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/*
* Copyright (C) 2011-2019 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.
*/
#include "config.h"
#include "DFGOperations.h"
#include "ArrayConstructor.h"
#include "ButterflyInlines.h"
#include "ClonedArguments.h"
#include "CodeBlock.h"
#include "CommonSlowPaths.h"
#include "DFGDriver.h"
#include "DFGJITCode.h"
#include "DFGOSRExit.h"
#include "DFGThunks.h"
#include "DFGToFTLDeferredCompilationCallback.h"
#include "DFGToFTLForOSREntryDeferredCompilationCallback.h"
#include "DFGWorklist.h"
#include "DefinePropertyAttributes.h"
#include "DirectArguments.h"
#include "FTLForOSREntryJITCode.h"
#include "FTLOSREntry.h"
#include "FrameTracers.h"
#include "HasOwnPropertyCache.h"
#include "HostCallReturnValue.h"
#include "Interpreter.h"
#include "JIT.h"
#include "JITExceptions.h"
#include "JSArrayInlines.h"
#include "JSBigInt.h"
#include "JSCInlines.h"
#include "JSFixedArray.h"
#include "JSGenericTypedArrayViewConstructorInlines.h"
#include "JSGlobalObjectFunctions.h"
#include "JSImmutableButterfly.h"
#include "JSInternalPromise.h"
#include "JSInternalPromiseConstructor.h"
#include "JSLexicalEnvironment.h"
#include "JSMap.h"
#include "JSPromiseConstructor.h"
#include "JSPropertyNameEnumerator.h"
#include "JSSet.h"
#include "JSWeakMap.h"
#include "JSWeakSet.h"
#include "NumberConstructor.h"
#include "ObjectConstructor.h"
#include "Operations.h"
#include "ParseInt.h"
#include "RegExpGlobalDataInlines.h"
#include "RegExpMatchesArray.h"
#include "RegExpObjectInlines.h"
#include "Repatch.h"
#include "ScopedArguments.h"
#include "StringConstructor.h"
#include "StringPrototypeInlines.h"
#include "SuperSampler.h"
#include "Symbol.h"
#include "TypeProfilerLog.h"
#include "TypedArrayInlines.h"
#include "VMInlines.h"
#include <wtf/InlineASM.h>
#include <wtf/Variant.h>
#if ENABLE(JIT)
#if ENABLE(DFG_JIT)
namespace JSC { namespace DFG {
template<bool strict, bool direct>
static inline void putByVal(ExecState* exec, VM& vm, JSValue baseValue, uint32_t index, JSValue value)
{
ASSERT(isIndex(index));
if (direct) {
RELEASE_ASSERT(baseValue.isObject());
asObject(baseValue)->putDirectIndex(exec, index, value, 0, strict ? PutDirectIndexShouldThrow : PutDirectIndexShouldNotThrow);
return;
}
if (baseValue.isObject()) {
JSObject* object = asObject(baseValue);
if (object->canSetIndexQuickly(index, value)) {
object->setIndexQuickly(vm, index, value);
return;
}
object->methodTable(vm)->putByIndex(object, exec, index, value, strict);
return;
}
baseValue.putByIndex(exec, index, value, strict);
}
template<bool strict, bool direct>
ALWAYS_INLINE static void putByValInternal(ExecState* exec, VM& vm, EncodedJSValue encodedBase, EncodedJSValue encodedProperty, EncodedJSValue encodedValue)
{
auto scope = DECLARE_THROW_SCOPE(vm);
JSValue baseValue = JSValue::decode(encodedBase);
JSValue property = JSValue::decode(encodedProperty);
JSValue value = JSValue::decode(encodedValue);
if (LIKELY(property.isUInt32())) {
// Despite its name, JSValue::isUInt32 will return true only for positive boxed int32_t; all those values are valid array indices.
ASSERT(isIndex(property.asUInt32()));
scope.release();
putByVal<strict, direct>(exec, vm, baseValue, property.asUInt32(), value);
return;
}
if (property.isDouble()) {
double propertyAsDouble = property.asDouble();
uint32_t propertyAsUInt32 = static_cast<uint32_t>(propertyAsDouble);
if (propertyAsDouble == propertyAsUInt32 && isIndex(propertyAsUInt32)) {
scope.release();
putByVal<strict, direct>(exec, vm, baseValue, propertyAsUInt32, value);
return;
}
}
// Don't put to an object if toString throws an exception.
auto propertyName = property.toPropertyKey(exec);
RETURN_IF_EXCEPTION(scope, void());
PutPropertySlot slot(baseValue, strict);
if (direct) {
RELEASE_ASSERT(baseValue.isObject());
JSObject* baseObject = asObject(baseValue);
if (Optional<uint32_t> index = parseIndex(propertyName)) {
scope.release();
baseObject->putDirectIndex(exec, index.value(), value, 0, strict ? PutDirectIndexShouldThrow : PutDirectIndexShouldNotThrow);
return;
}
scope.release();
CommonSlowPaths::putDirectWithReify(vm, exec, baseObject, propertyName, value, slot);
return;
}
scope.release();
baseValue.put(exec, propertyName, value, slot);
}
template<bool strict, bool direct>
ALWAYS_INLINE static void putByValCellInternal(ExecState* exec, VM& vm, JSCell* base, PropertyName propertyName, JSValue value)
{
PutPropertySlot slot(base, strict);
if (direct) {
RELEASE_ASSERT(base->isObject());
JSObject* baseObject = asObject(base);
if (Optional<uint32_t> index = parseIndex(propertyName)) {
baseObject->putDirectIndex(exec, index.value(), value, 0, strict ? PutDirectIndexShouldThrow : PutDirectIndexShouldNotThrow);
return;
}
CommonSlowPaths::putDirectWithReify(vm, exec, baseObject, propertyName, value, slot);
return;
}
base->putInline(exec, propertyName, value, slot);
}
template<bool strict, bool direct>
ALWAYS_INLINE static void putByValCellStringInternal(ExecState* exec, VM& vm, JSCell* base, JSString* property, JSValue value)
{
auto scope = DECLARE_THROW_SCOPE(vm);
auto propertyName = property->toIdentifier(exec);
RETURN_IF_EXCEPTION(scope, void());
scope.release();
putByValCellInternal<strict, direct>(exec, vm, base, propertyName, value);
}
template<typename ViewClass>
char* newTypedArrayWithSize(ExecState* exec, Structure* structure, int32_t size, char* vector)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
auto scope = DECLARE_THROW_SCOPE(vm);
if (size < 0) {
throwException(exec, scope, createRangeError(exec, "Requested length is negative"_s));
return 0;
}
if (vector)
return bitwise_cast<char*>(ViewClass::createWithFastVector(exec, structure, size, untagArrayPtr(vector, size)));
RELEASE_AND_RETURN(scope, bitwise_cast<char*>(ViewClass::create(exec, structure, size)));
}
template <bool strict>
static ALWAYS_INLINE void putWithThis(ExecState* exec, EncodedJSValue encodedBase, EncodedJSValue encodedThis, EncodedJSValue encodedValue, const Identifier& ident)
{
JSValue baseValue = JSValue::decode(encodedBase);
JSValue thisVal = JSValue::decode(encodedThis);
JSValue putValue = JSValue::decode(encodedValue);
PutPropertySlot slot(thisVal, strict);
baseValue.putInline(exec, ident, putValue, slot);
}
template<typename BigIntOperation, typename NumberOperation>
static ALWAYS_INLINE EncodedJSValue binaryOp(ExecState* exec, EncodedJSValue encodedOp1, EncodedJSValue encodedOp2, BigIntOperation&& bigIntOp, NumberOperation&& numberOp, const char* errorMessage)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
auto scope = DECLARE_THROW_SCOPE(vm);
JSValue op1 = JSValue::decode(encodedOp1);
JSValue op2 = JSValue::decode(encodedOp2);
auto leftNumeric = op1.toNumeric(exec);
RETURN_IF_EXCEPTION(scope, encodedJSValue());
auto rightNumeric = op2.toNumeric(exec);
RETURN_IF_EXCEPTION(scope, encodedJSValue());
if (WTF::holds_alternative<JSBigInt*>(leftNumeric) || WTF::holds_alternative<JSBigInt*>(rightNumeric)) {
if (WTF::holds_alternative<JSBigInt*>(leftNumeric) && WTF::holds_alternative<JSBigInt*>(rightNumeric))
RELEASE_AND_RETURN(scope, JSValue::encode(bigIntOp(exec, WTF::get<JSBigInt*>(leftNumeric), WTF::get<JSBigInt*>(rightNumeric))));
return throwVMTypeError(exec, scope, errorMessage);
}
scope.release();
return JSValue::encode(jsNumber(numberOp(WTF::get<double>(leftNumeric), WTF::get<double>(rightNumeric))));
}
template<typename BigIntOperation, typename Int32Operation>
static ALWAYS_INLINE EncodedJSValue bitwiseBinaryOp(ExecState* exec, EncodedJSValue encodedOp1, EncodedJSValue encodedOp2, BigIntOperation&& bigIntOp, Int32Operation&& int32Op, const char* errorMessage)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
auto scope = DECLARE_THROW_SCOPE(vm);
JSValue op1 = JSValue::decode(encodedOp1);
JSValue op2 = JSValue::decode(encodedOp2);
auto leftNumeric = op1.toBigIntOrInt32(exec);
RETURN_IF_EXCEPTION(scope, encodedJSValue());
auto rightNumeric = op2.toBigIntOrInt32(exec);
RETURN_IF_EXCEPTION(scope, encodedJSValue());
if (WTF::holds_alternative<JSBigInt*>(leftNumeric) || WTF::holds_alternative<JSBigInt*>(rightNumeric)) {
if (WTF::holds_alternative<JSBigInt*>(leftNumeric) && WTF::holds_alternative<JSBigInt*>(rightNumeric))
RELEASE_AND_RETURN(scope, JSValue::encode(bigIntOp(exec, WTF::get<JSBigInt*>(leftNumeric), WTF::get<JSBigInt*>(rightNumeric))));
return throwVMTypeError(exec, scope, errorMessage);
}
scope.release();
return JSValue::encode(jsNumber(int32Op(WTF::get<int32_t>(leftNumeric), WTF::get<int32_t>(rightNumeric))));
}
static ALWAYS_INLINE EncodedJSValue parseIntResult(double input)
{
int asInt = static_cast<int>(input);
if (static_cast<double>(asInt) == input)
return JSValue::encode(jsNumber(asInt));
return JSValue::encode(jsNumber(input));
}
ALWAYS_INLINE static JSValue getByValObject(ExecState* exec, VM& vm, JSObject* base, PropertyName propertyName)
{
Structure& structure = *base->structure(vm);
if (JSCell::canUseFastGetOwnProperty(structure)) {
if (JSValue result = base->fastGetOwnProperty(vm, structure, propertyName))
return result;
}
return base->get(exec, propertyName);
}
extern "C" {
EncodedJSValue JIT_OPERATION operationToThis(ExecState* exec, EncodedJSValue encodedOp)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
return JSValue::encode(JSValue::decode(encodedOp).toThis(exec, NotStrictMode));
}
EncodedJSValue JIT_OPERATION operationToThisStrict(ExecState* exec, EncodedJSValue encodedOp)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
return JSValue::encode(JSValue::decode(encodedOp).toThis(exec, StrictMode));
}
JSArray* JIT_OPERATION operationObjectKeys(ExecState* exec, EncodedJSValue encodedObject)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
auto scope = DECLARE_THROW_SCOPE(vm);
JSObject* object = JSValue::decode(encodedObject).toObject(exec);
RETURN_IF_EXCEPTION(scope, nullptr);
scope.release();
return ownPropertyKeys(exec, object, PropertyNameMode::Strings, DontEnumPropertiesMode::Exclude);
}
JSArray* JIT_OPERATION operationObjectKeysObject(ExecState* exec, JSObject* object)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
return ownPropertyKeys(exec, object, PropertyNameMode::Strings, DontEnumPropertiesMode::Exclude);
}
JSCell* JIT_OPERATION operationObjectCreate(ExecState* exec, EncodedJSValue encodedPrototype)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
auto scope = DECLARE_THROW_SCOPE(vm);
JSValue prototype = JSValue::decode(encodedPrototype);
if (!prototype.isObject() && !prototype.isNull()) {
throwVMTypeError(exec, scope, "Object prototype may only be an Object or null."_s);
return nullptr;
}
if (prototype.isObject())
RELEASE_AND_RETURN(scope, constructEmptyObject(exec, asObject(prototype)));
RELEASE_AND_RETURN(scope, constructEmptyObject(exec, exec->lexicalGlobalObject()->nullPrototypeObjectStructure()));
}
JSCell* JIT_OPERATION operationObjectCreateObject(ExecState* exec, JSObject* prototype)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
return constructEmptyObject(exec, prototype);
}
JSCell* JIT_OPERATION operationCreateThis(ExecState* exec, JSObject* constructor, uint32_t inlineCapacity)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
auto scope = DECLARE_THROW_SCOPE(vm);
if (constructor->type() == JSFunctionType && jsCast<JSFunction*>(constructor)->canUseAllocationProfile()) {
auto rareData = jsCast<JSFunction*>(constructor)->ensureRareDataAndAllocationProfile(exec, inlineCapacity);
scope.releaseAssertNoException();
ObjectAllocationProfileWithPrototype* allocationProfile = rareData->objectAllocationProfile();
Structure* structure = allocationProfile->structure();
JSObject* result = constructEmptyObject(exec, structure);
if (structure->hasPolyProto()) {
JSObject* prototype = allocationProfile->prototype();
ASSERT(prototype == jsCast<JSFunction*>(constructor)->prototypeForConstruction(vm, exec));
result->putDirect(vm, knownPolyProtoOffset, prototype);
prototype->didBecomePrototype();
ASSERT_WITH_MESSAGE(!hasIndexedProperties(result->indexingType()), "We rely on JSFinalObject not starting out with an indexing type otherwise we would potentially need to convert to slow put storage");
}
return result;
}
JSValue proto = constructor->get(exec, vm.propertyNames->prototype);
RETURN_IF_EXCEPTION(scope, nullptr);
if (proto.isObject())
return constructEmptyObject(exec, asObject(proto));
return constructEmptyObject(exec);
}
JSCell* JIT_OPERATION operationCreatePromise(ExecState* exec, JSObject* constructor, JSGlobalObject* globalObject)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
auto scope = DECLARE_THROW_SCOPE(vm);
Structure* structure = InternalFunction::createSubclassStructure(exec, globalObject->promiseConstructor(), constructor, globalObject->promiseStructure());
RETURN_IF_EXCEPTION(scope, nullptr);
RELEASE_AND_RETURN(scope, JSPromise::create(vm, structure));
}
JSCell* JIT_OPERATION operationCreateInternalPromise(ExecState* exec, JSObject* constructor, JSGlobalObject* globalObject)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
auto scope = DECLARE_THROW_SCOPE(vm);
Structure* structure = InternalFunction::createSubclassStructure(exec, globalObject->internalPromiseConstructor(), constructor, globalObject->internalPromiseStructure());
RETURN_IF_EXCEPTION(scope, nullptr);
RELEASE_AND_RETURN(scope, JSInternalPromise::create(vm, structure));
}
JSCell* JIT_OPERATION operationCreateGenerator(ExecState* exec, JSObject* constructor, JSGlobalObject* globalObject)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
auto scope = DECLARE_THROW_SCOPE(vm);
Structure* structure = InternalFunction::createSubclassStructure(exec, nullptr, constructor, globalObject->generatorStructure());
RETURN_IF_EXCEPTION(scope, nullptr);
RELEASE_AND_RETURN(scope, JSGenerator::create(vm, structure));
}
JSCell* JIT_OPERATION operationCreateAsyncGenerator(ExecState* exec, JSObject* constructor, JSGlobalObject* globalObject)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
auto scope = DECLARE_THROW_SCOPE(vm);
Structure* structure = InternalFunction::createSubclassStructure(exec, nullptr, constructor, globalObject->asyncGeneratorStructure());
RETURN_IF_EXCEPTION(scope, nullptr);
RELEASE_AND_RETURN(scope, JSAsyncGenerator::create(vm, structure));
}
JSCell* JIT_OPERATION operationCallObjectConstructor(ExecState* exec, JSGlobalObject* globalObject, EncodedJSValue encodedTarget)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
JSValue value = JSValue::decode(encodedTarget);
ASSERT(!value.isObject());
if (value.isUndefinedOrNull())
return constructEmptyObject(exec, globalObject->objectPrototype());
return value.toObject(exec, globalObject);
}
JSCell* JIT_OPERATION operationToObject(ExecState* exec, JSGlobalObject* globalObject, EncodedJSValue encodedTarget, UniquedStringImpl* errorMessage)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
auto scope = DECLARE_THROW_SCOPE(vm);
JSValue value = JSValue::decode(encodedTarget);
ASSERT(!value.isObject());
if (UNLIKELY(value.isUndefinedOrNull())) {
if (errorMessage->length()) {
throwVMTypeError(exec, scope, errorMessage);
return nullptr;
}
}
RELEASE_AND_RETURN(scope, value.toObject(exec, globalObject));
}
EncodedJSValue JIT_OPERATION operationValueMod(ExecState* exec, EncodedJSValue encodedOp1, EncodedJSValue encodedOp2)
{
auto bigIntOp = [] (ExecState* exec, JSBigInt* left, JSBigInt* right) -> JSBigInt* {
return JSBigInt::remainder(exec, left, right);
};
auto numberOp = [] (double left, double right) -> double {
return jsMod(left, right);
};
return binaryOp(exec, encodedOp1, encodedOp2, bigIntOp, numberOp, "Invalid mix of BigInt and other type in remainder operation.");
}
EncodedJSValue JIT_OPERATION operationValueBitNot(ExecState* exec, EncodedJSValue encodedOp1)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
auto scope = DECLARE_THROW_SCOPE(vm);
JSValue op1 = JSValue::decode(encodedOp1);
auto operandNumeric = op1.toBigIntOrInt32(exec);
RETURN_IF_EXCEPTION(scope, encodedJSValue());
if (WTF::holds_alternative<JSBigInt*>(operandNumeric))
RELEASE_AND_RETURN(scope, JSValue::encode(JSBigInt::bitwiseNot(exec, WTF::get<JSBigInt*>(operandNumeric))));
return JSValue::encode(jsNumber(~WTF::get<int32_t>(operandNumeric)));
}
EncodedJSValue JIT_OPERATION operationValueBitAnd(ExecState* exec, EncodedJSValue encodedOp1, EncodedJSValue encodedOp2)
{
auto bigIntOp = [] (ExecState* exec, JSBigInt* left, JSBigInt* right) -> JSBigInt* {
return JSBigInt::bitwiseAnd(exec, left, right);
};
auto int32Op = [] (int32_t left, int32_t right) -> int32_t {
return left & right;
};
return bitwiseBinaryOp(exec, encodedOp1, encodedOp2, bigIntOp, int32Op, "Invalid mix of BigInt and other type in bitwise 'and' operation."_s);
}
EncodedJSValue JIT_OPERATION operationValueBitOr(ExecState* exec, EncodedJSValue encodedOp1, EncodedJSValue encodedOp2)
{
auto bigIntOp = [] (ExecState* exec, JSBigInt* left, JSBigInt* right) -> JSBigInt* {
return JSBigInt::bitwiseOr(exec, left, right);
};
auto int32Op = [] (int32_t left, int32_t right) -> int32_t {
return left | right;
};
return bitwiseBinaryOp(exec, encodedOp1, encodedOp2, bigIntOp, int32Op, "Invalid mix of BigInt and other type in bitwise 'or' operation."_s);
}
EncodedJSValue JIT_OPERATION operationValueBitXor(ExecState* exec, EncodedJSValue encodedOp1, EncodedJSValue encodedOp2)
{
auto bigIntOp = [] (ExecState* exec, JSBigInt* left, JSBigInt* right) -> JSBigInt* {
return JSBigInt::bitwiseXor(exec, left, right);
};
auto int32Op = [] (int32_t left, int32_t right) -> int32_t {
return left ^ right;
};
return bitwiseBinaryOp(exec, encodedOp1, encodedOp2, bigIntOp, int32Op, "Invalid mix of BigInt and other type in bitwise 'xor' operation."_s);
}
EncodedJSValue JIT_OPERATION operationValueBitLShift(ExecState* exec, EncodedJSValue encodedOp1, EncodedJSValue encodedOp2)
{
auto bigIntOp = [] (ExecState* exec, JSBigInt* left, JSBigInt* right) -> JSBigInt* {
return JSBigInt::leftShift(exec, left, right);
};
auto int32Op = [] (int32_t left, int32_t right) -> int32_t {
return left << (right & 0x1f);
};
return bitwiseBinaryOp(exec, encodedOp1, encodedOp2, bigIntOp, int32Op, "Invalid mix of BigInt and other type in left shift operation."_s);
}
EncodedJSValue JIT_OPERATION operationValueBitRShift(ExecState* exec, EncodedJSValue encodedOp1, EncodedJSValue encodedOp2)
{
auto bigIntOp = [] (ExecState* exec, JSBigInt* left, JSBigInt* right) -> JSBigInt* {
return JSBigInt::signedRightShift(exec, left, right);
};
auto int32Op = [] (int32_t left, int32_t right) -> int32_t {
return left >> (right & 0x1f);
};
return bitwiseBinaryOp(exec, encodedOp1, encodedOp2, bigIntOp, int32Op, "Invalid mix of BigInt and other type in signed right shift operation."_s);
}
EncodedJSValue JIT_OPERATION operationValueBitURShift(ExecState* exec, EncodedJSValue encodedOp1, EncodedJSValue encodedOp2)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
auto scope = DECLARE_THROW_SCOPE(vm);
JSValue op1 = JSValue::decode(encodedOp1);
JSValue op2 = JSValue::decode(encodedOp2);
uint32_t a = op1.toUInt32(exec);
RETURN_IF_EXCEPTION(scope, encodedJSValue());
scope.release();
uint32_t b = op2.toUInt32(exec);
return JSValue::encode(jsNumber(static_cast<int32_t>(a >> (b & 0x1f))));
}
EncodedJSValue JIT_OPERATION operationValueAddNotNumber(ExecState* exec, EncodedJSValue encodedOp1, EncodedJSValue encodedOp2)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
JSValue op1 = JSValue::decode(encodedOp1);
JSValue op2 = JSValue::decode(encodedOp2);
return JSValue::encode(jsAddNonNumber(exec, op1, op2));
}
EncodedJSValue JIT_OPERATION operationValueDiv(ExecState* exec, EncodedJSValue encodedOp1, EncodedJSValue encodedOp2)
{
auto bigIntOp = [] (ExecState* exec, JSBigInt* left, JSBigInt* right) -> JSBigInt* {
return JSBigInt::divide(exec, left, right);
};
auto numberOp = [] (double left, double right) -> double {
return left / right;
};
return binaryOp(exec, encodedOp1, encodedOp2, bigIntOp, numberOp, "Invalid mix of BigInt and other type in division operation.");
}
EncodedJSValue JIT_OPERATION operationValuePow(ExecState* exec, EncodedJSValue encodedOp1, EncodedJSValue encodedOp2)
{
auto bigIntOp = [] (ExecState* exec, JSBigInt* left, JSBigInt* right) -> JSBigInt* {
return JSBigInt::exponentiate(exec, left, right);
};
auto numberOp = [] (double left, double right) -> double {
return operationMathPow(left, right);
};
return binaryOp(exec, encodedOp1, encodedOp2, bigIntOp, numberOp, "Invalid mix of BigInt and other type in exponentiation operation."_s);
}
double JIT_OPERATION operationArithAbs(ExecState* exec, EncodedJSValue encodedOp1)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
auto scope = DECLARE_THROW_SCOPE(vm);
JSValue op1 = JSValue::decode(encodedOp1);
double a = op1.toNumber(exec);
RETURN_IF_EXCEPTION(scope, PNaN);
return fabs(a);
}
uint32_t JIT_OPERATION operationArithClz32(ExecState* exec, EncodedJSValue encodedOp1)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
auto scope = DECLARE_THROW_SCOPE(vm);
JSValue op1 = JSValue::decode(encodedOp1);
uint32_t value = op1.toUInt32(exec);
RETURN_IF_EXCEPTION(scope, 0);
return clz(value);
}
double JIT_OPERATION operationArithFRound(ExecState* exec, EncodedJSValue encodedOp1)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
auto scope = DECLARE_THROW_SCOPE(vm);
JSValue op1 = JSValue::decode(encodedOp1);
double a = op1.toNumber(exec);
RETURN_IF_EXCEPTION(scope, PNaN);
return static_cast<float>(a);
}
#define DFG_ARITH_UNARY(capitalizedName, lowerName) \
double JIT_OPERATION operationArith##capitalizedName(ExecState* exec, EncodedJSValue encodedOp1) \
{ \
VM& vm = exec->vm(); \
NativeCallFrameTracer tracer(vm, exec); \
auto scope = DECLARE_THROW_SCOPE(vm); \
JSValue op1 = JSValue::decode(encodedOp1); \
double result = op1.toNumber(exec); \
RETURN_IF_EXCEPTION(scope, PNaN); \
return JSC::Math::lowerName(result); \
}
FOR_EACH_DFG_ARITH_UNARY_OP(DFG_ARITH_UNARY)
#undef DFG_ARITH_UNARY
double JIT_OPERATION operationArithSqrt(ExecState* exec, EncodedJSValue encodedOp1)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
auto scope = DECLARE_THROW_SCOPE(vm);
JSValue op1 = JSValue::decode(encodedOp1);
double a = op1.toNumber(exec);
RETURN_IF_EXCEPTION(scope, PNaN);
return sqrt(a);
}
EncodedJSValue JIT_OPERATION operationArithRound(ExecState* exec, EncodedJSValue encodedArgument)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
auto scope = DECLARE_THROW_SCOPE(vm);
JSValue argument = JSValue::decode(encodedArgument);
double valueOfArgument = argument.toNumber(exec);
RETURN_IF_EXCEPTION(scope, encodedJSValue());
return JSValue::encode(jsNumber(jsRound(valueOfArgument)));
}
EncodedJSValue JIT_OPERATION operationArithFloor(ExecState* exec, EncodedJSValue encodedArgument)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
auto scope = DECLARE_THROW_SCOPE(vm);
JSValue argument = JSValue::decode(encodedArgument);
double valueOfArgument = argument.toNumber(exec);
RETURN_IF_EXCEPTION(scope, encodedJSValue());
return JSValue::encode(jsNumber(floor(valueOfArgument)));
}
EncodedJSValue JIT_OPERATION operationArithCeil(ExecState* exec, EncodedJSValue encodedArgument)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
auto scope = DECLARE_THROW_SCOPE(vm);
JSValue argument = JSValue::decode(encodedArgument);
double valueOfArgument = argument.toNumber(exec);
RETURN_IF_EXCEPTION(scope, encodedJSValue());
return JSValue::encode(jsNumber(ceil(valueOfArgument)));
}
EncodedJSValue JIT_OPERATION operationArithTrunc(ExecState* exec, EncodedJSValue encodedArgument)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
auto scope = DECLARE_THROW_SCOPE(vm);
JSValue argument = JSValue::decode(encodedArgument);
double truncatedValueOfArgument = argument.toIntegerPreserveNaN(exec);
RETURN_IF_EXCEPTION(scope, encodedJSValue());
return JSValue::encode(jsNumber(truncatedValueOfArgument));
}
static ALWAYS_INLINE EncodedJSValue getByVal(ExecState* exec, JSCell* base, uint32_t index)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
if (base->isObject()) {
JSObject* object = asObject(base);
if (object->canGetIndexQuickly(index))
return JSValue::encode(object->getIndexQuickly(index));
}
if (isJSString(base) && asString(base)->canGetIndex(index))
return JSValue::encode(asString(base)->getIndex(exec, index));
return JSValue::encode(JSValue(base).get(exec, index));
}
EncodedJSValue JIT_OPERATION operationGetByVal(ExecState* exec, EncodedJSValue encodedBase, EncodedJSValue encodedProperty)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
auto scope = DECLARE_THROW_SCOPE(vm);
JSValue baseValue = JSValue::decode(encodedBase);
JSValue property = JSValue::decode(encodedProperty);
if (LIKELY(baseValue.isCell())) {
JSCell* base = baseValue.asCell();
if (property.isUInt32())
RELEASE_AND_RETURN(scope, getByVal(exec, base, property.asUInt32()));
if (property.isDouble()) {
double propertyAsDouble = property.asDouble();
uint32_t propertyAsUInt32 = static_cast<uint32_t>(propertyAsDouble);
if (propertyAsUInt32 == propertyAsDouble && isIndex(propertyAsUInt32))
RELEASE_AND_RETURN(scope, getByVal(exec, base, propertyAsUInt32));
} else if (property.isString()) {
Structure& structure = *base->structure(vm);
if (JSCell::canUseFastGetOwnProperty(structure)) {
RefPtr<AtomStringImpl> existingAtomString = asString(property)->toExistingAtomString(exec);
RETURN_IF_EXCEPTION(scope, encodedJSValue());
if (existingAtomString) {
if (JSValue result = base->fastGetOwnProperty(vm, structure, existingAtomString.get()))
return JSValue::encode(result);
}
}
}
}
baseValue.requireObjectCoercible(exec);
RETURN_IF_EXCEPTION(scope, encodedJSValue());
auto propertyName = property.toPropertyKey(exec);
RETURN_IF_EXCEPTION(scope, encodedJSValue());
RELEASE_AND_RETURN(scope, JSValue::encode(baseValue.get(exec, propertyName)));
}
EncodedJSValue JIT_OPERATION operationGetByValCell(ExecState* exec, JSCell* base, EncodedJSValue encodedProperty)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
auto scope = DECLARE_THROW_SCOPE(vm);
JSValue property = JSValue::decode(encodedProperty);
if (property.isUInt32())
RELEASE_AND_RETURN(scope, getByVal(exec, base, property.asUInt32()));
if (property.isDouble()) {
double propertyAsDouble = property.asDouble();
uint32_t propertyAsUInt32 = static_cast<uint32_t>(propertyAsDouble);
if (propertyAsUInt32 == propertyAsDouble)
RELEASE_AND_RETURN(scope, getByVal(exec, base, propertyAsUInt32));
} else if (property.isString()) {
Structure& structure = *base->structure(vm);
if (JSCell::canUseFastGetOwnProperty(structure)) {
RefPtr<AtomStringImpl> existingAtomString = asString(property)->toExistingAtomString(exec);
RETURN_IF_EXCEPTION(scope, encodedJSValue());
if (existingAtomString) {
if (JSValue result = base->fastGetOwnProperty(vm, structure, existingAtomString.get()))
return JSValue::encode(result);
}
}
}
auto propertyName = property.toPropertyKey(exec);
RETURN_IF_EXCEPTION(scope, encodedJSValue());
RELEASE_AND_RETURN(scope, JSValue::encode(JSValue(base).get(exec, propertyName)));
}
ALWAYS_INLINE EncodedJSValue getByValCellInt(ExecState* exec, JSCell* base, int32_t index)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
if (index < 0) {
// Go the slowest way possible because negative indices don't use indexed storage.
return JSValue::encode(JSValue(base).get(exec, Identifier::from(vm, index)));
}
// Use this since we know that the value is out of bounds.
return JSValue::encode(JSValue(base).get(exec, static_cast<unsigned>(index)));
}
EncodedJSValue JIT_OPERATION operationGetByValObjectInt(ExecState* exec, JSObject* base, int32_t index)
{
return getByValCellInt(exec, base, index);
}
EncodedJSValue JIT_OPERATION operationGetByValStringInt(ExecState* exec, JSString* base, int32_t index)
{
return getByValCellInt(exec, base, index);
}
EncodedJSValue JIT_OPERATION operationGetByValObjectString(ExecState* exec, JSCell* base, JSCell* string)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
auto scope = DECLARE_THROW_SCOPE(vm);
auto propertyName = asString(string)->toIdentifier(exec);
RETURN_IF_EXCEPTION(scope, encodedJSValue());
RELEASE_AND_RETURN(scope, JSValue::encode(getByValObject(exec, vm, asObject(base), propertyName)));
}
EncodedJSValue JIT_OPERATION operationGetByValObjectSymbol(ExecState* exec, JSCell* base, JSCell* symbol)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
auto propertyName = asSymbol(symbol)->privateName();
return JSValue::encode(getByValObject(exec, vm, asObject(base), propertyName));
}
void JIT_OPERATION operationPutByValStrict(ExecState* exec, EncodedJSValue encodedBase, EncodedJSValue encodedProperty, EncodedJSValue encodedValue)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
putByValInternal<true, false>(exec, vm, encodedBase, encodedProperty, encodedValue);
}
void JIT_OPERATION operationPutByValNonStrict(ExecState* exec, EncodedJSValue encodedBase, EncodedJSValue encodedProperty, EncodedJSValue encodedValue)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
putByValInternal<false, false>(exec, vm, encodedBase, encodedProperty, encodedValue);
}
void JIT_OPERATION operationPutByValCellStrict(ExecState* exec, JSCell* cell, EncodedJSValue encodedProperty, EncodedJSValue encodedValue)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
putByValInternal<true, false>(exec, vm, JSValue::encode(cell), encodedProperty, encodedValue);
}
void JIT_OPERATION operationPutByValCellNonStrict(ExecState* exec, JSCell* cell, EncodedJSValue encodedProperty, EncodedJSValue encodedValue)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
putByValInternal<false, false>(exec, vm, JSValue::encode(cell), encodedProperty, encodedValue);
}
void JIT_OPERATION operationPutByValCellStringStrict(ExecState* exec, JSCell* cell, JSCell* string, EncodedJSValue encodedValue)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
putByValCellStringInternal<true, false>(exec, vm, cell, asString(string), JSValue::decode(encodedValue));
}
void JIT_OPERATION operationPutByValCellStringNonStrict(ExecState* exec, JSCell* cell, JSCell* string, EncodedJSValue encodedValue)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
putByValCellStringInternal<false, false>(exec, vm, cell, asString(string), JSValue::decode(encodedValue));
}
void JIT_OPERATION operationPutByValCellSymbolStrict(ExecState* exec, JSCell* cell, JSCell* symbol, EncodedJSValue encodedValue)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
auto propertyName = asSymbol(symbol)->privateName();
putByValCellInternal<true, false>(exec, vm, cell, propertyName, JSValue::decode(encodedValue));
}
void JIT_OPERATION operationPutByValCellSymbolNonStrict(ExecState* exec, JSCell* cell, JSCell* symbol, EncodedJSValue encodedValue)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
auto propertyName = asSymbol(symbol)->privateName();
putByValCellInternal<false, false>(exec, vm, cell, propertyName, JSValue::decode(encodedValue));
}
void JIT_OPERATION operationPutByValBeyondArrayBoundsStrict(ExecState* exec, JSObject* object, int32_t index, EncodedJSValue encodedValue)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
if (index >= 0) {
object->putByIndexInline(exec, index, JSValue::decode(encodedValue), true);
return;
}
PutPropertySlot slot(object, true);
object->methodTable(vm)->put(
object, exec, Identifier::from(vm, index), JSValue::decode(encodedValue), slot);
}
void JIT_OPERATION operationPutByValBeyondArrayBoundsNonStrict(ExecState* exec, JSObject* object, int32_t index, EncodedJSValue encodedValue)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
if (index >= 0) {
object->putByIndexInline(exec, index, JSValue::decode(encodedValue), false);
return;
}
PutPropertySlot slot(object, false);
object->methodTable(vm)->put(
object, exec, Identifier::from(vm, index), JSValue::decode(encodedValue), slot);
}
void JIT_OPERATION operationPutDoubleByValBeyondArrayBoundsStrict(ExecState* exec, JSObject* object, int32_t index, double value)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
JSValue jsValue = JSValue(JSValue::EncodeAsDouble, value);
if (index >= 0) {
object->putByIndexInline(exec, index, jsValue, true);
return;
}
PutPropertySlot slot(object, true);
object->methodTable(vm)->put(
object, exec, Identifier::from(vm, index), jsValue, slot);
}
void JIT_OPERATION operationPutDoubleByValBeyondArrayBoundsNonStrict(ExecState* exec, JSObject* object, int32_t index, double value)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
JSValue jsValue = JSValue(JSValue::EncodeAsDouble, value);
if (index >= 0) {
object->putByIndexInline(exec, index, jsValue, false);
return;
}
PutPropertySlot slot(object, false);
object->methodTable(vm)->put(
object, exec, Identifier::from(vm, index), jsValue, slot);
}
void JIT_OPERATION operationPutDoubleByValDirectBeyondArrayBoundsStrict(ExecState* exec, JSObject* object, int32_t index, double value)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
JSValue jsValue = JSValue(JSValue::EncodeAsDouble, value);
if (index >= 0) {
object->putDirectIndex(exec, index, jsValue, 0, PutDirectIndexShouldThrow);
return;
}
PutPropertySlot slot(object, true);
CommonSlowPaths::putDirectWithReify(vm, exec, object, Identifier::from(vm, index), jsValue, slot);
}
void JIT_OPERATION operationPutDoubleByValDirectBeyondArrayBoundsNonStrict(ExecState* exec, JSObject* object, int32_t index, double value)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
JSValue jsValue = JSValue(JSValue::EncodeAsDouble, value);
if (index >= 0) {
object->putDirectIndex(exec, index, jsValue);
return;
}
PutPropertySlot slot(object, false);
CommonSlowPaths::putDirectWithReify(vm, exec, object, Identifier::from(vm, index), jsValue, slot);
}
void JIT_OPERATION operationPutByValDirectStrict(ExecState* exec, EncodedJSValue encodedBase, EncodedJSValue encodedProperty, EncodedJSValue encodedValue)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
putByValInternal<true, true>(exec, vm, encodedBase, encodedProperty, encodedValue);
}
void JIT_OPERATION operationPutByValDirectNonStrict(ExecState* exec, EncodedJSValue encodedBase, EncodedJSValue encodedProperty, EncodedJSValue encodedValue)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
putByValInternal<false, true>(exec, vm, encodedBase, encodedProperty, encodedValue);
}
void JIT_OPERATION operationPutByValDirectCellStrict(ExecState* exec, JSCell* cell, EncodedJSValue encodedProperty, EncodedJSValue encodedValue)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
putByValInternal<true, true>(exec, vm, JSValue::encode(cell), encodedProperty, encodedValue);
}
void JIT_OPERATION operationPutByValDirectCellNonStrict(ExecState* exec, JSCell* cell, EncodedJSValue encodedProperty, EncodedJSValue encodedValue)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
putByValInternal<false, true>(exec, vm, JSValue::encode(cell), encodedProperty, encodedValue);
}
void JIT_OPERATION operationPutByValDirectCellStringStrict(ExecState* exec, JSCell* cell, JSCell* string, EncodedJSValue encodedValue)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
putByValCellStringInternal<true, true>(exec, vm, cell, asString(string), JSValue::decode(encodedValue));
}
void JIT_OPERATION operationPutByValDirectCellStringNonStrict(ExecState* exec, JSCell* cell, JSCell* string, EncodedJSValue encodedValue)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
putByValCellStringInternal<false, true>(exec, vm, cell, asString(string), JSValue::decode(encodedValue));
}
void JIT_OPERATION operationPutByValDirectCellSymbolStrict(ExecState* exec, JSCell* cell, JSCell* symbol, EncodedJSValue encodedValue)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
auto propertyName = asSymbol(symbol)->privateName();
putByValCellInternal<true, true>(exec, vm, cell, propertyName, JSValue::decode(encodedValue));
}
void JIT_OPERATION operationPutByValDirectCellSymbolNonStrict(ExecState* exec, JSCell* cell, JSCell* symbol, EncodedJSValue encodedValue)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
auto propertyName = asSymbol(symbol)->privateName();
putByValCellInternal<false, true>(exec, vm, cell, propertyName, JSValue::decode(encodedValue));
}
void JIT_OPERATION operationPutByValDirectBeyondArrayBoundsStrict(ExecState* exec, JSObject* object, int32_t index, EncodedJSValue encodedValue)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
if (index >= 0) {
object->putDirectIndex(exec, index, JSValue::decode(encodedValue), 0, PutDirectIndexShouldThrow);
return;
}
PutPropertySlot slot(object, true);
CommonSlowPaths::putDirectWithReify(vm, exec, object, Identifier::from(vm, index), JSValue::decode(encodedValue), slot);
}
void JIT_OPERATION operationPutByValDirectBeyondArrayBoundsNonStrict(ExecState* exec, JSObject* object, int32_t index, EncodedJSValue encodedValue)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
if (index >= 0) {
object->putDirectIndex(exec, index, JSValue::decode(encodedValue));
return;
}
PutPropertySlot slot(object, false);
CommonSlowPaths::putDirectWithReify(vm, exec, object, Identifier::from(vm, index), JSValue::decode(encodedValue), slot);
}
EncodedJSValue JIT_OPERATION operationArrayPush(ExecState* exec, EncodedJSValue encodedValue, JSArray* array)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
array->pushInline(exec, JSValue::decode(encodedValue));
return JSValue::encode(jsNumber(array->length()));
}
EncodedJSValue JIT_OPERATION operationArrayPushDouble(ExecState* exec, double value, JSArray* array)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
array->pushInline(exec, JSValue(JSValue::EncodeAsDouble, value));
return JSValue::encode(jsNumber(array->length()));
}
EncodedJSValue JIT_OPERATION operationArrayPushMultiple(ExecState* exec, JSArray* array, void* buffer, int32_t elementCount)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
auto scope = DECLARE_THROW_SCOPE(vm);
// We assume that multiple JSArray::push calls with ArrayWithInt32/ArrayWithContiguous do not cause JS traps.
// If it can cause any JS interactions, we can call the caller JS function of this function and overwrite the
// content of ScratchBuffer. If the IndexingType is now ArrayWithInt32/ArrayWithContiguous, we can ensure
// that there is no indexed accessors in this object and its prototype chain.
//
// ArrayWithArrayStorage is also OK. It can have indexed accessors. But if you define an indexed accessor, the array's length
// becomes larger than that index. So Array#push never overlaps with this accessor. So accessors are never called unless
// the IndexingType is ArrayWithSlowPutArrayStorage which could have an indexed accessor in a prototype chain.
RELEASE_ASSERT(!shouldUseSlowPut(array->indexingType()));
EncodedJSValue* values = static_cast<EncodedJSValue*>(buffer);
for (int32_t i = 0; i < elementCount; ++i) {
array->pushInline(exec, JSValue::decode(values[i]));
RETURN_IF_EXCEPTION(scope, encodedJSValue());
}
return JSValue::encode(jsNumber(array->length()));
}
EncodedJSValue JIT_OPERATION operationArrayPushDoubleMultiple(ExecState* exec, JSArray* array, void* buffer, int32_t elementCount)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
auto scope = DECLARE_THROW_SCOPE(vm);
// We assume that multiple JSArray::push calls with ArrayWithDouble do not cause JS traps.
// If it can cause any JS interactions, we can call the caller JS function of this function and overwrite the
// content of ScratchBuffer. If the IndexingType is now ArrayWithDouble, we can ensure
// that there is no indexed accessors in this object and its prototype chain.
ASSERT(array->indexingMode() == ArrayWithDouble);
double* values = static_cast<double*>(buffer);
for (int32_t i = 0; i < elementCount; ++i) {
array->pushInline(exec, JSValue(JSValue::EncodeAsDouble, values[i]));
RETURN_IF_EXCEPTION(scope, encodedJSValue());
}
return JSValue::encode(jsNumber(array->length()));
}
EncodedJSValue JIT_OPERATION operationArrayPop(ExecState* exec, JSArray* array)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
return JSValue::encode(array->pop(exec));
}
EncodedJSValue JIT_OPERATION operationArrayPopAndRecoverLength(ExecState* exec, JSArray* array)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
array->butterfly()->setPublicLength(array->butterfly()->publicLength() + 1);
return JSValue::encode(array->pop(exec));
}
EncodedJSValue JIT_OPERATION operationRegExpExecString(ExecState* exec, JSGlobalObject* globalObject, RegExpObject* regExpObject, JSString* argument)
{
SuperSamplerScope superSamplerScope(false);
VM& vm = globalObject->vm();
NativeCallFrameTracer tracer(vm, exec);
return JSValue::encode(regExpObject->execInline(exec, globalObject, argument));
}
EncodedJSValue JIT_OPERATION operationRegExpExec(ExecState* exec, JSGlobalObject* globalObject, RegExpObject* regExpObject, EncodedJSValue encodedArgument)
{
SuperSamplerScope superSamplerScope(false);
VM& vm = globalObject->vm();
NativeCallFrameTracer tracer(vm, exec);
auto scope = DECLARE_THROW_SCOPE(vm);
JSValue argument = JSValue::decode(encodedArgument);
JSString* input = argument.toStringOrNull(exec);
EXCEPTION_ASSERT(!!scope.exception() == !input);
if (!input)
return encodedJSValue();
RELEASE_AND_RETURN(scope, JSValue::encode(regExpObject->execInline(exec, globalObject, input)));
}
EncodedJSValue JIT_OPERATION operationRegExpExecGeneric(ExecState* exec, JSGlobalObject* globalObject, EncodedJSValue encodedBase, EncodedJSValue encodedArgument)
{
SuperSamplerScope superSamplerScope(false);
VM& vm = globalObject->vm();
NativeCallFrameTracer tracer(vm, exec);
auto scope = DECLARE_THROW_SCOPE(vm);
JSValue base = JSValue::decode(encodedBase);
JSValue argument = JSValue::decode(encodedArgument);
auto* regexp = jsDynamicCast<RegExpObject*>(vm, base);
if (UNLIKELY(!regexp))
return throwVMTypeError(exec, scope);
JSString* input = argument.toStringOrNull(exec);
EXCEPTION_ASSERT(!!scope.exception() == !input);
if (!input)
return JSValue::encode(jsUndefined());
RELEASE_AND_RETURN(scope, JSValue::encode(regexp->exec(exec, globalObject, input)));
}
EncodedJSValue JIT_OPERATION operationRegExpExecNonGlobalOrSticky(ExecState* exec, JSGlobalObject* globalObject, RegExp* regExp, JSString* string)
{
SuperSamplerScope superSamplerScope(false);
VM& vm = globalObject->vm();
NativeCallFrameTracer tracer(vm, exec);
auto scope = DECLARE_THROW_SCOPE(vm);
String input = string->value(exec);
RETURN_IF_EXCEPTION(scope, { });
unsigned lastIndex = 0;
MatchResult result;
JSArray* array = createRegExpMatchesArray(vm, globalObject, string, input, regExp, lastIndex, result);
if (!array) {
ASSERT(!scope.exception());
return JSValue::encode(jsNull());
}
RETURN_IF_EXCEPTION(scope, { });
globalObject->regExpGlobalData().recordMatch(vm, globalObject, regExp, string, result);
return JSValue::encode(array);
}
EncodedJSValue JIT_OPERATION operationRegExpMatchFastString(ExecState* exec, JSGlobalObject* globalObject, RegExpObject* regExpObject, JSString* argument)
{
SuperSamplerScope superSamplerScope(false);
VM& vm = globalObject->vm();
NativeCallFrameTracer tracer(vm, exec);
if (!regExpObject->regExp()->global())
return JSValue::encode(regExpObject->execInline(exec, globalObject, argument));
return JSValue::encode(regExpObject->matchGlobal(exec, globalObject, argument));
}
EncodedJSValue JIT_OPERATION operationRegExpMatchFastGlobalString(ExecState* exec, JSGlobalObject* globalObject, RegExp* regExp, JSString* string)
{
SuperSamplerScope superSamplerScope(false);
VM& vm = globalObject->vm();
NativeCallFrameTracer tracer(vm, exec);
auto scope = DECLARE_THROW_SCOPE(vm);
ASSERT(regExp->global());
String s = string->value(exec);
RETURN_IF_EXCEPTION(scope, { });
if (regExp->unicode()) {
unsigned stringLength = s.length();
RELEASE_AND_RETURN(scope, JSValue::encode(collectMatches(
vm, exec, string, s, globalObject, regExp,
[&] (size_t end) -> size_t {
return advanceStringUnicode(s, stringLength, end);
})));
}
RELEASE_AND_RETURN(scope, JSValue::encode(collectMatches(
vm, exec, string, s, globalObject, regExp,
[&] (size_t end) -> size_t {
return end + 1;
})));
}
EncodedJSValue JIT_OPERATION operationParseIntNoRadixGeneric(ExecState* exec, EncodedJSValue value)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
return toStringView(exec, JSValue::decode(value), [&] (StringView view) {
// This version is as if radix was undefined. Hence, undefined.toNumber() === 0.
return parseIntResult(parseInt(view, 0));
});
}
EncodedJSValue JIT_OPERATION operationParseIntStringNoRadix(ExecState* exec, JSString* string)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
auto scope = DECLARE_THROW_SCOPE(vm);
auto viewWithString = string->viewWithUnderlyingString(exec);
RETURN_IF_EXCEPTION(scope, { });
// This version is as if radix was undefined. Hence, undefined.toNumber() === 0.
return parseIntResult(parseInt(viewWithString.view, 0));
}
EncodedJSValue JIT_OPERATION operationParseIntString(ExecState* exec, JSString* string, int32_t radix)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
auto scope = DECLARE_THROW_SCOPE(vm);
auto viewWithString = string->viewWithUnderlyingString(exec);
RETURN_IF_EXCEPTION(scope, { });
return parseIntResult(parseInt(viewWithString.view, radix));
}
EncodedJSValue JIT_OPERATION operationParseIntGeneric(ExecState* exec, EncodedJSValue value, int32_t radix)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
return toStringView(exec, JSValue::decode(value), [&] (StringView view) {
return parseIntResult(parseInt(view, radix));
});
}
size_t JIT_OPERATION operationRegExpTestString(ExecState* exec, JSGlobalObject* globalObject, RegExpObject* regExpObject, JSString* input)
{
SuperSamplerScope superSamplerScope(false);
VM& vm = globalObject->vm();
NativeCallFrameTracer tracer(vm, exec);
return regExpObject->testInline(exec, globalObject, input);
}
size_t JIT_OPERATION operationRegExpTest(ExecState* exec, JSGlobalObject* globalObject, RegExpObject* regExpObject, EncodedJSValue encodedArgument)
{
SuperSamplerScope superSamplerScope(false);
VM& vm = globalObject->vm();
NativeCallFrameTracer tracer(vm, exec);
JSValue argument = JSValue::decode(encodedArgument);
JSString* input = argument.toStringOrNull(exec);
if (!input)
return false;
return regExpObject->testInline(exec, globalObject, input);
}
size_t JIT_OPERATION operationRegExpTestGeneric(ExecState* exec, JSGlobalObject* globalObject, EncodedJSValue encodedBase, EncodedJSValue encodedArgument)
{
SuperSamplerScope superSamplerScope(false);
VM& vm = globalObject->vm();
NativeCallFrameTracer tracer(vm, exec);
auto scope = DECLARE_THROW_SCOPE(vm);
JSValue base = JSValue::decode(encodedBase);
JSValue argument = JSValue::decode(encodedArgument);
auto* regexp = jsDynamicCast<RegExpObject*>(vm, base);
if (UNLIKELY(!regexp)) {
throwTypeError(exec, scope);
return false;
}
JSString* input = argument.toStringOrNull(exec);
EXCEPTION_ASSERT(!!scope.exception() == !input);
if (!input)
return false;
RELEASE_AND_RETURN(scope, regexp->test(exec, globalObject, input));
}
JSCell* JIT_OPERATION operationSubBigInt(ExecState* exec, JSCell* op1, JSCell* op2)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
JSBigInt* leftOperand = jsCast<JSBigInt*>(op1);
JSBigInt* rightOperand = jsCast<JSBigInt*>(op2);
return JSBigInt::sub(exec, leftOperand, rightOperand);
}
JSCell* JIT_OPERATION operationBitNotBigInt(ExecState* exec, JSCell* op1)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
JSBigInt* operand = jsCast<JSBigInt*>(op1);
return JSBigInt::bitwiseNot(exec, operand);
}
JSCell* JIT_OPERATION operationMulBigInt(ExecState* exec, JSCell* op1, JSCell* op2)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
JSBigInt* leftOperand = jsCast<JSBigInt*>(op1);
JSBigInt* rightOperand = jsCast<JSBigInt*>(op2);
return JSBigInt::multiply(exec, leftOperand, rightOperand);
}
JSCell* JIT_OPERATION operationModBigInt(ExecState* exec, JSCell* op1, JSCell* op2)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
JSBigInt* leftOperand = jsCast<JSBigInt*>(op1);
JSBigInt* rightOperand = jsCast<JSBigInt*>(op2);
return JSBigInt::remainder(exec, leftOperand, rightOperand);
}
JSCell* JIT_OPERATION operationDivBigInt(ExecState* exec, JSCell* op1, JSCell* op2)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
JSBigInt* leftOperand = jsCast<JSBigInt*>(op1);
JSBigInt* rightOperand = jsCast<JSBigInt*>(op2);
return JSBigInt::divide(exec, leftOperand, rightOperand);
}
JSCell* JIT_OPERATION operationPowBigInt(ExecState* exec, JSCell* op1, JSCell* op2)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
JSBigInt* leftOperand = jsCast<JSBigInt*>(op1);
JSBigInt* rightOperand = jsCast<JSBigInt*>(op2);
return JSBigInt::exponentiate(exec, leftOperand, rightOperand);
}
JSCell* JIT_OPERATION operationBitAndBigInt(ExecState* exec, JSCell* op1, JSCell* op2)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
JSBigInt* leftOperand = jsCast<JSBigInt*>(op1);
JSBigInt* rightOperand = jsCast<JSBigInt*>(op2);
return JSBigInt::bitwiseAnd(exec, leftOperand, rightOperand);
}
JSCell* JIT_OPERATION operationBitLShiftBigInt(ExecState* exec, JSCell* op1, JSCell* op2)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
JSBigInt* leftOperand = jsCast<JSBigInt*>(op1);
JSBigInt* rightOperand = jsCast<JSBigInt*>(op2);
return JSBigInt::leftShift(exec, leftOperand, rightOperand);
}
JSCell* JIT_OPERATION operationAddBigInt(ExecState* exec, JSCell* op1, JSCell* op2)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
JSBigInt* leftOperand = jsCast<JSBigInt*>(op1);
JSBigInt* rightOperand = jsCast<JSBigInt*>(op2);
return JSBigInt::add(exec, leftOperand, rightOperand);
}
JSCell* JIT_OPERATION operationBitRShiftBigInt(ExecState* exec, JSCell* op1, JSCell* op2)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
JSBigInt* leftOperand = jsCast<JSBigInt*>(op1);
JSBigInt* rightOperand = jsCast<JSBigInt*>(op2);
return JSBigInt::signedRightShift(exec, leftOperand, rightOperand);
}
JSCell* JIT_OPERATION operationBitOrBigInt(ExecState* exec, JSCell* op1, JSCell* op2)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
JSBigInt* leftOperand = jsCast<JSBigInt*>(op1);
JSBigInt* rightOperand = jsCast<JSBigInt*>(op2);
return JSBigInt::bitwiseOr(exec, leftOperand, rightOperand);
}
JSCell* JIT_OPERATION operationBitXorBigInt(ExecState* exec, JSCell* op1, JSCell* op2)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
JSBigInt* leftOperand = jsCast<JSBigInt*>(op1);
JSBigInt* rightOperand = jsCast<JSBigInt*>(op2);
return JSBigInt::bitwiseXor(exec, leftOperand, rightOperand);
}
size_t JIT_OPERATION operationCompareStrictEqCell(ExecState* exec, JSCell* op1, JSCell* op2)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
return JSValue::strictEqualSlowCaseInline(exec, op1, op2);
}
size_t JIT_OPERATION operationSameValue(ExecState* exec, EncodedJSValue arg1, EncodedJSValue arg2)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
return sameValue(exec, JSValue::decode(arg1), JSValue::decode(arg2));
}
EncodedJSValue JIT_OPERATION operationToPrimitive(ExecState* exec, EncodedJSValue value)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
return JSValue::encode(JSValue::decode(value).toPrimitive(exec));
}
EncodedJSValue JIT_OPERATION operationToNumber(ExecState* exec, EncodedJSValue value)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
return JSValue::encode(jsNumber(JSValue::decode(value).toNumber(exec)));
}
EncodedJSValue JIT_OPERATION operationGetByValWithThis(ExecState* exec, EncodedJSValue encodedBase, EncodedJSValue encodedThis, EncodedJSValue encodedSubscript)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
auto scope = DECLARE_THROW_SCOPE(vm);
JSValue baseValue = JSValue::decode(encodedBase);
JSValue thisVal = JSValue::decode(encodedThis);
JSValue subscript = JSValue::decode(encodedSubscript);
if (LIKELY(baseValue.isCell() && subscript.isString())) {
Structure& structure = *baseValue.asCell()->structure(vm);
if (JSCell::canUseFastGetOwnProperty(structure)) {
RefPtr<AtomStringImpl> existingAtomString = asString(subscript)->toExistingAtomString(exec);
RETURN_IF_EXCEPTION(scope, encodedJSValue());
if (existingAtomString) {
if (JSValue result = baseValue.asCell()->fastGetOwnProperty(vm, structure, existingAtomString.get()))
return JSValue::encode(result);
}
}
}
PropertySlot slot(thisVal, PropertySlot::PropertySlot::InternalMethodType::Get);
if (subscript.isUInt32()) {
uint32_t i = subscript.asUInt32();
if (isJSString(baseValue) && asString(baseValue)->canGetIndex(i))
return JSValue::encode(asString(baseValue)->getIndex(exec, i));
RELEASE_AND_RETURN(scope, JSValue::encode(baseValue.get(exec, i, slot)));
}
baseValue.requireObjectCoercible(exec);
RETURN_IF_EXCEPTION(scope, encodedJSValue());
auto property = subscript.toPropertyKey(exec);
RETURN_IF_EXCEPTION(scope, encodedJSValue());
RELEASE_AND_RETURN(scope, JSValue::encode(baseValue.get(exec, property, slot)));
}
void JIT_OPERATION operationPutByIdWithThisStrict(ExecState* exec, EncodedJSValue encodedBase, EncodedJSValue encodedThis, EncodedJSValue encodedValue, UniquedStringImpl* impl)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
putWithThis<true>(exec, encodedBase, encodedThis, encodedValue, Identifier::fromUid(vm, impl));
}
void JIT_OPERATION operationPutByIdWithThis(ExecState* exec, EncodedJSValue encodedBase, EncodedJSValue encodedThis, EncodedJSValue encodedValue, UniquedStringImpl* impl)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
putWithThis<false>(exec, encodedBase, encodedThis, encodedValue, Identifier::fromUid(vm, impl));
}
void JIT_OPERATION operationPutByValWithThisStrict(ExecState* exec, EncodedJSValue encodedBase, EncodedJSValue encodedThis, EncodedJSValue encodedSubscript, EncodedJSValue encodedValue)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
auto scope = DECLARE_THROW_SCOPE(vm);
Identifier property = JSValue::decode(encodedSubscript).toPropertyKey(exec);
RETURN_IF_EXCEPTION(scope, void());
scope.release();
putWithThis<true>(exec, encodedBase, encodedThis, encodedValue, property);
}
void JIT_OPERATION operationPutByValWithThis(ExecState* exec, EncodedJSValue encodedBase, EncodedJSValue encodedThis, EncodedJSValue encodedSubscript, EncodedJSValue encodedValue)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
auto scope = DECLARE_THROW_SCOPE(vm);
Identifier property = JSValue::decode(encodedSubscript).toPropertyKey(exec);
RETURN_IF_EXCEPTION(scope, void());
scope.release();
putWithThis<false>(exec, encodedBase, encodedThis, encodedValue, property);
}
ALWAYS_INLINE static void defineDataProperty(ExecState* exec, VM& vm, JSObject* base, const Identifier& propertyName, JSValue value, int32_t attributes)
{
PropertyDescriptor descriptor = toPropertyDescriptor(value, jsUndefined(), jsUndefined(), DefinePropertyAttributes(attributes));
ASSERT((descriptor.attributes() & PropertyAttribute::Accessor) || (!descriptor.isAccessorDescriptor()));
if (base->methodTable(vm)->defineOwnProperty == JSObject::defineOwnProperty)
JSObject::defineOwnProperty(base, exec, propertyName, descriptor, true);
else
base->methodTable(vm)->defineOwnProperty(base, exec, propertyName, descriptor, true);
}
void JIT_OPERATION operationDefineDataProperty(ExecState* exec, JSObject* base, EncodedJSValue encodedProperty, EncodedJSValue encodedValue, int32_t attributes)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
auto scope = DECLARE_THROW_SCOPE(vm);
Identifier propertyName = JSValue::decode(encodedProperty).toPropertyKey(exec);
RETURN_IF_EXCEPTION(scope, void());
scope.release();
defineDataProperty(exec, vm, base, propertyName, JSValue::decode(encodedValue), attributes);
}
void JIT_OPERATION operationDefineDataPropertyString(ExecState* exec, JSObject* base, JSString* property, EncodedJSValue encodedValue, int32_t attributes)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
auto scope = DECLARE_THROW_SCOPE(vm);
Identifier propertyName = property->toIdentifier(exec);
RETURN_IF_EXCEPTION(scope, void());
scope.release();
defineDataProperty(exec, vm, base, propertyName, JSValue::decode(encodedValue), attributes);
}
void JIT_OPERATION operationDefineDataPropertyStringIdent(ExecState* exec, JSObject* base, UniquedStringImpl* property, EncodedJSValue encodedValue, int32_t attributes)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
defineDataProperty(exec, vm, base, Identifier::fromUid(vm, property), JSValue::decode(encodedValue), attributes);
}
void JIT_OPERATION operationDefineDataPropertySymbol(ExecState* exec, JSObject* base, Symbol* property, EncodedJSValue encodedValue, int32_t attributes)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
defineDataProperty(exec, vm, base, Identifier::fromUid(property->privateName()), JSValue::decode(encodedValue), attributes);
}
ALWAYS_INLINE static void defineAccessorProperty(ExecState* exec, VM& vm, JSObject* base, const Identifier& propertyName, JSObject* getter, JSObject* setter, int32_t attributes)
{
PropertyDescriptor descriptor = toPropertyDescriptor(jsUndefined(), getter, setter, DefinePropertyAttributes(attributes));
ASSERT((descriptor.attributes() & PropertyAttribute::Accessor) || (!descriptor.isAccessorDescriptor()));
if (base->methodTable(vm)->defineOwnProperty == JSObject::defineOwnProperty)
JSObject::defineOwnProperty(base, exec, propertyName, descriptor, true);
else
base->methodTable(vm)->defineOwnProperty(base, exec, propertyName, descriptor, true);
}
void JIT_OPERATION operationDefineAccessorProperty(ExecState* exec, JSObject* base, EncodedJSValue encodedProperty, JSObject* getter, JSObject* setter, int32_t attributes)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
auto scope = DECLARE_THROW_SCOPE(vm);
Identifier propertyName = JSValue::decode(encodedProperty).toPropertyKey(exec);
RETURN_IF_EXCEPTION(scope, void());
defineAccessorProperty(exec, vm, base, propertyName, getter, setter, attributes);
}
void JIT_OPERATION operationDefineAccessorPropertyString(ExecState* exec, JSObject* base, JSString* property, JSObject* getter, JSObject* setter, int32_t attributes)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
auto scope = DECLARE_THROW_SCOPE(vm);
Identifier propertyName = property->toIdentifier(exec);
RETURN_IF_EXCEPTION(scope, void());
defineAccessorProperty(exec, vm, base, propertyName, getter, setter, attributes);
}
void JIT_OPERATION operationDefineAccessorPropertyStringIdent(ExecState* exec, JSObject* base, UniquedStringImpl* property, JSObject* getter, JSObject* setter, int32_t attributes)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
defineAccessorProperty(exec, vm, base, Identifier::fromUid(vm, property), getter, setter, attributes);
}
void JIT_OPERATION operationDefineAccessorPropertySymbol(ExecState* exec, JSObject* base, Symbol* property, JSObject* getter, JSObject* setter, int32_t attributes)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
defineAccessorProperty(exec, vm, base, Identifier::fromUid(property->privateName()), getter, setter, attributes);
}
char* JIT_OPERATION operationNewArray(ExecState* exec, Structure* arrayStructure, void* buffer, size_t size)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
return bitwise_cast<char*>(constructArray(exec, arrayStructure, static_cast<JSValue*>(buffer), size));
}
char* JIT_OPERATION operationNewEmptyArray(ExecState* exec, Structure* arrayStructure)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
return bitwise_cast<char*>(JSArray::create(vm, arrayStructure));
}
char* JIT_OPERATION operationNewArrayWithSize(ExecState* exec, Structure* arrayStructure, int32_t size, Butterfly* butterfly)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
auto scope = DECLARE_THROW_SCOPE(vm);
if (UNLIKELY(size < 0))
return bitwise_cast<char*>(throwException(exec, scope, createRangeError(exec, "Array size is not a small enough positive integer."_s)));
JSArray* result;
if (butterfly)
result = JSArray::createWithButterfly(vm, nullptr, arrayStructure, butterfly);
else
result = JSArray::create(vm, arrayStructure, size);
return bitwise_cast<char*>(result);
}
char* JIT_OPERATION operationNewArrayWithSizeAndHint(ExecState* exec, Structure* arrayStructure, int32_t size, int32_t vectorLengthHint, Butterfly* butterfly)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
auto scope = DECLARE_THROW_SCOPE(vm);
if (UNLIKELY(size < 0))
return bitwise_cast<char*>(throwException(exec, scope, createRangeError(exec, "Array size is not a small enough positive integer."_s)));
JSArray* result;
if (butterfly)
result = JSArray::createWithButterfly(vm, nullptr, arrayStructure, butterfly);
else {
result = JSArray::tryCreate(vm, arrayStructure, size, vectorLengthHint);
RELEASE_ASSERT(result);
}
return bitwise_cast<char*>(result);
}
JSCell* JIT_OPERATION operationNewArrayBuffer(ExecState* exec, Structure* arrayStructure, JSCell* immutableButterflyCell)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
ASSERT(!arrayStructure->outOfLineCapacity());
auto* immutableButterfly = jsCast<JSImmutableButterfly*>(immutableButterflyCell);
ASSERT(arrayStructure->indexingMode() == immutableButterfly->indexingMode() || hasAnyArrayStorage(arrayStructure->indexingMode()));
auto* result = CommonSlowPaths::allocateNewArrayBuffer(vm, arrayStructure, immutableButterfly);
ASSERT(result->indexingMode() == result->structure(vm)->indexingMode());
ASSERT(result->structure(vm) == arrayStructure);
return result;
}
char* JIT_OPERATION operationNewInt8ArrayWithSize(
ExecState* exec, Structure* structure, int32_t length, char* vector)
{
return newTypedArrayWithSize<JSInt8Array>(exec, structure, length, vector);
}
char* JIT_OPERATION operationNewInt8ArrayWithOneArgument(
ExecState* exec, Structure* structure, EncodedJSValue encodedValue)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
return reinterpret_cast<char*>(constructGenericTypedArrayViewWithArguments<JSInt8Array>(exec, structure, encodedValue, 0, WTF::nullopt));
}
char* JIT_OPERATION operationNewInt16ArrayWithSize(
ExecState* exec, Structure* structure, int32_t length, char* vector)
{
return newTypedArrayWithSize<JSInt16Array>(exec, structure, length, vector);
}
char* JIT_OPERATION operationNewInt16ArrayWithOneArgument(
ExecState* exec, Structure* structure, EncodedJSValue encodedValue)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
return reinterpret_cast<char*>(constructGenericTypedArrayViewWithArguments<JSInt16Array>(exec, structure, encodedValue, 0, WTF::nullopt));
}
char* JIT_OPERATION operationNewInt32ArrayWithSize(
ExecState* exec, Structure* structure, int32_t length, char* vector)
{
return newTypedArrayWithSize<JSInt32Array>(exec, structure, length, vector);
}
char* JIT_OPERATION operationNewInt32ArrayWithOneArgument(
ExecState* exec, Structure* structure, EncodedJSValue encodedValue)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
return reinterpret_cast<char*>(constructGenericTypedArrayViewWithArguments<JSInt32Array>(exec, structure, encodedValue, 0, WTF::nullopt));
}
char* JIT_OPERATION operationNewUint8ArrayWithSize(
ExecState* exec, Structure* structure, int32_t length, char* vector)
{
return newTypedArrayWithSize<JSUint8Array>(exec, structure, length, vector);
}
char* JIT_OPERATION operationNewUint8ArrayWithOneArgument(
ExecState* exec, Structure* structure, EncodedJSValue encodedValue)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
return reinterpret_cast<char*>(constructGenericTypedArrayViewWithArguments<JSUint8Array>(exec, structure, encodedValue, 0, WTF::nullopt));
}
char* JIT_OPERATION operationNewUint8ClampedArrayWithSize(
ExecState* exec, Structure* structure, int32_t length, char* vector)
{
return newTypedArrayWithSize<JSUint8ClampedArray>(exec, structure, length, vector);
}
char* JIT_OPERATION operationNewUint8ClampedArrayWithOneArgument(
ExecState* exec, Structure* structure, EncodedJSValue encodedValue)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
return reinterpret_cast<char*>(constructGenericTypedArrayViewWithArguments<JSUint8ClampedArray>(exec, structure, encodedValue, 0, WTF::nullopt));
}
char* JIT_OPERATION operationNewUint16ArrayWithSize(
ExecState* exec, Structure* structure, int32_t length, char* vector)
{
return newTypedArrayWithSize<JSUint16Array>(exec, structure, length, vector);
}
char* JIT_OPERATION operationNewUint16ArrayWithOneArgument(
ExecState* exec, Structure* structure, EncodedJSValue encodedValue)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
return reinterpret_cast<char*>(constructGenericTypedArrayViewWithArguments<JSUint16Array>(exec, structure, encodedValue, 0, WTF::nullopt));
}
char* JIT_OPERATION operationNewUint32ArrayWithSize(
ExecState* exec, Structure* structure, int32_t length, char* vector)
{
return newTypedArrayWithSize<JSUint32Array>(exec, structure, length, vector);
}
char* JIT_OPERATION operationNewUint32ArrayWithOneArgument(
ExecState* exec, Structure* structure, EncodedJSValue encodedValue)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
return reinterpret_cast<char*>(constructGenericTypedArrayViewWithArguments<JSUint32Array>(exec, structure, encodedValue, 0, WTF::nullopt));
}
char* JIT_OPERATION operationNewFloat32ArrayWithSize(
ExecState* exec, Structure* structure, int32_t length, char* vector)
{
return newTypedArrayWithSize<JSFloat32Array>(exec, structure, length, vector);
}
char* JIT_OPERATION operationNewFloat32ArrayWithOneArgument(
ExecState* exec, Structure* structure, EncodedJSValue encodedValue)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
return reinterpret_cast<char*>(constructGenericTypedArrayViewWithArguments<JSFloat32Array>(exec, structure, encodedValue, 0, WTF::nullopt));
}
char* JIT_OPERATION operationNewFloat64ArrayWithSize(
ExecState* exec, Structure* structure, int32_t length, char* vector)
{
return newTypedArrayWithSize<JSFloat64Array>(exec, structure, length, vector);
}
char* JIT_OPERATION operationNewFloat64ArrayWithOneArgument(
ExecState* exec, Structure* structure, EncodedJSValue encodedValue)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
return reinterpret_cast<char*>(constructGenericTypedArrayViewWithArguments<JSFloat64Array>(exec, structure, encodedValue, 0, WTF::nullopt));
}
JSCell* JIT_OPERATION operationCreateActivationDirect(ExecState* exec, Structure* structure, JSScope* scope, SymbolTable* table, EncodedJSValue initialValueEncoded)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
JSValue initialValue = JSValue::decode(initialValueEncoded);
ASSERT(initialValue == jsUndefined() || initialValue == jsTDZValue());
return JSLexicalEnvironment::create(vm, structure, scope, table, initialValue);
}
JSCell* JIT_OPERATION operationCreateDirectArguments(ExecState* exec, Structure* structure, uint32_t length, uint32_t minCapacity)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
DirectArguments* result = DirectArguments::create(
vm, structure, length, std::max(length, minCapacity));
// The caller will store to this object without barriers. Most likely, at this point, this is
// still a young object and so no barriers are needed. But it's good to be careful anyway,
// since the GC should be allowed to do crazy (like pretenuring, for example).
vm.heap.writeBarrier(result);
return result;
}
JSCell* JIT_OPERATION operationCreateScopedArguments(ExecState* exec, Structure* structure, Register* argumentStart, uint32_t length, JSFunction* callee, JSLexicalEnvironment* scope)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
// We could pass the ScopedArgumentsTable* as an argument. We currently don't because I
// didn't feel like changing the max number of arguments for a slow path call from 6 to 7.
ScopedArgumentsTable* table = scope->symbolTable()->arguments();
return ScopedArguments::createByCopyingFrom(
vm, structure, argumentStart, length, callee, table, scope);
}
JSCell* JIT_OPERATION operationCreateClonedArguments(ExecState* exec, Structure* structure, Register* argumentStart, uint32_t length, JSFunction* callee)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
return ClonedArguments::createByCopyingFrom(
exec, structure, argumentStart, length, callee);
}
JSCell* JIT_OPERATION operationCreateDirectArgumentsDuringExit(ExecState* exec, InlineCallFrame* inlineCallFrame, JSFunction* callee, uint32_t argumentCount)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
DeferGCForAWhile deferGC(vm.heap);
CodeBlock* codeBlock;
if (inlineCallFrame)
codeBlock = baselineCodeBlockForInlineCallFrame(inlineCallFrame);
else
codeBlock = exec->codeBlock();
unsigned length = argumentCount - 1;
unsigned capacity = std::max(length, static_cast<unsigned>(codeBlock->numParameters() - 1));
DirectArguments* result = DirectArguments::create(
vm, codeBlock->globalObject()->directArgumentsStructure(), length, capacity);
result->setCallee(vm, callee);
Register* arguments =
exec->registers() + (inlineCallFrame ? inlineCallFrame->stackOffset : 0) +
CallFrame::argumentOffset(0);
for (unsigned i = length; i--;)
result->setIndexQuickly(vm, i, arguments[i].jsValue());
return result;
}
JSCell* JIT_OPERATION operationCreateClonedArgumentsDuringExit(ExecState* exec, InlineCallFrame* inlineCallFrame, JSFunction* callee, uint32_t argumentCount)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
DeferGCForAWhile deferGC(vm.heap);
CodeBlock* codeBlock;
if (inlineCallFrame)
codeBlock = baselineCodeBlockForInlineCallFrame(inlineCallFrame);
else
codeBlock = exec->codeBlock();
unsigned length = argumentCount - 1;
ClonedArguments* result = ClonedArguments::createEmpty(
vm, codeBlock->globalObject()->clonedArgumentsStructure(), callee, length);
Register* arguments =
exec->registers() + (inlineCallFrame ? inlineCallFrame->stackOffset : 0) +
CallFrame::argumentOffset(0);
for (unsigned i = length; i--;)
result->putDirectIndex(exec, i, arguments[i].jsValue());
return result;
}
JSCell* JIT_OPERATION operationCreateRest(ExecState* exec, Register* argumentStart, unsigned numberOfParamsToSkip, unsigned arraySize)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
JSGlobalObject* globalObject = exec->lexicalGlobalObject();
Structure* structure = globalObject->restParameterStructure();
static_assert(sizeof(Register) == sizeof(JSValue), "This is a strong assumption here.");
JSValue* argumentsToCopyRegion = bitwise_cast<JSValue*>(argumentStart) + numberOfParamsToSkip;
return constructArray(exec, structure, argumentsToCopyRegion, arraySize);
}
size_t JIT_OPERATION operationObjectIsObject(ExecState* exec, JSGlobalObject* globalObject, JSCell* object)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
ASSERT(jsDynamicCast<JSObject*>(vm, object));
if (object->structure(vm)->masqueradesAsUndefined(globalObject))
return false;
if (object->isFunction(vm))
return false;
return true;
}
size_t JIT_OPERATION operationObjectIsFunction(ExecState* exec, JSGlobalObject* globalObject, JSCell* object)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
ASSERT(jsDynamicCast<JSObject*>(vm, object));
if (object->structure(vm)->masqueradesAsUndefined(globalObject))
return false;
if (object->isFunction(vm))
return true;
return false;
}
JSCell* JIT_OPERATION operationTypeOfObject(ExecState* exec, JSGlobalObject* globalObject, JSCell* object)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
ASSERT(jsDynamicCast<JSObject*>(vm, object));
if (object->structure(vm)->masqueradesAsUndefined(globalObject))
return vm.smallStrings.undefinedString();
if (object->isFunction(vm))
return vm.smallStrings.functionString();
return vm.smallStrings.objectString();
}
int32_t JIT_OPERATION operationTypeOfObjectAsTypeofType(ExecState* exec, JSGlobalObject* globalObject, JSCell* object)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
ASSERT(jsDynamicCast<JSObject*>(vm, object));
if (object->structure(vm)->masqueradesAsUndefined(globalObject))
return static_cast<int32_t>(TypeofType::Undefined);
if (object->isFunction(vm))
return static_cast<int32_t>(TypeofType::Function);
return static_cast<int32_t>(TypeofType::Object);
}
char* JIT_OPERATION operationAllocateSimplePropertyStorageWithInitialCapacity(ExecState* exec)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
return reinterpret_cast<char*>(
Butterfly::createUninitialized(vm, 0, 0, initialOutOfLineCapacity, false, 0));
}
char* JIT_OPERATION operationAllocateSimplePropertyStorage(ExecState* exec, size_t newSize)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
return reinterpret_cast<char*>(
Butterfly::createUninitialized(vm, 0, 0, newSize, false, 0));
}
char* JIT_OPERATION operationAllocateComplexPropertyStorageWithInitialCapacity(ExecState* exec, JSObject* object)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
ASSERT(!object->structure(vm)->outOfLineCapacity());
return reinterpret_cast<char*>(
object->allocateMoreOutOfLineStorage(vm, 0, initialOutOfLineCapacity));
}
char* JIT_OPERATION operationAllocateComplexPropertyStorage(ExecState* exec, JSObject* object, size_t newSize)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
return reinterpret_cast<char*>(
object->allocateMoreOutOfLineStorage(vm, object->structure(vm)->outOfLineCapacity(), newSize));
}
char* JIT_OPERATION operationEnsureInt32(ExecState* exec, JSCell* cell)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
if (!cell->isObject())
return 0;
auto* result = reinterpret_cast<char*>(asObject(cell)->tryMakeWritableInt32(vm).data());
ASSERT((!isCopyOnWrite(asObject(cell)->indexingMode()) && hasInt32(cell->indexingMode())) || !result);
return result;
}
char* JIT_OPERATION operationEnsureDouble(ExecState* exec, JSCell* cell)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
if (!cell->isObject())
return 0;
auto* result = reinterpret_cast<char*>(asObject(cell)->tryMakeWritableDouble(vm).data());
ASSERT((!isCopyOnWrite(asObject(cell)->indexingMode()) && hasDouble(cell->indexingMode())) || !result);
return result;
}
char* JIT_OPERATION operationEnsureContiguous(ExecState* exec, JSCell* cell)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
if (!cell->isObject())
return 0;
auto* result = reinterpret_cast<char*>(asObject(cell)->tryMakeWritableContiguous(vm).data());
ASSERT((!isCopyOnWrite(asObject(cell)->indexingMode()) && hasContiguous(cell->indexingMode())) || !result);
return result;
}
char* JIT_OPERATION operationEnsureArrayStorage(ExecState* exec, JSCell* cell)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
if (!cell->isObject())
return 0;
auto* result = reinterpret_cast<char*>(asObject(cell)->ensureArrayStorage(vm));
ASSERT((!isCopyOnWrite(asObject(cell)->indexingMode()) && hasAnyArrayStorage(cell->indexingMode())) || !result);
return result;
}
EncodedJSValue JIT_OPERATION operationHasGenericProperty(ExecState* exec, EncodedJSValue encodedBaseValue, JSCell* property)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
auto scope = DECLARE_THROW_SCOPE(vm);
JSValue baseValue = JSValue::decode(encodedBaseValue);
if (baseValue.isUndefinedOrNull())
return JSValue::encode(jsBoolean(false));
JSObject* base = baseValue.toObject(exec);
ASSERT(!scope.exception() || !base);
if (!base)
return JSValue::encode(JSValue());
auto propertyName = asString(property)->toIdentifier(exec);
RETURN_IF_EXCEPTION(scope, { });
RELEASE_AND_RETURN(scope, JSValue::encode(jsBoolean(base->hasPropertyGeneric(exec, propertyName, PropertySlot::InternalMethodType::GetOwnProperty))));
}
size_t JIT_OPERATION operationHasIndexedPropertyByInt(ExecState* exec, JSCell* baseCell, int32_t subscript, int32_t internalMethodType)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
JSObject* object = baseCell->toObject(exec, exec->lexicalGlobalObject());
if (UNLIKELY(subscript < 0)) {
// Go the slowest way possible because negative indices don't use indexed storage.
return object->hasPropertyGeneric(exec, Identifier::from(vm, subscript), static_cast<PropertySlot::InternalMethodType>(internalMethodType));
}
return object->hasPropertyGeneric(exec, subscript, static_cast<PropertySlot::InternalMethodType>(internalMethodType));
}
JSCell* JIT_OPERATION operationGetPropertyEnumerator(ExecState* exec, EncodedJSValue encodedBase)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
auto scope = DECLARE_THROW_SCOPE(vm);
JSValue base = JSValue::decode(encodedBase);
if (base.isUndefinedOrNull())
return vm.emptyPropertyNameEnumerator();
JSObject* baseObject = base.toObject(exec);
RETURN_IF_EXCEPTION(scope, { });
RELEASE_AND_RETURN(scope, propertyNameEnumerator(exec, baseObject));
}
JSCell* JIT_OPERATION operationGetPropertyEnumeratorCell(ExecState* exec, JSCell* cell)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
auto scope = DECLARE_THROW_SCOPE(vm);
JSObject* base = cell->toObject(exec, exec->lexicalGlobalObject());
RETURN_IF_EXCEPTION(scope, { });
RELEASE_AND_RETURN(scope, propertyNameEnumerator(exec, base));
}
JSCell* JIT_OPERATION operationToIndexString(ExecState* exec, int32_t index)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
return jsString(vm, Identifier::from(vm, index).string());
}
JSCell* JIT_OPERATION operationNewRegexpWithLastIndex(ExecState* exec, JSCell* regexpPtr, EncodedJSValue encodedLastIndex)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
RegExp* regexp = static_cast<RegExp*>(regexpPtr);
ASSERT(regexp->isValid());
return RegExpObject::create(vm, exec->lexicalGlobalObject()->regExpStructure(), regexp, JSValue::decode(encodedLastIndex));
}
StringImpl* JIT_OPERATION operationResolveRope(ExecState* exec, JSString* string)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
return string->value(exec).impl();
}
JSString* JIT_OPERATION operationStringValueOf(ExecState* exec, EncodedJSValue encodedArgument)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
auto scope = DECLARE_THROW_SCOPE(vm);
JSValue argument = JSValue::decode(encodedArgument);
if (argument.isString())
return asString(argument);
if (auto* stringObject = jsDynamicCast<StringObject*>(vm, argument))
return stringObject->internalValue();
throwVMTypeError(exec, scope);
return nullptr;
}
JSCell* JIT_OPERATION operationStringSubstr(ExecState* exec, JSCell* cell, int32_t from, int32_t span)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
return jsSubstring(vm, exec, jsCast<JSString*>(cell), from, span);
}
JSCell* JIT_OPERATION operationStringSlice(ExecState* exec, JSCell* cell, int32_t start, int32_t end)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
JSString* string = asString(cell);
static_assert(static_cast<uint64_t>(JSString::MaxLength) <= static_cast<uint64_t>(std::numeric_limits<int32_t>::max()), "");
return stringSlice(exec, vm, string, string->length(), start, end);
}
JSString* JIT_OPERATION operationToLowerCase(ExecState* exec, JSString* string, uint32_t failingIndex)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
auto scope = DECLARE_THROW_SCOPE(vm);
String inputString = string->value(exec);
RETURN_IF_EXCEPTION(scope, nullptr);
if (!inputString.length())
return vm.smallStrings.emptyString();
String lowercasedString = inputString.is8Bit() ? inputString.convertToLowercaseWithoutLocaleStartingAtFailingIndex8Bit(failingIndex) : inputString.convertToLowercaseWithoutLocale();
if (lowercasedString.impl() == inputString.impl())
return string;
RELEASE_AND_RETURN(scope, jsString(vm, lowercasedString));
}
char* JIT_OPERATION operationInt32ToString(ExecState* exec, int32_t value, int32_t radix)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
auto scope = DECLARE_THROW_SCOPE(vm);
if (radix < 2 || radix > 36) {
throwVMError(exec, scope, createRangeError(exec, "toString() radix argument must be between 2 and 36"_s));
return nullptr;
}
return reinterpret_cast<char*>(int32ToString(vm, value, radix));
}
char* JIT_OPERATION operationInt52ToString(ExecState* exec, int64_t value, int32_t radix)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
auto scope = DECLARE_THROW_SCOPE(vm);
if (radix < 2 || radix > 36) {
throwVMError(exec, scope, createRangeError(exec, "toString() radix argument must be between 2 and 36"_s));
return nullptr;
}
return reinterpret_cast<char*>(int52ToString(vm, value, radix));
}
char* JIT_OPERATION operationDoubleToString(ExecState* exec, double value, int32_t radix)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
auto scope = DECLARE_THROW_SCOPE(vm);
if (radix < 2 || radix > 36) {
throwVMError(exec, scope, createRangeError(exec, "toString() radix argument must be between 2 and 36"_s));
return nullptr;
}
return reinterpret_cast<char*>(numberToString(vm, value, radix));
}
char* JIT_OPERATION operationInt32ToStringWithValidRadix(ExecState* exec, int32_t value, int32_t radix)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
return reinterpret_cast<char*>(int32ToString(vm, value, radix));
}
char* JIT_OPERATION operationInt52ToStringWithValidRadix(ExecState* exec, int64_t value, int32_t radix)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
return reinterpret_cast<char*>(int52ToString(vm, value, radix));
}
char* JIT_OPERATION operationDoubleToStringWithValidRadix(ExecState* exec, double value, int32_t radix)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
return reinterpret_cast<char*>(numberToString(vm, value, radix));
}
JSString* JIT_OPERATION operationSingleCharacterString(ExecState* exec, int32_t character)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
return jsSingleCharacterString(vm, static_cast<UChar>(character));
}
Symbol* JIT_OPERATION operationNewSymbol(ExecState* exec)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
return Symbol::create(vm);
}
Symbol* JIT_OPERATION operationNewSymbolWithDescription(ExecState* exec, JSString* description)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
auto scope = DECLARE_THROW_SCOPE(vm);
String string = description->value(exec);
RETURN_IF_EXCEPTION(scope, nullptr);
return Symbol::createWithDescription(vm, string);
}
JSCell* JIT_OPERATION operationNewStringObject(ExecState* exec, JSString* string, Structure* structure)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
return StringObject::create(vm, structure, string);
}
JSString* JIT_OPERATION operationToStringOnCell(ExecState* exec, JSCell* cell)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
return JSValue(cell).toString(exec);
}
JSString* JIT_OPERATION operationToString(ExecState* exec, EncodedJSValue value)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
return JSValue::decode(value).toString(exec);
}
JSString* JIT_OPERATION operationCallStringConstructorOnCell(ExecState* exec, JSCell* cell)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
return stringConstructor(exec, cell);
}
JSString* JIT_OPERATION operationCallStringConstructor(ExecState* exec, EncodedJSValue value)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
return stringConstructor(exec, JSValue::decode(value));
}
JSString* JIT_OPERATION operationMakeRope2(ExecState* exec, JSString* left, JSString* right)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
return jsString(exec, left, right);
}
JSString* JIT_OPERATION operationMakeRope3(ExecState* exec, JSString* a, JSString* b, JSString* c)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
return jsString(exec, a, b, c);
}
JSString* JIT_OPERATION operationStrCat2(ExecState* exec, EncodedJSValue a, EncodedJSValue b)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
auto scope = DECLARE_THROW_SCOPE(vm);
ASSERT(!JSValue::decode(a).isSymbol());
ASSERT(!JSValue::decode(b).isSymbol());
JSString* str1 = JSValue::decode(a).toString(exec);
scope.assertNoException(); // Impossible, since we must have been given non-Symbol primitives.
JSString* str2 = JSValue::decode(b).toString(exec);
scope.assertNoException();
RELEASE_AND_RETURN(scope, jsString(exec, str1, str2));
}
JSString* JIT_OPERATION operationStrCat3(ExecState* exec, EncodedJSValue a, EncodedJSValue b, EncodedJSValue c)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
auto scope = DECLARE_THROW_SCOPE(vm);
ASSERT(!JSValue::decode(a).isSymbol());
ASSERT(!JSValue::decode(b).isSymbol());
ASSERT(!JSValue::decode(c).isSymbol());
JSString* str1 = JSValue::decode(a).toString(exec);
scope.assertNoException(); // Impossible, since we must have been given non-Symbol primitives.
JSString* str2 = JSValue::decode(b).toString(exec);
scope.assertNoException();
JSString* str3 = JSValue::decode(c).toString(exec);
scope.assertNoException();
RELEASE_AND_RETURN(scope, jsString(exec, str1, str2, str3));
}
char* JIT_OPERATION operationFindSwitchImmTargetForDouble(
ExecState* exec, EncodedJSValue encodedValue, size_t tableIndex)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
CodeBlock* codeBlock = exec->codeBlock();
SimpleJumpTable& table = codeBlock->switchJumpTable(tableIndex);
JSValue value = JSValue::decode(encodedValue);
ASSERT(value.isDouble());
double asDouble = value.asDouble();
int32_t asInt32 = static_cast<int32_t>(asDouble);
if (asDouble == asInt32)
return table.ctiForValue(asInt32).executableAddress<char*>();
return table.ctiDefault.executableAddress<char*>();
}
char* JIT_OPERATION operationSwitchString(ExecState* exec, size_t tableIndex, JSString* string)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
auto throwScope = DECLARE_THROW_SCOPE(vm);
StringImpl* strImpl = string->value(exec).impl();
RETURN_IF_EXCEPTION(throwScope, nullptr);
return exec->codeBlock()->stringSwitchJumpTable(tableIndex).ctiForValue(strImpl).executableAddress<char*>();
}
int32_t JIT_OPERATION operationSwitchStringAndGetBranchOffset(ExecState* exec, size_t tableIndex, JSString* string)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
auto throwScope = DECLARE_THROW_SCOPE(vm);
StringImpl* strImpl = string->value(exec).impl();
RETURN_IF_EXCEPTION(throwScope, 0);
return exec->codeBlock()->stringSwitchJumpTable(tableIndex).offsetForValue(strImpl, std::numeric_limits<int32_t>::min());
}
uintptr_t JIT_OPERATION operationCompareStringImplLess(StringImpl* a, StringImpl* b)
{
return codePointCompare(a, b) < 0;
}
uintptr_t JIT_OPERATION operationCompareStringImplLessEq(StringImpl* a, StringImpl* b)
{
return codePointCompare(a, b) <= 0;
}
uintptr_t JIT_OPERATION operationCompareStringImplGreater(StringImpl* a, StringImpl* b)
{
return codePointCompare(a, b) > 0;
}
uintptr_t JIT_OPERATION operationCompareStringImplGreaterEq(StringImpl* a, StringImpl* b)
{
return codePointCompare(a, b) >= 0;
}
uintptr_t JIT_OPERATION operationCompareStringLess(ExecState* exec, JSString* a, JSString* b)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
return codePointCompareLessThan(asString(a)->value(exec), asString(b)->value(exec));
}
uintptr_t JIT_OPERATION operationCompareStringLessEq(ExecState* exec, JSString* a, JSString* b)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
return !codePointCompareLessThan(asString(b)->value(exec), asString(a)->value(exec));
}
uintptr_t JIT_OPERATION operationCompareStringGreater(ExecState* exec, JSString* a, JSString* b)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
return codePointCompareLessThan(asString(b)->value(exec), asString(a)->value(exec));
}
uintptr_t JIT_OPERATION operationCompareStringGreaterEq(ExecState* exec, JSString* a, JSString* b)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
return !codePointCompareLessThan(asString(a)->value(exec), asString(b)->value(exec));
}
void JIT_OPERATION operationNotifyWrite(ExecState* exec, WatchpointSet* set)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
set->touch(vm, "Executed NotifyWrite");
}
void JIT_OPERATION operationThrowStackOverflowForVarargs(ExecState* exec)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
auto scope = DECLARE_THROW_SCOPE(vm);
throwStackOverflowError(exec, scope);
}
int32_t JIT_OPERATION operationSizeOfVarargs(ExecState* exec, EncodedJSValue encodedArguments, uint32_t firstVarArgOffset)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
JSValue arguments = JSValue::decode(encodedArguments);
return sizeOfVarargs(exec, arguments, firstVarArgOffset);
}
int32_t JIT_OPERATION operationHasOwnProperty(ExecState* exec, JSObject* thisObject, EncodedJSValue encodedKey)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
auto scope = DECLARE_THROW_SCOPE(vm);
JSValue key = JSValue::decode(encodedKey);
Identifier propertyName = key.toPropertyKey(exec);
RETURN_IF_EXCEPTION(scope, false);
PropertySlot slot(thisObject, PropertySlot::InternalMethodType::GetOwnProperty);
bool result = thisObject->hasOwnProperty(exec, propertyName.impl(), slot);
RETURN_IF_EXCEPTION(scope, false);
HasOwnPropertyCache* hasOwnPropertyCache = vm.hasOwnPropertyCache();
ASSERT(hasOwnPropertyCache);
hasOwnPropertyCache->tryAdd(vm, slot, thisObject, propertyName.impl(), result);
return result;
}
int32_t JIT_OPERATION operationNumberIsInteger(ExecState* exec, EncodedJSValue value)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
return NumberConstructor::isIntegerImpl(JSValue::decode(value));
}
int32_t JIT_OPERATION operationArrayIndexOfString(ExecState* exec, Butterfly* butterfly, JSString* searchElement, int32_t index)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
auto scope = DECLARE_THROW_SCOPE(vm);
int32_t length = butterfly->publicLength();
auto data = butterfly->contiguous().data();
for (; index < length; ++index) {
JSValue value = data[index].get();
if (!value || !value.isString())
continue;
auto* string = asString(value);
if (string == searchElement)
return index;
if (string->equal(exec, searchElement)) {
scope.assertNoException();
return index;
}
RETURN_IF_EXCEPTION(scope, { });
}
return -1;
}
int32_t JIT_OPERATION operationArrayIndexOfValueInt32OrContiguous(ExecState* exec, Butterfly* butterfly, EncodedJSValue encodedValue, int32_t index)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
auto scope = DECLARE_THROW_SCOPE(vm);
JSValue searchElement = JSValue::decode(encodedValue);
int32_t length = butterfly->publicLength();
auto data = butterfly->contiguous().data();
for (; index < length; ++index) {
JSValue value = data[index].get();
if (!value)
continue;
bool isEqual = JSValue::strictEqual(exec, searchElement, value);
RETURN_IF_EXCEPTION(scope, { });
if (isEqual)
return index;
}
return -1;
}
int32_t JIT_OPERATION operationArrayIndexOfValueDouble(ExecState* exec, Butterfly* butterfly, EncodedJSValue encodedValue, int32_t index)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
JSValue searchElement = JSValue::decode(encodedValue);
if (!searchElement.isNumber())
return -1;
double number = searchElement.asNumber();
int32_t length = butterfly->publicLength();
const double* data = butterfly->contiguousDouble().data();
for (; index < length; ++index) {
// This comparison ignores NaN.
if (data[index] == number)
return index;
}
return -1;
}
void JIT_OPERATION operationLoadVarargs(ExecState* exec, int32_t firstElementDest, EncodedJSValue encodedArguments, uint32_t offset, uint32_t length, uint32_t mandatoryMinimum)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
JSValue arguments = JSValue::decode(encodedArguments);
loadVarargs(exec, VirtualRegister(firstElementDest), arguments, offset, length);
for (uint32_t i = length; i < mandatoryMinimum; ++i)
exec->r(firstElementDest + i) = jsUndefined();
}
double JIT_OPERATION operationFModOnInts(int32_t a, int32_t b)
{
return fmod(a, b);
}
#if USE(JSVALUE32_64)
double JIT_OPERATION operationRandom(JSGlobalObject* globalObject)
{
return globalObject->weakRandomNumber();
}
#endif
JSCell* JIT_OPERATION operationStringFromCharCode(ExecState* exec, int32_t op1)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
return JSC::stringFromCharCode(exec, op1);
}
EncodedJSValue JIT_OPERATION operationStringFromCharCodeUntyped(ExecState* exec, EncodedJSValue encodedValue)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
JSValue charValue = JSValue::decode(encodedValue);
int32_t chInt = charValue.toUInt32(exec);
return JSValue::encode(JSC::stringFromCharCode(exec, chInt));
}
int64_t JIT_OPERATION operationConvertBoxedDoubleToInt52(EncodedJSValue encodedValue)
{
JSValue value = JSValue::decode(encodedValue);
if (!value.isDouble())
return JSValue::notInt52;
return tryConvertToInt52(value.asDouble());
}
int64_t JIT_OPERATION operationConvertDoubleToInt52(double value)
{
return tryConvertToInt52(value);
}
char* JIT_OPERATION operationNewRawObject(ExecState* exec, Structure* structure, int32_t length, Butterfly* butterfly)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
if (!butterfly
&& (structure->outOfLineCapacity() || hasIndexedProperties(structure->indexingType()))) {
IndexingHeader header;
header.setVectorLength(length);
header.setPublicLength(0);
butterfly = Butterfly::create(
vm, nullptr, 0, structure->outOfLineCapacity(),
hasIndexedProperties(structure->indexingType()), header,
length * sizeof(EncodedJSValue));
}
JSObject* result = JSObject::createRawObject(exec, structure, butterfly);
return bitwise_cast<char*>(result);
}
JSCell* JIT_OPERATION operationNewObjectWithButterfly(ExecState* exec, Structure* structure, Butterfly* butterfly)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
if (!butterfly) {
butterfly = Butterfly::create(
vm, nullptr, 0, structure->outOfLineCapacity(), false, IndexingHeader(), 0);
}
JSObject* result = JSObject::createRawObject(exec, structure, butterfly);
return result;
}
JSCell* JIT_OPERATION operationNewObjectWithButterflyWithIndexingHeaderAndVectorLength(ExecState* exec, Structure* structure, unsigned length, Butterfly* butterfly)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
IndexingHeader header;
header.setVectorLength(length);
header.setPublicLength(0);
if (butterfly)
*butterfly->indexingHeader() = header;
else {
butterfly = Butterfly::create(
vm, nullptr, 0, structure->outOfLineCapacity(), true, header,
sizeof(EncodedJSValue) * length);
}
// Paradoxically this may allocate a JSArray. That's totally cool.
JSObject* result = JSObject::createRawObject(exec, structure, butterfly);
return result;
}
JSCell* JIT_OPERATION operationNewArrayWithSpreadSlow(ExecState* exec, void* buffer, uint32_t numItems)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
auto scope = DECLARE_THROW_SCOPE(vm);
EncodedJSValue* values = static_cast<EncodedJSValue*>(buffer);
Checked<unsigned, RecordOverflow> checkedLength = 0;
for (unsigned i = 0; i < numItems; i++) {
JSValue value = JSValue::decode(values[i]);
if (JSFixedArray* array = jsDynamicCast<JSFixedArray*>(vm, value))
checkedLength += array->size();
else
++checkedLength;
}
if (UNLIKELY(checkedLength.hasOverflowed())) {
throwOutOfMemoryError(exec, scope);
return nullptr;
}
unsigned length = checkedLength.unsafeGet();
if (UNLIKELY(length >= MIN_ARRAY_STORAGE_CONSTRUCTION_LENGTH)) {
throwOutOfMemoryError(exec, scope);
return nullptr;
}
JSGlobalObject* globalObject = exec->lexicalGlobalObject();
Structure* structure = globalObject->arrayStructureForIndexingTypeDuringAllocation(ArrayWithContiguous);
JSArray* result = JSArray::tryCreate(vm, structure, length);
if (UNLIKELY(!result)) {
throwOutOfMemoryError(exec, scope);
return nullptr;
}
RETURN_IF_EXCEPTION(scope, nullptr);
unsigned index = 0;
for (unsigned i = 0; i < numItems; i++) {
JSValue value = JSValue::decode(values[i]);
if (JSFixedArray* array = jsDynamicCast<JSFixedArray*>(vm, value)) {
// We are spreading.
for (unsigned i = 0; i < array->size(); i++) {
result->putDirectIndex(exec, index, array->get(i));
RETURN_IF_EXCEPTION(scope, nullptr);
++index;
}
} else {
// We are not spreading.
result->putDirectIndex(exec, index, value);
RETURN_IF_EXCEPTION(scope, nullptr);
++index;
}
}
return result;
}
JSCell* operationCreateFixedArray(ExecState* exec, unsigned length)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
auto scope = DECLARE_THROW_SCOPE(vm);
if (JSFixedArray* result = JSFixedArray::tryCreate(vm, vm.fixedArrayStructure.get(), length))
return result;
throwOutOfMemoryError(exec, scope);
return nullptr;
}
JSCell* JIT_OPERATION operationSpreadGeneric(ExecState* exec, JSCell* iterable)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
auto throwScope = DECLARE_THROW_SCOPE(vm);
if (isJSArray(iterable)) {
JSArray* array = jsCast<JSArray*>(iterable);
if (array->isIteratorProtocolFastAndNonObservable())
RELEASE_AND_RETURN(throwScope, JSFixedArray::createFromArray(exec, vm, array));
}
// FIXME: we can probably make this path faster by having our caller JS code call directly into
// the iteration protocol builtin: https://bugs.webkit.org/show_bug.cgi?id=164520
JSGlobalObject* globalObject = exec->lexicalGlobalObject();
JSArray* array;
{
JSFunction* iterationFunction = globalObject->iteratorProtocolFunction();
CallData callData;
CallType callType = JSC::getCallData(vm, iterationFunction, callData);
ASSERT(callType != CallType::None);
MarkedArgumentBuffer arguments;
arguments.append(iterable);
ASSERT(!arguments.hasOverflowed());
JSValue arrayResult = call(exec, iterationFunction, callType, callData, jsNull(), arguments);
RETURN_IF_EXCEPTION(throwScope, nullptr);
array = jsCast<JSArray*>(arrayResult);
}
RELEASE_AND_RETURN(throwScope, JSFixedArray::createFromArray(exec, vm, array));
}
JSCell* JIT_OPERATION operationSpreadFastArray(ExecState* exec, JSCell* cell)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
ASSERT(isJSArray(cell));
JSArray* array = jsCast<JSArray*>(cell);
ASSERT(array->isIteratorProtocolFastAndNonObservable());
return JSFixedArray::createFromArray(exec, vm, array);
}
void JIT_OPERATION operationProcessTypeProfilerLogDFG(ExecState* exec)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
vm.typeProfilerLog()->processLogEntries(vm, "Log Full, called from inside DFG."_s);
}
EncodedJSValue JIT_OPERATION operationResolveScopeForHoistingFuncDeclInEval(ExecState* exec, JSScope* scope, UniquedStringImpl* impl)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
JSValue resolvedScope = JSScope::resolveScopeForHoistingFuncDeclInEval(exec, scope, Identifier::fromUid(vm, impl));
return JSValue::encode(resolvedScope);
}
JSCell* JIT_OPERATION operationResolveScope(ExecState* exec, JSScope* scope, UniquedStringImpl* impl)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
JSObject* resolvedScope = JSScope::resolve(exec, scope, Identifier::fromUid(vm, impl));
return resolvedScope;
}
EncodedJSValue JIT_OPERATION operationGetDynamicVar(ExecState* exec, JSObject* scope, UniquedStringImpl* impl, unsigned getPutInfoBits)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
auto throwScope = DECLARE_THROW_SCOPE(vm);
Identifier ident = Identifier::fromUid(vm, impl);
RELEASE_AND_RETURN(throwScope, JSValue::encode(scope->getPropertySlot(exec, ident, [&] (bool found, PropertySlot& slot) -> JSValue {
if (!found) {
GetPutInfo getPutInfo(getPutInfoBits);
if (getPutInfo.resolveMode() == ThrowIfNotFound)
throwException(exec, throwScope, createUndefinedVariableError(exec, ident));
return jsUndefined();
}
if (scope->isGlobalLexicalEnvironment()) {
// When we can't statically prove we need a TDZ check, we must perform the check on the slow path.
JSValue result = slot.getValue(exec, ident);
if (result == jsTDZValue()) {
throwException(exec, throwScope, createTDZError(exec));
return jsUndefined();
}
return result;
}
return slot.getValue(exec, ident);
})));
}
ALWAYS_INLINE static void putDynamicVar(ExecState* exec, VM& vm, JSObject* scope, EncodedJSValue value, UniquedStringImpl* impl, unsigned getPutInfoBits, bool isStrictMode)
{
auto throwScope = DECLARE_THROW_SCOPE(vm);
const Identifier& ident = Identifier::fromUid(vm, impl);
GetPutInfo getPutInfo(getPutInfoBits);
bool hasProperty = scope->hasProperty(exec, ident);
RETURN_IF_EXCEPTION(throwScope, void());
if (hasProperty
&& scope->isGlobalLexicalEnvironment()
&& !isInitialization(getPutInfo.initializationMode())) {
// When we can't statically prove we need a TDZ check, we must perform the check on the slow path.
PropertySlot slot(scope, PropertySlot::InternalMethodType::Get);
JSGlobalLexicalEnvironment::getOwnPropertySlot(scope, exec, ident, slot);
if (slot.getValue(exec, ident) == jsTDZValue()) {
throwException(exec, throwScope, createTDZError(exec));
return;
}
}
if (getPutInfo.resolveMode() == ThrowIfNotFound && !hasProperty) {
throwException(exec, throwScope, createUndefinedVariableError(exec, ident));
return;
}
PutPropertySlot slot(scope, isStrictMode, PutPropertySlot::UnknownContext, isInitialization(getPutInfo.initializationMode()));
throwScope.release();
scope->methodTable(vm)->put(scope, exec, ident, JSValue::decode(value), slot);
}
void JIT_OPERATION operationPutDynamicVarStrict(ExecState* exec, JSObject* scope, EncodedJSValue value, UniquedStringImpl* impl, unsigned getPutInfoBits)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
constexpr bool isStrictMode = true;
return putDynamicVar(exec, vm, scope, value, impl, getPutInfoBits, isStrictMode);
}
void JIT_OPERATION operationPutDynamicVarNonStrict(ExecState* exec, JSObject* scope, EncodedJSValue value, UniquedStringImpl* impl, unsigned getPutInfoBits)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
constexpr bool isStrictMode = false;
return putDynamicVar(exec, vm, scope, value, impl, getPutInfoBits, isStrictMode);
}
int32_t JIT_OPERATION operationMapHash(ExecState* exec, EncodedJSValue input)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
return jsMapHash(exec, vm, JSValue::decode(input));
}
JSCell* JIT_OPERATION operationJSMapFindBucket(ExecState* exec, JSCell* map, EncodedJSValue key, int32_t hash)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
JSMap::BucketType** bucket = jsCast<JSMap*>(map)->findBucket(exec, JSValue::decode(key), hash);
if (!bucket)
return vm.sentinelMapBucket();
return *bucket;
}
JSCell* JIT_OPERATION operationJSSetFindBucket(ExecState* exec, JSCell* map, EncodedJSValue key, int32_t hash)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
JSSet::BucketType** bucket = jsCast<JSSet*>(map)->findBucket(exec, JSValue::decode(key), hash);
if (!bucket)
return vm.sentinelSetBucket();
return *bucket;
}
JSCell* JIT_OPERATION operationSetAdd(ExecState* exec, JSCell* set, EncodedJSValue key, int32_t hash)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
auto* bucket = jsCast<JSSet*>(set)->addNormalized(exec, JSValue::decode(key), JSValue(), hash);
if (!bucket)
return vm.sentinelSetBucket();
return bucket;
}
JSCell* JIT_OPERATION operationMapSet(ExecState* exec, JSCell* map, EncodedJSValue key, EncodedJSValue value, int32_t hash)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
auto* bucket = jsCast<JSMap*>(map)->addNormalized(exec, JSValue::decode(key), JSValue::decode(value), hash);
if (!bucket)
return vm.sentinelMapBucket();
return bucket;
}
void JIT_OPERATION operationWeakSetAdd(ExecState* exec, JSCell* set, JSCell* key, int32_t hash)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
jsCast<JSWeakSet*>(set)->add(vm, asObject(key), JSValue(), hash);
}
void JIT_OPERATION operationWeakMapSet(ExecState* exec, JSCell* map, JSCell* key, EncodedJSValue value, int32_t hash)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
jsCast<JSWeakMap*>(map)->add(vm, asObject(key), JSValue::decode(value), hash);
}
EncodedJSValue JIT_OPERATION operationGetPrototypeOfObject(ExecState* exec, JSObject* thisObject)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
return JSValue::encode(thisObject->getPrototype(vm, exec));
}
EncodedJSValue JIT_OPERATION operationGetPrototypeOf(ExecState* exec, EncodedJSValue encodedValue)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
auto scope = DECLARE_THROW_SCOPE(vm);
JSValue thisValue = JSValue::decode(encodedValue).toThis(exec, StrictMode);
if (thisValue.isUndefinedOrNull())
return throwVMError(exec, scope, createNotAnObjectError(exec, thisValue));
JSObject* thisObject = jsDynamicCast<JSObject*>(vm, thisValue);
if (!thisObject) {
JSObject* prototype = thisValue.synthesizePrototype(exec);
EXCEPTION_ASSERT(!!scope.exception() == !prototype);
if (UNLIKELY(!prototype))
return JSValue::encode(JSValue());
return JSValue::encode(prototype);
}
RELEASE_AND_RETURN(scope, JSValue::encode(thisObject->getPrototype(vm, exec)));
}
void JIT_OPERATION operationThrowDFG(ExecState* exec, EncodedJSValue valueToThrow)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
auto scope = DECLARE_THROW_SCOPE(vm);
scope.throwException(exec, JSValue::decode(valueToThrow));
}
void JIT_OPERATION operationThrowStaticError(ExecState* exec, JSString* message, uint32_t errorType)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
auto scope = DECLARE_THROW_SCOPE(vm);
String errorMessage = message->value(exec);
scope.throwException(exec, createError(exec, static_cast<ErrorType>(errorType), errorMessage));
}
extern "C" void JIT_OPERATION triggerReoptimizationNow(CodeBlock* codeBlock, CodeBlock* optimizedCodeBlock, OSRExitBase* exit)
{
// It's sort of preferable that we don't GC while in here. Anyways, doing so wouldn't
// really be profitable.
DeferGCForAWhile deferGC(codeBlock->vm().heap);
sanitizeStackForVM(codeBlock->vm());
if (Options::verboseOSR())
dataLog(*codeBlock, ": Entered reoptimize\n");
// We must be called with the baseline code block.
ASSERT(JITCode::isBaselineCode(codeBlock->jitType()));
// If I am my own replacement, then reoptimization has already been triggered.
// This can happen in recursive functions.
//
// Note that even if optimizedCodeBlock is an FTLForOSREntry style CodeBlock, this condition is a
// sure bet that we don't have anything else left to do.
CodeBlock* replacement = codeBlock->replacement();
if (!replacement || replacement == codeBlock) {
if (Options::verboseOSR())
dataLog(*codeBlock, ": Not reoptimizing because we've already been jettisoned.\n");
return;
}
// Otherwise, the replacement must be optimized code. Use this as an opportunity
// to check our logic.
ASSERT(codeBlock->hasOptimizedReplacement());
ASSERT(JITCode::isOptimizingJIT(optimizedCodeBlock->jitType()));
bool didTryToEnterIntoInlinedLoops = false;
for (InlineCallFrame* inlineCallFrame = exit->m_codeOrigin.inlineCallFrame(); inlineCallFrame; inlineCallFrame = inlineCallFrame->directCaller.inlineCallFrame()) {
if (inlineCallFrame->baselineCodeBlock->ownerExecutable()->didTryToEnterInLoop()) {
didTryToEnterIntoInlinedLoops = true;
break;
}
}
// In order to trigger reoptimization, one of two things must have happened:
// 1) We exited more than some number of times.
// 2) We exited and got stuck in a loop, and now we're exiting again.
bool didExitABunch = optimizedCodeBlock->shouldReoptimizeNow();
bool didGetStuckInLoop =
(codeBlock->checkIfOptimizationThresholdReached() || didTryToEnterIntoInlinedLoops)
&& optimizedCodeBlock->shouldReoptimizeFromLoopNow();
if (!didExitABunch && !didGetStuckInLoop) {
if (Options::verboseOSR())
dataLog(*codeBlock, ": Not reoptimizing ", *optimizedCodeBlock, " because it either didn't exit enough or didn't loop enough after exit.\n");
codeBlock->optimizeAfterLongWarmUp();
return;
}
optimizedCodeBlock->jettison(Profiler::JettisonDueToOSRExit, CountReoptimization);
}
#if ENABLE(FTL_JIT)
static bool shouldTriggerFTLCompile(CodeBlock* codeBlock, JITCode* jitCode)
{
if (codeBlock->baselineVersion()->m_didFailFTLCompilation) {
CODEBLOCK_LOG_EVENT(codeBlock, "abortFTLCompile", ());
if (Options::verboseOSR())
dataLog("Deferring FTL-optimization of ", *codeBlock, " indefinitely because there was an FTL failure.\n");
jitCode->dontOptimizeAnytimeSoon(codeBlock);
return false;
}
if (!codeBlock->hasOptimizedReplacement()
&& !jitCode->checkIfOptimizationThresholdReached(codeBlock)) {
CODEBLOCK_LOG_EVENT(codeBlock, "delayFTLCompile", ("counter = ", jitCode->tierUpCounter));
if (Options::verboseOSR())
dataLog("Choosing not to FTL-optimize ", *codeBlock, " yet.\n");
return false;
}
return true;
}
static void triggerFTLReplacementCompile(VM& vm, CodeBlock* codeBlock, JITCode* jitCode)
{
if (codeBlock->codeType() == GlobalCode) {
// Global code runs once, so we don't want to do anything. We don't want to defer indefinitely,
// since this may have been spuriously called from tier-up initiated in a loop, and that loop may
// later want to run faster code. Deferring for warm-up seems safest.
jitCode->optimizeAfterWarmUp(codeBlock);
return;
}
Worklist::State worklistState;
if (Worklist* worklist = existingGlobalFTLWorklistOrNull()) {
worklistState = worklist->completeAllReadyPlansForVM(
vm, CompilationKey(codeBlock->baselineVersion(), FTLMode));
} else
worklistState = Worklist::NotKnown;
if (worklistState == Worklist::Compiling) {
CODEBLOCK_LOG_EVENT(codeBlock, "delayFTLCompile", ("still compiling"));
jitCode->setOptimizationThresholdBasedOnCompilationResult(
codeBlock, CompilationDeferred);
return;
}
if (codeBlock->hasOptimizedReplacement()) {
CODEBLOCK_LOG_EVENT(codeBlock, "delayFTLCompile", ("has replacement"));
// That's great, we've compiled the code - next time we call this function,
// we'll enter that replacement.
jitCode->optimizeSoon(codeBlock);
return;
}
if (worklistState == Worklist::Compiled) {
CODEBLOCK_LOG_EVENT(codeBlock, "delayFTLCompile", ("compiled and failed"));
// This means that we finished compiling, but failed somehow; in that case the
// thresholds will be set appropriately.
if (Options::verboseOSR())
dataLog("Code block ", *codeBlock, " was compiled but it doesn't have an optimized replacement.\n");
return;
}
CODEBLOCK_LOG_EVENT(codeBlock, "triggerFTLReplacement", ());
// We need to compile the code.
compile(
vm, codeBlock->newReplacement(), codeBlock, FTLMode, UINT_MAX,
Operands<Optional<JSValue>>(), ToFTLDeferredCompilationCallback::create());
// If we reached here, the counter has not be reset. Do that now.
jitCode->setOptimizationThresholdBasedOnCompilationResult(
codeBlock, CompilationDeferred);
}
void JIT_OPERATION triggerTierUpNow(ExecState* exec)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
DeferGCForAWhile deferGC(vm.heap);
CodeBlock* codeBlock = exec->codeBlock();
sanitizeStackForVM(vm);
if (codeBlock->jitType() != JITType::DFGJIT) {
dataLog("Unexpected code block in DFG->FTL tier-up: ", *codeBlock, "\n");
RELEASE_ASSERT_NOT_REACHED();
}
JITCode* jitCode = codeBlock->jitCode()->dfg();
if (Options::verboseOSR()) {
dataLog(
*codeBlock, ": Entered triggerTierUpNow with executeCounter = ",
jitCode->tierUpCounter, "\n");
}
if (shouldTriggerFTLCompile(codeBlock, jitCode))
triggerFTLReplacementCompile(vm, codeBlock, jitCode);
if (codeBlock->hasOptimizedReplacement()) {
if (jitCode->tierUpEntryTriggers.isEmpty()) {
CODEBLOCK_LOG_EVENT(codeBlock, "delayFTLCompile", ("replacement in place, delaying indefinitely"));
// There is nothing more we can do, the only way this will be entered
// is through the function entry point.
jitCode->dontOptimizeAnytimeSoon(codeBlock);
return;
}
if (jitCode->osrEntryBlock() && jitCode->tierUpEntryTriggers.size() == 1) {
CODEBLOCK_LOG_EVENT(codeBlock, "delayFTLCompile", ("trigger in place, delaying indefinitely"));
// There is only one outer loop and its trigger must have been set
// when the plan completed.
// Exiting the inner loop is useless, we can ignore the counter and leave
// the trigger do its job.
jitCode->dontOptimizeAnytimeSoon(codeBlock);
return;
}
}
}
static char* tierUpCommon(ExecState* exec, unsigned originBytecodeIndex, bool canOSREnterHere)
{
VM& vm = exec->vm();
CodeBlock* codeBlock = exec->codeBlock();
// Resolve any pending plan for OSR Enter on this function.
Worklist::State worklistState;
if (Worklist* worklist = existingGlobalFTLWorklistOrNull()) {
worklistState = worklist->completeAllReadyPlansForVM(
vm, CompilationKey(codeBlock->baselineVersion(), FTLForOSREntryMode));
} else
worklistState = Worklist::NotKnown;
JITCode* jitCode = codeBlock->jitCode()->dfg();
bool triggeredSlowPathToStartCompilation = false;
auto tierUpEntryTriggers = jitCode->tierUpEntryTriggers.find(originBytecodeIndex);
if (tierUpEntryTriggers != jitCode->tierUpEntryTriggers.end()) {
switch (tierUpEntryTriggers->value) {
case JITCode::TriggerReason::DontTrigger:
// The trigger isn't set, we entered because the counter reached its
// threshold.
break;
case JITCode::TriggerReason::CompilationDone:
// The trigger was set because compilation completed. Don't unset it
// so that further DFG executions OSR enter as well.
break;
case JITCode::TriggerReason::StartCompilation:
// We were asked to enter as soon as possible and start compiling an
// entry for the current bytecode location. Unset this trigger so we
// don't continually enter.
tierUpEntryTriggers->value = JITCode::TriggerReason::DontTrigger;
triggeredSlowPathToStartCompilation = true;
break;
}
}
if (worklistState == Worklist::Compiling) {
CODEBLOCK_LOG_EVENT(codeBlock, "delayFTLCompile", ("still compiling"));
jitCode->setOptimizationThresholdBasedOnCompilationResult(codeBlock, CompilationDeferred);
return nullptr;
}
// If we can OSR Enter, do it right away.
if (canOSREnterHere) {
auto iter = jitCode->bytecodeIndexToStreamIndex.find(originBytecodeIndex);
if (iter != jitCode->bytecodeIndexToStreamIndex.end()) {
unsigned streamIndex = iter->value;
if (CodeBlock* entryBlock = jitCode->osrEntryBlock()) {
if (Options::verboseOSR())
dataLog("OSR entry: From ", RawPointer(jitCode), " got entry block ", RawPointer(entryBlock), "\n");
if (void* address = FTL::prepareOSREntry(exec, codeBlock, entryBlock, originBytecodeIndex, streamIndex)) {
CODEBLOCK_LOG_EVENT(entryBlock, "osrEntry", ("at bc#", originBytecodeIndex));
return retagCodePtr<char*>(address, JSEntryPtrTag, bitwise_cast<PtrTag>(exec));
}
}
}
}
if (worklistState == Worklist::Compiled) {
CODEBLOCK_LOG_EVENT(codeBlock, "delayFTLCompile", ("compiled and failed"));
// This means that compilation failed and we already set the thresholds.
if (Options::verboseOSR())
dataLog("Code block ", *codeBlock, " was compiled but it doesn't have an optimized replacement.\n");
return nullptr;
}
// - If we don't have an FTL code block, then try to compile one.
// - If we do have an FTL code block, then try to enter for a while.
// - If we couldn't enter for a while, then trigger OSR entry.
if (!shouldTriggerFTLCompile(codeBlock, jitCode) && !triggeredSlowPathToStartCompilation)
return nullptr;
if (!jitCode->neverExecutedEntry && !triggeredSlowPathToStartCompilation) {
triggerFTLReplacementCompile(vm, codeBlock, jitCode);
if (!codeBlock->hasOptimizedReplacement())
return nullptr;
if (jitCode->osrEntryRetry < Options::ftlOSREntryRetryThreshold()) {
CODEBLOCK_LOG_EVENT(codeBlock, "delayFTLCompile", ("avoiding OSR entry compile"));
jitCode->osrEntryRetry++;
return nullptr;
}
} else
CODEBLOCK_LOG_EVENT(codeBlock, "delayFTLCompile", ("avoiding replacement compile"));
if (CodeBlock* entryBlock = jitCode->osrEntryBlock()) {
if (jitCode->osrEntryRetry < Options::ftlOSREntryRetryThreshold()) {
CODEBLOCK_LOG_EVENT(codeBlock, "delayFTLCompile", ("OSR entry failed, OSR entry threshold not met"));
jitCode->osrEntryRetry++;
jitCode->setOptimizationThresholdBasedOnCompilationResult(
codeBlock, CompilationDeferred);
return nullptr;
}
FTL::ForOSREntryJITCode* entryCode = entryBlock->jitCode()->ftlForOSREntry();
entryCode->countEntryFailure();
if (entryCode->entryFailureCount() <
Options::ftlOSREntryFailureCountForReoptimization()) {
CODEBLOCK_LOG_EVENT(codeBlock, "delayFTLCompile", ("OSR entry failed"));
jitCode->setOptimizationThresholdBasedOnCompilationResult(
codeBlock, CompilationDeferred);
return nullptr;
}
// OSR entry failed. Oh no! This implies that we need to retry. We retry
// without exponential backoff and we only do this for the entry code block.
CODEBLOCK_LOG_EVENT(codeBlock, "delayFTLCompile", ("OSR entry failed too many times"));
jitCode->clearOSREntryBlockAndResetThresholds(codeBlock);
return nullptr;
}
// It's time to try to compile code for OSR entry.
if (!triggeredSlowPathToStartCompilation) {
// An inner loop didn't specifically ask for us to kick off a compilation. This means the counter
// crossed its threshold. We either fall through and kick off a compile for originBytecodeIndex,
// or we flag an outer loop to immediately try to compile itself. If there are outer loops,
// we first try to make them compile themselves. But we will eventually fall back to compiling
// a progressively inner loop if it takes too long for control to reach an outer loop.
auto tryTriggerOuterLoopToCompile = [&] {
auto tierUpHierarchyEntry = jitCode->tierUpInLoopHierarchy.find(originBytecodeIndex);
if (tierUpHierarchyEntry == jitCode->tierUpInLoopHierarchy.end())
return false;
// This vector is ordered from innermost to outermost loop. Every bytecode entry in this vector is
// allowed to do OSR entry. We start with the outermost loop and make our way inwards (hence why we
// iterate the vector in reverse). Our policy is that we will trigger an outer loop to compile
// immediately when program control reaches it. If program control is taking too long to reach that
// outer loop, we progressively move inwards, meaning, we'll eventually trigger some loop that is
// executing to compile. We start with trying to compile outer loops since we believe outer loop
// compilations reveal the best opportunities for optimizing code.
for (auto iter = tierUpHierarchyEntry->value.rbegin(), end = tierUpHierarchyEntry->value.rend(); iter != end; ++iter) {
unsigned osrEntryCandidate = *iter;
if (jitCode->tierUpEntryTriggers.get(osrEntryCandidate) == JITCode::TriggerReason::StartCompilation) {
// This means that we already asked this loop to compile. If we've reached here, it
// means program control has not yet reached that loop. So it's taking too long to compile.
// So we move on to asking the inner loop of this loop to compile itself.
continue;
}
// This is where we ask the outer to loop to immediately compile itself if program
// control reaches it.
if (Options::verboseOSR())
dataLog("Inner-loop bc#", originBytecodeIndex, " in ", *codeBlock, " setting parent loop bc#", osrEntryCandidate, "'s trigger and backing off.\n");
jitCode->tierUpEntryTriggers.set(osrEntryCandidate, JITCode::TriggerReason::StartCompilation);
return true;
}
return false;
};
if (tryTriggerOuterLoopToCompile()) {
jitCode->setOptimizationThresholdBasedOnCompilationResult(codeBlock, CompilationDeferred);
return nullptr;
}
}
if (!canOSREnterHere) {
jitCode->setOptimizationThresholdBasedOnCompilationResult(codeBlock, CompilationDeferred);
return nullptr;
}
// We aren't compiling and haven't compiled anything for OSR entry. So, try to compile
// something.
auto triggerIterator = jitCode->tierUpEntryTriggers.find(originBytecodeIndex);
if (triggerIterator == jitCode->tierUpEntryTriggers.end()) {
jitCode->setOptimizationThresholdBasedOnCompilationResult(codeBlock, CompilationDeferred);
return nullptr;
}
JITCode::TriggerReason* triggerAddress = &(triggerIterator->value);
Operands<Optional<JSValue>> mustHandleValues;
unsigned streamIndex = jitCode->bytecodeIndexToStreamIndex.get(originBytecodeIndex);
jitCode->reconstruct(
exec, codeBlock, CodeOrigin(originBytecodeIndex), streamIndex, mustHandleValues);
CodeBlock* replacementCodeBlock = codeBlock->newReplacement();
CODEBLOCK_LOG_EVENT(codeBlock, "triggerFTLOSR", ());
CompilationResult forEntryResult = compile(
vm, replacementCodeBlock, codeBlock, FTLForOSREntryMode, originBytecodeIndex,
mustHandleValues, ToFTLForOSREntryDeferredCompilationCallback::create(triggerAddress));
if (jitCode->neverExecutedEntry)
triggerFTLReplacementCompile(vm, codeBlock, jitCode);
if (forEntryResult != CompilationSuccessful) {
CODEBLOCK_LOG_EVENT(codeBlock, "delayFTLCompile", ("OSR ecompilation not successful"));
jitCode->setOptimizationThresholdBasedOnCompilationResult(
codeBlock, CompilationDeferred);
return nullptr;
}
CODEBLOCK_LOG_EVENT(jitCode->osrEntryBlock(), "osrEntry", ("at bc#", originBytecodeIndex));
// It's possible that the for-entry compile already succeeded. In that case OSR
// entry will succeed unless we ran out of stack. It's not clear what we should do.
// We signal to try again after a while if that happens.
if (Options::verboseOSR())
dataLog("Immediate OSR entry: From ", RawPointer(jitCode), " got entry block ", RawPointer(jitCode->osrEntryBlock()), "\n");
void* address = FTL::prepareOSREntry(
exec, codeBlock, jitCode->osrEntryBlock(), originBytecodeIndex, streamIndex);
if (!address)
return nullptr;
return retagCodePtr<char*>(address, JSEntryPtrTag, bitwise_cast<PtrTag>(exec));
}
void JIT_OPERATION triggerTierUpNowInLoop(ExecState* exec, unsigned bytecodeIndex)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
DeferGCForAWhile deferGC(vm.heap);
CodeBlock* codeBlock = exec->codeBlock();
sanitizeStackForVM(vm);
if (codeBlock->jitType() != JITType::DFGJIT) {
dataLog("Unexpected code block in DFG->FTL trigger tier up now in loop: ", *codeBlock, "\n");
RELEASE_ASSERT_NOT_REACHED();
}
JITCode* jitCode = codeBlock->jitCode()->dfg();
if (Options::verboseOSR()) {
dataLog(
*codeBlock, ": Entered triggerTierUpNowInLoop with executeCounter = ",
jitCode->tierUpCounter, "\n");
}
if (jitCode->tierUpInLoopHierarchy.contains(bytecodeIndex))
tierUpCommon(exec, bytecodeIndex, false);
else if (shouldTriggerFTLCompile(codeBlock, jitCode))
triggerFTLReplacementCompile(vm, codeBlock, jitCode);
// Since we cannot OSR Enter here, the default "optimizeSoon()" is not useful.
if (codeBlock->hasOptimizedReplacement()) {
CODEBLOCK_LOG_EVENT(codeBlock, "delayFTLCompile", ("OSR in loop failed, deferring"));
jitCode->setOptimizationThresholdBasedOnCompilationResult(codeBlock, CompilationDeferred);
}
}
char* JIT_OPERATION triggerOSREntryNow(ExecState* exec, unsigned bytecodeIndex)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(vm, exec);
DeferGCForAWhile deferGC(vm.heap);
CodeBlock* codeBlock = exec->codeBlock();
sanitizeStackForVM(vm);
if (codeBlock->jitType() != JITType::DFGJIT) {
dataLog("Unexpected code block in DFG->FTL tier-up: ", *codeBlock, "\n");
RELEASE_ASSERT_NOT_REACHED();
}
JITCode* jitCode = codeBlock->jitCode()->dfg();
if (Options::verboseOSR()) {
dataLog(
*codeBlock, ": Entered triggerOSREntryNow with executeCounter = ",
jitCode->tierUpCounter, "\n");
}
return tierUpCommon(exec, bytecodeIndex, true);
}
#endif // ENABLE(FTL_JIT)
} // extern "C"
} } // namespace JSC::DFG
#endif // ENABLE(DFG_JIT)
#endif // ENABLE(JIT)