000, + A64I_TBZ = 0x36000000, + A64I_TBNZ = 0x37000000, + A64I_CBZ = 0x34000000, + A64I_CBNZ = 0x35000000, + + A64I_NOP = 0xd503201f, + + /* FP */ + A64I_FADDd = 0x1e602800, + A64I_FSUBd = 0x1e603800, + A64I_FMADDd = 0x1f400000, + A64I_FMSUBd = 0x1f408000, + A64I_FNMADDd = 0x1f600000, + A64I_FNMSUBd = 0x1f608000, + A64I_FMULd = 0x1e600800, + A64I_FDIVd = 0x1e601800, + A64I_FNEGd = 0x1e614000, + A64I_FABS = 0x1e60c000, + A64I_FSQRTd = 0x1e61c000, + A64I_LDRs = 0xbd400000, + A64I_LDRd = 0xfd400000, + A64I_STRs = 0xbd000000, + A64I_STRd = 0xfd000000, + A64I_LDPs = 0x2d400000, + A64I_LDPd = 0x6d400000, + A64I_STPs = 0x2d000000, + A64I_STPd = 0x6d000000, + A64I_FCMPd = 0x1e602000, + A64I_FCMPZd = 0x1e602008, + A64I_FCSELd = 0x1e600c00, + A64I_FRINTMd = 0x1e654000, + A64I_FRINTPd = 0x1e64c000, + A64I_FRINTZd = 0x1e65c000, + + A64I_FCVT_F32_F64 = 0x1e624000, + A64I_FCVT_F64_F32 = 0x1e22c000, + A64I_FCVT_F32_S32 = 0x1e220000, + A64I_FCVT_F64_S32 = 0x1e620000, + A64I_FCVT_F32_U32 = 0x1e230000, + A64I_FCVT_F64_U32 = 0x1e630000, + A64I_FCVT_F32_S64 = 0x9e220000, + A64I_FCVT_F64_S64 = 0x9e620000, + A64I_FCVT_F32_U64 = 0x9e230000, + A64I_FCVT_F64_U64 = 0x9e630000, + A64I_FCVT_S32_F64 = 0x1e780000, + A64I_FCVT_S32_F32 = 0x1e380000, + A64I_FCVT_U32_F64 = 0x1e790000, + A64I_FCVT_U32_F32 = 0x1e390000, + A64I_FCVT_S64_F64 = 0x9e780000, + A64I_FCVT_S64_F32 = 0x9e380000, + A64I_FCVT_U64_F64 = 0x9e790000, + A64I_FCVT_U64_F32 = 0x9e390000, + + A64I_FMOV_S = 0x1e204000, + A64I_FMOV_D = 0x1e604000, + A64I_FMOV_R_S = 0x1e260000, + A64I_FMOV_S_R = 0x1e270000, + A64I_FMOV_R_D = 0x9e660000, + A64I_FMOV_D_R = 0x9e670000, + A64I_FMOV_DI = 0x1e601000, +} A64Ins; + +typedef enum A64Shift { + A64SH_LSL, A64SH_LSR, A64SH_ASR, A64SH_ROR +} A64Shift; + +typedef enum A64Extend { + A64EX_UXTB, A64EX_UXTH, A64EX_UXTW, A64EX_UXTX, + A64EX_SXTB, A64EX_SXTH, A64EX_SXTW, A64EX_SXTX, +} A64Extend; + +/* ARM condition codes. */ +typedef enum A64CC { + CC_EQ, CC_NE, CC_CS, CC_CC, CC_MI, CC_PL, CC_VS, CC_VC, + CC_HI, CC_LS, CC_GE, CC_LT, CC_GT, CC_LE, CC_AL, + CC_HS = CC_CS, CC_LO = CC_CC +} A64CC; + +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_target_mips.h b/fluent-bit/lib/luajit-3065c9/src/lj_target_mips.h new file mode 100644 index 00000000..da72d61a --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_target_mips.h @@ -0,0 +1,417 @@ +/* +** Definitions for MIPS CPUs. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#ifndef _LJ_TARGET_MIPS_H +#define _LJ_TARGET_MIPS_H + +/* -- Registers IDs ------------------------------------------------------- */ + +#define GPRDEF(_) \ + _(R0) _(R1) _(R2) _(R3) _(R4) _(R5) _(R6) _(R7) \ + _(R8) _(R9) _(R10) _(R11) _(R12) _(R13) _(R14) _(R15) \ + _(R16) _(R17) _(R18) _(R19) _(R20) _(R21) _(R22) _(R23) \ + _(R24) _(R25) _(SYS1) _(SYS2) _(R28) _(SP) _(R30) _(RA) +#if LJ_SOFTFP +#define FPRDEF(_) +#else +#define FPRDEF(_) \ + _(F0) _(F1) _(F2) _(F3) _(F4) _(F5) _(F6) _(F7) \ + _(F8) _(F9) _(F10) _(F11) _(F12) _(F13) _(F14) _(F15) \ + _(F16) _(F17) _(F18) _(F19) _(F20) _(F21) _(F22) _(F23) \ + _(F24) _(F25) _(F26) _(F27) _(F28) _(F29) _(F30) _(F31) +#endif +#define VRIDDEF(_) + +#define RIDENUM(name) RID_##name, + +enum { + GPRDEF(RIDENUM) /* General-purpose registers (GPRs). */ + FPRDEF(RIDENUM) /* Floating-point registers (FPRs). */ + RID_MAX, + RID_ZERO = RID_R0, + RID_TMP = RID_RA, + RID_GP = RID_R28, + + /* Calling conventions. */ + RID_RET = RID_R2, +#if LJ_LE + RID_RETHI = RID_R3, + RID_RETLO = RID_R2, +#else + RID_RETHI = RID_R2, + RID_RETLO = RID_R3, +#endif +#if LJ_SOFTFP + RID_FPRET = RID_R2, +#else + RID_FPRET = RID_F0, +#endif + RID_CFUNCADDR = RID_R25, + + /* These definitions must match with the *.dasc file(s): */ + RID_BASE = RID_R16, /* Interpreter BASE. */ + RID_LPC = RID_R18, /* Interpreter PC. */ + RID_DISPATCH = RID_R19, /* Interpreter DISPATCH table. */ + RID_LREG = RID_R20, /* Interpreter L. */ + RID_JGL = RID_R30, /* On-trace: global_State + 32768. */ + + /* Register ranges [min, max) and number of registers. */ + RID_MIN_GPR = RID_R0, + RID_MAX_GPR = RID_RA+1, + RID_MIN_FPR = RID_MAX_GPR, +#if LJ_SOFTFP + RID_MAX_FPR = RID_MIN_FPR, +#else + RID_MAX_FPR = RID_F31+1, +#endif + RID_NUM_GPR = RID_MAX_GPR - RID_MIN_GPR, + RID_NUM_FPR = RID_MAX_FPR - RID_MIN_FPR /* Only even regs are used. */ +}; + +#define RID_NUM_KREF RID_NUM_GPR +#define RID_MIN_KREF RID_R0 + +/* -- Register sets ------------------------------------------------------- */ + +/* Make use of all registers, except ZERO, TMP, SP, SYS1, SYS2, JGL and GP. */ +#define RSET_FIXED \ + (RID2RSET(RID_ZERO)|RID2RSET(RID_TMP)|RID2RSET(RID_SP)|\ + RID2RSET(RID_SYS1)|RID2RSET(RID_SYS2)|RID2RSET(RID_JGL)|RID2RSET(RID_GP)) +#define RSET_GPR (RSET_RANGE(RID_MIN_GPR, RID_MAX_GPR) - RSET_FIXED) +#if LJ_SOFTFP +#define RSET_FPR 0 +#else +#if LJ_32 +#define RSET_FPR \ + (RID2RSET(RID_F0)|RID2RSET(RID_F2)|RID2RSET(RID_F4)|RID2RSET(RID_F6)|\ + RID2RSET(RID_F8)|RID2RSET(RID_F10)|RID2RSET(RID_F12)|RID2RSET(RID_F14)|\ + RID2RSET(RID_F16)|RID2RSET(RID_F18)|RID2RSET(RID_F20)|RID2RSET(RID_F22)|\ + RID2RSET(RID_F24)|RID2RSET(RID_F26)|RID2RSET(RID_F28)|RID2RSET(RID_F30)) +#else +#define RSET_FPR RSET_RANGE(RID_MIN_FPR, RID_MAX_FPR) +#endif +#endif +#define RSET_ALL (RSET_GPR|RSET_FPR) +#define RSET_INIT RSET_ALL + +#define RSET_SCRATCH_GPR \ + (RSET_RANGE(RID_R1, RID_R15+1)|\ + RID2RSET(RID_R24)|RID2RSET(RID_R25)) +#if LJ_SOFTFP +#define RSET_SCRATCH_FPR 0 +#else +#if LJ_32 +#define RSET_SCRATCH_FPR \ + (RID2RSET(RID_F0)|RID2RSET(RID_F2)|RID2RSET(RID_F4)|RID2RSET(RID_F6)|\ + RID2RSET(RID_F8)|RID2RSET(RID_F10)|RID2RSET(RID_F12)|RID2RSET(RID_F14)|\ + RID2RSET(RID_F16)|RID2RSET(RID_F18)) +#else +#define RSET_SCRATCH_FPR RSET_RANGE(RID_F0, RID_F24) +#endif +#endif +#define RSET_SCRATCH (RSET_SCRATCH_GPR|RSET_SCRATCH_FPR) +#define REGARG_FIRSTGPR RID_R4 +#if LJ_32 +#define REGARG_LASTGPR RID_R7 +#define REGARG_NUMGPR 4 +#else +#define REGARG_LASTGPR RID_R11 +#define REGARG_NUMGPR 8 +#endif +#if LJ_ABI_SOFTFP +#define REGARG_FIRSTFPR 0 +#define REGARG_LASTFPR 0 +#define REGARG_NUMFPR 0 +#else +#define REGARG_FIRSTFPR RID_F12 +#if LJ_32 +#define REGARG_LASTFPR RID_F14 +#define REGARG_NUMFPR 2 +#else +#define REGARG_LASTFPR RID_F19 +#define REGARG_NUMFPR 8 +#endif +#endif + +/* -- Spill slots --------------------------------------------------------- */ + +/* Spill slots are 32 bit wide. An even/odd pair is used for FPRs. +** +** SPS_FIXED: Available fixed spill slots in interpreter frame. +** This definition must match with the *.dasc file(s). +** +** SPS_FIRST: First spill slot for general use. +*/ +#if LJ_32 +#define SPS_FIXED 5 +#else +#define SPS_FIXED 4 +#endif +#define SPS_FIRST 4 + +#define SPOFS_TMP 0 + +#define sps_scale(slot) (4 * (int32_t)(slot)) +#define sps_align(slot) (((slot) - SPS_FIXED + 1) & ~1) + +/* -- Exit state ---------------------------------------------------------- */ + +/* This definition must match with the *.dasc file(s). */ +typedef struct { +#if !LJ_SOFTFP + lua_Number fpr[RID_NUM_FPR]; /* Floating-point registers. */ +#endif + intptr_t gpr[RID_NUM_GPR]; /* General-purpose registers. */ + int32_t spill[256]; /* Spill slots. */ +} ExitState; + +/* Highest exit + 1 indicates stack check. */ +#define EXITSTATE_CHECKEXIT 1 + +/* Return the address of a per-trace exit stub. */ +static LJ_AINLINE uint32_t *exitstub_trace_addr_(uint32_t *p) +{ + while (*p == 0x00000000) p++; /* Skip MIPSI_NOP. */ + return p; +} +/* Avoid dependence on lj_jit.h if only including lj_target.h. */ +#define exitstub_trace_addr(T, exitno) \ + exitstub_trace_addr_((MCode *)((char *)(T)->mcode + (T)->szmcode)) + +/* -- Instructions -------------------------------------------------------- */ + +/* Instruction fields. */ +#define MIPSF_S(r) ((r) << 21) +#define MIPSF_T(r) ((r) << 16) +#define MIPSF_D(r) ((r) << 11) +#define MIPSF_R(r) ((r) << 21) +#define MIPSF_H(r) ((r) << 16) +#define MIPSF_G(r) ((r) << 11) +#define MIPSF_F(r) ((r) << 6) +#define MIPSF_A(n) ((n) << 6) +#define MIPSF_M(n) ((n) << 11) +#define MIPSF_L(n) ((n) << 6) + +typedef enum MIPSIns { + MIPSI_D = 0x38, + MIPSI_DV = 0x10, + MIPSI_D32 = 0x3c, + /* Integer instructions. */ + MIPSI_MOVE = 0x00000025, + MIPSI_NOP = 0x00000000, + + MIPSI_LI = 0x24000000, + MIPSI_LU = 0x34000000, + MIPSI_LUI = 0x3c000000, + + MIPSI_AND = 0x00000024, + MIPSI_ANDI = 0x30000000, + MIPSI_OR = 0x00000025, + MIPSI_ORI = 0x34000000, + MIPSI_XOR = 0x00000026, + MIPSI_XORI = 0x38000000, + MIPSI_NOR = 0x00000027, + + MIPSI_SLT = 0x0000002a, + MIPSI_SLTU = 0x0000002b, + MIPSI_SLTI = 0x28000000, + MIPSI_SLTIU = 0x2c000000, + + MIPSI_ADDU = 0x00000021, + MIPSI_ADDIU = 0x24000000, + MIPSI_SUB = 0x00000022, + MIPSI_SUBU = 0x00000023, + +#if !LJ_TARGET_MIPSR6 + MIPSI_MUL = 0x70000002, + MIPSI_DIV = 0x0000001a, + MIPSI_DIVU = 0x0000001b, + + MIPSI_MOVZ = 0x0000000a, + MIPSI_MOVN = 0x0000000b, + MIPSI_MFHI = 0x00000010, + MIPSI_MFLO = 0x00000012, + MIPSI_MULT = 0x00000018, +#else + MIPSI_MUL = 0x00000098, + MIPSI_MUH = 0x000000d8, + MIPSI_DIV = 0x0000009a, + MIPSI_DIVU = 0x0000009b, + + MIPSI_SELEQZ = 0x00000035, + MIPSI_SELNEZ = 0x00000037, +#endif + + MIPSI_SLL = 0x00000000, + MIPSI_SRL = 0x00000002, + MIPSI_SRA = 0x00000003, + MIPSI_ROTR = 0x00200002, /* MIPSXXR2 */ + MIPSI_DROTR = 0x0020003a, + MIPSI_DROTR32 = 0x0020003e, + MIPSI_SLLV = 0x00000004, + MIPSI_SRLV = 0x00000006, + MIPSI_SRAV = 0x00000007, + MIPSI_ROTRV = 0x00000046, /* MIPSXXR2 */ + MIPSI_DROTRV = 0x00000056, + + MIPSI_INS = 0x7c000004, /* MIPSXXR2 */ + + MIPSI_SEB = 0x7c000420, /* MIPSXXR2 */ + MIPSI_SEH = 0x7c000620, /* MIPSXXR2 */ + MIPSI_WSBH = 0x7c0000a0, /* MIPSXXR2 */ + MIPSI_DSBH = 0x7c0000a4, + + MIPSI_B = 0x10000000, + MIPSI_J = 0x08000000, + MIPSI_JAL = 0x0c000000, +#if !LJ_TARGET_MIPSR6 + MIPSI_JALX = 0x74000000, + MIPSI_JR = 0x00000008, +#else + MIPSI_JR = 0x00000009, + MIPSI_BALC = 0xe8000000, +#endif + MIPSI_JALR = 0x0000f809, + + MIPSI_BEQ = 0x10000000, + MIPSI_BNE = 0x14000000, + MIPSI_BLEZ = 0x18000000, + MIPSI_BGTZ = 0x1c000000, + MIPSI_BLTZ = 0x04000000, + MIPSI_BGEZ = 0x04010000, + + /* Load/store instructions. */ + MIPSI_LW = 0x8c000000, + MIPSI_LD = 0xdc000000, + MIPSI_SW = 0xac000000, + MIPSI_SD = 0xfc000000, + MIPSI_LB = 0x80000000, + MIPSI_SB = 0xa0000000, + MIPSI_LH = 0x84000000, + MIPSI_SH = 0xa4000000, + MIPSI_LBU = 0x90000000, + MIPSI_LHU = 0x94000000, + MIPSI_LWC1 = 0xc4000000, + MIPSI_SWC1 = 0xe4000000, + MIPSI_LDC1 = 0xd4000000, + MIPSI_SDC1 = 0xf4000000, + + /* MIPS64 instructions. */ + MIPSI_DADD = 0x0000002c, + MIPSI_DADDU = 0x0000002d, + MIPSI_DADDIU = 0x64000000, + MIPSI_DSUB = 0x0000002e, + MIPSI_DSUBU = 0x0000002f, +#if !LJ_TARGET_MIPSR6 + MIPSI_DDIV = 0x0000001e, + MIPSI_DDIVU = 0x0000001f, + MIPSI_DMULT = 0x0000001c, + MIPSI_DMULTU = 0x0000001d, +#else + MIPSI_DDIV = 0x0000009e, + MIPSI_DMOD = 0x000000de, + MIPSI_DDIVU = 0x0000009f, + MIPSI_DMODU = 0x000000df, + MIPSI_DMUL = 0x0000009c, + MIPSI_DMUH = 0x000000dc, +#endif + + MIPSI_DSLL = 0x00000038, + MIPSI_DSRL = 0x0000003a, + MIPSI_DSLLV = 0x00000014, + MIPSI_DSRLV = 0x00000016, + MIPSI_DSRA = 0x0000003b, + MIPSI_DSRAV = 0x00000017, + MIPSI_DSRA32 = 0x0000003f, + MIPSI_DSLL32 = 0x0000003c, + MIPSI_DSRL32 = 0x0000003e, + MIPSI_DSHD = 0x7c000164, + + MIPSI_AADDU = LJ_32 ? MIPSI_ADDU : MIPSI_DADDU, + MIPSI_AADDIU = LJ_32 ? MIPSI_ADDIU : MIPSI_DADDIU, + MIPSI_ASUBU = LJ_32 ? MIPSI_SUBU : MIPSI_DSUBU, + MIPSI_AL = LJ_32 ? MIPSI_LW : MIPSI_LD, + MIPSI_AS = LJ_32 ? MIPSI_SW : MIPSI_SD, +#if LJ_TARGET_MIPSR6 + MIPSI_LSA = 0x00000005, + MIPSI_DLSA = 0x00000015, + MIPSI_ALSA = LJ_32 ? MIPSI_LSA : MIPSI_DLSA, +#endif + + /* Extract/insert instructions. */ + MIPSI_DEXTM = 0x7c000001, + MIPSI_DEXTU = 0x7c000002, + MIPSI_DEXT = 0x7c000003, + MIPSI_DINSM = 0x7c000005, + MIPSI_DINSU = 0x7c000006, + MIPSI_DINS = 0x7c000007, + + MIPSI_FLOOR_D = 0x4620000b, + + /* FP instructions. */ + MIPSI_MOV_S = 0x46000006, + MIPSI_MOV_D = 0x46200006, +#if !LJ_TARGET_MIPSR6 + MIPSI_MOVT_D = 0x46210011, + MIPSI_MOVF_D = 0x46200011, +#else + MIPSI_MIN_D = 0x4620001C, + MIPSI_MAX_D = 0x4620001E, + MIPSI_SEL_D = 0x46200010, +#endif + + MIPSI_ABS_D = 0x46200005, + MIPSI_NEG_D = 0x46200007, + + MIPSI_ADD_D = 0x46200000, + MIPSI_SUB_D = 0x46200001, + MIPSI_MUL_D = 0x46200002, + MIPSI_DIV_D = 0x46200003, + MIPSI_SQRT_D = 0x46200004, + + MIPSI_ADD_S = 0x46000000, + MIPSI_SUB_S = 0x46000001, + + MIPSI_CVT_D_S = 0x46000021, + MIPSI_CVT_W_S = 0x46000024, + MIPSI_CVT_S_D = 0x46200020, + MIPSI_CVT_W_D = 0x46200024, + MIPSI_CVT_S_W = 0x46800020, + MIPSI_CVT_D_W = 0x46800021, + MIPSI_CVT_S_L = 0x46a00020, + MIPSI_CVT_D_L = 0x46a00021, + + MIPSI_TRUNC_W_S = 0x4600000d, + MIPSI_TRUNC_W_D = 0x4620000d, + MIPSI_TRUNC_L_S = 0x46000009, + MIPSI_TRUNC_L_D = 0x46200009, + MIPSI_FLOOR_W_S = 0x4600000f, + MIPSI_FLOOR_W_D = 0x4620000f, + + MIPSI_MFC1 = 0x44000000, + MIPSI_MTC1 = 0x44800000, + MIPSI_DMTC1 = 0x44a00000, + MIPSI_DMFC1 = 0x44200000, + +#if !LJ_TARGET_MIPSR6 + MIPSI_BC1F = 0x45000000, + MIPSI_BC1T = 0x45010000, + MIPSI_C_EQ_D = 0x46200032, + MIPSI_C_OLT_S = 0x46000034, + MIPSI_C_OLT_D = 0x46200034, + MIPSI_C_ULT_D = 0x46200035, + MIPSI_C_OLE_D = 0x46200036, + MIPSI_C_ULE_D = 0x46200037, +#else + MIPSI_BC1EQZ = 0x45200000, + MIPSI_BC1NEZ = 0x45a00000, + MIPSI_CMP_EQ_D = 0x46a00002, + MIPSI_CMP_LT_S = 0x46800004, + MIPSI_CMP_LT_D = 0x46a00004, +#endif + +} MIPSIns; + +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_target_ppc.h b/fluent-bit/lib/luajit-3065c9/src/lj_target_ppc.h new file mode 100644 index 00000000..bc9802a4 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_target_ppc.h @@ -0,0 +1,280 @@ +/* +** Definitions for PPC CPUs. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#ifndef _LJ_TARGET_PPC_H +#define _LJ_TARGET_PPC_H + +/* -- Registers IDs ------------------------------------------------------- */ + +#define GPRDEF(_) \ + _(R0) _(SP) _(SYS1) _(R3) _(R4) _(R5) _(R6) _(R7) \ + _(R8) _(R9) _(R10) _(R11) _(R12) _(SYS2) _(R14) _(R15) \ + _(R16) _(R17) _(R18) _(R19) _(R20) _(R21) _(R22) _(R23) \ + _(R24) _(R25) _(R26) _(R27) _(R28) _(R29) _(R30) _(R31) +#define FPRDEF(_) \ + _(F0) _(F1) _(F2) _(F3) _(F4) _(F5) _(F6) _(F7) \ + _(F8) _(F9) _(F10) _(F11) _(F12) _(F13) _(F14) _(F15) \ + _(F16) _(F17) _(F18) _(F19) _(F20) _(F21) _(F22) _(F23) \ + _(F24) _(F25) _(F26) _(F27) _(F28) _(F29) _(F30) _(F31) +#define VRIDDEF(_) + +#define RIDENUM(name) RID_##name, + +enum { + GPRDEF(RIDENUM) /* General-purpose registers (GPRs). */ + FPRDEF(RIDENUM) /* Floating-point registers (FPRs). */ + RID_MAX, + RID_TMP = RID_R0, + + /* Calling conventions. */ + RID_RET = RID_R3, + RID_RETHI = RID_R3, + RID_RETLO = RID_R4, + RID_FPRET = RID_F1, + + /* These definitions must match with the *.dasc file(s): */ + RID_BASE = RID_R14, /* Interpreter BASE. */ + RID_LPC = RID_R16, /* Interpreter PC. */ + RID_DISPATCH = RID_R17, /* Interpreter DISPATCH table. */ + RID_LREG = RID_R18, /* Interpreter L. */ + RID_JGL = RID_R31, /* On-trace: global_State + 32768. */ + + /* Register ranges [min, max) and number of registers. */ + RID_MIN_GPR = RID_R0, + RID_MAX_GPR = RID_R31+1, + RID_MIN_FPR = RID_F0, + RID_MAX_FPR = RID_F31+1, + RID_NUM_GPR = RID_MAX_GPR - RID_MIN_GPR, + RID_NUM_FPR = RID_MAX_FPR - RID_MIN_FPR +}; + +#define RID_NUM_KREF RID_NUM_GPR +#define RID_MIN_KREF RID_R0 + +/* -- Register sets ------------------------------------------------------- */ + +/* Make use of all registers, except TMP, SP, SYS1, SYS2 and JGL. */ +#define RSET_FIXED \ + (RID2RSET(RID_TMP)|RID2RSET(RID_SP)|RID2RSET(RID_SYS1)|\ + RID2RSET(RID_SYS2)|RID2RSET(RID_JGL)) +#define RSET_GPR (RSET_RANGE(RID_MIN_GPR, RID_MAX_GPR) - RSET_FIXED) +#define RSET_FPR RSET_RANGE(RID_MIN_FPR, RID_MAX_FPR) +#define RSET_ALL (RSET_GPR|RSET_FPR) +#define RSET_INIT RSET_ALL + +#define RSET_SCRATCH_GPR (RSET_RANGE(RID_R3, RID_R12+1)) +#define RSET_SCRATCH_FPR (RSET_RANGE(RID_F0, RID_F13+1)) +#define RSET_SCRATCH (RSET_SCRATCH_GPR|RSET_SCRATCH_FPR) +#define REGARG_FIRSTGPR RID_R3 +#define REGARG_LASTGPR RID_R10 +#define REGARG_NUMGPR 8 +#define REGARG_FIRSTFPR RID_F1 +#define REGARG_LASTFPR RID_F8 +#define REGARG_NUMFPR 8 + +/* -- Spill slots --------------------------------------------------------- */ + +/* Spill slots are 32 bit wide. An even/odd pair is used for FPRs. +** +** SPS_FIXED: Available fixed spill slots in interpreter frame. +** This definition must match with the *.dasc file(s). +** +** SPS_FIRST: First spill slot for general use. +** [sp+12] tmplo word \ +** [sp+ 8] tmphi word / tmp dword, parameter area for callee +** [sp+ 4] tmpw, LR of callee +** [sp+ 0] stack chain +*/ +#define SPS_FIXED 7 +#define SPS_FIRST 4 + +/* Stack offsets for temporary slots. Used for FP<->int conversions etc. */ +#define SPOFS_TMPW 4 +#define SPOFS_TMP 8 +#define SPOFS_TMPHI 8 +#define SPOFS_TMPLO 12 + +#define sps_scale(slot) (4 * (int32_t)(slot)) +#define sps_align(slot) (((slot) - SPS_FIXED + 3) & ~3) + +/* -- Exit state ---------------------------------------------------------- */ + +/* This definition must match with the *.dasc file(s). */ +typedef struct { + lua_Number fpr[RID_NUM_FPR]; /* Floating-point registers. */ + intptr_t gpr[RID_NUM_GPR]; /* General-purpose registers. */ + int32_t spill[256]; /* Spill slots. */ +} ExitState; + +/* Highest exit + 1 indicates stack check. */ +#define EXITSTATE_CHECKEXIT 1 + +/* Return the address of a per-trace exit stub. */ +static LJ_AINLINE uint32_t *exitstub_trace_addr_(uint32_t *p, uint32_t exitno) +{ + while (*p == 0x60000000) p++; /* Skip PPCI_NOP. */ + return p + 3 + exitno; +} +/* Avoid dependence on lj_jit.h if only including lj_target.h. */ +#define exitstub_trace_addr(T, exitno) \ + exitstub_trace_addr_((MCode *)((char *)(T)->mcode + (T)->szmcode), (exitno)) + +/* -- Instructions -------------------------------------------------------- */ + +/* Instruction fields. */ +#define PPCF_CC(cc) ((((cc) & 3) << 16) | (((cc) & 4) << 22)) +#define PPCF_T(r) ((r) << 21) +#define PPCF_A(r) ((r) << 16) +#define PPCF_B(r) ((r) << 11) +#define PPCF_C(r) ((r) << 6) +#define PPCF_MB(n) ((n) << 6) +#define PPCF_ME(n) ((n) << 1) +#define PPCF_Y 0x00200000 +#define PPCF_DOT 0x00000001 + +typedef enum PPCIns { + /* Integer instructions. */ + PPCI_MR = 0x7c000378, + PPCI_NOP = 0x60000000, + + PPCI_LI = 0x38000000, + PPCI_LIS = 0x3c000000, + + PPCI_ADD = 0x7c000214, + PPCI_ADDC = 0x7c000014, + PPCI_ADDO = 0x7c000614, + PPCI_ADDE = 0x7c000114, + PPCI_ADDZE = 0x7c000194, + PPCI_ADDME = 0x7c0001d4, + PPCI_ADDI = 0x38000000, + PPCI_ADDIS = 0x3c000000, + PPCI_ADDIC = 0x30000000, + PPCI_ADDICDOT = 0x34000000, + + PPCI_SUBF = 0x7c000050, + PPCI_SUBFC = 0x7c000010, + PPCI_SUBFO = 0x7c000450, + PPCI_SUBFE = 0x7c000110, + PPCI_SUBFZE = 0x7c000190, + PPCI_SUBFME = 0x7c0001d0, + PPCI_SUBFIC = 0x20000000, + + PPCI_NEG = 0x7c0000d0, + + PPCI_AND = 0x7c000038, + PPCI_ANDC = 0x7c000078, + PPCI_NAND = 0x7c0003b8, + PPCI_ANDIDOT = 0x70000000, + PPCI_ANDISDOT = 0x74000000, + + PPCI_OR = 0x7c000378, + PPCI_NOR = 0x7c0000f8, + PPCI_ORI = 0x60000000, + PPCI_ORIS = 0x64000000, + + PPCI_XOR = 0x7c000278, + PPCI_EQV = 0x7c000238, + PPCI_XORI = 0x68000000, + PPCI_XORIS = 0x6c000000, + + PPCI_CMPW = 0x7c000000, + PPCI_CMPLW = 0x7c000040, + PPCI_CMPWI = 0x2c000000, + PPCI_CMPLWI = 0x28000000, + + PPCI_MULLW = 0x7c0001d6, + PPCI_MULLI = 0x1c000000, + PPCI_MULLWO = 0x7c0005d6, + + PPCI_EXTSB = 0x7c000774, + PPCI_EXTSH = 0x7c000734, + + PPCI_SLW = 0x7c000030, + PPCI_SRW = 0x7c000430, + PPCI_SRAW = 0x7c000630, + PPCI_SRAWI = 0x7c000670, + + PPCI_RLWNM = 0x5c000000, + PPCI_RLWINM = 0x54000000, + PPCI_RLWIMI = 0x50000000, + + PPCI_B = 0x48000000, + PPCI_BL = 0x48000001, + PPCI_BC = 0x40800000, + PPCI_BCL = 0x40800001, + PPCI_BCTR = 0x4e800420, + PPCI_BCTRL = 0x4e800421, + + PPCI_CRANDC = 0x4c000102, + PPCI_CRXOR = 0x4c000182, + PPCI_CRAND = 0x4c000202, + PPCI_CREQV = 0x4c000242, + PPCI_CRORC = 0x4c000342, + PPCI_CROR = 0x4c000382, + + PPCI_MFLR = 0x7c0802a6, + PPCI_MTCTR = 0x7c0903a6, + + PPCI_MCRXR = 0x7c000400, + + /* Load/store instructions. */ + PPCI_LWZ = 0x80000000, + PPCI_LBZ = 0x88000000, + PPCI_STW = 0x90000000, + PPCI_STB = 0x98000000, + PPCI_LHZ = 0xa0000000, + PPCI_LHA = 0xa8000000, + PPCI_STH = 0xb0000000, + + PPCI_STWU = 0x94000000, + + PPCI_LFS = 0xc0000000, + PPCI_LFD = 0xc8000000, + PPCI_STFS = 0xd0000000, + PPCI_STFD = 0xd8000000, + + PPCI_LWZX = 0x7c00002e, + PPCI_LBZX = 0x7c0000ae, + PPCI_STWX = 0x7c00012e, + PPCI_STBX = 0x7c0001ae, + PPCI_LHZX = 0x7c00022e, + PPCI_LHAX = 0x7c0002ae, + PPCI_STHX = 0x7c00032e, + + PPCI_LWBRX = 0x7c00042c, + PPCI_STWBRX = 0x7c00052c, + + PPCI_LFSX = 0x7c00042e, + PPCI_LFDX = 0x7c0004ae, + PPCI_STFSX = 0x7c00052e, + PPCI_STFDX = 0x7c0005ae, + + /* FP instructions. */ + PPCI_FMR = 0xfc000090, + PPCI_FNEG = 0xfc000050, + PPCI_FABS = 0xfc000210, + + PPCI_FRSP = 0xfc000018, + PPCI_FCTIWZ = 0xfc00001e, + + PPCI_FADD = 0xfc00002a, + PPCI_FSUB = 0xfc000028, + PPCI_FMUL = 0xfc000032, + PPCI_FDIV = 0xfc000024, + PPCI_FSQRT = 0xfc00002c, + + PPCI_FMADD = 0xfc00003a, + PPCI_FMSUB = 0xfc000038, + PPCI_FNMSUB = 0xfc00003c, + + PPCI_FCMPU = 0xfc000000, + PPCI_FSEL = 0xfc00002e, +} PPCIns; + +typedef enum PPCCC { + CC_GE, CC_LE, CC_NE, CC_NS, CC_LT, CC_GT, CC_EQ, CC_SO +} PPCCC; + +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_target_x86.h b/fluent-bit/lib/luajit-3065c9/src/lj_target_x86.h new file mode 100644 index 00000000..69cb8ca5 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_target_x86.h @@ -0,0 +1,357 @@ +/* +** Definitions for x86 and x64 CPUs. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#ifndef _LJ_TARGET_X86_H +#define _LJ_TARGET_X86_H + +/* -- Registers IDs ------------------------------------------------------- */ + +#if LJ_64 +#define GPRDEF(_) \ + _(EAX) _(ECX) _(EDX) _(EBX) _(ESP) _(EBP) _(ESI) _(EDI) \ + _(R8D) _(R9D) _(R10D) _(R11D) _(R12D) _(R13D) _(R14D) _(R15D) +#define FPRDEF(_) \ + _(XMM0) _(XMM1) _(XMM2) _(XMM3) _(XMM4) _(XMM5) _(XMM6) _(XMM7) \ + _(XMM8) _(XMM9) _(XMM10) _(XMM11) _(XMM12) _(XMM13) _(XMM14) _(XMM15) +#else +#define GPRDEF(_) \ + _(EAX) _(ECX) _(EDX) _(EBX) _(ESP) _(EBP) _(ESI) _(EDI) +#define FPRDEF(_) \ + _(XMM0) _(XMM1) _(XMM2) _(XMM3) _(XMM4) _(XMM5) _(XMM6) _(XMM7) +#endif +#define VRIDDEF(_) \ + _(MRM) _(RIP) + +#define RIDENUM(name) RID_##name, + +enum { + GPRDEF(RIDENUM) /* General-purpose registers (GPRs). */ + FPRDEF(RIDENUM) /* Floating-point registers (FPRs). */ + RID_MAX, + RID_MRM = RID_MAX, /* Pseudo-id for ModRM operand. */ + RID_RIP = RID_MAX+5, /* Pseudo-id for RIP (x64 only), rm bits = 5. */ + + /* Calling conventions. */ + RID_SP = RID_ESP, + RID_RET = RID_EAX, +#if LJ_64 + RID_FPRET = RID_XMM0, +#endif + RID_RETLO = RID_EAX, + RID_RETHI = RID_EDX, + + /* These definitions must match with the *.dasc file(s): */ + RID_BASE = RID_EDX, /* Interpreter BASE. */ +#if LJ_64 && !LJ_ABI_WIN + RID_LPC = RID_EBX, /* Interpreter PC. */ + RID_DISPATCH = RID_R14D, /* Interpreter DISPATCH table. */ +#else + RID_LPC = RID_ESI, /* Interpreter PC. */ + RID_DISPATCH = RID_EBX, /* Interpreter DISPATCH table. */ +#endif + + /* Register ranges [min, max) and number of registers. */ + RID_MIN_GPR = RID_EAX, + RID_MIN_FPR = RID_XMM0, + RID_MAX_GPR = RID_MIN_FPR, + RID_MAX_FPR = RID_MAX, + RID_NUM_GPR = RID_MAX_GPR - RID_MIN_GPR, + RID_NUM_FPR = RID_MAX_FPR - RID_MIN_FPR, +}; + +/* -- Register sets ------------------------------------------------------- */ + +/* Make use of all registers, except the stack pointer (and maybe DISPATCH). */ +#define RSET_GPR (RSET_RANGE(RID_MIN_GPR, RID_MAX_GPR) \ + - RID2RSET(RID_ESP) \ + - LJ_GC64*RID2RSET(RID_DISPATCH)) +#define RSET_FPR (RSET_RANGE(RID_MIN_FPR, RID_MAX_FPR)) +#define RSET_ALL (RSET_GPR|RSET_FPR) +#define RSET_INIT RSET_ALL + +#if LJ_64 +/* Note: this requires the use of FORCE_REX! */ +#define RSET_GPR8 RSET_GPR +#else +#define RSET_GPR8 (RSET_RANGE(RID_EAX, RID_EBX+1)) +#endif + +/* ABI-specific register sets. */ +#define RSET_ACD (RID2RSET(RID_EAX)|RID2RSET(RID_ECX)|RID2RSET(RID_EDX)) +#if LJ_64 +#if LJ_ABI_WIN +/* Windows x64 ABI. */ +#define RSET_SCRATCH \ + (RSET_ACD|RSET_RANGE(RID_R8D, RID_R11D+1)|RSET_RANGE(RID_XMM0, RID_XMM5+1)) +#define REGARG_GPRS \ + (RID_ECX|((RID_EDX|((RID_R8D|(RID_R9D<<5))<<5))<<5)) +#define REGARG_NUMGPR 4 +#define REGARG_NUMFPR 4 +#define REGARG_FIRSTFPR RID_XMM0 +#define REGARG_LASTFPR RID_XMM3 +#define STACKARG_OFS (4*8) +#else +/* The rest of the civilized x64 world has a common ABI. */ +#define RSET_SCRATCH \ + (RSET_ACD|RSET_RANGE(RID_ESI, RID_R11D+1)|RSET_FPR) +#define REGARG_GPRS \ + (RID_EDI|((RID_ESI|((RID_EDX|((RID_ECX|((RID_R8D|(RID_R9D \ + <<5))<<5))<<5))<<5))<<5)) +#define REGARG_NUMGPR 6 +#define REGARG_NUMFPR 8 +#define REGARG_FIRSTFPR RID_XMM0 +#define REGARG_LASTFPR RID_XMM7 +#define STACKARG_OFS 0 +#endif +#else +/* Common x86 ABI. */ +#define RSET_SCRATCH (RSET_ACD|RSET_FPR) +#define REGARG_GPRS (RID_ECX|(RID_EDX<<5)) /* Fastcall only. */ +#define REGARG_NUMGPR 2 /* Fastcall only. */ +#define REGARG_NUMFPR 0 +#define STACKARG_OFS 0 +#endif + +#if LJ_64 +/* Prefer the low 8 regs of each type to reduce REX prefixes. */ +#undef rset_picktop +#define rset_picktop(rs) (lj_fls(lj_bswap(rs)) ^ 0x18) +#endif + +/* -- Spill slots --------------------------------------------------------- */ + +/* Spill slots are 32 bit wide. An even/odd pair is used for FPRs. +** +** SPS_FIXED: Available fixed spill slots in interpreter frame. +** This definition must match with the *.dasc file(s). +** +** SPS_FIRST: First spill slot for general use. Reserve min. two 32 bit slots. +*/ +#if LJ_64 +#if LJ_ABI_WIN +#define SPS_FIXED (4*2) +#define SPS_FIRST (4*2) /* Don't use callee register save area. */ +#else +#if LJ_GC64 +#define SPS_FIXED 2 +#else +#define SPS_FIXED 4 +#endif +#define SPS_FIRST 2 +#endif +#else +#define SPS_FIXED 6 +#define SPS_FIRST 2 +#endif + +#define SPOFS_TMP 0 + +#define sps_scale(slot) (4 * (int32_t)(slot)) +#define sps_align(slot) (((slot) - SPS_FIXED + 3) & ~3) + +/* -- Exit state ---------------------------------------------------------- */ + +/* This definition must match with the *.dasc file(s). */ +typedef struct { + lua_Number fpr[RID_NUM_FPR]; /* Floating-point registers. */ + intptr_t gpr[RID_NUM_GPR]; /* General-purpose registers. */ + int32_t spill[256]; /* Spill slots. */ +} ExitState; + +/* Limited by the range of a short fwd jump (127): (2+2)*(32-1)-2 = 122. */ +#define EXITSTUB_SPACING (2+2) +#define EXITSTUBS_PER_GROUP 32 + +#define EXITTRACE_VMSTATE 1 /* g->vmstate has traceno on exit. */ + +/* -- x86 ModRM operand encoding ------------------------------------------ */ + +typedef enum { + XM_OFS0 = 0x00, XM_OFS8 = 0x40, XM_OFS32 = 0x80, XM_REG = 0xc0, + XM_SCALE1 = 0x00, XM_SCALE2 = 0x40, XM_SCALE4 = 0x80, XM_SCALE8 = 0xc0, + XM_MASK = 0xc0 +} x86Mode; + +/* Structure to hold variable ModRM operand. */ +typedef struct { + int32_t ofs; /* Offset. */ + uint8_t base; /* Base register or RID_NONE. */ + uint8_t idx; /* Index register or RID_NONE. */ + uint8_t scale; /* Index scale (XM_SCALE1 .. XM_SCALE8). */ +} x86ModRM; + +/* -- Opcodes ------------------------------------------------------------- */ + +/* Macros to construct variable-length x86 opcodes. -(len+1) is in LSB. */ +#define XO_(o) ((uint32_t)(0x0000fe + (0x##o<<24))) +#define XO_FPU(a,b) ((uint32_t)(0x00fd + (0x##a<<16)+(0x##b<<24))) +#define XO_0f(o) ((uint32_t)(0x0f00fd + (0x##o<<24))) +#define XO_66(o) ((uint32_t)(0x6600fd + (0x##o<<24))) +#define XO_660f(o) ((uint32_t)(0x0f66fc + (0x##o<<24))) +#define XO_f20f(o) ((uint32_t)(0x0ff2fc + (0x##o<<24))) +#define XO_f30f(o) ((uint32_t)(0x0ff3fc + (0x##o<<24))) + +#define XV_660f38(o) ((uint32_t)(0x79e2c4 + (0x##o<<24))) +#define XV_f20f38(o) ((uint32_t)(0x7be2c4 + (0x##o<<24))) +#define XV_f20f3a(o) ((uint32_t)(0x7be3c4 + (0x##o<<24))) +#define XV_f30f38(o) ((uint32_t)(0x7ae2c4 + (0x##o<<24))) + +/* This list of x86 opcodes is not intended to be complete. Opcodes are only +** included when needed. Take a look at DynASM or jit.dis_x86 to see the +** whole mess. +*/ +typedef enum { + /* Fixed length opcodes. XI_* prefix. */ + XI_O16 = 0x66, + XI_NOP = 0x90, + XI_XCHGa = 0x90, + XI_CALL = 0xe8, + XI_JMP = 0xe9, + XI_JMPs = 0xeb, + XI_PUSH = 0x50, /* Really 50+r. */ + XI_JCCs = 0x70, /* Really 7x. */ + XI_JCCn = 0x80, /* Really 0f8x. */ + XI_LEA = 0x8d, + XI_MOVrib = 0xb0, /* Really b0+r. */ + XI_MOVri = 0xb8, /* Really b8+r. */ + XI_ARITHib = 0x80, + XI_ARITHi = 0x81, + XI_ARITHi8 = 0x83, + XI_PUSHi8 = 0x6a, + XI_TESTb = 0x84, + XI_TEST = 0x85, + XI_INT3 = 0xcc, + XI_MOVmi = 0xc7, + XI_GROUP5 = 0xff, + + /* Note: little-endian byte-order! */ + XI_FLDZ = 0xeed9, + XI_FLD1 = 0xe8d9, + XI_FDUP = 0xc0d9, /* Really fld st0. */ + XI_FPOP = 0xd8dd, /* Really fstp st0. */ + XI_FPOP1 = 0xd9dd, /* Really fstp st1. */ + XI_FRNDINT = 0xfcd9, + XI_FSCALE = 0xfdd9, + XI_FYL2X = 0xf1d9, + + /* VEX-encoded instructions. XV_* prefix. */ + XV_RORX = XV_f20f3a(f0), + XV_SARX = XV_f30f38(f7), + XV_SHLX = XV_660f38(f7), + XV_SHRX = XV_f20f38(f7), + + /* Variable-length opcodes. XO_* prefix. */ + XO_OR = XO_(0b), + XO_MOV = XO_(8b), + XO_MOVto = XO_(89), + XO_MOVtow = XO_66(89), + XO_MOVtob = XO_(88), + XO_MOVmi = XO_(c7), + XO_MOVmib = XO_(c6), + XO_LEA = XO_(8d), + XO_ARITHib = XO_(80), + XO_ARITHi = XO_(81), + XO_ARITHi8 = XO_(83), + XO_ARITHiw8 = XO_66(83), + XO_SHIFTi = XO_(c1), + XO_SHIFT1 = XO_(d1), + XO_SHIFTcl = XO_(d3), + XO_IMUL = XO_0f(af), + XO_IMULi = XO_(69), + XO_IMULi8 = XO_(6b), + XO_CMP = XO_(3b), + XO_TESTb = XO_(84), + XO_TEST = XO_(85), + XO_GROUP3b = XO_(f6), + XO_GROUP3 = XO_(f7), + XO_GROUP5b = XO_(fe), + XO_GROUP5 = XO_(ff), + XO_MOVZXb = XO_0f(b6), + XO_MOVZXw = XO_0f(b7), + XO_MOVSXb = XO_0f(be), + XO_MOVSXw = XO_0f(bf), + XO_MOVSXd = XO_(63), + XO_BSWAP = XO_0f(c8), + XO_CMOV = XO_0f(40), + + XO_MOVSD = XO_f20f(10), + XO_MOVSDto = XO_f20f(11), + XO_MOVSS = XO_f30f(10), + XO_MOVSSto = XO_f30f(11), + XO_MOVLPD = XO_660f(12), + XO_MOVAPS = XO_0f(28), + XO_XORPS = XO_0f(57), + XO_ANDPS = XO_0f(54), + XO_ADDSD = XO_f20f(58), + XO_SUBSD = XO_f20f(5c), + XO_MULSD = XO_f20f(59), + XO_DIVSD = XO_f20f(5e), + XO_SQRTSD = XO_f20f(51), + XO_MINSD = XO_f20f(5d), + XO_MAXSD = XO_f20f(5f), + XO_ROUNDSD = 0x0b3a0ffc, /* Really 66 0f 3a 0b. See asm_fpmath. */ + XO_UCOMISD = XO_660f(2e), + XO_CVTSI2SD = XO_f20f(2a), + XO_CVTTSD2SI= XO_f20f(2c), + XO_CVTSI2SS = XO_f30f(2a), + XO_CVTTSS2SI= XO_f30f(2c), + XO_CVTSS2SD = XO_f30f(5a), + XO_CVTSD2SS = XO_f20f(5a), + XO_ADDSS = XO_f30f(58), + XO_MOVD = XO_660f(6e), + XO_MOVDto = XO_660f(7e), + + XO_FLDd = XO_(d9), XOg_FLDd = 0, + XO_FLDq = XO_(dd), XOg_FLDq = 0, + XO_FILDd = XO_(db), XOg_FILDd = 0, + XO_FILDq = XO_(df), XOg_FILDq = 5, + XO_FSTPd = XO_(d9), XOg_FSTPd = 3, + XO_FSTPq = XO_(dd), XOg_FSTPq = 3, + XO_FISTPq = XO_(df), XOg_FISTPq = 7, + XO_FISTTPq = XO_(dd), XOg_FISTTPq = 1, + XO_FADDq = XO_(dc), XOg_FADDq = 0, + XO_FLDCW = XO_(d9), XOg_FLDCW = 5, + XO_FNSTCW = XO_(d9), XOg_FNSTCW = 7 +} x86Op; + +/* x86 opcode groups. */ +typedef uint32_t x86Group; + +#define XG_(i8, i, g) ((x86Group)(((i8) << 16) + ((i) << 8) + (g))) +#define XG_ARITHi(g) XG_(XI_ARITHi8, XI_ARITHi, g) +#define XG_TOXOi(xg) ((x86Op)(0x000000fe + (((xg)<<16) & 0xff000000))) +#define XG_TOXOi8(xg) ((x86Op)(0x000000fe + (((xg)<<8) & 0xff000000))) + +#define XO_ARITH(a) ((x86Op)(0x030000fe + ((a)<<27))) +#define XO_ARITHw(a) ((x86Op)(0x036600fd + ((a)<<27))) + +typedef enum { + XOg_ADD, XOg_OR, XOg_ADC, XOg_SBB, XOg_AND, XOg_SUB, XOg_XOR, XOg_CMP, + XOg_X_IMUL +} x86Arith; + +typedef enum { + XOg_ROL, XOg_ROR, XOg_RCL, XOg_RCR, XOg_SHL, XOg_SHR, XOg_SAL, XOg_SAR +} x86Shift; + +typedef enum { + XOg_TEST, XOg_TEST_, XOg_NOT, XOg_NEG, XOg_MUL, XOg_IMUL, XOg_DIV, XOg_IDIV +} x86Group3; + +typedef enum { + XOg_INC, XOg_DEC, XOg_CALL, XOg_CALLfar, XOg_JMP, XOg_JMPfar, XOg_PUSH +} x86Group5; + +/* x86 condition codes. */ +typedef enum { + CC_O, CC_NO, CC_B, CC_NB, CC_E, CC_NE, CC_BE, CC_NBE, + CC_S, CC_NS, CC_P, CC_NP, CC_L, CC_NL, CC_LE, CC_NLE, + CC_C = CC_B, CC_NAE = CC_C, CC_NC = CC_NB, CC_AE = CC_NB, + CC_Z = CC_E, CC_NZ = CC_NE, CC_NA = CC_BE, CC_A = CC_NBE, + CC_PE = CC_P, CC_PO = CC_NP, CC_NGE = CC_L, CC_GE = CC_NL, + CC_NG = CC_LE, CC_G = CC_NLE +} x86CC; + +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_trace.c b/fluent-bit/lib/luajit-3065c9/src/lj_trace.c new file mode 100644 index 00000000..c2329394 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_trace.c @@ -0,0 +1,987 @@ +/* +** Trace management. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#define lj_trace_c +#define LUA_CORE + +#include "lj_obj.h" + +#if LJ_HASJIT + +#include "lj_gc.h" +#include "lj_err.h" +#include "lj_debug.h" +#include "lj_str.h" +#include "lj_frame.h" +#include "lj_state.h" +#include "lj_bc.h" +#include "lj_ir.h" +#include "lj_jit.h" +#include "lj_iropt.h" +#include "lj_mcode.h" +#include "lj_trace.h" +#include "lj_snap.h" +#include "lj_gdbjit.h" +#include "lj_record.h" +#include "lj_asm.h" +#include "lj_dispatch.h" +#include "lj_vm.h" +#include "lj_vmevent.h" +#include "lj_target.h" +#include "lj_prng.h" + +/* -- Error handling ------------------------------------------------------ */ + +/* Synchronous abort with error message. */ +void lj_trace_err(jit_State *J, TraceError e) +{ + setnilV(&J->errinfo); /* No error info. */ + setintV(J->L->top++, (int32_t)e); + lj_err_throw(J->L, LUA_ERRRUN); +} + +/* Synchronous abort with error message and error info. */ +void lj_trace_err_info(jit_State *J, TraceError e) +{ + setintV(J->L->top++, (int32_t)e); + lj_err_throw(J->L, LUA_ERRRUN); +} + +/* -- Trace management ---------------------------------------------------- */ + +/* The current trace is first assembled in J->cur. The variable length +** arrays point to shared, growable buffers (J->irbuf etc.). When trace +** recording ends successfully, the current trace and its data structures +** are copied to a new (compact) GCtrace object. +*/ + +/* Find a free trace number. */ +static TraceNo trace_findfree(jit_State *J) +{ + MSize osz, lim; + if (J->freetrace == 0) + J->freetrace = 1; + for (; J->freetrace < J->sizetrace; J->freetrace++) + if (traceref(J, J->freetrace) == NULL) + return J->freetrace++; + /* Need to grow trace array. */ + lim = (MSize)J->param[JIT_P_maxtrace] + 1; + if (lim < 2) lim = 2; else if (lim > 65535) lim = 65535; + osz = J->sizetrace; + if (osz >= lim) + return 0; /* Too many traces. */ + lj_mem_growvec(J->L, J->trace, J->sizetrace, lim, GCRef); + for (; osz < J->sizetrace; osz++) + setgcrefnull(J->trace[osz]); + return J->freetrace; +} + +#define TRACE_APPENDVEC(field, szfield, tp) \ + T->field = (tp *)p; \ + memcpy(p, J->cur.field, J->cur.szfield*sizeof(tp)); \ + p += J->cur.szfield*sizeof(tp); + +#ifdef LUAJIT_USE_PERFTOOLS +/* +** Create symbol table of JIT-compiled code. For use with Linux perf tools. +** Example usage: +** perf record -f -e cycles luajit test.lua +** perf report -s symbol +** rm perf.data /tmp/perf-*.map +*/ +#include +#include + +static void perftools_addtrace(GCtrace *T) +{ + static FILE *fp; + GCproto *pt = &gcref(T->startpt)->pt; + const BCIns *startpc = mref(T->startpc, const BCIns); + const char *name = proto_chunknamestr(pt); + BCLine lineno; + if (name[0] == '@' || name[0] == '=') + name++; + else + name = "(string)"; + lj_assertX(startpc >= proto_bc(pt) && startpc < proto_bc(pt) + pt->sizebc, + "trace PC out of range"); + lineno = lj_debug_line(pt, proto_bcpos(pt, startpc)); + if (!fp) { + char fname[40]; + sprintf(fname, "/tmp/perf-%d.map", getpid()); + if (!(fp = fopen(fname, "w"))) return; + setlinebuf(fp); + } + fprintf(fp, "%lx %x TRACE_%d::%s:%u\n", + (long)T->mcode, T->szmcode, T->traceno, name, lineno); +} +#endif + +/* Allocate space for copy of T. */ +GCtrace * LJ_FASTCALL lj_trace_alloc(lua_State *L, GCtrace *T) +{ + size_t sztr = ((sizeof(GCtrace)+7)&~7); + size_t szins = (T->nins-T->nk)*sizeof(IRIns); + size_t sz = sztr + szins + + T->nsnap*sizeof(SnapShot) + + T->nsnapmap*sizeof(SnapEntry); + GCtrace *T2 = lj_mem_newt(L, (MSize)sz, GCtrace); + char *p = (char *)T2 + sztr; + T2->gct = ~LJ_TTRACE; + T2->marked = 0; + T2->traceno = 0; + T2->ir = (IRIns *)p - T->nk; + T2->nins = T->nins; + T2->nk = T->nk; + T2->nsnap = T->nsnap; + T2->nsnapmap = T->nsnapmap; + memcpy(p, T->ir + T->nk, szins); + return T2; +} + +/* Save current trace by copying and compacting it. */ +static void trace_save(jit_State *J, GCtrace *T) +{ + size_t sztr = ((sizeof(GCtrace)+7)&~7); + size_t szins = (J->cur.nins-J->cur.nk)*sizeof(IRIns); + char *p = (char *)T + sztr; + memcpy(T, &J->cur, sizeof(GCtrace)); + setgcrefr(T->nextgc, J2G(J)->gc.root); + setgcrefp(J2G(J)->gc.root, T); + newwhite(J2G(J), T); + T->gct = ~LJ_TTRACE; + T->ir = (IRIns *)p - J->cur.nk; /* The IR has already been copied above. */ + p += szins; + TRACE_APPENDVEC(snap, nsnap, SnapShot) + TRACE_APPENDVEC(snapmap, nsnapmap, SnapEntry) + J->cur.traceno = 0; + J->curfinal = NULL; + setgcrefp(J->trace[T->traceno], T); + lj_gc_barriertrace(J2G(J), T->traceno); + lj_gdbjit_addtrace(J, T); +#ifdef LUAJIT_USE_PERFTOOLS + perftools_addtrace(T); +#endif +} + +void LJ_FASTCALL lj_trace_free(global_State *g, GCtrace *T) +{ + jit_State *J = G2J(g); + if (T->traceno) { + lj_gdbjit_deltrace(J, T); + if (T->traceno < J->freetrace) + J->freetrace = T->traceno; + setgcrefnull(J->trace[T->traceno]); + } + lj_mem_free(g, T, + ((sizeof(GCtrace)+7)&~7) + (T->nins-T->nk)*sizeof(IRIns) + + T->nsnap*sizeof(SnapShot) + T->nsnapmap*sizeof(SnapEntry)); +} + +/* Re-enable compiling a prototype by unpatching any modified bytecode. */ +void lj_trace_reenableproto(GCproto *pt) +{ + if ((pt->flags & PROTO_ILOOP)) { + BCIns *bc = proto_bc(pt); + BCPos i, sizebc = pt->sizebc; + pt->flags &= ~PROTO_ILOOP; + if (bc_op(bc[0]) == BC_IFUNCF) + setbc_op(&bc[0], BC_FUNCF); + for (i = 1; i < sizebc; i++) { + BCOp op = bc_op(bc[i]); + if (op == BC_IFORL || op == BC_IITERL || op == BC_ILOOP) + setbc_op(&bc[i], (int)op+(int)BC_LOOP-(int)BC_ILOOP); + } + } +} + +/* Unpatch the bytecode modified by a root trace. */ +static void trace_unpatch(jit_State *J, GCtrace *T) +{ + BCOp op = bc_op(T->startins); + BCIns *pc = mref(T->startpc, BCIns); + UNUSED(J); + if (op == BC_JMP) + return; /* No need to unpatch branches in parent traces (yet). */ + switch (bc_op(*pc)) { + case BC_JFORL: + lj_assertJ(traceref(J, bc_d(*pc)) == T, "JFORL references other trace"); + *pc = T->startins; + pc += bc_j(T->startins); + lj_assertJ(bc_op(*pc) == BC_JFORI, "FORL does not point to JFORI"); + setbc_op(pc, BC_FORI); + break; + case BC_JITERL: + case BC_JLOOP: + lj_assertJ(op == BC_ITERL || op == BC_ITERN || op == BC_LOOP || + bc_isret(op), "bad original bytecode %d", op); + *pc = T->startins; + break; + case BC_JMP: + lj_assertJ(op == BC_ITERL, "bad original bytecode %d", op); + pc += bc_j(*pc)+2; + if (bc_op(*pc) == BC_JITERL) { + lj_assertJ(traceref(J, bc_d(*pc)) == T, "JITERL references other trace"); + *pc = T->startins; + } + break; + case BC_JFUNCF: + lj_assertJ(op == BC_FUNCF, "bad original bytecode %d", op); + *pc = T->startins; + break; + default: /* Already unpatched. */ + break; + } +} + +/* Flush a root trace. */ +static void trace_flushroot(jit_State *J, GCtrace *T) +{ + GCproto *pt = &gcref(T->startpt)->pt; + lj_assertJ(T->root == 0, "not a root trace"); + lj_assertJ(pt != NULL, "trace has no prototype"); + /* First unpatch any modified bytecode. */ + trace_unpatch(J, T); + /* Unlink root trace from chain anchored in prototype. */ + if (pt->trace == T->traceno) { /* Trace is first in chain. Easy. */ + pt->trace = T->nextroot; + } else if (pt->trace) { /* Otherwise search in chain of root traces. */ + GCtrace *T2 = traceref(J, pt->trace); + if (T2) { + for (; T2->nextroot; T2 = traceref(J, T2->nextroot)) + if (T2->nextroot == T->traceno) { + T2->nextroot = T->nextroot; /* Unlink from chain. */ + break; + } + } + } +} + +/* Flush a trace. Only root traces are considered. */ +void lj_trace_flush(jit_State *J, TraceNo traceno) +{ + if (traceno > 0 && traceno < J->sizetrace) { + GCtrace *T = traceref(J, traceno); + if (T && T->root == 0) + trace_flushroot(J, T); + } +} + +/* Flush all traces associated with a prototype. */ +void lj_trace_flushproto(global_State *g, GCproto *pt) +{ + while (pt->trace != 0) + trace_flushroot(G2J(g), traceref(G2J(g), pt->trace)); +} + +/* Flush all traces. */ +int lj_trace_flushall(lua_State *L) +{ + jit_State *J = L2J(L); + ptrdiff_t i; + if ((J2G(J)->hookmask & HOOK_GC)) + return 1; + for (i = (ptrdiff_t)J->sizetrace-1; i > 0; i--) { + GCtrace *T = traceref(J, i); + if (T) { + if (T->root == 0) + trace_flushroot(J, T); + lj_gdbjit_deltrace(J, T); + T->traceno = T->link = 0; /* Blacklist the link for cont_stitch. */ + setgcrefnull(J->trace[i]); + } + } + J->cur.traceno = 0; + J->freetrace = 0; + /* Clear penalty cache. */ + memset(J->penalty, 0, sizeof(J->penalty)); + /* Free the whole machine code and invalidate all exit stub groups. */ + lj_mcode_free(J); + memset(J->exitstubgroup, 0, sizeof(J->exitstubgroup)); + lj_vmevent_send(L, TRACE, + setstrV(L, L->top++, lj_str_newlit(L, "flush")); + ); + return 0; +} + +/* Initialize JIT compiler state. */ +void lj_trace_initstate(global_State *g) +{ + jit_State *J = G2J(g); + TValue *tv; + + /* Initialize aligned SIMD constants. */ + tv = LJ_KSIMD(J, LJ_KSIMD_ABS); + tv[0].u64 = U64x(7fffffff,ffffffff); + tv[1].u64 = U64x(7fffffff,ffffffff); + tv = LJ_KSIMD(J, LJ_KSIMD_NEG); + tv[0].u64 = U64x(80000000,00000000); + tv[1].u64 = U64x(80000000,00000000); + + /* Initialize 32/64 bit constants. */ +#if LJ_TARGET_X86ORX64 + J->k64[LJ_K64_TOBIT].u64 = U64x(43380000,00000000); +#if LJ_32 + J->k64[LJ_K64_M2P64_31].u64 = U64x(c1e00000,00000000); +#endif + J->k64[LJ_K64_2P64].u64 = U64x(43f00000,00000000); + J->k32[LJ_K32_M2P64_31] = LJ_64 ? 0xdf800000 : 0xcf000000; +#endif +#if LJ_TARGET_X86ORX64 || LJ_TARGET_MIPS64 + J->k64[LJ_K64_M2P64].u64 = U64x(c3f00000,00000000); +#endif +#if LJ_TARGET_PPC + J->k32[LJ_K32_2P52_2P31] = 0x59800004; + J->k32[LJ_K32_2P52] = 0x59800000; +#endif +#if LJ_TARGET_PPC || LJ_TARGET_MIPS + J->k32[LJ_K32_2P31] = 0x4f000000; +#endif +#if LJ_TARGET_MIPS + J->k64[LJ_K64_2P31].u64 = U64x(41e00000,00000000); +#if LJ_64 + J->k64[LJ_K64_2P63].u64 = U64x(43e00000,00000000); + J->k32[LJ_K32_2P63] = 0x5f000000; + J->k32[LJ_K32_M2P64] = 0xdf800000; +#endif +#endif +} + +/* Free everything associated with the JIT compiler state. */ +void lj_trace_freestate(global_State *g) +{ + jit_State *J = G2J(g); +#ifdef LUA_USE_ASSERT + { /* This assumes all traces have already been freed. */ + ptrdiff_t i; + for (i = 1; i < (ptrdiff_t)J->sizetrace; i++) + lj_assertG(i == (ptrdiff_t)J->cur.traceno || traceref(J, i) == NULL, + "trace still allocated"); + } +#endif + lj_mcode_free(J); + lj_mem_freevec(g, J->snapmapbuf, J->sizesnapmap, SnapEntry); + lj_mem_freevec(g, J->snapbuf, J->sizesnap, SnapShot); + lj_mem_freevec(g, J->irbuf + J->irbotlim, J->irtoplim - J->irbotlim, IRIns); + lj_mem_freevec(g, J->trace, J->sizetrace, GCRef); +} + +/* -- Penalties and blacklisting ------------------------------------------ */ + +/* Blacklist a bytecode instruction. */ +static void blacklist_pc(GCproto *pt, BCIns *pc) +{ + if (bc_op(*pc) == BC_ITERN) { + setbc_op(pc, BC_ITERC); + setbc_op(pc+1+bc_j(pc[1]), BC_JMP); + } else { + setbc_op(pc, (int)bc_op(*pc)+(int)BC_ILOOP-(int)BC_LOOP); + pt->flags |= PROTO_ILOOP; + } +} + +/* Penalize a bytecode instruction. */ +static void penalty_pc(jit_State *J, GCproto *pt, BCIns *pc, TraceError e) +{ + uint32_t i, val = PENALTY_MIN; + for (i = 0; i < PENALTY_SLOTS; i++) + if (mref(J->penalty[i].pc, const BCIns) == pc) { /* Cache slot found? */ + /* First try to bump its hotcount several times. */ + val = ((uint32_t)J->penalty[i].val << 1) + + (lj_prng_u64(&J2G(J)->prng) & ((1u< PENALTY_MAX) { + blacklist_pc(pt, pc); /* Blacklist it, if that didn't help. */ + return; + } + goto setpenalty; + } + /* Assign a new penalty cache slot. */ + i = J->penaltyslot; + J->penaltyslot = (J->penaltyslot + 1) & (PENALTY_SLOTS-1); + setmref(J->penalty[i].pc, pc); +setpenalty: + J->penalty[i].val = (uint16_t)val; + J->penalty[i].reason = e; + hotcount_set(J2GG(J), pc+1, val); +} + +/* -- Trace compiler state machine ---------------------------------------- */ + +/* Start tracing. */ +static void trace_start(jit_State *J) +{ + lua_State *L; + TraceNo traceno; + + if ((J->pt->flags & PROTO_NOJIT)) { /* JIT disabled for this proto? */ + if (J->parent == 0 && J->exitno == 0 && bc_op(*J->pc) != BC_ITERN) { + /* Lazy bytecode patching to disable hotcount events. */ + lj_assertJ(bc_op(*J->pc) == BC_FORL || bc_op(*J->pc) == BC_ITERL || + bc_op(*J->pc) == BC_LOOP || bc_op(*J->pc) == BC_FUNCF, + "bad hot bytecode %d", bc_op(*J->pc)); + setbc_op(J->pc, (int)bc_op(*J->pc)+(int)BC_ILOOP-(int)BC_LOOP); + J->pt->flags |= PROTO_ILOOP; + } + J->state = LJ_TRACE_IDLE; /* Silently ignored. */ + return; + } + + /* Get a new trace number. */ + traceno = trace_findfree(J); + if (LJ_UNLIKELY(traceno == 0)) { /* No free trace? */ + lj_assertJ((J2G(J)->hookmask & HOOK_GC) == 0, + "recorder called from GC hook"); + lj_trace_flushall(J->L); + J->state = LJ_TRACE_IDLE; /* Silently ignored. */ + return; + } + setgcrefp(J->trace[traceno], &J->cur); + + /* Setup enough of the current trace to be able to send the vmevent. */ + memset(&J->cur, 0, sizeof(GCtrace)); + J->cur.traceno = traceno; + J->cur.nins = J->cur.nk = REF_BASE; + J->cur.ir = J->irbuf; + J->cur.snap = J->snapbuf; + J->cur.snapmap = J->snapmapbuf; + J->mergesnap = 0; + J->needsnap = 0; + J->bcskip = 0; + J->guardemit.irt = 0; + J->postproc = LJ_POST_NONE; + lj_resetsplit(J); + J->retryrec = 0; + J->ktrace = 0; + setgcref(J->cur.startpt, obj2gco(J->pt)); + + L = J->L; + lj_vmevent_send(L, TRACE, + setstrV(L, L->top++, lj_str_newlit(L, "start")); + setintV(L->top++, traceno); + setfuncV(L, L->top++, J->fn); + setintV(L->top++, proto_bcpos(J->pt, J->pc)); + if (J->parent) { + setintV(L->top++, J->parent); + setintV(L->top++, J->exitno); + } else { + BCOp op = bc_op(*J->pc); + if (op == BC_CALLM || op == BC_CALL || op == BC_ITERC) { + setintV(L->top++, J->exitno); /* Parent of stitched trace. */ + setintV(L->top++, -1); + } + } + ); + lj_record_setup(J); +} + +/* Stop tracing. */ +static void trace_stop(jit_State *J) +{ + BCIns *pc = mref(J->cur.startpc, BCIns); + BCOp op = bc_op(J->cur.startins); + GCproto *pt = &gcref(J->cur.startpt)->pt; + TraceNo traceno = J->cur.traceno; + GCtrace *T = J->curfinal; + lua_State *L; + + switch (op) { + case BC_FORL: + setbc_op(pc+bc_j(J->cur.startins), BC_JFORI); /* Patch FORI, too. */ + /* fallthrough */ + case BC_LOOP: + case BC_ITERL: + case BC_FUNCF: + /* Patch bytecode of starting instruction in root trace. */ + setbc_op(pc, (int)op+(int)BC_JLOOP-(int)BC_LOOP); + setbc_d(pc, traceno); + addroot: + /* Add to root trace chain in prototype. */ + J->cur.nextroot = pt->trace; + pt->trace = (TraceNo1)traceno; + break; + case BC_ITERN: + case BC_RET: + case BC_RET0: + case BC_RET1: + *pc = BCINS_AD(BC_JLOOP, J->cur.snap[0].nslots, traceno); + goto addroot; + case BC_JMP: + /* Patch exit branch in parent to side trace entry. */ + lj_assertJ(J->parent != 0 && J->cur.root != 0, "not a side trace"); + lj_asm_patchexit(J, traceref(J, J->parent), J->exitno, J->cur.mcode); + /* Avoid compiling a side trace twice (stack resizing uses parent exit). */ + { + SnapShot *snap = &traceref(J, J->parent)->snap[J->exitno]; + snap->count = SNAPCOUNT_DONE; + if (J->cur.topslot > snap->topslot) snap->topslot = J->cur.topslot; + } + /* Add to side trace chain in root trace. */ + { + GCtrace *root = traceref(J, J->cur.root); + root->nchild++; + J->cur.nextside = root->nextside; + root->nextside = (TraceNo1)traceno; + } + break; + case BC_CALLM: + case BC_CALL: + case BC_ITERC: + /* Trace stitching: patch link of previous trace. */ + traceref(J, J->exitno)->link = traceno; + break; + default: + lj_assertJ(0, "bad stop bytecode %d", op); + break; + } + + /* Commit new mcode only after all patching is done. */ + lj_mcode_commit(J, J->cur.mcode); + J->postproc = LJ_POST_NONE; + trace_save(J, T); + + L = J->L; + lj_vmevent_send(L, TRACE, + setstrV(L, L->top++, lj_str_newlit(L, "stop")); + setintV(L->top++, traceno); + setfuncV(L, L->top++, J->fn); + ); +} + +/* Start a new root trace for down-recursion. */ +static int trace_downrec(jit_State *J) +{ + /* Restart recording at the return instruction. */ + lj_assertJ(J->pt != NULL, "no active prototype"); + lj_assertJ(bc_isret(bc_op(*J->pc)), "not at a return bytecode"); + if (bc_op(*J->pc) == BC_RETM) + return 0; /* NYI: down-recursion with RETM. */ + J->parent = 0; + J->exitno = 0; + J->state = LJ_TRACE_RECORD; + trace_start(J); + return 1; +} + +/* Abort tracing. */ +static int trace_abort(jit_State *J) +{ + lua_State *L = J->L; + TraceError e = LJ_TRERR_RECERR; + TraceNo traceno; + + J->postproc = LJ_POST_NONE; + lj_mcode_abort(J); + if (J->curfinal) { + lj_trace_free(J2G(J), J->curfinal); + J->curfinal = NULL; + } + if (tvisnumber(L->top-1)) + e = (TraceError)numberVint(L->top-1); + if (e == LJ_TRERR_MCODELM) { + L->top--; /* Remove error object */ + J->state = LJ_TRACE_ASM; + return 1; /* Retry ASM with new MCode area. */ + } + /* Penalize or blacklist starting bytecode instruction. */ + if (J->parent == 0 && !bc_isret(bc_op(J->cur.startins))) { + if (J->exitno == 0) { + BCIns *startpc = mref(J->cur.startpc, BCIns); + if (e == LJ_TRERR_RETRY) + hotcount_set(J2GG(J), startpc+1, 1); /* Immediate retry. */ + else + penalty_pc(J, &gcref(J->cur.startpt)->pt, startpc, e); + } else { + traceref(J, J->exitno)->link = J->exitno; /* Self-link is blacklisted. */ + } + } + + /* Is there anything to abort? */ + traceno = J->cur.traceno; + if (traceno) { + ptrdiff_t errobj = savestack(L, L->top-1); /* Stack may be resized. */ + J->cur.link = 0; + J->cur.linktype = LJ_TRLINK_NONE; + lj_vmevent_send(L, TRACE, + TValue *frame; + const BCIns *pc; + GCfunc *fn; + setstrV(L, L->top++, lj_str_newlit(L, "abort")); + setintV(L->top++, traceno); + /* Find original Lua function call to generate a better error message. */ + frame = J->L->base-1; + pc = J->pc; + while (!isluafunc(frame_func(frame))) { + pc = (frame_iscont(frame) ? frame_contpc(frame) : frame_pc(frame)) - 1; + frame = frame_prev(frame); + } + fn = frame_func(frame); + setfuncV(L, L->top++, fn); + setintV(L->top++, proto_bcpos(funcproto(fn), pc)); + copyTV(L, L->top++, restorestack(L, errobj)); + copyTV(L, L->top++, &J->errinfo); + ); + /* Drop aborted trace after the vmevent (which may still access it). */ + setgcrefnull(J->trace[traceno]); + if (traceno < J->freetrace) + J->freetrace = traceno; + J->cur.traceno = 0; + } + L->top--; /* Remove error object */ + if (e == LJ_TRERR_DOWNREC) + return trace_downrec(J); + else if (e == LJ_TRERR_MCODEAL) + lj_trace_flushall(L); + return 0; +} + +/* Perform pending re-patch of a bytecode instruction. */ +static LJ_AINLINE void trace_pendpatch(jit_State *J, int force) +{ + if (LJ_UNLIKELY(J->patchpc)) { + if (force || J->bcskip == 0) { + *J->patchpc = J->patchins; + J->patchpc = NULL; + } else { + J->bcskip = 0; + } + } +} + +/* State machine for the trace compiler. Protected callback. */ +static TValue *trace_state(lua_State *L, lua_CFunction dummy, void *ud) +{ + jit_State *J = (jit_State *)ud; + UNUSED(dummy); + do { + retry: + switch (J->state) { + case LJ_TRACE_START: + J->state = LJ_TRACE_RECORD; /* trace_start() may change state. */ + trace_start(J); + lj_dispatch_update(J2G(J)); + if (J->state != LJ_TRACE_RECORD_1ST) + break; + /* fallthrough */ + + case LJ_TRACE_RECORD_1ST: + J->state = LJ_TRACE_RECORD; + /* fallthrough */ + case LJ_TRACE_RECORD: + trace_pendpatch(J, 0); + setvmstate(J2G(J), RECORD); + lj_vmevent_send_(L, RECORD, + /* Save/restore state for trace recorder. */ + TValue savetv = J2G(J)->tmptv; + TValue savetv2 = J2G(J)->tmptv2; + TraceNo parent = J->parent; + ExitNo exitno = J->exitno; + setintV(L->top++, J->cur.traceno); + setfuncV(L, L->top++, J->fn); + setintV(L->top++, J->pt ? (int32_t)proto_bcpos(J->pt, J->pc) : -1); + setintV(L->top++, J->framedepth); + , + J2G(J)->tmptv = savetv; + J2G(J)->tmptv2 = savetv2; + J->parent = parent; + J->exitno = exitno; + ); + lj_record_ins(J); + break; + + case LJ_TRACE_END: + trace_pendpatch(J, 1); + J->loopref = 0; + if ((J->flags & JIT_F_OPT_LOOP) && + J->cur.link == J->cur.traceno && J->framedepth + J->retdepth == 0) { + setvmstate(J2G(J), OPT); + lj_opt_dce(J); + if (lj_opt_loop(J)) { /* Loop optimization failed? */ + J->cur.link = 0; + J->cur.linktype = LJ_TRLINK_NONE; + J->loopref = J->cur.nins; + J->state = LJ_TRACE_RECORD; /* Try to continue recording. */ + break; + } + J->loopref = J->chain[IR_LOOP]; /* Needed by assembler. */ + } + lj_opt_split(J); + lj_opt_sink(J); + if (!J->loopref) J->cur.snap[J->cur.nsnap-1].count = SNAPCOUNT_DONE; + J->state = LJ_TRACE_ASM; + break; + + case LJ_TRACE_ASM: + setvmstate(J2G(J), ASM); + lj_asm_trace(J, &J->cur); + trace_stop(J); + setvmstate(J2G(J), INTERP); + J->state = LJ_TRACE_IDLE; + lj_dispatch_update(J2G(J)); + return NULL; + + default: /* Trace aborted asynchronously. */ + setintV(L->top++, (int32_t)LJ_TRERR_RECERR); + /* fallthrough */ + case LJ_TRACE_ERR: + trace_pendpatch(J, 1); + if (trace_abort(J)) + goto retry; + setvmstate(J2G(J), INTERP); + J->state = LJ_TRACE_IDLE; + lj_dispatch_update(J2G(J)); + return NULL; + } + } while (J->state > LJ_TRACE_RECORD); + return NULL; +} + +/* -- Event handling ------------------------------------------------------ */ + +/* A bytecode instruction is about to be executed. Record it. */ +void lj_trace_ins(jit_State *J, const BCIns *pc) +{ + /* Note: J->L must already be set. pc is the true bytecode PC here. */ + J->pc = pc; + J->fn = curr_func(J->L); + J->pt = isluafunc(J->fn) ? funcproto(J->fn) : NULL; + while (lj_vm_cpcall(J->L, NULL, (void *)J, trace_state) != 0) + J->state = LJ_TRACE_ERR; +} + +/* A hotcount triggered. Start recording a root trace. */ +void LJ_FASTCALL lj_trace_hot(jit_State *J, const BCIns *pc) +{ + /* Note: pc is the interpreter bytecode PC here. It's offset by 1. */ + ERRNO_SAVE + /* Reset hotcount. */ + hotcount_set(J2GG(J), pc, J->param[JIT_P_hotloop]*HOTCOUNT_LOOP); + /* Only start a new trace if not recording or inside __gc call or vmevent. */ + if (J->state == LJ_TRACE_IDLE && + !(J2G(J)->hookmask & (HOOK_GC|HOOK_VMEVENT))) { + J->parent = 0; /* Root trace. */ + J->exitno = 0; + J->state = LJ_TRACE_START; + lj_trace_ins(J, pc-1); + } + ERRNO_RESTORE +} + +/* Check for a hot side exit. If yes, start recording a side trace. */ +static void trace_hotside(jit_State *J, const BCIns *pc) +{ + SnapShot *snap = &traceref(J, J->parent)->snap[J->exitno]; + if (!(J2G(J)->hookmask & (HOOK_GC|HOOK_VMEVENT)) && + isluafunc(curr_func(J->L)) && + snap->count != SNAPCOUNT_DONE && + ++snap->count >= J->param[JIT_P_hotexit]) { + lj_assertJ(J->state == LJ_TRACE_IDLE, "hot side exit while recording"); + /* J->parent is non-zero for a side trace. */ + J->state = LJ_TRACE_START; + lj_trace_ins(J, pc); + } +} + +/* Stitch a new trace to the previous trace. */ +void LJ_FASTCALL lj_trace_stitch(jit_State *J, const BCIns *pc) +{ + /* Only start a new trace if not recording or inside __gc call or vmevent. */ + if (J->state == LJ_TRACE_IDLE && + !(J2G(J)->hookmask & (HOOK_GC|HOOK_VMEVENT))) { + J->parent = 0; /* Have to treat it like a root trace. */ + /* J->exitno is set to the invoking trace. */ + J->state = LJ_TRACE_START; + lj_trace_ins(J, pc); + } +} + + +/* Tiny struct to pass data to protected call. */ +typedef struct ExitDataCP { + jit_State *J; + void *exptr; /* Pointer to exit state. */ + const BCIns *pc; /* Restart interpreter at this PC. */ +} ExitDataCP; + +/* Need to protect lj_snap_restore because it may throw. */ +static TValue *trace_exit_cp(lua_State *L, lua_CFunction dummy, void *ud) +{ + ExitDataCP *exd = (ExitDataCP *)ud; + /* Always catch error here and don't call error function. */ + cframe_errfunc(L->cframe) = 0; + cframe_nres(L->cframe) = -2*LUAI_MAXSTACK*(int)sizeof(TValue); + exd->pc = lj_snap_restore(exd->J, exd->exptr); + UNUSED(dummy); + return NULL; +} + +#ifndef LUAJIT_DISABLE_VMEVENT +/* Push all registers from exit state. */ +static void trace_exit_regs(lua_State *L, ExitState *ex) +{ + int32_t i; + setintV(L->top++, RID_NUM_GPR); + setintV(L->top++, RID_NUM_FPR); + for (i = 0; i < RID_NUM_GPR; i++) { + if (sizeof(ex->gpr[i]) == sizeof(int32_t)) + setintV(L->top++, (int32_t)ex->gpr[i]); + else + setnumV(L->top++, (lua_Number)ex->gpr[i]); + } +#if !LJ_SOFTFP + for (i = 0; i < RID_NUM_FPR; i++) { + setnumV(L->top, ex->fpr[i]); + if (LJ_UNLIKELY(tvisnan(L->top))) + setnanV(L->top); + L->top++; + } +#endif +} +#endif + +#if defined(EXITSTATE_PCREG) || (LJ_UNWIND_JIT && !EXITTRACE_VMSTATE) +/* Determine trace number from pc of exit instruction. */ +static TraceNo trace_exit_find(jit_State *J, MCode *pc) +{ + TraceNo traceno; + for (traceno = 1; traceno < J->sizetrace; traceno++) { + GCtrace *T = traceref(J, traceno); + if (T && pc >= T->mcode && pc < (MCode *)((char *)T->mcode + T->szmcode)) + return traceno; + } + lj_assertJ(0, "bad exit pc"); + return 0; +} +#endif + +/* A trace exited. Restore interpreter state. */ +int LJ_FASTCALL lj_trace_exit(jit_State *J, void *exptr) +{ + ERRNO_SAVE + lua_State *L = J->L; + ExitState *ex = (ExitState *)exptr; + ExitDataCP exd; + int errcode, exitcode = J->exitcode; + TValue exiterr; + const BCIns *pc; + void *cf; + GCtrace *T; + + setnilV(&exiterr); + if (exitcode) { /* Trace unwound with error code. */ + J->exitcode = 0; + copyTV(L, &exiterr, L->top-1); + } + +#ifdef EXITSTATE_PCREG + J->parent = trace_exit_find(J, (MCode *)(intptr_t)ex->gpr[EXITSTATE_PCREG]); +#endif + T = traceref(J, J->parent); UNUSED(T); +#ifdef EXITSTATE_CHECKEXIT + if (J->exitno == T->nsnap) { /* Treat stack check like a parent exit. */ + lj_assertJ(T->root != 0, "stack check in root trace"); + J->exitno = T->ir[REF_BASE].op2; + J->parent = T->ir[REF_BASE].op1; + T = traceref(J, J->parent); + } +#endif + lj_assertJ(T != NULL && J->exitno < T->nsnap, "bad trace or exit number"); + exd.J = J; + exd.exptr = exptr; + errcode = lj_vm_cpcall(L, NULL, &exd, trace_exit_cp); + if (errcode) + return -errcode; /* Return negated error code. */ + + if (exitcode) copyTV(L, L->top++, &exiterr); /* Anchor the error object. */ + + if (!(LJ_HASPROFILE && (G(L)->hookmask & HOOK_PROFILE))) + lj_vmevent_send(L, TEXIT, + lj_state_checkstack(L, 4+RID_NUM_GPR+RID_NUM_FPR+LUA_MINSTACK); + setintV(L->top++, J->parent); + setintV(L->top++, J->exitno); + trace_exit_regs(L, ex); + ); + + pc = exd.pc; + cf = cframe_raw(L->cframe); + setcframe_pc(cf, pc); + if (exitcode) { + return -exitcode; + } else if (LJ_HASPROFILE && (G(L)->hookmask & HOOK_PROFILE)) { + /* Just exit to interpreter. */ + } else if (G(L)->gc.state == GCSatomic || G(L)->gc.state == GCSfinalize) { + if (!(G(L)->hookmask & HOOK_GC)) + lj_gc_step(L); /* Exited because of GC: drive GC forward. */ + } else { + trace_hotside(J, pc); + } + if (bc_op(*pc) == BC_JLOOP) { + BCIns *retpc = &traceref(J, bc_d(*pc))->startins; + int isret = bc_isret(bc_op(*retpc)); + if (isret || bc_op(*retpc) == BC_ITERN) { + if (J->state == LJ_TRACE_RECORD) { + J->patchins = *pc; + J->patchpc = (BCIns *)pc; + *J->patchpc = *retpc; + J->bcskip = 1; + } else if (isret) { + pc = retpc; + setcframe_pc(cf, pc); + } + } + } + /* Return MULTRES or 0. */ + ERRNO_RESTORE + switch (bc_op(*pc)) { + case BC_CALLM: case BC_CALLMT: + return (int)((BCReg)(L->top - L->base) - bc_a(*pc) - bc_c(*pc) - LJ_FR2); + case BC_RETM: + return (int)((BCReg)(L->top - L->base) + 1 - bc_a(*pc) - bc_d(*pc)); + case BC_TSETM: + return (int)((BCReg)(L->top - L->base) + 1 - bc_a(*pc)); + default: + if (bc_op(*pc) >= BC_FUNCF) + return (int)((BCReg)(L->top - L->base) + 1); + return 0; + } +} + +#if LJ_UNWIND_JIT +/* Given an mcode address determine trace exit address for unwinding. */ +uintptr_t LJ_FASTCALL lj_trace_unwind(jit_State *J, uintptr_t addr, ExitNo *ep) +{ +#if EXITTRACE_VMSTATE + TraceNo traceno = J2G(J)->vmstate; +#else + TraceNo traceno = trace_exit_find(J, (MCode *)addr); +#endif + GCtrace *T = traceref(J, traceno); + if (T +#if EXITTRACE_VMSTATE + && addr >= (uintptr_t)T->mcode && addr < (uintptr_t)T->mcode + T->szmcode +#endif + ) { + SnapShot *snap = T->snap; + SnapNo lo = 0, exitno = T->nsnap; + uintptr_t ofs = (uintptr_t)((MCode *)addr - T->mcode); /* MCode units! */ + /* Rightmost binary search for mcode offset to determine exit number. */ + do { + SnapNo mid = (lo+exitno) >> 1; + if (ofs < snap[mid].mcofs) exitno = mid; else lo = mid + 1; + } while (lo < exitno); + exitno--; + *ep = exitno; +#ifdef EXITSTUBS_PER_GROUP + return (uintptr_t)exitstub_addr(J, exitno); +#else + return (uintptr_t)exitstub_trace_addr(T, exitno); +#endif + } + /* Cannot correlate addr with trace/exit. This will be fatal. */ + lj_assertJ(0, "bad exit pc"); + return 0; +} +#endif + +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_trace.h b/fluent-bit/lib/luajit-3065c9/src/lj_trace.h new file mode 100644 index 00000000..3d7f76f0 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_trace.h @@ -0,0 +1,58 @@ +/* +** Trace management. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#ifndef _LJ_TRACE_H +#define _LJ_TRACE_H + +#include "lj_obj.h" + +#if LJ_HASJIT +#include "lj_jit.h" +#include "lj_dispatch.h" + +/* Trace errors. */ +typedef enum { +#define TREDEF(name, msg) LJ_TRERR_##name, +#include "lj_traceerr.h" + LJ_TRERR__MAX +} TraceError; + +LJ_FUNC_NORET void lj_trace_err(jit_State *J, TraceError e); +LJ_FUNC_NORET void lj_trace_err_info(jit_State *J, TraceError e); + +/* Trace management. */ +LJ_FUNC GCtrace * LJ_FASTCALL lj_trace_alloc(lua_State *L, GCtrace *T); +LJ_FUNC void LJ_FASTCALL lj_trace_free(global_State *g, GCtrace *T); +LJ_FUNC void lj_trace_reenableproto(GCproto *pt); +LJ_FUNC void lj_trace_flushproto(global_State *g, GCproto *pt); +LJ_FUNC void lj_trace_flush(jit_State *J, TraceNo traceno); +LJ_FUNC int lj_trace_flushall(lua_State *L); +LJ_FUNC void lj_trace_initstate(global_State *g); +LJ_FUNC void lj_trace_freestate(global_State *g); + +/* Event handling. */ +LJ_FUNC void lj_trace_ins(jit_State *J, const BCIns *pc); +LJ_FUNCA void LJ_FASTCALL lj_trace_hot(jit_State *J, const BCIns *pc); +LJ_FUNCA void LJ_FASTCALL lj_trace_stitch(jit_State *J, const BCIns *pc); +LJ_FUNCA int LJ_FASTCALL lj_trace_exit(jit_State *J, void *exptr); +#if LJ_UNWIND_EXT +LJ_FUNC uintptr_t LJ_FASTCALL lj_trace_unwind(jit_State *J, uintptr_t addr, ExitNo *ep); +#endif + +/* Signal asynchronous abort of trace or end of trace. */ +#define lj_trace_abort(g) (G2J(g)->state &= ~LJ_TRACE_ACTIVE) +#define lj_trace_end(J) (J->state = LJ_TRACE_END) + +#else + +#define lj_trace_flushall(L) (UNUSED(L), 0) +#define lj_trace_initstate(g) UNUSED(g) +#define lj_trace_freestate(g) UNUSED(g) +#define lj_trace_abort(g) UNUSED(g) +#define lj_trace_end(J) UNUSED(J) + +#endif + +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_traceerr.h b/fluent-bit/lib/luajit-3065c9/src/lj_traceerr.h new file mode 100644 index 00000000..8ed8ac82 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_traceerr.h @@ -0,0 +1,61 @@ +/* +** Trace compiler error messages. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +/* This file may be included multiple times with different TREDEF macros. */ + +/* Recording. */ +TREDEF(RECERR, "error thrown or hook called during recording") +TREDEF(TRACEUV, "trace too short") +TREDEF(TRACEOV, "trace too long") +TREDEF(STACKOV, "trace too deep") +TREDEF(SNAPOV, "too many snapshots") +TREDEF(BLACKL, "blacklisted") +TREDEF(RETRY, "retry recording") +TREDEF(NYIBC, "NYI: bytecode %d") + +/* Recording loop ops. */ +TREDEF(LLEAVE, "leaving loop in root trace") +TREDEF(LINNER, "inner loop in root trace") +TREDEF(LUNROLL, "loop unroll limit reached") + +/* Recording calls/returns. */ +TREDEF(BADTYPE, "bad argument type") +TREDEF(CJITOFF, "JIT compilation disabled for function") +TREDEF(CUNROLL, "call unroll limit reached") +TREDEF(DOWNREC, "down-recursion, restarting") +TREDEF(NYIFFU, "NYI: unsupported variant of FastFunc %s") +TREDEF(NYIRETL, "NYI: return to lower frame") + +/* Recording indexed load/store. */ +TREDEF(STORENN, "store with nil or NaN key") +TREDEF(NOMM, "missing metamethod") +TREDEF(IDXLOOP, "looping index lookup") +TREDEF(NYITMIX, "NYI: mixed sparse/dense table") + +/* Recording C data operations. */ +TREDEF(NOCACHE, "symbol not in cache") +TREDEF(NYICONV, "NYI: unsupported C type conversion") +TREDEF(NYICALL, "NYI: unsupported C function type") + +/* Optimizations. */ +TREDEF(GFAIL, "guard would always fail") +TREDEF(PHIOV, "too many PHIs") +TREDEF(TYPEINS, "persistent type instability") + +/* Assembler. */ +TREDEF(MCODEAL, "failed to allocate mcode memory") +TREDEF(MCODEOV, "machine code too long") +TREDEF(MCODELM, "hit mcode limit (retrying)") +TREDEF(SPILLOV, "too many spill slots") +TREDEF(BADRA, "inconsistent register allocation") +TREDEF(NYIIR, "NYI: cannot assemble IR instruction %d") +TREDEF(NYIPHI, "NYI: PHI shuffling too complex") +TREDEF(NYICOAL, "NYI: register coalescing too complex") + +#undef TREDEF + +/* Detecting unused error messages: + awk -F, '/^TREDEF/ { gsub(/TREDEF./, ""); printf "grep -q LJ_TRERR_%s *.[ch] || echo %s\n", $1, $1}' lj_traceerr.h | sh +*/ diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_udata.c b/fluent-bit/lib/luajit-3065c9/src/lj_udata.c new file mode 100644 index 00000000..ee4a145d --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_udata.c @@ -0,0 +1,62 @@ +/* +** Userdata handling. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#define lj_udata_c +#define LUA_CORE + +#include "lj_obj.h" +#include "lj_gc.h" +#include "lj_err.h" +#include "lj_udata.h" + +GCudata *lj_udata_new(lua_State *L, MSize sz, GCtab *env) +{ + GCudata *ud = lj_mem_newt(L, sizeof(GCudata) + sz, GCudata); + global_State *g = G(L); + newwhite(g, ud); /* Not finalized. */ + ud->gct = ~LJ_TUDATA; + ud->udtype = UDTYPE_USERDATA; + ud->len = sz; + /* NOBARRIER: The GCudata is new (marked white). */ + setgcrefnull(ud->metatable); + setgcref(ud->env, obj2gco(env)); + /* Chain to userdata list (after main thread). */ + setgcrefr(ud->nextgc, mainthread(g)->nextgc); + setgcref(mainthread(g)->nextgc, obj2gco(ud)); + return ud; +} + +void LJ_FASTCALL lj_udata_free(global_State *g, GCudata *ud) +{ + lj_mem_free(g, ud, sizeudata(ud)); +} + +#if LJ_64 +void *lj_lightud_intern(lua_State *L, void *p) +{ + global_State *g = G(L); + uint64_t u = (uint64_t)p; + uint32_t up = lightudup(u); + uint32_t *segmap = mref(g->gc.lightudseg, uint32_t); + MSize segnum = g->gc.lightudnum; + if (segmap) { + MSize seg; + for (seg = 0; seg <= segnum; seg++) + if (segmap[seg] == up) /* Fast path. */ + return (void *)(((uint64_t)seg << LJ_LIGHTUD_BITS_LO) | lightudlo(u)); + segnum++; + /* Leave last segment unused to avoid clash with ITERN key. */ + if (segnum >= (1 << LJ_LIGHTUD_BITS_SEG)-1) lj_err_msg(L, LJ_ERR_BADLU); + } + if (!((segnum-1) & segnum) && segnum != 1) { + lj_mem_reallocvec(L, segmap, segnum, segnum ? 2*segnum : 2u, uint32_t); + setmref(g->gc.lightudseg, segmap); + } + g->gc.lightudnum = segnum; + segmap[segnum] = up; + return (void *)(((uint64_t)segnum << LJ_LIGHTUD_BITS_LO) | lightudlo(u)); +} +#endif + diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_udata.h b/fluent-bit/lib/luajit-3065c9/src/lj_udata.h new file mode 100644 index 00000000..503c9e30 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_udata.h @@ -0,0 +1,17 @@ +/* +** Userdata handling. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#ifndef _LJ_UDATA_H +#define _LJ_UDATA_H + +#include "lj_obj.h" + +LJ_FUNC GCudata *lj_udata_new(lua_State *L, MSize sz, GCtab *env); +LJ_FUNC void LJ_FASTCALL lj_udata_free(global_State *g, GCudata *ud); +#if LJ_64 +LJ_FUNC void * LJ_FASTCALL lj_lightud_intern(lua_State *L, void *p); +#endif + +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_vm.h b/fluent-bit/lib/luajit-3065c9/src/lj_vm.h new file mode 100644 index 00000000..c66db004 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_vm.h @@ -0,0 +1,116 @@ +/* +** Assembler VM interface definitions. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#ifndef _LJ_VM_H +#define _LJ_VM_H + +#include "lj_obj.h" + +/* Entry points for ASM parts of VM. */ +LJ_ASMF void lj_vm_call(lua_State *L, TValue *base, int nres1); +LJ_ASMF int lj_vm_pcall(lua_State *L, TValue *base, int nres1, ptrdiff_t ef); +typedef TValue *(*lua_CPFunction)(lua_State *L, lua_CFunction func, void *ud); +LJ_ASMF int lj_vm_cpcall(lua_State *L, lua_CFunction func, void *ud, + lua_CPFunction cp); +LJ_ASMF int lj_vm_resume(lua_State *L, TValue *base, int nres1, ptrdiff_t ef); +LJ_ASMF_NORET void LJ_FASTCALL lj_vm_unwind_c(void *cframe, int errcode); +LJ_ASMF_NORET void LJ_FASTCALL lj_vm_unwind_ff(void *cframe); +#if LJ_ABI_WIN && LJ_TARGET_X86 +LJ_ASMF_NORET void LJ_FASTCALL lj_vm_rtlunwind(void *cframe, void *excptrec, + void *unwinder, int errcode); +#endif +LJ_ASMF void lj_vm_unwind_c_eh(void); +LJ_ASMF void lj_vm_unwind_ff_eh(void); +#if LJ_TARGET_X86ORX64 +LJ_ASMF void lj_vm_unwind_rethrow(void); +#endif +#if LJ_TARGET_MIPS +LJ_ASMF void lj_vm_unwind_stub(void); +#endif + +/* Miscellaneous functions. */ +#if LJ_TARGET_X86ORX64 +LJ_ASMF int lj_vm_cpuid(uint32_t f, uint32_t res[4]); +#endif +#if LJ_TARGET_PPC +void lj_vm_cachesync(void *start, void *end); +#endif +LJ_ASMF double lj_vm_foldarith(double x, double y, int op); +#if LJ_HASJIT +LJ_ASMF double lj_vm_foldfpm(double x, int op); +#endif +#if !LJ_ARCH_HASFPU +/* Declared in lj_obj.h: LJ_ASMF int32_t lj_vm_tobit(double x); */ +#endif + +/* Dispatch targets for recording and hooks. */ +LJ_ASMF void lj_vm_record(void); +LJ_ASMF void lj_vm_inshook(void); +LJ_ASMF void lj_vm_rethook(void); +LJ_ASMF void lj_vm_callhook(void); +LJ_ASMF void lj_vm_profhook(void); +LJ_ASMF void lj_vm_IITERN(void); + +/* Trace exit handling. */ +LJ_ASMF void lj_vm_exit_handler(void); +LJ_ASMF void lj_vm_exit_interp(void); + +/* Internal math helper functions. */ +#if LJ_TARGET_PPC || LJ_TARGET_ARM64 || (LJ_TARGET_MIPS && LJ_ABI_SOFTFP) +#define lj_vm_floor floor +#define lj_vm_ceil ceil +#else +LJ_ASMF double lj_vm_floor(double); +LJ_ASMF double lj_vm_ceil(double); +#if LJ_TARGET_ARM +LJ_ASMF double lj_vm_floor_sf(double); +LJ_ASMF double lj_vm_ceil_sf(double); +#endif +#endif +#ifdef LUAJIT_NO_LOG2 +LJ_ASMF double lj_vm_log2(double); +#else +#define lj_vm_log2 log2 +#endif +#if !(defined(_LJ_DISPATCH_H) && LJ_TARGET_MIPS) +LJ_ASMF int32_t LJ_FASTCALL lj_vm_modi(int32_t, int32_t); +#endif + +#if LJ_HASJIT +#if LJ_TARGET_X86ORX64 +LJ_ASMF void lj_vm_floor_sse(void); +LJ_ASMF void lj_vm_ceil_sse(void); +LJ_ASMF void lj_vm_trunc_sse(void); +#endif +#if LJ_TARGET_PPC || LJ_TARGET_ARM64 +#define lj_vm_trunc trunc +#else +LJ_ASMF double lj_vm_trunc(double); +#if LJ_TARGET_ARM +LJ_ASMF double lj_vm_trunc_sf(double); +#endif +#endif +#if LJ_HASFFI +LJ_ASMF int lj_vm_errno(void); +#endif +LJ_ASMF TValue *lj_vm_next(GCtab *t, uint32_t idx); +#endif + +/* Continuations for metamethods. */ +LJ_ASMF void lj_cont_cat(void); /* Continue with concatenation. */ +LJ_ASMF void lj_cont_ra(void); /* Store result in RA from instruction. */ +LJ_ASMF void lj_cont_nop(void); /* Do nothing, just continue execution. */ +LJ_ASMF void lj_cont_condt(void); /* Branch if result is true. */ +LJ_ASMF void lj_cont_condf(void); /* Branch if result is false. */ +LJ_ASMF void lj_cont_hook(void); /* Continue from hook yield. */ +LJ_ASMF void lj_cont_stitch(void); /* Trace stitching. */ + +/* Start of the ASM code. */ +LJ_ASMF char lj_vm_asm_begin[]; + +/* Bytecode offsets are relative to lj_vm_asm_begin. */ +#define makeasmfunc(ofs) ((ASMFunction)(lj_vm_asm_begin + (ofs))) + +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_vmevent.c b/fluent-bit/lib/luajit-3065c9/src/lj_vmevent.c new file mode 100644 index 00000000..c8491d82 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_vmevent.c @@ -0,0 +1,58 @@ +/* +** VM event handling. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#include + +#define lj_vmevent_c +#define LUA_CORE + +#include "lj_obj.h" +#include "lj_str.h" +#include "lj_tab.h" +#include "lj_state.h" +#include "lj_dispatch.h" +#include "lj_vm.h" +#include "lj_vmevent.h" + +ptrdiff_t lj_vmevent_prepare(lua_State *L, VMEvent ev) +{ + global_State *g = G(L); + GCstr *s = lj_str_newlit(L, LJ_VMEVENTS_REGKEY); + cTValue *tv = lj_tab_getstr(tabV(registry(L)), s); + if (tvistab(tv)) { + int hash = VMEVENT_HASH(ev); + tv = lj_tab_getint(tabV(tv), hash); + if (tv && tvisfunc(tv)) { + lj_state_checkstack(L, LUA_MINSTACK); + setfuncV(L, L->top++, funcV(tv)); + if (LJ_FR2) setnilV(L->top++); + return savestack(L, L->top); + } + } + g->vmevmask &= ~VMEVENT_MASK(ev); /* No handler: cache this fact. */ + return 0; +} + +void lj_vmevent_call(lua_State *L, ptrdiff_t argbase) +{ + global_State *g = G(L); + uint8_t oldmask = g->vmevmask; + uint8_t oldh = hook_save(g); + int status; + g->vmevmask = 0; /* Disable all events. */ + hook_vmevent(g); + status = lj_vm_pcall(L, restorestack(L, argbase), 0+1, 0); + if (LJ_UNLIKELY(status)) { + /* Really shouldn't use stderr here, but where else to complain? */ + L->top--; + fputs("VM handler failed: ", stderr); + fputs(tvisstr(L->top) ? strVdata(L->top) : "?", stderr); + fputc('\n', stderr); + } + hook_restore(g, oldh); + if (g->vmevmask != VMEVENT_NOCACHE) + g->vmevmask = oldmask; /* Restore event mask, but not if not modified. */ +} + diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_vmevent.h b/fluent-bit/lib/luajit-3065c9/src/lj_vmevent.h new file mode 100644 index 00000000..40f9c631 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_vmevent.h @@ -0,0 +1,59 @@ +/* +** VM event handling. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#ifndef _LJ_VMEVENT_H +#define _LJ_VMEVENT_H + +#include "lj_obj.h" + +/* Registry key for VM event handler table. */ +#define LJ_VMEVENTS_REGKEY "_VMEVENTS" +#define LJ_VMEVENTS_HSIZE 4 + +#define VMEVENT_MASK(ev) ((uint8_t)1 << ((int)(ev) & 7)) +#define VMEVENT_HASH(ev) ((int)(ev) & ~7) +#define VMEVENT_HASHIDX(h) ((int)(h) << 3) +#define VMEVENT_NOCACHE 255 + +#define VMEVENT_DEF(name, hash) \ + LJ_VMEVENT_##name##_, \ + LJ_VMEVENT_##name = ((LJ_VMEVENT_##name##_) & 7)|((hash) << 3) + +/* VM event IDs. */ +typedef enum { + VMEVENT_DEF(BC, 0x00003883), + VMEVENT_DEF(TRACE, 0xb2d91467), + VMEVENT_DEF(RECORD, 0x9284bf4f), + VMEVENT_DEF(TEXIT, 0xb29df2b0), + LJ_VMEVENT__MAX +} VMEvent; + +#ifdef LUAJIT_DISABLE_VMEVENT +#define lj_vmevent_send(L, ev, args) UNUSED(L) +#define lj_vmevent_send_(L, ev, args, post) UNUSED(L) +#else +#define lj_vmevent_send(L, ev, args) \ + if (G(L)->vmevmask & VMEVENT_MASK(LJ_VMEVENT_##ev)) { \ + ptrdiff_t argbase = lj_vmevent_prepare(L, LJ_VMEVENT_##ev); \ + if (argbase) { \ + args \ + lj_vmevent_call(L, argbase); \ + } \ + } +#define lj_vmevent_send_(L, ev, args, post) \ + if (G(L)->vmevmask & VMEVENT_MASK(LJ_VMEVENT_##ev)) { \ + ptrdiff_t argbase = lj_vmevent_prepare(L, LJ_VMEVENT_##ev); \ + if (argbase) { \ + args \ + lj_vmevent_call(L, argbase); \ + post \ + } \ + } + +LJ_FUNC ptrdiff_t lj_vmevent_prepare(lua_State *L, VMEvent ev); +LJ_FUNC void lj_vmevent_call(lua_State *L, ptrdiff_t argbase); +#endif + +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/lj_vmmath.c b/fluent-bit/lib/luajit-3065c9/src/lj_vmmath.c new file mode 100644 index 00000000..b6cc60ba --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lj_vmmath.c @@ -0,0 +1,107 @@ +/* +** Math helper functions for assembler VM. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#define lj_vmmath_c +#define LUA_CORE + +#include +#include + +#include "lj_obj.h" +#include "lj_ir.h" +#include "lj_vm.h" + +/* -- Wrapper functions --------------------------------------------------- */ + +#if LJ_TARGET_X86 && __ELF__ && __PIC__ +/* Wrapper functions to deal with the ELF/x86 PIC disaster. */ +LJ_FUNCA double lj_wrap_log(double x) { return log(x); } +LJ_FUNCA double lj_wrap_log10(double x) { return log10(x); } +LJ_FUNCA double lj_wrap_exp(double x) { return exp(x); } +LJ_FUNCA double lj_wrap_sin(double x) { return sin(x); } +LJ_FUNCA double lj_wrap_cos(double x) { return cos(x); } +LJ_FUNCA double lj_wrap_tan(double x) { return tan(x); } +LJ_FUNCA double lj_wrap_asin(double x) { return asin(x); } +LJ_FUNCA double lj_wrap_acos(double x) { return acos(x); } +LJ_FUNCA double lj_wrap_atan(double x) { return atan(x); } +LJ_FUNCA double lj_wrap_sinh(double x) { return sinh(x); } +LJ_FUNCA double lj_wrap_cosh(double x) { return cosh(x); } +LJ_FUNCA double lj_wrap_tanh(double x) { return tanh(x); } +LJ_FUNCA double lj_wrap_atan2(double x, double y) { return atan2(x, y); } +LJ_FUNCA double lj_wrap_pow(double x, double y) { return pow(x, y); } +LJ_FUNCA double lj_wrap_fmod(double x, double y) { return fmod(x, y); } +#endif + +/* -- Helper functions ---------------------------------------------------- */ + +double lj_vm_foldarith(double x, double y, int op) +{ + switch (op) { + case IR_ADD - IR_ADD: return x+y; break; + case IR_SUB - IR_ADD: return x-y; break; + case IR_MUL - IR_ADD: return x*y; break; + case IR_DIV - IR_ADD: return x/y; break; + case IR_MOD - IR_ADD: return x-lj_vm_floor(x/y)*y; break; + case IR_POW - IR_ADD: return pow(x, y); break; + case IR_NEG - IR_ADD: return -x; break; + case IR_ABS - IR_ADD: return fabs(x); break; +#if LJ_HASJIT + case IR_LDEXP - IR_ADD: return ldexp(x, (int)y); break; + case IR_MIN - IR_ADD: return x < y ? x : y; break; + case IR_MAX - IR_ADD: return x > y ? x : y; break; +#endif + default: return x; + } +} + +/* -- Helper functions for generated machine code ------------------------- */ + +#if (LJ_HASJIT && !(LJ_TARGET_ARM || LJ_TARGET_ARM64 || LJ_TARGET_PPC)) || LJ_TARGET_MIPS +int32_t LJ_FASTCALL lj_vm_modi(int32_t a, int32_t b) +{ + uint32_t y, ua, ub; + /* This must be checked before using this function. */ + lj_assertX(b != 0, "modulo with zero divisor"); + ua = a < 0 ? (uint32_t)-a : (uint32_t)a; + ub = b < 0 ? (uint32_t)-b : (uint32_t)b; + y = ua % ub; + if (y != 0 && (a^b) < 0) y = y - ub; + if (((int32_t)y^b) < 0) y = (uint32_t)-(int32_t)y; + return (int32_t)y; +} +#endif + +#if LJ_HASJIT + +#ifdef LUAJIT_NO_LOG2 +double lj_vm_log2(double a) +{ + return log(a) * 1.4426950408889634074; +} +#endif + +/* Computes fpm(x) for extended math functions. */ +double lj_vm_foldfpm(double x, int fpm) +{ + switch (fpm) { + case IRFPM_FLOOR: return lj_vm_floor(x); + case IRFPM_CEIL: return lj_vm_ceil(x); + case IRFPM_TRUNC: return lj_vm_trunc(x); + case IRFPM_SQRT: return sqrt(x); + case IRFPM_LOG: return log(x); + case IRFPM_LOG2: return lj_vm_log2(x); + default: lj_assertX(0, "bad fpm %d", fpm); + } + return 0; +} + +#if LJ_HASFFI +int lj_vm_errno(void) +{ + return errno; +} +#endif + +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/ljamalg.c b/fluent-bit/lib/luajit-3065c9/src/ljamalg.c new file mode 100644 index 00000000..cae8356c --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/ljamalg.c @@ -0,0 +1,91 @@ +/* +** LuaJIT core and libraries amalgamation. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#define ljamalg_c +#define LUA_CORE + +/* To get the mremap prototype. Must be defined before any system includes. */ +#if defined(__linux__) && !defined(_GNU_SOURCE) +#define _GNU_SOURCE +#endif + +#ifndef WINVER +#define WINVER 0x0501 +#endif + +#include "lua.h" +#include "lauxlib.h" + +#include "lj_assert.c" +#include "lj_gc.c" +#include "lj_err.c" +#include "lj_char.c" +#include "lj_bc.c" +#include "lj_obj.c" +#include "lj_buf.c" +#include "lj_str.c" +#include "lj_tab.c" +#include "lj_func.c" +#include "lj_udata.c" +#include "lj_meta.c" +#include "lj_debug.c" +#include "lj_prng.c" +#include "lj_state.c" +#include "lj_dispatch.c" +#include "lj_vmevent.c" +#include "lj_vmmath.c" +#include "lj_strscan.c" +#include "lj_strfmt.c" +#include "lj_strfmt_num.c" +#include "lj_serialize.c" +#include "lj_api.c" +#include "lj_profile.c" +#include "lj_lex.c" +#include "lj_parse.c" +#include "lj_bcread.c" +#include "lj_bcwrite.c" +#include "lj_load.c" +#include "lj_ctype.c" +#include "lj_cdata.c" +#include "lj_cconv.c" +#include "lj_ccall.c" +#include "lj_ccallback.c" +#include "lj_carith.c" +#include "lj_clib.c" +#include "lj_cparse.c" +#include "lj_lib.c" +#include "lj_ir.c" +#include "lj_opt_mem.c" +#include "lj_opt_fold.c" +#include "lj_opt_narrow.c" +#include "lj_opt_dce.c" +#include "lj_opt_loop.c" +#include "lj_opt_split.c" +#include "lj_opt_sink.c" +#include "lj_mcode.c" +#include "lj_snap.c" +#include "lj_record.c" +#include "lj_crecord.c" +#include "lj_ffrecord.c" +#include "lj_asm.c" +#include "lj_trace.c" +#include "lj_gdbjit.c" +#include "lj_alloc.c" + +#include "lib_aux.c" +#include "lib_base.c" +#include "lib_math.c" +#include "lib_string.c" +#include "lib_table.c" +#include "lib_io.c" +#include "lib_os.c" +#include "lib_package.c" +#include "lib_debug.c" +#include "lib_bit.c" +#include "lib_jit.c" +#include "lib_ffi.c" +#include "lib_buffer.c" +#include "lib_init.c" + diff --git a/fluent-bit/lib/luajit-3065c9/src/lua.h b/fluent-bit/lib/luajit-3065c9/src/lua.h new file mode 100644 index 00000000..6d1634d1 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lua.h @@ -0,0 +1,402 @@ +/* +** $Id: lua.h,v 1.218.1.5 2008/08/06 13:30:12 roberto Exp $ +** Lua - An Extensible Extension Language +** Lua.org, PUC-Rio, Brazil (https://www.lua.org) +** See Copyright Notice at the end of this file +*/ + + +#ifndef lua_h +#define lua_h + +#include +#include + + +#include "luaconf.h" + + +#define LUA_VERSION "Lua 5.1" +#define LUA_RELEASE "Lua 5.1.4" +#define LUA_VERSION_NUM 501 +#define LUA_COPYRIGHT "Copyright (C) 1994-2008 Lua.org, PUC-Rio" +#define LUA_AUTHORS "R. Ierusalimschy, L. H. de Figueiredo & W. Celes" + + +/* mark for precompiled code (`Lua') */ +#define LUA_SIGNATURE "\033Lua" + +/* option for multiple returns in `lua_pcall' and `lua_call' */ +#define LUA_MULTRET (-1) + + +/* +** pseudo-indices +*/ +#define LUA_REGISTRYINDEX (-10000) +#define LUA_ENVIRONINDEX (-10001) +#define LUA_GLOBALSINDEX (-10002) +#define lua_upvalueindex(i) (LUA_GLOBALSINDEX-(i)) + + +/* thread status */ +#define LUA_OK 0 +#define LUA_YIELD 1 +#define LUA_ERRRUN 2 +#define LUA_ERRSYNTAX 3 +#define LUA_ERRMEM 4 +#define LUA_ERRERR 5 + + +typedef struct lua_State lua_State; + +typedef int (*lua_CFunction) (lua_State *L); + + +/* +** functions that read/write blocks when loading/dumping Lua chunks +*/ +typedef const char * (*lua_Reader) (lua_State *L, void *ud, size_t *sz); + +typedef int (*lua_Writer) (lua_State *L, const void* p, size_t sz, void* ud); + + +/* +** prototype for memory-allocation functions +*/ +typedef void * (*lua_Alloc) (void *ud, void *ptr, size_t osize, size_t nsize); + + +/* +** basic types +*/ +#define LUA_TNONE (-1) + +#define LUA_TNIL 0 +#define LUA_TBOOLEAN 1 +#define LUA_TLIGHTUSERDATA 2 +#define LUA_TNUMBER 3 +#define LUA_TSTRING 4 +#define LUA_TTABLE 5 +#define LUA_TFUNCTION 6 +#define LUA_TUSERDATA 7 +#define LUA_TTHREAD 8 + + + +/* minimum Lua stack available to a C function */ +#define LUA_MINSTACK 20 + + +/* +** generic extra include file +*/ +#if defined(LUA_USER_H) +#include LUA_USER_H +#endif + + +/* type of numbers in Lua */ +typedef LUA_NUMBER lua_Number; + + +/* type for integer functions */ +typedef LUA_INTEGER lua_Integer; + + + +/* +** state manipulation +*/ +LUA_API lua_State *(lua_newstate) (lua_Alloc f, void *ud); +LUA_API void (lua_close) (lua_State *L); +LUA_API lua_State *(lua_newthread) (lua_State *L); + +LUA_API lua_CFunction (lua_atpanic) (lua_State *L, lua_CFunction panicf); + + +/* +** basic stack manipulation +*/ +LUA_API int (lua_gettop) (lua_State *L); +LUA_API void (lua_settop) (lua_State *L, int idx); +LUA_API void (lua_pushvalue) (lua_State *L, int idx); +LUA_API void (lua_remove) (lua_State *L, int idx); +LUA_API void (lua_insert) (lua_State *L, int idx); +LUA_API void (lua_replace) (lua_State *L, int idx); +LUA_API int (lua_checkstack) (lua_State *L, int sz); + +LUA_API void (lua_xmove) (lua_State *from, lua_State *to, int n); + + +/* +** access functions (stack -> C) +*/ + +LUA_API int (lua_isnumber) (lua_State *L, int idx); +LUA_API int (lua_isstring) (lua_State *L, int idx); +LUA_API int (lua_iscfunction) (lua_State *L, int idx); +LUA_API int (lua_isuserdata) (lua_State *L, int idx); +LUA_API int (lua_type) (lua_State *L, int idx); +LUA_API const char *(lua_typename) (lua_State *L, int tp); + +LUA_API int (lua_equal) (lua_State *L, int idx1, int idx2); +LUA_API int (lua_rawequal) (lua_State *L, int idx1, int idx2); +LUA_API int (lua_lessthan) (lua_State *L, int idx1, int idx2); + +LUA_API lua_Number (lua_tonumber) (lua_State *L, int idx); +LUA_API lua_Integer (lua_tointeger) (lua_State *L, int idx); +LUA_API int (lua_toboolean) (lua_State *L, int idx); +LUA_API const char *(lua_tolstring) (lua_State *L, int idx, size_t *len); +LUA_API size_t (lua_objlen) (lua_State *L, int idx); +LUA_API lua_CFunction (lua_tocfunction) (lua_State *L, int idx); +LUA_API void *(lua_touserdata) (lua_State *L, int idx); +LUA_API lua_State *(lua_tothread) (lua_State *L, int idx); +LUA_API const void *(lua_topointer) (lua_State *L, int idx); + + +/* +** push functions (C -> stack) +*/ +LUA_API void (lua_pushnil) (lua_State *L); +LUA_API void (lua_pushnumber) (lua_State *L, lua_Number n); +LUA_API void (lua_pushinteger) (lua_State *L, lua_Integer n); +LUA_API void (lua_pushlstring) (lua_State *L, const char *s, size_t l); +LUA_API void (lua_pushstring) (lua_State *L, const char *s); +LUA_API const char *(lua_pushvfstring) (lua_State *L, const char *fmt, + va_list argp); +LUA_API const char *(lua_pushfstring) (lua_State *L, const char *fmt, ...); +LUA_API void (lua_pushcclosure) (lua_State *L, lua_CFunction fn, int n); +LUA_API void (lua_pushboolean) (lua_State *L, int b); +LUA_API void (lua_pushlightuserdata) (lua_State *L, void *p); +LUA_API int (lua_pushthread) (lua_State *L); + + +/* +** get functions (Lua -> stack) +*/ +LUA_API void (lua_gettable) (lua_State *L, int idx); +LUA_API void (lua_getfield) (lua_State *L, int idx, const char *k); +LUA_API void (lua_rawget) (lua_State *L, int idx); +LUA_API void (lua_rawgeti) (lua_State *L, int idx, int n); +LUA_API void (lua_createtable) (lua_State *L, int narr, int nrec); +LUA_API void *(lua_newuserdata) (lua_State *L, size_t sz); +LUA_API int (lua_getmetatable) (lua_State *L, int objindex); +LUA_API void (lua_getfenv) (lua_State *L, int idx); + + +/* +** set functions (stack -> Lua) +*/ +LUA_API void (lua_settable) (lua_State *L, int idx); +LUA_API void (lua_setfield) (lua_State *L, int idx, const char *k); +LUA_API void (lua_rawset) (lua_State *L, int idx); +LUA_API void (lua_rawseti) (lua_State *L, int idx, int n); +LUA_API int (lua_setmetatable) (lua_State *L, int objindex); +LUA_API int (lua_setfenv) (lua_State *L, int idx); + + +/* +** `load' and `call' functions (load and run Lua code) +*/ +LUA_API void (lua_call) (lua_State *L, int nargs, int nresults); +LUA_API int (lua_pcall) (lua_State *L, int nargs, int nresults, int errfunc); +LUA_API int (lua_cpcall) (lua_State *L, lua_CFunction func, void *ud); +LUA_API int (lua_load) (lua_State *L, lua_Reader reader, void *dt, + const char *chunkname); + +LUA_API int (lua_dump) (lua_State *L, lua_Writer writer, void *data); + + +/* +** coroutine functions +*/ +LUA_API int (lua_yield) (lua_State *L, int nresults); +LUA_API int (lua_resume) (lua_State *L, int narg); +LUA_API int (lua_status) (lua_State *L); + +/* +** garbage-collection function and options +*/ + +#define LUA_GCSTOP 0 +#define LUA_GCRESTART 1 +#define LUA_GCCOLLECT 2 +#define LUA_GCCOUNT 3 +#define LUA_GCCOUNTB 4 +#define LUA_GCSTEP 5 +#define LUA_GCSETPAUSE 6 +#define LUA_GCSETSTEPMUL 7 +#define LUA_GCISRUNNING 9 + +LUA_API int (lua_gc) (lua_State *L, int what, int data); + + +/* +** miscellaneous functions +*/ + +LUA_API int (lua_error) (lua_State *L); + +LUA_API int (lua_next) (lua_State *L, int idx); + +LUA_API void (lua_concat) (lua_State *L, int n); + +LUA_API lua_Alloc (lua_getallocf) (lua_State *L, void **ud); +LUA_API void lua_setallocf (lua_State *L, lua_Alloc f, void *ud); + + + +/* +** =============================================================== +** some useful macros +** =============================================================== +*/ + +#define lua_pop(L,n) lua_settop(L, -(n)-1) + +#define lua_newtable(L) lua_createtable(L, 0, 0) + +#define lua_register(L,n,f) (lua_pushcfunction(L, (f)), lua_setglobal(L, (n))) + +#define lua_pushcfunction(L,f) lua_pushcclosure(L, (f), 0) + +#define lua_strlen(L,i) lua_objlen(L, (i)) + +#define lua_isfunction(L,n) (lua_type(L, (n)) == LUA_TFUNCTION) +#define lua_istable(L,n) (lua_type(L, (n)) == LUA_TTABLE) +#define lua_islightuserdata(L,n) (lua_type(L, (n)) == LUA_TLIGHTUSERDATA) +#define lua_isnil(L,n) (lua_type(L, (n)) == LUA_TNIL) +#define lua_isboolean(L,n) (lua_type(L, (n)) == LUA_TBOOLEAN) +#define lua_isthread(L,n) (lua_type(L, (n)) == LUA_TTHREAD) +#define lua_isnone(L,n) (lua_type(L, (n)) == LUA_TNONE) +#define lua_isnoneornil(L, n) (lua_type(L, (n)) <= 0) + +#define lua_pushliteral(L, s) \ + lua_pushlstring(L, "" s, (sizeof(s)/sizeof(char))-1) + +#define lua_setglobal(L,s) lua_setfield(L, LUA_GLOBALSINDEX, (s)) +#define lua_getglobal(L,s) lua_getfield(L, LUA_GLOBALSINDEX, (s)) + +#define lua_tostring(L,i) lua_tolstring(L, (i), NULL) + + + +/* +** compatibility macros and functions +*/ + +#define lua_open() luaL_newstate() + +#define lua_getregistry(L) lua_pushvalue(L, LUA_REGISTRYINDEX) + +#define lua_getgccount(L) lua_gc(L, LUA_GCCOUNT, 0) + +#define lua_Chunkreader lua_Reader +#define lua_Chunkwriter lua_Writer + + +/* hack */ +LUA_API void lua_setlevel (lua_State *from, lua_State *to); + + +/* +** {====================================================================== +** Debug API +** ======================================================================= +*/ + + +/* +** Event codes +*/ +#define LUA_HOOKCALL 0 +#define LUA_HOOKRET 1 +#define LUA_HOOKLINE 2 +#define LUA_HOOKCOUNT 3 +#define LUA_HOOKTAILRET 4 + + +/* +** Event masks +*/ +#define LUA_MASKCALL (1 << LUA_HOOKCALL) +#define LUA_MASKRET (1 << LUA_HOOKRET) +#define LUA_MASKLINE (1 << LUA_HOOKLINE) +#define LUA_MASKCOUNT (1 << LUA_HOOKCOUNT) + +typedef struct lua_Debug lua_Debug; /* activation record */ + + +/* Functions to be called by the debuger in specific events */ +typedef void (*lua_Hook) (lua_State *L, lua_Debug *ar); + + +LUA_API int lua_getstack (lua_State *L, int level, lua_Debug *ar); +LUA_API int lua_getinfo (lua_State *L, const char *what, lua_Debug *ar); +LUA_API const char *lua_getlocal (lua_State *L, const lua_Debug *ar, int n); +LUA_API const char *lua_setlocal (lua_State *L, const lua_Debug *ar, int n); +LUA_API const char *lua_getupvalue (lua_State *L, int funcindex, int n); +LUA_API const char *lua_setupvalue (lua_State *L, int funcindex, int n); +LUA_API int lua_sethook (lua_State *L, lua_Hook func, int mask, int count); +LUA_API lua_Hook lua_gethook (lua_State *L); +LUA_API int lua_gethookmask (lua_State *L); +LUA_API int lua_gethookcount (lua_State *L); + +/* From Lua 5.2. */ +LUA_API void *lua_upvalueid (lua_State *L, int idx, int n); +LUA_API void lua_upvaluejoin (lua_State *L, int idx1, int n1, int idx2, int n2); +LUA_API int lua_loadx (lua_State *L, lua_Reader reader, void *dt, + const char *chunkname, const char *mode); +LUA_API const lua_Number *lua_version (lua_State *L); +LUA_API void lua_copy (lua_State *L, int fromidx, int toidx); +LUA_API lua_Number lua_tonumberx (lua_State *L, int idx, int *isnum); +LUA_API lua_Integer lua_tointegerx (lua_State *L, int idx, int *isnum); + +/* From Lua 5.3. */ +LUA_API int lua_isyieldable (lua_State *L); + + +struct lua_Debug { + int event; + const char *name; /* (n) */ + const char *namewhat; /* (n) `global', `local', `field', `method' */ + const char *what; /* (S) `Lua', `C', `main', `tail' */ + const char *source; /* (S) */ + int currentline; /* (l) */ + int nups; /* (u) number of upvalues */ + int linedefined; /* (S) */ + int lastlinedefined; /* (S) */ + char short_src[LUA_IDSIZE]; /* (S) */ + /* private part */ + int i_ci; /* active function */ +}; + +/* }====================================================================== */ + + +/****************************************************************************** +* Copyright (C) 1994-2008 Lua.org, PUC-Rio. All rights reserved. +* +* Permission is hereby granted, free of charge, to any person obtaining +* a copy of this software and associated documentation files (the +* "Software"), to deal in the Software without restriction, including +* without limitation the rights to use, copy, modify, merge, publish, +* distribute, sublicense, and/or sell copies of the Software, and to +* permit persons to whom the Software is furnished to do so, subject to +* the following conditions: +* +* The above copyright notice and this permission notice shall be +* included in all copies or substantial portions of the Software. +* +* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, +* EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF +* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. +* IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY +* CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, +* TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE +* SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. +******************************************************************************/ + + +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/lua.hpp b/fluent-bit/lib/luajit-3065c9/src/lua.hpp new file mode 100644 index 00000000..07e9002d --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lua.hpp @@ -0,0 +1,9 @@ +// C++ wrapper for LuaJIT header files. + +extern "C" { +#include "lua.h" +#include "lauxlib.h" +#include "lualib.h" +#include "luajit.h" +} + diff --git a/fluent-bit/lib/luajit-3065c9/src/luaconf.h b/fluent-bit/lib/luajit-3065c9/src/luaconf.h new file mode 100644 index 00000000..e8790c1d --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/luaconf.h @@ -0,0 +1,152 @@ +/* +** Configuration header. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#ifndef luaconf_h +#define luaconf_h + +#ifndef WINVER +#define WINVER 0x0501 +#endif +#include +#include + +/* Default path for loading Lua and C modules with require(). */ +#if defined(_WIN32) +/* +** In Windows, any exclamation mark ('!') in the path is replaced by the +** path of the directory of the executable file of the current process. +*/ +#define LUA_LDIR "!\\lua\\" +#define LUA_CDIR "!\\" +#define LUA_PATH_DEFAULT \ + ".\\?.lua;" LUA_LDIR"?.lua;" LUA_LDIR"?\\init.lua;" +#define LUA_CPATH_DEFAULT \ + ".\\?.dll;" LUA_CDIR"?.dll;" LUA_CDIR"loadall.dll" +#else +/* +** Note to distribution maintainers: do NOT patch the following lines! +** Please read ../doc/install.html#distro and pass PREFIX=/usr instead. +*/ +#ifndef LUA_MULTILIB +#define LUA_MULTILIB "lib" +#endif +#ifndef LUA_LMULTILIB +#define LUA_LMULTILIB "lib" +#endif +#define LUA_LROOT "/usr/local" +#define LUA_LUADIR "/lua/5.1/" +#define LUA_LJDIR "/luajit-2.1.0-beta3/" + +#ifdef LUA_ROOT +#define LUA_JROOT LUA_ROOT +#define LUA_RLDIR LUA_ROOT "/share" LUA_LUADIR +#define LUA_RCDIR LUA_ROOT "/" LUA_MULTILIB LUA_LUADIR +#define LUA_RLPATH ";" LUA_RLDIR "?.lua;" LUA_RLDIR "?/init.lua" +#define LUA_RCPATH ";" LUA_RCDIR "?.so" +#else +#define LUA_JROOT LUA_LROOT +#define LUA_RLPATH +#define LUA_RCPATH +#endif + +#define LUA_JPATH ";" LUA_JROOT "/share" LUA_LJDIR "?.lua" +#define LUA_LLDIR LUA_LROOT "/share" LUA_LUADIR +#define LUA_LCDIR LUA_LROOT "/" LUA_LMULTILIB LUA_LUADIR +#define LUA_LLPATH ";" LUA_LLDIR "?.lua;" LUA_LLDIR "?/init.lua" +#define LUA_LCPATH1 ";" LUA_LCDIR "?.so" +#define LUA_LCPATH2 ";" LUA_LCDIR "loadall.so" + +#define LUA_PATH_DEFAULT "./?.lua" LUA_JPATH LUA_LLPATH LUA_RLPATH +#define LUA_CPATH_DEFAULT "./?.so" LUA_LCPATH1 LUA_RCPATH LUA_LCPATH2 +#endif + +/* Environment variable names for path overrides and initialization code. */ +#define LUA_PATH "LUA_PATH" +#define LUA_CPATH "LUA_CPATH" +#define LUA_INIT "LUA_INIT" + +/* Special file system characters. */ +#if defined(_WIN32) +#define LUA_DIRSEP "\\" +#else +#define LUA_DIRSEP "/" +#endif +#define LUA_PATHSEP ";" +#define LUA_PATH_MARK "?" +#define LUA_EXECDIR "!" +#define LUA_IGMARK "-" +#define LUA_PATH_CONFIG \ + LUA_DIRSEP "\n" LUA_PATHSEP "\n" LUA_PATH_MARK "\n" \ + LUA_EXECDIR "\n" LUA_IGMARK "\n" + +/* Quoting in error messages. */ +#define LUA_QL(x) "'" x "'" +#define LUA_QS LUA_QL("%s") + +/* Various tunables. */ +#define LUAI_MAXSTACK 65500 /* Max. # of stack slots for a thread (<64K). */ +#define LUAI_MAXCSTACK 8000 /* Max. # of stack slots for a C func (<10K). */ +#define LUAI_GCPAUSE 200 /* Pause GC until memory is at 200%. */ +#define LUAI_GCMUL 200 /* Run GC at 200% of allocation speed. */ +#define LUA_MAXCAPTURES 32 /* Max. pattern captures. */ + +/* Configuration for the frontend (the luajit executable). */ +#if defined(luajit_c) +#define LUA_PROGNAME "luajit" /* Fallback frontend name. */ +#define LUA_PROMPT "> " /* Interactive prompt. */ +#define LUA_PROMPT2 ">> " /* Continuation prompt. */ +#define LUA_MAXINPUT 512 /* Max. input line length. */ +#endif + +/* Note: changing the following defines breaks the Lua 5.1 ABI. */ +#define LUA_INTEGER ptrdiff_t +#define LUA_IDSIZE 60 /* Size of lua_Debug.short_src. */ +/* +** Size of lauxlib and io.* on-stack buffers. Weird workaround to avoid using +** unreasonable amounts of stack space, but still retain ABI compatibility. +** Blame Lua for depending on BUFSIZ in the ABI, blame **** for wrecking it. +*/ +#define LUAL_BUFFERSIZE (BUFSIZ > 16384 ? 8192 : BUFSIZ) + +/* The following defines are here only for compatibility with luaconf.h +** from the standard Lua distribution. They must not be changed for LuaJIT. +*/ +#define LUA_NUMBER_DOUBLE +#define LUA_NUMBER double +#define LUAI_UACNUMBER double +#define LUA_NUMBER_SCAN "%lf" +#define LUA_NUMBER_FMT "%.14g" +#define lua_number2str(s, n) sprintf((s), LUA_NUMBER_FMT, (n)) +#define LUAI_MAXNUMBER2STR 32 +#define LUA_INTFRMLEN "l" +#define LUA_INTFRM_T long + +/* Linkage of public API functions. */ +#if defined(LUA_BUILD_AS_DLL) +#if defined(LUA_CORE) || defined(LUA_LIB) +#define LUA_API __declspec(dllexport) +#else +#define LUA_API __declspec(dllimport) +#endif +#else +#define LUA_API extern +#endif + +#define LUALIB_API LUA_API + +/* Compatibility support for assertions. */ +#if defined(LUA_USE_ASSERT) || defined(LUA_USE_APICHECK) +#include +#endif +#ifdef LUA_USE_ASSERT +#define lua_assert(x) assert(x) +#endif +#ifdef LUA_USE_APICHECK +#define luai_apicheck(L, o) { (void)L; assert(o); } +#else +#define luai_apicheck(L, o) { (void)L; } +#endif + +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/luajit.c b/fluent-bit/lib/luajit-3065c9/src/luajit.c new file mode 100644 index 00000000..6dd64026 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/luajit.c @@ -0,0 +1,586 @@ +/* +** LuaJIT frontend. Runs commands, scripts, read-eval-print (REPL) etc. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +** +** Major portions taken verbatim or adapted from the Lua interpreter. +** Copyright (C) 1994-2008 Lua.org, PUC-Rio. See Copyright Notice in lua.h +*/ + +#include +#include +#include + +#define luajit_c + +#include "lua.h" +#include "lauxlib.h" +#include "lualib.h" +#include "luajit.h" + +#include "lj_arch.h" + +#if LJ_TARGET_POSIX +#include +#define lua_stdin_is_tty() isatty(0) +#elif LJ_TARGET_WINDOWS +#include +#ifdef __BORLANDC__ +#define lua_stdin_is_tty() isatty(_fileno(stdin)) +#else +#define lua_stdin_is_tty() _isatty(_fileno(stdin)) +#endif +#else +#define lua_stdin_is_tty() 1 +#endif + +#if !LJ_TARGET_CONSOLE +#include +#endif + +static lua_State *globalL = NULL; +static const char *progname = LUA_PROGNAME; +static char *empty_argv[2] = { NULL, NULL }; + +#if !LJ_TARGET_CONSOLE +static void lstop(lua_State *L, lua_Debug *ar) +{ + (void)ar; /* unused arg. */ + lua_sethook(L, NULL, 0, 0); + /* Avoid luaL_error -- a C hook doesn't add an extra frame. */ + luaL_where(L, 0); + lua_pushfstring(L, "%sinterrupted!", lua_tostring(L, -1)); + lua_error(L); +} + +static void laction(int i) +{ + signal(i, SIG_DFL); /* if another SIGINT happens before lstop, + terminate process (default action) */ + lua_sethook(globalL, lstop, LUA_MASKCALL | LUA_MASKRET | LUA_MASKCOUNT, 1); +} +#endif + +static void print_usage(void) +{ + fputs("usage: ", stderr); + fputs(progname, stderr); + fputs(" [options]... [script [args]...].\n" + "Available options are:\n" + " -e chunk Execute string " LUA_QL("chunk") ".\n" + " -l name Require library " LUA_QL("name") ".\n" + " -b ... Save or list bytecode.\n" + " -j cmd Perform LuaJIT control command.\n" + " -O[opt] Control LuaJIT optimizations.\n" + " -i Enter interactive mode after executing " LUA_QL("script") ".\n" + " -v Show version information.\n" + " -E Ignore environment variables.\n" + " -- Stop handling options.\n" + " - Execute stdin and stop handling options.\n", stderr); + fflush(stderr); +} + +static void l_message(const char *msg) +{ + if (progname) { fputs(progname, stderr); fputc(':', stderr); fputc(' ', stderr); } + fputs(msg, stderr); fputc('\n', stderr); + fflush(stderr); +} + +static int report(lua_State *L, int status) +{ + if (status && !lua_isnil(L, -1)) { + const char *msg = lua_tostring(L, -1); + if (msg == NULL) msg = "(error object is not a string)"; + l_message(msg); + lua_pop(L, 1); + } + return status; +} + +static int traceback(lua_State *L) +{ + if (!lua_isstring(L, 1)) { /* Non-string error object? Try metamethod. */ + if (lua_isnoneornil(L, 1) || + !luaL_callmeta(L, 1, "__tostring") || + !lua_isstring(L, -1)) + return 1; /* Return non-string error object. */ + lua_remove(L, 1); /* Replace object by result of __tostring metamethod. */ + } + luaL_traceback(L, L, lua_tostring(L, 1), 1); + return 1; +} + +static int docall(lua_State *L, int narg, int clear) +{ + int status; + int base = lua_gettop(L) - narg; /* function index */ + lua_pushcfunction(L, traceback); /* push traceback function */ + lua_insert(L, base); /* put it under chunk and args */ +#if !LJ_TARGET_CONSOLE + signal(SIGINT, laction); +#endif + status = lua_pcall(L, narg, (clear ? 0 : LUA_MULTRET), base); +#if !LJ_TARGET_CONSOLE + signal(SIGINT, SIG_DFL); +#endif + lua_remove(L, base); /* remove traceback function */ + /* force a complete garbage collection in case of errors */ + if (status != LUA_OK) lua_gc(L, LUA_GCCOLLECT, 0); + return status; +} + +static void print_version(void) +{ + fputs(LUAJIT_VERSION " -- " LUAJIT_COPYRIGHT ". " LUAJIT_URL "\n", stdout); +} + +static void print_jit_status(lua_State *L) +{ + int n; + const char *s; + lua_getfield(L, LUA_REGISTRYINDEX, "_LOADED"); + lua_getfield(L, -1, "jit"); /* Get jit.* module table. */ + lua_remove(L, -2); + lua_getfield(L, -1, "status"); + lua_remove(L, -2); + n = lua_gettop(L); + lua_call(L, 0, LUA_MULTRET); + fputs(lua_toboolean(L, n) ? "JIT: ON" : "JIT: OFF", stdout); + for (n++; (s = lua_tostring(L, n)); n++) { + putc(' ', stdout); + fputs(s, stdout); + } + putc('\n', stdout); + lua_settop(L, 0); /* clear stack */ +} + +static void createargtable(lua_State *L, char **argv, int argc, int argf) +{ + int i; + lua_createtable(L, argc - argf, argf); + for (i = 0; i < argc; i++) { + lua_pushstring(L, argv[i]); + lua_rawseti(L, -2, i - argf); + } + lua_setglobal(L, "arg"); +} + +static int dofile(lua_State *L, const char *name) +{ + int status = luaL_loadfile(L, name) || docall(L, 0, 1); + return report(L, status); +} + +static int dostring(lua_State *L, const char *s, const char *name) +{ + int status = luaL_loadbuffer(L, s, strlen(s), name) || docall(L, 0, 1); + return report(L, status); +} + +static int dolibrary(lua_State *L, const char *name) +{ + lua_getglobal(L, "require"); + lua_pushstring(L, name); + return report(L, docall(L, 1, 1)); +} + +static void write_prompt(lua_State *L, int firstline) +{ + const char *p; + lua_getfield(L, LUA_GLOBALSINDEX, firstline ? "_PROMPT" : "_PROMPT2"); + p = lua_tostring(L, -1); + if (p == NULL) p = firstline ? LUA_PROMPT : LUA_PROMPT2; + fputs(p, stdout); + fflush(stdout); + lua_pop(L, 1); /* remove global */ +} + +static int incomplete(lua_State *L, int status) +{ + if (status == LUA_ERRSYNTAX) { + size_t lmsg; + const char *msg = lua_tolstring(L, -1, &lmsg); + const char *tp = msg + lmsg - (sizeof(LUA_QL("")) - 1); + if (strstr(msg, LUA_QL("")) == tp) { + lua_pop(L, 1); + return 1; + } + } + return 0; /* else... */ +} + +static int pushline(lua_State *L, int firstline) +{ + char buf[LUA_MAXINPUT]; + write_prompt(L, firstline); + if (fgets(buf, LUA_MAXINPUT, stdin)) { + size_t len = strlen(buf); + if (len > 0 && buf[len-1] == '\n') + buf[len-1] = '\0'; + if (firstline && buf[0] == '=') + lua_pushfstring(L, "return %s", buf+1); + else + lua_pushstring(L, buf); + return 1; + } + return 0; +} + +static int loadline(lua_State *L) +{ + int status; + lua_settop(L, 0); + if (!pushline(L, 1)) + return -1; /* no input */ + for (;;) { /* repeat until gets a complete line */ + status = luaL_loadbuffer(L, lua_tostring(L, 1), lua_strlen(L, 1), "=stdin"); + if (!incomplete(L, status)) break; /* cannot try to add lines? */ + if (!pushline(L, 0)) /* no more input? */ + return -1; + lua_pushliteral(L, "\n"); /* add a new line... */ + lua_insert(L, -2); /* ...between the two lines */ + lua_concat(L, 3); /* join them */ + } + lua_remove(L, 1); /* remove line */ + return status; +} + +static void dotty(lua_State *L) +{ + int status; + const char *oldprogname = progname; + progname = NULL; + while ((status = loadline(L)) != -1) { + if (status == LUA_OK) status = docall(L, 0, 0); + report(L, status); + if (status == LUA_OK && lua_gettop(L) > 0) { /* any result to print? */ + lua_getglobal(L, "print"); + lua_insert(L, 1); + if (lua_pcall(L, lua_gettop(L)-1, 0, 0) != 0) + l_message(lua_pushfstring(L, "error calling " LUA_QL("print") " (%s)", + lua_tostring(L, -1))); + } + } + lua_settop(L, 0); /* clear stack */ + fputs("\n", stdout); + fflush(stdout); + progname = oldprogname; +} + +static int handle_script(lua_State *L, char **argx) +{ + int status; + const char *fname = argx[0]; + if (strcmp(fname, "-") == 0 && strcmp(argx[-1], "--") != 0) + fname = NULL; /* stdin */ + status = luaL_loadfile(L, fname); + if (status == LUA_OK) { + /* Fetch args from arg table. LUA_INIT or -e might have changed them. */ + int narg = 0; + lua_getglobal(L, "arg"); + if (lua_istable(L, -1)) { + do { + narg++; + lua_rawgeti(L, -narg, narg); + } while (!lua_isnil(L, -1)); + lua_pop(L, 1); + lua_remove(L, -narg); + narg--; + } else { + lua_pop(L, 1); + } + status = docall(L, narg, 0); + } + return report(L, status); +} + +/* Load add-on module. */ +static int loadjitmodule(lua_State *L) +{ + lua_getglobal(L, "require"); + lua_pushliteral(L, "jit."); + lua_pushvalue(L, -3); + lua_concat(L, 2); + if (lua_pcall(L, 1, 1, 0)) { + const char *msg = lua_tostring(L, -1); + if (msg && !strncmp(msg, "module ", 7)) + goto nomodule; + return report(L, 1); + } + lua_getfield(L, -1, "start"); + if (lua_isnil(L, -1)) { + nomodule: + l_message("unknown luaJIT command or jit.* modules not installed"); + return 1; + } + lua_remove(L, -2); /* Drop module table. */ + return 0; +} + +/* Run command with options. */ +static int runcmdopt(lua_State *L, const char *opt) +{ + int narg = 0; + if (opt && *opt) { + for (;;) { /* Split arguments. */ + const char *p = strchr(opt, ','); + narg++; + if (!p) break; + if (p == opt) + lua_pushnil(L); + else + lua_pushlstring(L, opt, (size_t)(p - opt)); + opt = p + 1; + } + if (*opt) + lua_pushstring(L, opt); + else + lua_pushnil(L); + } + return report(L, lua_pcall(L, narg, 0, 0)); +} + +/* JIT engine control command: try jit library first or load add-on module. */ +static int dojitcmd(lua_State *L, const char *cmd) +{ + const char *opt = strchr(cmd, '='); + lua_pushlstring(L, cmd, opt ? (size_t)(opt - cmd) : strlen(cmd)); + lua_getfield(L, LUA_REGISTRYINDEX, "_LOADED"); + lua_getfield(L, -1, "jit"); /* Get jit.* module table. */ + lua_remove(L, -2); + lua_pushvalue(L, -2); + lua_gettable(L, -2); /* Lookup library function. */ + if (!lua_isfunction(L, -1)) { + lua_pop(L, 2); /* Drop non-function and jit.* table, keep module name. */ + if (loadjitmodule(L)) + return 1; + } else { + lua_remove(L, -2); /* Drop jit.* table. */ + } + lua_remove(L, -2); /* Drop module name. */ + return runcmdopt(L, opt ? opt+1 : opt); +} + +/* Optimization flags. */ +static int dojitopt(lua_State *L, const char *opt) +{ + lua_getfield(L, LUA_REGISTRYINDEX, "_LOADED"); + lua_getfield(L, -1, "jit.opt"); /* Get jit.opt.* module table. */ + lua_remove(L, -2); + lua_getfield(L, -1, "start"); + lua_remove(L, -2); + return runcmdopt(L, opt); +} + +/* Save or list bytecode. */ +static int dobytecode(lua_State *L, char **argv) +{ + int narg = 0; + lua_pushliteral(L, "bcsave"); + if (loadjitmodule(L)) + return 1; + if (argv[0][2]) { + narg++; + argv[0][1] = '-'; + lua_pushstring(L, argv[0]+1); + } + for (argv++; *argv != NULL; narg++, argv++) + lua_pushstring(L, *argv); + report(L, lua_pcall(L, narg, 0, 0)); + return -1; +} + +/* check that argument has no extra characters at the end */ +#define notail(x) {if ((x)[2] != '\0') return -1;} + +#define FLAGS_INTERACTIVE 1 +#define FLAGS_VERSION 2 +#define FLAGS_EXEC 4 +#define FLAGS_OPTION 8 +#define FLAGS_NOENV 16 + +static int collectargs(char **argv, int *flags) +{ + int i; + for (i = 1; argv[i] != NULL; i++) { + if (argv[i][0] != '-') /* Not an option? */ + return i; + switch (argv[i][1]) { /* Check option. */ + case '-': + notail(argv[i]); + return i+1; + case '\0': + return i; + case 'i': + notail(argv[i]); + *flags |= FLAGS_INTERACTIVE; + /* fallthrough */ + case 'v': + notail(argv[i]); + *flags |= FLAGS_VERSION; + break; + case 'e': + *flags |= FLAGS_EXEC; + /* fallthrough */ + case 'j': /* LuaJIT extension */ + case 'l': + *flags |= FLAGS_OPTION; + if (argv[i][2] == '\0') { + i++; + if (argv[i] == NULL) return -1; + } + break; + case 'O': break; /* LuaJIT extension */ + case 'b': /* LuaJIT extension */ + if (*flags) return -1; + *flags |= FLAGS_EXEC; + return i+1; + case 'E': + *flags |= FLAGS_NOENV; + break; + default: return -1; /* invalid option */ + } + } + return i; +} + +static int runargs(lua_State *L, char **argv, int argn) +{ + int i; + for (i = 1; i < argn; i++) { + if (argv[i] == NULL) continue; + lua_assert(argv[i][0] == '-'); + switch (argv[i][1]) { + case 'e': { + const char *chunk = argv[i] + 2; + if (*chunk == '\0') chunk = argv[++i]; + lua_assert(chunk != NULL); + if (dostring(L, chunk, "=(command line)") != 0) + return 1; + break; + } + case 'l': { + const char *filename = argv[i] + 2; + if (*filename == '\0') filename = argv[++i]; + lua_assert(filename != NULL); + if (dolibrary(L, filename)) + return 1; + break; + } + case 'j': { /* LuaJIT extension. */ + const char *cmd = argv[i] + 2; + if (*cmd == '\0') cmd = argv[++i]; + lua_assert(cmd != NULL); + if (dojitcmd(L, cmd)) + return 1; + break; + } + case 'O': /* LuaJIT extension. */ + if (dojitopt(L, argv[i] + 2)) + return 1; + break; + case 'b': /* LuaJIT extension. */ + return dobytecode(L, argv+i); + default: break; + } + } + return LUA_OK; +} + +static int handle_luainit(lua_State *L) +{ +#if LJ_TARGET_CONSOLE + const char *init = NULL; +#else + const char *init = getenv(LUA_INIT); +#endif + if (init == NULL) + return LUA_OK; + else if (init[0] == '@') + return dofile(L, init+1); + else + return dostring(L, init, "=" LUA_INIT); +} + +static struct Smain { + char **argv; + int argc; + int status; +} smain; + +static int pmain(lua_State *L) +{ + struct Smain *s = &smain; + char **argv = s->argv; + int argn; + int flags = 0; + globalL = L; + LUAJIT_VERSION_SYM(); /* Linker-enforced version check. */ + + argn = collectargs(argv, &flags); + if (argn < 0) { /* Invalid args? */ + print_usage(); + s->status = 1; + return 0; + } + + if ((flags & FLAGS_NOENV)) { + lua_pushboolean(L, 1); + lua_setfield(L, LUA_REGISTRYINDEX, "LUA_NOENV"); + } + + /* Stop collector during library initialization. */ + lua_gc(L, LUA_GCSTOP, 0); + luaL_openlibs(L); + lua_gc(L, LUA_GCRESTART, -1); + + createargtable(L, argv, s->argc, argn); + + if (!(flags & FLAGS_NOENV)) { + s->status = handle_luainit(L); + if (s->status != LUA_OK) return 0; + } + + if ((flags & FLAGS_VERSION)) print_version(); + + s->status = runargs(L, argv, argn); + if (s->status != LUA_OK) return 0; + + if (s->argc > argn) { + s->status = handle_script(L, argv + argn); + if (s->status != LUA_OK) return 0; + } + + if ((flags & FLAGS_INTERACTIVE)) { + print_jit_status(L); + dotty(L); + } else if (s->argc == argn && !(flags & (FLAGS_EXEC|FLAGS_VERSION))) { + if (lua_stdin_is_tty()) { + print_version(); + print_jit_status(L); + dotty(L); + } else { + dofile(L, NULL); /* Executes stdin as a file. */ + } + } + return 0; +} + +int main(int argc, char **argv) +{ + int status; + lua_State *L; + if (!argv[0]) argv = empty_argv; else if (argv[0][0]) progname = argv[0]; + L = lua_open(); + if (L == NULL) { + l_message("cannot create state: not enough memory"); + return EXIT_FAILURE; + } + smain.argc = argc; + smain.argv = argv; + status = lua_cpcall(L, pmain, NULL); + report(L, status); + lua_close(L); + return (status || smain.status > 0) ? EXIT_FAILURE : EXIT_SUCCESS; +} + diff --git a/fluent-bit/lib/luajit-3065c9/src/luajit.h b/fluent-bit/lib/luajit-3065c9/src/luajit.h new file mode 100644 index 00000000..31f1eb1f --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/luajit.h @@ -0,0 +1,79 @@ +/* +** LuaJIT -- a Just-In-Time Compiler for Lua. https://luajit.org/ +** +** Copyright (C) 2005-2022 Mike Pall. All rights reserved. +** +** Permission is hereby granted, free of charge, to any person obtaining +** a copy of this software and associated documentation files (the +** "Software"), to deal in the Software without restriction, including +** without limitation the rights to use, copy, modify, merge, publish, +** distribute, sublicense, and/or sell copies of the Software, and to +** permit persons to whom the Software is furnished to do so, subject to +** the following conditions: +** +** The above copyright notice and this permission notice shall be +** included in all copies or substantial portions of the Software. +** +** THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, +** EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF +** MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. +** IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY +** CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, +** TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE +** SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. +** +** [ MIT license: https://www.opensource.org/licenses/mit-license.php ] +*/ + +#ifndef _LUAJIT_H +#define _LUAJIT_H + +#include "lua.h" + +#define LUAJIT_VERSION "LuaJIT 2.1.0-beta3" +#define LUAJIT_VERSION_NUM 20100 /* Version 2.1.0 = 02.01.00. */ +#define LUAJIT_VERSION_SYM luaJIT_version_2_1_0_beta3 +#define LUAJIT_COPYRIGHT "Copyright (C) 2005-2022 Mike Pall" +#define LUAJIT_URL "https://luajit.org/" + +/* Modes for luaJIT_setmode. */ +#define LUAJIT_MODE_MASK 0x00ff + +enum { + LUAJIT_MODE_ENGINE, /* Set mode for whole JIT engine. */ + LUAJIT_MODE_DEBUG, /* Set debug mode (idx = level). */ + + LUAJIT_MODE_FUNC, /* Change mode for a function. */ + LUAJIT_MODE_ALLFUNC, /* Recurse into subroutine protos. */ + LUAJIT_MODE_ALLSUBFUNC, /* Change only the subroutines. */ + + LUAJIT_MODE_TRACE, /* Flush a compiled trace. */ + + LUAJIT_MODE_WRAPCFUNC = 0x10, /* Set wrapper mode for C function calls. */ + + LUAJIT_MODE_MAX +}; + +/* Flags or'ed in to the mode. */ +#define LUAJIT_MODE_OFF 0x0000 /* Turn feature off. */ +#define LUAJIT_MODE_ON 0x0100 /* Turn feature on. */ +#define LUAJIT_MODE_FLUSH 0x0200 /* Flush JIT-compiled code. */ + +/* LuaJIT public C API. */ + +/* Control the JIT engine. */ +LUA_API int luaJIT_setmode(lua_State *L, int idx, int mode); + +/* Low-overhead profiling API. */ +typedef void (*luaJIT_profile_callback)(void *data, lua_State *L, + int samples, int vmstate); +LUA_API void luaJIT_profile_start(lua_State *L, const char *mode, + luaJIT_profile_callback cb, void *data); +LUA_API void luaJIT_profile_stop(lua_State *L); +LUA_API const char *luaJIT_profile_dumpstack(lua_State *L, const char *fmt, + int depth, size_t *len); + +/* Enforce (dynamic) linker error for version mismatches. Call from main. */ +LUA_API void LUAJIT_VERSION_SYM(void); + +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/lualib.h b/fluent-bit/lib/luajit-3065c9/src/lualib.h new file mode 100644 index 00000000..87748456 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/lualib.h @@ -0,0 +1,44 @@ +/* +** Standard library header. +** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +*/ + +#ifndef _LUALIB_H +#define _LUALIB_H + +#include "lua.h" + +#define LUA_FILEHANDLE "FILE*" + +#define LUA_COLIBNAME "coroutine" +#define LUA_MATHLIBNAME "math" +#define LUA_STRLIBNAME "string" +#define LUA_TABLIBNAME "table" +#define LUA_IOLIBNAME "io" +#define LUA_OSLIBNAME "os" +#define LUA_LOADLIBNAME "package" +#define LUA_DBLIBNAME "debug" +#define LUA_BITLIBNAME "bit" +#define LUA_JITLIBNAME "jit" +#define LUA_FFILIBNAME "ffi" + +LUALIB_API int luaopen_base(lua_State *L); +LUALIB_API int luaopen_math(lua_State *L); +LUALIB_API int luaopen_string(lua_State *L); +LUALIB_API int luaopen_table(lua_State *L); +LUALIB_API int luaopen_io(lua_State *L); +LUALIB_API int luaopen_os(lua_State *L); +LUALIB_API int luaopen_package(lua_State *L); +LUALIB_API int luaopen_debug(lua_State *L); +LUALIB_API int luaopen_bit(lua_State *L); +LUALIB_API int luaopen_jit(lua_State *L); +LUALIB_API int luaopen_ffi(lua_State *L); +LUALIB_API int luaopen_string_buffer(lua_State *L); + +LUALIB_API void luaL_openlibs(lua_State *L); + +#ifndef lua_assert +#define lua_assert(x) ((void)0) +#endif + +#endif diff --git a/fluent-bit/lib/luajit-3065c9/src/msvcbuild.bat b/fluent-bit/lib/luajit-3065c9/src/msvcbuild.bat new file mode 100644 index 00000000..d323d8d4 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/msvcbuild.bat @@ -0,0 +1,127 @@ +@rem Script to build LuaJIT with MSVC. +@rem Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +@rem +@rem Open a "Visual Studio Command Prompt" (either x86 or x64). +@rem Then cd to this directory and run this script. Use the following +@rem options (in order), if needed. The default is a dynamic release build. +@rem +@rem nogc64 disable LJ_GC64 mode for x64 +@rem debug emit debug symbols +@rem amalg amalgamated build +@rem static static linkage + +@if not defined INCLUDE goto :FAIL + +@setlocal +@rem Add more debug flags here, e.g. DEBUGCFLAGS=/DLUA_USE_APICHECK +@set DEBUGCFLAGS= +@set LJCOMPILE=cl /nologo /c /O2 /W3 /D_CRT_SECURE_NO_DEPRECATE /D_CRT_STDIO_INLINE=__declspec(dllexport)__inline +@set LJLINK=link /nologo +@set LJMT=mt /nologo +@set LJLIB=lib /nologo /nodefaultlib +@set DASMDIR=..\dynasm +@set DASM=%DASMDIR%\dynasm.lua +@set DASC=vm_x64.dasc +@set LJDLLNAME=lua51.dll +@set LJLIBNAME=lua51.lib +@set BUILDTYPE=release +@set ALL_LIB=lib_base.c lib_math.c lib_bit.c lib_string.c lib_table.c lib_io.c lib_os.c lib_package.c lib_debug.c lib_jit.c lib_ffi.c lib_buffer.c + +%LJCOMPILE% host\minilua.c +@if errorlevel 1 goto :BAD +%LJLINK% /out:minilua.exe minilua.obj +@if errorlevel 1 goto :BAD +if exist minilua.exe.manifest^ + %LJMT% -manifest minilua.exe.manifest -outputresource:minilua.exe + +@set DASMFLAGS=-D WIN -D JIT -D FFI -D P64 +@set LJARCH=x64 +@minilua +@if errorlevel 8 goto :X64 +@set DASC=vm_x86.dasc +@set DASMFLAGS=-D WIN -D JIT -D FFI +@set LJARCH=x86 +@set LJCOMPILE=%LJCOMPILE% /arch:SSE2 +:X64 +@if "%1" neq "nogc64" goto :GC64 +@shift +@set DASC=vm_x86.dasc +@set LJCOMPILE=%LJCOMPILE% /DLUAJIT_DISABLE_GC64 +:GC64 +minilua %DASM% -LN %DASMFLAGS% -o host\buildvm_arch.h %DASC% +@if errorlevel 1 goto :BAD + +%LJCOMPILE% /I "." /I %DASMDIR% host\buildvm*.c +@if errorlevel 1 goto :BAD +%LJLINK% /out:buildvm.exe buildvm*.obj +@if errorlevel 1 goto :BAD +if exist buildvm.exe.manifest^ + %LJMT% -manifest buildvm.exe.manifest -outputresource:buildvm.exe + +buildvm -m peobj -o lj_vm.obj +@if errorlevel 1 goto :BAD +buildvm -m bcdef -o lj_bcdef.h %ALL_LIB% +@if errorlevel 1 goto :BAD +buildvm -m ffdef -o lj_ffdef.h %ALL_LIB% +@if errorlevel 1 goto :BAD +buildvm -m libdef -o lj_libdef.h %ALL_LIB% +@if errorlevel 1 goto :BAD +buildvm -m recdef -o lj_recdef.h %ALL_LIB% +@if errorlevel 1 goto :BAD +buildvm -m vmdef -o jit\vmdef.lua %ALL_LIB% +@if errorlevel 1 goto :BAD +buildvm -m folddef -o lj_folddef.h lj_opt_fold.c +@if errorlevel 1 goto :BAD + +@if "%1" neq "debug" goto :NODEBUG +@shift +@set BUILDTYPE=debug +@set LJCOMPILE=%LJCOMPILE% /Zi %DEBUGCFLAGS% +@set LJLINK=%LJLINK% /opt:ref /opt:icf /incremental:no +:NODEBUG +@set LJLINK=%LJLINK% /%BUILDTYPE% +@if "%1"=="amalg" goto :AMALGDLL +@if "%1"=="static" goto :STATIC +%LJCOMPILE% /MD /DLUA_BUILD_AS_DLL lj_*.c lib_*.c +@if errorlevel 1 goto :BAD +%LJLINK% /DLL /out:%LJDLLNAME% lj_*.obj lib_*.obj +@if errorlevel 1 goto :BAD +@goto :MTDLL +:STATIC +%LJCOMPILE% lj_*.c lib_*.c +@if errorlevel 1 goto :BAD +%LJLIB% /OUT:%LJLIBNAME% lj_*.obj lib_*.obj +@if errorlevel 1 goto :BAD +@goto :MTDLL +:AMALGDLL +%LJCOMPILE% /MD /DLUA_BUILD_AS_DLL ljamalg.c +@if errorlevel 1 goto :BAD +%LJLINK% /DLL /out:%LJDLLNAME% ljamalg.obj lj_vm.obj +@if errorlevel 1 goto :BAD +:MTDLL +if exist %LJDLLNAME%.manifest^ + %LJMT% -manifest %LJDLLNAME%.manifest -outputresource:%LJDLLNAME%;2 + +%LJCOMPILE% luajit.c +@if errorlevel 1 goto :BAD +%LJLINK% /out:luajit.exe luajit.obj %LJLIBNAME% +@if errorlevel 1 goto :BAD +if exist luajit.exe.manifest^ + %LJMT% -manifest luajit.exe.manifest -outputresource:luajit.exe + +@del *.obj *.manifest minilua.exe buildvm.exe +@del host\buildvm_arch.h +@del lj_bcdef.h lj_ffdef.h lj_libdef.h lj_recdef.h lj_folddef.h +@echo. +@echo === Successfully built LuaJIT for Windows/%LJARCH% === + +@goto :END +:BAD +@echo. +@echo ******************************************************* +@echo *** Build FAILED -- Please check the error messages *** +@echo ******************************************************* +@goto :END +:FAIL +@echo You must open a "Visual Studio Command Prompt" to run this script +:END diff --git a/fluent-bit/lib/luajit-3065c9/src/nxbuild.bat b/fluent-bit/lib/luajit-3065c9/src/nxbuild.bat new file mode 100644 index 00000000..c4a21f05 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/nxbuild.bat @@ -0,0 +1,159 @@ +@rem Script to build LuaJIT with NintendoSDK + NX Addon. +@rem Donated to the public domain by Swyter. +@rem +@rem To run this script you must open a "Native Tools Command Prompt for VS". +@rem +@rem Either the x86 version for NX32, or x64 for the NX64 target. +@rem This is because the pointer size of the LuaJIT host tools (buildvm.exe) +@rem must match the cross-compiled target (32 or 64 bits). +@rem +@rem Then cd to this directory and run this script. +@rem +@rem Recommended invocation: +@rem +@rem nxbuild # release build, amalgamated +@rem nxbuild debug # debug build, amalgamated +@rem +@rem Additional command-line options (not generally recommended): +@rem +@rem noamalg # (after debug) non-amalgamated build + +@if not defined INCLUDE goto :FAIL +@if not defined NINTENDO_SDK_ROOT goto :FAIL +@if not defined PLATFORM goto :FAIL + +@if "%platform%" == "x86" goto :DO_NX32 +@if "%platform%" == "x64" goto :DO_NX64 + +@echo Error: Current host platform is %platform%! +@echo. +@goto :FAIL + +@setlocal + +:DO_NX32 +@set DASC=vm_arm.dasc +@set DASMFLAGS= -D HFABI -D FPU +@set DASMTARGET= -D LUAJIT_TARGET=LUAJIT_ARCH_ARM +@set HOST_PTR_SIZE=4 +goto :BEGIN + +:DO_NX64 +@set DASC=vm_arm64.dasc +@set DASMFLAGS= -D ENDIAN_LE +@set DASMTARGET= -D LUAJIT_TARGET=LUAJIT_ARCH_ARM64 +@set HOST_PTR_SIZE=8 + +:BEGIN +@rem ---- Host compiler ---- +@set LJCOMPILE=cl /nologo /c /MD /O2 /W3 /wo4146 /wo4244 /D_CRT_SECURE_NO_DEPRECATE +@set LJLINK=link /nologo +@set LJMT=mt /nologo +@set DASMDIR=..\dynasm +@set DASM=%DASMDIR%\dynasm.lua +@set ALL_LIB=lib_base.c lib_math.c lib_bit.c lib_string.c lib_table.c lib_io.c lib_os.c lib_package.c lib_debug.c lib_jit.c lib_ffi.c lib_buffer.c + +%LJCOMPILE% host\minilua.c +@if errorlevel 1 goto :BAD +%LJLINK% /out:minilua.exe minilua.obj +@if errorlevel 1 goto :BAD +if exist minilua.exe.manifest^ + %LJMT% -manifest minilua.exe.manifest -outputresource:minilua.exe + +@rem Check that we have the right 32/64 bit host compiler to generate the right virtual machine files. +@minilua +@if "%ERRORLEVEL%" == "%HOST_PTR_SIZE%" goto :PASSED_PTR_CHECK + +@echo The pointer size of the host in bytes (%HOST_PTR_SIZE%) does not match the expected value (%errorlevel%). +@echo Check that the script is being ran under the correct x86/x64 VS prompt. +@goto :BAD + +:PASSED_PTR_CHECK +@set DASMFLAGS=%DASMFLAGS% %DASMTARGET% -D LJ_TARGET_NX -D LUAJIT_OS=LUAJIT_OS_OTHER -D LUAJIT_DISABLE_JIT -D LUAJIT_DISABLE_FFI +minilua %DASM% -LN %DASMFLAGS% -o host\buildvm_arch.h %DASC% +@if errorlevel 1 goto :BAD +%LJCOMPILE% /I "." /I %DASMDIR% %DASMTARGET% -D LJ_TARGET_NX -DLUAJIT_OS=LUAJIT_OS_OTHER -DLUAJIT_DISABLE_JIT -DLUAJIT_DISABLE_FFI host\buildvm*.c +@if errorlevel 1 goto :BAD +%LJLINK% /out:buildvm.exe buildvm*.obj +@if errorlevel 1 goto :BAD +if exist buildvm.exe.manifest^ + %LJMT% -manifest buildvm.exe.manifest -outputresource:buildvm.exe + +buildvm -m elfasm -o lj_vm.s +@if errorlevel 1 goto :BAD +buildvm -m bcdef -o lj_bcdef.h %ALL_LIB% +@if errorlevel 1 goto :BAD +buildvm -m ffdef -o lj_ffdef.h %ALL_LIB% +@if errorlevel 1 goto :BAD +buildvm -m libdef -o lj_libdef.h %ALL_LIB% +@if errorlevel 1 goto :BAD +buildvm -m recdef -o lj_recdef.h %ALL_LIB% +@if errorlevel 1 goto :BAD +buildvm -m vmdef -o jit\vmdef.lua %ALL_LIB% +@if errorlevel 1 goto :BAD +buildvm -m folddef -o lj_folddef.h lj_opt_fold.c +@if errorlevel 1 goto :BAD + +@rem ---- Cross compiler ---- +@if "%platform%" neq "x64" goto :NX32_CROSSBUILD +@set LJCOMPILE="%NINTENDO_SDK_ROOT%\Compilers\NX\nx\aarch64\bin\clang" -Wall -I%NINTENDO_SDK_ROOT%\Include %DASMTARGET% -DLUAJIT_OS=LUAJIT_OS_OTHER -DLUAJIT_DISABLE_JIT -DLUAJIT_DISABLE_FFI -DLUAJIT_USE_SYSMALLOC -c +@set LJLIB="%NINTENDO_SDK_ROOT%\Compilers\NX\nx\aarch64\bin\aarch64-nintendo-nx-elf-ar" rc +@set TARGETLIB_SUFFIX=nx64 + +%NINTENDO_SDK_ROOT%\Compilers\NX\nx\aarch64\bin\aarch64-nintendo-nx-elf-as -o lj_vm.o lj_vm.s +goto :DEBUGCHECK + +:NX32_CROSSBUILD +@set LJCOMPILE="%NINTENDO_SDK_ROOT%\Compilers\NX\nx\armv7l\bin\clang" -Wall -I%NINTENDO_SDK_ROOT%\Include %DASMTARGET% -DLUAJIT_OS=LUAJIT_OS_OTHER -DLUAJIT_DISABLE_JIT -DLUAJIT_DISABLE_FFI -DLUAJIT_USE_SYSMALLOC -c +@set LJLIB="%NINTENDO_SDK_ROOT%\Compilers\NX\nx\armv7l\bin\armv7l-nintendo-nx-eabihf-ar" rc +@set TARGETLIB_SUFFIX=nx32 + +%NINTENDO_SDK_ROOT%\Compilers\NX\nx\armv7l\bin\armv7l-nintendo-nx-eabihf-as -o lj_vm.o lj_vm.s +:DEBUGCHECK + +@if "%1" neq "debug" goto :NODEBUG +@shift +@set LJCOMPILE=%LJCOMPILE% -DNN_SDK_BUILD_DEBUG -g -O0 +@set TARGETLIB=libluajitD_%TARGETLIB_SUFFIX%.a +goto :BUILD +:NODEBUG +@set LJCOMPILE=%LJCOMPILE% -DNN_SDK_BUILD_RELEASE -O3 +@set TARGETLIB=libluajit_%TARGETLIB_SUFFIX%.a +:BUILD +del %TARGETLIB% +@if "%1" neq "noamalg" goto :AMALG +for %%f in (lj_*.c lib_*.c) do ( + %LJCOMPILE% %%f + @if errorlevel 1 goto :BAD +) + +%LJLIB% %TARGETLIB% lj_*.o lib_*.o +@if errorlevel 1 goto :BAD +@goto :NOAMALG +:AMALG +%LJCOMPILE% ljamalg.c +@if errorlevel 1 goto :BAD +%LJLIB% %TARGETLIB% ljamalg.o lj_vm.o +@if errorlevel 1 goto :BAD +:NOAMALG + +@del *.o *.obj *.manifest minilua.exe buildvm.exe +@echo. +@echo === Successfully built LuaJIT for Nintendo Switch (%TARGETLIB_SUFFIX%) === + +@goto :END +:BAD +@echo. +@echo ******************************************************* +@echo *** Build FAILED -- Please check the error messages *** +@echo ******************************************************* +@goto :END +:FAIL +@echo To run this script you must open a "Native Tools Command Prompt for VS". +@echo. +@echo Either the x86 version for NX32, or x64 for the NX64 target. +@echo This is because the pointer size of the LuaJIT host tools (buildvm.exe) +@echo must match the cross-compiled target (32 or 64 bits). +@echo. +@echo Keep in mind that NintendoSDK + NX Addon must be installed, too. +:END diff --git a/fluent-bit/lib/luajit-3065c9/src/ps4build.bat b/fluent-bit/lib/luajit-3065c9/src/ps4build.bat new file mode 100644 index 00000000..fdd09d81 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/ps4build.bat @@ -0,0 +1,123 @@ +@rem Script to build LuaJIT with the PS4 SDK. +@rem Donated to the public domain. +@rem +@rem Open a "Visual Studio .NET Command Prompt" (64 bit host compiler) +@rem or "VS2015 x64 Native Tools Command Prompt". +@rem +@rem Then cd to this directory and run this script. +@rem +@rem Recommended invocation: +@rem +@rem ps4build release build, amalgamated, 64-bit GC +@rem ps4build debug debug build, amalgamated, 64-bit GC +@rem +@rem Additional command-line options (not generally recommended): +@rem +@rem gc32 (before debug) 32-bit GC +@rem noamalg (after debug) non-amalgamated build + +@if not defined INCLUDE goto :FAIL +@if not defined SCE_ORBIS_SDK_DIR goto :FAIL + +@setlocal +@rem ---- Host compiler ---- +@set LJCOMPILE=cl /nologo /c /MD /O2 /W3 /D_CRT_SECURE_NO_DEPRECATE +@set LJLINK=link /nologo +@set LJMT=mt /nologo +@set DASMDIR=..\dynasm +@set DASM=%DASMDIR%\dynasm.lua +@set ALL_LIB=lib_base.c lib_math.c lib_bit.c lib_string.c lib_table.c lib_io.c lib_os.c lib_package.c lib_debug.c lib_jit.c lib_ffi.c lib_buffer.c +@set GC64= +@set DASC=vm_x64.dasc + +@if "%1" neq "gc32" goto :NOGC32 +@shift +@set GC64=-DLUAJIT_DISABLE_GC64 +@set DASC=vm_x86.dasc +:NOGC32 + +%LJCOMPILE% host\minilua.c +@if errorlevel 1 goto :BAD +%LJLINK% /out:minilua.exe minilua.obj +@if errorlevel 1 goto :BAD +if exist minilua.exe.manifest^ + %LJMT% -manifest minilua.exe.manifest -outputresource:minilua.exe + +@rem Check for 64 bit host compiler. +@minilua +@if not errorlevel 8 goto :FAIL + +@set DASMFLAGS=-D P64 -D NO_UNWIND +minilua %DASM% -LN %DASMFLAGS% -o host\buildvm_arch.h %DASC% +@if errorlevel 1 goto :BAD + +%LJCOMPILE% /I "." /I %DASMDIR% %GC64% -DLUAJIT_TARGET=LUAJIT_ARCH_X64 -DLUAJIT_OS=LUAJIT_OS_OTHER -DLUAJIT_DISABLE_JIT -DLUAJIT_DISABLE_FFI -DLUAJIT_NO_UNWIND host\buildvm*.c +@if errorlevel 1 goto :BAD +%LJLINK% /out:buildvm.exe buildvm*.obj +@if errorlevel 1 goto :BAD +if exist buildvm.exe.manifest^ + %LJMT% -manifest buildvm.exe.manifest -outputresource:buildvm.exe + +buildvm -m elfasm -o lj_vm.s +@if errorlevel 1 goto :BAD +buildvm -m bcdef -o lj_bcdef.h %ALL_LIB% +@if errorlevel 1 goto :BAD +buildvm -m ffdef -o lj_ffdef.h %ALL_LIB% +@if errorlevel 1 goto :BAD +buildvm -m libdef -o lj_libdef.h %ALL_LIB% +@if errorlevel 1 goto :BAD +buildvm -m recdef -o lj_recdef.h %ALL_LIB% +@if errorlevel 1 goto :BAD +buildvm -m vmdef -o jit\vmdef.lua %ALL_LIB% +@if errorlevel 1 goto :BAD +buildvm -m folddef -o lj_folddef.h lj_opt_fold.c +@if errorlevel 1 goto :BAD + +@rem ---- Cross compiler ---- +@set LJCOMPILE="%SCE_ORBIS_SDK_DIR%\host_tools\bin\orbis-clang" -c -Wall -DLUAJIT_DISABLE_FFI %GC64% +@set LJLIB="%SCE_ORBIS_SDK_DIR%\host_tools\bin\orbis-ar" rcus +@set INCLUDE="" + +orbis-as -o lj_vm.o lj_vm.s + +@if "%1" neq "debug" goto :NODEBUG +@shift +@set LJCOMPILE=%LJCOMPILE% -g -O0 +@set TARGETLIB=libluajitD_ps4.a +goto :BUILD +:NODEBUG +@set LJCOMPILE=%LJCOMPILE% -O2 +@set TARGETLIB=libluajit_ps4.a +:BUILD +del %TARGETLIB% +@if "%1" neq "noamalg" goto :AMALG +for %%f in (lj_*.c lib_*.c) do ( + %LJCOMPILE% %%f + @if errorlevel 1 goto :BAD +) + +%LJLIB% %TARGETLIB% lj_*.o lib_*.o +@if errorlevel 1 goto :BAD +@goto :NOAMALG +:AMALG +%LJCOMPILE% ljamalg.c +@if errorlevel 1 goto :BAD +%LJLIB% %TARGETLIB% ljamalg.o lj_vm.o +@if errorlevel 1 goto :BAD +:NOAMALG + +@del *.o *.obj *.manifest minilua.exe buildvm.exe +@echo. +@echo === Successfully built LuaJIT for PS4 === + +@goto :END +:BAD +@echo. +@echo ******************************************************* +@echo *** Build FAILED -- Please check the error messages *** +@echo ******************************************************* +@goto :END +:FAIL +@echo To run this script you must open a "Visual Studio .NET Command Prompt" +@echo (64 bit host compiler). The PS4 Orbis SDK must be installed, too. +:END diff --git a/fluent-bit/lib/luajit-3065c9/src/ps5build.bat b/fluent-bit/lib/luajit-3065c9/src/ps5build.bat new file mode 100644 index 00000000..0b1ebd5b --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/ps5build.bat @@ -0,0 +1,123 @@ +@rem Script to build LuaJIT with the PS5 SDK. +@rem Donated to the public domain. +@rem +@rem Open a "Visual Studio .NET Command Prompt" (64 bit host compiler) +@rem or "VS20xx x64 Native Tools Command Prompt". +@rem +@rem Then cd to this directory and run this script. +@rem +@rem Recommended invocation: +@rem +@rem ps5build release build, amalgamated, 64-bit GC +@rem ps5build debug debug build, amalgamated, 64-bit GC +@rem +@rem Additional command-line options (not generally recommended): +@rem +@rem gc32 (before debug) 32-bit GC +@rem noamalg (after debug) non-amalgamated build + +@if not defined INCLUDE goto :FAIL +@if not defined SCE_PROSPERO_SDK_DIR goto :FAIL + +@setlocal +@rem ---- Host compiler ---- +@set LJCOMPILE=cl /nologo /c /MD /O2 /W3 /D_CRT_SECURE_NO_DEPRECATE +@set LJLINK=link /nologo +@set LJMT=mt /nologo +@set DASMDIR=..\dynasm +@set DASM=%DASMDIR%\dynasm.lua +@set ALL_LIB=lib_base.c lib_math.c lib_bit.c lib_string.c lib_table.c lib_io.c lib_os.c lib_package.c lib_debug.c lib_jit.c lib_ffi.c lib_buffer.c +@set GC64= +@set DASC=vm_x64.dasc + +@if "%1" neq "gc32" goto :NOGC32 +@shift +@set GC64=-DLUAJIT_DISABLE_GC64 +@set DASC=vm_x86.dasc +:NOGC32 + +%LJCOMPILE% host\minilua.c +@if errorlevel 1 goto :BAD +%LJLINK% /out:minilua.exe minilua.obj +@if errorlevel 1 goto :BAD +if exist minilua.exe.manifest^ + %LJMT% -manifest minilua.exe.manifest -outputresource:minilua.exe + +@rem Check for 64 bit host compiler. +@minilua +@if not errorlevel 8 goto :FAIL + +@set DASMFLAGS=-D P64 -D NO_UNWIND +minilua %DASM% -LN %DASMFLAGS% -o host\buildvm_arch.h %DASC% +@if errorlevel 1 goto :BAD + +%LJCOMPILE% /I "." /I %DASMDIR% %GC64% -DLUAJIT_TARGET=LUAJIT_ARCH_X64 -DLUAJIT_OS=LUAJIT_OS_OTHER -DLUAJIT_DISABLE_JIT -DLUAJIT_DISABLE_FFI -DLUAJIT_NO_UNWIND host\buildvm*.c +@if errorlevel 1 goto :BAD +%LJLINK% /out:buildvm.exe buildvm*.obj +@if errorlevel 1 goto :BAD +if exist buildvm.exe.manifest^ + %LJMT% -manifest buildvm.exe.manifest -outputresource:buildvm.exe + +buildvm -m elfasm -o lj_vm.s +@if errorlevel 1 goto :BAD +buildvm -m bcdef -o lj_bcdef.h %ALL_LIB% +@if errorlevel 1 goto :BAD +buildvm -m ffdef -o lj_ffdef.h %ALL_LIB% +@if errorlevel 1 goto :BAD +buildvm -m libdef -o lj_libdef.h %ALL_LIB% +@if errorlevel 1 goto :BAD +buildvm -m recdef -o lj_recdef.h %ALL_LIB% +@if errorlevel 1 goto :BAD +buildvm -m vmdef -o jit\vmdef.lua %ALL_LIB% +@if errorlevel 1 goto :BAD +buildvm -m folddef -o lj_folddef.h lj_opt_fold.c +@if errorlevel 1 goto :BAD + +@rem ---- Cross compiler ---- +@set LJCOMPILE="%SCE_PROSPERO_SDK_DIR%\host_tools\bin\prospero-clang" -c -Wall -DLUAJIT_DISABLE_FFI %GC64% +@set LJLIB="%SCE_PROSPERO_SDK_DIR%\host_tools\bin\prospero-llvm-ar" rcus +@set INCLUDE="" + +%SCE_PROSPERO_SDK_DIR%\host_tools\bin\prospero-llvm-as -o lj_vm.o lj_vm.s + +@if "%1" neq "debug" goto :NODEBUG +@shift +@set LJCOMPILE=%LJCOMPILE% -g -O0 +@set TARGETLIB=libluajitD_ps5.a +goto :BUILD +:NODEBUG +@set LJCOMPILE=%LJCOMPILE% -O2 +@set TARGETLIB=libluajit_ps5.a +:BUILD +del %TARGETLIB% +@if "%1" neq "noamalg" goto :AMALG +for %%f in (lj_*.c lib_*.c) do ( + %LJCOMPILE% %%f + @if errorlevel 1 goto :BAD +) + +%LJLIB% %TARGETLIB% lj_*.o lib_*.o +@if errorlevel 1 goto :BAD +@goto :NOAMALG +:AMALG +%LJCOMPILE% ljamalg.c +@if errorlevel 1 goto :BAD +%LJLIB% %TARGETLIB% ljamalg.o lj_vm.o +@if errorlevel 1 goto :BAD +:NOAMALG + +@del *.o *.obj *.manifest minilua.exe buildvm.exe +@echo. +@echo === Successfully built LuaJIT for PS5 === + +@goto :END +:BAD +@echo. +@echo ******************************************************* +@echo *** Build FAILED -- Please check the error messages *** +@echo ******************************************************* +@goto :END +:FAIL +@echo To run this script you must open a "Visual Studio .NET Command Prompt" +@echo (64 bit host compiler). The PS5 Prospero SDK must be installed, too. +:END diff --git a/fluent-bit/lib/luajit-3065c9/src/psvitabuild.bat b/fluent-bit/lib/luajit-3065c9/src/psvitabuild.bat new file mode 100644 index 00000000..2980e157 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/psvitabuild.bat @@ -0,0 +1,93 @@ +@rem Script to build LuaJIT with the PS Vita SDK. +@rem Donated to the public domain. +@rem +@rem Open a "Visual Studio .NET Command Prompt" (32 bit host compiler) +@rem Then cd to this directory and run this script. + +@if not defined INCLUDE goto :FAIL +@if not defined SCE_PSP2_SDK_DIR goto :FAIL + +@setlocal +@rem ---- Host compiler ---- +@set LJCOMPILE=cl /nologo /c /MD /O2 /W3 /D_CRT_SECURE_NO_DEPRECATE +@set LJLINK=link /nologo +@set LJMT=mt /nologo +@set DASMDIR=..\dynasm +@set DASM=%DASMDIR%\dynasm.lua +@set ALL_LIB=lib_base.c lib_math.c lib_bit.c lib_string.c lib_table.c lib_io.c lib_os.c lib_package.c lib_debug.c lib_jit.c lib_ffi.c lib_buffer.c + +%LJCOMPILE% host\minilua.c +@if errorlevel 1 goto :BAD +%LJLINK% /out:minilua.exe minilua.obj +@if errorlevel 1 goto :BAD +if exist minilua.exe.manifest^ + %LJMT% -manifest minilua.exe.manifest -outputresource:minilua.exe + +@rem Check for 32 bit host compiler. +@minilua +@if errorlevel 8 goto :FAIL + +@set DASMFLAGS=-D FPU -D HFABI +minilua %DASM% -LN %DASMFLAGS% -o host\buildvm_arch.h vm_arm.dasc +@if errorlevel 1 goto :BAD + +%LJCOMPILE% /I "." /I %DASMDIR% -DLUAJIT_TARGET=LUAJIT_ARCH_ARM -DLUAJIT_OS=LUAJIT_OS_OTHER -DLUAJIT_DISABLE_JIT -DLUAJIT_DISABLE_FFI -DLJ_TARGET_PSVITA=1 host\buildvm*.c +@if errorlevel 1 goto :BAD +%LJLINK% /out:buildvm.exe buildvm*.obj +@if errorlevel 1 goto :BAD +if exist buildvm.exe.manifest^ + %LJMT% -manifest buildvm.exe.manifest -outputresource:buildvm.exe + +buildvm -m elfasm -o lj_vm.s +@if errorlevel 1 goto :BAD +buildvm -m bcdef -o lj_bcdef.h %ALL_LIB% +@if errorlevel 1 goto :BAD +buildvm -m ffdef -o lj_ffdef.h %ALL_LIB% +@if errorlevel 1 goto :BAD +buildvm -m libdef -o lj_libdef.h %ALL_LIB% +@if errorlevel 1 goto :BAD +buildvm -m recdef -o lj_recdef.h %ALL_LIB% +@if errorlevel 1 goto :BAD +buildvm -m vmdef -o jit\vmdef.lua %ALL_LIB% +@if errorlevel 1 goto :BAD +buildvm -m folddef -o lj_folddef.h lj_opt_fold.c +@if errorlevel 1 goto :BAD + +@rem ---- Cross compiler ---- +@set LJCOMPILE="%SCE_PSP2_SDK_DIR%\host_tools\build\bin\psp2snc" -c -w -DLUAJIT_DISABLE_FFI -DLUAJIT_USE_SYSMALLOC +@set LJLIB="%SCE_PSP2_SDK_DIR%\host_tools\build\bin\psp2ld32" -r --output= +@set INCLUDE="" + +"%SCE_PSP2_SDK_DIR%\host_tools\build\bin\psp2as" -o lj_vm.o lj_vm.s + +@if "%1" neq "debug" goto :NODEBUG +@shift +@set LJCOMPILE=%LJCOMPILE% -g -O0 +@set TARGETLIB=libluajitD.a +goto :BUILD +:NODEBUG +@set LJCOMPILE=%LJCOMPILE% -O2 +@set TARGETLIB=libluajit.a +:BUILD +del %TARGETLIB% + +%LJCOMPILE% ljamalg.c +@if errorlevel 1 goto :BAD +%LJLIB%%TARGETLIB% ljamalg.o lj_vm.o +@if errorlevel 1 goto :BAD + +@del *.o *.obj *.manifest minilua.exe buildvm.exe +@echo. +@echo === Successfully built LuaJIT for PS Vita === + +@goto :END +:BAD +@echo. +@echo ******************************************************* +@echo *** Build FAILED -- Please check the error messages *** +@echo ******************************************************* +@goto :END +:FAIL +@echo To run this script you must open a "Visual Studio .NET Command Prompt" +@echo (32 bit host compiler). The PS Vita SDK must be installed, too. +:END diff --git a/fluent-bit/lib/luajit-3065c9/src/vm_arm.dasc b/fluent-bit/lib/luajit-3065c9/src/vm_arm.dasc new file mode 100644 index 00000000..770c1602 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/vm_arm.dasc @@ -0,0 +1,4663 @@ +|// Low-level VM code for ARM CPUs. +|// Bytecode interpreter, fast functions and helper functions. +|// Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +| +|.arch arm +|.section code_op, code_sub +| +|.actionlist build_actionlist +|.globals GLOB_ +|.globalnames globnames +|.externnames extnames +| +|// Note: The ragged indentation of the instructions is intentional. +|// The starting columns indicate data dependencies. +| +|//----------------------------------------------------------------------- +| +|// Fixed register assignments for the interpreter. +| +|// The following must be C callee-save. +|.define MASKR8, r4 // 255*8 constant for fast bytecode decoding. +|.define KBASE, r5 // Constants of current Lua function. +|.define PC, r6 // Next PC. +|.define DISPATCH, r7 // Opcode dispatch table. +|.define LREG, r8 // Register holding lua_State (also in SAVE_L). +| +|// C callee-save in EABI, but often refetched. Temporary in iOS 3.0+. +|.define BASE, r9 // Base of current Lua stack frame. +| +|// The following temporaries are not saved across C calls, except for RA/RC. +|.define RA, r10 // Callee-save. +|.define RC, r11 // Callee-save. +|.define RB, r12 +|.define OP, r12 // Overlaps RB, must not be lr. +|.define INS, lr +| +|// Calling conventions. Also used as temporaries. +|.define CARG1, r0 +|.define CARG2, r1 +|.define CARG3, r2 +|.define CARG4, r3 +|.define CARG12, r0 // For 1st soft-fp double. +|.define CARG34, r2 // For 2nd soft-fp double. +| +|.define CRET1, r0 +|.define CRET2, r1 +| +|// Stack layout while in interpreter. Must match with lj_frame.h. +|.define SAVE_R4, [sp, #28] +|.define CFRAME_SPACE, #28 +|.define SAVE_ERRF, [sp, #24] +|.define SAVE_NRES, [sp, #20] +|.define SAVE_CFRAME, [sp, #16] +|.define SAVE_L, [sp, #12] +|.define SAVE_PC, [sp, #8] +|.define SAVE_MULTRES, [sp, #4] +|.define ARG5, [sp] +| +|.define TMPDhi, [sp, #4] +|.define TMPDlo, [sp] +|.define TMPD, [sp] +|.define TMPDp, sp +| +|.if FPU +|.macro saveregs +| push {r5, r6, r7, r8, r9, r10, r11, lr} +| vpush {d8-d15} +| sub sp, sp, CFRAME_SPACE+4 +| str r4, SAVE_R4 +|.endmacro +|.macro restoreregs_ret +| ldr r4, SAVE_R4 +| add sp, sp, CFRAME_SPACE+4 +| vpop {d8-d15} +| pop {r5, r6, r7, r8, r9, r10, r11, pc} +|.endmacro +|.else +|.macro saveregs +| push {r4, r5, r6, r7, r8, r9, r10, r11, lr} +| sub sp, sp, CFRAME_SPACE +|.endmacro +|.macro restoreregs_ret +| add sp, sp, CFRAME_SPACE +| pop {r4, r5, r6, r7, r8, r9, r10, r11, pc} +|.endmacro +|.endif +| +|// Type definitions. Some of these are only used for documentation. +|.type L, lua_State, LREG +|.type GL, global_State +|.type TVALUE, TValue +|.type GCOBJ, GCobj +|.type STR, GCstr +|.type TAB, GCtab +|.type LFUNC, GCfuncL +|.type CFUNC, GCfuncC +|.type PROTO, GCproto +|.type UPVAL, GCupval +|.type NODE, Node +|.type NARGS8, int +|.type TRACE, GCtrace +|.type SBUF, SBuf +| +|//----------------------------------------------------------------------- +| +|// Trap for not-yet-implemented parts. +|.macro NYI; ud; .endmacro +| +|//----------------------------------------------------------------------- +| +|// Access to frame relative to BASE. +|.define FRAME_FUNC, #-8 +|.define FRAME_PC, #-4 +| +|.macro decode_RA8, dst, ins; and dst, MASKR8, ins, lsr #5; .endmacro +|.macro decode_RB8, dst, ins; and dst, MASKR8, ins, lsr #21; .endmacro +|.macro decode_RC8, dst, ins; and dst, MASKR8, ins, lsr #13; .endmacro +|.macro decode_RD, dst, ins; lsr dst, ins, #16; .endmacro +|.macro decode_OP, dst, ins; and dst, ins, #255; .endmacro +| +|// Instruction fetch. +|.macro ins_NEXT1 +| ldrb OP, [PC] +|.endmacro +|.macro ins_NEXT2 +| ldr INS, [PC], #4 +|.endmacro +|// Instruction decode+dispatch. +|.macro ins_NEXT3 +| ldr OP, [DISPATCH, OP, lsl #2] +| decode_RA8 RA, INS +| decode_RD RC, INS +| bx OP +|.endmacro +|.macro ins_NEXT +| ins_NEXT1 +| ins_NEXT2 +| ins_NEXT3 +|.endmacro +| +|// Instruction footer. +|.if 1 +| // Replicated dispatch. Less unpredictable branches, but higher I-Cache use. +| .define ins_next, ins_NEXT +| .define ins_next_, ins_NEXT +| .define ins_next1, ins_NEXT1 +| .define ins_next2, ins_NEXT2 +| .define ins_next3, ins_NEXT3 +|.else +| // Common dispatch. Lower I-Cache use, only one (very) unpredictable branch. +| // Affects only certain kinds of benchmarks (and only with -j off). +| .macro ins_next +| b ->ins_next +| .endmacro +| .macro ins_next1 +| .endmacro +| .macro ins_next2 +| .endmacro +| .macro ins_next3 +| b ->ins_next +| .endmacro +| .macro ins_next_ +| ->ins_next: +| ins_NEXT +| .endmacro +|.endif +| +|// Avoid register name substitution for field name. +#define field_pc pc +| +|// Call decode and dispatch. +|.macro ins_callt +| // BASE = new base, CARG3 = LFUNC/CFUNC, RC = nargs*8, FRAME_PC(BASE) = PC +| ldr PC, LFUNC:CARG3->field_pc +| ldrb OP, [PC] // STALL: load PC. early PC. +| ldr INS, [PC], #4 +| ldr OP, [DISPATCH, OP, lsl #2] // STALL: load OP. early OP. +| decode_RA8 RA, INS +| add RA, RA, BASE +| bx OP +|.endmacro +| +|.macro ins_call +| // BASE = new base, CARG3 = LFUNC/CFUNC, RC = nargs*8, PC = caller PC +| str PC, [BASE, FRAME_PC] +| ins_callt // STALL: locked PC. +|.endmacro +| +|//----------------------------------------------------------------------- +| +|// Macros to test operand types. +|.macro checktp, reg, tp; cmn reg, #-tp; .endmacro +|.macro checktpeq, reg, tp; cmneq reg, #-tp; .endmacro +|.macro checktpne, reg, tp; cmnne reg, #-tp; .endmacro +|.macro checkstr, reg, target; checktp reg, LJ_TSTR; bne target; .endmacro +|.macro checktab, reg, target; checktp reg, LJ_TTAB; bne target; .endmacro +|.macro checkfunc, reg, target; checktp reg, LJ_TFUNC; bne target; .endmacro +| +|// Assumes DISPATCH is relative to GL. +#define DISPATCH_GL(field) (GG_DISP2G + (int)offsetof(global_State, field)) +#define DISPATCH_J(field) (GG_DISP2J + (int)offsetof(jit_State, field)) +| +#define PC2PROTO(field) ((int)offsetof(GCproto, field)-(int)sizeof(GCproto)) +| +|.macro hotcheck, delta +| lsr CARG1, PC, #1 +| and CARG1, CARG1, #126 +| sub CARG1, CARG1, #-GG_DISP2HOT +| ldrh CARG2, [DISPATCH, CARG1] +| subs CARG2, CARG2, #delta +| strh CARG2, [DISPATCH, CARG1] +|.endmacro +| +|.macro hotloop +| hotcheck HOTCOUNT_LOOP +| blo ->vm_hotloop +|.endmacro +| +|.macro hotcall +| hotcheck HOTCOUNT_CALL +| blo ->vm_hotcall +|.endmacro +| +|// Set current VM state. +|.macro mv_vmstate, reg, st; mvn reg, #LJ_VMST_..st; .endmacro +|.macro st_vmstate, reg; str reg, [DISPATCH, #DISPATCH_GL(vmstate)]; .endmacro +| +|// Move table write barrier back. Overwrites mark and tmp. +|.macro barrierback, tab, mark, tmp +| ldr tmp, [DISPATCH, #DISPATCH_GL(gc.grayagain)] +| bic mark, mark, #LJ_GC_BLACK // black2gray(tab) +| str tab, [DISPATCH, #DISPATCH_GL(gc.grayagain)] +| strb mark, tab->marked +| str tmp, tab->gclist +|.endmacro +| +|.macro .IOS, a, b +|.if IOS +| a, b +|.endif +|.endmacro +| +|//----------------------------------------------------------------------- + +#if !LJ_DUALNUM +#error "Only dual-number mode supported for ARM target" +#endif + +/* Generate subroutines used by opcodes and other parts of the VM. */ +/* The .code_sub section should be last to help static branch prediction. */ +static void build_subroutines(BuildCtx *ctx) +{ + |.code_sub + | + |//----------------------------------------------------------------------- + |//-- Return handling ---------------------------------------------------- + |//----------------------------------------------------------------------- + | + |->vm_returnp: + | // See vm_return. Also: RB = previous base. + | tst PC, #FRAME_P + | beq ->cont_dispatch + | + | // Return from pcall or xpcall fast func. + | ldr PC, [RB, FRAME_PC] // Fetch PC of previous frame. + | mvn CARG2, #~LJ_TTRUE + | mov BASE, RB + | // Prepending may overwrite the pcall frame, so do it at the end. + | str CARG2, [RA, FRAME_PC] // Prepend true to results. + | sub RA, RA, #8 + | + |->vm_returnc: + | adds RC, RC, #8 // RC = (nresults+1)*8. + | mov CRET1, #LUA_YIELD + | beq ->vm_unwind_c_eh + | str RC, SAVE_MULTRES + | ands CARG1, PC, #FRAME_TYPE + | beq ->BC_RET_Z // Handle regular return to Lua. + | + |->vm_return: + | // BASE = base, RA = resultptr, RC/MULTRES = (nresults+1)*8, PC = return + | // CARG1 = PC & FRAME_TYPE + | bic RB, PC, #FRAME_TYPEP + | cmp CARG1, #FRAME_C + | sub RB, BASE, RB // RB = previous base. + | bne ->vm_returnp + | + | str RB, L->base + | ldr KBASE, SAVE_NRES + | mv_vmstate CARG4, C + | sub BASE, BASE, #8 + | subs CARG3, RC, #8 + | lsl KBASE, KBASE, #3 // KBASE = (nresults_wanted+1)*8 + | st_vmstate CARG4 + | beq >2 + |1: + | subs CARG3, CARG3, #8 + | ldrd CARG12, [RA], #8 + | strd CARG12, [BASE], #8 + | bne <1 + |2: + | cmp KBASE, RC // More/less results wanted? + | bne >6 + |3: + | str BASE, L->top // Store new top. + | + |->vm_leave_cp: + | ldr RC, SAVE_CFRAME // Restore previous C frame. + | mov CRET1, #0 // Ok return status for vm_pcall. + | str RC, L->cframe + | + |->vm_leave_unw: + | restoreregs_ret + | + |6: + | blt >7 // Less results wanted? + | // More results wanted. Check stack size and fill up results with nil. + | ldr CARG3, L->maxstack + | mvn CARG2, #~LJ_TNIL + | cmp BASE, CARG3 + | bhs >8 + | str CARG2, [BASE, #4] + | add RC, RC, #8 + | add BASE, BASE, #8 + | b <2 + | + |7: // Less results wanted. + | sub CARG1, RC, KBASE + | cmp KBASE, #0 // LUA_MULTRET+1 case? + | subne BASE, BASE, CARG1 // Either keep top or shrink it. + | b <3 + | + |8: // Corner case: need to grow stack for filling up results. + | // This can happen if: + | // - A C function grows the stack (a lot). + | // - The GC shrinks the stack in between. + | // - A return back from a lua_call() with (high) nresults adjustment. + | str BASE, L->top // Save current top held in BASE (yes). + | lsr CARG2, KBASE, #3 + | mov CARG1, L + | bl extern lj_state_growstack // (lua_State *L, int n) + | ldr BASE, L->top // Need the (realloced) L->top in BASE. + | b <2 + | + |->vm_unwind_c: // Unwind C stack, return from vm_pcall. + | // (void *cframe, int errcode) + | mov sp, CARG1 + | mov CRET1, CARG2 + |->vm_unwind_c_eh: // Landing pad for external unwinder. + | ldr L, SAVE_L + | mv_vmstate CARG4, C + | ldr GL:CARG3, L->glref + | str CARG4, GL:CARG3->vmstate + | b ->vm_leave_unw + | + |->vm_unwind_ff: // Unwind C stack, return from ff pcall. + | // (void *cframe) + | bic CARG1, CARG1, #~CFRAME_RAWMASK // Use two steps: bic sp is deprecated. + | mov sp, CARG1 + |->vm_unwind_ff_eh: // Landing pad for external unwinder. + | ldr L, SAVE_L + | mov MASKR8, #255 + | mov RC, #16 // 2 results: false + error message. + | lsl MASKR8, MASKR8, #3 // MASKR8 = 255*8. + | ldr BASE, L->base + | ldr DISPATCH, L->glref // Setup pointer to dispatch table. + | mvn CARG1, #~LJ_TFALSE + | sub RA, BASE, #8 // Results start at BASE-8. + | ldr PC, [BASE, FRAME_PC] // Fetch PC of previous frame. + | add DISPATCH, DISPATCH, #GG_G2DISP + | mv_vmstate CARG2, INTERP + | str CARG1, [BASE, #-4] // Prepend false to error message. + | st_vmstate CARG2 + | b ->vm_returnc + | + |->vm_unwind_ext: // Complete external unwind. +#if !LJ_NO_UNWIND + | push {r0, r1, r2, lr} + | bl extern _Unwind_Complete + | ldr r0, [sp] + | bl extern _Unwind_DeleteException + | pop {r0, r1, r2, lr} + | mov r0, r1 + | bx r2 +#endif + | + |//----------------------------------------------------------------------- + |//-- Grow stack for calls ----------------------------------------------- + |//----------------------------------------------------------------------- + | + |->vm_growstack_c: // Grow stack for C function. + | // CARG1 = L + | mov CARG2, #LUA_MINSTACK + | b >2 + | + |->vm_growstack_l: // Grow stack for Lua function. + | // BASE = new base, RA = BASE+framesize*8, RC = nargs*8, PC = first PC + | add RC, BASE, RC + | sub RA, RA, BASE + | mov CARG1, L + | str BASE, L->base + | add PC, PC, #4 // Must point after first instruction. + | str RC, L->top + | lsr CARG2, RA, #3 + |2: + | // L->base = new base, L->top = top + | str PC, SAVE_PC + | bl extern lj_state_growstack // (lua_State *L, int n) + | ldr BASE, L->base + | ldr RC, L->top + | ldr LFUNC:CARG3, [BASE, FRAME_FUNC] + | sub NARGS8:RC, RC, BASE + | // BASE = new base, RB = LFUNC/CFUNC, RC = nargs*8, FRAME_PC(BASE) = PC + | ins_callt // Just retry the call. + | + |//----------------------------------------------------------------------- + |//-- Entry points into the assembler VM --------------------------------- + |//----------------------------------------------------------------------- + | + |->vm_resume: // Setup C frame and resume thread. + | // (lua_State *L, TValue *base, int nres1 = 0, ptrdiff_t ef = 0) + | saveregs + | mov L, CARG1 + | ldr DISPATCH, L:CARG1->glref // Setup pointer to dispatch table. + | mov BASE, CARG2 + | add DISPATCH, DISPATCH, #GG_G2DISP + | str L, SAVE_L + | mov PC, #FRAME_CP + | str CARG3, SAVE_NRES + | add CARG2, sp, #CFRAME_RESUME + | ldrb CARG1, L->status + | str CARG3, SAVE_ERRF + | str L, SAVE_PC // Any value outside of bytecode is ok. + | str CARG3, SAVE_CFRAME + | cmp CARG1, #0 + | str CARG2, L->cframe + | beq >3 + | + | // Resume after yield (like a return). + | str L, [DISPATCH, #DISPATCH_GL(cur_L)] + | mov RA, BASE + | ldr BASE, L->base + | ldr CARG1, L->top + | mov MASKR8, #255 + | strb CARG3, L->status + | sub RC, CARG1, BASE + | ldr PC, [BASE, FRAME_PC] + | lsl MASKR8, MASKR8, #3 // MASKR8 = 255*8. + | mv_vmstate CARG2, INTERP + | add RC, RC, #8 + | ands CARG1, PC, #FRAME_TYPE + | st_vmstate CARG2 + | str RC, SAVE_MULTRES + | beq ->BC_RET_Z + | b ->vm_return + | + |->vm_pcall: // Setup protected C frame and enter VM. + | // (lua_State *L, TValue *base, int nres1, ptrdiff_t ef) + | saveregs + | mov PC, #FRAME_CP + | str CARG4, SAVE_ERRF + | b >1 + | + |->vm_call: // Setup C frame and enter VM. + | // (lua_State *L, TValue *base, int nres1) + | saveregs + | mov PC, #FRAME_C + | + |1: // Entry point for vm_pcall above (PC = ftype). + | ldr RC, L:CARG1->cframe + | str CARG3, SAVE_NRES + | mov L, CARG1 + | str CARG1, SAVE_L + | ldr DISPATCH, L->glref // Setup pointer to dispatch table. + | mov BASE, CARG2 + | str CARG1, SAVE_PC // Any value outside of bytecode is ok. + | str RC, SAVE_CFRAME + | add DISPATCH, DISPATCH, #GG_G2DISP + | str sp, L->cframe // Add our C frame to cframe chain. + | + |3: // Entry point for vm_cpcall/vm_resume (BASE = base, PC = ftype). + | str L, [DISPATCH, #DISPATCH_GL(cur_L)] + | ldr RB, L->base // RB = old base (for vmeta_call). + | ldr CARG1, L->top + | mov MASKR8, #255 + | add PC, PC, BASE + | lsl MASKR8, MASKR8, #3 // MASKR8 = 255*8. + | sub PC, PC, RB // PC = frame delta + frame type + | mv_vmstate CARG2, INTERP + | sub NARGS8:RC, CARG1, BASE + | st_vmstate CARG2 + | + |->vm_call_dispatch: + | // RB = old base, BASE = new base, RC = nargs*8, PC = caller PC + | ldrd CARG34, [BASE, FRAME_FUNC] + | checkfunc CARG4, ->vmeta_call + | + |->vm_call_dispatch_f: + | ins_call + | // BASE = new base, CARG3 = func, RC = nargs*8, PC = caller PC + | + |->vm_cpcall: // Setup protected C frame, call C. + | // (lua_State *L, lua_CFunction func, void *ud, lua_CPFunction cp) + | saveregs + | mov L, CARG1 + | ldr RA, L:CARG1->stack + | str CARG1, SAVE_L + | ldr DISPATCH, L->glref // Setup pointer to dispatch table. + | ldr RB, L->top + | str CARG1, SAVE_PC // Any value outside of bytecode is ok. + | ldr RC, L->cframe + | add DISPATCH, DISPATCH, #GG_G2DISP + | sub RA, RA, RB // Compute -savestack(L, L->top). + | mov RB, #0 + | str RA, SAVE_NRES // Neg. delta means cframe w/o frame. + | str RB, SAVE_ERRF // No error function. + | str RC, SAVE_CFRAME + | str sp, L->cframe // Add our C frame to cframe chain. + | str L, [DISPATCH, #DISPATCH_GL(cur_L)] + | blx CARG4 // (lua_State *L, lua_CFunction func, void *ud) + | movs BASE, CRET1 + | mov PC, #FRAME_CP + | bne <3 // Else continue with the call. + | b ->vm_leave_cp // No base? Just remove C frame. + | + |//----------------------------------------------------------------------- + |//-- Metamethod handling ------------------------------------------------ + |//----------------------------------------------------------------------- + | + |//-- Continuation dispatch ---------------------------------------------- + | + |->cont_dispatch: + | // BASE = meta base, RA = resultptr, RC = (nresults+1)*8 + | ldr LFUNC:CARG3, [RB, FRAME_FUNC] + | ldr CARG1, [BASE, #-16] // Get continuation. + | mov CARG4, BASE + | mov BASE, RB // Restore caller BASE. + |.if FFI + | cmp CARG1, #1 + |.endif + | ldr PC, [CARG4, #-12] // Restore PC from [cont|PC]. + | mvn INS, #~LJ_TNIL + | add CARG2, RA, RC + | str INS, [CARG2, #-4] // Ensure one valid arg. + |.if FFI + | bls >1 + |.endif + | ldr CARG3, LFUNC:CARG3->field_pc + | ldr KBASE, [CARG3, #PC2PROTO(k)] + | // BASE = base, RA = resultptr, CARG4 = meta base + | bx CARG1 + | + |.if FFI + |1: + | beq ->cont_ffi_callback // cont = 1: return from FFI callback. + | // cont = 0: tailcall from C function. + | sub CARG4, CARG4, #16 + | sub RC, CARG4, BASE + | b ->vm_call_tail + |.endif + | + |->cont_cat: // RA = resultptr, CARG4 = meta base + | ldr INS, [PC, #-4] + | sub CARG2, CARG4, #16 + | ldrd CARG34, [RA] + | str BASE, L->base + | decode_RB8 RC, INS + | decode_RA8 RA, INS + | add CARG1, BASE, RC + | subs CARG1, CARG2, CARG1 + | strdne CARG34, [CARG2] + | movne CARG3, CARG1 + | bne ->BC_CAT_Z + | strd CARG34, [BASE, RA] + | b ->cont_nop + | + |//-- Table indexing metamethods ----------------------------------------- + | + |->vmeta_tgets1: + | add CARG2, BASE, RB + | b >2 + | + |->vmeta_tgets: + | sub CARG2, DISPATCH, #-DISPATCH_GL(tmptv) + | mvn CARG4, #~LJ_TTAB + | str TAB:RB, [CARG2] + | str CARG4, [CARG2, #4] + |2: + | mvn CARG4, #~LJ_TSTR + | str STR:RC, TMPDlo + | str CARG4, TMPDhi + | mov CARG3, TMPDp + | b >1 + | + |->vmeta_tgetb: // RC = index + | decode_RB8 RB, INS + | str RC, TMPDlo + | mvn CARG4, #~LJ_TISNUM + | add CARG2, BASE, RB + | str CARG4, TMPDhi + | mov CARG3, TMPDp + | b >1 + | + |->vmeta_tgetv: + | add CARG2, BASE, RB + | add CARG3, BASE, RC + |1: + | str BASE, L->base + | mov CARG1, L + | str PC, SAVE_PC + | bl extern lj_meta_tget // (lua_State *L, TValue *o, TValue *k) + | // Returns TValue * (finished) or NULL (metamethod). + | .IOS ldr BASE, L->base + | cmp CRET1, #0 + | beq >3 + | ldrd CARG34, [CRET1] + | ins_next1 + | ins_next2 + | strd CARG34, [BASE, RA] + | ins_next3 + | + |3: // Call __index metamethod. + | // BASE = base, L->top = new base, stack = cont/func/t/k + | rsb CARG1, BASE, #FRAME_CONT + | ldr BASE, L->top + | mov NARGS8:RC, #16 // 2 args for func(t, k). + | str PC, [BASE, #-12] // [cont|PC] + | add PC, CARG1, BASE + | ldr LFUNC:CARG3, [BASE, FRAME_FUNC] // Guaranteed to be a function here. + | b ->vm_call_dispatch_f + | + |->vmeta_tgetr: + | .IOS mov RC, BASE + | bl extern lj_tab_getinth // (GCtab *t, int32_t key) + | // Returns cTValue * or NULL. + | .IOS mov BASE, RC + | cmp CRET1, #0 + | ldrdne CARG12, [CRET1] + | mvneq CARG2, #~LJ_TNIL + | b ->BC_TGETR_Z + | + |//----------------------------------------------------------------------- + | + |->vmeta_tsets1: + | add CARG2, BASE, RB + | b >2 + | + |->vmeta_tsets: + | sub CARG2, DISPATCH, #-DISPATCH_GL(tmptv) + | mvn CARG4, #~LJ_TTAB + | str TAB:RB, [CARG2] + | str CARG4, [CARG2, #4] + |2: + | mvn CARG4, #~LJ_TSTR + | str STR:RC, TMPDlo + | str CARG4, TMPDhi + | mov CARG3, TMPDp + | b >1 + | + |->vmeta_tsetb: // RC = index + | decode_RB8 RB, INS + | str RC, TMPDlo + | mvn CARG4, #~LJ_TISNUM + | add CARG2, BASE, RB + | str CARG4, TMPDhi + | mov CARG3, TMPDp + | b >1 + | + |->vmeta_tsetv: + | add CARG2, BASE, RB + | add CARG3, BASE, RC + |1: + | str BASE, L->base + | mov CARG1, L + | str PC, SAVE_PC + | bl extern lj_meta_tset // (lua_State *L, TValue *o, TValue *k) + | // Returns TValue * (finished) or NULL (metamethod). + | .IOS ldr BASE, L->base + | cmp CRET1, #0 + | ldrd CARG34, [BASE, RA] + | beq >3 + | ins_next1 + | // NOBARRIER: lj_meta_tset ensures the table is not black. + | strd CARG34, [CRET1] + | ins_next2 + | ins_next3 + | + |3: // Call __newindex metamethod. + | // BASE = base, L->top = new base, stack = cont/func/t/k/(v) + | rsb CARG1, BASE, #FRAME_CONT + | ldr BASE, L->top + | mov NARGS8:RC, #24 // 3 args for func(t, k, v). + | strd CARG34, [BASE, #16] // Copy value to third argument. + | str PC, [BASE, #-12] // [cont|PC] + | add PC, CARG1, BASE + | ldr LFUNC:CARG3, [BASE, FRAME_FUNC] // Guaranteed to be a function here. + | b ->vm_call_dispatch_f + | + |->vmeta_tsetr: + | str BASE, L->base + | .IOS mov RC, BASE + | mov CARG1, L + | str PC, SAVE_PC + | bl extern lj_tab_setinth // (lua_State *L, GCtab *t, int32_t key) + | // Returns TValue *. + | .IOS mov BASE, RC + | b ->BC_TSETR_Z + | + |//-- Comparison metamethods --------------------------------------------- + | + |->vmeta_comp: + | mov CARG1, L + | sub PC, PC, #4 + | mov CARG2, RA + | str BASE, L->base + | mov CARG3, RC + | str PC, SAVE_PC + | decode_OP CARG4, INS + | bl extern lj_meta_comp // (lua_State *L, TValue *o1, *o2, int op) + | // Returns 0/1 or TValue * (metamethod). + |3: + | .IOS ldr BASE, L->base + | cmp CRET1, #1 + | bhi ->vmeta_binop + |4: + | ldrh RB, [PC, #2] + | add PC, PC, #4 + | add RB, PC, RB, lsl #2 + | subhs PC, RB, #0x20000 + |->cont_nop: + | ins_next + | + |->cont_ra: // RA = resultptr + | ldr INS, [PC, #-4] + | ldrd CARG12, [RA] + | decode_RA8 CARG3, INS + | strd CARG12, [BASE, CARG3] + | b ->cont_nop + | + |->cont_condt: // RA = resultptr + | ldr CARG2, [RA, #4] + | mvn CARG1, #~LJ_TTRUE + | cmp CARG1, CARG2 // Branch if result is true. + | b <4 + | + |->cont_condf: // RA = resultptr + | ldr CARG2, [RA, #4] + | checktp CARG2, LJ_TFALSE // Branch if result is false. + | b <4 + | + |->vmeta_equal: + | // CARG2, CARG3, CARG4 are already set by BC_ISEQV/BC_ISNEV. + | sub PC, PC, #4 + | str BASE, L->base + | mov CARG1, L + | str PC, SAVE_PC + | bl extern lj_meta_equal // (lua_State *L, GCobj *o1, *o2, int ne) + | // Returns 0/1 or TValue * (metamethod). + | b <3 + | + |->vmeta_equal_cd: + |.if FFI + | sub PC, PC, #4 + | str BASE, L->base + | mov CARG1, L + | mov CARG2, INS + | str PC, SAVE_PC + | bl extern lj_meta_equal_cd // (lua_State *L, BCIns op) + | // Returns 0/1 or TValue * (metamethod). + | b <3 + |.endif + | + |->vmeta_istype: + | sub PC, PC, #4 + | str BASE, L->base + | mov CARG1, L + | lsr CARG2, RA, #3 + | mov CARG3, RC + | str PC, SAVE_PC + | bl extern lj_meta_istype // (lua_State *L, BCReg ra, BCReg tp) + | .IOS ldr BASE, L->base + | b ->cont_nop + | + |//-- Arithmetic metamethods --------------------------------------------- + | + |->vmeta_arith_vn: + | decode_RB8 RB, INS + | decode_RC8 RC, INS + | add CARG3, BASE, RB + | add CARG4, KBASE, RC + | b >1 + | + |->vmeta_arith_nv: + | decode_RB8 RB, INS + | decode_RC8 RC, INS + | add CARG4, BASE, RB + | add CARG3, KBASE, RC + | b >1 + | + |->vmeta_unm: + | ldr INS, [PC, #-8] + | sub PC, PC, #4 + | add CARG3, BASE, RC + | add CARG4, BASE, RC + | b >1 + | + |->vmeta_arith_vv: + | decode_RB8 RB, INS + | decode_RC8 RC, INS + | add CARG3, BASE, RB + | add CARG4, BASE, RC + |1: + | decode_OP OP, INS + | add CARG2, BASE, RA + | str BASE, L->base + | mov CARG1, L + | str PC, SAVE_PC + | str OP, ARG5 + | bl extern lj_meta_arith // (lua_State *L, TValue *ra,*rb,*rc, BCReg op) + | // Returns NULL (finished) or TValue * (metamethod). + | .IOS ldr BASE, L->base + | cmp CRET1, #0 + | beq ->cont_nop + | + | // Call metamethod for binary op. + |->vmeta_binop: + | // BASE = old base, CRET1 = new base, stack = cont/func/o1/o2 + | sub CARG2, CRET1, BASE + | str PC, [CRET1, #-12] // [cont|PC] + | add PC, CARG2, #FRAME_CONT + | mov BASE, CRET1 + | mov NARGS8:RC, #16 // 2 args for func(o1, o2). + | b ->vm_call_dispatch + | + |->vmeta_len: + | add CARG2, BASE, RC + | str BASE, L->base + | mov CARG1, L + | str PC, SAVE_PC + | bl extern lj_meta_len // (lua_State *L, TValue *o) + | // Returns NULL (retry) or TValue * (metamethod base). + | .IOS ldr BASE, L->base +#if LJ_52 + | cmp CRET1, #0 + | bne ->vmeta_binop // Binop call for compatibility. + | ldr TAB:CARG1, [BASE, RC] + | b ->BC_LEN_Z +#else + | b ->vmeta_binop // Binop call for compatibility. +#endif + | + |//-- Call metamethod ---------------------------------------------------- + | + |->vmeta_call: // Resolve and call __call metamethod. + | // RB = old base, BASE = new base, RC = nargs*8 + | mov CARG1, L + | str RB, L->base // This is the callers base! + | sub CARG2, BASE, #8 + | str PC, SAVE_PC + | add CARG3, BASE, NARGS8:RC + | .IOS mov RA, BASE + | bl extern lj_meta_call // (lua_State *L, TValue *func, TValue *top) + | .IOS mov BASE, RA + | ldr LFUNC:CARG3, [BASE, FRAME_FUNC] // Guaranteed to be a function here. + | add NARGS8:RC, NARGS8:RC, #8 // Got one more argument now. + | ins_call + | + |->vmeta_callt: // Resolve __call for BC_CALLT. + | // BASE = old base, RA = new base, RC = nargs*8 + | mov CARG1, L + | str BASE, L->base + | sub CARG2, RA, #8 + | str PC, SAVE_PC + | add CARG3, RA, NARGS8:RC + | bl extern lj_meta_call // (lua_State *L, TValue *func, TValue *top) + | .IOS ldr BASE, L->base + | ldr LFUNC:CARG3, [RA, FRAME_FUNC] // Guaranteed to be a function here. + | ldr PC, [BASE, FRAME_PC] + | add NARGS8:RC, NARGS8:RC, #8 // Got one more argument now. + | b ->BC_CALLT2_Z + | + |//-- Argument coercion for 'for' statement ------------------------------ + | + |->vmeta_for: + | mov CARG1, L + | str BASE, L->base + | mov CARG2, RA + | str PC, SAVE_PC + | bl extern lj_meta_for // (lua_State *L, TValue *base) + | .IOS ldr BASE, L->base + |.if JIT + | ldrb OP, [PC, #-4] + |.endif + | ldr INS, [PC, #-4] + |.if JIT + | cmp OP, #BC_JFORI + |.endif + | decode_RA8 RA, INS + | decode_RD RC, INS + |.if JIT + | beq =>BC_JFORI + |.endif + | b =>BC_FORI + | + |//----------------------------------------------------------------------- + |//-- Fast functions ----------------------------------------------------- + |//----------------------------------------------------------------------- + | + |.macro .ffunc, name + |->ff_ .. name: + |.endmacro + | + |.macro .ffunc_1, name + |->ff_ .. name: + | ldrd CARG12, [BASE] + | cmp NARGS8:RC, #8 + | blo ->fff_fallback + |.endmacro + | + |.macro .ffunc_2, name + |->ff_ .. name: + | ldrd CARG12, [BASE] + | ldrd CARG34, [BASE, #8] + | cmp NARGS8:RC, #16 + | blo ->fff_fallback + |.endmacro + | + |.macro .ffunc_n, name + | .ffunc_1 name + | checktp CARG2, LJ_TISNUM + | bhs ->fff_fallback + |.endmacro + | + |.macro .ffunc_nn, name + | .ffunc_2 name + | checktp CARG2, LJ_TISNUM + | cmnlo CARG4, #-LJ_TISNUM + | bhs ->fff_fallback + |.endmacro + | + |.macro .ffunc_d, name + | .ffunc name + | ldr CARG2, [BASE, #4] + | cmp NARGS8:RC, #8 + | vldr d0, [BASE] + | blo ->fff_fallback + | checktp CARG2, LJ_TISNUM + | bhs ->fff_fallback + |.endmacro + | + |.macro .ffunc_dd, name + | .ffunc name + | ldr CARG2, [BASE, #4] + | ldr CARG4, [BASE, #12] + | cmp NARGS8:RC, #16 + | vldr d0, [BASE] + | vldr d1, [BASE, #8] + | blo ->fff_fallback + | checktp CARG2, LJ_TISNUM + | cmnlo CARG4, #-LJ_TISNUM + | bhs ->fff_fallback + |.endmacro + | + |// Inlined GC threshold check. Caveat: uses CARG1 and CARG2. + |.macro ffgccheck + | ldr CARG1, [DISPATCH, #DISPATCH_GL(gc.total)] + | ldr CARG2, [DISPATCH, #DISPATCH_GL(gc.threshold)] + | cmp CARG1, CARG2 + | blge ->fff_gcstep + |.endmacro + | + |//-- Base library: checks ----------------------------------------------- + | + |.ffunc_1 assert + | checktp CARG2, LJ_TTRUE + | bhi ->fff_fallback + | ldr PC, [BASE, FRAME_PC] + | strd CARG12, [BASE, #-8] + | mov RB, BASE + | subs RA, NARGS8:RC, #8 + | add RC, NARGS8:RC, #8 // Compute (nresults+1)*8. + | beq ->fff_res // Done if exactly 1 argument. + |1: + | ldrd CARG12, [RB, #8] + | subs RA, RA, #8 + | strd CARG12, [RB], #8 + | bne <1 + | b ->fff_res + | + |.ffunc type + | ldr CARG2, [BASE, #4] + | cmp NARGS8:RC, #8 + | blo ->fff_fallback + | checktp CARG2, LJ_TISNUM + | mvnlo CARG2, #~LJ_TISNUM + | rsb CARG4, CARG2, #(int)(offsetof(GCfuncC, upvalue)>>3)-1 + | lsl CARG4, CARG4, #3 + | ldrd CARG12, [CFUNC:CARG3, CARG4] + | b ->fff_restv + | + |//-- Base library: getters and setters --------------------------------- + | + |.ffunc_1 getmetatable + | checktp CARG2, LJ_TTAB + | cmnne CARG2, #-LJ_TUDATA + | bne >6 + |1: // Field metatable must be at same offset for GCtab and GCudata! + | ldr TAB:RB, TAB:CARG1->metatable + |2: + | mvn CARG2, #~LJ_TNIL + | ldr STR:RC, [DISPATCH, #DISPATCH_GL(gcroot[GCROOT_MMNAME+MM_metatable])] + | cmp TAB:RB, #0 + | beq ->fff_restv + | ldr CARG3, TAB:RB->hmask + | ldr CARG4, STR:RC->sid + | ldr NODE:INS, TAB:RB->node + | and CARG3, CARG3, CARG4 // idx = str->sid & tab->hmask + | add CARG3, CARG3, CARG3, lsl #1 + | add NODE:INS, NODE:INS, CARG3, lsl #3 // node = tab->node + idx*3*8 + |3: // Rearranged logic, because we expect _not_ to find the key. + | ldrd CARG34, NODE:INS->key // STALL: early NODE:INS. + | ldrd CARG12, NODE:INS->val + | ldr NODE:INS, NODE:INS->next + | checktp CARG4, LJ_TSTR + | cmpeq CARG3, STR:RC + | beq >5 + | cmp NODE:INS, #0 + | bne <3 + |4: + | mov CARG1, RB // Use metatable as default result. + | mvn CARG2, #~LJ_TTAB + | b ->fff_restv + |5: + | checktp CARG2, LJ_TNIL + | bne ->fff_restv + | b <4 + | + |6: + | checktp CARG2, LJ_TISNUM + | mvnhs CARG2, CARG2 + | movlo CARG2, #~LJ_TISNUM + | add CARG4, DISPATCH, CARG2, lsl #2 + | ldr TAB:RB, [CARG4, #DISPATCH_GL(gcroot[GCROOT_BASEMT])] + | b <2 + | + |.ffunc_2 setmetatable + | // Fast path: no mt for table yet and not clearing the mt. + | checktp CARG2, LJ_TTAB + | ldreq TAB:RB, TAB:CARG1->metatable + | checktpeq CARG4, LJ_TTAB + | ldrbeq CARG4, TAB:CARG1->marked + | cmpeq TAB:RB, #0 + | bne ->fff_fallback + | tst CARG4, #LJ_GC_BLACK // isblack(table) + | str TAB:CARG3, TAB:CARG1->metatable + | beq ->fff_restv + | barrierback TAB:CARG1, CARG4, CARG3 + | b ->fff_restv + | + |.ffunc rawget + | ldrd CARG34, [BASE] + | cmp NARGS8:RC, #16 + | blo ->fff_fallback + | mov CARG2, CARG3 + | checktab CARG4, ->fff_fallback + | mov CARG1, L + | add CARG3, BASE, #8 + | .IOS mov RA, BASE + | bl extern lj_tab_get // (lua_State *L, GCtab *t, cTValue *key) + | // Returns cTValue *. + | .IOS mov BASE, RA + | ldrd CARG12, [CRET1] + | b ->fff_restv + | + |//-- Base library: conversions ------------------------------------------ + | + |.ffunc tonumber + | // Only handles the number case inline (without a base argument). + | ldrd CARG12, [BASE] + | cmp NARGS8:RC, #8 + | bne ->fff_fallback + | checktp CARG2, LJ_TISNUM + | bls ->fff_restv + | b ->fff_fallback + | + |.ffunc_1 tostring + | // Only handles the string or number case inline. + | checktp CARG2, LJ_TSTR + | // A __tostring method in the string base metatable is ignored. + | beq ->fff_restv + | // Handle numbers inline, unless a number base metatable is present. + | ldr CARG4, [DISPATCH, #DISPATCH_GL(gcroot[GCROOT_BASEMT_NUM])] + | str BASE, L->base + | checktp CARG2, LJ_TISNUM + | cmpls CARG4, #0 + | str PC, SAVE_PC // Redundant (but a defined value). + | bhi ->fff_fallback + | ffgccheck + | mov CARG1, L + | mov CARG2, BASE + | bl extern lj_strfmt_number // (lua_State *L, cTValue *o) + | // Returns GCstr *. + | ldr BASE, L->base + | mvn CARG2, #~LJ_TSTR + | b ->fff_restv + | + |//-- Base library: iterators ------------------------------------------- + | + |.ffunc_1 next + | mvn CARG4, #~LJ_TNIL + | checktab CARG2, ->fff_fallback + | strd CARG34, [BASE, NARGS8:RC] // Set missing 2nd arg to nil. + | ldr PC, [BASE, FRAME_PC] + | add CARG2, BASE, #8 + | sub CARG3, BASE, #8 + | bl extern lj_tab_next // (GCtab *t, cTValue *key, TValue *o) + | // Returns 1=found, 0=end, -1=error. + | .IOS ldr BASE, L->base + | cmp CRET1, #0 + | mov RC, #(2+1)*8 + | bgt ->fff_res // Found key/value. + | bmi ->fff_fallback // Invalid key. + | // End of traversal: return nil. + | mvn CRET2, #~LJ_TNIL + | b ->fff_restv + | + |.ffunc_1 pairs + | checktab CARG2, ->fff_fallback +#if LJ_52 + | ldr TAB:RB, TAB:CARG1->metatable +#endif + | ldrd CFUNC:CARG34, CFUNC:CARG3->upvalue[0] + | ldr PC, [BASE, FRAME_PC] +#if LJ_52 + | cmp TAB:RB, #0 + | bne ->fff_fallback +#endif + | mvn CARG2, #~LJ_TNIL + | mov RC, #(3+1)*8 + | strd CFUNC:CARG34, [BASE, #-8] + | str CARG2, [BASE, #12] + | b ->fff_res + | + |.ffunc_2 ipairs_aux + | checktp CARG2, LJ_TTAB + | checktpeq CARG4, LJ_TISNUM + | bne ->fff_fallback + | ldr RB, TAB:CARG1->asize + | ldr RC, TAB:CARG1->array + | add CARG3, CARG3, #1 + | ldr PC, [BASE, FRAME_PC] + | cmp CARG3, RB + | add RC, RC, CARG3, lsl #3 + | strd CARG34, [BASE, #-8] + | ldrdlo CARG12, [RC] + | mov RC, #(0+1)*8 + | bhs >2 // Not in array part? + |1: + | checktp CARG2, LJ_TNIL + | movne RC, #(2+1)*8 + | strdne CARG12, [BASE] + | b ->fff_res + |2: // Check for empty hash part first. Otherwise call C function. + | ldr RB, TAB:CARG1->hmask + | mov CARG2, CARG3 + | cmp RB, #0 + | beq ->fff_res + | .IOS mov RA, BASE + | bl extern lj_tab_getinth // (GCtab *t, int32_t key) + | // Returns cTValue * or NULL. + | .IOS mov BASE, RA + | cmp CRET1, #0 + | beq ->fff_res + | ldrd CARG12, [CRET1] + | b <1 + | + |.ffunc_1 ipairs + | checktab CARG2, ->fff_fallback +#if LJ_52 + | ldr TAB:RB, TAB:CARG1->metatable +#endif + | ldrd CFUNC:CARG34, CFUNC:CARG3->upvalue[0] + | ldr PC, [BASE, FRAME_PC] +#if LJ_52 + | cmp TAB:RB, #0 + | bne ->fff_fallback +#endif + | mov CARG1, #0 + | mvn CARG2, #~LJ_TISNUM + | mov RC, #(3+1)*8 + | strd CFUNC:CARG34, [BASE, #-8] + | strd CARG12, [BASE, #8] + | b ->fff_res + | + |//-- Base library: catch errors ---------------------------------------- + | + |.ffunc pcall + | ldrb RA, [DISPATCH, #DISPATCH_GL(hookmask)] + | cmp NARGS8:RC, #8 + | blo ->fff_fallback + | tst RA, #HOOK_ACTIVE // Remember active hook before pcall. + | mov RB, BASE + | add BASE, BASE, #8 + | moveq PC, #8+FRAME_PCALL + | movne PC, #8+FRAME_PCALLH + | sub NARGS8:RC, NARGS8:RC, #8 + | b ->vm_call_dispatch + | + |.ffunc_2 xpcall + | ldrb RA, [DISPATCH, #DISPATCH_GL(hookmask)] + | checkfunc CARG4, ->fff_fallback // Traceback must be a function. + | mov RB, BASE + | strd CARG12, [BASE, #8] // Swap function and traceback. + | strd CARG34, [BASE] + | tst RA, #HOOK_ACTIVE // Remember active hook before pcall. + | add BASE, BASE, #16 + | moveq PC, #16+FRAME_PCALL + | movne PC, #16+FRAME_PCALLH + | sub NARGS8:RC, NARGS8:RC, #16 + | b ->vm_call_dispatch + | + |//-- Coroutine library -------------------------------------------------- + | + |.macro coroutine_resume_wrap, resume + |.if resume + |.ffunc_1 coroutine_resume + | checktp CARG2, LJ_TTHREAD + | bne ->fff_fallback + |.else + |.ffunc coroutine_wrap_aux + | ldr L:CARG1, CFUNC:CARG3->upvalue[0].gcr + |.endif + | ldr PC, [BASE, FRAME_PC] + | str BASE, L->base + | ldr CARG2, L:CARG1->top + | ldrb RA, L:CARG1->status + | ldr RB, L:CARG1->base + | add CARG3, CARG2, NARGS8:RC + | add CARG4, CARG2, RA + | str PC, SAVE_PC + | cmp CARG4, RB + | beq ->fff_fallback + | ldr CARG4, L:CARG1->maxstack + | ldr RB, L:CARG1->cframe + | cmp RA, #LUA_YIELD + | cmpls CARG3, CARG4 + | cmpls RB, #0 + | bhi ->fff_fallback + |1: + |.if resume + | sub CARG3, CARG3, #8 // Keep resumed thread in stack for GC. + | add BASE, BASE, #8 + | sub NARGS8:RC, NARGS8:RC, #8 + |.endif + | str CARG3, L:CARG1->top + | str BASE, L->top + |2: // Move args to coroutine. + | ldrd CARG34, [BASE, RB] + | cmp RB, NARGS8:RC + | strdne CARG34, [CARG2, RB] + | add RB, RB, #8 + | bne <2 + | + | mov CARG3, #0 + | mov L:RA, L:CARG1 + | mov CARG4, #0 + | bl ->vm_resume // (lua_State *L, TValue *base, 0, 0) + | // Returns thread status. + |4: + | ldr CARG3, L:RA->base + | mv_vmstate CARG2, INTERP + | ldr CARG4, L:RA->top + | cmp CRET1, #LUA_YIELD + | ldr BASE, L->base + | str L, [DISPATCH, #DISPATCH_GL(cur_L)] + | st_vmstate CARG2 + | bhi >8 + | subs RC, CARG4, CARG3 + | ldr CARG1, L->maxstack + | add CARG2, BASE, RC + | beq >6 // No results? + | cmp CARG2, CARG1 + | mov RB, #0 + | bhi >9 // Need to grow stack? + | + | sub CARG4, RC, #8 + | str CARG3, L:RA->top // Clear coroutine stack. + |5: // Move results from coroutine. + | ldrd CARG12, [CARG3, RB] + | cmp RB, CARG4 + | strd CARG12, [BASE, RB] + | add RB, RB, #8 + | bne <5 + |6: + |.if resume + | mvn CARG3, #~LJ_TTRUE + | add RC, RC, #16 + |7: + | str CARG3, [BASE, #-4] // Prepend true/false to results. + | sub RA, BASE, #8 + |.else + | mov RA, BASE + | add RC, RC, #8 + |.endif + | ands CARG1, PC, #FRAME_TYPE + | str PC, SAVE_PC + | str RC, SAVE_MULTRES + | beq ->BC_RET_Z + | b ->vm_return + | + |8: // Coroutine returned with error (at co->top-1). + |.if resume + | ldrd CARG12, [CARG4, #-8]! + | mvn CARG3, #~LJ_TFALSE + | mov RC, #(2+1)*8 + | str CARG4, L:RA->top // Remove error from coroutine stack. + | strd CARG12, [BASE] // Copy error message. + | b <7 + |.else + | mov CARG1, L + | mov CARG2, L:RA + | bl extern lj_ffh_coroutine_wrap_err // (lua_State *L, lua_State *co) + | // Never returns. + |.endif + | + |9: // Handle stack expansion on return from yield. + | mov CARG1, L + | lsr CARG2, RC, #3 + | bl extern lj_state_growstack // (lua_State *L, int n) + | mov CRET1, #0 + | b <4 + |.endmacro + | + | coroutine_resume_wrap 1 // coroutine.resume + | coroutine_resume_wrap 0 // coroutine.wrap + | + |.ffunc coroutine_yield + | ldr CARG1, L->cframe + | add CARG2, BASE, NARGS8:RC + | str BASE, L->base + | tst CARG1, #CFRAME_RESUME + | str CARG2, L->top + | mov CRET1, #LUA_YIELD + | mov CARG3, #0 + | beq ->fff_fallback + | str CARG3, L->cframe + | strb CRET1, L->status + | b ->vm_leave_unw + | + |//-- Math library ------------------------------------------------------- + | + |.macro math_round, func + | .ffunc_1 math_ .. func + | checktp CARG2, LJ_TISNUM + | beq ->fff_restv + | bhi ->fff_fallback + | // Round FP value and normalize result. + | lsl CARG3, CARG2, #1 + | adds RB, CARG3, #0x00200000 + | bpl >2 // |x| < 1? + | mvn CARG4, #0x3e0 + | subs RB, CARG4, RB, asr #21 + | lsl CARG4, CARG2, #11 + | lsl CARG3, CARG1, #11 + | orr CARG4, CARG4, #0x80000000 + | rsb INS, RB, #32 + | orr CARG4, CARG4, CARG1, lsr #21 + | bls >3 // |x| >= 2^31? + | orr CARG3, CARG3, CARG4, lsl INS + | lsr CARG1, CARG4, RB + |.if "func" == "floor" + | tst CARG3, CARG2, asr #31 + | addne CARG1, CARG1, #1 + |.else + | bics CARG3, CARG3, CARG2, asr #31 + | addsne CARG1, CARG1, #1 + | ldrdvs CARG12, >9 + | bvs ->fff_restv + |.endif + | cmp CARG2, #0 + | rsblt CARG1, CARG1, #0 + |1: + | mvn CARG2, #~LJ_TISNUM + | b ->fff_restv + | + |2: // |x| < 1 + | bcs ->fff_restv // |x| is not finite. + | orr CARG3, CARG3, CARG1 // ztest = abs(hi) | lo + |.if "func" == "floor" + | tst CARG3, CARG2, asr #31 // return (ztest & sign) == 0 ? 0 : -1 + | moveq CARG1, #0 + | mvnne CARG1, #0 + |.else + | bics CARG3, CARG3, CARG2, asr #31 // return (ztest & ~sign) == 0 ? 0 : 1 + | moveq CARG1, #0 + | movne CARG1, #1 + |.endif + | mvn CARG2, #~LJ_TISNUM + | b ->fff_restv + | + |3: // |x| >= 2^31. Check for x == -(2^31). + | cmpeq CARG4, #0x80000000 + |.if "func" == "floor" + | cmpeq CARG3, #0 + |.endif + | bne >4 + | cmp CARG2, #0 + | movmi CARG1, #0x80000000 + | bmi <1 + |4: + | bl ->vm_..func.._sf + | b ->fff_restv + |.endmacro + | + | math_round floor + | math_round ceil + | + |.align 8 + |9: + | .long 0x00000000, 0x41e00000 // 2^31. + | + |.ffunc_1 math_abs + | checktp CARG2, LJ_TISNUM + | bhi ->fff_fallback + | bicne CARG2, CARG2, #0x80000000 + | bne ->fff_restv + | cmp CARG1, #0 + | rsbslt CARG1, CARG1, #0 + | ldrdvs CARG12, <9 + | // Fallthrough. + | + |->fff_restv: + | // CARG12 = TValue result. + | ldr PC, [BASE, FRAME_PC] + | strd CARG12, [BASE, #-8] + |->fff_res1: + | // PC = return. + | mov RC, #(1+1)*8 + |->fff_res: + | // RC = (nresults+1)*8, PC = return. + | ands CARG1, PC, #FRAME_TYPE + | ldreq INS, [PC, #-4] + | str RC, SAVE_MULTRES + | sub RA, BASE, #8 + | bne ->vm_return + | decode_RB8 RB, INS + |5: + | cmp RB, RC // More results expected? + | bhi >6 + | decode_RA8 CARG1, INS + | ins_next1 + | ins_next2 + | // Adjust BASE. KBASE is assumed to be set for the calling frame. + | sub BASE, RA, CARG1 + | ins_next3 + | + |6: // Fill up results with nil. + | add CARG2, RA, RC + | mvn CARG1, #~LJ_TNIL + | add RC, RC, #8 + | str CARG1, [CARG2, #-4] + | b <5 + | + |.macro math_extern, func + |.if HFABI + | .ffunc_d math_ .. func + |.else + | .ffunc_n math_ .. func + |.endif + | .IOS mov RA, BASE + | bl extern func + | .IOS mov BASE, RA + |.if HFABI + | b ->fff_resd + |.else + | b ->fff_restv + |.endif + |.endmacro + | + |.macro math_extern2, func + |.if HFABI + | .ffunc_dd math_ .. func + |.else + | .ffunc_nn math_ .. func + |.endif + | .IOS mov RA, BASE + | bl extern func + | .IOS mov BASE, RA + |.if HFABI + | b ->fff_resd + |.else + | b ->fff_restv + |.endif + |.endmacro + | + |.if FPU + | .ffunc_d math_sqrt + | vsqrt.f64 d0, d0 + |->fff_resd: + | ldr PC, [BASE, FRAME_PC] + | vstr d0, [BASE, #-8] + | b ->fff_res1 + |.else + | math_extern sqrt + |.endif + | + |.ffunc math_log + |.if HFABI + | ldr CARG2, [BASE, #4] + | cmp NARGS8:RC, #8 // Need exactly 1 argument. + | vldr d0, [BASE] + | bne ->fff_fallback + |.else + | ldrd CARG12, [BASE] + | cmp NARGS8:RC, #8 // Need exactly 1 argument. + | bne ->fff_fallback + |.endif + | checktp CARG2, LJ_TISNUM + | bhs ->fff_fallback + | .IOS mov RA, BASE + | bl extern log + | .IOS mov BASE, RA + |.if HFABI + | b ->fff_resd + |.else + | b ->fff_restv + |.endif + | + | math_extern log10 + | math_extern exp + | math_extern sin + | math_extern cos + | math_extern tan + | math_extern asin + | math_extern acos + | math_extern atan + | math_extern sinh + | math_extern cosh + | math_extern tanh + | math_extern2 pow + | math_extern2 atan2 + | math_extern2 fmod + | + |.if HFABI + | .ffunc math_ldexp + | ldr CARG4, [BASE, #4] + | ldrd CARG12, [BASE, #8] + | cmp NARGS8:RC, #16 + | blo ->fff_fallback + | vldr d0, [BASE] + | checktp CARG4, LJ_TISNUM + | bhs ->fff_fallback + | checktp CARG2, LJ_TISNUM + | bne ->fff_fallback + | .IOS mov RA, BASE + | bl extern ldexp // (double x, int exp) + | .IOS mov BASE, RA + | b ->fff_resd + |.else + |.ffunc_2 math_ldexp + | checktp CARG2, LJ_TISNUM + | bhs ->fff_fallback + | checktp CARG4, LJ_TISNUM + | bne ->fff_fallback + | .IOS mov RA, BASE + | bl extern ldexp // (double x, int exp) + | .IOS mov BASE, RA + | b ->fff_restv + |.endif + | + |.if HFABI + |.ffunc_d math_frexp + | mov CARG1, sp + | .IOS mov RA, BASE + | bl extern frexp + | .IOS mov BASE, RA + | ldr CARG3, [sp] + | mvn CARG4, #~LJ_TISNUM + | ldr PC, [BASE, FRAME_PC] + | vstr d0, [BASE, #-8] + | mov RC, #(2+1)*8 + | strd CARG34, [BASE] + | b ->fff_res + |.else + |.ffunc_n math_frexp + | mov CARG3, sp + | .IOS mov RA, BASE + | bl extern frexp + | .IOS mov BASE, RA + | ldr CARG3, [sp] + | mvn CARG4, #~LJ_TISNUM + | ldr PC, [BASE, FRAME_PC] + | strd CARG12, [BASE, #-8] + | mov RC, #(2+1)*8 + | strd CARG34, [BASE] + | b ->fff_res + |.endif + | + |.if HFABI + |.ffunc_d math_modf + | sub CARG1, BASE, #8 + | ldr PC, [BASE, FRAME_PC] + | .IOS mov RA, BASE + | bl extern modf + | .IOS mov BASE, RA + | mov RC, #(2+1)*8 + | vstr d0, [BASE] + | b ->fff_res + |.else + |.ffunc_n math_modf + | sub CARG3, BASE, #8 + | ldr PC, [BASE, FRAME_PC] + | .IOS mov RA, BASE + | bl extern modf + | .IOS mov BASE, RA + | mov RC, #(2+1)*8 + | strd CARG12, [BASE] + | b ->fff_res + |.endif + | + |.macro math_minmax, name, cond, fcond + |.if FPU + | .ffunc_1 name + | add RB, BASE, RC + | checktp CARG2, LJ_TISNUM + | add RA, BASE, #8 + | bne >4 + |1: // Handle integers. + | ldrd CARG34, [RA] + | cmp RA, RB + | bhs ->fff_restv + | checktp CARG4, LJ_TISNUM + | bne >3 + | cmp CARG1, CARG3 + | add RA, RA, #8 + | mov..cond CARG1, CARG3 + | b <1 + |3: // Convert intermediate result to number and continue below. + | vmov s4, CARG1 + | bhi ->fff_fallback + | vldr d1, [RA] + | vcvt.f64.s32 d0, s4 + | b >6 + | + |4: + | vldr d0, [BASE] + | bhi ->fff_fallback + |5: // Handle numbers. + | ldrd CARG34, [RA] + | vldr d1, [RA] + | cmp RA, RB + | bhs ->fff_resd + | checktp CARG4, LJ_TISNUM + | bhs >7 + |6: + | vcmp.f64 d0, d1 + | vmrs + | add RA, RA, #8 + | vmov..fcond.f64 d0, d1 + | b <5 + |7: // Convert integer to number and continue above. + | vmov s4, CARG3 + | bhi ->fff_fallback + | vcvt.f64.s32 d1, s4 + | b <6 + | + |.else + | + | .ffunc_1 name + | checktp CARG2, LJ_TISNUM + | mov RA, #8 + | bne >4 + |1: // Handle integers. + | ldrd CARG34, [BASE, RA] + | cmp RA, RC + | bhs ->fff_restv + | checktp CARG4, LJ_TISNUM + | bne >3 + | cmp CARG1, CARG3 + | add RA, RA, #8 + | mov..cond CARG1, CARG3 + | b <1 + |3: // Convert intermediate result to number and continue below. + | bhi ->fff_fallback + | bl extern __aeabi_i2d + | ldrd CARG34, [BASE, RA] + | b >6 + | + |4: + | bhi ->fff_fallback + |5: // Handle numbers. + | ldrd CARG34, [BASE, RA] + | cmp RA, RC + | bhs ->fff_restv + | checktp CARG4, LJ_TISNUM + | bhs >7 + |6: + | bl extern __aeabi_cdcmple + | add RA, RA, #8 + | mov..fcond CARG1, CARG3 + | mov..fcond CARG2, CARG4 + | b <5 + |7: // Convert integer to number and continue above. + | bhi ->fff_fallback + | strd CARG12, TMPD + | mov CARG1, CARG3 + | bl extern __aeabi_i2d + | ldrd CARG34, TMPD + | b <6 + |.endif + |.endmacro + | + | math_minmax math_min, gt, pl + | math_minmax math_max, lt, le + | + |//-- String library ----------------------------------------------------- + | + |.ffunc string_byte // Only handle the 1-arg case here. + | ldrd CARG12, [BASE] + | ldr PC, [BASE, FRAME_PC] + | cmp NARGS8:RC, #8 + | checktpeq CARG2, LJ_TSTR // Need exactly 1 argument. + | bne ->fff_fallback + | ldr CARG3, STR:CARG1->len + | ldrb CARG1, STR:CARG1[1] // Access is always ok (NUL at end). + | mvn CARG2, #~LJ_TISNUM + | cmp CARG3, #0 + | moveq RC, #(0+1)*8 + | movne RC, #(1+1)*8 + | strd CARG12, [BASE, #-8] + | b ->fff_res + | + |.ffunc string_char // Only handle the 1-arg case here. + | ffgccheck + | ldrd CARG12, [BASE] + | ldr PC, [BASE, FRAME_PC] + | cmp NARGS8:RC, #8 // Need exactly 1 argument. + | checktpeq CARG2, LJ_TISNUM + | bicseq CARG4, CARG1, #255 + | mov CARG3, #1 + | bne ->fff_fallback + | str CARG1, TMPD + | mov CARG2, TMPDp // Points to stack. Little-endian. + |->fff_newstr: + | // CARG2 = str, CARG3 = len. + | str BASE, L->base + | mov CARG1, L + | str PC, SAVE_PC + | bl extern lj_str_new // (lua_State *L, char *str, size_t l) + |->fff_resstr: + | // Returns GCstr *. + | ldr BASE, L->base + | mvn CARG2, #~LJ_TSTR + | b ->fff_restv + | + |.ffunc string_sub + | ffgccheck + | ldrd CARG12, [BASE] + | ldrd CARG34, [BASE, #16] + | cmp NARGS8:RC, #16 + | mvn RB, #0 + | beq >1 + | blo ->fff_fallback + | checktp CARG4, LJ_TISNUM + | mov RB, CARG3 + | bne ->fff_fallback + |1: + | ldrd CARG34, [BASE, #8] + | checktp CARG2, LJ_TSTR + | ldreq CARG2, STR:CARG1->len + | checktpeq CARG4, LJ_TISNUM + | bne ->fff_fallback + | // CARG1 = str, CARG2 = str->len, CARG3 = start, RB = end + | add CARG4, CARG2, #1 + | cmp CARG3, #0 // if (start < 0) start += len+1 + | addlt CARG3, CARG3, CARG4 + | cmp CARG3, #1 // if (start < 1) start = 1 + | movlt CARG3, #1 + | cmp RB, #0 // if (end < 0) end += len+1 + | addlt RB, RB, CARG4 + | bic RB, RB, RB, asr #31 // if (end < 0) end = 0 + | cmp RB, CARG2 // if (end > len) end = len + | add CARG1, STR:CARG1, #sizeof(GCstr)-1 + | movgt RB, CARG2 + | add CARG2, CARG1, CARG3 + | subs CARG3, RB, CARG3 // len = end - start + | add CARG3, CARG3, #1 // len += 1 + | bge ->fff_newstr + |->fff_emptystr: + | sub STR:CARG1, DISPATCH, #-DISPATCH_GL(strempty) + | mvn CARG2, #~LJ_TSTR + | b ->fff_restv + | + |.macro ffstring_op, name + | .ffunc string_ .. name + | ffgccheck + | ldr CARG3, [BASE, #4] + | cmp NARGS8:RC, #8 + | ldr STR:CARG2, [BASE] + | blo ->fff_fallback + | sub SBUF:CARG1, DISPATCH, #-DISPATCH_GL(tmpbuf) + | checkstr CARG3, ->fff_fallback + | ldr CARG4, SBUF:CARG1->b + | str BASE, L->base + | str PC, SAVE_PC + | str L, SBUF:CARG1->L + | str CARG4, SBUF:CARG1->w + | bl extern lj_buf_putstr_ .. name + | bl extern lj_buf_tostr + | b ->fff_resstr + |.endmacro + | + |ffstring_op reverse + |ffstring_op lower + |ffstring_op upper + | + |//-- Bit library -------------------------------------------------------- + | + |// FP number to bit conversion for soft-float. Clobbers r0-r3. + |->vm_tobit_fb: + | bhi ->fff_fallback + |->vm_tobit: + | lsl RB, CARG2, #1 + | adds RB, RB, #0x00200000 + | movpl CARG1, #0 // |x| < 1? + | bxpl lr + | mvn CARG4, #0x3e0 + | subs RB, CARG4, RB, asr #21 + | bmi >1 // |x| >= 2^32? + | lsl CARG4, CARG2, #11 + | orr CARG4, CARG4, #0x80000000 + | orr CARG4, CARG4, CARG1, lsr #21 + | cmp CARG2, #0 + | lsr CARG1, CARG4, RB + | rsblt CARG1, CARG1, #0 + | bx lr + |1: + | add RB, RB, #21 + | lsr CARG4, CARG1, RB + | rsb RB, RB, #20 + | lsl CARG1, CARG2, #12 + | cmp CARG2, #0 + | orr CARG1, CARG4, CARG1, lsl RB + | rsblt CARG1, CARG1, #0 + | bx lr + | + |.macro .ffunc_bit, name + | .ffunc_1 bit_..name + | checktp CARG2, LJ_TISNUM + | blne ->vm_tobit_fb + |.endmacro + | + |.ffunc_bit tobit + | mvn CARG2, #~LJ_TISNUM + | b ->fff_restv + | + |.macro .ffunc_bit_op, name, ins + | .ffunc_bit name + | mov CARG3, CARG1 + | mov RA, #8 + |1: + | ldrd CARG12, [BASE, RA] + | cmp RA, NARGS8:RC + | add RA, RA, #8 + | bge >2 + | checktp CARG2, LJ_TISNUM + | blne ->vm_tobit_fb + | ins CARG3, CARG3, CARG1 + | b <1 + |.endmacro + | + |.ffunc_bit_op band, and + |.ffunc_bit_op bor, orr + |.ffunc_bit_op bxor, eor + | + |2: + | mvn CARG4, #~LJ_TISNUM + | ldr PC, [BASE, FRAME_PC] + | strd CARG34, [BASE, #-8] + | b ->fff_res1 + | + |.ffunc_bit bswap + | eor CARG3, CARG1, CARG1, ror #16 + | bic CARG3, CARG3, #0x00ff0000 + | ror CARG1, CARG1, #8 + | mvn CARG2, #~LJ_TISNUM + | eor CARG1, CARG1, CARG3, lsr #8 + | b ->fff_restv + | + |.ffunc_bit bnot + | mvn CARG1, CARG1 + | mvn CARG2, #~LJ_TISNUM + | b ->fff_restv + | + |.macro .ffunc_bit_sh, name, ins, shmod + | .ffunc bit_..name + | ldrd CARG12, [BASE, #8] + | cmp NARGS8:RC, #16 + | blo ->fff_fallback + | checktp CARG2, LJ_TISNUM + | blne ->vm_tobit_fb + |.if shmod == 0 + | and RA, CARG1, #31 + |.else + | rsb RA, CARG1, #0 + |.endif + | ldrd CARG12, [BASE] + | checktp CARG2, LJ_TISNUM + | blne ->vm_tobit_fb + | ins CARG1, CARG1, RA + | mvn CARG2, #~LJ_TISNUM + | b ->fff_restv + |.endmacro + | + |.ffunc_bit_sh lshift, lsl, 0 + |.ffunc_bit_sh rshift, lsr, 0 + |.ffunc_bit_sh arshift, asr, 0 + |.ffunc_bit_sh rol, ror, 1 + |.ffunc_bit_sh ror, ror, 0 + | + |//----------------------------------------------------------------------- + | + |->fff_fallback: // Call fast function fallback handler. + | // BASE = new base, RC = nargs*8 + | ldr CARG3, [BASE, FRAME_FUNC] + | ldr CARG2, L->maxstack + | add CARG1, BASE, NARGS8:RC + | ldr PC, [BASE, FRAME_PC] // Fallback may overwrite PC. + | str CARG1, L->top + | ldr CARG3, CFUNC:CARG3->f + | str BASE, L->base + | add CARG1, CARG1, #8*LUA_MINSTACK + | str PC, SAVE_PC // Redundant (but a defined value). + | cmp CARG1, CARG2 + | mov CARG1, L + | bhi >5 // Need to grow stack. + | blx CARG3 // (lua_State *L) + | // Either throws an error, or recovers and returns -1, 0 or nresults+1. + | ldr BASE, L->base + | cmp CRET1, #0 + | lsl RC, CRET1, #3 + | sub RA, BASE, #8 + | bgt ->fff_res // Returned nresults+1? + |1: // Returned 0 or -1: retry fast path. + | ldr CARG1, L->top + | ldr LFUNC:CARG3, [BASE, FRAME_FUNC] + | sub NARGS8:RC, CARG1, BASE + | bne ->vm_call_tail // Returned -1? + | ins_callt // Returned 0: retry fast path. + | + |// Reconstruct previous base for vmeta_call during tailcall. + |->vm_call_tail: + | ands CARG1, PC, #FRAME_TYPE + | bic CARG2, PC, #FRAME_TYPEP + | ldreq INS, [PC, #-4] + | andeq CARG2, MASKR8, INS, lsr #5 // Conditional decode_RA8. + | addeq CARG2, CARG2, #8 + | sub RB, BASE, CARG2 + | b ->vm_call_dispatch // Resolve again for tailcall. + | + |5: // Grow stack for fallback handler. + | mov CARG2, #LUA_MINSTACK + | bl extern lj_state_growstack // (lua_State *L, int n) + | ldr BASE, L->base + | cmp CARG1, CARG1 // Set zero-flag to force retry. + | b <1 + | + |->fff_gcstep: // Call GC step function. + | // BASE = new base, RC = nargs*8 + | mov RA, lr + | str BASE, L->base + | add CARG2, BASE, NARGS8:RC + | str PC, SAVE_PC // Redundant (but a defined value). + | str CARG2, L->top + | mov CARG1, L + | bl extern lj_gc_step // (lua_State *L) + | ldr BASE, L->base + | mov lr, RA // Help return address predictor. + | ldr CFUNC:CARG3, [BASE, FRAME_FUNC] + | bx lr + | + |//----------------------------------------------------------------------- + |//-- Special dispatch targets ------------------------------------------- + |//----------------------------------------------------------------------- + | + |->vm_record: // Dispatch target for recording phase. + |.if JIT + | ldrb CARG1, [DISPATCH, #DISPATCH_GL(hookmask)] + | tst CARG1, #HOOK_VMEVENT // No recording while in vmevent. + | bne >5 + | // Decrement the hookcount for consistency, but always do the call. + | ldr CARG2, [DISPATCH, #DISPATCH_GL(hookcount)] + | tst CARG1, #HOOK_ACTIVE + | bne >1 + | sub CARG2, CARG2, #1 + | tst CARG1, #LUA_MASKLINE|LUA_MASKCOUNT + | strne CARG2, [DISPATCH, #DISPATCH_GL(hookcount)] + | b >1 + |.endif + | + |->vm_rethook: // Dispatch target for return hooks. + | ldrb CARG1, [DISPATCH, #DISPATCH_GL(hookmask)] + | tst CARG1, #HOOK_ACTIVE // Hook already active? + | beq >1 + |5: // Re-dispatch to static ins. + | decode_OP OP, INS + | add OP, DISPATCH, OP, lsl #2 + | ldr pc, [OP, #GG_DISP2STATIC] + | + |->vm_inshook: // Dispatch target for instr/line hooks. + | ldrb CARG1, [DISPATCH, #DISPATCH_GL(hookmask)] + | ldr CARG2, [DISPATCH, #DISPATCH_GL(hookcount)] + | tst CARG1, #HOOK_ACTIVE // Hook already active? + | bne <5 + | tst CARG1, #LUA_MASKLINE|LUA_MASKCOUNT + | beq <5 + | subs CARG2, CARG2, #1 + | str CARG2, [DISPATCH, #DISPATCH_GL(hookcount)] + | beq >1 + | tst CARG1, #LUA_MASKLINE + | beq <5 + |1: + | mov CARG1, L + | str BASE, L->base + | mov CARG2, PC + | // SAVE_PC must hold the _previous_ PC. The callee updates it with PC. + | bl extern lj_dispatch_ins // (lua_State *L, const BCIns *pc) + |3: + | ldr BASE, L->base + |4: // Re-dispatch to static ins. + | ldrb OP, [PC, #-4] + | ldr INS, [PC, #-4] + | add OP, DISPATCH, OP, lsl #2 + | ldr OP, [OP, #GG_DISP2STATIC] + | decode_RA8 RA, INS + | decode_RD RC, INS + | bx OP + | + |->cont_hook: // Continue from hook yield. + | ldr CARG1, [CARG4, #-24] + | add PC, PC, #4 + | str CARG1, SAVE_MULTRES // Restore MULTRES for *M ins. + | b <4 + | + |->vm_hotloop: // Hot loop counter underflow. + |.if JIT + | ldr LFUNC:CARG3, [BASE, FRAME_FUNC] // Same as curr_topL(L). + | sub CARG1, DISPATCH, #-GG_DISP2J + | str PC, SAVE_PC + | ldr CARG3, LFUNC:CARG3->field_pc + | mov CARG2, PC + | str L, [DISPATCH, #DISPATCH_J(L)] + | ldrb CARG3, [CARG3, #PC2PROTO(framesize)] + | str BASE, L->base + | add CARG3, BASE, CARG3, lsl #3 + | str CARG3, L->top + | bl extern lj_trace_hot // (jit_State *J, const BCIns *pc) + | b <3 + |.endif + | + |->vm_callhook: // Dispatch target for call hooks. + | mov CARG2, PC + |.if JIT + | b >1 + |.endif + | + |->vm_hotcall: // Hot call counter underflow. + |.if JIT + | orr CARG2, PC, #1 + |1: + |.endif + | add CARG4, BASE, RC + | str PC, SAVE_PC + | mov CARG1, L + | str BASE, L->base + | sub RA, RA, BASE + | str CARG4, L->top + | bl extern lj_dispatch_call // (lua_State *L, const BCIns *pc) + | // Returns ASMFunction. + | ldr BASE, L->base + | ldr CARG4, L->top + | mov CARG2, #0 + | add RA, BASE, RA + | sub NARGS8:RC, CARG4, BASE + | str CARG2, SAVE_PC // Invalidate for subsequent line hook. + | ldr LFUNC:CARG3, [BASE, FRAME_FUNC] + | ldr INS, [PC, #-4] + | bx CRET1 + | + |->cont_stitch: // Trace stitching. + |.if JIT + | // RA = resultptr, CARG4 = meta base + | ldr RB, SAVE_MULTRES + | ldr INS, [PC, #-4] + | ldr TRACE:CARG3, [CARG4, #-24] // Save previous trace. + | subs RB, RB, #8 + | decode_RA8 RC, INS // Call base. + | beq >2 + |1: // Move results down. + | ldrd CARG12, [RA] + | add RA, RA, #8 + | subs RB, RB, #8 + | strd CARG12, [BASE, RC] + | add RC, RC, #8 + | bne <1 + |2: + | decode_RA8 RA, INS + | decode_RB8 RB, INS + | add RA, RA, RB + |3: + | cmp RA, RC + | mvn CARG2, #~LJ_TNIL + | bhi >9 // More results wanted? + | + | ldrh RA, TRACE:CARG3->traceno + | ldrh RC, TRACE:CARG3->link + | cmp RC, RA + | beq ->cont_nop // Blacklisted. + | cmp RC, #0 + | bne =>BC_JLOOP // Jump to stitched trace. + | + | // Stitch a new trace to the previous trace. + | str RA, [DISPATCH, #DISPATCH_J(exitno)] + | str L, [DISPATCH, #DISPATCH_J(L)] + | str BASE, L->base + | sub CARG1, DISPATCH, #-GG_DISP2J + | mov CARG2, PC + | bl extern lj_dispatch_stitch // (jit_State *J, const BCIns *pc) + | ldr BASE, L->base + | b ->cont_nop + | + |9: // Fill up results with nil. + | strd CARG12, [BASE, RC] + | add RC, RC, #8 + | b <3 + |.endif + | + |->vm_profhook: // Dispatch target for profiler hook. +#if LJ_HASPROFILE + | mov CARG1, L + | str BASE, L->base + | mov CARG2, PC + | bl extern lj_dispatch_profile // (lua_State *L, const BCIns *pc) + | // HOOK_PROFILE is off again, so re-dispatch to dynamic instruction. + | ldr BASE, L->base + | sub PC, PC, #4 + | b ->cont_nop +#endif + | + |//----------------------------------------------------------------------- + |//-- Trace exit handler ------------------------------------------------- + |//----------------------------------------------------------------------- + | + |->vm_exit_handler: + |.if JIT + | sub sp, sp, #12 + | push {r0,r1,r2,r3,r4,r5,r6,r7,r8,r9,r10,r11,r12} + | ldr CARG1, [sp, #64] // Load original value of lr. + | ldr DISPATCH, [lr] // Load DISPATCH. + | add CARG3, sp, #64 // Recompute original value of sp. + | mv_vmstate CARG4, EXIT + | str CARG3, [sp, #52] // Store sp in RID_SP + | st_vmstate CARG4 + | ldr CARG2, [CARG1, #-4]! // Get exit instruction. + | str CARG1, [sp, #56] // Store exit pc in RID_LR and RID_PC. + | str CARG1, [sp, #60] + |.if FPU + | vpush {d0-d15} + |.endif + | lsl CARG2, CARG2, #8 + | add CARG1, CARG1, CARG2, asr #6 + | ldr CARG2, [lr, #4] // Load exit stub group offset. + | sub CARG1, CARG1, lr + | ldr L, [DISPATCH, #DISPATCH_GL(cur_L)] + | add CARG1, CARG2, CARG1, lsr #2 // Compute exit number. + | ldr BASE, [DISPATCH, #DISPATCH_GL(jit_base)] + | str CARG1, [DISPATCH, #DISPATCH_J(exitno)] + | mov CARG4, #0 + | str BASE, L->base + | str L, [DISPATCH, #DISPATCH_J(L)] + | str CARG4, [DISPATCH, #DISPATCH_GL(jit_base)] + | sub CARG1, DISPATCH, #-GG_DISP2J + | mov CARG2, sp + | bl extern lj_trace_exit // (jit_State *J, ExitState *ex) + | // Returns MULTRES (unscaled) or negated error code. + | ldr CARG2, L->cframe + | ldr BASE, L->base + | bic CARG2, CARG2, #~CFRAME_RAWMASK // Use two steps: bic sp is deprecated. + | mov sp, CARG2 + | ldr PC, SAVE_PC // Get SAVE_PC. + | str L, SAVE_L // Set SAVE_L (on-trace resume/yield). + | b >1 + |.endif + |->vm_exit_interp: + | // CARG1 = MULTRES or negated error code, BASE, PC and DISPATCH set. + |.if JIT + | ldr L, SAVE_L + |1: + | cmp CARG1, #0 + | blt >9 // Check for error from exit. + | lsl RC, CARG1, #3 + | ldr LFUNC:CARG2, [BASE, FRAME_FUNC] + | str RC, SAVE_MULTRES + | mov CARG3, #0 + | str BASE, L->base + | ldr CARG2, LFUNC:CARG2->field_pc + | str CARG3, [DISPATCH, #DISPATCH_GL(jit_base)] + | mv_vmstate CARG4, INTERP + | ldr KBASE, [CARG2, #PC2PROTO(k)] + | // Modified copy of ins_next which handles function header dispatch, too. + | ldrb OP, [PC] + | mov MASKR8, #255 + | ldr INS, [PC], #4 + | lsl MASKR8, MASKR8, #3 // MASKR8 = 255*8. + | st_vmstate CARG4 + | cmp OP, #BC_FUNCC+2 // Fast function? + | bhs >4 + |2: + | cmp OP, #BC_FUNCF // Function header? + | ldr OP, [DISPATCH, OP, lsl #2] + | decode_RA8 RA, INS + | lsrlo RC, INS, #16 // No: Decode operands A*8 and D. + | subhs RC, RC, #8 + | addhs RA, RA, BASE // Yes: RA = BASE+framesize*8, RC = nargs*8 + | ldrhs CARG3, [BASE, FRAME_FUNC] + | bx OP + | + |4: // Check frame below fast function. + | ldr CARG1, [BASE, FRAME_PC] + | ands CARG2, CARG1, #FRAME_TYPE + | bne <2 // Trace stitching continuation? + | // Otherwise set KBASE for Lua function below fast function. + | ldr CARG3, [CARG1, #-4] + | decode_RA8 CARG1, CARG3 + | sub CARG2, BASE, CARG1 + | ldr LFUNC:CARG3, [CARG2, #-16] + | ldr CARG3, LFUNC:CARG3->field_pc + | ldr KBASE, [CARG3, #PC2PROTO(k)] + | b <2 + | + |9: // Rethrow error from the right C frame. + | rsb CARG2, CARG1, #0 + | mov CARG1, L + | bl extern lj_err_trace // (lua_State *L, int errcode) + |.endif + | + |//----------------------------------------------------------------------- + |//-- Math helper functions ---------------------------------------------- + |//----------------------------------------------------------------------- + | + |// FP value rounding. Called from JIT code. + |// + |// double lj_vm_floor/ceil/trunc(double x); + |.macro vm_round, func, hf + |.if hf == 1 + | vmov CARG1, CARG2, d0 + |.endif + | lsl CARG3, CARG2, #1 + | adds RB, CARG3, #0x00200000 + | bpl >2 // |x| < 1? + | mvn CARG4, #0x3cc + | subs RB, CARG4, RB, asr #21 // 2^0: RB = 51, 2^51: RB = 0. + | bxlo lr // |x| >= 2^52: done. + | mvn CARG4, #1 + | bic CARG3, CARG1, CARG4, lsl RB // ztest = lo & ~lomask + | and CARG1, CARG1, CARG4, lsl RB // lo &= lomask + | subs RB, RB, #32 + | bicpl CARG4, CARG2, CARG4, lsl RB // |x| <= 2^20: ztest |= hi & ~himask + | orrpl CARG3, CARG3, CARG4 + | mvnpl CARG4, #1 + | andpl CARG2, CARG2, CARG4, lsl RB // |x| <= 2^20: hi &= himask + |.if "func" == "floor" + | tst CARG3, CARG2, asr #31 // iszero = ((ztest & signmask) == 0) + |.else + | bics CARG3, CARG3, CARG2, asr #31 // iszero = ((ztest & ~signmask) == 0) + |.endif + |.if hf == 1 + | vmoveq d0, CARG1, CARG2 + |.endif + | bxeq lr // iszero: done. + | mvn CARG4, #1 + | cmp RB, #0 + | lslpl CARG3, CARG4, RB + | mvnmi CARG3, #0 + | add RB, RB, #32 + | subs CARG1, CARG1, CARG4, lsl RB // lo = lo-lomask + | sbc CARG2, CARG2, CARG3 // hi = hi-himask+carry + |.if hf == 1 + | vmov d0, CARG1, CARG2 + |.endif + | bx lr + | + |2: // |x| < 1: + | bxcs lr // |x| is not finite. + | orr CARG3, CARG3, CARG1 // ztest = (2*hi) | lo + |.if "func" == "floor" + | tst CARG3, CARG2, asr #31 // iszero = ((ztest & signmask) == 0) + |.else + | bics CARG3, CARG3, CARG2, asr #31 // iszero = ((ztest & ~signmask) == 0) + |.endif + | mov CARG1, #0 // lo = 0 + | and CARG2, CARG2, #0x80000000 + | ldrne CARG4, <9 // hi = sign(x) | (iszero ? 0.0 : 1.0) + | orrne CARG2, CARG2, CARG4 + |.if hf == 1 + | vmov d0, CARG1, CARG2 + |.endif + | bx lr + |.endmacro + | + |9: + | .long 0x3ff00000 // hiword(+1.0) + | + |->vm_floor: + |.if HFABI + | vm_round floor, 1 + |.endif + |->vm_floor_sf: + | vm_round floor, 0 + | + |->vm_ceil: + |.if HFABI + | vm_round ceil, 1 + |.endif + |->vm_ceil_sf: + | vm_round ceil, 0 + | + |.macro vm_trunc, hf + |.if JIT + |.if hf == 1 + | vmov CARG1, CARG2, d0 + |.endif + | lsl CARG3, CARG2, #1 + | adds RB, CARG3, #0x00200000 + | andpl CARG2, CARG2, #0x80000000 // |x| < 1? hi = sign(x), lo = 0. + | movpl CARG1, #0 + |.if hf == 1 + | vmovpl d0, CARG1, CARG2 + |.endif + | bxpl lr + | mvn CARG4, #0x3cc + | subs RB, CARG4, RB, asr #21 // 2^0: RB = 51, 2^51: RB = 0. + | bxlo lr // |x| >= 2^52: already done. + | mvn CARG4, #1 + | and CARG1, CARG1, CARG4, lsl RB // lo &= lomask + | subs RB, RB, #32 + | andpl CARG2, CARG2, CARG4, lsl RB // |x| <= 2^20: hi &= himask + |.if hf == 1 + | vmov d0, CARG1, CARG2 + |.endif + | bx lr + |.endif + |.endmacro + | + |->vm_trunc: + |.if HFABI + | vm_trunc 1 + |.endif + |->vm_trunc_sf: + | vm_trunc 0 + | + | // double lj_vm_mod(double dividend, double divisor); + |->vm_mod: + |.if FPU + | // Special calling convention. Also, RC (r11) is not preserved. + | vdiv.f64 d0, d6, d7 + | mov RC, lr + | vmov CARG1, CARG2, d0 + | bl ->vm_floor_sf + | vmov d0, CARG1, CARG2 + | vmul.f64 d0, d0, d7 + | mov lr, RC + | vsub.f64 d6, d6, d0 + | bx lr + |.else + | push {r0, r1, r2, r3, r4, lr} + | bl extern __aeabi_ddiv + | bl ->vm_floor_sf + | ldrd CARG34, [sp, #8] + | bl extern __aeabi_dmul + | ldrd CARG34, [sp] + | eor CARG2, CARG2, #0x80000000 + | bl extern __aeabi_dadd + | add sp, sp, #20 + | pop {pc} + |.endif + | + | // int lj_vm_modi(int dividend, int divisor); + |->vm_modi: + | ands RB, CARG1, #0x80000000 + | rsbmi CARG1, CARG1, #0 // a = |dividend| + | eor RB, RB, CARG2, asr #1 // Keep signdiff and sign(divisor). + | cmp CARG2, #0 + | rsbmi CARG2, CARG2, #0 // b = |divisor| + | subs CARG4, CARG2, #1 + | cmpne CARG1, CARG2 + | moveq CARG1, #0 // if (b == 1 || a == b) a = 0 + | tsthi CARG2, CARG4 + | andeq CARG1, CARG1, CARG4 // else if ((b & (b-1)) == 0) a &= b-1 + | bls >1 + | // Use repeated subtraction to get the remainder. + | clz CARG3, CARG1 + | clz CARG4, CARG2 + | sub CARG4, CARG4, CARG3 + | rsbs CARG3, CARG4, #31 // entry = (31-(clz(b)-clz(a)))*8 + | addne pc, pc, CARG3, lsl #3 // Duff's device. + | nop + { + int i; + for (i = 31; i >= 0; i--) { + | cmp CARG1, CARG2, lsl #i + | subhs CARG1, CARG1, CARG2, lsl #i + } + } + |1: + | cmp CARG1, #0 + | cmpne RB, #0 + | submi CARG1, CARG1, CARG2 // if (y != 0 && signdiff) y = y - b + | eors CARG2, CARG1, RB, lsl #1 + | rsbmi CARG1, CARG1, #0 // if (sign(divisor) != sign(y)) y = -y + | bx lr + | + |//----------------------------------------------------------------------- + |//-- Miscellaneous functions -------------------------------------------- + |//----------------------------------------------------------------------- + | + |.define NEXT_TAB, TAB:CARG1 + |.define NEXT_RES, CARG1 + |.define NEXT_IDX, CARG2 + |.define NEXT_TMP0, CARG3 + |.define NEXT_TMP1, CARG4 + |.define NEXT_LIM, r12 + |.define NEXT_RES_PTR, sp + |.define NEXT_RES_VAL, [sp] + |.define NEXT_RES_KEY_I, [sp, #8] + |.define NEXT_RES_KEY_IT, [sp, #12] + | + |// TValue *lj_vm_next(GCtab *t, uint32_t idx) + |// Next idx returned in CRET2. + |->vm_next: + |.if JIT + | ldr NEXT_TMP0, NEXT_TAB->array + | ldr NEXT_LIM, NEXT_TAB->asize + | add NEXT_TMP0, NEXT_TMP0, NEXT_IDX, lsl #3 + |1: // Traverse array part. + | subs NEXT_TMP1, NEXT_IDX, NEXT_LIM + | bhs >5 + | ldr NEXT_TMP1, [NEXT_TMP0, #4] + | str NEXT_IDX, NEXT_RES_KEY_I + | add NEXT_TMP0, NEXT_TMP0, #8 + | add NEXT_IDX, NEXT_IDX, #1 + | checktp NEXT_TMP1, LJ_TNIL + | beq <1 // Skip holes in array part. + | ldr NEXT_TMP0, [NEXT_TMP0, #-8] + | mov NEXT_RES, NEXT_RES_PTR + | strd NEXT_TMP0, NEXT_RES_VAL // Stores NEXT_TMP1, too. + | mvn NEXT_TMP0, #~LJ_TISNUM + | str NEXT_TMP0, NEXT_RES_KEY_IT + | bx lr + | + |5: // Traverse hash part. + | ldr NEXT_TMP0, NEXT_TAB->hmask + | ldr NODE:NEXT_RES, NEXT_TAB->node + | add NEXT_TMP1, NEXT_TMP1, NEXT_TMP1, lsl #1 + | add NEXT_LIM, NEXT_LIM, NEXT_TMP0 + | add NODE:NEXT_RES, NODE:NEXT_RES, NEXT_TMP1, lsl #3 + |6: + | cmp NEXT_IDX, NEXT_LIM + | bhi >9 + | ldr NEXT_TMP1, NODE:NEXT_RES->val.it + | checktp NEXT_TMP1, LJ_TNIL + | add NEXT_IDX, NEXT_IDX, #1 + | bxne lr + | // Skip holes in hash part. + | add NEXT_RES, NEXT_RES, #sizeof(Node) + | b <6 + | + |9: // End of iteration. Set the key to nil (not the value). + | mvn NEXT_TMP0, #0 + | mov NEXT_RES, NEXT_RES_PTR + | str NEXT_TMP0, NEXT_RES_KEY_IT + | bx lr + |.endif + | + |//----------------------------------------------------------------------- + |//-- FFI helper functions ----------------------------------------------- + |//----------------------------------------------------------------------- + | + |// Handler for callback functions. + |// Saveregs already performed. Callback slot number in [sp], g in r12. + |->vm_ffi_callback: + |.if FFI + |.type CTSTATE, CTState, PC + | ldr CTSTATE, GL:r12->ctype_state + | add DISPATCH, r12, #GG_G2DISP + |.if FPU + | str r4, SAVE_R4 + | add r4, sp, CFRAME_SPACE+4+8*8 + | vstmdb r4!, {d8-d15} + |.endif + |.if HFABI + | add r12, CTSTATE, #offsetof(CTState, cb.fpr[8]) + |.endif + | strd CARG34, CTSTATE->cb.gpr[2] + | strd CARG12, CTSTATE->cb.gpr[0] + |.if HFABI + | vstmdb r12!, {d0-d7} + |.endif + | ldr CARG4, [sp] + | add CARG3, sp, #CFRAME_SIZE + | mov CARG1, CTSTATE + | lsr CARG4, CARG4, #3 + | str CARG3, CTSTATE->cb.stack + | mov CARG2, sp + | str CARG4, CTSTATE->cb.slot + | str CTSTATE, SAVE_PC // Any value outside of bytecode is ok. + | bl extern lj_ccallback_enter // (CTState *cts, void *cf) + | // Returns lua_State *. + | ldr BASE, L:CRET1->base + | mv_vmstate CARG2, INTERP + | ldr RC, L:CRET1->top + | mov MASKR8, #255 + | ldr LFUNC:CARG3, [BASE, FRAME_FUNC] + | mov L, CRET1 + | sub RC, RC, BASE + | lsl MASKR8, MASKR8, #3 // MASKR8 = 255*8. + | st_vmstate CARG2 + | ins_callt + |.endif + | + |->cont_ffi_callback: // Return from FFI callback. + |.if FFI + | ldr CTSTATE, [DISPATCH, #DISPATCH_GL(ctype_state)] + | str BASE, L->base + | str CARG4, L->top + | str L, CTSTATE->L + | mov CARG1, CTSTATE + | mov CARG2, RA + | bl extern lj_ccallback_leave // (CTState *cts, TValue *o) + | ldrd CARG12, CTSTATE->cb.gpr[0] + |.if HFABI + | vldr d0, CTSTATE->cb.fpr[0] + |.endif + | b ->vm_leave_unw + |.endif + | + |->vm_ffi_call: // Call C function via FFI. + | // Caveat: needs special frame unwinding, see below. + |.if FFI + | .type CCSTATE, CCallState, r4 + | push {CCSTATE, r5, r11, lr} + | mov CCSTATE, CARG1 + | ldr CARG1, CCSTATE:CARG1->spadj + | ldrb CARG2, CCSTATE->nsp + | add CARG3, CCSTATE, #offsetof(CCallState, stack) + |.if HFABI + | add RB, CCSTATE, #offsetof(CCallState, fpr[0]) + |.endif + | mov r11, sp + | sub sp, sp, CARG1 // Readjust stack. + | subs CARG2, CARG2, #1 + |.if HFABI + | vldm RB, {d0-d7} + |.endif + | ldr RB, CCSTATE->func + | bmi >2 + |1: // Copy stack slots. + | ldr CARG4, [CARG3, CARG2, lsl #2] + | str CARG4, [sp, CARG2, lsl #2] + | subs CARG2, CARG2, #1 + | bpl <1 + |2: + | ldrd CARG12, CCSTATE->gpr[0] + | ldrd CARG34, CCSTATE->gpr[2] + | blx RB + | mov sp, r11 + |.if HFABI + | add r12, CCSTATE, #offsetof(CCallState, fpr[4]) + |.endif + | strd CRET1, CCSTATE->gpr[0] + |.if HFABI + | vstmdb r12!, {d0-d3} + |.endif + | pop {CCSTATE, r5, r11, pc} + |.endif + |// Note: vm_ffi_call must be the last function in this object file! + | + |//----------------------------------------------------------------------- +} + +/* Generate the code for a single instruction. */ +static void build_ins(BuildCtx *ctx, BCOp op, int defop) +{ + int vk = 0; + |=>defop: + + switch (op) { + + /* -- Comparison ops ---------------------------------------------------- */ + + /* Remember: all ops branch for a true comparison, fall through otherwise. */ + + case BC_ISLT: case BC_ISGE: case BC_ISLE: case BC_ISGT: + | // RA = src1*8, RC = src2, JMP with RC = target + | lsl RC, RC, #3 + | ldrd CARG12, [RA, BASE]! + | ldrh RB, [PC, #2] + | ldrd CARG34, [RC, BASE]! + | add PC, PC, #4 + | add RB, PC, RB, lsl #2 + | checktp CARG2, LJ_TISNUM + | bne >3 + | checktp CARG4, LJ_TISNUM + | bne >4 + | cmp CARG1, CARG3 + if (op == BC_ISLT) { + | sublt PC, RB, #0x20000 + } else if (op == BC_ISGE) { + | subge PC, RB, #0x20000 + } else if (op == BC_ISLE) { + | suble PC, RB, #0x20000 + } else { + | subgt PC, RB, #0x20000 + } + |1: + | ins_next + | + |3: // CARG12 is not an integer. + |.if FPU + | vldr d0, [RA] + | bhi ->vmeta_comp + | // d0 is a number. + | checktp CARG4, LJ_TISNUM + | vldr d1, [RC] + | blo >5 + | bhi ->vmeta_comp + | // d0 is a number, CARG3 is an integer. + | vmov s4, CARG3 + | vcvt.f64.s32 d1, s4 + | b >5 + |4: // CARG1 is an integer, CARG34 is not an integer. + | vldr d1, [RC] + | bhi ->vmeta_comp + | // CARG1 is an integer, d1 is a number. + | vmov s4, CARG1 + | vcvt.f64.s32 d0, s4 + |5: // d0 and d1 are numbers. + | vcmp.f64 d0, d1 + | vmrs + | // To preserve NaN semantics GE/GT branch on unordered, but LT/LE don't. + if (op == BC_ISLT) { + | sublo PC, RB, #0x20000 + } else if (op == BC_ISGE) { + | subhs PC, RB, #0x20000 + } else if (op == BC_ISLE) { + | subls PC, RB, #0x20000 + } else { + | subhi PC, RB, #0x20000 + } + | b <1 + |.else + | bhi ->vmeta_comp + | // CARG12 is a number. + | checktp CARG4, LJ_TISNUM + | movlo RA, RB // Save RB. + | blo >5 + | bhi ->vmeta_comp + | // CARG12 is a number, CARG3 is an integer. + | mov CARG1, CARG3 + | mov RC, RA + | mov RA, RB // Save RB. + | bl extern __aeabi_i2d + | mov CARG3, CARG1 + | mov CARG4, CARG2 + | ldrd CARG12, [RC] // Restore first operand. + | b >5 + |4: // CARG1 is an integer, CARG34 is not an integer. + | bhi ->vmeta_comp + | // CARG1 is an integer, CARG34 is a number. + | mov RA, RB // Save RB. + | bl extern __aeabi_i2d + | ldrd CARG34, [RC] // Restore second operand. + |5: // CARG12 and CARG34 are numbers. + | bl extern __aeabi_cdcmple + | // To preserve NaN semantics GE/GT branch on unordered, but LT/LE don't. + if (op == BC_ISLT) { + | sublo PC, RA, #0x20000 + } else if (op == BC_ISGE) { + | subhs PC, RA, #0x20000 + } else if (op == BC_ISLE) { + | subls PC, RA, #0x20000 + } else { + | subhi PC, RA, #0x20000 + } + | b <1 + |.endif + break; + + case BC_ISEQV: case BC_ISNEV: + vk = op == BC_ISEQV; + | // RA = src1*8, RC = src2, JMP with RC = target + | lsl RC, RC, #3 + | ldrd CARG12, [RA, BASE]! + | ldrh RB, [PC, #2] + | ldrd CARG34, [RC, BASE]! + | add PC, PC, #4 + | add RB, PC, RB, lsl #2 + | checktp CARG2, LJ_TISNUM + | cmnls CARG4, #-LJ_TISNUM + if (vk) { + | bls ->BC_ISEQN_Z + } else { + | bls ->BC_ISNEN_Z + } + | // Either or both types are not numbers. + |.if FFI + | checktp CARG2, LJ_TCDATA + | checktpne CARG4, LJ_TCDATA + | beq ->vmeta_equal_cd + |.endif + | cmp CARG2, CARG4 // Compare types. + | bne >2 // Not the same type? + | checktp CARG2, LJ_TISPRI + | bhs >1 // Same type and primitive type? + | + | // Same types and not a primitive type. Compare GCobj or pvalue. + | cmp CARG1, CARG3 + if (vk) { + | bne >3 // Different GCobjs or pvalues? + |1: // Branch if same. + | sub PC, RB, #0x20000 + |2: // Different. + | ins_next + |3: + | checktp CARG2, LJ_TISTABUD + | bhi <2 // Different objects and not table/ud? + } else { + | beq >1 // Same GCobjs or pvalues? + | checktp CARG2, LJ_TISTABUD + | bhi >2 // Different objects and not table/ud? + } + | // Different tables or userdatas. Need to check __eq metamethod. + | // Field metatable must be at same offset for GCtab and GCudata! + | ldr TAB:RA, TAB:CARG1->metatable + | cmp TAB:RA, #0 + if (vk) { + | beq <2 // No metatable? + } else { + | beq >2 // No metatable? + } + | ldrb RA, TAB:RA->nomm + | mov CARG4, #1-vk // ne = 0 or 1. + | mov CARG2, CARG1 + | tst RA, #1<vmeta_equal // 'no __eq' flag not set? + if (vk) { + | b <2 + } else { + |2: // Branch if different. + | sub PC, RB, #0x20000 + |1: // Same. + | ins_next + } + break; + + case BC_ISEQS: case BC_ISNES: + vk = op == BC_ISEQS; + | // RA = src*8, RC = str_const (~), JMP with RC = target + | mvn RC, RC + | ldrd CARG12, [BASE, RA] + | ldrh RB, [PC, #2] + | ldr STR:CARG3, [KBASE, RC, lsl #2] + | add PC, PC, #4 + | add RB, PC, RB, lsl #2 + | checktp CARG2, LJ_TSTR + |.if FFI + | bne >7 + | cmp CARG1, CARG3 + |.else + | cmpeq CARG1, CARG3 + |.endif + if (vk) { + | subeq PC, RB, #0x20000 + |1: + } else { + |1: + | subne PC, RB, #0x20000 + } + | ins_next + | + |.if FFI + |7: + | checktp CARG2, LJ_TCDATA + | bne <1 + | b ->vmeta_equal_cd + |.endif + break; + + case BC_ISEQN: case BC_ISNEN: + vk = op == BC_ISEQN; + | // RA = src*8, RC = num_const (~), JMP with RC = target + | lsl RC, RC, #3 + | ldrd CARG12, [RA, BASE]! + | ldrh RB, [PC, #2] + | ldrd CARG34, [RC, KBASE]! + | add PC, PC, #4 + | add RB, PC, RB, lsl #2 + if (vk) { + |->BC_ISEQN_Z: + } else { + |->BC_ISNEN_Z: + } + | checktp CARG2, LJ_TISNUM + | bne >3 + | checktp CARG4, LJ_TISNUM + | bne >4 + | cmp CARG1, CARG3 + if (vk) { + | subeq PC, RB, #0x20000 + |1: + } else { + |1: + | subne PC, RB, #0x20000 + } + |2: + | ins_next + | + |3: // CARG12 is not an integer. + |.if FFI + | bhi >7 + |.else + if (!vk) { + | subhi PC, RB, #0x20000 + } + | bhi <2 + |.endif + |.if FPU + | checktp CARG4, LJ_TISNUM + | vmov s4, CARG3 + | vldr d0, [RA] + | vldrlo d1, [RC] + | vcvths.f64.s32 d1, s4 + | b >5 + |4: // CARG1 is an integer, d1 is a number. + | vmov s4, CARG1 + | vldr d1, [RC] + | vcvt.f64.s32 d0, s4 + |5: // d0 and d1 are numbers. + | vcmp.f64 d0, d1 + | vmrs + if (vk) { + | subeq PC, RB, #0x20000 + } else { + | subne PC, RB, #0x20000 + } + | b <2 + |.else + | // CARG12 is a number. + | checktp CARG4, LJ_TISNUM + | movlo RA, RB // Save RB. + | blo >5 + | // CARG12 is a number, CARG3 is an integer. + | mov CARG1, CARG3 + | mov RC, RA + |4: // CARG1 is an integer, CARG34 is a number. + | mov RA, RB // Save RB. + | bl extern __aeabi_i2d + | ldrd CARG34, [RC] // Restore other operand. + |5: // CARG12 and CARG34 are numbers. + | bl extern __aeabi_cdcmpeq + if (vk) { + | subeq PC, RA, #0x20000 + } else { + | subne PC, RA, #0x20000 + } + | b <2 + |.endif + | + |.if FFI + |7: + | checktp CARG2, LJ_TCDATA + | bne <1 + | b ->vmeta_equal_cd + |.endif + break; + + case BC_ISEQP: case BC_ISNEP: + vk = op == BC_ISEQP; + | // RA = src*8, RC = primitive_type (~), JMP with RC = target + | ldrd CARG12, [BASE, RA] + | ldrh RB, [PC, #2] + | add PC, PC, #4 + | mvn RC, RC + | add RB, PC, RB, lsl #2 + |.if FFI + | checktp CARG2, LJ_TCDATA + | beq ->vmeta_equal_cd + |.endif + | cmp CARG2, RC + if (vk) { + | subeq PC, RB, #0x20000 + } else { + | subne PC, RB, #0x20000 + } + | ins_next + break; + + /* -- Unary test and copy ops ------------------------------------------- */ + + case BC_ISTC: case BC_ISFC: case BC_IST: case BC_ISF: + | // RA = dst*8 or unused, RC = src, JMP with RC = target + | add RC, BASE, RC, lsl #3 + | ldrh RB, [PC, #2] + | ldrd CARG12, [RC] + | add PC, PC, #4 + | add RB, PC, RB, lsl #2 + | checktp CARG2, LJ_TTRUE + if (op == BC_ISTC || op == BC_IST) { + | subls PC, RB, #0x20000 + if (op == BC_ISTC) { + | strdls CARG12, [BASE, RA] + } + } else { + | subhi PC, RB, #0x20000 + if (op == BC_ISFC) { + | strdhi CARG12, [BASE, RA] + } + } + | ins_next + break; + + case BC_ISTYPE: + | // RA = src*8, RC = -type + | ldrd CARG12, [BASE, RA] + | ins_next1 + | cmn CARG2, RC + | ins_next2 + | bne ->vmeta_istype + | ins_next3 + break; + case BC_ISNUM: + | // RA = src*8, RC = -(TISNUM-1) + | ldrd CARG12, [BASE, RA] + | ins_next1 + | checktp CARG2, LJ_TISNUM + | ins_next2 + | bhs ->vmeta_istype + | ins_next3 + break; + + /* -- Unary ops --------------------------------------------------------- */ + + case BC_MOV: + | // RA = dst*8, RC = src + | lsl RC, RC, #3 + | ins_next1 + | ldrd CARG12, [BASE, RC] + | ins_next2 + | strd CARG12, [BASE, RA] + | ins_next3 + break; + case BC_NOT: + | // RA = dst*8, RC = src + | add RC, BASE, RC, lsl #3 + | ins_next1 + | ldr CARG1, [RC, #4] + | add RA, BASE, RA + | ins_next2 + | checktp CARG1, LJ_TTRUE + | mvnls CARG2, #~LJ_TFALSE + | mvnhi CARG2, #~LJ_TTRUE + | str CARG2, [RA, #4] + | ins_next3 + break; + case BC_UNM: + | // RA = dst*8, RC = src + | lsl RC, RC, #3 + | ldrd CARG12, [BASE, RC] + | ins_next1 + | ins_next2 + | checktp CARG2, LJ_TISNUM + | bhi ->vmeta_unm + | eorne CARG2, CARG2, #0x80000000 + | bne >5 + | rsbseq CARG1, CARG1, #0 + | ldrdvs CARG12, >9 + |5: + | strd CARG12, [BASE, RA] + | ins_next3 + | + |.align 8 + |9: + | .long 0x00000000, 0x41e00000 // 2^31. + break; + case BC_LEN: + | // RA = dst*8, RC = src + | lsl RC, RC, #3 + | ldrd CARG12, [BASE, RC] + | checkstr CARG2, >2 + | ldr CARG1, STR:CARG1->len + |1: + | mvn CARG2, #~LJ_TISNUM + | ins_next1 + | ins_next2 + | strd CARG12, [BASE, RA] + | ins_next3 + |2: + | checktab CARG2, ->vmeta_len +#if LJ_52 + | ldr TAB:CARG3, TAB:CARG1->metatable + | cmp TAB:CARG3, #0 + | bne >9 + |3: +#endif + |->BC_LEN_Z: + | .IOS mov RC, BASE + | bl extern lj_tab_len // (GCtab *t) + | // Returns uint32_t (but less than 2^31). + | .IOS mov BASE, RC + | b <1 +#if LJ_52 + |9: + | ldrb CARG4, TAB:CARG3->nomm + | tst CARG4, #1<vmeta_len +#endif + break; + + /* -- Binary ops -------------------------------------------------------- */ + + |.macro ins_arithcheck, cond, ncond, target + ||if (vk == 1) { + | cmn CARG4, #-LJ_TISNUM + | cmn..cond CARG2, #-LJ_TISNUM + ||} else { + | cmn CARG2, #-LJ_TISNUM + | cmn..cond CARG4, #-LJ_TISNUM + ||} + | b..ncond target + |.endmacro + |.macro ins_arithcheck_int, target + | ins_arithcheck eq, ne, target + |.endmacro + |.macro ins_arithcheck_num, target + | ins_arithcheck lo, hs, target + |.endmacro + | + |.macro ins_arithpre + | decode_RB8 RB, INS + | decode_RC8 RC, INS + | // RA = dst*8, RB = src1*8, RC = src2*8 | num_const*8 + ||vk = ((int)op - BC_ADDVN) / (BC_ADDNV-BC_ADDVN); + ||switch (vk) { + ||case 0: + | .if FPU + | ldrd CARG12, [RB, BASE]! + | ldrd CARG34, [RC, KBASE]! + | .else + | ldrd CARG12, [BASE, RB] + | ldrd CARG34, [KBASE, RC] + | .endif + || break; + ||case 1: + | .if FPU + | ldrd CARG34, [RB, BASE]! + | ldrd CARG12, [RC, KBASE]! + | .else + | ldrd CARG34, [BASE, RB] + | ldrd CARG12, [KBASE, RC] + | .endif + || break; + ||default: + | .if FPU + | ldrd CARG12, [RB, BASE]! + | ldrd CARG34, [RC, BASE]! + | .else + | ldrd CARG12, [BASE, RB] + | ldrd CARG34, [BASE, RC] + | .endif + || break; + ||} + |.endmacro + | + |.macro ins_arithpre_fpu, reg1, reg2 + |.if FPU + ||if (vk == 1) { + | vldr reg2, [RB] + | vldr reg1, [RC] + ||} else { + | vldr reg1, [RB] + | vldr reg2, [RC] + ||} + |.endif + |.endmacro + | + |.macro ins_arithpost_fpu, reg + | ins_next1 + | add RA, BASE, RA + | ins_next2 + | vstr reg, [RA] + | ins_next3 + |.endmacro + | + |.macro ins_arithfallback, ins + ||switch (vk) { + ||case 0: + | ins ->vmeta_arith_vn + || break; + ||case 1: + | ins ->vmeta_arith_nv + || break; + ||default: + | ins ->vmeta_arith_vv + || break; + ||} + |.endmacro + | + |.macro ins_arithdn, intins, fpins, fpcall + | ins_arithpre + |.if "intins" ~= "vm_modi" and not FPU + | ins_next1 + |.endif + | ins_arithcheck_int >5 + |.if "intins" == "smull" + | smull CARG1, RC, CARG3, CARG1 + | cmp RC, CARG1, asr #31 + | ins_arithfallback bne + |.elif "intins" == "vm_modi" + | movs CARG2, CARG3 + | ins_arithfallback beq + | bl ->vm_modi + | mvn CARG2, #~LJ_TISNUM + |.else + | intins CARG1, CARG1, CARG3 + | ins_arithfallback bvs + |.endif + |4: + |.if "intins" == "vm_modi" or FPU + | ins_next1 + |.endif + | ins_next2 + | strd CARG12, [BASE, RA] + | ins_next3 + |5: // FP variant. + | ins_arithpre_fpu d6, d7 + | ins_arithfallback ins_arithcheck_num + |.if FPU + |.if "intins" == "vm_modi" + | bl fpcall + |.else + | fpins d6, d6, d7 + |.endif + | ins_arithpost_fpu d6 + |.else + | bl fpcall + |.if "intins" ~= "vm_modi" + | ins_next1 + |.endif + | b <4 + |.endif + |.endmacro + | + |.macro ins_arithfp, fpins, fpcall + | ins_arithpre + |.if "fpins" ~= "extern" or HFABI + | ins_arithpre_fpu d0, d1 + |.endif + | ins_arithfallback ins_arithcheck_num + |.if "fpins" == "extern" + | .IOS mov RC, BASE + | bl fpcall + | .IOS mov BASE, RC + |.elif FPU + | fpins d0, d0, d1 + |.else + | bl fpcall + |.endif + |.if ("fpins" ~= "extern" or HFABI) and FPU + | ins_arithpost_fpu d0 + |.else + | ins_next1 + | ins_next2 + | strd CARG12, [BASE, RA] + | ins_next3 + |.endif + |.endmacro + + case BC_ADDVN: case BC_ADDNV: case BC_ADDVV: + | ins_arithdn adds, vadd.f64, extern __aeabi_dadd + break; + case BC_SUBVN: case BC_SUBNV: case BC_SUBVV: + | ins_arithdn subs, vsub.f64, extern __aeabi_dsub + break; + case BC_MULVN: case BC_MULNV: case BC_MULVV: + | ins_arithdn smull, vmul.f64, extern __aeabi_dmul + break; + case BC_DIVVN: case BC_DIVNV: case BC_DIVVV: + | ins_arithfp vdiv.f64, extern __aeabi_ddiv + break; + case BC_MODVN: case BC_MODNV: case BC_MODVV: + | ins_arithdn vm_modi, vm_mod, ->vm_mod + break; + case BC_POW: + | // NYI: (partial) integer arithmetic. + | ins_arithfp extern, extern pow + break; + + case BC_CAT: + | decode_RB8 RC, INS + | decode_RC8 RB, INS + | // RA = dst*8, RC = src_start*8, RB = src_end*8 (note: RB/RC swapped!) + | sub CARG3, RB, RC + | str BASE, L->base + | add CARG2, BASE, RB + |->BC_CAT_Z: + | // RA = dst*8, RC = src_start*8, CARG2 = top-1 + | mov CARG1, L + | str PC, SAVE_PC + | lsr CARG3, CARG3, #3 + | bl extern lj_meta_cat // (lua_State *L, TValue *top, int left) + | // Returns NULL (finished) or TValue * (metamethod). + | ldr BASE, L->base + | cmp CRET1, #0 + | bne ->vmeta_binop + | ldrd CARG34, [BASE, RC] + | ins_next1 + | ins_next2 + | strd CARG34, [BASE, RA] // Copy result to RA. + | ins_next3 + break; + + /* -- Constant ops ------------------------------------------------------ */ + + case BC_KSTR: + | // RA = dst*8, RC = str_const (~) + | mvn RC, RC + | ins_next1 + | ldr CARG1, [KBASE, RC, lsl #2] + | mvn CARG2, #~LJ_TSTR + | ins_next2 + | strd CARG12, [BASE, RA] + | ins_next3 + break; + case BC_KCDATA: + |.if FFI + | // RA = dst*8, RC = cdata_const (~) + | mvn RC, RC + | ins_next1 + | ldr CARG1, [KBASE, RC, lsl #2] + | mvn CARG2, #~LJ_TCDATA + | ins_next2 + | strd CARG12, [BASE, RA] + | ins_next3 + |.endif + break; + case BC_KSHORT: + | // RA = dst*8, (RC = int16_literal) + | mov CARG1, INS, asr #16 // Refetch sign-extended reg. + | mvn CARG2, #~LJ_TISNUM + | ins_next1 + | ins_next2 + | strd CARG12, [BASE, RA] + | ins_next3 + break; + case BC_KNUM: + | // RA = dst*8, RC = num_const + | lsl RC, RC, #3 + | ins_next1 + | ldrd CARG12, [KBASE, RC] + | ins_next2 + | strd CARG12, [BASE, RA] + | ins_next3 + break; + case BC_KPRI: + | // RA = dst*8, RC = primitive_type (~) + | add RA, BASE, RA + | mvn RC, RC + | ins_next1 + | ins_next2 + | str RC, [RA, #4] + | ins_next3 + break; + case BC_KNIL: + | // RA = base*8, RC = end + | add RA, BASE, RA + | add RC, BASE, RC, lsl #3 + | mvn CARG1, #~LJ_TNIL + | str CARG1, [RA, #4] + | add RA, RA, #8 + |1: + | str CARG1, [RA, #4] + | cmp RA, RC + | add RA, RA, #8 + | blt <1 + | ins_next_ + break; + + /* -- Upvalue and function ops ------------------------------------------ */ + + case BC_UGET: + | // RA = dst*8, RC = uvnum + | ldr LFUNC:CARG2, [BASE, FRAME_FUNC] + | lsl RC, RC, #2 + | add RC, RC, #offsetof(GCfuncL, uvptr) + | ldr UPVAL:CARG2, [LFUNC:CARG2, RC] + | ldr CARG2, UPVAL:CARG2->v + | ldrd CARG34, [CARG2] + | ins_next1 + | ins_next2 + | strd CARG34, [BASE, RA] + | ins_next3 + break; + case BC_USETV: + | // RA = uvnum*8, RC = src + | ldr LFUNC:CARG2, [BASE, FRAME_FUNC] + | lsr RA, RA, #1 + | add RA, RA, #offsetof(GCfuncL, uvptr) + | lsl RC, RC, #3 + | ldr UPVAL:CARG2, [LFUNC:CARG2, RA] + | ldrd CARG34, [BASE, RC] + | ldrb RB, UPVAL:CARG2->marked + | ldrb RC, UPVAL:CARG2->closed + | ldr CARG2, UPVAL:CARG2->v + | tst RB, #LJ_GC_BLACK // isblack(uv) + | add RB, CARG4, #-LJ_TISGCV + | cmpne RC, #0 + | strd CARG34, [CARG2] + | bne >2 // Upvalue is closed and black? + |1: + | ins_next + | + |2: // Check if new value is collectable. + | cmn RB, #-(LJ_TNUMX - LJ_TISGCV) + | ldrbhi RC, GCOBJ:CARG3->gch.marked + | bls <1 // tvisgcv(v) + | sub CARG1, DISPATCH, #-GG_DISP2G + | tst RC, #LJ_GC_WHITES + | // Crossed a write barrier. Move the barrier forward. + |.if IOS + | beq <1 + | mov RC, BASE + | bl extern lj_gc_barrieruv // (global_State *g, TValue *tv) + | mov BASE, RC + |.else + | blne extern lj_gc_barrieruv // (global_State *g, TValue *tv) + |.endif + | b <1 + break; + case BC_USETS: + | // RA = uvnum*8, RC = str_const (~) + | ldr LFUNC:CARG2, [BASE, FRAME_FUNC] + | lsr RA, RA, #1 + | add RA, RA, #offsetof(GCfuncL, uvptr) + | mvn RC, RC + | ldr UPVAL:CARG2, [LFUNC:CARG2, RA] + | ldr STR:CARG3, [KBASE, RC, lsl #2] + | ldrb RB, UPVAL:CARG2->marked + | ldrb RC, UPVAL:CARG2->closed + | ldr CARG2, UPVAL:CARG2->v + | mvn CARG4, #~LJ_TSTR + | tst RB, #LJ_GC_BLACK // isblack(uv) + | ldrb RB, STR:CARG3->marked + | strd CARG34, [CARG2] + | bne >2 + |1: + | ins_next + | + |2: // Check if string is white and ensure upvalue is closed. + | tst RB, #LJ_GC_WHITES // iswhite(str) + | cmpne RC, #0 + | sub CARG1, DISPATCH, #-GG_DISP2G + | // Crossed a write barrier. Move the barrier forward. + |.if IOS + | beq <1 + | mov RC, BASE + | bl extern lj_gc_barrieruv // (global_State *g, TValue *tv) + | mov BASE, RC + |.else + | blne extern lj_gc_barrieruv // (global_State *g, TValue *tv) + |.endif + | b <1 + break; + case BC_USETN: + | // RA = uvnum*8, RC = num_const + | ldr LFUNC:CARG2, [BASE, FRAME_FUNC] + | lsr RA, RA, #1 + | add RA, RA, #offsetof(GCfuncL, uvptr) + | lsl RC, RC, #3 + | ldr UPVAL:CARG2, [LFUNC:CARG2, RA] + | ldrd CARG34, [KBASE, RC] + | ldr CARG2, UPVAL:CARG2->v + | ins_next1 + | ins_next2 + | strd CARG34, [CARG2] + | ins_next3 + break; + case BC_USETP: + | // RA = uvnum*8, RC = primitive_type (~) + | ldr LFUNC:CARG2, [BASE, FRAME_FUNC] + | lsr RA, RA, #1 + | add RA, RA, #offsetof(GCfuncL, uvptr) + | ldr UPVAL:CARG2, [LFUNC:CARG2, RA] + | mvn RC, RC + | ldr CARG2, UPVAL:CARG2->v + | ins_next1 + | ins_next2 + | str RC, [CARG2, #4] + | ins_next3 + break; + + case BC_UCLO: + | // RA = level*8, RC = target + | ldr CARG3, L->openupval + | add RC, PC, RC, lsl #2 + | str BASE, L->base + | cmp CARG3, #0 + | sub PC, RC, #0x20000 + | beq >1 + | mov CARG1, L + | add CARG2, BASE, RA + | bl extern lj_func_closeuv // (lua_State *L, TValue *level) + | ldr BASE, L->base + |1: + | ins_next + break; + + case BC_FNEW: + | // RA = dst*8, RC = proto_const (~) (holding function prototype) + | mvn RC, RC + | str BASE, L->base + | ldr CARG2, [KBASE, RC, lsl #2] + | str PC, SAVE_PC + | ldr CARG3, [BASE, FRAME_FUNC] + | mov CARG1, L + | // (lua_State *L, GCproto *pt, GCfuncL *parent) + | bl extern lj_func_newL_gc + | // Returns GCfuncL *. + | ldr BASE, L->base + | mvn CARG2, #~LJ_TFUNC + | ins_next1 + | ins_next2 + | strd CARG12, [BASE, RA] + | ins_next3 + break; + + /* -- Table ops --------------------------------------------------------- */ + + case BC_TNEW: + case BC_TDUP: + | // RA = dst*8, RC = (hbits|asize) | tab_const (~) + if (op == BC_TDUP) { + | mvn RC, RC + } + | ldr CARG3, [DISPATCH, #DISPATCH_GL(gc.total)] + | ldr CARG4, [DISPATCH, #DISPATCH_GL(gc.threshold)] + | str BASE, L->base + | str PC, SAVE_PC + | cmp CARG3, CARG4 + | mov CARG1, L + | bhs >5 + |1: + if (op == BC_TNEW) { + | lsl CARG2, RC, #21 + | lsr CARG3, RC, #11 + | asr RC, CARG2, #21 + | lsr CARG2, CARG2, #21 + | cmn RC, #1 + | addeq CARG2, CARG2, #2 + | bl extern lj_tab_new // (lua_State *L, int32_t asize, uint32_t hbits) + | // Returns GCtab *. + } else { + | ldr CARG2, [KBASE, RC, lsl #2] + | bl extern lj_tab_dup // (lua_State *L, Table *kt) + | // Returns GCtab *. + } + | ldr BASE, L->base + | mvn CARG2, #~LJ_TTAB + | ins_next1 + | ins_next2 + | strd CARG12, [BASE, RA] + | ins_next3 + |5: + | bl extern lj_gc_step_fixtop // (lua_State *L) + | mov CARG1, L + | b <1 + break; + + case BC_GGET: + | // RA = dst*8, RC = str_const (~) + case BC_GSET: + | // RA = dst*8, RC = str_const (~) + | ldr LFUNC:CARG2, [BASE, FRAME_FUNC] + | mvn RC, RC + | ldr TAB:CARG1, LFUNC:CARG2->env + | ldr STR:RC, [KBASE, RC, lsl #2] + if (op == BC_GGET) { + | b ->BC_TGETS_Z + } else { + | b ->BC_TSETS_Z + } + break; + + case BC_TGETV: + | decode_RB8 RB, INS + | decode_RC8 RC, INS + | // RA = dst*8, RB = table*8, RC = key*8 + | ldrd TAB:CARG12, [BASE, RB] + | ldrd CARG34, [BASE, RC] + | checktab CARG2, ->vmeta_tgetv // STALL: load CARG12. + | checktp CARG4, LJ_TISNUM // Integer key? + | ldreq CARG4, TAB:CARG1->array + | ldreq CARG2, TAB:CARG1->asize + | bne >9 + | + | add CARG4, CARG4, CARG3, lsl #3 + | cmp CARG3, CARG2 // In array part? + | ldrdlo CARG34, [CARG4] + | bhs ->vmeta_tgetv + | ins_next1 // Overwrites RB! + | checktp CARG4, LJ_TNIL + | beq >5 + |1: + | ins_next2 + | strd CARG34, [BASE, RA] + | ins_next3 + | + |5: // Check for __index if table value is nil. + | ldr TAB:CARG2, TAB:CARG1->metatable + | cmp TAB:CARG2, #0 + | beq <1 // No metatable: done. + | ldrb CARG2, TAB:CARG2->nomm + | tst CARG2, #1<vmeta_tgetv + | + |9: + | checktp CARG4, LJ_TSTR // String key? + | moveq STR:RC, CARG3 + | beq ->BC_TGETS_Z + | b ->vmeta_tgetv + break; + case BC_TGETS: + | decode_RB8 RB, INS + | and RC, RC, #255 + | // RA = dst*8, RB = table*8, RC = str_const (~) + | ldrd CARG12, [BASE, RB] + | mvn RC, RC + | ldr STR:RC, [KBASE, RC, lsl #2] // STALL: early RC. + | checktab CARG2, ->vmeta_tgets1 + |->BC_TGETS_Z: + | // (TAB:RB =) TAB:CARG1 = GCtab *, STR:RC = GCstr *, RA = dst*8 + | ldr CARG3, TAB:CARG1->hmask + | ldr CARG4, STR:RC->sid + | ldr NODE:INS, TAB:CARG1->node + | mov TAB:RB, TAB:CARG1 + | and CARG3, CARG3, CARG4 // idx = str->sid & tab->hmask + | add CARG3, CARG3, CARG3, lsl #1 + | add NODE:INS, NODE:INS, CARG3, lsl #3 // node = tab->node + idx*3*8 + |1: + | ldrd CARG12, NODE:INS->key // STALL: early NODE:INS. + | ldrd CARG34, NODE:INS->val + | ldr NODE:INS, NODE:INS->next + | checktp CARG2, LJ_TSTR + | cmpeq CARG1, STR:RC + | bne >4 + | checktp CARG4, LJ_TNIL + | beq >5 + |3: + | ins_next1 + | ins_next2 + | strd CARG34, [BASE, RA] + | ins_next3 + | + |4: // Follow hash chain. + | cmp NODE:INS, #0 + | bne <1 + | // End of hash chain: key not found, nil result. + | + |5: // Check for __index if table value is nil. + | ldr TAB:CARG1, TAB:RB->metatable + | mov CARG3, #0 // Optional clear of undef. value (during load stall). + | mvn CARG4, #~LJ_TNIL + | cmp TAB:CARG1, #0 + | beq <3 // No metatable: done. + | ldrb CARG2, TAB:CARG1->nomm + | tst CARG2, #1<vmeta_tgets + break; + case BC_TGETB: + | decode_RB8 RB, INS + | and RC, RC, #255 + | // RA = dst*8, RB = table*8, RC = index + | ldrd CARG12, [BASE, RB] + | checktab CARG2, ->vmeta_tgetb // STALL: load CARG12. + | ldr CARG3, TAB:CARG1->asize + | ldr CARG4, TAB:CARG1->array + | lsl CARG2, RC, #3 + | cmp RC, CARG3 + | ldrdlo CARG34, [CARG4, CARG2] + | bhs ->vmeta_tgetb + | ins_next1 // Overwrites RB! + | checktp CARG4, LJ_TNIL + | beq >5 + |1: + | ins_next2 + | strd CARG34, [BASE, RA] + | ins_next3 + | + |5: // Check for __index if table value is nil. + | ldr TAB:CARG2, TAB:CARG1->metatable + | cmp TAB:CARG2, #0 + | beq <1 // No metatable: done. + | ldrb CARG2, TAB:CARG2->nomm + | tst CARG2, #1<vmeta_tgetb + break; + case BC_TGETR: + | decode_RB8 RB, INS + | decode_RC8 RC, INS + | // RA = dst*8, RB = table*8, RC = key*8 + | ldr TAB:CARG1, [BASE, RB] + | ldr CARG2, [BASE, RC] + | ldr CARG4, TAB:CARG1->array + | ldr CARG3, TAB:CARG1->asize + | add CARG4, CARG4, CARG2, lsl #3 + | cmp CARG2, CARG3 // In array part? + | bhs ->vmeta_tgetr + | ldrd CARG12, [CARG4] + |->BC_TGETR_Z: + | ins_next1 + | ins_next2 + | strd CARG12, [BASE, RA] + | ins_next3 + break; + + case BC_TSETV: + | decode_RB8 RB, INS + | decode_RC8 RC, INS + | // RA = src*8, RB = table*8, RC = key*8 + | ldrd TAB:CARG12, [BASE, RB] + | ldrd CARG34, [BASE, RC] + | checktab CARG2, ->vmeta_tsetv // STALL: load CARG12. + | checktp CARG4, LJ_TISNUM // Integer key? + | ldreq CARG2, TAB:CARG1->array + | ldreq CARG4, TAB:CARG1->asize + | bne >9 + | + | add CARG2, CARG2, CARG3, lsl #3 + | cmp CARG3, CARG4 // In array part? + | ldrlo INS, [CARG2, #4] + | bhs ->vmeta_tsetv + | ins_next1 // Overwrites RB! + | checktp INS, LJ_TNIL + | ldrb INS, TAB:CARG1->marked + | ldrd CARG34, [BASE, RA] + | beq >5 + |1: + | tst INS, #LJ_GC_BLACK // isblack(table) + | strd CARG34, [CARG2] + | bne >7 + |2: + | ins_next2 + | ins_next3 + | + |5: // Check for __newindex if previous value is nil. + | ldr TAB:RA, TAB:CARG1->metatable + | cmp TAB:RA, #0 + | beq <1 // No metatable: done. + | ldrb RA, TAB:RA->nomm + | tst RA, #1<vmeta_tsetv + | + |7: // Possible table write barrier for the value. Skip valiswhite check. + | barrierback TAB:CARG1, INS, CARG3 + | b <2 + | + |9: + | checktp CARG4, LJ_TSTR // String key? + | moveq STR:RC, CARG3 + | beq ->BC_TSETS_Z + | b ->vmeta_tsetv + break; + case BC_TSETS: + | decode_RB8 RB, INS + | and RC, RC, #255 + | // RA = src*8, RB = table*8, RC = str_const (~) + | ldrd CARG12, [BASE, RB] + | mvn RC, RC + | ldr STR:RC, [KBASE, RC, lsl #2] // STALL: early RC. + | checktab CARG2, ->vmeta_tsets1 + |->BC_TSETS_Z: + | // (TAB:RB =) TAB:CARG1 = GCtab *, STR:RC = GCstr *, RA = dst*8 + | ldr CARG3, TAB:CARG1->hmask + | ldr CARG4, STR:RC->sid + | ldr NODE:INS, TAB:CARG1->node + | mov TAB:RB, TAB:CARG1 + | and CARG3, CARG3, CARG4 // idx = str->sid & tab->hmask + | add CARG3, CARG3, CARG3, lsl #1 + | mov CARG4, #0 + | add NODE:INS, NODE:INS, CARG3, lsl #3 // node = tab->node + idx*3*8 + | strb CARG4, TAB:RB->nomm // Clear metamethod cache. + |1: + | ldrd CARG12, NODE:INS->key + | ldr CARG4, NODE:INS->val.it + | ldr NODE:CARG3, NODE:INS->next + | checktp CARG2, LJ_TSTR + | cmpeq CARG1, STR:RC + | bne >5 + | ldrb CARG2, TAB:RB->marked + | checktp CARG4, LJ_TNIL // Key found, but nil value? + | ldrd CARG34, [BASE, RA] + | beq >4 + |2: + | tst CARG2, #LJ_GC_BLACK // isblack(table) + | strd CARG34, NODE:INS->val + | bne >7 + |3: + | ins_next + | + |4: // Check for __newindex if previous value is nil. + | ldr TAB:CARG1, TAB:RB->metatable + | cmp TAB:CARG1, #0 + | beq <2 // No metatable: done. + | ldrb CARG1, TAB:CARG1->nomm + | tst CARG1, #1<vmeta_tsets + | + |5: // Follow hash chain. + | movs NODE:INS, NODE:CARG3 + | bne <1 + | // End of hash chain: key not found, add a new one. + | + | // But check for __newindex first. + | ldr TAB:CARG1, TAB:RB->metatable + | mov CARG3, TMPDp + | str PC, SAVE_PC + | cmp TAB:CARG1, #0 // No metatable: continue. + | str BASE, L->base + | ldrbne CARG2, TAB:CARG1->nomm + | mov CARG1, L + | beq >6 + | tst CARG2, #1<vmeta_tsets // 'no __newindex' flag NOT set: check. + |6: + | mvn CARG4, #~LJ_TSTR + | str STR:RC, TMPDlo + | mov CARG2, TAB:RB + | str CARG4, TMPDhi + | bl extern lj_tab_newkey // (lua_State *L, GCtab *t, TValue *k) + | // Returns TValue *. + | ldr BASE, L->base + | ldrd CARG34, [BASE, RA] + | strd CARG34, [CRET1] + | b <3 // No 2nd write barrier needed. + | + |7: // Possible table write barrier for the value. Skip valiswhite check. + | barrierback TAB:RB, CARG2, CARG3 + | b <3 + break; + case BC_TSETB: + | decode_RB8 RB, INS + | and RC, RC, #255 + | // RA = src*8, RB = table*8, RC = index + | ldrd CARG12, [BASE, RB] + | checktab CARG2, ->vmeta_tsetb // STALL: load CARG12. + | ldr CARG3, TAB:CARG1->asize + | ldr RB, TAB:CARG1->array + | lsl CARG2, RC, #3 + | cmp RC, CARG3 + | ldrdlo CARG34, [CARG2, RB]! + | bhs ->vmeta_tsetb + | ins_next1 // Overwrites RB! + | checktp CARG4, LJ_TNIL + | ldrb INS, TAB:CARG1->marked + | ldrd CARG34, [BASE, RA] + | beq >5 + |1: + | tst INS, #LJ_GC_BLACK // isblack(table) + | strd CARG34, [CARG2] + | bne >7 + |2: + | ins_next2 + | ins_next3 + | + |5: // Check for __newindex if previous value is nil. + | ldr TAB:RA, TAB:CARG1->metatable + | cmp TAB:RA, #0 + | beq <1 // No metatable: done. + | ldrb RA, TAB:RA->nomm + | tst RA, #1<vmeta_tsetb + | + |7: // Possible table write barrier for the value. Skip valiswhite check. + | barrierback TAB:CARG1, INS, CARG3 + | b <2 + break; + case BC_TSETR: + | decode_RB8 RB, INS + | decode_RC8 RC, INS + | // RA = src*8, RB = table*8, RC = key*8 + | ldr TAB:CARG2, [BASE, RB] + | ldr CARG3, [BASE, RC] + | ldrb INS, TAB:CARG2->marked + | ldr CARG1, TAB:CARG2->array + | ldr CARG4, TAB:CARG2->asize + | tst INS, #LJ_GC_BLACK // isblack(table) + | add CARG1, CARG1, CARG3, lsl #3 + | bne >7 + |2: + | cmp CARG3, CARG4 // In array part? + | bhs ->vmeta_tsetr + |->BC_TSETR_Z: + | ldrd CARG34, [BASE, RA] + | ins_next1 + | ins_next2 + | strd CARG34, [CARG1] + | ins_next3 + | + |7: // Possible table write barrier for the value. Skip valiswhite check. + | barrierback TAB:CARG2, INS, RB + | b <2 + break; + + case BC_TSETM: + | // RA = base*8 (table at base-1), RC = num_const (start index) + | add RA, BASE, RA + |1: + | ldr RB, SAVE_MULTRES + | ldr TAB:CARG2, [RA, #-8] // Guaranteed to be a table. + | ldr CARG1, [KBASE, RC, lsl #3] // Integer constant is in lo-word. + | subs RB, RB, #8 + | ldr CARG4, TAB:CARG2->asize + | beq >4 // Nothing to copy? + | add CARG3, CARG1, RB, lsr #3 + | cmp CARG3, CARG4 + | ldr CARG4, TAB:CARG2->array + | add RB, RA, RB + | bhi >5 + | add INS, CARG4, CARG1, lsl #3 + | ldrb CARG1, TAB:CARG2->marked + |3: // Copy result slots to table. + | ldrd CARG34, [RA], #8 + | strd CARG34, [INS], #8 + | cmp RA, RB + | blo <3 + | tst CARG1, #LJ_GC_BLACK // isblack(table) + | bne >7 + |4: + | ins_next + | + |5: // Need to resize array part. + | str BASE, L->base + | mov CARG1, L + | str PC, SAVE_PC + | bl extern lj_tab_reasize // (lua_State *L, GCtab *t, int nasize) + | // Must not reallocate the stack. + | .IOS ldr BASE, L->base + | b <1 + | + |7: // Possible table write barrier for any value. Skip valiswhite check. + | barrierback TAB:CARG2, CARG1, CARG3 + | b <4 + break; + + /* -- Calls and vararg handling ----------------------------------------- */ + + case BC_CALLM: + | // RA = base*8, (RB = nresults+1,) RC = extra_nargs + | ldr CARG1, SAVE_MULTRES + | decode_RC8 NARGS8:RC, INS + | add NARGS8:RC, NARGS8:RC, CARG1 + | b ->BC_CALL_Z + break; + case BC_CALL: + | decode_RC8 NARGS8:RC, INS + | // RA = base*8, (RB = nresults+1,) RC = (nargs+1)*8 + |->BC_CALL_Z: + | mov RB, BASE // Save old BASE for vmeta_call. + | ldrd CARG34, [BASE, RA]! + | sub NARGS8:RC, NARGS8:RC, #8 + | add BASE, BASE, #8 + | checkfunc CARG4, ->vmeta_call + | ins_call + break; + + case BC_CALLMT: + | // RA = base*8, (RB = 0,) RC = extra_nargs + | ldr CARG1, SAVE_MULTRES + | add NARGS8:RC, CARG1, RC, lsl #3 + | b ->BC_CALLT1_Z + break; + case BC_CALLT: + | lsl NARGS8:RC, RC, #3 + | // RA = base*8, (RB = 0,) RC = (nargs+1)*8 + |->BC_CALLT1_Z: + | ldrd LFUNC:CARG34, [RA, BASE]! + | sub NARGS8:RC, NARGS8:RC, #8 + | add RA, RA, #8 + | checkfunc CARG4, ->vmeta_callt + | ldr PC, [BASE, FRAME_PC] + |->BC_CALLT2_Z: + | mov RB, #0 + | ldrb CARG4, LFUNC:CARG3->ffid + | tst PC, #FRAME_TYPE + | bne >7 + |1: + | str LFUNC:CARG3, [BASE, FRAME_FUNC] // Copy function down, but keep PC. + | cmp NARGS8:RC, #0 + | beq >3 + |2: + | ldrd CARG12, [RA, RB] + | add INS, RB, #8 + | cmp INS, NARGS8:RC + | strd CARG12, [BASE, RB] + | mov RB, INS + | bne <2 + |3: + | cmp CARG4, #1 // (> FF_C) Calling a fast function? + | bhi >5 + |4: + | ins_callt + | + |5: // Tailcall to a fast function with a Lua frame below. + | ldr INS, [PC, #-4] + | decode_RA8 RA, INS + | sub CARG1, BASE, RA + | ldr LFUNC:CARG1, [CARG1, #-16] + | ldr CARG1, LFUNC:CARG1->field_pc + | ldr KBASE, [CARG1, #PC2PROTO(k)] + | b <4 + | + |7: // Tailcall from a vararg function. + | eor PC, PC, #FRAME_VARG + | tst PC, #FRAME_TYPEP // Vararg frame below? + | movne CARG4, #0 // Clear ffid if no Lua function below. + | bne <1 + | sub BASE, BASE, PC + | ldr PC, [BASE, FRAME_PC] + | tst PC, #FRAME_TYPE + | movne CARG4, #0 // Clear ffid if no Lua function below. + | b <1 + break; + + case BC_ITERC: + | // RA = base*8, (RB = nresults+1, RC = nargs+1 (2+1)) + | add RA, BASE, RA + | mov RB, BASE // Save old BASE for vmeta_call. + | ldrd CARG34, [RA, #-16] + | ldrd CARG12, [RA, #-8] + | add BASE, RA, #8 + | strd CARG34, [RA, #8] // Copy state. + | strd CARG12, [RA, #16] // Copy control var. + | // STALL: locked CARG34. + | ldrd LFUNC:CARG34, [RA, #-24] + | mov NARGS8:RC, #16 // Iterators get 2 arguments. + | // STALL: load CARG34. + | strd LFUNC:CARG34, [RA] // Copy callable. + | checkfunc CARG4, ->vmeta_call + | ins_call + break; + + case BC_ITERN: + |.if JIT + | hotloop + |.endif + |->vm_IITERN: + | // RA = base*8, (RB = nresults+1, RC = nargs+1 (2+1)) + | add RA, BASE, RA + | ldr TAB:RB, [RA, #-16] + | ldr CARG1, [RA, #-8] // Get index from control var. + | ldr INS, TAB:RB->asize + | ldr CARG2, TAB:RB->array + | add PC, PC, #4 + |1: // Traverse array part. + | subs RC, CARG1, INS + | add CARG3, CARG2, CARG1, lsl #3 + | bhs >5 // Index points after array part? + | ldrd CARG34, [CARG3] + | checktp CARG4, LJ_TNIL + | addeq CARG1, CARG1, #1 // Skip holes in array part. + | beq <1 + | ldrh RC, [PC, #-2] + | mvn CARG2, #~LJ_TISNUM + | strd CARG34, [RA, #8] + | add RC, PC, RC, lsl #2 + | add RB, CARG1, #1 + | strd CARG12, [RA] + | sub PC, RC, #0x20000 + | str RB, [RA, #-8] // Update control var. + |3: + | ins_next + | + |5: // Traverse hash part. + | ldr CARG4, TAB:RB->hmask + | ldr NODE:RB, TAB:RB->node + |6: + | add CARG1, RC, RC, lsl #1 + | cmp RC, CARG4 // End of iteration? Branch to ITERL+1. + | add NODE:CARG3, NODE:RB, CARG1, lsl #3 // node = tab->node + idx*3*8 + | bhi <3 + | ldrd CARG12, NODE:CARG3->val + | checktp CARG2, LJ_TNIL + | add RC, RC, #1 + | beq <6 // Skip holes in hash part. + | ldrh RB, [PC, #-2] + | add RC, RC, INS + | ldrd CARG34, NODE:CARG3->key + | str RC, [RA, #-8] // Update control var. + | strd CARG12, [RA, #8] + | add RC, PC, RB, lsl #2 + | sub PC, RC, #0x20000 + | strd CARG34, [RA] + | b <3 + break; + + case BC_ISNEXT: + | // RA = base*8, RC = target (points to ITERN) + | add RA, BASE, RA + | add RC, PC, RC, lsl #2 + | ldrd CFUNC:CARG12, [RA, #-24] + | ldr CARG3, [RA, #-12] + | ldr CARG4, [RA, #-4] + | checktp CARG2, LJ_TFUNC + | ldrbeq CARG1, CFUNC:CARG1->ffid + | checktpeq CARG3, LJ_TTAB + | checktpeq CARG4, LJ_TNIL + | cmpeq CARG1, #FF_next_N + | subeq PC, RC, #0x20000 + | bne >5 + | ins_next1 + | ins_next2 + | mov CARG1, #0 + | mvn CARG2, #~LJ_KEYINDEX + | strd CARG1, [RA, #-8] // Initialize control var. + |1: + | ins_next3 + |5: // Despecialize bytecode if any of the checks fail. + | mov CARG1, #BC_JMP + | mov OP, #BC_ITERC + | strb CARG1, [PC, #-4] + | sub PC, RC, #0x20000 + |.if JIT + | ldrb CARG1, [PC] + | cmp CARG1, #BC_ITERN + | bne >6 + |.endif + | strb OP, [PC] // Subsumes ins_next1. + | ins_next2 + | b <1 + |.if JIT + |6: // Unpatch JLOOP. + | ldr CARG1, [DISPATCH, #DISPATCH_J(trace)] + | ldrh CARG2, [PC, #2] + | ldr TRACE:CARG1, [CARG1, CARG2, lsl #2] + | // Subsumes ins_next1 and ins_next2. + | ldr INS, TRACE:CARG1->startins + | bfi INS, OP, #0, #8 + | str INS, [PC], #4 + | b <1 + |.endif + break; + + case BC_VARG: + | decode_RB8 RB, INS + | decode_RC8 RC, INS + | // RA = base*8, RB = (nresults+1)*8, RC = numparams*8 + | ldr CARG1, [BASE, FRAME_PC] + | add RC, BASE, RC + | add RA, BASE, RA + | add RC, RC, #FRAME_VARG + | add CARG4, RA, RB + | sub CARG3, BASE, #8 // CARG3 = vtop + | sub RC, RC, CARG1 // RC = vbase + | // Note: RC may now be even _above_ BASE if nargs was < numparams. + | cmp RB, #0 + | sub CARG1, CARG3, RC + | beq >5 // Copy all varargs? + | sub CARG4, CARG4, #16 + |1: // Copy vararg slots to destination slots. + | cmp RC, CARG3 + | ldrdlo CARG12, [RC], #8 + | mvnhs CARG2, #~LJ_TNIL + | cmp RA, CARG4 + | strd CARG12, [RA], #8 + | blo <1 + |2: + | ins_next + | + |5: // Copy all varargs. + | ldr CARG4, L->maxstack + | cmp CARG1, #0 + | movle RB, #8 // MULTRES = (0+1)*8 + | addgt RB, CARG1, #8 + | add CARG2, RA, CARG1 + | str RB, SAVE_MULTRES + | ble <2 + | cmp CARG2, CARG4 + | bhi >7 + |6: + | ldrd CARG12, [RC], #8 + | strd CARG12, [RA], #8 + | cmp RC, CARG3 + | blo <6 + | b <2 + | + |7: // Grow stack for varargs. + | lsr CARG2, CARG1, #3 + | str RA, L->top + | mov CARG1, L + | str BASE, L->base + | sub RC, RC, BASE // Need delta, because BASE may change. + | str PC, SAVE_PC + | sub RA, RA, BASE + | bl extern lj_state_growstack // (lua_State *L, int n) + | ldr BASE, L->base + | add RA, BASE, RA + | add RC, BASE, RC + | sub CARG3, BASE, #8 + | b <6 + break; + + /* -- Returns ----------------------------------------------------------- */ + + case BC_RETM: + | // RA = results*8, RC = extra results + | ldr CARG1, SAVE_MULTRES + | ldr PC, [BASE, FRAME_PC] + | add RA, BASE, RA + | add RC, CARG1, RC, lsl #3 + | b ->BC_RETM_Z + break; + + case BC_RET: + | // RA = results*8, RC = nresults+1 + | ldr PC, [BASE, FRAME_PC] + | lsl RC, RC, #3 + | add RA, BASE, RA + |->BC_RETM_Z: + | str RC, SAVE_MULTRES + |1: + | ands CARG1, PC, #FRAME_TYPE + | eor CARG2, PC, #FRAME_VARG + | bne ->BC_RETV2_Z + | + |->BC_RET_Z: + | // BASE = base, RA = resultptr, RC = (nresults+1)*8, PC = return + | ldr INS, [PC, #-4] + | subs CARG4, RC, #8 + | sub CARG3, BASE, #8 + | beq >3 + |2: + | ldrd CARG12, [RA], #8 + | add BASE, BASE, #8 + | subs CARG4, CARG4, #8 + | strd CARG12, [BASE, #-16] + | bne <2 + |3: + | decode_RA8 RA, INS + | sub CARG4, CARG3, RA + | decode_RB8 RB, INS + | ldr LFUNC:CARG1, [CARG4, FRAME_FUNC] + |5: + | cmp RB, RC // More results expected? + | bhi >6 + | mov BASE, CARG4 + | ldr CARG2, LFUNC:CARG1->field_pc + | ins_next1 + | ins_next2 + | ldr KBASE, [CARG2, #PC2PROTO(k)] + | ins_next3 + | + |6: // Fill up results with nil. + | mvn CARG2, #~LJ_TNIL + | add BASE, BASE, #8 + | add RC, RC, #8 + | str CARG2, [BASE, #-12] + | b <5 + | + |->BC_RETV1_Z: // Non-standard return case. + | add RA, BASE, RA + |->BC_RETV2_Z: + | tst CARG2, #FRAME_TYPEP + | bne ->vm_return + | // Return from vararg function: relocate BASE down. + | sub BASE, BASE, CARG2 + | ldr PC, [BASE, FRAME_PC] + | b <1 + break; + + case BC_RET0: case BC_RET1: + | // RA = results*8, RC = nresults+1 + | ldr PC, [BASE, FRAME_PC] + | lsl RC, RC, #3 + | str RC, SAVE_MULTRES + | ands CARG1, PC, #FRAME_TYPE + | eor CARG2, PC, #FRAME_VARG + | ldreq INS, [PC, #-4] + | bne ->BC_RETV1_Z + if (op == BC_RET1) { + | ldrd CARG12, [BASE, RA] + } + | sub CARG4, BASE, #8 + | decode_RA8 RA, INS + if (op == BC_RET1) { + | strd CARG12, [CARG4] + } + | sub BASE, CARG4, RA + | decode_RB8 RB, INS + | ldr LFUNC:CARG1, [BASE, FRAME_FUNC] + |5: + | cmp RB, RC + | bhi >6 + | ldr CARG2, LFUNC:CARG1->field_pc + | ins_next1 + | ins_next2 + | ldr KBASE, [CARG2, #PC2PROTO(k)] + | ins_next3 + | + |6: // Fill up results with nil. + | sub CARG2, CARG4, #4 + | mvn CARG3, #~LJ_TNIL + | str CARG3, [CARG2, RC] + | add RC, RC, #8 + | b <5 + break; + + /* -- Loops and branches ------------------------------------------------ */ + + |.define FOR_IDX, [RA]; .define FOR_TIDX, [RA, #4] + |.define FOR_STOP, [RA, #8]; .define FOR_TSTOP, [RA, #12] + |.define FOR_STEP, [RA, #16]; .define FOR_TSTEP, [RA, #20] + |.define FOR_EXT, [RA, #24]; .define FOR_TEXT, [RA, #28] + + case BC_FORL: + |.if JIT + | hotloop + |.endif + | // Fall through. Assumes BC_IFORL follows. + break; + + case BC_JFORI: + case BC_JFORL: +#if !LJ_HASJIT + break; +#endif + case BC_FORI: + case BC_IFORL: + | // RA = base*8, RC = target (after end of loop or start of loop) + vk = (op == BC_IFORL || op == BC_JFORL); + | ldrd CARG12, [RA, BASE]! + if (op != BC_JFORL) { + | add RC, PC, RC, lsl #2 + } + if (!vk) { + | ldrd CARG34, FOR_STOP + | checktp CARG2, LJ_TISNUM + | ldr RB, FOR_TSTEP + | bne >5 + | checktp CARG4, LJ_TISNUM + | ldr CARG4, FOR_STEP + | checktpeq RB, LJ_TISNUM + | bne ->vmeta_for + | cmp CARG4, #0 + | blt >4 + | cmp CARG1, CARG3 + } else { + | ldrd CARG34, FOR_STEP + | checktp CARG2, LJ_TISNUM + | bne >5 + | adds CARG1, CARG1, CARG3 + | ldr CARG4, FOR_STOP + if (op == BC_IFORL) { + | addvs RC, PC, #0x20000 // Overflow: prevent branch. + } else { + | bvs >2 // Overflow: do not enter mcode. + } + | cmp CARG3, #0 + | blt >4 + | cmp CARG1, CARG4 + } + |1: + if (op == BC_FORI) { + | subgt PC, RC, #0x20000 + } else if (op == BC_JFORI) { + | sub PC, RC, #0x20000 + | ldrhle RC, [PC, #-2] + } else if (op == BC_IFORL) { + | suble PC, RC, #0x20000 + } + if (vk) { + | strd CARG12, FOR_IDX + } + |2: + | ins_next1 + | ins_next2 + | strd CARG12, FOR_EXT + if (op == BC_JFORI || op == BC_JFORL) { + | ble =>BC_JLOOP + } + |3: + | ins_next3 + | + |4: // Invert check for negative step. + if (!vk) { + | cmp CARG3, CARG1 + } else { + | cmp CARG4, CARG1 + } + | b <1 + | + |5: // FP loop. + if (!vk) { + | cmnlo CARG4, #-LJ_TISNUM + | cmnlo RB, #-LJ_TISNUM + | bhs ->vmeta_for + |.if FPU + | vldr d0, FOR_IDX + | vldr d1, FOR_STOP + | cmp RB, #0 + | vstr d0, FOR_EXT + |.else + | cmp RB, #0 + | strd CARG12, FOR_EXT + | blt >8 + |.endif + } else { + |.if FPU + | vldr d0, FOR_IDX + | vldr d2, FOR_STEP + | vldr d1, FOR_STOP + | cmp CARG4, #0 + | vadd.f64 d0, d0, d2 + |.else + | cmp CARG4, #0 + | blt >8 + | bl extern __aeabi_dadd + | strd CARG12, FOR_IDX + | ldrd CARG34, FOR_STOP + | strd CARG12, FOR_EXT + |.endif + } + |6: + |.if FPU + | vcmpge.f64 d0, d1 + | vcmplt.f64 d1, d0 + | vmrs + |.else + | bl extern __aeabi_cdcmple + |.endif + if (vk) { + |.if FPU + | vstr d0, FOR_IDX + | vstr d0, FOR_EXT + |.endif + } + if (op == BC_FORI) { + | subhi PC, RC, #0x20000 + } else if (op == BC_JFORI) { + | sub PC, RC, #0x20000 + | ldrhls RC, [PC, #-2] + | bls =>BC_JLOOP + } else if (op == BC_IFORL) { + | subls PC, RC, #0x20000 + } else { + | bls =>BC_JLOOP + } + | ins_next1 + | ins_next2 + | b <3 + | + |.if not FPU + |8: // Invert check for negative step. + if (vk) { + | bl extern __aeabi_dadd + | strd CARG12, FOR_IDX + | strd CARG12, FOR_EXT + } + | mov CARG3, CARG1 + | mov CARG4, CARG2 + | ldrd CARG12, FOR_STOP + | b <6 + |.endif + break; + + case BC_ITERL: + |.if JIT + | hotloop + |.endif + | // Fall through. Assumes BC_IITERL follows. + break; + + case BC_JITERL: +#if !LJ_HASJIT + break; +#endif + case BC_IITERL: + | // RA = base*8, RC = target + | ldrd CARG12, [RA, BASE]! + if (op == BC_JITERL) { + | cmn CARG2, #-LJ_TNIL // Stop if iterator returned nil. + | strdne CARG12, [RA, #-8] + | bne =>BC_JLOOP + } else { + | add RC, PC, RC, lsl #2 + | // STALL: load CARG12. + | cmn CARG2, #-LJ_TNIL // Stop if iterator returned nil. + | subne PC, RC, #0x20000 // Otherwise save control var + branch. + | strdne CARG12, [RA, #-8] + } + | ins_next + break; + + case BC_LOOP: + | // RA = base*8, RC = target (loop extent) + | // Note: RA/RC is only used by trace recorder to determine scope/extent + | // This opcode does NOT jump, it's only purpose is to detect a hot loop. + |.if JIT + | hotloop + |.endif + | // Fall through. Assumes BC_ILOOP follows. + break; + + case BC_ILOOP: + | // RA = base*8, RC = target (loop extent) + | ins_next + break; + + case BC_JLOOP: + |.if JIT + | // RA = base (ignored), RC = traceno + | ldr CARG1, [DISPATCH, #DISPATCH_J(trace)] + | mov CARG2, #0 // Traces on ARM don't store the trace number, so use 0. + | ldr TRACE:RC, [CARG1, RC, lsl #2] + | st_vmstate CARG2 + | ldr RA, TRACE:RC->mcode + | str BASE, [DISPATCH, #DISPATCH_GL(jit_base)] + | str L, [DISPATCH, #DISPATCH_GL(tmpbuf.L)] + | bx RA + |.endif + break; + + case BC_JMP: + | // RA = base*8 (only used by trace recorder), RC = target + | add RC, PC, RC, lsl #2 + | sub PC, RC, #0x20000 + | ins_next + break; + + /* -- Function headers -------------------------------------------------- */ + + case BC_FUNCF: + |.if JIT + | hotcall + |.endif + case BC_FUNCV: /* NYI: compiled vararg functions. */ + | // Fall through. Assumes BC_IFUNCF/BC_IFUNCV follow. + break; + + case BC_JFUNCF: +#if !LJ_HASJIT + break; +#endif + case BC_IFUNCF: + | // BASE = new base, RA = BASE+framesize*8, CARG3 = LFUNC, RC = nargs*8 + | ldr CARG1, L->maxstack + | ldrb CARG2, [PC, #-4+PC2PROTO(numparams)] + | ldr KBASE, [PC, #-4+PC2PROTO(k)] + | cmp RA, CARG1 + | bhi ->vm_growstack_l + if (op != BC_JFUNCF) { + | ins_next1 + | ins_next2 + } + |2: + | cmp NARGS8:RC, CARG2, lsl #3 // Check for missing parameters. + | mvn CARG4, #~LJ_TNIL + | blo >3 + if (op == BC_JFUNCF) { + | decode_RD RC, INS + | b =>BC_JLOOP + } else { + | ins_next3 + } + | + |3: // Clear missing parameters. + | strd CARG34, [BASE, NARGS8:RC] + | add NARGS8:RC, NARGS8:RC, #8 + | b <2 + break; + + case BC_JFUNCV: +#if !LJ_HASJIT + break; +#endif + | NYI // NYI: compiled vararg functions + break; /* NYI: compiled vararg functions. */ + + case BC_IFUNCV: + | // BASE = new base, RA = BASE+framesize*8, CARG3 = LFUNC, RC = nargs*8 + | ldr CARG1, L->maxstack + | add CARG4, BASE, RC + | add RA, RA, RC + | str LFUNC:CARG3, [CARG4] // Store copy of LFUNC. + | add CARG2, RC, #8+FRAME_VARG + | ldr KBASE, [PC, #-4+PC2PROTO(k)] + | cmp RA, CARG1 + | str CARG2, [CARG4, #4] // Store delta + FRAME_VARG. + | bhs ->vm_growstack_l + | ldrb RB, [PC, #-4+PC2PROTO(numparams)] + | mov RA, BASE + | mov RC, CARG4 + | cmp RB, #0 + | add BASE, CARG4, #8 + | beq >3 + | mvn CARG3, #~LJ_TNIL + |1: + | cmp RA, RC // Less args than parameters? + | ldrdlo CARG12, [RA], #8 + | movhs CARG2, CARG3 + | strlo CARG3, [RA, #-4] // Clear old fixarg slot (help the GC). + |2: + | subs RB, RB, #1 + | strd CARG12, [CARG4, #8]! + | bne <1 + |3: + | ins_next + break; + + case BC_FUNCC: + case BC_FUNCCW: + | // BASE = new base, RA = BASE+framesize*8, CARG3 = CFUNC, RC = nargs*8 + if (op == BC_FUNCC) { + | ldr CARG4, CFUNC:CARG3->f + } else { + | ldr CARG4, [DISPATCH, #DISPATCH_GL(wrapf)] + } + | add CARG2, RA, NARGS8:RC + | ldr CARG1, L->maxstack + | add RC, BASE, NARGS8:RC + | str BASE, L->base + | cmp CARG2, CARG1 + | str RC, L->top + if (op == BC_FUNCCW) { + | ldr CARG2, CFUNC:CARG3->f + } + | mv_vmstate CARG3, C + | mov CARG1, L + | bhi ->vm_growstack_c // Need to grow stack. + | st_vmstate CARG3 + | blx CARG4 // (lua_State *L [, lua_CFunction f]) + | // Returns nresults. + | ldr BASE, L->base + | mv_vmstate CARG3, INTERP + | ldr CRET2, L->top + | str L, [DISPATCH, #DISPATCH_GL(cur_L)] + | lsl RC, CRET1, #3 + | st_vmstate CARG3 + | ldr PC, [BASE, FRAME_PC] + | sub RA, CRET2, RC // RA = L->top - nresults*8 + | b ->vm_returnc + break; + + /* ---------------------------------------------------------------------- */ + + default: + fprintf(stderr, "Error: undefined opcode BC_%s\n", bc_names[op]); + exit(2); + break; + } +} + +static int build_backend(BuildCtx *ctx) +{ + int op; + + dasm_growpc(Dst, BC__MAX); + + build_subroutines(ctx); + + |.code_op + for (op = 0; op < BC__MAX; op++) + build_ins(ctx, (BCOp)op, op); + + return BC__MAX; +} + +/* Emit pseudo frame-info for all assembler functions. */ +static void emit_asm_debug(BuildCtx *ctx) +{ + int fcofs = (int)((uint8_t *)ctx->glob[GLOB_vm_ffi_call] - ctx->code); + int i; + switch (ctx->mode) { + case BUILD_elfasm: + fprintf(ctx->fp, "\t.section .debug_frame,\"\",%%progbits\n"); + fprintf(ctx->fp, + ".Lframe0:\n" + "\t.long .LECIE0-.LSCIE0\n" + ".LSCIE0:\n" + "\t.long 0xffffffff\n" + "\t.byte 0x1\n" + "\t.string \"\"\n" + "\t.uleb128 0x1\n" + "\t.sleb128 -4\n" + "\t.byte 0xe\n" /* Return address is in lr. */ + "\t.byte 0xc\n\t.uleb128 0xd\n\t.uleb128 0\n" /* def_cfa sp */ + "\t.align 2\n" + ".LECIE0:\n\n"); + fprintf(ctx->fp, + ".LSFDE0:\n" + "\t.long .LEFDE0-.LASFDE0\n" + ".LASFDE0:\n" + "\t.long .Lframe0\n" + "\t.long .Lbegin\n" + "\t.long %d\n" + "\t.byte 0xe\n\t.uleb128 %d\n" /* def_cfa_offset */ + "\t.byte 0x8e\n\t.uleb128 1\n", /* offset lr */ + fcofs, CFRAME_SIZE); + for (i = 11; i >= (LJ_ARCH_HASFPU ? 5 : 4); i--) /* offset r4-r11 */ + fprintf(ctx->fp, "\t.byte %d\n\t.uleb128 %d\n", 0x80+i, 2+(11-i)); +#if LJ_ARCH_HASFPU + for (i = 15; i >= 8; i--) /* offset d8-d15 */ + fprintf(ctx->fp, "\t.byte 5\n\t.uleb128 %d, %d\n", + 64+2*i, 10+2*(15-i)); + fprintf(ctx->fp, "\t.byte 0x84\n\t.uleb128 %d\n", 25); /* offset r4 */ +#endif + fprintf(ctx->fp, + "\t.align 2\n" + ".LEFDE0:\n\n"); +#if LJ_HASFFI + fprintf(ctx->fp, + ".LSFDE1:\n" + "\t.long .LEFDE1-.LASFDE1\n" + ".LASFDE1:\n" + "\t.long .Lframe0\n" + "\t.long lj_vm_ffi_call\n" + "\t.long %d\n" + "\t.byte 0xe\n\t.uleb128 16\n" /* def_cfa_offset */ + "\t.byte 0x8e\n\t.uleb128 1\n" /* offset lr */ + "\t.byte 0x8b\n\t.uleb128 2\n" /* offset r11 */ + "\t.byte 0x85\n\t.uleb128 3\n" /* offset r5 */ + "\t.byte 0x84\n\t.uleb128 4\n" /* offset r4 */ + "\t.byte 0xd\n\t.uleb128 0xb\n" /* def_cfa_register r11 */ + "\t.align 2\n" + ".LEFDE1:\n\n", (int)ctx->codesz - fcofs); +#endif + break; + default: + break; + } +} + diff --git a/fluent-bit/lib/luajit-3065c9/src/vm_arm64.dasc b/fluent-bit/lib/luajit-3065c9/src/vm_arm64.dasc new file mode 100644 index 00000000..3448d0d2 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/vm_arm64.dasc @@ -0,0 +1,4158 @@ +|// Low-level VM code for ARM64 CPUs. +|// Bytecode interpreter, fast functions and helper functions. +|// Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +| +|.arch arm64 +|.section code_op, code_sub +| +|.actionlist build_actionlist +|.globals GLOB_ +|.globalnames globnames +|.externnames extnames +| +|// Note: The ragged indentation of the instructions is intentional. +|// The starting columns indicate data dependencies. +| +|//----------------------------------------------------------------------- +| +|// ARM64 registers and the AAPCS64 ABI 1.0 at a glance: +|// +|// x0-x17 temp, x19-x28 callee-saved, x29 fp, x30 lr +|// x18 is reserved on most platforms. Don't use it, save it or restore it. +|// x31 doesn't exist. Register number 31 either means xzr/wzr (zero) or sp, +|// depending on the instruction. +|// v0-v7 temp, v8-v15 callee-saved (only d8-d15 preserved), v16-v31 temp +|// +|// x0-x7/v0-v7 hold parameters and results. +| +|// Fixed register assignments for the interpreter. +| +|// The following must be C callee-save. +|.define BASE, x19 // Base of current Lua stack frame. +|.define KBASE, x20 // Constants of current Lua function. +|.define PC, x21 // Next PC. +|.define GLREG, x22 // Global state. +|.define LREG, x23 // Register holding lua_State (also in SAVE_L). +|.define TISNUM, x24 // Constant LJ_TISNUM << 47. +|.define TISNUMhi, x25 // Constant LJ_TISNUM << 15. +|.define TISNIL, x26 // Constant -1LL. +|.define fp, x29 // Yes, we have to maintain a frame pointer. +| +|.define ST_INTERP, w26 // Constant -1. +| +|// The following temporaries are not saved across C calls, except for RA/RC. +|.define RA, x27 +|.define RC, x28 +|.define RB, x17 +|.define RAw, w27 +|.define RCw, w28 +|.define RBw, w17 +|.define INS, x16 +|.define INSw, w16 +|.define ITYPE, x15 +|.define TMP0, x8 +|.define TMP1, x9 +|.define TMP2, x10 +|.define TMP3, x11 +|.define TMP0w, w8 +|.define TMP1w, w9 +|.define TMP2w, w10 +|.define TMP3w, w11 +| +|// Calling conventions. Also used as temporaries. +|.define CARG1, x0 +|.define CARG2, x1 +|.define CARG3, x2 +|.define CARG4, x3 +|.define CARG5, x4 +|.define CARG1w, w0 +|.define CARG2w, w1 +|.define CARG3w, w2 +|.define CARG4w, w3 +|.define CARG5w, w4 +| +|.define FARG1, d0 +|.define FARG2, d1 +| +|.define CRET1, x0 +|.define CRET1w, w0 +| +|// Stack layout while in interpreter. Must match with lj_frame.h. +| +|.define CFRAME_SPACE, 208 +|//----- 16 byte aligned, <-- sp entering interpreter +|.define SAVE_FP_LR_, 192 +|.define SAVE_GPR_, 112 // 112+10*8: 64 bit GPR saves +|.define SAVE_FPR_, 48 // 48+8*8: 64 bit FPR saves +|// Unused [sp, #44] // 32 bit values +|.define SAVE_NRES, [sp, #40] +|.define SAVE_ERRF, [sp, #36] +|.define SAVE_MULTRES, [sp, #32] +|.define TMPD, [sp, #24] // 64 bit values +|.define SAVE_L, [sp, #16] +|.define SAVE_PC, [sp, #8] +|.define SAVE_CFRAME, [sp, #0] +|//----- 16 byte aligned, <-- sp while in interpreter. +| +|.define TMPDofs, #24 +| +|.macro save_, gpr1, gpr2, fpr1, fpr2 +| stp d..fpr2, d..fpr1, [sp, # SAVE_FPR_+(14-fpr1)*8] +| stp x..gpr2, x..gpr1, [sp, # SAVE_GPR_+(27-gpr1)*8] +|.endmacro +|.macro rest_, gpr1, gpr2, fpr1, fpr2 +| ldp d..fpr2, d..fpr1, [sp, # SAVE_FPR_+(14-fpr1)*8] +| ldp x..gpr2, x..gpr1, [sp, # SAVE_GPR_+(27-gpr1)*8] +|.endmacro +| +|.macro saveregs +| sub sp, sp, # CFRAME_SPACE +| stp fp, lr, [sp, # SAVE_FP_LR_] +| add fp, sp, # SAVE_FP_LR_ +| stp x20, x19, [sp, # SAVE_GPR_+(27-19)*8] +| save_ 21, 22, 8, 9 +| save_ 23, 24, 10, 11 +| save_ 25, 26, 12, 13 +| save_ 27, 28, 14, 15 +|.endmacro +|.macro restoreregs +| ldp x20, x19, [sp, # SAVE_GPR_+(27-19)*8] +| rest_ 21, 22, 8, 9 +| rest_ 23, 24, 10, 11 +| rest_ 25, 26, 12, 13 +| rest_ 27, 28, 14, 15 +| ldp fp, lr, [sp, # SAVE_FP_LR_] +| add sp, sp, # CFRAME_SPACE +|.endmacro +| +|// Type definitions. Some of these are only used for documentation. +|.type L, lua_State, LREG +|.type GL, global_State, GLREG +|.type TVALUE, TValue +|.type GCOBJ, GCobj +|.type STR, GCstr +|.type TAB, GCtab +|.type LFUNC, GCfuncL +|.type CFUNC, GCfuncC +|.type PROTO, GCproto +|.type UPVAL, GCupval +|.type NODE, Node +|.type NARGS8, int +|.type TRACE, GCtrace +|.type SBUF, SBuf +| +|//----------------------------------------------------------------------- +| +|// Trap for not-yet-implemented parts. +|.macro NYI; brk; .endmacro +| +|//----------------------------------------------------------------------- +| +|// Access to frame relative to BASE. +|.define FRAME_FUNC, #-16 +|.define FRAME_PC, #-8 +| +|// Endian-specific defines. +|.if ENDIAN_LE +|.define LO, 0 +|.define OFS_RD, 2 +|.define OFS_RB, 3 +|.define OFS_RA, 1 +|.define OFS_OP, 0 +|.else +|.define LO, 4 +|.define OFS_RD, 0 +|.define OFS_RB, 0 +|.define OFS_RA, 2 +|.define OFS_OP, 3 +|.endif +| +|.macro decode_RA, dst, ins; ubfx dst, ins, #8, #8; .endmacro +|.macro decode_RB, dst, ins; ubfx dst, ins, #24, #8; .endmacro +|.macro decode_RC, dst, ins; ubfx dst, ins, #16, #8; .endmacro +|.macro decode_RD, dst, ins; ubfx dst, ins, #16, #16; .endmacro +|.macro decode_RC8RD, dst, src; ubfiz dst, src, #3, #8; .endmacro +| +|// Instruction decode+dispatch. +|.macro ins_NEXT +| ldr INSw, [PC], #4 +| add TMP1, GL, INS, uxtb #3 +| decode_RA RA, INS +| ldr TMP0, [TMP1, #GG_G2DISP] +| decode_RD RC, INS +| br TMP0 +|.endmacro +| +|// Instruction footer. +|.if 1 +| // Replicated dispatch. Less unpredictable branches, but higher I-Cache use. +| .define ins_next, ins_NEXT +| .define ins_next_, ins_NEXT +|.else +| // Common dispatch. Lower I-Cache use, only one (very) unpredictable branch. +| // Affects only certain kinds of benchmarks (and only with -j off). +| .macro ins_next +| b ->ins_next +| .endmacro +| .macro ins_next_ +| ->ins_next: +| ins_NEXT +| .endmacro +|.endif +| +|// Call decode and dispatch. +|.macro ins_callt +| // BASE = new base, CARG3 = LFUNC/CFUNC, RC = nargs*8, FRAME_PC(BASE) = PC +| ldr PC, LFUNC:CARG3->pc +| ldr INSw, [PC], #4 +| add TMP1, GL, INS, uxtb #3 +| decode_RA RA, INS +| ldr TMP0, [TMP1, #GG_G2DISP] +| add RA, BASE, RA, lsl #3 +| br TMP0 +|.endmacro +| +|.macro ins_call +| // BASE = new base, CARG3 = LFUNC/CFUNC, RC = nargs*8, PC = caller PC +| str PC, [BASE, FRAME_PC] +| ins_callt +|.endmacro +| +|//----------------------------------------------------------------------- +| +|// Macros to check the TValue type and extract the GCobj. Branch on failure. +|.macro checktp, reg, tp, target +| asr ITYPE, reg, #47 +| cmn ITYPE, #-tp +| and reg, reg, #LJ_GCVMASK +| bne target +|.endmacro +|.macro checktp, dst, reg, tp, target +| asr ITYPE, reg, #47 +| cmn ITYPE, #-tp +| and dst, reg, #LJ_GCVMASK +| bne target +|.endmacro +|.macro checkstr, reg, target; checktp reg, LJ_TSTR, target; .endmacro +|.macro checktab, reg, target; checktp reg, LJ_TTAB, target; .endmacro +|.macro checkfunc, reg, target; checktp reg, LJ_TFUNC, target; .endmacro +|.macro checkint, reg, target +| cmp TISNUMhi, reg, lsr #32 +| bne target +|.endmacro +|.macro checknum, reg, target +| cmp TISNUMhi, reg, lsr #32 +| bls target +|.endmacro +|.macro checknumber, reg, target +| cmp TISNUMhi, reg, lsr #32 +| blo target +|.endmacro +| +|.macro mov_false, reg; movn reg, #0x8000, lsl #32; .endmacro +|.macro mov_true, reg; movn reg, #0x0001, lsl #48; .endmacro +| +#define GL_J(field) (GG_G2J + (int)offsetof(jit_State, field)) +| +#define PC2PROTO(field) ((int)offsetof(GCproto, field)-(int)sizeof(GCproto)) +| +|.macro hotcheck, delta +| lsr CARG1, PC, #1 +| and CARG1, CARG1, #126 +| add CARG1, CARG1, #GG_G2DISP+GG_DISP2HOT +| ldrh CARG2w, [GL, CARG1] +| subs CARG2, CARG2, #delta +| strh CARG2w, [GL, CARG1] +|.endmacro +| +|.macro hotloop +| hotcheck HOTCOUNT_LOOP +| blo ->vm_hotloop +|.endmacro +| +|.macro hotcall +| hotcheck HOTCOUNT_CALL +| blo ->vm_hotcall +|.endmacro +| +|// Set current VM state. +|.macro mv_vmstate, reg, st; movn reg, #LJ_VMST_..st; .endmacro +|.macro st_vmstate, reg; str reg, GL->vmstate; .endmacro +| +|// Move table write barrier back. Overwrites mark and tmp. +|.macro barrierback, tab, mark, tmp +| ldr tmp, GL->gc.grayagain +| and mark, mark, #~LJ_GC_BLACK // black2gray(tab) +| str tab, GL->gc.grayagain +| strb mark, tab->marked +| str tmp, tab->gclist +|.endmacro +| +|//----------------------------------------------------------------------- + +#if !LJ_DUALNUM +#error "Only dual-number mode supported for ARM64 target" +#endif + +/* Generate subroutines used by opcodes and other parts of the VM. */ +/* The .code_sub section should be last to help static branch prediction. */ +static void build_subroutines(BuildCtx *ctx) +{ + |.code_sub + | + |//----------------------------------------------------------------------- + |//-- Return handling ---------------------------------------------------- + |//----------------------------------------------------------------------- + | + |->vm_returnp: + | // See vm_return. Also: RB = previous base. + | tbz PC, #2, ->cont_dispatch // (PC & FRAME_P) == 0? + | + | // Return from pcall or xpcall fast func. + | ldr PC, [RB, FRAME_PC] // Fetch PC of previous frame. + | mov_true TMP0 + | mov BASE, RB + | // Prepending may overwrite the pcall frame, so do it at the end. + | str TMP0, [RA, #-8]! // Prepend true to results. + | + |->vm_returnc: + | adds RC, RC, #8 // RC = (nresults+1)*8. + | mov CRET1, #LUA_YIELD + | beq ->vm_unwind_c_eh + | str RCw, SAVE_MULTRES + | ands CARG1, PC, #FRAME_TYPE + | beq ->BC_RET_Z // Handle regular return to Lua. + | + |->vm_return: + | // BASE = base, RA = resultptr, RC/MULTRES = (nresults+1)*8, PC = return + | // CARG1 = PC & FRAME_TYPE + | and RB, PC, #~FRAME_TYPEP + | cmp CARG1, #FRAME_C + | sub RB, BASE, RB // RB = previous base. + | bne ->vm_returnp + | + | str RB, L->base + | ldrsw CARG2, SAVE_NRES // CARG2 = nresults+1. + | mv_vmstate TMP0w, C + | sub BASE, BASE, #16 + | subs TMP2, RC, #8 + | st_vmstate TMP0w + | beq >2 + |1: + | subs TMP2, TMP2, #8 + | ldr TMP0, [RA], #8 + | str TMP0, [BASE], #8 + | bne <1 + |2: + | cmp RC, CARG2, lsl #3 // More/less results wanted? + | bne >6 + |3: + | str BASE, L->top // Store new top. + | + |->vm_leave_cp: + | ldr RC, SAVE_CFRAME // Restore previous C frame. + | mov CRET1, #0 // Ok return status for vm_pcall. + | str RC, L->cframe + | + |->vm_leave_unw: + | restoreregs + | ret + | + |6: + | bgt >7 // Less results wanted? + | // More results wanted. Check stack size and fill up results with nil. + | ldr CARG3, L->maxstack + | cmp BASE, CARG3 + | bhs >8 + | str TISNIL, [BASE], #8 + | add RC, RC, #8 + | b <2 + | + |7: // Less results wanted. + | cbz CARG2, <3 // LUA_MULTRET+1 case? + | sub CARG1, RC, CARG2, lsl #3 + | sub BASE, BASE, CARG1 // Shrink top. + | b <3 + | + |8: // Corner case: need to grow stack for filling up results. + | // This can happen if: + | // - A C function grows the stack (a lot). + | // - The GC shrinks the stack in between. + | // - A return back from a lua_call() with (high) nresults adjustment. + | str BASE, L->top // Save current top held in BASE (yes). + | mov CARG1, L + | bl extern lj_state_growstack // (lua_State *L, int n) + | ldr BASE, L->top // Need the (realloced) L->top in BASE. + | ldrsw CARG2, SAVE_NRES + | b <2 + | + |->vm_unwind_c: // Unwind C stack, return from vm_pcall. + | // (void *cframe, int errcode) + | mov sp, CARG1 + | mov CRET1, CARG2 + |->vm_unwind_c_eh: // Landing pad for external unwinder. + | ldr L, SAVE_L + | mv_vmstate TMP0w, C + | ldr GL, L->glref + | st_vmstate TMP0w + | b ->vm_leave_unw + | + |->vm_unwind_ff: // Unwind C stack, return from ff pcall. + | // (void *cframe) + | and sp, CARG1, #CFRAME_RAWMASK + |->vm_unwind_ff_eh: // Landing pad for external unwinder. + | ldr L, SAVE_L + | movz TISNUM, #(LJ_TISNUM>>1)&0xffff, lsl #48 + | movz TISNUMhi, #(LJ_TISNUM>>1)&0xffff, lsl #16 + | movn TISNIL, #0 + | mov RC, #16 // 2 results: false + error message. + | ldr BASE, L->base + | ldr GL, L->glref // Setup pointer to global state. + | mov_false TMP0 + | sub RA, BASE, #8 // Results start at BASE-8. + | ldr PC, [BASE, FRAME_PC] // Fetch PC of previous frame. + | str TMP0, [BASE, #-8] // Prepend false to error message. + | st_vmstate ST_INTERP + | b ->vm_returnc + | + |//----------------------------------------------------------------------- + |//-- Grow stack for calls ----------------------------------------------- + |//----------------------------------------------------------------------- + | + |->vm_growstack_c: // Grow stack for C function. + | // CARG1 = L + | mov CARG2, #LUA_MINSTACK + | b >2 + | + |->vm_growstack_l: // Grow stack for Lua function. + | // BASE = new base, RA = BASE+framesize*8, RC = nargs*8, PC = first PC + | add RC, BASE, RC + | sub RA, RA, BASE + | mov CARG1, L + | stp BASE, RC, L->base + | add PC, PC, #4 // Must point after first instruction. + | lsr CARG2, RA, #3 + |2: + | // L->base = new base, L->top = top + | str PC, SAVE_PC + | bl extern lj_state_growstack // (lua_State *L, int n) + | ldp BASE, RC, L->base + | ldr LFUNC:CARG3, [BASE, FRAME_FUNC] + | sub NARGS8:RC, RC, BASE + | and LFUNC:CARG3, CARG3, #LJ_GCVMASK + | // BASE = new base, RB = LFUNC/CFUNC, RC = nargs*8, FRAME_PC(BASE) = PC + | ins_callt // Just retry the call. + | + |//----------------------------------------------------------------------- + |//-- Entry points into the assembler VM --------------------------------- + |//----------------------------------------------------------------------- + | + |->vm_resume: // Setup C frame and resume thread. + | // (lua_State *L, TValue *base, int nres1 = 0, ptrdiff_t ef = 0) + | saveregs + | mov L, CARG1 + | ldr GL, L->glref // Setup pointer to global state. + | mov BASE, CARG2 + | str L, SAVE_L + | mov PC, #FRAME_CP + | str wzr, SAVE_NRES + | add TMP0, sp, #CFRAME_RESUME + | ldrb TMP1w, L->status + | str wzr, SAVE_ERRF + | str L, SAVE_PC // Any value outside of bytecode is ok. + | str xzr, SAVE_CFRAME + | str TMP0, L->cframe + | cbz TMP1w, >3 + | + | // Resume after yield (like a return). + | str L, GL->cur_L + | mov RA, BASE + | ldp BASE, CARG1, L->base + | movz TISNUM, #(LJ_TISNUM>>1)&0xffff, lsl #48 + | movz TISNUMhi, #(LJ_TISNUM>>1)&0xffff, lsl #16 + | ldr PC, [BASE, FRAME_PC] + | strb wzr, L->status + | movn TISNIL, #0 + | sub RC, CARG1, BASE + | ands CARG1, PC, #FRAME_TYPE + | add RC, RC, #8 + | st_vmstate ST_INTERP + | str RCw, SAVE_MULTRES + | beq ->BC_RET_Z + | b ->vm_return + | + |->vm_pcall: // Setup protected C frame and enter VM. + | // (lua_State *L, TValue *base, int nres1, ptrdiff_t ef) + | saveregs + | mov PC, #FRAME_CP + | str CARG4w, SAVE_ERRF + | b >1 + | + |->vm_call: // Setup C frame and enter VM. + | // (lua_State *L, TValue *base, int nres1) + | saveregs + | mov PC, #FRAME_C + | + |1: // Entry point for vm_pcall above (PC = ftype). + | ldr RC, L:CARG1->cframe + | str CARG3w, SAVE_NRES + | mov L, CARG1 + | str CARG1, SAVE_L + | ldr GL, L->glref // Setup pointer to global state. + | mov BASE, CARG2 + | str CARG1, SAVE_PC // Any value outside of bytecode is ok. + | add TMP0, sp, #0 + | str RC, SAVE_CFRAME + | str TMP0, L->cframe // Add our C frame to cframe chain. + | + |3: // Entry point for vm_cpcall/vm_resume (BASE = base, PC = ftype). + | str L, GL->cur_L + | ldp RB, CARG1, L->base // RB = old base (for vmeta_call). + | movz TISNUM, #(LJ_TISNUM>>1)&0xffff, lsl #48 + | movz TISNUMhi, #(LJ_TISNUM>>1)&0xffff, lsl #16 + | add PC, PC, BASE + | movn TISNIL, #0 + | sub PC, PC, RB // PC = frame delta + frame type + | sub NARGS8:RC, CARG1, BASE + | st_vmstate ST_INTERP + | + |->vm_call_dispatch: + | // RB = old base, BASE = new base, RC = nargs*8, PC = caller PC + | ldr CARG3, [BASE, FRAME_FUNC] + | checkfunc CARG3, ->vmeta_call + | + |->vm_call_dispatch_f: + | ins_call + | // BASE = new base, CARG3 = func, RC = nargs*8, PC = caller PC + | + |->vm_cpcall: // Setup protected C frame, call C. + | // (lua_State *L, lua_CFunction func, void *ud, lua_CPFunction cp) + | saveregs + | mov L, CARG1 + | ldr RA, L:CARG1->stack + | str CARG1, SAVE_L + | ldr GL, L->glref // Setup pointer to global state. + | ldr RB, L->top + | str CARG1, SAVE_PC // Any value outside of bytecode is ok. + | ldr RC, L->cframe + | sub RA, RA, RB // Compute -savestack(L, L->top). + | str RAw, SAVE_NRES // Neg. delta means cframe w/o frame. + | str wzr, SAVE_ERRF // No error function. + | add TMP0, sp, #0 + | str RC, SAVE_CFRAME + | str TMP0, L->cframe // Add our C frame to cframe chain. + | str L, GL->cur_L + | blr CARG4 // (lua_State *L, lua_CFunction func, void *ud) + | mov BASE, CRET1 + | mov PC, #FRAME_CP + | cbnz BASE, <3 // Else continue with the call. + | b ->vm_leave_cp // No base? Just remove C frame. + | + |//----------------------------------------------------------------------- + |//-- Metamethod handling ------------------------------------------------ + |//----------------------------------------------------------------------- + | + |//-- Continuation dispatch ---------------------------------------------- + | + |->cont_dispatch: + | // BASE = meta base, RA = resultptr, RC = (nresults+1)*8 + | ldr LFUNC:CARG3, [RB, FRAME_FUNC] + | ldr CARG1, [BASE, #-32] // Get continuation. + | mov CARG4, BASE + | mov BASE, RB // Restore caller BASE. + | and LFUNC:CARG3, CARG3, #LJ_GCVMASK + |.if FFI + | cmp CARG1, #1 + |.endif + | ldr PC, [CARG4, #-24] // Restore PC from [cont|PC]. + | add TMP0, RA, RC + | str TISNIL, [TMP0, #-8] // Ensure one valid arg. + |.if FFI + | bls >1 + |.endif + | ldr CARG3, LFUNC:CARG3->pc + | ldr KBASE, [CARG3, #PC2PROTO(k)] + | // BASE = base, RA = resultptr, CARG4 = meta base + | br CARG1 + | + |.if FFI + |1: + | beq ->cont_ffi_callback // cont = 1: return from FFI callback. + | // cont = 0: tailcall from C function. + | sub CARG4, CARG4, #32 + | sub RC, CARG4, BASE + | b ->vm_call_tail + |.endif + | + |->cont_cat: // RA = resultptr, CARG4 = meta base + | ldr INSw, [PC, #-4] + | sub CARG2, CARG4, #32 + | ldr TMP0, [RA] + | str BASE, L->base + | decode_RB RB, INS + | decode_RA RA, INS + | add TMP1, BASE, RB, lsl #3 + | subs TMP1, CARG2, TMP1 + | beq >1 + | str TMP0, [CARG2] + | lsr CARG3, TMP1, #3 + | b ->BC_CAT_Z + | + |1: + | str TMP0, [BASE, RA, lsl #3] + | b ->cont_nop + | + |//-- Table indexing metamethods ----------------------------------------- + | + |->vmeta_tgets1: + | movn CARG4, #~LJ_TSTR + | add CARG2, BASE, RB, lsl #3 + | add CARG4, STR:RC, CARG4, lsl #47 + | b >2 + | + |->vmeta_tgets: + | movk CARG2, #(LJ_TTAB>>1)&0xffff, lsl #48 + | str CARG2, GL->tmptv + | add CARG2, GL, #offsetof(global_State, tmptv) + |2: + | add CARG3, sp, TMPDofs + | str CARG4, TMPD + | b >1 + | + |->vmeta_tgetb: // RB = table, RC = index + | add RC, RC, TISNUM + | add CARG2, BASE, RB, lsl #3 + | add CARG3, sp, TMPDofs + | str RC, TMPD + | b >1 + | + |->vmeta_tgetv: // RB = table, RC = key + | add CARG2, BASE, RB, lsl #3 + | add CARG3, BASE, RC, lsl #3 + |1: + | str BASE, L->base + | mov CARG1, L + | str PC, SAVE_PC + | bl extern lj_meta_tget // (lua_State *L, TValue *o, TValue *k) + | // Returns TValue * (finished) or NULL (metamethod). + | cbz CRET1, >3 + | ldr TMP0, [CRET1] + | str TMP0, [BASE, RA, lsl #3] + | ins_next + | + |3: // Call __index metamethod. + | // BASE = base, L->top = new base, stack = cont/func/t/k + | sub TMP1, BASE, #FRAME_CONT + | ldr BASE, L->top + | mov NARGS8:RC, #16 // 2 args for func(t, k). + | ldr LFUNC:CARG3, [BASE, FRAME_FUNC] // Guaranteed to be a function here. + | str PC, [BASE, #-24] // [cont|PC] + | sub PC, BASE, TMP1 + | and LFUNC:CARG3, CARG3, #LJ_GCVMASK + | b ->vm_call_dispatch_f + | + |->vmeta_tgetr: + | sxtw CARG2, TMP1w + | bl extern lj_tab_getinth // (GCtab *t, int32_t key) + | // Returns cTValue * or NULL. + | mov TMP0, TISNIL + | cbz CRET1, ->BC_TGETR_Z + | ldr TMP0, [CRET1] + | b ->BC_TGETR_Z + | + |//----------------------------------------------------------------------- + | + |->vmeta_tsets1: + | movn CARG4, #~LJ_TSTR + | add CARG2, BASE, RB, lsl #3 + | add CARG4, STR:RC, CARG4, lsl #47 + | b >2 + | + |->vmeta_tsets: + | movk CARG2, #(LJ_TTAB>>1)&0xffff, lsl #48 + | str CARG2, GL->tmptv + | add CARG2, GL, #offsetof(global_State, tmptv) + |2: + | add CARG3, sp, TMPDofs + | str CARG4, TMPD + | b >1 + | + |->vmeta_tsetb: // RB = table, RC = index + | add RC, RC, TISNUM + | add CARG2, BASE, RB, lsl #3 + | add CARG3, sp, TMPDofs + | str RC, TMPD + | b >1 + | + |->vmeta_tsetv: + | add CARG2, BASE, RB, lsl #3 + | add CARG3, BASE, RC, lsl #3 + |1: + | str BASE, L->base + | mov CARG1, L + | str PC, SAVE_PC + | bl extern lj_meta_tset // (lua_State *L, TValue *o, TValue *k) + | // Returns TValue * (finished) or NULL (metamethod). + | ldr TMP0, [BASE, RA, lsl #3] + | cbz CRET1, >3 + | // NOBARRIER: lj_meta_tset ensures the table is not black. + | str TMP0, [CRET1] + | ins_next + | + |3: // Call __newindex metamethod. + | // BASE = base, L->top = new base, stack = cont/func/t/k/(v) + | sub TMP1, BASE, #FRAME_CONT + | ldr BASE, L->top + | mov NARGS8:RC, #24 // 3 args for func(t, k, v). + | ldr LFUNC:CARG3, [BASE, FRAME_FUNC] // Guaranteed to be a function here. + | str TMP0, [BASE, #16] // Copy value to third argument. + | str PC, [BASE, #-24] // [cont|PC] + | sub PC, BASE, TMP1 + | and LFUNC:CARG3, CARG3, #LJ_GCVMASK + | b ->vm_call_dispatch_f + | + |->vmeta_tsetr: + | sxtw CARG3, TMP1w + | str BASE, L->base + | mov CARG1, L + | str PC, SAVE_PC + | bl extern lj_tab_setinth // (lua_State *L, GCtab *t, int32_t key) + | // Returns TValue *. + | b ->BC_TSETR_Z + | + |//-- Comparison metamethods --------------------------------------------- + | + |->vmeta_comp: + | add CARG2, BASE, RA, lsl #3 + | sub PC, PC, #4 + | add CARG3, BASE, RC, lsl #3 + | str BASE, L->base + | mov CARG1, L + | str PC, SAVE_PC + | uxtb CARG4w, INSw + | bl extern lj_meta_comp // (lua_State *L, TValue *o1, *o2, int op) + | // Returns 0/1 or TValue * (metamethod). + |3: + | cmp CRET1, #1 + | bhi ->vmeta_binop + |4: + | ldrh RBw, [PC, # OFS_RD] + | add PC, PC, #4 + | add RB, PC, RB, lsl #2 + | sub RB, RB, #0x20000 + | csel PC, PC, RB, lo + |->cont_nop: + | ins_next + | + |->cont_ra: // RA = resultptr + | ldr INSw, [PC, #-4] + | ldr TMP0, [RA] + | decode_RA TMP1, INS + | str TMP0, [BASE, TMP1, lsl #3] + | b ->cont_nop + | + |->cont_condt: // RA = resultptr + | ldr TMP0, [RA] + | mov_true TMP1 + | cmp TMP1, TMP0 // Branch if result is true. + | b <4 + | + |->cont_condf: // RA = resultptr + | ldr TMP0, [RA] + | mov_false TMP1 + | cmp TMP0, TMP1 // Branch if result is false. + | b <4 + | + |->vmeta_equal: + | // CARG2, CARG3, CARG4 are already set by BC_ISEQV/BC_ISNEV. + | and TAB:CARG3, CARG3, #LJ_GCVMASK + | sub PC, PC, #4 + | str BASE, L->base + | mov CARG1, L + | str PC, SAVE_PC + | bl extern lj_meta_equal // (lua_State *L, GCobj *o1, *o2, int ne) + | // Returns 0/1 or TValue * (metamethod). + | b <3 + | + |->vmeta_equal_cd: + |.if FFI + | sub PC, PC, #4 + | str BASE, L->base + | mov CARG1, L + | mov CARG2, INS + | str PC, SAVE_PC + | bl extern lj_meta_equal_cd // (lua_State *L, BCIns op) + | // Returns 0/1 or TValue * (metamethod). + | b <3 + |.endif + | + |->vmeta_istype: + | sub PC, PC, #4 + | str BASE, L->base + | mov CARG1, L + | mov CARG2, RA + | mov CARG3, RC + | str PC, SAVE_PC + | bl extern lj_meta_istype // (lua_State *L, BCReg ra, BCReg tp) + | b ->cont_nop + | + |//-- Arithmetic metamethods --------------------------------------------- + | + |->vmeta_arith_vn: + | add CARG3, BASE, RB, lsl #3 + | add CARG4, KBASE, RC, lsl #3 + | b >1 + | + |->vmeta_arith_nv: + | add CARG4, BASE, RB, lsl #3 + | add CARG3, KBASE, RC, lsl #3 + | b >1 + | + |->vmeta_unm: + | add CARG3, BASE, RC, lsl #3 + | mov CARG4, CARG3 + | b >1 + | + |->vmeta_arith_vv: + | add CARG3, BASE, RB, lsl #3 + | add CARG4, BASE, RC, lsl #3 + |1: + | uxtb CARG5w, INSw + | add CARG2, BASE, RA, lsl #3 + | str BASE, L->base + | mov CARG1, L + | str PC, SAVE_PC + | bl extern lj_meta_arith // (lua_State *L, TValue *ra,*rb,*rc, BCReg op) + | // Returns NULL (finished) or TValue * (metamethod). + | cbz CRET1, ->cont_nop + | + | // Call metamethod for binary op. + |->vmeta_binop: + | // BASE = old base, CRET1 = new base, stack = cont/func/o1/o2 + | sub TMP1, CRET1, BASE + | str PC, [CRET1, #-24] // [cont|PC] + | add PC, TMP1, #FRAME_CONT + | mov BASE, CRET1 + | mov NARGS8:RC, #16 // 2 args for func(o1, o2). + | b ->vm_call_dispatch + | + |->vmeta_len: + | add CARG2, BASE, RC, lsl #3 +#if LJ_52 + | mov TAB:RC, TAB:CARG1 // Save table (ignored for other types). +#endif + | str BASE, L->base + | mov CARG1, L + | str PC, SAVE_PC + | bl extern lj_meta_len // (lua_State *L, TValue *o) + | // Returns NULL (retry) or TValue * (metamethod base). +#if LJ_52 + | cbnz CRET1, ->vmeta_binop // Binop call for compatibility. + | mov TAB:CARG1, TAB:RC + | b ->BC_LEN_Z +#else + | b ->vmeta_binop // Binop call for compatibility. +#endif + | + |//-- Call metamethod ---------------------------------------------------- + | + |->vmeta_call: // Resolve and call __call metamethod. + | // RB = old base, BASE = new base, RC = nargs*8 + | mov CARG1, L + | str RB, L->base // This is the callers base! + | sub CARG2, BASE, #16 + | str PC, SAVE_PC + | add CARG3, BASE, NARGS8:RC + | bl extern lj_meta_call // (lua_State *L, TValue *func, TValue *top) + | ldr LFUNC:CARG3, [BASE, FRAME_FUNC] // Guaranteed to be a function here. + | add NARGS8:RC, NARGS8:RC, #8 // Got one more argument now. + | and LFUNC:CARG3, CARG3, #LJ_GCVMASK + | ins_call + | + |->vmeta_callt: // Resolve __call for BC_CALLT. + | // BASE = old base, RA = new base, RC = nargs*8 + | mov CARG1, L + | str BASE, L->base + | sub CARG2, RA, #16 + | str PC, SAVE_PC + | add CARG3, RA, NARGS8:RC + | bl extern lj_meta_call // (lua_State *L, TValue *func, TValue *top) + | ldr TMP1, [RA, FRAME_FUNC] // Guaranteed to be a function here. + | ldr PC, [BASE, FRAME_PC] + | add NARGS8:RC, NARGS8:RC, #8 // Got one more argument now. + | and LFUNC:CARG3, TMP1, #LJ_GCVMASK + | b ->BC_CALLT2_Z + | + |//-- Argument coercion for 'for' statement ------------------------------ + | + |->vmeta_for: + | mov CARG1, L + | str BASE, L->base + | mov CARG2, RA + | str PC, SAVE_PC + | bl extern lj_meta_for // (lua_State *L, TValue *base) + | ldr INSw, [PC, #-4] + |.if JIT + | uxtb TMP0w, INSw + |.endif + | decode_RA RA, INS + | decode_RD RC, INS + |.if JIT + | cmp TMP0, #BC_JFORI + | beq =>BC_JFORI + |.endif + | b =>BC_FORI + | + |//----------------------------------------------------------------------- + |//-- Fast functions ----------------------------------------------------- + |//----------------------------------------------------------------------- + | + |.macro .ffunc, name + |->ff_ .. name: + |.endmacro + | + |.macro .ffunc_1, name + |->ff_ .. name: + | ldr CARG1, [BASE] + | cmp NARGS8:RC, #8 + | blo ->fff_fallback + |.endmacro + | + |.macro .ffunc_2, name + |->ff_ .. name: + | ldp CARG1, CARG2, [BASE] + | cmp NARGS8:RC, #16 + | blo ->fff_fallback + |.endmacro + | + |.macro .ffunc_n, name + | .ffunc name + | ldr CARG1, [BASE] + | cmp NARGS8:RC, #8 + | ldr FARG1, [BASE] + | blo ->fff_fallback + | checknum CARG1, ->fff_fallback + |.endmacro + | + |.macro .ffunc_nn, name + | .ffunc name + | ldp CARG1, CARG2, [BASE] + | cmp NARGS8:RC, #16 + | ldp FARG1, FARG2, [BASE] + | blo ->fff_fallback + | checknum CARG1, ->fff_fallback + | checknum CARG2, ->fff_fallback + |.endmacro + | + |// Inlined GC threshold check. Caveat: uses CARG1 and CARG2. + |.macro ffgccheck + | ldp CARG1, CARG2, GL->gc.total // Assumes threshold follows total. + | cmp CARG1, CARG2 + | blt >1 + | bl ->fff_gcstep + |1: + |.endmacro + | + |//-- Base library: checks ----------------------------------------------- + | + |.ffunc_1 assert + | ldr PC, [BASE, FRAME_PC] + | mov_false TMP1 + | cmp CARG1, TMP1 + | bhs ->fff_fallback + | str CARG1, [BASE, #-16] + | sub RB, BASE, #8 + | subs RA, NARGS8:RC, #8 + | add RC, NARGS8:RC, #8 // Compute (nresults+1)*8. + | cbz RA, ->fff_res // Done if exactly 1 argument. + |1: + | ldr CARG1, [RB, #16] + | sub RA, RA, #8 + | str CARG1, [RB], #8 + | cbnz RA, <1 + | b ->fff_res + | + |.ffunc_1 type + | mov TMP0, #~LJ_TISNUM + | asr ITYPE, CARG1, #47 + | cmn ITYPE, #~LJ_TISNUM + | csinv TMP1, TMP0, ITYPE, lo + | add TMP1, TMP1, #offsetof(GCfuncC, upvalue)/8 + | ldr CARG1, [CFUNC:CARG3, TMP1, lsl #3] + | b ->fff_restv + | + |//-- Base library: getters and setters --------------------------------- + | + |.ffunc_1 getmetatable + | asr ITYPE, CARG1, #47 + | cmn ITYPE, #-LJ_TTAB + | ccmn ITYPE, #-LJ_TUDATA, #4, ne + | and TAB:CARG1, CARG1, #LJ_GCVMASK + | bne >6 + |1: // Field metatable must be at same offset for GCtab and GCudata! + | ldr TAB:RB, TAB:CARG1->metatable + |2: + | mov CARG1, TISNIL + | ldr STR:RC, GL->gcroot[GCROOT_MMNAME+MM_metatable] + | cbz TAB:RB, ->fff_restv + | ldr TMP1w, TAB:RB->hmask + | ldr TMP2w, STR:RC->sid + | ldr NODE:CARG3, TAB:RB->node + | and TMP1w, TMP1w, TMP2w // idx = str->sid & tab->hmask + | add TMP1, TMP1, TMP1, lsl #1 + | movn CARG4, #~LJ_TSTR + | add NODE:CARG3, NODE:CARG3, TMP1, lsl #3 // node = tab->node + idx*3*8 + | add CARG4, STR:RC, CARG4, lsl #47 // Tagged key to look for. + |3: // Rearranged logic, because we expect _not_ to find the key. + | ldp CARG1, TMP0, NODE:CARG3->val + | ldr NODE:CARG3, NODE:CARG3->next + | cmp TMP0, CARG4 + | beq >5 + | cbnz NODE:CARG3, <3 + |4: + | mov CARG1, RB // Use metatable as default result. + | movk CARG1, #(LJ_TTAB>>1)&0xffff, lsl #48 + | b ->fff_restv + |5: + | cmp TMP0, TISNIL + | bne ->fff_restv + | b <4 + | + |6: + | movn TMP0, #~LJ_TISNUM + | cmp ITYPE, TMP0 + | csel ITYPE, ITYPE, TMP0, hs + | sub TMP1, GL, ITYPE, lsl #3 + | ldr TAB:RB, [TMP1, #offsetof(global_State, gcroot[GCROOT_BASEMT])-8] + | b <2 + | + |.ffunc_2 setmetatable + | // Fast path: no mt for table yet and not clearing the mt. + | checktp TMP1, CARG1, LJ_TTAB, ->fff_fallback + | ldr TAB:TMP0, TAB:TMP1->metatable + | asr ITYPE, CARG2, #47 + | ldrb TMP2w, TAB:TMP1->marked + | cmn ITYPE, #-LJ_TTAB + | and TAB:CARG2, CARG2, #LJ_GCVMASK + | ccmp TAB:TMP0, #0, #0, eq + | bne ->fff_fallback + | str TAB:CARG2, TAB:TMP1->metatable + | tbz TMP2w, #2, ->fff_restv // isblack(table) + | barrierback TAB:TMP1, TMP2w, TMP0 + | b ->fff_restv + | + |.ffunc rawget + | ldr CARG2, [BASE] + | cmp NARGS8:RC, #16 + | blo ->fff_fallback + | checktab CARG2, ->fff_fallback + | mov CARG1, L + | add CARG3, BASE, #8 + | bl extern lj_tab_get // (lua_State *L, GCtab *t, cTValue *key) + | // Returns cTValue *. + | ldr CARG1, [CRET1] + | b ->fff_restv + | + |//-- Base library: conversions ------------------------------------------ + | + |.ffunc tonumber + | // Only handles the number case inline (without a base argument). + | ldr CARG1, [BASE] + | cmp NARGS8:RC, #8 + | bne ->fff_fallback + | checknumber CARG1, ->fff_fallback + | b ->fff_restv + | + |.ffunc_1 tostring + | // Only handles the string or number case inline. + | asr ITYPE, CARG1, #47 + | cmn ITYPE, #-LJ_TSTR + | // A __tostring method in the string base metatable is ignored. + | beq ->fff_restv + | // Handle numbers inline, unless a number base metatable is present. + | ldr TMP1, GL->gcroot[GCROOT_BASEMT_NUM] + | str BASE, L->base + | cmn ITYPE, #-LJ_TISNUM + | ccmp TMP1, #0, #0, ls + | str PC, SAVE_PC // Redundant (but a defined value). + | bne ->fff_fallback + | ffgccheck + | mov CARG1, L + | mov CARG2, BASE + | bl extern lj_strfmt_number // (lua_State *L, cTValue *o) + | // Returns GCstr *. + | movn TMP1, #~LJ_TSTR + | ldr BASE, L->base + | add CARG1, CARG1, TMP1, lsl #47 + | b ->fff_restv + | + |//-- Base library: iterators ------------------------------------------- + | + |.ffunc_1 next + | checktp CARG1, LJ_TTAB, ->fff_fallback + | str TISNIL, [BASE, NARGS8:RC] // Set missing 2nd arg to nil. + | ldr PC, [BASE, FRAME_PC] + | add CARG2, BASE, #8 + | sub CARG3, BASE, #16 + | bl extern lj_tab_next // (GCtab *t, cTValue *key, TValue *o) + | // Returns 1=found, 0=end, -1=error. + | mov RC, #(2+1)*8 + | tbnz CRET1w, #31, ->fff_fallback // Invalid key. + | cbnz CRET1, ->fff_res // Found key/value. + | // End of traversal: return nil. + | str TISNIL, [BASE, #-16] + | b ->fff_res1 + | + |.ffunc_1 pairs + | checktp TMP1, CARG1, LJ_TTAB, ->fff_fallback +#if LJ_52 + | ldr TAB:CARG2, TAB:TMP1->metatable +#endif + | ldr CFUNC:CARG4, CFUNC:CARG3->upvalue[0] + | ldr PC, [BASE, FRAME_PC] +#if LJ_52 + | cbnz TAB:CARG2, ->fff_fallback +#endif + | mov RC, #(3+1)*8 + | stp CARG1, TISNIL, [BASE, #-8] + | str CFUNC:CARG4, [BASE, #-16] + | b ->fff_res + | + |.ffunc_2 ipairs_aux + | checktab CARG1, ->fff_fallback + | checkint CARG2, ->fff_fallback + | ldr TMP1w, TAB:CARG1->asize + | ldr CARG3, TAB:CARG1->array + | ldr TMP0w, TAB:CARG1->hmask + | add CARG2w, CARG2w, #1 + | cmp CARG2w, TMP1w + | ldr PC, [BASE, FRAME_PC] + | add TMP2, CARG2, TISNUM + | mov RC, #(0+1)*8 + | str TMP2, [BASE, #-16] + | bhs >2 // Not in array part? + | ldr TMP0, [CARG3, CARG2, lsl #3] + |1: + | mov TMP1, #(2+1)*8 + | cmp TMP0, TISNIL + | str TMP0, [BASE, #-8] + | csel RC, RC, TMP1, eq + | b ->fff_res + |2: // Check for empty hash part first. Otherwise call C function. + | cbz TMP0w, ->fff_res + | bl extern lj_tab_getinth // (GCtab *t, int32_t key) + | // Returns cTValue * or NULL. + | cbz CRET1, ->fff_res + | ldr TMP0, [CRET1] + | b <1 + | + |.ffunc_1 ipairs + | checktp TMP1, CARG1, LJ_TTAB, ->fff_fallback +#if LJ_52 + | ldr TAB:CARG2, TAB:TMP1->metatable +#endif + | ldr CFUNC:CARG4, CFUNC:CARG3->upvalue[0] + | ldr PC, [BASE, FRAME_PC] +#if LJ_52 + | cbnz TAB:CARG2, ->fff_fallback +#endif + | mov RC, #(3+1)*8 + | stp CARG1, TISNUM, [BASE, #-8] + | str CFUNC:CARG4, [BASE, #-16] + | b ->fff_res + | + |//-- Base library: catch errors ---------------------------------------- + | + |.ffunc pcall + | cmp NARGS8:RC, #8 + | ldrb TMP0w, GL->hookmask + | blo ->fff_fallback + | sub NARGS8:RC, NARGS8:RC, #8 + | mov RB, BASE + | add BASE, BASE, #16 + | ubfx TMP0w, TMP0w, #HOOK_ACTIVE_SHIFT, #1 + | add PC, TMP0, #16+FRAME_PCALL + | beq ->vm_call_dispatch + |1: + | add TMP2, BASE, NARGS8:RC + |2: + | ldr TMP0, [TMP2, #-16] + | str TMP0, [TMP2, #-8]! + | cmp TMP2, BASE + | bne <2 + | b ->vm_call_dispatch + | + |.ffunc xpcall + | ldp CARG1, CARG2, [BASE] + | ldrb TMP0w, GL->hookmask + | subs NARGS8:TMP1, NARGS8:RC, #16 + | blo ->fff_fallback + | mov RB, BASE + | asr ITYPE, CARG2, #47 + | ubfx TMP0w, TMP0w, #HOOK_ACTIVE_SHIFT, #1 + | cmn ITYPE, #-LJ_TFUNC + | add PC, TMP0, #24+FRAME_PCALL + | bne ->fff_fallback // Traceback must be a function. + | mov NARGS8:RC, NARGS8:TMP1 + | add BASE, BASE, #24 + | stp CARG2, CARG1, [RB] // Swap function and traceback. + | cbz NARGS8:RC, ->vm_call_dispatch + | b <1 + | + |//-- Coroutine library -------------------------------------------------- + | + |.macro coroutine_resume_wrap, resume + |.if resume + |.ffunc_1 coroutine_resume + | checktp CARG1, LJ_TTHREAD, ->fff_fallback + |.else + |.ffunc coroutine_wrap_aux + | ldr L:CARG1, CFUNC:CARG3->upvalue[0].gcr + | and L:CARG1, CARG1, #LJ_GCVMASK + |.endif + | ldr PC, [BASE, FRAME_PC] + | str BASE, L->base + | ldp RB, CARG2, L:CARG1->base + | ldrb TMP1w, L:CARG1->status + | add TMP0, CARG2, TMP1 + | str PC, SAVE_PC + | cmp TMP0, RB + | beq ->fff_fallback + | cmp TMP1, #LUA_YIELD + | add TMP0, CARG2, #8 + | csel CARG2, CARG2, TMP0, hs + | ldr CARG4, L:CARG1->maxstack + | add CARG3, CARG2, NARGS8:RC + | ldr RB, L:CARG1->cframe + | ccmp CARG3, CARG4, #2, ls + | ccmp RB, #0, #2, ls + | bhi ->fff_fallback + |.if resume + | sub CARG3, CARG3, #8 // Keep resumed thread in stack for GC. + | add BASE, BASE, #8 + | sub NARGS8:RC, NARGS8:RC, #8 + |.endif + | str CARG3, L:CARG1->top + | str BASE, L->top + | cbz NARGS8:RC, >3 + |2: // Move args to coroutine. + | ldr TMP0, [BASE, RB] + | cmp RB, NARGS8:RC + | str TMP0, [CARG2, RB] + | add RB, RB, #8 + | bne <2 + |3: + | mov CARG3, #0 + | mov L:RA, L:CARG1 + | mov CARG4, #0 + | bl ->vm_resume // (lua_State *L, TValue *base, 0, 0) + | // Returns thread status. + |4: + | ldp CARG3, CARG4, L:RA->base + | cmp CRET1, #LUA_YIELD + | ldr BASE, L->base + | str L, GL->cur_L + | st_vmstate ST_INTERP + | bhi >8 + | sub RC, CARG4, CARG3 + | ldr CARG1, L->maxstack + | add CARG2, BASE, RC + | cbz RC, >6 // No results? + | cmp CARG2, CARG1 + | mov RB, #0 + | bhi >9 // Need to grow stack? + | + | sub CARG4, RC, #8 + | str CARG3, L:RA->top // Clear coroutine stack. + |5: // Move results from coroutine. + | ldr TMP0, [CARG3, RB] + | cmp RB, CARG4 + | str TMP0, [BASE, RB] + | add RB, RB, #8 + | bne <5 + |6: + |.if resume + | mov_true TMP1 + | add RC, RC, #16 + |7: + | str TMP1, [BASE, #-8] // Prepend true/false to results. + | sub RA, BASE, #8 + |.else + | mov RA, BASE + | add RC, RC, #8 + |.endif + | ands CARG1, PC, #FRAME_TYPE + | str PC, SAVE_PC + | str RCw, SAVE_MULTRES + | beq ->BC_RET_Z + | b ->vm_return + | + |8: // Coroutine returned with error (at co->top-1). + |.if resume + | ldr TMP0, [CARG4, #-8]! + | mov_false TMP1 + | mov RC, #(2+1)*8 + | str CARG4, L:RA->top // Remove error from coroutine stack. + | str TMP0, [BASE] // Copy error message. + | b <7 + |.else + | mov CARG1, L + | mov CARG2, L:RA + | bl extern lj_ffh_coroutine_wrap_err // (lua_State *L, lua_State *co) + | // Never returns. + |.endif + | + |9: // Handle stack expansion on return from yield. + | mov CARG1, L + | lsr CARG2, RC, #3 + | bl extern lj_state_growstack // (lua_State *L, int n) + | mov CRET1, #0 + | b <4 + |.endmacro + | + | coroutine_resume_wrap 1 // coroutine.resume + | coroutine_resume_wrap 0 // coroutine.wrap + | + |.ffunc coroutine_yield + | ldr TMP0, L->cframe + | add TMP1, BASE, NARGS8:RC + | mov CRET1, #LUA_YIELD + | stp BASE, TMP1, L->base + | tbz TMP0, #0, ->fff_fallback + | str xzr, L->cframe + | strb CRET1w, L->status + | b ->vm_leave_unw + | + |//-- Math library ------------------------------------------------------- + | + |.macro math_round, func, round + | .ffunc math_ .. func + | ldr CARG1, [BASE] + | cmp NARGS8:RC, #8 + | ldr d0, [BASE] + | blo ->fff_fallback + | cmp TISNUMhi, CARG1, lsr #32 + | beq ->fff_restv + | blo ->fff_fallback + | round d0, d0 + | b ->fff_resn + |.endmacro + | + | math_round floor, frintm + | math_round ceil, frintp + | + |.ffunc_1 math_abs + | checknumber CARG1, ->fff_fallback + | and CARG1, CARG1, #U64x(7fffffff,ffffffff) + | bne ->fff_restv + | eor CARG2w, CARG1w, CARG1w, asr #31 + | movz CARG3, #0x41e0, lsl #48 // 2^31. + | subs CARG1w, CARG2w, CARG1w, asr #31 + | add CARG1, CARG1, TISNUM + | csel CARG1, CARG1, CARG3, pl + | // Fallthrough. + | + |->fff_restv: + | // CARG1 = TValue result. + | ldr PC, [BASE, FRAME_PC] + | str CARG1, [BASE, #-16] + |->fff_res1: + | // PC = return. + | mov RC, #(1+1)*8 + |->fff_res: + | // RC = (nresults+1)*8, PC = return. + | ands CARG1, PC, #FRAME_TYPE + | str RCw, SAVE_MULTRES + | sub RA, BASE, #16 + | bne ->vm_return + | ldr INSw, [PC, #-4] + | decode_RB RB, INS + |5: + | cmp RC, RB, lsl #3 // More results expected? + | blo >6 + | decode_RA TMP1, INS + | // Adjust BASE. KBASE is assumed to be set for the calling frame. + | sub BASE, RA, TMP1, lsl #3 + | ins_next + | + |6: // Fill up results with nil. + | add TMP1, RA, RC + | add RC, RC, #8 + | str TISNIL, [TMP1, #-8] + | b <5 + | + |.macro math_extern, func + | .ffunc_n math_ .. func + | bl extern func + | b ->fff_resn + |.endmacro + | + |.macro math_extern2, func + | .ffunc_nn math_ .. func + | bl extern func + | b ->fff_resn + |.endmacro + | + |.ffunc_n math_sqrt + | fsqrt d0, d0 + |->fff_resn: + | ldr PC, [BASE, FRAME_PC] + | str d0, [BASE, #-16] + | b ->fff_res1 + | + |.ffunc math_log + | ldr CARG1, [BASE] + | cmp NARGS8:RC, #8 + | ldr FARG1, [BASE] + | bne ->fff_fallback // Need exactly 1 argument. + | checknum CARG1, ->fff_fallback + | bl extern log + | b ->fff_resn + | + | math_extern log10 + | math_extern exp + | math_extern sin + | math_extern cos + | math_extern tan + | math_extern asin + | math_extern acos + | math_extern atan + | math_extern sinh + | math_extern cosh + | math_extern tanh + | math_extern2 pow + | math_extern2 atan2 + | math_extern2 fmod + | + |.ffunc_2 math_ldexp + | ldr FARG1, [BASE] + | checknum CARG1, ->fff_fallback + | checkint CARG2, ->fff_fallback + | sxtw CARG1, CARG2w + | bl extern ldexp // (double x, int exp) + | b ->fff_resn + | + |.ffunc_n math_frexp + | add CARG1, sp, TMPDofs + | bl extern frexp + | ldr CARG2w, TMPD + | ldr PC, [BASE, FRAME_PC] + | str d0, [BASE, #-16] + | mov RC, #(2+1)*8 + | add CARG2, CARG2, TISNUM + | str CARG2, [BASE, #-8] + | b ->fff_res + | + |.ffunc_n math_modf + | sub CARG1, BASE, #16 + | ldr PC, [BASE, FRAME_PC] + | bl extern modf + | mov RC, #(2+1)*8 + | str d0, [BASE, #-8] + | b ->fff_res + | + |.macro math_minmax, name, cond, fcond + | .ffunc_1 name + | add RB, BASE, RC + | add RA, BASE, #8 + | checkint CARG1, >4 + |1: // Handle integers. + | ldr CARG2, [RA] + | cmp RA, RB + | bhs ->fff_restv + | checkint CARG2, >3 + | cmp CARG1w, CARG2w + | add RA, RA, #8 + | csel CARG1, CARG2, CARG1, cond + | b <1 + |3: // Convert intermediate result to number and continue below. + | scvtf d0, CARG1w + | blo ->fff_fallback + | ldr d1, [RA] + | b >6 + | + |4: + | ldr d0, [BASE] + | blo ->fff_fallback + |5: // Handle numbers. + | ldr CARG2, [RA] + | ldr d1, [RA] + | cmp RA, RB + | bhs ->fff_resn + | checknum CARG2, >7 + |6: + | fcmp d0, d1 + | add RA, RA, #8 + | fcsel d0, d1, d0, fcond + | b <5 + |7: // Convert integer to number and continue above. + | scvtf d1, CARG2w + | blo ->fff_fallback + | b <6 + |.endmacro + | + | math_minmax math_min, gt, pl + | math_minmax math_max, lt, le + | + |//-- String library ----------------------------------------------------- + | + |.ffunc string_byte // Only handle the 1-arg case here. + | ldp PC, CARG1, [BASE, FRAME_PC] + | cmp NARGS8:RC, #8 + | asr ITYPE, CARG1, #47 + | ccmn ITYPE, #-LJ_TSTR, #0, eq + | and STR:CARG1, CARG1, #LJ_GCVMASK + | bne ->fff_fallback + | ldrb TMP0w, STR:CARG1[1] // Access is always ok (NUL at end). + | ldr CARG3w, STR:CARG1->len + | add TMP0, TMP0, TISNUM + | str TMP0, [BASE, #-16] + | mov RC, #(0+1)*8 + | cbz CARG3, ->fff_res + | b ->fff_res1 + | + |.ffunc string_char // Only handle the 1-arg case here. + | ffgccheck + | ldp PC, CARG1, [BASE, FRAME_PC] + | cmp CARG1w, #255 + | ccmp NARGS8:RC, #8, #0, ls // Need exactly 1 argument. + | bne ->fff_fallback + | checkint CARG1, ->fff_fallback + | mov CARG3, #1 + | // Point to the char inside the integer in the stack slot. + |.if ENDIAN_LE + | mov CARG2, BASE + |.else + | add CARG2, BASE, #7 + |.endif + |->fff_newstr: + | // CARG2 = str, CARG3 = len. + | str BASE, L->base + | mov CARG1, L + | str PC, SAVE_PC + | bl extern lj_str_new // (lua_State *L, char *str, size_t l) + |->fff_resstr: + | // Returns GCstr *. + | ldr BASE, L->base + | movn TMP1, #~LJ_TSTR + | add CARG1, CARG1, TMP1, lsl #47 + | b ->fff_restv + | + |.ffunc string_sub + | ffgccheck + | ldr CARG1, [BASE] + | ldr CARG3, [BASE, #16] + | cmp NARGS8:RC, #16 + | movn RB, #0 + | beq >1 + | blo ->fff_fallback + | checkint CARG3, ->fff_fallback + | sxtw RB, CARG3w + |1: + | ldr CARG2, [BASE, #8] + | checkstr CARG1, ->fff_fallback + | ldr TMP1w, STR:CARG1->len + | checkint CARG2, ->fff_fallback + | sxtw CARG2, CARG2w + | // CARG1 = str, TMP1 = str->len, CARG2 = start, RB = end + | add TMP2, RB, TMP1 + | cmp RB, #0 + | add TMP0, CARG2, TMP1 + | csinc RB, RB, TMP2, ge // if (end < 0) end += len+1 + | cmp CARG2, #0 + | csinc CARG2, CARG2, TMP0, ge // if (start < 0) start += len+1 + | cmp RB, #0 + | csel RB, RB, xzr, ge // if (end < 0) end = 0 + | cmp CARG2, #1 + | csinc CARG2, CARG2, xzr, ge // if (start < 1) start = 1 + | cmp RB, TMP1 + | csel RB, RB, TMP1, le // if (end > len) end = len + | add CARG1, STR:CARG1, #sizeof(GCstr)-1 + | subs CARG3, RB, CARG2 // len = end - start + | add CARG2, CARG1, CARG2 + | add CARG3, CARG3, #1 // len += 1 + | bge ->fff_newstr + | add STR:CARG1, GL, #offsetof(global_State, strempty) + | movn TMP1, #~LJ_TSTR + | add CARG1, CARG1, TMP1, lsl #47 + | b ->fff_restv + | + |.macro ffstring_op, name + | .ffunc string_ .. name + | ffgccheck + | ldr CARG2, [BASE] + | cmp NARGS8:RC, #8 + | asr ITYPE, CARG2, #47 + | ccmn ITYPE, #-LJ_TSTR, #0, hs + | and STR:CARG2, CARG2, #LJ_GCVMASK + | bne ->fff_fallback + | ldr TMP0, GL->tmpbuf.b + | add SBUF:CARG1, GL, #offsetof(global_State, tmpbuf) + | str BASE, L->base + | str PC, SAVE_PC + | str L, GL->tmpbuf.L + | str TMP0, GL->tmpbuf.w + | bl extern lj_buf_putstr_ .. name + | bl extern lj_buf_tostr + | b ->fff_resstr + |.endmacro + | + |ffstring_op reverse + |ffstring_op lower + |ffstring_op upper + | + |//-- Bit library -------------------------------------------------------- + | + |// FP number to bit conversion for soft-float. Clobbers CARG1-CARG3 + |->vm_tobit_fb: + | bls ->fff_fallback + | add CARG2, CARG1, CARG1 + | mov CARG3, #1076 + | sub CARG3, CARG3, CARG2, lsr #53 + | cmp CARG3, #53 + | bhi >1 + | and CARG2, CARG2, #U64x(001fffff,ffffffff) + | orr CARG2, CARG2, #U64x(00200000,00000000) + | cmp CARG1, #0 + | lsr CARG2, CARG2, CARG3 + | cneg CARG1w, CARG2w, mi + | br lr + |1: + | mov CARG1w, #0 + | br lr + | + |.macro .ffunc_bit, name + | .ffunc_1 bit_..name + | adr lr, >1 + | checkint CARG1, ->vm_tobit_fb + |1: + |.endmacro + | + |.macro .ffunc_bit_op, name, ins + | .ffunc_bit name + | mov RA, #8 + | mov TMP0w, CARG1w + | adr lr, >2 + |1: + | ldr CARG1, [BASE, RA] + | cmp RA, NARGS8:RC + | add RA, RA, #8 + | bge >9 + | checkint CARG1, ->vm_tobit_fb + |2: + | ins TMP0w, TMP0w, CARG1w + | b <1 + |.endmacro + | + |.ffunc_bit_op band, and + |.ffunc_bit_op bor, orr + |.ffunc_bit_op bxor, eor + | + |.ffunc_bit tobit + | mov TMP0w, CARG1w + |9: // Label reused by .ffunc_bit_op users. + | add CARG1, TMP0, TISNUM + | b ->fff_restv + | + |.ffunc_bit bswap + | rev TMP0w, CARG1w + | add CARG1, TMP0, TISNUM + | b ->fff_restv + | + |.ffunc_bit bnot + | mvn TMP0w, CARG1w + | add CARG1, TMP0, TISNUM + | b ->fff_restv + | + |.macro .ffunc_bit_sh, name, ins, shmod + | .ffunc bit_..name + | ldp TMP0, CARG1, [BASE] + | cmp NARGS8:RC, #16 + | blo ->fff_fallback + | adr lr, >1 + | checkint CARG1, ->vm_tobit_fb + |1: + |.if shmod == 0 + | mov TMP1, CARG1 + |.else + | neg TMP1, CARG1 + |.endif + | mov CARG1, TMP0 + | adr lr, >2 + | checkint CARG1, ->vm_tobit_fb + |2: + | ins TMP0w, CARG1w, TMP1w + | add CARG1, TMP0, TISNUM + | b ->fff_restv + |.endmacro + | + |.ffunc_bit_sh lshift, lsl, 0 + |.ffunc_bit_sh rshift, lsr, 0 + |.ffunc_bit_sh arshift, asr, 0 + |.ffunc_bit_sh rol, ror, 1 + |.ffunc_bit_sh ror, ror, 0 + | + |//----------------------------------------------------------------------- + | + |->fff_fallback: // Call fast function fallback handler. + | // BASE = new base, RC = nargs*8 + | ldp CFUNC:CARG3, PC, [BASE, FRAME_FUNC] // Fallback may overwrite PC. + | ldr TMP2, L->maxstack + | add TMP1, BASE, NARGS8:RC + | stp BASE, TMP1, L->base + | and CFUNC:CARG3, CARG3, #LJ_GCVMASK + | add TMP1, TMP1, #8*LUA_MINSTACK + | ldr CARG3, CFUNC:CARG3->f + | str PC, SAVE_PC // Redundant (but a defined value). + | cmp TMP1, TMP2 + | mov CARG1, L + | bhi >5 // Need to grow stack. + | blr CARG3 // (lua_State *L) + | // Either throws an error, or recovers and returns -1, 0 or nresults+1. + | ldr BASE, L->base + | cmp CRET1w, #0 + | lsl RC, CRET1, #3 + | sub RA, BASE, #16 + | bgt ->fff_res // Returned nresults+1? + |1: // Returned 0 or -1: retry fast path. + | ldr CARG1, L->top + | ldr CFUNC:CARG3, [BASE, FRAME_FUNC] + | sub NARGS8:RC, CARG1, BASE + | bne ->vm_call_tail // Returned -1? + | and CFUNC:CARG3, CARG3, #LJ_GCVMASK + | ins_callt // Returned 0: retry fast path. + | + |// Reconstruct previous base for vmeta_call during tailcall. + |->vm_call_tail: + | ands TMP0, PC, #FRAME_TYPE + | and TMP1, PC, #~FRAME_TYPEP + | bne >3 + | ldrb RAw, [PC, #-4+OFS_RA] + | lsl RA, RA, #3 + | add TMP1, RA, #16 + |3: + | sub RB, BASE, TMP1 + | b ->vm_call_dispatch // Resolve again for tailcall. + | + |5: // Grow stack for fallback handler. + | mov CARG2, #LUA_MINSTACK + | bl extern lj_state_growstack // (lua_State *L, int n) + | ldr BASE, L->base + | cmp CARG1, CARG1 // Set zero-flag to force retry. + | b <1 + | + |->fff_gcstep: // Call GC step function. + | // BASE = new base, RC = nargs*8 + | add CARG2, BASE, NARGS8:RC // Calculate L->top. + | mov RA, lr + | stp BASE, CARG2, L->base + | str PC, SAVE_PC // Redundant (but a defined value). + | mov CARG1, L + | bl extern lj_gc_step // (lua_State *L) + | ldp BASE, CARG2, L->base + | ldr CFUNC:CARG3, [BASE, FRAME_FUNC] + | mov lr, RA // Help return address predictor. + | sub NARGS8:RC, CARG2, BASE // Calculate nargs*8. + | and CFUNC:CARG3, CARG3, #LJ_GCVMASK + | ret + | + |//----------------------------------------------------------------------- + |//-- Special dispatch targets ------------------------------------------- + |//----------------------------------------------------------------------- + | + |->vm_record: // Dispatch target for recording phase. + |.if JIT + | ldrb CARG1w, GL->hookmask + | tst CARG1, #HOOK_VMEVENT // No recording while in vmevent. + | bne >5 + | // Decrement the hookcount for consistency, but always do the call. + | ldr CARG2w, GL->hookcount + | tst CARG1, #HOOK_ACTIVE + | bne >1 + | sub CARG2w, CARG2w, #1 + | tst CARG1, #LUA_MASKLINE|LUA_MASKCOUNT + | beq >1 + | str CARG2w, GL->hookcount + | b >1 + |.endif + | + |->vm_rethook: // Dispatch target for return hooks. + | ldrb TMP2w, GL->hookmask + | tbz TMP2w, #HOOK_ACTIVE_SHIFT, >1 // Hook already active? + |5: // Re-dispatch to static ins. + | ldr TMP0, [TMP1, #GG_G2DISP+GG_DISP2STATIC] + | br TMP0 + | + |->vm_inshook: // Dispatch target for instr/line hooks. + | ldrb TMP2w, GL->hookmask + | ldr TMP3w, GL->hookcount + | tbnz TMP2w, #HOOK_ACTIVE_SHIFT, <5 // Hook already active? + | tst TMP2w, #LUA_MASKLINE|LUA_MASKCOUNT + | beq <5 + | sub TMP3w, TMP3w, #1 + | str TMP3w, GL->hookcount + | cbz TMP3w, >1 + | tbz TMP2w, #LUA_HOOKLINE, <5 + |1: + | mov CARG1, L + | str BASE, L->base + | mov CARG2, PC + | // SAVE_PC must hold the _previous_ PC. The callee updates it with PC. + | bl extern lj_dispatch_ins // (lua_State *L, const BCIns *pc) + |3: + | ldr BASE, L->base + |4: // Re-dispatch to static ins. + | ldr INSw, [PC, #-4] + | add TMP1, GL, INS, uxtb #3 + | decode_RA RA, INS + | ldr TMP0, [TMP1, #GG_G2DISP+GG_DISP2STATIC] + | decode_RD RC, INS + | br TMP0 + | + |->cont_hook: // Continue from hook yield. + | ldr CARG1, [CARG4, #-40] + | add PC, PC, #4 + | str CARG1w, SAVE_MULTRES // Restore MULTRES for *M ins. + | b <4 + | + |->vm_hotloop: // Hot loop counter underflow. + |.if JIT + | ldr LFUNC:CARG3, [BASE, FRAME_FUNC] // Same as curr_topL(L). + | add CARG1, GL, #GG_G2DISP+GG_DISP2J + | and LFUNC:CARG3, CARG3, #LJ_GCVMASK + | str PC, SAVE_PC + | ldr CARG3, LFUNC:CARG3->pc + | mov CARG2, PC + | str L, [GL, #GL_J(L)] + | ldrb CARG3w, [CARG3, #PC2PROTO(framesize)] + | str BASE, L->base + | add CARG3, BASE, CARG3, lsl #3 + | str CARG3, L->top + | bl extern lj_trace_hot // (jit_State *J, const BCIns *pc) + | b <3 + |.endif + | + |->vm_callhook: // Dispatch target for call hooks. + | mov CARG2, PC + |.if JIT + | b >1 + |.endif + | + |->vm_hotcall: // Hot call counter underflow. + |.if JIT + | orr CARG2, PC, #1 + |1: + |.endif + | add TMP1, BASE, NARGS8:RC + | str PC, SAVE_PC + | mov CARG1, L + | sub RA, RA, BASE + | stp BASE, TMP1, L->base + | bl extern lj_dispatch_call // (lua_State *L, const BCIns *pc) + | // Returns ASMFunction. + | ldp BASE, TMP1, L->base + | str xzr, SAVE_PC // Invalidate for subsequent line hook. + | ldr LFUNC:CARG3, [BASE, FRAME_FUNC] + | add RA, BASE, RA + | sub NARGS8:RC, TMP1, BASE + | ldr INSw, [PC, #-4] + | and LFUNC:CARG3, CARG3, #LJ_GCVMASK + | br CRET1 + | + |->cont_stitch: // Trace stitching. + |.if JIT + | // RA = resultptr, CARG4 = meta base + | ldr RBw, SAVE_MULTRES + | ldr INSw, [PC, #-4] + | ldr TRACE:CARG3, [CARG4, #-40] // Save previous trace. + | subs RB, RB, #8 + | decode_RA RC, INS // Call base. + | and CARG3, CARG3, #LJ_GCVMASK + | beq >2 + |1: // Move results down. + | ldr CARG1, [RA] + | add RA, RA, #8 + | subs RB, RB, #8 + | str CARG1, [BASE, RC, lsl #3] + | add RC, RC, #1 + | bne <1 + |2: + | decode_RA RA, INS + | decode_RB RB, INS + | add RA, RA, RB + |3: + | cmp RA, RC + | bhi >9 // More results wanted? + | + | ldrh RAw, TRACE:CARG3->traceno + | ldrh RCw, TRACE:CARG3->link + | cmp RCw, RAw + | beq ->cont_nop // Blacklisted. + | cmp RCw, #0 + | bne =>BC_JLOOP // Jump to stitched trace. + | + | // Stitch a new trace to the previous trace. + | mov CARG1, #GL_J(exitno) + | str RAw, [GL, CARG1] + | mov CARG1, #GL_J(L) + | str L, [GL, CARG1] + | str BASE, L->base + | add CARG1, GL, #GG_G2J + | mov CARG2, PC + | bl extern lj_dispatch_stitch // (jit_State *J, const BCIns *pc) + | ldr BASE, L->base + | b ->cont_nop + | + |9: // Fill up results with nil. + | str TISNIL, [BASE, RC, lsl #3] + | add RC, RC, #1 + | b <3 + |.endif + | + |->vm_profhook: // Dispatch target for profiler hook. +#if LJ_HASPROFILE + | mov CARG1, L + | str BASE, L->base + | mov CARG2, PC + | bl extern lj_dispatch_profile // (lua_State *L, const BCIns *pc) + | // HOOK_PROFILE is off again, so re-dispatch to dynamic instruction. + | ldr BASE, L->base + | sub PC, PC, #4 + | b ->cont_nop +#endif + | + |//----------------------------------------------------------------------- + |//-- Trace exit handler ------------------------------------------------- + |//----------------------------------------------------------------------- + | + |.macro savex_, a, b + | stp d..a, d..b, [sp, #a*8] + | stp x..a, x..b, [sp, #32*8+a*8] + |.endmacro + | + |->vm_exit_handler: + |.if JIT + | sub sp, sp, #(64*8) + | savex_, 0, 1 + | savex_, 2, 3 + | savex_, 4, 5 + | savex_, 6, 7 + | savex_, 8, 9 + | savex_, 10, 11 + | savex_, 12, 13 + | savex_, 14, 15 + | savex_, 16, 17 + | savex_, 18, 19 + | savex_, 20, 21 + | savex_, 22, 23 + | savex_, 24, 25 + | savex_, 26, 27 + | savex_, 28, 29 + | stp d30, d31, [sp, #30*8] + | ldr CARG1, [sp, #64*8] // Load original value of lr. + | add CARG3, sp, #64*8 // Recompute original value of sp. + | mv_vmstate CARG4w, EXIT + | stp xzr, CARG3, [sp, #62*8] // Store 0/sp in RID_LR/RID_SP. + | sub CARG1, CARG1, lr + | ldr L, GL->cur_L + | lsr CARG1, CARG1, #2 + | ldr BASE, GL->jit_base + | sub CARG1, CARG1, #2 + | ldr CARG2w, [lr] // Load trace number. + | st_vmstate CARG4w + |.if ENDIAN_BE + | rev32 CARG2, CARG2 + |.endif + | str BASE, L->base + | ubfx CARG2w, CARG2w, #5, #16 + | str CARG1w, [GL, #GL_J(exitno)] + | str CARG2w, [GL, #GL_J(parent)] + | str L, [GL, #GL_J(L)] + | str xzr, GL->jit_base + | add CARG1, GL, #GG_G2J + | mov CARG2, sp + | bl extern lj_trace_exit // (jit_State *J, ExitState *ex) + | // Returns MULTRES (unscaled) or negated error code. + | ldr CARG2, L->cframe + | ldr BASE, L->base + | and sp, CARG2, #CFRAME_RAWMASK + | ldr PC, SAVE_PC // Get SAVE_PC. + | str L, SAVE_L // Set SAVE_L (on-trace resume/yield). + | b >1 + |.endif + | + |->vm_exit_interp: + | // CARG1 = MULTRES or negated error code, BASE, PC and GL set. + |.if JIT + | ldr L, SAVE_L + |1: + | cmp CARG1w, #0 + | blt >9 // Check for error from exit. + | lsl RC, CARG1, #3 + | ldr LFUNC:CARG2, [BASE, FRAME_FUNC] + | movz TISNUM, #(LJ_TISNUM>>1)&0xffff, lsl #48 + | movz TISNUMhi, #(LJ_TISNUM>>1)&0xffff, lsl #16 + | movn TISNIL, #0 + | and LFUNC:CARG2, CARG2, #LJ_GCVMASK + | str RCw, SAVE_MULTRES + | str BASE, L->base + | ldr CARG2, LFUNC:CARG2->pc + | str xzr, GL->jit_base + | mv_vmstate CARG4w, INTERP + | ldr KBASE, [CARG2, #PC2PROTO(k)] + | // Modified copy of ins_next which handles function header dispatch, too. + | ldrb RBw, [PC, # OFS_OP] + | ldr INSw, [PC], #4 + | st_vmstate CARG4w + | cmp RBw, #BC_FUNCC+2 // Fast function? + | add TMP1, GL, INS, uxtb #3 + | bhs >4 + |2: + | cmp RBw, #BC_FUNCF // Function header? + | add TMP0, GL, RB, uxtb #3 + | ldr RB, [TMP0, #GG_G2DISP] + | decode_RA RA, INS + | lsr TMP0, INS, #16 + | csel RC, TMP0, RC, lo + | blo >5 + | ldr CARG3, [BASE, FRAME_FUNC] + | sub RC, RC, #8 + | add RA, BASE, RA, lsl #3 // Yes: RA = BASE+framesize*8, RC = nargs*8 + | and LFUNC:CARG3, CARG3, #LJ_GCVMASK + |5: + | br RB + | + |4: // Check frame below fast function. + | ldr CARG1, [BASE, FRAME_PC] + | ands CARG2, CARG1, #FRAME_TYPE + | bne <2 // Trace stitching continuation? + | // Otherwise set KBASE for Lua function below fast function. + | ldr CARG3w, [CARG1, #-4] + | decode_RA CARG1, CARG3 + | sub CARG2, BASE, CARG1, lsl #3 + | ldr LFUNC:CARG3, [CARG2, #-32] + | and LFUNC:CARG3, CARG3, #LJ_GCVMASK + | ldr CARG3, LFUNC:CARG3->pc + | ldr KBASE, [CARG3, #PC2PROTO(k)] + | b <2 + | + |9: // Rethrow error from the right C frame. + | neg CARG2w, CARG1w + | mov CARG1, L + | bl extern lj_err_trace // (lua_State *L, int errcode) + |.endif + | + |//----------------------------------------------------------------------- + |//-- Math helper functions ---------------------------------------------- + |//----------------------------------------------------------------------- + | + | // int lj_vm_modi(int dividend, int divisor); + |->vm_modi: + | eor CARG4w, CARG1w, CARG2w + | cmp CARG4w, #0 + | eor CARG3w, CARG1w, CARG1w, asr #31 + | eor CARG4w, CARG2w, CARG2w, asr #31 + | sub CARG3w, CARG3w, CARG1w, asr #31 + | sub CARG4w, CARG4w, CARG2w, asr #31 + | udiv CARG1w, CARG3w, CARG4w + | msub CARG1w, CARG1w, CARG4w, CARG3w + | ccmp CARG1w, #0, #4, mi + | sub CARG3w, CARG1w, CARG4w + | csel CARG1w, CARG1w, CARG3w, eq + | eor CARG3w, CARG1w, CARG2w + | cmp CARG3w, #0 + | cneg CARG1w, CARG1w, mi + | ret + | + |//----------------------------------------------------------------------- + |//-- Miscellaneous functions -------------------------------------------- + |//----------------------------------------------------------------------- + | + |.define NEXT_TAB, TAB:CARG1 + |.define NEXT_RES, CARG1 + |.define NEXT_IDX, CARG2w + |.define NEXT_LIM, CARG3w + |.define NEXT_TMP0, TMP0 + |.define NEXT_TMP0w, TMP0w + |.define NEXT_TMP1, TMP1 + |.define NEXT_TMP1w, TMP1w + |.define NEXT_RES_PTR, sp + |.define NEXT_RES_VAL, [sp] + |.define NEXT_RES_KEY, [sp, #8] + | + |// TValue *lj_vm_next(GCtab *t, uint32_t idx) + |// Next idx returned in CRET2w. + |->vm_next: + |.if JIT + | ldr NEXT_LIM, NEXT_TAB->asize + | ldr NEXT_TMP1, NEXT_TAB->array + |1: // Traverse array part. + | subs NEXT_TMP0w, NEXT_IDX, NEXT_LIM + | bhs >5 // Index points after array part? + | ldr NEXT_TMP0, [NEXT_TMP1, NEXT_IDX, uxtw #3] + | cmn NEXT_TMP0, #-LJ_TNIL + | cinc NEXT_IDX, NEXT_IDX, eq + | beq <1 // Skip holes in array part. + | str NEXT_TMP0, NEXT_RES_VAL + | movz NEXT_TMP0w, #(LJ_TISNUM>>1)&0xffff, lsl #16 + | stp NEXT_IDX, NEXT_TMP0w, NEXT_RES_KEY + | add NEXT_IDX, NEXT_IDX, #1 + | mov NEXT_RES, NEXT_RES_PTR + |4: + | ret + | + |5: // Traverse hash part. + | ldr NEXT_TMP1w, NEXT_TAB->hmask + | ldr NODE:NEXT_RES, NEXT_TAB->node + | add NEXT_TMP0w, NEXT_TMP0w, NEXT_TMP0w, lsl #1 + | add NEXT_LIM, NEXT_LIM, NEXT_TMP1w + | add NODE:NEXT_RES, NODE:NEXT_RES, NEXT_TMP0w, uxtw #3 + |6: + | cmp NEXT_IDX, NEXT_LIM + | bhi >9 + | ldr NEXT_TMP0, NODE:NEXT_RES->val + | cmn NEXT_TMP0, #-LJ_TNIL + | add NEXT_IDX, NEXT_IDX, #1 + | bne <4 + | // Skip holes in hash part. + | add NODE:NEXT_RES, NODE:NEXT_RES, #sizeof(Node) + | b <6 + | + |9: // End of iteration. Set the key to nil (not the value). + | movn NEXT_TMP0, #0 + | str NEXT_TMP0, NEXT_RES_KEY + | mov NEXT_RES, NEXT_RES_PTR + | ret + |.endif + | + |//----------------------------------------------------------------------- + |//-- FFI helper functions ----------------------------------------------- + |//----------------------------------------------------------------------- + | + |// Handler for callback functions. + |// Saveregs already performed. Callback slot number in [sp], g in r12. + |->vm_ffi_callback: + |.if FFI + |.type CTSTATE, CTState, PC + | saveregs + | ldr CTSTATE, GL:x10->ctype_state + | mov GL, x10 + | add x10, sp, # CFRAME_SPACE + | str w9, CTSTATE->cb.slot + | stp x0, x1, CTSTATE->cb.gpr[0] + | stp d0, d1, CTSTATE->cb.fpr[0] + | stp x2, x3, CTSTATE->cb.gpr[2] + | stp d2, d3, CTSTATE->cb.fpr[2] + | stp x4, x5, CTSTATE->cb.gpr[4] + | stp d4, d5, CTSTATE->cb.fpr[4] + | stp x6, x7, CTSTATE->cb.gpr[6] + | stp d6, d7, CTSTATE->cb.fpr[6] + | str x10, CTSTATE->cb.stack + | mov CARG1, CTSTATE + | str CTSTATE, SAVE_PC // Any value outside of bytecode is ok. + | mov CARG2, sp + | bl extern lj_ccallback_enter // (CTState *cts, void *cf) + | // Returns lua_State *. + | ldp BASE, RC, L:CRET1->base + | movz TISNUM, #(LJ_TISNUM>>1)&0xffff, lsl #48 + | movz TISNUMhi, #(LJ_TISNUM>>1)&0xffff, lsl #16 + | movn TISNIL, #0 + | mov L, CRET1 + | ldr LFUNC:CARG3, [BASE, FRAME_FUNC] + | sub RC, RC, BASE + | st_vmstate ST_INTERP + | and LFUNC:CARG3, CARG3, #LJ_GCVMASK + | ins_callt + |.endif + | + |->cont_ffi_callback: // Return from FFI callback. + |.if FFI + | ldr CTSTATE, GL->ctype_state + | stp BASE, CARG4, L->base + | str L, CTSTATE->L + | mov CARG1, CTSTATE + | mov CARG2, RA + | bl extern lj_ccallback_leave // (CTState *cts, TValue *o) + | ldp x0, x1, CTSTATE->cb.gpr[0] + | ldp d0, d1, CTSTATE->cb.fpr[0] + | b ->vm_leave_unw + |.endif + | + |->vm_ffi_call: // Call C function via FFI. + | // Caveat: needs special frame unwinding, see below. + |.if FFI + | .type CCSTATE, CCallState, x19 + | stp x20, CCSTATE, [sp, #-32]! + | stp fp, lr, [sp, #16] + | add fp, sp, #16 + | mov CCSTATE, x0 + | ldr TMP0w, CCSTATE:x0->spadj + | ldrb TMP1w, CCSTATE->nsp + | add TMP2, CCSTATE, #offsetof(CCallState, stack) + | subs TMP1, TMP1, #1 + | ldr TMP3, CCSTATE->func + | sub sp, sp, TMP0 + | bmi >2 + |1: // Copy stack slots + | ldr TMP0, [TMP2, TMP1, lsl #3] + | str TMP0, [sp, TMP1, lsl #3] + | subs TMP1, TMP1, #1 + | bpl <1 + |2: + | ldp x0, x1, CCSTATE->gpr[0] + | ldp d0, d1, CCSTATE->fpr[0] + | ldp x2, x3, CCSTATE->gpr[2] + | ldp d2, d3, CCSTATE->fpr[2] + | ldp x4, x5, CCSTATE->gpr[4] + | ldp d4, d5, CCSTATE->fpr[4] + | ldp x6, x7, CCSTATE->gpr[6] + | ldp d6, d7, CCSTATE->fpr[6] + | ldr x8, CCSTATE->retp + | blr TMP3 + | sub sp, fp, #16 + | stp x0, x1, CCSTATE->gpr[0] + | stp d0, d1, CCSTATE->fpr[0] + | stp d2, d3, CCSTATE->fpr[2] + | ldp fp, lr, [sp, #16] + | ldp x20, CCSTATE, [sp], #32 + | ret + |.endif + |// Note: vm_ffi_call must be the last function in this object file! + | + |//----------------------------------------------------------------------- +} + +/* Generate the code for a single instruction. */ +static void build_ins(BuildCtx *ctx, BCOp op, int defop) +{ + int vk = 0; + |=>defop: + + switch (op) { + + /* -- Comparison ops ---------------------------------------------------- */ + + /* Remember: all ops branch for a true comparison, fall through otherwise. */ + + case BC_ISLT: case BC_ISGE: case BC_ISLE: case BC_ISGT: + | // RA = src1, RC = src2, JMP with RC = target + | ldr CARG1, [BASE, RA, lsl #3] + | ldrh RBw, [PC, # OFS_RD] + | ldr CARG2, [BASE, RC, lsl #3] + | add PC, PC, #4 + | add RB, PC, RB, lsl #2 + | sub RB, RB, #0x20000 + | checkint CARG1, >3 + | checkint CARG2, >4 + | cmp CARG1w, CARG2w + if (op == BC_ISLT) { + | csel PC, RB, PC, lt + } else if (op == BC_ISGE) { + | csel PC, RB, PC, ge + } else if (op == BC_ISLE) { + | csel PC, RB, PC, le + } else { + | csel PC, RB, PC, gt + } + |1: + | ins_next + | + |3: // RA not int. + | ldr FARG1, [BASE, RA, lsl #3] + | blo ->vmeta_comp + | ldr FARG2, [BASE, RC, lsl #3] + | cmp TISNUMhi, CARG2, lsr #32 + | bhi >5 + | bne ->vmeta_comp + | // RA number, RC int. + | scvtf FARG2, CARG2w + | b >5 + | + |4: // RA int, RC not int + | ldr FARG2, [BASE, RC, lsl #3] + | blo ->vmeta_comp + | // RA int, RC number. + | scvtf FARG1, CARG1w + | + |5: // RA number, RC number + | fcmp FARG1, FARG2 + | // To preserve NaN semantics GE/GT branch on unordered, but LT/LE don't. + if (op == BC_ISLT) { + | csel PC, RB, PC, lo + } else if (op == BC_ISGE) { + | csel PC, RB, PC, hs + } else if (op == BC_ISLE) { + | csel PC, RB, PC, ls + } else { + | csel PC, RB, PC, hi + } + | b <1 + break; + + case BC_ISEQV: case BC_ISNEV: + vk = op == BC_ISEQV; + | // RA = src1, RC = src2, JMP with RC = target + | ldr CARG1, [BASE, RA, lsl #3] + | add RC, BASE, RC, lsl #3 + | ldrh RBw, [PC, # OFS_RD] + | ldr CARG3, [RC] + | add PC, PC, #4 + | add RB, PC, RB, lsl #2 + | sub RB, RB, #0x20000 + | asr ITYPE, CARG3, #47 + | cmn ITYPE, #-LJ_TISNUM + if (vk) { + | bls ->BC_ISEQN_Z + } else { + | bls ->BC_ISNEN_Z + } + | // RC is not a number. + | asr TMP0, CARG1, #47 + |.if FFI + | // Check if RC or RA is a cdata. + | cmn ITYPE, #-LJ_TCDATA + | ccmn TMP0, #-LJ_TCDATA, #4, ne + | beq ->vmeta_equal_cd + |.endif + | cmp CARG1, CARG3 + | bne >2 + | // Tag and value are equal. + if (vk) { + |->BC_ISEQV_Z: + | mov PC, RB // Perform branch. + } + |1: + | ins_next + | + |2: // Check if the tags are the same and it's a table or userdata. + | cmp ITYPE, TMP0 + | ccmn ITYPE, #-LJ_TISTABUD, #2, eq + if (vk) { + | bhi <1 + } else { + | bhi ->BC_ISEQV_Z // Reuse code from opposite instruction. + } + | // Different tables or userdatas. Need to check __eq metamethod. + | // Field metatable must be at same offset for GCtab and GCudata! + | and TAB:CARG2, CARG1, #LJ_GCVMASK + | ldr TAB:TMP2, TAB:CARG2->metatable + if (vk) { + | cbz TAB:TMP2, <1 // No metatable? + | ldrb TMP1w, TAB:TMP2->nomm + | mov CARG4, #0 // ne = 0 + | tbnz TMP1w, #MM_eq, <1 // 'no __eq' flag set: done. + } else { + | cbz TAB:TMP2, ->BC_ISEQV_Z // No metatable? + | ldrb TMP1w, TAB:TMP2->nomm + | mov CARG4, #1 // ne = 1. + | tbnz TMP1w, #MM_eq, ->BC_ISEQV_Z // 'no __eq' flag set: done. + } + | b ->vmeta_equal + break; + + case BC_ISEQS: case BC_ISNES: + vk = op == BC_ISEQS; + | // RA = src, RC = str_const (~), JMP with RC = target + | ldr CARG1, [BASE, RA, lsl #3] + | mvn RC, RC + | ldrh RBw, [PC, # OFS_RD] + | ldr CARG2, [KBASE, RC, lsl #3] + | add PC, PC, #4 + | movn TMP0, #~LJ_TSTR + |.if FFI + | asr ITYPE, CARG1, #47 + |.endif + | add RB, PC, RB, lsl #2 + | add CARG2, CARG2, TMP0, lsl #47 + | sub RB, RB, #0x20000 + |.if FFI + | cmn ITYPE, #-LJ_TCDATA + | beq ->vmeta_equal_cd + |.endif + | cmp CARG1, CARG2 + if (vk) { + | csel PC, RB, PC, eq + } else { + | csel PC, RB, PC, ne + } + | ins_next + break; + + case BC_ISEQN: case BC_ISNEN: + vk = op == BC_ISEQN; + | // RA = src, RC = num_const (~), JMP with RC = target + | ldr CARG1, [BASE, RA, lsl #3] + | add RC, KBASE, RC, lsl #3 + | ldrh RBw, [PC, # OFS_RD] + | ldr CARG3, [RC] + | add PC, PC, #4 + | add RB, PC, RB, lsl #2 + | sub RB, RB, #0x20000 + if (vk) { + |->BC_ISEQN_Z: + } else { + |->BC_ISNEN_Z: + } + | checkint CARG1, >4 + | checkint CARG3, >6 + | cmp CARG1w, CARG3w + |1: + if (vk) { + | csel PC, RB, PC, eq + |2: + } else { + |2: + | csel PC, RB, PC, ne + } + |3: + | ins_next + | + |4: // RA not int. + |.if FFI + | blo >7 + |.else + | blo <2 + |.endif + | ldr FARG1, [BASE, RA, lsl #3] + | ldr FARG2, [RC] + | cmp TISNUMhi, CARG3, lsr #32 + | bne >5 + | // RA number, RC int. + | scvtf FARG2, CARG3w + |5: + | // RA number, RC number. + | fcmp FARG1, FARG2 + | b <1 + | + |6: // RA int, RC number + | ldr FARG2, [RC] + | scvtf FARG1, CARG1w + | fcmp FARG1, FARG2 + | b <1 + | + |.if FFI + |7: + | asr ITYPE, CARG1, #47 + | cmn ITYPE, #-LJ_TCDATA + | bne <2 + | b ->vmeta_equal_cd + |.endif + break; + + case BC_ISEQP: case BC_ISNEP: + vk = op == BC_ISEQP; + | // RA = src, RC = primitive_type (~), JMP with RC = target + | ldr TMP0, [BASE, RA, lsl #3] + | ldrh RBw, [PC, # OFS_RD] + | add PC, PC, #4 + | add RC, RC, #1 + | add RB, PC, RB, lsl #2 + |.if FFI + | asr ITYPE, TMP0, #47 + | cmn ITYPE, #-LJ_TCDATA + | beq ->vmeta_equal_cd + | cmn RC, ITYPE + |.else + | cmn RC, TMP0, asr #47 + |.endif + | sub RB, RB, #0x20000 + if (vk) { + | csel PC, RB, PC, eq + } else { + | csel PC, RB, PC, ne + } + | ins_next + break; + + /* -- Unary test and copy ops ------------------------------------------- */ + + case BC_ISTC: case BC_ISFC: case BC_IST: case BC_ISF: + | // RA = dst or unused, RC = src, JMP with RC = target + | ldrh RBw, [PC, # OFS_RD] + | ldr TMP0, [BASE, RC, lsl #3] + | add PC, PC, #4 + | mov_false TMP1 + | add RB, PC, RB, lsl #2 + | cmp TMP0, TMP1 + | sub RB, RB, #0x20000 + if (op == BC_ISTC || op == BC_IST) { + if (op == BC_ISTC) { + | csel RA, RA, RC, lo + } + | csel PC, RB, PC, lo + } else { + if (op == BC_ISFC) { + | csel RA, RA, RC, hs + } + | csel PC, RB, PC, hs + } + if (op == BC_ISTC || op == BC_ISFC) { + | str TMP0, [BASE, RA, lsl #3] + } + | ins_next + break; + + case BC_ISTYPE: + | // RA = src, RC = -type + | ldr TMP0, [BASE, RA, lsl #3] + | cmn RC, TMP0, asr #47 + | bne ->vmeta_istype + | ins_next + break; + case BC_ISNUM: + | // RA = src, RC = -(TISNUM-1) + | ldr TMP0, [BASE, RA] + | checknum TMP0, ->vmeta_istype + | ins_next + break; + + /* -- Unary ops --------------------------------------------------------- */ + + case BC_MOV: + | // RA = dst, RC = src + | ldr TMP0, [BASE, RC, lsl #3] + | str TMP0, [BASE, RA, lsl #3] + | ins_next + break; + case BC_NOT: + | // RA = dst, RC = src + | ldr TMP0, [BASE, RC, lsl #3] + | mov_false TMP1 + | mov_true TMP2 + | cmp TMP0, TMP1 + | csel TMP0, TMP1, TMP2, lo + | str TMP0, [BASE, RA, lsl #3] + | ins_next + break; + case BC_UNM: + | // RA = dst, RC = src + | ldr TMP0, [BASE, RC, lsl #3] + | asr ITYPE, TMP0, #47 + | cmn ITYPE, #-LJ_TISNUM + | bhi ->vmeta_unm + | eor TMP0, TMP0, #U64x(80000000,00000000) + | bne >5 + | negs TMP0w, TMP0w + | movz CARG3, #0x41e0, lsl #48 // 2^31. + | add TMP0, TMP0, TISNUM + | csel TMP0, TMP0, CARG3, vc + |5: + | str TMP0, [BASE, RA, lsl #3] + | ins_next + break; + case BC_LEN: + | // RA = dst, RC = src + | ldr CARG1, [BASE, RC, lsl #3] + | asr ITYPE, CARG1, #47 + | cmn ITYPE, #-LJ_TSTR + | and CARG1, CARG1, #LJ_GCVMASK + | bne >2 + | ldr CARG1w, STR:CARG1->len + |1: + | add CARG1, CARG1, TISNUM + | str CARG1, [BASE, RA, lsl #3] + | ins_next + | + |2: + | cmn ITYPE, #-LJ_TTAB + | bne ->vmeta_len +#if LJ_52 + | ldr TAB:CARG2, TAB:CARG1->metatable + | cbnz TAB:CARG2, >9 + |3: +#endif + |->BC_LEN_Z: + | bl extern lj_tab_len // (GCtab *t) + | // Returns uint32_t (but less than 2^31). + | b <1 + | +#if LJ_52 + |9: + | ldrb TMP1w, TAB:CARG2->nomm + | tbnz TMP1w, #MM_len, <3 // 'no __len' flag set: done. + | b ->vmeta_len +#endif + break; + + /* -- Binary ops -------------------------------------------------------- */ + + |.macro ins_arithcheck_int, target + | checkint CARG1, target + | checkint CARG2, target + |.endmacro + | + |.macro ins_arithcheck_num, target + | checknum CARG1, target + | checknum CARG2, target + |.endmacro + | + |.macro ins_arithcheck_nzdiv, target + | cbz CARG2w, target + |.endmacro + | + |.macro ins_arithhead + ||vk = ((int)op - BC_ADDVN) / (BC_ADDNV-BC_ADDVN); + ||if (vk == 1) { + | and RC, RC, #255 + | decode_RB RB, INS + ||} else { + | decode_RB RB, INS + | and RC, RC, #255 + ||} + |.endmacro + | + |.macro ins_arithload, reg1, reg2 + | // RA = dst, RB = src1, RC = src2 | num_const + ||switch (vk) { + ||case 0: + | ldr reg1, [BASE, RB, lsl #3] + | ldr reg2, [KBASE, RC, lsl #3] + || break; + ||case 1: + | ldr reg1, [KBASE, RC, lsl #3] + | ldr reg2, [BASE, RB, lsl #3] + || break; + ||default: + | ldr reg1, [BASE, RB, lsl #3] + | ldr reg2, [BASE, RC, lsl #3] + || break; + ||} + |.endmacro + | + |.macro ins_arithfallback, ins + ||switch (vk) { + ||case 0: + | ins ->vmeta_arith_vn + || break; + ||case 1: + | ins ->vmeta_arith_nv + || break; + ||default: + | ins ->vmeta_arith_vv + || break; + ||} + |.endmacro + | + |.macro ins_arithmod, res, reg1, reg2 + | fdiv d2, reg1, reg2 + | frintm d2, d2 + | fmsub res, d2, reg2, reg1 + |.endmacro + | + |.macro ins_arithdn, intins, fpins + | ins_arithhead + | ins_arithload CARG1, CARG2 + | ins_arithcheck_int >5 + |.if "intins" == "smull" + | smull CARG1, CARG1w, CARG2w + | cmp CARG1, CARG1, sxtw + | mov CARG1w, CARG1w + | ins_arithfallback bne + |.elif "intins" == "ins_arithmodi" + | ins_arithfallback ins_arithcheck_nzdiv + | bl ->vm_modi + |.else + | intins CARG1w, CARG1w, CARG2w + | ins_arithfallback bvs + |.endif + | add CARG1, CARG1, TISNUM + | str CARG1, [BASE, RA, lsl #3] + |4: + | ins_next + | + |5: // FP variant. + | ins_arithload FARG1, FARG2 + | ins_arithfallback ins_arithcheck_num + | fpins FARG1, FARG1, FARG2 + | str FARG1, [BASE, RA, lsl #3] + | b <4 + |.endmacro + | + |.macro ins_arithfp, fpins + | ins_arithhead + | ins_arithload CARG1, CARG2 + | ins_arithload FARG1, FARG2 + | ins_arithfallback ins_arithcheck_num + |.if "fpins" == "fpow" + | bl extern pow + |.else + | fpins FARG1, FARG1, FARG2 + |.endif + | str FARG1, [BASE, RA, lsl #3] + | ins_next + |.endmacro + + case BC_ADDVN: case BC_ADDNV: case BC_ADDVV: + | ins_arithdn adds, fadd + break; + case BC_SUBVN: case BC_SUBNV: case BC_SUBVV: + | ins_arithdn subs, fsub + break; + case BC_MULVN: case BC_MULNV: case BC_MULVV: + | ins_arithdn smull, fmul + break; + case BC_DIVVN: case BC_DIVNV: case BC_DIVVV: + | ins_arithfp fdiv + break; + case BC_MODVN: case BC_MODNV: case BC_MODVV: + | ins_arithdn ins_arithmodi, ins_arithmod + break; + case BC_POW: + | // NYI: (partial) integer arithmetic. + | ins_arithfp fpow + break; + + case BC_CAT: + | decode_RB RB, INS + | and RC, RC, #255 + | // RA = dst, RB = src_start, RC = src_end + | str BASE, L->base + | sub CARG3, RC, RB + | add CARG2, BASE, RC, lsl #3 + |->BC_CAT_Z: + | // RA = dst, CARG2 = top-1, CARG3 = left + | mov CARG1, L + | str PC, SAVE_PC + | bl extern lj_meta_cat // (lua_State *L, TValue *top, int left) + | // Returns NULL (finished) or TValue * (metamethod). + | ldrb RBw, [PC, #-4+OFS_RB] + | ldr BASE, L->base + | cbnz CRET1, ->vmeta_binop + | ldr TMP0, [BASE, RB, lsl #3] + | str TMP0, [BASE, RA, lsl #3] // Copy result to RA. + | ins_next + break; + + /* -- Constant ops ------------------------------------------------------ */ + + case BC_KSTR: + | // RA = dst, RC = str_const (~) + | mvn RC, RC + | ldr TMP0, [KBASE, RC, lsl #3] + | movn TMP1, #~LJ_TSTR + | add TMP0, TMP0, TMP1, lsl #47 + | str TMP0, [BASE, RA, lsl #3] + | ins_next + break; + case BC_KCDATA: + |.if FFI + | // RA = dst, RC = cdata_const (~) + | mvn RC, RC + | ldr TMP0, [KBASE, RC, lsl #3] + | movn TMP1, #~LJ_TCDATA + | add TMP0, TMP0, TMP1, lsl #47 + | str TMP0, [BASE, RA, lsl #3] + | ins_next + |.endif + break; + case BC_KSHORT: + | // RA = dst, RC = int16_literal + | sxth RCw, RCw + | add TMP0, RC, TISNUM + | str TMP0, [BASE, RA, lsl #3] + | ins_next + break; + case BC_KNUM: + | // RA = dst, RC = num_const + | ldr TMP0, [KBASE, RC, lsl #3] + | str TMP0, [BASE, RA, lsl #3] + | ins_next + break; + case BC_KPRI: + | // RA = dst, RC = primitive_type (~) + | mvn TMP0, RC, lsl #47 + | str TMP0, [BASE, RA, lsl #3] + | ins_next + break; + case BC_KNIL: + | // RA = base, RC = end + | add RA, BASE, RA, lsl #3 + | add RC, BASE, RC, lsl #3 + | str TISNIL, [RA], #8 + |1: + | cmp RA, RC + | str TISNIL, [RA], #8 + | blt <1 + | ins_next_ + break; + + /* -- Upvalue and function ops ------------------------------------------ */ + + case BC_UGET: + | // RA = dst, RC = uvnum + | ldr LFUNC:CARG2, [BASE, FRAME_FUNC] + | add RC, RC, #offsetof(GCfuncL, uvptr)/8 + | and LFUNC:CARG2, CARG2, #LJ_GCVMASK + | ldr UPVAL:CARG2, [LFUNC:CARG2, RC, lsl #3] + | ldr CARG2, UPVAL:CARG2->v + | ldr TMP0, [CARG2] + | str TMP0, [BASE, RA, lsl #3] + | ins_next + break; + case BC_USETV: + | // RA = uvnum, RC = src + | ldr LFUNC:CARG2, [BASE, FRAME_FUNC] + | add RA, RA, #offsetof(GCfuncL, uvptr)/8 + | and LFUNC:CARG2, CARG2, #LJ_GCVMASK + | ldr UPVAL:CARG1, [LFUNC:CARG2, RA, lsl #3] + | ldr CARG3, [BASE, RC, lsl #3] + | ldr CARG2, UPVAL:CARG1->v + | ldrb TMP2w, UPVAL:CARG1->marked + | ldrb TMP0w, UPVAL:CARG1->closed + | asr ITYPE, CARG3, #47 + | str CARG3, [CARG2] + | add ITYPE, ITYPE, #-LJ_TISGCV + | tst TMP2w, #LJ_GC_BLACK // isblack(uv) + | ccmp TMP0w, #0, #4, ne // && uv->closed + | ccmn ITYPE, #-(LJ_TNUMX - LJ_TISGCV), #0, ne // && tvisgcv(v) + | bhi >2 + |1: + | ins_next + | + |2: // Check if new value is white. + | and GCOBJ:CARG3, CARG3, #LJ_GCVMASK + | ldrb TMP1w, GCOBJ:CARG3->gch.marked + | tst TMP1w, #LJ_GC_WHITES // iswhite(str) + | beq <1 + | // Crossed a write barrier. Move the barrier forward. + | mov CARG1, GL + | bl extern lj_gc_barrieruv // (global_State *g, TValue *tv) + | b <1 + break; + case BC_USETS: + | // RA = uvnum, RC = str_const (~) + | ldr LFUNC:CARG2, [BASE, FRAME_FUNC] + | add RA, RA, #offsetof(GCfuncL, uvptr)/8 + | mvn RC, RC + | and LFUNC:CARG2, CARG2, #LJ_GCVMASK + | ldr UPVAL:CARG1, [LFUNC:CARG2, RA, lsl #3] + | ldr STR:CARG3, [KBASE, RC, lsl #3] + | movn TMP0, #~LJ_TSTR + | ldr CARG2, UPVAL:CARG1->v + | ldrb TMP2w, UPVAL:CARG1->marked + | add TMP0, STR:CARG3, TMP0, lsl #47 + | ldrb TMP1w, STR:CARG3->marked + | str TMP0, [CARG2] + | tbnz TMP2w, #2, >2 // isblack(uv) + |1: + | ins_next + | + |2: // Check if string is white and ensure upvalue is closed. + | ldrb TMP0w, UPVAL:CARG1->closed + | tst TMP1w, #LJ_GC_WHITES // iswhite(str) + | ccmp TMP0w, #0, #4, ne + | beq <1 + | // Crossed a write barrier. Move the barrier forward. + | mov CARG1, GL + | bl extern lj_gc_barrieruv // (global_State *g, TValue *tv) + | b <1 + break; + case BC_USETN: + | // RA = uvnum, RC = num_const + | ldr LFUNC:CARG2, [BASE, FRAME_FUNC] + | add RA, RA, #offsetof(GCfuncL, uvptr)/8 + | and LFUNC:CARG2, CARG2, #LJ_GCVMASK + | ldr UPVAL:CARG2, [LFUNC:CARG2, RA, lsl #3] + | ldr TMP0, [KBASE, RC, lsl #3] + | ldr CARG2, UPVAL:CARG2->v + | str TMP0, [CARG2] + | ins_next + break; + case BC_USETP: + | // RA = uvnum, RC = primitive_type (~) + | ldr LFUNC:CARG2, [BASE, FRAME_FUNC] + | add RA, RA, #offsetof(GCfuncL, uvptr)/8 + | and LFUNC:CARG2, CARG2, #LJ_GCVMASK + | ldr UPVAL:CARG2, [LFUNC:CARG2, RA, lsl #3] + | mvn TMP0, RC, lsl #47 + | ldr CARG2, UPVAL:CARG2->v + | str TMP0, [CARG2] + | ins_next + break; + + case BC_UCLO: + | // RA = level, RC = target + | ldr CARG3, L->openupval + | add RC, PC, RC, lsl #2 + | str BASE, L->base + | sub PC, RC, #0x20000 + | cbz CARG3, >1 + | mov CARG1, L + | add CARG2, BASE, RA, lsl #3 + | bl extern lj_func_closeuv // (lua_State *L, TValue *level) + | ldr BASE, L->base + |1: + | ins_next + break; + + case BC_FNEW: + | // RA = dst, RC = proto_const (~) (holding function prototype) + | mvn RC, RC + | str BASE, L->base + | ldr LFUNC:CARG3, [BASE, FRAME_FUNC] + | str PC, SAVE_PC + | ldr CARG2, [KBASE, RC, lsl #3] + | mov CARG1, L + | and LFUNC:CARG3, CARG3, #LJ_GCVMASK + | // (lua_State *L, GCproto *pt, GCfuncL *parent) + | bl extern lj_func_newL_gc + | // Returns GCfuncL *. + | ldr BASE, L->base + | movn TMP0, #~LJ_TFUNC + | add CRET1, CRET1, TMP0, lsl #47 + | str CRET1, [BASE, RA, lsl #3] + | ins_next + break; + + /* -- Table ops --------------------------------------------------------- */ + + case BC_TNEW: + case BC_TDUP: + | // RA = dst, RC = (hbits|asize) | tab_const (~) + | ldp CARG3, CARG4, GL->gc.total // Assumes threshold follows total. + | str BASE, L->base + | str PC, SAVE_PC + | mov CARG1, L + | cmp CARG3, CARG4 + | bhs >5 + |1: + if (op == BC_TNEW) { + | and CARG2, RC, #0x7ff + | lsr CARG3, RC, #11 + | cmp CARG2, #0x7ff + | mov TMP0, #0x801 + | csel CARG2, CARG2, TMP0, ne + | bl extern lj_tab_new // (lua_State *L, int32_t asize, uint32_t hbits) + | // Returns GCtab *. + } else { + | mvn RC, RC + | ldr CARG2, [KBASE, RC, lsl #3] + | bl extern lj_tab_dup // (lua_State *L, Table *kt) + | // Returns GCtab *. + } + | ldr BASE, L->base + | movk CRET1, #(LJ_TTAB>>1)&0xffff, lsl #48 + | str CRET1, [BASE, RA, lsl #3] + | ins_next + | + |5: + | bl extern lj_gc_step_fixtop // (lua_State *L) + | mov CARG1, L + | b <1 + break; + + case BC_GGET: + | // RA = dst, RC = str_const (~) + case BC_GSET: + | // RA = src, RC = str_const (~) + | ldr LFUNC:CARG1, [BASE, FRAME_FUNC] + | mvn RC, RC + | and LFUNC:CARG1, CARG1, #LJ_GCVMASK + | ldr TAB:CARG2, LFUNC:CARG1->env + | ldr STR:RC, [KBASE, RC, lsl #3] + if (op == BC_GGET) { + | b ->BC_TGETS_Z + } else { + | b ->BC_TSETS_Z + } + break; + + case BC_TGETV: + | decode_RB RB, INS + | and RC, RC, #255 + | // RA = dst, RB = table, RC = key + | ldr CARG2, [BASE, RB, lsl #3] + | ldr TMP1, [BASE, RC, lsl #3] + | checktab CARG2, ->vmeta_tgetv + | checkint TMP1, >9 // Integer key? + | ldr CARG3, TAB:CARG2->array + | ldr CARG1w, TAB:CARG2->asize + | add CARG3, CARG3, TMP1, uxtw #3 + | cmp TMP1w, CARG1w // In array part? + | bhs ->vmeta_tgetv + | ldr TMP0, [CARG3] + | cmp TMP0, TISNIL + | beq >5 + |1: + | str TMP0, [BASE, RA, lsl #3] + | ins_next + | + |5: // Check for __index if table value is nil. + | ldr TAB:CARG1, TAB:CARG2->metatable + | cbz TAB:CARG1, <1 // No metatable: done. + | ldrb TMP1w, TAB:CARG1->nomm + | tbnz TMP1w, #MM_index, <1 // 'no __index' flag set: done. + | b ->vmeta_tgetv + | + |9: + | asr ITYPE, TMP1, #47 + | cmn ITYPE, #-LJ_TSTR // String key? + | bne ->vmeta_tgetv + | and STR:RC, TMP1, #LJ_GCVMASK + | b ->BC_TGETS_Z + break; + case BC_TGETS: + | decode_RB RB, INS + | and RC, RC, #255 + | // RA = dst, RB = table, RC = str_const (~) + | ldr CARG2, [BASE, RB, lsl #3] + | mvn RC, RC + | ldr STR:RC, [KBASE, RC, lsl #3] + | checktab CARG2, ->vmeta_tgets1 + |->BC_TGETS_Z: + | // TAB:CARG2 = GCtab *, STR:RC = GCstr *, RA = dst + | ldr TMP1w, TAB:CARG2->hmask + | ldr TMP2w, STR:RC->sid + | ldr NODE:CARG3, TAB:CARG2->node + | and TMP1w, TMP1w, TMP2w // idx = str->sid & tab->hmask + | add TMP1, TMP1, TMP1, lsl #1 + | movn CARG4, #~LJ_TSTR + | add NODE:CARG3, NODE:CARG3, TMP1, lsl #3 // node = tab->node + idx*3*8 + | add CARG4, STR:RC, CARG4, lsl #47 // Tagged key to look for. + |1: + | ldp TMP0, CARG1, NODE:CARG3->val + | ldr NODE:CARG3, NODE:CARG3->next + | cmp CARG1, CARG4 + | bne >4 + | cmp TMP0, TISNIL + | beq >5 + |3: + | str TMP0, [BASE, RA, lsl #3] + | ins_next + | + |4: // Follow hash chain. + | cbnz NODE:CARG3, <1 + | // End of hash chain: key not found, nil result. + | mov TMP0, TISNIL + | + |5: // Check for __index if table value is nil. + | ldr TAB:CARG1, TAB:CARG2->metatable + | cbz TAB:CARG1, <3 // No metatable: done. + | ldrb TMP1w, TAB:CARG1->nomm + | tbnz TMP1w, #MM_index, <3 // 'no __index' flag set: done. + | b ->vmeta_tgets + break; + case BC_TGETB: + | decode_RB RB, INS + | and RC, RC, #255 + | // RA = dst, RB = table, RC = index + | ldr CARG2, [BASE, RB, lsl #3] + | checktab CARG2, ->vmeta_tgetb + | ldr CARG3, TAB:CARG2->array + | ldr CARG1w, TAB:CARG2->asize + | add CARG3, CARG3, RC, lsl #3 + | cmp RCw, CARG1w // In array part? + | bhs ->vmeta_tgetb + | ldr TMP0, [CARG3] + | cmp TMP0, TISNIL + | beq >5 + |1: + | str TMP0, [BASE, RA, lsl #3] + | ins_next + | + |5: // Check for __index if table value is nil. + | ldr TAB:CARG1, TAB:CARG2->metatable + | cbz TAB:CARG1, <1 // No metatable: done. + | ldrb TMP1w, TAB:CARG1->nomm + | tbnz TMP1w, #MM_index, <1 // 'no __index' flag set: done. + | b ->vmeta_tgetb + break; + case BC_TGETR: + | decode_RB RB, INS + | and RC, RC, #255 + | // RA = dst, RB = table, RC = key + | ldr CARG1, [BASE, RB, lsl #3] + | ldr TMP1, [BASE, RC, lsl #3] + | and TAB:CARG1, CARG1, #LJ_GCVMASK + | ldr CARG3, TAB:CARG1->array + | ldr TMP2w, TAB:CARG1->asize + | add CARG3, CARG3, TMP1w, uxtw #3 + | cmp TMP1w, TMP2w // In array part? + | bhs ->vmeta_tgetr + | ldr TMP0, [CARG3] + |->BC_TGETR_Z: + | str TMP0, [BASE, RA, lsl #3] + | ins_next + break; + + case BC_TSETV: + | decode_RB RB, INS + | and RC, RC, #255 + | // RA = src, RB = table, RC = key + | ldr CARG2, [BASE, RB, lsl #3] + | ldr TMP1, [BASE, RC, lsl #3] + | checktab CARG2, ->vmeta_tsetv + | checkint TMP1, >9 // Integer key? + | ldr CARG3, TAB:CARG2->array + | ldr CARG1w, TAB:CARG2->asize + | add CARG3, CARG3, TMP1, uxtw #3 + | cmp TMP1w, CARG1w // In array part? + | bhs ->vmeta_tsetv + | ldr TMP1, [CARG3] + | ldr TMP0, [BASE, RA, lsl #3] + | ldrb TMP2w, TAB:CARG2->marked + | cmp TMP1, TISNIL // Previous value is nil? + | beq >5 + |1: + | str TMP0, [CARG3] + | tbnz TMP2w, #2, >7 // isblack(table) + |2: + | ins_next + | + |5: // Check for __newindex if previous value is nil. + | ldr TAB:CARG1, TAB:CARG2->metatable + | cbz TAB:CARG1, <1 // No metatable: done. + | ldrb TMP1w, TAB:CARG1->nomm + | tbnz TMP1w, #MM_newindex, <1 // 'no __newindex' flag set: done. + | b ->vmeta_tsetv + | + |7: // Possible table write barrier for the value. Skip valiswhite check. + | barrierback TAB:CARG2, TMP2w, TMP1 + | b <2 + | + |9: + | asr ITYPE, TMP1, #47 + | cmn ITYPE, #-LJ_TSTR // String key? + | bne ->vmeta_tsetv + | and STR:RC, TMP1, #LJ_GCVMASK + | b ->BC_TSETS_Z + break; + case BC_TSETS: + | decode_RB RB, INS + | and RC, RC, #255 + | // RA = dst, RB = table, RC = str_const (~) + | ldr CARG2, [BASE, RB, lsl #3] + | mvn RC, RC + | ldr STR:RC, [KBASE, RC, lsl #3] + | checktab CARG2, ->vmeta_tsets1 + |->BC_TSETS_Z: + | // TAB:CARG2 = GCtab *, STR:RC = GCstr *, RA = src + | ldr TMP1w, TAB:CARG2->hmask + | ldr TMP2w, STR:RC->sid + | ldr NODE:CARG3, TAB:CARG2->node + | and TMP1w, TMP1w, TMP2w // idx = str->sid & tab->hmask + | add TMP1, TMP1, TMP1, lsl #1 + | movn CARG4, #~LJ_TSTR + | add NODE:CARG3, NODE:CARG3, TMP1, lsl #3 // node = tab->node + idx*3*8 + | add CARG4, STR:RC, CARG4, lsl #47 // Tagged key to look for. + | strb wzr, TAB:CARG2->nomm // Clear metamethod cache. + |1: + | ldp TMP1, CARG1, NODE:CARG3->val + | ldr NODE:TMP3, NODE:CARG3->next + | ldrb TMP2w, TAB:CARG2->marked + | cmp CARG1, CARG4 + | bne >5 + | ldr TMP0, [BASE, RA, lsl #3] + | cmp TMP1, TISNIL // Previous value is nil? + | beq >4 + |2: + | str TMP0, NODE:CARG3->val + | tbnz TMP2w, #2, >7 // isblack(table) + |3: + | ins_next + | + |4: // Check for __newindex if previous value is nil. + | ldr TAB:CARG1, TAB:CARG2->metatable + | cbz TAB:CARG1, <2 // No metatable: done. + | ldrb TMP1w, TAB:CARG1->nomm + | tbnz TMP1w, #MM_newindex, <2 // 'no __newindex' flag set: done. + | b ->vmeta_tsets + | + |5: // Follow hash chain. + | mov NODE:CARG3, NODE:TMP3 + | cbnz NODE:TMP3, <1 + | // End of hash chain: key not found, add a new one. + | + | // But check for __newindex first. + | ldr TAB:CARG1, TAB:CARG2->metatable + | cbz TAB:CARG1, >6 // No metatable: continue. + | ldrb TMP1w, TAB:CARG1->nomm + | // 'no __newindex' flag NOT set: check. + | tbz TMP1w, #MM_newindex, ->vmeta_tsets + |6: + | movn TMP1, #~LJ_TSTR + | str PC, SAVE_PC + | add TMP0, STR:RC, TMP1, lsl #47 + | str BASE, L->base + | mov CARG1, L + | str TMP0, TMPD + | add CARG3, sp, TMPDofs + | bl extern lj_tab_newkey // (lua_State *L, GCtab *t, TValue *k) + | // Returns TValue *. + | ldr BASE, L->base + | ldr TMP0, [BASE, RA, lsl #3] + | str TMP0, [CRET1] + | b <3 // No 2nd write barrier needed. + | + |7: // Possible table write barrier for the value. Skip valiswhite check. + | barrierback TAB:CARG2, TMP2w, TMP1 + | b <3 + break; + case BC_TSETB: + | decode_RB RB, INS + | and RC, RC, #255 + | // RA = src, RB = table, RC = index + | ldr CARG2, [BASE, RB, lsl #3] + | checktab CARG2, ->vmeta_tsetb + | ldr CARG3, TAB:CARG2->array + | ldr CARG1w, TAB:CARG2->asize + | add CARG3, CARG3, RC, lsl #3 + | cmp RCw, CARG1w // In array part? + | bhs ->vmeta_tsetb + | ldr TMP1, [CARG3] + | ldr TMP0, [BASE, RA, lsl #3] + | ldrb TMP2w, TAB:CARG2->marked + | cmp TMP1, TISNIL // Previous value is nil? + | beq >5 + |1: + | str TMP0, [CARG3] + | tbnz TMP2w, #2, >7 // isblack(table) + |2: + | ins_next + | + |5: // Check for __newindex if previous value is nil. + | ldr TAB:CARG1, TAB:CARG2->metatable + | cbz TAB:CARG1, <1 // No metatable: done. + | ldrb TMP1w, TAB:CARG1->nomm + | tbnz TMP1w, #MM_newindex, <1 // 'no __newindex' flag set: done. + | b ->vmeta_tsetb + | + |7: // Possible table write barrier for the value. Skip valiswhite check. + | barrierback TAB:CARG2, TMP2w, TMP1 + | b <2 + break; + case BC_TSETR: + | decode_RB RB, INS + | and RC, RC, #255 + | // RA = src, RB = table, RC = key + | ldr CARG2, [BASE, RB, lsl #3] + | ldr TMP1, [BASE, RC, lsl #3] + | and TAB:CARG2, CARG2, #LJ_GCVMASK + | ldr CARG1, TAB:CARG2->array + | ldrb TMP2w, TAB:CARG2->marked + | ldr CARG4w, TAB:CARG2->asize + | add CARG1, CARG1, TMP1, uxtw #3 + | tbnz TMP2w, #2, >7 // isblack(table) + |2: + | cmp TMP1w, CARG4w // In array part? + | bhs ->vmeta_tsetr + |->BC_TSETR_Z: + | ldr TMP0, [BASE, RA, lsl #3] + | str TMP0, [CARG1] + | ins_next + | + |7: // Possible table write barrier for the value. Skip valiswhite check. + | barrierback TAB:CARG2, TMP2w, TMP0 + | b <2 + break; + + case BC_TSETM: + | // RA = base (table at base-1), RC = num_const (start index) + | add RA, BASE, RA, lsl #3 + |1: + | ldr RBw, SAVE_MULTRES + | ldr TAB:CARG2, [RA, #-8] // Guaranteed to be a table. + | ldr TMP1, [KBASE, RC, lsl #3] // Integer constant is in lo-word. + | sub RB, RB, #8 + | cbz RB, >4 // Nothing to copy? + | and TAB:CARG2, CARG2, #LJ_GCVMASK + | ldr CARG1w, TAB:CARG2->asize + | add CARG3w, TMP1w, RBw, lsr #3 + | ldr CARG4, TAB:CARG2->array + | cmp CARG3, CARG1 + | add RB, RA, RB + | bhi >5 + | add TMP1, CARG4, TMP1w, uxtw #3 + | ldrb TMP2w, TAB:CARG2->marked + |3: // Copy result slots to table. + | ldr TMP0, [RA], #8 + | str TMP0, [TMP1], #8 + | cmp RA, RB + | blo <3 + | tbnz TMP2w, #2, >7 // isblack(table) + |4: + | ins_next + | + |5: // Need to resize array part. + | str BASE, L->base + | mov CARG1, L + | str PC, SAVE_PC + | bl extern lj_tab_reasize // (lua_State *L, GCtab *t, int nasize) + | // Must not reallocate the stack. + | b <1 + | + |7: // Possible table write barrier for any value. Skip valiswhite check. + | barrierback TAB:CARG2, TMP2w, TMP1 + | b <4 + break; + + /* -- Calls and vararg handling ----------------------------------------- */ + + case BC_CALLM: + | // RA = base, (RB = nresults+1,) RC = extra_nargs + | ldr TMP0w, SAVE_MULTRES + | decode_RC8RD NARGS8:RC, RC + | add NARGS8:RC, NARGS8:RC, TMP0 + | b ->BC_CALL_Z + break; + case BC_CALL: + | decode_RC8RD NARGS8:RC, RC + | // RA = base, (RB = nresults+1,) RC = (nargs+1)*8 + |->BC_CALL_Z: + | mov RB, BASE // Save old BASE for vmeta_call. + | add BASE, BASE, RA, lsl #3 + | ldr CARG3, [BASE] + | sub NARGS8:RC, NARGS8:RC, #8 + | add BASE, BASE, #16 + | checkfunc CARG3, ->vmeta_call + | ins_call + break; + + case BC_CALLMT: + | // RA = base, (RB = 0,) RC = extra_nargs + | ldr TMP0w, SAVE_MULTRES + | add NARGS8:RC, TMP0, RC, lsl #3 + | b ->BC_CALLT1_Z + break; + case BC_CALLT: + | lsl NARGS8:RC, RC, #3 + | // RA = base, (RB = 0,) RC = (nargs+1)*8 + |->BC_CALLT1_Z: + | add RA, BASE, RA, lsl #3 + | ldr TMP1, [RA] + | sub NARGS8:RC, NARGS8:RC, #8 + | add RA, RA, #16 + | checktp CARG3, TMP1, LJ_TFUNC, ->vmeta_callt + | ldr PC, [BASE, FRAME_PC] + |->BC_CALLT2_Z: + | mov RB, #0 + | ldrb TMP2w, LFUNC:CARG3->ffid + | tst PC, #FRAME_TYPE + | bne >7 + |1: + | str TMP1, [BASE, FRAME_FUNC] // Copy function down, but keep PC. + | cbz NARGS8:RC, >3 + |2: + | ldr TMP0, [RA, RB] + | add TMP1, RB, #8 + | cmp TMP1, NARGS8:RC + | str TMP0, [BASE, RB] + | mov RB, TMP1 + | bne <2 + |3: + | cmp TMP2, #1 // (> FF_C) Calling a fast function? + | bhi >5 + |4: + | ins_callt + | + |5: // Tailcall to a fast function with a Lua frame below. + | ldrb RAw, [PC, #-4+OFS_RA] + | sub CARG1, BASE, RA, lsl #3 + | ldr LFUNC:CARG1, [CARG1, #-32] + | and LFUNC:CARG1, CARG1, #LJ_GCVMASK + | ldr CARG1, LFUNC:CARG1->pc + | ldr KBASE, [CARG1, #PC2PROTO(k)] + | b <4 + | + |7: // Tailcall from a vararg function. + | eor PC, PC, #FRAME_VARG + | tst PC, #FRAME_TYPEP // Vararg frame below? + | csel TMP2, RB, TMP2, ne // Clear ffid if no Lua function below. + | bne <1 + | sub BASE, BASE, PC + | ldr PC, [BASE, FRAME_PC] + | tst PC, #FRAME_TYPE + | csel TMP2, RB, TMP2, ne // Clear ffid if no Lua function below. + | b <1 + break; + + case BC_ITERC: + | // RA = base, (RB = nresults+1, RC = nargs+1 (2+1)) + | add RA, BASE, RA, lsl #3 + | ldr CARG3, [RA, #-24] + | mov RB, BASE // Save old BASE for vmeta_call. + | ldp CARG1, CARG2, [RA, #-16] + | add BASE, RA, #16 + | mov NARGS8:RC, #16 // Iterators get 2 arguments. + | str CARG3, [RA] // Copy callable. + | stp CARG1, CARG2, [RA, #16] // Copy state and control var. + | checkfunc CARG3, ->vmeta_call + | ins_call + break; + + case BC_ITERN: + |.if JIT + | hotloop + |.endif + |->vm_IITERN: + | // RA = base, (RB = nresults+1, RC = nargs+1 (2+1)) + | add RA, BASE, RA, lsl #3 + | ldr TAB:RB, [RA, #-16] + | ldrh TMP3w, [PC, # OFS_RD] + | ldr CARG1w, [RA, #-8+LO] // Get index from control var. + | add PC, PC, #4 + | add TMP3, PC, TMP3, lsl #2 + | and TAB:RB, RB, #LJ_GCVMASK + | sub TMP3, TMP3, #0x20000 + | ldr TMP1w, TAB:RB->asize + | ldr CARG2, TAB:RB->array + |1: // Traverse array part. + | subs RC, CARG1, TMP1 + | add CARG3, CARG2, CARG1, lsl #3 + | bhs >5 // Index points after array part? + | ldr TMP0, [CARG3] + | cmp TMP0, TISNIL + | cinc CARG1, CARG1, eq // Skip holes in array part. + | beq <1 + | add CARG1, CARG1, TISNUM + | stp CARG1, TMP0, [RA] + | add CARG1, CARG1, #1 + |3: + | str CARG1w, [RA, #-8+LO] // Update control var. + | mov PC, TMP3 + |4: + | ins_next + | + |5: // Traverse hash part. + | ldr TMP2w, TAB:RB->hmask + | ldr NODE:RB, TAB:RB->node + |6: + | add CARG1, RC, RC, lsl #1 + | cmp RC, TMP2 // End of iteration? Branch to ITERN+1. + | add NODE:CARG3, NODE:RB, CARG1, lsl #3 // node = tab->node + idx*3*8 + | bhi <4 + | ldp TMP0, CARG1, NODE:CARG3->val + | cmp TMP0, TISNIL + | add RC, RC, #1 + | beq <6 // Skip holes in hash part. + | stp CARG1, TMP0, [RA] + | add CARG1, RC, TMP1 + | b <3 + break; + + case BC_ISNEXT: + | // RA = base, RC = target (points to ITERN) + | add RA, BASE, RA, lsl #3 + | ldr CFUNC:CARG1, [RA, #-24] + | add RC, PC, RC, lsl #2 + | ldp TAB:CARG3, CARG4, [RA, #-16] + | sub RC, RC, #0x20000 + | checkfunc CFUNC:CARG1, >5 + | asr TMP0, TAB:CARG3, #47 + | ldrb TMP1w, CFUNC:CARG1->ffid + | cmn TMP0, #-LJ_TTAB + | ccmp CARG4, TISNIL, #0, eq + | ccmp TMP1w, #FF_next_N, #0, eq + | bne >5 + | mov TMP0w, #0xfffe7fff // LJ_KEYINDEX + | lsl TMP0, TMP0, #32 + | str TMP0, [RA, #-8] // Initialize control var. + |1: + | mov PC, RC + | ins_next + | + |5: // Despecialize bytecode if any of the checks fail. + |.if JIT + | ldrb TMP2w, [RC, # OFS_OP] + |.endif + | mov TMP0, #BC_JMP + | mov TMP1, #BC_ITERC + | strb TMP0w, [PC, #-4+OFS_OP] + |.if JIT + | cmp TMP2w, #BC_ITERN + | bne >6 + |.endif + | strb TMP1w, [RC, # OFS_OP] + | b <1 + |.if JIT + |6: // Unpatch JLOOP. + | ldr RA, [GL, #GL_J(trace)] + | ldrh TMP2w, [RC, # OFS_RD] + | ldr TRACE:RA, [RA, TMP2, lsl #3] + | ldr TMP2w, TRACE:RA->startins + | bfxil TMP2w, TMP1w, #0, #8 + | str TMP2w, [RC] + | b <1 + |.endif + break; + + case BC_VARG: + | decode_RB RB, INS + | and RC, RC, #255 + | // RA = base, RB = (nresults+1), RC = numparams + | ldr TMP1, [BASE, FRAME_PC] + | add RC, BASE, RC, lsl #3 + | add RA, BASE, RA, lsl #3 + | add RC, RC, #FRAME_VARG + | add TMP2, RA, RB, lsl #3 + | sub RC, RC, TMP1 // RC = vbase + | // Note: RC may now be even _above_ BASE if nargs was < numparams. + | sub TMP3, BASE, #16 // TMP3 = vtop + | cbz RB, >5 + | sub TMP2, TMP2, #16 + |1: // Copy vararg slots to destination slots. + | cmp RC, TMP3 + | ldr TMP0, [RC], #8 + | csel TMP0, TMP0, TISNIL, lo + | cmp RA, TMP2 + | str TMP0, [RA], #8 + | blo <1 + |2: + | ins_next + | + |5: // Copy all varargs. + | ldr TMP0, L->maxstack + | subs TMP2, TMP3, RC + | csel RB, xzr, TMP2, le // MULTRES = (max(vtop-vbase,0)+1)*8 + | add RB, RB, #8 + | add TMP1, RA, TMP2 + | str RBw, SAVE_MULTRES + | ble <2 // Nothing to copy. + | cmp TMP1, TMP0 + | bhi >7 + |6: + | ldr TMP0, [RC], #8 + | str TMP0, [RA], #8 + | cmp RC, TMP3 + | blo <6 + | b <2 + | + |7: // Grow stack for varargs. + | lsr CARG2, TMP2, #3 + | stp BASE, RA, L->base + | mov CARG1, L + | sub RC, RC, BASE // Need delta, because BASE may change. + | str PC, SAVE_PC + | bl extern lj_state_growstack // (lua_State *L, int n) + | ldp BASE, RA, L->base + | add RC, BASE, RC + | sub TMP3, BASE, #16 + | b <6 + break; + + /* -- Returns ----------------------------------------------------------- */ + + case BC_RETM: + | // RA = results, RC = extra results + | ldr TMP0w, SAVE_MULTRES + | ldr PC, [BASE, FRAME_PC] + | add RA, BASE, RA, lsl #3 + | add RC, TMP0, RC, lsl #3 + | b ->BC_RETM_Z + break; + + case BC_RET: + | // RA = results, RC = nresults+1 + | ldr PC, [BASE, FRAME_PC] + | lsl RC, RC, #3 + | add RA, BASE, RA, lsl #3 + |->BC_RETM_Z: + | str RCw, SAVE_MULTRES + |1: + | ands CARG1, PC, #FRAME_TYPE + | eor CARG2, PC, #FRAME_VARG + | bne ->BC_RETV2_Z + | + |->BC_RET_Z: + | // BASE = base, RA = resultptr, RC = (nresults+1)*8, PC = return + | ldr INSw, [PC, #-4] + | subs TMP1, RC, #8 + | sub CARG3, BASE, #16 + | beq >3 + |2: + | ldr TMP0, [RA], #8 + | add BASE, BASE, #8 + | sub TMP1, TMP1, #8 + | str TMP0, [BASE, #-24] + | cbnz TMP1, <2 + |3: + | decode_RA RA, INS + | sub CARG4, CARG3, RA, lsl #3 + | decode_RB RB, INS + | ldr LFUNC:CARG1, [CARG4, FRAME_FUNC] + |5: + | cmp RC, RB, lsl #3 // More results expected? + | blo >6 + | and LFUNC:CARG1, CARG1, #LJ_GCVMASK + | mov BASE, CARG4 + | ldr CARG2, LFUNC:CARG1->pc + | ldr KBASE, [CARG2, #PC2PROTO(k)] + | ins_next + | + |6: // Fill up results with nil. + | add BASE, BASE, #8 + | add RC, RC, #8 + | str TISNIL, [BASE, #-24] + | b <5 + | + |->BC_RETV1_Z: // Non-standard return case. + | add RA, BASE, RA, lsl #3 + |->BC_RETV2_Z: + | tst CARG2, #FRAME_TYPEP + | bne ->vm_return + | // Return from vararg function: relocate BASE down. + | sub BASE, BASE, CARG2 + | ldr PC, [BASE, FRAME_PC] + | b <1 + break; + + case BC_RET0: case BC_RET1: + | // RA = results, RC = nresults+1 + | ldr PC, [BASE, FRAME_PC] + | lsl RC, RC, #3 + | str RCw, SAVE_MULTRES + | ands CARG1, PC, #FRAME_TYPE + | eor CARG2, PC, #FRAME_VARG + | bne ->BC_RETV1_Z + | ldr INSw, [PC, #-4] + if (op == BC_RET1) { + | ldr TMP0, [BASE, RA, lsl #3] + } + | sub CARG4, BASE, #16 + | decode_RA RA, INS + | sub BASE, CARG4, RA, lsl #3 + if (op == BC_RET1) { + | str TMP0, [CARG4], #8 + } + | decode_RB RB, INS + | ldr LFUNC:CARG1, [BASE, FRAME_FUNC] + |5: + | cmp RC, RB, lsl #3 + | blo >6 + | and LFUNC:CARG1, CARG1, #LJ_GCVMASK + | ldr CARG2, LFUNC:CARG1->pc + | ldr KBASE, [CARG2, #PC2PROTO(k)] + | ins_next + | + |6: // Fill up results with nil. + | add RC, RC, #8 + | str TISNIL, [CARG4], #8 + | b <5 + break; + + /* -- Loops and branches ------------------------------------------------ */ + + |.define FOR_IDX, [RA]; .define FOR_TIDX, [RA, #4] + |.define FOR_STOP, [RA, #8]; .define FOR_TSTOP, [RA, #12] + |.define FOR_STEP, [RA, #16]; .define FOR_TSTEP, [RA, #20] + |.define FOR_EXT, [RA, #24]; .define FOR_TEXT, [RA, #28] + + case BC_FORL: + |.if JIT + | hotloop + |.endif + | // Fall through. Assumes BC_IFORL follows. + break; + + case BC_JFORI: + case BC_JFORL: +#if !LJ_HASJIT + break; +#endif + case BC_FORI: + case BC_IFORL: + | // RA = base, RC = target (after end of loop or start of loop) + vk = (op == BC_IFORL || op == BC_JFORL); + | add RA, BASE, RA, lsl #3 + | ldp CARG1, CARG2, FOR_IDX // CARG1 = IDX, CARG2 = STOP + | ldr CARG3, FOR_STEP // CARG3 = STEP + if (op != BC_JFORL) { + | add RC, PC, RC, lsl #2 + | sub RC, RC, #0x20000 + } + | checkint CARG1, >5 + if (!vk) { + | checkint CARG2, ->vmeta_for + | checkint CARG3, ->vmeta_for + | tbnz CARG3w, #31, >4 + | cmp CARG1w, CARG2w + } else { + | adds CARG1w, CARG1w, CARG3w + | bvs >2 + | add TMP0, CARG1, TISNUM + | tbnz CARG3w, #31, >4 + | cmp CARG1w, CARG2w + } + |1: + if (op == BC_FORI) { + | csel PC, RC, PC, gt + } else if (op == BC_JFORI) { + | mov PC, RC + | ldrh RCw, [RC, #-4+OFS_RD] + } else if (op == BC_IFORL) { + | csel PC, RC, PC, le + } + if (vk) { + | str TMP0, FOR_IDX + | str TMP0, FOR_EXT + } else { + | str CARG1, FOR_EXT + } + if (op == BC_JFORI || op == BC_JFORL) { + | ble =>BC_JLOOP + } + |2: + | ins_next + | + |4: // Invert check for negative step. + | cmp CARG2w, CARG1w + | b <1 + | + |5: // FP loop. + | ldp d0, d1, FOR_IDX + | blo ->vmeta_for + if (!vk) { + | checknum CARG2, ->vmeta_for + | checknum CARG3, ->vmeta_for + | str d0, FOR_EXT + } else { + | ldr d2, FOR_STEP + | fadd d0, d0, d2 + } + | tbnz CARG3, #63, >7 + | fcmp d0, d1 + |6: + if (vk) { + | str d0, FOR_IDX + | str d0, FOR_EXT + } + if (op == BC_FORI) { + | csel PC, RC, PC, hi + } else if (op == BC_JFORI) { + | ldrh RCw, [RC, #-4+OFS_RD] + | bls =>BC_JLOOP + } else if (op == BC_IFORL) { + | csel PC, RC, PC, ls + } else { + | bls =>BC_JLOOP + } + | b <2 + | + |7: // Invert check for negative step. + | fcmp d1, d0 + | b <6 + break; + + case BC_ITERL: + |.if JIT + | hotloop + |.endif + | // Fall through. Assumes BC_IITERL follows. + break; + + case BC_JITERL: +#if !LJ_HASJIT + break; +#endif + case BC_IITERL: + | // RA = base, RC = target + | ldr CARG1, [BASE, RA, lsl #3] + | add TMP1, BASE, RA, lsl #3 + | cmp CARG1, TISNIL + | beq >1 // Stop if iterator returned nil. + if (op == BC_JITERL) { + | str CARG1, [TMP1, #-8] + | b =>BC_JLOOP + } else { + | add TMP0, PC, RC, lsl #2 // Otherwise save control var + branch. + | sub PC, TMP0, #0x20000 + | str CARG1, [TMP1, #-8] + } + |1: + | ins_next + break; + + case BC_LOOP: + | // RA = base, RC = target (loop extent) + | // Note: RA/RC is only used by trace recorder to determine scope/extent + | // This opcode does NOT jump, it's only purpose is to detect a hot loop. + |.if JIT + | hotloop + |.endif + | // Fall through. Assumes BC_ILOOP follows. + break; + + case BC_ILOOP: + | // RA = base, RC = target (loop extent) + | ins_next + break; + + case BC_JLOOP: + |.if JIT + | // RA = base (ignored), RC = traceno + | ldr CARG1, [GL, #GL_J(trace)] + | mov CARG2w, #0 // Traces on ARM64 don't store the trace #, so use 0. + | ldr TRACE:RC, [CARG1, RC, lsl #3] + | st_vmstate CARG2w + | ldr RA, TRACE:RC->mcode + | str BASE, GL->jit_base + | str L, GL->tmpbuf.L + | sub sp, sp, #16 // See SPS_FIXED. Avoids sp adjust in every root trace. + | br RA + |.endif + break; + + case BC_JMP: + | // RA = base (only used by trace recorder), RC = target + | add RC, PC, RC, lsl #2 + | sub PC, RC, #0x20000 + | ins_next + break; + + /* -- Function headers -------------------------------------------------- */ + + case BC_FUNCF: + |.if JIT + | hotcall + |.endif + case BC_FUNCV: /* NYI: compiled vararg functions. */ + | // Fall through. Assumes BC_IFUNCF/BC_IFUNCV follow. + break; + + case BC_JFUNCF: +#if !LJ_HASJIT + break; +#endif + case BC_IFUNCF: + | // BASE = new base, RA = BASE+framesize*8, CARG3 = LFUNC, RC = nargs*8 + | ldr CARG1, L->maxstack + | ldrb TMP1w, [PC, #-4+PC2PROTO(numparams)] + | ldr KBASE, [PC, #-4+PC2PROTO(k)] + | cmp RA, CARG1 + | bhi ->vm_growstack_l + |2: + | cmp NARGS8:RC, TMP1, lsl #3 // Check for missing parameters. + | blo >3 + if (op == BC_JFUNCF) { + | decode_RD RC, INS + | b =>BC_JLOOP + } else { + | ins_next + } + | + |3: // Clear missing parameters. + | str TISNIL, [BASE, NARGS8:RC] + | add NARGS8:RC, NARGS8:RC, #8 + | b <2 + break; + + case BC_JFUNCV: +#if !LJ_HASJIT + break; +#endif + | NYI // NYI: compiled vararg functions + break; /* NYI: compiled vararg functions. */ + + case BC_IFUNCV: + | // BASE = new base, RA = BASE+framesize*8, CARG3 = LFUNC, RC = nargs*8 + | ldr CARG1, L->maxstack + | movn TMP0, #~LJ_TFUNC + | add TMP2, BASE, RC + | add LFUNC:CARG3, CARG3, TMP0, lsl #47 + | add RA, RA, RC + | add TMP0, RC, #16+FRAME_VARG + | str LFUNC:CARG3, [TMP2], #8 // Store (tagged) copy of LFUNC. + | ldr KBASE, [PC, #-4+PC2PROTO(k)] + | cmp RA, CARG1 + | str TMP0, [TMP2], #8 // Store delta + FRAME_VARG. + | bhs ->vm_growstack_l + | sub RC, TMP2, #16 + | ldrb TMP1w, [PC, #-4+PC2PROTO(numparams)] + | mov RA, BASE + | mov BASE, TMP2 + | cbz TMP1, >2 + |1: + | cmp RA, RC // Less args than parameters? + | bhs >3 + | ldr TMP0, [RA] + | sub TMP1, TMP1, #1 + | str TISNIL, [RA], #8 // Clear old fixarg slot (help the GC). + | str TMP0, [TMP2], #8 + | cbnz TMP1, <1 + |2: + | ins_next + | + |3: + | sub TMP1, TMP1, #1 + | str TISNIL, [TMP2], #8 + | cbz TMP1, <2 + | b <3 + break; + + case BC_FUNCC: + case BC_FUNCCW: + | // BASE = new base, RA = BASE+framesize*8, CARG3 = CFUNC, RC = nargs*8 + if (op == BC_FUNCC) { + | ldr CARG4, CFUNC:CARG3->f + } else { + | ldr CARG4, GL->wrapf + } + | add CARG2, RA, NARGS8:RC + | ldr CARG1, L->maxstack + | add RC, BASE, NARGS8:RC + | cmp CARG2, CARG1 + | stp BASE, RC, L->base + if (op == BC_FUNCCW) { + | ldr CARG2, CFUNC:CARG3->f + } + | mv_vmstate TMP0w, C + | mov CARG1, L + | bhi ->vm_growstack_c // Need to grow stack. + | st_vmstate TMP0w + | blr CARG4 // (lua_State *L [, lua_CFunction f]) + | // Returns nresults. + | ldp BASE, TMP1, L->base + | str L, GL->cur_L + | sbfiz RC, CRET1, #3, #32 + | st_vmstate ST_INTERP + | ldr PC, [BASE, FRAME_PC] + | sub RA, TMP1, RC // RA = L->top - nresults*8 + | b ->vm_returnc + break; + + /* ---------------------------------------------------------------------- */ + + default: + fprintf(stderr, "Error: undefined opcode BC_%s\n", bc_names[op]); + exit(2); + break; + } +} + +static int build_backend(BuildCtx *ctx) +{ + int op; + + dasm_growpc(Dst, BC__MAX); + + build_subroutines(ctx); + + |.code_op + for (op = 0; op < BC__MAX; op++) + build_ins(ctx, (BCOp)op, op); + + return BC__MAX; +} + +/* Emit pseudo frame-info for all assembler functions. */ +static void emit_asm_debug(BuildCtx *ctx) +{ + int fcofs = (int)((uint8_t *)ctx->glob[GLOB_vm_ffi_call] - ctx->code); + int i; + switch (ctx->mode) { + case BUILD_elfasm: + fprintf(ctx->fp, "\t.section .debug_frame,\"\",%%progbits\n"); + fprintf(ctx->fp, + ".Lframe0:\n" + "\t.long .LECIE0-.LSCIE0\n" + ".LSCIE0:\n" + "\t.long 0xffffffff\n" + "\t.byte 0x1\n" + "\t.string \"\"\n" + "\t.uleb128 0x1\n" + "\t.sleb128 -8\n" + "\t.byte 30\n" /* Return address is in lr. */ + "\t.byte 0xc\n\t.uleb128 29\n\t.uleb128 16\n" /* def_cfa fp 16 */ + "\t.align 3\n" + ".LECIE0:\n\n"); + fprintf(ctx->fp, + ".LSFDE0:\n" + "\t.long .LEFDE0-.LASFDE0\n" + ".LASFDE0:\n" + "\t.long .Lframe0\n" + "\t.quad .Lbegin\n" + "\t.quad %d\n" + "\t.byte 0x9e\n\t.uleb128 1\n" /* offset lr */ + "\t.byte 0x9d\n\t.uleb128 2\n", /* offset fp */ + fcofs); + for (i = 19; i <= 28; i++) /* offset x19-x28 */ + fprintf(ctx->fp, "\t.byte 0x%x\n\t.uleb128 %d\n", 0x80+i, i+(3-19)); + for (i = 8; i <= 15; i++) /* offset d8-d15 */ + fprintf(ctx->fp, "\t.byte 5\n\t.uleb128 0x%x\n\t.uleb128 %d\n", + 64+i, i+(3+(28-19+1)-8)); + fprintf(ctx->fp, + "\t.align 3\n" + ".LEFDE0:\n\n"); +#if LJ_HASFFI + fprintf(ctx->fp, + ".LSFDE1:\n" + "\t.long .LEFDE1-.LASFDE1\n" + ".LASFDE1:\n" + "\t.long .Lframe0\n" + "\t.quad lj_vm_ffi_call\n" + "\t.quad %d\n" + "\t.byte 0x9e\n\t.uleb128 1\n" /* offset lr */ + "\t.byte 0x9d\n\t.uleb128 2\n" /* offset fp */ + "\t.byte 0x93\n\t.uleb128 3\n" /* offset x19 */ + "\t.byte 0x94\n\t.uleb128 4\n" /* offset x20 */ + "\t.align 3\n" + ".LEFDE1:\n\n", (int)ctx->codesz - fcofs); +#endif +#if !LJ_NO_UNWIND + fprintf(ctx->fp, "\t.section .eh_frame,\"a\",%%progbits\n"); + fprintf(ctx->fp, + ".Lframe1:\n" + "\t.long .LECIE1-.LSCIE1\n" + ".LSCIE1:\n" + "\t.long 0\n" + "\t.byte 0x1\n" + "\t.string \"zPR\"\n" + "\t.uleb128 0x1\n" + "\t.sleb128 -8\n" + "\t.byte 30\n" /* Return address is in lr. */ + "\t.uleb128 6\n" /* augmentation length */ + "\t.byte 0x1b\n" /* pcrel|sdata4 */ + "\t.long lj_err_unwind_dwarf-.\n" + "\t.byte 0x1b\n" /* pcrel|sdata4 */ + "\t.byte 0xc\n\t.uleb128 29\n\t.uleb128 16\n" /* def_cfa fp 16 */ + "\t.align 3\n" + ".LECIE1:\n\n"); + fprintf(ctx->fp, + ".LSFDE2:\n" + "\t.long .LEFDE2-.LASFDE2\n" + ".LASFDE2:\n" + "\t.long .LASFDE2-.Lframe1\n" + "\t.long .Lbegin-.\n" + "\t.long %d\n" + "\t.uleb128 0\n" /* augmentation length */ + "\t.byte 0x9e\n\t.uleb128 1\n" /* offset lr */ + "\t.byte 0x9d\n\t.uleb128 2\n", /* offset fp */ + fcofs); + for (i = 19; i <= 28; i++) /* offset x19-x28 */ + fprintf(ctx->fp, "\t.byte 0x%x\n\t.uleb128 %d\n", 0x80+i, i+(3-19)); + for (i = 8; i <= 15; i++) /* offset d8-d15 */ + fprintf(ctx->fp, "\t.byte 5\n\t.uleb128 0x%x\n\t.uleb128 %d\n", + 64+i, i+(3+(28-19+1)-8)); + fprintf(ctx->fp, + "\t.align 3\n" + ".LEFDE2:\n\n"); +#if LJ_HASFFI + fprintf(ctx->fp, + ".Lframe2:\n" + "\t.long .LECIE2-.LSCIE2\n" + ".LSCIE2:\n" + "\t.long 0\n" + "\t.byte 0x1\n" + "\t.string \"zR\"\n" + "\t.uleb128 0x1\n" + "\t.sleb128 -8\n" + "\t.byte 30\n" /* Return address is in lr. */ + "\t.uleb128 1\n" /* augmentation length */ + "\t.byte 0x1b\n" /* pcrel|sdata4 */ + "\t.byte 0xc\n\t.uleb128 29\n\t.uleb128 16\n" /* def_cfa fp 16 */ + "\t.align 3\n" + ".LECIE2:\n\n"); + fprintf(ctx->fp, + ".LSFDE3:\n" + "\t.long .LEFDE3-.LASFDE3\n" + ".LASFDE3:\n" + "\t.long .LASFDE3-.Lframe2\n" + "\t.long lj_vm_ffi_call-.\n" + "\t.long %d\n" + "\t.uleb128 0\n" /* augmentation length */ + "\t.byte 0x9e\n\t.uleb128 1\n" /* offset lr */ + "\t.byte 0x9d\n\t.uleb128 2\n" /* offset fp */ + "\t.byte 0x93\n\t.uleb128 3\n" /* offset x19 */ + "\t.byte 0x94\n\t.uleb128 4\n" /* offset x20 */ + "\t.align 3\n" + ".LEFDE3:\n\n", (int)ctx->codesz - fcofs); +#endif +#endif + break; +#if !LJ_NO_UNWIND + case BUILD_machasm: { +#if LJ_HASFFI + int fcsize = 0; +#endif + int j; + fprintf(ctx->fp, "\t.section __TEXT,__eh_frame,coalesced,no_toc+strip_static_syms+live_support\n"); + fprintf(ctx->fp, + "EH_frame1:\n" + "\t.set L$set$x,LECIEX-LSCIEX\n" + "\t.long L$set$x\n" + "LSCIEX:\n" + "\t.long 0\n" + "\t.byte 0x1\n" + "\t.ascii \"zPR\\0\"\n" + "\t.uleb128 0x1\n" + "\t.sleb128 -8\n" + "\t.byte 30\n" /* Return address is in lr. */ + "\t.uleb128 6\n" /* augmentation length */ + "\t.byte 0x9b\n" /* indirect|pcrel|sdata4 */ + "\t.long _lj_err_unwind_dwarf@GOT-.\n" + "\t.byte 0x1b\n" /* pcrel|sdata4 */ + "\t.byte 0xc\n\t.uleb128 29\n\t.uleb128 16\n" /* def_cfa fp 16 */ + "\t.align 3\n" + "LECIEX:\n\n"); + for (j = 0; j < ctx->nsym; j++) { + const char *name = ctx->sym[j].name; + int32_t size = ctx->sym[j+1].ofs - ctx->sym[j].ofs; + if (size == 0) continue; +#if LJ_HASFFI + if (!strcmp(name, "_lj_vm_ffi_call")) { fcsize = size; continue; } +#endif + fprintf(ctx->fp, + "LSFDE%d:\n" + "\t.set L$set$%d,LEFDE%d-LASFDE%d\n" + "\t.long L$set$%d\n" + "LASFDE%d:\n" + "\t.long LASFDE%d-EH_frame1\n" + "\t.long %s-.\n" + "\t.long %d\n" + "\t.uleb128 0\n" /* augmentation length */ + "\t.byte 0x9e\n\t.uleb128 1\n" /* offset lr */ + "\t.byte 0x9d\n\t.uleb128 2\n", /* offset fp */ + j, j, j, j, j, j, j, name, size); + for (i = 19; i <= 28; i++) /* offset x19-x28 */ + fprintf(ctx->fp, "\t.byte 0x%x\n\t.uleb128 %d\n", 0x80+i, i+(3-19)); + for (i = 8; i <= 15; i++) /* offset d8-d15 */ + fprintf(ctx->fp, "\t.byte 5\n\t.uleb128 0x%x\n\t.uleb128 %d\n", + 64+i, i+(3+(28-19+1)-8)); + fprintf(ctx->fp, + "\t.align 3\n" + "LEFDE%d:\n\n", j); + } +#if LJ_HASFFI + if (fcsize) { + fprintf(ctx->fp, + "EH_frame2:\n" + "\t.set L$set$y,LECIEY-LSCIEY\n" + "\t.long L$set$y\n" + "LSCIEY:\n" + "\t.long 0\n" + "\t.byte 0x1\n" + "\t.ascii \"zR\\0\"\n" + "\t.uleb128 0x1\n" + "\t.sleb128 -8\n" + "\t.byte 30\n" /* Return address is in lr. */ + "\t.uleb128 1\n" /* augmentation length */ + "\t.byte 0x1b\n" /* pcrel|sdata4 */ + "\t.byte 0xc\n\t.uleb128 29\n\t.uleb128 16\n" /* def_cfa fp 16 */ + "\t.align 3\n" + "LECIEY:\n\n"); + fprintf(ctx->fp, + "LSFDEY:\n" + "\t.set L$set$yy,LEFDEY-LASFDEY\n" + "\t.long L$set$yy\n" + "LASFDEY:\n" + "\t.long LASFDEY-EH_frame2\n" + "\t.long _lj_vm_ffi_call-.\n" + "\t.long %d\n" + "\t.uleb128 0\n" /* augmentation length */ + "\t.byte 0x9e\n\t.uleb128 1\n" /* offset lr */ + "\t.byte 0x9d\n\t.uleb128 2\n" /* offset fp */ + "\t.byte 0x93\n\t.uleb128 3\n" /* offset x19 */ + "\t.byte 0x94\n\t.uleb128 4\n" /* offset x20 */ + "\t.align 3\n" + "LEFDEY:\n\n", fcsize); + } +#endif + fprintf(ctx->fp, ".subsections_via_symbols\n"); + } + break; +#endif + default: + break; + } +} + diff --git a/fluent-bit/lib/luajit-3065c9/src/vm_mips.dasc b/fluent-bit/lib/luajit-3065c9/src/vm_mips.dasc new file mode 100644 index 00000000..34645bf1 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/vm_mips.dasc @@ -0,0 +1,5392 @@ +|// Low-level VM code for MIPS CPUs. +|// Bytecode interpreter, fast functions and helper functions. +|// Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +|// +|// MIPS soft-float support contributed by Djordje Kovacevic and +|// Stefan Pejic from RT-RK.com, sponsored by Cisco Systems, Inc. +| +|.arch mips +|.section code_op, code_sub +| +|.actionlist build_actionlist +|.globals GLOB_ +|.globalnames globnames +|.externnames extnames +| +|// Note: The ragged indentation of the instructions is intentional. +|// The starting columns indicate data dependencies. +| +|//----------------------------------------------------------------------- +| +|// Fixed register assignments for the interpreter. +|// Don't use: r0 = 0, r26/r27 = reserved, r28 = gp, r29 = sp, r31 = ra +| +|.macro .FPU, a, b +|.if FPU +| a, b +|.endif +|.endmacro +| +|// The following must be C callee-save (but BASE is often refetched). +|.define BASE, r16 // Base of current Lua stack frame. +|.define KBASE, r17 // Constants of current Lua function. +|.define PC, r18 // Next PC. +|.define DISPATCH, r19 // Opcode dispatch table. +|.define LREG, r20 // Register holding lua_State (also in SAVE_L). +|.define MULTRES, r21 // Size of multi-result: (nresults+1)*8. +| +|.define JGL, r30 // On-trace: global_State + 32768. +| +|// Constants for type-comparisons, stores and conversions. C callee-save. +|.define TISNUM, r22 +|.define TISNIL, r30 +|.if FPU +|.define TOBIT, f30 // 2^52 + 2^51. +|.endif +| +|// The following temporaries are not saved across C calls, except for RA. +|.define RA, r23 // Callee-save. +|.define RB, r8 +|.define RC, r9 +|.define RD, r10 +|.define INS, r11 +| +|.define AT, r1 // Assembler temporary. +|.define TMP0, r12 +|.define TMP1, r13 +|.define TMP2, r14 +|.define TMP3, r15 +| +|// MIPS o32 calling convention. +|.define CFUNCADDR, r25 +|.define CARG1, r4 +|.define CARG2, r5 +|.define CARG3, r6 +|.define CARG4, r7 +| +|.define CRET1, r2 +|.define CRET2, r3 +| +|.if ENDIAN_LE +|.define SFRETLO, CRET1 +|.define SFRETHI, CRET2 +|.define SFARG1LO, CARG1 +|.define SFARG1HI, CARG2 +|.define SFARG2LO, CARG3 +|.define SFARG2HI, CARG4 +|.else +|.define SFRETLO, CRET2 +|.define SFRETHI, CRET1 +|.define SFARG1LO, CARG2 +|.define SFARG1HI, CARG1 +|.define SFARG2LO, CARG4 +|.define SFARG2HI, CARG3 +|.endif +| +|.if FPU +|.define FARG1, f12 +|.define FARG2, f14 +| +|.define FRET1, f0 +|.define FRET2, f2 +|.endif +| +|// Stack layout while in interpreter. Must match with lj_frame.h. +|.if FPU // MIPS32 hard-float. +| +|.define CFRAME_SPACE, 112 // Delta for sp. +| +|.define SAVE_ERRF, 124(sp) // 32 bit C frame info. +|.define SAVE_NRES, 120(sp) +|.define SAVE_CFRAME, 116(sp) +|.define SAVE_L, 112(sp) +|//----- 8 byte aligned, ^^^^ 16 byte register save area, owned by interpreter. +|.define SAVE_GPR_, 72 // .. 72+10*4: 32 bit GPR saves. +|.define SAVE_FPR_, 24 // .. 24+6*8: 64 bit FPR saves. +| +|.else // MIPS32 soft-float +| +|.define CFRAME_SPACE, 64 // Delta for sp. +| +|.define SAVE_ERRF, 76(sp) // 32 bit C frame info. +|.define SAVE_NRES, 72(sp) +|.define SAVE_CFRAME, 68(sp) +|.define SAVE_L, 64(sp) +|//----- 8 byte aligned, ^^^^ 16 byte register save area, owned by interpreter. +|.define SAVE_GPR_, 24 // .. 24+10*4: 32 bit GPR saves. +| +|.endif +| +|.define SAVE_PC, 20(sp) +|.define ARG5, 16(sp) +|.define CSAVE_4, 12(sp) +|.define CSAVE_3, 8(sp) +|.define CSAVE_2, 4(sp) +|.define CSAVE_1, 0(sp) +|//----- 8 byte aligned, ^^^^ 16 byte register save area, owned by callee. +| +|.define ARG5_OFS, 16 +|.define SAVE_MULTRES, ARG5 +| +|//----------------------------------------------------------------------- +| +|.macro saveregs +| addiu sp, sp, -CFRAME_SPACE +| sw ra, SAVE_GPR_+9*4(sp) +| sw r30, SAVE_GPR_+8*4(sp) +| .FPU sdc1 f30, SAVE_FPR_+5*8(sp) +| sw r23, SAVE_GPR_+7*4(sp) +| sw r22, SAVE_GPR_+6*4(sp) +| .FPU sdc1 f28, SAVE_FPR_+4*8(sp) +| sw r21, SAVE_GPR_+5*4(sp) +| sw r20, SAVE_GPR_+4*4(sp) +| .FPU sdc1 f26, SAVE_FPR_+3*8(sp) +| sw r19, SAVE_GPR_+3*4(sp) +| sw r18, SAVE_GPR_+2*4(sp) +| .FPU sdc1 f24, SAVE_FPR_+2*8(sp) +| sw r17, SAVE_GPR_+1*4(sp) +| sw r16, SAVE_GPR_+0*4(sp) +| .FPU sdc1 f22, SAVE_FPR_+1*8(sp) +| .FPU sdc1 f20, SAVE_FPR_+0*8(sp) +|.endmacro +| +|.macro restoreregs_ret +| lw ra, SAVE_GPR_+9*4(sp) +| lw r30, SAVE_GPR_+8*4(sp) +| .FPU ldc1 f30, SAVE_FPR_+5*8(sp) +| lw r23, SAVE_GPR_+7*4(sp) +| lw r22, SAVE_GPR_+6*4(sp) +| .FPU ldc1 f28, SAVE_FPR_+4*8(sp) +| lw r21, SAVE_GPR_+5*4(sp) +| lw r20, SAVE_GPR_+4*4(sp) +| .FPU ldc1 f26, SAVE_FPR_+3*8(sp) +| lw r19, SAVE_GPR_+3*4(sp) +| lw r18, SAVE_GPR_+2*4(sp) +| .FPU ldc1 f24, SAVE_FPR_+2*8(sp) +| lw r17, SAVE_GPR_+1*4(sp) +| lw r16, SAVE_GPR_+0*4(sp) +| .FPU ldc1 f22, SAVE_FPR_+1*8(sp) +| .FPU ldc1 f20, SAVE_FPR_+0*8(sp) +| jr ra +| addiu sp, sp, CFRAME_SPACE +|.endmacro +| +|// Type definitions. Some of these are only used for documentation. +|.type L, lua_State, LREG +|.type GL, global_State +|.type TVALUE, TValue +|.type GCOBJ, GCobj +|.type STR, GCstr +|.type TAB, GCtab +|.type LFUNC, GCfuncL +|.type CFUNC, GCfuncC +|.type PROTO, GCproto +|.type UPVAL, GCupval +|.type NODE, Node +|.type NARGS8, int +|.type TRACE, GCtrace +|.type SBUF, SBuf +| +|//----------------------------------------------------------------------- +| +|// Trap for not-yet-implemented parts. +|.macro NYI; .long 0xec1cf0f0; .endmacro +| +|// Macros to mark delay slots. +|.macro ., a; a; .endmacro +|.macro ., a,b; a,b; .endmacro +|.macro ., a,b,c; a,b,c; .endmacro +| +|//----------------------------------------------------------------------- +| +|// Endian-specific defines. +|.if ENDIAN_LE +|.define FRAME_PC, -4 +|.define FRAME_FUNC, -8 +|.define HI, 4 +|.define LO, 0 +|.define OFS_RD, 2 +|.define OFS_RA, 1 +|.define OFS_OP, 0 +|.else +|.define FRAME_PC, -8 +|.define FRAME_FUNC, -4 +|.define HI, 0 +|.define LO, 4 +|.define OFS_RD, 0 +|.define OFS_RA, 2 +|.define OFS_OP, 3 +|.endif +| +|// Instruction decode. +|.macro decode_OP1, dst, ins; andi dst, ins, 0xff; .endmacro +|.macro decode_OP4a, dst, ins; andi dst, ins, 0xff; .endmacro +|.macro decode_OP4b, dst; sll dst, dst, 2; .endmacro +|.macro decode_RC4a, dst, ins; srl dst, ins, 14; .endmacro +|.macro decode_RC4b, dst; andi dst, dst, 0x3fc; .endmacro +|.macro decode_RD4b, dst; sll dst, dst, 2; .endmacro +|.macro decode_RA8a, dst, ins; srl dst, ins, 5; .endmacro +|.macro decode_RA8b, dst; andi dst, dst, 0x7f8; .endmacro +|.macro decode_RB8a, dst, ins; srl dst, ins, 21; .endmacro +|.macro decode_RB8b, dst; andi dst, dst, 0x7f8; .endmacro +|.macro decode_RD8a, dst, ins; srl dst, ins, 16; .endmacro +|.macro decode_RD8b, dst; sll dst, dst, 3; .endmacro +|.macro decode_RDtoRC8, dst, src; andi dst, src, 0x7f8; .endmacro +| +|// Instruction fetch. +|.macro ins_NEXT1 +| lw INS, 0(PC) +| addiu PC, PC, 4 +|.endmacro +|// Instruction decode+dispatch. +|.macro ins_NEXT2 +| decode_OP4a TMP1, INS +| decode_OP4b TMP1 +| addu TMP0, DISPATCH, TMP1 +| decode_RD8a RD, INS +| lw AT, 0(TMP0) +| decode_RA8a RA, INS +| decode_RD8b RD +| jr AT +| decode_RA8b RA +|.endmacro +|.macro ins_NEXT +| ins_NEXT1 +| ins_NEXT2 +|.endmacro +| +|// Instruction footer. +|.if 1 +| // Replicated dispatch. Less unpredictable branches, but higher I-Cache use. +| .define ins_next, ins_NEXT +| .define ins_next_, ins_NEXT +| .define ins_next1, ins_NEXT1 +| .define ins_next2, ins_NEXT2 +|.else +| // Common dispatch. Lower I-Cache use, only one (very) unpredictable branch. +| // Affects only certain kinds of benchmarks (and only with -j off). +| .macro ins_next +| b ->ins_next +| .endmacro +| .macro ins_next1 +| .endmacro +| .macro ins_next2 +| b ->ins_next +| .endmacro +| .macro ins_next_ +| ->ins_next: +| ins_NEXT +| .endmacro +|.endif +| +|// Call decode and dispatch. +|.macro ins_callt +| // BASE = new base, RB = LFUNC/CFUNC, RC = nargs*8, FRAME_PC(BASE) = PC +| lw PC, LFUNC:RB->pc +| lw INS, 0(PC) +| addiu PC, PC, 4 +| decode_OP4a TMP1, INS +| decode_RA8a RA, INS +| decode_OP4b TMP1 +| decode_RA8b RA +| addu TMP0, DISPATCH, TMP1 +| lw TMP0, 0(TMP0) +| jr TMP0 +| addu RA, RA, BASE +|.endmacro +| +|.macro ins_call +| // BASE = new base, RB = LFUNC/CFUNC, RC = nargs*8, PC = caller PC +| sw PC, FRAME_PC(BASE) +| ins_callt +|.endmacro +| +|//----------------------------------------------------------------------- +| +|.macro branch_RD +| srl TMP0, RD, 1 +| lui AT, (-(BCBIAS_J*4 >> 16) & 65535) +| addu TMP0, TMP0, AT +| addu PC, PC, TMP0 +|.endmacro +| +|// Assumes DISPATCH is relative to GL. +#define DISPATCH_GL(field) (GG_DISP2G + (int)offsetof(global_State, field)) +#define DISPATCH_J(field) (GG_DISP2J + (int)offsetof(jit_State, field)) +#define GG_DISP2GOT (GG_OFS(got) - GG_OFS(dispatch)) +#define DISPATCH_GOT(name) (GG_DISP2GOT + 4*LJ_GOT_##name) +| +#define PC2PROTO(field) ((int)offsetof(GCproto, field)-(int)sizeof(GCproto)) +| +|.macro load_got, func +| lw CFUNCADDR, DISPATCH_GOT(func)(DISPATCH) +|.endmacro +|// Much faster. Sadly, there's no easy way to force the required code layout. +|// .macro call_intern, func; bal extern func; .endmacro +|.macro call_intern, func; jalr CFUNCADDR; .endmacro +|.macro call_extern; jalr CFUNCADDR; .endmacro +|.macro jmp_extern; jr CFUNCADDR; .endmacro +| +|.macro hotcheck, delta, target +| srl TMP1, PC, 1 +| andi TMP1, TMP1, 126 +| addu TMP1, TMP1, DISPATCH +| lhu TMP2, GG_DISP2HOT(TMP1) +| addiu TMP2, TMP2, -delta +| bltz TMP2, target +|. sh TMP2, GG_DISP2HOT(TMP1) +|.endmacro +| +|.macro hotloop +| hotcheck HOTCOUNT_LOOP, ->vm_hotloop +|.endmacro +| +|.macro hotcall +| hotcheck HOTCOUNT_CALL, ->vm_hotcall +|.endmacro +| +|// Set current VM state. Uses TMP0. +|.macro li_vmstate, st; li TMP0, ~LJ_VMST_..st; .endmacro +|.macro st_vmstate; sw TMP0, DISPATCH_GL(vmstate)(DISPATCH); .endmacro +| +|// Move table write barrier back. Overwrites mark and tmp. +|.macro barrierback, tab, mark, tmp, target +| lw tmp, DISPATCH_GL(gc.grayagain)(DISPATCH) +| andi mark, mark, ~LJ_GC_BLACK & 255 // black2gray(tab) +| sw tab, DISPATCH_GL(gc.grayagain)(DISPATCH) +| sb mark, tab->marked +| b target +|. sw tmp, tab->gclist +|.endmacro +| +|//----------------------------------------------------------------------- + +/* Generate subroutines used by opcodes and other parts of the VM. */ +/* The .code_sub section should be last to help static branch prediction. */ +static void build_subroutines(BuildCtx *ctx) +{ + |.code_sub + | + |//----------------------------------------------------------------------- + |//-- Return handling ---------------------------------------------------- + |//----------------------------------------------------------------------- + | + |->vm_returnp: + | // See vm_return. Also: TMP2 = previous base. + | andi AT, PC, FRAME_P + | beqz AT, ->cont_dispatch + |. li TMP1, LJ_TTRUE + | + | // Return from pcall or xpcall fast func. + | lw PC, FRAME_PC(TMP2) // Fetch PC of previous frame. + | move BASE, TMP2 // Restore caller base. + | // Prepending may overwrite the pcall frame, so do it at the end. + | sw TMP1, FRAME_PC(RA) // Prepend true to results. + | addiu RA, RA, -8 + | + |->vm_returnc: + | addiu RD, RD, 8 // RD = (nresults+1)*8. + | andi TMP0, PC, FRAME_TYPE + | beqz RD, ->vm_unwind_c_eh + |. li CRET1, LUA_YIELD + | beqz TMP0, ->BC_RET_Z // Handle regular return to Lua. + |. move MULTRES, RD + | + |->vm_return: + | // BASE = base, RA = resultptr, RD/MULTRES = (nresults+1)*8, PC = return + | // TMP0 = PC & FRAME_TYPE + | li TMP2, -8 + | xori AT, TMP0, FRAME_C + | and TMP2, PC, TMP2 + | bnez AT, ->vm_returnp + |. subu TMP2, BASE, TMP2 // TMP2 = previous base. + | + | addiu TMP1, RD, -8 + | sw TMP2, L->base + | li_vmstate C + | lw TMP2, SAVE_NRES + | addiu BASE, BASE, -8 + | st_vmstate + | beqz TMP1, >2 + |. sll TMP2, TMP2, 3 + |1: + | addiu TMP1, TMP1, -8 + | lw SFRETHI, HI(RA) + | lw SFRETLO, LO(RA) + | addiu RA, RA, 8 + | sw SFRETHI, HI(BASE) + | sw SFRETLO, LO(BASE) + | bnez TMP1, <1 + |. addiu BASE, BASE, 8 + | + |2: + | bne TMP2, RD, >6 + |3: + |. sw BASE, L->top // Store new top. + | + |->vm_leave_cp: + | lw TMP0, SAVE_CFRAME // Restore previous C frame. + | move CRET1, r0 // Ok return status for vm_pcall. + | sw TMP0, L->cframe + | + |->vm_leave_unw: + | restoreregs_ret + | + |6: + | lw TMP1, L->maxstack + | slt AT, TMP2, RD + | bnez AT, >7 // Less results wanted? + | // More results wanted. Check stack size and fill up results with nil. + |. slt AT, BASE, TMP1 + | beqz AT, >8 + |. nop + | sw TISNIL, HI(BASE) + | addiu RD, RD, 8 + | b <2 + |. addiu BASE, BASE, 8 + | + |7: // Less results wanted. + | subu TMP0, RD, TMP2 + | subu TMP0, BASE, TMP0 // Either keep top or shrink it. + | b <3 + |. movn BASE, TMP0, TMP2 // LUA_MULTRET+1 case? + | + |8: // Corner case: need to grow stack for filling up results. + | // This can happen if: + | // - A C function grows the stack (a lot). + | // - The GC shrinks the stack in between. + | // - A return back from a lua_call() with (high) nresults adjustment. + | load_got lj_state_growstack + | move MULTRES, RD + | srl CARG2, TMP2, 3 + | call_intern lj_state_growstack // (lua_State *L, int n) + |. move CARG1, L + | lw TMP2, SAVE_NRES + | lw BASE, L->top // Need the (realloced) L->top in BASE. + | move RD, MULTRES + | b <2 + |. sll TMP2, TMP2, 3 + | + |->vm_unwind_c: // Unwind C stack, return from vm_pcall. + | // (void *cframe, int errcode) + | move sp, CARG1 + | move CRET1, CARG2 + |->vm_unwind_c_eh: // Landing pad for external unwinder. + | lw L, SAVE_L + | li TMP0, ~LJ_VMST_C + | lw GL:TMP1, L->glref + | b ->vm_leave_unw + |. sw TMP0, GL:TMP1->vmstate + | + |->vm_unwind_ff: // Unwind C stack, return from ff pcall. + | // (void *cframe) + | li AT, -4 + | and sp, CARG1, AT + |->vm_unwind_ff_eh: // Landing pad for external unwinder. + | lw L, SAVE_L + | .FPU lui TMP3, 0x59c0 // TOBIT = 2^52 + 2^51 (float). + | li TISNUM, LJ_TISNUM // Setup type comparison constants. + | li TISNIL, LJ_TNIL + | lw BASE, L->base + | lw DISPATCH, L->glref // Setup pointer to dispatch table. + | .FPU mtc1 TMP3, TOBIT + | li TMP1, LJ_TFALSE + | li_vmstate INTERP + | lw PC, FRAME_PC(BASE) // Fetch PC of previous frame. + | .FPU cvt.d.s TOBIT, TOBIT + | addiu RA, BASE, -8 // Results start at BASE-8. + | addiu DISPATCH, DISPATCH, GG_G2DISP + | sw TMP1, HI(RA) // Prepend false to error message. + | st_vmstate + | b ->vm_returnc + |. li RD, 16 // 2 results: false + error message. + | + |->vm_unwind_stub: // Jump to exit stub from unwinder. + | jr CARG1 + |. move ra, CARG2 + | + |//----------------------------------------------------------------------- + |//-- Grow stack for calls ----------------------------------------------- + |//----------------------------------------------------------------------- + | + |->vm_growstack_c: // Grow stack for C function. + | b >2 + |. li CARG2, LUA_MINSTACK + | + |->vm_growstack_l: // Grow stack for Lua function. + | // BASE = new base, RA = BASE+framesize*8, RC = nargs*8, PC = first PC + | addu RC, BASE, RC + | subu RA, RA, BASE + | sw BASE, L->base + | addiu PC, PC, 4 // Must point after first instruction. + | sw RC, L->top + | srl CARG2, RA, 3 + |2: + | // L->base = new base, L->top = top + | load_got lj_state_growstack + | sw PC, SAVE_PC + | call_intern lj_state_growstack // (lua_State *L, int n) + |. move CARG1, L + | lw BASE, L->base + | lw RC, L->top + | lw LFUNC:RB, FRAME_FUNC(BASE) + | subu RC, RC, BASE + | // BASE = new base, RB = LFUNC/CFUNC, RC = nargs*8, FRAME_PC(BASE) = PC + | ins_callt // Just retry the call. + | + |//----------------------------------------------------------------------- + |//-- Entry points into the assembler VM --------------------------------- + |//----------------------------------------------------------------------- + | + |->vm_resume: // Setup C frame and resume thread. + | // (lua_State *L, TValue *base, int nres1 = 0, ptrdiff_t ef = 0) + | saveregs + | move L, CARG1 + | lw DISPATCH, L->glref // Setup pointer to dispatch table. + | move BASE, CARG2 + | lbu TMP1, L->status + | sw L, SAVE_L + | li PC, FRAME_CP + | addiu TMP0, sp, CFRAME_RESUME + | addiu DISPATCH, DISPATCH, GG_G2DISP + | sw r0, SAVE_NRES + | sw r0, SAVE_ERRF + | sw CARG1, SAVE_PC // Any value outside of bytecode is ok. + | sw r0, SAVE_CFRAME + | beqz TMP1, >3 + |. sw TMP0, L->cframe + | + | // Resume after yield (like a return). + | sw L, DISPATCH_GL(cur_L)(DISPATCH) + | move RA, BASE + | lw BASE, L->base + | li TISNUM, LJ_TISNUM // Setup type comparison constants. + | lw TMP1, L->top + | lw PC, FRAME_PC(BASE) + | .FPU lui TMP3, 0x59c0 // TOBIT = 2^52 + 2^51 (float). + | subu RD, TMP1, BASE + | .FPU mtc1 TMP3, TOBIT + | sb r0, L->status + | .FPU cvt.d.s TOBIT, TOBIT + | li_vmstate INTERP + | addiu RD, RD, 8 + | st_vmstate + | move MULTRES, RD + | andi TMP0, PC, FRAME_TYPE + | beqz TMP0, ->BC_RET_Z + |. li TISNIL, LJ_TNIL + | b ->vm_return + |. nop + | + |->vm_pcall: // Setup protected C frame and enter VM. + | // (lua_State *L, TValue *base, int nres1, ptrdiff_t ef) + | saveregs + | sw CARG4, SAVE_ERRF + | b >1 + |. li PC, FRAME_CP + | + |->vm_call: // Setup C frame and enter VM. + | // (lua_State *L, TValue *base, int nres1) + | saveregs + | li PC, FRAME_C + | + |1: // Entry point for vm_pcall above (PC = ftype). + | lw TMP1, L:CARG1->cframe + | move L, CARG1 + | sw CARG3, SAVE_NRES + | lw DISPATCH, L->glref // Setup pointer to dispatch table. + | sw CARG1, SAVE_L + | move BASE, CARG2 + | addiu DISPATCH, DISPATCH, GG_G2DISP + | sw CARG1, SAVE_PC // Any value outside of bytecode is ok. + | sw TMP1, SAVE_CFRAME + | sw sp, L->cframe // Add our C frame to cframe chain. + | + |3: // Entry point for vm_cpcall/vm_resume (BASE = base, PC = ftype). + | sw L, DISPATCH_GL(cur_L)(DISPATCH) + | lw TMP2, L->base // TMP2 = old base (used in vmeta_call). + | li TISNUM, LJ_TISNUM // Setup type comparison constants. + | .FPU lui TMP3, 0x59c0 // TOBIT = 2^52 + 2^51 (float). + | lw TMP1, L->top + | .FPU mtc1 TMP3, TOBIT + | addu PC, PC, BASE + | subu NARGS8:RC, TMP1, BASE + | subu PC, PC, TMP2 // PC = frame delta + frame type + | .FPU cvt.d.s TOBIT, TOBIT + | li_vmstate INTERP + | li TISNIL, LJ_TNIL + | st_vmstate + | + |->vm_call_dispatch: + | // TMP2 = old base, BASE = new base, RC = nargs*8, PC = caller PC + | lw TMP0, FRAME_PC(BASE) + | li AT, LJ_TFUNC + | bne TMP0, AT, ->vmeta_call + |. lw LFUNC:RB, FRAME_FUNC(BASE) + | + |->vm_call_dispatch_f: + | ins_call + | // BASE = new base, RB = func, RC = nargs*8, PC = caller PC + | + |->vm_cpcall: // Setup protected C frame, call C. + | // (lua_State *L, lua_CFunction func, void *ud, lua_CPFunction cp) + | saveregs + | move L, CARG1 + | lw TMP0, L:CARG1->stack + | sw CARG1, SAVE_L + | lw TMP1, L->top + | lw DISPATCH, L->glref // Setup pointer to dispatch table. + | sw CARG1, SAVE_PC // Any value outside of bytecode is ok. + | subu TMP0, TMP0, TMP1 // Compute -savestack(L, L->top). + | lw TMP1, L->cframe + | addiu DISPATCH, DISPATCH, GG_G2DISP + | sw TMP0, SAVE_NRES // Neg. delta means cframe w/o frame. + | sw r0, SAVE_ERRF // No error function. + | sw TMP1, SAVE_CFRAME + | sw sp, L->cframe // Add our C frame to cframe chain. + | sw L, DISPATCH_GL(cur_L)(DISPATCH) + | jalr CARG4 // (lua_State *L, lua_CFunction func, void *ud) + |. move CFUNCADDR, CARG4 + | move BASE, CRET1 + | bnez CRET1, <3 // Else continue with the call. + |. li PC, FRAME_CP + | b ->vm_leave_cp // No base? Just remove C frame. + |. nop + | + |//----------------------------------------------------------------------- + |//-- Metamethod handling ------------------------------------------------ + |//----------------------------------------------------------------------- + | + |// The lj_meta_* functions (except for lj_meta_cat) don't reallocate the + |// stack, so BASE doesn't need to be reloaded across these calls. + | + |//-- Continuation dispatch ---------------------------------------------- + | + |->cont_dispatch: + | // BASE = meta base, RA = resultptr, RD = (nresults+1)*8 + | lw TMP0, -16+LO(BASE) // Continuation. + | move RB, BASE + | move BASE, TMP2 // Restore caller BASE. + | lw LFUNC:TMP1, FRAME_FUNC(TMP2) + |.if FFI + | sltiu AT, TMP0, 2 + |.endif + | lw PC, -16+HI(RB) // Restore PC from [cont|PC]. + | addu TMP2, RA, RD + |.if FFI + | bnez AT, >1 + |.endif + |. sw TISNIL, -8+HI(TMP2) // Ensure one valid arg. + | lw TMP1, LFUNC:TMP1->pc + | // BASE = base, RA = resultptr, RB = meta base + | jr TMP0 // Jump to continuation. + |. lw KBASE, PC2PROTO(k)(TMP1) + | + |.if FFI + |1: + | bnez TMP0, ->cont_ffi_callback // cont = 1: return from FFI callback. + | // cont = 0: tailcall from C function. + |. addiu TMP1, RB, -16 + | b ->vm_call_tail + |. subu RC, TMP1, BASE + |.endif + | + |->cont_cat: // RA = resultptr, RB = meta base + | lw INS, -4(PC) + | addiu CARG2, RB, -16 + | lw SFRETHI, HI(RA) + | lw SFRETLO, LO(RA) + | decode_RB8a MULTRES, INS + | decode_RA8a RA, INS + | decode_RB8b MULTRES + | decode_RA8b RA + | addu TMP1, BASE, MULTRES + | sw BASE, L->base + | subu CARG3, CARG2, TMP1 + | sw SFRETHI, HI(CARG2) + | bne TMP1, CARG2, ->BC_CAT_Z + |. sw SFRETLO, LO(CARG2) + | addu RA, BASE, RA + | sw SFRETHI, HI(RA) + | b ->cont_nop + |. sw SFRETLO, LO(RA) + | + |//-- Table indexing metamethods ----------------------------------------- + | + |->vmeta_tgets1: + | addiu CARG3, DISPATCH, DISPATCH_GL(tmptv) + | li TMP0, LJ_TSTR + | sw STR:RC, LO(CARG3) + | b >1 + |. sw TMP0, HI(CARG3) + | + |->vmeta_tgets: + | addiu CARG2, DISPATCH, DISPATCH_GL(tmptv) + | li TMP0, LJ_TTAB + | sw TAB:RB, LO(CARG2) + | addiu CARG3, DISPATCH, DISPATCH_GL(tmptv2) + | sw TMP0, HI(CARG2) + | li TMP1, LJ_TSTR + | sw STR:RC, LO(CARG3) + | b >1 + |. sw TMP1, HI(CARG3) + | + |->vmeta_tgetb: // TMP0 = index + | addiu CARG3, DISPATCH, DISPATCH_GL(tmptv) + | sw TMP0, LO(CARG3) + | sw TISNUM, HI(CARG3) + | + |->vmeta_tgetv: + |1: + | load_got lj_meta_tget + | sw BASE, L->base + | sw PC, SAVE_PC + | call_intern lj_meta_tget // (lua_State *L, TValue *o, TValue *k) + |. move CARG1, L + | // Returns TValue * (finished) or NULL (metamethod). + | beqz CRET1, >3 + |. addiu TMP1, BASE, -FRAME_CONT + | lw SFARG1HI, HI(CRET1) + | lw SFARG2HI, LO(CRET1) + | ins_next1 + | sw SFARG1HI, HI(RA) + | sw SFARG2HI, LO(RA) + | ins_next2 + | + |3: // Call __index metamethod. + | // BASE = base, L->top = new base, stack = cont/func/t/k + | lw BASE, L->top + | sw PC, -16+HI(BASE) // [cont|PC] + | subu PC, BASE, TMP1 + | lw LFUNC:RB, FRAME_FUNC(BASE) // Guaranteed to be a function here. + | b ->vm_call_dispatch_f + |. li NARGS8:RC, 16 // 2 args for func(t, k). + | + |->vmeta_tgetr: + | load_got lj_tab_getinth + | call_intern lj_tab_getinth // (GCtab *t, int32_t key) + |. nop + | // Returns cTValue * or NULL. + | beqz CRET1, ->BC_TGETR_Z + |. move SFARG2HI, TISNIL + | lw SFARG2HI, HI(CRET1) + | b ->BC_TGETR_Z + |. lw SFARG2LO, LO(CRET1) + | + |//----------------------------------------------------------------------- + | + |->vmeta_tsets1: + | addiu CARG3, DISPATCH, DISPATCH_GL(tmptv) + | li TMP0, LJ_TSTR + | sw STR:RC, LO(CARG3) + | b >1 + |. sw TMP0, HI(CARG3) + | + |->vmeta_tsets: + | addiu CARG2, DISPATCH, DISPATCH_GL(tmptv) + | li TMP0, LJ_TTAB + | sw TAB:RB, LO(CARG2) + | addiu CARG3, DISPATCH, DISPATCH_GL(tmptv2) + | sw TMP0, HI(CARG2) + | li TMP1, LJ_TSTR + | sw STR:RC, LO(CARG3) + | b >1 + |. sw TMP1, HI(CARG3) + | + |->vmeta_tsetb: // TMP0 = index + | addiu CARG3, DISPATCH, DISPATCH_GL(tmptv) + | sw TMP0, LO(CARG3) + | sw TISNUM, HI(CARG3) + | + |->vmeta_tsetv: + |1: + | load_got lj_meta_tset + | sw BASE, L->base + | sw PC, SAVE_PC + | call_intern lj_meta_tset // (lua_State *L, TValue *o, TValue *k) + |. move CARG1, L + | // Returns TValue * (finished) or NULL (metamethod). + | lw SFARG1HI, HI(RA) + | beqz CRET1, >3 + |. lw SFARG1LO, LO(RA) + | // NOBARRIER: lj_meta_tset ensures the table is not black. + | ins_next1 + | sw SFARG1HI, HI(CRET1) + | sw SFARG1LO, LO(CRET1) + | ins_next2 + | + |3: // Call __newindex metamethod. + | // BASE = base, L->top = new base, stack = cont/func/t/k/(v) + | addiu TMP1, BASE, -FRAME_CONT + | lw BASE, L->top + | sw PC, -16+HI(BASE) // [cont|PC] + | subu PC, BASE, TMP1 + | lw LFUNC:RB, FRAME_FUNC(BASE) // Guaranteed to be a function here. + | sw SFARG1HI, 16+HI(BASE) // Copy value to third argument. + | sw SFARG1LO, 16+LO(BASE) + | b ->vm_call_dispatch_f + |. li NARGS8:RC, 24 // 3 args for func(t, k, v) + | + |->vmeta_tsetr: + | load_got lj_tab_setinth + | sw BASE, L->base + | sw PC, SAVE_PC + | call_intern lj_tab_setinth // (lua_State *L, GCtab *t, int32_t key) + |. move CARG1, L + | // Returns TValue *. + | b ->BC_TSETR_Z + |. nop + | + |//-- Comparison metamethods --------------------------------------------- + | + |->vmeta_comp: + | // RA/RD point to o1/o2. + | move CARG2, RA + | move CARG3, RD + | load_got lj_meta_comp + | addiu PC, PC, -4 + | sw BASE, L->base + | sw PC, SAVE_PC + | decode_OP1 CARG4, INS + | call_intern lj_meta_comp // (lua_State *L, TValue *o1, *o2, int op) + |. move CARG1, L + | // Returns 0/1 or TValue * (metamethod). + |3: + | sltiu AT, CRET1, 2 + | beqz AT, ->vmeta_binop + | negu TMP2, CRET1 + |4: + | lhu RD, OFS_RD(PC) + | addiu PC, PC, 4 + | lui TMP1, (-(BCBIAS_J*4 >> 16) & 65535) + | sll RD, RD, 2 + | addu RD, RD, TMP1 + | and RD, RD, TMP2 + | addu PC, PC, RD + |->cont_nop: + | ins_next + | + |->cont_ra: // RA = resultptr + | lbu TMP1, -4+OFS_RA(PC) + | lw SFRETHI, HI(RA) + | lw SFRETLO, LO(RA) + | sll TMP1, TMP1, 3 + | addu TMP1, BASE, TMP1 + | sw SFRETHI, HI(TMP1) + | b ->cont_nop + |. sw SFRETLO, LO(TMP1) + | + |->cont_condt: // RA = resultptr + | lw TMP0, HI(RA) + | sltiu AT, TMP0, LJ_TISTRUECOND + | b <4 + |. negu TMP2, AT // Branch if result is true. + | + |->cont_condf: // RA = resultptr + | lw TMP0, HI(RA) + | sltiu AT, TMP0, LJ_TISTRUECOND + | b <4 + |. addiu TMP2, AT, -1 // Branch if result is false. + | + |->vmeta_equal: + | // SFARG1LO/SFARG2LO point to o1/o2. TMP0 is set to 0/1. + | load_got lj_meta_equal + | move CARG2, SFARG1LO + | move CARG3, SFARG2LO + | move CARG4, TMP0 + | addiu PC, PC, -4 + | sw BASE, L->base + | sw PC, SAVE_PC + | call_intern lj_meta_equal // (lua_State *L, GCobj *o1, *o2, int ne) + |. move CARG1, L + | // Returns 0/1 or TValue * (metamethod). + | b <3 + |. nop + | + |->vmeta_equal_cd: + |.if FFI + | load_got lj_meta_equal_cd + | move CARG2, INS + | addiu PC, PC, -4 + | sw BASE, L->base + | sw PC, SAVE_PC + | call_intern lj_meta_equal_cd // (lua_State *L, BCIns op) + |. move CARG1, L + | // Returns 0/1 or TValue * (metamethod). + | b <3 + |. nop + |.endif + | + |->vmeta_istype: + | load_got lj_meta_istype + | addiu PC, PC, -4 + | sw BASE, L->base + | srl CARG2, RA, 3 + | srl CARG3, RD, 3 + | sw PC, SAVE_PC + | call_intern lj_meta_istype // (lua_State *L, BCReg ra, BCReg tp) + |. move CARG1, L + | b ->cont_nop + |. nop + | + |//-- Arithmetic metamethods --------------------------------------------- + | + |->vmeta_unm: + | move RC, RB + | + |->vmeta_arith: + | load_got lj_meta_arith + | decode_OP1 TMP0, INS + | sw BASE, L->base + | move CARG2, RA + | sw PC, SAVE_PC + | move CARG3, RB + | move CARG4, RC + | sw TMP0, ARG5 + | call_intern lj_meta_arith // (lua_State *L, TValue *ra,*rb,*rc, BCReg op) + |. move CARG1, L + | // Returns NULL (finished) or TValue * (metamethod). + | beqz CRET1, ->cont_nop + |. nop + | + | // Call metamethod for binary op. + |->vmeta_binop: + | // BASE = old base, CRET1 = new base, stack = cont/func/o1/o2 + | subu TMP1, CRET1, BASE + | sw PC, -16+HI(CRET1) // [cont|PC] + | move TMP2, BASE + | addiu PC, TMP1, FRAME_CONT + | move BASE, CRET1 + | b ->vm_call_dispatch + |. li NARGS8:RC, 16 // 2 args for func(o1, o2). + | + |->vmeta_len: + | // CARG2 already set by BC_LEN. +#if LJ_52 + | move MULTRES, CARG1 +#endif + | load_got lj_meta_len + | sw BASE, L->base + | sw PC, SAVE_PC + | call_intern lj_meta_len // (lua_State *L, TValue *o) + |. move CARG1, L + | // Returns NULL (retry) or TValue * (metamethod base). +#if LJ_52 + | bnez CRET1, ->vmeta_binop // Binop call for compatibility. + |. nop + | b ->BC_LEN_Z + |. move CARG1, MULTRES +#else + | b ->vmeta_binop // Binop call for compatibility. + |. nop +#endif + | + |//-- Call metamethod ---------------------------------------------------- + | + |->vmeta_call: // Resolve and call __call metamethod. + | // TMP2 = old base, BASE = new base, RC = nargs*8 + | load_got lj_meta_call + | sw TMP2, L->base // This is the callers base! + | addiu CARG2, BASE, -8 + | sw PC, SAVE_PC + | addu CARG3, BASE, RC + | move MULTRES, NARGS8:RC + | call_intern lj_meta_call // (lua_State *L, TValue *func, TValue *top) + |. move CARG1, L + | lw LFUNC:RB, FRAME_FUNC(BASE) // Guaranteed to be a function here. + | addiu NARGS8:RC, MULTRES, 8 // Got one more argument now. + | ins_call + | + |->vmeta_callt: // Resolve __call for BC_CALLT. + | // BASE = old base, RA = new base, RC = nargs*8 + | load_got lj_meta_call + | sw BASE, L->base + | addiu CARG2, RA, -8 + | sw PC, SAVE_PC + | addu CARG3, RA, RC + | move MULTRES, NARGS8:RC + | call_intern lj_meta_call // (lua_State *L, TValue *func, TValue *top) + |. move CARG1, L + | lw TMP1, FRAME_PC(BASE) + | lw LFUNC:RB, FRAME_FUNC(RA) // Guaranteed to be a function here. + | b ->BC_CALLT_Z + |. addiu NARGS8:RC, MULTRES, 8 // Got one more argument now. + | + |//-- Argument coercion for 'for' statement ------------------------------ + | + |->vmeta_for: + | load_got lj_meta_for + | sw BASE, L->base + | move CARG2, RA + | sw PC, SAVE_PC + | move MULTRES, INS + | call_intern lj_meta_for // (lua_State *L, TValue *base) + |. move CARG1, L + |.if JIT + | decode_OP1 TMP0, MULTRES + | li AT, BC_JFORI + |.endif + | decode_RA8a RA, MULTRES + | decode_RD8a RD, MULTRES + | decode_RA8b RA + |.if JIT + | beq TMP0, AT, =>BC_JFORI + |. decode_RD8b RD + | b =>BC_FORI + |. nop + |.else + | b =>BC_FORI + |. decode_RD8b RD + |.endif + | + |//----------------------------------------------------------------------- + |//-- Fast functions ----------------------------------------------------- + |//----------------------------------------------------------------------- + | + |.macro .ffunc, name + |->ff_ .. name: + |.endmacro + | + |.macro .ffunc_1, name + |->ff_ .. name: + | lw SFARG1HI, HI(BASE) + | beqz NARGS8:RC, ->fff_fallback + |. lw SFARG1LO, LO(BASE) + |.endmacro + | + |.macro .ffunc_2, name + |->ff_ .. name: + | sltiu AT, NARGS8:RC, 16 + | lw SFARG1HI, HI(BASE) + | bnez AT, ->fff_fallback + |. lw SFARG2HI, 8+HI(BASE) + | lw SFARG1LO, LO(BASE) + | lw SFARG2LO, 8+LO(BASE) + |.endmacro + | + |.macro .ffunc_n, name // Caveat: has delay slot! + |->ff_ .. name: + | lw SFARG1HI, HI(BASE) + |.if FPU + | ldc1 FARG1, 0(BASE) + |.else + | lw SFARG1LO, LO(BASE) + |.endif + | beqz NARGS8:RC, ->fff_fallback + |. sltiu AT, SFARG1HI, LJ_TISNUM + | beqz AT, ->fff_fallback + |.endmacro + | + |.macro .ffunc_nn, name // Caveat: has delay slot! + |->ff_ .. name: + | sltiu AT, NARGS8:RC, 16 + | lw SFARG1HI, HI(BASE) + | bnez AT, ->fff_fallback + |. lw SFARG2HI, 8+HI(BASE) + | sltiu TMP0, SFARG1HI, LJ_TISNUM + |.if FPU + | ldc1 FARG1, 0(BASE) + |.else + | lw SFARG1LO, LO(BASE) + |.endif + | sltiu TMP1, SFARG2HI, LJ_TISNUM + |.if FPU + | ldc1 FARG2, 8(BASE) + |.else + | lw SFARG2LO, 8+LO(BASE) + |.endif + | and TMP0, TMP0, TMP1 + | beqz TMP0, ->fff_fallback + |.endmacro + | + |// Inlined GC threshold check. Caveat: uses TMP0 and TMP1 and has delay slot! + |.macro ffgccheck + | lw TMP0, DISPATCH_GL(gc.total)(DISPATCH) + | lw TMP1, DISPATCH_GL(gc.threshold)(DISPATCH) + | subu AT, TMP0, TMP1 + | bgezal AT, ->fff_gcstep + |.endmacro + | + |//-- Base library: checks ----------------------------------------------- + | + |.ffunc_1 assert + | sltiu AT, SFARG1HI, LJ_TISTRUECOND + | beqz AT, ->fff_fallback + |. addiu RA, BASE, -8 + | lw PC, FRAME_PC(BASE) + | addiu RD, NARGS8:RC, 8 // Compute (nresults+1)*8. + | addu TMP2, RA, NARGS8:RC + | sw SFARG1HI, HI(RA) + | addiu TMP1, BASE, 8 + | beq BASE, TMP2, ->fff_res // Done if exactly 1 argument. + |. sw SFARG1LO, LO(RA) + |1: + | lw SFRETHI, HI(TMP1) + | lw SFRETLO, LO(TMP1) + | sw SFRETHI, -8+HI(TMP1) + | sw SFRETLO, -8+LO(TMP1) + | bne TMP1, TMP2, <1 + |. addiu TMP1, TMP1, 8 + | b ->fff_res + |. nop + | + |.ffunc type + | lw SFARG1HI, HI(BASE) + | beqz NARGS8:RC, ->fff_fallback + |. sltiu TMP0, SFARG1HI, LJ_TISNUM + | movn SFARG1HI, TISNUM, TMP0 + | not TMP1, SFARG1HI + | sll TMP1, TMP1, 3 + | addu TMP1, CFUNC:RB, TMP1 + | lw SFARG1HI, CFUNC:TMP1->upvalue[0].u32.hi + | b ->fff_restv + |. lw SFARG1LO, CFUNC:TMP1->upvalue[0].u32.lo + | + |//-- Base library: getters and setters --------------------------------- + | + |.ffunc_1 getmetatable + | li AT, LJ_TTAB + | bne SFARG1HI, AT, >6 + |. li AT, LJ_TUDATA + |1: // Field metatable must be at same offset for GCtab and GCudata! + | lw TAB:SFARG1LO, TAB:SFARG1LO->metatable + |2: + | lw STR:RC, DISPATCH_GL(gcroot[GCROOT_MMNAME+MM_metatable])(DISPATCH) + | beqz TAB:SFARG1LO, ->fff_restv + |. li SFARG1HI, LJ_TNIL + | lw TMP0, TAB:SFARG1LO->hmask + | li SFARG1HI, LJ_TTAB // Use metatable as default result. + | lw TMP1, STR:RC->sid + | lw NODE:TMP2, TAB:SFARG1LO->node + | and TMP1, TMP1, TMP0 // idx = str->sid & tab->hmask + | sll TMP0, TMP1, 5 + | sll TMP1, TMP1, 3 + | subu TMP1, TMP0, TMP1 + | addu NODE:TMP2, NODE:TMP2, TMP1 // node = tab->node + (idx*32-idx*8) + | li AT, LJ_TSTR + |3: // Rearranged logic, because we expect _not_ to find the key. + | lw CARG4, offsetof(Node, key)+HI(NODE:TMP2) + | lw TMP0, offsetof(Node, key)+LO(NODE:TMP2) + | lw NODE:TMP3, NODE:TMP2->next + | bne CARG4, AT, >4 + |. lw CARG3, offsetof(Node, val)+HI(NODE:TMP2) + | beq TMP0, STR:RC, >5 + |. lw TMP1, offsetof(Node, val)+LO(NODE:TMP2) + |4: + | beqz NODE:TMP3, ->fff_restv // Not found, keep default result. + |. move NODE:TMP2, NODE:TMP3 + | b <3 + |. nop + |5: + | beq CARG3, TISNIL, ->fff_restv // Ditto for nil value. + |. nop + | move SFARG1HI, CARG3 // Return value of mt.__metatable. + | b ->fff_restv + |. move SFARG1LO, TMP1 + | + |6: + | beq SFARG1HI, AT, <1 + |. sltu AT, TISNUM, SFARG1HI + | movz SFARG1HI, TISNUM, AT + | not TMP1, SFARG1HI + | sll TMP1, TMP1, 2 + | addu TMP1, DISPATCH, TMP1 + | b <2 + |. lw TAB:SFARG1LO, DISPATCH_GL(gcroot[GCROOT_BASEMT])(TMP1) + | + |.ffunc_2 setmetatable + | // Fast path: no mt for table yet and not clearing the mt. + | li AT, LJ_TTAB + | bne SFARG1HI, AT, ->fff_fallback + |. addiu SFARG2HI, SFARG2HI, -LJ_TTAB + | lw TAB:TMP1, TAB:SFARG1LO->metatable + | lbu TMP3, TAB:SFARG1LO->marked + | or AT, SFARG2HI, TAB:TMP1 + | bnez AT, ->fff_fallback + |. andi AT, TMP3, LJ_GC_BLACK // isblack(table) + | beqz AT, ->fff_restv + |. sw TAB:SFARG2LO, TAB:SFARG1LO->metatable + | barrierback TAB:SFARG1LO, TMP3, TMP0, ->fff_restv + | + |.ffunc rawget + | lw CARG4, HI(BASE) + | sltiu AT, NARGS8:RC, 16 + | lw TAB:CARG2, LO(BASE) + | load_got lj_tab_get + | addiu CARG4, CARG4, -LJ_TTAB + | or AT, AT, CARG4 + | bnez AT, ->fff_fallback + | addiu CARG3, BASE, 8 + | call_intern lj_tab_get // (lua_State *L, GCtab *t, cTValue *key) + |. move CARG1, L + | // Returns cTValue *. + | lw SFARG1HI, HI(CRET1) + | b ->fff_restv + |. lw SFARG1LO, LO(CRET1) + | + |//-- Base library: conversions ------------------------------------------ + | + |.ffunc tonumber + | // Only handles the number case inline (without a base argument). + | lw CARG1, HI(BASE) + | xori AT, NARGS8:RC, 8 // Exactly one number argument. + | sltu TMP0, TISNUM, CARG1 + | or AT, AT, TMP0 + | bnez AT, ->fff_fallback + |. lw SFARG1HI, HI(BASE) + | b ->fff_restv + |. lw SFARG1LO, LO(BASE) + | + |.ffunc_1 tostring + | // Only handles the string or number case inline. + | li AT, LJ_TSTR + | // A __tostring method in the string base metatable is ignored. + | beq SFARG1HI, AT, ->fff_restv // String key? + | // Handle numbers inline, unless a number base metatable is present. + |. lw TMP1, DISPATCH_GL(gcroot[GCROOT_BASEMT_NUM])(DISPATCH) + | sltu TMP0, TISNUM, SFARG1HI + | or TMP0, TMP0, TMP1 + | bnez TMP0, ->fff_fallback + |. sw BASE, L->base // Add frame since C call can throw. + | ffgccheck + |. sw PC, SAVE_PC // Redundant (but a defined value). + | load_got lj_strfmt_number + | move CARG1, L + | call_intern lj_strfmt_number // (lua_State *L, cTValue *o) + |. move CARG2, BASE + | // Returns GCstr *. + | li SFARG1HI, LJ_TSTR + | b ->fff_restv + |. move SFARG1LO, CRET1 + | + |//-- Base library: iterators ------------------------------------------- + | + |.ffunc next + | lw CARG2, HI(BASE) + | lw TAB:CARG1, LO(BASE) + | beqz NARGS8:RC, ->fff_fallback + |. addu TMP2, BASE, NARGS8:RC + | li AT, LJ_TTAB + | sw TISNIL, HI(TMP2) // Set missing 2nd arg to nil. + | bne CARG2, AT, ->fff_fallback + |. lw PC, FRAME_PC(BASE) + | load_got lj_tab_next + | addiu CARG2, BASE, 8 + | call_intern lj_tab_next // (GCtab *t, cTValue *key, TValue *o) + |. addiu CARG3, BASE, -8 + | // Returns 1=found, 0=end, -1=error. + | addiu RA, BASE, -8 + | bgtz CRET1, ->fff_res // Found key/value. + |. li RD, (2+1)*8 + | beqz CRET1, ->fff_restv // End of traversal: return nil. + |. li SFARG1HI, LJ_TNIL + | lw CFUNC:RB, FRAME_FUNC(BASE) + | b ->fff_fallback // Invalid key. + |. li RC, 2*8 + | + |.ffunc_1 pairs + | li AT, LJ_TTAB + | bne SFARG1HI, AT, ->fff_fallback + |. lw PC, FRAME_PC(BASE) +#if LJ_52 + | lw TAB:TMP2, TAB:SFARG1LO->metatable + | lw TMP0, CFUNC:RB->upvalue[0].u32.hi + | lw TMP1, CFUNC:RB->upvalue[0].u32.lo + | bnez TAB:TMP2, ->fff_fallback +#else + | lw TMP0, CFUNC:RB->upvalue[0].u32.hi + | lw TMP1, CFUNC:RB->upvalue[0].u32.lo +#endif + |. addiu RA, BASE, -8 + | sw TISNIL, 8+HI(BASE) + | sw TMP0, HI(RA) + | sw TMP1, LO(RA) + | b ->fff_res + |. li RD, (3+1)*8 + | + |.ffunc ipairs_aux + | sltiu AT, NARGS8:RC, 16 + | lw CARG3, HI(BASE) + | lw TAB:CARG1, LO(BASE) + | lw CARG4, 8+HI(BASE) + | bnez AT, ->fff_fallback + |. addiu CARG3, CARG3, -LJ_TTAB + | xor CARG4, CARG4, TISNUM + | and AT, CARG3, CARG4 + | bnez AT, ->fff_fallback + |. lw PC, FRAME_PC(BASE) + | lw TMP2, 8+LO(BASE) + | lw TMP0, TAB:CARG1->asize + | lw TMP1, TAB:CARG1->array + | addiu TMP2, TMP2, 1 + | sw TISNUM, -8+HI(BASE) + | sltu AT, TMP2, TMP0 + | sw TMP2, -8+LO(BASE) + | beqz AT, >2 // Not in array part? + |. addiu RA, BASE, -8 + | sll TMP3, TMP2, 3 + | addu TMP3, TMP1, TMP3 + | lw TMP1, HI(TMP3) + | lw TMP2, LO(TMP3) + |1: + | beq TMP1, TISNIL, ->fff_res // End of iteration, return 0 results. + |. li RD, (0+1)*8 + | sw TMP1, 8+HI(RA) + | sw TMP2, 8+LO(RA) + | b ->fff_res + |. li RD, (2+1)*8 + | + |2: // Check for empty hash part first. Otherwise call C function. + | lw TMP0, TAB:CARG1->hmask + | load_got lj_tab_getinth + | beqz TMP0, ->fff_res + |. li RD, (0+1)*8 + | call_intern lj_tab_getinth // (GCtab *t, int32_t key) + |. move CARG2, TMP2 + | // Returns cTValue * or NULL. + | beqz CRET1, ->fff_res + |. li RD, (0+1)*8 + | lw TMP1, HI(CRET1) + | b <1 + |. lw TMP2, LO(CRET1) + | + |.ffunc_1 ipairs + | li AT, LJ_TTAB + | bne SFARG1HI, AT, ->fff_fallback + |. lw PC, FRAME_PC(BASE) +#if LJ_52 + | lw TAB:TMP2, TAB:SFARG1LO->metatable + | lw TMP0, CFUNC:RB->upvalue[0].u32.hi + | lw TMP1, CFUNC:RB->upvalue[0].u32.lo + | bnez TAB:TMP2, ->fff_fallback +#else + | lw TMP0, CFUNC:RB->upvalue[0].u32.hi + | lw TMP1, CFUNC:RB->upvalue[0].u32.lo +#endif + |. addiu RA, BASE, -8 + | sw TISNUM, 8+HI(BASE) + | sw r0, 8+LO(BASE) + | sw TMP0, HI(RA) + | sw TMP1, LO(RA) + | b ->fff_res + |. li RD, (3+1)*8 + | + |//-- Base library: catch errors ---------------------------------------- + | + |.ffunc pcall + | lbu TMP3, DISPATCH_GL(hookmask)(DISPATCH) + | beqz NARGS8:RC, ->fff_fallback + | move TMP2, BASE + | addiu BASE, BASE, 8 + | // Remember active hook before pcall. + | srl TMP3, TMP3, HOOK_ACTIVE_SHIFT + | andi TMP3, TMP3, 1 + | addiu PC, TMP3, 8+FRAME_PCALL + | b ->vm_call_dispatch + |. addiu NARGS8:RC, NARGS8:RC, -8 + | + |.ffunc xpcall + | sltiu AT, NARGS8:RC, 16 + | lw CARG4, 8+HI(BASE) + | bnez AT, ->fff_fallback + |. lw CARG3, 8+LO(BASE) + | lw CARG1, LO(BASE) + | lw CARG2, HI(BASE) + | lbu TMP1, DISPATCH_GL(hookmask)(DISPATCH) + | li AT, LJ_TFUNC + | move TMP2, BASE + | bne CARG4, AT, ->fff_fallback // Traceback must be a function. + | addiu BASE, BASE, 16 + | // Remember active hook before pcall. + | srl TMP3, TMP3, HOOK_ACTIVE_SHIFT + | sw CARG3, LO(TMP2) // Swap function and traceback. + | sw CARG4, HI(TMP2) + | andi TMP3, TMP3, 1 + | sw CARG1, 8+LO(TMP2) + | sw CARG2, 8+HI(TMP2) + | addiu PC, TMP3, 16+FRAME_PCALL + | b ->vm_call_dispatch + |. addiu NARGS8:RC, NARGS8:RC, -16 + | + |//-- Coroutine library -------------------------------------------------- + | + |.macro coroutine_resume_wrap, resume + |.if resume + |.ffunc coroutine_resume + | lw CARG3, HI(BASE) + | beqz NARGS8:RC, ->fff_fallback + |. lw CARG1, LO(BASE) + | li AT, LJ_TTHREAD + | bne CARG3, AT, ->fff_fallback + |.else + |.ffunc coroutine_wrap_aux + | lw L:CARG1, CFUNC:RB->upvalue[0].gcr + |.endif + | lbu TMP0, L:CARG1->status + | lw TMP1, L:CARG1->cframe + | lw CARG2, L:CARG1->top + | lw TMP2, L:CARG1->base + | addiu TMP3, TMP0, -LUA_YIELD + | bgtz TMP3, ->fff_fallback // st > LUA_YIELD? + |. xor TMP2, TMP2, CARG2 + | bnez TMP1, ->fff_fallback // cframe != 0? + |. or AT, TMP2, TMP0 + | lw TMP0, L:CARG1->maxstack + | beqz AT, ->fff_fallback // base == top && st == 0? + |. lw PC, FRAME_PC(BASE) + | addu TMP2, CARG2, NARGS8:RC + | sltu AT, TMP0, TMP2 + | bnez AT, ->fff_fallback // Stack overflow? + |. sw PC, SAVE_PC + | sw BASE, L->base + |1: + |.if resume + | addiu BASE, BASE, 8 // Keep resumed thread in stack for GC. + | addiu NARGS8:RC, NARGS8:RC, -8 + | addiu TMP2, TMP2, -8 + |.endif + | sw TMP2, L:CARG1->top + | addu TMP1, BASE, NARGS8:RC + | move CARG3, CARG2 + | sw BASE, L->top + |2: // Move args to coroutine. + | lw SFRETHI, HI(BASE) + | lw SFRETLO, LO(BASE) + | sltu AT, BASE, TMP1 + | beqz AT, >3 + |. addiu BASE, BASE, 8 + | sw SFRETHI, HI(CARG3) + | sw SFRETLO, LO(CARG3) + | b <2 + |. addiu CARG3, CARG3, 8 + |3: + | bal ->vm_resume // (lua_State *L, TValue *base, 0, 0) + |. move L:RA, L:CARG1 + | // Returns thread status. + |4: + | lw TMP2, L:RA->base + | sltiu AT, CRET1, LUA_YIELD+1 + | lw TMP3, L:RA->top + | li_vmstate INTERP + | lw BASE, L->base + | sw L, DISPATCH_GL(cur_L)(DISPATCH) + | st_vmstate + | beqz AT, >8 + |. subu RD, TMP3, TMP2 + | lw TMP0, L->maxstack + | beqz RD, >6 // No results? + |. addu TMP1, BASE, RD + | sltu AT, TMP0, TMP1 + | bnez AT, >9 // Need to grow stack? + |. addu TMP3, TMP2, RD + | sw TMP2, L:RA->top // Clear coroutine stack. + | move TMP1, BASE + |5: // Move results from coroutine. + | lw SFRETHI, HI(TMP2) + | lw SFRETLO, LO(TMP2) + | addiu TMP2, TMP2, 8 + | sltu AT, TMP2, TMP3 + | sw SFRETHI, HI(TMP1) + | sw SFRETLO, LO(TMP1) + | bnez AT, <5 + |. addiu TMP1, TMP1, 8 + |6: + | andi TMP0, PC, FRAME_TYPE + |.if resume + | li TMP1, LJ_TTRUE + | addiu RA, BASE, -8 + | sw TMP1, -8+HI(BASE) // Prepend true to results. + | addiu RD, RD, 16 + |.else + | move RA, BASE + | addiu RD, RD, 8 + |.endif + |7: + | sw PC, SAVE_PC + | beqz TMP0, ->BC_RET_Z + |. move MULTRES, RD + | b ->vm_return + |. nop + | + |8: // Coroutine returned with error (at co->top-1). + |.if resume + | addiu TMP3, TMP3, -8 + | li TMP1, LJ_TFALSE + | lw SFRETHI, HI(TMP3) + | lw SFRETLO, LO(TMP3) + | sw TMP3, L:RA->top // Remove error from coroutine stack. + | li RD, (2+1)*8 + | sw TMP1, -8+HI(BASE) // Prepend false to results. + | addiu RA, BASE, -8 + | sw SFRETHI, HI(BASE) // Copy error message. + | sw SFRETLO, LO(BASE) + | b <7 + |. andi TMP0, PC, FRAME_TYPE + |.else + | load_got lj_ffh_coroutine_wrap_err + | move CARG2, L:RA + | call_intern lj_ffh_coroutine_wrap_err // (lua_State *L, lua_State *co) + |. move CARG1, L + |.endif + | + |9: // Handle stack expansion on return from yield. + | load_got lj_state_growstack + | srl CARG2, RD, 3 + | call_intern lj_state_growstack // (lua_State *L, int n) + |. move CARG1, L + | b <4 + |. li CRET1, 0 + |.endmacro + | + | coroutine_resume_wrap 1 // coroutine.resume + | coroutine_resume_wrap 0 // coroutine.wrap + | + |.ffunc coroutine_yield + | lw TMP0, L->cframe + | addu TMP1, BASE, NARGS8:RC + | sw BASE, L->base + | andi TMP0, TMP0, CFRAME_RESUME + | sw TMP1, L->top + | beqz TMP0, ->fff_fallback + |. li CRET1, LUA_YIELD + | sw r0, L->cframe + | b ->vm_leave_unw + |. sb CRET1, L->status + | + |//-- Math library ------------------------------------------------------- + | + |.ffunc_1 math_abs + | bne SFARG1HI, TISNUM, >1 + |. sra TMP0, SFARG1LO, 31 + | xor TMP1, SFARG1LO, TMP0 + | subu SFARG1LO, TMP1, TMP0 + | bgez SFARG1LO, ->fff_restv + |. nop + | lui SFARG1HI, 0x41e0 // 2^31 as a double. + | b ->fff_restv + |. li SFARG1LO, 0 + |1: + | sltiu AT, SFARG1HI, LJ_TISNUM + | beqz AT, ->fff_fallback + |. sll SFARG1HI, SFARG1HI, 1 + | srl SFARG1HI, SFARG1HI, 1 + |// fallthrough + | + |->fff_restv: + | // SFARG1LO/SFARG1HI = TValue result. + | lw PC, FRAME_PC(BASE) + | sw SFARG1HI, -8+HI(BASE) + | addiu RA, BASE, -8 + | sw SFARG1LO, -8+LO(BASE) + |->fff_res1: + | // RA = results, PC = return. + | li RD, (1+1)*8 + |->fff_res: + | // RA = results, RD = (nresults+1)*8, PC = return. + | andi TMP0, PC, FRAME_TYPE + | bnez TMP0, ->vm_return + |. move MULTRES, RD + | lw INS, -4(PC) + | decode_RB8a RB, INS + | decode_RB8b RB + |5: + | sltu AT, RD, RB + | bnez AT, >6 // More results expected? + |. decode_RA8a TMP0, INS + | decode_RA8b TMP0 + | ins_next1 + | // Adjust BASE. KBASE is assumed to be set for the calling frame. + | subu BASE, RA, TMP0 + | ins_next2 + | + |6: // Fill up results with nil. + | addu TMP1, RA, RD + | addiu RD, RD, 8 + | b <5 + |. sw TISNIL, -8+HI(TMP1) + | + |.macro math_extern, func + | .ffunc math_ .. func + | lw SFARG1HI, HI(BASE) + | beqz NARGS8:RC, ->fff_fallback + |. load_got func + | sltiu AT, SFARG1HI, LJ_TISNUM + | beqz AT, ->fff_fallback + |.if FPU + |. ldc1 FARG1, 0(BASE) + |.else + |. lw SFARG1LO, LO(BASE) + |.endif + | call_extern + |. nop + | b ->fff_resn + |. nop + |.endmacro + | + |.macro math_extern2, func + | .ffunc_nn math_ .. func + |. load_got func + | call_extern + |. nop + | b ->fff_resn + |. nop + |.endmacro + | + |// TODO: Return integer type if result is integer (own sf implementation). + |.macro math_round, func + |->ff_math_ .. func: + | lw SFARG1HI, HI(BASE) + | beqz NARGS8:RC, ->fff_fallback + |. lw SFARG1LO, LO(BASE) + | beq SFARG1HI, TISNUM, ->fff_restv + |. sltu AT, SFARG1HI, TISNUM + | beqz AT, ->fff_fallback + |.if FPU + |. ldc1 FARG1, 0(BASE) + | bal ->vm_ .. func + |.else + |. load_got func + | call_extern + |.endif + |. nop + | b ->fff_resn + |. nop + |.endmacro + | + | math_round floor + | math_round ceil + | + |.ffunc math_log + | li AT, 8 + | bne NARGS8:RC, AT, ->fff_fallback // Exactly 1 argument. + |. lw SFARG1HI, HI(BASE) + | sltiu AT, SFARG1HI, LJ_TISNUM + | beqz AT, ->fff_fallback + |. load_got log + |.if FPU + | call_extern + |. ldc1 FARG1, 0(BASE) + |.else + | call_extern + |. lw SFARG1LO, LO(BASE) + |.endif + | b ->fff_resn + |. nop + | + | math_extern log10 + | math_extern exp + | math_extern sin + | math_extern cos + | math_extern tan + | math_extern asin + | math_extern acos + | math_extern atan + | math_extern sinh + | math_extern cosh + | math_extern tanh + | math_extern2 pow + | math_extern2 atan2 + | math_extern2 fmod + | + |.if FPU + |.ffunc_n math_sqrt + |. sqrt.d FRET1, FARG1 + |// fallthrough to ->fff_resn + |.else + | math_extern sqrt + |.endif + | + |->fff_resn: + | lw PC, FRAME_PC(BASE) + | addiu RA, BASE, -8 + |.if FPU + | b ->fff_res1 + |. sdc1 FRET1, -8(BASE) + |.else + | sw SFRETHI, -8+HI(BASE) + | b ->fff_res1 + |. sw SFRETLO, -8+LO(BASE) + |.endif + | + | + |.ffunc math_ldexp + | sltiu AT, NARGS8:RC, 16 + | lw SFARG1HI, HI(BASE) + | bnez AT, ->fff_fallback + |. lw CARG4, 8+HI(BASE) + | bne CARG4, TISNUM, ->fff_fallback + | load_got ldexp + |. sltu AT, SFARG1HI, TISNUM + | beqz AT, ->fff_fallback + |.if FPU + |. ldc1 FARG1, 0(BASE) + |.else + |. lw SFARG1LO, LO(BASE) + |.endif + | call_extern + |. lw CARG3, 8+LO(BASE) + | b ->fff_resn + |. nop + | + |.ffunc_n math_frexp + | load_got frexp + | lw PC, FRAME_PC(BASE) + | call_extern + |. addiu CARG3, DISPATCH, DISPATCH_GL(tmptv) + | lw TMP1, DISPATCH_GL(tmptv)(DISPATCH) + | addiu RA, BASE, -8 + |.if FPU + | mtc1 TMP1, FARG2 + | sdc1 FRET1, 0(RA) + | cvt.d.w FARG2, FARG2 + | sdc1 FARG2, 8(RA) + |.else + | sw SFRETLO, LO(RA) + | sw SFRETHI, HI(RA) + | sw TMP1, 8+LO(RA) + | sw TISNUM, 8+HI(RA) + |.endif + | b ->fff_res + |. li RD, (2+1)*8 + | + |.ffunc_n math_modf + | load_got modf + | lw PC, FRAME_PC(BASE) + | call_extern + |. addiu CARG3, BASE, -8 + | addiu RA, BASE, -8 + |.if FPU + | sdc1 FRET1, 0(BASE) + |.else + | sw SFRETLO, LO(BASE) + | sw SFRETHI, HI(BASE) + |.endif + | b ->fff_res + |. li RD, (2+1)*8 + | + |.macro math_minmax, name, intins, ismax + | .ffunc_1 name + | addu TMP3, BASE, NARGS8:RC + | bne SFARG1HI, TISNUM, >5 + |. addiu TMP2, BASE, 8 + |1: // Handle integers. + |. lw SFARG2HI, HI(TMP2) + | beq TMP2, TMP3, ->fff_restv + |. lw SFARG2LO, LO(TMP2) + | bne SFARG2HI, TISNUM, >3 + |. slt AT, SFARG1LO, SFARG2LO + | intins SFARG1LO, SFARG2LO, AT + | b <1 + |. addiu TMP2, TMP2, 8 + | + |3: // Convert intermediate result to number and continue with number loop. + | sltiu AT, SFARG2HI, LJ_TISNUM + | beqz AT, ->fff_fallback + |.if FPU + |. mtc1 SFARG1LO, FRET1 + | cvt.d.w FRET1, FRET1 + | b >7 + |. ldc1 FARG1, 0(TMP2) + |.else + |. nop + | bal ->vm_sfi2d_1 + |. nop + | b >7 + |. nop + |.endif + | + |5: + |. sltiu AT, SFARG1HI, LJ_TISNUM + | beqz AT, ->fff_fallback + |.if FPU + |. ldc1 FRET1, 0(BASE) + |.endif + | + |6: // Handle numbers. + |. lw SFARG2HI, HI(TMP2) + |.if FPU + | beq TMP2, TMP3, ->fff_resn + |.else + | beq TMP2, TMP3, ->fff_restv + |.endif + |. sltiu AT, SFARG2HI, LJ_TISNUM + | beqz AT, >8 + |.if FPU + |. ldc1 FARG1, 0(TMP2) + |.else + |. lw SFARG2LO, LO(TMP2) + |.endif + |7: + |.if FPU + |.if ismax + | c.olt.d FARG1, FRET1 + |.else + | c.olt.d FRET1, FARG1 + |.endif + | movf.d FRET1, FARG1 + |.else + |.if ismax + | bal ->vm_sfcmpogt + |.else + | bal ->vm_sfcmpolt + |.endif + |. nop + | movz SFARG1LO, SFARG2LO, CRET1 + | movz SFARG1HI, SFARG2HI, CRET1 + |.endif + | b <6 + |. addiu TMP2, TMP2, 8 + | + |8: // Convert integer to number and continue with number loop. + | bne SFARG2HI, TISNUM, ->fff_fallback + |.if FPU + |. lwc1 FARG1, LO(TMP2) + | b <7 + |. cvt.d.w FARG1, FARG1 + |.else + |. nop + | bal ->vm_sfi2d_2 + |. nop + | b <7 + |. nop + |.endif + | + |.endmacro + | + | math_minmax math_min, movz, 0 + | math_minmax math_max, movn, 1 + | + |//-- String library ----------------------------------------------------- + | + |.ffunc string_byte // Only handle the 1-arg case here. + | lw CARG3, HI(BASE) + | lw STR:CARG1, LO(BASE) + | xori AT, NARGS8:RC, 8 + | addiu CARG3, CARG3, -LJ_TSTR + | or AT, AT, CARG3 + | bnez AT, ->fff_fallback // Need exactly 1 string argument. + |. nop + | lw TMP0, STR:CARG1->len + | addiu RA, BASE, -8 + | lw PC, FRAME_PC(BASE) + | sltu RD, r0, TMP0 + | lbu TMP1, STR:CARG1[1] // Access is always ok (NUL at end). + | addiu RD, RD, 1 + | sll RD, RD, 3 // RD = ((str->len != 0)+1)*8 + | sw TISNUM, HI(RA) + | b ->fff_res + |. sw TMP1, LO(RA) + | + |.ffunc string_char // Only handle the 1-arg case here. + | ffgccheck + |. nop + | lw CARG3, HI(BASE) + | lw CARG1, LO(BASE) + | li TMP1, 255 + | xori AT, NARGS8:RC, 8 // Exactly 1 argument. + | xor TMP0, CARG3, TISNUM // Integer. + | sltu TMP1, TMP1, CARG1 // !(255 < n). + | or AT, AT, TMP0 + | or AT, AT, TMP1 + | bnez AT, ->fff_fallback + |. li CARG3, 1 + | addiu CARG2, sp, ARG5_OFS + | sb CARG1, ARG5 + |->fff_newstr: + | load_got lj_str_new + | sw BASE, L->base + | sw PC, SAVE_PC + | call_intern lj_str_new // (lua_State *L, char *str, size_t l) + |. move CARG1, L + | // Returns GCstr *. + | lw BASE, L->base + |->fff_resstr: + | move SFARG1LO, CRET1 + | b ->fff_restv + |. li SFARG1HI, LJ_TSTR + | + |.ffunc string_sub + | ffgccheck + |. nop + | addiu AT, NARGS8:RC, -16 + | lw CARG3, 16+HI(BASE) + | lw TMP0, HI(BASE) + | lw STR:CARG1, LO(BASE) + | bltz AT, ->fff_fallback + |. lw CARG2, 8+HI(BASE) + | beqz AT, >1 + |. li CARG4, -1 + | bne CARG3, TISNUM, ->fff_fallback + |. lw CARG4, 16+LO(BASE) + |1: + | bne CARG2, TISNUM, ->fff_fallback + |. li AT, LJ_TSTR + | bne TMP0, AT, ->fff_fallback + |. lw CARG3, 8+LO(BASE) + | lw CARG2, STR:CARG1->len + | // STR:CARG1 = str, CARG2 = str->len, CARG3 = start, CARG4 = end + | slt AT, CARG4, r0 + | addiu TMP0, CARG2, 1 + | addu TMP1, CARG4, TMP0 + | slt TMP3, CARG3, r0 + | movn CARG4, TMP1, AT // if (end < 0) end += len+1 + | addu TMP1, CARG3, TMP0 + | movn CARG3, TMP1, TMP3 // if (start < 0) start += len+1 + | li TMP2, 1 + | slt AT, CARG4, r0 + | slt TMP3, r0, CARG3 + | movn CARG4, r0, AT // if (end < 0) end = 0 + | movz CARG3, TMP2, TMP3 // if (start < 1) start = 1 + | slt AT, CARG2, CARG4 + | movn CARG4, CARG2, AT // if (end > len) end = len + | addu CARG2, STR:CARG1, CARG3 + | subu CARG3, CARG4, CARG3 // len = end - start + | addiu CARG2, CARG2, sizeof(GCstr)-1 + | bgez CARG3, ->fff_newstr + |. addiu CARG3, CARG3, 1 // len++ + |->fff_emptystr: // Return empty string. + | addiu STR:SFARG1LO, DISPATCH, DISPATCH_GL(strempty) + | b ->fff_restv + |. li SFARG1HI, LJ_TSTR + | + |.macro ffstring_op, name + | .ffunc string_ .. name + | ffgccheck + |. nop + | lw CARG3, HI(BASE) + | lw STR:CARG2, LO(BASE) + | beqz NARGS8:RC, ->fff_fallback + |. li AT, LJ_TSTR + | bne CARG3, AT, ->fff_fallback + |. addiu SBUF:CARG1, DISPATCH, DISPATCH_GL(tmpbuf) + | load_got lj_buf_putstr_ .. name + | lw TMP0, SBUF:CARG1->b + | sw L, SBUF:CARG1->L + | sw BASE, L->base + | sw TMP0, SBUF:CARG1->w + | call_intern extern lj_buf_putstr_ .. name + |. sw PC, SAVE_PC + | load_got lj_buf_tostr + | call_intern lj_buf_tostr + |. move SBUF:CARG1, SBUF:CRET1 + | b ->fff_resstr + |. lw BASE, L->base + |.endmacro + | + |ffstring_op reverse + |ffstring_op lower + |ffstring_op upper + | + |//-- Bit library -------------------------------------------------------- + | + |->vm_tobit_fb: + | beqz TMP1, ->fff_fallback + |.if FPU + |. ldc1 FARG1, 0(BASE) + | add.d FARG1, FARG1, TOBIT + | jr ra + |. mfc1 CRET1, FARG1 + |.else + |// FP number to bit conversion for soft-float. + |->vm_tobit: + | sll TMP0, SFARG1HI, 1 + | lui AT, 0x0020 + | addu TMP0, TMP0, AT + | slt AT, TMP0, r0 + | movz SFARG1LO, r0, AT + | beqz AT, >2 + |. li TMP1, 0x3e0 + | not TMP1, TMP1 + | sra TMP0, TMP0, 21 + | subu TMP0, TMP1, TMP0 + | slt AT, TMP0, r0 + | bnez AT, >1 + |. sll TMP1, SFARG1HI, 11 + | lui AT, 0x8000 + | or TMP1, TMP1, AT + | srl AT, SFARG1LO, 21 + | or TMP1, TMP1, AT + | slt AT, SFARG1HI, r0 + | beqz AT, >2 + |. srlv SFARG1LO, TMP1, TMP0 + | subu SFARG1LO, r0, SFARG1LO + |2: + | jr ra + |. move CRET1, SFARG1LO + |1: + | addiu TMP0, TMP0, 21 + | srlv TMP1, SFARG1LO, TMP0 + | li AT, 20 + | subu TMP0, AT, TMP0 + | sll SFARG1LO, SFARG1HI, 12 + | sllv AT, SFARG1LO, TMP0 + | or SFARG1LO, TMP1, AT + | slt AT, SFARG1HI, r0 + | beqz AT, <2 + |. nop + | jr ra + |. subu CRET1, r0, SFARG1LO + |.endif + | + |.macro .ffunc_bit, name + | .ffunc_1 bit_..name + | beq SFARG1HI, TISNUM, >6 + |. move CRET1, SFARG1LO + | bal ->vm_tobit_fb + |. sltu TMP1, SFARG1HI, TISNUM + |6: + |.endmacro + | + |.macro .ffunc_bit_op, name, ins + | .ffunc_bit name + | addiu TMP2, BASE, 8 + | addu TMP3, BASE, NARGS8:RC + |1: + | lw SFARG1HI, HI(TMP2) + | beq TMP2, TMP3, ->fff_resi + |. lw SFARG1LO, LO(TMP2) + |.if FPU + | bne SFARG1HI, TISNUM, >2 + |. addiu TMP2, TMP2, 8 + | b <1 + |. ins CRET1, CRET1, SFARG1LO + |2: + | ldc1 FARG1, -8(TMP2) + | sltu TMP1, SFARG1HI, TISNUM + | beqz TMP1, ->fff_fallback + |. add.d FARG1, FARG1, TOBIT + | mfc1 SFARG1LO, FARG1 + | b <1 + |. ins CRET1, CRET1, SFARG1LO + |.else + | beq SFARG1HI, TISNUM, >2 + |. move CRET2, CRET1 + | bal ->vm_tobit_fb + |. sltu TMP1, SFARG1HI, TISNUM + | move SFARG1LO, CRET2 + |2: + | ins CRET1, CRET1, SFARG1LO + | b <1 + |. addiu TMP2, TMP2, 8 + |.endif + |.endmacro + | + |.ffunc_bit_op band, and + |.ffunc_bit_op bor, or + |.ffunc_bit_op bxor, xor + | + |.ffunc_bit bswap + | srl TMP0, CRET1, 24 + | srl TMP2, CRET1, 8 + | sll TMP1, CRET1, 24 + | andi TMP2, TMP2, 0xff00 + | or TMP0, TMP0, TMP1 + | andi CRET1, CRET1, 0xff00 + | or TMP0, TMP0, TMP2 + | sll CRET1, CRET1, 8 + | b ->fff_resi + |. or CRET1, TMP0, CRET1 + | + |.ffunc_bit bnot + | b ->fff_resi + |. not CRET1, CRET1 + | + |.macro .ffunc_bit_sh, name, ins, shmod + | .ffunc_2 bit_..name + | beq SFARG1HI, TISNUM, >1 + |. nop + | bal ->vm_tobit_fb + |. sltu TMP1, SFARG1HI, TISNUM + | move SFARG1LO, CRET1 + |1: + | bne SFARG2HI, TISNUM, ->fff_fallback + |. nop + |.if shmod == 1 + | li AT, 32 + | subu TMP0, AT, SFARG2LO + | sllv SFARG2LO, SFARG1LO, SFARG2LO + | srlv SFARG1LO, SFARG1LO, TMP0 + |.elif shmod == 2 + | li AT, 32 + | subu TMP0, AT, SFARG2LO + | srlv SFARG2LO, SFARG1LO, SFARG2LO + | sllv SFARG1LO, SFARG1LO, TMP0 + |.endif + | b ->fff_resi + |. ins CRET1, SFARG1LO, SFARG2LO + |.endmacro + | + |.ffunc_bit_sh lshift, sllv, 0 + |.ffunc_bit_sh rshift, srlv, 0 + |.ffunc_bit_sh arshift, srav, 0 + |// Can't use rotrv, since it's only in MIPS32R2. + |.ffunc_bit_sh rol, or, 1 + |.ffunc_bit_sh ror, or, 2 + | + |.ffunc_bit tobit + |->fff_resi: + | lw PC, FRAME_PC(BASE) + | addiu RA, BASE, -8 + | sw TISNUM, -8+HI(BASE) + | b ->fff_res1 + |. sw CRET1, -8+LO(BASE) + | + |//----------------------------------------------------------------------- + | + |->fff_fallback: // Call fast function fallback handler. + | // BASE = new base, RB = CFUNC, RC = nargs*8 + | lw TMP3, CFUNC:RB->f + | addu TMP1, BASE, NARGS8:RC + | lw PC, FRAME_PC(BASE) // Fallback may overwrite PC. + | addiu TMP0, TMP1, 8*LUA_MINSTACK + | lw TMP2, L->maxstack + | sw PC, SAVE_PC // Redundant (but a defined value). + | sltu AT, TMP2, TMP0 + | sw BASE, L->base + | sw TMP1, L->top + | bnez AT, >5 // Need to grow stack. + |. move CFUNCADDR, TMP3 + | jalr TMP3 // (lua_State *L) + |. move CARG1, L + | // Either throws an error, or recovers and returns -1, 0 or nresults+1. + | lw BASE, L->base + | sll RD, CRET1, 3 + | bgtz CRET1, ->fff_res // Returned nresults+1? + |. addiu RA, BASE, -8 + |1: // Returned 0 or -1: retry fast path. + | lw TMP0, L->top + | lw LFUNC:RB, FRAME_FUNC(BASE) + | bnez CRET1, ->vm_call_tail // Returned -1? + |. subu NARGS8:RC, TMP0, BASE + | ins_callt // Returned 0: retry fast path. + | + |// Reconstruct previous base for vmeta_call during tailcall. + |->vm_call_tail: + | andi TMP0, PC, FRAME_TYPE + | li AT, -4 + | bnez TMP0, >3 + |. and TMP1, PC, AT + | lbu TMP1, OFS_RA(PC) + | sll TMP1, TMP1, 3 + | addiu TMP1, TMP1, 8 + |3: + | b ->vm_call_dispatch // Resolve again for tailcall. + |. subu TMP2, BASE, TMP1 + | + |5: // Grow stack for fallback handler. + | load_got lj_state_growstack + | li CARG2, LUA_MINSTACK + | call_intern lj_state_growstack // (lua_State *L, int n) + |. move CARG1, L + | lw BASE, L->base + | b <1 + |. li CRET1, 0 // Force retry. + | + |->fff_gcstep: // Call GC step function. + | // BASE = new base, RC = nargs*8 + | move MULTRES, ra + | load_got lj_gc_step + | sw BASE, L->base + | addu TMP0, BASE, NARGS8:RC + | sw PC, SAVE_PC // Redundant (but a defined value). + | sw TMP0, L->top + | call_intern lj_gc_step // (lua_State *L) + |. move CARG1, L + | lw BASE, L->base + | move ra, MULTRES + | lw TMP0, L->top + | lw CFUNC:RB, FRAME_FUNC(BASE) + | jr ra + |. subu NARGS8:RC, TMP0, BASE + | + |//----------------------------------------------------------------------- + |//-- Special dispatch targets ------------------------------------------- + |//----------------------------------------------------------------------- + | + |->vm_record: // Dispatch target for recording phase. + |.if JIT + | lbu TMP3, DISPATCH_GL(hookmask)(DISPATCH) + | andi AT, TMP3, HOOK_VMEVENT // No recording while in vmevent. + | bnez AT, >5 + | // Decrement the hookcount for consistency, but always do the call. + |. lw TMP2, DISPATCH_GL(hookcount)(DISPATCH) + | andi AT, TMP3, HOOK_ACTIVE + | bnez AT, >1 + |. addiu TMP2, TMP2, -1 + | andi AT, TMP3, LUA_MASKLINE|LUA_MASKCOUNT + | beqz AT, >1 + |. nop + | b >1 + |. sw TMP2, DISPATCH_GL(hookcount)(DISPATCH) + |.endif + | + |->vm_rethook: // Dispatch target for return hooks. + | lbu TMP3, DISPATCH_GL(hookmask)(DISPATCH) + | andi AT, TMP3, HOOK_ACTIVE // Hook already active? + | beqz AT, >1 + |5: // Re-dispatch to static ins. + |. lw AT, GG_DISP2STATIC(TMP0) // Assumes TMP0 holds DISPATCH+OP*4. + | jr AT + |. nop + | + |->vm_inshook: // Dispatch target for instr/line hooks. + | lbu TMP3, DISPATCH_GL(hookmask)(DISPATCH) + | lw TMP2, DISPATCH_GL(hookcount)(DISPATCH) + | andi AT, TMP3, HOOK_ACTIVE // Hook already active? + | bnez AT, <5 + |. andi AT, TMP3, LUA_MASKLINE|LUA_MASKCOUNT + | beqz AT, <5 + |. addiu TMP2, TMP2, -1 + | beqz TMP2, >1 + |. sw TMP2, DISPATCH_GL(hookcount)(DISPATCH) + | andi AT, TMP3, LUA_MASKLINE + | beqz AT, <5 + |1: + |. load_got lj_dispatch_ins + | sw MULTRES, SAVE_MULTRES + | move CARG2, PC + | sw BASE, L->base + | // SAVE_PC must hold the _previous_ PC. The callee updates it with PC. + | call_intern lj_dispatch_ins // (lua_State *L, const BCIns *pc) + |. move CARG1, L + |3: + | lw BASE, L->base + |4: // Re-dispatch to static ins. + | lw INS, -4(PC) + | decode_OP4a TMP1, INS + | decode_OP4b TMP1 + | addu TMP0, DISPATCH, TMP1 + | decode_RD8a RD, INS + | lw AT, GG_DISP2STATIC(TMP0) + | decode_RA8a RA, INS + | decode_RD8b RD + | jr AT + | decode_RA8b RA + | + |->cont_hook: // Continue from hook yield. + | addiu PC, PC, 4 + | b <4 + |. lw MULTRES, -24+LO(RB) // Restore MULTRES for *M ins. + | + |->vm_hotloop: // Hot loop counter underflow. + |.if JIT + | lw LFUNC:TMP1, FRAME_FUNC(BASE) + | addiu CARG1, DISPATCH, GG_DISP2J + | sw PC, SAVE_PC + | lw TMP1, LFUNC:TMP1->pc + | move CARG2, PC + | sw L, DISPATCH_J(L)(DISPATCH) + | lbu TMP1, PC2PROTO(framesize)(TMP1) + | load_got lj_trace_hot + | sw BASE, L->base + | sll TMP1, TMP1, 3 + | addu TMP1, BASE, TMP1 + | call_intern lj_trace_hot // (jit_State *J, const BCIns *pc) + |. sw TMP1, L->top + | b <3 + |. nop + |.endif + | + |->vm_callhook: // Dispatch target for call hooks. + |.if JIT + | b >1 + |.endif + |. move CARG2, PC + | + |->vm_hotcall: // Hot call counter underflow. + |.if JIT + | ori CARG2, PC, 1 + |1: + |.endif + | load_got lj_dispatch_call + | addu TMP0, BASE, RC + | sw PC, SAVE_PC + | sw BASE, L->base + | subu RA, RA, BASE + | sw TMP0, L->top + | call_intern lj_dispatch_call // (lua_State *L, const BCIns *pc) + |. move CARG1, L + | // Returns ASMFunction. + | lw BASE, L->base + | lw TMP0, L->top + | sw r0, SAVE_PC // Invalidate for subsequent line hook. + | subu NARGS8:RC, TMP0, BASE + | addu RA, BASE, RA + | lw LFUNC:RB, FRAME_FUNC(BASE) + | jr CRET1 + |. lw INS, -4(PC) + | + |->cont_stitch: // Trace stitching. + |.if JIT + | // RA = resultptr, RB = meta base + | lw INS, -4(PC) + | lw TMP2, -24+LO(RB) // Save previous trace. + | decode_RA8a RC, INS + | addiu AT, MULTRES, -8 + | decode_RA8b RC + | beqz AT, >2 + |. addu RC, BASE, RC // Call base. + |1: // Move results down. + | lw SFRETHI, HI(RA) + | lw SFRETLO, LO(RA) + | addiu AT, AT, -8 + | addiu RA, RA, 8 + | sw SFRETHI, HI(RC) + | sw SFRETLO, LO(RC) + | bnez AT, <1 + |. addiu RC, RC, 8 + |2: + | decode_RA8a RA, INS + | decode_RB8a RB, INS + | decode_RA8b RA + | decode_RB8b RB + | addu RA, RA, RB + | addu RA, BASE, RA + |3: + | sltu AT, RC, RA + | bnez AT, >9 // More results wanted? + |. nop + | + | lhu TMP3, TRACE:TMP2->traceno + | lhu RD, TRACE:TMP2->link + | beq RD, TMP3, ->cont_nop // Blacklisted. + |. load_got lj_dispatch_stitch + | bnez RD, =>BC_JLOOP // Jump to stitched trace. + |. sll RD, RD, 3 + | + | // Stitch a new trace to the previous trace. + | sw TMP3, DISPATCH_J(exitno)(DISPATCH) + | sw L, DISPATCH_J(L)(DISPATCH) + | sw BASE, L->base + | addiu CARG1, DISPATCH, GG_DISP2J + | call_intern lj_dispatch_stitch // (jit_State *J, const BCIns *pc) + |. move CARG2, PC + | b ->cont_nop + |. lw BASE, L->base + | + |9: + | sw TISNIL, HI(RC) + | b <3 + |. addiu RC, RC, 8 + |.endif + | + |->vm_profhook: // Dispatch target for profiler hook. +#if LJ_HASPROFILE + | load_got lj_dispatch_profile + | sw MULTRES, SAVE_MULTRES + | move CARG2, PC + | sw BASE, L->base + | call_intern lj_dispatch_profile // (lua_State *L, const BCIns *pc) + |. move CARG1, L + | // HOOK_PROFILE is off again, so re-dispatch to dynamic instruction. + | addiu PC, PC, -4 + | b ->cont_nop + |. lw BASE, L->base +#endif + | + |//----------------------------------------------------------------------- + |//-- Trace exit handler ------------------------------------------------- + |//----------------------------------------------------------------------- + | + |.macro savex_, a, b + |.if FPU + | sdc1 f..a, 16+a*8(sp) + | sw r..a, 16+32*8+a*4(sp) + | sw r..b, 16+32*8+b*4(sp) + |.else + | sw r..a, 16+a*4(sp) + | sw r..b, 16+b*4(sp) + |.endif + |.endmacro + | + |->vm_exit_handler: + |.if JIT + |.if FPU + | addiu sp, sp, -(16+32*8+32*4) + |.else + | addiu sp, sp, -(16+32*4) + |.endif + | savex_ 0, 1 + | savex_ 2, 3 + | savex_ 4, 5 + | savex_ 6, 7 + | savex_ 8, 9 + | savex_ 10, 11 + | savex_ 12, 13 + | savex_ 14, 15 + | savex_ 16, 17 + | savex_ 18, 19 + | savex_ 20, 21 + | savex_ 22, 23 + | savex_ 24, 25 + | savex_ 26, 27 + |.if FPU + | sdc1 f28, 16+28*8(sp) + | sdc1 f30, 16+30*8(sp) + | sw r28, 16+32*8+28*4(sp) + | sw r30, 16+32*8+30*4(sp) + | sw r0, 16+32*8+31*4(sp) // Clear RID_TMP. + | addiu TMP2, sp, 16+32*8+32*4 // Recompute original value of sp. + | sw TMP2, 16+32*8+29*4(sp) // Store sp in RID_SP + |.else + | sw r28, 16+28*4(sp) + | sw r30, 16+30*4(sp) + | sw r0, 16+31*4(sp) // Clear RID_TMP. + | addiu TMP2, sp, 16+32*4 // Recompute original value of sp. + | sw TMP2, 16+29*4(sp) // Store sp in RID_SP + |.endif + | li_vmstate EXIT + | addiu DISPATCH, JGL, -GG_DISP2G-32768 + | lw TMP1, 0(TMP2) // Load exit number. + | st_vmstate + | lw L, DISPATCH_GL(cur_L)(DISPATCH) + | lw BASE, DISPATCH_GL(jit_base)(DISPATCH) + | load_got lj_trace_exit + | sw L, DISPATCH_J(L)(DISPATCH) + | sw ra, DISPATCH_J(parent)(DISPATCH) // Store trace number. + | sw BASE, L->base + | sw TMP1, DISPATCH_J(exitno)(DISPATCH) // Store exit number. + | addiu CARG1, DISPATCH, GG_DISP2J + | sw r0, DISPATCH_GL(jit_base)(DISPATCH) + | call_intern lj_trace_exit // (jit_State *J, ExitState *ex) + |. addiu CARG2, sp, 16 + | // Returns MULTRES (unscaled) or negated error code. + | lw TMP1, L->cframe + | li AT, -4 + | lw BASE, L->base + | and sp, TMP1, AT + | lw PC, SAVE_PC // Get SAVE_PC. + | b >1 + |. sw L, SAVE_L // Set SAVE_L (on-trace resume/yield). + |.endif + |->vm_exit_interp: + |.if JIT + | // CRET1 = MULTRES or negated error code, BASE, PC and JGL set. + | lw L, SAVE_L + | addiu DISPATCH, JGL, -GG_DISP2G-32768 + | sw BASE, L->base + |1: + | bltz CRET1, >9 // Check for error from exit. + |. lw LFUNC:RB, FRAME_FUNC(BASE) + | .FPU lui TMP3, 0x59c0 // TOBIT = 2^52 + 2^51 (float). + | sll MULTRES, CRET1, 3 + | li TISNIL, LJ_TNIL + | li TISNUM, LJ_TISNUM // Setup type comparison constants. + | sw MULTRES, SAVE_MULTRES + | .FPU mtc1 TMP3, TOBIT + | lw TMP1, LFUNC:RB->pc + | sw r0, DISPATCH_GL(jit_base)(DISPATCH) + | lw KBASE, PC2PROTO(k)(TMP1) + | .FPU cvt.d.s TOBIT, TOBIT + | // Modified copy of ins_next which handles function header dispatch, too. + | lw INS, 0(PC) + | addiu PC, PC, 4 + | // Assumes TISNIL == ~LJ_VMST_INTERP == -1 + | sw TISNIL, DISPATCH_GL(vmstate)(DISPATCH) + | decode_OP4a TMP1, INS + | decode_OP4b TMP1 + | sltiu TMP2, TMP1, BC_FUNCF*4 + | addu TMP0, DISPATCH, TMP1 + | decode_RD8a RD, INS + | lw AT, 0(TMP0) + | decode_RA8a RA, INS + | beqz TMP2, >2 + |. decode_RA8b RA + | jr AT + |. decode_RD8b RD + |2: + | sltiu TMP2, TMP1, (BC_FUNCC+2)*4 // Fast function? + | bnez TMP2, >3 + |. lw TMP1, FRAME_PC(BASE) + | // Check frame below fast function. + | andi TMP0, TMP1, FRAME_TYPE + | bnez TMP0, >3 // Trace stitching continuation? + |. nop + | // Otherwise set KBASE for Lua function below fast function. + | lw TMP2, -4(TMP1) + | decode_RA8a TMP0, TMP2 + | decode_RA8b TMP0 + | subu TMP1, BASE, TMP0 + | lw LFUNC:TMP2, -8+FRAME_FUNC(TMP1) + | lw TMP1, LFUNC:TMP2->pc + | lw KBASE, PC2PROTO(k)(TMP1) + |3: + | addiu RC, MULTRES, -8 + | jr AT + |. addu RA, RA, BASE + | + |9: // Rethrow error from the right C frame. + | load_got lj_err_trace + | sub CARG2, r0, CRET1 + | call_intern lj_err_trace // (lua_State *L, int errcode) + |. move CARG1, L + |.endif + | + |//----------------------------------------------------------------------- + |//-- Math helper functions ---------------------------------------------- + |//----------------------------------------------------------------------- + | + |// Hard-float round to integer. + |// Modifies AT, TMP0, FRET1, FRET2, f4. Keeps all others incl. FARG1. + |.macro vm_round_hf, func + | lui TMP0, 0x4330 // Hiword of 2^52 (double). + | mtc1 r0, f4 + | mtc1 TMP0, f5 + | abs.d FRET2, FARG1 // |x| + | mfc1 AT, f13 + | c.olt.d 0, FRET2, f4 + | add.d FRET1, FRET2, f4 // (|x| + 2^52) - 2^52 + | bc1f 0, >1 // Truncate only if |x| < 2^52. + |. sub.d FRET1, FRET1, f4 + | slt AT, AT, r0 + |.if "func" == "ceil" + | lui TMP0, 0xbff0 // Hiword of -1 (double). Preserves -0. + |.else + | lui TMP0, 0x3ff0 // Hiword of +1 (double). + |.endif + |.if "func" == "trunc" + | mtc1 TMP0, f5 + | c.olt.d 0, FRET2, FRET1 // |x| < result? + | sub.d FRET2, FRET1, f4 + | movt.d FRET1, FRET2, 0 // If yes, subtract +1. + | neg.d FRET2, FRET1 + | jr ra + |. movn.d FRET1, FRET2, AT // Merge sign bit back in. + |.else + | neg.d FRET2, FRET1 + | mtc1 TMP0, f5 + | movn.d FRET1, FRET2, AT // Merge sign bit back in. + |.if "func" == "ceil" + | c.olt.d 0, FRET1, FARG1 // x > result? + |.else + | c.olt.d 0, FARG1, FRET1 // x < result? + |.endif + | sub.d FRET2, FRET1, f4 // If yes, subtract +-1. + | jr ra + |. movt.d FRET1, FRET2, 0 + |.endif + |1: + | jr ra + |. mov.d FRET1, FARG1 + |.endmacro + | + |.macro vm_round, func + |.if FPU + | vm_round_hf, func + |.endif + |.endmacro + | + |->vm_floor: + | vm_round floor + |->vm_ceil: + | vm_round ceil + |->vm_trunc: + |.if JIT + | vm_round trunc + |.endif + | + |// Soft-float integer to number conversion. + |.macro sfi2d, AHI, ALO + |.if not FPU + | beqz ALO, >9 // Handle zero first. + |. sra TMP0, ALO, 31 + | xor TMP1, ALO, TMP0 + | subu TMP1, TMP1, TMP0 // Absolute value in TMP1. + | clz AHI, TMP1 + | andi TMP0, TMP0, 0x800 // Mask sign bit. + | li AT, 0x3ff+31-1 + | sllv TMP1, TMP1, AHI // Align mantissa left with leading 1. + | subu AHI, AT, AHI // Exponent - 1 in AHI. + | sll ALO, TMP1, 21 + | or AHI, AHI, TMP0 // Sign | Exponent. + | srl TMP1, TMP1, 11 + | sll AHI, AHI, 20 // Align left. + | jr ra + |. addu AHI, AHI, TMP1 // Add mantissa, increment exponent. + |9: + | jr ra + |. li AHI, 0 + |.endif + |.endmacro + | + |// Input SFARG1LO. Output: SFARG1*. Temporaries: AT, TMP0, TMP1. + |->vm_sfi2d_1: + | sfi2d SFARG1HI, SFARG1LO + | + |// Input SFARG2LO. Output: SFARG2*. Temporaries: AT, TMP0, TMP1. + |->vm_sfi2d_2: + | sfi2d SFARG2HI, SFARG2LO + | + |// Soft-float comparison. Equivalent to c.eq.d. + |// Input: SFARG*. Output: CRET1. Temporaries: AT, TMP0, TMP1. + |->vm_sfcmpeq: + |.if not FPU + | sll AT, SFARG1HI, 1 + | sll TMP0, SFARG2HI, 1 + | or CRET1, SFARG1LO, SFARG2LO + | or TMP1, AT, TMP0 + | or TMP1, TMP1, CRET1 + | beqz TMP1, >8 // Both args +-0: return 1. + |. sltu CRET1, r0, SFARG1LO + | lui TMP1, 0xffe0 + | addu AT, AT, CRET1 + | sltu CRET1, r0, SFARG2LO + | sltu AT, TMP1, AT + | addu TMP0, TMP0, CRET1 + | sltu TMP0, TMP1, TMP0 + | or TMP1, AT, TMP0 + | bnez TMP1, >9 // Either arg is NaN: return 0; + |. xor TMP0, SFARG1HI, SFARG2HI + | xor TMP1, SFARG1LO, SFARG2LO + | or AT, TMP0, TMP1 + | jr ra + |. sltiu CRET1, AT, 1 // Same values: return 1. + |8: + | jr ra + |. li CRET1, 1 + |9: + | jr ra + |. li CRET1, 0 + |.endif + | + |// Soft-float comparison. Equivalent to c.ult.d and c.olt.d. + |// Input: SFARG*. Output: CRET1. Temporaries: AT, TMP0, TMP1, CRET2. + |->vm_sfcmpult: + |.if not FPU + | b >1 + |. li CRET2, 1 + |.endif + | + |->vm_sfcmpolt: + |.if not FPU + | li CRET2, 0 + |1: + | sll AT, SFARG1HI, 1 + | sll TMP0, SFARG2HI, 1 + | or CRET1, SFARG1LO, SFARG2LO + | or TMP1, AT, TMP0 + | or TMP1, TMP1, CRET1 + | beqz TMP1, >8 // Both args +-0: return 0. + |. sltu CRET1, r0, SFARG1LO + | lui TMP1, 0xffe0 + | addu AT, AT, CRET1 + | sltu CRET1, r0, SFARG2LO + | sltu AT, TMP1, AT + | addu TMP0, TMP0, CRET1 + | sltu TMP0, TMP1, TMP0 + | or TMP1, AT, TMP0 + | bnez TMP1, >9 // Either arg is NaN: return 0 or 1; + |. and AT, SFARG1HI, SFARG2HI + | bltz AT, >5 // Both args negative? + |. nop + | beq SFARG1HI, SFARG2HI, >8 + |. sltu CRET1, SFARG1LO, SFARG2LO + | jr ra + |. slt CRET1, SFARG1HI, SFARG2HI + |5: // Swap conditions if both operands are negative. + | beq SFARG1HI, SFARG2HI, >8 + |. sltu CRET1, SFARG2LO, SFARG1LO + | jr ra + |. slt CRET1, SFARG2HI, SFARG1HI + |8: + | jr ra + |. nop + |9: + | jr ra + |. move CRET1, CRET2 + |.endif + | + |->vm_sfcmpogt: + |.if not FPU + | sll AT, SFARG2HI, 1 + | sll TMP0, SFARG1HI, 1 + | or CRET1, SFARG2LO, SFARG1LO + | or TMP1, AT, TMP0 + | or TMP1, TMP1, CRET1 + | beqz TMP1, >8 // Both args +-0: return 0. + |. sltu CRET1, r0, SFARG2LO + | lui TMP1, 0xffe0 + | addu AT, AT, CRET1 + | sltu CRET1, r0, SFARG1LO + | sltu AT, TMP1, AT + | addu TMP0, TMP0, CRET1 + | sltu TMP0, TMP1, TMP0 + | or TMP1, AT, TMP0 + | bnez TMP1, >9 // Either arg is NaN: return 0 or 1; + |. and AT, SFARG2HI, SFARG1HI + | bltz AT, >5 // Both args negative? + |. nop + | beq SFARG2HI, SFARG1HI, >8 + |. sltu CRET1, SFARG2LO, SFARG1LO + | jr ra + |. slt CRET1, SFARG2HI, SFARG1HI + |5: // Swap conditions if both operands are negative. + | beq SFARG2HI, SFARG1HI, >8 + |. sltu CRET1, SFARG1LO, SFARG2LO + | jr ra + |. slt CRET1, SFARG1HI, SFARG2HI + |8: + | jr ra + |. nop + |9: + | jr ra + |. li CRET1, 0 + |.endif + | + |// Soft-float comparison. Equivalent to c.ole.d a, b or c.ole.d b, a. + |// Input: SFARG*, TMP3. Output: CRET1. Temporaries: AT, TMP0, TMP1. + |->vm_sfcmpolex: + |.if not FPU + | sll AT, SFARG1HI, 1 + | sll TMP0, SFARG2HI, 1 + | or CRET1, SFARG1LO, SFARG2LO + | or TMP1, AT, TMP0 + | or TMP1, TMP1, CRET1 + | beqz TMP1, >8 // Both args +-0: return 1. + |. sltu CRET1, r0, SFARG1LO + | lui TMP1, 0xffe0 + | addu AT, AT, CRET1 + | sltu CRET1, r0, SFARG2LO + | sltu AT, TMP1, AT + | addu TMP0, TMP0, CRET1 + | sltu TMP0, TMP1, TMP0 + | or TMP1, AT, TMP0 + | bnez TMP1, >9 // Either arg is NaN: return 0; + |. and AT, SFARG1HI, SFARG2HI + | xor AT, AT, TMP3 + | bltz AT, >5 // Both args negative? + |. nop + | beq SFARG1HI, SFARG2HI, >6 + |. sltu CRET1, SFARG2LO, SFARG1LO + | jr ra + |. slt CRET1, SFARG2HI, SFARG1HI + |5: // Swap conditions if both operands are negative. + | beq SFARG1HI, SFARG2HI, >6 + |. sltu CRET1, SFARG1LO, SFARG2LO + | slt CRET1, SFARG1HI, SFARG2HI + |6: + | jr ra + |. nop + |8: + | jr ra + |. li CRET1, 1 + |9: + | jr ra + |. li CRET1, 0 + |.endif + | + |.macro sfmin_max, name, fpcall + |->vm_sf .. name: + |.if JIT and not FPU + | move TMP2, ra + | bal ->fpcall + |. nop + | move TMP0, CRET1 + | move SFRETHI, SFARG1HI + | move SFRETLO, SFARG1LO + | move ra, TMP2 + | movz SFRETHI, SFARG2HI, TMP0 + | jr ra + |. movz SFRETLO, SFARG2LO, TMP0 + |.endif + |.endmacro + | + | sfmin_max min, vm_sfcmpolt + | sfmin_max max, vm_sfcmpogt + | + |//----------------------------------------------------------------------- + |//-- Miscellaneous functions -------------------------------------------- + |//----------------------------------------------------------------------- + | + |.define NEXT_TAB, TAB:CARG1 + |.define NEXT_IDX, CARG2 + |.define NEXT_ASIZE, CARG3 + |.define NEXT_NIL, CARG4 + |.define NEXT_TMP0, r12 + |.define NEXT_TMP1, r13 + |.define NEXT_TMP2, r14 + |.define NEXT_RES_VK, CRET1 + |.define NEXT_RES_IDX, CRET2 + |.define NEXT_RES_PTR, sp + |.define NEXT_RES_VAL_I, 0(sp) + |.define NEXT_RES_VAL_IT, 4(sp) + |.define NEXT_RES_KEY_I, 8(sp) + |.define NEXT_RES_KEY_IT, 12(sp) + | + |// TValue *lj_vm_next(GCtab *t, uint32_t idx) + |// Next idx returned in CRET2. + |->vm_next: + |.if JIT and ENDIAN_LE + | lw NEXT_ASIZE, NEXT_TAB->asize + | lw NEXT_TMP0, NEXT_TAB->array + | li NEXT_NIL, LJ_TNIL + |1: // Traverse array part. + | sltu AT, NEXT_IDX, NEXT_ASIZE + | sll NEXT_TMP1, NEXT_IDX, 3 + | beqz AT, >5 + |. addu NEXT_TMP1, NEXT_TMP0, NEXT_TMP1 + | lw NEXT_TMP2, 4(NEXT_TMP1) + | sw NEXT_IDX, NEXT_RES_KEY_I + | beq NEXT_TMP2, NEXT_NIL, <1 + |. addiu NEXT_IDX, NEXT_IDX, 1 + | lw NEXT_TMP0, 0(NEXT_TMP1) + | li AT, LJ_TISNUM + | sw NEXT_TMP2, NEXT_RES_VAL_IT + | sw AT, NEXT_RES_KEY_IT + | sw NEXT_TMP0, NEXT_RES_VAL_I + | move NEXT_RES_VK, NEXT_RES_PTR + | jr ra + |. move NEXT_RES_IDX, NEXT_IDX + | + |5: // Traverse hash part. + | subu NEXT_RES_IDX, NEXT_IDX, NEXT_ASIZE + | lw NODE:NEXT_RES_VK, NEXT_TAB->node + | sll NEXT_TMP2, NEXT_RES_IDX, 5 + | lw NEXT_TMP0, NEXT_TAB->hmask + | sll AT, NEXT_RES_IDX, 3 + | subu AT, NEXT_TMP2, AT + | addu NODE:NEXT_RES_VK, NODE:NEXT_RES_VK, AT + |6: + | sltu AT, NEXT_TMP0, NEXT_RES_IDX + | bnez AT, >8 + |. nop + | lw NEXT_TMP2, NODE:NEXT_RES_VK->val.it + | bne NEXT_TMP2, NEXT_NIL, >9 + |. addiu NEXT_RES_IDX, NEXT_RES_IDX, 1 + | // Skip holes in hash part. + | b <6 + |. addiu NODE:NEXT_RES_VK, NODE:NEXT_RES_VK, sizeof(Node) + | + |8: // End of iteration. Set the key to nil (not the value). + | sw NEXT_NIL, NEXT_RES_KEY_IT + | move NEXT_RES_VK, NEXT_RES_PTR + |9: + | jr ra + |. addu NEXT_RES_IDX, NEXT_RES_IDX, NEXT_ASIZE + |.endif + | + |//----------------------------------------------------------------------- + |//-- FFI helper functions ----------------------------------------------- + |//----------------------------------------------------------------------- + | + |// Handler for callback functions. Callback slot number in r1, g in r2. + |->vm_ffi_callback: + |.if FFI + |.type CTSTATE, CTState, PC + | saveregs + | lw CTSTATE, GL:r2->ctype_state + | addiu DISPATCH, r2, GG_G2DISP + | load_got lj_ccallback_enter + | sw r1, CTSTATE->cb.slot + | sw CARG1, CTSTATE->cb.gpr[0] + | sw CARG2, CTSTATE->cb.gpr[1] + | .FPU sdc1 FARG1, CTSTATE->cb.fpr[0] + | sw CARG3, CTSTATE->cb.gpr[2] + | sw CARG4, CTSTATE->cb.gpr[3] + | .FPU sdc1 FARG2, CTSTATE->cb.fpr[1] + | addiu TMP0, sp, CFRAME_SPACE+16 + | sw TMP0, CTSTATE->cb.stack + | sw r0, SAVE_PC // Any value outside of bytecode is ok. + | move CARG2, sp + | call_intern lj_ccallback_enter // (CTState *cts, void *cf) + |. move CARG1, CTSTATE + | // Returns lua_State *. + | lw BASE, L:CRET1->base + | lw RC, L:CRET1->top + | li TISNUM, LJ_TISNUM // Setup type comparison constants. + | move L, CRET1 + | .FPU lui TMP3, 0x59c0 // TOBIT = 2^52 + 2^51 (float). + | lw LFUNC:RB, FRAME_FUNC(BASE) + | .FPU mtc1 TMP3, TOBIT + | li_vmstate INTERP + | li TISNIL, LJ_TNIL + | subu RC, RC, BASE + | st_vmstate + | .FPU cvt.d.s TOBIT, TOBIT + | ins_callt + |.endif + | + |->cont_ffi_callback: // Return from FFI callback. + |.if FFI + | load_got lj_ccallback_leave + | lw CTSTATE, DISPATCH_GL(ctype_state)(DISPATCH) + | sw BASE, L->base + | sw RB, L->top + | sw L, CTSTATE->L + | move CARG2, RA + | call_intern lj_ccallback_leave // (CTState *cts, TValue *o) + |. move CARG1, CTSTATE + | .FPU ldc1 FRET1, CTSTATE->cb.fpr[0] + | lw CRET1, CTSTATE->cb.gpr[0] + | .FPU ldc1 FRET2, CTSTATE->cb.fpr[1] + | b ->vm_leave_unw + |. lw CRET2, CTSTATE->cb.gpr[1] + |.endif + | + |->vm_ffi_call: // Call C function via FFI. + | // Caveat: needs special frame unwinding, see below. + |.if FFI + | .type CCSTATE, CCallState, CARG1 + | lw TMP1, CCSTATE->spadj + | lbu CARG2, CCSTATE->nsp + | move TMP2, sp + | subu sp, sp, TMP1 + | sw ra, -4(TMP2) + | sll CARG2, CARG2, 2 + | sw r16, -8(TMP2) + | sw CCSTATE, -12(TMP2) + | move r16, TMP2 + | addiu TMP1, CCSTATE, offsetof(CCallState, stack) + | addiu TMP2, sp, 16 + | beqz CARG2, >2 + |. addu TMP3, TMP1, CARG2 + |1: + | lw TMP0, 0(TMP1) + | addiu TMP1, TMP1, 4 + | sltu AT, TMP1, TMP3 + | sw TMP0, 0(TMP2) + | bnez AT, <1 + |. addiu TMP2, TMP2, 4 + |2: + | lw CFUNCADDR, CCSTATE->func + | lw CARG2, CCSTATE->gpr[1] + | lw CARG3, CCSTATE->gpr[2] + | lw CARG4, CCSTATE->gpr[3] + | .FPU ldc1 FARG1, CCSTATE->fpr[0] + | .FPU ldc1 FARG2, CCSTATE->fpr[1] + | jalr CFUNCADDR + |. lw CARG1, CCSTATE->gpr[0] // Do this last, since CCSTATE is CARG1. + | lw CCSTATE:TMP1, -12(r16) + | lw TMP2, -8(r16) + | lw ra, -4(r16) + | sw CRET1, CCSTATE:TMP1->gpr[0] + | sw CRET2, CCSTATE:TMP1->gpr[1] + |.if FPU + | sdc1 FRET1, CCSTATE:TMP1->fpr[0] + | sdc1 FRET2, CCSTATE:TMP1->fpr[1] + |.else + | sw CARG1, CCSTATE:TMP1->gpr[2] // Soft-float: complex double .im part. + | sw CARG2, CCSTATE:TMP1->gpr[3] + |.endif + | move sp, r16 + | jr ra + |. move r16, TMP2 + |.endif + |// Note: vm_ffi_call must be the last function in this object file! + | + |//----------------------------------------------------------------------- +} + +/* Generate the code for a single instruction. */ +static void build_ins(BuildCtx *ctx, BCOp op, int defop) +{ + int vk = 0; + |=>defop: + + switch (op) { + + /* -- Comparison ops ---------------------------------------------------- */ + + /* Remember: all ops branch for a true comparison, fall through otherwise. */ + + case BC_ISLT: case BC_ISGE: case BC_ISLE: case BC_ISGT: + | // RA = src1*8, RD = src2*8, JMP with RD = target + |.macro bc_comp, FRA, FRD, RAHI, RALO, RDHI, RDLO, movop, fmovop, fcomp, sfcomp + | addu RA, BASE, RA + | addu RD, BASE, RD + | lw RAHI, HI(RA) + | lw RDHI, HI(RD) + | lhu TMP2, OFS_RD(PC) + | addiu PC, PC, 4 + | bne RAHI, TISNUM, >2 + |. lw RALO, LO(RA) + | lui TMP3, (-(BCBIAS_J*4 >> 16) & 65535) + | lw RDLO, LO(RD) + | bne RDHI, TISNUM, >5 + |. decode_RD4b TMP2 + | slt AT, SFARG1LO, SFARG2LO + | addu TMP2, TMP2, TMP3 + | movop TMP2, r0, AT + |1: + | addu PC, PC, TMP2 + | ins_next + | + |2: // RA is not an integer. + | sltiu AT, RAHI, LJ_TISNUM + | beqz AT, ->vmeta_comp + |. lui TMP3, (-(BCBIAS_J*4 >> 16) & 65535) + | sltiu AT, RDHI, LJ_TISNUM + |.if FPU + | ldc1 FRA, 0(RA) + | ldc1 FRD, 0(RD) + |.else + | lw RDLO, LO(RD) + |.endif + | beqz AT, >4 + |. decode_RD4b TMP2 + |3: // RA and RD are both numbers. + |.if FPU + | fcomp f20, f22 + | addu TMP2, TMP2, TMP3 + | b <1 + |. fmovop TMP2, r0 + |.else + | bal sfcomp + |. addu TMP2, TMP2, TMP3 + | b <1 + |. movop TMP2, r0, CRET1 + |.endif + | + |4: // RA is a number, RD is not a number. + | bne RDHI, TISNUM, ->vmeta_comp + | // RA is a number, RD is an integer. Convert RD to a number. + |.if FPU + |. lwc1 FRD, LO(RD) + | b <3 + |. cvt.d.w FRD, FRD + |.else + |. nop + |.if "RDHI" == "SFARG1HI" + | bal ->vm_sfi2d_1 + |.else + | bal ->vm_sfi2d_2 + |.endif + |. nop + | b <3 + |. nop + |.endif + | + |5: // RA is an integer, RD is not an integer + | sltiu AT, RDHI, LJ_TISNUM + | beqz AT, ->vmeta_comp + | // RA is an integer, RD is a number. Convert RA to a number. + |.if FPU + |. mtc1 RALO, FRA + | ldc1 FRD, 0(RD) + | b <3 + | cvt.d.w FRA, FRA + |.else + |. nop + |.if "RAHI" == "SFARG1HI" + | bal ->vm_sfi2d_1 + |.else + | bal ->vm_sfi2d_2 + |.endif + |. nop + | b <3 + |. nop + |.endif + |.endmacro + | + if (op == BC_ISLT) { + | bc_comp f20, f22, SFARG1HI, SFARG1LO, SFARG2HI, SFARG2LO, movz, movf, c.olt.d, ->vm_sfcmpolt + } else if (op == BC_ISGE) { + | bc_comp f20, f22, SFARG1HI, SFARG1LO, SFARG2HI, SFARG2LO, movn, movt, c.olt.d, ->vm_sfcmpolt + } else if (op == BC_ISLE) { + | bc_comp f22, f20, SFARG2HI, SFARG2LO, SFARG1HI, SFARG1LO, movn, movt, c.ult.d, ->vm_sfcmpult + } else { + | bc_comp f22, f20, SFARG2HI, SFARG2LO, SFARG1HI, SFARG1LO, movz, movf, c.ult.d, ->vm_sfcmpult + } + break; + + case BC_ISEQV: case BC_ISNEV: + vk = op == BC_ISEQV; + | // RA = src1*8, RD = src2*8, JMP with RD = target + | addu RA, BASE, RA + | addiu PC, PC, 4 + | addu RD, BASE, RD + | lw SFARG1HI, HI(RA) + | lhu TMP2, -4+OFS_RD(PC) + | lw SFARG2HI, HI(RD) + | lui TMP3, (-(BCBIAS_J*4 >> 16) & 65535) + | sltu AT, TISNUM, SFARG1HI + | sltu TMP0, TISNUM, SFARG2HI + | or AT, AT, TMP0 + if (vk) { + | beqz AT, ->BC_ISEQN_Z + } else { + | beqz AT, ->BC_ISNEN_Z + } + |. decode_RD4b TMP2 + | // Either or both types are not numbers. + | lw SFARG1LO, LO(RA) + | lw SFARG2LO, LO(RD) + | addu TMP2, TMP2, TMP3 + |.if FFI + | li TMP3, LJ_TCDATA + | beq SFARG1HI, TMP3, ->vmeta_equal_cd + |.endif + |. sltiu AT, SFARG1HI, LJ_TISPRI // Not a primitive? + |.if FFI + | beq SFARG2HI, TMP3, ->vmeta_equal_cd + |.endif + |. xor TMP3, SFARG1LO, SFARG2LO // Same tv? + | xor SFARG2HI, SFARG2HI, SFARG1HI // Same type? + | sltiu TMP0, SFARG1HI, LJ_TISTABUD+1 // Table or userdata? + | movz TMP3, r0, AT // Ignore tv if primitive. + | movn TMP0, r0, SFARG2HI // Tab/ud and same type? + | or AT, SFARG2HI, TMP3 // Same type && (pri||same tv). + | movz TMP0, r0, AT + | beqz TMP0, >1 // Done if not tab/ud or not same type or same tv. + if (vk) { + |. movn TMP2, r0, AT + } else { + |. movz TMP2, r0, AT + } + | // Different tables or userdatas. Need to check __eq metamethod. + | // Field metatable must be at same offset for GCtab and GCudata! + | lw TAB:TMP1, TAB:SFARG1LO->metatable + | beqz TAB:TMP1, >1 // No metatable? + |. nop + | lbu TMP1, TAB:TMP1->nomm + | andi TMP1, TMP1, 1<1 // Or 'no __eq' flag set? + |. nop + | b ->vmeta_equal // Handle __eq metamethod. + |. li TMP0, 1-vk // ne = 0 or 1. + |1: + | addu PC, PC, TMP2 + | ins_next + break; + + case BC_ISEQS: case BC_ISNES: + vk = op == BC_ISEQS; + | // RA = src*8, RD = str_const*8 (~), JMP with RD = target + | addu RA, BASE, RA + | addiu PC, PC, 4 + | lw TMP0, HI(RA) + | srl RD, RD, 1 + | lw STR:TMP3, LO(RA) + | subu RD, KBASE, RD + | lhu TMP2, -4+OFS_RD(PC) + |.if FFI + | li AT, LJ_TCDATA + | beq TMP0, AT, ->vmeta_equal_cd + |.endif + |. lw STR:TMP1, -4(RD) // KBASE-4-str_const*4 + | addiu TMP0, TMP0, -LJ_TSTR + | decode_RD4b TMP2 + | xor TMP1, STR:TMP1, STR:TMP3 + | or TMP0, TMP0, TMP1 + | lui TMP3, (-(BCBIAS_J*4 >> 16) & 65535) + | addu TMP2, TMP2, TMP3 + if (vk) { + | movn TMP2, r0, TMP0 + } else { + | movz TMP2, r0, TMP0 + } + | addu PC, PC, TMP2 + | ins_next + break; + + case BC_ISEQN: case BC_ISNEN: + vk = op == BC_ISEQN; + | // RA = src*8, RD = num_const*8, JMP with RD = target + | addu RA, BASE, RA + | addu RD, KBASE, RD + | lw SFARG1HI, HI(RA) + | lw SFARG2HI, HI(RD) + | lhu TMP2, OFS_RD(PC) + | addiu PC, PC, 4 + | lui TMP3, (-(BCBIAS_J*4 >> 16) & 65535) + | decode_RD4b TMP2 + if (vk) { + |->BC_ISEQN_Z: + } else { + |->BC_ISNEN_Z: + } + | bne SFARG1HI, TISNUM, >3 + |. lw SFARG1LO, LO(RA) + | lw SFARG2LO, LO(RD) + | addu TMP2, TMP2, TMP3 + | bne SFARG2HI, TISNUM, >6 + |. xor AT, SFARG1LO, SFARG2LO + if (vk) { + | movn TMP2, r0, AT + |1: + | addu PC, PC, TMP2 + |2: + } else { + | movz TMP2, r0, AT + |1: + |2: + | addu PC, PC, TMP2 + } + | ins_next + | + |3: // RA is not an integer. + | sltiu AT, SFARG1HI, LJ_TISNUM + |.if FFI + | beqz AT, >8 + |.else + | beqz AT, <2 + |.endif + |. addu TMP2, TMP2, TMP3 + | sltiu AT, SFARG2HI, LJ_TISNUM + |.if FPU + | ldc1 f20, 0(RA) + | ldc1 f22, 0(RD) + |.endif + | beqz AT, >5 + |. lw SFARG2LO, LO(RD) + |4: // RA and RD are both numbers. + |.if FPU + | c.eq.d f20, f22 + | b <1 + if (vk) { + |. movf TMP2, r0 + } else { + |. movt TMP2, r0 + } + |.else + | bal ->vm_sfcmpeq + |. nop + | b <1 + if (vk) { + |. movz TMP2, r0, CRET1 + } else { + |. movn TMP2, r0, CRET1 + } + |.endif + | + |5: // RA is a number, RD is not a number. + |.if FFI + | bne SFARG2HI, TISNUM, >9 + |.else + | bne SFARG2HI, TISNUM, <2 + |.endif + | // RA is a number, RD is an integer. Convert RD to a number. + |.if FPU + |. lwc1 f22, LO(RD) + | b <4 + |. cvt.d.w f22, f22 + |.else + |. nop + | bal ->vm_sfi2d_2 + |. nop + | b <4 + |. nop + |.endif + | + |6: // RA is an integer, RD is not an integer + | sltiu AT, SFARG2HI, LJ_TISNUM + |.if FFI + | beqz AT, >9 + |.else + | beqz AT, <2 + |.endif + | // RA is an integer, RD is a number. Convert RA to a number. + |.if FPU + |. mtc1 SFARG1LO, f20 + | ldc1 f22, 0(RD) + | b <4 + | cvt.d.w f20, f20 + |.else + |. nop + | bal ->vm_sfi2d_1 + |. nop + | b <4 + |. nop + |.endif + | + |.if FFI + |8: + | li AT, LJ_TCDATA + | bne SFARG1HI, AT, <2 + |. nop + | b ->vmeta_equal_cd + |. nop + |9: + | li AT, LJ_TCDATA + | bne SFARG2HI, AT, <2 + |. nop + | b ->vmeta_equal_cd + |. nop + |.endif + break; + + case BC_ISEQP: case BC_ISNEP: + vk = op == BC_ISEQP; + | // RA = src*8, RD = primitive_type*8 (~), JMP with RD = target + | addu RA, BASE, RA + | srl TMP1, RD, 3 + | lw TMP0, HI(RA) + | lhu TMP2, OFS_RD(PC) + | not TMP1, TMP1 + | addiu PC, PC, 4 + |.if FFI + | li AT, LJ_TCDATA + | beq TMP0, AT, ->vmeta_equal_cd + |.endif + |. xor TMP0, TMP0, TMP1 + | decode_RD4b TMP2 + | lui TMP3, (-(BCBIAS_J*4 >> 16) & 65535) + | addu TMP2, TMP2, TMP3 + if (vk) { + | movn TMP2, r0, TMP0 + } else { + | movz TMP2, r0, TMP0 + } + | addu PC, PC, TMP2 + | ins_next + break; + + /* -- Unary test and copy ops ------------------------------------------- */ + + case BC_ISTC: case BC_ISFC: case BC_IST: case BC_ISF: + | // RA = dst*8 or unused, RD = src*8, JMP with RD = target + | addu RD, BASE, RD + | lhu TMP2, OFS_RD(PC) + | lw TMP0, HI(RD) + | addiu PC, PC, 4 + if (op == BC_IST || op == BC_ISF) { + | sltiu TMP0, TMP0, LJ_TISTRUECOND + | decode_RD4b TMP2 + | lui TMP3, (-(BCBIAS_J*4 >> 16) & 65535) + | addu TMP2, TMP2, TMP3 + if (op == BC_IST) { + | movz TMP2, r0, TMP0 + } else { + | movn TMP2, r0, TMP0 + } + | addu PC, PC, TMP2 + } else { + | sltiu TMP0, TMP0, LJ_TISTRUECOND + | lw SFRETHI, HI(RD) + | lw SFRETLO, LO(RD) + if (op == BC_ISTC) { + | beqz TMP0, >1 + } else { + | bnez TMP0, >1 + } + |. addu RA, BASE, RA + | decode_RD4b TMP2 + | lui TMP3, (-(BCBIAS_J*4 >> 16) & 65535) + | addu TMP2, TMP2, TMP3 + | sw SFRETHI, HI(RA) + | sw SFRETLO, LO(RA) + | addu PC, PC, TMP2 + |1: + } + | ins_next + break; + + case BC_ISTYPE: + | // RA = src*8, RD = -type*8 + | addu TMP2, BASE, RA + | srl TMP1, RD, 3 + | lw TMP0, HI(TMP2) + | ins_next1 + | addu AT, TMP0, TMP1 + | bnez AT, ->vmeta_istype + |. ins_next2 + break; + case BC_ISNUM: + | // RA = src*8, RD = -(TISNUM-1)*8 + | addu TMP2, BASE, RA + | lw TMP0, HI(TMP2) + | ins_next1 + | sltiu AT, TMP0, LJ_TISNUM + | beqz AT, ->vmeta_istype + |. ins_next2 + break; + + /* -- Unary ops --------------------------------------------------------- */ + + case BC_MOV: + | // RA = dst*8, RD = src*8 + | addu RD, BASE, RD + | addu RA, BASE, RA + | lw SFRETHI, HI(RD) + | lw SFRETLO, LO(RD) + | ins_next1 + | sw SFRETHI, HI(RA) + | sw SFRETLO, LO(RA) + | ins_next2 + break; + case BC_NOT: + | // RA = dst*8, RD = src*8 + | addu RD, BASE, RD + | addu RA, BASE, RA + | lw TMP0, HI(RD) + | li TMP1, LJ_TFALSE + | sltiu TMP0, TMP0, LJ_TISTRUECOND + | addiu TMP1, TMP0, LJ_TTRUE + | ins_next1 + | sw TMP1, HI(RA) + | ins_next2 + break; + case BC_UNM: + | // RA = dst*8, RD = src*8 + | addu RB, BASE, RD + | lw SFARG1HI, HI(RB) + | addu RA, BASE, RA + | bne SFARG1HI, TISNUM, >2 + |. lw SFARG1LO, LO(RB) + | lui TMP1, 0x8000 + | beq SFARG1LO, TMP1, ->vmeta_unm // Meta handler deals with -2^31. + |. negu SFARG1LO, SFARG1LO + |1: + | ins_next1 + | sw SFARG1HI, HI(RA) + | sw SFARG1LO, LO(RA) + | ins_next2 + |2: + | sltiu AT, SFARG1HI, LJ_TISNUM + | beqz AT, ->vmeta_unm + |. lui TMP1, 0x8000 + | b <1 + |. xor SFARG1HI, SFARG1HI, TMP1 + break; + case BC_LEN: + | // RA = dst*8, RD = src*8 + | addu CARG2, BASE, RD + | addu RA, BASE, RA + | lw TMP0, HI(CARG2) + | lw CARG1, LO(CARG2) + | li AT, LJ_TSTR + | bne TMP0, AT, >2 + |. li AT, LJ_TTAB + | lw CRET1, STR:CARG1->len + |1: + | ins_next1 + | sw TISNUM, HI(RA) + | sw CRET1, LO(RA) + | ins_next2 + |2: + | bne TMP0, AT, ->vmeta_len + |. nop +#if LJ_52 + | lw TAB:TMP2, TAB:CARG1->metatable + | bnez TAB:TMP2, >9 + |. nop + |3: +#endif + |->BC_LEN_Z: + | load_got lj_tab_len + | call_intern lj_tab_len // (GCtab *t) + |. nop + | // Returns uint32_t (but less than 2^31). + | b <1 + |. nop +#if LJ_52 + |9: + | lbu TMP0, TAB:TMP2->nomm + | andi TMP0, TMP0, 1<vmeta_len + |. nop +#endif + break; + + /* -- Binary ops -------------------------------------------------------- */ + + |.macro fpmod, a, b, c + | bal ->vm_floor // floor(b/c) + |. div.d FARG1, b, c + | mul.d a, FRET1, c + | sub.d a, b, a // b - floor(b/c)*c + |.endmacro + + |.macro sfpmod + | addiu sp, sp, -16 + | + | load_got __divdf3 + | sw SFARG1HI, HI(sp) + | sw SFARG1LO, LO(sp) + | sw SFARG2HI, 8+HI(sp) + | call_extern + |. sw SFARG2LO, 8+LO(sp) + | + | load_got floor + | move SFARG1HI, SFRETHI + | call_extern + |. move SFARG1LO, SFRETLO + | + | load_got __muldf3 + | move SFARG1HI, SFRETHI + | move SFARG1LO, SFRETLO + | lw SFARG2HI, 8+HI(sp) + | call_extern + |. lw SFARG2LO, 8+LO(sp) + | + | load_got __subdf3 + | lw SFARG1HI, HI(sp) + | lw SFARG1LO, LO(sp) + | move SFARG2HI, SFRETHI + | call_extern + |. move SFARG2LO, SFRETLO + | + | addiu sp, sp, 16 + |.endmacro + + |.macro ins_arithpre, label + ||vk = ((int)op - BC_ADDVN) / (BC_ADDNV-BC_ADDVN); + | // RA = dst*8, RB = src1*8, RC = src2*8 | num_const*8 + ||switch (vk) { + ||case 0: + | decode_RB8a RB, INS + | decode_RB8b RB + | decode_RDtoRC8 RC, RD + | // RA = dst*8, RB = src1*8, RC = num_const*8 + | addu RB, BASE, RB + |.if "label" ~= "none" + | b label + |.endif + |. addu RC, KBASE, RC + || break; + ||case 1: + | decode_RB8a RC, INS + | decode_RB8b RC + | decode_RDtoRC8 RB, RD + | // RA = dst*8, RB = num_const*8, RC = src1*8 + | addu RC, BASE, RC + |.if "label" ~= "none" + | b label + |.endif + |. addu RB, KBASE, RB + || break; + ||default: + | decode_RB8a RB, INS + | decode_RB8b RB + | decode_RDtoRC8 RC, RD + | // RA = dst*8, RB = src1*8, RC = src2*8 + | addu RB, BASE, RB + |.if "label" ~= "none" + | b label + |.endif + |. addu RC, BASE, RC + || break; + ||} + |.endmacro + | + |.macro ins_arith, intins, fpins, fpcall, label + | ins_arithpre none + | + |.if "label" ~= "none" + |label: + |.endif + | + | lw SFARG1HI, HI(RB) + | lw SFARG2HI, HI(RC) + | + |.if "intins" ~= "div" + | + | // Check for two integers. + | lw SFARG1LO, LO(RB) + | bne SFARG1HI, TISNUM, >5 + |. lw SFARG2LO, LO(RC) + | bne SFARG2HI, TISNUM, >5 + | + |.if "intins" == "addu" + |. intins CRET1, SFARG1LO, SFARG2LO + | xor TMP1, CRET1, SFARG1LO // ((y^a) & (y^b)) < 0: overflow. + | xor TMP2, CRET1, SFARG2LO + | and TMP1, TMP1, TMP2 + | bltz TMP1, ->vmeta_arith + |. addu RA, BASE, RA + |.elif "intins" == "subu" + |. intins CRET1, SFARG1LO, SFARG2LO + | xor TMP1, CRET1, SFARG1LO // ((y^a) & (a^b)) < 0: overflow. + | xor TMP2, SFARG1LO, SFARG2LO + | and TMP1, TMP1, TMP2 + | bltz TMP1, ->vmeta_arith + |. addu RA, BASE, RA + |.elif "intins" == "mult" + |. intins SFARG1LO, SFARG2LO + | mflo CRET1 + | mfhi TMP2 + | sra TMP1, CRET1, 31 + | bne TMP1, TMP2, ->vmeta_arith + |. addu RA, BASE, RA + |.else + |. load_got lj_vm_modi + | beqz SFARG2LO, ->vmeta_arith + |. addu RA, BASE, RA + |.if ENDIAN_BE + | move CARG1, SFARG1LO + |.endif + | call_extern + |. move CARG2, SFARG2LO + |.endif + | + | ins_next1 + | sw TISNUM, HI(RA) + | sw CRET1, LO(RA) + |3: + | ins_next2 + | + |.elif not FPU + | + | lw SFARG1LO, LO(RB) + | lw SFARG2LO, LO(RC) + | + |.endif + | + |5: // Check for two numbers. + | .FPU ldc1 f20, 0(RB) + | sltiu AT, SFARG1HI, LJ_TISNUM + | sltiu TMP0, SFARG2HI, LJ_TISNUM + | .FPU ldc1 f22, 0(RC) + | and AT, AT, TMP0 + | beqz AT, ->vmeta_arith + |. addu RA, BASE, RA + | + |.if FPU + | fpins FRET1, f20, f22 + |.elif "fpcall" == "sfpmod" + | sfpmod + |.else + | load_got fpcall + | call_extern + |. nop + |.endif + | + | ins_next1 + |.if not FPU + | sw SFRETHI, HI(RA) + |.endif + |.if "intins" ~= "div" + | b <3 + |.endif + |.if FPU + |. sdc1 FRET1, 0(RA) + |.else + |. sw SFRETLO, LO(RA) + |.endif + |.if "intins" == "div" + | ins_next2 + |.endif + | + |.endmacro + + case BC_ADDVN: case BC_ADDNV: case BC_ADDVV: + | ins_arith addu, add.d, __adddf3, none + break; + case BC_SUBVN: case BC_SUBNV: case BC_SUBVV: + | ins_arith subu, sub.d, __subdf3, none + break; + case BC_MULVN: case BC_MULNV: case BC_MULVV: + | ins_arith mult, mul.d, __muldf3, none + break; + case BC_DIVVN: + | ins_arith div, div.d, __divdf3, ->BC_DIVVN_Z + break; + case BC_DIVNV: case BC_DIVVV: + | ins_arithpre ->BC_DIVVN_Z + break; + case BC_MODVN: + | ins_arith modi, fpmod, sfpmod, ->BC_MODVN_Z + break; + case BC_MODNV: case BC_MODVV: + | ins_arithpre ->BC_MODVN_Z + break; + case BC_POW: + | ins_arithpre none + | lw SFARG1HI, HI(RB) + | lw SFARG2HI, HI(RC) + | sltiu AT, SFARG1HI, LJ_TISNUM + | sltiu TMP0, SFARG2HI, LJ_TISNUM + | and AT, AT, TMP0 + | load_got pow + | beqz AT, ->vmeta_arith + |. addu RA, BASE, RA + |.if FPU + | ldc1 FARG1, 0(RB) + | ldc1 FARG2, 0(RC) + |.else + | lw SFARG1LO, LO(RB) + | lw SFARG2LO, LO(RC) + |.endif + | call_extern + |. nop + | ins_next1 + |.if FPU + | sdc1 FRET1, 0(RA) + |.else + | sw SFRETHI, HI(RA) + | sw SFRETLO, LO(RA) + |.endif + | ins_next2 + break; + + case BC_CAT: + | // RA = dst*8, RB = src_start*8, RC = src_end*8 + | decode_RB8a RB, INS + | decode_RB8b RB + | decode_RDtoRC8 RC, RD + | subu CARG3, RC, RB + | sw BASE, L->base + | addu CARG2, BASE, RC + | move MULTRES, RB + |->BC_CAT_Z: + | load_got lj_meta_cat + | srl CARG3, CARG3, 3 + | sw PC, SAVE_PC + | call_intern lj_meta_cat // (lua_State *L, TValue *top, int left) + |. move CARG1, L + | // Returns NULL (finished) or TValue * (metamethod). + | bnez CRET1, ->vmeta_binop + |. lw BASE, L->base + | addu RB, BASE, MULTRES + | lw SFRETHI, HI(RB) + | lw SFRETLO, LO(RB) + | addu RA, BASE, RA + | ins_next1 + | sw SFRETHI, HI(RA) + | sw SFRETLO, LO(RA) + | ins_next2 + break; + + /* -- Constant ops ------------------------------------------------------ */ + + case BC_KSTR: + | // RA = dst*8, RD = str_const*8 (~) + | srl TMP1, RD, 1 + | subu TMP1, KBASE, TMP1 + | ins_next1 + | lw TMP0, -4(TMP1) // KBASE-4-str_const*4 + | addu RA, BASE, RA + | li TMP2, LJ_TSTR + | sw TMP0, LO(RA) + | sw TMP2, HI(RA) + | ins_next2 + break; + case BC_KCDATA: + |.if FFI + | // RA = dst*8, RD = cdata_const*8 (~) + | srl TMP1, RD, 1 + | subu TMP1, KBASE, TMP1 + | ins_next1 + | lw TMP0, -4(TMP1) // KBASE-4-cdata_const*4 + | addu RA, BASE, RA + | li TMP2, LJ_TCDATA + | sw TMP0, LO(RA) + | sw TMP2, HI(RA) + | ins_next2 + |.endif + break; + case BC_KSHORT: + | // RA = dst*8, RD = int16_literal*8 + | sra RD, INS, 16 + | addu RA, BASE, RA + | ins_next1 + | sw TISNUM, HI(RA) + | sw RD, LO(RA) + | ins_next2 + break; + case BC_KNUM: + | // RA = dst*8, RD = num_const*8 + | addu RD, KBASE, RD + | addu RA, BASE, RA + | lw SFRETHI, HI(RD) + | lw SFRETLO, LO(RD) + | ins_next1 + | sw SFRETHI, HI(RA) + | sw SFRETLO, LO(RA) + | ins_next2 + break; + case BC_KPRI: + | // RA = dst*8, RD = primitive_type*8 (~) + | srl TMP1, RD, 3 + | addu RA, BASE, RA + | not TMP0, TMP1 + | ins_next1 + | sw TMP0, HI(RA) + | ins_next2 + break; + case BC_KNIL: + | // RA = base*8, RD = end*8 + | addu RA, BASE, RA + | sw TISNIL, HI(RA) + | addiu RA, RA, 8 + | addu RD, BASE, RD + |1: + | sw TISNIL, HI(RA) + | slt AT, RA, RD + | bnez AT, <1 + |. addiu RA, RA, 8 + | ins_next_ + break; + + /* -- Upvalue and function ops ------------------------------------------ */ + + case BC_UGET: + | // RA = dst*8, RD = uvnum*8 + | lw LFUNC:RB, FRAME_FUNC(BASE) + | srl RD, RD, 1 + | addu RD, RD, LFUNC:RB + | lw UPVAL:RB, LFUNC:RD->uvptr + | ins_next1 + | lw TMP1, UPVAL:RB->v + | lw SFRETHI, HI(TMP1) + | lw SFRETLO, LO(TMP1) + | addu RA, BASE, RA + | sw SFRETHI, HI(RA) + | sw SFRETLO, LO(RA) + | ins_next2 + break; + case BC_USETV: + | // RA = uvnum*8, RD = src*8 + | lw LFUNC:RB, FRAME_FUNC(BASE) + | srl RA, RA, 1 + | addu RD, BASE, RD + | addu RA, RA, LFUNC:RB + | lw UPVAL:RB, LFUNC:RA->uvptr + | lw SFRETHI, HI(RD) + | lw SFRETLO, LO(RD) + | lbu TMP3, UPVAL:RB->marked + | lw CARG2, UPVAL:RB->v + | andi TMP3, TMP3, LJ_GC_BLACK // isblack(uv) + | lbu TMP0, UPVAL:RB->closed + | sw SFRETHI, HI(CARG2) + | sw SFRETLO, LO(CARG2) + | li AT, LJ_GC_BLACK|1 + | or TMP3, TMP3, TMP0 + | beq TMP3, AT, >2 // Upvalue is closed and black? + |. addiu TMP2, SFRETHI, -(LJ_TNUMX+1) + |1: + | ins_next + | + |2: // Check if new value is collectable. + | sltiu AT, TMP2, LJ_TISGCV - (LJ_TNUMX+1) + | beqz AT, <1 // tvisgcv(v) + |. nop + | lbu TMP3, GCOBJ:SFRETLO->gch.marked + | andi TMP3, TMP3, LJ_GC_WHITES // iswhite(v) + | beqz TMP3, <1 + |. load_got lj_gc_barrieruv + | // Crossed a write barrier. Move the barrier forward. + | call_intern lj_gc_barrieruv // (global_State *g, TValue *tv) + |. addiu CARG1, DISPATCH, GG_DISP2G + | b <1 + |. nop + break; + case BC_USETS: + | // RA = uvnum*8, RD = str_const*8 (~) + | lw LFUNC:RB, FRAME_FUNC(BASE) + | srl RA, RA, 1 + | srl TMP1, RD, 1 + | addu RA, RA, LFUNC:RB + | subu TMP1, KBASE, TMP1 + | lw UPVAL:RB, LFUNC:RA->uvptr + | lw STR:TMP1, -4(TMP1) // KBASE-4-str_const*4 + | lbu TMP2, UPVAL:RB->marked + | lw CARG2, UPVAL:RB->v + | lbu TMP3, STR:TMP1->marked + | andi AT, TMP2, LJ_GC_BLACK // isblack(uv) + | lbu TMP2, UPVAL:RB->closed + | li TMP0, LJ_TSTR + | sw STR:TMP1, LO(CARG2) + | bnez AT, >2 + |. sw TMP0, HI(CARG2) + |1: + | ins_next + | + |2: // Check if string is white and ensure upvalue is closed. + | beqz TMP2, <1 + |. andi AT, TMP3, LJ_GC_WHITES // iswhite(str) + | beqz AT, <1 + |. load_got lj_gc_barrieruv + | // Crossed a write barrier. Move the barrier forward. + | call_intern lj_gc_barrieruv // (global_State *g, TValue *tv) + |. addiu CARG1, DISPATCH, GG_DISP2G + | b <1 + |. nop + break; + case BC_USETN: + | // RA = uvnum*8, RD = num_const*8 + | lw LFUNC:RB, FRAME_FUNC(BASE) + | srl RA, RA, 1 + | addu RD, KBASE, RD + | addu RA, RA, LFUNC:RB + | lw UPVAL:RB, LFUNC:RA->uvptr + | lw SFRETHI, HI(RD) + | lw SFRETLO, LO(RD) + | lw TMP1, UPVAL:RB->v + | ins_next1 + | sw SFRETHI, HI(TMP1) + | sw SFRETLO, LO(TMP1) + | ins_next2 + break; + case BC_USETP: + | // RA = uvnum*8, RD = primitive_type*8 (~) + | lw LFUNC:RB, FRAME_FUNC(BASE) + | srl RA, RA, 1 + | srl TMP0, RD, 3 + | addu RA, RA, LFUNC:RB + | not TMP0, TMP0 + | lw UPVAL:RB, LFUNC:RA->uvptr + | ins_next1 + | lw TMP1, UPVAL:RB->v + | sw TMP0, HI(TMP1) + | ins_next2 + break; + + case BC_UCLO: + | // RA = level*8, RD = target + | lw TMP2, L->openupval + | branch_RD // Do this first since RD is not saved. + | load_got lj_func_closeuv + | sw BASE, L->base + | beqz TMP2, >1 + |. move CARG1, L + | call_intern lj_func_closeuv // (lua_State *L, TValue *level) + |. addu CARG2, BASE, RA + | lw BASE, L->base + |1: + | ins_next + break; + + case BC_FNEW: + | // RA = dst*8, RD = proto_const*8 (~) (holding function prototype) + | srl TMP1, RD, 1 + | load_got lj_func_newL_gc + | subu TMP1, KBASE, TMP1 + | lw CARG3, FRAME_FUNC(BASE) + | lw CARG2, -4(TMP1) // KBASE-4-tab_const*4 + | sw BASE, L->base + | sw PC, SAVE_PC + | // (lua_State *L, GCproto *pt, GCfuncL *parent) + | call_intern lj_func_newL_gc + |. move CARG1, L + | // Returns GCfuncL *. + | lw BASE, L->base + | li TMP0, LJ_TFUNC + | ins_next1 + | addu RA, BASE, RA + | sw LFUNC:CRET1, LO(RA) + | sw TMP0, HI(RA) + | ins_next2 + break; + + /* -- Table ops --------------------------------------------------------- */ + + case BC_TNEW: + case BC_TDUP: + | // RA = dst*8, RD = (hbits|asize)*8 | tab_const*8 (~) + | lw TMP0, DISPATCH_GL(gc.total)(DISPATCH) + | lw TMP1, DISPATCH_GL(gc.threshold)(DISPATCH) + | sw BASE, L->base + | sw PC, SAVE_PC + | sltu AT, TMP0, TMP1 + | beqz AT, >5 + |1: + if (op == BC_TNEW) { + | load_got lj_tab_new + | srl CARG2, RD, 3 + | andi CARG2, CARG2, 0x7ff + | li TMP0, 0x801 + | addiu AT, CARG2, -0x7ff + | srl CARG3, RD, 14 + | movz CARG2, TMP0, AT + | // (lua_State *L, int32_t asize, uint32_t hbits) + | call_intern lj_tab_new + |. move CARG1, L + | // Returns Table *. + } else { + | load_got lj_tab_dup + | srl TMP1, RD, 1 + | subu TMP1, KBASE, TMP1 + | move CARG1, L + | call_intern lj_tab_dup // (lua_State *L, Table *kt) + |. lw CARG2, -4(TMP1) // KBASE-4-str_const*4 + | // Returns Table *. + } + | lw BASE, L->base + | ins_next1 + | addu RA, BASE, RA + | li TMP0, LJ_TTAB + | sw TAB:CRET1, LO(RA) + | sw TMP0, HI(RA) + | ins_next2 + |5: + | load_got lj_gc_step_fixtop + | move MULTRES, RD + | call_intern lj_gc_step_fixtop // (lua_State *L) + |. move CARG1, L + | b <1 + |. move RD, MULTRES + break; + + case BC_GGET: + | // RA = dst*8, RD = str_const*8 (~) + case BC_GSET: + | // RA = src*8, RD = str_const*8 (~) + | lw LFUNC:TMP2, FRAME_FUNC(BASE) + | srl TMP1, RD, 1 + | subu TMP1, KBASE, TMP1 + | lw TAB:RB, LFUNC:TMP2->env + | lw STR:RC, -4(TMP1) // KBASE-4-str_const*4 + if (op == BC_GGET) { + | b ->BC_TGETS_Z + } else { + | b ->BC_TSETS_Z + } + |. addu RA, BASE, RA + break; + + case BC_TGETV: + | // RA = dst*8, RB = table*8, RC = key*8 + | decode_RB8a RB, INS + | decode_RB8b RB + | decode_RDtoRC8 RC, RD + | addu CARG2, BASE, RB + | addu CARG3, BASE, RC + | lw TMP1, HI(CARG2) + | lw TMP2, HI(CARG3) + | lw TAB:RB, LO(CARG2) + | li AT, LJ_TTAB + | bne TMP1, AT, ->vmeta_tgetv + |. addu RA, BASE, RA + | bne TMP2, TISNUM, >5 + |. lw RC, LO(CARG3) + | lw TMP0, TAB:RB->asize + | lw TMP1, TAB:RB->array + | sltu AT, RC, TMP0 + | sll TMP2, RC, 3 + | beqz AT, ->vmeta_tgetv // Integer key and in array part? + |. addu TMP2, TMP1, TMP2 + | lw SFRETHI, HI(TMP2) + | beq SFRETHI, TISNIL, >2 + |. lw SFRETLO, LO(TMP2) + |1: + | ins_next1 + | sw SFRETHI, HI(RA) + | sw SFRETLO, LO(RA) + | ins_next2 + | + |2: // Check for __index if table value is nil. + | lw TAB:TMP2, TAB:RB->metatable + | beqz TAB:TMP2, <1 // No metatable: done. + |. nop + | lbu TMP0, TAB:TMP2->nomm + | andi TMP0, TMP0, 1<vmeta_tgetv + |. nop + | + |5: + | li AT, LJ_TSTR + | bne TMP2, AT, ->vmeta_tgetv + |. nop + | b ->BC_TGETS_Z // String key? + |. nop + break; + case BC_TGETS: + | // RA = dst*8, RB = table*8, RC = str_const*4 (~) + | decode_RB8a RB, INS + | decode_RB8b RB + | addu CARG2, BASE, RB + | decode_RC4a RC, INS + | lw TMP0, HI(CARG2) + | decode_RC4b RC + | li AT, LJ_TTAB + | lw TAB:RB, LO(CARG2) + | subu CARG3, KBASE, RC + | lw STR:RC, -4(CARG3) // KBASE-4-str_const*4 + | bne TMP0, AT, ->vmeta_tgets1 + |. addu RA, BASE, RA + |->BC_TGETS_Z: + | // TAB:RB = GCtab *, STR:RC = GCstr *, RA = dst*8 + | lw TMP0, TAB:RB->hmask + | lw TMP1, STR:RC->sid + | lw NODE:TMP2, TAB:RB->node + | and TMP1, TMP1, TMP0 // idx = str->sid & tab->hmask + | sll TMP0, TMP1, 5 + | sll TMP1, TMP1, 3 + | subu TMP1, TMP0, TMP1 + | addu NODE:TMP2, NODE:TMP2, TMP1 // node = tab->node + (idx*32-idx*8) + |1: + | lw CARG1, offsetof(Node, key)+HI(NODE:TMP2) + | lw TMP0, offsetof(Node, key)+LO(NODE:TMP2) + | lw NODE:TMP1, NODE:TMP2->next + | lw SFRETHI, offsetof(Node, val)+HI(NODE:TMP2) + | addiu CARG1, CARG1, -LJ_TSTR + | xor TMP0, TMP0, STR:RC + | or AT, CARG1, TMP0 + | bnez AT, >4 + |. lw TAB:TMP3, TAB:RB->metatable + | beq SFRETHI, TISNIL, >5 // Key found, but nil value? + |. lw SFRETLO, offsetof(Node, val)+LO(NODE:TMP2) + |3: + | ins_next1 + | sw SFRETHI, HI(RA) + | sw SFRETLO, LO(RA) + | ins_next2 + | + |4: // Follow hash chain. + | bnez NODE:TMP1, <1 + |. move NODE:TMP2, NODE:TMP1 + | // End of hash chain: key not found, nil result. + | + |5: // Check for __index if table value is nil. + | beqz TAB:TMP3, <3 // No metatable: done. + |. li SFRETHI, LJ_TNIL + | lbu TMP0, TAB:TMP3->nomm + | andi TMP0, TMP0, 1<vmeta_tgets + |. nop + break; + case BC_TGETB: + | // RA = dst*8, RB = table*8, RC = index*8 + | decode_RB8a RB, INS + | decode_RB8b RB + | addu CARG2, BASE, RB + | decode_RDtoRC8 RC, RD + | lw CARG1, HI(CARG2) + | li AT, LJ_TTAB + | lw TAB:RB, LO(CARG2) + | addu RA, BASE, RA + | bne CARG1, AT, ->vmeta_tgetb + |. srl TMP0, RC, 3 + | lw TMP1, TAB:RB->asize + | lw TMP2, TAB:RB->array + | sltu AT, TMP0, TMP1 + | beqz AT, ->vmeta_tgetb + |. addu RC, TMP2, RC + | lw SFRETHI, HI(RC) + | beq SFRETHI, TISNIL, >5 + |. lw SFRETLO, LO(RC) + |1: + | ins_next1 + | sw SFRETHI, HI(RA) + | sw SFRETLO, LO(RA) + | ins_next2 + | + |5: // Check for __index if table value is nil. + | lw TAB:TMP2, TAB:RB->metatable + | beqz TAB:TMP2, <1 // No metatable: done. + |. nop + | lbu TMP1, TAB:TMP2->nomm + | andi TMP1, TMP1, 1<vmeta_tgetb // Caveat: preserve TMP0 and CARG2! + |. nop + break; + case BC_TGETR: + | // RA = dst*8, RB = table*8, RC = key*8 + | decode_RB8a RB, INS + | decode_RB8b RB + | decode_RDtoRC8 RC, RD + | addu RB, BASE, RB + | addu RC, BASE, RC + | lw TAB:CARG1, LO(RB) + | lw CARG2, LO(RC) + | addu RA, BASE, RA + | lw TMP0, TAB:CARG1->asize + | lw TMP1, TAB:CARG1->array + | sltu AT, CARG2, TMP0 + | sll TMP2, CARG2, 3 + | beqz AT, ->vmeta_tgetr // In array part? + |. addu CRET1, TMP1, TMP2 + | lw SFARG2HI, HI(CRET1) + | lw SFARG2LO, LO(CRET1) + |->BC_TGETR_Z: + | ins_next1 + | sw SFARG2HI, HI(RA) + | sw SFARG2LO, LO(RA) + | ins_next2 + break; + + case BC_TSETV: + | // RA = src*8, RB = table*8, RC = key*8 + | decode_RB8a RB, INS + | decode_RB8b RB + | decode_RDtoRC8 RC, RD + | addu CARG2, BASE, RB + | addu CARG3, BASE, RC + | lw TMP1, HI(CARG2) + | lw TMP2, HI(CARG3) + | lw TAB:RB, LO(CARG2) + | li AT, LJ_TTAB + | bne TMP1, AT, ->vmeta_tsetv + |. addu RA, BASE, RA + | bne TMP2, TISNUM, >5 + |. lw RC, LO(CARG3) + | lw TMP0, TAB:RB->asize + | lw TMP1, TAB:RB->array + | sltu AT, RC, TMP0 + | sll TMP2, RC, 3 + | beqz AT, ->vmeta_tsetv // Integer key and in array part? + |. addu TMP1, TMP1, TMP2 + | lw TMP0, HI(TMP1) + | lbu TMP3, TAB:RB->marked + | lw SFRETHI, HI(RA) + | beq TMP0, TISNIL, >3 + |. lw SFRETLO, LO(RA) + |1: + | andi AT, TMP3, LJ_GC_BLACK // isblack(table) + | sw SFRETHI, HI(TMP1) + | bnez AT, >7 + |. sw SFRETLO, LO(TMP1) + |2: + | ins_next + | + |3: // Check for __newindex if previous value is nil. + | lw TAB:TMP2, TAB:RB->metatable + | beqz TAB:TMP2, <1 // No metatable: done. + |. nop + | lbu TMP2, TAB:TMP2->nomm + | andi TMP2, TMP2, 1<vmeta_tsetv + |. nop + | + |5: + | li AT, LJ_TSTR + | bne TMP2, AT, ->vmeta_tsetv + |. nop + | b ->BC_TSETS_Z // String key? + |. nop + | + |7: // Possible table write barrier for the value. Skip valiswhite check. + | barrierback TAB:RB, TMP3, TMP0, <2 + break; + case BC_TSETS: + | // RA = src*8, RB = table*8, RC = str_const*8 (~) + | decode_RB8a RB, INS + | decode_RB8b RB + | addu CARG2, BASE, RB + | decode_RC4a RC, INS + | lw TMP0, HI(CARG2) + | decode_RC4b RC + | li AT, LJ_TTAB + | subu CARG3, KBASE, RC + | lw TAB:RB, LO(CARG2) + | lw STR:RC, -4(CARG3) // KBASE-4-str_const*4 + | bne TMP0, AT, ->vmeta_tsets1 + |. addu RA, BASE, RA + |->BC_TSETS_Z: + | // TAB:RB = GCtab *, STR:RC = GCstr *, RA = BASE+src*8 + | lw TMP0, TAB:RB->hmask + | lw TMP1, STR:RC->sid + | lw NODE:TMP2, TAB:RB->node + | sb r0, TAB:RB->nomm // Clear metamethod cache. + | and TMP1, TMP1, TMP0 // idx = str->sid & tab->hmask + | sll TMP0, TMP1, 5 + | sll TMP1, TMP1, 3 + | subu TMP1, TMP0, TMP1 + | addu NODE:TMP2, NODE:TMP2, TMP1 // node = tab->node + (idx*32-idx*8) + |.if FPU + | ldc1 f20, 0(RA) + |.else + | lw SFRETHI, HI(RA) + | lw SFRETLO, LO(RA) + |.endif + |1: + | lw CARG1, offsetof(Node, key)+HI(NODE:TMP2) + | lw TMP0, offsetof(Node, key)+LO(NODE:TMP2) + | li AT, LJ_TSTR + | lw NODE:TMP1, NODE:TMP2->next + | bne CARG1, AT, >5 + |. lw CARG2, offsetof(Node, val)+HI(NODE:TMP2) + | bne TMP0, STR:RC, >5 + |. lbu TMP3, TAB:RB->marked + | beq CARG2, TISNIL, >4 // Key found, but nil value? + |. lw TAB:TMP0, TAB:RB->metatable + |2: + | andi AT, TMP3, LJ_GC_BLACK // isblack(table) + |.if FPU + | bnez AT, >7 + |. sdc1 f20, NODE:TMP2->val + |.else + | sw SFRETHI, NODE:TMP2->val.u32.hi + | bnez AT, >7 + |. sw SFRETLO, NODE:TMP2->val.u32.lo + |.endif + |3: + | ins_next + | + |4: // Check for __newindex if previous value is nil. + | beqz TAB:TMP0, <2 // No metatable: done. + |. nop + | lbu TMP0, TAB:TMP0->nomm + | andi TMP0, TMP0, 1<vmeta_tsets + |. nop + | + |5: // Follow hash chain. + | bnez NODE:TMP1, <1 + |. move NODE:TMP2, NODE:TMP1 + | // End of hash chain: key not found, add a new one + | + | // But check for __newindex first. + | lw TAB:TMP2, TAB:RB->metatable + | beqz TAB:TMP2, >6 // No metatable: continue. + |. addiu CARG3, DISPATCH, DISPATCH_GL(tmptv) + | lbu TMP0, TAB:TMP2->nomm + | andi TMP0, TMP0, 1<vmeta_tsets // 'no __newindex' flag NOT set: check. + |. li AT, LJ_TSTR + |6: + | load_got lj_tab_newkey + | sw STR:RC, LO(CARG3) + | sw AT, HI(CARG3) + | sw BASE, L->base + | move CARG2, TAB:RB + | sw PC, SAVE_PC + | call_intern lj_tab_newkey // (lua_State *L, GCtab *t, TValue *k + |. move CARG1, L + | // Returns TValue *. + | lw BASE, L->base + |.if FPU + | b <3 // No 2nd write barrier needed. + |. sdc1 f20, 0(CRET1) + |.else + | lw SFARG1HI, HI(RA) + | lw SFARG1LO, LO(RA) + | sw SFARG1HI, HI(CRET1) + | b <3 // No 2nd write barrier needed. + |. sw SFARG1LO, LO(CRET1) + |.endif + | + |7: // Possible table write barrier for the value. Skip valiswhite check. + | barrierback TAB:RB, TMP3, TMP0, <3 + break; + case BC_TSETB: + | // RA = src*8, RB = table*8, RC = index*8 + | decode_RB8a RB, INS + | decode_RB8b RB + | addu CARG2, BASE, RB + | decode_RDtoRC8 RC, RD + | lw CARG1, HI(CARG2) + | li AT, LJ_TTAB + | lw TAB:RB, LO(CARG2) + | addu RA, BASE, RA + | bne CARG1, AT, ->vmeta_tsetb + |. srl TMP0, RC, 3 + | lw TMP1, TAB:RB->asize + | lw TMP2, TAB:RB->array + | sltu AT, TMP0, TMP1 + | beqz AT, ->vmeta_tsetb + |. addu RC, TMP2, RC + | lw TMP1, HI(RC) + | lbu TMP3, TAB:RB->marked + | beq TMP1, TISNIL, >5 + |1: + |. lw SFRETHI, HI(RA) + | lw SFRETLO, LO(RA) + | andi AT, TMP3, LJ_GC_BLACK // isblack(table) + | sw SFRETHI, HI(RC) + | bnez AT, >7 + |. sw SFRETLO, LO(RC) + |2: + | ins_next + | + |5: // Check for __newindex if previous value is nil. + | lw TAB:TMP2, TAB:RB->metatable + | beqz TAB:TMP2, <1 // No metatable: done. + |. nop + | lbu TMP1, TAB:TMP2->nomm + | andi TMP1, TMP1, 1<vmeta_tsetb // Caveat: preserve TMP0 and CARG2! + |. nop + | + |7: // Possible table write barrier for the value. Skip valiswhite check. + | barrierback TAB:RB, TMP3, TMP0, <2 + break; + case BC_TSETR: + | // RA = dst*8, RB = table*8, RC = key*8 + | decode_RB8a RB, INS + | decode_RB8b RB + | decode_RDtoRC8 RC, RD + | addu CARG1, BASE, RB + | addu CARG3, BASE, RC + | lw TAB:CARG2, LO(CARG1) + | lw CARG3, LO(CARG3) + | lbu TMP3, TAB:CARG2->marked + | lw TMP0, TAB:CARG2->asize + | lw TMP1, TAB:CARG2->array + | andi AT, TMP3, LJ_GC_BLACK // isblack(table) + | bnez AT, >7 + |. addu RA, BASE, RA + |2: + | sltu AT, CARG3, TMP0 + | sll TMP2, CARG3, 3 + | beqz AT, ->vmeta_tsetr // In array part? + |. addu CRET1, TMP1, TMP2 + |->BC_TSETR_Z: + | lw SFARG1HI, HI(RA) + | lw SFARG1LO, LO(RA) + | ins_next1 + | sw SFARG1HI, HI(CRET1) + | sw SFARG1LO, LO(CRET1) + | ins_next2 + | + |7: // Possible table write barrier for the value. Skip valiswhite check. + | barrierback TAB:CARG2, TMP3, CRET1, <2 + break; + + case BC_TSETM: + | // RA = base*8 (table at base-1), RD = num_const*8 (start index) + | addu RA, BASE, RA + |1: + | addu TMP3, KBASE, RD + | lw TAB:CARG2, -8+LO(RA) // Guaranteed to be a table. + | addiu TMP0, MULTRES, -8 + | lw TMP3, LO(TMP3) // Integer constant is in lo-word. + | beqz TMP0, >4 // Nothing to copy? + |. srl CARG3, TMP0, 3 + | addu CARG3, CARG3, TMP3 + | lw TMP2, TAB:CARG2->asize + | sll TMP1, TMP3, 3 + | lbu TMP3, TAB:CARG2->marked + | lw CARG1, TAB:CARG2->array + | sltu AT, TMP2, CARG3 + | bnez AT, >5 + |. addu TMP2, RA, TMP0 + | addu TMP1, TMP1, CARG1 + | andi TMP0, TMP3, LJ_GC_BLACK // isblack(table) + |3: // Copy result slots to table. + | lw SFRETHI, HI(RA) + | lw SFRETLO, LO(RA) + | addiu RA, RA, 8 + | sltu AT, RA, TMP2 + | sw SFRETHI, HI(TMP1) + | sw SFRETLO, LO(TMP1) + | bnez AT, <3 + |. addiu TMP1, TMP1, 8 + | bnez TMP0, >7 + |. nop + |4: + | ins_next + | + |5: // Need to resize array part. + | load_got lj_tab_reasize + | sw BASE, L->base + | sw PC, SAVE_PC + | move BASE, RD + | call_intern lj_tab_reasize // (lua_State *L, GCtab *t, int nasize) + |. move CARG1, L + | // Must not reallocate the stack. + | move RD, BASE + | b <1 + |. lw BASE, L->base // Reload BASE for lack of a saved register. + | + |7: // Possible table write barrier for any value. Skip valiswhite check. + | barrierback TAB:CARG2, TMP3, TMP0, <4 + break; + + /* -- Calls and vararg handling ----------------------------------------- */ + + case BC_CALLM: + | // RA = base*8, (RB = (nresults+1)*8,) RC = extra_nargs*8 + | decode_RDtoRC8 NARGS8:RC, RD + | b ->BC_CALL_Z + |. addu NARGS8:RC, NARGS8:RC, MULTRES + break; + case BC_CALL: + | // RA = base*8, (RB = (nresults+1)*8,) RC = (nargs+1)*8 + | decode_RDtoRC8 NARGS8:RC, RD + |->BC_CALL_Z: + | move TMP2, BASE + | addu BASE, BASE, RA + | li AT, LJ_TFUNC + | lw TMP0, HI(BASE) + | lw LFUNC:RB, LO(BASE) + | addiu BASE, BASE, 8 + | bne TMP0, AT, ->vmeta_call + |. addiu NARGS8:RC, NARGS8:RC, -8 + | ins_call + break; + + case BC_CALLMT: + | // RA = base*8, (RB = 0,) RC = extra_nargs*8 + | addu NARGS8:RD, NARGS8:RD, MULTRES // BC_CALLT gets RC from RD. + | // Fall through. Assumes BC_CALLT follows. + break; + case BC_CALLT: + | // RA = base*8, (RB = 0,) RC = (nargs+1)*8 + | addu RA, BASE, RA + | li AT, LJ_TFUNC + | lw TMP0, HI(RA) + | lw LFUNC:RB, LO(RA) + | move NARGS8:RC, RD + | lw TMP1, FRAME_PC(BASE) + | addiu RA, RA, 8 + | bne TMP0, AT, ->vmeta_callt + |. addiu NARGS8:RC, NARGS8:RC, -8 + |->BC_CALLT_Z: + | andi TMP0, TMP1, FRAME_TYPE // Caveat: preserve TMP0 until the 'or'. + | lbu TMP3, LFUNC:RB->ffid + | bnez TMP0, >7 + |. xori TMP2, TMP1, FRAME_VARG + |1: + | sw LFUNC:RB, FRAME_FUNC(BASE) // Copy function down, but keep PC. + | sltiu AT, TMP3, 2 // (> FF_C) Calling a fast function? + | move TMP2, BASE + | beqz NARGS8:RC, >3 + |. move TMP3, NARGS8:RC + |2: + | lw SFRETHI, HI(RA) + | lw SFRETLO, LO(RA) + | addiu RA, RA, 8 + | addiu TMP3, TMP3, -8 + | sw SFRETHI, HI(TMP2) + | sw SFRETLO, LO(TMP2) + | bnez TMP3, <2 + |. addiu TMP2, TMP2, 8 + |3: + | or TMP0, TMP0, AT + | beqz TMP0, >5 + |. nop + |4: + | ins_callt + | + |5: // Tailcall to a fast function with a Lua frame below. + | lw INS, -4(TMP1) + | decode_RA8a RA, INS + | decode_RA8b RA + | subu TMP1, BASE, RA + | lw LFUNC:TMP1, -8+FRAME_FUNC(TMP1) + | lw TMP1, LFUNC:TMP1->pc + | b <4 + |. lw KBASE, PC2PROTO(k)(TMP1) // Need to prepare KBASE. + | + |7: // Tailcall from a vararg function. + | andi AT, TMP2, FRAME_TYPEP + | bnez AT, <1 // Vararg frame below? + |. subu TMP2, BASE, TMP2 // Relocate BASE down. + | move BASE, TMP2 + | lw TMP1, FRAME_PC(TMP2) + | b <1 + |. andi TMP0, TMP1, FRAME_TYPE + break; + + case BC_ITERC: + | // RA = base*8, (RB = (nresults+1)*8, RC = (nargs+1)*8 ((2+1)*8)) + | move TMP2, BASE + | addu BASE, BASE, RA + | li AT, LJ_TFUNC + | lw TMP1, -24+HI(BASE) + | lw LFUNC:RB, -24+LO(BASE) + | lw SFARG1HI, -16+HI(BASE) + | lw SFARG1LO, -16+LO(BASE) + | lw SFARG2HI, -8+HI(BASE) + | lw SFARG2LO, -8+LO(BASE) + | sw TMP1, HI(BASE) // Copy callable. + | sw LFUNC:RB, LO(BASE) + | sw SFARG1HI, 8+HI(BASE) // Copy state. + | sw SFARG1LO, 8+LO(BASE) + | sw SFARG2HI, 16+HI(BASE) // Copy control var. + | sw SFARG2LO, 16+LO(BASE) + | addiu BASE, BASE, 8 + | bne TMP1, AT, ->vmeta_call + |. li NARGS8:RC, 16 // Iterators get 2 arguments. + | ins_call + break; + + case BC_ITERN: + |.if JIT and ENDIAN_LE + | hotloop + |.endif + |->vm_IITERN: + | // RA = base*8, (RB = (nresults+1)*8, RC = (nargs+1)*8 (2+1)*8) + | addu RA, BASE, RA + | lw TAB:RB, -16+LO(RA) + | lw RC, -8+LO(RA) // Get index from control var. + | lw TMP0, TAB:RB->asize + | lw TMP1, TAB:RB->array + | addiu PC, PC, 4 + |1: // Traverse array part. + | sltu AT, RC, TMP0 + | beqz AT, >5 // Index points after array part? + |. sll TMP3, RC, 3 + | addu TMP3, TMP1, TMP3 + | lw SFARG1HI, HI(TMP3) + | lw SFARG1LO, LO(TMP3) + | lhu RD, -4+OFS_RD(PC) + | sw TISNUM, HI(RA) + | sw RC, LO(RA) + | beq SFARG1HI, TISNIL, <1 // Skip holes in array part. + |. addiu RC, RC, 1 + | sw SFARG1HI, 8+HI(RA) + | sw SFARG1LO, 8+LO(RA) + | lui TMP3, (-(BCBIAS_J*4 >> 16) & 65535) + | decode_RD4b RD + | addu RD, RD, TMP3 + | sw RC, -8+LO(RA) // Update control var. + | addu PC, PC, RD + |3: + | ins_next + | + |5: // Traverse hash part. + | lw TMP1, TAB:RB->hmask + | subu RC, RC, TMP0 + | lw TMP2, TAB:RB->node + |6: + | sltu AT, TMP1, RC // End of iteration? Branch to ITERL+1. + | bnez AT, <3 + |. sll TMP3, RC, 5 + | sll RB, RC, 3 + | subu TMP3, TMP3, RB + | addu NODE:TMP3, TMP3, TMP2 + | lw SFARG1HI, NODE:TMP3->val.u32.hi + | lw SFARG1LO, NODE:TMP3->val.u32.lo + | lhu RD, -4+OFS_RD(PC) + | beq SFARG1HI, TISNIL, <6 // Skip holes in hash part. + |. addiu RC, RC, 1 + | lw SFARG2HI, NODE:TMP3->key.u32.hi + | lw SFARG2LO, NODE:TMP3->key.u32.lo + | lui TMP3, (-(BCBIAS_J*4 >> 16) & 65535) + | sw SFARG1HI, 8+HI(RA) + | sw SFARG1LO, 8+LO(RA) + | addu RC, RC, TMP0 + | decode_RD4b RD + | addu RD, RD, TMP3 + | sw SFARG2HI, HI(RA) + | sw SFARG2LO, LO(RA) + | addu PC, PC, RD + | b <3 + |. sw RC, -8+LO(RA) // Update control var. + break; + + case BC_ISNEXT: + | // RA = base*8, RD = target (points to ITERN) + | addu RA, BASE, RA + | srl TMP0, RD, 1 + | lw CARG1, -24+HI(RA) + | lw CFUNC:CARG2, -24+LO(RA) + | addu TMP0, PC, TMP0 + | lw CARG3, -16+HI(RA) + | lw CARG4, -8+HI(RA) + | li AT, LJ_TFUNC + | bne CARG1, AT, >5 + |. lui TMP2, (-(BCBIAS_J*4 >> 16) & 65535) + | lbu CARG2, CFUNC:CARG2->ffid + | addiu CARG3, CARG3, -LJ_TTAB + | addiu CARG4, CARG4, -LJ_TNIL + | or CARG3, CARG3, CARG4 + | addiu CARG2, CARG2, -FF_next_N + | or CARG2, CARG2, CARG3 + | bnez CARG2, >5 + |. lui TMP1, (LJ_KEYINDEX >> 16) + | addu PC, TMP0, TMP2 + | ori TMP1, TMP1, (LJ_KEYINDEX & 0xffff) + | sw r0, -8+LO(RA) // Initialize control var. + | sw TMP1, -8+HI(RA) + |1: + | ins_next + |5: // Despecialize bytecode if any of the checks fail. + | li TMP3, BC_JMP + | li TMP1, BC_ITERC + | sb TMP3, -4+OFS_OP(PC) + | addu PC, TMP0, TMP2 + |.if JIT + | lb TMP0, OFS_OP(PC) + | li AT, BC_ITERN + | bne TMP0, AT, >6 + |. lhu TMP2, OFS_RD(PC) + |.endif + | b <1 + |. sb TMP1, OFS_OP(PC) + |.if JIT + |6: // Unpatch JLOOP. + | lw TMP0, DISPATCH_J(trace)(DISPATCH) + | sll TMP2, TMP2, 2 + | addu TMP0, TMP0, TMP2 + | lw TRACE:TMP2, 0(TMP0) + | lw TMP0, TRACE:TMP2->startins + | li AT, -256 + | and TMP0, TMP0, AT + | or TMP0, TMP0, TMP1 + | b <1 + |. sw TMP0, 0(PC) + |.endif + break; + + case BC_VARG: + | // RA = base*8, RB = (nresults+1)*8, RC = numparams*8 + | lw TMP0, FRAME_PC(BASE) + | decode_RDtoRC8 RC, RD + | decode_RB8a RB, INS + | addu RC, BASE, RC + | decode_RB8b RB + | addu RA, BASE, RA + | addiu RC, RC, FRAME_VARG + | addu TMP2, RA, RB + | addiu TMP3, BASE, -8 // TMP3 = vtop + | subu RC, RC, TMP0 // RC = vbase + | // Note: RC may now be even _above_ BASE if nargs was < numparams. + | beqz RB, >5 // Copy all varargs? + |. subu TMP1, TMP3, RC + | addiu TMP2, TMP2, -16 + |1: // Copy vararg slots to destination slots. + | lw CARG1, HI(RC) + | sltu AT, RC, TMP3 + | lw CARG2, LO(RC) + | addiu RC, RC, 8 + | movz CARG1, TISNIL, AT + | sw CARG1, HI(RA) + | sw CARG2, LO(RA) + | sltu AT, RA, TMP2 + | bnez AT, <1 + |. addiu RA, RA, 8 + |3: + | ins_next + | + |5: // Copy all varargs. + | lw TMP0, L->maxstack + | blez TMP1, <3 // No vararg slots? + |. li MULTRES, 8 // MULTRES = (0+1)*8 + | addu TMP2, RA, TMP1 + | sltu AT, TMP0, TMP2 + | bnez AT, >7 + |. addiu MULTRES, TMP1, 8 + |6: + | lw SFRETHI, HI(RC) + | lw SFRETLO, LO(RC) + | addiu RC, RC, 8 + | sw SFRETHI, HI(RA) + | sw SFRETLO, LO(RA) + | sltu AT, RC, TMP3 + | bnez AT, <6 // More vararg slots? + |. addiu RA, RA, 8 + | b <3 + |. nop + | + |7: // Grow stack for varargs. + | load_got lj_state_growstack + | sw RA, L->top + | subu RA, RA, BASE + | sw BASE, L->base + | subu BASE, RC, BASE // Need delta, because BASE may change. + | sw PC, SAVE_PC + | srl CARG2, TMP1, 3 + | call_intern lj_state_growstack // (lua_State *L, int n) + |. move CARG1, L + | move RC, BASE + | lw BASE, L->base + | addu RA, BASE, RA + | addu RC, BASE, RC + | b <6 + |. addiu TMP3, BASE, -8 + break; + + /* -- Returns ----------------------------------------------------------- */ + + case BC_RETM: + | // RA = results*8, RD = extra_nresults*8 + | addu RD, RD, MULTRES // MULTRES >= 8, so RD >= 8. + | // Fall through. Assumes BC_RET follows. + break; + + case BC_RET: + | // RA = results*8, RD = (nresults+1)*8 + | lw PC, FRAME_PC(BASE) + | addu RA, BASE, RA + | move MULTRES, RD + |1: + | andi TMP0, PC, FRAME_TYPE + | bnez TMP0, ->BC_RETV_Z + |. xori TMP1, PC, FRAME_VARG + | + |->BC_RET_Z: + | // BASE = base, RA = resultptr, RD = (nresults+1)*8, PC = return + | lw INS, -4(PC) + | addiu TMP2, BASE, -8 + | addiu RC, RD, -8 + | decode_RA8a TMP0, INS + | decode_RB8a RB, INS + | decode_RA8b TMP0 + | decode_RB8b RB + | addu TMP3, TMP2, RB + | beqz RC, >3 + |. subu BASE, TMP2, TMP0 + |2: + | lw SFRETHI, HI(RA) + | lw SFRETLO, LO(RA) + | addiu RA, RA, 8 + | addiu RC, RC, -8 + | sw SFRETHI, HI(TMP2) + | sw SFRETLO, LO(TMP2) + | bnez RC, <2 + |. addiu TMP2, TMP2, 8 + |3: + | addiu TMP3, TMP3, -8 + |5: + | sltu AT, TMP2, TMP3 + | bnez AT, >6 + |. lw LFUNC:TMP1, FRAME_FUNC(BASE) + | ins_next1 + | lw TMP1, LFUNC:TMP1->pc + | lw KBASE, PC2PROTO(k)(TMP1) + | ins_next2 + | + |6: // Fill up results with nil. + | sw TISNIL, HI(TMP2) + | b <5 + |. addiu TMP2, TMP2, 8 + | + |->BC_RETV_Z: // Non-standard return case. + | andi TMP2, TMP1, FRAME_TYPEP + | bnez TMP2, ->vm_return + |. nop + | // Return from vararg function: relocate BASE down. + | subu BASE, BASE, TMP1 + | b <1 + |. lw PC, FRAME_PC(BASE) + break; + + case BC_RET0: case BC_RET1: + | // RA = results*8, RD = (nresults+1)*8 + | lw PC, FRAME_PC(BASE) + | addu RA, BASE, RA + | move MULTRES, RD + | andi TMP0, PC, FRAME_TYPE + | bnez TMP0, ->BC_RETV_Z + |. xori TMP1, PC, FRAME_VARG + | + | lw INS, -4(PC) + | addiu TMP2, BASE, -8 + if (op == BC_RET1) { + | lw SFRETHI, HI(RA) + | lw SFRETLO, LO(RA) + } + | decode_RB8a RB, INS + | decode_RA8a RA, INS + | decode_RB8b RB + | decode_RA8b RA + if (op == BC_RET1) { + | sw SFRETHI, HI(TMP2) + | sw SFRETLO, LO(TMP2) + } + | subu BASE, TMP2, RA + |5: + | sltu AT, RD, RB + | bnez AT, >6 + |. lw LFUNC:TMP1, FRAME_FUNC(BASE) + | ins_next1 + | lw TMP1, LFUNC:TMP1->pc + | lw KBASE, PC2PROTO(k)(TMP1) + | ins_next2 + | + |6: // Fill up results with nil. + | addiu TMP2, TMP2, 8 + | addiu RD, RD, 8 + | b <5 + if (op == BC_RET1) { + |. sw TISNIL, HI(TMP2) + } else { + |. sw TISNIL, -8+HI(TMP2) + } + break; + + /* -- Loops and branches ------------------------------------------------ */ + + case BC_FORL: + |.if JIT + | hotloop + |.endif + | // Fall through. Assumes BC_IFORL follows. + break; + + case BC_JFORI: + case BC_JFORL: +#if !LJ_HASJIT + break; +#endif + case BC_FORI: + case BC_IFORL: + | // RA = base*8, RD = target (after end of loop or start of loop) + vk = (op == BC_IFORL || op == BC_JFORL); + | addu RA, BASE, RA + | lw SFARG1HI, FORL_IDX*8+HI(RA) + | lw SFARG1LO, FORL_IDX*8+LO(RA) + if (op != BC_JFORL) { + | srl RD, RD, 1 + | lui TMP2, (-(BCBIAS_J*4 >> 16) & 65535) + | addu TMP2, RD, TMP2 + } + if (!vk) { + | lw SFARG2HI, FORL_STOP*8+HI(RA) + | lw SFARG2LO, FORL_STOP*8+LO(RA) + | bne SFARG1HI, TISNUM, >5 + |. lw SFRETHI, FORL_STEP*8+HI(RA) + | xor AT, SFARG2HI, TISNUM + | lw SFRETLO, FORL_STEP*8+LO(RA) + | xor TMP0, SFRETHI, TISNUM + | or AT, AT, TMP0 + | bnez AT, ->vmeta_for + |. slt AT, SFRETLO, r0 + | slt CRET1, SFARG2LO, SFARG1LO + | slt TMP1, SFARG1LO, SFARG2LO + | movn CRET1, TMP1, AT + } else { + | bne SFARG1HI, TISNUM, >5 + |. lw SFARG2LO, FORL_STEP*8+LO(RA) + | lw SFRETLO, FORL_STOP*8+LO(RA) + | move TMP3, SFARG1LO + | addu SFARG1LO, SFARG1LO, SFARG2LO + | xor TMP0, SFARG1LO, TMP3 + | xor TMP1, SFARG1LO, SFARG2LO + | and TMP0, TMP0, TMP1 + | slt TMP1, SFARG1LO, SFRETLO + | slt CRET1, SFRETLO, SFARG1LO + | slt AT, SFARG2LO, r0 + | slt TMP0, TMP0, r0 // ((y^a) & (y^b)) < 0: overflow. + | movn CRET1, TMP1, AT + | or CRET1, CRET1, TMP0 + } + |1: + if (op == BC_FORI) { + | movz TMP2, r0, CRET1 + | addu PC, PC, TMP2 + } else if (op == BC_JFORI) { + | addu PC, PC, TMP2 + | lhu RD, -4+OFS_RD(PC) + } else if (op == BC_IFORL) { + | movn TMP2, r0, CRET1 + | addu PC, PC, TMP2 + } + if (vk) { + | sw SFARG1HI, FORL_IDX*8+HI(RA) + | sw SFARG1LO, FORL_IDX*8+LO(RA) + } + | ins_next1 + | sw SFARG1HI, FORL_EXT*8+HI(RA) + | sw SFARG1LO, FORL_EXT*8+LO(RA) + |2: + if (op == BC_JFORI) { + | beqz CRET1, =>BC_JLOOP + |. decode_RD8b RD + } else if (op == BC_JFORL) { + | beqz CRET1, =>BC_JLOOP + } + | ins_next2 + | + |5: // FP loop. + |.if FPU + if (!vk) { + | ldc1 f0, FORL_IDX*8(RA) + | ldc1 f2, FORL_STOP*8(RA) + | sltiu TMP0, SFARG1HI, LJ_TISNUM + | sltiu TMP1, SFARG2HI, LJ_TISNUM + | sltiu AT, SFRETHI, LJ_TISNUM + | and TMP0, TMP0, TMP1 + | and AT, AT, TMP0 + | beqz AT, ->vmeta_for + |. slt TMP3, SFRETHI, r0 + | c.ole.d 0, f0, f2 + | c.ole.d 1, f2, f0 + | li CRET1, 1 + | movt CRET1, r0, 0 + | movt AT, r0, 1 + | b <1 + |. movn CRET1, AT, TMP3 + } else { + | ldc1 f0, FORL_IDX*8(RA) + | ldc1 f4, FORL_STEP*8(RA) + | ldc1 f2, FORL_STOP*8(RA) + | lw SFARG2HI, FORL_STEP*8+HI(RA) + | add.d f0, f0, f4 + | c.ole.d 0, f0, f2 + | c.ole.d 1, f2, f0 + | slt TMP3, SFARG2HI, r0 + | li CRET1, 1 + | li AT, 1 + | movt CRET1, r0, 0 + | movt AT, r0, 1 + | movn CRET1, AT, TMP3 + if (op == BC_IFORL) { + | movn TMP2, r0, CRET1 + | addu PC, PC, TMP2 + } + | sdc1 f0, FORL_IDX*8(RA) + | ins_next1 + | b <2 + |. sdc1 f0, FORL_EXT*8(RA) + } + |.else + if (!vk) { + | sltiu TMP0, SFARG1HI, LJ_TISNUM + | sltiu TMP1, SFARG2HI, LJ_TISNUM + | sltiu AT, SFRETHI, LJ_TISNUM + | and TMP0, TMP0, TMP1 + | and AT, AT, TMP0 + | beqz AT, ->vmeta_for + |. nop + | bal ->vm_sfcmpolex + |. move TMP3, SFRETHI + | b <1 + |. nop + } else { + | lw SFARG2HI, FORL_STEP*8+HI(RA) + | load_got __adddf3 + | call_extern + |. sw TMP2, ARG5 + | lw SFARG2HI, FORL_STOP*8+HI(RA) + | lw SFARG2LO, FORL_STOP*8+LO(RA) + | move SFARG1HI, SFRETHI + | move SFARG1LO, SFRETLO + | bal ->vm_sfcmpolex + |. lw TMP3, FORL_STEP*8+HI(RA) + if ( op == BC_JFORL ) { + | lhu RD, -4+OFS_RD(PC) + | lw TMP2, ARG5 + | b <1 + |. decode_RD8b RD + } else { + | b <1 + |. lw TMP2, ARG5 + } + } + |.endif + break; + + case BC_ITERL: + |.if JIT + | hotloop + |.endif + | // Fall through. Assumes BC_IITERL follows. + break; + + case BC_JITERL: +#if !LJ_HASJIT + break; +#endif + case BC_IITERL: + | // RA = base*8, RD = target + | addu RA, BASE, RA + | lw TMP1, HI(RA) + | beq TMP1, TISNIL, >1 // Stop if iterator returned nil. + |. lw TMP2, LO(RA) + if (op == BC_JITERL) { + | sw TMP1, -8+HI(RA) + | b =>BC_JLOOP + |. sw TMP2, -8+LO(RA) + } else { + | branch_RD // Otherwise save control var + branch. + | sw TMP1, -8+HI(RA) + | sw TMP2, -8+LO(RA) + } + |1: + | ins_next + break; + + case BC_LOOP: + | // RA = base*8, RD = target (loop extent) + | // Note: RA/RD is only used by trace recorder to determine scope/extent + | // This opcode does NOT jump, it's only purpose is to detect a hot loop. + |.if JIT + | hotloop + |.endif + | // Fall through. Assumes BC_ILOOP follows. + break; + + case BC_ILOOP: + | // RA = base*8, RD = target (loop extent) + | ins_next + break; + + case BC_JLOOP: + |.if JIT + | // RA = base*8 (ignored), RD = traceno*8 + | lw TMP1, DISPATCH_J(trace)(DISPATCH) + | srl RD, RD, 1 + | li AT, 0 + | addu TMP1, TMP1, RD + | // Traces on MIPS don't store the trace number, so use 0. + | sw AT, DISPATCH_GL(vmstate)(DISPATCH) + | lw TRACE:TMP2, 0(TMP1) + | sw BASE, DISPATCH_GL(jit_base)(DISPATCH) + | lw TMP2, TRACE:TMP2->mcode + | sw L, DISPATCH_GL(tmpbuf.L)(DISPATCH) + | jr TMP2 + |. addiu JGL, DISPATCH, GG_DISP2G+32768 + |.endif + break; + + case BC_JMP: + | // RA = base*8 (only used by trace recorder), RD = target + | branch_RD + | ins_next + break; + + /* -- Function headers -------------------------------------------------- */ + + case BC_FUNCF: + |.if JIT + | hotcall + |.endif + case BC_FUNCV: /* NYI: compiled vararg functions. */ + | // Fall through. Assumes BC_IFUNCF/BC_IFUNCV follow. + break; + + case BC_JFUNCF: +#if !LJ_HASJIT + break; +#endif + case BC_IFUNCF: + | // BASE = new base, RA = BASE+framesize*8, RB = LFUNC, RC = nargs*8 + | lw TMP2, L->maxstack + | lbu TMP1, -4+PC2PROTO(numparams)(PC) + | lw KBASE, -4+PC2PROTO(k)(PC) + | sltu AT, TMP2, RA + | bnez AT, ->vm_growstack_l + |. sll TMP1, TMP1, 3 + if (op != BC_JFUNCF) { + | ins_next1 + } + |2: + | sltu AT, NARGS8:RC, TMP1 // Check for missing parameters. + | bnez AT, >3 + |. addu AT, BASE, NARGS8:RC + if (op == BC_JFUNCF) { + | decode_RD8a RD, INS + | b =>BC_JLOOP + |. decode_RD8b RD + } else { + | ins_next2 + } + | + |3: // Clear missing parameters. + | sw TISNIL, HI(AT) + | b <2 + |. addiu NARGS8:RC, NARGS8:RC, 8 + break; + + case BC_JFUNCV: +#if !LJ_HASJIT + break; +#endif + | NYI // NYI: compiled vararg functions + break; /* NYI: compiled vararg functions. */ + + case BC_IFUNCV: + | // BASE = new base, RA = BASE+framesize*8, RB = LFUNC, RC = nargs*8 + | addu TMP1, BASE, RC + | lw TMP2, L->maxstack + | addu TMP0, RA, RC + | sw LFUNC:RB, LO(TMP1) // Store copy of LFUNC. + | addiu TMP3, RC, 8+FRAME_VARG + | sltu AT, TMP0, TMP2 + | lw KBASE, -4+PC2PROTO(k)(PC) + | beqz AT, ->vm_growstack_l + |. sw TMP3, HI(TMP1) // Store delta + FRAME_VARG. + | lbu TMP2, -4+PC2PROTO(numparams)(PC) + | move RA, BASE + | move RC, TMP1 + | ins_next1 + | beqz TMP2, >3 + |. addiu BASE, TMP1, 8 + |1: + | lw TMP0, HI(RA) + | lw TMP3, LO(RA) + | sltu AT, RA, RC // Less args than parameters? + | move CARG1, TMP0 + | movz TMP0, TISNIL, AT // Clear missing parameters. + | movn CARG1, TISNIL, AT // Clear old fixarg slot (help the GC). + | sw TMP3, 8+LO(TMP1) + | addiu TMP2, TMP2, -1 + | sw TMP0, 8+HI(TMP1) + | addiu TMP1, TMP1, 8 + | sw CARG1, HI(RA) + | bnez TMP2, <1 + |. addiu RA, RA, 8 + |3: + | ins_next2 + break; + + case BC_FUNCC: + case BC_FUNCCW: + | // BASE = new base, RA = BASE+framesize*8, RB = CFUNC, RC = nargs*8 + if (op == BC_FUNCC) { + | lw CFUNCADDR, CFUNC:RB->f + } else { + | lw CFUNCADDR, DISPATCH_GL(wrapf)(DISPATCH) + } + | addu TMP1, RA, NARGS8:RC + | lw TMP2, L->maxstack + | addu RC, BASE, NARGS8:RC + | sw BASE, L->base + | sltu AT, TMP2, TMP1 + | sw RC, L->top + | li_vmstate C + if (op == BC_FUNCCW) { + | lw CARG2, CFUNC:RB->f + } + | bnez AT, ->vm_growstack_c // Need to grow stack. + |. move CARG1, L + | jalr CFUNCADDR // (lua_State *L [, lua_CFunction f]) + |. st_vmstate + | // Returns nresults. + | lw BASE, L->base + | sll RD, CRET1, 3 + | lw TMP1, L->top + | li_vmstate INTERP + | lw PC, FRAME_PC(BASE) // Fetch PC of caller. + | subu RA, TMP1, RD // RA = L->top - nresults*8 + | sw L, DISPATCH_GL(cur_L)(DISPATCH) + | b ->vm_returnc + |. st_vmstate + break; + + /* ---------------------------------------------------------------------- */ + + default: + fprintf(stderr, "Error: undefined opcode BC_%s\n", bc_names[op]); + exit(2); + break; + } +} + +static int build_backend(BuildCtx *ctx) +{ + int op; + + dasm_growpc(Dst, BC__MAX); + + build_subroutines(ctx); + + |.code_op + for (op = 0; op < BC__MAX; op++) + build_ins(ctx, (BCOp)op, op); + + return BC__MAX; +} + +/* Emit pseudo frame-info for all assembler functions. */ +static void emit_asm_debug(BuildCtx *ctx) +{ + int fcofs = (int)((uint8_t *)ctx->glob[GLOB_vm_ffi_call] - ctx->code); + int i; + switch (ctx->mode) { + case BUILD_elfasm: + fprintf(ctx->fp, "\t.section .debug_frame,\"\",@progbits\n"); + fprintf(ctx->fp, + ".Lframe0:\n" + "\t.4byte .LECIE0-.LSCIE0\n" + ".LSCIE0:\n" + "\t.4byte 0xffffffff\n" + "\t.byte 0x1\n" + "\t.string \"\"\n" + "\t.uleb128 0x1\n" + "\t.sleb128 -4\n" + "\t.byte 31\n" + "\t.byte 0xc\n\t.uleb128 29\n\t.uleb128 0\n" + "\t.align 2\n" + ".LECIE0:\n\n"); + fprintf(ctx->fp, + ".LSFDE0:\n" + "\t.4byte .LEFDE0-.LASFDE0\n" + ".LASFDE0:\n" + "\t.4byte .Lframe0\n" + "\t.4byte .Lbegin\n" + "\t.4byte %d\n" + "\t.byte 0xe\n\t.uleb128 %d\n" + "\t.byte 0x9f\n\t.sleb128 1\n" + "\t.byte 0x9e\n\t.sleb128 2\n", + fcofs, CFRAME_SIZE); + for (i = 23; i >= 16; i--) + fprintf(ctx->fp, "\t.byte %d\n\t.uleb128 %d\n", 0x80+i, 26-i); +#if !LJ_SOFTFP + for (i = 30; i >= 20; i -= 2) + fprintf(ctx->fp, "\t.byte %d\n\t.uleb128 %d\n", 0x80+32+i, 42-i); +#endif + fprintf(ctx->fp, + "\t.align 2\n" + ".LEFDE0:\n\n"); +#if LJ_HASFFI + fprintf(ctx->fp, + ".LSFDE1:\n" + "\t.4byte .LEFDE1-.LASFDE1\n" + ".LASFDE1:\n" + "\t.4byte .Lframe0\n" + "\t.4byte lj_vm_ffi_call\n" + "\t.4byte %d\n" + "\t.byte 0x9f\n\t.uleb128 1\n" + "\t.byte 0x90\n\t.uleb128 2\n" + "\t.byte 0xd\n\t.uleb128 0x10\n" + "\t.align 2\n" + ".LEFDE1:\n\n", (int)ctx->codesz - fcofs); +#endif +#if !LJ_NO_UNWIND + fprintf(ctx->fp, "\t.section .eh_frame,\"aw\",@progbits\n"); + fprintf(ctx->fp, + "\t.globl lj_err_unwind_dwarf\n" + ".Lframe1:\n" + "\t.4byte .LECIE1-.LSCIE1\n" + ".LSCIE1:\n" + "\t.4byte 0\n" + "\t.byte 0x1\n" + "\t.string \"zPR\"\n" + "\t.uleb128 0x1\n" + "\t.sleb128 -4\n" + "\t.byte 31\n" + "\t.uleb128 6\n" /* augmentation length */ + "\t.byte 0\n" + "\t.4byte lj_err_unwind_dwarf\n" + "\t.byte 0\n" + "\t.byte 0xc\n\t.uleb128 29\n\t.uleb128 0\n" + "\t.align 2\n" + ".LECIE1:\n\n"); + fprintf(ctx->fp, + ".LSFDE2:\n" + "\t.4byte .LEFDE2-.LASFDE2\n" + ".LASFDE2:\n" + "\t.4byte .LASFDE2-.Lframe1\n" + "\t.4byte .Lbegin\n" + "\t.4byte %d\n" + "\t.uleb128 0\n" /* augmentation length */ + "\t.byte 0xe\n\t.uleb128 %d\n" + "\t.byte 0x9f\n\t.sleb128 1\n" + "\t.byte 0x9e\n\t.sleb128 2\n", + fcofs, CFRAME_SIZE); + for (i = 23; i >= 16; i--) + fprintf(ctx->fp, "\t.byte %d\n\t.uleb128 %d\n", 0x80+i, 26-i); +#if !LJ_SOFTFP + for (i = 30; i >= 20; i -= 2) + fprintf(ctx->fp, "\t.byte %d\n\t.uleb128 %d\n", 0x80+32+i, 42-i); +#endif + fprintf(ctx->fp, + "\t.align 2\n" + ".LEFDE2:\n\n"); +#if LJ_HASFFI + fprintf(ctx->fp, + ".Lframe2:\n" + "\t.4byte .LECIE2-.LSCIE2\n" + ".LSCIE2:\n" + "\t.4byte 0\n" + "\t.byte 0x1\n" + "\t.string \"zR\"\n" + "\t.uleb128 0x1\n" + "\t.sleb128 -4\n" + "\t.byte 31\n" + "\t.uleb128 1\n" /* augmentation length */ + "\t.byte 0\n" + "\t.byte 0xc\n\t.uleb128 29\n\t.uleb128 0\n" + "\t.align 2\n" + ".LECIE2:\n\n"); + fprintf(ctx->fp, + ".LSFDE3:\n" + "\t.4byte .LEFDE3-.LASFDE3\n" + ".LASFDE3:\n" + "\t.4byte .LASFDE3-.Lframe2\n" + "\t.4byte lj_vm_ffi_call\n" + "\t.4byte %d\n" + "\t.uleb128 0\n" /* augmentation length */ + "\t.byte 0x9f\n\t.uleb128 1\n" + "\t.byte 0x90\n\t.uleb128 2\n" + "\t.byte 0xd\n\t.uleb128 0x10\n" + "\t.align 2\n" + ".LEFDE3:\n\n", (int)ctx->codesz - fcofs); +#endif +#endif + break; + default: + break; + } +} + diff --git a/fluent-bit/lib/luajit-3065c9/src/vm_mips64.dasc b/fluent-bit/lib/luajit-3065c9/src/vm_mips64.dasc new file mode 100644 index 00000000..651bc42e --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/vm_mips64.dasc @@ -0,0 +1,5538 @@ +|// Low-level VM code for MIPS64 CPUs. +|// Bytecode interpreter, fast functions and helper functions. +|// Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +|// +|// Contributed by Djordje Kovacevic and Stefan Pejic from RT-RK.com. +|// Sponsored by Cisco Systems, Inc. +| +|.arch mips64 +|.section code_op, code_sub +| +|.actionlist build_actionlist +|.globals GLOB_ +|.globalnames globnames +|.externnames extnames +| +|// Note: The ragged indentation of the instructions is intentional. +|// The starting columns indicate data dependencies. +| +|//----------------------------------------------------------------------- +| +|// Fixed register assignments for the interpreter. +|// Don't use: r0 = 0, r26/r27 = reserved, r28 = gp, r29 = sp, r31 = ra +| +|.macro .FPU, a, b +|.if FPU +| a, b +|.endif +|.endmacro +| +|// The following must be C callee-save (but BASE is often refetched). +|.define BASE, r16 // Base of current Lua stack frame. +|.define KBASE, r17 // Constants of current Lua function. +|.define PC, r18 // Next PC. +|.define DISPATCH, r19 // Opcode dispatch table. +|.define LREG, r20 // Register holding lua_State (also in SAVE_L). +|.define MULTRES, r21 // Size of multi-result: (nresults+1)*8. +| +|.define JGL, r30 // On-trace: global_State + 32768. +| +|// Constants for type-comparisons, stores and conversions. C callee-save. +|.define TISNIL, r30 +|.define TISNUM, r22 +|.if FPU +|.define TOBIT, f30 // 2^52 + 2^51. +|.endif +| +|// The following temporaries are not saved across C calls, except for RA. +|.define RA, r23 // Callee-save. +|.define RB, r8 +|.define RC, r9 +|.define RD, r10 +|.define INS, r11 +| +|.define AT, r1 // Assembler temporary. +|.define TMP0, r12 +|.define TMP1, r13 +|.define TMP2, r14 +|.define TMP3, r15 +| +|// MIPS n64 calling convention. +|.define CFUNCADDR, r25 +|.define CARG1, r4 +|.define CARG2, r5 +|.define CARG3, r6 +|.define CARG4, r7 +|.define CARG5, r8 +|.define CARG6, r9 +|.define CARG7, r10 +|.define CARG8, r11 +| +|.define CRET1, r2 +|.define CRET2, r3 +| +|.if FPU +|.define FARG1, f12 +|.define FARG2, f13 +|.define FARG3, f14 +|.define FARG4, f15 +|.define FARG5, f16 +|.define FARG6, f17 +|.define FARG7, f18 +|.define FARG8, f19 +| +|.define FRET1, f0 +|.define FRET2, f2 +| +|.define FTMP0, f20 +|.define FTMP1, f21 +|.define FTMP2, f22 +|.endif +| +|// Stack layout while in interpreter. Must match with lj_frame.h. +|.if FPU // MIPS64 hard-float. +| +|.define CFRAME_SPACE, 192 // Delta for sp. +| +|//----- 16 byte aligned, <-- sp entering interpreter +|.define SAVE_ERRF, 188(sp) // 32 bit values. +|.define SAVE_NRES, 184(sp) +|.define SAVE_CFRAME, 176(sp) // 64 bit values. +|.define SAVE_L, 168(sp) +|.define SAVE_PC, 160(sp) +|//----- 16 byte aligned +|.define SAVE_GPR_, 80 // .. 80+10*8: 64 bit GPR saves. +|.define SAVE_FPR_, 16 // .. 16+8*8: 64 bit FPR saves. +| +|.else // MIPS64 soft-float +| +|.define CFRAME_SPACE, 128 // Delta for sp. +| +|//----- 16 byte aligned, <-- sp entering interpreter +|.define SAVE_ERRF, 124(sp) // 32 bit values. +|.define SAVE_NRES, 120(sp) +|.define SAVE_CFRAME, 112(sp) // 64 bit values. +|.define SAVE_L, 104(sp) +|.define SAVE_PC, 96(sp) +|//----- 16 byte aligned +|.define SAVE_GPR_, 16 // .. 16+10*8: 64 bit GPR saves. +| +|.endif +| +|.define TMPX, 8(sp) // Unused by interpreter, temp for JIT code. +|.define TMPD, 0(sp) +|//----- 16 byte aligned +| +|.define TMPD_OFS, 0 +| +|.define SAVE_MULTRES, TMPD +| +|//----------------------------------------------------------------------- +| +|.macro saveregs +| daddiu sp, sp, -CFRAME_SPACE +| sd ra, SAVE_GPR_+9*8(sp) +| sd r30, SAVE_GPR_+8*8(sp) +| .FPU sdc1 f31, SAVE_FPR_+7*8(sp) +| sd r23, SAVE_GPR_+7*8(sp) +| .FPU sdc1 f30, SAVE_FPR_+6*8(sp) +| sd r22, SAVE_GPR_+6*8(sp) +| .FPU sdc1 f29, SAVE_FPR_+5*8(sp) +| sd r21, SAVE_GPR_+5*8(sp) +| .FPU sdc1 f28, SAVE_FPR_+4*8(sp) +| sd r20, SAVE_GPR_+4*8(sp) +| .FPU sdc1 f27, SAVE_FPR_+3*8(sp) +| sd r19, SAVE_GPR_+3*8(sp) +| .FPU sdc1 f26, SAVE_FPR_+2*8(sp) +| sd r18, SAVE_GPR_+2*8(sp) +| .FPU sdc1 f25, SAVE_FPR_+1*8(sp) +| sd r17, SAVE_GPR_+1*8(sp) +| .FPU sdc1 f24, SAVE_FPR_+0*8(sp) +| sd r16, SAVE_GPR_+0*8(sp) +|.endmacro +| +|.macro restoreregs_ret +| ld ra, SAVE_GPR_+9*8(sp) +| ld r30, SAVE_GPR_+8*8(sp) +| ld r23, SAVE_GPR_+7*8(sp) +| .FPU ldc1 f31, SAVE_FPR_+7*8(sp) +| ld r22, SAVE_GPR_+6*8(sp) +| .FPU ldc1 f30, SAVE_FPR_+6*8(sp) +| ld r21, SAVE_GPR_+5*8(sp) +| .FPU ldc1 f29, SAVE_FPR_+5*8(sp) +| ld r20, SAVE_GPR_+4*8(sp) +| .FPU ldc1 f28, SAVE_FPR_+4*8(sp) +| ld r19, SAVE_GPR_+3*8(sp) +| .FPU ldc1 f27, SAVE_FPR_+3*8(sp) +| ld r18, SAVE_GPR_+2*8(sp) +| .FPU ldc1 f26, SAVE_FPR_+2*8(sp) +| ld r17, SAVE_GPR_+1*8(sp) +| .FPU ldc1 f25, SAVE_FPR_+1*8(sp) +| ld r16, SAVE_GPR_+0*8(sp) +| .FPU ldc1 f24, SAVE_FPR_+0*8(sp) +| jr ra +| daddiu sp, sp, CFRAME_SPACE +|.endmacro +| +|// Type definitions. Some of these are only used for documentation. +|.type L, lua_State, LREG +|.type GL, global_State +|.type TVALUE, TValue +|.type GCOBJ, GCobj +|.type STR, GCstr +|.type TAB, GCtab +|.type LFUNC, GCfuncL +|.type CFUNC, GCfuncC +|.type PROTO, GCproto +|.type UPVAL, GCupval +|.type NODE, Node +|.type NARGS8, int +|.type TRACE, GCtrace +|.type SBUF, SBuf +| +|//----------------------------------------------------------------------- +| +|// Trap for not-yet-implemented parts. +|.macro NYI; .long 0xec1cf0f0; .endmacro +| +|// Macros to mark delay slots. +|.macro ., a; a; .endmacro +|.macro ., a,b; a,b; .endmacro +|.macro ., a,b,c; a,b,c; .endmacro +|.macro ., a,b,c,d; a,b,c,d; .endmacro +| +|.define FRAME_PC, -8 +|.define FRAME_FUNC, -16 +| +|//----------------------------------------------------------------------- +| +|// Endian-specific defines. +|.if ENDIAN_LE +|.define HI, 4 +|.define LO, 0 +|.define OFS_RD, 2 +|.define OFS_RA, 1 +|.define OFS_OP, 0 +|.else +|.define HI, 0 +|.define LO, 4 +|.define OFS_RD, 0 +|.define OFS_RA, 2 +|.define OFS_OP, 3 +|.endif +| +|// Instruction decode. +|.macro decode_OP1, dst, ins; andi dst, ins, 0xff; .endmacro +|.macro decode_OP8a, dst, ins; andi dst, ins, 0xff; .endmacro +|.macro decode_OP8b, dst; sll dst, dst, 3; .endmacro +|.macro decode_RC8a, dst, ins; srl dst, ins, 13; .endmacro +|.macro decode_RC8b, dst; andi dst, dst, 0x7f8; .endmacro +|.macro decode_RD4b, dst; sll dst, dst, 2; .endmacro +|.macro decode_RA8a, dst, ins; srl dst, ins, 5; .endmacro +|.macro decode_RA8b, dst; andi dst, dst, 0x7f8; .endmacro +|.macro decode_RB8a, dst, ins; srl dst, ins, 21; .endmacro +|.macro decode_RB8b, dst; andi dst, dst, 0x7f8; .endmacro +|.macro decode_RD8a, dst, ins; srl dst, ins, 16; .endmacro +|.macro decode_RD8b, dst; sll dst, dst, 3; .endmacro +|.macro decode_RDtoRC8, dst, src; andi dst, src, 0x7f8; .endmacro +| +|// Instruction fetch. +|.macro ins_NEXT1 +| lw INS, 0(PC) +| daddiu PC, PC, 4 +|.endmacro +|// Instruction decode+dispatch. +|.macro ins_NEXT2 +| decode_OP8a TMP1, INS +| decode_OP8b TMP1 +| daddu TMP0, DISPATCH, TMP1 +| decode_RD8a RD, INS +| ld AT, 0(TMP0) +| decode_RA8a RA, INS +| decode_RD8b RD +| jr AT +| decode_RA8b RA +|.endmacro +|.macro ins_NEXT +| ins_NEXT1 +| ins_NEXT2 +|.endmacro +| +|// Instruction footer. +|.if 1 +| // Replicated dispatch. Less unpredictable branches, but higher I-Cache use. +| .define ins_next, ins_NEXT +| .define ins_next_, ins_NEXT +| .define ins_next1, ins_NEXT1 +| .define ins_next2, ins_NEXT2 +|.else +| // Common dispatch. Lower I-Cache use, only one (very) unpredictable branch. +| // Affects only certain kinds of benchmarks (and only with -j off). +| .macro ins_next +| b ->ins_next +| .endmacro +| .macro ins_next1 +| .endmacro +| .macro ins_next2 +| b ->ins_next +| .endmacro +| .macro ins_next_ +| ->ins_next: +| ins_NEXT +| .endmacro +|.endif +| +|// Call decode and dispatch. +|.macro ins_callt +| // BASE = new base, RB = LFUNC/CFUNC, RC = nargs*8, FRAME_PC(BASE) = PC +| ld PC, LFUNC:RB->pc +| lw INS, 0(PC) +| daddiu PC, PC, 4 +| decode_OP8a TMP1, INS +| decode_RA8a RA, INS +| decode_OP8b TMP1 +| decode_RA8b RA +| daddu TMP0, DISPATCH, TMP1 +| ld TMP0, 0(TMP0) +| jr TMP0 +| daddu RA, RA, BASE +|.endmacro +| +|.macro ins_call +| // BASE = new base, RB = LFUNC/CFUNC, RC = nargs*8, PC = caller PC +| sd PC, FRAME_PC(BASE) +| ins_callt +|.endmacro +| +|//----------------------------------------------------------------------- +| +|.macro branch_RD +| srl TMP0, RD, 1 +| lui AT, (-(BCBIAS_J*4 >> 16) & 65535) +| addu TMP0, TMP0, AT +| daddu PC, PC, TMP0 +|.endmacro +| +|// Assumes DISPATCH is relative to GL. +#define DISPATCH_GL(field) (GG_DISP2G + (int)offsetof(global_State, field)) +#define DISPATCH_J(field) (GG_DISP2J + (int)offsetof(jit_State, field)) +#define GG_DISP2GOT (GG_OFS(got) - GG_OFS(dispatch)) +#define DISPATCH_GOT(name) (GG_DISP2GOT + sizeof(void*)*LJ_GOT_##name) +| +#define PC2PROTO(field) ((int)offsetof(GCproto, field)-(int)sizeof(GCproto)) +| +|.macro load_got, func +| ld CFUNCADDR, DISPATCH_GOT(func)(DISPATCH) +|.endmacro +|// Much faster. Sadly, there's no easy way to force the required code layout. +|// .macro call_intern, func; bal extern func; .endmacro +|.macro call_intern, func; jalr CFUNCADDR; .endmacro +|.macro call_extern; jalr CFUNCADDR; .endmacro +|.macro jmp_extern; jr CFUNCADDR; .endmacro +| +|.macro hotcheck, delta, target +| dsrl TMP1, PC, 1 +| andi TMP1, TMP1, 126 +| daddu TMP1, TMP1, DISPATCH +| lhu TMP2, GG_DISP2HOT(TMP1) +| addiu TMP2, TMP2, -delta +| bltz TMP2, target +|. sh TMP2, GG_DISP2HOT(TMP1) +|.endmacro +| +|.macro hotloop +| hotcheck HOTCOUNT_LOOP, ->vm_hotloop +|.endmacro +| +|.macro hotcall +| hotcheck HOTCOUNT_CALL, ->vm_hotcall +|.endmacro +| +|// Set current VM state. Uses TMP0. +|.macro li_vmstate, st; li TMP0, ~LJ_VMST_..st; .endmacro +|.macro st_vmstate; sw TMP0, DISPATCH_GL(vmstate)(DISPATCH); .endmacro +| +|// Move table write barrier back. Overwrites mark and tmp. +|.macro barrierback, tab, mark, tmp, target +| ld tmp, DISPATCH_GL(gc.grayagain)(DISPATCH) +| andi mark, mark, ~LJ_GC_BLACK & 255 // black2gray(tab) +| sd tab, DISPATCH_GL(gc.grayagain)(DISPATCH) +| sb mark, tab->marked +| b target +|. sd tmp, tab->gclist +|.endmacro +| +|// Clear type tag. Isolate lowest 14+32+1=47 bits of reg. +|.macro cleartp, reg; dextm reg, reg, 0, 14; .endmacro +|.macro cleartp, dst, reg; dextm dst, reg, 0, 14; .endmacro +| +|// Set type tag: Merge 17 type bits into bits [15+32=47, 31+32+1=64) of dst. +|.macro settp, dst, tp; dinsu dst, tp, 15, 31; .endmacro +| +|// Extract (negative) type tag. +|.macro gettp, dst, src; dsra dst, src, 47; .endmacro +| +|// Macros to check the TValue type and extract the GCobj. Branch on failure. +|.macro checktp, reg, tp, target +| gettp AT, reg +| daddiu AT, AT, tp +| bnez AT, target +|. cleartp reg +|.endmacro +|.macro checktp, dst, reg, tp, target +| gettp AT, reg +| daddiu AT, AT, tp +| bnez AT, target +|. cleartp dst, reg +|.endmacro +|.macro checkstr, reg, target; checktp reg, -LJ_TSTR, target; .endmacro +|.macro checktab, reg, target; checktp reg, -LJ_TTAB, target; .endmacro +|.macro checkfunc, reg, target; checktp reg, -LJ_TFUNC, target; .endmacro +|.macro checkint, reg, target // Caveat: has delay slot! +| gettp AT, reg +| bne AT, TISNUM, target +|.endmacro +|.macro checknum, reg, target // Caveat: has delay slot! +| gettp AT, reg +| sltiu AT, AT, LJ_TISNUM +| beqz AT, target +|.endmacro +| +|.macro mov_false, reg +| lu reg, 0x8000 +| dsll reg, reg, 32 +| not reg, reg +|.endmacro +|.macro mov_true, reg +| li reg, 0x0001 +| dsll reg, reg, 48 +| not reg, reg +|.endmacro +| +|//----------------------------------------------------------------------- + +/* Generate subroutines used by opcodes and other parts of the VM. */ +/* The .code_sub section should be last to help static branch prediction. */ +static void build_subroutines(BuildCtx *ctx) +{ + |.code_sub + | + |//----------------------------------------------------------------------- + |//-- Return handling ---------------------------------------------------- + |//----------------------------------------------------------------------- + | + |->vm_returnp: + | // See vm_return. Also: TMP2 = previous base. + | andi AT, PC, FRAME_P + | beqz AT, ->cont_dispatch + | + | // Return from pcall or xpcall fast func. + |. mov_true TMP1 + | ld PC, FRAME_PC(TMP2) // Fetch PC of previous frame. + | move BASE, TMP2 // Restore caller base. + | // Prepending may overwrite the pcall frame, so do it at the end. + | sd TMP1, -8(RA) // Prepend true to results. + | daddiu RA, RA, -8 + | + |->vm_returnc: + | addiu RD, RD, 8 // RD = (nresults+1)*8. + | andi TMP0, PC, FRAME_TYPE + | beqz RD, ->vm_unwind_c_eh + |. li CRET1, LUA_YIELD + | beqz TMP0, ->BC_RET_Z // Handle regular return to Lua. + |. move MULTRES, RD + | + |->vm_return: + | // BASE = base, RA = resultptr, RD/MULTRES = (nresults+1)*8, PC = return + | // TMP0 = PC & FRAME_TYPE + | li TMP2, -8 + | xori AT, TMP0, FRAME_C + | and TMP2, PC, TMP2 + | bnez AT, ->vm_returnp + | dsubu TMP2, BASE, TMP2 // TMP2 = previous base. + | + | addiu TMP1, RD, -8 + | sd TMP2, L->base + | li_vmstate C + | lw TMP2, SAVE_NRES + | daddiu BASE, BASE, -16 + | st_vmstate + | beqz TMP1, >2 + |. sll TMP2, TMP2, 3 + |1: + | addiu TMP1, TMP1, -8 + | ld CRET1, 0(RA) + | daddiu RA, RA, 8 + | sd CRET1, 0(BASE) + | bnez TMP1, <1 + |. daddiu BASE, BASE, 8 + | + |2: + | bne TMP2, RD, >6 + |3: + |. sd BASE, L->top // Store new top. + | + |->vm_leave_cp: + | ld TMP0, SAVE_CFRAME // Restore previous C frame. + | move CRET1, r0 // Ok return status for vm_pcall. + | sd TMP0, L->cframe + | + |->vm_leave_unw: + | restoreregs_ret + | + |6: + | ld TMP1, L->maxstack + | slt AT, TMP2, RD + | bnez AT, >7 // Less results wanted? + | // More results wanted. Check stack size and fill up results with nil. + |. slt AT, BASE, TMP1 + | beqz AT, >8 + |. nop + | sd TISNIL, 0(BASE) + | addiu RD, RD, 8 + | b <2 + |. daddiu BASE, BASE, 8 + | + |7: // Less results wanted. + | subu TMP0, RD, TMP2 + | dsubu TMP0, BASE, TMP0 // Either keep top or shrink it. + |.if MIPSR6 + | selnez TMP0, TMP0, TMP2 // LUA_MULTRET+1 case? + | seleqz BASE, BASE, TMP2 + | b <3 + |. or BASE, BASE, TMP0 + |.else + | b <3 + |. movn BASE, TMP0, TMP2 // LUA_MULTRET+1 case? + |.endif + | + |8: // Corner case: need to grow stack for filling up results. + | // This can happen if: + | // - A C function grows the stack (a lot). + | // - The GC shrinks the stack in between. + | // - A return back from a lua_call() with (high) nresults adjustment. + | load_got lj_state_growstack + | move MULTRES, RD + | srl CARG2, TMP2, 3 + | call_intern lj_state_growstack // (lua_State *L, int n) + |. move CARG1, L + | lw TMP2, SAVE_NRES + | ld BASE, L->top // Need the (realloced) L->top in BASE. + | move RD, MULTRES + | b <2 + |. sll TMP2, TMP2, 3 + | + |->vm_unwind_c: // Unwind C stack, return from vm_pcall. + | // (void *cframe, int errcode) + | move sp, CARG1 + | move CRET1, CARG2 + |->vm_unwind_c_eh: // Landing pad for external unwinder. + | ld L, SAVE_L + | li TMP0, ~LJ_VMST_C + | ld GL:TMP1, L->glref + | b ->vm_leave_unw + |. sw TMP0, GL:TMP1->vmstate + | + |->vm_unwind_ff: // Unwind C stack, return from ff pcall. + | // (void *cframe) + | li AT, -4 + | and sp, CARG1, AT + |->vm_unwind_ff_eh: // Landing pad for external unwinder. + | ld L, SAVE_L + | .FPU lui TMP3, 0x59c0 // TOBIT = 2^52 + 2^51 (float). + | li TISNIL, LJ_TNIL + | li TISNUM, LJ_TISNUM + | ld BASE, L->base + | ld DISPATCH, L->glref // Setup pointer to dispatch table. + | .FPU mtc1 TMP3, TOBIT + | mov_false TMP1 + | li_vmstate INTERP + | ld PC, FRAME_PC(BASE) // Fetch PC of previous frame. + | .FPU cvt.d.s TOBIT, TOBIT + | daddiu RA, BASE, -8 // Results start at BASE-8. + | daddiu DISPATCH, DISPATCH, GG_G2DISP + | sd TMP1, 0(RA) // Prepend false to error message. + | st_vmstate + | b ->vm_returnc + |. li RD, 16 // 2 results: false + error message. + | + |->vm_unwind_stub: // Jump to exit stub from unwinder. + | jr CARG1 + |. move ra, CARG2 + | + |//----------------------------------------------------------------------- + |//-- Grow stack for calls ----------------------------------------------- + |//----------------------------------------------------------------------- + | + |->vm_growstack_c: // Grow stack for C function. + | b >2 + |. li CARG2, LUA_MINSTACK + | + |->vm_growstack_l: // Grow stack for Lua function. + | // BASE = new base, RA = BASE+framesize*8, RC = nargs*8, PC = first PC + | daddu RC, BASE, RC + | dsubu RA, RA, BASE + | sd BASE, L->base + | daddiu PC, PC, 4 // Must point after first instruction. + | sd RC, L->top + | srl CARG2, RA, 3 + |2: + | // L->base = new base, L->top = top + | load_got lj_state_growstack + | sd PC, SAVE_PC + | call_intern lj_state_growstack // (lua_State *L, int n) + |. move CARG1, L + | ld BASE, L->base + | ld RC, L->top + | ld LFUNC:RB, FRAME_FUNC(BASE) + | dsubu RC, RC, BASE + | cleartp LFUNC:RB + | // BASE = new base, RB = LFUNC/CFUNC, RC = nargs*8, FRAME_PC(BASE) = PC + | ins_callt // Just retry the call. + | + |//----------------------------------------------------------------------- + |//-- Entry points into the assembler VM --------------------------------- + |//----------------------------------------------------------------------- + | + |->vm_resume: // Setup C frame and resume thread. + | // (lua_State *L, TValue *base, int nres1 = 0, ptrdiff_t ef = 0) + | saveregs + | move L, CARG1 + | ld DISPATCH, L->glref // Setup pointer to dispatch table. + | move BASE, CARG2 + | lbu TMP1, L->status + | sd L, SAVE_L + | li PC, FRAME_CP + | daddiu TMP0, sp, CFRAME_RESUME + | daddiu DISPATCH, DISPATCH, GG_G2DISP + | sw r0, SAVE_NRES + | sw r0, SAVE_ERRF + | sd CARG1, SAVE_PC // Any value outside of bytecode is ok. + | sd r0, SAVE_CFRAME + | beqz TMP1, >3 + |. sd TMP0, L->cframe + | + | // Resume after yield (like a return). + | sd L, DISPATCH_GL(cur_L)(DISPATCH) + | move RA, BASE + | ld BASE, L->base + | ld TMP1, L->top + | ld PC, FRAME_PC(BASE) + | .FPU lui TMP3, 0x59c0 // TOBIT = 2^52 + 2^51 (float). + | dsubu RD, TMP1, BASE + | .FPU mtc1 TMP3, TOBIT + | sb r0, L->status + | .FPU cvt.d.s TOBIT, TOBIT + | li_vmstate INTERP + | daddiu RD, RD, 8 + | st_vmstate + | move MULTRES, RD + | andi TMP0, PC, FRAME_TYPE + | li TISNIL, LJ_TNIL + | beqz TMP0, ->BC_RET_Z + |. li TISNUM, LJ_TISNUM + | b ->vm_return + |. nop + | + |->vm_pcall: // Setup protected C frame and enter VM. + | // (lua_State *L, TValue *base, int nres1, ptrdiff_t ef) + | saveregs + | sw CARG4, SAVE_ERRF + | b >1 + |. li PC, FRAME_CP + | + |->vm_call: // Setup C frame and enter VM. + | // (lua_State *L, TValue *base, int nres1) + | saveregs + | li PC, FRAME_C + | + |1: // Entry point for vm_pcall above (PC = ftype). + | ld TMP1, L:CARG1->cframe + | move L, CARG1 + | sw CARG3, SAVE_NRES + | ld DISPATCH, L->glref // Setup pointer to dispatch table. + | sd CARG1, SAVE_L + | move BASE, CARG2 + | daddiu DISPATCH, DISPATCH, GG_G2DISP + | sd CARG1, SAVE_PC // Any value outside of bytecode is ok. + | sd TMP1, SAVE_CFRAME + | sd sp, L->cframe // Add our C frame to cframe chain. + | + |3: // Entry point for vm_cpcall/vm_resume (BASE = base, PC = ftype). + | sd L, DISPATCH_GL(cur_L)(DISPATCH) + | ld TMP2, L->base // TMP2 = old base (used in vmeta_call). + | .FPU lui TMP3, 0x59c0 // TOBIT = 2^52 + 2^51 (float). + | ld TMP1, L->top + | .FPU mtc1 TMP3, TOBIT + | daddu PC, PC, BASE + | dsubu NARGS8:RC, TMP1, BASE + | li TISNUM, LJ_TISNUM + | dsubu PC, PC, TMP2 // PC = frame delta + frame type + | .FPU cvt.d.s TOBIT, TOBIT + | li_vmstate INTERP + | li TISNIL, LJ_TNIL + | st_vmstate + | + |->vm_call_dispatch: + | // TMP2 = old base, BASE = new base, RC = nargs*8, PC = caller PC + | ld LFUNC:RB, FRAME_FUNC(BASE) + | checkfunc LFUNC:RB, ->vmeta_call + | + |->vm_call_dispatch_f: + | ins_call + | // BASE = new base, RB = func, RC = nargs*8, PC = caller PC + | + |->vm_cpcall: // Setup protected C frame, call C. + | // (lua_State *L, lua_CFunction func, void *ud, lua_CPFunction cp) + | saveregs + | move L, CARG1 + | ld TMP0, L:CARG1->stack + | sd CARG1, SAVE_L + | ld TMP1, L->top + | ld DISPATCH, L->glref // Setup pointer to dispatch table. + | sd CARG1, SAVE_PC // Any value outside of bytecode is ok. + | dsubu TMP0, TMP0, TMP1 // Compute -savestack(L, L->top). + | ld TMP1, L->cframe + | daddiu DISPATCH, DISPATCH, GG_G2DISP + | sw TMP0, SAVE_NRES // Neg. delta means cframe w/o frame. + | sw r0, SAVE_ERRF // No error function. + | sd TMP1, SAVE_CFRAME + | sd sp, L->cframe // Add our C frame to cframe chain. + | sd L, DISPATCH_GL(cur_L)(DISPATCH) + | jalr CARG4 // (lua_State *L, lua_CFunction func, void *ud) + |. move CFUNCADDR, CARG4 + | move BASE, CRET1 + | bnez CRET1, <3 // Else continue with the call. + |. li PC, FRAME_CP + | b ->vm_leave_cp // No base? Just remove C frame. + |. nop + | + |//----------------------------------------------------------------------- + |//-- Metamethod handling ------------------------------------------------ + |//----------------------------------------------------------------------- + | + |// The lj_meta_* functions (except for lj_meta_cat) don't reallocate the + |// stack, so BASE doesn't need to be reloaded across these calls. + | + |//-- Continuation dispatch ---------------------------------------------- + | + |->cont_dispatch: + | // BASE = meta base, RA = resultptr, RD = (nresults+1)*8 + | ld TMP0, -32(BASE) // Continuation. + | move RB, BASE + | move BASE, TMP2 // Restore caller BASE. + | ld LFUNC:TMP1, FRAME_FUNC(TMP2) + |.if FFI + | sltiu AT, TMP0, 2 + |.endif + | ld PC, -24(RB) // Restore PC from [cont|PC]. + | cleartp LFUNC:TMP1 + | daddu TMP2, RA, RD + |.if FFI + | bnez AT, >1 + |.endif + |. sd TISNIL, -8(TMP2) // Ensure one valid arg. + | ld TMP1, LFUNC:TMP1->pc + | // BASE = base, RA = resultptr, RB = meta base + | jr TMP0 // Jump to continuation. + |. ld KBASE, PC2PROTO(k)(TMP1) + | + |.if FFI + |1: + | bnez TMP0, ->cont_ffi_callback // cont = 1: return from FFI callback. + | // cont = 0: tailcall from C function. + |. daddiu TMP1, RB, -32 + | b ->vm_call_tail + |. dsubu RC, TMP1, BASE + |.endif + | + |->cont_cat: // RA = resultptr, RB = meta base + | lw INS, -4(PC) + | daddiu CARG2, RB, -32 + | ld CRET1, 0(RA) + | decode_RB8a MULTRES, INS + | decode_RA8a RA, INS + | decode_RB8b MULTRES + | decode_RA8b RA + | daddu TMP1, BASE, MULTRES + | sd BASE, L->base + | dsubu CARG3, CARG2, TMP1 + | bne TMP1, CARG2, ->BC_CAT_Z + |. sd CRET1, 0(CARG2) + | daddu RA, BASE, RA + | b ->cont_nop + |. sd CRET1, 0(RA) + | + |//-- Table indexing metamethods ----------------------------------------- + | + |->vmeta_tgets1: + | daddiu CARG3, DISPATCH, DISPATCH_GL(tmptv) + | li TMP0, LJ_TSTR + | settp STR:RC, TMP0 + | b >1 + |. sd STR:RC, 0(CARG3) + | + |->vmeta_tgets: + | daddiu CARG2, DISPATCH, DISPATCH_GL(tmptv) + | li TMP0, LJ_TTAB + | li TMP1, LJ_TSTR + | settp TAB:RB, TMP0 + | daddiu CARG3, DISPATCH, DISPATCH_GL(tmptv2) + | sd TAB:RB, 0(CARG2) + | settp STR:RC, TMP1 + | b >1 + |. sd STR:RC, 0(CARG3) + | + |->vmeta_tgetb: // TMP0 = index + | daddiu CARG3, DISPATCH, DISPATCH_GL(tmptv) + | settp TMP0, TISNUM + | sd TMP0, 0(CARG3) + | + |->vmeta_tgetv: + |1: + | load_got lj_meta_tget + | sd BASE, L->base + | sd PC, SAVE_PC + | call_intern lj_meta_tget // (lua_State *L, TValue *o, TValue *k) + |. move CARG1, L + | // Returns TValue * (finished) or NULL (metamethod). + | beqz CRET1, >3 + |. daddiu TMP1, BASE, -FRAME_CONT + | ld CARG1, 0(CRET1) + | ins_next1 + | sd CARG1, 0(RA) + | ins_next2 + | + |3: // Call __index metamethod. + | // BASE = base, L->top = new base, stack = cont/func/t/k + | ld BASE, L->top + | sd PC, -24(BASE) // [cont|PC] + | dsubu PC, BASE, TMP1 + | ld LFUNC:RB, FRAME_FUNC(BASE) // Guaranteed to be a function here. + | cleartp LFUNC:RB + | b ->vm_call_dispatch_f + |. li NARGS8:RC, 16 // 2 args for func(t, k). + | + |->vmeta_tgetr: + | load_got lj_tab_getinth + | call_intern lj_tab_getinth // (GCtab *t, int32_t key) + |. nop + | // Returns cTValue * or NULL. + | beqz CRET1, ->BC_TGETR_Z + |. move CARG2, TISNIL + | b ->BC_TGETR_Z + |. ld CARG2, 0(CRET1) + | + |//----------------------------------------------------------------------- + | + |->vmeta_tsets1: + | daddiu CARG3, DISPATCH, DISPATCH_GL(tmptv) + | li TMP0, LJ_TSTR + | settp STR:RC, TMP0 + | b >1 + |. sd STR:RC, 0(CARG3) + | + |->vmeta_tsets: + | daddiu CARG2, DISPATCH, DISPATCH_GL(tmptv) + | li TMP0, LJ_TTAB + | li TMP1, LJ_TSTR + | settp TAB:RB, TMP0 + | daddiu CARG3, DISPATCH, DISPATCH_GL(tmptv2) + | sd TAB:RB, 0(CARG2) + | settp STR:RC, TMP1 + | b >1 + |. sd STR:RC, 0(CARG3) + | + |->vmeta_tsetb: // TMP0 = index + | daddiu CARG3, DISPATCH, DISPATCH_GL(tmptv) + | settp TMP0, TISNUM + | sd TMP0, 0(CARG3) + | + |->vmeta_tsetv: + |1: + | load_got lj_meta_tset + | sd BASE, L->base + | sd PC, SAVE_PC + | call_intern lj_meta_tset // (lua_State *L, TValue *o, TValue *k) + |. move CARG1, L + | // Returns TValue * (finished) or NULL (metamethod). + | beqz CRET1, >3 + |. ld CARG1, 0(RA) + | // NOBARRIER: lj_meta_tset ensures the table is not black. + | ins_next1 + | sd CARG1, 0(CRET1) + | ins_next2 + | + |3: // Call __newindex metamethod. + | // BASE = base, L->top = new base, stack = cont/func/t/k/(v) + | daddiu TMP1, BASE, -FRAME_CONT + | ld BASE, L->top + | sd PC, -24(BASE) // [cont|PC] + | dsubu PC, BASE, TMP1 + | ld LFUNC:RB, FRAME_FUNC(BASE) // Guaranteed to be a function here. + | cleartp LFUNC:RB + | sd CARG1, 16(BASE) // Copy value to third argument. + | b ->vm_call_dispatch_f + |. li NARGS8:RC, 24 // 3 args for func(t, k, v) + | + |->vmeta_tsetr: + | load_got lj_tab_setinth + | sd BASE, L->base + | sd PC, SAVE_PC + | call_intern lj_tab_setinth // (lua_State *L, GCtab *t, int32_t key) + |. move CARG1, L + | // Returns TValue *. + | b ->BC_TSETR_Z + |. nop + | + |//-- Comparison metamethods --------------------------------------------- + | + |->vmeta_comp: + | // RA/RD point to o1/o2. + | move CARG2, RA + | move CARG3, RD + | load_got lj_meta_comp + | daddiu PC, PC, -4 + | sd BASE, L->base + | sd PC, SAVE_PC + | decode_OP1 CARG4, INS + | call_intern lj_meta_comp // (lua_State *L, TValue *o1, *o2, int op) + |. move CARG1, L + | // Returns 0/1 or TValue * (metamethod). + |3: + | sltiu AT, CRET1, 2 + | beqz AT, ->vmeta_binop + | negu TMP2, CRET1 + |4: + | lhu RD, OFS_RD(PC) + | daddiu PC, PC, 4 + | lui TMP1, (-(BCBIAS_J*4 >> 16) & 65535) + | sll RD, RD, 2 + | addu RD, RD, TMP1 + | and RD, RD, TMP2 + | daddu PC, PC, RD + |->cont_nop: + | ins_next + | + |->cont_ra: // RA = resultptr + | lbu TMP1, -4+OFS_RA(PC) + | ld CRET1, 0(RA) + | sll TMP1, TMP1, 3 + | daddu TMP1, BASE, TMP1 + | b ->cont_nop + |. sd CRET1, 0(TMP1) + | + |->cont_condt: // RA = resultptr + | ld TMP0, 0(RA) + | gettp TMP0, TMP0 + | sltiu AT, TMP0, LJ_TISTRUECOND + | b <4 + |. negu TMP2, AT // Branch if result is true. + | + |->cont_condf: // RA = resultptr + | ld TMP0, 0(RA) + | gettp TMP0, TMP0 + | sltiu AT, TMP0, LJ_TISTRUECOND + | b <4 + |. addiu TMP2, AT, -1 // Branch if result is false. + | + |->vmeta_equal: + | // CARG1/CARG2 point to o1/o2. TMP0 is set to 0/1. + | load_got lj_meta_equal + | cleartp LFUNC:CARG3, CARG2 + | cleartp LFUNC:CARG2, CARG1 + | move CARG4, TMP0 + | daddiu PC, PC, -4 + | sd BASE, L->base + | sd PC, SAVE_PC + | call_intern lj_meta_equal // (lua_State *L, GCobj *o1, *o2, int ne) + |. move CARG1, L + | // Returns 0/1 or TValue * (metamethod). + | b <3 + |. nop + | + |->vmeta_equal_cd: + |.if FFI + | load_got lj_meta_equal_cd + | move CARG2, INS + | daddiu PC, PC, -4 + | sd BASE, L->base + | sd PC, SAVE_PC + | call_intern lj_meta_equal_cd // (lua_State *L, BCIns op) + |. move CARG1, L + | // Returns 0/1 or TValue * (metamethod). + | b <3 + |. nop + |.endif + | + |->vmeta_istype: + | load_got lj_meta_istype + | daddiu PC, PC, -4 + | sd BASE, L->base + | srl CARG2, RA, 3 + | srl CARG3, RD, 3 + | sd PC, SAVE_PC + | call_intern lj_meta_istype // (lua_State *L, BCReg ra, BCReg tp) + |. move CARG1, L + | b ->cont_nop + |. nop + | + |//-- Arithmetic metamethods --------------------------------------------- + | + |->vmeta_unm: + | move RC, RB + | + |->vmeta_arith: + | load_got lj_meta_arith + | sd BASE, L->base + | move CARG2, RA + | sd PC, SAVE_PC + | move CARG3, RB + | move CARG4, RC + | decode_OP1 CARG5, INS // CARG5 == RB. + | call_intern lj_meta_arith // (lua_State *L, TValue *ra,*rb,*rc, BCReg op) + |. move CARG1, L + | // Returns NULL (finished) or TValue * (metamethod). + | beqz CRET1, ->cont_nop + |. nop + | + | // Call metamethod for binary op. + |->vmeta_binop: + | // BASE = old base, CRET1 = new base, stack = cont/func/o1/o2 + | dsubu TMP1, CRET1, BASE + | sd PC, -24(CRET1) // [cont|PC] + | move TMP2, BASE + | daddiu PC, TMP1, FRAME_CONT + | move BASE, CRET1 + | b ->vm_call_dispatch + |. li NARGS8:RC, 16 // 2 args for func(o1, o2). + | + |->vmeta_len: + | // CARG2 already set by BC_LEN. +#if LJ_52 + | move MULTRES, CARG1 +#endif + | load_got lj_meta_len + | sd BASE, L->base + | sd PC, SAVE_PC + | call_intern lj_meta_len // (lua_State *L, TValue *o) + |. move CARG1, L + | // Returns NULL (retry) or TValue * (metamethod base). +#if LJ_52 + | bnez CRET1, ->vmeta_binop // Binop call for compatibility. + |. nop + | b ->BC_LEN_Z + |. move CARG1, MULTRES +#else + | b ->vmeta_binop // Binop call for compatibility. + |. nop +#endif + | + |//-- Call metamethod ---------------------------------------------------- + | + |->vmeta_call: // Resolve and call __call metamethod. + | // TMP2 = old base, BASE = new base, RC = nargs*8 + | load_got lj_meta_call + | sd TMP2, L->base // This is the callers base! + | daddiu CARG2, BASE, -16 + | sd PC, SAVE_PC + | daddu CARG3, BASE, RC + | move MULTRES, NARGS8:RC + | call_intern lj_meta_call // (lua_State *L, TValue *func, TValue *top) + |. move CARG1, L + | ld LFUNC:RB, FRAME_FUNC(BASE) // Guaranteed to be a function here. + | daddiu NARGS8:RC, MULTRES, 8 // Got one more argument now. + | cleartp LFUNC:RB + | ins_call + | + |->vmeta_callt: // Resolve __call for BC_CALLT. + | // BASE = old base, RA = new base, RC = nargs*8 + | load_got lj_meta_call + | sd BASE, L->base + | daddiu CARG2, RA, -16 + | sd PC, SAVE_PC + | daddu CARG3, RA, RC + | move MULTRES, NARGS8:RC + | call_intern lj_meta_call // (lua_State *L, TValue *func, TValue *top) + |. move CARG1, L + | ld RB, FRAME_FUNC(RA) // Guaranteed to be a function here. + | ld TMP1, FRAME_PC(BASE) + | daddiu NARGS8:RC, MULTRES, 8 // Got one more argument now. + | b ->BC_CALLT_Z + |. cleartp LFUNC:CARG3, RB + | + |//-- Argument coercion for 'for' statement ------------------------------ + | + |->vmeta_for: + | load_got lj_meta_for + | sd BASE, L->base + | move CARG2, RA + | sd PC, SAVE_PC + | move MULTRES, INS + | call_intern lj_meta_for // (lua_State *L, TValue *base) + |. move CARG1, L + |.if JIT + | decode_OP1 TMP0, MULTRES + | li AT, BC_JFORI + |.endif + | decode_RA8a RA, MULTRES + | decode_RD8a RD, MULTRES + | decode_RA8b RA + |.if JIT + | beq TMP0, AT, =>BC_JFORI + |. decode_RD8b RD + | b =>BC_FORI + |. nop + |.else + | b =>BC_FORI + |. decode_RD8b RD + |.endif + | + |//----------------------------------------------------------------------- + |//-- Fast functions ----------------------------------------------------- + |//----------------------------------------------------------------------- + | + |.macro .ffunc, name + |->ff_ .. name: + |.endmacro + | + |.macro .ffunc_1, name + |->ff_ .. name: + | beqz NARGS8:RC, ->fff_fallback + |. ld CARG1, 0(BASE) + |.endmacro + | + |.macro .ffunc_2, name + |->ff_ .. name: + | sltiu AT, NARGS8:RC, 16 + | ld CARG1, 0(BASE) + | bnez AT, ->fff_fallback + |. ld CARG2, 8(BASE) + |.endmacro + | + |.macro .ffunc_n, name // Caveat: has delay slot! + |->ff_ .. name: + | ld CARG1, 0(BASE) + | beqz NARGS8:RC, ->fff_fallback + | // Either ldc1 or the 1st instruction of checknum is in the delay slot. + | .FPU ldc1 FARG1, 0(BASE) + | checknum CARG1, ->fff_fallback + |.endmacro + | + |.macro .ffunc_nn, name // Caveat: has delay slot! + |->ff_ .. name: + | ld CARG1, 0(BASE) + | sltiu AT, NARGS8:RC, 16 + | ld CARG2, 8(BASE) + | bnez AT, ->fff_fallback + |. gettp TMP0, CARG1 + | gettp TMP1, CARG2 + | sltiu TMP0, TMP0, LJ_TISNUM + | sltiu TMP1, TMP1, LJ_TISNUM + | .FPU ldc1 FARG1, 0(BASE) + | and TMP0, TMP0, TMP1 + | .FPU ldc1 FARG2, 8(BASE) + | beqz TMP0, ->fff_fallback + |.endmacro + | + |// Inlined GC threshold check. Caveat: uses TMP0 and TMP1 and has delay slot! + |// MIPSR6: no delay slot, but a forbidden slot. + |.macro ffgccheck + | ld TMP0, DISPATCH_GL(gc.total)(DISPATCH) + | ld TMP1, DISPATCH_GL(gc.threshold)(DISPATCH) + | dsubu AT, TMP0, TMP1 + |.if MIPSR6 + | bgezalc AT, ->fff_gcstep + |.else + | bgezal AT, ->fff_gcstep + |.endif + |.endmacro + | + |//-- Base library: checks ----------------------------------------------- + |.ffunc_1 assert + | gettp AT, CARG1 + | sltiu AT, AT, LJ_TISTRUECOND + | beqz AT, ->fff_fallback + |. daddiu RA, BASE, -16 + | ld PC, FRAME_PC(BASE) + | addiu RD, NARGS8:RC, 8 // Compute (nresults+1)*8. + | daddu TMP2, RA, RD + | daddiu TMP1, BASE, 8 + | beq BASE, TMP2, ->fff_res // Done if exactly 1 argument. + |. sd CARG1, 0(RA) + |1: + | ld CRET1, 0(TMP1) + | sd CRET1, -16(TMP1) + | bne TMP1, TMP2, <1 + |. daddiu TMP1, TMP1, 8 + | b ->fff_res + |. nop + | + |.ffunc_1 type + | gettp TMP0, CARG1 + | sltu TMP1, TISNUM, TMP0 + | not TMP2, TMP0 + | li TMP3, ~LJ_TISNUM + |.if MIPSR6 + | selnez TMP2, TMP2, TMP1 + | seleqz TMP3, TMP3, TMP1 + | or TMP2, TMP2, TMP3 + |.else + | movz TMP2, TMP3, TMP1 + |.endif + | dsll TMP2, TMP2, 3 + | daddu TMP2, CFUNC:RB, TMP2 + | b ->fff_restv + |. ld CARG1, CFUNC:TMP2->upvalue + | + |//-- Base library: getters and setters --------------------------------- + | + |.ffunc_1 getmetatable + | gettp TMP2, CARG1 + | daddiu TMP0, TMP2, -LJ_TTAB + | daddiu TMP1, TMP2, -LJ_TUDATA + |.if MIPSR6 + | selnez TMP0, TMP1, TMP0 + |.else + | movn TMP0, TMP1, TMP0 + |.endif + | bnez TMP0, >6 + |. cleartp TAB:CARG1 + |1: // Field metatable must be at same offset for GCtab and GCudata! + | ld TAB:RB, TAB:CARG1->metatable + |2: + | ld STR:RC, DISPATCH_GL(gcroot[GCROOT_MMNAME+MM_metatable])(DISPATCH) + | beqz TAB:RB, ->fff_restv + |. li CARG1, LJ_TNIL + | lw TMP0, TAB:RB->hmask + | lw TMP1, STR:RC->sid + | ld NODE:TMP2, TAB:RB->node + | and TMP1, TMP1, TMP0 // idx = str->sid & tab->hmask + | dsll TMP0, TMP1, 5 + | dsll TMP1, TMP1, 3 + | dsubu TMP1, TMP0, TMP1 + | daddu NODE:TMP2, NODE:TMP2, TMP1 // node = tab->node + (idx*32-idx*8) + | li CARG4, LJ_TSTR + | settp STR:RC, CARG4 // Tagged key to look for. + |3: // Rearranged logic, because we expect _not_ to find the key. + | ld TMP0, NODE:TMP2->key + | ld CARG1, NODE:TMP2->val + | ld NODE:TMP2, NODE:TMP2->next + | beq RC, TMP0, >5 + |. li AT, LJ_TTAB + | bnez NODE:TMP2, <3 + |. nop + |4: + | move CARG1, RB + | b ->fff_restv // Not found, keep default result. + |. settp CARG1, AT + |5: + | bne CARG1, TISNIL, ->fff_restv + |. nop + | b <4 // Ditto for nil value. + |. nop + | + |6: + | sltiu AT, TMP2, LJ_TISNUM + |.if MIPSR6 + | selnez TMP0, TISNUM, AT + | seleqz AT, TMP2, AT + | or TMP2, TMP0, AT + |.else + | movn TMP2, TISNUM, AT + |.endif + | dsll TMP2, TMP2, 3 + | dsubu TMP0, DISPATCH, TMP2 + | b <2 + |. ld TAB:RB, DISPATCH_GL(gcroot[GCROOT_BASEMT])-8(TMP0) + | + |.ffunc_2 setmetatable + | // Fast path: no mt for table yet and not clearing the mt. + | checktp TMP1, CARG1, -LJ_TTAB, ->fff_fallback + | gettp TMP3, CARG2 + | ld TAB:TMP0, TAB:TMP1->metatable + | lbu TMP2, TAB:TMP1->marked + | daddiu AT, TMP3, -LJ_TTAB + | cleartp TAB:CARG2 + | or AT, AT, TAB:TMP0 + | bnez AT, ->fff_fallback + |. andi AT, TMP2, LJ_GC_BLACK // isblack(table) + | beqz AT, ->fff_restv + |. sd TAB:CARG2, TAB:TMP1->metatable + | barrierback TAB:TMP1, TMP2, TMP0, ->fff_restv + | + |.ffunc rawget + | ld CARG2, 0(BASE) + | sltiu AT, NARGS8:RC, 16 + | load_got lj_tab_get + | gettp TMP0, CARG2 + | cleartp CARG2 + | daddiu TMP0, TMP0, -LJ_TTAB + | or AT, AT, TMP0 + | bnez AT, ->fff_fallback + |. daddiu CARG3, BASE, 8 + | call_intern lj_tab_get // (lua_State *L, GCtab *t, cTValue *key) + |. move CARG1, L + | b ->fff_restv + |. ld CARG1, 0(CRET1) + | + |//-- Base library: conversions ------------------------------------------ + | + |.ffunc tonumber + | // Only handles the number case inline (without a base argument). + | ld CARG1, 0(BASE) + | xori AT, NARGS8:RC, 8 // Exactly one number argument. + | gettp TMP1, CARG1 + | sltu TMP0, TISNUM, TMP1 + | or AT, AT, TMP0 + | bnez AT, ->fff_fallback + |. nop + | b ->fff_restv + |. nop + | + |.ffunc_1 tostring + | // Only handles the string or number case inline. + | gettp TMP0, CARG1 + | daddiu AT, TMP0, -LJ_TSTR + | // A __tostring method in the string base metatable is ignored. + | beqz AT, ->fff_restv // String key? + | // Handle numbers inline, unless a number base metatable is present. + |. ld TMP1, DISPATCH_GL(gcroot[GCROOT_BASEMT_NUM])(DISPATCH) + | sltu TMP0, TISNUM, TMP0 + | or TMP0, TMP0, TMP1 + | bnez TMP0, ->fff_fallback + |. sd BASE, L->base // Add frame since C call can throw. + |.if MIPSR6 + | sd PC, SAVE_PC // Redundant (but a defined value). + | ffgccheck + |.else + | ffgccheck + |. sd PC, SAVE_PC // Redundant (but a defined value). + |.endif + | load_got lj_strfmt_number + | move CARG1, L + | call_intern lj_strfmt_number // (lua_State *L, cTValue *o) + |. move CARG2, BASE + | // Returns GCstr *. + | li AT, LJ_TSTR + | settp CRET1, AT + | b ->fff_restv + |. move CARG1, CRET1 + | + |//-- Base library: iterators ------------------------------------------- + | + |.ffunc_1 next + | checktp CARG1, -LJ_TTAB, ->fff_fallback + | daddu TMP2, BASE, NARGS8:RC + | sd TISNIL, 0(TMP2) // Set missing 2nd arg to nil. + | load_got lj_tab_next + | ld PC, FRAME_PC(BASE) + | daddiu CARG2, BASE, 8 + | call_intern lj_tab_next // (GCtab *t, cTValue *key, TValue *o) + |. daddiu CARG3, BASE, -16 + | // Returns 1=found, 0=end, -1=error. + | daddiu RA, BASE, -16 + | bgtz CRET1, ->fff_res // Found key/value. + |. li RD, (2+1)*8 + | beqz CRET1, ->fff_restv // End of traversal: return nil. + |. move CARG1, TISNIL + | ld CFUNC:RB, FRAME_FUNC(BASE) + | cleartp CFUNC:RB + | b ->fff_fallback // Invalid key. + |. li RC, 2*8 + | + |.ffunc_1 pairs + | checktp TAB:TMP1, CARG1, -LJ_TTAB, ->fff_fallback + | ld PC, FRAME_PC(BASE) +#if LJ_52 + | ld TAB:TMP2, TAB:TMP1->metatable + | ld TMP0, CFUNC:RB->upvalue[0] + | bnez TAB:TMP2, ->fff_fallback +#else + | ld TMP0, CFUNC:RB->upvalue[0] +#endif + |. daddiu RA, BASE, -16 + | sd TISNIL, 0(BASE) + | sd CARG1, -8(BASE) + | sd TMP0, 0(RA) + | b ->fff_res + |. li RD, (3+1)*8 + | + |.ffunc_2 ipairs_aux + | checktab CARG1, ->fff_fallback + | checkint CARG2, ->fff_fallback + |. lw TMP0, TAB:CARG1->asize + | ld TMP1, TAB:CARG1->array + | ld PC, FRAME_PC(BASE) + | sextw TMP2, CARG2 + | addiu TMP2, TMP2, 1 + | sltu AT, TMP2, TMP0 + | daddiu RA, BASE, -16 + | zextw TMP0, TMP2 + | settp TMP0, TISNUM + | beqz AT, >2 // Not in array part? + |. sd TMP0, 0(RA) + | dsll TMP3, TMP2, 3 + | daddu TMP3, TMP1, TMP3 + | ld TMP1, 0(TMP3) + |1: + | beq TMP1, TISNIL, ->fff_res // End of iteration, return 0 results. + |. li RD, (0+1)*8 + | sd TMP1, -8(BASE) + | b ->fff_res + |. li RD, (2+1)*8 + |2: // Check for empty hash part first. Otherwise call C function. + | lw TMP0, TAB:CARG1->hmask + | load_got lj_tab_getinth + | beqz TMP0, ->fff_res + |. li RD, (0+1)*8 + | call_intern lj_tab_getinth // (GCtab *t, int32_t key) + |. move CARG2, TMP2 + | // Returns cTValue * or NULL. + | beqz CRET1, ->fff_res + |. li RD, (0+1)*8 + | b <1 + |. ld TMP1, 0(CRET1) + | + |.ffunc_1 ipairs + | checktp TAB:TMP1, CARG1, -LJ_TTAB, ->fff_fallback + | ld PC, FRAME_PC(BASE) +#if LJ_52 + | ld TAB:TMP2, TAB:TMP1->metatable + | ld CFUNC:TMP0, CFUNC:RB->upvalue[0] + | bnez TAB:TMP2, ->fff_fallback +#else + | ld TMP0, CFUNC:RB->upvalue[0] +#endif + | daddiu RA, BASE, -16 + | dsll AT, TISNUM, 47 + | sd CARG1, -8(BASE) + | sd AT, 0(BASE) + | sd CFUNC:TMP0, 0(RA) + | b ->fff_res + |. li RD, (3+1)*8 + | + |//-- Base library: catch errors ---------------------------------------- + | + |.ffunc pcall + | daddiu NARGS8:RC, NARGS8:RC, -8 + | lbu TMP3, DISPATCH_GL(hookmask)(DISPATCH) + | bltz NARGS8:RC, ->fff_fallback + |. move TMP2, BASE + | daddiu BASE, BASE, 16 + | // Remember active hook before pcall. + | srl TMP3, TMP3, HOOK_ACTIVE_SHIFT + | andi TMP3, TMP3, 1 + | daddiu PC, TMP3, 16+FRAME_PCALL + | beqz NARGS8:RC, ->vm_call_dispatch + |1: + |. daddu TMP0, BASE, NARGS8:RC + |2: + | ld TMP1, -16(TMP0) + | sd TMP1, -8(TMP0) + | daddiu TMP0, TMP0, -8 + | bne TMP0, BASE, <2 + |. nop + | b ->vm_call_dispatch + |. nop + | + |.ffunc xpcall + | daddiu NARGS8:TMP0, NARGS8:RC, -16 + | ld CARG1, 0(BASE) + | ld CARG2, 8(BASE) + | bltz NARGS8:TMP0, ->fff_fallback + |. lbu TMP1, DISPATCH_GL(hookmask)(DISPATCH) + | gettp AT, CARG2 + | daddiu AT, AT, -LJ_TFUNC + | bnez AT, ->fff_fallback // Traceback must be a function. + |. move TMP2, BASE + | move NARGS8:RC, NARGS8:TMP0 + | daddiu BASE, BASE, 24 + | // Remember active hook before pcall. + | srl TMP3, TMP3, HOOK_ACTIVE_SHIFT + | sd CARG2, 0(TMP2) // Swap function and traceback. + | andi TMP3, TMP3, 1 + | sd CARG1, 8(TMP2) + | beqz NARGS8:RC, ->vm_call_dispatch + |. daddiu PC, TMP3, 24+FRAME_PCALL + | b <1 + |. nop + | + |//-- Coroutine library -------------------------------------------------- + | + |.macro coroutine_resume_wrap, resume + |.if resume + |.ffunc_1 coroutine_resume + | checktp CARG1, CARG1, -LJ_TTHREAD, ->fff_fallback + |.else + |.ffunc coroutine_wrap_aux + | ld L:CARG1, CFUNC:RB->upvalue[0].gcr + | cleartp L:CARG1 + |.endif + | lbu TMP0, L:CARG1->status + | ld TMP1, L:CARG1->cframe + | ld CARG2, L:CARG1->top + | ld TMP2, L:CARG1->base + | addiu AT, TMP0, -LUA_YIELD + | daddu CARG3, CARG2, TMP0 + | daddiu TMP3, CARG2, 8 + |.if MIPSR6 + | seleqz CARG2, CARG2, AT + | selnez TMP3, TMP3, AT + | bgtz AT, ->fff_fallback // st > LUA_YIELD? + |. or CARG2, TMP3, CARG2 + |.else + | bgtz AT, ->fff_fallback // st > LUA_YIELD? + |. movn CARG2, TMP3, AT + |.endif + | xor TMP2, TMP2, CARG3 + | bnez TMP1, ->fff_fallback // cframe != 0? + |. or AT, TMP2, TMP0 + | ld TMP0, L:CARG1->maxstack + | beqz AT, ->fff_fallback // base == top && st == 0? + |. ld PC, FRAME_PC(BASE) + | daddu TMP2, CARG2, NARGS8:RC + | sltu AT, TMP0, TMP2 + | bnez AT, ->fff_fallback // Stack overflow? + |. sd PC, SAVE_PC + | sd BASE, L->base + |1: + |.if resume + | daddiu BASE, BASE, 8 // Keep resumed thread in stack for GC. + | daddiu NARGS8:RC, NARGS8:RC, -8 + | daddiu TMP2, TMP2, -8 + |.endif + | sd TMP2, L:CARG1->top + | daddu TMP1, BASE, NARGS8:RC + | move CARG3, CARG2 + | sd BASE, L->top + |2: // Move args to coroutine. + | ld CRET1, 0(BASE) + | sltu AT, BASE, TMP1 + | beqz AT, >3 + |. daddiu BASE, BASE, 8 + | sd CRET1, 0(CARG3) + | b <2 + |. daddiu CARG3, CARG3, 8 + |3: + | bal ->vm_resume // (lua_State *L, TValue *base, 0, 0) + |. move L:RA, L:CARG1 + | // Returns thread status. + |4: + | ld TMP2, L:RA->base + | sltiu AT, CRET1, LUA_YIELD+1 + | ld TMP3, L:RA->top + | li_vmstate INTERP + | ld BASE, L->base + | sd L, DISPATCH_GL(cur_L)(DISPATCH) + | st_vmstate + | beqz AT, >8 + |. dsubu RD, TMP3, TMP2 + | ld TMP0, L->maxstack + | beqz RD, >6 // No results? + |. daddu TMP1, BASE, RD + | sltu AT, TMP0, TMP1 + | bnez AT, >9 // Need to grow stack? + |. daddu TMP3, TMP2, RD + | sd TMP2, L:RA->top // Clear coroutine stack. + | move TMP1, BASE + |5: // Move results from coroutine. + | ld CRET1, 0(TMP2) + | daddiu TMP2, TMP2, 8 + | sltu AT, TMP2, TMP3 + | sd CRET1, 0(TMP1) + | bnez AT, <5 + |. daddiu TMP1, TMP1, 8 + |6: + | andi TMP0, PC, FRAME_TYPE + |.if resume + | mov_true TMP1 + | daddiu RA, BASE, -8 + | sd TMP1, -8(BASE) // Prepend true to results. + | daddiu RD, RD, 16 + |.else + | move RA, BASE + | daddiu RD, RD, 8 + |.endif + |7: + | sd PC, SAVE_PC + | beqz TMP0, ->BC_RET_Z + |. move MULTRES, RD + | b ->vm_return + |. nop + | + |8: // Coroutine returned with error (at co->top-1). + |.if resume + | daddiu TMP3, TMP3, -8 + | mov_false TMP1 + | ld CRET1, 0(TMP3) + | sd TMP3, L:RA->top // Remove error from coroutine stack. + | li RD, (2+1)*8 + | sd TMP1, -8(BASE) // Prepend false to results. + | daddiu RA, BASE, -8 + | sd CRET1, 0(BASE) // Copy error message. + | b <7 + |. andi TMP0, PC, FRAME_TYPE + |.else + | load_got lj_ffh_coroutine_wrap_err + | move CARG2, L:RA + | call_intern lj_ffh_coroutine_wrap_err // (lua_State *L, lua_State *co) + |. move CARG1, L + |.endif + | + |9: // Handle stack expansion on return from yield. + | load_got lj_state_growstack + | srl CARG2, RD, 3 + | call_intern lj_state_growstack // (lua_State *L, int n) + |. move CARG1, L + | b <4 + |. li CRET1, 0 + |.endmacro + | + | coroutine_resume_wrap 1 // coroutine.resume + | coroutine_resume_wrap 0 // coroutine.wrap + | + |.ffunc coroutine_yield + | ld TMP0, L->cframe + | daddu TMP1, BASE, NARGS8:RC + | sd BASE, L->base + | andi TMP0, TMP0, CFRAME_RESUME + | sd TMP1, L->top + | beqz TMP0, ->fff_fallback + |. li CRET1, LUA_YIELD + | sd r0, L->cframe + | b ->vm_leave_unw + |. sb CRET1, L->status + | + |//-- Math library ------------------------------------------------------- + | + |.ffunc_1 math_abs + | gettp CARG2, CARG1 + | daddiu AT, CARG2, -LJ_TISNUM + | bnez AT, >1 + |. sextw TMP1, CARG1 + | sra TMP0, TMP1, 31 // Extract sign. + | xor TMP1, TMP1, TMP0 + | dsubu CARG1, TMP1, TMP0 + | dsll TMP3, CARG1, 32 + | bgez TMP3, ->fff_restv + |. settp CARG1, TISNUM + | li CARG1, 0x41e0 // 2^31 as a double. + | b ->fff_restv + |. dsll CARG1, CARG1, 48 + |1: + | sltiu AT, CARG2, LJ_TISNUM + | beqz AT, ->fff_fallback + |. dextm CARG1, CARG1, 0, 30 + |// fallthrough + | + |->fff_restv: + | // CARG1 = TValue result. + | ld PC, FRAME_PC(BASE) + | daddiu RA, BASE, -16 + | sd CARG1, -16(BASE) + |->fff_res1: + | // RA = results, PC = return. + | li RD, (1+1)*8 + |->fff_res: + | // RA = results, RD = (nresults+1)*8, PC = return. + | andi TMP0, PC, FRAME_TYPE + | bnez TMP0, ->vm_return + |. move MULTRES, RD + | lw INS, -4(PC) + | decode_RB8a RB, INS + | decode_RB8b RB + |5: + | sltu AT, RD, RB + | bnez AT, >6 // More results expected? + |. decode_RA8a TMP0, INS + | decode_RA8b TMP0 + | ins_next1 + | // Adjust BASE. KBASE is assumed to be set for the calling frame. + | dsubu BASE, RA, TMP0 + | ins_next2 + | + |6: // Fill up results with nil. + | daddu TMP1, RA, RD + | daddiu RD, RD, 8 + | b <5 + |. sd TISNIL, -8(TMP1) + | + |.macro math_extern, func + | .ffunc_n math_ .. func + | load_got func + | call_extern + |. nop + | b ->fff_resn + |. nop + |.endmacro + | + |.macro math_extern2, func + | .ffunc_nn math_ .. func + |. load_got func + | call_extern + |. nop + | b ->fff_resn + |. nop + |.endmacro + | + |// TODO: Return integer type if result is integer (own sf implementation). + |.macro math_round, func + |->ff_math_ .. func: + | ld CARG1, 0(BASE) + | beqz NARGS8:RC, ->fff_fallback + |. gettp TMP0, CARG1 + | beq TMP0, TISNUM, ->fff_restv + |. sltu AT, TMP0, TISNUM + | beqz AT, ->fff_fallback + |.if FPU + |. ldc1 FARG1, 0(BASE) + | bal ->vm_ .. func + |. nop + |.else + |. load_got func + | call_extern + |. nop + |.endif + | b ->fff_resn + |. nop + |.endmacro + | + | math_round floor + | math_round ceil + | + |.ffunc math_log + | li AT, 8 + | bne NARGS8:RC, AT, ->fff_fallback // Exactly 1 argument. + |. ld CARG1, 0(BASE) + | checknum CARG1, ->fff_fallback + |. load_got log + |.if FPU + | call_extern + |. ldc1 FARG1, 0(BASE) + |.else + | call_extern + |. nop + |.endif + | b ->fff_resn + |. nop + | + | math_extern log10 + | math_extern exp + | math_extern sin + | math_extern cos + | math_extern tan + | math_extern asin + | math_extern acos + | math_extern atan + | math_extern sinh + | math_extern cosh + | math_extern tanh + | math_extern2 pow + | math_extern2 atan2 + | math_extern2 fmod + | + |.if FPU + |.ffunc_n math_sqrt + |. sqrt.d FRET1, FARG1 + |// fallthrough to ->fff_resn + |.else + | math_extern sqrt + |.endif + | + |->fff_resn: + | ld PC, FRAME_PC(BASE) + | daddiu RA, BASE, -16 + | b ->fff_res1 + |.if FPU + |. sdc1 FRET1, 0(RA) + |.else + |. sd CRET1, 0(RA) + |.endif + | + | + |.ffunc_2 math_ldexp + | checknum CARG1, ->fff_fallback + | checkint CARG2, ->fff_fallback + |. load_got ldexp + | .FPU ldc1 FARG1, 0(BASE) + | call_extern + |. lw CARG2, 8+LO(BASE) + | b ->fff_resn + |. nop + | + |.ffunc_n math_frexp + | load_got frexp + | ld PC, FRAME_PC(BASE) + | call_extern + |. daddiu CARG2, DISPATCH, DISPATCH_GL(tmptv) + | lw TMP1, DISPATCH_GL(tmptv)(DISPATCH) + | daddiu RA, BASE, -16 + |.if FPU + | mtc1 TMP1, FARG2 + | sdc1 FRET1, 0(RA) + | cvt.d.w FARG2, FARG2 + | sdc1 FARG2, 8(RA) + |.else + | sd CRET1, 0(RA) + | zextw TMP1, TMP1 + | settp TMP1, TISNUM + | sd TMP1, 8(RA) + |.endif + | b ->fff_res + |. li RD, (2+1)*8 + | + |.ffunc_n math_modf + | load_got modf + | ld PC, FRAME_PC(BASE) + | call_extern + |. daddiu CARG2, BASE, -16 + | daddiu RA, BASE, -16 + |.if FPU + | sdc1 FRET1, -8(BASE) + |.else + | sd CRET1, -8(BASE) + |.endif + | b ->fff_res + |. li RD, (2+1)*8 + | + |.macro math_minmax, name, intins, intinsc, fpins + | .ffunc_1 name + | daddu TMP3, BASE, NARGS8:RC + | checkint CARG1, >5 + |. daddiu TMP2, BASE, 8 + |1: // Handle integers. + | beq TMP2, TMP3, ->fff_restv + |. ld CARG2, 0(TMP2) + | checkint CARG2, >3 + |. sextw CARG1, CARG1 + | lw CARG2, LO(TMP2) + |. slt AT, CARG1, CARG2 + |.if MIPSR6 + | intins TMP1, CARG2, AT + | intinsc CARG1, CARG1, AT + | or CARG1, CARG1, TMP1 + |.else + | intins CARG1, CARG2, AT + |.endif + | daddiu TMP2, TMP2, 8 + | zextw CARG1, CARG1 + | b <1 + |. settp CARG1, TISNUM + | + |3: // Convert intermediate result to number and continue with number loop. + | checknum CARG2, ->fff_fallback + |.if FPU + |. mtc1 CARG1, FRET1 + | cvt.d.w FRET1, FRET1 + | b >7 + |. ldc1 FARG1, 0(TMP2) + |.else + |. nop + | bal ->vm_sfi2d_1 + |. nop + | b >7 + |. nop + |.endif + | + |5: + | .FPU ldc1 FRET1, 0(BASE) + | checknum CARG1, ->fff_fallback + |6: // Handle numbers. + |. ld CARG2, 0(TMP2) + | beq TMP2, TMP3, ->fff_resn + |.if FPU + | ldc1 FARG1, 0(TMP2) + |.else + | move CRET1, CARG1 + |.endif + | checknum CARG2, >8 + |. nop + |7: + |.if FPU + |.if MIPSR6 + | fpins FRET1, FRET1, FARG1 + |.else + |.if fpins // ismax + | c.olt.d FARG1, FRET1 + |.else + | c.olt.d FRET1, FARG1 + |.endif + | movf.d FRET1, FARG1 + |.endif + |.else + |.if fpins // ismax + | bal ->vm_sfcmpogt + |.else + | bal ->vm_sfcmpolt + |.endif + |. nop + |.if MIPSR6 + | seleqz AT, CARG2, CRET1 + | selnez CARG1, CARG1, CRET1 + | or CARG1, CARG1, AT + |.else + | movz CARG1, CARG2, CRET1 + |.endif + |.endif + | b <6 + |. daddiu TMP2, TMP2, 8 + | + |8: // Convert integer to number and continue with number loop. + | checkint CARG2, ->fff_fallback + |.if FPU + |. lwc1 FARG1, LO(TMP2) + | b <7 + |. cvt.d.w FARG1, FARG1 + |.else + |. lw CARG2, LO(TMP2) + | bal ->vm_sfi2d_2 + |. nop + | b <7 + |. nop + |.endif + | + |.endmacro + | + |.if MIPSR6 + | math_minmax math_min, seleqz, selnez, min.d + | math_minmax math_max, selnez, seleqz, max.d + |.else + | math_minmax math_min, movz, _, 0 + | math_minmax math_max, movn, _, 1 + |.endif + | + |//-- String library ----------------------------------------------------- + | + |.ffunc string_byte // Only handle the 1-arg case here. + | ld CARG1, 0(BASE) + | gettp TMP0, CARG1 + | xori AT, NARGS8:RC, 8 + | daddiu TMP0, TMP0, -LJ_TSTR + | or AT, AT, TMP0 + | bnez AT, ->fff_fallback // Need exactly 1 string argument. + |. cleartp STR:CARG1 + | lw TMP0, STR:CARG1->len + | daddiu RA, BASE, -16 + | ld PC, FRAME_PC(BASE) + | sltu RD, r0, TMP0 + | lbu TMP1, STR:CARG1[1] // Access is always ok (NUL at end). + | addiu RD, RD, 1 + | sll RD, RD, 3 // RD = ((str->len != 0)+1)*8 + | settp TMP1, TISNUM + | b ->fff_res + |. sd TMP1, 0(RA) + | + |.ffunc string_char // Only handle the 1-arg case here. + | ffgccheck + |.if not MIPSR6 + |. nop + |.endif + | ld CARG1, 0(BASE) + | gettp TMP0, CARG1 + | xori AT, NARGS8:RC, 8 // Exactly 1 argument. + | daddiu TMP0, TMP0, -LJ_TISNUM // Integer. + | li TMP1, 255 + | sextw CARG1, CARG1 + | or AT, AT, TMP0 + | sltu TMP1, TMP1, CARG1 // !(255 < n). + | or AT, AT, TMP1 + | bnez AT, ->fff_fallback + |. li CARG3, 1 + | daddiu CARG2, sp, TMPD_OFS + | sb CARG1, TMPD + |->fff_newstr: + | load_got lj_str_new + | sd BASE, L->base + | sd PC, SAVE_PC + | call_intern lj_str_new // (lua_State *L, char *str, size_t l) + |. move CARG1, L + | // Returns GCstr *. + | ld BASE, L->base + |->fff_resstr: + | li AT, LJ_TSTR + | settp CRET1, AT + | b ->fff_restv + |. move CARG1, CRET1 + | + |.ffunc string_sub + | ffgccheck + |.if not MIPSR6 + |. nop + |.endif + | addiu AT, NARGS8:RC, -16 + | ld TMP0, 0(BASE) + | bltz AT, ->fff_fallback + |. gettp TMP3, TMP0 + | cleartp STR:CARG1, TMP0 + | ld CARG2, 8(BASE) + | beqz AT, >1 + |. li CARG4, -1 + | ld CARG3, 16(BASE) + | checkint CARG3, ->fff_fallback + |. sextw CARG4, CARG3 + |1: + | checkint CARG2, ->fff_fallback + |. li AT, LJ_TSTR + | bne TMP3, AT, ->fff_fallback + |. sextw CARG3, CARG2 + | lw CARG2, STR:CARG1->len + | // STR:CARG1 = str, CARG2 = str->len, CARG3 = start, CARG4 = end + | slt AT, CARG4, r0 + | addiu TMP0, CARG2, 1 + | addu TMP1, CARG4, TMP0 + | slt TMP3, CARG3, r0 + |.if MIPSR6 + | seleqz CARG4, CARG4, AT + | selnez TMP1, TMP1, AT + | or CARG4, TMP1, CARG4 // if (end < 0) end += len+1 + |.else + | movn CARG4, TMP1, AT // if (end < 0) end += len+1 + |.endif + | addu TMP1, CARG3, TMP0 + |.if MIPSR6 + | selnez TMP1, TMP1, TMP3 + | seleqz CARG3, CARG3, TMP3 + | or CARG3, TMP1, CARG3 // if (start < 0) start += len+1 + | li TMP2, 1 + | slt AT, CARG4, r0 + | slt TMP3, r0, CARG3 + | seleqz CARG4, CARG4, AT // if (end < 0) end = 0 + | selnez CARG3, CARG3, TMP3 + | seleqz TMP2, TMP2, TMP3 + | or CARG3, TMP2, CARG3 // if (start < 1) start = 1 + | slt AT, CARG2, CARG4 + | seleqz CARG4, CARG4, AT + | selnez CARG2, CARG2, AT + | or CARG4, CARG2, CARG4 // if (end > len) end = len + |.else + | movn CARG3, TMP1, TMP3 // if (start < 0) start += len+1 + | li TMP2, 1 + | slt AT, CARG4, r0 + | slt TMP3, r0, CARG3 + | movn CARG4, r0, AT // if (end < 0) end = 0 + | movz CARG3, TMP2, TMP3 // if (start < 1) start = 1 + | slt AT, CARG2, CARG4 + | movn CARG4, CARG2, AT // if (end > len) end = len + |.endif + | daddu CARG2, STR:CARG1, CARG3 + | subu CARG3, CARG4, CARG3 // len = end - start + | daddiu CARG2, CARG2, sizeof(GCstr)-1 + | bgez CARG3, ->fff_newstr + |. addiu CARG3, CARG3, 1 // len++ + |->fff_emptystr: // Return empty string. + | li AT, LJ_TSTR + | daddiu STR:CARG1, DISPATCH, DISPATCH_GL(strempty) + | b ->fff_restv + |. settp CARG1, AT + | + |.macro ffstring_op, name + | .ffunc string_ .. name + | ffgccheck + |. nop + | beqz NARGS8:RC, ->fff_fallback + |. ld CARG2, 0(BASE) + | checkstr STR:CARG2, ->fff_fallback + | daddiu SBUF:CARG1, DISPATCH, DISPATCH_GL(tmpbuf) + | load_got lj_buf_putstr_ .. name + | ld TMP0, SBUF:CARG1->b + | sd L, SBUF:CARG1->L + | sd BASE, L->base + | sd TMP0, SBUF:CARG1->w + | call_intern extern lj_buf_putstr_ .. name + |. sd PC, SAVE_PC + | load_got lj_buf_tostr + | call_intern lj_buf_tostr + |. move SBUF:CARG1, SBUF:CRET1 + | b ->fff_resstr + |. ld BASE, L->base + |.endmacro + | + |ffstring_op reverse + |ffstring_op lower + |ffstring_op upper + | + |//-- Bit library -------------------------------------------------------- + | + |->vm_tobit_fb: + | beqz TMP1, ->fff_fallback + |.if FPU + |. ldc1 FARG1, 0(BASE) + | add.d FARG1, FARG1, TOBIT + | mfc1 CRET1, FARG1 + | jr ra + |. zextw CRET1, CRET1 + |.else + |// FP number to bit conversion for soft-float. + |->vm_tobit: + | dsll TMP0, CARG1, 1 + | li CARG3, 1076 + | dsrl AT, TMP0, 53 + | dsubu CARG3, CARG3, AT + | sltiu AT, CARG3, 54 + | beqz AT, >1 + |. dextm TMP0, TMP0, 0, 20 + | dinsu TMP0, AT, 21, 21 + | slt AT, CARG1, r0 + | dsrlv CRET1, TMP0, CARG3 + | dsubu TMP0, r0, CRET1 + |.if MIPSR6 + | selnez TMP0, TMP0, AT + | seleqz CRET1, CRET1, AT + | or CRET1, CRET1, TMP0 + |.else + | movn CRET1, TMP0, AT + |.endif + | jr ra + |. zextw CRET1, CRET1 + |1: + | jr ra + |. move CRET1, r0 + | + |// FP number to int conversion with a check for soft-float. + |// Modifies CARG1, CRET1, CRET2, TMP0, AT. + |->vm_tointg: + |.if JIT + | dsll CRET2, CARG1, 1 + | beqz CRET2, >2 + |. li TMP0, 1076 + | dsrl AT, CRET2, 53 + | dsubu TMP0, TMP0, AT + | sltiu AT, TMP0, 54 + | beqz AT, >1 + |. dextm CRET2, CRET2, 0, 20 + | dinsu CRET2, AT, 21, 21 + | slt AT, CARG1, r0 + | dsrlv CRET1, CRET2, TMP0 + | dsubu CARG1, r0, CRET1 + |.if MIPSR6 + | seleqz CRET1, CRET1, AT + | selnez CARG1, CARG1, AT + | or CRET1, CRET1, CARG1 + |.else + | movn CRET1, CARG1, AT + |.endif + | li CARG1, 64 + | subu TMP0, CARG1, TMP0 + | dsllv CRET2, CRET2, TMP0 // Integer check. + | sextw AT, CRET1 + | xor AT, CRET1, AT // Range check. + |.if MIPSR6 + | seleqz AT, AT, CRET2 + | selnez CRET2, CRET2, CRET2 + | jr ra + |. or CRET2, AT, CRET2 + |.else + | jr ra + |. movz CRET2, AT, CRET2 + |.endif + |1: + | jr ra + |. li CRET2, 1 + |2: + | jr ra + |. move CRET1, r0 + |.endif + |.endif + | + |.macro .ffunc_bit, name + | .ffunc_1 bit_..name + | gettp TMP0, CARG1 + | beq TMP0, TISNUM, >6 + |. zextw CRET1, CARG1 + | bal ->vm_tobit_fb + |. sltiu TMP1, TMP0, LJ_TISNUM + |6: + |.endmacro + | + |.macro .ffunc_bit_op, name, bins + | .ffunc_bit name + | daddiu TMP2, BASE, 8 + | daddu TMP3, BASE, NARGS8:RC + |1: + | beq TMP2, TMP3, ->fff_resi + |. ld CARG1, 0(TMP2) + | gettp TMP0, CARG1 + |.if FPU + | bne TMP0, TISNUM, >2 + |. daddiu TMP2, TMP2, 8 + | zextw CARG1, CARG1 + | b <1 + |. bins CRET1, CRET1, CARG1 + |2: + | ldc1 FARG1, -8(TMP2) + | sltiu AT, TMP0, LJ_TISNUM + | beqz AT, ->fff_fallback + |. add.d FARG1, FARG1, TOBIT + | mfc1 CARG1, FARG1 + | zextw CARG1, CARG1 + | b <1 + |. bins CRET1, CRET1, CARG1 + |.else + | beq TMP0, TISNUM, >2 + |. move CRET2, CRET1 + | bal ->vm_tobit_fb + |. sltiu TMP1, TMP0, LJ_TISNUM + | move CARG1, CRET2 + |2: + | zextw CARG1, CARG1 + | bins CRET1, CRET1, CARG1 + | b <1 + |. daddiu TMP2, TMP2, 8 + |.endif + |.endmacro + | + |.ffunc_bit_op band, and + |.ffunc_bit_op bor, or + |.ffunc_bit_op bxor, xor + | + |.ffunc_bit bswap + | dsrl TMP0, CRET1, 8 + | dsrl TMP1, CRET1, 24 + | andi TMP2, TMP0, 0xff00 + | dins TMP1, CRET1, 24, 31 + | dins TMP2, TMP0, 16, 23 + | b ->fff_resi + |. or CRET1, TMP1, TMP2 + | + |.ffunc_bit bnot + | not CRET1, CRET1 + | b ->fff_resi + |. zextw CRET1, CRET1 + | + |.macro .ffunc_bit_sh, name, shins, shmod + | .ffunc_2 bit_..name + | gettp TMP0, CARG1 + | beq TMP0, TISNUM, >1 + |. nop + | bal ->vm_tobit_fb + |. sltiu TMP1, TMP0, LJ_TISNUM + | move CARG1, CRET1 + |1: + | gettp TMP0, CARG2 + | bne TMP0, TISNUM, ->fff_fallback + |. zextw CARG2, CARG2 + | sextw CARG1, CARG1 + |.if shmod == 1 + | negu CARG2, CARG2 + |.endif + | shins CRET1, CARG1, CARG2 + | b ->fff_resi + |. zextw CRET1, CRET1 + |.endmacro + | + |.ffunc_bit_sh lshift, sllv, 0 + |.ffunc_bit_sh rshift, srlv, 0 + |.ffunc_bit_sh arshift, srav, 0 + |.ffunc_bit_sh rol, rotrv, 1 + |.ffunc_bit_sh ror, rotrv, 0 + | + |.ffunc_bit tobit + |->fff_resi: + | ld PC, FRAME_PC(BASE) + | daddiu RA, BASE, -16 + | settp CRET1, TISNUM + | b ->fff_res1 + |. sd CRET1, -16(BASE) + | + |//----------------------------------------------------------------------- + |->fff_fallback: // Call fast function fallback handler. + | // BASE = new base, RB = CFUNC, RC = nargs*8 + | ld TMP3, CFUNC:RB->f + | daddu TMP1, BASE, NARGS8:RC + | ld PC, FRAME_PC(BASE) // Fallback may overwrite PC. + | daddiu TMP0, TMP1, 8*LUA_MINSTACK + | ld TMP2, L->maxstack + | sd PC, SAVE_PC // Redundant (but a defined value). + | sltu AT, TMP2, TMP0 + | sd BASE, L->base + | sd TMP1, L->top + | bnez AT, >5 // Need to grow stack. + |. move CFUNCADDR, TMP3 + | jalr TMP3 // (lua_State *L) + |. move CARG1, L + | // Either throws an error, or recovers and returns -1, 0 or nresults+1. + | ld BASE, L->base + | sll RD, CRET1, 3 + | bgtz CRET1, ->fff_res // Returned nresults+1? + |. daddiu RA, BASE, -16 + |1: // Returned 0 or -1: retry fast path. + | ld LFUNC:RB, FRAME_FUNC(BASE) + | ld TMP0, L->top + | cleartp LFUNC:RB + | bnez CRET1, ->vm_call_tail // Returned -1? + |. dsubu NARGS8:RC, TMP0, BASE + | ins_callt // Returned 0: retry fast path. + | + |// Reconstruct previous base for vmeta_call during tailcall. + |->vm_call_tail: + | andi TMP0, PC, FRAME_TYPE + | li AT, -4 + | bnez TMP0, >3 + |. and TMP1, PC, AT + | lbu TMP1, OFS_RA(PC) + | sll TMP1, TMP1, 3 + | addiu TMP1, TMP1, 16 + |3: + | b ->vm_call_dispatch // Resolve again for tailcall. + |. dsubu TMP2, BASE, TMP1 + | + |5: // Grow stack for fallback handler. + | load_got lj_state_growstack + | li CARG2, LUA_MINSTACK + | call_intern lj_state_growstack // (lua_State *L, int n) + |. move CARG1, L + | ld BASE, L->base + | b <1 + |. li CRET1, 0 // Force retry. + | + |->fff_gcstep: // Call GC step function. + | // BASE = new base, RC = nargs*8 + | move MULTRES, ra + | load_got lj_gc_step + | sd BASE, L->base + | daddu TMP0, BASE, NARGS8:RC + | sd PC, SAVE_PC // Redundant (but a defined value). + | sd TMP0, L->top + | call_intern lj_gc_step // (lua_State *L) + |. move CARG1, L + | ld BASE, L->base + | move ra, MULTRES + | ld TMP0, L->top + | ld CFUNC:RB, FRAME_FUNC(BASE) + | cleartp CFUNC:RB + | jr ra + |. dsubu NARGS8:RC, TMP0, BASE + | + |//----------------------------------------------------------------------- + |//-- Special dispatch targets ------------------------------------------- + |//----------------------------------------------------------------------- + | + |->vm_record: // Dispatch target for recording phase. + |.if JIT + | lbu TMP3, DISPATCH_GL(hookmask)(DISPATCH) + | andi AT, TMP3, HOOK_VMEVENT // No recording while in vmevent. + | bnez AT, >5 + | // Decrement the hookcount for consistency, but always do the call. + |. lw TMP2, DISPATCH_GL(hookcount)(DISPATCH) + | andi AT, TMP3, HOOK_ACTIVE + | bnez AT, >1 + |. addiu TMP2, TMP2, -1 + | andi AT, TMP3, LUA_MASKLINE|LUA_MASKCOUNT + | beqz AT, >1 + |. nop + | b >1 + |. sw TMP2, DISPATCH_GL(hookcount)(DISPATCH) + |.endif + | + |->vm_rethook: // Dispatch target for return hooks. + | lbu TMP3, DISPATCH_GL(hookmask)(DISPATCH) + | andi AT, TMP3, HOOK_ACTIVE // Hook already active? + | beqz AT, >1 + |5: // Re-dispatch to static ins. + |. ld AT, GG_DISP2STATIC(TMP0) // Assumes TMP0 holds DISPATCH+OP*4. + | jr AT + |. nop + | + |->vm_inshook: // Dispatch target for instr/line hooks. + | lbu TMP3, DISPATCH_GL(hookmask)(DISPATCH) + | lw TMP2, DISPATCH_GL(hookcount)(DISPATCH) + | andi AT, TMP3, HOOK_ACTIVE // Hook already active? + | bnez AT, <5 + |. andi AT, TMP3, LUA_MASKLINE|LUA_MASKCOUNT + | beqz AT, <5 + |. addiu TMP2, TMP2, -1 + | beqz TMP2, >1 + |. sw TMP2, DISPATCH_GL(hookcount)(DISPATCH) + | andi AT, TMP3, LUA_MASKLINE + | beqz AT, <5 + |1: + |. load_got lj_dispatch_ins + | sw MULTRES, SAVE_MULTRES + | move CARG2, PC + | sd BASE, L->base + | // SAVE_PC must hold the _previous_ PC. The callee updates it with PC. + | call_intern lj_dispatch_ins // (lua_State *L, const BCIns *pc) + |. move CARG1, L + |3: + | ld BASE, L->base + |4: // Re-dispatch to static ins. + | lw INS, -4(PC) + | decode_OP8a TMP1, INS + | decode_OP8b TMP1 + | daddu TMP0, DISPATCH, TMP1 + | decode_RD8a RD, INS + | ld AT, GG_DISP2STATIC(TMP0) + | decode_RA8a RA, INS + | decode_RD8b RD + | jr AT + | decode_RA8b RA + | + |->cont_hook: // Continue from hook yield. + | daddiu PC, PC, 4 + | b <4 + |. lw MULTRES, -24+LO(RB) // Restore MULTRES for *M ins. + | + |->vm_hotloop: // Hot loop counter underflow. + |.if JIT + | ld LFUNC:TMP1, FRAME_FUNC(BASE) + | daddiu CARG1, DISPATCH, GG_DISP2J + | cleartp LFUNC:TMP1 + | sd PC, SAVE_PC + | ld TMP1, LFUNC:TMP1->pc + | move CARG2, PC + | sd L, DISPATCH_J(L)(DISPATCH) + | lbu TMP1, PC2PROTO(framesize)(TMP1) + | load_got lj_trace_hot + | sd BASE, L->base + | dsll TMP1, TMP1, 3 + | daddu TMP1, BASE, TMP1 + | call_intern lj_trace_hot // (jit_State *J, const BCIns *pc) + |. sd TMP1, L->top + | b <3 + |. nop + |.endif + | + | + |->vm_callhook: // Dispatch target for call hooks. + |.if JIT + | b >1 + |.endif + |. move CARG2, PC + | + |->vm_hotcall: // Hot call counter underflow. + |.if JIT + | ori CARG2, PC, 1 + |1: + |.endif + | load_got lj_dispatch_call + | daddu TMP0, BASE, RC + | sd PC, SAVE_PC + | sd BASE, L->base + | dsubu RA, RA, BASE + | sd TMP0, L->top + | call_intern lj_dispatch_call // (lua_State *L, const BCIns *pc) + |. move CARG1, L + | // Returns ASMFunction. + | ld BASE, L->base + | ld TMP0, L->top + | sd r0, SAVE_PC // Invalidate for subsequent line hook. + | dsubu NARGS8:RC, TMP0, BASE + | daddu RA, BASE, RA + | ld LFUNC:RB, FRAME_FUNC(BASE) + | cleartp LFUNC:RB + | jr CRET1 + |. lw INS, -4(PC) + | + |->cont_stitch: // Trace stitching. + |.if JIT + | // RA = resultptr, RB = meta base + | lw INS, -4(PC) + | ld TRACE:TMP2, -40(RB) // Save previous trace. + | decode_RA8a RC, INS + | daddiu AT, MULTRES, -8 + | cleartp TRACE:TMP2 + | decode_RA8b RC + | beqz AT, >2 + |. daddu RC, BASE, RC // Call base. + |1: // Move results down. + | ld CARG1, 0(RA) + | daddiu AT, AT, -8 + | daddiu RA, RA, 8 + | sd CARG1, 0(RC) + | bnez AT, <1 + |. daddiu RC, RC, 8 + |2: + | decode_RA8a RA, INS + | decode_RB8a RB, INS + | decode_RA8b RA + | decode_RB8b RB + | daddu RA, RA, RB + | daddu RA, BASE, RA + |3: + | sltu AT, RC, RA + | bnez AT, >9 // More results wanted? + |. nop + | + | lhu TMP3, TRACE:TMP2->traceno + | lhu RD, TRACE:TMP2->link + | beq RD, TMP3, ->cont_nop // Blacklisted. + |. load_got lj_dispatch_stitch + | bnez RD, =>BC_JLOOP // Jump to stitched trace. + |. sll RD, RD, 3 + | + | // Stitch a new trace to the previous trace. + | sw TMP3, DISPATCH_J(exitno)(DISPATCH) + | sd L, DISPATCH_J(L)(DISPATCH) + | sd BASE, L->base + | daddiu CARG1, DISPATCH, GG_DISP2J + | call_intern lj_dispatch_stitch // (jit_State *J, const BCIns *pc) + |. move CARG2, PC + | b ->cont_nop + |. ld BASE, L->base + | + |9: + | sd TISNIL, 0(RC) + | b <3 + |. daddiu RC, RC, 8 + |.endif + | + |->vm_profhook: // Dispatch target for profiler hook. +#if LJ_HASPROFILE + | load_got lj_dispatch_profile + | sw MULTRES, SAVE_MULTRES + | move CARG2, PC + | sd BASE, L->base + | call_intern lj_dispatch_profile // (lua_State *L, const BCIns *pc) + |. move CARG1, L + | // HOOK_PROFILE is off again, so re-dispatch to dynamic instruction. + | daddiu PC, PC, -4 + | b ->cont_nop + |. ld BASE, L->base +#endif + | + |//----------------------------------------------------------------------- + |//-- Trace exit handler ------------------------------------------------- + |//----------------------------------------------------------------------- + | + |.macro savex_, a, b + |.if FPU + | sdc1 f..a, a*8(sp) + | sdc1 f..b, b*8(sp) + | sd r..a, 32*8+a*8(sp) + | sd r..b, 32*8+b*8(sp) + |.else + | sd r..a, a*8(sp) + | sd r..b, b*8(sp) + |.endif + |.endmacro + | + |->vm_exit_handler: + |.if JIT + |.if FPU + | daddiu sp, sp, -(32*8+32*8) + |.else + | daddiu sp, sp, -(32*8) + |.endif + | savex_ 0, 1 + | savex_ 2, 3 + | savex_ 4, 5 + | savex_ 6, 7 + | savex_ 8, 9 + | savex_ 10, 11 + | savex_ 12, 13 + | savex_ 14, 15 + | savex_ 16, 17 + | savex_ 18, 19 + | savex_ 20, 21 + | savex_ 22, 23 + | savex_ 24, 25 + | savex_ 26, 27 + | savex_ 28, 30 + |.if FPU + | sdc1 f29, 29*8(sp) + | sdc1 f31, 31*8(sp) + | sd r0, 32*8+31*8(sp) // Clear RID_TMP. + | daddiu TMP2, sp, 32*8+32*8 // Recompute original value of sp. + | sd TMP2, 32*8+29*8(sp) // Store sp in RID_SP + |.else + | sd r0, 31*8(sp) // Clear RID_TMP. + | daddiu TMP2, sp, 32*8 // Recompute original value of sp. + | sd TMP2, 29*8(sp) // Store sp in RID_SP + |.endif + | li_vmstate EXIT + | daddiu DISPATCH, JGL, -GG_DISP2G-32768 + | lw TMP1, 0(TMP2) // Load exit number. + | st_vmstate + | ld L, DISPATCH_GL(cur_L)(DISPATCH) + | ld BASE, DISPATCH_GL(jit_base)(DISPATCH) + | load_got lj_trace_exit + | sd L, DISPATCH_J(L)(DISPATCH) + | sw ra, DISPATCH_J(parent)(DISPATCH) // Store trace number. + | sd BASE, L->base + | sw TMP1, DISPATCH_J(exitno)(DISPATCH) // Store exit number. + | daddiu CARG1, DISPATCH, GG_DISP2J + | sd r0, DISPATCH_GL(jit_base)(DISPATCH) + | call_intern lj_trace_exit // (jit_State *J, ExitState *ex) + |. move CARG2, sp + | // Returns MULTRES (unscaled) or negated error code. + | ld TMP1, L->cframe + | li AT, -4 + | ld BASE, L->base + | and sp, TMP1, AT + | ld PC, SAVE_PC // Get SAVE_PC. + | b >1 + |. sd L, SAVE_L // Set SAVE_L (on-trace resume/yield). + |.endif + |->vm_exit_interp: + |.if JIT + | // CRET1 = MULTRES or negated error code, BASE, PC and JGL set. + | ld L, SAVE_L + | daddiu DISPATCH, JGL, -GG_DISP2G-32768 + | sd BASE, L->base + |1: + | bltz CRET1, >9 // Check for error from exit. + |. ld LFUNC:RB, FRAME_FUNC(BASE) + | .FPU lui TMP3, 0x59c0 // TOBIT = 2^52 + 2^51 (float). + | dsll MULTRES, CRET1, 3 + | cleartp LFUNC:RB + | sw MULTRES, SAVE_MULTRES + | li TISNIL, LJ_TNIL + | li TISNUM, LJ_TISNUM // Setup type comparison constants. + | .FPU mtc1 TMP3, TOBIT + | ld TMP1, LFUNC:RB->pc + | sd r0, DISPATCH_GL(jit_base)(DISPATCH) + | ld KBASE, PC2PROTO(k)(TMP1) + | .FPU cvt.d.s TOBIT, TOBIT + | // Modified copy of ins_next which handles function header dispatch, too. + | lw INS, 0(PC) + | daddiu PC, PC, 4 + | // Assumes TISNIL == ~LJ_VMST_INTERP == -1 + | sw TISNIL, DISPATCH_GL(vmstate)(DISPATCH) + | decode_OP8a TMP1, INS + | decode_OP8b TMP1 + | sltiu TMP2, TMP1, BC_FUNCF*8 + | daddu TMP0, DISPATCH, TMP1 + | decode_RD8a RD, INS + | ld AT, 0(TMP0) + | decode_RA8a RA, INS + | beqz TMP2, >2 + |. decode_RA8b RA + | jr AT + |. decode_RD8b RD + |2: + | sltiu TMP2, TMP1, (BC_FUNCC+2)*8 // Fast function? + | bnez TMP2, >3 + |. ld TMP1, FRAME_PC(BASE) + | // Check frame below fast function. + | andi TMP0, TMP1, FRAME_TYPE + | bnez TMP0, >3 // Trace stitching continuation? + |. nop + | // Otherwise set KBASE for Lua function below fast function. + | lw TMP2, -4(TMP1) + | decode_RA8a TMP0, TMP2 + | decode_RA8b TMP0 + | dsubu TMP1, BASE, TMP0 + | ld LFUNC:TMP2, -32(TMP1) + | cleartp LFUNC:TMP2 + | ld TMP1, LFUNC:TMP2->pc + | ld KBASE, PC2PROTO(k)(TMP1) + |3: + | daddiu RC, MULTRES, -8 + | jr AT + |. daddu RA, RA, BASE + | + |9: // Rethrow error from the right C frame. + | load_got lj_err_trace + | sub CARG2, r0, CRET1 + | call_intern lj_err_trace // (lua_State *L, int errcode) + |. move CARG1, L + |.endif + | + |//----------------------------------------------------------------------- + |//-- Math helper functions ---------------------------------------------- + |//----------------------------------------------------------------------- + | + |// Hard-float round to integer. + |// Modifies AT, TMP0, FRET1, FRET2, f4. Keeps all others incl. FARG1. + |// MIPSR6: Modifies FTMP1, too. + |.macro vm_round_hf, func + | lui TMP0, 0x4330 // Hiword of 2^52 (double). + | dsll TMP0, TMP0, 32 + | dmtc1 TMP0, f4 + | abs.d FRET2, FARG1 // |x| + | dmfc1 AT, FARG1 + |.if MIPSR6 + | cmp.lt.d FTMP1, FRET2, f4 + | add.d FRET1, FRET2, f4 // (|x| + 2^52) - 2^52 + | bc1eqz FTMP1, >1 // Truncate only if |x| < 2^52. + |.else + | c.olt.d 0, FRET2, f4 + | add.d FRET1, FRET2, f4 // (|x| + 2^52) - 2^52 + | bc1f 0, >1 // Truncate only if |x| < 2^52. + |.endif + |. sub.d FRET1, FRET1, f4 + | slt AT, AT, r0 + |.if "func" == "ceil" + | lui TMP0, 0xbff0 // Hiword of -1 (double). Preserves -0. + |.else + | lui TMP0, 0x3ff0 // Hiword of +1 (double). + |.endif + |.if "func" == "trunc" + | dsll TMP0, TMP0, 32 + | dmtc1 TMP0, f4 + |.if MIPSR6 + | cmp.lt.d FTMP1, FRET2, FRET1 // |x| < result? + | sub.d FRET2, FRET1, f4 + | sel.d FTMP1, FRET1, FRET2 // If yes, subtract +1. + | dmtc1 AT, FRET1 + | neg.d FRET2, FTMP1 + | jr ra + |. sel.d FRET1, FTMP1, FRET2 // Merge sign bit back in. + |.else + | c.olt.d 0, FRET2, FRET1 // |x| < result? + | sub.d FRET2, FRET1, f4 + | movt.d FRET1, FRET2, 0 // If yes, subtract +1. + | neg.d FRET2, FRET1 + | jr ra + |. movn.d FRET1, FRET2, AT // Merge sign bit back in. + |.endif + |.else + | neg.d FRET2, FRET1 + | dsll TMP0, TMP0, 32 + | dmtc1 TMP0, f4 + |.if MIPSR6 + | dmtc1 AT, FTMP1 + | sel.d FTMP1, FRET1, FRET2 + |.if "func" == "ceil" + | cmp.lt.d FRET1, FTMP1, FARG1 // x > result? + |.else + | cmp.lt.d FRET1, FARG1, FTMP1 // x < result? + |.endif + | sub.d FRET2, FTMP1, f4 // If yes, subtract +-1. + | jr ra + |. sel.d FRET1, FTMP1, FRET2 + |.else + | movn.d FRET1, FRET2, AT // Merge sign bit back in. + |.if "func" == "ceil" + | c.olt.d 0, FRET1, FARG1 // x > result? + |.else + | c.olt.d 0, FARG1, FRET1 // x < result? + |.endif + | sub.d FRET2, FRET1, f4 // If yes, subtract +-1. + | jr ra + |. movt.d FRET1, FRET2, 0 + |.endif + |.endif + |1: + | jr ra + |. mov.d FRET1, FARG1 + |.endmacro + | + |.macro vm_round, func + |.if FPU + | vm_round_hf, func + |.endif + |.endmacro + | + |->vm_floor: + | vm_round floor + |->vm_ceil: + | vm_round ceil + |->vm_trunc: + |.if JIT + | vm_round trunc + |.endif + | + |// Soft-float integer to number conversion. + |.macro sfi2d, ARG + |.if not FPU + | beqz ARG, >9 // Handle zero first. + |. sra TMP0, ARG, 31 + | xor TMP1, ARG, TMP0 + | dsubu TMP1, TMP1, TMP0 // Absolute value in TMP1. + | dclz ARG, TMP1 + | addiu ARG, ARG, -11 + | li AT, 0x3ff+63-11-1 + | dsllv TMP1, TMP1, ARG // Align mantissa left with leading 1. + | subu ARG, AT, ARG // Exponent - 1. + | ins ARG, TMP0, 11, 11 // Sign | Exponent. + | dsll ARG, ARG, 52 // Align left. + | jr ra + |. daddu ARG, ARG, TMP1 // Add mantissa, increment exponent. + |9: + | jr ra + |. nop + |.endif + |.endmacro + | + |// Input CARG1. Output: CARG1. Temporaries: AT, TMP0, TMP1. + |->vm_sfi2d_1: + | sfi2d CARG1 + | + |// Input CARG2. Output: CARG2. Temporaries: AT, TMP0, TMP1. + |->vm_sfi2d_2: + | sfi2d CARG2 + | + |// Soft-float comparison. Equivalent to c.eq.d. + |// Input: CARG*. Output: CRET1. Temporaries: AT, TMP0, TMP1. + |->vm_sfcmpeq: + |.if not FPU + | dsll AT, CARG1, 1 + | dsll TMP0, CARG2, 1 + | or TMP1, AT, TMP0 + | beqz TMP1, >8 // Both args +-0: return 1. + |. lui TMP1, 0xffe0 + | dsll TMP1, TMP1, 32 + | sltu AT, TMP1, AT + | sltu TMP0, TMP1, TMP0 + | or TMP1, AT, TMP0 + | bnez TMP1, >9 // Either arg is NaN: return 0; + |. xor AT, CARG1, CARG2 + | jr ra + |. sltiu CRET1, AT, 1 // Same values: return 1. + |8: + | jr ra + |. li CRET1, 1 + |9: + | jr ra + |. li CRET1, 0 + |.endif + | + |// Soft-float comparison. Equivalent to c.ult.d and c.olt.d. + |// Input: CARG1, CARG2. Output: CRET1. Temporaries: AT, TMP0, TMP1, CRET2. + |->vm_sfcmpult: + |.if not FPU + | b >1 + |. li CRET2, 1 + |.endif + | + |->vm_sfcmpolt: + |.if not FPU + | li CRET2, 0 + |1: + | dsll AT, CARG1, 1 + | dsll TMP0, CARG2, 1 + | or TMP1, AT, TMP0 + | beqz TMP1, >8 // Both args +-0: return 0. + |. lui TMP1, 0xffe0 + | dsll TMP1, TMP1, 32 + | sltu AT, TMP1, AT + | sltu TMP0, TMP1, TMP0 + | or TMP1, AT, TMP0 + | bnez TMP1, >9 // Either arg is NaN: return 0 or 1; + |. and AT, CARG1, CARG2 + | bltz AT, >5 // Both args negative? + |. nop + | jr ra + |. slt CRET1, CARG1, CARG2 + |5: // Swap conditions if both operands are negative. + | jr ra + |. slt CRET1, CARG2, CARG1 + |8: + | jr ra + |. li CRET1, 0 + |9: + | jr ra + |. move CRET1, CRET2 + |.endif + | + |->vm_sfcmpogt: + |.if not FPU + | dsll AT, CARG2, 1 + | dsll TMP0, CARG1, 1 + | or TMP1, AT, TMP0 + | beqz TMP1, >8 // Both args +-0: return 0. + |. lui TMP1, 0xffe0 + | dsll TMP1, TMP1, 32 + | sltu AT, TMP1, AT + | sltu TMP0, TMP1, TMP0 + | or TMP1, AT, TMP0 + | bnez TMP1, >9 // Either arg is NaN: return 0 or 1; + |. and AT, CARG2, CARG1 + | bltz AT, >5 // Both args negative? + |. nop + | jr ra + |. slt CRET1, CARG2, CARG1 + |5: // Swap conditions if both operands are negative. + | jr ra + |. slt CRET1, CARG1, CARG2 + |8: + | jr ra + |. li CRET1, 0 + |9: + | jr ra + |. li CRET1, 0 + |.endif + | + |// Soft-float comparison. Equivalent to c.ole.d a, b or c.ole.d b, a. + |// Input: CARG1, CARG2, TMP3. Output: CRET1. Temporaries: AT, TMP0, TMP1. + |->vm_sfcmpolex: + |.if not FPU + | dsll AT, CARG1, 1 + | dsll TMP0, CARG2, 1 + | or TMP1, AT, TMP0 + | beqz TMP1, >8 // Both args +-0: return 1. + |. lui TMP1, 0xffe0 + | dsll TMP1, TMP1, 32 + | sltu AT, TMP1, AT + | sltu TMP0, TMP1, TMP0 + | or TMP1, AT, TMP0 + | bnez TMP1, >9 // Either arg is NaN: return 0; + |. and AT, CARG1, CARG2 + | xor AT, AT, TMP3 + | bltz AT, >5 // Both args negative? + |. nop + | jr ra + |. slt CRET1, CARG2, CARG1 + |5: // Swap conditions if both operands are negative. + | jr ra + |. slt CRET1, CARG1, CARG2 + |8: + | jr ra + |. li CRET1, 1 + |9: + | jr ra + |. li CRET1, 0 + |.endif + | + |.macro sfmin_max, name, fpcall + |->vm_sf .. name: + |.if JIT and not FPU + | move TMP2, ra + | bal ->fpcall + |. nop + | move ra, TMP2 + | move TMP0, CRET1 + | move CRET1, CARG1 + |.if MIPSR6 + | selnez CRET1, CRET1, TMP0 + | seleqz TMP0, CARG2, TMP0 + | jr ra + |. or CRET1, CRET1, TMP0 + |.else + | jr ra + |. movz CRET1, CARG2, TMP0 + |.endif + |.endif + |.endmacro + | + | sfmin_max min, vm_sfcmpolt + | sfmin_max max, vm_sfcmpogt + | + |//----------------------------------------------------------------------- + |//-- Miscellaneous functions -------------------------------------------- + |//----------------------------------------------------------------------- + | + |.define NEXT_TAB, TAB:CARG1 + |.define NEXT_IDX, CARG2 + |.define NEXT_ASIZE, CARG3 + |.define NEXT_NIL, CARG4 + |.define NEXT_TMP0, r12 + |.define NEXT_TMP1, r13 + |.define NEXT_TMP2, r14 + |.define NEXT_RES_VK, CRET1 + |.define NEXT_RES_IDX, CRET2 + |.define NEXT_RES_PTR, sp + |.define NEXT_RES_VAL, 0(sp) + |.define NEXT_RES_KEY, 8(sp) + | + |// TValue *lj_vm_next(GCtab *t, uint32_t idx) + |// Next idx returned in CRET2. + |->vm_next: + |.if JIT and ENDIAN_LE + | lw NEXT_ASIZE, NEXT_TAB->asize + | ld NEXT_TMP0, NEXT_TAB->array + | li NEXT_NIL, LJ_TNIL + |1: // Traverse array part. + | sltu AT, NEXT_IDX, NEXT_ASIZE + | sll NEXT_TMP1, NEXT_IDX, 3 + | beqz AT, >5 + |. daddu NEXT_TMP1, NEXT_TMP0, NEXT_TMP1 + | li AT, LJ_TISNUM + | ld NEXT_TMP2, 0(NEXT_TMP1) + | dsll AT, AT, 47 + | or NEXT_TMP1, NEXT_IDX, AT + | beq NEXT_TMP2, NEXT_NIL, <1 + |. addiu NEXT_IDX, NEXT_IDX, 1 + | sd NEXT_TMP2, NEXT_RES_VAL + | sd NEXT_TMP1, NEXT_RES_KEY + | move NEXT_RES_VK, NEXT_RES_PTR + | jr ra + |. move NEXT_RES_IDX, NEXT_IDX + | + |5: // Traverse hash part. + | subu NEXT_RES_IDX, NEXT_IDX, NEXT_ASIZE + | ld NODE:NEXT_RES_VK, NEXT_TAB->node + | sll NEXT_TMP2, NEXT_RES_IDX, 5 + | lw NEXT_TMP0, NEXT_TAB->hmask + | sll AT, NEXT_RES_IDX, 3 + | subu AT, NEXT_TMP2, AT + | daddu NODE:NEXT_RES_VK, NODE:NEXT_RES_VK, AT + |6: + | sltu AT, NEXT_TMP0, NEXT_RES_IDX + | bnez AT, >8 + |. nop + | ld NEXT_TMP2, NODE:NEXT_RES_VK->val + | bne NEXT_TMP2, NEXT_NIL, >9 + |. addiu NEXT_RES_IDX, NEXT_RES_IDX, 1 + | // Skip holes in hash part. + | b <6 + |. daddiu NODE:NEXT_RES_VK, NODE:NEXT_RES_VK, sizeof(Node) + | + |8: // End of iteration. Set the key to nil (not the value). + | sd NEXT_NIL, NEXT_RES_KEY + | move NEXT_RES_VK, NEXT_RES_PTR + |9: + | jr ra + |. addu NEXT_RES_IDX, NEXT_RES_IDX, NEXT_ASIZE + |.endif + | + |//----------------------------------------------------------------------- + |//-- FFI helper functions ----------------------------------------------- + |//----------------------------------------------------------------------- + | + |// Handler for callback functions. Callback slot number in r1, g in r2. + |->vm_ffi_callback: + |.if FFI + |.type CTSTATE, CTState, PC + | saveregs + | ld CTSTATE, GL:r2->ctype_state + | daddiu DISPATCH, r2, GG_G2DISP + | load_got lj_ccallback_enter + | sw r1, CTSTATE->cb.slot + | sd CARG1, CTSTATE->cb.gpr[0] + | .FPU sdc1 FARG1, CTSTATE->cb.fpr[0] + | sd CARG2, CTSTATE->cb.gpr[1] + | .FPU sdc1 FARG2, CTSTATE->cb.fpr[1] + | sd CARG3, CTSTATE->cb.gpr[2] + | .FPU sdc1 FARG3, CTSTATE->cb.fpr[2] + | sd CARG4, CTSTATE->cb.gpr[3] + | .FPU sdc1 FARG4, CTSTATE->cb.fpr[3] + | sd CARG5, CTSTATE->cb.gpr[4] + | .FPU sdc1 FARG5, CTSTATE->cb.fpr[4] + | sd CARG6, CTSTATE->cb.gpr[5] + | .FPU sdc1 FARG6, CTSTATE->cb.fpr[5] + | sd CARG7, CTSTATE->cb.gpr[6] + | .FPU sdc1 FARG7, CTSTATE->cb.fpr[6] + | sd CARG8, CTSTATE->cb.gpr[7] + | .FPU sdc1 FARG8, CTSTATE->cb.fpr[7] + | daddiu TMP0, sp, CFRAME_SPACE + | sd TMP0, CTSTATE->cb.stack + | sd r0, SAVE_PC // Any value outside of bytecode is ok. + | move CARG2, sp + | call_intern lj_ccallback_enter // (CTState *cts, void *cf) + |. move CARG1, CTSTATE + | // Returns lua_State *. + | ld BASE, L:CRET1->base + | ld RC, L:CRET1->top + | move L, CRET1 + | .FPU lui TMP3, 0x59c0 // TOBIT = 2^52 + 2^51 (float). + | ld LFUNC:RB, FRAME_FUNC(BASE) + | .FPU mtc1 TMP3, TOBIT + | li TISNIL, LJ_TNIL + | li TISNUM, LJ_TISNUM + | li_vmstate INTERP + | subu RC, RC, BASE + | cleartp LFUNC:RB + | st_vmstate + | .FPU cvt.d.s TOBIT, TOBIT + | ins_callt + |.endif + | + |->cont_ffi_callback: // Return from FFI callback. + |.if FFI + | load_got lj_ccallback_leave + | ld CTSTATE, DISPATCH_GL(ctype_state)(DISPATCH) + | sd BASE, L->base + | sd RB, L->top + | sd L, CTSTATE->L + | move CARG2, RA + | call_intern lj_ccallback_leave // (CTState *cts, TValue *o) + |. move CARG1, CTSTATE + | .FPU ldc1 FRET1, CTSTATE->cb.fpr[0] + | ld CRET1, CTSTATE->cb.gpr[0] + | .FPU ldc1 FRET2, CTSTATE->cb.fpr[1] + | b ->vm_leave_unw + |. ld CRET2, CTSTATE->cb.gpr[1] + |.endif + | + |->vm_ffi_call: // Call C function via FFI. + | // Caveat: needs special frame unwinding, see below. + |.if FFI + | .type CCSTATE, CCallState, CARG1 + | lw TMP1, CCSTATE->spadj + | lbu CARG2, CCSTATE->nsp + | move TMP2, sp + | dsubu sp, sp, TMP1 + | sd ra, -8(TMP2) + | sll CARG2, CARG2, 3 + | sd r16, -16(TMP2) + | sd CCSTATE, -24(TMP2) + | move r16, TMP2 + | daddiu TMP1, CCSTATE, offsetof(CCallState, stack) + | move TMP2, sp + | beqz CARG2, >2 + |. daddu TMP3, TMP1, CARG2 + |1: + | ld TMP0, 0(TMP1) + | daddiu TMP1, TMP1, 8 + | sltu AT, TMP1, TMP3 + | sd TMP0, 0(TMP2) + | bnez AT, <1 + |. daddiu TMP2, TMP2, 8 + |2: + | ld CFUNCADDR, CCSTATE->func + | .FPU ldc1 FARG1, CCSTATE->gpr[0] + | ld CARG2, CCSTATE->gpr[1] + | .FPU ldc1 FARG2, CCSTATE->gpr[1] + | ld CARG3, CCSTATE->gpr[2] + | .FPU ldc1 FARG3, CCSTATE->gpr[2] + | ld CARG4, CCSTATE->gpr[3] + | .FPU ldc1 FARG4, CCSTATE->gpr[3] + | ld CARG5, CCSTATE->gpr[4] + | .FPU ldc1 FARG5, CCSTATE->gpr[4] + | ld CARG6, CCSTATE->gpr[5] + | .FPU ldc1 FARG6, CCSTATE->gpr[5] + | ld CARG7, CCSTATE->gpr[6] + | .FPU ldc1 FARG7, CCSTATE->gpr[6] + | ld CARG8, CCSTATE->gpr[7] + | .FPU ldc1 FARG8, CCSTATE->gpr[7] + | jalr CFUNCADDR + |. ld CARG1, CCSTATE->gpr[0] // Do this last, since CCSTATE is CARG1. + | ld CCSTATE:TMP1, -24(r16) + | ld TMP2, -16(r16) + | ld ra, -8(r16) + | sd CRET1, CCSTATE:TMP1->gpr[0] + | sd CRET2, CCSTATE:TMP1->gpr[1] + |.if FPU + | sdc1 FRET1, CCSTATE:TMP1->fpr[0] + | sdc1 FRET2, CCSTATE:TMP1->fpr[1] + |.else + | sd CARG1, CCSTATE:TMP1->gpr[2] // 2nd FP struct field for soft-float. + |.endif + | move sp, r16 + | jr ra + |. move r16, TMP2 + |.endif + |// Note: vm_ffi_call must be the last function in this object file! + | + |//----------------------------------------------------------------------- +} + +/* Generate the code for a single instruction. */ +static void build_ins(BuildCtx *ctx, BCOp op, int defop) +{ + int vk = 0; + |=>defop: + + switch (op) { + + /* -- Comparison ops ---------------------------------------------------- */ + + /* Remember: all ops branch for a true comparison, fall through otherwise. */ + + case BC_ISLT: case BC_ISGE: case BC_ISLE: case BC_ISGT: + | // RA = src1*8, RD = src2*8, JMP with RD = target + |.macro bc_comp, FRA, FRD, ARGRA, ARGRD, movop, fmovop, fcomp, sfcomp + | daddu RA, BASE, RA + | daddu RD, BASE, RD + | ld ARGRA, 0(RA) + | ld ARGRD, 0(RD) + | lhu TMP2, OFS_RD(PC) + | gettp CARG3, ARGRA + | gettp CARG4, ARGRD + | bne CARG3, TISNUM, >2 + |. daddiu PC, PC, 4 + | bne CARG4, TISNUM, >5 + |. decode_RD4b TMP2 + | sextw ARGRA, ARGRA + | sextw ARGRD, ARGRD + | lui TMP3, (-(BCBIAS_J*4 >> 16) & 65535) + | slt AT, CARG1, CARG2 + | addu TMP2, TMP2, TMP3 + |.if MIPSR6 + | movop TMP2, TMP2, AT + |.else + | movop TMP2, r0, AT + |.endif + |1: + | daddu PC, PC, TMP2 + | ins_next + | + |2: // RA is not an integer. + | sltiu AT, CARG3, LJ_TISNUM + | beqz AT, ->vmeta_comp + |. lui TMP3, (-(BCBIAS_J*4 >> 16) & 65535) + | sltiu AT, CARG4, LJ_TISNUM + | beqz AT, >4 + |. decode_RD4b TMP2 + |.if FPU + | ldc1 FRA, 0(RA) + | ldc1 FRD, 0(RD) + |.endif + |3: // RA and RD are both numbers. + |.if FPU + |.if MIPSR6 + | fcomp FTMP0, FTMP0, FTMP2 + | addu TMP2, TMP2, TMP3 + | mfc1 TMP3, FTMP0 + | b <1 + |. fmovop TMP2, TMP2, TMP3 + |.else + | fcomp FTMP0, FTMP2 + | addu TMP2, TMP2, TMP3 + | b <1 + |. fmovop TMP2, r0 + |.endif + |.else + | bal sfcomp + |. addu TMP2, TMP2, TMP3 + | b <1 + |.if MIPSR6 + |. movop TMP2, TMP2, CRET1 + |.else + |. movop TMP2, r0, CRET1 + |.endif + |.endif + | + |4: // RA is a number, RD is not a number. + | bne CARG4, TISNUM, ->vmeta_comp + | // RA is a number, RD is an integer. Convert RD to a number. + |.if FPU + |. lwc1 FRD, LO(RD) + | ldc1 FRA, 0(RA) + | b <3 + |. cvt.d.w FRD, FRD + |.else + |.if "ARGRD" == "CARG1" + |. sextw CARG1, CARG1 + | bal ->vm_sfi2d_1 + |. nop + |.else + |. sextw CARG2, CARG2 + | bal ->vm_sfi2d_2 + |. nop + |.endif + | b <3 + |. nop + |.endif + | + |5: // RA is an integer, RD is not an integer + | sltiu AT, CARG4, LJ_TISNUM + | beqz AT, ->vmeta_comp + |. lui TMP3, (-(BCBIAS_J*4 >> 16) & 65535) + | // RA is an integer, RD is a number. Convert RA to a number. + |.if FPU + | lwc1 FRA, LO(RA) + | ldc1 FRD, 0(RD) + | b <3 + | cvt.d.w FRA, FRA + |.else + |.if "ARGRA" == "CARG1" + | bal ->vm_sfi2d_1 + |. sextw CARG1, CARG1 + |.else + | bal ->vm_sfi2d_2 + |. sextw CARG2, CARG2 + |.endif + | b <3 + |. nop + |.endif + |.endmacro + | + |.if MIPSR6 + if (op == BC_ISLT) { + | bc_comp FTMP0, FTMP2, CARG1, CARG2, selnez, selnez, cmp.lt.d, ->vm_sfcmpolt + } else if (op == BC_ISGE) { + | bc_comp FTMP0, FTMP2, CARG1, CARG2, seleqz, seleqz, cmp.lt.d, ->vm_sfcmpolt + } else if (op == BC_ISLE) { + | bc_comp FTMP2, FTMP0, CARG2, CARG1, seleqz, seleqz, cmp.ult.d, ->vm_sfcmpult + } else { + | bc_comp FTMP2, FTMP0, CARG2, CARG1, selnez, selnez, cmp.ult.d, ->vm_sfcmpult + } + |.else + if (op == BC_ISLT) { + | bc_comp FTMP0, FTMP2, CARG1, CARG2, movz, movf, c.olt.d, ->vm_sfcmpolt + } else if (op == BC_ISGE) { + | bc_comp FTMP0, FTMP2, CARG1, CARG2, movn, movt, c.olt.d, ->vm_sfcmpolt + } else if (op == BC_ISLE) { + | bc_comp FTMP2, FTMP0, CARG2, CARG1, movn, movt, c.ult.d, ->vm_sfcmpult + } else { + | bc_comp FTMP2, FTMP0, CARG2, CARG1, movz, movf, c.ult.d, ->vm_sfcmpult + } + |.endif + break; + + case BC_ISEQV: case BC_ISNEV: + vk = op == BC_ISEQV; + | // RA = src1*8, RD = src2*8, JMP with RD = target + | daddu RA, BASE, RA + | daddiu PC, PC, 4 + | daddu RD, BASE, RD + | ld CARG1, 0(RA) + | lhu TMP2, -4+OFS_RD(PC) + | ld CARG2, 0(RD) + | gettp CARG3, CARG1 + | gettp CARG4, CARG2 + | sltu AT, TISNUM, CARG3 + | sltu TMP1, TISNUM, CARG4 + | or AT, AT, TMP1 + if (vk) { + | beqz AT, ->BC_ISEQN_Z + } else { + | beqz AT, ->BC_ISNEN_Z + } + | // Either or both types are not numbers. + | lui TMP3, (-(BCBIAS_J*4 >> 16) & 65535) + |.if FFI + |. li AT, LJ_TCDATA + | beq CARG3, AT, ->vmeta_equal_cd + |.endif + | decode_RD4b TMP2 + |.if FFI + | beq CARG4, AT, ->vmeta_equal_cd + |. nop + |.endif + | bne CARG1, CARG2, >2 + |. addu TMP2, TMP2, TMP3 + | // Tag and value are equal. + if (vk) { + |->BC_ISEQV_Z: + | daddu PC, PC, TMP2 + } + |1: + | ins_next + | + |2: // Check if the tags are the same and it's a table or userdata. + | xor AT, CARG3, CARG4 // Same type? + | sltiu TMP0, CARG3, LJ_TISTABUD+1 // Table or userdata? + |.if MIPSR6 + | seleqz TMP0, TMP0, AT + |.else + | movn TMP0, r0, AT + |.endif + if (vk) { + | beqz TMP0, <1 + } else { + | beqz TMP0, ->BC_ISEQV_Z // Reuse code from opposite instruction. + } + | // Different tables or userdatas. Need to check __eq metamethod. + | // Field metatable must be at same offset for GCtab and GCudata! + |. cleartp TAB:TMP1, CARG1 + | ld TAB:TMP3, TAB:TMP1->metatable + if (vk) { + | beqz TAB:TMP3, <1 // No metatable? + |. nop + | lbu TMP3, TAB:TMP3->nomm + | andi TMP3, TMP3, 1<1 // Or 'no __eq' flag set? + } else { + | beqz TAB:TMP3,->BC_ISEQV_Z // No metatable? + |. nop + | lbu TMP3, TAB:TMP3->nomm + | andi TMP3, TMP3, 1<BC_ISEQV_Z // Or 'no __eq' flag set? + } + |. nop + | b ->vmeta_equal // Handle __eq metamethod. + |. li TMP0, 1-vk // ne = 0 or 1. + break; + + case BC_ISEQS: case BC_ISNES: + vk = op == BC_ISEQS; + | // RA = src*8, RD = str_const*8 (~), JMP with RD = target + | daddu RA, BASE, RA + | daddiu PC, PC, 4 + | ld CARG1, 0(RA) + | dsubu RD, KBASE, RD + | lhu TMP2, -4+OFS_RD(PC) + | ld CARG2, -8(RD) // KBASE-8-str_const*8 + |.if FFI + | gettp TMP0, CARG1 + | li AT, LJ_TCDATA + |.endif + | li TMP1, LJ_TSTR + | decode_RD4b TMP2 + |.if FFI + | beq TMP0, AT, ->vmeta_equal_cd + |.endif + |. settp CARG2, TMP1 + | lui TMP3, (-(BCBIAS_J*4 >> 16) & 65535) + | xor TMP1, CARG1, CARG2 + | addu TMP2, TMP2, TMP3 + |.if MIPSR6 + if (vk) { + | seleqz TMP2, TMP2, TMP1 + } else { + | selnez TMP2, TMP2, TMP1 + } + |.else + if (vk) { + | movn TMP2, r0, TMP1 + } else { + | movz TMP2, r0, TMP1 + } + |.endif + | daddu PC, PC, TMP2 + | ins_next + break; + + case BC_ISEQN: case BC_ISNEN: + vk = op == BC_ISEQN; + | // RA = src*8, RD = num_const*8, JMP with RD = target + | daddu RA, BASE, RA + | daddu RD, KBASE, RD + | ld CARG1, 0(RA) + | ld CARG2, 0(RD) + | lhu TMP2, OFS_RD(PC) + | gettp CARG3, CARG1 + | gettp CARG4, CARG2 + | daddiu PC, PC, 4 + | lui TMP3, (-(BCBIAS_J*4 >> 16) & 65535) + if (vk) { + |->BC_ISEQN_Z: + } else { + |->BC_ISNEN_Z: + } + | bne CARG3, TISNUM, >3 + |. decode_RD4b TMP2 + | bne CARG4, TISNUM, >6 + |. addu TMP2, TMP2, TMP3 + | xor AT, CARG1, CARG2 + |.if MIPSR6 + if (vk) { + | seleqz TMP2, TMP2, AT + |1: + | daddu PC, PC, TMP2 + |2: + } else { + | selnez TMP2, TMP2, AT + |1: + |2: + | daddu PC, PC, TMP2 + } + |.else + if (vk) { + | movn TMP2, r0, AT + |1: + | daddu PC, PC, TMP2 + |2: + } else { + | movz TMP2, r0, AT + |1: + |2: + | daddu PC, PC, TMP2 + } + |.endif + | ins_next + | + |3: // RA is not an integer. + | sltu AT, CARG3, TISNUM + |.if FFI + | beqz AT, >8 + |.else + | beqz AT, <2 + |.endif + |. addu TMP2, TMP2, TMP3 + | sltu AT, CARG4, TISNUM + |.if FPU + | ldc1 FTMP0, 0(RA) + | ldc1 FTMP2, 0(RD) + |.endif + | beqz AT, >5 + |. nop + |4: // RA and RD are both numbers. + |.if FPU + |.if MIPSR6 + | cmp.eq.d FTMP0, FTMP0, FTMP2 + | dmfc1 TMP1, FTMP0 + | b <1 + if (vk) { + |. selnez TMP2, TMP2, TMP1 + } else { + |. seleqz TMP2, TMP2, TMP1 + } + |.else + | c.eq.d FTMP0, FTMP2 + | b <1 + if (vk) { + |. movf TMP2, r0 + } else { + |. movt TMP2, r0 + } + |.endif + |.else + | bal ->vm_sfcmpeq + |. nop + | b <1 + |.if MIPSR6 + if (vk) { + |. selnez TMP2, TMP2, CRET1 + } else { + |. seleqz TMP2, TMP2, CRET1 + } + |.else + if (vk) { + |. movz TMP2, r0, CRET1 + } else { + |. movn TMP2, r0, CRET1 + } + |.endif + |.endif + | + |5: // RA is a number, RD is not a number. + |.if FFI + | bne CARG4, TISNUM, >9 + |.else + | bne CARG4, TISNUM, <2 + |.endif + | // RA is a number, RD is an integer. Convert RD to a number. + |.if FPU + |. lwc1 FTMP2, LO(RD) + | b <4 + |. cvt.d.w FTMP2, FTMP2 + |.else + |. sextw CARG2, CARG2 + | bal ->vm_sfi2d_2 + |. nop + | b <4 + |. nop + |.endif + | + |6: // RA is an integer, RD is not an integer + | sltu AT, CARG4, TISNUM + |.if FFI + | beqz AT, >9 + |.else + | beqz AT, <2 + |.endif + | // RA is an integer, RD is a number. Convert RA to a number. + |.if FPU + |. lwc1 FTMP0, LO(RA) + | ldc1 FTMP2, 0(RD) + | b <4 + | cvt.d.w FTMP0, FTMP0 + |.else + |. sextw CARG1, CARG1 + | bal ->vm_sfi2d_1 + |. nop + | b <4 + |. nop + |.endif + | + |.if FFI + |8: + | li AT, LJ_TCDATA + | bne CARG3, AT, <2 + |. nop + | b ->vmeta_equal_cd + |. nop + |9: + | li AT, LJ_TCDATA + | bne CARG4, AT, <2 + |. nop + | b ->vmeta_equal_cd + |. nop + |.endif + break; + + case BC_ISEQP: case BC_ISNEP: + vk = op == BC_ISEQP; + | // RA = src*8, RD = primitive_type*8 (~), JMP with RD = target + | daddu RA, BASE, RA + | srl TMP1, RD, 3 + | ld TMP0, 0(RA) + | lhu TMP2, OFS_RD(PC) + | not TMP1, TMP1 + | gettp TMP0, TMP0 + | daddiu PC, PC, 4 + |.if FFI + | li AT, LJ_TCDATA + | beq TMP0, AT, ->vmeta_equal_cd + |.endif + |. xor TMP0, TMP0, TMP1 + | decode_RD4b TMP2 + | lui TMP3, (-(BCBIAS_J*4 >> 16) & 65535) + | addu TMP2, TMP2, TMP3 + |.if MIPSR6 + if (vk) { + | seleqz TMP2, TMP2, TMP0 + } else { + | selnez TMP2, TMP2, TMP0 + } + |.else + if (vk) { + | movn TMP2, r0, TMP0 + } else { + | movz TMP2, r0, TMP0 + } + |.endif + | daddu PC, PC, TMP2 + | ins_next + break; + + /* -- Unary test and copy ops ------------------------------------------- */ + + case BC_ISTC: case BC_ISFC: case BC_IST: case BC_ISF: + | // RA = dst*8 or unused, RD = src*8, JMP with RD = target + | daddu RD, BASE, RD + | lhu TMP2, OFS_RD(PC) + | ld TMP0, 0(RD) + | daddiu PC, PC, 4 + | gettp TMP0, TMP0 + | sltiu TMP0, TMP0, LJ_TISTRUECOND + if (op == BC_IST || op == BC_ISF) { + | decode_RD4b TMP2 + | lui TMP3, (-(BCBIAS_J*4 >> 16) & 65535) + | addu TMP2, TMP2, TMP3 + |.if MIPSR6 + if (op == BC_IST) { + | selnez TMP2, TMP2, TMP0; + } else { + | seleqz TMP2, TMP2, TMP0; + } + |.else + if (op == BC_IST) { + | movz TMP2, r0, TMP0 + } else { + | movn TMP2, r0, TMP0 + } + |.endif + | daddu PC, PC, TMP2 + } else { + | ld CRET1, 0(RD) + if (op == BC_ISTC) { + | beqz TMP0, >1 + } else { + | bnez TMP0, >1 + } + |. daddu RA, BASE, RA + | decode_RD4b TMP2 + | lui TMP3, (-(BCBIAS_J*4 >> 16) & 65535) + | addu TMP2, TMP2, TMP3 + | sd CRET1, 0(RA) + | daddu PC, PC, TMP2 + |1: + } + | ins_next + break; + + case BC_ISTYPE: + | // RA = src*8, RD = -type*8 + | daddu TMP2, BASE, RA + | srl TMP1, RD, 3 + | ld TMP0, 0(TMP2) + | ins_next1 + | gettp TMP0, TMP0 + | daddu AT, TMP0, TMP1 + | bnez AT, ->vmeta_istype + |. ins_next2 + break; + case BC_ISNUM: + | // RA = src*8, RD = -(TISNUM-1)*8 + | daddu TMP2, BASE, RA + | ld TMP0, 0(TMP2) + | ins_next1 + | checknum TMP0, ->vmeta_istype + |. ins_next2 + break; + + /* -- Unary ops --------------------------------------------------------- */ + + case BC_MOV: + | // RA = dst*8, RD = src*8 + | daddu RD, BASE, RD + | daddu RA, BASE, RA + | ld CRET1, 0(RD) + | ins_next1 + | sd CRET1, 0(RA) + | ins_next2 + break; + case BC_NOT: + | // RA = dst*8, RD = src*8 + | daddu RD, BASE, RD + | daddu RA, BASE, RA + | ld TMP0, 0(RD) + | li AT, LJ_TTRUE + | gettp TMP0, TMP0 + | sltu TMP0, AT, TMP0 + | addiu TMP0, TMP0, 1 + | dsll TMP0, TMP0, 47 + | not TMP0, TMP0 + | ins_next1 + | sd TMP0, 0(RA) + | ins_next2 + break; + case BC_UNM: + | // RA = dst*8, RD = src*8 + | daddu RB, BASE, RD + | ld CARG1, 0(RB) + | daddu RA, BASE, RA + | gettp CARG3, CARG1 + | bne CARG3, TISNUM, >2 + |. lui TMP1, 0x8000 + | sextw CARG1, CARG1 + | beq CARG1, TMP1, ->vmeta_unm // Meta handler deals with -2^31. + |. negu CARG1, CARG1 + | zextw CARG1, CARG1 + | settp CARG1, TISNUM + |1: + | ins_next1 + | sd CARG1, 0(RA) + | ins_next2 + |2: + | sltiu AT, CARG3, LJ_TISNUM + | beqz AT, ->vmeta_unm + |. dsll TMP1, TMP1, 32 + | b <1 + |. xor CARG1, CARG1, TMP1 + break; + case BC_LEN: + | // RA = dst*8, RD = src*8 + | daddu CARG2, BASE, RD + | daddu RA, BASE, RA + | ld TMP0, 0(CARG2) + | gettp TMP1, TMP0 + | daddiu AT, TMP1, -LJ_TSTR + | bnez AT, >2 + |. cleartp STR:CARG1, TMP0 + | lw CRET1, STR:CARG1->len + |1: + | settp CRET1, TISNUM + | ins_next1 + | sd CRET1, 0(RA) + | ins_next2 + |2: + | daddiu AT, TMP1, -LJ_TTAB + | bnez AT, ->vmeta_len + |. nop +#if LJ_52 + | ld TAB:TMP2, TAB:CARG1->metatable + | bnez TAB:TMP2, >9 + |. nop + |3: +#endif + |->BC_LEN_Z: + | load_got lj_tab_len + | call_intern lj_tab_len // (GCtab *t) + |. nop + | // Returns uint32_t (but less than 2^31). + | b <1 + |. nop +#if LJ_52 + |9: + | lbu TMP0, TAB:TMP2->nomm + | andi TMP0, TMP0, 1<vmeta_len + |. nop +#endif + break; + + /* -- Binary ops -------------------------------------------------------- */ + + |.macro fpmod, a, b, c + | bal ->vm_floor // floor(b/c) + |. div.d FARG1, b, c + | mul.d a, FRET1, c + | sub.d a, b, a // b - floor(b/c)*c + |.endmacro + + |.macro sfpmod + | daddiu sp, sp, -16 + | + | load_got __divdf3 + | sd CARG1, 0(sp) + | call_extern + |. sd CARG2, 8(sp) + | + | load_got floor + | call_extern + |. move CARG1, CRET1 + | + | load_got __muldf3 + | move CARG1, CRET1 + | call_extern + |. ld CARG2, 8(sp) + | + | load_got __subdf3 + | ld CARG1, 0(sp) + | call_extern + |. move CARG2, CRET1 + | + | daddiu sp, sp, 16 + |.endmacro + + |.macro ins_arithpre, label + ||vk = ((int)op - BC_ADDVN) / (BC_ADDNV-BC_ADDVN); + | // RA = dst*8, RB = src1*8, RC = src2*8 | num_const*8 + ||switch (vk) { + ||case 0: + | decode_RB8a RB, INS + | decode_RB8b RB + | decode_RDtoRC8 RC, RD + | // RA = dst*8, RB = src1*8, RC = num_const*8 + | daddu RB, BASE, RB + |.if "label" ~= "none" + | b label + |.endif + |. daddu RC, KBASE, RC + || break; + ||case 1: + | decode_RB8a RC, INS + | decode_RB8b RC + | decode_RDtoRC8 RB, RD + | // RA = dst*8, RB = num_const*8, RC = src1*8 + | daddu RC, BASE, RC + |.if "label" ~= "none" + | b label + |.endif + |. daddu RB, KBASE, RB + || break; + ||default: + | decode_RB8a RB, INS + | decode_RB8b RB + | decode_RDtoRC8 RC, RD + | // RA = dst*8, RB = src1*8, RC = src2*8 + | daddu RB, BASE, RB + |.if "label" ~= "none" + | b label + |.endif + |. daddu RC, BASE, RC + || break; + ||} + |.endmacro + | + |.macro ins_arith, intins, fpins, fpcall, label + | ins_arithpre none + | + |.if "label" ~= "none" + |label: + |.endif + | + |// Used in 5. + | ld CARG1, 0(RB) + | ld CARG2, 0(RC) + | gettp TMP0, CARG1 + | gettp TMP1, CARG2 + | + |.if "intins" ~= "div" + | + | // Check for two integers. + | sextw CARG3, CARG1 + | bne TMP0, TISNUM, >5 + |. sextw CARG4, CARG2 + | bne TMP1, TISNUM, >5 + | + |.if "intins" == "addu" + |. intins CRET1, CARG3, CARG4 + | xor TMP1, CRET1, CARG3 // ((y^a) & (y^b)) < 0: overflow. + | xor TMP2, CRET1, CARG4 + | and TMP1, TMP1, TMP2 + | bltz TMP1, ->vmeta_arith + |. daddu RA, BASE, RA + |.elif "intins" == "subu" + |. intins CRET1, CARG3, CARG4 + | xor TMP1, CRET1, CARG3 // ((y^a) & (a^b)) < 0: overflow. + | xor TMP2, CARG3, CARG4 + | and TMP1, TMP1, TMP2 + | bltz TMP1, ->vmeta_arith + |. daddu RA, BASE, RA + |.elif "intins" == "mult" + |.if MIPSR6 + |. nop + | mul CRET1, CARG3, CARG4 + | muh TMP2, CARG3, CARG4 + |.else + |. intins CARG3, CARG4 + | mflo CRET1 + | mfhi TMP2 + |.endif + | sra TMP1, CRET1, 31 + | bne TMP1, TMP2, ->vmeta_arith + |. daddu RA, BASE, RA + |.else + |. load_got lj_vm_modi + | beqz CARG4, ->vmeta_arith + |. daddu RA, BASE, RA + | move CARG1, CARG3 + | call_extern + |. move CARG2, CARG4 + |.endif + | + | zextw CRET1, CRET1 + | settp CRET1, TISNUM + | ins_next1 + | sd CRET1, 0(RA) + |3: + | ins_next2 + | + |.endif + | + |5: // Check for two numbers. + | .FPU ldc1 FTMP0, 0(RB) + | sltu AT, TMP0, TISNUM + | sltu TMP0, TMP1, TISNUM + | .FPU ldc1 FTMP2, 0(RC) + | and AT, AT, TMP0 + | beqz AT, ->vmeta_arith + |. daddu RA, BASE, RA + | + |.if FPU + | fpins FRET1, FTMP0, FTMP2 + |.elif "fpcall" == "sfpmod" + | sfpmod + |.else + | load_got fpcall + | call_extern + |. nop + |.endif + | + | ins_next1 + |.if "intins" ~= "div" + | b <3 + |.endif + |.if FPU + |. sdc1 FRET1, 0(RA) + |.else + |. sd CRET1, 0(RA) + |.endif + |.if "intins" == "div" + | ins_next2 + |.endif + | + |.endmacro + + case BC_ADDVN: case BC_ADDNV: case BC_ADDVV: + | ins_arith addu, add.d, __adddf3, none + break; + case BC_SUBVN: case BC_SUBNV: case BC_SUBVV: + | ins_arith subu, sub.d, __subdf3, none + break; + case BC_MULVN: case BC_MULNV: case BC_MULVV: + | ins_arith mult, mul.d, __muldf3, none + break; + case BC_DIVVN: + | ins_arith div, div.d, __divdf3, ->BC_DIVVN_Z + break; + case BC_DIVNV: case BC_DIVVV: + | ins_arithpre ->BC_DIVVN_Z + break; + case BC_MODVN: + | ins_arith modi, fpmod, sfpmod, ->BC_MODVN_Z + break; + case BC_MODNV: case BC_MODVV: + | ins_arithpre ->BC_MODVN_Z + break; + case BC_POW: + | ins_arithpre none + | ld CARG1, 0(RB) + | ld CARG2, 0(RC) + | gettp TMP0, CARG1 + | gettp TMP1, CARG2 + | sltiu TMP0, TMP0, LJ_TISNUM + | sltiu TMP1, TMP1, LJ_TISNUM + | and AT, TMP0, TMP1 + | load_got pow + | beqz AT, ->vmeta_arith + |. daddu RA, BASE, RA + |.if FPU + | ldc1 FARG1, 0(RB) + | ldc1 FARG2, 0(RC) + |.endif + | call_extern + |. nop + | ins_next1 + |.if FPU + | sdc1 FRET1, 0(RA) + |.else + | sd CRET1, 0(RA) + |.endif + | ins_next2 + break; + + case BC_CAT: + | // RA = dst*8, RB = src_start*8, RC = src_end*8 + | decode_RB8a RB, INS + | decode_RB8b RB + | decode_RDtoRC8 RC, RD + | dsubu CARG3, RC, RB + | sd BASE, L->base + | daddu CARG2, BASE, RC + | move MULTRES, RB + |->BC_CAT_Z: + | load_got lj_meta_cat + | srl CARG3, CARG3, 3 + | sd PC, SAVE_PC + | call_intern lj_meta_cat // (lua_State *L, TValue *top, int left) + |. move CARG1, L + | // Returns NULL (finished) or TValue * (metamethod). + | bnez CRET1, ->vmeta_binop + |. ld BASE, L->base + | daddu RB, BASE, MULTRES + | ld CRET1, 0(RB) + | daddu RA, BASE, RA + | ins_next1 + | sd CRET1, 0(RA) + | ins_next2 + break; + + /* -- Constant ops ------------------------------------------------------ */ + + case BC_KSTR: + | // RA = dst*8, RD = str_const*8 (~) + | dsubu TMP1, KBASE, RD + | ins_next1 + | li TMP2, LJ_TSTR + | ld TMP0, -8(TMP1) // KBASE-8-str_const*8 + | daddu RA, BASE, RA + | settp TMP0, TMP2 + | sd TMP0, 0(RA) + | ins_next2 + break; + case BC_KCDATA: + |.if FFI + | // RA = dst*8, RD = cdata_const*8 (~) + | dsubu TMP1, KBASE, RD + | ins_next1 + | ld TMP0, -8(TMP1) // KBASE-8-cdata_const*8 + | li TMP2, LJ_TCDATA + | daddu RA, BASE, RA + | settp TMP0, TMP2 + | sd TMP0, 0(RA) + | ins_next2 + |.endif + break; + case BC_KSHORT: + | // RA = dst*8, RD = int16_literal*8 + | sra RD, INS, 16 + | daddu RA, BASE, RA + | zextw RD, RD + | ins_next1 + | settp RD, TISNUM + | sd RD, 0(RA) + | ins_next2 + break; + case BC_KNUM: + | // RA = dst*8, RD = num_const*8 + | daddu RD, KBASE, RD + | daddu RA, BASE, RA + | ld CRET1, 0(RD) + | ins_next1 + | sd CRET1, 0(RA) + | ins_next2 + break; + case BC_KPRI: + | // RA = dst*8, RD = primitive_type*8 (~) + | daddu RA, BASE, RA + | dsll TMP0, RD, 44 + | not TMP0, TMP0 + | ins_next1 + | sd TMP0, 0(RA) + | ins_next2 + break; + case BC_KNIL: + | // RA = base*8, RD = end*8 + | daddu RA, BASE, RA + | sd TISNIL, 0(RA) + | daddiu RA, RA, 8 + | daddu RD, BASE, RD + |1: + | sd TISNIL, 0(RA) + | slt AT, RA, RD + | bnez AT, <1 + |. daddiu RA, RA, 8 + | ins_next_ + break; + + /* -- Upvalue and function ops ------------------------------------------ */ + + case BC_UGET: + | // RA = dst*8, RD = uvnum*8 + | ld LFUNC:RB, FRAME_FUNC(BASE) + | daddu RA, BASE, RA + | cleartp LFUNC:RB + | daddu RD, RD, LFUNC:RB + | ld UPVAL:RB, LFUNC:RD->uvptr + | ins_next1 + | ld TMP1, UPVAL:RB->v + | ld CRET1, 0(TMP1) + | sd CRET1, 0(RA) + | ins_next2 + break; + case BC_USETV: + | // RA = uvnum*8, RD = src*8 + | ld LFUNC:RB, FRAME_FUNC(BASE) + | daddu RD, BASE, RD + | cleartp LFUNC:RB + | daddu RA, RA, LFUNC:RB + | ld UPVAL:RB, LFUNC:RA->uvptr + | ld CRET1, 0(RD) + | lbu TMP3, UPVAL:RB->marked + | ld CARG2, UPVAL:RB->v + | andi TMP3, TMP3, LJ_GC_BLACK // isblack(uv) + | lbu TMP0, UPVAL:RB->closed + | gettp TMP2, CRET1 + | sd CRET1, 0(CARG2) + | li AT, LJ_GC_BLACK|1 + | or TMP3, TMP3, TMP0 + | beq TMP3, AT, >2 // Upvalue is closed and black? + |. daddiu TMP2, TMP2, -(LJ_TNUMX+1) + |1: + | ins_next + | + |2: // Check if new value is collectable. + | sltiu AT, TMP2, LJ_TISGCV - (LJ_TNUMX+1) + | beqz AT, <1 // tvisgcv(v) + |. cleartp GCOBJ:CRET1, CRET1 + | lbu TMP3, GCOBJ:CRET1->gch.marked + | andi TMP3, TMP3, LJ_GC_WHITES // iswhite(v) + | beqz TMP3, <1 + |. load_got lj_gc_barrieruv + | // Crossed a write barrier. Move the barrier forward. + | call_intern lj_gc_barrieruv // (global_State *g, TValue *tv) + |. daddiu CARG1, DISPATCH, GG_DISP2G + | b <1 + |. nop + break; + case BC_USETS: + | // RA = uvnum*8, RD = str_const*8 (~) + | ld LFUNC:RB, FRAME_FUNC(BASE) + | dsubu TMP1, KBASE, RD + | cleartp LFUNC:RB + | daddu RA, RA, LFUNC:RB + | ld UPVAL:RB, LFUNC:RA->uvptr + | ld STR:TMP1, -8(TMP1) // KBASE-8-str_const*8 + | lbu TMP2, UPVAL:RB->marked + | ld CARG2, UPVAL:RB->v + | lbu TMP3, STR:TMP1->marked + | andi AT, TMP2, LJ_GC_BLACK // isblack(uv) + | lbu TMP2, UPVAL:RB->closed + | li TMP0, LJ_TSTR + | settp TMP1, TMP0 + | bnez AT, >2 + |. sd TMP1, 0(CARG2) + |1: + | ins_next + | + |2: // Check if string is white and ensure upvalue is closed. + | beqz TMP2, <1 + |. andi AT, TMP3, LJ_GC_WHITES // iswhite(str) + | beqz AT, <1 + |. load_got lj_gc_barrieruv + | // Crossed a write barrier. Move the barrier forward. + | call_intern lj_gc_barrieruv // (global_State *g, TValue *tv) + |. daddiu CARG1, DISPATCH, GG_DISP2G + | b <1 + |. nop + break; + case BC_USETN: + | // RA = uvnum*8, RD = num_const*8 + | ld LFUNC:RB, FRAME_FUNC(BASE) + | daddu RD, KBASE, RD + | cleartp LFUNC:RB + | daddu RA, RA, LFUNC:RB + | ld UPVAL:RB, LFUNC:RA->uvptr + | ld CRET1, 0(RD) + | ld TMP1, UPVAL:RB->v + | ins_next1 + | sd CRET1, 0(TMP1) + | ins_next2 + break; + case BC_USETP: + | // RA = uvnum*8, RD = primitive_type*8 (~) + | ld LFUNC:RB, FRAME_FUNC(BASE) + | dsll TMP0, RD, 44 + | cleartp LFUNC:RB + | daddu RA, RA, LFUNC:RB + | not TMP0, TMP0 + | ld UPVAL:RB, LFUNC:RA->uvptr + | ins_next1 + | ld TMP1, UPVAL:RB->v + | sd TMP0, 0(TMP1) + | ins_next2 + break; + + case BC_UCLO: + | // RA = level*8, RD = target + | ld TMP2, L->openupval + | branch_RD // Do this first since RD is not saved. + | load_got lj_func_closeuv + | sd BASE, L->base + | beqz TMP2, >1 + |. move CARG1, L + | call_intern lj_func_closeuv // (lua_State *L, TValue *level) + |. daddu CARG2, BASE, RA + | ld BASE, L->base + |1: + | ins_next + break; + + case BC_FNEW: + | // RA = dst*8, RD = proto_const*8 (~) (holding function prototype) + | load_got lj_func_newL_gc + | dsubu TMP1, KBASE, RD + | ld CARG3, FRAME_FUNC(BASE) + | ld CARG2, -8(TMP1) // KBASE-8-tab_const*8 + | sd BASE, L->base + | sd PC, SAVE_PC + | cleartp CARG3 + | // (lua_State *L, GCproto *pt, GCfuncL *parent) + | call_intern lj_func_newL_gc + |. move CARG1, L + | // Returns GCfuncL *. + | li TMP0, LJ_TFUNC + | ld BASE, L->base + | ins_next1 + | settp CRET1, TMP0 + | daddu RA, BASE, RA + | sd CRET1, 0(RA) + | ins_next2 + break; + + /* -- Table ops --------------------------------------------------------- */ + + case BC_TNEW: + case BC_TDUP: + | // RA = dst*8, RD = (hbits|asize)*8 | tab_const*8 (~) + | ld TMP0, DISPATCH_GL(gc.total)(DISPATCH) + | ld TMP1, DISPATCH_GL(gc.threshold)(DISPATCH) + | sd BASE, L->base + | sd PC, SAVE_PC + | sltu AT, TMP0, TMP1 + | beqz AT, >5 + |1: + if (op == BC_TNEW) { + | load_got lj_tab_new + | srl CARG2, RD, 3 + | andi CARG2, CARG2, 0x7ff + | li TMP0, 0x801 + | addiu AT, CARG2, -0x7ff + | srl CARG3, RD, 14 + |.if MIPSR6 + | seleqz TMP0, TMP0, AT + | selnez CARG2, CARG2, AT + | or CARG2, CARG2, TMP0 + |.else + | movz CARG2, TMP0, AT + |.endif + | // (lua_State *L, int32_t asize, uint32_t hbits) + | call_intern lj_tab_new + |. move CARG1, L + | // Returns Table *. + } else { + | load_got lj_tab_dup + | dsubu TMP1, KBASE, RD + | move CARG1, L + | call_intern lj_tab_dup // (lua_State *L, Table *kt) + |. ld CARG2, -8(TMP1) // KBASE-8-str_const*8 + | // Returns Table *. + } + | li TMP0, LJ_TTAB + | ld BASE, L->base + | ins_next1 + | daddu RA, BASE, RA + | settp CRET1, TMP0 + | sd CRET1, 0(RA) + | ins_next2 + |5: + | load_got lj_gc_step_fixtop + | move MULTRES, RD + | call_intern lj_gc_step_fixtop // (lua_State *L) + |. move CARG1, L + | b <1 + |. move RD, MULTRES + break; + + case BC_GGET: + | // RA = dst*8, RD = str_const*8 (~) + case BC_GSET: + | // RA = src*8, RD = str_const*8 (~) + | ld LFUNC:TMP2, FRAME_FUNC(BASE) + | dsubu TMP1, KBASE, RD + | ld STR:RC, -8(TMP1) // KBASE-8-str_const*8 + | cleartp LFUNC:TMP2 + | ld TAB:RB, LFUNC:TMP2->env + if (op == BC_GGET) { + | b ->BC_TGETS_Z + } else { + | b ->BC_TSETS_Z + } + |. daddu RA, BASE, RA + break; + + case BC_TGETV: + | // RA = dst*8, RB = table*8, RC = key*8 + | decode_RB8a RB, INS + | decode_RB8b RB + | decode_RDtoRC8 RC, RD + | daddu CARG2, BASE, RB + | daddu CARG3, BASE, RC + | ld TAB:RB, 0(CARG2) + | ld TMP2, 0(CARG3) + | daddu RA, BASE, RA + | checktab TAB:RB, ->vmeta_tgetv + | gettp TMP3, TMP2 + | bne TMP3, TISNUM, >5 // Integer key? + |. lw TMP0, TAB:RB->asize + | sextw TMP2, TMP2 + | ld TMP1, TAB:RB->array + | sltu AT, TMP2, TMP0 + | sll TMP2, TMP2, 3 + | beqz AT, ->vmeta_tgetv // Integer key and in array part? + |. daddu TMP2, TMP1, TMP2 + | ld AT, 0(TMP2) + | beq AT, TISNIL, >2 + |. ld CRET1, 0(TMP2) + |1: + | ins_next1 + | sd CRET1, 0(RA) + | ins_next2 + | + |2: // Check for __index if table value is nil. + | ld TAB:TMP2, TAB:RB->metatable + | beqz TAB:TMP2, <1 // No metatable: done. + |. nop + | lbu TMP0, TAB:TMP2->nomm + | andi TMP0, TMP0, 1<vmeta_tgetv + |. nop + | + |5: + | li AT, LJ_TSTR + | bne TMP3, AT, ->vmeta_tgetv + |. cleartp RC, TMP2 + | b ->BC_TGETS_Z // String key? + |. nop + break; + case BC_TGETS: + | // RA = dst*8, RB = table*8, RC = str_const*8 (~) + | decode_RB8a RB, INS + | decode_RB8b RB + | decode_RC8a RC, INS + | daddu CARG2, BASE, RB + | decode_RC8b RC + | ld TAB:RB, 0(CARG2) + | dsubu CARG3, KBASE, RC + | daddu RA, BASE, RA + | ld STR:RC, -8(CARG3) // KBASE-8-str_const*8 + | checktab TAB:RB, ->vmeta_tgets1 + |->BC_TGETS_Z: + | // TAB:RB = GCtab *, STR:RC = GCstr *, RA = dst*8 + | lw TMP0, TAB:RB->hmask + | lw TMP1, STR:RC->sid + | ld NODE:TMP2, TAB:RB->node + | and TMP1, TMP1, TMP0 // idx = str->sid & tab->hmask + | sll TMP0, TMP1, 5 + | sll TMP1, TMP1, 3 + | subu TMP1, TMP0, TMP1 + | li TMP3, LJ_TSTR + | daddu NODE:TMP2, NODE:TMP2, TMP1 // node = tab->node + (idx*32-idx*8) + | settp STR:RC, TMP3 // Tagged key to look for. + |1: + | ld CARG1, NODE:TMP2->key + | ld CRET1, NODE:TMP2->val + | ld NODE:TMP1, NODE:TMP2->next + | bne CARG1, RC, >4 + |. ld TAB:TMP3, TAB:RB->metatable + | beq CRET1, TISNIL, >5 // Key found, but nil value? + |. nop + |3: + | ins_next1 + | sd CRET1, 0(RA) + | ins_next2 + | + |4: // Follow hash chain. + | bnez NODE:TMP1, <1 + |. move NODE:TMP2, NODE:TMP1 + | // End of hash chain: key not found, nil result. + | + |5: // Check for __index if table value is nil. + | beqz TAB:TMP3, <3 // No metatable: done. + |. move CRET1, TISNIL + | lbu TMP0, TAB:TMP3->nomm + | andi TMP0, TMP0, 1<vmeta_tgets + |. nop + break; + case BC_TGETB: + | // RA = dst*8, RB = table*8, RC = index*8 + | decode_RB8a RB, INS + | decode_RB8b RB + | daddu CARG2, BASE, RB + | decode_RDtoRC8 RC, RD + | ld TAB:RB, 0(CARG2) + | daddu RA, BASE, RA + | srl TMP0, RC, 3 + | checktab TAB:RB, ->vmeta_tgetb + | lw TMP1, TAB:RB->asize + | ld TMP2, TAB:RB->array + | sltu AT, TMP0, TMP1 + | beqz AT, ->vmeta_tgetb + |. daddu RC, TMP2, RC + | ld AT, 0(RC) + | beq AT, TISNIL, >5 + |. ld CRET1, 0(RC) + |1: + | ins_next1 + | sd CRET1, 0(RA) + | ins_next2 + | + |5: // Check for __index if table value is nil. + | ld TAB:TMP2, TAB:RB->metatable + | beqz TAB:TMP2, <1 // No metatable: done. + |. nop + | lbu TMP1, TAB:TMP2->nomm + | andi TMP1, TMP1, 1<vmeta_tgetb // Caveat: preserve TMP0 and CARG2! + |. nop + break; + case BC_TGETR: + | // RA = dst*8, RB = table*8, RC = key*8 + | decode_RB8a RB, INS + | decode_RB8b RB + | decode_RDtoRC8 RC, RD + | daddu RB, BASE, RB + | daddu RC, BASE, RC + | ld TAB:CARG1, 0(RB) + | lw CARG2, LO(RC) + | daddu RA, BASE, RA + | cleartp TAB:CARG1 + | lw TMP0, TAB:CARG1->asize + | ld TMP1, TAB:CARG1->array + | sltu AT, CARG2, TMP0 + | sll TMP2, CARG2, 3 + | beqz AT, ->vmeta_tgetr // In array part? + |. daddu CRET1, TMP1, TMP2 + | ld CARG2, 0(CRET1) + |->BC_TGETR_Z: + | ins_next1 + | sd CARG2, 0(RA) + | ins_next2 + break; + + case BC_TSETV: + | // RA = src*8, RB = table*8, RC = key*8 + | decode_RB8a RB, INS + | decode_RB8b RB + | decode_RDtoRC8 RC, RD + | daddu CARG2, BASE, RB + | daddu CARG3, BASE, RC + | ld RB, 0(CARG2) + | ld TMP2, 0(CARG3) + | daddu RA, BASE, RA + | checktab RB, ->vmeta_tsetv + | checkint TMP2, >5 + |. sextw RC, TMP2 + | lw TMP0, TAB:RB->asize + | ld TMP1, TAB:RB->array + | sltu AT, RC, TMP0 + | sll TMP2, RC, 3 + | beqz AT, ->vmeta_tsetv // Integer key and in array part? + |. daddu TMP1, TMP1, TMP2 + | ld TMP0, 0(TMP1) + | lbu TMP3, TAB:RB->marked + | beq TMP0, TISNIL, >3 + |. ld CRET1, 0(RA) + |1: + | andi AT, TMP3, LJ_GC_BLACK // isblack(table) + | bnez AT, >7 + |. sd CRET1, 0(TMP1) + |2: + | ins_next + | + |3: // Check for __newindex if previous value is nil. + | ld TAB:TMP2, TAB:RB->metatable + | beqz TAB:TMP2, <1 // No metatable: done. + |. nop + | lbu TMP2, TAB:TMP2->nomm + | andi TMP2, TMP2, 1<vmeta_tsetv + |. nop + | + |5: + | gettp AT, TMP2 + | daddiu AT, AT, -LJ_TSTR + | bnez AT, ->vmeta_tsetv + |. nop + | b ->BC_TSETS_Z // String key? + |. cleartp STR:RC, TMP2 + | + |7: // Possible table write barrier for the value. Skip valiswhite check. + | barrierback TAB:RB, TMP3, TMP0, <2 + break; + case BC_TSETS: + | // RA = src*8, RB = table*8, RC = str_const*8 (~) + | decode_RB8a RB, INS + | decode_RB8b RB + | daddu CARG2, BASE, RB + | decode_RC8a RC, INS + | ld TAB:RB, 0(CARG2) + | decode_RC8b RC + | dsubu CARG3, KBASE, RC + | ld RC, -8(CARG3) // KBASE-8-str_const*8 + | daddu RA, BASE, RA + | cleartp STR:RC + | checktab TAB:RB, ->vmeta_tsets1 + |->BC_TSETS_Z: + | // TAB:RB = GCtab *, STR:RC = GCstr *, RA = BASE+src*8 + | lw TMP0, TAB:RB->hmask + | lw TMP1, STR:RC->sid + | ld NODE:TMP2, TAB:RB->node + | sb r0, TAB:RB->nomm // Clear metamethod cache. + | and TMP1, TMP1, TMP0 // idx = str->sid & tab->hmask + | sll TMP0, TMP1, 5 + | sll TMP1, TMP1, 3 + | subu TMP1, TMP0, TMP1 + | li TMP3, LJ_TSTR + | daddu NODE:TMP2, NODE:TMP2, TMP1 // node = tab->node + (idx*32-idx*8) + | settp STR:RC, TMP3 // Tagged key to look for. + |.if FPU + | ldc1 FTMP0, 0(RA) + |.else + | ld CRET1, 0(RA) + |.endif + |1: + | ld TMP0, NODE:TMP2->key + | ld CARG2, NODE:TMP2->val + | ld NODE:TMP1, NODE:TMP2->next + | bne TMP0, RC, >5 + |. lbu TMP3, TAB:RB->marked + | beq CARG2, TISNIL, >4 // Key found, but nil value? + |. ld TAB:TMP0, TAB:RB->metatable + |2: + | andi AT, TMP3, LJ_GC_BLACK // isblack(table) + | bnez AT, >7 + |.if FPU + |. sdc1 FTMP0, NODE:TMP2->val + |.else + |. sd CRET1, NODE:TMP2->val + |.endif + |3: + | ins_next + | + |4: // Check for __newindex if previous value is nil. + | beqz TAB:TMP0, <2 // No metatable: done. + |. nop + | lbu TMP0, TAB:TMP0->nomm + | andi TMP0, TMP0, 1<vmeta_tsets + |. nop + | + |5: // Follow hash chain. + | bnez NODE:TMP1, <1 + |. move NODE:TMP2, NODE:TMP1 + | // End of hash chain: key not found, add a new one + | + | // But check for __newindex first. + | ld TAB:TMP2, TAB:RB->metatable + | beqz TAB:TMP2, >6 // No metatable: continue. + |. daddiu CARG3, DISPATCH, DISPATCH_GL(tmptv) + | lbu TMP0, TAB:TMP2->nomm + | andi TMP0, TMP0, 1<vmeta_tsets // 'no __newindex' flag NOT set: check. + |6: + | load_got lj_tab_newkey + | sd RC, 0(CARG3) + | sd BASE, L->base + | move CARG2, TAB:RB + | sd PC, SAVE_PC + | call_intern lj_tab_newkey // (lua_State *L, GCtab *t, TValue *k + |. move CARG1, L + | // Returns TValue *. + | ld BASE, L->base + |.if FPU + | b <3 // No 2nd write barrier needed. + |. sdc1 FTMP0, 0(CRET1) + |.else + | ld CARG1, 0(RA) + | b <3 // No 2nd write barrier needed. + |. sd CARG1, 0(CRET1) + |.endif + | + |7: // Possible table write barrier for the value. Skip valiswhite check. + | barrierback TAB:RB, TMP3, TMP0, <3 + break; + case BC_TSETB: + | // RA = src*8, RB = table*8, RC = index*8 + | decode_RB8a RB, INS + | decode_RB8b RB + | daddu CARG2, BASE, RB + | decode_RDtoRC8 RC, RD + | ld TAB:RB, 0(CARG2) + | daddu RA, BASE, RA + | srl TMP0, RC, 3 + | checktab RB, ->vmeta_tsetb + | lw TMP1, TAB:RB->asize + | ld TMP2, TAB:RB->array + | sltu AT, TMP0, TMP1 + | beqz AT, ->vmeta_tsetb + |. daddu RC, TMP2, RC + | ld TMP1, 0(RC) + | lbu TMP3, TAB:RB->marked + | beq TMP1, TISNIL, >5 + |1: + |. ld CRET1, 0(RA) + | andi AT, TMP3, LJ_GC_BLACK // isblack(table) + | bnez AT, >7 + |. sd CRET1, 0(RC) + |2: + | ins_next + | + |5: // Check for __newindex if previous value is nil. + | ld TAB:TMP2, TAB:RB->metatable + | beqz TAB:TMP2, <1 // No metatable: done. + |. nop + | lbu TMP1, TAB:TMP2->nomm + | andi TMP1, TMP1, 1<vmeta_tsetb // Caveat: preserve TMP0 and CARG2! + |. nop + | + |7: // Possible table write barrier for the value. Skip valiswhite check. + | barrierback TAB:RB, TMP3, TMP0, <2 + break; + case BC_TSETR: + | // RA = dst*8, RB = table*8, RC = key*8 + | decode_RB8a RB, INS + | decode_RB8b RB + | decode_RDtoRC8 RC, RD + | daddu CARG1, BASE, RB + | daddu CARG3, BASE, RC + | ld TAB:CARG2, 0(CARG1) + | lw CARG3, LO(CARG3) + | cleartp TAB:CARG2 + | lbu TMP3, TAB:CARG2->marked + | lw TMP0, TAB:CARG2->asize + | ld TMP1, TAB:CARG2->array + | andi AT, TMP3, LJ_GC_BLACK // isblack(table) + | bnez AT, >7 + |. daddu RA, BASE, RA + |2: + | sltu AT, CARG3, TMP0 + | sll TMP2, CARG3, 3 + | beqz AT, ->vmeta_tsetr // In array part? + |. daddu CRET1, TMP1, TMP2 + |->BC_TSETR_Z: + | ld CARG1, 0(RA) + | ins_next1 + | sd CARG1, 0(CRET1) + | ins_next2 + | + |7: // Possible table write barrier for the value. Skip valiswhite check. + | barrierback TAB:CARG2, TMP3, CRET1, <2 + break; + + case BC_TSETM: + | // RA = base*8 (table at base-1), RD = num_const*8 (start index) + | daddu RA, BASE, RA + |1: + | daddu TMP3, KBASE, RD + | ld TAB:CARG2, -8(RA) // Guaranteed to be a table. + | addiu TMP0, MULTRES, -8 + | lw TMP3, LO(TMP3) // Integer constant is in lo-word. + | beqz TMP0, >4 // Nothing to copy? + |. srl CARG3, TMP0, 3 + | cleartp CARG2 + | addu CARG3, CARG3, TMP3 + | lw TMP2, TAB:CARG2->asize + | sll TMP1, TMP3, 3 + | lbu TMP3, TAB:CARG2->marked + | ld CARG1, TAB:CARG2->array + | sltu AT, TMP2, CARG3 + | bnez AT, >5 + |. daddu TMP2, RA, TMP0 + | daddu TMP1, TMP1, CARG1 + | andi TMP0, TMP3, LJ_GC_BLACK // isblack(table) + |3: // Copy result slots to table. + | ld CRET1, 0(RA) + | daddiu RA, RA, 8 + | sltu AT, RA, TMP2 + | sd CRET1, 0(TMP1) + | bnez AT, <3 + |. daddiu TMP1, TMP1, 8 + | bnez TMP0, >7 + |. nop + |4: + | ins_next + | + |5: // Need to resize array part. + | load_got lj_tab_reasize + | sd BASE, L->base + | sd PC, SAVE_PC + | move BASE, RD + | call_intern lj_tab_reasize // (lua_State *L, GCtab *t, int nasize) + |. move CARG1, L + | // Must not reallocate the stack. + | move RD, BASE + | b <1 + |. ld BASE, L->base // Reload BASE for lack of a saved register. + | + |7: // Possible table write barrier for any value. Skip valiswhite check. + | barrierback TAB:CARG2, TMP3, TMP0, <4 + break; + + /* -- Calls and vararg handling ----------------------------------------- */ + + case BC_CALLM: + | // RA = base*8, (RB = (nresults+1)*8,) RC = extra_nargs*8 + | decode_RDtoRC8 NARGS8:RC, RD + | b ->BC_CALL_Z + |. addu NARGS8:RC, NARGS8:RC, MULTRES + break; + case BC_CALL: + | // RA = base*8, (RB = (nresults+1)*8,) RC = (nargs+1)*8 + | decode_RDtoRC8 NARGS8:RC, RD + |->BC_CALL_Z: + | move TMP2, BASE + | daddu BASE, BASE, RA + | ld LFUNC:RB, 0(BASE) + | daddiu BASE, BASE, 16 + | addiu NARGS8:RC, NARGS8:RC, -8 + | checkfunc RB, ->vmeta_call + | ins_call + break; + + case BC_CALLMT: + | // RA = base*8, (RB = 0,) RC = extra_nargs*8 + | addu NARGS8:RD, NARGS8:RD, MULTRES // BC_CALLT gets RC from RD. + | // Fall through. Assumes BC_CALLT follows. + break; + case BC_CALLT: + | // RA = base*8, (RB = 0,) RC = (nargs+1)*8 + | daddu RA, BASE, RA + | ld RB, 0(RA) + | move NARGS8:RC, RD + | ld TMP1, FRAME_PC(BASE) + | daddiu RA, RA, 16 + | addiu NARGS8:RC, NARGS8:RC, -8 + | checktp CARG3, RB, -LJ_TFUNC, ->vmeta_callt + |->BC_CALLT_Z: + | andi TMP0, TMP1, FRAME_TYPE // Caveat: preserve TMP0 until the 'or'. + | lbu TMP3, LFUNC:CARG3->ffid + | bnez TMP0, >7 + |. xori TMP2, TMP1, FRAME_VARG + |1: + | sd RB, FRAME_FUNC(BASE) // Copy function down, but keep PC. + | sltiu AT, TMP3, 2 // (> FF_C) Calling a fast function? + | move TMP2, BASE + | move RB, CARG3 + | beqz NARGS8:RC, >3 + |. move TMP3, NARGS8:RC + |2: + | ld CRET1, 0(RA) + | daddiu RA, RA, 8 + | addiu TMP3, TMP3, -8 + | sd CRET1, 0(TMP2) + | bnez TMP3, <2 + |. daddiu TMP2, TMP2, 8 + |3: + | or TMP0, TMP0, AT + | beqz TMP0, >5 + |. nop + |4: + | ins_callt + | + |5: // Tailcall to a fast function with a Lua frame below. + | lw INS, -4(TMP1) + | decode_RA8a RA, INS + | decode_RA8b RA + | dsubu TMP1, BASE, RA + | ld TMP1, -32(TMP1) + | cleartp LFUNC:TMP1 + | ld TMP1, LFUNC:TMP1->pc + | b <4 + |. ld KBASE, PC2PROTO(k)(TMP1) // Need to prepare KBASE. + | + |7: // Tailcall from a vararg function. + | andi AT, TMP2, FRAME_TYPEP + | bnez AT, <1 // Vararg frame below? + |. dsubu TMP2, BASE, TMP2 // Relocate BASE down. + | move BASE, TMP2 + | ld TMP1, FRAME_PC(TMP2) + | b <1 + |. andi TMP0, TMP1, FRAME_TYPE + break; + + case BC_ITERC: + | // RA = base*8, (RB = (nresults+1)*8, RC = (nargs+1)*8 ((2+1)*8)) + | move TMP2, BASE // Save old BASE fir vmeta_call. + | daddu BASE, BASE, RA + | ld RB, -24(BASE) + | ld CARG1, -16(BASE) + | ld CARG2, -8(BASE) + | li NARGS8:RC, 16 // Iterators get 2 arguments. + | sd RB, 0(BASE) // Copy callable. + | sd CARG1, 16(BASE) // Copy state. + | sd CARG2, 24(BASE) // Copy control var. + | daddiu BASE, BASE, 16 + | checkfunc RB, ->vmeta_call + | ins_call + break; + + case BC_ITERN: + |.if JIT and ENDIAN_LE + | hotloop + |.endif + |->vm_IITERN: + | // RA = base*8, (RB = (nresults+1)*8, RC = (nargs+1)*8 (2+1)*8) + | daddu RA, BASE, RA + | ld TAB:RB, -16(RA) + | lw RC, -8+LO(RA) // Get index from control var. + | cleartp TAB:RB + | daddiu PC, PC, 4 + | lw TMP0, TAB:RB->asize + | ld TMP1, TAB:RB->array + | dsll CARG3, TISNUM, 47 + |1: // Traverse array part. + | sltu AT, RC, TMP0 + | beqz AT, >5 // Index points after array part? + |. sll TMP3, RC, 3 + | daddu TMP3, TMP1, TMP3 + | ld CARG1, 0(TMP3) + | lhu RD, -4+OFS_RD(PC) + | or TMP2, RC, CARG3 + | beq CARG1, TISNIL, <1 // Skip holes in array part. + |. addiu RC, RC, 1 + | sd TMP2, 0(RA) + | sd CARG1, 8(RA) + | lui TMP3, (-(BCBIAS_J*4 >> 16) & 65535) + | decode_RD4b RD + | daddu RD, RD, TMP3 + | sw RC, -8+LO(RA) // Update control var. + | daddu PC, PC, RD + |3: + | ins_next + | + |5: // Traverse hash part. + | lw TMP1, TAB:RB->hmask + | subu RC, RC, TMP0 + | ld TMP2, TAB:RB->node + |6: + | sltu AT, TMP1, RC // End of iteration? Branch to ITERL+1. + | bnez AT, <3 + |. sll TMP3, RC, 5 + | sll RB, RC, 3 + | subu TMP3, TMP3, RB + | daddu NODE:TMP3, TMP3, TMP2 + | ld CARG1, 0(NODE:TMP3) + | lhu RD, -4+OFS_RD(PC) + | beq CARG1, TISNIL, <6 // Skip holes in hash part. + |. addiu RC, RC, 1 + | ld CARG2, NODE:TMP3->key + | lui TMP3, (-(BCBIAS_J*4 >> 16) & 65535) + | sd CARG1, 8(RA) + | addu RC, RC, TMP0 + | decode_RD4b RD + | addu RD, RD, TMP3 + | sd CARG2, 0(RA) + | daddu PC, PC, RD + | b <3 + |. sw RC, -8+LO(RA) // Update control var. + break; + + case BC_ISNEXT: + | // RA = base*8, RD = target (points to ITERN) + | daddu RA, BASE, RA + | srl TMP0, RD, 1 + | ld CFUNC:CARG1, -24(RA) + | daddu TMP0, PC, TMP0 + | ld CARG2, -16(RA) + | ld CARG3, -8(RA) + | lui TMP2, (-(BCBIAS_J*4 >> 16) & 65535) + | checkfunc CFUNC:CARG1, >5 + | gettp CARG2, CARG2 + | daddiu CARG2, CARG2, -LJ_TTAB + | lbu TMP1, CFUNC:CARG1->ffid + | daddiu CARG3, CARG3, -LJ_TNIL + | or AT, CARG2, CARG3 + | daddiu TMP1, TMP1, -FF_next_N + | or AT, AT, TMP1 + | bnez AT, >5 + |. lui TMP1, (LJ_KEYINDEX >> 16) + | daddu PC, TMP0, TMP2 + | ori TMP1, TMP1, (LJ_KEYINDEX & 0xffff) + | dsll TMP1, TMP1, 32 + | sd TMP1, -8(RA) + |1: + | ins_next + |5: // Despecialize bytecode if any of the checks fail. + | li TMP3, BC_JMP + | li TMP1, BC_ITERC + | sb TMP3, -4+OFS_OP(PC) + | daddu PC, TMP0, TMP2 + |.if JIT + | lb TMP0, OFS_OP(PC) + | li AT, BC_ITERN + | bne TMP0, AT, >6 + |. lhu TMP2, OFS_RD(PC) + |.endif + | b <1 + |. sb TMP1, OFS_OP(PC) + |.if JIT + |6: // Unpatch JLOOP. + | ld TMP0, DISPATCH_J(trace)(DISPATCH) + | sll TMP2, TMP2, 3 + | daddu TMP0, TMP0, TMP2 + | ld TRACE:TMP2, 0(TMP0) + | lw TMP0, TRACE:TMP2->startins + | li AT, -256 + | and TMP0, TMP0, AT + | or TMP0, TMP0, TMP1 + | b <1 + |. sw TMP0, 0(PC) + |.endif + break; + + case BC_VARG: + | // RA = base*8, RB = (nresults+1)*8, RC = numparams*8 + | ld TMP0, FRAME_PC(BASE) + | decode_RDtoRC8 RC, RD + | decode_RB8a RB, INS + | daddu RC, BASE, RC + | decode_RB8b RB + | daddu RA, BASE, RA + | daddiu RC, RC, FRAME_VARG + | daddu TMP2, RA, RB + | daddiu TMP3, BASE, -16 // TMP3 = vtop + | dsubu RC, RC, TMP0 // RC = vbase + | // Note: RC may now be even _above_ BASE if nargs was < numparams. + | beqz RB, >5 // Copy all varargs? + |. dsubu TMP1, TMP3, RC + | daddiu TMP2, TMP2, -16 + |1: // Copy vararg slots to destination slots. + | ld CARG1, 0(RC) + | sltu AT, RC, TMP3 + | daddiu RC, RC, 8 + |.if MIPSR6 + | selnez CARG1, CARG1, AT + | seleqz AT, TISNIL, AT + | or CARG1, CARG1, AT + |.else + | movz CARG1, TISNIL, AT + |.endif + | sd CARG1, 0(RA) + | sltu AT, RA, TMP2 + | bnez AT, <1 + |. daddiu RA, RA, 8 + |3: + | ins_next + | + |5: // Copy all varargs. + | ld TMP0, L->maxstack + | blez TMP1, <3 // No vararg slots? + |. li MULTRES, 8 // MULTRES = (0+1)*8 + | daddu TMP2, RA, TMP1 + | sltu AT, TMP0, TMP2 + | bnez AT, >7 + |. daddiu MULTRES, TMP1, 8 + |6: + | ld CRET1, 0(RC) + | daddiu RC, RC, 8 + | sd CRET1, 0(RA) + | sltu AT, RC, TMP3 + | bnez AT, <6 // More vararg slots? + |. daddiu RA, RA, 8 + | b <3 + |. nop + | + |7: // Grow stack for varargs. + | load_got lj_state_growstack + | sd RA, L->top + | dsubu RA, RA, BASE + | sd BASE, L->base + | dsubu BASE, RC, BASE // Need delta, because BASE may change. + | sd PC, SAVE_PC + | srl CARG2, TMP1, 3 + | call_intern lj_state_growstack // (lua_State *L, int n) + |. move CARG1, L + | move RC, BASE + | ld BASE, L->base + | daddu RA, BASE, RA + | daddu RC, BASE, RC + | b <6 + |. daddiu TMP3, BASE, -16 + break; + + /* -- Returns ----------------------------------------------------------- */ + + case BC_RETM: + | // RA = results*8, RD = extra_nresults*8 + | addu RD, RD, MULTRES // MULTRES >= 8, so RD >= 8. + | // Fall through. Assumes BC_RET follows. + break; + + case BC_RET: + | // RA = results*8, RD = (nresults+1)*8 + | ld PC, FRAME_PC(BASE) + | daddu RA, BASE, RA + | move MULTRES, RD + |1: + | andi TMP0, PC, FRAME_TYPE + | bnez TMP0, ->BC_RETV_Z + |. xori TMP1, PC, FRAME_VARG + | + |->BC_RET_Z: + | // BASE = base, RA = resultptr, RD = (nresults+1)*8, PC = return + | lw INS, -4(PC) + | daddiu TMP2, BASE, -16 + | daddiu RC, RD, -8 + | decode_RA8a TMP0, INS + | decode_RB8a RB, INS + | decode_RA8b TMP0 + | decode_RB8b RB + | daddu TMP3, TMP2, RB + | beqz RC, >3 + |. dsubu BASE, TMP2, TMP0 + |2: + | ld CRET1, 0(RA) + | daddiu RA, RA, 8 + | daddiu RC, RC, -8 + | sd CRET1, 0(TMP2) + | bnez RC, <2 + |. daddiu TMP2, TMP2, 8 + |3: + | daddiu TMP3, TMP3, -8 + |5: + | sltu AT, TMP2, TMP3 + | bnez AT, >6 + |. ld LFUNC:TMP1, FRAME_FUNC(BASE) + | ins_next1 + | cleartp LFUNC:TMP1 + | ld TMP1, LFUNC:TMP1->pc + | ld KBASE, PC2PROTO(k)(TMP1) + | ins_next2 + | + |6: // Fill up results with nil. + | sd TISNIL, 0(TMP2) + | b <5 + |. daddiu TMP2, TMP2, 8 + | + |->BC_RETV_Z: // Non-standard return case. + | andi TMP2, TMP1, FRAME_TYPEP + | bnez TMP2, ->vm_return + |. nop + | // Return from vararg function: relocate BASE down. + | dsubu BASE, BASE, TMP1 + | b <1 + |. ld PC, FRAME_PC(BASE) + break; + + case BC_RET0: case BC_RET1: + | // RA = results*8, RD = (nresults+1)*8 + | ld PC, FRAME_PC(BASE) + | daddu RA, BASE, RA + | move MULTRES, RD + | andi TMP0, PC, FRAME_TYPE + | bnez TMP0, ->BC_RETV_Z + |. xori TMP1, PC, FRAME_VARG + | lw INS, -4(PC) + | daddiu TMP2, BASE, -16 + if (op == BC_RET1) { + | ld CRET1, 0(RA) + } + | decode_RB8a RB, INS + | decode_RA8a RA, INS + | decode_RB8b RB + | decode_RA8b RA + | dsubu BASE, TMP2, RA + if (op == BC_RET1) { + | sd CRET1, 0(TMP2) + } + |5: + | sltu AT, RD, RB + | bnez AT, >6 + |. ld TMP1, FRAME_FUNC(BASE) + | ins_next1 + | cleartp LFUNC:TMP1 + | ld TMP1, LFUNC:TMP1->pc + | ld KBASE, PC2PROTO(k)(TMP1) + | ins_next2 + | + |6: // Fill up results with nil. + | daddiu TMP2, TMP2, 8 + | daddiu RD, RD, 8 + | b <5 + if (op == BC_RET1) { + |. sd TISNIL, 0(TMP2) + } else { + |. sd TISNIL, -8(TMP2) + } + break; + + /* -- Loops and branches ------------------------------------------------ */ + + case BC_FORL: + |.if JIT + | hotloop + |.endif + | // Fall through. Assumes BC_IFORL follows. + break; + + case BC_JFORI: + case BC_JFORL: +#if !LJ_HASJIT + break; +#endif + case BC_FORI: + case BC_IFORL: + | // RA = base*8, RD = target (after end of loop or start of loop) + vk = (op == BC_IFORL || op == BC_JFORL); + | daddu RA, BASE, RA + | ld CARG1, FORL_IDX*8(RA) // IDX CARG1 - CARG3 type + | gettp CARG3, CARG1 + if (op != BC_JFORL) { + | srl RD, RD, 1 + | lui TMP2, (-(BCBIAS_J*4 >> 16) & 65535) + | daddu TMP2, RD, TMP2 + } + if (!vk) { + | ld CARG2, FORL_STOP*8(RA) // STOP CARG2 - CARG4 type + | ld CRET1, FORL_STEP*8(RA) // STEP CRET1 - CRET2 type + | gettp CARG4, CARG2 + | bne CARG3, TISNUM, >5 + |. gettp CRET2, CRET1 + | bne CARG4, TISNUM, ->vmeta_for + |. sextw CARG3, CARG1 + | bne CRET2, TISNUM, ->vmeta_for + |. sextw CARG2, CARG2 + | dext AT, CRET1, 31, 0 + | slt CRET1, CARG2, CARG3 + | slt TMP1, CARG3, CARG2 + |.if MIPSR6 + | selnez TMP1, TMP1, AT + | seleqz CRET1, CRET1, AT + | or CRET1, CRET1, TMP1 + |.else + | movn CRET1, TMP1, AT + |.endif + } else { + | bne CARG3, TISNUM, >5 + |. ld CARG2, FORL_STEP*8(RA) // STEP CARG2 - CARG4 type + | ld CRET1, FORL_STOP*8(RA) // STOP CRET1 - CRET2 type + | sextw TMP3, CARG1 + | sextw CARG2, CARG2 + | sextw CRET1, CRET1 + | addu CARG1, TMP3, CARG2 + | xor TMP0, CARG1, TMP3 + | xor TMP1, CARG1, CARG2 + | and TMP0, TMP0, TMP1 + | slt TMP1, CARG1, CRET1 + | slt CRET1, CRET1, CARG1 + | slt AT, CARG2, r0 + | slt TMP0, TMP0, r0 // ((y^a) & (y^b)) < 0: overflow. + |.if MIPSR6 + | selnez TMP1, TMP1, AT + | seleqz CRET1, CRET1, AT + | or CRET1, CRET1, TMP1 + |.else + | movn CRET1, TMP1, AT + |.endif + | or CRET1, CRET1, TMP0 + | zextw CARG1, CARG1 + | settp CARG1, TISNUM + } + |1: + if (op == BC_FORI) { + |.if MIPSR6 + | selnez TMP2, TMP2, CRET1 + |.else + | movz TMP2, r0, CRET1 + |.endif + | daddu PC, PC, TMP2 + } else if (op == BC_JFORI) { + | daddu PC, PC, TMP2 + | lhu RD, -4+OFS_RD(PC) + } else if (op == BC_IFORL) { + |.if MIPSR6 + | seleqz TMP2, TMP2, CRET1 + |.else + | movn TMP2, r0, CRET1 + |.endif + | daddu PC, PC, TMP2 + } + if (vk) { + | sd CARG1, FORL_IDX*8(RA) + } + | ins_next1 + | sd CARG1, FORL_EXT*8(RA) + |2: + if (op == BC_JFORI) { + | beqz CRET1, =>BC_JLOOP + |. decode_RD8b RD + } else if (op == BC_JFORL) { + | beqz CRET1, =>BC_JLOOP + } + | ins_next2 + | + |5: // FP loop. + |.if FPU + if (!vk) { + | ldc1 f0, FORL_IDX*8(RA) + | ldc1 f2, FORL_STOP*8(RA) + | sltiu TMP0, CARG3, LJ_TISNUM + | sltiu TMP1, CARG4, LJ_TISNUM + | sltiu AT, CRET2, LJ_TISNUM + | ld TMP3, FORL_STEP*8(RA) + | and TMP0, TMP0, TMP1 + | and AT, AT, TMP0 + | beqz AT, ->vmeta_for + |. slt TMP3, TMP3, r0 + |.if MIPSR6 + | dmtc1 TMP3, FTMP2 + | cmp.lt.d FTMP0, f0, f2 + | cmp.lt.d FTMP1, f2, f0 + | sel.d FTMP2, FTMP1, FTMP0 + | b <1 + |. dmfc1 CRET1, FTMP2 + |.else + | c.ole.d 0, f0, f2 + | c.ole.d 1, f2, f0 + | li CRET1, 1 + | movt CRET1, r0, 0 + | movt AT, r0, 1 + | b <1 + |. movn CRET1, AT, TMP3 + |.endif + } else { + | ldc1 f0, FORL_IDX*8(RA) + | ldc1 f4, FORL_STEP*8(RA) + | ldc1 f2, FORL_STOP*8(RA) + | ld TMP3, FORL_STEP*8(RA) + | add.d f0, f0, f4 + |.if MIPSR6 + | slt TMP3, TMP3, r0 + | dmtc1 TMP3, FTMP2 + | cmp.lt.d FTMP0, f0, f2 + | cmp.lt.d FTMP1, f2, f0 + | sel.d FTMP2, FTMP1, FTMP0 + | dmfc1 CRET1, FTMP2 + if (op == BC_IFORL) { + | seleqz TMP2, TMP2, CRET1 + | daddu PC, PC, TMP2 + } + |.else + | c.ole.d 0, f0, f2 + | c.ole.d 1, f2, f0 + | slt TMP3, TMP3, r0 + | li CRET1, 1 + | li AT, 1 + | movt CRET1, r0, 0 + | movt AT, r0, 1 + | movn CRET1, AT, TMP3 + if (op == BC_IFORL) { + | movn TMP2, r0, CRET1 + | daddu PC, PC, TMP2 + } + |.endif + | sdc1 f0, FORL_IDX*8(RA) + | ins_next1 + | b <2 + |. sdc1 f0, FORL_EXT*8(RA) + } + |.else + if (!vk) { + | sltiu TMP0, CARG3, LJ_TISNUM + | sltiu TMP1, CARG4, LJ_TISNUM + | sltiu AT, CRET2, LJ_TISNUM + | and TMP0, TMP0, TMP1 + | and AT, AT, TMP0 + | beqz AT, ->vmeta_for + |. nop + | bal ->vm_sfcmpolex + |. lw TMP3, FORL_STEP*8+HI(RA) + | b <1 + |. nop + } else { + | load_got __adddf3 + | call_extern + |. sw TMP2, TMPD + | ld CARG2, FORL_STOP*8(RA) + | move CARG1, CRET1 + if ( op == BC_JFORL ) { + | lhu RD, -4+OFS_RD(PC) + | decode_RD8b RD + } + | bal ->vm_sfcmpolex + |. lw TMP3, FORL_STEP*8+HI(RA) + | b <1 + |. lw TMP2, TMPD + } + |.endif + break; + + case BC_ITERL: + |.if JIT + | hotloop + |.endif + | // Fall through. Assumes BC_IITERL follows. + break; + + case BC_JITERL: +#if !LJ_HASJIT + break; +#endif + case BC_IITERL: + | // RA = base*8, RD = target + | daddu RA, BASE, RA + | ld TMP1, 0(RA) + | beq TMP1, TISNIL, >1 // Stop if iterator returned nil. + |. nop + if (op == BC_JITERL) { + | b =>BC_JLOOP + |. sd TMP1, -8(RA) + } else { + | branch_RD // Otherwise save control var + branch. + | sd TMP1, -8(RA) + } + |1: + | ins_next + break; + + case BC_LOOP: + | // RA = base*8, RD = target (loop extent) + | // Note: RA/RD is only used by trace recorder to determine scope/extent + | // This opcode does NOT jump, it's only purpose is to detect a hot loop. + |.if JIT + | hotloop + |.endif + | // Fall through. Assumes BC_ILOOP follows. + break; + + case BC_ILOOP: + | // RA = base*8, RD = target (loop extent) + | ins_next + break; + + case BC_JLOOP: + |.if JIT + | // RA = base*8 (ignored), RD = traceno*8 + | ld TMP1, DISPATCH_J(trace)(DISPATCH) + | li AT, 0 + | daddu TMP1, TMP1, RD + | // Traces on MIPS don't store the trace number, so use 0. + | sd AT, DISPATCH_GL(vmstate)(DISPATCH) + | ld TRACE:TMP2, 0(TMP1) + | sd BASE, DISPATCH_GL(jit_base)(DISPATCH) + | ld TMP2, TRACE:TMP2->mcode + | sd L, DISPATCH_GL(tmpbuf.L)(DISPATCH) + | jr TMP2 + |. daddiu JGL, DISPATCH, GG_DISP2G+32768 + |.endif + break; + + case BC_JMP: + | // RA = base*8 (only used by trace recorder), RD = target + | branch_RD + | ins_next + break; + + /* -- Function headers -------------------------------------------------- */ + + case BC_FUNCF: + |.if JIT + | hotcall + |.endif + case BC_FUNCV: /* NYI: compiled vararg functions. */ + | // Fall through. Assumes BC_IFUNCF/BC_IFUNCV follow. + break; + + case BC_JFUNCF: +#if !LJ_HASJIT + break; +#endif + case BC_IFUNCF: + | // BASE = new base, RA = BASE+framesize*8, RB = LFUNC, RC = nargs*8 + | ld TMP2, L->maxstack + | lbu TMP1, -4+PC2PROTO(numparams)(PC) + | ld KBASE, -4+PC2PROTO(k)(PC) + | sltu AT, TMP2, RA + | bnez AT, ->vm_growstack_l + |. sll TMP1, TMP1, 3 + if (op != BC_JFUNCF) { + | ins_next1 + } + |2: + | sltu AT, NARGS8:RC, TMP1 // Check for missing parameters. + | bnez AT, >3 + |. daddu AT, BASE, NARGS8:RC + if (op == BC_JFUNCF) { + | decode_RD8a RD, INS + | b =>BC_JLOOP + |. decode_RD8b RD + } else { + | ins_next2 + } + | + |3: // Clear missing parameters. + | sd TISNIL, 0(AT) + | b <2 + |. addiu NARGS8:RC, NARGS8:RC, 8 + break; + + case BC_JFUNCV: +#if !LJ_HASJIT + break; +#endif + | NYI // NYI: compiled vararg functions + break; /* NYI: compiled vararg functions. */ + + case BC_IFUNCV: + | // BASE = new base, RA = BASE+framesize*8, RB = LFUNC, RC = nargs*8 + | li TMP0, LJ_TFUNC + | daddu TMP1, BASE, RC + | ld TMP2, L->maxstack + | settp LFUNC:RB, TMP0 + | daddu TMP0, RA, RC + | sd LFUNC:RB, 0(TMP1) // Store (tagged) copy of LFUNC. + | daddiu TMP3, RC, 16+FRAME_VARG + | sltu AT, TMP0, TMP2 + | ld KBASE, -4+PC2PROTO(k)(PC) + | beqz AT, ->vm_growstack_l + |. sd TMP3, 8(TMP1) // Store delta + FRAME_VARG. + | lbu TMP2, -4+PC2PROTO(numparams)(PC) + | move RA, BASE + | move RC, TMP1 + | ins_next1 + | beqz TMP2, >3 + |. daddiu BASE, TMP1, 16 + |1: + | ld TMP0, 0(RA) + | sltu AT, RA, RC // Less args than parameters? + | move CARG1, TMP0 + |.if MIPSR6 + | selnez TMP0, TMP0, AT + | seleqz TMP3, TISNIL, AT + | or TMP0, TMP0, TMP3 + | seleqz TMP3, CARG1, AT + | selnez CARG1, TISNIL, AT + | or CARG1, CARG1, TMP3 + |.else + | movz TMP0, TISNIL, AT // Clear missing parameters. + | movn CARG1, TISNIL, AT // Clear old fixarg slot (help the GC). + |.endif + | addiu TMP2, TMP2, -1 + | sd TMP0, 16(TMP1) + | daddiu TMP1, TMP1, 8 + | sd CARG1, 0(RA) + | bnez TMP2, <1 + |. daddiu RA, RA, 8 + |3: + | ins_next2 + break; + + case BC_FUNCC: + case BC_FUNCCW: + | // BASE = new base, RA = BASE+framesize*8, RB = CFUNC, RC = nargs*8 + if (op == BC_FUNCC) { + | ld CFUNCADDR, CFUNC:RB->f + } else { + | ld CFUNCADDR, DISPATCH_GL(wrapf)(DISPATCH) + } + | daddu TMP1, RA, NARGS8:RC + | ld TMP2, L->maxstack + | daddu RC, BASE, NARGS8:RC + | sd BASE, L->base + | sltu AT, TMP2, TMP1 + | sd RC, L->top + | li_vmstate C + if (op == BC_FUNCCW) { + | ld CARG2, CFUNC:RB->f + } + | bnez AT, ->vm_growstack_c // Need to grow stack. + |. move CARG1, L + | jalr CFUNCADDR // (lua_State *L [, lua_CFunction f]) + |. st_vmstate + | // Returns nresults. + | ld BASE, L->base + | sll RD, CRET1, 3 + | ld TMP1, L->top + | li_vmstate INTERP + | ld PC, FRAME_PC(BASE) // Fetch PC of caller. + | dsubu RA, TMP1, RD // RA = L->top - nresults*8 + | sd L, DISPATCH_GL(cur_L)(DISPATCH) + | b ->vm_returnc + |. st_vmstate + break; + + /* ---------------------------------------------------------------------- */ + + default: + fprintf(stderr, "Error: undefined opcode BC_%s\n", bc_names[op]); + exit(2); + break; + } +} + +static int build_backend(BuildCtx *ctx) +{ + int op; + + dasm_growpc(Dst, BC__MAX); + + build_subroutines(ctx); + + |.code_op + for (op = 0; op < BC__MAX; op++) + build_ins(ctx, (BCOp)op, op); + + return BC__MAX; +} + +/* Emit pseudo frame-info for all assembler functions. */ +static void emit_asm_debug(BuildCtx *ctx) +{ + int fcofs = (int)((uint8_t *)ctx->glob[GLOB_vm_ffi_call] - ctx->code); + int i; + switch (ctx->mode) { + case BUILD_elfasm: + fprintf(ctx->fp, "\t.section .debug_frame,\"\",@progbits\n"); + fprintf(ctx->fp, + ".Lframe0:\n" + "\t.4byte .LECIE0-.LSCIE0\n" + ".LSCIE0:\n" + "\t.4byte 0xffffffff\n" + "\t.byte 0x1\n" + "\t.string \"\"\n" + "\t.uleb128 0x1\n" + "\t.sleb128 -4\n" + "\t.byte 31\n" + "\t.byte 0xc\n\t.uleb128 29\n\t.uleb128 0\n" + "\t.align 2\n" + ".LECIE0:\n\n"); + fprintf(ctx->fp, + ".LSFDE0:\n" + "\t.4byte .LEFDE0-.LASFDE0\n" + ".LASFDE0:\n" + "\t.4byte .Lframe0\n" + "\t.8byte .Lbegin\n" + "\t.8byte %d\n" + "\t.byte 0xe\n\t.uleb128 %d\n" + "\t.byte 0x9f\n\t.sleb128 2*5\n" + "\t.byte 0x9e\n\t.sleb128 2*6\n", + fcofs, CFRAME_SIZE); + for (i = 23; i >= 16; i--) + fprintf(ctx->fp, "\t.byte %d\n\t.uleb128 %d\n", 0x80+i, 2*(30-i)); +#if !LJ_SOFTFP + for (i = 31; i >= 24; i--) + fprintf(ctx->fp, "\t.byte %d\n\t.uleb128 %d\n", 0x80+32+i, 2*(46-i)); +#endif + fprintf(ctx->fp, + "\t.align 2\n" + ".LEFDE0:\n\n"); +#if LJ_HASFFI + fprintf(ctx->fp, + ".LSFDE1:\n" + "\t.4byte .LEFDE1-.LASFDE1\n" + ".LASFDE1:\n" + "\t.4byte .Lframe0\n" + "\t.4byte lj_vm_ffi_call\n" + "\t.4byte %d\n" + "\t.byte 0x9f\n\t.uleb128 2*1\n" + "\t.byte 0x90\n\t.uleb128 2*2\n" + "\t.byte 0xd\n\t.uleb128 0x10\n" + "\t.align 2\n" + ".LEFDE1:\n\n", (int)ctx->codesz - fcofs); +#endif +#if !LJ_NO_UNWIND + /* NYI */ +#endif + break; + default: + break; + } +} + diff --git a/fluent-bit/lib/luajit-3065c9/src/vm_ppc.dasc b/fluent-bit/lib/luajit-3065c9/src/vm_ppc.dasc new file mode 100644 index 00000000..3cad37d2 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/vm_ppc.dasc @@ -0,0 +1,6041 @@ +|// Low-level VM code for PowerPC 32 bit or 32on64 bit mode. +|// Bytecode interpreter, fast functions and helper functions. +|// Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +| +|.arch ppc +|.section code_op, code_sub +| +|.actionlist build_actionlist +|.globals GLOB_ +|.globalnames globnames +|.externnames extnames +| +|// Note: The ragged indentation of the instructions is intentional. +|// The starting columns indicate data dependencies. +| +|//----------------------------------------------------------------------- +| +|// DynASM defines used by the PPC port: +|// +|// P64 64 bit pointers (only for GPR64 testing). +|// GPR64 64 bit registers (but possibly 32 bit pointers, e.g. PS3). +|// Affects reg saves, stack layout, carry/overflow/dot flags etc. +|// FRAME32 Use 32 bit frame layout, even with GPR64 (Xbox 360). +|// TOC Need table of contents (64 bit or 32 bit variant, e.g. PS3). +|// Function pointers are really a struct: code, TOC, env (optional). +|// TOCENV Function pointers have an environment pointer, too (not on PS3). +|// PPE Power Processor Element of Cell (PS3) or Xenon (Xbox 360). +|// Must avoid (slow) micro-coded instructions. +| +|.if P64 +|.define TOC, 1 +|.define TOCENV, 1 +|.macro lpx, a, b, c; ldx a, b, c; .endmacro +|.macro lp, a, b; ld a, b; .endmacro +|.macro stp, a, b; std a, b; .endmacro +|.define decode_OPP, decode_OP8 +|.if FFI +|// Missing: Calling conventions, 64 bit regs, TOC. +|.error lib_ffi not yet implemented for PPC64 +|.endif +|.else +|.macro lpx, a, b, c; lwzx a, b, c; .endmacro +|.macro lp, a, b; lwz a, b; .endmacro +|.macro stp, a, b; stw a, b; .endmacro +|.define decode_OPP, decode_OP4 +|.endif +| +|// Convenience macros for TOC handling. +|.if TOC +|// Linker needs a TOC patch area for every external call relocation. +|.macro blex, target; bl extern target@plt; nop; .endmacro +|.macro .toc, a, b; a, b; .endmacro +|.if P64 +|.define TOC_OFS, 8 +|.define ENV_OFS, 16 +|.else +|.define TOC_OFS, 4 +|.define ENV_OFS, 8 +|.endif +|.else // No TOC. +|.macro blex, target; bl extern target@plt; .endmacro +|.macro .toc, a, b; .endmacro +|.endif +|.macro .tocenv, a, b; .if TOCENV; a, b; .endif; .endmacro +| +|.macro .gpr64, a, b; .if GPR64; a, b; .endif; .endmacro +| +|.macro andix., y, a, i +|.if PPE +| rlwinm y, a, 0, 31-lj_fls(i), 31-lj_ffs(i) +| cmpwi y, 0 +|.else +| andi. y, a, i +|.endif +|.endmacro +| +|.macro clrso, reg +|.if PPE +| li reg, 0 +| mtxer reg +|.else +| mcrxr cr0 +|.endif +|.endmacro +| +|.macro checkov, reg, noov +|.if PPE +| mfxer reg +| add reg, reg, reg +| cmpwi reg, 0 +| li reg, 0 +| mtxer reg +| bgey noov +|.else +| mcrxr cr0 +| bley noov +|.endif +|.endmacro +| +|//----------------------------------------------------------------------- +| +|// Fixed register assignments for the interpreter. +|// Don't use: r1 = sp, r2 and r13 = reserved (TOC, TLS or SDATA) +| +|.macro .FPU, a, b +|.if FPU +| a, b +|.endif +|.endmacro +| +|.macro .FPU, a, b, c +|.if FPU +| a, b, c +|.endif +|.endmacro +| +|// The following must be C callee-save (but BASE is often refetched). +|.define BASE, r14 // Base of current Lua stack frame. +|.define KBASE, r15 // Constants of current Lua function. +|.define PC, r16 // Next PC. +|.define DISPATCH, r17 // Opcode dispatch table. +|.define LREG, r18 // Register holding lua_State (also in SAVE_L). +|.define MULTRES, r19 // Size of multi-result: (nresults+1)*8. +|.define JGL, r31 // On-trace: global_State + 32768. +| +|// Constants for type-comparisons, stores and conversions. C callee-save. +|.define TISNUM, r22 +|.define TISNIL, r23 +|.define ZERO, r24 +|.if FPU +|.define TOBIT, f30 // 2^52 + 2^51. +|.define TONUM, f31 // 2^52 + 2^51 + 2^31. +|.endif +| +|// The following temporaries are not saved across C calls, except for RA. +|.define RA, r20 // Callee-save. +|.define RB, r10 +|.define RC, r11 +|.define RD, r12 +|.define INS, r7 // Overlaps CARG5. +| +|.define TMP0, r0 +|.define TMP1, r8 +|.define TMP2, r9 +|.define TMP3, r6 // Overlaps CARG4. +| +|// Saved temporaries. +|.define SAVE0, r21 +|.define SAVE1, r25 +| +|// Calling conventions. +|.define CARG1, r3 +|.define CARG2, r4 +|.define CARG3, r5 +|.define CARG4, r6 // Overlaps TMP3. +|.define CARG5, r7 // Overlaps INS. +| +|.if FPU +|.define FARG1, f1 +|.define FARG2, f2 +|.endif +| +|.define CRET1, r3 +|.define CRET2, r4 +| +|.define TOCREG, r2 // TOC register (only used by C code). +|.define ENVREG, r11 // Environment pointer (nested C functions). +| +|// Stack layout while in interpreter. Must match with lj_frame.h. +|.if GPR64 +|.if FRAME32 +| +|// 456(sp) // \ 32/64 bit C frame info +|.define TONUM_LO, 452(sp) // | +|.define TONUM_HI, 448(sp) // | +|.define TMPD_LO, 444(sp) // | +|.define TMPD_HI, 440(sp) // | +|.define SAVE_CR, 432(sp) // | 64 bit CR save. +|.define SAVE_ERRF, 424(sp) // > Parameter save area. +|.define SAVE_NRES, 420(sp) // | +|.define SAVE_L, 416(sp) // | +|.define SAVE_PC, 412(sp) // | +|.define SAVE_MULTRES, 408(sp) // | +|.define SAVE_CFRAME, 400(sp) // / 64 bit C frame chain. +|// 392(sp) // Reserved. +|.define CFRAME_SPACE, 384 // Delta for sp. +|// Back chain for sp: 384(sp) <-- sp entering interpreter +|.define SAVE_LR, 376(sp) // 32 bit LR stored in hi-part. +|.define SAVE_GPR_, 232 // .. 232+18*8: 64 bit GPR saves. +|.define SAVE_FPR_, 88 // .. 88+18*8: 64 bit FPR saves. +|// 80(sp) // Needed for 16 byte stack frame alignment. +|// 16(sp) // Callee parameter save area (ABI mandated). +|// 8(sp) // Reserved +|// Back chain for sp: 0(sp) <-- sp while in interpreter +|// 32 bit sp stored in hi-part of 0(sp). +| +|.define TMPD_BLO, 447(sp) +|.define TMPD, TMPD_HI +|.define TONUM_D, TONUM_HI +| +|.else +| +|// 508(sp) // \ 32 bit C frame info. +|.define SAVE_ERRF, 472(sp) // | +|.define SAVE_NRES, 468(sp) // | +|.define SAVE_L, 464(sp) // > Parameter save area. +|.define SAVE_PC, 460(sp) // | +|.define SAVE_MULTRES, 456(sp) // | +|.define SAVE_CFRAME, 448(sp) // / 64 bit C frame chain. +|.define SAVE_LR, 416(sp) +|.define CFRAME_SPACE, 400 // Delta for sp. +|// Back chain for sp: 400(sp) <-- sp entering interpreter +|.define SAVE_FPR_, 256 // .. 256+18*8: 64 bit FPR saves. +|.define SAVE_GPR_, 112 // .. 112+18*8: 64 bit GPR saves. +|// 48(sp) // Callee parameter save area (ABI mandated). +|.define SAVE_TOC, 40(sp) // TOC save area. +|.define TMPD_LO, 36(sp) // \ Link editor temp (ABI mandated). +|.define TMPD_HI, 32(sp) // / +|.define TONUM_LO, 28(sp) // \ Compiler temp (ABI mandated). +|.define TONUM_HI, 24(sp) // / +|// Next frame lr: 16(sp) +|.define SAVE_CR, 8(sp) // 64 bit CR save. +|// Back chain for sp: 0(sp) <-- sp while in interpreter +| +|.define TMPD_BLO, 39(sp) +|.define TMPD, TMPD_HI +|.define TONUM_D, TONUM_HI +| +|.endif +|.else +| +|.if FPU +|.define SAVE_LR, 276(sp) +|.define CFRAME_SPACE, 272 // Delta for sp. +|// Back chain for sp: 272(sp) <-- sp entering interpreter +|.define SAVE_FPR_, 128 // .. 128+18*8: 64 bit FPR saves. +|.else +|.define SAVE_LR, 132(sp) +|.define CFRAME_SPACE, 128 // Delta for sp. +|// Back chain for sp: 128(sp) <-- sp entering interpreter +|.endif +|.define SAVE_GPR_, 56 // .. 56+18*4: 32 bit GPR saves. +|.define SAVE_CR, 52(sp) // 32 bit CR save. +|.define SAVE_ERRF, 48(sp) // 32 bit C frame info. +|.define SAVE_NRES, 44(sp) +|.define SAVE_CFRAME, 40(sp) +|.define SAVE_L, 36(sp) +|.define SAVE_PC, 32(sp) +|.define SAVE_MULTRES, 28(sp) +|.define UNUSED1, 24(sp) +|.if FPU +|.define TMPD_LO, 20(sp) +|.define TMPD_HI, 16(sp) +|.define TONUM_LO, 12(sp) +|.define TONUM_HI, 8(sp) +|.else +|.define SFSAVE_4, 20(sp) +|.define SFSAVE_3, 16(sp) +|.define SFSAVE_2, 12(sp) +|.define SFSAVE_1, 8(sp) +|.endif +|// Next frame lr: 4(sp) +|// Back chain for sp: 0(sp) <-- sp while in interpreter +| +|.if FPU +|.define TMPD_BLO, 23(sp) +|.define TMPD, TMPD_HI +|.define TONUM_D, TONUM_HI +|.endif +| +|.endif +| +|.macro save_, reg +|.if GPR64 +| std r..reg, SAVE_GPR_+(reg-14)*8(sp) +|.else +| stw r..reg, SAVE_GPR_+(reg-14)*4(sp) +|.endif +| .FPU stfd f..reg, SAVE_FPR_+(reg-14)*8(sp) +|.endmacro +|.macro rest_, reg +|.if GPR64 +| ld r..reg, SAVE_GPR_+(reg-14)*8(sp) +|.else +| lwz r..reg, SAVE_GPR_+(reg-14)*4(sp) +|.endif +| .FPU lfd f..reg, SAVE_FPR_+(reg-14)*8(sp) +|.endmacro +| +|.macro saveregs +|.if GPR64 and not FRAME32 +| stdu sp, -CFRAME_SPACE(sp) +|.else +| stwu sp, -CFRAME_SPACE(sp) +|.endif +| save_ 14; save_ 15; save_ 16 +| mflr r0 +| save_ 17; save_ 18; save_ 19; save_ 20; save_ 21; save_ 22 +|.if GPR64 and not FRAME32 +| std r0, SAVE_LR +|.else +| stw r0, SAVE_LR +|.endif +| save_ 23; save_ 24; save_ 25 +| mfcr r0 +| save_ 26; save_ 27; save_ 28; save_ 29; save_ 30; save_ 31 +|.if GPR64 +| std r0, SAVE_CR +|.else +| stw r0, SAVE_CR +|.endif +| .toc std TOCREG, SAVE_TOC +|.endmacro +| +|.macro restoreregs +|.if GPR64 and not FRAME32 +| ld r0, SAVE_LR +|.else +| lwz r0, SAVE_LR +|.endif +|.if GPR64 +| ld r12, SAVE_CR +|.else +| lwz r12, SAVE_CR +|.endif +| rest_ 14; rest_ 15; rest_ 16; rest_ 17; rest_ 18; rest_ 19 +| mtlr r0; +|.if PPE; mtocrf 0x20, r12; .else; mtcrf 0x38, r12; .endif +| rest_ 20; rest_ 21; rest_ 22; rest_ 23; rest_ 24; rest_ 25 +|.if PPE; mtocrf 0x10, r12; .endif +| rest_ 26; rest_ 27; rest_ 28; rest_ 29; rest_ 30; rest_ 31 +|.if PPE; mtocrf 0x08, r12; .endif +| addi sp, sp, CFRAME_SPACE +|.endmacro +| +|// Type definitions. Some of these are only used for documentation. +|.type L, lua_State, LREG +|.type GL, global_State +|.type TVALUE, TValue +|.type GCOBJ, GCobj +|.type STR, GCstr +|.type TAB, GCtab +|.type LFUNC, GCfuncL +|.type CFUNC, GCfuncC +|.type PROTO, GCproto +|.type UPVAL, GCupval +|.type NODE, Node +|.type NARGS8, int +|.type TRACE, GCtrace +|.type SBUF, SBuf +| +|//----------------------------------------------------------------------- +| +|// Trap for not-yet-implemented parts. +|.macro NYI; tw 4, sp, sp; .endmacro +| +|.if FPU +|// int/FP conversions. +|.macro tonum_i, freg, reg +| xoris reg, reg, 0x8000 +| stw reg, TONUM_LO +| lfd freg, TONUM_D +| fsub freg, freg, TONUM +|.endmacro +| +|.macro tonum_u, freg, reg +| stw reg, TONUM_LO +| lfd freg, TONUM_D +| fsub freg, freg, TOBIT +|.endmacro +| +|.macro toint, reg, freg, tmpfreg +| fctiwz tmpfreg, freg +| stfd tmpfreg, TMPD +| lwz reg, TMPD_LO +|.endmacro +| +|.macro toint, reg, freg +| toint reg, freg, freg +|.endmacro +|.endif +| +|//----------------------------------------------------------------------- +| +|// Access to frame relative to BASE. +|.define FRAME_PC, -8 +|.define FRAME_FUNC, -4 +| +|// Instruction decode. +|.macro decode_OP4, dst, ins; rlwinm dst, ins, 2, 22, 29; .endmacro +|.macro decode_OP8, dst, ins; rlwinm dst, ins, 3, 21, 28; .endmacro +|.macro decode_RA8, dst, ins; rlwinm dst, ins, 27, 21, 28; .endmacro +|.macro decode_RB8, dst, ins; rlwinm dst, ins, 11, 21, 28; .endmacro +|.macro decode_RC8, dst, ins; rlwinm dst, ins, 19, 21, 28; .endmacro +|.macro decode_RD8, dst, ins; rlwinm dst, ins, 19, 13, 28; .endmacro +| +|.macro decode_OP1, dst, ins; rlwinm dst, ins, 0, 24, 31; .endmacro +|.macro decode_RD4, dst, ins; rlwinm dst, ins, 18, 14, 29; .endmacro +| +|// Instruction fetch. +|.macro ins_NEXT1 +| lwz INS, 0(PC) +| addi PC, PC, 4 +|.endmacro +|// Instruction decode+dispatch. Note: optimized for e300! +|.macro ins_NEXT2 +| decode_OPP TMP1, INS +| lpx TMP0, DISPATCH, TMP1 +| mtctr TMP0 +| decode_RB8 RB, INS +| decode_RD8 RD, INS +| decode_RA8 RA, INS +| decode_RC8 RC, INS +| bctr +|.endmacro +|.macro ins_NEXT +| ins_NEXT1 +| ins_NEXT2 +|.endmacro +| +|// Instruction footer. +|.if 1 +| // Replicated dispatch. Less unpredictable branches, but higher I-Cache use. +| .define ins_next, ins_NEXT +| .define ins_next_, ins_NEXT +| .define ins_next1, ins_NEXT1 +| .define ins_next2, ins_NEXT2 +|.else +| // Common dispatch. Lower I-Cache use, only one (very) unpredictable branch. +| // Affects only certain kinds of benchmarks (and only with -j off). +| .macro ins_next +| b ->ins_next +| .endmacro +| .macro ins_next1 +| .endmacro +| .macro ins_next2 +| b ->ins_next +| .endmacro +| .macro ins_next_ +| ->ins_next: +| ins_NEXT +| .endmacro +|.endif +| +|// Call decode and dispatch. +|.macro ins_callt +| // BASE = new base, RB = LFUNC/CFUNC, RC = nargs*8, FRAME_PC(BASE) = PC +| lwz PC, LFUNC:RB->pc +| lwz INS, 0(PC) +| addi PC, PC, 4 +| decode_OPP TMP1, INS +| decode_RA8 RA, INS +| lpx TMP0, DISPATCH, TMP1 +| add RA, RA, BASE +| mtctr TMP0 +| bctr +|.endmacro +| +|.macro ins_call +| // BASE = new base, RB = LFUNC/CFUNC, RC = nargs*8, PC = caller PC +| stw PC, FRAME_PC(BASE) +| ins_callt +|.endmacro +| +|//----------------------------------------------------------------------- +| +|// Macros to test operand types. +|.macro checknum, reg; cmplw reg, TISNUM; .endmacro +|.macro checknum, cr, reg; cmplw cr, reg, TISNUM; .endmacro +|.macro checkstr, reg; cmpwi reg, LJ_TSTR; .endmacro +|.macro checktab, reg; cmpwi reg, LJ_TTAB; .endmacro +|.macro checkfunc, reg; cmpwi reg, LJ_TFUNC; .endmacro +|.macro checknil, reg; cmpwi reg, LJ_TNIL; .endmacro +| +|.macro branch_RD +| srwi TMP0, RD, 1 +| addis PC, PC, -(BCBIAS_J*4 >> 16) +| add PC, PC, TMP0 +|.endmacro +| +|// Assumes DISPATCH is relative to GL. +#define DISPATCH_GL(field) (GG_DISP2G + (int)offsetof(global_State, field)) +#define DISPATCH_J(field) (GG_DISP2J + (int)offsetof(jit_State, field)) +| +#define PC2PROTO(field) ((int)offsetof(GCproto, field)-(int)sizeof(GCproto)) +| +|.macro hotcheck, delta, target +| rlwinm TMP1, PC, 31, 25, 30 +| addi TMP1, TMP1, GG_DISP2HOT +| lhzx TMP2, DISPATCH, TMP1 +| addic. TMP2, TMP2, -delta +| sthx TMP2, DISPATCH, TMP1 +| blt target +|.endmacro +| +|.macro hotloop +| hotcheck HOTCOUNT_LOOP, ->vm_hotloop +|.endmacro +| +|.macro hotcall +| hotcheck HOTCOUNT_CALL, ->vm_hotcall +|.endmacro +| +|// Set current VM state. Uses TMP0. +|.macro li_vmstate, st; li TMP0, ~LJ_VMST_..st; .endmacro +|.macro st_vmstate; stw TMP0, DISPATCH_GL(vmstate)(DISPATCH); .endmacro +| +|// Move table write barrier back. Overwrites mark and tmp. +|.macro barrierback, tab, mark, tmp +| lwz tmp, DISPATCH_GL(gc.grayagain)(DISPATCH) +| // Assumes LJ_GC_BLACK is 0x04. +| rlwinm mark, mark, 0, 30, 28 // black2gray(tab) +| stw tab, DISPATCH_GL(gc.grayagain)(DISPATCH) +| stb mark, tab->marked +| stw tmp, tab->gclist +|.endmacro +| +|//----------------------------------------------------------------------- + +/* Generate subroutines used by opcodes and other parts of the VM. */ +/* The .code_sub section should be last to help static branch prediction. */ +static void build_subroutines(BuildCtx *ctx) +{ + |.code_sub + | + |//----------------------------------------------------------------------- + |//-- Return handling ---------------------------------------------------- + |//----------------------------------------------------------------------- + | + |->vm_returnp: + | // See vm_return. Also: TMP2 = previous base. + | andix. TMP0, PC, FRAME_P + | li TMP1, LJ_TTRUE + | beq ->cont_dispatch + | + | // Return from pcall or xpcall fast func. + | lwz PC, FRAME_PC(TMP2) // Fetch PC of previous frame. + | mr BASE, TMP2 // Restore caller base. + | // Prepending may overwrite the pcall frame, so do it at the end. + | stwu TMP1, FRAME_PC(RA) // Prepend true to results. + | + |->vm_returnc: + | addi RD, RD, 8 // RD = (nresults+1)*8. + | andix. TMP0, PC, FRAME_TYPE + | cmpwi cr1, RD, 0 + | li CRET1, LUA_YIELD + | beq cr1, ->vm_unwind_c_eh + | mr MULTRES, RD + | beq ->BC_RET_Z // Handle regular return to Lua. + | + |->vm_return: + | // BASE = base, RA = resultptr, RD/MULTRES = (nresults+1)*8, PC = return + | // TMP0 = PC & FRAME_TYPE + | cmpwi TMP0, FRAME_C + | rlwinm TMP2, PC, 0, 0, 28 + | li_vmstate C + | sub TMP2, BASE, TMP2 // TMP2 = previous base. + | bney ->vm_returnp + | + | addic. TMP1, RD, -8 + | stp TMP2, L->base + | lwz TMP2, SAVE_NRES + | subi BASE, BASE, 8 + | st_vmstate + | slwi TMP2, TMP2, 3 + | beq >2 + |1: + | addic. TMP1, TMP1, -8 + |.if FPU + | lfd f0, 0(RA) + |.else + | lwz CARG1, 0(RA) + | lwz CARG2, 4(RA) + |.endif + | addi RA, RA, 8 + |.if FPU + | stfd f0, 0(BASE) + |.else + | stw CARG1, 0(BASE) + | stw CARG2, 4(BASE) + |.endif + | addi BASE, BASE, 8 + | bney <1 + | + |2: + | cmpw TMP2, RD // More/less results wanted? + | bne >6 + |3: + | stp BASE, L->top // Store new top. + | + |->vm_leave_cp: + | lp TMP0, SAVE_CFRAME // Restore previous C frame. + | li CRET1, 0 // Ok return status for vm_pcall. + | stp TMP0, L->cframe + | + |->vm_leave_unw: + | restoreregs + | blr + | + |6: + | ble >7 // Less results wanted? + | // More results wanted. Check stack size and fill up results with nil. + | lwz TMP1, L->maxstack + | cmplw BASE, TMP1 + | bge >8 + | stw TISNIL, 0(BASE) + | addi RD, RD, 8 + | addi BASE, BASE, 8 + | b <2 + | + |7: // Less results wanted. + | subfic TMP3, TMP2, 0 // LUA_MULTRET+1 case? + | sub TMP0, RD, TMP2 + | subfe TMP1, TMP1, TMP1 // TMP1 = TMP2 == 0 ? 0 : -1 + | and TMP0, TMP0, TMP1 + | sub BASE, BASE, TMP0 // Either keep top or shrink it. + | b <3 + | + |8: // Corner case: need to grow stack for filling up results. + | // This can happen if: + | // - A C function grows the stack (a lot). + | // - The GC shrinks the stack in between. + | // - A return back from a lua_call() with (high) nresults adjustment. + | stp BASE, L->top // Save current top held in BASE (yes). + | mr SAVE0, RD + | srwi CARG2, TMP2, 3 + | mr CARG1, L + | bl extern lj_state_growstack // (lua_State *L, int n) + | lwz TMP2, SAVE_NRES + | mr RD, SAVE0 + | slwi TMP2, TMP2, 3 + | lp BASE, L->top // Need the (realloced) L->top in BASE. + | b <2 + | + |->vm_unwind_c: // Unwind C stack, return from vm_pcall. + | // (void *cframe, int errcode) + | mr sp, CARG1 + | mr CRET1, CARG2 + |->vm_unwind_c_eh: // Landing pad for external unwinder. + | lwz L, SAVE_L + | .toc ld TOCREG, SAVE_TOC + | li TMP0, ~LJ_VMST_C + | lwz GL:TMP1, L->glref + | stw TMP0, GL:TMP1->vmstate + | b ->vm_leave_unw + | + |->vm_unwind_ff: // Unwind C stack, return from ff pcall. + | // (void *cframe) + |.if GPR64 + | rldicr sp, CARG1, 0, 61 + |.else + | rlwinm sp, CARG1, 0, 0, 29 + |.endif + |->vm_unwind_ff_eh: // Landing pad for external unwinder. + | lwz L, SAVE_L + | .toc ld TOCREG, SAVE_TOC + | li TISNUM, LJ_TISNUM // Setup type comparison constants. + | lp BASE, L->base + | .FPU lus TMP3, 0x59c0 // TOBIT = 2^52 + 2^51 (float). + | lwz DISPATCH, L->glref // Setup pointer to dispatch table. + | li ZERO, 0 + | .FPU stw TMP3, TMPD + | li TMP1, LJ_TFALSE + | .FPU ori TMP3, TMP3, 0x0004 // TONUM = 2^52 + 2^51 + 2^31 (float). + | li TISNIL, LJ_TNIL + | li_vmstate INTERP + | .FPU lfs TOBIT, TMPD + | lwz PC, FRAME_PC(BASE) // Fetch PC of previous frame. + | la RA, -8(BASE) // Results start at BASE-8. + | .FPU stw TMP3, TMPD + | addi DISPATCH, DISPATCH, GG_G2DISP + | stw TMP1, 0(RA) // Prepend false to error message. + | li RD, 16 // 2 results: false + error message. + | st_vmstate + | .FPU lfs TONUM, TMPD + | b ->vm_returnc + | + |//----------------------------------------------------------------------- + |//-- Grow stack for calls ----------------------------------------------- + |//----------------------------------------------------------------------- + | + |->vm_growstack_c: // Grow stack for C function. + | li CARG2, LUA_MINSTACK + | b >2 + | + |->vm_growstack_l: // Grow stack for Lua function. + | // BASE = new base, RA = BASE+framesize*8, RC = nargs*8, PC = first PC + | add RC, BASE, RC + | sub RA, RA, BASE + | stp BASE, L->base + | addi PC, PC, 4 // Must point after first instruction. + | stp RC, L->top + | srwi CARG2, RA, 3 + |2: + | // L->base = new base, L->top = top + | stw PC, SAVE_PC + | mr CARG1, L + | bl extern lj_state_growstack // (lua_State *L, int n) + | lp BASE, L->base + | lp RC, L->top + | lwz LFUNC:RB, FRAME_FUNC(BASE) + | sub RC, RC, BASE + | // BASE = new base, RB = LFUNC/CFUNC, RC = nargs*8, FRAME_PC(BASE) = PC + | ins_callt // Just retry the call. + | + |//----------------------------------------------------------------------- + |//-- Entry points into the assembler VM --------------------------------- + |//----------------------------------------------------------------------- + | + |->vm_resume: // Setup C frame and resume thread. + | // (lua_State *L, TValue *base, int nres1 = 0, ptrdiff_t ef = 0) + | saveregs + | mr L, CARG1 + | lwz DISPATCH, L->glref // Setup pointer to dispatch table. + | mr BASE, CARG2 + | lbz TMP1, L->status + | stw L, SAVE_L + | li PC, FRAME_CP + | addi TMP0, sp, CFRAME_RESUME + | addi DISPATCH, DISPATCH, GG_G2DISP + | stw CARG3, SAVE_NRES + | cmplwi TMP1, 0 + | stw CARG3, SAVE_ERRF + | stp CARG3, SAVE_CFRAME + | stw CARG1, SAVE_PC // Any value outside of bytecode is ok. + | stp TMP0, L->cframe + | beq >3 + | + | // Resume after yield (like a return). + | stw L, DISPATCH_GL(cur_L)(DISPATCH) + | mr RA, BASE + | lp BASE, L->base + | li TISNUM, LJ_TISNUM // Setup type comparison constants. + | lp TMP1, L->top + | lwz PC, FRAME_PC(BASE) + | .FPU lus TMP3, 0x59c0 // TOBIT = 2^52 + 2^51 (float). + | stb CARG3, L->status + | .FPU stw TMP3, TMPD + | .FPU ori TMP3, TMP3, 0x0004 // TONUM = 2^52 + 2^51 + 2^31 (float). + | .FPU lfs TOBIT, TMPD + | sub RD, TMP1, BASE + | .FPU stw TMP3, TMPD + | .FPU lus TMP0, 0x4338 // Hiword of 2^52 + 2^51 (double) + | addi RD, RD, 8 + | .FPU stw TMP0, TONUM_HI + | li_vmstate INTERP + | li ZERO, 0 + | st_vmstate + | andix. TMP0, PC, FRAME_TYPE + | mr MULTRES, RD + | .FPU lfs TONUM, TMPD + | li TISNIL, LJ_TNIL + | beq ->BC_RET_Z + | b ->vm_return + | + |->vm_pcall: // Setup protected C frame and enter VM. + | // (lua_State *L, TValue *base, int nres1, ptrdiff_t ef) + | saveregs + | li PC, FRAME_CP + | stw CARG4, SAVE_ERRF + | b >1 + | + |->vm_call: // Setup C frame and enter VM. + | // (lua_State *L, TValue *base, int nres1) + | saveregs + | li PC, FRAME_C + | + |1: // Entry point for vm_pcall above (PC = ftype). + | lp TMP1, L:CARG1->cframe + | mr L, CARG1 + | stw CARG3, SAVE_NRES + | lwz DISPATCH, L->glref // Setup pointer to dispatch table. + | stw CARG1, SAVE_L + | mr BASE, CARG2 + | addi DISPATCH, DISPATCH, GG_G2DISP + | stw CARG1, SAVE_PC // Any value outside of bytecode is ok. + | stp TMP1, SAVE_CFRAME + | stp sp, L->cframe // Add our C frame to cframe chain. + | + |3: // Entry point for vm_cpcall/vm_resume (BASE = base, PC = ftype). + | stw L, DISPATCH_GL(cur_L)(DISPATCH) + | lp TMP2, L->base // TMP2 = old base (used in vmeta_call). + | li TISNUM, LJ_TISNUM // Setup type comparison constants. + | lp TMP1, L->top + | .FPU lus TMP3, 0x59c0 // TOBIT = 2^52 + 2^51 (float). + | add PC, PC, BASE + | .FPU stw TMP3, TMPD + | li ZERO, 0 + | .FPU ori TMP3, TMP3, 0x0004 // TONUM = 2^52 + 2^51 + 2^31 (float). + | .FPU lfs TOBIT, TMPD + | sub PC, PC, TMP2 // PC = frame delta + frame type + | .FPU stw TMP3, TMPD + | .FPU lus TMP0, 0x4338 // Hiword of 2^52 + 2^51 (double) + | sub NARGS8:RC, TMP1, BASE + | .FPU stw TMP0, TONUM_HI + | li_vmstate INTERP + | .FPU lfs TONUM, TMPD + | li TISNIL, LJ_TNIL + | st_vmstate + | + |->vm_call_dispatch: + | // TMP2 = old base, BASE = new base, RC = nargs*8, PC = caller PC + | lwz TMP0, FRAME_PC(BASE) + | lwz LFUNC:RB, FRAME_FUNC(BASE) + | checkfunc TMP0; bne ->vmeta_call + | + |->vm_call_dispatch_f: + | ins_call + | // BASE = new base, RB = func, RC = nargs*8, PC = caller PC + | + |->vm_cpcall: // Setup protected C frame, call C. + | // (lua_State *L, lua_CFunction func, void *ud, lua_CPFunction cp) + | saveregs + | mr L, CARG1 + | lwz TMP0, L:CARG1->stack + | stw CARG1, SAVE_L + | lp TMP1, L->top + | lwz DISPATCH, L->glref // Setup pointer to dispatch table. + | stw CARG1, SAVE_PC // Any value outside of bytecode is ok. + | sub TMP0, TMP0, TMP1 // Compute -savestack(L, L->top). + | lp TMP1, L->cframe + | addi DISPATCH, DISPATCH, GG_G2DISP + | .toc lp CARG4, 0(CARG4) + | li TMP2, 0 + | stw TMP0, SAVE_NRES // Neg. delta means cframe w/o frame. + | stw TMP2, SAVE_ERRF // No error function. + | stp TMP1, SAVE_CFRAME + | stp sp, L->cframe // Add our C frame to cframe chain. + | stw L, DISPATCH_GL(cur_L)(DISPATCH) + | mtctr CARG4 + | bctrl // (lua_State *L, lua_CFunction func, void *ud) + |.if PPE + | mr BASE, CRET1 + | cmpwi CRET1, 0 + |.else + | mr. BASE, CRET1 + |.endif + | li PC, FRAME_CP + | bne <3 // Else continue with the call. + | b ->vm_leave_cp // No base? Just remove C frame. + | + |//----------------------------------------------------------------------- + |//-- Metamethod handling ------------------------------------------------ + |//----------------------------------------------------------------------- + | + |// The lj_meta_* functions (except for lj_meta_cat) don't reallocate the + |// stack, so BASE doesn't need to be reloaded across these calls. + | + |//-- Continuation dispatch ---------------------------------------------- + | + |->cont_dispatch: + | // BASE = meta base, RA = resultptr, RD = (nresults+1)*8 + | lwz TMP0, -12(BASE) // Continuation. + | mr RB, BASE + | mr BASE, TMP2 // Restore caller BASE. + | lwz LFUNC:TMP1, FRAME_FUNC(TMP2) + |.if FFI + | cmplwi TMP0, 1 + |.endif + | lwz PC, -16(RB) // Restore PC from [cont|PC]. + | subi TMP2, RD, 8 + | stwx TISNIL, RA, TMP2 // Ensure one valid arg. + |.if FFI + | ble >1 + |.endif + | lwz TMP1, LFUNC:TMP1->pc + | lwz KBASE, PC2PROTO(k)(TMP1) + | // BASE = base, RA = resultptr, RB = meta base + | mtctr TMP0 + | bctr // Jump to continuation. + | + |.if FFI + |1: + | beq ->cont_ffi_callback // cont = 1: return from FFI callback. + | // cont = 0: tailcall from C function. + | subi TMP1, RB, 16 + | sub RC, TMP1, BASE + | b ->vm_call_tail + |.endif + | + |->cont_cat: // RA = resultptr, RB = meta base + | lwz INS, -4(PC) + | subi CARG2, RB, 16 + | decode_RB8 SAVE0, INS + |.if FPU + | lfd f0, 0(RA) + |.else + | lwz TMP2, 0(RA) + | lwz TMP3, 4(RA) + |.endif + | add TMP1, BASE, SAVE0 + | stp BASE, L->base + | cmplw TMP1, CARG2 + | sub CARG3, CARG2, TMP1 + | decode_RA8 RA, INS + |.if FPU + | stfd f0, 0(CARG2) + |.else + | stw TMP2, 0(CARG2) + | stw TMP3, 4(CARG2) + |.endif + | bney ->BC_CAT_Z + |.if FPU + | stfdx f0, BASE, RA + |.else + | stwux TMP2, RA, BASE + | stw TMP3, 4(RA) + |.endif + | b ->cont_nop + | + |//-- Table indexing metamethods ----------------------------------------- + | + |->vmeta_tgets1: + | la CARG3, DISPATCH_GL(tmptv)(DISPATCH) + | li TMP0, LJ_TSTR + | decode_RB8 RB, INS + | stw STR:RC, 4(CARG3) + | add CARG2, BASE, RB + | stw TMP0, 0(CARG3) + | b >1 + | + |->vmeta_tgets: + | la CARG2, DISPATCH_GL(tmptv)(DISPATCH) + | li TMP0, LJ_TTAB + | stw TAB:RB, 4(CARG2) + | la CARG3, DISPATCH_GL(tmptv2)(DISPATCH) + | stw TMP0, 0(CARG2) + | li TMP1, LJ_TSTR + | stw STR:RC, 4(CARG3) + | stw TMP1, 0(CARG3) + | b >1 + | + |->vmeta_tgetb: // TMP0 = index + |.if not DUALNUM + | tonum_u f0, TMP0 + |.endif + | decode_RB8 RB, INS + | la CARG3, DISPATCH_GL(tmptv)(DISPATCH) + | add CARG2, BASE, RB + |.if DUALNUM + | stw TISNUM, 0(CARG3) + | stw TMP0, 4(CARG3) + |.else + | stfd f0, 0(CARG3) + |.endif + | b >1 + | + |->vmeta_tgetv: + | decode_RB8 RB, INS + | decode_RC8 RC, INS + | add CARG2, BASE, RB + | add CARG3, BASE, RC + |1: + | stp BASE, L->base + | mr CARG1, L + | stw PC, SAVE_PC + | bl extern lj_meta_tget // (lua_State *L, TValue *o, TValue *k) + | // Returns TValue * (finished) or NULL (metamethod). + | cmplwi CRET1, 0 + | beq >3 + |.if FPU + | lfd f0, 0(CRET1) + |.else + | lwz TMP0, 0(CRET1) + | lwz TMP1, 4(CRET1) + |.endif + | ins_next1 + |.if FPU + | stfdx f0, BASE, RA + |.else + | stwux TMP0, RA, BASE + | stw TMP1, 4(RA) + |.endif + | ins_next2 + | + |3: // Call __index metamethod. + | // BASE = base, L->top = new base, stack = cont/func/t/k + | subfic TMP1, BASE, FRAME_CONT + | lp BASE, L->top + | stw PC, -16(BASE) // [cont|PC] + | add PC, TMP1, BASE + | lwz LFUNC:RB, FRAME_FUNC(BASE) // Guaranteed to be a function here. + | li NARGS8:RC, 16 // 2 args for func(t, k). + | b ->vm_call_dispatch_f + | + |->vmeta_tgetr: + | bl extern lj_tab_getinth // (GCtab *t, int32_t key) + | // Returns cTValue * or NULL. + | cmplwi CRET1, 0 + | beq >1 + |.if FPU + | lfd f14, 0(CRET1) + |.else + | lwz SAVE0, 0(CRET1) + | lwz SAVE1, 4(CRET1) + |.endif + | b ->BC_TGETR_Z + |1: + | stwx TISNIL, BASE, RA + | b ->cont_nop + | + |//----------------------------------------------------------------------- + | + |->vmeta_tsets1: + | la CARG3, DISPATCH_GL(tmptv)(DISPATCH) + | li TMP0, LJ_TSTR + | decode_RB8 RB, INS + | stw STR:RC, 4(CARG3) + | add CARG2, BASE, RB + | stw TMP0, 0(CARG3) + | b >1 + | + |->vmeta_tsets: + | la CARG2, DISPATCH_GL(tmptv)(DISPATCH) + | li TMP0, LJ_TTAB + | stw TAB:RB, 4(CARG2) + | la CARG3, DISPATCH_GL(tmptv2)(DISPATCH) + | stw TMP0, 0(CARG2) + | li TMP1, LJ_TSTR + | stw STR:RC, 4(CARG3) + | stw TMP1, 0(CARG3) + | b >1 + | + |->vmeta_tsetb: // TMP0 = index + |.if not DUALNUM + | tonum_u f0, TMP0 + |.endif + | decode_RB8 RB, INS + | la CARG3, DISPATCH_GL(tmptv)(DISPATCH) + | add CARG2, BASE, RB + |.if DUALNUM + | stw TISNUM, 0(CARG3) + | stw TMP0, 4(CARG3) + |.else + | stfd f0, 0(CARG3) + |.endif + | b >1 + | + |->vmeta_tsetv: + | decode_RB8 RB, INS + | decode_RC8 RC, INS + | add CARG2, BASE, RB + | add CARG3, BASE, RC + |1: + | stp BASE, L->base + | mr CARG1, L + | stw PC, SAVE_PC + | bl extern lj_meta_tset // (lua_State *L, TValue *o, TValue *k) + | // Returns TValue * (finished) or NULL (metamethod). + | cmplwi CRET1, 0 + |.if FPU + | lfdx f0, BASE, RA + |.else + | lwzux TMP2, RA, BASE + | lwz TMP3, 4(RA) + |.endif + | beq >3 + | // NOBARRIER: lj_meta_tset ensures the table is not black. + | ins_next1 + |.if FPU + | stfd f0, 0(CRET1) + |.else + | stw TMP2, 0(CRET1) + | stw TMP3, 4(CRET1) + |.endif + | ins_next2 + | + |3: // Call __newindex metamethod. + | // BASE = base, L->top = new base, stack = cont/func/t/k/(v) + | subfic TMP1, BASE, FRAME_CONT + | lp BASE, L->top + | stw PC, -16(BASE) // [cont|PC] + | add PC, TMP1, BASE + | lwz LFUNC:RB, FRAME_FUNC(BASE) // Guaranteed to be a function here. + | li NARGS8:RC, 24 // 3 args for func(t, k, v) + |.if FPU + | stfd f0, 16(BASE) // Copy value to third argument. + |.else + | stw TMP2, 16(BASE) + | stw TMP3, 20(BASE) + |.endif + | b ->vm_call_dispatch_f + | + |->vmeta_tsetr: + | stp BASE, L->base + | mr CARG1, L + | stw PC, SAVE_PC + | bl extern lj_tab_setinth // (lua_State *L, GCtab *t, int32_t key) + | // Returns TValue *. + |.if FPU + | stfd f14, 0(CRET1) + |.else + | stw SAVE0, 0(CRET1) + | stw SAVE1, 4(CRET1) + |.endif + | b ->cont_nop + | + |//-- Comparison metamethods --------------------------------------------- + | + |->vmeta_comp: + | mr CARG1, L + | subi PC, PC, 4 + |.if DUALNUM + | mr CARG2, RA + |.else + | add CARG2, BASE, RA + |.endif + | stw PC, SAVE_PC + |.if DUALNUM + | mr CARG3, RD + |.else + | add CARG3, BASE, RD + |.endif + | stp BASE, L->base + | decode_OP1 CARG4, INS + | bl extern lj_meta_comp // (lua_State *L, TValue *o1, *o2, int op) + | // Returns 0/1 or TValue * (metamethod). + |3: + | cmplwi CRET1, 1 + | bgt ->vmeta_binop + | subfic CRET1, CRET1, 0 + |4: + | lwz INS, 0(PC) + | addi PC, PC, 4 + | decode_RD4 TMP2, INS + | addis TMP2, TMP2, -(BCBIAS_J*4 >> 16) + | and TMP2, TMP2, CRET1 + | add PC, PC, TMP2 + |->cont_nop: + | ins_next + | + |->cont_ra: // RA = resultptr + | lwz INS, -4(PC) + |.if FPU + | lfd f0, 0(RA) + |.else + | lwz CARG1, 0(RA) + | lwz CARG2, 4(RA) + |.endif + | decode_RA8 TMP1, INS + |.if FPU + | stfdx f0, BASE, TMP1 + |.else + | stwux CARG1, TMP1, BASE + | stw CARG2, 4(TMP1) + |.endif + | b ->cont_nop + | + |->cont_condt: // RA = resultptr + | lwz TMP0, 0(RA) + | .gpr64 extsw TMP0, TMP0 + | subfic TMP0, TMP0, LJ_TTRUE // Branch if result is true. + | subfe CRET1, CRET1, CRET1 + | not CRET1, CRET1 + | b <4 + | + |->cont_condf: // RA = resultptr + | lwz TMP0, 0(RA) + | .gpr64 extsw TMP0, TMP0 + | subfic TMP0, TMP0, LJ_TTRUE // Branch if result is false. + | subfe CRET1, CRET1, CRET1 + | b <4 + | + |->vmeta_equal: + | // CARG2, CARG3, CARG4 are already set by BC_ISEQV/BC_ISNEV. + | subi PC, PC, 4 + | stp BASE, L->base + | mr CARG1, L + | stw PC, SAVE_PC + | bl extern lj_meta_equal // (lua_State *L, GCobj *o1, *o2, int ne) + | // Returns 0/1 or TValue * (metamethod). + | b <3 + | + |->vmeta_equal_cd: + |.if FFI + | mr CARG2, INS + | subi PC, PC, 4 + | stp BASE, L->base + | mr CARG1, L + | stw PC, SAVE_PC + | bl extern lj_meta_equal_cd // (lua_State *L, BCIns op) + | // Returns 0/1 or TValue * (metamethod). + | b <3 + |.endif + | + |->vmeta_istype: + | subi PC, PC, 4 + | stp BASE, L->base + | srwi CARG2, RA, 3 + | mr CARG1, L + | srwi CARG3, RD, 3 + | stw PC, SAVE_PC + | bl extern lj_meta_istype // (lua_State *L, BCReg ra, BCReg tp) + | b ->cont_nop + | + |//-- Arithmetic metamethods --------------------------------------------- + | + |->vmeta_arith_nv: + | add CARG3, KBASE, RC + | add CARG4, BASE, RB + | b >1 + |->vmeta_arith_nv2: + |.if DUALNUM + | mr CARG3, RC + | mr CARG4, RB + | b >1 + |.endif + | + |->vmeta_unm: + | mr CARG3, RD + | mr CARG4, RD + | b >1 + | + |->vmeta_arith_vn: + | add CARG3, BASE, RB + | add CARG4, KBASE, RC + | b >1 + | + |->vmeta_arith_vv: + | add CARG3, BASE, RB + | add CARG4, BASE, RC + |.if DUALNUM + | b >1 + |.endif + |->vmeta_arith_vn2: + |->vmeta_arith_vv2: + |.if DUALNUM + | mr CARG3, RB + | mr CARG4, RC + |.endif + |1: + | add CARG2, BASE, RA + | stp BASE, L->base + | mr CARG1, L + | stw PC, SAVE_PC + | decode_OP1 CARG5, INS // Caveat: CARG5 overlaps INS. + | bl extern lj_meta_arith // (lua_State *L, TValue *ra,*rb,*rc, BCReg op) + | // Returns NULL (finished) or TValue * (metamethod). + | cmplwi CRET1, 0 + | beq ->cont_nop + | + | // Call metamethod for binary op. + |->vmeta_binop: + | // BASE = old base, CRET1 = new base, stack = cont/func/o1/o2 + | sub TMP1, CRET1, BASE + | stw PC, -16(CRET1) // [cont|PC] + | mr TMP2, BASE + | addi PC, TMP1, FRAME_CONT + | mr BASE, CRET1 + | li NARGS8:RC, 16 // 2 args for func(o1, o2). + | b ->vm_call_dispatch + | + |->vmeta_len: +#if LJ_52 + | mr SAVE0, CARG1 +#endif + | mr CARG2, RD + | stp BASE, L->base + | mr CARG1, L + | stw PC, SAVE_PC + | bl extern lj_meta_len // (lua_State *L, TValue *o) + | // Returns NULL (retry) or TValue * (metamethod base). +#if LJ_52 + | cmplwi CRET1, 0 + | bne ->vmeta_binop // Binop call for compatibility. + | mr CARG1, SAVE0 + | b ->BC_LEN_Z +#else + | b ->vmeta_binop // Binop call for compatibility. +#endif + | + |//-- Call metamethod ---------------------------------------------------- + | + |->vmeta_call: // Resolve and call __call metamethod. + | // TMP2 = old base, BASE = new base, RC = nargs*8 + | mr CARG1, L + | stp TMP2, L->base // This is the callers base! + | subi CARG2, BASE, 8 + | stw PC, SAVE_PC + | add CARG3, BASE, RC + | mr SAVE0, NARGS8:RC + | bl extern lj_meta_call // (lua_State *L, TValue *func, TValue *top) + | lwz LFUNC:RB, FRAME_FUNC(BASE) // Guaranteed to be a function here. + | addi NARGS8:RC, SAVE0, 8 // Got one more argument now. + | ins_call + | + |->vmeta_callt: // Resolve __call for BC_CALLT. + | // BASE = old base, RA = new base, RC = nargs*8 + | mr CARG1, L + | stp BASE, L->base + | subi CARG2, RA, 8 + | stw PC, SAVE_PC + | add CARG3, RA, RC + | mr SAVE0, NARGS8:RC + | bl extern lj_meta_call // (lua_State *L, TValue *func, TValue *top) + | lwz TMP1, FRAME_PC(BASE) + | addi NARGS8:RC, SAVE0, 8 // Got one more argument now. + | lwz LFUNC:RB, FRAME_FUNC(RA) // Guaranteed to be a function here. + | b ->BC_CALLT_Z + | + |//-- Argument coercion for 'for' statement ------------------------------ + | + |->vmeta_for: + | mr CARG1, L + | stp BASE, L->base + | mr CARG2, RA + | stw PC, SAVE_PC + | mr SAVE0, INS + | bl extern lj_meta_for // (lua_State *L, TValue *base) + |.if JIT + | decode_OP1 TMP0, SAVE0 + |.endif + | decode_RA8 RA, SAVE0 + |.if JIT + | cmpwi TMP0, BC_JFORI + |.endif + | decode_RD8 RD, SAVE0 + |.if JIT + | beqy =>BC_JFORI + |.endif + | b =>BC_FORI + | + |//----------------------------------------------------------------------- + |//-- Fast functions ----------------------------------------------------- + |//----------------------------------------------------------------------- + | + |.macro .ffunc, name + |->ff_ .. name: + |.endmacro + | + |.macro .ffunc_1, name + |->ff_ .. name: + | cmplwi NARGS8:RC, 8 + | lwz CARG3, 0(BASE) + | lwz CARG1, 4(BASE) + | blt ->fff_fallback + |.endmacro + | + |.macro .ffunc_2, name + |->ff_ .. name: + | cmplwi NARGS8:RC, 16 + | lwz CARG3, 0(BASE) + | lwz CARG4, 8(BASE) + | lwz CARG1, 4(BASE) + | lwz CARG2, 12(BASE) + | blt ->fff_fallback + |.endmacro + | + |.macro .ffunc_n, name + |->ff_ .. name: + | cmplwi NARGS8:RC, 8 + | lwz CARG1, 0(BASE) + |.if FPU + | lfd FARG1, 0(BASE) + |.else + | lwz CARG2, 4(BASE) + |.endif + | blt ->fff_fallback + | checknum CARG1; bge ->fff_fallback + |.endmacro + | + |.macro .ffunc_nn, name + |->ff_ .. name: + | cmplwi NARGS8:RC, 16 + | lwz CARG1, 0(BASE) + |.if FPU + | lfd FARG1, 0(BASE) + | lwz CARG3, 8(BASE) + | lfd FARG2, 8(BASE) + |.else + | lwz CARG2, 4(BASE) + | lwz CARG3, 8(BASE) + | lwz CARG4, 12(BASE) + |.endif + | blt ->fff_fallback + | checknum CARG1; bge ->fff_fallback + | checknum CARG3; bge ->fff_fallback + |.endmacro + | + |// Inlined GC threshold check. Caveat: uses TMP0 and TMP1. + |.macro ffgccheck + | lwz TMP0, DISPATCH_GL(gc.total)(DISPATCH) + | lwz TMP1, DISPATCH_GL(gc.threshold)(DISPATCH) + | cmplw TMP0, TMP1 + | bgel ->fff_gcstep + |.endmacro + | + |//-- Base library: checks ----------------------------------------------- + | + |.ffunc_1 assert + | li TMP1, LJ_TFALSE + | la RA, -8(BASE) + | cmplw cr1, CARG3, TMP1 + | lwz PC, FRAME_PC(BASE) + | bge cr1, ->fff_fallback + | stw CARG3, 0(RA) + | addi RD, NARGS8:RC, 8 // Compute (nresults+1)*8. + | addi TMP1, BASE, 8 + | add TMP2, RA, NARGS8:RC + | stw CARG1, 4(RA) + | beq ->fff_res // Done if exactly 1 argument. + |1: + | cmplw TMP1, TMP2 + |.if FPU + | lfd f0, 0(TMP1) + | stfd f0, 0(TMP1) + |.else + | lwz CARG1, 0(TMP1) + | lwz CARG2, 4(TMP1) + | stw CARG1, -8(TMP1) + | stw CARG2, -4(TMP1) + |.endif + | addi TMP1, TMP1, 8 + | bney <1 + | b ->fff_res + | + |.ffunc type + | cmplwi NARGS8:RC, 8 + | lwz CARG1, 0(BASE) + | blt ->fff_fallback + | .gpr64 extsw CARG1, CARG1 + | subfc TMP0, TISNUM, CARG1 + | subfe TMP2, CARG1, CARG1 + | orc TMP1, TMP2, TMP0 + | addi TMP1, TMP1, ~LJ_TISNUM+1 + | slwi TMP1, TMP1, 3 + |.if FPU + | la TMP2, CFUNC:RB->upvalue + | lfdx FARG1, TMP2, TMP1 + |.else + | add TMP1, CFUNC:RB, TMP1 + | lwz CARG1, CFUNC:TMP1->upvalue[0].u32.hi + | lwz CARG2, CFUNC:TMP1->upvalue[0].u32.lo + |.endif + | b ->fff_resn + | + |//-- Base library: getters and setters --------------------------------- + | + |.ffunc_1 getmetatable + | checktab CARG3; bne >6 + |1: // Field metatable must be at same offset for GCtab and GCudata! + | lwz TAB:CARG1, TAB:CARG1->metatable + |2: + | li CARG3, LJ_TNIL + | cmplwi TAB:CARG1, 0 + | lwz STR:RC, DISPATCH_GL(gcroot[GCROOT_MMNAME+MM_metatable])(DISPATCH) + | beq ->fff_restv + | lwz TMP0, TAB:CARG1->hmask + | li CARG3, LJ_TTAB // Use metatable as default result. + | lwz TMP1, STR:RC->sid + | lwz NODE:TMP2, TAB:CARG1->node + | and TMP1, TMP1, TMP0 // idx = str->sid & tab->hmask + | slwi TMP0, TMP1, 5 + | slwi TMP1, TMP1, 3 + | sub TMP1, TMP0, TMP1 + | add NODE:TMP2, NODE:TMP2, TMP1 // node = tab->node + (idx*32-idx*8) + |3: // Rearranged logic, because we expect _not_ to find the key. + | lwz CARG4, NODE:TMP2->key + | lwz TMP0, 4+offsetof(Node, key)(NODE:TMP2) + | lwz CARG2, NODE:TMP2->val + | lwz TMP1, 4+offsetof(Node, val)(NODE:TMP2) + | checkstr CARG4; bne >4 + | cmpw TMP0, STR:RC; beq >5 + |4: + | lwz NODE:TMP2, NODE:TMP2->next + | cmplwi NODE:TMP2, 0 + | beq ->fff_restv // Not found, keep default result. + | b <3 + |5: + | checknil CARG2 + | beq ->fff_restv // Ditto for nil value. + | mr CARG3, CARG2 // Return value of mt.__metatable. + | mr CARG1, TMP1 + | b ->fff_restv + | + |6: + | cmpwi CARG3, LJ_TUDATA; beq <1 + | .gpr64 extsw CARG3, CARG3 + | subfc TMP0, TISNUM, CARG3 + | subfe TMP2, CARG3, CARG3 + | orc TMP1, TMP2, TMP0 + | addi TMP1, TMP1, ~LJ_TISNUM+1 + | slwi TMP1, TMP1, 2 + | la TMP2, DISPATCH_GL(gcroot[GCROOT_BASEMT])(DISPATCH) + | lwzx TAB:CARG1, TMP2, TMP1 + | b <2 + | + |.ffunc_2 setmetatable + | // Fast path: no mt for table yet and not clearing the mt. + | checktab CARG3; bne ->fff_fallback + | lwz TAB:TMP1, TAB:CARG1->metatable + | checktab CARG4; bne ->fff_fallback + | cmplwi TAB:TMP1, 0 + | lbz TMP3, TAB:CARG1->marked + | bne ->fff_fallback + | andix. TMP0, TMP3, LJ_GC_BLACK // isblack(table) + | stw TAB:CARG2, TAB:CARG1->metatable + | beq ->fff_restv + | barrierback TAB:CARG1, TMP3, TMP0 + | b ->fff_restv + | + |.ffunc rawget + | cmplwi NARGS8:RC, 16 + | lwz CARG4, 0(BASE) + | lwz TAB:CARG2, 4(BASE) + | blt ->fff_fallback + | checktab CARG4; bne ->fff_fallback + | la CARG3, 8(BASE) + | mr CARG1, L + | bl extern lj_tab_get // (lua_State *L, GCtab *t, cTValue *key) + | // Returns cTValue *. + |.if FPU + | lfd FARG1, 0(CRET1) + |.else + | lwz CARG2, 4(CRET1) + | lwz CARG1, 0(CRET1) // Caveat: CARG1 == CRET1. + |.endif + | b ->fff_resn + | + |//-- Base library: conversions ------------------------------------------ + | + |.ffunc tonumber + | // Only handles the number case inline (without a base argument). + | cmplwi NARGS8:RC, 8 + | lwz CARG1, 0(BASE) + |.if FPU + | lfd FARG1, 0(BASE) + |.else + | lwz CARG2, 4(BASE) + |.endif + | bne ->fff_fallback // Exactly one argument. + | checknum CARG1; bgt ->fff_fallback + | b ->fff_resn + | + |.ffunc_1 tostring + | // Only handles the string or number case inline. + | checkstr CARG3 + | // A __tostring method in the string base metatable is ignored. + | beq ->fff_restv // String key? + | // Handle numbers inline, unless a number base metatable is present. + | lwz TMP0, DISPATCH_GL(gcroot[GCROOT_BASEMT_NUM])(DISPATCH) + | checknum CARG3 + | cmplwi cr1, TMP0, 0 + | stp BASE, L->base // Add frame since C call can throw. + | crorc 4*cr0+eq, 4*cr0+gt, 4*cr1+eq + | stw PC, SAVE_PC // Redundant (but a defined value). + | beq ->fff_fallback + | ffgccheck + | mr CARG1, L + | mr CARG2, BASE + |.if DUALNUM + | bl extern lj_strfmt_number // (lua_State *L, cTValue *o) + |.else + | bl extern lj_strfmt_num // (lua_State *L, lua_Number *np) + |.endif + | // Returns GCstr *. + | li CARG3, LJ_TSTR + | b ->fff_restv + | + |//-- Base library: iterators ------------------------------------------- + | + |.ffunc_1 next + | stwx TISNIL, BASE, NARGS8:RC // Set missing 2nd arg to nil. + | checktab CARG3 + | lwz PC, FRAME_PC(BASE) + | bne ->fff_fallback + | la CARG2, 8(BASE) + | la CARG3, -8(BASE) + | bl extern lj_tab_next // (GCtab *t, cTValue *key, TValue *o) + | // Returns 1=found, 0=end, -1=error. + | cmpwi CRET1, 0 + | la RA, -8(BASE) + | li RD, (2+1)*8 + | bgt ->fff_res // Found key/value. + | li CARG3, LJ_TNIL + | beq ->fff_restv // End of traversal: return nil. + | lwz CFUNC:RB, FRAME_FUNC(BASE) + | li NARGS8:RC, 2*8 + | b ->fff_fallback // Invalid key. + | + |.ffunc_1 pairs + | checktab CARG3 + | lwz PC, FRAME_PC(BASE) + | bne ->fff_fallback +#if LJ_52 + | lwz TAB:TMP2, TAB:CARG1->metatable + |.if FPU + | lfd f0, CFUNC:RB->upvalue[0] + |.else + | lwz TMP0, CFUNC:RB->upvalue[0].u32.hi + | lwz TMP1, CFUNC:RB->upvalue[0].u32.lo + |.endif + | cmplwi TAB:TMP2, 0 + | la RA, -8(BASE) + | bne ->fff_fallback +#else + |.if FPU + | lfd f0, CFUNC:RB->upvalue[0] + |.else + | lwz TMP0, CFUNC:RB->upvalue[0].u32.hi + | lwz TMP1, CFUNC:RB->upvalue[0].u32.lo + |.endif + | la RA, -8(BASE) +#endif + | stw TISNIL, 8(BASE) + | li RD, (3+1)*8 + |.if FPU + | stfd f0, 0(RA) + |.else + | stw TMP0, 0(RA) + | stw TMP1, 4(RA) + |.endif + | b ->fff_res + | + |.ffunc ipairs_aux + | cmplwi NARGS8:RC, 16 + | lwz CARG3, 0(BASE) + | lwz TAB:CARG1, 4(BASE) + | lwz CARG4, 8(BASE) + |.if DUALNUM + | lwz TMP2, 12(BASE) + |.else + | lfd FARG2, 8(BASE) + |.endif + | blt ->fff_fallback + | checktab CARG3 + | checknum cr1, CARG4 + | lwz PC, FRAME_PC(BASE) + |.if DUALNUM + | bne ->fff_fallback + | bne cr1, ->fff_fallback + |.else + | lus TMP0, 0x3ff0 + | stw ZERO, TMPD_LO + | bne ->fff_fallback + | stw TMP0, TMPD_HI + | bge cr1, ->fff_fallback + | lfd FARG1, TMPD + | toint TMP2, FARG2, f0 + |.endif + | lwz TMP0, TAB:CARG1->asize + | lwz TMP1, TAB:CARG1->array + |.if not DUALNUM + | fadd FARG2, FARG2, FARG1 + |.endif + | addi TMP2, TMP2, 1 + | la RA, -8(BASE) + | cmplw TMP0, TMP2 + |.if DUALNUM + | stw TISNUM, 0(RA) + | slwi TMP3, TMP2, 3 + | stw TMP2, 4(RA) + |.else + | slwi TMP3, TMP2, 3 + | stfd FARG2, 0(RA) + |.endif + | ble >2 // Not in array part? + |.if FPU + | lwzx TMP2, TMP1, TMP3 + | lfdx f0, TMP1, TMP3 + |.else + | lwzux TMP2, TMP1, TMP3 + | lwz TMP3, 4(TMP1) + |.endif + |1: + | checknil TMP2 + | li RD, (0+1)*8 + | beq ->fff_res // End of iteration, return 0 results. + | li RD, (2+1)*8 + |.if FPU + | stfd f0, 8(RA) + |.else + | stw TMP2, 8(RA) + | stw TMP3, 12(RA) + |.endif + | b ->fff_res + |2: // Check for empty hash part first. Otherwise call C function. + | lwz TMP0, TAB:CARG1->hmask + | cmplwi TMP0, 0 + | li RD, (0+1)*8 + | beq ->fff_res + | mr CARG2, TMP2 + | bl extern lj_tab_getinth // (GCtab *t, int32_t key) + | // Returns cTValue * or NULL. + | cmplwi CRET1, 0 + | li RD, (0+1)*8 + | beq ->fff_res + | lwz TMP2, 0(CRET1) + |.if FPU + | lfd f0, 0(CRET1) + |.else + | lwz TMP3, 4(CRET1) + |.endif + | b <1 + | + |.ffunc_1 ipairs + | checktab CARG3 + | lwz PC, FRAME_PC(BASE) + | bne ->fff_fallback +#if LJ_52 + | lwz TAB:TMP2, TAB:CARG1->metatable + |.if FPU + | lfd f0, CFUNC:RB->upvalue[0] + |.else + | lwz TMP0, CFUNC:RB->upvalue[0].u32.hi + | lwz TMP1, CFUNC:RB->upvalue[0].u32.lo + |.endif + | cmplwi TAB:TMP2, 0 + | la RA, -8(BASE) + | bne ->fff_fallback +#else + |.if FPU + | lfd f0, CFUNC:RB->upvalue[0] + |.else + | lwz TMP0, CFUNC:RB->upvalue[0].u32.hi + | lwz TMP1, CFUNC:RB->upvalue[0].u32.lo + |.endif + | la RA, -8(BASE) +#endif + |.if DUALNUM + | stw TISNUM, 8(BASE) + |.else + | stw ZERO, 8(BASE) + |.endif + | stw ZERO, 12(BASE) + | li RD, (3+1)*8 + |.if FPU + | stfd f0, 0(RA) + |.else + | stw TMP0, 0(RA) + | stw TMP1, 4(RA) + |.endif + | b ->fff_res + | + |//-- Base library: catch errors ---------------------------------------- + | + |.ffunc pcall + | cmplwi NARGS8:RC, 8 + | lbz TMP3, DISPATCH_GL(hookmask)(DISPATCH) + | blt ->fff_fallback + | mr TMP2, BASE + | la BASE, 8(BASE) + | // Remember active hook before pcall. + | rlwinm TMP3, TMP3, 32-HOOK_ACTIVE_SHIFT, 31, 31 + | subi NARGS8:RC, NARGS8:RC, 8 + | addi PC, TMP3, 8+FRAME_PCALL + | b ->vm_call_dispatch + | + |.ffunc xpcall + | cmplwi NARGS8:RC, 16 + | lwz CARG3, 8(BASE) + |.if FPU + | lfd FARG2, 8(BASE) + | lfd FARG1, 0(BASE) + |.else + | lwz CARG1, 0(BASE) + | lwz CARG2, 4(BASE) + | lwz CARG4, 12(BASE) + |.endif + | blt ->fff_fallback + | lbz TMP1, DISPATCH_GL(hookmask)(DISPATCH) + | mr TMP2, BASE + | checkfunc CARG3; bne ->fff_fallback // Traceback must be a function. + | la BASE, 16(BASE) + | // Remember active hook before pcall. + | rlwinm TMP1, TMP1, 32-HOOK_ACTIVE_SHIFT, 31, 31 + |.if FPU + | stfd FARG2, 0(TMP2) // Swap function and traceback. + | stfd FARG1, 8(TMP2) + |.else + | stw CARG3, 0(TMP2) + | stw CARG4, 4(TMP2) + | stw CARG1, 8(TMP2) + | stw CARG2, 12(TMP2) + |.endif + | subi NARGS8:RC, NARGS8:RC, 16 + | addi PC, TMP1, 16+FRAME_PCALL + | b ->vm_call_dispatch + | + |//-- Coroutine library -------------------------------------------------- + | + |.macro coroutine_resume_wrap, resume + |.if resume + |.ffunc_1 coroutine_resume + | cmpwi CARG3, LJ_TTHREAD; bne ->fff_fallback + |.else + |.ffunc coroutine_wrap_aux + | lwz L:CARG1, CFUNC:RB->upvalue[0].gcr + |.endif + | lbz TMP0, L:CARG1->status + | lp TMP1, L:CARG1->cframe + | lp CARG2, L:CARG1->top + | cmplwi cr0, TMP0, LUA_YIELD + | lp TMP2, L:CARG1->base + | cmplwi cr1, TMP1, 0 + | lwz TMP0, L:CARG1->maxstack + | cmplw cr7, CARG2, TMP2 + | lwz PC, FRAME_PC(BASE) + | crorc 4*cr6+lt, 4*cr0+gt, 4*cr1+eq // st>LUA_YIELD || cframe!=0 + | add TMP2, CARG2, NARGS8:RC + | crandc 4*cr6+gt, 4*cr7+eq, 4*cr0+eq // base==top && st!=LUA_YIELD + | cmplw cr1, TMP2, TMP0 + | cror 4*cr6+lt, 4*cr6+lt, 4*cr6+gt + | stw PC, SAVE_PC + | cror 4*cr6+lt, 4*cr6+lt, 4*cr1+gt // cond1 || cond2 || stackov + | stp BASE, L->base + | blt cr6, ->fff_fallback + |1: + |.if resume + | addi BASE, BASE, 8 // Keep resumed thread in stack for GC. + | subi NARGS8:RC, NARGS8:RC, 8 + | subi TMP2, TMP2, 8 + |.endif + | stp TMP2, L:CARG1->top + | li TMP1, 0 + | stp BASE, L->top + |2: // Move args to coroutine. + | cmpw TMP1, NARGS8:RC + |.if FPU + | lfdx f0, BASE, TMP1 + |.else + | add CARG3, BASE, TMP1 + | lwz TMP2, 0(CARG3) + | lwz TMP3, 4(CARG3) + |.endif + | beq >3 + |.if FPU + | stfdx f0, CARG2, TMP1 + |.else + | add CARG3, CARG2, TMP1 + | stw TMP2, 0(CARG3) + | stw TMP3, 4(CARG3) + |.endif + | addi TMP1, TMP1, 8 + | b <2 + |3: + | li CARG3, 0 + | mr L:SAVE0, L:CARG1 + | li CARG4, 0 + | bl ->vm_resume // (lua_State *L, TValue *base, 0, 0) + | // Returns thread status. + |4: + | lp TMP2, L:SAVE0->base + | cmplwi CRET1, LUA_YIELD + | lp TMP3, L:SAVE0->top + | li_vmstate INTERP + | lp BASE, L->base + | stw L, DISPATCH_GL(cur_L)(DISPATCH) + | st_vmstate + | bgt >8 + | sub RD, TMP3, TMP2 + | lwz TMP0, L->maxstack + | cmplwi RD, 0 + | add TMP1, BASE, RD + | beq >6 // No results? + | cmplw TMP1, TMP0 + | li TMP1, 0 + | bgt >9 // Need to grow stack? + | + | subi TMP3, RD, 8 + | stp TMP2, L:SAVE0->top // Clear coroutine stack. + |5: // Move results from coroutine. + | cmplw TMP1, TMP3 + |.if FPU + | lfdx f0, TMP2, TMP1 + | stfdx f0, BASE, TMP1 + |.else + | add CARG3, TMP2, TMP1 + | lwz CARG1, 0(CARG3) + | lwz CARG2, 4(CARG3) + | add CARG3, BASE, TMP1 + | stw CARG1, 0(CARG3) + | stw CARG2, 4(CARG3) + |.endif + | addi TMP1, TMP1, 8 + | bne <5 + |6: + | andix. TMP0, PC, FRAME_TYPE + |.if resume + | li TMP1, LJ_TTRUE + | la RA, -8(BASE) + | stw TMP1, -8(BASE) // Prepend true to results. + | addi RD, RD, 16 + |.else + | mr RA, BASE + | addi RD, RD, 8 + |.endif + |7: + | stw PC, SAVE_PC + | mr MULTRES, RD + | beq ->BC_RET_Z + | b ->vm_return + | + |8: // Coroutine returned with error (at co->top-1). + |.if resume + | andix. TMP0, PC, FRAME_TYPE + | la TMP3, -8(TMP3) + | li TMP1, LJ_TFALSE + |.if FPU + | lfd f0, 0(TMP3) + |.else + | lwz CARG1, 0(TMP3) + | lwz CARG2, 4(TMP3) + |.endif + | stp TMP3, L:SAVE0->top // Remove error from coroutine stack. + | li RD, (2+1)*8 + | stw TMP1, -8(BASE) // Prepend false to results. + | la RA, -8(BASE) + |.if FPU + | stfd f0, 0(BASE) // Copy error message. + |.else + | stw CARG1, 0(BASE) // Copy error message. + | stw CARG2, 4(BASE) + |.endif + | b <7 + |.else + | mr CARG1, L + | mr CARG2, L:SAVE0 + | bl extern lj_ffh_coroutine_wrap_err // (lua_State *L, lua_State *co) + |.endif + | + |9: // Handle stack expansion on return from yield. + | mr CARG1, L + | srwi CARG2, RD, 3 + | bl extern lj_state_growstack // (lua_State *L, int n) + | li CRET1, 0 + | b <4 + |.endmacro + | + | coroutine_resume_wrap 1 // coroutine.resume + | coroutine_resume_wrap 0 // coroutine.wrap + | + |.ffunc coroutine_yield + | lp TMP0, L->cframe + | add TMP1, BASE, NARGS8:RC + | stp BASE, L->base + | andix. TMP0, TMP0, CFRAME_RESUME + | stp TMP1, L->top + | li CRET1, LUA_YIELD + | beq ->fff_fallback + | stp ZERO, L->cframe + | stb CRET1, L->status + | b ->vm_leave_unw + | + |//-- Math library ------------------------------------------------------- + | + |.ffunc_1 math_abs + | checknum CARG3 + |.if DUALNUM + | bne >2 + | srawi TMP1, CARG1, 31 + | xor TMP2, TMP1, CARG1 + |.if GPR64 + | lus TMP0, 0x8000 + | sub CARG1, TMP2, TMP1 + | cmplw CARG1, TMP0 + | beq >1 + |.else + | sub. CARG1, TMP2, TMP1 + | blt >1 + |.endif + |->fff_resi: + | lwz PC, FRAME_PC(BASE) + | la RA, -8(BASE) + | stw TISNUM, -8(BASE) + | stw CRET1, -4(BASE) + | b ->fff_res1 + |1: + | lus CARG3, 0x41e0 // 2^31. + | li CARG1, 0 + | b ->fff_restv + |2: + |.endif + | bge ->fff_fallback + | rlwinm CARG3, CARG3, 0, 1, 31 + | // Fallthrough. + | + |->fff_restv: + | // CARG3/CARG1 = TValue result. + | lwz PC, FRAME_PC(BASE) + | stw CARG3, -8(BASE) + | la RA, -8(BASE) + | stw CARG1, -4(BASE) + |->fff_res1: + | // RA = results, PC = return. + | li RD, (1+1)*8 + |->fff_res: + | // RA = results, RD = (nresults+1)*8, PC = return. + | andix. TMP0, PC, FRAME_TYPE + | mr MULTRES, RD + | bney ->vm_return + | lwz INS, -4(PC) + | decode_RB8 RB, INS + |5: + | cmplw RB, RD // More results expected? + | decode_RA8 TMP0, INS + | bgt >6 + | ins_next1 + | // Adjust BASE. KBASE is assumed to be set for the calling frame. + | sub BASE, RA, TMP0 + | ins_next2 + | + |6: // Fill up results with nil. + | subi TMP1, RD, 8 + | addi RD, RD, 8 + | stwx TISNIL, RA, TMP1 + | b <5 + | + |.macro math_extern, func + | .ffunc_n math_ .. func + | blex func + | b ->fff_resn + |.endmacro + | + |.macro math_extern2, func + | .ffunc_nn math_ .. func + | blex func + | b ->fff_resn + |.endmacro + | + |.macro math_round, func + | .ffunc_1 math_ .. func + | checknum CARG3; beqy ->fff_restv + | rlwinm TMP2, CARG3, 12, 21, 31 + | bge ->fff_fallback + | addic. TMP2, TMP2, -1023 // exp = exponent(x) - 1023 + | cmplwi cr1, TMP2, 31 // 0 <= exp < 31? + | subfic TMP0, TMP2, 31 + | blt >3 + | slwi TMP1, CARG3, 11 + | srwi TMP3, CARG1, 21 + | oris TMP1, TMP1, 0x8000 + | addi TMP2, TMP2, 1 + | or TMP1, TMP1, TMP3 + | slwi CARG2, CARG1, 11 + | bge cr1, >4 + | slw TMP3, TMP1, TMP2 + | srw RD, TMP1, TMP0 + | or TMP3, TMP3, CARG2 + | srawi TMP2, CARG3, 31 + |.if "func" == "floor" + | and TMP1, TMP3, TMP2 + | addic TMP0, TMP1, -1 + | subfe TMP1, TMP0, TMP1 + | add CARG1, RD, TMP1 + | xor CARG1, CARG1, TMP2 + | sub CARG1, CARG1, TMP2 + | b ->fff_resi + |.else + | andc TMP1, TMP3, TMP2 + | addic TMP0, TMP1, -1 + | subfe TMP1, TMP0, TMP1 + | add CARG1, RD, TMP1 + | cmpw CARG1, RD + | xor CARG1, CARG1, TMP2 + | sub CARG1, CARG1, TMP2 + | bge ->fff_resi + | // Overflow to 2^31. + | lus CARG3, 0x41e0 // 2^31. + | li CARG1, 0 + | b ->fff_restv + |.endif + |3: // |x| < 1 + | slwi TMP2, CARG3, 1 + | srawi TMP1, CARG3, 31 + | or TMP2, CARG1, TMP2 // ztest = (hi+hi) | lo + |.if "func" == "floor" + | and TMP1, TMP2, TMP1 // (ztest & sign) == 0 ? 0 : -1 + | subfic TMP2, TMP1, 0 + | subfe CARG1, CARG1, CARG1 + |.else + | andc TMP1, TMP2, TMP1 // (ztest & ~sign) == 0 ? 0 : 1 + | addic TMP2, TMP1, -1 + | subfe CARG1, TMP2, TMP1 + |.endif + | b ->fff_resi + |4: // exp >= 31. Check for -(2^31). + | xoris TMP1, TMP1, 0x8000 + | srawi TMP2, CARG3, 31 + |.if "func" == "floor" + | or TMP1, TMP1, CARG2 + |.endif + |.if PPE + | orc TMP1, TMP1, TMP2 + | cmpwi TMP1, 0 + |.else + | orc. TMP1, TMP1, TMP2 + |.endif + | crand 4*cr0+eq, 4*cr0+eq, 4*cr1+eq + | lus CARG1, 0x8000 // -(2^31). + | beqy ->fff_resi + |5: + |.if FPU + | lfd FARG1, 0(BASE) + |.else + | lwz CARG1, 0(BASE) + | lwz CARG2, 4(BASE) + |.endif + | blex func + | b ->fff_resn + |.endmacro + | + |.if DUALNUM + | math_round floor + | math_round ceil + |.else + | // NYI: use internal implementation. + | math_extern floor + | math_extern ceil + |.endif + | + |.if SQRT + |.ffunc_n math_sqrt + | fsqrt FARG1, FARG1 + | b ->fff_resn + |.else + | math_extern sqrt + |.endif + | + |.ffunc math_log + | cmplwi NARGS8:RC, 8 + | lwz CARG1, 0(BASE) + | bne ->fff_fallback // Need exactly 1 argument. + | checknum CARG1; bge ->fff_fallback + |.if FPU + | lfd FARG1, 0(BASE) + |.else + | lwz CARG2, 4(BASE) + |.endif + | blex log + | b ->fff_resn + | + | math_extern log10 + | math_extern exp + | math_extern sin + | math_extern cos + | math_extern tan + | math_extern asin + | math_extern acos + | math_extern atan + | math_extern sinh + | math_extern cosh + | math_extern tanh + | math_extern2 pow + | math_extern2 atan2 + | math_extern2 fmod + | + |.if DUALNUM + |.ffunc math_ldexp + | cmplwi NARGS8:RC, 16 + | lwz TMP0, 0(BASE) + |.if FPU + | lfd FARG1, 0(BASE) + |.else + | lwz CARG1, 0(BASE) + | lwz CARG2, 4(BASE) + |.endif + | lwz TMP1, 8(BASE) + |.if GPR64 + | lwz CARG2, 12(BASE) + |.elif FPU + | lwz CARG1, 12(BASE) + |.else + | lwz CARG3, 12(BASE) + |.endif + | blt ->fff_fallback + | checknum TMP0; bge ->fff_fallback + | checknum TMP1; bne ->fff_fallback + |.else + |.ffunc_nn math_ldexp + |.if GPR64 + | toint CARG2, FARG2 + |.else + | toint CARG1, FARG2 + |.endif + |.endif + | blex ldexp + | b ->fff_resn + | + |.ffunc_n math_frexp + |.if GPR64 + | la CARG2, DISPATCH_GL(tmptv)(DISPATCH) + |.elif FPU + | la CARG1, DISPATCH_GL(tmptv)(DISPATCH) + |.else + | la CARG3, DISPATCH_GL(tmptv)(DISPATCH) + |.endif + | lwz PC, FRAME_PC(BASE) + | blex frexp + | lwz TMP1, DISPATCH_GL(tmptv)(DISPATCH) + | la RA, -8(BASE) + |.if not DUALNUM + | tonum_i FARG2, TMP1 + |.endif + |.if FPU + | stfd FARG1, 0(RA) + |.else + | stw CRET1, 0(RA) + | stw CRET2, 4(RA) + |.endif + | li RD, (2+1)*8 + |.if DUALNUM + | stw TISNUM, 8(RA) + | stw TMP1, 12(RA) + |.else + | stfd FARG2, 8(RA) + |.endif + | b ->fff_res + | + |.ffunc_n math_modf + |.if GPR64 + | la CARG2, -8(BASE) + |.elif FPU + | la CARG1, -8(BASE) + |.else + | la CARG3, -8(BASE) + |.endif + | lwz PC, FRAME_PC(BASE) + | blex modf + | la RA, -8(BASE) + |.if FPU + | stfd FARG1, 0(BASE) + |.else + | stw CRET1, 0(BASE) + | stw CRET2, 4(BASE) + |.endif + | li RD, (2+1)*8 + | b ->fff_res + | + |.macro math_minmax, name, ismax + |.if DUALNUM + | .ffunc_1 name + | checknum CARG3 + | addi SAVE0, BASE, 8 + | add SAVE1, BASE, NARGS8:RC + | bne >4 + |1: // Handle integers. + | lwz CARG4, 0(SAVE0) + | cmplw cr1, SAVE0, SAVE1 + | lwz CARG2, 4(SAVE0) + | bge cr1, ->fff_resi + | checknum CARG4 + | xoris TMP0, CARG1, 0x8000 + | xoris TMP3, CARG2, 0x8000 + | bne >3 + | subfc TMP3, TMP3, TMP0 + | subfe TMP0, TMP0, TMP0 + |.if ismax + | andc TMP3, TMP3, TMP0 + |.else + | and TMP3, TMP3, TMP0 + |.endif + | add CARG1, TMP3, CARG2 + |.if GPR64 + | rldicl CARG1, CARG1, 0, 32 + |.endif + | addi SAVE0, SAVE0, 8 + | b <1 + |3: + | bge ->fff_fallback + | // Convert intermediate result to number and continue below. + |.if FPU + | tonum_i FARG1, CARG1 + | lfd FARG2, 0(SAVE0) + |.else + | mr CARG2, CARG1 + | bl ->vm_sfi2d_1 + | lwz CARG3, 0(SAVE0) + | lwz CARG4, 4(SAVE0) + |.endif + | b >6 + |4: + |.if FPU + | lfd FARG1, 0(BASE) + |.else + | lwz CARG1, 0(BASE) + | lwz CARG2, 4(BASE) + |.endif + | bge ->fff_fallback + |5: // Handle numbers. + | lwz CARG3, 0(SAVE0) + | cmplw cr1, SAVE0, SAVE1 + |.if FPU + | lfd FARG2, 0(SAVE0) + |.else + | lwz CARG4, 4(SAVE0) + |.endif + | bge cr1, ->fff_resn + | checknum CARG3; bge >7 + |6: + | addi SAVE0, SAVE0, 8 + |.if FPU + |.if ismax + | fsub f0, FARG1, FARG2 + |.else + | fsub f0, FARG2, FARG1 + |.endif + | fsel FARG1, f0, FARG1, FARG2 + |.else + | stw CARG1, SFSAVE_1 + | stw CARG2, SFSAVE_2 + | stw CARG3, SFSAVE_3 + | stw CARG4, SFSAVE_4 + | blex __ledf2 + | cmpwi CRET1, 0 + |.if ismax + | blt >8 + |.else + | bge >8 + |.endif + | lwz CARG1, SFSAVE_1 + | lwz CARG2, SFSAVE_2 + | b <5 + |8: + | lwz CARG1, SFSAVE_3 + | lwz CARG2, SFSAVE_4 + |.endif + | b <5 + |7: // Convert integer to number and continue above. + | lwz CARG3, 4(SAVE0) + | bne ->fff_fallback + |.if FPU + | tonum_i FARG2, CARG3 + |.else + | bl ->vm_sfi2d_2 + |.endif + | b <6 + |.else + | .ffunc_n name + | li TMP1, 8 + |1: + | lwzx CARG2, BASE, TMP1 + | lfdx FARG2, BASE, TMP1 + | cmplw cr1, TMP1, NARGS8:RC + | checknum CARG2 + | bge cr1, ->fff_resn + | bge ->fff_fallback + |.if ismax + | fsub f0, FARG1, FARG2 + |.else + | fsub f0, FARG2, FARG1 + |.endif + | addi TMP1, TMP1, 8 + | fsel FARG1, f0, FARG1, FARG2 + | b <1 + |.endif + |.endmacro + | + | math_minmax math_min, 0 + | math_minmax math_max, 1 + | + |//-- String library ----------------------------------------------------- + | + |.ffunc string_byte // Only handle the 1-arg case here. + | cmplwi NARGS8:RC, 8 + | lwz CARG3, 0(BASE) + | lwz STR:CARG1, 4(BASE) + | bne ->fff_fallback // Need exactly 1 argument. + | checkstr CARG3 + | bne ->fff_fallback + | lwz TMP0, STR:CARG1->len + |.if DUALNUM + | lbz CARG1, STR:CARG1[1] // Access is always ok (NUL at end). + | li RD, (0+1)*8 + | lwz PC, FRAME_PC(BASE) + | cmplwi TMP0, 0 + | la RA, -8(BASE) + | beqy ->fff_res + | b ->fff_resi + |.else + | lbz TMP1, STR:CARG1[1] // Access is always ok (NUL at end). + | addic TMP3, TMP0, -1 // RD = ((str->len != 0)+1)*8 + | subfe RD, TMP3, TMP0 + | stw TMP1, TONUM_LO // Inlined tonum_u f0, TMP1. + | addi RD, RD, 1 + | lfd f0, TONUM_D + | la RA, -8(BASE) + | lwz PC, FRAME_PC(BASE) + | fsub f0, f0, TOBIT + | slwi RD, RD, 3 + | stfd f0, 0(RA) + | b ->fff_res + |.endif + | + |.ffunc string_char // Only handle the 1-arg case here. + | ffgccheck + | cmplwi NARGS8:RC, 8 + | lwz CARG3, 0(BASE) + |.if DUALNUM + | lwz TMP0, 4(BASE) + | bne ->fff_fallback // Exactly 1 argument. + | checknum CARG3; bne ->fff_fallback + | la CARG2, 7(BASE) + |.else + | lfd FARG1, 0(BASE) + | bne ->fff_fallback // Exactly 1 argument. + | checknum CARG3; bge ->fff_fallback + | toint TMP0, FARG1 + | la CARG2, TMPD_BLO + |.endif + | li CARG3, 1 + | cmplwi TMP0, 255; bgt ->fff_fallback + |->fff_newstr: + | mr CARG1, L + | stp BASE, L->base + | stw PC, SAVE_PC + | bl extern lj_str_new // (lua_State *L, char *str, size_t l) + |->fff_resstr: + | // Returns GCstr *. + | lp BASE, L->base + | li CARG3, LJ_TSTR + | b ->fff_restv + | + |.ffunc string_sub + | ffgccheck + | cmplwi NARGS8:RC, 16 + | lwz CARG3, 16(BASE) + |.if not DUALNUM + | lfd f0, 16(BASE) + |.endif + | lwz TMP0, 0(BASE) + | lwz STR:CARG1, 4(BASE) + | blt ->fff_fallback + | lwz CARG2, 8(BASE) + |.if DUALNUM + | lwz TMP1, 12(BASE) + |.else + | lfd f1, 8(BASE) + |.endif + | li TMP2, -1 + | beq >1 + |.if DUALNUM + | checknum CARG3 + | lwz TMP2, 20(BASE) + | bne ->fff_fallback + |1: + | checknum CARG2; bne ->fff_fallback + |.else + | checknum CARG3; bge ->fff_fallback + | toint TMP2, f0 + |1: + | checknum CARG2; bge ->fff_fallback + |.endif + | checkstr TMP0; bne ->fff_fallback + |.if not DUALNUM + | toint TMP1, f1 + |.endif + | lwz TMP0, STR:CARG1->len + | cmplw TMP0, TMP2 // len < end? (unsigned compare) + | addi TMP3, TMP2, 1 + | blt >5 + |2: + | cmpwi TMP1, 0 // start <= 0? + | add TMP3, TMP1, TMP0 + | ble >7 + |3: + | sub CARG3, TMP2, TMP1 + | addi CARG2, STR:CARG1, #STR-1 + | srawi TMP0, CARG3, 31 + | addi CARG3, CARG3, 1 + | add CARG2, CARG2, TMP1 + | andc CARG3, CARG3, TMP0 + |.if GPR64 + | rldicl CARG2, CARG2, 0, 32 + | rldicl CARG3, CARG3, 0, 32 + |.endif + | b ->fff_newstr + | + |5: // Negative end or overflow. + | cmpw TMP0, TMP2 // len >= end? (signed compare) + | add TMP2, TMP0, TMP3 // Negative end: end = end+len+1. + | bge <2 + | mr TMP2, TMP0 // Overflow: end = len. + | b <2 + | + |7: // Negative start or underflow. + | .gpr64 extsw TMP1, TMP1 + | addic CARG3, TMP1, -1 + | subfe CARG3, CARG3, CARG3 + | srawi CARG2, TMP3, 31 // Note: modifies carry. + | andc TMP3, TMP3, CARG3 + | andc TMP1, TMP3, CARG2 + | addi TMP1, TMP1, 1 // start = 1 + (start ? start+len : 0) + | b <3 + | + |.macro ffstring_op, name + | .ffunc string_ .. name + | ffgccheck + | cmplwi NARGS8:RC, 8 + | lwz CARG3, 0(BASE) + | lwz STR:CARG2, 4(BASE) + | blt ->fff_fallback + | checkstr CARG3 + | la SBUF:CARG1, DISPATCH_GL(tmpbuf)(DISPATCH) + | bne ->fff_fallback + | lwz TMP0, SBUF:CARG1->b + | stw L, SBUF:CARG1->L + | stp BASE, L->base + | stw PC, SAVE_PC + | stw TMP0, SBUF:CARG1->w + | bl extern lj_buf_putstr_ .. name + | bl extern lj_buf_tostr + | b ->fff_resstr + |.endmacro + | + |ffstring_op reverse + |ffstring_op lower + |ffstring_op upper + | + |//-- Bit library -------------------------------------------------------- + | + |.macro .ffunc_bit, name + |.if DUALNUM + | .ffunc_1 bit_..name + | checknum CARG3; bnel ->fff_tobit_fb + |.else + | .ffunc_n bit_..name + | fadd FARG1, FARG1, TOBIT + | stfd FARG1, TMPD + | lwz CARG1, TMPD_LO + |.endif + |.endmacro + | + |.macro .ffunc_bit_op, name, ins + | .ffunc_bit name + | addi SAVE0, BASE, 8 + | add SAVE1, BASE, NARGS8:RC + |1: + | lwz CARG4, 0(SAVE0) + | cmplw cr1, SAVE0, SAVE1 + |.if DUALNUM + | lwz CARG2, 4(SAVE0) + |.else + | lfd FARG1, 0(SAVE0) + |.endif + | bgey cr1, ->fff_resi + | checknum CARG4 + |.if DUALNUM + |.if FPU + | bnel ->fff_bitop_fb + |.else + | beq >3 + | stw CARG1, SFSAVE_1 + | bl ->fff_bitop_fb + | mr CARG2, CARG1 + | lwz CARG1, SFSAVE_1 + |3: + |.endif + |.else + | fadd FARG1, FARG1, TOBIT + | bge ->fff_fallback + | stfd FARG1, TMPD + | lwz CARG2, TMPD_LO + |.endif + | ins CARG1, CARG1, CARG2 + | addi SAVE0, SAVE0, 8 + | b <1 + |.endmacro + | + |.ffunc_bit_op band, and + |.ffunc_bit_op bor, or + |.ffunc_bit_op bxor, xor + | + |.ffunc_bit bswap + | rotlwi TMP0, CARG1, 8 + | rlwimi TMP0, CARG1, 24, 0, 7 + | rlwimi TMP0, CARG1, 24, 16, 23 + | mr CRET1, TMP0 + | b ->fff_resi + | + |.ffunc_bit bnot + | not CRET1, CARG1 + | b ->fff_resi + | + |.macro .ffunc_bit_sh, name, ins, shmod + |.if DUALNUM + | .ffunc_2 bit_..name + |.if FPU + | checknum CARG3; bnel ->fff_tobit_fb + |.else + | checknum CARG3; beq >1 + | bl ->fff_tobit_fb + | lwz CARG2, 12(BASE) // Conversion polluted CARG2. + |1: + |.endif + | // Note: no inline conversion from number for 2nd argument! + | checknum CARG4; bne ->fff_fallback + |.else + | .ffunc_nn bit_..name + | fadd FARG1, FARG1, TOBIT + | fadd FARG2, FARG2, TOBIT + | stfd FARG1, TMPD + | lwz CARG1, TMPD_LO + | stfd FARG2, TMPD + | lwz CARG2, TMPD_LO + |.endif + |.if shmod == 1 + | rlwinm CARG2, CARG2, 0, 27, 31 + |.elif shmod == 2 + | neg CARG2, CARG2 + |.endif + | ins CRET1, CARG1, CARG2 + | b ->fff_resi + |.endmacro + | + |.ffunc_bit_sh lshift, slw, 1 + |.ffunc_bit_sh rshift, srw, 1 + |.ffunc_bit_sh arshift, sraw, 1 + |.ffunc_bit_sh rol, rotlw, 0 + |.ffunc_bit_sh ror, rotlw, 2 + | + |.ffunc_bit tobit + |.if DUALNUM + | b ->fff_resi + |.else + |->fff_resi: + | tonum_i FARG1, CRET1 + |.endif + |->fff_resn: + | lwz PC, FRAME_PC(BASE) + | la RA, -8(BASE) + |.if FPU + | stfd FARG1, -8(BASE) + |.else + | stw CARG1, -8(BASE) + | stw CARG2, -4(BASE) + |.endif + | b ->fff_res1 + | + |// Fallback FP number to bit conversion. + |->fff_tobit_fb: + |.if DUALNUM + |.if FPU + | lfd FARG1, 0(BASE) + | bgt ->fff_fallback + | fadd FARG1, FARG1, TOBIT + | stfd FARG1, TMPD + | lwz CARG1, TMPD_LO + | blr + |.else + | bgt ->fff_fallback + | mr CARG2, CARG1 + | mr CARG1, CARG3 + |// Modifies: CARG1, CARG2, TMP0, TMP1, TMP2. + |->vm_tobit: + | slwi TMP2, CARG1, 1 + | addis TMP2, TMP2, 0x0020 + | cmpwi TMP2, 0 + | bge >2 + | li TMP1, 0x3e0 + | srawi TMP2, TMP2, 21 + | not TMP1, TMP1 + | sub. TMP2, TMP1, TMP2 + | cmpwi cr7, CARG1, 0 + | blt >1 + | slwi TMP1, CARG1, 11 + | srwi TMP0, CARG2, 21 + | oris TMP1, TMP1, 0x8000 + | or TMP1, TMP1, TMP0 + | srw CARG1, TMP1, TMP2 + | bclr 4, 28 // Return if cr7[lt] == 0, no hint. + | neg CARG1, CARG1 + | blr + |1: + | addi TMP2, TMP2, 21 + | srw TMP1, CARG2, TMP2 + | slwi CARG2, CARG1, 12 + | subfic TMP2, TMP2, 20 + | slw TMP0, CARG2, TMP2 + | or CARG1, TMP1, TMP0 + | bclr 4, 28 // Return if cr7[lt] == 0, no hint. + | neg CARG1, CARG1 + | blr + |2: + | li CARG1, 0 + | blr + |.endif + |.endif + |->fff_bitop_fb: + |.if DUALNUM + |.if FPU + | lfd FARG1, 0(SAVE0) + | bgt ->fff_fallback + | fadd FARG1, FARG1, TOBIT + | stfd FARG1, TMPD + | lwz CARG2, TMPD_LO + | blr + |.else + | bgt ->fff_fallback + | mr CARG1, CARG4 + | b ->vm_tobit + |.endif + |.endif + | + |//----------------------------------------------------------------------- + | + |->fff_fallback: // Call fast function fallback handler. + | // BASE = new base, RB = CFUNC, RC = nargs*8 + | lp TMP3, CFUNC:RB->f + | add TMP1, BASE, NARGS8:RC + | lwz PC, FRAME_PC(BASE) // Fallback may overwrite PC. + | addi TMP0, TMP1, 8*LUA_MINSTACK + | lwz TMP2, L->maxstack + | stw PC, SAVE_PC // Redundant (but a defined value). + | .toc lp TMP3, 0(TMP3) + | cmplw TMP0, TMP2 + | stp BASE, L->base + | stp TMP1, L->top + | mr CARG1, L + | bgt >5 // Need to grow stack. + | mtctr TMP3 + | bctrl // (lua_State *L) + | // Either throws an error, or recovers and returns -1, 0 or nresults+1. + | lp BASE, L->base + | cmpwi CRET1, 0 + | slwi RD, CRET1, 3 + | la RA, -8(BASE) + | bgt ->fff_res // Returned nresults+1? + |1: // Returned 0 or -1: retry fast path. + | lp TMP0, L->top + | lwz LFUNC:RB, FRAME_FUNC(BASE) + | sub NARGS8:RC, TMP0, BASE + | bne ->vm_call_tail // Returned -1? + | ins_callt // Returned 0: retry fast path. + | + |// Reconstruct previous base for vmeta_call during tailcall. + |->vm_call_tail: + | andix. TMP0, PC, FRAME_TYPE + | rlwinm TMP1, PC, 0, 0, 28 + | bne >3 + | lwz INS, -4(PC) + | decode_RA8 TMP1, INS + | addi TMP1, TMP1, 8 + |3: + | sub TMP2, BASE, TMP1 + | b ->vm_call_dispatch // Resolve again for tailcall. + | + |5: // Grow stack for fallback handler. + | li CARG2, LUA_MINSTACK + | bl extern lj_state_growstack // (lua_State *L, int n) + | lp BASE, L->base + | cmpw TMP0, TMP0 // Set 4*cr0+eq to force retry. + | b <1 + | + |->fff_gcstep: // Call GC step function. + | // BASE = new base, RC = nargs*8 + | mflr SAVE0 + | stp BASE, L->base + | add TMP0, BASE, NARGS8:RC + | stw PC, SAVE_PC // Redundant (but a defined value). + | stp TMP0, L->top + | mr CARG1, L + | bl extern lj_gc_step // (lua_State *L) + | lp BASE, L->base + | mtlr SAVE0 + | lp TMP0, L->top + | sub NARGS8:RC, TMP0, BASE + | lwz CFUNC:RB, FRAME_FUNC(BASE) + | blr + | + |//----------------------------------------------------------------------- + |//-- Special dispatch targets ------------------------------------------- + |//----------------------------------------------------------------------- + | + |->vm_record: // Dispatch target for recording phase. + |.if JIT + | lbz TMP3, DISPATCH_GL(hookmask)(DISPATCH) + | andix. TMP0, TMP3, HOOK_VMEVENT // No recording while in vmevent. + | bne >5 + | // Decrement the hookcount for consistency, but always do the call. + | lwz TMP2, DISPATCH_GL(hookcount)(DISPATCH) + | andix. TMP0, TMP3, HOOK_ACTIVE + | bne >1 + | subi TMP2, TMP2, 1 + | andi. TMP0, TMP3, LUA_MASKLINE|LUA_MASKCOUNT + | beqy >1 + | stw TMP2, DISPATCH_GL(hookcount)(DISPATCH) + | b >1 + |.endif + | + |->vm_rethook: // Dispatch target for return hooks. + | lbz TMP3, DISPATCH_GL(hookmask)(DISPATCH) + | andix. TMP0, TMP3, HOOK_ACTIVE // Hook already active? + | beq >1 + |5: // Re-dispatch to static ins. + | addi TMP1, TMP1, GG_DISP2STATIC // Assumes decode_OPP TMP1, INS. + | lpx TMP0, DISPATCH, TMP1 + | mtctr TMP0 + | bctr + | + |->vm_inshook: // Dispatch target for instr/line hooks. + | lbz TMP3, DISPATCH_GL(hookmask)(DISPATCH) + | lwz TMP2, DISPATCH_GL(hookcount)(DISPATCH) + | andix. TMP0, TMP3, HOOK_ACTIVE // Hook already active? + | rlwinm TMP0, TMP3, 31-LUA_HOOKLINE, 31, 0 + | bne <5 + | + | cmpwi cr1, TMP0, 0 + | addic. TMP2, TMP2, -1 + | beq cr1, <5 + | stw TMP2, DISPATCH_GL(hookcount)(DISPATCH) + | beq >1 + | bge cr1, <5 + |1: + | mr CARG1, L + | stw MULTRES, SAVE_MULTRES + | mr CARG2, PC + | stp BASE, L->base + | // SAVE_PC must hold the _previous_ PC. The callee updates it with PC. + | bl extern lj_dispatch_ins // (lua_State *L, const BCIns *pc) + |3: + | lp BASE, L->base + |4: // Re-dispatch to static ins. + | lwz INS, -4(PC) + | decode_OPP TMP1, INS + | decode_RB8 RB, INS + | addi TMP1, TMP1, GG_DISP2STATIC + | decode_RD8 RD, INS + | lpx TMP0, DISPATCH, TMP1 + | decode_RA8 RA, INS + | decode_RC8 RC, INS + | mtctr TMP0 + | bctr + | + |->cont_hook: // Continue from hook yield. + | addi PC, PC, 4 + | lwz MULTRES, -20(RB) // Restore MULTRES for *M ins. + | b <4 + | + |->vm_hotloop: // Hot loop counter underflow. + |.if JIT + | lwz LFUNC:TMP1, FRAME_FUNC(BASE) + | addi CARG1, DISPATCH, GG_DISP2J + | stw PC, SAVE_PC + | lwz TMP1, LFUNC:TMP1->pc + | mr CARG2, PC + | stw L, DISPATCH_J(L)(DISPATCH) + | lbz TMP1, PC2PROTO(framesize)(TMP1) + | stp BASE, L->base + | slwi TMP1, TMP1, 3 + | add TMP1, BASE, TMP1 + | stp TMP1, L->top + | bl extern lj_trace_hot // (jit_State *J, const BCIns *pc) + | b <3 + |.endif + | + |->vm_callhook: // Dispatch target for call hooks. + | mr CARG2, PC + |.if JIT + | b >1 + |.endif + | + |->vm_hotcall: // Hot call counter underflow. + |.if JIT + | ori CARG2, PC, 1 + |1: + |.endif + | add TMP0, BASE, RC + | stw PC, SAVE_PC + | mr CARG1, L + | stp BASE, L->base + | sub RA, RA, BASE + | stp TMP0, L->top + | bl extern lj_dispatch_call // (lua_State *L, const BCIns *pc) + | // Returns ASMFunction. + | lp BASE, L->base + | lp TMP0, L->top + | stw ZERO, SAVE_PC // Invalidate for subsequent line hook. + | sub NARGS8:RC, TMP0, BASE + | add RA, BASE, RA + | lwz LFUNC:RB, FRAME_FUNC(BASE) + | lwz INS, -4(PC) + | mtctr CRET1 + | bctr + | + |->cont_stitch: // Trace stitching. + |.if JIT + | // RA = resultptr, RB = meta base + | lwz INS, -4(PC) + | lwz TRACE:TMP2, -20(RB) // Save previous trace. + | addic. TMP1, MULTRES, -8 + | decode_RA8 RC, INS // Call base. + | beq >2 + |1: // Move results down. + |.if FPU + | lfd f0, 0(RA) + |.else + | lwz CARG1, 0(RA) + | lwz CARG2, 4(RA) + |.endif + | addic. TMP1, TMP1, -8 + | addi RA, RA, 8 + |.if FPU + | stfdx f0, BASE, RC + |.else + | add CARG3, BASE, RC + | stw CARG1, 0(CARG3) + | stw CARG2, 4(CARG3) + |.endif + | addi RC, RC, 8 + | bne <1 + |2: + | decode_RA8 RA, INS + | decode_RB8 RB, INS + | add RA, RA, RB + |3: + | cmplw RA, RC + | bgt >9 // More results wanted? + | + | lhz TMP3, TRACE:TMP2->traceno + | lhz RD, TRACE:TMP2->link + | cmpw RD, TMP3 + | cmpwi cr1, RD, 0 + | beq ->cont_nop // Blacklisted. + | slwi RD, RD, 3 + | bne cr1, =>BC_JLOOP // Jump to stitched trace. + | + | // Stitch a new trace to the previous trace. + | stw TMP3, DISPATCH_J(exitno)(DISPATCH) + | stp L, DISPATCH_J(L)(DISPATCH) + | stp BASE, L->base + | addi CARG1, DISPATCH, GG_DISP2J + | mr CARG2, PC + | bl extern lj_dispatch_stitch // (jit_State *J, const BCIns *pc) + | lp BASE, L->base + | b ->cont_nop + | + |9: + | stwx TISNIL, BASE, RC + | addi RC, RC, 8 + | b <3 + |.endif + | + |->vm_profhook: // Dispatch target for profiler hook. +#if LJ_HASPROFILE + | mr CARG1, L + | stw MULTRES, SAVE_MULTRES + | mr CARG2, PC + | stp BASE, L->base + | bl extern lj_dispatch_profile // (lua_State *L, const BCIns *pc) + | // HOOK_PROFILE is off again, so re-dispatch to dynamic instruction. + | lp BASE, L->base + | subi PC, PC, 4 + | b ->cont_nop +#endif + | + |//----------------------------------------------------------------------- + |//-- Trace exit handler ------------------------------------------------- + |//----------------------------------------------------------------------- + | + |.macro savex_, a, b, c, d + |.if FPU + | stfd f..a, 16+a*8(sp) + | stfd f..b, 16+b*8(sp) + | stfd f..c, 16+c*8(sp) + | stfd f..d, 16+d*8(sp) + |.endif + |.endmacro + | + |->vm_exit_handler: + |.if JIT + | addi sp, sp, -(16+32*8+32*4) + | stmw r2, 16+32*8+2*4(sp) + | addi DISPATCH, JGL, -GG_DISP2G-32768 + | li CARG2, ~LJ_VMST_EXIT + | lwz CARG1, 16+32*8+32*4(sp) // Get stack chain. + | stw CARG2, DISPATCH_GL(vmstate)(DISPATCH) + | savex_ 0,1,2,3 + | stw CARG1, 0(sp) // Store extended stack chain. + | clrso TMP1 + | savex_ 4,5,6,7 + | addi CARG2, sp, 16+32*8+32*4 // Recompute original value of sp. + | savex_ 8,9,10,11 + | stw CARG2, 16+32*8+1*4(sp) // Store sp in RID_SP. + | savex_ 12,13,14,15 + | mflr CARG3 + | li TMP1, 0 + | savex_ 16,17,18,19 + | stw TMP1, 16+32*8+0*4(sp) // Clear RID_TMP. + | savex_ 20,21,22,23 + | lhz CARG4, 2(CARG3) // Load trace number. + | savex_ 24,25,26,27 + | lwz L, DISPATCH_GL(cur_L)(DISPATCH) + | savex_ 28,29,30,31 + | sub CARG3, TMP0, CARG3 // Compute exit number. + | lp BASE, DISPATCH_GL(jit_base)(DISPATCH) + | srwi CARG3, CARG3, 2 + | stp L, DISPATCH_J(L)(DISPATCH) + | subi CARG3, CARG3, 2 + | stp BASE, L->base + | stw CARG4, DISPATCH_J(parent)(DISPATCH) + | stw TMP1, DISPATCH_GL(jit_base)(DISPATCH) + | addi CARG1, DISPATCH, GG_DISP2J + | stw CARG3, DISPATCH_J(exitno)(DISPATCH) + | addi CARG2, sp, 16 + | bl extern lj_trace_exit // (jit_State *J, ExitState *ex) + | // Returns MULTRES (unscaled) or negated error code. + | lp TMP1, L->cframe + | lwz TMP2, 0(sp) + | lp BASE, L->base + |.if GPR64 + | rldicr sp, TMP1, 0, 61 + |.else + | rlwinm sp, TMP1, 0, 0, 29 + |.endif + | lwz PC, SAVE_PC // Get SAVE_PC. + | stw TMP2, 0(sp) + | stw L, SAVE_L // Set SAVE_L (on-trace resume/yield). + | b >1 + |.endif + |->vm_exit_interp: + |.if JIT + | // CARG1 = MULTRES or negated error code, BASE, PC and JGL set. + | lwz L, SAVE_L + | addi DISPATCH, JGL, -GG_DISP2G-32768 + | stp BASE, L->base + |1: + | cmpwi CARG1, 0 + | blt >9 // Check for error from exit. + | lwz LFUNC:RB, FRAME_FUNC(BASE) + | slwi MULTRES, CARG1, 3 + | li TMP2, 0 + | stw MULTRES, SAVE_MULTRES + | lwz TMP1, LFUNC:RB->pc + | stw TMP2, DISPATCH_GL(jit_base)(DISPATCH) + | lwz KBASE, PC2PROTO(k)(TMP1) + | // Setup type comparison constants. + | li TISNUM, LJ_TISNUM + | .FPU lus TMP3, 0x59c0 // TOBIT = 2^52 + 2^51 (float). + | .FPU stw TMP3, TMPD + | li ZERO, 0 + | .FPU ori TMP3, TMP3, 0x0004 // TONUM = 2^52 + 2^51 + 2^31 (float). + | .FPU lfs TOBIT, TMPD + | .FPU stw TMP3, TMPD + | .FPU lus TMP0, 0x4338 // Hiword of 2^52 + 2^51 (double) + | li TISNIL, LJ_TNIL + | .FPU stw TMP0, TONUM_HI + | .FPU lfs TONUM, TMPD + | // Modified copy of ins_next which handles function header dispatch, too. + | lwz INS, 0(PC) + | addi PC, PC, 4 + | // Assumes TISNIL == ~LJ_VMST_INTERP == -1. + | stw TISNIL, DISPATCH_GL(vmstate)(DISPATCH) + | decode_OPP TMP1, INS + | decode_RA8 RA, INS + | lpx TMP0, DISPATCH, TMP1 + | mtctr TMP0 + | cmplwi TMP1, BC_FUNCF*4 // Function header? + | bge >2 + | decode_RB8 RB, INS + | decode_RD8 RD, INS + | decode_RC8 RC, INS + | bctr + |2: + | cmplwi TMP1, (BC_FUNCC+2)*4 // Fast function? + | blt >3 + | // Check frame below fast function. + | lwz TMP1, FRAME_PC(BASE) + | andix. TMP0, TMP1, FRAME_TYPE + | bney >3 // Trace stitching continuation? + | // Otherwise set KBASE for Lua function below fast function. + | lwz TMP2, -4(TMP1) + | decode_RA8 TMP0, TMP2 + | sub TMP1, BASE, TMP0 + | lwz LFUNC:TMP2, -12(TMP1) + | lwz TMP1, LFUNC:TMP2->pc + | lwz KBASE, PC2PROTO(k)(TMP1) + |3: + | subi RC, MULTRES, 8 + | add RA, RA, BASE + | bctr + | + |9: // Rethrow error from the right C frame. + | neg CARG2, CARG1 + | mr CARG1, L + | bl extern lj_err_trace // (lua_State *L, int errcode) + |.endif + | + |//----------------------------------------------------------------------- + |//-- Math helper functions ---------------------------------------------- + |//----------------------------------------------------------------------- + | + |// NYI: Use internal implementations of floor, ceil, trunc, sfcmp. + | + |.macro sfi2d, AHI, ALO + |.if not FPU + | mr. AHI, ALO + | bclr 12, 2 // Handle zero first. + | srawi TMP0, ALO, 31 + | xor TMP1, ALO, TMP0 + | sub TMP1, TMP1, TMP0 // Absolute value in TMP1. + | cntlzw AHI, TMP1 + | andix. TMP0, TMP0, 0x800 // Mask sign bit. + | slw TMP1, TMP1, AHI // Align mantissa left with leading 1. + | subfic AHI, AHI, 0x3ff+31-1 // Exponent -1 in AHI. + | slwi ALO, TMP1, 21 + | or AHI, AHI, TMP0 // Sign | Exponent. + | srwi TMP1, TMP1, 11 + | slwi AHI, AHI, 20 // Align left. + | add AHI, AHI, TMP1 // Add mantissa, increment exponent. + | blr + |.endif + |.endmacro + | + |// Input: CARG2. Output: CARG1, CARG2. Temporaries: TMP0, TMP1. + |->vm_sfi2d_1: + | sfi2d CARG1, CARG2 + | + |// Input: CARG4. Output: CARG3, CARG4. Temporaries: TMP0, TMP1. + |->vm_sfi2d_2: + | sfi2d CARG3, CARG4 + | + |->vm_modi: + | divwo. TMP0, CARG1, CARG2 + | bso >1 + |.if GPR64 + | xor CARG3, CARG1, CARG2 + | cmpwi CARG3, 0 + |.else + | xor. CARG3, CARG1, CARG2 + |.endif + | mullw TMP0, TMP0, CARG2 + | sub CARG1, CARG1, TMP0 + | bgelr + | cmpwi CARG1, 0; beqlr + | add CARG1, CARG1, CARG2 + | blr + |1: + | cmpwi CARG2, 0 + | li CARG1, 0 + | beqlr + | clrso TMP0 // Clear SO for -2147483648 % -1 and return 0. + | blr + | + |//----------------------------------------------------------------------- + |//-- Miscellaneous functions -------------------------------------------- + |//----------------------------------------------------------------------- + | + |// void lj_vm_cachesync(void *start, void *end) + |// Flush D-Cache and invalidate I-Cache. Assumes 32 byte cache line size. + |// This is a good lower bound, except for very ancient PPC models. + |->vm_cachesync: + |.if JIT or FFI + | // Compute start of first cache line and number of cache lines. + | rlwinm CARG1, CARG1, 0, 0, 26 + | sub CARG2, CARG2, CARG1 + | addi CARG2, CARG2, 31 + | rlwinm. CARG2, CARG2, 27, 5, 31 + | beqlr + | mtctr CARG2 + | mr CARG3, CARG1 + |1: // Flush D-Cache. + | dcbst r0, CARG1 + | addi CARG1, CARG1, 32 + | bdnz <1 + | sync + | mtctr CARG2 + |1: // Invalidate I-Cache. + | icbi r0, CARG3 + | addi CARG3, CARG3, 32 + | bdnz <1 + | isync + | blr + |.endif + | + |->vm_next: + |.if JIT + | NYI // On big-endian. + |.endif + | + |//----------------------------------------------------------------------- + |//-- FFI helper functions ----------------------------------------------- + |//----------------------------------------------------------------------- + | + |// Handler for callback functions. Callback slot number in r11, g in r12. + |->vm_ffi_callback: + |.if FFI + |.type CTSTATE, CTState, PC + | saveregs + | lwz CTSTATE, GL:r12->ctype_state + | addi DISPATCH, r12, GG_G2DISP + | stw r11, CTSTATE->cb.slot + | stw r3, CTSTATE->cb.gpr[0] + | .FPU stfd f1, CTSTATE->cb.fpr[0] + | stw r4, CTSTATE->cb.gpr[1] + | .FPU stfd f2, CTSTATE->cb.fpr[1] + | stw r5, CTSTATE->cb.gpr[2] + | .FPU stfd f3, CTSTATE->cb.fpr[2] + | stw r6, CTSTATE->cb.gpr[3] + | .FPU stfd f4, CTSTATE->cb.fpr[3] + | stw r7, CTSTATE->cb.gpr[4] + | .FPU stfd f5, CTSTATE->cb.fpr[4] + | stw r8, CTSTATE->cb.gpr[5] + | .FPU stfd f6, CTSTATE->cb.fpr[5] + | stw r9, CTSTATE->cb.gpr[6] + | .FPU stfd f7, CTSTATE->cb.fpr[6] + | stw r10, CTSTATE->cb.gpr[7] + | .FPU stfd f8, CTSTATE->cb.fpr[7] + | addi TMP0, sp, CFRAME_SPACE+8 + | stw TMP0, CTSTATE->cb.stack + | mr CARG1, CTSTATE + | stw CTSTATE, SAVE_PC // Any value outside of bytecode is ok. + | mr CARG2, sp + | bl extern lj_ccallback_enter // (CTState *cts, void *cf) + | // Returns lua_State *. + | lp BASE, L:CRET1->base + | li TISNUM, LJ_TISNUM // Setup type comparison constants. + | lp RC, L:CRET1->top + | .FPU lus TMP3, 0x59c0 // TOBIT = 2^52 + 2^51 (float). + | li ZERO, 0 + | mr L, CRET1 + | .FPU stw TMP3, TMPD + | .FPU lus TMP0, 0x4338 // Hiword of 2^52 + 2^51 (double) + | lwz LFUNC:RB, FRAME_FUNC(BASE) + | .FPU ori TMP3, TMP3, 0x0004 // TONUM = 2^52 + 2^51 + 2^31 (float). + | .FPU stw TMP0, TONUM_HI + | li TISNIL, LJ_TNIL + | li_vmstate INTERP + | .FPU lfs TOBIT, TMPD + | .FPU stw TMP3, TMPD + | sub RC, RC, BASE + | st_vmstate + | .FPU lfs TONUM, TMPD + | ins_callt + |.endif + | + |->cont_ffi_callback: // Return from FFI callback. + |.if FFI + | lwz CTSTATE, DISPATCH_GL(ctype_state)(DISPATCH) + | stp BASE, L->base + | stp RB, L->top + | stp L, CTSTATE->L + | mr CARG1, CTSTATE + | mr CARG2, RA + | bl extern lj_ccallback_leave // (CTState *cts, TValue *o) + | lwz CRET1, CTSTATE->cb.gpr[0] + | .FPU lfd FARG1, CTSTATE->cb.fpr[0] + | lwz CRET2, CTSTATE->cb.gpr[1] + | b ->vm_leave_unw + |.endif + | + |->vm_ffi_call: // Call C function via FFI. + | // Caveat: needs special frame unwinding, see below. + |.if FFI + | .type CCSTATE, CCallState, CARG1 + | lwz TMP1, CCSTATE->spadj + | mflr TMP0 + | lbz CARG2, CCSTATE->nsp + | lbz CARG3, CCSTATE->nfpr + | neg TMP1, TMP1 + | stw TMP0, 4(sp) + | cmpwi cr1, CARG3, 0 + | mr TMP2, sp + | addic. CARG2, CARG2, -1 + | stwux sp, sp, TMP1 + | crnot 4*cr1+eq, 4*cr1+eq // For vararg calls. + | stw r14, -4(TMP2) + | stw CCSTATE, -8(TMP2) + | mr r14, TMP2 + | la TMP1, CCSTATE->stack + | slwi CARG2, CARG2, 2 + | blty >2 + | la TMP2, 8(sp) + |1: + | lwzx TMP0, TMP1, CARG2 + | stwx TMP0, TMP2, CARG2 + | addic. CARG2, CARG2, -4 + | bge <1 + |2: + | bney cr1, >3 + | .FPU lfd f1, CCSTATE->fpr[0] + | .FPU lfd f2, CCSTATE->fpr[1] + | .FPU lfd f3, CCSTATE->fpr[2] + | .FPU lfd f4, CCSTATE->fpr[3] + | .FPU lfd f5, CCSTATE->fpr[4] + | .FPU lfd f6, CCSTATE->fpr[5] + | .FPU lfd f7, CCSTATE->fpr[6] + | .FPU lfd f8, CCSTATE->fpr[7] + |3: + | lp TMP0, CCSTATE->func + | lwz CARG2, CCSTATE->gpr[1] + | lwz CARG3, CCSTATE->gpr[2] + | lwz CARG4, CCSTATE->gpr[3] + | lwz CARG5, CCSTATE->gpr[4] + | mtctr TMP0 + | lwz r8, CCSTATE->gpr[5] + | lwz r9, CCSTATE->gpr[6] + | lwz r10, CCSTATE->gpr[7] + | lwz CARG1, CCSTATE->gpr[0] // Do this last, since CCSTATE is CARG1. + | bctrl + | lwz CCSTATE:TMP1, -8(r14) + | lwz TMP2, -4(r14) + | lwz TMP0, 4(r14) + | stw CARG1, CCSTATE:TMP1->gpr[0] + | .FPU stfd FARG1, CCSTATE:TMP1->fpr[0] + | stw CARG2, CCSTATE:TMP1->gpr[1] + | mtlr TMP0 + | stw CARG3, CCSTATE:TMP1->gpr[2] + | mr sp, r14 + | stw CARG4, CCSTATE:TMP1->gpr[3] + | mr r14, TMP2 + | blr + |.endif + |// Note: vm_ffi_call must be the last function in this object file! + | + |//----------------------------------------------------------------------- +} + +/* Generate the code for a single instruction. */ +static void build_ins(BuildCtx *ctx, BCOp op, int defop) +{ + int vk = 0; + |=>defop: + + switch (op) { + + /* -- Comparison ops ---------------------------------------------------- */ + + /* Remember: all ops branch for a true comparison, fall through otherwise. */ + + case BC_ISLT: case BC_ISGE: case BC_ISLE: case BC_ISGT: + | // RA = src1*8, RD = src2*8, JMP with RD = target + |.if DUALNUM + | lwzux CARG1, RA, BASE + | addi PC, PC, 4 + | lwz CARG2, 4(RA) + | lwzux CARG3, RD, BASE + | lwz TMP2, -4(PC) + | checknum cr0, CARG1 + | lwz CARG4, 4(RD) + | decode_RD4 TMP2, TMP2 + | checknum cr1, CARG3 + | addis SAVE0, TMP2, -(BCBIAS_J*4 >> 16) + | bne cr0, >7 + | bne cr1, >8 + | cmpw CARG2, CARG4 + if (op == BC_ISLT) { + | bge >2 + } else if (op == BC_ISGE) { + | blt >2 + } else if (op == BC_ISLE) { + | bgt >2 + } else { + | ble >2 + } + |1: + | add PC, PC, SAVE0 + |2: + | ins_next + | + |7: // RA is not an integer. + | bgt cr0, ->vmeta_comp + | // RA is a number. + | .FPU lfd f0, 0(RA) + | bgt cr1, ->vmeta_comp + | blt cr1, >4 + | // RA is a number, RD is an integer. + |.if FPU + | tonum_i f1, CARG4 + |.else + | bl ->vm_sfi2d_2 + |.endif + | b >5 + | + |8: // RA is an integer, RD is not an integer. + | bgt cr1, ->vmeta_comp + | // RA is an integer, RD is a number. + |.if FPU + | tonum_i f0, CARG2 + |.else + | bl ->vm_sfi2d_1 + |.endif + |4: + | .FPU lfd f1, 0(RD) + |5: + |.if FPU + | fcmpu cr0, f0, f1 + |.else + | blex __ledf2 + | cmpwi CRET1, 0 + |.endif + if (op == BC_ISLT) { + | bge <2 + } else if (op == BC_ISGE) { + | blt <2 + } else if (op == BC_ISLE) { + | cror 4*cr0+lt, 4*cr0+lt, 4*cr0+eq + | bge <2 + } else { + | cror 4*cr0+lt, 4*cr0+lt, 4*cr0+eq + | blt <2 + } + | b <1 + |.else + | lwzx TMP0, BASE, RA + | addi PC, PC, 4 + | lfdx f0, BASE, RA + | lwzx TMP1, BASE, RD + | checknum cr0, TMP0 + | lwz TMP2, -4(PC) + | lfdx f1, BASE, RD + | checknum cr1, TMP1 + | decode_RD4 TMP2, TMP2 + | bge cr0, ->vmeta_comp + | addis TMP2, TMP2, -(BCBIAS_J*4 >> 16) + | bge cr1, ->vmeta_comp + | fcmpu cr0, f0, f1 + if (op == BC_ISLT) { + | bge >1 + } else if (op == BC_ISGE) { + | blt >1 + } else if (op == BC_ISLE) { + | cror 4*cr0+lt, 4*cr0+lt, 4*cr0+eq + | bge >1 + } else { + | cror 4*cr0+lt, 4*cr0+lt, 4*cr0+eq + | blt >1 + } + | add PC, PC, TMP2 + |1: + | ins_next + |.endif + break; + + case BC_ISEQV: case BC_ISNEV: + vk = op == BC_ISEQV; + | // RA = src1*8, RD = src2*8, JMP with RD = target + |.if DUALNUM + | lwzux CARG1, RA, BASE + | addi PC, PC, 4 + | lwz CARG2, 4(RA) + | lwzux CARG3, RD, BASE + | checknum cr0, CARG1 + | lwz SAVE0, -4(PC) + | checknum cr1, CARG3 + | decode_RD4 SAVE0, SAVE0 + | lwz CARG4, 4(RD) + | cror 4*cr7+gt, 4*cr0+gt, 4*cr1+gt + | addis SAVE0, SAVE0, -(BCBIAS_J*4 >> 16) + if (vk) { + | ble cr7, ->BC_ISEQN_Z + } else { + | ble cr7, ->BC_ISNEN_Z + } + |.else + | lwzux CARG1, RA, BASE + | lwz SAVE0, 0(PC) + | lfd f0, 0(RA) + | addi PC, PC, 4 + | lwzux CARG3, RD, BASE + | checknum cr0, CARG1 + | decode_RD4 SAVE0, SAVE0 + | lfd f1, 0(RD) + | checknum cr1, CARG3 + | addis SAVE0, SAVE0, -(BCBIAS_J*4 >> 16) + | bge cr0, >5 + | bge cr1, >5 + | fcmpu cr0, f0, f1 + if (vk) { + | bne >1 + | add PC, PC, SAVE0 + } else { + | beq >1 + | add PC, PC, SAVE0 + } + |1: + | ins_next + |.endif + |5: // Either or both types are not numbers. + |.if not DUALNUM + | lwz CARG2, 4(RA) + | lwz CARG4, 4(RD) + |.endif + |.if FFI + | cmpwi cr7, CARG1, LJ_TCDATA + | cmpwi cr5, CARG3, LJ_TCDATA + |.endif + | not TMP2, CARG1 + | cmplw CARG1, CARG3 + | cmplwi cr1, TMP2, ~LJ_TISPRI // Primitive? + |.if FFI + | cror 4*cr7+eq, 4*cr7+eq, 4*cr5+eq + |.endif + | cmplwi cr6, TMP2, ~LJ_TISTABUD // Table or userdata? + |.if FFI + | beq cr7, ->vmeta_equal_cd + |.endif + | cmplw cr5, CARG2, CARG4 + | crandc 4*cr0+gt, 4*cr0+eq, 4*cr1+gt // 2: Same type and primitive. + | crorc 4*cr0+lt, 4*cr5+eq, 4*cr0+eq // 1: Same tv or different type. + | crand 4*cr0+eq, 4*cr0+eq, 4*cr5+eq // 0: Same type and same tv. + | mr SAVE1, PC + | cror 4*cr0+eq, 4*cr0+eq, 4*cr0+gt // 0 or 2. + | cror 4*cr0+lt, 4*cr0+lt, 4*cr0+gt // 1 or 2. + if (vk) { + | bne cr0, >6 + | add PC, PC, SAVE0 + |6: + } else { + | beq cr0, >6 + | add PC, PC, SAVE0 + |6: + } + |.if DUALNUM + | bge cr0, >2 // Done if 1 or 2. + |1: + | ins_next + |2: + |.else + | blt cr0, <1 // Done if 1 or 2. + |.endif + | blt cr6, <1 // Done if not tab/ud. + | + | // Different tables or userdatas. Need to check __eq metamethod. + | // Field metatable must be at same offset for GCtab and GCudata! + | mr CARG3, CARG4 + | lwz TAB:TMP2, TAB:CARG2->metatable + | li CARG4, 1-vk // ne = 0 or 1. + | cmplwi TAB:TMP2, 0 + | beq <1 // No metatable? + | lbz TMP2, TAB:TMP2->nomm + | andix. TMP2, TMP2, 1<vmeta_equal // Handle __eq metamethod. + break; + + case BC_ISEQS: case BC_ISNES: + vk = op == BC_ISEQS; + | // RA = src*8, RD = str_const*8 (~), JMP with RD = target + | lwzux TMP0, RA, BASE + | srwi RD, RD, 1 + | lwz STR:TMP3, 4(RA) + | lwz TMP2, 0(PC) + | subfic RD, RD, -4 + | addi PC, PC, 4 + |.if FFI + | cmpwi TMP0, LJ_TCDATA + |.endif + | lwzx STR:TMP1, KBASE, RD // KBASE-4-str_const*4 + | .gpr64 extsw TMP0, TMP0 + | subfic TMP0, TMP0, LJ_TSTR + |.if FFI + | beq ->vmeta_equal_cd + |.endif + | sub TMP1, STR:TMP1, STR:TMP3 + | or TMP0, TMP0, TMP1 + | decode_RD4 TMP2, TMP2 + | subfic TMP0, TMP0, 0 + | addis TMP2, TMP2, -(BCBIAS_J*4 >> 16) + | subfe TMP1, TMP1, TMP1 + if (vk) { + | andc TMP2, TMP2, TMP1 + } else { + | and TMP2, TMP2, TMP1 + } + | add PC, PC, TMP2 + | ins_next + break; + + case BC_ISEQN: case BC_ISNEN: + vk = op == BC_ISEQN; + | // RA = src*8, RD = num_const*8, JMP with RD = target + |.if DUALNUM + | lwzux CARG1, RA, BASE + | addi PC, PC, 4 + | lwz CARG2, 4(RA) + | lwzux CARG3, RD, KBASE + | checknum cr0, CARG1 + | lwz SAVE0, -4(PC) + | checknum cr1, CARG3 + | decode_RD4 SAVE0, SAVE0 + | lwz CARG4, 4(RD) + | addis SAVE0, SAVE0, -(BCBIAS_J*4 >> 16) + if (vk) { + |->BC_ISEQN_Z: + } else { + |->BC_ISNEN_Z: + } + | bne cr0, >7 + | bne cr1, >8 + | cmpw CARG2, CARG4 + |4: + |.else + if (vk) { + |->BC_ISEQN_Z: // Dummy label. + } else { + |->BC_ISNEN_Z: // Dummy label. + } + | lwzx CARG1, BASE, RA + | addi PC, PC, 4 + | lfdx f0, BASE, RA + | lwz SAVE0, -4(PC) + | lfdx f1, KBASE, RD + | decode_RD4 SAVE0, SAVE0 + | checknum CARG1 + | addis SAVE0, SAVE0, -(BCBIAS_J*4 >> 16) + | bge >3 + | fcmpu cr0, f0, f1 + |.endif + if (vk) { + | bne >1 + | add PC, PC, SAVE0 + |1: + |.if not FFI + |3: + |.endif + } else { + | beq >2 + |1: + |.if not FFI + |3: + |.endif + | add PC, PC, SAVE0 + |2: + } + | ins_next + |.if FFI + |3: + | cmpwi CARG1, LJ_TCDATA + | beq ->vmeta_equal_cd + | b <1 + |.endif + |.if DUALNUM + |7: // RA is not an integer. + | bge cr0, <3 + | // RA is a number. + | .FPU lfd f0, 0(RA) + | blt cr1, >1 + | // RA is a number, RD is an integer. + |.if FPU + | tonum_i f1, CARG4 + |.else + | bl ->vm_sfi2d_2 + |.endif + | b >2 + | + |8: // RA is an integer, RD is a number. + |.if FPU + | tonum_i f0, CARG2 + |.else + | bl ->vm_sfi2d_1 + |.endif + |1: + | .FPU lfd f1, 0(RD) + |2: + |.if FPU + | fcmpu cr0, f0, f1 + |.else + | blex __ledf2 + | cmpwi CRET1, 0 + |.endif + | b <4 + |.endif + break; + + case BC_ISEQP: case BC_ISNEP: + vk = op == BC_ISEQP; + | // RA = src*8, RD = primitive_type*8 (~), JMP with RD = target + | lwzx TMP0, BASE, RA + | srwi TMP1, RD, 3 + | lwz TMP2, 0(PC) + | not TMP1, TMP1 + | addi PC, PC, 4 + |.if FFI + | cmpwi TMP0, LJ_TCDATA + |.endif + | sub TMP0, TMP0, TMP1 + |.if FFI + | beq ->vmeta_equal_cd + |.endif + | decode_RD4 TMP2, TMP2 + | .gpr64 extsw TMP0, TMP0 + | addic TMP0, TMP0, -1 + | addis TMP2, TMP2, -(BCBIAS_J*4 >> 16) + | subfe TMP1, TMP1, TMP1 + if (vk) { + | and TMP2, TMP2, TMP1 + } else { + | andc TMP2, TMP2, TMP1 + } + | add PC, PC, TMP2 + | ins_next + break; + + /* -- Unary test and copy ops ------------------------------------------- */ + + case BC_ISTC: case BC_ISFC: case BC_IST: case BC_ISF: + | // RA = dst*8 or unused, RD = src*8, JMP with RD = target + | lwzx TMP0, BASE, RD + | lwz INS, 0(PC) + | addi PC, PC, 4 + if (op == BC_IST || op == BC_ISF) { + | .gpr64 extsw TMP0, TMP0 + | subfic TMP0, TMP0, LJ_TTRUE + | decode_RD4 TMP2, INS + | subfe TMP1, TMP1, TMP1 + | addis TMP2, TMP2, -(BCBIAS_J*4 >> 16) + if (op == BC_IST) { + | andc TMP2, TMP2, TMP1 + } else { + | and TMP2, TMP2, TMP1 + } + | add PC, PC, TMP2 + } else { + | li TMP1, LJ_TFALSE + |.if FPU + | lfdx f0, BASE, RD + |.else + | lwzux CARG1, RD, BASE + | lwz CARG2, 4(RD) + |.endif + | cmplw TMP0, TMP1 + if (op == BC_ISTC) { + | bge >1 + } else { + | blt >1 + } + | addis PC, PC, -(BCBIAS_J*4 >> 16) + | decode_RD4 TMP2, INS + |.if FPU + | stfdx f0, BASE, RA + |.else + | stwux CARG1, RA, BASE + | stw CARG2, 4(RA) + |.endif + | add PC, PC, TMP2 + |1: + } + | ins_next + break; + + case BC_ISTYPE: + | // RA = src*8, RD = -type*8 + | lwzx TMP0, BASE, RA + | srwi TMP1, RD, 3 + | ins_next1 + |.if not PPE and not GPR64 + | add. TMP0, TMP0, TMP1 + |.else + | neg TMP1, TMP1 + | cmpw TMP0, TMP1 + |.endif + | bne ->vmeta_istype + | ins_next2 + break; + case BC_ISNUM: + | // RA = src*8, RD = -(TISNUM-1)*8 + | lwzx TMP0, BASE, RA + | ins_next1 + | checknum TMP0 + | bge ->vmeta_istype + | ins_next2 + break; + + /* -- Unary ops --------------------------------------------------------- */ + + case BC_MOV: + | // RA = dst*8, RD = src*8 + | ins_next1 + |.if FPU + | lfdx f0, BASE, RD + | stfdx f0, BASE, RA + |.else + | lwzux TMP0, RD, BASE + | lwz TMP1, 4(RD) + | stwux TMP0, RA, BASE + | stw TMP1, 4(RA) + |.endif + | ins_next2 + break; + case BC_NOT: + | // RA = dst*8, RD = src*8 + | ins_next1 + | lwzx TMP0, BASE, RD + | .gpr64 extsw TMP0, TMP0 + | subfic TMP1, TMP0, LJ_TTRUE + | adde TMP0, TMP0, TMP1 + | stwx TMP0, BASE, RA + | ins_next2 + break; + case BC_UNM: + | // RA = dst*8, RD = src*8 + | lwzux TMP1, RD, BASE + | lwz TMP0, 4(RD) + | checknum TMP1 + |.if DUALNUM + | bne >5 + |.if GPR64 + | lus TMP2, 0x8000 + | neg TMP0, TMP0 + | cmplw TMP0, TMP2 + | beq >4 + |.else + | nego. TMP0, TMP0 + | bso >4 + |1: + |.endif + | ins_next1 + | stwux TISNUM, RA, BASE + | stw TMP0, 4(RA) + |3: + | ins_next2 + |4: + |.if not GPR64 + | // Potential overflow. + | checkov TMP1, <1 // Ignore unrelated overflow. + |.endif + | lus TMP1, 0x41e0 // 2^31. + | li TMP0, 0 + | b >7 + |.endif + |5: + | bge ->vmeta_unm + | xoris TMP1, TMP1, 0x8000 + |7: + | ins_next1 + | stwux TMP1, RA, BASE + | stw TMP0, 4(RA) + |.if DUALNUM + | b <3 + |.else + | ins_next2 + |.endif + break; + case BC_LEN: + | // RA = dst*8, RD = src*8 + | lwzux TMP0, RD, BASE + | lwz CARG1, 4(RD) + | checkstr TMP0; bne >2 + | lwz CRET1, STR:CARG1->len + |1: + |.if DUALNUM + | ins_next1 + | stwux TISNUM, RA, BASE + | stw CRET1, 4(RA) + |.else + | tonum_u f0, CRET1 // Result is a non-negative integer. + | ins_next1 + | stfdx f0, BASE, RA + |.endif + | ins_next2 + |2: + | checktab TMP0; bne ->vmeta_len +#if LJ_52 + | lwz TAB:TMP2, TAB:CARG1->metatable + | cmplwi TAB:TMP2, 0 + | bne >9 + |3: +#endif + |->BC_LEN_Z: + | bl extern lj_tab_len // (GCtab *t) + | // Returns uint32_t (but less than 2^31). + | b <1 +#if LJ_52 + |9: + | lbz TMP0, TAB:TMP2->nomm + | andix. TMP0, TMP0, 1<vmeta_len +#endif + break; + + /* -- Binary ops -------------------------------------------------------- */ + + |.macro ins_arithpre + | // RA = dst*8, RB = src1*8, RC = src2*8 | num_const*8 + ||vk = ((int)op - BC_ADDVN) / (BC_ADDNV-BC_ADDVN); + ||switch (vk) { + ||case 0: + | lwzx CARG1, BASE, RB + | .if DUALNUM + | lwzx CARG3, KBASE, RC + | .endif + | .if FPU + | lfdx f14, BASE, RB + | lfdx f15, KBASE, RC + | .else + | add TMP1, BASE, RB + | add TMP2, KBASE, RC + | lwz CARG2, 4(TMP1) + | lwz CARG4, 4(TMP2) + | .endif + | .if DUALNUM + | checknum cr0, CARG1 + | checknum cr1, CARG3 + | crand 4*cr0+lt, 4*cr0+lt, 4*cr1+lt + | bge ->vmeta_arith_vn + | .else + | checknum CARG1; bge ->vmeta_arith_vn + | .endif + || break; + ||case 1: + | lwzx CARG1, BASE, RB + | .if DUALNUM + | lwzx CARG3, KBASE, RC + | .endif + | .if FPU + | lfdx f15, BASE, RB + | lfdx f14, KBASE, RC + | .else + | add TMP1, BASE, RB + | add TMP2, KBASE, RC + | lwz CARG2, 4(TMP1) + | lwz CARG4, 4(TMP2) + | .endif + | .if DUALNUM + | checknum cr0, CARG1 + | checknum cr1, CARG3 + | crand 4*cr0+lt, 4*cr0+lt, 4*cr1+lt + | bge ->vmeta_arith_nv + | .else + | checknum CARG1; bge ->vmeta_arith_nv + | .endif + || break; + ||default: + | lwzx CARG1, BASE, RB + | lwzx CARG3, BASE, RC + | .if FPU + | lfdx f14, BASE, RB + | lfdx f15, BASE, RC + | .else + | add TMP1, BASE, RB + | add TMP2, BASE, RC + | lwz CARG2, 4(TMP1) + | lwz CARG4, 4(TMP2) + | .endif + | checknum cr0, CARG1 + | checknum cr1, CARG3 + | crand 4*cr0+lt, 4*cr0+lt, 4*cr1+lt + | bge ->vmeta_arith_vv + || break; + ||} + |.endmacro + | + |.macro ins_arithfallback, ins + ||switch (vk) { + ||case 0: + | ins ->vmeta_arith_vn2 + || break; + ||case 1: + | ins ->vmeta_arith_nv2 + || break; + ||default: + | ins ->vmeta_arith_vv2 + || break; + ||} + |.endmacro + | + |.macro intmod, a, b, c + | bl ->vm_modi + |.endmacro + | + |.macro fpmod, a, b, c + |->BC_MODVN_Z: + | fdiv FARG1, b, c + | // NYI: Use internal implementation of floor. + | blex floor // floor(b/c) + | fmul a, FARG1, c + | fsub a, b, a // b - floor(b/c)*c + |.endmacro + | + |.macro sfpmod + |->BC_MODVN_Z: + | stw CARG1, SFSAVE_1 + | stw CARG2, SFSAVE_2 + | mr SAVE0, CARG3 + | mr SAVE1, CARG4 + | blex __divdf3 + | blex floor + | mr CARG3, SAVE0 + | mr CARG4, SAVE1 + | blex __muldf3 + | mr CARG3, CRET1 + | mr CARG4, CRET2 + | lwz CARG1, SFSAVE_1 + | lwz CARG2, SFSAVE_2 + | blex __subdf3 + |.endmacro + | + |.macro ins_arithfp, fpins + | ins_arithpre + |.if "fpins" == "fpmod_" + | b ->BC_MODVN_Z // Avoid 3 copies. It's slow anyway. + |.elif FPU + | fpins f0, f14, f15 + | ins_next1 + | stfdx f0, BASE, RA + | ins_next2 + |.else + | blex __divdf3 // Only soft-float div uses this macro. + | ins_next1 + | stwux CRET1, RA, BASE + | stw CRET2, 4(RA) + | ins_next2 + |.endif + |.endmacro + | + |.macro ins_arithdn, intins, fpins, fpcall + | // RA = dst*8, RB = src1*8, RC = src2*8 | num_const*8 + ||vk = ((int)op - BC_ADDVN) / (BC_ADDNV-BC_ADDVN); + ||switch (vk) { + ||case 0: + | lwzux CARG1, RB, BASE + | lwzux CARG3, RC, KBASE + | lwz CARG2, 4(RB) + | checknum cr0, CARG1 + | lwz CARG4, 4(RC) + | checknum cr1, CARG3 + || break; + ||case 1: + | lwzux CARG3, RB, BASE + | lwzux CARG1, RC, KBASE + | lwz CARG4, 4(RB) + | checknum cr0, CARG3 + | lwz CARG2, 4(RC) + | checknum cr1, CARG1 + || break; + ||default: + | lwzux CARG1, RB, BASE + | lwzux CARG3, RC, BASE + | lwz CARG2, 4(RB) + | checknum cr0, CARG1 + | lwz CARG4, 4(RC) + | checknum cr1, CARG3 + || break; + ||} + | bne >5 + | bne cr1, >5 + |.if "intins" == "intmod" + | mr CARG1, CARG2 + | mr CARG2, CARG4 + |.endif + | intins CARG1, CARG2, CARG4 + | bso >4 + |1: + | ins_next1 + | stwux TISNUM, RA, BASE + | stw CARG1, 4(RA) + |2: + | ins_next2 + |4: // Overflow. + | checkov TMP0, <1 // Ignore unrelated overflow. + | ins_arithfallback b + |5: // FP variant. + |.if FPU + ||if (vk == 1) { + | lfd f15, 0(RB) + | lfd f14, 0(RC) + ||} else { + | lfd f14, 0(RB) + | lfd f15, 0(RC) + ||} + |.endif + | crand 4*cr0+lt, 4*cr0+lt, 4*cr1+lt + | ins_arithfallback bge + |.if "fpins" == "fpmod_" + | b ->BC_MODVN_Z // Avoid 3 copies. It's slow anyway. + |.else + |.if FPU + | fpins f0, f14, f15 + | stfdx f0, BASE, RA + |.else + |.if "fpcall" == "sfpmod" + | sfpmod + |.else + | blex fpcall + |.endif + | stwux CRET1, RA, BASE + | stw CRET2, 4(RA) + |.endif + | ins_next1 + | b <2 + |.endif + |.endmacro + | + |.macro ins_arith, intins, fpins, fpcall + |.if DUALNUM + | ins_arithdn intins, fpins, fpcall + |.else + | ins_arithfp fpins + |.endif + |.endmacro + + case BC_ADDVN: case BC_ADDNV: case BC_ADDVV: + |.if GPR64 + |.macro addo32., y, a, b + | // Need to check overflow for (a<<32) + (b<<32). + | rldicr TMP0, a, 32, 31 + | rldicr TMP1, b, 32, 31 + | addo. TMP0, TMP0, TMP1 + | add y, a, b + |.endmacro + | ins_arith addo32., fadd, __adddf3 + |.else + | ins_arith addo., fadd, __adddf3 + |.endif + break; + case BC_SUBVN: case BC_SUBNV: case BC_SUBVV: + |.if GPR64 + |.macro subo32., y, a, b + | // Need to check overflow for (a<<32) - (b<<32). + | rldicr TMP0, a, 32, 31 + | rldicr TMP1, b, 32, 31 + | subo. TMP0, TMP0, TMP1 + | sub y, a, b + |.endmacro + | ins_arith subo32., fsub, __subdf3 + |.else + | ins_arith subo., fsub, __subdf3 + |.endif + break; + case BC_MULVN: case BC_MULNV: case BC_MULVV: + | ins_arith mullwo., fmul, __muldf3 + break; + case BC_DIVVN: case BC_DIVNV: case BC_DIVVV: + | ins_arithfp fdiv + break; + case BC_MODVN: + | ins_arith intmod, fpmod, sfpmod + break; + case BC_MODNV: case BC_MODVV: + | ins_arith intmod, fpmod_, sfpmod + break; + case BC_POW: + | // NYI: (partial) integer arithmetic. + | lwzx CARG1, BASE, RB + | lwzx CARG3, BASE, RC + |.if FPU + | lfdx FARG1, BASE, RB + | lfdx FARG2, BASE, RC + |.else + | add TMP1, BASE, RB + | add TMP2, BASE, RC + | lwz CARG2, 4(TMP1) + | lwz CARG4, 4(TMP2) + |.endif + | checknum cr0, CARG1 + | checknum cr1, CARG3 + | crand 4*cr0+lt, 4*cr0+lt, 4*cr1+lt + | bge ->vmeta_arith_vv + | blex pow + | ins_next1 + |.if FPU + | stfdx FARG1, BASE, RA + |.else + | stwux CARG1, RA, BASE + | stw CARG2, 4(RA) + |.endif + | ins_next2 + break; + + case BC_CAT: + | // RA = dst*8, RB = src_start*8, RC = src_end*8 + | sub CARG3, RC, RB + | stp BASE, L->base + | add CARG2, BASE, RC + | mr SAVE0, RB + |->BC_CAT_Z: + | stw PC, SAVE_PC + | mr CARG1, L + | srwi CARG3, CARG3, 3 + | bl extern lj_meta_cat // (lua_State *L, TValue *top, int left) + | // Returns NULL (finished) or TValue * (metamethod). + | cmplwi CRET1, 0 + | lp BASE, L->base + | bne ->vmeta_binop + | ins_next1 + |.if FPU + | lfdx f0, BASE, SAVE0 // Copy result from RB to RA. + | stfdx f0, BASE, RA + |.else + | lwzux TMP0, SAVE0, BASE + | lwz TMP1, 4(SAVE0) + | stwux TMP0, RA, BASE + | stw TMP1, 4(RA) + |.endif + | ins_next2 + break; + + /* -- Constant ops ------------------------------------------------------ */ + + case BC_KSTR: + | // RA = dst*8, RD = str_const*8 (~) + | srwi TMP1, RD, 1 + | subfic TMP1, TMP1, -4 + | ins_next1 + | lwzx TMP0, KBASE, TMP1 // KBASE-4-str_const*4 + | li TMP2, LJ_TSTR + | stwux TMP2, RA, BASE + | stw TMP0, 4(RA) + | ins_next2 + break; + case BC_KCDATA: + |.if FFI + | // RA = dst*8, RD = cdata_const*8 (~) + | srwi TMP1, RD, 1 + | subfic TMP1, TMP1, -4 + | ins_next1 + | lwzx TMP0, KBASE, TMP1 // KBASE-4-cdata_const*4 + | li TMP2, LJ_TCDATA + | stwux TMP2, RA, BASE + | stw TMP0, 4(RA) + | ins_next2 + |.endif + break; + case BC_KSHORT: + | // RA = dst*8, RD = int16_literal*8 + |.if DUALNUM + | slwi RD, RD, 13 + | srawi RD, RD, 16 + | ins_next1 + | stwux TISNUM, RA, BASE + | stw RD, 4(RA) + | ins_next2 + |.else + | // The soft-float approach is faster. + | slwi RD, RD, 13 + | srawi TMP1, RD, 31 + | xor TMP2, TMP1, RD + | sub TMP2, TMP2, TMP1 // TMP2 = abs(x) + | cntlzw TMP3, TMP2 + | subfic TMP1, TMP3, 0x40d // TMP1 = exponent-1 + | slw TMP2, TMP2, TMP3 // TMP2 = left aligned mantissa + | subfic TMP3, RD, 0 + | slwi TMP1, TMP1, 20 + | rlwimi RD, TMP2, 21, 1, 31 // hi = sign(x) | (mantissa>>11) + | subfe TMP0, TMP0, TMP0 + | add RD, RD, TMP1 // hi = hi + exponent-1 + | and RD, RD, TMP0 // hi = x == 0 ? 0 : hi + | ins_next1 + | stwux RD, RA, BASE + | stw ZERO, 4(RA) + | ins_next2 + |.endif + break; + case BC_KNUM: + | // RA = dst*8, RD = num_const*8 + | ins_next1 + |.if FPU + | lfdx f0, KBASE, RD + | stfdx f0, BASE, RA + |.else + | lwzux TMP0, RD, KBASE + | lwz TMP1, 4(RD) + | stwux TMP0, RA, BASE + | stw TMP1, 4(RA) + |.endif + | ins_next2 + break; + case BC_KPRI: + | // RA = dst*8, RD = primitive_type*8 (~) + | srwi TMP1, RD, 3 + | not TMP0, TMP1 + | ins_next1 + | stwx TMP0, BASE, RA + | ins_next2 + break; + case BC_KNIL: + | // RA = base*8, RD = end*8 + | stwx TISNIL, BASE, RA + | addi RA, RA, 8 + |1: + | stwx TISNIL, BASE, RA + | cmpw RA, RD + | addi RA, RA, 8 + | blt <1 + | ins_next_ + break; + + /* -- Upvalue and function ops ------------------------------------------ */ + + case BC_UGET: + | // RA = dst*8, RD = uvnum*8 + | lwz LFUNC:RB, FRAME_FUNC(BASE) + | srwi RD, RD, 1 + | addi RD, RD, offsetof(GCfuncL, uvptr) + | lwzx UPVAL:RB, LFUNC:RB, RD + | ins_next1 + | lwz TMP1, UPVAL:RB->v + |.if FPU + | lfd f0, 0(TMP1) + | stfdx f0, BASE, RA + |.else + | lwz TMP2, 0(TMP1) + | lwz TMP3, 4(TMP1) + | stwux TMP2, RA, BASE + | stw TMP3, 4(RA) + |.endif + | ins_next2 + break; + case BC_USETV: + | // RA = uvnum*8, RD = src*8 + | lwz LFUNC:RB, FRAME_FUNC(BASE) + | srwi RA, RA, 1 + | addi RA, RA, offsetof(GCfuncL, uvptr) + |.if FPU + | lfdux f0, RD, BASE + |.else + | lwzux CARG1, RD, BASE + | lwz CARG3, 4(RD) + |.endif + | lwzx UPVAL:RB, LFUNC:RB, RA + | lbz TMP3, UPVAL:RB->marked + | lwz CARG2, UPVAL:RB->v + | andix. TMP3, TMP3, LJ_GC_BLACK // isblack(uv) + | lbz TMP0, UPVAL:RB->closed + | lwz TMP2, 0(RD) + |.if FPU + | stfd f0, 0(CARG2) + |.else + | stw CARG1, 0(CARG2) + | stw CARG3, 4(CARG2) + |.endif + | cmplwi cr1, TMP0, 0 + | lwz TMP1, 4(RD) + | cror 4*cr0+eq, 4*cr0+eq, 4*cr1+eq + | subi TMP2, TMP2, (LJ_TNUMX+1) + | bne >2 // Upvalue is closed and black? + |1: + | ins_next + | + |2: // Check if new value is collectable. + | cmplwi TMP2, LJ_TISGCV - (LJ_TNUMX+1) + | bge <1 // tvisgcv(v) + | lbz TMP3, GCOBJ:TMP1->gch.marked + | andix. TMP3, TMP3, LJ_GC_WHITES // iswhite(v) + | la CARG1, GG_DISP2G(DISPATCH) + | // Crossed a write barrier. Move the barrier forward. + | beq <1 + | bl extern lj_gc_barrieruv // (global_State *g, TValue *tv) + | b <1 + break; + case BC_USETS: + | // RA = uvnum*8, RD = str_const*8 (~) + | lwz LFUNC:RB, FRAME_FUNC(BASE) + | srwi TMP1, RD, 1 + | srwi RA, RA, 1 + | subfic TMP1, TMP1, -4 + | addi RA, RA, offsetof(GCfuncL, uvptr) + | lwzx STR:TMP1, KBASE, TMP1 // KBASE-4-str_const*4 + | lwzx UPVAL:RB, LFUNC:RB, RA + | lbz TMP3, UPVAL:RB->marked + | lwz CARG2, UPVAL:RB->v + | andix. TMP3, TMP3, LJ_GC_BLACK // isblack(uv) + | lbz TMP3, STR:TMP1->marked + | lbz TMP2, UPVAL:RB->closed + | li TMP0, LJ_TSTR + | stw STR:TMP1, 4(CARG2) + | stw TMP0, 0(CARG2) + | bne >2 + |1: + | ins_next + | + |2: // Check if string is white and ensure upvalue is closed. + | andix. TMP3, TMP3, LJ_GC_WHITES // iswhite(str) + | cmplwi cr1, TMP2, 0 + | cror 4*cr0+eq, 4*cr0+eq, 4*cr1+eq + | la CARG1, GG_DISP2G(DISPATCH) + | // Crossed a write barrier. Move the barrier forward. + | beq <1 + | bl extern lj_gc_barrieruv // (global_State *g, TValue *tv) + | b <1 + break; + case BC_USETN: + | // RA = uvnum*8, RD = num_const*8 + | lwz LFUNC:RB, FRAME_FUNC(BASE) + | srwi RA, RA, 1 + | addi RA, RA, offsetof(GCfuncL, uvptr) + |.if FPU + | lfdx f0, KBASE, RD + |.else + | lwzux TMP2, RD, KBASE + | lwz TMP3, 4(RD) + |.endif + | lwzx UPVAL:RB, LFUNC:RB, RA + | ins_next1 + | lwz TMP1, UPVAL:RB->v + |.if FPU + | stfd f0, 0(TMP1) + |.else + | stw TMP2, 0(TMP1) + | stw TMP3, 4(TMP1) + |.endif + | ins_next2 + break; + case BC_USETP: + | // RA = uvnum*8, RD = primitive_type*8 (~) + | lwz LFUNC:RB, FRAME_FUNC(BASE) + | srwi RA, RA, 1 + | srwi TMP0, RD, 3 + | addi RA, RA, offsetof(GCfuncL, uvptr) + | not TMP0, TMP0 + | lwzx UPVAL:RB, LFUNC:RB, RA + | ins_next1 + | lwz TMP1, UPVAL:RB->v + | stw TMP0, 0(TMP1) + | ins_next2 + break; + + case BC_UCLO: + | // RA = level*8, RD = target + | lwz TMP1, L->openupval + | branch_RD // Do this first since RD is not saved. + | stp BASE, L->base + | cmplwi TMP1, 0 + | mr CARG1, L + | beq >1 + | add CARG2, BASE, RA + | bl extern lj_func_closeuv // (lua_State *L, TValue *level) + | lp BASE, L->base + |1: + | ins_next + break; + + case BC_FNEW: + | // RA = dst*8, RD = proto_const*8 (~) (holding function prototype) + | srwi TMP1, RD, 1 + | stp BASE, L->base + | subfic TMP1, TMP1, -4 + | stw PC, SAVE_PC + | lwzx CARG2, KBASE, TMP1 // KBASE-4-tab_const*4 + | mr CARG1, L + | lwz CARG3, FRAME_FUNC(BASE) + | // (lua_State *L, GCproto *pt, GCfuncL *parent) + | bl extern lj_func_newL_gc + | // Returns GCfuncL *. + | lp BASE, L->base + | li TMP0, LJ_TFUNC + | stwux TMP0, RA, BASE + | stw LFUNC:CRET1, 4(RA) + | ins_next + break; + + /* -- Table ops --------------------------------------------------------- */ + + case BC_TNEW: + case BC_TDUP: + | // RA = dst*8, RD = (hbits|asize)*8 | tab_const*8 (~) + | lwz TMP0, DISPATCH_GL(gc.total)(DISPATCH) + | mr CARG1, L + | lwz TMP1, DISPATCH_GL(gc.threshold)(DISPATCH) + | stp BASE, L->base + | cmplw TMP0, TMP1 + | stw PC, SAVE_PC + | bge >5 + |1: + if (op == BC_TNEW) { + | rlwinm CARG2, RD, 29, 21, 31 + | rlwinm CARG3, RD, 18, 27, 31 + | cmpwi CARG2, 0x7ff; beq >3 + |2: + | bl extern lj_tab_new // (lua_State *L, int32_t asize, uint32_t hbits) + | // Returns Table *. + } else { + | srwi TMP1, RD, 1 + | subfic TMP1, TMP1, -4 + | lwzx CARG2, KBASE, TMP1 // KBASE-4-tab_const*4 + | bl extern lj_tab_dup // (lua_State *L, Table *kt) + | // Returns Table *. + } + | lp BASE, L->base + | li TMP0, LJ_TTAB + | stwux TMP0, RA, BASE + | stw TAB:CRET1, 4(RA) + | ins_next + if (op == BC_TNEW) { + |3: + | li CARG2, 0x801 + | b <2 + } + |5: + | mr SAVE0, RD + | bl extern lj_gc_step_fixtop // (lua_State *L) + | mr RD, SAVE0 + | mr CARG1, L + | b <1 + break; + + case BC_GGET: + | // RA = dst*8, RD = str_const*8 (~) + case BC_GSET: + | // RA = src*8, RD = str_const*8 (~) + | lwz LFUNC:TMP2, FRAME_FUNC(BASE) + | srwi TMP1, RD, 1 + | lwz TAB:RB, LFUNC:TMP2->env + | subfic TMP1, TMP1, -4 + | lwzx STR:RC, KBASE, TMP1 // KBASE-4-str_const*4 + if (op == BC_GGET) { + | b ->BC_TGETS_Z + } else { + | b ->BC_TSETS_Z + } + break; + + case BC_TGETV: + | // RA = dst*8, RB = table*8, RC = key*8 + | lwzux CARG1, RB, BASE + | lwzux CARG2, RC, BASE + | lwz TAB:RB, 4(RB) + |.if DUALNUM + | lwz RC, 4(RC) + |.else + | lfd f0, 0(RC) + |.endif + | checktab CARG1 + | checknum cr1, CARG2 + | bne ->vmeta_tgetv + |.if DUALNUM + | lwz TMP0, TAB:RB->asize + | bne cr1, >5 + | lwz TMP1, TAB:RB->array + | cmplw TMP0, RC + | slwi TMP2, RC, 3 + |.else + | bge cr1, >5 + | // Convert number key to integer, check for integerness and range. + | fctiwz f1, f0 + | fadd f2, f0, TOBIT + | stfd f1, TMPD + | lwz TMP0, TAB:RB->asize + | fsub f2, f2, TOBIT + | lwz TMP2, TMPD_LO + | lwz TMP1, TAB:RB->array + | fcmpu cr1, f0, f2 + | cmplw cr0, TMP0, TMP2 + | crand 4*cr0+gt, 4*cr0+gt, 4*cr1+eq + | slwi TMP2, TMP2, 3 + |.endif + | ble ->vmeta_tgetv // Integer key and in array part? + | lwzx TMP0, TMP1, TMP2 + |.if FPU + | lfdx f14, TMP1, TMP2 + |.else + | lwzux SAVE0, TMP1, TMP2 + | lwz SAVE1, 4(TMP1) + |.endif + | checknil TMP0; beq >2 + |1: + | ins_next1 + |.if FPU + | stfdx f14, BASE, RA + |.else + | stwux SAVE0, RA, BASE + | stw SAVE1, 4(RA) + |.endif + | ins_next2 + | + |2: // Check for __index if table value is nil. + | lwz TAB:TMP2, TAB:RB->metatable + | cmplwi TAB:TMP2, 0 + | beq <1 // No metatable: done. + | lbz TMP0, TAB:TMP2->nomm + | andix. TMP0, TMP0, 1<vmeta_tgetv + | + |5: + | checkstr CARG2; bne ->vmeta_tgetv + |.if not DUALNUM + | lwz STR:RC, 4(RC) + |.endif + | b ->BC_TGETS_Z // String key? + break; + case BC_TGETS: + | // RA = dst*8, RB = table*8, RC = str_const*8 (~) + | lwzux CARG1, RB, BASE + | srwi TMP1, RC, 1 + | lwz TAB:RB, 4(RB) + | subfic TMP1, TMP1, -4 + | checktab CARG1 + | lwzx STR:RC, KBASE, TMP1 // KBASE-4-str_const*4 + | bne ->vmeta_tgets1 + |->BC_TGETS_Z: + | // TAB:RB = GCtab *, STR:RC = GCstr *, RA = dst*8 + | lwz TMP0, TAB:RB->hmask + | lwz TMP1, STR:RC->sid + | lwz NODE:TMP2, TAB:RB->node + | and TMP1, TMP1, TMP0 // idx = str->sid & tab->hmask + | slwi TMP0, TMP1, 5 + | slwi TMP1, TMP1, 3 + | sub TMP1, TMP0, TMP1 + | add NODE:TMP2, NODE:TMP2, TMP1 // node = tab->node + (idx*32-idx*8) + |1: + | lwz CARG1, NODE:TMP2->key + | lwz TMP0, 4+offsetof(Node, key)(NODE:TMP2) + | lwz CARG2, NODE:TMP2->val + | lwz TMP1, 4+offsetof(Node, val)(NODE:TMP2) + | checkstr CARG1; bne >4 + | cmpw TMP0, STR:RC; bne >4 + | checknil CARG2; beq >5 // Key found, but nil value? + |3: + | stwux CARG2, RA, BASE + | stw TMP1, 4(RA) + | ins_next + | + |4: // Follow hash chain. + | lwz NODE:TMP2, NODE:TMP2->next + | cmplwi NODE:TMP2, 0 + | bne <1 + | // End of hash chain: key not found, nil result. + | li CARG2, LJ_TNIL + | + |5: // Check for __index if table value is nil. + | lwz TAB:TMP2, TAB:RB->metatable + | cmplwi TAB:TMP2, 0 + | beq <3 // No metatable: done. + | lbz TMP0, TAB:TMP2->nomm + | andix. TMP0, TMP0, 1<vmeta_tgets + break; + case BC_TGETB: + | // RA = dst*8, RB = table*8, RC = index*8 + | lwzux CARG1, RB, BASE + | srwi TMP0, RC, 3 + | lwz TAB:RB, 4(RB) + | checktab CARG1; bne ->vmeta_tgetb + | lwz TMP1, TAB:RB->asize + | lwz TMP2, TAB:RB->array + | cmplw TMP0, TMP1; bge ->vmeta_tgetb + |.if FPU + | lwzx TMP1, TMP2, RC + | lfdx f0, TMP2, RC + |.else + | lwzux TMP1, TMP2, RC + | lwz TMP3, 4(TMP2) + |.endif + | checknil TMP1; beq >5 + |1: + | ins_next1 + |.if FPU + | stfdx f0, BASE, RA + |.else + | stwux TMP1, RA, BASE + | stw TMP3, 4(RA) + |.endif + | ins_next2 + | + |5: // Check for __index if table value is nil. + | lwz TAB:TMP2, TAB:RB->metatable + | cmplwi TAB:TMP2, 0 + | beq <1 // No metatable: done. + | lbz TMP2, TAB:TMP2->nomm + | andix. TMP2, TMP2, 1<vmeta_tgetb // Caveat: preserve TMP0! + break; + case BC_TGETR: + | // RA = dst*8, RB = table*8, RC = key*8 + | add RB, BASE, RB + | lwz TAB:CARG1, 4(RB) + |.if DUALNUM + | add RC, BASE, RC + | lwz TMP0, TAB:CARG1->asize + | lwz CARG2, 4(RC) + | lwz TMP1, TAB:CARG1->array + |.else + | lfdx f0, BASE, RC + | lwz TMP0, TAB:CARG1->asize + | toint CARG2, f0 + | lwz TMP1, TAB:CARG1->array + |.endif + | cmplw TMP0, CARG2 + | slwi TMP2, CARG2, 3 + | ble ->vmeta_tgetr // In array part? + |.if FPU + | lfdx f14, TMP1, TMP2 + |.else + | lwzux SAVE0, TMP2, TMP1 + | lwz SAVE1, 4(TMP2) + |.endif + |->BC_TGETR_Z: + | ins_next1 + |.if FPU + | stfdx f14, BASE, RA + |.else + | stwux SAVE0, RA, BASE + | stw SAVE1, 4(RA) + |.endif + | ins_next2 + break; + + case BC_TSETV: + | // RA = src*8, RB = table*8, RC = key*8 + | lwzux CARG1, RB, BASE + | lwzux CARG2, RC, BASE + | lwz TAB:RB, 4(RB) + |.if DUALNUM + | lwz RC, 4(RC) + |.else + | lfd f0, 0(RC) + |.endif + | checktab CARG1 + | checknum cr1, CARG2 + | bne ->vmeta_tsetv + |.if DUALNUM + | lwz TMP0, TAB:RB->asize + | bne cr1, >5 + | lwz TMP1, TAB:RB->array + | cmplw TMP0, RC + | slwi TMP0, RC, 3 + |.else + | bge cr1, >5 + | // Convert number key to integer, check for integerness and range. + | fctiwz f1, f0 + | fadd f2, f0, TOBIT + | stfd f1, TMPD + | lwz TMP0, TAB:RB->asize + | fsub f2, f2, TOBIT + | lwz TMP2, TMPD_LO + | lwz TMP1, TAB:RB->array + | fcmpu cr1, f0, f2 + | cmplw cr0, TMP0, TMP2 + | crand 4*cr0+gt, 4*cr0+gt, 4*cr1+eq + | slwi TMP0, TMP2, 3 + |.endif + | ble ->vmeta_tsetv // Integer key and in array part? + | lwzx TMP2, TMP1, TMP0 + | lbz TMP3, TAB:RB->marked + |.if FPU + | lfdx f14, BASE, RA + |.else + | add SAVE1, BASE, RA + | lwz SAVE0, 0(SAVE1) + | lwz SAVE1, 4(SAVE1) + |.endif + | checknil TMP2; beq >3 + |1: + | andix. TMP2, TMP3, LJ_GC_BLACK // isblack(table) + |.if FPU + | stfdx f14, TMP1, TMP0 + |.else + | stwux SAVE0, TMP1, TMP0 + | stw SAVE1, 4(TMP1) + |.endif + | bne >7 + |2: + | ins_next + | + |3: // Check for __newindex if previous value is nil. + | lwz TAB:TMP2, TAB:RB->metatable + | cmplwi TAB:TMP2, 0 + | beq <1 // No metatable: done. + | lbz TMP2, TAB:TMP2->nomm + | andix. TMP2, TMP2, 1<vmeta_tsetv + | + |5: + | checkstr CARG2; bne ->vmeta_tsetv + |.if not DUALNUM + | lwz STR:RC, 4(RC) + |.endif + | b ->BC_TSETS_Z // String key? + | + |7: // Possible table write barrier for the value. Skip valiswhite check. + | barrierback TAB:RB, TMP3, TMP0 + | b <2 + break; + case BC_TSETS: + | // RA = src*8, RB = table*8, RC = str_const*8 (~) + | lwzux CARG1, RB, BASE + | srwi TMP1, RC, 1 + | lwz TAB:RB, 4(RB) + | subfic TMP1, TMP1, -4 + | checktab CARG1 + | lwzx STR:RC, KBASE, TMP1 // KBASE-4-str_const*4 + | bne ->vmeta_tsets1 + |->BC_TSETS_Z: + | // TAB:RB = GCtab *, STR:RC = GCstr *, RA = src*8 + | lwz TMP0, TAB:RB->hmask + | lwz TMP1, STR:RC->sid + | lwz NODE:TMP2, TAB:RB->node + | stb ZERO, TAB:RB->nomm // Clear metamethod cache. + | and TMP1, TMP1, TMP0 // idx = str->sid & tab->hmask + |.if FPU + | lfdx f14, BASE, RA + |.else + | add CARG2, BASE, RA + | lwz SAVE0, 0(CARG2) + | lwz SAVE1, 4(CARG2) + |.endif + | slwi TMP0, TMP1, 5 + | slwi TMP1, TMP1, 3 + | sub TMP1, TMP0, TMP1 + | lbz TMP3, TAB:RB->marked + | add NODE:TMP2, NODE:TMP2, TMP1 // node = tab->node + (idx*32-idx*8) + |1: + | lwz CARG1, NODE:TMP2->key + | lwz TMP0, 4+offsetof(Node, key)(NODE:TMP2) + | lwz CARG2, NODE:TMP2->val + | lwz NODE:TMP1, NODE:TMP2->next + | checkstr CARG1; bne >5 + | cmpw TMP0, STR:RC; bne >5 + | checknil CARG2; beq >4 // Key found, but nil value? + |2: + | andix. TMP0, TMP3, LJ_GC_BLACK // isblack(table) + |.if FPU + | stfd f14, NODE:TMP2->val + |.else + | stw SAVE0, NODE:TMP2->val.u32.hi + | stw SAVE1, NODE:TMP2->val.u32.lo + |.endif + | bne >7 + |3: + | ins_next + | + |4: // Check for __newindex if previous value is nil. + | lwz TAB:TMP1, TAB:RB->metatable + | cmplwi TAB:TMP1, 0 + | beq <2 // No metatable: done. + | lbz TMP0, TAB:TMP1->nomm + | andix. TMP0, TMP0, 1<vmeta_tsets + | + |5: // Follow hash chain. + | cmplwi NODE:TMP1, 0 + | mr NODE:TMP2, NODE:TMP1 + | bne <1 + | // End of hash chain: key not found, add a new one. + | + | // But check for __newindex first. + | lwz TAB:TMP1, TAB:RB->metatable + | la CARG3, DISPATCH_GL(tmptv)(DISPATCH) + | stw PC, SAVE_PC + | mr CARG1, L + | cmplwi TAB:TMP1, 0 + | stp BASE, L->base + | beq >6 // No metatable: continue. + | lbz TMP0, TAB:TMP1->nomm + | andix. TMP0, TMP0, 1<vmeta_tsets // 'no __newindex' flag NOT set: check. + |6: + | li TMP0, LJ_TSTR + | stw STR:RC, 4(CARG3) + | mr CARG2, TAB:RB + | stw TMP0, 0(CARG3) + | bl extern lj_tab_newkey // (lua_State *L, GCtab *t, TValue *k) + | // Returns TValue *. + | lp BASE, L->base + |.if FPU + | stfd f14, 0(CRET1) + |.else + | stw SAVE0, 0(CRET1) + | stw SAVE1, 4(CRET1) + |.endif + | b <3 // No 2nd write barrier needed. + | + |7: // Possible table write barrier for the value. Skip valiswhite check. + | barrierback TAB:RB, TMP3, TMP0 + | b <3 + break; + case BC_TSETB: + | // RA = src*8, RB = table*8, RC = index*8 + | lwzux CARG1, RB, BASE + | srwi TMP0, RC, 3 + | lwz TAB:RB, 4(RB) + | checktab CARG1; bne ->vmeta_tsetb + | lwz TMP1, TAB:RB->asize + | lwz TMP2, TAB:RB->array + | lbz TMP3, TAB:RB->marked + | cmplw TMP0, TMP1 + |.if FPU + | lfdx f14, BASE, RA + |.else + | add CARG2, BASE, RA + | lwz SAVE0, 0(CARG2) + | lwz SAVE1, 4(CARG2) + |.endif + | bge ->vmeta_tsetb + | lwzx TMP1, TMP2, RC + | checknil TMP1; beq >5 + |1: + | andix. TMP0, TMP3, LJ_GC_BLACK // isblack(table) + |.if FPU + | stfdx f14, TMP2, RC + |.else + | stwux SAVE0, RC, TMP2 + | stw SAVE1, 4(RC) + |.endif + | bne >7 + |2: + | ins_next + | + |5: // Check for __newindex if previous value is nil. + | lwz TAB:TMP1, TAB:RB->metatable + | cmplwi TAB:TMP1, 0 + | beq <1 // No metatable: done. + | lbz TMP1, TAB:TMP1->nomm + | andix. TMP1, TMP1, 1<vmeta_tsetb // Caveat: preserve TMP0! + | + |7: // Possible table write barrier for the value. Skip valiswhite check. + | barrierback TAB:RB, TMP3, TMP0 + | b <2 + break; + case BC_TSETR: + | // RA = dst*8, RB = table*8, RC = key*8 + | add RB, BASE, RB + | lwz TAB:CARG2, 4(RB) + |.if DUALNUM + | add RC, BASE, RC + | lbz TMP3, TAB:CARG2->marked + | lwz TMP0, TAB:CARG2->asize + | lwz CARG3, 4(RC) + | lwz TMP1, TAB:CARG2->array + |.else + | lfdx f0, BASE, RC + | lbz TMP3, TAB:CARG2->marked + | lwz TMP0, TAB:CARG2->asize + | toint CARG3, f0 + | lwz TMP1, TAB:CARG2->array + |.endif + | andix. TMP2, TMP3, LJ_GC_BLACK // isblack(table) + | bne >7 + |2: + | cmplw TMP0, CARG3 + | slwi TMP2, CARG3, 3 + |.if FPU + | lfdx f14, BASE, RA + |.else + | lwzux SAVE0, RA, BASE + | lwz SAVE1, 4(RA) + |.endif + | ble ->vmeta_tsetr // In array part? + | ins_next1 + |.if FPU + | stfdx f14, TMP1, TMP2 + |.else + | stwux SAVE0, TMP1, TMP2 + | stw SAVE1, 4(TMP1) + |.endif + | ins_next2 + | + |7: // Possible table write barrier for the value. Skip valiswhite check. + | barrierback TAB:CARG2, TMP3, TMP2 + | b <2 + break; + + + case BC_TSETM: + | // RA = base*8 (table at base-1), RD = num_const*8 (start index) + | add RA, BASE, RA + |1: + | add TMP3, KBASE, RD + | lwz TAB:CARG2, -4(RA) // Guaranteed to be a table. + | addic. TMP0, MULTRES, -8 + | lwz TMP3, 4(TMP3) // Integer constant is in lo-word. + | srwi CARG3, TMP0, 3 + | beq >4 // Nothing to copy? + | add CARG3, CARG3, TMP3 + | lwz TMP2, TAB:CARG2->asize + | slwi TMP1, TMP3, 3 + | lbz TMP3, TAB:CARG2->marked + | cmplw CARG3, TMP2 + | add TMP2, RA, TMP0 + | lwz TMP0, TAB:CARG2->array + | bgt >5 + | add TMP1, TMP1, TMP0 + | andix. TMP0, TMP3, LJ_GC_BLACK // isblack(table) + |3: // Copy result slots to table. + |.if FPU + | lfd f0, 0(RA) + |.else + | lwz SAVE0, 0(RA) + | lwz SAVE1, 4(RA) + |.endif + | addi RA, RA, 8 + | cmpw cr1, RA, TMP2 + |.if FPU + | stfd f0, 0(TMP1) + |.else + | stw SAVE0, 0(TMP1) + | stw SAVE1, 4(TMP1) + |.endif + | addi TMP1, TMP1, 8 + | blt cr1, <3 + | bne >7 + |4: + | ins_next + | + |5: // Need to resize array part. + | stp BASE, L->base + | mr CARG1, L + | stw PC, SAVE_PC + | mr SAVE0, RD + | bl extern lj_tab_reasize // (lua_State *L, GCtab *t, int nasize) + | // Must not reallocate the stack. + | mr RD, SAVE0 + | b <1 + | + |7: // Possible table write barrier for any value. Skip valiswhite check. + | barrierback TAB:CARG2, TMP3, TMP0 + | b <4 + break; + + /* -- Calls and vararg handling ----------------------------------------- */ + + case BC_CALLM: + | // RA = base*8, (RB = (nresults+1)*8,) RC = extra_nargs*8 + | add NARGS8:RC, NARGS8:RC, MULTRES + | // Fall through. Assumes BC_CALL follows. + break; + case BC_CALL: + | // RA = base*8, (RB = (nresults+1)*8,) RC = (nargs+1)*8 + | mr TMP2, BASE + | lwzux TMP0, BASE, RA + | lwz LFUNC:RB, 4(BASE) + | subi NARGS8:RC, NARGS8:RC, 8 + | addi BASE, BASE, 8 + | checkfunc TMP0; bne ->vmeta_call + | ins_call + break; + + case BC_CALLMT: + | // RA = base*8, (RB = 0,) RC = extra_nargs*8 + | add NARGS8:RC, NARGS8:RC, MULTRES + | // Fall through. Assumes BC_CALLT follows. + break; + case BC_CALLT: + | // RA = base*8, (RB = 0,) RC = (nargs+1)*8 + | lwzux TMP0, RA, BASE + | lwz LFUNC:RB, 4(RA) + | subi NARGS8:RC, NARGS8:RC, 8 + | lwz TMP1, FRAME_PC(BASE) + | checkfunc TMP0 + | addi RA, RA, 8 + | bne ->vmeta_callt + |->BC_CALLT_Z: + | andix. TMP0, TMP1, FRAME_TYPE // Caveat: preserve cr0 until the crand. + | lbz TMP3, LFUNC:RB->ffid + | xori TMP2, TMP1, FRAME_VARG + | cmplwi cr1, NARGS8:RC, 0 + | bne >7 + |1: + | stw LFUNC:RB, FRAME_FUNC(BASE) // Copy function down, but keep PC. + | li TMP2, 0 + | cmplwi cr7, TMP3, 1 // (> FF_C) Calling a fast function? + | beq cr1, >3 + |2: + | addi TMP3, TMP2, 8 + |.if FPU + | lfdx f0, RA, TMP2 + |.else + | add CARG3, RA, TMP2 + | lwz CARG1, 0(CARG3) + | lwz CARG2, 4(CARG3) + |.endif + | cmplw cr1, TMP3, NARGS8:RC + |.if FPU + | stfdx f0, BASE, TMP2 + |.else + | stwux CARG1, TMP2, BASE + | stw CARG2, 4(TMP2) + |.endif + | mr TMP2, TMP3 + | bne cr1, <2 + |3: + | crand 4*cr0+eq, 4*cr0+eq, 4*cr7+gt + | beq >5 + |4: + | ins_callt + | + |5: // Tailcall to a fast function with a Lua frame below. + | lwz INS, -4(TMP1) + | decode_RA8 RA, INS + | sub TMP1, BASE, RA + | lwz LFUNC:TMP1, FRAME_FUNC-8(TMP1) + | lwz TMP1, LFUNC:TMP1->pc + | lwz KBASE, PC2PROTO(k)(TMP1) // Need to prepare KBASE. + | b <4 + | + |7: // Tailcall from a vararg function. + | andix. TMP0, TMP2, FRAME_TYPEP + | bne <1 // Vararg frame below? + | sub BASE, BASE, TMP2 // Relocate BASE down. + | lwz TMP1, FRAME_PC(BASE) + | andix. TMP0, TMP1, FRAME_TYPE + | b <1 + break; + + case BC_ITERC: + | // RA = base*8, (RB = (nresults+1)*8, RC = (nargs+1)*8 ((2+1)*8)) + | mr TMP2, BASE + | add BASE, BASE, RA + | lwz TMP1, -24(BASE) + | lwz LFUNC:RB, -20(BASE) + |.if FPU + | lfd f1, -8(BASE) + | lfd f0, -16(BASE) + |.else + | lwz CARG1, -8(BASE) + | lwz CARG2, -4(BASE) + | lwz CARG3, -16(BASE) + | lwz CARG4, -12(BASE) + |.endif + | stw TMP1, 0(BASE) // Copy callable. + | stw LFUNC:RB, 4(BASE) + | checkfunc TMP1 + | li NARGS8:RC, 16 // Iterators get 2 arguments. + |.if FPU + | stfd f1, 16(BASE) // Copy control var. + | stfdu f0, 8(BASE) // Copy state. + |.else + | stw CARG1, 16(BASE) // Copy control var. + | stw CARG2, 20(BASE) + | stwu CARG3, 8(BASE) // Copy state. + | stw CARG4, 4(BASE) + |.endif + | bne ->vmeta_call + | ins_call + break; + + case BC_ITERN: + | // RA = base*8, (RB = (nresults+1)*8, RC = (nargs+1)*8 (2+1)*8) + |.if JIT + | // NYI on big-endian + |.endif + |->vm_IITERN: + | add RA, BASE, RA + | lwz TAB:RB, -12(RA) + | lwz RC, -4(RA) // Get index from control var. + | lwz TMP0, TAB:RB->asize + | lwz TMP1, TAB:RB->array + | addi PC, PC, 4 + |1: // Traverse array part. + | cmplw RC, TMP0 + | slwi TMP3, RC, 3 + | bge >5 // Index points after array part? + | lwzx TMP2, TMP1, TMP3 + |.if FPU + | lfdx f0, TMP1, TMP3 + |.else + | lwzux CARG1, TMP3, TMP1 + | lwz CARG2, 4(TMP3) + |.endif + | checknil TMP2 + | lwz INS, -4(PC) + | beq >4 + |.if DUALNUM + | stw RC, 4(RA) + | stw TISNUM, 0(RA) + |.else + | tonum_u f1, RC + |.endif + | addi RC, RC, 1 + | addis TMP3, PC, -(BCBIAS_J*4 >> 16) + |.if FPU + | stfd f0, 8(RA) + |.else + | stw CARG1, 8(RA) + | stw CARG2, 12(RA) + |.endif + | decode_RD4 TMP1, INS + | stw RC, -4(RA) // Update control var. + | add PC, TMP1, TMP3 + |.if not DUALNUM + | stfd f1, 0(RA) + |.endif + |3: + | ins_next + | + |4: // Skip holes in array part. + | addi RC, RC, 1 + | b <1 + | + |5: // Traverse hash part. + | lwz TMP1, TAB:RB->hmask + | sub RC, RC, TMP0 + | lwz TMP2, TAB:RB->node + |6: + | cmplw RC, TMP1 // End of iteration? Branch to ITERL+1. + | slwi TMP3, RC, 5 + | bgty <3 + | slwi RB, RC, 3 + | sub TMP3, TMP3, RB + | lwzx RB, TMP2, TMP3 + |.if FPU + | lfdx f0, TMP2, TMP3 + |.else + | add CARG3, TMP2, TMP3 + | lwz CARG1, 0(CARG3) + | lwz CARG2, 4(CARG3) + |.endif + | add NODE:TMP3, TMP2, TMP3 + | checknil RB + | lwz INS, -4(PC) + | beq >7 + |.if FPU + | lfd f1, NODE:TMP3->key + |.else + | lwz CARG3, NODE:TMP3->key.u32.hi + | lwz CARG4, NODE:TMP3->key.u32.lo + |.endif + | addis TMP2, PC, -(BCBIAS_J*4 >> 16) + |.if FPU + | stfd f0, 8(RA) + |.else + | stw CARG1, 8(RA) + | stw CARG2, 12(RA) + |.endif + | add RC, RC, TMP0 + | decode_RD4 TMP1, INS + |.if FPU + | stfd f1, 0(RA) + |.else + | stw CARG3, 0(RA) + | stw CARG4, 4(RA) + |.endif + | addi RC, RC, 1 + | add PC, TMP1, TMP2 + | stw RC, -4(RA) // Update control var. + | b <3 + | + |7: // Skip holes in hash part. + | addi RC, RC, 1 + | b <6 + break; + + case BC_ISNEXT: + | // RA = base*8, RD = target (points to ITERN) + | add RA, BASE, RA + | lwz TMP0, -24(RA) + | lwz CFUNC:TMP1, -20(RA) + | lwz TMP2, -16(RA) + | lwz TMP3, -8(RA) + | cmpwi cr0, TMP2, LJ_TTAB + | cmpwi cr1, TMP0, LJ_TFUNC + | cmpwi cr6, TMP3, LJ_TNIL + | bne cr1, >5 + | lbz TMP1, CFUNC:TMP1->ffid + | crand 4*cr0+eq, 4*cr0+eq, 4*cr6+eq + | cmpwi cr7, TMP1, FF_next_N + | srwi TMP0, RD, 1 + | crand 4*cr0+eq, 4*cr0+eq, 4*cr7+eq + | add TMP3, PC, TMP0 + | bne cr0, >5 + | lus TMP1, (LJ_KEYINDEX >> 16) + | ori TMP1, TMP1, (LJ_KEYINDEX & 0xffff) + | stw ZERO, -4(RA) // Initialize control var. + | stw TMP1, -8(RA) + | addis PC, TMP3, -(BCBIAS_J*4 >> 16) + |1: + | ins_next + |5: // Despecialize bytecode if any of the checks fail. + | li TMP0, BC_JMP + | li TMP1, BC_ITERC + | stb TMP0, -1(PC) + | addis PC, TMP3, -(BCBIAS_J*4 >> 16) + | // NYI on big-endian: unpatch JLOOP. + | stb TMP1, 3(PC) + | b <1 + break; + + case BC_VARG: + | // RA = base*8, RB = (nresults+1)*8, RC = numparams*8 + | lwz TMP0, FRAME_PC(BASE) + | add RC, BASE, RC + | add RA, BASE, RA + | addi RC, RC, FRAME_VARG + | add TMP2, RA, RB + | subi TMP3, BASE, 8 // TMP3 = vtop + | sub RC, RC, TMP0 // RC = vbase + | // Note: RC may now be even _above_ BASE if nargs was < numparams. + | cmplwi cr1, RB, 0 + |.if PPE + | sub TMP1, TMP3, RC + | cmpwi TMP1, 0 + |.else + | sub. TMP1, TMP3, RC + |.endif + | beq cr1, >5 // Copy all varargs? + | subi TMP2, TMP2, 16 + | ble >2 // No vararg slots? + |1: // Copy vararg slots to destination slots. + |.if FPU + | lfd f0, 0(RC) + |.else + | lwz CARG1, 0(RC) + | lwz CARG2, 4(RC) + |.endif + | addi RC, RC, 8 + |.if FPU + | stfd f0, 0(RA) + |.else + | stw CARG1, 0(RA) + | stw CARG2, 4(RA) + |.endif + | cmplw RA, TMP2 + | cmplw cr1, RC, TMP3 + | bge >3 // All destination slots filled? + | addi RA, RA, 8 + | blt cr1, <1 // More vararg slots? + |2: // Fill up remainder with nil. + | stw TISNIL, 0(RA) + | cmplw RA, TMP2 + | addi RA, RA, 8 + | blt <2 + |3: + | ins_next + | + |5: // Copy all varargs. + | lwz TMP0, L->maxstack + | li MULTRES, 8 // MULTRES = (0+1)*8 + | bley <3 // No vararg slots? + | add TMP2, RA, TMP1 + | cmplw TMP2, TMP0 + | addi MULTRES, TMP1, 8 + | bgt >7 + |6: + |.if FPU + | lfd f0, 0(RC) + |.else + | lwz CARG1, 0(RC) + | lwz CARG2, 4(RC) + |.endif + | addi RC, RC, 8 + |.if FPU + | stfd f0, 0(RA) + |.else + | stw CARG1, 0(RA) + | stw CARG2, 4(RA) + |.endif + | cmplw RC, TMP3 + | addi RA, RA, 8 + | blt <6 // More vararg slots? + | b <3 + | + |7: // Grow stack for varargs. + | mr CARG1, L + | stp RA, L->top + | sub SAVE0, RC, BASE // Need delta, because BASE may change. + | stp BASE, L->base + | sub RA, RA, BASE + | stw PC, SAVE_PC + | srwi CARG2, TMP1, 3 + | bl extern lj_state_growstack // (lua_State *L, int n) + | lp BASE, L->base + | add RA, BASE, RA + | add RC, BASE, SAVE0 + | subi TMP3, BASE, 8 + | b <6 + break; + + /* -- Returns ----------------------------------------------------------- */ + + case BC_RETM: + | // RA = results*8, RD = extra_nresults*8 + | add RD, RD, MULTRES // MULTRES >= 8, so RD >= 8. + | // Fall through. Assumes BC_RET follows. + break; + + case BC_RET: + | // RA = results*8, RD = (nresults+1)*8 + | lwz PC, FRAME_PC(BASE) + | add RA, BASE, RA + | mr MULTRES, RD + |1: + | andix. TMP0, PC, FRAME_TYPE + | xori TMP1, PC, FRAME_VARG + | bne ->BC_RETV_Z + | + |->BC_RET_Z: + | // BASE = base, RA = resultptr, RD = (nresults+1)*8, PC = return + | lwz INS, -4(PC) + | cmpwi RD, 8 + | subi TMP2, BASE, 8 + | subi RC, RD, 8 + | decode_RB8 RB, INS + | beq >3 + | li TMP1, 0 + |2: + | addi TMP3, TMP1, 8 + |.if FPU + | lfdx f0, RA, TMP1 + |.else + | add CARG3, RA, TMP1 + | lwz CARG1, 0(CARG3) + | lwz CARG2, 4(CARG3) + |.endif + | cmpw TMP3, RC + |.if FPU + | stfdx f0, TMP2, TMP1 + |.else + | add CARG3, TMP2, TMP1 + | stw CARG1, 0(CARG3) + | stw CARG2, 4(CARG3) + |.endif + | beq >3 + | addi TMP1, TMP3, 8 + |.if FPU + | lfdx f1, RA, TMP3 + |.else + | add CARG3, RA, TMP3 + | lwz CARG1, 0(CARG3) + | lwz CARG2, 4(CARG3) + |.endif + | cmpw TMP1, RC + |.if FPU + | stfdx f1, TMP2, TMP3 + |.else + | add CARG3, TMP2, TMP3 + | stw CARG1, 0(CARG3) + | stw CARG2, 4(CARG3) + |.endif + | bne <2 + |3: + |5: + | cmplw RB, RD + | decode_RA8 RA, INS + | bgt >6 + | sub BASE, TMP2, RA + | lwz LFUNC:TMP1, FRAME_FUNC(BASE) + | ins_next1 + | lwz TMP1, LFUNC:TMP1->pc + | lwz KBASE, PC2PROTO(k)(TMP1) + | ins_next2 + | + |6: // Fill up results with nil. + | subi TMP1, RD, 8 + | addi RD, RD, 8 + | stwx TISNIL, TMP2, TMP1 + | b <5 + | + |->BC_RETV_Z: // Non-standard return case. + | andix. TMP2, TMP1, FRAME_TYPEP + | bne ->vm_return + | // Return from vararg function: relocate BASE down. + | sub BASE, BASE, TMP1 + | lwz PC, FRAME_PC(BASE) + | b <1 + break; + + case BC_RET0: case BC_RET1: + | // RA = results*8, RD = (nresults+1)*8 + | lwz PC, FRAME_PC(BASE) + | add RA, BASE, RA + | mr MULTRES, RD + | andix. TMP0, PC, FRAME_TYPE + | xori TMP1, PC, FRAME_VARG + | bney ->BC_RETV_Z + | + | lwz INS, -4(PC) + | subi TMP2, BASE, 8 + | decode_RB8 RB, INS + if (op == BC_RET1) { + |.if FPU + | lfd f0, 0(RA) + | stfd f0, 0(TMP2) + |.else + | lwz CARG1, 0(RA) + | lwz CARG2, 4(RA) + | stw CARG1, 0(TMP2) + | stw CARG2, 4(TMP2) + |.endif + } + |5: + | cmplw RB, RD + | decode_RA8 RA, INS + | bgt >6 + | sub BASE, TMP2, RA + | lwz LFUNC:TMP1, FRAME_FUNC(BASE) + | ins_next1 + | lwz TMP1, LFUNC:TMP1->pc + | lwz KBASE, PC2PROTO(k)(TMP1) + | ins_next2 + | + |6: // Fill up results with nil. + | subi TMP1, RD, 8 + | addi RD, RD, 8 + | stwx TISNIL, TMP2, TMP1 + | b <5 + break; + + /* -- Loops and branches ------------------------------------------------ */ + + case BC_FORL: + |.if JIT + | hotloop + |.endif + | // Fall through. Assumes BC_IFORL follows. + break; + + case BC_JFORI: + case BC_JFORL: +#if !LJ_HASJIT + break; +#endif + case BC_FORI: + case BC_IFORL: + | // RA = base*8, RD = target (after end of loop or start of loop) + vk = (op == BC_IFORL || op == BC_JFORL); + |.if DUALNUM + | // Integer loop. + | lwzux TMP1, RA, BASE + | lwz CARG1, FORL_IDX*8+4(RA) + | cmplw cr0, TMP1, TISNUM + if (vk) { + | lwz CARG3, FORL_STEP*8+4(RA) + | bne >9 + |.if GPR64 + | // Need to check overflow for (a<<32) + (b<<32). + | rldicr TMP0, CARG1, 32, 31 + | rldicr TMP2, CARG3, 32, 31 + | add CARG1, CARG1, CARG3 + | addo. TMP0, TMP0, TMP2 + |.else + | addo. CARG1, CARG1, CARG3 + |.endif + | cmpwi cr6, CARG3, 0 + | lwz CARG2, FORL_STOP*8+4(RA) + | bso >6 + |4: + | stw CARG1, FORL_IDX*8+4(RA) + } else { + | lwz SAVE0, FORL_STEP*8(RA) + | lwz CARG3, FORL_STEP*8+4(RA) + | lwz TMP2, FORL_STOP*8(RA) + | lwz CARG2, FORL_STOP*8+4(RA) + | cmplw cr7, SAVE0, TISNUM + | cmplw cr1, TMP2, TISNUM + | crand 4*cr0+eq, 4*cr0+eq, 4*cr7+eq + | crand 4*cr0+eq, 4*cr0+eq, 4*cr1+eq + | cmpwi cr6, CARG3, 0 + | bne >9 + } + | blt cr6, >5 + | cmpw CARG1, CARG2 + |1: + | stw TISNUM, FORL_EXT*8(RA) + if (op != BC_JFORL) { + | srwi RD, RD, 1 + } + | stw CARG1, FORL_EXT*8+4(RA) + if (op != BC_JFORL) { + | add RD, PC, RD + } + if (op == BC_FORI) { + | bgt >3 // See FP loop below. + } else if (op == BC_JFORI) { + | addis PC, RD, -(BCBIAS_J*4 >> 16) + | bley >7 + } else if (op == BC_IFORL) { + | bgt >2 + | addis PC, RD, -(BCBIAS_J*4 >> 16) + } else { + | bley =>BC_JLOOP + } + |2: + | ins_next + |5: // Invert check for negative step. + | cmpw CARG2, CARG1 + | b <1 + if (vk) { + |6: // Potential overflow. + | checkov TMP0, <4 // Ignore unrelated overflow. + | b <2 + } + |.endif + if (vk) { + |.if DUALNUM + |9: // FP loop. + |.if FPU + | lfd f1, FORL_IDX*8(RA) + |.else + | lwz CARG1, FORL_IDX*8(RA) + | lwz CARG2, FORL_IDX*8+4(RA) + |.endif + |.else + | lfdux f1, RA, BASE + |.endif + |.if FPU + | lfd f3, FORL_STEP*8(RA) + | lfd f2, FORL_STOP*8(RA) + | fadd f1, f1, f3 + | stfd f1, FORL_IDX*8(RA) + |.else + | lwz CARG3, FORL_STEP*8(RA) + | lwz CARG4, FORL_STEP*8+4(RA) + | mr SAVE1, RD + | blex __adddf3 + | mr RD, SAVE1 + | stw CRET1, FORL_IDX*8(RA) + | stw CRET2, FORL_IDX*8+4(RA) + | lwz CARG3, FORL_STOP*8(RA) + | lwz CARG4, FORL_STOP*8+4(RA) + |.endif + | lwz SAVE0, FORL_STEP*8(RA) + } else { + |.if DUALNUM + |9: // FP loop. + |.else + | lwzux TMP1, RA, BASE + | lwz SAVE0, FORL_STEP*8(RA) + | lwz TMP2, FORL_STOP*8(RA) + | cmplw cr0, TMP1, TISNUM + | cmplw cr7, SAVE0, TISNUM + | cmplw cr1, TMP2, TISNUM + |.endif + |.if FPU + | lfd f1, FORL_IDX*8(RA) + |.else + | lwz CARG1, FORL_IDX*8(RA) + | lwz CARG2, FORL_IDX*8+4(RA) + |.endif + | crand 4*cr0+lt, 4*cr0+lt, 4*cr7+lt + | crand 4*cr0+lt, 4*cr0+lt, 4*cr1+lt + |.if FPU + | lfd f2, FORL_STOP*8(RA) + |.else + | lwz CARG3, FORL_STOP*8(RA) + | lwz CARG4, FORL_STOP*8+4(RA) + |.endif + | bge ->vmeta_for + } + | cmpwi cr6, SAVE0, 0 + if (op != BC_JFORL) { + | srwi RD, RD, 1 + } + |.if FPU + | stfd f1, FORL_EXT*8(RA) + |.else + | stw CARG1, FORL_EXT*8(RA) + | stw CARG2, FORL_EXT*8+4(RA) + |.endif + if (op != BC_JFORL) { + | add RD, PC, RD + } + |.if FPU + | fcmpu cr0, f1, f2 + |.else + | mr SAVE1, RD + | blex __ledf2 + | cmpwi CRET1, 0 + | mr RD, SAVE1 + |.endif + if (op == BC_JFORI) { + | addis PC, RD, -(BCBIAS_J*4 >> 16) + } + | blt cr6, >5 + if (op == BC_FORI) { + | bgt >3 + } else if (op == BC_IFORL) { + |.if DUALNUM + | bgty <2 + |.else + | bgt >2 + |.endif + |1: + | addis PC, RD, -(BCBIAS_J*4 >> 16) + } else if (op == BC_JFORI) { + | bley >7 + } else { + | bley =>BC_JLOOP + } + |.if DUALNUM + | b <2 + |.else + |2: + | ins_next + |.endif + |5: // Negative step. + if (op == BC_FORI) { + | bge <2 + |3: // Used by integer loop, too. + | addis PC, RD, -(BCBIAS_J*4 >> 16) + } else if (op == BC_IFORL) { + | bgey <1 + } else if (op == BC_JFORI) { + | bgey >7 + } else { + | bgey =>BC_JLOOP + } + | b <2 + if (op == BC_JFORI) { + |7: + | lwz INS, -4(PC) + | decode_RD8 RD, INS + | b =>BC_JLOOP + } + break; + + case BC_ITERL: + |.if JIT + | hotloop + |.endif + | // Fall through. Assumes BC_IITERL follows. + break; + + case BC_JITERL: +#if !LJ_HASJIT + break; +#endif + case BC_IITERL: + | // RA = base*8, RD = target + | lwzux TMP1, RA, BASE + | lwz TMP2, 4(RA) + | checknil TMP1; beq >1 // Stop if iterator returned nil. + if (op == BC_JITERL) { + | stw TMP1, -8(RA) + | stw TMP2, -4(RA) + | b =>BC_JLOOP + } else { + | branch_RD // Otherwise save control var + branch. + | stw TMP1, -8(RA) + | stw TMP2, -4(RA) + } + |1: + | ins_next + break; + + case BC_LOOP: + | // RA = base*8, RD = target (loop extent) + | // Note: RA/RD is only used by trace recorder to determine scope/extent + | // This opcode does NOT jump, it's only purpose is to detect a hot loop. + |.if JIT + | hotloop + |.endif + | // Fall through. Assumes BC_ILOOP follows. + break; + + case BC_ILOOP: + | // RA = base*8, RD = target (loop extent) + | ins_next + break; + + case BC_JLOOP: + |.if JIT + | // RA = base*8 (ignored), RD = traceno*8 + | lwz TMP1, DISPATCH_J(trace)(DISPATCH) + | srwi RD, RD, 1 + | // Traces on PPC don't store the trace number, so use 0. + | stw ZERO, DISPATCH_GL(vmstate)(DISPATCH) + | lwzx TRACE:TMP2, TMP1, RD + | clrso TMP1 + | lp TMP2, TRACE:TMP2->mcode + | stw BASE, DISPATCH_GL(jit_base)(DISPATCH) + | mtctr TMP2 + | addi JGL, DISPATCH, GG_DISP2G+32768 + | stw L, DISPATCH_GL(tmpbuf.L)(DISPATCH) + | bctr + |.endif + break; + + case BC_JMP: + | // RA = base*8 (only used by trace recorder), RD = target + | branch_RD + | ins_next + break; + + /* -- Function headers -------------------------------------------------- */ + + case BC_FUNCF: + |.if JIT + | hotcall + |.endif + case BC_FUNCV: /* NYI: compiled vararg functions. */ + | // Fall through. Assumes BC_IFUNCF/BC_IFUNCV follow. + break; + + case BC_JFUNCF: +#if !LJ_HASJIT + break; +#endif + case BC_IFUNCF: + | // BASE = new base, RA = BASE+framesize*8, RB = LFUNC, RC = nargs*8 + | lwz TMP2, L->maxstack + | lbz TMP1, -4+PC2PROTO(numparams)(PC) + | lwz KBASE, -4+PC2PROTO(k)(PC) + | cmplw RA, TMP2 + | slwi TMP1, TMP1, 3 + | bgt ->vm_growstack_l + if (op != BC_JFUNCF) { + | ins_next1 + } + |2: + | cmplw NARGS8:RC, TMP1 // Check for missing parameters. + | blt >3 + if (op == BC_JFUNCF) { + | decode_RD8 RD, INS + | b =>BC_JLOOP + } else { + | ins_next2 + } + | + |3: // Clear missing parameters. + | stwx TISNIL, BASE, NARGS8:RC + | addi NARGS8:RC, NARGS8:RC, 8 + | b <2 + break; + + case BC_JFUNCV: +#if !LJ_HASJIT + break; +#endif + | NYI // NYI: compiled vararg functions + break; /* NYI: compiled vararg functions. */ + + case BC_IFUNCV: + | // BASE = new base, RA = BASE+framesize*8, RB = LFUNC, RC = nargs*8 + | lwz TMP2, L->maxstack + | add TMP1, BASE, RC + | add TMP0, RA, RC + | stw LFUNC:RB, 4(TMP1) // Store copy of LFUNC. + | addi TMP3, RC, 8+FRAME_VARG + | lwz KBASE, -4+PC2PROTO(k)(PC) + | cmplw TMP0, TMP2 + | stw TMP3, 0(TMP1) // Store delta + FRAME_VARG. + | bge ->vm_growstack_l + | lbz TMP2, -4+PC2PROTO(numparams)(PC) + | mr RA, BASE + | mr RC, TMP1 + | ins_next1 + | cmpwi TMP2, 0 + | addi BASE, TMP1, 8 + | beq >3 + |1: + | cmplw RA, RC // Less args than parameters? + | lwz TMP0, 0(RA) + | lwz TMP3, 4(RA) + | bge >4 + | stw TISNIL, 0(RA) // Clear old fixarg slot (help the GC). + | addi RA, RA, 8 + |2: + | addic. TMP2, TMP2, -1 + | stw TMP0, 8(TMP1) + | stw TMP3, 12(TMP1) + | addi TMP1, TMP1, 8 + | bne <1 + |3: + | ins_next2 + | + |4: // Clear missing parameters. + | li TMP0, LJ_TNIL + | b <2 + break; + + case BC_FUNCC: + case BC_FUNCCW: + | // BASE = new base, RA = BASE+framesize*8, RB = CFUNC, RC = nargs*8 + if (op == BC_FUNCC) { + | lp RD, CFUNC:RB->f + } else { + | lp RD, DISPATCH_GL(wrapf)(DISPATCH) + } + | add TMP1, RA, NARGS8:RC + | lwz TMP2, L->maxstack + | .toc lp TMP3, 0(RD) + | add RC, BASE, NARGS8:RC + | stp BASE, L->base + | cmplw TMP1, TMP2 + | stp RC, L->top + | li_vmstate C + |.if TOC + | mtctr TMP3 + |.else + | mtctr RD + |.endif + if (op == BC_FUNCCW) { + | lp CARG2, CFUNC:RB->f + } + | mr CARG1, L + | bgt ->vm_growstack_c // Need to grow stack. + | .toc lp TOCREG, TOC_OFS(RD) + | .tocenv lp ENVREG, ENV_OFS(RD) + | st_vmstate + | bctrl // (lua_State *L [, lua_CFunction f]) + | // Returns nresults. + | lp BASE, L->base + | .toc ld TOCREG, SAVE_TOC + | slwi RD, CRET1, 3 + | lp TMP1, L->top + | li_vmstate INTERP + | lwz PC, FRAME_PC(BASE) // Fetch PC of caller. + | stw L, DISPATCH_GL(cur_L)(DISPATCH) + | sub RA, TMP1, RD // RA = L->top - nresults*8 + | st_vmstate + | b ->vm_returnc + break; + + /* ---------------------------------------------------------------------- */ + + default: + fprintf(stderr, "Error: undefined opcode BC_%s\n", bc_names[op]); + exit(2); + break; + } +} + +static int build_backend(BuildCtx *ctx) +{ + int op; + + dasm_growpc(Dst, BC__MAX); + + build_subroutines(ctx); + + |.code_op + for (op = 0; op < BC__MAX; op++) + build_ins(ctx, (BCOp)op, op); + + return BC__MAX; +} + +/* Emit pseudo frame-info for all assembler functions. */ +static void emit_asm_debug(BuildCtx *ctx) +{ + int fcofs = (int)((uint8_t *)ctx->glob[GLOB_vm_ffi_call] - ctx->code); + int i; + switch (ctx->mode) { + case BUILD_elfasm: + fprintf(ctx->fp, "\t.section .debug_frame,\"\",@progbits\n"); + fprintf(ctx->fp, + ".Lframe0:\n" + "\t.long .LECIE0-.LSCIE0\n" + ".LSCIE0:\n" + "\t.long 0xffffffff\n" + "\t.byte 0x1\n" + "\t.string \"\"\n" + "\t.uleb128 0x1\n" + "\t.sleb128 -4\n" + "\t.byte 65\n" + "\t.byte 0xc\n\t.uleb128 1\n\t.uleb128 0\n" + "\t.align 2\n" + ".LECIE0:\n\n"); + fprintf(ctx->fp, + ".LSFDE0:\n" + "\t.long .LEFDE0-.LASFDE0\n" + ".LASFDE0:\n" + "\t.long .Lframe0\n" + "\t.long .Lbegin\n" + "\t.long %d\n" + "\t.byte 0xe\n\t.uleb128 %d\n" + "\t.byte 0x11\n\t.uleb128 65\n\t.sleb128 -1\n" + "\t.byte 0x5\n\t.uleb128 70\n\t.uleb128 55\n", + fcofs, CFRAME_SIZE); + for (i = 14; i <= 31; i++) + fprintf(ctx->fp, + "\t.byte %d\n\t.uleb128 %d\n" + "\t.byte %d\n\t.uleb128 %d\n", + 0x80+i, 37+(31-i), 0x80+32+i, 2+2*(31-i)); + fprintf(ctx->fp, + "\t.align 2\n" + ".LEFDE0:\n\n"); +#if LJ_HASFFI + fprintf(ctx->fp, + ".LSFDE1:\n" + "\t.long .LEFDE1-.LASFDE1\n" + ".LASFDE1:\n" + "\t.long .Lframe0\n" +#if LJ_TARGET_PS3 + "\t.long .lj_vm_ffi_call\n" +#else + "\t.long lj_vm_ffi_call\n" +#endif + "\t.long %d\n" + "\t.byte 0x11\n\t.uleb128 65\n\t.sleb128 -1\n" + "\t.byte 0x8e\n\t.uleb128 2\n" + "\t.byte 0xd\n\t.uleb128 0xe\n" + "\t.align 2\n" + ".LEFDE1:\n\n", (int)ctx->codesz - fcofs); +#endif +#if !LJ_NO_UNWIND + fprintf(ctx->fp, "\t.section .eh_frame,\"a\",@progbits\n"); + fprintf(ctx->fp, + ".Lframe1:\n" + "\t.long .LECIE1-.LSCIE1\n" + ".LSCIE1:\n" + "\t.long 0\n" + "\t.byte 0x1\n" + "\t.string \"zPR\"\n" + "\t.uleb128 0x1\n" + "\t.sleb128 -4\n" + "\t.byte 65\n" + "\t.uleb128 6\n" /* augmentation length */ + "\t.byte 0x1b\n" /* pcrel|sdata4 */ + "\t.long lj_err_unwind_dwarf-.\n" + "\t.byte 0x1b\n" /* pcrel|sdata4 */ + "\t.byte 0xc\n\t.uleb128 1\n\t.uleb128 0\n" + "\t.align 2\n" + ".LECIE1:\n\n"); + fprintf(ctx->fp, + ".LSFDE2:\n" + "\t.long .LEFDE2-.LASFDE2\n" + ".LASFDE2:\n" + "\t.long .LASFDE2-.Lframe1\n" + "\t.long .Lbegin-.\n" + "\t.long %d\n" + "\t.uleb128 0\n" /* augmentation length */ + "\t.byte 0xe\n\t.uleb128 %d\n" + "\t.byte 0x11\n\t.uleb128 65\n\t.sleb128 -1\n" + "\t.byte 0x5\n\t.uleb128 70\n\t.uleb128 55\n", + fcofs, CFRAME_SIZE); + for (i = 14; i <= 31; i++) + fprintf(ctx->fp, + "\t.byte %d\n\t.uleb128 %d\n" + "\t.byte %d\n\t.uleb128 %d\n", + 0x80+i, 37+(31-i), 0x80+32+i, 2+2*(31-i)); + fprintf(ctx->fp, + "\t.align 2\n" + ".LEFDE2:\n\n"); +#if LJ_HASFFI + fprintf(ctx->fp, + ".Lframe2:\n" + "\t.long .LECIE2-.LSCIE2\n" + ".LSCIE2:\n" + "\t.long 0\n" + "\t.byte 0x1\n" + "\t.string \"zR\"\n" + "\t.uleb128 0x1\n" + "\t.sleb128 -4\n" + "\t.byte 65\n" + "\t.uleb128 1\n" /* augmentation length */ + "\t.byte 0x1b\n" /* pcrel|sdata4 */ + "\t.byte 0xc\n\t.uleb128 1\n\t.uleb128 0\n" + "\t.align 2\n" + ".LECIE2:\n\n"); + fprintf(ctx->fp, + ".LSFDE3:\n" + "\t.long .LEFDE3-.LASFDE3\n" + ".LASFDE3:\n" + "\t.long .LASFDE3-.Lframe2\n" + "\t.long lj_vm_ffi_call-.\n" + "\t.long %d\n" + "\t.uleb128 0\n" /* augmentation length */ + "\t.byte 0x11\n\t.uleb128 65\n\t.sleb128 -1\n" + "\t.byte 0x8e\n\t.uleb128 2\n" + "\t.byte 0xd\n\t.uleb128 0xe\n" + "\t.align 2\n" + ".LEFDE3:\n\n", (int)ctx->codesz - fcofs); +#endif +#endif + break; + default: + break; + } +} + diff --git a/fluent-bit/lib/luajit-3065c9/src/vm_x64.dasc b/fluent-bit/lib/luajit-3065c9/src/vm_x64.dasc new file mode 100644 index 00000000..03d96557 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/vm_x64.dasc @@ -0,0 +1,4935 @@ +|// Low-level VM code for x64 CPUs in LJ_GC64 mode. +|// Bytecode interpreter, fast functions and helper functions. +|// Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +| +|.arch x64 +|.section code_op, code_sub +| +|.actionlist build_actionlist +|.globals GLOB_ +|.globalnames globnames +|.externnames extnames +| +|//----------------------------------------------------------------------- +| +|.if WIN +|.define X64WIN, 1 // Windows/x64 calling conventions. +|.endif +| +|// Fixed register assignments for the interpreter. +|// This is very fragile and has many dependencies. Caveat emptor. +|.define BASE, rdx // Not C callee-save, refetched anyway. +|.if X64WIN +|.define KBASE, rdi // Must be C callee-save. +|.define PC, rsi // Must be C callee-save. +|.define DISPATCH, rbx // Must be C callee-save. +|.define KBASEd, edi +|.define PCd, esi +|.define DISPATCHd, ebx +|.else +|.define KBASE, r15 // Must be C callee-save. +|.define PC, rbx // Must be C callee-save. +|.define DISPATCH, r14 // Must be C callee-save. +|.define KBASEd, r15d +|.define PCd, ebx +|.define DISPATCHd, r14d +|.endif +| +|.define RA, rcx +|.define RAd, ecx +|.define RAH, ch +|.define RAL, cl +|.define RB, rbp // Must be rbp (C callee-save). +|.define RBd, ebp +|.define RC, rax // Must be rax. +|.define RCd, eax +|.define RCW, ax +|.define RCH, ah +|.define RCL, al +|.define OP, RBd +|.define RD, RC +|.define RDd, RCd +|.define RDW, RCW +|.define RDL, RCL +|.define TMPR, r10 +|.define TMPRd, r10d +|.define ITYPE, r11 +|.define ITYPEd, r11d +| +|.if X64WIN +|.define CARG1, rcx // x64/WIN64 C call arguments. +|.define CARG2, rdx +|.define CARG3, r8 +|.define CARG4, r9 +|.define CARG1d, ecx +|.define CARG2d, edx +|.define CARG3d, r8d +|.define CARG4d, r9d +|.else +|.define CARG1, rdi // x64/POSIX C call arguments. +|.define CARG2, rsi +|.define CARG3, rdx +|.define CARG4, rcx +|.define CARG5, r8 +|.define CARG6, r9 +|.define CARG1d, edi +|.define CARG2d, esi +|.define CARG3d, edx +|.define CARG4d, ecx +|.define CARG5d, r8d +|.define CARG6d, r9d +|.endif +| +|// Type definitions. Some of these are only used for documentation. +|.type L, lua_State +|.type GL, global_State +|.type TVALUE, TValue +|.type GCOBJ, GCobj +|.type STR, GCstr +|.type TAB, GCtab +|.type LFUNC, GCfuncL +|.type CFUNC, GCfuncC +|.type PROTO, GCproto +|.type UPVAL, GCupval +|.type NODE, Node +|.type NARGS, int +|.type TRACE, GCtrace +|.type SBUF, SBuf +| +|// Stack layout while in interpreter. Must match with lj_frame.h. +|//----------------------------------------------------------------------- +|.if X64WIN // x64/Windows stack layout +| +|.define CFRAME_SPACE, aword*5 // Delta for rsp (see <--). +|.macro saveregs_ +| push rdi; push rsi; push rbx +| sub rsp, CFRAME_SPACE +|.endmacro +|.macro saveregs +| push rbp; saveregs_ +|.endmacro +|.macro restoreregs +| add rsp, CFRAME_SPACE +| pop rbx; pop rsi; pop rdi; pop rbp +|.endmacro +| +|.define SAVE_CFRAME, aword [rsp+aword*13] +|.define SAVE_PC, aword [rsp+aword*12] +|.define SAVE_L, aword [rsp+aword*11] +|.define SAVE_ERRF, dword [rsp+dword*21] +|.define SAVE_NRES, dword [rsp+dword*20] +|//----- 16 byte aligned, ^^^ 32 byte register save area, owned by interpreter +|.define SAVE_RET, aword [rsp+aword*9] //<-- rsp entering interpreter. +|.define SAVE_R4, aword [rsp+aword*8] +|.define SAVE_R3, aword [rsp+aword*7] +|.define SAVE_R2, aword [rsp+aword*6] +|.define SAVE_R1, aword [rsp+aword*5] //<-- rsp after register saves. +|.define ARG5, aword [rsp+aword*4] +|.define CSAVE_4, aword [rsp+aword*3] +|.define CSAVE_3, aword [rsp+aword*2] +|.define CSAVE_2, aword [rsp+aword*1] +|.define CSAVE_1, aword [rsp] //<-- rsp while in interpreter. +|//----- 16 byte aligned, ^^^ 32 byte register save area, owned by callee +| +|.define ARG5d, dword [rsp+dword*8] +|.define TMP1, ARG5 // TMP1 overlaps ARG5 +|.define TMP1d, ARG5d +|.define TMP1hi, dword [rsp+dword*9] +|.define MULTRES, TMP1d // MULTRES overlaps TMP1d. +| +|//----------------------------------------------------------------------- +|.else // x64/POSIX stack layout +| +|.define CFRAME_SPACE, aword*5 // Delta for rsp (see <--). +|.macro saveregs_ +| push rbx; push r15; push r14 +|.if NO_UNWIND +| push r13; push r12 +|.endif +| sub rsp, CFRAME_SPACE +|.endmacro +|.macro saveregs +| push rbp; saveregs_ +|.endmacro +|.macro restoreregs +| add rsp, CFRAME_SPACE +|.if NO_UNWIND +| pop r12; pop r13 +|.endif +| pop r14; pop r15; pop rbx; pop rbp +|.endmacro +| +|//----- 16 byte aligned, +|.if NO_UNWIND +|.define SAVE_RET, aword [rsp+aword*11] //<-- rsp entering interpreter. +|.define SAVE_R4, aword [rsp+aword*10] +|.define SAVE_R3, aword [rsp+aword*9] +|.define SAVE_R2, aword [rsp+aword*8] +|.define SAVE_R1, aword [rsp+aword*7] +|.define SAVE_RU2, aword [rsp+aword*6] +|.define SAVE_RU1, aword [rsp+aword*5] //<-- rsp after register saves. +|.else +|.define SAVE_RET, aword [rsp+aword*9] //<-- rsp entering interpreter. +|.define SAVE_R4, aword [rsp+aword*8] +|.define SAVE_R3, aword [rsp+aword*7] +|.define SAVE_R2, aword [rsp+aword*6] +|.define SAVE_R1, aword [rsp+aword*5] //<-- rsp after register saves. +|.endif +|.define SAVE_CFRAME, aword [rsp+aword*4] +|.define SAVE_PC, aword [rsp+aword*3] +|.define SAVE_L, aword [rsp+aword*2] +|.define SAVE_ERRF, dword [rsp+dword*3] +|.define SAVE_NRES, dword [rsp+dword*2] +|.define TMP1, aword [rsp] //<-- rsp while in interpreter. +|//----- 16 byte aligned +| +|.define TMP1d, dword [rsp] +|.define TMP1hi, dword [rsp+dword*1] +|.define MULTRES, TMP1d // MULTRES overlaps TMP1d. +| +|.endif +| +|//----------------------------------------------------------------------- +| +|// Instruction headers. +|.macro ins_A; .endmacro +|.macro ins_AD; .endmacro +|.macro ins_AJ; .endmacro +|.macro ins_ABC; movzx RBd, RCH; movzx RCd, RCL; .endmacro +|.macro ins_AB_; movzx RBd, RCH; .endmacro +|.macro ins_A_C; movzx RCd, RCL; .endmacro +|.macro ins_AND; not RD; .endmacro +| +|// Instruction decode+dispatch. Carefully tuned (nope, lodsd is not faster). +|.macro ins_NEXT +| mov RCd, [PC] +| movzx RAd, RCH +| movzx OP, RCL +| add PC, 4 +| shr RCd, 16 +| jmp aword [DISPATCH+OP*8] +|.endmacro +| +|// Instruction footer. +|.if 1 +| // Replicated dispatch. Less unpredictable branches, but higher I-Cache use. +| .define ins_next, ins_NEXT +| .define ins_next_, ins_NEXT +|.else +| // Common dispatch. Lower I-Cache use, only one (very) unpredictable branch. +| // Affects only certain kinds of benchmarks (and only with -j off). +| // Around 10%-30% slower on Core2, a lot more slower on P4. +| .macro ins_next +| jmp ->ins_next +| .endmacro +| .macro ins_next_ +| ->ins_next: +| ins_NEXT +| .endmacro +|.endif +| +|// Call decode and dispatch. +|.macro ins_callt +| // BASE = new base, RB = LFUNC, RD = nargs+1, [BASE-8] = PC +| mov PC, LFUNC:RB->pc +| mov RAd, [PC] +| movzx OP, RAL +| movzx RAd, RAH +| add PC, 4 +| jmp aword [DISPATCH+OP*8] +|.endmacro +| +|.macro ins_call +| // BASE = new base, RB = LFUNC, RD = nargs+1 +| mov [BASE-8], PC +| ins_callt +|.endmacro +| +|//----------------------------------------------------------------------- +| +|// Macros to clear or set tags. +|.macro cleartp, reg; shl reg, 17; shr reg, 17; .endmacro +|.macro settp, reg, tp +| mov64 ITYPE, ((uint64_t)tp<<47) +| or reg, ITYPE +|.endmacro +|.macro settp, dst, reg, tp +| mov64 dst, ((uint64_t)tp<<47) +| or dst, reg +|.endmacro +|.macro setint, reg +| settp reg, LJ_TISNUM +|.endmacro +|.macro setint, dst, reg +| settp dst, reg, LJ_TISNUM +|.endmacro +| +|// Macros to test operand types. +|.macro checktp_nc, reg, tp, target +| mov ITYPE, reg +| sar ITYPE, 47 +| cmp ITYPEd, tp +| jne target +|.endmacro +|.macro checktp, reg, tp, target +| mov ITYPE, reg +| cleartp reg +| sar ITYPE, 47 +| cmp ITYPEd, tp +| jne target +|.endmacro +|.macro checktptp, src, tp, target +| mov ITYPE, src +| sar ITYPE, 47 +| cmp ITYPEd, tp +| jne target +|.endmacro +|.macro checkstr, reg, target; checktp reg, LJ_TSTR, target; .endmacro +|.macro checktab, reg, target; checktp reg, LJ_TTAB, target; .endmacro +|.macro checkfunc, reg, target; checktp reg, LJ_TFUNC, target; .endmacro +| +|.macro checknumx, reg, target, jump +| mov ITYPE, reg +| sar ITYPE, 47 +| cmp ITYPEd, LJ_TISNUM +| jump target +|.endmacro +|.macro checkint, reg, target; checknumx reg, target, jne; .endmacro +|.macro checkinttp, src, target; checknumx src, target, jne; .endmacro +|.macro checknum, reg, target; checknumx reg, target, jae; .endmacro +|.macro checknumtp, src, target; checknumx src, target, jae; .endmacro +|.macro checknumber, src, target; checknumx src, target, ja; .endmacro +| +|.macro mov_false, reg; mov64 reg, (int64_t)~((uint64_t)1<<47); .endmacro +|.macro mov_true, reg; mov64 reg, (int64_t)~((uint64_t)2<<47); .endmacro +| +|// These operands must be used with movzx. +|.define PC_OP, byte [PC-4] +|.define PC_RA, byte [PC-3] +|.define PC_RB, byte [PC-1] +|.define PC_RC, byte [PC-2] +|.define PC_RD, word [PC-2] +| +|.macro branchPC, reg +| lea PC, [PC+reg*4-BCBIAS_J*4] +|.endmacro +| +|// Assumes DISPATCH is relative to GL. +#define DISPATCH_GL(field) (GG_DISP2G + (int)offsetof(global_State, field)) +#define DISPATCH_J(field) (GG_DISP2J + (int)offsetof(jit_State, field)) +| +#define PC2PROTO(field) ((int)offsetof(GCproto, field)-(int)sizeof(GCproto)) +| +|// Decrement hashed hotcount and trigger trace recorder if zero. +|.macro hotloop, reg +| mov reg, PCd +| shr reg, 1 +| and reg, HOTCOUNT_PCMASK +| sub word [DISPATCH+reg+GG_DISP2HOT], HOTCOUNT_LOOP +| jb ->vm_hotloop +|.endmacro +| +|.macro hotcall, reg +| mov reg, PCd +| shr reg, 1 +| and reg, HOTCOUNT_PCMASK +| sub word [DISPATCH+reg+GG_DISP2HOT], HOTCOUNT_CALL +| jb ->vm_hotcall +|.endmacro +| +|// Set current VM state. +|.macro set_vmstate, st +| mov dword [DISPATCH+DISPATCH_GL(vmstate)], ~LJ_VMST_..st +|.endmacro +| +|.macro fpop1; fstp st1; .endmacro +| +|// Synthesize SSE FP constants. +|.macro sseconst_abs, reg, tmp // Synthesize abs mask. +| mov64 tmp, U64x(7fffffff,ffffffff); movd reg, tmp +|.endmacro +| +|.macro sseconst_hi, reg, tmp, val // Synthesize hi-32 bit const. +| mov64 tmp, U64x(val,00000000); movd reg, tmp +|.endmacro +| +|.macro sseconst_sign, reg, tmp // Synthesize sign mask. +| sseconst_hi reg, tmp, 80000000 +|.endmacro +|.macro sseconst_1, reg, tmp // Synthesize 1.0. +| sseconst_hi reg, tmp, 3ff00000 +|.endmacro +|.macro sseconst_2p52, reg, tmp // Synthesize 2^52. +| sseconst_hi reg, tmp, 43300000 +|.endmacro +|.macro sseconst_tobit, reg, tmp // Synthesize 2^52 + 2^51. +| sseconst_hi reg, tmp, 43380000 +|.endmacro +| +|// Move table write barrier back. Overwrites reg. +|.macro barrierback, tab, reg +| and byte tab->marked, (uint8_t)~LJ_GC_BLACK // black2gray(tab) +| mov reg, [DISPATCH+DISPATCH_GL(gc.grayagain)] +| mov [DISPATCH+DISPATCH_GL(gc.grayagain)], tab +| mov tab->gclist, reg +|.endmacro +| +|//----------------------------------------------------------------------- + +/* Generate subroutines used by opcodes and other parts of the VM. */ +/* The .code_sub section should be last to help static branch prediction. */ +static void build_subroutines(BuildCtx *ctx) +{ + |.code_sub + | + |//----------------------------------------------------------------------- + |//-- Return handling ---------------------------------------------------- + |//----------------------------------------------------------------------- + | + |->vm_returnp: + | test PCd, FRAME_P + | jz ->cont_dispatch + | + | // Return from pcall or xpcall fast func. + | and PC, -8 + | sub BASE, PC // Restore caller base. + | lea RA, [RA+PC-8] // Rebase RA and prepend one result. + | mov PC, [BASE-8] // Fetch PC of previous frame. + | // Prepending may overwrite the pcall frame, so do it at the end. + | mov_true ITYPE + | mov aword [BASE+RA], ITYPE // Prepend true to results. + | + |->vm_returnc: + | add RDd, 1 // RD = nresults+1 + | jz ->vm_unwind_yield + | mov MULTRES, RDd + | test PC, FRAME_TYPE + | jz ->BC_RET_Z // Handle regular return to Lua. + | + |->vm_return: + | // BASE = base, RA = resultofs, RD = nresults+1 (= MULTRES), PC = return + | xor PC, FRAME_C + | test PCd, FRAME_TYPE + | jnz ->vm_returnp + | + | // Return to C. + | set_vmstate C + | and PC, -8 + | sub PC, BASE + | neg PC // Previous base = BASE - delta. + | + | sub RDd, 1 + | jz >2 + |1: // Move results down. + | mov RB, [BASE+RA] + | mov [BASE-16], RB + | add BASE, 8 + | sub RDd, 1 + | jnz <1 + |2: + | mov L:RB, SAVE_L + | mov L:RB->base, PC + |3: + | mov RDd, MULTRES + | mov RAd, SAVE_NRES // RA = wanted nresults+1 + |4: + | cmp RAd, RDd + | jne >6 // More/less results wanted? + |5: + | sub BASE, 16 + | mov L:RB->top, BASE + | + |->vm_leave_cp: + | mov RA, SAVE_CFRAME // Restore previous C frame. + | mov L:RB->cframe, RA + | xor eax, eax // Ok return status for vm_pcall. + | + |->vm_leave_unw: + | restoreregs + | ret + | + |6: + | jb >7 // Less results wanted? + | // More results wanted. Check stack size and fill up results with nil. + | cmp BASE, L:RB->maxstack + | ja >8 + | mov aword [BASE-16], LJ_TNIL + | add BASE, 8 + | add RDd, 1 + | jmp <4 + | + |7: // Less results wanted. + | test RAd, RAd + | jz <5 // But check for LUA_MULTRET+1. + | sub RA, RD // Negative result! + | lea BASE, [BASE+RA*8] // Correct top. + | jmp <5 + | + |8: // Corner case: need to grow stack for filling up results. + | // This can happen if: + | // - A C function grows the stack (a lot). + | // - The GC shrinks the stack in between. + | // - A return back from a lua_call() with (high) nresults adjustment. + | mov L:RB->top, BASE // Save current top held in BASE (yes). + | mov MULTRES, RDd // Need to fill only remainder with nil. + | mov CARG2d, RAd + | mov CARG1, L:RB + | call extern lj_state_growstack // (lua_State *L, int n) + | mov BASE, L:RB->top // Need the (realloced) L->top in BASE. + | jmp <3 + | + |->vm_unwind_yield: + | mov al, LUA_YIELD + | jmp ->vm_unwind_c_eh + | + |->vm_unwind_c: // Unwind C stack, return from vm_pcall. + | // (void *cframe, int errcode) + | mov eax, CARG2d // Error return status for vm_pcall. + | mov rsp, CARG1 + |->vm_unwind_c_eh: // Landing pad for external unwinder. + | mov L:RB, SAVE_L + | mov GL:RB, L:RB->glref + | mov dword GL:RB->vmstate, ~LJ_VMST_C + | jmp ->vm_leave_unw + | + |->vm_unwind_rethrow: + |.if not X64WIN + | mov CARG1, SAVE_L + | mov CARG2d, eax + | restoreregs + | jmp extern lj_err_throw // (lua_State *L, int errcode) + |.endif + | + |->vm_unwind_ff: // Unwind C stack, return from ff pcall. + | // (void *cframe) + | and CARG1, CFRAME_RAWMASK + | mov rsp, CARG1 + |->vm_unwind_ff_eh: // Landing pad for external unwinder. + | mov L:RB, SAVE_L + | mov RDd, 1+1 // Really 1+2 results, incr. later. + | mov BASE, L:RB->base + | mov DISPATCH, L:RB->glref // Setup pointer to dispatch table. + | add DISPATCH, GG_G2DISP + | mov PC, [BASE-8] // Fetch PC of previous frame. + | mov_false RA + | mov RB, [BASE] + | mov [BASE-16], RA // Prepend false to error message. + | mov [BASE-8], RB + | mov RA, -16 // Results start at BASE+RA = BASE-16. + | set_vmstate INTERP + | jmp ->vm_returnc // Increments RD/MULTRES and returns. + | + |//----------------------------------------------------------------------- + |//-- Grow stack for calls ----------------------------------------------- + |//----------------------------------------------------------------------- + | + |->vm_growstack_c: // Grow stack for C function. + | mov CARG2d, LUA_MINSTACK + | jmp >2 + | + |->vm_growstack_v: // Grow stack for vararg Lua function. + | sub RD, 16 // LJ_FR2 + | jmp >1 + | + |->vm_growstack_f: // Grow stack for fixarg Lua function. + | // BASE = new base, RD = nargs+1, RB = L, PC = first PC + | lea RD, [BASE+NARGS:RD*8-8] + |1: + | movzx RAd, byte [PC-4+PC2PROTO(framesize)] + | add PC, 4 // Must point after first instruction. + | mov L:RB->base, BASE + | mov L:RB->top, RD + | mov SAVE_PC, PC + | mov CARG2, RA + |2: + | // RB = L, L->base = new base, L->top = top + | mov CARG1, L:RB + | call extern lj_state_growstack // (lua_State *L, int n) + | mov BASE, L:RB->base + | mov RD, L:RB->top + | mov LFUNC:RB, [BASE-16] + | cleartp LFUNC:RB + | sub RD, BASE + | shr RDd, 3 + | add NARGS:RDd, 1 + | // BASE = new base, RB = LFUNC, RD = nargs+1 + | ins_callt // Just retry the call. + | + |//----------------------------------------------------------------------- + |//-- Entry points into the assembler VM --------------------------------- + |//----------------------------------------------------------------------- + | + |->vm_resume: // Setup C frame and resume thread. + | // (lua_State *L, TValue *base, int nres1 = 0, ptrdiff_t ef = 0) + | saveregs + | mov L:RB, CARG1 // Caveat: CARG1 may be RA. + | mov SAVE_L, CARG1 + | mov RA, CARG2 + | mov PCd, FRAME_CP + | xor RDd, RDd + | lea KBASE, [esp+CFRAME_RESUME] + | mov DISPATCH, L:RB->glref // Setup pointer to dispatch table. + | add DISPATCH, GG_G2DISP + | mov SAVE_PC, RD // Any value outside of bytecode is ok. + | mov SAVE_CFRAME, RD + | mov SAVE_NRES, RDd + | mov SAVE_ERRF, RDd + | mov L:RB->cframe, KBASE + | cmp byte L:RB->status, RDL + | je >2 // Initial resume (like a call). + | + | // Resume after yield (like a return). + | mov [DISPATCH+DISPATCH_GL(cur_L)], L:RB + | set_vmstate INTERP + | mov byte L:RB->status, RDL + | mov BASE, L:RB->base + | mov RD, L:RB->top + | sub RD, RA + | shr RDd, 3 + | add RDd, 1 // RD = nresults+1 + | sub RA, BASE // RA = resultofs + | mov PC, [BASE-8] + | mov MULTRES, RDd + | test PCd, FRAME_TYPE + | jz ->BC_RET_Z + | jmp ->vm_return + | + |->vm_pcall: // Setup protected C frame and enter VM. + | // (lua_State *L, TValue *base, int nres1, ptrdiff_t ef) + | saveregs + | mov PCd, FRAME_CP + | mov SAVE_ERRF, CARG4d + | jmp >1 + | + |->vm_call: // Setup C frame and enter VM. + | // (lua_State *L, TValue *base, int nres1) + | saveregs + | mov PCd, FRAME_C + | + |1: // Entry point for vm_pcall above (PC = ftype). + | mov SAVE_NRES, CARG3d + | mov L:RB, CARG1 // Caveat: CARG1 may be RA. + | mov SAVE_L, CARG1 + | mov RA, CARG2 + | + | mov DISPATCH, L:RB->glref // Setup pointer to dispatch table. + | mov KBASE, L:RB->cframe // Add our C frame to cframe chain. + | mov SAVE_CFRAME, KBASE + | mov SAVE_PC, L:RB // Any value outside of bytecode is ok. + | add DISPATCH, GG_G2DISP + | mov L:RB->cframe, rsp + | + |2: // Entry point for vm_resume/vm_cpcall (RA = base, RB = L, PC = ftype). + | mov [DISPATCH+DISPATCH_GL(cur_L)], L:RB + | set_vmstate INTERP + | mov BASE, L:RB->base // BASE = old base (used in vmeta_call). + | add PC, RA + | sub PC, BASE // PC = frame delta + frame type + | + | mov RD, L:RB->top + | sub RD, RA + | shr NARGS:RDd, 3 + | add NARGS:RDd, 1 // RD = nargs+1 + | + |->vm_call_dispatch: + | mov LFUNC:RB, [RA-16] + | checkfunc LFUNC:RB, ->vmeta_call // Ensure KBASE defined and != BASE. + | + |->vm_call_dispatch_f: + | mov BASE, RA + | ins_call + | // BASE = new base, RB = func, RD = nargs+1, PC = caller PC + | + |->vm_cpcall: // Setup protected C frame, call C. + | // (lua_State *L, lua_CFunction func, void *ud, lua_CPFunction cp) + | saveregs + | mov L:RB, CARG1 // Caveat: CARG1 may be RA. + | mov SAVE_L, CARG1 + | mov SAVE_PC, L:RB // Any value outside of bytecode is ok. + | + | mov KBASE, L:RB->stack // Compute -savestack(L, L->top). + | sub KBASE, L:RB->top + | mov DISPATCH, L:RB->glref // Setup pointer to dispatch table. + | mov SAVE_ERRF, 0 // No error function. + | mov SAVE_NRES, KBASEd // Neg. delta means cframe w/o frame. + | add DISPATCH, GG_G2DISP + | // Handler may change cframe_nres(L->cframe) or cframe_errfunc(L->cframe). + | + | mov KBASE, L:RB->cframe // Add our C frame to cframe chain. + | mov SAVE_CFRAME, KBASE + | mov L:RB->cframe, rsp + | mov [DISPATCH+DISPATCH_GL(cur_L)], L:RB + | + | call CARG4 // (lua_State *L, lua_CFunction func, void *ud) + | // TValue * (new base) or NULL returned in eax (RC). + | test RC, RC + | jz ->vm_leave_cp // No base? Just remove C frame. + | mov RA, RC + | mov PCd, FRAME_CP + | jmp <2 // Else continue with the call. + | + |//----------------------------------------------------------------------- + |//-- Metamethod handling ------------------------------------------------ + |//----------------------------------------------------------------------- + | + |//-- Continuation dispatch ---------------------------------------------- + | + |->cont_dispatch: + | // BASE = meta base, RA = resultofs, RD = nresults+1 (also in MULTRES) + | add RA, BASE + | and PC, -8 + | mov RB, BASE + | sub BASE, PC // Restore caller BASE. + | mov aword [RA+RD*8-8], LJ_TNIL // Ensure one valid arg. + | mov RC, RA // ... in [RC] + | mov PC, [RB-24] // Restore PC from [cont|PC]. + | mov RA, qword [RB-32] // May be negative on WIN64 with debug. + |.if FFI + | cmp RA, 1 + | jbe >1 + |.endif + | mov LFUNC:KBASE, [BASE-16] + | cleartp LFUNC:KBASE + | mov KBASE, LFUNC:KBASE->pc + | mov KBASE, [KBASE+PC2PROTO(k)] + | // BASE = base, RC = result, RB = meta base + | jmp RA // Jump to continuation. + | + |.if FFI + |1: + | je ->cont_ffi_callback // cont = 1: return from FFI callback. + | // cont = 0: Tail call from C function. + | sub RB, BASE + | shr RBd, 3 + | lea RDd, [RBd-3] + | jmp ->vm_call_tail + |.endif + | + |->cont_cat: // BASE = base, RC = result, RB = mbase + | movzx RAd, PC_RB + | sub RB, 32 + | lea RA, [BASE+RA*8] + | sub RA, RB + | je ->cont_ra + | neg RA + | shr RAd, 3 + |.if X64WIN + | mov CARG3d, RAd + | mov L:CARG1, SAVE_L + | mov L:CARG1->base, BASE + | mov RC, [RC] + | mov [RB], RC + | mov CARG2, RB + |.else + | mov L:CARG1, SAVE_L + | mov L:CARG1->base, BASE + | mov CARG3d, RAd + | mov RA, [RC] + | mov [RB], RA + | mov CARG2, RB + |.endif + | jmp ->BC_CAT_Z + | + |//-- Table indexing metamethods ----------------------------------------- + | + |->vmeta_tgets: + | settp STR:RC, LJ_TSTR // STR:RC = GCstr * + | mov TMP1, STR:RC + | lea RC, TMP1 + | cmp PC_OP, BC_GGET + | jne >1 + | settp TAB:RA, TAB:RB, LJ_TTAB // TAB:RB = GCtab * + | lea RB, [DISPATCH+DISPATCH_GL(tmptv)] // Store fn->l.env in g->tmptv. + | mov [RB], TAB:RA + | jmp >2 + | + |->vmeta_tgetb: + | movzx RCd, PC_RC + |.if DUALNUM + | setint RC + | mov TMP1, RC + |.else + | cvtsi2sd xmm0, RCd + | movsd TMP1, xmm0 + |.endif + | lea RC, TMP1 + | jmp >1 + | + |->vmeta_tgetv: + | movzx RCd, PC_RC // Reload TValue *k from RC. + | lea RC, [BASE+RC*8] + |1: + | movzx RBd, PC_RB // Reload TValue *t from RB. + | lea RB, [BASE+RB*8] + |2: + | mov L:CARG1, SAVE_L + | mov L:CARG1->base, BASE // Caveat: CARG2/CARG3 may be BASE. + | mov CARG2, RB + | mov CARG3, RC + | mov L:RB, L:CARG1 + | mov SAVE_PC, PC + | call extern lj_meta_tget // (lua_State *L, TValue *o, TValue *k) + | // TValue * (finished) or NULL (metamethod) returned in eax (RC). + | mov BASE, L:RB->base + | test RC, RC + | jz >3 + |->cont_ra: // BASE = base, RC = result + | movzx RAd, PC_RA + | mov RB, [RC] + | mov [BASE+RA*8], RB + | ins_next + | + |3: // Call __index metamethod. + | // BASE = base, L->top = new base, stack = cont/func/t/k + | mov RA, L:RB->top + | mov [RA-24], PC // [cont|PC] + | lea PC, [RA+FRAME_CONT] + | sub PC, BASE + | mov LFUNC:RB, [RA-16] // Guaranteed to be a function here. + | mov NARGS:RDd, 2+1 // 2 args for func(t, k). + | cleartp LFUNC:RB + | jmp ->vm_call_dispatch_f + | + |->vmeta_tgetr: + | mov CARG1, TAB:RB + | mov RB, BASE // Save BASE. + | mov CARG2d, RCd // Caveat: CARG2 == BASE + | call extern lj_tab_getinth // (GCtab *t, int32_t key) + | // cTValue * or NULL returned in eax (RC). + | movzx RAd, PC_RA + | mov BASE, RB // Restore BASE. + | test RC, RC + | jnz ->BC_TGETR_Z + | mov ITYPE, LJ_TNIL + | jmp ->BC_TGETR2_Z + | + |//----------------------------------------------------------------------- + | + |->vmeta_tsets: + | settp STR:RC, LJ_TSTR // STR:RC = GCstr * + | mov TMP1, STR:RC + | lea RC, TMP1 + | cmp PC_OP, BC_GSET + | jne >1 + | settp TAB:RA, TAB:RB, LJ_TTAB // TAB:RB = GCtab * + | lea RB, [DISPATCH+DISPATCH_GL(tmptv)] // Store fn->l.env in g->tmptv. + | mov [RB], TAB:RA + | jmp >2 + | + |->vmeta_tsetb: + | movzx RCd, PC_RC + |.if DUALNUM + | setint RC + | mov TMP1, RC + |.else + | cvtsi2sd xmm0, RCd + | movsd TMP1, xmm0 + |.endif + | lea RC, TMP1 + | jmp >1 + | + |->vmeta_tsetv: + | movzx RCd, PC_RC // Reload TValue *k from RC. + | lea RC, [BASE+RC*8] + |1: + | movzx RBd, PC_RB // Reload TValue *t from RB. + | lea RB, [BASE+RB*8] + |2: + | mov L:CARG1, SAVE_L + | mov L:CARG1->base, BASE // Caveat: CARG2/CARG3 may be BASE. + | mov CARG2, RB + | mov CARG3, RC + | mov L:RB, L:CARG1 + | mov SAVE_PC, PC + | call extern lj_meta_tset // (lua_State *L, TValue *o, TValue *k) + | // TValue * (finished) or NULL (metamethod) returned in eax (RC). + | mov BASE, L:RB->base + | test RC, RC + | jz >3 + | // NOBARRIER: lj_meta_tset ensures the table is not black. + | movzx RAd, PC_RA + | mov RB, [BASE+RA*8] + | mov [RC], RB + |->cont_nop: // BASE = base, (RC = result) + | ins_next + | + |3: // Call __newindex metamethod. + | // BASE = base, L->top = new base, stack = cont/func/t/k/(v) + | mov RA, L:RB->top + | mov [RA-24], PC // [cont|PC] + | movzx RCd, PC_RA + | // Copy value to third argument. + | mov RB, [BASE+RC*8] + | mov [RA+16], RB + | lea PC, [RA+FRAME_CONT] + | sub PC, BASE + | mov LFUNC:RB, [RA-16] // Guaranteed to be a function here. + | mov NARGS:RDd, 3+1 // 3 args for func(t, k, v). + | cleartp LFUNC:RB + | jmp ->vm_call_dispatch_f + | + |->vmeta_tsetr: + |.if X64WIN + | mov L:CARG1, SAVE_L + | mov CARG3d, RCd + | mov L:CARG1->base, BASE + | xchg CARG2, TAB:RB // Caveat: CARG2 == BASE. + |.else + | mov L:CARG1, SAVE_L + | mov CARG2, TAB:RB + | mov L:CARG1->base, BASE + | mov RB, BASE // Save BASE. + | mov CARG3d, RCd // Caveat: CARG3 == BASE. + |.endif + | mov SAVE_PC, PC + | call extern lj_tab_setinth // (lua_State *L, GCtab *t, int32_t key) + | // TValue * returned in eax (RC). + | movzx RAd, PC_RA + | mov BASE, RB // Restore BASE. + | jmp ->BC_TSETR_Z + | + |//-- Comparison metamethods --------------------------------------------- + | + |->vmeta_comp: + | movzx RDd, PC_RD + | movzx RAd, PC_RA + | mov L:RB, SAVE_L + | mov L:RB->base, BASE // Caveat: CARG2/CARG3 == BASE. + |.if X64WIN + | lea CARG3, [BASE+RD*8] + | lea CARG2, [BASE+RA*8] + |.else + | lea CARG2, [BASE+RA*8] + | lea CARG3, [BASE+RD*8] + |.endif + | mov CARG1, L:RB // Caveat: CARG1/CARG4 == RA. + | movzx CARG4d, PC_OP + | mov SAVE_PC, PC + | call extern lj_meta_comp // (lua_State *L, TValue *o1, *o2, int op) + | // 0/1 or TValue * (metamethod) returned in eax (RC). + |3: + | mov BASE, L:RB->base + | cmp RC, 1 + | ja ->vmeta_binop + |4: + | lea PC, [PC+4] + | jb >6 + |5: + | movzx RDd, PC_RD + | branchPC RD + |6: + | ins_next + | + |->cont_condt: // BASE = base, RC = result + | add PC, 4 + | mov ITYPE, [RC] + | sar ITYPE, 47 + | cmp ITYPEd, LJ_TISTRUECOND // Branch if result is true. + | jb <5 + | jmp <6 + | + |->cont_condf: // BASE = base, RC = result + | mov ITYPE, [RC] + | sar ITYPE, 47 + | cmp ITYPEd, LJ_TISTRUECOND // Branch if result is false. + | jmp <4 + | + |->vmeta_equal: + | cleartp TAB:RD + | sub PC, 4 + |.if X64WIN + | mov CARG3, RD + | mov CARG4d, RBd + | mov L:RB, SAVE_L + | mov L:RB->base, BASE // Caveat: CARG2 == BASE. + | mov CARG2, RA + | mov CARG1, L:RB // Caveat: CARG1 == RA. + |.else + | mov CARG2, RA + | mov CARG4d, RBd // Caveat: CARG4 == RA. + | mov L:RB, SAVE_L + | mov L:RB->base, BASE // Caveat: CARG3 == BASE. + | mov CARG3, RD + | mov CARG1, L:RB + |.endif + | mov SAVE_PC, PC + | call extern lj_meta_equal // (lua_State *L, GCobj *o1, *o2, int ne) + | // 0/1 or TValue * (metamethod) returned in eax (RC). + | jmp <3 + | + |->vmeta_equal_cd: + |.if FFI + | sub PC, 4 + | mov L:RB, SAVE_L + | mov L:RB->base, BASE + | mov CARG1, L:RB + | mov CARG2d, dword [PC-4] + | mov SAVE_PC, PC + | call extern lj_meta_equal_cd // (lua_State *L, BCIns ins) + | // 0/1 or TValue * (metamethod) returned in eax (RC). + | jmp <3 + |.endif + | + |->vmeta_istype: + | mov L:RB, SAVE_L + | mov L:RB->base, BASE // Caveat: CARG2/CARG3 may be BASE. + | mov CARG2d, RAd + | mov CARG3d, RDd + | mov L:CARG1, L:RB + | mov SAVE_PC, PC + | call extern lj_meta_istype // (lua_State *L, BCReg ra, BCReg tp) + | mov BASE, L:RB->base + | jmp <6 + | + |//-- Arithmetic metamethods --------------------------------------------- + | + |->vmeta_arith_vno: + |.if DUALNUM + | movzx RBd, PC_RB + | movzx RCd, PC_RC + |.endif + |->vmeta_arith_vn: + | lea RC, [KBASE+RC*8] + | jmp >1 + | + |->vmeta_arith_nvo: + |.if DUALNUM + | movzx RBd, PC_RB + | movzx RCd, PC_RC + |.endif + |->vmeta_arith_nv: + | lea TMPR, [KBASE+RC*8] + | lea RC, [BASE+RB*8] + | mov RB, TMPR + | jmp >2 + | + |->vmeta_unm: + | lea RC, [BASE+RD*8] + | mov RB, RC + | jmp >2 + | + |->vmeta_arith_vvo: + |.if DUALNUM + | movzx RBd, PC_RB + | movzx RCd, PC_RC + |.endif + |->vmeta_arith_vv: + | lea RC, [BASE+RC*8] + |1: + | lea RB, [BASE+RB*8] + |2: + | lea RA, [BASE+RA*8] + |.if X64WIN + | mov CARG3, RB + | mov CARG4, RC + | movzx RCd, PC_OP + | mov ARG5d, RCd + | mov L:RB, SAVE_L + | mov L:RB->base, BASE // Caveat: CARG2 == BASE. + | mov CARG2, RA + | mov CARG1, L:RB // Caveat: CARG1 == RA. + |.else + | movzx CARG5d, PC_OP + | mov CARG2, RA + | mov CARG4, RC // Caveat: CARG4 == RA. + | mov L:CARG1, SAVE_L + | mov L:CARG1->base, BASE // Caveat: CARG3 == BASE. + | mov CARG3, RB + | mov L:RB, L:CARG1 + |.endif + | mov SAVE_PC, PC + | call extern lj_meta_arith // (lua_State *L, TValue *ra,*rb,*rc, BCReg op) + | // NULL (finished) or TValue * (metamethod) returned in eax (RC). + | mov BASE, L:RB->base + | test RC, RC + | jz ->cont_nop + | + | // Call metamethod for binary op. + |->vmeta_binop: + | // BASE = base, RC = new base, stack = cont/func/o1/o2 + | mov RA, RC + | sub RC, BASE + | mov [RA-24], PC // [cont|PC] + | lea PC, [RC+FRAME_CONT] + | mov NARGS:RDd, 2+1 // 2 args for func(o1, o2). + | jmp ->vm_call_dispatch + | + |->vmeta_len: + | movzx RDd, PC_RD + | mov L:RB, SAVE_L + | mov L:RB->base, BASE + | lea CARG2, [BASE+RD*8] // Caveat: CARG2 == BASE + | mov L:CARG1, L:RB + | mov SAVE_PC, PC + | call extern lj_meta_len // (lua_State *L, TValue *o) + | // NULL (retry) or TValue * (metamethod) returned in eax (RC). + | mov BASE, L:RB->base +#if LJ_52 + | test RC, RC + | jne ->vmeta_binop // Binop call for compatibility. + | movzx RDd, PC_RD + | mov TAB:CARG1, [BASE+RD*8] + | cleartp TAB:CARG1 + | jmp ->BC_LEN_Z +#else + | jmp ->vmeta_binop // Binop call for compatibility. +#endif + | + |//-- Call metamethod ---------------------------------------------------- + | + |->vmeta_call_ra: + | lea RA, [BASE+RA*8+16] + |->vmeta_call: // Resolve and call __call metamethod. + | // BASE = old base, RA = new base, RC = nargs+1, PC = return + | mov TMP1d, NARGS:RDd // Save RA, RC for us. + | mov RB, RA + |.if X64WIN + | mov L:TMPR, SAVE_L + | mov L:TMPR->base, BASE // Caveat: CARG2 is BASE. + | lea CARG2, [RA-16] + | lea CARG3, [RA+NARGS:RD*8-8] + | mov CARG1, L:TMPR // Caveat: CARG1 is RA. + |.else + | mov L:CARG1, SAVE_L + | mov L:CARG1->base, BASE // Caveat: CARG3 is BASE. + | lea CARG2, [RA-16] + | lea CARG3, [RA+NARGS:RD*8-8] + |.endif + | mov SAVE_PC, PC + | call extern lj_meta_call // (lua_State *L, TValue *func, TValue *top) + | mov RA, RB + | mov L:RB, SAVE_L + | mov BASE, L:RB->base + | mov NARGS:RDd, TMP1d + | mov LFUNC:RB, [RA-16] + | add NARGS:RDd, 1 + | // This is fragile. L->base must not move, KBASE must always be defined. + | cmp KBASE, BASE // Continue with CALLT if flag set. + | je ->BC_CALLT_Z + | cleartp LFUNC:RB + | mov BASE, RA + | ins_call // Otherwise call resolved metamethod. + | + |//-- Argument coercion for 'for' statement ------------------------------ + | + |->vmeta_for: + | mov L:RB, SAVE_L + | mov L:RB->base, BASE + | mov CARG2, RA // Caveat: CARG2 == BASE + | mov L:CARG1, L:RB // Caveat: CARG1 == RA + | mov SAVE_PC, PC + | call extern lj_meta_for // (lua_State *L, TValue *base) + | mov BASE, L:RB->base + | mov RCd, [PC-4] + | movzx RAd, RCH + | movzx OP, RCL + | shr RCd, 16 + | jmp aword [DISPATCH+OP*8+GG_DISP2STATIC] // Retry FORI or JFORI. + | + |//----------------------------------------------------------------------- + |//-- Fast functions ----------------------------------------------------- + |//----------------------------------------------------------------------- + | + |.macro .ffunc, name + |->ff_ .. name: + |.endmacro + | + |.macro .ffunc_1, name + |->ff_ .. name: + | cmp NARGS:RDd, 1+1; jb ->fff_fallback + |.endmacro + | + |.macro .ffunc_2, name + |->ff_ .. name: + | cmp NARGS:RDd, 2+1; jb ->fff_fallback + |.endmacro + | + |.macro .ffunc_n, name, op + | .ffunc_1 name + | checknumtp [BASE], ->fff_fallback + | op xmm0, qword [BASE] + |.endmacro + | + |.macro .ffunc_n, name + | .ffunc_n name, movsd + |.endmacro + | + |.macro .ffunc_nn, name + | .ffunc_2 name + | checknumtp [BASE], ->fff_fallback + | checknumtp [BASE+8], ->fff_fallback + | movsd xmm0, qword [BASE] + | movsd xmm1, qword [BASE+8] + |.endmacro + | + |// Inlined GC threshold check. Caveat: uses label 1. + |.macro ffgccheck + | mov RB, [DISPATCH+DISPATCH_GL(gc.total)] + | cmp RB, [DISPATCH+DISPATCH_GL(gc.threshold)] + | jb >1 + | call ->fff_gcstep + |1: + |.endmacro + | + |//-- Base library: checks ----------------------------------------------- + | + |.ffunc_1 assert + | mov ITYPE, [BASE] + | mov RB, ITYPE + | sar ITYPE, 47 + | cmp ITYPEd, LJ_TISTRUECOND; jae ->fff_fallback + | mov PC, [BASE-8] + | mov MULTRES, RDd + | mov RB, [BASE] + | mov [BASE-16], RB + | sub RDd, 2 + | jz >2 + | mov RA, BASE + |1: + | add RA, 8 + | mov RB, [RA] + | mov [RA-16], RB + | sub RDd, 1 + | jnz <1 + |2: + | mov RDd, MULTRES + | jmp ->fff_res_ + | + |.ffunc_1 type + | mov RC, [BASE] + | sar RC, 47 + | mov RBd, LJ_TISNUM + | cmp RCd, RBd + | cmovb RCd, RBd + | not RCd + |2: + | mov CFUNC:RB, [BASE-16] + | cleartp CFUNC:RB + | mov STR:RC, [CFUNC:RB+RC*8+((char *)(&((GCfuncC *)0)->upvalue))] + | mov PC, [BASE-8] + | settp STR:RC, LJ_TSTR + | mov [BASE-16], STR:RC + | jmp ->fff_res1 + | + |//-- Base library: getters and setters --------------------------------- + | + |.ffunc_1 getmetatable + | mov TAB:RB, [BASE] + | mov PC, [BASE-8] + | checktab TAB:RB, >6 + |1: // Field metatable must be at same offset for GCtab and GCudata! + | mov TAB:RB, TAB:RB->metatable + |2: + | test TAB:RB, TAB:RB + | mov aword [BASE-16], LJ_TNIL + | jz ->fff_res1 + | settp TAB:RC, TAB:RB, LJ_TTAB + | mov [BASE-16], TAB:RC // Store metatable as default result. + | mov STR:RC, [DISPATCH+DISPATCH_GL(gcroot)+8*(GCROOT_MMNAME+MM_metatable)] + | mov RAd, TAB:RB->hmask + | and RAd, STR:RC->sid + | settp STR:RC, LJ_TSTR + | imul RAd, #NODE + | add NODE:RA, TAB:RB->node + |3: // Rearranged logic, because we expect _not_ to find the key. + | cmp NODE:RA->key, STR:RC + | je >5 + |4: + | mov NODE:RA, NODE:RA->next + | test NODE:RA, NODE:RA + | jnz <3 + | jmp ->fff_res1 // Not found, keep default result. + |5: + | mov RB, NODE:RA->val + | cmp RB, LJ_TNIL; je ->fff_res1 // Ditto for nil value. + | mov [BASE-16], RB // Return value of mt.__metatable. + | jmp ->fff_res1 + | + |6: + | cmp ITYPEd, LJ_TUDATA; je <1 + | cmp ITYPEd, LJ_TISNUM; ja >7 + | mov ITYPEd, LJ_TISNUM + |7: + | not ITYPEd + | mov TAB:RB, [DISPATCH+ITYPE*8+DISPATCH_GL(gcroot[GCROOT_BASEMT])] + | jmp <2 + | + |.ffunc_2 setmetatable + | mov TAB:RB, [BASE] + | mov TAB:TMPR, TAB:RB + | checktab TAB:RB, ->fff_fallback + | // Fast path: no mt for table yet and not clearing the mt. + | cmp aword TAB:RB->metatable, 0; jne ->fff_fallback + | mov TAB:RA, [BASE+8] + | checktab TAB:RA, ->fff_fallback + | mov TAB:RB->metatable, TAB:RA + | mov PC, [BASE-8] + | mov [BASE-16], TAB:TMPR // Return original table. + | test byte TAB:RB->marked, LJ_GC_BLACK // isblack(table) + | jz >1 + | // Possible write barrier. Table is black, but skip iswhite(mt) check. + | barrierback TAB:RB, RC + |1: + | jmp ->fff_res1 + | + |.ffunc_2 rawget + |.if X64WIN + | mov TAB:RA, [BASE] + | checktab TAB:RA, ->fff_fallback + | mov RB, BASE // Save BASE. + | lea CARG3, [BASE+8] + | mov CARG2, TAB:RA // Caveat: CARG2 == BASE. + | mov CARG1, SAVE_L + |.else + | mov TAB:CARG2, [BASE] + | checktab TAB:CARG2, ->fff_fallback + | mov RB, BASE // Save BASE. + | lea CARG3, [BASE+8] // Caveat: CARG3 == BASE. + | mov CARG1, SAVE_L + |.endif + | call extern lj_tab_get // (lua_State *L, GCtab *t, cTValue *key) + | // cTValue * returned in eax (RD). + | mov BASE, RB // Restore BASE. + | // Copy table slot. + | mov RB, [RD] + | mov PC, [BASE-8] + | mov [BASE-16], RB + | jmp ->fff_res1 + | + |//-- Base library: conversions ------------------------------------------ + | + |.ffunc tonumber + | // Only handles the number case inline (without a base argument). + | cmp NARGS:RDd, 1+1; jne ->fff_fallback // Exactly one argument. + | mov RB, [BASE] + | checknumber RB, ->fff_fallback + | mov PC, [BASE-8] + | mov [BASE-16], RB + | jmp ->fff_res1 + | + |.ffunc_1 tostring + | // Only handles the string or number case inline. + | mov PC, [BASE-8] + | mov STR:RB, [BASE] + | checktp_nc STR:RB, LJ_TSTR, >3 + | // A __tostring method in the string base metatable is ignored. + |2: + | mov [BASE-16], STR:RB + | jmp ->fff_res1 + |3: // Handle numbers inline, unless a number base metatable is present. + | cmp ITYPEd, LJ_TISNUM; ja ->fff_fallback_1 + | cmp aword [DISPATCH+DISPATCH_GL(gcroot[GCROOT_BASEMT_NUM])], 0 + | jne ->fff_fallback + | ffgccheck // Caveat: uses label 1. + | mov L:RB, SAVE_L + | mov L:RB->base, BASE // Add frame since C call can throw. + | mov SAVE_PC, PC // Redundant (but a defined value). + |.if not X64WIN + | mov CARG2, BASE // Otherwise: CARG2 == BASE + |.endif + | mov L:CARG1, L:RB + |.if DUALNUM + | call extern lj_strfmt_number // (lua_State *L, cTValue *o) + |.else + | call extern lj_strfmt_num // (lua_State *L, lua_Number *np) + |.endif + | // GCstr returned in eax (RD). + | mov BASE, L:RB->base + | settp STR:RB, RD, LJ_TSTR + | jmp <2 + | + |//-- Base library: iterators ------------------------------------------- + | + |.ffunc_1 next + | je >2 // Missing 2nd arg? + |1: + | mov CARG1, [BASE] + | mov PC, [BASE-8] + | checktab CARG1, ->fff_fallback + | mov RB, BASE // Save BASE. + |.if X64WIN + | lea CARG3, [BASE-16] + | lea CARG2, [BASE+8] // Caveat: CARG2 == BASE. + |.else + | lea CARG2, [BASE+8] + | lea CARG3, [BASE-16] // Caveat: CARG3 == BASE. + |.endif + | call extern lj_tab_next // (GCtab *t, cTValue *key, TValue *o) + | // 1=found, 0=end, -1=error returned in eax (RD). + | mov BASE, RB // Restore BASE. + | test RDd, RDd; jg ->fff_res2 // Found key/value. + | js ->fff_fallback_2 // Invalid key. + | // End of traversal: return nil. + | mov aword [BASE-16], LJ_TNIL + | jmp ->fff_res1 + |2: // Set missing 2nd arg to nil. + | mov aword [BASE+8], LJ_TNIL + | jmp <1 + | + |.ffunc_1 pairs + | mov TAB:RB, [BASE] + | mov TMPR, TAB:RB + | checktab TAB:RB, ->fff_fallback +#if LJ_52 + | cmp aword TAB:RB->metatable, 0; jne ->fff_fallback +#endif + | mov CFUNC:RD, [BASE-16] + | cleartp CFUNC:RD + | mov CFUNC:RD, CFUNC:RD->upvalue[0] + | settp CFUNC:RD, LJ_TFUNC + | mov PC, [BASE-8] + | mov [BASE-16], CFUNC:RD + | mov [BASE-8], TMPR + | mov aword [BASE], LJ_TNIL + | mov RDd, 1+3 + | jmp ->fff_res + | + |.ffunc_2 ipairs_aux + | mov TAB:RB, [BASE] + | checktab TAB:RB, ->fff_fallback + |.if DUALNUM + | mov RA, [BASE+8] + | checkint RA, ->fff_fallback + |.else + | checknumtp [BASE+8], ->fff_fallback + | movsd xmm0, qword [BASE+8] + |.endif + | mov PC, [BASE-8] + |.if DUALNUM + | add RAd, 1 + | setint ITYPE, RA + | mov [BASE-16], ITYPE + |.else + | sseconst_1 xmm1, TMPR + | addsd xmm0, xmm1 + | cvttsd2si RAd, xmm0 + | movsd qword [BASE-16], xmm0 + |.endif + | cmp RAd, TAB:RB->asize; jae >2 // Not in array part? + | mov RD, TAB:RB->array + | lea RD, [RD+RA*8] + |1: + | cmp aword [RD], LJ_TNIL; je ->fff_res0 + | // Copy array slot. + | mov RB, [RD] + | mov [BASE-8], RB + |->fff_res2: + | mov RDd, 1+2 + | jmp ->fff_res + |2: // Check for empty hash part first. Otherwise call C function. + | cmp dword TAB:RB->hmask, 0; je ->fff_res0 + |.if X64WIN + | mov TMPR, BASE + | mov CARG2d, RAd + | mov CARG1, TAB:RB + | mov RB, TMPR + |.else + | mov CARG1, TAB:RB + | mov RB, BASE // Save BASE. + | mov CARG2d, RAd // Caveat: CARG2 == BASE + |.endif + | call extern lj_tab_getinth // (GCtab *t, int32_t key) + | // cTValue * or NULL returned in eax (RD). + | mov BASE, RB + | test RD, RD + | jnz <1 + |->fff_res0: + | mov RDd, 1+0 + | jmp ->fff_res + | + |.ffunc_1 ipairs + | mov TAB:RB, [BASE] + | mov TMPR, TAB:RB + | checktab TAB:RB, ->fff_fallback +#if LJ_52 + | cmp aword TAB:RB->metatable, 0; jne ->fff_fallback +#endif + | mov CFUNC:RD, [BASE-16] + | cleartp CFUNC:RD + | mov CFUNC:RD, CFUNC:RD->upvalue[0] + | settp CFUNC:RD, LJ_TFUNC + | mov PC, [BASE-8] + | mov [BASE-16], CFUNC:RD + | mov [BASE-8], TMPR + |.if DUALNUM + | mov64 RD, ((uint64_t)LJ_TISNUM<<47) + | mov [BASE], RD + |.else + | mov qword [BASE], 0 + |.endif + | mov RDd, 1+3 + | jmp ->fff_res + | + |//-- Base library: catch errors ---------------------------------------- + | + |.ffunc_1 pcall + | lea RA, [BASE+16] + | sub NARGS:RDd, 1 + | mov PCd, 16+FRAME_PCALL + |1: + | movzx RBd, byte [DISPATCH+DISPATCH_GL(hookmask)] + | shr RB, HOOK_ACTIVE_SHIFT + | and RB, 1 + | add PC, RB // Remember active hook before pcall. + | // Note: this does a (harmless) copy of the function to the PC slot, too. + | mov KBASE, RD + |2: + | mov RB, [RA+KBASE*8-24] + | mov [RA+KBASE*8-16], RB + | sub KBASE, 1 + | ja <2 + | jmp ->vm_call_dispatch + | + |.ffunc_2 xpcall + | mov LFUNC:RA, [BASE+8] + | checktp_nc LFUNC:RA, LJ_TFUNC, ->fff_fallback + | mov LFUNC:RB, [BASE] // Swap function and traceback. + | mov [BASE], LFUNC:RA + | mov [BASE+8], LFUNC:RB + | lea RA, [BASE+24] + | sub NARGS:RDd, 2 + | mov PCd, 24+FRAME_PCALL + | jmp <1 + | + |//-- Coroutine library -------------------------------------------------- + | + |.macro coroutine_resume_wrap, resume + |.if resume + |.ffunc_1 coroutine_resume + | mov L:RB, [BASE] + | cleartp L:RB + |.else + |.ffunc coroutine_wrap_aux + | mov CFUNC:RB, [BASE-16] + | cleartp CFUNC:RB + | mov L:RB, CFUNC:RB->upvalue[0].gcr + | cleartp L:RB + |.endif + | mov PC, [BASE-8] + | mov SAVE_PC, PC + | mov TMP1, L:RB + |.if resume + | checktptp [BASE], LJ_TTHREAD, ->fff_fallback + |.endif + | cmp aword L:RB->cframe, 0; jne ->fff_fallback + | cmp byte L:RB->status, LUA_YIELD; ja ->fff_fallback + | mov RA, L:RB->top + | je >1 // Status != LUA_YIELD (i.e. 0)? + | cmp RA, L:RB->base // Check for presence of initial func. + | je ->fff_fallback + | mov PC, [RA-8] // Move initial function up. + | mov [RA], PC + | add RA, 8 + |1: + |.if resume + | lea PC, [RA+NARGS:RD*8-16] // Check stack space (-1-thread). + |.else + | lea PC, [RA+NARGS:RD*8-8] // Check stack space (-1). + |.endif + | cmp PC, L:RB->maxstack; ja ->fff_fallback + | mov L:RB->top, PC + | + | mov L:RB, SAVE_L + | mov L:RB->base, BASE + |.if resume + | add BASE, 8 // Keep resumed thread in stack for GC. + |.endif + | mov L:RB->top, BASE + |.if resume + | lea RB, [BASE+NARGS:RD*8-24] // RB = end of source for stack move. + |.else + | lea RB, [BASE+NARGS:RD*8-16] // RB = end of source for stack move. + |.endif + | sub RB, PC // Relative to PC. + | + | cmp PC, RA + | je >3 + |2: // Move args to coroutine. + | mov RC, [PC+RB] + | mov [PC-8], RC + | sub PC, 8 + | cmp PC, RA + | jne <2 + |3: + | mov CARG2, RA + | mov CARG1, TMP1 + | call ->vm_resume // (lua_State *L, TValue *base, 0, 0) + | + | mov L:RB, SAVE_L + | mov L:PC, TMP1 + | mov BASE, L:RB->base + | mov [DISPATCH+DISPATCH_GL(cur_L)], L:RB + | set_vmstate INTERP + | + | cmp eax, LUA_YIELD + | ja >8 + |4: + | mov RA, L:PC->base + | mov KBASE, L:PC->top + | mov L:PC->top, RA // Clear coroutine stack. + | mov PC, KBASE + | sub PC, RA + | je >6 // No results? + | lea RD, [BASE+PC] + | shr PCd, 3 + | cmp RD, L:RB->maxstack + | ja >9 // Need to grow stack? + | + | mov RB, BASE + | sub RB, RA + |5: // Move results from coroutine. + | mov RD, [RA] + | mov [RA+RB], RD + | add RA, 8 + | cmp RA, KBASE + | jne <5 + |6: + |.if resume + | lea RDd, [PCd+2] // nresults+1 = 1 + true + results. + | mov_true ITYPE // Prepend true to results. + | mov [BASE-8], ITYPE + |.else + | lea RDd, [PCd+1] // nresults+1 = 1 + results. + |.endif + |7: + | mov PC, SAVE_PC + | mov MULTRES, RDd + |.if resume + | mov RA, -8 + |.else + | xor RAd, RAd + |.endif + | test PCd, FRAME_TYPE + | jz ->BC_RET_Z + | jmp ->vm_return + | + |8: // Coroutine returned with error (at co->top-1). + |.if resume + | mov_false ITYPE // Prepend false to results. + | mov [BASE-8], ITYPE + | mov RA, L:PC->top + | sub RA, 8 + | mov L:PC->top, RA // Clear error from coroutine stack. + | // Copy error message. + | mov RD, [RA] + | mov [BASE], RD + | mov RDd, 1+2 // nresults+1 = 1 + false + error. + | jmp <7 + |.else + | mov CARG2, L:PC + | mov CARG1, L:RB + | call extern lj_ffh_coroutine_wrap_err // (lua_State *L, lua_State *co) + | // Error function does not return. + |.endif + | + |9: // Handle stack expansion on return from yield. + | mov L:RA, TMP1 + | mov L:RA->top, KBASE // Undo coroutine stack clearing. + | mov CARG2, PC + | mov CARG1, L:RB + | call extern lj_state_growstack // (lua_State *L, int n) + | mov L:PC, TMP1 + | mov BASE, L:RB->base + | jmp <4 // Retry the stack move. + |.endmacro + | + | coroutine_resume_wrap 1 // coroutine.resume + | coroutine_resume_wrap 0 // coroutine.wrap + | + |.ffunc coroutine_yield + | mov L:RB, SAVE_L + | test aword L:RB->cframe, CFRAME_RESUME + | jz ->fff_fallback + | mov L:RB->base, BASE + | lea RD, [BASE+NARGS:RD*8-8] + | mov L:RB->top, RD + | xor RDd, RDd + | mov aword L:RB->cframe, RD + | mov al, LUA_YIELD + | mov byte L:RB->status, al + | jmp ->vm_leave_unw + | + |//-- Math library ------------------------------------------------------- + | + | .ffunc_1 math_abs + | mov RB, [BASE] + |.if DUALNUM + | checkint RB, >3 + | cmp RBd, 0; jns ->fff_resi + | neg RBd; js >2 + |->fff_resbit: + |->fff_resi: + | setint RB + |->fff_resRB: + | mov PC, [BASE-8] + | mov [BASE-16], RB + | jmp ->fff_res1 + |2: + | mov64 RB, U64x(41e00000,00000000) // 2^31. + | jmp ->fff_resRB + |3: + | ja ->fff_fallback + |.else + | checknum RB, ->fff_fallback + |.endif + | shl RB, 1 + | shr RB, 1 + | mov PC, [BASE-8] + | mov [BASE-16], RB + | jmp ->fff_res1 + | + |.ffunc_n math_sqrt, sqrtsd + |->fff_resxmm0: + | mov PC, [BASE-8] + | movsd qword [BASE-16], xmm0 + | // fallthrough + | + |->fff_res1: + | mov RDd, 1+1 + |->fff_res: + | mov MULTRES, RDd + |->fff_res_: + | test PCd, FRAME_TYPE + | jnz >7 + |5: + | cmp PC_RB, RDL // More results expected? + | ja >6 + | // Adjust BASE. KBASE is assumed to be set for the calling frame. + | movzx RAd, PC_RA + | neg RA + | lea BASE, [BASE+RA*8-16] // base = base - (RA+2)*8 + | ins_next + | + |6: // Fill up results with nil. + | mov aword [BASE+RD*8-24], LJ_TNIL + | add RD, 1 + | jmp <5 + | + |7: // Non-standard return case. + | mov RA, -16 // Results start at BASE+RA = BASE-16. + | jmp ->vm_return + | + |.macro math_round, func + | .ffunc math_ .. func + |.if DUALNUM + | mov RB, [BASE] + | checknumx RB, ->fff_resRB, je + | ja ->fff_fallback + |.else + | checknumtp [BASE], ->fff_fallback + |.endif + | movsd xmm0, qword [BASE] + | call ->vm_ .. func .. _sse + |.if DUALNUM + | cvttsd2si RBd, xmm0 + | cmp RBd, 0x80000000 + | jne ->fff_resi + | cvtsi2sd xmm1, RBd + | ucomisd xmm0, xmm1 + | jp ->fff_resxmm0 + | je ->fff_resi + |.endif + | jmp ->fff_resxmm0 + |.endmacro + | + | math_round floor + | math_round ceil + | + |.ffunc math_log + | cmp NARGS:RDd, 1+1; jne ->fff_fallback // Exactly one argument. + | checknumtp [BASE], ->fff_fallback + | movsd xmm0, qword [BASE] + | mov RB, BASE + | call extern log + | mov BASE, RB + | jmp ->fff_resxmm0 + | + |.macro math_extern, func + | .ffunc_n math_ .. func + | mov RB, BASE + | call extern func + | mov BASE, RB + | jmp ->fff_resxmm0 + |.endmacro + | + |.macro math_extern2, func + | .ffunc_nn math_ .. func + | mov RB, BASE + | call extern func + | mov BASE, RB + | jmp ->fff_resxmm0 + |.endmacro + | + | math_extern log10 + | math_extern exp + | math_extern sin + | math_extern cos + | math_extern tan + | math_extern asin + | math_extern acos + | math_extern atan + | math_extern sinh + | math_extern cosh + | math_extern tanh + | math_extern2 pow + | math_extern2 atan2 + | math_extern2 fmod + | + |.ffunc_2 math_ldexp + | checknumtp [BASE], ->fff_fallback + | checknumtp [BASE+8], ->fff_fallback + | fld qword [BASE+8] + | fld qword [BASE] + | fscale + | fpop1 + | mov PC, [BASE-8] + | fstp qword [BASE-16] + | jmp ->fff_res1 + | + |.ffunc_n math_frexp + | mov RB, BASE + |.if X64WIN + | lea CARG2, TMP1 // Caveat: CARG2 == BASE + |.else + | lea CARG1, TMP1 + |.endif + | call extern frexp + | mov BASE, RB + | mov RBd, TMP1d + | mov PC, [BASE-8] + | movsd qword [BASE-16], xmm0 + |.if DUALNUM + | setint RB + | mov [BASE-8], RB + |.else + | cvtsi2sd xmm1, RBd + | movsd qword [BASE-8], xmm1 + |.endif + | mov RDd, 1+2 + | jmp ->fff_res + | + |.ffunc_n math_modf + | mov RB, BASE + |.if X64WIN + | lea CARG2, [BASE-16] // Caveat: CARG2 == BASE + |.else + | lea CARG1, [BASE-16] + |.endif + | call extern modf + | mov BASE, RB + | mov PC, [BASE-8] + | movsd qword [BASE-8], xmm0 + | mov RDd, 1+2 + | jmp ->fff_res + | + |.macro math_minmax, name, cmovop, sseop + | .ffunc_1 name + | mov RAd, 2 + |.if DUALNUM + | mov RB, [BASE] + | checkint RB, >4 + |1: // Handle integers. + | cmp RAd, RDd; jae ->fff_resRB + | mov TMPR, [BASE+RA*8-8] + | checkint TMPR, >3 + | cmp RBd, TMPRd + | cmovop RB, TMPR + | add RAd, 1 + | jmp <1 + |3: + | ja ->fff_fallback + | // Convert intermediate result to number and continue below. + | cvtsi2sd xmm0, RBd + | jmp >6 + |4: + | ja ->fff_fallback + |.else + | checknumtp [BASE], ->fff_fallback + |.endif + | + | movsd xmm0, qword [BASE] + |5: // Handle numbers or integers. + | cmp RAd, RDd; jae ->fff_resxmm0 + |.if DUALNUM + | mov RB, [BASE+RA*8-8] + | checknumx RB, >6, jb + | ja ->fff_fallback + | cvtsi2sd xmm1, RBd + | jmp >7 + |.else + | checknumtp [BASE+RA*8-8], ->fff_fallback + |.endif + |6: + | movsd xmm1, qword [BASE+RA*8-8] + |7: + | sseop xmm0, xmm1 + | add RAd, 1 + | jmp <5 + |.endmacro + | + | math_minmax math_min, cmovg, minsd + | math_minmax math_max, cmovl, maxsd + | + |//-- String library ----------------------------------------------------- + | + |.ffunc string_byte // Only handle the 1-arg case here. + | cmp NARGS:RDd, 1+1; jne ->fff_fallback + | mov STR:RB, [BASE] + | checkstr STR:RB, ->fff_fallback + | mov PC, [BASE-8] + | cmp dword STR:RB->len, 1 + | jb ->fff_res0 // Return no results for empty string. + | movzx RBd, byte STR:RB[1] + |.if DUALNUM + | jmp ->fff_resi + |.else + | cvtsi2sd xmm0, RBd; jmp ->fff_resxmm0 + |.endif + | + |.ffunc string_char // Only handle the 1-arg case here. + | ffgccheck + | cmp NARGS:RDd, 1+1; jne ->fff_fallback // *Exactly* 1 arg. + |.if DUALNUM + | mov RB, [BASE] + | checkint RB, ->fff_fallback + |.else + | checknumtp [BASE], ->fff_fallback + | cvttsd2si RBd, qword [BASE] + |.endif + | cmp RBd, 255; ja ->fff_fallback + | mov TMP1d, RBd + | mov TMPRd, 1 + | lea RD, TMP1 // Points to stack. Little-endian. + |->fff_newstr: + | mov L:RB, SAVE_L + | mov L:RB->base, BASE + | mov CARG3d, TMPRd // Zero-extended to size_t. + | mov CARG2, RD + | mov CARG1, L:RB + | mov SAVE_PC, PC + | call extern lj_str_new // (lua_State *L, char *str, size_t l) + |->fff_resstr: + | // GCstr * returned in eax (RD). + | mov BASE, L:RB->base + | mov PC, [BASE-8] + | settp STR:RD, LJ_TSTR + | mov [BASE-16], STR:RD + | jmp ->fff_res1 + | + |.ffunc string_sub + | ffgccheck + | mov TMPRd, -1 + | cmp NARGS:RDd, 1+2; jb ->fff_fallback + | jna >1 + |.if DUALNUM + | mov TMPR, [BASE+16] + | checkint TMPR, ->fff_fallback + |.else + | checknumtp [BASE+16], ->fff_fallback + | cvttsd2si TMPRd, qword [BASE+16] + |.endif + |1: + | mov STR:RB, [BASE] + | checkstr STR:RB, ->fff_fallback + |.if DUALNUM + | mov ITYPE, [BASE+8] + | mov RAd, ITYPEd // Must clear hiword for lea below. + | sar ITYPE, 47 + | cmp ITYPEd, LJ_TISNUM + | jne ->fff_fallback + |.else + | checknumtp [BASE+8], ->fff_fallback + | cvttsd2si RAd, qword [BASE+8] + |.endif + | mov RCd, STR:RB->len + | cmp RCd, TMPRd // len < end? (unsigned compare) + | jb >5 + |2: + | test RAd, RAd // start <= 0? + | jle >7 + |3: + | sub TMPRd, RAd // start > end? + | jl ->fff_emptystr + | lea RD, [STR:RB+RAd+#STR-1] + | add TMPRd, 1 + |4: + | jmp ->fff_newstr + | + |5: // Negative end or overflow. + | jl >6 + | lea TMPRd, [TMPRd+RCd+1] // end = end+(len+1) + | jmp <2 + |6: // Overflow. + | mov TMPRd, RCd // end = len + | jmp <2 + | + |7: // Negative start or underflow. + | je >8 + | add RAd, RCd // start = start+(len+1) + | add RAd, 1 + | jg <3 // start > 0? + |8: // Underflow. + | mov RAd, 1 // start = 1 + | jmp <3 + | + |->fff_emptystr: // Range underflow. + | xor TMPRd, TMPRd // Zero length. Any ptr in RD is ok. + | jmp <4 + | + |.macro ffstring_op, name + | .ffunc_1 string_ .. name + | ffgccheck + |.if X64WIN + | mov STR:TMPR, [BASE] + | checkstr STR:TMPR, ->fff_fallback + |.else + | mov STR:CARG2, [BASE] + | checkstr STR:CARG2, ->fff_fallback + |.endif + | mov L:RB, SAVE_L + | lea SBUF:CARG1, [DISPATCH+DISPATCH_GL(tmpbuf)] + | mov L:RB->base, BASE + |.if X64WIN + | mov STR:CARG2, STR:TMPR // Caveat: CARG2 == BASE + |.endif + | mov RC, SBUF:CARG1->b + | mov SBUF:CARG1->L, L:RB + | mov SBUF:CARG1->w, RC + | mov SAVE_PC, PC + | call extern lj_buf_putstr_ .. name + | mov CARG1, rax + | call extern lj_buf_tostr + | jmp ->fff_resstr + |.endmacro + | + |ffstring_op reverse + |ffstring_op lower + |ffstring_op upper + | + |//-- Bit library -------------------------------------------------------- + | + |.macro .ffunc_bit, name, kind, fdef + | fdef name + |.if kind == 2 + | sseconst_tobit xmm1, RB + |.endif + |.if DUALNUM + | mov RB, [BASE] + | checkint RB, >1 + |.if kind > 0 + | jmp >2 + |.else + | jmp ->fff_resbit + |.endif + |1: + | ja ->fff_fallback + | movd xmm0, RB + |.else + | checknumtp [BASE], ->fff_fallback + | movsd xmm0, qword [BASE] + |.endif + |.if kind < 2 + | sseconst_tobit xmm1, RB + |.endif + | addsd xmm0, xmm1 + | movd RBd, xmm0 + |2: + |.endmacro + | + |.macro .ffunc_bit, name, kind + | .ffunc_bit name, kind, .ffunc_1 + |.endmacro + | + |.ffunc_bit bit_tobit, 0 + | jmp ->fff_resbit + | + |.macro .ffunc_bit_op, name, ins + | .ffunc_bit name, 2 + | mov TMPRd, NARGS:RDd // Save for fallback. + | lea RD, [BASE+NARGS:RD*8-16] + |1: + | cmp RD, BASE + | jbe ->fff_resbit + |.if DUALNUM + | mov RA, [RD] + | checkint RA, >2 + | ins RBd, RAd + | sub RD, 8 + | jmp <1 + |2: + | ja ->fff_fallback_bit_op + | movd xmm0, RA + |.else + | checknumtp [RD], ->fff_fallback_bit_op + | movsd xmm0, qword [RD] + |.endif + | addsd xmm0, xmm1 + | movd RAd, xmm0 + | ins RBd, RAd + | sub RD, 8 + | jmp <1 + |.endmacro + | + |.ffunc_bit_op bit_band, and + |.ffunc_bit_op bit_bor, or + |.ffunc_bit_op bit_bxor, xor + | + |.ffunc_bit bit_bswap, 1 + | bswap RBd + | jmp ->fff_resbit + | + |.ffunc_bit bit_bnot, 1 + | not RBd + |.if DUALNUM + | jmp ->fff_resbit + |.else + |->fff_resbit: + | cvtsi2sd xmm0, RBd + | jmp ->fff_resxmm0 + |.endif + | + |->fff_fallback_bit_op: + | mov NARGS:RDd, TMPRd // Restore for fallback + | jmp ->fff_fallback + | + |.macro .ffunc_bit_sh, name, ins + |.if DUALNUM + | .ffunc_bit name, 1, .ffunc_2 + | // Note: no inline conversion from number for 2nd argument! + | mov RA, [BASE+8] + | checkint RA, ->fff_fallback + |.else + | .ffunc_nn name + | sseconst_tobit xmm2, RB + | addsd xmm0, xmm2 + | addsd xmm1, xmm2 + | movd RBd, xmm0 + | movd RAd, xmm1 + |.endif + | ins RBd, cl // Assumes RA is ecx. + | jmp ->fff_resbit + |.endmacro + | + |.ffunc_bit_sh bit_lshift, shl + |.ffunc_bit_sh bit_rshift, shr + |.ffunc_bit_sh bit_arshift, sar + |.ffunc_bit_sh bit_rol, rol + |.ffunc_bit_sh bit_ror, ror + | + |//----------------------------------------------------------------------- + | + |->fff_fallback_2: + | mov NARGS:RDd, 1+2 // Other args are ignored, anyway. + | jmp ->fff_fallback + |->fff_fallback_1: + | mov NARGS:RDd, 1+1 // Other args are ignored, anyway. + |->fff_fallback: // Call fast function fallback handler. + | // BASE = new base, RD = nargs+1 + | mov L:RB, SAVE_L + | mov PC, [BASE-8] // Fallback may overwrite PC. + | mov SAVE_PC, PC // Redundant (but a defined value). + | mov L:RB->base, BASE + | lea RD, [BASE+NARGS:RD*8-8] + | lea RA, [RD+8*LUA_MINSTACK] // Ensure enough space for handler. + | mov L:RB->top, RD + | mov CFUNC:RD, [BASE-16] + | cleartp CFUNC:RD + | cmp RA, L:RB->maxstack + | ja >5 // Need to grow stack. + | mov CARG1, L:RB + | call aword CFUNC:RD->f // (lua_State *L) + | mov BASE, L:RB->base + | // Either throws an error, or recovers and returns -1, 0 or nresults+1. + | test RDd, RDd; jg ->fff_res // Returned nresults+1? + |1: + | mov RA, L:RB->top + | sub RA, BASE + | shr RAd, 3 + | test RDd, RDd + | lea NARGS:RDd, [RAd+1] + | mov LFUNC:RB, [BASE-16] + | jne ->vm_call_tail // Returned -1? + | cleartp LFUNC:RB + | ins_callt // Returned 0: retry fast path. + | + |// Reconstruct previous base for vmeta_call during tailcall. + |->vm_call_tail: + | mov RA, BASE + | test PCd, FRAME_TYPE + | jnz >3 + | movzx RBd, PC_RA + | neg RB + | lea BASE, [BASE+RB*8-16] // base = base - (RB+2)*8 + | jmp ->vm_call_dispatch // Resolve again for tailcall. + |3: + | mov RB, PC + | and RB, -8 + | sub BASE, RB + | jmp ->vm_call_dispatch // Resolve again for tailcall. + | + |5: // Grow stack for fallback handler. + | mov CARG2d, LUA_MINSTACK + | mov CARG1, L:RB + | call extern lj_state_growstack // (lua_State *L, int n) + | mov BASE, L:RB->base + | xor RDd, RDd // Simulate a return 0. + | jmp <1 // Dumb retry (goes through ff first). + | + |->fff_gcstep: // Call GC step function. + | // BASE = new base, RD = nargs+1 + | pop RB // Must keep stack at same level. + | mov TMP1, RB // Save return address + | mov L:RB, SAVE_L + | mov SAVE_PC, PC // Redundant (but a defined value). + | mov L:RB->base, BASE + | lea RD, [BASE+NARGS:RD*8-8] + | mov CARG1, L:RB + | mov L:RB->top, RD + | call extern lj_gc_step // (lua_State *L) + | mov BASE, L:RB->base + | mov RD, L:RB->top + | sub RD, BASE + | shr RDd, 3 + | add NARGS:RDd, 1 + | mov RB, TMP1 + | push RB // Restore return address. + | ret + | + |//----------------------------------------------------------------------- + |//-- Special dispatch targets ------------------------------------------- + |//----------------------------------------------------------------------- + | + |->vm_record: // Dispatch target for recording phase. + |.if JIT + | movzx RDd, byte [DISPATCH+DISPATCH_GL(hookmask)] + | test RDL, HOOK_VMEVENT // No recording while in vmevent. + | jnz >5 + | // Decrement the hookcount for consistency, but always do the call. + | test RDL, HOOK_ACTIVE + | jnz >1 + | test RDL, LUA_MASKLINE|LUA_MASKCOUNT + | jz >1 + | dec dword [DISPATCH+DISPATCH_GL(hookcount)] + | jmp >1 + |.endif + | + |->vm_rethook: // Dispatch target for return hooks. + | movzx RDd, byte [DISPATCH+DISPATCH_GL(hookmask)] + | test RDL, HOOK_ACTIVE // Hook already active? + | jnz >5 + | jmp >1 + | + |->vm_inshook: // Dispatch target for instr/line hooks. + | movzx RDd, byte [DISPATCH+DISPATCH_GL(hookmask)] + | test RDL, HOOK_ACTIVE // Hook already active? + | jnz >5 + | + | test RDL, LUA_MASKLINE|LUA_MASKCOUNT + | jz >5 + | dec dword [DISPATCH+DISPATCH_GL(hookcount)] + | jz >1 + | test RDL, LUA_MASKLINE + | jz >5 + |1: + | mov L:RB, SAVE_L + | mov L:RB->base, BASE + | mov CARG2, PC // Caveat: CARG2 == BASE + | mov CARG1, L:RB + | // SAVE_PC must hold the _previous_ PC. The callee updates it with PC. + | call extern lj_dispatch_ins // (lua_State *L, const BCIns *pc) + |3: + | mov BASE, L:RB->base + |4: + | movzx RAd, PC_RA + |5: + | movzx OP, PC_OP + | movzx RDd, PC_RD + | jmp aword [DISPATCH+OP*8+GG_DISP2STATIC] // Re-dispatch to static ins. + | + |->cont_hook: // Continue from hook yield. + | add PC, 4 + | mov RA, [RB-40] + | mov MULTRES, RAd // Restore MULTRES for *M ins. + | jmp <4 + | + |->vm_hotloop: // Hot loop counter underflow. + |.if JIT + | mov LFUNC:RB, [BASE-16] // Same as curr_topL(L). + | cleartp LFUNC:RB + | mov RB, LFUNC:RB->pc + | movzx RDd, byte [RB+PC2PROTO(framesize)] + | lea RD, [BASE+RD*8] + | mov L:RB, SAVE_L + | mov L:RB->base, BASE + | mov L:RB->top, RD + | mov CARG2, PC + | lea CARG1, [DISPATCH+GG_DISP2J] + | mov aword [DISPATCH+DISPATCH_J(L)], L:RB + | mov SAVE_PC, PC + | call extern lj_trace_hot // (jit_State *J, const BCIns *pc) + | jmp <3 + |.endif + | + |->vm_callhook: // Dispatch target for call hooks. + | mov SAVE_PC, PC + |.if JIT + | jmp >1 + |.endif + | + |->vm_hotcall: // Hot call counter underflow. + |.if JIT + | mov SAVE_PC, PC + | or PC, 1 // Marker for hot call. + |1: + |.endif + | lea RD, [BASE+NARGS:RD*8-8] + | mov L:RB, SAVE_L + | mov L:RB->base, BASE + | mov L:RB->top, RD + | mov CARG2, PC + | mov CARG1, L:RB + | call extern lj_dispatch_call // (lua_State *L, const BCIns *pc) + | // ASMFunction returned in eax/rax (RD). + | mov SAVE_PC, 0 // Invalidate for subsequent line hook. + |.if JIT + | and PC, -2 + |.endif + | mov BASE, L:RB->base + | mov RA, RD + | mov RD, L:RB->top + | sub RD, BASE + | mov RB, RA + | movzx RAd, PC_RA + | shr RDd, 3 + | add NARGS:RDd, 1 + | jmp RB + | + |->cont_stitch: // Trace stitching. + |.if JIT + | // BASE = base, RC = result, RB = mbase + | mov TRACE:ITYPE, [RB-40] // Save previous trace. + | cleartp TRACE:ITYPE + | mov TMPRd, MULTRES + | movzx RAd, PC_RA + | lea RA, [BASE+RA*8] // Call base. + | sub TMPRd, 1 + | jz >2 + |1: // Move results down. + | mov RB, [RC] + | mov [RA], RB + | add RC, 8 + | add RA, 8 + | sub TMPRd, 1 + | jnz <1 + |2: + | movzx RCd, PC_RA + | movzx RBd, PC_RB + | add RC, RB + | lea RC, [BASE+RC*8-8] + |3: + | cmp RC, RA + | ja >9 // More results wanted? + | + | test TRACE:ITYPE, TRACE:ITYPE + | jz ->cont_nop + | movzx RBd, word TRACE:ITYPE->traceno + | movzx RDd, word TRACE:ITYPE->link + | cmp RDd, RBd + | je ->cont_nop // Blacklisted. + | test RDd, RDd + | jne =>BC_JLOOP // Jump to stitched trace. + | + | // Stitch a new trace to the previous trace. + | mov [DISPATCH+DISPATCH_J(exitno)], RB + | mov L:RB, SAVE_L + | mov L:RB->base, BASE + | mov CARG2, PC + | lea CARG1, [DISPATCH+GG_DISP2J] + | mov aword [DISPATCH+DISPATCH_J(L)], L:RB + | call extern lj_dispatch_stitch // (jit_State *J, const BCIns *pc) + | mov BASE, L:RB->base + | jmp ->cont_nop + | + |9: // Fill up results with nil. + | mov aword [RA], LJ_TNIL + | add RA, 8 + | jmp <3 + |.endif + | + |->vm_profhook: // Dispatch target for profiler hook. +#if LJ_HASPROFILE + | mov L:RB, SAVE_L + | mov L:RB->base, BASE + | mov CARG2, PC // Caveat: CARG2 == BASE + | mov CARG1, L:RB + | call extern lj_dispatch_profile // (lua_State *L, const BCIns *pc) + | mov BASE, L:RB->base + | // HOOK_PROFILE is off again, so re-dispatch to dynamic instruction. + | sub PC, 4 + | jmp ->cont_nop +#endif + | + |//----------------------------------------------------------------------- + |//-- Trace exit handler ------------------------------------------------- + |//----------------------------------------------------------------------- + | + |// Called from an exit stub with the exit number on the stack. + |// The 16 bit exit number is stored with two (sign-extended) push imm8. + |->vm_exit_handler: + |.if JIT + | push r13; push r12 + | push r11; push r10; push r9; push r8 + | push rdi; push rsi; push rbp; lea rbp, [rsp+88]; push rbp + | push rbx; push rdx; push rcx; push rax + | movzx RCd, byte [rbp-8] // Reconstruct exit number. + | mov RCH, byte [rbp-16] + | mov [rbp-8], r15; mov [rbp-16], r14 + | // DISPATCH is preserved on-trace in LJ_GC64 mode. + | mov RAd, [DISPATCH+DISPATCH_GL(vmstate)] // Get trace number. + | set_vmstate EXIT + | mov [DISPATCH+DISPATCH_J(exitno)], RCd + | mov [DISPATCH+DISPATCH_J(parent)], RAd + |.if X64WIN + | sub rsp, 16*8+4*8 // Room for SSE regs + save area. + |.else + | sub rsp, 16*8 // Room for SSE regs. + |.endif + | add rbp, -128 + | movsd qword [rbp-8], xmm15; movsd qword [rbp-16], xmm14 + | movsd qword [rbp-24], xmm13; movsd qword [rbp-32], xmm12 + | movsd qword [rbp-40], xmm11; movsd qword [rbp-48], xmm10 + | movsd qword [rbp-56], xmm9; movsd qword [rbp-64], xmm8 + | movsd qword [rbp-72], xmm7; movsd qword [rbp-80], xmm6 + | movsd qword [rbp-88], xmm5; movsd qword [rbp-96], xmm4 + | movsd qword [rbp-104], xmm3; movsd qword [rbp-112], xmm2 + | movsd qword [rbp-120], xmm1; movsd qword [rbp-128], xmm0 + | // Caveat: RB is rbp. + | mov L:RB, [DISPATCH+DISPATCH_GL(cur_L)] + | mov BASE, [DISPATCH+DISPATCH_GL(jit_base)] + | mov aword [DISPATCH+DISPATCH_J(L)], L:RB + | mov L:RB->base, BASE + |.if X64WIN + | lea CARG2, [rsp+4*8] + |.else + | mov CARG2, rsp + |.endif + | lea CARG1, [DISPATCH+GG_DISP2J] + | mov qword [DISPATCH+DISPATCH_GL(jit_base)], 0 + | call extern lj_trace_exit // (jit_State *J, ExitState *ex) + | // MULTRES or negated error code returned in eax (RD). + | mov RA, L:RB->cframe + | and RA, CFRAME_RAWMASK + | mov [RA+CFRAME_OFS_L], L:RB // Set SAVE_L (on-trace resume/yield). + | mov BASE, L:RB->base + | mov PC, [RA+CFRAME_OFS_PC] // Get SAVE_PC. + | jmp >1 + |.endif + |->vm_exit_interp: + | // RD = MULTRES or negated error code, BASE, PC and DISPATCH set. + |.if JIT + | // Restore additional callee-save registers only used in compiled code. + |.if X64WIN + | lea RA, [rsp+10*16+4*8] + |1: + | movdqa xmm15, [RA-10*16] + | movdqa xmm14, [RA-9*16] + | movdqa xmm13, [RA-8*16] + | movdqa xmm12, [RA-7*16] + | movdqa xmm11, [RA-6*16] + | movdqa xmm10, [RA-5*16] + | movdqa xmm9, [RA-4*16] + | movdqa xmm8, [RA-3*16] + | movdqa xmm7, [RA-2*16] + | mov rsp, RA // Reposition stack to C frame. + | movdqa xmm6, [RA-1*16] + | mov r15, CSAVE_1 + | mov r14, CSAVE_2 + | mov r13, CSAVE_3 + | mov r12, CSAVE_4 + |.else + | lea RA, [rsp+16] + |1: + | mov r13, [RA-8] + | mov r12, [RA] + | mov rsp, RA // Reposition stack to C frame. + |.endif + | test RDd, RDd; js >9 // Check for error from exit. + | mov L:RB, SAVE_L + | mov MULTRES, RDd + | mov LFUNC:KBASE, [BASE-16] + | cleartp LFUNC:KBASE + | mov KBASE, LFUNC:KBASE->pc + | mov KBASE, [KBASE+PC2PROTO(k)] + | mov L:RB->base, BASE + | mov qword [DISPATCH+DISPATCH_GL(jit_base)], 0 + | set_vmstate INTERP + | // Modified copy of ins_next which handles function header dispatch, too. + | mov RCd, [PC] + | movzx RAd, RCH + | movzx OP, RCL + | add PC, 4 + | shr RCd, 16 + | cmp OP, BC_FUNCF // Function header? + | jb >3 + | cmp OP, BC_FUNCC+2 // Fast function? + | jae >4 + |2: + | mov RCd, MULTRES // RC/RD holds nres+1. + |3: + | jmp aword [DISPATCH+OP*8] + | + |4: // Check frame below fast function. + | mov RC, [BASE-8] + | test RCd, FRAME_TYPE + | jnz <2 // Trace stitching continuation? + | // Otherwise set KBASE for Lua function below fast function. + | movzx RCd, byte [RC-3] + | neg RC + | mov LFUNC:KBASE, [BASE+RC*8-32] + | cleartp LFUNC:KBASE + | mov KBASE, LFUNC:KBASE->pc + | mov KBASE, [KBASE+PC2PROTO(k)] + | jmp <2 + | + |9: // Rethrow error from the right C frame. + | mov CARG2d, RDd + | mov CARG1, L:RB + | neg CARG2d + | call extern lj_err_trace // (lua_State *L, int errcode) + |.endif + | + |//----------------------------------------------------------------------- + |//-- Math helper functions ---------------------------------------------- + |//----------------------------------------------------------------------- + | + |// FP value rounding. Called by math.floor/math.ceil fast functions + |// and from JIT code. arg/ret is xmm0. xmm0-xmm3 and RD (eax) modified. + |.macro vm_round, name, mode, cond + |->name: + |->name .. _sse: + | sseconst_abs xmm2, RD + | sseconst_2p52 xmm3, RD + | movaps xmm1, xmm0 + | andpd xmm1, xmm2 // |x| + | ucomisd xmm3, xmm1 // No truncation if 2^52 <= |x|. + | jbe >1 + | andnpd xmm2, xmm0 // Isolate sign bit. + |.if mode == 2 // trunc(x)? + | movaps xmm0, xmm1 + | addsd xmm1, xmm3 // (|x| + 2^52) - 2^52 + | subsd xmm1, xmm3 + | sseconst_1 xmm3, RD + | cmpsd xmm0, xmm1, 1 // |x| < result? + | andpd xmm0, xmm3 + | subsd xmm1, xmm0 // If yes, subtract -1. + | orpd xmm1, xmm2 // Merge sign bit back in. + |.else + | addsd xmm1, xmm3 // (|x| + 2^52) - 2^52 + | subsd xmm1, xmm3 + | orpd xmm1, xmm2 // Merge sign bit back in. + | sseconst_1 xmm3, RD + | .if mode == 1 // ceil(x)? + | cmpsd xmm0, xmm1, 6 // x > result? + | andpd xmm0, xmm3 + | addsd xmm1, xmm0 // If yes, add 1. + | orpd xmm1, xmm2 // Merge sign bit back in (again). + | .else // floor(x)? + | cmpsd xmm0, xmm1, 1 // x < result? + | andpd xmm0, xmm3 + | subsd xmm1, xmm0 // If yes, subtract 1. + | .endif + |.endif + | movaps xmm0, xmm1 + |1: + | ret + |.endmacro + | + | vm_round vm_floor, 0, 1 + | vm_round vm_ceil, 1, JIT + | vm_round vm_trunc, 2, JIT + | + |// FP modulo x%y. Called by BC_MOD* and vm_arith. + |->vm_mod: + |// Args in xmm0/xmm1, return value in xmm0. + |// Caveat: xmm0-xmm5 and RC (eax) modified! + | movaps xmm5, xmm0 + | divsd xmm0, xmm1 + | sseconst_abs xmm2, RD + | sseconst_2p52 xmm3, RD + | movaps xmm4, xmm0 + | andpd xmm4, xmm2 // |x/y| + | ucomisd xmm3, xmm4 // No truncation if 2^52 <= |x/y|. + | jbe >1 + | andnpd xmm2, xmm0 // Isolate sign bit. + | addsd xmm4, xmm3 // (|x/y| + 2^52) - 2^52 + | subsd xmm4, xmm3 + | orpd xmm4, xmm2 // Merge sign bit back in. + | sseconst_1 xmm2, RD + | cmpsd xmm0, xmm4, 1 // x/y < result? + | andpd xmm0, xmm2 + | subsd xmm4, xmm0 // If yes, subtract 1.0. + | movaps xmm0, xmm5 + | mulsd xmm1, xmm4 + | subsd xmm0, xmm1 + | ret + |1: + | mulsd xmm1, xmm0 + | movaps xmm0, xmm5 + | subsd xmm0, xmm1 + | ret + | + |//----------------------------------------------------------------------- + |//-- Miscellaneous functions -------------------------------------------- + |//----------------------------------------------------------------------- + | + |// int lj_vm_cpuid(uint32_t f, uint32_t res[4]) + |->vm_cpuid: + | mov eax, CARG1d + | .if X64WIN; push rsi; mov rsi, CARG2; .endif + | push rbx + | xor ecx, ecx + | cpuid + | mov [rsi], eax + | mov [rsi+4], ebx + | mov [rsi+8], ecx + | mov [rsi+12], edx + | pop rbx + | .if X64WIN; pop rsi; .endif + | ret + | + |.define NEXT_TAB, TAB:CARG1 + |.define NEXT_IDX, CARG2d + |.define NEXT_IDXa, CARG2 + |.define NEXT_PTR, RC + |.define NEXT_PTRd, RCd + |.define NEXT_TMP, CARG3 + |.define NEXT_ASIZE, CARG4d + |.macro NEXT_RES_IDXL, op2; lea edx, [NEXT_IDX+op2]; .endmacro + |.if X64WIN + |.define NEXT_RES_PTR, [rsp+aword*5] + |.macro NEXT_RES_IDX, op2; add NEXT_IDX, op2; .endmacro + |.else + |.define NEXT_RES_PTR, [rsp+aword*1] + |.macro NEXT_RES_IDX, op2; lea edx, [NEXT_IDX+op2]; .endmacro + |.endif + | + |// TValue *lj_vm_next(GCtab *t, uint32_t idx) + |// Next idx returned in edx. + |->vm_next: + |.if JIT + | mov NEXT_ASIZE, NEXT_TAB->asize + |1: // Traverse array part. + | cmp NEXT_IDX, NEXT_ASIZE; jae >5 + | mov NEXT_TMP, NEXT_TAB->array + | mov NEXT_TMP, qword [NEXT_TMP+NEXT_IDX*8] + | cmp NEXT_TMP, LJ_TNIL; je >2 + | lea NEXT_PTR, NEXT_RES_PTR + | mov qword [NEXT_PTR], NEXT_TMP + |.if DUALNUM + | setint NEXT_TMP, NEXT_IDXa + | mov qword [NEXT_PTR+qword*1], NEXT_TMP + |.else + | cvtsi2sd xmm0, NEXT_IDX + | movsd qword [NEXT_PTR+qword*1], xmm0 + |.endif + | NEXT_RES_IDX 1 + | ret + |2: // Skip holes in array part. + | add NEXT_IDX, 1 + | jmp <1 + | + |5: // Traverse hash part. + | sub NEXT_IDX, NEXT_ASIZE + |6: + | cmp NEXT_IDX, NEXT_TAB->hmask; ja >9 + | imul NEXT_PTRd, NEXT_IDX, #NODE + | add NODE:NEXT_PTR, NEXT_TAB->node + | cmp qword NODE:NEXT_PTR->val, LJ_TNIL; je >7 + | NEXT_RES_IDXL NEXT_ASIZE+1 + | ret + |7: // Skip holes in hash part. + | add NEXT_IDX, 1 + | jmp <6 + | + |9: // End of iteration. Set the key to nil (not the value). + | NEXT_RES_IDX NEXT_ASIZE + | lea NEXT_PTR, NEXT_RES_PTR + | mov qword [NEXT_PTR+qword*1], LJ_TNIL + | ret + |.endif + | + |//----------------------------------------------------------------------- + |//-- Assertions --------------------------------------------------------- + |//----------------------------------------------------------------------- + | + |->assert_bad_for_arg_type: +#ifdef LUA_USE_ASSERT + | int3 +#endif + | int3 + | + |//----------------------------------------------------------------------- + |//-- FFI helper functions ----------------------------------------------- + |//----------------------------------------------------------------------- + | + |// Handler for callback functions. Callback slot number in ah/al. + |->vm_ffi_callback: + |.if FFI + |.type CTSTATE, CTState, PC + | saveregs_ // ebp/rbp already saved. ebp now holds global_State *. + | lea DISPATCH, [ebp+GG_G2DISP] + | mov CTSTATE, GL:ebp->ctype_state + | movzx eax, ax + | mov CTSTATE->cb.slot, eax + | mov CTSTATE->cb.gpr[0], CARG1 + | mov CTSTATE->cb.gpr[1], CARG2 + | mov CTSTATE->cb.gpr[2], CARG3 + | mov CTSTATE->cb.gpr[3], CARG4 + | movsd qword CTSTATE->cb.fpr[0], xmm0 + | movsd qword CTSTATE->cb.fpr[1], xmm1 + | movsd qword CTSTATE->cb.fpr[2], xmm2 + | movsd qword CTSTATE->cb.fpr[3], xmm3 + |.if X64WIN + | lea rax, [rsp+CFRAME_SIZE+4*8] + |.else + | lea rax, [rsp+CFRAME_SIZE] + | mov CTSTATE->cb.gpr[4], CARG5 + | mov CTSTATE->cb.gpr[5], CARG6 + | movsd qword CTSTATE->cb.fpr[4], xmm4 + | movsd qword CTSTATE->cb.fpr[5], xmm5 + | movsd qword CTSTATE->cb.fpr[6], xmm6 + | movsd qword CTSTATE->cb.fpr[7], xmm7 + |.endif + | mov CTSTATE->cb.stack, rax + | mov CARG2, rsp + | mov SAVE_PC, CTSTATE // Any value outside of bytecode is ok. + | mov CARG1, CTSTATE + | call extern lj_ccallback_enter // (CTState *cts, void *cf) + | // lua_State * returned in eax (RD). + | set_vmstate INTERP + | mov BASE, L:RD->base + | mov RD, L:RD->top + | sub RD, BASE + | mov LFUNC:RB, [BASE-16] + | cleartp LFUNC:RB + | shr RD, 3 + | add RD, 1 + | ins_callt + |.endif + | + |->cont_ffi_callback: // Return from FFI callback. + |.if FFI + | mov L:RA, SAVE_L + | mov CTSTATE, [DISPATCH+DISPATCH_GL(ctype_state)] + | mov aword CTSTATE->L, L:RA + | mov L:RA->base, BASE + | mov L:RA->top, RB + | mov CARG1, CTSTATE + | mov CARG2, RC + | call extern lj_ccallback_leave // (CTState *cts, TValue *o) + | mov rax, CTSTATE->cb.gpr[0] + | movsd xmm0, qword CTSTATE->cb.fpr[0] + | jmp ->vm_leave_unw + |.endif + | + |->vm_ffi_call: // Call C function via FFI. + | // Caveat: needs special frame unwinding, see below. + |.if FFI + | .type CCSTATE, CCallState, rbx + | push rbp; mov rbp, rsp; push rbx; mov CCSTATE, CARG1 + | + | // Readjust stack. + | mov eax, CCSTATE->spadj + | sub rsp, rax + | + | // Copy stack slots. + | movzx ecx, byte CCSTATE->nsp + | sub ecx, 1 + | js >2 + |1: + | mov rax, [CCSTATE+rcx*8+offsetof(CCallState, stack)] + | mov [rsp+rcx*8+CCALL_SPS_EXTRA*8], rax + | sub ecx, 1 + | jns <1 + |2: + | + | movzx eax, byte CCSTATE->nfpr + | mov CARG1, CCSTATE->gpr[0] + | mov CARG2, CCSTATE->gpr[1] + | mov CARG3, CCSTATE->gpr[2] + | mov CARG4, CCSTATE->gpr[3] + |.if not X64WIN + | mov CARG5, CCSTATE->gpr[4] + | mov CARG6, CCSTATE->gpr[5] + |.endif + | test eax, eax; jz >5 + | movaps xmm0, CCSTATE->fpr[0] + | movaps xmm1, CCSTATE->fpr[1] + | movaps xmm2, CCSTATE->fpr[2] + | movaps xmm3, CCSTATE->fpr[3] + |.if not X64WIN + | cmp eax, 4; jbe >5 + | movaps xmm4, CCSTATE->fpr[4] + | movaps xmm5, CCSTATE->fpr[5] + | movaps xmm6, CCSTATE->fpr[6] + | movaps xmm7, CCSTATE->fpr[7] + |.endif + |5: + | + | call aword CCSTATE->func + | + | mov CCSTATE->gpr[0], rax + | movaps CCSTATE->fpr[0], xmm0 + |.if not X64WIN + | mov CCSTATE->gpr[1], rdx + | movaps CCSTATE->fpr[1], xmm1 + |.endif + | + | mov rbx, [rbp-8]; leave; ret + |.endif + |// Note: vm_ffi_call must be the last function in this object file! + | + |//----------------------------------------------------------------------- +} + +/* Generate the code for a single instruction. */ +static void build_ins(BuildCtx *ctx, BCOp op, int defop) +{ + int vk = 0; + |// Note: aligning all instructions does not pay off. + |=>defop: + + switch (op) { + + /* -- Comparison ops ---------------------------------------------------- */ + + /* Remember: all ops branch for a true comparison, fall through otherwise. */ + + |.macro jmp_comp, lt, ge, le, gt, target + ||switch (op) { + ||case BC_ISLT: + | lt target + ||break; + ||case BC_ISGE: + | ge target + ||break; + ||case BC_ISLE: + | le target + ||break; + ||case BC_ISGT: + | gt target + ||break; + ||default: break; /* Shut up GCC. */ + ||} + |.endmacro + + case BC_ISLT: case BC_ISGE: case BC_ISLE: case BC_ISGT: + | // RA = src1, RD = src2, JMP with RD = target + | ins_AD + | mov ITYPE, [BASE+RA*8] + | mov RB, [BASE+RD*8] + | mov RA, ITYPE + | mov RD, RB + | sar ITYPE, 47 + | sar RB, 47 + |.if DUALNUM + | cmp ITYPEd, LJ_TISNUM; jne >7 + | cmp RBd, LJ_TISNUM; jne >8 + | add PC, 4 + | cmp RAd, RDd + | jmp_comp jge, jl, jg, jle, >9 + |6: + | movzx RDd, PC_RD + | branchPC RD + |9: + | ins_next + | + |7: // RA is not an integer. + | ja ->vmeta_comp + | // RA is a number. + | cmp RBd, LJ_TISNUM; jb >1; jne ->vmeta_comp + | // RA is a number, RD is an integer. + | cvtsi2sd xmm0, RDd + | jmp >2 + | + |8: // RA is an integer, RD is not an integer. + | ja ->vmeta_comp + | // RA is an integer, RD is a number. + | cvtsi2sd xmm1, RAd + | movd xmm0, RD + | jmp >3 + |.else + | cmp ITYPEd, LJ_TISNUM; jae ->vmeta_comp + | cmp RBd, LJ_TISNUM; jae ->vmeta_comp + |.endif + |1: + | movd xmm0, RD + |2: + | movd xmm1, RA + |3: + | add PC, 4 + | ucomisd xmm0, xmm1 + | // Unordered: all of ZF CF PF set, ordered: PF clear. + | // To preserve NaN semantics GE/GT branch on unordered, but LT/LE don't. + |.if DUALNUM + | jmp_comp jbe, ja, jb, jae, <9 + | jmp <6 + |.else + | jmp_comp jbe, ja, jb, jae, >1 + | movzx RDd, PC_RD + | branchPC RD + |1: + | ins_next + |.endif + break; + + case BC_ISEQV: case BC_ISNEV: + vk = op == BC_ISEQV; + | ins_AD // RA = src1, RD = src2, JMP with RD = target + | mov RB, [BASE+RD*8] + | mov ITYPE, [BASE+RA*8] + | add PC, 4 + | mov RD, RB + | mov RA, ITYPE + | sar RB, 47 + | sar ITYPE, 47 + |.if DUALNUM + | cmp RBd, LJ_TISNUM; jne >7 + | cmp ITYPEd, LJ_TISNUM; jne >8 + | cmp RDd, RAd + if (vk) { + | jne >9 + } else { + | je >9 + } + | movzx RDd, PC_RD + | branchPC RD + |9: + | ins_next + | + |7: // RD is not an integer. + | ja >5 + | // RD is a number. + | movd xmm1, RD + | cmp ITYPEd, LJ_TISNUM; jb >1; jne >5 + | // RD is a number, RA is an integer. + | cvtsi2sd xmm0, RAd + | jmp >2 + | + |8: // RD is an integer, RA is not an integer. + | ja >5 + | // RD is an integer, RA is a number. + | cvtsi2sd xmm1, RDd + | jmp >1 + | + |.else + | cmp RBd, LJ_TISNUM; jae >5 + | cmp ITYPEd, LJ_TISNUM; jae >5 + | movd xmm1, RD + |.endif + |1: + | movd xmm0, RA + |2: + | ucomisd xmm0, xmm1 + |4: + iseqne_fp: + if (vk) { + | jp >2 // Unordered means not equal. + | jne >2 + } else { + | jp >2 // Unordered means not equal. + | je >1 + } + iseqne_end: + if (vk) { + |1: // EQ: Branch to the target. + | movzx RDd, PC_RD + | branchPC RD + |2: // NE: Fallthrough to next instruction. + |.if not FFI + |3: + |.endif + } else { + |.if not FFI + |3: + |.endif + |2: // NE: Branch to the target. + | movzx RDd, PC_RD + | branchPC RD + |1: // EQ: Fallthrough to next instruction. + } + if (LJ_DUALNUM && (op == BC_ISEQV || op == BC_ISNEV || + op == BC_ISEQN || op == BC_ISNEN)) { + | jmp <9 + } else { + | ins_next + } + | + if (op == BC_ISEQV || op == BC_ISNEV) { + |5: // Either or both types are not numbers. + |.if FFI + | cmp RBd, LJ_TCDATA; je ->vmeta_equal_cd + | cmp ITYPEd, LJ_TCDATA; je ->vmeta_equal_cd + |.endif + | cmp RA, RD + | je <1 // Same GCobjs or pvalues? + | cmp RBd, ITYPEd + | jne <2 // Not the same type? + | cmp RBd, LJ_TISTABUD + | ja <2 // Different objects and not table/ud? + | + | // Different tables or userdatas. Need to check __eq metamethod. + | // Field metatable must be at same offset for GCtab and GCudata! + | cleartp TAB:RA + | mov TAB:RB, TAB:RA->metatable + | test TAB:RB, TAB:RB + | jz <2 // No metatable? + | test byte TAB:RB->nomm, 1<vmeta_equal // Handle __eq metamethod. + } else { + |.if FFI + |3: + | cmp ITYPEd, LJ_TCDATA + if (LJ_DUALNUM && vk) { + | jne <9 + } else { + | jne <2 + } + | jmp ->vmeta_equal_cd + |.endif + } + break; + case BC_ISEQS: case BC_ISNES: + vk = op == BC_ISEQS; + | ins_AND // RA = src, RD = str const, JMP with RD = target + | mov RB, [BASE+RA*8] + | add PC, 4 + | checkstr RB, >3 + | cmp RB, [KBASE+RD*8] + iseqne_test: + if (vk) { + | jne >2 + } else { + | je >1 + } + goto iseqne_end; + case BC_ISEQN: case BC_ISNEN: + vk = op == BC_ISEQN; + | ins_AD // RA = src, RD = num const, JMP with RD = target + | mov RB, [BASE+RA*8] + | add PC, 4 + |.if DUALNUM + | checkint RB, >7 + | mov RD, [KBASE+RD*8] + | checkint RD, >8 + | cmp RBd, RDd + if (vk) { + | jne >9 + } else { + | je >9 + } + | movzx RDd, PC_RD + | branchPC RD + |9: + | ins_next + | + |7: // RA is not an integer. + | ja >3 + | // RA is a number. + | mov RD, [KBASE+RD*8] + | checkint RD, >1 + | // RA is a number, RD is an integer. + | cvtsi2sd xmm0, RDd + | jmp >2 + | + |8: // RA is an integer, RD is a number. + | cvtsi2sd xmm0, RBd + | movd xmm1, RD + | ucomisd xmm0, xmm1 + | jmp >4 + |1: + | movd xmm0, RD + |.else + | checknum RB, >3 + |1: + | movsd xmm0, qword [KBASE+RD*8] + |.endif + |2: + | ucomisd xmm0, qword [BASE+RA*8] + |4: + goto iseqne_fp; + case BC_ISEQP: case BC_ISNEP: + vk = op == BC_ISEQP; + | ins_AND // RA = src, RD = primitive type (~), JMP with RD = target + | mov RB, [BASE+RA*8] + | sar RB, 47 + | add PC, 4 + | cmp RBd, RDd + if (!LJ_HASFFI) goto iseqne_test; + if (vk) { + | jne >3 + | movzx RDd, PC_RD + | branchPC RD + |2: + | ins_next + |3: + | cmp RBd, LJ_TCDATA; jne <2 + | jmp ->vmeta_equal_cd + } else { + | je >2 + | cmp RBd, LJ_TCDATA; je ->vmeta_equal_cd + | movzx RDd, PC_RD + | branchPC RD + |2: + | ins_next + } + break; + + /* -- Unary test and copy ops ------------------------------------------- */ + + case BC_ISTC: case BC_ISFC: case BC_IST: case BC_ISF: + | ins_AD // RA = dst or unused, RD = src, JMP with RD = target + | mov ITYPE, [BASE+RD*8] + | add PC, 4 + if (op == BC_ISTC || op == BC_ISFC) { + | mov RB, ITYPE + } + | sar ITYPE, 47 + | cmp ITYPEd, LJ_TISTRUECOND + if (op == BC_IST || op == BC_ISTC) { + | jae >1 + } else { + | jb >1 + } + if (op == BC_ISTC || op == BC_ISFC) { + | mov [BASE+RA*8], RB + } + | movzx RDd, PC_RD + | branchPC RD + |1: // Fallthrough to the next instruction. + | ins_next + break; + + case BC_ISTYPE: + | ins_AD // RA = src, RD = -type + | mov RB, [BASE+RA*8] + | sar RB, 47 + | add RBd, RDd + | jne ->vmeta_istype + | ins_next + break; + case BC_ISNUM: + | ins_AD // RA = src, RD = -(TISNUM-1) + | checknumtp [BASE+RA*8], ->vmeta_istype + | ins_next + break; + + /* -- Unary ops --------------------------------------------------------- */ + + case BC_MOV: + | ins_AD // RA = dst, RD = src + | mov RB, [BASE+RD*8] + | mov [BASE+RA*8], RB + | ins_next_ + break; + case BC_NOT: + | ins_AD // RA = dst, RD = src + | mov RB, [BASE+RD*8] + | sar RB, 47 + | mov RCd, 2 + | cmp RB, LJ_TISTRUECOND + | sbb RCd, 0 + | shl RC, 47 + | not RC + | mov [BASE+RA*8], RC + | ins_next + break; + case BC_UNM: + | ins_AD // RA = dst, RD = src + | mov RB, [BASE+RD*8] + |.if DUALNUM + | checkint RB, >5 + | neg RBd + | jo >4 + | setint RB + |9: + | mov [BASE+RA*8], RB + | ins_next + |4: + | mov64 RB, U64x(41e00000,00000000) // 2^31. + | jmp <9 + |5: + | ja ->vmeta_unm + |.else + | checknum RB, ->vmeta_unm + |.endif + | mov64 RD, U64x(80000000,00000000) + | xor RB, RD + |.if DUALNUM + | jmp <9 + |.else + | mov [BASE+RA*8], RB + | ins_next + |.endif + break; + case BC_LEN: + | ins_AD // RA = dst, RD = src + | mov RD, [BASE+RD*8] + | checkstr RD, >2 + |.if DUALNUM + | mov RDd, dword STR:RD->len + |1: + | setint RD + | mov [BASE+RA*8], RD + |.else + | xorps xmm0, xmm0 + | cvtsi2sd xmm0, dword STR:RD->len + |1: + | movsd qword [BASE+RA*8], xmm0 + |.endif + | ins_next + |2: + | cmp ITYPEd, LJ_TTAB; jne ->vmeta_len + | mov TAB:CARG1, TAB:RD +#if LJ_52 + | mov TAB:RB, TAB:RD->metatable + | cmp TAB:RB, 0 + | jnz >9 + |3: +#endif + |->BC_LEN_Z: + | mov RB, BASE // Save BASE. + | call extern lj_tab_len // (GCtab *t) + | // Length of table returned in eax (RD). + |.if DUALNUM + | // Nothing to do. + |.else + | cvtsi2sd xmm0, RDd + |.endif + | mov BASE, RB // Restore BASE. + | movzx RAd, PC_RA + | jmp <1 +#if LJ_52 + |9: // Check for __len. + | test byte TAB:RB->nomm, 1<vmeta_len // 'no __len' flag NOT set: check. +#endif + break; + + /* -- Binary ops -------------------------------------------------------- */ + + |.macro ins_arithpre, sseins, ssereg + | ins_ABC + ||vk = ((int)op - BC_ADDVN) / (BC_ADDNV-BC_ADDVN); + ||switch (vk) { + ||case 0: + | checknumtp [BASE+RB*8], ->vmeta_arith_vn + | .if DUALNUM + | checknumtp [KBASE+RC*8], ->vmeta_arith_vn + | .endif + | movsd xmm0, qword [BASE+RB*8] + | sseins ssereg, qword [KBASE+RC*8] + || break; + ||case 1: + | checknumtp [BASE+RB*8], ->vmeta_arith_nv + | .if DUALNUM + | checknumtp [KBASE+RC*8], ->vmeta_arith_nv + | .endif + | movsd xmm0, qword [KBASE+RC*8] + | sseins ssereg, qword [BASE+RB*8] + || break; + ||default: + | checknumtp [BASE+RB*8], ->vmeta_arith_vv + | checknumtp [BASE+RC*8], ->vmeta_arith_vv + | movsd xmm0, qword [BASE+RB*8] + | sseins ssereg, qword [BASE+RC*8] + || break; + ||} + |.endmacro + | + |.macro ins_arithdn, intins + | ins_ABC + ||vk = ((int)op - BC_ADDVN) / (BC_ADDNV-BC_ADDVN); + ||switch (vk) { + ||case 0: + | mov RB, [BASE+RB*8] + | mov RC, [KBASE+RC*8] + | checkint RB, ->vmeta_arith_vno + | checkint RC, ->vmeta_arith_vno + | intins RBd, RCd; jo ->vmeta_arith_vno + || break; + ||case 1: + | mov RB, [BASE+RB*8] + | mov RC, [KBASE+RC*8] + | checkint RB, ->vmeta_arith_nvo + | checkint RC, ->vmeta_arith_nvo + | intins RCd, RBd; jo ->vmeta_arith_nvo + || break; + ||default: + | mov RB, [BASE+RB*8] + | mov RC, [BASE+RC*8] + | checkint RB, ->vmeta_arith_vvo + | checkint RC, ->vmeta_arith_vvo + | intins RBd, RCd; jo ->vmeta_arith_vvo + || break; + ||} + ||if (vk == 1) { + | setint RC + | mov [BASE+RA*8], RC + ||} else { + | setint RB + | mov [BASE+RA*8], RB + ||} + | ins_next + |.endmacro + | + |.macro ins_arithpost + | movsd qword [BASE+RA*8], xmm0 + |.endmacro + | + |.macro ins_arith, sseins + | ins_arithpre sseins, xmm0 + | ins_arithpost + | ins_next + |.endmacro + | + |.macro ins_arith, intins, sseins + |.if DUALNUM + | ins_arithdn intins + |.else + | ins_arith, sseins + |.endif + |.endmacro + + | // RA = dst, RB = src1 or num const, RC = src2 or num const + case BC_ADDVN: case BC_ADDNV: case BC_ADDVV: + | ins_arith add, addsd + break; + case BC_SUBVN: case BC_SUBNV: case BC_SUBVV: + | ins_arith sub, subsd + break; + case BC_MULVN: case BC_MULNV: case BC_MULVV: + | ins_arith imul, mulsd + break; + case BC_DIVVN: case BC_DIVNV: case BC_DIVVV: + | ins_arith divsd + break; + case BC_MODVN: + | ins_arithpre movsd, xmm1 + |->BC_MODVN_Z: + | call ->vm_mod + | ins_arithpost + | ins_next + break; + case BC_MODNV: case BC_MODVV: + | ins_arithpre movsd, xmm1 + | jmp ->BC_MODVN_Z // Avoid 3 copies. It's slow anyway. + break; + case BC_POW: + | ins_arithpre movsd, xmm1 + | mov RB, BASE + | call extern pow + | movzx RAd, PC_RA + | mov BASE, RB + | ins_arithpost + | ins_next + break; + + case BC_CAT: + | ins_ABC // RA = dst, RB = src_start, RC = src_end + | mov L:CARG1, SAVE_L + | mov L:CARG1->base, BASE + | lea CARG2, [BASE+RC*8] + | mov CARG3d, RCd + | sub CARG3d, RBd + |->BC_CAT_Z: + | mov L:RB, L:CARG1 + | mov SAVE_PC, PC + | call extern lj_meta_cat // (lua_State *L, TValue *top, int left) + | // NULL (finished) or TValue * (metamethod) returned in eax (RC). + | mov BASE, L:RB->base + | test RC, RC + | jnz ->vmeta_binop + | movzx RBd, PC_RB // Copy result to Stk[RA] from Stk[RB]. + | movzx RAd, PC_RA + | mov RC, [BASE+RB*8] + | mov [BASE+RA*8], RC + | ins_next + break; + + /* -- Constant ops ------------------------------------------------------ */ + + case BC_KSTR: + | ins_AND // RA = dst, RD = str const (~) + | mov RD, [KBASE+RD*8] + | settp RD, LJ_TSTR + | mov [BASE+RA*8], RD + | ins_next + break; + case BC_KCDATA: + |.if FFI + | ins_AND // RA = dst, RD = cdata const (~) + | mov RD, [KBASE+RD*8] + | settp RD, LJ_TCDATA + | mov [BASE+RA*8], RD + | ins_next + |.endif + break; + case BC_KSHORT: + | ins_AD // RA = dst, RD = signed int16 literal + |.if DUALNUM + | movsx RDd, RDW + | setint RD + | mov [BASE+RA*8], RD + |.else + | movsx RDd, RDW // Sign-extend literal. + | cvtsi2sd xmm0, RDd + | movsd qword [BASE+RA*8], xmm0 + |.endif + | ins_next + break; + case BC_KNUM: + | ins_AD // RA = dst, RD = num const + | movsd xmm0, qword [KBASE+RD*8] + | movsd qword [BASE+RA*8], xmm0 + | ins_next + break; + case BC_KPRI: + | ins_AD // RA = dst, RD = primitive type (~) + | shl RD, 47 + | not RD + | mov [BASE+RA*8], RD + | ins_next + break; + case BC_KNIL: + | ins_AD // RA = dst_start, RD = dst_end + | lea RA, [BASE+RA*8+8] + | lea RD, [BASE+RD*8] + | mov RB, LJ_TNIL + | mov [RA-8], RB // Sets minimum 2 slots. + |1: + | mov [RA], RB + | add RA, 8 + | cmp RA, RD + | jbe <1 + | ins_next + break; + + /* -- Upvalue and function ops ------------------------------------------ */ + + case BC_UGET: + | ins_AD // RA = dst, RD = upvalue # + | mov LFUNC:RB, [BASE-16] + | cleartp LFUNC:RB + | mov UPVAL:RB, [LFUNC:RB+RD*8+offsetof(GCfuncL, uvptr)] + | mov RB, UPVAL:RB->v + | mov RD, [RB] + | mov [BASE+RA*8], RD + | ins_next + break; + case BC_USETV: +#define TV2MARKOFS \ + ((int32_t)offsetof(GCupval, marked)-(int32_t)offsetof(GCupval, tv)) + | ins_AD // RA = upvalue #, RD = src + | mov LFUNC:RB, [BASE-16] + | cleartp LFUNC:RB + | mov UPVAL:RB, [LFUNC:RB+RA*8+offsetof(GCfuncL, uvptr)] + | cmp byte UPVAL:RB->closed, 0 + | mov RB, UPVAL:RB->v + | mov RA, [BASE+RD*8] + | mov [RB], RA + | jz >1 + | // Check barrier for closed upvalue. + | test byte [RB+TV2MARKOFS], LJ_GC_BLACK // isblack(uv) + | jnz >2 + |1: + | ins_next + | + |2: // Upvalue is black. Check if new value is collectable and white. + | mov RD, RA + | sar RD, 47 + | sub RDd, LJ_TISGCV + | cmp RDd, LJ_TNUMX - LJ_TISGCV // tvisgcv(v) + | jbe <1 + | cleartp GCOBJ:RA + | test byte GCOBJ:RA->gch.marked, LJ_GC_WHITES // iswhite(v) + | jz <1 + | // Crossed a write barrier. Move the barrier forward. + |.if not X64WIN + | mov CARG2, RB + | mov RB, BASE // Save BASE. + |.else + | xchg CARG2, RB // Save BASE (CARG2 == BASE). + |.endif + | lea GL:CARG1, [DISPATCH+GG_DISP2G] + | call extern lj_gc_barrieruv // (global_State *g, TValue *tv) + | mov BASE, RB // Restore BASE. + | jmp <1 + break; +#undef TV2MARKOFS + case BC_USETS: + | ins_AND // RA = upvalue #, RD = str const (~) + | mov LFUNC:RB, [BASE-16] + | cleartp LFUNC:RB + | mov UPVAL:RB, [LFUNC:RB+RA*8+offsetof(GCfuncL, uvptr)] + | mov STR:RA, [KBASE+RD*8] + | mov RD, UPVAL:RB->v + | settp STR:ITYPE, STR:RA, LJ_TSTR + | mov [RD], STR:ITYPE + | test byte UPVAL:RB->marked, LJ_GC_BLACK // isblack(uv) + | jnz >2 + |1: + | ins_next + | + |2: // Check if string is white and ensure upvalue is closed. + | test byte GCOBJ:RA->gch.marked, LJ_GC_WHITES // iswhite(str) + | jz <1 + | cmp byte UPVAL:RB->closed, 0 + | jz <1 + | // Crossed a write barrier. Move the barrier forward. + | mov RB, BASE // Save BASE (CARG2 == BASE). + | mov CARG2, RD + | lea GL:CARG1, [DISPATCH+GG_DISP2G] + | call extern lj_gc_barrieruv // (global_State *g, TValue *tv) + | mov BASE, RB // Restore BASE. + | jmp <1 + break; + case BC_USETN: + | ins_AD // RA = upvalue #, RD = num const + | mov LFUNC:RB, [BASE-16] + | cleartp LFUNC:RB + | movsd xmm0, qword [KBASE+RD*8] + | mov UPVAL:RB, [LFUNC:RB+RA*8+offsetof(GCfuncL, uvptr)] + | mov RA, UPVAL:RB->v + | movsd qword [RA], xmm0 + | ins_next + break; + case BC_USETP: + | ins_AD // RA = upvalue #, RD = primitive type (~) + | mov LFUNC:RB, [BASE-16] + | cleartp LFUNC:RB + | mov UPVAL:RB, [LFUNC:RB+RA*8+offsetof(GCfuncL, uvptr)] + | shl RD, 47 + | not RD + | mov RA, UPVAL:RB->v + | mov [RA], RD + | ins_next + break; + case BC_UCLO: + | ins_AD // RA = level, RD = target + | branchPC RD // Do this first to free RD. + | mov L:RB, SAVE_L + | cmp aword L:RB->openupval, 0 + | je >1 + | mov L:RB->base, BASE + | lea CARG2, [BASE+RA*8] // Caveat: CARG2 == BASE + | mov L:CARG1, L:RB // Caveat: CARG1 == RA + | call extern lj_func_closeuv // (lua_State *L, TValue *level) + | mov BASE, L:RB->base + |1: + | ins_next + break; + + case BC_FNEW: + | ins_AND // RA = dst, RD = proto const (~) (holding function prototype) + | mov L:RB, SAVE_L + | mov L:RB->base, BASE // Caveat: CARG2/CARG3 may be BASE. + | mov CARG3, [BASE-16] + | cleartp CARG3 + | mov CARG2, [KBASE+RD*8] // Fetch GCproto *. + | mov CARG1, L:RB + | mov SAVE_PC, PC + | // (lua_State *L, GCproto *pt, GCfuncL *parent) + | call extern lj_func_newL_gc + | // GCfuncL * returned in eax (RC). + | mov BASE, L:RB->base + | movzx RAd, PC_RA + | settp LFUNC:RC, LJ_TFUNC + | mov [BASE+RA*8], LFUNC:RC + | ins_next + break; + + /* -- Table ops --------------------------------------------------------- */ + + case BC_TNEW: + | ins_AD // RA = dst, RD = hbits|asize + | mov L:RB, SAVE_L + | mov L:RB->base, BASE + | mov RA, [DISPATCH+DISPATCH_GL(gc.total)] + | cmp RA, [DISPATCH+DISPATCH_GL(gc.threshold)] + | mov SAVE_PC, PC + | jae >5 + |1: + | mov CARG3d, RDd + | and RDd, 0x7ff + | shr CARG3d, 11 + | cmp RDd, 0x7ff + | je >3 + |2: + | mov L:CARG1, L:RB + | mov CARG2d, RDd + | call extern lj_tab_new // (lua_State *L, int32_t asize, uint32_t hbits) + | // Table * returned in eax (RC). + | mov BASE, L:RB->base + | movzx RAd, PC_RA + | settp TAB:RC, LJ_TTAB + | mov [BASE+RA*8], TAB:RC + | ins_next + |3: // Turn 0x7ff into 0x801. + | mov RDd, 0x801 + | jmp <2 + |5: + | mov L:CARG1, L:RB + | call extern lj_gc_step_fixtop // (lua_State *L) + | movzx RDd, PC_RD + | jmp <1 + break; + case BC_TDUP: + | ins_AND // RA = dst, RD = table const (~) (holding template table) + | mov L:RB, SAVE_L + | mov RA, [DISPATCH+DISPATCH_GL(gc.total)] + | mov SAVE_PC, PC + | cmp RA, [DISPATCH+DISPATCH_GL(gc.threshold)] + | mov L:RB->base, BASE + | jae >3 + |2: + | mov TAB:CARG2, [KBASE+RD*8] // Caveat: CARG2 == BASE + | mov L:CARG1, L:RB // Caveat: CARG1 == RA + | call extern lj_tab_dup // (lua_State *L, Table *kt) + | // Table * returned in eax (RC). + | mov BASE, L:RB->base + | movzx RAd, PC_RA + | settp TAB:RC, LJ_TTAB + | mov [BASE+RA*8], TAB:RC + | ins_next + |3: + | mov L:CARG1, L:RB + | call extern lj_gc_step_fixtop // (lua_State *L) + | movzx RDd, PC_RD // Need to reload RD. + | not RD + | jmp <2 + break; + + case BC_GGET: + | ins_AND // RA = dst, RD = str const (~) + | mov LFUNC:RB, [BASE-16] + | cleartp LFUNC:RB + | mov TAB:RB, LFUNC:RB->env + | mov STR:RC, [KBASE+RD*8] + | jmp ->BC_TGETS_Z + break; + case BC_GSET: + | ins_AND // RA = src, RD = str const (~) + | mov LFUNC:RB, [BASE-16] + | cleartp LFUNC:RB + | mov TAB:RB, LFUNC:RB->env + | mov STR:RC, [KBASE+RD*8] + | jmp ->BC_TSETS_Z + break; + + case BC_TGETV: + | ins_ABC // RA = dst, RB = table, RC = key + | mov TAB:RB, [BASE+RB*8] + | mov RC, [BASE+RC*8] + | checktab TAB:RB, ->vmeta_tgetv + | + | // Integer key? + |.if DUALNUM + | checkint RC, >5 + |.else + | // Convert number to int and back and compare. + | checknum RC, >5 + | movd xmm0, RC + | cvttsd2si RCd, xmm0 + | cvtsi2sd xmm1, RCd + | ucomisd xmm0, xmm1 + | jne ->vmeta_tgetv // Generic numeric key? Use fallback. + |.endif + | cmp RCd, TAB:RB->asize // Takes care of unordered, too. + | jae ->vmeta_tgetv // Not in array part? Use fallback. + | shl RCd, 3 + | add RC, TAB:RB->array + | // Get array slot. + | mov ITYPE, [RC] + | cmp ITYPE, LJ_TNIL // Avoid overwriting RB in fastpath. + | je >2 + |1: + | mov [BASE+RA*8], ITYPE + | ins_next + | + |2: // Check for __index if table value is nil. + | mov TAB:TMPR, TAB:RB->metatable + | test TAB:TMPR, TAB:TMPR + | jz <1 + | test byte TAB:TMPR->nomm, 1<vmeta_tgetv // 'no __index' flag NOT set: check. + | jmp <1 + | + |5: // String key? + | cmp ITYPEd, LJ_TSTR; jne ->vmeta_tgetv + | cleartp STR:RC + | jmp ->BC_TGETS_Z + break; + case BC_TGETS: + | ins_ABC // RA = dst, RB = table, RC = str const (~) + | mov TAB:RB, [BASE+RB*8] + | not RC + | mov STR:RC, [KBASE+RC*8] + | checktab TAB:RB, ->vmeta_tgets + |->BC_TGETS_Z: // RB = GCtab *, RC = GCstr * + | mov TMPRd, TAB:RB->hmask + | and TMPRd, STR:RC->sid + | imul TMPRd, #NODE + | add NODE:TMPR, TAB:RB->node + | settp ITYPE, STR:RC, LJ_TSTR + |1: + | cmp NODE:TMPR->key, ITYPE + | jne >4 + | // Get node value. + | mov ITYPE, NODE:TMPR->val + | cmp ITYPE, LJ_TNIL + | je >5 // Key found, but nil value? + |2: + | mov [BASE+RA*8], ITYPE + | ins_next + | + |4: // Follow hash chain. + | mov NODE:TMPR, NODE:TMPR->next + | test NODE:TMPR, NODE:TMPR + | jnz <1 + | // End of hash chain: key not found, nil result. + | mov ITYPE, LJ_TNIL + | + |5: // Check for __index if table value is nil. + | mov TAB:TMPR, TAB:RB->metatable + | test TAB:TMPR, TAB:TMPR + | jz <2 // No metatable: done. + | test byte TAB:TMPR->nomm, 1<vmeta_tgets // Caveat: preserve STR:RC. + break; + case BC_TGETB: + | ins_ABC // RA = dst, RB = table, RC = byte literal + | mov TAB:RB, [BASE+RB*8] + | checktab TAB:RB, ->vmeta_tgetb + | cmp RCd, TAB:RB->asize + | jae ->vmeta_tgetb + | shl RCd, 3 + | add RC, TAB:RB->array + | // Get array slot. + | mov ITYPE, [RC] + | cmp ITYPE, LJ_TNIL + | je >2 + |1: + | mov [BASE+RA*8], ITYPE + | ins_next + | + |2: // Check for __index if table value is nil. + | mov TAB:TMPR, TAB:RB->metatable + | test TAB:TMPR, TAB:TMPR + | jz <1 + | test byte TAB:TMPR->nomm, 1<vmeta_tgetb // 'no __index' flag NOT set: check. + | jmp <1 + break; + case BC_TGETR: + | ins_ABC // RA = dst, RB = table, RC = key + | mov TAB:RB, [BASE+RB*8] + | cleartp TAB:RB + |.if DUALNUM + | mov RCd, dword [BASE+RC*8] + |.else + | cvttsd2si RCd, qword [BASE+RC*8] + |.endif + | cmp RCd, TAB:RB->asize + | jae ->vmeta_tgetr // Not in array part? Use fallback. + | shl RCd, 3 + | add RC, TAB:RB->array + | // Get array slot. + |->BC_TGETR_Z: + | mov ITYPE, [RC] + |->BC_TGETR2_Z: + | mov [BASE+RA*8], ITYPE + | ins_next + break; + + case BC_TSETV: + | ins_ABC // RA = src, RB = table, RC = key + | mov TAB:RB, [BASE+RB*8] + | mov RC, [BASE+RC*8] + | checktab TAB:RB, ->vmeta_tsetv + | + | // Integer key? + |.if DUALNUM + | checkint RC, >5 + |.else + | // Convert number to int and back and compare. + | checknum RC, >5 + | movd xmm0, RC + | cvttsd2si RCd, xmm0 + | cvtsi2sd xmm1, RCd + | ucomisd xmm0, xmm1 + | jne ->vmeta_tsetv // Generic numeric key? Use fallback. + |.endif + | cmp RCd, TAB:RB->asize // Takes care of unordered, too. + | jae ->vmeta_tsetv + | shl RCd, 3 + | add RC, TAB:RB->array + | cmp aword [RC], LJ_TNIL + | je >3 // Previous value is nil? + |1: + | test byte TAB:RB->marked, LJ_GC_BLACK // isblack(table) + | jnz >7 + |2: // Set array slot. + | mov RB, [BASE+RA*8] + | mov [RC], RB + | ins_next + | + |3: // Check for __newindex if previous value is nil. + | mov TAB:TMPR, TAB:RB->metatable + | test TAB:TMPR, TAB:TMPR + | jz <1 + | test byte TAB:TMPR->nomm, 1<vmeta_tsetv // 'no __newindex' flag NOT set: check. + | jmp <1 + | + |5: // String key? + | cmp ITYPEd, LJ_TSTR; jne ->vmeta_tsetv + | cleartp STR:RC + | jmp ->BC_TSETS_Z + | + |7: // Possible table write barrier for the value. Skip valiswhite check. + | barrierback TAB:RB, TMPR + | jmp <2 + break; + case BC_TSETS: + | ins_ABC // RA = src, RB = table, RC = str const (~) + | mov TAB:RB, [BASE+RB*8] + | not RC + | mov STR:RC, [KBASE+RC*8] + | checktab TAB:RB, ->vmeta_tsets + |->BC_TSETS_Z: // RB = GCtab *, RC = GCstr * + | mov TMPRd, TAB:RB->hmask + | and TMPRd, STR:RC->sid + | imul TMPRd, #NODE + | mov byte TAB:RB->nomm, 0 // Clear metamethod cache. + | add NODE:TMPR, TAB:RB->node + | settp ITYPE, STR:RC, LJ_TSTR + |1: + | cmp NODE:TMPR->key, ITYPE + | jne >5 + | // Ok, key found. Assumes: offsetof(Node, val) == 0 + | cmp aword [TMPR], LJ_TNIL + | je >4 // Previous value is nil? + |2: + | test byte TAB:RB->marked, LJ_GC_BLACK // isblack(table) + | jnz >7 + |3: // Set node value. + | mov ITYPE, [BASE+RA*8] + | mov [TMPR], ITYPE + | ins_next + | + |4: // Check for __newindex if previous value is nil. + | mov TAB:ITYPE, TAB:RB->metatable + | test TAB:ITYPE, TAB:ITYPE + | jz <2 + | test byte TAB:ITYPE->nomm, 1<vmeta_tsets // 'no __newindex' flag NOT set: check. + | jmp <2 + | + |5: // Follow hash chain. + | mov NODE:TMPR, NODE:TMPR->next + | test NODE:TMPR, NODE:TMPR + | jnz <1 + | // End of hash chain: key not found, add a new one. + | + | // But check for __newindex first. + | mov TAB:TMPR, TAB:RB->metatable + | test TAB:TMPR, TAB:TMPR + | jz >6 // No metatable: continue. + | test byte TAB:TMPR->nomm, 1<vmeta_tsets // 'no __newindex' flag NOT set: check. + |6: + | mov TMP1, ITYPE + | mov L:CARG1, SAVE_L + | mov L:CARG1->base, BASE + | lea CARG3, TMP1 + | mov CARG2, TAB:RB + | mov SAVE_PC, PC + | call extern lj_tab_newkey // (lua_State *L, GCtab *t, TValue *k) + | // Handles write barrier for the new key. TValue * returned in eax (RC). + | mov L:CARG1, SAVE_L + | mov BASE, L:CARG1->base + | mov TMPR, rax + | movzx RAd, PC_RA + | jmp <2 // Must check write barrier for value. + | + |7: // Possible table write barrier for the value. Skip valiswhite check. + | barrierback TAB:RB, ITYPE + | jmp <3 + break; + case BC_TSETB: + | ins_ABC // RA = src, RB = table, RC = byte literal + | mov TAB:RB, [BASE+RB*8] + | checktab TAB:RB, ->vmeta_tsetb + | cmp RCd, TAB:RB->asize + | jae ->vmeta_tsetb + | shl RCd, 3 + | add RC, TAB:RB->array + | cmp aword [RC], LJ_TNIL + | je >3 // Previous value is nil? + |1: + | test byte TAB:RB->marked, LJ_GC_BLACK // isblack(table) + | jnz >7 + |2: // Set array slot. + | mov ITYPE, [BASE+RA*8] + | mov [RC], ITYPE + | ins_next + | + |3: // Check for __newindex if previous value is nil. + | mov TAB:TMPR, TAB:RB->metatable + | test TAB:TMPR, TAB:TMPR + | jz <1 + | test byte TAB:TMPR->nomm, 1<vmeta_tsetb // 'no __newindex' flag NOT set: check. + | jmp <1 + | + |7: // Possible table write barrier for the value. Skip valiswhite check. + | barrierback TAB:RB, TMPR + | jmp <2 + break; + case BC_TSETR: + | ins_ABC // RA = src, RB = table, RC = key + | mov TAB:RB, [BASE+RB*8] + | cleartp TAB:RB + |.if DUALNUM + | mov RC, [BASE+RC*8] + |.else + | cvttsd2si RCd, qword [BASE+RC*8] + |.endif + | test byte TAB:RB->marked, LJ_GC_BLACK // isblack(table) + | jnz >7 + |2: + | cmp RCd, TAB:RB->asize + | jae ->vmeta_tsetr + | shl RCd, 3 + | add RC, TAB:RB->array + | // Set array slot. + |->BC_TSETR_Z: + | mov ITYPE, [BASE+RA*8] + | mov [RC], ITYPE + | ins_next + | + |7: // Possible table write barrier for the value. Skip valiswhite check. + | barrierback TAB:RB, TMPR + | jmp <2 + break; + + case BC_TSETM: + | ins_AD // RA = base (table at base-1), RD = num const (start index) + |1: + | mov TMPRd, dword [KBASE+RD*8] // Integer constant is in lo-word. + | lea RA, [BASE+RA*8] + | mov TAB:RB, [RA-8] // Guaranteed to be a table. + | cleartp TAB:RB + | test byte TAB:RB->marked, LJ_GC_BLACK // isblack(table) + | jnz >7 + |2: + | mov RDd, MULTRES + | sub RDd, 1 + | jz >4 // Nothing to copy? + | add RDd, TMPRd // Compute needed size. + | cmp RDd, TAB:RB->asize + | ja >5 // Doesn't fit into array part? + | sub RDd, TMPRd + | shl TMPRd, 3 + | add TMPR, TAB:RB->array + |3: // Copy result slots to table. + | mov RB, [RA] + | add RA, 8 + | mov [TMPR], RB + | add TMPR, 8 + | sub RDd, 1 + | jnz <3 + |4: + | ins_next + | + |5: // Need to resize array part. + | mov L:CARG1, SAVE_L + | mov L:CARG1->base, BASE // Caveat: CARG2/CARG3 may be BASE. + | mov CARG2, TAB:RB + | mov CARG3d, RDd + | mov L:RB, L:CARG1 + | mov SAVE_PC, PC + | call extern lj_tab_reasize // (lua_State *L, GCtab *t, int nasize) + | mov BASE, L:RB->base + | movzx RAd, PC_RA // Restore RA. + | movzx RDd, PC_RD // Restore RD. + | jmp <1 // Retry. + | + |7: // Possible table write barrier for any value. Skip valiswhite check. + | barrierback TAB:RB, RD + | jmp <2 + break; + + /* -- Calls and vararg handling ----------------------------------------- */ + + case BC_CALL: case BC_CALLM: + | ins_A_C // RA = base, (RB = nresults+1,) RC = nargs+1 | extra_nargs + if (op == BC_CALLM) { + | add NARGS:RDd, MULTRES + } + | mov LFUNC:RB, [BASE+RA*8] + | checkfunc LFUNC:RB, ->vmeta_call_ra + | lea BASE, [BASE+RA*8+16] + | ins_call + break; + + case BC_CALLMT: + | ins_AD // RA = base, RD = extra_nargs + | add NARGS:RDd, MULTRES + | // Fall through. Assumes BC_CALLT follows and ins_AD is a no-op. + break; + case BC_CALLT: + | ins_AD // RA = base, RD = nargs+1 + | lea RA, [BASE+RA*8+16] + | mov KBASE, BASE // Use KBASE for move + vmeta_call hint. + | mov LFUNC:RB, [RA-16] + | checktp_nc LFUNC:RB, LJ_TFUNC, ->vmeta_call + |->BC_CALLT_Z: + | mov PC, [BASE-8] + | test PCd, FRAME_TYPE + | jnz >7 + |1: + | mov [BASE-16], LFUNC:RB // Copy func+tag down, reloaded below. + | mov MULTRES, NARGS:RDd + | sub NARGS:RDd, 1 + | jz >3 + |2: // Move args down. + | mov RB, [RA] + | add RA, 8 + | mov [KBASE], RB + | add KBASE, 8 + | sub NARGS:RDd, 1 + | jnz <2 + | + | mov LFUNC:RB, [BASE-16] + |3: + | cleartp LFUNC:RB + | mov NARGS:RDd, MULTRES + | cmp byte LFUNC:RB->ffid, 1 // (> FF_C) Calling a fast function? + | ja >5 + |4: + | ins_callt + | + |5: // Tailcall to a fast function. + | test PCd, FRAME_TYPE // Lua frame below? + | jnz <4 + | movzx RAd, PC_RA + | neg RA + | mov LFUNC:KBASE, [BASE+RA*8-32] // Need to prepare KBASE. + | cleartp LFUNC:KBASE + | mov KBASE, LFUNC:KBASE->pc + | mov KBASE, [KBASE+PC2PROTO(k)] + | jmp <4 + | + |7: // Tailcall from a vararg function. + | sub PC, FRAME_VARG + | test PCd, FRAME_TYPEP + | jnz >8 // Vararg frame below? + | sub BASE, PC // Need to relocate BASE/KBASE down. + | mov KBASE, BASE + | mov PC, [BASE-8] + | jmp <1 + |8: + | add PCd, FRAME_VARG + | jmp <1 + break; + + case BC_ITERC: + | ins_A // RA = base, (RB = nresults+1,) RC = nargs+1 (2+1) + | lea RA, [BASE+RA*8+16] // fb = base+2 + | mov RB, [RA-32] // Copy state. fb[0] = fb[-4]. + | mov RC, [RA-24] // Copy control var. fb[1] = fb[-3]. + | mov [RA], RB + | mov [RA+8], RC + | mov LFUNC:RB, [RA-40] // Copy callable. fb[-2] = fb[-5] + | mov [RA-16], LFUNC:RB + | mov NARGS:RDd, 2+1 // Handle like a regular 2-arg call. + | checkfunc LFUNC:RB, ->vmeta_call + | mov BASE, RA + | ins_call + break; + + case BC_ITERN: + |.if JIT + | hotloop RBd + |.endif + |->vm_IITERN: + | ins_A // RA = base, (RB = nresults+1, RC = nargs+1 (2+1)) + | mov TAB:RB, [BASE+RA*8-16] + | cleartp TAB:RB + | mov RCd, [BASE+RA*8-8] // Get index from control var. + | mov TMPRd, TAB:RB->asize + | add PC, 4 + | mov ITYPE, TAB:RB->array + |1: // Traverse array part. + | cmp RCd, TMPRd; jae >5 // Index points after array part? + | cmp aword [ITYPE+RC*8], LJ_TNIL; je >4 + |.if not DUALNUM + | cvtsi2sd xmm0, RCd + |.endif + | // Copy array slot to returned value. + | mov RB, [ITYPE+RC*8] + | mov [BASE+RA*8+8], RB + | // Return array index as a numeric key. + |.if DUALNUM + | setint ITYPE, RC + | mov [BASE+RA*8], ITYPE + |.else + | movsd qword [BASE+RA*8], xmm0 + |.endif + | add RCd, 1 + | mov [BASE+RA*8-8], RCd // Update control var. + |2: + | movzx RDd, PC_RD // Get target from ITERL. + | branchPC RD + |3: + | ins_next + | + |4: // Skip holes in array part. + | add RCd, 1 + | jmp <1 + | + |5: // Traverse hash part. + | sub RCd, TMPRd + |6: + | cmp RCd, TAB:RB->hmask; ja <3 // End of iteration? Branch to ITERL+1. + | imul ITYPEd, RCd, #NODE + | add NODE:ITYPE, TAB:RB->node + | cmp aword NODE:ITYPE->val, LJ_TNIL; je >7 + | lea TMPRd, [RCd+TMPRd+1] + | // Copy key and value from hash slot. + | mov RB, NODE:ITYPE->key + | mov RC, NODE:ITYPE->val + | mov [BASE+RA*8], RB + | mov [BASE+RA*8+8], RC + | mov [BASE+RA*8-8], TMPRd + | jmp <2 + | + |7: // Skip holes in hash part. + | add RCd, 1 + | jmp <6 + break; + + case BC_ISNEXT: + | ins_AD // RA = base, RD = target (points to ITERN) + | mov CFUNC:RB, [BASE+RA*8-24] + | checkfunc CFUNC:RB, >5 + | checktptp [BASE+RA*8-16], LJ_TTAB, >5 + | cmp aword [BASE+RA*8-8], LJ_TNIL; jne >5 + | cmp byte CFUNC:RB->ffid, FF_next_N; jne >5 + | branchPC RD + | mov64 TMPR, ((uint64_t)LJ_KEYINDEX << 32) + | mov [BASE+RA*8-8], TMPR // Initialize control var. + |1: + | ins_next + |5: // Despecialize bytecode if any of the checks fail. + | mov PC_OP, BC_JMP + | branchPC RD + |.if JIT + | cmp byte [PC], BC_ITERN + | jne >6 + |.endif + | mov byte [PC], BC_ITERC + | jmp <1 + |.if JIT + |6: // Unpatch JLOOP. + | mov RA, [DISPATCH+DISPATCH_J(trace)] + | movzx RCd, word [PC+2] + | mov TRACE:RA, [RA+RC*8] + | mov eax, TRACE:RA->startins + | mov al, BC_ITERC + | mov dword [PC], eax + | jmp <1 + |.endif + break; + + case BC_VARG: + | ins_ABC // RA = base, RB = nresults+1, RC = numparams + | lea TMPR, [BASE+RC*8+(16+FRAME_VARG)] + | lea RA, [BASE+RA*8] + | sub TMPR, [BASE-8] + | // Note: TMPR may now be even _above_ BASE if nargs was < numparams. + | test RB, RB + | jz >5 // Copy all varargs? + | lea RB, [RA+RB*8-8] + | cmp TMPR, BASE // No vararg slots? + | jnb >2 + |1: // Copy vararg slots to destination slots. + | mov RC, [TMPR-16] + | add TMPR, 8 + | mov [RA], RC + | add RA, 8 + | cmp RA, RB // All destination slots filled? + | jnb >3 + | cmp TMPR, BASE // No more vararg slots? + | jb <1 + |2: // Fill up remainder with nil. + | mov aword [RA], LJ_TNIL + | add RA, 8 + | cmp RA, RB + | jb <2 + |3: + | ins_next + | + |5: // Copy all varargs. + | mov MULTRES, 1 // MULTRES = 0+1 + | mov RC, BASE + | sub RC, TMPR + | jbe <3 // No vararg slots? + | mov RBd, RCd + | shr RBd, 3 + | add RBd, 1 + | mov MULTRES, RBd // MULTRES = #varargs+1 + | mov L:RB, SAVE_L + | add RC, RA + | cmp RC, L:RB->maxstack + | ja >7 // Need to grow stack? + |6: // Copy all vararg slots. + | mov RC, [TMPR-16] + | add TMPR, 8 + | mov [RA], RC + | add RA, 8 + | cmp TMPR, BASE // No more vararg slots? + | jb <6 + | jmp <3 + | + |7: // Grow stack for varargs. + | mov L:RB->base, BASE + | mov L:RB->top, RA + | mov SAVE_PC, PC + | sub TMPR, BASE // Need delta, because BASE may change. + | mov TMP1hi, TMPRd + | mov CARG2d, MULTRES + | sub CARG2d, 1 + | mov CARG1, L:RB + | call extern lj_state_growstack // (lua_State *L, int n) + | mov BASE, L:RB->base + | movsxd TMPR, TMP1hi + | mov RA, L:RB->top + | add TMPR, BASE + | jmp <6 + break; + + /* -- Returns ----------------------------------------------------------- */ + + case BC_RETM: + | ins_AD // RA = results, RD = extra_nresults + | add RDd, MULTRES // MULTRES >=1, so RD >=1. + | // Fall through. Assumes BC_RET follows and ins_AD is a no-op. + break; + + case BC_RET: case BC_RET0: case BC_RET1: + | ins_AD // RA = results, RD = nresults+1 + if (op != BC_RET0) { + | shl RAd, 3 + } + |1: + | mov PC, [BASE-8] + | mov MULTRES, RDd // Save nresults+1. + | test PCd, FRAME_TYPE // Check frame type marker. + | jnz >7 // Not returning to a fixarg Lua func? + switch (op) { + case BC_RET: + |->BC_RET_Z: + | mov KBASE, BASE // Use KBASE for result move. + | sub RDd, 1 + | jz >3 + |2: // Move results down. + | mov RB, [KBASE+RA] + | mov [KBASE-16], RB + | add KBASE, 8 + | sub RDd, 1 + | jnz <2 + |3: + | mov RDd, MULTRES // Note: MULTRES may be >255. + | movzx RBd, PC_RB // So cannot compare with RDL! + |5: + | cmp RBd, RDd // More results expected? + | ja >6 + break; + case BC_RET1: + | mov RB, [BASE+RA] + | mov [BASE-16], RB + /* fallthrough */ + case BC_RET0: + |5: + | cmp PC_RB, RDL // More results expected? + | ja >6 + default: + break; + } + | movzx RAd, PC_RA + | neg RA + | lea BASE, [BASE+RA*8-16] // base = base - (RA+2)*8 + | mov LFUNC:KBASE, [BASE-16] + | cleartp LFUNC:KBASE + | mov KBASE, LFUNC:KBASE->pc + | mov KBASE, [KBASE+PC2PROTO(k)] + | ins_next + | + |6: // Fill up results with nil. + if (op == BC_RET) { + | mov aword [KBASE-16], LJ_TNIL // Note: relies on shifted base. + | add KBASE, 8 + } else { + | mov aword [BASE+RD*8-24], LJ_TNIL + } + | add RD, 1 + | jmp <5 + | + |7: // Non-standard return case. + | lea RB, [PC-FRAME_VARG] + | test RBd, FRAME_TYPEP + | jnz ->vm_return + | // Return from vararg function: relocate BASE down and RA up. + | sub BASE, RB + if (op != BC_RET0) { + | add RA, RB + } + | jmp <1 + break; + + /* -- Loops and branches ------------------------------------------------ */ + + |.define FOR_IDX, [RA] + |.define FOR_STOP, [RA+8] + |.define FOR_STEP, [RA+16] + |.define FOR_EXT, [RA+24] + + case BC_FORL: + |.if JIT + | hotloop RBd + |.endif + | // Fall through. Assumes BC_IFORL follows and ins_AJ is a no-op. + break; + + case BC_JFORI: + case BC_JFORL: +#if !LJ_HASJIT + break; +#endif + case BC_FORI: + case BC_IFORL: + vk = (op == BC_IFORL || op == BC_JFORL); + | ins_AJ // RA = base, RD = target (after end of loop or start of loop) + | lea RA, [BASE+RA*8] + if (LJ_DUALNUM) { + | mov RB, FOR_IDX + | checkint RB, >9 + | mov TMPR, FOR_STOP + if (!vk) { + | checkint TMPR, ->vmeta_for + | mov ITYPE, FOR_STEP + | test ITYPEd, ITYPEd; js >5 + | sar ITYPE, 47; + | cmp ITYPEd, LJ_TISNUM; jne ->vmeta_for + } else { +#ifdef LUA_USE_ASSERT + | checkinttp FOR_STOP, ->assert_bad_for_arg_type + | checkinttp FOR_STEP, ->assert_bad_for_arg_type +#endif + | mov ITYPE, FOR_STEP + | test ITYPEd, ITYPEd; js >5 + | add RBd, ITYPEd; jo >1 + | setint RB + | mov FOR_IDX, RB + } + | cmp RBd, TMPRd + | mov FOR_EXT, RB + if (op == BC_FORI) { + | jle >7 + |1: + |6: + | branchPC RD + } else if (op == BC_JFORI) { + | branchPC RD + | movzx RDd, PC_RD + | jle =>BC_JLOOP + |1: + |6: + } else if (op == BC_IFORL) { + | jg >7 + |6: + | branchPC RD + |1: + } else { + | jle =>BC_JLOOP + |1: + |6: + } + |7: + | ins_next + | + |5: // Invert check for negative step. + if (!vk) { + | sar ITYPE, 47; + | cmp ITYPEd, LJ_TISNUM; jne ->vmeta_for + } else { + | add RBd, ITYPEd; jo <1 + | setint RB + | mov FOR_IDX, RB + } + | cmp RBd, TMPRd + | mov FOR_EXT, RB + if (op == BC_FORI) { + | jge <7 + } else if (op == BC_JFORI) { + | branchPC RD + | movzx RDd, PC_RD + | jge =>BC_JLOOP + } else if (op == BC_IFORL) { + | jl <7 + } else { + | jge =>BC_JLOOP + } + | jmp <6 + |9: // Fallback to FP variant. + if (!vk) { + | jae ->vmeta_for + } + } else if (!vk) { + | checknumtp FOR_IDX, ->vmeta_for + } + if (!vk) { + | checknumtp FOR_STOP, ->vmeta_for + } else { +#ifdef LUA_USE_ASSERT + | checknumtp FOR_STOP, ->assert_bad_for_arg_type + | checknumtp FOR_STEP, ->assert_bad_for_arg_type +#endif + } + | mov RB, FOR_STEP + if (!vk) { + | checknum RB, ->vmeta_for + } + | movsd xmm0, qword FOR_IDX + | movsd xmm1, qword FOR_STOP + if (vk) { + | addsd xmm0, qword FOR_STEP + | movsd qword FOR_IDX, xmm0 + | test RB, RB; js >3 + } else { + | jl >3 + } + | ucomisd xmm1, xmm0 + |1: + | movsd qword FOR_EXT, xmm0 + if (op == BC_FORI) { + |.if DUALNUM + | jnb <7 + |.else + | jnb >2 + | branchPC RD + |.endif + } else if (op == BC_JFORI) { + | branchPC RD + | movzx RDd, PC_RD + | jnb =>BC_JLOOP + } else if (op == BC_IFORL) { + |.if DUALNUM + | jb <7 + |.else + | jb >2 + | branchPC RD + |.endif + } else { + | jnb =>BC_JLOOP + } + |.if DUALNUM + | jmp <6 + |.else + |2: + | ins_next + |.endif + | + |3: // Invert comparison if step is negative. + | ucomisd xmm0, xmm1 + | jmp <1 + break; + + case BC_ITERL: + |.if JIT + | hotloop RBd + |.endif + | // Fall through. Assumes BC_IITERL follows and ins_AJ is a no-op. + break; + + case BC_JITERL: +#if !LJ_HASJIT + break; +#endif + case BC_IITERL: + | ins_AJ // RA = base, RD = target + | lea RA, [BASE+RA*8] + | mov RB, [RA] + | cmp RB, LJ_TNIL; je >1 // Stop if iterator returned nil. + if (op == BC_JITERL) { + | mov [RA-8], RB + | jmp =>BC_JLOOP + } else { + | branchPC RD // Otherwise save control var + branch. + | mov [RA-8], RB + } + |1: + | ins_next + break; + + case BC_LOOP: + | ins_A // RA = base, RD = target (loop extent) + | // Note: RA/RD is only used by trace recorder to determine scope/extent + | // This opcode does NOT jump, it's only purpose is to detect a hot loop. + |.if JIT + | hotloop RBd + |.endif + | // Fall through. Assumes BC_ILOOP follows and ins_A is a no-op. + break; + + case BC_ILOOP: + | ins_A // RA = base, RD = target (loop extent) + | ins_next + break; + + case BC_JLOOP: + |.if JIT + | ins_AD // RA = base (ignored), RD = traceno + | mov RA, [DISPATCH+DISPATCH_J(trace)] + | mov TRACE:RD, [RA+RD*8] + | mov RD, TRACE:RD->mcode + | mov L:RB, SAVE_L + | mov [DISPATCH+DISPATCH_GL(jit_base)], BASE + | mov [DISPATCH+DISPATCH_GL(tmpbuf.L)], L:RB + | // Save additional callee-save registers only used in compiled code. + |.if X64WIN + | mov CSAVE_4, r12 + | mov CSAVE_3, r13 + | mov CSAVE_2, r14 + | mov CSAVE_1, r15 + | mov RA, rsp + | sub rsp, 10*16+4*8 + | movdqa [RA-1*16], xmm6 + | movdqa [RA-2*16], xmm7 + | movdqa [RA-3*16], xmm8 + | movdqa [RA-4*16], xmm9 + | movdqa [RA-5*16], xmm10 + | movdqa [RA-6*16], xmm11 + | movdqa [RA-7*16], xmm12 + | movdqa [RA-8*16], xmm13 + | movdqa [RA-9*16], xmm14 + | movdqa [RA-10*16], xmm15 + |.else + | sub rsp, 16 + | mov [rsp+16], r12 + | mov [rsp+8], r13 + |.endif + | jmp RD + |.endif + break; + + case BC_JMP: + | ins_AJ // RA = unused, RD = target + | branchPC RD + | ins_next + break; + + /* -- Function headers -------------------------------------------------- */ + + /* + ** Reminder: A function may be called with func/args above L->maxstack, + ** i.e. occupying EXTRA_STACK slots. And vmeta_call may add one extra slot, + ** too. This means all FUNC* ops (including fast functions) must check + ** for stack overflow _before_ adding more slots! + */ + + case BC_FUNCF: + |.if JIT + | hotcall RBd + |.endif + case BC_FUNCV: /* NYI: compiled vararg functions. */ + | // Fall through. Assumes BC_IFUNCF/BC_IFUNCV follow and ins_AD is a no-op. + break; + + case BC_JFUNCF: +#if !LJ_HASJIT + break; +#endif + case BC_IFUNCF: + | ins_AD // BASE = new base, RA = framesize, RD = nargs+1 + | mov KBASE, [PC-4+PC2PROTO(k)] + | mov L:RB, SAVE_L + | lea RA, [BASE+RA*8] // Top of frame. + | cmp RA, L:RB->maxstack + | ja ->vm_growstack_f + | movzx RAd, byte [PC-4+PC2PROTO(numparams)] + | cmp NARGS:RDd, RAd // Check for missing parameters. + | jbe >3 + |2: + if (op == BC_JFUNCF) { + | movzx RDd, PC_RD + | jmp =>BC_JLOOP + } else { + | ins_next + } + | + |3: // Clear missing parameters. + | mov aword [BASE+NARGS:RD*8-8], LJ_TNIL + | add NARGS:RDd, 1 + | cmp NARGS:RDd, RAd + | jbe <3 + | jmp <2 + break; + + case BC_JFUNCV: +#if !LJ_HASJIT + break; +#endif + | int3 // NYI: compiled vararg functions + break; /* NYI: compiled vararg functions. */ + + case BC_IFUNCV: + | ins_AD // BASE = new base, RA = framesize, RD = nargs+1 + | lea RBd, [NARGS:RD*8+FRAME_VARG+8] + | lea RD, [BASE+NARGS:RD*8+8] + | mov LFUNC:KBASE, [BASE-16] + | mov [RD-8], RB // Store delta + FRAME_VARG. + | mov [RD-16], LFUNC:KBASE // Store copy of LFUNC. + | mov L:RB, SAVE_L + | lea RA, [RD+RA*8] + | cmp RA, L:RB->maxstack + | ja ->vm_growstack_v // Need to grow stack. + | mov RA, BASE + | mov BASE, RD + | movzx RBd, byte [PC-4+PC2PROTO(numparams)] + | test RBd, RBd + | jz >2 + | add RA, 8 + |1: // Copy fixarg slots up to new frame. + | add RA, 8 + | cmp RA, BASE + | jnb >3 // Less args than parameters? + | mov KBASE, [RA-16] + | mov [RD], KBASE + | add RD, 8 + | mov aword [RA-16], LJ_TNIL // Clear old fixarg slot (help the GC). + | sub RBd, 1 + | jnz <1 + |2: + if (op == BC_JFUNCV) { + | movzx RDd, PC_RD + | jmp =>BC_JLOOP + } else { + | mov KBASE, [PC-4+PC2PROTO(k)] + | ins_next + } + | + |3: // Clear missing parameters. + | mov aword [RD], LJ_TNIL + | add RD, 8 + | sub RBd, 1 + | jnz <3 + | jmp <2 + break; + + case BC_FUNCC: + case BC_FUNCCW: + | ins_AD // BASE = new base, RA = ins RA|RD (unused), RD = nargs+1 + | mov CFUNC:RB, [BASE-16] + | cleartp CFUNC:RB + | mov KBASE, CFUNC:RB->f + | mov L:RB, SAVE_L + | lea RD, [BASE+NARGS:RD*8-8] + | mov L:RB->base, BASE + | lea RA, [RD+8*LUA_MINSTACK] + | cmp RA, L:RB->maxstack + | mov L:RB->top, RD + if (op == BC_FUNCC) { + | mov CARG1, L:RB // Caveat: CARG1 may be RA. + } else { + | mov CARG2, KBASE + | mov CARG1, L:RB // Caveat: CARG1 may be RA. + } + | ja ->vm_growstack_c // Need to grow stack. + | set_vmstate C + if (op == BC_FUNCC) { + | call KBASE // (lua_State *L) + } else { + | // (lua_State *L, lua_CFunction f) + | call aword [DISPATCH+DISPATCH_GL(wrapf)] + } + | // nresults returned in eax (RD). + | mov BASE, L:RB->base + | mov [DISPATCH+DISPATCH_GL(cur_L)], L:RB + | set_vmstate INTERP + | lea RA, [BASE+RD*8] + | neg RA + | add RA, L:RB->top // RA = (L->top-(L->base+nresults))*8 + | mov PC, [BASE-8] // Fetch PC of caller. + | jmp ->vm_returnc + break; + + /* ---------------------------------------------------------------------- */ + + default: + fprintf(stderr, "Error: undefined opcode BC_%s\n", bc_names[op]); + exit(2); + break; + } +} + +static int build_backend(BuildCtx *ctx) +{ + int op; + dasm_growpc(Dst, BC__MAX); + build_subroutines(ctx); + |.code_op + for (op = 0; op < BC__MAX; op++) + build_ins(ctx, (BCOp)op, op); + return BC__MAX; +} + +/* Emit pseudo frame-info for all assembler functions. */ +static void emit_asm_debug(BuildCtx *ctx) +{ + int fcofs = (int)((uint8_t *)ctx->glob[GLOB_vm_ffi_call] - ctx->code); + switch (ctx->mode) { + case BUILD_elfasm: + fprintf(ctx->fp, "\t.section .debug_frame,\"\",@progbits\n"); + fprintf(ctx->fp, + ".Lframe0:\n" + "\t.long .LECIE0-.LSCIE0\n" + ".LSCIE0:\n" + "\t.long 0xffffffff\n" + "\t.byte 0x1\n" + "\t.string \"\"\n" + "\t.uleb128 0x1\n" + "\t.sleb128 -8\n" + "\t.byte 0x10\n" + "\t.byte 0xc\n\t.uleb128 0x7\n\t.uleb128 8\n" + "\t.byte 0x80+0x10\n\t.uleb128 0x1\n" + "\t.align 8\n" + ".LECIE0:\n\n"); + fprintf(ctx->fp, + ".LSFDE0:\n" + "\t.long .LEFDE0-.LASFDE0\n" + ".LASFDE0:\n" + "\t.long .Lframe0\n" + "\t.quad .Lbegin\n" + "\t.quad %d\n" + "\t.byte 0xe\n\t.uleb128 %d\n" /* def_cfa_offset */ + "\t.byte 0x86\n\t.uleb128 0x2\n" /* offset rbp */ + "\t.byte 0x83\n\t.uleb128 0x3\n" /* offset rbx */ + "\t.byte 0x8f\n\t.uleb128 0x4\n" /* offset r15 */ + "\t.byte 0x8e\n\t.uleb128 0x5\n" /* offset r14 */ +#if LJ_NO_UNWIND + "\t.byte 0x8d\n\t.uleb128 0x6\n" /* offset r13 */ + "\t.byte 0x8c\n\t.uleb128 0x7\n" /* offset r12 */ +#endif + "\t.align 8\n" + ".LEFDE0:\n\n", fcofs, CFRAME_SIZE); +#if LJ_HASFFI + fprintf(ctx->fp, + ".LSFDE1:\n" + "\t.long .LEFDE1-.LASFDE1\n" + ".LASFDE1:\n" + "\t.long .Lframe0\n" + "\t.quad lj_vm_ffi_call\n" + "\t.quad %d\n" + "\t.byte 0xe\n\t.uleb128 16\n" /* def_cfa_offset */ + "\t.byte 0x86\n\t.uleb128 0x2\n" /* offset rbp */ + "\t.byte 0xd\n\t.uleb128 0x6\n" /* def_cfa_register rbp */ + "\t.byte 0x83\n\t.uleb128 0x3\n" /* offset rbx */ + "\t.align 8\n" + ".LEFDE1:\n\n", (int)ctx->codesz - fcofs); +#endif +#if !LJ_NO_UNWIND +#if LJ_TARGET_SOLARIS + fprintf(ctx->fp, "\t.section .eh_frame,\"a\",@unwind\n"); +#else + fprintf(ctx->fp, "\t.section .eh_frame,\"a\",@progbits\n"); +#endif + fprintf(ctx->fp, + ".Lframe1:\n" + "\t.long .LECIE1-.LSCIE1\n" + ".LSCIE1:\n" + "\t.long 0\n" + "\t.byte 0x1\n" + "\t.string \"zPR\"\n" + "\t.uleb128 0x1\n" + "\t.sleb128 -8\n" + "\t.byte 0x10\n" + "\t.uleb128 6\n" /* augmentation length */ + "\t.byte 0x1b\n" /* pcrel|sdata4 */ + "\t.long lj_err_unwind_dwarf-.\n" + "\t.byte 0x1b\n" /* pcrel|sdata4 */ + "\t.byte 0xc\n\t.uleb128 0x7\n\t.uleb128 8\n" + "\t.byte 0x80+0x10\n\t.uleb128 0x1\n" + "\t.align 8\n" + ".LECIE1:\n\n"); + fprintf(ctx->fp, + ".LSFDE2:\n" + "\t.long .LEFDE2-.LASFDE2\n" + ".LASFDE2:\n" + "\t.long .LASFDE2-.Lframe1\n" + "\t.long .Lbegin-.\n" + "\t.long %d\n" + "\t.uleb128 0\n" /* augmentation length */ + "\t.byte 0xe\n\t.uleb128 %d\n" /* def_cfa_offset */ + "\t.byte 0x86\n\t.uleb128 0x2\n" /* offset rbp */ + "\t.byte 0x83\n\t.uleb128 0x3\n" /* offset rbx */ + "\t.byte 0x8f\n\t.uleb128 0x4\n" /* offset r15 */ + "\t.byte 0x8e\n\t.uleb128 0x5\n" /* offset r14 */ + "\t.align 8\n" + ".LEFDE2:\n\n", fcofs, CFRAME_SIZE); +#if LJ_HASFFI + fprintf(ctx->fp, + ".Lframe2:\n" + "\t.long .LECIE2-.LSCIE2\n" + ".LSCIE2:\n" + "\t.long 0\n" + "\t.byte 0x1\n" + "\t.string \"zR\"\n" + "\t.uleb128 0x1\n" + "\t.sleb128 -8\n" + "\t.byte 0x10\n" + "\t.uleb128 1\n" /* augmentation length */ + "\t.byte 0x1b\n" /* pcrel|sdata4 */ + "\t.byte 0xc\n\t.uleb128 0x7\n\t.uleb128 8\n" + "\t.byte 0x80+0x10\n\t.uleb128 0x1\n" + "\t.align 8\n" + ".LECIE2:\n\n"); + fprintf(ctx->fp, + ".LSFDE3:\n" + "\t.long .LEFDE3-.LASFDE3\n" + ".LASFDE3:\n" + "\t.long .LASFDE3-.Lframe2\n" + "\t.long lj_vm_ffi_call-.\n" + "\t.long %d\n" + "\t.uleb128 0\n" /* augmentation length */ + "\t.byte 0xe\n\t.uleb128 16\n" /* def_cfa_offset */ + "\t.byte 0x86\n\t.uleb128 0x2\n" /* offset rbp */ + "\t.byte 0xd\n\t.uleb128 0x6\n" /* def_cfa_register rbp */ + "\t.byte 0x83\n\t.uleb128 0x3\n" /* offset rbx */ + "\t.align 8\n" + ".LEFDE3:\n\n", (int)ctx->codesz - fcofs); +#endif +#endif + break; +#if !LJ_NO_UNWIND + /* Mental note: never let Apple design an assembler. + ** Or a linker. Or a plastic case. But I digress. + */ + case BUILD_machasm: { +#if LJ_HASFFI + int fcsize = 0; +#endif + int i; + fprintf(ctx->fp, "\t.section __TEXT,__eh_frame,coalesced,no_toc+strip_static_syms+live_support\n"); + fprintf(ctx->fp, + "EH_frame1:\n" + "\t.set L$set$x,LECIEX-LSCIEX\n" + "\t.long L$set$x\n" + "LSCIEX:\n" + "\t.long 0\n" + "\t.byte 0x1\n" + "\t.ascii \"zPR\\0\"\n" + "\t.byte 0x1\n" + "\t.byte 128-8\n" + "\t.byte 0x10\n" + "\t.byte 6\n" /* augmentation length */ + "\t.byte 0x9b\n" /* indirect|pcrel|sdata4 */ + "\t.long _lj_err_unwind_dwarf+4@GOTPCREL\n" + "\t.byte 0x1b\n" /* pcrel|sdata4 */ + "\t.byte 0xc\n\t.byte 0x7\n\t.byte 8\n" + "\t.byte 0x80+0x10\n\t.byte 0x1\n" + "\t.align 3\n" + "LECIEX:\n\n"); + for (i = 0; i < ctx->nsym; i++) { + const char *name = ctx->sym[i].name; + int32_t size = ctx->sym[i+1].ofs - ctx->sym[i].ofs; + if (size == 0) continue; +#if LJ_HASFFI + if (!strcmp(name, "_lj_vm_ffi_call")) { fcsize = size; continue; } +#endif + fprintf(ctx->fp, + "%s.eh:\n" + "LSFDE%d:\n" + "\t.set L$set$%d,LEFDE%d-LASFDE%d\n" + "\t.long L$set$%d\n" + "LASFDE%d:\n" + "\t.long LASFDE%d-EH_frame1\n" + "\t.long %s-.\n" + "\t.long %d\n" + "\t.byte 0\n" /* augmentation length */ + "\t.byte 0xe\n\t.byte %d\n" /* def_cfa_offset */ + "\t.byte 0x86\n\t.byte 0x2\n" /* offset rbp */ + "\t.byte 0x83\n\t.byte 0x3\n" /* offset rbx */ + "\t.byte 0x8f\n\t.byte 0x4\n" /* offset r15 */ + "\t.byte 0x8e\n\t.byte 0x5\n" /* offset r14 */ + "\t.align 3\n" + "LEFDE%d:\n\n", + name, i, i, i, i, i, i, i, name, size, CFRAME_SIZE, i); + } +#if LJ_HASFFI + if (fcsize) { + fprintf(ctx->fp, + "EH_frame2:\n" + "\t.set L$set$y,LECIEY-LSCIEY\n" + "\t.long L$set$y\n" + "LSCIEY:\n" + "\t.long 0\n" + "\t.byte 0x1\n" + "\t.ascii \"zR\\0\"\n" + "\t.byte 0x1\n" + "\t.byte 128-8\n" + "\t.byte 0x10\n" + "\t.byte 1\n" /* augmentation length */ + "\t.byte 0x1b\n" /* pcrel|sdata4 */ + "\t.byte 0xc\n\t.byte 0x7\n\t.byte 8\n" + "\t.byte 0x80+0x10\n\t.byte 0x1\n" + "\t.align 3\n" + "LECIEY:\n\n"); + fprintf(ctx->fp, + "_lj_vm_ffi_call.eh:\n" + "LSFDEY:\n" + "\t.set L$set$yy,LEFDEY-LASFDEY\n" + "\t.long L$set$yy\n" + "LASFDEY:\n" + "\t.long LASFDEY-EH_frame2\n" + "\t.long _lj_vm_ffi_call-.\n" + "\t.long %d\n" + "\t.byte 0\n" /* augmentation length */ + "\t.byte 0xe\n\t.byte 16\n" /* def_cfa_offset */ + "\t.byte 0x86\n\t.byte 0x2\n" /* offset rbp */ + "\t.byte 0xd\n\t.byte 0x6\n" /* def_cfa_register rbp */ + "\t.byte 0x83\n\t.byte 0x3\n" /* offset rbx */ + "\t.align 3\n" + "LEFDEY:\n\n", fcsize); + } +#endif + fprintf(ctx->fp, ".subsections_via_symbols\n"); + } + break; +#endif + default: /* Difficult for other modes. */ + break; + } +} + diff --git a/fluent-bit/lib/luajit-3065c9/src/vm_x86.dasc b/fluent-bit/lib/luajit-3065c9/src/vm_x86.dasc new file mode 100644 index 00000000..18ca87b5 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/vm_x86.dasc @@ -0,0 +1,5825 @@ +|// Low-level VM code for x86 CPUs. +|// Bytecode interpreter, fast functions and helper functions. +|// Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h +| +|.if P64 +|.arch x64 +|.else +|.arch x86 +|.endif +|.section code_op, code_sub +| +|.actionlist build_actionlist +|.globals GLOB_ +|.globalnames globnames +|.externnames extnames +| +|//----------------------------------------------------------------------- +| +|.if P64 +|.define X64, 1 +|.if WIN +|.define X64WIN, 1 +|.endif +|.endif +| +|// Fixed register assignments for the interpreter. +|// This is very fragile and has many dependencies. Caveat emptor. +|.define BASE, edx // Not C callee-save, refetched anyway. +|.if not X64 +|.define KBASE, edi // Must be C callee-save. +|.define KBASEa, KBASE +|.define PC, esi // Must be C callee-save. +|.define PCa, PC +|.define DISPATCH, ebx // Must be C callee-save. +|.elif X64WIN +|.define KBASE, edi // Must be C callee-save. +|.define KBASEa, rdi +|.define PC, esi // Must be C callee-save. +|.define PCa, rsi +|.define DISPATCH, ebx // Must be C callee-save. +|.else +|.define KBASE, r15d // Must be C callee-save. +|.define KBASEa, r15 +|.define PC, ebx // Must be C callee-save. +|.define PCa, rbx +|.define DISPATCH, r14d // Must be C callee-save. +|.endif +| +|.define RA, ecx +|.define RAH, ch +|.define RAL, cl +|.define RB, ebp // Must be ebp (C callee-save). +|.define RC, eax // Must be eax. +|.define RCW, ax +|.define RCH, ah +|.define RCL, al +|.define OP, RB +|.define RD, RC +|.define RDW, RCW +|.define RDL, RCL +|.if X64 +|.define RAa, rcx +|.define RBa, rbp +|.define RCa, rax +|.define RDa, rax +|.else +|.define RAa, RA +|.define RBa, RB +|.define RCa, RC +|.define RDa, RD +|.endif +| +|.if not X64 +|.define FCARG1, ecx // x86 fastcall arguments. +|.define FCARG2, edx +|.elif X64WIN +|.define CARG1, rcx // x64/WIN64 C call arguments. +|.define CARG2, rdx +|.define CARG3, r8 +|.define CARG4, r9 +|.define CARG1d, ecx +|.define CARG2d, edx +|.define CARG3d, r8d +|.define CARG4d, r9d +|.define FCARG1, CARG1d // Upwards compatible to x86 fastcall. +|.define FCARG2, CARG2d +|.else +|.define CARG1, rdi // x64/POSIX C call arguments. +|.define CARG2, rsi +|.define CARG3, rdx +|.define CARG4, rcx +|.define CARG5, r8 +|.define CARG6, r9 +|.define CARG1d, edi +|.define CARG2d, esi +|.define CARG3d, edx +|.define CARG4d, ecx +|.define CARG5d, r8d +|.define CARG6d, r9d +|.define FCARG1, CARG1d // Simulate x86 fastcall. +|.define FCARG2, CARG2d +|.endif +| +|// Type definitions. Some of these are only used for documentation. +|.type L, lua_State +|.type GL, global_State +|.type TVALUE, TValue +|.type GCOBJ, GCobj +|.type STR, GCstr +|.type TAB, GCtab +|.type LFUNC, GCfuncL +|.type CFUNC, GCfuncC +|.type PROTO, GCproto +|.type UPVAL, GCupval +|.type NODE, Node +|.type NARGS, int +|.type TRACE, GCtrace +|.type SBUF, SBuf +| +|// Stack layout while in interpreter. Must match with lj_frame.h. +|//----------------------------------------------------------------------- +|.if not X64 // x86 stack layout. +| +|.if WIN +| +|.define CFRAME_SPACE, aword*9 // Delta for esp (see <--). +|.macro saveregs_ +| push edi; push esi; push ebx +| push extern lj_err_unwind_win +| fs; push dword [0] +| fs; mov [0], esp +| sub esp, CFRAME_SPACE +|.endmacro +|.macro restoreregs +| add esp, CFRAME_SPACE +| fs; pop dword [0] +| pop edi // Short for esp += 4. +| pop ebx; pop esi; pop edi; pop ebp +|.endmacro +| +|.else +| +|.define CFRAME_SPACE, aword*7 // Delta for esp (see <--). +|.macro saveregs_ +| push edi; push esi; push ebx +| sub esp, CFRAME_SPACE +|.endmacro +|.macro restoreregs +| add esp, CFRAME_SPACE +| pop ebx; pop esi; pop edi; pop ebp +|.endmacro +| +|.endif +| +|.macro saveregs +| push ebp; saveregs_ +|.endmacro +| +|.if WIN +|.define SAVE_ERRF, aword [esp+aword*19] // vm_pcall/vm_cpcall only. +|.define SAVE_NRES, aword [esp+aword*18] +|.define SAVE_CFRAME, aword [esp+aword*17] +|.define SAVE_L, aword [esp+aword*16] +|//----- 16 byte aligned, ^^^ arguments from C caller +|.define SAVE_RET, aword [esp+aword*15] //<-- esp entering interpreter. +|.define SAVE_R4, aword [esp+aword*14] +|.define SAVE_R3, aword [esp+aword*13] +|.define SAVE_R2, aword [esp+aword*12] +|//----- 16 byte aligned +|.define SAVE_R1, aword [esp+aword*11] +|.define SEH_FUNC, aword [esp+aword*10] +|.define SEH_NEXT, aword [esp+aword*9] //<-- esp after register saves. +|.define UNUSED2, aword [esp+aword*8] +|//----- 16 byte aligned +|.define UNUSED1, aword [esp+aword*7] +|.define SAVE_PC, aword [esp+aword*6] +|.define TMP2, aword [esp+aword*5] +|.define TMP1, aword [esp+aword*4] +|//----- 16 byte aligned +|.define ARG4, aword [esp+aword*3] +|.define ARG3, aword [esp+aword*2] +|.define ARG2, aword [esp+aword*1] +|.define ARG1, aword [esp] //<-- esp while in interpreter. +|//----- 16 byte aligned, ^^^ arguments for C callee +|.else +|.define SAVE_ERRF, aword [esp+aword*15] // vm_pcall/vm_cpcall only. +|.define SAVE_NRES, aword [esp+aword*14] +|.define SAVE_CFRAME, aword [esp+aword*13] +|.define SAVE_L, aword [esp+aword*12] +|//----- 16 byte aligned, ^^^ arguments from C caller +|.define SAVE_RET, aword [esp+aword*11] //<-- esp entering interpreter. +|.define SAVE_R4, aword [esp+aword*10] +|.define SAVE_R3, aword [esp+aword*9] +|.define SAVE_R2, aword [esp+aword*8] +|//----- 16 byte aligned +|.define SAVE_R1, aword [esp+aword*7] //<-- esp after register saves. +|.define SAVE_PC, aword [esp+aword*6] +|.define TMP2, aword [esp+aword*5] +|.define TMP1, aword [esp+aword*4] +|//----- 16 byte aligned +|.define ARG4, aword [esp+aword*3] +|.define ARG3, aword [esp+aword*2] +|.define ARG2, aword [esp+aword*1] +|.define ARG1, aword [esp] //<-- esp while in interpreter. +|//----- 16 byte aligned, ^^^ arguments for C callee +|.endif +| +|// FPARGx overlaps ARGx and ARG(x+1) on x86. +|.define FPARG3, qword [esp+qword*1] +|.define FPARG1, qword [esp] +|// TMPQ overlaps TMP1/TMP2. ARG5/MULTRES overlap TMP1/TMP2 (and TMPQ). +|.define TMPQ, qword [esp+aword*4] +|.define TMP3, ARG4 +|.define ARG5, TMP1 +|.define TMPa, TMP1 +|.define MULTRES, TMP2 +| +|// Arguments for vm_call and vm_pcall. +|.define INARG_BASE, SAVE_CFRAME // Overwritten by SAVE_CFRAME! +| +|// Arguments for vm_cpcall. +|.define INARG_CP_CALL, SAVE_ERRF +|.define INARG_CP_UD, SAVE_NRES +|.define INARG_CP_FUNC, SAVE_CFRAME +| +|//----------------------------------------------------------------------- +|.elif X64WIN // x64/Windows stack layout +| +|.define CFRAME_SPACE, aword*5 // Delta for rsp (see <--). +|.macro saveregs_ +| push rdi; push rsi; push rbx +| sub rsp, CFRAME_SPACE +|.endmacro +|.macro saveregs +| push rbp; saveregs_ +|.endmacro +|.macro restoreregs +| add rsp, CFRAME_SPACE +| pop rbx; pop rsi; pop rdi; pop rbp +|.endmacro +| +|.define SAVE_CFRAME, aword [rsp+aword*13] +|.define SAVE_PC, dword [rsp+dword*25] +|.define SAVE_L, dword [rsp+dword*24] +|.define SAVE_ERRF, dword [rsp+dword*23] +|.define SAVE_NRES, dword [rsp+dword*22] +|.define TMP2, dword [rsp+dword*21] +|.define TMP1, dword [rsp+dword*20] +|//----- 16 byte aligned, ^^^ 32 byte register save area, owned by interpreter +|.define SAVE_RET, aword [rsp+aword*9] //<-- rsp entering interpreter. +|.define SAVE_R4, aword [rsp+aword*8] +|.define SAVE_R3, aword [rsp+aword*7] +|.define SAVE_R2, aword [rsp+aword*6] +|.define SAVE_R1, aword [rsp+aword*5] //<-- rsp after register saves. +|.define ARG5, aword [rsp+aword*4] +|.define CSAVE_4, aword [rsp+aword*3] +|.define CSAVE_3, aword [rsp+aword*2] +|.define CSAVE_2, aword [rsp+aword*1] +|.define CSAVE_1, aword [rsp] //<-- rsp while in interpreter. +|//----- 16 byte aligned, ^^^ 32 byte register save area, owned by callee +| +|// TMPQ overlaps TMP1/TMP2. MULTRES overlaps TMP2 (and TMPQ). +|.define TMPQ, qword [rsp+aword*10] +|.define MULTRES, TMP2 +|.define TMPa, ARG5 +|.define ARG5d, dword [rsp+aword*4] +|.define TMP3, ARG5d +| +|//----------------------------------------------------------------------- +|.else // x64/POSIX stack layout +| +|.define CFRAME_SPACE, aword*5 // Delta for rsp (see <--). +|.macro saveregs_ +| push rbx; push r15; push r14 +|.if NO_UNWIND +| push r13; push r12 +|.endif +| sub rsp, CFRAME_SPACE +|.endmacro +|.macro saveregs +| push rbp; saveregs_ +|.endmacro +|.macro restoreregs +| add rsp, CFRAME_SPACE +|.if NO_UNWIND +| pop r12; pop r13 +|.endif +| pop r14; pop r15; pop rbx; pop rbp +|.endmacro +| +|//----- 16 byte aligned, +|.if NO_UNWIND +|.define SAVE_RET, aword [rsp+aword*11] //<-- rsp entering interpreter. +|.define SAVE_R4, aword [rsp+aword*10] +|.define SAVE_R3, aword [rsp+aword*9] +|.define SAVE_R2, aword [rsp+aword*8] +|.define SAVE_R1, aword [rsp+aword*7] +|.define SAVE_RU2, aword [rsp+aword*6] +|.define SAVE_RU1, aword [rsp+aword*5] //<-- rsp after register saves. +|.else +|.define SAVE_RET, aword [rsp+aword*9] //<-- rsp entering interpreter. +|.define SAVE_R4, aword [rsp+aword*8] +|.define SAVE_R3, aword [rsp+aword*7] +|.define SAVE_R2, aword [rsp+aword*6] +|.define SAVE_R1, aword [rsp+aword*5] //<-- rsp after register saves. +|.endif +|.define SAVE_CFRAME, aword [rsp+aword*4] +|.define SAVE_PC, dword [rsp+dword*7] +|.define SAVE_L, dword [rsp+dword*6] +|.define SAVE_ERRF, dword [rsp+dword*5] +|.define SAVE_NRES, dword [rsp+dword*4] +|.define TMPa, aword [rsp+aword*1] +|.define TMP2, dword [rsp+dword*1] +|.define TMP1, dword [rsp] //<-- rsp while in interpreter. +|//----- 16 byte aligned +| +|// TMPQ overlaps TMP1/TMP2. MULTRES overlaps TMP2 (and TMPQ). +|.define TMPQ, qword [rsp] +|.define TMP3, dword [rsp+aword*1] +|.define MULTRES, TMP2 +| +|.endif +| +|//----------------------------------------------------------------------- +| +|// Instruction headers. +|.macro ins_A; .endmacro +|.macro ins_AD; .endmacro +|.macro ins_AJ; .endmacro +|.macro ins_ABC; movzx RB, RCH; movzx RC, RCL; .endmacro +|.macro ins_AB_; movzx RB, RCH; .endmacro +|.macro ins_A_C; movzx RC, RCL; .endmacro +|.macro ins_AND; not RDa; .endmacro +| +|// Instruction decode+dispatch. Carefully tuned (nope, lodsd is not faster). +|.macro ins_NEXT +| mov RC, [PC] +| movzx RA, RCH +| movzx OP, RCL +| add PC, 4 +| shr RC, 16 +|.if X64 +| jmp aword [DISPATCH+OP*8] +|.else +| jmp aword [DISPATCH+OP*4] +|.endif +|.endmacro +| +|// Instruction footer. +|.if 1 +| // Replicated dispatch. Less unpredictable branches, but higher I-Cache use. +| .define ins_next, ins_NEXT +| .define ins_next_, ins_NEXT +|.else +| // Common dispatch. Lower I-Cache use, only one (very) unpredictable branch. +| // Affects only certain kinds of benchmarks (and only with -j off). +| // Around 10%-30% slower on Core2, a lot more slower on P4. +| .macro ins_next +| jmp ->ins_next +| .endmacro +| .macro ins_next_ +| ->ins_next: +| ins_NEXT +| .endmacro +|.endif +| +|// Call decode and dispatch. +|.macro ins_callt +| // BASE = new base, RB = LFUNC, RD = nargs+1, [BASE-4] = PC +| mov PC, LFUNC:RB->pc +| mov RA, [PC] +| movzx OP, RAL +| movzx RA, RAH +| add PC, 4 +|.if X64 +| jmp aword [DISPATCH+OP*8] +|.else +| jmp aword [DISPATCH+OP*4] +|.endif +|.endmacro +| +|.macro ins_call +| // BASE = new base, RB = LFUNC, RD = nargs+1 +| mov [BASE-4], PC +| ins_callt +|.endmacro +| +|//----------------------------------------------------------------------- +| +|// Macros to test operand types. +|.macro checktp, reg, tp; cmp dword [BASE+reg*8+4], tp; .endmacro +|.macro checknum, reg, target; checktp reg, LJ_TISNUM; jae target; .endmacro +|.macro checkint, reg, target; checktp reg, LJ_TISNUM; jne target; .endmacro +|.macro checkstr, reg, target; checktp reg, LJ_TSTR; jne target; .endmacro +|.macro checktab, reg, target; checktp reg, LJ_TTAB; jne target; .endmacro +| +|// These operands must be used with movzx. +|.define PC_OP, byte [PC-4] +|.define PC_RA, byte [PC-3] +|.define PC_RB, byte [PC-1] +|.define PC_RC, byte [PC-2] +|.define PC_RD, word [PC-2] +| +|.macro branchPC, reg +| lea PC, [PC+reg*4-BCBIAS_J*4] +|.endmacro +| +|// Assumes DISPATCH is relative to GL. +#define DISPATCH_GL(field) (GG_DISP2G + (int)offsetof(global_State, field)) +#define DISPATCH_J(field) (GG_DISP2J + (int)offsetof(jit_State, field)) +| +#define PC2PROTO(field) ((int)offsetof(GCproto, field)-(int)sizeof(GCproto)) +| +|// Decrement hashed hotcount and trigger trace recorder if zero. +|.macro hotloop, reg +| mov reg, PC +| shr reg, 1 +| and reg, HOTCOUNT_PCMASK +| sub word [DISPATCH+reg+GG_DISP2HOT], HOTCOUNT_LOOP +| jb ->vm_hotloop +|.endmacro +| +|.macro hotcall, reg +| mov reg, PC +| shr reg, 1 +| and reg, HOTCOUNT_PCMASK +| sub word [DISPATCH+reg+GG_DISP2HOT], HOTCOUNT_CALL +| jb ->vm_hotcall +|.endmacro +| +|// Set current VM state. +|.macro set_vmstate, st +| mov dword [DISPATCH+DISPATCH_GL(vmstate)], ~LJ_VMST_..st +|.endmacro +| +|// x87 compares. +|.macro fcomparepp // Compare and pop st0 >< st1. +| fucomip st1 +| fpop +|.endmacro +| +|.macro fpop1; fstp st1; .endmacro +| +|// Synthesize SSE FP constants. +|.macro sseconst_abs, reg, tmp // Synthesize abs mask. +|.if X64 +| mov64 tmp, U64x(7fffffff,ffffffff); movd reg, tmp +|.else +| pxor reg, reg; pcmpeqd reg, reg; psrlq reg, 1 +|.endif +|.endmacro +| +|.macro sseconst_hi, reg, tmp, val // Synthesize hi-32 bit const. +|.if X64 +| mov64 tmp, U64x(val,00000000); movd reg, tmp +|.else +| mov tmp, 0x .. val; movd reg, tmp; pshufd reg, reg, 0x51 +|.endif +|.endmacro +| +|.macro sseconst_sign, reg, tmp // Synthesize sign mask. +| sseconst_hi reg, tmp, 80000000 +|.endmacro +|.macro sseconst_1, reg, tmp // Synthesize 1.0. +| sseconst_hi reg, tmp, 3ff00000 +|.endmacro +|.macro sseconst_2p52, reg, tmp // Synthesize 2^52. +| sseconst_hi reg, tmp, 43300000 +|.endmacro +|.macro sseconst_tobit, reg, tmp // Synthesize 2^52 + 2^51. +| sseconst_hi reg, tmp, 43380000 +|.endmacro +| +|// Move table write barrier back. Overwrites reg. +|.macro barrierback, tab, reg +| and byte tab->marked, (uint8_t)~LJ_GC_BLACK // black2gray(tab) +| mov reg, [DISPATCH+DISPATCH_GL(gc.grayagain)] +| mov [DISPATCH+DISPATCH_GL(gc.grayagain)], tab +| mov tab->gclist, reg +|.endmacro +| +|//----------------------------------------------------------------------- + +/* Generate subroutines used by opcodes and other parts of the VM. */ +/* The .code_sub section should be last to help static branch prediction. */ +static void build_subroutines(BuildCtx *ctx) +{ + |.code_sub + | + |//----------------------------------------------------------------------- + |//-- Return handling ---------------------------------------------------- + |//----------------------------------------------------------------------- + | + |->vm_returnp: + | test PC, FRAME_P + | jz ->cont_dispatch + | + | // Return from pcall or xpcall fast func. + | and PC, -8 + | sub BASE, PC // Restore caller base. + | lea RAa, [RA+PC-8] // Rebase RA and prepend one result. + | mov PC, [BASE-4] // Fetch PC of previous frame. + | // Prepending may overwrite the pcall frame, so do it at the end. + | mov dword [BASE+RA+4], LJ_TTRUE // Prepend true to results. + | + |->vm_returnc: + | add RD, 1 // RD = nresults+1 + | jz ->vm_unwind_yield + | mov MULTRES, RD + | test PC, FRAME_TYPE + | jz ->BC_RET_Z // Handle regular return to Lua. + | + |->vm_return: + | // BASE = base, RA = resultofs, RD = nresults+1 (= MULTRES), PC = return + | xor PC, FRAME_C + | test PC, FRAME_TYPE + | jnz ->vm_returnp + | + | // Return to C. + | set_vmstate C + | and PC, -8 + | sub PC, BASE + | neg PC // Previous base = BASE - delta. + | + | sub RD, 1 + | jz >2 + |1: // Move results down. + |.if X64 + | mov RBa, [BASE+RA] + | mov [BASE-8], RBa + |.else + | mov RB, [BASE+RA] + | mov [BASE-8], RB + | mov RB, [BASE+RA+4] + | mov [BASE-4], RB + |.endif + | add BASE, 8 + | sub RD, 1 + | jnz <1 + |2: + | mov L:RB, SAVE_L + | mov L:RB->base, PC + |3: + | mov RD, MULTRES + | mov RA, SAVE_NRES // RA = wanted nresults+1 + |4: + | cmp RA, RD + | jne >6 // More/less results wanted? + |5: + | sub BASE, 8 + | mov L:RB->top, BASE + | + |->vm_leave_cp: + | mov RAa, SAVE_CFRAME // Restore previous C frame. + | mov L:RB->cframe, RAa + | xor eax, eax // Ok return status for vm_pcall. + | + |->vm_leave_unw: + | restoreregs + | ret + | + |6: + | jb >7 // Less results wanted? + | // More results wanted. Check stack size and fill up results with nil. + | cmp BASE, L:RB->maxstack + | ja >8 + | mov dword [BASE-4], LJ_TNIL + | add BASE, 8 + | add RD, 1 + | jmp <4 + | + |7: // Less results wanted. + | test RA, RA + | jz <5 // But check for LUA_MULTRET+1. + | sub RA, RD // Negative result! + | lea BASE, [BASE+RA*8] // Correct top. + | jmp <5 + | + |8: // Corner case: need to grow stack for filling up results. + | // This can happen if: + | // - A C function grows the stack (a lot). + | // - The GC shrinks the stack in between. + | // - A return back from a lua_call() with (high) nresults adjustment. + | mov L:RB->top, BASE // Save current top held in BASE (yes). + | mov MULTRES, RD // Need to fill only remainder with nil. + | mov FCARG2, RA + | mov FCARG1, L:RB + | call extern lj_state_growstack@8 // (lua_State *L, int n) + | mov BASE, L:RB->top // Need the (realloced) L->top in BASE. + | jmp <3 + | + |->vm_unwind_yield: + | mov al, LUA_YIELD + | jmp ->vm_unwind_c_eh + | + |->vm_unwind_c@8: // Unwind C stack, return from vm_pcall. + | // (void *cframe, int errcode) + |.if X64 + | mov eax, CARG2d // Error return status for vm_pcall. + | mov rsp, CARG1 + |.else + | mov eax, FCARG2 // Error return status for vm_pcall. + | mov esp, FCARG1 + |.if WIN + | lea FCARG1, SEH_NEXT + | fs; mov [0], FCARG1 + |.endif + |.endif + |->vm_unwind_c_eh: // Landing pad for external unwinder. + | mov L:RB, SAVE_L + | mov GL:RB, L:RB->glref + | mov dword GL:RB->vmstate, ~LJ_VMST_C + | jmp ->vm_leave_unw + | + |->vm_unwind_rethrow: + |.if X64 and not X64WIN + | mov FCARG1, SAVE_L + | mov FCARG2, eax + | restoreregs + | jmp extern lj_err_throw@8 // (lua_State *L, int errcode) + |.endif + | + |->vm_unwind_ff@4: // Unwind C stack, return from ff pcall. + | // (void *cframe) + |.if X64 + | and CARG1, CFRAME_RAWMASK + | mov rsp, CARG1 + |.else + | and FCARG1, CFRAME_RAWMASK + | mov esp, FCARG1 + |.if WIN + | lea FCARG1, SEH_NEXT + | fs; mov [0], FCARG1 + |.endif + |.endif + |->vm_unwind_ff_eh: // Landing pad for external unwinder. + | mov L:RB, SAVE_L + | mov RAa, -8 // Results start at BASE+RA = BASE-8. + | mov RD, 1+1 // Really 1+2 results, incr. later. + | mov BASE, L:RB->base + | mov DISPATCH, L:RB->glref // Setup pointer to dispatch table. + | add DISPATCH, GG_G2DISP + | mov PC, [BASE-4] // Fetch PC of previous frame. + | mov dword [BASE-4], LJ_TFALSE // Prepend false to error message. + | set_vmstate INTERP + | jmp ->vm_returnc // Increments RD/MULTRES and returns. + | + |.if WIN and not X64 + |->vm_rtlunwind@16: // Thin layer around RtlUnwind. + | // (void *cframe, void *excptrec, void *unwinder, int errcode) + | mov [esp], FCARG1 // Return value for RtlUnwind. + | push FCARG2 // Exception record for RtlUnwind. + | push 0 // Ignored by RtlUnwind. + | push dword [FCARG1+CFRAME_OFS_SEH] + | call extern RtlUnwind@16 // Violates ABI (clobbers too much). + | mov FCARG1, eax + | mov FCARG2, [esp+4] // errcode (for vm_unwind_c). + | ret // Jump to unwinder. + |.endif + | + |//----------------------------------------------------------------------- + |//-- Grow stack for calls ----------------------------------------------- + |//----------------------------------------------------------------------- + | + |->vm_growstack_c: // Grow stack for C function. + | mov FCARG2, LUA_MINSTACK + | jmp >2 + | + |->vm_growstack_v: // Grow stack for vararg Lua function. + | sub RD, 8 + | jmp >1 + | + |->vm_growstack_f: // Grow stack for fixarg Lua function. + | // BASE = new base, RD = nargs+1, RB = L, PC = first PC + | lea RD, [BASE+NARGS:RD*8-8] + |1: + | movzx RA, byte [PC-4+PC2PROTO(framesize)] + | add PC, 4 // Must point after first instruction. + | mov L:RB->base, BASE + | mov L:RB->top, RD + | mov SAVE_PC, PC + | mov FCARG2, RA + |2: + | // RB = L, L->base = new base, L->top = top + | mov FCARG1, L:RB + | call extern lj_state_growstack@8 // (lua_State *L, int n) + | mov BASE, L:RB->base + | mov RD, L:RB->top + | mov LFUNC:RB, [BASE-8] + | sub RD, BASE + | shr RD, 3 + | add NARGS:RD, 1 + | // BASE = new base, RB = LFUNC, RD = nargs+1 + | ins_callt // Just retry the call. + | + |//----------------------------------------------------------------------- + |//-- Entry points into the assembler VM --------------------------------- + |//----------------------------------------------------------------------- + | + |->vm_resume: // Setup C frame and resume thread. + | // (lua_State *L, TValue *base, int nres1 = 0, ptrdiff_t ef = 0) + | saveregs + |.if X64 + | mov L:RB, CARG1d // Caveat: CARG1d may be RA. + | mov SAVE_L, CARG1d + | mov RA, CARG2d + |.else + | mov L:RB, SAVE_L + | mov RA, INARG_BASE // Caveat: overlaps SAVE_CFRAME! + |.endif + | mov PC, FRAME_CP + | xor RD, RD + | lea KBASEa, [esp+CFRAME_RESUME] + | mov DISPATCH, L:RB->glref // Setup pointer to dispatch table. + | add DISPATCH, GG_G2DISP + | mov SAVE_PC, RD // Any value outside of bytecode is ok. + | mov SAVE_CFRAME, RDa + |.if X64 + | mov SAVE_NRES, RD + | mov SAVE_ERRF, RD + |.endif + | mov L:RB->cframe, KBASEa + | cmp byte L:RB->status, RDL + | je >2 // Initial resume (like a call). + | + | // Resume after yield (like a return). + | mov [DISPATCH+DISPATCH_GL(cur_L)], L:RB + | set_vmstate INTERP + | mov byte L:RB->status, RDL + | mov BASE, L:RB->base + | mov RD, L:RB->top + | sub RD, RA + | shr RD, 3 + | add RD, 1 // RD = nresults+1 + | sub RA, BASE // RA = resultofs + | mov PC, [BASE-4] + | mov MULTRES, RD + | test PC, FRAME_TYPE + | jz ->BC_RET_Z + | jmp ->vm_return + | + |->vm_pcall: // Setup protected C frame and enter VM. + | // (lua_State *L, TValue *base, int nres1, ptrdiff_t ef) + | saveregs + | mov PC, FRAME_CP + |.if X64 + | mov SAVE_ERRF, CARG4d + |.endif + | jmp >1 + | + |->vm_call: // Setup C frame and enter VM. + | // (lua_State *L, TValue *base, int nres1) + | saveregs + | mov PC, FRAME_C + | + |1: // Entry point for vm_pcall above (PC = ftype). + |.if X64 + | mov SAVE_NRES, CARG3d + | mov L:RB, CARG1d // Caveat: CARG1d may be RA. + | mov SAVE_L, CARG1d + | mov RA, CARG2d + |.else + | mov L:RB, SAVE_L + | mov RA, INARG_BASE // Caveat: overlaps SAVE_CFRAME! + |.endif + | + | mov DISPATCH, L:RB->glref // Setup pointer to dispatch table. + | mov KBASEa, L:RB->cframe // Add our C frame to cframe chain. + | mov SAVE_CFRAME, KBASEa + | mov SAVE_PC, L:RB // Any value outside of bytecode is ok. + | add DISPATCH, GG_G2DISP + |.if X64 + | mov L:RB->cframe, rsp + |.else + | mov L:RB->cframe, esp + |.endif + | + |2: // Entry point for vm_resume/vm_cpcall (RA = base, RB = L, PC = ftype). + | mov [DISPATCH+DISPATCH_GL(cur_L)], L:RB + | set_vmstate INTERP + | mov BASE, L:RB->base // BASE = old base (used in vmeta_call). + | add PC, RA + | sub PC, BASE // PC = frame delta + frame type + | + | mov RD, L:RB->top + | sub RD, RA + | shr NARGS:RD, 3 + | add NARGS:RD, 1 // RD = nargs+1 + | + |->vm_call_dispatch: + | mov LFUNC:RB, [RA-8] + | cmp dword [RA-4], LJ_TFUNC + | jne ->vmeta_call // Ensure KBASE defined and != BASE. + | + |->vm_call_dispatch_f: + | mov BASE, RA + | ins_call + | // BASE = new base, RB = func, RD = nargs+1, PC = caller PC + | + |->vm_cpcall: // Setup protected C frame, call C. + | // (lua_State *L, lua_CFunction func, void *ud, lua_CPFunction cp) + | saveregs + |.if X64 + | mov L:RB, CARG1d // Caveat: CARG1d may be RA. + | mov SAVE_L, CARG1d + |.else + | mov L:RB, SAVE_L + | // Caveat: INARG_CP_* and SAVE_CFRAME/SAVE_NRES/SAVE_ERRF overlap! + | mov RC, INARG_CP_UD // Get args before they are overwritten. + | mov RA, INARG_CP_FUNC + | mov BASE, INARG_CP_CALL + |.endif + | mov SAVE_PC, L:RB // Any value outside of bytecode is ok. + | + | mov KBASE, L:RB->stack // Compute -savestack(L, L->top). + | sub KBASE, L:RB->top + | mov DISPATCH, L:RB->glref // Setup pointer to dispatch table. + | mov SAVE_ERRF, 0 // No error function. + | mov SAVE_NRES, KBASE // Neg. delta means cframe w/o frame. + | add DISPATCH, GG_G2DISP + | // Handler may change cframe_nres(L->cframe) or cframe_errfunc(L->cframe). + | + |.if X64 + | mov KBASEa, L:RB->cframe // Add our C frame to cframe chain. + | mov SAVE_CFRAME, KBASEa + | mov L:RB->cframe, rsp + | mov [DISPATCH+DISPATCH_GL(cur_L)], L:RB + | + | call CARG4 // (lua_State *L, lua_CFunction func, void *ud) + |.else + | mov ARG3, RC // Have to copy args downwards. + | mov ARG2, RA + | mov ARG1, L:RB + | + | mov KBASE, L:RB->cframe // Add our C frame to cframe chain. + | mov SAVE_CFRAME, KBASE + | mov L:RB->cframe, esp + | mov [DISPATCH+DISPATCH_GL(cur_L)], L:RB + | + | call BASE // (lua_State *L, lua_CFunction func, void *ud) + |.endif + | // TValue * (new base) or NULL returned in eax (RC). + | test RC, RC + | jz ->vm_leave_cp // No base? Just remove C frame. + | mov RA, RC + | mov PC, FRAME_CP + | jmp <2 // Else continue with the call. + | + |//----------------------------------------------------------------------- + |//-- Metamethod handling ------------------------------------------------ + |//----------------------------------------------------------------------- + | + |//-- Continuation dispatch ---------------------------------------------- + | + |->cont_dispatch: + | // BASE = meta base, RA = resultofs, RD = nresults+1 (also in MULTRES) + | add RA, BASE + | and PC, -8 + | mov RB, BASE + | sub BASE, PC // Restore caller BASE. + | mov dword [RA+RD*8-4], LJ_TNIL // Ensure one valid arg. + | mov RC, RA // ... in [RC] + | mov PC, [RB-12] // Restore PC from [cont|PC]. + |.if X64 + | movsxd RAa, dword [RB-16] // May be negative on WIN64 with debug. + |.if FFI + | cmp RA, 1 + | jbe >1 + |.endif + | lea KBASEa, qword [=>0] + | add RAa, KBASEa + |.else + | mov RA, dword [RB-16] + |.if FFI + | cmp RA, 1 + | jbe >1 + |.endif + |.endif + | mov LFUNC:KBASE, [BASE-8] + | mov KBASE, LFUNC:KBASE->pc + | mov KBASE, [KBASE+PC2PROTO(k)] + | // BASE = base, RC = result, RB = meta base + | jmp RAa // Jump to continuation. + | + |.if FFI + |1: + | je ->cont_ffi_callback // cont = 1: return from FFI callback. + | // cont = 0: Tail call from C function. + | sub RB, BASE + | shr RB, 3 + | lea RD, [RB-1] + | jmp ->vm_call_tail + |.endif + | + |->cont_cat: // BASE = base, RC = result, RB = mbase + | movzx RA, PC_RB + | sub RB, 16 + | lea RA, [BASE+RA*8] + | sub RA, RB + | je ->cont_ra + | neg RA + | shr RA, 3 + |.if X64WIN + | mov CARG3d, RA + | mov L:CARG1d, SAVE_L + | mov L:CARG1d->base, BASE + | mov RCa, [RC] + | mov [RB], RCa + | mov CARG2d, RB + |.elif X64 + | mov L:CARG1d, SAVE_L + | mov L:CARG1d->base, BASE + | mov CARG3d, RA + | mov RAa, [RC] + | mov [RB], RAa + | mov CARG2d, RB + |.else + | mov ARG3, RA + | mov RA, [RC+4] + | mov RC, [RC] + | mov [RB+4], RA + | mov [RB], RC + | mov ARG2, RB + |.endif + | jmp ->BC_CAT_Z + | + |//-- Table indexing metamethods ----------------------------------------- + | + |->vmeta_tgets: + | mov TMP1, RC // RC = GCstr * + | mov TMP2, LJ_TSTR + | lea RCa, TMP1 // Store temp. TValue in TMP1/TMP2. + | cmp PC_OP, BC_GGET + | jne >1 + | lea RA, [DISPATCH+DISPATCH_GL(tmptv)] // Store fn->l.env in g->tmptv. + | mov [RA], TAB:RB // RB = GCtab * + | mov dword [RA+4], LJ_TTAB + | mov RB, RA + | jmp >2 + | + |->vmeta_tgetb: + | movzx RC, PC_RC + |.if DUALNUM + | mov TMP2, LJ_TISNUM + | mov TMP1, RC + |.else + | cvtsi2sd xmm0, RC + | movsd TMPQ, xmm0 + |.endif + | lea RCa, TMPQ // Store temp. TValue in TMPQ. + | jmp >1 + | + |->vmeta_tgetv: + | movzx RC, PC_RC // Reload TValue *k from RC. + | lea RC, [BASE+RC*8] + |1: + | movzx RB, PC_RB // Reload TValue *t from RB. + | lea RB, [BASE+RB*8] + |2: + |.if X64 + | mov L:CARG1d, SAVE_L + | mov L:CARG1d->base, BASE // Caveat: CARG2d/CARG3d may be BASE. + | mov CARG2d, RB + | mov CARG3, RCa // May be 64 bit ptr to stack. + | mov L:RB, L:CARG1d + |.else + | mov ARG2, RB + | mov L:RB, SAVE_L + | mov ARG3, RC + | mov ARG1, L:RB + | mov L:RB->base, BASE + |.endif + | mov SAVE_PC, PC + | call extern lj_meta_tget // (lua_State *L, TValue *o, TValue *k) + | // TValue * (finished) or NULL (metamethod) returned in eax (RC). + | mov BASE, L:RB->base + | test RC, RC + | jz >3 + |->cont_ra: // BASE = base, RC = result + | movzx RA, PC_RA + |.if X64 + | mov RBa, [RC] + | mov [BASE+RA*8], RBa + |.else + | mov RB, [RC+4] + | mov RC, [RC] + | mov [BASE+RA*8+4], RB + | mov [BASE+RA*8], RC + |.endif + | ins_next + | + |3: // Call __index metamethod. + | // BASE = base, L->top = new base, stack = cont/func/t/k + | mov RA, L:RB->top + | mov [RA-12], PC // [cont|PC] + | lea PC, [RA+FRAME_CONT] + | sub PC, BASE + | mov LFUNC:RB, [RA-8] // Guaranteed to be a function here. + | mov NARGS:RD, 2+1 // 2 args for func(t, k). + | jmp ->vm_call_dispatch_f + | + |->vmeta_tgetr: + | mov FCARG1, TAB:RB + | mov RB, BASE // Save BASE. + | mov FCARG2, RC // Caveat: FCARG2 == BASE + | call extern lj_tab_getinth@8 // (GCtab *t, int32_t key) + | // cTValue * or NULL returned in eax (RC). + | movzx RA, PC_RA + | mov BASE, RB // Restore BASE. + | test RC, RC + | jnz ->BC_TGETR_Z + | mov dword [BASE+RA*8+4], LJ_TNIL + | jmp ->BC_TGETR2_Z + | + |//----------------------------------------------------------------------- + | + |->vmeta_tsets: + | mov TMP1, RC // RC = GCstr * + | mov TMP2, LJ_TSTR + | lea RCa, TMP1 // Store temp. TValue in TMP1/TMP2. + | cmp PC_OP, BC_GSET + | jne >1 + | lea RA, [DISPATCH+DISPATCH_GL(tmptv)] // Store fn->l.env in g->tmptv. + | mov [RA], TAB:RB // RB = GCtab * + | mov dword [RA+4], LJ_TTAB + | mov RB, RA + | jmp >2 + | + |->vmeta_tsetb: + | movzx RC, PC_RC + |.if DUALNUM + | mov TMP2, LJ_TISNUM + | mov TMP1, RC + |.else + | cvtsi2sd xmm0, RC + | movsd TMPQ, xmm0 + |.endif + | lea RCa, TMPQ // Store temp. TValue in TMPQ. + | jmp >1 + | + |->vmeta_tsetv: + | movzx RC, PC_RC // Reload TValue *k from RC. + | lea RC, [BASE+RC*8] + |1: + | movzx RB, PC_RB // Reload TValue *t from RB. + | lea RB, [BASE+RB*8] + |2: + |.if X64 + | mov L:CARG1d, SAVE_L + | mov L:CARG1d->base, BASE // Caveat: CARG2d/CARG3d may be BASE. + | mov CARG2d, RB + | mov CARG3, RCa // May be 64 bit ptr to stack. + | mov L:RB, L:CARG1d + |.else + | mov ARG2, RB + | mov L:RB, SAVE_L + | mov ARG3, RC + | mov ARG1, L:RB + | mov L:RB->base, BASE + |.endif + | mov SAVE_PC, PC + | call extern lj_meta_tset // (lua_State *L, TValue *o, TValue *k) + | // TValue * (finished) or NULL (metamethod) returned in eax (RC). + | mov BASE, L:RB->base + | test RC, RC + | jz >3 + | // NOBARRIER: lj_meta_tset ensures the table is not black. + | movzx RA, PC_RA + |.if X64 + | mov RBa, [BASE+RA*8] + | mov [RC], RBa + |.else + | mov RB, [BASE+RA*8+4] + | mov RA, [BASE+RA*8] + | mov [RC+4], RB + | mov [RC], RA + |.endif + |->cont_nop: // BASE = base, (RC = result) + | ins_next + | + |3: // Call __newindex metamethod. + | // BASE = base, L->top = new base, stack = cont/func/t/k/(v) + | mov RA, L:RB->top + | mov [RA-12], PC // [cont|PC] + | movzx RC, PC_RA + | // Copy value to third argument. + |.if X64 + | mov RBa, [BASE+RC*8] + | mov [RA+16], RBa + |.else + | mov RB, [BASE+RC*8+4] + | mov RC, [BASE+RC*8] + | mov [RA+20], RB + | mov [RA+16], RC + |.endif + | lea PC, [RA+FRAME_CONT] + | sub PC, BASE + | mov LFUNC:RB, [RA-8] // Guaranteed to be a function here. + | mov NARGS:RD, 3+1 // 3 args for func(t, k, v). + | jmp ->vm_call_dispatch_f + | + |->vmeta_tsetr: + |.if X64WIN + | mov L:CARG1d, SAVE_L + | mov CARG3d, RC + | mov L:CARG1d->base, BASE + | xchg CARG2d, TAB:RB // Caveat: CARG2d == BASE. + |.elif X64 + | mov L:CARG1d, SAVE_L + | mov CARG2d, TAB:RB + | mov L:CARG1d->base, BASE + | mov RB, BASE // Save BASE. + | mov CARG3d, RC // Caveat: CARG3d == BASE. + |.else + | mov L:RA, SAVE_L + | mov ARG2, TAB:RB + | mov RB, BASE // Save BASE. + | mov ARG3, RC + | mov ARG1, L:RA + | mov L:RA->base, BASE + |.endif + | mov SAVE_PC, PC + | call extern lj_tab_setinth // (lua_State *L, GCtab *t, int32_t key) + | // TValue * returned in eax (RC). + | movzx RA, PC_RA + | mov BASE, RB // Restore BASE. + | jmp ->BC_TSETR_Z + | + |//-- Comparison metamethods --------------------------------------------- + | + |->vmeta_comp: + |.if X64 + | mov L:RB, SAVE_L + | mov L:RB->base, BASE // Caveat: CARG2d/CARG3d == BASE. + |.if X64WIN + | lea CARG3d, [BASE+RD*8] + | lea CARG2d, [BASE+RA*8] + |.else + | lea CARG2d, [BASE+RA*8] + | lea CARG3d, [BASE+RD*8] + |.endif + | mov CARG1d, L:RB // Caveat: CARG1d/CARG4d == RA. + | movzx CARG4d, PC_OP + |.else + | movzx RB, PC_OP + | lea RD, [BASE+RD*8] + | lea RA, [BASE+RA*8] + | mov ARG4, RB + | mov L:RB, SAVE_L + | mov ARG3, RD + | mov ARG2, RA + | mov ARG1, L:RB + | mov L:RB->base, BASE + |.endif + | mov SAVE_PC, PC + | call extern lj_meta_comp // (lua_State *L, TValue *o1, *o2, int op) + | // 0/1 or TValue * (metamethod) returned in eax (RC). + |3: + | mov BASE, L:RB->base + | cmp RC, 1 + | ja ->vmeta_binop + |4: + | lea PC, [PC+4] + | jb >6 + |5: + | movzx RD, PC_RD + | branchPC RD + |6: + | ins_next + | + |->cont_condt: // BASE = base, RC = result + | add PC, 4 + | cmp dword [RC+4], LJ_TISTRUECOND // Branch if result is true. + | jb <5 + | jmp <6 + | + |->cont_condf: // BASE = base, RC = result + | cmp dword [RC+4], LJ_TISTRUECOND // Branch if result is false. + | jmp <4 + | + |->vmeta_equal: + | sub PC, 4 + |.if X64WIN + | mov CARG3d, RD + | mov CARG4d, RB + | mov L:RB, SAVE_L + | mov L:RB->base, BASE // Caveat: CARG2d == BASE. + | mov CARG2d, RA + | mov CARG1d, L:RB // Caveat: CARG1d == RA. + |.elif X64 + | mov CARG2d, RA + | mov CARG4d, RB // Caveat: CARG4d == RA. + | mov L:RB, SAVE_L + | mov L:RB->base, BASE // Caveat: CARG3d == BASE. + | mov CARG3d, RD + | mov CARG1d, L:RB + |.else + | mov ARG4, RB + | mov L:RB, SAVE_L + | mov ARG3, RD + | mov ARG2, RA + | mov ARG1, L:RB + | mov L:RB->base, BASE + |.endif + | mov SAVE_PC, PC + | call extern lj_meta_equal // (lua_State *L, GCobj *o1, *o2, int ne) + | // 0/1 or TValue * (metamethod) returned in eax (RC). + | jmp <3 + | + |->vmeta_equal_cd: + |.if FFI + | sub PC, 4 + | mov L:RB, SAVE_L + | mov L:RB->base, BASE + | mov FCARG1, L:RB + | mov FCARG2, dword [PC-4] + | mov SAVE_PC, PC + | call extern lj_meta_equal_cd@8 // (lua_State *L, BCIns ins) + | // 0/1 or TValue * (metamethod) returned in eax (RC). + | jmp <3 + |.endif + | + |->vmeta_istype: + |.if X64 + | mov L:RB, SAVE_L + | mov L:RB->base, BASE // Caveat: CARG2d/CARG3d may be BASE. + | mov CARG2d, RA + | movzx CARG3d, PC_RD + | mov L:CARG1d, L:RB + |.else + | movzx RD, PC_RD + | mov ARG2, RA + | mov L:RB, SAVE_L + | mov ARG3, RD + | mov ARG1, L:RB + | mov L:RB->base, BASE + |.endif + | mov SAVE_PC, PC + | call extern lj_meta_istype // (lua_State *L, BCReg ra, BCReg tp) + | mov BASE, L:RB->base + | jmp <6 + | + |//-- Arithmetic metamethods --------------------------------------------- + | + |->vmeta_arith_vno: + |.if DUALNUM + | movzx RB, PC_RB + |.endif + |->vmeta_arith_vn: + | lea RC, [KBASE+RC*8] + | jmp >1 + | + |->vmeta_arith_nvo: + |.if DUALNUM + | movzx RC, PC_RC + |.endif + |->vmeta_arith_nv: + | lea RC, [KBASE+RC*8] + | lea RB, [BASE+RB*8] + | xchg RB, RC + | jmp >2 + | + |->vmeta_unm: + | lea RC, [BASE+RD*8] + | mov RB, RC + | jmp >2 + | + |->vmeta_arith_vvo: + |.if DUALNUM + | movzx RB, PC_RB + |.endif + |->vmeta_arith_vv: + | lea RC, [BASE+RC*8] + |1: + | lea RB, [BASE+RB*8] + |2: + | lea RA, [BASE+RA*8] + |.if X64WIN + | mov CARG3d, RB + | mov CARG4d, RC + | movzx RC, PC_OP + | mov ARG5d, RC + | mov L:RB, SAVE_L + | mov L:RB->base, BASE // Caveat: CARG2d == BASE. + | mov CARG2d, RA + | mov CARG1d, L:RB // Caveat: CARG1d == RA. + |.elif X64 + | movzx CARG5d, PC_OP + | mov CARG2d, RA + | mov CARG4d, RC // Caveat: CARG4d == RA. + | mov L:CARG1d, SAVE_L + | mov L:CARG1d->base, BASE // Caveat: CARG3d == BASE. + | mov CARG3d, RB + | mov L:RB, L:CARG1d + |.else + | mov ARG3, RB + | mov L:RB, SAVE_L + | mov ARG4, RC + | movzx RC, PC_OP + | mov ARG2, RA + | mov ARG5, RC + | mov ARG1, L:RB + | mov L:RB->base, BASE + |.endif + | mov SAVE_PC, PC + | call extern lj_meta_arith // (lua_State *L, TValue *ra,*rb,*rc, BCReg op) + | // NULL (finished) or TValue * (metamethod) returned in eax (RC). + | mov BASE, L:RB->base + | test RC, RC + | jz ->cont_nop + | + | // Call metamethod for binary op. + |->vmeta_binop: + | // BASE = base, RC = new base, stack = cont/func/o1/o2 + | mov RA, RC + | sub RC, BASE + | mov [RA-12], PC // [cont|PC] + | lea PC, [RC+FRAME_CONT] + | mov NARGS:RD, 2+1 // 2 args for func(o1, o2). + | jmp ->vm_call_dispatch + | + |->vmeta_len: + | mov L:RB, SAVE_L + | mov L:RB->base, BASE + | lea FCARG2, [BASE+RD*8] // Caveat: FCARG2 == BASE + | mov L:FCARG1, L:RB + | mov SAVE_PC, PC + | call extern lj_meta_len@8 // (lua_State *L, TValue *o) + | // NULL (retry) or TValue * (metamethod) returned in eax (RC). + | mov BASE, L:RB->base +#if LJ_52 + | test RC, RC + | jne ->vmeta_binop // Binop call for compatibility. + | movzx RD, PC_RD + | mov TAB:FCARG1, [BASE+RD*8] + | jmp ->BC_LEN_Z +#else + | jmp ->vmeta_binop // Binop call for compatibility. +#endif + | + |//-- Call metamethod ---------------------------------------------------- + | + |->vmeta_call_ra: + | lea RA, [BASE+RA*8+8] + |->vmeta_call: // Resolve and call __call metamethod. + | // BASE = old base, RA = new base, RC = nargs+1, PC = return + | mov TMP2, RA // Save RA, RC for us. + | mov TMP1, NARGS:RD + | sub RA, 8 + |.if X64 + | mov L:RB, SAVE_L + | mov L:RB->base, BASE // Caveat: CARG2d/CARG3d may be BASE. + | mov CARG2d, RA + | lea CARG3d, [RA+NARGS:RD*8] + | mov CARG1d, L:RB // Caveat: CARG1d may be RA. + |.else + | lea RC, [RA+NARGS:RD*8] + | mov L:RB, SAVE_L + | mov ARG2, RA + | mov ARG3, RC + | mov ARG1, L:RB + | mov L:RB->base, BASE // This is the callers base! + |.endif + | mov SAVE_PC, PC + | call extern lj_meta_call // (lua_State *L, TValue *func, TValue *top) + | mov BASE, L:RB->base + | mov RA, TMP2 + | mov NARGS:RD, TMP1 + | mov LFUNC:RB, [RA-8] + | add NARGS:RD, 1 + | // This is fragile. L->base must not move, KBASE must always be defined. + |.if x64 + | cmp KBASEa, rdx // Continue with CALLT if flag set. + |.else + | cmp KBASE, BASE // Continue with CALLT if flag set. + |.endif + | je ->BC_CALLT_Z + | mov BASE, RA + | ins_call // Otherwise call resolved metamethod. + | + |//-- Argument coercion for 'for' statement ------------------------------ + | + |->vmeta_for: + | mov L:RB, SAVE_L + | mov L:RB->base, BASE + | mov FCARG2, RA // Caveat: FCARG2 == BASE + | mov L:FCARG1, L:RB // Caveat: FCARG1 == RA + | mov SAVE_PC, PC + | call extern lj_meta_for@8 // (lua_State *L, TValue *base) + | mov BASE, L:RB->base + | mov RC, [PC-4] + | movzx RA, RCH + | movzx OP, RCL + | shr RC, 16 + |.if X64 + | jmp aword [DISPATCH+OP*8+GG_DISP2STATIC] // Retry FORI or JFORI. + |.else + | jmp aword [DISPATCH+OP*4+GG_DISP2STATIC] // Retry FORI or JFORI. + |.endif + | + |//----------------------------------------------------------------------- + |//-- Fast functions ----------------------------------------------------- + |//----------------------------------------------------------------------- + | + |.macro .ffunc, name + |->ff_ .. name: + |.endmacro + | + |.macro .ffunc_1, name + |->ff_ .. name: + | cmp NARGS:RD, 1+1; jb ->fff_fallback + |.endmacro + | + |.macro .ffunc_2, name + |->ff_ .. name: + | cmp NARGS:RD, 2+1; jb ->fff_fallback + |.endmacro + | + |.macro .ffunc_nsse, name, op + | .ffunc_1 name + | cmp dword [BASE+4], LJ_TISNUM; jae ->fff_fallback + | op xmm0, qword [BASE] + |.endmacro + | + |.macro .ffunc_nsse, name + | .ffunc_nsse name, movsd + |.endmacro + | + |.macro .ffunc_nnsse, name + | .ffunc_2 name + | cmp dword [BASE+4], LJ_TISNUM; jae ->fff_fallback + | cmp dword [BASE+12], LJ_TISNUM; jae ->fff_fallback + | movsd xmm0, qword [BASE] + | movsd xmm1, qword [BASE+8] + |.endmacro + | + |.macro .ffunc_nnr, name + | .ffunc_2 name + | cmp dword [BASE+4], LJ_TISNUM; jae ->fff_fallback + | cmp dword [BASE+12], LJ_TISNUM; jae ->fff_fallback + | fld qword [BASE+8] + | fld qword [BASE] + |.endmacro + | + |// Inlined GC threshold check. Caveat: uses label 1. + |.macro ffgccheck + | mov RB, [DISPATCH+DISPATCH_GL(gc.total)] + | cmp RB, [DISPATCH+DISPATCH_GL(gc.threshold)] + | jb >1 + | call ->fff_gcstep + |1: + |.endmacro + | + |//-- Base library: checks ----------------------------------------------- + | + |.ffunc_1 assert + | mov RB, [BASE+4] + | cmp RB, LJ_TISTRUECOND; jae ->fff_fallback + | mov PC, [BASE-4] + | mov MULTRES, RD + | mov [BASE-4], RB + | mov RB, [BASE] + | mov [BASE-8], RB + | sub RD, 2 + | jz >2 + | mov RA, BASE + |1: + | add RA, 8 + |.if X64 + | mov RBa, [RA] + | mov [RA-8], RBa + |.else + | mov RB, [RA+4] + | mov [RA-4], RB + | mov RB, [RA] + | mov [RA-8], RB + |.endif + | sub RD, 1 + | jnz <1 + |2: + | mov RD, MULTRES + | jmp ->fff_res_ + | + |.ffunc_1 type + | mov RB, [BASE+4] + |.if X64 + | mov RA, RB + | sar RA, 15 + | cmp RA, -2 + | je >3 + |.endif + | mov RC, ~LJ_TNUMX + | not RB + | cmp RC, RB + | cmova RC, RB + |2: + | mov CFUNC:RB, [BASE-8] + | mov STR:RC, [CFUNC:RB+RC*8+((char *)(&((GCfuncC *)0)->upvalue))] + | mov PC, [BASE-4] + | mov dword [BASE-4], LJ_TSTR + | mov [BASE-8], STR:RC + | jmp ->fff_res1 + |.if X64 + |3: + | mov RC, ~LJ_TLIGHTUD + | jmp <2 + |.endif + | + |//-- Base library: getters and setters --------------------------------- + | + |.ffunc_1 getmetatable + | mov RB, [BASE+4] + | mov PC, [BASE-4] + | cmp RB, LJ_TTAB; jne >6 + |1: // Field metatable must be at same offset for GCtab and GCudata! + | mov TAB:RB, [BASE] + | mov TAB:RB, TAB:RB->metatable + |2: + | test TAB:RB, TAB:RB + | mov dword [BASE-4], LJ_TNIL + | jz ->fff_res1 + | mov STR:RC, [DISPATCH+DISPATCH_GL(gcroot)+4*(GCROOT_MMNAME+MM_metatable)] + | mov dword [BASE-4], LJ_TTAB // Store metatable as default result. + | mov [BASE-8], TAB:RB + | mov RA, TAB:RB->hmask + | and RA, STR:RC->sid + | imul RA, #NODE + | add NODE:RA, TAB:RB->node + |3: // Rearranged logic, because we expect _not_ to find the key. + | cmp dword NODE:RA->key.it, LJ_TSTR + | jne >4 + | cmp dword NODE:RA->key.gcr, STR:RC + | je >5 + |4: + | mov NODE:RA, NODE:RA->next + | test NODE:RA, NODE:RA + | jnz <3 + | jmp ->fff_res1 // Not found, keep default result. + |5: + | mov RB, [RA+4] + | cmp RB, LJ_TNIL; je ->fff_res1 // Ditto for nil value. + | mov RC, [RA] + | mov [BASE-4], RB // Return value of mt.__metatable. + | mov [BASE-8], RC + | jmp ->fff_res1 + | + |6: + | cmp RB, LJ_TUDATA; je <1 + |.if X64 + | cmp RB, LJ_TNUMX; ja >8 + | cmp RB, LJ_TISNUM; jbe >7 + | mov RB, LJ_TLIGHTUD + | jmp >8 + |7: + |.else + | cmp RB, LJ_TISNUM; ja >8 + |.endif + | mov RB, LJ_TNUMX + |8: + | not RB + | mov TAB:RB, [DISPATCH+RB*4+DISPATCH_GL(gcroot[GCROOT_BASEMT])] + | jmp <2 + | + |.ffunc_2 setmetatable + | cmp dword [BASE+4], LJ_TTAB; jne ->fff_fallback + | // Fast path: no mt for table yet and not clearing the mt. + | mov TAB:RB, [BASE] + | cmp dword TAB:RB->metatable, 0; jne ->fff_fallback + | cmp dword [BASE+12], LJ_TTAB; jne ->fff_fallback + | mov TAB:RC, [BASE+8] + | mov TAB:RB->metatable, TAB:RC + | mov PC, [BASE-4] + | mov dword [BASE-4], LJ_TTAB // Return original table. + | mov [BASE-8], TAB:RB + | test byte TAB:RB->marked, LJ_GC_BLACK // isblack(table) + | jz >1 + | // Possible write barrier. Table is black, but skip iswhite(mt) check. + | barrierback TAB:RB, RC + |1: + | jmp ->fff_res1 + | + |.ffunc_2 rawget + | cmp dword [BASE+4], LJ_TTAB; jne ->fff_fallback + |.if X64WIN + | mov RB, BASE // Save BASE. + | lea CARG3d, [BASE+8] + | mov CARG2d, [BASE] // Caveat: CARG2d == BASE. + | mov CARG1d, SAVE_L + |.elif X64 + | mov RB, BASE // Save BASE. + | mov CARG2d, [BASE] + | lea CARG3d, [BASE+8] // Caveat: CARG3d == BASE. + | mov CARG1d, SAVE_L + |.else + | mov TAB:RD, [BASE] + | mov L:RB, SAVE_L + | mov ARG2, TAB:RD + | mov ARG1, L:RB + | mov RB, BASE // Save BASE. + | add BASE, 8 + | mov ARG3, BASE + |.endif + | call extern lj_tab_get // (lua_State *L, GCtab *t, cTValue *key) + | // cTValue * returned in eax (RD). + | mov BASE, RB // Restore BASE. + | // Copy table slot. + |.if X64 + | mov RBa, [RD] + | mov PC, [BASE-4] + | mov [BASE-8], RBa + |.else + | mov RB, [RD] + | mov RD, [RD+4] + | mov PC, [BASE-4] + | mov [BASE-8], RB + | mov [BASE-4], RD + |.endif + | jmp ->fff_res1 + | + |//-- Base library: conversions ------------------------------------------ + | + |.ffunc tonumber + | // Only handles the number case inline (without a base argument). + | cmp NARGS:RD, 1+1; jne ->fff_fallback // Exactly one argument. + | cmp dword [BASE+4], LJ_TISNUM + |.if DUALNUM + | jne >1 + | mov RB, dword [BASE]; jmp ->fff_resi + |1: + | ja ->fff_fallback + |.else + | jae ->fff_fallback + |.endif + | movsd xmm0, qword [BASE]; jmp ->fff_resxmm0 + | + |.ffunc_1 tostring + | // Only handles the string or number case inline. + | mov PC, [BASE-4] + | cmp dword [BASE+4], LJ_TSTR; jne >3 + | // A __tostring method in the string base metatable is ignored. + | mov STR:RD, [BASE] + |2: + | mov dword [BASE-4], LJ_TSTR + | mov [BASE-8], STR:RD + | jmp ->fff_res1 + |3: // Handle numbers inline, unless a number base metatable is present. + | cmp dword [BASE+4], LJ_TISNUM; ja ->fff_fallback + | cmp dword [DISPATCH+DISPATCH_GL(gcroot[GCROOT_BASEMT_NUM])], 0 + | jne ->fff_fallback + | ffgccheck // Caveat: uses label 1. + | mov L:RB, SAVE_L + | mov L:RB->base, BASE // Add frame since C call can throw. + | mov SAVE_PC, PC // Redundant (but a defined value). + |.if X64 and not X64WIN + | mov FCARG2, BASE // Otherwise: FCARG2 == BASE + |.endif + | mov L:FCARG1, L:RB + |.if DUALNUM + | call extern lj_strfmt_number@8 // (lua_State *L, cTValue *o) + |.else + | call extern lj_strfmt_num@8 // (lua_State *L, lua_Number *np) + |.endif + | // GCstr returned in eax (RD). + | mov BASE, L:RB->base + | jmp <2 + | + |//-- Base library: iterators ------------------------------------------- + | + |.ffunc_1 next + | je >2 // Missing 2nd arg? + |1: + | cmp dword [BASE+4], LJ_TTAB; jne ->fff_fallback + | mov PC, [BASE-4] + | mov RB, BASE // Save BASE. + |.if X64WIN + | mov CARG1d, [BASE] + | lea CARG3d, [BASE-8] + | lea CARG2d, [BASE+8] // Caveat: CARG2d == BASE. + |.elif X64 + | mov CARG1d, [BASE] + | lea CARG2d, [BASE+8] + | lea CARG3d, [BASE-8] // Caveat: CARG3d == BASE. + |.else + | mov TAB:RD, [BASE] + | mov ARG1, TAB:RD + | add BASE, 8 + | mov ARG2, BASE + | sub BASE, 8+8 + | mov ARG3, BASE + |.endif + | call extern lj_tab_next // (GCtab *t, cTValue *key, TValue *o) + | // 1=found, 0=end, -1=error returned in eax (RD). + | mov BASE, RB // Restore BASE. + | test RD, RD; jg ->fff_res2 // Found key/value. + | js ->fff_fallback_2 // Invalid key. + | // End of traversal: return nil. + | mov dword [BASE-4], LJ_TNIL + | jmp ->fff_res1 + |2: // Set missing 2nd arg to nil. + | mov dword [BASE+12], LJ_TNIL + | jmp <1 + | + |.ffunc_1 pairs + | mov TAB:RB, [BASE] + | cmp dword [BASE+4], LJ_TTAB; jne ->fff_fallback +#if LJ_52 + | cmp dword TAB:RB->metatable, 0; jne ->fff_fallback +#endif + | mov CFUNC:RB, [BASE-8] + | mov CFUNC:RD, CFUNC:RB->upvalue[0] + | mov PC, [BASE-4] + | mov dword [BASE-4], LJ_TFUNC + | mov [BASE-8], CFUNC:RD + | mov dword [BASE+12], LJ_TNIL + | mov RD, 1+3 + | jmp ->fff_res + | + |.ffunc_2 ipairs_aux + | cmp dword [BASE+4], LJ_TTAB; jne ->fff_fallback + | cmp dword [BASE+12], LJ_TISNUM + |.if DUALNUM + | jne ->fff_fallback + |.else + | jae ->fff_fallback + |.endif + | mov PC, [BASE-4] + |.if DUALNUM + | mov RD, dword [BASE+8] + | add RD, 1 + | mov dword [BASE-4], LJ_TISNUM + | mov dword [BASE-8], RD + |.else + | movsd xmm0, qword [BASE+8] + | sseconst_1 xmm1, RBa + | addsd xmm0, xmm1 + | cvttsd2si RD, xmm0 + | movsd qword [BASE-8], xmm0 + |.endif + | mov TAB:RB, [BASE] + | cmp RD, TAB:RB->asize; jae >2 // Not in array part? + | shl RD, 3 + | add RD, TAB:RB->array + |1: + | cmp dword [RD+4], LJ_TNIL; je ->fff_res0 + | // Copy array slot. + |.if X64 + | mov RBa, [RD] + | mov [BASE], RBa + |.else + | mov RB, [RD] + | mov RD, [RD+4] + | mov [BASE], RB + | mov [BASE+4], RD + |.endif + |->fff_res2: + | mov RD, 1+2 + | jmp ->fff_res + |2: // Check for empty hash part first. Otherwise call C function. + | cmp dword TAB:RB->hmask, 0; je ->fff_res0 + | mov FCARG1, TAB:RB + | mov RB, BASE // Save BASE. + | mov FCARG2, RD // Caveat: FCARG2 == BASE + | call extern lj_tab_getinth@8 // (GCtab *t, int32_t key) + | // cTValue * or NULL returned in eax (RD). + | mov BASE, RB + | test RD, RD + | jnz <1 + |->fff_res0: + | mov RD, 1+0 + | jmp ->fff_res + | + |.ffunc_1 ipairs + | mov TAB:RB, [BASE] + | cmp dword [BASE+4], LJ_TTAB; jne ->fff_fallback +#if LJ_52 + | cmp dword TAB:RB->metatable, 0; jne ->fff_fallback +#endif + | mov CFUNC:RB, [BASE-8] + | mov CFUNC:RD, CFUNC:RB->upvalue[0] + | mov PC, [BASE-4] + | mov dword [BASE-4], LJ_TFUNC + | mov [BASE-8], CFUNC:RD + |.if DUALNUM + | mov dword [BASE+12], LJ_TISNUM + | mov dword [BASE+8], 0 + |.else + | xorps xmm0, xmm0 + | movsd qword [BASE+8], xmm0 + |.endif + | mov RD, 1+3 + | jmp ->fff_res + | + |//-- Base library: catch errors ---------------------------------------- + | + |.ffunc_1 pcall + | lea RA, [BASE+8] + | sub NARGS:RD, 1 + | mov PC, 8+FRAME_PCALL + |1: + | movzx RB, byte [DISPATCH+DISPATCH_GL(hookmask)] + | shr RB, HOOK_ACTIVE_SHIFT + | and RB, 1 + | add PC, RB // Remember active hook before pcall. + | jmp ->vm_call_dispatch + | + |.ffunc_2 xpcall + | cmp dword [BASE+12], LJ_TFUNC; jne ->fff_fallback + | mov RB, [BASE+4] // Swap function and traceback. + | mov [BASE+12], RB + | mov dword [BASE+4], LJ_TFUNC + | mov LFUNC:RB, [BASE] + | mov PC, [BASE+8] + | mov [BASE+8], LFUNC:RB + | mov [BASE], PC + | lea RA, [BASE+16] + | sub NARGS:RD, 2 + | mov PC, 16+FRAME_PCALL + | jmp <1 + | + |//-- Coroutine library -------------------------------------------------- + | + |.macro coroutine_resume_wrap, resume + |.if resume + |.ffunc_1 coroutine_resume + | mov L:RB, [BASE] + |.else + |.ffunc coroutine_wrap_aux + | mov CFUNC:RB, [BASE-8] + | mov L:RB, CFUNC:RB->upvalue[0].gcr + |.endif + | mov PC, [BASE-4] + | mov SAVE_PC, PC + |.if X64 + | mov TMP1, L:RB + |.else + | mov ARG1, L:RB + |.endif + |.if resume + | cmp dword [BASE+4], LJ_TTHREAD; jne ->fff_fallback + |.endif + | cmp aword L:RB->cframe, 0; jne ->fff_fallback + | cmp byte L:RB->status, LUA_YIELD; ja ->fff_fallback + | mov RA, L:RB->top + | je >1 // Status != LUA_YIELD (i.e. 0)? + | cmp RA, L:RB->base // Check for presence of initial func. + | je ->fff_fallback + |1: + |.if resume + | lea PC, [RA+NARGS:RD*8-16] // Check stack space (-1-thread). + |.else + | lea PC, [RA+NARGS:RD*8-8] // Check stack space (-1). + |.endif + | cmp PC, L:RB->maxstack; ja ->fff_fallback + | mov L:RB->top, PC + | + | mov L:RB, SAVE_L + | mov L:RB->base, BASE + |.if resume + | add BASE, 8 // Keep resumed thread in stack for GC. + |.endif + | mov L:RB->top, BASE + |.if resume + | lea RB, [BASE+NARGS:RD*8-24] // RB = end of source for stack move. + |.else + | lea RB, [BASE+NARGS:RD*8-16] // RB = end of source for stack move. + |.endif + | sub RBa, PCa // Relative to PC. + | + | cmp PC, RA + | je >3 + |2: // Move args to coroutine. + |.if X64 + | mov RCa, [PC+RB] + | mov [PC-8], RCa + |.else + | mov RC, [PC+RB+4] + | mov [PC-4], RC + | mov RC, [PC+RB] + | mov [PC-8], RC + |.endif + | sub PC, 8 + | cmp PC, RA + | jne <2 + |3: + |.if X64 + | mov CARG2d, RA + | mov CARG1d, TMP1 + |.else + | mov ARG2, RA + | xor RA, RA + | mov ARG4, RA + | mov ARG3, RA + |.endif + | call ->vm_resume // (lua_State *L, TValue *base, 0, 0) + | + | mov L:RB, SAVE_L + |.if X64 + | mov L:PC, TMP1 + |.else + | mov L:PC, ARG1 // The callee doesn't modify SAVE_L. + |.endif + | mov BASE, L:RB->base + | mov [DISPATCH+DISPATCH_GL(cur_L)], L:RB + | set_vmstate INTERP + | + | cmp eax, LUA_YIELD + | ja >8 + |4: + | mov RA, L:PC->base + | mov KBASE, L:PC->top + | mov L:PC->top, RA // Clear coroutine stack. + | mov PC, KBASE + | sub PC, RA + | je >6 // No results? + | lea RD, [BASE+PC] + | shr PC, 3 + | cmp RD, L:RB->maxstack + | ja >9 // Need to grow stack? + | + | mov RB, BASE + | sub RBa, RAa + |5: // Move results from coroutine. + |.if X64 + | mov RDa, [RA] + | mov [RA+RB], RDa + |.else + | mov RD, [RA] + | mov [RA+RB], RD + | mov RD, [RA+4] + | mov [RA+RB+4], RD + |.endif + | add RA, 8 + | cmp RA, KBASE + | jne <5 + |6: + |.if resume + | lea RD, [PC+2] // nresults+1 = 1 + true + results. + | mov dword [BASE-4], LJ_TTRUE // Prepend true to results. + |.else + | lea RD, [PC+1] // nresults+1 = 1 + results. + |.endif + |7: + | mov PC, SAVE_PC + | mov MULTRES, RD + |.if resume + | mov RAa, -8 + |.else + | xor RA, RA + |.endif + | test PC, FRAME_TYPE + | jz ->BC_RET_Z + | jmp ->vm_return + | + |8: // Coroutine returned with error (at co->top-1). + |.if resume + | mov dword [BASE-4], LJ_TFALSE // Prepend false to results. + | mov RA, L:PC->top + | sub RA, 8 + | mov L:PC->top, RA // Clear error from coroutine stack. + | // Copy error message. + |.if X64 + | mov RDa, [RA] + | mov [BASE], RDa + |.else + | mov RD, [RA] + | mov [BASE], RD + | mov RD, [RA+4] + | mov [BASE+4], RD + |.endif + | mov RD, 1+2 // nresults+1 = 1 + false + error. + | jmp <7 + |.else + | mov FCARG2, L:PC + | mov FCARG1, L:RB + | call extern lj_ffh_coroutine_wrap_err@8 // (lua_State *L, lua_State *co) + | // Error function does not return. + |.endif + | + |9: // Handle stack expansion on return from yield. + |.if X64 + | mov L:RA, TMP1 + |.else + | mov L:RA, ARG1 // The callee doesn't modify SAVE_L. + |.endif + | mov L:RA->top, KBASE // Undo coroutine stack clearing. + | mov FCARG2, PC + | mov FCARG1, L:RB + | call extern lj_state_growstack@8 // (lua_State *L, int n) + |.if X64 + | mov L:PC, TMP1 + |.else + | mov L:PC, ARG1 + |.endif + | mov BASE, L:RB->base + | jmp <4 // Retry the stack move. + |.endmacro + | + | coroutine_resume_wrap 1 // coroutine.resume + | coroutine_resume_wrap 0 // coroutine.wrap + | + |.ffunc coroutine_yield + | mov L:RB, SAVE_L + | test aword L:RB->cframe, CFRAME_RESUME + | jz ->fff_fallback + | mov L:RB->base, BASE + | lea RD, [BASE+NARGS:RD*8-8] + | mov L:RB->top, RD + | xor RD, RD + | mov aword L:RB->cframe, RDa + | mov al, LUA_YIELD + | mov byte L:RB->status, al + | jmp ->vm_leave_unw + | + |//-- Math library ------------------------------------------------------- + | + |.if not DUALNUM + |->fff_resi: // Dummy. + |.endif + | + |->fff_resn: + | mov PC, [BASE-4] + | fstp qword [BASE-8] + | jmp ->fff_res1 + | + | .ffunc_1 math_abs + |.if DUALNUM + | cmp dword [BASE+4], LJ_TISNUM; jne >2 + | mov RB, dword [BASE] + | cmp RB, 0; jns ->fff_resi + | neg RB; js >1 + |->fff_resbit: + |->fff_resi: + | mov PC, [BASE-4] + | mov dword [BASE-4], LJ_TISNUM + | mov dword [BASE-8], RB + | jmp ->fff_res1 + |1: + | mov PC, [BASE-4] + | mov dword [BASE-4], 0x41e00000 // 2^31. + | mov dword [BASE-8], 0 + | jmp ->fff_res1 + |2: + | ja ->fff_fallback + |.else + | cmp dword [BASE+4], LJ_TISNUM; jae ->fff_fallback + |.endif + | movsd xmm0, qword [BASE] + | sseconst_abs xmm1, RDa + | andps xmm0, xmm1 + |->fff_resxmm0: + | mov PC, [BASE-4] + | movsd qword [BASE-8], xmm0 + | // fallthrough + | + |->fff_res1: + | mov RD, 1+1 + |->fff_res: + | mov MULTRES, RD + |->fff_res_: + | test PC, FRAME_TYPE + | jnz >7 + |5: + | cmp PC_RB, RDL // More results expected? + | ja >6 + | // Adjust BASE. KBASE is assumed to be set for the calling frame. + | movzx RA, PC_RA + | not RAa // Note: ~RA = -(RA+1) + | lea BASE, [BASE+RA*8] // base = base - (RA+1)*8 + | ins_next + | + |6: // Fill up results with nil. + | mov dword [BASE+RD*8-12], LJ_TNIL + | add RD, 1 + | jmp <5 + | + |7: // Non-standard return case. + | mov RAa, -8 // Results start at BASE+RA = BASE-8. + | jmp ->vm_return + | + |.if X64 + |.define fff_resfp, fff_resxmm0 + |.else + |.define fff_resfp, fff_resn + |.endif + | + |.macro math_round, func + | .ffunc math_ .. func + |.if DUALNUM + | cmp dword [BASE+4], LJ_TISNUM; jne >1 + | mov RB, dword [BASE]; jmp ->fff_resi + |1: + | ja ->fff_fallback + |.else + | cmp dword [BASE+4], LJ_TISNUM; jae ->fff_fallback + |.endif + | movsd xmm0, qword [BASE] + | call ->vm_ .. func .. _sse + |.if DUALNUM + | cvttsd2si RB, xmm0 + | cmp RB, 0x80000000 + | jne ->fff_resi + | cvtsi2sd xmm1, RB + | ucomisd xmm0, xmm1 + | jp ->fff_resxmm0 + | je ->fff_resi + |.endif + | jmp ->fff_resxmm0 + |.endmacro + | + | math_round floor + | math_round ceil + | + |.ffunc_nsse math_sqrt, sqrtsd; jmp ->fff_resxmm0 + | + |.ffunc math_log + | cmp NARGS:RD, 1+1; jne ->fff_fallback // Exactly one argument. + | cmp dword [BASE+4], LJ_TISNUM; jae ->fff_fallback + | movsd xmm0, qword [BASE] + |.if not X64 + | movsd FPARG1, xmm0 + |.endif + | mov RB, BASE + | call extern log + | mov BASE, RB + | jmp ->fff_resfp + | + |.macro math_extern, func + | .ffunc_nsse math_ .. func + |.if not X64 + | movsd FPARG1, xmm0 + |.endif + | mov RB, BASE + | call extern func + | mov BASE, RB + | jmp ->fff_resfp + |.endmacro + | + |.macro math_extern2, func + | .ffunc_nnsse math_ .. func + |.if not X64 + | movsd FPARG1, xmm0 + | movsd FPARG3, xmm1 + |.endif + | mov RB, BASE + | call extern func + | mov BASE, RB + | jmp ->fff_resfp + |.endmacro + | + | math_extern log10 + | math_extern exp + | math_extern sin + | math_extern cos + | math_extern tan + | math_extern asin + | math_extern acos + | math_extern atan + | math_extern sinh + | math_extern cosh + | math_extern tanh + | math_extern2 pow + | math_extern2 atan2 + | math_extern2 fmod + | + |.ffunc_nnr math_ldexp; fscale; fpop1; jmp ->fff_resn + | + |.ffunc_1 math_frexp + | mov RB, [BASE+4] + | cmp RB, LJ_TISNUM; jae ->fff_fallback + | mov PC, [BASE-4] + | mov RC, [BASE] + | mov [BASE-4], RB; mov [BASE-8], RC + | shl RB, 1; cmp RB, 0xffe00000; jae >3 + | or RC, RB; jz >3 + | mov RC, 1022 + | cmp RB, 0x00200000; jb >4 + |1: + | shr RB, 21; sub RB, RC // Extract and unbias exponent. + | cvtsi2sd xmm0, RB + | mov RB, [BASE-4] + | and RB, 0x800fffff // Mask off exponent. + | or RB, 0x3fe00000 // Put mantissa in range [0.5,1) or 0. + | mov [BASE-4], RB + |2: + | movsd qword [BASE], xmm0 + | mov RD, 1+2 + | jmp ->fff_res + |3: // Return +-0, +-Inf, NaN unmodified and an exponent of 0. + | xorps xmm0, xmm0; jmp <2 + |4: // Handle denormals by multiplying with 2^54 and adjusting the bias. + | movsd xmm0, qword [BASE] + | sseconst_hi xmm1, RBa, 43500000 // 2^54. + | mulsd xmm0, xmm1 + | movsd qword [BASE-8], xmm0 + | mov RB, [BASE-4]; mov RC, 1076; shl RB, 1; jmp <1 + | + |.ffunc_nsse math_modf + | mov RB, [BASE+4] + | mov PC, [BASE-4] + | shl RB, 1; cmp RB, 0xffe00000; je >4 // +-Inf? + | movaps xmm4, xmm0 + | call ->vm_trunc_sse + | subsd xmm4, xmm0 + |1: + | movsd qword [BASE-8], xmm0 + | movsd qword [BASE], xmm4 + | mov RC, [BASE-4]; mov RB, [BASE+4] + | xor RC, RB; js >3 // Need to adjust sign? + |2: + | mov RD, 1+2 + | jmp ->fff_res + |3: + | xor RB, 0x80000000; mov [BASE+4], RB // Flip sign of fraction. + | jmp <2 + |4: + | xorps xmm4, xmm4; jmp <1 // Return +-Inf and +-0. + | + |.macro math_minmax, name, cmovop, sseop + | .ffunc_1 name + | mov RA, 2 + | cmp dword [BASE+4], LJ_TISNUM + |.if DUALNUM + | jne >4 + | mov RB, dword [BASE] + |1: // Handle integers. + | cmp RA, RD; jae ->fff_resi + | cmp dword [BASE+RA*8-4], LJ_TISNUM; jne >3 + | cmp RB, dword [BASE+RA*8-8] + | cmovop RB, dword [BASE+RA*8-8] + | add RA, 1 + | jmp <1 + |3: + | ja ->fff_fallback + | // Convert intermediate result to number and continue below. + | cvtsi2sd xmm0, RB + | jmp >6 + |4: + | ja ->fff_fallback + |.else + | jae ->fff_fallback + |.endif + | + | movsd xmm0, qword [BASE] + |5: // Handle numbers or integers. + | cmp RA, RD; jae ->fff_resxmm0 + | cmp dword [BASE+RA*8-4], LJ_TISNUM + |.if DUALNUM + | jb >6 + | ja ->fff_fallback + | cvtsi2sd xmm1, dword [BASE+RA*8-8] + | jmp >7 + |.else + | jae ->fff_fallback + |.endif + |6: + | movsd xmm1, qword [BASE+RA*8-8] + |7: + | sseop xmm0, xmm1 + | add RA, 1 + | jmp <5 + |.endmacro + | + | math_minmax math_min, cmovg, minsd + | math_minmax math_max, cmovl, maxsd + | + |//-- String library ----------------------------------------------------- + | + |.ffunc string_byte // Only handle the 1-arg case here. + | cmp NARGS:RD, 1+1; jne ->fff_fallback + | cmp dword [BASE+4], LJ_TSTR; jne ->fff_fallback + | mov STR:RB, [BASE] + | mov PC, [BASE-4] + | cmp dword STR:RB->len, 1 + | jb ->fff_res0 // Return no results for empty string. + | movzx RB, byte STR:RB[1] + |.if DUALNUM + | jmp ->fff_resi + |.else + | cvtsi2sd xmm0, RB; jmp ->fff_resxmm0 + |.endif + | + |.ffunc string_char // Only handle the 1-arg case here. + | ffgccheck + | cmp NARGS:RD, 1+1; jne ->fff_fallback // *Exactly* 1 arg. + | cmp dword [BASE+4], LJ_TISNUM + |.if DUALNUM + | jne ->fff_fallback + | mov RB, dword [BASE] + | cmp RB, 255; ja ->fff_fallback + | mov TMP2, RB + |.else + | jae ->fff_fallback + | cvttsd2si RB, qword [BASE] + | cmp RB, 255; ja ->fff_fallback + | mov TMP2, RB + |.endif + |.if X64 + | mov TMP3, 1 + |.else + | mov ARG3, 1 + |.endif + | lea RDa, TMP2 // Points to stack. Little-endian. + |->fff_newstr: + | mov L:RB, SAVE_L + | mov L:RB->base, BASE + |.if X64 + | mov CARG3d, TMP3 // Zero-extended to size_t. + | mov CARG2, RDa // May be 64 bit ptr to stack. + | mov CARG1d, L:RB + |.else + | mov ARG2, RD + | mov ARG1, L:RB + |.endif + | mov SAVE_PC, PC + | call extern lj_str_new // (lua_State *L, char *str, size_t l) + |->fff_resstr: + | // GCstr * returned in eax (RD). + | mov BASE, L:RB->base + | mov PC, [BASE-4] + | mov dword [BASE-4], LJ_TSTR + | mov [BASE-8], STR:RD + | jmp ->fff_res1 + | + |.ffunc string_sub + | ffgccheck + | mov TMP2, -1 + | cmp NARGS:RD, 1+2; jb ->fff_fallback + | jna >1 + | cmp dword [BASE+20], LJ_TISNUM + |.if DUALNUM + | jne ->fff_fallback + | mov RB, dword [BASE+16] + | mov TMP2, RB + |.else + | jae ->fff_fallback + | cvttsd2si RB, qword [BASE+16] + | mov TMP2, RB + |.endif + |1: + | cmp dword [BASE+4], LJ_TSTR; jne ->fff_fallback + | cmp dword [BASE+12], LJ_TISNUM + |.if DUALNUM + | jne ->fff_fallback + |.else + | jae ->fff_fallback + |.endif + | mov STR:RB, [BASE] + | mov TMP3, STR:RB + | mov RB, STR:RB->len + |.if DUALNUM + | mov RA, dword [BASE+8] + |.else + | cvttsd2si RA, qword [BASE+8] + |.endif + | mov RC, TMP2 + | cmp RB, RC // len < end? (unsigned compare) + | jb >5 + |2: + | test RA, RA // start <= 0? + | jle >7 + |3: + | mov STR:RB, TMP3 + | sub RC, RA // start > end? + | jl ->fff_emptystr + | lea RB, [STR:RB+RA+#STR-1] + | add RC, 1 + |4: + |.if X64 + | mov TMP3, RC + |.else + | mov ARG3, RC + |.endif + | mov RD, RB + | jmp ->fff_newstr + | + |5: // Negative end or overflow. + | jl >6 + | lea RC, [RC+RB+1] // end = end+(len+1) + | jmp <2 + |6: // Overflow. + | mov RC, RB // end = len + | jmp <2 + | + |7: // Negative start or underflow. + | je >8 + | add RA, RB // start = start+(len+1) + | add RA, 1 + | jg <3 // start > 0? + |8: // Underflow. + | mov RA, 1 // start = 1 + | jmp <3 + | + |->fff_emptystr: // Range underflow. + | xor RC, RC // Zero length. Any ptr in RB is ok. + | jmp <4 + | + |.macro ffstring_op, name + | .ffunc_1 string_ .. name + | ffgccheck + | cmp dword [BASE+4], LJ_TSTR; jne ->fff_fallback + | mov L:RB, SAVE_L + | lea SBUF:FCARG1, [DISPATCH+DISPATCH_GL(tmpbuf)] + | mov L:RB->base, BASE + | mov STR:FCARG2, [BASE] // Caveat: FCARG2 == BASE + | mov RCa, SBUF:FCARG1->b + | mov SBUF:FCARG1->L, L:RB + | mov SBUF:FCARG1->w, RCa + | mov SAVE_PC, PC + | call extern lj_buf_putstr_ .. name .. @8 + | mov FCARG1, eax + | call extern lj_buf_tostr@4 + | jmp ->fff_resstr + |.endmacro + | + |ffstring_op reverse + |ffstring_op lower + |ffstring_op upper + | + |//-- Bit library -------------------------------------------------------- + | + |.macro .ffunc_bit, name, kind, fdef + | fdef name + |.if kind == 2 + | sseconst_tobit xmm1, RBa + |.endif + | cmp dword [BASE+4], LJ_TISNUM + |.if DUALNUM + | jne >1 + | mov RB, dword [BASE] + |.if kind > 0 + | jmp >2 + |.else + | jmp ->fff_resbit + |.endif + |1: + | ja ->fff_fallback + |.else + | jae ->fff_fallback + |.endif + | movsd xmm0, qword [BASE] + |.if kind < 2 + | sseconst_tobit xmm1, RBa + |.endif + | addsd xmm0, xmm1 + | movd RB, xmm0 + |2: + |.endmacro + | + |.macro .ffunc_bit, name, kind + | .ffunc_bit name, kind, .ffunc_1 + |.endmacro + | + |.ffunc_bit bit_tobit, 0 + | jmp ->fff_resbit + | + |.macro .ffunc_bit_op, name, ins + | .ffunc_bit name, 2 + | mov TMP2, NARGS:RD // Save for fallback. + | lea RD, [BASE+NARGS:RD*8-16] + |1: + | cmp RD, BASE + | jbe ->fff_resbit + | cmp dword [RD+4], LJ_TISNUM + |.if DUALNUM + | jne >2 + | ins RB, dword [RD] + | sub RD, 8 + | jmp <1 + |2: + | ja ->fff_fallback_bit_op + |.else + | jae ->fff_fallback_bit_op + |.endif + | movsd xmm0, qword [RD] + | addsd xmm0, xmm1 + | movd RA, xmm0 + | ins RB, RA + | sub RD, 8 + | jmp <1 + |.endmacro + | + |.ffunc_bit_op bit_band, and + |.ffunc_bit_op bit_bor, or + |.ffunc_bit_op bit_bxor, xor + | + |.ffunc_bit bit_bswap, 1 + | bswap RB + | jmp ->fff_resbit + | + |.ffunc_bit bit_bnot, 1 + | not RB + |.if DUALNUM + | jmp ->fff_resbit + |.else + |->fff_resbit: + | cvtsi2sd xmm0, RB + | jmp ->fff_resxmm0 + |.endif + | + |->fff_fallback_bit_op: + | mov NARGS:RD, TMP2 // Restore for fallback + | jmp ->fff_fallback + | + |.macro .ffunc_bit_sh, name, ins + |.if DUALNUM + | .ffunc_bit name, 1, .ffunc_2 + | // Note: no inline conversion from number for 2nd argument! + | cmp dword [BASE+12], LJ_TISNUM; jne ->fff_fallback + | mov RA, dword [BASE+8] + |.else + | .ffunc_nnsse name + | sseconst_tobit xmm2, RBa + | addsd xmm0, xmm2 + | addsd xmm1, xmm2 + | movd RB, xmm0 + | movd RA, xmm1 + |.endif + | ins RB, cl // Assumes RA is ecx. + | jmp ->fff_resbit + |.endmacro + | + |.ffunc_bit_sh bit_lshift, shl + |.ffunc_bit_sh bit_rshift, shr + |.ffunc_bit_sh bit_arshift, sar + |.ffunc_bit_sh bit_rol, rol + |.ffunc_bit_sh bit_ror, ror + | + |//----------------------------------------------------------------------- + | + |->fff_fallback_2: + | mov NARGS:RD, 1+2 // Other args are ignored, anyway. + | jmp ->fff_fallback + |->fff_fallback_1: + | mov NARGS:RD, 1+1 // Other args are ignored, anyway. + |->fff_fallback: // Call fast function fallback handler. + | // BASE = new base, RD = nargs+1 + | mov L:RB, SAVE_L + | mov PC, [BASE-4] // Fallback may overwrite PC. + | mov SAVE_PC, PC // Redundant (but a defined value). + | mov L:RB->base, BASE + | lea RD, [BASE+NARGS:RD*8-8] + | lea RA, [RD+8*LUA_MINSTACK] // Ensure enough space for handler. + | mov L:RB->top, RD + | mov CFUNC:RD, [BASE-8] + | cmp RA, L:RB->maxstack + | ja >5 // Need to grow stack. + |.if X64 + | mov CARG1d, L:RB + |.else + | mov ARG1, L:RB + |.endif + | call aword CFUNC:RD->f // (lua_State *L) + | mov BASE, L:RB->base + | // Either throws an error, or recovers and returns -1, 0 or nresults+1. + | test RD, RD; jg ->fff_res // Returned nresults+1? + |1: + | mov RA, L:RB->top + | sub RA, BASE + | shr RA, 3 + | test RD, RD + | lea NARGS:RD, [RA+1] + | mov LFUNC:RB, [BASE-8] + | jne ->vm_call_tail // Returned -1? + | ins_callt // Returned 0: retry fast path. + | + |// Reconstruct previous base for vmeta_call during tailcall. + |->vm_call_tail: + | mov RA, BASE + | test PC, FRAME_TYPE + | jnz >3 + | movzx RB, PC_RA + | not RBa // Note: ~RB = -(RB+1) + | lea BASE, [BASE+RB*8] // base = base - (RB+1)*8 + | jmp ->vm_call_dispatch // Resolve again for tailcall. + |3: + | mov RB, PC + | and RB, -8 + | sub BASE, RB + | jmp ->vm_call_dispatch // Resolve again for tailcall. + | + |5: // Grow stack for fallback handler. + | mov FCARG2, LUA_MINSTACK + | mov FCARG1, L:RB + | call extern lj_state_growstack@8 // (lua_State *L, int n) + | mov BASE, L:RB->base + | xor RD, RD // Simulate a return 0. + | jmp <1 // Dumb retry (goes through ff first). + | + |->fff_gcstep: // Call GC step function. + | // BASE = new base, RD = nargs+1 + | pop RBa // Must keep stack at same level. + | mov TMPa, RBa // Save return address + | mov L:RB, SAVE_L + | mov SAVE_PC, PC // Redundant (but a defined value). + | mov L:RB->base, BASE + | lea RD, [BASE+NARGS:RD*8-8] + | mov FCARG1, L:RB + | mov L:RB->top, RD + | call extern lj_gc_step@4 // (lua_State *L) + | mov BASE, L:RB->base + | mov RD, L:RB->top + | sub RD, BASE + | shr RD, 3 + | add NARGS:RD, 1 + | mov RBa, TMPa + | push RBa // Restore return address. + | ret + | + |//----------------------------------------------------------------------- + |//-- Special dispatch targets ------------------------------------------- + |//----------------------------------------------------------------------- + | + |->vm_record: // Dispatch target for recording phase. + |.if JIT + | movzx RD, byte [DISPATCH+DISPATCH_GL(hookmask)] + | test RDL, HOOK_VMEVENT // No recording while in vmevent. + | jnz >5 + | // Decrement the hookcount for consistency, but always do the call. + | test RDL, HOOK_ACTIVE + | jnz >1 + | test RDL, LUA_MASKLINE|LUA_MASKCOUNT + | jz >1 + | dec dword [DISPATCH+DISPATCH_GL(hookcount)] + | jmp >1 + |.endif + | + |->vm_rethook: // Dispatch target for return hooks. + | movzx RD, byte [DISPATCH+DISPATCH_GL(hookmask)] + | test RDL, HOOK_ACTIVE // Hook already active? + | jnz >5 + | jmp >1 + | + |->vm_inshook: // Dispatch target for instr/line hooks. + | movzx RD, byte [DISPATCH+DISPATCH_GL(hookmask)] + | test RDL, HOOK_ACTIVE // Hook already active? + | jnz >5 + | + | test RDL, LUA_MASKLINE|LUA_MASKCOUNT + | jz >5 + | dec dword [DISPATCH+DISPATCH_GL(hookcount)] + | jz >1 + | test RDL, LUA_MASKLINE + | jz >5 + |1: + | mov L:RB, SAVE_L + | mov L:RB->base, BASE + | mov FCARG2, PC // Caveat: FCARG2 == BASE + | mov FCARG1, L:RB + | // SAVE_PC must hold the _previous_ PC. The callee updates it with PC. + | call extern lj_dispatch_ins@8 // (lua_State *L, const BCIns *pc) + |3: + | mov BASE, L:RB->base + |4: + | movzx RA, PC_RA + |5: + | movzx OP, PC_OP + | movzx RD, PC_RD + |.if X64 + | jmp aword [DISPATCH+OP*8+GG_DISP2STATIC] // Re-dispatch to static ins. + |.else + | jmp aword [DISPATCH+OP*4+GG_DISP2STATIC] // Re-dispatch to static ins. + |.endif + | + |->cont_hook: // Continue from hook yield. + | add PC, 4 + | mov RA, [RB-24] + | mov MULTRES, RA // Restore MULTRES for *M ins. + | jmp <4 + | + |->vm_hotloop: // Hot loop counter underflow. + |.if JIT + | mov LFUNC:RB, [BASE-8] // Same as curr_topL(L). + | mov RB, LFUNC:RB->pc + | movzx RD, byte [RB+PC2PROTO(framesize)] + | lea RD, [BASE+RD*8] + | mov L:RB, SAVE_L + | mov L:RB->base, BASE + | mov L:RB->top, RD + | mov FCARG2, PC + | lea FCARG1, [DISPATCH+GG_DISP2J] + | mov aword [DISPATCH+DISPATCH_J(L)], L:RBa + | mov SAVE_PC, PC + | call extern lj_trace_hot@8 // (jit_State *J, const BCIns *pc) + | jmp <3 + |.endif + | + |->vm_callhook: // Dispatch target for call hooks. + | mov SAVE_PC, PC + |.if JIT + | jmp >1 + |.endif + | + |->vm_hotcall: // Hot call counter underflow. + |.if JIT + | mov SAVE_PC, PC + | or PC, 1 // Marker for hot call. + |1: + |.endif + | lea RD, [BASE+NARGS:RD*8-8] + | mov L:RB, SAVE_L + | mov L:RB->base, BASE + | mov L:RB->top, RD + | mov FCARG2, PC + | mov FCARG1, L:RB + | call extern lj_dispatch_call@8 // (lua_State *L, const BCIns *pc) + | // ASMFunction returned in eax/rax (RDa). + | mov SAVE_PC, 0 // Invalidate for subsequent line hook. + |.if JIT + | and PC, -2 + |.endif + | mov BASE, L:RB->base + | mov RAa, RDa + | mov RD, L:RB->top + | sub RD, BASE + | mov RBa, RAa + | movzx RA, PC_RA + | shr RD, 3 + | add NARGS:RD, 1 + | jmp RBa + | + |->cont_stitch: // Trace stitching. + |.if JIT + | // BASE = base, RC = result, RB = mbase + | mov TRACE:RA, [RB-24] // Save previous trace. + | mov TMP1, TRACE:RA + | mov TMP3, DISPATCH // Need one more register. + | mov DISPATCH, MULTRES + | movzx RA, PC_RA + | lea RA, [BASE+RA*8] // Call base. + | sub DISPATCH, 1 + | jz >2 + |1: // Move results down. + |.if X64 + | mov RBa, [RC] + | mov [RA], RBa + |.else + | mov RB, [RC] + | mov [RA], RB + | mov RB, [RC+4] + | mov [RA+4], RB + |.endif + | add RC, 8 + | add RA, 8 + | sub DISPATCH, 1 + | jnz <1 + |2: + | movzx RC, PC_RA + | movzx RB, PC_RB + | add RC, RB + | lea RC, [BASE+RC*8-8] + |3: + | cmp RC, RA + | ja >9 // More results wanted? + | + | mov DISPATCH, TMP3 + | mov TRACE:RD, TMP1 // Get previous trace. + | movzx RB, word TRACE:RD->traceno + | movzx RD, word TRACE:RD->link + | cmp RD, RB + | je ->cont_nop // Blacklisted. + | test RD, RD + | jne =>BC_JLOOP // Jump to stitched trace. + | + | // Stitch a new trace to the previous trace. + | mov [DISPATCH+DISPATCH_J(exitno)], RB + | mov L:RB, SAVE_L + | mov L:RB->base, BASE + | mov FCARG2, PC + | lea FCARG1, [DISPATCH+GG_DISP2J] + | mov aword [DISPATCH+DISPATCH_J(L)], L:RBa + | call extern lj_dispatch_stitch@8 // (jit_State *J, const BCIns *pc) + | mov BASE, L:RB->base + | jmp ->cont_nop + | + |9: // Fill up results with nil. + | mov dword [RA+4], LJ_TNIL + | add RA, 8 + | jmp <3 + |.endif + | + |->vm_profhook: // Dispatch target for profiler hook. +#if LJ_HASPROFILE + | mov L:RB, SAVE_L + | mov L:RB->base, BASE + | mov FCARG2, PC // Caveat: FCARG2 == BASE + | mov FCARG1, L:RB + | call extern lj_dispatch_profile@8 // (lua_State *L, const BCIns *pc) + | mov BASE, L:RB->base + | // HOOK_PROFILE is off again, so re-dispatch to dynamic instruction. + | sub PC, 4 + | jmp ->cont_nop +#endif + | + |//----------------------------------------------------------------------- + |//-- Trace exit handler ------------------------------------------------- + |//----------------------------------------------------------------------- + | + |// Called from an exit stub with the exit number on the stack. + |// The 16 bit exit number is stored with two (sign-extended) push imm8. + |->vm_exit_handler: + |.if JIT + |.if X64 + | push r13; push r12 + | push r11; push r10; push r9; push r8 + | push rdi; push rsi; push rbp; lea rbp, [rsp+88]; push rbp + | push rbx; push rdx; push rcx; push rax + | movzx RC, byte [rbp-8] // Reconstruct exit number. + | mov RCH, byte [rbp-16] + | mov [rbp-8], r15; mov [rbp-16], r14 + |.else + | push ebp; lea ebp, [esp+12]; push ebp + | push ebx; push edx; push ecx; push eax + | movzx RC, byte [ebp-4] // Reconstruct exit number. + | mov RCH, byte [ebp-8] + | mov [ebp-4], edi; mov [ebp-8], esi + |.endif + | // Caveat: DISPATCH is ebx. + | mov DISPATCH, [ebp] + | mov RA, [DISPATCH+DISPATCH_GL(vmstate)] // Get trace number. + | set_vmstate EXIT + | mov [DISPATCH+DISPATCH_J(exitno)], RC + | mov [DISPATCH+DISPATCH_J(parent)], RA + |.if X64 + |.if X64WIN + | sub rsp, 16*8+4*8 // Room for SSE regs + save area. + |.else + | sub rsp, 16*8 // Room for SSE regs. + |.endif + | add rbp, -128 + | movsd qword [rbp-8], xmm15; movsd qword [rbp-16], xmm14 + | movsd qword [rbp-24], xmm13; movsd qword [rbp-32], xmm12 + | movsd qword [rbp-40], xmm11; movsd qword [rbp-48], xmm10 + | movsd qword [rbp-56], xmm9; movsd qword [rbp-64], xmm8 + | movsd qword [rbp-72], xmm7; movsd qword [rbp-80], xmm6 + | movsd qword [rbp-88], xmm5; movsd qword [rbp-96], xmm4 + | movsd qword [rbp-104], xmm3; movsd qword [rbp-112], xmm2 + | movsd qword [rbp-120], xmm1; movsd qword [rbp-128], xmm0 + |.else + | sub esp, 8*8+16 // Room for SSE regs + args. + | movsd qword [ebp-40], xmm7; movsd qword [ebp-48], xmm6 + | movsd qword [ebp-56], xmm5; movsd qword [ebp-64], xmm4 + | movsd qword [ebp-72], xmm3; movsd qword [ebp-80], xmm2 + | movsd qword [ebp-88], xmm1; movsd qword [ebp-96], xmm0 + |.endif + | // Caveat: RB is ebp. + | mov L:RB, [DISPATCH+DISPATCH_GL(cur_L)] + | mov BASE, [DISPATCH+DISPATCH_GL(jit_base)] + | mov aword [DISPATCH+DISPATCH_J(L)], L:RBa + | mov L:RB->base, BASE + |.if X64WIN + | lea CARG2, [rsp+4*8] + |.elif X64 + | mov CARG2, rsp + |.else + | lea FCARG2, [esp+16] + |.endif + | lea FCARG1, [DISPATCH+GG_DISP2J] + | mov dword [DISPATCH+DISPATCH_GL(jit_base)], 0 + | call extern lj_trace_exit@8 // (jit_State *J, ExitState *ex) + | // MULTRES or negated error code returned in eax (RD). + | mov RAa, L:RB->cframe + | and RAa, CFRAME_RAWMASK + |.if X64WIN + | // Reposition stack later. + |.elif X64 + | mov rsp, RAa // Reposition stack to C frame. + |.else + | mov esp, RAa // Reposition stack to C frame. + |.endif + | mov [RAa+CFRAME_OFS_L], L:RB // Set SAVE_L (on-trace resume/yield). + | mov BASE, L:RB->base + | mov PC, [RAa+CFRAME_OFS_PC] // Get SAVE_PC. + |.if X64 + | jmp >1 + |.endif + |.endif + |->vm_exit_interp: + | // RD = MULTRES or negated error code, BASE, PC and DISPATCH set. + |.if JIT + |.if X64 + | // Restore additional callee-save registers only used in compiled code. + |.if X64WIN + | lea RAa, [rsp+9*16+4*8] + |1: + | movdqa xmm15, [RAa-9*16] + | movdqa xmm14, [RAa-8*16] + | movdqa xmm13, [RAa-7*16] + | movdqa xmm12, [RAa-6*16] + | movdqa xmm11, [RAa-5*16] + | movdqa xmm10, [RAa-4*16] + | movdqa xmm9, [RAa-3*16] + | movdqa xmm8, [RAa-2*16] + | movdqa xmm7, [RAa-1*16] + | mov rsp, RAa // Reposition stack to C frame. + | movdqa xmm6, [RAa] + | mov r15, CSAVE_3 + | mov r14, CSAVE_4 + |.else + | add rsp, 16 // Reposition stack to C frame. + |1: + |.endif + | mov r13, TMPa + | mov r12, TMPQ + |.endif + | test RD, RD; js >9 // Check for error from exit. + | mov L:RB, SAVE_L + | mov MULTRES, RD + | mov LFUNC:KBASE, [BASE-8] + | mov KBASE, LFUNC:KBASE->pc + | mov KBASE, [KBASE+PC2PROTO(k)] + | mov L:RB->base, BASE + | mov dword [DISPATCH+DISPATCH_GL(jit_base)], 0 + | set_vmstate INTERP + | // Modified copy of ins_next which handles function header dispatch, too. + | mov RC, [PC] + | movzx RA, RCH + | movzx OP, RCL + | add PC, 4 + | shr RC, 16 + | cmp OP, BC_FUNCF // Function header? + | jb >3 + | cmp OP, BC_FUNCC+2 // Fast function? + | jae >4 + |2: + | mov RC, MULTRES // RC/RD holds nres+1. + |3: + |.if X64 + | jmp aword [DISPATCH+OP*8] + |.else + | jmp aword [DISPATCH+OP*4] + |.endif + | + |4: // Check frame below fast function. + | mov RC, [BASE-4] + | test RC, FRAME_TYPE + | jnz <2 // Trace stitching continuation? + | // Otherwise set KBASE for Lua function below fast function. + | movzx RC, byte [RC-3] + | not RCa + | mov LFUNC:KBASE, [BASE+RC*8-8] + | mov KBASE, LFUNC:KBASE->pc + | mov KBASE, [KBASE+PC2PROTO(k)] + | jmp <2 + | + |9: // Rethrow error from the right C frame. + | mov FCARG2, RD + | mov FCARG1, L:RB + | neg FCARG2 + | call extern lj_err_trace@8 // (lua_State *L, int errcode) + |.endif + | + |//----------------------------------------------------------------------- + |//-- Math helper functions ---------------------------------------------- + |//----------------------------------------------------------------------- + | + |// FP value rounding. Called by math.floor/math.ceil fast functions + |// and from JIT code. arg/ret is xmm0. xmm0-xmm3 and RD (eax) modified. + |.macro vm_round, name, mode, cond + |->name: + |.if not X64 and cond + | movsd xmm0, qword [esp+4] + | call ->name .. _sse + | movsd qword [esp+4], xmm0 // Overwrite callee-owned arg. + | fld qword [esp+4] + | ret + |.endif + | + |->name .. _sse: + | sseconst_abs xmm2, RDa + | sseconst_2p52 xmm3, RDa + | movaps xmm1, xmm0 + | andpd xmm1, xmm2 // |x| + | ucomisd xmm3, xmm1 // No truncation if 2^52 <= |x|. + | jbe >1 + | andnpd xmm2, xmm0 // Isolate sign bit. + |.if mode == 2 // trunc(x)? + | movaps xmm0, xmm1 + | addsd xmm1, xmm3 // (|x| + 2^52) - 2^52 + | subsd xmm1, xmm3 + | sseconst_1 xmm3, RDa + | cmpsd xmm0, xmm1, 1 // |x| < result? + | andpd xmm0, xmm3 + | subsd xmm1, xmm0 // If yes, subtract -1. + | orpd xmm1, xmm2 // Merge sign bit back in. + |.else + | addsd xmm1, xmm3 // (|x| + 2^52) - 2^52 + | subsd xmm1, xmm3 + | orpd xmm1, xmm2 // Merge sign bit back in. + | sseconst_1 xmm3, RDa + | .if mode == 1 // ceil(x)? + | cmpsd xmm0, xmm1, 6 // x > result? + | andpd xmm0, xmm3 + | addsd xmm1, xmm0 // If yes, add 1. + | orpd xmm1, xmm2 // Merge sign bit back in (again). + | .else // floor(x)? + | cmpsd xmm0, xmm1, 1 // x < result? + | andpd xmm0, xmm3 + | subsd xmm1, xmm0 // If yes, subtract 1. + | .endif + |.endif + | movaps xmm0, xmm1 + |1: + | ret + |.endmacro + | + | vm_round vm_floor, 0, 1 + | vm_round vm_ceil, 1, JIT + | vm_round vm_trunc, 2, JIT + | + |// FP modulo x%y. Called by BC_MOD* and vm_arith. + |->vm_mod: + |// Args in xmm0/xmm1, return value in xmm0. + |// Caveat: xmm0-xmm5 and RC (eax) modified! + | movaps xmm5, xmm0 + | divsd xmm0, xmm1 + | sseconst_abs xmm2, RDa + | sseconst_2p52 xmm3, RDa + | movaps xmm4, xmm0 + | andpd xmm4, xmm2 // |x/y| + | ucomisd xmm3, xmm4 // No truncation if 2^52 <= |x/y|. + | jbe >1 + | andnpd xmm2, xmm0 // Isolate sign bit. + | addsd xmm4, xmm3 // (|x/y| + 2^52) - 2^52 + | subsd xmm4, xmm3 + | orpd xmm4, xmm2 // Merge sign bit back in. + | sseconst_1 xmm2, RDa + | cmpsd xmm0, xmm4, 1 // x/y < result? + | andpd xmm0, xmm2 + | subsd xmm4, xmm0 // If yes, subtract 1.0. + | movaps xmm0, xmm5 + | mulsd xmm1, xmm4 + | subsd xmm0, xmm1 + | ret + |1: + | mulsd xmm1, xmm0 + | movaps xmm0, xmm5 + | subsd xmm0, xmm1 + | ret + | + |//----------------------------------------------------------------------- + |//-- Miscellaneous functions -------------------------------------------- + |//----------------------------------------------------------------------- + | + |// int lj_vm_cpuid(uint32_t f, uint32_t res[4]) + |->vm_cpuid: + |.if X64 + | mov eax, CARG1d + | .if X64WIN; push rsi; mov rsi, CARG2; .endif + | push rbx + | xor ecx, ecx + | cpuid + | mov [rsi], eax + | mov [rsi+4], ebx + | mov [rsi+8], ecx + | mov [rsi+12], edx + | pop rbx + | .if X64WIN; pop rsi; .endif + | ret + |.else + | pushfd + | pop edx + | mov ecx, edx + | xor edx, 0x00200000 // Toggle ID bit in flags. + | push edx + | popfd + | pushfd + | pop edx + | xor eax, eax // Zero means no features supported. + | cmp ecx, edx + | jz >1 // No ID toggle means no CPUID support. + | mov eax, [esp+4] // Argument 1 is function number. + | push edi + | push ebx + | xor ecx, ecx + | cpuid + | mov edi, [esp+16] // Argument 2 is result area. + | mov [edi], eax + | mov [edi+4], ebx + | mov [edi+8], ecx + | mov [edi+12], edx + | pop ebx + | pop edi + |1: + | ret + |.endif + | + |.define NEXT_TAB, TAB:FCARG1 + |.define NEXT_IDX, FCARG2 + |.define NEXT_PTR, RCa + |.define NEXT_PTRd, RC + |.macro NEXT_RES_IDXL, op2; lea edx, [NEXT_IDX+op2]; .endmacro + |.if X64 + |.define NEXT_TMP, CARG3d + |.define NEXT_TMPq, CARG3 + |.define NEXT_ASIZE, CARG4d + |.macro NEXT_ENTER; .endmacro + |.macro NEXT_LEAVE; ret; .endmacro + |.if X64WIN + |.define NEXT_RES_PTR, [rsp+aword*5] + |.macro NEXT_RES_IDX, op2; add NEXT_IDX, op2; .endmacro + |.else + |.define NEXT_RES_PTR, [rsp+aword*1] + |.macro NEXT_RES_IDX, op2; lea edx, [NEXT_IDX+op2]; .endmacro + |.endif + |.else + |.define NEXT_ASIZE, esi + |.define NEXT_TMP, edi + |.macro NEXT_ENTER; push esi; push edi; .endmacro + |.macro NEXT_LEAVE; pop edi; pop esi; ret; .endmacro + |.define NEXT_RES_PTR, [esp+dword*3] + |.macro NEXT_RES_IDX, op2; add NEXT_IDX, op2; .endmacro + |.endif + | + |// TValue *lj_vm_next(GCtab *t, uint32_t idx) + |// Next idx returned in edx. + |->vm_next: + |.if JIT + | NEXT_ENTER + | mov NEXT_ASIZE, NEXT_TAB->asize + |1: // Traverse array part. + | cmp NEXT_IDX, NEXT_ASIZE; jae >5 + | mov NEXT_TMP, NEXT_TAB->array + | cmp dword [NEXT_TMP+NEXT_IDX*8+4], LJ_TNIL; je >2 + | lea NEXT_PTR, NEXT_RES_PTR + |.if X64 + | mov NEXT_TMPq, qword [NEXT_TMP+NEXT_IDX*8] + | mov qword [NEXT_PTR], NEXT_TMPq + |.else + | mov NEXT_ASIZE, dword [NEXT_TMP+NEXT_IDX*8+4] + | mov NEXT_TMP, dword [NEXT_TMP+NEXT_IDX*8] + | mov dword [NEXT_PTR+4], NEXT_ASIZE + | mov dword [NEXT_PTR], NEXT_TMP + |.endif + |.if DUALNUM + | mov dword [NEXT_PTR+dword*3], LJ_TISNUM + | mov dword [NEXT_PTR+dword*2], NEXT_IDX + |.else + | cvtsi2sd xmm0, NEXT_IDX + | movsd qword [NEXT_PTR+dword*2], xmm0 + |.endif + | NEXT_RES_IDX 1 + | NEXT_LEAVE + |2: // Skip holes in array part. + | add NEXT_IDX, 1 + | jmp <1 + | + |5: // Traverse hash part. + | sub NEXT_IDX, NEXT_ASIZE + |6: + | cmp NEXT_IDX, NEXT_TAB->hmask; ja >9 + | imul NEXT_PTRd, NEXT_IDX, #NODE + | add NODE:NEXT_PTRd, dword NEXT_TAB->node + | cmp dword NODE:NEXT_PTR->val.it, LJ_TNIL; je >7 + | NEXT_RES_IDXL NEXT_ASIZE+1 + | NEXT_LEAVE + |7: // Skip holes in hash part. + | add NEXT_IDX, 1 + | jmp <6 + | + |9: // End of iteration. Set the key to nil (not the value). + | NEXT_RES_IDX NEXT_ASIZE + | lea NEXT_PTR, NEXT_RES_PTR + | mov dword [NEXT_PTR+dword*3], LJ_TNIL + | NEXT_LEAVE + |.endif + | + |//----------------------------------------------------------------------- + |//-- Assertions --------------------------------------------------------- + |//----------------------------------------------------------------------- + | + |->assert_bad_for_arg_type: +#ifdef LUA_USE_ASSERT + | int3 +#endif + | int3 + | + |//----------------------------------------------------------------------- + |//-- FFI helper functions ----------------------------------------------- + |//----------------------------------------------------------------------- + | + |// Handler for callback functions. Callback slot number in ah/al. + |->vm_ffi_callback: + |.if FFI + |.type CTSTATE, CTState, PC + |.if not X64 + | sub esp, 16 // Leave room for SAVE_ERRF etc. + |.endif + | saveregs_ // ebp/rbp already saved. ebp now holds global_State *. + | lea DISPATCH, [ebp+GG_G2DISP] + | mov CTSTATE, GL:ebp->ctype_state + | movzx eax, ax + | mov CTSTATE->cb.slot, eax + |.if X64 + | mov CTSTATE->cb.gpr[0], CARG1 + | mov CTSTATE->cb.gpr[1], CARG2 + | mov CTSTATE->cb.gpr[2], CARG3 + | mov CTSTATE->cb.gpr[3], CARG4 + | movsd qword CTSTATE->cb.fpr[0], xmm0 + | movsd qword CTSTATE->cb.fpr[1], xmm1 + | movsd qword CTSTATE->cb.fpr[2], xmm2 + | movsd qword CTSTATE->cb.fpr[3], xmm3 + |.if X64WIN + | lea rax, [rsp+CFRAME_SIZE+4*8] + |.else + | lea rax, [rsp+CFRAME_SIZE] + | mov CTSTATE->cb.gpr[4], CARG5 + | mov CTSTATE->cb.gpr[5], CARG6 + | movsd qword CTSTATE->cb.fpr[4], xmm4 + | movsd qword CTSTATE->cb.fpr[5], xmm5 + | movsd qword CTSTATE->cb.fpr[6], xmm6 + | movsd qword CTSTATE->cb.fpr[7], xmm7 + |.endif + | mov CTSTATE->cb.stack, rax + | mov CARG2, rsp + |.else + | lea eax, [esp+CFRAME_SIZE+16] + | mov CTSTATE->cb.gpr[0], FCARG1 + | mov CTSTATE->cb.gpr[1], FCARG2 + | mov CTSTATE->cb.stack, eax + | mov FCARG1, [esp+CFRAME_SIZE+12] // Move around misplaced retaddr/ebp. + | mov FCARG2, [esp+CFRAME_SIZE+8] + | mov SAVE_RET, FCARG1 + | mov SAVE_R4, FCARG2 + | mov FCARG2, esp + |.endif + | mov SAVE_PC, CTSTATE // Any value outside of bytecode is ok. + | mov FCARG1, CTSTATE + | call extern lj_ccallback_enter@8 // (CTState *cts, void *cf) + | // lua_State * returned in eax (RD). + | set_vmstate INTERP + | mov BASE, L:RD->base + | mov RD, L:RD->top + | sub RD, BASE + | mov LFUNC:RB, [BASE-8] + | shr RD, 3 + | add RD, 1 + | ins_callt + |.endif + | + |->cont_ffi_callback: // Return from FFI callback. + |.if FFI + | mov L:RA, SAVE_L + | mov CTSTATE, [DISPATCH+DISPATCH_GL(ctype_state)] + | mov aword CTSTATE->L, L:RAa + | mov L:RA->base, BASE + | mov L:RA->top, RB + | mov FCARG1, CTSTATE + | mov FCARG2, RC + | call extern lj_ccallback_leave@8 // (CTState *cts, TValue *o) + |.if X64 + | mov rax, CTSTATE->cb.gpr[0] + | movsd xmm0, qword CTSTATE->cb.fpr[0] + | jmp ->vm_leave_unw + |.else + | mov L:RB, SAVE_L + | mov eax, CTSTATE->cb.gpr[0] + | mov edx, CTSTATE->cb.gpr[1] + | cmp dword CTSTATE->cb.gpr[2], 1 + | jb >7 + | je >6 + | fld qword CTSTATE->cb.fpr[0].d + | jmp >7 + |6: + | fld dword CTSTATE->cb.fpr[0].f + |7: + | mov ecx, L:RB->top + | movzx ecx, word [ecx+6] // Get stack adjustment and copy up. + | mov SAVE_L, ecx // Must be one slot above SAVE_RET + | restoreregs + | pop ecx // Move return addr from SAVE_RET. + | add esp, [esp] // Adjust stack. + | add esp, 16 + | push ecx + | ret + |.endif + |.endif + | + |->vm_ffi_call@4: // Call C function via FFI. + | // Caveat: needs special frame unwinding, see below. + |.if FFI + |.if X64 + | .type CCSTATE, CCallState, rbx + | push rbp; mov rbp, rsp; push rbx; mov CCSTATE, CARG1 + |.else + | .type CCSTATE, CCallState, ebx + | push ebp; mov ebp, esp; push ebx; mov CCSTATE, FCARG1 + |.endif + | + | // Readjust stack. + |.if X64 + | mov eax, CCSTATE->spadj + | sub rsp, rax + |.else + | sub esp, CCSTATE->spadj + |.if WIN + | mov CCSTATE->spadj, esp + |.endif + |.endif + | + | // Copy stack slots. + | movzx ecx, byte CCSTATE->nsp + | sub ecx, 1 + | js >2 + |1: + |.if X64 + | mov rax, [CCSTATE+rcx*8+offsetof(CCallState, stack)] + | mov [rsp+rcx*8+CCALL_SPS_EXTRA*8], rax + |.else + | mov eax, [CCSTATE+ecx*4+offsetof(CCallState, stack)] + | mov [esp+ecx*4], eax + |.endif + | sub ecx, 1 + | jns <1 + |2: + | + |.if X64 + | movzx eax, byte CCSTATE->nfpr + | mov CARG1, CCSTATE->gpr[0] + | mov CARG2, CCSTATE->gpr[1] + | mov CARG3, CCSTATE->gpr[2] + | mov CARG4, CCSTATE->gpr[3] + |.if not X64WIN + | mov CARG5, CCSTATE->gpr[4] + | mov CARG6, CCSTATE->gpr[5] + |.endif + | test eax, eax; jz >5 + | movaps xmm0, CCSTATE->fpr[0] + | movaps xmm1, CCSTATE->fpr[1] + | movaps xmm2, CCSTATE->fpr[2] + | movaps xmm3, CCSTATE->fpr[3] + |.if not X64WIN + | cmp eax, 4; jbe >5 + | movaps xmm4, CCSTATE->fpr[4] + | movaps xmm5, CCSTATE->fpr[5] + | movaps xmm6, CCSTATE->fpr[6] + | movaps xmm7, CCSTATE->fpr[7] + |.endif + |5: + |.else + | mov FCARG1, CCSTATE->gpr[0] + | mov FCARG2, CCSTATE->gpr[1] + |.endif + | + | call aword CCSTATE->func + | + |.if X64 + | mov CCSTATE->gpr[0], rax + | movaps CCSTATE->fpr[0], xmm0 + |.if not X64WIN + | mov CCSTATE->gpr[1], rdx + | movaps CCSTATE->fpr[1], xmm1 + |.endif + |.else + | mov CCSTATE->gpr[0], eax + | mov CCSTATE->gpr[1], edx + | cmp byte CCSTATE->resx87, 1 + | jb >7 + | je >6 + | fstp qword CCSTATE->fpr[0].d[0] + | jmp >7 + |6: + | fstp dword CCSTATE->fpr[0].f[0] + |7: + |.if WIN + | sub CCSTATE->spadj, esp + |.endif + |.endif + | + |.if X64 + | mov rbx, [rbp-8]; leave; ret + |.else + | mov ebx, [ebp-4]; leave; ret + |.endif + |.endif + |// Note: vm_ffi_call must be the last function in this object file! + | + |//----------------------------------------------------------------------- +} + +/* Generate the code for a single instruction. */ +static void build_ins(BuildCtx *ctx, BCOp op, int defop) +{ + int vk = 0; + |// Note: aligning all instructions does not pay off. + |=>defop: + + switch (op) { + + /* -- Comparison ops ---------------------------------------------------- */ + + /* Remember: all ops branch for a true comparison, fall through otherwise. */ + + |.macro jmp_comp, lt, ge, le, gt, target + ||switch (op) { + ||case BC_ISLT: + | lt target + ||break; + ||case BC_ISGE: + | ge target + ||break; + ||case BC_ISLE: + | le target + ||break; + ||case BC_ISGT: + | gt target + ||break; + ||default: break; /* Shut up GCC. */ + ||} + |.endmacro + + case BC_ISLT: case BC_ISGE: case BC_ISLE: case BC_ISGT: + | // RA = src1, RD = src2, JMP with RD = target + | ins_AD + |.if DUALNUM + | checkint RA, >7 + | checkint RD, >8 + | mov RB, dword [BASE+RA*8] + | add PC, 4 + | cmp RB, dword [BASE+RD*8] + | jmp_comp jge, jl, jg, jle, >9 + |6: + | movzx RD, PC_RD + | branchPC RD + |9: + | ins_next + | + |7: // RA is not an integer. + | ja ->vmeta_comp + | // RA is a number. + | cmp dword [BASE+RD*8+4], LJ_TISNUM; jb >1; jne ->vmeta_comp + | // RA is a number, RD is an integer. + | cvtsi2sd xmm0, dword [BASE+RD*8] + | jmp >2 + | + |8: // RA is an integer, RD is not an integer. + | ja ->vmeta_comp + | // RA is an integer, RD is a number. + | cvtsi2sd xmm1, dword [BASE+RA*8] + | movsd xmm0, qword [BASE+RD*8] + | add PC, 4 + | ucomisd xmm0, xmm1 + | jmp_comp jbe, ja, jb, jae, <9 + | jmp <6 + |.else + | checknum RA, ->vmeta_comp + | checknum RD, ->vmeta_comp + |.endif + |1: + | movsd xmm0, qword [BASE+RD*8] + |2: + | add PC, 4 + | ucomisd xmm0, qword [BASE+RA*8] + |3: + | // Unordered: all of ZF CF PF set, ordered: PF clear. + | // To preserve NaN semantics GE/GT branch on unordered, but LT/LE don't. + |.if DUALNUM + | jmp_comp jbe, ja, jb, jae, <9 + | jmp <6 + |.else + | jmp_comp jbe, ja, jb, jae, >1 + | movzx RD, PC_RD + | branchPC RD + |1: + | ins_next + |.endif + break; + + case BC_ISEQV: case BC_ISNEV: + vk = op == BC_ISEQV; + | ins_AD // RA = src1, RD = src2, JMP with RD = target + | mov RB, [BASE+RD*8+4] + | add PC, 4 + |.if DUALNUM + | cmp RB, LJ_TISNUM; jne >7 + | checkint RA, >8 + | mov RB, dword [BASE+RD*8] + | cmp RB, dword [BASE+RA*8] + if (vk) { + | jne >9 + } else { + | je >9 + } + | movzx RD, PC_RD + | branchPC RD + |9: + | ins_next + | + |7: // RD is not an integer. + | ja >5 + | // RD is a number. + | cmp dword [BASE+RA*8+4], LJ_TISNUM; jb >1; jne >5 + | // RD is a number, RA is an integer. + | cvtsi2sd xmm0, dword [BASE+RA*8] + | jmp >2 + | + |8: // RD is an integer, RA is not an integer. + | ja >5 + | // RD is an integer, RA is a number. + | cvtsi2sd xmm0, dword [BASE+RD*8] + | ucomisd xmm0, qword [BASE+RA*8] + | jmp >4 + | + |.else + | cmp RB, LJ_TISNUM; jae >5 + | checknum RA, >5 + |.endif + |1: + | movsd xmm0, qword [BASE+RA*8] + |2: + | ucomisd xmm0, qword [BASE+RD*8] + |4: + iseqne_fp: + if (vk) { + | jp >2 // Unordered means not equal. + | jne >2 + } else { + | jp >2 // Unordered means not equal. + | je >1 + } + iseqne_end: + if (vk) { + |1: // EQ: Branch to the target. + | movzx RD, PC_RD + | branchPC RD + |2: // NE: Fallthrough to next instruction. + |.if not FFI + |3: + |.endif + } else { + |.if not FFI + |3: + |.endif + |2: // NE: Branch to the target. + | movzx RD, PC_RD + | branchPC RD + |1: // EQ: Fallthrough to next instruction. + } + if (LJ_DUALNUM && (op == BC_ISEQV || op == BC_ISNEV || + op == BC_ISEQN || op == BC_ISNEN)) { + | jmp <9 + } else { + | ins_next + } + | + if (op == BC_ISEQV || op == BC_ISNEV) { + |5: // Either or both types are not numbers. + |.if FFI + | cmp RB, LJ_TCDATA; je ->vmeta_equal_cd + | checktp RA, LJ_TCDATA; je ->vmeta_equal_cd + |.endif + | checktp RA, RB // Compare types. + | jne <2 // Not the same type? + | cmp RB, LJ_TISPRI + | jae <1 // Same type and primitive type? + | + | // Same types and not a primitive type. Compare GCobj or pvalue. + | mov RA, [BASE+RA*8] + | mov RD, [BASE+RD*8] + | cmp RA, RD + | je <1 // Same GCobjs or pvalues? + | cmp RB, LJ_TISTABUD + | ja <2 // Different objects and not table/ud? + |.if X64 + | cmp RB, LJ_TUDATA // And not 64 bit lightuserdata. + | jb <2 + |.endif + | + | // Different tables or userdatas. Need to check __eq metamethod. + | // Field metatable must be at same offset for GCtab and GCudata! + | mov TAB:RB, TAB:RA->metatable + | test TAB:RB, TAB:RB + | jz <2 // No metatable? + | test byte TAB:RB->nomm, 1<vmeta_equal // Handle __eq metamethod. + } else { + |.if FFI + |3: + | cmp RB, LJ_TCDATA + if (LJ_DUALNUM && vk) { + | jne <9 + } else { + | jne <2 + } + | jmp ->vmeta_equal_cd + |.endif + } + break; + case BC_ISEQS: case BC_ISNES: + vk = op == BC_ISEQS; + | ins_AND // RA = src, RD = str const, JMP with RD = target + | mov RB, [BASE+RA*8+4] + | add PC, 4 + | cmp RB, LJ_TSTR; jne >3 + | mov RA, [BASE+RA*8] + | cmp RA, [KBASE+RD*4] + iseqne_test: + if (vk) { + | jne >2 + } else { + | je >1 + } + goto iseqne_end; + case BC_ISEQN: case BC_ISNEN: + vk = op == BC_ISEQN; + | ins_AD // RA = src, RD = num const, JMP with RD = target + | mov RB, [BASE+RA*8+4] + | add PC, 4 + |.if DUALNUM + | cmp RB, LJ_TISNUM; jne >7 + | cmp dword [KBASE+RD*8+4], LJ_TISNUM; jne >8 + | mov RB, dword [KBASE+RD*8] + | cmp RB, dword [BASE+RA*8] + if (vk) { + | jne >9 + } else { + | je >9 + } + | movzx RD, PC_RD + | branchPC RD + |9: + | ins_next + | + |7: // RA is not an integer. + | ja >3 + | // RA is a number. + | cmp dword [KBASE+RD*8+4], LJ_TISNUM; jb >1 + | // RA is a number, RD is an integer. + | cvtsi2sd xmm0, dword [KBASE+RD*8] + | jmp >2 + | + |8: // RA is an integer, RD is a number. + | cvtsi2sd xmm0, dword [BASE+RA*8] + | ucomisd xmm0, qword [KBASE+RD*8] + | jmp >4 + |.else + | cmp RB, LJ_TISNUM; jae >3 + |.endif + |1: + | movsd xmm0, qword [KBASE+RD*8] + |2: + | ucomisd xmm0, qword [BASE+RA*8] + |4: + goto iseqne_fp; + case BC_ISEQP: case BC_ISNEP: + vk = op == BC_ISEQP; + | ins_AND // RA = src, RD = primitive type (~), JMP with RD = target + | mov RB, [BASE+RA*8+4] + | add PC, 4 + | cmp RB, RD + if (!LJ_HASFFI) goto iseqne_test; + if (vk) { + | jne >3 + | movzx RD, PC_RD + | branchPC RD + |2: + | ins_next + |3: + | cmp RB, LJ_TCDATA; jne <2 + | jmp ->vmeta_equal_cd + } else { + | je >2 + | cmp RB, LJ_TCDATA; je ->vmeta_equal_cd + | movzx RD, PC_RD + | branchPC RD + |2: + | ins_next + } + break; + + /* -- Unary test and copy ops ------------------------------------------- */ + + case BC_ISTC: case BC_ISFC: case BC_IST: case BC_ISF: + | ins_AD // RA = dst or unused, RD = src, JMP with RD = target + | mov RB, [BASE+RD*8+4] + | add PC, 4 + | cmp RB, LJ_TISTRUECOND + if (op == BC_IST || op == BC_ISTC) { + | jae >1 + } else { + | jb >1 + } + if (op == BC_ISTC || op == BC_ISFC) { + | mov [BASE+RA*8+4], RB + | mov RB, [BASE+RD*8] + | mov [BASE+RA*8], RB + } + | movzx RD, PC_RD + | branchPC RD + |1: // Fallthrough to the next instruction. + | ins_next + break; + + case BC_ISTYPE: + | ins_AD // RA = src, RD = -type + | add RD, [BASE+RA*8+4] + | jne ->vmeta_istype + | ins_next + break; + case BC_ISNUM: + | ins_AD // RA = src, RD = -(TISNUM-1) + | checknum RA, ->vmeta_istype + | ins_next + break; + + /* -- Unary ops --------------------------------------------------------- */ + + case BC_MOV: + | ins_AD // RA = dst, RD = src + |.if X64 + | mov RBa, [BASE+RD*8] + | mov [BASE+RA*8], RBa + |.else + | mov RB, [BASE+RD*8+4] + | mov RD, [BASE+RD*8] + | mov [BASE+RA*8+4], RB + | mov [BASE+RA*8], RD + |.endif + | ins_next_ + break; + case BC_NOT: + | ins_AD // RA = dst, RD = src + | xor RB, RB + | checktp RD, LJ_TISTRUECOND + | adc RB, LJ_TTRUE + | mov [BASE+RA*8+4], RB + | ins_next + break; + case BC_UNM: + | ins_AD // RA = dst, RD = src + |.if DUALNUM + | checkint RD, >5 + | mov RB, [BASE+RD*8] + | neg RB + | jo >4 + | mov dword [BASE+RA*8+4], LJ_TISNUM + | mov dword [BASE+RA*8], RB + |9: + | ins_next + |4: + | mov dword [BASE+RA*8+4], 0x41e00000 // 2^31. + | mov dword [BASE+RA*8], 0 + | jmp <9 + |5: + | ja ->vmeta_unm + |.else + | checknum RD, ->vmeta_unm + |.endif + | movsd xmm0, qword [BASE+RD*8] + | sseconst_sign xmm1, RDa + | xorps xmm0, xmm1 + | movsd qword [BASE+RA*8], xmm0 + |.if DUALNUM + | jmp <9 + |.else + | ins_next + |.endif + break; + case BC_LEN: + | ins_AD // RA = dst, RD = src + | checkstr RD, >2 + | mov STR:RD, [BASE+RD*8] + |.if DUALNUM + | mov RD, dword STR:RD->len + |1: + | mov dword [BASE+RA*8+4], LJ_TISNUM + | mov dword [BASE+RA*8], RD + |.else + | xorps xmm0, xmm0 + | cvtsi2sd xmm0, dword STR:RD->len + |1: + | movsd qword [BASE+RA*8], xmm0 + |.endif + | ins_next + |2: + | checktab RD, ->vmeta_len + | mov TAB:FCARG1, [BASE+RD*8] +#if LJ_52 + | mov TAB:RB, TAB:FCARG1->metatable + | cmp TAB:RB, 0 + | jnz >9 + |3: +#endif + |->BC_LEN_Z: + | mov RB, BASE // Save BASE. + | call extern lj_tab_len@4 // (GCtab *t) + | // Length of table returned in eax (RD). + |.if DUALNUM + | // Nothing to do. + |.else + | cvtsi2sd xmm0, RD + |.endif + | mov BASE, RB // Restore BASE. + | movzx RA, PC_RA + | jmp <1 +#if LJ_52 + |9: // Check for __len. + | test byte TAB:RB->nomm, 1<vmeta_len // 'no __len' flag NOT set: check. +#endif + break; + + /* -- Binary ops -------------------------------------------------------- */ + + |.macro ins_arithpre, sseins, ssereg + | ins_ABC + ||vk = ((int)op - BC_ADDVN) / (BC_ADDNV-BC_ADDVN); + ||switch (vk) { + ||case 0: + | checknum RB, ->vmeta_arith_vn + | .if DUALNUM + | cmp dword [KBASE+RC*8+4], LJ_TISNUM; jae ->vmeta_arith_vn + | .endif + | movsd xmm0, qword [BASE+RB*8] + | sseins ssereg, qword [KBASE+RC*8] + || break; + ||case 1: + | checknum RB, ->vmeta_arith_nv + | .if DUALNUM + | cmp dword [KBASE+RC*8+4], LJ_TISNUM; jae ->vmeta_arith_nv + | .endif + | movsd xmm0, qword [KBASE+RC*8] + | sseins ssereg, qword [BASE+RB*8] + || break; + ||default: + | checknum RB, ->vmeta_arith_vv + | checknum RC, ->vmeta_arith_vv + | movsd xmm0, qword [BASE+RB*8] + | sseins ssereg, qword [BASE+RC*8] + || break; + ||} + |.endmacro + | + |.macro ins_arithdn, intins + | ins_ABC + ||vk = ((int)op - BC_ADDVN) / (BC_ADDNV-BC_ADDVN); + ||switch (vk) { + ||case 0: + | checkint RB, ->vmeta_arith_vn + | cmp dword [KBASE+RC*8+4], LJ_TISNUM; jne ->vmeta_arith_vn + | mov RB, [BASE+RB*8] + | intins RB, [KBASE+RC*8]; jo ->vmeta_arith_vno + || break; + ||case 1: + | checkint RB, ->vmeta_arith_nv + | cmp dword [KBASE+RC*8+4], LJ_TISNUM; jne ->vmeta_arith_nv + | mov RC, [KBASE+RC*8] + | intins RC, [BASE+RB*8]; jo ->vmeta_arith_nvo + || break; + ||default: + | checkint RB, ->vmeta_arith_vv + | checkint RC, ->vmeta_arith_vv + | mov RB, [BASE+RB*8] + | intins RB, [BASE+RC*8]; jo ->vmeta_arith_vvo + || break; + ||} + | mov dword [BASE+RA*8+4], LJ_TISNUM + ||if (vk == 1) { + | mov dword [BASE+RA*8], RC + ||} else { + | mov dword [BASE+RA*8], RB + ||} + | ins_next + |.endmacro + | + |.macro ins_arithpost + | movsd qword [BASE+RA*8], xmm0 + |.endmacro + | + |.macro ins_arith, sseins + | ins_arithpre sseins, xmm0 + | ins_arithpost + | ins_next + |.endmacro + | + |.macro ins_arith, intins, sseins + |.if DUALNUM + | ins_arithdn intins + |.else + | ins_arith, sseins + |.endif + |.endmacro + + | // RA = dst, RB = src1 or num const, RC = src2 or num const + case BC_ADDVN: case BC_ADDNV: case BC_ADDVV: + | ins_arith add, addsd + break; + case BC_SUBVN: case BC_SUBNV: case BC_SUBVV: + | ins_arith sub, subsd + break; + case BC_MULVN: case BC_MULNV: case BC_MULVV: + | ins_arith imul, mulsd + break; + case BC_DIVVN: case BC_DIVNV: case BC_DIVVV: + | ins_arith divsd + break; + case BC_MODVN: + | ins_arithpre movsd, xmm1 + |->BC_MODVN_Z: + | call ->vm_mod + | ins_arithpost + | ins_next + break; + case BC_MODNV: case BC_MODVV: + | ins_arithpre movsd, xmm1 + | jmp ->BC_MODVN_Z // Avoid 3 copies. It's slow anyway. + break; + case BC_POW: + | ins_arithpre movsd, xmm1 + | mov RB, BASE + |.if not X64 + | movsd FPARG1, xmm0 + | movsd FPARG3, xmm1 + |.endif + | call extern pow + | movzx RA, PC_RA + | mov BASE, RB + |.if X64 + | ins_arithpost + |.else + | fstp qword [BASE+RA*8] + |.endif + | ins_next + break; + + case BC_CAT: + | ins_ABC // RA = dst, RB = src_start, RC = src_end + |.if X64 + | mov L:CARG1d, SAVE_L + | mov L:CARG1d->base, BASE + | lea CARG2d, [BASE+RC*8] + | mov CARG3d, RC + | sub CARG3d, RB + |->BC_CAT_Z: + | mov L:RB, L:CARG1d + |.else + | lea RA, [BASE+RC*8] + | sub RC, RB + | mov ARG2, RA + | mov ARG3, RC + |->BC_CAT_Z: + | mov L:RB, SAVE_L + | mov ARG1, L:RB + | mov L:RB->base, BASE + |.endif + | mov SAVE_PC, PC + | call extern lj_meta_cat // (lua_State *L, TValue *top, int left) + | // NULL (finished) or TValue * (metamethod) returned in eax (RC). + | mov BASE, L:RB->base + | test RC, RC + | jnz ->vmeta_binop + | movzx RB, PC_RB // Copy result to Stk[RA] from Stk[RB]. + | movzx RA, PC_RA + |.if X64 + | mov RCa, [BASE+RB*8] + | mov [BASE+RA*8], RCa + |.else + | mov RC, [BASE+RB*8+4] + | mov RB, [BASE+RB*8] + | mov [BASE+RA*8+4], RC + | mov [BASE+RA*8], RB + |.endif + | ins_next + break; + + /* -- Constant ops ------------------------------------------------------ */ + + case BC_KSTR: + | ins_AND // RA = dst, RD = str const (~) + | mov RD, [KBASE+RD*4] + | mov dword [BASE+RA*8+4], LJ_TSTR + | mov [BASE+RA*8], RD + | ins_next + break; + case BC_KCDATA: + |.if FFI + | ins_AND // RA = dst, RD = cdata const (~) + | mov RD, [KBASE+RD*4] + | mov dword [BASE+RA*8+4], LJ_TCDATA + | mov [BASE+RA*8], RD + | ins_next + |.endif + break; + case BC_KSHORT: + | ins_AD // RA = dst, RD = signed int16 literal + |.if DUALNUM + | movsx RD, RDW + | mov dword [BASE+RA*8+4], LJ_TISNUM + | mov dword [BASE+RA*8], RD + |.else + | movsx RD, RDW // Sign-extend literal. + | cvtsi2sd xmm0, RD + | movsd qword [BASE+RA*8], xmm0 + |.endif + | ins_next + break; + case BC_KNUM: + | ins_AD // RA = dst, RD = num const + | movsd xmm0, qword [KBASE+RD*8] + | movsd qword [BASE+RA*8], xmm0 + | ins_next + break; + case BC_KPRI: + | ins_AND // RA = dst, RD = primitive type (~) + | mov [BASE+RA*8+4], RD + | ins_next + break; + case BC_KNIL: + | ins_AD // RA = dst_start, RD = dst_end + | lea RA, [BASE+RA*8+12] + | lea RD, [BASE+RD*8+4] + | mov RB, LJ_TNIL + | mov [RA-8], RB // Sets minimum 2 slots. + |1: + | mov [RA], RB + | add RA, 8 + | cmp RA, RD + | jbe <1 + | ins_next + break; + + /* -- Upvalue and function ops ------------------------------------------ */ + + case BC_UGET: + | ins_AD // RA = dst, RD = upvalue # + | mov LFUNC:RB, [BASE-8] + | mov UPVAL:RB, [LFUNC:RB+RD*4+offsetof(GCfuncL, uvptr)] + | mov RB, UPVAL:RB->v + |.if X64 + | mov RDa, [RB] + | mov [BASE+RA*8], RDa + |.else + | mov RD, [RB+4] + | mov RB, [RB] + | mov [BASE+RA*8+4], RD + | mov [BASE+RA*8], RB + |.endif + | ins_next + break; + case BC_USETV: +#define TV2MARKOFS \ + ((int32_t)offsetof(GCupval, marked)-(int32_t)offsetof(GCupval, tv)) + | ins_AD // RA = upvalue #, RD = src + | mov LFUNC:RB, [BASE-8] + | mov UPVAL:RB, [LFUNC:RB+RA*4+offsetof(GCfuncL, uvptr)] + | cmp byte UPVAL:RB->closed, 0 + | mov RB, UPVAL:RB->v + | mov RA, [BASE+RD*8] + | mov RD, [BASE+RD*8+4] + | mov [RB], RA + | mov [RB+4], RD + | jz >1 + | // Check barrier for closed upvalue. + | test byte [RB+TV2MARKOFS], LJ_GC_BLACK // isblack(uv) + | jnz >2 + |1: + | ins_next + | + |2: // Upvalue is black. Check if new value is collectable and white. + | sub RD, LJ_TISGCV + | cmp RD, LJ_TNUMX - LJ_TISGCV // tvisgcv(v) + | jbe <1 + | test byte GCOBJ:RA->gch.marked, LJ_GC_WHITES // iswhite(v) + | jz <1 + | // Crossed a write barrier. Move the barrier forward. + |.if X64 and not X64WIN + | mov FCARG2, RB + | mov RB, BASE // Save BASE. + |.else + | xchg FCARG2, RB // Save BASE (FCARG2 == BASE). + |.endif + | lea GL:FCARG1, [DISPATCH+GG_DISP2G] + | call extern lj_gc_barrieruv@8 // (global_State *g, TValue *tv) + | mov BASE, RB // Restore BASE. + | jmp <1 + break; +#undef TV2MARKOFS + case BC_USETS: + | ins_AND // RA = upvalue #, RD = str const (~) + | mov LFUNC:RB, [BASE-8] + | mov UPVAL:RB, [LFUNC:RB+RA*4+offsetof(GCfuncL, uvptr)] + | mov GCOBJ:RA, [KBASE+RD*4] + | mov RD, UPVAL:RB->v + | mov [RD], GCOBJ:RA + | mov dword [RD+4], LJ_TSTR + | test byte UPVAL:RB->marked, LJ_GC_BLACK // isblack(uv) + | jnz >2 + |1: + | ins_next + | + |2: // Check if string is white and ensure upvalue is closed. + | test byte GCOBJ:RA->gch.marked, LJ_GC_WHITES // iswhite(str) + | jz <1 + | cmp byte UPVAL:RB->closed, 0 + | jz <1 + | // Crossed a write barrier. Move the barrier forward. + | mov RB, BASE // Save BASE (FCARG2 == BASE). + | mov FCARG2, RD + | lea GL:FCARG1, [DISPATCH+GG_DISP2G] + | call extern lj_gc_barrieruv@8 // (global_State *g, TValue *tv) + | mov BASE, RB // Restore BASE. + | jmp <1 + break; + case BC_USETN: + | ins_AD // RA = upvalue #, RD = num const + | mov LFUNC:RB, [BASE-8] + | movsd xmm0, qword [KBASE+RD*8] + | mov UPVAL:RB, [LFUNC:RB+RA*4+offsetof(GCfuncL, uvptr)] + | mov RA, UPVAL:RB->v + | movsd qword [RA], xmm0 + | ins_next + break; + case BC_USETP: + | ins_AND // RA = upvalue #, RD = primitive type (~) + | mov LFUNC:RB, [BASE-8] + | mov UPVAL:RB, [LFUNC:RB+RA*4+offsetof(GCfuncL, uvptr)] + | mov RA, UPVAL:RB->v + | mov [RA+4], RD + | ins_next + break; + case BC_UCLO: + | ins_AD // RA = level, RD = target + | branchPC RD // Do this first to free RD. + | mov L:RB, SAVE_L + | cmp dword L:RB->openupval, 0 + | je >1 + | mov L:RB->base, BASE + | lea FCARG2, [BASE+RA*8] // Caveat: FCARG2 == BASE + | mov L:FCARG1, L:RB // Caveat: FCARG1 == RA + | call extern lj_func_closeuv@8 // (lua_State *L, TValue *level) + | mov BASE, L:RB->base + |1: + | ins_next + break; + + case BC_FNEW: + | ins_AND // RA = dst, RD = proto const (~) (holding function prototype) + |.if X64 + | mov L:RB, SAVE_L + | mov L:RB->base, BASE // Caveat: CARG2d/CARG3d may be BASE. + | mov CARG3d, [BASE-8] + | mov CARG2d, [KBASE+RD*4] // Fetch GCproto *. + | mov CARG1d, L:RB + |.else + | mov LFUNC:RA, [BASE-8] + | mov PROTO:RD, [KBASE+RD*4] // Fetch GCproto *. + | mov L:RB, SAVE_L + | mov ARG3, LFUNC:RA + | mov ARG2, PROTO:RD + | mov ARG1, L:RB + | mov L:RB->base, BASE + |.endif + | mov SAVE_PC, PC + | // (lua_State *L, GCproto *pt, GCfuncL *parent) + | call extern lj_func_newL_gc + | // GCfuncL * returned in eax (RC). + | mov BASE, L:RB->base + | movzx RA, PC_RA + | mov [BASE+RA*8], LFUNC:RC + | mov dword [BASE+RA*8+4], LJ_TFUNC + | ins_next + break; + + /* -- Table ops --------------------------------------------------------- */ + + case BC_TNEW: + | ins_AD // RA = dst, RD = hbits|asize + | mov L:RB, SAVE_L + | mov L:RB->base, BASE + | mov RA, [DISPATCH+DISPATCH_GL(gc.total)] + | cmp RA, [DISPATCH+DISPATCH_GL(gc.threshold)] + | mov SAVE_PC, PC + | jae >5 + |1: + |.if X64 + | mov CARG3d, RD + | and RD, 0x7ff + | shr CARG3d, 11 + |.else + | mov RA, RD + | and RD, 0x7ff + | shr RA, 11 + | mov ARG3, RA + |.endif + | cmp RD, 0x7ff + | je >3 + |2: + |.if X64 + | mov L:CARG1d, L:RB + | mov CARG2d, RD + |.else + | mov ARG1, L:RB + | mov ARG2, RD + |.endif + | call extern lj_tab_new // (lua_State *L, int32_t asize, uint32_t hbits) + | // Table * returned in eax (RC). + | mov BASE, L:RB->base + | movzx RA, PC_RA + | mov [BASE+RA*8], TAB:RC + | mov dword [BASE+RA*8+4], LJ_TTAB + | ins_next + |3: // Turn 0x7ff into 0x801. + | mov RD, 0x801 + | jmp <2 + |5: + | mov L:FCARG1, L:RB + | call extern lj_gc_step_fixtop@4 // (lua_State *L) + | movzx RD, PC_RD + | jmp <1 + break; + case BC_TDUP: + | ins_AND // RA = dst, RD = table const (~) (holding template table) + | mov L:RB, SAVE_L + | mov RA, [DISPATCH+DISPATCH_GL(gc.total)] + | mov SAVE_PC, PC + | cmp RA, [DISPATCH+DISPATCH_GL(gc.threshold)] + | mov L:RB->base, BASE + | jae >3 + |2: + | mov TAB:FCARG2, [KBASE+RD*4] // Caveat: FCARG2 == BASE + | mov L:FCARG1, L:RB // Caveat: FCARG1 == RA + | call extern lj_tab_dup@8 // (lua_State *L, Table *kt) + | // Table * returned in eax (RC). + | mov BASE, L:RB->base + | movzx RA, PC_RA + | mov [BASE+RA*8], TAB:RC + | mov dword [BASE+RA*8+4], LJ_TTAB + | ins_next + |3: + | mov L:FCARG1, L:RB + | call extern lj_gc_step_fixtop@4 // (lua_State *L) + | movzx RD, PC_RD // Need to reload RD. + | not RDa + | jmp <2 + break; + + case BC_GGET: + | ins_AND // RA = dst, RD = str const (~) + | mov LFUNC:RB, [BASE-8] + | mov TAB:RB, LFUNC:RB->env + | mov STR:RC, [KBASE+RD*4] + | jmp ->BC_TGETS_Z + break; + case BC_GSET: + | ins_AND // RA = src, RD = str const (~) + | mov LFUNC:RB, [BASE-8] + | mov TAB:RB, LFUNC:RB->env + | mov STR:RC, [KBASE+RD*4] + | jmp ->BC_TSETS_Z + break; + + case BC_TGETV: + | ins_ABC // RA = dst, RB = table, RC = key + | checktab RB, ->vmeta_tgetv + | mov TAB:RB, [BASE+RB*8] + | + | // Integer key? + |.if DUALNUM + | checkint RC, >5 + | mov RC, dword [BASE+RC*8] + |.else + | // Convert number to int and back and compare. + | checknum RC, >5 + | movsd xmm0, qword [BASE+RC*8] + | cvttsd2si RC, xmm0 + | cvtsi2sd xmm1, RC + | ucomisd xmm0, xmm1 + | jne ->vmeta_tgetv // Generic numeric key? Use fallback. + |.endif + | cmp RC, TAB:RB->asize // Takes care of unordered, too. + | jae ->vmeta_tgetv // Not in array part? Use fallback. + | shl RC, 3 + | add RC, TAB:RB->array + | cmp dword [RC+4], LJ_TNIL // Avoid overwriting RB in fastpath. + | je >2 + | // Get array slot. + |.if X64 + | mov RBa, [RC] + | mov [BASE+RA*8], RBa + |.else + | mov RB, [RC] + | mov RC, [RC+4] + | mov [BASE+RA*8], RB + | mov [BASE+RA*8+4], RC + |.endif + |1: + | ins_next + | + |2: // Check for __index if table value is nil. + | cmp dword TAB:RB->metatable, 0 // Shouldn't overwrite RA for fastpath. + | jz >3 + | mov TAB:RA, TAB:RB->metatable + | test byte TAB:RA->nomm, 1<vmeta_tgetv // 'no __index' flag NOT set: check. + | movzx RA, PC_RA // Restore RA. + |3: + | mov dword [BASE+RA*8+4], LJ_TNIL + | jmp <1 + | + |5: // String key? + | checkstr RC, ->vmeta_tgetv + | mov STR:RC, [BASE+RC*8] + | jmp ->BC_TGETS_Z + break; + case BC_TGETS: + | ins_ABC // RA = dst, RB = table, RC = str const (~) + | not RCa + | mov STR:RC, [KBASE+RC*4] + | checktab RB, ->vmeta_tgets + | mov TAB:RB, [BASE+RB*8] + |->BC_TGETS_Z: // RB = GCtab *, RC = GCstr *, refetches PC_RA. + | mov RA, TAB:RB->hmask + | and RA, STR:RC->sid + | imul RA, #NODE + | add NODE:RA, TAB:RB->node + |1: + | cmp dword NODE:RA->key.it, LJ_TSTR + | jne >4 + | cmp dword NODE:RA->key.gcr, STR:RC + | jne >4 + | // Ok, key found. Assumes: offsetof(Node, val) == 0 + | cmp dword [RA+4], LJ_TNIL // Avoid overwriting RB in fastpath. + | je >5 // Key found, but nil value? + | movzx RC, PC_RA + | // Get node value. + |.if X64 + | mov RBa, [RA] + | mov [BASE+RC*8], RBa + |.else + | mov RB, [RA] + | mov RA, [RA+4] + | mov [BASE+RC*8], RB + | mov [BASE+RC*8+4], RA + |.endif + |2: + | ins_next + | + |3: + | movzx RC, PC_RA + | mov dword [BASE+RC*8+4], LJ_TNIL + | jmp <2 + | + |4: // Follow hash chain. + | mov NODE:RA, NODE:RA->next + | test NODE:RA, NODE:RA + | jnz <1 + | // End of hash chain: key not found, nil result. + | + |5: // Check for __index if table value is nil. + | mov TAB:RA, TAB:RB->metatable + | test TAB:RA, TAB:RA + | jz <3 // No metatable: done. + | test byte TAB:RA->nomm, 1<vmeta_tgets // Caveat: preserve STR:RC. + break; + case BC_TGETB: + | ins_ABC // RA = dst, RB = table, RC = byte literal + | checktab RB, ->vmeta_tgetb + | mov TAB:RB, [BASE+RB*8] + | cmp RC, TAB:RB->asize + | jae ->vmeta_tgetb + | shl RC, 3 + | add RC, TAB:RB->array + | cmp dword [RC+4], LJ_TNIL // Avoid overwriting RB in fastpath. + | je >2 + | // Get array slot. + |.if X64 + | mov RBa, [RC] + | mov [BASE+RA*8], RBa + |.else + | mov RB, [RC] + | mov RC, [RC+4] + | mov [BASE+RA*8], RB + | mov [BASE+RA*8+4], RC + |.endif + |1: + | ins_next + | + |2: // Check for __index if table value is nil. + | cmp dword TAB:RB->metatable, 0 // Shouldn't overwrite RA for fastpath. + | jz >3 + | mov TAB:RA, TAB:RB->metatable + | test byte TAB:RA->nomm, 1<vmeta_tgetb // 'no __index' flag NOT set: check. + | movzx RA, PC_RA // Restore RA. + |3: + | mov dword [BASE+RA*8+4], LJ_TNIL + | jmp <1 + break; + case BC_TGETR: + | ins_ABC // RA = dst, RB = table, RC = key + | mov TAB:RB, [BASE+RB*8] + |.if DUALNUM + | mov RC, dword [BASE+RC*8] + |.else + | cvttsd2si RC, qword [BASE+RC*8] + |.endif + | cmp RC, TAB:RB->asize + | jae ->vmeta_tgetr // Not in array part? Use fallback. + | shl RC, 3 + | add RC, TAB:RB->array + | // Get array slot. + |->BC_TGETR_Z: + |.if X64 + | mov RBa, [RC] + | mov [BASE+RA*8], RBa + |.else + | mov RB, [RC] + | mov RC, [RC+4] + | mov [BASE+RA*8], RB + | mov [BASE+RA*8+4], RC + |.endif + |->BC_TGETR2_Z: + | ins_next + break; + + case BC_TSETV: + | ins_ABC // RA = src, RB = table, RC = key + | checktab RB, ->vmeta_tsetv + | mov TAB:RB, [BASE+RB*8] + | + | // Integer key? + |.if DUALNUM + | checkint RC, >5 + | mov RC, dword [BASE+RC*8] + |.else + | // Convert number to int and back and compare. + | checknum RC, >5 + | movsd xmm0, qword [BASE+RC*8] + | cvttsd2si RC, xmm0 + | cvtsi2sd xmm1, RC + | ucomisd xmm0, xmm1 + | jne ->vmeta_tsetv // Generic numeric key? Use fallback. + |.endif + | cmp RC, TAB:RB->asize // Takes care of unordered, too. + | jae ->vmeta_tsetv + | shl RC, 3 + | add RC, TAB:RB->array + | cmp dword [RC+4], LJ_TNIL + | je >3 // Previous value is nil? + |1: + | test byte TAB:RB->marked, LJ_GC_BLACK // isblack(table) + | jnz >7 + |2: // Set array slot. + |.if X64 + | mov RBa, [BASE+RA*8] + | mov [RC], RBa + |.else + | mov RB, [BASE+RA*8+4] + | mov RA, [BASE+RA*8] + | mov [RC+4], RB + | mov [RC], RA + |.endif + | ins_next + | + |3: // Check for __newindex if previous value is nil. + | cmp dword TAB:RB->metatable, 0 // Shouldn't overwrite RA for fastpath. + | jz <1 + | mov TAB:RA, TAB:RB->metatable + | test byte TAB:RA->nomm, 1<vmeta_tsetv // 'no __newindex' flag NOT set: check. + | movzx RA, PC_RA // Restore RA. + | jmp <1 + | + |5: // String key? + | checkstr RC, ->vmeta_tsetv + | mov STR:RC, [BASE+RC*8] + | jmp ->BC_TSETS_Z + | + |7: // Possible table write barrier for the value. Skip valiswhite check. + | barrierback TAB:RB, RA + | movzx RA, PC_RA // Restore RA. + | jmp <2 + break; + case BC_TSETS: + | ins_ABC // RA = src, RB = table, RC = str const (~) + | not RCa + | mov STR:RC, [KBASE+RC*4] + | checktab RB, ->vmeta_tsets + | mov TAB:RB, [BASE+RB*8] + |->BC_TSETS_Z: // RB = GCtab *, RC = GCstr *, refetches PC_RA. + | mov RA, TAB:RB->hmask + | and RA, STR:RC->sid + | imul RA, #NODE + | mov byte TAB:RB->nomm, 0 // Clear metamethod cache. + | add NODE:RA, TAB:RB->node + |1: + | cmp dword NODE:RA->key.it, LJ_TSTR + | jne >5 + | cmp dword NODE:RA->key.gcr, STR:RC + | jne >5 + | // Ok, key found. Assumes: offsetof(Node, val) == 0 + | cmp dword [RA+4], LJ_TNIL + | je >4 // Previous value is nil? + |2: + | test byte TAB:RB->marked, LJ_GC_BLACK // isblack(table) + | jnz >7 + |3: // Set node value. + | movzx RC, PC_RA + |.if X64 + | mov RBa, [BASE+RC*8] + | mov [RA], RBa + |.else + | mov RB, [BASE+RC*8+4] + | mov RC, [BASE+RC*8] + | mov [RA+4], RB + | mov [RA], RC + |.endif + | ins_next + | + |4: // Check for __newindex if previous value is nil. + | cmp dword TAB:RB->metatable, 0 // Shouldn't overwrite RA for fastpath. + | jz <2 + | mov TMP1, RA // Save RA. + | mov TAB:RA, TAB:RB->metatable + | test byte TAB:RA->nomm, 1<vmeta_tsets // 'no __newindex' flag NOT set: check. + | mov RA, TMP1 // Restore RA. + | jmp <2 + | + |5: // Follow hash chain. + | mov NODE:RA, NODE:RA->next + | test NODE:RA, NODE:RA + | jnz <1 + | // End of hash chain: key not found, add a new one. + | + | // But check for __newindex first. + | mov TAB:RA, TAB:RB->metatable + | test TAB:RA, TAB:RA + | jz >6 // No metatable: continue. + | test byte TAB:RA->nomm, 1<vmeta_tsets // 'no __newindex' flag NOT set: check. + |6: + | mov TMP1, STR:RC + | mov TMP2, LJ_TSTR + | mov TMP3, TAB:RB // Save TAB:RB for us. + |.if X64 + | mov L:CARG1d, SAVE_L + | mov L:CARG1d->base, BASE + | lea CARG3, TMP1 + | mov CARG2d, TAB:RB + | mov L:RB, L:CARG1d + |.else + | lea RC, TMP1 // Store temp. TValue in TMP1/TMP2. + | mov ARG2, TAB:RB + | mov L:RB, SAVE_L + | mov ARG3, RC + | mov ARG1, L:RB + | mov L:RB->base, BASE + |.endif + | mov SAVE_PC, PC + | call extern lj_tab_newkey // (lua_State *L, GCtab *t, TValue *k) + | // Handles write barrier for the new key. TValue * returned in eax (RC). + | mov BASE, L:RB->base + | mov TAB:RB, TMP3 // Need TAB:RB for barrier. + | mov RA, eax + | jmp <2 // Must check write barrier for value. + | + |7: // Possible table write barrier for the value. Skip valiswhite check. + | barrierback TAB:RB, RC // Destroys STR:RC. + | jmp <3 + break; + case BC_TSETB: + | ins_ABC // RA = src, RB = table, RC = byte literal + | checktab RB, ->vmeta_tsetb + | mov TAB:RB, [BASE+RB*8] + | cmp RC, TAB:RB->asize + | jae ->vmeta_tsetb + | shl RC, 3 + | add RC, TAB:RB->array + | cmp dword [RC+4], LJ_TNIL + | je >3 // Previous value is nil? + |1: + | test byte TAB:RB->marked, LJ_GC_BLACK // isblack(table) + | jnz >7 + |2: // Set array slot. + |.if X64 + | mov RAa, [BASE+RA*8] + | mov [RC], RAa + |.else + | mov RB, [BASE+RA*8+4] + | mov RA, [BASE+RA*8] + | mov [RC+4], RB + | mov [RC], RA + |.endif + | ins_next + | + |3: // Check for __newindex if previous value is nil. + | cmp dword TAB:RB->metatable, 0 // Shouldn't overwrite RA for fastpath. + | jz <1 + | mov TAB:RA, TAB:RB->metatable + | test byte TAB:RA->nomm, 1<vmeta_tsetb // 'no __newindex' flag NOT set: check. + | movzx RA, PC_RA // Restore RA. + | jmp <1 + | + |7: // Possible table write barrier for the value. Skip valiswhite check. + | barrierback TAB:RB, RA + | movzx RA, PC_RA // Restore RA. + | jmp <2 + break; + case BC_TSETR: + | ins_ABC // RA = src, RB = table, RC = key + | mov TAB:RB, [BASE+RB*8] + |.if DUALNUM + | mov RC, dword [BASE+RC*8] + |.else + | cvttsd2si RC, qword [BASE+RC*8] + |.endif + | test byte TAB:RB->marked, LJ_GC_BLACK // isblack(table) + | jnz >7 + |2: + | cmp RC, TAB:RB->asize + | jae ->vmeta_tsetr + | shl RC, 3 + | add RC, TAB:RB->array + | // Set array slot. + |->BC_TSETR_Z: + |.if X64 + | mov RBa, [BASE+RA*8] + | mov [RC], RBa + |.else + | mov RB, [BASE+RA*8+4] + | mov RA, [BASE+RA*8] + | mov [RC+4], RB + | mov [RC], RA + |.endif + | ins_next + | + |7: // Possible table write barrier for the value. Skip valiswhite check. + | barrierback TAB:RB, RA + | movzx RA, PC_RA // Restore RA. + | jmp <2 + break; + + case BC_TSETM: + | ins_AD // RA = base (table at base-1), RD = num const (start index) + | mov TMP1, KBASE // Need one more free register. + | mov KBASE, dword [KBASE+RD*8] // Integer constant is in lo-word. + |1: + | lea RA, [BASE+RA*8] + | mov TAB:RB, [RA-8] // Guaranteed to be a table. + | test byte TAB:RB->marked, LJ_GC_BLACK // isblack(table) + | jnz >7 + |2: + | mov RD, MULTRES + | sub RD, 1 + | jz >4 // Nothing to copy? + | add RD, KBASE // Compute needed size. + | cmp RD, TAB:RB->asize + | ja >5 // Doesn't fit into array part? + | sub RD, KBASE + | shl KBASE, 3 + | add KBASE, TAB:RB->array + |3: // Copy result slots to table. + |.if X64 + | mov RBa, [RA] + | add RA, 8 + | mov [KBASE], RBa + |.else + | mov RB, [RA] + | mov [KBASE], RB + | mov RB, [RA+4] + | add RA, 8 + | mov [KBASE+4], RB + |.endif + | add KBASE, 8 + | sub RD, 1 + | jnz <3 + |4: + | mov KBASE, TMP1 + | ins_next + | + |5: // Need to resize array part. + |.if X64 + | mov L:CARG1d, SAVE_L + | mov L:CARG1d->base, BASE // Caveat: CARG2d/CARG3d may be BASE. + | mov CARG2d, TAB:RB + | mov CARG3d, RD + | mov L:RB, L:CARG1d + |.else + | mov ARG2, TAB:RB + | mov L:RB, SAVE_L + | mov L:RB->base, BASE + | mov ARG3, RD + | mov ARG1, L:RB + |.endif + | mov SAVE_PC, PC + | call extern lj_tab_reasize // (lua_State *L, GCtab *t, int nasize) + | mov BASE, L:RB->base + | movzx RA, PC_RA // Restore RA. + | jmp <1 // Retry. + | + |7: // Possible table write barrier for any value. Skip valiswhite check. + | barrierback TAB:RB, RD + | jmp <2 + break; + + /* -- Calls and vararg handling ----------------------------------------- */ + + case BC_CALL: case BC_CALLM: + | ins_A_C // RA = base, (RB = nresults+1,) RC = nargs+1 | extra_nargs + if (op == BC_CALLM) { + | add NARGS:RD, MULTRES + } + | cmp dword [BASE+RA*8+4], LJ_TFUNC + | mov LFUNC:RB, [BASE+RA*8] + | jne ->vmeta_call_ra + | lea BASE, [BASE+RA*8+8] + | ins_call + break; + + case BC_CALLMT: + | ins_AD // RA = base, RD = extra_nargs + | add NARGS:RD, MULTRES + | // Fall through. Assumes BC_CALLT follows and ins_AD is a no-op. + break; + case BC_CALLT: + | ins_AD // RA = base, RD = nargs+1 + | lea RA, [BASE+RA*8+8] + | mov KBASE, BASE // Use KBASE for move + vmeta_call hint. + | mov LFUNC:RB, [RA-8] + | cmp dword [RA-4], LJ_TFUNC + | jne ->vmeta_call + |->BC_CALLT_Z: + | mov PC, [BASE-4] + | test PC, FRAME_TYPE + | jnz >7 + |1: + | mov [BASE-8], LFUNC:RB // Copy function down, reloaded below. + | mov MULTRES, NARGS:RD + | sub NARGS:RD, 1 + | jz >3 + |2: // Move args down. + |.if X64 + | mov RBa, [RA] + | add RA, 8 + | mov [KBASE], RBa + |.else + | mov RB, [RA] + | mov [KBASE], RB + | mov RB, [RA+4] + | add RA, 8 + | mov [KBASE+4], RB + |.endif + | add KBASE, 8 + | sub NARGS:RD, 1 + | jnz <2 + | + | mov LFUNC:RB, [BASE-8] + |3: + | mov NARGS:RD, MULTRES + | cmp byte LFUNC:RB->ffid, 1 // (> FF_C) Calling a fast function? + | ja >5 + |4: + | ins_callt + | + |5: // Tailcall to a fast function. + | test PC, FRAME_TYPE // Lua frame below? + | jnz <4 + | movzx RA, PC_RA + | not RAa + | mov LFUNC:KBASE, [BASE+RA*8-8] // Need to prepare KBASE. + | mov KBASE, LFUNC:KBASE->pc + | mov KBASE, [KBASE+PC2PROTO(k)] + | jmp <4 + | + |7: // Tailcall from a vararg function. + | sub PC, FRAME_VARG + | test PC, FRAME_TYPEP + | jnz >8 // Vararg frame below? + | sub BASE, PC // Need to relocate BASE/KBASE down. + | mov KBASE, BASE + | mov PC, [BASE-4] + | jmp <1 + |8: + | add PC, FRAME_VARG + | jmp <1 + break; + + case BC_ITERC: + | ins_A // RA = base, (RB = nresults+1,) RC = nargs+1 (2+1) + | lea RA, [BASE+RA*8+8] // fb = base+1 + |.if X64 + | mov RBa, [RA-24] // Copy state. fb[0] = fb[-3]. + | mov RCa, [RA-16] // Copy control var. fb[1] = fb[-2]. + | mov [RA], RBa + | mov [RA+8], RCa + |.else + | mov RB, [RA-24] // Copy state. fb[0] = fb[-3]. + | mov RC, [RA-20] + | mov [RA], RB + | mov [RA+4], RC + | mov RB, [RA-16] // Copy control var. fb[1] = fb[-2]. + | mov RC, [RA-12] + | mov [RA+8], RB + | mov [RA+12], RC + |.endif + | mov LFUNC:RB, [RA-32] // Copy callable. fb[-1] = fb[-4] + | mov RC, [RA-28] + | mov [RA-8], LFUNC:RB + | mov [RA-4], RC + | cmp RC, LJ_TFUNC // Handle like a regular 2-arg call. + | mov NARGS:RD, 2+1 + | jne ->vmeta_call + | mov BASE, RA + | ins_call + break; + + case BC_ITERN: + |.if JIT + | hotloop RB + |.endif + |->vm_IITERN: + | ins_A // RA = base, (RB = nresults+1, RC = nargs+1 (2+1)) + | mov TMP1, KBASE // Need two more free registers. + | mov TMP2, DISPATCH + | mov TAB:RB, [BASE+RA*8-16] + | mov RC, [BASE+RA*8-8] // Get index from control var. + | mov DISPATCH, TAB:RB->asize + | add PC, 4 + | mov KBASE, TAB:RB->array + |1: // Traverse array part. + | cmp RC, DISPATCH; jae >5 // Index points after array part? + | cmp dword [KBASE+RC*8+4], LJ_TNIL; je >4 + |.if DUALNUM + | mov dword [BASE+RA*8+4], LJ_TISNUM + | mov dword [BASE+RA*8], RC + |.else + | cvtsi2sd xmm0, RC + |.endif + | // Copy array slot to returned value. + |.if X64 + | mov RBa, [KBASE+RC*8] + | mov [BASE+RA*8+8], RBa + |.else + | mov RB, [KBASE+RC*8+4] + | mov [BASE+RA*8+12], RB + | mov RB, [KBASE+RC*8] + | mov [BASE+RA*8+8], RB + |.endif + | add RC, 1 + | // Return array index as a numeric key. + |.if DUALNUM + | // See above. + |.else + | movsd qword [BASE+RA*8], xmm0 + |.endif + | mov [BASE+RA*8-8], RC // Update control var. + |2: + | movzx RD, PC_RD // Get target from ITERL. + | branchPC RD + |3: + | mov DISPATCH, TMP2 + | mov KBASE, TMP1 + | ins_next + | + |4: // Skip holes in array part. + | add RC, 1 + | jmp <1 + | + |5: // Traverse hash part. + | sub RC, DISPATCH + |6: + | cmp RC, TAB:RB->hmask; ja <3 // End of iteration? Branch to ITERL+1. + | imul KBASE, RC, #NODE + | add NODE:KBASE, TAB:RB->node + | cmp dword NODE:KBASE->val.it, LJ_TNIL; je >7 + | lea DISPATCH, [RC+DISPATCH+1] + | // Copy key and value from hash slot. + |.if X64 + | mov RBa, NODE:KBASE->key + | mov RCa, NODE:KBASE->val + | mov [BASE+RA*8], RBa + | mov [BASE+RA*8+8], RCa + |.else + | mov RB, NODE:KBASE->key.gcr + | mov RC, NODE:KBASE->key.it + | mov [BASE+RA*8], RB + | mov [BASE+RA*8+4], RC + | mov RB, NODE:KBASE->val.gcr + | mov RC, NODE:KBASE->val.it + | mov [BASE+RA*8+8], RB + | mov [BASE+RA*8+12], RC + |.endif + | mov [BASE+RA*8-8], DISPATCH + | jmp <2 + | + |7: // Skip holes in hash part. + | add RC, 1 + | jmp <6 + break; + + case BC_ISNEXT: + | ins_AD // RA = base, RD = target (points to ITERN) + | cmp dword [BASE+RA*8-20], LJ_TFUNC; jne >5 + | mov CFUNC:RB, [BASE+RA*8-24] + | cmp dword [BASE+RA*8-12], LJ_TTAB; jne >5 + | cmp dword [BASE+RA*8-4], LJ_TNIL; jne >5 + | cmp byte CFUNC:RB->ffid, FF_next_N; jne >5 + | branchPC RD + | mov dword [BASE+RA*8-8], 0 // Initialize control var. + | mov dword [BASE+RA*8-4], LJ_KEYINDEX + |1: + | ins_next + |5: // Despecialize bytecode if any of the checks fail. + | mov PC_OP, BC_JMP + | branchPC RD + |.if JIT + | cmp byte [PC], BC_ITERN + | jne >6 + |.endif + | mov byte [PC], BC_ITERC + | jmp <1 + |.if JIT + |6: // Unpatch JLOOP. + | mov RA, [DISPATCH+DISPATCH_J(trace)] + | movzx RC, word [PC+2] + | mov TRACE:RA, [RA+RC*4] + | mov eax, TRACE:RA->startins + | mov al, BC_ITERC + | mov dword [PC], eax + | jmp <1 + |.endif + break; + + case BC_VARG: + | ins_ABC // RA = base, RB = nresults+1, RC = numparams + | mov TMP1, KBASE // Need one more free register. + | lea KBASE, [BASE+RC*8+(8+FRAME_VARG)] + | lea RA, [BASE+RA*8] + | sub KBASE, [BASE-4] + | // Note: KBASE may now be even _above_ BASE if nargs was < numparams. + | test RB, RB + | jz >5 // Copy all varargs? + | lea RB, [RA+RB*8-8] + | cmp KBASE, BASE // No vararg slots? + | jnb >2 + |1: // Copy vararg slots to destination slots. + |.if X64 + | mov RCa, [KBASE-8] + | add KBASE, 8 + | mov [RA], RCa + |.else + | mov RC, [KBASE-8] + | mov [RA], RC + | mov RC, [KBASE-4] + | add KBASE, 8 + | mov [RA+4], RC + |.endif + | add RA, 8 + | cmp RA, RB // All destination slots filled? + | jnb >3 + | cmp KBASE, BASE // No more vararg slots? + | jb <1 + |2: // Fill up remainder with nil. + | mov dword [RA+4], LJ_TNIL + | add RA, 8 + | cmp RA, RB + | jb <2 + |3: + | mov KBASE, TMP1 + | ins_next + | + |5: // Copy all varargs. + | mov MULTRES, 1 // MULTRES = 0+1 + | mov RC, BASE + | sub RC, KBASE + | jbe <3 // No vararg slots? + | mov RB, RC + | shr RB, 3 + | add RB, 1 + | mov MULTRES, RB // MULTRES = #varargs+1 + | mov L:RB, SAVE_L + | add RC, RA + | cmp RC, L:RB->maxstack + | ja >7 // Need to grow stack? + |6: // Copy all vararg slots. + |.if X64 + | mov RCa, [KBASE-8] + | add KBASE, 8 + | mov [RA], RCa + |.else + | mov RC, [KBASE-8] + | mov [RA], RC + | mov RC, [KBASE-4] + | add KBASE, 8 + | mov [RA+4], RC + |.endif + | add RA, 8 + | cmp KBASE, BASE // No more vararg slots? + | jb <6 + | jmp <3 + | + |7: // Grow stack for varargs. + | mov L:RB->base, BASE + | mov L:RB->top, RA + | mov SAVE_PC, PC + | sub KBASE, BASE // Need delta, because BASE may change. + | mov FCARG2, MULTRES + | sub FCARG2, 1 + | mov FCARG1, L:RB + | call extern lj_state_growstack@8 // (lua_State *L, int n) + | mov BASE, L:RB->base + | mov RA, L:RB->top + | add KBASE, BASE + | jmp <6 + break; + + /* -- Returns ----------------------------------------------------------- */ + + case BC_RETM: + | ins_AD // RA = results, RD = extra_nresults + | add RD, MULTRES // MULTRES >=1, so RD >=1. + | // Fall through. Assumes BC_RET follows and ins_AD is a no-op. + break; + + case BC_RET: case BC_RET0: case BC_RET1: + | ins_AD // RA = results, RD = nresults+1 + if (op != BC_RET0) { + | shl RA, 3 + } + |1: + | mov PC, [BASE-4] + | mov MULTRES, RD // Save nresults+1. + | test PC, FRAME_TYPE // Check frame type marker. + | jnz >7 // Not returning to a fixarg Lua func? + switch (op) { + case BC_RET: + |->BC_RET_Z: + | mov KBASE, BASE // Use KBASE for result move. + | sub RD, 1 + | jz >3 + |2: // Move results down. + |.if X64 + | mov RBa, [KBASE+RA] + | mov [KBASE-8], RBa + |.else + | mov RB, [KBASE+RA] + | mov [KBASE-8], RB + | mov RB, [KBASE+RA+4] + | mov [KBASE-4], RB + |.endif + | add KBASE, 8 + | sub RD, 1 + | jnz <2 + |3: + | mov RD, MULTRES // Note: MULTRES may be >255. + | movzx RB, PC_RB // So cannot compare with RDL! + |5: + | cmp RB, RD // More results expected? + | ja >6 + break; + case BC_RET1: + |.if X64 + | mov RBa, [BASE+RA] + | mov [BASE-8], RBa + |.else + | mov RB, [BASE+RA+4] + | mov [BASE-4], RB + | mov RB, [BASE+RA] + | mov [BASE-8], RB + |.endif + /* fallthrough */ + case BC_RET0: + |5: + | cmp PC_RB, RDL // More results expected? + | ja >6 + default: + break; + } + | movzx RA, PC_RA + | not RAa // Note: ~RA = -(RA+1) + | lea BASE, [BASE+RA*8] // base = base - (RA+1)*8 + | mov LFUNC:KBASE, [BASE-8] + | mov KBASE, LFUNC:KBASE->pc + | mov KBASE, [KBASE+PC2PROTO(k)] + | ins_next + | + |6: // Fill up results with nil. + if (op == BC_RET) { + | mov dword [KBASE-4], LJ_TNIL // Note: relies on shifted base. + | add KBASE, 8 + } else { + | mov dword [BASE+RD*8-12], LJ_TNIL + } + | add RD, 1 + | jmp <5 + | + |7: // Non-standard return case. + | lea RB, [PC-FRAME_VARG] + | test RB, FRAME_TYPEP + | jnz ->vm_return + | // Return from vararg function: relocate BASE down and RA up. + | sub BASE, RB + if (op != BC_RET0) { + | add RA, RB + } + | jmp <1 + break; + + /* -- Loops and branches ------------------------------------------------ */ + + |.define FOR_IDX, [RA]; .define FOR_TIDX, dword [RA+4] + |.define FOR_STOP, [RA+8]; .define FOR_TSTOP, dword [RA+12] + |.define FOR_STEP, [RA+16]; .define FOR_TSTEP, dword [RA+20] + |.define FOR_EXT, [RA+24]; .define FOR_TEXT, dword [RA+28] + + case BC_FORL: + |.if JIT + | hotloop RB + |.endif + | // Fall through. Assumes BC_IFORL follows and ins_AJ is a no-op. + break; + + case BC_JFORI: + case BC_JFORL: +#if !LJ_HASJIT + break; +#endif + case BC_FORI: + case BC_IFORL: + vk = (op == BC_IFORL || op == BC_JFORL); + | ins_AJ // RA = base, RD = target (after end of loop or start of loop) + | lea RA, [BASE+RA*8] + if (LJ_DUALNUM) { + | cmp FOR_TIDX, LJ_TISNUM; jne >9 + if (!vk) { + | cmp FOR_TSTOP, LJ_TISNUM; jne ->vmeta_for + | cmp FOR_TSTEP, LJ_TISNUM; jne ->vmeta_for + | mov RB, dword FOR_IDX + | cmp dword FOR_STEP, 0; jl >5 + } else { +#ifdef LUA_USE_ASSERT + | cmp FOR_TSTOP, LJ_TISNUM; jne ->assert_bad_for_arg_type + | cmp FOR_TSTEP, LJ_TISNUM; jne ->assert_bad_for_arg_type +#endif + | mov RB, dword FOR_STEP + | test RB, RB; js >5 + | add RB, dword FOR_IDX; jo >1 + | mov dword FOR_IDX, RB + } + | cmp RB, dword FOR_STOP + | mov FOR_TEXT, LJ_TISNUM + | mov dword FOR_EXT, RB + if (op == BC_FORI) { + | jle >7 + |1: + |6: + | branchPC RD + } else if (op == BC_JFORI) { + | branchPC RD + | movzx RD, PC_RD + | jle =>BC_JLOOP + |1: + |6: + } else if (op == BC_IFORL) { + | jg >7 + |6: + | branchPC RD + |1: + } else { + | jle =>BC_JLOOP + |1: + |6: + } + |7: + | ins_next + | + |5: // Invert check for negative step. + if (vk) { + | add RB, dword FOR_IDX; jo <1 + | mov dword FOR_IDX, RB + } + | cmp RB, dword FOR_STOP + | mov FOR_TEXT, LJ_TISNUM + | mov dword FOR_EXT, RB + if (op == BC_FORI) { + | jge <7 + } else if (op == BC_JFORI) { + | branchPC RD + | movzx RD, PC_RD + | jge =>BC_JLOOP + } else if (op == BC_IFORL) { + | jl <7 + } else { + | jge =>BC_JLOOP + } + | jmp <6 + |9: // Fallback to FP variant. + } else if (!vk) { + | cmp FOR_TIDX, LJ_TISNUM + } + if (!vk) { + | jae ->vmeta_for + | cmp FOR_TSTOP, LJ_TISNUM; jae ->vmeta_for + } else { +#ifdef LUA_USE_ASSERT + | cmp FOR_TSTOP, LJ_TISNUM; jae ->assert_bad_for_arg_type + | cmp FOR_TSTEP, LJ_TISNUM; jae ->assert_bad_for_arg_type +#endif + } + | mov RB, FOR_TSTEP // Load type/hiword of for step. + if (!vk) { + | cmp RB, LJ_TISNUM; jae ->vmeta_for + } + | movsd xmm0, qword FOR_IDX + | movsd xmm1, qword FOR_STOP + if (vk) { + | addsd xmm0, qword FOR_STEP + | movsd qword FOR_IDX, xmm0 + | test RB, RB; js >3 + } else { + | jl >3 + } + | ucomisd xmm1, xmm0 + |1: + | movsd qword FOR_EXT, xmm0 + if (op == BC_FORI) { + |.if DUALNUM + | jnb <7 + |.else + | jnb >2 + | branchPC RD + |.endif + } else if (op == BC_JFORI) { + | branchPC RD + | movzx RD, PC_RD + | jnb =>BC_JLOOP + } else if (op == BC_IFORL) { + |.if DUALNUM + | jb <7 + |.else + | jb >2 + | branchPC RD + |.endif + } else { + | jnb =>BC_JLOOP + } + |.if DUALNUM + | jmp <6 + |.else + |2: + | ins_next + |.endif + | + |3: // Invert comparison if step is negative. + | ucomisd xmm0, xmm1 + | jmp <1 + break; + + case BC_ITERL: + |.if JIT + | hotloop RB + |.endif + | // Fall through. Assumes BC_IITERL follows and ins_AJ is a no-op. + break; + + case BC_JITERL: +#if !LJ_HASJIT + break; +#endif + case BC_IITERL: + | ins_AJ // RA = base, RD = target + | lea RA, [BASE+RA*8] + | mov RB, [RA+4] + | cmp RB, LJ_TNIL; je >1 // Stop if iterator returned nil. + if (op == BC_JITERL) { + | mov [RA-4], RB + | mov RB, [RA] + | mov [RA-8], RB + | jmp =>BC_JLOOP + } else { + | branchPC RD // Otherwise save control var + branch. + | mov RD, [RA] + | mov [RA-4], RB + | mov [RA-8], RD + } + |1: + | ins_next + break; + + case BC_LOOP: + | ins_A // RA = base, RD = target (loop extent) + | // Note: RA/RD is only used by trace recorder to determine scope/extent + | // This opcode does NOT jump, it's only purpose is to detect a hot loop. + |.if JIT + | hotloop RB + |.endif + | // Fall through. Assumes BC_ILOOP follows and ins_A is a no-op. + break; + + case BC_ILOOP: + | ins_A // RA = base, RD = target (loop extent) + | ins_next + break; + + case BC_JLOOP: + |.if JIT + | ins_AD // RA = base (ignored), RD = traceno + | mov RA, [DISPATCH+DISPATCH_J(trace)] + | mov TRACE:RD, [RA+RD*4] + | mov RDa, TRACE:RD->mcode + | mov L:RB, SAVE_L + | mov [DISPATCH+DISPATCH_GL(jit_base)], BASE + | mov [DISPATCH+DISPATCH_GL(tmpbuf.L)], L:RB + | // Save additional callee-save registers only used in compiled code. + |.if X64WIN + | mov TMPQ, r12 + | mov TMPa, r13 + | mov CSAVE_4, r14 + | mov CSAVE_3, r15 + | mov RAa, rsp + | sub rsp, 9*16+4*8 + | movdqa [RAa], xmm6 + | movdqa [RAa-1*16], xmm7 + | movdqa [RAa-2*16], xmm8 + | movdqa [RAa-3*16], xmm9 + | movdqa [RAa-4*16], xmm10 + | movdqa [RAa-5*16], xmm11 + | movdqa [RAa-6*16], xmm12 + | movdqa [RAa-7*16], xmm13 + | movdqa [RAa-8*16], xmm14 + | movdqa [RAa-9*16], xmm15 + |.elif X64 + | mov TMPQ, r12 + | mov TMPa, r13 + | sub rsp, 16 + |.endif + | jmp RDa + |.endif + break; + + case BC_JMP: + | ins_AJ // RA = unused, RD = target + | branchPC RD + | ins_next + break; + + /* -- Function headers -------------------------------------------------- */ + + /* + ** Reminder: A function may be called with func/args above L->maxstack, + ** i.e. occupying EXTRA_STACK slots. And vmeta_call may add one extra slot, + ** too. This means all FUNC* ops (including fast functions) must check + ** for stack overflow _before_ adding more slots! + */ + + case BC_FUNCF: + |.if JIT + | hotcall RB + |.endif + case BC_FUNCV: /* NYI: compiled vararg functions. */ + | // Fall through. Assumes BC_IFUNCF/BC_IFUNCV follow and ins_AD is a no-op. + break; + + case BC_JFUNCF: +#if !LJ_HASJIT + break; +#endif + case BC_IFUNCF: + | ins_AD // BASE = new base, RA = framesize, RD = nargs+1 + | mov KBASE, [PC-4+PC2PROTO(k)] + | mov L:RB, SAVE_L + | lea RA, [BASE+RA*8] // Top of frame. + | cmp RA, L:RB->maxstack + | ja ->vm_growstack_f + | movzx RA, byte [PC-4+PC2PROTO(numparams)] + | cmp NARGS:RD, RA // Check for missing parameters. + | jbe >3 + |2: + if (op == BC_JFUNCF) { + | movzx RD, PC_RD + | jmp =>BC_JLOOP + } else { + | ins_next + } + | + |3: // Clear missing parameters. + | mov dword [BASE+NARGS:RD*8-4], LJ_TNIL + | add NARGS:RD, 1 + | cmp NARGS:RD, RA + | jbe <3 + | jmp <2 + break; + + case BC_JFUNCV: +#if !LJ_HASJIT + break; +#endif + | int3 // NYI: compiled vararg functions + break; /* NYI: compiled vararg functions. */ + + case BC_IFUNCV: + | ins_AD // BASE = new base, RA = framesize, RD = nargs+1 + | lea RB, [NARGS:RD*8+FRAME_VARG] + | lea RD, [BASE+NARGS:RD*8] + | mov LFUNC:KBASE, [BASE-8] + | mov [RD-4], RB // Store delta + FRAME_VARG. + | mov [RD-8], LFUNC:KBASE // Store copy of LFUNC. + | mov L:RB, SAVE_L + | lea RA, [RD+RA*8] + | cmp RA, L:RB->maxstack + | ja ->vm_growstack_v // Need to grow stack. + | mov RA, BASE + | mov BASE, RD + | movzx RB, byte [PC-4+PC2PROTO(numparams)] + | test RB, RB + | jz >2 + |1: // Copy fixarg slots up to new frame. + | add RA, 8 + | cmp RA, BASE + | jnb >3 // Less args than parameters? + | mov KBASE, [RA-8] + | mov [RD], KBASE + | mov KBASE, [RA-4] + | mov [RD+4], KBASE + | add RD, 8 + | mov dword [RA-4], LJ_TNIL // Clear old fixarg slot (help the GC). + | sub RB, 1 + | jnz <1 + |2: + if (op == BC_JFUNCV) { + | movzx RD, PC_RD + | jmp =>BC_JLOOP + } else { + | mov KBASE, [PC-4+PC2PROTO(k)] + | ins_next + } + | + |3: // Clear missing parameters. + | mov dword [RD+4], LJ_TNIL + | add RD, 8 + | sub RB, 1 + | jnz <3 + | jmp <2 + break; + + case BC_FUNCC: + case BC_FUNCCW: + | ins_AD // BASE = new base, RA = ins RA|RD (unused), RD = nargs+1 + | mov CFUNC:RB, [BASE-8] + | mov KBASEa, CFUNC:RB->f + | mov L:RB, SAVE_L + | lea RD, [BASE+NARGS:RD*8-8] + | mov L:RB->base, BASE + | lea RA, [RD+8*LUA_MINSTACK] + | cmp RA, L:RB->maxstack + | mov L:RB->top, RD + if (op == BC_FUNCC) { + |.if X64 + | mov CARG1d, L:RB // Caveat: CARG1d may be RA. + |.else + | mov ARG1, L:RB + |.endif + } else { + |.if X64 + | mov CARG2, KBASEa + | mov CARG1d, L:RB // Caveat: CARG1d may be RA. + |.else + | mov ARG2, KBASEa + | mov ARG1, L:RB + |.endif + } + | ja ->vm_growstack_c // Need to grow stack. + | set_vmstate C + if (op == BC_FUNCC) { + | call KBASEa // (lua_State *L) + } else { + | // (lua_State *L, lua_CFunction f) + | call aword [DISPATCH+DISPATCH_GL(wrapf)] + } + | // nresults returned in eax (RD). + | mov BASE, L:RB->base + | mov [DISPATCH+DISPATCH_GL(cur_L)], L:RB + | set_vmstate INTERP + | lea RA, [BASE+RD*8] + | neg RA + | add RA, L:RB->top // RA = (L->top-(L->base+nresults))*8 + | mov PC, [BASE-4] // Fetch PC of caller. + | jmp ->vm_returnc + break; + + /* ---------------------------------------------------------------------- */ + + default: + fprintf(stderr, "Error: undefined opcode BC_%s\n", bc_names[op]); + exit(2); + break; + } +} + +static int build_backend(BuildCtx *ctx) +{ + int op; + dasm_growpc(Dst, BC__MAX); + build_subroutines(ctx); + |.code_op + for (op = 0; op < BC__MAX; op++) + build_ins(ctx, (BCOp)op, op); + return BC__MAX; +} + +/* Emit pseudo frame-info for all assembler functions. */ +static void emit_asm_debug(BuildCtx *ctx) +{ + int fcofs = (int)((uint8_t *)ctx->glob[GLOB_vm_ffi_call] - ctx->code); +#if LJ_64 +#define SZPTR "8" +#define BSZPTR "3" +#define REG_SP "0x7" +#define REG_RA "0x10" +#else +#define SZPTR "4" +#define BSZPTR "2" +#define REG_SP "0x4" +#define REG_RA "0x8" +#endif + switch (ctx->mode) { + case BUILD_elfasm: + fprintf(ctx->fp, "\t.section .debug_frame,\"\",@progbits\n"); + fprintf(ctx->fp, + ".Lframe0:\n" + "\t.long .LECIE0-.LSCIE0\n" + ".LSCIE0:\n" + "\t.long 0xffffffff\n" + "\t.byte 0x1\n" + "\t.string \"\"\n" + "\t.uleb128 0x1\n" + "\t.sleb128 -" SZPTR "\n" + "\t.byte " REG_RA "\n" + "\t.byte 0xc\n\t.uleb128 " REG_SP "\n\t.uleb128 " SZPTR "\n" + "\t.byte 0x80+" REG_RA "\n\t.uleb128 0x1\n" + "\t.align " SZPTR "\n" + ".LECIE0:\n\n"); + fprintf(ctx->fp, + ".LSFDE0:\n" + "\t.long .LEFDE0-.LASFDE0\n" + ".LASFDE0:\n" + "\t.long .Lframe0\n" +#if LJ_64 + "\t.quad .Lbegin\n" + "\t.quad %d\n" + "\t.byte 0xe\n\t.uleb128 %d\n" /* def_cfa_offset */ + "\t.byte 0x86\n\t.uleb128 0x2\n" /* offset rbp */ + "\t.byte 0x83\n\t.uleb128 0x3\n" /* offset rbx */ + "\t.byte 0x8f\n\t.uleb128 0x4\n" /* offset r15 */ + "\t.byte 0x8e\n\t.uleb128 0x5\n" /* offset r14 */ +#if LJ_NO_UNWIND + "\t.byte 0x8d\n\t.uleb128 0x6\n" /* offset r13 */ + "\t.byte 0x8c\n\t.uleb128 0x7\n" /* offset r12 */ +#endif +#else + "\t.long .Lbegin\n" + "\t.long %d\n" + "\t.byte 0xe\n\t.uleb128 %d\n" /* def_cfa_offset */ + "\t.byte 0x85\n\t.uleb128 0x2\n" /* offset ebp */ + "\t.byte 0x87\n\t.uleb128 0x3\n" /* offset edi */ + "\t.byte 0x86\n\t.uleb128 0x4\n" /* offset esi */ + "\t.byte 0x83\n\t.uleb128 0x5\n" /* offset ebx */ +#endif + "\t.align " SZPTR "\n" + ".LEFDE0:\n\n", fcofs, CFRAME_SIZE); +#if LJ_HASFFI + fprintf(ctx->fp, + ".LSFDE1:\n" + "\t.long .LEFDE1-.LASFDE1\n" + ".LASFDE1:\n" + "\t.long .Lframe0\n" +#if LJ_64 + "\t.quad lj_vm_ffi_call\n" + "\t.quad %d\n" + "\t.byte 0xe\n\t.uleb128 16\n" /* def_cfa_offset */ + "\t.byte 0x86\n\t.uleb128 0x2\n" /* offset rbp */ + "\t.byte 0xd\n\t.uleb128 0x6\n" /* def_cfa_register rbp */ + "\t.byte 0x83\n\t.uleb128 0x3\n" /* offset rbx */ +#else + "\t.long lj_vm_ffi_call\n" + "\t.long %d\n" + "\t.byte 0xe\n\t.uleb128 8\n" /* def_cfa_offset */ + "\t.byte 0x85\n\t.uleb128 0x2\n" /* offset ebp */ + "\t.byte 0xd\n\t.uleb128 0x5\n" /* def_cfa_register ebp */ + "\t.byte 0x83\n\t.uleb128 0x3\n" /* offset ebx */ +#endif + "\t.align " SZPTR "\n" + ".LEFDE1:\n\n", (int)ctx->codesz - fcofs); +#endif +#if !LJ_NO_UNWIND +#if LJ_TARGET_SOLARIS +#if LJ_64 + fprintf(ctx->fp, "\t.section .eh_frame,\"a\",@unwind\n"); +#else + fprintf(ctx->fp, "\t.section .eh_frame,\"aw\",@progbits\n"); +#endif +#else + fprintf(ctx->fp, "\t.section .eh_frame,\"a\",@progbits\n"); +#endif + fprintf(ctx->fp, + ".Lframe1:\n" + "\t.long .LECIE1-.LSCIE1\n" + ".LSCIE1:\n" + "\t.long 0\n" + "\t.byte 0x1\n" + "\t.string \"zPR\"\n" + "\t.uleb128 0x1\n" + "\t.sleb128 -" SZPTR "\n" + "\t.byte " REG_RA "\n" + "\t.uleb128 6\n" /* augmentation length */ + "\t.byte 0x1b\n" /* pcrel|sdata4 */ + "\t.long lj_err_unwind_dwarf-.\n" + "\t.byte 0x1b\n" /* pcrel|sdata4 */ + "\t.byte 0xc\n\t.uleb128 " REG_SP "\n\t.uleb128 " SZPTR "\n" + "\t.byte 0x80+" REG_RA "\n\t.uleb128 0x1\n" + "\t.align " SZPTR "\n" + ".LECIE1:\n\n"); + fprintf(ctx->fp, + ".LSFDE2:\n" + "\t.long .LEFDE2-.LASFDE2\n" + ".LASFDE2:\n" + "\t.long .LASFDE2-.Lframe1\n" + "\t.long .Lbegin-.\n" + "\t.long %d\n" + "\t.uleb128 0\n" /* augmentation length */ + "\t.byte 0xe\n\t.uleb128 %d\n" /* def_cfa_offset */ +#if LJ_64 + "\t.byte 0x86\n\t.uleb128 0x2\n" /* offset rbp */ + "\t.byte 0x83\n\t.uleb128 0x3\n" /* offset rbx */ + "\t.byte 0x8f\n\t.uleb128 0x4\n" /* offset r15 */ + "\t.byte 0x8e\n\t.uleb128 0x5\n" /* offset r14 */ +#else + "\t.byte 0x85\n\t.uleb128 0x2\n" /* offset ebp */ + "\t.byte 0x87\n\t.uleb128 0x3\n" /* offset edi */ + "\t.byte 0x86\n\t.uleb128 0x4\n" /* offset esi */ + "\t.byte 0x83\n\t.uleb128 0x5\n" /* offset ebx */ +#endif + "\t.align " SZPTR "\n" + ".LEFDE2:\n\n", fcofs, CFRAME_SIZE); +#if LJ_HASFFI + fprintf(ctx->fp, + ".Lframe2:\n" + "\t.long .LECIE2-.LSCIE2\n" + ".LSCIE2:\n" + "\t.long 0\n" + "\t.byte 0x1\n" + "\t.string \"zR\"\n" + "\t.uleb128 0x1\n" + "\t.sleb128 -" SZPTR "\n" + "\t.byte " REG_RA "\n" + "\t.uleb128 1\n" /* augmentation length */ + "\t.byte 0x1b\n" /* pcrel|sdata4 */ + "\t.byte 0xc\n\t.uleb128 " REG_SP "\n\t.uleb128 " SZPTR "\n" + "\t.byte 0x80+" REG_RA "\n\t.uleb128 0x1\n" + "\t.align " SZPTR "\n" + ".LECIE2:\n\n"); + fprintf(ctx->fp, + ".LSFDE3:\n" + "\t.long .LEFDE3-.LASFDE3\n" + ".LASFDE3:\n" + "\t.long .LASFDE3-.Lframe2\n" + "\t.long lj_vm_ffi_call-.\n" + "\t.long %d\n" + "\t.uleb128 0\n" /* augmentation length */ +#if LJ_64 + "\t.byte 0xe\n\t.uleb128 16\n" /* def_cfa_offset */ + "\t.byte 0x86\n\t.uleb128 0x2\n" /* offset rbp */ + "\t.byte 0xd\n\t.uleb128 0x6\n" /* def_cfa_register rbp */ + "\t.byte 0x83\n\t.uleb128 0x3\n" /* offset rbx */ +#else + "\t.byte 0xe\n\t.uleb128 8\n" /* def_cfa_offset */ + "\t.byte 0x85\n\t.uleb128 0x2\n" /* offset ebp */ + "\t.byte 0xd\n\t.uleb128 0x5\n" /* def_cfa_register ebp */ + "\t.byte 0x83\n\t.uleb128 0x3\n" /* offset ebx */ +#endif + "\t.align " SZPTR "\n" + ".LEFDE3:\n\n", (int)ctx->codesz - fcofs); +#endif +#endif + break; +#if !LJ_NO_UNWIND + /* Mental note: never let Apple design an assembler. + ** Or a linker. Or a plastic case. But I digress. + */ + case BUILD_machasm: { +#if LJ_HASFFI + int fcsize = 0; +#endif + int i; + fprintf(ctx->fp, "\t.section __TEXT,__eh_frame,coalesced,no_toc+strip_static_syms+live_support\n"); + fprintf(ctx->fp, + "EH_frame1:\n" + "\t.set L$set$x,LECIEX-LSCIEX\n" + "\t.long L$set$x\n" + "LSCIEX:\n" + "\t.long 0\n" + "\t.byte 0x1\n" + "\t.ascii \"zPR\\0\"\n" + "\t.byte 0x1\n" + "\t.byte 128-" SZPTR "\n" + "\t.byte " REG_RA "\n" + "\t.byte 6\n" /* augmentation length */ + "\t.byte 0x9b\n" /* indirect|pcrel|sdata4 */ +#if LJ_64 + "\t.long _lj_err_unwind_dwarf+4@GOTPCREL\n" + "\t.byte 0x1b\n" /* pcrel|sdata4 */ + "\t.byte 0xc\n\t.byte " REG_SP "\n\t.byte " SZPTR "\n" +#else + "\t.long L_lj_err_unwind_dwarf$non_lazy_ptr-.\n" + "\t.byte 0x1b\n" /* pcrel|sdata4 */ + "\t.byte 0xc\n\t.byte 0x5\n\t.byte 0x4\n" /* esp=5 on 32 bit MACH-O. */ +#endif + "\t.byte 0x80+" REG_RA "\n\t.byte 0x1\n" + "\t.align " BSZPTR "\n" + "LECIEX:\n\n"); + for (i = 0; i < ctx->nsym; i++) { + const char *name = ctx->sym[i].name; + int32_t size = ctx->sym[i+1].ofs - ctx->sym[i].ofs; + if (size == 0) continue; +#if LJ_HASFFI + if (!strcmp(name, "_lj_vm_ffi_call")) { fcsize = size; continue; } +#endif + fprintf(ctx->fp, + "%s.eh:\n" + "LSFDE%d:\n" + "\t.set L$set$%d,LEFDE%d-LASFDE%d\n" + "\t.long L$set$%d\n" + "LASFDE%d:\n" + "\t.long LASFDE%d-EH_frame1\n" + "\t.long %s-.\n" + "\t.long %d\n" + "\t.byte 0\n" /* augmentation length */ + "\t.byte 0xe\n\t.byte %d\n" /* def_cfa_offset */ +#if LJ_64 + "\t.byte 0x86\n\t.byte 0x2\n" /* offset rbp */ + "\t.byte 0x83\n\t.byte 0x3\n" /* offset rbx */ + "\t.byte 0x8f\n\t.byte 0x4\n" /* offset r15 */ + "\t.byte 0x8e\n\t.byte 0x5\n" /* offset r14 */ +#else + "\t.byte 0x84\n\t.byte 0x2\n" /* offset ebp (4 for MACH-O)*/ + "\t.byte 0x87\n\t.byte 0x3\n" /* offset edi */ + "\t.byte 0x86\n\t.byte 0x4\n" /* offset esi */ + "\t.byte 0x83\n\t.byte 0x5\n" /* offset ebx */ +#endif + "\t.align " BSZPTR "\n" + "LEFDE%d:\n\n", + name, i, i, i, i, i, i, i, name, size, CFRAME_SIZE, i); + } +#if LJ_HASFFI + if (fcsize) { + fprintf(ctx->fp, + "EH_frame2:\n" + "\t.set L$set$y,LECIEY-LSCIEY\n" + "\t.long L$set$y\n" + "LSCIEY:\n" + "\t.long 0\n" + "\t.byte 0x1\n" + "\t.ascii \"zR\\0\"\n" + "\t.byte 0x1\n" + "\t.byte 128-" SZPTR "\n" + "\t.byte " REG_RA "\n" + "\t.byte 1\n" /* augmentation length */ +#if LJ_64 + "\t.byte 0x1b\n" /* pcrel|sdata4 */ + "\t.byte 0xc\n\t.byte " REG_SP "\n\t.byte " SZPTR "\n" +#else + "\t.byte 0x1b\n" /* pcrel|sdata4 */ + "\t.byte 0xc\n\t.byte 0x5\n\t.byte 0x4\n" /* esp=5 on 32 bit MACH. */ +#endif + "\t.byte 0x80+" REG_RA "\n\t.byte 0x1\n" + "\t.align " BSZPTR "\n" + "LECIEY:\n\n"); + fprintf(ctx->fp, + "_lj_vm_ffi_call.eh:\n" + "LSFDEY:\n" + "\t.set L$set$yy,LEFDEY-LASFDEY\n" + "\t.long L$set$yy\n" + "LASFDEY:\n" + "\t.long LASFDEY-EH_frame2\n" + "\t.long _lj_vm_ffi_call-.\n" + "\t.long %d\n" + "\t.byte 0\n" /* augmentation length */ +#if LJ_64 + "\t.byte 0xe\n\t.byte 16\n" /* def_cfa_offset */ + "\t.byte 0x86\n\t.byte 0x2\n" /* offset rbp */ + "\t.byte 0xd\n\t.byte 0x6\n" /* def_cfa_register rbp */ + "\t.byte 0x83\n\t.byte 0x3\n" /* offset rbx */ +#else + "\t.byte 0xe\n\t.byte 8\n" /* def_cfa_offset */ + "\t.byte 0x84\n\t.byte 0x2\n" /* offset ebp (4 for MACH-O)*/ + "\t.byte 0xd\n\t.byte 0x4\n" /* def_cfa_register ebp */ + "\t.byte 0x83\n\t.byte 0x3\n" /* offset ebx */ +#endif + "\t.align " BSZPTR "\n" + "LEFDEY:\n\n", fcsize); + } +#endif +#if !LJ_64 + fprintf(ctx->fp, + "\t.non_lazy_symbol_pointer\n" + "L_lj_err_unwind_dwarf$non_lazy_ptr:\n" + ".indirect_symbol _lj_err_unwind_dwarf\n" + ".long 0\n\n"); + fprintf(ctx->fp, "\t.section __IMPORT,__jump_table,symbol_stubs,pure_instructions+self_modifying_code,5\n"); + { + const char *const *xn; + for (xn = ctx->extnames; *xn; xn++) + if (strncmp(*xn, LABEL_PREFIX, sizeof(LABEL_PREFIX)-1)) + fprintf(ctx->fp, "L_%s$stub:\n\t.indirect_symbol _%s\n\t.ascii \"\\364\\364\\364\\364\\364\"\n", *xn, *xn); + } +#endif + fprintf(ctx->fp, ".subsections_via_symbols\n"); + } + break; +#endif + default: /* Difficult for other modes. */ + break; + } +} + diff --git a/fluent-bit/lib/luajit-3065c9/src/xb1build.bat b/fluent-bit/lib/luajit-3065c9/src/xb1build.bat new file mode 100644 index 00000000..2eb68171 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/xb1build.bat @@ -0,0 +1,101 @@ +@rem Script to build LuaJIT with the Xbox One SDK. +@rem Donated to the public domain. +@rem +@rem Open a "Visual Studio .NET Command Prompt" (64 bit host compiler) +@rem Then cd to this directory and run this script. + +@if not defined INCLUDE goto :FAIL +@if not defined DurangoXDK goto :FAIL + +@setlocal +@echo ---- Host compiler ---- +@set LJCOMPILE=cl /nologo /c /MD /O2 /W3 /D_CRT_SECURE_NO_DEPRECATE +@set LJLINK=link /nologo +@set LJMT=mt /nologo +@set DASMDIR=..\dynasm +@set DASM=%DASMDIR%\dynasm.lua +@set ALL_LIB=lib_base.c lib_math.c lib_bit.c lib_string.c lib_table.c lib_io.c lib_os.c lib_package.c lib_debug.c lib_jit.c lib_ffi.c lib_buffer.c + +%LJCOMPILE% host\minilua.c +@if errorlevel 1 goto :BAD +%LJLINK% /out:minilua.exe minilua.obj +@if errorlevel 1 goto :BAD +if exist minilua.exe.manifest^ + %LJMT% -manifest minilua.exe.manifest -outputresource:minilua.exe + +@rem Error out for 64 bit host compiler +@minilua +@if not errorlevel 8 goto :FAIL + +@set DASMFLAGS=-D WIN -D FFI -D P64 +minilua %DASM% -LN %DASMFLAGS% -o host\buildvm_arch.h vm_x64.dasc +@if errorlevel 1 goto :BAD + +%LJCOMPILE% /I "." /I %DASMDIR% /D_DURANGO host\buildvm*.c +@if errorlevel 1 goto :BAD +%LJLINK% /out:buildvm.exe buildvm*.obj +@if errorlevel 1 goto :BAD +if exist buildvm.exe.manifest^ + %LJMT% -manifest buildvm.exe.manifest -outputresource:buildvm.exe + +buildvm -m peobj -o lj_vm.obj +@if errorlevel 1 goto :BAD +buildvm -m bcdef -o lj_bcdef.h %ALL_LIB% +@if errorlevel 1 goto :BAD +buildvm -m ffdef -o lj_ffdef.h %ALL_LIB% +@if errorlevel 1 goto :BAD +buildvm -m libdef -o lj_libdef.h %ALL_LIB% +@if errorlevel 1 goto :BAD +buildvm -m recdef -o lj_recdef.h %ALL_LIB% +@if errorlevel 1 goto :BAD +buildvm -m vmdef -o jit\vmdef.lua %ALL_LIB% +@if errorlevel 1 goto :BAD +buildvm -m folddef -o lj_folddef.h lj_opt_fold.c +@if errorlevel 1 goto :BAD + +@echo ---- Cross compiler ---- + +@set CWD=%cd% +@call "%DurangoXDK%\xdk\DurangoVars.cmd" XDK +@cd /D "%CWD%" +@shift + +@set LJCOMPILE="cl" /nologo /c /W3 /GF /Gm- /GR- /GS- /Gy /openmp- /D_CRT_SECURE_NO_DEPRECATE /D_LIB /D_UNICODE /D_DURANGO +@set LJLIB="lib" /nologo + +@if "%1"=="debug" ( + @shift + @set LJCOMPILE=%LJCOMPILE% /Zi /MDd /Od + @set LJLINK=%LJLINK% /debug +) else ( + @set LJCOMPILE=%LJCOMPILE% /MD /O2 /DNDEBUG +) + +@if "%1"=="amalg" goto :AMALG +%LJCOMPILE% /DLUA_BUILD_AS_DLL lj_*.c lib_*.c +@if errorlevel 1 goto :BAD +%LJLIB% /OUT:luajit.lib lj_*.obj lib_*.obj +@if errorlevel 1 goto :BAD +@goto :NOAMALG +:AMALG +%LJCOMPILE% /DLUA_BUILD_AS_DLL ljamalg.c +@if errorlevel 1 goto :BAD +%LJLIB% /OUT:luajit.lib ljamalg.obj lj_vm.obj +@if errorlevel 1 goto :BAD +:NOAMALG + +@del *.obj *.manifest minilua.exe buildvm.exe +@echo. +@echo === Successfully built LuaJIT for Xbox One === + +@goto :END +:BAD +@echo. +@echo ******************************************************* +@echo *** Build FAILED -- Please check the error messages *** +@echo ******************************************************* +@goto :END +:FAIL +@echo To run this script you must open a "Visual Studio .NET Command Prompt" +@echo (64 bit host compiler). The Xbox One SDK must be installed, too. +:END diff --git a/fluent-bit/lib/luajit-3065c9/src/xedkbuild.bat b/fluent-bit/lib/luajit-3065c9/src/xedkbuild.bat new file mode 100644 index 00000000..37322d03 --- /dev/null +++ b/fluent-bit/lib/luajit-3065c9/src/xedkbuild.bat @@ -0,0 +1,92 @@ +@rem Script to build LuaJIT with the Xbox 360 SDK. +@rem Donated to the public domain. +@rem +@rem Open a "Visual Studio .NET Command Prompt" (32 bit host compiler) +@rem Then cd to this directory and run this script. + +@if not defined INCLUDE goto :FAIL +@if not defined XEDK goto :FAIL + +@setlocal +@rem ---- Host compiler ---- +@set LJCOMPILE=cl /nologo /c /MD /O2 /W3 /D_CRT_SECURE_NO_DEPRECATE +@set LJLINK=link /nologo +@set LJMT=mt /nologo +@set DASMDIR=..\dynasm +@set DASM=%DASMDIR%\dynasm.lua +@set ALL_LIB=lib_base.c lib_math.c lib_bit.c lib_string.c lib_table.c lib_io.c lib_os.c lib_package.c lib_debug.c lib_jit.c lib_ffi.c lib_buffer.c + +%LJCOMPILE% host\minilua.c +@if errorlevel 1 goto :BAD +%LJLINK% /out:minilua.exe minilua.obj +@if errorlevel 1 goto :BAD +if exist minilua.exe.manifest^ + %LJMT% -manifest minilua.exe.manifest -outputresource:minilua.exe + +@rem Error out for 64 bit host compiler +@minilua +@if errorlevel 8 goto :FAIL + +@set DASMFLAGS=-D GPR64 -D FRAME32 -D PPE -D SQRT -D DUALNUM +minilua %DASM% -LN %DASMFLAGS% -o host\buildvm_arch.h vm_ppc.dasc +@if errorlevel 1 goto :BAD + +%LJCOMPILE% /I "." /I %DASMDIR% /D_XBOX_VER=200 /DLUAJIT_TARGET=LUAJIT_ARCH_PPC host\buildvm*.c +@if errorlevel 1 goto :BAD +%LJLINK% /out:buildvm.exe buildvm*.obj +@if errorlevel 1 goto :BAD +if exist buildvm.exe.manifest^ + %LJMT% -manifest buildvm.exe.manifest -outputresource:buildvm.exe + +buildvm -m peobj -o lj_vm.obj +@if errorlevel 1 goto :BAD +buildvm -m bcdef -o lj_bcdef.h %ALL_LIB% +@if errorlevel 1 goto :BAD +buildvm -m ffdef -o lj_ffdef.h %ALL_LIB% +@if errorlevel 1 goto :BAD +buildvm -m libdef -o lj_libdef.h %ALL_LIB% +@if errorlevel 1 goto :BAD +buildvm -m recdef -o lj_recdef.h %ALL_LIB% +@if errorlevel 1 goto :BAD +buildvm -m vmdef -o jit\vmdef.lua %ALL_LIB% +@if errorlevel 1 goto :BAD +buildvm -m folddef -o lj_folddef.h lj_opt_fold.c +@if errorlevel 1 goto :BAD + +@rem ---- Cross compiler ---- +@set LJCOMPILE="%XEDK%\bin\win32\cl" /nologo /c /MT /O2 /W3 /GF /Gm- /GR- /GS- /Gy /openmp- /D_CRT_SECURE_NO_DEPRECATE /DNDEBUG /D_XBOX /D_LIB /DLUAJIT_USE_SYSMALLOC +@set LJLIB="%XEDK%\bin\win32\lib" /nologo +@set "INCLUDE=%XEDK%\include\xbox" + +@if "%1" neq "debug" goto :NODEBUG +@shift +@set "LJCOMPILE=%LJCOMPILE% /Zi" +:NODEBUG +@if "%1"=="amalg" goto :AMALG +%LJCOMPILE% /DLUA_BUILD_AS_DLL lj_*.c lib_*.c +@if errorlevel 1 goto :BAD +%LJLIB% /OUT:luajit20.lib lj_*.obj lib_*.obj +@if errorlevel 1 goto :BAD +@goto :NOAMALG +:AMALG +%LJCOMPILE% /DLUA_BUILD_AS_DLL ljamalg.c +@if errorlevel 1 goto :BAD +%LJLIB% /OUT:luajit20.lib ljamalg.obj lj_vm.obj +@if errorlevel 1 goto :BAD +:NOAMALG + +@del *.obj *.manifest minilua.exe buildvm.exe +@echo. +@echo === Successfully built LuaJIT for Xbox 360 === + +@goto :END +:BAD +@echo. +@echo ******************************************************* +@echo *** Build FAILED -- Please check the error messages *** +@echo ******************************************************* +@goto :END +:FAIL +@echo To run this script you must open a "Visual Studio .NET Command Prompt" +@echo (32 bit host compiler). The Xbox 360 SDK must be installed, too. +:END -- cgit v1.2.3