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/*
* Copyright (C) 2011-2020 Apple Inc. All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
*
* THIS SOFTWARE IS PROVIDED BY APPLE INC. ``AS IS'' AND ANY
* EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
* PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL APPLE INC. OR
* CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL,
* EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO,
* PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR
* PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY
* OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
* OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
#pragma once
#include "CatchScope.h"
#include "Error.h"
#include "ExceptionHelpers.h"
#include "Identifier.h"
#include "InternalFunction.h"
#include "JSBigInt.h"
#include "JSCJSValue.h"
#include "JSCellInlines.h"
#include "JSFunction.h"
#include "JSObject.h"
#include "JSProxy.h"
#include "JSStringInlines.h"
#include "MathCommon.h"
#include <wtf/text/StringImpl.h>
namespace JSC {
ALWAYS_INLINE int32_t JSValue::toInt32(JSGlobalObject* globalObject) const
{
if (isInt32())
return asInt32();
double d = toNumber(globalObject);
return JSC::toInt32(d);
}
inline uint32_t JSValue::toUInt32(JSGlobalObject* globalObject) const
{
// The only difference between toInt32 and toUint32 is that toUint32 reinterprets resulted int32_t value as uint32_t.
// https://tc39.es/ecma262/#sec-touint32
return toInt32(globalObject);
}
inline uint32_t JSValue::toIndex(JSGlobalObject* globalObject, const char* errorName) const
{
VM& vm = getVM(globalObject);
auto scope = DECLARE_THROW_SCOPE(vm);
double d = toNumber(globalObject);
RETURN_IF_EXCEPTION(scope, 0);
if (d <= -1) {
throwException(globalObject, scope, createRangeError(globalObject, makeString(errorName, " cannot be negative")));
return 0;
}
if (d > std::numeric_limits<unsigned>::max()) {
throwException(globalObject, scope, createRangeError(globalObject, makeString(errorName, " too large")));
return 0;
}
if (isInt32())
return asInt32();
RELEASE_AND_RETURN(scope, JSC::toInt32(d));
}
inline bool JSValue::isUInt32() const
{
return isInt32() && asInt32() >= 0;
}
inline uint32_t JSValue::asUInt32() const
{
ASSERT(isUInt32());
return asInt32();
}
inline double JSValue::asNumber() const
{
ASSERT(isNumber());
return isInt32() ? asInt32() : asDouble();
}
inline Optional<uint32_t> JSValue::tryGetAsUint32Index()
{
if (isUInt32()) {
ASSERT(isIndex(asUInt32()));
return asUInt32();
}
if (isNumber()) {
double number = asNumber();
uint32_t asUint = static_cast<uint32_t>(number);
if (static_cast<double>(asUint) == number && isIndex(asUint))
return asUint;
}
return WTF::nullopt;
}
inline Optional<int32_t> JSValue::tryGetAsInt32()
{
if (isInt32())
return asInt32();
if (isNumber()) {
double number = asNumber();
int32_t asInt = static_cast<int32_t>(number);
if (static_cast<double>(asInt) == number)
return asInt;
}
return WTF::nullopt;
}
inline JSValue jsNaN()
{
return JSValue(JSValue::EncodeAsDouble, PNaN);
}
inline JSValue::JSValue(char i)
{
*this = JSValue(static_cast<int32_t>(i));
}
inline JSValue::JSValue(unsigned char i)
{
*this = JSValue(static_cast<int32_t>(i));
}
inline JSValue::JSValue(short i)
{
*this = JSValue(static_cast<int32_t>(i));
}
inline JSValue::JSValue(unsigned short i)
{
*this = JSValue(static_cast<int32_t>(i));
}
inline JSValue::JSValue(unsigned i)
{
if (static_cast<int32_t>(i) < 0) {
*this = JSValue(EncodeAsDouble, static_cast<double>(i));
return;
}
*this = JSValue(static_cast<int32_t>(i));
}
inline JSValue::JSValue(long i)
{
if (static_cast<int32_t>(i) != i) {
*this = JSValue(EncodeAsDouble, static_cast<double>(i));
return;
}
*this = JSValue(static_cast<int32_t>(i));
}
inline JSValue::JSValue(unsigned long i)
{
if (static_cast<uint32_t>(i) != i) {
*this = JSValue(EncodeAsDouble, static_cast<double>(i));
return;
}
*this = JSValue(static_cast<uint32_t>(i));
}
inline JSValue::JSValue(long long i)
{
if (static_cast<int32_t>(i) != i) {
*this = JSValue(EncodeAsDouble, static_cast<double>(i));
return;
}
*this = JSValue(static_cast<int32_t>(i));
}
inline JSValue::JSValue(unsigned long long i)
{
if (static_cast<uint32_t>(i) != i) {
*this = JSValue(EncodeAsDouble, static_cast<double>(i));
return;
}
*this = JSValue(static_cast<uint32_t>(i));
}
inline JSValue::JSValue(double d)
{
if (canBeStrictInt32(d)) {
*this = JSValue(static_cast<int32_t>(d));
return;
}
*this = JSValue(EncodeAsDouble, d);
}
inline EncodedJSValue JSValue::encode(JSValue value)
{
return value.u.asInt64;
}
inline JSValue JSValue::decode(EncodedJSValue encodedJSValue)
{
JSValue v;
v.u.asInt64 = encodedJSValue;
return v;
}
#if USE(JSVALUE32_64)
inline JSValue::JSValue()
{
u.asBits.tag = EmptyValueTag;
u.asBits.payload = 0;
}
inline JSValue::JSValue(JSNullTag)
{
u.asBits.tag = NullTag;
u.asBits.payload = 0;
}
inline JSValue::JSValue(JSUndefinedTag)
{
u.asBits.tag = UndefinedTag;
u.asBits.payload = 0;
}
inline JSValue::JSValue(JSTrueTag)
{
u.asBits.tag = BooleanTag;
u.asBits.payload = 1;
}
inline JSValue::JSValue(JSFalseTag)
{
u.asBits.tag = BooleanTag;
u.asBits.payload = 0;
}
inline JSValue::JSValue(HashTableDeletedValueTag)
{
u.asBits.tag = DeletedValueTag;
u.asBits.payload = 0;
}
inline JSValue::JSValue(JSCell* ptr)
{
if (ptr)
u.asBits.tag = CellTag;
else
u.asBits.tag = EmptyValueTag;
u.asBits.payload = reinterpret_cast<int32_t>(ptr);
}
inline JSValue::JSValue(const JSCell* ptr)
{
if (ptr)
u.asBits.tag = CellTag;
else
u.asBits.tag = EmptyValueTag;
u.asBits.payload = reinterpret_cast<int32_t>(const_cast<JSCell*>(ptr));
}
inline JSValue::operator bool() const
{
ASSERT(tag() != DeletedValueTag);
return tag() != EmptyValueTag;
}
inline bool JSValue::operator==(const JSValue& other) const
{
return u.asInt64 == other.u.asInt64;
}
inline bool JSValue::operator!=(const JSValue& other) const
{
return u.asInt64 != other.u.asInt64;
}
inline bool JSValue::isEmpty() const
{
return tag() == EmptyValueTag;
}
inline bool JSValue::isUndefined() const
{
return tag() == UndefinedTag;
}
inline bool JSValue::isNull() const
{
return tag() == NullTag;
}
inline bool JSValue::isUndefinedOrNull() const
{
return isUndefined() || isNull();
}
inline bool JSValue::isCell() const
{
return tag() == CellTag;
}
inline bool JSValue::isInt32() const
{
return tag() == Int32Tag;
}
inline bool JSValue::isDouble() const
{
return tag() < LowestTag;
}
inline bool JSValue::isTrue() const
{
return tag() == BooleanTag && payload();
}
inline bool JSValue::isFalse() const
{
return tag() == BooleanTag && !payload();
}
inline uint32_t JSValue::tag() const
{
return u.asBits.tag;
}
inline int32_t JSValue::payload() const
{
return u.asBits.payload;
}
inline int32_t JSValue::asInt32() const
{
ASSERT(isInt32());
return u.asBits.payload;
}
inline double JSValue::asDouble() const
{
ASSERT(isDouble());
return u.asDouble;
}
ALWAYS_INLINE JSCell* JSValue::asCell() const
{
ASSERT(isCell());
return reinterpret_cast<JSCell*>(u.asBits.payload);
}
ALWAYS_INLINE JSBigInt* JSValue::asHeapBigInt() const
{
ASSERT(isHeapBigInt());
return reinterpret_cast<JSBigInt*>(u.asBits.payload);
}
ALWAYS_INLINE JSValue::JSValue(EncodeAsDoubleTag, double d)
{
ASSERT(!isImpureNaN(d));
u.asDouble = d;
}
inline JSValue::JSValue(int i)
{
u.asBits.tag = Int32Tag;
u.asBits.payload = i;
}
inline JSValue::JSValue(int32_t tag, int32_t payload)
{
u.asBits.tag = tag;
u.asBits.payload = payload;
}
inline bool JSValue::isNumber() const
{
return isInt32() || isDouble();
}
inline bool JSValue::isBoolean() const
{
return tag() == BooleanTag;
}
inline bool JSValue::asBoolean() const
{
ASSERT(isBoolean());
return payload();
}
#else // !USE(JSVALUE32_64) i.e. USE(JSVALUE64)
// 0x0 can never occur naturally because it has a tag of 00, indicating a pointer value, but a payload of 0x0, which is in the (invalid) zero page.
inline JSValue::JSValue()
{
u.asInt64 = ValueEmpty;
}
// 0x4 can never occur naturally because it has a tag of 00, indicating a pointer value, but a payload of 0x4, which is in the (invalid) zero page.
inline JSValue::JSValue(HashTableDeletedValueTag)
{
u.asInt64 = ValueDeleted;
}
inline JSValue::JSValue(JSCell* ptr)
{
u.asInt64 = reinterpret_cast<uintptr_t>(ptr);
}
inline JSValue::JSValue(const JSCell* ptr)
{
u.asInt64 = reinterpret_cast<uintptr_t>(const_cast<JSCell*>(ptr));
}
inline JSValue::operator bool() const
{
return u.asInt64;
}
inline bool JSValue::operator==(const JSValue& other) const
{
return u.asInt64 == other.u.asInt64;
}
inline bool JSValue::operator!=(const JSValue& other) const
{
return u.asInt64 != other.u.asInt64;
}
inline bool JSValue::isEmpty() const
{
return u.asInt64 == ValueEmpty;
}
inline bool JSValue::isUndefined() const
{
return asValue() == JSValue(JSUndefined);
}
inline bool JSValue::isNull() const
{
return asValue() == JSValue(JSNull);
}
inline bool JSValue::isTrue() const
{
return asValue() == JSValue(JSTrue);
}
inline bool JSValue::isFalse() const
{
return asValue() == JSValue(JSFalse);
}
inline bool JSValue::asBoolean() const
{
ASSERT(isBoolean());
return asValue() == JSValue(JSTrue);
}
inline int32_t JSValue::asInt32() const
{
ASSERT(isInt32());
return static_cast<int32_t>(u.asInt64);
}
inline bool JSValue::isDouble() const
{
return isNumber() && !isInt32();
}
inline JSValue::JSValue(JSNullTag)
{
u.asInt64 = ValueNull;
}
inline JSValue::JSValue(JSUndefinedTag)
{
u.asInt64 = ValueUndefined;
}
inline JSValue::JSValue(JSTrueTag)
{
u.asInt64 = ValueTrue;
}
inline JSValue::JSValue(JSFalseTag)
{
u.asInt64 = ValueFalse;
}
inline bool JSValue::isUndefinedOrNull() const
{
// Undefined and null share the same value, bar the 'undefined' bit in the extended tag.
return (u.asInt64 & ~UndefinedTag) == ValueNull;
}
inline bool JSValue::isBoolean() const
{
return (u.asInt64 & ~1) == ValueFalse;
}
inline bool JSValue::isCell() const
{
return !(u.asInt64 & NotCellMask);
}
inline bool JSValue::isInt32() const
{
return (u.asInt64 & NumberTag) == NumberTag;
}
inline int64_t reinterpretDoubleToInt64(double value)
{
return bitwise_cast<int64_t>(value);
}
inline double reinterpretInt64ToDouble(int64_t value)
{
return bitwise_cast<double>(value);
}
ALWAYS_INLINE JSValue::JSValue(EncodeAsDoubleTag, double d)
{
ASSERT(!isImpureNaN(d));
u.asInt64 = reinterpretDoubleToInt64(d) + JSValue::DoubleEncodeOffset;
}
inline JSValue::JSValue(int i)
{
u.asInt64 = JSValue::NumberTag | static_cast<uint32_t>(i);
}
inline double JSValue::asDouble() const
{
ASSERT(isDouble());
return reinterpretInt64ToDouble(u.asInt64 - JSValue::DoubleEncodeOffset);
}
inline bool JSValue::isNumber() const
{
return u.asInt64 & JSValue::NumberTag;
}
ALWAYS_INLINE JSCell* JSValue::asCell() const
{
ASSERT(isCell());
return u.ptr;
}
ALWAYS_INLINE JSBigInt* JSValue::asHeapBigInt() const
{
ASSERT(isHeapBigInt());
return static_cast<JSBigInt*>(u.ptr);
}
#endif // USE(JSVALUE64)
#if USE(BIGINT32)
inline JSValue::JSValue(EncodeAsBigInt32Tag, int32_t value)
{
uint64_t shiftedValue = static_cast<uint64_t>(static_cast<uint32_t>(value)) << 16;
ASSERT(!(shiftedValue & NumberTag));
u.asInt64 = shiftedValue | BigInt32Tag;
}
#endif // USE(BIGINT32)
inline int64_t tryConvertToInt52(double number)
{
if (number != number)
return JSValue::notInt52;
#if OS(WINDOWS) && CPU(X86)
// The VS Compiler for 32-bit builds generates a floating point error when attempting to cast
// from an infinity to a 64-bit integer. We leave this routine with the floating point error
// left in a register, causing undefined behavior in later floating point operations.
//
// To avoid this issue, we check for infinity here, and return false in that case.
if (std::isinf(number))
return JSValue::notInt52;
#endif
int64_t asInt64 = static_cast<int64_t>(number);
if (asInt64 != number)
return JSValue::notInt52;
if (!asInt64 && std::signbit(number))
return JSValue::notInt52;
if (asInt64 >= (static_cast<int64_t>(1) << (JSValue::numberOfInt52Bits - 1)))
return JSValue::notInt52;
if (asInt64 < -(static_cast<int64_t>(1) << (JSValue::numberOfInt52Bits - 1)))
return JSValue::notInt52;
return asInt64;
}
inline bool isInt52(double number)
{
return tryConvertToInt52(number) != JSValue::notInt52;
}
inline bool JSValue::isAnyInt() const
{
if (isInt32())
return true;
if (!isNumber())
return false;
return isInt52(asDouble());
}
inline int64_t JSValue::asAnyInt() const
{
ASSERT(isAnyInt());
if (isInt32())
return asInt32();
return static_cast<int64_t>(asDouble());
}
inline bool JSValue::isInt32AsAnyInt() const
{
if (!isAnyInt())
return false;
int64_t value = asAnyInt();
return value >= INT32_MIN && value <= INT32_MAX;
}
inline int32_t JSValue::asInt32AsAnyInt() const
{
ASSERT(isInt32AsAnyInt());
if (isInt32())
return asInt32();
return static_cast<int32_t>(asDouble());
}
inline bool JSValue::isUInt32AsAnyInt() const
{
if (!isAnyInt())
return false;
int64_t value = asAnyInt();
return value >= 0 && value <= UINT32_MAX;
}
inline uint32_t JSValue::asUInt32AsAnyInt() const
{
ASSERT(isUInt32AsAnyInt());
if (isUInt32())
return asUInt32();
return static_cast<uint32_t>(asDouble());
}
inline bool JSValue::isString() const
{
return isCell() && asCell()->isString();
}
inline bool JSValue::isBigInt() const
{
return isBigInt32() || isHeapBigInt();
}
inline bool JSValue::isHeapBigInt() const
{
return isCell() && asCell()->isHeapBigInt();
}
inline bool JSValue::isBigInt32() const
{
#if USE(BIGINT32)
return (u.asInt64 & BigInt32Mask) == BigInt32Tag;
#else
return false;
#endif
}
#if USE(BIGINT32)
inline int32_t JSValue::bigInt32AsInt32() const
{
ASSERT(isBigInt32());
return static_cast<int32_t>(u.asInt64 >> 16);
}
#endif // USE(BIGINT32)
inline bool JSValue::isSymbol() const
{
return isCell() && asCell()->isSymbol();
}
inline bool JSValue::isPrimitive() const
{
return !isCell() || asCell()->isString() || asCell()->isSymbol() || asCell()->isHeapBigInt();
}
inline bool JSValue::isGetterSetter() const
{
return isCell() && asCell()->isGetterSetter();
}
inline bool JSValue::isCustomGetterSetter() const
{
return isCell() && asCell()->isCustomGetterSetter();
}
inline bool JSValue::isObject() const
{
return isCell() && asCell()->isObject();
}
inline bool JSValue::getString(JSGlobalObject* globalObject, String& s) const
{
return isCell() && asCell()->getString(globalObject, s);
}
inline String JSValue::getString(JSGlobalObject* globalObject) const
{
return isCell() ? asCell()->getString(globalObject) : String();
}
template <typename Base> String HandleConverter<Base, Unknown>::getString(JSGlobalObject* globalObject) const
{
return jsValue().getString(globalObject);
}
inline JSObject* JSValue::getObject() const
{
return isCell() ? asCell()->getObject() : nullptr;
}
ALWAYS_INLINE bool JSValue::getUInt32(uint32_t& v) const
{
if (isInt32()) {
int32_t i = asInt32();
v = static_cast<uint32_t>(i);
return i >= 0;
}
if (isDouble()) {
double d = asDouble();
v = static_cast<uint32_t>(d);
return v == d;
}
return false;
}
ALWAYS_INLINE Identifier JSValue::toPropertyKey(JSGlobalObject* globalObject) const
{
VM& vm = getVM(globalObject);
auto scope = DECLARE_THROW_SCOPE(vm);
if (isString())
RELEASE_AND_RETURN(scope, asString(*this)->toIdentifier(globalObject));
JSValue primitive = toPrimitive(globalObject, PreferString);
RETURN_IF_EXCEPTION(scope, vm.propertyNames->emptyIdentifier);
if (primitive.isSymbol())
RELEASE_AND_RETURN(scope, Identifier::fromUid(asSymbol(primitive)->privateName()));
auto string = primitive.toString(globalObject);
RETURN_IF_EXCEPTION(scope, { });
RELEASE_AND_RETURN(scope, string->toIdentifier(globalObject));
}
ALWAYS_INLINE JSValue JSValue::toPropertyKeyValue(JSGlobalObject* globalObject) const
{
VM& vm = getVM(globalObject);
auto scope = DECLARE_THROW_SCOPE(vm);
if (isString() || isSymbol())
return *this;
JSValue primitive = toPrimitive(globalObject, PreferString);
RETURN_IF_EXCEPTION(scope, JSValue());
if (primitive.isSymbol())
return primitive;
RELEASE_AND_RETURN(scope, primitive.toString(globalObject));
}
inline JSValue JSValue::toPrimitive(JSGlobalObject* globalObject, PreferredPrimitiveType preferredType) const
{
return isCell() ? asCell()->toPrimitive(globalObject, preferredType) : asValue();
}
inline PreferredPrimitiveType toPreferredPrimitiveType(JSGlobalObject* globalObject, JSValue value)
{
VM& vm = getVM(globalObject);
auto scope = DECLARE_THROW_SCOPE(vm);
if (!value.isString()) {
throwTypeError(globalObject, scope, "Primitive hint is not a string."_s);
return NoPreference;
}
StringImpl* hintString = asString(value)->value(globalObject).impl();
RETURN_IF_EXCEPTION(scope, NoPreference);
if (WTF::equal(hintString, "default"))
return NoPreference;
if (WTF::equal(hintString, "number"))
return PreferNumber;
if (WTF::equal(hintString, "string"))
return PreferString;
throwTypeError(globalObject, scope, "Expected primitive hint to match one of 'default', 'number', 'string'."_s);
return NoPreference;
}
inline bool JSValue::getPrimitiveNumber(JSGlobalObject* globalObject, double& number, JSValue& value)
{
VM& vm = globalObject->vm();
auto scope = DECLARE_THROW_SCOPE(vm);
if (isInt32()) {
number = asInt32();
value = *this;
return true;
}
if (isDouble()) {
number = asDouble();
value = *this;
return true;
}
if (isCell())
return asCell()->getPrimitiveNumber(globalObject, number, value);
if (isTrue()) {
number = 1.0;
value = *this;
return true;
}
if (isFalse() || isNull()) {
number = 0.0;
value = *this;
return true;
}
if (isUndefined()) {
number = PNaN;
value = *this;
return true;
}
ASSERT(isBigInt32());
throwTypeError(globalObject, scope, "Conversion from 'BigInt' to 'number' is not allowed."_s);
number = 0.0;
value = *this;
return true;
}
ALWAYS_INLINE double JSValue::toNumber(JSGlobalObject* globalObject) const
{
if (isInt32())
return asInt32();
if (isDouble())
return asDouble();
return toNumberSlowCase(globalObject);
}
ALWAYS_INLINE JSValue JSValue::toNumeric(JSGlobalObject* globalObject) const
{
VM& vm = globalObject->vm();
auto scope = DECLARE_THROW_SCOPE(vm);
if (isInt32() || isDouble() || isBigInt())
return *this;
JSValue primValue = this->toPrimitive(globalObject, PreferNumber);
RETURN_IF_EXCEPTION(scope, { });
if (primValue.isDouble() || primValue.isBigInt())
return primValue;
double value = primValue.toNumber(globalObject);
RETURN_IF_EXCEPTION(scope, { });
return jsNumber(value);
}
ALWAYS_INLINE Optional<uint32_t> JSValue::toUInt32AfterToNumeric(JSGlobalObject* globalObject) const
{
VM& vm = getVM(globalObject);
auto scope = DECLARE_THROW_SCOPE(vm);
JSValue result = toBigIntOrInt32(globalObject);
RETURN_IF_EXCEPTION(scope, { });
if (LIKELY(result.isInt32()))
return static_cast<uint32_t>(result.asInt32());
return WTF::nullopt;
}
ALWAYS_INLINE JSValue JSValue::toBigIntOrInt32(JSGlobalObject* globalObject) const
{
VM& vm = getVM(globalObject);
auto scope = DECLARE_THROW_SCOPE(vm);
if (isInt32() || isBigInt())
return *this;
if (isDouble() && canBeInt32(asDouble()))
return jsNumber(static_cast<int32_t>(asDouble()));
JSValue primValue = this->toPrimitive(globalObject, PreferNumber);
RETURN_IF_EXCEPTION(scope, { });
if (primValue.isInt32() || primValue.isBigInt())
return primValue;
int32_t value = primValue.toInt32(globalObject);
RETURN_IF_EXCEPTION(scope, { });
return jsNumber(value);
}
inline JSObject* JSValue::toObject(JSGlobalObject* globalObject) const
{
return isCell() ? asCell()->toObject(globalObject) : toObjectSlowCase(globalObject);
}
inline bool JSValue::isCallable(VM& vm) const
{
return isCell() && asCell()->isCallable(vm);
}
inline bool JSValue::isConstructor(VM& vm) const
{
return isCell() && asCell()->isConstructor(vm);
}
// this method is here to be after the inline declaration of JSCell::inherits
inline bool JSValue::inherits(VM& vm, const ClassInfo* classInfo) const
{
return isCell() && asCell()->inherits(vm, classInfo);
}
template<typename Target>
inline bool JSValue::inherits(VM& vm) const
{
return isCell() && asCell()->inherits<Target>(vm);
}
inline const ClassInfo* JSValue::classInfoOrNull(VM& vm) const
{
return isCell() ? asCell()->classInfo(vm) : nullptr;
}
inline JSValue JSValue::toThis(JSGlobalObject* globalObject, ECMAMode ecmaMode) const
{
return isCell() ? asCell()->methodTable(getVM(globalObject))->toThis(asCell(), globalObject, ecmaMode) : toThisSlowCase(globalObject, ecmaMode);
}
ALWAYS_INLINE JSValue JSValue::get(JSGlobalObject* globalObject, PropertyName propertyName) const
{
PropertySlot slot(asValue(), PropertySlot::InternalMethodType::Get);
return get(globalObject, propertyName, slot);
}
ALWAYS_INLINE JSValue JSValue::get(JSGlobalObject* globalObject, PropertyName propertyName, PropertySlot& slot) const
{
auto scope = DECLARE_THROW_SCOPE(getVM(globalObject));
bool hasSlot = getPropertySlot(globalObject, propertyName, slot);
EXCEPTION_ASSERT(!scope.exception() || !hasSlot);
if (!hasSlot)
return jsUndefined();
RELEASE_AND_RETURN(scope, slot.getValue(globalObject, propertyName));
}
template<typename CallbackWhenNoException>
ALWAYS_INLINE typename std::result_of<CallbackWhenNoException(bool, PropertySlot&)>::type JSValue::getPropertySlot(JSGlobalObject* globalObject, PropertyName propertyName, CallbackWhenNoException callback) const
{
PropertySlot slot(asValue(), PropertySlot::InternalMethodType::Get);
return getPropertySlot(globalObject, propertyName, slot, callback);
}
template<typename CallbackWhenNoException>
ALWAYS_INLINE typename std::result_of<CallbackWhenNoException(bool, PropertySlot&)>::type JSValue::getPropertySlot(JSGlobalObject* globalObject, PropertyName propertyName, PropertySlot& slot, CallbackWhenNoException callback) const
{
auto scope = DECLARE_THROW_SCOPE(getVM(globalObject));
bool found = getPropertySlot(globalObject, propertyName, slot);
RETURN_IF_EXCEPTION(scope, { });
RELEASE_AND_RETURN(scope, callback(found, slot));
}
ALWAYS_INLINE bool JSValue::getPropertySlot(JSGlobalObject* globalObject, PropertyName propertyName, PropertySlot& slot) const
{
auto scope = DECLARE_THROW_SCOPE(getVM(globalObject));
// If this is a primitive, we'll need to synthesize the prototype -
// and if it's a string there are special properties to check first.
JSObject* object;
if (UNLIKELY(!isObject())) {
if (isString()) {
bool hasProperty = asString(*this)->getStringPropertySlot(globalObject, propertyName, slot);
RETURN_IF_EXCEPTION(scope, false);
if (hasProperty)
return true;
}
object = synthesizePrototype(globalObject);
EXCEPTION_ASSERT(!!scope.exception() == !object);
if (UNLIKELY(!object))
return false;
} else
object = asObject(asCell());
RELEASE_AND_RETURN(scope, object->getPropertySlot(globalObject, propertyName, slot));
}
ALWAYS_INLINE bool JSValue::getOwnPropertySlot(JSGlobalObject* globalObject, PropertyName propertyName, PropertySlot& slot) const
{
// If this is a primitive, we'll need to synthesize the prototype -
// and if it's a string there are special properties to check first.
auto scope = DECLARE_THROW_SCOPE(getVM(globalObject));
if (UNLIKELY(!isObject())) {
if (isString())
RELEASE_AND_RETURN(scope, asString(*this)->getStringPropertySlot(globalObject, propertyName, slot));
if (isUndefinedOrNull())
throwException(globalObject, scope, createNotAnObjectError(globalObject, *this));
return false;
}
RELEASE_AND_RETURN(scope, asObject(asCell())->getOwnPropertySlotInline(globalObject, propertyName, slot));
}
ALWAYS_INLINE JSValue JSValue::get(JSGlobalObject* globalObject, unsigned propertyName) const
{
PropertySlot slot(asValue(), PropertySlot::InternalMethodType::Get);
return get(globalObject, propertyName, slot);
}
ALWAYS_INLINE JSValue JSValue::get(JSGlobalObject* globalObject, unsigned propertyName, PropertySlot& slot) const
{
auto scope = DECLARE_THROW_SCOPE(getVM(globalObject));
// If this is a primitive, we'll need to synthesize the prototype -
// and if it's a string there are special properties to check first.
JSObject* object;
if (UNLIKELY(!isObject())) {
if (isString()) {
bool hasProperty = asString(*this)->getStringPropertySlot(globalObject, propertyName, slot);
RETURN_IF_EXCEPTION(scope, { });
if (hasProperty)
RELEASE_AND_RETURN(scope, slot.getValue(globalObject, propertyName));
}
object = synthesizePrototype(globalObject);
EXCEPTION_ASSERT(!!scope.exception() == !object);
if (UNLIKELY(!object))
return JSValue();
} else
object = asObject(asCell());
bool hasSlot = object->getPropertySlot(globalObject, propertyName, slot);
EXCEPTION_ASSERT(!scope.exception() || !hasSlot);
if (!hasSlot)
return jsUndefined();
RELEASE_AND_RETURN(scope, slot.getValue(globalObject, propertyName));
}
ALWAYS_INLINE JSValue JSValue::get(JSGlobalObject* globalObject, uint64_t propertyName) const
{
if (LIKELY(propertyName <= std::numeric_limits<unsigned>::max()))
return get(globalObject, static_cast<unsigned>(propertyName));
return get(globalObject, Identifier::from(getVM(globalObject), static_cast<double>(propertyName)));
}
inline bool JSValue::put(JSGlobalObject* globalObject, PropertyName propertyName, JSValue value, PutPropertySlot& slot)
{
if (UNLIKELY(!isCell()))
return putToPrimitive(globalObject, propertyName, value, slot);
return asCell()->methodTable(getVM(globalObject))->put(asCell(), globalObject, propertyName, value, slot);
}
ALWAYS_INLINE bool JSValue::putInline(JSGlobalObject* globalObject, PropertyName propertyName, JSValue value, PutPropertySlot& slot)
{
if (UNLIKELY(!isCell()))
return putToPrimitive(globalObject, propertyName, value, slot);
return asCell()->putInline(globalObject, propertyName, value, slot);
}
inline bool JSValue::putByIndex(JSGlobalObject* globalObject, unsigned propertyName, JSValue value, bool shouldThrow)
{
if (UNLIKELY(!isCell()))
return putToPrimitiveByIndex(globalObject, propertyName, value, shouldThrow);
return asCell()->methodTable(getVM(globalObject))->putByIndex(asCell(), globalObject, propertyName, value, shouldThrow);
}
ALWAYS_INLINE JSValue JSValue::getPrototype(JSGlobalObject* globalObject) const
{
VM& vm = getVM(globalObject);
if (isObject())
return asObject(asCell())->getPrototype(vm, globalObject);
return synthesizePrototype(globalObject);
}
inline Structure* JSValue::structureOrNull() const
{
if (isCell())
return asCell()->structure();
return nullptr;
}
inline JSValue JSValue::structureOrUndefined() const
{
if (isCell())
return JSValue(asCell()->structure());
return jsUndefined();
}
// ECMA 11.9.3
inline bool JSValue::equal(JSGlobalObject* globalObject, JSValue v1, JSValue v2)
{
if (v1.isInt32() && v2.isInt32())
return v1 == v2;
return equalSlowCase(globalObject, v1, v2);
}
ALWAYS_INLINE bool JSValue::equalSlowCaseInline(JSGlobalObject* globalObject, JSValue v1, JSValue v2)
{
VM& vm = getVM(globalObject);
auto scope = DECLARE_THROW_SCOPE(vm);
do {
if (v1.isNumber()) {
if (v2.isNumber())
return v1.asNumber() == v2.asNumber();
// Guaranteeing that if we have a number it is v2 makes some of the cases below simpler.
std::swap(v1, v2);
}
// This deals with Booleans, BigInt32, Objects, and is a shortcut for a few more types.
// It has to come here and not before, because it is NOT true that NaN == NaN
if (v1 == v2)
return true;
if (v1.isUndefinedOrNull()) {
if (v2.isUndefinedOrNull())
return true;
if (!v2.isCell())
return false;
return v2.asCell()->structure(vm)->masqueradesAsUndefined(globalObject);
}
if (v2.isUndefinedOrNull()) {
if (!v1.isCell())
return false;
return v1.asCell()->structure(vm)->masqueradesAsUndefined(globalObject);
}
if (v1.isObject()) {
if (v2.isObject())
return false; // v1 == v2 is already dealt with previously
JSValue p1 = v1.toPrimitive(globalObject);
RETURN_IF_EXCEPTION(scope, false);
v1 = p1;
if (v1.isInt32() && v2.isInt32())
return v1 == v2;
continue;
}
if (v2.isObject()) {
JSValue p2 = v2.toPrimitive(globalObject);
RETURN_IF_EXCEPTION(scope, false);
v2 = p2;
if (v1.isInt32() && v2.isInt32())
return v1 == v2;
continue;
}
bool sym1 = v1.isSymbol();
bool sym2 = v2.isSymbol();
if (sym1 || sym2) {
if (sym1 && sym2)
return false; // v1 == v2 is already dealt with previously
return false;
}
bool s1 = v1.isString();
bool s2 = v2.isString();
if (s1) {
if (s2)
RELEASE_AND_RETURN(scope, asString(v1)->equal(globalObject, asString(v2)));
std::swap(v1, v2);
// We are guaranteed to enter the next case, so losing the invariant of only v2 being a number is fine
}
if (s1 || s2) {
// We are guaranteed that the string is v2 (thanks to the swap above)
if (v1.isBigInt()) {
String v2String = asString(v2)->value(globalObject);
RETURN_IF_EXCEPTION(scope, false);
v2 = JSBigInt::stringToBigInt(globalObject, v2String);
RETURN_IF_EXCEPTION(scope, false);
if (!v2)
return false;
if (v1 == v2)
return true; // For BigInt32
// We fallthrough to the generic code for comparing BigInts (which is only missing the BigInt32/BigInt32 case, hence the check above)
} else {
ASSERT(v1.isNumber() || v1.isBoolean());
double d1 = v1.toNumber(globalObject);
RETURN_IF_EXCEPTION(scope, false);
double d2 = v2.toNumber(globalObject);
RETURN_IF_EXCEPTION(scope, false);
return d1 == d2;
}
}
if (v1.isBoolean()) {
if (v2.isNumber())
return static_cast<double>(v1.asBoolean()) == v2.asNumber();
v1 = JSValue(v1.toNumber(globalObject));
RETURN_IF_EXCEPTION(scope, false);
// We fallthrough to the BigInt/Number comparison below
// We just need one more swap to repair the rule that only v2 is allowed to be a number in these comparisons
std::swap(v1, v2);
} else if (v2.isBoolean()) {
v2 = JSValue(v2.toNumber(globalObject));
RETURN_IF_EXCEPTION(scope, false);
// We fallthrough to the BigInt/Number comparison below
}
#if USE(BIGINT32)
if (v1.isBigInt32()) {
if (v2.isInt32())
return v1.bigInt32AsInt32() == v2.asInt32();
if (v2.isDouble())
return static_cast<double>(v1.bigInt32AsInt32()) == v2.asDouble();
std::swap(v1, v2);
}
#endif // USE(BIGINT32)
if (v1.isHeapBigInt()) {
if (v2.isHeapBigInt())
return JSBigInt::equals(v1.asHeapBigInt(), v2.asHeapBigInt());
#if USE(BIGINT32)
if (v2.isBigInt32())
return v1.asHeapBigInt()->equalsToInt32(v2.bigInt32AsInt32());
#endif // USE(BIGINT32)
if (v2.isNumber())
return v1.asHeapBigInt()->equalsToNumber(v2);
}
return false;
} while (true);
}
// ECMA 11.9.3
ALWAYS_INLINE bool JSValue::strictEqualForCells(JSGlobalObject* globalObject, JSCell* v1, JSCell* v2)
{
if (v1->isString() && v2->isString())
return asString(v1)->equal(globalObject, asString(v2));
if (v1->isHeapBigInt() && v2->isHeapBigInt())
return JSBigInt::equals(static_cast<JSBigInt*>(v1), static_cast<JSBigInt*>(v2));
return v1 == v2;
}
inline bool JSValue::strictEqual(JSGlobalObject* globalObject, JSValue v1, JSValue v2)
{
if (v1.isInt32() && v2.isInt32())
return v1 == v2;
if (v1.isNumber() && v2.isNumber())
return v1.asNumber() == v2.asNumber();
#if USE(BIGINT32)
if (v1.isHeapBigInt() && v2.isBigInt32())
return v1.asHeapBigInt()->equalsToInt32(v2.bigInt32AsInt32());
if (v1.isBigInt32() && v2.isHeapBigInt())
return v2.asHeapBigInt()->equalsToInt32(v1.bigInt32AsInt32());
#endif
if (v1.isCell() && v2.isCell())
return strictEqualForCells(globalObject, v1.asCell(), v2.asCell());
return v1 == v2;
}
inline int32_t JSValue::asInt32ForArithmetic() const
{
if (isBoolean())
return asBoolean();
return asInt32();
}
inline TriState JSValue::pureStrictEqual(JSValue v1, JSValue v2)
{
if (v1.isInt32() && v2.isInt32())
return triState(v1 == v2);
if (v1.isNumber() && v2.isNumber())
return triState(v1.asNumber() == v2.asNumber());
#if USE(BIGINT32)
if (v1.isHeapBigInt() && v2.isBigInt32())
return triState(v1.asHeapBigInt()->equalsToInt32(v2.bigInt32AsInt32()));
if (v1.isBigInt32() && v2.isHeapBigInt())
return triState(v2.asHeapBigInt()->equalsToInt32(v1.bigInt32AsInt32()));
#endif
if (v1.isCell() && v2.isCell()) {
if (v1.asCell()->isString() && v2.asCell()->isString()) {
const StringImpl* v1String = asString(v1)->tryGetValueImpl();
const StringImpl* v2String = asString(v2)->tryGetValueImpl();
if (!v1String || !v2String)
return TriState::Indeterminate;
return triState(WTF::equal(*v1String, *v2String));
}
if (v1.asCell()->isHeapBigInt() && v2.asCell()->isHeapBigInt())
return triState(JSBigInt::equals(v1.asHeapBigInt(), v2.asHeapBigInt()));
}
return triState(v1 == v2);
}
inline TriState JSValue::pureToBoolean() const
{
if (isInt32())
return asInt32() ? TriState::True : TriState::False;
if (isDouble())
return isNotZeroAndOrdered(asDouble()) ? TriState::True : TriState::False; // false for NaN
if (isCell())
return asCell()->pureToBoolean();
#if USE(BIGINT32)
if (isBigInt32())
return bigInt32AsInt32() ? TriState::True : TriState::False;
#endif
return isTrue() ? TriState::True : TriState::False;
}
ALWAYS_INLINE bool JSValue::requireObjectCoercible(JSGlobalObject* globalObject) const
{
VM& vm = getVM(globalObject);
auto scope = DECLARE_THROW_SCOPE(vm);
if (!isUndefinedOrNull())
return true;
throwException(globalObject, scope, createNotAnObjectError(globalObject, *this));
return false;
}
ALWAYS_INLINE bool isThisValueAltered(const PutPropertySlot& slot, JSObject* baseObject)
{
JSValue thisValue = slot.thisValue();
if (LIKELY(thisValue == baseObject))
return false;
if (!thisValue.isObject())
return true;
JSObject* thisObject = asObject(thisValue);
// Only PureForwardingProxyType can be seen as the same to the original target object.
if (thisObject->type() == PureForwardingProxyType && jsCast<JSProxy*>(thisObject)->target() == baseObject)
return false;
return true;
}
// See section 7.2.9: https://tc39.github.io/ecma262/#sec-samevalue
ALWAYS_INLINE bool sameValue(JSGlobalObject* globalObject, JSValue a, JSValue b)
{
if (!a.isNumber())
return JSValue::strictEqual(globalObject, a, b);
if (!b.isNumber())
return false;
double x = a.asNumber();
double y = b.asNumber();
bool xIsNaN = std::isnan(x);
bool yIsNaN = std::isnan(y);
if (xIsNaN || yIsNaN)
return xIsNaN && yIsNaN;
return bitwise_cast<uint64_t>(x) == bitwise_cast<uint64_t>(y);
}
} // namespace JSC