// Copyright 2012 the V8 project authors. All rights reserved.
// Use of this source code is governed by a BSD-style license that can be
// found in the LICENSE file.
#include "src/compiler/simplified-operator.h"
#include "src/base/lazy-instance.h"
#include "src/compiler/opcodes.h"
#include "src/compiler/operator.h"
#include "src/compiler/types.h"
namespace v8 {
namespace internal {
namespace compiler {
size_t hash_value(BaseTaggedness base_taggedness) {
return static_cast<uint8_t>(base_taggedness);
}
std::ostream& operator<<(std::ostream& os, BaseTaggedness base_taggedness) {
switch (base_taggedness) {
case kUntaggedBase:
return os << "untagged base";
case kTaggedBase:
return os << "tagged base";
}
UNREACHABLE();
return os;
}
MachineType BufferAccess::machine_type() const {
switch (external_array_type_) {
case kExternalUint8Array:
case kExternalUint8ClampedArray:
return MachineType::Uint8();
case kExternalInt8Array:
return MachineType::Int8();
case kExternalUint16Array:
return MachineType::Uint16();
case kExternalInt16Array:
return MachineType::Int16();
case kExternalUint32Array:
return MachineType::Uint32();
case kExternalInt32Array:
return MachineType::Int32();
case kExternalFloat32Array:
return MachineType::Float32();
case kExternalFloat64Array:
return MachineType::Float64();
}
UNREACHABLE();
return MachineType::None();
}
bool operator==(BufferAccess lhs, BufferAccess rhs) {
return lhs.external_array_type() == rhs.external_array_type();
}
bool operator!=(BufferAccess lhs, BufferAccess rhs) { return !(lhs == rhs); }
size_t hash_value(BufferAccess access) {
return base::hash<ExternalArrayType>()(access.external_array_type());
}
std::ostream& operator<<(std::ostream& os, BufferAccess access) {
switch (access.external_array_type()) {
#define TYPED_ARRAY_CASE(Type, type, TYPE, ctype, size) \
case kExternal##Type##Array: \
return os << #Type;
TYPED_ARRAYS(TYPED_ARRAY_CASE)
#undef TYPED_ARRAY_CASE
}
UNREACHABLE();
return os;
}
BufferAccess const BufferAccessOf(const Operator* op) {
DCHECK(op->opcode() == IrOpcode::kLoadBuffer ||
op->opcode() == IrOpcode::kStoreBuffer);
return OpParameter<BufferAccess>(op);
}
bool operator==(FieldAccess const& lhs, FieldAccess const& rhs) {
// On purpose we don't include the write barrier kind here, as this method is
// really only relevant for eliminating loads and they don't care about the
// write barrier mode.
return lhs.base_is_tagged == rhs.base_is_tagged && lhs.offset == rhs.offset &&
lhs.map.address() == rhs.map.address() &&
lhs.machine_type == rhs.machine_type;
}
bool operator!=(FieldAccess const& lhs, FieldAccess const& rhs) {
return !(lhs == rhs);
}
size_t hash_value(FieldAccess const& access) {
// On purpose we don't include the write barrier kind here, as this method is
// really only relevant for eliminating loads and they don't care about the
// write barrier mode.
return base::hash_combine(access.base_is_tagged, access.offset,
access.machine_type);
}
std::ostream& operator<<(std::ostream& os, FieldAccess const& access) {
os << "[" << access.base_is_tagged << ", " << access.offset << ", ";
#ifdef OBJECT_PRINT
Handle<Name> name;
if (access.name.ToHandle(&name)) {
name->Print(os);
os << ", ";
}
Handle<Map> map;
if (access.map.ToHandle(&map)) {
os << Brief(*map) << ", ";
}
#endif
access.type->PrintTo(os);
os << ", " << access.machine_type << ", " << access.write_barrier_kind << "]";
return os;
}
template <>
void Operator1<FieldAccess>::PrintParameter(std::ostream& os,
PrintVerbosity verbose) const {
if (verbose == PrintVerbosity::kVerbose) {
os << parameter();
} else {
os << "[+" << parameter().offset << "]";
}
}
bool operator==(ElementAccess const& lhs, ElementAccess const& rhs) {
// On purpose we don't include the write barrier kind here, as this method is
// really only relevant for eliminating loads and they don't care about the
// write barrier mode.
return lhs.base_is_tagged == rhs.base_is_tagged &&
lhs.header_size == rhs.header_size &&
lhs.machine_type == rhs.machine_type;
}
bool operator!=(ElementAccess const& lhs, ElementAccess const& rhs) {
return !(lhs == rhs);
}
size_t hash_value(ElementAccess const& access) {
// On purpose we don't include the write barrier kind here, as this method is
// really only relevant for eliminating loads and they don't care about the
// write barrier mode.
return base::hash_combine(access.base_is_tagged, access.header_size,
access.machine_type);
}
std::ostream& operator<<(std::ostream& os, ElementAccess const& access) {
os << access.base_is_tagged << ", " << access.header_size << ", ";
access.type->PrintTo(os);
os << ", " << access.machine_type << ", " << access.write_barrier_kind;
return os;
}
const FieldAccess& FieldAccessOf(const Operator* op) {
DCHECK_NOT_NULL(op);
DCHECK(op->opcode() == IrOpcode::kLoadField ||
op->opcode() == IrOpcode::kStoreField);
return OpParameter<FieldAccess>(op);
}
const ElementAccess& ElementAccessOf(const Operator* op) {
DCHECK_NOT_NULL(op);
DCHECK(op->opcode() == IrOpcode::kLoadElement ||
op->opcode() == IrOpcode::kStoreElement);
return OpParameter<ElementAccess>(op);
}
ExternalArrayType ExternalArrayTypeOf(const Operator* op) {
DCHECK(op->opcode() == IrOpcode::kLoadTypedElement ||
op->opcode() == IrOpcode::kStoreTypedElement);
return OpParameter<ExternalArrayType>(op);
}
size_t hash_value(CheckFloat64HoleMode mode) {
return static_cast<size_t>(mode);
}
std::ostream& operator<<(std::ostream& os, CheckFloat64HoleMode mode) {
switch (mode) {
case CheckFloat64HoleMode::kAllowReturnHole:
return os << "allow-return-hole";
case CheckFloat64HoleMode::kNeverReturnHole:
return os << "never-return-hole";
}
UNREACHABLE();
return os;
}
CheckFloat64HoleMode CheckFloat64HoleModeOf(const Operator* op) {
DCHECK_EQ(IrOpcode::kCheckFloat64Hole, op->opcode());
return OpParameter<CheckFloat64HoleMode>(op);
}
CheckForMinusZeroMode CheckMinusZeroModeOf(const Operator* op) {
DCHECK(op->opcode() == IrOpcode::kCheckedInt32Mul ||
op->opcode() == IrOpcode::kCheckedFloat64ToInt32 ||
op->opcode() == IrOpcode::kCheckedTaggedToInt32);
return OpParameter<CheckForMinusZeroMode>(op);
}
size_t hash_value(CheckForMinusZeroMode mode) {
return static_cast<size_t>(mode);
}
std::ostream& operator<<(std::ostream& os, CheckForMinusZeroMode mode) {
switch (mode) {
case CheckForMinusZeroMode::kCheckForMinusZero:
return os << "check-for-minus-zero";
case CheckForMinusZeroMode::kDontCheckForMinusZero:
return os << "dont-check-for-minus-zero";
}
UNREACHABLE();
return os;
}
std::ostream& operator<<(std::ostream& os, CheckMapsFlags flags) {
bool empty = true;
if (flags & CheckMapsFlag::kTryMigrateInstance) {
os << "TryMigrateInstance";
empty = false;
}
if (empty) os << "None";
return os;
}
bool operator==(CheckMapsParameters const& lhs,
CheckMapsParameters const& rhs) {
return lhs.flags() == rhs.flags() && lhs.maps() == rhs.maps();
}
bool operator!=(CheckMapsParameters const& lhs,
CheckMapsParameters const& rhs) {
return !(lhs == rhs);
}
size_t hash_value(CheckMapsParameters const& p) {
return base::hash_combine(p.flags(), p.maps());
}
std::ostream& operator<<(std::ostream& os, CheckMapsParameters const& p) {
ZoneHandleSet<Map> const& maps = p.maps();
os << p.flags();
for (size_t i = 0; i < maps.size(); ++i) {
os << ", " << Brief(*maps[i]);
}
return os;
}
CheckMapsParameters const& CheckMapsParametersOf(Operator const* op) {
DCHECK_EQ(IrOpcode::kCheckMaps, op->opcode());
return OpParameter<CheckMapsParameters>(op);
}
size_t hash_value(CheckTaggedInputMode mode) {
return static_cast<size_t>(mode);
}
std::ostream& operator<<(std::ostream& os, CheckTaggedInputMode mode) {
switch (mode) {
case CheckTaggedInputMode::kNumber:
return os << "Number";
case CheckTaggedInputMode::kNumberOrOddball:
return os << "NumberOrOddball";
}
UNREACHABLE();
return os;
}
CheckTaggedInputMode CheckTaggedInputModeOf(const Operator* op) {
DCHECK_EQ(IrOpcode::kCheckedTaggedToFloat64, op->opcode());
return OpParameter<CheckTaggedInputMode>(op);
}
std::ostream& operator<<(std::ostream& os, GrowFastElementsFlags flags) {
bool empty = true;
if (flags & GrowFastElementsFlag::kArrayObject) {
os << "ArrayObject";
empty = false;
}
if (flags & GrowFastElementsFlag::kDoubleElements) {
if (!empty) os << "|";
os << "DoubleElements";
empty = false;
}
if (flags & GrowFastElementsFlag::kHoleyElements) {
if (!empty) os << "|";
os << "HoleyElements";
empty = false;
}
if (empty) os << "None";
return os;
}
GrowFastElementsFlags GrowFastElementsFlagsOf(const Operator* op) {
DCHECK_EQ(IrOpcode::kMaybeGrowFastElements, op->opcode());
return OpParameter<GrowFastElementsFlags>(op);
}
bool operator==(ElementsTransition const& lhs, ElementsTransition const& rhs) {
return lhs.mode() == rhs.mode() &&
lhs.source().address() == rhs.source().address() &&
lhs.target().address() == rhs.target().address();
}
bool operator!=(ElementsTransition const& lhs, ElementsTransition const& rhs) {
return !(lhs == rhs);
}
size_t hash_value(ElementsTransition transition) {
return base::hash_combine(static_cast<uint8_t>(transition.mode()),
transition.source().address(),
transition.target().address());
}
std::ostream& operator<<(std::ostream& os, ElementsTransition transition) {
switch (transition.mode()) {
case ElementsTransition::kFastTransition:
return os << "fast-transition from " << Brief(*transition.source())
<< " to " << Brief(*transition.target());
case ElementsTransition::kSlowTransition:
return os << "slow-transition from " << Brief(*transition.source())
<< " to " << Brief(*transition.target());
}
UNREACHABLE();
return os;
}
ElementsTransition const& ElementsTransitionOf(const Operator* op) {
DCHECK_EQ(IrOpcode::kTransitionElementsKind, op->opcode());
return OpParameter<ElementsTransition>(op);
}
std::ostream& operator<<(std::ostream& os, NumberOperationHint hint) {
switch (hint) {
case NumberOperationHint::kSignedSmall:
return os << "SignedSmall";
case NumberOperationHint::kSigned32:
return os << "Signed32";
case NumberOperationHint::kNumber:
return os << "Number";
case NumberOperationHint::kNumberOrOddball:
return os << "NumberOrOddball";
}
UNREACHABLE();
return os;
}
size_t hash_value(NumberOperationHint hint) {
return static_cast<uint8_t>(hint);
}
NumberOperationHint NumberOperationHintOf(const Operator* op) {
DCHECK(op->opcode() == IrOpcode::kSpeculativeNumberAdd ||
op->opcode() == IrOpcode::kSpeculativeNumberSubtract ||
op->opcode() == IrOpcode::kSpeculativeNumberMultiply ||
op->opcode() == IrOpcode::kSpeculativeNumberDivide ||
op->opcode() == IrOpcode::kSpeculativeNumberModulus ||
op->opcode() == IrOpcode::kSpeculativeNumberShiftLeft ||
op->opcode() == IrOpcode::kSpeculativeNumberShiftRight ||
op->opcode() == IrOpcode::kSpeculativeNumberShiftRightLogical ||
op->opcode() == IrOpcode::kSpeculativeNumberBitwiseAnd ||
op->opcode() == IrOpcode::kSpeculativeNumberBitwiseOr ||
op->opcode() == IrOpcode::kSpeculativeNumberBitwiseXor ||
op->opcode() == IrOpcode::kSpeculativeNumberEqual ||
op->opcode() == IrOpcode::kSpeculativeNumberLessThan ||
op->opcode() == IrOpcode::kSpeculativeNumberLessThanOrEqual);
return OpParameter<NumberOperationHint>(op);
}
int ParameterCountOf(const Operator* op) {
DCHECK(op->opcode() == IrOpcode::kNewUnmappedArgumentsElements ||
op->opcode() == IrOpcode::kNewRestParameterElements);
return OpParameter<int>(op);
}
PretenureFlag PretenureFlagOf(const Operator* op) {
DCHECK_EQ(IrOpcode::kAllocate, op->opcode());
return OpParameter<PretenureFlag>(op);
}
UnicodeEncoding UnicodeEncodingOf(const Operator* op) {
DCHECK(op->opcode() == IrOpcode::kStringFromCodePoint);
return OpParameter<UnicodeEncoding>(op);
}
#define PURE_OP_LIST(V) \
V(BooleanNot, Operator::kNoProperties, 1, 0) \
V(NumberEqual, Operator::kCommutative, 2, 0) \
V(NumberLessThan, Operator::kNoProperties, 2, 0) \
V(NumberLessThanOrEqual, Operator::kNoProperties, 2, 0) \
V(NumberAdd, Operator::kCommutative, 2, 0) \
V(NumberSubtract, Operator::kNoProperties, 2, 0) \
V(NumberMultiply, Operator::kCommutative, 2, 0) \
V(NumberDivide, Operator::kNoProperties, 2, 0) \
V(NumberModulus, Operator::kNoProperties, 2, 0) \
V(NumberBitwiseOr, Operator::kCommutative, 2, 0) \
V(NumberBitwiseXor, Operator::kCommutative, 2, 0) \
V(NumberBitwiseAnd, Operator::kCommutative, 2, 0) \
V(NumberShiftLeft, Operator::kNoProperties, 2, 0) \
V(NumberShiftRight, Operator::kNoProperties, 2, 0) \
V(NumberShiftRightLogical, Operator::kNoProperties, 2, 0) \
V(NumberImul, Operator::kCommutative, 2, 0) \
V(NumberAbs, Operator::kNoProperties, 1, 0) \
V(NumberClz32, Operator::kNoProperties, 1, 0) \
V(NumberCeil, Operator::kNoProperties, 1, 0) \
V(NumberFloor, Operator::kNoProperties, 1, 0) \
V(NumberFround, Operator::kNoProperties, 1, 0) \
V(NumberAcos, Operator::kNoProperties, 1, 0) \
V(NumberAcosh, Operator::kNoProperties, 1, 0) \
V(NumberAsin, Operator::kNoProperties, 1, 0) \
V(NumberAsinh, Operator::kNoProperties, 1, 0) \
V(NumberAtan, Operator::kNoProperties, 1, 0) \
V(NumberAtan2, Operator::kNoProperties, 2, 0) \
V(NumberAtanh, Operator::kNoProperties, 1, 0) \
V(NumberCbrt, Operator::kNoProperties, 1, 0) \
V(NumberCos, Operator::kNoProperties, 1, 0) \
V(NumberCosh, Operator::kNoProperties, 1, 0) \
V(NumberExp, Operator::kNoProperties, 1, 0) \
V(NumberExpm1, Operator::kNoProperties, 1, 0) \
V(NumberLog, Operator::kNoProperties, 1, 0) \
V(NumberLog1p, Operator::kNoProperties, 1, 0) \
V(NumberLog10, Operator::kNoProperties, 1, 0) \
V(NumberLog2, Operator::kNoProperties, 1, 0) \
V(NumberMax, Operator::kNoProperties, 2, 0) \
V(NumberMin, Operator::kNoProperties, 2, 0) \
V(NumberPow, Operator::kNoProperties, 2, 0) \
V(NumberRound, Operator::kNoProperties, 1, 0) \
V(NumberSign, Operator::kNoProperties, 1, 0) \
V(NumberSin, Operator::kNoProperties, 1, 0) \
V(NumberSinh, Operator::kNoProperties, 1, 0) \
V(NumberSqrt, Operator::kNoProperties, 1, 0) \
V(NumberTan, Operator::kNoProperties, 1, 0) \
V(NumberTanh, Operator::kNoProperties, 1, 0) \
V(NumberTrunc, Operator::kNoProperties, 1, 0) \
V(NumberToBoolean, Operator::kNoProperties, 1, 0) \
V(NumberToInt32, Operator::kNoProperties, 1, 0) \
V(NumberToUint32, Operator::kNoProperties, 1, 0) \
V(NumberToUint8Clamped, Operator::kNoProperties, 1, 0) \
V(NumberSilenceNaN, Operator::kNoProperties, 1, 0) \
V(StringCharAt, Operator::kNoProperties, 2, 1) \
V(StringCharCodeAt, Operator::kNoProperties, 2, 1) \
V(StringFromCharCode, Operator::kNoProperties, 1, 0) \
V(StringIndexOf, Operator::kNoProperties, 3, 0) \
V(PlainPrimitiveToNumber, Operator::kNoProperties, 1, 0) \
V(PlainPrimitiveToWord32, Operator::kNoProperties, 1, 0) \
V(PlainPrimitiveToFloat64, Operator::kNoProperties, 1, 0) \
V(ChangeTaggedSignedToInt32, Operator::kNoProperties, 1, 0) \
V(ChangeTaggedToInt32, Operator::kNoProperties, 1, 0) \
V(ChangeTaggedToUint32, Operator::kNoProperties, 1, 0) \
V(ChangeTaggedToFloat64, Operator::kNoProperties, 1, 0) \
V(ChangeTaggedToTaggedSigned, Operator::kNoProperties, 1, 0) \
V(ChangeFloat64ToTagged, Operator::kNoProperties, 1, 0) \
V(ChangeFloat64ToTaggedPointer, Operator::kNoProperties, 1, 0) \
V(ChangeInt31ToTaggedSigned, Operator::kNoProperties, 1, 0) \
V(ChangeInt32ToTagged, Operator::kNoProperties, 1, 0) \
V(ChangeUint32ToTagged, Operator::kNoProperties, 1, 0) \
V(ChangeTaggedToBit, Operator::kNoProperties, 1, 0) \
V(ChangeBitToTagged, Operator::kNoProperties, 1, 0) \
V(TruncateTaggedToBit, Operator::kNoProperties, 1, 0) \
V(TruncateTaggedToWord32, Operator::kNoProperties, 1, 0) \
V(TruncateTaggedToFloat64, Operator::kNoProperties, 1, 0) \
V(ObjectIsDetectableCallable, Operator::kNoProperties, 1, 0) \
V(ObjectIsNonCallable, Operator::kNoProperties, 1, 0) \
V(ObjectIsNumber, Operator::kNoProperties, 1, 0) \
V(ObjectIsReceiver, Operator::kNoProperties, 1, 0) \
V(ObjectIsSmi, Operator::kNoProperties, 1, 0) \
V(ObjectIsString, Operator::kNoProperties, 1, 0) \
V(ObjectIsUndetectable, Operator::kNoProperties, 1, 0) \
V(ConvertTaggedHoleToUndefined, Operator::kNoProperties, 1, 0) \
V(ReferenceEqual, Operator::kCommutative, 2, 0) \
V(StringEqual, Operator::kCommutative, 2, 0) \
V(StringLessThan, Operator::kNoProperties, 2, 0) \
V(StringLessThanOrEqual, Operator::kNoProperties, 2, 0)
#define SPECULATIVE_NUMBER_BINOP_LIST(V) \
SIMPLIFIED_SPECULATIVE_NUMBER_BINOP_LIST(V) \
V(SpeculativeNumberEqual) \
V(SpeculativeNumberLessThan) \
V(SpeculativeNumberLessThanOrEqual)
#define CHECKED_OP_LIST(V) \
V(CheckBounds, 2, 1) \
V(CheckHeapObject, 1, 1) \
V(CheckIf, 1, 0) \
V(CheckInternalizedString, 1, 1) \
V(CheckNumber, 1, 1) \
V(CheckReceiver, 1, 1) \
V(CheckSmi, 1, 1) \
V(CheckString, 1, 1) \
V(CheckTaggedHole, 1, 1) \
V(CheckedInt32Add, 2, 1) \
V(CheckedInt32Sub, 2, 1) \
V(CheckedInt32Div, 2, 1) \
V(CheckedInt32Mod, 2, 1) \
V(CheckedUint32Div, 2, 1) \
V(CheckedUint32Mod, 2, 1) \
V(CheckedUint32ToInt32, 1, 1) \
V(CheckedUint32ToTaggedSigned, 1, 1) \
V(CheckedInt32ToTaggedSigned, 1, 1) \
V(CheckedTaggedSignedToInt32, 1, 1) \
V(CheckedTaggedToTaggedSigned, 1, 1) \
V(CheckedTaggedToTaggedPointer, 1, 1) \
V(CheckedTruncateTaggedToWord32, 1, 1)
struct SimplifiedOperatorGlobalCache final {
#define PURE(Name, properties, value_input_count, control_input_count) \
struct Name##Operator final : public Operator { \
Name##Operator() \
: Operator(IrOpcode::k##Name, Operator::kPure | properties, #Name, \
value_input_count, 0, control_input_count, 1, 0, 0) {} \
}; \
Name##Operator k##Name;
PURE_OP_LIST(PURE)
#undef PURE
#define CHECKED(Name, value_input_count, value_output_count) \
struct Name##Operator final : public Operator { \
Name##Operator() \
: Operator(IrOpcode::k##Name, \
Operator::kFoldable | Operator::kNoThrow, #Name, \
value_input_count, 1, 1, value_output_count, 1, 0) {} \
}; \
Name##Operator k##Name;
CHECKED_OP_LIST(CHECKED)
#undef CHECKED
template <UnicodeEncoding kEncoding>
struct StringFromCodePointOperator final : public Operator1<UnicodeEncoding> {
StringFromCodePointOperator()
: Operator1<UnicodeEncoding>(IrOpcode::kStringFromCodePoint,
Operator::kPure, "StringFromCodePoint", 1,
0, 0, 1, 0, 0, kEncoding) {}
};
StringFromCodePointOperator<UnicodeEncoding::UTF16>
kStringFromCodePointOperatorUTF16;
StringFromCodePointOperator<UnicodeEncoding::UTF32>
kStringFromCodePointOperatorUTF32;
struct ArrayBufferWasNeuteredOperator final : public Operator {
ArrayBufferWasNeuteredOperator()
: Operator(IrOpcode::kArrayBufferWasNeutered, Operator::kEliminatable,
"ArrayBufferWasNeutered", 1, 1, 1, 1, 1, 0) {}
};
ArrayBufferWasNeuteredOperator kArrayBufferWasNeutered;
template <CheckForMinusZeroMode kMode>
struct CheckedInt32MulOperator final
: public Operator1<CheckForMinusZeroMode> {
CheckedInt32MulOperator()
: Operator1<CheckForMinusZeroMode>(
IrOpcode::kCheckedInt32Mul,
Operator::kFoldable | Operator::kNoThrow, "CheckedInt32Mul", 2, 1,
1, 1, 1, 0, kMode) {}
};
CheckedInt32MulOperator<CheckForMinusZeroMode::kCheckForMinusZero>
kCheckedInt32MulCheckForMinusZeroOperator;
CheckedInt32MulOperator<CheckForMinusZeroMode::kDontCheckForMinusZero>
kCheckedInt32MulDontCheckForMinusZeroOperator;
template <CheckForMinusZeroMode kMode>
struct CheckedFloat64ToInt32Operator final
: public Operator1<CheckForMinusZeroMode> {
CheckedFloat64ToInt32Operator()
: Operator1<CheckForMinusZeroMode>(
IrOpcode::kCheckedFloat64ToInt32,
Operator::kFoldable | Operator::kNoThrow, "CheckedFloat64ToInt32",
1, 1, 1, 1, 1, 0, kMode) {}
};
CheckedFloat64ToInt32Operator<CheckForMinusZeroMode::kCheckForMinusZero>
kCheckedFloat64ToInt32CheckForMinusZeroOperator;
CheckedFloat64ToInt32Operator<CheckForMinusZeroMode::kDontCheckForMinusZero>
kCheckedFloat64ToInt32DontCheckForMinusZeroOperator;
template <CheckForMinusZeroMode kMode>
struct CheckedTaggedToInt32Operator final
: public Operator1<CheckForMinusZeroMode> {
CheckedTaggedToInt32Operator()
: Operator1<CheckForMinusZeroMode>(
IrOpcode::kCheckedTaggedToInt32,
Operator::kFoldable | Operator::kNoThrow, "CheckedTaggedToInt32",
1, 1, 1, 1, 1, 0, kMode) {}
};
CheckedTaggedToInt32Operator<CheckForMinusZeroMode::kCheckForMinusZero>
kCheckedTaggedToInt32CheckForMinusZeroOperator;
CheckedTaggedToInt32Operator<CheckForMinusZeroMode::kDontCheckForMinusZero>
kCheckedTaggedToInt32DontCheckForMinusZeroOperator;
template <CheckTaggedInputMode kMode>
struct CheckedTaggedToFloat64Operator final
: public Operator1<CheckTaggedInputMode> {
CheckedTaggedToFloat64Operator()
: Operator1<CheckTaggedInputMode>(
IrOpcode::kCheckedTaggedToFloat64,
Operator::kFoldable | Operator::kNoThrow,
"CheckedTaggedToFloat64", 1, 1, 1, 1, 1, 0, kMode) {}
};
CheckedTaggedToFloat64Operator<CheckTaggedInputMode::kNumber>
kCheckedTaggedToFloat64NumberOperator;
CheckedTaggedToFloat64Operator<CheckTaggedInputMode::kNumberOrOddball>
kCheckedTaggedToFloat64NumberOrOddballOperator;
template <CheckFloat64HoleMode kMode>
struct CheckFloat64HoleNaNOperator final
: public Operator1<CheckFloat64HoleMode> {
CheckFloat64HoleNaNOperator()
: Operator1<CheckFloat64HoleMode>(
IrOpcode::kCheckFloat64Hole,
Operator::kFoldable | Operator::kNoThrow, "CheckFloat64Hole", 1,
1, 1, 1, 1, 0, kMode) {}
};
CheckFloat64HoleNaNOperator<CheckFloat64HoleMode::kAllowReturnHole>
kCheckFloat64HoleAllowReturnHoleOperator;
CheckFloat64HoleNaNOperator<CheckFloat64HoleMode::kNeverReturnHole>
kCheckFloat64HoleNeverReturnHoleOperator;
template <PretenureFlag kPretenure>
struct AllocateOperator final : public Operator1<PretenureFlag> {
AllocateOperator()
: Operator1<PretenureFlag>(
IrOpcode::kAllocate,
Operator::kNoDeopt | Operator::kNoThrow | Operator::kNoWrite,
"Allocate", 1, 1, 1, 1, 1, 0, kPretenure) {}
};
AllocateOperator<NOT_TENURED> kAllocateNotTenuredOperator;
AllocateOperator<TENURED> kAllocateTenuredOperator;
struct EnsureWritableFastElementsOperator final : public Operator {
EnsureWritableFastElementsOperator()
: Operator( // --
IrOpcode::kEnsureWritableFastElements, // opcode
Operator::kNoDeopt | Operator::kNoThrow, // flags
"EnsureWritableFastElements", // name
2, 1, 1, 1, 1, 0) {} // counts
};
EnsureWritableFastElementsOperator kEnsureWritableFastElements;
#define SPECULATIVE_NUMBER_BINOP(Name) \
template <NumberOperationHint kHint> \
struct Name##Operator final : public Operator1<NumberOperationHint> { \
Name##Operator() \
: Operator1<NumberOperationHint>( \
IrOpcode::k##Name, Operator::kFoldable | Operator::kNoThrow, \
#Name, 2, 1, 1, 1, 1, 0, kHint) {} \
}; \
Name##Operator<NumberOperationHint::kSignedSmall> \
k##Name##SignedSmallOperator; \
Name##Operator<NumberOperationHint::kSigned32> k##Name##Signed32Operator; \
Name##Operator<NumberOperationHint::kNumber> k##Name##NumberOperator; \
Name##Operator<NumberOperationHint::kNumberOrOddball> \
k##Name##NumberOrOddballOperator;
SPECULATIVE_NUMBER_BINOP_LIST(SPECULATIVE_NUMBER_BINOP)
#undef SPECULATIVE_NUMBER_BINOP
#define BUFFER_ACCESS(Type, type, TYPE, ctype, size) \
struct LoadBuffer##Type##Operator final : public Operator1<BufferAccess> { \
LoadBuffer##Type##Operator() \
: Operator1<BufferAccess>( \
IrOpcode::kLoadBuffer, \
Operator::kNoDeopt | Operator::kNoThrow | Operator::kNoWrite, \
"LoadBuffer", 3, 1, 1, 1, 1, 0, \
BufferAccess(kExternal##Type##Array)) {} \
}; \
struct StoreBuffer##Type##Operator final : public Operator1<BufferAccess> { \
StoreBuffer##Type##Operator() \
: Operator1<BufferAccess>( \
IrOpcode::kStoreBuffer, \
Operator::kNoDeopt | Operator::kNoRead | Operator::kNoThrow, \
"StoreBuffer", 4, 1, 1, 0, 1, 0, \
BufferAccess(kExternal##Type##Array)) {} \
}; \
LoadBuffer##Type##Operator kLoadBuffer##Type; \
StoreBuffer##Type##Operator kStoreBuffer##Type;
TYPED_ARRAYS(BUFFER_ACCESS)
#undef BUFFER_ACCESS
};
static base::LazyInstance<SimplifiedOperatorGlobalCache>::type kCache =
LAZY_INSTANCE_INITIALIZER;
SimplifiedOperatorBuilder::SimplifiedOperatorBuilder(Zone* zone)
: cache_(kCache.Get()), zone_(zone) {}
#define GET_FROM_CACHE(Name, ...) \
const Operator* SimplifiedOperatorBuilder::Name() { return &cache_.k##Name; }
PURE_OP_LIST(GET_FROM_CACHE)
CHECKED_OP_LIST(GET_FROM_CACHE)
GET_FROM_CACHE(ArrayBufferWasNeutered)
#undef GET_FROM_CACHE
const Operator* SimplifiedOperatorBuilder::CheckedInt32Mul(
CheckForMinusZeroMode mode) {
switch (mode) {
case CheckForMinusZeroMode::kCheckForMinusZero:
return &cache_.kCheckedInt32MulCheckForMinusZeroOperator;
case CheckForMinusZeroMode::kDontCheckForMinusZero:
return &cache_.kCheckedInt32MulDontCheckForMinusZeroOperator;
}
UNREACHABLE();
return nullptr;
}
const Operator* SimplifiedOperatorBuilder::CheckedFloat64ToInt32(
CheckForMinusZeroMode mode) {
switch (mode) {
case CheckForMinusZeroMode::kCheckForMinusZero:
return &cache_.kCheckedFloat64ToInt32CheckForMinusZeroOperator;
case CheckForMinusZeroMode::kDontCheckForMinusZero:
return &cache_.kCheckedFloat64ToInt32DontCheckForMinusZeroOperator;
}
UNREACHABLE();
return nullptr;
}
const Operator* SimplifiedOperatorBuilder::CheckedTaggedToInt32(
CheckForMinusZeroMode mode) {
switch (mode) {
case CheckForMinusZeroMode::kCheckForMinusZero:
return &cache_.kCheckedTaggedToInt32CheckForMinusZeroOperator;
case CheckForMinusZeroMode::kDontCheckForMinusZero:
return &cache_.kCheckedTaggedToInt32DontCheckForMinusZeroOperator;
}
UNREACHABLE();
return nullptr;
}
const Operator* SimplifiedOperatorBuilder::CheckedTaggedToFloat64(
CheckTaggedInputMode mode) {
switch (mode) {
case CheckTaggedInputMode::kNumber:
return &cache_.kCheckedTaggedToFloat64NumberOperator;
case CheckTaggedInputMode::kNumberOrOddball:
return &cache_.kCheckedTaggedToFloat64NumberOrOddballOperator;
}
UNREACHABLE();
return nullptr;
}
const Operator* SimplifiedOperatorBuilder::CheckMaps(CheckMapsFlags flags,
ZoneHandleSet<Map> maps) {
CheckMapsParameters const parameters(flags, maps);
return new (zone()) Operator1<CheckMapsParameters>( // --
IrOpcode::kCheckMaps, // opcode
Operator::kNoThrow | Operator::kNoWrite, // flags
"CheckMaps", // name
1, 1, 1, 0, 1, 0, // counts
parameters); // parameter
}
const Operator* SimplifiedOperatorBuilder::CheckFloat64Hole(
CheckFloat64HoleMode mode) {
switch (mode) {
case CheckFloat64HoleMode::kAllowReturnHole:
return &cache_.kCheckFloat64HoleAllowReturnHoleOperator;
case CheckFloat64HoleMode::kNeverReturnHole:
return &cache_.kCheckFloat64HoleNeverReturnHoleOperator;
}
UNREACHABLE();
return nullptr;
}
const Operator* SimplifiedOperatorBuilder::EnsureWritableFastElements() {
return &cache_.kEnsureWritableFastElements;
}
const Operator* SimplifiedOperatorBuilder::MaybeGrowFastElements(
GrowFastElementsFlags flags) {
return new (zone()) Operator1<GrowFastElementsFlags>( // --
IrOpcode::kMaybeGrowFastElements, // opcode
Operator::kNoThrow, // flags
"MaybeGrowFastElements", // name
4, 1, 1, 1, 1, 0, // counts
flags); // parameter
}
const Operator* SimplifiedOperatorBuilder::TransitionElementsKind(
ElementsTransition transition) {
return new (zone()) Operator1<ElementsTransition>( // --
IrOpcode::kTransitionElementsKind, // opcode
Operator::kNoDeopt | Operator::kNoThrow, // flags
"TransitionElementsKind", // name
1, 1, 1, 0, 1, 0, // counts
transition); // parameter
}
const Operator* SimplifiedOperatorBuilder::NewUnmappedArgumentsElements(
int parameter_count) {
return new (zone()) Operator1<int>( // --
IrOpcode::kNewUnmappedArgumentsElements, // opcode
Operator::kEliminatable, // flags
"NewUnmappedArgumentsElements", // name
0, 1, 0, 1, 1, 0, // counts
parameter_count); // parameter
}
const Operator* SimplifiedOperatorBuilder::NewRestParameterElements(
int parameter_count) {
return new (zone()) Operator1<int>( // --
IrOpcode::kNewRestParameterElements, // opcode
Operator::kEliminatable, // flags
"NewRestParameterElements", // name
0, 1, 0, 1, 1, 0, // counts
parameter_count); // parameter
}
const Operator* SimplifiedOperatorBuilder::Allocate(PretenureFlag pretenure) {
switch (pretenure) {
case NOT_TENURED:
return &cache_.kAllocateNotTenuredOperator;
case TENURED:
return &cache_.kAllocateTenuredOperator;
}
UNREACHABLE();
return nullptr;
}
const Operator* SimplifiedOperatorBuilder::LoadBuffer(BufferAccess access) {
switch (access.external_array_type()) {
#define LOAD_BUFFER(Type, type, TYPE, ctype, size) \
case kExternal##Type##Array: \
return &cache_.kLoadBuffer##Type;
TYPED_ARRAYS(LOAD_BUFFER)
#undef LOAD_BUFFER
}
UNREACHABLE();
return nullptr;
}
const Operator* SimplifiedOperatorBuilder::StoreBuffer(BufferAccess access) {
switch (access.external_array_type()) {
#define STORE_BUFFER(Type, type, TYPE, ctype, size) \
case kExternal##Type##Array: \
return &cache_.kStoreBuffer##Type;
TYPED_ARRAYS(STORE_BUFFER)
#undef STORE_BUFFER
}
UNREACHABLE();
return nullptr;
}
const Operator* SimplifiedOperatorBuilder::StringFromCodePoint(
UnicodeEncoding encoding) {
switch (encoding) {
case UnicodeEncoding::UTF16:
return &cache_.kStringFromCodePointOperatorUTF16;
case UnicodeEncoding::UTF32:
return &cache_.kStringFromCodePointOperatorUTF32;
}
UNREACHABLE();
return nullptr;
}
#define SPECULATIVE_NUMBER_BINOP(Name) \
const Operator* SimplifiedOperatorBuilder::Name(NumberOperationHint hint) { \
switch (hint) { \
case NumberOperationHint::kSignedSmall: \
return &cache_.k##Name##SignedSmallOperator; \
case NumberOperationHint::kSigned32: \
return &cache_.k##Name##Signed32Operator; \
case NumberOperationHint::kNumber: \
return &cache_.k##Name##NumberOperator; \
case NumberOperationHint::kNumberOrOddball: \
return &cache_.k##Name##NumberOrOddballOperator; \
} \
UNREACHABLE(); \
return nullptr; \
}
SPECULATIVE_NUMBER_BINOP_LIST(SPECULATIVE_NUMBER_BINOP)
#undef SPECULATIVE_NUMBER_BINOP
#define ACCESS_OP_LIST(V) \
V(LoadField, FieldAccess, Operator::kNoWrite, 1, 1, 1) \
V(StoreField, FieldAccess, Operator::kNoRead, 2, 1, 0) \
V(LoadElement, ElementAccess, Operator::kNoWrite, 2, 1, 1) \
V(StoreElement, ElementAccess, Operator::kNoRead, 3, 1, 0) \
V(LoadTypedElement, ExternalArrayType, Operator::kNoWrite, 4, 1, 1) \
V(StoreTypedElement, ExternalArrayType, Operator::kNoRead, 5, 1, 0)
#define ACCESS(Name, Type, properties, value_input_count, control_input_count, \
output_count) \
const Operator* SimplifiedOperatorBuilder::Name(const Type& access) { \
return new (zone()) \
Operator1<Type>(IrOpcode::k##Name, \
Operator::kNoDeopt | Operator::kNoThrow | properties, \
#Name, value_input_count, 1, control_input_count, \
output_count, 1, 0, access); \
}
ACCESS_OP_LIST(ACCESS)
#undef ACCESS
} // namespace compiler
} // namespace internal
} // namespace v8