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cobalt / cobalt / e77c070364e97b7a7deea396227c08805cb9e66d / . / src / third_party / WebKit / Source / JavaScriptCore / interpreter / Interpreter.cpp
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/*
* Copyright (C) 2008, 2009, 2010, 2012 Apple Inc. All rights reserved.
* Copyright (C) 2008 Cameron Zwarich <cwzwarich@uwaterloo.ca>
*
* 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.
* 3. Neither the name of Apple Computer, Inc. ("Apple") nor the names of
* its contributors may be used to endorse or promote products derived
* from this software without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY APPLE AND ITS CONTRIBUTORS "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 OR ITS 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 "Interpreter.h"
#include "Arguments.h"
#include "BatchedTransitionOptimizer.h"
#include "CallFrame.h"
#include "CallFrameClosure.h"
#include "CodeBlock.h"
#include "Heap.h"
#include "Debugger.h"
#include "DebuggerCallFrame.h"
#include "ErrorInstance.h"
#include "EvalCodeCache.h"
#include "ExceptionHelpers.h"
#include "GetterSetter.h"
#include "JSActivation.h"
#include "JSArray.h"
#include "JSBoundFunction.h"
#include "JSNameScope.h"
#include "JSNotAnObject.h"
#include "JSPropertyNameIterator.h"
#include "JSStackInlines.h"
#include "JSString.h"
#include "JSWithScope.h"
#include "LLIntCLoop.h"
#include "LegacyProfiler.h"
#include "LiteralParser.h"
#include "NameInstance.h"
#include "ObjectPrototype.h"
#include "Operations.h"
#include "Parser.h"
#include "RegExpObject.h"
#include "RegExpPrototype.h"
#include "Register.h"
#include "SamplingTool.h"
#include "StrictEvalActivation.h"
#include "StrongInlines.h"
#include <limits.h>
#include <stdio.h>
#include <wtf/StackStats.h>
#include <wtf/StringPrintStream.h>
#include <wtf/Threading.h>
#include <wtf/WTFThreadData.h>
#include <wtf/text/StringBuilder.h>
#if ENABLE(JIT)
#include "JIT.h"
#endif
#define WTF_USE_GCC_COMPUTED_GOTO_WORKAROUND (ENABLE(LLINT) && !defined(__llvm__))
using namespace std;
namespace JSC {
Interpreter::ErrorHandlingMode::ErrorHandlingMode(ExecState *exec)
: m_interpreter(*exec->interpreter())
{
if (!m_interpreter.m_errorHandlingModeReentry)
m_interpreter.stack().enableErrorStackReserve();
m_interpreter.m_errorHandlingModeReentry++;
}
Interpreter::ErrorHandlingMode::~ErrorHandlingMode()
{
m_interpreter.m_errorHandlingModeReentry--;
ASSERT(m_interpreter.m_errorHandlingModeReentry >= 0);
if (!m_interpreter.m_errorHandlingModeReentry)
m_interpreter.stack().disableErrorStackReserve();
}
// The Interpreter::StackPolicy class is used to compute a stack capacity
// requirement to ensure that we have enough room on the native stack for:
// 1. the max cumulative stack used by the interpreter and all code
// paths sub of it up till leaf functions.
// 2. the max cumulative stack used by the interpreter before it reaches
// the next checkpoint (execute...() function) in the interpreter.
//
// The interpreter can be run on different threads and hence, different
// native stacks (with different sizes) before exiting out of the first
// frame. Hence, the required capacity needs to be re-computed on every
// entry into the interpreter.
//
// Currently the requiredStack is computed based on a policy. See comments
// in StackPolicy::StackPolicy() for details.
Interpreter::StackPolicy::StackPolicy(Interpreter& interpreter, const StackBounds& stack)
: m_interpreter(interpreter)
{
const size_t size = stack.size();
const size_t DEFAULT_REQUIRED_STACK = 1024 * 1024;
#if (defined(__LB_SHELL__) || OS(STARBOARD)) && !defined(NDEBUG)
// JS requires a larger stack when running in debug on Windows based
// platforms, presumably because of extra debugging information.
// LBShell uses a default stack size of 1MB which restricts the JS stack
// to 128KB. While this is not enough on Debug builds, it works well on
// other configurations since they typically don't exceed 50KB.
const size_t DEFAULT_MINIMUM_USEABLE_STACK = 512 * 1024;
#else
const size_t DEFAULT_MINIMUM_USEABLE_STACK = 128 * 1024;
#endif
const size_t DEFAULT_ERROR_MODE_REQUIRED_STACK = 32 * 1024;
// Here's the policy in a nutshell:
//
// 1. If we have a large stack, let JS use as much stack as possible
// but require that we have at least DEFAULT_REQUIRED_STACK capacity
// remaining on the stack:
//
// stack grows this way -->
// ---------------------------------------------------------
// | ... | <-- DEFAULT_REQUIRED_STACK --> | ...
// ---------------------------------------------------------
// ^ ^
// start current sp
//
// 2. In event that we're re-entering the interpreter to handle
// exceptions (in error mode), we'll be a little more generous and
// require less stack capacity for the interpreter to be re-entered.
//
// This is needed because we may have just detected an eminent stack
// overflow based on the normally computed required stack capacity.
// However, the normal required capacity far exceeds what is needed
// for exception handling work. Hence, in error mode, we only require
// DEFAULT_ERROR_MODE_REQUIRED_STACK capacity.
//
// stack grows this way -->
// -----------------------------------------------------------------
// | ... | <-- DEFAULT_ERROR_MODE_REQUIRED_STACK --> | ...
// -----------------------------------------------------------------
// ^ ^
// start current sp
//
// This smaller required capacity also means that we won't re-trigger
// a stack overflow for processing the exception caused by the original
// StackOverflowError.
//
// 3. If the stack is not large enough, give JS at least a minimum
// amount of useable stack:
//
// stack grows this way -->
// --------------------------------------------------------------------
// | <-- DEFAULT_MINIMUM_USEABLE_STACK --> | <-- requiredCapacity --> |
// --------------------------------------------------------------------
// ^ ^
// start current sp
//
// The minimum useable capacity is DEFAULT_MINIMUM_USEABLE_STACK.
// In this case, the requiredCapacity is whatever is left of the
// total stack capacity after we have give JS its minimum stack
// i.e. requiredCapacity can even be 0 if there's not enough stack.
// Policy 1: Normal mode: required = DEFAULT_REQUIRED_STACK.
// Policy 2: Error mode: required = DEFAULT_ERROR_MODE_REQUIRED_STACK.
size_t requiredCapacity = !m_interpreter.m_errorHandlingModeReentry ?
DEFAULT_REQUIRED_STACK : DEFAULT_ERROR_MODE_REQUIRED_STACK;
size_t useableStack = (requiredCapacity <= size) ?
size - requiredCapacity : DEFAULT_MINIMUM_USEABLE_STACK;
// Policy 3: Ensure the useable stack is not too small:
if (useableStack < DEFAULT_MINIMUM_USEABLE_STACK)
useableStack = DEFAULT_MINIMUM_USEABLE_STACK;
// Sanity check: Make sure we do not use more space than the stack's
// total capacity:
if (useableStack > size)
useableStack = size;
// Re-compute the requiredCapacity based on the adjusted useable stack
// size:
requiredCapacity = size - useableStack;
ASSERT(requiredCapacity < size);
m_requiredCapacity = requiredCapacity;
}
static CallFrame* getCallerInfo(JSGlobalData*, CallFrame*, int& lineNumber, unsigned& bytecodeOffset);
// Returns the depth of the scope chain within a given call frame.
static int depth(CodeBlock* codeBlock, JSScope* sc)
{
if (!codeBlock->needsFullScopeChain())
return 0;
return sc->localDepth();
}
JSValue eval(CallFrame* callFrame)
{
if (!callFrame->argumentCount())
return jsUndefined();
JSValue program = callFrame->argument(0);
if (!program.isString())
return program;
TopCallFrameSetter topCallFrame(callFrame->globalData(), callFrame);
String programSource = asString(program)->value(callFrame);
if (callFrame->hadException())
return JSValue();
CallFrame* callerFrame = callFrame->callerFrame();
CodeBlock* callerCodeBlock = callerFrame->codeBlock();
JSScope* callerScopeChain = callerFrame->scope();
EvalExecutable* eval = callerCodeBlock->evalCodeCache().tryGet(callerCodeBlock->isStrictMode(), programSource, callerScopeChain);
if (!eval) {
if (!callerCodeBlock->isStrictMode()) {
// FIXME: We can use the preparser in strict mode, we just need additional logic
// to prevent duplicates.
if (programSource.is8Bit()) {
LiteralParser<LChar> preparser(callFrame, programSource.characters8(), programSource.length(), NonStrictJSON);
if (JSValue parsedObject = preparser.tryLiteralParse())
return parsedObject;
} else {
LiteralParser<UChar> preparser(callFrame, programSource.characters16(), programSource.length(), NonStrictJSON);
if (JSValue parsedObject = preparser.tryLiteralParse())
return parsedObject;
}
}
// If the literal parser bailed, it should not have thrown exceptions.
ASSERT(!callFrame->globalData().exception);
JSValue exceptionValue;
eval = callerCodeBlock->evalCodeCache().getSlow(callFrame, callerCodeBlock->ownerExecutable(), callerCodeBlock->isStrictMode(), programSource, callerScopeChain, exceptionValue);
ASSERT((!eval) == exceptionValue);
if (UNLIKELY(!eval))
return throwError(callFrame, exceptionValue);
}
JSValue thisValue = callerFrame->thisValue();
ASSERT(isValidThisObject(thisValue, callFrame));
Interpreter* interpreter = callFrame->globalData().interpreter;
return interpreter->execute(eval, callFrame, thisValue, callerScopeChain);
}
CallFrame* loadVarargs(CallFrame* callFrame, JSStack* stack, JSValue thisValue, JSValue arguments, int firstFreeRegister)
{
if (!arguments) { // f.apply(x, arguments), with arguments unmodified.
unsigned argumentCountIncludingThis = callFrame->argumentCountIncludingThis();
CallFrame* newCallFrame = CallFrame::create(callFrame->registers() + firstFreeRegister + argumentCountIncludingThis + JSStack::CallFrameHeaderSize);
if (argumentCountIncludingThis > Arguments::MaxArguments + 1 || !stack->grow(newCallFrame->registers())) {
callFrame->globalData().exception = createStackOverflowError(callFrame);
return 0;
}
newCallFrame->setArgumentCountIncludingThis(argumentCountIncludingThis);
newCallFrame->setThisValue(thisValue);
for (size_t i = 0; i < callFrame->argumentCount(); ++i)
newCallFrame->setArgument(i, callFrame->argumentAfterCapture(i));
return newCallFrame;
}
if (arguments.isUndefinedOrNull()) {
CallFrame* newCallFrame = CallFrame::create(callFrame->registers() + firstFreeRegister + 1 + JSStack::CallFrameHeaderSize);
if (!stack->grow(newCallFrame->registers())) {
callFrame->globalData().exception = createStackOverflowError(callFrame);
return 0;
}
newCallFrame->setArgumentCountIncludingThis(1);
newCallFrame->setThisValue(thisValue);
return newCallFrame;
}
if (!arguments.isObject()) {
callFrame->globalData().exception = createInvalidParamError(callFrame, "Function.prototype.apply", arguments);
return 0;
}
if (asObject(arguments)->classInfo() == &Arguments::s_info) {
Arguments* argsObject = asArguments(arguments);
unsigned argCount = argsObject->length(callFrame);
CallFrame* newCallFrame = CallFrame::create(callFrame->registers() + firstFreeRegister + CallFrame::offsetFor(argCount + 1));
if (argCount > Arguments::MaxArguments || !stack->grow(newCallFrame->registers())) {
callFrame->globalData().exception = createStackOverflowError(callFrame);
return 0;
}
newCallFrame->setArgumentCountIncludingThis(argCount + 1);
newCallFrame->setThisValue(thisValue);
argsObject->copyToArguments(callFrame, newCallFrame, argCount);
return newCallFrame;
}
if (isJSArray(arguments)) {
JSArray* array = asArray(arguments);
unsigned argCount = array->length();
CallFrame* newCallFrame = CallFrame::create(callFrame->registers() + firstFreeRegister + CallFrame::offsetFor(argCount + 1));
if (argCount > Arguments::MaxArguments || !stack->grow(newCallFrame->registers())) {
callFrame->globalData().exception = createStackOverflowError(callFrame);
return 0;
}
newCallFrame->setArgumentCountIncludingThis(argCount + 1);
newCallFrame->setThisValue(thisValue);
array->copyToArguments(callFrame, newCallFrame, argCount);
return newCallFrame;
}
JSObject* argObject = asObject(arguments);
unsigned argCount = argObject->get(callFrame, callFrame->propertyNames().length).toUInt32(callFrame);
CallFrame* newCallFrame = CallFrame::create(callFrame->registers() + firstFreeRegister + CallFrame::offsetFor(argCount + 1));
if (argCount > Arguments::MaxArguments || !stack->grow(newCallFrame->registers())) {
callFrame->globalData().exception = createStackOverflowError(callFrame);
return 0;
}
newCallFrame->setArgumentCountIncludingThis(argCount + 1);
newCallFrame->setThisValue(thisValue);
for (size_t i = 0; i < argCount; ++i) {
newCallFrame->setArgument(i, asObject(arguments)->get(callFrame, i));
if (UNLIKELY(callFrame->globalData().exception))
return 0;
}
return newCallFrame;
}
Interpreter::Interpreter(JSGlobalData& globalData)
: m_sampleEntryDepth(0)
, m_stack(globalData)
, m_errorHandlingModeReentry(0)
#if !ASSERT_DISABLED
, m_initialized(false)
#endif
{
}
Interpreter::~Interpreter()
{
}
void Interpreter::initialize(bool canUseJIT)
{
UNUSED_PARAM(canUseJIT);
#if ENABLE(COMPUTED_GOTO_OPCODES) && ENABLE(LLINT)
m_opcodeTable = LLInt::opcodeMap();
for (int i = 0; i < numOpcodeIDs; ++i)
m_opcodeIDTable.add(m_opcodeTable[i], static_cast<OpcodeID>(i));
#endif
#if !ASSERT_DISABLED
m_initialized = true;
#endif
#if ENABLE(OPCODE_SAMPLING)
enableSampler();
#endif
}
#ifdef NDEBUG
void Interpreter::dumpCallFrame(CallFrame*)
{
}
#else
void Interpreter::dumpCallFrame(CallFrame* callFrame)
{
callFrame->codeBlock()->dumpBytecode();
dumpRegisters(callFrame);
}
void Interpreter::dumpRegisters(CallFrame* callFrame)
{
dataLogF("Register frame: \n\n");
dataLogF("-----------------------------------------------------------------------------\n");
dataLogF(" use | address | value \n");
dataLogF("-----------------------------------------------------------------------------\n");
CodeBlock* codeBlock = callFrame->codeBlock();
const Register* it;
const Register* end;
it = callFrame->registers() - JSStack::CallFrameHeaderSize - callFrame->argumentCountIncludingThis();
end = callFrame->registers() - JSStack::CallFrameHeaderSize;
while (it < end) {
JSValue v = it->jsValue();
int registerNumber = it - callFrame->registers();
String name = codeBlock->nameForRegister(registerNumber);
dataLogF("[r% 3d %14s] | %10p | %-16s 0x%lld \n", registerNumber, name.ascii().data(), it, toCString(v).data(), (long long)JSValue::encode(v));
it++;
}
dataLogF("-----------------------------------------------------------------------------\n");
dataLogF("[ArgumentCount] | %10p | %lu \n", it, (unsigned long) callFrame->argumentCount());
++it;
dataLogF("[CallerFrame] | %10p | %p \n", it, callFrame->callerFrame());
++it;
dataLogF("[Callee] | %10p | %p \n", it, callFrame->callee());
++it;
dataLogF("[ScopeChain] | %10p | %p \n", it, callFrame->scope());
++it;
#if ENABLE(JIT)
AbstractPC pc = callFrame->abstractReturnPC(callFrame->globalData());
if (pc.hasJITReturnAddress())
dataLogF("[ReturnJITPC] | %10p | %p \n", it, pc.jitReturnAddress().value());
#endif
unsigned bytecodeOffset = 0;
int line = 0;
getCallerInfo(&callFrame->globalData(), callFrame, line, bytecodeOffset);
dataLogF("[ReturnVPC] | %10p | %d (line %d)\n", it, bytecodeOffset, line);
++it;
dataLogF("[CodeBlock] | %10p | %p \n", it, callFrame->codeBlock());
++it;
dataLogF("-----------------------------------------------------------------------------\n");
int registerCount = 0;
end = it + codeBlock->m_numVars;
if (it != end) {
do {
JSValue v = it->jsValue();
int registerNumber = it - callFrame->registers();
String name = codeBlock->nameForRegister(registerNumber);
dataLogF("[r% 3d %14s] | %10p | %-16s 0x%lld \n", registerNumber, name.ascii().data(), it, toCString(v).data(), (long long)JSValue::encode(v));
++it;
++registerCount;
} while (it != end);
}
dataLogF("-----------------------------------------------------------------------------\n");
end = it + codeBlock->m_numCalleeRegisters - codeBlock->m_numVars;
if (it != end) {
do {
JSValue v = (*it).jsValue();
dataLogF("[r% 3d] | %10p | %-16s 0x%lld \n", registerCount, it, toCString(v).data(), (long long)JSValue::encode(v));
++it;
++registerCount;
} while (it != end);
}
dataLogF("-----------------------------------------------------------------------------\n");
}
#endif
bool Interpreter::isOpcode(Opcode opcode)
{
#if ENABLE(COMPUTED_GOTO_OPCODES)
#if !ENABLE(LLINT)
return static_cast<OpcodeID>(bitwise_cast<uintptr_t>(opcode)) <= op_end;
#else
return opcode != HashTraits<Opcode>::emptyValue()
&& !HashTraits<Opcode>::isDeletedValue(opcode)
&& m_opcodeIDTable.contains(opcode);
#endif
#else
return opcode >= 0 && opcode <= op_end;
#endif
}
NEVER_INLINE bool Interpreter::unwindCallFrame(CallFrame*& callFrame, JSValue exceptionValue, unsigned& bytecodeOffset, CodeBlock*& codeBlock)
{
CodeBlock* oldCodeBlock = codeBlock;
JSScope* scope = callFrame->scope();
if (Debugger* debugger = callFrame->dynamicGlobalObject()->debugger()) {
DebuggerCallFrame debuggerCallFrame(callFrame, exceptionValue);
if (callFrame->callee())
debugger->returnEvent(debuggerCallFrame, codeBlock->ownerExecutable()->sourceID(), codeBlock->ownerExecutable()->lastLine(), 0);
else
debugger->didExecuteProgram(debuggerCallFrame, codeBlock->ownerExecutable()->sourceID(), codeBlock->ownerExecutable()->lastLine(), 0);
}
JSValue activation;
if (oldCodeBlock->codeType() == FunctionCode && oldCodeBlock->needsActivation()) {
activation = callFrame->uncheckedR(oldCodeBlock->activationRegister()).jsValue();
if (activation)
jsCast<JSActivation*>(activation)->tearOff(*scope->globalData());
}
if (oldCodeBlock->codeType() == FunctionCode && oldCodeBlock->usesArguments()) {
if (JSValue arguments = callFrame->uncheckedR(unmodifiedArgumentsRegister(oldCodeBlock->argumentsRegister())).jsValue()) {
if (activation)
jsCast<Arguments*>(arguments)->didTearOffActivation(callFrame, jsCast<JSActivation*>(activation));
else
jsCast<Arguments*>(arguments)->tearOff(callFrame);
}
}
CallFrame* callerFrame = callFrame->callerFrame();
callFrame->globalData().topCallFrame = callerFrame;
if (callerFrame->hasHostCallFrameFlag())
return false;
codeBlock = callerFrame->codeBlock();
// Because of how the JIT records call site->bytecode offset
// information the JIT reports the bytecodeOffset for the returnPC
// to be at the beginning of the opcode that has caused the call.
#if ENABLE(JIT) || ENABLE(LLINT)
bytecodeOffset = codeBlock->bytecodeOffset(callerFrame, callFrame->returnPC());
#endif
callFrame = callerFrame;
return true;
}
static void appendSourceToError(CallFrame* callFrame, ErrorInstance* exception, unsigned bytecodeOffset)
{
exception->clearAppendSourceToMessage();
if (!callFrame->codeBlock()->hasExpressionInfo())
return;
int startOffset = 0;
int endOffset = 0;
int divotPoint = 0;
CodeBlock* codeBlock = callFrame->codeBlock();
codeBlock->expressionRangeForBytecodeOffset(bytecodeOffset, divotPoint, startOffset, endOffset);
int expressionStart = divotPoint - startOffset;
int expressionStop = divotPoint + endOffset;
const String& sourceString = codeBlock->source()->source();
if (!expressionStop || expressionStart > static_cast<int>(sourceString.length()))
return;
JSGlobalData* globalData = &callFrame->globalData();
JSValue jsMessage = exception->getDirect(*globalData, globalData->propertyNames->message);
if (!jsMessage || !jsMessage.isString())
return;
String message = asString(jsMessage)->value(callFrame);
if (expressionStart < expressionStop)
message = makeString(message, " (evaluating '", codeBlock->source()->getRange(expressionStart, expressionStop), "')");
else {
// No range information, so give a few characters of context
const StringImpl* data = sourceString.impl();
int dataLength = sourceString.length();
int start = expressionStart;
int stop = expressionStart;
// Get up to 20 characters of context to the left and right of the divot, clamping to the line.
// then strip whitespace.
while (start > 0 && (expressionStart - start < 20) && (*data)[start - 1] != '\n')
start--;
while (start < (expressionStart - 1) && isStrWhiteSpace((*data)[start]))
start++;
while (stop < dataLength && (stop - expressionStart < 20) && (*data)[stop] != '\n')
stop++;
while (stop > expressionStart && isStrWhiteSpace((*data)[stop - 1]))
stop--;
message = makeString(message, " (near '...", codeBlock->source()->getRange(start, stop), "...')");
}
exception->putDirect(*globalData, globalData->propertyNames->message, jsString(globalData, message));
}
static int getLineNumberForCallFrame(JSGlobalData* globalData, CallFrame* callFrame)
{
UNUSED_PARAM(globalData);
callFrame = callFrame->removeHostCallFrameFlag();
CodeBlock* codeBlock = callFrame->codeBlock();
if (!codeBlock)
return -1;
#if ENABLE(JIT) || ENABLE(LLINT)
#if ENABLE(DFG_JIT)
if (codeBlock->getJITType() == JITCode::DFGJIT)
return codeBlock->lineNumberForBytecodeOffset(codeBlock->codeOrigin(callFrame->codeOriginIndexForDFG()).bytecodeIndex);
#endif
return codeBlock->lineNumberForBytecodeOffset(callFrame->bytecodeOffsetForNonDFGCode());
#endif
}
static CallFrame* getCallerInfo(JSGlobalData* globalData, CallFrame* callFrame, int& lineNumber, unsigned& bytecodeOffset)
{
UNUSED_PARAM(globalData);
bytecodeOffset = 0;
lineNumber = -1;
ASSERT(!callFrame->hasHostCallFrameFlag());
CallFrame* callerFrame = callFrame->codeBlock() ? callFrame->trueCallerFrame() : callFrame->callerFrame()->removeHostCallFrameFlag();
bool callframeIsHost = callerFrame->addHostCallFrameFlag() == callFrame->callerFrame();
ASSERT(!callerFrame->hasHostCallFrameFlag());
if (callerFrame == CallFrame::noCaller() || !callerFrame || !callerFrame->codeBlock())
return callerFrame;
CodeBlock* callerCodeBlock = callerFrame->codeBlock();
#if ENABLE(JIT) || ENABLE(LLINT)
if (!callFrame->hasReturnPC())
callframeIsHost = true;
#endif
#if ENABLE(DFG_JIT)
if (callFrame->isInlineCallFrame())
callframeIsHost = false;
#endif
if (callframeIsHost) {
// Don't need to deal with inline callframes here as by definition we haven't
// inlined a call with an intervening native call frame.
#if ENABLE(JIT) || ENABLE(LLINT)
#if ENABLE(DFG_JIT)
if (callerCodeBlock && callerCodeBlock->getJITType() == JITCode::DFGJIT) {
unsigned codeOriginIndex = callerFrame->codeOriginIndexForDFG();
bytecodeOffset = callerCodeBlock->codeOrigin(codeOriginIndex).bytecodeIndex;
} else
#endif
bytecodeOffset = callerFrame->bytecodeOffsetForNonDFGCode();
#endif
} else {
#if ENABLE(JIT) || ENABLE(LLINT)
#if ENABLE(DFG_JIT)
if (callFrame->isInlineCallFrame()) {
InlineCallFrame* icf = callFrame->inlineCallFrame();
bytecodeOffset = icf->caller.bytecodeIndex;
if (InlineCallFrame* parentCallFrame = icf->caller.inlineCallFrame) {
FunctionExecutable* executable = static_cast<FunctionExecutable*>(parentCallFrame->executable.get());
CodeBlock* newCodeBlock = executable->baselineCodeBlockFor(parentCallFrame->isCall ? CodeForCall : CodeForConstruct);
ASSERT(newCodeBlock);
ASSERT(newCodeBlock->instructionCount() > bytecodeOffset);
callerCodeBlock = newCodeBlock;
}
} else if (callerCodeBlock && callerCodeBlock->getJITType() == JITCode::DFGJIT) {
CodeOrigin origin;
if (!callerCodeBlock->codeOriginForReturn(callFrame->returnPC(), origin))
ASSERT_NOT_REACHED();
bytecodeOffset = origin.bytecodeIndex;
if (InlineCallFrame* icf = origin.inlineCallFrame) {
FunctionExecutable* executable = static_cast<FunctionExecutable*>(icf->executable.get());
CodeBlock* newCodeBlock = executable->baselineCodeBlockFor(icf->isCall ? CodeForCall : CodeForConstruct);
ASSERT(newCodeBlock);
ASSERT(newCodeBlock->instructionCount() > bytecodeOffset);
callerCodeBlock = newCodeBlock;
}
} else
#endif
bytecodeOffset = callerCodeBlock->bytecodeOffset(callerFrame, callFrame->returnPC());
#endif
}
lineNumber = callerCodeBlock->lineNumberForBytecodeOffset(bytecodeOffset);
return callerFrame;
}
static ALWAYS_INLINE const String getSourceURLFromCallFrame(CallFrame* callFrame)
{
ASSERT(!callFrame->hasHostCallFrameFlag());
return callFrame->codeBlock()->ownerExecutable()->sourceURL();
}
static StackFrameCodeType getStackFrameCodeType(CallFrame* callFrame)
{
ASSERT(!callFrame->hasHostCallFrameFlag());
switch (callFrame->codeBlock()->codeType()) {
case EvalCode:
return StackFrameEvalCode;
case FunctionCode:
return StackFrameFunctionCode;
case GlobalCode:
return StackFrameGlobalCode;
}
ASSERT_NOT_REACHED();
return StackFrameGlobalCode;
}
void Interpreter::getStackTrace(JSGlobalData* globalData, Vector<StackFrame, 0>& results)
{
CallFrame* callFrame = globalData->topCallFrame->removeHostCallFrameFlag();
if (!callFrame || callFrame == CallFrame::noCaller())
return;
int line = getLineNumberForCallFrame(globalData, callFrame);
callFrame = callFrame->trueCallFrameFromVMCode();
while (callFrame && callFrame != CallFrame::noCaller()) {
String sourceURL;
if (callFrame->codeBlock()) {
sourceURL = getSourceURLFromCallFrame(callFrame);
StackFrame s = { Strong<JSObject>(*globalData, callFrame->callee()), getStackFrameCodeType(callFrame), Strong<ExecutableBase>(*globalData, callFrame->codeBlock()->ownerExecutable()), line, sourceURL};
results.append(s);
} else {
StackFrame s = { Strong<JSObject>(*globalData, callFrame->callee()), StackFrameNativeCode, Strong<ExecutableBase>(), -1, String()};
results.append(s);
}
unsigned unusedBytecodeOffset = 0;
callFrame = getCallerInfo(globalData, callFrame, line, unusedBytecodeOffset);
}
}
void Interpreter::addStackTraceIfNecessary(CallFrame* callFrame, JSObject* error)
{
JSGlobalData* globalData = &callFrame->globalData();
ASSERT(callFrame == globalData->topCallFrame || callFrame == callFrame->lexicalGlobalObject()->globalExec() || callFrame == callFrame->dynamicGlobalObject()->globalExec());
if (error->hasProperty(callFrame, globalData->propertyNames->stack))
return;
Vector<StackFrame> stackTrace;
getStackTrace(&callFrame->globalData(), stackTrace);
if (stackTrace.isEmpty())
return;
JSGlobalObject* globalObject = 0;
if (isTerminatedExecutionException(error) || isInterruptedExecutionException(error))
globalObject = globalData->dynamicGlobalObject;
else
globalObject = error->globalObject();
// FIXME: JSStringJoiner could be more efficient than StringBuilder here.
StringBuilder builder;
for (unsigned i = 0; i < stackTrace.size(); i++) {
builder.append(String(stackTrace[i].toString(globalObject->globalExec()).impl()));
if (i != stackTrace.size() - 1)
builder.append('\n');
}
error->putDirect(*globalData, globalData->propertyNames->stack, jsString(globalData, builder.toString()), ReadOnly | DontDelete);
}
NEVER_INLINE HandlerInfo* Interpreter::throwException(CallFrame*& callFrame, JSValue& exceptionValue, unsigned bytecodeOffset)
{
CodeBlock* codeBlock = callFrame->codeBlock();
bool isInterrupt = false;
ASSERT(!exceptionValue.isEmpty());
ASSERT(!exceptionValue.isCell() || exceptionValue.asCell());
// This shouldn't be possible (hence the assertions), but we're already in the slowest of
// slow cases, so let's harden against it anyway to be safe.
if (exceptionValue.isEmpty() || (exceptionValue.isCell() && !exceptionValue.asCell()))
exceptionValue = jsNull();
// Set up the exception object
if (exceptionValue.isObject()) {
JSObject* exception = asObject(exceptionValue);
if (exception->isErrorInstance() && static_cast<ErrorInstance*>(exception)->appendSourceToMessage())
appendSourceToError(callFrame, static_cast<ErrorInstance*>(exception), bytecodeOffset);
if (!hasErrorInfo(callFrame, exception)) {
// FIXME: should only really be adding these properties to VM generated exceptions,
// but the inspector currently requires these for all thrown objects.
addErrorInfo(callFrame, exception, codeBlock->lineNumberForBytecodeOffset(bytecodeOffset), codeBlock->ownerExecutable()->source());
}
isInterrupt = isInterruptedExecutionException(exception) || isTerminatedExecutionException(exception);
}
if (Debugger* debugger = callFrame->dynamicGlobalObject()->debugger()) {
DebuggerCallFrame debuggerCallFrame(callFrame, exceptionValue);
bool hasHandler = codeBlock->handlerForBytecodeOffset(bytecodeOffset);
debugger->exception(debuggerCallFrame, codeBlock->ownerExecutable()->sourceID(), codeBlock->lineNumberForBytecodeOffset(bytecodeOffset), 0, hasHandler);
}
// Calculate an exception handler vPC, unwinding call frames as necessary.
HandlerInfo* handler = 0;
while (isInterrupt || !(handler = codeBlock->handlerForBytecodeOffset(bytecodeOffset))) {
if (!unwindCallFrame(callFrame, exceptionValue, bytecodeOffset, codeBlock)) {
if (LegacyProfiler* profiler = callFrame->globalData().enabledProfiler())
profiler->exceptionUnwind(callFrame);
return 0;
}
}
if (LegacyProfiler* profiler = callFrame->globalData().enabledProfiler())
profiler->exceptionUnwind(callFrame);
// Unwind the scope chain within the exception handler's call frame.
JSScope* scope = callFrame->scope();
int scopeDelta = 0;
if (!codeBlock->needsFullScopeChain() || codeBlock->codeType() != FunctionCode
|| callFrame->uncheckedR(codeBlock->activationRegister()).jsValue()) {
int currentDepth = depth(codeBlock, scope);
int targetDepth = handler->scopeDepth;
scopeDelta = currentDepth - targetDepth;
ASSERT(scopeDelta >= 0);
}
while (scopeDelta--)
scope = scope->next();
callFrame->setScope(scope);
return handler;
}
static inline JSValue checkedReturn(JSValue returnValue)
{
ASSERT(returnValue);
return returnValue;
}
static inline JSObject* checkedReturn(JSObject* returnValue)
{
ASSERT(returnValue);
return returnValue;
}
class SamplingScope {
public:
SamplingScope(Interpreter* interpreter)
: m_interpreter(interpreter)
{
interpreter->startSampling();
}
~SamplingScope()
{
m_interpreter->stopSampling();
}
private:
Interpreter* m_interpreter;
};
JSValue Interpreter::execute(ProgramExecutable* program, CallFrame* callFrame, JSObject* thisObj)
{
SamplingScope samplingScope(this);
JSScope* scope = callFrame->scope();
JSGlobalData& globalData = *scope->globalData();
ASSERT(isValidThisObject(thisObj, callFrame));
ASSERT(!globalData.exception);
ASSERT(!globalData.isCollectorBusy());
if (globalData.isCollectorBusy())
CRASH();
StackStats::CheckPoint stackCheckPoint;
const StackBounds& nativeStack = wtfThreadData().stack();
StackPolicy policy(*this, nativeStack);
if (!nativeStack.isSafeToRecurse(policy.requiredCapacity()))
return checkedReturn(throwStackOverflowError(callFrame));
// First check if the "program" is actually just a JSON object. If so,
// we'll handle the JSON object here. Else, we'll handle real JS code
// below at failedJSONP.
DynamicGlobalObjectScope globalObjectScope(globalData, scope->globalObject());
Vector<JSONPData> JSONPData;
bool parseResult;
const String programSource = program->source().toString();
if (programSource.isNull())
return jsUndefined();
if (programSource.is8Bit()) {
LiteralParser<LChar> literalParser(callFrame, programSource.characters8(), programSource.length(), JSONP);
parseResult = literalParser.tryJSONPParse(JSONPData, scope->globalObject()->globalObjectMethodTable()->supportsRichSourceInfo(scope->globalObject()));
} else {
LiteralParser<UChar> literalParser(callFrame, programSource.characters16(), programSource.length(), JSONP);
parseResult = literalParser.tryJSONPParse(JSONPData, scope->globalObject()->globalObjectMethodTable()->supportsRichSourceInfo(scope->globalObject()));
}
if (parseResult) {
JSGlobalObject* globalObject = scope->globalObject();
JSValue result;
for (unsigned entry = 0; entry < JSONPData.size(); entry++) {
Vector<JSONPPathEntry> JSONPPath;
JSONPPath.swap(JSONPData[entry].m_path);
JSValue JSONPValue = JSONPData[entry].m_value.get();
if (JSONPPath.size() == 1 && JSONPPath[0].m_type == JSONPPathEntryTypeDeclare) {
if (globalObject->hasProperty(callFrame, JSONPPath[0].m_pathEntryName)) {
PutPropertySlot slot;
globalObject->methodTable()->put(globalObject, callFrame, JSONPPath[0].m_pathEntryName, JSONPValue, slot);
} else
globalObject->methodTable()->putDirectVirtual(globalObject, callFrame, JSONPPath[0].m_pathEntryName, JSONPValue, DontEnum | DontDelete);
// var declarations return undefined
result = jsUndefined();
continue;
}
JSValue baseObject(globalObject);
for (unsigned i = 0; i < JSONPPath.size() - 1; i++) {
ASSERT(JSONPPath[i].m_type != JSONPPathEntryTypeDeclare);
switch (JSONPPath[i].m_type) {
case JSONPPathEntryTypeDot: {
if (i == 0) {
PropertySlot slot(globalObject);
if (!globalObject->getPropertySlot(callFrame, JSONPPath[i].m_pathEntryName, slot)) {
if (entry)
return throwError(callFrame, createUndefinedVariableError(globalObject->globalExec(), JSONPPath[i].m_pathEntryName));
goto failedJSONP;
}
baseObject = slot.getValue(callFrame, JSONPPath[i].m_pathEntryName);
} else
baseObject = baseObject.get(callFrame, JSONPPath[i].m_pathEntryName);
if (callFrame->hadException())
return jsUndefined();
continue;
}
case JSONPPathEntryTypeLookup: {
baseObject = baseObject.get(callFrame, JSONPPath[i].m_pathIndex);
if (callFrame->hadException())
return jsUndefined();
continue;
}
default:
ASSERT_NOT_REACHED();
return jsUndefined();
}
}
PutPropertySlot slot;
switch (JSONPPath.last().m_type) {
case JSONPPathEntryTypeCall: {
JSValue function = baseObject.get(callFrame, JSONPPath.last().m_pathEntryName);
if (callFrame->hadException())
return jsUndefined();
CallData callData;
CallType callType = getCallData(function, callData);
if (callType == CallTypeNone)
return throwError(callFrame, createNotAFunctionError(callFrame, function));
MarkedArgumentBuffer jsonArg;
jsonArg.append(JSONPValue);
JSValue thisValue = JSONPPath.size() == 1 ? jsUndefined(): baseObject;
JSONPValue = JSC::call(callFrame, function, callType, callData, thisValue, jsonArg);
if (callFrame->hadException())
return jsUndefined();
break;
}
case JSONPPathEntryTypeDot: {
baseObject.put(callFrame, JSONPPath.last().m_pathEntryName, JSONPValue, slot);
if (callFrame->hadException())
return jsUndefined();
break;
}
case JSONPPathEntryTypeLookup: {
baseObject.putByIndex(callFrame, JSONPPath.last().m_pathIndex, JSONPValue, slot.isStrictMode());
if (callFrame->hadException())
return jsUndefined();
break;
}
default:
ASSERT_NOT_REACHED();
return jsUndefined();
}
result = JSONPValue;
}
return result;
}
failedJSONP:
// If we get here, then we have already proven that the script is not a JSON
// object.
// Compile source to bytecode if necessary:
if (JSObject* error = program->initalizeGlobalProperties(globalData, callFrame, scope))
return checkedReturn(throwError(callFrame, error));
if (JSObject* error = program->compile(callFrame, scope))
return checkedReturn(throwError(callFrame, error));
ProgramCodeBlock* codeBlock = &program->generatedBytecode();
// Push the call frame for this invocation:
ASSERT(codeBlock->numParameters() == 1); // 1 parameter for 'this'.
CallFrame* newCallFrame = m_stack.pushFrame(callFrame, codeBlock, scope, 1, 0);
if (UNLIKELY(!newCallFrame))
return checkedReturn(throwStackOverflowError(callFrame));
// Set the arguments for the callee:
newCallFrame->setThisValue(thisObj);
if (LegacyProfiler* profiler = globalData.enabledProfiler())
profiler->willExecute(callFrame, program->sourceURL(), program->lineNo());
// Execute the code:
JSValue result;
{
SamplingTool::CallRecord callRecord(m_sampler.get());
#if ENABLE(LLINT_C_LOOP)
result = LLInt::CLoop::execute(newCallFrame, llint_program_prologue);
#elif ENABLE(JIT)
result = program->generatedJITCode().execute(&m_stack, newCallFrame, &globalData);
#endif // ENABLE(JIT)
}
if (LegacyProfiler* profiler = globalData.enabledProfiler())
profiler->didExecute(callFrame, program->sourceURL(), program->lineNo());
m_stack.popFrame(newCallFrame);
return checkedReturn(result);
}
JSValue Interpreter::executeCall(CallFrame* callFrame, JSObject* function, CallType callType, const CallData& callData, JSValue thisValue, const ArgList& args)
{
JSGlobalData& globalData = callFrame->globalData();
ASSERT(isValidThisObject(thisValue, callFrame));
ASSERT(!callFrame->hadException());
ASSERT(!globalData.isCollectorBusy());
if (globalData.isCollectorBusy())
return jsNull();
StackStats::CheckPoint stackCheckPoint;
const StackBounds& nativeStack = wtfThreadData().stack();
StackPolicy policy(*this, nativeStack);
if (!nativeStack.isSafeToRecurse(policy.requiredCapacity()))
return checkedReturn(throwStackOverflowError(callFrame));
bool isJSCall = (callType == CallTypeJS);
JSScope* scope;
CodeBlock* newCodeBlock;
size_t argsCount = 1 + args.size(); // implicit "this" parameter
if (isJSCall)
scope = callData.js.scope;
else {
ASSERT(callType == CallTypeHost);
scope = callFrame->scope();
}
DynamicGlobalObjectScope globalObjectScope(globalData, scope->globalObject());
if (isJSCall) {
// Compile the callee:
JSObject* compileError = callData.js.functionExecutable->compileForCall(callFrame, scope);
if (UNLIKELY(!!compileError)) {
return checkedReturn(throwError(callFrame, compileError));
}
newCodeBlock = &callData.js.functionExecutable->generatedBytecodeForCall();
ASSERT(!!newCodeBlock);
} else
newCodeBlock = 0;
CallFrame* newCallFrame = m_stack.pushFrame(callFrame, newCodeBlock, scope, argsCount, function);
if (UNLIKELY(!newCallFrame))
return checkedReturn(throwStackOverflowError(callFrame));
// Set the arguments for the callee:
newCallFrame->setThisValue(thisValue);
for (size_t i = 0; i < args.size(); ++i)
newCallFrame->setArgument(i, args.at(i));
if (LegacyProfiler* profiler = globalData.enabledProfiler())
profiler->willExecute(callFrame, function);
JSValue result;
{
SamplingTool::CallRecord callRecord(m_sampler.get(), !isJSCall);
// Execute the code:
if (isJSCall) {
#if ENABLE(LLINT_C_LOOP)
result = LLInt::CLoop::execute(newCallFrame, llint_function_for_call_prologue);
#elif ENABLE(JIT)
result = callData.js.functionExecutable->generatedJITCodeForCall().execute(&m_stack, newCallFrame, &globalData);
#endif // ENABLE(JIT)
} else
result = JSValue::decode(callData.native.function(newCallFrame));
}
if (LegacyProfiler* profiler = globalData.enabledProfiler())
profiler->didExecute(callFrame, function);
m_stack.popFrame(newCallFrame);
return checkedReturn(result);
}
JSObject* Interpreter::executeConstruct(CallFrame* callFrame, JSObject* constructor, ConstructType constructType, const ConstructData& constructData, const ArgList& args)
{
JSGlobalData& globalData = callFrame->globalData();
ASSERT(!callFrame->hadException());
ASSERT(!globalData.isCollectorBusy());
// We throw in this case because we have to return something "valid" but we're
// already in an invalid state.
if (globalData.isCollectorBusy())
return checkedReturn(throwStackOverflowError(callFrame));
StackStats::CheckPoint stackCheckPoint;
const StackBounds& nativeStack = wtfThreadData().stack();
StackPolicy policy(*this, nativeStack);
if (!nativeStack.isSafeToRecurse(policy.requiredCapacity()))
return checkedReturn(throwStackOverflowError(callFrame));
bool isJSConstruct = (constructType == ConstructTypeJS);
JSScope* scope;
CodeBlock* newCodeBlock;
size_t argsCount = 1 + args.size(); // implicit "this" parameter
if (isJSConstruct)
scope = constructData.js.scope;
else {
ASSERT(constructType == ConstructTypeHost);
scope = callFrame->scope();
}
DynamicGlobalObjectScope globalObjectScope(globalData, scope->globalObject());
if (isJSConstruct) {
// Compile the callee:
JSObject* compileError = constructData.js.functionExecutable->compileForConstruct(callFrame, scope);
if (UNLIKELY(!!compileError)) {
return checkedReturn(throwError(callFrame, compileError));
}
newCodeBlock = &constructData.js.functionExecutable->generatedBytecodeForConstruct();
ASSERT(!!newCodeBlock);
} else
newCodeBlock = 0;
CallFrame* newCallFrame = m_stack.pushFrame(callFrame, newCodeBlock, scope, argsCount, constructor);
if (UNLIKELY(!newCallFrame))
return checkedReturn(throwStackOverflowError(callFrame));
// Set the arguments for the callee:
newCallFrame->setThisValue(jsUndefined());
for (size_t i = 0; i < args.size(); ++i)
newCallFrame->setArgument(i, args.at(i));
if (LegacyProfiler* profiler = globalData.enabledProfiler())
profiler->willExecute(callFrame, constructor);
JSValue result;
{
SamplingTool::CallRecord callRecord(m_sampler.get(), !isJSConstruct);
// Execute the code.
if (isJSConstruct) {
#if ENABLE(LLINT_C_LOOP)
result = LLInt::CLoop::execute(newCallFrame, llint_function_for_construct_prologue);
#elif ENABLE(JIT)
result = constructData.js.functionExecutable->generatedJITCodeForConstruct().execute(&m_stack, newCallFrame, &globalData);
#endif // ENABLE(JIT)
} else {
result = JSValue::decode(constructData.native.function(newCallFrame));
}
}
if (LegacyProfiler* profiler = globalData.enabledProfiler())
profiler->didExecute(callFrame, constructor);
m_stack.popFrame(newCallFrame);
if (callFrame->hadException())
return 0;
ASSERT(result.isObject());
return checkedReturn(asObject(result));
}
CallFrameClosure Interpreter::prepareForRepeatCall(FunctionExecutable* functionExecutable, CallFrame* callFrame, JSFunction* function, int argumentCountIncludingThis, JSScope* scope)
{
JSGlobalData& globalData = *scope->globalData();
ASSERT(!globalData.exception);
if (globalData.isCollectorBusy())
return CallFrameClosure();
StackStats::CheckPoint stackCheckPoint;
const StackBounds& nativeStack = wtfThreadData().stack();
StackPolicy policy(*this, nativeStack);
if (!nativeStack.isSafeToRecurse(policy.requiredCapacity())) {
throwStackOverflowError(callFrame);
return CallFrameClosure();
}
// Compile the callee:
JSObject* error = functionExecutable->compileForCall(callFrame, scope);
if (error) {
throwError(callFrame, error);
return CallFrameClosure();
}
CodeBlock* newCodeBlock = &functionExecutable->generatedBytecodeForCall();
size_t argsCount = argumentCountIncludingThis;
CallFrame* newCallFrame = m_stack.pushFrame(callFrame, newCodeBlock, scope, argsCount, function);
if (UNLIKELY(!newCallFrame)) {
throwStackOverflowError(callFrame);
return CallFrameClosure();
}
if (UNLIKELY(!newCallFrame)) {
throwStackOverflowError(callFrame);
return CallFrameClosure();
}
// Return the successful closure:
CallFrameClosure result = { callFrame, newCallFrame, function, functionExecutable, &globalData, scope, newCodeBlock->numParameters(), argumentCountIncludingThis };
return result;
}
JSValue Interpreter::execute(CallFrameClosure& closure)
{
JSGlobalData& globalData = *closure.globalData;
SamplingScope samplingScope(this);
ASSERT(!globalData.isCollectorBusy());
if (globalData.isCollectorBusy())
return jsNull();
StackStats::CheckPoint stackCheckPoint;
m_stack.validateFence(closure.newCallFrame, "BEFORE");
closure.resetCallFrame();
m_stack.validateFence(closure.newCallFrame, "STEP 1");
if (LegacyProfiler* profiler = globalData.enabledProfiler())
profiler->willExecute(closure.oldCallFrame, closure.function);
// The code execution below may push more frames and point the topCallFrame
// to those newer frames, or it may pop to the top frame to the caller of
// the current repeat frame, or it may leave the top frame pointing to the
// current repeat frame.
//
// Hence, we need to preserve the topCallFrame here ourselves before
// repeating this call on a second callback function.
TopCallFrameSetter topCallFrame(globalData, closure.newCallFrame);
// Execute the code:
JSValue result;
{
SamplingTool::CallRecord callRecord(m_sampler.get());
#if ENABLE(LLINT_C_LOOP)
result = LLInt::CLoop::execute(closure.newCallFrame, llint_function_for_call_prologue);
#elif ENABLE(JIT)
result = closure.functionExecutable->generatedJITCodeForCall().execute(&m_stack, closure.newCallFrame, &globalData);
#endif // ENABLE(JIT)
}
if (LegacyProfiler* profiler = globalData.enabledProfiler())
profiler->didExecute(closure.oldCallFrame, closure.function);
m_stack.validateFence(closure.newCallFrame, "AFTER");
return checkedReturn(result);
}
void Interpreter::endRepeatCall(CallFrameClosure& closure)
{
m_stack.popFrame(closure.newCallFrame);
}
JSValue Interpreter::execute(EvalExecutable* eval, CallFrame* callFrame, JSValue thisValue, JSScope* scope)
{
JSGlobalData& globalData = *scope->globalData();
SamplingScope samplingScope(this);
ASSERT(scope->globalData() == &callFrame->globalData());
ASSERT(isValidThisObject(thisValue, callFrame));
ASSERT(!globalData.exception);
ASSERT(!globalData.isCollectorBusy());
if (globalData.isCollectorBusy())
return jsNull();
DynamicGlobalObjectScope globalObjectScope(globalData, scope->globalObject());
StackStats::CheckPoint stackCheckPoint;
const StackBounds& nativeStack = wtfThreadData().stack();
StackPolicy policy(*this, nativeStack);
if (!nativeStack.isSafeToRecurse(policy.requiredCapacity()))
return checkedReturn(throwStackOverflowError(callFrame));
// Compile the callee:
JSObject* compileError = eval->compile(callFrame, scope);
if (UNLIKELY(!!compileError))
return checkedReturn(throwError(callFrame, compileError));
EvalCodeBlock* codeBlock = &eval->generatedBytecode();
JSObject* variableObject;
for (JSScope* node = scope; ; node = node->next()) {
ASSERT(node);
if (node->isVariableObject() && !node->isNameScopeObject()) {
variableObject = node;
break;
}
}
unsigned numVariables = codeBlock->numVariables();
int numFunctions = codeBlock->numberOfFunctionDecls();
if (numVariables || numFunctions) {
if (codeBlock->isStrictMode()) {
scope = StrictEvalActivation::create(callFrame);
variableObject = scope;
}
// Scope for BatchedTransitionOptimizer
BatchedTransitionOptimizer optimizer(globalData, variableObject);
for (unsigned i = 0; i < numVariables; ++i) {
const Identifier& ident = codeBlock->variable(i);
if (!variableObject->hasProperty(callFrame, ident)) {
PutPropertySlot slot;
variableObject->methodTable()->put(variableObject, callFrame, ident, jsUndefined(), slot);
}
}
for (int i = 0; i < numFunctions; ++i) {
FunctionExecutable* function = codeBlock->functionDecl(i);
PutPropertySlot slot;
variableObject->methodTable()->put(variableObject, callFrame, function->name(), JSFunction::create(callFrame, function, scope), slot);
}
}
// Push the frame:
ASSERT(codeBlock->numParameters() == 1); // 1 parameter for 'this'.
CallFrame* newCallFrame = m_stack.pushFrame(callFrame, codeBlock, scope, 1, 0);
if (UNLIKELY(!newCallFrame))
return checkedReturn(throwStackOverflowError(callFrame));
// Set the arguments for the callee:
newCallFrame->setThisValue(thisValue);
if (LegacyProfiler* profiler = globalData.enabledProfiler())
profiler->willExecute(callFrame, eval->sourceURL(), eval->lineNo());
// Execute the code:
JSValue result;
{
SamplingTool::CallRecord callRecord(m_sampler.get());
#if ENABLE(LLINT_C_LOOP)
result = LLInt::CLoop::execute(newCallFrame, llint_eval_prologue);
#elif ENABLE(JIT)
result = eval->generatedJITCode().execute(&m_stack, newCallFrame, &globalData);
#endif // ENABLE(JIT)
}
if (LegacyProfiler* profiler = globalData.enabledProfiler())
profiler->didExecute(callFrame, eval->sourceURL(), eval->lineNo());
m_stack.popFrame(newCallFrame);
return checkedReturn(result);
}
NEVER_INLINE void Interpreter::debug(CallFrame* callFrame, DebugHookID debugHookID, int firstLine, int lastLine, int column)
{
Debugger* debugger = callFrame->dynamicGlobalObject()->debugger();
if (!debugger)
return;
switch (debugHookID) {
case DidEnterCallFrame:
debugger->callEvent(callFrame, callFrame->codeBlock()->ownerExecutable()->sourceID(), firstLine, column);
return;
case WillLeaveCallFrame:
debugger->returnEvent(callFrame, callFrame->codeBlock()->ownerExecutable()->sourceID(), lastLine, column);
return;
case WillExecuteStatement:
debugger->atStatement(callFrame, callFrame->codeBlock()->ownerExecutable()->sourceID(), firstLine, column);
return;
case WillExecuteProgram:
debugger->willExecuteProgram(callFrame, callFrame->codeBlock()->ownerExecutable()->sourceID(), firstLine, column);
return;
case DidExecuteProgram:
debugger->didExecuteProgram(callFrame, callFrame->codeBlock()->ownerExecutable()->sourceID(), lastLine, column);
return;
case DidReachBreakpoint:
debugger->didReachBreakpoint(callFrame, callFrame->codeBlock()->ownerExecutable()->sourceID(), lastLine, column);
return;
}
}
JSValue Interpreter::retrieveArgumentsFromVMCode(CallFrame* callFrame, JSFunction* function) const
{
CallFrame* functionCallFrame = findFunctionCallFrameFromVMCode(callFrame, function);
if (!functionCallFrame)
return jsNull();
Arguments* arguments = Arguments::create(functionCallFrame->globalData(), functionCallFrame);
arguments->tearOff(functionCallFrame);
return JSValue(arguments);
}
JSValue Interpreter::retrieveCallerFromVMCode(CallFrame* callFrame, JSFunction* function) const
{
CallFrame* functionCallFrame = findFunctionCallFrameFromVMCode(callFrame, function);
if (!functionCallFrame)
return jsNull();
int lineNumber;
unsigned bytecodeOffset;
CallFrame* callerFrame = getCallerInfo(&callFrame->globalData(), functionCallFrame, lineNumber, bytecodeOffset);
if (!callerFrame)
return jsNull();
JSValue caller = callerFrame->callee();
if (!caller)
return jsNull();
// Skip over function bindings.
ASSERT(caller.isObject());
while (asObject(caller)->inherits(JSBoundFunction::s_classinfo())) {
callerFrame = getCallerInfo(&callFrame->globalData(), callerFrame, lineNumber, bytecodeOffset);
if (!callerFrame)
return jsNull();
caller = callerFrame->callee();
if (!caller)
return jsNull();
}
return caller;
}
void Interpreter::retrieveLastCaller(CallFrame* callFrame, int& lineNumber, intptr_t& sourceID, String& sourceURL, JSValue& function) const
{
function = JSValue();
lineNumber = -1;
sourceURL = String();
CallFrame* callerFrame = callFrame->callerFrame();
if (callerFrame->hasHostCallFrameFlag())
return;
CodeBlock* callerCodeBlock = callerFrame->codeBlock();
if (!callerCodeBlock)
return;
unsigned bytecodeOffset = 0;
bytecodeOffset = callerCodeBlock->bytecodeOffset(callerFrame, callFrame->returnPC());
lineNumber = callerCodeBlock->lineNumberForBytecodeOffset(bytecodeOffset - 1);
sourceID = callerCodeBlock->ownerExecutable()->sourceID();
sourceURL = callerCodeBlock->ownerExecutable()->sourceURL();
function = callerFrame->callee();
}
CallFrame* Interpreter::findFunctionCallFrameFromVMCode(CallFrame* callFrame, JSFunction* function)
{
for (CallFrame* candidate = callFrame->trueCallFrameFromVMCode(); candidate; candidate = candidate->trueCallerFrame()) {
if (candidate->callee() == function)
return candidate;
}
return 0;
}
void Interpreter::enableSampler()
{
#if ENABLE(OPCODE_SAMPLING)
if (!m_sampler) {
m_sampler = adoptPtr(new SamplingTool(this));
m_sampler->setup();
}
#endif
}
void Interpreter::dumpSampleData(ExecState* exec)
{
#if ENABLE(OPCODE_SAMPLING)
if (m_sampler)
m_sampler->dump(exec);
#else
UNUSED_PARAM(exec);
#endif
}
void Interpreter::startSampling()
{
#if ENABLE(SAMPLING_THREAD)
if (!m_sampleEntryDepth)
SamplingThread::start();
m_sampleEntryDepth++;
#endif
}
void Interpreter::stopSampling()
{
#if ENABLE(SAMPLING_THREAD)
m_sampleEntryDepth--;
if (!m_sampleEntryDepth)
SamplingThread::stop();
#endif
}
} // namespace JSC