/* * Copyright (C) 2012-2016 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. */ #ifndef UnlinkedCodeBlock_h #define UnlinkedCodeBlock_h #include "BytecodeConventions.h" #include "CodeSpecializationKind.h" #include "CodeType.h" #include "ConstructAbility.h" #include "ExpressionRangeInfo.h" #include "HandlerInfo.h" #include "Identifier.h" #include "JSCell.h" #include "JSString.h" #include "ParserModes.h" #include "RegExp.h" #include "SpecialPointer.h" #include "UnlinkedFunctionExecutable.h" #include "VariableEnvironment.h" #include "VirtualRegister.h" #include #include #include namespace JSC { class Debugger; class FunctionMetadataNode; class FunctionExecutable; class JSScope; class ParserError; class ScriptExecutable; class SourceCode; class SourceProvider; class UnlinkedCodeBlock; class UnlinkedFunctionCodeBlock; class UnlinkedFunctionExecutable; class UnlinkedInstructionStream; struct ExecutableInfo; typedef unsigned UnlinkedValueProfile; typedef unsigned UnlinkedArrayProfile; typedef unsigned UnlinkedArrayAllocationProfile; typedef unsigned UnlinkedObjectAllocationProfile; typedef unsigned UnlinkedLLIntCallLinkInfo; struct UnlinkedStringJumpTable { typedef HashMap, int32_t> StringOffsetTable; StringOffsetTable offsetTable; inline int32_t offsetForValue(StringImpl* value, int32_t defaultOffset) { StringOffsetTable::const_iterator end = offsetTable.end(); StringOffsetTable::const_iterator loc = offsetTable.find(value); if (loc == end) return defaultOffset; return loc->value; } }; struct UnlinkedSimpleJumpTable { Vector branchOffsets; int32_t min; int32_t offsetForValue(int32_t value, int32_t defaultOffset); void add(int32_t key, int32_t offset) { if (!branchOffsets[key]) branchOffsets[key] = offset; } }; struct UnlinkedInstruction { UnlinkedInstruction() { u.operand = 0; } UnlinkedInstruction(OpcodeID opcode) { u.opcode = opcode; } UnlinkedInstruction(int operand) { u.operand = operand; } union { OpcodeID opcode; int32_t operand; unsigned index; } u; }; class UnlinkedCodeBlock : public JSCell { public: typedef JSCell Base; static const unsigned StructureFlags = Base::StructureFlags; static const bool needsDestruction = true; enum { CallFunction, ApplyFunction }; bool isConstructor() const { return m_isConstructor; } bool isStrictMode() const { return m_isStrictMode; } bool usesEval() const { return m_usesEval; } SourceParseMode parseMode() const { return m_parseMode; } bool isArrowFunction() const { return m_parseMode == SourceParseMode::ArrowFunctionMode; } DerivedContextType derivedContextType() const { return static_cast(m_derivedContextType); } EvalContextType evalContextType() const { return static_cast(m_evalContextType); } bool isArrowFunctionContext() const { return m_isArrowFunctionContext; } bool isClassContext() const { return m_isClassContext; } void addExpressionInfo(unsigned instructionOffset, int divot, int startOffset, int endOffset, unsigned line, unsigned column); void addTypeProfilerExpressionInfo(unsigned instructionOffset, unsigned startDivot, unsigned endDivot); bool hasExpressionInfo() { return m_expressionInfo.size(); } const Vector& expressionInfo() { return m_expressionInfo; } // Special registers void setThisRegister(VirtualRegister thisRegister) { m_thisRegister = thisRegister; } void setScopeRegister(VirtualRegister scopeRegister) { m_scopeRegister = scopeRegister; } bool usesGlobalObject() const { return m_globalObjectRegister.isValid(); } void setGlobalObjectRegister(VirtualRegister globalObjectRegister) { m_globalObjectRegister = globalObjectRegister; } VirtualRegister globalObjectRegister() const { return m_globalObjectRegister; } // Parameter information void setNumParameters(int newValue) { m_numParameters = newValue; } void addParameter() { m_numParameters++; } unsigned numParameters() const { return m_numParameters; } unsigned addRegExp(RegExp* r) { createRareDataIfNecessary(); unsigned size = m_rareData->m_regexps.size(); m_rareData->m_regexps.append(WriteBarrier(*vm(), this, r)); return size; } unsigned numberOfRegExps() const { if (!m_rareData) return 0; return m_rareData->m_regexps.size(); } RegExp* regexp(int index) const { ASSERT(m_rareData); return m_rareData->m_regexps[index].get(); } // Constant Pools size_t numberOfIdentifiers() const { return m_identifiers.size(); } void addIdentifier(const Identifier& i) { return m_identifiers.append(i); } const Identifier& identifier(int index) const { return m_identifiers[index]; } const Vector& identifiers() const { return m_identifiers; } unsigned addConstant(JSValue v, SourceCodeRepresentation sourceCodeRepresentation = SourceCodeRepresentation::Other) { unsigned result = m_constantRegisters.size(); m_constantRegisters.append(WriteBarrier()); m_constantRegisters.last().set(*vm(), this, v); m_constantsSourceCodeRepresentation.append(sourceCodeRepresentation); return result; } unsigned addConstant(LinkTimeConstant type) { unsigned result = m_constantRegisters.size(); ASSERT(result); unsigned index = static_cast(type); ASSERT(index < LinkTimeConstantCount); m_linkTimeConstants[index] = result; m_constantRegisters.append(WriteBarrier()); m_constantsSourceCodeRepresentation.append(SourceCodeRepresentation::Other); return result; } unsigned registerIndexForLinkTimeConstant(LinkTimeConstant type) { unsigned index = static_cast(type); ASSERT(index < LinkTimeConstantCount); return m_linkTimeConstants[index]; } const Vector>& constantRegisters() { return m_constantRegisters; } const WriteBarrier& constantRegister(int index) const { return m_constantRegisters[index - FirstConstantRegisterIndex]; } ALWAYS_INLINE bool isConstantRegisterIndex(int index) const { return index >= FirstConstantRegisterIndex; } const Vector& constantsSourceCodeRepresentation() { return m_constantsSourceCodeRepresentation; } // Jumps size_t numberOfJumpTargets() const { return m_jumpTargets.size(); } void addJumpTarget(unsigned jumpTarget) { m_jumpTargets.append(jumpTarget); } unsigned jumpTarget(int index) const { return m_jumpTargets[index]; } unsigned lastJumpTarget() const { return m_jumpTargets.last(); } bool isBuiltinFunction() const { return m_isBuiltinFunction; } ConstructorKind constructorKind() const { return static_cast(m_constructorKind); } SuperBinding superBinding() const { return static_cast(m_superBinding); } void shrinkToFit() { m_jumpTargets.shrinkToFit(); m_identifiers.shrinkToFit(); m_constantRegisters.shrinkToFit(); m_constantsSourceCodeRepresentation.shrinkToFit(); m_functionDecls.shrinkToFit(); m_functionExprs.shrinkToFit(); m_propertyAccessInstructions.shrinkToFit(); m_expressionInfo.shrinkToFit(); if (m_rareData) { m_rareData->m_exceptionHandlers.shrinkToFit(); m_rareData->m_regexps.shrinkToFit(); m_rareData->m_constantBuffers.shrinkToFit(); m_rareData->m_switchJumpTables.shrinkToFit(); m_rareData->m_stringSwitchJumpTables.shrinkToFit(); m_rareData->m_expressionInfoFatPositions.shrinkToFit(); } } void setInstructions(std::unique_ptr); const UnlinkedInstructionStream& instructions() const; int m_numVars; int m_numCapturedVars; int m_numCalleeLocals; // Jump Tables size_t numberOfSwitchJumpTables() const { return m_rareData ? m_rareData->m_switchJumpTables.size() : 0; } UnlinkedSimpleJumpTable& addSwitchJumpTable() { createRareDataIfNecessary(); m_rareData->m_switchJumpTables.append(UnlinkedSimpleJumpTable()); return m_rareData->m_switchJumpTables.last(); } UnlinkedSimpleJumpTable& switchJumpTable(int tableIndex) { ASSERT(m_rareData); return m_rareData->m_switchJumpTables[tableIndex]; } size_t numberOfStringSwitchJumpTables() const { return m_rareData ? m_rareData->m_stringSwitchJumpTables.size() : 0; } UnlinkedStringJumpTable& addStringSwitchJumpTable() { createRareDataIfNecessary(); m_rareData->m_stringSwitchJumpTables.append(UnlinkedStringJumpTable()); return m_rareData->m_stringSwitchJumpTables.last(); } UnlinkedStringJumpTable& stringSwitchJumpTable(int tableIndex) { ASSERT(m_rareData); return m_rareData->m_stringSwitchJumpTables[tableIndex]; } unsigned addFunctionDecl(UnlinkedFunctionExecutable* n) { unsigned size = m_functionDecls.size(); m_functionDecls.append(WriteBarrier()); m_functionDecls.last().set(*vm(), this, n); return size; } UnlinkedFunctionExecutable* functionDecl(int index) { return m_functionDecls[index].get(); } size_t numberOfFunctionDecls() { return m_functionDecls.size(); } unsigned addFunctionExpr(UnlinkedFunctionExecutable* n) { unsigned size = m_functionExprs.size(); m_functionExprs.append(WriteBarrier()); m_functionExprs.last().set(*vm(), this, n); return size; } UnlinkedFunctionExecutable* functionExpr(int index) { return m_functionExprs[index].get(); } size_t numberOfFunctionExprs() { return m_functionExprs.size(); } // Exception handling support size_t numberOfExceptionHandlers() const { return m_rareData ? m_rareData->m_exceptionHandlers.size() : 0; } void addExceptionHandler(const UnlinkedHandlerInfo& handler) { createRareDataIfNecessary(); return m_rareData->m_exceptionHandlers.append(handler); } UnlinkedHandlerInfo& exceptionHandler(int index) { ASSERT(m_rareData); return m_rareData->m_exceptionHandlers[index]; } VM* vm() const; UnlinkedArrayProfile addArrayProfile() { return m_arrayProfileCount++; } unsigned numberOfArrayProfiles() { return m_arrayProfileCount; } UnlinkedArrayAllocationProfile addArrayAllocationProfile() { return m_arrayAllocationProfileCount++; } unsigned numberOfArrayAllocationProfiles() { return m_arrayAllocationProfileCount; } UnlinkedObjectAllocationProfile addObjectAllocationProfile() { return m_objectAllocationProfileCount++; } unsigned numberOfObjectAllocationProfiles() { return m_objectAllocationProfileCount; } UnlinkedValueProfile addValueProfile() { return m_valueProfileCount++; } unsigned numberOfValueProfiles() { return m_valueProfileCount; } UnlinkedLLIntCallLinkInfo addLLIntCallLinkInfo() { return m_llintCallLinkInfoCount++; } unsigned numberOfLLintCallLinkInfos() { return m_llintCallLinkInfoCount; } CodeType codeType() const { return m_codeType; } VirtualRegister thisRegister() const { return m_thisRegister; } VirtualRegister scopeRegister() const { return m_scopeRegister; } void addPropertyAccessInstruction(unsigned propertyAccessInstruction) { m_propertyAccessInstructions.append(propertyAccessInstruction); } size_t numberOfPropertyAccessInstructions() const { return m_propertyAccessInstructions.size(); } const Vector& propertyAccessInstructions() const { return m_propertyAccessInstructions; } typedef Vector ConstantBuffer; size_t constantBufferCount() { ASSERT(m_rareData); return m_rareData->m_constantBuffers.size(); } unsigned addConstantBuffer(unsigned length) { createRareDataIfNecessary(); unsigned size = m_rareData->m_constantBuffers.size(); m_rareData->m_constantBuffers.append(Vector(length)); return size; } const ConstantBuffer& constantBuffer(unsigned index) const { ASSERT(m_rareData); return m_rareData->m_constantBuffers[index]; } ConstantBuffer& constantBuffer(unsigned index) { ASSERT(m_rareData); return m_rareData->m_constantBuffers[index]; } bool hasRareData() const { return m_rareData.get(); } int lineNumberForBytecodeOffset(unsigned bytecodeOffset); void expressionRangeForBytecodeOffset(unsigned bytecodeOffset, int& divot, int& startOffset, int& endOffset, unsigned& line, unsigned& column) const; bool typeProfilerExpressionInfoForBytecodeOffset(unsigned bytecodeOffset, unsigned& startDivot, unsigned& endDivot); void recordParse(CodeFeatures features, bool hasCapturedVariables, unsigned firstLine, unsigned lineCount, unsigned endColumn) { m_features = features; m_hasCapturedVariables = hasCapturedVariables; m_firstLine = firstLine; m_lineCount = lineCount; // For the UnlinkedCodeBlock, startColumn is always 0. m_endColumn = endColumn; } const String& sourceURLDirective() const { return m_sourceURLDirective; } const String& sourceMappingURLDirective() const { return m_sourceMappingURLDirective; } void setSourceURLDirective(const String& sourceURL) { m_sourceURLDirective = sourceURL; } void setSourceMappingURLDirective(const String& sourceMappingURL) { m_sourceMappingURLDirective = sourceMappingURL; } CodeFeatures codeFeatures() const { return m_features; } bool hasCapturedVariables() const { return m_hasCapturedVariables; } unsigned firstLine() const { return m_firstLine; } unsigned lineCount() const { return m_lineCount; } ALWAYS_INLINE unsigned startColumn() const { return 0; } unsigned endColumn() const { return m_endColumn; } void addOpProfileControlFlowBytecodeOffset(size_t offset) { createRareDataIfNecessary(); m_rareData->m_opProfileControlFlowBytecodeOffsets.append(offset); } const Vector& opProfileControlFlowBytecodeOffsets() const { ASSERT(m_rareData); return m_rareData->m_opProfileControlFlowBytecodeOffsets; } bool hasOpProfileControlFlowBytecodeOffsets() const { return m_rareData && !m_rareData->m_opProfileControlFlowBytecodeOffsets.isEmpty(); } void dumpExpressionRangeInfo(); // For debugging purpose only. bool wasCompiledWithDebuggingOpcodes() const { return m_wasCompiledWithDebuggingOpcodes; } protected: UnlinkedCodeBlock(VM*, Structure*, CodeType, const ExecutableInfo&, DebuggerMode); ~UnlinkedCodeBlock(); void finishCreation(VM& vm) { Base::finishCreation(vm); } private: void createRareDataIfNecessary() { if (!m_rareData) m_rareData = std::make_unique(); } void getLineAndColumn(const ExpressionRangeInfo&, unsigned& line, unsigned& column) const; int m_numParameters; std::unique_ptr m_unlinkedInstructions; VirtualRegister m_thisRegister; VirtualRegister m_scopeRegister; VirtualRegister m_globalObjectRegister; String m_sourceURLDirective; String m_sourceMappingURLDirective; unsigned m_usesEval : 1; unsigned m_isStrictMode : 1; unsigned m_isConstructor : 1; unsigned m_hasCapturedVariables : 1; unsigned m_isBuiltinFunction : 1; unsigned m_constructorKind : 2; unsigned m_superBinding : 1; unsigned m_derivedContextType : 2; unsigned m_evalContextType : 2; unsigned m_isArrowFunctionContext : 1; unsigned m_isClassContext : 1; unsigned m_wasCompiledWithDebuggingOpcodes : 1; unsigned m_firstLine; unsigned m_lineCount; unsigned m_endColumn; SourceParseMode m_parseMode; CodeFeatures m_features; CodeType m_codeType; Vector m_jumpTargets; Vector m_propertyAccessInstructions; // Constant Pools Vector m_identifiers; Vector> m_constantRegisters; Vector m_constantsSourceCodeRepresentation; typedef Vector> FunctionExpressionVector; FunctionExpressionVector m_functionDecls; FunctionExpressionVector m_functionExprs; std::array m_linkTimeConstants; unsigned m_arrayProfileCount; unsigned m_arrayAllocationProfileCount; unsigned m_objectAllocationProfileCount; unsigned m_valueProfileCount; unsigned m_llintCallLinkInfoCount; public: struct RareData { WTF_MAKE_FAST_ALLOCATED; public: Vector m_exceptionHandlers; // Rare Constants Vector> m_regexps; // Buffers used for large array literals Vector m_constantBuffers; // Jump Tables Vector m_switchJumpTables; Vector m_stringSwitchJumpTables; Vector m_expressionInfoFatPositions; struct TypeProfilerExpressionRange { unsigned m_startDivot; unsigned m_endDivot; }; HashMap m_typeProfilerInfoMap; Vector m_opProfileControlFlowBytecodeOffsets; }; private: std::unique_ptr m_rareData; Vector m_expressionInfo; protected: static void visitChildren(JSCell*, SlotVisitor&); static size_t estimatedSize(JSCell*); public: DECLARE_INFO; }; class UnlinkedGlobalCodeBlock : public UnlinkedCodeBlock { public: typedef UnlinkedCodeBlock Base; protected: UnlinkedGlobalCodeBlock(VM* vm, Structure* structure, CodeType codeType, const ExecutableInfo& info, DebuggerMode debuggerMode) : Base(vm, structure, codeType, info, debuggerMode) { } DECLARE_INFO; }; class UnlinkedProgramCodeBlock final : public UnlinkedGlobalCodeBlock { private: friend class CodeCache; static UnlinkedProgramCodeBlock* create(VM* vm, const ExecutableInfo& info, DebuggerMode debuggerMode) { UnlinkedProgramCodeBlock* instance = new (NotNull, allocateCell(vm->heap)) UnlinkedProgramCodeBlock(vm, vm->unlinkedProgramCodeBlockStructure.get(), info, debuggerMode); instance->finishCreation(*vm); return instance; } public: typedef UnlinkedGlobalCodeBlock Base; static const unsigned StructureFlags = Base::StructureFlags | StructureIsImmortal; static void destroy(JSCell*); void setVariableDeclarations(const VariableEnvironment& environment) { m_varDeclarations = environment; } const VariableEnvironment& variableDeclarations() const { return m_varDeclarations; } void setLexicalDeclarations(const VariableEnvironment& environment) { m_lexicalDeclarations = environment; } const VariableEnvironment& lexicalDeclarations() const { return m_lexicalDeclarations; } static void visitChildren(JSCell*, SlotVisitor&); private: UnlinkedProgramCodeBlock(VM* vm, Structure* structure, const ExecutableInfo& info, DebuggerMode debuggerMode) : Base(vm, structure, GlobalCode, info, debuggerMode) { } VariableEnvironment m_varDeclarations; VariableEnvironment m_lexicalDeclarations; public: static Structure* createStructure(VM& vm, JSGlobalObject* globalObject, JSValue proto) { return Structure::create(vm, globalObject, proto, TypeInfo(UnlinkedProgramCodeBlockType, StructureFlags), info()); } DECLARE_INFO; }; class UnlinkedModuleProgramCodeBlock final : public UnlinkedGlobalCodeBlock { private: friend class CodeCache; static UnlinkedModuleProgramCodeBlock* create(VM* vm, const ExecutableInfo& info, DebuggerMode debuggerMode) { UnlinkedModuleProgramCodeBlock* instance = new (NotNull, allocateCell(vm->heap)) UnlinkedModuleProgramCodeBlock(vm, vm->unlinkedModuleProgramCodeBlockStructure.get(), info, debuggerMode); instance->finishCreation(*vm); return instance; } public: typedef UnlinkedGlobalCodeBlock Base; static const unsigned StructureFlags = Base::StructureFlags | StructureIsImmortal; static void destroy(JSCell*); static void visitChildren(JSCell*, SlotVisitor&); // This offset represents the constant register offset to the stored symbol table that represents the layout of the // module environment. This symbol table is created by the byte code generator since the module environment includes // the top-most lexical captured variables inside the module code. This means that, once the module environment is // allocated and instantiated from this symbol table, it is titely coupled with the specific unlinked module program // code block and the stored symbol table. So before executing the module code, we should not clear the unlinked module // program code block in the module executable. This requirement is met because the garbage collector only clears // unlinked code in (1) unmarked executables and (2) function executables. // // Since the function code may be executed repeatedly and the environment of each function execution is different, // the function code need to allocate and instantiate the environment in the prologue of the function code. On the // other hand, the module code is executed only once. So we can instantiate the module environment outside the module // code. At that time, we construct the module environment by using the symbol table that is held by the module executable. // The symbol table held by the executable is the cloned one from one in the unlinked code block. Instantiating the module // environment before executing and linking the module code is required to link the imported bindings between the modules. // // The unlinked module program code block only holds the pre-cloned symbol table in its constant register pool. It does // not hold the instantiated module environment. So while the module environment requires the specific unlinked module // program code block, the unlinked module code block can be used for the module environment instantiated from this // unlinked code block. There is 1:N relation between the unlinked module code block and the module environments. So the // unlinked module program code block can be cached. // // On the other hand, the linked code block for the module environment includes the resolved references to the imported // bindings. The imported binding references the other module environment, so the linked code block is titly coupled // with the specific set of the module environments. Thus, the linked code block should not be cached. int moduleEnvironmentSymbolTableConstantRegisterOffset() { return m_moduleEnvironmentSymbolTableConstantRegisterOffset; } void setModuleEnvironmentSymbolTableConstantRegisterOffset(int offset) { m_moduleEnvironmentSymbolTableConstantRegisterOffset = offset; } private: UnlinkedModuleProgramCodeBlock(VM* vm, Structure* structure, const ExecutableInfo& info, DebuggerMode debuggerMode) : Base(vm, structure, ModuleCode, info, debuggerMode) { } int m_moduleEnvironmentSymbolTableConstantRegisterOffset { 0 }; public: static Structure* createStructure(VM& vm, JSGlobalObject* globalObject, JSValue proto) { return Structure::create(vm, globalObject, proto, TypeInfo(UnlinkedModuleProgramCodeBlockType, StructureFlags), info()); } DECLARE_INFO; }; class UnlinkedEvalCodeBlock final : public UnlinkedGlobalCodeBlock { private: friend class CodeCache; static UnlinkedEvalCodeBlock* create(VM* vm, const ExecutableInfo& info, DebuggerMode debuggerMode) { UnlinkedEvalCodeBlock* instance = new (NotNull, allocateCell(vm->heap)) UnlinkedEvalCodeBlock(vm, vm->unlinkedEvalCodeBlockStructure.get(), info, debuggerMode); instance->finishCreation(*vm); return instance; } public: typedef UnlinkedGlobalCodeBlock Base; static const unsigned StructureFlags = Base::StructureFlags | StructureIsImmortal; static void destroy(JSCell*); const Identifier& variable(unsigned index) { return m_variables[index]; } unsigned numVariables() { return m_variables.size(); } void adoptVariables(Vector& variables) { ASSERT(m_variables.isEmpty()); m_variables.swap(variables); } private: UnlinkedEvalCodeBlock(VM* vm, Structure* structure, const ExecutableInfo& info, DebuggerMode debuggerMode) : Base(vm, structure, EvalCode, info, debuggerMode) { } Vector m_variables; public: static Structure* createStructure(VM& vm, JSGlobalObject* globalObject, JSValue proto) { return Structure::create(vm, globalObject, proto, TypeInfo(UnlinkedEvalCodeBlockType, StructureFlags), info()); } DECLARE_INFO; }; class UnlinkedFunctionCodeBlock final : public UnlinkedCodeBlock { public: typedef UnlinkedCodeBlock Base; static const unsigned StructureFlags = Base::StructureFlags | StructureIsImmortal; static UnlinkedFunctionCodeBlock* create(VM* vm, CodeType codeType, const ExecutableInfo& info, DebuggerMode debuggerMode) { UnlinkedFunctionCodeBlock* instance = new (NotNull, allocateCell(vm->heap)) UnlinkedFunctionCodeBlock(vm, vm->unlinkedFunctionCodeBlockStructure.get(), codeType, info, debuggerMode); instance->finishCreation(*vm); return instance; } static void destroy(JSCell*); private: UnlinkedFunctionCodeBlock(VM* vm, Structure* structure, CodeType codeType, const ExecutableInfo& info, DebuggerMode debuggerMode) : Base(vm, structure, codeType, info, debuggerMode) { } public: static Structure* createStructure(VM& vm, JSGlobalObject* globalObject, JSValue proto) { return Structure::create(vm, globalObject, proto, TypeInfo(UnlinkedFunctionCodeBlockType, StructureFlags), info()); } DECLARE_INFO; }; } #endif // UnlinkedCodeBlock_h