/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 4 -*- * vim: set ts=8 sts=4 et sw=4 tw=99: * This Source Code Form is subject to the terms of the Mozilla Public * License, v. 2.0. If a copy of the MPL was not distributed with this * file, You can obtain one at http://mozilla.org/MPL/2.0/. */ #ifndef jit_mips_shared_MacroAssembler_mips_shared_inl_h #define jit_mips_shared_MacroAssembler_mips_shared_inl_h #include "jit/mips-shared/MacroAssembler-mips-shared.h" namespace js { namespace jit { //{{{ check_macroassembler_style void MacroAssembler::moveFloat32ToGPR(FloatRegister src, Register dest) { moveFromFloat32(src, dest); } void MacroAssembler::moveGPRToFloat32(Register src, FloatRegister dest) { moveToFloat32(src, dest); } void MacroAssembler::move8SignExtend(Register src, Register dest) { as_seb(dest, src); } void MacroAssembler::move16SignExtend(Register src, Register dest) { as_seh(dest, src); } // =============================================================== // Logical instructions void MacroAssembler::not32(Register reg) { ma_not(reg, reg); } void MacroAssembler::and32(Register src, Register dest) { as_and(dest, dest, src); } void MacroAssembler::and32(Imm32 imm, Register dest) { ma_and(dest, imm); } void MacroAssembler::and32(Imm32 imm, const Address& dest) { load32(dest, SecondScratchReg); ma_and(SecondScratchReg, imm); store32(SecondScratchReg, dest); } void MacroAssembler::and32(const Address& src, Register dest) { load32(src, SecondScratchReg); ma_and(dest, SecondScratchReg); } void MacroAssembler::or32(Register src, Register dest) { ma_or(dest, src); } void MacroAssembler::or32(Imm32 imm, Register dest) { ma_or(dest, imm); } void MacroAssembler::or32(Imm32 imm, const Address& dest) { load32(dest, SecondScratchReg); ma_or(SecondScratchReg, imm); store32(SecondScratchReg, dest); } void MacroAssembler::xor32(Register src, Register dest) { ma_xor(dest, src); } void MacroAssembler::xor32(Imm32 imm, Register dest) { ma_xor(dest, imm); } // =============================================================== // Arithmetic instructions void MacroAssembler::add32(Register src, Register dest) { as_addu(dest, dest, src); } void MacroAssembler::add32(Imm32 imm, Register dest) { ma_addu(dest, dest, imm); } void MacroAssembler::add32(Imm32 imm, const Address& dest) { load32(dest, SecondScratchReg); ma_addu(SecondScratchReg, imm); store32(SecondScratchReg, dest); } void MacroAssembler::addPtr(Imm32 imm, const Address& dest) { loadPtr(dest, ScratchRegister); addPtr(imm, ScratchRegister); storePtr(ScratchRegister, dest); } void MacroAssembler::addPtr(const Address& src, Register dest) { loadPtr(src, ScratchRegister); addPtr(ScratchRegister, dest); } void MacroAssembler::addDouble(FloatRegister src, FloatRegister dest) { as_addd(dest, dest, src); } void MacroAssembler::addFloat32(FloatRegister src, FloatRegister dest) { as_adds(dest, dest, src); } void MacroAssembler::sub32(Register src, Register dest) { as_subu(dest, dest, src); } void MacroAssembler::sub32(Imm32 imm, Register dest) { ma_subu(dest, dest, imm); } void MacroAssembler::sub32(const Address& src, Register dest) { load32(src, SecondScratchReg); as_subu(dest, dest, SecondScratchReg); } void MacroAssembler::subPtr(Register src, const Address& dest) { loadPtr(dest, SecondScratchReg); subPtr(src, SecondScratchReg); storePtr(SecondScratchReg, dest); } void MacroAssembler::subPtr(const Address& addr, Register dest) { loadPtr(addr, SecondScratchReg); subPtr(SecondScratchReg, dest); } void MacroAssembler::subDouble(FloatRegister src, FloatRegister dest) { as_subd(dest, dest, src); } void MacroAssembler::subFloat32(FloatRegister src, FloatRegister dest) { as_subs(dest, dest, src); } void MacroAssembler::mul32(Register rhs, Register srcDest) { as_mul(srcDest, srcDest, rhs); } void MacroAssembler::mulFloat32(FloatRegister src, FloatRegister dest) { as_muls(dest, dest, src); } void MacroAssembler::mulDouble(FloatRegister src, FloatRegister dest) { as_muld(dest, dest, src); } void MacroAssembler::mulDoublePtr(ImmPtr imm, Register temp, FloatRegister dest) { movePtr(imm, ScratchRegister); loadDouble(Address(ScratchRegister, 0), ScratchDoubleReg); mulDouble(ScratchDoubleReg, dest); } void MacroAssembler::quotient32(Register rhs, Register srcDest, bool isUnsigned) { if (isUnsigned) as_divu(srcDest, rhs); else as_div(srcDest, rhs); as_mflo(srcDest); } void MacroAssembler::remainder32(Register rhs, Register srcDest, bool isUnsigned) { if (isUnsigned) as_divu(srcDest, rhs); else as_div(srcDest, rhs); as_mfhi(srcDest); } void MacroAssembler::divFloat32(FloatRegister src, FloatRegister dest) { as_divs(dest, dest, src); } void MacroAssembler::divDouble(FloatRegister src, FloatRegister dest) { as_divd(dest, dest, src); } void MacroAssembler::neg32(Register reg) { ma_negu(reg, reg); } void MacroAssembler::negateDouble(FloatRegister reg) { as_negd(reg, reg); } void MacroAssembler::negateFloat(FloatRegister reg) { as_negs(reg, reg); } void MacroAssembler::absFloat32(FloatRegister src, FloatRegister dest) { as_abss(dest, src); } void MacroAssembler::absDouble(FloatRegister src, FloatRegister dest) { as_absd(dest, src); } void MacroAssembler::sqrtFloat32(FloatRegister src, FloatRegister dest) { as_sqrts(dest, src); } void MacroAssembler::sqrtDouble(FloatRegister src, FloatRegister dest) { as_sqrtd(dest, src); } void MacroAssembler::minFloat32(FloatRegister other, FloatRegister srcDest, bool handleNaN) { minMaxFloat32(srcDest, other, handleNaN, false); } void MacroAssembler::minDouble(FloatRegister other, FloatRegister srcDest, bool handleNaN) { minMaxDouble(srcDest, other, handleNaN, false); } void MacroAssembler::maxFloat32(FloatRegister other, FloatRegister srcDest, bool handleNaN) { minMaxFloat32(srcDest, other, handleNaN, true); } void MacroAssembler::maxDouble(FloatRegister other, FloatRegister srcDest, bool handleNaN) { minMaxDouble(srcDest, other, handleNaN, true); } // =============================================================== // Shift functions void MacroAssembler::lshift32(Register src, Register dest) { ma_sll(dest, dest, src); } void MacroAssembler::lshift32(Imm32 imm, Register dest) { ma_sll(dest, dest, imm); } void MacroAssembler::rshift32(Register src, Register dest) { ma_srl(dest, dest, src); } void MacroAssembler::rshift32(Imm32 imm, Register dest) { ma_srl(dest, dest, imm); } void MacroAssembler::rshift32Arithmetic(Register src, Register dest) { ma_sra(dest, dest, src); } void MacroAssembler::rshift32Arithmetic(Imm32 imm, Register dest) { ma_sra(dest, dest, imm); } // =============================================================== // Rotation functions void MacroAssembler::rotateLeft(Imm32 count, Register input, Register dest) { if (count.value) ma_rol(dest, input, count); else ma_move(dest, input); } void MacroAssembler::rotateLeft(Register count, Register input, Register dest) { ma_rol(dest, input, count); } void MacroAssembler::rotateRight(Imm32 count, Register input, Register dest) { if (count.value) ma_ror(dest, input, count); else ma_move(dest, input); } void MacroAssembler::rotateRight(Register count, Register input, Register dest) { ma_ror(dest, input, count); } // =============================================================== // Bit counting functions void MacroAssembler::clz32(Register src, Register dest, bool knownNotZero) { as_clz(dest, src); } void MacroAssembler::ctz32(Register src, Register dest, bool knownNotZero) { ma_ctz(dest, src); } void MacroAssembler::popcnt32(Register input, Register output, Register tmp) { // Equivalent to GCC output of mozilla::CountPopulation32() ma_move(output, input); ma_sra(tmp, input, Imm32(1)); ma_and(tmp, Imm32(0x55555555)); ma_subu(output, tmp); ma_sra(tmp, output, Imm32(2)); ma_and(output, Imm32(0x33333333)); ma_and(tmp, Imm32(0x33333333)); ma_addu(output, tmp); ma_srl(tmp, output, Imm32(4)); ma_addu(output, tmp); ma_and(output, Imm32(0xF0F0F0F)); ma_sll(tmp, output, Imm32(8)); ma_addu(output, tmp); ma_sll(tmp, output, Imm32(16)); ma_addu(output, tmp); ma_sra(output, output, Imm32(24)); } // =============================================================== // Branch functions template void MacroAssembler::branch32(Condition cond, Register lhs, Register rhs, L label) { ma_b(lhs, rhs, label, cond); } template void MacroAssembler::branch32(Condition cond, Register lhs, Imm32 imm, L label) { ma_b(lhs, imm, label, cond); } void MacroAssembler::branch32(Condition cond, const Address& lhs, Register rhs, Label* label) { load32(lhs, SecondScratchReg); ma_b(SecondScratchReg, rhs, label, cond); } void MacroAssembler::branch32(Condition cond, const Address& lhs, Imm32 rhs, Label* label) { load32(lhs, SecondScratchReg); ma_b(SecondScratchReg, rhs, label, cond); } void MacroAssembler::branch32(Condition cond, const AbsoluteAddress& lhs, Register rhs, Label* label) { load32(lhs, SecondScratchReg); ma_b(SecondScratchReg, rhs, label, cond); } void MacroAssembler::branch32(Condition cond, const AbsoluteAddress& lhs, Imm32 rhs, Label* label) { load32(lhs, SecondScratchReg); ma_b(SecondScratchReg, rhs, label, cond); } void MacroAssembler::branch32(Condition cond, const BaseIndex& lhs, Imm32 rhs, Label* label) { load32(lhs, SecondScratchReg); ma_b(SecondScratchReg, rhs, label, cond); } void MacroAssembler::branch32(Condition cond, wasm::SymbolicAddress addr, Imm32 imm, Label* label) { load32(addr, SecondScratchReg); ma_b(SecondScratchReg, imm, label, cond); } template void MacroAssembler::branchPtr(Condition cond, Register lhs, Register rhs, L label) { ma_b(lhs, rhs, label, cond); } void MacroAssembler::branchPtr(Condition cond, Register lhs, Imm32 rhs, Label* label) { ma_b(lhs, rhs, label, cond); } void MacroAssembler::branchPtr(Condition cond, Register lhs, ImmPtr rhs, Label* label) { ma_b(lhs, rhs, label, cond); } void MacroAssembler::branchPtr(Condition cond, Register lhs, ImmGCPtr rhs, Label* label) { ma_b(lhs, rhs, label, cond); } void MacroAssembler::branchPtr(Condition cond, Register lhs, ImmWord rhs, Label* label) { ma_b(lhs, rhs, label, cond); } template void MacroAssembler::branchPtr(Condition cond, const Address& lhs, Register rhs, L label) { loadPtr(lhs, SecondScratchReg); branchPtr(cond, SecondScratchReg, rhs, label); } void MacroAssembler::branchPtr(Condition cond, const Address& lhs, ImmPtr rhs, Label* label) { loadPtr(lhs, SecondScratchReg); branchPtr(cond, SecondScratchReg, rhs, label); } void MacroAssembler::branchPtr(Condition cond, const Address& lhs, ImmGCPtr rhs, Label* label) { loadPtr(lhs, SecondScratchReg); branchPtr(cond, SecondScratchReg, rhs, label); } void MacroAssembler::branchPtr(Condition cond, const Address& lhs, ImmWord rhs, Label* label) { loadPtr(lhs, SecondScratchReg); branchPtr(cond, SecondScratchReg, rhs, label); } void MacroAssembler::branchPtr(Condition cond, const AbsoluteAddress& lhs, Register rhs, Label* label) { loadPtr(lhs, SecondScratchReg); branchPtr(cond, SecondScratchReg, rhs, label); } void MacroAssembler::branchPtr(Condition cond, const AbsoluteAddress& lhs, ImmWord rhs, Label* label) { loadPtr(lhs, SecondScratchReg); branchPtr(cond, SecondScratchReg, rhs, label); } void MacroAssembler::branchPtr(Condition cond, wasm::SymbolicAddress lhs, Register rhs, Label* label) { loadPtr(lhs, SecondScratchReg); branchPtr(cond, SecondScratchReg, rhs, label); } template CodeOffsetJump MacroAssembler::branchPtrWithPatch(Condition cond, Register lhs, T rhs, RepatchLabel* label) { movePtr(rhs, ScratchRegister); Label skipJump; ma_b(lhs, ScratchRegister, &skipJump, InvertCondition(cond), ShortJump); CodeOffsetJump off = jumpWithPatch(label); bind(&skipJump); return off; } template CodeOffsetJump MacroAssembler::branchPtrWithPatch(Condition cond, Address lhs, T rhs, RepatchLabel* label) { loadPtr(lhs, SecondScratchReg); movePtr(rhs, ScratchRegister); Label skipJump; ma_b(SecondScratchReg, ScratchRegister, &skipJump, InvertCondition(cond), ShortJump); CodeOffsetJump off = jumpWithPatch(label); bind(&skipJump); return off; } void MacroAssembler::branchFloat(DoubleCondition cond, FloatRegister lhs, FloatRegister rhs, Label* label) { ma_bc1s(lhs, rhs, label, cond); } void MacroAssembler::branchTruncateFloat32MaybeModUint32(FloatRegister src, Register dest, Label* fail) { Label test, success; as_truncws(ScratchFloat32Reg, src); as_mfc1(dest, ScratchFloat32Reg); ma_b(dest, Imm32(INT32_MAX), fail, Assembler::Equal); } void MacroAssembler::branchTruncateFloat32ToInt32(FloatRegister src, Register dest, Label* fail) { convertFloat32ToInt32(src, dest, fail); } void MacroAssembler::branchDouble(DoubleCondition cond, FloatRegister lhs, FloatRegister rhs, Label* label) { ma_bc1d(lhs, rhs, label, cond); } // Convert the floating point value to an integer, if it did not fit, then it // was clamped to INT32_MIN/INT32_MAX, and we can test it. // NOTE: if the value really was supposed to be INT32_MAX / INT32_MIN then it // will be wrong. void MacroAssembler::branchTruncateDoubleMaybeModUint32(FloatRegister src, Register dest, Label* fail) { Label test, success; as_truncwd(ScratchDoubleReg, src); as_mfc1(dest, ScratchDoubleReg); ma_b(dest, Imm32(INT32_MAX), fail, Assembler::Equal); ma_b(dest, Imm32(INT32_MIN), fail, Assembler::Equal); } void MacroAssembler::branchTruncateDoubleToInt32(FloatRegister src, Register dest, Label* fail) { convertDoubleToInt32(src, dest, fail); } template void MacroAssembler::branchAdd32(Condition cond, T src, Register dest, L overflow) { switch (cond) { case Overflow: ma_addTestOverflow(dest, dest, src, overflow); break; case CarrySet: ma_addTestCarry(dest, dest, src, overflow); break; default: MOZ_CRASH("NYI"); } } template void MacroAssembler::branchSub32(Condition cond, T src, Register dest, Label* overflow) { switch (cond) { case Overflow: ma_subTestOverflow(dest, dest, src, overflow); break; case NonZero: case Zero: ma_subu(dest, src); ma_b(dest, dest, overflow, cond); break; default: MOZ_CRASH("NYI"); } } void MacroAssembler::decBranchPtr(Condition cond, Register lhs, Imm32 rhs, Label* label) { subPtr(rhs, lhs); branchPtr(cond, lhs, Imm32(0), label); } template void MacroAssembler::branchTest32(Condition cond, Register lhs, Register rhs, L label) { MOZ_ASSERT(cond == Zero || cond == NonZero || cond == Signed || cond == NotSigned); if (lhs == rhs) { ma_b(lhs, rhs, label, cond); } else { as_and(ScratchRegister, lhs, rhs); ma_b(ScratchRegister, ScratchRegister, label, cond); } } template void MacroAssembler::branchTest32(Condition cond, Register lhs, Imm32 rhs, L label) { MOZ_ASSERT(cond == Zero || cond == NonZero || cond == Signed || cond == NotSigned); ma_and(ScratchRegister, lhs, rhs); ma_b(ScratchRegister, ScratchRegister, label, cond); } void MacroAssembler::branchTest32(Condition cond, const Address& lhs, Imm32 rhs, Label* label) { load32(lhs, SecondScratchReg); branchTest32(cond, SecondScratchReg, rhs, label); } void MacroAssembler::branchTest32(Condition cond, const AbsoluteAddress& lhs, Imm32 rhs, Label* label) { load32(lhs, SecondScratchReg); branchTest32(cond, SecondScratchReg, rhs, label); } template void MacroAssembler::branchTestPtr(Condition cond, Register lhs, Register rhs, L label) { MOZ_ASSERT(cond == Zero || cond == NonZero || cond == Signed || cond == NotSigned); if (lhs == rhs) { ma_b(lhs, rhs, label, cond); } else { as_and(ScratchRegister, lhs, rhs); ma_b(ScratchRegister, ScratchRegister, label, cond); } } void MacroAssembler::branchTestPtr(Condition cond, Register lhs, Imm32 rhs, Label* label) { MOZ_ASSERT(cond == Zero || cond == NonZero || cond == Signed || cond == NotSigned); ma_and(ScratchRegister, lhs, rhs); ma_b(ScratchRegister, ScratchRegister, label, cond); } void MacroAssembler::branchTestPtr(Condition cond, const Address& lhs, Imm32 rhs, Label* label) { loadPtr(lhs, SecondScratchReg); branchTestPtr(cond, SecondScratchReg, rhs, label); } void MacroAssembler::branchTestUndefined(Condition cond, Register tag, Label* label) { MOZ_ASSERT(cond == Equal || cond == NotEqual); ma_b(tag, ImmTag(JSVAL_TAG_UNDEFINED), label, cond); } void MacroAssembler::branchTestUndefined(Condition cond, const Address& address, Label* label) { SecondScratchRegisterScope scratch2(*this); extractTag(address, scratch2); branchTestUndefined(cond, scratch2, label); } void MacroAssembler::branchTestUndefined(Condition cond, const BaseIndex& address, Label* label) { SecondScratchRegisterScope scratch2(*this); extractTag(address, scratch2); branchTestUndefined(cond, scratch2, label); } void MacroAssembler::branchTestInt32(Condition cond, Register tag, Label* label) { MOZ_ASSERT(cond == Equal || cond == NotEqual); ma_b(tag, ImmTag(JSVAL_TAG_INT32), label, cond); } void MacroAssembler::branchTestInt32(Condition cond, const Address& address, Label* label) { SecondScratchRegisterScope scratch2(*this); extractTag(address, scratch2); branchTestInt32(cond, scratch2, label); } void MacroAssembler::branchTestInt32(Condition cond, const BaseIndex& address, Label* label) { SecondScratchRegisterScope scratch2(*this); extractTag(address, scratch2); branchTestInt32(cond, scratch2, label); } void MacroAssembler::branchTestDouble(Condition cond, const Address& address, Label* label) { SecondScratchRegisterScope scratch2(*this); extractTag(address, scratch2); branchTestDouble(cond, scratch2, label); } void MacroAssembler::branchTestDouble(Condition cond, const BaseIndex& address, Label* label) { SecondScratchRegisterScope scratch2(*this); extractTag(address, scratch2); branchTestDouble(cond, scratch2, label); } void MacroAssembler::branchTestDoubleTruthy(bool b, FloatRegister value, Label* label) { ma_lid(ScratchDoubleReg, 0.0); DoubleCondition cond = b ? DoubleNotEqual : DoubleEqualOrUnordered; ma_bc1d(value, ScratchDoubleReg, label, cond); } void MacroAssembler::branchTestNumber(Condition cond, Register tag, Label* label) { MOZ_ASSERT(cond == Equal || cond == NotEqual); Condition actual = cond == Equal ? BelowOrEqual : Above; ma_b(tag, ImmTag(JSVAL_UPPER_INCL_TAG_OF_NUMBER_SET), label, actual); } void MacroAssembler::branchTestBoolean(Condition cond, Register tag, Label* label) { MOZ_ASSERT(cond == Equal || cond == NotEqual); ma_b(tag, ImmTag(JSVAL_TAG_BOOLEAN), label, cond); } void MacroAssembler::branchTestBoolean(Condition cond, const Address& address, Label* label) { SecondScratchRegisterScope scratch2(*this); extractTag(address, scratch2); branchTestBoolean(cond, scratch2, label); } void MacroAssembler::branchTestBoolean(Condition cond, const BaseIndex& address, Label* label) { SecondScratchRegisterScope scratch2(*this); extractTag(address, scratch2); branchTestBoolean(cond, scratch2, label); } void MacroAssembler::branchTestString(Condition cond, Register tag, Label* label) { MOZ_ASSERT(cond == Equal || cond == NotEqual); ma_b(tag, ImmTag(JSVAL_TAG_STRING), label, cond); } void MacroAssembler::branchTestString(Condition cond, const BaseIndex& address, Label* label) { SecondScratchRegisterScope scratch2(*this); extractTag(address, scratch2); branchTestString(cond, scratch2, label); } void MacroAssembler::branchTestSymbol(Condition cond, Register tag, Label* label) { MOZ_ASSERT(cond == Equal || cond == NotEqual); ma_b(tag, ImmTag(JSVAL_TAG_SYMBOL), label, cond); } void MacroAssembler::branchTestSymbol(Condition cond, const BaseIndex& address, Label* label) { SecondScratchRegisterScope scratch2(*this); extractTag(address, scratch2); branchTestSymbol(cond, scratch2, label); } void MacroAssembler::branchTestNull(Condition cond, Register tag, Label* label) { MOZ_ASSERT(cond == Equal || cond == NotEqual); ma_b(tag, ImmTag(JSVAL_TAG_NULL), label, cond); } void MacroAssembler::branchTestNull(Condition cond, const Address& address, Label* label) { SecondScratchRegisterScope scratch2(*this); extractTag(address, scratch2); branchTestNull(cond, scratch2, label); } void MacroAssembler::branchTestNull(Condition cond, const BaseIndex& address, Label* label) { SecondScratchRegisterScope scratch2(*this); extractTag(address, scratch2); branchTestNull(cond, scratch2, label); } void MacroAssembler::branchTestObject(Condition cond, Register tag, Label* label) { MOZ_ASSERT(cond == Equal || cond == NotEqual); ma_b(tag, ImmTag(JSVAL_TAG_OBJECT), label, cond); } void MacroAssembler::branchTestObject(Condition cond, const Address& address, Label* label) { SecondScratchRegisterScope scratch2(*this); extractTag(address, scratch2); branchTestObject(cond, scratch2, label); } void MacroAssembler::branchTestObject(Condition cond, const BaseIndex& address, Label* label) { SecondScratchRegisterScope scratch2(*this); extractTag(address, scratch2); branchTestObject(cond, scratch2, label); } void MacroAssembler::branchTestGCThing(Condition cond, const Address& address, Label* label) { MOZ_ASSERT(cond == Equal || cond == NotEqual); SecondScratchRegisterScope scratch2(*this); extractTag(address, scratch2); ma_b(scratch2, ImmTag(JSVAL_LOWER_INCL_TAG_OF_GCTHING_SET), label, (cond == Equal) ? AboveOrEqual : Below); } void MacroAssembler::branchTestGCThing(Condition cond, const BaseIndex& address, Label* label) { MOZ_ASSERT(cond == Equal || cond == NotEqual); SecondScratchRegisterScope scratch2(*this); extractTag(address, scratch2); ma_b(scratch2, ImmTag(JSVAL_LOWER_INCL_TAG_OF_GCTHING_SET), label, (cond == Equal) ? AboveOrEqual : Below); } void MacroAssembler::branchTestPrimitive(Condition cond, Register tag, Label* label) { MOZ_ASSERT(cond == Equal || cond == NotEqual); ma_b(tag, ImmTag(JSVAL_UPPER_EXCL_TAG_OF_PRIMITIVE_SET), label, (cond == Equal) ? Below : AboveOrEqual); } void MacroAssembler::branchTestMagic(Condition cond, Register tag, Label* label) { MOZ_ASSERT(cond == Equal || cond == NotEqual); ma_b(tag, ImmTag(JSVAL_TAG_MAGIC), label, cond); } void MacroAssembler::branchTestMagic(Condition cond, const Address& address, Label* label) { SecondScratchRegisterScope scratch2(*this); extractTag(address, scratch2); branchTestMagic(cond, scratch2, label); } void MacroAssembler::branchTestMagic(Condition cond, const BaseIndex& address, Label* label) { SecondScratchRegisterScope scratch2(*this); extractTag(address, scratch2); branchTestMagic(cond, scratch2, label); } // ======================================================================== // Memory access primitives. void MacroAssembler::storeFloat32x3(FloatRegister src, const Address& dest) { MOZ_CRASH("NYI"); } void MacroAssembler::storeFloat32x3(FloatRegister src, const BaseIndex& dest) { MOZ_CRASH("NYI"); } void MacroAssembler::memoryBarrier(MemoryBarrierBits barrier) { if (barrier == MembarLoadLoad) as_sync(19); else if (barrier == MembarStoreStore) as_sync(4); else if (barrier & MembarSynchronizing) as_sync(); else if (barrier) as_sync(16); } // =============================================================== // Clamping functions. void MacroAssembler::clampIntToUint8(Register reg) { // If reg is < 0, then we want to clamp to 0. as_slti(ScratchRegister, reg, 0); as_movn(reg, zero, ScratchRegister); // If reg is >= 255, then we want to clamp to 255. ma_li(SecondScratchReg, Imm32(255)); as_slti(ScratchRegister, reg, 255); as_movz(reg, SecondScratchReg, ScratchRegister); } //}}} check_macroassembler_style // =============================================================== } // namespace jit } // namespace js #endif /* jit_mips_shared_MacroAssembler_mips_shared_inl_h */