/* -*- 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/x64/CodeGenerator-x64.h"
#include "mozilla/MathAlgorithms.h"
#include "jit/IonCaches.h"
#include "jit/MIR.h"
#include "jsscriptinlines.h"
#include "jit/MacroAssembler-inl.h"
#include "jit/shared/CodeGenerator-shared-inl.h"
using namespace js;
using namespace js::jit;
using mozilla::DebugOnly;
CodeGeneratorX64::CodeGeneratorX64(MIRGenerator* gen, LIRGraph* graph, MacroAssembler* masm)
: CodeGeneratorX86Shared(gen, graph, masm)
{
}
ValueOperand
CodeGeneratorX64::ToValue(LInstruction* ins, size_t pos)
{
return ValueOperand(ToRegister(ins->getOperand(pos)));
}
ValueOperand
CodeGeneratorX64::ToOutValue(LInstruction* ins)
{
return ValueOperand(ToRegister(ins->getDef(0)));
}
ValueOperand
CodeGeneratorX64::ToTempValue(LInstruction* ins, size_t pos)
{
return ValueOperand(ToRegister(ins->getTemp(pos)));
}
Operand
CodeGeneratorX64::ToOperand64(const LInt64Allocation& a64)
{
const LAllocation& a = a64.value();
MOZ_ASSERT(!a.isFloatReg());
if (a.isGeneralReg())
return Operand(a.toGeneralReg()->reg());
return Operand(masm.getStackPointer(), ToStackOffset(a));
}
FrameSizeClass
FrameSizeClass::FromDepth(uint32_t frameDepth)
{
return FrameSizeClass::None();
}
FrameSizeClass
FrameSizeClass::ClassLimit()
{
return FrameSizeClass(0);
}
uint32_t
FrameSizeClass::frameSize() const
{
MOZ_CRASH("x64 does not use frame size classes");
}
void
CodeGeneratorX64::visitValue(LValue* value)
{
LDefinition* reg = value->getDef(0);
masm.moveValue(value->value(), ToRegister(reg));
}
void
CodeGeneratorX64::visitBox(LBox* box)
{
const LAllocation* in = box->getOperand(0);
const LDefinition* result = box->getDef(0);
if (IsFloatingPointType(box->type())) {
ScratchDoubleScope scratch(masm);
FloatRegister reg = ToFloatRegister(in);
if (box->type() == MIRType::Float32) {
masm.convertFloat32ToDouble(reg, scratch);
reg = scratch;
}
masm.vmovq(reg, ToRegister(result));
} else {
masm.boxValue(ValueTypeFromMIRType(box->type()), ToRegister(in), ToRegister(result));
}
}
void
CodeGeneratorX64::visitUnbox(LUnbox* unbox)
{
MUnbox* mir = unbox->mir();
if (mir->fallible()) {
const ValueOperand value = ToValue(unbox, LUnbox::Input);
Assembler::Condition cond;
switch (mir->type()) {
case MIRType::Int32:
cond = masm.testInt32(Assembler::NotEqual, value);
break;
case MIRType::Boolean:
cond = masm.testBoolean(Assembler::NotEqual, value);
break;
case MIRType::Object:
cond = masm.testObject(Assembler::NotEqual, value);
break;
case MIRType::String:
cond = masm.testString(Assembler::NotEqual, value);
break;
case MIRType::Symbol:
cond = masm.testSymbol(Assembler::NotEqual, value);
break;
default:
MOZ_CRASH("Given MIRType cannot be unboxed.");
}
bailoutIf(cond, unbox->snapshot());
}
Operand input = ToOperand(unbox->getOperand(LUnbox::Input));
Register result = ToRegister(unbox->output());
switch (mir->type()) {
case MIRType::Int32:
masm.unboxInt32(input, result);
break;
case MIRType::Boolean:
masm.unboxBoolean(input, result);
break;
case MIRType::Object:
masm.unboxObject(input, result);
break;
case MIRType::String:
masm.unboxString(input, result);
break;
case MIRType::Symbol:
masm.unboxSymbol(input, result);
break;
default:
MOZ_CRASH("Given MIRType cannot be unboxed.");
}
}
void
CodeGeneratorX64::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);
// Load boxed boolean in ScratchReg.
ScratchRegisterScope scratch(masm);
if (rhs->isConstant())
masm.moveValue(rhs->toConstant()->toJSValue(), scratch);
else
masm.boxValue(JSVAL_TYPE_BOOLEAN, ToRegister(rhs), scratch);
// Perform the comparison.
masm.cmpPtr(lhs.valueReg(), scratch);
masm.emitSet(JSOpToCondition(mir->compareType(), mir->jsop()), output);
}
void
CodeGeneratorX64::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);
// Load boxed boolean in ScratchReg.
ScratchRegisterScope scratch(masm);
if (rhs->isConstant())
masm.moveValue(rhs->toConstant()->toJSValue(), scratch);
else
masm.boxValue(JSVAL_TYPE_BOOLEAN, ToRegister(rhs), scratch);
// Perform the comparison.
masm.cmpPtr(lhs.valueReg(), scratch);
emitBranch(JSOpToCondition(mir->compareType(), mir->jsop()), lir->ifTrue(), lir->ifFalse());
}
void
CodeGeneratorX64::visitCompareBitwise(LCompareBitwise* lir)
{
MCompare* mir = lir->mir();
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()));
masm.cmpPtr(lhs.valueReg(), rhs.valueReg());
masm.emitSet(JSOpToCondition(mir->compareType(), mir->jsop()), output);
}
void
CodeGeneratorX64::visitCompareBitwiseAndBranch(LCompareBitwiseAndBranch* lir)
{
MCompare* mir = lir->cmpMir();
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);
masm.cmpPtr(lhs.valueReg(), rhs.valueReg());
emitBranch(JSOpToCondition(mir->compareType(), mir->jsop()), lir->ifTrue(), lir->ifFalse());
}
void
CodeGeneratorX64::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);
Register lhsReg = ToRegister64(lhs).reg;
Register output = ToRegister(lir->output());
if (IsConstant(rhs))
masm.cmpPtr(lhsReg, ImmWord(ToInt64(rhs)));
else
masm.cmpPtr(lhsReg, ToOperand64(rhs));
bool isSigned = mir->compareType() == MCompare::Compare_Int64;
masm.emitSet(JSOpToCondition(lir->jsop(), isSigned), output);
}
void
CodeGeneratorX64::visitCompareI64AndBranch(LCompareI64AndBranch* lir)
{
MCompare* mir = lir->cmpMir();
MOZ_ASSERT(mir->compareType() == MCompare::Compare_Int64 ||
mir->compareType() == MCompare::Compare_UInt64);
LInt64Allocation lhs = lir->getInt64Operand(LCompareI64::Lhs);
LInt64Allocation rhs = lir->getInt64Operand(LCompareI64::Rhs);
Register lhsReg = ToRegister64(lhs).reg;
if (IsConstant(rhs))
masm.cmpPtr(lhsReg, ImmWord(ToInt64(rhs)));
else
masm.cmpPtr(lhsReg, ToOperand64(rhs));
bool isSigned = mir->compareType() == MCompare::Compare_Int64;
emitBranch(JSOpToCondition(lir->jsop(), isSigned), lir->ifTrue(), lir->ifFalse());
}
void
CodeGeneratorX64::visitDivOrModI64(LDivOrModI64* lir)
{
Register lhs = ToRegister(lir->lhs());
Register rhs = ToRegister(lir->rhs());
Register output = ToRegister(lir->output());
MOZ_ASSERT_IF(lhs != rhs, rhs != rax);
MOZ_ASSERT(rhs != rdx);
MOZ_ASSERT_IF(output == rax, ToRegister(lir->remainder()) == rdx);
MOZ_ASSERT_IF(output == rdx, ToRegister(lir->remainder()) == rax);
Label done;
// Put the lhs in rax.
if (lhs != rax)
masm.mov(lhs, rax);
// Handle divide by zero.
if (lir->canBeDivideByZero()) {
masm.branchTestPtr(Assembler::Zero, rhs, rhs, trap(lir, wasm::Trap::IntegerDivideByZero));
}
// Handle an integer overflow exception from INT64_MIN / -1.
if (lir->canBeNegativeOverflow()) {
Label notmin;
masm.branchPtr(Assembler::NotEqual, lhs, ImmWord(INT64_MIN), ¬min);
masm.branchPtr(Assembler::NotEqual, rhs, ImmWord(-1), ¬min);
if (lir->mir()->isMod())
masm.xorl(output, output);
else
masm.jump(trap(lir, wasm::Trap::IntegerOverflow));
masm.jump(&done);
masm.bind(¬min);
}
// Sign extend the lhs into rdx to make rdx:rax.
masm.cqo();
masm.idivq(rhs);
masm.bind(&done);
}
void
CodeGeneratorX64::visitUDivOrModI64(LUDivOrModI64* lir)
{
Register lhs = ToRegister(lir->lhs());
Register rhs = ToRegister(lir->rhs());
DebugOnly<Register> output = ToRegister(lir->output());
MOZ_ASSERT_IF(lhs != rhs, rhs != rax);
MOZ_ASSERT(rhs != rdx);
MOZ_ASSERT_IF(output.value == rax, ToRegister(lir->remainder()) == rdx);
MOZ_ASSERT_IF(output.value == rdx, ToRegister(lir->remainder()) == rax);
// Put the lhs in rax.
if (lhs != rax)
masm.mov(lhs, rax);
Label done;
// Prevent divide by zero.
if (lir->canBeDivideByZero())
masm.branchTestPtr(Assembler::Zero, rhs, rhs, trap(lir, wasm::Trap::IntegerDivideByZero));
// Zero extend the lhs into rdx to make (rdx:rax).
masm.xorl(rdx, rdx);
masm.udivq(rhs);
masm.bind(&done);
}
void
CodeGeneratorX64::visitWasmSelectI64(LWasmSelectI64* lir)
{
MOZ_ASSERT(lir->mir()->type() == MIRType::Int64);
Register cond = ToRegister(lir->condExpr());
Operand falseExpr = ToOperandOrRegister64(lir->falseExpr());
Register64 out = ToOutRegister64(lir);
MOZ_ASSERT(ToRegister64(lir->trueExpr()) == out, "true expr is reused for input");
masm.test32(cond, cond);
masm.cmovzq(falseExpr, out.reg);
}
void
CodeGeneratorX64::visitWasmReinterpretFromI64(LWasmReinterpretFromI64* lir)
{
MOZ_ASSERT(lir->mir()->type() == MIRType::Double);
MOZ_ASSERT(lir->mir()->input()->type() == MIRType::Int64);
masm.vmovq(ToRegister(lir->input()), ToFloatRegister(lir->output()));
}
void
CodeGeneratorX64::visitWasmReinterpretToI64(LWasmReinterpretToI64* lir)
{
MOZ_ASSERT(lir->mir()->type() == MIRType::Int64);
MOZ_ASSERT(lir->mir()->input()->type() == MIRType::Double);
masm.vmovq(ToFloatRegister(lir->input()), ToRegister(lir->output()));
}
void
CodeGeneratorX64::visitWasmUint32ToDouble(LWasmUint32ToDouble* lir)
{
masm.convertUInt32ToDouble(ToRegister(lir->input()), ToFloatRegister(lir->output()));
}
void
CodeGeneratorX64::visitWasmUint32ToFloat32(LWasmUint32ToFloat32* lir)
{
masm.convertUInt32ToFloat32(ToRegister(lir->input()), ToFloatRegister(lir->output()));
}
void
CodeGeneratorX64::visitLoadTypedArrayElementStatic(LLoadTypedArrayElementStatic* ins)
{
MOZ_CRASH("NYI");
}
void
CodeGeneratorX64::visitStoreTypedArrayElementStatic(LStoreTypedArrayElementStatic* ins)
{
MOZ_CRASH("NYI");
}
void
CodeGeneratorX64::visitWasmCall(LWasmCall* ins)
{
emitWasmCallBase(ins);
}
void
CodeGeneratorX64::visitWasmCallI64(LWasmCallI64* ins)
{
emitWasmCallBase(ins);
}
void
CodeGeneratorX64::wasmStore(const wasm::MemoryAccessDesc& access, const LAllocation* value,
Operand dstAddr)
{
if (value->isConstant()) {
MOZ_ASSERT(!access.isSimd());
masm.memoryBarrier(access.barrierBefore());
const MConstant* mir = value->toConstant();
Imm32 cst = Imm32(mir->type() == MIRType::Int32 ? mir->toInt32() : mir->toInt64());
size_t storeOffset = masm.size();
switch (access.type()) {
case Scalar::Int8:
case Scalar::Uint8:
masm.movb(cst, dstAddr);
break;
case Scalar::Int16:
case Scalar::Uint16:
masm.movw(cst, dstAddr);
break;
case Scalar::Int32:
case Scalar::Uint32:
masm.movl(cst, dstAddr);
break;
case Scalar::Int64:
case Scalar::Float32:
case Scalar::Float64:
case Scalar::Float32x4:
case Scalar::Int8x16:
case Scalar::Int16x8:
case Scalar::Int32x4:
case Scalar::Uint8Clamped:
case Scalar::MaxTypedArrayViewType:
MOZ_CRASH("unexpected array type");
}
masm.append(access, storeOffset, masm.framePushed());
masm.memoryBarrier(access.barrierAfter());
} else {
masm.wasmStore(access, ToAnyRegister(value), dstAddr);
}
}
template <typename T>
void
CodeGeneratorX64::emitWasmLoad(T* ins)
{
const MWasmLoad* mir = ins->mir();
uint32_t offset = mir->access().offset();
MOZ_ASSERT(offset < wasm::OffsetGuardLimit);
const LAllocation* ptr = ins->ptr();
Operand srcAddr = ptr->isBogus()
? Operand(HeapReg, offset)
: Operand(HeapReg, ToRegister(ptr), TimesOne, offset);
if (mir->type() == MIRType::Int64)
masm.wasmLoadI64(mir->access(), srcAddr, ToOutRegister64(ins));
else
masm.wasmLoad(mir->access(), srcAddr, ToAnyRegister(ins->output()));
}
void
CodeGeneratorX64::visitWasmLoad(LWasmLoad* ins)
{
emitWasmLoad(ins);
}
void
CodeGeneratorX64::visitWasmLoadI64(LWasmLoadI64* ins)
{
emitWasmLoad(ins);
}
template <typename T>
void
CodeGeneratorX64::emitWasmStore(T* ins)
{
const MWasmStore* mir = ins->mir();
uint32_t offset = mir->access().offset();
MOZ_ASSERT(offset < wasm::OffsetGuardLimit);
const LAllocation* value = ins->getOperand(ins->ValueIndex);
const LAllocation* ptr = ins->ptr();
Operand dstAddr = ptr->isBogus()
? Operand(HeapReg, offset)
: Operand(HeapReg, ToRegister(ptr), TimesOne, offset);
wasmStore(mir->access(), value, dstAddr);
}
void
CodeGeneratorX64::visitWasmStore(LWasmStore* ins)
{
emitWasmStore(ins);
}
void
CodeGeneratorX64::visitWasmStoreI64(LWasmStoreI64* ins)
{
emitWasmStore(ins);
}
void
CodeGeneratorX64::visitAsmJSLoadHeap(LAsmJSLoadHeap* ins)
{
const MAsmJSLoadHeap* mir = ins->mir();
MOZ_ASSERT(mir->offset() < wasm::OffsetGuardLimit);
const LAllocation* ptr = ins->ptr();
const LDefinition* out = ins->output();
Scalar::Type accessType = mir->access().type();
MOZ_ASSERT(!Scalar::isSimdType(accessType));
Operand srcAddr = ptr->isBogus()
? Operand(HeapReg, mir->offset())
: Operand(HeapReg, ToRegister(ptr), TimesOne, mir->offset());
uint32_t before = masm.size();
masm.wasmLoad(mir->access(), srcAddr, ToAnyRegister(out));
uint32_t after = masm.size();
verifyLoadDisassembly(before, after, accessType, srcAddr, *out->output());
}
void
CodeGeneratorX64::visitAsmJSStoreHeap(LAsmJSStoreHeap* ins)
{
const MAsmJSStoreHeap* mir = ins->mir();
MOZ_ASSERT(mir->offset() < wasm::OffsetGuardLimit);
const LAllocation* ptr = ins->ptr();
const LAllocation* value = ins->value();
Scalar::Type accessType = mir->access().type();
MOZ_ASSERT(!Scalar::isSimdType(accessType));
canonicalizeIfDeterministic(accessType, value);
Operand dstAddr = ptr->isBogus()
? Operand(HeapReg, mir->offset())
: Operand(HeapReg, ToRegister(ptr), TimesOne, mir->offset());
uint32_t before = masm.size();
wasmStore(mir->access(), value, dstAddr);
uint32_t after = masm.size();
verifyStoreDisassembly(before, after, accessType, dstAddr, *value);
}
void
CodeGeneratorX64::visitAsmJSCompareExchangeHeap(LAsmJSCompareExchangeHeap* ins)
{
MAsmJSCompareExchangeHeap* mir = ins->mir();
MOZ_ASSERT(mir->access().offset() == 0);
Register ptr = ToRegister(ins->ptr());
Register oldval = ToRegister(ins->oldValue());
Register newval = ToRegister(ins->newValue());
MOZ_ASSERT(ins->addrTemp()->isBogusTemp());
Scalar::Type accessType = mir->access().type();
BaseIndex srcAddr(HeapReg, ptr, TimesOne);
masm.compareExchangeToTypedIntArray(accessType == Scalar::Uint32 ? Scalar::Int32 : accessType,
srcAddr,
oldval,
newval,
InvalidReg,
ToAnyRegister(ins->output()));
}
void
CodeGeneratorX64::visitAsmJSAtomicExchangeHeap(LAsmJSAtomicExchangeHeap* ins)
{
MAsmJSAtomicExchangeHeap* mir = ins->mir();
MOZ_ASSERT(mir->access().offset() == 0);
Register ptr = ToRegister(ins->ptr());
Register value = ToRegister(ins->value());
MOZ_ASSERT(ins->addrTemp()->isBogusTemp());
Scalar::Type accessType = mir->access().type();
MOZ_ASSERT(accessType <= Scalar::Uint32);
BaseIndex srcAddr(HeapReg, ptr, TimesOne);
masm.atomicExchangeToTypedIntArray(accessType == Scalar::Uint32 ? Scalar::Int32 : accessType,
srcAddr,
value,
InvalidReg,
ToAnyRegister(ins->output()));
}
void
CodeGeneratorX64::visitAsmJSAtomicBinopHeap(LAsmJSAtomicBinopHeap* ins)
{
MAsmJSAtomicBinopHeap* mir = ins->mir();
MOZ_ASSERT(mir->access().offset() == 0);
MOZ_ASSERT(mir->hasUses());
Register ptr = ToRegister(ins->ptr());
const LAllocation* value = ins->value();
Register temp = ins->temp()->isBogusTemp() ? InvalidReg : ToRegister(ins->temp());
AnyRegister output = ToAnyRegister(ins->output());
MOZ_ASSERT(ins->addrTemp()->isBogusTemp());
Scalar::Type accessType = mir->access().type();
if (accessType == Scalar::Uint32)
accessType = Scalar::Int32;
AtomicOp op = mir->operation();
BaseIndex srcAddr(HeapReg, ptr, TimesOne);
if (value->isConstant()) {
atomicBinopToTypedIntArray(op, accessType, Imm32(ToInt32(value)), srcAddr, temp, InvalidReg,
output);
} else {
atomicBinopToTypedIntArray(op, accessType, ToRegister(value), srcAddr, temp, InvalidReg,
output);
}
}
void
CodeGeneratorX64::visitAsmJSAtomicBinopHeapForEffect(LAsmJSAtomicBinopHeapForEffect* ins)
{
MAsmJSAtomicBinopHeap* mir = ins->mir();
MOZ_ASSERT(mir->access().offset() == 0);
MOZ_ASSERT(!mir->hasUses());
Register ptr = ToRegister(ins->ptr());
const LAllocation* value = ins->value();
MOZ_ASSERT(ins->addrTemp()->isBogusTemp());
Scalar::Type accessType = mir->access().type();
AtomicOp op = mir->operation();
BaseIndex srcAddr(HeapReg, ptr, TimesOne);
if (value->isConstant())
atomicBinopToTypedIntArray(op, accessType, Imm32(ToInt32(value)), srcAddr);
else
atomicBinopToTypedIntArray(op, accessType, ToRegister(value), srcAddr);
}
void
CodeGeneratorX64::visitWasmLoadGlobalVar(LWasmLoadGlobalVar* ins)
{
MWasmLoadGlobalVar* mir = ins->mir();
MIRType type = mir->type();
MOZ_ASSERT(IsNumberType(type) || IsSimdType(type));
CodeOffset label;
switch (type) {
case MIRType::Int32:
label = masm.loadRipRelativeInt32(ToRegister(ins->output()));
break;
case MIRType::Float32:
label = masm.loadRipRelativeFloat32(ToFloatRegister(ins->output()));
break;
case MIRType::Double:
label = masm.loadRipRelativeDouble(ToFloatRegister(ins->output()));
break;
// Aligned access: code is aligned on PageSize + there is padding
// before the global data section.
case MIRType::Int8x16:
case MIRType::Int16x8:
case MIRType::Int32x4:
case MIRType::Bool8x16:
case MIRType::Bool16x8:
case MIRType::Bool32x4:
label = masm.loadRipRelativeInt32x4(ToFloatRegister(ins->output()));
break;
case MIRType::Float32x4:
label = masm.loadRipRelativeFloat32x4(ToFloatRegister(ins->output()));
break;
default:
MOZ_CRASH("unexpected type in visitWasmLoadGlobalVar");
}
masm.append(wasm::GlobalAccess(label, mir->globalDataOffset()));
}
void
CodeGeneratorX64::visitWasmLoadGlobalVarI64(LWasmLoadGlobalVarI64* ins)
{
MWasmLoadGlobalVar* mir = ins->mir();
MOZ_ASSERT(mir->type() == MIRType::Int64);
CodeOffset label = masm.loadRipRelativeInt64(ToRegister(ins->output()));
masm.append(wasm::GlobalAccess(label, mir->globalDataOffset()));
}
void
CodeGeneratorX64::visitWasmStoreGlobalVar(LWasmStoreGlobalVar* ins)
{
MWasmStoreGlobalVar* mir = ins->mir();
MIRType type = mir->value()->type();
MOZ_ASSERT(IsNumberType(type) || IsSimdType(type));
CodeOffset label;
switch (type) {
case MIRType::Int32:
label = masm.storeRipRelativeInt32(ToRegister(ins->value()));
break;
case MIRType::Float32:
label = masm.storeRipRelativeFloat32(ToFloatRegister(ins->value()));
break;
case MIRType::Double:
label = masm.storeRipRelativeDouble(ToFloatRegister(ins->value()));
break;
// Aligned access: code is aligned on PageSize + there is padding
// before the global data section.
case MIRType::Int32x4:
case MIRType::Bool32x4:
label = masm.storeRipRelativeInt32x4(ToFloatRegister(ins->value()));
break;
case MIRType::Float32x4:
label = masm.storeRipRelativeFloat32x4(ToFloatRegister(ins->value()));
break;
default:
MOZ_CRASH("unexpected type in visitWasmStoreGlobalVar");
}
masm.append(wasm::GlobalAccess(label, mir->globalDataOffset()));
}
void
CodeGeneratorX64::visitWasmStoreGlobalVarI64(LWasmStoreGlobalVarI64* ins)
{
MWasmStoreGlobalVar* mir = ins->mir();
MOZ_ASSERT(mir->value()->type() == MIRType::Int64);
Register value = ToRegister(ins->getOperand(LWasmStoreGlobalVarI64::InputIndex));
CodeOffset label = masm.storeRipRelativeInt64(value);
masm.append(wasm::GlobalAccess(label, mir->globalDataOffset()));
}
void
CodeGeneratorX64::visitTruncateDToInt32(LTruncateDToInt32* ins)
{
FloatRegister input = ToFloatRegister(ins->input());
Register output = ToRegister(ins->output());
// On x64, branchTruncateDouble uses vcvttsd2sq. Unlike the x86
// implementation, this should handle most doubles and we can just
// call a stub if it fails.
emitTruncateDouble(input, output, ins->mir());
}
void
CodeGeneratorX64::visitTruncateFToInt32(LTruncateFToInt32* ins)
{
FloatRegister input = ToFloatRegister(ins->input());
Register output = ToRegister(ins->output());
// On x64, branchTruncateFloat32 uses vcvttss2sq. Unlike the x86
// implementation, this should handle most floats and we can just
// call a stub if it fails.
emitTruncateFloat32(input, output, ins->mir());
}
void
CodeGeneratorX64::visitWrapInt64ToInt32(LWrapInt64ToInt32* lir)
{
const LAllocation* input = lir->getOperand(0);
Register output = ToRegister(lir->output());
if (lir->mir()->bottomHalf())
masm.movl(ToOperand(input), output);
else
MOZ_CRASH("Not implemented.");
}
void
CodeGeneratorX64::visitExtendInt32ToInt64(LExtendInt32ToInt64* lir)
{
const LAllocation* input = lir->getOperand(0);
Register output = ToRegister(lir->output());
if (lir->mir()->isUnsigned())
masm.movl(ToOperand(input), output);
else
masm.movslq(ToOperand(input), output);
}
void
CodeGeneratorX64::visitWasmTruncateToInt64(LWasmTruncateToInt64* lir)
{
FloatRegister input = ToFloatRegister(lir->input());
Register64 output = ToOutRegister64(lir);
MWasmTruncateToInt64* mir = lir->mir();
MIRType inputType = mir->input()->type();
MOZ_ASSERT(inputType == MIRType::Double || inputType == MIRType::Float32);
auto* ool = new(alloc()) OutOfLineWasmTruncateCheck(mir, input);
addOutOfLineCode(ool, mir);
FloatRegister temp = mir->isUnsigned() ? ToFloatRegister(lir->temp()) : InvalidFloatReg;
Label* oolEntry = ool->entry();
Label* oolRejoin = ool->rejoin();
if (inputType == MIRType::Double) {
if (mir->isUnsigned())
masm.wasmTruncateDoubleToUInt64(input, output, oolEntry, oolRejoin, temp);
else
masm.wasmTruncateDoubleToInt64(input, output, oolEntry, oolRejoin, temp);
} else {
if (mir->isUnsigned())
masm.wasmTruncateFloat32ToUInt64(input, output, oolEntry, oolRejoin, temp);
else
masm.wasmTruncateFloat32ToInt64(input, output, oolEntry, oolRejoin, temp);
}
}
void
CodeGeneratorX64::visitInt64ToFloatingPoint(LInt64ToFloatingPoint* lir)
{
Register64 input = ToRegister64(lir->getInt64Operand(0));
FloatRegister output = ToFloatRegister(lir->output());
MIRType outputType = lir->mir()->type();
MOZ_ASSERT(outputType == MIRType::Double || outputType == MIRType::Float32);
if (outputType == MIRType::Double) {
if (lir->mir()->isUnsigned())
masm.convertUInt64ToDouble(input, output, Register::Invalid());
else
masm.convertInt64ToDouble(input, output);
} else {
if (lir->mir()->isUnsigned())
masm.convertUInt64ToFloat32(input, output, Register::Invalid());
else
masm.convertInt64ToFloat32(input, output);
}
}
void
CodeGeneratorX64::visitNotI64(LNotI64* lir)
{
masm.cmpq(Imm32(0), ToRegister(lir->input()));
masm.emitSet(Assembler::Equal, ToRegister(lir->output()));
}
void
CodeGeneratorX64::visitClzI64(LClzI64* lir)
{
Register64 input = ToRegister64(lir->getInt64Operand(0));
Register64 output = ToOutRegister64(lir);
masm.clz64(input, output.reg);
}
void
CodeGeneratorX64::visitCtzI64(LCtzI64* lir)
{
Register64 input = ToRegister64(lir->getInt64Operand(0));
Register64 output = ToOutRegister64(lir);
masm.ctz64(input, output.reg);
}
void
CodeGeneratorX64::visitTestI64AndBranch(LTestI64AndBranch* lir)
{
Register input = ToRegister(lir->input());
masm.testq(input, input);
emitBranch(Assembler::NonZero, lir->ifTrue(), lir->ifFalse());
}