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/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 2 -*-
* vim: set ts=8 sts=2 et sw=2 tw=80:
* This Source Code Form is subject to the terms of the Mozilla Public
* License, v. 2.0. If a copy of the MPL was not distributed with this
* file, You can obtain one at http://mozilla.org/MPL/2.0/. */
#ifndef jit_arm64_MacroAssembler_arm64_h
#define jit_arm64_MacroAssembler_arm64_h
#include "jit/arm64/Assembler-arm64.h"
#include "jit/arm64/vixl/Debugger-vixl.h"
#include "jit/arm64/vixl/MacroAssembler-vixl.h"
#include "jit/AtomicOp.h"
#include "jit/MoveResolver.h"
#include "vm/BigIntType.h" // JS::BigInt
#include "wasm/WasmTypes.h"
#ifdef _M_ARM64
# ifdef move32
# undef move32
# endif
# ifdef move64
# undef move64
# endif
#endif
namespace js {
namespace jit {
// Import VIXL operands directly into the jit namespace for shared code.
using vixl::MemOperand;
using vixl::Operand;
struct ImmShiftedTag : public ImmWord {
explicit ImmShiftedTag(JSValueShiftedTag shtag) : ImmWord((uintptr_t)shtag) {}
explicit ImmShiftedTag(JSValueType type)
: ImmWord(uintptr_t(JSValueShiftedTag(JSVAL_TYPE_TO_SHIFTED_TAG(type)))) {
}
};
struct ImmTag : public Imm32 {
explicit ImmTag(JSValueTag tag) : Imm32(tag) {}
};
class ScratchTagScope;
class MacroAssemblerCompat : public vixl::MacroAssembler {
public:
typedef vixl::Condition Condition;
private:
// Perform a downcast. Should be removed by Bug 996602.
js::jit::MacroAssembler& asMasm();
const js::jit::MacroAssembler& asMasm() const;
public:
// Restrict to only VIXL-internal functions.
vixl::MacroAssembler& asVIXL();
const MacroAssembler& asVIXL() const;
protected:
bool enoughMemory_;
uint32_t framePushed_;
MacroAssemblerCompat()
: vixl::MacroAssembler(), enoughMemory_(true), framePushed_(0) {}
protected:
MoveResolver moveResolver_;
public:
bool oom() const { return Assembler::oom() || !enoughMemory_; }
static ARMRegister toARMRegister(RegisterOrSP r, size_t size) {
if (IsHiddenSP(r)) {
MOZ_ASSERT(size == 64);
return sp;
}
return ARMRegister(AsRegister(r), size);
}
static MemOperand toMemOperand(const Address& a) {
return MemOperand(toARMRegister(a.base, 64), a.offset);
}
void doBaseIndex(const vixl::CPURegister& rt, const BaseIndex& addr,
vixl::LoadStoreOp op) {
const ARMRegister base = toARMRegister(addr.base, 64);
const ARMRegister index = ARMRegister(addr.index, 64);
const unsigned scale = addr.scale;
if (!addr.offset &&
(!scale || scale == static_cast<unsigned>(CalcLSDataSize(op)))) {
LoadStoreMacro(rt, MemOperand(base, index, vixl::LSL, scale), op);
return;
}
vixl::UseScratchRegisterScope temps(this);
ARMRegister scratch64 = temps.AcquireX();
MOZ_ASSERT(!scratch64.Is(rt));
MOZ_ASSERT(!scratch64.Is(base));
MOZ_ASSERT(!scratch64.Is(index));
Add(scratch64, base, Operand(index, vixl::LSL, scale));
LoadStoreMacro(rt, MemOperand(scratch64, addr.offset), op);
}
void Push(ARMRegister reg) {
push(reg);
adjustFrame(reg.size() / 8);
}
void Push(Register reg) {
vixl::MacroAssembler::Push(ARMRegister(reg, 64));
adjustFrame(8);
}
void Push(Imm32 imm) {
push(imm);
adjustFrame(8);
}
void Push(FloatRegister f) {
push(ARMFPRegister(f, 64));
adjustFrame(8);
}
void Push(ImmPtr imm) {
push(imm);
adjustFrame(sizeof(void*));
}
void push(FloatRegister f) {
vixl::MacroAssembler::Push(ARMFPRegister(f, 64));
}
void push(ARMFPRegister f) { vixl::MacroAssembler::Push(f); }
void push(Imm32 imm) {
if (imm.value == 0) {
vixl::MacroAssembler::Push(vixl::xzr);
} else {
vixl::UseScratchRegisterScope temps(this);
const ARMRegister scratch64 = temps.AcquireX();
move32(imm, scratch64.asUnsized());
vixl::MacroAssembler::Push(scratch64);
}
}
void push(ImmWord imm) {
if (imm.value == 0) {
vixl::MacroAssembler::Push(vixl::xzr);
} else {
vixl::UseScratchRegisterScope temps(this);
const ARMRegister scratch64 = temps.AcquireX();
Mov(scratch64, imm.value);
vixl::MacroAssembler::Push(scratch64);
}
}
void push(ImmPtr imm) {
if (imm.value == nullptr) {
vixl::MacroAssembler::Push(vixl::xzr);
} else {
vixl::UseScratchRegisterScope temps(this);
const ARMRegister scratch64 = temps.AcquireX();
movePtr(imm, scratch64.asUnsized());
vixl::MacroAssembler::Push(scratch64);
}
}
void push(ImmGCPtr imm) {
if (imm.value == nullptr) {
vixl::MacroAssembler::Push(vixl::xzr);
} else {
vixl::UseScratchRegisterScope temps(this);
const ARMRegister scratch64 = temps.AcquireX();
movePtr(imm, scratch64.asUnsized());
vixl::MacroAssembler::Push(scratch64);
}
}
void push(ARMRegister reg) { vixl::MacroAssembler::Push(reg); }
void push(Address a) {
vixl::UseScratchRegisterScope temps(this);
const ARMRegister scratch64 = temps.AcquireX();
MOZ_ASSERT(a.base != scratch64.asUnsized());
loadPtr(a, scratch64.asUnsized());
vixl::MacroAssembler::Push(scratch64);
}
// Push registers.
void push(Register reg) { vixl::MacroAssembler::Push(ARMRegister(reg, 64)); }
void push(RegisterOrSP reg) {
if (IsHiddenSP(reg)) {
vixl::MacroAssembler::Push(sp);
}
vixl::MacroAssembler::Push(toARMRegister(reg, 64));
}
void push(Register r0, Register r1) {
vixl::MacroAssembler::Push(ARMRegister(r0, 64), ARMRegister(r1, 64));
}
void push(Register r0, Register r1, Register r2) {
vixl::MacroAssembler::Push(ARMRegister(r0, 64), ARMRegister(r1, 64),
ARMRegister(r2, 64));
}
void push(Register r0, Register r1, Register r2, Register r3) {
vixl::MacroAssembler::Push(ARMRegister(r0, 64), ARMRegister(r1, 64),
ARMRegister(r2, 64), ARMRegister(r3, 64));
}
void push(ARMFPRegister r0, ARMFPRegister r1, ARMFPRegister r2,
ARMFPRegister r3) {
vixl::MacroAssembler::Push(r0, r1, r2, r3);
}
// Pop registers.
void pop(Register reg) { vixl::MacroAssembler::Pop(ARMRegister(reg, 64)); }
void pop(Register r0, Register r1) {
vixl::MacroAssembler::Pop(ARMRegister(r0, 64), ARMRegister(r1, 64));
}
void pop(Register r0, Register r1, Register r2) {
vixl::MacroAssembler::Pop(ARMRegister(r0, 64), ARMRegister(r1, 64),
ARMRegister(r2, 64));
}
void pop(Register r0, Register r1, Register r2, Register r3) {
vixl::MacroAssembler::Pop(ARMRegister(r0, 64), ARMRegister(r1, 64),
ARMRegister(r2, 64), ARMRegister(r3, 64));
}
void pop(ARMFPRegister r0, ARMFPRegister r1, ARMFPRegister r2,
ARMFPRegister r3) {
vixl::MacroAssembler::Pop(r0, r1, r2, r3);
}
void pop(const ValueOperand& v) { pop(v.valueReg()); }
void pop(const FloatRegister& f) {
vixl::MacroAssembler::Pop(ARMFPRegister(f, 64));
}
void implicitPop(uint32_t args) {
MOZ_ASSERT(args % sizeof(intptr_t) == 0);
adjustFrame(0 - args);
}
void Pop(ARMRegister r) {
vixl::MacroAssembler::Pop(r);
adjustFrame(0 - r.size() / 8);
}
// FIXME: This is the same on every arch.
// FIXME: If we can share framePushed_, we can share this.
// FIXME: Or just make it at the highest level.
CodeOffset PushWithPatch(ImmWord word) {
framePushed_ += sizeof(word.value);
return pushWithPatch(word);
}
CodeOffset PushWithPatch(ImmPtr ptr) {
return PushWithPatch(ImmWord(uintptr_t(ptr.value)));
}
uint32_t framePushed() const { return framePushed_; }
void adjustFrame(int32_t diff) { setFramePushed(framePushed_ + diff); }
void setFramePushed(uint32_t framePushed) { framePushed_ = framePushed; }
void freeStack(Register amount) {
vixl::MacroAssembler::Drop(Operand(ARMRegister(amount, 64)));
}
#ifdef ENABLE_WASM_SIMD
void PushRegsInMaskForWasmStubs(LiveRegisterSet set);
void PopRegsInMaskForWasmStubs(LiveRegisterSet set, LiveRegisterSet ignore);
#endif
// Update sp with the value of the current active stack pointer, if necessary.
void syncStackPtr() {
if (!GetStackPointer64().Is(vixl::sp)) {
Mov(vixl::sp, GetStackPointer64());
}
}
void initPseudoStackPtr() {
if (!GetStackPointer64().Is(vixl::sp)) {
Mov(GetStackPointer64(), vixl::sp);
}
}
void storeValue(ValueOperand val, const Address& dest) {
storePtr(val.valueReg(), dest);
}
template <typename T>
void storeValue(JSValueType type, Register reg, const T& dest) {
vixl::UseScratchRegisterScope temps(this);
const Register scratch = temps.AcquireX().asUnsized();
MOZ_ASSERT(scratch != reg);
tagValue(type, reg, ValueOperand(scratch));
storeValue(ValueOperand(scratch), dest);
}
template <typename T>
void storeValue(const Value& val, const T& dest) {
vixl::UseScratchRegisterScope temps(this);
const Register scratch = temps.AcquireX().asUnsized();
moveValue(val, ValueOperand(scratch));
storeValue(ValueOperand(scratch), dest);
}
void storeValue(ValueOperand val, BaseIndex dest) {
storePtr(val.valueReg(), dest);
}
void storeValue(const Address& src, const Address& dest, Register temp) {
loadPtr(src, temp);
storePtr(temp, dest);
}
void loadValue(Address src, Register val) {
Ldr(ARMRegister(val, 64), MemOperand(src));
}
void loadValue(Address src, ValueOperand val) {
Ldr(ARMRegister(val.valueReg(), 64), MemOperand(src));
}
void loadValue(const BaseIndex& src, ValueOperand val) {
doBaseIndex(ARMRegister(val.valueReg(), 64), src, vixl::LDR_x);
}
void loadUnalignedValue(const Address& src, ValueOperand dest) {
loadValue(src, dest);
}
void tagValue(JSValueType type, Register payload, ValueOperand dest) {
// This could be cleverer, but the first attempt had bugs.
Orr(ARMRegister(dest.valueReg(), 64), ARMRegister(payload, 64),
Operand(ImmShiftedTag(type).value));
}
void pushValue(ValueOperand val) {
vixl::MacroAssembler::Push(ARMRegister(val.valueReg(), 64));
}
void popValue(ValueOperand val) {
vixl::MacroAssembler::Pop(ARMRegister(val.valueReg(), 64));
}
void pushValue(const Value& val) {
vixl::UseScratchRegisterScope temps(this);
const Register scratch = temps.AcquireX().asUnsized();
if (val.isGCThing()) {
BufferOffset load =
movePatchablePtr(ImmPtr(val.bitsAsPunboxPointer()), scratch);
writeDataRelocation(val, load);
push(scratch);
} else {
moveValue(val, scratch);
push(scratch);
}
}
void pushValue(JSValueType type, Register reg) {
vixl::UseScratchRegisterScope temps(this);
const Register scratch = temps.AcquireX().asUnsized();
MOZ_ASSERT(scratch != reg);
tagValue(type, reg, ValueOperand(scratch));
push(scratch);
}
void pushValue(const Address& addr) {
vixl::UseScratchRegisterScope temps(this);
const Register scratch = temps.AcquireX().asUnsized();
MOZ_ASSERT(scratch != addr.base);
loadValue(addr, scratch);
push(scratch);
}
template <typename T>
void storeUnboxedPayload(ValueOperand value, T address, size_t nbytes,
JSValueType type) {
switch (nbytes) {
case 8: {
vixl::UseScratchRegisterScope temps(this);
const Register scratch = temps.AcquireX().asUnsized();
if (type == JSVAL_TYPE_OBJECT) {
unboxObjectOrNull(value, scratch);
} else {
unboxNonDouble(value, scratch, type);
}
storePtr(scratch, address);
return;
}
case 4:
store32(value.valueReg(), address);
return;
case 1:
store8(value.valueReg(), address);
return;
default:
MOZ_CRASH("Bad payload width");
}
}
void moveValue(const Value& val, Register dest) {
if (val.isGCThing()) {
BufferOffset load =
movePatchablePtr(ImmPtr(val.bitsAsPunboxPointer()), dest);
writeDataRelocation(val, load);
} else {
movePtr(ImmWord(val.asRawBits()), dest);
}
}
void moveValue(const Value& src, const ValueOperand& dest) {
moveValue(src, dest.valueReg());
}
CodeOffset pushWithPatch(ImmWord imm) {
vixl::UseScratchRegisterScope temps(this);
const Register scratch = temps.AcquireX().asUnsized();
CodeOffset label = movWithPatch(imm, scratch);
push(scratch);
return label;
}
CodeOffset movWithPatch(ImmWord imm, Register dest) {
BufferOffset off = immPool64(ARMRegister(dest, 64), imm.value);
return CodeOffset(off.getOffset());
}
CodeOffset movWithPatch(ImmPtr imm, Register dest) {
BufferOffset off = immPool64(ARMRegister(dest, 64), uint64_t(imm.value));
return CodeOffset(off.getOffset());
}
void boxValue(JSValueType type, Register src, Register dest);
void splitSignExtTag(Register src, Register dest) {
sbfx(ARMRegister(dest, 64), ARMRegister(src, 64), JSVAL_TAG_SHIFT,
(64 - JSVAL_TAG_SHIFT));
}
[[nodiscard]] Register extractTag(const Address& address, Register scratch) {
loadPtr(address, scratch);
splitSignExtTag(scratch, scratch);
return scratch;
}
[[nodiscard]] Register extractTag(const ValueOperand& value,
Register scratch) {
splitSignExtTag(value.valueReg(), scratch);
return scratch;
}
[[nodiscard]] Register extractObject(const Address& address,
Register scratch) {
loadPtr(address, scratch);
unboxObject(scratch, scratch);
return scratch;
}
[[nodiscard]] Register extractObject(const ValueOperand& value,
Register scratch) {
unboxObject(value, scratch);
return scratch;
}
[[nodiscard]] Register extractSymbol(const ValueOperand& value,
Register scratch) {
unboxSymbol(value, scratch);
return scratch;
}
[[nodiscard]] Register extractInt32(const ValueOperand& value,
Register scratch) {
unboxInt32(value, scratch);
return scratch;
}
[[nodiscard]] Register extractBoolean(const ValueOperand& value,
Register scratch) {
unboxBoolean(value, scratch);
return scratch;
}
inline void ensureDouble(const ValueOperand& source, FloatRegister dest,
Label* failure);
void emitSet(Condition cond, Register dest) {
Cset(ARMRegister(dest, 64), cond);
}
void testNullSet(Condition cond, const ValueOperand& value, Register dest) {
cond = testNull(cond, value);
emitSet(cond, dest);
}
void testObjectSet(Condition cond, const ValueOperand& value, Register dest) {
cond = testObject(cond, value);
emitSet(cond, dest);
}
void testUndefinedSet(Condition cond, const ValueOperand& value,
Register dest) {
cond = testUndefined(cond, value);
emitSet(cond, dest);
}
void convertBoolToInt32(Register source, Register dest) {
Uxtb(ARMRegister(dest, 64), ARMRegister(source, 64));
}
void convertInt32ToDouble(Register src, FloatRegister dest) {
Scvtf(ARMFPRegister(dest, 64),
ARMRegister(src, 32)); // Uses FPCR rounding mode.
}
void convertInt32ToDouble(const Address& src, FloatRegister dest) {
vixl::UseScratchRegisterScope temps(this);
const Register scratch = temps.AcquireX().asUnsized();
MOZ_ASSERT(scratch != src.base);
load32(src, scratch);
convertInt32ToDouble(scratch, dest);
}
void convertInt32ToDouble(const BaseIndex& src, FloatRegister dest) {
vixl::UseScratchRegisterScope temps(this);
const Register scratch = temps.AcquireX().asUnsized();
MOZ_ASSERT(scratch != src.base);
MOZ_ASSERT(scratch != src.index);
load32(src, scratch);
convertInt32ToDouble(scratch, dest);
}
void convertInt32ToFloat32(Register src, FloatRegister dest) {
Scvtf(ARMFPRegister(dest, 32),
ARMRegister(src, 32)); // Uses FPCR rounding mode.
}
void convertInt32ToFloat32(const Address& src, FloatRegister dest) {
vixl::UseScratchRegisterScope temps(this);
const Register scratch = temps.AcquireX().asUnsized();
MOZ_ASSERT(scratch != src.base);
load32(src, scratch);
convertInt32ToFloat32(scratch, dest);
}
void convertUInt32ToDouble(Register src, FloatRegister dest) {
Ucvtf(ARMFPRegister(dest, 64),
ARMRegister(src, 32)); // Uses FPCR rounding mode.
}
void convertUInt32ToDouble(const Address& src, FloatRegister dest) {
vixl::UseScratchRegisterScope temps(this);
const Register scratch = temps.AcquireX().asUnsized();
MOZ_ASSERT(scratch != src.base);
load32(src, scratch);
convertUInt32ToDouble(scratch, dest);
}
void convertUInt32ToFloat32(Register src, FloatRegister dest) {
Ucvtf(ARMFPRegister(dest, 32),
ARMRegister(src, 32)); // Uses FPCR rounding mode.
}
void convertUInt32ToFloat32(const Address& src, FloatRegister dest) {
vixl::UseScratchRegisterScope temps(this);
const Register scratch = temps.AcquireX().asUnsized();
MOZ_ASSERT(scratch != src.base);
load32(src, scratch);
convertUInt32ToFloat32(scratch, dest);
}
void convertFloat32ToDouble(FloatRegister src, FloatRegister dest) {
Fcvt(ARMFPRegister(dest, 64), ARMFPRegister(src, 32));
}
void convertDoubleToFloat32(FloatRegister src, FloatRegister dest) {
Fcvt(ARMFPRegister(dest, 32), ARMFPRegister(src, 64));
}
using vixl::MacroAssembler::B;
void convertDoubleToInt32(FloatRegister src, Register dest, Label* fail,
bool negativeZeroCheck = true) {
ARMFPRegister fsrc64(src, 64);
ARMRegister dest32(dest, 32);
// ARMv8.3 chips support the FJCVTZS instruction, which handles
// exactly this logic.
if (CPUHas(vixl::CPUFeatures::kFP, vixl::CPUFeatures::kJSCVT)) {
// Convert double to integer, rounding toward zero.
// The Z-flag is set iff the conversion is exact. -0 unsets the Z-flag.
Fjcvtzs(dest32, fsrc64);
if (negativeZeroCheck) {
B(fail, Assembler::NonZero);
} else {
Label done;
B(&done, Assembler::Zero); // If conversion was exact, go to end.
// The conversion was inexact, but the caller intends to allow -0.
vixl::UseScratchRegisterScope temps(this);
const ARMFPRegister scratch64 = temps.AcquireD();
MOZ_ASSERT(!scratch64.Is(fsrc64));
// Compare fsrc64 to 0.
// If fsrc64 == 0 and FJCVTZS conversion was inexact, then fsrc64 is -0.
Fmov(scratch64, xzr);
Fcmp(scratch64, fsrc64);
B(fail, Assembler::NotEqual); // Pass through -0; fail otherwise.
bind(&done);
}
} else {
// Older processors use a significantly slower path.
ARMRegister dest64(dest, 64);
vixl::UseScratchRegisterScope temps(this);
const ARMFPRegister scratch64 = temps.AcquireD();
MOZ_ASSERT(!scratch64.Is(fsrc64));
Fcvtzs(dest32, fsrc64); // Convert, rounding toward zero.
Scvtf(scratch64, dest32); // Convert back, using FPCR rounding mode.
Fcmp(scratch64, fsrc64);
B(fail, Assembler::NotEqual);
if (negativeZeroCheck) {
Label nonzero;
Cbnz(dest32, &nonzero);
Fmov(dest64, fsrc64);
Cbnz(dest64, fail);
bind(&nonzero);
}
}
}
void convertFloat32ToInt32(FloatRegister src, Register dest, Label* fail,
bool negativeZeroCheck = true) {
vixl::UseScratchRegisterScope temps(this);
const ARMFPRegister scratch32 = temps.AcquireS();
ARMFPRegister fsrc(src, 32);
ARMRegister dest32(dest, 32);
ARMRegister dest64(dest, 64);
MOZ_ASSERT(!scratch32.Is(fsrc));
Fcvtzs(dest64, fsrc); // Convert, rounding toward zero.
Scvtf(scratch32, dest32); // Convert back, using FPCR rounding mode.
Fcmp(scratch32, fsrc);
B(fail, Assembler::NotEqual);
if (negativeZeroCheck) {
Label nonzero;
Cbnz(dest32, &nonzero);
Fmov(dest32, fsrc);
Cbnz(dest32, fail);
bind(&nonzero);
}
And(dest64, dest64, Operand(0xffffffff));
}
void convertDoubleToPtr(FloatRegister src, Register dest, Label* fail,
bool negativeZeroCheck = true) {
ARMFPRegister fsrc64(src, 64);
ARMRegister dest64(dest, 64);
vixl::UseScratchRegisterScope temps(this);
const ARMFPRegister scratch64 = temps.AcquireD();
MOZ_ASSERT(!scratch64.Is(fsrc64));
// Note: we can't use the FJCVTZS instruction here because that only works
// for 32-bit values.
Fcvtzs(dest64, fsrc64); // Convert, rounding toward zero.
Scvtf(scratch64, dest64); // Convert back, using FPCR rounding mode.
Fcmp(scratch64, fsrc64);
B(fail, Assembler::NotEqual);
if (negativeZeroCheck) {
Label nonzero;
Cbnz(dest64, &nonzero);
Fmov(dest64, fsrc64);
Cbnz(dest64, fail);
bind(&nonzero);
}
}
void floor(FloatRegister input, Register output, Label* bail) {
Label handleZero;
// Label handleNeg;
Label fin;
ARMFPRegister iDbl(input, 64);
ARMRegister o64(output, 64);
ARMRegister o32(output, 32);
Fcmp(iDbl, 0.0);
B(Assembler::Equal, &handleZero);
// B(Assembler::Signed, &handleNeg);
// NaN is always a bail condition, just bail directly.
B(Assembler::Overflow, bail);
Fcvtms(o64, iDbl);
Cmp(o64, Operand(o64, vixl::SXTW));
B(NotEqual, bail);
Mov(o32, o32);
B(&fin);
bind(&handleZero);
// Move the top word of the double into the output reg, if it is non-zero,
// then the original value was -0.0.
Fmov(o64, iDbl);
Cbnz(o64, bail);
bind(&fin);
}
void floorf(FloatRegister input, Register output, Label* bail) {
Label handleZero;
// Label handleNeg;
Label fin;
ARMFPRegister iFlt(input, 32);
ARMRegister o64(output, 64);
ARMRegister o32(output, 32);
Fcmp(iFlt, 0.0);
B(Assembler::Equal, &handleZero);
// B(Assembler::Signed, &handleNeg);
// NaN is always a bail condition, just bail directly.
B(Assembler::Overflow, bail);
Fcvtms(o64, iFlt);
Cmp(o64, Operand(o64, vixl::SXTW));
B(NotEqual, bail);
Mov(o32, o32);
B(&fin);
bind(&handleZero);
// Move the top word of the double into the output reg, if it is non-zero,
// then the original value was -0.0.
Fmov(o32, iFlt);
Cbnz(o32, bail);
bind(&fin);
}
void ceil(FloatRegister input, Register output, Label* bail) {
Label handleZero;
Label fin;
ARMFPRegister iDbl(input, 64);
ARMRegister o64(output, 64);
ARMRegister o32(output, 32);
Fcmp(iDbl, 0.0);
B(Assembler::Overflow, bail);
Fcvtps(o64, iDbl);
Cmp(o64, Operand(o64, vixl::SXTW));
B(NotEqual, bail);
Cbz(o64, &handleZero);
Mov(o32, o32);
B(&fin);
bind(&handleZero);
vixl::UseScratchRegisterScope temps(this);
const ARMRegister scratch = temps.AcquireX();
Fmov(scratch, iDbl);
Cbnz(scratch, bail);
bind(&fin);
}
void ceilf(FloatRegister input, Register output, Label* bail) {
Label handleZero;
Label fin;
ARMFPRegister iFlt(input, 32);
ARMRegister o64(output, 64);
ARMRegister o32(output, 32);
Fcmp(iFlt, 0.0);
// NaN is always a bail condition, just bail directly.
B(Assembler::Overflow, bail);
Fcvtps(o64, iFlt);
Cmp(o64, Operand(o64, vixl::SXTW));
B(NotEqual, bail);
Cbz(o64, &handleZero);
Mov(o32, o32);
B(&fin);
bind(&handleZero);
// Move the top word of the double into the output reg, if it is non-zero,
// then the original value was -0.0.
Fmov(o32, iFlt);
Cbnz(o32, bail);
bind(&fin);
}
void jump(Label* label) { B(label); }
void jump(JitCode* code) { branch(code); }
void jump(ImmPtr ptr) {
syncStackPtr();
BufferOffset loc =
b(-1,
LabelDoc()); // The jump target will be patched by executableCopy().
addPendingJump(loc, ptr, RelocationKind::HARDCODED);
}
void jump(TrampolinePtr code) { jump(ImmPtr(code.value)); }
void jump(Register reg) { Br(ARMRegister(reg, 64)); }
void jump(const Address& addr) {
vixl::UseScratchRegisterScope temps(this);
MOZ_ASSERT(temps.IsAvailable(ScratchReg64)); // ip0
temps.Exclude(ScratchReg64);
MOZ_ASSERT(addr.base != ScratchReg64.asUnsized());
loadPtr(addr, ScratchReg64.asUnsized());
br(ScratchReg64);
}
void align(int alignment) { armbuffer_.align(alignment); }
void haltingAlign(int alignment) {
armbuffer_.align(alignment, vixl::HLT | ImmException(0xBAAD));
}
void nopAlign(int alignment) { armbuffer_.align(alignment); }
void movePtr(Register src, Register dest) {
Mov(ARMRegister(dest, 64), ARMRegister(src, 64));
}
void movePtr(ImmWord imm, Register dest) {
Mov(ARMRegister(dest, 64), int64_t(imm.value));
}
void movePtr(ImmPtr imm, Register dest) {
Mov(ARMRegister(dest, 64), int64_t(imm.value));
}
void movePtr(wasm::SymbolicAddress imm, Register dest) {
BufferOffset off = movePatchablePtr(ImmWord(0xffffffffffffffffULL), dest);
append(wasm::SymbolicAccess(CodeOffset(off.getOffset()), imm));
}
void movePtr(ImmGCPtr imm, Register dest) {
BufferOffset load = movePatchablePtr(ImmPtr(imm.value), dest);
writeDataRelocation(imm, load);
}
void mov(ImmWord imm, Register dest) { movePtr(imm, dest); }
void mov(ImmPtr imm, Register dest) { movePtr(imm, dest); }
void mov(wasm::SymbolicAddress imm, Register dest) { movePtr(imm, dest); }
void mov(Register src, Register dest) { movePtr(src, dest); }
void mov(CodeLabel* label, Register dest);
void move32(Imm32 imm, Register dest) {
Mov(ARMRegister(dest, 32), (int64_t)imm.value);
}
void move32(Register src, Register dest) {
Mov(ARMRegister(dest, 32), ARMRegister(src, 32));
}
// Move a pointer using a literal pool, so that the pointer
// may be easily patched or traced.
// Returns the BufferOffset of the load instruction emitted.
BufferOffset movePatchablePtr(ImmWord ptr, Register dest);
BufferOffset movePatchablePtr(ImmPtr ptr, Register dest);
void loadPtr(wasm::SymbolicAddress address, Register dest) {
vixl::UseScratchRegisterScope temps(this);
const ARMRegister scratch = temps.AcquireX();
movePtr(address, scratch.asUnsized());
Ldr(ARMRegister(dest, 64), MemOperand(scratch));
}
void loadPtr(AbsoluteAddress address, Register dest) {
vixl::UseScratchRegisterScope temps(this);
const ARMRegister scratch = temps.AcquireX();
movePtr(ImmWord((uintptr_t)address.addr), scratch.asUnsized());
Ldr(ARMRegister(dest, 64), MemOperand(scratch));
}
void loadPtr(const Address& address, Register dest) {
Ldr(ARMRegister(dest, 64), MemOperand(address));
}
void loadPtr(const BaseIndex& src, Register dest) {
ARMRegister base = toARMRegister(src.base, 64);
uint32_t scale = Imm32::ShiftOf(src.scale).value;
ARMRegister dest64(dest, 64);
ARMRegister index64(src.index, 64);
if (src.offset) {
vixl::UseScratchRegisterScope temps(this);
const ARMRegister scratch = temps.AcquireX();
MOZ_ASSERT(!scratch.Is(base));
MOZ_ASSERT(!scratch.Is(dest64));
MOZ_ASSERT(!scratch.Is(index64));
Add(scratch, base, Operand(int64_t(src.offset)));
Ldr(dest64, MemOperand(scratch, index64, vixl::LSL, scale));
return;
}
Ldr(dest64, MemOperand(base, index64, vixl::LSL, scale));
}
void loadPrivate(const Address& src, Register dest);
void store8(Register src, const Address& address) {
Strb(ARMRegister(src, 32), toMemOperand(address));
}
void store8(Imm32 imm, const Address& address) {
vixl::UseScratchRegisterScope temps(this);
const ARMRegister scratch32 = temps.AcquireW();
MOZ_ASSERT(scratch32.asUnsized() != address.base);
move32(imm, scratch32.asUnsized());
Strb(scratch32, toMemOperand(address));
}
void store8(Register src, const BaseIndex& address) {
doBaseIndex(ARMRegister(src, 32), address, vixl::STRB_w);
}
void store8(Imm32 imm, const BaseIndex& address) {
vixl::UseScratchRegisterScope temps(this);
const ARMRegister scratch32 = temps.AcquireW();
MOZ_ASSERT(scratch32.asUnsized() != address.base);
MOZ_ASSERT(scratch32.asUnsized() != address.index);
Mov(scratch32, Operand(imm.value));
doBaseIndex(scratch32, address, vixl::STRB_w);
}
void store16(Register src, const Address& address) {
Strh(ARMRegister(src, 32), toMemOperand(address));
}
void store16(Imm32 imm, const Address& address) {
vixl::UseScratchRegisterScope temps(this);
const ARMRegister scratch32 = temps.AcquireW();
MOZ_ASSERT(scratch32.asUnsized() != address.base);
move32(imm, scratch32.asUnsized());
Strh(scratch32, toMemOperand(address));
}
void store16(Register src, const BaseIndex& address) {
doBaseIndex(ARMRegister(src, 32), address, vixl::STRH_w);
}
void store16(Imm32 imm, const BaseIndex& address) {
vixl::UseScratchRegisterScope temps(this);
const ARMRegister scratch32 = temps.AcquireW();
MOZ_ASSERT(scratch32.asUnsized() != address.base);
MOZ_ASSERT(scratch32.asUnsized() != address.index);
Mov(scratch32, Operand(imm.value));
doBaseIndex(scratch32, address, vixl::STRH_w);
}
template <typename S, typename T>
void store16Unaligned(const S& src, const T& dest) {
store16(src, dest);
}
void storePtr(ImmWord imm, const Address& address) {
vixl::UseScratchRegisterScope temps(this);
const Register scratch = temps.AcquireX().asUnsized();
MOZ_ASSERT(scratch != address.base);
movePtr(imm, scratch);
storePtr(scratch, address);
}
void storePtr(ImmPtr imm, const Address& address) {
vixl::UseScratchRegisterScope temps(this);
const ARMRegister scratch64 = temps.AcquireX();
MOZ_ASSERT(scratch64.asUnsized() != address.base);
Mov(scratch64, uint64_t(imm.value));
Str(scratch64, toMemOperand(address));
}
void storePtr(ImmGCPtr imm, const Address& address) {
vixl::UseScratchRegisterScope temps(this);
const Register scratch = temps.AcquireX().asUnsized();
MOZ_ASSERT(scratch != address.base);
movePtr(imm, scratch);
storePtr(scratch, address);
}
void storePtr(Register src, const Address& address) {
Str(ARMRegister(src, 64), toMemOperand(address));
}
void storePtr(ImmWord imm, const BaseIndex& address) {
vixl::UseScratchRegisterScope temps(this);
const ARMRegister scratch64 = temps.AcquireX();
MOZ_ASSERT(scratch64.asUnsized() != address.base);
MOZ_ASSERT(scratch64.asUnsized() != address.index);
Mov(scratch64, Operand(imm.value));
doBaseIndex(scratch64, address, vixl::STR_x);
}
void storePtr(ImmGCPtr imm, const BaseIndex& address) {
vixl::UseScratchRegisterScope temps(this);
const Register scratch = temps.AcquireX().asUnsized();
MOZ_ASSERT(scratch != address.base);
MOZ_ASSERT(scratch != address.index);
movePtr(imm, scratch);
doBaseIndex(ARMRegister(scratch, 64), address, vixl::STR_x);
}
void storePtr(Register src, const BaseIndex& address) {
doBaseIndex(ARMRegister(src, 64), address, vixl::STR_x);
}
void storePtr(Register src, AbsoluteAddress address) {
vixl::UseScratchRegisterScope temps(this);
const ARMRegister scratch64 = temps.AcquireX();
Mov(scratch64, uint64_t(address.addr));
Str(ARMRegister(src, 64), MemOperand(scratch64));
}
void store32(Register src, AbsoluteAddress address) {
vixl::UseScratchRegisterScope temps(this);
const ARMRegister scratch64 = temps.AcquireX();
Mov(scratch64, uint64_t(address.addr));
Str(ARMRegister(src, 32), MemOperand(scratch64));
}
void store32(Imm32 imm, const Address& address) {
vixl::UseScratchRegisterScope temps(this);
const ARMRegister scratch32 = temps.AcquireW();
MOZ_ASSERT(scratch32.asUnsized() != address.base);
Mov(scratch32, uint64_t(imm.value));
Str(scratch32, toMemOperand(address));
}
void store32(Register r, const Address& address) {
Str(ARMRegister(r, 32), toMemOperand(address));
}
void store32(Imm32 imm, const BaseIndex& address) {
vixl::UseScratchRegisterScope temps(this);
const ARMRegister scratch32 = temps.AcquireW();
MOZ_ASSERT(scratch32.asUnsized() != address.base);
MOZ_ASSERT(scratch32.asUnsized() != address.index);
Mov(scratch32, imm.value);
doBaseIndex(scratch32, address, vixl::STR_w);
}
void store32(Register r, const BaseIndex& address) {
doBaseIndex(ARMRegister(r, 32), address, vixl::STR_w);
}
void store32_NoSecondScratch(Imm32 imm, const Address& address) {
vixl::UseScratchRegisterScope temps(this);
temps.Exclude(ARMRegister(ScratchReg2, 32)); // Disallow ScratchReg2.
const ARMRegister scratch32 = temps.AcquireW();
MOZ_ASSERT(scratch32.asUnsized() != address.base);
Mov(scratch32, uint64_t(imm.value));
Str(scratch32, toMemOperand(address));
}
template <typename S, typename T>
void store32Unaligned(const S& src, const T& dest) {
store32(src, dest);
}
void store64(Register64 src, Address address) { storePtr(src.reg, address); }
void store64(Register64 src, const BaseIndex& address) {
storePtr(src.reg, address);
}
void store64(Imm64 imm, const BaseIndex& address) {
storePtr(ImmWord(imm.value), address);
}
void store64(Imm64 imm, const Address& address) {
storePtr(ImmWord(imm.value), address);
}
template <typename S, typename T>
void store64Unaligned(const S& src, const T& dest) {
store64(src, dest);
}
// StackPointer manipulation.
inline void addToStackPtr(Register src);
inline void addToStackPtr(Imm32 imm);
inline void addToStackPtr(const Address& src);
inline void addStackPtrTo(Register dest);
inline void subFromStackPtr(Register src);
inline void subFromStackPtr(Imm32 imm);
inline void subStackPtrFrom(Register dest);
inline void andToStackPtr(Imm32 t);
inline void andStackPtrTo(Register dest);
inline void moveToStackPtr(Register src);
inline void moveStackPtrTo(Register dest);
inline void loadStackPtr(const Address& src);
inline void storeStackPtr(const Address& dest);
// StackPointer testing functions.
inline void branchTestStackPtr(Condition cond, Imm32 rhs, Label* label);
inline void branchStackPtr(Condition cond, Register rhs, Label* label);
inline void branchStackPtrRhs(Condition cond, Address lhs, Label* label);
inline void branchStackPtrRhs(Condition cond, AbsoluteAddress lhs,
Label* label);
void testPtr(Register lhs, Register rhs) {
Tst(ARMRegister(lhs, 64), Operand(ARMRegister(rhs, 64)));
}
void test32(Register lhs, Register rhs) {
Tst(ARMRegister(lhs, 32), Operand(ARMRegister(rhs, 32)));
}
void test32(const Address& addr, Imm32 imm) {
vixl::UseScratchRegisterScope temps(this);
const ARMRegister scratch32 = temps.AcquireW();
MOZ_ASSERT(scratch32.asUnsized() != addr.base);
load32(addr, scratch32.asUnsized());
Tst(scratch32, Operand(imm.value));
}
void test32(Register lhs, Imm32 rhs) {
Tst(ARMRegister(lhs, 32), Operand(rhs.value));
}
void cmp32(Register lhs, Imm32 rhs) {
Cmp(ARMRegister(lhs, 32), Operand(rhs.value));
}
void cmp32(Register a, Register b) {
Cmp(ARMRegister(a, 32), Operand(ARMRegister(b, 32)));
}
void cmp32(const Address& lhs, Imm32 rhs) {
vixl::UseScratchRegisterScope temps(this);
const ARMRegister scratch32 = temps.AcquireW();
MOZ_ASSERT(scratch32.asUnsized() != lhs.base);
Ldr(scratch32, toMemOperand(lhs));
Cmp(scratch32, Operand(rhs.value));
}
void cmp32(const Address& lhs, Register rhs) {
vixl::UseScratchRegisterScope temps(this);
const ARMRegister scratch32 = temps.AcquireW();
MOZ_ASSERT(scratch32.asUnsized() != lhs.base);
MOZ_ASSERT(scratch32.asUnsized() != rhs);
Ldr(scratch32, toMemOperand(lhs));
Cmp(scratch32, Operand(ARMRegister(rhs, 32)));
}
void cmp32(const vixl::Operand& lhs, Imm32 rhs) {
vixl::UseScratchRegisterScope temps(this);
const ARMRegister scratch32 = temps.AcquireW();
Mov(scratch32, lhs);
Cmp(scratch32, Operand(rhs.value));
}
void cmp32(const vixl::Operand& lhs, Register rhs) {
vixl::UseScratchRegisterScope temps(this);
const ARMRegister scratch32 = temps.AcquireW();
Mov(scratch32, lhs);
Cmp(scratch32, Operand(ARMRegister(rhs, 32)));
}
void cmn32(Register lhs, Imm32 rhs) {
Cmn(ARMRegister(lhs, 32), Operand(rhs.value));
}
void cmpPtr(Register lhs, Imm32 rhs) {
Cmp(ARMRegister(lhs, 64), Operand(rhs.value));
}
void cmpPtr(Register lhs, ImmWord rhs) {
Cmp(ARMRegister(lhs, 64), Operand(rhs.value));
}
void cmpPtr(Register lhs, ImmPtr rhs) {
Cmp(ARMRegister(lhs, 64), Operand(uint64_t(rhs.value)));
}
void cmpPtr(Register lhs, Register rhs) {
Cmp(ARMRegister(lhs, 64), ARMRegister(rhs, 64));
}
void cmpPtr(Register lhs, ImmGCPtr rhs) {
vixl::UseScratchRegisterScope temps(this);
const Register scratch = temps.AcquireX().asUnsized();
MOZ_ASSERT(scratch != lhs);
movePtr(rhs, scratch);
cmpPtr(lhs, scratch);
}
void cmpPtr(const Address& lhs, Register rhs) {
vixl::UseScratchRegisterScope temps(this);
const ARMRegister scratch64 = temps.AcquireX();
MOZ_ASSERT(scratch64.asUnsized() != lhs.base);
MOZ_ASSERT(scratch64.asUnsized() != rhs);
Ldr(scratch64, toMemOperand(lhs));
Cmp(scratch64, Operand(ARMRegister(rhs, 64)));
}
void cmpPtr(const Address& lhs, ImmWord rhs) {
vixl::UseScratchRegisterScope temps(this);
const ARMRegister scratch64 = temps.AcquireX();
MOZ_ASSERT(scratch64.asUnsized() != lhs.base);
Ldr(scratch64, toMemOperand(lhs));
Cmp(scratch64, Operand(rhs.value));
}
void cmpPtr(const Address& lhs, ImmPtr rhs) {
vixl::UseScratchRegisterScope temps(this);
const ARMRegister scratch64 = temps.AcquireX();
MOZ_ASSERT(scratch64.asUnsized() != lhs.base);
Ldr(scratch64, toMemOperand(lhs));
Cmp(scratch64, Operand(uint64_t(rhs.value)));
}
void cmpPtr(const Address& lhs, ImmGCPtr rhs) {
vixl::UseScratchRegisterScope temps(this);
const Register scratch = temps.AcquireX().asUnsized();
MOZ_ASSERT(scratch != lhs.base);
loadPtr(lhs, scratch);
cmpPtr(scratch, rhs);
}
void loadDouble(const Address& src, FloatRegister dest) {
Ldr(ARMFPRegister(dest, 64), MemOperand(src));
}
void loadDouble(const BaseIndex& src, FloatRegister dest) {
ARMRegister base = toARMRegister(src.base, 64);
ARMRegister index(src.index, 64);
if (src.offset == 0) {
Ldr(ARMFPRegister(dest, 64),
MemOperand(base, index, vixl::LSL, unsigned(src.scale)));
return;
}
vixl::UseScratchRegisterScope temps(this);
const ARMRegister scratch64 = temps.AcquireX();
MOZ_ASSERT(scratch64.asUnsized() != src.base);
MOZ_ASSERT(scratch64.asUnsized() != src.index);
Add(scratch64, base, Operand(index, vixl::LSL, unsigned(src.scale)));
Ldr(ARMFPRegister(dest, 64), MemOperand(scratch64, src.offset));
}
void loadFloatAsDouble(const Address& addr, FloatRegister dest) {
Ldr(ARMFPRegister(dest, 32), toMemOperand(addr));
fcvt(ARMFPRegister(dest, 64), ARMFPRegister(dest, 32));
}
void loadFloatAsDouble(const BaseIndex& src, FloatRegister dest) {
ARMRegister base = toARMRegister(src.base, 64);
ARMRegister index(src.index, 64);
if (src.offset == 0) {
Ldr(ARMFPRegister(dest, 32),
MemOperand(base, index, vixl::LSL, unsigned(src.scale)));
} else {
vixl::UseScratchRegisterScope temps(this);
const ARMRegister scratch64 = temps.AcquireX();
MOZ_ASSERT(scratch64.asUnsized() != src.base);
MOZ_ASSERT(scratch64.asUnsized() != src.index);
Add(scratch64, base, Operand(index, vixl::LSL, unsigned(src.scale)));
Ldr(ARMFPRegister(dest, 32), MemOperand(scratch64, src.offset));
}
fcvt(ARMFPRegister(dest, 64), ARMFPRegister(dest, 32));
}
void loadFloat32(const Address& addr, FloatRegister dest) {
Ldr(ARMFPRegister(dest, 32), toMemOperand(addr));
}
void loadFloat32(const BaseIndex& src, FloatRegister dest) {
ARMRegister base = toARMRegister(src.base, 64);
ARMRegister index(src.index, 64);
if (src.offset == 0) {
Ldr(ARMFPRegister(dest, 32),
MemOperand(base, index, vixl::LSL, unsigned(src.scale)));
} else {
vixl::UseScratchRegisterScope temps(this);
const ARMRegister scratch64 = temps.AcquireX();
MOZ_ASSERT(scratch64.asUnsized() != src.base);
MOZ_ASSERT(scratch64.asUnsized() != src.index);
Add(scratch64, base, Operand(index, vixl::LSL, unsigned(src.scale)));
Ldr(ARMFPRegister(dest, 32), MemOperand(scratch64, src.offset));
}
}
void moveDouble(FloatRegister src, FloatRegister dest) {
fmov(ARMFPRegister(dest, 64), ARMFPRegister(src, 64));
}
void zeroDouble(FloatRegister reg) {
fmov(ARMFPRegister(reg, 64), vixl::xzr);
}
void zeroFloat32(FloatRegister reg) {
fmov(ARMFPRegister(reg, 32), vixl::wzr);
}
void moveFloat32(FloatRegister src, FloatRegister dest) {
fmov(ARMFPRegister(dest, 32), ARMFPRegister(src, 32));
}
void moveFloatAsDouble(Register src, FloatRegister dest) {
MOZ_CRASH("moveFloatAsDouble");
}
void splitSignExtTag(const ValueOperand& operand, Register dest) {
splitSignExtTag(operand.valueReg(), dest);
}
void splitSignExtTag(const Address& operand, Register dest) {
loadPtr(operand, dest);
splitSignExtTag(dest, dest);
}
void splitSignExtTag(const BaseIndex& operand, Register dest) {
loadPtr(operand, dest);
splitSignExtTag(dest, dest);
}
// Extracts the tag of a value and places it in tag
inline void splitTagForTest(const ValueOperand& value, ScratchTagScope& tag);
void cmpTag(const ValueOperand& operand, ImmTag tag) { MOZ_CRASH("cmpTag"); }
void load32(const Address& address, Register dest) {
Ldr(ARMRegister(dest, 32), toMemOperand(address));
}
void load32(const BaseIndex& src, Register dest) {
doBaseIndex(ARMRegister(dest, 32), src, vixl::LDR_w);
}
void load32(AbsoluteAddress address, Register dest) {
vixl::UseScratchRegisterScope temps(this);
const ARMRegister scratch64 = temps.AcquireX();
movePtr(ImmWord((uintptr_t)address.addr), scratch64.asUnsized());
ldr(ARMRegister(dest, 32), MemOperand(scratch64));
}
template <typename S>
void load32Unaligned(const S& src, Register dest) {
load32(src, dest);
}
void load64(const Address& address, Register64 dest) {
loadPtr(address, dest.reg);
}
void load64(const BaseIndex& address, Register64 dest) {
loadPtr(address, dest.reg);
}
template <typename S>
void load64Unaligned(const S& src, Register64 dest) {
load64(src, dest);
}
void load8SignExtend(const Address& address, Register dest) {
Ldrsb(ARMRegister(dest, 32), toMemOperand(address));
}
void load8SignExtend(const BaseIndex& src, Register dest) {
doBaseIndex(ARMRegister(dest, 32), src, vixl::LDRSB_w);
}
void load8ZeroExtend(const Address& address, Register dest) {
Ldrb(ARMRegister(dest, 32), toMemOperand(address));
}
void load8ZeroExtend(const BaseIndex& src, Register dest) {
doBaseIndex(ARMRegister(dest, 32), src, vixl::LDRB_w);
}
void load16SignExtend(const Address& address, Register dest) {
Ldrsh(ARMRegister(dest, 32), toMemOperand(address));
}
void load16SignExtend(const BaseIndex& src, Register dest) {
doBaseIndex(ARMRegister(dest, 32), src, vixl::LDRSH_w);
}
template <typename S>
void load16UnalignedSignExtend(const S& src, Register dest) {
load16SignExtend(src, dest);
}
void load16ZeroExtend(const Address& address, Register dest) {
Ldrh(ARMRegister(dest, 32), toMemOperand(address));
}
void load16ZeroExtend(const BaseIndex& src, Register dest) {
doBaseIndex(ARMRegister(dest, 32), src, vixl::LDRH_w);
}
template <typename S>
void load16UnalignedZeroExtend(const S& src, Register dest) {
load16ZeroExtend(src, dest);
}
void adds32(Register src, Register dest) {
Adds(ARMRegister(dest, 32), ARMRegister(dest, 32),
Operand(ARMRegister(src, 32)));
}
void adds32(Imm32 imm, Register dest) {
Adds(ARMRegister(dest, 32), ARMRegister(dest, 32), Operand(imm.value));
}
void adds32(Imm32 imm, const Address& dest) {
vixl::UseScratchRegisterScope temps(this);
const ARMRegister scratch32 = temps.AcquireW();
MOZ_ASSERT(scratch32.asUnsized() != dest.base);
Ldr(scratch32, toMemOperand(dest));
Adds(scratch32, scratch32, Operand(imm.value));
Str(scratch32, toMemOperand(dest));
}
void adds64(Imm32 imm, Register dest) {
Adds(ARMRegister(dest, 64), ARMRegister(dest, 64), Operand(imm.value));
}
void adds64(Register src, Register dest) {
Adds(ARMRegister(dest, 64), ARMRegister(dest, 64),
Operand(ARMRegister(src, 64)));
}
void subs32(Imm32 imm, Register dest) {
Subs(ARMRegister(dest, 32), ARMRegister(dest, 32), Operand(imm.value));
}
void subs32(Register src, Register dest) {
Subs(ARMRegister(dest, 32), ARMRegister(dest, 32),
Operand(ARMRegister(src, 32)));
}
void subs64(Imm32 imm, Register dest) {
Subs(ARMRegister(dest, 64), ARMRegister(dest, 64), Operand(imm.value));
}
void subs64(Register src, Register dest) {
Subs(ARMRegister(dest, 64), ARMRegister(dest, 64),
Operand(ARMRegister(src, 64)));
}
void ret() {
pop(lr);
abiret();
}
void retn(Imm32 n) {
vixl::UseScratchRegisterScope temps(this);
MOZ_ASSERT(temps.IsAvailable(ScratchReg64)); // ip0
temps.Exclude(ScratchReg64);
// ip0 <- [sp]; sp += n; ret ip0
Ldr(ScratchReg64,
MemOperand(GetStackPointer64(), ptrdiff_t(n.value), vixl::PostIndex));
syncStackPtr(); // SP is always used to transmit the stack between calls.
Ret(ScratchReg64);
}
void j(Condition cond, Label* dest) { B(dest, cond); }
void branch(Condition cond, Label* label) { B(label, cond); }
void branch(JitCode* target) {
syncStackPtr();
BufferOffset loc =
b(-1,
LabelDoc()); // The jump target will be patched by executableCopy().
addPendingJump(loc, ImmPtr(target->raw()), RelocationKind::JITCODE);
}
void compareDouble(DoubleCondition cond, FloatRegister lhs,
FloatRegister rhs) {
Fcmp(ARMFPRegister(lhs, 64), ARMFPRegister(rhs, 64));
}
void compareFloat(DoubleCondition cond, FloatRegister lhs,
FloatRegister rhs) {
Fcmp(ARMFPRegister(lhs, 32), ARMFPRegister(rhs, 32));
}
void compareSimd128Int(Assembler::Condition cond, ARMFPRegister dest,
ARMFPRegister lhs, ARMFPRegister rhs);
void compareSimd128Float(Assembler::Condition cond, ARMFPRegister dest,
ARMFPRegister lhs, ARMFPRegister rhs);
void rightShiftInt8x16(Register rhs, FloatRegister lhsDest,
FloatRegister temp, bool isUnsigned);
void rightShiftInt16x8(Register rhs, FloatRegister lhsDest,
FloatRegister temp, bool isUnsigned);
void rightShiftInt32x4(Register rhs, FloatRegister lhsDest,
FloatRegister temp, bool isUnsigned);
void branchNegativeZero(FloatRegister reg, Register scratch, Label* label) {
MOZ_CRASH("branchNegativeZero");
}
void branchNegativeZeroFloat32(FloatRegister reg, Register scratch,
Label* label) {
MOZ_CRASH("branchNegativeZeroFloat32");
}
void boxDouble(FloatRegister src, const ValueOperand& dest, FloatRegister) {
Fmov(ARMRegister(dest.valueReg(), 64), ARMFPRegister(src, 64));
}
void boxNonDouble(JSValueType type, Register src, const ValueOperand& dest) {
boxValue(type, src, dest.valueReg());
}
// Note that the |dest| register here may be ScratchReg, so we shouldn't use
// it.
void unboxInt32(const ValueOperand& src, Register dest) {
move32(src.valueReg(), dest);
}
void unboxInt32(const Address& src, Register dest) { load32(src, dest); }
void unboxInt32(const BaseIndex& src, Register dest) { load32(src, dest); }
template <typename T>
void unboxDouble(const T& src, FloatRegister dest) {
loadDouble(src, dest);
}
void unboxDouble(const ValueOperand& src, FloatRegister dest) {
Fmov(ARMFPRegister(dest, 64), ARMRegister(src.valueReg(), 64));
}
void unboxArgObjMagic(const ValueOperand& src, Register dest) {
MOZ_CRASH("unboxArgObjMagic");
}
void unboxArgObjMagic(const Address& src, Register dest) {
MOZ_CRASH("unboxArgObjMagic");
}
void unboxBoolean(const ValueOperand& src, Register dest) {
move32(src.valueReg(), dest);
}
void unboxBoolean(const Address& src, Register dest) { load32(src, dest); }
void unboxBoolean(const BaseIndex& src, Register dest) { load32(src, dest); }
void unboxMagic(const ValueOperand& src, Register dest) {
move32(src.valueReg(), dest);
}
void unboxNonDouble(const ValueOperand& src, Register dest,
JSValueType type) {
unboxNonDouble(src.valueReg(), dest, type);
}
template <typename T>
void unboxNonDouble(T src, Register dest, JSValueType type) {
MOZ_ASSERT(type != JSVAL_TYPE_DOUBLE);
if (type == JSVAL_TYPE_INT32 || type == JSVAL_TYPE_BOOLEAN) {
load32(src, dest);
return;
}
loadPtr(src, dest);
unboxNonDouble(dest, dest, type);
}
void unboxNonDouble(Register src, Register dest, JSValueType type) {
MOZ_ASSERT(type != JSVAL_TYPE_DOUBLE);
if (type == JSVAL_TYPE_INT32 || type == JSVAL_TYPE_BOOLEAN) {
move32(src, dest);
return;
}
Eor(ARMRegister(dest, 64), ARMRegister(src, 64),
Operand(JSVAL_TYPE_TO_SHIFTED_TAG(type)));
}
void notBoolean(const ValueOperand& val) {
ARMRegister r(val.valueReg(), 64);
eor(r, r, Operand(1));
}
void unboxObject(const ValueOperand& src, Register dest) {
unboxNonDouble(src.valueReg(), dest, JSVAL_TYPE_OBJECT);
}
void unboxObject(Register src, Register dest) {
unboxNonDouble(src, dest, JSVAL_TYPE_OBJECT);
}
void unboxObject(const Address& src, Register dest) {
loadPtr(src, dest);
unboxNonDouble(dest, dest, JSVAL_TYPE_OBJECT);
}
void unboxObject(const BaseIndex& src, Register dest) {
doBaseIndex(ARMRegister(dest, 64), src, vixl::LDR_x);
unboxNonDouble(dest, dest, JSVAL_TYPE_OBJECT);
}
template <typename T>
void unboxObjectOrNull(const T& src, Register dest) {
unboxNonDouble(src, dest, JSVAL_TYPE_OBJECT);
And(ARMRegister(dest, 64), ARMRegister(dest, 64),
Operand(~JS::detail::ValueObjectOrNullBit));
}
// See comment in MacroAssembler-x64.h.
void unboxGCThingForGCBarrier(const Address& src, Register dest) {
loadPtr(src, dest);
And(ARMRegister(dest, 64), ARMRegister(dest, 64),
Operand(JS::detail::ValueGCThingPayloadMask));
}
void unboxGCThingForGCBarrier(const ValueOperand& src, Register dest) {
And(ARMRegister(dest, 64), ARMRegister(src.valueReg(), 64),
Operand(JS::detail::ValueGCThingPayloadMask));
}
inline void unboxValue(const ValueOperand& src, AnyRegister dest,
JSValueType type);
void unboxString(const ValueOperand& operand, Register dest) {
unboxNonDouble(operand, dest, JSVAL_TYPE_STRING);
}
void unboxString(const Address& src, Register dest) {
unboxNonDouble(src, dest, JSVAL_TYPE_STRING);
}
void unboxSymbol(const ValueOperand& operand, Register dest) {
unboxNonDouble(operand, dest, JSVAL_TYPE_SYMBOL);
}
void unboxSymbol(const Address& src, Register dest) {
unboxNonDouble(src, dest, JSVAL_TYPE_SYMBOL);
}
void unboxBigInt(const ValueOperand& operand, Register dest) {
unboxNonDouble(operand, dest, JSVAL_TYPE_BIGINT);
}
void unboxBigInt(const Address& src, Register dest) {
unboxNonDouble(src, dest, JSVAL_TYPE_BIGINT);
}
// These two functions use the low 32-bits of the full value register.
void boolValueToDouble(const ValueOperand& operand, FloatRegister dest) {
convertInt32ToDouble(operand.valueReg(), dest);
}
void int32ValueToDouble(const ValueOperand& operand, FloatRegister dest) {
convertInt32ToDouble(operand.valueReg(), dest);
}
void boolValueToFloat32(const ValueOperand& operand, FloatRegister dest) {
convertInt32ToFloat32(operand.valueReg(), dest);
}
void int32ValueToFloat32(const ValueOperand& operand, FloatRegister dest) {
convertInt32ToFloat32(operand.valueReg(), dest);
}
void loadConstantDouble(double d, FloatRegister dest) {
Fmov(ARMFPRegister(dest, 64), d);
}
void loadConstantFloat32(float f, FloatRegister dest) {
Fmov(ARMFPRegister(dest, 32), f);
}
void cmpTag(Register tag, ImmTag ref) {
// As opposed to other architecture, splitTag is replaced by splitSignExtTag
// which extract the tag with a sign extension. The reason being that cmp32
// with a tag value would be too large to fit as a 12 bits immediate value,
// and would require the VIXL macro assembler to add an extra instruction
// and require extra scratch register to load the Tag value.
//
// Instead, we compare with the negative value of the sign extended tag with
// the CMN instruction. The sign extended tag is expected to be a negative
// value. Therefore the negative of the sign extended tag is expected to be
// near 0 and fit on 12 bits.
//
// Ignoring the sign extension, the logic is the following:
//
// CMP32(Reg, Tag) = Reg - Tag
// = Reg + (-Tag)
// = CMN32(Reg, -Tag)
//
// Note: testGCThing, testPrimitive and testNumber which are checking for
// inequalities should use unsigned comparisons (as done by default) in
// order to keep the same relation order after the sign extension, i.e.
// using Above or Below which are based on the carry flag.
uint32_t hiShift = JSVAL_TAG_SHIFT - 32;
int32_t seTag = int32_t(ref.value);
seTag = (seTag << hiShift) >> hiShift;
MOZ_ASSERT(seTag < 0);
int32_t negTag = -seTag;
// Check thest negTag is encoded on a 12 bits immediate value.
MOZ_ASSERT((negTag & ~0xFFF) == 0);
cmn32(tag, Imm32(negTag));
}
// Register-based tests.
Condition testUndefined(Condition cond, Register tag) {
MOZ_ASSERT(cond == Equal || cond == NotEqual);
cmpTag(tag, ImmTag(JSVAL_TAG_UNDEFINED));
return cond;
}
Condition testInt32(Condition cond, Register tag) {
MOZ_ASSERT(cond == Equal || cond == NotEqual);
cmpTag(tag, ImmTag(JSVAL_TAG_INT32));
return cond;
}
Condition testBoolean(Condition cond, Register tag) {
MOZ_ASSERT(cond == Equal || cond == NotEqual);
cmpTag(tag, ImmTag(JSVAL_TAG_BOOLEAN));
return cond;
}
Condition testNull(Condition cond, Register tag) {
MOZ_ASSERT(cond == Equal || cond == NotEqual);
cmpTag(tag, ImmTag(JSVAL_TAG_NULL));
return cond;
}
Condition testString(Condition cond, Register tag) {
MOZ_ASSERT(cond == Equal || cond == NotEqual);
cmpTag(tag, ImmTag(JSVAL_TAG_STRING));
return cond;
}
Condition testSymbol(Condition cond, Register tag) {
MOZ_ASSERT(cond == Equal || cond == NotEqual);
cmpTag(tag, ImmTag(JSVAL_TAG_SYMBOL));
return cond;
}
Condition testBigInt(Condition cond, Register tag) {
MOZ_ASSERT(cond == Equal || cond == NotEqual);
cmpTag(tag, ImmTag(JSVAL_TAG_BIGINT));
return cond;
}
Condition testObject(Condition cond, Register tag) {
MOZ_ASSERT(cond == Equal || cond == NotEqual);
cmpTag(tag, ImmTag(JSVAL_TAG_OBJECT));
return cond;
}
Condition testDouble(Condition cond, Register tag) {
MOZ_ASSERT(cond == Equal || cond == NotEqual);
cmpTag(tag, ImmTag(JSVAL_TAG_MAX_DOUBLE));
// Requires unsigned comparison due to cmpTag internals.
return (cond == Equal) ? BelowOrEqual : Above;
}
Condition testNumber(Condition cond, Register tag) {
MOZ_ASSERT(cond == Equal || cond == NotEqual);
cmpTag(tag, ImmTag(JS::detail::ValueUpperInclNumberTag));
// Requires unsigned comparison due to cmpTag internals.
return (cond == Equal) ? BelowOrEqual : Above;
}
Condition testGCThing(Condition cond, Register tag) {
MOZ_ASSERT(cond == Equal || cond == NotEqual);
cmpTag(tag, ImmTag(JS::detail::ValueLowerInclGCThingTag));
// Requires unsigned comparison due to cmpTag internals.
return (cond == Equal) ? AboveOrEqual : Below;
}
Condition testMagic(Condition cond, Register tag) {
MOZ_ASSERT(cond == Equal || cond == NotEqual);
cmpTag(tag, ImmTag(JSVAL_TAG_MAGIC));
return cond;
}
Condition testPrimitive(Condition cond, Register tag) {
MOZ_ASSERT(cond == Equal || cond == NotEqual);
cmpTag(tag, ImmTag(JS::detail::ValueUpperExclPrimitiveTag));
// Requires unsigned comparison due to cmpTag internals.
return (cond == Equal) ? Below : AboveOrEqual;
}
Condition testError(Condition cond, Register tag) {
return testMagic(cond, tag);
}
// ValueOperand-based tests.
Condition testInt32(Condition cond, const ValueOperand& value) {
// The incoming ValueOperand may use scratch registers.
vixl::UseScratchRegisterScope temps(this);
const Register scratch = temps.AcquireX().asUnsized();
MOZ_ASSERT(scratch != value.valueReg());
splitSignExtTag(value, scratch);
return testInt32(cond, scratch);
}
Condition testBoolean(Condition cond, const ValueOperand& value) {
vixl::UseScratchRegisterScope temps(this);
const Register scratch = temps.AcquireX().asUnsized();
MOZ_ASSERT(value.valueReg() != scratch);
splitSignExtTag(value, scratch);
return testBoolean(cond, scratch);
}
Condition testDouble(Condition cond, const ValueOperand& value) {
vixl::UseScratchRegisterScope temps(this);
const Register scratch = temps.AcquireX().asUnsized();
MOZ_ASSERT(value.valueReg() != scratch);
splitSignExtTag(value, scratch);
return testDouble(cond, scratch);
}
Condition testNull(Condition cond, const ValueOperand& value) {
vixl::UseScratchRegisterScope temps(this);
const Register scratch = temps.AcquireX().asUnsized();
MOZ_ASSERT(value.valueReg() != scratch);
splitSignExtTag(value, scratch);
return testNull(cond, scratch);
}
Condition testUndefined(Condition cond, const ValueOperand& value) {
vixl::UseScratchRegisterScope temps(this);
const Register scratch = temps.AcquireX().asUnsized();
MOZ_ASSERT(value.valueReg() != scratch);
splitSignExtTag(value, scratch);
return testUndefined(cond, scratch);
}
Condition testString(Condition cond, const ValueOperand& value) {
vixl::UseScratchRegisterScope temps(this);
const Register scratch = temps.AcquireX().asUnsized();
MOZ_ASSERT(value.valueReg() != scratch);
splitSignExtTag(value, scratch);
return testString(cond, scratch);
}
Condition testSymbol(Condition cond, const ValueOperand& value) {
vixl::UseScratchRegisterScope temps(this);
const Register scratch = temps.AcquireX().asUnsized();
MOZ_ASSERT(value.valueReg() != scratch);
splitSignExtTag(value, scratch);
return testSymbol(cond, scratch);
}
Condition testBigInt(Condition cond, const ValueOperand& value) {
vixl::UseScratchRegisterScope temps(this);
const Register scratch = temps.AcquireX().asUnsized();
MOZ_ASSERT(value.valueReg() != scratch);
splitSignExtTag(value, scratch);
return testBigInt(cond, scratch);
}
Condition testObject(Condition cond, const ValueOperand& value) {
vixl::UseScratchRegisterScope temps(this);
const Register scratch = temps.AcquireX().asUnsized();
MOZ_ASSERT(value.valueReg() != scratch);
splitSignExtTag(value, scratch);
return testObject(cond, scratch);
}
Condition testNumber(Condition cond, const ValueOperand& value) {
vixl::UseScratchRegisterScope temps(this);
const Register scratch = temps.AcquireX().asUnsized();
MOZ_ASSERT(value.valueReg() != scratch);
splitSignExtTag(value, scratch);
return testNumber(cond, scratch);
}
Condition testPrimitive(Condition cond, const ValueOperand& value) {
vixl::UseScratchRegisterScope temps(this);
const Register scratch = temps.AcquireX().asUnsized();
MOZ_ASSERT(value.valueReg() != scratch);
splitSignExtTag(value, scratch);
return testPrimitive(cond, scratch);
}
Condition testMagic(Condition cond, const ValueOperand& value) {
vixl::UseScratchRegisterScope temps(this);
const Register scratch = temps.AcquireX().asUnsized();
MOZ_ASSERT(value.valueReg() != scratch);
splitSignExtTag(value, scratch);
return testMagic(cond, scratch);
}
Condition testGCThing(Condition cond, const ValueOperand& value) {
vixl::UseScratchRegisterScope temps(this);
const Register scratch = temps.AcquireX().asUnsized();
MOZ_ASSERT(value.valueReg() != scratch);
splitSignExtTag(value, scratch);
return testGCThing(cond, scratch);
}
Condition testError(Condition cond, const ValueOperand& value) {
return testMagic(cond, value);
}
// Address-based tests.
Condition testGCThing(Condition cond, const Address& address) {
vixl::UseScratchRegisterScope temps(this);
const Register scratch = temps.AcquireX().asUnsized();
MOZ_ASSERT(address.base != scratch);
splitSignExtTag(address, scratch);
return testGCThing(cond, scratch);
}
Condition testMagic(Condition cond, const Address& address) {
vixl::UseScratchRegisterScope temps(this);
const Register scratch = temps.AcquireX().asUnsized();
MOZ_ASSERT(address.base != scratch);
splitSignExtTag(address, scratch);
return testMagic(cond, scratch);
}
Condition testInt32(Condition cond, const Address& address) {
vixl::UseScratchRegisterScope temps(this);
const Register scratch = temps.AcquireX().asUnsized();
MOZ_ASSERT(address.base != scratch);
splitSignExtTag(address, scratch);
return testInt32(cond, scratch);
}
Condition testDouble(Condition cond, const Address& address) {
vixl::UseScratchRegisterScope temps(this);
const Register scratch = temps.AcquireX().asUnsized();
MOZ_ASSERT(address.base != scratch);
splitSignExtTag(address, scratch);
return testDouble(cond, scratch);
}
Condition testBoolean(Condition cond, const Address& address) {
vixl::UseScratchRegisterScope temps(this);
const Register scratch = temps.AcquireX().asUnsized();
MOZ_ASSERT(address.base != scratch);
splitSignExtTag(address, scratch);
return testBoolean(cond, scratch);
}
Condition testNull(Condition cond, const Address& address) {
vixl::UseScratchRegisterScope temps(this);
const Register scratch = temps.AcquireX().asUnsized();
MOZ_ASSERT(address.base != scratch);
splitSignExtTag(address, scratch);
return testNull(cond, scratch);
}
Condition testUndefined(Condition cond, const Address& address) {
vixl::UseScratchRegisterScope temps(this);
const Register scratch = temps.AcquireX().asUnsized();
MOZ_ASSERT(address.base != scratch);
splitSignExtTag(address, scratch);
return testUndefined(cond, scratch);
}
Condition testString(Condition cond, const Address& address) {
vixl::UseScratchRegisterScope temps(this);
const Register scratch = temps.AcquireX().asUnsized();
MOZ_ASSERT(address.base != scratch);
splitSignExtTag(address, scratch);
return testString(cond, scratch);
}
Condition testSymbol(Condition cond, const Address& address) {
vixl::UseScratchRegisterScope temps(this);
const Register scratch = temps.AcquireX().asUnsized();
MOZ_ASSERT(address.base != scratch);
splitSignExtTag(address, scratch);
return testSymbol(cond, scratch);
}
Condition testBigInt(Condition cond, const Address& address) {
vixl::UseScratchRegisterScope temps(this);
const Register scratch = temps.AcquireX().asUnsized();
MOZ_ASSERT(address.base != scratch);
splitSignExtTag(address, scratch);
return testBigInt(cond, scratch);
}
Condition testObject(Condition cond, const Address& address) {
vixl::UseScratchRegisterScope temps(this);
const Register scratch = temps.AcquireX().asUnsized();
MOZ_ASSERT(address.base != scratch);
splitSignExtTag(address, scratch);
return testObject(cond, scratch);
}
Condition testNumber(Condition cond, const Address& address) {
vixl::UseScratchRegisterScope temps(this);
const Register scratch = temps.AcquireX().asUnsized();
MOZ_ASSERT(address.base != scratch);
splitSignExtTag(address, scratch);
return testNumber(cond, scratch);
}
// BaseIndex-based tests.
Condition testUndefined(Condition cond, const BaseIndex& src) {
vixl::UseScratchRegisterScope temps(this);
const Register scratch = temps.AcquireX().asUnsized();
MOZ_ASSERT(src.base != scratch);
MOZ_ASSERT(src.index != scratch);
splitSignExtTag(src, scratch);
return testUndefined(cond, scratch);
}
Condition testNull(Condition cond, const BaseIndex& src) {
vixl::UseScratchRegisterScope temps(this);
const Register scratch = temps.AcquireX().asUnsized();
MOZ_ASSERT(src.base != scratch);
MOZ_ASSERT(src.index != scratch);
splitSignExtTag(src, scratch);
return testNull(cond, scratch);
}
Condition testBoolean(Condition cond, const BaseIndex& src) {
vixl::UseScratchRegisterScope temps(this);
const Register scratch = temps.AcquireX().asUnsized();
MOZ_ASSERT(src.base != scratch);
MOZ_ASSERT(src.index != scratch);
splitSignExtTag(src, scratch);
return testBoolean(cond, scratch);
}
Condition testString(Condition cond, const BaseIndex& src) {
vixl::UseScratchRegisterScope temps(this);
const Register scratch = temps.AcquireX().asUnsized();
MOZ_ASSERT(src.base != scratch);
MOZ_ASSERT(src.index != scratch);
splitSignExtTag(src, scratch);
return testString(cond, scratch);
}
Condition testSymbol(Condition cond, const BaseIndex& src) {
vixl::UseScratchRegisterScope temps(this);
const Register scratch = temps.AcquireX().asUnsized();
MOZ_ASSERT(src.base != scratch);
MOZ_ASSERT(src.index != scratch);
splitSignExtTag(src, scratch);
return testSymbol(cond, scratch);
}
Condition testBigInt(Condition cond, const BaseIndex& src) {
vixl::UseScratchRegisterScope temps(this);
const Register scratch = temps.AcquireX().asUnsized();
MOZ_ASSERT(src.base != scratch);
MOZ_ASSERT(src.index != scratch);
splitSignExtTag(src, scratch);
return testBigInt(cond, scratch);
}
Condition testBigIntTruthy(bool truthy, const ValueOperand& value) {
vixl::UseScratchRegisterScope temps(this);
const Register scratch = temps.AcquireX().asUnsized();
MOZ_ASSERT(value.valueReg() != scratch);
unboxBigInt(value, scratch);
load32(Address(scratch, BigInt::offsetOfDigitLength()), scratch);
cmp32(scratch, Imm32(0));
return truthy ? Condition::NonZero : Condition::Zero;
}
Condition testInt32(Condition cond, const BaseIndex& src) {
vixl::UseScratchRegisterScope temps(this);
const Register scratch = temps.AcquireX().asUnsized();
MOZ_ASSERT(src.base != scratch);
MOZ_ASSERT(src.index != scratch);
splitSignExtTag(src, scratch);
return testInt32(cond, scratch);
}
Condition testObject(Condition cond, const BaseIndex& src) {
vixl::UseScratchRegisterScope temps(this);
const Register scratch = temps.AcquireX().asUnsized();
MOZ_ASSERT(src.base != scratch);
MOZ_ASSERT(src.index != scratch);
splitSignExtTag(src, scratch);
return testObject(cond, scratch);
}
Condition testDouble(Condition cond, const BaseIndex& src) {
vixl::UseScratchRegisterScope temps(this);
const Register scratch = temps.AcquireX().asUnsized();
MOZ_ASSERT(src.base != scratch);
MOZ_ASSERT(src.index != scratch);
splitSignExtTag(src, scratch);
return testDouble(cond, scratch);
}
Condition testMagic(Condition cond, const BaseIndex& src) {
vixl::UseScratchRegisterScope temps(this);
const Register scratch = temps.AcquireX().asUnsized();
MOZ_ASSERT(src.base != scratch);
MOZ_ASSERT(src.index != scratch);
splitSignExtTag(src, scratch);
return testMagic(cond, scratch);
}
Condition testGCThing(Condition cond, const BaseIndex& src) {
vixl::UseScratchRegisterScope temps(this);
const Register scratch = temps.AcquireX().asUnsized();
MOZ_ASSERT(src.base != scratch);
MOZ_ASSERT(src.index != scratch);
splitSignExtTag(src, scratch);
return testGCThing(cond, scratch);
}
Condition testInt32Truthy(bool truthy, const ValueOperand& operand) {
ARMRegister payload32(operand.valueReg(), 32);
Tst(payload32, payload32);
return truthy ? NonZero : Zero;
}
Condition testBooleanTruthy(bool truthy, const ValueOperand& operand) {
ARMRegister payload32(operand.valueReg(), 32);
Tst(payload32, payload32);
return truthy ? NonZero : Zero;
}
Condition testStringTruthy(bool truthy, const ValueOperand& value) {
vixl::UseScratchRegisterScope temps(this);
const Register scratch = temps.AcquireX().asUnsized();
const ARMRegister scratch32(scratch, 32);
const ARMRegister scratch64(scratch, 64);
MOZ_ASSERT(value.valueReg() != scratch);
unboxString(value, scratch);
Ldr(scratch32, MemOperand(scratch64, JSString::offsetOfLength()));
Cmp(scratch32, Operand(0));
return truthy ? Condition::NonZero : Condition::Zero;
}
void int32OrDouble(Register src, ARMFPRegister dest) {
Label isInt32;
Label join;
testInt32(Equal, ValueOperand(src));
B(&isInt32, Equal);
// is double, move the bits as is
Fmov(dest, ARMRegister(src, 64));
B(&join);
bind(&isInt32);
// is int32, do a conversion while moving
Scvtf(dest, ARMRegister(src, 32));
bind(&join);
}
void loadUnboxedValue(Address address, MIRType type, AnyRegister dest) {
if (dest.isFloat()) {
vixl::UseScratchRegisterScope temps(this);
const ARMRegister scratch64 = temps.AcquireX();
MOZ_ASSERT(scratch64.asUnsized() != address.base);
Ldr(scratch64, toMemOperand(address));
int32OrDouble(scratch64.asUnsized(), ARMFPRegister(dest.fpu(), 64));
} else {
unboxNonDouble(address, dest.gpr(), ValueTypeFromMIRType(type));
}
}
void loadUnboxedValue(BaseIndex address, MIRType type, AnyRegister dest) {
if (dest.isFloat()) {
vixl::UseScratchRegisterScope temps(this);
const ARMRegister scratch64 = temps.AcquireX();
MOZ_ASSERT(scratch64.asUnsized() != address.base);
MOZ_ASSERT(scratch64.asUnsized() != address.index);
doBaseIndex(scratch64, address, vixl::LDR_x);
int32OrDouble(scratch64.asUnsized(), ARMFPRegister(dest.fpu(), 64));
} else {
unboxNonDouble(address, dest.gpr(), ValueTypeFromMIRType(type));
}
}
void loadInstructionPointerAfterCall(Register dest) {
MOZ_CRASH("loadInstructionPointerAfterCall");
}
// Emit a B that can be toggled to a CMP. See ToggleToJmp(), ToggleToCmp().
CodeOffset toggledJump(Label* label) {
BufferOffset offset = b(label, Always);
CodeOffset ret(offset.getOffset());
return ret;
}
// load: offset to the load instruction obtained by movePatchablePtr().
void writeDataRelocation(ImmGCPtr ptr, BufferOffset load) {
// Raw GC pointer relocations and Value relocations both end up in
// Assembler::TraceDataRelocations.
if (ptr.value) {
if (gc::IsInsideNursery(ptr.value)) {
embedsNurseryPointers_ = true;
}
dataRelocations_.writeUnsigned(load.getOffset());
}
}
void writeDataRelocation(const Value& val, BufferOffset load) {
// Raw GC pointer relocations and Value relocations both end up in
// Assembler::TraceDataRelocations.
if (val.isGCThing()) {
gc::Cell* cell = val.toGCThing();
if (cell && gc::IsInsideNursery(cell)) {
embedsNurseryPointers_ = true;
}
dataRelocations_.writeUnsigned(load.getOffset());
}
}
void computeEffectiveAddress(const Address& address, Register dest) {
Add(ARMRegister(dest, 64), toARMRegister(address.base, 64),
Operand(address.offset));
}
void computeEffectiveAddress(const Address& address, RegisterOrSP dest) {
Add(toARMRegister(dest, 64), toARMRegister(address.base, 64),
Operand(address.offset));
}
void computeEffectiveAddress(const BaseIndex& address, Register dest) {
ARMRegister dest64(dest, 64);
ARMRegister base64 = toARMRegister(address.base, 64);
ARMRegister index64(address.index, 64);
Add(dest64, base64, Operand(index64, vixl::LSL, address.scale));
if (address.offset) {
Add(dest64, dest64, Operand(address.offset));
}
}
public:
void handleFailureWithHandlerTail(Label* profilerExitTail);
void profilerEnterFrame(Register framePtr, Register scratch);
void profilerEnterFrame(RegisterOrSP framePtr, Register scratch);
void profilerExitFrame();
Address ToPayload(Address value) { return value; }
Address ToType(Address value) { return value; }
void wasmLoadImpl(const wasm::MemoryAccessDesc& access, Register memoryBase,
Register ptr, AnyRegister outany, Register64 out64);
void wasmLoadImpl(const wasm::MemoryAccessDesc& access, MemOperand srcAddr,
AnyRegister outany, Register64 out64);
void wasmStoreImpl(const wasm::MemoryAccessDesc& access, AnyRegister valany,
Register64 val64, Register memoryBase, Register ptr);
void wasmStoreImpl(const wasm::MemoryAccessDesc& access, MemOperand destAddr,
AnyRegister valany, Register64 val64);
// Emit a BLR or NOP instruction. ToggleCall can be used to patch
// this instruction.
CodeOffset toggledCall(JitCode* target, bool enabled) {
// The returned offset must be to the first instruction generated,
// for the debugger to match offset with Baseline's pcMappingEntries_.
BufferOffset offset = nextOffset();
syncStackPtr();
BufferOffset loadOffset;
{
vixl::UseScratchRegisterScope temps(this);
// The register used for the load is hardcoded, so that ToggleCall
// can patch in the branch instruction easily. This could be changed,
// but then ToggleCall must read the target register from the load.
MOZ_ASSERT(temps.IsAvailable(ScratchReg2_64));
temps.Exclude(ScratchReg2_64);
loadOffset = immPool64(ScratchReg2_64, uint64_t(target->raw()));
if (enabled) {
blr(ScratchReg2_64);
} else {
nop();
}
}
addPendingJump(loadOffset, ImmPtr(target->raw()), RelocationKind::JITCODE);
CodeOffset ret(offset.getOffset());
return ret;
}
static size_t ToggledCallSize(uint8_t* code) {
// The call site is a sequence of two or three instructions:
//
// syncStack (optional)
// ldr/adr
// nop/blr
//
// Flushed constant pools can appear before any of the instructions.
const Instruction* cur = (const Instruction*)code;
cur = cur->skipPool();
if (cur->IsStackPtrSync()) cur = cur->NextInstruction();
cur = cur->skipPool();
cur = cur->NextInstruction(); // LDR/ADR
cur = cur->skipPool();
cur = cur->NextInstruction(); // NOP/BLR
return (uint8_t*)cur - code;
}
void checkARMRegAlignment(const ARMRegister& reg) {
#ifdef DEBUG
vixl::UseScratchRegisterScope temps(this);
const ARMRegister scratch64 = temps.AcquireX();
MOZ_ASSERT_IF(!reg.IsSP(), scratch64.asUnsized() != reg.asUnsized());
Label aligned;
Mov(scratch64, reg);
Tst(scratch64, Operand(StackAlignment - 1));
B(Zero, &aligned);
breakpoint();
bind(&aligned);
Mov(scratch64, vixl::xzr); // Clear the scratch register for sanity.
#endif
}
void checkStackAlignment() {
#ifdef DEBUG
checkARMRegAlignment(GetStackPointer64());
// If another register is being used to track pushes, check sp explicitly.
if (!GetStackPointer64().Is(vixl::sp)) {
checkARMRegAlignment(vixl::sp);
}
#endif
}
void abiret() {
syncStackPtr(); // SP is always used to transmit the stack between calls.
vixl::MacroAssembler::Ret(vixl::lr);
}
void clampCheck(Register r, Label* handleNotAnInt) {
MOZ_CRASH("clampCheck");
}
void stackCheck(ImmWord limitAddr, Label* label) { MOZ_CRASH("stackCheck"); }
void incrementInt32Value(const Address& addr) {
vixl::UseScratchRegisterScope temps(this);
const ARMRegister scratch32 = temps.AcquireW();
MOZ_ASSERT(scratch32.asUnsized() != addr.base);
load32(addr, scratch32.asUnsized());
Add(scratch32, scratch32, Operand(1));
store32(scratch32.asUnsized(), addr);
}
void breakpoint();
// Emits a simulator directive to save the current sp on an internal stack.
void simulatorMarkSP() {
#ifdef JS_SIMULATOR_ARM64
svc(vixl::kMarkStackPointer);
#endif
}
// Emits a simulator directive to pop from its internal stack
// and assert that the value is equal to the current sp.
void simulatorCheckSP() {
#ifdef JS_SIMULATOR_ARM64
svc(vixl::kCheckStackPointer);
#endif
}
void loadWasmGlobalPtr(uint32_t globalDataOffset, Register dest) {
loadPtr(Address(WasmTlsReg,
offsetof(wasm::TlsData, globalArea) + globalDataOffset),
dest);
}
void loadWasmPinnedRegsFromTls() {
loadPtr(Address(WasmTlsReg, offsetof(wasm::TlsData, memoryBase)), HeapReg);
}
// Overwrites the payload bits of a dest register containing a Value.
void movePayload(Register src, Register dest) {
// Bfxil cannot be used with the zero register as a source.
if (src == rzr) {
And(ARMRegister(dest, 64), ARMRegister(dest, 64),
Operand(JS::detail::ValueTagMask));
} else {
Bfxil(ARMRegister(dest, 64), ARMRegister(src, 64), 0, JSVAL_TAG_SHIFT);
}
}
protected:
bool buildOOLFakeExitFrame(void* fakeReturnAddr);
};
// See documentation for ScratchTagScope and ScratchTagScopeRelease in
// MacroAssembler-x64.h.
class ScratchTagScope {
vixl::UseScratchRegisterScope temps_;
ARMRegister scratch64_;
bool owned_;
mozilla::DebugOnly<bool> released_;
public:
ScratchTagScope(MacroAssemblerCompat& masm, const ValueOperand&)
: temps_(&masm), owned_(true), released_(false) {
scratch64_ = temps_.AcquireX();
}
operator Register() {
MOZ_ASSERT(!released_);
return scratch64_.asUnsized();
}
void release() {
MOZ_ASSERT(!released_);
released_ = true;
if (owned_) {
temps_.Release(scratch64_);
owned_ = false;
}
}
void reacquire() {
MOZ_ASSERT(released_);
released_ = false;
}
};
class ScratchTagScopeRelease {
ScratchTagScope* ts_;
public:
explicit ScratchTagScopeRelease(ScratchTagScope* ts) : ts_(ts) {
ts_->release();
}
~ScratchTagScopeRelease() { ts_->reacquire(); }
};
inline void MacroAssemblerCompat::splitTagForTest(const ValueOperand& value,
ScratchTagScope& tag) {
splitSignExtTag(value, tag);
}
typedef MacroAssemblerCompat MacroAssemblerSpecific;
} // namespace jit
} // namespace js
#endif // jit_arm64_MacroAssembler_arm64_h
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