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webkit / WebKit / 0e4328c5b03a383f0100ef33ad31b474fc1d9cab / . / Source / JavaScriptCore / jit / JITOperations.cpp
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/*
* Copyright (C) 2013-2017 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 "JITOperations.h"
#if ENABLE(JIT)
#include "ArithProfile.h"
#include "ArrayConstructor.h"
#include "CommonSlowPaths.h"
#include "DFGCompilationMode.h"
#include "DFGDriver.h"
#include "DFGOSREntry.h"
#include "DFGThunks.h"
#include "DFGWorklist.h"
#include "Debugger.h"
#include "DirectArguments.h"
#include "Error.h"
#include "ErrorHandlingScope.h"
#include "EvalCodeBlock.h"
#include "ExceptionFuzz.h"
#include "FTLOSREntry.h"
#include "FrameTracers.h"
#include "FunctionCodeBlock.h"
#include "GetterSetter.h"
#include "HostCallReturnValue.h"
#include "ICStats.h"
#include "Interpreter.h"
#include "JIT.h"
#include "JITExceptions.h"
#include "JITToDFGDeferredCompilationCallback.h"
#include "JSAsyncFunction.h"
#include "JSAsyncGeneratorFunction.h"
#include "JSCInlines.h"
#include "JSGeneratorFunction.h"
#include "JSGlobalObjectFunctions.h"
#include "JSLexicalEnvironment.h"
#include "JSWithScope.h"
#include "ModuleProgramCodeBlock.h"
#include "ObjectConstructor.h"
#include "PolymorphicAccess.h"
#include "ProgramCodeBlock.h"
#include "PropertyName.h"
#include "RegExpObject.h"
#include "Repatch.h"
#include "ScopedArguments.h"
#include "ShadowChicken.h"
#include "StructureStubInfo.h"
#include "SuperSampler.h"
#include "TestRunnerUtils.h"
#include "ThunkGenerators.h"
#include "TypeProfilerLog.h"
#include "VMInlines.h"
#include <wtf/InlineASM.h>
namespace JSC {
extern "C" {
#if COMPILER(MSVC)
void * _ReturnAddress(void);
#pragma intrinsic(_ReturnAddress)
#define OUR_RETURN_ADDRESS _ReturnAddress()
#else
#define OUR_RETURN_ADDRESS __builtin_return_address(0)
#endif
#if ENABLE(OPCODE_SAMPLING)
#define CTI_SAMPLER vm->interpreter->sampler()
#else
#define CTI_SAMPLER 0
#endif
void JIT_OPERATION operationThrowStackOverflowError(ExecState* exec, CodeBlock* codeBlock)
{
// We pass in our own code block, because the callframe hasn't been populated.
VM* vm = codeBlock->vm();
auto scope = DECLARE_THROW_SCOPE(*vm);
EntryFrame* entryFrame = vm->topEntryFrame;
CallFrame* callerFrame = exec->callerFrame(entryFrame);
if (!callerFrame) {
callerFrame = exec;
entryFrame = vm->topEntryFrame;
}
NativeCallFrameTracerWithRestore tracer(vm, entryFrame, callerFrame);
throwStackOverflowError(callerFrame, scope);
}
#if ENABLE(WEBASSEMBLY)
void JIT_OPERATION operationThrowDivideError(ExecState* exec)
{
VM* vm = &exec->vm();
auto scope = DECLARE_THROW_SCOPE(*vm);
EntryFrame* entryFrame = vm->topEntryFrame;
CallFrame* callerFrame = exec->callerFrame(entryFrame);
NativeCallFrameTracerWithRestore tracer(vm, entryFrame, callerFrame);
ErrorHandlingScope errorScope(*vm);
throwException(callerFrame, scope, createError(callerFrame, ASCIILiteral("Division by zero or division overflow.")));
}
void JIT_OPERATION operationThrowOutOfBoundsAccessError(ExecState* exec)
{
VM* vm = &exec->vm();
auto scope = DECLARE_THROW_SCOPE(*vm);
EntryFrame* entryFrame = vm->topEntryFrame;
CallFrame* callerFrame = exec->callerFrame(entryFrame);
NativeCallFrameTracerWithRestore tracer(vm, entryFrame, callerFrame);
ErrorHandlingScope errorScope(*vm);
throwException(callerFrame, scope, createError(callerFrame, ASCIILiteral("Out-of-bounds access.")));
}
#endif
int32_t JIT_OPERATION operationCallArityCheck(ExecState* exec)
{
VM* vm = &exec->vm();
auto scope = DECLARE_THROW_SCOPE(*vm);
int32_t missingArgCount = CommonSlowPaths::arityCheckFor(exec, *vm, CodeForCall);
if (missingArgCount < 0) {
EntryFrame* entryFrame = vm->topEntryFrame;
CallFrame* callerFrame = exec->callerFrame(entryFrame);
NativeCallFrameTracerWithRestore tracer(vm, entryFrame, callerFrame);
throwStackOverflowError(callerFrame, scope);
}
return missingArgCount;
}
int32_t JIT_OPERATION operationConstructArityCheck(ExecState* exec)
{
VM* vm = &exec->vm();
auto scope = DECLARE_THROW_SCOPE(*vm);
int32_t missingArgCount = CommonSlowPaths::arityCheckFor(exec, *vm, CodeForConstruct);
if (missingArgCount < 0) {
EntryFrame* entryFrame = vm->topEntryFrame;
CallFrame* callerFrame = exec->callerFrame(entryFrame);
NativeCallFrameTracerWithRestore tracer(vm, entryFrame, callerFrame);
throwStackOverflowError(callerFrame, scope);
}
return missingArgCount;
}
EncodedJSValue JIT_OPERATION operationTryGetById(ExecState* exec, StructureStubInfo* stubInfo, EncodedJSValue base, UniquedStringImpl* uid)
{
VM* vm = &exec->vm();
NativeCallFrameTracer tracer(vm, exec);
Identifier ident = Identifier::fromUid(vm, uid);
stubInfo->tookSlowPath = true;
JSValue baseValue = JSValue::decode(base);
PropertySlot slot(baseValue, PropertySlot::InternalMethodType::VMInquiry);
baseValue.getPropertySlot(exec, ident, slot);
return JSValue::encode(slot.getPureResult());
}
EncodedJSValue JIT_OPERATION operationTryGetByIdGeneric(ExecState* exec, EncodedJSValue base, UniquedStringImpl* uid)
{
VM* vm = &exec->vm();
NativeCallFrameTracer tracer(vm, exec);
Identifier ident = Identifier::fromUid(vm, uid);
JSValue baseValue = JSValue::decode(base);
PropertySlot slot(baseValue, PropertySlot::InternalMethodType::VMInquiry);
baseValue.getPropertySlot(exec, ident, slot);
return JSValue::encode(slot.getPureResult());
}
EncodedJSValue JIT_OPERATION operationTryGetByIdOptimize(ExecState* exec, StructureStubInfo* stubInfo, EncodedJSValue base, UniquedStringImpl* uid)
{
VM* vm = &exec->vm();
NativeCallFrameTracer tracer(vm, exec);
auto scope = DECLARE_THROW_SCOPE(*vm);
Identifier ident = Identifier::fromUid(vm, uid);
JSValue baseValue = JSValue::decode(base);
PropertySlot slot(baseValue, PropertySlot::InternalMethodType::VMInquiry);
baseValue.getPropertySlot(exec, ident, slot);
RETURN_IF_EXCEPTION(scope, encodedJSValue());
if (stubInfo->considerCaching(exec->codeBlock(), baseValue.structureOrNull()) && !slot.isTaintedByOpaqueObject() && (slot.isCacheableValue() || slot.isCacheableGetter() || slot.isUnset()))
repatchGetByID(exec, baseValue, ident, slot, *stubInfo, GetByIDKind::Try);
return JSValue::encode(slot.getPureResult());
}
EncodedJSValue JIT_OPERATION operationGetById(ExecState* exec, StructureStubInfo* stubInfo, EncodedJSValue base, UniquedStringImpl* uid)
{
SuperSamplerScope superSamplerScope(false);
VM* vm = &exec->vm();
NativeCallFrameTracer tracer(vm, exec);
stubInfo->tookSlowPath = true;
JSValue baseValue = JSValue::decode(base);
PropertySlot slot(baseValue, PropertySlot::InternalMethodType::Get);
Identifier ident = Identifier::fromUid(vm, uid);
LOG_IC((ICEvent::OperationGetById, baseValue.classInfoOrNull(*vm), ident));
return JSValue::encode(baseValue.get(exec, ident, slot));
}
EncodedJSValue JIT_OPERATION operationGetByIdGeneric(ExecState* exec, EncodedJSValue base, UniquedStringImpl* uid)
{
SuperSamplerScope superSamplerScope(false);
VM* vm = &exec->vm();
NativeCallFrameTracer tracer(vm, exec);
JSValue baseValue = JSValue::decode(base);
PropertySlot slot(baseValue, PropertySlot::InternalMethodType::Get);
Identifier ident = Identifier::fromUid(vm, uid);
LOG_IC((ICEvent::OperationGetByIdGeneric, baseValue.classInfoOrNull(*vm), ident));
return JSValue::encode(baseValue.get(exec, ident, slot));
}
EncodedJSValue JIT_OPERATION operationGetByIdOptimize(ExecState* exec, StructureStubInfo* stubInfo, EncodedJSValue base, UniquedStringImpl* uid)
{
SuperSamplerScope superSamplerScope(false);
VM* vm = &exec->vm();
NativeCallFrameTracer tracer(vm, exec);
Identifier ident = Identifier::fromUid(vm, uid);
JSValue baseValue = JSValue::decode(base);
LOG_IC((ICEvent::OperationGetByIdOptimize, baseValue.classInfoOrNull(*vm), ident));
return JSValue::encode(baseValue.getPropertySlot(exec, ident, [&] (bool found, PropertySlot& slot) -> JSValue {
if (stubInfo->considerCaching(exec->codeBlock(), baseValue.structureOrNull()))
repatchGetByID(exec, baseValue, ident, slot, *stubInfo, GetByIDKind::Normal);
return found ? slot.getValue(exec, ident) : jsUndefined();
}));
}
EncodedJSValue JIT_OPERATION operationGetByIdWithThisGeneric(ExecState* exec, StructureStubInfo* stubInfo, EncodedJSValue base, EncodedJSValue thisEncoded, UniquedStringImpl* uid)
{
SuperSamplerScope superSamplerScope(false);
VM* vm = &exec->vm();
NativeCallFrameTracer tracer(vm, exec);
Identifier ident = Identifier::fromUid(vm, uid);
stubInfo->tookSlowPath = true;
JSValue baseValue = JSValue::decode(base);
JSValue thisValue = JSValue::decode(thisEncoded);
PropertySlot slot(thisValue, PropertySlot::InternalMethodType::Get);
return JSValue::encode(baseValue.get(exec, ident, slot));
}
EncodedJSValue JIT_OPERATION operationGetByIdWithThisOptimize(ExecState* exec, StructureStubInfo* stubInfo, EncodedJSValue base, EncodedJSValue thisEncoded, UniquedStringImpl* uid)
{
SuperSamplerScope superSamplerScope(false);
VM* vm = &exec->vm();
NativeCallFrameTracer tracer(vm, exec);
Identifier ident = Identifier::fromUid(vm, uid);
JSValue baseValue = JSValue::decode(base);
JSValue thisValue = JSValue::decode(thisEncoded);
LOG_IC((ICEvent::OperationGetByIdWithThisOptimize, baseValue.classInfoOrNull(*vm), ident));
PropertySlot slot(thisValue, PropertySlot::InternalMethodType::Get);
return JSValue::encode(baseValue.getPropertySlot(exec, ident, slot, [&] (bool found, PropertySlot& slot) -> JSValue {
if (stubInfo->considerCaching(exec->codeBlock(), baseValue.structureOrNull()))
repatchGetByID(exec, baseValue, ident, slot, *stubInfo, GetByIDKind::WithThis);
return found ? slot.getValue(exec, ident) : jsUndefined();
}));
}
EncodedJSValue JIT_OPERATION operationInOptimize(ExecState* exec, StructureStubInfo* stubInfo, JSCell* base, UniquedStringImpl* key)
{
SuperSamplerScope superSamplerScope(false);
VM* vm = &exec->vm();
NativeCallFrameTracer tracer(vm, exec);
auto scope = DECLARE_THROW_SCOPE(*vm);
if (!base->isObject()) {
throwException(exec, scope, createInvalidInParameterError(exec, base));
return JSValue::encode(jsUndefined());
}
AccessType accessType = static_cast<AccessType>(stubInfo->accessType);
Identifier ident = Identifier::fromUid(vm, key);
LOG_IC((ICEvent::OperationInOptimize, base->classInfo(*vm), ident));
PropertySlot slot(base, PropertySlot::InternalMethodType::HasProperty);
bool result = asObject(base)->getPropertySlot(exec, ident, slot);
RETURN_IF_EXCEPTION(scope, encodedJSValue());
RELEASE_ASSERT(accessType == stubInfo->accessType);
if (stubInfo->considerCaching(exec->codeBlock(), asObject(base)->structure()))
repatchIn(exec, base, ident, result, slot, *stubInfo);
return JSValue::encode(jsBoolean(result));
}
EncodedJSValue JIT_OPERATION operationIn(ExecState* exec, StructureStubInfo* stubInfo, JSCell* base, UniquedStringImpl* key)
{
SuperSamplerScope superSamplerScope(false);
VM* vm = &exec->vm();
NativeCallFrameTracer tracer(vm, exec);
auto scope = DECLARE_THROW_SCOPE(*vm);
stubInfo->tookSlowPath = true;
if (!base->isObject()) {
throwException(exec, scope, createInvalidInParameterError(exec, base));
return JSValue::encode(jsUndefined());
}
Identifier ident = Identifier::fromUid(vm, key);
LOG_IC((ICEvent::OperationIn, base->classInfo(*vm), ident));
scope.release();
return JSValue::encode(jsBoolean(asObject(base)->hasProperty(exec, ident)));
}
EncodedJSValue JIT_OPERATION operationGenericIn(ExecState* exec, JSCell* base, EncodedJSValue key)
{
SuperSamplerScope superSamplerScope(false);
VM* vm = &exec->vm();
NativeCallFrameTracer tracer(vm, exec);
return JSValue::encode(jsBoolean(CommonSlowPaths::opIn(exec, base, JSValue::decode(key))));
}
void JIT_OPERATION operationPutByIdStrict(ExecState* exec, StructureStubInfo* stubInfo, EncodedJSValue encodedValue, EncodedJSValue encodedBase, UniquedStringImpl* uid)
{
SuperSamplerScope superSamplerScope(false);
VM* vm = &exec->vm();
NativeCallFrameTracer tracer(vm, exec);
stubInfo->tookSlowPath = true;
JSValue baseValue = JSValue::decode(encodedBase);
Identifier ident = Identifier::fromUid(vm, uid);
LOG_IC((ICEvent::OperationPutByIdStrict, baseValue.classInfoOrNull(*vm), ident));
PutPropertySlot slot(baseValue, true, exec->codeBlock()->putByIdContext());
baseValue.putInline(exec, ident, JSValue::decode(encodedValue), slot);
}
void JIT_OPERATION operationPutByIdNonStrict(ExecState* exec, StructureStubInfo* stubInfo, EncodedJSValue encodedValue, EncodedJSValue encodedBase, UniquedStringImpl* uid)
{
SuperSamplerScope superSamplerScope(false);
VM* vm = &exec->vm();
NativeCallFrameTracer tracer(vm, exec);
stubInfo->tookSlowPath = true;
JSValue baseValue = JSValue::decode(encodedBase);
Identifier ident = Identifier::fromUid(vm, uid);
LOG_IC((ICEvent::OperationPutByIdNonStrict, baseValue.classInfoOrNull(*vm), ident));
PutPropertySlot slot(baseValue, false, exec->codeBlock()->putByIdContext());
baseValue.putInline(exec, ident, JSValue::decode(encodedValue), slot);
}
void JIT_OPERATION operationPutByIdDirectStrict(ExecState* exec, StructureStubInfo* stubInfo, EncodedJSValue encodedValue, EncodedJSValue encodedBase, UniquedStringImpl* uid)
{
SuperSamplerScope superSamplerScope(false);
VM* vm = &exec->vm();
NativeCallFrameTracer tracer(vm, exec);
stubInfo->tookSlowPath = true;
JSValue baseValue = JSValue::decode(encodedBase);
Identifier ident = Identifier::fromUid(vm, uid);
LOG_IC((ICEvent::OperationPutByIdDirectStrict, baseValue.classInfoOrNull(*vm), ident));
PutPropertySlot slot(baseValue, true, exec->codeBlock()->putByIdContext());
asObject(baseValue)->putDirect(*vm, ident, JSValue::decode(encodedValue), slot);
}
void JIT_OPERATION operationPutByIdDirectNonStrict(ExecState* exec, StructureStubInfo* stubInfo, EncodedJSValue encodedValue, EncodedJSValue encodedBase, UniquedStringImpl* uid)
{
SuperSamplerScope superSamplerScope(false);
VM* vm = &exec->vm();
NativeCallFrameTracer tracer(vm, exec);
stubInfo->tookSlowPath = true;
JSValue baseValue = JSValue::decode(encodedBase);
Identifier ident = Identifier::fromUid(vm, uid);
LOG_IC((ICEvent::OperationPutByIdDirectNonStrict, baseValue.classInfoOrNull(*vm), ident));
PutPropertySlot slot(baseValue, false, exec->codeBlock()->putByIdContext());
asObject(baseValue)->putDirect(*vm, ident, JSValue::decode(encodedValue), slot);
}
void JIT_OPERATION operationPutByIdStrictOptimize(ExecState* exec, StructureStubInfo* stubInfo, EncodedJSValue encodedValue, EncodedJSValue encodedBase, UniquedStringImpl* uid)
{
SuperSamplerScope superSamplerScope(false);
VM* vm = &exec->vm();
NativeCallFrameTracer tracer(vm, exec);
auto scope = DECLARE_THROW_SCOPE(*vm);
Identifier ident = Identifier::fromUid(vm, uid);
AccessType accessType = static_cast<AccessType>(stubInfo->accessType);
JSValue value = JSValue::decode(encodedValue);
JSValue baseValue = JSValue::decode(encodedBase);
LOG_IC((ICEvent::OperationPutByIdStrictOptimize, baseValue.classInfoOrNull(*vm), ident));
CodeBlock* codeBlock = exec->codeBlock();
PutPropertySlot slot(baseValue, true, codeBlock->putByIdContext());
Structure* structure = baseValue.isCell() ? baseValue.asCell()->structure(*vm) : nullptr;
baseValue.putInline(exec, ident, value, slot);
RETURN_IF_EXCEPTION(scope, void());
if (accessType != static_cast<AccessType>(stubInfo->accessType))
return;
if (stubInfo->considerCaching(codeBlock, structure))
repatchPutByID(exec, baseValue, structure, ident, slot, *stubInfo, NotDirect);
}
void JIT_OPERATION operationPutByIdNonStrictOptimize(ExecState* exec, StructureStubInfo* stubInfo, EncodedJSValue encodedValue, EncodedJSValue encodedBase, UniquedStringImpl* uid)
{
SuperSamplerScope superSamplerScope(false);
VM* vm = &exec->vm();
NativeCallFrameTracer tracer(vm, exec);
auto scope = DECLARE_THROW_SCOPE(*vm);
Identifier ident = Identifier::fromUid(vm, uid);
AccessType accessType = static_cast<AccessType>(stubInfo->accessType);
JSValue value = JSValue::decode(encodedValue);
JSValue baseValue = JSValue::decode(encodedBase);
LOG_IC((ICEvent::OperationPutByIdNonStrictOptimize, baseValue.classInfoOrNull(*vm), ident));
CodeBlock* codeBlock = exec->codeBlock();
PutPropertySlot slot(baseValue, false, codeBlock->putByIdContext());
Structure* structure = baseValue.isCell() ? baseValue.asCell()->structure(*vm) : nullptr;
baseValue.putInline(exec, ident, value, slot);
RETURN_IF_EXCEPTION(scope, void());
if (accessType != static_cast<AccessType>(stubInfo->accessType))
return;
if (stubInfo->considerCaching(codeBlock, structure))
repatchPutByID(exec, baseValue, structure, ident, slot, *stubInfo, NotDirect);
}
void JIT_OPERATION operationPutByIdDirectStrictOptimize(ExecState* exec, StructureStubInfo* stubInfo, EncodedJSValue encodedValue, EncodedJSValue encodedBase, UniquedStringImpl* uid)
{
SuperSamplerScope superSamplerScope(false);
VM* vm = &exec->vm();
NativeCallFrameTracer tracer(vm, exec);
Identifier ident = Identifier::fromUid(vm, uid);
AccessType accessType = static_cast<AccessType>(stubInfo->accessType);
JSValue value = JSValue::decode(encodedValue);
JSObject* baseObject = asObject(JSValue::decode(encodedBase));
LOG_IC((ICEvent::OperationPutByIdDirectStrictOptimize, baseObject->classInfo(*vm), ident));
CodeBlock* codeBlock = exec->codeBlock();
PutPropertySlot slot(baseObject, true, codeBlock->putByIdContext());
Structure* structure = baseObject->structure(*vm);
baseObject->putDirect(*vm, ident, value, slot);
if (accessType != static_cast<AccessType>(stubInfo->accessType))
return;
if (stubInfo->considerCaching(codeBlock, structure))
repatchPutByID(exec, baseObject, structure, ident, slot, *stubInfo, Direct);
}
void JIT_OPERATION operationPutByIdDirectNonStrictOptimize(ExecState* exec, StructureStubInfo* stubInfo, EncodedJSValue encodedValue, EncodedJSValue encodedBase, UniquedStringImpl* uid)
{
SuperSamplerScope superSamplerScope(false);
VM* vm = &exec->vm();
NativeCallFrameTracer tracer(vm, exec);
Identifier ident = Identifier::fromUid(vm, uid);
AccessType accessType = static_cast<AccessType>(stubInfo->accessType);
JSValue value = JSValue::decode(encodedValue);
JSObject* baseObject = asObject(JSValue::decode(encodedBase));
LOG_IC((ICEvent::OperationPutByIdDirectNonStrictOptimize, baseObject->classInfo(*vm), ident));
CodeBlock* codeBlock = exec->codeBlock();
PutPropertySlot slot(baseObject, false, codeBlock->putByIdContext());
Structure* structure = baseObject->structure(*vm);
baseObject->putDirect(*vm, ident, value, slot);
if (accessType != static_cast<AccessType>(stubInfo->accessType))
return;
if (stubInfo->considerCaching(codeBlock, structure))
repatchPutByID(exec, baseObject, structure, ident, slot, *stubInfo, Direct);
}
ALWAYS_INLINE static bool isStringOrSymbol(JSValue value)
{
return value.isString() || value.isSymbol();
}
static void putByVal(CallFrame* callFrame, JSValue baseValue, JSValue subscript, JSValue value, ByValInfo* byValInfo)
{
VM& vm = callFrame->vm();
auto scope = DECLARE_THROW_SCOPE(vm);
if (LIKELY(subscript.isUInt32())) {
byValInfo->tookSlowPath = true;
uint32_t i = subscript.asUInt32();
if (baseValue.isObject()) {
JSObject* object = asObject(baseValue);
if (object->canSetIndexQuickly(i)) {
object->setIndexQuickly(vm, i, value);
return;
}
// FIXME: This will make us think that in-bounds typed array accesses are actually
// out-of-bounds.
// https://bugs.webkit.org/show_bug.cgi?id=149886
byValInfo->arrayProfile->setOutOfBounds();
scope.release();
object->methodTable(vm)->putByIndex(object, callFrame, i, value, callFrame->codeBlock()->isStrictMode());
return;
}
scope.release();
baseValue.putByIndex(callFrame, i, value, callFrame->codeBlock()->isStrictMode());
return;
}
auto property = subscript.toPropertyKey(callFrame);
// Don't put to an object if toString threw an exception.
RETURN_IF_EXCEPTION(scope, void());
if (byValInfo->stubInfo && (!isStringOrSymbol(subscript) || byValInfo->cachedId != property))
byValInfo->tookSlowPath = true;
scope.release();
PutPropertySlot slot(baseValue, callFrame->codeBlock()->isStrictMode());
baseValue.putInline(callFrame, property, value, slot);
}
static void directPutByVal(CallFrame* callFrame, JSObject* baseObject, JSValue subscript, JSValue value, ByValInfo* byValInfo)
{
VM& vm = callFrame->vm();
auto scope = DECLARE_THROW_SCOPE(vm);
bool isStrictMode = callFrame->codeBlock()->isStrictMode();
if (LIKELY(subscript.isUInt32())) {
// Despite its name, JSValue::isUInt32 will return true only for positive boxed int32_t; all those values are valid array indices.
byValInfo->tookSlowPath = true;
uint32_t index = subscript.asUInt32();
ASSERT(isIndex(index));
switch (baseObject->indexingType()) {
case ALL_INT32_INDEXING_TYPES:
case ALL_DOUBLE_INDEXING_TYPES:
case ALL_CONTIGUOUS_INDEXING_TYPES:
case ALL_ARRAY_STORAGE_INDEXING_TYPES:
if (index < baseObject->butterfly()->vectorLength())
break;
FALLTHROUGH;
default:
byValInfo->arrayProfile->setOutOfBounds();
break;
}
scope.release();
baseObject->putDirectIndex(callFrame, index, value, 0, isStrictMode ? PutDirectIndexShouldThrow : PutDirectIndexShouldNotThrow);
return;
}
if (subscript.isDouble()) {
double subscriptAsDouble = subscript.asDouble();
uint32_t subscriptAsUInt32 = static_cast<uint32_t>(subscriptAsDouble);
if (subscriptAsDouble == subscriptAsUInt32 && isIndex(subscriptAsUInt32)) {
byValInfo->tookSlowPath = true;
scope.release();
baseObject->putDirectIndex(callFrame, subscriptAsUInt32, value, 0, isStrictMode ? PutDirectIndexShouldThrow : PutDirectIndexShouldNotThrow);
return;
}
}
// Don't put to an object if toString threw an exception.
auto property = subscript.toPropertyKey(callFrame);
RETURN_IF_EXCEPTION(scope, void());
if (std::optional<uint32_t> index = parseIndex(property)) {
byValInfo->tookSlowPath = true;
scope.release();
baseObject->putDirectIndex(callFrame, index.value(), value, 0, isStrictMode ? PutDirectIndexShouldThrow : PutDirectIndexShouldNotThrow);
return;
}
if (byValInfo->stubInfo && (!isStringOrSymbol(subscript) || byValInfo->cachedId != property))
byValInfo->tookSlowPath = true;
PutPropertySlot slot(baseObject, isStrictMode);
baseObject->putDirect(vm, property, value, slot);
}
enum class OptimizationResult {
NotOptimized,
SeenOnce,
Optimized,
GiveUp,
};
static OptimizationResult tryPutByValOptimize(ExecState* exec, JSValue baseValue, JSValue subscript, ByValInfo* byValInfo, ReturnAddressPtr returnAddress)
{
// See if it's worth optimizing at all.
OptimizationResult optimizationResult = OptimizationResult::NotOptimized;
VM& vm = exec->vm();
if (baseValue.isObject() && subscript.isInt32()) {
JSObject* object = asObject(baseValue);
ASSERT(exec->bytecodeOffset());
ASSERT(!byValInfo->stubRoutine);
Structure* structure = object->structure(vm);
if (hasOptimizableIndexing(structure)) {
// Attempt to optimize.
JITArrayMode arrayMode = jitArrayModeForStructure(structure);
if (jitArrayModePermitsPut(arrayMode) && arrayMode != byValInfo->arrayMode) {
CodeBlock* codeBlock = exec->codeBlock();
ConcurrentJSLocker locker(codeBlock->m_lock);
byValInfo->arrayProfile->computeUpdatedPrediction(locker, codeBlock, structure);
JIT::compilePutByVal(&vm, codeBlock, byValInfo, returnAddress, arrayMode);
optimizationResult = OptimizationResult::Optimized;
}
}
// If we failed to patch and we have some object that intercepts indexed get, then don't even wait until 10 times.
if (optimizationResult != OptimizationResult::Optimized && object->structure(vm)->typeInfo().interceptsGetOwnPropertySlotByIndexEvenWhenLengthIsNotZero())
optimizationResult = OptimizationResult::GiveUp;
}
if (baseValue.isObject() && isStringOrSymbol(subscript)) {
const Identifier propertyName = subscript.toPropertyKey(exec);
if (subscript.isSymbol() || !parseIndex(propertyName)) {
ASSERT(exec->bytecodeOffset());
ASSERT(!byValInfo->stubRoutine);
if (byValInfo->seen) {
if (byValInfo->cachedId == propertyName) {
JIT::compilePutByValWithCachedId(&vm, exec->codeBlock(), byValInfo, returnAddress, NotDirect, propertyName);
optimizationResult = OptimizationResult::Optimized;
} else {
// Seem like a generic property access site.
optimizationResult = OptimizationResult::GiveUp;
}
} else {
CodeBlock* codeBlock = exec->codeBlock();
ConcurrentJSLocker locker(codeBlock->m_lock);
byValInfo->seen = true;
byValInfo->cachedId = propertyName;
if (subscript.isSymbol())
byValInfo->cachedSymbol.set(vm, codeBlock, asSymbol(subscript));
optimizationResult = OptimizationResult::SeenOnce;
}
}
}
if (optimizationResult != OptimizationResult::Optimized && optimizationResult != OptimizationResult::SeenOnce) {
// If we take slow path more than 10 times without patching then make sure we
// never make that mistake again. For cases where we see non-index-intercepting
// objects, this gives 10 iterations worth of opportunity for us to observe
// that the put_by_val may be polymorphic. We count up slowPathCount even if
// the result is GiveUp.
if (++byValInfo->slowPathCount >= 10)
optimizationResult = OptimizationResult::GiveUp;
}
return optimizationResult;
}
void JIT_OPERATION operationPutByValOptimize(ExecState* exec, EncodedJSValue encodedBaseValue, EncodedJSValue encodedSubscript, EncodedJSValue encodedValue, ByValInfo* byValInfo)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(&vm, exec);
JSValue baseValue = JSValue::decode(encodedBaseValue);
JSValue subscript = JSValue::decode(encodedSubscript);
JSValue value = JSValue::decode(encodedValue);
if (tryPutByValOptimize(exec, baseValue, subscript, byValInfo, ReturnAddressPtr(OUR_RETURN_ADDRESS)) == OptimizationResult::GiveUp) {
// Don't ever try to optimize.
byValInfo->tookSlowPath = true;
ctiPatchCallByReturnAddress(ReturnAddressPtr(OUR_RETURN_ADDRESS), FunctionPtr(operationPutByValGeneric));
}
putByVal(exec, baseValue, subscript, value, byValInfo);
}
static OptimizationResult tryDirectPutByValOptimize(ExecState* exec, JSObject* object, JSValue subscript, ByValInfo* byValInfo, ReturnAddressPtr returnAddress)
{
// See if it's worth optimizing at all.
OptimizationResult optimizationResult = OptimizationResult::NotOptimized;
VM& vm = exec->vm();
if (subscript.isInt32()) {
ASSERT(exec->bytecodeOffset());
ASSERT(!byValInfo->stubRoutine);
Structure* structure = object->structure(vm);
if (hasOptimizableIndexing(structure)) {
// Attempt to optimize.
JITArrayMode arrayMode = jitArrayModeForStructure(structure);
if (jitArrayModePermitsPutDirect(arrayMode) && arrayMode != byValInfo->arrayMode) {
CodeBlock* codeBlock = exec->codeBlock();
ConcurrentJSLocker locker(codeBlock->m_lock);
byValInfo->arrayProfile->computeUpdatedPrediction(locker, codeBlock, structure);
JIT::compileDirectPutByVal(&vm, codeBlock, byValInfo, returnAddress, arrayMode);
optimizationResult = OptimizationResult::Optimized;
}
}
// If we failed to patch and we have some object that intercepts indexed get, then don't even wait until 10 times.
if (optimizationResult != OptimizationResult::Optimized && object->structure(vm)->typeInfo().interceptsGetOwnPropertySlotByIndexEvenWhenLengthIsNotZero())
optimizationResult = OptimizationResult::GiveUp;
} else if (isStringOrSymbol(subscript)) {
const Identifier propertyName = subscript.toPropertyKey(exec);
if (subscript.isSymbol() || !parseIndex(propertyName)) {
ASSERT(exec->bytecodeOffset());
ASSERT(!byValInfo->stubRoutine);
if (byValInfo->seen) {
if (byValInfo->cachedId == propertyName) {
JIT::compilePutByValWithCachedId(&vm, exec->codeBlock(), byValInfo, returnAddress, Direct, propertyName);
optimizationResult = OptimizationResult::Optimized;
} else {
// Seem like a generic property access site.
optimizationResult = OptimizationResult::GiveUp;
}
} else {
CodeBlock* codeBlock = exec->codeBlock();
ConcurrentJSLocker locker(codeBlock->m_lock);
byValInfo->seen = true;
byValInfo->cachedId = propertyName;
if (subscript.isSymbol())
byValInfo->cachedSymbol.set(vm, codeBlock, asSymbol(subscript));
optimizationResult = OptimizationResult::SeenOnce;
}
}
}
if (optimizationResult != OptimizationResult::Optimized && optimizationResult != OptimizationResult::SeenOnce) {
// If we take slow path more than 10 times without patching then make sure we
// never make that mistake again. For cases where we see non-index-intercepting
// objects, this gives 10 iterations worth of opportunity for us to observe
// that the get_by_val may be polymorphic. We count up slowPathCount even if
// the result is GiveUp.
if (++byValInfo->slowPathCount >= 10)
optimizationResult = OptimizationResult::GiveUp;
}
return optimizationResult;
}
void JIT_OPERATION operationDirectPutByValOptimize(ExecState* exec, EncodedJSValue encodedBaseValue, EncodedJSValue encodedSubscript, EncodedJSValue encodedValue, ByValInfo* byValInfo)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(&vm, exec);
JSValue baseValue = JSValue::decode(encodedBaseValue);
JSValue subscript = JSValue::decode(encodedSubscript);
JSValue value = JSValue::decode(encodedValue);
RELEASE_ASSERT(baseValue.isObject());
JSObject* object = asObject(baseValue);
if (tryDirectPutByValOptimize(exec, object, subscript, byValInfo, ReturnAddressPtr(OUR_RETURN_ADDRESS)) == OptimizationResult::GiveUp) {
// Don't ever try to optimize.
byValInfo->tookSlowPath = true;
ctiPatchCallByReturnAddress(ReturnAddressPtr(OUR_RETURN_ADDRESS), FunctionPtr(operationDirectPutByValGeneric));
}
directPutByVal(exec, object, subscript, value, byValInfo);
}
void JIT_OPERATION operationPutByValGeneric(ExecState* exec, EncodedJSValue encodedBaseValue, EncodedJSValue encodedSubscript, EncodedJSValue encodedValue, ByValInfo* byValInfo)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(&vm, exec);
JSValue baseValue = JSValue::decode(encodedBaseValue);
JSValue subscript = JSValue::decode(encodedSubscript);
JSValue value = JSValue::decode(encodedValue);
putByVal(exec, baseValue, subscript, value, byValInfo);
}
void JIT_OPERATION operationDirectPutByValGeneric(ExecState* exec, EncodedJSValue encodedBaseValue, EncodedJSValue encodedSubscript, EncodedJSValue encodedValue, ByValInfo* byValInfo)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(&vm, exec);
JSValue baseValue = JSValue::decode(encodedBaseValue);
JSValue subscript = JSValue::decode(encodedSubscript);
JSValue value = JSValue::decode(encodedValue);
RELEASE_ASSERT(baseValue.isObject());
directPutByVal(exec, asObject(baseValue), subscript, value, byValInfo);
}
EncodedJSValue JIT_OPERATION operationCallEval(ExecState* exec, ExecState* execCallee)
{
VM* vm = &exec->vm();
auto scope = DECLARE_THROW_SCOPE(*vm);
execCallee->setCodeBlock(0);
if (!isHostFunction(execCallee->guaranteedJSValueCallee(), globalFuncEval))
return JSValue::encode(JSValue());
JSValue result = eval(execCallee);
RETURN_IF_EXCEPTION(scope, encodedJSValue());
return JSValue::encode(result);
}
static SlowPathReturnType handleHostCall(ExecState* execCallee, JSValue callee, CallLinkInfo* callLinkInfo)
{
ExecState* exec = execCallee->callerFrame();
VM* vm = &exec->vm();
auto scope = DECLARE_THROW_SCOPE(*vm);
execCallee->setCodeBlock(0);
if (callLinkInfo->specializationKind() == CodeForCall) {
CallData callData;
CallType callType = getCallData(callee, callData);
ASSERT(callType != CallType::JS);
if (callType == CallType::Host) {
NativeCallFrameTracer tracer(vm, execCallee);
execCallee->setCallee(asObject(callee));
vm->hostCallReturnValue = JSValue::decode(callData.native.function(execCallee));
if (UNLIKELY(scope.exception())) {
return encodeResult(
vm->getCTIStub(throwExceptionFromCallSlowPathGenerator).code().executableAddress(),
reinterpret_cast<void*>(KeepTheFrame));
}
return encodeResult(
bitwise_cast<void*>(getHostCallReturnValue),
reinterpret_cast<void*>(callLinkInfo->callMode() == CallMode::Tail ? ReuseTheFrame : KeepTheFrame));
}
ASSERT(callType == CallType::None);
throwException(exec, scope, createNotAFunctionError(exec, callee));
return encodeResult(
vm->getCTIStub(throwExceptionFromCallSlowPathGenerator).code().executableAddress(),
reinterpret_cast<void*>(KeepTheFrame));
}
ASSERT(callLinkInfo->specializationKind() == CodeForConstruct);
ConstructData constructData;
ConstructType constructType = getConstructData(callee, constructData);
ASSERT(constructType != ConstructType::JS);
if (constructType == ConstructType::Host) {
NativeCallFrameTracer tracer(vm, execCallee);
execCallee->setCallee(asObject(callee));
vm->hostCallReturnValue = JSValue::decode(constructData.native.function(execCallee));
if (UNLIKELY(scope.exception())) {
return encodeResult(
vm->getCTIStub(throwExceptionFromCallSlowPathGenerator).code().executableAddress(),
reinterpret_cast<void*>(KeepTheFrame));
}
return encodeResult(bitwise_cast<void*>(getHostCallReturnValue), reinterpret_cast<void*>(KeepTheFrame));
}
ASSERT(constructType == ConstructType::None);
throwException(exec, scope, createNotAConstructorError(exec, callee));
return encodeResult(
vm->getCTIStub(throwExceptionFromCallSlowPathGenerator).code().executableAddress(),
reinterpret_cast<void*>(KeepTheFrame));
}
SlowPathReturnType JIT_OPERATION operationLinkCall(ExecState* execCallee, CallLinkInfo* callLinkInfo)
{
ExecState* exec = execCallee->callerFrame();
VM* vm = &exec->vm();
auto throwScope = DECLARE_THROW_SCOPE(*vm);
CodeSpecializationKind kind = callLinkInfo->specializationKind();
NativeCallFrameTracer tracer(vm, exec);
RELEASE_ASSERT(!callLinkInfo->isDirect());
JSValue calleeAsValue = execCallee->guaranteedJSValueCallee();
JSCell* calleeAsFunctionCell = getJSFunction(calleeAsValue);
if (!calleeAsFunctionCell) {
if (auto* internalFunction = jsDynamicCast<InternalFunction*>(*vm, calleeAsValue)) {
MacroAssemblerCodePtr codePtr = vm->getCTIInternalFunctionTrampolineFor(kind);
RELEASE_ASSERT(!!codePtr);
if (!callLinkInfo->seenOnce())
callLinkInfo->setSeen();
else
linkFor(execCallee, *callLinkInfo, nullptr, internalFunction, codePtr);
return encodeResult(codePtr.executableAddress(), reinterpret_cast<void*>(callLinkInfo->callMode() == CallMode::Tail ? ReuseTheFrame : KeepTheFrame));
}
throwScope.release();
return handleHostCall(execCallee, calleeAsValue, callLinkInfo);
}
JSFunction* callee = jsCast<JSFunction*>(calleeAsFunctionCell);
JSScope* scope = callee->scopeUnchecked();
ExecutableBase* executable = callee->executable();
MacroAssemblerCodePtr codePtr;
CodeBlock* codeBlock = nullptr;
if (executable->isHostFunction()) {
codePtr = executable->entrypointFor(kind, MustCheckArity);
} else {
FunctionExecutable* functionExecutable = static_cast<FunctionExecutable*>(executable);
if (!isCall(kind) && functionExecutable->constructAbility() == ConstructAbility::CannotConstruct) {
throwException(exec, throwScope, createNotAConstructorError(exec, callee));
return encodeResult(
vm->getCTIStub(throwExceptionFromCallSlowPathGenerator).code().executableAddress(),
reinterpret_cast<void*>(KeepTheFrame));
}
CodeBlock** codeBlockSlot = execCallee->addressOfCodeBlock();
JSObject* error = functionExecutable->prepareForExecution<FunctionExecutable>(*vm, callee, scope, kind, *codeBlockSlot);
EXCEPTION_ASSERT(throwScope.exception() == reinterpret_cast<Exception*>(error));
if (error) {
return encodeResult(
vm->getCTIStub(throwExceptionFromCallSlowPathGenerator).code().executableAddress(),
reinterpret_cast<void*>(KeepTheFrame));
}
codeBlock = *codeBlockSlot;
ArityCheckMode arity;
if (execCallee->argumentCountIncludingThis() < static_cast<size_t>(codeBlock->numParameters()) || callLinkInfo->isVarargs())
arity = MustCheckArity;
else
arity = ArityCheckNotRequired;
codePtr = functionExecutable->entrypointFor(kind, arity);
}
if (!callLinkInfo->seenOnce())
callLinkInfo->setSeen();
else
linkFor(execCallee, *callLinkInfo, codeBlock, callee, codePtr);
return encodeResult(codePtr.executableAddress(), reinterpret_cast<void*>(callLinkInfo->callMode() == CallMode::Tail ? ReuseTheFrame : KeepTheFrame));
}
void JIT_OPERATION operationLinkDirectCall(ExecState* exec, CallLinkInfo* callLinkInfo, JSFunction* callee)
{
VM* vm = &exec->vm();
auto throwScope = DECLARE_THROW_SCOPE(*vm);
CodeSpecializationKind kind = callLinkInfo->specializationKind();
NativeCallFrameTracer tracer(vm, exec);
RELEASE_ASSERT(callLinkInfo->isDirect());
// This would happen if the executable died during GC but the CodeBlock did not die. That should
// not happen because the CodeBlock should have a weak reference to any executable it uses for
// this purpose.
RELEASE_ASSERT(callLinkInfo->executable());
// Having a CodeBlock indicates that this is linked. We shouldn't be taking this path if it's
// linked.
RELEASE_ASSERT(!callLinkInfo->codeBlock());
// We just don't support this yet.
RELEASE_ASSERT(!callLinkInfo->isVarargs());
ExecutableBase* executable = callLinkInfo->executable();
RELEASE_ASSERT(callee->executable() == callLinkInfo->executable());
JSScope* scope = callee->scopeUnchecked();
MacroAssemblerCodePtr codePtr;
CodeBlock* codeBlock = nullptr;
if (executable->isHostFunction())
codePtr = executable->entrypointFor(kind, MustCheckArity);
else {
FunctionExecutable* functionExecutable = static_cast<FunctionExecutable*>(executable);
RELEASE_ASSERT(isCall(kind) || functionExecutable->constructAbility() != ConstructAbility::CannotConstruct);
JSObject* error = functionExecutable->prepareForExecution<FunctionExecutable>(*vm, callee, scope, kind, codeBlock);
EXCEPTION_ASSERT_UNUSED(throwScope, throwScope.exception() == reinterpret_cast<Exception*>(error));
if (error)
return;
ArityCheckMode arity;
unsigned argumentStackSlots = callLinkInfo->maxNumArguments();
if (argumentStackSlots < static_cast<size_t>(codeBlock->numParameters()))
arity = MustCheckArity;
else
arity = ArityCheckNotRequired;
codePtr = functionExecutable->entrypointFor(kind, arity);
}
linkDirectFor(exec, *callLinkInfo, codeBlock, codePtr);
}
inline SlowPathReturnType virtualForWithFunction(
ExecState* execCallee, CallLinkInfo* callLinkInfo, JSCell*& calleeAsFunctionCell)
{
ExecState* exec = execCallee->callerFrame();
VM* vm = &exec->vm();
auto throwScope = DECLARE_THROW_SCOPE(*vm);
CodeSpecializationKind kind = callLinkInfo->specializationKind();
NativeCallFrameTracer tracer(vm, exec);
JSValue calleeAsValue = execCallee->guaranteedJSValueCallee();
calleeAsFunctionCell = getJSFunction(calleeAsValue);
if (UNLIKELY(!calleeAsFunctionCell)) {
if (jsDynamicCast<InternalFunction*>(*vm, calleeAsValue)) {
MacroAssemblerCodePtr codePtr = vm->getCTIInternalFunctionTrampolineFor(kind);
ASSERT(!!codePtr);
return encodeResult(codePtr.executableAddress(), reinterpret_cast<void*>(callLinkInfo->callMode() == CallMode::Tail ? ReuseTheFrame : KeepTheFrame));
}
throwScope.release();
return handleHostCall(execCallee, calleeAsValue, callLinkInfo);
}
JSFunction* function = jsCast<JSFunction*>(calleeAsFunctionCell);
JSScope* scope = function->scopeUnchecked();
ExecutableBase* executable = function->executable();
if (UNLIKELY(!executable->hasJITCodeFor(kind))) {
FunctionExecutable* functionExecutable = static_cast<FunctionExecutable*>(executable);
if (!isCall(kind) && functionExecutable->constructAbility() == ConstructAbility::CannotConstruct) {
throwException(exec, throwScope, createNotAConstructorError(exec, function));
return encodeResult(
vm->getCTIStub(throwExceptionFromCallSlowPathGenerator).code().executableAddress(),
reinterpret_cast<void*>(KeepTheFrame));
}
CodeBlock** codeBlockSlot = execCallee->addressOfCodeBlock();
JSObject* error = functionExecutable->prepareForExecution<FunctionExecutable>(*vm, function, scope, kind, *codeBlockSlot);
EXCEPTION_ASSERT(throwScope.exception() == reinterpret_cast<Exception*>(error));
if (error) {
return encodeResult(
vm->getCTIStub(throwExceptionFromCallSlowPathGenerator).code().executableAddress(),
reinterpret_cast<void*>(KeepTheFrame));
}
}
return encodeResult(executable->entrypointFor(
kind, MustCheckArity).executableAddress(),
reinterpret_cast<void*>(callLinkInfo->callMode() == CallMode::Tail ? ReuseTheFrame : KeepTheFrame));
}
SlowPathReturnType JIT_OPERATION operationLinkPolymorphicCall(ExecState* execCallee, CallLinkInfo* callLinkInfo)
{
ASSERT(callLinkInfo->specializationKind() == CodeForCall);
JSCell* calleeAsFunctionCell;
SlowPathReturnType result = virtualForWithFunction(execCallee, callLinkInfo, calleeAsFunctionCell);
linkPolymorphicCall(execCallee, *callLinkInfo, CallVariant(calleeAsFunctionCell));
return result;
}
SlowPathReturnType JIT_OPERATION operationVirtualCall(ExecState* execCallee, CallLinkInfo* callLinkInfo)
{
JSCell* calleeAsFunctionCellIgnored;
return virtualForWithFunction(execCallee, callLinkInfo, calleeAsFunctionCellIgnored);
}
size_t JIT_OPERATION operationCompareLess(ExecState* exec, EncodedJSValue encodedOp1, EncodedJSValue encodedOp2)
{
VM* vm = &exec->vm();
NativeCallFrameTracer tracer(vm, exec);
return jsLess<true>(exec, JSValue::decode(encodedOp1), JSValue::decode(encodedOp2));
}
size_t JIT_OPERATION operationCompareLessEq(ExecState* exec, EncodedJSValue encodedOp1, EncodedJSValue encodedOp2)
{
VM* vm = &exec->vm();
NativeCallFrameTracer tracer(vm, exec);
return jsLessEq<true>(exec, JSValue::decode(encodedOp1), JSValue::decode(encodedOp2));
}
size_t JIT_OPERATION operationCompareGreater(ExecState* exec, EncodedJSValue encodedOp1, EncodedJSValue encodedOp2)
{
VM* vm = &exec->vm();
NativeCallFrameTracer tracer(vm, exec);
return jsLess<false>(exec, JSValue::decode(encodedOp2), JSValue::decode(encodedOp1));
}
size_t JIT_OPERATION operationCompareGreaterEq(ExecState* exec, EncodedJSValue encodedOp1, EncodedJSValue encodedOp2)
{
VM* vm = &exec->vm();
NativeCallFrameTracer tracer(vm, exec);
return jsLessEq<false>(exec, JSValue::decode(encodedOp2), JSValue::decode(encodedOp1));
}
size_t JIT_OPERATION operationCompareEq(ExecState* exec, EncodedJSValue encodedOp1, EncodedJSValue encodedOp2)
{
VM* vm = &exec->vm();
NativeCallFrameTracer tracer(vm, exec);
return JSValue::equalSlowCaseInline(exec, JSValue::decode(encodedOp1), JSValue::decode(encodedOp2));
}
#if USE(JSVALUE64)
EncodedJSValue JIT_OPERATION operationCompareStringEq(ExecState* exec, JSCell* left, JSCell* right)
#else
size_t JIT_OPERATION operationCompareStringEq(ExecState* exec, JSCell* left, JSCell* right)
#endif
{
VM* vm = &exec->vm();
NativeCallFrameTracer tracer(vm, exec);
bool result = asString(left)->equal(exec, asString(right));
#if USE(JSVALUE64)
return JSValue::encode(jsBoolean(result));
#else
return result;
#endif
}
size_t JIT_OPERATION operationCompareStrictEq(ExecState* exec, EncodedJSValue encodedOp1, EncodedJSValue encodedOp2)
{
VM* vm = &exec->vm();
NativeCallFrameTracer tracer(vm, exec);
JSValue src1 = JSValue::decode(encodedOp1);
JSValue src2 = JSValue::decode(encodedOp2);
return JSValue::strictEqual(exec, src1, src2);
}
EncodedJSValue JIT_OPERATION operationNewArrayWithProfile(ExecState* exec, ArrayAllocationProfile* profile, const JSValue* values, int size)
{
VM* vm = &exec->vm();
NativeCallFrameTracer tracer(vm, exec);
return JSValue::encode(constructArrayNegativeIndexed(exec, profile, values, size));
}
EncodedJSValue JIT_OPERATION operationNewArrayWithSizeAndProfile(ExecState* exec, ArrayAllocationProfile* profile, EncodedJSValue size)
{
VM* vm = &exec->vm();
NativeCallFrameTracer tracer(vm, exec);
JSValue sizeValue = JSValue::decode(size);
return JSValue::encode(constructArrayWithSizeQuirk(exec, profile, exec->lexicalGlobalObject(), sizeValue));
}
}
template<typename FunctionType>
static EncodedJSValue operationNewFunctionCommon(ExecState* exec, JSScope* scope, JSCell* functionExecutable, bool isInvalidated)
{
VM& vm = exec->vm();
ASSERT(functionExecutable->inherits<FunctionExecutable>(vm));
NativeCallFrameTracer tracer(&vm, exec);
if (isInvalidated)
return JSValue::encode(FunctionType::createWithInvalidatedReallocationWatchpoint(vm, static_cast<FunctionExecutable*>(functionExecutable), scope));
return JSValue::encode(FunctionType::create(vm, static_cast<FunctionExecutable*>(functionExecutable), scope));
}
extern "C" {
EncodedJSValue JIT_OPERATION operationNewFunction(ExecState* exec, JSScope* scope, JSCell* functionExecutable)
{
return operationNewFunctionCommon<JSFunction>(exec, scope, functionExecutable, false);
}
EncodedJSValue JIT_OPERATION operationNewFunctionWithInvalidatedReallocationWatchpoint(ExecState* exec, JSScope* scope, JSCell* functionExecutable)
{
return operationNewFunctionCommon<JSFunction>(exec, scope, functionExecutable, true);
}
EncodedJSValue JIT_OPERATION operationNewGeneratorFunction(ExecState* exec, JSScope* scope, JSCell* functionExecutable)
{
return operationNewFunctionCommon<JSGeneratorFunction>(exec, scope, functionExecutable, false);
}
EncodedJSValue JIT_OPERATION operationNewGeneratorFunctionWithInvalidatedReallocationWatchpoint(ExecState* exec, JSScope* scope, JSCell* functionExecutable)
{
return operationNewFunctionCommon<JSGeneratorFunction>(exec, scope, functionExecutable, true);
}
EncodedJSValue JIT_OPERATION operationNewAsyncFunction(ExecState* exec, JSScope* scope, JSCell* functionExecutable)
{
return operationNewFunctionCommon<JSAsyncFunction>(exec, scope, functionExecutable, false);
}
EncodedJSValue JIT_OPERATION operationNewAsyncFunctionWithInvalidatedReallocationWatchpoint(ExecState* exec, JSScope* scope, JSCell* functionExecutable)
{
return operationNewFunctionCommon<JSAsyncFunction>(exec, scope, functionExecutable, true);
}
EncodedJSValue JIT_OPERATION operationNewAsyncGeneratorFunction(ExecState* exec, JSScope* scope, JSCell* functionExecutable)
{
return operationNewFunctionCommon<JSAsyncGeneratorFunction>(exec, scope, functionExecutable, false);
}
EncodedJSValue JIT_OPERATION operationNewAsyncGeneratorFunctionWithInvalidatedReallocationWatchpoint(ExecState* exec, JSScope* scope, JSCell* functionExecutable)
{
return operationNewFunctionCommon<JSAsyncGeneratorFunction>(exec, scope, functionExecutable, true);
}
void JIT_OPERATION operationSetFunctionName(ExecState* exec, JSCell* funcCell, EncodedJSValue encodedName)
{
VM* vm = &exec->vm();
NativeCallFrameTracer tracer(vm, exec);
JSFunction* func = jsCast<JSFunction*>(funcCell);
JSValue name = JSValue::decode(encodedName);
func->setFunctionName(exec, name);
}
JSCell* JIT_OPERATION operationNewObject(ExecState* exec, Structure* structure)
{
VM* vm = &exec->vm();
NativeCallFrameTracer tracer(vm, exec);
return constructEmptyObject(exec, structure);
}
JSCell* JIT_OPERATION operationNewRegexp(ExecState* exec, JSCell* regexpPtr)
{
SuperSamplerScope superSamplerScope(false);
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);
}
// The only reason for returning an UnusedPtr (instead of void) is so that we can reuse the
// existing DFG slow path generator machinery when creating the slow path for CheckTraps
// in the DFG. If a DFG slow path generator that supports a void return type is added in the
// future, we can switch to using that then.
UnusedPtr JIT_OPERATION operationHandleTraps(ExecState* exec)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(&vm, exec);
ASSERT(vm.needTrapHandling());
vm.handleTraps(exec);
return nullptr;
}
void JIT_OPERATION operationDebug(ExecState* exec, int32_t debugHookType)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(&vm, exec);
vm.interpreter->debug(exec, static_cast<DebugHookType>(debugHookType));
}
#if ENABLE(DFG_JIT)
static void updateAllPredictionsAndOptimizeAfterWarmUp(CodeBlock* codeBlock)
{
codeBlock->updateAllPredictions();
codeBlock->optimizeAfterWarmUp();
}
SlowPathReturnType JIT_OPERATION operationOptimize(ExecState* exec, uint32_t bytecodeIndex)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(&vm, exec);
// Defer GC for a while so that it doesn't run between when we enter into this
// slow path and when we figure out the state of our code block. This prevents
// a number of awkward reentrancy scenarios, including:
//
// - The optimized version of our code block being jettisoned by GC right after
// we concluded that we wanted to use it, but have not planted it into the JS
// stack yet.
//
// - An optimized version of our code block being installed just as we decided
// that it wasn't ready yet.
//
// Note that jettisoning won't happen if we already initiated OSR, because in
// that case we would have already planted the optimized code block into the JS
// stack.
DeferGCForAWhile deferGC(vm.heap);
CodeBlock* codeBlock = exec->codeBlock();
if (UNLIKELY(codeBlock->jitType() != JITCode::BaselineJIT)) {
dataLog("Unexpected code block in Baseline->DFG tier-up: ", *codeBlock, "\n");
RELEASE_ASSERT_NOT_REACHED();
}
if (bytecodeIndex) {
// If we're attempting to OSR from a loop, assume that this should be
// separately optimized.
codeBlock->m_shouldAlwaysBeInlined = false;
}
if (UNLIKELY(Options::verboseOSR())) {
dataLog(
*codeBlock, ": Entered optimize with bytecodeIndex = ", bytecodeIndex,
", executeCounter = ", codeBlock->jitExecuteCounter(),
", optimizationDelayCounter = ", codeBlock->reoptimizationRetryCounter(),
", exitCounter = ");
if (codeBlock->hasOptimizedReplacement())
dataLog(codeBlock->replacement()->osrExitCounter());
else
dataLog("N/A");
dataLog("\n");
}
if (!codeBlock->checkIfOptimizationThresholdReached()) {
CODEBLOCK_LOG_EVENT(codeBlock, "delayOptimizeToDFG", ("counter = ", codeBlock->jitExecuteCounter()));
codeBlock->updateAllPredictions();
if (UNLIKELY(Options::verboseOSR()))
dataLog("Choosing not to optimize ", *codeBlock, " yet, because the threshold hasn't been reached.\n");
return encodeResult(0, 0);
}
Debugger* debugger = codeBlock->globalObject()->debugger();
if (UNLIKELY(debugger && (debugger->isStepping() || codeBlock->baselineAlternative()->hasDebuggerRequests()))) {
CODEBLOCK_LOG_EVENT(codeBlock, "delayOptimizeToDFG", ("debugger is stepping or has requests"));
updateAllPredictionsAndOptimizeAfterWarmUp(codeBlock);
return encodeResult(0, 0);
}
if (codeBlock->m_shouldAlwaysBeInlined) {
CODEBLOCK_LOG_EVENT(codeBlock, "delayOptimizeToDFG", ("should always be inlined"));
updateAllPredictionsAndOptimizeAfterWarmUp(codeBlock);
if (UNLIKELY(Options::verboseOSR()))
dataLog("Choosing not to optimize ", *codeBlock, " yet, because m_shouldAlwaysBeInlined == true.\n");
return encodeResult(0, 0);
}
// We cannot be in the process of asynchronous compilation and also have an optimized
// replacement.
DFG::Worklist* worklist = DFG::existingGlobalDFGWorklistOrNull();
ASSERT(
!worklist
|| !(worklist->compilationState(DFG::CompilationKey(codeBlock, DFG::DFGMode)) != DFG::Worklist::NotKnown
&& codeBlock->hasOptimizedReplacement()));
DFG::Worklist::State worklistState;
if (worklist) {
// The call to DFG::Worklist::completeAllReadyPlansForVM() will complete all ready
// (i.e. compiled) code blocks. But if it completes ours, we also need to know
// what the result was so that we don't plow ahead and attempt OSR or immediate
// reoptimization. This will have already also set the appropriate JIT execution
// count threshold depending on what happened, so if the compilation was anything
// but successful we just want to return early. See the case for worklistState ==
// DFG::Worklist::Compiled, below.
// Note that we could have alternatively just called Worklist::compilationState()
// here, and if it returned Compiled, we could have then called
// completeAndScheduleOSR() below. But that would have meant that it could take
// longer for code blocks to be completed: they would only complete when *their*
// execution count trigger fired; but that could take a while since the firing is
// racy. It could also mean that code blocks that never run again after being
// compiled would sit on the worklist until next GC. That's fine, but it's
// probably a waste of memory. Our goal here is to complete code blocks as soon as
// possible in order to minimize the chances of us executing baseline code after
// optimized code is already available.
worklistState = worklist->completeAllReadyPlansForVM(
vm, DFG::CompilationKey(codeBlock, DFG::DFGMode));
} else
worklistState = DFG::Worklist::NotKnown;
if (worklistState == DFG::Worklist::Compiling) {
CODEBLOCK_LOG_EVENT(codeBlock, "delayOptimizeToDFG", ("compiling"));
// We cannot be in the process of asynchronous compilation and also have an optimized
// replacement.
RELEASE_ASSERT(!codeBlock->hasOptimizedReplacement());
codeBlock->setOptimizationThresholdBasedOnCompilationResult(CompilationDeferred);
return encodeResult(0, 0);
}
if (worklistState == DFG::Worklist::Compiled) {
// If we don't have an optimized replacement but we did just get compiled, then
// the compilation failed or was invalidated, in which case the execution count
// thresholds have already been set appropriately by
// CodeBlock::setOptimizationThresholdBasedOnCompilationResult() and we have
// nothing left to do.
if (!codeBlock->hasOptimizedReplacement()) {
CODEBLOCK_LOG_EVENT(codeBlock, "delayOptimizeToDFG", ("compiled and failed"));
codeBlock->updateAllPredictions();
if (UNLIKELY(Options::verboseOSR()))
dataLog("Code block ", *codeBlock, " was compiled but it doesn't have an optimized replacement.\n");
return encodeResult(0, 0);
}
} else if (codeBlock->hasOptimizedReplacement()) {
if (UNLIKELY(Options::verboseOSR()))
dataLog("Considering OSR ", *codeBlock, " -> ", *codeBlock->replacement(), ".\n");
// If we have an optimized replacement, then it must be the case that we entered
// cti_optimize from a loop. That's because if there's an optimized replacement,
// then all calls to this function will be relinked to the replacement and so
// the prologue OSR will never fire.
// This is an interesting threshold check. Consider that a function OSR exits
// in the middle of a loop, while having a relatively low exit count. The exit
// will reset the execution counter to some target threshold, meaning that this
// code won't be reached until that loop heats up for >=1000 executions. But then
// we do a second check here, to see if we should either reoptimize, or just
// attempt OSR entry. Hence it might even be correct for
// shouldReoptimizeFromLoopNow() to always return true. But we make it do some
// additional checking anyway, to reduce the amount of recompilation thrashing.
if (codeBlock->replacement()->shouldReoptimizeFromLoopNow()) {
CODEBLOCK_LOG_EVENT(codeBlock, "delayOptimizeToDFG", ("should reoptimize from loop now"));
if (UNLIKELY(Options::verboseOSR())) {
dataLog(
"Triggering reoptimization of ", *codeBlock,
"(", *codeBlock->replacement(), ") (in loop).\n");
}
codeBlock->replacement()->jettison(Profiler::JettisonDueToBaselineLoopReoptimizationTrigger, CountReoptimization);
return encodeResult(0, 0);
}
} else {
if (!codeBlock->shouldOptimizeNow()) {
CODEBLOCK_LOG_EVENT(codeBlock, "delayOptimizeToDFG", ("insufficient profiling"));
if (UNLIKELY(Options::verboseOSR())) {
dataLog(
"Delaying optimization for ", *codeBlock,
" because of insufficient profiling.\n");
}
return encodeResult(0, 0);
}
if (UNLIKELY(Options::verboseOSR()))
dataLog("Triggering optimized compilation of ", *codeBlock, "\n");
unsigned numVarsWithValues;
if (bytecodeIndex)
numVarsWithValues = codeBlock->m_numCalleeLocals;
else
numVarsWithValues = 0;
Operands<JSValue> mustHandleValues(codeBlock->numParameters(), numVarsWithValues);
int localsUsedForCalleeSaves = static_cast<int>(CodeBlock::llintBaselineCalleeSaveSpaceAsVirtualRegisters());
for (size_t i = 0; i < mustHandleValues.size(); ++i) {
int operand = mustHandleValues.operandForIndex(i);
if (operandIsLocal(operand) && VirtualRegister(operand).toLocal() < localsUsedForCalleeSaves)
continue;
mustHandleValues[i] = exec->uncheckedR(operand).jsValue();
}
CodeBlock* replacementCodeBlock = codeBlock->newReplacement();
CompilationResult result = DFG::compile(
vm, replacementCodeBlock, nullptr, DFG::DFGMode, bytecodeIndex,
mustHandleValues, JITToDFGDeferredCompilationCallback::create());
if (result != CompilationSuccessful) {
CODEBLOCK_LOG_EVENT(codeBlock, "delayOptimizeToDFG", ("compilation failed"));
return encodeResult(0, 0);
}
}
CodeBlock* optimizedCodeBlock = codeBlock->replacement();
ASSERT(JITCode::isOptimizingJIT(optimizedCodeBlock->jitType()));
if (void* dataBuffer = DFG::prepareOSREntry(exec, optimizedCodeBlock, bytecodeIndex)) {
CODEBLOCK_LOG_EVENT(optimizedCodeBlock, "osrEntry", ("at bc#", bytecodeIndex));
if (UNLIKELY(Options::verboseOSR())) {
dataLog(
"Performing OSR ", *codeBlock, " -> ", *optimizedCodeBlock, ".\n");
}
codeBlock->optimizeSoon();
codeBlock->unlinkedCodeBlock()->setDidOptimize(TrueTriState);
return encodeResult(vm.getCTIStub(DFG::osrEntryThunkGenerator).code().executableAddress(), dataBuffer);
}
if (UNLIKELY(Options::verboseOSR())) {
dataLog(
"Optimizing ", *codeBlock, " -> ", *codeBlock->replacement(),
" succeeded, OSR failed, after a delay of ",
codeBlock->optimizationDelayCounter(), ".\n");
}
// Count the OSR failure as a speculation failure. If this happens a lot, then
// reoptimize.
optimizedCodeBlock->countOSRExit();
// We are a lot more conservative about triggering reoptimization after OSR failure than
// before it. If we enter the optimize_from_loop trigger with a bucket full of fail
// already, then we really would like to reoptimize immediately. But this case covers
// something else: there weren't many (or any) speculation failures before, but we just
// failed to enter the speculative code because some variable had the wrong value or
// because the OSR code decided for any spurious reason that it did not want to OSR
// right now. So, we only trigger reoptimization only upon the more conservative (non-loop)
// reoptimization trigger.
if (optimizedCodeBlock->shouldReoptimizeNow()) {
CODEBLOCK_LOG_EVENT(codeBlock, "delayOptimizeToDFG", ("should reoptimize now"));
if (UNLIKELY(Options::verboseOSR())) {
dataLog(
"Triggering reoptimization of ", *codeBlock, " -> ",
*codeBlock->replacement(), " (after OSR fail).\n");
}
optimizedCodeBlock->jettison(Profiler::JettisonDueToBaselineLoopReoptimizationTriggerOnOSREntryFail, CountReoptimization);
return encodeResult(0, 0);
}
// OSR failed this time, but it might succeed next time! Let the code run a bit
// longer and then try again.
codeBlock->optimizeAfterWarmUp();
CODEBLOCK_LOG_EVENT(codeBlock, "delayOptimizeToDFG", ("OSR failed"));
return encodeResult(0, 0);
}
char* JIT_OPERATION operationTryOSREnterAtCatch(ExecState* exec, uint32_t bytecodeIndex)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(&vm, exec);
CodeBlock* optimizedReplacement = exec->codeBlock()->replacement();
switch (optimizedReplacement->jitType()) {
case JITCode::DFGJIT:
case JITCode::FTLJIT:
return static_cast<char*>(DFG::prepareCatchOSREntry(exec, optimizedReplacement, bytecodeIndex));
default:
break;
}
return nullptr;
}
char* JIT_OPERATION operationTryOSREnterAtCatchAndValueProfile(ExecState* exec, uint32_t bytecodeIndex)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(&vm, exec);
CodeBlock* codeBlock = exec->codeBlock();
CodeBlock* optimizedReplacement = codeBlock->replacement();
switch (optimizedReplacement->jitType()) {
case JITCode::DFGJIT:
case JITCode::FTLJIT:
return static_cast<char*>(DFG::prepareCatchOSREntry(exec, optimizedReplacement, bytecodeIndex));
default:
break;
}
codeBlock->ensureCatchLivenessIsComputedForBytecodeOffset(bytecodeIndex);
ValueProfileAndOperandBuffer* buffer = static_cast<ValueProfileAndOperandBuffer*>(codeBlock->instructions()[bytecodeIndex + 3].u.pointer);
buffer->forEach([&] (ValueProfileAndOperand& profile) {
profile.m_profile.m_buckets[0] = JSValue::encode(exec->uncheckedR(profile.m_operand).jsValue());
});
return nullptr;
}
#endif
void JIT_OPERATION operationPutByIndex(ExecState* exec, EncodedJSValue encodedArrayValue, int32_t index, EncodedJSValue encodedValue)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(&vm, exec);
JSValue arrayValue = JSValue::decode(encodedArrayValue);
ASSERT(isJSArray(arrayValue));
asArray(arrayValue)->putDirectIndex(exec, index, JSValue::decode(encodedValue));
}
enum class AccessorType {
Getter,
Setter
};
static void putAccessorByVal(ExecState* exec, JSObject* base, JSValue subscript, int32_t attribute, JSObject* accessor, AccessorType accessorType)
{
VM& vm = exec->vm();
auto scope = DECLARE_THROW_SCOPE(vm);
auto propertyKey = subscript.toPropertyKey(exec);
RETURN_IF_EXCEPTION(scope, void());
scope.release();
if (accessorType == AccessorType::Getter)
base->putGetter(exec, propertyKey, accessor, attribute);
else
base->putSetter(exec, propertyKey, accessor, attribute);
}
void JIT_OPERATION operationPutGetterById(ExecState* exec, JSCell* object, UniquedStringImpl* uid, int32_t options, JSCell* getter)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(&vm, exec);
ASSERT(object && object->isObject());
JSObject* baseObj = object->getObject();
ASSERT(getter->isObject());
baseObj->putGetter(exec, uid, getter, options);
}
void JIT_OPERATION operationPutSetterById(ExecState* exec, JSCell* object, UniquedStringImpl* uid, int32_t options, JSCell* setter)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(&vm, exec);
ASSERT(object && object->isObject());
JSObject* baseObj = object->getObject();
ASSERT(setter->isObject());
baseObj->putSetter(exec, uid, setter, options);
}
void JIT_OPERATION operationPutGetterByVal(ExecState* exec, JSCell* base, EncodedJSValue encodedSubscript, int32_t attribute, JSCell* getter)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(&vm, exec);
putAccessorByVal(exec, asObject(base), JSValue::decode(encodedSubscript), attribute, asObject(getter), AccessorType::Getter);
}
void JIT_OPERATION operationPutSetterByVal(ExecState* exec, JSCell* base, EncodedJSValue encodedSubscript, int32_t attribute, JSCell* setter)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(&vm, exec);
putAccessorByVal(exec, asObject(base), JSValue::decode(encodedSubscript), attribute, asObject(setter), AccessorType::Setter);
}
#if USE(JSVALUE64)
void JIT_OPERATION operationPutGetterSetter(ExecState* exec, JSCell* object, UniquedStringImpl* uid, int32_t attribute, EncodedJSValue encodedGetterValue, EncodedJSValue encodedSetterValue)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(&vm, exec);
ASSERT(object && object->isObject());
JSObject* baseObj = asObject(object);
GetterSetter* accessor = GetterSetter::create(vm, exec->lexicalGlobalObject());
JSValue getter = JSValue::decode(encodedGetterValue);
JSValue setter = JSValue::decode(encodedSetterValue);
ASSERT(getter.isObject() || getter.isUndefined());
ASSERT(setter.isObject() || setter.isUndefined());
ASSERT(getter.isObject() || setter.isObject());
if (!getter.isUndefined())
accessor->setGetter(vm, exec->lexicalGlobalObject(), asObject(getter));
if (!setter.isUndefined())
accessor->setSetter(vm, exec->lexicalGlobalObject(), asObject(setter));
baseObj->putDirectAccessor(exec, uid, accessor, attribute);
}
#else
void JIT_OPERATION operationPutGetterSetter(ExecState* exec, JSCell* object, UniquedStringImpl* uid, int32_t attribute, JSCell* getter, JSCell* setter)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(&vm, exec);
ASSERT(object && object->isObject());
JSObject* baseObj = asObject(object);
GetterSetter* accessor = GetterSetter::create(vm, exec->lexicalGlobalObject());
ASSERT(!getter || getter->isObject());
ASSERT(!setter || setter->isObject());
ASSERT(getter || setter);
if (getter)
accessor->setGetter(vm, exec->lexicalGlobalObject(), getter->getObject());
if (setter)
accessor->setSetter(vm, exec->lexicalGlobalObject(), setter->getObject());
baseObj->putDirectAccessor(exec, uid, accessor, attribute);
}
#endif
void JIT_OPERATION operationPopScope(ExecState* exec, int32_t scopeReg)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(&vm, exec);
JSScope* scope = exec->uncheckedR(scopeReg).Register::scope();
exec->uncheckedR(scopeReg) = scope->next();
}
int32_t JIT_OPERATION operationInstanceOfCustom(ExecState* exec, EncodedJSValue encodedValue, JSObject* constructor, EncodedJSValue encodedHasInstance)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(&vm, exec);
JSValue value = JSValue::decode(encodedValue);
JSValue hasInstanceValue = JSValue::decode(encodedHasInstance);
ASSERT(hasInstanceValue != exec->lexicalGlobalObject()->functionProtoHasInstanceSymbolFunction() || !constructor->structure()->typeInfo().implementsDefaultHasInstance());
if (constructor->hasInstance(exec, value, hasInstanceValue))
return 1;
return 0;
}
}
static JSValue getByVal(ExecState* exec, JSValue baseValue, JSValue subscript, ByValInfo* byValInfo, ReturnAddressPtr returnAddress)
{
VM& vm = exec->vm();
auto scope = DECLARE_THROW_SCOPE(vm);
if (LIKELY(baseValue.isCell() && subscript.isString())) {
Structure& structure = *baseValue.asCell()->structure(vm);
if (JSCell::canUseFastGetOwnProperty(structure)) {
if (RefPtr<AtomicStringImpl> existingAtomicString = asString(subscript)->toExistingAtomicString(exec)) {
if (JSValue result = baseValue.asCell()->fastGetOwnProperty(vm, structure, existingAtomicString.get())) {
ASSERT(exec->bytecodeOffset());
if (byValInfo->stubInfo && byValInfo->cachedId.impl() != existingAtomicString)
byValInfo->tookSlowPath = true;
return result;
}
}
}
}
if (subscript.isUInt32()) {
ASSERT(exec->bytecodeOffset());
byValInfo->tookSlowPath = true;
uint32_t i = subscript.asUInt32();
if (isJSString(baseValue)) {
if (asString(baseValue)->canGetIndex(i)) {
ctiPatchCallByReturnAddress(returnAddress, FunctionPtr(operationGetByValString));
scope.release();
return asString(baseValue)->getIndex(exec, i);
}
byValInfo->arrayProfile->setOutOfBounds();
} else if (baseValue.isObject()) {
JSObject* object = asObject(baseValue);
if (object->canGetIndexQuickly(i))
return object->getIndexQuickly(i);
bool skipMarkingOutOfBounds = false;
if (object->indexingType() == ArrayWithContiguous && i < object->butterfly()->publicLength()) {
// FIXME: expand this to ArrayStorage, Int32, and maybe Double:
// https://bugs.webkit.org/show_bug.cgi?id=182940
auto* globalObject = object->globalObject();
skipMarkingOutOfBounds = globalObject->isOriginalArrayStructure(object->structure()) && globalObject->arrayPrototypeChainIsSane();
}
if (!skipMarkingOutOfBounds && !CommonSlowPaths::canAccessArgumentIndexQuickly(*object, i)) {
// FIXME: This will make us think that in-bounds typed array accesses are actually
// out-of-bounds.
// https://bugs.webkit.org/show_bug.cgi?id=149886
byValInfo->arrayProfile->setOutOfBounds();
}
}
scope.release();
return baseValue.get(exec, i);
}
baseValue.requireObjectCoercible(exec);
RETURN_IF_EXCEPTION(scope, JSValue());
auto property = subscript.toPropertyKey(exec);
RETURN_IF_EXCEPTION(scope, JSValue());
ASSERT(exec->bytecodeOffset());
if (byValInfo->stubInfo && (!isStringOrSymbol(subscript) || byValInfo->cachedId != property))
byValInfo->tookSlowPath = true;
scope.release();
return baseValue.get(exec, property);
}
static OptimizationResult tryGetByValOptimize(ExecState* exec, JSValue baseValue, JSValue subscript, ByValInfo* byValInfo, ReturnAddressPtr returnAddress)
{
// See if it's worth optimizing this at all.
OptimizationResult optimizationResult = OptimizationResult::NotOptimized;
VM& vm = exec->vm();
if (baseValue.isObject() && subscript.isInt32()) {
JSObject* object = asObject(baseValue);
ASSERT(exec->bytecodeOffset());
ASSERT(!byValInfo->stubRoutine);
if (hasOptimizableIndexing(object->structure(vm))) {
// Attempt to optimize.
Structure* structure = object->structure(vm);
JITArrayMode arrayMode = jitArrayModeForStructure(structure);
if (arrayMode != byValInfo->arrayMode) {
// If we reached this case, we got an interesting array mode we did not expect when we compiled.
// Let's update the profile to do better next time.
CodeBlock* codeBlock = exec->codeBlock();
ConcurrentJSLocker locker(codeBlock->m_lock);
byValInfo->arrayProfile->computeUpdatedPrediction(locker, codeBlock, structure);
JIT::compileGetByVal(&vm, exec->codeBlock(), byValInfo, returnAddress, arrayMode);
optimizationResult = OptimizationResult::Optimized;
}
}
// If we failed to patch and we have some object that intercepts indexed get, then don't even wait until 10 times.
if (optimizationResult != OptimizationResult::Optimized && object->structure(vm)->typeInfo().interceptsGetOwnPropertySlotByIndexEvenWhenLengthIsNotZero())
optimizationResult = OptimizationResult::GiveUp;
}
if (baseValue.isObject() && isStringOrSymbol(subscript)) {
const Identifier propertyName = subscript.toPropertyKey(exec);
if (subscript.isSymbol() || !parseIndex(propertyName)) {
ASSERT(exec->bytecodeOffset());
ASSERT(!byValInfo->stubRoutine);
if (byValInfo->seen) {
if (byValInfo->cachedId == propertyName) {
JIT::compileGetByValWithCachedId(&vm, exec->codeBlock(), byValInfo, returnAddress, propertyName);
optimizationResult = OptimizationResult::Optimized;
} else {
// Seem like a generic property access site.
optimizationResult = OptimizationResult::GiveUp;
}
} else {
CodeBlock* codeBlock = exec->codeBlock();
ConcurrentJSLocker locker(codeBlock->m_lock);
byValInfo->seen = true;
byValInfo->cachedId = propertyName;
if (subscript.isSymbol())
byValInfo->cachedSymbol.set(vm, codeBlock, asSymbol(subscript));
optimizationResult = OptimizationResult::SeenOnce;
}
}
}
if (optimizationResult != OptimizationResult::Optimized && optimizationResult != OptimizationResult::SeenOnce) {
// If we take slow path more than 10 times without patching then make sure we
// never make that mistake again. For cases where we see non-index-intercepting
// objects, this gives 10 iterations worth of opportunity for us to observe
// that the get_by_val may be polymorphic. We count up slowPathCount even if
// the result is GiveUp.
if (++byValInfo->slowPathCount >= 10)
optimizationResult = OptimizationResult::GiveUp;
}
return optimizationResult;
}
extern "C" {
EncodedJSValue JIT_OPERATION operationGetByValGeneric(ExecState* exec, EncodedJSValue encodedBase, EncodedJSValue encodedSubscript, ByValInfo* byValInfo)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(&vm, exec);
JSValue baseValue = JSValue::decode(encodedBase);
JSValue subscript = JSValue::decode(encodedSubscript);
JSValue result = getByVal(exec, baseValue, subscript, byValInfo, ReturnAddressPtr(OUR_RETURN_ADDRESS));
return JSValue::encode(result);
}
EncodedJSValue JIT_OPERATION operationGetByValOptimize(ExecState* exec, EncodedJSValue encodedBase, EncodedJSValue encodedSubscript, ByValInfo* byValInfo)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(&vm, exec);
JSValue baseValue = JSValue::decode(encodedBase);
JSValue subscript = JSValue::decode(encodedSubscript);
ReturnAddressPtr returnAddress = ReturnAddressPtr(OUR_RETURN_ADDRESS);
if (tryGetByValOptimize(exec, baseValue, subscript, byValInfo, returnAddress) == OptimizationResult::GiveUp) {
// Don't ever try to optimize.
byValInfo->tookSlowPath = true;
ctiPatchCallByReturnAddress(returnAddress, FunctionPtr(operationGetByValGeneric));
}
return JSValue::encode(getByVal(exec, baseValue, subscript, byValInfo, returnAddress));
}
EncodedJSValue JIT_OPERATION operationHasIndexedPropertyDefault(ExecState* exec, EncodedJSValue encodedBase, EncodedJSValue encodedSubscript, ByValInfo* byValInfo)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(&vm, exec);
JSValue baseValue = JSValue::decode(encodedBase);
JSValue subscript = JSValue::decode(encodedSubscript);
ASSERT(baseValue.isObject());
ASSERT(subscript.isUInt32());
JSObject* object = asObject(baseValue);
bool didOptimize = false;
ASSERT(exec->bytecodeOffset());
ASSERT(!byValInfo->stubRoutine);
if (hasOptimizableIndexing(object->structure(vm))) {
// Attempt to optimize.
JITArrayMode arrayMode = jitArrayModeForStructure(object->structure(vm));
if (arrayMode != byValInfo->arrayMode) {
JIT::compileHasIndexedProperty(&vm, exec->codeBlock(), byValInfo, ReturnAddressPtr(OUR_RETURN_ADDRESS), arrayMode);
didOptimize = true;
}
}
if (!didOptimize) {
// If we take slow path more than 10 times without patching then make sure we
// never make that mistake again. Or, if we failed to patch and we have some object
// that intercepts indexed get, then don't even wait until 10 times. For cases
// where we see non-index-intercepting objects, this gives 10 iterations worth of
// opportunity for us to observe that the get_by_val may be polymorphic.
if (++byValInfo->slowPathCount >= 10
|| object->structure(vm)->typeInfo().interceptsGetOwnPropertySlotByIndexEvenWhenLengthIsNotZero()) {
// Don't ever try to optimize.
ctiPatchCallByReturnAddress(ReturnAddressPtr(OUR_RETURN_ADDRESS), FunctionPtr(operationHasIndexedPropertyGeneric));
}
}
uint32_t index = subscript.asUInt32();
if (object->canGetIndexQuickly(index))
return JSValue::encode(JSValue(JSValue::JSTrue));
if (!CommonSlowPaths::canAccessArgumentIndexQuickly(*object, index)) {
// FIXME: This will make us think that in-bounds typed array accesses are actually
// out-of-bounds.
// https://bugs.webkit.org/show_bug.cgi?id=149886
byValInfo->arrayProfile->setOutOfBounds();
}
return JSValue::encode(jsBoolean(object->hasPropertyGeneric(exec, index, PropertySlot::InternalMethodType::GetOwnProperty)));
}
EncodedJSValue JIT_OPERATION operationHasIndexedPropertyGeneric(ExecState* exec, EncodedJSValue encodedBase, EncodedJSValue encodedSubscript, ByValInfo* byValInfo)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(&vm, exec);
JSValue baseValue = JSValue::decode(encodedBase);
JSValue subscript = JSValue::decode(encodedSubscript);
ASSERT(baseValue.isObject());
ASSERT(subscript.isUInt32());
JSObject* object = asObject(baseValue);
uint32_t index = subscript.asUInt32();
if (object->canGetIndexQuickly(index))
return JSValue::encode(JSValue(JSValue::JSTrue));
if (!CommonSlowPaths::canAccessArgumentIndexQuickly(*object, index)) {
// FIXME: This will make us think that in-bounds typed array accesses are actually
// out-of-bounds.
// https://bugs.webkit.org/show_bug.cgi?id=149886
byValInfo->arrayProfile->setOutOfBounds();
}
return JSValue::encode(jsBoolean(object->hasPropertyGeneric(exec, subscript.asUInt32(), PropertySlot::InternalMethodType::GetOwnProperty)));
}
EncodedJSValue JIT_OPERATION operationGetByValString(ExecState* exec, EncodedJSValue encodedBase, EncodedJSValue encodedSubscript, ByValInfo* byValInfo)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(&vm, exec);
auto scope = DECLARE_THROW_SCOPE(vm);
JSValue baseValue = JSValue::decode(encodedBase);
JSValue subscript = JSValue::decode(encodedSubscript);
JSValue result;
if (LIKELY(subscript.isUInt32())) {
uint32_t i = subscript.asUInt32();
if (isJSString(baseValue) && asString(baseValue)->canGetIndex(i)) {
scope.release();
return JSValue::encode(asString(baseValue)->getIndex(exec, i));
}
result = baseValue.get(exec, i);
RETURN_IF_EXCEPTION(scope, encodedJSValue());
if (!isJSString(baseValue)) {
ASSERT(exec->bytecodeOffset());
ctiPatchCallByReturnAddress(ReturnAddressPtr(OUR_RETURN_ADDRESS), FunctionPtr(byValInfo->stubRoutine ? operationGetByValGeneric : operationGetByValOptimize));
}
} else {
baseValue.requireObjectCoercible(exec);
RETURN_IF_EXCEPTION(scope, encodedJSValue());
auto property = subscript.toPropertyKey(exec);
RETURN_IF_EXCEPTION(scope, encodedJSValue());
scope.release();
result = baseValue.get(exec, property);
}
return JSValue::encode(result);
}
EncodedJSValue JIT_OPERATION operationDeleteByIdJSResult(ExecState* exec, EncodedJSValue base, UniquedStringImpl* uid)
{
return JSValue::encode(jsBoolean(operationDeleteById(exec, base, uid)));
}
size_t JIT_OPERATION operationDeleteById(ExecState* exec, EncodedJSValue encodedBase, UniquedStringImpl* uid)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(&vm, exec);
auto scope = DECLARE_THROW_SCOPE(vm);
JSObject* baseObj = JSValue::decode(encodedBase).toObject(exec);
RETURN_IF_EXCEPTION(scope, false);
if (!baseObj)
return false;
bool couldDelete = baseObj->methodTable(vm)->deleteProperty(baseObj, exec, Identifier::fromUid(&vm, uid));
RETURN_IF_EXCEPTION(scope, false);
if (!couldDelete && exec->codeBlock()->isStrictMode())
throwTypeError(exec, scope, ASCIILiteral(UnableToDeletePropertyError));
return couldDelete;
}
EncodedJSValue JIT_OPERATION operationDeleteByValJSResult(ExecState* exec, EncodedJSValue base, EncodedJSValue key)
{
return JSValue::encode(jsBoolean(operationDeleteByVal(exec, base, key)));
}
size_t JIT_OPERATION operationDeleteByVal(ExecState* exec, EncodedJSValue encodedBase, EncodedJSValue encodedKey)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(&vm, exec);
auto scope = DECLARE_THROW_SCOPE(vm);
JSObject* baseObj = JSValue::decode(encodedBase).toObject(exec);
RETURN_IF_EXCEPTION(scope, false);
JSValue key = JSValue::decode(encodedKey);
if (!baseObj)
return false;
bool couldDelete;
uint32_t index;
if (key.getUInt32(index))
couldDelete = baseObj->methodTable(vm)->deletePropertyByIndex(baseObj, exec, index);
else {
Identifier property = key.toPropertyKey(exec);
RETURN_IF_EXCEPTION(scope, false);
couldDelete = baseObj->methodTable(vm)->deleteProperty(baseObj, exec, property);
}
RETURN_IF_EXCEPTION(scope, false);
if (!couldDelete && exec->codeBlock()->isStrictMode())
throwTypeError(exec, scope, ASCIILiteral(UnableToDeletePropertyError));
return couldDelete;
}
JSCell* JIT_OPERATION operationPushWithScope(ExecState* exec, JSCell* currentScopeCell, EncodedJSValue objectValue)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(&vm, exec);
auto scope = DECLARE_THROW_SCOPE(vm);
JSObject* object = JSValue::decode(objectValue).toObject(exec);
RETURN_IF_EXCEPTION(scope, nullptr);
JSScope* currentScope = jsCast<JSScope*>(currentScopeCell);
return JSWithScope::create(vm, exec->lexicalGlobalObject(), currentScope, object);
}
JSCell* JIT_OPERATION operationPushWithScopeObject(ExecState* exec, JSCell* currentScopeCell, JSObject* object)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(&vm, exec);
JSScope* currentScope = jsCast<JSScope*>(currentScopeCell);
return JSWithScope::create(vm, exec->lexicalGlobalObject(), currentScope, object);
}
EncodedJSValue JIT_OPERATION operationInstanceOf(ExecState* exec, EncodedJSValue encodedValue, EncodedJSValue encodedProto)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(&vm, exec);
JSValue value = JSValue::decode(encodedValue);
JSValue proto = JSValue::decode(encodedProto);
bool result = JSObject::defaultHasInstance(exec, value, proto);
return JSValue::encode(jsBoolean(result));
}
int32_t JIT_OPERATION operationSizeFrameForForwardArguments(ExecState* exec, EncodedJSValue, int32_t numUsedStackSlots, int32_t)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(&vm, exec);
return sizeFrameForForwardArguments(exec, vm, numUsedStackSlots);
}
int32_t JIT_OPERATION operationSizeFrameForVarargs(ExecState* exec, EncodedJSValue encodedArguments, int32_t numUsedStackSlots, int32_t firstVarArgOffset)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(&vm, exec);
JSValue arguments = JSValue::decode(encodedArguments);
return sizeFrameForVarargs(exec, vm, arguments, numUsedStackSlots, firstVarArgOffset);
}
CallFrame* JIT_OPERATION operationSetupForwardArgumentsFrame(ExecState* exec, CallFrame* newCallFrame, EncodedJSValue, int32_t, int32_t length)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(&vm, exec);
setupForwardArgumentsFrame(exec, newCallFrame, length);
return newCallFrame;
}
CallFrame* JIT_OPERATION operationSetupVarargsFrame(ExecState* exec, CallFrame* newCallFrame, EncodedJSValue encodedArguments, int32_t firstVarArgOffset, int32_t length)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(&vm, exec);
JSValue arguments = JSValue::decode(encodedArguments);
setupVarargsFrame(exec, newCallFrame, arguments, firstVarArgOffset, length);
return newCallFrame;
}
char* JIT_OPERATION operationSwitchCharWithUnknownKeyType(ExecState* exec, EncodedJSValue encodedKey, size_t tableIndex)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(&vm, exec);
JSValue key = JSValue::decode(encodedKey);
CodeBlock* codeBlock = exec->codeBlock();
SimpleJumpTable& jumpTable = codeBlock->switchJumpTable(tableIndex);
void* result = jumpTable.ctiDefault.executableAddress();
if (key.isString()) {
StringImpl* value = asString(key)->value(exec).impl();
if (value->length() == 1)
result = jumpTable.ctiForValue((*value)[0]).executableAddress();
}
return reinterpret_cast<char*>(result);
}
char* JIT_OPERATION operationSwitchImmWithUnknownKeyType(ExecState* exec, EncodedJSValue encodedKey, size_t tableIndex)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(&vm, exec);
JSValue key = JSValue::decode(encodedKey);
CodeBlock* codeBlock = exec->codeBlock();
SimpleJumpTable& jumpTable = codeBlock->switchJumpTable(tableIndex);
void* result;
if (key.isInt32())
result = jumpTable.ctiForValue(key.asInt32()).executableAddress();
else if (key.isDouble() && key.asDouble() == static_cast<int32_t>(key.asDouble()))
result = jumpTable.ctiForValue(static_cast<int32_t>(key.asDouble())).executableAddress();
else
result = jumpTable.ctiDefault.executableAddress();
return reinterpret_cast<char*>(result);
}
char* JIT_OPERATION operationSwitchStringWithUnknownKeyType(ExecState* exec, EncodedJSValue encodedKey, size_t tableIndex)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(&vm, exec);
JSValue key = JSValue::decode(encodedKey);
CodeBlock* codeBlock = exec->codeBlock();
void* result;
StringJumpTable& jumpTable = codeBlock->stringSwitchJumpTable(tableIndex);
if (key.isString()) {
StringImpl* value = asString(key)->value(exec).impl();
result = jumpTable.ctiForValue(value).executableAddress();
} else
result = jumpTable.ctiDefault.executableAddress();
return reinterpret_cast<char*>(result);
}
EncodedJSValue JIT_OPERATION operationGetFromScope(ExecState* exec, Instruction* bytecodePC)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(&vm, exec);
auto throwScope = DECLARE_THROW_SCOPE(vm);
CodeBlock* codeBlock = exec->codeBlock();
Instruction* pc = bytecodePC;
const Identifier& ident = codeBlock->identifier(pc[3].u.operand);
JSObject* scope = jsCast<JSObject*>(exec->uncheckedR(pc[2].u.operand).jsValue());
GetPutInfo getPutInfo(pc[4].u.operand);
// ModuleVar is always converted to ClosureVar for get_from_scope.
ASSERT(getPutInfo.resolveType() != ModuleVar);
throwScope.release();
return JSValue::encode(scope->getPropertySlot(exec, ident, [&] (bool found, PropertySlot& slot) -> JSValue {
if (!found) {
if (getPutInfo.resolveMode() == ThrowIfNotFound)
throwException(exec, throwScope, createUndefinedVariableError(exec, ident));
return jsUndefined();
}
JSValue result = JSValue();
if (scope->isGlobalLexicalEnvironment()) {
// When we can't statically prove we need a TDZ check, we must perform the check on the slow path.
result = slot.getValue(exec, ident);
if (result == jsTDZValue()) {
throwException(exec, throwScope, createTDZError(exec));
return jsUndefined();
}
}
CommonSlowPaths::tryCacheGetFromScopeGlobal(exec, vm, pc, scope, slot, ident);
if (!result)
return slot.getValue(exec, ident);
return result;
}));
}
void JIT_OPERATION operationPutToScope(ExecState* exec, Instruction* bytecodePC)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(&vm, exec);
auto throwScope = DECLARE_THROW_SCOPE(vm);
Instruction* pc = bytecodePC;
CodeBlock* codeBlock = exec->codeBlock();
const Identifier& ident = codeBlock->identifier(pc[2].u.operand);
JSObject* scope = jsCast<JSObject*>(exec->uncheckedR(pc[1].u.operand).jsValue());
JSValue value = exec->r(pc[3].u.operand).jsValue();
GetPutInfo getPutInfo = GetPutInfo(pc[4].u.operand);
// ModuleVar does not keep the scope register value alive in DFG.
ASSERT(getPutInfo.resolveType() != ModuleVar);
if (getPutInfo.resolveType() == LocalClosureVar) {
JSLexicalEnvironment* environment = jsCast<JSLexicalEnvironment*>(scope);
environment->variableAt(ScopeOffset(pc[6].u.operand)).set(vm, environment, value);
if (WatchpointSet* set = pc[5].u.watchpointSet)
set->touch(vm, "Executed op_put_scope<LocalClosureVar>");
return;
}
bool hasProperty = scope->hasProperty(exec, ident);
EXCEPTION_ASSERT(!throwScope.exception() || !hasProperty);
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, codeBlock->isStrictMode(), PutPropertySlot::UnknownContext, isInitialization(getPutInfo.initializationMode()));
scope->methodTable(vm)->put(scope, exec, ident, value, slot);
RETURN_IF_EXCEPTION(throwScope, void());
CommonSlowPaths::tryCachePutToScopeGlobal(exec, codeBlock, pc, scope, getPutInfo, slot, ident);
}
void JIT_OPERATION operationThrow(ExecState* exec, EncodedJSValue encodedExceptionValue)
{
VM* vm = &exec->vm();
NativeCallFrameTracer tracer(vm, exec);
auto scope = DECLARE_THROW_SCOPE(*vm);
JSValue exceptionValue = JSValue::decode(encodedExceptionValue);
throwException(exec, scope, exceptionValue);
// Results stored out-of-band in vm.targetMachinePCForThrow & vm.callFrameForCatch
genericUnwind(vm, exec);
}
char* JIT_OPERATION operationReallocateButterflyToHavePropertyStorageWithInitialCapacity(ExecState* exec, JSObject* object)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(&vm, exec);
ASSERT(!object->structure()->outOfLineCapacity());
Butterfly* result = object->allocateMoreOutOfLineStorage(vm, 0, initialOutOfLineCapacity);
object->nukeStructureAndSetButterfly(vm, object->structureID(), result, object->indexingType());
return reinterpret_cast<char*>(result);
}
char* JIT_OPERATION operationReallocateButterflyToGrowPropertyStorage(ExecState* exec, JSObject* object, size_t newSize)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(&vm, exec);
Butterfly* result = object->allocateMoreOutOfLineStorage(vm, object->structure()->outOfLineCapacity(), newSize);
object->nukeStructureAndSetButterfly(vm, object->structureID(), result, object->indexingType());
return reinterpret_cast<char*>(result);
}
void JIT_OPERATION operationOSRWriteBarrier(ExecState* exec, JSCell* cell)
{
VM* vm = &exec->vm();
NativeCallFrameTracer tracer(vm, exec);
vm->heap.writeBarrier(cell);
}
void JIT_OPERATION operationWriteBarrierSlowPath(ExecState* exec, JSCell* cell)
{
VM* vm = &exec->vm();
NativeCallFrameTracer tracer(vm, exec);
vm->heap.writeBarrierSlowPath(cell);
}
void JIT_OPERATION lookupExceptionHandler(VM* vm, ExecState* exec)
{
NativeCallFrameTracer tracer(vm, exec);
genericUnwind(vm, exec);
ASSERT(vm->targetMachinePCForThrow);
}
void JIT_OPERATION lookupExceptionHandlerFromCallerFrame(VM* vm, ExecState* exec)
{
vm->topCallFrame = exec->callerFrame();
genericUnwind(vm, exec, UnwindFromCallerFrame);
ASSERT(vm->targetMachinePCForThrow);
}
void JIT_OPERATION operationVMHandleException(ExecState* exec)
{
VM* vm = &exec->vm();
NativeCallFrameTracer tracer(vm, exec);
genericUnwind(vm, exec);
}
// This function "should" just take the ExecState*, but doing so would make it more difficult
// to call from exception check sites. So, unlike all of our other functions, we allow
// ourselves to play some gnarly ABI tricks just to simplify the calling convention. This is
// particularly safe here since this is never called on the critical path - it's only for
// testing.
void JIT_OPERATION operationExceptionFuzz(ExecState* exec)
{
VM* vm = &exec->vm();
NativeCallFrameTracer tracer(vm, exec);
auto scope = DECLARE_THROW_SCOPE(*vm);
UNUSED_PARAM(scope);
#if COMPILER(GCC_OR_CLANG)
void* returnPC = __builtin_return_address(0);
doExceptionFuzzing(exec, scope, "JITOperations", returnPC);
#endif // COMPILER(GCC_OR_CLANG)
}
ALWAYS_INLINE static EncodedJSValue unprofiledAdd(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(jsAdd(exec, op1, op2));
}
ALWAYS_INLINE static EncodedJSValue profiledAdd(ExecState* exec, EncodedJSValue encodedOp1, EncodedJSValue encodedOp2, ArithProfile& arithProfile)
{
VM* vm = &exec->vm();
NativeCallFrameTracer tracer(vm, exec);
JSValue op1 = JSValue::decode(encodedOp1);
JSValue op2 = JSValue::decode(encodedOp2);
arithProfile.observeLHSAndRHS(op1, op2);
JSValue result = jsAdd(exec, op1, op2);
arithProfile.observeResult(result);
return JSValue::encode(result);
}
EncodedJSValue JIT_OPERATION operationValueAdd(ExecState* exec, EncodedJSValue encodedOp1, EncodedJSValue encodedOp2)
{
return unprofiledAdd(exec, encodedOp1, encodedOp2);
}
EncodedJSValue JIT_OPERATION operationValueAddProfiled(ExecState* exec, EncodedJSValue encodedOp1, EncodedJSValue encodedOp2, ArithProfile* arithProfile)
{
ASSERT(arithProfile);
return profiledAdd(exec, encodedOp1, encodedOp2, *arithProfile);
}
EncodedJSValue JIT_OPERATION operationValueAddProfiledOptimize(ExecState* exec, EncodedJSValue encodedOp1, EncodedJSValue encodedOp2, JITAddIC* addIC)
{
VM* vm = &exec->vm();
NativeCallFrameTracer tracer(vm, exec);
JSValue op1 = JSValue::decode(encodedOp1);
JSValue op2 = JSValue::decode(encodedOp2);
ArithProfile* arithProfile = addIC->arithProfile();
ASSERT(arithProfile);
arithProfile->observeLHSAndRHS(op1, op2);
auto nonOptimizeVariant = operationValueAddProfiledNoOptimize;
addIC->generateOutOfLine(exec->codeBlock(), nonOptimizeVariant);
#if ENABLE(MATH_IC_STATS)
exec->codeBlock()->dumpMathICStats();
#endif
JSValue result = jsAdd(exec, op1, op2);
arithProfile->observeResult(result);
return JSValue::encode(result);
}
EncodedJSValue JIT_OPERATION operationValueAddProfiledNoOptimize(ExecState* exec, EncodedJSValue encodedOp1, EncodedJSValue encodedOp2, JITAddIC* addIC)
{
VM* vm = &exec->vm();
NativeCallFrameTracer tracer(vm, exec);
ArithProfile* arithProfile = addIC->arithProfile();
ASSERT(arithProfile);
return profiledAdd(exec, encodedOp1, encodedOp2, *arithProfile);
}
EncodedJSValue JIT_OPERATION operationValueAddOptimize(ExecState* exec, EncodedJSValue encodedOp1, EncodedJSValue encodedOp2, JITAddIC* addIC)
{
VM* vm = &exec->vm();
NativeCallFrameTracer tracer(vm, exec);
JSValue op1 = JSValue::decode(encodedOp1);
JSValue op2 = JSValue::decode(encodedOp2);
auto nonOptimizeVariant = operationValueAddNoOptimize;
if (ArithProfile* arithProfile = addIC->arithProfile())
arithProfile->observeLHSAndRHS(op1, op2);
addIC->generateOutOfLine(exec->codeBlock(), nonOptimizeVariant);
#if ENABLE(MATH_IC_STATS)
exec->codeBlock()->dumpMathICStats();
#endif
return JSValue::encode(jsAdd(exec, op1, op2));
}
EncodedJSValue JIT_OPERATION operationValueAddNoOptimize(ExecState* exec, EncodedJSValue encodedOp1, EncodedJSValue encodedOp2, JITAddIC*)
{
VM* vm = &exec->vm();
NativeCallFrameTracer tracer(vm, exec);
JSValue op1 = JSValue::decode(encodedOp1);
JSValue op2 = JSValue::decode(encodedOp2);
JSValue result = jsAdd(exec, op1, op2);
return JSValue::encode(result);
}
ALWAYS_INLINE static EncodedJSValue unprofiledMul(VM& vm, ExecState* exec, EncodedJSValue encodedOp1, EncodedJSValue encodedOp2)
{
auto scope = DECLARE_THROW_SCOPE(vm);
JSValue op1 = JSValue::decode(encodedOp1);
JSValue op2 = JSValue::decode(encodedOp2);
double a = op1.toNumber(exec);
RETURN_IF_EXCEPTION(scope, encodedJSValue());
scope.release();
double b = op2.toNumber(exec);
return JSValue::encode(jsNumber(a * b));
}
ALWAYS_INLINE static EncodedJSValue profiledMul(VM& vm, ExecState* exec, EncodedJSValue encodedOp1, EncodedJSValue encodedOp2, ArithProfile& arithProfile, bool shouldObserveLHSAndRHSTypes = true)
{
auto scope = DECLARE_THROW_SCOPE(vm);
JSValue op1 = JSValue::decode(encodedOp1);
JSValue op2 = JSValue::decode(encodedOp2);
if (shouldObserveLHSAndRHSTypes)
arithProfile.observeLHSAndRHS(op1, op2);
double a = op1.toNumber(exec);
RETURN_IF_EXCEPTION(scope, encodedJSValue());
double b = op2.toNumber(exec);
RETURN_IF_EXCEPTION(scope, encodedJSValue());
JSValue result = jsNumber(a * b);
arithProfile.observeResult(result);
return JSValue::encode(result);
}
EncodedJSValue JIT_OPERATION operationValueMul(ExecState* exec, EncodedJSValue encodedOp1, EncodedJSValue encodedOp2)
{
VM* vm = &exec->vm();
NativeCallFrameTracer tracer(vm, exec);
return unprofiledMul(*vm, exec, encodedOp1, encodedOp2);
}
EncodedJSValue JIT_OPERATION operationValueMulNoOptimize(ExecState* exec, EncodedJSValue encodedOp1, EncodedJSValue encodedOp2, JITMulIC*)
{
VM* vm = &exec->vm();
NativeCallFrameTracer tracer(vm, exec);
return unprofiledMul(*vm, exec, encodedOp1, encodedOp2);
}
EncodedJSValue JIT_OPERATION operationValueMulOptimize(ExecState* exec, EncodedJSValue encodedOp1, EncodedJSValue encodedOp2, JITMulIC* mulIC)
{
VM* vm = &exec->vm();
NativeCallFrameTracer tracer(vm, exec);
auto nonOptimizeVariant = operationValueMulNoOptimize;
if (ArithProfile* arithProfile = mulIC->arithProfile())
arithProfile->observeLHSAndRHS(JSValue::decode(encodedOp1), JSValue::decode(encodedOp2));
mulIC->generateOutOfLine(exec->codeBlock(), nonOptimizeVariant);
#if ENABLE(MATH_IC_STATS)
exec->codeBlock()->dumpMathICStats();
#endif
return unprofiledMul(*vm, exec, encodedOp1, encodedOp2);
}
EncodedJSValue JIT_OPERATION operationValueMulProfiled(ExecState* exec, EncodedJSValue encodedOp1, EncodedJSValue encodedOp2, ArithProfile* arithProfile)
{
VM* vm = &exec->vm();
NativeCallFrameTracer tracer(vm, exec);
ASSERT(arithProfile);
return profiledMul(*vm, exec, encodedOp1, encodedOp2, *arithProfile);
}
EncodedJSValue JIT_OPERATION operationValueMulProfiledOptimize(ExecState* exec, EncodedJSValue encodedOp1, EncodedJSValue encodedOp2, JITMulIC* mulIC)
{
VM* vm = &exec->vm();
NativeCallFrameTracer tracer(vm, exec);
ArithProfile* arithProfile = mulIC->arithProfile();
ASSERT(arithProfile);
arithProfile->observeLHSAndRHS(JSValue::decode(encodedOp1), JSValue::decode(encodedOp2));
auto nonOptimizeVariant = operationValueMulProfiledNoOptimize;
mulIC->generateOutOfLine(exec->codeBlock(), nonOptimizeVariant);
#if ENABLE(MATH_IC_STATS)
exec->codeBlock()->dumpMathICStats();
#endif
return profiledMul(*vm, exec, encodedOp1, encodedOp2, *arithProfile, false);
}
EncodedJSValue JIT_OPERATION operationValueMulProfiledNoOptimize(ExecState* exec, EncodedJSValue encodedOp1, EncodedJSValue encodedOp2, JITMulIC* mulIC)
{
VM* vm = &exec->vm();
NativeCallFrameTracer tracer(vm, exec);
ArithProfile* arithProfile = mulIC->arithProfile();
ASSERT(arithProfile);
return profiledMul(*vm, exec, encodedOp1, encodedOp2, *arithProfile);
}
ALWAYS_INLINE static EncodedJSValue unprofiledNegate(ExecState* exec, EncodedJSValue encodedOperand)
{
VM& vm = exec->vm();
auto scope = DECLARE_THROW_SCOPE(vm);
NativeCallFrameTracer tracer(&vm, exec);
JSValue operand = JSValue::decode(encodedOperand);
double number = operand.toNumber(exec);
RETURN_IF_EXCEPTION(scope, encodedJSValue());
return JSValue::encode(jsNumber(-number));
}
ALWAYS_INLINE static EncodedJSValue profiledNegate(ExecState* exec, EncodedJSValue encodedOperand, ArithProfile& arithProfile)
{
VM& vm = exec->vm();
auto scope = DECLARE_THROW_SCOPE(vm);
NativeCallFrameTracer tracer(&vm, exec);
JSValue operand = JSValue::decode(encodedOperand);
arithProfile.observeLHS(operand);
double number = operand.toNumber(exec);
RETURN_IF_EXCEPTION(scope, encodedJSValue());
JSValue result = jsNumber(-number);
arithProfile.observeResult(result);
return JSValue::encode(result);
}
EncodedJSValue JIT_OPERATION operationArithNegate(ExecState* exec, EncodedJSValue operand)
{
return unprofiledNegate(exec, operand);
}
EncodedJSValue JIT_OPERATION operationArithNegateProfiled(ExecState* exec, EncodedJSValue operand, ArithProfile* arithProfile)
{
ASSERT(arithProfile);
return profiledNegate(exec, operand, *arithProfile);
}
EncodedJSValue JIT_OPERATION operationArithNegateProfiledOptimize(ExecState* exec, EncodedJSValue encodedOperand, JITNegIC* negIC)
{
VM& vm = exec->vm();
auto scope = DECLARE_THROW_SCOPE(vm);
NativeCallFrameTracer tracer(&vm, exec);
JSValue operand = JSValue::decode(encodedOperand);
ArithProfile* arithProfile = negIC->arithProfile();
ASSERT(arithProfile);
arithProfile->observeLHS(operand);
negIC->generateOutOfLine(exec->codeBlock(), operationArithNegateProfiled);
#if ENABLE(MATH_IC_STATS)
exec->codeBlock()->dumpMathICStats();
#endif
double number = operand.toNumber(exec);
RETURN_IF_EXCEPTION(scope, encodedJSValue());
JSValue result = jsNumber(-number);
arithProfile->observeResult(result);
return JSValue::encode(result);
}
EncodedJSValue JIT_OPERATION operationArithNegateOptimize(ExecState* exec, EncodedJSValue encodedOperand, JITNegIC* negIC)
{
VM& vm = exec->vm();
auto scope = DECLARE_THROW_SCOPE(vm);
NativeCallFrameTracer tracer(&vm, exec);
JSValue operand = JSValue::decode(encodedOperand);
if (ArithProfile* arithProfile = negIC->arithProfile())
arithProfile->observeLHS(operand);
negIC->generateOutOfLine(exec->codeBlock(), operationArithNegate);
#if ENABLE(MATH_IC_STATS)
exec->codeBlock()->dumpMathICStats();
#endif
double number = operand.toNumber(exec);
RETURN_IF_EXCEPTION(scope, encodedJSValue());
return JSValue::encode(jsNumber(-number));
}
ALWAYS_INLINE static EncodedJSValue unprofiledSub(VM& vm, ExecState* exec, EncodedJSValue encodedOp1, EncodedJSValue encodedOp2)
{
auto scope = DECLARE_THROW_SCOPE(vm);
JSValue op1 = JSValue::decode(encodedOp1);
JSValue op2 = JSValue::decode(encodedOp2);
double a = op1.toNumber(exec);
RETURN_IF_EXCEPTION(scope, encodedJSValue());
scope.release();
double b = op2.toNumber(exec);
return JSValue::encode(jsNumber(a - b));
}
ALWAYS_INLINE static EncodedJSValue profiledSub(VM& vm, ExecState* exec, EncodedJSValue encodedOp1, EncodedJSValue encodedOp2, ArithProfile& arithProfile, bool shouldObserveLHSAndRHSTypes = true)
{
auto scope = DECLARE_THROW_SCOPE(vm);
JSValue op1 = JSValue::decode(encodedOp1);
JSValue op2 = JSValue::decode(encodedOp2);
if (shouldObserveLHSAndRHSTypes)
arithProfile.observeLHSAndRHS(op1, op2);
double a = op1.toNumber(exec);
RETURN_IF_EXCEPTION(scope, encodedJSValue());
double b = op2.toNumber(exec);
RETURN_IF_EXCEPTION(scope, encodedJSValue());
JSValue result = jsNumber(a - b);
arithProfile.observeResult(result);
return JSValue::encode(result);
}
EncodedJSValue JIT_OPERATION operationValueSub(ExecState* exec, EncodedJSValue encodedOp1, EncodedJSValue encodedOp2)
{
VM* vm = &exec->vm();
NativeCallFrameTracer tracer(vm, exec);
return unprofiledSub(*vm, exec, encodedOp1, encodedOp2);
}
EncodedJSValue JIT_OPERATION operationValueSubProfiled(ExecState* exec, EncodedJSValue encodedOp1, EncodedJSValue encodedOp2, ArithProfile* arithProfile)
{
ASSERT(arithProfile);
VM* vm = &exec->vm();
NativeCallFrameTracer tracer(vm, exec);
return profiledSub(*vm, exec, encodedOp1, encodedOp2, *arithProfile);
}
EncodedJSValue JIT_OPERATION operationValueSubOptimize(ExecState* exec, EncodedJSValue encodedOp1, EncodedJSValue encodedOp2, JITSubIC* subIC)
{
VM* vm = &exec->vm();
NativeCallFrameTracer tracer(vm, exec);
auto nonOptimizeVariant = operationValueSubNoOptimize;
if (ArithProfile* arithProfile = subIC->arithProfile())
arithProfile->observeLHSAndRHS(JSValue::decode(encodedOp1), JSValue::decode(encodedOp2));
subIC->generateOutOfLine(exec->codeBlock(), nonOptimizeVariant);
#if ENABLE(MATH_IC_STATS)
exec->codeBlock()->dumpMathICStats();
#endif
return unprofiledSub(*vm, exec, encodedOp1, encodedOp2);
}
EncodedJSValue JIT_OPERATION operationValueSubNoOptimize(ExecState* exec, EncodedJSValue encodedOp1, EncodedJSValue encodedOp2, JITSubIC*)
{
VM* vm = &exec->vm();
NativeCallFrameTracer tracer(vm, exec);
return unprofiledSub(*vm, exec, encodedOp1, encodedOp2);
}
EncodedJSValue JIT_OPERATION operationValueSubProfiledOptimize(ExecState* exec, EncodedJSValue encodedOp1, EncodedJSValue encodedOp2, JITSubIC* subIC)
{
VM* vm = &exec->vm();
NativeCallFrameTracer tracer(vm, exec);
ArithProfile* arithProfile = subIC->arithProfile();
ASSERT(arithProfile);
arithProfile->observeLHSAndRHS(JSValue::decode(encodedOp1), JSValue::decode(encodedOp2));
auto nonOptimizeVariant = operationValueSubProfiledNoOptimize;
subIC->generateOutOfLine(exec->codeBlock(), nonOptimizeVariant);
#if ENABLE(MATH_IC_STATS)
exec->codeBlock()->dumpMathICStats();
#endif
return profiledSub(*vm, exec, encodedOp1, encodedOp2, *arithProfile, false);
}
EncodedJSValue JIT_OPERATION operationValueSubProfiledNoOptimize(ExecState* exec, EncodedJSValue encodedOp1, EncodedJSValue encodedOp2, JITSubIC* subIC)
{
VM* vm = &exec->vm();
NativeCallFrameTracer tracer(vm, exec);
ArithProfile* arithProfile = subIC->arithProfile();
ASSERT(arithProfile);
return profiledSub(*vm, exec, encodedOp1, encodedOp2, *arithProfile);
}
void JIT_OPERATION operationProcessTypeProfilerLog(ExecState* exec)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(&vm, exec);
vm.typeProfilerLog()->processLogEntries(ASCIILiteral("Log Full, called from inside baseline JIT"));
}
void JIT_OPERATION operationProcessShadowChickenLog(ExecState* exec)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(&vm, exec);
vm.shadowChicken().update(vm, exec);
}
int32_t JIT_OPERATION operationCheckIfExceptionIsUncatchableAndNotifyProfiler(ExecState* exec)
{
VM& vm = exec->vm();
NativeCallFrameTracer tracer(&vm, exec);
auto scope = DECLARE_THROW_SCOPE(vm);
RELEASE_ASSERT(!!scope.exception());
if (isTerminatedExecutionException(vm, scope.exception())) {
genericUnwind(&vm, exec);
return 1;
}
return 0;
}
} // extern "C"
// Note: getHostCallReturnValueWithExecState() needs to be placed before the
// definition of getHostCallReturnValue() below because the Windows build
// requires it.
extern "C" EncodedJSValue HOST_CALL_RETURN_VALUE_OPTION getHostCallReturnValueWithExecState(ExecState* exec)
{
if (!exec)
return JSValue::encode(JSValue());
return JSValue::encode(exec->vm().hostCallReturnValue);
}
#if COMPILER(GCC_OR_CLANG) && CPU(X86_64)
asm (
".globl " SYMBOL_STRING(getHostCallReturnValue) "\n"
HIDE_SYMBOL(getHostCallReturnValue) "\n"
SYMBOL_STRING(getHostCallReturnValue) ":" "\n"
"lea -8(%rsp), %rdi\n"
"jmp " LOCAL_REFERENCE(getHostCallReturnValueWithExecState) "\n"
);
#elif COMPILER(GCC_OR_CLANG) && CPU(X86)
asm (
".text" "\n" \
".globl " SYMBOL_STRING(getHostCallReturnValue) "\n"
HIDE_SYMBOL(getHostCallReturnValue) "\n"
SYMBOL_STRING(getHostCallReturnValue) ":" "\n"
"push %ebp\n"
"mov %esp, %eax\n"
"leal -4(%esp), %esp\n"
"push %eax\n"
"call " LOCAL_REFERENCE(getHostCallReturnValueWithExecState) "\n"
"leal 8(%esp), %esp\n"
"pop %ebp\n"
"ret\n"
);
#elif COMPILER(GCC_OR_CLANG) && CPU(ARM_THUMB2)
asm (
".text" "\n"
".align 2" "\n"
".globl " SYMBOL_STRING(getHostCallReturnValue) "\n"
HIDE_SYMBOL(getHostCallReturnValue) "\n"
".thumb" "\n"
".thumb_func " THUMB_FUNC_PARAM(getHostCallReturnValue) "\n"
SYMBOL_STRING(getHostCallReturnValue) ":" "\n"
"sub r0, sp, #8" "\n"
"b " LOCAL_REFERENCE(getHostCallReturnValueWithExecState) "\n"
);
#elif COMPILER(GCC_OR_CLANG) && CPU(ARM_TRADITIONAL)
asm (
".text" "\n"
".globl " SYMBOL_STRING(getHostCallReturnValue) "\n"
HIDE_SYMBOL(getHostCallReturnValue) "\n"
INLINE_ARM_FUNCTION(getHostCallReturnValue)
SYMBOL_STRING(getHostCallReturnValue) ":" "\n"
"sub r0, sp, #8" "\n"
"b " LOCAL_REFERENCE(getHostCallReturnValueWithExecState) "\n"
);
#elif CPU(ARM64)
asm (
".text" "\n"
".align 2" "\n"
".globl " SYMBOL_STRING(getHostCallReturnValue) "\n"
HIDE_SYMBOL(getHostCallReturnValue) "\n"
SYMBOL_STRING(getHostCallReturnValue) ":" "\n"
"sub x0, sp, #16" "\n"
"b " LOCAL_REFERENCE(getHostCallReturnValueWithExecState) "\n"
);
#elif COMPILER(GCC_OR_CLANG) && CPU(MIPS)
#if WTF_MIPS_PIC
#define LOAD_FUNCTION_TO_T9(function) \
".set noreorder" "\n" \
".cpload $25" "\n" \
".set reorder" "\n" \
"la $t9, " LOCAL_REFERENCE(function) "\n"
#else
#define LOAD_FUNCTION_TO_T9(function) "" "\n"
#endif
asm (
".text" "\n"
".globl " SYMBOL_STRING(getHostCallReturnValue) "\n"
HIDE_SYMBOL(getHostCallReturnValue) "\n"
SYMBOL_STRING(getHostCallReturnValue) ":" "\n"
LOAD_FUNCTION_TO_T9(getHostCallReturnValueWithExecState)
"addi $a0, $sp, -8" "\n"
"b " LOCAL_REFERENCE(getHostCallReturnValueWithExecState) "\n"
);
#elif COMPILER(MSVC) && CPU(X86)
extern "C" {
__declspec(naked) EncodedJSValue HOST_CALL_RETURN_VALUE_OPTION getHostCallReturnValue()
{
__asm lea eax, [esp - 4]
__asm mov [esp + 4], eax;
__asm jmp getHostCallReturnValueWithExecState
}
}
#endif
} // namespace JSC
#endif // ENABLE(JIT)