/* * Copyright (C) 2008, 2014 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 MacroAssemblerX86_h #define MacroAssemblerX86_h #if ENABLE(ASSEMBLER) && CPU(X86) #include "MacroAssemblerX86Common.h" namespace JSC { class MacroAssemblerX86 : public MacroAssemblerX86Common { public: static const Scale ScalePtr = TimesFour; using MacroAssemblerX86Common::add32; using MacroAssemblerX86Common::and32; using MacroAssemblerX86Common::branchAdd32; using MacroAssemblerX86Common::branchSub32; using MacroAssemblerX86Common::sub32; using MacroAssemblerX86Common::or32; using MacroAssemblerX86Common::load32; using MacroAssemblerX86Common::load8; using MacroAssemblerX86Common::store32; using MacroAssemblerX86Common::store8; using MacroAssemblerX86Common::branch32; using MacroAssemblerX86Common::call; using MacroAssemblerX86Common::jump; using MacroAssemblerX86Common::addDouble; using MacroAssemblerX86Common::loadDouble; using MacroAssemblerX86Common::storeDouble; using MacroAssemblerX86Common::convertInt32ToDouble; using MacroAssemblerX86Common::branch8; using MacroAssemblerX86Common::branchTest8; void add32(TrustedImm32 imm, RegisterID src, RegisterID dest) { m_assembler.leal_mr(imm.m_value, src, dest); } void add32(TrustedImm32 imm, AbsoluteAddress address) { m_assembler.addl_im(imm.m_value, address.m_ptr); } void add32(AbsoluteAddress address, RegisterID dest) { m_assembler.addl_mr(address.m_ptr, dest); } void add64(TrustedImm32 imm, AbsoluteAddress address) { m_assembler.addl_im(imm.m_value, address.m_ptr); m_assembler.adcl_im(imm.m_value >> 31, reinterpret_cast(address.m_ptr) + sizeof(int32_t)); } void and32(TrustedImm32 imm, AbsoluteAddress address) { m_assembler.andl_im(imm.m_value, address.m_ptr); } void or32(TrustedImm32 imm, AbsoluteAddress address) { m_assembler.orl_im(imm.m_value, address.m_ptr); } void or32(RegisterID reg, AbsoluteAddress address) { m_assembler.orl_rm(reg, address.m_ptr); } void sub32(TrustedImm32 imm, AbsoluteAddress address) { m_assembler.subl_im(imm.m_value, address.m_ptr); } void load32(const void* address, RegisterID dest) { m_assembler.movl_mr(address, dest); } void load8(const void* address, RegisterID dest) { m_assembler.movzbl_mr(address, dest); } void abortWithReason(AbortReason reason) { move(TrustedImm32(reason), X86Registers::eax); breakpoint(); } void abortWithReason(AbortReason reason, intptr_t misc) { move(TrustedImm32(misc), X86Registers::edx); abortWithReason(reason); } ConvertibleLoadLabel convertibleLoadPtr(Address address, RegisterID dest) { ConvertibleLoadLabel result = ConvertibleLoadLabel(this); m_assembler.movl_mr(address.offset, address.base, dest); return result; } void addDouble(AbsoluteAddress address, FPRegisterID dest) { m_assembler.addsd_mr(address.m_ptr, dest); } void storeDouble(FPRegisterID src, TrustedImmPtr address) { ASSERT(isSSE2Present()); ASSERT(address.m_value); m_assembler.movsd_rm(src, address.m_value); } void convertInt32ToDouble(AbsoluteAddress src, FPRegisterID dest) { m_assembler.cvtsi2sd_mr(src.m_ptr, dest); } void store32(TrustedImm32 imm, void* address) { m_assembler.movl_i32m(imm.m_value, address); } void store32(RegisterID src, void* address) { m_assembler.movl_rm(src, address); } void store8(RegisterID src, void* address) { m_assembler.movb_rm(src, address); } void store8(TrustedImm32 imm, void* address) { ASSERT(-128 <= imm.m_value && imm.m_value < 128); m_assembler.movb_i8m(imm.m_value, address); } void moveDoubleToInts(FPRegisterID src, RegisterID dest1, RegisterID dest2) { ASSERT(isSSE2Present()); m_assembler.pextrw_irr(3, src, dest1); m_assembler.pextrw_irr(2, src, dest2); lshift32(TrustedImm32(16), dest1); or32(dest1, dest2); moveFloatTo32(src, dest1); } void moveIntsToDouble(RegisterID src1, RegisterID src2, FPRegisterID dest, FPRegisterID scratch) { move32ToFloat(src1, dest); move32ToFloat(src2, scratch); lshiftPacked(TrustedImm32(32), scratch); orPacked(scratch, dest); } Jump branchAdd32(ResultCondition cond, TrustedImm32 imm, AbsoluteAddress dest) { m_assembler.addl_im(imm.m_value, dest.m_ptr); return Jump(m_assembler.jCC(x86Condition(cond))); } Jump branchSub32(ResultCondition cond, TrustedImm32 imm, AbsoluteAddress dest) { m_assembler.subl_im(imm.m_value, dest.m_ptr); return Jump(m_assembler.jCC(x86Condition(cond))); } Jump branch32(RelationalCondition cond, AbsoluteAddress left, RegisterID right) { m_assembler.cmpl_rm(right, left.m_ptr); return Jump(m_assembler.jCC(x86Condition(cond))); } Jump branch32(RelationalCondition cond, AbsoluteAddress left, TrustedImm32 right) { m_assembler.cmpl_im(right.m_value, left.m_ptr); return Jump(m_assembler.jCC(x86Condition(cond))); } Call call() { return Call(m_assembler.call(), Call::Linkable); } // Address is a memory location containing the address to jump to void jump(AbsoluteAddress address) { m_assembler.jmp_m(address.m_ptr); } Call tailRecursiveCall() { return Call::fromTailJump(jump()); } Call makeTailRecursiveCall(Jump oldJump) { return Call::fromTailJump(oldJump); } DataLabelPtr moveWithPatch(TrustedImmPtr initialValue, RegisterID dest) { padBeforePatch(); m_assembler.movl_i32r(initialValue.asIntptr(), dest); return DataLabelPtr(this); } Jump branch8(RelationalCondition cond, AbsoluteAddress left, TrustedImm32 right) { m_assembler.cmpb_im(right.m_value, left.m_ptr); return Jump(m_assembler.jCC(x86Condition(cond))); } Jump branchTest8(ResultCondition cond, AbsoluteAddress address, TrustedImm32 mask = TrustedImm32(-1)) { ASSERT(mask.m_value >= -128 && mask.m_value <= 255); if (mask.m_value == -1) m_assembler.cmpb_im(0, address.m_ptr); else m_assembler.testb_im(mask.m_value, address.m_ptr); return Jump(m_assembler.jCC(x86Condition(cond))); } Jump branchPtrWithPatch(RelationalCondition cond, RegisterID left, DataLabelPtr& dataLabel, TrustedImmPtr initialRightValue = TrustedImmPtr(0)) { padBeforePatch(); m_assembler.cmpl_ir_force32(initialRightValue.asIntptr(), left); dataLabel = DataLabelPtr(this); return Jump(m_assembler.jCC(x86Condition(cond))); } Jump branchPtrWithPatch(RelationalCondition cond, Address left, DataLabelPtr& dataLabel, TrustedImmPtr initialRightValue = TrustedImmPtr(0)) { padBeforePatch(); m_assembler.cmpl_im_force32(initialRightValue.asIntptr(), left.offset, left.base); dataLabel = DataLabelPtr(this); return Jump(m_assembler.jCC(x86Condition(cond))); } Jump branch32WithPatch(RelationalCondition cond, Address left, DataLabel32& dataLabel, TrustedImm32 initialRightValue = TrustedImm32(0)) { padBeforePatch(); m_assembler.cmpl_im_force32(initialRightValue.m_value, left.offset, left.base); dataLabel = DataLabel32(this); return Jump(m_assembler.jCC(x86Condition(cond))); } DataLabelPtr storePtrWithPatch(TrustedImmPtr initialValue, ImplicitAddress address) { padBeforePatch(); m_assembler.movl_i32m(initialValue.asIntptr(), address.offset, address.base); return DataLabelPtr(this); } static bool supportsFloatingPoint() { return isSSE2Present(); } static bool supportsFloatingPointTruncate() { return isSSE2Present(); } static bool supportsFloatingPointSqrt() { return isSSE2Present(); } static bool supportsFloatingPointAbs() { return isSSE2Present(); } static FunctionPtr readCallTarget(CodeLocationCall call) { intptr_t offset = reinterpret_cast(call.dataLocation())[-1]; return FunctionPtr(reinterpret_cast(reinterpret_cast(call.dataLocation()) + offset)); } static bool canJumpReplacePatchableBranchPtrWithPatch() { return true; } static bool canJumpReplacePatchableBranch32WithPatch() { return true; } static CodeLocationLabel startOfBranchPtrWithPatchOnRegister(CodeLocationDataLabelPtr label) { const int opcodeBytes = 1; const int modRMBytes = 1; const int immediateBytes = 4; const int totalBytes = opcodeBytes + modRMBytes + immediateBytes; ASSERT(totalBytes >= maxJumpReplacementSize()); return label.labelAtOffset(-totalBytes); } static CodeLocationLabel startOfPatchableBranchPtrWithPatchOnAddress(CodeLocationDataLabelPtr label) { const int opcodeBytes = 1; const int modRMBytes = 1; const int offsetBytes = 0; const int immediateBytes = 4; const int totalBytes = opcodeBytes + modRMBytes + offsetBytes + immediateBytes; ASSERT(totalBytes >= maxJumpReplacementSize()); return label.labelAtOffset(-totalBytes); } static CodeLocationLabel startOfPatchableBranch32WithPatchOnAddress(CodeLocationDataLabel32 label) { const int opcodeBytes = 1; const int modRMBytes = 1; const int offsetBytes = 0; const int immediateBytes = 4; const int totalBytes = opcodeBytes + modRMBytes + offsetBytes + immediateBytes; ASSERT(totalBytes >= maxJumpReplacementSize()); return label.labelAtOffset(-totalBytes); } static void revertJumpReplacementToBranchPtrWithPatch(CodeLocationLabel instructionStart, RegisterID reg, void* initialValue) { X86Assembler::revertJumpTo_cmpl_ir_force32(instructionStart.executableAddress(), reinterpret_cast(initialValue), reg); } static void revertJumpReplacementToPatchableBranchPtrWithPatch(CodeLocationLabel instructionStart, Address address, void* initialValue) { ASSERT(!address.offset); X86Assembler::revertJumpTo_cmpl_im_force32(instructionStart.executableAddress(), reinterpret_cast(initialValue), 0, address.base); } static void revertJumpReplacementToPatchableBranch32WithPatch(CodeLocationLabel instructionStart, Address address, int32_t initialValue) { ASSERT(!address.offset); X86Assembler::revertJumpTo_cmpl_im_force32(instructionStart.executableAddress(), initialValue, 0, address.base); } static void repatchCall(CodeLocationCall call, CodeLocationLabel destination) { X86Assembler::relinkCall(call.dataLocation(), destination.executableAddress()); } static void repatchCall(CodeLocationCall call, FunctionPtr destination) { X86Assembler::relinkCall(call.dataLocation(), destination.executableAddress()); } private: friend class LinkBuffer; static void linkCall(void* code, Call call, FunctionPtr function) { if (call.isFlagSet(Call::Tail)) X86Assembler::linkJump(code, call.m_label, function.value()); else X86Assembler::linkCall(code, call.m_label, function.value()); } }; } // namespace JSC #endif // ENABLE(ASSEMBLER) #endif // MacroAssemblerX86_h