/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 4 -*-
* vim: set ts=8 sts=4 et sw=4 tw=99:
* This Source Code Form is subject to the terms of the Mozilla Public
* License, v. 2.0. If a copy of the MPL was not distributed with this
* file, You can obtain one at http://mozilla.org/MPL/2.0/. */
#include "jit/mips32/CodeGenerator-mips32.h"
#include "mozilla/MathAlgorithms.h"
#include "jit/CodeGenerator.h"
#include "jit/JitCompartment.h"
#include "jit/JitFrames.h"
#include "jit/MIR.h"
#include "jit/MIRGraph.h"
#include "js/Conversions.h"
#include "vm/Shape.h"
#include "vm/TraceLogging.h"
#include "jit/MacroAssembler-inl.h"
#include "jit/shared/CodeGenerator-shared-inl.h"
using namespace js;
using namespace js::jit;
class js::jit::OutOfLineTableSwitch : public OutOfLineCodeBase<CodeGeneratorMIPS>
{
MTableSwitch* mir_;
CodeLabel jumpLabel_;
void accept(CodeGeneratorMIPS* codegen) {
codegen->visitOutOfLineTableSwitch(this);
}
public:
OutOfLineTableSwitch(MTableSwitch* mir)
: mir_(mir)
{}
MTableSwitch* mir() const {
return mir_;
}
CodeLabel* jumpLabel() {
return &jumpLabel_;
}
};
void
CodeGeneratorMIPS::visitOutOfLineBailout(OutOfLineBailout* ool)
{
// Push snapshotOffset and make sure stack is aligned.
masm.subPtr(Imm32(2 * sizeof(void*)), StackPointer);
masm.storePtr(ImmWord(ool->snapshot()->snapshotOffset()), Address(StackPointer, 0));
masm.jump(&deoptLabel_);
}
void
CodeGeneratorMIPS::visitOutOfLineTableSwitch(OutOfLineTableSwitch* ool)
{
MTableSwitch* mir = ool->mir();
masm.haltingAlign(sizeof(void*));
masm.bind(ool->jumpLabel()->target());
masm.addCodeLabel(*ool->jumpLabel());
for (size_t i = 0; i < mir->numCases(); i++) {
LBlock* caseblock = skipTrivialBlocks(mir->getCase(i))->lir();
Label* caseheader = caseblock->label();
uint32_t caseoffset = caseheader->offset();
// The entries of the jump table need to be absolute addresses and thus
// must be patched after codegen is finished.
CodeLabel cl;
masm.ma_li(ScratchRegister, cl.patchAt());
masm.branch(ScratchRegister);
cl.target()->bind(caseoffset);
masm.addCodeLabel(cl);
}
}
void
CodeGeneratorMIPS::emitTableSwitchDispatch(MTableSwitch* mir, Register index,
Register address)
{
Label* defaultcase = skipTrivialBlocks(mir->getDefault())->lir()->label();
// Lower value with low value
if (mir->low() != 0)
masm.subPtr(Imm32(mir->low()), index);
// Jump to default case if input is out of range
int32_t cases = mir->numCases();
masm.branchPtr(Assembler::AboveOrEqual, index, ImmWord(cases), defaultcase);
// To fill in the CodeLabels for the case entries, we need to first
// generate the case entries (we don't yet know their offsets in the
// instruction stream).
OutOfLineTableSwitch* ool = new(alloc()) OutOfLineTableSwitch(mir);
addOutOfLineCode(ool, mir);
// Compute the position where a pointer to the right case stands.
masm.ma_li(address, ool->jumpLabel()->patchAt());
masm.lshiftPtr(Imm32(4), index);
masm.addPtr(index, address);
masm.branch(address);
}
static const uint32_t FrameSizes[] = { 128, 256, 512, 1024 };
FrameSizeClass
FrameSizeClass::FromDepth(uint32_t frameDepth)
{
for (uint32_t i = 0; i < JS_ARRAY_LENGTH(FrameSizes); i++) {
if (frameDepth < FrameSizes[i])
return FrameSizeClass(i);
}
return FrameSizeClass::None();
}
FrameSizeClass
FrameSizeClass::ClassLimit()
{
return FrameSizeClass(JS_ARRAY_LENGTH(FrameSizes));
}
uint32_t
FrameSizeClass::frameSize() const
{
MOZ_ASSERT(class_ != NO_FRAME_SIZE_CLASS_ID);
MOZ_ASSERT(class_ < JS_ARRAY_LENGTH(FrameSizes));
return FrameSizes[class_];
}
ValueOperand
CodeGeneratorMIPS::ToValue(LInstruction* ins, size_t pos)
{
Register typeReg = ToRegister(ins->getOperand(pos + TYPE_INDEX));
Register payloadReg = ToRegister(ins->getOperand(pos + PAYLOAD_INDEX));
return ValueOperand(typeReg, payloadReg);
}
ValueOperand
CodeGeneratorMIPS::ToOutValue(LInstruction* ins)
{
Register typeReg = ToRegister(ins->getDef(TYPE_INDEX));
Register payloadReg = ToRegister(ins->getDef(PAYLOAD_INDEX));
return ValueOperand(typeReg, payloadReg);
}
ValueOperand
CodeGeneratorMIPS::ToTempValue(LInstruction* ins, size_t pos)
{
Register typeReg = ToRegister(ins->getTemp(pos + TYPE_INDEX));
Register payloadReg = ToRegister(ins->getTemp(pos + PAYLOAD_INDEX));
return ValueOperand(typeReg, payloadReg);
}
void
CodeGeneratorMIPS::visitBox(LBox* box)
{
const LDefinition* type = box->getDef(TYPE_INDEX);
MOZ_ASSERT(!box->getOperand(0)->isConstant());
// For NUNBOX32, the input operand and the output payload have the same
// virtual register. All that needs to be written is the type tag for
// the type definition.
masm.move32(Imm32(MIRTypeToTag(box->type())), ToRegister(type));
}
void
CodeGeneratorMIPS::visitBoxFloatingPoint(LBoxFloatingPoint* box)
{
const LDefinition* payload = box->getDef(PAYLOAD_INDEX);
const LDefinition* type = box->getDef(TYPE_INDEX);
const LAllocation* in = box->getOperand(0);
FloatRegister reg = ToFloatRegister(in);
if (box->type() == MIRType::Float32) {
masm.convertFloat32ToDouble(reg, ScratchDoubleReg);
reg = ScratchDoubleReg;
}
masm.ma_mv(reg, ValueOperand(ToRegister(type), ToRegister(payload)));
}
void
CodeGeneratorMIPS::visitUnbox(LUnbox* unbox)
{
// Note that for unbox, the type and payload indexes are switched on the
// inputs.
MUnbox* mir = unbox->mir();
Register type = ToRegister(unbox->type());
if (mir->fallible()) {
bailoutCmp32(Assembler::NotEqual, type, Imm32(MIRTypeToTag(mir->type())),
unbox->snapshot());
}
}
Register
CodeGeneratorMIPS::splitTagForTest(const ValueOperand& value)
{
return value.typeReg();
}
void
CodeGeneratorMIPS::visitCompareB(LCompareB* lir)
{
MCompare* mir = lir->mir();
const ValueOperand lhs = ToValue(lir, LCompareB::Lhs);
const LAllocation* rhs = lir->rhs();
const Register output = ToRegister(lir->output());
MOZ_ASSERT(mir->jsop() == JSOP_STRICTEQ || mir->jsop() == JSOP_STRICTNE);
Assembler::Condition cond = JSOpToCondition(mir->compareType(), mir->jsop());
Label notBoolean, done;
masm.branchTestBoolean(Assembler::NotEqual, lhs, ¬Boolean);
{
if (rhs->isConstant())
masm.cmp32Set(cond, lhs.payloadReg(), Imm32(rhs->toConstant()->toBoolean()), output);
else
masm.cmp32Set(cond, lhs.payloadReg(), ToRegister(rhs), output);
masm.jump(&done);
}
masm.bind(¬Boolean);
{
masm.move32(Imm32(mir->jsop() == JSOP_STRICTNE), output);
}
masm.bind(&done);
}
void
CodeGeneratorMIPS::visitCompareBAndBranch(LCompareBAndBranch* lir)
{
MCompare* mir = lir->cmpMir();
const ValueOperand lhs = ToValue(lir, LCompareBAndBranch::Lhs);
const LAllocation* rhs = lir->rhs();
MOZ_ASSERT(mir->jsop() == JSOP_STRICTEQ || mir->jsop() == JSOP_STRICTNE);
MBasicBlock* mirNotBoolean = (mir->jsop() == JSOP_STRICTEQ) ? lir->ifFalse() : lir->ifTrue();
branchToBlock(lhs.typeReg(), ImmType(JSVAL_TYPE_BOOLEAN), mirNotBoolean, Assembler::NotEqual);
Assembler::Condition cond = JSOpToCondition(mir->compareType(), mir->jsop());
if (rhs->isConstant())
emitBranch(lhs.payloadReg(), Imm32(rhs->toConstant()->toBoolean()), cond, lir->ifTrue(),
lir->ifFalse());
else
emitBranch(lhs.payloadReg(), ToRegister(rhs), cond, lir->ifTrue(), lir->ifFalse());
}
void
CodeGeneratorMIPS::visitCompareBitwise(LCompareBitwise* lir)
{
MCompare* mir = lir->mir();
Assembler::Condition cond = JSOpToCondition(mir->compareType(), mir->jsop());
const ValueOperand lhs = ToValue(lir, LCompareBitwise::LhsInput);
const ValueOperand rhs = ToValue(lir, LCompareBitwise::RhsInput);
const Register output = ToRegister(lir->output());
MOZ_ASSERT(IsEqualityOp(mir->jsop()));
Label notEqual, done;
masm.ma_b(lhs.typeReg(), rhs.typeReg(), ¬Equal, Assembler::NotEqual, ShortJump);
{
masm.cmp32Set(cond, lhs.payloadReg(), rhs.payloadReg(), output);
masm.ma_b(&done, ShortJump);
}
masm.bind(¬Equal);
{
masm.move32(Imm32(cond == Assembler::NotEqual), output);
}
masm.bind(&done);
}
void
CodeGeneratorMIPS::visitCompareBitwiseAndBranch(LCompareBitwiseAndBranch* lir)
{
MCompare* mir = lir->cmpMir();
Assembler::Condition cond = JSOpToCondition(mir->compareType(), mir->jsop());
const ValueOperand lhs = ToValue(lir, LCompareBitwiseAndBranch::LhsInput);
const ValueOperand rhs = ToValue(lir, LCompareBitwiseAndBranch::RhsInput);
MOZ_ASSERT(mir->jsop() == JSOP_EQ || mir->jsop() == JSOP_STRICTEQ ||
mir->jsop() == JSOP_NE || mir->jsop() == JSOP_STRICTNE);
MBasicBlock* notEqual = (cond == Assembler::Equal) ? lir->ifFalse() : lir->ifTrue();
branchToBlock(lhs.typeReg(), rhs.typeReg(), notEqual, Assembler::NotEqual);
emitBranch(lhs.payloadReg(), rhs.payloadReg(), cond, lir->ifTrue(), lir->ifFalse());
}
void
CodeGeneratorMIPS::visitCompareI64(LCompareI64* lir)
{
MCompare* mir = lir->mir();
MOZ_ASSERT(mir->compareType() == MCompare::Compare_Int64 ||
mir->compareType() == MCompare::Compare_UInt64);
const LInt64Allocation lhs = lir->getInt64Operand(LCompareI64::Lhs);
const LInt64Allocation rhs = lir->getInt64Operand(LCompareI64::Rhs);
Register64 lhsRegs = ToRegister64(lhs);
Register output = ToRegister(lir->output());
bool isSigned = mir->compareType() == MCompare::Compare_Int64;
Assembler::Condition condition = JSOpToCondition(lir->jsop(), isSigned);
Label done;
masm.move32(Imm32(1), output);
if (IsConstant(rhs)) {
Imm64 imm = Imm64(ToInt64(rhs));
masm.branch64(condition, lhsRegs, imm, &done);
} else {
Register64 rhsRegs = ToRegister64(rhs);
masm.branch64(condition, lhsRegs, rhsRegs, &done);
}
masm.move32(Imm32(0), output);
masm.bind(&done);
}
void
CodeGeneratorMIPS::visitCompareI64AndBranch(LCompareI64AndBranch* lir)
{
MCompare* mir = lir->cmpMir();
MOZ_ASSERT(mir->compareType() == MCompare::Compare_Int64 ||
mir->compareType() == MCompare::Compare_UInt64);
const LInt64Allocation lhs = lir->getInt64Operand(LCompareI64::Lhs);
const LInt64Allocation rhs = lir->getInt64Operand(LCompareI64::Rhs);
Register64 lhsRegs = ToRegister64(lhs);
bool isSigned = mir->compareType() == MCompare::Compare_Int64;
Assembler::Condition condition = JSOpToCondition(lir->jsop(), isSigned);
Label* trueLabel = getJumpLabelForBranch(lir->ifTrue());
Label* falseLabel = getJumpLabelForBranch(lir->ifFalse());
if (isNextBlock(lir->ifFalse()->lir())) {
falseLabel = nullptr;
} else if (isNextBlock(lir->ifTrue()->lir())) {
condition = Assembler::InvertCondition(condition);
trueLabel = falseLabel;
falseLabel = nullptr;
}
if (IsConstant(rhs)) {
Imm64 imm = Imm64(ToInt64(rhs));
masm.branch64(condition, lhsRegs, imm, trueLabel, falseLabel);
} else {
Register64 rhsRegs = ToRegister64(rhs);
masm.branch64(condition, lhsRegs, rhsRegs, trueLabel, falseLabel);
}
}
void
CodeGeneratorMIPS::visitDivOrModI64(LDivOrModI64* lir)
{
Register64 lhs = ToRegister64(lir->getInt64Operand(LDivOrModI64::Lhs));
Register64 rhs = ToRegister64(lir->getInt64Operand(LDivOrModI64::Rhs));
Register64 output = ToOutRegister64(lir);
MOZ_ASSERT(output == ReturnReg64);
// All inputs are useAtStart for a call instruction. As a result we cannot
// ask for a non-aliasing temp. Using the following to get such a temp.
AllocatableGeneralRegisterSet regs(GeneralRegisterSet::All());
regs.take(lhs.low);
regs.take(lhs.high);
if (lhs != rhs) {
regs.take(rhs.low);
regs.take(rhs.high);
}
Register temp = regs.takeAny();
Label done;
// Handle divide by zero.
if (lir->canBeDivideByZero())
masm.branchTest64(Assembler::Zero, rhs, rhs, temp, trap(lir, wasm::Trap::IntegerDivideByZero));
// Handle an integer overflow exception from INT64_MIN / -1.
if (lir->canBeNegativeOverflow()) {
Label notmin;
masm.branch64(Assembler::NotEqual, lhs, Imm64(INT64_MIN), ¬min);
masm.branch64(Assembler::NotEqual, rhs, Imm64(-1), ¬min);
if (lir->mir()->isMod()) {
masm.xor64(output, output);
} else {
masm.jump(trap(lir, wasm::Trap::IntegerOverflow));
}
masm.jump(&done);
masm.bind(¬min);
}
masm.setupUnalignedABICall(temp);
masm.passABIArg(lhs.high);
masm.passABIArg(lhs.low);
masm.passABIArg(rhs.high);
masm.passABIArg(rhs.low);
MOZ_ASSERT(gen->compilingWasm());
if (lir->mir()->isMod())
masm.callWithABI(wasm::SymbolicAddress::ModI64);
else
masm.callWithABI(wasm::SymbolicAddress::DivI64);
MOZ_ASSERT(ReturnReg64 == output);
masm.bind(&done);
}
void
CodeGeneratorMIPS::visitUDivOrModI64(LUDivOrModI64* lir)
{
Register64 lhs = ToRegister64(lir->getInt64Operand(LDivOrModI64::Lhs));
Register64 rhs = ToRegister64(lir->getInt64Operand(LDivOrModI64::Rhs));
MOZ_ASSERT(ToOutRegister64(lir) == ReturnReg64);
// All inputs are useAtStart for a call instruction. As a result we cannot
// ask for a non-aliasing temp. Using the following to get such a temp.
AllocatableGeneralRegisterSet regs(GeneralRegisterSet::All());
regs.take(lhs.low);
regs.take(lhs.high);
if (lhs != rhs) {
regs.take(rhs.low);
regs.take(rhs.high);
}
Register temp = regs.takeAny();
// Prevent divide by zero.
if (lir->canBeDivideByZero())
masm.branchTest64(Assembler::Zero, rhs, rhs, temp, trap(lir, wasm::Trap::IntegerDivideByZero));
masm.setupUnalignedABICall(temp);
masm.passABIArg(lhs.high);
masm.passABIArg(lhs.low);
masm.passABIArg(rhs.high);
masm.passABIArg(rhs.low);
MOZ_ASSERT(gen->compilingWasm());
if (lir->mir()->isMod())
masm.callWithABI(wasm::SymbolicAddress::UModI64);
else
masm.callWithABI(wasm::SymbolicAddress::UDivI64);
}
template <typename T>
void
CodeGeneratorMIPS::emitWasmLoadI64(T* lir)
{
const MWasmLoad* mir = lir->mir();
Register64 output = ToOutRegister64(lir);
uint32_t offset = mir->access().offset();
MOZ_ASSERT(offset < wasm::OffsetGuardLimit);
Register ptr = ToRegister(lir->ptr());
if (offset) {
Register ptrPlusOffset = ToRegister(lir->ptrCopy());
masm.addPtr(Imm32(offset), ptrPlusOffset);
ptr = ptrPlusOffset;
} else {
MOZ_ASSERT(lir->ptrCopy()->isBogusTemp());
}
unsigned byteSize = mir->access().byteSize();
bool isSigned;
switch (mir->access().type()) {
case Scalar::Int8: isSigned = true; break;
case Scalar::Uint8: isSigned = false; break;
case Scalar::Int16: isSigned = true; break;
case Scalar::Uint16: isSigned = false; break;
case Scalar::Int32: isSigned = true; break;
case Scalar::Uint32: isSigned = false; break;
case Scalar::Int64: isSigned = true; break;
default: MOZ_CRASH("unexpected array type");
}
masm.memoryBarrier(mir->access().barrierBefore());
MOZ_ASSERT(INT64LOW_OFFSET == 0);
if (mir->access().isUnaligned()) {
Register temp = ToRegister(lir->getTemp(1));
if (byteSize <= 4) {
masm.ma_load_unaligned(output.low, BaseIndex(HeapReg, ptr, TimesOne),
temp, static_cast<LoadStoreSize>(8 * byteSize),
isSigned ? SignExtend : ZeroExtend);
if (!isSigned)
masm.move32(Imm32(0), output.high);
else
masm.ma_sra(output.high, output.low, Imm32(31));
} else {
ScratchRegisterScope scratch(masm);
masm.ma_load_unaligned(output.low, BaseIndex(HeapReg, ptr, TimesOne),
temp, SizeWord, isSigned ? SignExtend : ZeroExtend);
masm.ma_addu(scratch, ptr, Imm32(INT64HIGH_OFFSET));
masm.ma_load_unaligned(output.high, BaseIndex(HeapReg, scratch, TimesOne),
temp, SizeWord, isSigned ? SignExtend : ZeroExtend);
}
return;
}
if (byteSize <= 4) {
masm.ma_load(output.low, BaseIndex(HeapReg, ptr, TimesOne),
static_cast<LoadStoreSize>(8 * byteSize), isSigned ? SignExtend : ZeroExtend);
if (!isSigned)
masm.move32(Imm32(0), output.high);
else
masm.ma_sra(output.high, output.low, Imm32(31));
} else {
ScratchRegisterScope scratch(masm);
masm.ma_load(output.low, BaseIndex(HeapReg, ptr, TimesOne), SizeWord);
masm.ma_addu(scratch, ptr, Imm32(INT64HIGH_OFFSET));
masm.ma_load(output.high, BaseIndex(HeapReg, scratch, TimesOne), SizeWord);
}
masm.memoryBarrier(mir->access().barrierAfter());
}
void
CodeGeneratorMIPS::visitWasmLoadI64(LWasmLoadI64* lir)
{
emitWasmLoadI64(lir);
}
void
CodeGeneratorMIPS::visitWasmUnalignedLoadI64(LWasmUnalignedLoadI64* lir)
{
emitWasmLoadI64(lir);
}
template <typename T>
void
CodeGeneratorMIPS::emitWasmStoreI64(T* lir)
{
const MWasmStore* mir = lir->mir();
Register64 value = ToRegister64(lir->getInt64Operand(lir->ValueIndex));
uint32_t offset = mir->access().offset();
MOZ_ASSERT(offset < wasm::OffsetGuardLimit);
Register ptr = ToRegister(lir->ptr());
if (offset) {
Register ptrPlusOffset = ToRegister(lir->ptrCopy());
masm.addPtr(Imm32(offset), ptrPlusOffset);
ptr = ptrPlusOffset;
} else {
MOZ_ASSERT(lir->ptrCopy()->isBogusTemp());
}
unsigned byteSize = mir->access().byteSize();
bool isSigned;
switch (mir->access().type()) {
case Scalar::Int8: isSigned = true; break;
case Scalar::Uint8: isSigned = false; break;
case Scalar::Int16: isSigned = true; break;
case Scalar::Uint16: isSigned = false; break;
case Scalar::Int32: isSigned = true; break;
case Scalar::Uint32: isSigned = false; break;
case Scalar::Int64: isSigned = true; break;
default: MOZ_CRASH("unexpected array type");
}
masm.memoryBarrier(mir->access().barrierBefore());
MOZ_ASSERT(INT64LOW_OFFSET == 0);
if (mir->access().isUnaligned()) {
Register temp = ToRegister(lir->getTemp(1));
if (byteSize <= 4) {
masm.ma_store_unaligned(value.low, BaseIndex(HeapReg, ptr, TimesOne),
temp, static_cast<LoadStoreSize>(8 * byteSize),
isSigned ? SignExtend : ZeroExtend);
} else {
ScratchRegisterScope scratch(masm);
masm.ma_store_unaligned(value.low, BaseIndex(HeapReg, ptr, TimesOne),
temp, SizeWord, isSigned ? SignExtend : ZeroExtend);
masm.ma_addu(scratch, ptr, Imm32(INT64HIGH_OFFSET));
masm.ma_store_unaligned(value.high, BaseIndex(HeapReg, scratch, TimesOne),
temp, SizeWord, isSigned ? SignExtend : ZeroExtend);
}
return;
}
if (byteSize <= 4) {
masm.ma_store(value.low, BaseIndex(HeapReg, ptr, TimesOne),
static_cast<LoadStoreSize>(8 * byteSize));
} else {
ScratchRegisterScope scratch(masm);
masm.ma_store(value.low, BaseIndex(HeapReg, ptr, TimesOne), SizeWord);
masm.ma_addu(scratch, ptr, Imm32(INT64HIGH_OFFSET));
masm.ma_store(value.high, BaseIndex(HeapReg, scratch, TimesOne), SizeWord);
}
masm.memoryBarrier(mir->access().barrierAfter());
}
void
CodeGeneratorMIPS::visitWasmStoreI64(LWasmStoreI64* lir)
{
emitWasmStoreI64(lir);
}
void
CodeGeneratorMIPS::visitWasmUnalignedStoreI64(LWasmUnalignedStoreI64* lir)
{
emitWasmStoreI64(lir);
}
void
CodeGeneratorMIPS::visitWasmLoadGlobalVarI64(LWasmLoadGlobalVarI64* ins)
{
const MWasmLoadGlobalVar* mir = ins->mir();
unsigned addr = mir->globalDataOffset() - WasmGlobalRegBias;
MOZ_ASSERT(mir->type() == MIRType::Int64);
Register64 output = ToOutRegister64(ins);
masm.load32(Address(GlobalReg, addr + INT64LOW_OFFSET), output.low);
masm.load32(Address(GlobalReg, addr + INT64HIGH_OFFSET), output.high);
}
void
CodeGeneratorMIPS::visitWasmStoreGlobalVarI64(LWasmStoreGlobalVarI64* ins)
{
const MWasmStoreGlobalVar* mir = ins->mir();
unsigned addr = mir->globalDataOffset() - WasmGlobalRegBias;
MOZ_ASSERT (mir->value()->type() == MIRType::Int64);
Register64 input = ToRegister64(ins->value());
masm.store32(input.low, Address(GlobalReg, addr + INT64LOW_OFFSET));
masm.store32(input.high, Address(GlobalReg, addr + INT64HIGH_OFFSET));
}
void
CodeGeneratorMIPS::visitWasmSelectI64(LWasmSelectI64* lir)
{
MOZ_ASSERT(lir->mir()->type() == MIRType::Int64);
Register cond = ToRegister(lir->condExpr());
const LInt64Allocation trueExpr = lir->trueExpr();
const LInt64Allocation falseExpr = lir->falseExpr();
Register64 output = ToOutRegister64(lir);
masm.move64(ToRegister64(trueExpr), output);
if (falseExpr.low().isRegister()) {
masm.as_movz(output.low, ToRegister(falseExpr.low()), cond);
masm.as_movz(output.high, ToRegister(falseExpr.high()), cond);
} else {
Label done;
masm.ma_b(cond, cond, &done, Assembler::NonZero, ShortJump);
masm.loadPtr(ToAddress(falseExpr.low()), output.low);
masm.loadPtr(ToAddress(falseExpr.high()), output.high);
masm.bind(&done);
}
}
void
CodeGeneratorMIPS::visitWasmReinterpretFromI64(LWasmReinterpretFromI64* lir)
{
MOZ_ASSERT(lir->mir()->type() == MIRType::Double);
MOZ_ASSERT(lir->mir()->input()->type() == MIRType::Int64);
Register64 input = ToRegister64(lir->getInt64Operand(0));
FloatRegister output = ToFloatRegister(lir->output());
masm.moveToDoubleLo(input.low, output);
masm.moveToDoubleHi(input.high, output);
}
void
CodeGeneratorMIPS::visitWasmReinterpretToI64(LWasmReinterpretToI64* lir)
{
MOZ_ASSERT(lir->mir()->type() == MIRType::Int64);
MOZ_ASSERT(lir->mir()->input()->type() == MIRType::Double);
FloatRegister input = ToFloatRegister(lir->getOperand(0));
Register64 output = ToOutRegister64(lir);
masm.moveFromDoubleLo(input, output.low);
masm.moveFromDoubleHi(input, output.high);
}
void
CodeGeneratorMIPS::visitExtendInt32ToInt64(LExtendInt32ToInt64* lir)
{
Register input = ToRegister(lir->input());
Register64 output = ToOutRegister64(lir);
if (input != output.low)
masm.move32(input, output.low);
if (lir->mir()->isUnsigned())
masm.move32(Imm32(0), output.high);
else
masm.ma_sra(output.high, output.low, Imm32(31));
}
void
CodeGeneratorMIPS::visitWrapInt64ToInt32(LWrapInt64ToInt32* lir)
{
const LInt64Allocation& input = lir->getInt64Operand(0);
Register output = ToRegister(lir->output());
if (lir->mir()->bottomHalf())
masm.move32(ToRegister(input.low()), output);
else
masm.move32(ToRegister(input.high()), output);
}
void
CodeGeneratorMIPS::visitClzI64(LClzI64* lir)
{
Register64 input = ToRegister64(lir->getInt64Operand(0));
Register64 output = ToOutRegister64(lir);
masm.clz64(input, output.low);
masm.move32(Imm32(0), output.high);
}
void
CodeGeneratorMIPS::visitCtzI64(LCtzI64* lir)
{
Register64 input = ToRegister64(lir->getInt64Operand(0));
Register64 output = ToOutRegister64(lir);
masm.ctz64(input, output.low);
masm.move32(Imm32(0), output.high);
}
void
CodeGeneratorMIPS::visitNotI64(LNotI64* lir)
{
Register64 input = ToRegister64(lir->getInt64Operand(0));
Register output = ToRegister(lir->output());
masm.as_or(output, input.low, input.high);
masm.cmp32Set(Assembler::Equal, output, Imm32(0), output);
}
void
CodeGeneratorMIPS::visitWasmTruncateToInt64(LWasmTruncateToInt64* lir)
{
FloatRegister input = ToFloatRegister(lir->input());
FloatRegister scratch = input;
Register64 output = ToOutRegister64(lir);
MWasmTruncateToInt64* mir = lir->mir();
MIRType fromType = mir->input()->type();
auto* ool = new(alloc()) OutOfLineWasmTruncateCheck(mir, input);
addOutOfLineCode(ool, mir);
if (fromType == MIRType::Double) {
masm.branchDouble(Assembler::DoubleUnordered, input, input, ool->entry());
} else if (fromType == MIRType::Float32) {
masm.branchFloat(Assembler::DoubleUnordered, input, input, ool->entry());
scratch = ScratchDoubleReg;
masm.convertFloat32ToDouble(input, scratch);
} else {
MOZ_CRASH("unexpected type in visitOutOfLineWasmTruncateCheck");
}
masm.setupUnalignedABICall(output.high);
masm.passABIArg(scratch, MoveOp::DOUBLE);
if (lir->mir()->isUnsigned())
masm.callWithABI(wasm::SymbolicAddress::TruncateDoubleToUint64);
else
masm.callWithABI(wasm::SymbolicAddress::TruncateDoubleToInt64);
masm.ma_b(output.high, Imm32(0x80000000), ool->rejoin(), Assembler::NotEqual);
masm.ma_b(output.low, Imm32(0x00000000), ool->rejoin(), Assembler::NotEqual);
masm.ma_b(ool->entry());
masm.bind(ool->rejoin());
MOZ_ASSERT(ReturnReg64 == output);
}
void
CodeGeneratorMIPS::visitInt64ToFloatingPoint(LInt64ToFloatingPoint* lir)
{
Register64 input = ToRegister64(lir->getInt64Operand(0));
FloatRegister output = ToFloatRegister(lir->output());
MInt64ToFloatingPoint* mir = lir->mir();
MIRType toType = mir->type();
AllocatableGeneralRegisterSet regs(GeneralRegisterSet::All());
regs.take(input.low);
regs.take(input.high);
Register temp = regs.takeAny();
masm.setupUnalignedABICall(temp);
masm.passABIArg(input.high);
masm.passABIArg(input.low);
if (lir->mir()->isUnsigned())
masm.callWithABI(wasm::SymbolicAddress::Uint64ToFloatingPoint, MoveOp::DOUBLE);
else
masm.callWithABI(wasm::SymbolicAddress::Int64ToFloatingPoint, MoveOp::DOUBLE);
MOZ_ASSERT_IF(toType == MIRType::Double, output == ReturnDoubleReg);
if (toType == MIRType::Float32) {
MOZ_ASSERT(output == ReturnFloat32Reg);
masm.convertDoubleToFloat32(ReturnDoubleReg, output);
}
}
void
CodeGeneratorMIPS::visitTestI64AndBranch(LTestI64AndBranch* lir)
{
Register64 input = ToRegister64(lir->getInt64Operand(0));
branchToBlock(input.high, Imm32(0), lir->ifTrue(), Assembler::NonZero);
emitBranch(input.low, Imm32(0), Assembler::NonZero, lir->ifTrue(), lir->ifFalse());
}
void
CodeGeneratorMIPS::setReturnDoubleRegs(LiveRegisterSet* regs)
{
MOZ_ASSERT(ReturnFloat32Reg.code_ == ReturnDoubleReg.code_);
regs->add(ReturnFloat32Reg);
regs->add(ReturnDoubleReg.singleOverlay(1));
regs->add(ReturnDoubleReg);
}