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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_mips64_MacroAssembler_mips64_h
#define jit_mips64_MacroAssembler_mips64_h
#include "jit/mips-shared/MacroAssembler-mips-shared.h"
#include "jit/MoveResolver.h"
#include "vm/BytecodeUtil.h"
#include "wasm/WasmTypes.h"
namespace js {
namespace jit {
enum LiFlags {
Li64 = 0,
Li48 = 1,
};
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 {
ImmTag(JSValueTag mask) : Imm32(int32_t(mask)) {}
};
static constexpr ValueOperand JSReturnOperand{JSReturnReg};
static const int defaultShift = 3;
static_assert(1 << defaultShift == sizeof(JS::Value),
"The defaultShift is wrong");
// See documentation for ScratchTagScope and ScratchTagScopeRelease in
// MacroAssembler-x64.h.
class ScratchTagScope : public SecondScratchRegisterScope {
public:
ScratchTagScope(MacroAssembler& masm, const ValueOperand&)
: SecondScratchRegisterScope(masm) {}
};
class ScratchTagScopeRelease {
ScratchTagScope* ts_;
public:
explicit ScratchTagScopeRelease(ScratchTagScope* ts) : ts_(ts) {
ts_->release();
}
~ScratchTagScopeRelease() { ts_->reacquire(); }
};
class MacroAssemblerMIPS64 : public MacroAssemblerMIPSShared {
public:
using MacroAssemblerMIPSShared::ma_b;
using MacroAssemblerMIPSShared::ma_cmp_set;
using MacroAssemblerMIPSShared::ma_ld;
using MacroAssemblerMIPSShared::ma_li;
using MacroAssemblerMIPSShared::ma_load;
using MacroAssemblerMIPSShared::ma_ls;
using MacroAssemblerMIPSShared::ma_sd;
using MacroAssemblerMIPSShared::ma_ss;
using MacroAssemblerMIPSShared::ma_store;
using MacroAssemblerMIPSShared::ma_subTestOverflow;
void ma_li(Register dest, CodeLabel* label);
void ma_li(Register dest, ImmWord imm);
void ma_liPatchable(Register dest, ImmPtr imm);
void ma_liPatchable(Register dest, ImmWord imm, LiFlags flags = Li48);
// Negate
void ma_dnegu(Register rd, Register rs);
// Shift operations
void ma_dsll(Register rd, Register rt, Imm32 shift);
void ma_dsrl(Register rd, Register rt, Imm32 shift);
void ma_dsra(Register rd, Register rt, Imm32 shift);
void ma_dror(Register rd, Register rt, Imm32 shift);
void ma_drol(Register rd, Register rt, Imm32 shift);
void ma_dsll(Register rd, Register rt, Register shift);
void ma_dsrl(Register rd, Register rt, Register shift);
void ma_dsra(Register rd, Register rt, Register shift);
void ma_dror(Register rd, Register rt, Register shift);
void ma_drol(Register rd, Register rt, Register shift);
void ma_dins(Register rt, Register rs, Imm32 pos, Imm32 size);
void ma_dext(Register rt, Register rs, Imm32 pos, Imm32 size);
// doubleword swap bytes
void ma_dsbh(Register rd, Register rt);
void ma_dshd(Register rd, Register rt);
void ma_dctz(Register rd, Register rs);
// load
void ma_load(Register dest, Address address, LoadStoreSize size = SizeWord,
LoadStoreExtension extension = SignExtend);
// store
void ma_store(Register data, Address address, LoadStoreSize size = SizeWord,
LoadStoreExtension extension = SignExtend);
// arithmetic based ops
// add
void ma_daddu(Register rd, Register rs, Imm32 imm);
void ma_daddu(Register rd, Register rs);
void ma_daddu(Register rd, Imm32 imm);
void ma_addTestOverflow(Register rd, Register rs, Register rt,
Label* overflow);
void ma_addTestOverflow(Register rd, Register rs, Imm32 imm, Label* overflow);
// subtract
void ma_dsubu(Register rd, Register rs, Imm32 imm);
void ma_dsubu(Register rd, Register rs);
void ma_dsubu(Register rd, Imm32 imm);
void ma_subTestOverflow(Register rd, Register rs, Register rt,
Label* overflow);
// multiplies. For now, there are only few that we care about.
void ma_dmult(Register rs, Imm32 imm);
// stack
void ma_pop(Register r);
void ma_push(Register r);
void branchWithCode(InstImm code, Label* label, JumpKind jumpKind);
// branches when done from within mips-specific code
void ma_b(Register lhs, ImmWord imm, Label* l, Condition c,
JumpKind jumpKind = LongJump);
void ma_b(Register lhs, Address addr, Label* l, Condition c,
JumpKind jumpKind = LongJump);
void ma_b(Address addr, Imm32 imm, Label* l, Condition c,
JumpKind jumpKind = LongJump);
void ma_b(Address addr, ImmGCPtr imm, Label* l, Condition c,
JumpKind jumpKind = LongJump);
void ma_b(Address addr, Register rhs, Label* l, Condition c,
JumpKind jumpKind = LongJump) {
MOZ_ASSERT(rhs != ScratchRegister);
ma_load(ScratchRegister, addr, SizeDouble);
ma_b(ScratchRegister, rhs, l, c, jumpKind);
}
void ma_bal(Label* l, DelaySlotFill delaySlotFill = FillDelaySlot);
// fp instructions
void ma_lid(FloatRegister dest, double value);
void ma_mv(FloatRegister src, ValueOperand dest);
void ma_mv(ValueOperand src, FloatRegister dest);
void ma_ls(FloatRegister ft, Address address);
void ma_ld(FloatRegister ft, Address address);
void ma_sd(FloatRegister ft, Address address);
void ma_ss(FloatRegister ft, Address address);
void ma_pop(FloatRegister f);
void ma_push(FloatRegister f);
void ma_cmp_set(Register dst, Register lhs, ImmWord imm, Condition c);
void ma_cmp_set(Register dst, Register lhs, ImmPtr imm, Condition c);
// These functions abstract the access to high part of the double precision
// float register. They are intended to work on both 32 bit and 64 bit
// floating point coprocessor.
void moveToDoubleHi(Register src, FloatRegister dest) { as_mthc1(src, dest); }
void moveFromDoubleHi(FloatRegister src, Register dest) {
as_mfhc1(dest, src);
}
void moveToDouble(Register src, FloatRegister dest) { as_dmtc1(src, dest); }
void moveFromDouble(FloatRegister src, Register dest) { as_dmfc1(dest, src); }
};
class MacroAssembler;
class MacroAssemblerMIPS64Compat : public MacroAssemblerMIPS64 {
public:
using MacroAssemblerMIPS64::call;
MacroAssemblerMIPS64Compat() {}
void convertBoolToInt32(Register source, Register dest);
void convertInt32ToDouble(Register src, FloatRegister dest);
void convertInt32ToDouble(const Address& src, FloatRegister dest);
void convertInt32ToDouble(const BaseIndex& src, FloatRegister dest);
void convertUInt32ToDouble(Register src, FloatRegister dest);
void convertUInt32ToFloat32(Register src, FloatRegister dest);
void convertDoubleToFloat32(FloatRegister src, FloatRegister dest);
void convertDoubleToInt32(FloatRegister src, Register dest, Label* fail,
bool negativeZeroCheck = true);
void convertFloat32ToInt32(FloatRegister src, Register dest, Label* fail,
bool negativeZeroCheck = true);
void convertFloat32ToDouble(FloatRegister src, FloatRegister dest);
void convertInt32ToFloat32(Register src, FloatRegister dest);
void convertInt32ToFloat32(const Address& src, FloatRegister dest);
void movq(Register rs, Register rd);
void computeScaledAddress(const BaseIndex& address, Register dest);
void computeEffectiveAddress(const Address& address, Register dest) {
ma_daddu(dest, address.base, Imm32(address.offset));
}
void computeEffectiveAddress(const BaseIndex& address, Register dest);
void j(Label* dest) { ma_b(dest); }
void mov(Register src, Register dest) { as_ori(dest, src, 0); }
void mov(ImmWord imm, Register dest) { ma_li(dest, imm); }
void mov(ImmPtr imm, Register dest) {
mov(ImmWord(uintptr_t(imm.value)), dest);
}
void mov(CodeLabel* label, Register dest) { ma_li(dest, label); }
void mov(Register src, Address dest) { MOZ_CRASH("NYI-IC"); }
void mov(Address src, Register dest) { MOZ_CRASH("NYI-IC"); }
void writeDataRelocation(const Value& val) {
// Raw GC pointer relocations and Value relocations both end up in
// TraceOneDataRelocation.
if (val.isGCThing()) {
gc::Cell* cell = val.toGCThing();
if (cell && gc::IsInsideNursery(cell)) {
embedsNurseryPointers_ = true;
}
dataRelocations_.writeUnsigned(currentOffset());
}
}
void branch(JitCode* c) {
BufferOffset bo = m_buffer.nextOffset();
addPendingJump(bo, ImmPtr(c->raw()), RelocationKind::JITCODE);
ma_liPatchable(ScratchRegister, ImmPtr(c->raw()));
as_jr(ScratchRegister);
as_nop();
}
void branch(const Register reg) {
as_jr(reg);
as_nop();
}
void nop() { as_nop(); }
void ret() {
ma_pop(ra);
as_jr(ra);
as_nop();
}
inline void retn(Imm32 n);
void push(Imm32 imm) {
ma_li(ScratchRegister, imm);
ma_push(ScratchRegister);
}
void push(ImmWord imm) {
ma_li(ScratchRegister, imm);
ma_push(ScratchRegister);
}
void push(ImmGCPtr imm) {
ma_li(ScratchRegister, imm);
ma_push(ScratchRegister);
}
void push(const Address& address) {
loadPtr(address, ScratchRegister);
ma_push(ScratchRegister);
}
void push(Register reg) { ma_push(reg); }
void push(FloatRegister reg) { ma_push(reg); }
void pop(Register reg) { ma_pop(reg); }
void pop(FloatRegister reg) { ma_pop(reg); }
// Emit a branch that can be toggled to a non-operation. On MIPS64 we use
// "andi" instruction to toggle the branch.
// See ToggleToJmp(), ToggleToCmp().
CodeOffset toggledJump(Label* label);
// Emit a "jalr" or "nop" instruction. ToggleCall can be used to patch
// this instruction.
CodeOffset toggledCall(JitCode* target, bool enabled);
static size_t ToggledCallSize(uint8_t* code) {
// Six instructions used in: MacroAssemblerMIPS64Compat::toggledCall
return 6 * sizeof(uint32_t);
}
CodeOffset pushWithPatch(ImmWord imm) {
CodeOffset offset = movWithPatch(imm, ScratchRegister);
ma_push(ScratchRegister);
return offset;
}
CodeOffset movWithPatch(ImmWord imm, Register dest) {
CodeOffset offset = CodeOffset(currentOffset());
ma_liPatchable(dest, imm, Li64);
return offset;
}
CodeOffset movWithPatch(ImmPtr imm, Register dest) {
CodeOffset offset = CodeOffset(currentOffset());
ma_liPatchable(dest, imm);
return offset;
}
void writeCodePointer(CodeLabel* label) {
label->patchAt()->bind(currentOffset());
label->setLinkMode(CodeLabel::RawPointer);
m_buffer.ensureSpace(sizeof(void*));
writeInst(-1);
writeInst(-1);
}
void jump(Label* label) { ma_b(label); }
void jump(Register reg) {
as_jr(reg);
as_nop();
}
void jump(const Address& address) {
loadPtr(address, ScratchRegister);
as_jr(ScratchRegister);
as_nop();
}
void jump(JitCode* code) { branch(code); }
void jump(ImmPtr ptr) {
BufferOffset bo = m_buffer.nextOffset();
addPendingJump(bo, ptr, RelocationKind::HARDCODED);
ma_jump(ptr);
}
void jump(TrampolinePtr code) { jump(ImmPtr(code.value)); }
void splitTag(Register src, Register dest) {
ma_dsrl(dest, src, Imm32(JSVAL_TAG_SHIFT));
}
void splitTag(const ValueOperand& operand, Register dest) {
splitTag(operand.valueReg(), dest);
}
void splitTagForTest(const ValueOperand& value, ScratchTagScope& tag) {
splitTag(value, tag);
}
// unboxing code
void unboxNonDouble(const ValueOperand& operand, Register dest,
JSValueType type) {
unboxNonDouble(operand.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) {
ma_sll(dest, src, Imm32(0));
return;
}
MOZ_ASSERT(ScratchRegister != src);
mov(ImmWord(JSVAL_TYPE_TO_SHIFTED_TAG(type)), ScratchRegister);
as_xor(dest, src, ScratchRegister);
}
template <typename T>
void unboxObjectOrNull(const T& src, Register dest) {
unboxNonDouble(src, dest, JSVAL_TYPE_OBJECT);
static_assert(JS::detail::ValueObjectOrNullBit ==
(uint64_t(0x8) << JSVAL_TAG_SHIFT));
ma_dins(dest, zero, Imm32(JSVAL_TAG_SHIFT + 3), Imm32(1));
}
void unboxGCThingForGCBarrier(const Address& src, Register dest) {
loadPtr(src, dest);
ma_dext(dest, dest, Imm32(0), Imm32(JSVAL_TAG_SHIFT));
}
void unboxGCThingForGCBarrier(const ValueOperand& src, Register dest) {
ma_dext(dest, src.valueReg(), Imm32(0), Imm32(JSVAL_TAG_SHIFT));
}
void unboxInt32(const ValueOperand& operand, Register dest);
void unboxInt32(Register src, Register dest);
void unboxInt32(const Address& src, Register dest);
void unboxInt32(const BaseIndex& src, Register dest);
void unboxBoolean(const ValueOperand& operand, Register dest);
void unboxBoolean(Register src, Register dest);
void unboxBoolean(const Address& src, Register dest);
void unboxBoolean(const BaseIndex& src, Register dest);
void unboxDouble(const ValueOperand& operand, FloatRegister dest);
void unboxDouble(Register src, Register dest);
void unboxDouble(const Address& src, FloatRegister dest);
void unboxDouble(const BaseIndex& src, FloatRegister dest);
void unboxString(const ValueOperand& operand, Register dest);
void unboxString(Register src, Register dest);
void unboxString(const Address& src, Register dest);
void unboxSymbol(const ValueOperand& src, Register dest);
void unboxSymbol(Register src, Register dest);
void unboxSymbol(const Address& src, Register dest);
void unboxBigInt(const ValueOperand& operand, Register dest);
void unboxBigInt(Register src, Register dest);
void unboxBigInt(const Address& src, Register dest);
void unboxObject(const ValueOperand& src, Register dest);
void unboxObject(Register src, Register dest);
void unboxObject(const Address& src, Register dest);
void unboxObject(const BaseIndex& src, Register dest) {
unboxNonDouble(src, dest, JSVAL_TYPE_OBJECT);
}
void unboxValue(const ValueOperand& src, AnyRegister dest, JSValueType type);
void notBoolean(const ValueOperand& val) {
as_xori(val.valueReg(), val.valueReg(), 1);
}
// boxing code
void boxDouble(FloatRegister src, const ValueOperand& dest, FloatRegister);
void boxNonDouble(JSValueType type, Register src, const ValueOperand& dest);
// Extended unboxing API. If the payload is already in a register, returns
// that register. Otherwise, provides a move to the given scratch register,
// and returns that.
[[nodiscard]] Register extractObject(const Address& address,
Register scratch);
[[nodiscard]] Register extractObject(const ValueOperand& value,
Register scratch) {
unboxObject(value, scratch);
return scratch;
}
[[nodiscard]] Register extractString(const ValueOperand& value,
Register scratch) {
unboxString(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;
}
[[nodiscard]] Register extractTag(const Address& address, Register scratch);
[[nodiscard]] Register extractTag(const BaseIndex& address, Register scratch);
[[nodiscard]] Register extractTag(const ValueOperand& value,
Register scratch) {
MOZ_ASSERT(scratch != ScratchRegister);
splitTag(value, scratch);
return scratch;
}
void boolValueToDouble(const ValueOperand& operand, FloatRegister dest);
void int32ValueToDouble(const ValueOperand& operand, FloatRegister dest);
void loadInt32OrDouble(const Address& src, FloatRegister dest);
void loadInt32OrDouble(const BaseIndex& addr, FloatRegister dest);
void loadConstantDouble(double dp, FloatRegister dest);
void boolValueToFloat32(const ValueOperand& operand, FloatRegister dest);
void int32ValueToFloat32(const ValueOperand& operand, FloatRegister dest);
void loadConstantFloat32(float f, FloatRegister dest);
void testNullSet(Condition cond, const ValueOperand& value, Register dest);
void testObjectSet(Condition cond, const ValueOperand& value, Register dest);
void testUndefinedSet(Condition cond, const ValueOperand& value,
Register dest);
// higher level tag testing code
Address ToPayload(Address value) { return value; }
template <typename T>
void loadUnboxedValue(const T& address, MIRType type, AnyRegister dest) {
if (dest.isFloat()) {
loadInt32OrDouble(address, dest.fpu());
} else {
unboxNonDouble(address, dest.gpr(), ValueTypeFromMIRType(type));
}
}
void storeUnboxedPayload(ValueOperand value, BaseIndex address, size_t nbytes,
JSValueType type) {
switch (nbytes) {
case 8:
if (type == JSVAL_TYPE_OBJECT) {
unboxObjectOrNull(value, SecondScratchReg);
} else {
unboxNonDouble(value, SecondScratchReg, type);
}
computeEffectiveAddress(address, ScratchRegister);
as_sd(SecondScratchReg, ScratchRegister, 0);
return;
case 4:
store32(value.valueReg(), address);
return;
case 1:
store8(value.valueReg(), address);
return;
default:
MOZ_CRASH("Bad payload width");
}
}
void storeUnboxedPayload(ValueOperand value, Address address, size_t nbytes,
JSValueType type) {
switch (nbytes) {
case 8:
if (type == JSVAL_TYPE_OBJECT) {
unboxObjectOrNull(value, SecondScratchReg);
} else {
unboxNonDouble(value, SecondScratchReg, type);
}
storePtr(SecondScratchReg, address);
return;
case 4:
store32(value.valueReg(), address);
return;
case 1:
store8(value.valueReg(), address);
return;
default:
MOZ_CRASH("Bad payload width");
}
}
void boxValue(JSValueType type, Register src, Register dest) {
MOZ_ASSERT(src != dest);
JSValueTag tag = (JSValueTag)JSVAL_TYPE_TO_TAG(type);
ma_li(dest, Imm32(tag));
ma_dsll(dest, dest, Imm32(JSVAL_TAG_SHIFT));
ma_dins(dest, src, Imm32(0), Imm32(JSVAL_TAG_SHIFT));
}
void storeValue(ValueOperand val, Operand dst);
void storeValue(ValueOperand val, const BaseIndex& dest);
void storeValue(JSValueType type, Register reg, BaseIndex dest);
void storeValue(ValueOperand val, const Address& dest);
void storeValue(JSValueType type, Register reg, Address dest);
void storeValue(const Value& val, Address dest);
void storeValue(const Value& val, BaseIndex dest);
void storeValue(const Address& src, const Address& dest, Register temp) {
loadPtr(src, temp);
storePtr(temp, dest);
}
void loadValue(Address src, ValueOperand val);
void loadValue(Operand dest, ValueOperand val) {
loadValue(dest.toAddress(), val);
}
void loadValue(const BaseIndex& addr, ValueOperand val);
void loadUnalignedValue(const Address& src, ValueOperand dest) {
loadValue(src, dest);
}
void tagValue(JSValueType type, Register payload, ValueOperand dest);
void pushValue(ValueOperand val);
void popValue(ValueOperand val);
void pushValue(const Value& val) {
if (val.isGCThing()) {
writeDataRelocation(val);
movWithPatch(ImmWord(val.asRawBits()), ScratchRegister);
push(ScratchRegister);
} else {
push(ImmWord(val.asRawBits()));
}
}
void pushValue(JSValueType type, Register reg) {
boxValue(type, reg, ScratchRegister);
push(ScratchRegister);
}
void pushValue(const Address& addr);
void handleFailureWithHandlerTail(Label* profilerExitTail);
/////////////////////////////////////////////////////////////////
// Common interface.
/////////////////////////////////////////////////////////////////
public:
// The following functions are exposed for use in platform-shared code.
inline void incrementInt32Value(const Address& addr);
void move32(Imm32 imm, Register dest);
void move32(Register src, Register dest);
void movePtr(Register src, Register dest);
void movePtr(ImmWord imm, Register dest);
void movePtr(ImmPtr imm, Register dest);
void movePtr(wasm::SymbolicAddress imm, Register dest);
void movePtr(ImmGCPtr imm, Register dest);
void load8SignExtend(const Address& address, Register dest);
void load8SignExtend(const BaseIndex& src, Register dest);
void load8ZeroExtend(const Address& address, Register dest);
void load8ZeroExtend(const BaseIndex& src, Register dest);
void load16SignExtend(const Address& address, Register dest);
void load16SignExtend(const BaseIndex& src, Register dest);
template <typename S>
void load16UnalignedSignExtend(const S& src, Register dest) {
ma_load_unaligned(dest, src, SizeHalfWord, SignExtend);
}
void load16ZeroExtend(const Address& address, Register dest);
void load16ZeroExtend(const BaseIndex& src, Register dest);
template <typename S>
void load16UnalignedZeroExtend(const S& src, Register dest) {
ma_load_unaligned(dest, src, SizeHalfWord, ZeroExtend);
}
void load32(const Address& address, Register dest);
void load32(const BaseIndex& address, Register dest);
void load32(AbsoluteAddress address, Register dest);
void load32(wasm::SymbolicAddress address, Register dest);
template <typename S>
void load32Unaligned(const S& src, Register dest) {
ma_load_unaligned(dest, src, SizeWord, SignExtend);
}
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) {
ma_load_unaligned(dest.reg, src, SizeDouble, ZeroExtend);
}
void loadPtr(const Address& address, Register dest);
void loadPtr(const BaseIndex& src, Register dest);
void loadPtr(AbsoluteAddress address, Register dest);
void loadPtr(wasm::SymbolicAddress address, Register dest);
void loadPrivate(const Address& address, Register dest);
void loadUnalignedDouble(const wasm::MemoryAccessDesc& access,
const BaseIndex& src, Register temp,
FloatRegister dest);
void loadUnalignedFloat32(const wasm::MemoryAccessDesc& access,
const BaseIndex& src, Register temp,
FloatRegister dest);
void store8(Register src, const Address& address);
void store8(Imm32 imm, const Address& address);
void store8(Register src, const BaseIndex& address);
void store8(Imm32 imm, const BaseIndex& address);
void store16(Register src, const Address& address);
void store16(Imm32 imm, const Address& address);
void store16(Register src, const BaseIndex& address);
void store16(Imm32 imm, const BaseIndex& address);
template <typename T>
void store16Unaligned(Register src, const T& dest) {
ma_store_unaligned(src, dest, SizeHalfWord);
}
void store32(Register src, AbsoluteAddress address);
void store32(Register src, const Address& address);
void store32(Register src, const BaseIndex& address);
void store32(Imm32 src, const Address& address);
void store32(Imm32 src, const BaseIndex& address);
// NOTE: This will use second scratch on MIPS64. Only ARM needs the
// implementation without second scratch.
void store32_NoSecondScratch(Imm32 src, const Address& address) {
store32(src, address);
}
template <typename T>
void store32Unaligned(Register src, const T& dest) {
ma_store_unaligned(src, dest, SizeWord);
}
void store64(Imm64 imm, Address address) {
storePtr(ImmWord(imm.value), address);
}
void store64(Imm64 imm, const BaseIndex& address) {
storePtr(ImmWord(imm.value), address);
}
void store64(Register64 src, Address address) { storePtr(src.reg, address); }
void store64(Register64 src, const BaseIndex& address) {
storePtr(src.reg, address);
}
template <typename T>
void store64Unaligned(Register64 src, const T& dest) {
ma_store_unaligned(src.reg, dest, SizeDouble);
}
template <typename T>
void storePtr(ImmWord imm, T address);
template <typename T>
void storePtr(ImmPtr imm, T address);
template <typename T>
void storePtr(ImmGCPtr imm, T address);
void storePtr(Register src, const Address& address);
void storePtr(Register src, const BaseIndex& address);
void storePtr(Register src, AbsoluteAddress dest);
void storeUnalignedFloat32(const wasm::MemoryAccessDesc& access,
FloatRegister src, Register temp,
const BaseIndex& dest);
void storeUnalignedDouble(const wasm::MemoryAccessDesc& access,
FloatRegister src, Register temp,
const BaseIndex& dest);
void moveDouble(FloatRegister src, FloatRegister dest) { as_movd(dest, src); }
void zeroDouble(FloatRegister reg) { moveToDouble(zero, reg); }
void convertUInt64ToDouble(Register src, FloatRegister dest);
void breakpoint();
void checkStackAlignment();
static void calculateAlignedStackPointer(void** stackPointer);
// If source is a double, load it into dest. If source is int32,
// convert it to double. Else, branch to failure.
void ensureDouble(const ValueOperand& source, FloatRegister dest,
Label* failure);
void cmpPtrSet(Assembler::Condition cond, Address lhs, ImmPtr rhs,
Register dest);
void cmpPtrSet(Assembler::Condition cond, Register lhs, Address rhs,
Register dest);
void cmpPtrSet(Assembler::Condition cond, Address lhs, Register rhs,
Register dest);
void cmp32Set(Assembler::Condition cond, Register lhs, Address rhs,
Register dest);
void cmp64Set(Assembler::Condition cond, Register lhs, Imm32 rhs,
Register dest) {
ma_cmp_set(dest, lhs, rhs, cond);
}
protected:
bool buildOOLFakeExitFrame(void* fakeReturnAddr);
void wasmLoadI64Impl(const wasm::MemoryAccessDesc& access,
Register memoryBase, Register ptr, Register ptrScratch,
Register64 output, Register tmp);
void wasmStoreI64Impl(const wasm::MemoryAccessDesc& access, Register64 value,
Register memoryBase, Register ptr, Register ptrScratch,
Register tmp);
public:
void lea(Operand addr, Register dest) {
ma_daddu(dest, addr.baseReg(), Imm32(addr.disp()));
}
void abiret() {
as_jr(ra);
as_nop();
}
void moveFloat32(FloatRegister src, FloatRegister dest) {
as_movs(dest, src);
}
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);
}
// Instrumentation for entering and leaving the profiler.
void profilerEnterFrame(Register framePtr, Register scratch);
void profilerExitFrame();
};
typedef MacroAssemblerMIPS64Compat MacroAssemblerSpecific;
} // namespace jit
} // namespace js
#endif /* jit_mips64_MacroAssembler_mips64_h */
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