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/*
* Copyright (C) 2008-2021 Apple Inc. All rights reserved.
* Copyright (C) 2010 MIPS Technologies, 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 MIPS TECHNOLOGIES, 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 MIPS TECHNOLOGIES, 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.
*/
#pragma once
#if ENABLE(ASSEMBLER) && CPU(MIPS)
#include "MIPSAssembler.h"
#include "AbstractMacroAssembler.h"
namespace JSC {
using Assembler = TARGET_ASSEMBLER;
class MacroAssemblerMIPS : public AbstractMacroAssembler<Assembler> {
public:
typedef MIPSRegisters::FPRegisterID FPRegisterID;
static constexpr unsigned numGPRs = 32;
static constexpr unsigned numFPRs = 32;
static constexpr size_t nearJumpRange = 2 * GB;
MacroAssemblerMIPS()
: m_fixedWidth(false)
{
}
static bool isCompactPtrAlignedAddressOffset(ptrdiff_t value)
{
return value >= -2147483647 - 1 && value <= 2147483647;
}
inline bool isPowerOf2(int32_t v)
{
return hasOneBitSet(v);
}
inline int bitPosition(int32_t v)
{
return getLSBSet(v);
}
// For storing immediate number
static constexpr RegisterID immTempRegister = MIPSRegisters::t0;
// For storing data loaded from the memory
static constexpr RegisterID dataTempRegister = MIPSRegisters::t1;
// For storing address base
static constexpr RegisterID addrTempRegister = MIPSRegisters::t7;
// For storing compare result
static constexpr RegisterID cmpTempRegister = MIPSRegisters::t8;
// FP temp register
static constexpr FPRegisterID fpTempRegister = MIPSRegisters::f16;
RegisterID scratchRegister() { return dataTempRegister; }
static constexpr int MaximumCompactPtrAlignedAddressOffset = 0x7FFFFFFF;
enum RelationalCondition {
Equal,
NotEqual,
Above,
AboveOrEqual,
Below,
BelowOrEqual,
GreaterThan,
GreaterThanOrEqual,
LessThan,
LessThanOrEqual
};
enum ResultCondition {
Overflow,
Signed,
PositiveOrZero,
Zero,
NonZero
};
enum DoubleCondition {
DoubleEqualAndOrdered,
DoubleNotEqualAndOrdered,
DoubleGreaterThanAndOrdered,
DoubleGreaterThanOrEqualAndOrdered,
DoubleLessThanAndOrdered,
DoubleLessThanOrEqualAndOrdered,
DoubleEqualOrUnordered,
DoubleNotEqualOrUnordered,
DoubleGreaterThanOrUnordered,
DoubleGreaterThanOrEqualOrUnordered,
DoubleLessThanOrUnordered,
DoubleLessThanOrEqualOrUnordered
};
enum class LoadAddressMode {
ScaleAndAddOffsetIfOffsetIsOutOfBounds,
Scale
};
static constexpr RegisterID stackPointerRegister = MIPSRegisters::sp;
static constexpr RegisterID framePointerRegister = MIPSRegisters::fp;
static constexpr RegisterID returnAddressRegister = MIPSRegisters::ra;
// 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.addu(dest, dest, src);
}
void add32(RegisterID op1, RegisterID op2, RegisterID dest)
{
m_assembler.addu(dest, op1, op2);
}
void add32(TrustedImm32 imm, RegisterID dest)
{
add32(imm, dest, dest);
}
void add32(TrustedImm32 imm, RegisterID src, RegisterID dest)
{
if (imm.m_value >= -32768 && imm.m_value <= 32767
&& !m_fixedWidth) {
/*
addiu dest, src, imm
*/
m_assembler.addiu(dest, src, imm.m_value);
} else {
/*
li immTemp, imm
addu dest, src, immTemp
*/
move(imm, immTempRegister);
m_assembler.addu(dest, src, immTempRegister);
}
}
void add32(RegisterID src, TrustedImm32 imm, RegisterID dest)
{
add32(imm, src, dest);
}
void add32(TrustedImm32 imm, Address address)
{
if (address.offset >= -32768 && address.offset <= 32767
&& !m_fixedWidth) {
/*
lw dataTemp, offset(base)
li immTemp, imm
addu dataTemp, dataTemp, immTemp
sw dataTemp, offset(base)
*/
m_assembler.lw(dataTempRegister, address.base, address.offset);
if (imm.m_value >= -32768 && imm.m_value <= 32767
&& !m_fixedWidth)
m_assembler.addiu(dataTempRegister, dataTempRegister, imm.m_value);
else {
move(imm, immTempRegister);
m_assembler.addu(dataTempRegister, dataTempRegister, immTempRegister);
}
m_assembler.sw(dataTempRegister, address.base, address.offset);
} else {
/*
lui addrTemp, (offset + 0x8000) >> 16
addu addrTemp, addrTemp, base
lw dataTemp, (offset & 0xffff)(addrTemp)
li immtemp, imm
addu dataTemp, dataTemp, immTemp
sw dataTemp, (offset & 0xffff)(addrTemp)
*/
m_assembler.lui(addrTempRegister, (address.offset + 0x8000) >> 16);
m_assembler.addu(addrTempRegister, addrTempRegister, address.base);
m_assembler.lw(dataTempRegister, addrTempRegister, address.offset);
if (imm.m_value >= -32768 && imm.m_value <= 32767 && !m_fixedWidth)
m_assembler.addiu(dataTempRegister, dataTempRegister, imm.m_value);
else {
move(imm, immTempRegister);
m_assembler.addu(dataTempRegister, dataTempRegister, immTempRegister);
}
m_assembler.sw(dataTempRegister, addrTempRegister, address.offset);
}
}
void add32(Address src, RegisterID dest)
{
load32(src, dataTempRegister);
add32(dataTempRegister, dest);
}
void add32(AbsoluteAddress src, RegisterID dest)
{
load32(src.m_ptr, dataTempRegister);
add32(dataTempRegister, dest);
}
void add32(RegisterID src, Address dest)
{
if (dest.offset >= -32768 && dest.offset <= 32767 && !m_fixedWidth) {
/*
lw dataTemp, offset(base)
addu dataTemp, dataTemp, src
sw dataTemp, offset(base)
*/
m_assembler.lw(dataTempRegister, dest.base, dest.offset);
m_assembler.addu(dataTempRegister, dataTempRegister, src);
m_assembler.sw(dataTempRegister, dest.base, dest.offset);
} else {
/*
lui addrTemp, (offset + 0x8000) >> 16
addu addrTemp, addrTemp, base
lw dataTemp, (offset & 0xffff)(addrTemp)
addu dataTemp, dataTemp, src
sw dataTemp, (offset & 0xffff)(addrTemp)
*/
m_assembler.lui(addrTempRegister, (dest.offset + 0x8000) >> 16);
m_assembler.addu(addrTempRegister, addrTempRegister, dest.base);
m_assembler.lw(dataTempRegister, addrTempRegister, dest.offset);
m_assembler.addu(dataTempRegister, dataTempRegister, src);
m_assembler.sw(dataTempRegister, addrTempRegister, dest.offset);
}
}
void add32(TrustedImm32 imm, AbsoluteAddress address)
{
if (!m_fixedWidth) {
uintptr_t adr = reinterpret_cast<uintptr_t>(address.m_ptr);
m_assembler.lui(addrTempRegister, (adr + 0x8000) >> 16);
m_assembler.lw(cmpTempRegister, addrTempRegister, adr & 0xffff);
if (imm.m_value >= -32768 && imm.m_value <= 32767)
m_assembler.addiu(dataTempRegister, cmpTempRegister, imm.m_value);
else {
move(imm, immTempRegister);
m_assembler.addu(dataTempRegister, cmpTempRegister, immTempRegister);
}
m_assembler.sw(dataTempRegister, addrTempRegister, adr & 0xffff);
} else {
/*
li addrTemp, address
li immTemp, imm
lw cmpTemp, 0(addrTemp)
addu dataTemp, cmpTemp, immTemp
sw dataTemp, 0(addrTemp)
*/
move(TrustedImmPtr(address.m_ptr), addrTempRegister);
m_assembler.lw(cmpTempRegister, addrTempRegister, 0);
move(imm, immTempRegister);
m_assembler.addu(dataTempRegister, cmpTempRegister, immTempRegister);
m_assembler.sw(dataTempRegister, addrTempRegister, 0);
}
}
void add64(TrustedImm32 imm, AbsoluteAddress address)
{
if (!m_fixedWidth) {
uintptr_t adr = reinterpret_cast<uintptr_t>(address.m_ptr);
if ((adr >> 15) == ((adr + 4) >> 15)) {
m_assembler.lui(addrTempRegister, (adr + 0x8000) >> 16);
m_assembler.lw(cmpTempRegister, addrTempRegister, adr & 0xffff);
if (imm.m_value >= -32768 && imm.m_value <= 32767)
m_assembler.addiu(dataTempRegister, cmpTempRegister, imm.m_value);
else {
move(imm, immTempRegister);
m_assembler.addu(dataTempRegister, cmpTempRegister, immTempRegister);
}
m_assembler.sw(dataTempRegister, addrTempRegister, adr & 0xffff);
m_assembler.sltu(immTempRegister, dataTempRegister, cmpTempRegister);
m_assembler.lw(dataTempRegister, addrTempRegister, (adr + 4) & 0xffff);
if (imm.m_value >> 31)
m_assembler.addiu(dataTempRegister, dataTempRegister, -1);
m_assembler.addu(dataTempRegister, dataTempRegister, immTempRegister);
m_assembler.sw(dataTempRegister, addrTempRegister, (adr + 4) & 0xffff);
return;
}
}
/*
add32(imm, address)
sltu immTemp, dataTemp, cmpTemp # set carry-in bit
lw dataTemp, 4(addrTemp)
addiu dataTemp, imm.m_value >> 31 ? -1 : 0
addu dataTemp, dataTemp, immTemp
sw dataTemp, 4(addrTemp)
*/
move(TrustedImmPtr(address.m_ptr), addrTempRegister);
m_assembler.lw(cmpTempRegister, addrTempRegister, 0);
if (imm.m_value >= -32768 && imm.m_value <= 32767 && !m_fixedWidth)
m_assembler.addiu(dataTempRegister, cmpTempRegister, imm.m_value);
else {
move(imm, immTempRegister);
m_assembler.addu(dataTempRegister, cmpTempRegister, immTempRegister);
}
m_assembler.sw(dataTempRegister, addrTempRegister, 0);
m_assembler.sltu(immTempRegister, dataTempRegister, cmpTempRegister);
m_assembler.lw(dataTempRegister, addrTempRegister, 4);
if (imm.m_value >> 31)
m_assembler.addiu(dataTempRegister, dataTempRegister, -1);
m_assembler.addu(dataTempRegister, dataTempRegister, immTempRegister);
m_assembler.sw(dataTempRegister, addrTempRegister, 4);
}
void loadAddress(BaseIndex address, LoadAddressMode mode)
{
if (mode == LoadAddressMode::ScaleAndAddOffsetIfOffsetIsOutOfBounds) {
if (!address.scale)
m_assembler.addu(addrTempRegister, address.index, address.base);
else {
m_assembler.sll(addrTempRegister, address.index, address.scale);
m_assembler.addu(addrTempRegister, addrTempRegister, address.base);
}
if (address.offset < -32768 || address.offset > 32767) {
m_assembler.lui(immTempRegister, (address.offset + 0x8000) >> 16);
m_assembler.addu(addrTempRegister, addrTempRegister, immTempRegister);
}
} else {
if (!address.scale)
m_assembler.addu(addrTempRegister, address.index, address.base);
else {
m_assembler.sll(addrTempRegister, address.index, address.scale);
m_assembler.addu(addrTempRegister, addrTempRegister, address.base);
}
}
}
void getEffectiveAddress(BaseIndex address, RegisterID dest)
{
if (!address.scale && !m_fixedWidth)
m_assembler.addu(dest, address.index, address.base);
else {
m_assembler.sll(addrTempRegister, address.index, address.scale);
m_assembler.addu(dest, addrTempRegister, address.base);
}
if (address.offset)
add32(TrustedImm32(address.offset), dest);
}
void and16(Address src, RegisterID dest)
{
load16(src, dataTempRegister);
and32(dataTempRegister, dest);
}
void and32(Address src, RegisterID dest)
{
load32(src, dataTempRegister);
and32(dataTempRegister, dest);
}
void and32(RegisterID src, RegisterID dest)
{
m_assembler.andInsn(dest, dest, src);
}
void and32(RegisterID op1, RegisterID op2, RegisterID dest)
{
m_assembler.andInsn(dest, op1, op2);
}
void and32(TrustedImm32 imm, RegisterID dest)
{
if (!imm.m_value && !m_fixedWidth)
move(MIPSRegisters::zero, dest);
else if (imm.m_value > 0 && imm.m_value <= 65535 && !m_fixedWidth)
m_assembler.andi(dest, dest, imm.m_value);
else {
/*
li immTemp, imm
and dest, dest, immTemp
*/
move(imm, immTempRegister);
m_assembler.andInsn(dest, dest, immTempRegister);
}
}
void and32(TrustedImm32 imm, RegisterID src, RegisterID dest)
{
if (!imm.m_value && !m_fixedWidth)
move(MIPSRegisters::zero, dest);
else if (imm.m_value > 0 && imm.m_value <= 65535 && !m_fixedWidth)
m_assembler.andi(dest, src, imm.m_value);
else {
move(imm, immTempRegister);
m_assembler.andInsn(dest, src, immTempRegister);
}
}
void countLeadingZeros32(RegisterID src, RegisterID dest)
{
#if WTF_MIPS_ISA_AT_LEAST(32)
m_assembler.clz(dest, src);
#else
static_assert(false, "CLZ opcode is not available for this ISA");
#endif
}
void lshift32(RegisterID shiftAmount, RegisterID dest)
{
m_assembler.sllv(dest, dest, shiftAmount);
}
void lshift32(RegisterID src, RegisterID shiftAmount, RegisterID dest)
{
m_assembler.sllv(dest, src, shiftAmount);
}
void lshift32(TrustedImm32 imm, RegisterID dest)
{
m_assembler.sll(dest, dest, imm.m_value);
}
void lshift32(RegisterID src, TrustedImm32 imm, RegisterID dest)
{
m_assembler.sll(dest, src, imm.m_value);
}
void mul32(RegisterID src, RegisterID dest)
{
m_assembler.mul(dest, dest, src);
}
void mul32(RegisterID op1, RegisterID op2, RegisterID dest)
{
m_assembler.mul(dest, op1, op2);
}
void mul32(TrustedImm32 imm, RegisterID src, RegisterID dest)
{
if (!imm.m_value && !m_fixedWidth)
move(MIPSRegisters::zero, dest);
else if (imm.m_value == 1 && !m_fixedWidth)
move(src, dest);
else {
/*
li dataTemp, imm
mul dest, src, dataTemp
*/
move(imm, dataTempRegister);
m_assembler.mul(dest, src, dataTempRegister);
}
}
void neg32(RegisterID srcDest)
{
m_assembler.subu(srcDest, MIPSRegisters::zero, srcDest);
}
void neg32(RegisterID src, RegisterID dest)
{
m_assembler.subu(dest, MIPSRegisters::zero, src);
}
void or8(TrustedImm32 imm, AbsoluteAddress dest)
{
if (!imm.m_value && !m_fixedWidth)
return;
if (m_fixedWidth) {
load8(dest.m_ptr, immTempRegister);
or32(imm, immTempRegister);
store8(immTempRegister, dest.m_ptr);
} else {
uintptr_t adr = reinterpret_cast<uintptr_t>(dest.m_ptr);
m_assembler.lui(addrTempRegister, (adr + 0x8000) >> 16);
m_assembler.lbu(immTempRegister, addrTempRegister, adr & 0xffff);
or32(imm, immTempRegister);
m_assembler.sb(immTempRegister, addrTempRegister, adr & 0xffff);
}
}
void or16(TrustedImm32 imm, AbsoluteAddress dest)
{
if (!imm.m_value && !m_fixedWidth)
return;
if (m_fixedWidth) {
// TODO: Swap dataTempRegister and immTempRegister usage
load16(dest.m_ptr, immTempRegister);
or32(imm, immTempRegister);
store16(immTempRegister, dest.m_ptr);
} else {
uintptr_t adr = reinterpret_cast<uintptr_t>(dest.m_ptr);
m_assembler.lui(addrTempRegister, (adr + 0x8000) >> 16);
m_assembler.lhu(immTempRegister, addrTempRegister, adr & 0xffff);
or32(imm, immTempRegister);
m_assembler.sh(immTempRegister, addrTempRegister, adr & 0xffff);
}
}
void or32(RegisterID src, RegisterID dest)
{
m_assembler.orInsn(dest, dest, src);
}
void or32(RegisterID op1, RegisterID op2, RegisterID dest)
{
m_assembler.orInsn(dest, op1, op2);
}
void or32(TrustedImm32 imm, AbsoluteAddress dest)
{
if (!imm.m_value && !m_fixedWidth)
return;
if (m_fixedWidth) {
// TODO: Swap dataTempRegister and immTempRegister usage
load32(dest.m_ptr, immTempRegister);
or32(imm, immTempRegister);
store32(immTempRegister, dest.m_ptr);
} else {
uintptr_t adr = reinterpret_cast<uintptr_t>(dest.m_ptr);
m_assembler.lui(addrTempRegister, (adr + 0x8000) >> 16);
m_assembler.lw(immTempRegister, addrTempRegister, adr & 0xffff);
or32(imm, immTempRegister);
m_assembler.sw(immTempRegister, addrTempRegister, adr & 0xffff);
}
}
void or32(TrustedImm32 imm, RegisterID dest)
{
if (!imm.m_value && !m_fixedWidth)
return;
if (imm.m_value > 0 && imm.m_value <= 65535
&& !m_fixedWidth) {
m_assembler.ori(dest, dest, imm.m_value);
return;
}
/*
li dataTemp, imm
or dest, dest, dataTemp
*/
move(imm, dataTempRegister);
m_assembler.orInsn(dest, dest, dataTempRegister);
}
void or32(TrustedImm32 imm, RegisterID src, RegisterID dest)
{
if (!imm.m_value && !m_fixedWidth) {
move(src, dest);
return;
}
if (imm.m_value > 0 && imm.m_value <= 65535 && !m_fixedWidth) {
m_assembler.ori(dest, src, imm.m_value);
return;
}
/*
li dataTemp, imm
or dest, src, dataTemp
*/
move(imm, dataTempRegister);
m_assembler.orInsn(dest, src, dataTempRegister);
}
void or32(RegisterID src, AbsoluteAddress dest)
{
if (m_fixedWidth) {
load32(dest.m_ptr, dataTempRegister);
m_assembler.orInsn(dataTempRegister, dataTempRegister, src);
store32(dataTempRegister, dest.m_ptr);
} else {
uintptr_t adr = reinterpret_cast<uintptr_t>(dest.m_ptr);
m_assembler.lui(addrTempRegister, (adr + 0x8000) >> 16);
m_assembler.lw(dataTempRegister, addrTempRegister, adr & 0xffff);
m_assembler.orInsn(dataTempRegister, dataTempRegister, src);
m_assembler.sw(dataTempRegister, addrTempRegister, adr & 0xffff);
}
}
void or32(TrustedImm32 imm, Address address)
{
if (address.offset >= -32768 && address.offset <= 32767
&& !m_fixedWidth) {
/*
lw dataTemp, offset(base)
li immTemp, imm
or dataTemp, dataTemp, immTemp
sw dataTemp, offset(base)
*/
m_assembler.lw(dataTempRegister, address.base, address.offset);
if (imm.m_value >= 0 && imm.m_value <= 65535 && !m_fixedWidth)
m_assembler.ori(dataTempRegister, dataTempRegister, imm.m_value);
else {
move(imm, immTempRegister);
m_assembler.orInsn(dataTempRegister, dataTempRegister, immTempRegister);
}
m_assembler.sw(dataTempRegister, address.base, address.offset);
} else {
/*
lui addrTemp, (offset + 0x8000) >> 16
addu addrTemp, addrTemp, base
lw dataTemp, (offset & 0xffff)(addrTemp)
li immtemp, imm
or dataTemp, dataTemp, immTemp
sw dataTemp, (offset & 0xffff)(addrTemp)
*/
m_assembler.lui(addrTempRegister, (address.offset + 0x8000) >> 16);
m_assembler.addu(addrTempRegister, addrTempRegister, address.base);
m_assembler.lw(dataTempRegister, addrTempRegister, address.offset);
if (imm.m_value >= 0 && imm.m_value <= 65535 && !m_fixedWidth)
m_assembler.ori(dataTempRegister, dataTempRegister, imm.m_value);
else {
move(imm, immTempRegister);
m_assembler.orInsn(dataTempRegister, dataTempRegister, immTempRegister);
}
m_assembler.sw(dataTempRegister, addrTempRegister, address.offset);
}
}
// This is only referenced by code intented for ARM64_32.
void rotateRight32(TrustedImm32, RegisterID)
{
UNREACHABLE_FOR_PLATFORM();
}
void rshift32(RegisterID shiftAmount, RegisterID dest)
{
m_assembler.srav(dest, dest, shiftAmount);
}
void rshift32(RegisterID src, RegisterID shiftAmount, RegisterID dest)
{
m_assembler.srav(dest, src, shiftAmount);
}
void rshift32(TrustedImm32 imm, RegisterID dest)
{
m_assembler.sra(dest, dest, imm.m_value);
}
void rshift32(RegisterID src, TrustedImm32 imm, RegisterID dest)
{
m_assembler.sra(dest, src, imm.m_value);
}
void urshift32(RegisterID shiftAmount, RegisterID dest)
{
m_assembler.srlv(dest, dest, shiftAmount);
}
void urshift32(RegisterID src, RegisterID shiftAmount, RegisterID dest)
{
m_assembler.srlv(dest, src, shiftAmount);
}
void urshift32(TrustedImm32 imm, RegisterID dest)
{
m_assembler.srl(dest, dest, imm.m_value);
}
void urshift32(RegisterID src, TrustedImm32 imm, RegisterID dest)
{
m_assembler.srl(dest, src, imm.m_value);
}
void sub32(RegisterID src, RegisterID dest)
{
m_assembler.subu(dest, dest, src);
}
void sub32(RegisterID op1, RegisterID op2, RegisterID dest)
{
m_assembler.subu(dest, op1, op2);
}
void sub32(TrustedImm32 imm, RegisterID dest)
{
if (imm.m_value >= -32767 && imm.m_value <= 32768
&& !m_fixedWidth) {
/*
addiu dest, src, imm
*/
m_assembler.addiu(dest, dest, -imm.m_value);
} else {
/*
li immTemp, imm
subu dest, src, immTemp
*/
move(imm, immTempRegister);
m_assembler.subu(dest, dest, immTempRegister);
}
}
void sub32(RegisterID src, TrustedImm32 imm, RegisterID dest)
{
if (imm.m_value >= -32767 && imm.m_value <= 32768
&& !m_fixedWidth) {
/*
addiu dest, src, imm
*/
m_assembler.addiu(dest, src, -imm.m_value);
} else {
/*
li immTemp, imm
subu dest, src, immTemp
*/
move(imm, immTempRegister);
m_assembler.subu(dest, src, immTempRegister);
}
}
void sub32(TrustedImm32 imm, Address address)
{
if (address.offset >= -32768 && address.offset <= 32767
&& !m_fixedWidth) {
/*
lw dataTemp, offset(base)
li immTemp, imm
subu dataTemp, dataTemp, immTemp
sw dataTemp, offset(base)
*/
m_assembler.lw(dataTempRegister, address.base, address.offset);
if (imm.m_value >= -32767 && imm.m_value <= 32768 && !m_fixedWidth)
m_assembler.addiu(dataTempRegister, dataTempRegister, -imm.m_value);
else {
move(imm, immTempRegister);
m_assembler.subu(dataTempRegister, dataTempRegister, immTempRegister);
}
m_assembler.sw(dataTempRegister, address.base, address.offset);
} else {
/*
lui addrTemp, (offset + 0x8000) >> 16
addu addrTemp, addrTemp, base
lw dataTemp, (offset & 0xffff)(addrTemp)
li immtemp, imm
subu dataTemp, dataTemp, immTemp
sw dataTemp, (offset & 0xffff)(addrTemp)
*/
m_assembler.lui(addrTempRegister, (address.offset + 0x8000) >> 16);
m_assembler.addu(addrTempRegister, addrTempRegister, address.base);
m_assembler.lw(dataTempRegister, addrTempRegister, address.offset);
if (imm.m_value >= -32767 && imm.m_value <= 32768
&& !m_fixedWidth)
m_assembler.addiu(dataTempRegister, dataTempRegister, -imm.m_value);
else {
move(imm, immTempRegister);
m_assembler.subu(dataTempRegister, dataTempRegister, immTempRegister);
}
m_assembler.sw(dataTempRegister, addrTempRegister, address.offset);
}
}
void sub32(Address src, RegisterID dest)
{
load32(src, dataTempRegister);
sub32(dataTempRegister, dest);
}
void sub32(TrustedImm32 imm, AbsoluteAddress address)
{
if (!m_fixedWidth) {
uintptr_t adr = reinterpret_cast<uintptr_t>(address.m_ptr);
m_assembler.lui(addrTempRegister, (adr + 0x8000) >> 16);
m_assembler.lw(cmpTempRegister, addrTempRegister, adr & 0xffff);
if (imm.m_value >= -32767 && imm.m_value <= 32768)
m_assembler.addiu(dataTempRegister, cmpTempRegister, -imm.m_value);
else {
move(imm, immTempRegister);
m_assembler.subu(dataTempRegister, cmpTempRegister, immTempRegister);
}
m_assembler.sw(dataTempRegister, addrTempRegister, adr & 0xffff);
} else {
/*
li addrTemp, address
lw dataTemp, 0(addrTemp)
li immTemp, imm
subu dataTemp, dataTemp, immTemp
sw dataTemp, 0(addrTemp)
*/
move(TrustedImmPtr(address.m_ptr), addrTempRegister);
m_assembler.lw(cmpTempRegister, addrTempRegister, 0);
move(imm, immTempRegister);
m_assembler.subu(dataTempRegister, cmpTempRegister, immTempRegister);
m_assembler.sw(dataTempRegister, addrTempRegister, 0);
}
}
void xor32(RegisterID src, RegisterID dest)
{
m_assembler.xorInsn(dest, dest, src);
}
void xor32(RegisterID op1, RegisterID op2, RegisterID dest)
{
m_assembler.xorInsn(dest, op1, op2);
}
void xor32(Address src, RegisterID dest)
{
load32(src, dataTempRegister);
xor32(dataTempRegister, dest);
}
void xor32(TrustedImm32 imm, RegisterID dest)
{
if (!m_fixedWidth) {
if (imm.m_value == -1) {
m_assembler.nor(dest, dest, MIPSRegisters::zero);
return;
}
if (imm.m_value >= 0 && imm.m_value <= 65535) {
m_assembler.xori(dest, dest, imm.m_value);
return;
}
}
/*
li immTemp, imm
xor dest, dest, immTemp
*/
move(imm, immTempRegister);
m_assembler.xorInsn(dest, dest, immTempRegister);
}
void xor32(TrustedImm32 imm, RegisterID src, RegisterID dest)
{
if (!m_fixedWidth) {
if (imm.m_value == -1) {
m_assembler.nor(dest, src, MIPSRegisters::zero);
return;
}
if (imm.m_value >= 0 && imm.m_value <= 65535) {
m_assembler.xori(dest, src, imm.m_value);
return;
}
}
/*
li immTemp, imm
xor dest, src, immTemp
*/
move(imm, immTempRegister);
m_assembler.xorInsn(dest, src, immTempRegister);
}
void not32(RegisterID srcDest)
{
m_assembler.nor(srcDest, srcDest, MIPSRegisters::zero);
}
void sqrtDouble(FPRegisterID src, FPRegisterID dst)
{
m_assembler.sqrtd(dst, src);
}
void absDouble(FPRegisterID src, FPRegisterID dst)
{
m_assembler.absd(dst, src);
}
NO_RETURN_DUE_TO_CRASH void ceilDouble(FPRegisterID, FPRegisterID)
{
ASSERT(!supportsFloatingPointRounding());
CRASH();
}
NO_RETURN_DUE_TO_CRASH void floorDouble(FPRegisterID, FPRegisterID)
{
ASSERT(!supportsFloatingPointRounding());
CRASH();
}
NO_RETURN_DUE_TO_CRASH void roundTowardZeroDouble(FPRegisterID, FPRegisterID)
{
ASSERT(!supportsFloatingPointRounding());
CRASH();
}
ConvertibleLoadLabel convertibleLoadPtr(Address address, RegisterID dest)
{
ConvertibleLoadLabel result(this);
/*
lui addrTemp, (offset + 0x8000) >> 16
addu addrTemp, addrTemp, base
lw dest, (offset & 0xffff)(addrTemp)
*/
m_assembler.lui(addrTempRegister, (address.offset + 0x8000) >> 16);
m_assembler.addu(addrTempRegister, addrTempRegister, address.base);
m_assembler.lw(dest, addrTempRegister, address.offset);
return result;
}
// 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.
/* Need to use zero-extened load byte for load8. */
void load8(Address address, RegisterID dest)
{
if (address.offset >= -32768 && address.offset <= 32767
&& !m_fixedWidth)
m_assembler.lbu(dest, address.base, address.offset);
else {
/*
lui addrTemp, (offset + 0x8000) >> 16
addu addrTemp, addrTemp, base
lbu dest, (offset & 0xffff)(addrTemp)
*/
m_assembler.lui(addrTempRegister, (address.offset + 0x8000) >> 16);
m_assembler.addu(addrTempRegister, addrTempRegister, address.base);
m_assembler.lbu(dest, addrTempRegister, address.offset);
}
}
void load8(BaseIndex address, RegisterID dest)
{
if (!m_fixedWidth) {
loadAddress(address, LoadAddressMode::ScaleAndAddOffsetIfOffsetIsOutOfBounds);
m_assembler.lbu(dest, addrTempRegister, address.offset);
} else {
/*
sll addrTemp, address.index, address.scale
addu addrTemp, addrTemp, address.base
lui immTemp, (address.offset + 0x8000) >> 16
addu addrTemp, addrTemp, immTemp
lbu dest, (address.offset & 0xffff)(at)
*/
m_assembler.sll(addrTempRegister, address.index, address.scale);
m_assembler.addu(addrTempRegister, addrTempRegister, address.base);
m_assembler.lui(immTempRegister, (address.offset + 0x8000) >> 16);
m_assembler.addu(addrTempRegister, addrTempRegister, immTempRegister);
m_assembler.lbu(dest, addrTempRegister, address.offset);
}
}
ALWAYS_INLINE void load8(AbsoluteAddress address, RegisterID dest)
{
load8(address.m_ptr, dest);
}
void load8(const void* address, RegisterID dest)
{
if (m_fixedWidth) {
/*
li addrTemp, address
lbu dest, 0(addrTemp)
*/
move(TrustedImmPtr(address), addrTempRegister);
m_assembler.lbu(dest, addrTempRegister, 0);
} else {
uintptr_t adr = reinterpret_cast<uintptr_t>(address);
m_assembler.lui(addrTempRegister, (adr + 0x8000) >> 16);
m_assembler.lbu(dest, addrTempRegister, adr & 0xffff);
}
}
void load8SignedExtendTo32(Address address, RegisterID dest)
{
if (address.offset >= -32768 && address.offset <= 32767
&& !m_fixedWidth)
m_assembler.lb(dest, address.base, address.offset);
else {
/*
lui addrTemp, (offset + 0x8000) >> 16
addu addrTemp, addrTemp, base
lb dest, (offset & 0xffff)(addrTemp)
*/
m_assembler.lui(addrTempRegister, (address.offset + 0x8000) >> 16);
m_assembler.addu(addrTempRegister, addrTempRegister, address.base);
m_assembler.lb(dest, addrTempRegister, address.offset);
}
}
void load8SignedExtendTo32(BaseIndex address, RegisterID dest)
{
if (!m_fixedWidth) {
loadAddress(address, LoadAddressMode::ScaleAndAddOffsetIfOffsetIsOutOfBounds);
m_assembler.lb(dest, addrTempRegister, address.offset);
} else {
/*
sll addrTemp, address.index, address.scale
addu addrTemp, addrTemp, address.base
lui immTemp, (address.offset + 0x8000) >> 16
addu addrTemp, addrTemp, immTemp
lb dest, (address.offset & 0xffff)(at)
*/
m_assembler.sll(addrTempRegister, address.index, address.scale);
m_assembler.addu(addrTempRegister, addrTempRegister, address.base);
m_assembler.lui(immTempRegister, (address.offset + 0x8000) >> 16);
m_assembler.addu(addrTempRegister, addrTempRegister, immTempRegister);
m_assembler.lb(dest, addrTempRegister, address.offset);
}
}
ALWAYS_INLINE void load8SignedExtendTo32(AbsoluteAddress address, RegisterID dest)
{
load8SignedExtendTo32(address.m_ptr, dest);
}
void load8SignedExtendTo32(const void* address, RegisterID dest)
{
if (m_fixedWidth) {
/*
li addrTemp, address
lb dest, 0(addrTemp)
*/
move(TrustedImmPtr(address), addrTempRegister);
m_assembler.lb(dest, addrTempRegister, 0);
} else {
uintptr_t adr = reinterpret_cast<uintptr_t>(address);
m_assembler.lui(addrTempRegister, (adr + 0x8000) >> 16);
m_assembler.lb(dest, addrTempRegister, adr & 0xffff);
}
}
void load32(Address address, RegisterID dest)
{
if (address.offset >= -32768 && address.offset <= 32767
&& !m_fixedWidth)
m_assembler.lw(dest, address.base, address.offset);
else {
/*
lui addrTemp, (offset + 0x8000) >> 16
addu addrTemp, addrTemp, base
lw dest, (offset & 0xffff)(addrTemp)
*/
m_assembler.lui(addrTempRegister, (address.offset + 0x8000) >> 16);
m_assembler.addu(addrTempRegister, addrTempRegister, address.base);
m_assembler.lw(dest, addrTempRegister, address.offset);
}
}
void load32(BaseIndex address, RegisterID dest)
{
if (!m_fixedWidth) {
loadAddress(address, LoadAddressMode::ScaleAndAddOffsetIfOffsetIsOutOfBounds);
m_assembler.lw(dest, addrTempRegister, address.offset);
} else {
/*
sll addrTemp, address.index, address.scale
addu addrTemp, addrTemp, address.base
lui immTemp, (address.offset + 0x8000) >> 16
addu addrTemp, addrTemp, immTemp
lw dest, (address.offset & 0xffff)(at)
*/
m_assembler.sll(addrTempRegister, address.index, address.scale);
m_assembler.addu(addrTempRegister, addrTempRegister, address.base);
m_assembler.lui(immTempRegister, (address.offset + 0x8000) >> 16);
m_assembler.addu(addrTempRegister, addrTempRegister, immTempRegister);
m_assembler.lw(dest, addrTempRegister, address.offset);
}
}
void load16Unaligned(BaseIndex address, RegisterID dest)
{
if (address.offset >= -32768 && address.offset <= 32767 && !m_fixedWidth) {
/*
sll addrtemp, address.index, address.scale
addu addrtemp, addrtemp, address.base
lbu immTemp, address.offset+x(addrtemp) (x=0 for LE, x=1 for BE)
lbu dest, address.offset+x(addrtemp) (x=1 for LE, x=0 for BE)
sll dest, dest, 8
or dest, dest, immTemp
*/
loadAddress(address, LoadAddressMode::Scale);
#if CPU(BIG_ENDIAN)
m_assembler.lbu(immTempRegister, addrTempRegister, address.offset + 1);
m_assembler.lbu(dest, addrTempRegister, address.offset);
#else
m_assembler.lbu(immTempRegister, addrTempRegister, address.offset);
m_assembler.lbu(dest, addrTempRegister, address.offset + 1);
#endif
m_assembler.sll(dest, dest, 8);
m_assembler.orInsn(dest, dest, immTempRegister);
} else {
/*
sll addrTemp, address.index, address.scale
addu addrTemp, addrTemp, address.base
lui immTemp, address.offset >> 16
ori immTemp, immTemp, address.offset & 0xffff
addu addrTemp, addrTemp, immTemp
lbu immTemp, x(addrtemp) (x=0 for LE, x=1 for BE)
lbu dest, x(addrtemp) (x=1 for LE, x=0 for BE)
sll dest, dest, 8
or dest, dest, immTemp
*/
m_assembler.sll(addrTempRegister, address.index, address.scale);
m_assembler.addu(addrTempRegister, addrTempRegister, address.base);
m_assembler.lui(immTempRegister, address.offset >> 16);
m_assembler.ori(immTempRegister, immTempRegister, address.offset);
m_assembler.addu(addrTempRegister, addrTempRegister, immTempRegister);
#if CPU(BIG_ENDIAN)
m_assembler.lbu(immTempRegister, addrTempRegister, 1);
m_assembler.lbu(dest, addrTempRegister, 0);
#else
m_assembler.lbu(immTempRegister, addrTempRegister, 0);
m_assembler.lbu(dest, addrTempRegister, 1);
#endif
m_assembler.sll(dest, dest, 8);
m_assembler.orInsn(dest, dest, immTempRegister);
}
}
void load32WithUnalignedHalfWords(BaseIndex address, RegisterID dest)
{
if (address.offset >= -32768 && address.offset <= 32764
&& !m_fixedWidth) {
/*
sll addrTemp, address.index, address.scale
addu addrTemp, addrTemp, address.base
(Big-Endian)
lwl dest, address.offset(addrTemp)
lwr dest, address.offset+3(addrTemp)
(Little-Endian)
lwl dest, address.offset+3(addrTemp)
lwr dest, address.offset(addrTemp)
*/
loadAddress(address, LoadAddressMode::Scale);
#if CPU(BIG_ENDIAN)
m_assembler.lwl(dest, addrTempRegister, address.offset);
m_assembler.lwr(dest, addrTempRegister, address.offset + 3);
#else
m_assembler.lwl(dest, addrTempRegister, address.offset + 3);
m_assembler.lwr(dest, addrTempRegister, address.offset);
#endif
} else {
/*
sll addrTemp, address.index, address.scale
addu addrTemp, addrTemp, address.base
lui immTemp, address.offset >> 16
ori immTemp, immTemp, address.offset & 0xffff
addu addrTemp, addrTemp, immTemp
(Big-Endian)
lw dest, 0(at)
lw dest, 3(at)
(Little-Endian)
lw dest, 3(at)
lw dest, 0(at)
*/
m_assembler.sll(addrTempRegister, address.index, address.scale);
m_assembler.addu(addrTempRegister, addrTempRegister, address.base);
m_assembler.lui(immTempRegister, address.offset >> 16);
m_assembler.ori(immTempRegister, immTempRegister, address.offset);
m_assembler.addu(addrTempRegister, addrTempRegister, immTempRegister);
#if CPU(BIG_ENDIAN)
m_assembler.lwl(dest, addrTempRegister, 0);
m_assembler.lwr(dest, addrTempRegister, 3);
#else
m_assembler.lwl(dest, addrTempRegister, 3);
m_assembler.lwr(dest, addrTempRegister, 0);
#endif
}
}
void load32(const void* address, RegisterID dest)
{
if (m_fixedWidth) {
/*
li addrTemp, address
lw dest, 0(addrTemp)
*/
move(TrustedImmPtr(address), addrTempRegister);
m_assembler.lw(dest, addrTempRegister, 0);
} else {
uintptr_t adr = reinterpret_cast<uintptr_t>(address);
m_assembler.lui(addrTempRegister, (adr + 0x8000) >> 16);
m_assembler.lw(dest, addrTempRegister, adr & 0xffff);
}
}
void load16(const void* address, RegisterID dest)
{
if (m_fixedWidth) {
/*
li addrTemp, address
lhu dest, 0(addrTemp)
*/
move(TrustedImmPtr(address), addrTempRegister);
m_assembler.lhu(dest, addrTempRegister, 0);
} else {
uintptr_t adr = reinterpret_cast<uintptr_t>(address);
m_assembler.lui(addrTempRegister, (adr + 0x8000) >> 16);
m_assembler.lhu(dest, addrTempRegister, adr & 0xffff);
}
}
/* Need to use zero-extened load half-word for load16. */
void load16(Address address, RegisterID dest)
{
if (address.offset >= -32768 && address.offset <= 32767
&& !m_fixedWidth)
m_assembler.lhu(dest, address.base, address.offset);
else {
/*
lui addrTemp, (offset + 0x8000) >> 16
addu addrTemp, addrTemp, base
lhu dest, (offset & 0xffff)(addrTemp)
*/
m_assembler.lui(addrTempRegister, (address.offset + 0x8000) >> 16);
m_assembler.addu(addrTempRegister, addrTempRegister, address.base);
m_assembler.lhu(dest, addrTempRegister, address.offset);
}
}
/* Need to use zero-extened load half-word for load16. */
void load16(BaseIndex address, RegisterID dest)
{
if (!m_fixedWidth) {
loadAddress(address, LoadAddressMode::ScaleAndAddOffsetIfOffsetIsOutOfBounds);
m_assembler.lhu(dest, addrTempRegister, address.offset);
} else {
/*
sll addrTemp, address.index, address.scale
addu addrTemp, addrTemp, address.base
lui immTemp, (address.offset + 0x8000) >> 16
addu addrTemp, addrTemp, immTemp
lhu dest, (address.offset & 0xffff)(addrTemp)
*/
m_assembler.sll(addrTempRegister, address.index, address.scale);
m_assembler.addu(addrTempRegister, addrTempRegister, address.base);
m_assembler.lui(immTempRegister, (address.offset + 0x8000) >> 16);
m_assembler.addu(addrTempRegister, addrTempRegister, immTempRegister);
m_assembler.lhu(dest, addrTempRegister, address.offset);
}
}
ALWAYS_INLINE void load16(AbsoluteAddress address, RegisterID dest)
{
load16(address.m_ptr, dest);
}
/* Need to use zero-extened load half-word for load16. */
void load16SignedExtendTo32(Address address, RegisterID dest)
{
if (address.offset >= -32768 && address.offset <= 32767
&& !m_fixedWidth)
m_assembler.lh(dest, address.base, address.offset);
else {
/*
lui addrTemp, (offset + 0x8000) >> 16
addu addrTemp, addrTemp, base
lh dest, (offset & 0xffff)(addrTemp)
*/
m_assembler.lui(addrTempRegister, (address.offset + 0x8000) >> 16);
m_assembler.addu(addrTempRegister, addrTempRegister, address.base);
m_assembler.lh(dest, addrTempRegister, address.offset);
}
}
void load16SignedExtendTo32(BaseIndex address, RegisterID dest)
{
if (!m_fixedWidth) {
loadAddress(address, LoadAddressMode::ScaleAndAddOffsetIfOffsetIsOutOfBounds);
m_assembler.lh(dest, addrTempRegister, address.offset);
} else {
/*
sll addrTemp, address.index, address.scale
addu addrTemp, addrTemp, address.base
lui immTemp, (address.offset + 0x8000) >> 16
addu addrTemp, addrTemp, immTemp
lh dest, (address.offset & 0xffff)(addrTemp)
*/
m_assembler.sll(addrTempRegister, address.index, address.scale);
m_assembler.addu(addrTempRegister, addrTempRegister, address.base);
m_assembler.lui(immTempRegister, (address.offset + 0x8000) >> 16);
m_assembler.addu(addrTempRegister, addrTempRegister, immTempRegister);
m_assembler.lh(dest, addrTempRegister, address.offset);
}
}
ALWAYS_INLINE void load16SignedExtendTo32(AbsoluteAddress address, RegisterID dest)
{
load16SignedExtendTo32(address.m_ptr, dest);
}
void load16SignedExtendTo32(const void* address, RegisterID dest)
{
if (m_fixedWidth) {
/*
li addrTemp, address
lh dest, 0(addrTemp)
*/
move(TrustedImmPtr(address), addrTempRegister);
m_assembler.lh(dest, addrTempRegister, 0);
} else {
uintptr_t adr = reinterpret_cast<uintptr_t>(address);
m_assembler.lui(addrTempRegister, (adr + 0x8000) >> 16);
m_assembler.lh(dest, addrTempRegister, adr & 0xffff);
}
}
void loadPair32(RegisterID src, RegisterID dest1, RegisterID dest2)
{
loadPair32(src, TrustedImm32(0), dest1, dest2);
}
void loadPair32(RegisterID src, TrustedImm32 offset, RegisterID dest1, RegisterID dest2)
{
loadPair32(Address(src, offset.m_value), dest1, dest2);
}
void loadPair32(Address address, RegisterID dest1, RegisterID dest2)
{
ASSERT(dest1 != dest2); // If it is the same, ldp becomes illegal instruction.
if (address.base == dest1) {
load32(address.withOffset(4), dest2);
load32(address, dest1);
} else {
load32(address, dest1);
load32(address.withOffset(4), dest2);
}
}
void loadPair32(AbsoluteAddress address, RegisterID dest1, RegisterID dest2)
{
move(TrustedImmPtr(address.m_ptr), addrTempRegister);
loadPair32(addrTempRegister, dest1, dest2);
}
void loadPair32(BaseIndex address, RegisterID dest1, RegisterID dest2)
{
if (address.base == dest1 || address.index == dest1) {
RELEASE_ASSERT(address.base != dest2);
RELEASE_ASSERT(address.index != dest2);
load32(address.withOffset(4), dest2);
load32(address, dest1);
} else {
load32(address, dest1);
load32(address.withOffset(4), dest2);
}
}
void store8(RegisterID src, Address address)
{
if (address.offset >= -32768 && address.offset <= 32767
&& !m_fixedWidth)
m_assembler.sb(src, address.base, address.offset);
else {
/*
lui addrTemp, (offset + 0x8000) >> 16
addu addrTemp, addrTemp, base
sb src, (offset & 0xffff)(addrTemp)
*/
m_assembler.lui(addrTempRegister, (address.offset + 0x8000) >> 16);
m_assembler.addu(addrTempRegister, addrTempRegister, address.base);
m_assembler.sb(src, addrTempRegister, address.offset);
}
}
void store8(RegisterID src, BaseIndex address)
{
if (!m_fixedWidth) {
loadAddress(address, LoadAddressMode::ScaleAndAddOffsetIfOffsetIsOutOfBounds);
m_assembler.sb(src, addrTempRegister, address.offset);
} else {
/*
sll addrTemp, address.index, address.scale
addu addrTemp, addrTemp, address.base
lui immTemp, (address.offset + 0x8000) >> 16
addu addrTemp, addrTemp, immTemp
sb src, (address.offset & 0xffff)(at)
*/
m_assembler.sll(addrTempRegister, address.index, address.scale);
m_assembler.addu(addrTempRegister, addrTempRegister, address.base);
m_assembler.lui(immTempRegister, (address.offset + 0x8000) >> 16);
m_assembler.addu(addrTempRegister, addrTempRegister, immTempRegister);
m_assembler.sb(src, addrTempRegister, address.offset);
}
}
void store8(RegisterID src, const void* address)
{
if (m_fixedWidth) {
/*
li addrTemp, address
sb src, 0(addrTemp)
*/
move(TrustedImmPtr(address), addrTempRegister);
m_assembler.sb(src, addrTempRegister, 0);
} else {
uintptr_t adr = reinterpret_cast<uintptr_t>(address);
m_assembler.lui(addrTempRegister, (adr + 0x8000) >> 16);
m_assembler.sb(src, addrTempRegister, adr & 0xffff);
}
}
void store8(TrustedImm32 imm, void* address)
{
if (m_fixedWidth) {
/*
li immTemp, imm
li addrTemp, address
sb src, 0(addrTemp)
*/
TrustedImm32 imm8(static_cast<int8_t>(imm.m_value));
move(imm8, immTempRegister);
move(TrustedImmPtr(address), addrTempRegister);
m_assembler.sb(immTempRegister, addrTempRegister, 0);
} else {
uintptr_t adr = reinterpret_cast<uintptr_t>(address);
m_assembler.lui(addrTempRegister, (adr + 0x8000) >> 16);
if (!imm.m_value)
m_assembler.sb(MIPSRegisters::zero, addrTempRegister, adr & 0xffff);
else {
TrustedImm32 imm8(static_cast<int8_t>(imm.m_value));
move(imm8, immTempRegister);
m_assembler.sb(immTempRegister, addrTempRegister, adr & 0xffff);
}
}
}
void store8(TrustedImm32 imm, Address address)
{
TrustedImm32 imm8(static_cast<int8_t>(imm.m_value));
if (address.offset >= -32768 && address.offset <= 32767
&& !m_fixedWidth) {
if (!imm8.m_value)
m_assembler.sb(MIPSRegisters::zero, address.base, address.offset);
else {
move(imm8, immTempRegister);
m_assembler.sb(immTempRegister, address.base, address.offset);
}
} else {
/*
lui addrTemp, (offset + 0x8000) >> 16
addu addrTemp, addrTemp, base
sb immTemp, (offset & 0xffff)(addrTemp)
*/
m_assembler.lui(addrTempRegister, (address.offset + 0x8000) >> 16);
m_assembler.addu(addrTempRegister, addrTempRegister, address.base);
if (!imm8.m_value && !m_fixedWidth)
m_assembler.sb(MIPSRegisters::zero, addrTempRegister, address.offset);
else {
move(imm8, immTempRegister);
m_assembler.sb(immTempRegister, addrTempRegister, address.offset);
}
}
}
void store16(RegisterID src, const void* address)
{
if (m_fixedWidth) {
/*
li addrTemp, address
sh src, 0(addrTemp)
*/
move(TrustedImmPtr(address), addrTempRegister);
m_assembler.sh(src, addrTempRegister, 0);
} else {
uintptr_t adr = reinterpret_cast<uintptr_t>(address);
m_assembler.lui(addrTempRegister, (adr + 0x8000) >> 16);
m_assembler.sh(src, addrTempRegister, adr & 0xffff);
}
}
void store16(RegisterID src, Address address)
{
if (address.offset >= -32768 && address.offset <= 32767
&& !m_fixedWidth) {
m_assembler.sh(src, address.base, address.offset);
} else {
/*
lui addrTemp, (offset + 0x8000) >> 16
addu addrTemp, addrTemp, base
sh src, (offset & 0xffff)(addrTemp)
*/
m_assembler.lui(addrTempRegister, (address.offset + 0x8000) >> 16);
m_assembler.addu(addrTempRegister, addrTempRegister, address.base);
m_assembler.sh(src, addrTempRegister, address.offset);
}
}
void store16(RegisterID src, BaseIndex address)
{
if (!m_fixedWidth) {
loadAddress(address, LoadAddressMode::ScaleAndAddOffsetIfOffsetIsOutOfBounds);
m_assembler.sh(src, addrTempRegister, address.offset);
} else {
/*
sll addrTemp, address.index, address.scale
addu addrTemp, addrTemp, address.base
lui immTemp, (address.offset + 0x8000) >> 16
addu addrTemp, addrTemp, immTemp
sh src, (address.offset & 0xffff)(at)
*/
m_assembler.sll(addrTempRegister, address.index, address.scale);
m_assembler.addu(addrTempRegister, addrTempRegister, address.base);
m_assembler.lui(immTempRegister, (address.offset + 0x8000) >> 16);
m_assembler.addu(addrTempRegister, addrTempRegister, immTempRegister);
m_assembler.sh(src, addrTempRegister, address.offset);
}
}
void store32(RegisterID src, Address address)
{
if (address.offset >= -32768 && address.offset <= 32767
&& !m_fixedWidth)
m_assembler.sw(src, address.base, address.offset);
else {
/*
lui addrTemp, (offset + 0x8000) >> 16
addu addrTemp, addrTemp, base
sw src, (offset & 0xffff)(addrTemp)
*/
m_assembler.lui(addrTempRegister, (address.offset + 0x8000) >> 16);
m_assembler.addu(addrTempRegister, addrTempRegister, address.base);
m_assembler.sw(src, addrTempRegister, address.offset);
}
}
void store32(RegisterID src, BaseIndex address)
{
if (!m_fixedWidth) {
loadAddress(address, LoadAddressMode::ScaleAndAddOffsetIfOffsetIsOutOfBounds);
m_assembler.sw(src, addrTempRegister, address.offset);
} else {
/*
sll addrTemp, address.index, address.scale
addu addrTemp, addrTemp, address.base
lui immTemp, (address.offset + 0x8000) >> 16
addu addrTemp, addrTemp, immTemp
sw src, (address.offset & 0xffff)(at)
*/
m_assembler.sll(addrTempRegister, address.index, address.scale);
m_assembler.addu(addrTempRegister, addrTempRegister, address.base);
m_assembler.lui(immTempRegister, (address.offset + 0x8000) >> 16);
m_assembler.addu(addrTempRegister, addrTempRegister, immTempRegister);
m_assembler.sw(src, addrTempRegister, address.offset);
}
}
void store32(TrustedImm32 imm, Address address)
{
if (address.offset >= -32768 && address.offset <= 32767
&& !m_fixedWidth) {
if (!imm.m_value)
m_assembler.sw(MIPSRegisters::zero, address.base, address.offset);
else {
move(imm, immTempRegister);
m_assembler.sw(immTempRegister, address.base, address.offset);
}
} else {
/*
lui addrTemp, (offset + 0x8000) >> 16
addu addrTemp, addrTemp, base
sw immTemp, (offset & 0xffff)(addrTemp)
*/
m_assembler.lui(addrTempRegister, (address.offset + 0x8000) >> 16);
m_assembler.addu(addrTempRegister, addrTempRegister, address.base);
if (!imm.m_value && !m_fixedWidth)
m_assembler.sw(MIPSRegisters::zero, addrTempRegister, address.offset);
else {
move(imm, immTempRegister);
m_assembler.sw(immTempRegister, addrTempRegister, address.offset);
}
}
}
void store32(TrustedImm32 imm, BaseIndex address)
{
if (!m_fixedWidth) {
loadAddress(address, LoadAddressMode::ScaleAndAddOffsetIfOffsetIsOutOfBounds);
if (!imm.m_value)
m_assembler.sw(MIPSRegisters::zero, addrTempRegister, address.offset);
else {
move(imm, immTempRegister);
m_assembler.sw(immTempRegister, addrTempRegister, address.offset);
}
} else {
/*
sll addrTemp, address.index, address.scale
addu addrTemp, addrTemp, address.base
lui immTemp, (address.offset + 0x8000) >> 16
addu addrTemp, addrTemp, immTemp
sw src, (address.offset & 0xffff)(at)
*/
m_assembler.sll(addrTempRegister, address.index, address.scale);
m_assembler.addu(addrTempRegister, addrTempRegister, address.base);
m_assembler.lui(immTempRegister, (address.offset + 0x8000) >> 16);
m_assembler.addu(addrTempRegister, addrTempRegister, immTempRegister);
move(imm, immTempRegister);
m_assembler.sw(immTempRegister, addrTempRegister, address.offset);
}
}
void store32(RegisterID src, const void* address)
{
if (m_fixedWidth) {
/*
li addrTemp, address
sw src, 0(addrTemp)
*/
move(TrustedImmPtr(address), addrTempRegister);
m_assembler.sw(src, addrTempRegister, 0);
} else {
uintptr_t adr = reinterpret_cast<uintptr_t>(address);
m_assembler.lui(addrTempRegister, (adr + 0x8000) >> 16);
m_assembler.sw(src, addrTempRegister, adr & 0xffff);
}
}
void store32(TrustedImm32 imm, const void* address)
{
if (m_fixedWidth) {
/*
li immTemp, imm
li addrTemp, address
sw src, 0(addrTemp)
*/
move(imm, immTempRegister);
move(TrustedImmPtr(address), addrTempRegister);
m_assembler.sw(immTempRegister, addrTempRegister, 0);
} else {
uintptr_t adr = reinterpret_cast<uintptr_t>(address);
m_assembler.lui(addrTempRegister, (adr + 0x8000) >> 16);
if (!imm.m_value)
m_assembler.sw(MIPSRegisters::zero, addrTempRegister, adr & 0xffff);
else {
move(imm, immTempRegister);
m_assembler.sw(immTempRegister, addrTempRegister, adr & 0xffff);
}
}
}
void storePair32(RegisterID src1, TrustedImm32 imm, Address address)
{
move(imm, addrTempRegister);
storePair32(src1, addrTempRegister, address);
}
void storePair32(TrustedImmPtr immPtr, TrustedImm32 imm32, Address address)
{
move(immPtr, addrTempRegister);
move(imm32, dataTempRegister);
storePair32(addrTempRegister, dataTempRegister, address);
}
void storePair32(TrustedImm32 imm1, TrustedImm32 imm2, Address address)
{
move(imm1, addrTempRegister);
RegisterID scratch = addrTempRegister;
if (imm1.m_value != imm2.m_value) {
scratch = dataTempRegister;
move(imm2, scratch);
}
storePair32(addrTempRegister, scratch, address);
}
void storePair32(RegisterID src1, RegisterID src2, RegisterID dest)
{
storePair32(src1, src2, dest, TrustedImm32(0));
}
void storePair32(RegisterID src1, RegisterID src2, RegisterID dest, TrustedImm32 offset)
{
storePair32(src1, src2, Address(dest, offset.m_value));
}
void storePair32(RegisterID src1, RegisterID src2, Address address)
{
store32(src1, address);
store32(src2, address.withOffset(4));
}
void storePair32(RegisterID src1, RegisterID src2, BaseIndex address)
{
store32(src1, address);
store32(src2, address.withOffset(4));
}
void storePair32(TrustedImm32 imm1, TrustedImm32 imm2, BaseIndex address)
{
store32(imm1, address);
store32(imm2, address.withOffset(4));
}
void storePair32(RegisterID src1, TrustedImm32 imm, const void* address)
{
move(TrustedImmPtr(address), addrTempRegister);
move(imm, dataTempRegister);
storePair32(src1, dataTempRegister, addrTempRegister);
}
void storePair32(RegisterID src1, RegisterID src2, const void* address)
{
move(TrustedImmPtr(address), addrTempRegister);
storePair32(src1, src2, addrTempRegister);
}
// Floating-point operations:
static bool supportsFloatingPoint()
{
#if WTF_MIPS_DOUBLE_FLOAT
return true;
#else
return false;
#endif
}
static bool supportsFloatingPointTruncate()
{
#if WTF_MIPS_DOUBLE_FLOAT && WTF_MIPS_ISA_AT_LEAST(2)
return true;
#else
return false;
#endif
}
static bool supportsFloatingPointSqrt()
{
#if WTF_MIPS_DOUBLE_FLOAT && WTF_MIPS_ISA_AT_LEAST(2)
return true;
#else
return false;
#endif
}
static bool supportsFloatingPointAbs()
{
#if WTF_MIPS_DOUBLE_FLOAT && WTF_MIPS_ISA_AT_LEAST(2)
return true;
#else
return false;
#endif
}
static bool supportsFloatingPointRounding() { return false; }
// 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.lw(dest, MIPSRegisters::sp, 0);
m_assembler.addiu(MIPSRegisters::sp, MIPSRegisters::sp, 4);
}
void popPair(RegisterID dest1, RegisterID dest2)
{
m_assembler.lw(dest1, MIPSRegisters::sp, 0);
m_assembler.lw(dest2, MIPSRegisters::sp, 4);
m_assembler.addiu(MIPSRegisters::sp, MIPSRegisters::sp, 8);
}
void push(RegisterID src)
{
m_assembler.addiu(MIPSRegisters::sp, MIPSRegisters::sp, -4);
m_assembler.sw(src, MIPSRegisters::sp, 0);
}
void push(Address address)
{
load32(address, dataTempRegister);
push(dataTempRegister);
}
void push(TrustedImm32 imm)
{
move(imm, immTempRegister);
push(immTempRegister);
}
void pushPair(RegisterID src1, RegisterID src2)
{
m_assembler.addiu(MIPSRegisters::sp, MIPSRegisters::sp, -8);
m_assembler.sw(src2, MIPSRegisters::sp, 4);
m_assembler.sw(src1, MIPSRegisters::sp, 0);
}
// Register move operations:
//
// Move values in registers.
void move(TrustedImm32 imm, RegisterID dest)
{
if (!imm.m_value && !m_fixedWidth)
move(MIPSRegisters::zero, dest);
else if (m_fixedWidth) {
m_assembler.lui(dest, imm.m_value >> 16);
m_assembler.ori(dest, dest, imm.m_value);
} else
m_assembler.li(dest, imm.m_value);
}
void move(RegisterID src, RegisterID dest)
{
if (src != dest || m_fixedWidth)
m_assembler.move(dest, src);
}
void move(TrustedImmPtr imm, RegisterID dest)
{
move(TrustedImm32(imm), dest);
}
void swap(RegisterID reg1, RegisterID reg2)
{
move(reg1, immTempRegister);
move(reg2, reg1);
move(immTempRegister, reg2);
}
void signExtend32ToPtr(RegisterID src, RegisterID dest)
{
if (src != dest || m_fixedWidth)
move(src, dest);
}
void zeroExtend32ToWord(RegisterID src, RegisterID dest)
{
if (src != dest || m_fixedWidth)
move(src, dest);
}
// 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.
Jump branch8(RelationalCondition cond, Address left, TrustedImm32 right)
{
TrustedImm32 right8 = MacroAssemblerHelpers::mask8OnCondition(*this, cond, right);
MacroAssemblerHelpers::load8OnCondition(*this, cond, left, dataTempRegister);
return branch32(cond, dataTempRegister, right8);
}
Jump branch8(RelationalCondition cond, AbsoluteAddress left, TrustedImm32 right)
{
TrustedImm32 right8 = MacroAssemblerHelpers::mask8OnCondition(*this, cond, right);
MacroAssemblerHelpers::load8OnCondition(*this, cond, left, dataTempRegister);
return branch32(cond, dataTempRegister, right8);
}
void compare8(RelationalCondition cond, Address left, TrustedImm32 right, RegisterID dest)
{
TrustedImm32 right8 = MacroAssemblerHelpers::mask8OnCondition(*this, cond, right);
MacroAssemblerHelpers::load8OnCondition(*this, cond, left, dataTempRegister);
compare32(cond, dataTempRegister, right8, dest);
}
Jump branch8(RelationalCondition cond, BaseIndex left, TrustedImm32 right)
{
TrustedImm32 right8 = MacroAssemblerHelpers::mask8OnCondition(*this, cond, right);
MacroAssemblerHelpers::load8OnCondition(*this, cond, left, dataTempRegister);
return branch32(cond, dataTempRegister, right8);
}
Jump branchPtr(RelationalCondition cond, BaseIndex left, RegisterID right)
{
load32(left, dataTempRegister);
return branch32(cond, dataTempRegister, right);
}
Jump branch32(RelationalCondition cond, RegisterID left, RegisterID right)
{
if (cond == Equal)
return branchEqual(left, right);
if (cond == NotEqual)
return branchNotEqual(left, right);
if (cond == Above) {
m_assembler.sltu(cmpTempRegister, right, left);
return branchNotEqual(cmpTempRegister, MIPSRegisters::zero);
}
if (cond == AboveOrEqual) {
m_assembler.sltu(cmpTempRegister, left, right);
return branchEqual(cmpTempRegister, MIPSRegisters::zero);
}
if (cond == Below) {
m_assembler.sltu(cmpTempRegister, left, right);
return branchNotEqual(cmpTempRegister, MIPSRegisters::zero);
}
if (cond == BelowOrEqual) {
m_assembler.sltu(cmpTempRegister, right, left);
return branchEqual(cmpTempRegister, MIPSRegisters::zero);
}
if (cond == GreaterThan) {
m_assembler.slt(cmpTempRegister, right, left);
return branchNotEqual(cmpTempRegister, MIPSRegisters::zero);
}
if (cond == GreaterThanOrEqual) {
m_assembler.slt(cmpTempRegister, left, right);
return branchEqual(cmpTempRegister, MIPSRegisters::zero);
}
if (cond == LessThan) {
m_assembler.slt(cmpTempRegister, left, right);
return branchNotEqual(cmpTempRegister, MIPSRegisters::zero);
}
if (cond == LessThanOrEqual) {
m_assembler.slt(cmpTempRegister, right, left);
return branchEqual(cmpTempRegister, MIPSRegisters::zero);
}
ASSERT(0);
return Jump();
}
Jump branch32(RelationalCondition cond, RegisterID left, TrustedImm32 right)
{
if (!m_fixedWidth) {
if (!right.m_value)
return branch32(cond, left, MIPSRegisters::zero);
if (right.m_value >= -32768 && right.m_value <= 32767) {
if (cond == AboveOrEqual) {
m_assembler.sltiu(cmpTempRegister, left, right.m_value);
return branchEqual(cmpTempRegister, MIPSRegisters::zero);
}
if (cond == Below) {
m_assembler.sltiu(cmpTempRegister, left, right.m_value);
return branchNotEqual(cmpTempRegister, MIPSRegisters::zero);
}
if (cond == GreaterThanOrEqual) {
m_assembler.slti(cmpTempRegister, left, right.m_value);
return branchEqual(cmpTempRegister, MIPSRegisters::zero);
}
if (cond == LessThan) {
m_assembler.slti(cmpTempRegister, left, right.m_value);
return branchNotEqual(cmpTempRegister, MIPSRegisters::zero);
}
}
}
move(right, immTempRegister);
return branch32(cond, left, immTempRegister);
}
Jump branch32(RelationalCondition cond, RegisterID left, Address right)
{
load32(right, dataTempRegister);
return branch32(cond, left, dataTempRegister);
}
Jump branch32(RelationalCondition cond, Address left, RegisterID right)
{
load32(left, dataTempRegister);
return branch32(cond, dataTempRegister, right);
}
Jump branch32(RelationalCondition cond, Address left, TrustedImm32 right)
{
load32(left, dataTempRegister);
return branch32(cond, dataTempRegister, right);
}
Jump branch32(RelationalCondition cond, BaseIndex left, TrustedImm32 right)
{
load32(left, dataTempRegister);
return branch32(cond, dataTempRegister, right);
}
Jump branch32WithUnalignedHalfWords(RelationalCondition cond, BaseIndex left, TrustedImm32 right)
{
load32WithUnalignedHalfWords(left, dataTempRegister);
return branch32(cond, dataTempRegister, right);
}
Jump branch32(RelationalCondition cond, AbsoluteAddress left, RegisterID right)
{
load32(left.m_ptr, dataTempRegister);
return branch32(cond, dataTempRegister, right);
}
Jump branch32(RelationalCondition cond, AbsoluteAddress left, TrustedImm32 right)
{
load32(left.m_ptr, dataTempRegister);
return branch32(cond, dataTempRegister, right);
}
Jump branchTest32(ResultCondition cond, RegisterID reg, RegisterID mask)
{
ASSERT((cond == Zero) || (cond == NonZero) || (cond == Signed));
m_assembler.andInsn(cmpTempRegister, reg, mask);
switch (cond) {
case Zero:
return branchEqual(cmpTempRegister, MIPSRegisters::zero);
case NonZero:
return branchNotEqual(cmpTempRegister, MIPSRegisters::zero);
case Signed:
m_assembler.slt(cmpTempRegister, cmpTempRegister, MIPSRegisters::zero);
return branchNotEqual(cmpTempRegister, MIPSRegisters::zero);
default:
RELEASE_ASSERT_NOT_REACHED();
}
}
Jump branchTest32(ResultCondition cond, RegisterID reg, TrustedImm32 mask = TrustedImm32(-1))
{
ASSERT((cond == Zero) || (cond == NonZero) || (cond == Signed));
if (!m_fixedWidth) {
if (mask.m_value == -1) {
switch (cond) {
case Zero:
return branchEqual(reg, MIPSRegisters::zero);
case NonZero:
return branchNotEqual(reg, MIPSRegisters::zero);
case Signed:
m_assembler.slt(cmpTempRegister, reg, MIPSRegisters::zero);
return branchNotEqual(cmpTempRegister, MIPSRegisters::zero);
default:
RELEASE_ASSERT_NOT_REACHED();
}
}
#if WTF_MIPS_ISA_REV(2)
if (isPowerOf2(mask.m_value)) {
uint16_t pos= bitPosition(mask.m_value);
m_assembler.ext(cmpTempRegister, reg, pos, 1);
switch (cond) {
case Zero:
return branchEqual(cmpTempRegister, MIPSRegisters::zero);
case NonZero:
return branchNotEqual(cmpTempRegister, MIPSRegisters::zero);
case Signed:
m_assembler.slt(cmpTempRegister, cmpTempRegister, MIPSRegisters::zero);
return branchNotEqual(cmpTempRegister, MIPSRegisters::zero);
default:
RELEASE_ASSERT_NOT_REACHED();
}
}
#endif
if (mask.m_value >= 0 && mask.m_value <= 65535) {
m_assembler.andi(cmpTempRegister, reg, mask.m_value);
switch (cond) {
case Zero:
return branchEqual(cmpTempRegister, MIPSRegisters::zero);
case NonZero:
return branchNotEqual(cmpTempRegister, MIPSRegisters::zero);
case Signed:
m_assembler.slt(cmpTempRegister, cmpTempRegister, MIPSRegisters::zero);
return branchNotEqual(cmpTempRegister, MIPSRegisters::zero);
default:
RELEASE_ASSERT_NOT_REACHED();
}
}
}
move(mask, immTempRegister);
return branchTest32(cond, reg, immTempRegister);
}
Jump branchTest32(ResultCondition cond, Address address, TrustedImm32 mask = TrustedImm32(-1))
{
load32(address, dataTempRegister);
return branchTest32(cond, dataTempRegister, mask);
}
Jump branchTest32(ResultCondition cond, BaseIndex address, TrustedImm32 mask = TrustedImm32(-1))
{
load32(address, dataTempRegister);
return branchTest32(cond, dataTempRegister, mask);
}
Jump branchTest32(ResultCondition cond, AbsoluteAddress address, TrustedImm32 mask = TrustedImm32(-1))
{
load32(address.m_ptr, dataTempRegister);
return branchTest32(cond, dataTempRegister, mask);
}
TrustedImm32 mask8OnTest(ResultCondition cond, TrustedImm32 mask)
{
if (mask.m_value == -1 && !m_fixedWidth)
return TrustedImm32(-1);
return MacroAssemblerHelpers::mask8OnCondition(*this, cond, mask);
}
Jump branchTest8(ResultCondition cond, BaseIndex address, TrustedImm32 mask = TrustedImm32(-1))
{
TrustedImm32 mask8 = mask8OnTest(cond, mask);
MacroAssemblerHelpers::load8OnCondition(*this, cond, address, dataTempRegister);
return branchTest32(cond, dataTempRegister, mask8);
}
Jump branchTest8(ResultCondition cond, Address address, TrustedImm32 mask = TrustedImm32(-1))
{
TrustedImm32 mask8 = mask8OnTest(cond, mask);
MacroAssemblerHelpers::load8OnCondition(*this, cond, address, dataTempRegister);
return branchTest32(cond, dataTempRegister, mask8);
}
Jump branchTest8(ResultCondition cond, AbsoluteAddress address, TrustedImm32 mask = TrustedImm32(-1))
{
TrustedImm32 mask8 = mask8OnTest(cond, mask);
MacroAssemblerHelpers::load8OnCondition(*this, cond, address, dataTempRegister);
return branchTest32(cond, dataTempRegister, mask8);
}
TrustedImm32 mask16OnTest(ResultCondition cond, TrustedImm32 mask)
{
if (mask.m_value == -1 && !m_fixedWidth)
return TrustedImm32(-1);
return MacroAssemblerHelpers::mask16OnCondition(*this, cond, mask);
}
Jump branchTest16(ResultCondition cond, BaseIndex address, TrustedImm32 mask = TrustedImm32(-1))
{
TrustedImm32 mask16 = mask16OnTest(cond, mask);
MacroAssemblerHelpers::load16OnCondition(*this, cond, address, dataTempRegister);
return branchTest32(cond, dataTempRegister, mask16);
}
Jump branchTest16(ResultCondition cond, Address address, TrustedImm32 mask = TrustedImm32(-1))
{
TrustedImm32 mask16 = mask16OnTest(cond, mask);
MacroAssemblerHelpers::load16OnCondition(*this, cond, address, dataTempRegister);
return branchTest32(cond, dataTempRegister, mask16);
}
Jump branchTest16(ResultCondition cond, AbsoluteAddress address, TrustedImm32 mask = TrustedImm32(-1))
{
TrustedImm32 mask16 = mask16OnTest(cond, mask);
MacroAssemblerHelpers::load16OnCondition(*this, cond, address, dataTempRegister);
return branchTest32(cond, dataTempRegister, mask16);
}
Jump jump()
{
return branchEqual(MIPSRegisters::zero, MIPSRegisters::zero);
}
void farJump(RegisterID target, PtrTag)
{
move(target, MIPSRegisters::t9);
m_assembler.jr(MIPSRegisters::t9);
m_assembler.nop();
}
void farJump(TrustedImmPtr target, PtrTag)
{
move(target, MIPSRegisters::t9);
m_assembler.jr(MIPSRegisters::t9);
m_assembler.nop();
}
void farJump(Address address, PtrTag)
{
m_fixedWidth = true;
load32(address, MIPSRegisters::t9);
m_assembler.jr(MIPSRegisters::t9);
m_assembler.nop();
m_fixedWidth = false;
}
void farJump(AbsoluteAddress address, PtrTag)
{
m_fixedWidth = true;
load32(address.m_ptr, MIPSRegisters::t9);
m_assembler.jr(MIPSRegisters::t9);
m_assembler.nop();
m_fixedWidth = false;
}
ALWAYS_INLINE void farJump(RegisterID target, RegisterID jumpTag) { UNUSED_PARAM(jumpTag), farJump(target, NoPtrTag); }
ALWAYS_INLINE void farJump(Address address, RegisterID jumpTag) { UNUSED_PARAM(jumpTag), farJump(address, NoPtrTag); }
ALWAYS_INLINE void farJump(AbsoluteAddress address, RegisterID jumpTag) { UNUSED_PARAM(jumpTag), farJump(address, NoPtrTag); }
void moveDoubleToInts(FPRegisterID src, RegisterID dest1, RegisterID dest2)
{
m_assembler.vmov(dest1, dest2, src);
}
void moveIntsToDouble(RegisterID src1, RegisterID src2, FPRegisterID dest)
{
m_assembler.vmov(dest, src1, src2);
}
// 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)
{
ASSERT((cond == Overflow) || (cond == Signed) || (cond == PositiveOrZero) || (cond == Zero) || (cond == NonZero));
if (cond == Overflow) {
/*
move dest, dataTemp
xor cmpTemp, dataTemp, src
bltz cmpTemp, No_overflow # diff sign bit -> no overflow
addu dest, dataTemp, src
xor cmpTemp, dest, dataTemp
bgez cmpTemp, No_overflow # same sign big -> no overflow
nop
b Overflow
nop
b No_overflow
nop
nop
nop
No_overflow:
*/
move(dest, dataTempRegister);
m_assembler.xorInsn(cmpTempRegister, dataTempRegister, src);
m_assembler.bltz(cmpTempRegister, 10);
m_assembler.addu(dest, dataTempRegister, src);
m_assembler.xorInsn(cmpTempRegister, dest, dataTempRegister);
m_assembler.bgez(cmpTempRegister, 7);
m_assembler.nop();
return jump();
}
if (cond == Signed) {
add32(src, dest);
// Check if dest is negative.
m_assembler.slt(cmpTempRegister, dest, MIPSRegisters::zero);
return branchNotEqual(cmpTempRegister, MIPSRegisters::zero);
}
if (cond == PositiveOrZero) {
add32(src, dest);
// Check if dest is not negative.
m_assembler.slt(cmpTempRegister, dest, MIPSRegisters::zero);
return branchEqual(cmpTempRegister, MIPSRegisters::zero);
}
if (cond == Zero) {
add32(src, dest);
return branchEqual(dest, MIPSRegisters::zero);
}
if (cond == NonZero) {
add32(src, dest);
return branchNotEqual(dest, MIPSRegisters::zero);
}
ASSERT(0);
return Jump();
}
Jump branchAdd32(ResultCondition cond, RegisterID op1, RegisterID op2, RegisterID dest)
{
ASSERT((cond == Overflow) || (cond == Signed) || (cond == PositiveOrZero) || (cond == Zero) || (cond == NonZero));
if (cond == Overflow) {
/*
move dataTemp, op1
xor cmpTemp, dataTemp, op2
bltz cmpTemp, No_overflow # diff sign bit -> no overflow
addu dest, dataTemp, op2
xor cmpTemp, dest, dataTemp
bgez cmpTemp, No_overflow # same sign big -> no overflow
nop
b Overflow
nop
b No_overflow
nop
nop
nop
No_overflow:
*/
move(op1, dataTempRegister);
m_assembler.xorInsn(cmpTempRegister, dataTempRegister, op2);
m_assembler.bltz(cmpTempRegister, 10);
m_assembler.addu(dest, dataTempRegister, op2);
m_assembler.xorInsn(cmpTempRegister, dest, dataTempRegister);
m_assembler.bgez(cmpTempRegister, 7);
m_assembler.nop();
return jump();
}
if (cond == Signed) {
add32(op1, op2, dest);
// Check if dest is negative.
m_assembler.slt(cmpTempRegister, dest, MIPSRegisters::zero);
return branchNotEqual(cmpTempRegister, MIPSRegisters::zero);
}
if (cond == PositiveOrZero) {
add32(op1, op2, dest);
// Check if dest is not negative.
m_assembler.slt(cmpTempRegister, dest, MIPSRegisters::zero);
return branchEqual(cmpTempRegister, MIPSRegisters::zero);
}
if (cond == Zero) {
add32(op1, op2, dest);
return branchEqual(dest, MIPSRegisters::zero);
}
if (cond == NonZero) {
add32(op1, op2, dest);
return branchNotEqual(dest, MIPSRegisters::zero);
}
ASSERT(0);
return Jump();
}
Jump branchAdd32(ResultCondition cond, TrustedImm32 imm, RegisterID dest)
{
return branchAdd32(cond, dest, imm, dest);
}
Jump branchAdd32(ResultCondition cond, Address address, RegisterID dest)
{
load32(address, immTempRegister);
return branchAdd32(cond, immTempRegister, dest);
}
Jump branchAdd32(ResultCondition cond, RegisterID src, TrustedImm32 imm, RegisterID dest)
{
if (imm.m_value >= -32768 && imm.m_value <= 32767 && !m_fixedWidth) {
ASSERT((cond == Overflow) || (cond == Signed) || (cond == PositiveOrZero) || (cond == Zero) || (cond == NonZero));
if (cond == Overflow) {
if (imm.m_value >= 0) {
m_assembler.bltz(src, 9);
m_assembler.addiu(dest, src, imm.m_value);
m_assembler.bgez(dest, 7);
m_assembler.nop();
} else {
m_assembler.bgez(src, 9);
m_assembler.addiu(dest, src, imm.m_value);
m_assembler.bltz(dest, 7);
m_assembler.nop();
}
return jump();
}
m_assembler.addiu(dest, src, imm.m_value);
if (cond == Signed) {
// Check if dest is negative.
m_assembler.slt(cmpTempRegister, dest, MIPSRegisters::zero);
return branchNotEqual(cmpTempRegister, MIPSRegisters::zero);
}
if (cond == PositiveOrZero) {
// Check if dest is not negative.
m_assembler.slt(cmpTempRegister, dest, MIPSRegisters::zero);
return branchEqual(cmpTempRegister, MIPSRegisters::zero);
}
if (cond == Zero)
return branchEqual(dest, MIPSRegisters::zero);
if (cond == NonZero)
return branchNotEqual(dest, MIPSRegisters::zero);
ASSERT_NOT_REACHED();
return Jump();
}
move(imm, immTempRegister);
return branchAdd32(cond, src, immTempRegister, dest);
}
Jump branchAdd32(ResultCondition cond, TrustedImm32 imm, AbsoluteAddress dest)
{
ASSERT((cond == Overflow) || (cond == Signed) || (cond == PositiveOrZero) || (cond == Zero) || (cond == NonZero));
if (cond == Overflow) {
if (m_fixedWidth) {
/*
load dest, dataTemp
move imm, immTemp
xor cmpTemp, dataTemp, immTemp
addu dataTemp, dataTemp, immTemp
store dataTemp, dest
bltz cmpTemp, No_overflow # diff sign bit -> no overflow
xor cmpTemp, dataTemp, immTemp
bgez cmpTemp, No_overflow # same sign big -> no overflow
nop
b Overflow
nop
b No_overflow
nop
nop
nop
No_overflow:
*/
load32(dest.m_ptr, dataTempRegister);
move(imm, immTempRegister);
m_assembler.xorInsn(cmpTempRegister, dataTempRegister, immTempRegister);
m_assembler.addu(dataTempRegister, dataTempRegister, immTempRegister);
store32(dataTempRegister, dest.m_ptr);
m_assembler.bltz(cmpTempRegister, 9);
m_assembler.xorInsn(cmpTempRegister, dataTempRegister, immTempRegister);
m_assembler.bgez(cmpTempRegister, 7);
m_assembler.nop();
} else {
uintptr_t adr = reinterpret_cast<uintptr_t>(dest.m_ptr);
m_assembler.lui(addrTempRegister, (adr + 0x8000) >> 16);
m_assembler.lw(dataTempRegister, addrTempRegister, adr & 0xffff);
if (imm.m_value >= 0 && imm.m_value <= 32767) {
move(dataTempRegister, cmpTempRegister);
m_assembler.addiu(dataTempRegister, dataTempRegister, imm.m_value);
m_assembler.bltz(cmpTempRegister, 9);
m_assembler.sw(dataTempRegister, addrTempRegister, adr & 0xffff);
m_assembler.bgez(dataTempRegister, 7);
m_assembler.nop();
} else if (imm.m_value >= -32768 && imm.m_value < 0) {
move(dataTempRegister, cmpTempRegister);
m_assembler.addiu(dataTempRegister, dataTempRegister, imm.m_value);
m_assembler.bgez(cmpTempRegister, 9);
m_assembler.sw(dataTempRegister, addrTempRegister, adr & 0xffff);
m_assembler.bltz(cmpTempRegister, 7);
m_assembler.nop();
} else {
move(imm, immTempRegister);
m_assembler.xorInsn(cmpTempRegister, dataTempRegister, immTempRegister);
m_assembler.addu(dataTempRegister, dataTempRegister, immTempRegister);
m_assembler.bltz(cmpTempRegister, 10);
m_assembler.sw(dataTempRegister, addrTempRegister, adr & 0xffff);
m_assembler.xorInsn(cmpTempRegister, dataTempRegister, immTempRegister);
m_assembler.bgez(cmpTempRegister, 7);
m_assembler.nop();
}
}
return jump();
}
if (m_fixedWidth) {
move(imm, immTempRegister);
load32(dest.m_ptr, dataTempRegister);
add32(immTempRegister, dataTempRegister);
store32(dataTempRegister, dest.m_ptr);
} else {
uintptr_t adr = reinterpret_cast<uintptr_t>(dest.m_ptr);
m_assembler.lui(addrTempRegister, (adr + 0x8000) >> 16);
m_assembler.lw(dataTempRegister, addrTempRegister, adr & 0xffff);
add32(imm, dataTempRegister);
m_assembler.sw(dataTempRegister, addrTempRegister, adr & 0xffff);
}
if (cond == Signed) {
// Check if dest is negative.
m_assembler.slt(cmpTempRegister, dataTempRegister, MIPSRegisters::zero);
return branchNotEqual(cmpTempRegister, MIPSRegisters::zero);
}
if (cond == PositiveOrZero) {
// Check if dest is not negative.
m_assembler.slt(cmpTempRegister, dataTempRegister, MIPSRegisters::zero);
return branchEqual(cmpTempRegister, MIPSRegisters::zero);
}
if (cond == Zero)
return branchEqual(dataTempRegister, MIPSRegisters::zero);
if (cond == NonZero)
return branchNotEqual(dataTempRegister, MIPSRegisters::zero);
ASSERT(0);
return Jump();
}
Jump branchAdd32(ResultCondition cond, TrustedImm32 imm, Address dest)
{
ASSERT((cond == Overflow) || (cond == Signed) || (cond == PositiveOrZero) || (cond == Zero) || (cond == NonZero));
if (cond == Overflow) {
if (m_fixedWidth) {
/*
load dest, dataTemp
move imm, immTemp
xor cmpTemp, dataTemp, immTemp
addu dataTemp, dataTemp, immTemp
store dataTemp, dest
bltz cmpTemp, No_overflow # diff sign bit -> no overflow
xor cmpTemp, dataTemp, immTemp
bgez cmpTemp, No_overflow # same sign big -> no overflow
nop
b Overflow
nop
b No_overflow
nop
nop
nop
No_overflow:
*/
load32(dest, dataTempRegister);
move(imm, immTempRegister);
m_assembler.xorInsn(cmpTempRegister, dataTempRegister, immTempRegister);
m_assembler.addu(dataTempRegister, dataTempRegister, immTempRegister);
store32(dataTempRegister, dest);
m_assembler.bltz(cmpTempRegister, 9);
m_assembler.xorInsn(cmpTempRegister, dataTempRegister, immTempRegister);
m_assembler.bgez(cmpTempRegister, 7);
m_assembler.nop();
} else {
m_assembler.lw(dataTempRegister, dest.base, dest.offset);
if (imm.m_value >= 0 && imm.m_value <= 32767) {
move(dataTempRegister, cmpTempRegister);
m_assembler.addiu(dataTempRegister, dataTempRegister, imm.m_value);
m_assembler.bltz(cmpTempRegister, 9);
m_assembler.sw(dataTempRegister, dest.base, dest.offset);
m_assembler.bgez(dataTempRegister, 7);
m_assembler.nop();
} else if (imm.m_value >= -32768 && imm.m_value < 0) {
move(dataTempRegister, cmpTempRegister);
m_assembler.addiu(dataTempRegister, dataTempRegister, imm.m_value);
m_assembler.bgez(cmpTempRegister, 9);
m_assembler.sw(dataTempRegister, dest.base, dest.offset);
m_assembler.bltz(cmpTempRegister, 7);
m_assembler.nop();
} else {
move(imm, immTempRegister);
m_assembler.xorInsn(cmpTempRegister, dataTempRegister, immTempRegister);
m_assembler.addu(dataTempRegister, dataTempRegister, immTempRegister);
m_assembler.bltz(cmpTempRegister, 10);
m_assembler.sw(dataTempRegister, dest.base, dest.offset);
m_assembler.xorInsn(cmpTempRegister, dataTempRegister, immTempRegister);
m_assembler.bgez(cmpTempRegister, 7);
m_assembler.nop();
}
}
return jump();
}
if (m_fixedWidth) {
move(imm, immTempRegister);
load32(dest, dataTempRegister);
add32(immTempRegister, dataTempRegister);
store32(dataTempRegister, dest);
} else {
m_assembler.lw(dataTempRegister, dest.base, dest.offset);
add32(imm, dataTempRegister);
m_assembler.sw(dataTempRegister, dest.base, dest.offset);
}
if (cond == Signed) {
// Check if dest is negative.
m_assembler.slt(cmpTempRegister, dataTempRegister, MIPSRegisters::zero);
return branchNotEqual(cmpTempRegister, MIPSRegisters::zero);
}
if (cond == PositiveOrZero) {
// Check if dest is not negative.
m_assembler.slt(cmpTempRegister, dataTempRegister, MIPSRegisters::zero);
return branchEqual(cmpTempRegister, MIPSRegisters::zero);
}
if (cond == Zero)
return branchEqual(dataTempRegister, MIPSRegisters::zero);
if (cond == NonZero)
return branchNotEqual(dataTempRegister, MIPSRegisters::zero);
ASSERT(0);
return Jump();
}
Jump branchMul32(ResultCondition cond, RegisterID src1, RegisterID src2, RegisterID dest)
{
ASSERT((cond == Overflow) || (cond == Signed) || (cond == Zero) || (cond == NonZero));
if (cond == Overflow) {
/*
mult src, dest
mfhi dataTemp
mflo dest
sra addrTemp, dest, 31
beq dataTemp, addrTemp, No_overflow # all sign bits (bit 63 to bit 31) are the same -> no overflow
nop
b Overflow
nop
b No_overflow
nop
nop
nop
No_overflow:
*/
m_assembler.mult(src1, src2);
m_assembler.mfhi(dataTempRegister);
m_assembler.mflo(dest);
m_assembler.sra(addrTempRegister, dest, 31);
m_assembler.beq(dataTempRegister, addrTempRegister, 7);
m_assembler.nop();
return jump();
}
if (cond == Signed) {
mul32(src1, src2, dest);
// Check if dest is negative.
m_assembler.slt(cmpTempRegister, dest, MIPSRegisters::zero);
return branchNotEqual(cmpTempRegister, MIPSRegisters::zero);
}
if (cond == Zero) {
mul32(src1, src2, dest);
return branchEqual(dest, MIPSRegisters::zero);
}
if (cond == NonZero) {
mul32(src1, src2, dest);
return branchNotEqual(dest, MIPSRegisters::zero);
}
ASSERT(0);
return Jump();
}
Jump branchMul32(ResultCondition cond, RegisterID src, RegisterID dest)
{
ASSERT((cond == Overflow) || (cond == Signed) || (cond == Zero) || (cond == NonZero));
if (cond == Overflow) {
/*
mult src, dest
mfhi dataTemp
mflo dest
sra addrTemp, dest, 31
beq dataTemp, addrTemp, No_overflow # all sign bits (bit 63 to bit 31) are the same -> no overflow
nop
b Overflow
nop
b No_overflow
nop
nop
nop
No_overflow:
*/
m_assembler.mult(src, dest);
m_assembler.mfhi(dataTempRegister);
m_assembler.mflo(dest);
m_assembler.sra(addrTempRegister, dest, 31);
m_assembler.beq(dataTempRegister, addrTempRegister, 7);
m_assembler.nop();
return jump();
}
if (cond == Signed) {
mul32(src, dest);
// Check if dest is negative.
m_assembler.slt(cmpTempRegister, dest, MIPSRegisters::zero);
return branchNotEqual(cmpTempRegister, MIPSRegisters::zero);
}
if (cond == Zero) {
mul32(src, dest);
return branchEqual(dest, MIPSRegisters::zero);
}
if (cond == NonZero) {
mul32(src, dest);
return branchNotEqual(dest, MIPSRegisters::zero);
}
ASSERT(0);
return Jump();
}
Jump branchMul32(ResultCondition cond, RegisterID src, TrustedImm32 imm, RegisterID dest)
{
move(imm, immTempRegister);
return branchMul32(cond, immTempRegister, src, dest);
}
Jump branchSub32(ResultCondition cond, RegisterID src, RegisterID dest)
{
ASSERT((cond == Overflow) || (cond == Signed) || (cond == Zero) || (cond == NonZero));
if (cond == Overflow) {
/*
move dest, dataTemp
xor cmpTemp, dataTemp, src
bgez cmpTemp, No_overflow # same sign bit -> no overflow
subu dest, dataTemp, src
xor cmpTemp, dest, dataTemp
bgez cmpTemp, No_overflow # same sign bit -> no overflow
nop
b Overflow
nop
b No_overflow
nop
nop
nop
No_overflow:
*/
move(dest, dataTempRegister);
m_assembler.xorInsn(cmpTempRegister, dataTempRegister, src);
m_assembler.bgez(cmpTempRegister, 10);
m_assembler.subu(dest, dataTempRegister, src);
m_assembler.xorInsn(cmpTempRegister, dest, dataTempRegister);
m_assembler.bgez(cmpTempRegister, 7);
m_assembler.nop();
return jump();
}
if (cond == Signed) {
sub32(src, dest);
// Check if dest is negative.
m_assembler.slt(cmpTempRegister, dest, MIPSRegisters::zero);
return branchNotEqual(cmpTempRegister, MIPSRegisters::zero);
}
if (cond == Zero) {
sub32(src, dest);
return branchEqual(dest, MIPSRegisters::zero);
}
if (cond == NonZero) {
sub32(src, dest);
return branchNotEqual(dest, MIPSRegisters::zero);
}
ASSERT(0);
return Jump();
}
Jump branchSub32(ResultCondition cond, TrustedImm32 imm, RegisterID dest)
{
move(imm, immTempRegister);
return branchSub32(cond, immTempRegister, dest);
}
Jump branchSub32(ResultCondition cond, RegisterID src, TrustedImm32 imm, RegisterID dest)
{
move(imm, immTempRegister);
return branchSub32(cond, src, immTempRegister, dest);
}
Jump branchSub32(ResultCondition cond, RegisterID op1, RegisterID op2, RegisterID dest)
{
ASSERT((cond == Overflow) || (cond == Signed) || (cond == Zero) || (cond == NonZero));
if (cond == Overflow) {
/*
move dataTemp, op1
xor cmpTemp, dataTemp, op2
bgez cmpTemp, No_overflow # same sign bit -> no overflow
subu dest, dataTemp, op2
xor cmpTemp, dest, dataTemp
bgez cmpTemp, No_overflow # same sign bit -> no overflow
nop
b Overflow
nop
b No_overflow
nop
nop
nop
No_overflow:
*/
move(op1, dataTempRegister);
m_assembler.xorInsn(cmpTempRegister, dataTempRegister, op2);
m_assembler.bgez(cmpTempRegister, 10);
m_assembler.subu(dest, dataTempRegister, op2);
m_assembler.xorInsn(cmpTempRegister, dest, dataTempRegister);
m_assembler.bgez(cmpTempRegister, 7);
m_assembler.nop();
return jump();
}
if (cond == Signed) {
sub32(op1, op2, dest);
// Check if dest is negative.
m_assembler.slt(cmpTempRegister, dest, MIPSRegisters::zero);
return branchNotEqual(cmpTempRegister, MIPSRegisters::zero);
}
if (cond == Zero) {
sub32(op1, op2, dest);
return branchEqual(dest, MIPSRegisters::zero);
}
if (cond == NonZero) {
sub32(op1, op2, dest);
return branchNotEqual(dest, MIPSRegisters::zero);
}
ASSERT(0);
return Jump();
}
Jump branchNeg32(ResultCondition cond, RegisterID srcDest)
{
ASSERT((cond == Overflow) || (cond == Signed) || (cond == Zero) || (cond == NonZero));
if (cond == Overflow) {
/*
bgez srcDest, No_overflow # positive input -> no overflow
subu srcDest, zero, srcDest
bgez srcDest, No_overflow # negative input, positive output -> no overflow
nop
b Overflow
nop
b No_overflow
nop
nop
nop
No_overflow:
*/
m_assembler.bgez(srcDest, 9);
m_assembler.subu(srcDest, MIPSRegisters::zero, srcDest);
m_assembler.bgez(srcDest, 7);
m_assembler.nop();
return jump();
}
if (cond == Signed) {
m_assembler.subu(srcDest, MIPSRegisters::zero, srcDest);
// Check if dest is negative.
m_assembler.slt(cmpTempRegister, srcDest, MIPSRegisters::zero);
return branchNotEqual(cmpTempRegister, MIPSRegisters::zero);
}
if (cond == Zero) {
m_assembler.subu(srcDest, MIPSRegisters::zero, srcDest);
return branchEqual(srcDest, MIPSRegisters::zero);
}
if (cond == NonZero) {
m_assembler.subu(srcDest, MIPSRegisters::zero, srcDest);
return branchNotEqual(srcDest, MIPSRegisters::zero);
}
ASSERT_NOT_REACHED();
return Jump();
}
Jump branchOr32(ResultCondition cond, RegisterID src, RegisterID dest)
{
ASSERT((cond == Signed) || (cond == Zero) || (cond == NonZero));
if (cond == Signed) {
or32(src, dest);
// Check if dest is negative.
m_assembler.slt(cmpTempRegister, dest, MIPSRegisters::zero);
return branchNotEqual(cmpTempRegister, MIPSRegisters::zero);
}
if (cond == Zero) {
or32(src, dest);
return branchEqual(dest, MIPSRegisters::zero);
}
if (cond == NonZero) {
or32(src, dest);
return branchNotEqual(dest, MIPSRegisters::zero);
}
ASSERT(0);
return Jump();
}
// Miscellaneous operations:
void breakpoint()
{
m_assembler.bkpt();
}
static bool isBreakpoint(void* address) { return MIPSAssembler::isBkpt(address); }
Call nearCall()
{
/* We need two words for relaxation. */
m_assembler.nop();
m_assembler.nop();
m_assembler.jal();
m_assembler.nop();
return Call(m_assembler.label(), Call::LinkableNear);
}
Call nearTailCall()
{
m_assembler.nop();
m_assembler.nop();
m_assembler.beq(MIPSRegisters::zero, MIPSRegisters::zero, 0);
m_assembler.nop();
insertRelaxationWords();
return Call(m_assembler.label(), Call::LinkableNearTail);
}
Call call(PtrTag)
{
m_assembler.lui(MIPSRegisters::t9, 0);
m_assembler.ori(MIPSRegisters::t9, MIPSRegisters::t9, 0);
m_assembler.jalr(MIPSRegisters::t9);
m_assembler.nop();
return Call(m_assembler.label(), Call::Linkable);
}
Call call(RegisterID target, PtrTag)
{
move(target, MIPSRegisters::t9);
m_assembler.jalr(MIPSRegisters::t9);
m_assembler.nop();
return Call(m_assembler.label(), Call::None);
}
Call call(Address address, PtrTag)
{
m_fixedWidth = true;
load32(address, MIPSRegisters::t9);
m_assembler.jalr(MIPSRegisters::t9);
m_assembler.nop();
m_fixedWidth = false;
return Call(m_assembler.label(), Call::None);
}
ALWAYS_INLINE Call call(RegisterID callTag) { return UNUSED_PARAM(callTag), call(NoPtrTag); }
ALWAYS_INLINE Call call(RegisterID target, RegisterID callTag) { return UNUSED_PARAM(callTag), call(target, NoPtrTag); }
ALWAYS_INLINE Call call(Address address, RegisterID callTag) { return UNUSED_PARAM(callTag), call(address, NoPtrTag); }
void ret()
{
m_assembler.jr(MIPSRegisters::ra);
m_assembler.nop();
}
void compare32(RelationalCondition cond, RegisterID left, RegisterID right, RegisterID dest)
{
if (cond == Equal) {
if (right == MIPSRegisters::zero && !m_fixedWidth)
m_assembler.sltiu(dest, left, 1);
else {
m_assembler.xorInsn(dest, left, right);
m_assembler.sltiu(dest, dest, 1);
}
} else if (cond == NotEqual) {
if (right == MIPSRegisters::zero && !m_fixedWidth)
m_assembler.sltu(dest, MIPSRegisters::zero, left);
else {
m_assembler.xorInsn(dest, left, right);
m_assembler.sltu(dest, MIPSRegisters::zero, dest);
}
} else if (cond == Above)
m_assembler.sltu(dest, right, left);
else if (cond == AboveOrEqual) {
m_assembler.sltu(dest, left, right);
m_assembler.xori(dest, dest, 1);
} else if (cond == Below)
m_assembler.sltu(dest, left, right);
else if (cond == BelowOrEqual) {
m_assembler.sltu(dest, right, left);
m_assembler.xori(dest, dest, 1);
} else if (cond == GreaterThan)
m_assembler.slt(dest, right, left);
else if (cond == GreaterThanOrEqual) {
m_assembler.slt(dest, left, right);
m_assembler.xori(dest, dest, 1);
} else if (cond == LessThan)
m_assembler.slt(dest, left, right);
else if (cond == LessThanOrEqual) {
m_assembler.slt(dest, right, left);
m_assembler.xori(dest, dest, 1);
}
}
void compare32(RelationalCondition cond, RegisterID left, TrustedImm32 right, RegisterID dest)
{
if (!right.m_value && !m_fixedWidth)
compare32(cond, left, MIPSRegisters::zero, dest);
else {
move(right, immTempRegister);
compare32(cond, left, immTempRegister, dest);
}
}
void test8(ResultCondition cond, Address address, TrustedImm32 mask, RegisterID dest)
{
ASSERT((cond == Zero) || (cond == NonZero));
TrustedImm32 mask8 = mask8OnTest(cond, mask);
MacroAssemblerHelpers::load8OnCondition(*this, cond, address, dataTempRegister);
if ((mask8.m_value & 0xff) == 0xff && !m_fixedWidth) {
if (cond == Zero)
m_assembler.sltiu(dest, dataTempRegister, 1);
else
m_assembler.sltu(dest, MIPSRegisters::zero, dataTempRegister);
} else {
move(mask8, immTempRegister);
m_assembler.andInsn(cmpTempRegister, dataTempRegister, immTempRegister);
if (cond == Zero)
m_assembler.sltiu(dest, cmpTempRegister, 1);
else
m_assembler.sltu(dest, MIPSRegisters::zero, cmpTempRegister);
}
}
void test32(ResultCondition cond, Address address, TrustedImm32 mask, RegisterID dest)
{
ASSERT((cond == Zero) || (cond == NonZero));
load32(address, dataTempRegister);
if (mask.m_value == -1 && !m_fixedWidth) {
if (cond == Zero)
m_assembler.sltiu(dest, dataTempRegister, 1);
else
m_assembler.sltu(dest, MIPSRegisters::zero, dataTempRegister);
} else {
move(mask, immTempRegister);
m_assembler.andInsn(cmpTempRegister, dataTempRegister, immTempRegister);
if (cond == Zero)
m_assembler.sltiu(dest, cmpTempRegister, 1);
else
m_assembler.sltu(dest, MIPSRegisters::zero, cmpTempRegister);
}
}
DataLabel32 moveWithPatch(TrustedImm32 imm, RegisterID dest)
{
m_fixedWidth = true;
DataLabel32 label(this);
move(imm, dest);
m_fixedWidth = false;
return label;
}
DataLabelPtr moveWithPatch(TrustedImmPtr initialValue, RegisterID dest)
{
m_fixedWidth = true;
DataLabelPtr label(this);
move(initialValue, dest);
m_fixedWidth = false;
return label;
}
Jump branchPtrWithPatch(RelationalCondition cond, RegisterID left, DataLabelPtr& dataLabel, TrustedImmPtr initialRightValue = TrustedImmPtr(nullptr))
{
m_fixedWidth = true;
dataLabel = moveWithPatch(initialRightValue, immTempRegister);
m_assembler.nop();
m_assembler.nop();
Jump temp = branch32(cond, left, immTempRegister);
m_fixedWidth = false;
return temp;
}
Jump branchPtrWithPatch(RelationalCondition cond, Address left, DataLabelPtr& dataLabel, TrustedImmPtr initialRightValue = TrustedImmPtr(nullptr))
{
m_fixedWidth = true;
load32(left, dataTempRegister);
dataLabel = moveWithPatch(initialRightValue, immTempRegister);
m_assembler.nop();
m_assembler.nop();
Jump temp = branch32(cond, dataTempRegister, immTempRegister);
m_fixedWidth = false;
return temp;
}
Jump branch32WithPatch(RelationalCondition cond, Address left, DataLabel32& dataLabel, TrustedImm32 initialRightValue = TrustedImm32(0))
{
m_fixedWidth = true;
load32(left, dataTempRegister);
dataLabel = moveWithPatch(initialRightValue, immTempRegister);
Jump temp = branch32(cond, dataTempRegister, immTempRegister);
m_fixedWidth = false;
return temp;
}
DataLabelPtr storePtrWithPatch(TrustedImmPtr initialValue, Address address)
{
m_fixedWidth = true;
DataLabelPtr dataLabel = moveWithPatch(initialValue, dataTempRegister);
store32(dataTempRegister, address);
m_fixedWidth = false;
return dataLabel;
}
DataLabelPtr storePtrWithPatch(Address address)
{
return storePtrWithPatch(TrustedImmPtr(nullptr), address);
}
void loadFloat(BaseIndex address, FPRegisterID dest)
{
if (!m_fixedWidth) {
loadAddress(address, LoadAddressMode::ScaleAndAddOffsetIfOffsetIsOutOfBounds);
m_assembler.lwc1(dest, addrTempRegister, address.offset);
} else {
/*
sll addrTemp, address.index, address.scale
addu addrTemp, addrTemp, address.base
lui immTemp, (address.offset + 0x8000) >> 16
addu addrTemp, addrTemp, immTemp
lwc1 dest, (address.offset & 0xffff)(at)
*/
m_assembler.sll(addrTempRegister, address.index, address.scale);
m_assembler.addu(addrTempRegister, addrTempRegister, address.base);
m_assembler.lui(immTempRegister, (address.offset + 0x8000) >> 16);
m_assembler.addu(addrTempRegister, addrTempRegister, immTempRegister);
m_assembler.lwc1(dest, addrTempRegister, address.offset);
}
}
void loadFloat(Address address, FPRegisterID dest)
{
if (address.offset >= -32768 && address.offset <= 32767
&& !m_fixedWidth) {
m_assembler.lwc1(dest, address.base, address.offset);
} else {
/*
lui addrTemp, (offset + 0x8000) >> 16
addu addrTemp, addrTemp, base
lwc1 dest, (offset & 0xffff)(addrTemp)
*/
m_assembler.lui(addrTempRegister, (address.offset + 0x8000) >> 16);
m_assembler.addu(addrTempRegister, addrTempRegister, address.base);
m_assembler.lwc1(dest, addrTempRegister, address.offset);
}
}
void loadDouble(Address address, FPRegisterID dest)
{
#if WTF_MIPS_ISA(1)
/*
li addrTemp, address.offset
addu addrTemp, addrTemp, base
lwc1 dest, 0(addrTemp)
lwc1 dest+1, 4(addrTemp)
*/
move(TrustedImm32(address.offset), addrTempRegister);
m_assembler.addu(addrTempRegister, addrTempRegister, address.base);
m_assembler.lwc1(dest, addrTempRegister, 0);
m_assembler.lwc1(FPRegisterID(dest + 1), addrTempRegister, 4);
#else
if (address.offset >= -32768 && address.offset <= 32767
&& !m_fixedWidth) {
m_assembler.ldc1(dest, address.base, address.offset);
} else {
/*
lui addrTemp, (offset + 0x8000) >> 16
addu addrTemp, addrTemp, base
ldc1 dest, (offset & 0xffff)(addrTemp)
*/
m_assembler.lui(addrTempRegister, (address.offset + 0x8000) >> 16);
m_assembler.addu(addrTempRegister, addrTempRegister, address.base);
m_assembler.ldc1(dest, addrTempRegister, address.offset);
}
#endif
}
void loadDouble(BaseIndex address, FPRegisterID dest)
{
#if WTF_MIPS_ISA(1)
if (!m_fixedWidth) {
loadAddress(address, LoadAddressMode::ScaleAndAddOffsetIfOffsetIsOutOfBounds);
m_assembler.lwc1(dest, addrTempRegister, address.offset);
m_assembler.lwc1(FPRegisterID(dest + 1), addrTempRegister, address.offset + 4);
} else {
/*
sll addrTemp, address.index, address.scale
addu addrTemp, addrTemp, address.base
lui immTemp, (address.offset + 0x8000) >> 16
addu addrTemp, addrTemp, immTemp
lwc1 dest, (address.offset & 0xffff)(at)
lwc1 dest+1, (address.offset & 0xffff + 4)(at)
*/
m_assembler.sll(addrTempRegister, address.index, address.scale);
m_assembler.addu(addrTempRegister, addrTempRegister, address.base);
m_assembler.lui(immTempRegister, (address.offset + 0x8000) >> 16);
m_assembler.addu(addrTempRegister, addrTempRegister, immTempRegister);
m_assembler.lwc1(dest, addrTempRegister, address.offset);
m_assembler.lwc1(FPRegisterID(dest + 1), addrTempRegister, address.offset + 4);
}
#else
if (!m_fixedWidth) {
loadAddress(address, LoadAddressMode::ScaleAndAddOffsetIfOffsetIsOutOfBounds);
m_assembler.ldc1(dest, addrTempRegister, address.offset);
} else {
/*
sll addrTemp, address.index, address.scale
addu addrTemp, addrTemp, address.base
lui immTemp, (address.offset + 0x8000) >> 16
addu addrTemp, addrTemp, immTemp
ldc1 dest, (address.offset & 0xffff)(at)
*/
m_assembler.sll(addrTempRegister, address.index, address.scale);
m_assembler.addu(addrTempRegister, addrTempRegister, address.base);
m_assembler.lui(immTempRegister, (address.offset + 0x8000) >> 16);
m_assembler.addu(addrTempRegister, addrTempRegister, immTempRegister);
m_assembler.ldc1(dest, addrTempRegister, address.offset);
}
#endif
}
void loadDouble(TrustedImmPtr address, FPRegisterID dest)
{
#if WTF_MIPS_ISA(1)
/*
li addrTemp, address
lwc1 dest, 0(addrTemp)
lwc1 dest+1, 4(addrTemp)
*/
move(address, addrTempRegister);
m_assembler.lwc1(dest, addrTempRegister, 0);
m_assembler.lwc1(FPRegisterID(dest + 1), addrTempRegister, 4);
#else
if (m_fixedWidth) {
/*
li addrTemp, address
ldc1 dest, 0(addrTemp)
*/
move(TrustedImmPtr(address), addrTempRegister);
m_assembler.ldc1(dest, addrTempRegister, 0);
} else {
uintptr_t adr = reinterpret_cast<uintptr_t>(address.m_value);
m_assembler.lui(addrTempRegister, (adr + 0x8000) >> 16);
m_assembler.ldc1(dest, addrTempRegister, adr & 0xffff);
}
#endif
}
void storeFloat(FPRegisterID src, BaseIndex address)
{
if (!m_fixedWidth) {
loadAddress(address, LoadAddressMode::ScaleAndAddOffsetIfOffsetIsOutOfBounds);
m_assembler.swc1(src, addrTempRegister, address.offset);
} else {
/*
sll addrTemp, address.index, address.scale
addu addrTemp, addrTemp, address.base
lui immTemp, (address.offset + 0x8000) >> 16
addu addrTemp, addrTemp, immTemp
swc1 src, (address.offset & 0xffff)(at)
*/
m_assembler.sll(addrTempRegister, address.index, address.scale);
m_assembler.addu(addrTempRegister, addrTempRegister, address.base);
m_assembler.lui(immTempRegister, (address.offset + 0x8000) >> 16);
m_assembler.addu(addrTempRegister, addrTempRegister, immTempRegister);
m_assembler.swc1(src, addrTempRegister, address.offset);
}
}
void storeFloat(FPRegisterID src, Address address)
{
if (address.offset >= -32768 && address.offset <= 32767
&& !m_fixedWidth)
m_assembler.swc1(src, address.base, address.offset);
else {
/*
lui addrTemp, (offset + 0x8000) >> 16
addu addrTemp, addrTemp, base
swc1 src, (offset & 0xffff)(addrTemp)
*/
m_assembler.lui(addrTempRegister, (address.offset + 0x8000) >> 16);
m_assembler.addu(addrTempRegister, addrTempRegister, address.base);
m_assembler.swc1(src, addrTempRegister, address.offset);
}
}
void storeDouble(FPRegisterID src, Address address)
{
#if WTF_MIPS_ISA(1)
/*
li addrTemp, address.offset
addu addrTemp, addrTemp, base
swc1 dest, 0(addrTemp)
swc1 dest+1, 4(addrTemp)
*/
move(TrustedImm32(address.offset), addrTempRegister);
m_assembler.addu(addrTempRegister, addrTempRegister, address.base);
m_assembler.swc1(src, addrTempRegister, 0);
m_assembler.swc1(FPRegisterID(src + 1), addrTempRegister, 4);
#else
if (address.offset >= -32768 && address.offset <= 32767
&& !m_fixedWidth)
m_assembler.sdc1(src, address.base, address.offset);
else {
/*
lui addrTemp, (offset + 0x8000) >> 16
addu addrTemp, addrTemp, base
sdc1 src, (offset & 0xffff)(addrTemp)
*/
m_assembler.lui(addrTempRegister, (address.offset + 0x8000) >> 16);
m_assembler.addu(addrTempRegister, addrTempRegister, address.base);
m_assembler.sdc1(src, addrTempRegister, address.offset);
}
#endif
}
void storeDouble(FPRegisterID src, BaseIndex address)
{
#if WTF_MIPS_ISA(1)
if (!m_fixedWidth) {
loadAddress(address, LoadAddressMode::ScaleAndAddOffsetIfOffsetIsOutOfBounds);
m_assembler.swc1(src, addrTempRegister, address.offset);
m_assembler.swc1(FPRegisterID(src + 1), addrTempRegister, address.offset + 4);
} else {
/*
sll addrTemp, address.index, address.scale
addu addrTemp, addrTemp, address.base
lui immTemp, (address.offset + 0x8000) >> 16
addu addrTemp, addrTemp, immTemp
swc1 src, (address.offset & 0xffff)(at)
swc1 src+1, (address.offset & 0xffff + 4)(at)
*/
m_assembler.sll(addrTempRegister, address.index, address.scale);
m_assembler.addu(addrTempRegister, addrTempRegister, address.base);
m_assembler.lui(immTempRegister, (address.offset + 0x8000) >> 16);
m_assembler.addu(addrTempRegister, addrTempRegister, immTempRegister);
m_assembler.swc1(src, addrTempRegister, address.offset);
m_assembler.swc1(FPRegisterID(src + 1), addrTempRegister, address.offset + 4);
}
#else
if (!m_fixedWidth) {
loadAddress(address, LoadAddressMode::ScaleAndAddOffsetIfOffsetIsOutOfBounds);
m_assembler.sdc1(src, addrTempRegister, address.offset);
} else {
/*
sll addrTemp, address.index, address.scale
addu addrTemp, addrTemp, address.base
lui immTemp, (address.offset + 0x8000) >> 16
addu addrTemp, addrTemp, immTemp
sdc1 src, (address.offset & 0xffff)(at)
*/
m_assembler.sll(addrTempRegister, address.index, address.scale);
m_assembler.addu(addrTempRegister, addrTempRegister, address.base);
m_assembler.lui(immTempRegister, (address.offset + 0x8000) >> 16);
m_assembler.addu(addrTempRegister, addrTempRegister, immTempRegister);
m_assembler.sdc1(src, addrTempRegister, address.offset);
}
#endif
}
void storeDouble(FPRegisterID src, TrustedImmPtr address)
{
#if WTF_MIPS_ISA(1)
move(address, addrTempRegister);
m_assembler.swc1(src, addrTempRegister, 0);
m_assembler.swc1(FPRegisterID(src + 1), addrTempRegister, 4);
#else
if (m_fixedWidth) {
/*
li addrTemp, address
sdc1 src, 0(addrTemp)
*/
move(TrustedImmPtr(address), addrTempRegister);
m_assembler.sdc1(src, addrTempRegister, 0);
} else {
uintptr_t adr = reinterpret_cast<uintptr_t>(address.m_value);
m_assembler.lui(addrTempRegister, (adr + 0x8000) >> 16);
m_assembler.sdc1(src, addrTempRegister, adr & 0xffff);
}
#endif
}
void moveDouble(FPRegisterID src, FPRegisterID dest)
{
if (src != dest || m_fixedWidth)
m_assembler.movd(dest, src);
}
void moveDouble(FPRegisterID src, RegisterID dest)
{
m_assembler.mfc1(dest, src);
m_assembler.mfc1(RegisterID(dest + 1), FPRegisterID(src + 1));
}
void moveZeroToDouble(FPRegisterID reg)
{
convertInt32ToDouble(MIPSRegisters::zero, reg);
}
void swap(FPRegisterID fr1, FPRegisterID fr2)
{
moveDouble(fr1, fpTempRegister);
moveDouble(fr2, fr1);
moveDouble(fpTempRegister, fr2);
}
void addDouble(FPRegisterID src, FPRegisterID dest)
{
m_assembler.addd(dest, dest, src);
}
void addDouble(FPRegisterID op1, FPRegisterID op2, FPRegisterID dest)
{
m_assembler.addd(dest, op1, op2);
}
void addDouble(Address src, FPRegisterID dest)
{
loadDouble(src, fpTempRegister);
m_assembler.addd(dest, dest, fpTempRegister);
}
void addDouble(AbsoluteAddress address, FPRegisterID dest)
{
loadDouble(TrustedImmPtr(address.m_ptr), fpTempRegister);
m_assembler.addd(dest, dest, fpTempRegister);
}
// andDouble and orDouble are a bit convoluted to implement
// because we don't have FP instructions for those
// operations. That means we'll have to go back and forth between
// the FPU and the CPU, which accounts for most of the code here.
void andDouble(FPRegisterID op1, FPRegisterID op2, FPRegisterID dest)
{
m_assembler.mfc1(immTempRegister, op1);
m_assembler.mfc1(dataTempRegister, op2);
m_assembler.andInsn(cmpTempRegister, immTempRegister, dataTempRegister);
m_assembler.mtc1(cmpTempRegister, dest);
#if WTF_MIPS_ISA_REV(2) && WTF_MIPS_FP64
m_assembler.mfhc1(immTempRegister, op1);
m_assembler.mfhc1(dataTempRegister, op2);
#else
m_assembler.mfc1(immTempRegister, FPRegisterID(op1+1));
m_assembler.mfc1(dataTempRegister, FPRegisterID(op2+1));
#endif
m_assembler.andInsn(cmpTempRegister, immTempRegister, dataTempRegister);
#if WTF_MIPS_ISA_REV(2) && WTF_MIPS_FP64
m_assembler.mthc1(cmpTempRegister, dest);
#else
m_assembler.mtc1(cmpTempRegister, FPRegisterID(dest+1));
#endif
}
void orDouble(FPRegisterID op1, FPRegisterID op2, FPRegisterID dest)
{
m_assembler.mfc1(immTempRegister, op1);
m_assembler.mfc1(dataTempRegister, op2);
m_assembler.orInsn(cmpTempRegister, immTempRegister, dataTempRegister);
m_assembler.mtc1(cmpTempRegister, dest);
#if WTF_MIPS_ISA_REV(2) && WTF_MIPS_FP64
m_assembler.mfhc1(immTempRegister, op1);
m_assembler.mfhc1(dataTempRegister, op2);
#else
m_assembler.mfc1(immTempRegister, FPRegisterID(op1+1));
m_assembler.mfc1(dataTempRegister, FPRegisterID(op2+1));
#endif
m_assembler.orInsn(cmpTempRegister, immTempRegister, dataTempRegister);
#if WTF_MIPS_ISA_REV(2) && WTF_MIPS_FP64
m_assembler.mthc1(cmpTempRegister, dest);
#else
m_assembler.mtc1(cmpTempRegister, FPRegisterID(dest+1));
#endif
}
void subDouble(FPRegisterID src, FPRegisterID dest)
{
m_assembler.subd(dest, dest, src);
}
void subDouble(FPRegisterID op1, FPRegisterID op2, FPRegisterID dest)
{
m_assembler.subd(dest, op1, op2);
}
void subDouble(Address src, FPRegisterID dest)
{
loadDouble(src, fpTempRegister);
m_assembler.subd(dest, dest, fpTempRegister);
}
void mulDouble(FPRegisterID src, FPRegisterID dest)
{
m_assembler.muld(dest, dest, src);
}
void mulDouble(Address src, FPRegisterID dest)
{
loadDouble(src, fpTempRegister);
m_assembler.muld(dest, dest, fpTempRegister);
}
void mulDouble(FPRegisterID op1, FPRegisterID op2, FPRegisterID dest)
{
m_assembler.muld(dest, op1, op2);
}
void divDouble(FPRegisterID src, FPRegisterID dest)
{
m_assembler.divd(dest, dest, src);
}
void divDouble(FPRegisterID op1, FPRegisterID op2, FPRegisterID dest)
{
m_assembler.divd(dest, op1, op2);
}
void divDouble(Address src, FPRegisterID dest)
{
loadDouble(src, fpTempRegister);
m_assembler.divd(dest, dest, fpTempRegister);
}
void negateDouble(FPRegisterID src, FPRegisterID dest)
{
m_assembler.negd(dest, src);
}
void convertInt32ToDouble(RegisterID src, FPRegisterID dest)
{
m_assembler.mtc1(src, fpTempRegister);
m_assembler.cvtdw(dest, fpTempRegister);
}
void convertInt32ToDouble(Address src, FPRegisterID dest)
{
load32(src, dataTempRegister);
m_assembler.mtc1(dataTempRegister, fpTempRegister);
m_assembler.cvtdw(dest, fpTempRegister);
}
void convertInt32ToDouble(AbsoluteAddress src, FPRegisterID dest)
{
load32(src.m_ptr, dataTempRegister);
m_assembler.mtc1(dataTempRegister, fpTempRegister);
m_assembler.cvtdw(dest, fpTempRegister);
}
void convertFloatToDouble(FPRegisterID src, FPRegisterID dst)
{
m_assembler.cvtds(dst, src);
}
void convertDoubleToFloat(FPRegisterID src, FPRegisterID dst)
{
m_assembler.cvtsd(dst, src);
}
void insertRelaxationWords()
{
/* We need four words for relaxation. */
m_assembler.beq(MIPSRegisters::zero, MIPSRegisters::zero, 3); // Jump over nops;
m_assembler.nop();
m_assembler.nop();
m_assembler.nop();
}
Jump branchTrue()
{
m_assembler.appendJump();
m_assembler.bc1t();
m_assembler.nop();
insertRelaxationWords();
return Jump(m_assembler.label());
}
Jump branchFalse()
{
m_assembler.appendJump();
m_assembler.bc1f();
m_assembler.nop();
insertRelaxationWords();
return Jump(m_assembler.label());
}
Jump branchEqual(RegisterID rs, RegisterID rt)
{
m_assembler.appendJump();
m_assembler.beq(rs, rt, 0);
m_assembler.nop();
insertRelaxationWords();
return Jump(m_assembler.label());
}
Jump branchNotEqual(RegisterID rs, RegisterID rt)
{
m_assembler.appendJump();
m_assembler.bne(rs, rt, 0);
m_assembler.nop();
insertRelaxationWords();
return Jump(m_assembler.label());
}
Jump branchDouble(DoubleCondition cond, FPRegisterID left, FPRegisterID right)
{
if (cond == DoubleEqualAndOrdered) {
m_assembler.ceqd(left, right);
return branchTrue();
}
if (cond == DoubleNotEqualAndOrdered) {
m_assembler.cueqd(left, right);
return branchFalse(); // false
}
if (cond == DoubleGreaterThanAndOrdered) {
m_assembler.cngtd(left, right);
return branchFalse(); // false
}
if (cond == DoubleGreaterThanOrEqualAndOrdered) {
m_assembler.cnged(left, right);
return branchFalse(); // false
}
if (cond == DoubleLessThanAndOrdered) {
m_assembler.cltd(left, right);
return branchTrue();
}
if (cond == DoubleLessThanOrEqualAndOrdered) {
m_assembler.cled(left, right);
return branchTrue();
}
if (cond == DoubleEqualOrUnordered) {
m_assembler.cueqd(left, right);
return branchTrue();
}
if (cond == DoubleNotEqualOrUnordered) {
m_assembler.ceqd(left, right);
return branchFalse(); // false
}
if (cond == DoubleGreaterThanOrUnordered) {
m_assembler.coled(left, right);
return branchFalse(); // false
}
if (cond == DoubleGreaterThanOrEqualOrUnordered) {
m_assembler.coltd(left, right);
return branchFalse(); // false
}
if (cond == DoubleLessThanOrUnordered) {
m_assembler.cultd(left, right);
return branchTrue();
}
if (cond == DoubleLessThanOrEqualOrUnordered) {
m_assembler.culed(left, right);
return branchTrue();
}
ASSERT(0);
return Jump();
}
// Truncates 'src' to an integer, and places the resulting 'dest'.
// If the result is not representable as a 32 bit value, branch.
enum BranchTruncateType { BranchIfTruncateFailed, BranchIfTruncateSuccessful };
Jump branchTruncateDoubleToInt32(FPRegisterID src, RegisterID dest, BranchTruncateType branchType = BranchIfTruncateFailed)
{
m_assembler.truncwd(fpTempRegister, src);
m_assembler.cfc1(dataTempRegister, MIPSRegisters::fcsr);
m_assembler.mfc1(dest, fpTempRegister);
and32(TrustedImm32(MIPSAssembler::FP_CAUSE_INVALID_OPERATION), dataTempRegister);
return branch32(branchType == BranchIfTruncateFailed ? NotEqual : Equal, dataTempRegister, MIPSRegisters::zero);
}
// Result is undefined if the value is outside of the integer range.
void truncateDoubleToInt32(FPRegisterID src, RegisterID dest)
{
m_assembler.truncwd(fpTempRegister, src);
m_assembler.mfc1(dest, fpTempRegister);
}
// Result is undefined if src > 2^31
void truncateDoubleToUint32(FPRegisterID src, RegisterID dest)
{
m_assembler.truncwd(fpTempRegister, src);
m_assembler.mfc1(dest, fpTempRegister);
}
// 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, bool negZeroCheck = true)
{
m_assembler.cvtwd(fpTempRegister, src);
m_assembler.mfc1(dest, fpTempRegister);
// If the result is zero, it might have been -0.0, and the double comparison won't catch this!
if (negZeroCheck)
failureCases.append(branch32(Equal, dest, MIPSRegisters::zero));
// Convert the integer result back to float & compare to the original value - if not equal or unordered (NaN) then jump.
convertInt32ToDouble(dest, fpTemp);
failureCases.append(branchDouble(DoubleNotEqualOrUnordered, fpTemp, src));
}
Jump branchDoubleNonZero(FPRegisterID reg, FPRegisterID scratch)
{
m_assembler.vmov(scratch, MIPSRegisters::zero, MIPSRegisters::zero);
return branchDouble(DoubleNotEqualAndOrdered, reg, scratch);
}
Jump branchDoubleZeroOrNaN(FPRegisterID reg, FPRegisterID scratch)
{
m_assembler.vmov(scratch, MIPSRegisters::zero, MIPSRegisters::zero);
return branchDouble(DoubleEqualOrUnordered, reg, scratch);
}
// Invert a relational condition, e.g. == becomes !=, < becomes >=, etc.
static RelationalCondition invert(RelationalCondition cond)
{
RelationalCondition r;
if (cond == Equal)
r = NotEqual;
else if (cond == NotEqual)
r = Equal;
else if (cond == Above)
r = BelowOrEqual;
else if (cond == AboveOrEqual)
r = Below;
else if (cond == Below)
r = AboveOrEqual;
else if (cond == BelowOrEqual)
r = Above;
else if (cond == GreaterThan)
r = LessThanOrEqual;
else if (cond == GreaterThanOrEqual)
r = LessThan;
else if (cond == LessThan)
r = GreaterThanOrEqual;
else if (cond == LessThanOrEqual)
r = GreaterThan;
return r;
}
void nop()
{
m_assembler.nop();
}
void memoryFence()
{
m_assembler.sync();
}
void abortWithReason(AbortReason reason)
{
move(TrustedImm32(reason), dataTempRegister);
breakpoint();
}
void storeFence()
{
m_assembler.sync();
}
void abortWithReason(AbortReason reason, intptr_t misc)
{
move(TrustedImm32(misc), immTempRegister);
abortWithReason(reason);
}
template<PtrTag resultTag, PtrTag locationTag>
static FunctionPtr<resultTag> readCallTarget(CodeLocationCall<locationTag> call)
{
return FunctionPtr<resultTag>(reinterpret_cast<void(*)()>(MIPSAssembler::readCallTarget(call.dataLocation())));
}
template<PtrTag startTag, PtrTag destTag>
static void replaceWithJump(CodeLocationLabel<startTag> instructionStart, CodeLocationLabel<destTag> destination)
{
MIPSAssembler::replaceWithJump(instructionStart.dataLocation(), destination.dataLocation());
}
static ptrdiff_t maxJumpReplacementSize()
{
MIPSAssembler::maxJumpReplacementSize();
return 0;
}
static ptrdiff_t patchableJumpSize()
{
return MIPSAssembler::patchableJumpSize();
}
static bool canJumpReplacePatchableBranchPtrWithPatch() { return false; }
static bool canJumpReplacePatchableBranch32WithPatch() { return false; }
template<PtrTag tag>
static CodeLocationLabel<tag> startOfPatchableBranch32WithPatchOnAddress(CodeLocationDataLabel32<tag>)
{
UNREACHABLE_FOR_PLATFORM();
return CodeLocationLabel<tag>();
}
template<PtrTag tag>
static CodeLocationLabel<tag> startOfBranchPtrWithPatchOnRegister(CodeLocationDataLabelPtr<tag> label)
{
return label.labelAtOffset(0);
}
template<PtrTag tag>
static void revertJumpReplacementToBranchPtrWithPatch(CodeLocationLabel<tag> instructionStart, RegisterID, void* initialValue)
{
MIPSAssembler::revertJumpToMove(instructionStart.dataLocation(), immTempRegister, reinterpret_cast<int>(initialValue) & 0xffff);
}
template<PtrTag tag>
static CodeLocationLabel<tag> startOfPatchableBranchPtrWithPatchOnAddress(CodeLocationDataLabelPtr<tag>)
{
UNREACHABLE_FOR_PLATFORM();
return CodeLocationLabel<tag>();
}
template<PtrTag tag>
static void revertJumpReplacementToPatchableBranch32WithPatch(CodeLocationLabel<tag>, Address, int32_t)
{
UNREACHABLE_FOR_PLATFORM();
}
template<PtrTag tag>
static void revertJumpReplacementToPatchableBranchPtrWithPatch(CodeLocationLabel<tag>, Address, void*)
{
UNREACHABLE_FOR_PLATFORM();
}
template<PtrTag callTag, PtrTag destTag>
static void repatchCall(CodeLocationCall<callTag> call, CodeLocationLabel<destTag> destination)
{
MIPSAssembler::relinkCall(call.dataLocation(), destination.executableAddress());
}
template<PtrTag callTag, PtrTag destTag>
static void repatchCall(CodeLocationCall<callTag> call, FunctionPtr<destTag> destination)
{
MIPSAssembler::relinkCall(call.dataLocation(), destination.executableAddress());
}
private:
// If m_fixedWidth is true, we will generate a fixed number of instructions.
// Otherwise, we can emit any number of instructions.
bool m_fixedWidth;
friend class LinkBuffer;
template<PtrTag tag>
static void linkCall(void* code, Call call, FunctionPtr<tag> function)
{
if (call.isFlagSet(Call::Tail))
MIPSAssembler::linkJump(code, call.m_label, function.executableAddress());
else
MIPSAssembler::linkCall(code, call.m_label, function.executableAddress());
}
};
} // namespace JSC
#endif // ENABLE(ASSEMBLER) && CPU(MIPS)