// Inferno utils/8l/asm.c // https://bitbucket.org/inferno-os/inferno-os/src/master/utils/8l/asm.c // // Copyright © 1994-1999 Lucent Technologies Inc. All rights reserved. // Portions Copyright © 1995-1997 C H Forsyth (forsyth@terzarima.net) // Portions Copyright © 1997-1999 Vita Nuova Limited // Portions Copyright © 2000-2007 Vita Nuova Holdings Limited (www.vitanuova.com) // Portions Copyright © 2004,2006 Bruce Ellis // Portions Copyright © 2005-2007 C H Forsyth (forsyth@terzarima.net) // Revisions Copyright © 2000-2007 Lucent Technologies Inc. and others // Portions Copyright © 2009 The Go Authors. 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. package ld import ( "bytes" "cmd/internal/bio" "cmd/internal/goobj" "cmd/internal/obj" "cmd/internal/objabi" "cmd/internal/sys" "cmd/link/internal/loadelf" "cmd/link/internal/loader" "cmd/link/internal/loadmacho" "cmd/link/internal/loadpe" "cmd/link/internal/loadxcoff" "cmd/link/internal/sym" "crypto/sha1" "debug/elf" "debug/macho" "encoding/base64" "encoding/binary" "fmt" "internal/buildcfg" exec "internal/execabs" "io" "io/ioutil" "log" "os" "path/filepath" "runtime" "strings" "sync" ) // Data layout and relocation. // Derived from Inferno utils/6l/l.h // https://bitbucket.org/inferno-os/inferno-os/src/master/utils/6l/l.h // // Copyright © 1994-1999 Lucent Technologies Inc. All rights reserved. // Portions Copyright © 1995-1997 C H Forsyth (forsyth@terzarima.net) // Portions Copyright © 1997-1999 Vita Nuova Limited // Portions Copyright © 2000-2007 Vita Nuova Holdings Limited (www.vitanuova.com) // Portions Copyright © 2004,2006 Bruce Ellis // Portions Copyright © 2005-2007 C H Forsyth (forsyth@terzarima.net) // Revisions Copyright © 2000-2007 Lucent Technologies Inc. and others // Portions Copyright © 2009 The Go Authors. 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. // ArchSyms holds a number of architecture specific symbols used during // relocation. Rather than allowing them universal access to all symbols, // we keep a subset for relocation application. type ArchSyms struct { Rel loader.Sym Rela loader.Sym RelPLT loader.Sym RelaPLT loader.Sym LinkEditGOT loader.Sym LinkEditPLT loader.Sym TOC loader.Sym DotTOC []loader.Sym // for each version GOT loader.Sym PLT loader.Sym GOTPLT loader.Sym Tlsg loader.Sym Tlsoffset int Dynamic loader.Sym DynSym loader.Sym DynStr loader.Sym unreachableMethod loader.Sym } // mkArchSym is a helper for setArchSyms, to set up a special symbol. func (ctxt *Link) mkArchSym(name string, ver int, ls *loader.Sym) { *ls = ctxt.loader.LookupOrCreateSym(name, ver) ctxt.loader.SetAttrReachable(*ls, true) } // mkArchVecSym is similar to setArchSyms, but operates on elements within // a slice, where each element corresponds to some symbol version. func (ctxt *Link) mkArchSymVec(name string, ver int, ls []loader.Sym) { ls[ver] = ctxt.loader.LookupOrCreateSym(name, ver) ctxt.loader.SetAttrReachable(ls[ver], true) } // setArchSyms sets up the ArchSyms structure, and must be called before // relocations are applied. func (ctxt *Link) setArchSyms() { ctxt.mkArchSym(".got", 0, &ctxt.GOT) ctxt.mkArchSym(".plt", 0, &ctxt.PLT) ctxt.mkArchSym(".got.plt", 0, &ctxt.GOTPLT) ctxt.mkArchSym(".dynamic", 0, &ctxt.Dynamic) ctxt.mkArchSym(".dynsym", 0, &ctxt.DynSym) ctxt.mkArchSym(".dynstr", 0, &ctxt.DynStr) ctxt.mkArchSym("runtime.unreachableMethod", abiInternalVer, &ctxt.unreachableMethod) if ctxt.IsPPC64() { ctxt.mkArchSym("TOC", 0, &ctxt.TOC) ctxt.DotTOC = make([]loader.Sym, ctxt.MaxVersion()+1) for i := 0; i <= ctxt.MaxVersion(); i++ { if i >= sym.SymVerABICount && i < sym.SymVerStatic { // these versions are not used currently continue } ctxt.mkArchSymVec(".TOC.", i, ctxt.DotTOC) } } if ctxt.IsElf() { ctxt.mkArchSym(".rel", 0, &ctxt.Rel) ctxt.mkArchSym(".rela", 0, &ctxt.Rela) ctxt.mkArchSym(".rel.plt", 0, &ctxt.RelPLT) ctxt.mkArchSym(".rela.plt", 0, &ctxt.RelaPLT) } if ctxt.IsDarwin() { ctxt.mkArchSym(".linkedit.got", 0, &ctxt.LinkEditGOT) ctxt.mkArchSym(".linkedit.plt", 0, &ctxt.LinkEditPLT) } } type Arch struct { Funcalign int Maxalign int Minalign int Dwarfregsp int Dwarfreglr int // Threshold of total text size, used for trampoline insertion. If the total // text size is smaller than TrampLimit, we won't need to insert trampolines. // It is pretty close to the offset range of a direct CALL machine instruction. // We leave some room for extra stuff like PLT stubs. TrampLimit uint64 Androiddynld string Linuxdynld string Freebsddynld string Netbsddynld string Openbsddynld string Dragonflydynld string Solarisdynld string // Empty spaces between codeblocks will be padded with this value. // For example an architecture might want to pad with a trap instruction to // catch wayward programs. Architectures that do not define a padding value // are padded with zeros. CodePad []byte // Plan 9 variables. Plan9Magic uint32 Plan9_64Bit bool Adddynrel func(*Target, *loader.Loader, *ArchSyms, loader.Sym, loader.Reloc, int) bool Archinit func(*Link) // Archreloc is an arch-specific hook that assists in relocation processing // (invoked by 'relocsym'); it handles target-specific relocation tasks. // Here "rel" is the current relocation being examined, "sym" is the symbol // containing the chunk of data to which the relocation applies, and "off" // is the contents of the to-be-relocated data item (from sym.P). Return // value is the appropriately relocated value (to be written back to the // same spot in sym.P), number of external _host_ relocations needed (i.e. // ELF/Mach-O/etc. relocations, not Go relocations, this must match Elfreloc1, // etc.), and a boolean indicating success/failure (a failing value indicates // a fatal error). Archreloc func(*Target, *loader.Loader, *ArchSyms, loader.Reloc, loader.Sym, int64) (relocatedOffset int64, nExtReloc int, ok bool) // Archrelocvariant is a second arch-specific hook used for // relocation processing; it handles relocations where r.Type is // insufficient to describe the relocation (r.Variant != // sym.RV_NONE). Here "rel" is the relocation being applied, "sym" // is the symbol containing the chunk of data to which the // relocation applies, and "off" is the contents of the // to-be-relocated data item (from sym.P). Return is an updated // offset value. Archrelocvariant func(target *Target, ldr *loader.Loader, rel loader.Reloc, rv sym.RelocVariant, sym loader.Sym, offset int64, data []byte) (relocatedOffset int64) // Generate a trampoline for a call from s to rs if necessary. ri is // index of the relocation. Trampoline func(ctxt *Link, ldr *loader.Loader, ri int, rs, s loader.Sym) // Assembling the binary breaks into two phases, writing the code/data/ // dwarf information (which is rather generic), and some more architecture // specific work like setting up the elf headers/dynamic relocations, etc. // The phases are called "Asmb" and "Asmb2". Asmb2 needs to be defined for // every architecture, but only if architecture has an Asmb function will // it be used for assembly. Otherwise a generic assembly Asmb function is // used. Asmb func(*Link, *loader.Loader) Asmb2 func(*Link, *loader.Loader) // Extreloc is an arch-specific hook that converts a Go relocation to an // external relocation. Return the external relocation and whether it is // needed. Extreloc func(*Target, *loader.Loader, loader.Reloc, loader.Sym) (loader.ExtReloc, bool) Elfreloc1 func(*Link, *OutBuf, *loader.Loader, loader.Sym, loader.ExtReloc, int, int64) bool ElfrelocSize uint32 // size of an ELF relocation record, must match Elfreloc1. Elfsetupplt func(ctxt *Link, plt, gotplt *loader.SymbolBuilder, dynamic loader.Sym) Gentext func(*Link, *loader.Loader) // Generate text before addressing has been performed. Machoreloc1 func(*sys.Arch, *OutBuf, *loader.Loader, loader.Sym, loader.ExtReloc, int64) bool MachorelocSize uint32 // size of an Mach-O relocation record, must match Machoreloc1. PEreloc1 func(*sys.Arch, *OutBuf, *loader.Loader, loader.Sym, loader.ExtReloc, int64) bool Xcoffreloc1 func(*sys.Arch, *OutBuf, *loader.Loader, loader.Sym, loader.ExtReloc, int64) bool // Generate additional symbols for the native symbol table just prior to // code generation. GenSymsLate func(*Link, *loader.Loader) // TLSIEtoLE converts a TLS Initial Executable relocation to // a TLS Local Executable relocation. // // This is possible when a TLS IE relocation refers to a local // symbol in an executable, which is typical when internally // linking PIE binaries. TLSIEtoLE func(P []byte, off, size int) // optional override for assignAddress AssignAddress func(ldr *loader.Loader, sect *sym.Section, n int, s loader.Sym, va uint64, isTramp bool) (*sym.Section, int, uint64) } var ( thearch Arch lcSize int32 rpath Rpath spSize int32 symSize int32 ) const ( MINFUNC = 16 // minimum size for a function ) // Symbol version of ABIInternal symbols. It is sym.SymVerABIInternal if ABI wrappers // are used, 0 otherwise. var abiInternalVer = sym.SymVerABIInternal // DynlinkingGo reports whether we are producing Go code that can live // in separate shared libraries linked together at runtime. func (ctxt *Link) DynlinkingGo() bool { if !ctxt.Loaded { panic("DynlinkingGo called before all symbols loaded") } return ctxt.BuildMode == BuildModeShared || ctxt.linkShared || ctxt.BuildMode == BuildModePlugin || ctxt.canUsePlugins } // CanUsePlugins reports whether a plugins can be used func (ctxt *Link) CanUsePlugins() bool { if !ctxt.Loaded { panic("CanUsePlugins called before all symbols loaded") } return ctxt.canUsePlugins } // NeedCodeSign reports whether we need to code-sign the output binary. func (ctxt *Link) NeedCodeSign() bool { return ctxt.IsDarwin() && ctxt.IsARM64() } var ( dynlib []string ldflag []string havedynamic int Funcalign int iscgo bool elfglobalsymndx int interpreter string debug_s bool // backup old value of debug['s'] HEADR int32 nerrors int liveness int64 // size of liveness data (funcdata), printed if -v // See -strictdups command line flag. checkStrictDups int // 0=off 1=warning 2=error strictDupMsgCount int ) var ( Segtext sym.Segment Segrodata sym.Segment Segrelrodata sym.Segment Segdata sym.Segment Segdwarf sym.Segment Segments = []*sym.Segment{&Segtext, &Segrodata, &Segrelrodata, &Segdata, &Segdwarf} ) const pkgdef = "__.PKGDEF" var ( // externalobj is set to true if we see an object compiled by // the host compiler that is not from a package that is known // to support internal linking mode. externalobj = false // unknownObjFormat is set to true if we see an object whose // format we don't recognize. unknownObjFormat = false theline string ) func Lflag(ctxt *Link, arg string) { ctxt.Libdir = append(ctxt.Libdir, arg) } /* * Unix doesn't like it when we write to a running (or, sometimes, * recently run) binary, so remove the output file before writing it. * On Windows 7, remove() can force a subsequent create() to fail. * S_ISREG() does not exist on Plan 9. */ func mayberemoveoutfile() { if fi, err := os.Lstat(*flagOutfile); err == nil && !fi.Mode().IsRegular() { return } os.Remove(*flagOutfile) } func libinit(ctxt *Link) { Funcalign = thearch.Funcalign // add goroot to the end of the libdir list. suffix := "" suffixsep := "" if *flagInstallSuffix != "" { suffixsep = "_" suffix = *flagInstallSuffix } else if *flagRace { suffixsep = "_" suffix = "race" } else if *flagMsan { suffixsep = "_" suffix = "msan" } else if *flagAsan { suffixsep = "_" suffix = "asan" } Lflag(ctxt, filepath.Join(buildcfg.GOROOT, "pkg", fmt.Sprintf("%s_%s%s%s", buildcfg.GOOS, buildcfg.GOARCH, suffixsep, suffix))) mayberemoveoutfile() if err := ctxt.Out.Open(*flagOutfile); err != nil { Exitf("cannot create %s: %v", *flagOutfile, err) } if *flagEntrySymbol == "" { switch ctxt.BuildMode { case BuildModeCShared, BuildModeCArchive: *flagEntrySymbol = fmt.Sprintf("_rt0_%s_%s_lib", buildcfg.GOARCH, buildcfg.GOOS) case BuildModeExe, BuildModePIE: *flagEntrySymbol = fmt.Sprintf("_rt0_%s_%s", buildcfg.GOARCH, buildcfg.GOOS) case BuildModeShared, BuildModePlugin: // No *flagEntrySymbol for -buildmode=shared and plugin default: Errorf(nil, "unknown *flagEntrySymbol for buildmode %v", ctxt.BuildMode) } } } func exitIfErrors() { if nerrors != 0 || checkStrictDups > 1 && strictDupMsgCount > 0 { mayberemoveoutfile() Exit(2) } } func errorexit() { exitIfErrors() Exit(0) } func loadinternal(ctxt *Link, name string) *sym.Library { zerofp := goobj.FingerprintType{} if ctxt.linkShared && ctxt.PackageShlib != nil { if shlib := ctxt.PackageShlib[name]; shlib != "" { return addlibpath(ctxt, "internal", "internal", "", name, shlib, zerofp) } } if ctxt.PackageFile != nil { if pname := ctxt.PackageFile[name]; pname != "" { return addlibpath(ctxt, "internal", "internal", pname, name, "", zerofp) } ctxt.Logf("loadinternal: cannot find %s\n", name) return nil } for _, libdir := range ctxt.Libdir { if ctxt.linkShared { shlibname := filepath.Join(libdir, name+".shlibname") if ctxt.Debugvlog != 0 { ctxt.Logf("searching for %s.a in %s\n", name, shlibname) } if _, err := os.Stat(shlibname); err == nil { return addlibpath(ctxt, "internal", "internal", "", name, shlibname, zerofp) } } pname := filepath.Join(libdir, name+".a") if ctxt.Debugvlog != 0 { ctxt.Logf("searching for %s.a in %s\n", name, pname) } if _, err := os.Stat(pname); err == nil { return addlibpath(ctxt, "internal", "internal", pname, name, "", zerofp) } } ctxt.Logf("warning: unable to find %s.a\n", name) return nil } // extld returns the current external linker. func (ctxt *Link) extld() []string { if len(flagExtld) == 0 { flagExtld = []string{"gcc"} } return flagExtld } // findLibPathCmd uses cmd command to find gcc library libname. // It returns library full path if found, or "none" if not found. func (ctxt *Link) findLibPathCmd(cmd, libname string) string { extld := ctxt.extld() name, args := extld[0], extld[1:] args = append(args, hostlinkArchArgs(ctxt.Arch)...) args = append(args, cmd) if ctxt.Debugvlog != 0 { ctxt.Logf("%s %v\n", extld, args) } out, err := exec.Command(name, args...).Output() if err != nil { if ctxt.Debugvlog != 0 { ctxt.Logf("not using a %s file because compiler failed\n%v\n%s\n", libname, err, out) } return "none" } return strings.TrimSpace(string(out)) } // findLibPath searches for library libname. // It returns library full path if found, or "none" if not found. func (ctxt *Link) findLibPath(libname string) string { return ctxt.findLibPathCmd("--print-file-name="+libname, libname) } func (ctxt *Link) loadlib() { var flags uint32 switch *FlagStrictDups { case 0: // nothing to do case 1, 2: flags |= loader.FlagStrictDups default: log.Fatalf("invalid -strictdups flag value %d", *FlagStrictDups) } elfsetstring1 := func(str string, off int) { elfsetstring(ctxt, 0, str, off) } ctxt.loader = loader.NewLoader(flags, elfsetstring1, &ctxt.ErrorReporter.ErrorReporter) ctxt.ErrorReporter.SymName = func(s loader.Sym) string { return ctxt.loader.SymName(s) } // ctxt.Library grows during the loop, so not a range loop. i := 0 for ; i < len(ctxt.Library); i++ { lib := ctxt.Library[i] if lib.Shlib == "" { if ctxt.Debugvlog > 1 { ctxt.Logf("autolib: %s (from %s)\n", lib.File, lib.Objref) } loadobjfile(ctxt, lib) } } // load internal packages, if not already if *flagRace { loadinternal(ctxt, "runtime/race") } if *flagMsan { loadinternal(ctxt, "runtime/msan") } if *flagAsan { loadinternal(ctxt, "runtime/asan") } loadinternal(ctxt, "runtime") for ; i < len(ctxt.Library); i++ { lib := ctxt.Library[i] if lib.Shlib == "" { loadobjfile(ctxt, lib) } } // At this point, the Go objects are "preloaded". Not all the symbols are // added to the symbol table (only defined package symbols are). Looking // up symbol by name may not get expected result. iscgo = ctxt.LibraryByPkg["runtime/cgo"] != nil // Plugins a require cgo support to function. Similarly, plugins may require additional // internal linker support on some platforms which may not be implemented. ctxt.canUsePlugins = ctxt.LibraryByPkg["plugin"] != nil && iscgo // We now have enough information to determine the link mode. determineLinkMode(ctxt) if ctxt.LinkMode == LinkExternal && !iscgo && !(buildcfg.GOOS == "darwin" && ctxt.BuildMode != BuildModePlugin && ctxt.Arch.Family == sys.AMD64) { // This indicates a user requested -linkmode=external. // The startup code uses an import of runtime/cgo to decide // whether to initialize the TLS. So give it one. This could // be handled differently but it's an unusual case. if lib := loadinternal(ctxt, "runtime/cgo"); lib != nil && lib.Shlib == "" { if ctxt.BuildMode == BuildModeShared || ctxt.linkShared { Exitf("cannot implicitly include runtime/cgo in a shared library") } for ; i < len(ctxt.Library); i++ { lib := ctxt.Library[i] if lib.Shlib == "" { loadobjfile(ctxt, lib) } } } } // Add non-package symbols and references of externally defined symbols. ctxt.loader.LoadSyms(ctxt.Arch) // Load symbols from shared libraries, after all Go object symbols are loaded. for _, lib := range ctxt.Library { if lib.Shlib != "" { if ctxt.Debugvlog > 1 { ctxt.Logf("autolib: %s (from %s)\n", lib.Shlib, lib.Objref) } ldshlibsyms(ctxt, lib.Shlib) } } // Process cgo directives (has to be done before host object loading). ctxt.loadcgodirectives() // Conditionally load host objects, or setup for external linking. hostobjs(ctxt) hostlinksetup(ctxt) if ctxt.LinkMode == LinkInternal && len(hostobj) != 0 { // If we have any undefined symbols in external // objects, try to read them from the libgcc file. any := false undefs := ctxt.loader.UndefinedRelocTargets(1) if len(undefs) > 0 { any = true } if any { if *flagLibGCC == "" { *flagLibGCC = ctxt.findLibPathCmd("--print-libgcc-file-name", "libgcc") } if runtime.GOOS == "openbsd" && *flagLibGCC == "libgcc.a" { // On OpenBSD `clang --print-libgcc-file-name` returns "libgcc.a". // In this case we fail to load libgcc.a and can encounter link // errors - see if we can find libcompiler_rt.a instead. *flagLibGCC = ctxt.findLibPathCmd("--print-file-name=libcompiler_rt.a", "libcompiler_rt") } if ctxt.HeadType == objabi.Hwindows { if p := ctxt.findLibPath("libmingwex.a"); p != "none" { hostArchive(ctxt, p) } if p := ctxt.findLibPath("libmingw32.a"); p != "none" { hostArchive(ctxt, p) } // Link libmsvcrt.a to resolve '__acrt_iob_func' symbol // (see https://golang.org/issue/23649 for details). if p := ctxt.findLibPath("libmsvcrt.a"); p != "none" { hostArchive(ctxt, p) } // TODO: maybe do something similar to peimporteddlls to collect all lib names // and try link them all to final exe just like libmingwex.a and libmingw32.a: /* for: #cgo windows LDFLAGS: -lmsvcrt -lm import: libmsvcrt.a libm.a */ } if *flagLibGCC != "none" { hostArchive(ctxt, *flagLibGCC) } } } // We've loaded all the code now. ctxt.Loaded = true importcycles() strictDupMsgCount = ctxt.loader.NStrictDupMsgs() } // loadcgodirectives reads the previously discovered cgo directives, creating // symbols in preparation for host object loading or use later in the link. func (ctxt *Link) loadcgodirectives() { l := ctxt.loader hostObjSyms := make(map[loader.Sym]struct{}) for _, d := range ctxt.cgodata { setCgoAttr(ctxt, d.file, d.pkg, d.directives, hostObjSyms) } ctxt.cgodata = nil if ctxt.LinkMode == LinkInternal { // Drop all the cgo_import_static declarations. // Turns out we won't be needing them. for symIdx := range hostObjSyms { if l.SymType(symIdx) == sym.SHOSTOBJ { // If a symbol was marked both // cgo_import_static and cgo_import_dynamic, // then we want to make it cgo_import_dynamic // now. su := l.MakeSymbolUpdater(symIdx) if l.SymExtname(symIdx) != "" && l.SymDynimplib(symIdx) != "" && !(l.AttrCgoExportStatic(symIdx) || l.AttrCgoExportDynamic(symIdx)) { su.SetType(sym.SDYNIMPORT) } else { su.SetType(0) } } } } } // Set up flags and special symbols depending on the platform build mode. // This version works with loader.Loader. func (ctxt *Link) linksetup() { switch ctxt.BuildMode { case BuildModeCShared, BuildModePlugin: symIdx := ctxt.loader.LookupOrCreateSym("runtime.islibrary", 0) sb := ctxt.loader.MakeSymbolUpdater(symIdx) sb.SetType(sym.SNOPTRDATA) sb.AddUint8(1) case BuildModeCArchive: symIdx := ctxt.loader.LookupOrCreateSym("runtime.isarchive", 0) sb := ctxt.loader.MakeSymbolUpdater(symIdx) sb.SetType(sym.SNOPTRDATA) sb.AddUint8(1) } // Recalculate pe parameters now that we have ctxt.LinkMode set. if ctxt.HeadType == objabi.Hwindows { Peinit(ctxt) } if ctxt.LinkMode == LinkExternal { // When external linking, we are creating an object file. The // absolute address is irrelevant. *FlagTextAddr = 0 } // If there are no dynamic libraries needed, gcc disables dynamic linking. // Because of this, glibc's dynamic ELF loader occasionally (like in version 2.13) // assumes that a dynamic binary always refers to at least one dynamic library. // Rather than be a source of test cases for glibc, disable dynamic linking // the same way that gcc would. // // Exception: on OS X, programs such as Shark only work with dynamic // binaries, so leave it enabled on OS X (Mach-O) binaries. // Also leave it enabled on Solaris which doesn't support // statically linked binaries. if ctxt.BuildMode == BuildModeExe { if havedynamic == 0 && ctxt.HeadType != objabi.Hdarwin && ctxt.HeadType != objabi.Hsolaris { *FlagD = true } } if ctxt.LinkMode == LinkExternal && ctxt.Arch.Family == sys.PPC64 && buildcfg.GOOS != "aix" { toc := ctxt.loader.LookupOrCreateSym(".TOC.", 0) sb := ctxt.loader.MakeSymbolUpdater(toc) sb.SetType(sym.SDYNIMPORT) } // The Android Q linker started to complain about underalignment of the our TLS // section. We don't actually use the section on android, so don't // generate it. if buildcfg.GOOS != "android" { tlsg := ctxt.loader.LookupOrCreateSym("runtime.tlsg", 0) sb := ctxt.loader.MakeSymbolUpdater(tlsg) // runtime.tlsg is used for external linking on platforms that do not define // a variable to hold g in assembly (currently only intel). if sb.Type() == 0 { sb.SetType(sym.STLSBSS) sb.SetSize(int64(ctxt.Arch.PtrSize)) } else if sb.Type() != sym.SDYNIMPORT { Errorf(nil, "runtime declared tlsg variable %v", sb.Type()) } ctxt.loader.SetAttrReachable(tlsg, true) ctxt.Tlsg = tlsg } var moduledata loader.Sym var mdsb *loader.SymbolBuilder if ctxt.BuildMode == BuildModePlugin { moduledata = ctxt.loader.LookupOrCreateSym("local.pluginmoduledata", 0) mdsb = ctxt.loader.MakeSymbolUpdater(moduledata) ctxt.loader.SetAttrLocal(moduledata, true) } else { moduledata = ctxt.loader.LookupOrCreateSym("runtime.firstmoduledata", 0) mdsb = ctxt.loader.MakeSymbolUpdater(moduledata) } if mdsb.Type() != 0 && mdsb.Type() != sym.SDYNIMPORT { // If the module (toolchain-speak for "executable or shared // library") we are linking contains the runtime package, it // will define the runtime.firstmoduledata symbol and we // truncate it back to 0 bytes so we can define its entire // contents in symtab.go:symtab(). mdsb.SetSize(0) // In addition, on ARM, the runtime depends on the linker // recording the value of GOARM. if ctxt.Arch.Family == sys.ARM { goarm := ctxt.loader.LookupOrCreateSym("runtime.goarm", 0) sb := ctxt.loader.MakeSymbolUpdater(goarm) sb.SetType(sym.SDATA) sb.SetSize(0) sb.AddUint8(uint8(buildcfg.GOARM)) } // Set runtime.disableMemoryProfiling bool if // runtime.MemProfile is not retained in the binary after // deadcode (and we're not dynamically linking). memProfile := ctxt.loader.Lookup("runtime.MemProfile", abiInternalVer) if memProfile != 0 && !ctxt.loader.AttrReachable(memProfile) && !ctxt.DynlinkingGo() { memProfSym := ctxt.loader.LookupOrCreateSym("runtime.disableMemoryProfiling", 0) sb := ctxt.loader.MakeSymbolUpdater(memProfSym) sb.SetType(sym.SDATA) sb.SetSize(0) sb.AddUint8(1) // true bool } } else { // If OTOH the module does not contain the runtime package, // create a local symbol for the moduledata. moduledata = ctxt.loader.LookupOrCreateSym("local.moduledata", 0) mdsb = ctxt.loader.MakeSymbolUpdater(moduledata) ctxt.loader.SetAttrLocal(moduledata, true) } // In all cases way we mark the moduledata as noptrdata to hide it from // the GC. mdsb.SetType(sym.SNOPTRDATA) ctxt.loader.SetAttrReachable(moduledata, true) ctxt.Moduledata = moduledata if ctxt.Arch == sys.Arch386 && ctxt.HeadType != objabi.Hwindows { if (ctxt.BuildMode == BuildModeCArchive && ctxt.IsELF) || ctxt.BuildMode == BuildModeCShared || ctxt.BuildMode == BuildModePIE || ctxt.DynlinkingGo() { got := ctxt.loader.LookupOrCreateSym("_GLOBAL_OFFSET_TABLE_", 0) sb := ctxt.loader.MakeSymbolUpdater(got) sb.SetType(sym.SDYNIMPORT) ctxt.loader.SetAttrReachable(got, true) } } // DWARF-gen and other phases require that the unit Textp slices // be populated, so that it can walk the functions in each unit. // Call into the loader to do this (requires that we collect the // set of internal libraries first). NB: might be simpler if we // moved isRuntimeDepPkg to cmd/internal and then did the test in // loader.AssignTextSymbolOrder. ctxt.Library = postorder(ctxt.Library) intlibs := []bool{} for _, lib := range ctxt.Library { intlibs = append(intlibs, isRuntimeDepPkg(lib.Pkg)) } ctxt.Textp = ctxt.loader.AssignTextSymbolOrder(ctxt.Library, intlibs, ctxt.Textp) } // mangleTypeSym shortens the names of symbols that represent Go types // if they are visible in the symbol table. // // As the names of these symbols are derived from the string of // the type, they can run to many kilobytes long. So we shorten // them using a SHA-1 when the name appears in the final binary. // This also removes characters that upset external linkers. // // These are the symbols that begin with the prefix 'type.' and // contain run-time type information used by the runtime and reflect // packages. All Go binaries contain these symbols, but only // those programs loaded dynamically in multiple parts need these // symbols to have entries in the symbol table. func (ctxt *Link) mangleTypeSym() { if ctxt.BuildMode != BuildModeShared && !ctxt.linkShared && ctxt.BuildMode != BuildModePlugin && !ctxt.CanUsePlugins() { return } ldr := ctxt.loader for s := loader.Sym(1); s < loader.Sym(ldr.NSym()); s++ { if !ldr.AttrReachable(s) && !ctxt.linkShared { // If -linkshared, the GCProg generation code may need to reach // out to the shared library for the type descriptor's data, even // the type descriptor itself is not actually needed at run time // (therefore not reachable). We still need to mangle its name, // so it is consistent with the one stored in the shared library. continue } name := ldr.SymName(s) newName := typeSymbolMangle(name) if newName != name { ldr.SetSymExtname(s, newName) // When linking against a shared library, the Go object file may // have reference to the original symbol name whereas the shared // library provides a symbol with the mangled name. We need to // copy the payload of mangled to original. // XXX maybe there is a better way to do this. dup := ldr.Lookup(newName, ldr.SymVersion(s)) if dup != 0 { st := ldr.SymType(s) dt := ldr.SymType(dup) if st == sym.Sxxx && dt != sym.Sxxx { ldr.CopySym(dup, s) } } } } } // typeSymbolMangle mangles the given symbol name into something shorter. // // Keep the type.. prefix, which parts of the linker (like the // DWARF generator) know means the symbol is not decodable. // Leave type.runtime. symbols alone, because other parts of // the linker manipulates them. func typeSymbolMangle(name string) string { if !strings.HasPrefix(name, "type.") { return name } if strings.HasPrefix(name, "type.runtime.") { return name } if len(name) <= 14 && !strings.Contains(name, "@") { // Issue 19529 return name } hash := sha1.Sum([]byte(name)) prefix := "type." if name[5] == '.' { prefix = "type.." } return prefix + base64.StdEncoding.EncodeToString(hash[:6]) } /* * look for the next file in an archive. * adapted from libmach. */ func nextar(bp *bio.Reader, off int64, a *ArHdr) int64 { if off&1 != 0 { off++ } bp.MustSeek(off, 0) var buf [SAR_HDR]byte if n, err := io.ReadFull(bp, buf[:]); err != nil { if n == 0 && err != io.EOF { return -1 } return 0 } a.name = artrim(buf[0:16]) a.date = artrim(buf[16:28]) a.uid = artrim(buf[28:34]) a.gid = artrim(buf[34:40]) a.mode = artrim(buf[40:48]) a.size = artrim(buf[48:58]) a.fmag = artrim(buf[58:60]) arsize := atolwhex(a.size) if arsize&1 != 0 { arsize++ } return arsize + SAR_HDR } func loadobjfile(ctxt *Link, lib *sym.Library) { pkg := objabi.PathToPrefix(lib.Pkg) if ctxt.Debugvlog > 1 { ctxt.Logf("ldobj: %s (%s)\n", lib.File, pkg) } f, err := bio.Open(lib.File) if err != nil { Exitf("cannot open file %s: %v", lib.File, err) } defer f.Close() defer func() { if pkg == "main" && !lib.Main { Exitf("%s: not package main", lib.File) } }() for i := 0; i < len(ARMAG); i++ { if c, err := f.ReadByte(); err == nil && c == ARMAG[i] { continue } /* load it as a regular file */ l := f.MustSeek(0, 2) f.MustSeek(0, 0) ldobj(ctxt, f, lib, l, lib.File, lib.File) return } /* * load all the object files from the archive now. * this gives us sequential file access and keeps us * from needing to come back later to pick up more * objects. it breaks the usual C archive model, but * this is Go, not C. the common case in Go is that * we need to load all the objects, and then we throw away * the individual symbols that are unused. * * loading every object will also make it possible to * load foreign objects not referenced by __.PKGDEF. */ var arhdr ArHdr off := f.Offset() for { l := nextar(f, off, &arhdr) if l == 0 { break } if l < 0 { Exitf("%s: malformed archive", lib.File) } off += l // __.PKGDEF isn't a real Go object file, and it's // absent in -linkobj builds anyway. Skipping it // ensures consistency between -linkobj and normal // build modes. if arhdr.name == pkgdef { continue } // Skip other special (non-object-file) sections that // build tools may have added. Such sections must have // short names so that the suffix is not truncated. if len(arhdr.name) < 16 { if ext := filepath.Ext(arhdr.name); ext != ".o" && ext != ".syso" { continue } } pname := fmt.Sprintf("%s(%s)", lib.File, arhdr.name) l = atolwhex(arhdr.size) ldobj(ctxt, f, lib, l, pname, lib.File) } } type Hostobj struct { ld func(*Link, *bio.Reader, string, int64, string) pkg string pn string file string off int64 length int64 } var hostobj []Hostobj // These packages can use internal linking mode. // Others trigger external mode. var internalpkg = []string{ "crypto/x509", "net", "os/user", "runtime/cgo", "runtime/race", "runtime/msan", "runtime/asan", } func ldhostobj(ld func(*Link, *bio.Reader, string, int64, string), headType objabi.HeadType, f *bio.Reader, pkg string, length int64, pn string, file string) *Hostobj { isinternal := false for _, intpkg := range internalpkg { if pkg == intpkg { isinternal = true break } } // DragonFly declares errno with __thread, which results in a symbol // type of R_386_TLS_GD or R_X86_64_TLSGD. The Go linker does not // currently know how to handle TLS relocations, hence we have to // force external linking for any libraries that link in code that // uses errno. This can be removed if the Go linker ever supports // these relocation types. if headType == objabi.Hdragonfly { if pkg == "net" || pkg == "os/user" { isinternal = false } } if !isinternal { externalobj = true } hostobj = append(hostobj, Hostobj{}) h := &hostobj[len(hostobj)-1] h.ld = ld h.pkg = pkg h.pn = pn h.file = file h.off = f.Offset() h.length = length return h } func hostobjs(ctxt *Link) { if ctxt.LinkMode != LinkInternal { return } var h *Hostobj for i := 0; i < len(hostobj); i++ { h = &hostobj[i] f, err := bio.Open(h.file) if err != nil { Exitf("cannot reopen %s: %v", h.pn, err) } f.MustSeek(h.off, 0) if h.ld == nil { Errorf(nil, "%s: unrecognized object file format", h.pn) continue } h.ld(ctxt, f, h.pkg, h.length, h.pn) f.Close() } } func hostlinksetup(ctxt *Link) { if ctxt.LinkMode != LinkExternal { return } // For external link, record that we need to tell the external linker -s, // and turn off -s internally: the external linker needs the symbol // information for its final link. debug_s = *FlagS *FlagS = false // create temporary directory and arrange cleanup if *flagTmpdir == "" { dir, err := ioutil.TempDir("", "go-link-") if err != nil { log.Fatal(err) } *flagTmpdir = dir ownTmpDir = true AtExit(func() { os.RemoveAll(*flagTmpdir) }) } // change our output to temporary object file if err := ctxt.Out.Close(); err != nil { Exitf("error closing output file") } mayberemoveoutfile() p := filepath.Join(*flagTmpdir, "go.o") if err := ctxt.Out.Open(p); err != nil { Exitf("cannot create %s: %v", p, err) } } // hostobjCopy creates a copy of the object files in hostobj in a // temporary directory. func hostobjCopy() (paths []string) { var wg sync.WaitGroup sema := make(chan struct{}, runtime.NumCPU()) // limit open file descriptors for i, h := range hostobj { h := h dst := filepath.Join(*flagTmpdir, fmt.Sprintf("%06d.o", i)) paths = append(paths, dst) wg.Add(1) go func() { sema <- struct{}{} defer func() { <-sema wg.Done() }() f, err := os.Open(h.file) if err != nil { Exitf("cannot reopen %s: %v", h.pn, err) } defer f.Close() if _, err := f.Seek(h.off, 0); err != nil { Exitf("cannot seek %s: %v", h.pn, err) } w, err := os.Create(dst) if err != nil { Exitf("cannot create %s: %v", dst, err) } if _, err := io.CopyN(w, f, h.length); err != nil { Exitf("cannot write %s: %v", dst, err) } if err := w.Close(); err != nil { Exitf("cannot close %s: %v", dst, err) } }() } wg.Wait() return paths } // writeGDBLinkerScript creates gcc linker script file in temp // directory. writeGDBLinkerScript returns created file path. // The script is used to work around gcc bug // (see https://golang.org/issue/20183 for details). func writeGDBLinkerScript() string { name := "fix_debug_gdb_scripts.ld" path := filepath.Join(*flagTmpdir, name) src := `SECTIONS { .debug_gdb_scripts BLOCK(__section_alignment__) (NOLOAD) : { *(.debug_gdb_scripts) } } INSERT AFTER .debug_types; ` err := ioutil.WriteFile(path, []byte(src), 0666) if err != nil { Errorf(nil, "WriteFile %s failed: %v", name, err) } return path } // archive builds a .a archive from the hostobj object files. func (ctxt *Link) archive() { if ctxt.BuildMode != BuildModeCArchive { return } exitIfErrors() if *flagExtar == "" { *flagExtar = "ar" } mayberemoveoutfile() // Force the buffer to flush here so that external // tools will see a complete file. if err := ctxt.Out.Close(); err != nil { Exitf("error closing %v", *flagOutfile) } argv := []string{*flagExtar, "-q", "-c", "-s"} if ctxt.HeadType == objabi.Haix { argv = append(argv, "-X64") } argv = append(argv, *flagOutfile) argv = append(argv, filepath.Join(*flagTmpdir, "go.o")) argv = append(argv, hostobjCopy()...) if ctxt.Debugvlog != 0 { ctxt.Logf("archive: %s\n", strings.Join(argv, " ")) } // If supported, use syscall.Exec() to invoke the archive command, // which should be the final remaining step needed for the link. // This will reduce peak RSS for the link (and speed up linking of // large applications), since when the archive command runs we // won't be holding onto all of the linker's live memory. if syscallExecSupported && !ownTmpDir { runAtExitFuncs() ctxt.execArchive(argv) panic("should not get here") } // Otherwise invoke 'ar' in the usual way (fork + exec). if out, err := exec.Command(argv[0], argv[1:]...).CombinedOutput(); err != nil { Exitf("running %s failed: %v\n%s", argv[0], err, out) } } func (ctxt *Link) hostlink() { if ctxt.LinkMode != LinkExternal || nerrors > 0 { return } if ctxt.BuildMode == BuildModeCArchive { return } var argv []string argv = append(argv, ctxt.extld()...) argv = append(argv, hostlinkArchArgs(ctxt.Arch)...) if *FlagS || debug_s { if ctxt.HeadType == objabi.Hdarwin { // Recent versions of macOS print // ld: warning: option -s is obsolete and being ignored // so do not pass any arguments. } else { argv = append(argv, "-s") } } // On darwin, whether to combine DWARF into executable. // Only macOS supports unmapped segments such as our __DWARF segment. combineDwarf := ctxt.IsDarwin() && !*FlagS && !*FlagW && !debug_s && machoPlatform == PLATFORM_MACOS switch ctxt.HeadType { case objabi.Hdarwin: if combineDwarf { // Leave room for DWARF combining. // -headerpad is incompatible with -fembed-bitcode. argv = append(argv, "-Wl,-headerpad,1144") } if ctxt.DynlinkingGo() && buildcfg.GOOS != "ios" { // -flat_namespace is deprecated on iOS. // It is useful for supporting plugins. We don't support plugins on iOS. // -flat_namespace may cause the dynamic linker to hang at forkExec when // resolving a lazy binding. See issue 38824. // Force eager resolution to work around. argv = append(argv, "-Wl,-flat_namespace", "-Wl,-bind_at_load") } if !combineDwarf { argv = append(argv, "-Wl,-S") // suppress STAB (symbolic debugging) symbols } case objabi.Hopenbsd: argv = append(argv, "-Wl,-nopie") argv = append(argv, "-pthread") case objabi.Hwindows: if windowsgui { argv = append(argv, "-mwindows") } else { argv = append(argv, "-mconsole") } // Mark as having awareness of terminal services, to avoid // ancient compatibility hacks. argv = append(argv, "-Wl,--tsaware") // Enable DEP argv = append(argv, "-Wl,--nxcompat") argv = append(argv, fmt.Sprintf("-Wl,--major-os-version=%d", PeMinimumTargetMajorVersion)) argv = append(argv, fmt.Sprintf("-Wl,--minor-os-version=%d", PeMinimumTargetMinorVersion)) argv = append(argv, fmt.Sprintf("-Wl,--major-subsystem-version=%d", PeMinimumTargetMajorVersion)) argv = append(argv, fmt.Sprintf("-Wl,--minor-subsystem-version=%d", PeMinimumTargetMinorVersion)) case objabi.Haix: argv = append(argv, "-pthread") // prevent ld to reorder .text functions to keep the same // first/last functions for moduledata. argv = append(argv, "-Wl,-bnoobjreorder") // mcmodel=large is needed for every gcc generated files, but // ld still need -bbigtoc in order to allow larger TOC. argv = append(argv, "-mcmodel=large") argv = append(argv, "-Wl,-bbigtoc") } // Enable ASLR on Windows. addASLRargs := func(argv []string) []string { // Enable ASLR. argv = append(argv, "-Wl,--dynamicbase") // enable high-entropy ASLR on 64-bit. if ctxt.Arch.PtrSize >= 8 { argv = append(argv, "-Wl,--high-entropy-va") } return argv } switch ctxt.BuildMode { case BuildModeExe: if ctxt.HeadType == objabi.Hdarwin { if machoPlatform == PLATFORM_MACOS && ctxt.IsAMD64() { argv = append(argv, "-Wl,-no_pie") } } case BuildModePIE: switch ctxt.HeadType { case objabi.Hdarwin, objabi.Haix: case objabi.Hwindows: argv = addASLRargs(argv) default: // ELF. if ctxt.UseRelro() { argv = append(argv, "-Wl,-z,relro") } argv = append(argv, "-pie") } case BuildModeCShared: if ctxt.HeadType == objabi.Hdarwin { argv = append(argv, "-dynamiclib") } else { if ctxt.UseRelro() { argv = append(argv, "-Wl,-z,relro") } argv = append(argv, "-shared") if ctxt.HeadType == objabi.Hwindows { if *flagAslr { argv = addASLRargs(argv) } } else { // Pass -z nodelete to mark the shared library as // non-closeable: a dlclose will do nothing. argv = append(argv, "-Wl,-z,nodelete") // Only pass Bsymbolic on non-Windows. argv = append(argv, "-Wl,-Bsymbolic") } } case BuildModeShared: if ctxt.UseRelro() { argv = append(argv, "-Wl,-z,relro") } argv = append(argv, "-shared") case BuildModePlugin: if ctxt.HeadType == objabi.Hdarwin { argv = append(argv, "-dynamiclib") } else { if ctxt.UseRelro() { argv = append(argv, "-Wl,-z,relro") } argv = append(argv, "-shared") } } var altLinker string if ctxt.IsELF && ctxt.DynlinkingGo() { // We force all symbol resolution to be done at program startup // because lazy PLT resolution can use large amounts of stack at // times we cannot allow it to do so. argv = append(argv, "-Wl,-znow") // Do not let the host linker generate COPY relocations. These // can move symbols out of sections that rely on stable offsets // from the beginning of the section (like sym.STYPE). argv = append(argv, "-Wl,-znocopyreloc") if buildcfg.GOOS == "android" { // Use lld to avoid errors from default linker (issue #38838) altLinker = "lld" } if ctxt.Arch.InFamily(sys.ARM, sys.ARM64) && buildcfg.GOOS == "linux" { // On ARM, the GNU linker will generate COPY relocations // even with -znocopyreloc set. // https://sourceware.org/bugzilla/show_bug.cgi?id=19962 // // On ARM64, the GNU linker will fail instead of // generating COPY relocations. // // In both cases, switch to gold. altLinker = "gold" // If gold is not installed, gcc will silently switch // back to ld.bfd. So we parse the version information // and provide a useful error if gold is missing. name, args := flagExtld[0], flagExtld[1:] args = append(args, "-fuse-ld=gold", "-Wl,--version") cmd := exec.Command(name, args...) if out, err := cmd.CombinedOutput(); err == nil { if !bytes.Contains(out, []byte("GNU gold")) { log.Fatalf("ARM external linker must be gold (issue #15696), but is not: %s", out) } } } } if ctxt.Arch.Family == sys.ARM64 && buildcfg.GOOS == "freebsd" { // Switch to ld.bfd on freebsd/arm64. altLinker = "bfd" // Provide a useful error if ld.bfd is missing. name, args := flagExtld[0], flagExtld[1:] args = append(args, "-fuse-ld=bfd", "-Wl,--version") cmd := exec.Command(name, args...) if out, err := cmd.CombinedOutput(); err == nil { if !bytes.Contains(out, []byte("GNU ld")) { log.Fatalf("ARM64 external linker must be ld.bfd (issue #35197), please install devel/binutils") } } } if altLinker != "" { argv = append(argv, "-fuse-ld="+altLinker) } if ctxt.IsELF && len(buildinfo) > 0 { argv = append(argv, fmt.Sprintf("-Wl,--build-id=0x%x", buildinfo)) } // On Windows, given -o foo, GCC will append ".exe" to produce // "foo.exe". We have decided that we want to honor the -o // option. To make this work, we append a '.' so that GCC // will decide that the file already has an extension. We // only want to do this when producing a Windows output file // on a Windows host. outopt := *flagOutfile if buildcfg.GOOS == "windows" && runtime.GOOS == "windows" && filepath.Ext(outopt) == "" { outopt += "." } argv = append(argv, "-o") argv = append(argv, outopt) if rpath.val != "" { argv = append(argv, fmt.Sprintf("-Wl,-rpath,%s", rpath.val)) } if *flagInterpreter != "" { // Many linkers support both -I and the --dynamic-linker flags // to set the ELF interpreter, but lld only supports // --dynamic-linker so prefer that (ld on very old Solaris only // supports -I but that seems less important). argv = append(argv, fmt.Sprintf("-Wl,--dynamic-linker,%s", *flagInterpreter)) } // Force global symbols to be exported for dlopen, etc. if ctxt.IsELF { argv = append(argv, "-rdynamic") } if ctxt.HeadType == objabi.Haix { fileName := xcoffCreateExportFile(ctxt) argv = append(argv, "-Wl,-bE:"+fileName) } const unusedArguments = "-Qunused-arguments" if linkerFlagSupported(ctxt.Arch, argv[0], altLinker, unusedArguments) { argv = append(argv, unusedArguments) } const compressDWARF = "-Wl,--compress-debug-sections=zlib-gnu" if ctxt.compressDWARF && linkerFlagSupported(ctxt.Arch, argv[0], altLinker, compressDWARF) { argv = append(argv, compressDWARF) } argv = append(argv, filepath.Join(*flagTmpdir, "go.o")) argv = append(argv, hostobjCopy()...) if ctxt.HeadType == objabi.Haix { // We want to have C files after Go files to remove // trampolines csects made by ld. argv = append(argv, "-nostartfiles") argv = append(argv, "/lib/crt0_64.o") extld := ctxt.extld() name, args := extld[0], extld[1:] // Get starting files. getPathFile := func(file string) string { args := append(args, "-maix64", "--print-file-name="+file) out, err := exec.Command(name, args...).CombinedOutput() if err != nil { log.Fatalf("running %s failed: %v\n%s", extld, err, out) } return strings.Trim(string(out), "\n") } // Since GCC version 11, the 64-bit version of GCC starting files // are now suffixed by "_64". Even under "-maix64" multilib directory // "crtcxa.o" is 32-bit. crtcxa := getPathFile("crtcxa_64.o") if !filepath.IsAbs(crtcxa) { crtcxa = getPathFile("crtcxa.o") } crtdbase := getPathFile("crtdbase_64.o") if !filepath.IsAbs(crtdbase) { crtdbase = getPathFile("crtdbase.o") } argv = append(argv, crtcxa) argv = append(argv, crtdbase) } if ctxt.linkShared { seenDirs := make(map[string]bool) seenLibs := make(map[string]bool) addshlib := func(path string) { dir, base := filepath.Split(path) if !seenDirs[dir] { argv = append(argv, "-L"+dir) if !rpath.set { argv = append(argv, "-Wl,-rpath="+dir) } seenDirs[dir] = true } base = strings.TrimSuffix(base, ".so") base = strings.TrimPrefix(base, "lib") if !seenLibs[base] { argv = append(argv, "-l"+base) seenLibs[base] = true } } for _, shlib := range ctxt.Shlibs { addshlib(shlib.Path) for _, dep := range shlib.Deps { if dep == "" { continue } libpath := findshlib(ctxt, dep) if libpath != "" { addshlib(libpath) } } } } // clang, unlike GCC, passes -rdynamic to the linker // even when linking with -static, causing a linker // error when using GNU ld. So take out -rdynamic if // we added it. We do it in this order, rather than // only adding -rdynamic later, so that -extldflags // can override -rdynamic without using -static. // Similarly for -Wl,--dynamic-linker. checkStatic := func(arg string) { if ctxt.IsELF && arg == "-static" { for i := range argv { if argv[i] == "-rdynamic" || strings.HasPrefix(argv[i], "-Wl,--dynamic-linker,") { argv[i] = "-static" } } } } for _, p := range ldflag { argv = append(argv, p) checkStatic(p) } // When building a program with the default -buildmode=exe the // gc compiler generates code requires DT_TEXTREL in a // position independent executable (PIE). On systems where the // toolchain creates PIEs by default, and where DT_TEXTREL // does not work, the resulting programs will not run. See // issue #17847. To avoid this problem pass -no-pie to the // toolchain if it is supported. if ctxt.BuildMode == BuildModeExe && !ctxt.linkShared && !(ctxt.IsDarwin() && ctxt.IsARM64()) { // GCC uses -no-pie, clang uses -nopie. for _, nopie := range []string{"-no-pie", "-nopie"} { if linkerFlagSupported(ctxt.Arch, argv[0], altLinker, nopie) { argv = append(argv, nopie) break } } } for _, p := range flagExtldflags { argv = append(argv, p) checkStatic(p) } if ctxt.HeadType == objabi.Hwindows { // Determine which linker we're using. Add in the extldflags in // case used has specified "-fuse-ld=...". extld := ctxt.extld() name, args := extld[0], extld[1:] args = append(args, flagExtldflags...) args = append(args, "-Wl,--version") cmd := exec.Command(name, args...) usingLLD := false if out, err := cmd.CombinedOutput(); err == nil { if bytes.Contains(out, []byte("LLD ")) { usingLLD = true } } // use gcc linker script to work around gcc bug // (see https://golang.org/issue/20183 for details). if !usingLLD { p := writeGDBLinkerScript() argv = append(argv, "-Wl,-T,"+p) } // libmingw32 and libmingwex have some inter-dependencies, // so must use linker groups. argv = append(argv, "-Wl,--start-group", "-lmingwex", "-lmingw32", "-Wl,--end-group") argv = append(argv, peimporteddlls()...) } if ctxt.Debugvlog != 0 { ctxt.Logf("host link:") for _, v := range argv { ctxt.Logf(" %q", v) } ctxt.Logf("\n") } out, err := exec.Command(argv[0], argv[1:]...).CombinedOutput() if err != nil { Exitf("running %s failed: %v\n%s", argv[0], err, out) } // Filter out useless linker warnings caused by bugs outside Go. // See also cmd/go/internal/work/exec.go's gccld method. var save [][]byte var skipLines int for _, line := range bytes.SplitAfter(out, []byte("\n")) { // golang.org/issue/26073 - Apple Xcode bug if bytes.Contains(line, []byte("ld: warning: text-based stub file")) { continue } if skipLines > 0 { skipLines-- continue } // Remove TOC overflow warning on AIX. if bytes.Contains(line, []byte("ld: 0711-783")) { skipLines = 2 continue } save = append(save, line) } out = bytes.Join(save, nil) if len(out) > 0 { // always print external output even if the command is successful, so that we don't // swallow linker warnings (see https://golang.org/issue/17935). if ctxt.IsDarwin() && ctxt.IsAMD64() { const noPieWarning = "ld: warning: -no_pie is deprecated when targeting new OS versions\n" if i := bytes.Index(out, []byte(noPieWarning)); i >= 0 { // swallow -no_pie deprecation warning, issue 54482 out = append(out[:i], out[i+len(noPieWarning):]...) } } ctxt.Logf("%s", out) } if combineDwarf { // Find "dsymutils" and "strip" tools using CC --print-prog-name. var cc []string cc = append(cc, ctxt.extld()...) cc = append(cc, hostlinkArchArgs(ctxt.Arch)...) cc = append(cc, "--print-prog-name", "dsymutil") out, err := exec.Command(cc[0], cc[1:]...).CombinedOutput() if err != nil { Exitf("%s: finding dsymutil failed: %v\n%s", os.Args[0], err, out) } dsymutilCmd := strings.TrimSuffix(string(out), "\n") cc[len(cc)-1] = "strip" out, err = exec.Command(cc[0], cc[1:]...).CombinedOutput() if err != nil { Exitf("%s: finding strip failed: %v\n%s", os.Args[0], err, out) } stripCmd := strings.TrimSuffix(string(out), "\n") dsym := filepath.Join(*flagTmpdir, "go.dwarf") if out, err := exec.Command(dsymutilCmd, "-f", *flagOutfile, "-o", dsym).CombinedOutput(); err != nil { Exitf("%s: running dsymutil failed: %v\n%s", os.Args[0], err, out) } // Remove STAB (symbolic debugging) symbols after we are done with them (by dsymutil). // They contain temporary file paths and make the build not reproducible. if out, err := exec.Command(stripCmd, "-S", *flagOutfile).CombinedOutput(); err != nil { Exitf("%s: running strip failed: %v\n%s", os.Args[0], err, out) } // Skip combining if `dsymutil` didn't generate a file. See #11994. if _, err := os.Stat(dsym); os.IsNotExist(err) { return } // For os.Rename to work reliably, must be in same directory as outfile. combinedOutput := *flagOutfile + "~" exef, err := os.Open(*flagOutfile) if err != nil { Exitf("%s: combining dwarf failed: %v", os.Args[0], err) } defer exef.Close() exem, err := macho.NewFile(exef) if err != nil { Exitf("%s: parsing Mach-O header failed: %v", os.Args[0], err) } if err := machoCombineDwarf(ctxt, exef, exem, dsym, combinedOutput); err != nil { Exitf("%s: combining dwarf failed: %v", os.Args[0], err) } os.Remove(*flagOutfile) if err := os.Rename(combinedOutput, *flagOutfile); err != nil { Exitf("%s: %v", os.Args[0], err) } } if ctxt.NeedCodeSign() { err := machoCodeSign(ctxt, *flagOutfile) if err != nil { Exitf("%s: code signing failed: %v", os.Args[0], err) } } } var createTrivialCOnce sync.Once func linkerFlagSupported(arch *sys.Arch, linker, altLinker, flag string) bool { createTrivialCOnce.Do(func() { src := filepath.Join(*flagTmpdir, "trivial.c") if err := ioutil.WriteFile(src, []byte("int main() { return 0; }"), 0666); err != nil { Errorf(nil, "WriteFile trivial.c failed: %v", err) } }) flagsWithNextArgSkip := []string{ "-F", "-l", "-L", "-framework", "-Wl,-framework", "-Wl,-rpath", "-Wl,-undefined", } flagsWithNextArgKeep := []string{ "-arch", "-isysroot", "--sysroot", "-target", } prefixesToKeep := []string{ "-f", "-m", "-p", "-Wl,", "-arch", "-isysroot", "--sysroot", "-target", } flags := hostlinkArchArgs(arch) keep := false skip := false for _, f := range append(flagExtldflags, ldflag...) { if keep { flags = append(flags, f) keep = false } else if skip { skip = false } else if f == "" || f[0] != '-' { } else if contains(flagsWithNextArgSkip, f) { skip = true } else if contains(flagsWithNextArgKeep, f) { flags = append(flags, f) keep = true } else { for _, p := range prefixesToKeep { if strings.HasPrefix(f, p) { flags = append(flags, f) break } } } } if altLinker != "" { flags = append(flags, "-fuse-ld="+altLinker) } flags = append(flags, flag, "trivial.c") cmd := exec.Command(linker, flags...) cmd.Dir = *flagTmpdir cmd.Env = append([]string{"LC_ALL=C"}, os.Environ()...) out, err := cmd.CombinedOutput() // GCC says "unrecognized command line option ‘-no-pie’" // clang says "unknown argument: '-no-pie'" return err == nil && !bytes.Contains(out, []byte("unrecognized")) && !bytes.Contains(out, []byte("unknown")) } // hostlinkArchArgs returns arguments to pass to the external linker // based on the architecture. func hostlinkArchArgs(arch *sys.Arch) []string { switch arch.Family { case sys.I386: return []string{"-m32"} case sys.AMD64: if buildcfg.GOOS == "darwin" { return []string{"-arch", "x86_64", "-m64"} } return []string{"-m64"} case sys.S390X: return []string{"-m64"} case sys.ARM: return []string{"-marm"} case sys.ARM64: if buildcfg.GOOS == "darwin" { return []string{"-arch", "arm64"} } case sys.MIPS64: return []string{"-mabi=64"} case sys.MIPS: return []string{"-mabi=32"} case sys.PPC64: if buildcfg.GOOS == "aix" { return []string{"-maix64"} } else { return []string{"-m64"} } } return nil } var wantHdr = objabi.HeaderString() // ldobj loads an input object. If it is a host object (an object // compiled by a non-Go compiler) it returns the Hostobj pointer. If // it is a Go object, it returns nil. func ldobj(ctxt *Link, f *bio.Reader, lib *sym.Library, length int64, pn string, file string) *Hostobj { pkg := objabi.PathToPrefix(lib.Pkg) eof := f.Offset() + length start := f.Offset() c1 := bgetc(f) c2 := bgetc(f) c3 := bgetc(f) c4 := bgetc(f) f.MustSeek(start, 0) unit := &sym.CompilationUnit{Lib: lib} lib.Units = append(lib.Units, unit) magic := uint32(c1)<<24 | uint32(c2)<<16 | uint32(c3)<<8 | uint32(c4) if magic == 0x7f454c46 { // \x7F E L F ldelf := func(ctxt *Link, f *bio.Reader, pkg string, length int64, pn string) { textp, flags, err := loadelf.Load(ctxt.loader, ctxt.Arch, ctxt.IncVersion(), f, pkg, length, pn, ehdr.Flags) if err != nil { Errorf(nil, "%v", err) return } ehdr.Flags = flags ctxt.Textp = append(ctxt.Textp, textp...) } return ldhostobj(ldelf, ctxt.HeadType, f, pkg, length, pn, file) } if magic&^1 == 0xfeedface || magic&^0x01000000 == 0xcefaedfe { ldmacho := func(ctxt *Link, f *bio.Reader, pkg string, length int64, pn string) { textp, err := loadmacho.Load(ctxt.loader, ctxt.Arch, ctxt.IncVersion(), f, pkg, length, pn) if err != nil { Errorf(nil, "%v", err) return } ctxt.Textp = append(ctxt.Textp, textp...) } return ldhostobj(ldmacho, ctxt.HeadType, f, pkg, length, pn, file) } switch c1<<8 | c2 { case 0x4c01, // 386 0x6486, // amd64 0xc401, // arm 0x64aa: // arm64 ldpe := func(ctxt *Link, f *bio.Reader, pkg string, length int64, pn string) { textp, rsrc, err := loadpe.Load(ctxt.loader, ctxt.Arch, ctxt.IncVersion(), f, pkg, length, pn) if err != nil { Errorf(nil, "%v", err) return } if len(rsrc) != 0 { setpersrc(ctxt, rsrc) } ctxt.Textp = append(ctxt.Textp, textp...) } return ldhostobj(ldpe, ctxt.HeadType, f, pkg, length, pn, file) } if c1 == 0x01 && (c2 == 0xD7 || c2 == 0xF7) { ldxcoff := func(ctxt *Link, f *bio.Reader, pkg string, length int64, pn string) { textp, err := loadxcoff.Load(ctxt.loader, ctxt.Arch, ctxt.IncVersion(), f, pkg, length, pn) if err != nil { Errorf(nil, "%v", err) return } ctxt.Textp = append(ctxt.Textp, textp...) } return ldhostobj(ldxcoff, ctxt.HeadType, f, pkg, length, pn, file) } if c1 != 'g' || c2 != 'o' || c3 != ' ' || c4 != 'o' { // An unrecognized object is just passed to the external linker. // If we try to read symbols from this object, we will // report an error at that time. unknownObjFormat = true return ldhostobj(nil, ctxt.HeadType, f, pkg, length, pn, file) } /* check the header */ line, err := f.ReadString('\n') if err != nil { Errorf(nil, "truncated object file: %s: %v", pn, err) return nil } if !strings.HasPrefix(line, "go object ") { if strings.HasSuffix(pn, ".go") { Exitf("%s: uncompiled .go source file", pn) return nil } if line == ctxt.Arch.Name { // old header format: just $GOOS Errorf(nil, "%s: stale object file", pn) return nil } Errorf(nil, "%s: not an object file: @%d %q", pn, start, line) return nil } // First, check that the basic GOOS, GOARCH, and Version match. if line != wantHdr { Errorf(nil, "%s: linked object header mismatch:\nhave %q\nwant %q\n", pn, line, wantHdr) } // Skip over exports and other info -- ends with \n!\n. // // Note: It's possible for "\n!\n" to appear within the binary // package export data format. To avoid truncating the package // definition prematurely (issue 21703), we keep track of // how many "$$" delimiters we've seen. import0 := f.Offset() c1 = '\n' // the last line ended in \n c2 = bgetc(f) c3 = bgetc(f) markers := 0 for { if c1 == '\n' { if markers%2 == 0 && c2 == '!' && c3 == '\n' { break } if c2 == '$' && c3 == '$' { markers++ } } c1 = c2 c2 = c3 c3 = bgetc(f) if c3 == -1 { Errorf(nil, "truncated object file: %s", pn) return nil } } import1 := f.Offset() f.MustSeek(import0, 0) ldpkg(ctxt, f, lib, import1-import0-2, pn) // -2 for !\n f.MustSeek(import1, 0) fingerprint := ctxt.loader.Preload(ctxt.IncVersion(), f, lib, unit, eof-f.Offset()) if !fingerprint.IsZero() { // Assembly objects don't have fingerprints. Ignore them. // Check fingerprint, to ensure the importing and imported packages // have consistent view of symbol indices. // Normally the go command should ensure this. But in case something // goes wrong, it could lead to obscure bugs like run-time crash. // Check it here to be sure. if lib.Fingerprint.IsZero() { // Not yet imported. Update its fingerprint. lib.Fingerprint = fingerprint } checkFingerprint(lib, fingerprint, lib.Srcref, lib.Fingerprint) } addImports(ctxt, lib, pn) return nil } func checkFingerprint(lib *sym.Library, libfp goobj.FingerprintType, src string, srcfp goobj.FingerprintType) { if libfp != srcfp { Exitf("fingerprint mismatch: %s has %x, import from %s expecting %x", lib, libfp, src, srcfp) } } func readelfsymboldata(ctxt *Link, f *elf.File, sym *elf.Symbol) []byte { data := make([]byte, sym.Size) sect := f.Sections[sym.Section] if sect.Type != elf.SHT_PROGBITS && sect.Type != elf.SHT_NOTE { Errorf(nil, "reading %s from non-data section", sym.Name) } n, err := sect.ReadAt(data, int64(sym.Value-sect.Addr)) if uint64(n) != sym.Size { Errorf(nil, "reading contents of %s: %v", sym.Name, err) } return data } func readwithpad(r io.Reader, sz int32) ([]byte, error) { data := make([]byte, Rnd(int64(sz), 4)) _, err := io.ReadFull(r, data) if err != nil { return nil, err } data = data[:sz] return data, nil } func readnote(f *elf.File, name []byte, typ int32) ([]byte, error) { for _, sect := range f.Sections { if sect.Type != elf.SHT_NOTE { continue } r := sect.Open() for { var namesize, descsize, noteType int32 err := binary.Read(r, f.ByteOrder, &namesize) if err != nil { if err == io.EOF { break } return nil, fmt.Errorf("read namesize failed: %v", err) } err = binary.Read(r, f.ByteOrder, &descsize) if err != nil { return nil, fmt.Errorf("read descsize failed: %v", err) } err = binary.Read(r, f.ByteOrder, ¬eType) if err != nil { return nil, fmt.Errorf("read type failed: %v", err) } noteName, err := readwithpad(r, namesize) if err != nil { return nil, fmt.Errorf("read name failed: %v", err) } desc, err := readwithpad(r, descsize) if err != nil { return nil, fmt.Errorf("read desc failed: %v", err) } if string(name) == string(noteName) && typ == noteType { return desc, nil } } } return nil, nil } func findshlib(ctxt *Link, shlib string) string { if filepath.IsAbs(shlib) { return shlib } for _, libdir := range ctxt.Libdir { libpath := filepath.Join(libdir, shlib) if _, err := os.Stat(libpath); err == nil { return libpath } } Errorf(nil, "cannot find shared library: %s", shlib) return "" } func ldshlibsyms(ctxt *Link, shlib string) { var libpath string if filepath.IsAbs(shlib) { libpath = shlib shlib = filepath.Base(shlib) } else { libpath = findshlib(ctxt, shlib) if libpath == "" { return } } for _, processedlib := range ctxt.Shlibs { if processedlib.Path == libpath { return } } if ctxt.Debugvlog > 1 { ctxt.Logf("ldshlibsyms: found library with name %s at %s\n", shlib, libpath) } f, err := elf.Open(libpath) if err != nil { Errorf(nil, "cannot open shared library: %s", libpath) return } // Keep the file open as decodetypeGcprog needs to read from it. // TODO: fix. Maybe mmap the file. //defer f.Close() hash, err := readnote(f, ELF_NOTE_GO_NAME, ELF_NOTE_GOABIHASH_TAG) if err != nil { Errorf(nil, "cannot read ABI hash from shared library %s: %v", libpath, err) return } depsbytes, err := readnote(f, ELF_NOTE_GO_NAME, ELF_NOTE_GODEPS_TAG) if err != nil { Errorf(nil, "cannot read dep list from shared library %s: %v", libpath, err) return } var deps []string for _, dep := range strings.Split(string(depsbytes), "\n") { if dep == "" { continue } if !filepath.IsAbs(dep) { // If the dep can be interpreted as a path relative to the shlib // in which it was found, do that. Otherwise, we will leave it // to be resolved by libdir lookup. abs := filepath.Join(filepath.Dir(libpath), dep) if _, err := os.Stat(abs); err == nil { dep = abs } } deps = append(deps, dep) } syms, err := f.DynamicSymbols() if err != nil { Errorf(nil, "cannot read symbols from shared library: %s", libpath) return } for _, elfsym := range syms { if elf.ST_TYPE(elfsym.Info) == elf.STT_NOTYPE || elf.ST_TYPE(elfsym.Info) == elf.STT_SECTION { continue } // Symbols whose names start with "type." are compiler // generated, so make functions with that prefix internal. ver := 0 symname := elfsym.Name // (unmangled) symbol name if elf.ST_TYPE(elfsym.Info) == elf.STT_FUNC && strings.HasPrefix(elfsym.Name, "type.") { ver = abiInternalVer } else if buildcfg.Experiment.RegabiWrappers && elf.ST_TYPE(elfsym.Info) == elf.STT_FUNC { // Demangle the ABI name. Keep in sync with symtab.go:mangleABIName. if strings.HasSuffix(elfsym.Name, ".abiinternal") { ver = sym.SymVerABIInternal symname = strings.TrimSuffix(elfsym.Name, ".abiinternal") } else if strings.HasSuffix(elfsym.Name, ".abi0") { ver = 0 symname = strings.TrimSuffix(elfsym.Name, ".abi0") } } l := ctxt.loader s := l.LookupOrCreateSym(symname, ver) // Because loadlib above loads all .a files before loading // any shared libraries, any non-dynimport symbols we find // that duplicate symbols already loaded should be ignored // (the symbols from the .a files "win"). if l.SymType(s) != 0 && l.SymType(s) != sym.SDYNIMPORT { continue } su := l.MakeSymbolUpdater(s) su.SetType(sym.SDYNIMPORT) l.SetSymElfType(s, elf.ST_TYPE(elfsym.Info)) su.SetSize(int64(elfsym.Size)) if elfsym.Section != elf.SHN_UNDEF { // Set .File for the library that actually defines the symbol. l.SetSymPkg(s, libpath) // The decodetype_* functions in decodetype.go need access to // the type data. sname := l.SymName(s) if strings.HasPrefix(sname, "type.") && !strings.HasPrefix(sname, "type..") { su.SetData(readelfsymboldata(ctxt, f, &elfsym)) } } if symname != elfsym.Name { l.SetSymExtname(s, elfsym.Name) } } ctxt.Shlibs = append(ctxt.Shlibs, Shlib{Path: libpath, Hash: hash, Deps: deps, File: f}) } func addsection(ldr *loader.Loader, arch *sys.Arch, seg *sym.Segment, name string, rwx int) *sym.Section { sect := ldr.NewSection() sect.Rwx = uint8(rwx) sect.Name = name sect.Seg = seg sect.Align = int32(arch.PtrSize) // everything is at least pointer-aligned seg.Sections = append(seg.Sections, sect) return sect } type chain struct { sym loader.Sym up *chain limit int // limit on entry to sym } func haslinkregister(ctxt *Link) bool { return ctxt.FixedFrameSize() != 0 } func callsize(ctxt *Link) int { if haslinkregister(ctxt) { return 0 } return ctxt.Arch.RegSize } type stkChk struct { ldr *loader.Loader ctxt *Link morestack loader.Sym done loader.Bitmap } // Walk the call tree and check that there is always enough stack space // for the call frames, especially for a chain of nosplit functions. func (ctxt *Link) dostkcheck() { ldr := ctxt.loader sc := stkChk{ ldr: ldr, ctxt: ctxt, morestack: ldr.Lookup("runtime.morestack", 0), done: loader.MakeBitmap(ldr.NSym()), } // Every splitting function ensures that there are at least StackLimit // bytes available below SP when the splitting prologue finishes. // If the splitting function calls F, then F begins execution with // at least StackLimit - callsize() bytes available. // Check that every function behaves correctly with this amount // of stack, following direct calls in order to piece together chains // of non-splitting functions. var ch chain ch.limit = objabi.StackLimit - callsize(ctxt) if buildcfg.GOARCH == "arm64" { // need extra 8 bytes below SP to save FP ch.limit -= 8 } // Check every function, but do the nosplit functions in a first pass, // to make the printed failure chains as short as possible. for _, s := range ctxt.Textp { if ldr.IsNoSplit(s) { ch.sym = s sc.check(&ch, 0) } } for _, s := range ctxt.Textp { if !ldr.IsNoSplit(s) { ch.sym = s sc.check(&ch, 0) } } } func (sc *stkChk) check(up *chain, depth int) int { limit := up.limit s := up.sym ldr := sc.ldr ctxt := sc.ctxt // Don't duplicate work: only need to consider each // function at top of safe zone once. top := limit == objabi.StackLimit-callsize(ctxt) if top { if sc.done.Has(s) { return 0 } sc.done.Set(s) } if depth > 500 { sc.ctxt.Errorf(s, "nosplit stack check too deep") sc.broke(up, 0) return -1 } if ldr.AttrExternal(s) { // external function. // should never be called directly. // onlyctxt.Diagnose the direct caller. // TODO(mwhudson): actually think about this. // TODO(khr): disabled for now. Calls to external functions can only happen on the g0 stack. // See the trampolines in src/runtime/sys_darwin_$ARCH.go. //if depth == 1 && ldr.SymType(s) != sym.SXREF && !ctxt.DynlinkingGo() && // ctxt.BuildMode != BuildModeCArchive && ctxt.BuildMode != BuildModePIE && ctxt.BuildMode != BuildModeCShared && ctxt.BuildMode != BuildModePlugin { // Errorf(s, "call to external function") //} return -1 } info := ldr.FuncInfo(s) if !info.Valid() { // external function. see above. return -1 } if limit < 0 { sc.broke(up, limit) return -1 } // morestack looks like it calls functions, // but it switches the stack pointer first. if s == sc.morestack { return 0 } var ch chain ch.up = up if !ldr.IsNoSplit(s) { // Ensure we have enough stack to call morestack. ch.limit = limit - callsize(ctxt) ch.sym = sc.morestack if sc.check(&ch, depth+1) < 0 { return -1 } if !top { return 0 } // Raise limit to allow frame. locals := info.Locals() limit = objabi.StackLimit + int(locals) + int(ctxt.FixedFrameSize()) } // Walk through sp adjustments in function, consuming relocs. relocs := ldr.Relocs(s) var ch1 chain pcsp := obj.NewPCIter(uint32(ctxt.Arch.MinLC)) ri := 0 for pcsp.Init(ldr.Data(ldr.Pcsp(s))); !pcsp.Done; pcsp.Next() { // pcsp.value is in effect for [pcsp.pc, pcsp.nextpc). // Check stack size in effect for this span. if int32(limit)-pcsp.Value < 0 { sc.broke(up, int(int32(limit)-pcsp.Value)) return -1 } // Process calls in this span. for ; ri < relocs.Count(); ri++ { r := relocs.At(ri) if uint32(r.Off()) >= pcsp.NextPC { break } t := r.Type() switch { case t.IsDirectCall(): ch.limit = int(int32(limit) - pcsp.Value - int32(callsize(ctxt))) ch.sym = r.Sym() if sc.check(&ch, depth+1) < 0 { return -1 } // Indirect call. Assume it is a call to a splitting function, // so we have to make sure it can call morestack. // Arrange the data structures to report both calls, so that // if there is an error, stkprint shows all the steps involved. case t == objabi.R_CALLIND: ch.limit = int(int32(limit) - pcsp.Value - int32(callsize(ctxt))) ch.sym = 0 ch1.limit = ch.limit - callsize(ctxt) // for morestack in called prologue ch1.up = &ch ch1.sym = sc.morestack if sc.check(&ch1, depth+2) < 0 { return -1 } } } } return 0 } func (sc *stkChk) broke(ch *chain, limit int) { sc.ctxt.Errorf(ch.sym, "nosplit stack overflow") sc.print(ch, limit) } func (sc *stkChk) print(ch *chain, limit int) { ldr := sc.ldr ctxt := sc.ctxt var name string if ch.sym != 0 { name = fmt.Sprintf("%s<%d>", ldr.SymName(ch.sym), ldr.SymVersion(ch.sym)) if ldr.IsNoSplit(ch.sym) { name += " (nosplit)" } } else { name = "function pointer" } if ch.up == nil { // top of chain. ch.sym != 0. if ldr.IsNoSplit(ch.sym) { fmt.Printf("\t%d\tassumed on entry to %s\n", ch.limit, name) } else { fmt.Printf("\t%d\tguaranteed after split check in %s\n", ch.limit, name) } } else { sc.print(ch.up, ch.limit+callsize(ctxt)) if !haslinkregister(ctxt) { fmt.Printf("\t%d\ton entry to %s\n", ch.limit, name) } } if ch.limit != limit { fmt.Printf("\t%d\tafter %s uses %d\n", limit, name, ch.limit-limit) } } func usage() { fmt.Fprintf(os.Stderr, "usage: link [options] main.o\n") objabi.Flagprint(os.Stderr) Exit(2) } type SymbolType int8 // TODO: after genasmsym is gone, maybe rename to plan9typeChar or something const ( // see also https://9p.io/magic/man2html/1/nm TextSym SymbolType = 'T' DataSym SymbolType = 'D' BSSSym SymbolType = 'B' UndefinedSym SymbolType = 'U' TLSSym SymbolType = 't' FrameSym SymbolType = 'm' ParamSym SymbolType = 'p' AutoSym SymbolType = 'a' // Deleted auto (not a real sym, just placeholder for type) DeletedAutoSym = 'x' ) // defineInternal defines a symbol used internally by the go runtime. func (ctxt *Link) defineInternal(p string, t sym.SymKind) loader.Sym { s := ctxt.loader.CreateSymForUpdate(p, 0) s.SetType(t) s.SetSpecial(true) s.SetLocal(true) return s.Sym() } func (ctxt *Link) xdefine(p string, t sym.SymKind, v int64) loader.Sym { s := ctxt.defineInternal(p, t) ctxt.loader.SetSymValue(s, v) return s } func datoff(ldr *loader.Loader, s loader.Sym, addr int64) int64 { if uint64(addr) >= Segdata.Vaddr { return int64(uint64(addr) - Segdata.Vaddr + Segdata.Fileoff) } if uint64(addr) >= Segtext.Vaddr { return int64(uint64(addr) - Segtext.Vaddr + Segtext.Fileoff) } ldr.Errorf(s, "invalid datoff %#x", addr) return 0 } func Entryvalue(ctxt *Link) int64 { a := *flagEntrySymbol if a[0] >= '0' && a[0] <= '9' { return atolwhex(a) } ldr := ctxt.loader s := ldr.Lookup(a, 0) st := ldr.SymType(s) if st == 0 { return *FlagTextAddr } if !ctxt.IsAIX() && st != sym.STEXT { ldr.Errorf(s, "entry not text") } return ldr.SymValue(s) } func (ctxt *Link) callgraph() { if !*FlagC { return } ldr := ctxt.loader for _, s := range ctxt.Textp { relocs := ldr.Relocs(s) for i := 0; i < relocs.Count(); i++ { r := relocs.At(i) rs := r.Sym() if rs == 0 { continue } if r.Type().IsDirectCall() && ldr.SymType(rs) == sym.STEXT { ctxt.Logf("%s calls %s\n", ldr.SymName(s), ldr.SymName(rs)) } } } } func Rnd(v int64, r int64) int64 { if r <= 0 { return v } v += r - 1 c := v % r if c < 0 { c += r } v -= c return v } func bgetc(r *bio.Reader) int { c, err := r.ReadByte() if err != nil { if err != io.EOF { log.Fatalf("reading input: %v", err) } return -1 } return int(c) } type markKind uint8 // for postorder traversal const ( _ markKind = iota visiting visited ) func postorder(libs []*sym.Library) []*sym.Library { order := make([]*sym.Library, 0, len(libs)) // hold the result mark := make(map[*sym.Library]markKind, len(libs)) for _, lib := range libs { dfs(lib, mark, &order) } return order } func dfs(lib *sym.Library, mark map[*sym.Library]markKind, order *[]*sym.Library) { if mark[lib] == visited { return } if mark[lib] == visiting { panic("found import cycle while visiting " + lib.Pkg) } mark[lib] = visiting for _, i := range lib.Imports { dfs(i, mark, order) } mark[lib] = visited *order = append(*order, lib) } func ElfSymForReloc(ctxt *Link, s loader.Sym) int32 { // If putelfsym created a local version of this symbol, use that in all // relocations. les := ctxt.loader.SymLocalElfSym(s) if les != 0 { return les } else { return ctxt.loader.SymElfSym(s) } } func AddGotSym(target *Target, ldr *loader.Loader, syms *ArchSyms, s loader.Sym, elfRelocTyp uint32) { if ldr.SymGot(s) >= 0 { return } Adddynsym(ldr, target, syms, s) got := ldr.MakeSymbolUpdater(syms.GOT) ldr.SetGot(s, int32(got.Size())) got.AddUint(target.Arch, 0) if target.IsElf() { if target.Arch.PtrSize == 8 { rela := ldr.MakeSymbolUpdater(syms.Rela) rela.AddAddrPlus(target.Arch, got.Sym(), int64(ldr.SymGot(s))) rela.AddUint64(target.Arch, elf.R_INFO(uint32(ldr.SymDynid(s)), elfRelocTyp)) rela.AddUint64(target.Arch, 0) } else { rel := ldr.MakeSymbolUpdater(syms.Rel) rel.AddAddrPlus(target.Arch, got.Sym(), int64(ldr.SymGot(s))) rel.AddUint32(target.Arch, elf.R_INFO32(uint32(ldr.SymDynid(s)), elfRelocTyp)) } } else if target.IsDarwin() { leg := ldr.MakeSymbolUpdater(syms.LinkEditGOT) leg.AddUint32(target.Arch, uint32(ldr.SymDynid(s))) if target.IsPIE() && target.IsInternal() { // Mach-O relocations are a royal pain to lay out. // They use a compact stateful bytecode representation. // Here we record what are needed and encode them later. MachoAddBind(int64(ldr.SymGot(s)), s) } } else { ldr.Errorf(s, "addgotsym: unsupported binary format") } }