/* * 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 MacroAssemblerX86Common_h #define MacroAssemblerX86Common_h #if ENABLE(ASSEMBLER) #include "X86Assembler.h" #include "AbstractMacroAssembler.h" namespace JSC { class MacroAssemblerX86Common : public AbstractMacroAssembler { protected: #if CPU(X86_64) static const X86Registers::RegisterID scratchRegister = X86Registers::r11; #endif static const int DoubleConditionBitInvert = 0x10; static const int DoubleConditionBitSpecial = 0x20; static const int DoubleConditionBits = DoubleConditionBitInvert | DoubleConditionBitSpecial; public: typedef X86Assembler::FPRegisterID FPRegisterID; typedef X86Assembler::XMMRegisterID XMMRegisterID; static bool isCompactPtrAlignedAddressOffset(ptrdiff_t value) { return value >= -128 && value <= 127; } enum RelationalCondition { Equal = X86Assembler::ConditionE, NotEqual = X86Assembler::ConditionNE, Above = X86Assembler::ConditionA, AboveOrEqual = X86Assembler::ConditionAE, Below = X86Assembler::ConditionB, BelowOrEqual = X86Assembler::ConditionBE, GreaterThan = X86Assembler::ConditionG, GreaterThanOrEqual = X86Assembler::ConditionGE, LessThan = X86Assembler::ConditionL, LessThanOrEqual = X86Assembler::ConditionLE }; enum ResultCondition { Overflow = X86Assembler::ConditionO, Signed = X86Assembler::ConditionS, Zero = X86Assembler::ConditionE, NonZero = X86Assembler::ConditionNE }; enum DoubleCondition { // These conditions will only evaluate to true if the comparison is ordered - i.e. neither operand is NaN. DoubleEqual = X86Assembler::ConditionE | DoubleConditionBitSpecial, DoubleNotEqual = X86Assembler::ConditionNE, DoubleGreaterThan = X86Assembler::ConditionA, DoubleGreaterThanOrEqual = X86Assembler::ConditionAE, DoubleLessThan = X86Assembler::ConditionA | DoubleConditionBitInvert, DoubleLessThanOrEqual = X86Assembler::ConditionAE | DoubleConditionBitInvert, // If either operand is NaN, these conditions always evaluate to true. DoubleEqualOrUnordered = X86Assembler::ConditionE, DoubleNotEqualOrUnordered = X86Assembler::ConditionNE | DoubleConditionBitSpecial, DoubleGreaterThanOrUnordered = X86Assembler::ConditionB | DoubleConditionBitInvert, DoubleGreaterThanOrEqualOrUnordered = X86Assembler::ConditionBE | DoubleConditionBitInvert, DoubleLessThanOrUnordered = X86Assembler::ConditionB, DoubleLessThanOrEqualOrUnordered = X86Assembler::ConditionBE, }; COMPILE_ASSERT( !((X86Assembler::ConditionE | X86Assembler::ConditionNE | X86Assembler::ConditionA | X86Assembler::ConditionAE | X86Assembler::ConditionB | X86Assembler::ConditionBE) & DoubleConditionBits), DoubleConditionBits_should_not_interfere_with_X86Assembler_Condition_codes); static const RegisterID stackPointerRegister = X86Registers::esp; #if ENABLE(JIT_CONSTANT_BLINDING) static bool shouldBlindForSpecificArch(uint32_t value) { return value >= 0x00ffffff; } #if CPU(X86_64) static bool shouldBlindForSpecificArch(uint64_t value) { return value >= 0x00ffffff; } #if OS(DARWIN) // On 64-bit systems other than DARWIN uint64_t and uintptr_t are the same type so overload is prohibited. static bool shouldBlindForSpecificArch(uintptr_t value) { return value >= 0x00ffffff; } #endif #endif #endif // Integer arithmetic operations: // // Operations are typically two operand - operation(source, srcDst) // For many operations the source may be an TrustedImm32, the srcDst operand // may often be a memory location (explictly described using an Address // object). void add32(RegisterID src, RegisterID dest) { m_assembler.addl_rr(src, dest); } void add32(TrustedImm32 imm, Address address) { m_assembler.addl_im(imm.m_value, address.offset, address.base); } void add32(TrustedImm32 imm, RegisterID dest) { m_assembler.addl_ir(imm.m_value, dest); } void add32(Address src, RegisterID dest) { m_assembler.addl_mr(src.offset, src.base, dest); } void add32(RegisterID src, Address dest) { m_assembler.addl_rm(src, dest.offset, dest.base); } void add32(TrustedImm32 imm, RegisterID src, RegisterID dest) { m_assembler.leal_mr(imm.m_value, src, dest); } void and32(RegisterID src, RegisterID dest) { m_assembler.andl_rr(src, dest); } void add32(RegisterID op1, RegisterID op2, RegisterID dest) { if (op2 == dest) { add32(op1, dest); } else { move(op1, dest); add32(op2, dest); } } void and32(TrustedImm32 imm, RegisterID dest) { m_assembler.andl_ir(imm.m_value, dest); } void and32(RegisterID src, Address dest) { m_assembler.andl_rm(src, dest.offset, dest.base); } void and32(Address src, RegisterID dest) { m_assembler.andl_mr(src.offset, src.base, dest); } void and32(TrustedImm32 imm, Address address) { m_assembler.andl_im(imm.m_value, address.offset, address.base); } void and32(RegisterID op1, RegisterID op2, RegisterID dest) { if (op1 == op2) zeroExtend32ToPtr(op1, dest); else if (op1 == dest) and32(op2, dest); else { move(op2, dest); and32(op1, dest); } } void and32(TrustedImm32 imm, RegisterID src, RegisterID dest) { move(src, dest); and32(imm, dest); } void lshift32(RegisterID shift_amount, RegisterID dest) { ASSERT(shift_amount != dest); if (shift_amount == X86Registers::ecx) m_assembler.shll_CLr(dest); else { // On x86 we can only shift by ecx; if asked to shift by another register we'll // need rejig the shift amount into ecx first, and restore the registers afterwards. // If we dest is ecx, then shift the swapped register! swap(shift_amount, X86Registers::ecx); m_assembler.shll_CLr(dest == X86Registers::ecx ? shift_amount : dest); swap(shift_amount, X86Registers::ecx); } } void lshift32(RegisterID src, RegisterID shift_amount, RegisterID dest) { ASSERT(shift_amount != dest); if (src != dest) move(src, dest); lshift32(shift_amount, dest); } void lshift32(TrustedImm32 imm, RegisterID dest) { m_assembler.shll_i8r(imm.m_value, dest); } void lshift32(RegisterID src, TrustedImm32 imm, RegisterID dest) { if (src != dest) move(src, dest); lshift32(imm, dest); } void mul32(RegisterID src, RegisterID dest) { m_assembler.imull_rr(src, dest); } void mul32(RegisterID op1, RegisterID op2, RegisterID dest) { if (op2 == dest) { mul32(op1, dest); } else { move(op1, dest); mul32(op2, dest); } } void mul32(Address src, RegisterID dest) { m_assembler.imull_mr(src.offset, src.base, dest); } void mul32(TrustedImm32 imm, RegisterID src, RegisterID dest) { m_assembler.imull_i32r(src, imm.m_value, dest); } void neg32(RegisterID srcDest) { m_assembler.negl_r(srcDest); } void neg32(Address srcDest) { m_assembler.negl_m(srcDest.offset, srcDest.base); } void or32(RegisterID src, RegisterID dest) { m_assembler.orl_rr(src, dest); } void or32(TrustedImm32 imm, RegisterID dest) { m_assembler.orl_ir(imm.m_value, dest); } void or32(RegisterID src, Address dest) { m_assembler.orl_rm(src, dest.offset, dest.base); } void or32(Address src, RegisterID dest) { m_assembler.orl_mr(src.offset, src.base, dest); } void or32(TrustedImm32 imm, Address address) { m_assembler.orl_im(imm.m_value, address.offset, address.base); } void or32(RegisterID op1, RegisterID op2, RegisterID dest) { if (op1 == op2) zeroExtend32ToPtr(op1, dest); else if (op1 == dest) or32(op2, dest); else { move(op2, dest); or32(op1, dest); } } void or32(TrustedImm32 imm, RegisterID src, RegisterID dest) { move(src, dest); or32(imm, dest); } void rshift32(RegisterID shift_amount, RegisterID dest) { ASSERT(shift_amount != dest); if (shift_amount == X86Registers::ecx) m_assembler.sarl_CLr(dest); else { // On x86 we can only shift by ecx; if asked to shift by another register we'll // need rejig the shift amount into ecx first, and restore the registers afterwards. // If we dest is ecx, then shift the swapped register! swap(shift_amount, X86Registers::ecx); m_assembler.sarl_CLr(dest == X86Registers::ecx ? shift_amount : dest); swap(shift_amount, X86Registers::ecx); } } void rshift32(RegisterID src, RegisterID shift_amount, RegisterID dest) { ASSERT(shift_amount != dest); if (src != dest) move(src, dest); rshift32(shift_amount, dest); } void rshift32(TrustedImm32 imm, RegisterID dest) { m_assembler.sarl_i8r(imm.m_value, dest); } void rshift32(RegisterID src, TrustedImm32 imm, RegisterID dest) { if (src != dest) move(src, dest); rshift32(imm, dest); } void urshift32(RegisterID shift_amount, RegisterID dest) { ASSERT(shift_amount != dest); if (shift_amount == X86Registers::ecx) m_assembler.shrl_CLr(dest); else { // On x86 we can only shift by ecx; if asked to shift by another register we'll // need rejig the shift amount into ecx first, and restore the registers afterwards. // If we dest is ecx, then shift the swapped register! swap(shift_amount, X86Registers::ecx); m_assembler.shrl_CLr(dest == X86Registers::ecx ? shift_amount : dest); swap(shift_amount, X86Registers::ecx); } } void urshift32(RegisterID src, RegisterID shift_amount, RegisterID dest) { ASSERT(shift_amount != dest); if (src != dest) move(src, dest); urshift32(shift_amount, dest); } void urshift32(TrustedImm32 imm, RegisterID dest) { m_assembler.shrl_i8r(imm.m_value, dest); } void urshift32(RegisterID src, TrustedImm32 imm, RegisterID dest) { if (src != dest) move(src, dest); urshift32(imm, dest); } void sub32(RegisterID src, RegisterID dest) { m_assembler.subl_rr(src, dest); } void sub32(TrustedImm32 imm, RegisterID dest) { m_assembler.subl_ir(imm.m_value, dest); } void sub32(TrustedImm32 imm, Address address) { m_assembler.subl_im(imm.m_value, address.offset, address.base); } void sub32(Address src, RegisterID dest) { m_assembler.subl_mr(src.offset, src.base, dest); } void sub32(RegisterID src, Address dest) { m_assembler.subl_rm(src, dest.offset, dest.base); } void xor32(RegisterID src, RegisterID dest) { m_assembler.xorl_rr(src, dest); } void xor32(TrustedImm32 imm, Address dest) { if (imm.m_value == -1) m_assembler.notl_m(dest.offset, dest.base); else m_assembler.xorl_im(imm.m_value, dest.offset, dest.base); } void xor32(TrustedImm32 imm, RegisterID dest) { if (imm.m_value == -1) m_assembler.notl_r(dest); else m_assembler.xorl_ir(imm.m_value, dest); } void xor32(RegisterID src, Address dest) { m_assembler.xorl_rm(src, dest.offset, dest.base); } void xor32(Address src, RegisterID dest) { m_assembler.xorl_mr(src.offset, src.base, dest); } void xor32(RegisterID op1, RegisterID op2, RegisterID dest) { if (op1 == op2) move(TrustedImm32(0), dest); else if (op1 == dest) xor32(op2, dest); else { move(op2, dest); xor32(op1, dest); } } void xor32(TrustedImm32 imm, RegisterID src, RegisterID dest) { move(src, dest); xor32(imm, dest); } void sqrtDouble(FPRegisterID src, FPRegisterID dst) { m_assembler.sqrtsd_rr(src, dst); } void absDouble(FPRegisterID src, FPRegisterID dst) { ASSERT(src != dst); static const double negativeZeroConstant = -0.0; loadDouble(&negativeZeroConstant, dst); m_assembler.andnpd_rr(src, dst); } void negateDouble(FPRegisterID src, FPRegisterID dst) { ASSERT(src != dst); static const double negativeZeroConstant = -0.0; loadDouble(&negativeZeroConstant, dst); m_assembler.xorpd_rr(src, dst); } // Memory access operations: // // Loads are of the form load(address, destination) and stores of the form // store(source, address). The source for a store may be an TrustedImm32. Address // operand objects to loads and store will be implicitly constructed if a // register is passed. void load32(ImplicitAddress address, RegisterID dest) { m_assembler.movl_mr(address.offset, address.base, dest); } void load32(BaseIndex address, RegisterID dest) { m_assembler.movl_mr(address.offset, address.base, address.index, address.scale, dest); } void load32WithUnalignedHalfWords(BaseIndex address, RegisterID dest) { load32(address, dest); } void load16Unaligned(BaseIndex address, RegisterID dest) { load16(address, dest); } DataLabel32 load32WithAddressOffsetPatch(Address address, RegisterID dest) { padBeforePatch(); m_assembler.movl_mr_disp32(address.offset, address.base, dest); return DataLabel32(this); } DataLabelCompact load32WithCompactAddressOffsetPatch(Address address, RegisterID dest) { padBeforePatch(); m_assembler.movl_mr_disp8(address.offset, address.base, dest); return DataLabelCompact(this); } static void repatchCompact(CodeLocationDataLabelCompact dataLabelCompact, int32_t value) { ASSERT(isCompactPtrAlignedAddressOffset(value)); AssemblerType_T::repatchCompact(dataLabelCompact.dataLocation(), value); } DataLabelCompact loadCompactWithAddressOffsetPatch(Address address, RegisterID dest) { padBeforePatch(); m_assembler.movl_mr_disp8(address.offset, address.base, dest); return DataLabelCompact(this); } void load8(BaseIndex address, RegisterID dest) { m_assembler.movzbl_mr(address.offset, address.base, address.index, address.scale, dest); } void load8(ImplicitAddress address, RegisterID dest) { m_assembler.movzbl_mr(address.offset, address.base, dest); } void load8Signed(BaseIndex address, RegisterID dest) { m_assembler.movsbl_mr(address.offset, address.base, address.index, address.scale, dest); } void load8Signed(ImplicitAddress address, RegisterID dest) { m_assembler.movsbl_mr(address.offset, address.base, dest); } void load16(BaseIndex address, RegisterID dest) { m_assembler.movzwl_mr(address.offset, address.base, address.index, address.scale, dest); } void load16(Address address, RegisterID dest) { m_assembler.movzwl_mr(address.offset, address.base, dest); } void load16Signed(BaseIndex address, RegisterID dest) { m_assembler.movswl_mr(address.offset, address.base, address.index, address.scale, dest); } void load16Signed(Address address, RegisterID dest) { m_assembler.movswl_mr(address.offset, address.base, dest); } DataLabel32 store32WithAddressOffsetPatch(RegisterID src, Address address) { padBeforePatch(); m_assembler.movl_rm_disp32(src, address.offset, address.base); return DataLabel32(this); } void store32(RegisterID src, ImplicitAddress address) { m_assembler.movl_rm(src, address.offset, address.base); } void store32(RegisterID src, BaseIndex address) { m_assembler.movl_rm(src, address.offset, address.base, address.index, address.scale); } void store32(TrustedImm32 imm, ImplicitAddress address) { m_assembler.movl_i32m(imm.m_value, address.offset, address.base); } void store32(TrustedImm32 imm, BaseIndex address) { m_assembler.movl_i32m(imm.m_value, address.offset, address.base, address.index, address.scale); } void store8(TrustedImm32 imm, Address address) { ASSERT(-128 <= imm.m_value && imm.m_value < 128); m_assembler.movb_i8m(imm.m_value, address.offset, address.base); } void store8(TrustedImm32 imm, BaseIndex address) { ASSERT(-128 <= imm.m_value && imm.m_value < 128); m_assembler.movb_i8m(imm.m_value, address.offset, address.base, address.index, address.scale); } void store8(RegisterID src, BaseIndex address) { #if CPU(X86) // On 32-bit x86 we can only store from the first 4 registers; // esp..edi are mapped to the 'h' registers! if (src >= 4) { // Pick a temporary register. RegisterID temp; if (address.base != X86Registers::eax && address.index != X86Registers::eax) temp = X86Registers::eax; else if (address.base != X86Registers::ebx && address.index != X86Registers::ebx) temp = X86Registers::ebx; else { ASSERT(address.base != X86Registers::ecx && address.index != X86Registers::ecx); temp = X86Registers::ecx; } // Swap to the temporary register to perform the store. swap(src, temp); m_assembler.movb_rm(temp, address.offset, address.base, address.index, address.scale); swap(src, temp); return; } #endif m_assembler.movb_rm(src, address.offset, address.base, address.index, address.scale); } void store16(RegisterID src, BaseIndex address) { #if CPU(X86) // On 32-bit x86 we can only store from the first 4 registers; // esp..edi are mapped to the 'h' registers! if (src >= 4) { // Pick a temporary register. RegisterID temp; if (address.base != X86Registers::eax && address.index != X86Registers::eax) temp = X86Registers::eax; else if (address.base != X86Registers::ebx && address.index != X86Registers::ebx) temp = X86Registers::ebx; else { ASSERT(address.base != X86Registers::ecx && address.index != X86Registers::ecx); temp = X86Registers::ecx; } // Swap to the temporary register to perform the store. swap(src, temp); m_assembler.movw_rm(temp, address.offset, address.base, address.index, address.scale); swap(src, temp); return; } #endif m_assembler.movw_rm(src, address.offset, address.base, address.index, address.scale); } // Floating-point operation: // // Presently only supports SSE, not x87 floating point. void moveDouble(FPRegisterID src, FPRegisterID dest) { ASSERT(isSSE2Present()); if (src != dest) m_assembler.movsd_rr(src, dest); } void loadDouble(const void* address, FPRegisterID dest) { #if CPU(X86) ASSERT(isSSE2Present()); m_assembler.movsd_mr(address, dest); #else move(TrustedImmPtr(address), scratchRegister); loadDouble(scratchRegister, dest); #endif } void loadDouble(ImplicitAddress address, FPRegisterID dest) { ASSERT(isSSE2Present()); m_assembler.movsd_mr(address.offset, address.base, dest); } void loadDouble(BaseIndex address, FPRegisterID dest) { ASSERT(isSSE2Present()); m_assembler.movsd_mr(address.offset, address.base, address.index, address.scale, dest); } void loadFloat(BaseIndex address, FPRegisterID dest) { ASSERT(isSSE2Present()); m_assembler.movss_mr(address.offset, address.base, address.index, address.scale, dest); } void storeDouble(FPRegisterID src, ImplicitAddress address) { ASSERT(isSSE2Present()); m_assembler.movsd_rm(src, address.offset, address.base); } void storeDouble(FPRegisterID src, BaseIndex address) { ASSERT(isSSE2Present()); m_assembler.movsd_rm(src, address.offset, address.base, address.index, address.scale); } void storeFloat(FPRegisterID src, BaseIndex address) { ASSERT(isSSE2Present()); m_assembler.movss_rm(src, address.offset, address.base, address.index, address.scale); } void convertDoubleToFloat(FPRegisterID src, FPRegisterID dst) { ASSERT(isSSE2Present()); m_assembler.cvtsd2ss_rr(src, dst); } void convertFloatToDouble(FPRegisterID src, FPRegisterID dst) { ASSERT(isSSE2Present()); m_assembler.cvtss2sd_rr(src, dst); } void addDouble(FPRegisterID src, FPRegisterID dest) { ASSERT(isSSE2Present()); m_assembler.addsd_rr(src, dest); } void addDouble(FPRegisterID op1, FPRegisterID op2, FPRegisterID dest) { ASSERT(isSSE2Present()); if (op1 == dest) addDouble(op2, dest); else { moveDouble(op2, dest); addDouble(op1, dest); } } void addDouble(Address src, FPRegisterID dest) { ASSERT(isSSE2Present()); m_assembler.addsd_mr(src.offset, src.base, dest); } void divDouble(FPRegisterID src, FPRegisterID dest) { ASSERT(isSSE2Present()); m_assembler.divsd_rr(src, dest); } void divDouble(FPRegisterID op1, FPRegisterID op2, FPRegisterID dest) { // B := A / B is invalid. ASSERT(op1 == dest || op2 != dest); moveDouble(op1, dest); divDouble(op2, dest); } void divDouble(Address src, FPRegisterID dest) { ASSERT(isSSE2Present()); m_assembler.divsd_mr(src.offset, src.base, dest); } void subDouble(FPRegisterID src, FPRegisterID dest) { ASSERT(isSSE2Present()); m_assembler.subsd_rr(src, dest); } void subDouble(FPRegisterID op1, FPRegisterID op2, FPRegisterID dest) { // B := A - B is invalid. ASSERT(op1 == dest || op2 != dest); moveDouble(op1, dest); subDouble(op2, dest); } void subDouble(Address src, FPRegisterID dest) { ASSERT(isSSE2Present()); m_assembler.subsd_mr(src.offset, src.base, dest); } void mulDouble(FPRegisterID src, FPRegisterID dest) { ASSERT(isSSE2Present()); m_assembler.mulsd_rr(src, dest); } void mulDouble(FPRegisterID op1, FPRegisterID op2, FPRegisterID dest) { ASSERT(isSSE2Present()); if (op1 == dest) mulDouble(op2, dest); else { moveDouble(op2, dest); mulDouble(op1, dest); } } void mulDouble(Address src, FPRegisterID dest) { ASSERT(isSSE2Present()); m_assembler.mulsd_mr(src.offset, src.base, dest); } void convertInt32ToDouble(RegisterID src, FPRegisterID dest) { ASSERT(isSSE2Present()); m_assembler.cvtsi2sd_rr(src, dest); } void convertInt32ToDouble(Address src, FPRegisterID dest) { ASSERT(isSSE2Present()); m_assembler.cvtsi2sd_mr(src.offset, src.base, dest); } Jump branchDouble(DoubleCondition cond, FPRegisterID left, FPRegisterID right) { ASSERT(isSSE2Present()); if (cond & DoubleConditionBitInvert) m_assembler.ucomisd_rr(left, right); else m_assembler.ucomisd_rr(right, left); if (cond == DoubleEqual) { if (left == right) return Jump(m_assembler.jnp()); Jump isUnordered(m_assembler.jp()); Jump result = Jump(m_assembler.je()); isUnordered.link(this); return result; } else if (cond == DoubleNotEqualOrUnordered) { if (left == right) return Jump(m_assembler.jp()); Jump isUnordered(m_assembler.jp()); Jump isEqual(m_assembler.je()); isUnordered.link(this); Jump result = jump(); isEqual.link(this); return result; } ASSERT(!(cond & DoubleConditionBitSpecial)); return Jump(m_assembler.jCC(static_cast(cond & ~DoubleConditionBits))); } // Truncates 'src' to an integer, and places the resulting 'dest'. // If the result is not representable as a 32 bit value, branch. // May also branch for some values that are representable in 32 bits // (specifically, in this case, INT_MIN). enum BranchTruncateType { BranchIfTruncateFailed, BranchIfTruncateSuccessful }; Jump branchTruncateDoubleToInt32(FPRegisterID src, RegisterID dest, BranchTruncateType branchType = BranchIfTruncateFailed) { ASSERT(isSSE2Present()); m_assembler.cvttsd2si_rr(src, dest); return branch32(branchType ? NotEqual : Equal, dest, TrustedImm32(0x80000000)); } Jump branchTruncateDoubleToUint32(FPRegisterID src, RegisterID dest, BranchTruncateType branchType = BranchIfTruncateFailed) { ASSERT(isSSE2Present()); m_assembler.cvttsd2si_rr(src, dest); return branch32(branchType ? GreaterThanOrEqual : LessThan, dest, TrustedImm32(0)); } void truncateDoubleToInt32(FPRegisterID src, RegisterID dest) { ASSERT(isSSE2Present()); m_assembler.cvttsd2si_rr(src, dest); } #if CPU(X86_64) void truncateDoubleToUint32(FPRegisterID src, RegisterID dest) { ASSERT(isSSE2Present()); m_assembler.cvttsd2siq_rr(src, dest); } #endif // Convert 'src' to an integer, and places the resulting 'dest'. // If the result is not representable as a 32 bit value, branch. // May also branch for some values that are representable in 32 bits // (specifically, in this case, 0). void branchConvertDoubleToInt32(FPRegisterID src, RegisterID dest, JumpList& failureCases, FPRegisterID fpTemp) { ASSERT(isSSE2Present()); m_assembler.cvttsd2si_rr(src, dest); // If the result is zero, it might have been -0.0, and the double comparison won't catch this! failureCases.append(branchTest32(Zero, dest)); // Convert the integer result back to float & compare to the original value - if not equal or unordered (NaN) then jump. convertInt32ToDouble(dest, fpTemp); m_assembler.ucomisd_rr(fpTemp, src); failureCases.append(m_assembler.jp()); failureCases.append(m_assembler.jne()); } Jump branchDoubleNonZero(FPRegisterID reg, FPRegisterID scratch) { ASSERT(isSSE2Present()); m_assembler.xorpd_rr(scratch, scratch); return branchDouble(DoubleNotEqual, reg, scratch); } Jump branchDoubleZeroOrNaN(FPRegisterID reg, FPRegisterID scratch) { ASSERT(isSSE2Present()); m_assembler.xorpd_rr(scratch, scratch); return branchDouble(DoubleEqualOrUnordered, reg, scratch); } void lshiftPacked(TrustedImm32 imm, XMMRegisterID reg) { ASSERT(isSSE2Present()); m_assembler.psllq_i8r(imm.m_value, reg); } void rshiftPacked(TrustedImm32 imm, XMMRegisterID reg) { ASSERT(isSSE2Present()); m_assembler.psrlq_i8r(imm.m_value, reg); } void orPacked(XMMRegisterID src, XMMRegisterID dst) { ASSERT(isSSE2Present()); m_assembler.por_rr(src, dst); } void moveInt32ToPacked(RegisterID src, XMMRegisterID dst) { ASSERT(isSSE2Present()); m_assembler.movd_rr(src, dst); } void movePackedToInt32(XMMRegisterID src, RegisterID dst) { ASSERT(isSSE2Present()); m_assembler.movd_rr(src, dst); } // Stack manipulation operations: // // The ABI is assumed to provide a stack abstraction to memory, // containing machine word sized units of data. Push and pop // operations add and remove a single register sized unit of data // to or from the stack. Peek and poke operations read or write // values on the stack, without moving the current stack position. void pop(RegisterID dest) { m_assembler.pop_r(dest); } void push(RegisterID src) { m_assembler.push_r(src); } void push(Address address) { m_assembler.push_m(address.offset, address.base); } void push(TrustedImm32 imm) { m_assembler.push_i32(imm.m_value); } // Register move operations: // // Move values in registers. void move(TrustedImm32 imm, RegisterID dest) { // Note: on 64-bit the TrustedImm32 value is zero extended into the register, it // may be useful to have a separate version that sign extends the value? if (!imm.m_value) m_assembler.xorl_rr(dest, dest); else m_assembler.movl_i32r(imm.m_value, dest); } #if CPU(X86_64) void move(RegisterID src, RegisterID dest) { // Note: on 64-bit this is is a full register move; perhaps it would be // useful to have separate move32 & movePtr, with move32 zero extending? if (src != dest) m_assembler.movq_rr(src, dest); } void move(TrustedImmPtr imm, RegisterID dest) { m_assembler.movq_i64r(imm.asIntptr(), dest); } void move(TrustedImm64 imm, RegisterID dest) { m_assembler.movq_i64r(imm.m_value, dest); } void swap(RegisterID reg1, RegisterID reg2) { if (reg1 != reg2) m_assembler.xchgq_rr(reg1, reg2); } void signExtend32ToPtr(RegisterID src, RegisterID dest) { m_assembler.movsxd_rr(src, dest); } void zeroExtend32ToPtr(RegisterID src, RegisterID dest) { m_assembler.movl_rr(src, dest); } #else void move(RegisterID src, RegisterID dest) { if (src != dest) m_assembler.movl_rr(src, dest); } void move(TrustedImmPtr imm, RegisterID dest) { m_assembler.movl_i32r(imm.asIntptr(), dest); } void swap(RegisterID reg1, RegisterID reg2) { if (reg1 != reg2) m_assembler.xchgl_rr(reg1, reg2); } void signExtend32ToPtr(RegisterID src, RegisterID dest) { move(src, dest); } void zeroExtend32ToPtr(RegisterID src, RegisterID dest) { move(src, dest); } #endif // Forwards / external control flow operations: // // This set of jump and conditional branch operations return a Jump // object which may linked at a later point, allow forwards jump, // or jumps that will require external linkage (after the code has been // relocated). // // For branches, signed <, >, <= and >= are denoted as l, g, le, and ge // respecitvely, for unsigned comparisons the names b, a, be, and ae are // used (representing the names 'below' and 'above'). // // Operands to the comparision are provided in the expected order, e.g. // jle32(reg1, TrustedImm32(5)) will branch if the value held in reg1, when // treated as a signed 32bit value, is less than or equal to 5. // // jz and jnz test whether the first operand is equal to zero, and take // an optional second operand of a mask under which to perform the test. public: Jump branch8(RelationalCondition cond, Address left, TrustedImm32 right) { m_assembler.cmpb_im(right.m_value, left.offset, left.base); return Jump(m_assembler.jCC(x86Condition(cond))); } Jump branch32(RelationalCondition cond, RegisterID left, RegisterID right) { m_assembler.cmpl_rr(right, left); return Jump(m_assembler.jCC(x86Condition(cond))); } Jump branch32(RelationalCondition cond, RegisterID left, TrustedImm32 right) { if (((cond == Equal) || (cond == NotEqual)) && !right.m_value) m_assembler.testl_rr(left, left); else m_assembler.cmpl_ir(right.m_value, left); return Jump(m_assembler.jCC(x86Condition(cond))); } Jump branch32(RelationalCondition cond, RegisterID left, Address right) { m_assembler.cmpl_mr(right.offset, right.base, left); return Jump(m_assembler.jCC(x86Condition(cond))); } Jump branch32(RelationalCondition cond, Address left, RegisterID right) { m_assembler.cmpl_rm(right, left.offset, left.base); return Jump(m_assembler.jCC(x86Condition(cond))); } Jump branch32(RelationalCondition cond, Address left, TrustedImm32 right) { m_assembler.cmpl_im(right.m_value, left.offset, left.base); return Jump(m_assembler.jCC(x86Condition(cond))); } Jump branch32(RelationalCondition cond, BaseIndex left, TrustedImm32 right) { m_assembler.cmpl_im(right.m_value, left.offset, left.base, left.index, left.scale); return Jump(m_assembler.jCC(x86Condition(cond))); } Jump branch32WithUnalignedHalfWords(RelationalCondition cond, BaseIndex left, TrustedImm32 right) { return branch32(cond, left, right); } Jump branchTest32(ResultCondition cond, RegisterID reg, RegisterID mask) { m_assembler.testl_rr(reg, mask); return Jump(m_assembler.jCC(x86Condition(cond))); } Jump branchTest32(ResultCondition cond, RegisterID reg, TrustedImm32 mask = TrustedImm32(-1)) { // if we are only interested in the low seven bits, this can be tested with a testb if (mask.m_value == -1) m_assembler.testl_rr(reg, reg); else m_assembler.testl_i32r(mask.m_value, reg); return Jump(m_assembler.jCC(x86Condition(cond))); } Jump branchTest32(ResultCondition cond, Address address, TrustedImm32 mask = TrustedImm32(-1)) { if (mask.m_value == -1) m_assembler.cmpl_im(0, address.offset, address.base); else m_assembler.testl_i32m(mask.m_value, address.offset, address.base); return Jump(m_assembler.jCC(x86Condition(cond))); } Jump branchTest32(ResultCondition cond, BaseIndex address, TrustedImm32 mask = TrustedImm32(-1)) { if (mask.m_value == -1) m_assembler.cmpl_im(0, address.offset, address.base, address.index, address.scale); else m_assembler.testl_i32m(mask.m_value, address.offset, address.base, address.index, address.scale); return Jump(m_assembler.jCC(x86Condition(cond))); } Jump branchTest8(ResultCondition cond, Address address, TrustedImm32 mask = TrustedImm32(-1)) { // Byte in TrustedImm32 is not well defined, so be a little permisive here, but don't accept nonsense values. ASSERT(mask.m_value >= -128 && mask.m_value <= 255); if (mask.m_value == -1) m_assembler.cmpb_im(0, address.offset, address.base); else m_assembler.testb_im(mask.m_value, address.offset, address.base); return Jump(m_assembler.jCC(x86Condition(cond))); } Jump branchTest8(ResultCondition cond, BaseIndex address, TrustedImm32 mask = TrustedImm32(-1)) { // Byte in TrustedImm32 is not well defined, so be a little permisive here, but don't accept nonsense values. ASSERT(mask.m_value >= -128 && mask.m_value <= 255); if (mask.m_value == -1) m_assembler.cmpb_im(0, address.offset, address.base, address.index, address.scale); else m_assembler.testb_im(mask.m_value, address.offset, address.base, address.index, address.scale); return Jump(m_assembler.jCC(x86Condition(cond))); } Jump branch8(RelationalCondition cond, BaseIndex left, TrustedImm32 right) { ASSERT(!(right.m_value & 0xFFFFFF00)); m_assembler.cmpb_im(right.m_value, left.offset, left.base, left.index, left.scale); return Jump(m_assembler.jCC(x86Condition(cond))); } Jump jump() { return Jump(m_assembler.jmp()); } void jump(RegisterID target) { m_assembler.jmp_r(target); } // Address is a memory location containing the address to jump to void jump(Address address) { m_assembler.jmp_m(address.offset, address.base); } // Arithmetic control flow operations: // // This set of conditional branch operations branch based // on the result of an arithmetic operation. The operation // is performed as normal, storing the result. // // * jz operations branch if the result is zero. // * jo operations branch if the (signed) arithmetic // operation caused an overflow to occur. Jump branchAdd32(ResultCondition cond, RegisterID src, RegisterID dest) { add32(src, dest); return Jump(m_assembler.jCC(x86Condition(cond))); } Jump branchAdd32(ResultCondition cond, TrustedImm32 imm, RegisterID dest) { add32(imm, dest); return Jump(m_assembler.jCC(x86Condition(cond))); } Jump branchAdd32(ResultCondition cond, TrustedImm32 src, Address dest) { add32(src, dest); return Jump(m_assembler.jCC(x86Condition(cond))); } Jump branchAdd32(ResultCondition cond, RegisterID src, Address dest) { add32(src, dest); return Jump(m_assembler.jCC(x86Condition(cond))); } Jump branchAdd32(ResultCondition cond, Address src, RegisterID dest) { add32(src, dest); return Jump(m_assembler.jCC(x86Condition(cond))); } Jump branchAdd32(ResultCondition cond, RegisterID src1, RegisterID src2, RegisterID dest) { if (src1 == dest) return branchAdd32(cond, src2, dest); move(src2, dest); return branchAdd32(cond, src1, dest); } Jump branchAdd32(ResultCondition cond, RegisterID src, TrustedImm32 imm, RegisterID dest) { move(src, dest); return branchAdd32(cond, imm, dest); } Jump branchMul32(ResultCondition cond, RegisterID src, RegisterID dest) { mul32(src, dest); if (cond != Overflow) m_assembler.testl_rr(dest, dest); return Jump(m_assembler.jCC(x86Condition(cond))); } Jump branchMul32(ResultCondition cond, Address src, RegisterID dest) { mul32(src, dest); if (cond != Overflow) m_assembler.testl_rr(dest, dest); return Jump(m_assembler.jCC(x86Condition(cond))); } Jump branchMul32(ResultCondition cond, TrustedImm32 imm, RegisterID src, RegisterID dest) { mul32(imm, src, dest); if (cond != Overflow) m_assembler.testl_rr(dest, dest); return Jump(m_assembler.jCC(x86Condition(cond))); } Jump branchMul32(ResultCondition cond, RegisterID src1, RegisterID src2, RegisterID dest) { if (src1 == dest) return branchMul32(cond, src2, dest); move(src2, dest); return branchMul32(cond, src1, dest); } Jump branchSub32(ResultCondition cond, RegisterID src, RegisterID dest) { sub32(src, dest); return Jump(m_assembler.jCC(x86Condition(cond))); } Jump branchSub32(ResultCondition cond, TrustedImm32 imm, RegisterID dest) { sub32(imm, dest); return Jump(m_assembler.jCC(x86Condition(cond))); } Jump branchSub32(ResultCondition cond, TrustedImm32 imm, Address dest) { sub32(imm, dest); return Jump(m_assembler.jCC(x86Condition(cond))); } Jump branchSub32(ResultCondition cond, RegisterID src, Address dest) { sub32(src, dest); return Jump(m_assembler.jCC(x86Condition(cond))); } Jump branchSub32(ResultCondition cond, Address src, RegisterID dest) { sub32(src, dest); return Jump(m_assembler.jCC(x86Condition(cond))); } Jump branchSub32(ResultCondition cond, RegisterID src1, RegisterID src2, RegisterID dest) { // B := A - B is invalid. ASSERT(src1 == dest || src2 != dest); move(src1, dest); return branchSub32(cond, src2, dest); } Jump branchSub32(ResultCondition cond, RegisterID src1, TrustedImm32 src2, RegisterID dest) { move(src1, dest); return branchSub32(cond, src2, dest); } Jump branchNeg32(ResultCondition cond, RegisterID srcDest) { neg32(srcDest); return Jump(m_assembler.jCC(x86Condition(cond))); } Jump branchOr32(ResultCondition cond, RegisterID src, RegisterID dest) { or32(src, dest); return Jump(m_assembler.jCC(x86Condition(cond))); } // Miscellaneous operations: void breakpoint() { m_assembler.int3(); } Call nearCall() { return Call(m_assembler.call(), Call::LinkableNear); } Call call(RegisterID target) { return Call(m_assembler.call(target), Call::None); } void call(Address address) { m_assembler.call_m(address.offset, address.base); } void ret() { m_assembler.ret(); } void compare8(RelationalCondition cond, Address left, TrustedImm32 right, RegisterID dest) { m_assembler.cmpb_im(right.m_value, left.offset, left.base); set32(x86Condition(cond), dest); } void compare32(RelationalCondition cond, RegisterID left, RegisterID right, RegisterID dest) { m_assembler.cmpl_rr(right, left); set32(x86Condition(cond), dest); } void compare32(RelationalCondition cond, RegisterID left, TrustedImm32 right, RegisterID dest) { if (((cond == Equal) || (cond == NotEqual)) && !right.m_value) m_assembler.testl_rr(left, left); else m_assembler.cmpl_ir(right.m_value, left); set32(x86Condition(cond), dest); } // FIXME: // The mask should be optional... perhaps the argument order should be // dest-src, operations always have a dest? ... possibly not true, considering // asm ops like test, or pseudo ops like pop(). void test8(ResultCondition cond, Address address, TrustedImm32 mask, RegisterID dest) { if (mask.m_value == -1) m_assembler.cmpb_im(0, address.offset, address.base); else m_assembler.testb_im(mask.m_value, address.offset, address.base); set32(x86Condition(cond), dest); } void test32(ResultCondition cond, Address address, TrustedImm32 mask, RegisterID dest) { if (mask.m_value == -1) m_assembler.cmpl_im(0, address.offset, address.base); else m_assembler.testl_i32m(mask.m_value, address.offset, address.base); set32(x86Condition(cond), dest); } // Invert a relational condition, e.g. == becomes !=, < becomes >=, etc. static RelationalCondition invert(RelationalCondition cond) { return static_cast(cond ^ 1); } void nop() { m_assembler.nop(); } static void replaceWithJump(CodeLocationLabel instructionStart, CodeLocationLabel destination) { X86Assembler::replaceWithJump(instructionStart.executableAddress(), destination.executableAddress()); } static ptrdiff_t maxJumpReplacementSize() { return X86Assembler::maxJumpReplacementSize(); } protected: X86Assembler::Condition x86Condition(RelationalCondition cond) { return static_cast(cond); } X86Assembler::Condition x86Condition(ResultCondition cond) { return static_cast(cond); } void set32(X86Assembler::Condition cond, RegisterID dest) { #if CPU(X86) // On 32-bit x86 we can only set the first 4 registers; // esp..edi are mapped to the 'h' registers! if (dest >= 4) { m_assembler.xchgl_rr(dest, X86Registers::eax); m_assembler.setCC_r(cond, X86Registers::eax); m_assembler.movzbl_rr(X86Registers::eax, X86Registers::eax); m_assembler.xchgl_rr(dest, X86Registers::eax); return; } #endif m_assembler.setCC_r(cond, dest); m_assembler.movzbl_rr(dest, dest); } private: // Only MacroAssemblerX86 should be using the following method; SSE2 is always available on // x86_64, and clients & subclasses of MacroAssembler should be using 'supportsFloatingPoint()'. friend class MacroAssemblerX86; #if CPU(X86) #if OS(MAC_OS_X) // All X86 Macs are guaranteed to support at least SSE2, static bool isSSE2Present() { return true; } #else // OS(MAC_OS_X) enum SSE2CheckState { NotCheckedSSE2, HasSSE2, NoSSE2 }; static bool isSSE2Present() { if (s_sse2CheckState == NotCheckedSSE2) { // Default the flags value to zero; if the compiler is // not MSVC or GCC we will read this as SSE2 not present. int flags = 0; #if COMPILER(MSVC) _asm { mov eax, 1 // cpuid function 1 gives us the standard feature set cpuid; mov flags, edx; } #elif COMPILER(GCC) asm ( "movl $0x1, %%eax;" "pushl %%ebx;" "cpuid;" "popl %%ebx;" "movl %%edx, %0;" : "=g" (flags) : : "%eax", "%ecx", "%edx" ); #endif static const int SSE2FeatureBit = 1 << 26; s_sse2CheckState = (flags & SSE2FeatureBit) ? HasSSE2 : NoSSE2; } // Only check once. ASSERT(s_sse2CheckState != NotCheckedSSE2); return s_sse2CheckState == HasSSE2; } static SSE2CheckState s_sse2CheckState; #endif // OS(MAC_OS_X) #elif !defined(NDEBUG) // CPU(X86) // On x86-64 we should never be checking for SSE2 in a non-debug build, // but non debug add this method to keep the asserts above happy. static bool isSSE2Present() { return true; } #endif }; } // namespace JSC #endif // ENABLE(ASSEMBLER) #endif // MacroAssemblerX86Common_h