/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 2 -*- * vim: set ts=8 sts=2 et sw=2 tw=80: * This Source Code Form is subject to the terms of the Mozilla Public * License, v. 2.0. If a copy of the MPL was not distributed with this * file, You can obtain one at http://mozilla.org/MPL/2.0/. */ #include "jit/x86/MacroAssembler-x86.h" #include "mozilla/Alignment.h" #include "mozilla/Casting.h" #include "jit/AtomicOp.h" #include "jit/Bailouts.h" #include "jit/BaselineFrame.h" #include "jit/JitFrames.h" #include "jit/JitRuntime.h" #include "jit/MacroAssembler.h" #include "jit/MoveEmitter.h" #include "util/Memory.h" #include "vm/BigIntType.h" #include "vm/JitActivation.h" // js::jit::JitActivation #include "vm/JSContext.h" #include "vm/StringType.h" #include "jit/MacroAssembler-inl.h" #include "vm/JSScript-inl.h" using namespace js; using namespace js::jit; void MacroAssemblerX86::loadConstantDouble(double d, FloatRegister dest) { if (maybeInlineDouble(d, dest)) { return; } Double* dbl = getDouble(d); if (!dbl) { return; } masm.vmovsd_mr(nullptr, dest.encoding()); propagateOOM(dbl->uses.append(CodeOffset(masm.size()))); } void MacroAssemblerX86::loadConstantFloat32(float f, FloatRegister dest) { if (maybeInlineFloat(f, dest)) { return; } Float* flt = getFloat(f); if (!flt) { return; } masm.vmovss_mr(nullptr, dest.encoding()); propagateOOM(flt->uses.append(CodeOffset(masm.size()))); } void MacroAssemblerX86::loadConstantSimd128Int(const SimdConstant& v, FloatRegister dest) { if (maybeInlineSimd128Int(v, dest)) { return; } SimdData* i4 = getSimdData(v); if (!i4) { return; } masm.vmovdqa_mr(nullptr, dest.encoding()); propagateOOM(i4->uses.append(CodeOffset(masm.size()))); } void MacroAssemblerX86::loadConstantSimd128Float(const SimdConstant& v, FloatRegister dest) { if (maybeInlineSimd128Float(v, dest)) { return; } SimdData* f4 = getSimdData(v); if (!f4) { return; } masm.vmovaps_mr(nullptr, dest.encoding()); propagateOOM(f4->uses.append(CodeOffset(masm.size()))); } void MacroAssemblerX86::vpPatchOpSimd128( const SimdConstant& v, FloatRegister src, FloatRegister dest, void (X86Encoding::BaseAssemblerX86::*op)( const void* address, X86Encoding::XMMRegisterID srcId, X86Encoding::XMMRegisterID destId)) { SimdData* val = getSimdData(v); if (!val) { return; } (masm.*op)(nullptr, src.encoding(), dest.encoding()); propagateOOM(val->uses.append(CodeOffset(masm.size()))); } void MacroAssemblerX86::vpPatchOpSimd128( const SimdConstant& v, FloatRegister src, FloatRegister dest, size_t (X86Encoding::BaseAssemblerX86::*op)( const void* address, X86Encoding::XMMRegisterID srcId, X86Encoding::XMMRegisterID destId)) { SimdData* val = getSimdData(v); if (!val) { return; } size_t patchOffsetFromEnd = (masm.*op)(nullptr, src.encoding(), dest.encoding()); propagateOOM(val->uses.append(CodeOffset(masm.size() - patchOffsetFromEnd))); } void MacroAssemblerX86::vpaddbSimd128(const SimdConstant& v, FloatRegister lhs, FloatRegister dest) { vpPatchOpSimd128(v, lhs, dest, &X86Encoding::BaseAssemblerX86::vpaddb_mr); } void MacroAssemblerX86::vpaddwSimd128(const SimdConstant& v, FloatRegister lhs, FloatRegister dest) { vpPatchOpSimd128(v, lhs, dest, &X86Encoding::BaseAssemblerX86::vpaddw_mr); } void MacroAssemblerX86::vpadddSimd128(const SimdConstant& v, FloatRegister lhs, FloatRegister dest) { vpPatchOpSimd128(v, lhs, dest, &X86Encoding::BaseAssemblerX86::vpaddd_mr); } void MacroAssemblerX86::vpaddqSimd128(const SimdConstant& v, FloatRegister lhs, FloatRegister dest) { vpPatchOpSimd128(v, lhs, dest, &X86Encoding::BaseAssemblerX86::vpaddq_mr); } void MacroAssemblerX86::vpsubbSimd128(const SimdConstant& v, FloatRegister lhs, FloatRegister dest) { vpPatchOpSimd128(v, lhs, dest, &X86Encoding::BaseAssemblerX86::vpsubb_mr); } void MacroAssemblerX86::vpsubwSimd128(const SimdConstant& v, FloatRegister lhs, FloatRegister dest) { vpPatchOpSimd128(v, lhs, dest, &X86Encoding::BaseAssemblerX86::vpsubw_mr); } void MacroAssemblerX86::vpsubdSimd128(const SimdConstant& v, FloatRegister lhs, FloatRegister dest) { vpPatchOpSimd128(v, lhs, dest, &X86Encoding::BaseAssemblerX86::vpsubd_mr); } void MacroAssemblerX86::vpsubqSimd128(const SimdConstant& v, FloatRegister lhs, FloatRegister dest) { vpPatchOpSimd128(v, lhs, dest, &X86Encoding::BaseAssemblerX86::vpsubq_mr); } void MacroAssemblerX86::vpmullwSimd128(const SimdConstant& v, FloatRegister lhs, FloatRegister dest) { vpPatchOpSimd128(v, lhs, dest, &X86Encoding::BaseAssemblerX86::vpmullw_mr); } void MacroAssemblerX86::vpmulldSimd128(const SimdConstant& v, FloatRegister lhs, FloatRegister dest) { vpPatchOpSimd128(v, lhs, dest, &X86Encoding::BaseAssemblerX86::vpmulld_mr); } void MacroAssemblerX86::vpaddsbSimd128(const SimdConstant& v, FloatRegister lhs, FloatRegister dest) { vpPatchOpSimd128(v, lhs, dest, &X86Encoding::BaseAssemblerX86::vpaddsb_mr); } void MacroAssemblerX86::vpaddusbSimd128(const SimdConstant& v, FloatRegister lhs, FloatRegister dest) { vpPatchOpSimd128(v, lhs, dest, &X86Encoding::BaseAssemblerX86::vpaddusb_mr); } void MacroAssemblerX86::vpaddswSimd128(const SimdConstant& v, FloatRegister lhs, FloatRegister dest) { vpPatchOpSimd128(v, lhs, dest, &X86Encoding::BaseAssemblerX86::vpaddsw_mr); } void MacroAssemblerX86::vpadduswSimd128(const SimdConstant& v, FloatRegister lhs, FloatRegister dest) { vpPatchOpSimd128(v, lhs, dest, &X86Encoding::BaseAssemblerX86::vpaddusw_mr); } void MacroAssemblerX86::vpsubsbSimd128(const SimdConstant& v, FloatRegister lhs, FloatRegister dest) { vpPatchOpSimd128(v, lhs, dest, &X86Encoding::BaseAssemblerX86::vpsubsb_mr); } void MacroAssemblerX86::vpsubusbSimd128(const SimdConstant& v, FloatRegister lhs, FloatRegister dest) { vpPatchOpSimd128(v, lhs, dest, &X86Encoding::BaseAssemblerX86::vpsubusb_mr); } void MacroAssemblerX86::vpsubswSimd128(const SimdConstant& v, FloatRegister lhs, FloatRegister dest) { vpPatchOpSimd128(v, lhs, dest, &X86Encoding::BaseAssemblerX86::vpsubsw_mr); } void MacroAssemblerX86::vpsubuswSimd128(const SimdConstant& v, FloatRegister lhs, FloatRegister dest) { vpPatchOpSimd128(v, lhs, dest, &X86Encoding::BaseAssemblerX86::vpsubusw_mr); } void MacroAssemblerX86::vpminsbSimd128(const SimdConstant& v, FloatRegister lhs, FloatRegister dest) { vpPatchOpSimd128(v, lhs, dest, &X86Encoding::BaseAssemblerX86::vpminsb_mr); } void MacroAssemblerX86::vpminubSimd128(const SimdConstant& v, FloatRegister lhs, FloatRegister dest) { vpPatchOpSimd128(v, lhs, dest, &X86Encoding::BaseAssemblerX86::vpminub_mr); } void MacroAssemblerX86::vpminswSimd128(const SimdConstant& v, FloatRegister lhs, FloatRegister dest) { vpPatchOpSimd128(v, lhs, dest, &X86Encoding::BaseAssemblerX86::vpminsw_mr); } void MacroAssemblerX86::vpminuwSimd128(const SimdConstant& v, FloatRegister lhs, FloatRegister dest) { vpPatchOpSimd128(v, lhs, dest, &X86Encoding::BaseAssemblerX86::vpminuw_mr); } void MacroAssemblerX86::vpminsdSimd128(const SimdConstant& v, FloatRegister lhs, FloatRegister dest) { vpPatchOpSimd128(v, lhs, dest, &X86Encoding::BaseAssemblerX86::vpminsd_mr); } void MacroAssemblerX86::vpminudSimd128(const SimdConstant& v, FloatRegister lhs, FloatRegister dest) { vpPatchOpSimd128(v, lhs, dest, &X86Encoding::BaseAssemblerX86::vpminud_mr); } void MacroAssemblerX86::vpmaxsbSimd128(const SimdConstant& v, FloatRegister lhs, FloatRegister dest) { vpPatchOpSimd128(v, lhs, dest, &X86Encoding::BaseAssemblerX86::vpmaxsb_mr); } void MacroAssemblerX86::vpmaxubSimd128(const SimdConstant& v, FloatRegister lhs, FloatRegister dest) { vpPatchOpSimd128(v, lhs, dest, &X86Encoding::BaseAssemblerX86::vpmaxub_mr); } void MacroAssemblerX86::vpmaxswSimd128(const SimdConstant& v, FloatRegister lhs, FloatRegister dest) { vpPatchOpSimd128(v, lhs, dest, &X86Encoding::BaseAssemblerX86::vpmaxsw_mr); } void MacroAssemblerX86::vpmaxuwSimd128(const SimdConstant& v, FloatRegister lhs, FloatRegister dest) { vpPatchOpSimd128(v, lhs, dest, &X86Encoding::BaseAssemblerX86::vpmaxuw_mr); } void MacroAssemblerX86::vpmaxsdSimd128(const SimdConstant& v, FloatRegister lhs, FloatRegister dest) { vpPatchOpSimd128(v, lhs, dest, &X86Encoding::BaseAssemblerX86::vpmaxsd_mr); } void MacroAssemblerX86::vpmaxudSimd128(const SimdConstant& v, FloatRegister lhs, FloatRegister dest) { vpPatchOpSimd128(v, lhs, dest, &X86Encoding::BaseAssemblerX86::vpmaxud_mr); } void MacroAssemblerX86::vpandSimd128(const SimdConstant& v, FloatRegister lhs, FloatRegister dest) { vpPatchOpSimd128(v, lhs, dest, &X86Encoding::BaseAssemblerX86::vpand_mr); } void MacroAssemblerX86::vpxorSimd128(const SimdConstant& v, FloatRegister lhs, FloatRegister dest) { vpPatchOpSimd128(v, lhs, dest, &X86Encoding::BaseAssemblerX86::vpxor_mr); } void MacroAssemblerX86::vporSimd128(const SimdConstant& v, FloatRegister lhs, FloatRegister dest) { vpPatchOpSimd128(v, lhs, dest, &X86Encoding::BaseAssemblerX86::vpor_mr); } void MacroAssemblerX86::vaddpsSimd128(const SimdConstant& v, FloatRegister lhs, FloatRegister dest) { vpPatchOpSimd128(v, lhs, dest, &X86Encoding::BaseAssemblerX86::vaddps_mr); } void MacroAssemblerX86::vaddpdSimd128(const SimdConstant& v, FloatRegister lhs, FloatRegister dest) { vpPatchOpSimd128(v, lhs, dest, &X86Encoding::BaseAssemblerX86::vaddpd_mr); } void MacroAssemblerX86::vsubpsSimd128(const SimdConstant& v, FloatRegister lhs, FloatRegister dest) { vpPatchOpSimd128(v, lhs, dest, &X86Encoding::BaseAssemblerX86::vsubps_mr); } void MacroAssemblerX86::vsubpdSimd128(const SimdConstant& v, FloatRegister lhs, FloatRegister dest) { vpPatchOpSimd128(v, lhs, dest, &X86Encoding::BaseAssemblerX86::vsubpd_mr); } void MacroAssemblerX86::vdivpsSimd128(const SimdConstant& v, FloatRegister lhs, FloatRegister dest) { vpPatchOpSimd128(v, lhs, dest, &X86Encoding::BaseAssemblerX86::vdivps_mr); } void MacroAssemblerX86::vdivpdSimd128(const SimdConstant& v, FloatRegister lhs, FloatRegister dest) { vpPatchOpSimd128(v, lhs, dest, &X86Encoding::BaseAssemblerX86::vdivpd_mr); } void MacroAssemblerX86::vmulpsSimd128(const SimdConstant& v, FloatRegister lhs, FloatRegister dest) { vpPatchOpSimd128(v, lhs, dest, &X86Encoding::BaseAssemblerX86::vmulps_mr); } void MacroAssemblerX86::vmulpdSimd128(const SimdConstant& v, FloatRegister lhs, FloatRegister dest) { vpPatchOpSimd128(v, lhs, dest, &X86Encoding::BaseAssemblerX86::vmulpd_mr); } void MacroAssemblerX86::vandpdSimd128(const SimdConstant& v, FloatRegister lhs, FloatRegister dest) { vpPatchOpSimd128(v, lhs, dest, &X86Encoding::BaseAssemblerX86::vandpd_mr); } void MacroAssemblerX86::vminpdSimd128(const SimdConstant& v, FloatRegister lhs, FloatRegister dest) { vpPatchOpSimd128(v, lhs, dest, &X86Encoding::BaseAssemblerX86::vminpd_mr); } void MacroAssemblerX86::vpacksswbSimd128(const SimdConstant& v, FloatRegister lhs, FloatRegister dest) { vpPatchOpSimd128(v, lhs, dest, &X86Encoding::BaseAssemblerX86::vpacksswb_mr); } void MacroAssemblerX86::vpackuswbSimd128(const SimdConstant& v, FloatRegister lhs, FloatRegister dest) { vpPatchOpSimd128(v, lhs, dest, &X86Encoding::BaseAssemblerX86::vpackuswb_mr); } void MacroAssemblerX86::vpackssdwSimd128(const SimdConstant& v, FloatRegister lhs, FloatRegister dest) { vpPatchOpSimd128(v, lhs, dest, &X86Encoding::BaseAssemblerX86::vpackssdw_mr); } void MacroAssemblerX86::vpackusdwSimd128(const SimdConstant& v, FloatRegister lhs, FloatRegister dest) { vpPatchOpSimd128(v, lhs, dest, &X86Encoding::BaseAssemblerX86::vpackusdw_mr); } void MacroAssemblerX86::vpunpckldqSimd128(const SimdConstant& v, FloatRegister lhs, FloatRegister dest) { vpPatchOpSimd128(v, lhs, dest, &X86Encoding::BaseAssemblerX86::vpunpckldq_mr); } void MacroAssemblerX86::vunpcklpsSimd128(const SimdConstant& v, FloatRegister lhs, FloatRegister dest) { vpPatchOpSimd128(v, lhs, dest, &X86Encoding::BaseAssemblerX86::vunpcklps_mr); } void MacroAssemblerX86::vpshufbSimd128(const SimdConstant& v, FloatRegister lhs, FloatRegister dest) { vpPatchOpSimd128(v, lhs, dest, &X86Encoding::BaseAssemblerX86::vpshufb_mr); } void MacroAssemblerX86::vptestSimd128(const SimdConstant& v, FloatRegister lhs) { vpPatchOpSimd128(v, lhs, &X86Encoding::BaseAssemblerX86::vptest_mr); } void MacroAssemblerX86::vpmaddwdSimd128(const SimdConstant& v, FloatRegister lhs, FloatRegister dest) { vpPatchOpSimd128(v, lhs, dest, &X86Encoding::BaseAssemblerX86::vpmaddwd_mr); } void MacroAssemblerX86::vpcmpeqbSimd128(const SimdConstant& v, FloatRegister lhs, FloatRegister dest) { vpPatchOpSimd128(v, lhs, dest, &X86Encoding::BaseAssemblerX86::vpcmpeqb_mr); } void MacroAssemblerX86::vpcmpgtbSimd128(const SimdConstant& v, FloatRegister lhs, FloatRegister dest) { vpPatchOpSimd128(v, lhs, dest, &X86Encoding::BaseAssemblerX86::vpcmpgtb_mr); } void MacroAssemblerX86::vpcmpeqwSimd128(const SimdConstant& v, FloatRegister lhs, FloatRegister dest) { vpPatchOpSimd128(v, lhs, dest, &X86Encoding::BaseAssemblerX86::vpcmpeqw_mr); } void MacroAssemblerX86::vpcmpgtwSimd128(const SimdConstant& v, FloatRegister lhs, FloatRegister dest) { vpPatchOpSimd128(v, lhs, dest, &X86Encoding::BaseAssemblerX86::vpcmpgtw_mr); } void MacroAssemblerX86::vpcmpeqdSimd128(const SimdConstant& v, FloatRegister lhs, FloatRegister dest) { vpPatchOpSimd128(v, lhs, dest, &X86Encoding::BaseAssemblerX86::vpcmpeqd_mr); } void MacroAssemblerX86::vpcmpgtdSimd128(const SimdConstant& v, FloatRegister lhs, FloatRegister dest) { vpPatchOpSimd128(v, lhs, dest, &X86Encoding::BaseAssemblerX86::vpcmpgtd_mr); } void MacroAssemblerX86::vcmpeqpsSimd128(const SimdConstant& v, FloatRegister lhs, FloatRegister dest) { vpPatchOpSimd128(v, lhs, dest, &X86Encoding::BaseAssemblerX86::vcmpeqps_mr); } void MacroAssemblerX86::vcmpneqpsSimd128(const SimdConstant& v, FloatRegister lhs, FloatRegister dest) { vpPatchOpSimd128(v, lhs, dest, &X86Encoding::BaseAssemblerX86::vcmpneqps_mr); } void MacroAssemblerX86::vcmpltpsSimd128(const SimdConstant& v, FloatRegister lhs, FloatRegister dest) { vpPatchOpSimd128(v, lhs, dest, &X86Encoding::BaseAssemblerX86::vcmpltps_mr); } void MacroAssemblerX86::vcmplepsSimd128(const SimdConstant& v, FloatRegister lhs, FloatRegister dest) { vpPatchOpSimd128(v, lhs, dest, &X86Encoding::BaseAssemblerX86::vcmpleps_mr); } void MacroAssemblerX86::vcmpgepsSimd128(const SimdConstant& v, FloatRegister lhs, FloatRegister dest) { vpPatchOpSimd128(v, lhs, dest, &X86Encoding::BaseAssemblerX86::vcmpgeps_mr); } void MacroAssemblerX86::vcmpeqpdSimd128(const SimdConstant& v, FloatRegister lhs, FloatRegister dest) { vpPatchOpSimd128(v, lhs, dest, &X86Encoding::BaseAssemblerX86::vcmpeqpd_mr); } void MacroAssemblerX86::vcmpneqpdSimd128(const SimdConstant& v, FloatRegister lhs, FloatRegister dest) { vpPatchOpSimd128(v, lhs, dest, &X86Encoding::BaseAssemblerX86::vcmpneqpd_mr); } void MacroAssemblerX86::vcmpltpdSimd128(const SimdConstant& v, FloatRegister lhs, FloatRegister dest) { vpPatchOpSimd128(v, lhs, dest, &X86Encoding::BaseAssemblerX86::vcmpltpd_mr); } void MacroAssemblerX86::vcmplepdSimd128(const SimdConstant& v, FloatRegister lhs, FloatRegister dest) { vpPatchOpSimd128(v, lhs, dest, &X86Encoding::BaseAssemblerX86::vcmplepd_mr); } void MacroAssemblerX86::vpmaddubswSimd128(const SimdConstant& v, FloatRegister lhs, FloatRegister dest) { vpPatchOpSimd128(v, lhs, dest, &X86Encoding::BaseAssemblerX86::vpmaddubsw_mr); } void MacroAssemblerX86::vpmuludqSimd128(const SimdConstant& v, FloatRegister lhs, FloatRegister dest) { vpPatchOpSimd128(v, lhs, dest, &X86Encoding::BaseAssemblerX86::vpmuludq_mr); } void MacroAssemblerX86::finish() { // Last instruction may be an indirect jump so eagerly insert an undefined // instruction byte to prevent processors from decoding data values into // their pipelines. See Intel performance guides. masm.ud2(); if (!doubles_.empty()) { masm.haltingAlign(sizeof(double)); } for (const Double& d : doubles_) { CodeOffset cst(masm.currentOffset()); for (CodeOffset use : d.uses) { addCodeLabel(CodeLabel(use, cst)); } masm.doubleConstant(d.value); if (!enoughMemory_) { return; } } if (!floats_.empty()) { masm.haltingAlign(sizeof(float)); } for (const Float& f : floats_) { CodeOffset cst(masm.currentOffset()); for (CodeOffset use : f.uses) { addCodeLabel(CodeLabel(use, cst)); } masm.floatConstant(f.value); if (!enoughMemory_) { return; } } // SIMD memory values must be suitably aligned. if (!simds_.empty()) { masm.haltingAlign(SimdMemoryAlignment); } for (const SimdData& v : simds_) { CodeOffset cst(masm.currentOffset()); for (CodeOffset use : v.uses) { addCodeLabel(CodeLabel(use, cst)); } masm.simd128Constant(v.value.bytes()); if (!enoughMemory_) { return; } } } void MacroAssemblerX86::handleFailureWithHandlerTail(Label* profilerExitTail, Label* bailoutTail) { // Reserve space for exception information. subl(Imm32(sizeof(ResumeFromException)), esp); movl(esp, eax); // Call the handler. using Fn = void (*)(ResumeFromException* rfe); asMasm().setupUnalignedABICall(ecx); asMasm().passABIArg(eax); asMasm().callWithABI( ABIType::General, CheckUnsafeCallWithABI::DontCheckHasExitFrame); Label entryFrame; Label catch_; Label finally; Label returnBaseline; Label returnIon; Label bailout; Label wasm; Label wasmCatch; loadPtr(Address(esp, ResumeFromException::offsetOfKind()), eax); asMasm().branch32(Assembler::Equal, eax, Imm32(ExceptionResumeKind::EntryFrame), &entryFrame); asMasm().branch32(Assembler::Equal, eax, Imm32(ExceptionResumeKind::Catch), &catch_); asMasm().branch32(Assembler::Equal, eax, Imm32(ExceptionResumeKind::Finally), &finally); asMasm().branch32(Assembler::Equal, eax, Imm32(ExceptionResumeKind::ForcedReturnBaseline), &returnBaseline); asMasm().branch32(Assembler::Equal, eax, Imm32(ExceptionResumeKind::ForcedReturnIon), &returnIon); asMasm().branch32(Assembler::Equal, eax, Imm32(ExceptionResumeKind::Bailout), &bailout); asMasm().branch32(Assembler::Equal, eax, Imm32(ExceptionResumeKind::Wasm), &wasm); asMasm().branch32(Assembler::Equal, eax, Imm32(ExceptionResumeKind::WasmCatch), &wasmCatch); breakpoint(); // Invalid kind. // No exception handler. Load the error value, restore state and return from // the entry frame. bind(&entryFrame); asMasm().moveValue(MagicValue(JS_ION_ERROR), JSReturnOperand); loadPtr(Address(esp, ResumeFromException::offsetOfFramePointer()), ebp); loadPtr(Address(esp, ResumeFromException::offsetOfStackPointer()), esp); ret(); // If we found a catch handler, this must be a baseline frame. Restore state // and jump to the catch block. bind(&catch_); loadPtr(Address(esp, ResumeFromException::offsetOfTarget()), eax); loadPtr(Address(esp, ResumeFromException::offsetOfFramePointer()), ebp); loadPtr(Address(esp, ResumeFromException::offsetOfStackPointer()), esp); jmp(Operand(eax)); // If we found a finally block, this must be a baseline frame. Push three // values expected by the finally block: the exception, the exception stack, // and BooleanValue(true). bind(&finally); ValueOperand exception = ValueOperand(ecx, edx); loadValue(Address(esp, ResumeFromException::offsetOfException()), exception); ValueOperand exceptionStack = ValueOperand(esi, edi); loadValue(Address(esp, ResumeFromException::offsetOfExceptionStack()), exceptionStack); loadPtr(Address(esp, ResumeFromException::offsetOfTarget()), eax); loadPtr(Address(esp, ResumeFromException::offsetOfFramePointer()), ebp); loadPtr(Address(esp, ResumeFromException::offsetOfStackPointer()), esp); pushValue(exception); pushValue(exceptionStack); pushValue(BooleanValue(true)); jmp(Operand(eax)); // Return BaselineFrame->returnValue() to the caller. // Used in debug mode and for GeneratorReturn. Label profilingInstrumentation; bind(&returnBaseline); loadPtr(Address(esp, ResumeFromException::offsetOfFramePointer()), ebp); loadPtr(Address(esp, ResumeFromException::offsetOfStackPointer()), esp); loadValue(Address(ebp, BaselineFrame::reverseOffsetOfReturnValue()), JSReturnOperand); jump(&profilingInstrumentation); // Return the given value to the caller. bind(&returnIon); loadValue(Address(esp, ResumeFromException::offsetOfException()), JSReturnOperand); loadPtr(Address(esp, ResumeFromException::offsetOfFramePointer()), ebp); loadPtr(Address(esp, ResumeFromException::offsetOfStackPointer()), esp); // If profiling is enabled, then update the lastProfilingFrame to refer to // caller frame before returning. This code is shared by ForcedReturnIon // and ForcedReturnBaseline. bind(&profilingInstrumentation); { Label skipProfilingInstrumentation; // Test if profiler enabled. AbsoluteAddress addressOfEnabled( asMasm().runtime()->geckoProfiler().addressOfEnabled()); asMasm().branch32(Assembler::Equal, addressOfEnabled, Imm32(0), &skipProfilingInstrumentation); jump(profilerExitTail); bind(&skipProfilingInstrumentation); } movl(ebp, esp); pop(ebp); ret(); // If we are bailing out to baseline to handle an exception, jump to the // bailout tail stub. Load 1 (true) in ReturnReg to indicate success. bind(&bailout); loadPtr(Address(esp, ResumeFromException::offsetOfBailoutInfo()), ecx); loadPtr(Address(esp, ResumeFromException::offsetOfStackPointer()), esp); move32(Imm32(1), ReturnReg); jump(bailoutTail); // If we are throwing and the innermost frame was a wasm frame, reset SP and // FP; SP is pointing to the unwound return address to the wasm entry, so // we can just ret(). bind(&wasm); loadPtr(Address(esp, ResumeFromException::offsetOfFramePointer()), ebp); loadPtr(Address(esp, ResumeFromException::offsetOfStackPointer()), esp); movePtr(ImmPtr((const void*)wasm::FailInstanceReg), InstanceReg); masm.ret(); // Found a wasm catch handler, restore state and jump to it. bind(&wasmCatch); loadPtr(Address(esp, ResumeFromException::offsetOfTarget()), eax); loadPtr(Address(esp, ResumeFromException::offsetOfFramePointer()), ebp); loadPtr(Address(esp, ResumeFromException::offsetOfStackPointer()), esp); jmp(Operand(eax)); } void MacroAssemblerX86::profilerEnterFrame(Register framePtr, Register scratch) { asMasm().loadJSContext(scratch); loadPtr(Address(scratch, offsetof(JSContext, profilingActivation_)), scratch); storePtr(framePtr, Address(scratch, JitActivation::offsetOfLastProfilingFrame())); storePtr(ImmPtr(nullptr), Address(scratch, JitActivation::offsetOfLastProfilingCallSite())); } void MacroAssemblerX86::profilerExitFrame() { jump(asMasm().runtime()->jitRuntime()->getProfilerExitFrameTail()); } Assembler::Condition MacroAssemblerX86::testStringTruthy( bool truthy, const ValueOperand& value) { Register string = value.payloadReg(); cmp32(Operand(string, JSString::offsetOfLength()), Imm32(0)); return truthy ? Assembler::NotEqual : Assembler::Equal; } Assembler::Condition MacroAssemblerX86::testBigIntTruthy( bool truthy, const ValueOperand& value) { Register bi = value.payloadReg(); cmp32(Operand(bi, JS::BigInt::offsetOfDigitLength()), Imm32(0)); return truthy ? Assembler::NotEqual : Assembler::Equal; } MacroAssembler& MacroAssemblerX86::asMasm() { return *static_cast(this); } const MacroAssembler& MacroAssemblerX86::asMasm() const { return *static_cast(this); } void MacroAssembler::subFromStackPtr(Imm32 imm32) { if (imm32.value) { // On windows, we cannot skip very far down the stack without touching the // memory pages in-between. This is a corner-case code for situations where // the Ion frame data for a piece of code is very large. To handle this // special case, for frames over 4k in size we allocate memory on the stack // incrementally, touching it as we go. // // When the amount is quite large, which it can be, we emit an actual loop, // in order to keep the function prologue compact. Compactness is a // requirement for eg Wasm's CodeRange data structure, which can encode only // 8-bit offsets. uint32_t amountLeft = imm32.value; uint32_t fullPages = amountLeft / 4096; if (fullPages <= 8) { while (amountLeft > 4096) { subl(Imm32(4096), StackPointer); store32(Imm32(0), Address(StackPointer, 0)); amountLeft -= 4096; } subl(Imm32(amountLeft), StackPointer); } else { // Save scratch register. push(eax); amountLeft -= 4; fullPages = amountLeft / 4096; Label top; move32(Imm32(fullPages), eax); bind(&top); subl(Imm32(4096), StackPointer); store32(Imm32(0), Address(StackPointer, 0)); subl(Imm32(1), eax); j(Assembler::NonZero, &top); amountLeft -= fullPages * 4096; if (amountLeft) { subl(Imm32(amountLeft), StackPointer); } // Restore scratch register. movl(Operand(StackPointer, uint32_t(imm32.value) - 4), eax); } } } //{{{ check_macroassembler_style // =============================================================== // ABI function calls. void MacroAssembler::setupUnalignedABICall(Register scratch) { setupNativeABICall(); dynamicAlignment_ = true; movl(esp, scratch); andl(Imm32(~(ABIStackAlignment - 1)), esp); push(scratch); } void MacroAssembler::callWithABIPre(uint32_t* stackAdjust, bool callFromWasm) { MOZ_ASSERT(inCall_); uint32_t stackForCall = abiArgs_.stackBytesConsumedSoFar(); if (dynamicAlignment_) { // sizeof(intptr_t) accounts for the saved stack pointer pushed by // setupUnalignedABICall. stackForCall += ComputeByteAlignment(stackForCall + sizeof(intptr_t), ABIStackAlignment); } else { uint32_t alignmentAtPrologue = callFromWasm ? sizeof(wasm::Frame) : 0; stackForCall += ComputeByteAlignment( stackForCall + framePushed() + alignmentAtPrologue, ABIStackAlignment); } *stackAdjust = stackForCall; reserveStack(stackForCall); // Position all arguments. { enoughMemory_ &= moveResolver_.resolve(); if (!enoughMemory_) { return; } MoveEmitter emitter(*this); emitter.emit(moveResolver_); emitter.finish(); } assertStackAlignment(ABIStackAlignment); } void MacroAssembler::callWithABIPost(uint32_t stackAdjust, ABIType result, bool callFromWasm) { freeStack(stackAdjust); // Calls to native functions in wasm pass through a thunk which already // fixes up the return value for us. if (!callFromWasm) { if (result == ABIType::Float64) { reserveStack(sizeof(double)); fstp(Operand(esp, 0)); loadDouble(Operand(esp, 0), ReturnDoubleReg); freeStack(sizeof(double)); } else if (result == ABIType::Float32) { reserveStack(sizeof(float)); fstp32(Operand(esp, 0)); loadFloat32(Operand(esp, 0), ReturnFloat32Reg); freeStack(sizeof(float)); } } if (dynamicAlignment_) { pop(esp); } #ifdef DEBUG MOZ_ASSERT(inCall_); inCall_ = false; #endif } void MacroAssembler::callWithABINoProfiler(Register fun, ABIType result) { uint32_t stackAdjust; callWithABIPre(&stackAdjust); call(fun); callWithABIPost(stackAdjust, result); } void MacroAssembler::callWithABINoProfiler(const Address& fun, ABIType result) { uint32_t stackAdjust; callWithABIPre(&stackAdjust); call(fun); callWithABIPost(stackAdjust, result); } // =============================================================== // Move instructions void MacroAssembler::moveValue(const TypedOrValueRegister& src, const ValueOperand& dest) { if (src.hasValue()) { moveValue(src.valueReg(), dest); return; } MIRType type = src.type(); AnyRegister reg = src.typedReg(); if (!IsFloatingPointType(type)) { if (reg.gpr() != dest.payloadReg()) { movl(reg.gpr(), dest.payloadReg()); } mov(ImmWord(MIRTypeToTag(type)), dest.typeReg()); return; } ScratchDoubleScope scratch(*this); FloatRegister freg = reg.fpu(); if (type == MIRType::Float32) { convertFloat32ToDouble(freg, scratch); freg = scratch; } boxDouble(freg, dest, scratch); } void MacroAssembler::moveValue(const ValueOperand& src, const ValueOperand& dest) { Register s0 = src.typeReg(); Register s1 = src.payloadReg(); Register d0 = dest.typeReg(); Register d1 = dest.payloadReg(); // Either one or both of the source registers could be the same as a // destination register. if (s1 == d0) { if (s0 == d1) { // If both are, this is just a swap of two registers. xchgl(d0, d1); return; } // If only one is, copy that source first. std::swap(s0, s1); std::swap(d0, d1); } if (s0 != d0) { movl(s0, d0); } if (s1 != d1) { movl(s1, d1); } } void MacroAssembler::moveValue(const Value& src, const ValueOperand& dest) { movl(Imm32(src.toNunboxTag()), dest.typeReg()); if (src.isGCThing()) { movl(ImmGCPtr(src.toGCThing()), dest.payloadReg()); } else { movl(Imm32(src.toNunboxPayload()), dest.payloadReg()); } } // =============================================================== // Branch functions void MacroAssembler::loadStoreBuffer(Register ptr, Register buffer) { if (ptr != buffer) { movePtr(ptr, buffer); } andPtr(Imm32(~gc::ChunkMask), buffer); loadPtr(Address(buffer, gc::ChunkStoreBufferOffset), buffer); } void MacroAssembler::branchPtrInNurseryChunk(Condition cond, Register ptr, Register temp, Label* label) { MOZ_ASSERT(temp != InvalidReg); // A temp register is required for x86. MOZ_ASSERT(ptr != temp); movePtr(ptr, temp); branchPtrInNurseryChunkImpl(cond, temp, label); } void MacroAssembler::branchPtrInNurseryChunk(Condition cond, const Address& address, Register temp, Label* label) { MOZ_ASSERT(temp != InvalidReg); // A temp register is required for x86. loadPtr(address, temp); branchPtrInNurseryChunkImpl(cond, temp, label); } void MacroAssembler::branchPtrInNurseryChunkImpl(Condition cond, Register ptr, Label* label) { MOZ_ASSERT(cond == Assembler::Equal || cond == Assembler::NotEqual); andPtr(Imm32(~gc::ChunkMask), ptr); branchPtr(InvertCondition(cond), Address(ptr, gc::ChunkStoreBufferOffset), ImmWord(0), label); } void MacroAssembler::branchValueIsNurseryCell(Condition cond, const Address& address, Register temp, Label* label) { MOZ_ASSERT(cond == Assembler::Equal || cond == Assembler::NotEqual); Label done; branchTestGCThing(Assembler::NotEqual, address, cond == Assembler::Equal ? &done : label); branchPtrInNurseryChunk(cond, ToPayload(address), temp, label); bind(&done); } void MacroAssembler::branchValueIsNurseryCell(Condition cond, ValueOperand value, Register temp, Label* label) { MOZ_ASSERT(cond == Assembler::Equal || cond == Assembler::NotEqual); Label done; branchTestGCThing(Assembler::NotEqual, value, cond == Assembler::Equal ? &done : label); branchPtrInNurseryChunk(cond, value.payloadReg(), temp, label); bind(&done); } void MacroAssembler::branchTestValue(Condition cond, const ValueOperand& lhs, const Value& rhs, Label* label) { MOZ_ASSERT(cond == Equal || cond == NotEqual); if (rhs.isGCThing()) { cmpPtr(lhs.payloadReg(), ImmGCPtr(rhs.toGCThing())); } else { cmpPtr(lhs.payloadReg(), ImmWord(rhs.toNunboxPayload())); } if (cond == Equal) { Label done; j(NotEqual, &done); { cmp32(lhs.typeReg(), Imm32(rhs.toNunboxTag())); j(Equal, label); } bind(&done); } else { j(NotEqual, label); cmp32(lhs.typeReg(), Imm32(rhs.toNunboxTag())); j(NotEqual, label); } } // ======================================================================== // Memory access primitives. template void MacroAssembler::storeUnboxedValue(const ConstantOrRegister& value, MIRType valueType, const T& dest) { MOZ_ASSERT(valueType < MIRType::Value); if (valueType == MIRType::Double) { storeDouble(value.reg().typedReg().fpu(), dest); return; } // Store the type tag. storeTypeTag(ImmType(ValueTypeFromMIRType(valueType)), Operand(dest)); // Store the payload. if (value.constant()) { storePayload(value.value(), Operand(dest)); } else { storePayload(value.reg().typedReg().gpr(), Operand(dest)); } } template void MacroAssembler::storeUnboxedValue(const ConstantOrRegister& value, MIRType valueType, const Address& dest); template void MacroAssembler::storeUnboxedValue( const ConstantOrRegister& value, MIRType valueType, const BaseObjectElementIndex& dest); // wasm specific methods, used in both the wasm baseline compiler and ion. void MacroAssembler::wasmLoad(const wasm::MemoryAccessDesc& access, Operand srcAddr, AnyRegister out) { MOZ_ASSERT(srcAddr.kind() == Operand::MEM_REG_DISP || srcAddr.kind() == Operand::MEM_SCALE); MOZ_ASSERT_IF( access.isZeroExtendSimd128Load(), access.type() == Scalar::Float32 || access.type() == Scalar::Float64); MOZ_ASSERT_IF( access.isSplatSimd128Load(), access.type() == Scalar::Uint8 || access.type() == Scalar::Uint16 || access.type() == Scalar::Float32 || access.type() == Scalar::Float64); MOZ_ASSERT_IF(access.isWidenSimd128Load(), access.type() == Scalar::Float64); // NOTE: the generated code must match the assembly code in gen_load in // GenerateAtomicOperations.py memoryBarrierBefore(access.sync()); switch (access.type()) { case Scalar::Int8: append(access, wasm::TrapMachineInsn::Load8, FaultingCodeOffset(currentOffset())); movsbl(srcAddr, out.gpr()); break; case Scalar::Uint8: append(access, wasm::TrapMachineInsn::Load8, FaultingCodeOffset(currentOffset())); if (access.isSplatSimd128Load()) { vbroadcastb(srcAddr, out.fpu()); } else { movzbl(srcAddr, out.gpr()); } break; case Scalar::Int16: append(access, wasm::TrapMachineInsn::Load16, FaultingCodeOffset(currentOffset())); movswl(srcAddr, out.gpr()); break; case Scalar::Uint16: append(access, wasm::TrapMachineInsn::Load16, FaultingCodeOffset(currentOffset())); if (access.isSplatSimd128Load()) { vbroadcastw(srcAddr, out.fpu()); } else { movzwl(srcAddr, out.gpr()); } break; case Scalar::Int32: case Scalar::Uint32: append(access, wasm::TrapMachineInsn::Load32, FaultingCodeOffset(currentOffset())); movl(srcAddr, out.gpr()); break; case Scalar::Float32: append(access, wasm::TrapMachineInsn::Load32, FaultingCodeOffset(currentOffset())); if (access.isSplatSimd128Load()) { vbroadcastss(srcAddr, out.fpu()); } else { // vmovss does the right thing also for access.isZeroExtendSimd128Load() vmovss(srcAddr, out.fpu()); } break; case Scalar::Float64: append(access, wasm::TrapMachineInsn::Load64, FaultingCodeOffset(currentOffset())); if (access.isSplatSimd128Load()) { vmovddup(srcAddr, out.fpu()); } else if (access.isWidenSimd128Load()) { switch (access.widenSimdOp()) { case wasm::SimdOp::V128Load8x8S: vpmovsxbw(srcAddr, out.fpu()); break; case wasm::SimdOp::V128Load8x8U: vpmovzxbw(srcAddr, out.fpu()); break; case wasm::SimdOp::V128Load16x4S: vpmovsxwd(srcAddr, out.fpu()); break; case wasm::SimdOp::V128Load16x4U: vpmovzxwd(srcAddr, out.fpu()); break; case wasm::SimdOp::V128Load32x2S: vpmovsxdq(srcAddr, out.fpu()); break; case wasm::SimdOp::V128Load32x2U: vpmovzxdq(srcAddr, out.fpu()); break; default: MOZ_CRASH("Unexpected widening op for wasmLoad"); } } else { // vmovsd does the right thing also for access.isZeroExtendSimd128Load() vmovsd(srcAddr, out.fpu()); } break; case Scalar::Simd128: append(access, wasm::TrapMachineInsn::Load128, FaultingCodeOffset(currentOffset())); vmovups(srcAddr, out.fpu()); break; case Scalar::Int64: case Scalar::Uint8Clamped: case Scalar::BigInt64: case Scalar::BigUint64: case Scalar::MaxTypedArrayViewType: MOZ_CRASH("unexpected type"); } memoryBarrierAfter(access.sync()); } void MacroAssembler::wasmLoadI64(const wasm::MemoryAccessDesc& access, Operand srcAddr, Register64 out) { // Atomic i64 load must use lock_cmpxchg8b. MOZ_ASSERT_IF(access.isAtomic(), access.byteSize() <= 4); MOZ_ASSERT(srcAddr.kind() == Operand::MEM_REG_DISP || srcAddr.kind() == Operand::MEM_SCALE); MOZ_ASSERT(!access.isZeroExtendSimd128Load()); // Use wasmLoad() MOZ_ASSERT(!access.isSplatSimd128Load()); // Use wasmLoad() MOZ_ASSERT(!access.isWidenSimd128Load()); // Use wasmLoad() memoryBarrierBefore(access.sync()); switch (access.type()) { case Scalar::Int8: MOZ_ASSERT(out == Register64(edx, eax)); append(access, wasm::TrapMachineInsn::Load8, FaultingCodeOffset(currentOffset())); movsbl(srcAddr, out.low); cdq(); break; case Scalar::Uint8: append(access, wasm::TrapMachineInsn::Load8, FaultingCodeOffset(currentOffset())); movzbl(srcAddr, out.low); xorl(out.high, out.high); break; case Scalar::Int16: MOZ_ASSERT(out == Register64(edx, eax)); append(access, wasm::TrapMachineInsn::Load16, FaultingCodeOffset(currentOffset())); movswl(srcAddr, out.low); cdq(); break; case Scalar::Uint16: append(access, wasm::TrapMachineInsn::Load16, FaultingCodeOffset(currentOffset())); movzwl(srcAddr, out.low); xorl(out.high, out.high); break; case Scalar::Int32: MOZ_ASSERT(out == Register64(edx, eax)); append(access, wasm::TrapMachineInsn::Load32, FaultingCodeOffset(currentOffset())); movl(srcAddr, out.low); cdq(); break; case Scalar::Uint32: append(access, wasm::TrapMachineInsn::Load32, FaultingCodeOffset(currentOffset())); movl(srcAddr, out.low); xorl(out.high, out.high); break; case Scalar::Int64: { if (srcAddr.kind() == Operand::MEM_SCALE) { MOZ_RELEASE_ASSERT(srcAddr.toBaseIndex().base != out.low && srcAddr.toBaseIndex().index != out.low); } if (srcAddr.kind() == Operand::MEM_REG_DISP) { MOZ_RELEASE_ASSERT(srcAddr.toAddress().base != out.low); } append(access, wasm::TrapMachineInsn::Load32, FaultingCodeOffset(currentOffset())); movl(LowWord(srcAddr), out.low); append(access, wasm::TrapMachineInsn::Load32, FaultingCodeOffset(currentOffset())); movl(HighWord(srcAddr), out.high); break; } case Scalar::Float32: case Scalar::Float64: MOZ_CRASH("non-int64 loads should use load()"); case Scalar::Simd128: case Scalar::Uint8Clamped: case Scalar::BigInt64: case Scalar::BigUint64: case Scalar::MaxTypedArrayViewType: MOZ_CRASH("unexpected array type"); } memoryBarrierAfter(access.sync()); } void MacroAssembler::wasmStore(const wasm::MemoryAccessDesc& access, AnyRegister value, Operand dstAddr) { MOZ_ASSERT(dstAddr.kind() == Operand::MEM_REG_DISP || dstAddr.kind() == Operand::MEM_SCALE); // NOTE: the generated code must match the assembly code in gen_store in // GenerateAtomicOperations.py memoryBarrierBefore(access.sync()); switch (access.type()) { case Scalar::Int8: case Scalar::Uint8Clamped: case Scalar::Uint8: append(access, wasm::TrapMachineInsn::Store8, FaultingCodeOffset(currentOffset())); // FIXME figure out where this movb goes movb(value.gpr(), dstAddr); break; case Scalar::Int16: case Scalar::Uint16: append(access, wasm::TrapMachineInsn::Store16, FaultingCodeOffset(currentOffset())); movw(value.gpr(), dstAddr); break; case Scalar::Int32: case Scalar::Uint32: append(access, wasm::TrapMachineInsn::Store32, FaultingCodeOffset(currentOffset())); movl(value.gpr(), dstAddr); break; case Scalar::Float32: append(access, wasm::TrapMachineInsn::Store32, FaultingCodeOffset(currentOffset())); vmovss(value.fpu(), dstAddr); break; case Scalar::Float64: append(access, wasm::TrapMachineInsn::Store64, FaultingCodeOffset(currentOffset())); vmovsd(value.fpu(), dstAddr); break; case Scalar::Simd128: append(access, wasm::TrapMachineInsn::Store128, FaultingCodeOffset(currentOffset())); vmovups(value.fpu(), dstAddr); break; case Scalar::Int64: MOZ_CRASH("Should be handled in storeI64."); case Scalar::MaxTypedArrayViewType: case Scalar::BigInt64: case Scalar::BigUint64: MOZ_CRASH("unexpected type"); } memoryBarrierAfter(access.sync()); } void MacroAssembler::wasmStoreI64(const wasm::MemoryAccessDesc& access, Register64 value, Operand dstAddr) { // Atomic i64 store must use lock_cmpxchg8b. MOZ_ASSERT(!access.isAtomic()); MOZ_ASSERT(dstAddr.kind() == Operand::MEM_REG_DISP || dstAddr.kind() == Operand::MEM_SCALE); // Store the high word first so as to hit guard-page-based OOB checks without // writing partial data. append(access, wasm::TrapMachineInsn::Store32, FaultingCodeOffset(currentOffset())); movl(value.high, HighWord(dstAddr)); append(access, wasm::TrapMachineInsn::Store32, FaultingCodeOffset(currentOffset())); movl(value.low, LowWord(dstAddr)); } template static void AtomicLoad64(MacroAssembler& masm, const wasm::MemoryAccessDesc* access, const T& address, Register64 temp, Register64 output) { MOZ_ASSERT(temp.low == ebx); MOZ_ASSERT(temp.high == ecx); MOZ_ASSERT(output.high == edx); MOZ_ASSERT(output.low == eax); // In the event edx:eax matches what's in memory, ecx:ebx will be // stored. The two pairs must therefore have the same values. masm.movl(edx, ecx); masm.movl(eax, ebx); if (access) { masm.append(*access, wasm::TrapMachineInsn::Atomic, FaultingCodeOffset(masm.currentOffset())); } masm.lock_cmpxchg8b(edx, eax, ecx, ebx, Operand(address)); } void MacroAssembler::wasmAtomicLoad64(const wasm::MemoryAccessDesc& access, const Address& mem, Register64 temp, Register64 output) { AtomicLoad64(*this, &access, mem, temp, output); } void MacroAssembler::wasmAtomicLoad64(const wasm::MemoryAccessDesc& access, const BaseIndex& mem, Register64 temp, Register64 output) { AtomicLoad64(*this, &access, mem, temp, output); } template static void CompareExchange64(MacroAssembler& masm, const wasm::MemoryAccessDesc* access, const T& mem, Register64 expected, Register64 replacement, Register64 output) { MOZ_ASSERT(expected == output); MOZ_ASSERT(expected.high == edx); MOZ_ASSERT(expected.low == eax); MOZ_ASSERT(replacement.high == ecx); MOZ_ASSERT(replacement.low == ebx); // NOTE: the generated code must match the assembly code in gen_cmpxchg in // GenerateAtomicOperations.py if (access) { masm.append(*access, wasm::TrapMachineInsn::Atomic, FaultingCodeOffset(masm.currentOffset())); } masm.lock_cmpxchg8b(edx, eax, ecx, ebx, Operand(mem)); } void MacroAssembler::wasmCompareExchange64(const wasm::MemoryAccessDesc& access, const Address& mem, Register64 expected, Register64 replacement, Register64 output) { CompareExchange64(*this, &access, mem, expected, replacement, output); } void MacroAssembler::wasmCompareExchange64(const wasm::MemoryAccessDesc& access, const BaseIndex& mem, Register64 expected, Register64 replacement, Register64 output) { CompareExchange64(*this, &access, mem, expected, replacement, output); } template static void AtomicExchange64(MacroAssembler& masm, const wasm::MemoryAccessDesc* access, const T& mem, Register64 value, Register64 output) { MOZ_ASSERT(value.low == ebx); MOZ_ASSERT(value.high == ecx); MOZ_ASSERT(output.high == edx); MOZ_ASSERT(output.low == eax); // edx:eax has garbage initially, and that is the best we can do unless // we can guess with high probability what's in memory. MOZ_ASSERT(mem.base != edx && mem.base != eax); if constexpr (std::is_same_v) { MOZ_ASSERT(mem.index != edx && mem.index != eax); } else { static_assert(std::is_same_v); } Label again; masm.bind(&again); if (access) { masm.append(*access, wasm::TrapMachineInsn::Atomic, FaultingCodeOffset(masm.currentOffset())); } masm.lock_cmpxchg8b(edx, eax, ecx, ebx, Operand(mem)); masm.j(MacroAssembler::NonZero, &again); } void MacroAssembler::wasmAtomicExchange64(const wasm::MemoryAccessDesc& access, const Address& mem, Register64 value, Register64 output) { AtomicExchange64(*this, &access, mem, value, output); } void MacroAssembler::wasmAtomicExchange64(const wasm::MemoryAccessDesc& access, const BaseIndex& mem, Register64 value, Register64 output) { AtomicExchange64(*this, &access, mem, value, output); } template static void AtomicFetchOp64(MacroAssembler& masm, const wasm::MemoryAccessDesc* access, AtomicOp op, const Address& value, const T& mem, Register64 temp, Register64 output) { // We don't have enough registers for all the operands on x86, so the rhs // operand is in memory. #define ATOMIC_OP_BODY(OPERATE) \ do { \ MOZ_ASSERT(output.low == eax); \ MOZ_ASSERT(output.high == edx); \ MOZ_ASSERT(temp.low == ebx); \ MOZ_ASSERT(temp.high == ecx); \ FaultingCodeOffsetPair fcop = masm.load64(mem, output); \ if (access) { \ masm.append(*access, wasm::TrapMachineInsn::Load32, fcop.first); \ masm.append(*access, wasm::TrapMachineInsn::Load32, fcop.second); \ } \ Label again; \ masm.bind(&again); \ masm.move64(output, temp); \ masm.OPERATE(Operand(value), temp); \ masm.lock_cmpxchg8b(edx, eax, ecx, ebx, Operand(mem)); \ masm.j(MacroAssembler::NonZero, &again); \ } while (0) switch (op) { case AtomicFetchAddOp: ATOMIC_OP_BODY(add64FromMemory); break; case AtomicFetchSubOp: ATOMIC_OP_BODY(sub64FromMemory); break; case AtomicFetchAndOp: ATOMIC_OP_BODY(and64FromMemory); break; case AtomicFetchOrOp: ATOMIC_OP_BODY(or64FromMemory); break; case AtomicFetchXorOp: ATOMIC_OP_BODY(xor64FromMemory); break; default: MOZ_CRASH(); } #undef ATOMIC_OP_BODY } void MacroAssembler::wasmAtomicFetchOp64(const wasm::MemoryAccessDesc& access, AtomicOp op, const Address& value, const Address& mem, Register64 temp, Register64 output) { AtomicFetchOp64(*this, &access, op, value, mem, temp, output); } void MacroAssembler::wasmAtomicFetchOp64(const wasm::MemoryAccessDesc& access, AtomicOp op, const Address& value, const BaseIndex& mem, Register64 temp, Register64 output) { AtomicFetchOp64(*this, &access, op, value, mem, temp, output); } void MacroAssembler::wasmTruncateDoubleToUInt32(FloatRegister input, Register output, bool isSaturating, Label* oolEntry) { Label done; vcvttsd2si(input, output); branch32(Assembler::Condition::NotSigned, output, Imm32(0), &done); ScratchDoubleScope fpscratch(*this); loadConstantDouble(double(int32_t(0x80000000)), fpscratch); addDouble(input, fpscratch); vcvttsd2si(fpscratch, output); branch32(Assembler::Condition::Signed, output, Imm32(0), oolEntry); or32(Imm32(0x80000000), output); bind(&done); } void MacroAssembler::wasmTruncateFloat32ToUInt32(FloatRegister input, Register output, bool isSaturating, Label* oolEntry) { Label done; vcvttss2si(input, output); branch32(Assembler::Condition::NotSigned, output, Imm32(0), &done); ScratchFloat32Scope fpscratch(*this); loadConstantFloat32(float(int32_t(0x80000000)), fpscratch); addFloat32(input, fpscratch); vcvttss2si(fpscratch, output); branch32(Assembler::Condition::Signed, output, Imm32(0), oolEntry); or32(Imm32(0x80000000), output); bind(&done); } void MacroAssembler::wasmTruncateDoubleToInt64( FloatRegister input, Register64 output, bool isSaturating, Label* oolEntry, Label* oolRejoin, FloatRegister tempReg) { Label ok; Register temp = output.high; reserveStack(2 * sizeof(int32_t)); storeDouble(input, Operand(esp, 0)); truncateDoubleToInt64(Address(esp, 0), Address(esp, 0), temp); load64(Address(esp, 0), output); cmpl(Imm32(0), Operand(esp, 0)); j(Assembler::NotEqual, &ok); cmpl(Imm32(1), Operand(esp, 4)); j(Assembler::Overflow, oolEntry); bind(&ok); bind(oolRejoin); freeStack(2 * sizeof(int32_t)); } void MacroAssembler::wasmTruncateFloat32ToInt64( FloatRegister input, Register64 output, bool isSaturating, Label* oolEntry, Label* oolRejoin, FloatRegister tempReg) { Label ok; Register temp = output.high; reserveStack(2 * sizeof(int32_t)); storeFloat32(input, Operand(esp, 0)); truncateFloat32ToInt64(Address(esp, 0), Address(esp, 0), temp); load64(Address(esp, 0), output); cmpl(Imm32(0), Operand(esp, 0)); j(Assembler::NotEqual, &ok); cmpl(Imm32(1), Operand(esp, 4)); j(Assembler::Overflow, oolEntry); bind(&ok); bind(oolRejoin); freeStack(2 * sizeof(int32_t)); } void MacroAssembler::wasmTruncateDoubleToUInt64( FloatRegister input, Register64 output, bool isSaturating, Label* oolEntry, Label* oolRejoin, FloatRegister tempReg) { Label fail, convert; Register temp = output.high; // Make sure input fits in uint64. reserveStack(2 * sizeof(int32_t)); storeDouble(input, Operand(esp, 0)); branchDoubleNotInUInt64Range(Address(esp, 0), temp, &fail); size_t stackBeforeBranch = framePushed(); jump(&convert); bind(&fail); freeStack(2 * sizeof(int32_t)); jump(oolEntry); if (isSaturating) { // The OOL path computes the right values. setFramePushed(stackBeforeBranch); } else { // The OOL path just checks the input values. bind(oolRejoin); reserveStack(2 * sizeof(int32_t)); storeDouble(input, Operand(esp, 0)); } // Convert the double/float to uint64. bind(&convert); truncateDoubleToUInt64(Address(esp, 0), Address(esp, 0), temp, tempReg); // Load value into int64 register. load64(Address(esp, 0), output); freeStack(2 * sizeof(int32_t)); if (isSaturating) { bind(oolRejoin); } } void MacroAssembler::wasmTruncateFloat32ToUInt64( FloatRegister input, Register64 output, bool isSaturating, Label* oolEntry, Label* oolRejoin, FloatRegister tempReg) { Label fail, convert; Register temp = output.high; // Make sure input fits in uint64. reserveStack(2 * sizeof(int32_t)); storeFloat32(input, Operand(esp, 0)); branchFloat32NotInUInt64Range(Address(esp, 0), temp, &fail); size_t stackBeforeBranch = framePushed(); jump(&convert); bind(&fail); freeStack(2 * sizeof(int32_t)); jump(oolEntry); if (isSaturating) { // The OOL path computes the right values. setFramePushed(stackBeforeBranch); } else { // The OOL path just checks the input values. bind(oolRejoin); reserveStack(2 * sizeof(int32_t)); storeFloat32(input, Operand(esp, 0)); } // Convert the float to uint64. bind(&convert); truncateFloat32ToUInt64(Address(esp, 0), Address(esp, 0), temp, tempReg); // Load value into int64 register. load64(Address(esp, 0), output); freeStack(2 * sizeof(int32_t)); if (isSaturating) { bind(oolRejoin); } } // ======================================================================== // Primitive atomic operations. void MacroAssembler::atomicLoad64(const Synchronization&, const Address& mem, Register64 temp, Register64 output) { AtomicLoad64(*this, nullptr, mem, temp, output); } void MacroAssembler::atomicLoad64(const Synchronization&, const BaseIndex& mem, Register64 temp, Register64 output) { AtomicLoad64(*this, nullptr, mem, temp, output); } void MacroAssembler::atomicStore64(const Synchronization&, const Address& mem, Register64 value, Register64 temp) { AtomicExchange64(*this, nullptr, mem, value, temp); } void MacroAssembler::atomicStore64(const Synchronization&, const BaseIndex& mem, Register64 value, Register64 temp) { AtomicExchange64(*this, nullptr, mem, value, temp); } void MacroAssembler::compareExchange64(const Synchronization&, const Address& mem, Register64 expected, Register64 replacement, Register64 output) { CompareExchange64(*this, nullptr, mem, expected, replacement, output); } void MacroAssembler::compareExchange64(const Synchronization&, const BaseIndex& mem, Register64 expected, Register64 replacement, Register64 output) { CompareExchange64(*this, nullptr, mem, expected, replacement, output); } void MacroAssembler::atomicExchange64(const Synchronization&, const Address& mem, Register64 value, Register64 output) { AtomicExchange64(*this, nullptr, mem, value, output); } void MacroAssembler::atomicExchange64(const Synchronization&, const BaseIndex& mem, Register64 value, Register64 output) { AtomicExchange64(*this, nullptr, mem, value, output); } void MacroAssembler::atomicFetchOp64(const Synchronization&, AtomicOp op, const Address& value, const Address& mem, Register64 temp, Register64 output) { AtomicFetchOp64(*this, nullptr, op, value, mem, temp, output); } void MacroAssembler::atomicFetchOp64(const Synchronization&, AtomicOp op, const Address& value, const BaseIndex& mem, Register64 temp, Register64 output) { AtomicFetchOp64(*this, nullptr, op, value, mem, temp, output); } // ======================================================================== // Convert floating point. bool MacroAssembler::convertUInt64ToDoubleNeedsTemp() { return HasSSE3(); } void MacroAssembler::convertUInt64ToDouble(Register64 src, FloatRegister dest, Register temp) { // SUBPD needs SSE2, HADDPD needs SSE3. if (!HasSSE3()) { MOZ_ASSERT(temp == Register::Invalid()); // Zero the dest register to break dependencies, see convertInt32ToDouble. zeroDouble(dest); Push(src.high); Push(src.low); fild(Operand(esp, 0)); Label notNegative; branch32(Assembler::NotSigned, src.high, Imm32(0), ¬Negative); double add_constant = 18446744073709551616.0; // 2^64 store64(Imm64(mozilla::BitwiseCast(add_constant)), Address(esp, 0)); fld(Operand(esp, 0)); faddp(); bind(¬Negative); fstp(Operand(esp, 0)); vmovsd(Address(esp, 0), dest); freeStack(2 * sizeof(intptr_t)); return; } // Following operation uses entire 128-bit of dest XMM register. // Currently higher 64-bit is free when we have access to lower 64-bit. MOZ_ASSERT(dest.size() == 8); FloatRegister dest128 = FloatRegister(dest.encoding(), FloatRegisters::Simd128); // Assume that src is represented as following: // src = 0x HHHHHHHH LLLLLLLL { // Move src to dest (=dest128) and ScratchInt32x4Reg (=scratch): // dest = 0x 00000000 00000000 00000000 LLLLLLLL // scratch = 0x 00000000 00000000 00000000 HHHHHHHH ScratchSimd128Scope scratch(*this); vmovd(src.low, dest128); vmovd(src.high, scratch); // Unpack and interleave dest and scratch to dest: // dest = 0x 00000000 00000000 HHHHHHHH LLLLLLLL vpunpckldq(scratch, dest128, dest128); } // Unpack and interleave dest and a constant C1 to dest: // C1 = 0x 00000000 00000000 45300000 43300000 // dest = 0x 45300000 HHHHHHHH 43300000 LLLLLLLL // here, each 64-bit part of dest represents following double: // HI(dest) = 0x 1.00000HHHHHHHH * 2**84 == 2**84 + 0x HHHHHHHH 00000000 // LO(dest) = 0x 1.00000LLLLLLLL * 2**52 == 2**52 + 0x 00000000 LLLLLLLL // See convertUInt64ToDouble for the details. static const int32_t CST1[4] = { 0x43300000, 0x45300000, 0x0, 0x0, }; vpunpckldqSimd128(SimdConstant::CreateX4(CST1), dest128, dest128); // Subtract a constant C2 from dest, for each 64-bit part: // C2 = 0x 45300000 00000000 43300000 00000000 // here, each 64-bit part of C2 represents following double: // HI(C2) = 0x 1.0000000000000 * 2**84 == 2**84 // LO(C2) = 0x 1.0000000000000 * 2**52 == 2**52 // after the operation each 64-bit part of dest represents following: // HI(dest) = double(0x HHHHHHHH 00000000) // LO(dest) = double(0x 00000000 LLLLLLLL) static const int32_t CST2[4] = { 0x0, 0x43300000, 0x0, 0x45300000, }; vsubpdSimd128(SimdConstant::CreateX4(CST2), dest128, dest128); // Add HI(dest) and LO(dest) in double and store it into LO(dest), // LO(dest) = double(0x HHHHHHHH 00000000) + double(0x 00000000 LLLLLLLL) // = double(0x HHHHHHHH LLLLLLLL) // = double(src) vhaddpd(dest128, dest128); } void MacroAssembler::convertInt64ToDouble(Register64 input, FloatRegister output) { // Zero the output register to break dependencies, see convertInt32ToDouble. zeroDouble(output); Push(input.high); Push(input.low); fild(Operand(esp, 0)); fstp(Operand(esp, 0)); vmovsd(Address(esp, 0), output); freeStack(2 * sizeof(intptr_t)); } void MacroAssembler::convertUInt64ToFloat32(Register64 input, FloatRegister output, Register temp) { // Zero the dest register to break dependencies, see convertInt32ToDouble. zeroDouble(output); // Set the FPU precision to 80 bits. reserveStack(2 * sizeof(intptr_t)); fnstcw(Operand(esp, 0)); load32(Operand(esp, 0), temp); orl(Imm32(0x300), temp); store32(temp, Operand(esp, sizeof(intptr_t))); fldcw(Operand(esp, sizeof(intptr_t))); Push(input.high); Push(input.low); fild(Operand(esp, 0)); Label notNegative; branch32(Assembler::NotSigned, input.high, Imm32(0), ¬Negative); double add_constant = 18446744073709551616.0; // 2^64 uint64_t add_constant_u64 = mozilla::BitwiseCast(add_constant); store64(Imm64(add_constant_u64), Address(esp, 0)); fld(Operand(esp, 0)); faddp(); bind(¬Negative); fstp32(Operand(esp, 0)); vmovss(Address(esp, 0), output); freeStack(2 * sizeof(intptr_t)); // Restore FPU precision to the initial value. fldcw(Operand(esp, 0)); freeStack(2 * sizeof(intptr_t)); } void MacroAssembler::convertInt64ToFloat32(Register64 input, FloatRegister output) { // Zero the output register to break dependencies, see convertInt32ToDouble. zeroDouble(output); Push(input.high); Push(input.low); fild(Operand(esp, 0)); fstp32(Operand(esp, 0)); vmovss(Address(esp, 0), output); freeStack(2 * sizeof(intptr_t)); } void MacroAssembler::convertIntPtrToDouble(Register src, FloatRegister dest) { convertInt32ToDouble(src, dest); } void MacroAssembler::PushBoxed(FloatRegister reg) { Push(reg); } CodeOffset MacroAssembler::moveNearAddressWithPatch(Register dest) { return movWithPatch(ImmPtr(nullptr), dest); } void MacroAssembler::patchNearAddressMove(CodeLocationLabel loc, CodeLocationLabel target) { PatchDataWithValueCheck(loc, ImmPtr(target.raw()), ImmPtr(nullptr)); } void MacroAssembler::wasmBoundsCheck64(Condition cond, Register64 index, Register64 boundsCheckLimit, Label* ok) { Label notOk; cmp32(index.high, Imm32(0)); j(Assembler::NonZero, ¬Ok); wasmBoundsCheck32(cond, index.low, boundsCheckLimit.low, ok); bind(¬Ok); } void MacroAssembler::wasmBoundsCheck64(Condition cond, Register64 index, Address boundsCheckLimit, Label* ok) { Label notOk; cmp32(index.high, Imm32(0)); j(Assembler::NonZero, ¬Ok); wasmBoundsCheck32(cond, index.low, boundsCheckLimit, ok); bind(¬Ok); } #ifdef ENABLE_WASM_TAIL_CALLS void MacroAssembler::wasmMarkSlowCall() { static_assert(esi == InstanceReg); or32(esi, esi); } const int32_t SlowCallMarker = 0xf60b; // OR esi, esi void MacroAssembler::wasmCheckSlowCallsite(Register ra, Label* notSlow, Register temp1, Register temp2) { // Check if RA has slow marker. cmp16(Address(ra, 0), Imm32(SlowCallMarker)); j(Assembler::NotEqual, notSlow); } #endif // ENABLE_WASM_TAIL_CALLS //}}} check_macroassembler_style