/* -*- 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_arm_MacroAssembler_arm_inl_h
#define jit_arm_MacroAssembler_arm_inl_h
#include "jit/arm/MacroAssembler-arm.h"
namespace js {
namespace jit {
//{{{ check_macroassembler_style
void
MacroAssembler::move64(Register64 src, Register64 dest)
{
move32(src.low, dest.low);
move32(src.high, dest.high);
}
void
MacroAssembler::move64(Imm64 imm, Register64 dest)
{
move32(Imm32(imm.value & 0xFFFFFFFFL), dest.low);
move32(Imm32((imm.value >> 32) & 0xFFFFFFFFL), dest.high);
}
void
MacroAssembler::moveFloat32ToGPR(FloatRegister src, Register dest)
{
ma_vxfer(src, dest);
}
void
MacroAssembler::moveGPRToFloat32(Register src, FloatRegister dest)
{
ma_vxfer(src, dest);
}
void
MacroAssembler::move8SignExtend(Register src, Register dest)
{
as_sxtb(dest, src, 0);
}
void
MacroAssembler::move16SignExtend(Register src, Register dest)
{
as_sxth(dest, src, 0);
}
// ===============================================================
// Logical instructions
void
MacroAssembler::not32(Register reg)
{
ma_mvn(reg, reg);
}
void
MacroAssembler::and32(Register src, Register dest)
{
ma_and(src, dest, SetCC);
}
void
MacroAssembler::and32(Imm32 imm, Register dest)
{
ScratchRegisterScope scratch(*this);
ma_and(imm, dest, scratch, SetCC);
}
void
MacroAssembler::and32(Imm32 imm, const Address& dest)
{
ScratchRegisterScope scratch(*this);
SecondScratchRegisterScope scratch2(*this);
ma_ldr(dest, scratch, scratch2);
ma_and(imm, scratch, scratch2);
ma_str(scratch, dest, scratch2);
}
void
MacroAssembler::and32(const Address& src, Register dest)
{
ScratchRegisterScope scratch(*this);
SecondScratchRegisterScope scratch2(*this);
ma_ldr(src, scratch, scratch2);
ma_and(scratch, dest, SetCC);
}
void
MacroAssembler::andPtr(Register src, Register dest)
{
ma_and(src, dest);
}
void
MacroAssembler::andPtr(Imm32 imm, Register dest)
{
ScratchRegisterScope scratch(*this);
ma_and(imm, dest, scratch);
}
void
MacroAssembler::and64(Imm64 imm, Register64 dest)
{
if (imm.low().value != int32_t(0xFFFFFFFF))
and32(imm.low(), dest.low);
if (imm.hi().value != int32_t(0xFFFFFFFF))
and32(imm.hi(), dest.high);
}
void
MacroAssembler::or64(Imm64 imm, Register64 dest)
{
if (imm.low().value)
or32(imm.low(), dest.low);
if (imm.hi().value)
or32(imm.hi(), dest.high);
}
void
MacroAssembler::xor64(Imm64 imm, Register64 dest)
{
if (imm.low().value)
xor32(imm.low(), dest.low);
if (imm.hi().value)
xor32(imm.hi(), dest.high);
}
void
MacroAssembler::or32(Register src, Register dest)
{
ma_orr(src, dest);
}
void
MacroAssembler::or32(Imm32 imm, Register dest)
{
ScratchRegisterScope scratch(*this);
ma_orr(imm, dest, scratch);
}
void
MacroAssembler::or32(Imm32 imm, const Address& dest)
{
ScratchRegisterScope scratch(*this);
SecondScratchRegisterScope scratch2(*this);
ma_ldr(dest, scratch, scratch2);
ma_orr(imm, scratch, scratch2);
ma_str(scratch, dest, scratch2);
}
void
MacroAssembler::orPtr(Register src, Register dest)
{
ma_orr(src, dest);
}
void
MacroAssembler::orPtr(Imm32 imm, Register dest)
{
ScratchRegisterScope scratch(*this);
ma_orr(imm, dest, scratch);
}
void
MacroAssembler::and64(Register64 src, Register64 dest)
{
and32(src.low, dest.low);
and32(src.high, dest.high);
}
void
MacroAssembler::or64(Register64 src, Register64 dest)
{
or32(src.low, dest.low);
or32(src.high, dest.high);
}
void
MacroAssembler::xor64(Register64 src, Register64 dest)
{
ma_eor(src.low, dest.low);
ma_eor(src.high, dest.high);
}
void
MacroAssembler::xor32(Register src, Register dest)
{
ma_eor(src, dest, SetCC);
}
void
MacroAssembler::xor32(Imm32 imm, Register dest)
{
ScratchRegisterScope scratch(*this);
ma_eor(imm, dest, scratch, SetCC);
}
void
MacroAssembler::xorPtr(Register src, Register dest)
{
ma_eor(src, dest);
}
void
MacroAssembler::xorPtr(Imm32 imm, Register dest)
{
ScratchRegisterScope scratch(*this);
ma_eor(imm, dest, scratch);
}
// ===============================================================
// Arithmetic functions
void
MacroAssembler::add32(Register src, Register dest)
{
ma_add(src, dest, SetCC);
}
void
MacroAssembler::add32(Imm32 imm, Register dest)
{
ScratchRegisterScope scratch(*this);
ma_add(imm, dest, scratch, SetCC);
}
void
MacroAssembler::add32(Imm32 imm, const Address& dest)
{
ScratchRegisterScope scratch(*this);
SecondScratchRegisterScope scratch2(*this);
ma_ldr(dest, scratch, scratch2);
ma_add(imm, scratch, scratch2, SetCC);
ma_str(scratch, dest, scratch2);
}
void
MacroAssembler::addPtr(Register src, Register dest)
{
ma_add(src, dest);
}
void
MacroAssembler::addPtr(Imm32 imm, Register dest)
{
ScratchRegisterScope scratch(*this);
ma_add(imm, dest, scratch);
}
void
MacroAssembler::addPtr(ImmWord imm, Register dest)
{
addPtr(Imm32(imm.value), dest);
}
void
MacroAssembler::addPtr(Imm32 imm, const Address& dest)
{
ScratchRegisterScope scratch(*this);
SecondScratchRegisterScope scratch2(*this);
ma_ldr(dest, scratch, scratch2);
ma_add(imm, scratch, scratch2);
ma_str(scratch, dest, scratch2);
}
void
MacroAssembler::addPtr(const Address& src, Register dest)
{
ScratchRegisterScope scratch(*this);
SecondScratchRegisterScope scratch2(*this);
ma_ldr(src, scratch, scratch2);
ma_add(scratch, dest, SetCC);
}
void
MacroAssembler::add64(Register64 src, Register64 dest)
{
ma_add(src.low, dest.low, SetCC);
ma_adc(src.high, dest.high);
}
void
MacroAssembler::add64(Imm32 imm, Register64 dest)
{
ScratchRegisterScope scratch(*this);
ma_add(imm, dest.low, scratch, SetCC);
as_adc(dest.high, dest.high, Imm8(0), LeaveCC);
}
void
MacroAssembler::add64(Imm64 imm, Register64 dest)
{
ScratchRegisterScope scratch(*this);
ma_add(imm.low(), dest.low, scratch, SetCC);
ma_adc(imm.hi(), dest.high, scratch, LeaveCC);
}
void
MacroAssembler::addDouble(FloatRegister src, FloatRegister dest)
{
ma_vadd(dest, src, dest);
}
void
MacroAssembler::addFloat32(FloatRegister src, FloatRegister dest)
{
ma_vadd_f32(dest, src, dest);
}
void
MacroAssembler::sub32(Register src, Register dest)
{
ma_sub(src, dest, SetCC);
}
void
MacroAssembler::sub32(Imm32 imm, Register dest)
{
ScratchRegisterScope scratch(*this);
ma_sub(imm, dest, scratch, SetCC);
}
void
MacroAssembler::sub32(const Address& src, Register dest)
{
ScratchRegisterScope scratch(*this);
SecondScratchRegisterScope scratch2(*this);
ma_ldr(src, scratch, scratch2);
ma_sub(scratch, dest, SetCC);
}
void
MacroAssembler::subPtr(Register src, Register dest)
{
ma_sub(src, dest);
}
void
MacroAssembler::subPtr(Register src, const Address& dest)
{
ScratchRegisterScope scratch(*this);
SecondScratchRegisterScope scratch2(*this);
ma_ldr(dest, scratch, scratch2);
ma_sub(src, scratch);
ma_str(scratch, dest, scratch2);
}
void
MacroAssembler::subPtr(Imm32 imm, Register dest)
{
ScratchRegisterScope scratch(*this);
ma_sub(imm, dest, scratch);
}
void
MacroAssembler::subPtr(const Address& addr, Register dest)
{
ScratchRegisterScope scratch(*this);
SecondScratchRegisterScope scratch2(*this);
ma_ldr(addr, scratch, scratch2);
ma_sub(scratch, dest);
}
void
MacroAssembler::sub64(Register64 src, Register64 dest)
{
ma_sub(src.low, dest.low, SetCC);
ma_sbc(src.high, dest.high, LeaveCC);
}
void
MacroAssembler::sub64(Imm64 imm, Register64 dest)
{
ScratchRegisterScope scratch(*this);
ma_sub(imm.low(), dest.low, scratch, SetCC);
ma_sbc(imm.hi(), dest.high, scratch, LeaveCC);
}
void
MacroAssembler::subDouble(FloatRegister src, FloatRegister dest)
{
ma_vsub(dest, src, dest);
}
void
MacroAssembler::subFloat32(FloatRegister src, FloatRegister dest)
{
ma_vsub_f32(dest, src, dest);
}
void
MacroAssembler::mul32(Register rhs, Register srcDest)
{
as_mul(srcDest, srcDest, rhs);
}
void
MacroAssembler::mul64(Imm64 imm, const Register64& dest)
{
// LOW32 = LOW(LOW(dest) * LOW(imm));
// HIGH32 = LOW(HIGH(dest) * LOW(imm)) [multiply imm into upper bits]
// + LOW(LOW(dest) * HIGH(imm)) [multiply dest into upper bits]
// + HIGH(LOW(dest) * LOW(imm)) [carry]
ScratchRegisterScope scratch(*this);
SecondScratchRegisterScope scratch2(*this);
// HIGH(dest) = LOW(HIGH(dest) * LOW(imm));
ma_mov(Imm32(imm.value & 0xFFFFFFFFL), scratch);
as_mul(dest.high, dest.high, scratch);
// high:low = LOW(dest) * LOW(imm);
as_umull(scratch2, scratch, dest.low, scratch);
// HIGH(dest) += high;
as_add(dest.high, dest.high, O2Reg(scratch2));
// HIGH(dest) += LOW(LOW(dest) * HIGH(imm));
if (((imm.value >> 32) & 0xFFFFFFFFL) == 5)
as_add(scratch2, dest.low, lsl(dest.low, 2));
else
MOZ_CRASH("Not supported imm");
as_add(dest.high, dest.high, O2Reg(scratch2));
// LOW(dest) = low;
ma_mov(scratch, dest.low);
}
void
MacroAssembler::mul64(Imm64 imm, const Register64& dest, const Register temp)
{
// LOW32 = LOW(LOW(dest) * LOW(src)); (1)
// HIGH32 = LOW(HIGH(dest) * LOW(src)) [multiply src into upper bits] (2)
// + LOW(LOW(dest) * HIGH(src)) [multiply dest into upper bits] (3)
// + HIGH(LOW(dest) * LOW(src)) [carry] (4)
MOZ_ASSERT(temp != dest.high && temp != dest.low);
// Compute mul64
ScratchRegisterScope scratch(*this);
ma_mul(dest.high, imm.low(), dest.high, scratch); // (2)
ma_mul(dest.low, imm.hi(), temp, scratch); // (3)
ma_add(dest.high, temp, temp);
ma_umull(dest.low, imm.low(), dest.high, dest.low, scratch); // (4) + (1)
ma_add(temp, dest.high, dest.high);
}
void
MacroAssembler::mul64(const Register64& src, const Register64& dest, const Register temp)
{
// LOW32 = LOW(LOW(dest) * LOW(src)); (1)
// HIGH32 = LOW(HIGH(dest) * LOW(src)) [multiply src into upper bits] (2)
// + LOW(LOW(dest) * HIGH(src)) [multiply dest into upper bits] (3)
// + HIGH(LOW(dest) * LOW(src)) [carry] (4)
MOZ_ASSERT(dest != src);
MOZ_ASSERT(dest.low != src.high && dest.high != src.low);
// Compute mul64
ma_mul(dest.high, src.low, dest.high); // (2)
ma_mul(src.high, dest.low, temp); // (3)
ma_add(dest.high, temp, temp);
ma_umull(dest.low, src.low, dest.high, dest.low); // (4) + (1)
ma_add(temp, dest.high, dest.high);
}
void
MacroAssembler::mulBy3(Register src, Register dest)
{
as_add(dest, src, lsl(src, 1));
}
void
MacroAssembler::mulFloat32(FloatRegister src, FloatRegister dest)
{
ma_vmul_f32(dest, src, dest);
}
void
MacroAssembler::mulDouble(FloatRegister src, FloatRegister dest)
{
ma_vmul(dest, src, dest);
}
void
MacroAssembler::mulDoublePtr(ImmPtr imm, Register temp, FloatRegister dest)
{
ScratchRegisterScope scratch(*this);
ScratchDoubleScope scratchDouble(*this);
movePtr(imm, scratch);
ma_vldr(Operand(Address(scratch, 0)).toVFPAddr(), scratchDouble);
mulDouble(scratchDouble, dest);
}
void
MacroAssembler::quotient32(Register rhs, Register srcDest, bool isUnsigned)
{
MOZ_ASSERT(HasIDIV());
if (isUnsigned)
ma_udiv(srcDest, rhs, srcDest);
else
ma_sdiv(srcDest, rhs, srcDest);
}
void
MacroAssembler::remainder32(Register rhs, Register srcDest, bool isUnsigned)
{
MOZ_ASSERT(HasIDIV());
ScratchRegisterScope scratch(*this);
if (isUnsigned)
ma_umod(srcDest, rhs, srcDest, scratch);
else
ma_smod(srcDest, rhs, srcDest, scratch);
}
void
MacroAssembler::divFloat32(FloatRegister src, FloatRegister dest)
{
ma_vdiv_f32(dest, src, dest);
}
void
MacroAssembler::divDouble(FloatRegister src, FloatRegister dest)
{
ma_vdiv(dest, src, dest);
}
void
MacroAssembler::inc64(AbsoluteAddress dest)
{
ScratchRegisterScope scratch(*this);
ma_strd(r0, r1, EDtrAddr(sp, EDtrOffImm(-8)), PreIndex);
ma_mov(Imm32((int32_t)dest.addr), scratch);
ma_ldrd(EDtrAddr(scratch, EDtrOffImm(0)), r0, r1);
as_add(r0, r0, Imm8(1), SetCC);
as_adc(r1, r1, Imm8(0), LeaveCC);
ma_strd(r0, r1, EDtrAddr(scratch, EDtrOffImm(0)));
ma_ldrd(EDtrAddr(sp, EDtrOffImm(8)), r0, r1, PostIndex);
}
void
MacroAssembler::neg32(Register reg)
{
ma_neg(reg, reg, SetCC);
}
void
MacroAssembler::neg64(Register64 reg)
{
as_rsb(reg.low, reg.low, Imm8(0), SetCC);
as_rsc(reg.high, reg.high, Imm8(0));
}
void
MacroAssembler::negateDouble(FloatRegister reg)
{
ma_vneg(reg, reg);
}
void
MacroAssembler::negateFloat(FloatRegister reg)
{
ma_vneg_f32(reg, reg);
}
void
MacroAssembler::absFloat32(FloatRegister src, FloatRegister dest)
{
if (src != dest)
ma_vmov_f32(src, dest);
ma_vabs_f32(dest, dest);
}
void
MacroAssembler::absDouble(FloatRegister src, FloatRegister dest)
{
if (src != dest)
ma_vmov(src, dest);
ma_vabs(dest, dest);
}
void
MacroAssembler::sqrtFloat32(FloatRegister src, FloatRegister dest)
{
ma_vsqrt_f32(src, dest);
}
void
MacroAssembler::sqrtDouble(FloatRegister src, FloatRegister dest)
{
ma_vsqrt(src, dest);
}
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::lshiftPtr(Imm32 imm, Register dest)
{
MOZ_ASSERT(0 <= imm.value && imm.value < 32);
ma_lsl(imm, dest, dest);
}
void
MacroAssembler::lshift64(Imm32 imm, Register64 dest)
{
MOZ_ASSERT(0 <= imm.value && imm.value < 64);
if (imm.value == 0) {
return;
} else if (imm.value < 32) {
as_mov(dest.high, lsl(dest.high, imm.value));
as_orr(dest.high, dest.high, lsr(dest.low, 32 - imm.value));
as_mov(dest.low, lsl(dest.low, imm.value));
} else {
as_mov(dest.high, lsl(dest.low, imm.value - 32));
ma_mov(Imm32(0), dest.low);
}
}
void
MacroAssembler::lshift64(Register unmaskedShift, Register64 dest)
{
// dest.high = dest.high << shift | dest.low << shift - 32 | dest.low >> 32 - shift
// Note: one of the two dest.low shift will always yield zero due to negative shift.
ScratchRegisterScope shift(*this);
as_and(shift, unmaskedShift, Imm8(0x3f));
as_mov(dest.high, lsl(dest.high, shift));
as_sub(shift, shift, Imm8(32));
as_orr(dest.high, dest.high, lsl(dest.low, shift));
ma_neg(shift, shift);
as_orr(dest.high, dest.high, lsr(dest.low, shift));
as_and(shift, unmaskedShift, Imm8(0x3f));
as_mov(dest.low, lsl(dest.low, shift));
}
void
MacroAssembler::lshift32(Register src, Register dest)
{
ma_lsl(src, dest, dest);
}
void
MacroAssembler::lshift32(Imm32 imm, Register dest)
{
MOZ_ASSERT(0 <= imm.value && imm.value < 32);
lshiftPtr(imm, dest);
}
void
MacroAssembler::rshiftPtr(Imm32 imm, Register dest)
{
MOZ_ASSERT(0 <= imm.value && imm.value < 32);
ma_lsr(imm, dest, dest);
}
void
MacroAssembler::rshift32(Register src, Register dest)
{
ma_lsr(src, dest, dest);
}
void
MacroAssembler::rshift32(Imm32 imm, Register dest)
{
MOZ_ASSERT(0 <= imm.value && imm.value < 32);
rshiftPtr(imm, dest);
}
void
MacroAssembler::rshiftPtrArithmetic(Imm32 imm, Register dest)
{
MOZ_ASSERT(0 <= imm.value && imm.value < 32);
ma_asr(imm, dest, dest);
}
void
MacroAssembler::rshift64Arithmetic(Imm32 imm, Register64 dest)
{
MOZ_ASSERT(0 <= imm.value && imm.value < 64);
if (imm.value < 32) {
as_mov(dest.low, lsr(dest.low, imm.value));
as_orr(dest.low, dest.low, lsl(dest.high, 32 - imm.value));
as_mov(dest.high, asr(dest.high, imm.value));
} else if (imm.value == 32) {
as_mov(dest.low, O2Reg(dest.high));
as_mov(dest.high, asr(dest.high, 31));
} else {
as_mov(dest.low, asr(dest.high, imm.value - 32));
as_mov(dest.high, asr(dest.high, 31));
}
}
void
MacroAssembler::rshift64Arithmetic(Register unmaskedShift, Register64 dest)
{
Label proceed;
// dest.low = dest.low >>> shift | dest.high <<< 32 - shift
// if (shift - 32 >= 0)
// dest.low |= dest.high >>> shift - 32
// Note: Negative shifts yield a zero as result, except for the signed
// right shift. Therefore we need to test for it and only do it if
// it isn't negative.
ScratchRegisterScope shift(*this);
as_and(shift, unmaskedShift, Imm8(0x3f));
as_mov(dest.low, lsr(dest.low, shift));
as_rsb(shift, shift, Imm8(32));
as_orr(dest.low, dest.low, lsl(dest.high, shift));
ma_neg(shift, shift, SetCC);
ma_b(&proceed, Signed);
as_orr(dest.low, dest.low, asr(dest.high, shift));
bind(&proceed);
as_and(shift, unmaskedShift, Imm8(0x3f));
as_mov(dest.high, asr(dest.high, shift));
}
void
MacroAssembler::rshift32Arithmetic(Register src, Register dest)
{
ma_asr(src, dest, dest);
}
void
MacroAssembler::rshift32Arithmetic(Imm32 imm, Register dest)
{
MOZ_ASSERT(0 <= imm.value && imm.value < 32);
rshiftPtrArithmetic(imm, dest);
}
void
MacroAssembler::rshift64(Imm32 imm, Register64 dest)
{
MOZ_ASSERT(0 <= imm.value && imm.value < 64);
MOZ_ASSERT(0 <= imm.value && imm.value < 64);
if (imm.value < 32) {
as_mov(dest.low, lsr(dest.low, imm.value));
as_orr(dest.low, dest.low, lsl(dest.high, 32 - imm.value));
as_mov(dest.high, lsr(dest.high, imm.value));
} else if (imm.value == 32) {
ma_mov(dest.high, dest.low);
ma_mov(Imm32(0), dest.high);
} else {
ma_lsr(Imm32(imm.value - 32), dest.high, dest.low);
ma_mov(Imm32(0), dest.high);
}
}
void
MacroAssembler::rshift64(Register unmaskedShift, Register64 dest)
{
// dest.low = dest.low >> shift | dest.high >> shift - 32 | dest.high << 32 - shift
// Note: one of the two dest.high shifts will always yield zero due to negative shift.
ScratchRegisterScope shift(*this);
as_and(shift, unmaskedShift, Imm8(0x3f));
as_mov(dest.low, lsr(dest.low, shift));
as_sub(shift, shift, Imm8(32));
as_orr(dest.low, dest.low, lsr(dest.high, shift));
ma_neg(shift, shift);
as_orr(dest.low, dest.low, lsl(dest.high, shift));
as_and(shift, unmaskedShift, Imm8(0x3f));
as_mov(dest.high, lsr(dest.high, shift));
}
// ===============================================================
// Rotate functions
void
MacroAssembler::rotateLeft(Imm32 count, Register input, Register dest)
{
if (count.value)
ma_rol(count, input, dest);
else
ma_mov(input, dest);
}
void
MacroAssembler::rotateLeft(Register count, Register input, Register dest)
{
ScratchRegisterScope scratch(*this);
ma_rol(count, input, dest, scratch);
}
void
MacroAssembler::rotateLeft64(Imm32 count, Register64 input, Register64 dest, Register temp)
{
MOZ_ASSERT(temp == InvalidReg);
MOZ_ASSERT(input.low != dest.high && input.high != dest.low);
int32_t amount = count.value & 0x3f;
if (amount > 32) {
rotateRight64(Imm32(64 - amount), input, dest, temp);
} else {
ScratchRegisterScope scratch(*this);
if (amount == 0) {
ma_mov(input.low, dest.low);
ma_mov(input.high, dest.high);
} else if (amount == 32) {
ma_mov(input.low, scratch);
ma_mov(input.high, dest.low);
ma_mov(scratch, dest.high);
} else {
MOZ_ASSERT(0 < amount && amount < 32);
ma_mov(dest.high, scratch);
as_mov(dest.high, lsl(dest.high, amount));
as_orr(dest.high, dest.high, lsr(dest.low, 32 - amount));
as_mov(dest.low, lsl(dest.low, amount));
as_orr(dest.low, dest.low, lsr(scratch, 32 - amount));
}
}
}
void
MacroAssembler::rotateLeft64(Register shift, Register64 src, Register64 dest, Register temp)
{
MOZ_ASSERT(shift != temp);
MOZ_ASSERT(src == dest);
MOZ_ASSERT(temp != src.low && temp != src.high);
MOZ_ASSERT(shift != src.low && shift != src.high);
MOZ_ASSERT(temp != InvalidReg);
ScratchRegisterScope shift_value(*this);
Label high, done;
ma_mov(src.high, temp);
as_and(shift_value, shift, Imm8(0x3f));
as_cmp(shift_value, Imm8(32));
ma_b(&high, GreaterThanOrEqual);
// high = high << shift | low >> 32 - shift
// low = low << shift | high >> 32 - shift
as_mov(dest.high, lsl(src.high, shift_value));
as_rsb(shift_value, shift_value, Imm8(32));
as_orr(dest.high, dest.high, lsr(src.low, shift_value));
as_rsb(shift_value, shift_value, Imm8(32));
as_mov(dest.low, lsl(src.low, shift_value));
as_rsb(shift_value, shift_value, Imm8(32));
as_orr(dest.low, dest.low, lsr(temp, shift_value));
ma_b(&done);
// A 32 - 64 shift is a 0 - 32 shift in the other direction.
bind(&high);
as_rsb(shift_value, shift_value, Imm8(64));
as_mov(dest.high, lsr(src.high, shift_value));
as_rsb(shift_value, shift_value, Imm8(32));
as_orr(dest.high, dest.high, lsl(src.low, shift_value));
as_rsb(shift_value, shift_value, Imm8(32));
as_mov(dest.low, lsr(src.low, shift_value));
as_rsb(shift_value, shift_value, Imm8(32));
as_orr(dest.low, dest.low, lsl(temp, shift_value));
bind(&done);
}
void
MacroAssembler::rotateRight(Imm32 count, Register input, Register dest)
{
if (count.value)
ma_ror(count, input, dest);
else
ma_mov(input, dest);
}
void
MacroAssembler::rotateRight(Register count, Register input, Register dest)
{
ma_ror(count, input, dest);
}
void
MacroAssembler::rotateRight64(Imm32 count, Register64 input, Register64 dest, Register temp)
{
MOZ_ASSERT(temp == InvalidReg);
MOZ_ASSERT(input.low != dest.high && input.high != dest.low);
int32_t amount = count.value & 0x3f;
if (amount > 32) {
rotateLeft64(Imm32(64 - amount), input, dest, temp);
} else {
ScratchRegisterScope scratch(*this);
if (amount == 0) {
ma_mov(input.low, dest.low);
ma_mov(input.high, dest.high);
} else if (amount == 32) {
ma_mov(input.low, scratch);
ma_mov(input.high, dest.low);
ma_mov(scratch, dest.high);
} else {
MOZ_ASSERT(0 < amount && amount < 32);
ma_mov(dest.high, scratch);
as_mov(dest.high, lsr(dest.high, amount));
as_orr(dest.high, dest.high, lsl(dest.low, 32 - amount));
as_mov(dest.low, lsr(dest.low, amount));
as_orr(dest.low, dest.low, lsl(scratch, 32 - amount));
}
}
}
void
MacroAssembler::rotateRight64(Register shift, Register64 src, Register64 dest, Register temp)
{
MOZ_ASSERT(shift != temp);
MOZ_ASSERT(src == dest);
MOZ_ASSERT(temp != src.low && temp != src.high);
MOZ_ASSERT(shift != src.low && shift != src.high);
MOZ_ASSERT(temp != InvalidReg);
ScratchRegisterScope shift_value(*this);
Label high, done;
ma_mov(src.high, temp);
as_and(shift_value, shift, Imm8(0x3f));
as_cmp(shift_value, Imm8(32));
ma_b(&high, GreaterThanOrEqual);
// high = high >> shift | low << 32 - shift
// low = low >> shift | high << 32 - shift
as_mov(dest.high, lsr(src.high, shift_value));
as_rsb(shift_value, shift_value, Imm8(32));
as_orr(dest.high, dest.high, lsl(src.low, shift_value));
as_rsb(shift_value, shift_value, Imm8(32));
as_mov(dest.low, lsr(src.low, shift_value));
as_rsb(shift_value, shift_value, Imm8(32));
as_orr(dest.low, dest.low, lsl(temp, shift_value));
ma_b(&done);
// A 32 - 64 shift is a 0 - 32 shift in the other direction.
bind(&high);
as_rsb(shift_value, shift_value, Imm8(64));
as_mov(dest.high, lsl(src.high, shift_value));
as_rsb(shift_value, shift_value, Imm8(32));
as_orr(dest.high, dest.high, lsr(src.low, shift_value));
as_rsb(shift_value, shift_value, Imm8(32));
as_mov(dest.low, lsl(src.low, shift_value));
as_rsb(shift_value, shift_value, Imm8(32));
as_orr(dest.low, dest.low, lsr(temp, shift_value));
bind(&done);
}
// ===============================================================
// Condition functions
template <typename T1, typename T2>
void
MacroAssembler::cmp32Set(Condition cond, T1 lhs, T2 rhs, Register dest)
{
cmp32(lhs, rhs);
emitSet(cond, dest);
}
template <typename T1, typename T2>
void
MacroAssembler::cmpPtrSet(Condition cond, T1 lhs, T2 rhs, Register dest)
{
cmpPtr(lhs, rhs);
emitSet(cond, dest);
}
// ===============================================================
// Bit counting functions
void
MacroAssembler::clz32(Register src, Register dest, bool knownNotZero)
{
ma_clz(src, dest);
}
void
MacroAssembler::clz64(Register64 src, Register dest)
{
ScratchRegisterScope scratch(*this);
ma_clz(src.high, scratch);
as_cmp(scratch, Imm8(32));
ma_mov(scratch, dest, LeaveCC, NotEqual);
ma_clz(src.low, dest, Equal);
as_add(dest, dest, Imm8(32), LeaveCC, Equal);
}
void
MacroAssembler::ctz32(Register src, Register dest, bool knownNotZero)
{
ScratchRegisterScope scratch(*this);
ma_ctz(src, dest, scratch);
}
void
MacroAssembler::ctz64(Register64 src, Register dest)
{
Label done, high;
as_cmp(src.low, Imm8(0));
ma_b(&high, Equal);
ctz32(src.low, dest, /* knownNotZero = */ true);
ma_b(&done);
bind(&high);
ctz32(src.high, dest, /* knownNotZero = */ false);
as_add(dest, dest, Imm8(32));
bind(&done);
}
void
MacroAssembler::popcnt32(Register input, Register output, Register tmp)
{
// Equivalent to GCC output of mozilla::CountPopulation32()
ScratchRegisterScope scratch(*this);
if (input != output)
ma_mov(input, output);
as_mov(tmp, asr(output, 1));
ma_and(Imm32(0x55555555), tmp, scratch);
ma_sub(output, tmp, output);
as_mov(tmp, asr(output, 2));
ma_mov(Imm32(0x33333333), scratch);
ma_and(scratch, output);
ma_and(scratch, tmp);
ma_add(output, tmp, output);
as_add(output, output, lsr(output, 4));
ma_and(Imm32(0xF0F0F0F), output, scratch);
as_add(output, output, lsl(output, 8));
as_add(output, output, lsl(output, 16));
as_mov(output, asr(output, 24));
}
void
MacroAssembler::popcnt64(Register64 src, Register64 dest, Register tmp)
{
MOZ_ASSERT(dest.low != tmp);
MOZ_ASSERT(dest.high != tmp);
MOZ_ASSERT(dest.low != dest.high);
// The source and destination can overlap. Therefore make sure we don't
// clobber the source before we have the data.
if (dest.low != src.high) {
popcnt32(src.low, dest.low, tmp);
popcnt32(src.high, dest.high, tmp);
} else {
MOZ_ASSERT(dest.high != src.high);
popcnt32(src.low, dest.high, tmp);
popcnt32(src.high, dest.low, tmp);
}
ma_add(dest.high, dest.low);
ma_mov(Imm32(0), dest.high);
}
// ===============================================================
// Branch functions
template <class L>
void
MacroAssembler::branch32(Condition cond, Register lhs, Register rhs, L label)
{
ma_cmp(lhs, rhs);
ma_b(label, cond);
}
template <class L>
void
MacroAssembler::branch32(Condition cond, Register lhs, Imm32 rhs, L label)
{
ScratchRegisterScope scratch(*this);
ma_cmp(lhs, rhs, scratch);
ma_b(label, cond);
}
void
MacroAssembler::branch32(Condition cond, const Address& lhs, Register rhs, Label* label)
{
ScratchRegisterScope scratch(*this);
SecondScratchRegisterScope scratch2(*this);
ma_ldr(lhs, scratch, scratch2);
ma_cmp(scratch, rhs);
ma_b(label, cond);
}
void
MacroAssembler::branch32(Condition cond, const Address& lhs, Imm32 rhs, Label* label)
{
ScratchRegisterScope scratch(*this);
SecondScratchRegisterScope scratch2(*this);
ma_ldr(lhs, scratch, scratch2);
ma_cmp(scratch, rhs, scratch2);
ma_b(label, cond);
}
void
MacroAssembler::branch32(Condition cond, const AbsoluteAddress& lhs, Register rhs, Label* label)
{
ScratchRegisterScope scratch(*this);
// Load into scratch.
movePtr(ImmWord(uintptr_t(lhs.addr)), scratch);
ma_ldr(DTRAddr(scratch, DtrOffImm(0)), scratch);
ma_cmp(scratch, rhs);
ma_b(label, cond);
}
void
MacroAssembler::branch32(Condition cond, const AbsoluteAddress& lhs, Imm32 rhs, Label* label)
{
ScratchRegisterScope scratch(*this);
SecondScratchRegisterScope scratch2(*this);
// Load into scratch.
movePtr(ImmWord(uintptr_t(lhs.addr)), scratch);
ma_ldr(DTRAddr(scratch, DtrOffImm(0)), scratch);
ma_cmp(scratch, rhs, scratch2);
ma_b(label, cond);
}
void
MacroAssembler::branch32(Condition cond, const BaseIndex& lhs, Imm32 rhs, Label* label)
{
SecondScratchRegisterScope scratch2(*this);
{
ScratchRegisterScope scratch(*this);
Register base = lhs.base;
uint32_t scale = Imm32::ShiftOf(lhs.scale).value;
// Load lhs into scratch2.
if (lhs.offset != 0) {
ma_add(base, Imm32(lhs.offset), scratch, scratch2);
ma_ldr(DTRAddr(scratch, DtrRegImmShift(lhs.index, LSL, scale)), scratch2);
} else {
ma_ldr(DTRAddr(base, DtrRegImmShift(lhs.index, LSL, scale)), scratch2);
}
}
branch32(cond, scratch2, rhs, label);
}
void
MacroAssembler::branch32(Condition cond, wasm::SymbolicAddress lhs, Imm32 rhs, Label* label)
{
ScratchRegisterScope scratch(*this);
SecondScratchRegisterScope scratch2(*this);
movePtr(lhs, scratch);
ma_ldr(DTRAddr(scratch, DtrOffImm(0)), scratch);
ma_cmp(scratch, rhs, scratch2);
ma_b(label, cond);
}
void
MacroAssembler::branch64(Condition cond, const Address& lhs, Imm64 val, Label* label)
{
MOZ_ASSERT(cond == Assembler::NotEqual,
"other condition codes not supported");
branch32(cond, lhs, val.firstHalf(), label);
branch32(cond, Address(lhs.base, lhs.offset + sizeof(uint32_t)), val.secondHalf(), label);
}
void
MacroAssembler::branch64(Condition cond, const Address& lhs, const Address& rhs, Register scratch,
Label* label)
{
MOZ_ASSERT(cond == Assembler::NotEqual,
"other condition codes not supported");
MOZ_ASSERT(lhs.base != scratch);
MOZ_ASSERT(rhs.base != scratch);
load32(rhs, scratch);
branch32(cond, lhs, scratch, label);
load32(Address(rhs.base, rhs.offset + sizeof(uint32_t)), scratch);
branch32(cond, Address(lhs.base, lhs.offset + sizeof(uint32_t)), scratch, label);
}
void
MacroAssembler::branch64(Condition cond, Register64 lhs, Imm64 val, Label* success, Label* fail)
{
bool fallthrough = false;
Label fallthroughLabel;
if (!fail) {
fail = &fallthroughLabel;
fallthrough = true;
}
switch(cond) {
case Assembler::Equal:
branch32(Assembler::NotEqual, lhs.low, val.low(), fail);
branch32(Assembler::Equal, lhs.high, val.hi(), success);
if (!fallthrough)
jump(fail);
break;
case Assembler::NotEqual:
branch32(Assembler::NotEqual, lhs.low, val.low(), success);
branch32(Assembler::NotEqual, lhs.high, val.hi(), success);
if (!fallthrough)
jump(fail);
break;
case Assembler::LessThan:
case Assembler::LessThanOrEqual:
case Assembler::GreaterThan:
case Assembler::GreaterThanOrEqual:
case Assembler::Below:
case Assembler::BelowOrEqual:
case Assembler::Above:
case Assembler::AboveOrEqual: {
Assembler::Condition cond1 = Assembler::ConditionWithoutEqual(cond);
Assembler::Condition cond2 =
Assembler::ConditionWithoutEqual(Assembler::InvertCondition(cond));
Assembler::Condition cond3 = Assembler::UnsignedCondition(cond);
cmp32(lhs.high, val.hi());
ma_b(success, cond1);
ma_b(fail, cond2);
cmp32(lhs.low, val.low());
ma_b(success, cond3);
if (!fallthrough)
jump(fail);
break;
}
default:
MOZ_CRASH("Condition code not supported");
break;
}
if (fallthrough)
bind(fail);
}
void
MacroAssembler::branch64(Condition cond, Register64 lhs, Register64 rhs, Label* success, Label* fail)
{
bool fallthrough = false;
Label fallthroughLabel;
if (!fail) {
fail = &fallthroughLabel;
fallthrough = true;
}
switch(cond) {
case Assembler::Equal:
branch32(Assembler::NotEqual, lhs.low, rhs.low, fail);
branch32(Assembler::Equal, lhs.high, rhs.high, success);
if (!fallthrough)
jump(fail);
break;
case Assembler::NotEqual:
branch32(Assembler::NotEqual, lhs.low, rhs.low, success);
branch32(Assembler::NotEqual, lhs.high, rhs.high, success);
if (!fallthrough)
jump(fail);
break;
case Assembler::LessThan:
case Assembler::LessThanOrEqual:
case Assembler::GreaterThan:
case Assembler::GreaterThanOrEqual:
case Assembler::Below:
case Assembler::BelowOrEqual:
case Assembler::Above:
case Assembler::AboveOrEqual: {
Assembler::Condition cond1 = Assembler::ConditionWithoutEqual(cond);
Assembler::Condition cond2 =
Assembler::ConditionWithoutEqual(Assembler::InvertCondition(cond));
Assembler::Condition cond3 = Assembler::UnsignedCondition(cond);
cmp32(lhs.high, rhs.high);
ma_b(success, cond1);
ma_b(fail, cond2);
cmp32(lhs.low, rhs.low);
ma_b(success, cond3);
if (!fallthrough)
jump(fail);
break;
}
default:
MOZ_CRASH("Condition code not supported");
break;
}
if (fallthrough)
bind(fail);
}
template <class L>
void
MacroAssembler::branchPtr(Condition cond, Register lhs, Register rhs, L label)
{
branch32(cond, lhs, rhs, label);
}
void
MacroAssembler::branchPtr(Condition cond, Register lhs, Imm32 rhs, Label* label)
{
branch32(cond, lhs, rhs, label);
}
void
MacroAssembler::branchPtr(Condition cond, Register lhs, ImmPtr rhs, Label* label)
{
branchPtr(cond, lhs, ImmWord(uintptr_t(rhs.value)), label);
}
void
MacroAssembler::branchPtr(Condition cond, Register lhs, ImmGCPtr rhs, Label* label)
{
ScratchRegisterScope scratch(*this);
movePtr(rhs, scratch);
branchPtr(cond, lhs, scratch, label);
}
void
MacroAssembler::branchPtr(Condition cond, Register lhs, ImmWord rhs, Label* label)
{
branch32(cond, lhs, Imm32(rhs.value), label);
}
template <class L>
void
MacroAssembler::branchPtr(Condition cond, const Address& lhs, Register rhs, L label)
{
branch32(cond, lhs, rhs, label);
}
void
MacroAssembler::branchPtr(Condition cond, const Address& lhs, ImmPtr rhs, Label* label)
{
branchPtr(cond, lhs, ImmWord(uintptr_t(rhs.value)), label);
}
void
MacroAssembler::branchPtr(Condition cond, const Address& lhs, ImmGCPtr rhs, Label* label)
{
SecondScratchRegisterScope scratch2(*this);
loadPtr(lhs, scratch2);
branchPtr(cond, scratch2, rhs, label);
}
void
MacroAssembler::branchPtr(Condition cond, const Address& lhs, ImmWord rhs, Label* label)
{
SecondScratchRegisterScope scratch2(*this);
loadPtr(lhs, scratch2);
branchPtr(cond, scratch2, rhs, label);
}
void
MacroAssembler::branchPtr(Condition cond, const AbsoluteAddress& lhs, Register rhs, Label* label)
{
SecondScratchRegisterScope scratch2(*this);
loadPtr(lhs, scratch2);
branchPtr(cond, scratch2, rhs, label);
}
void
MacroAssembler::branchPtr(Condition cond, const AbsoluteAddress& lhs, ImmWord rhs, Label* label)
{
SecondScratchRegisterScope scratch2(*this);
loadPtr(lhs, scratch2);
branchPtr(cond, scratch2, rhs, label);
}
void
MacroAssembler::branchPtr(Condition cond, wasm::SymbolicAddress lhs, Register rhs, Label* label)
{
SecondScratchRegisterScope scratch2(*this);
loadPtr(lhs, scratch2);
branchPtr(cond, scratch2, rhs, label);
}
template <typename T>
inline CodeOffsetJump
MacroAssembler::branchPtrWithPatch(Condition cond, Register lhs, T rhs, RepatchLabel* label)
{
cmpPtr(lhs, rhs);
return jumpWithPatch(label, cond);
}
template <typename T>
inline CodeOffsetJump
MacroAssembler::branchPtrWithPatch(Condition cond, Address lhs, T rhs, RepatchLabel* label)
{
SecondScratchRegisterScope scratch2(*this);
{
ScratchRegisterScope scratch(*this);
ma_ldr(lhs, scratch2, scratch);
}
cmpPtr(scratch2, rhs);
return jumpWithPatch(label, cond);
}
void
MacroAssembler::branchPrivatePtr(Condition cond, const Address& lhs, Register rhs, Label* label)
{
branchPtr(cond, lhs, rhs, label);
}
void
MacroAssembler::branchFloat(DoubleCondition cond, FloatRegister lhs, FloatRegister rhs,
Label* label)
{
compareFloat(lhs, rhs);
if (cond == DoubleNotEqual) {
// Force the unordered cases not to jump.
Label unordered;
ma_b(&unordered, VFP_Unordered);
ma_b(label, VFP_NotEqualOrUnordered);
bind(&unordered);
return;
}
if (cond == DoubleEqualOrUnordered) {
ma_b(label, VFP_Unordered);
ma_b(label, VFP_Equal);
return;
}
ma_b(label, ConditionFromDoubleCondition(cond));
}
void
MacroAssembler::branchTruncateFloat32MaybeModUint32(FloatRegister src, Register dest, Label* fail)
{
branchTruncateFloat32ToInt32(src, dest, fail);
}
void
MacroAssembler::branchTruncateFloat32ToInt32(FloatRegister src, Register dest, Label* fail)
{
ScratchFloat32Scope scratchFloat32(*this);
ScratchRegisterScope scratch(*this);
ma_vcvt_F32_I32(src, scratchFloat32.sintOverlay());
ma_vxfer(scratchFloat32, dest);
ma_cmp(dest, Imm32(0x7fffffff), scratch);
ma_cmp(dest, Imm32(0x80000000), scratch, Assembler::NotEqual);
ma_b(fail, Assembler::Equal);
}
void
MacroAssembler::branchDouble(DoubleCondition cond, FloatRegister lhs, FloatRegister rhs,
Label* label)
{
compareDouble(lhs, rhs);
if (cond == DoubleNotEqual) {
// Force the unordered cases not to jump.
Label unordered;
ma_b(&unordered, VFP_Unordered);
ma_b(label, VFP_NotEqualOrUnordered);
bind(&unordered);
return;
}
if (cond == DoubleEqualOrUnordered) {
ma_b(label, VFP_Unordered);
ma_b(label, VFP_Equal);
return;
}
ma_b(label, ConditionFromDoubleCondition(cond));
}
void
MacroAssembler::branchTruncateDoubleMaybeModUint32(FloatRegister src, Register dest, Label* fail)
{
branchTruncateDoubleToInt32(src, dest, fail);
}
// There are two options for implementing branchTruncateDoubleToInt32:
//
// 1. Convert the floating point value to an integer, if it did not fit, then it
// was clamped to INT_MIN/INT_MAX, and we can test it. NOTE: if the value
// really was supposed to be INT_MAX / INT_MIN then it will be wrong.
//
// 2. Convert the floating point value to an integer, if it did not fit, then it
// set one or two bits in the fpcsr. Check those.
void
MacroAssembler::branchTruncateDoubleToInt32(FloatRegister src, Register dest, Label* fail)
{
ScratchDoubleScope scratchDouble(*this);
FloatRegister scratchSIntReg = scratchDouble.sintOverlay();
ScratchRegisterScope scratch(*this);
ma_vcvt_F64_I32(src, scratchSIntReg);
ma_vxfer(scratchSIntReg, dest);
ma_cmp(dest, Imm32(0x7fffffff), scratch);
ma_cmp(dest, Imm32(0x80000000), scratch, Assembler::NotEqual);
ma_b(fail, Assembler::Equal);
}
template <typename T, typename L>
void
MacroAssembler::branchAdd32(Condition cond, T src, Register dest, L label)
{
add32(src, dest);
as_b(label, cond);
}
template <typename T>
void
MacroAssembler::branchSub32(Condition cond, T src, Register dest, Label* label)
{
sub32(src, dest);
j(cond, label);
}
void
MacroAssembler::decBranchPtr(Condition cond, Register lhs, Imm32 rhs, Label* label)
{
ScratchRegisterScope scratch(*this);
ma_sub(rhs, lhs, scratch, SetCC);
as_b(label, cond);
}
template <class L>
void
MacroAssembler::branchTest32(Condition cond, Register lhs, Register rhs, L label)
{
MOZ_ASSERT(cond == Zero || cond == NonZero || cond == Signed || cond == NotSigned);
// x86 likes test foo, foo rather than cmp foo, #0.
// Convert the former into the latter.
if (lhs == rhs && (cond == Zero || cond == NonZero))
as_cmp(lhs, Imm8(0));
else
ma_tst(lhs, rhs);
ma_b(label, cond);
}
template <class L>
void
MacroAssembler::branchTest32(Condition cond, Register lhs, Imm32 rhs, L label)
{
MOZ_ASSERT(cond == Zero || cond == NonZero || cond == Signed || cond == NotSigned);
ScratchRegisterScope scratch(*this);
ma_tst(lhs, rhs, scratch);
ma_b(label, cond);
}
void
MacroAssembler::branchTest32(Condition cond, const Address& lhs, Imm32 rhs, Label* label)
{
SecondScratchRegisterScope scratch2(*this);
load32(lhs, scratch2);
branchTest32(cond, scratch2, rhs, label);
}
void
MacroAssembler::branchTest32(Condition cond, const AbsoluteAddress& lhs, Imm32 rhs, Label* label)
{
SecondScratchRegisterScope scratch2(*this);
load32(lhs, scratch2);
branchTest32(cond, scratch2, rhs, label);
}
template <class L>
void
MacroAssembler::branchTestPtr(Condition cond, Register lhs, Register rhs, L label)
{
branchTest32(cond, lhs, rhs, label);
}
void
MacroAssembler::branchTestPtr(Condition cond, Register lhs, Imm32 rhs, Label* label)
{
branchTest32(cond, lhs, rhs, label);
}
void
MacroAssembler::branchTestPtr(Condition cond, const Address& lhs, Imm32 rhs, Label* label)
{
branchTest32(cond, lhs, rhs, label);
}
template <class L>
void
MacroAssembler::branchTest64(Condition cond, Register64 lhs, Register64 rhs, Register temp,
L label)
{
ScratchRegisterScope scratch(*this);
if (cond == Assembler::Zero) {
MOZ_ASSERT(lhs.low == rhs.low);
MOZ_ASSERT(lhs.high == rhs.high);
ma_orr(lhs.low, lhs.high, scratch);
branchTestPtr(cond, scratch, scratch, label);
} else {
MOZ_CRASH("Unsupported condition");
}
}
void
MacroAssembler::branchTestUndefined(Condition cond, Register tag, Label* label)
{
branchTestUndefinedImpl(cond, tag, label);
}
void
MacroAssembler::branchTestUndefined(Condition cond, const Address& address, Label* label)
{
branchTestUndefinedImpl(cond, address, label);
}
void
MacroAssembler::branchTestUndefined(Condition cond, const BaseIndex& address, Label* label)
{
branchTestUndefinedImpl(cond, address, label);
}
void
MacroAssembler::branchTestUndefined(Condition cond, const ValueOperand& value, Label* label)
{
branchTestUndefinedImpl(cond, value, label);
}
template <typename T>
void
MacroAssembler::branchTestUndefinedImpl(Condition cond, const T& t, Label* label)
{
Condition c = testUndefined(cond, t);
ma_b(label, c);
}
void
MacroAssembler::branchTestInt32(Condition cond, Register tag, Label* label)
{
branchTestInt32Impl(cond, tag, label);
}
void
MacroAssembler::branchTestInt32(Condition cond, const Address& address, Label* label)
{
branchTestInt32Impl(cond, address, label);
}
void
MacroAssembler::branchTestInt32(Condition cond, const BaseIndex& address, Label* label)
{
branchTestInt32Impl(cond, address, label);
}
void
MacroAssembler::branchTestInt32(Condition cond, const ValueOperand& value, Label* label)
{
branchTestInt32Impl(cond, value, label);
}
template <typename T>
void
MacroAssembler::branchTestInt32Impl(Condition cond, const T& t, Label* label)
{
Condition c = testInt32(cond, t);
ma_b(label, c);
}
void
MacroAssembler::branchTestInt32Truthy(bool truthy, const ValueOperand& value, Label* label)
{
Condition c = testInt32Truthy(truthy, value);
ma_b(label, c);
}
void
MacroAssembler::branchTestDouble(Condition cond, Register tag, Label* label)
{
branchTestDoubleImpl(cond, tag, label);
}
void
MacroAssembler::branchTestDouble(Condition cond, const Address& address, Label* label)
{
branchTestDoubleImpl(cond, address, label);
}
void
MacroAssembler::branchTestDouble(Condition cond, const BaseIndex& address, Label* label)
{
branchTestDoubleImpl(cond, address, label);
}
void
MacroAssembler::branchTestDouble(Condition cond, const ValueOperand& value, Label* label)
{
branchTestDoubleImpl(cond, value, label);
}
template <typename T>
void
MacroAssembler::branchTestDoubleImpl(Condition cond, const T& t, Label* label)
{
Condition c = testDouble(cond, t);
ma_b(label, c);
}
void
MacroAssembler::branchTestDoubleTruthy(bool truthy, FloatRegister reg, Label* label)
{
Condition c = testDoubleTruthy(truthy, reg);
ma_b(label, c);
}
void
MacroAssembler::branchTestNumber(Condition cond, Register tag, Label* label)
{
branchTestNumberImpl(cond, tag, label);
}
void
MacroAssembler::branchTestNumber(Condition cond, const ValueOperand& value, Label* label)
{
branchTestNumberImpl(cond, value, label);
}
template <typename T>
void
MacroAssembler::branchTestNumberImpl(Condition cond, const T& t, Label* label)
{
cond = testNumber(cond, t);
ma_b(label, cond);
}
void
MacroAssembler::branchTestBoolean(Condition cond, Register tag, Label* label)
{
branchTestBooleanImpl(cond, tag, label);
}
void
MacroAssembler::branchTestBoolean(Condition cond, const Address& address, Label* label)
{
branchTestBooleanImpl(cond, address, label);
}
void
MacroAssembler::branchTestBoolean(Condition cond, const BaseIndex& address, Label* label)
{
branchTestBooleanImpl(cond, address, label);
}
void
MacroAssembler::branchTestBoolean(Condition cond, const ValueOperand& value, Label* label)
{
branchTestBooleanImpl(cond, value, label);
}
template <typename T>
void
MacroAssembler::branchTestBooleanImpl(Condition cond, const T& t, Label* label)
{
Condition c = testBoolean(cond, t);
ma_b(label, c);
}
void
MacroAssembler::branchTestBooleanTruthy(bool truthy, const ValueOperand& value, Label* label)
{
Condition c = testBooleanTruthy(truthy, value);
ma_b(label, c);
}
void
MacroAssembler::branchTestString(Condition cond, Register tag, Label* label)
{
branchTestStringImpl(cond, tag, label);
}
void
MacroAssembler::branchTestString(Condition cond, const BaseIndex& address, Label* label)
{
branchTestStringImpl(cond, address, label);
}
void
MacroAssembler::branchTestString(Condition cond, const ValueOperand& value, Label* label)
{
branchTestStringImpl(cond, value, label);
}
template <typename T>
void
MacroAssembler::branchTestStringImpl(Condition cond, const T& t, Label* label)
{
Condition c = testString(cond, t);
ma_b(label, c);
}
void
MacroAssembler::branchTestStringTruthy(bool truthy, const ValueOperand& value, Label* label)
{
Condition c = testStringTruthy(truthy, value);
ma_b(label, c);
}
void
MacroAssembler::branchTestSymbol(Condition cond, Register tag, Label* label)
{
branchTestSymbolImpl(cond, tag, label);
}
void
MacroAssembler::branchTestSymbol(Condition cond, const BaseIndex& address, Label* label)
{
branchTestSymbolImpl(cond, address, label);
}
void
MacroAssembler::branchTestSymbol(Condition cond, const ValueOperand& value, Label* label)
{
branchTestSymbolImpl(cond, value, label);
}
template <typename T>
void
MacroAssembler::branchTestSymbolImpl(Condition cond, const T& t, Label* label)
{
Condition c = testSymbol(cond, t);
ma_b(label, c);
}
void
MacroAssembler::branchTestNull(Condition cond, Register tag, Label* label)
{
branchTestNullImpl(cond, tag, label);
}
void
MacroAssembler::branchTestNull(Condition cond, const Address& address, Label* label)
{
branchTestNullImpl(cond, address, label);
}
void
MacroAssembler::branchTestNull(Condition cond, const BaseIndex& address, Label* label)
{
branchTestNullImpl(cond, address, label);
}
void
MacroAssembler::branchTestNull(Condition cond, const ValueOperand& value, Label* label)
{
branchTestNullImpl(cond, value, label);
}
template <typename T>
void
MacroAssembler::branchTestNullImpl(Condition cond, const T& t, Label* label)
{
Condition c = testNull(cond, t);
ma_b(label, c);
}
void
MacroAssembler::branchTestObject(Condition cond, Register tag, Label* label)
{
branchTestObjectImpl(cond, tag, label);
}
void
MacroAssembler::branchTestObject(Condition cond, const Address& address, Label* label)
{
branchTestObjectImpl(cond, address, label);
}
void
MacroAssembler::branchTestObject(Condition cond, const BaseIndex& address, Label* label)
{
branchTestObjectImpl(cond, address, label);
}
void
MacroAssembler::branchTestObject(Condition cond, const ValueOperand& value, Label* label)
{
branchTestObjectImpl(cond, value, label);
}
template <typename T>
void
MacroAssembler::branchTestObjectImpl(Condition cond, const T& t, Label* label)
{
Condition c = testObject(cond, t);
ma_b(label, c);
}
void
MacroAssembler::branchTestGCThing(Condition cond, const Address& address, Label* label)
{
branchTestGCThingImpl(cond, address, label);
}
void
MacroAssembler::branchTestGCThing(Condition cond, const BaseIndex& address, Label* label)
{
branchTestGCThingImpl(cond, address, label);
}
template <typename T>
void
MacroAssembler::branchTestGCThingImpl(Condition cond, const T& t, Label* label)
{
Condition c = testGCThing(cond, t);
ma_b(label, c);
}
void
MacroAssembler::branchTestPrimitive(Condition cond, Register tag, Label* label)
{
branchTestPrimitiveImpl(cond, tag, label);
}
void
MacroAssembler::branchTestPrimitive(Condition cond, const ValueOperand& value, Label* label)
{
branchTestPrimitiveImpl(cond, value, label);
}
template <typename T>
void
MacroAssembler::branchTestPrimitiveImpl(Condition cond, const T& t, Label* label)
{
Condition c = testPrimitive(cond, t);
ma_b(label, c);
}
void
MacroAssembler::branchTestMagic(Condition cond, Register tag, Label* label)
{
branchTestMagicImpl(cond, tag, label);
}
void
MacroAssembler::branchTestMagic(Condition cond, const Address& address, Label* label)
{
branchTestMagicImpl(cond, address, label);
}
void
MacroAssembler::branchTestMagic(Condition cond, const BaseIndex& address, Label* label)
{
branchTestMagicImpl(cond, address, label);
}
template <class L>
void
MacroAssembler::branchTestMagic(Condition cond, const ValueOperand& value, L label)
{
branchTestMagicImpl(cond, value, label);
}
template <typename T, class L>
void
MacroAssembler::branchTestMagicImpl(Condition cond, const T& t, L label)
{
cond = testMagic(cond, t);
ma_b(label, cond);
}
void
MacroAssembler::branchTestMagic(Condition cond, const Address& valaddr, JSWhyMagic why, Label* label)
{
branchTestMagic(cond, valaddr, label);
branch32(cond, ToPayload(valaddr), Imm32(why), label);
}
// ========================================================================
// Memory access primitives.
void
MacroAssembler::storeUncanonicalizedDouble(FloatRegister src, const Address& addr)
{
ScratchRegisterScope scratch(*this);
ma_vstr(src, addr, scratch);
}
void
MacroAssembler::storeUncanonicalizedDouble(FloatRegister src, const BaseIndex& addr)
{
ScratchRegisterScope scratch(*this);
SecondScratchRegisterScope scratch2(*this);
uint32_t scale = Imm32::ShiftOf(addr.scale).value;
ma_vstr(src, addr.base, addr.index, scratch, scratch2, scale, addr.offset);
}
void
MacroAssembler::storeUncanonicalizedFloat32(FloatRegister src, const Address& addr)
{
ScratchRegisterScope scratch(*this);
ma_vstr(src.asSingle(), addr, scratch);
}
void
MacroAssembler::storeUncanonicalizedFloat32(FloatRegister src, const BaseIndex& addr)
{
ScratchRegisterScope scratch(*this);
SecondScratchRegisterScope scratch2(*this);
uint32_t scale = Imm32::ShiftOf(addr.scale).value;
ma_vstr(src.asSingle(), addr.base, addr.index, scratch, scratch2, scale, addr.offset);
}
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)
{
// On ARMv6 the optional argument (BarrierST, etc) is ignored.
if (barrier == (MembarStoreStore|MembarSynchronizing))
ma_dsb(BarrierST);
else if (barrier & MembarSynchronizing)
ma_dsb();
else if (barrier == MembarStoreStore)
ma_dmb(BarrierST);
else if (barrier)
ma_dmb();
}
// ===============================================================
// Clamping functions.
void
MacroAssembler::clampIntToUint8(Register reg)
{
// Look at (reg >> 8) if it is 0, then reg shouldn't be clamped if it is
// <0, then we want to clamp to 0, otherwise, we wish to clamp to 255
ScratchRegisterScope scratch(*this);
as_mov(scratch, asr(reg, 8), SetCC);
ma_mov(Imm32(0xff), reg, NotEqual);
ma_mov(Imm32(0), reg, Signed);
}
// ========================================================================
// wasm support
template <class L>
void
MacroAssembler::wasmBoundsCheck(Condition cond, Register index, L label)
{
BufferOffset bo = as_cmp(index, Imm8(0));
append(wasm::BoundsCheck(bo.getOffset()));
as_b(label, cond);
}
void
MacroAssembler::wasmPatchBoundsCheck(uint8_t* patchAt, uint32_t limit)
{
Instruction* inst = (Instruction*) patchAt;
MOZ_ASSERT(inst->is<InstCMP>());
InstCMP* cmp = inst->as<InstCMP>();
Register index;
cmp->extractOp1(&index);
MOZ_ASSERT(cmp->extractOp2().isImm8());
Imm8 imm8 = Imm8(limit);
MOZ_RELEASE_ASSERT(!imm8.invalid());
*inst = InstALU(InvalidReg, index, imm8, OpCmp, SetCC, Always);
// Don't call Auto Flush Cache; the wasm caller has done this for us.
}
//}}} check_macroassembler_style
// ===============================================================
void
MacroAssemblerARMCompat::incrementInt32Value(const Address& addr)
{
asMasm().add32(Imm32(1), ToPayload(addr));
}
} // namespace jit
} // namespace js
#endif /* jit_arm_MacroAssembler_arm_inl_h */