/* -*- 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/x86/MacroAssembler-x86.h"
#include "mozilla/Alignment.h"
#include "mozilla/Casting.h"
#include "jit/Bailouts.h"
#include "jit/BaselineFrame.h"
#include "jit/JitFrames.h"
#include "jit/MacroAssembler.h"
#include "jit/MoveEmitter.h"
#include "jsscriptinlines.h"
#include "jit/MacroAssembler-inl.h"
using namespace js;
using namespace js::jit;
// vpunpckldq requires 16-byte boundary for memory operand.
// See convertUInt64ToDouble for the details.
MOZ_ALIGNED_DECL(static const uint64_t, 16) TO_DOUBLE[4] = {
0x4530000043300000LL,
0x0LL,
0x4330000000000000LL,
0x4530000000000000LL
};
static const double TO_DOUBLE_HIGH_SCALE = 0x100000000;
bool
MacroAssemblerX86::convertUInt64ToDoubleNeedsTemp()
{
return HasSSE3();
}
void
MacroAssemblerX86::convertUInt64ToDouble(Register64 src, FloatRegister dest, Register temp)
{
// SUBPD needs SSE2, HADDPD needs SSE3.
if (!HasSSE3()) {
MOZ_ASSERT(temp == Register::Invalid());
// Zero the dest register to break dependencies, see convertInt32ToDouble.
zeroDouble(dest);
asMasm().Push(src.high);
asMasm().Push(src.low);
fild(Operand(esp, 0));
Label notNegative;
asMasm().branch32(Assembler::NotSigned, src.high, Imm32(0), ¬Negative);
double add_constant = 18446744073709551616.0; // 2^64
store64(Imm64(mozilla::BitwiseCast<uint64_t>(add_constant)), Address(esp, 0));
fld(Operand(esp, 0));
faddp();
bind(¬Negative);
fstp(Operand(esp, 0));
vmovsd(Address(esp, 0), dest);
asMasm().freeStack(2*sizeof(intptr_t));
return;
}
// Following operation uses entire 128-bit of dest XMM register.
// Currently higher 64-bit is free when we have access to lower 64-bit.
MOZ_ASSERT(dest.size() == 8);
FloatRegister dest128 = FloatRegister(dest.encoding(), FloatRegisters::Simd128);
// Assume that src is represented as following:
// src = 0x HHHHHHHH LLLLLLLL
// Move src to dest (=dest128) and ScratchInt32x4Reg (=scratch):
// dest = 0x 00000000 00000000 00000000 LLLLLLLL
// scratch = 0x 00000000 00000000 00000000 HHHHHHHH
vmovd(src.low, dest128);
vmovd(src.high, ScratchSimd128Reg);
// Unpack and interleave dest and scratch to dest:
// dest = 0x 00000000 00000000 HHHHHHHH LLLLLLLL
vpunpckldq(ScratchSimd128Reg, dest128, dest128);
// Unpack and interleave dest and a constant C1 to dest:
// C1 = 0x 00000000 00000000 45300000 43300000
// dest = 0x 45300000 HHHHHHHH 43300000 LLLLLLLL
// here, each 64-bit part of dest represents following double:
// HI(dest) = 0x 1.00000HHHHHHHH * 2**84 == 2**84 + 0x HHHHHHHH 00000000
// LO(dest) = 0x 1.00000LLLLLLLL * 2**52 == 2**52 + 0x 00000000 LLLLLLLL
movePtr(ImmWord((uintptr_t)TO_DOUBLE), temp);
vpunpckldq(Operand(temp, 0), dest128, dest128);
// Subtract a constant C2 from dest, for each 64-bit part:
// C2 = 0x 45300000 00000000 43300000 00000000
// here, each 64-bit part of C2 represents following double:
// HI(C2) = 0x 1.0000000000000 * 2**84 == 2**84
// LO(C2) = 0x 1.0000000000000 * 2**52 == 2**52
// after the operation each 64-bit part of dest represents following:
// HI(dest) = double(0x HHHHHHHH 00000000)
// LO(dest) = double(0x 00000000 LLLLLLLL)
vsubpd(Operand(temp, sizeof(uint64_t) * 2), dest128, dest128);
// Add HI(dest) and LO(dest) in double and store it into LO(dest),
// LO(dest) = double(0x HHHHHHHH 00000000) + double(0x 00000000 LLLLLLLL)
// = double(0x HHHHHHHH LLLLLLLL)
// = double(src)
vhaddpd(dest128, dest128);
}
void
MacroAssemblerX86::loadConstantDouble(wasm::RawF64 d, FloatRegister dest)
{
if (maybeInlineDouble(d, dest))
return;
Double* dbl = getDouble(d);
if (!dbl)
return;
masm.vmovsd_mr(nullptr, dest.encoding());
propagateOOM(dbl->uses.append(CodeOffset(masm.size())));
}
void
MacroAssemblerX86::loadConstantDouble(double d, FloatRegister dest)
{
loadConstantDouble(wasm::RawF64(d), dest);
}
void
MacroAssemblerX86::loadConstantFloat32(wasm::RawF32 f, FloatRegister dest)
{
if (maybeInlineFloat(f, dest))
return;
Float* flt = getFloat(f);
if (!flt)
return;
masm.vmovss_mr(nullptr, dest.encoding());
propagateOOM(flt->uses.append(CodeOffset(masm.size())));
}
void
MacroAssemblerX86::loadConstantFloat32(float f, FloatRegister dest)
{
loadConstantFloat32(wasm::RawF32(f), dest);
}
void
MacroAssemblerX86::loadConstantSimd128Int(const SimdConstant& v, FloatRegister dest)
{
if (maybeInlineSimd128Int(v, dest))
return;
SimdData* i4 = getSimdData(v);
if (!i4)
return;
masm.vmovdqa_mr(nullptr, dest.encoding());
propagateOOM(i4->uses.append(CodeOffset(masm.size())));
}
void
MacroAssemblerX86::loadConstantSimd128Float(const SimdConstant& v, FloatRegister dest)
{
if (maybeInlineSimd128Float(v, dest))
return;
SimdData* f4 = getSimdData(v);
if (!f4)
return;
masm.vmovaps_mr(nullptr, dest.encoding());
propagateOOM(f4->uses.append(CodeOffset(masm.size())));
}
void
MacroAssemblerX86::finish()
{
if (!doubles_.empty())
masm.haltingAlign(sizeof(double));
for (const Double& d : doubles_) {
CodeOffset cst(masm.currentOffset());
for (CodeOffset use : d.uses)
addCodeLabel(CodeLabel(use, cst));
masm.int64Constant(d.value);
if (!enoughMemory_)
return;
}
if (!floats_.empty())
masm.haltingAlign(sizeof(float));
for (const Float& f : floats_) {
CodeOffset cst(masm.currentOffset());
for (CodeOffset use : f.uses)
addCodeLabel(CodeLabel(use, cst));
masm.int32Constant(f.value);
if (!enoughMemory_)
return;
}
// SIMD memory values must be suitably aligned.
if (!simds_.empty())
masm.haltingAlign(SimdMemoryAlignment);
for (const SimdData& v : simds_) {
CodeOffset cst(masm.currentOffset());
for (CodeOffset use : v.uses)
addCodeLabel(CodeLabel(use, cst));
masm.simd128Constant(v.value.bytes());
if (!enoughMemory_)
return;
}
}
void
MacroAssemblerX86::handleFailureWithHandlerTail(void* handler)
{
// Reserve space for exception information.
subl(Imm32(sizeof(ResumeFromException)), esp);
movl(esp, eax);
// Call the handler.
asMasm().setupUnalignedABICall(ecx);
asMasm().passABIArg(eax);
asMasm().callWithABI(handler);
Label entryFrame;
Label catch_;
Label finally;
Label return_;
Label bailout;
loadPtr(Address(esp, offsetof(ResumeFromException, kind)), eax);
asMasm().branch32(Assembler::Equal, eax, Imm32(ResumeFromException::RESUME_ENTRY_FRAME),
&entryFrame);
asMasm().branch32(Assembler::Equal, eax, Imm32(ResumeFromException::RESUME_CATCH), &catch_);
asMasm().branch32(Assembler::Equal, eax, Imm32(ResumeFromException::RESUME_FINALLY), &finally);
asMasm().branch32(Assembler::Equal, eax, Imm32(ResumeFromException::RESUME_FORCED_RETURN),
&return_);
asMasm().branch32(Assembler::Equal, eax, Imm32(ResumeFromException::RESUME_BAILOUT), &bailout);
breakpoint(); // Invalid kind.
// No exception handler. Load the error value, load the new stack pointer
// and return from the entry frame.
bind(&entryFrame);
moveValue(MagicValue(JS_ION_ERROR), JSReturnOperand);
loadPtr(Address(esp, offsetof(ResumeFromException, stackPointer)), esp);
ret();
// If we found a catch handler, this must be a baseline frame. Restore state
// and jump to the catch block.
bind(&catch_);
loadPtr(Address(esp, offsetof(ResumeFromException, target)), eax);
loadPtr(Address(esp, offsetof(ResumeFromException, framePointer)), ebp);
loadPtr(Address(esp, offsetof(ResumeFromException, stackPointer)), esp);
jmp(Operand(eax));
// If we found a finally block, this must be a baseline frame. Push
// two values expected by JSOP_RETSUB: BooleanValue(true) and the
// exception.
bind(&finally);
ValueOperand exception = ValueOperand(ecx, edx);
loadValue(Address(esp, offsetof(ResumeFromException, exception)), exception);
loadPtr(Address(esp, offsetof(ResumeFromException, target)), eax);
loadPtr(Address(esp, offsetof(ResumeFromException, framePointer)), ebp);
loadPtr(Address(esp, offsetof(ResumeFromException, stackPointer)), esp);
pushValue(BooleanValue(true));
pushValue(exception);
jmp(Operand(eax));
// Only used in debug mode. Return BaselineFrame->returnValue() to the caller.
bind(&return_);
loadPtr(Address(esp, offsetof(ResumeFromException, framePointer)), ebp);
loadPtr(Address(esp, offsetof(ResumeFromException, stackPointer)), esp);
loadValue(Address(ebp, BaselineFrame::reverseOffsetOfReturnValue()), JSReturnOperand);
movl(ebp, esp);
pop(ebp);
// If profiling is enabled, then update the lastProfilingFrame to refer to caller
// frame before returning.
{
Label skipProfilingInstrumentation;
// Test if profiler enabled.
AbsoluteAddress addressOfEnabled(GetJitContext()->runtime->spsProfiler().addressOfEnabled());
asMasm().branch32(Assembler::Equal, addressOfEnabled, Imm32(0),
&skipProfilingInstrumentation);
profilerExitFrame();
bind(&skipProfilingInstrumentation);
}
ret();
// If we are bailing out to baseline to handle an exception, jump to
// the bailout tail stub.
bind(&bailout);
loadPtr(Address(esp, offsetof(ResumeFromException, bailoutInfo)), ecx);
movl(Imm32(BAILOUT_RETURN_OK), eax);
jmp(Operand(esp, offsetof(ResumeFromException, target)));
}
void
MacroAssemblerX86::profilerEnterFrame(Register framePtr, Register scratch)
{
AbsoluteAddress activation(GetJitContext()->runtime->addressOfProfilingActivation());
loadPtr(activation, scratch);
storePtr(framePtr, Address(scratch, JitActivation::offsetOfLastProfilingFrame()));
storePtr(ImmPtr(nullptr), Address(scratch, JitActivation::offsetOfLastProfilingCallSite()));
}
void
MacroAssemblerX86::profilerExitFrame()
{
jmp(GetJitContext()->runtime->jitRuntime()->getProfilerExitFrameTail());
}
MacroAssembler&
MacroAssemblerX86::asMasm()
{
return *static_cast<MacroAssembler*>(this);
}
const MacroAssembler&
MacroAssemblerX86::asMasm() const
{
return *static_cast<const MacroAssembler*>(this);
}
void
MacroAssembler::subFromStackPtr(Imm32 imm32)
{
if (imm32.value) {
// On windows, we cannot skip very far down the stack without touching the
// memory pages in-between. This is a corner-case code for situations where the
// Ion frame data for a piece of code is very large. To handle this special case,
// for frames over 1k in size we allocate memory on the stack incrementally, touching
// it as we go.
uint32_t amountLeft = imm32.value;
while (amountLeft > 4096) {
subl(Imm32(4096), StackPointer);
store32(Imm32(0), Address(StackPointer, 0));
amountLeft -= 4096;
}
subl(Imm32(amountLeft), StackPointer);
}
}
//{{{ check_macroassembler_style
// ===============================================================
// ABI function calls.
void
MacroAssembler::setupUnalignedABICall(Register scratch)
{
setupABICall();
dynamicAlignment_ = true;
movl(esp, scratch);
andl(Imm32(~(ABIStackAlignment - 1)), esp);
push(scratch);
}
void
MacroAssembler::callWithABIPre(uint32_t* stackAdjust, bool callFromWasm)
{
MOZ_ASSERT(inCall_);
uint32_t stackForCall = abiArgs_.stackBytesConsumedSoFar();
if (dynamicAlignment_) {
// sizeof(intptr_t) accounts for the saved stack pointer pushed by
// setupUnalignedABICall.
stackForCall += ComputeByteAlignment(stackForCall + sizeof(intptr_t),
ABIStackAlignment);
} else {
uint32_t alignmentAtPrologue = callFromWasm ? sizeof(wasm::Frame) : 0;
stackForCall += ComputeByteAlignment(stackForCall + framePushed() + alignmentAtPrologue,
ABIStackAlignment);
}
*stackAdjust = stackForCall;
reserveStack(stackForCall);
// Position all arguments.
{
enoughMemory_ &= moveResolver_.resolve();
if (!enoughMemory_)
return;
MoveEmitter emitter(*this);
emitter.emit(moveResolver_);
emitter.finish();
}
assertStackAlignment(ABIStackAlignment);
}
void
MacroAssembler::callWithABIPost(uint32_t stackAdjust, MoveOp::Type result)
{
freeStack(stackAdjust);
if (result == MoveOp::DOUBLE) {
reserveStack(sizeof(double));
fstp(Operand(esp, 0));
loadDouble(Operand(esp, 0), ReturnDoubleReg);
freeStack(sizeof(double));
} else if (result == MoveOp::FLOAT32) {
reserveStack(sizeof(float));
fstp32(Operand(esp, 0));
loadFloat32(Operand(esp, 0), ReturnFloat32Reg);
freeStack(sizeof(float));
}
if (dynamicAlignment_)
pop(esp);
#ifdef DEBUG
MOZ_ASSERT(inCall_);
inCall_ = false;
#endif
}
void
MacroAssembler::callWithABINoProfiler(Register fun, MoveOp::Type result)
{
uint32_t stackAdjust;
callWithABIPre(&stackAdjust);
call(fun);
callWithABIPost(stackAdjust, result);
}
void
MacroAssembler::callWithABINoProfiler(const Address& fun, MoveOp::Type result)
{
uint32_t stackAdjust;
callWithABIPre(&stackAdjust);
call(fun);
callWithABIPost(stackAdjust, result);
}
// ===============================================================
// Branch functions
void
MacroAssembler::branchPtrInNurseryChunk(Condition cond, Register ptr, Register temp,
Label* label)
{
MOZ_ASSERT(temp != InvalidReg); // A temp register is required for x86.
MOZ_ASSERT(ptr != temp);
movePtr(ptr, temp);
branchPtrInNurseryChunkImpl(cond, temp, label);
}
void
MacroAssembler::branchPtrInNurseryChunk(Condition cond, const Address& address, Register temp,
Label* label)
{
MOZ_ASSERT(temp != InvalidReg); // A temp register is required for x86.
loadPtr(address, temp);
branchPtrInNurseryChunkImpl(cond, temp, label);
}
void
MacroAssembler::branchPtrInNurseryChunkImpl(Condition cond, Register ptr, Label* label)
{
MOZ_ASSERT(cond == Assembler::Equal || cond == Assembler::NotEqual);
orPtr(Imm32(gc::ChunkMask), ptr);
branch32(cond, Address(ptr, gc::ChunkLocationOffsetFromLastByte),
Imm32(int32_t(gc::ChunkLocation::Nursery)), label);
}
void
MacroAssembler::branchValueIsNurseryObject(Condition cond, const Address& address, Register temp,
Label* label)
{
MOZ_ASSERT(cond == Assembler::Equal || cond == Assembler::NotEqual);
Label done;
branchTestObject(Assembler::NotEqual, address, cond == Assembler::Equal ? &done : label);
branchPtrInNurseryChunk(cond, address, temp, label);
bind(&done);
}
void
MacroAssembler::branchValueIsNurseryObject(Condition cond, ValueOperand value, Register temp,
Label* label)
{
MOZ_ASSERT(cond == Assembler::Equal || cond == Assembler::NotEqual);
Label done;
branchTestObject(Assembler::NotEqual, value, cond == Assembler::Equal ? &done : label);
branchPtrInNurseryChunk(cond, value.payloadReg(), temp, label);
bind(&done);
}
void
MacroAssembler::branchTestValue(Condition cond, const ValueOperand& lhs,
const Value& rhs, Label* label)
{
MOZ_ASSERT(cond == Equal || cond == NotEqual);
if (rhs.isMarkable())
cmpPtr(lhs.payloadReg(), ImmGCPtr(rhs.toMarkablePointer()));
else
cmpPtr(lhs.payloadReg(), ImmWord(rhs.toNunboxPayload()));
if (cond == Equal) {
Label done;
j(NotEqual, &done);
{
cmp32(lhs.typeReg(), Imm32(rhs.toNunboxTag()));
j(Equal, label);
}
bind(&done);
} else {
j(NotEqual, label);
cmp32(lhs.typeReg(), Imm32(rhs.toNunboxTag()));
j(NotEqual, label);
}
}
// ========================================================================
// Memory access primitives.
template <typename T>
void
MacroAssembler::storeUnboxedValue(const ConstantOrRegister& value, MIRType valueType,
const T& dest, MIRType slotType)
{
if (valueType == MIRType::Double) {
storeDouble(value.reg().typedReg().fpu(), dest);
return;
}
// Store the type tag if needed.
if (valueType != slotType)
storeTypeTag(ImmType(ValueTypeFromMIRType(valueType)), Operand(dest));
// Store the payload.
if (value.constant())
storePayload(value.value(), Operand(dest));
else
storePayload(value.reg().typedReg().gpr(), Operand(dest));
}
template void
MacroAssembler::storeUnboxedValue(const ConstantOrRegister& value, MIRType valueType,
const Address& dest, MIRType slotType);
template void
MacroAssembler::storeUnboxedValue(const ConstantOrRegister& value, MIRType valueType,
const BaseIndex& dest, MIRType slotType);
// wasm specific methods, used in both the wasm baseline compiler and ion.
void
MacroAssembler::wasmLoad(const wasm::MemoryAccessDesc& access, Operand srcAddr, AnyRegister out)
{
memoryBarrier(access.barrierBefore());
size_t loadOffset = size();
switch (access.type()) {
case Scalar::Int8:
movsblWithPatch(srcAddr, out.gpr());
break;
case Scalar::Uint8:
movzblWithPatch(srcAddr, out.gpr());
break;
case Scalar::Int16:
movswlWithPatch(srcAddr, out.gpr());
break;
case Scalar::Uint16:
movzwlWithPatch(srcAddr, out.gpr());
break;
case Scalar::Int32:
case Scalar::Uint32:
movlWithPatch(srcAddr, out.gpr());
break;
case Scalar::Float32:
vmovssWithPatch(srcAddr, out.fpu());
break;
case Scalar::Float64:
vmovsdWithPatch(srcAddr, out.fpu());
break;
case Scalar::Float32x4:
switch (access.numSimdElems()) {
// In memory-to-register mode, movss zeroes out the high lanes.
case 1: vmovssWithPatch(srcAddr, out.fpu()); break;
// See comment above, which also applies to movsd.
case 2: vmovsdWithPatch(srcAddr, out.fpu()); break;
case 4: vmovupsWithPatch(srcAddr, out.fpu()); break;
default: MOZ_CRASH("unexpected size for partial load");
}
break;
case Scalar::Int32x4:
switch (access.numSimdElems()) {
// In memory-to-register mode, movd zeroes out the high lanes.
case 1: vmovdWithPatch(srcAddr, out.fpu()); break;
// See comment above, which also applies to movq.
case 2: vmovqWithPatch(srcAddr, out.fpu()); break;
case 4: vmovdquWithPatch(srcAddr, out.fpu()); break;
default: MOZ_CRASH("unexpected size for partial load");
}
break;
case Scalar::Int8x16:
MOZ_ASSERT(access.numSimdElems() == 16, "unexpected partial load");
vmovdquWithPatch(srcAddr, out.fpu());
break;
case Scalar::Int16x8:
MOZ_ASSERT(access.numSimdElems() == 8, "unexpected partial load");
vmovdquWithPatch(srcAddr, out.fpu());
break;
case Scalar::Int64:
case Scalar::Uint8Clamped:
case Scalar::MaxTypedArrayViewType:
MOZ_CRASH("unexpected type");
}
append(wasm::MemoryPatch(size()));
append(access, loadOffset, framePushed());
memoryBarrier(access.barrierAfter());
}
void
MacroAssembler::wasmLoadI64(const wasm::MemoryAccessDesc& access, Operand srcAddr, Register64 out)
{
MOZ_ASSERT(!access.isAtomic());
MOZ_ASSERT(!access.isSimd());
size_t loadOffset = size();
switch (access.type()) {
case Scalar::Int8:
MOZ_ASSERT(out == Register64(edx, eax));
movsblWithPatch(srcAddr, out.low);
append(wasm::MemoryPatch(size()));
append(access, loadOffset, framePushed());
cdq();
break;
case Scalar::Uint8:
movzblWithPatch(srcAddr, out.low);
append(wasm::MemoryPatch(size()));
append(access, loadOffset, framePushed());
xorl(out.high, out.high);
break;
case Scalar::Int16:
MOZ_ASSERT(out == Register64(edx, eax));
movswlWithPatch(srcAddr, out.low);
append(wasm::MemoryPatch(size()));
append(access, loadOffset, framePushed());
cdq();
break;
case Scalar::Uint16:
movzwlWithPatch(srcAddr, out.low);
append(wasm::MemoryPatch(size()));
append(access, loadOffset, framePushed());
xorl(out.high, out.high);
break;
case Scalar::Int32:
MOZ_ASSERT(out == Register64(edx, eax));
movlWithPatch(srcAddr, out.low);
append(wasm::MemoryPatch(size()));
append(access, loadOffset, framePushed());
cdq();
break;
case Scalar::Uint32:
movlWithPatch(srcAddr, out.low);
append(wasm::MemoryPatch(size()));
append(access, loadOffset, framePushed());
xorl(out.high, out.high);
break;
case Scalar::Int64:
if (srcAddr.kind() == Operand::MEM_ADDRESS32) {
Operand low(PatchedAbsoluteAddress(uint32_t(srcAddr.address()) + INT64LOW_OFFSET));
Operand high(PatchedAbsoluteAddress(uint32_t(srcAddr.address()) + INT64HIGH_OFFSET));
movlWithPatch(low, out.low);
append(wasm::MemoryPatch(size()));
append(access, loadOffset, framePushed());
loadOffset = size();
movlWithPatch(high, out.high);
append(wasm::MemoryPatch(size()));
append(access, loadOffset, framePushed());
} else {
MOZ_ASSERT(srcAddr.kind() == Operand::MEM_REG_DISP);
Address addr = srcAddr.toAddress();
Operand low(addr.base, addr.offset + INT64LOW_OFFSET);
Operand high(addr.base, addr.offset + INT64HIGH_OFFSET);
if (addr.base != out.low) {
movlWithPatch(low, out.low);
append(wasm::MemoryPatch(size()));
append(access, loadOffset, framePushed());
loadOffset = size();
movlWithPatch(high, out.high);
append(wasm::MemoryPatch(size()));
append(access, loadOffset, framePushed());
} else {
MOZ_ASSERT(addr.base != out.high);
movlWithPatch(high, out.high);
append(wasm::MemoryPatch(size()));
append(access, loadOffset, framePushed());
loadOffset = size();
movlWithPatch(low, out.low);
append(wasm::MemoryPatch(size()));
append(access, loadOffset, framePushed());
}
}
break;
case Scalar::Float32:
case Scalar::Float64:
case Scalar::Float32x4:
case Scalar::Int8x16:
case Scalar::Int16x8:
case Scalar::Int32x4:
MOZ_CRASH("non-int64 loads should use load()");
case Scalar::Uint8Clamped:
case Scalar::MaxTypedArrayViewType:
MOZ_CRASH("unexpected array type");
}
}
void
MacroAssembler::wasmStore(const wasm::MemoryAccessDesc& access, AnyRegister value, Operand dstAddr)
{
memoryBarrier(access.barrierBefore());
size_t storeOffset = size();
switch (access.type()) {
case Scalar::Int8:
case Scalar::Uint8Clamped:
case Scalar::Uint8:
movbWithPatch(value.gpr(), dstAddr);
break;
case Scalar::Int16:
case Scalar::Uint16:
movwWithPatch(value.gpr(), dstAddr);
break;
case Scalar::Int32:
case Scalar::Uint32:
movlWithPatch(value.gpr(), dstAddr);
break;
case Scalar::Float32:
vmovssWithPatch(value.fpu(), dstAddr);
break;
case Scalar::Float64:
vmovsdWithPatch(value.fpu(), dstAddr);
break;
case Scalar::Float32x4:
switch (access.numSimdElems()) {
// In memory-to-register mode, movss zeroes out the high lanes.
case 1: vmovssWithPatch(value.fpu(), dstAddr); break;
// See comment above, which also applies to movsd.
case 2: vmovsdWithPatch(value.fpu(), dstAddr); break;
case 4: vmovupsWithPatch(value.fpu(), dstAddr); break;
default: MOZ_CRASH("unexpected size for partial load");
}
break;
case Scalar::Int32x4:
switch (access.numSimdElems()) {
// In memory-to-register mode, movd zeroes out the high lanes.
case 1: vmovdWithPatch(value.fpu(), dstAddr); break;
// See comment above, which also applies to movsd.
case 2: vmovqWithPatch(value.fpu(), dstAddr); break;
case 4: vmovdquWithPatch(value.fpu(), dstAddr); break;
default: MOZ_CRASH("unexpected size for partial load");
}
break;
case Scalar::Int8x16:
MOZ_ASSERT(access.numSimdElems() == 16, "unexpected partial store");
vmovdquWithPatch(value.fpu(), dstAddr);
break;
case Scalar::Int16x8:
MOZ_ASSERT(access.numSimdElems() == 8, "unexpected partial store");
vmovdquWithPatch(value.fpu(), dstAddr);
break;
case Scalar::Int64:
MOZ_CRASH("Should be handled in storeI64.");
case Scalar::MaxTypedArrayViewType:
MOZ_CRASH("unexpected type");
}
append(wasm::MemoryPatch(size()));
append(access, storeOffset, framePushed());
memoryBarrier(access.barrierAfter());
}
void
MacroAssembler::wasmStoreI64(const wasm::MemoryAccessDesc& access, Register64 value, Operand dstAddr)
{
MOZ_ASSERT(!access.isAtomic());
MOZ_ASSERT(!access.isSimd());
size_t storeOffset = size();
if (dstAddr.kind() == Operand::MEM_ADDRESS32) {
Operand low(PatchedAbsoluteAddress(uint32_t(dstAddr.address()) + INT64LOW_OFFSET));
Operand high(PatchedAbsoluteAddress(uint32_t(dstAddr.address()) + INT64HIGH_OFFSET));
movlWithPatch(value.low, low);
append(wasm::MemoryPatch(size()));
append(access, storeOffset, framePushed());
storeOffset = size();
movlWithPatch(value.high, high);
append(wasm::MemoryPatch(size()));
append(access, storeOffset, framePushed());
} else {
MOZ_ASSERT(dstAddr.kind() == Operand::MEM_REG_DISP);
Address addr = dstAddr.toAddress();
Operand low(addr.base, addr.offset + INT64LOW_OFFSET);
Operand high(addr.base, addr.offset + INT64HIGH_OFFSET);
if (addr.base != value.low) {
movlWithPatch(value.low, low);
append(wasm::MemoryPatch(size()));
append(access, storeOffset, framePushed());
storeOffset = size();
movlWithPatch(value.high, high);
append(wasm::MemoryPatch(size()));
append(access, storeOffset, framePushed());
} else {
MOZ_ASSERT(addr.base != value.high);
movlWithPatch(value.high, high);
append(wasm::MemoryPatch(size()));
append(access, storeOffset, framePushed());
storeOffset = size();
movlWithPatch(value.low, low);
append(wasm::MemoryPatch(size()));
append(access, storeOffset, framePushed());
}
}
}
void
MacroAssembler::wasmTruncateDoubleToUInt32(FloatRegister input, Register output, Label* oolEntry)
{
Label done;
vcvttsd2si(input, output);
branch32(Assembler::Condition::NotSigned, output, Imm32(0), &done);
loadConstantDouble(double(int32_t(0x80000000)), ScratchDoubleReg);
addDouble(input, ScratchDoubleReg);
vcvttsd2si(ScratchDoubleReg, output);
branch32(Assembler::Condition::Signed, output, Imm32(0), oolEntry);
or32(Imm32(0x80000000), output);
bind(&done);
}
void
MacroAssembler::wasmTruncateFloat32ToUInt32(FloatRegister input, Register output, Label* oolEntry)
{
Label done;
vcvttss2si(input, output);
branch32(Assembler::Condition::NotSigned, output, Imm32(0), &done);
loadConstantFloat32(float(int32_t(0x80000000)), ScratchFloat32Reg);
addFloat32(input, ScratchFloat32Reg);
vcvttss2si(ScratchFloat32Reg, output);
branch32(Assembler::Condition::Signed, output, Imm32(0), oolEntry);
or32(Imm32(0x80000000), output);
bind(&done);
}
//}}} check_macroassembler_style
void
MacroAssemblerX86::convertInt64ToDouble(Register64 input, FloatRegister output)
{
// Zero the output register to break dependencies, see convertInt32ToDouble.
zeroDouble(output);
asMasm().Push(input.high);
asMasm().Push(input.low);
fild(Operand(esp, 0));
fstp(Operand(esp, 0));
vmovsd(Address(esp, 0), output);
asMasm().freeStack(2*sizeof(intptr_t));
}
void
MacroAssemblerX86::convertInt64ToFloat32(Register64 input, FloatRegister output)
{
convertInt64ToDouble(input, output);
convertDoubleToFloat32(output, output);
}
void
MacroAssemblerX86::convertUInt64ToFloat32(Register64 input, FloatRegister output, Register temp)
{
convertUInt64ToDouble(input, output.asDouble(), temp);
convertDoubleToFloat32(output, output);
}
void
MacroAssemblerX86::wasmTruncateDoubleToInt64(FloatRegister input, Register64 output, Label* oolEntry,
Label* oolRejoin, FloatRegister tempReg)
{
Label fail, convert;
Register temp = output.high;
// Make sure input fits in (u)int64.
asMasm().reserveStack(2 * sizeof(int32_t));
asMasm().storeDouble(input, Operand(esp, 0));
asMasm().branchDoubleNotInInt64Range(Address(esp, 0), temp, &fail);
jump(&convert);
// Handle failure in ool.
bind(&fail);
asMasm().freeStack(2 * sizeof(int32_t));
jump(oolEntry);
bind(oolRejoin);
asMasm().reserveStack(2 * sizeof(int32_t));
asMasm().storeDouble(input, Operand(esp, 0));
// Convert the double/float to int64.
bind(&convert);
asMasm().truncateDoubleToInt64(Address(esp, 0), Address(esp, 0), temp);
// Load value into int64 register.
load64(Address(esp, 0), output);
asMasm().freeStack(2 * sizeof(int32_t));
}
void
MacroAssemblerX86::wasmTruncateFloat32ToInt64(FloatRegister input, Register64 output, Label* oolEntry,
Label* oolRejoin, FloatRegister tempReg)
{
Label fail, convert;
Register temp = output.high;
// Make sure input fits in (u)int64.
asMasm().reserveStack(2 * sizeof(int32_t));
asMasm().storeFloat32(input, Operand(esp, 0));
asMasm().branchFloat32NotInInt64Range(Address(esp, 0), temp, &fail);
jump(&convert);
// Handle failure in ool.
bind(&fail);
asMasm().freeStack(2 * sizeof(int32_t));
jump(oolEntry);
bind(oolRejoin);
asMasm().reserveStack(2 * sizeof(int32_t));
asMasm().storeFloat32(input, Operand(esp, 0));
// Convert the double/float to int64.
bind(&convert);
asMasm().truncateFloat32ToInt64(Address(esp, 0), Address(esp, 0), temp);
// Load value into int64 register.
load64(Address(esp, 0), output);
asMasm().freeStack(2 * sizeof(int32_t));
}
void
MacroAssemblerX86::wasmTruncateDoubleToUInt64(FloatRegister input, Register64 output, Label* oolEntry,
Label* oolRejoin, FloatRegister tempReg)
{
Label fail, convert;
Register temp = output.high;
// Make sure input fits in (u)int64.
asMasm().reserveStack(2 * sizeof(int32_t));
asMasm().storeDouble(input, Operand(esp, 0));
asMasm().branchDoubleNotInUInt64Range(Address(esp, 0), temp, &fail);
jump(&convert);
// Handle failure in ool.
bind(&fail);
asMasm().freeStack(2 * sizeof(int32_t));
jump(oolEntry);
bind(oolRejoin);
asMasm().reserveStack(2 * sizeof(int32_t));
asMasm().storeDouble(input, Operand(esp, 0));
// Convert the double/float to int64.
bind(&convert);
asMasm().truncateDoubleToUInt64(Address(esp, 0), Address(esp, 0), temp, tempReg);
// Load value into int64 register.
load64(Address(esp, 0), output);
asMasm().freeStack(2 * sizeof(int32_t));
}
void
MacroAssemblerX86::wasmTruncateFloat32ToUInt64(FloatRegister input, Register64 output, Label* oolEntry,
Label* oolRejoin, FloatRegister tempReg)
{
Label fail, convert;
Register temp = output.high;
// Make sure input fits in (u)int64.
asMasm().reserveStack(2 * sizeof(int32_t));
asMasm().storeFloat32(input, Operand(esp, 0));
asMasm().branchFloat32NotInUInt64Range(Address(esp, 0), temp, &fail);
jump(&convert);
// Handle failure in ool.
bind(&fail);
asMasm().freeStack(2 * sizeof(int32_t));
jump(oolEntry);
bind(oolRejoin);
asMasm().reserveStack(2 * sizeof(int32_t));
asMasm().storeFloat32(input, Operand(esp, 0));
// Convert the double/float to int64.
bind(&convert);
asMasm().truncateFloat32ToUInt64(Address(esp, 0), Address(esp, 0), temp, tempReg);
// Load value into int64 register.
load64(Address(esp, 0), output);
asMasm().freeStack(2 * sizeof(int32_t));
}