// Copyright 2012 the V8 project authors. All rights reserved. // Use of this source code is governed by a BSD-style license that can be // found in the LICENSE file. #ifndef V8_AST_H_ #define V8_AST_H_ #include "src/v8.h" #include "src/assembler.h" #include "src/ast-value-factory.h" #include "src/bailout-reason.h" #include "src/factory.h" #include "src/isolate.h" #include "src/jsregexp.h" #include "src/list-inl.h" #include "src/modules.h" #include "src/runtime/runtime.h" #include "src/small-pointer-list.h" #include "src/smart-pointers.h" #include "src/token.h" #include "src/types.h" #include "src/utils.h" #include "src/variables.h" namespace v8 { namespace internal { // The abstract syntax tree is an intermediate, light-weight // representation of the parsed JavaScript code suitable for // compilation to native code. // Nodes are allocated in a separate zone, which allows faster // allocation and constant-time deallocation of the entire syntax // tree. // ---------------------------------------------------------------------------- // Nodes of the abstract syntax tree. Only concrete classes are // enumerated here. #define DECLARATION_NODE_LIST(V) \ V(VariableDeclaration) \ V(FunctionDeclaration) \ V(ModuleDeclaration) \ V(ImportDeclaration) \ V(ExportDeclaration) #define MODULE_NODE_LIST(V) \ V(ModuleLiteral) \ V(ModulePath) \ V(ModuleUrl) #define STATEMENT_NODE_LIST(V) \ V(Block) \ V(ModuleStatement) \ V(ExpressionStatement) \ V(EmptyStatement) \ V(IfStatement) \ V(ContinueStatement) \ V(BreakStatement) \ V(ReturnStatement) \ V(WithStatement) \ V(SwitchStatement) \ V(DoWhileStatement) \ V(WhileStatement) \ V(ForStatement) \ V(ForInStatement) \ V(ForOfStatement) \ V(TryCatchStatement) \ V(TryFinallyStatement) \ V(DebuggerStatement) #define EXPRESSION_NODE_LIST(V) \ V(FunctionLiteral) \ V(ClassLiteral) \ V(NativeFunctionLiteral) \ V(Conditional) \ V(VariableProxy) \ V(Literal) \ V(RegExpLiteral) \ V(ObjectLiteral) \ V(ArrayLiteral) \ V(Assignment) \ V(Yield) \ V(Throw) \ V(Property) \ V(Call) \ V(CallNew) \ V(CallRuntime) \ V(UnaryOperation) \ V(CountOperation) \ V(BinaryOperation) \ V(CompareOperation) \ V(ThisFunction) \ V(SuperReference) \ V(CaseClause) #define AST_NODE_LIST(V) \ DECLARATION_NODE_LIST(V) \ MODULE_NODE_LIST(V) \ STATEMENT_NODE_LIST(V) \ EXPRESSION_NODE_LIST(V) // Forward declarations class AstNodeFactory; class AstVisitor; class Declaration; class Module; class BreakableStatement; class Expression; class IterationStatement; class MaterializedLiteral; class Statement; class TypeFeedbackOracle; class RegExpAlternative; class RegExpAssertion; class RegExpAtom; class RegExpBackReference; class RegExpCapture; class RegExpCharacterClass; class RegExpCompiler; class RegExpDisjunction; class RegExpEmpty; class RegExpLookahead; class RegExpQuantifier; class RegExpText; #define DEF_FORWARD_DECLARATION(type) class type; AST_NODE_LIST(DEF_FORWARD_DECLARATION) #undef DEF_FORWARD_DECLARATION // Typedef only introduced to avoid unreadable code. // Please do appreciate the required space in "> >". typedef ZoneList > ZoneStringList; typedef ZoneList > ZoneObjectList; #define DECLARE_NODE_TYPE(type) \ void Accept(AstVisitor* v) OVERRIDE; \ AstNode::NodeType node_type() const FINAL { return AstNode::k##type; } \ friend class AstNodeFactory; enum AstPropertiesFlag { kDontSelfOptimize, kDontSoftInline, kDontCache }; class FeedbackVectorRequirements { public: FeedbackVectorRequirements(int slots, int ic_slots) : slots_(slots), ic_slots_(ic_slots) {} int slots() const { return slots_; } int ic_slots() const { return ic_slots_; } private: int slots_; int ic_slots_; }; class AstProperties FINAL BASE_EMBEDDED { public: class Flags : public EnumSet {}; AstProperties() : node_count_(0) {} Flags* flags() { return &flags_; } int node_count() { return node_count_; } void add_node_count(int count) { node_count_ += count; } int slots() const { return spec_.slots(); } void increase_slots(int count) { spec_.increase_slots(count); } int ic_slots() const { return spec_.ic_slots(); } void increase_ic_slots(int count) { spec_.increase_ic_slots(count); } void SetKind(int ic_slot, Code::Kind kind) { spec_.SetKind(ic_slot, kind); } const FeedbackVectorSpec& get_spec() const { return spec_; } private: Flags flags_; int node_count_; FeedbackVectorSpec spec_; }; class AstNode: public ZoneObject { public: #define DECLARE_TYPE_ENUM(type) k##type, enum NodeType { AST_NODE_LIST(DECLARE_TYPE_ENUM) kInvalid = -1 }; #undef DECLARE_TYPE_ENUM void* operator new(size_t size, Zone* zone) { return zone->New(size); } explicit AstNode(int position): position_(position) {} virtual ~AstNode() {} virtual void Accept(AstVisitor* v) = 0; virtual NodeType node_type() const = 0; int position() const { return position_; } // Type testing & conversion functions overridden by concrete subclasses. #define DECLARE_NODE_FUNCTIONS(type) \ bool Is##type() const { return node_type() == AstNode::k##type; } \ type* As##type() { \ return Is##type() ? reinterpret_cast(this) : NULL; \ } \ const type* As##type() const { \ return Is##type() ? reinterpret_cast(this) : NULL; \ } AST_NODE_LIST(DECLARE_NODE_FUNCTIONS) #undef DECLARE_NODE_FUNCTIONS virtual BreakableStatement* AsBreakableStatement() { return NULL; } virtual IterationStatement* AsIterationStatement() { return NULL; } virtual MaterializedLiteral* AsMaterializedLiteral() { return NULL; } // The interface for feedback slots, with default no-op implementations for // node types which don't actually have this. Note that this is conceptually // not really nice, but multiple inheritance would introduce yet another // vtable entry per node, something we don't want for space reasons. virtual FeedbackVectorRequirements ComputeFeedbackRequirements( Isolate* isolate) { return FeedbackVectorRequirements(0, 0); } virtual void SetFirstFeedbackSlot(FeedbackVectorSlot slot) { UNREACHABLE(); } virtual void SetFirstFeedbackICSlot(FeedbackVectorICSlot slot) { UNREACHABLE(); } // Each ICSlot stores a kind of IC which the participating node should know. virtual Code::Kind FeedbackICSlotKind(int index) { UNREACHABLE(); return Code::NUMBER_OF_KINDS; } private: // Hidden to prevent accidental usage. It would have to load the // current zone from the TLS. void* operator new(size_t size); friend class CaseClause; // Generates AST IDs. int position_; }; class Statement : public AstNode { public: explicit Statement(Zone* zone, int position) : AstNode(position) {} bool IsEmpty() { return AsEmptyStatement() != NULL; } virtual bool IsJump() const { return false; } }; class SmallMapList FINAL { public: SmallMapList() {} SmallMapList(int capacity, Zone* zone) : list_(capacity, zone) {} void Reserve(int capacity, Zone* zone) { list_.Reserve(capacity, zone); } void Clear() { list_.Clear(); } void Sort() { list_.Sort(); } bool is_empty() const { return list_.is_empty(); } int length() const { return list_.length(); } void AddMapIfMissing(Handle map, Zone* zone) { if (!Map::TryUpdate(map).ToHandle(&map)) return; for (int i = 0; i < length(); ++i) { if (at(i).is_identical_to(map)) return; } Add(map, zone); } void FilterForPossibleTransitions(Map* root_map) { for (int i = list_.length() - 1; i >= 0; i--) { if (at(i)->FindRootMap() != root_map) { list_.RemoveElement(list_.at(i)); } } } void Add(Handle handle, Zone* zone) { list_.Add(handle.location(), zone); } Handle at(int i) const { return Handle(list_.at(i)); } Handle first() const { return at(0); } Handle last() const { return at(length() - 1); } private: // The list stores pointers to Map*, that is Map**, so it's GC safe. SmallPointerList list_; DISALLOW_COPY_AND_ASSIGN(SmallMapList); }; class Expression : public AstNode { public: enum Context { // Not assigned a context yet, or else will not be visited during // code generation. kUninitialized, // Evaluated for its side effects. kEffect, // Evaluated for its value (and side effects). kValue, // Evaluated for control flow (and side effects). kTest }; virtual bool IsValidReferenceExpression() const { return false; } // Helpers for ToBoolean conversion. virtual bool ToBooleanIsTrue() const { return false; } virtual bool ToBooleanIsFalse() const { return false; } // Symbols that cannot be parsed as array indices are considered property // names. We do not treat symbols that can be array indexes as property // names because [] for string objects is handled only by keyed ICs. virtual bool IsPropertyName() const { return false; } // True iff the expression is a literal represented as a smi. bool IsSmiLiteral() const; // True iff the expression is a string literal. bool IsStringLiteral() const; // True iff the expression is the null literal. bool IsNullLiteral() const; // True if we can prove that the expression is the undefined literal. bool IsUndefinedLiteral(Isolate* isolate) const; // Expression type bounds Bounds bounds() const { return bounds_; } void set_bounds(Bounds bounds) { bounds_ = bounds; } // Whether the expression is parenthesized bool is_parenthesized() const { return IsParenthesizedField::decode(bit_field_); } bool is_multi_parenthesized() const { return IsMultiParenthesizedField::decode(bit_field_); } void increase_parenthesization_level() { bit_field_ = IsMultiParenthesizedField::update(bit_field_, is_parenthesized()); bit_field_ = IsParenthesizedField::update(bit_field_, true); } // Type feedback information for assignments and properties. virtual bool IsMonomorphic() { UNREACHABLE(); return false; } virtual SmallMapList* GetReceiverTypes() { UNREACHABLE(); return NULL; } virtual KeyedAccessStoreMode GetStoreMode() const { UNREACHABLE(); return STANDARD_STORE; } virtual IcCheckType GetKeyType() const { UNREACHABLE(); return ELEMENT; } // TODO(rossberg): this should move to its own AST node eventually. virtual void RecordToBooleanTypeFeedback(TypeFeedbackOracle* oracle); byte to_boolean_types() const { return ToBooleanTypesField::decode(bit_field_); } void set_base_id(int id) { base_id_ = id; } static int num_ids() { return parent_num_ids() + 2; } BailoutId id() const { return BailoutId(local_id(0)); } TypeFeedbackId test_id() const { return TypeFeedbackId(local_id(1)); } protected: Expression(Zone* zone, int pos) : AstNode(pos), base_id_(BailoutId::None().ToInt()), bounds_(Bounds::Unbounded(zone)), bit_field_(0) {} static int parent_num_ids() { return 0; } void set_to_boolean_types(byte types) { bit_field_ = ToBooleanTypesField::update(bit_field_, types); } int base_id() const { DCHECK(!BailoutId(base_id_).IsNone()); return base_id_; } private: int local_id(int n) const { return base_id() + parent_num_ids() + n; } int base_id_; Bounds bounds_; class ToBooleanTypesField : public BitField16 {}; class IsParenthesizedField : public BitField16 {}; class IsMultiParenthesizedField : public BitField16 {}; uint16_t bit_field_; // Ends with 16-bit field; deriving classes in turn begin with // 16-bit fields for optimum packing efficiency. }; class BreakableStatement : public Statement { public: enum BreakableType { TARGET_FOR_ANONYMOUS, TARGET_FOR_NAMED_ONLY }; // The labels associated with this statement. May be NULL; // if it is != NULL, guaranteed to contain at least one entry. ZoneList* labels() const { return labels_; } // Type testing & conversion. BreakableStatement* AsBreakableStatement() FINAL { return this; } // Code generation Label* break_target() { return &break_target_; } // Testers. bool is_target_for_anonymous() const { return breakable_type_ == TARGET_FOR_ANONYMOUS; } void set_base_id(int id) { base_id_ = id; } static int num_ids() { return parent_num_ids() + 2; } BailoutId EntryId() const { return BailoutId(local_id(0)); } BailoutId ExitId() const { return BailoutId(local_id(1)); } protected: BreakableStatement(Zone* zone, ZoneList* labels, BreakableType breakable_type, int position) : Statement(zone, position), labels_(labels), breakable_type_(breakable_type), base_id_(BailoutId::None().ToInt()) { DCHECK(labels == NULL || labels->length() > 0); } static int parent_num_ids() { return 0; } int base_id() const { DCHECK(!BailoutId(base_id_).IsNone()); return base_id_; } private: int local_id(int n) const { return base_id() + parent_num_ids() + n; } ZoneList* labels_; BreakableType breakable_type_; Label break_target_; int base_id_; }; class Block FINAL : public BreakableStatement { public: DECLARE_NODE_TYPE(Block) void AddStatement(Statement* statement, Zone* zone) { statements_.Add(statement, zone); } ZoneList* statements() { return &statements_; } bool is_initializer_block() const { return is_initializer_block_; } static int num_ids() { return parent_num_ids() + 1; } BailoutId DeclsId() const { return BailoutId(local_id(0)); } bool IsJump() const OVERRIDE { return !statements_.is_empty() && statements_.last()->IsJump() && labels() == NULL; // Good enough as an approximation... } Scope* scope() const { return scope_; } void set_scope(Scope* scope) { scope_ = scope; } protected: Block(Zone* zone, ZoneList* labels, int capacity, bool is_initializer_block, int pos) : BreakableStatement(zone, labels, TARGET_FOR_NAMED_ONLY, pos), statements_(capacity, zone), is_initializer_block_(is_initializer_block), scope_(NULL) {} static int parent_num_ids() { return BreakableStatement::num_ids(); } private: int local_id(int n) const { return base_id() + parent_num_ids() + n; } ZoneList statements_; bool is_initializer_block_; Scope* scope_; }; class Declaration : public AstNode { public: VariableProxy* proxy() const { return proxy_; } VariableMode mode() const { return mode_; } Scope* scope() const { return scope_; } virtual InitializationFlag initialization() const = 0; virtual bool IsInlineable() const; protected: Declaration(Zone* zone, VariableProxy* proxy, VariableMode mode, Scope* scope, int pos) : AstNode(pos), mode_(mode), proxy_(proxy), scope_(scope) { DCHECK(IsDeclaredVariableMode(mode)); } private: VariableMode mode_; VariableProxy* proxy_; // Nested scope from which the declaration originated. Scope* scope_; }; class VariableDeclaration FINAL : public Declaration { public: DECLARE_NODE_TYPE(VariableDeclaration) InitializationFlag initialization() const OVERRIDE { return mode() == VAR ? kCreatedInitialized : kNeedsInitialization; } protected: VariableDeclaration(Zone* zone, VariableProxy* proxy, VariableMode mode, Scope* scope, int pos) : Declaration(zone, proxy, mode, scope, pos) { } }; class FunctionDeclaration FINAL : public Declaration { public: DECLARE_NODE_TYPE(FunctionDeclaration) FunctionLiteral* fun() const { return fun_; } InitializationFlag initialization() const OVERRIDE { return kCreatedInitialized; } bool IsInlineable() const OVERRIDE; protected: FunctionDeclaration(Zone* zone, VariableProxy* proxy, VariableMode mode, FunctionLiteral* fun, Scope* scope, int pos) : Declaration(zone, proxy, mode, scope, pos), fun_(fun) { DCHECK(mode == VAR || mode == LET || mode == CONST); DCHECK(fun != NULL); } private: FunctionLiteral* fun_; }; class ModuleDeclaration FINAL : public Declaration { public: DECLARE_NODE_TYPE(ModuleDeclaration) Module* module() const { return module_; } InitializationFlag initialization() const OVERRIDE { return kCreatedInitialized; } protected: ModuleDeclaration(Zone* zone, VariableProxy* proxy, Module* module, Scope* scope, int pos) : Declaration(zone, proxy, CONST, scope, pos), module_(module) {} private: Module* module_; }; class ImportDeclaration FINAL : public Declaration { public: DECLARE_NODE_TYPE(ImportDeclaration) Module* module() const { return module_; } InitializationFlag initialization() const OVERRIDE { return kCreatedInitialized; } protected: ImportDeclaration(Zone* zone, VariableProxy* proxy, Module* module, Scope* scope, int pos) : Declaration(zone, proxy, LET, scope, pos), module_(module) { } private: Module* module_; }; class ExportDeclaration FINAL : public Declaration { public: DECLARE_NODE_TYPE(ExportDeclaration) InitializationFlag initialization() const OVERRIDE { return kCreatedInitialized; } protected: ExportDeclaration(Zone* zone, VariableProxy* proxy, Scope* scope, int pos) : Declaration(zone, proxy, LET, scope, pos) {} }; class Module : public AstNode { public: ModuleDescriptor* descriptor() const { return descriptor_; } Block* body() const { return body_; } protected: Module(Zone* zone, int pos) : AstNode(pos), descriptor_(ModuleDescriptor::New(zone)), body_(NULL) {} Module(Zone* zone, ModuleDescriptor* descriptor, int pos, Block* body = NULL) : AstNode(pos), descriptor_(descriptor), body_(body) {} private: ModuleDescriptor* descriptor_; Block* body_; }; class ModuleLiteral FINAL : public Module { public: DECLARE_NODE_TYPE(ModuleLiteral) protected: ModuleLiteral(Zone* zone, Block* body, ModuleDescriptor* descriptor, int pos) : Module(zone, descriptor, pos, body) {} }; class ModulePath FINAL : public Module { public: DECLARE_NODE_TYPE(ModulePath) Module* module() const { return module_; } Handle name() const { return name_->string(); } protected: ModulePath(Zone* zone, Module* module, const AstRawString* name, int pos) : Module(zone, pos), module_(module), name_(name) {} private: Module* module_; const AstRawString* name_; }; class ModuleUrl FINAL : public Module { public: DECLARE_NODE_TYPE(ModuleUrl) Handle url() const { return url_; } protected: ModuleUrl(Zone* zone, Handle url, int pos) : Module(zone, pos), url_(url) { } private: Handle url_; }; class ModuleStatement FINAL : public Statement { public: DECLARE_NODE_TYPE(ModuleStatement) Block* body() const { return body_; } protected: ModuleStatement(Zone* zone, Block* body, int pos) : Statement(zone, pos), body_(body) {} private: Block* body_; }; class IterationStatement : public BreakableStatement { public: // Type testing & conversion. IterationStatement* AsIterationStatement() FINAL { return this; } Statement* body() const { return body_; } static int num_ids() { return parent_num_ids() + 1; } BailoutId OsrEntryId() const { return BailoutId(local_id(0)); } virtual BailoutId ContinueId() const = 0; virtual BailoutId StackCheckId() const = 0; // Code generation Label* continue_target() { return &continue_target_; } protected: IterationStatement(Zone* zone, ZoneList* labels, int pos) : BreakableStatement(zone, labels, TARGET_FOR_ANONYMOUS, pos), body_(NULL) {} static int parent_num_ids() { return BreakableStatement::num_ids(); } void Initialize(Statement* body) { body_ = body; } private: int local_id(int n) const { return base_id() + parent_num_ids() + n; } Statement* body_; Label continue_target_; }; class DoWhileStatement FINAL : public IterationStatement { public: DECLARE_NODE_TYPE(DoWhileStatement) void Initialize(Expression* cond, Statement* body) { IterationStatement::Initialize(body); cond_ = cond; } Expression* cond() const { return cond_; } static int num_ids() { return parent_num_ids() + 2; } BailoutId ContinueId() const OVERRIDE { return BailoutId(local_id(0)); } BailoutId StackCheckId() const OVERRIDE { return BackEdgeId(); } BailoutId BackEdgeId() const { return BailoutId(local_id(1)); } protected: DoWhileStatement(Zone* zone, ZoneList* labels, int pos) : IterationStatement(zone, labels, pos), cond_(NULL) {} static int parent_num_ids() { return IterationStatement::num_ids(); } private: int local_id(int n) const { return base_id() + parent_num_ids() + n; } Expression* cond_; }; class WhileStatement FINAL : public IterationStatement { public: DECLARE_NODE_TYPE(WhileStatement) void Initialize(Expression* cond, Statement* body) { IterationStatement::Initialize(body); cond_ = cond; } Expression* cond() const { return cond_; } static int num_ids() { return parent_num_ids() + 1; } BailoutId ContinueId() const OVERRIDE { return EntryId(); } BailoutId StackCheckId() const OVERRIDE { return BodyId(); } BailoutId BodyId() const { return BailoutId(local_id(0)); } protected: WhileStatement(Zone* zone, ZoneList* labels, int pos) : IterationStatement(zone, labels, pos), cond_(NULL) {} static int parent_num_ids() { return IterationStatement::num_ids(); } private: int local_id(int n) const { return base_id() + parent_num_ids() + n; } Expression* cond_; }; class ForStatement FINAL : public IterationStatement { public: DECLARE_NODE_TYPE(ForStatement) void Initialize(Statement* init, Expression* cond, Statement* next, Statement* body) { IterationStatement::Initialize(body); init_ = init; cond_ = cond; next_ = next; } Statement* init() const { return init_; } Expression* cond() const { return cond_; } Statement* next() const { return next_; } static int num_ids() { return parent_num_ids() + 2; } BailoutId ContinueId() const OVERRIDE { return BailoutId(local_id(0)); } BailoutId StackCheckId() const OVERRIDE { return BodyId(); } BailoutId BodyId() const { return BailoutId(local_id(1)); } protected: ForStatement(Zone* zone, ZoneList* labels, int pos) : IterationStatement(zone, labels, pos), init_(NULL), cond_(NULL), next_(NULL) {} static int parent_num_ids() { return IterationStatement::num_ids(); } private: int local_id(int n) const { return base_id() + parent_num_ids() + n; } Statement* init_; Expression* cond_; Statement* next_; }; class ForEachStatement : public IterationStatement { public: enum VisitMode { ENUMERATE, // for (each in subject) body; ITERATE // for (each of subject) body; }; void Initialize(Expression* each, Expression* subject, Statement* body) { IterationStatement::Initialize(body); each_ = each; subject_ = subject; } Expression* each() const { return each_; } Expression* subject() const { return subject_; } protected: ForEachStatement(Zone* zone, ZoneList* labels, int pos) : IterationStatement(zone, labels, pos), each_(NULL), subject_(NULL) {} private: Expression* each_; Expression* subject_; }; class ForInStatement FINAL : public ForEachStatement { public: DECLARE_NODE_TYPE(ForInStatement) Expression* enumerable() const { return subject(); } // Type feedback information. virtual FeedbackVectorRequirements ComputeFeedbackRequirements( Isolate* isolate) OVERRIDE { return FeedbackVectorRequirements(1, 0); } void SetFirstFeedbackSlot(FeedbackVectorSlot slot) OVERRIDE { for_in_feedback_slot_ = slot; } FeedbackVectorSlot ForInFeedbackSlot() { DCHECK(!for_in_feedback_slot_.IsInvalid()); return for_in_feedback_slot_; } enum ForInType { FAST_FOR_IN, SLOW_FOR_IN }; ForInType for_in_type() const { return for_in_type_; } void set_for_in_type(ForInType type) { for_in_type_ = type; } static int num_ids() { return parent_num_ids() + 5; } BailoutId BodyId() const { return BailoutId(local_id(0)); } BailoutId PrepareId() const { return BailoutId(local_id(1)); } BailoutId EnumId() const { return BailoutId(local_id(2)); } BailoutId ToObjectId() const { return BailoutId(local_id(3)); } BailoutId AssignmentId() const { return BailoutId(local_id(4)); } BailoutId ContinueId() const OVERRIDE { return EntryId(); } BailoutId StackCheckId() const OVERRIDE { return BodyId(); } protected: ForInStatement(Zone* zone, ZoneList* labels, int pos) : ForEachStatement(zone, labels, pos), for_in_type_(SLOW_FOR_IN), for_in_feedback_slot_(FeedbackVectorSlot::Invalid()) {} static int parent_num_ids() { return ForEachStatement::num_ids(); } private: int local_id(int n) const { return base_id() + parent_num_ids() + n; } ForInType for_in_type_; FeedbackVectorSlot for_in_feedback_slot_; }; class ForOfStatement FINAL : public ForEachStatement { public: DECLARE_NODE_TYPE(ForOfStatement) void Initialize(Expression* each, Expression* subject, Statement* body, Expression* assign_iterator, Expression* next_result, Expression* result_done, Expression* assign_each) { ForEachStatement::Initialize(each, subject, body); assign_iterator_ = assign_iterator; next_result_ = next_result; result_done_ = result_done; assign_each_ = assign_each; } Expression* iterable() const { return subject(); } // var iterator = subject[Symbol.iterator](); Expression* assign_iterator() const { return assign_iterator_; } // var result = iterator.next(); Expression* next_result() const { return next_result_; } // result.done Expression* result_done() const { return result_done_; } // each = result.value Expression* assign_each() const { return assign_each_; } BailoutId ContinueId() const OVERRIDE { return EntryId(); } BailoutId StackCheckId() const OVERRIDE { return BackEdgeId(); } static int num_ids() { return parent_num_ids() + 1; } BailoutId BackEdgeId() const { return BailoutId(local_id(0)); } protected: ForOfStatement(Zone* zone, ZoneList* labels, int pos) : ForEachStatement(zone, labels, pos), assign_iterator_(NULL), next_result_(NULL), result_done_(NULL), assign_each_(NULL) {} static int parent_num_ids() { return ForEachStatement::num_ids(); } private: int local_id(int n) const { return base_id() + parent_num_ids() + n; } Expression* assign_iterator_; Expression* next_result_; Expression* result_done_; Expression* assign_each_; }; class ExpressionStatement FINAL : public Statement { public: DECLARE_NODE_TYPE(ExpressionStatement) void set_expression(Expression* e) { expression_ = e; } Expression* expression() const { return expression_; } bool IsJump() const OVERRIDE { return expression_->IsThrow(); } protected: ExpressionStatement(Zone* zone, Expression* expression, int pos) : Statement(zone, pos), expression_(expression) { } private: Expression* expression_; }; class JumpStatement : public Statement { public: bool IsJump() const FINAL { return true; } protected: explicit JumpStatement(Zone* zone, int pos) : Statement(zone, pos) {} }; class ContinueStatement FINAL : public JumpStatement { public: DECLARE_NODE_TYPE(ContinueStatement) IterationStatement* target() const { return target_; } protected: explicit ContinueStatement(Zone* zone, IterationStatement* target, int pos) : JumpStatement(zone, pos), target_(target) { } private: IterationStatement* target_; }; class BreakStatement FINAL : public JumpStatement { public: DECLARE_NODE_TYPE(BreakStatement) BreakableStatement* target() const { return target_; } protected: explicit BreakStatement(Zone* zone, BreakableStatement* target, int pos) : JumpStatement(zone, pos), target_(target) { } private: BreakableStatement* target_; }; class ReturnStatement FINAL : public JumpStatement { public: DECLARE_NODE_TYPE(ReturnStatement) Expression* expression() const { return expression_; } protected: explicit ReturnStatement(Zone* zone, Expression* expression, int pos) : JumpStatement(zone, pos), expression_(expression) { } private: Expression* expression_; }; class WithStatement FINAL : public Statement { public: DECLARE_NODE_TYPE(WithStatement) Scope* scope() { return scope_; } Expression* expression() const { return expression_; } Statement* statement() const { return statement_; } void set_base_id(int id) { base_id_ = id; } static int num_ids() { return parent_num_ids() + 1; } BailoutId EntryId() const { return BailoutId(local_id(0)); } protected: WithStatement(Zone* zone, Scope* scope, Expression* expression, Statement* statement, int pos) : Statement(zone, pos), scope_(scope), expression_(expression), statement_(statement), base_id_(BailoutId::None().ToInt()) {} static int parent_num_ids() { return 0; } int base_id() const { DCHECK(!BailoutId(base_id_).IsNone()); return base_id_; } private: int local_id(int n) const { return base_id() + parent_num_ids() + n; } Scope* scope_; Expression* expression_; Statement* statement_; int base_id_; }; class CaseClause FINAL : public Expression { public: DECLARE_NODE_TYPE(CaseClause) bool is_default() const { return label_ == NULL; } Expression* label() const { CHECK(!is_default()); return label_; } Label* body_target() { return &body_target_; } ZoneList* statements() const { return statements_; } static int num_ids() { return parent_num_ids() + 2; } BailoutId EntryId() const { return BailoutId(local_id(0)); } TypeFeedbackId CompareId() { return TypeFeedbackId(local_id(1)); } Type* compare_type() { return compare_type_; } void set_compare_type(Type* type) { compare_type_ = type; } protected: static int parent_num_ids() { return Expression::num_ids(); } private: CaseClause(Zone* zone, Expression* label, ZoneList* statements, int pos); int local_id(int n) const { return base_id() + parent_num_ids() + n; } Expression* label_; Label body_target_; ZoneList* statements_; Type* compare_type_; }; class SwitchStatement FINAL : public BreakableStatement { public: DECLARE_NODE_TYPE(SwitchStatement) void Initialize(Expression* tag, ZoneList* cases) { tag_ = tag; cases_ = cases; } Expression* tag() const { return tag_; } ZoneList* cases() const { return cases_; } protected: SwitchStatement(Zone* zone, ZoneList* labels, int pos) : BreakableStatement(zone, labels, TARGET_FOR_ANONYMOUS, pos), tag_(NULL), cases_(NULL) {} private: Expression* tag_; ZoneList* cases_; }; // If-statements always have non-null references to their then- and // else-parts. When parsing if-statements with no explicit else-part, // the parser implicitly creates an empty statement. Use the // HasThenStatement() and HasElseStatement() functions to check if a // given if-statement has a then- or an else-part containing code. class IfStatement FINAL : public Statement { public: DECLARE_NODE_TYPE(IfStatement) bool HasThenStatement() const { return !then_statement()->IsEmpty(); } bool HasElseStatement() const { return !else_statement()->IsEmpty(); } Expression* condition() const { return condition_; } Statement* then_statement() const { return then_statement_; } Statement* else_statement() const { return else_statement_; } bool IsJump() const OVERRIDE { return HasThenStatement() && then_statement()->IsJump() && HasElseStatement() && else_statement()->IsJump(); } void set_base_id(int id) { base_id_ = id; } static int num_ids() { return parent_num_ids() + 3; } BailoutId IfId() const { return BailoutId(local_id(0)); } BailoutId ThenId() const { return BailoutId(local_id(1)); } BailoutId ElseId() const { return BailoutId(local_id(2)); } protected: IfStatement(Zone* zone, Expression* condition, Statement* then_statement, Statement* else_statement, int pos) : Statement(zone, pos), condition_(condition), then_statement_(then_statement), else_statement_(else_statement), base_id_(BailoutId::None().ToInt()) {} static int parent_num_ids() { return 0; } int base_id() const { DCHECK(!BailoutId(base_id_).IsNone()); return base_id_; } private: int local_id(int n) const { return base_id() + parent_num_ids() + n; } Expression* condition_; Statement* then_statement_; Statement* else_statement_; int base_id_; }; class TryStatement : public Statement { public: int index() const { return index_; } Block* try_block() const { return try_block_; } protected: TryStatement(Zone* zone, int index, Block* try_block, int pos) : Statement(zone, pos), index_(index), try_block_(try_block) {} private: // Unique (per-function) index of this handler. This is not an AST ID. int index_; Block* try_block_; }; class TryCatchStatement FINAL : public TryStatement { public: DECLARE_NODE_TYPE(TryCatchStatement) Scope* scope() { return scope_; } Variable* variable() { return variable_; } Block* catch_block() const { return catch_block_; } protected: TryCatchStatement(Zone* zone, int index, Block* try_block, Scope* scope, Variable* variable, Block* catch_block, int pos) : TryStatement(zone, index, try_block, pos), scope_(scope), variable_(variable), catch_block_(catch_block) { } private: Scope* scope_; Variable* variable_; Block* catch_block_; }; class TryFinallyStatement FINAL : public TryStatement { public: DECLARE_NODE_TYPE(TryFinallyStatement) Block* finally_block() const { return finally_block_; } protected: TryFinallyStatement( Zone* zone, int index, Block* try_block, Block* finally_block, int pos) : TryStatement(zone, index, try_block, pos), finally_block_(finally_block) { } private: Block* finally_block_; }; class DebuggerStatement FINAL : public Statement { public: DECLARE_NODE_TYPE(DebuggerStatement) void set_base_id(int id) { base_id_ = id; } static int num_ids() { return parent_num_ids() + 1; } BailoutId DebugBreakId() const { return BailoutId(local_id(0)); } protected: explicit DebuggerStatement(Zone* zone, int pos) : Statement(zone, pos), base_id_(BailoutId::None().ToInt()) {} static int parent_num_ids() { return 0; } int base_id() const { DCHECK(!BailoutId(base_id_).IsNone()); return base_id_; } private: int local_id(int n) const { return base_id() + parent_num_ids() + n; } int base_id_; }; class EmptyStatement FINAL : public Statement { public: DECLARE_NODE_TYPE(EmptyStatement) protected: explicit EmptyStatement(Zone* zone, int pos): Statement(zone, pos) {} }; class Literal FINAL : public Expression { public: DECLARE_NODE_TYPE(Literal) bool IsPropertyName() const OVERRIDE { return value_->IsPropertyName(); } Handle AsPropertyName() { DCHECK(IsPropertyName()); return Handle::cast(value()); } const AstRawString* AsRawPropertyName() { DCHECK(IsPropertyName()); return value_->AsString(); } bool ToBooleanIsTrue() const OVERRIDE { return value()->BooleanValue(); } bool ToBooleanIsFalse() const OVERRIDE { return !value()->BooleanValue(); } Handle value() const { return value_->value(); } const AstValue* raw_value() const { return value_; } // Support for using Literal as a HashMap key. NOTE: Currently, this works // only for string and number literals! uint32_t Hash(); static bool Match(void* literal1, void* literal2); static int num_ids() { return parent_num_ids() + 1; } TypeFeedbackId LiteralFeedbackId() const { return TypeFeedbackId(local_id(0)); } protected: Literal(Zone* zone, const AstValue* value, int position) : Expression(zone, position), value_(value) {} static int parent_num_ids() { return Expression::num_ids(); } private: int local_id(int n) const { return base_id() + parent_num_ids() + n; } const AstValue* value_; }; // Base class for literals that needs space in the corresponding JSFunction. class MaterializedLiteral : public Expression { public: virtual MaterializedLiteral* AsMaterializedLiteral() { return this; } int literal_index() { return literal_index_; } int depth() const { // only callable after initialization. DCHECK(depth_ >= 1); return depth_; } protected: MaterializedLiteral(Zone* zone, int literal_index, int pos) : Expression(zone, pos), literal_index_(literal_index), is_simple_(false), depth_(0) {} // A materialized literal is simple if the values consist of only // constants and simple object and array literals. bool is_simple() const { return is_simple_; } void set_is_simple(bool is_simple) { is_simple_ = is_simple; } friend class CompileTimeValue; void set_depth(int depth) { DCHECK(depth >= 1); depth_ = depth; } // Populate the constant properties/elements fixed array. void BuildConstants(Isolate* isolate); friend class ArrayLiteral; friend class ObjectLiteral; // If the expression is a literal, return the literal value; // if the expression is a materialized literal and is simple return a // compile time value as encoded by CompileTimeValue::GetValue(). // Otherwise, return undefined literal as the placeholder // in the object literal boilerplate. Handle GetBoilerplateValue(Expression* expression, Isolate* isolate); private: int literal_index_; bool is_simple_; int depth_; }; // Property is used for passing information // about an object literal's properties from the parser // to the code generator. class ObjectLiteralProperty FINAL : public ZoneObject { public: enum Kind { CONSTANT, // Property with constant value (compile time). COMPUTED, // Property with computed value (execution time). MATERIALIZED_LITERAL, // Property value is a materialized literal. GETTER, SETTER, // Property is an accessor function. PROTOTYPE // Property is __proto__. }; Expression* key() { return key_; } Expression* value() { return value_; } Kind kind() { return kind_; } // Type feedback information. void RecordTypeFeedback(TypeFeedbackOracle* oracle); bool IsMonomorphic() { return !receiver_type_.is_null(); } Handle GetReceiverType() { return receiver_type_; } bool IsCompileTimeValue(); void set_emit_store(bool emit_store); bool emit_store(); bool is_static() const { return is_static_; } bool is_computed_name() const { return is_computed_name_; } protected: friend class AstNodeFactory; ObjectLiteralProperty(Expression* key, Expression* value, Kind kind, bool is_static, bool is_computed_name); ObjectLiteralProperty(AstValueFactory* ast_value_factory, Expression* key, Expression* value, bool is_static, bool is_computed_name); private: Expression* key_; Expression* value_; Kind kind_; bool emit_store_; bool is_static_; bool is_computed_name_; Handle receiver_type_; }; // An object literal has a boilerplate object that is used // for minimizing the work when constructing it at runtime. class ObjectLiteral FINAL : public MaterializedLiteral { public: typedef ObjectLiteralProperty Property; DECLARE_NODE_TYPE(ObjectLiteral) Handle constant_properties() const { return constant_properties_; } ZoneList* properties() const { return properties_; } bool fast_elements() const { return fast_elements_; } bool may_store_doubles() const { return may_store_doubles_; } bool has_function() const { return has_function_; } // Decide if a property should be in the object boilerplate. static bool IsBoilerplateProperty(Property* property); // Populate the constant properties fixed array. void BuildConstantProperties(Isolate* isolate); // Mark all computed expressions that are bound to a key that // is shadowed by a later occurrence of the same key. For the // marked expressions, no store code is emitted. void CalculateEmitStore(Zone* zone); // Assemble bitfield of flags for the CreateObjectLiteral helper. int ComputeFlags() const { int flags = fast_elements() ? kFastElements : kNoFlags; flags |= has_function() ? kHasFunction : kNoFlags; return flags; } enum Flags { kNoFlags = 0, kFastElements = 1, kHasFunction = 1 << 1 }; struct Accessors: public ZoneObject { Accessors() : getter(NULL), setter(NULL) {} Expression* getter; Expression* setter; }; BailoutId CreateLiteralId() const { return BailoutId(local_id(0)); } // Return an AST id for a property that is used in simulate instructions. BailoutId GetIdForProperty(int i) { return BailoutId(local_id(i + 1)); } // Unlike other AST nodes, this number of bailout IDs allocated for an // ObjectLiteral can vary, so num_ids() is not a static method. int num_ids() const { return parent_num_ids() + 1 + properties()->length(); } protected: ObjectLiteral(Zone* zone, ZoneList* properties, int literal_index, int boilerplate_properties, bool has_function, int pos) : MaterializedLiteral(zone, literal_index, pos), properties_(properties), boilerplate_properties_(boilerplate_properties), fast_elements_(false), may_store_doubles_(false), has_function_(has_function) {} static int parent_num_ids() { return MaterializedLiteral::num_ids(); } private: int local_id(int n) const { return base_id() + parent_num_ids() + n; } Handle constant_properties_; ZoneList* properties_; int boilerplate_properties_; bool fast_elements_; bool may_store_doubles_; bool has_function_; }; // Node for capturing a regexp literal. class RegExpLiteral FINAL : public MaterializedLiteral { public: DECLARE_NODE_TYPE(RegExpLiteral) Handle pattern() const { return pattern_->string(); } Handle flags() const { return flags_->string(); } protected: RegExpLiteral(Zone* zone, const AstRawString* pattern, const AstRawString* flags, int literal_index, int pos) : MaterializedLiteral(zone, literal_index, pos), pattern_(pattern), flags_(flags) { set_depth(1); } private: const AstRawString* pattern_; const AstRawString* flags_; }; // An array literal has a literals object that is used // for minimizing the work when constructing it at runtime. class ArrayLiteral FINAL : public MaterializedLiteral { public: DECLARE_NODE_TYPE(ArrayLiteral) Handle constant_elements() const { return constant_elements_; } ZoneList* values() const { return values_; } BailoutId CreateLiteralId() const { return BailoutId(local_id(0)); } // Return an AST id for an element that is used in simulate instructions. BailoutId GetIdForElement(int i) { return BailoutId(local_id(i + 1)); } // Unlike other AST nodes, this number of bailout IDs allocated for an // ArrayLiteral can vary, so num_ids() is not a static method. int num_ids() const { return parent_num_ids() + 1 + values()->length(); } // Populate the constant elements fixed array. void BuildConstantElements(Isolate* isolate); // Assemble bitfield of flags for the CreateArrayLiteral helper. int ComputeFlags() const { int flags = depth() == 1 ? kShallowElements : kNoFlags; flags |= ArrayLiteral::kDisableMementos; return flags; } enum Flags { kNoFlags = 0, kShallowElements = 1, kDisableMementos = 1 << 1 }; protected: ArrayLiteral(Zone* zone, ZoneList* values, int literal_index, int pos) : MaterializedLiteral(zone, literal_index, pos), values_(values) {} static int parent_num_ids() { return MaterializedLiteral::num_ids(); } private: int local_id(int n) const { return base_id() + parent_num_ids() + n; } Handle constant_elements_; ZoneList* values_; }; class VariableProxy FINAL : public Expression { public: DECLARE_NODE_TYPE(VariableProxy) bool IsValidReferenceExpression() const OVERRIDE { return !is_resolved() || var()->IsValidReference(); } bool IsArguments() const { return is_resolved() && var()->is_arguments(); } Handle name() const { return raw_name()->string(); } const AstRawString* raw_name() const { return is_resolved() ? var_->raw_name() : raw_name_; } Variable* var() const { DCHECK(is_resolved()); return var_; } void set_var(Variable* v) { DCHECK(!is_resolved()); DCHECK_NOT_NULL(v); var_ = v; } bool is_this() const { return IsThisField::decode(bit_field_); } bool is_assigned() const { return IsAssignedField::decode(bit_field_); } void set_is_assigned() { bit_field_ = IsAssignedField::update(bit_field_, true); } bool is_resolved() const { return IsResolvedField::decode(bit_field_); } void set_is_resolved() { bit_field_ = IsResolvedField::update(bit_field_, true); } // Bind this proxy to the variable var. void BindTo(Variable* var); bool UsesVariableFeedbackSlot() const { return FLAG_vector_ics && (var()->IsUnallocated() || var()->IsLookupSlot()); } virtual FeedbackVectorRequirements ComputeFeedbackRequirements( Isolate* isolate) OVERRIDE { return FeedbackVectorRequirements(0, UsesVariableFeedbackSlot() ? 1 : 0); } void SetFirstFeedbackICSlot(FeedbackVectorICSlot slot) OVERRIDE { variable_feedback_slot_ = slot; } Code::Kind FeedbackICSlotKind(int index) OVERRIDE { return Code::LOAD_IC; } FeedbackVectorICSlot VariableFeedbackSlot() { DCHECK(!UsesVariableFeedbackSlot() || !variable_feedback_slot_.IsInvalid()); return variable_feedback_slot_; } protected: VariableProxy(Zone* zone, Variable* var, int position); VariableProxy(Zone* zone, const AstRawString* name, bool is_this, int position); class IsThisField : public BitField8 {}; class IsAssignedField : public BitField8 {}; class IsResolvedField : public BitField8 {}; // Start with 16-bit (or smaller) field, which should get packed together // with Expression's trailing 16-bit field. uint8_t bit_field_; FeedbackVectorICSlot variable_feedback_slot_; union { const AstRawString* raw_name_; // if !is_resolved_ Variable* var_; // if is_resolved_ }; }; class Property FINAL : public Expression { public: DECLARE_NODE_TYPE(Property) bool IsValidReferenceExpression() const OVERRIDE { return true; } Expression* obj() const { return obj_; } Expression* key() const { return key_; } static int num_ids() { return parent_num_ids() + 2; } BailoutId LoadId() const { return BailoutId(local_id(0)); } TypeFeedbackId PropertyFeedbackId() { return TypeFeedbackId(local_id(1)); } bool IsStringAccess() const { return IsStringAccessField::decode(bit_field_); } // Type feedback information. bool IsMonomorphic() OVERRIDE { return receiver_types_.length() == 1; } SmallMapList* GetReceiverTypes() OVERRIDE { return &receiver_types_; } KeyedAccessStoreMode GetStoreMode() const OVERRIDE { return STANDARD_STORE; } IcCheckType GetKeyType() const OVERRIDE { return KeyTypeField::decode(bit_field_); } bool IsUninitialized() const { return !is_for_call() && HasNoTypeInformation(); } bool HasNoTypeInformation() const { return IsUninitializedField::decode(bit_field_); } void set_is_uninitialized(bool b) { bit_field_ = IsUninitializedField::update(bit_field_, b); } void set_is_string_access(bool b) { bit_field_ = IsStringAccessField::update(bit_field_, b); } void set_key_type(IcCheckType key_type) { bit_field_ = KeyTypeField::update(bit_field_, key_type); } void mark_for_call() { bit_field_ = IsForCallField::update(bit_field_, true); } bool is_for_call() const { return IsForCallField::decode(bit_field_); } bool IsSuperAccess() { return obj()->IsSuperReference(); } virtual FeedbackVectorRequirements ComputeFeedbackRequirements( Isolate* isolate) OVERRIDE { return FeedbackVectorRequirements(0, FLAG_vector_ics ? 1 : 0); } void SetFirstFeedbackICSlot(FeedbackVectorICSlot slot) OVERRIDE { property_feedback_slot_ = slot; } Code::Kind FeedbackICSlotKind(int index) OVERRIDE { return key()->IsPropertyName() ? Code::LOAD_IC : Code::KEYED_LOAD_IC; } FeedbackVectorICSlot PropertyFeedbackSlot() const { DCHECK(!FLAG_vector_ics || !property_feedback_slot_.IsInvalid()); return property_feedback_slot_; } protected: Property(Zone* zone, Expression* obj, Expression* key, int pos) : Expression(zone, pos), bit_field_(IsForCallField::encode(false) | IsUninitializedField::encode(false) | IsStringAccessField::encode(false)), property_feedback_slot_(FeedbackVectorICSlot::Invalid()), obj_(obj), key_(key) {} static int parent_num_ids() { return Expression::num_ids(); } private: int local_id(int n) const { return base_id() + parent_num_ids() + n; } class IsForCallField : public BitField8 {}; class IsUninitializedField : public BitField8 {}; class IsStringAccessField : public BitField8 {}; class KeyTypeField : public BitField8 {}; uint8_t bit_field_; FeedbackVectorICSlot property_feedback_slot_; Expression* obj_; Expression* key_; SmallMapList receiver_types_; }; class Call FINAL : public Expression { public: DECLARE_NODE_TYPE(Call) Expression* expression() const { return expression_; } ZoneList* arguments() const { return arguments_; } // Type feedback information. virtual FeedbackVectorRequirements ComputeFeedbackRequirements( Isolate* isolate) OVERRIDE; void SetFirstFeedbackICSlot(FeedbackVectorICSlot slot) OVERRIDE { ic_slot_or_slot_ = slot.ToInt(); } void SetFirstFeedbackSlot(FeedbackVectorSlot slot) OVERRIDE { ic_slot_or_slot_ = slot.ToInt(); } Code::Kind FeedbackICSlotKind(int index) OVERRIDE { return Code::CALL_IC; } FeedbackVectorSlot CallFeedbackSlot() const { DCHECK(ic_slot_or_slot_ != FeedbackVectorSlot::Invalid().ToInt()); return FeedbackVectorSlot(ic_slot_or_slot_); } FeedbackVectorICSlot CallFeedbackICSlot() const { DCHECK(ic_slot_or_slot_ != FeedbackVectorICSlot::Invalid().ToInt()); return FeedbackVectorICSlot(ic_slot_or_slot_); } SmallMapList* GetReceiverTypes() OVERRIDE { if (expression()->IsProperty()) { return expression()->AsProperty()->GetReceiverTypes(); } return NULL; } bool IsMonomorphic() OVERRIDE { if (expression()->IsProperty()) { return expression()->AsProperty()->IsMonomorphic(); } return !target_.is_null(); } bool global_call() const { VariableProxy* proxy = expression_->AsVariableProxy(); return proxy != NULL && proxy->var()->IsUnallocated(); } bool known_global_function() const { return global_call() && !target_.is_null(); } Handle target() { return target_; } Handle cell() { return cell_; } Handle allocation_site() { return allocation_site_; } void set_target(Handle target) { target_ = target; } void set_allocation_site(Handle site) { allocation_site_ = site; } bool ComputeGlobalTarget(Handle global, LookupIterator* it); static int num_ids() { return parent_num_ids() + 2; } BailoutId ReturnId() const { return BailoutId(local_id(0)); } BailoutId EvalOrLookupId() const { return BailoutId(local_id(1)); } bool is_uninitialized() const { return IsUninitializedField::decode(bit_field_); } void set_is_uninitialized(bool b) { bit_field_ = IsUninitializedField::update(bit_field_, b); } enum CallType { POSSIBLY_EVAL_CALL, GLOBAL_CALL, LOOKUP_SLOT_CALL, PROPERTY_CALL, SUPER_CALL, OTHER_CALL }; // Helpers to determine how to handle the call. CallType GetCallType(Isolate* isolate) const; bool IsUsingCallFeedbackSlot(Isolate* isolate) const; bool IsUsingCallFeedbackICSlot(Isolate* isolate) const; #ifdef DEBUG // Used to assert that the FullCodeGenerator records the return site. bool return_is_recorded_; #endif protected: Call(Zone* zone, Expression* expression, ZoneList* arguments, int pos) : Expression(zone, pos), ic_slot_or_slot_(FeedbackVectorICSlot::Invalid().ToInt()), expression_(expression), arguments_(arguments), bit_field_(IsUninitializedField::encode(false)) { if (expression->IsProperty()) { expression->AsProperty()->mark_for_call(); } } static int parent_num_ids() { return Expression::num_ids(); } private: int local_id(int n) const { return base_id() + parent_num_ids() + n; } // We store this as an integer because we don't know if we have a slot or // an ic slot until scoping time. int ic_slot_or_slot_; Expression* expression_; ZoneList* arguments_; Handle target_; Handle cell_; Handle allocation_site_; class IsUninitializedField : public BitField8 {}; uint8_t bit_field_; }; class CallNew FINAL : public Expression { public: DECLARE_NODE_TYPE(CallNew) Expression* expression() const { return expression_; } ZoneList* arguments() const { return arguments_; } // Type feedback information. virtual FeedbackVectorRequirements ComputeFeedbackRequirements( Isolate* isolate) OVERRIDE { return FeedbackVectorRequirements(FLAG_pretenuring_call_new ? 2 : 1, 0); } void SetFirstFeedbackSlot(FeedbackVectorSlot slot) OVERRIDE { callnew_feedback_slot_ = slot; } FeedbackVectorSlot CallNewFeedbackSlot() { DCHECK(!callnew_feedback_slot_.IsInvalid()); return callnew_feedback_slot_; } FeedbackVectorSlot AllocationSiteFeedbackSlot() { DCHECK(FLAG_pretenuring_call_new); return CallNewFeedbackSlot().next(); } void RecordTypeFeedback(TypeFeedbackOracle* oracle); bool IsMonomorphic() OVERRIDE { return is_monomorphic_; } Handle target() const { return target_; } Handle allocation_site() const { return allocation_site_; } static int num_ids() { return parent_num_ids() + 1; } static int feedback_slots() { return 1; } BailoutId ReturnId() const { return BailoutId(local_id(0)); } protected: CallNew(Zone* zone, Expression* expression, ZoneList* arguments, int pos) : Expression(zone, pos), expression_(expression), arguments_(arguments), is_monomorphic_(false), callnew_feedback_slot_(FeedbackVectorSlot::Invalid()) {} static int parent_num_ids() { return Expression::num_ids(); } private: int local_id(int n) const { return base_id() + parent_num_ids() + n; } Expression* expression_; ZoneList* arguments_; bool is_monomorphic_; Handle target_; Handle allocation_site_; FeedbackVectorSlot callnew_feedback_slot_; }; // The CallRuntime class does not represent any official JavaScript // language construct. Instead it is used to call a C or JS function // with a set of arguments. This is used from the builtins that are // implemented in JavaScript (see "v8natives.js"). class CallRuntime FINAL : public Expression { public: DECLARE_NODE_TYPE(CallRuntime) Handle name() const { return raw_name_->string(); } const AstRawString* raw_name() const { return raw_name_; } const Runtime::Function* function() const { return function_; } ZoneList* arguments() const { return arguments_; } bool is_jsruntime() const { return function_ == NULL; } // Type feedback information. bool HasCallRuntimeFeedbackSlot() const { return FLAG_vector_ics && is_jsruntime(); } virtual FeedbackVectorRequirements ComputeFeedbackRequirements( Isolate* isolate) OVERRIDE { return FeedbackVectorRequirements(0, HasCallRuntimeFeedbackSlot() ? 1 : 0); } void SetFirstFeedbackICSlot(FeedbackVectorICSlot slot) OVERRIDE { callruntime_feedback_slot_ = slot; } Code::Kind FeedbackICSlotKind(int index) OVERRIDE { return Code::LOAD_IC; } FeedbackVectorICSlot CallRuntimeFeedbackSlot() { DCHECK(!HasCallRuntimeFeedbackSlot() || !callruntime_feedback_slot_.IsInvalid()); return callruntime_feedback_slot_; } static int num_ids() { return parent_num_ids() + 1; } TypeFeedbackId CallRuntimeFeedbackId() const { return TypeFeedbackId(local_id(0)); } protected: CallRuntime(Zone* zone, const AstRawString* name, const Runtime::Function* function, ZoneList* arguments, int pos) : Expression(zone, pos), raw_name_(name), function_(function), arguments_(arguments), callruntime_feedback_slot_(FeedbackVectorICSlot::Invalid()) {} static int parent_num_ids() { return Expression::num_ids(); } private: int local_id(int n) const { return base_id() + parent_num_ids() + n; } const AstRawString* raw_name_; const Runtime::Function* function_; ZoneList* arguments_; FeedbackVectorICSlot callruntime_feedback_slot_; }; class UnaryOperation FINAL : public Expression { public: DECLARE_NODE_TYPE(UnaryOperation) Token::Value op() const { return op_; } Expression* expression() const { return expression_; } // For unary not (Token::NOT), the AST ids where true and false will // actually be materialized, respectively. static int num_ids() { return parent_num_ids() + 2; } BailoutId MaterializeTrueId() const { return BailoutId(local_id(0)); } BailoutId MaterializeFalseId() const { return BailoutId(local_id(1)); } virtual void RecordToBooleanTypeFeedback( TypeFeedbackOracle* oracle) OVERRIDE; protected: UnaryOperation(Zone* zone, Token::Value op, Expression* expression, int pos) : Expression(zone, pos), op_(op), expression_(expression) { DCHECK(Token::IsUnaryOp(op)); } static int parent_num_ids() { return Expression::num_ids(); } private: int local_id(int n) const { return base_id() + parent_num_ids() + n; } Token::Value op_; Expression* expression_; }; class BinaryOperation FINAL : public Expression { public: DECLARE_NODE_TYPE(BinaryOperation) Token::Value op() const { return static_cast(op_); } Expression* left() const { return left_; } Expression* right() const { return right_; } Handle allocation_site() const { return allocation_site_; } void set_allocation_site(Handle allocation_site) { allocation_site_ = allocation_site; } // The short-circuit logical operations need an AST ID for their // right-hand subexpression. static int num_ids() { return parent_num_ids() + 2; } BailoutId RightId() const { return BailoutId(local_id(0)); } TypeFeedbackId BinaryOperationFeedbackId() const { return TypeFeedbackId(local_id(1)); } Maybe fixed_right_arg() const { return has_fixed_right_arg_ ? Maybe(fixed_right_arg_value_) : Maybe(); } void set_fixed_right_arg(Maybe arg) { has_fixed_right_arg_ = arg.has_value; if (arg.has_value) fixed_right_arg_value_ = arg.value; } virtual void RecordToBooleanTypeFeedback( TypeFeedbackOracle* oracle) OVERRIDE; protected: BinaryOperation(Zone* zone, Token::Value op, Expression* left, Expression* right, int pos) : Expression(zone, pos), op_(static_cast(op)), has_fixed_right_arg_(false), fixed_right_arg_value_(0), left_(left), right_(right) { DCHECK(Token::IsBinaryOp(op)); } static int parent_num_ids() { return Expression::num_ids(); } private: int local_id(int n) const { return base_id() + parent_num_ids() + n; } const byte op_; // actually Token::Value // TODO(rossberg): the fixed arg should probably be represented as a Constant // type for the RHS. Currenty it's actually a Maybe bool has_fixed_right_arg_; int fixed_right_arg_value_; Expression* left_; Expression* right_; Handle allocation_site_; }; class CountOperation FINAL : public Expression { public: DECLARE_NODE_TYPE(CountOperation) bool is_prefix() const { return IsPrefixField::decode(bit_field_); } bool is_postfix() const { return !is_prefix(); } Token::Value op() const { return TokenField::decode(bit_field_); } Token::Value binary_op() { return (op() == Token::INC) ? Token::ADD : Token::SUB; } Expression* expression() const { return expression_; } bool IsMonomorphic() OVERRIDE { return receiver_types_.length() == 1; } SmallMapList* GetReceiverTypes() OVERRIDE { return &receiver_types_; } IcCheckType GetKeyType() const OVERRIDE { return KeyTypeField::decode(bit_field_); } KeyedAccessStoreMode GetStoreMode() const OVERRIDE { return StoreModeField::decode(bit_field_); } Type* type() const { return type_; } void set_key_type(IcCheckType type) { bit_field_ = KeyTypeField::update(bit_field_, type); } void set_store_mode(KeyedAccessStoreMode mode) { bit_field_ = StoreModeField::update(bit_field_, mode); } void set_type(Type* type) { type_ = type; } static int num_ids() { return parent_num_ids() + 4; } BailoutId AssignmentId() const { return BailoutId(local_id(0)); } BailoutId ToNumberId() const { return BailoutId(local_id(1)); } TypeFeedbackId CountBinOpFeedbackId() const { return TypeFeedbackId(local_id(2)); } TypeFeedbackId CountStoreFeedbackId() const { return TypeFeedbackId(local_id(3)); } protected: CountOperation(Zone* zone, Token::Value op, bool is_prefix, Expression* expr, int pos) : Expression(zone, pos), bit_field_(IsPrefixField::encode(is_prefix) | KeyTypeField::encode(ELEMENT) | StoreModeField::encode(STANDARD_STORE) | TokenField::encode(op)), type_(NULL), expression_(expr) {} static int parent_num_ids() { return Expression::num_ids(); } private: int local_id(int n) const { return base_id() + parent_num_ids() + n; } class IsPrefixField : public BitField16 {}; class KeyTypeField : public BitField16 {}; class StoreModeField : public BitField16 {}; class TokenField : public BitField16 {}; // Starts with 16-bit field, which should get packed together with // Expression's trailing 16-bit field. uint16_t bit_field_; Type* type_; Expression* expression_; SmallMapList receiver_types_; }; class CompareOperation FINAL : public Expression { public: DECLARE_NODE_TYPE(CompareOperation) Token::Value op() const { return op_; } Expression* left() const { return left_; } Expression* right() const { return right_; } // Type feedback information. static int num_ids() { return parent_num_ids() + 1; } TypeFeedbackId CompareOperationFeedbackId() const { return TypeFeedbackId(local_id(0)); } Type* combined_type() const { return combined_type_; } void set_combined_type(Type* type) { combined_type_ = type; } // Match special cases. bool IsLiteralCompareTypeof(Expression** expr, Handle* check); bool IsLiteralCompareUndefined(Expression** expr, Isolate* isolate); bool IsLiteralCompareNull(Expression** expr); protected: CompareOperation(Zone* zone, Token::Value op, Expression* left, Expression* right, int pos) : Expression(zone, pos), op_(op), left_(left), right_(right), combined_type_(Type::None(zone)) { DCHECK(Token::IsCompareOp(op)); } static int parent_num_ids() { return Expression::num_ids(); } private: int local_id(int n) const { return base_id() + parent_num_ids() + n; } Token::Value op_; Expression* left_; Expression* right_; Type* combined_type_; }; class Conditional FINAL : public Expression { public: DECLARE_NODE_TYPE(Conditional) Expression* condition() const { return condition_; } Expression* then_expression() const { return then_expression_; } Expression* else_expression() const { return else_expression_; } static int num_ids() { return parent_num_ids() + 2; } BailoutId ThenId() const { return BailoutId(local_id(0)); } BailoutId ElseId() const { return BailoutId(local_id(1)); } protected: Conditional(Zone* zone, Expression* condition, Expression* then_expression, Expression* else_expression, int position) : Expression(zone, position), condition_(condition), then_expression_(then_expression), else_expression_(else_expression) {} static int parent_num_ids() { return Expression::num_ids(); } private: int local_id(int n) const { return base_id() + parent_num_ids() + n; } Expression* condition_; Expression* then_expression_; Expression* else_expression_; }; class Assignment FINAL : public Expression { public: DECLARE_NODE_TYPE(Assignment) Assignment* AsSimpleAssignment() { return !is_compound() ? this : NULL; } Token::Value binary_op() const; Token::Value op() const { return TokenField::decode(bit_field_); } Expression* target() const { return target_; } Expression* value() const { return value_; } BinaryOperation* binary_operation() const { return binary_operation_; } // This check relies on the definition order of token in token.h. bool is_compound() const { return op() > Token::ASSIGN; } static int num_ids() { return parent_num_ids() + 2; } BailoutId AssignmentId() const { return BailoutId(local_id(0)); } // Type feedback information. TypeFeedbackId AssignmentFeedbackId() { return TypeFeedbackId(local_id(1)); } bool IsMonomorphic() OVERRIDE { return receiver_types_.length() == 1; } bool IsUninitialized() const { return IsUninitializedField::decode(bit_field_); } bool HasNoTypeInformation() { return IsUninitializedField::decode(bit_field_); } SmallMapList* GetReceiverTypes() OVERRIDE { return &receiver_types_; } IcCheckType GetKeyType() const OVERRIDE { return KeyTypeField::decode(bit_field_); } KeyedAccessStoreMode GetStoreMode() const OVERRIDE { return StoreModeField::decode(bit_field_); } void set_is_uninitialized(bool b) { bit_field_ = IsUninitializedField::update(bit_field_, b); } void set_key_type(IcCheckType key_type) { bit_field_ = KeyTypeField::update(bit_field_, key_type); } void set_store_mode(KeyedAccessStoreMode mode) { bit_field_ = StoreModeField::update(bit_field_, mode); } protected: Assignment(Zone* zone, Token::Value op, Expression* target, Expression* value, int pos); static int parent_num_ids() { return Expression::num_ids(); } private: int local_id(int n) const { return base_id() + parent_num_ids() + n; } class IsUninitializedField : public BitField16 {}; class KeyTypeField : public BitField16 {}; class StoreModeField : public BitField16 {}; class TokenField : public BitField16 {}; // Starts with 16-bit field, which should get packed together with // Expression's trailing 16-bit field. uint16_t bit_field_; Expression* target_; Expression* value_; BinaryOperation* binary_operation_; SmallMapList receiver_types_; }; class Yield FINAL : public Expression { public: DECLARE_NODE_TYPE(Yield) enum Kind { kInitial, // The initial yield that returns the unboxed generator object. kSuspend, // A normal yield: { value: EXPRESSION, done: false } kDelegating, // A yield*. kFinal // A return: { value: EXPRESSION, done: true } }; Expression* generator_object() const { return generator_object_; } Expression* expression() const { return expression_; } Kind yield_kind() const { return yield_kind_; } // Delegating yield surrounds the "yield" in a "try/catch". This index // locates the catch handler in the handler table, and is equivalent to // TryCatchStatement::index(). int index() const { DCHECK_EQ(kDelegating, yield_kind()); return index_; } void set_index(int index) { DCHECK_EQ(kDelegating, yield_kind()); index_ = index; } // Type feedback information. bool HasFeedbackSlots() const { return FLAG_vector_ics && (yield_kind() == kDelegating); } virtual FeedbackVectorRequirements ComputeFeedbackRequirements( Isolate* isolate) OVERRIDE { return FeedbackVectorRequirements(0, HasFeedbackSlots() ? 3 : 0); } void SetFirstFeedbackICSlot(FeedbackVectorICSlot slot) OVERRIDE { yield_first_feedback_slot_ = slot; } Code::Kind FeedbackICSlotKind(int index) OVERRIDE { return index == 0 ? Code::KEYED_LOAD_IC : Code::LOAD_IC; } FeedbackVectorICSlot KeyedLoadFeedbackSlot() { DCHECK(!HasFeedbackSlots() || !yield_first_feedback_slot_.IsInvalid()); return yield_first_feedback_slot_; } FeedbackVectorICSlot DoneFeedbackSlot() { return KeyedLoadFeedbackSlot().next(); } FeedbackVectorICSlot ValueFeedbackSlot() { return DoneFeedbackSlot().next(); } protected: Yield(Zone* zone, Expression* generator_object, Expression* expression, Kind yield_kind, int pos) : Expression(zone, pos), generator_object_(generator_object), expression_(expression), yield_kind_(yield_kind), index_(-1), yield_first_feedback_slot_(FeedbackVectorICSlot::Invalid()) {} private: Expression* generator_object_; Expression* expression_; Kind yield_kind_; int index_; FeedbackVectorICSlot yield_first_feedback_slot_; }; class Throw FINAL : public Expression { public: DECLARE_NODE_TYPE(Throw) Expression* exception() const { return exception_; } protected: Throw(Zone* zone, Expression* exception, int pos) : Expression(zone, pos), exception_(exception) {} private: Expression* exception_; }; class FunctionLiteral FINAL : public Expression { public: enum FunctionType { ANONYMOUS_EXPRESSION, NAMED_EXPRESSION, DECLARATION }; enum ParameterFlag { kNoDuplicateParameters = 0, kHasDuplicateParameters = 1 }; enum IsFunctionFlag { kGlobalOrEval, kIsFunction }; enum IsParenthesizedFlag { kIsParenthesized, kNotParenthesized }; enum ArityRestriction { NORMAL_ARITY, GETTER_ARITY, SETTER_ARITY }; DECLARE_NODE_TYPE(FunctionLiteral) Handle name() const { return raw_name_->string(); } const AstRawString* raw_name() const { return raw_name_; } Scope* scope() const { return scope_; } ZoneList* body() const { return body_; } void set_function_token_position(int pos) { function_token_position_ = pos; } int function_token_position() const { return function_token_position_; } int start_position() const; int end_position() const; int SourceSize() const { return end_position() - start_position(); } bool is_expression() const { return IsExpression::decode(bitfield_); } bool is_anonymous() const { return IsAnonymous::decode(bitfield_); } LanguageMode language_mode() const; bool uses_super_property() const; static bool NeedsHomeObject(Expression* literal) { return literal != NULL && literal->IsFunctionLiteral() && literal->AsFunctionLiteral()->uses_super_property(); } int materialized_literal_count() { return materialized_literal_count_; } int expected_property_count() { return expected_property_count_; } int handler_count() { return handler_count_; } int parameter_count() { return parameter_count_; } bool AllowsLazyCompilation(); bool AllowsLazyCompilationWithoutContext(); void InitializeSharedInfo(Handle code); Handle debug_name() const { if (raw_name_ != NULL && !raw_name_->IsEmpty()) { return raw_name_->string(); } return inferred_name(); } Handle inferred_name() const { if (!inferred_name_.is_null()) { DCHECK(raw_inferred_name_ == NULL); return inferred_name_; } if (raw_inferred_name_ != NULL) { return raw_inferred_name_->string(); } UNREACHABLE(); return Handle(); } // Only one of {set_inferred_name, set_raw_inferred_name} should be called. void set_inferred_name(Handle inferred_name) { DCHECK(!inferred_name.is_null()); inferred_name_ = inferred_name; DCHECK(raw_inferred_name_== NULL || raw_inferred_name_->IsEmpty()); raw_inferred_name_ = NULL; } void set_raw_inferred_name(const AstString* raw_inferred_name) { DCHECK(raw_inferred_name != NULL); raw_inferred_name_ = raw_inferred_name; DCHECK(inferred_name_.is_null()); inferred_name_ = Handle(); } // shared_info may be null if it's not cached in full code. Handle shared_info() { return shared_info_; } bool pretenure() { return Pretenure::decode(bitfield_); } void set_pretenure() { bitfield_ |= Pretenure::encode(true); } bool has_duplicate_parameters() { return HasDuplicateParameters::decode(bitfield_); } bool is_function() { return IsFunction::decode(bitfield_) == kIsFunction; } // This is used as a heuristic on when to eagerly compile a function // literal. We consider the following constructs as hints that the // function will be called immediately: // - (function() { ... })(); // - var x = function() { ... }(); bool is_parenthesized() { return IsParenthesized::decode(bitfield_) == kIsParenthesized; } void set_parenthesized() { bitfield_ = IsParenthesized::update(bitfield_, kIsParenthesized); } FunctionKind kind() { return FunctionKindBits::decode(bitfield_); } int ast_node_count() { return ast_properties_.node_count(); } AstProperties::Flags* flags() { return ast_properties_.flags(); } void set_ast_properties(AstProperties* ast_properties) { ast_properties_ = *ast_properties; } const FeedbackVectorSpec& feedback_vector_spec() const { return ast_properties_.get_spec(); } bool dont_optimize() { return dont_optimize_reason_ != kNoReason; } BailoutReason dont_optimize_reason() { return dont_optimize_reason_; } void set_dont_optimize_reason(BailoutReason reason) { dont_optimize_reason_ = reason; } protected: FunctionLiteral(Zone* zone, const AstRawString* name, AstValueFactory* ast_value_factory, Scope* scope, ZoneList* body, int materialized_literal_count, int expected_property_count, int handler_count, int parameter_count, FunctionType function_type, ParameterFlag has_duplicate_parameters, IsFunctionFlag is_function, IsParenthesizedFlag is_parenthesized, FunctionKind kind, int position) : Expression(zone, position), raw_name_(name), scope_(scope), body_(body), raw_inferred_name_(ast_value_factory->empty_string()), dont_optimize_reason_(kNoReason), materialized_literal_count_(materialized_literal_count), expected_property_count_(expected_property_count), handler_count_(handler_count), parameter_count_(parameter_count), function_token_position_(RelocInfo::kNoPosition) { bitfield_ = IsExpression::encode(function_type != DECLARATION) | IsAnonymous::encode(function_type == ANONYMOUS_EXPRESSION) | Pretenure::encode(false) | HasDuplicateParameters::encode(has_duplicate_parameters) | IsFunction::encode(is_function) | IsParenthesized::encode(is_parenthesized) | FunctionKindBits::encode(kind); DCHECK(IsValidFunctionKind(kind)); } private: const AstRawString* raw_name_; Handle name_; Handle shared_info_; Scope* scope_; ZoneList* body_; const AstString* raw_inferred_name_; Handle inferred_name_; AstProperties ast_properties_; BailoutReason dont_optimize_reason_; int materialized_literal_count_; int expected_property_count_; int handler_count_; int parameter_count_; int function_token_position_; unsigned bitfield_; class IsExpression : public BitField {}; class IsAnonymous : public BitField {}; class Pretenure : public BitField {}; class HasDuplicateParameters : public BitField {}; class IsFunction : public BitField {}; class IsParenthesized : public BitField {}; class FunctionKindBits : public BitField {}; }; class ClassLiteral FINAL : public Expression { public: typedef ObjectLiteralProperty Property; DECLARE_NODE_TYPE(ClassLiteral) Handle name() const { return raw_name_->string(); } const AstRawString* raw_name() const { return raw_name_; } Scope* scope() const { return scope_; } VariableProxy* class_variable_proxy() const { return class_variable_proxy_; } Expression* extends() const { return extends_; } FunctionLiteral* constructor() const { return constructor_; } ZoneList* properties() const { return properties_; } int start_position() const { return position(); } int end_position() const { return end_position_; } BailoutId EntryId() const { return BailoutId(local_id(0)); } BailoutId DeclsId() const { return BailoutId(local_id(1)); } BailoutId ExitId() { return BailoutId(local_id(2)); } // Return an AST id for a property that is used in simulate instructions. BailoutId GetIdForProperty(int i) { return BailoutId(local_id(i + 3)); } // Unlike other AST nodes, this number of bailout IDs allocated for an // ClassLiteral can vary, so num_ids() is not a static method. int num_ids() const { return parent_num_ids() + 3 + properties()->length(); } protected: ClassLiteral(Zone* zone, const AstRawString* name, Scope* scope, VariableProxy* class_variable_proxy, Expression* extends, FunctionLiteral* constructor, ZoneList* properties, int start_position, int end_position) : Expression(zone, start_position), raw_name_(name), scope_(scope), class_variable_proxy_(class_variable_proxy), extends_(extends), constructor_(constructor), properties_(properties), end_position_(end_position) {} static int parent_num_ids() { return Expression::num_ids(); } private: int local_id(int n) const { return base_id() + parent_num_ids() + n; } const AstRawString* raw_name_; Scope* scope_; VariableProxy* class_variable_proxy_; Expression* extends_; FunctionLiteral* constructor_; ZoneList* properties_; int end_position_; }; class NativeFunctionLiteral FINAL : public Expression { public: DECLARE_NODE_TYPE(NativeFunctionLiteral) Handle name() const { return name_->string(); } v8::Extension* extension() const { return extension_; } protected: NativeFunctionLiteral(Zone* zone, const AstRawString* name, v8::Extension* extension, int pos) : Expression(zone, pos), name_(name), extension_(extension) {} private: const AstRawString* name_; v8::Extension* extension_; }; class ThisFunction FINAL : public Expression { public: DECLARE_NODE_TYPE(ThisFunction) protected: ThisFunction(Zone* zone, int pos) : Expression(zone, pos) {} }; class SuperReference FINAL : public Expression { public: DECLARE_NODE_TYPE(SuperReference) VariableProxy* this_var() const { return this_var_; } static int num_ids() { return parent_num_ids() + 1; } TypeFeedbackId HomeObjectFeedbackId() { return TypeFeedbackId(local_id(0)); } // Type feedback information. virtual FeedbackVectorRequirements ComputeFeedbackRequirements( Isolate* isolate) OVERRIDE { return FeedbackVectorRequirements(0, FLAG_vector_ics ? 1 : 0); } void SetFirstFeedbackICSlot(FeedbackVectorICSlot slot) OVERRIDE { homeobject_feedback_slot_ = slot; } Code::Kind FeedbackICSlotKind(int index) OVERRIDE { return Code::LOAD_IC; } FeedbackVectorICSlot HomeObjectFeedbackSlot() { DCHECK(!FLAG_vector_ics || !homeobject_feedback_slot_.IsInvalid()); return homeobject_feedback_slot_; } protected: SuperReference(Zone* zone, VariableProxy* this_var, int pos) : Expression(zone, pos), this_var_(this_var), homeobject_feedback_slot_(FeedbackVectorICSlot::Invalid()) { DCHECK(this_var->is_this()); } static int parent_num_ids() { return Expression::num_ids(); } private: int local_id(int n) const { return base_id() + parent_num_ids() + n; } VariableProxy* this_var_; FeedbackVectorICSlot homeobject_feedback_slot_; }; #undef DECLARE_NODE_TYPE // ---------------------------------------------------------------------------- // Regular expressions class RegExpVisitor BASE_EMBEDDED { public: virtual ~RegExpVisitor() { } #define MAKE_CASE(Name) \ virtual void* Visit##Name(RegExp##Name*, void* data) = 0; FOR_EACH_REG_EXP_TREE_TYPE(MAKE_CASE) #undef MAKE_CASE }; class RegExpTree : public ZoneObject { public: static const int kInfinity = kMaxInt; virtual ~RegExpTree() {} virtual void* Accept(RegExpVisitor* visitor, void* data) = 0; virtual RegExpNode* ToNode(RegExpCompiler* compiler, RegExpNode* on_success) = 0; virtual bool IsTextElement() { return false; } virtual bool IsAnchoredAtStart() { return false; } virtual bool IsAnchoredAtEnd() { return false; } virtual int min_match() = 0; virtual int max_match() = 0; // Returns the interval of registers used for captures within this // expression. virtual Interval CaptureRegisters() { return Interval::Empty(); } virtual void AppendToText(RegExpText* text, Zone* zone); std::ostream& Print(std::ostream& os, Zone* zone); // NOLINT #define MAKE_ASTYPE(Name) \ virtual RegExp##Name* As##Name(); \ virtual bool Is##Name(); FOR_EACH_REG_EXP_TREE_TYPE(MAKE_ASTYPE) #undef MAKE_ASTYPE }; class RegExpDisjunction FINAL : public RegExpTree { public: explicit RegExpDisjunction(ZoneList* alternatives); void* Accept(RegExpVisitor* visitor, void* data) OVERRIDE; virtual RegExpNode* ToNode(RegExpCompiler* compiler, RegExpNode* on_success) OVERRIDE; RegExpDisjunction* AsDisjunction() OVERRIDE; Interval CaptureRegisters() OVERRIDE; bool IsDisjunction() OVERRIDE; bool IsAnchoredAtStart() OVERRIDE; bool IsAnchoredAtEnd() OVERRIDE; int min_match() OVERRIDE { return min_match_; } int max_match() OVERRIDE { return max_match_; } ZoneList* alternatives() { return alternatives_; } private: ZoneList* alternatives_; int min_match_; int max_match_; }; class RegExpAlternative FINAL : public RegExpTree { public: explicit RegExpAlternative(ZoneList* nodes); void* Accept(RegExpVisitor* visitor, void* data) OVERRIDE; virtual RegExpNode* ToNode(RegExpCompiler* compiler, RegExpNode* on_success) OVERRIDE; RegExpAlternative* AsAlternative() OVERRIDE; Interval CaptureRegisters() OVERRIDE; bool IsAlternative() OVERRIDE; bool IsAnchoredAtStart() OVERRIDE; bool IsAnchoredAtEnd() OVERRIDE; int min_match() OVERRIDE { return min_match_; } int max_match() OVERRIDE { return max_match_; } ZoneList* nodes() { return nodes_; } private: ZoneList* nodes_; int min_match_; int max_match_; }; class RegExpAssertion FINAL : public RegExpTree { public: enum AssertionType { START_OF_LINE, START_OF_INPUT, END_OF_LINE, END_OF_INPUT, BOUNDARY, NON_BOUNDARY }; explicit RegExpAssertion(AssertionType type) : assertion_type_(type) { } void* Accept(RegExpVisitor* visitor, void* data) OVERRIDE; virtual RegExpNode* ToNode(RegExpCompiler* compiler, RegExpNode* on_success) OVERRIDE; RegExpAssertion* AsAssertion() OVERRIDE; bool IsAssertion() OVERRIDE; bool IsAnchoredAtStart() OVERRIDE; bool IsAnchoredAtEnd() OVERRIDE; int min_match() OVERRIDE { return 0; } int max_match() OVERRIDE { return 0; } AssertionType assertion_type() { return assertion_type_; } private: AssertionType assertion_type_; }; class CharacterSet FINAL BASE_EMBEDDED { public: explicit CharacterSet(uc16 standard_set_type) : ranges_(NULL), standard_set_type_(standard_set_type) {} explicit CharacterSet(ZoneList* ranges) : ranges_(ranges), standard_set_type_(0) {} ZoneList* ranges(Zone* zone); uc16 standard_set_type() { return standard_set_type_; } void set_standard_set_type(uc16 special_set_type) { standard_set_type_ = special_set_type; } bool is_standard() { return standard_set_type_ != 0; } void Canonicalize(); private: ZoneList* ranges_; // If non-zero, the value represents a standard set (e.g., all whitespace // characters) without having to expand the ranges. uc16 standard_set_type_; }; class RegExpCharacterClass FINAL : public RegExpTree { public: RegExpCharacterClass(ZoneList* ranges, bool is_negated) : set_(ranges), is_negated_(is_negated) { } explicit RegExpCharacterClass(uc16 type) : set_(type), is_negated_(false) { } void* Accept(RegExpVisitor* visitor, void* data) OVERRIDE; virtual RegExpNode* ToNode(RegExpCompiler* compiler, RegExpNode* on_success) OVERRIDE; RegExpCharacterClass* AsCharacterClass() OVERRIDE; bool IsCharacterClass() OVERRIDE; bool IsTextElement() OVERRIDE { return true; } int min_match() OVERRIDE { return 1; } int max_match() OVERRIDE { return 1; } void AppendToText(RegExpText* text, Zone* zone) OVERRIDE; CharacterSet character_set() { return set_; } // TODO(lrn): Remove need for complex version if is_standard that // recognizes a mangled standard set and just do { return set_.is_special(); } bool is_standard(Zone* zone); // Returns a value representing the standard character set if is_standard() // returns true. // Currently used values are: // s : unicode whitespace // S : unicode non-whitespace // w : ASCII word character (digit, letter, underscore) // W : non-ASCII word character // d : ASCII digit // D : non-ASCII digit // . : non-unicode non-newline // * : All characters uc16 standard_type() { return set_.standard_set_type(); } ZoneList* ranges(Zone* zone) { return set_.ranges(zone); } bool is_negated() { return is_negated_; } private: CharacterSet set_; bool is_negated_; }; class RegExpAtom FINAL : public RegExpTree { public: explicit RegExpAtom(Vector data) : data_(data) { } void* Accept(RegExpVisitor* visitor, void* data) OVERRIDE; virtual RegExpNode* ToNode(RegExpCompiler* compiler, RegExpNode* on_success) OVERRIDE; RegExpAtom* AsAtom() OVERRIDE; bool IsAtom() OVERRIDE; bool IsTextElement() OVERRIDE { return true; } int min_match() OVERRIDE { return data_.length(); } int max_match() OVERRIDE { return data_.length(); } void AppendToText(RegExpText* text, Zone* zone) OVERRIDE; Vector data() { return data_; } int length() { return data_.length(); } private: Vector data_; }; class RegExpText FINAL : public RegExpTree { public: explicit RegExpText(Zone* zone) : elements_(2, zone), length_(0) {} void* Accept(RegExpVisitor* visitor, void* data) OVERRIDE; virtual RegExpNode* ToNode(RegExpCompiler* compiler, RegExpNode* on_success) OVERRIDE; RegExpText* AsText() OVERRIDE; bool IsText() OVERRIDE; bool IsTextElement() OVERRIDE { return true; } int min_match() OVERRIDE { return length_; } int max_match() OVERRIDE { return length_; } void AppendToText(RegExpText* text, Zone* zone) OVERRIDE; void AddElement(TextElement elm, Zone* zone) { elements_.Add(elm, zone); length_ += elm.length(); } ZoneList* elements() { return &elements_; } private: ZoneList elements_; int length_; }; class RegExpQuantifier FINAL : public RegExpTree { public: enum QuantifierType { GREEDY, NON_GREEDY, POSSESSIVE }; RegExpQuantifier(int min, int max, QuantifierType type, RegExpTree* body) : body_(body), min_(min), max_(max), min_match_(min * body->min_match()), quantifier_type_(type) { if (max > 0 && body->max_match() > kInfinity / max) { max_match_ = kInfinity; } else { max_match_ = max * body->max_match(); } } void* Accept(RegExpVisitor* visitor, void* data) OVERRIDE; virtual RegExpNode* ToNode(RegExpCompiler* compiler, RegExpNode* on_success) OVERRIDE; static RegExpNode* ToNode(int min, int max, bool is_greedy, RegExpTree* body, RegExpCompiler* compiler, RegExpNode* on_success, bool not_at_start = false); RegExpQuantifier* AsQuantifier() OVERRIDE; Interval CaptureRegisters() OVERRIDE; bool IsQuantifier() OVERRIDE; int min_match() OVERRIDE { return min_match_; } int max_match() OVERRIDE { return max_match_; } int min() { return min_; } int max() { return max_; } bool is_possessive() { return quantifier_type_ == POSSESSIVE; } bool is_non_greedy() { return quantifier_type_ == NON_GREEDY; } bool is_greedy() { return quantifier_type_ == GREEDY; } RegExpTree* body() { return body_; } private: RegExpTree* body_; int min_; int max_; int min_match_; int max_match_; QuantifierType quantifier_type_; }; class RegExpCapture FINAL : public RegExpTree { public: explicit RegExpCapture(RegExpTree* body, int index) : body_(body), index_(index) { } void* Accept(RegExpVisitor* visitor, void* data) OVERRIDE; virtual RegExpNode* ToNode(RegExpCompiler* compiler, RegExpNode* on_success) OVERRIDE; static RegExpNode* ToNode(RegExpTree* body, int index, RegExpCompiler* compiler, RegExpNode* on_success); RegExpCapture* AsCapture() OVERRIDE; bool IsAnchoredAtStart() OVERRIDE; bool IsAnchoredAtEnd() OVERRIDE; Interval CaptureRegisters() OVERRIDE; bool IsCapture() OVERRIDE; int min_match() OVERRIDE { return body_->min_match(); } int max_match() OVERRIDE { return body_->max_match(); } RegExpTree* body() { return body_; } int index() { return index_; } static int StartRegister(int index) { return index * 2; } static int EndRegister(int index) { return index * 2 + 1; } private: RegExpTree* body_; int index_; }; class RegExpLookahead FINAL : public RegExpTree { public: RegExpLookahead(RegExpTree* body, bool is_positive, int capture_count, int capture_from) : body_(body), is_positive_(is_positive), capture_count_(capture_count), capture_from_(capture_from) { } void* Accept(RegExpVisitor* visitor, void* data) OVERRIDE; virtual RegExpNode* ToNode(RegExpCompiler* compiler, RegExpNode* on_success) OVERRIDE; RegExpLookahead* AsLookahead() OVERRIDE; Interval CaptureRegisters() OVERRIDE; bool IsLookahead() OVERRIDE; bool IsAnchoredAtStart() OVERRIDE; int min_match() OVERRIDE { return 0; } int max_match() OVERRIDE { return 0; } RegExpTree* body() { return body_; } bool is_positive() { return is_positive_; } int capture_count() { return capture_count_; } int capture_from() { return capture_from_; } private: RegExpTree* body_; bool is_positive_; int capture_count_; int capture_from_; }; class RegExpBackReference FINAL : public RegExpTree { public: explicit RegExpBackReference(RegExpCapture* capture) : capture_(capture) { } void* Accept(RegExpVisitor* visitor, void* data) OVERRIDE; virtual RegExpNode* ToNode(RegExpCompiler* compiler, RegExpNode* on_success) OVERRIDE; RegExpBackReference* AsBackReference() OVERRIDE; bool IsBackReference() OVERRIDE; int min_match() OVERRIDE { return 0; } int max_match() OVERRIDE { return capture_->max_match(); } int index() { return capture_->index(); } RegExpCapture* capture() { return capture_; } private: RegExpCapture* capture_; }; class RegExpEmpty FINAL : public RegExpTree { public: RegExpEmpty() { } void* Accept(RegExpVisitor* visitor, void* data) OVERRIDE; virtual RegExpNode* ToNode(RegExpCompiler* compiler, RegExpNode* on_success) OVERRIDE; RegExpEmpty* AsEmpty() OVERRIDE; bool IsEmpty() OVERRIDE; int min_match() OVERRIDE { return 0; } int max_match() OVERRIDE { return 0; } }; // ---------------------------------------------------------------------------- // Basic visitor // - leaf node visitors are abstract. class AstVisitor BASE_EMBEDDED { public: AstVisitor() {} virtual ~AstVisitor() {} // Stack overflow check and dynamic dispatch. virtual void Visit(AstNode* node) = 0; // Iteration left-to-right. virtual void VisitDeclarations(ZoneList* declarations); virtual void VisitStatements(ZoneList* statements); virtual void VisitExpressions(ZoneList* expressions); // Individual AST nodes. #define DEF_VISIT(type) \ virtual void Visit##type(type* node) = 0; AST_NODE_LIST(DEF_VISIT) #undef DEF_VISIT }; #define DEFINE_AST_VISITOR_SUBCLASS_MEMBERS() \ public: \ void Visit(AstNode* node) FINAL { \ if (!CheckStackOverflow()) node->Accept(this); \ } \ \ void SetStackOverflow() { stack_overflow_ = true; } \ void ClearStackOverflow() { stack_overflow_ = false; } \ bool HasStackOverflow() const { return stack_overflow_; } \ \ bool CheckStackOverflow() { \ if (stack_overflow_) return true; \ StackLimitCheck check(isolate_); \ if (!check.HasOverflowed()) return false; \ stack_overflow_ = true; \ return true; \ } \ \ private: \ void InitializeAstVisitor(Isolate* isolate, Zone* zone) { \ isolate_ = isolate; \ zone_ = zone; \ stack_overflow_ = false; \ } \ Zone* zone() { return zone_; } \ Isolate* isolate() { return isolate_; } \ \ Isolate* isolate_; \ Zone* zone_; \ bool stack_overflow_ // ---------------------------------------------------------------------------- // AstNode factory class AstNodeFactory FINAL BASE_EMBEDDED { public: explicit AstNodeFactory(AstValueFactory* ast_value_factory) : zone_(ast_value_factory->zone()), ast_value_factory_(ast_value_factory) {} VariableDeclaration* NewVariableDeclaration(VariableProxy* proxy, VariableMode mode, Scope* scope, int pos) { return new (zone_) VariableDeclaration(zone_, proxy, mode, scope, pos); } FunctionDeclaration* NewFunctionDeclaration(VariableProxy* proxy, VariableMode mode, FunctionLiteral* fun, Scope* scope, int pos) { return new (zone_) FunctionDeclaration(zone_, proxy, mode, fun, scope, pos); } ModuleDeclaration* NewModuleDeclaration(VariableProxy* proxy, Module* module, Scope* scope, int pos) { return new (zone_) ModuleDeclaration(zone_, proxy, module, scope, pos); } ImportDeclaration* NewImportDeclaration(VariableProxy* proxy, Module* module, Scope* scope, int pos) { return new (zone_) ImportDeclaration(zone_, proxy, module, scope, pos); } ExportDeclaration* NewExportDeclaration(VariableProxy* proxy, Scope* scope, int pos) { return new (zone_) ExportDeclaration(zone_, proxy, scope, pos); } ModuleLiteral* NewModuleLiteral(Block* body, ModuleDescriptor* descriptor, int pos) { return new (zone_) ModuleLiteral(zone_, body, descriptor, pos); } ModulePath* NewModulePath(Module* origin, const AstRawString* name, int pos) { return new (zone_) ModulePath(zone_, origin, name, pos); } ModuleUrl* NewModuleUrl(Handle url, int pos) { return new (zone_) ModuleUrl(zone_, url, pos); } Block* NewBlock(ZoneList* labels, int capacity, bool is_initializer_block, int pos) { return new (zone_) Block(zone_, labels, capacity, is_initializer_block, pos); } #define STATEMENT_WITH_LABELS(NodeType) \ NodeType* New##NodeType(ZoneList* labels, int pos) { \ return new (zone_) NodeType(zone_, labels, pos); \ } STATEMENT_WITH_LABELS(DoWhileStatement) STATEMENT_WITH_LABELS(WhileStatement) STATEMENT_WITH_LABELS(ForStatement) STATEMENT_WITH_LABELS(SwitchStatement) #undef STATEMENT_WITH_LABELS ForEachStatement* NewForEachStatement(ForEachStatement::VisitMode visit_mode, ZoneList* labels, int pos) { switch (visit_mode) { case ForEachStatement::ENUMERATE: { return new (zone_) ForInStatement(zone_, labels, pos); } case ForEachStatement::ITERATE: { return new (zone_) ForOfStatement(zone_, labels, pos); } } UNREACHABLE(); return NULL; } ModuleStatement* NewModuleStatement(Block* body, int pos) { return new (zone_) ModuleStatement(zone_, body, pos); } ExpressionStatement* NewExpressionStatement(Expression* expression, int pos) { return new (zone_) ExpressionStatement(zone_, expression, pos); } ContinueStatement* NewContinueStatement(IterationStatement* target, int pos) { return new (zone_) ContinueStatement(zone_, target, pos); } BreakStatement* NewBreakStatement(BreakableStatement* target, int pos) { return new (zone_) BreakStatement(zone_, target, pos); } ReturnStatement* NewReturnStatement(Expression* expression, int pos) { return new (zone_) ReturnStatement(zone_, expression, pos); } WithStatement* NewWithStatement(Scope* scope, Expression* expression, Statement* statement, int pos) { return new (zone_) WithStatement(zone_, scope, expression, statement, pos); } IfStatement* NewIfStatement(Expression* condition, Statement* then_statement, Statement* else_statement, int pos) { return new (zone_) IfStatement(zone_, condition, then_statement, else_statement, pos); } TryCatchStatement* NewTryCatchStatement(int index, Block* try_block, Scope* scope, Variable* variable, Block* catch_block, int pos) { return new (zone_) TryCatchStatement(zone_, index, try_block, scope, variable, catch_block, pos); } TryFinallyStatement* NewTryFinallyStatement(int index, Block* try_block, Block* finally_block, int pos) { return new (zone_) TryFinallyStatement(zone_, index, try_block, finally_block, pos); } DebuggerStatement* NewDebuggerStatement(int pos) { return new (zone_) DebuggerStatement(zone_, pos); } EmptyStatement* NewEmptyStatement(int pos) { return new(zone_) EmptyStatement(zone_, pos); } CaseClause* NewCaseClause( Expression* label, ZoneList* statements, int pos) { return new (zone_) CaseClause(zone_, label, statements, pos); } Literal* NewStringLiteral(const AstRawString* string, int pos) { return new (zone_) Literal(zone_, ast_value_factory_->NewString(string), pos); } // A JavaScript symbol (ECMA-262 edition 6). Literal* NewSymbolLiteral(const char* name, int pos) { return new (zone_) Literal(zone_, ast_value_factory_->NewSymbol(name), pos); } Literal* NewNumberLiteral(double number, int pos) { return new (zone_) Literal(zone_, ast_value_factory_->NewNumber(number), pos); } Literal* NewSmiLiteral(int number, int pos) { return new (zone_) Literal(zone_, ast_value_factory_->NewSmi(number), pos); } Literal* NewBooleanLiteral(bool b, int pos) { return new (zone_) Literal(zone_, ast_value_factory_->NewBoolean(b), pos); } Literal* NewNullLiteral(int pos) { return new (zone_) Literal(zone_, ast_value_factory_->NewNull(), pos); } Literal* NewUndefinedLiteral(int pos) { return new (zone_) Literal(zone_, ast_value_factory_->NewUndefined(), pos); } Literal* NewTheHoleLiteral(int pos) { return new (zone_) Literal(zone_, ast_value_factory_->NewTheHole(), pos); } ObjectLiteral* NewObjectLiteral( ZoneList* properties, int literal_index, int boilerplate_properties, bool has_function, int pos) { return new (zone_) ObjectLiteral(zone_, properties, literal_index, boilerplate_properties, has_function, pos); } ObjectLiteral::Property* NewObjectLiteralProperty( Expression* key, Expression* value, ObjectLiteralProperty::Kind kind, bool is_static, bool is_computed_name) { return new (zone_) ObjectLiteral::Property(key, value, kind, is_static, is_computed_name); } ObjectLiteral::Property* NewObjectLiteralProperty(Expression* key, Expression* value, bool is_static, bool is_computed_name) { return new (zone_) ObjectLiteral::Property(ast_value_factory_, key, value, is_static, is_computed_name); } RegExpLiteral* NewRegExpLiteral(const AstRawString* pattern, const AstRawString* flags, int literal_index, int pos) { return new (zone_) RegExpLiteral(zone_, pattern, flags, literal_index, pos); } ArrayLiteral* NewArrayLiteral(ZoneList* values, int literal_index, int pos) { return new (zone_) ArrayLiteral(zone_, values, literal_index, pos); } VariableProxy* NewVariableProxy(Variable* var, int pos = RelocInfo::kNoPosition) { return new (zone_) VariableProxy(zone_, var, pos); } VariableProxy* NewVariableProxy(const AstRawString* name, bool is_this, int position = RelocInfo::kNoPosition) { return new (zone_) VariableProxy(zone_, name, is_this, position); } Property* NewProperty(Expression* obj, Expression* key, int pos) { return new (zone_) Property(zone_, obj, key, pos); } Call* NewCall(Expression* expression, ZoneList* arguments, int pos) { return new (zone_) Call(zone_, expression, arguments, pos); } CallNew* NewCallNew(Expression* expression, ZoneList* arguments, int pos) { return new (zone_) CallNew(zone_, expression, arguments, pos); } CallRuntime* NewCallRuntime(const AstRawString* name, const Runtime::Function* function, ZoneList* arguments, int pos) { return new (zone_) CallRuntime(zone_, name, function, arguments, pos); } UnaryOperation* NewUnaryOperation(Token::Value op, Expression* expression, int pos) { return new (zone_) UnaryOperation(zone_, op, expression, pos); } BinaryOperation* NewBinaryOperation(Token::Value op, Expression* left, Expression* right, int pos) { return new (zone_) BinaryOperation(zone_, op, left, right, pos); } CountOperation* NewCountOperation(Token::Value op, bool is_prefix, Expression* expr, int pos) { return new (zone_) CountOperation(zone_, op, is_prefix, expr, pos); } CompareOperation* NewCompareOperation(Token::Value op, Expression* left, Expression* right, int pos) { return new (zone_) CompareOperation(zone_, op, left, right, pos); } Conditional* NewConditional(Expression* condition, Expression* then_expression, Expression* else_expression, int position) { return new (zone_) Conditional(zone_, condition, then_expression, else_expression, position); } Assignment* NewAssignment(Token::Value op, Expression* target, Expression* value, int pos) { DCHECK(Token::IsAssignmentOp(op)); Assignment* assign = new (zone_) Assignment(zone_, op, target, value, pos); if (assign->is_compound()) { DCHECK(Token::IsAssignmentOp(op)); assign->binary_operation_ = NewBinaryOperation(assign->binary_op(), target, value, pos + 1); } return assign; } Yield* NewYield(Expression *generator_object, Expression* expression, Yield::Kind yield_kind, int pos) { if (!expression) expression = NewUndefinedLiteral(pos); return new (zone_) Yield(zone_, generator_object, expression, yield_kind, pos); } Throw* NewThrow(Expression* exception, int pos) { return new (zone_) Throw(zone_, exception, pos); } FunctionLiteral* NewFunctionLiteral( const AstRawString* name, AstValueFactory* ast_value_factory, Scope* scope, ZoneList* body, int materialized_literal_count, int expected_property_count, int handler_count, int parameter_count, FunctionLiteral::ParameterFlag has_duplicate_parameters, FunctionLiteral::FunctionType function_type, FunctionLiteral::IsFunctionFlag is_function, FunctionLiteral::IsParenthesizedFlag is_parenthesized, FunctionKind kind, int position) { return new (zone_) FunctionLiteral( zone_, name, ast_value_factory, scope, body, materialized_literal_count, expected_property_count, handler_count, parameter_count, function_type, has_duplicate_parameters, is_function, is_parenthesized, kind, position); } ClassLiteral* NewClassLiteral(const AstRawString* name, Scope* scope, VariableProxy* proxy, Expression* extends, FunctionLiteral* constructor, ZoneList* properties, int start_position, int end_position) { return new (zone_) ClassLiteral(zone_, name, scope, proxy, extends, constructor, properties, start_position, end_position); } NativeFunctionLiteral* NewNativeFunctionLiteral(const AstRawString* name, v8::Extension* extension, int pos) { return new (zone_) NativeFunctionLiteral(zone_, name, extension, pos); } ThisFunction* NewThisFunction(int pos) { return new (zone_) ThisFunction(zone_, pos); } SuperReference* NewSuperReference(VariableProxy* this_var, int pos) { return new (zone_) SuperReference(zone_, this_var, pos); } private: Zone* zone_; AstValueFactory* ast_value_factory_; }; } } // namespace v8::internal #endif // V8_AST_H_