/* * Copyright (C) 2008-2019 Apple Inc. All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY APPLE INC. ``AS IS'' AND ANY * EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR * PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL APPLE INC. OR * CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, * EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, * PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR * PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY * OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE * OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. */ #pragma once #if ENABLE(JIT) #include "BytecodeOperandsForCheckpoint.h" #include "CommonSlowPathsInlines.h" #include "JIT.h" #include "JSCInlines.h" namespace JSC { ALWAYS_INLINE MacroAssembler::JumpList JIT::emitLoadForArrayMode(const Instruction* currentInstruction, JITArrayMode arrayMode, PatchableJump& badType) { switch (arrayMode) { case JITInt32: return emitInt32Load(currentInstruction, badType); case JITDouble: return emitDoubleLoad(currentInstruction, badType); case JITContiguous: return emitContiguousLoad(currentInstruction, badType); case JITArrayStorage: return emitArrayStorageLoad(currentInstruction, badType); default: break; } RELEASE_ASSERT_NOT_REACHED(); return MacroAssembler::JumpList(); } ALWAYS_INLINE bool JIT::isOperandConstantDouble(VirtualRegister src) { return src.isConstant() && getConstantOperand(src).isDouble(); } ALWAYS_INLINE JSValue JIT::getConstantOperand(VirtualRegister src) { ASSERT(src.isConstant()); return m_codeBlock->getConstant(src); } ALWAYS_INLINE void JIT::emitPutIntToCallFrameHeader(RegisterID from, VirtualRegister entry) { ASSERT(entry.isHeader()); #if USE(JSVALUE32_64) store32(TrustedImm32(JSValue::Int32Tag), tagFor(entry)); store32(from, payloadFor(entry)); #else store64(from, addressFor(entry)); #endif } ALWAYS_INLINE void JIT::emitLoadCharacterString(RegisterID src, RegisterID dst, JumpList& failures) { failures.append(branchIfNotString(src)); loadPtr(MacroAssembler::Address(src, JSString::offsetOfValue()), dst); failures.append(branchIfRopeStringImpl(dst)); failures.append(branch32(NotEqual, MacroAssembler::Address(dst, StringImpl::lengthMemoryOffset()), TrustedImm32(1))); loadPtr(MacroAssembler::Address(dst, StringImpl::dataOffset()), regT1); auto is16Bit = branchTest32(Zero, Address(dst, StringImpl::flagsOffset()), TrustedImm32(StringImpl::flagIs8Bit())); load8(MacroAssembler::Address(regT1, 0), dst); auto done = jump(); is16Bit.link(this); load16(MacroAssembler::Address(regT1, 0), dst); done.link(this); } ALWAYS_INLINE JIT::Call JIT::emitNakedNearCall(CodePtr target) { ASSERT(m_bytecodeIndex); // This method should only be called during hot/cold path generation, so that m_bytecodeIndex is set. Call nakedCall = nearCall(); m_nearCalls.append(NearCallRecord(nakedCall, m_bytecodeIndex, FunctionPtr(target.retagged()))); return nakedCall; } ALWAYS_INLINE JIT::Call JIT::emitNakedNearTailCall(CodePtr target) { ASSERT(m_bytecodeIndex); // This method should only be called during hot/cold path generation, so that m_bytecodeIndex is set. Call nakedCall = nearTailCall(); m_nearCalls.append(NearCallRecord(nakedCall, m_bytecodeIndex, FunctionPtr(target.retagged()))); return nakedCall; } ALWAYS_INLINE void JIT::updateTopCallFrame() { uint32_t locationBits = CallSiteIndex(m_bytecodeIndex.offset()).bits(); store32(TrustedImm32(locationBits), tagFor(CallFrameSlot::argumentCountIncludingThis)); // FIXME: It's not clear that this is needed. JITOperations tend to update the top call frame on // the C++ side. // https://bugs.webkit.org/show_bug.cgi?id=155693 storePtr(callFrameRegister, &m_vm->topCallFrame); } ALWAYS_INLINE MacroAssembler::Call JIT::appendCallWithExceptionCheck(const FunctionPtr function) { updateTopCallFrame(); MacroAssembler::Call call = appendCall(function); exceptionCheck(); return call; } #if OS(WINDOWS) && CPU(X86_64) ALWAYS_INLINE MacroAssembler::Call JIT::appendCallWithExceptionCheckAndSlowPathReturnType(const FunctionPtr function) { updateTopCallFrame(); MacroAssembler::Call call = appendCallWithSlowPathReturnType(function); exceptionCheck(); return call; } #endif ALWAYS_INLINE MacroAssembler::Call JIT::appendCallWithCallFrameRollbackOnException(const FunctionPtr function) { updateTopCallFrame(); // The callee is responsible for setting topCallFrame to their caller MacroAssembler::Call call = appendCall(function); exceptionCheckWithCallFrameRollback(); return call; } ALWAYS_INLINE MacroAssembler::Call JIT::appendCallWithExceptionCheckSetJSValueResult(const FunctionPtr function, VirtualRegister dst) { MacroAssembler::Call call = appendCallWithExceptionCheck(function); #if USE(JSVALUE64) emitPutVirtualRegister(dst, returnValueGPR); #else emitStore(dst, returnValueGPR2, returnValueGPR); #endif return call; } template ALWAYS_INLINE MacroAssembler::Call JIT::appendCallWithExceptionCheckSetJSValueResultWithProfile(Metadata& metadata, const FunctionPtr function, VirtualRegister dst) { MacroAssembler::Call call = appendCallWithExceptionCheck(function); #if USE(JSVALUE64) emitValueProfilingSite(metadata, returnValueGPR); emitPutVirtualRegister(dst, returnValueGPR); #else emitValueProfilingSite(metadata, JSValueRegs(returnValueGPR2, returnValueGPR)); emitStore(dst, returnValueGPR2, returnValueGPR); #endif return call; } ALWAYS_INLINE void JIT::linkSlowCaseIfNotJSCell(Vector::iterator& iter, VirtualRegister reg) { if (!m_codeBlock->isKnownCell(reg)) linkSlowCase(iter); } ALWAYS_INLINE void JIT::linkAllSlowCasesForBytecodeIndex(Vector& slowCases, Vector::iterator& iter, BytecodeIndex bytecodeIndex) { while (iter != slowCases.end() && iter->to == bytecodeIndex) linkSlowCase(iter); } ALWAYS_INLINE bool JIT::hasAnySlowCases(Vector& slowCases, Vector::iterator& iter, BytecodeIndex bytecodeIndex) { if (iter != slowCases.end() && iter->to == bytecodeIndex) return true; return false; } inline void JIT::advanceToNextCheckpoint() { ASSERT_WITH_MESSAGE(m_bytecodeIndex, "This method should only be called during hot/cold path generation, so that m_bytecodeIndex is set"); ASSERT(m_codeBlock->instructionAt(m_bytecodeIndex)->hasCheckpoints()); m_bytecodeIndex = BytecodeIndex(m_bytecodeIndex.offset(), m_bytecodeIndex.checkpoint() + 1); auto result = m_checkpointLabels.add(m_bytecodeIndex, label()); ASSERT_UNUSED(result, result.isNewEntry); } inline void JIT::emitJumpSlowToHotForCheckpoint(Jump jump) { ASSERT_WITH_MESSAGE(m_bytecodeIndex, "This method should only be called during hot/cold path generation, so that m_bytecodeIndex is set"); ASSERT(m_codeBlock->instructionAt(m_bytecodeIndex)->hasCheckpoints()); m_bytecodeIndex = BytecodeIndex(m_bytecodeIndex.offset(), m_bytecodeIndex.checkpoint() + 1); auto iter = m_checkpointLabels.find(m_bytecodeIndex); ASSERT(iter != m_checkpointLabels.end()); jump.linkTo(iter->value, this); } ALWAYS_INLINE void JIT::addSlowCase(Jump jump) { ASSERT(m_bytecodeIndex); // This method should only be called during hot/cold path generation, so that m_bytecodeIndex is set. m_slowCases.append(SlowCaseEntry(jump, m_bytecodeIndex)); } ALWAYS_INLINE void JIT::addSlowCase(const JumpList& jumpList) { ASSERT(m_bytecodeIndex); // This method should only be called during hot/cold path generation, so that m_bytecodeIndex is set. for (const Jump& jump : jumpList.jumps()) m_slowCases.append(SlowCaseEntry(jump, m_bytecodeIndex)); } ALWAYS_INLINE void JIT::addSlowCase() { ASSERT(m_bytecodeIndex); // This method should only be called during hot/cold path generation, so that m_bytecodeIndex is set. Jump emptyJump; // Doing it this way to make Windows happy. m_slowCases.append(SlowCaseEntry(emptyJump, m_bytecodeIndex)); } ALWAYS_INLINE void JIT::addJump(Jump jump, int relativeOffset) { ASSERT(m_bytecodeIndex); // This method should only be called during hot/cold path generation, so that m_bytecodeIndex is set. m_jmpTable.append(JumpTable(jump, m_bytecodeIndex.offset() + relativeOffset)); } ALWAYS_INLINE void JIT::addJump(const JumpList& jumpList, int relativeOffset) { ASSERT(m_bytecodeIndex); // This method should only be called during hot/cold path generation, so that m_bytecodeIndex is set. for (auto& jump : jumpList.jumps()) addJump(jump, relativeOffset); } ALWAYS_INLINE void JIT::emitJumpSlowToHot(Jump jump, int relativeOffset) { ASSERT(m_bytecodeIndex); // This method should only be called during hot/cold path generation, so that m_bytecodeIndex is set. jump.linkTo(m_labels[m_bytecodeIndex.offset() + relativeOffset], this); } #if ENABLE(SAMPLING_FLAGS) ALWAYS_INLINE void JIT::setSamplingFlag(int32_t flag) { ASSERT(flag >= 1); ASSERT(flag <= 32); or32(TrustedImm32(1u << (flag - 1)), AbsoluteAddress(SamplingFlags::addressOfFlags())); } ALWAYS_INLINE void JIT::clearSamplingFlag(int32_t flag) { ASSERT(flag >= 1); ASSERT(flag <= 32); and32(TrustedImm32(~(1u << (flag - 1))), AbsoluteAddress(SamplingFlags::addressOfFlags())); } #endif #if ENABLE(SAMPLING_COUNTERS) ALWAYS_INLINE void JIT::emitCount(AbstractSamplingCounter& counter, int32_t count) { add64(TrustedImm32(count), AbsoluteAddress(counter.addressOfCounter())); } #endif #if ENABLE(OPCODE_SAMPLING) #if CPU(X86_64) ALWAYS_INLINE void JIT::sampleInstruction(const Instruction* instruction, bool inHostFunction) { move(TrustedImmPtr(m_interpreter->sampler()->sampleSlot()), X86Registers::ecx); storePtr(TrustedImmPtr(m_interpreter->sampler()->encodeSample(instruction, inHostFunction)), X86Registers::ecx); } #else ALWAYS_INLINE void JIT::sampleInstruction(const Instruction* instruction, bool inHostFunction) { storePtr(TrustedImmPtr(m_interpreter->sampler()->encodeSample(instruction, inHostFunction)), m_interpreter->sampler()->sampleSlot()); } #endif #endif #if ENABLE(CODEBLOCK_SAMPLING) #if CPU(X86_64) ALWAYS_INLINE void JIT::sampleCodeBlock(CodeBlock* codeBlock) { move(TrustedImmPtr(m_interpreter->sampler()->codeBlockSlot()), X86Registers::ecx); storePtr(TrustedImmPtr(codeBlock), X86Registers::ecx); } #else ALWAYS_INLINE void JIT::sampleCodeBlock(CodeBlock* codeBlock) { storePtr(TrustedImmPtr(codeBlock), m_interpreter->sampler()->codeBlockSlot()); } #endif #endif ALWAYS_INLINE bool JIT::isOperandConstantChar(VirtualRegister src) { return src.isConstant() && getConstantOperand(src).isString() && asString(getConstantOperand(src).asCell())->length() == 1; } inline void JIT::emitValueProfilingSite(ValueProfile& valueProfile, JSValueRegs value) { ASSERT(shouldEmitProfiling()); // We're in a simple configuration: only one bucket, so we can just do a direct // store. #if USE(JSVALUE64) store64(value.gpr(), valueProfile.m_buckets); #else EncodedValueDescriptor* descriptor = bitwise_cast(valueProfile.m_buckets); store32(value.payloadGPR(), &descriptor->asBits.payload); store32(value.tagGPR(), &descriptor->asBits.tag); #endif } template inline std::enable_if_t::value, void> JIT::emitValueProfilingSiteIfProfiledOpcode(Op bytecode) { #if USE(JSVALUE64) emitValueProfilingSite(bytecode.metadata(m_codeBlock), regT0); #else emitValueProfilingSite(bytecode.metadata(m_codeBlock), JSValueRegs(regT1, regT0)); #endif } inline void JIT::emitValueProfilingSiteIfProfiledOpcode(...) { } template inline void JIT::emitValueProfilingSite(Metadata& metadata, JSValueRegs value) { if (!shouldEmitProfiling()) return; emitValueProfilingSite(valueProfileFor(metadata, m_bytecodeIndex.checkpoint()), value); } #if USE(JSVALUE64) inline void JIT::emitValueProfilingSite(ValueProfile& valueProfile, GPRReg resultReg) { emitValueProfilingSite(valueProfile, JSValueRegs(resultReg)); } template inline void JIT::emitValueProfilingSite(Metadata& metadata, GPRReg resultReg) { emitValueProfilingSite(metadata, JSValueRegs(resultReg)); } #endif inline void JIT::emitArrayProfilingSiteWithCell(RegisterID cell, RegisterID indexingType, ArrayProfile* arrayProfile) { if (shouldEmitProfiling()) { load32(MacroAssembler::Address(cell, JSCell::structureIDOffset()), indexingType); store32(indexingType, arrayProfile->addressOfLastSeenStructureID()); } load8(Address(cell, JSCell::indexingTypeAndMiscOffset()), indexingType); } inline void JIT::emitArrayProfileStoreToHoleSpecialCase(ArrayProfile* arrayProfile) { store8(TrustedImm32(1), arrayProfile->addressOfMayStoreToHole()); } inline void JIT::emitArrayProfileOutOfBoundsSpecialCase(ArrayProfile* arrayProfile) { store8(TrustedImm32(1), arrayProfile->addressOfOutOfBounds()); } inline JITArrayMode JIT::chooseArrayMode(ArrayProfile* profile) { auto arrayProfileSaw = [] (ArrayModes arrayModes, IndexingType capability) { return arrayModesIncludeIgnoringTypedArrays(arrayModes, capability); }; ConcurrentJSLocker locker(m_codeBlock->m_lock); profile->computeUpdatedPrediction(locker, m_codeBlock); ArrayModes arrayModes = profile->observedArrayModes(locker); if (arrayProfileSaw(arrayModes, DoubleShape)) return JITDouble; if (arrayProfileSaw(arrayModes, Int32Shape)) return JITInt32; if (arrayProfileSaw(arrayModes, ArrayStorageShape)) return JITArrayStorage; return JITContiguous; } ALWAYS_INLINE int32_t JIT::getOperandConstantInt(VirtualRegister src) { return getConstantOperand(src).asInt32(); } ALWAYS_INLINE double JIT::getOperandConstantDouble(VirtualRegister src) { return getConstantOperand(src).asDouble(); } ALWAYS_INLINE void JIT::emitInitRegister(VirtualRegister dst) { storeTrustedValue(jsUndefined(), addressFor(dst)); } #if USE(JSVALUE32_64) inline void JIT::emitLoadDouble(VirtualRegister reg, FPRegisterID value) { if (reg.isConstant()) { WriteBarrier& inConstantPool = m_codeBlock->constantRegister(reg); loadDouble(TrustedImmPtr(&inConstantPool), value); } else loadDouble(addressFor(reg), value); } inline void JIT::emitLoadTag(VirtualRegister reg, RegisterID tag) { if (reg.isConstant()) { move(Imm32(getConstantOperand(reg).tag()), tag); return; } load32(tagFor(reg), tag); } inline void JIT::emitLoadPayload(VirtualRegister reg, RegisterID payload) { if (reg.isConstant()) { move(Imm32(getConstantOperand(reg).payload()), payload); return; } load32(payloadFor(reg), payload); } inline void JIT::emitLoad(const JSValue& v, RegisterID tag, RegisterID payload) { move(Imm32(v.payload()), payload); move(Imm32(v.tag()), tag); } ALWAYS_INLINE void JIT::emitGetVirtualRegister(VirtualRegister src, JSValueRegs dst) { emitLoad(src, dst.tagGPR(), dst.payloadGPR()); } ALWAYS_INLINE void JIT::emitPutVirtualRegister(VirtualRegister dst, JSValueRegs from) { emitStore(dst, from.tagGPR(), from.payloadGPR()); } inline void JIT::emitLoad(VirtualRegister reg, RegisterID tag, RegisterID payload, RegisterID base) { RELEASE_ASSERT(tag != payload); if (base == callFrameRegister) { RELEASE_ASSERT(payload != base); emitLoadPayload(reg, payload); emitLoadTag(reg, tag); return; } if (payload == base) { // avoid stomping base load32(tagFor(reg, base), tag); load32(payloadFor(reg, base), payload); return; } load32(payloadFor(reg, base), payload); load32(tagFor(reg, base), tag); } inline void JIT::emitLoad2(VirtualRegister reg1, RegisterID tag1, RegisterID payload1, VirtualRegister reg2, RegisterID tag2, RegisterID payload2) { emitLoad(reg2, tag2, payload2); emitLoad(reg1, tag1, payload1); } inline void JIT::emitStore(VirtualRegister reg, RegisterID tag, RegisterID payload, RegisterID base) { store32(payload, payloadFor(reg, base)); store32(tag, tagFor(reg, base)); } inline void JIT::emitStoreInt32(VirtualRegister reg, RegisterID payload, bool indexIsInt32) { store32(payload, payloadFor(reg)); if (!indexIsInt32) store32(TrustedImm32(JSValue::Int32Tag), tagFor(reg)); } inline void JIT::emitStoreInt32(VirtualRegister reg, TrustedImm32 payload, bool indexIsInt32) { store32(payload, payloadFor(reg)); if (!indexIsInt32) store32(TrustedImm32(JSValue::Int32Tag), tagFor(reg)); } inline void JIT::emitStoreCell(VirtualRegister reg, RegisterID payload, bool indexIsCell) { store32(payload, payloadFor(reg)); if (!indexIsCell) store32(TrustedImm32(JSValue::CellTag), tagFor(reg)); } inline void JIT::emitStoreBool(VirtualRegister reg, RegisterID payload, bool indexIsBool) { store32(payload, payloadFor(reg)); if (!indexIsBool) store32(TrustedImm32(JSValue::BooleanTag), tagFor(reg)); } inline void JIT::emitStoreDouble(VirtualRegister reg, FPRegisterID value) { storeDouble(value, addressFor(reg)); } inline void JIT::emitStore(VirtualRegister reg, const JSValue constant, RegisterID base) { store32(Imm32(constant.payload()), payloadFor(reg, base)); store32(Imm32(constant.tag()), tagFor(reg, base)); } inline void JIT::emitJumpSlowCaseIfNotJSCell(VirtualRegister reg) { if (!m_codeBlock->isKnownCell(reg)) { if (reg.isConstant()) addSlowCase(jump()); else addSlowCase(emitJumpIfNotJSCell(reg)); } } inline void JIT::emitJumpSlowCaseIfNotJSCell(VirtualRegister reg, RegisterID tag) { if (!m_codeBlock->isKnownCell(reg)) { if (reg.isConstant()) addSlowCase(jump()); else addSlowCase(branchIfNotCell(tag)); } } ALWAYS_INLINE bool JIT::isOperandConstantInt(VirtualRegister src) { return src.isConstant() && getConstantOperand(src).isInt32(); } ALWAYS_INLINE bool JIT::getOperandConstantInt(VirtualRegister op1, VirtualRegister op2, VirtualRegister& op, int32_t& constant) { if (isOperandConstantInt(op1)) { constant = getConstantOperand(op1).asInt32(); op = op2; return true; } if (isOperandConstantInt(op2)) { constant = getConstantOperand(op2).asInt32(); op = op1; return true; } return false; } #else // USE(JSVALUE32_64) // get arg puts an arg from the SF register array into a h/w register ALWAYS_INLINE void JIT::emitGetVirtualRegister(VirtualRegister src, RegisterID dst) { ASSERT(m_bytecodeIndex); // This method should only be called during hot/cold path generation, so that m_bytecodeIndex is set. if (src.isConstant()) { JSValue value = m_codeBlock->getConstant(src); if (!value.isNumber()) move(TrustedImm64(JSValue::encode(value)), dst); else move(Imm64(JSValue::encode(value)), dst); return; } load64(addressFor(src), dst); } ALWAYS_INLINE void JIT::emitGetVirtualRegister(VirtualRegister src, JSValueRegs dst) { emitGetVirtualRegister(src, dst.payloadGPR()); } ALWAYS_INLINE void JIT::emitGetVirtualRegisters(VirtualRegister src1, RegisterID dst1, VirtualRegister src2, RegisterID dst2) { emitGetVirtualRegister(src1, dst1); emitGetVirtualRegister(src2, dst2); } ALWAYS_INLINE bool JIT::isOperandConstantInt(VirtualRegister src) { return src.isConstant() && getConstantOperand(src).isInt32(); } ALWAYS_INLINE void JIT::emitPutVirtualRegister(VirtualRegister dst, RegisterID from) { store64(from, addressFor(dst)); } ALWAYS_INLINE void JIT::emitPutVirtualRegister(VirtualRegister dst, JSValueRegs from) { emitPutVirtualRegister(dst, from.payloadGPR()); } ALWAYS_INLINE JIT::Jump JIT::emitJumpIfBothJSCells(RegisterID reg1, RegisterID reg2, RegisterID scratch) { move(reg1, scratch); or64(reg2, scratch); return branchIfCell(scratch); } ALWAYS_INLINE void JIT::emitJumpSlowCaseIfJSCell(RegisterID reg) { addSlowCase(branchIfCell(reg)); } ALWAYS_INLINE void JIT::emitJumpSlowCaseIfNotJSCell(RegisterID reg, VirtualRegister vReg) { if (!m_codeBlock->isKnownCell(vReg)) emitJumpSlowCaseIfNotJSCell(reg); } ALWAYS_INLINE JIT::PatchableJump JIT::emitPatchableJumpIfNotInt(RegisterID reg) { return patchableBranch64(Below, reg, numberTagRegister); } ALWAYS_INLINE JIT::Jump JIT::emitJumpIfNotInt(RegisterID reg1, RegisterID reg2, RegisterID scratch) { move(reg1, scratch); and64(reg2, scratch); return branchIfNotInt32(scratch); } ALWAYS_INLINE void JIT::emitJumpSlowCaseIfNotInt(RegisterID reg) { addSlowCase(branchIfNotInt32(reg)); } ALWAYS_INLINE void JIT::emitJumpSlowCaseIfNotInt(RegisterID reg1, RegisterID reg2, RegisterID scratch) { addSlowCase(emitJumpIfNotInt(reg1, reg2, scratch)); } ALWAYS_INLINE void JIT::emitJumpSlowCaseIfNotNumber(RegisterID reg) { addSlowCase(branchIfNotNumber(reg)); } #endif // USE(JSVALUE32_64) ALWAYS_INLINE void JIT::emitJumpSlowCaseIfNotJSCell(RegisterID reg) { addSlowCase(branchIfNotCell(reg)); } ALWAYS_INLINE int JIT::jumpTarget(const Instruction* instruction, int target) { if (target) return target; return m_codeBlock->outOfLineJumpOffset(instruction); } ALWAYS_INLINE GetPutInfo JIT::copiedGetPutInfo(OpPutToScope bytecode) { unsigned key = bytecode.m_metadataID + 1; // HashMap doesn't like 0 as a key auto iterator = m_copiedGetPutInfos.find(key); if (iterator != m_copiedGetPutInfos.end()) return GetPutInfo(iterator->value); GetPutInfo getPutInfo = bytecode.metadata(m_codeBlock).m_getPutInfo; m_copiedGetPutInfos.add(key, getPutInfo.operand()); return getPutInfo; } template ALWAYS_INLINE BinaryArithProfile JIT::copiedArithProfile(BinaryOp bytecode) { uint64_t key = (static_cast(BinaryOp::opcodeID) + 1) << 32 | static_cast(bytecode.m_metadataID); auto iterator = m_copiedArithProfiles.find(key); if (iterator != m_copiedArithProfiles.end()) return iterator->value; BinaryArithProfile arithProfile = bytecode.metadata(m_codeBlock).m_arithProfile; m_copiedArithProfiles.add(key, arithProfile); return arithProfile; } template ALWAYS_INLINE ECMAMode JIT::ecmaMode(Op op) { return op.m_ecmaMode; } template<> ALWAYS_INLINE ECMAMode JIT::ecmaMode(OpPutById op) { return op.m_flags.ecmaMode(); } template<> ALWAYS_INLINE ECMAMode JIT::ecmaMode(OpPutPrivateName) { return ECMAMode::strict(); } } // namespace JSC #endif // ENABLE(JIT)