/* * Copyright (C) 2008 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. */ #ifndef JITInlineMethods_h #define JITInlineMethods_h #if ENABLE(JIT) namespace JSC { /* Deprecated: Please use JITStubCall instead. */ ALWAYS_INLINE void JIT::emitGetJITStubArg(unsigned argumentNumber, RegisterID dst) { unsigned argumentStackOffset = (argumentNumber * (sizeof(JSValue) / sizeof(void*))) + JITSTACKFRAME_ARGS_INDEX; peek(dst, argumentStackOffset); } ALWAYS_INLINE bool JIT::isOperandConstantImmediateDouble(unsigned src) { return m_codeBlock->isConstantRegisterIndex(src) && getConstantOperand(src).isDouble(); } ALWAYS_INLINE JSValue JIT::getConstantOperand(unsigned src) { ASSERT(m_codeBlock->isConstantRegisterIndex(src)); return m_codeBlock->getConstant(src); } ALWAYS_INLINE void JIT::emitPutToCallFrameHeader(RegisterID from, RegisterFile::CallFrameHeaderEntry entry) { storePtr(from, payloadFor(entry, callFrameRegister)); } ALWAYS_INLINE void JIT::emitPutCellToCallFrameHeader(RegisterID from, RegisterFile::CallFrameHeaderEntry entry) { #if USE(JSVALUE32_64) store32(TrustedImm32(JSValue::CellTag), tagFor(entry, callFrameRegister)); #endif storePtr(from, payloadFor(entry, callFrameRegister)); } ALWAYS_INLINE void JIT::emitPutIntToCallFrameHeader(RegisterID from, RegisterFile::CallFrameHeaderEntry entry) { store32(TrustedImm32(Int32Tag), intTagFor(entry, callFrameRegister)); store32(from, intPayloadFor(entry, callFrameRegister)); } ALWAYS_INLINE void JIT::emitPutImmediateToCallFrameHeader(void* value, RegisterFile::CallFrameHeaderEntry entry) { storePtr(TrustedImmPtr(value), Address(callFrameRegister, entry * sizeof(Register))); } ALWAYS_INLINE void JIT::emitGetFromCallFrameHeaderPtr(RegisterFile::CallFrameHeaderEntry entry, RegisterID to, RegisterID from) { loadPtr(Address(from, entry * sizeof(Register)), to); #if USE(JSVALUE64) killLastResultRegister(); #endif } ALWAYS_INLINE void JIT::emitLoadCharacterString(RegisterID src, RegisterID dst, JumpList& failures) { failures.append(branchPtr(NotEqual, Address(src), TrustedImmPtr(m_globalData->jsStringVPtr))); failures.append(branchTest32(NonZero, Address(src, OBJECT_OFFSETOF(JSString, m_fiberCount)))); failures.append(branch32(NotEqual, MacroAssembler::Address(src, ThunkHelpers::jsStringLengthOffset()), TrustedImm32(1))); loadPtr(MacroAssembler::Address(src, ThunkHelpers::jsStringValueOffset()), dst); loadPtr(MacroAssembler::Address(dst, ThunkHelpers::stringImplDataOffset()), dst); load16(MacroAssembler::Address(dst, 0), dst); } ALWAYS_INLINE void JIT::emitGetFromCallFrameHeader32(RegisterFile::CallFrameHeaderEntry entry, RegisterID to, RegisterID from) { load32(Address(from, entry * sizeof(Register)), to); #if USE(JSVALUE64) killLastResultRegister(); #endif } ALWAYS_INLINE JIT::Call JIT::emitNakedCall(CodePtr function) { ASSERT(m_bytecodeOffset != (unsigned)-1); // This method should only be called during hot/cold path generation, so that m_bytecodeOffset is set. Call nakedCall = nearCall(); m_calls.append(CallRecord(nakedCall, m_bytecodeOffset, function.executableAddress())); return nakedCall; } #if defined(ASSEMBLER_HAS_CONSTANT_POOL) && ASSEMBLER_HAS_CONSTANT_POOL ALWAYS_INLINE void JIT::beginUninterruptedSequence(int insnSpace, int constSpace) { JSInterfaceJIT::beginUninterruptedSequence(); #if CPU(ARM_TRADITIONAL) #ifndef NDEBUG // Ensure the label after the sequence can also fit insnSpace += sizeof(ARMWord); constSpace += sizeof(uint64_t); #endif ensureSpace(insnSpace, constSpace); #endif #if defined(ASSEMBLER_HAS_CONSTANT_POOL) && ASSEMBLER_HAS_CONSTANT_POOL #ifndef NDEBUG m_uninterruptedInstructionSequenceBegin = label(); m_uninterruptedConstantSequenceBegin = sizeOfConstantPool(); #endif #endif } ALWAYS_INLINE void JIT::endUninterruptedSequence(int insnSpace, int constSpace) { #if defined(ASSEMBLER_HAS_CONSTANT_POOL) && ASSEMBLER_HAS_CONSTANT_POOL /* There are several cases when the uninterrupted sequence is larger than * maximum required offset for pathing the same sequence. Eg.: if in a * uninterrupted sequence the last macroassembler's instruction is a stub * call, it emits store instruction(s) which should not be included in the * calculation of length of uninterrupted sequence. So, the insnSpace and * constSpace should be upper limit instead of hard limit. */ ASSERT(differenceBetween(m_uninterruptedInstructionSequenceBegin, label()) <= insnSpace); ASSERT(sizeOfConstantPool() - m_uninterruptedConstantSequenceBegin <= constSpace); #endif JSInterfaceJIT::endUninterruptedSequence(); } #endif #if CPU(ARM) ALWAYS_INLINE void JIT::preserveReturnAddressAfterCall(RegisterID reg) { move(linkRegister, reg); } ALWAYS_INLINE void JIT::restoreReturnAddressBeforeReturn(RegisterID reg) { move(reg, linkRegister); } ALWAYS_INLINE void JIT::restoreReturnAddressBeforeReturn(Address address) { loadPtr(address, linkRegister); } #elif CPU(MIPS) ALWAYS_INLINE void JIT::preserveReturnAddressAfterCall(RegisterID reg) { move(returnAddressRegister, reg); } ALWAYS_INLINE void JIT::restoreReturnAddressBeforeReturn(RegisterID reg) { move(reg, returnAddressRegister); } ALWAYS_INLINE void JIT::restoreReturnAddressBeforeReturn(Address address) { loadPtr(address, returnAddressRegister); } #else // CPU(X86) || CPU(X86_64) ALWAYS_INLINE void JIT::preserveReturnAddressAfterCall(RegisterID reg) { pop(reg); } ALWAYS_INLINE void JIT::restoreReturnAddressBeforeReturn(RegisterID reg) { push(reg); } ALWAYS_INLINE void JIT::restoreReturnAddressBeforeReturn(Address address) { push(address); } #endif ALWAYS_INLINE void JIT::restoreArgumentReference() { move(stackPointerRegister, firstArgumentRegister); poke(callFrameRegister, OBJECT_OFFSETOF(struct JITStackFrame, callFrame) / sizeof(void*)); } ALWAYS_INLINE void JIT::restoreArgumentReferenceForTrampoline() { #if CPU(X86) // Within a trampoline the return address will be on the stack at this point. addPtr(TrustedImm32(sizeof(void*)), stackPointerRegister, firstArgumentRegister); #elif CPU(ARM) move(stackPointerRegister, firstArgumentRegister); #endif // In the trampoline on x86-64, the first argument register is not overwritten. } ALWAYS_INLINE JIT::Jump JIT::checkStructure(RegisterID reg, Structure* structure) { return branchPtr(NotEqual, Address(reg, JSCell::structureOffset()), TrustedImmPtr(structure)); } ALWAYS_INLINE void JIT::linkSlowCaseIfNotJSCell(Vector::iterator& iter, int vReg) { if (!m_codeBlock->isKnownNotImmediate(vReg)) linkSlowCase(iter); } ALWAYS_INLINE void JIT::addSlowCase(Jump jump) { ASSERT(m_bytecodeOffset != (unsigned)-1); // This method should only be called during hot/cold path generation, so that m_bytecodeOffset is set. m_slowCases.append(SlowCaseEntry(jump, m_bytecodeOffset)); } ALWAYS_INLINE void JIT::addSlowCase(JumpList jumpList) { ASSERT(m_bytecodeOffset != (unsigned)-1); // This method should only be called during hot/cold path generation, so that m_bytecodeOffset is set. const JumpList::JumpVector& jumpVector = jumpList.jumps(); size_t size = jumpVector.size(); for (size_t i = 0; i < size; ++i) m_slowCases.append(SlowCaseEntry(jumpVector[i], m_bytecodeOffset)); } ALWAYS_INLINE void JIT::addJump(Jump jump, int relativeOffset) { ASSERT(m_bytecodeOffset != (unsigned)-1); // This method should only be called during hot/cold path generation, so that m_bytecodeOffset is set. m_jmpTable.append(JumpTable(jump, m_bytecodeOffset + relativeOffset)); } ALWAYS_INLINE void JIT::emitJumpSlowToHot(Jump jump, int relativeOffset) { ASSERT(m_bytecodeOffset != (unsigned)-1); // This method should only be called during hot/cold path generation, so that m_bytecodeOffset is set. jump.linkTo(m_labels[m_bytecodeOffset + 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::s_flags)); } ALWAYS_INLINE void JIT::clearSamplingFlag(int32_t flag) { ASSERT(flag >= 1); ASSERT(flag <= 32); and32(TrustedImm32(~(1u << (flag - 1))), AbsoluteAddress(&SamplingFlags::s_flags)); } #endif #if ENABLE(SAMPLING_COUNTERS) ALWAYS_INLINE void JIT::emitCount(AbstractSamplingCounter& counter, uint32_t count) { #if CPU(X86_64) // Or any other 64-bit plattform. addPtr(TrustedImm32(count), AbsoluteAddress(counter.addressOfCounter())); #elif CPU(X86) // Or any other little-endian 32-bit plattform. intptr_t hiWord = reinterpret_cast(counter.addressOfCounter()) + sizeof(int32_t); add32(TrustedImm32(count), AbsoluteAddress(counter.addressOfCounter())); addWithCarry32(TrustedImm32(0), AbsoluteAddress(reinterpret_cast(hiWord))); #else #error "SAMPLING_FLAGS not implemented on this platform." #endif } #endif #if ENABLE(OPCODE_SAMPLING) #if CPU(X86_64) ALWAYS_INLINE void JIT::sampleInstruction(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(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::isOperandConstantImmediateChar(unsigned src) { return m_codeBlock->isConstantRegisterIndex(src) && getConstantOperand(src).isString() && asString(getConstantOperand(src).asCell())->length() == 1; } #if USE(JSVALUE32_64) inline void JIT::emitLoadTag(unsigned index, RegisterID tag) { RegisterID mappedTag; if (getMappedTag(index, mappedTag)) { move(mappedTag, tag); unmap(tag); return; } if (m_codeBlock->isConstantRegisterIndex(index)) { move(Imm32(getConstantOperand(index).tag()), tag); unmap(tag); return; } load32(tagFor(index), tag); unmap(tag); } inline void JIT::emitLoadPayload(unsigned index, RegisterID payload) { RegisterID mappedPayload; if (getMappedPayload(index, mappedPayload)) { move(mappedPayload, payload); unmap(payload); return; } if (m_codeBlock->isConstantRegisterIndex(index)) { move(Imm32(getConstantOperand(index).payload()), payload); unmap(payload); return; } load32(payloadFor(index), payload); unmap(payload); } inline void JIT::emitLoad(const JSValue& v, RegisterID tag, RegisterID payload) { move(Imm32(v.payload()), payload); move(Imm32(v.tag()), tag); } inline void JIT::emitLoad(unsigned index, RegisterID tag, RegisterID payload, RegisterID base) { ASSERT(tag != payload); if (base == callFrameRegister) { ASSERT(payload != base); emitLoadPayload(index, payload); emitLoadTag(index, tag); return; } if (payload == base) { // avoid stomping base load32(tagFor(index, base), tag); load32(payloadFor(index, base), payload); return; } load32(payloadFor(index, base), payload); load32(tagFor(index, base), tag); } inline void JIT::emitLoad2(unsigned index1, RegisterID tag1, RegisterID payload1, unsigned index2, RegisterID tag2, RegisterID payload2) { if (isMapped(index1)) { emitLoad(index1, tag1, payload1); emitLoad(index2, tag2, payload2); return; } emitLoad(index2, tag2, payload2); emitLoad(index1, tag1, payload1); } inline void JIT::emitLoadDouble(unsigned index, FPRegisterID value) { if (m_codeBlock->isConstantRegisterIndex(index)) { WriteBarrier& inConstantPool = m_codeBlock->constantRegister(index); loadDouble(&inConstantPool, value); } else loadDouble(addressFor(index), value); } inline void JIT::emitLoadInt32ToDouble(unsigned index, FPRegisterID value) { if (m_codeBlock->isConstantRegisterIndex(index)) { WriteBarrier& inConstantPool = m_codeBlock->constantRegister(index); char* bytePointer = reinterpret_cast(&inConstantPool); convertInt32ToDouble(AbsoluteAddress(bytePointer + OBJECT_OFFSETOF(JSValue, u.asBits.payload)), value); } else convertInt32ToDouble(payloadFor(index), value); } inline void JIT::emitStore(unsigned index, RegisterID tag, RegisterID payload, RegisterID base) { store32(payload, payloadFor(index, base)); store32(tag, tagFor(index, base)); } inline void JIT::emitStoreInt32(unsigned index, RegisterID payload, bool indexIsInt32) { store32(payload, payloadFor(index, callFrameRegister)); if (!indexIsInt32) store32(TrustedImm32(JSValue::Int32Tag), tagFor(index, callFrameRegister)); } inline void JIT::emitStoreInt32(unsigned index, TrustedImm32 payload, bool indexIsInt32) { store32(payload, payloadFor(index, callFrameRegister)); if (!indexIsInt32) store32(TrustedImm32(JSValue::Int32Tag), tagFor(index, callFrameRegister)); } inline void JIT::emitStoreCell(unsigned index, RegisterID payload, bool indexIsCell) { store32(payload, payloadFor(index, callFrameRegister)); if (!indexIsCell) store32(TrustedImm32(JSValue::CellTag), tagFor(index, callFrameRegister)); } inline void JIT::emitStoreBool(unsigned index, RegisterID tag, bool indexIsBool) { if (!indexIsBool) store32(TrustedImm32(0), payloadFor(index, callFrameRegister)); store32(tag, tagFor(index, callFrameRegister)); } inline void JIT::emitStoreDouble(unsigned index, FPRegisterID value) { storeDouble(value, addressFor(index)); } inline void JIT::emitStore(unsigned index, const JSValue constant, RegisterID base) { store32(Imm32(constant.payload()), payloadFor(index, base)); store32(Imm32(constant.tag()), tagFor(index, base)); } ALWAYS_INLINE void JIT::emitInitRegister(unsigned dst) { emitStore(dst, jsUndefined()); } inline bool JIT::isLabeled(unsigned bytecodeOffset) { for (size_t numberOfJumpTargets = m_codeBlock->numberOfJumpTargets(); m_jumpTargetIndex != numberOfJumpTargets; ++m_jumpTargetIndex) { unsigned jumpTarget = m_codeBlock->jumpTarget(m_jumpTargetIndex); if (jumpTarget == bytecodeOffset) return true; if (jumpTarget > bytecodeOffset) return false; } return false; } inline void JIT::map(unsigned bytecodeOffset, unsigned virtualRegisterIndex, RegisterID tag, RegisterID payload) { if (isLabeled(bytecodeOffset)) return; m_mappedBytecodeOffset = bytecodeOffset; m_mappedVirtualRegisterIndex = virtualRegisterIndex; m_mappedTag = tag; m_mappedPayload = payload; } inline void JIT::unmap(RegisterID registerID) { if (m_mappedTag == registerID) m_mappedTag = (RegisterID)-1; else if (m_mappedPayload == registerID) m_mappedPayload = (RegisterID)-1; } inline void JIT::unmap() { m_mappedBytecodeOffset = (unsigned)-1; m_mappedVirtualRegisterIndex = (unsigned)-1; m_mappedTag = (RegisterID)-1; m_mappedPayload = (RegisterID)-1; } inline bool JIT::isMapped(unsigned virtualRegisterIndex) { if (m_mappedBytecodeOffset != m_bytecodeOffset) return false; if (m_mappedVirtualRegisterIndex != virtualRegisterIndex) return false; return true; } inline bool JIT::getMappedPayload(unsigned virtualRegisterIndex, RegisterID& payload) { if (m_mappedBytecodeOffset != m_bytecodeOffset) return false; if (m_mappedVirtualRegisterIndex != virtualRegisterIndex) return false; if (m_mappedPayload == (RegisterID)-1) return false; payload = m_mappedPayload; return true; } inline bool JIT::getMappedTag(unsigned virtualRegisterIndex, RegisterID& tag) { if (m_mappedBytecodeOffset != m_bytecodeOffset) return false; if (m_mappedVirtualRegisterIndex != virtualRegisterIndex) return false; if (m_mappedTag == (RegisterID)-1) return false; tag = m_mappedTag; return true; } inline void JIT::emitJumpSlowCaseIfNotJSCell(unsigned virtualRegisterIndex) { if (!m_codeBlock->isKnownNotImmediate(virtualRegisterIndex)) { if (m_codeBlock->isConstantRegisterIndex(virtualRegisterIndex)) addSlowCase(jump()); else addSlowCase(emitJumpIfNotJSCell(virtualRegisterIndex)); } } inline void JIT::emitJumpSlowCaseIfNotJSCell(unsigned virtualRegisterIndex, RegisterID tag) { if (!m_codeBlock->isKnownNotImmediate(virtualRegisterIndex)) { if (m_codeBlock->isConstantRegisterIndex(virtualRegisterIndex)) addSlowCase(jump()); else addSlowCase(branch32(NotEqual, tag, TrustedImm32(JSValue::CellTag))); } } inline void JIT::linkSlowCaseIfNotJSCell(Vector::iterator& iter, unsigned virtualRegisterIndex) { if (!m_codeBlock->isKnownNotImmediate(virtualRegisterIndex)) linkSlowCase(iter); } ALWAYS_INLINE bool JIT::isOperandConstantImmediateInt(unsigned src) { return m_codeBlock->isConstantRegisterIndex(src) && getConstantOperand(src).isInt32(); } ALWAYS_INLINE bool JIT::getOperandConstantImmediateInt(unsigned op1, unsigned op2, unsigned& op, int32_t& constant) { if (isOperandConstantImmediateInt(op1)) { constant = getConstantOperand(op1).asInt32(); op = op2; return true; } if (isOperandConstantImmediateInt(op2)) { constant = getConstantOperand(op2).asInt32(); op = op1; return true; } return false; } #else // USE(JSVALUE32_64) ALWAYS_INLINE void JIT::killLastResultRegister() { m_lastResultBytecodeRegister = std::numeric_limits::max(); } // get arg puts an arg from the SF register array into a h/w register ALWAYS_INLINE void JIT::emitGetVirtualRegister(int src, RegisterID dst) { ASSERT(m_bytecodeOffset != (unsigned)-1); // This method should only be called during hot/cold path generation, so that m_bytecodeOffset is set. // TODO: we want to reuse values that are already in registers if we can - add a register allocator! if (m_codeBlock->isConstantRegisterIndex(src)) { JSValue value = m_codeBlock->getConstant(src); move(ImmPtr(JSValue::encode(value)), dst); killLastResultRegister(); return; } if (src == m_lastResultBytecodeRegister && m_codeBlock->isTemporaryRegisterIndex(src)) { bool atJumpTarget = false; while (m_jumpTargetsPosition < m_codeBlock->numberOfJumpTargets() && m_codeBlock->jumpTarget(m_jumpTargetsPosition) <= m_bytecodeOffset) { if (m_codeBlock->jumpTarget(m_jumpTargetsPosition) == m_bytecodeOffset) atJumpTarget = true; ++m_jumpTargetsPosition; } if (!atJumpTarget) { // The argument we want is already stored in eax if (dst != cachedResultRegister) move(cachedResultRegister, dst); killLastResultRegister(); return; } } loadPtr(Address(callFrameRegister, src * sizeof(Register)), dst); killLastResultRegister(); } ALWAYS_INLINE void JIT::emitGetVirtualRegisters(int src1, RegisterID dst1, int src2, RegisterID dst2) { if (src2 == m_lastResultBytecodeRegister) { emitGetVirtualRegister(src2, dst2); emitGetVirtualRegister(src1, dst1); } else { emitGetVirtualRegister(src1, dst1); emitGetVirtualRegister(src2, dst2); } } ALWAYS_INLINE int32_t JIT::getConstantOperandImmediateInt(unsigned src) { return getConstantOperand(src).asInt32(); } ALWAYS_INLINE bool JIT::isOperandConstantImmediateInt(unsigned src) { return m_codeBlock->isConstantRegisterIndex(src) && getConstantOperand(src).isInt32(); } ALWAYS_INLINE void JIT::emitPutVirtualRegister(unsigned dst, RegisterID from) { storePtr(from, Address(callFrameRegister, dst * sizeof(Register))); m_lastResultBytecodeRegister = (from == cachedResultRegister) ? static_cast(dst) : std::numeric_limits::max(); } ALWAYS_INLINE void JIT::emitInitRegister(unsigned dst) { storePtr(TrustedImmPtr(JSValue::encode(jsUndefined())), Address(callFrameRegister, dst * sizeof(Register))); } ALWAYS_INLINE JIT::Jump JIT::emitJumpIfJSCell(RegisterID reg) { #if USE(JSVALUE64) return branchTestPtr(Zero, reg, tagMaskRegister); #else return branchTest32(Zero, reg, TrustedImm32(JSImmediate::TagMask)); #endif } ALWAYS_INLINE JIT::Jump JIT::emitJumpIfBothJSCells(RegisterID reg1, RegisterID reg2, RegisterID scratch) { move(reg1, scratch); orPtr(reg2, scratch); return emitJumpIfJSCell(scratch); } ALWAYS_INLINE void JIT::emitJumpSlowCaseIfJSCell(RegisterID reg) { addSlowCase(emitJumpIfJSCell(reg)); } ALWAYS_INLINE JIT::Jump JIT::emitJumpIfNotJSCell(RegisterID reg) { #if USE(JSVALUE64) return branchTestPtr(NonZero, reg, tagMaskRegister); #else return branchTest32(NonZero, reg, TrustedImm32(JSImmediate::TagMask)); #endif } ALWAYS_INLINE void JIT::emitJumpSlowCaseIfNotJSCell(RegisterID reg) { addSlowCase(emitJumpIfNotJSCell(reg)); } ALWAYS_INLINE void JIT::emitJumpSlowCaseIfNotJSCell(RegisterID reg, int vReg) { if (!m_codeBlock->isKnownNotImmediate(vReg)) emitJumpSlowCaseIfNotJSCell(reg); } #if USE(JSVALUE64) inline void JIT::emitLoadDouble(unsigned index, FPRegisterID value) { if (m_codeBlock->isConstantRegisterIndex(index)) { WriteBarrier& inConstantPool = m_codeBlock->constantRegister(index); loadDouble(&inConstantPool, value); } else loadDouble(addressFor(index), value); } inline void JIT::emitLoadInt32ToDouble(unsigned index, FPRegisterID value) { if (m_codeBlock->isConstantRegisterIndex(index)) { ASSERT(isOperandConstantImmediateInt(index)); convertInt32ToDouble(Imm32(getConstantOperand(index).asInt32()), value); } else convertInt32ToDouble(addressFor(index), value); } #endif ALWAYS_INLINE JIT::Jump JIT::emitJumpIfImmediateInteger(RegisterID reg) { #if USE(JSVALUE64) return branchPtr(AboveOrEqual, reg, tagTypeNumberRegister); #else return branchTest32(NonZero, reg, TrustedImm32(JSImmediate::TagTypeNumber)); #endif } ALWAYS_INLINE JIT::Jump JIT::emitJumpIfNotImmediateInteger(RegisterID reg) { #if USE(JSVALUE64) return branchPtr(Below, reg, tagTypeNumberRegister); #else return branchTest32(Zero, reg, TrustedImm32(JSImmediate::TagTypeNumber)); #endif } ALWAYS_INLINE JIT::Jump JIT::emitJumpIfNotImmediateIntegers(RegisterID reg1, RegisterID reg2, RegisterID scratch) { move(reg1, scratch); andPtr(reg2, scratch); return emitJumpIfNotImmediateInteger(scratch); } ALWAYS_INLINE void JIT::emitJumpSlowCaseIfNotImmediateInteger(RegisterID reg) { addSlowCase(emitJumpIfNotImmediateInteger(reg)); } ALWAYS_INLINE void JIT::emitJumpSlowCaseIfNotImmediateIntegers(RegisterID reg1, RegisterID reg2, RegisterID scratch) { addSlowCase(emitJumpIfNotImmediateIntegers(reg1, reg2, scratch)); } ALWAYS_INLINE void JIT::emitJumpSlowCaseIfNotImmediateNumber(RegisterID reg) { addSlowCase(emitJumpIfNotImmediateNumber(reg)); } #if USE(JSVALUE32_64) ALWAYS_INLINE void JIT::emitFastArithDeTagImmediate(RegisterID reg) { subPtr(TrustedImm32(JSImmediate::TagTypeNumber), reg); } ALWAYS_INLINE JIT::Jump JIT::emitFastArithDeTagImmediateJumpIfZero(RegisterID reg) { return branchSubPtr(Zero, TrustedImm32(JSImmediate::TagTypeNumber), reg); } #endif ALWAYS_INLINE void JIT::emitFastArithReTagImmediate(RegisterID src, RegisterID dest) { #if USE(JSVALUE64) emitFastArithIntToImmNoCheck(src, dest); #else if (src != dest) move(src, dest); addPtr(TrustedImm32(JSImmediate::TagTypeNumber), dest); #endif } // operand is int32_t, must have been zero-extended if register is 64-bit. ALWAYS_INLINE void JIT::emitFastArithIntToImmNoCheck(RegisterID src, RegisterID dest) { #if USE(JSVALUE64) if (src != dest) move(src, dest); orPtr(tagTypeNumberRegister, dest); #else signExtend32ToPtr(src, dest); addPtr(dest, dest); emitFastArithReTagImmediate(dest, dest); #endif } ALWAYS_INLINE void JIT::emitTagAsBoolImmediate(RegisterID reg) { lshift32(TrustedImm32(JSImmediate::ExtendedPayloadShift), reg); or32(TrustedImm32(static_cast(JSImmediate::FullTagTypeBool)), reg); } #endif // USE(JSVALUE32_64) } // namespace JSC #endif // ENABLE(JIT) #endif