src/compiler/ast-graph-builder.h - v8/v8 - Git at Google

 // Copyright 2014 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_COMPILER_AST_GRAPH_BUILDER_H_
 #define V8_COMPILER_AST_GRAPH_BUILDER_H_

 #include "src/ast.h"
 #include "src/compiler/js-graph.h"
 #include "src/compiler/liveness-analyzer.h"
 #include "src/compiler/state-values-utils.h"

 namespace v8 {
 namespace internal {

 class BitVector;

 namespace compiler {

 class ControlBuilder;
 class Graph;
 class JSTypeFeedbackTable;
 class LoopAssignmentAnalysis;
 class LoopBuilder;
 class Node;

 // The AstGraphBuilder produces a high-level IR graph, based on an
 // underlying AST. The produced graph can either be compiled into a
 // stand-alone function or be wired into another graph for the purposes
 // of function inlining.
 class AstGraphBuilder : public AstVisitor {
  public:
   AstGraphBuilder(Zone* local_zone, CompilationInfo* info, JSGraph* jsgraph,
                   LoopAssignmentAnalysis* loop_assignment = NULL,
                   JSTypeFeedbackTable* js_type_feedback = NULL);

   // Creates a graph by visiting the entire AST.
   bool CreateGraph(bool constant_context, bool stack_check = true);

   // Helpers to create new control nodes.
   Node* NewIfTrue() { return NewNode(common()->IfTrue()); }
   Node* NewIfFalse() { return NewNode(common()->IfFalse()); }
   Node* NewMerge() { return NewNode(common()->Merge(1), true); }
   Node* NewLoop() { return NewNode(common()->Loop(1), true); }
   Node* NewBranch(Node* condition, BranchHint hint = BranchHint::kNone) {
     return NewNode(common()->Branch(hint), condition);
   }

  protected:
 #define DECLARE_VISIT(type) void Visit##type(type* node) override;
   // Visiting functions for AST nodes make this an AstVisitor.
   AST_NODE_LIST(DECLARE_VISIT)
 #undef DECLARE_VISIT

   // Visiting function for declarations list is overridden.
   void VisitDeclarations(ZoneList<Declaration*>* declarations) override;

  private:
   class AstContext;
   class AstEffectContext;
   class AstValueContext;
   class AstTestContext;
   class ContextScope;
   class ControlScope;
   class ControlScopeForBreakable;
   class ControlScopeForIteration;
   class ControlScopeForCatch;
   class ControlScopeForFinally;
   class Environment;
   friend class ControlBuilder;

   Zone* local_zone_;
   CompilationInfo* info_;
   JSGraph* jsgraph_;
   Environment* environment_;
   AstContext* ast_context_;

   // List of global declarations for functions and variables.
   ZoneVector<Handle<Object>> globals_;

   // Stack of control scopes currently entered by the visitor.
   ControlScope* execution_control_;

   // Stack of context objects pushed onto the chain by the visitor.
   ContextScope* execution_context_;

   // Nodes representing values in the activation record.
   SetOncePointer<Node> function_closure_;
   SetOncePointer<Node> function_context_;

   // Tracks how many try-blocks are currently entered.
   int try_nesting_level_;

   // Temporary storage for building node input lists.
   int input_buffer_size_;
   Node** input_buffer_;

   // Merge of all control nodes that exit the function body.
   Node* exit_control_;

   // Result of loop assignment analysis performed before graph creation.
   LoopAssignmentAnalysis* loop_assignment_analysis_;

   // Cache for StateValues nodes for frame states.
   StateValuesCache state_values_cache_;

   // Analyzer of local variable liveness.
   LivenessAnalyzer liveness_analyzer_;

   // Type feedback table.
   JSTypeFeedbackTable* js_type_feedback_;

   // Growth increment for the temporary buffer used to construct input lists to
   // new nodes.
   static const int kInputBufferSizeIncrement = 64;

   Zone* local_zone() const { return local_zone_; }
   Environment* environment() const { return environment_; }
   AstContext* ast_context() const { return ast_context_; }
   ControlScope* execution_control() const { return execution_control_; }
   ContextScope* execution_context() const { return execution_context_; }
   CommonOperatorBuilder* common() const { return jsgraph_->common(); }
   CompilationInfo* info() const { return info_; }
   LanguageMode language_mode() const;
   JSGraph* jsgraph() { return jsgraph_; }
   Graph* graph() { return jsgraph_->graph(); }
   Zone* graph_zone() { return graph()->zone(); }
   JSOperatorBuilder* javascript() { return jsgraph_->javascript(); }
   ZoneVector<Handle<Object>>* globals() { return &globals_; }
   Scope* current_scope() const;
   Node* current_context() const;
   Node* exit_control() const { return exit_control_; }
   LivenessAnalyzer* liveness_analyzer() { return &liveness_analyzer_; }

   void set_environment(Environment* env) { environment_ = env; }
   void set_ast_context(AstContext* ctx) { ast_context_ = ctx; }
   void set_execution_control(ControlScope* ctrl) { execution_control_ = ctrl; }
   void set_execution_context(ContextScope* ctx) { execution_context_ = ctx; }
   void set_exit_control(Node* exit) { exit_control_ = exit; }

   // Create the main graph body by visiting the AST.
   void CreateGraphBody(bool stack_check);

   // Create the node that represents the outer context of the function.
   void CreateFunctionContext(bool constant_context);

   // Get or create the node that represents the outer function closure.
   Node* GetFunctionClosure();

   // Node creation helpers.
   Node* NewNode(const Operator* op, bool incomplete = false) {
     return MakeNode(op, 0, static_cast<Node**>(NULL), incomplete);
   }

   Node* NewNode(const Operator* op, Node* n1) {
     return MakeNode(op, 1, &n1, false);
   }

   Node* NewNode(const Operator* op, Node* n1, Node* n2) {
     Node* buffer[] = {n1, n2};
     return MakeNode(op, arraysize(buffer), buffer, false);
   }

   Node* NewNode(const Operator* op, Node* n1, Node* n2, Node* n3) {
     Node* buffer[] = {n1, n2, n3};
     return MakeNode(op, arraysize(buffer), buffer, false);
   }

   Node* NewNode(const Operator* op, Node* n1, Node* n2, Node* n3, Node* n4) {
     Node* buffer[] = {n1, n2, n3, n4};
     return MakeNode(op, arraysize(buffer), buffer, false);
   }

   Node* NewNode(const Operator* op, Node* n1, Node* n2, Node* n3, Node* n4,
                 Node* n5) {
     Node* buffer[] = {n1, n2, n3, n4, n5};
     return MakeNode(op, arraysize(buffer), buffer, false);
   }

   Node* NewNode(const Operator* op, Node* n1, Node* n2, Node* n3, Node* n4,
                 Node* n5, Node* n6) {
     Node* nodes[] = {n1, n2, n3, n4, n5, n6};
     return MakeNode(op, arraysize(nodes), nodes, false);
   }

   Node* NewNode(const Operator* op, int value_input_count, Node** value_inputs,
                 bool incomplete = false) {
     return MakeNode(op, value_input_count, value_inputs, incomplete);
   }

   // Creates a new Phi node having {count} input values.
   Node* NewPhi(int count, Node* input, Node* control);
   Node* NewEffectPhi(int count, Node* input, Node* control);

   Node* NewOuterContextParam();
   Node* NewCurrentContextOsrValue();

   // Helpers for merging control, effect or value dependencies.
   Node* MergeControl(Node* control, Node* other);
   Node* MergeEffect(Node* value, Node* other, Node* control);
   Node* MergeValue(Node* value, Node* other, Node* control);

   // The main node creation chokepoint. Adds context, frame state, effect,
   // and control dependencies depending on the operator.
   Node* MakeNode(const Operator* op, int value_input_count, Node** value_inputs,
                  bool incomplete);

   // Helper to indicate a node exits the function body.
   void UpdateControlDependencyToLeaveFunction(Node* exit);

   // Builds deoptimization for a given node.
   void PrepareFrameState(
       Node* node, BailoutId ast_id,
       OutputFrameStateCombine combine = OutputFrameStateCombine::Ignore());
   void PrepareFrameStateAfterAndBefore(Node* node, BailoutId ast_id,
                                        OutputFrameStateCombine combine,
                                        Node* frame_state_before);

   BitVector* GetVariablesAssignedInLoop(IterationStatement* stmt);

   // Check if the given statement is an OSR entry.
   // If so, record the stack height into the compilation and return {true}.
   bool CheckOsrEntry(IterationStatement* stmt);

   // Computes local variable liveness and replaces dead variables in
   // frame states with the undefined values.
   void ClearNonLiveSlotsInFrameStates();

   // Helper to wrap a Handle<T> into a Unique<T>.
   template <class T>
   Unique<T> MakeUnique(Handle<T> object) {
     return Unique<T>::CreateUninitialized(object);
   }

   Node** EnsureInputBufferSize(int size);

   // Named and keyed loads require a VectorSlotPair for successful lowering.
   VectorSlotPair CreateVectorSlotPair(FeedbackVectorICSlot slot) const;

   // ===========================================================================
   // The following build methods all generate graph fragments and return one
   // resulting node. The operand stack height remains the same, variables and
   // other dependencies tracked by the environment might be mutated though.

   // Builder to create a receiver check for sloppy mode.
   Node* BuildPatchReceiverToGlobalProxy(Node* receiver);

   // Builders to create local function, script and block contexts.
   Node* BuildLocalFunctionContext(Node* context);
   Node* BuildLocalScriptContext(Scope* scope);
   Node* BuildLocalBlockContext(Scope* scope);

   // Builder to create an arguments object if it is used.
   Node* BuildArgumentsObject(Variable* arguments);

   // Builder to create an array of rest parameters if used
   Node* BuildRestArgumentsArray(Variable* rest, int index);

   // Builders for variable load and assignment.
   Node* BuildVariableAssignment(Variable* var, Node* value, Token::Value op,
                                 BailoutId bailout_id,
                                 OutputFrameStateCombine state_combine =
                                     OutputFrameStateCombine::Ignore());
   Node* BuildVariableDelete(Variable* var, BailoutId bailout_id,
                             OutputFrameStateCombine state_combine);
   Node* BuildVariableLoad(Variable* var, BailoutId bailout_id,
                           const VectorSlotPair& feedback,
                           ContextualMode mode = CONTEXTUAL);

   // Builders for property loads and stores.
   Node* BuildKeyedLoad(Node* receiver, Node* key,
                        const VectorSlotPair& feedback, TypeFeedbackId id);
   Node* BuildNamedLoad(Node* receiver, Handle<Name> name,
                        const VectorSlotPair& feedback, TypeFeedbackId id,
                        ContextualMode mode = NOT_CONTEXTUAL);
   Node* BuildKeyedStore(Node* receiver, Node* key, Node* value,
                         TypeFeedbackId id);
   Node* BuildNamedStore(Node* receiver, Handle<Name>, Node* value,
                         TypeFeedbackId id);

   // Builders for accessing the function context.
   Node* BuildLoadBuiltinsObject();
   Node* BuildLoadGlobalObject();
   Node* BuildLoadGlobalProxy();
   Node* BuildLoadClosure();
   Node* BuildLoadObjectField(Node* object, int offset);

   // Builders for accessing external references.
   Node* BuildLoadExternal(ExternalReference ref, MachineType type);
   Node* BuildStoreExternal(ExternalReference ref, MachineType type, Node* val);

   // Builders for automatic type conversion.
   Node* BuildToBoolean(Node* value);
   Node* BuildToName(Node* value, BailoutId bailout_id);

   // Builder for adding the [[HomeObject]] to a value if the value came from a
   // function literal and needs a home object. Do nothing otherwise.
   Node* BuildSetHomeObject(Node* value, Node* home_object, Expression* expr);

   // Builders for error reporting at runtime.
   Node* BuildThrowError(Node* exception, BailoutId bailout_id);
   Node* BuildThrowReferenceError(Variable* var, BailoutId bailout_id);
   Node* BuildThrowConstAssignError(BailoutId bailout_id);
   Node* BuildThrowStaticPrototypeError(BailoutId bailout_id);

   // Builders for dynamic hole-checks at runtime.
   Node* BuildHoleCheckSilent(Node* value, Node* for_hole, Node* not_hole);
   Node* BuildHoleCheckThrow(Node* value, Variable* var, Node* not_hole,
                             BailoutId bailout_id);

   // Builders for conditional errors.
   Node* BuildThrowIfStaticPrototype(Node* name, BailoutId bailout_id);

   // Builders for non-local control flow.
   Node* BuildReturn(Node* return_value);
   Node* BuildThrow(Node* exception_value);

   // Builders for binary operations.
   Node* BuildBinaryOp(Node* left, Node* right, Token::Value op);

   // Process arguments to a call by popping {arity} elements off the operand
   // stack and build a call node using the given call operator.
   Node* ProcessArguments(const Operator* op, int arity);

   // ===========================================================================
   // The following visitation methods all recursively visit a subtree of the
   // underlying AST and extent the graph. The operand stack is mutated in a way
   // consistent with other compilers:
   //  - Expressions pop operands and push result, depending on {AstContext}.
   //  - Statements keep the operand stack balanced.

   // Visit statements.
   void VisitIfNotNull(Statement* stmt);

   // Visit expressions.
   void Visit(Expression* expr);
   void VisitForTest(Expression* expr);
   void VisitForEffect(Expression* expr);
   void VisitForValue(Expression* expr);
   void VisitForValueOrNull(Expression* expr);
   void VisitForValueOrTheHole(Expression* expr);
   void VisitForValues(ZoneList<Expression*>* exprs);

   // Common for all IterationStatement bodies.
   void VisitIterationBody(IterationStatement* stmt, LoopBuilder* loop);

   // Dispatched from VisitCallRuntime.
   void VisitCallJSRuntime(CallRuntime* expr);

   // Dispatched from VisitUnaryOperation.
   void VisitDelete(UnaryOperation* expr);
   void VisitVoid(UnaryOperation* expr);
   void VisitTypeof(UnaryOperation* expr);
   void VisitNot(UnaryOperation* expr);

   // Dispatched from VisitBinaryOperation.
   void VisitComma(BinaryOperation* expr);
   void VisitLogicalExpression(BinaryOperation* expr);
   void VisitArithmeticExpression(BinaryOperation* expr);

   // Dispatched from VisitForInStatement.
   void VisitForInAssignment(Expression* expr, Node* value,
                             BailoutId bailout_id);
   void VisitForInBody(ForInStatement* stmt);

   // Dispatched from VisitClassLiteral.
   void VisitClassLiteralContents(ClassLiteral* expr);

   DEFINE_AST_VISITOR_SUBCLASS_MEMBERS();
   DISALLOW_COPY_AND_ASSIGN(AstGraphBuilder);
 };


 // The abstract execution environment for generated code consists of
 // parameter variables, local variables and the operand stack. The
 // environment will perform proper SSA-renaming of all tracked nodes
 // at split and merge points in the control flow. Internally all the
 // values are stored in one list using the following layout:
 //
 //  [parameters (+receiver)] [locals] [operand stack]
 //
 class AstGraphBuilder::Environment : public ZoneObject {
  public:
   Environment(AstGraphBuilder* builder, Scope* scope, Node* control_dependency);

   int parameters_count() const { return parameters_count_; }
   int locals_count() const { return locals_count_; }
   int context_chain_length() { return static_cast<int>(contexts_.size()); }
   int stack_height() {
     return static_cast<int>(values()->size()) - parameters_count_ -
            locals_count_;
   }

   // Operations on parameter or local variables.
   void Bind(Variable* variable, Node* node);
   Node* Lookup(Variable* variable);
   void MarkAllLocalsLive();

   // Operations on the context chain.
   Node* Context() const { return contexts_.back(); }
   void PushContext(Node* context) { contexts()->push_back(context); }
   void PopContext() { contexts()->pop_back(); }
   void TrimContextChain(int trim_to_length) {
     contexts()->resize(trim_to_length);
   }

   // Operations on the operand stack.
   void Push(Node* node) {
     values()->push_back(node);
   }
   Node* Top() {
     DCHECK(stack_height() > 0);
     return values()->back();
   }
   Node* Pop() {
     DCHECK(stack_height() > 0);
     Node* back = values()->back();
     values()->pop_back();
     return back;
   }

   // Direct mutations of the operand stack.
   void Poke(int depth, Node* node) {
     DCHECK(depth >= 0 && depth < stack_height());
     int index = static_cast<int>(values()->size()) - depth - 1;
     values()->at(index) = node;
   }
   Node* Peek(int depth) {
     DCHECK(depth >= 0 && depth < stack_height());
     int index = static_cast<int>(values()->size()) - depth - 1;
     return values()->at(index);
   }
   void Drop(int depth) {
     DCHECK(depth >= 0 && depth <= stack_height());
     values()->erase(values()->end() - depth, values()->end());
   }
   void TrimStack(int trim_to_height) {
     int depth = stack_height() - trim_to_height;
     DCHECK(depth >= 0 && depth <= stack_height());
     values()->erase(values()->end() - depth, values()->end());
   }

   // Preserve a checkpoint of the environment for the IR graph. Any
   // further mutation of the environment will not affect checkpoints.
   Node* Checkpoint(BailoutId ast_id, OutputFrameStateCombine combine =
                                          OutputFrameStateCombine::Ignore());

   // Control dependency tracked by this environment.
   Node* GetControlDependency() { return control_dependency_; }
   void UpdateControlDependency(Node* dependency) {
     control_dependency_ = dependency;
   }

   // Effect dependency tracked by this environment.
   Node* GetEffectDependency() { return effect_dependency_; }
   void UpdateEffectDependency(Node* dependency) {
     effect_dependency_ = dependency;
   }

   // Mark this environment as being unreachable.
   void MarkAsUnreachable() {
     UpdateControlDependency(builder()->jsgraph()->DeadControl());
   }
   bool IsMarkedAsUnreachable() {
     return GetControlDependency()->opcode() == IrOpcode::kDead;
   }

   // Merge another environment into this one.
   void Merge(Environment* other);

   // Copies this environment at a control-flow split point.
   Environment* CopyForConditional() { return Copy(); }

   // Copies this environment to a potentially unreachable control-flow point.
   Environment* CopyAsUnreachable() {
     Environment* env = Copy();
     env->MarkAsUnreachable();
     return env;
   }

   // Copies this environment at a loop header control-flow point.
   Environment* CopyForLoop(BitVector* assigned, bool is_osr = false) {
     PrepareForLoop(assigned, is_osr);
     return CopyAndShareLiveness();
   }

  private:
   AstGraphBuilder* builder_;
   int parameters_count_;
   int locals_count_;
   LivenessAnalyzerBlock* liveness_block_;
   NodeVector values_;
   NodeVector contexts_;
   Node* control_dependency_;
   Node* effect_dependency_;
   Node* parameters_node_;
   Node* locals_node_;
   Node* stack_node_;

   explicit Environment(Environment* copy);
   Environment* Copy() { return new (zone()) Environment(this); }
   Environment* CopyAndShareLiveness();
   void UpdateStateValues(Node** state_values, int offset, int count);
   void UpdateStateValuesWithCache(Node** state_values, int offset, int count);
   Zone* zone() const { return builder_->local_zone(); }
   Graph* graph() const { return builder_->graph(); }
   AstGraphBuilder* builder() const { return builder_; }
   CommonOperatorBuilder* common() { return builder_->common(); }
   NodeVector* values() { return &values_; }
   NodeVector* contexts() { return &contexts_; }
   LivenessAnalyzerBlock* liveness_block() { return liveness_block_; }

   // Prepare environment to be used as loop header.
   void PrepareForLoop(BitVector* assigned, bool is_osr = false);
 };

 }  // namespace compiler
 }  // namespace internal
 }  // namespace v8

 #endif  // V8_COMPILER_AST_GRAPH_BUILDER_H_
	// Copyright 2014 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_COMPILER_AST_GRAPH_BUILDER_H_
	#define V8_COMPILER_AST_GRAPH_BUILDER_H_

	#include "src/ast.h"
	#include "src/compiler/js-graph.h"
	#include "src/compiler/liveness-analyzer.h"
	#include "src/compiler/state-values-utils.h"

	namespace v8 {
	namespace internal {

	class BitVector;

	namespace compiler {

	class ControlBuilder;
	class Graph;
	class JSTypeFeedbackTable;
	class LoopAssignmentAnalysis;
	class LoopBuilder;
	class Node;

	// The AstGraphBuilder produces a high-level IR graph, based on an
	// underlying AST. The produced graph can either be compiled into a
	// stand-alone function or be wired into another graph for the purposes
	// of function inlining.
	class AstGraphBuilder : public AstVisitor {
	public:
	AstGraphBuilder(Zone* local_zone, CompilationInfo* info, JSGraph* jsgraph,
	LoopAssignmentAnalysis* loop_assignment = NULL,
	JSTypeFeedbackTable* js_type_feedback = NULL);

	// Creates a graph by visiting the entire AST.
	bool CreateGraph(bool constant_context, bool stack_check = true);

	// Helpers to create new control nodes.
	Node* NewIfTrue() { return NewNode(common()->IfTrue()); }
	Node* NewIfFalse() { return NewNode(common()->IfFalse()); }
	Node* NewMerge() { return NewNode(common()->Merge(1), true); }
	Node* NewLoop() { return NewNode(common()->Loop(1), true); }
	Node* NewBranch(Node* condition, BranchHint hint = BranchHint::kNone) {
	return NewNode(common()->Branch(hint), condition);
	}

	protected:
	#define DECLARE_VISIT(type) void Visit##type(type* node) override;
	// Visiting functions for AST nodes make this an AstVisitor.
	AST_NODE_LIST(DECLARE_VISIT)
	#undef DECLARE_VISIT

	// Visiting function for declarations list is overridden.
	void VisitDeclarations(ZoneList<Declaration> declarations) override;

	private:
	class AstContext;
	class AstEffectContext;
	class AstValueContext;
	class AstTestContext;
	class ContextScope;
	class ControlScope;
	class ControlScopeForBreakable;
	class ControlScopeForIteration;
	class ControlScopeForCatch;
	class ControlScopeForFinally;
	class Environment;
	friend class ControlBuilder;

	Zone* local_zone_;
	CompilationInfo* info_;
	JSGraph* jsgraph_;
	Environment* environment_;
	AstContext* ast_context_;

	// List of global declarations for functions and variables.
	ZoneVector<Handle<Object>> globals_;

	// Stack of control scopes currently entered by the visitor.
	ControlScope* execution_control_;

	// Stack of context objects pushed onto the chain by the visitor.
	ContextScope* execution_context_;

	// Nodes representing values in the activation record.
	SetOncePointer<Node> function_closure_;
	SetOncePointer<Node> function_context_;

	// Tracks how many try-blocks are currently entered.
	int try_nesting_level_;

	// Temporary storage for building node input lists.
	int input_buffer_size_;
	Node** input_buffer_;

	// Merge of all control nodes that exit the function body.
	Node* exit_control_;

	// Result of loop assignment analysis performed before graph creation.
	LoopAssignmentAnalysis* loop_assignment_analysis_;

	// Cache for StateValues nodes for frame states.
	StateValuesCache state_values_cache_;

	// Analyzer of local variable liveness.
	LivenessAnalyzer liveness_analyzer_;

	// Type feedback table.
	JSTypeFeedbackTable* js_type_feedback_;

	// Growth increment for the temporary buffer used to construct input lists to
	// new nodes.
	static const int kInputBufferSizeIncrement = 64;

	Zone* local_zone() const { return local_zone_; }
	Environment* environment() const { return environment_; }
	AstContext* ast_context() const { return ast_context_; }
	ControlScope* execution_control() const { return execution_control_; }
	ContextScope* execution_context() const { return execution_context_; }
	CommonOperatorBuilder* common() const { return jsgraph_->common(); }
	CompilationInfo* info() const { return info_; }
	LanguageMode language_mode() const;
	JSGraph* jsgraph() { return jsgraph_; }
	Graph* graph() { return jsgraph_->graph(); }
	Zone* graph_zone() { return graph()->zone(); }
	JSOperatorBuilder* javascript() { return jsgraph_->javascript(); }
	ZoneVector<Handle<Object>>* globals() { return &globals_; }
	Scope* current_scope() const;
	Node* current_context() const;
	Node* exit_control() const { return exit_control_; }
	LivenessAnalyzer* liveness_analyzer() { return &liveness_analyzer_; }

	void set_environment(Environment* env) { environment_ = env; }
	void set_ast_context(AstContext* ctx) { ast_context_ = ctx; }
	void set_execution_control(ControlScope* ctrl) { execution_control_ = ctrl; }
	void set_execution_context(ContextScope* ctx) { execution_context_ = ctx; }
	void set_exit_control(Node* exit) { exit_control_ = exit; }

	// Create the main graph body by visiting the AST.
	void CreateGraphBody(bool stack_check);

	// Create the node that represents the outer context of the function.
	void CreateFunctionContext(bool constant_context);

	// Get or create the node that represents the outer function closure.
	Node* GetFunctionClosure();

	// Node creation helpers.
	Node* NewNode(const Operator* op, bool incomplete = false) {
	return MakeNode(op, 0, static_cast<Node**>(NULL), incomplete);
	}

	Node* NewNode(const Operator* op, Node* n1) {
	return MakeNode(op, 1, &n1, false);
	}

	Node* NewNode(const Operator* op, Node* n1, Node* n2) {
	Node* buffer[] = {n1, n2};
	return MakeNode(op, arraysize(buffer), buffer, false);
	}

	Node* NewNode(const Operator* op, Node* n1, Node* n2, Node* n3) {
	Node* buffer[] = {n1, n2, n3};
	return MakeNode(op, arraysize(buffer), buffer, false);
	}

	Node* NewNode(const Operator* op, Node* n1, Node* n2, Node* n3, Node* n4) {
	Node* buffer[] = {n1, n2, n3, n4};
	return MakeNode(op, arraysize(buffer), buffer, false);
	}

	Node* NewNode(const Operator* op, Node* n1, Node* n2, Node* n3, Node* n4,
	Node* n5) {
	Node* buffer[] = {n1, n2, n3, n4, n5};
	return MakeNode(op, arraysize(buffer), buffer, false);
	}

	Node* NewNode(const Operator* op, Node* n1, Node* n2, Node* n3, Node* n4,
	Node* n5, Node* n6) {
	Node* nodes[] = {n1, n2, n3, n4, n5, n6};
	return MakeNode(op, arraysize(nodes), nodes, false);
	}

	Node* NewNode(const Operator* op, int value_input_count, Node** value_inputs,
	bool incomplete = false) {
	return MakeNode(op, value_input_count, value_inputs, incomplete);
	}

	// Creates a new Phi node having {count} input values.
	Node* NewPhi(int count, Node* input, Node* control);
	Node* NewEffectPhi(int count, Node* input, Node* control);

	Node* NewOuterContextParam();
	Node* NewCurrentContextOsrValue();

	// Helpers for merging control, effect or value dependencies.
	Node* MergeControl(Node* control, Node* other);
	Node* MergeEffect(Node* value, Node* other, Node* control);
	Node* MergeValue(Node* value, Node* other, Node* control);

	// The main node creation chokepoint. Adds context, frame state, effect,
	// and control dependencies depending on the operator.
	Node* MakeNode(const Operator* op, int value_input_count, Node** value_inputs,
	bool incomplete);

	// Helper to indicate a node exits the function body.
	void UpdateControlDependencyToLeaveFunction(Node* exit);

	// Builds deoptimization for a given node.
	void PrepareFrameState(
	Node* node, BailoutId ast_id,
	OutputFrameStateCombine combine = OutputFrameStateCombine::Ignore());
	void PrepareFrameStateAfterAndBefore(Node* node, BailoutId ast_id,
	OutputFrameStateCombine combine,
	Node* frame_state_before);

	BitVector* GetVariablesAssignedInLoop(IterationStatement* stmt);

	// Check if the given statement is an OSR entry.
	// If so, record the stack height into the compilation and return {true}.
	bool CheckOsrEntry(IterationStatement* stmt);

	// Computes local variable liveness and replaces dead variables in
	// frame states with the undefined values.
	void ClearNonLiveSlotsInFrameStates();

	// Helper to wrap a Handle<T> into a Unique<T>.
	template <class T>
	Unique<T> MakeUnique(Handle<T> object) {
	return Unique<T>::CreateUninitialized(object);
	}

	Node** EnsureInputBufferSize(int size);

	// Named and keyed loads require a VectorSlotPair for successful lowering.
	VectorSlotPair CreateVectorSlotPair(FeedbackVectorICSlot slot) const;

	// ===========================================================================
	// The following build methods all generate graph fragments and return one
	// resulting node. The operand stack height remains the same, variables and
	// other dependencies tracked by the environment might be mutated though.

	// Builder to create a receiver check for sloppy mode.
	Node* BuildPatchReceiverToGlobalProxy(Node* receiver);

	// Builders to create local function, script and block contexts.
	Node* BuildLocalFunctionContext(Node* context);
	Node* BuildLocalScriptContext(Scope* scope);
	Node* BuildLocalBlockContext(Scope* scope);

	// Builder to create an arguments object if it is used.
	Node* BuildArgumentsObject(Variable* arguments);

	// Builder to create an array of rest parameters if used
	Node* BuildRestArgumentsArray(Variable* rest, int index);

	// Builders for variable load and assignment.
	Node* BuildVariableAssignment(Variable* var, Node* value, Token::Value op,
	BailoutId bailout_id,
	OutputFrameStateCombine state_combine =
	OutputFrameStateCombine::Ignore());
	Node* BuildVariableDelete(Variable* var, BailoutId bailout_id,
	OutputFrameStateCombine state_combine);
	Node* BuildVariableLoad(Variable* var, BailoutId bailout_id,
	const VectorSlotPair& feedback,
	ContextualMode mode = CONTEXTUAL);

	// Builders for property loads and stores.
	Node* BuildKeyedLoad(Node* receiver, Node* key,
	const VectorSlotPair& feedback, TypeFeedbackId id);
	Node* BuildNamedLoad(Node* receiver, Handle<Name> name,
	const VectorSlotPair& feedback, TypeFeedbackId id,
	ContextualMode mode = NOT_CONTEXTUAL);
	Node* BuildKeyedStore(Node* receiver, Node* key, Node* value,
	TypeFeedbackId id);
	Node* BuildNamedStore(Node* receiver, Handle<Name>, Node* value,
	TypeFeedbackId id);

	// Builders for accessing the function context.
	Node* BuildLoadBuiltinsObject();
	Node* BuildLoadGlobalObject();
	Node* BuildLoadGlobalProxy();
	Node* BuildLoadClosure();
	Node* BuildLoadObjectField(Node* object, int offset);

	// Builders for accessing external references.
	Node* BuildLoadExternal(ExternalReference ref, MachineType type);
	Node* BuildStoreExternal(ExternalReference ref, MachineType type, Node* val);

	// Builders for automatic type conversion.
	Node* BuildToBoolean(Node* value);
	Node* BuildToName(Node* value, BailoutId bailout_id);

	// Builder for adding the [[HomeObject]] to a value if the value came from a
	// function literal and needs a home object. Do nothing otherwise.
	Node* BuildSetHomeObject(Node* value, Node* home_object, Expression* expr);

	// Builders for error reporting at runtime.
	Node* BuildThrowError(Node* exception, BailoutId bailout_id);
	Node* BuildThrowReferenceError(Variable* var, BailoutId bailout_id);
	Node* BuildThrowConstAssignError(BailoutId bailout_id);
	Node* BuildThrowStaticPrototypeError(BailoutId bailout_id);

	// Builders for dynamic hole-checks at runtime.
	Node* BuildHoleCheckSilent(Node* value, Node* for_hole, Node* not_hole);
	Node* BuildHoleCheckThrow(Node* value, Variable* var, Node* not_hole,
	BailoutId bailout_id);

	// Builders for conditional errors.
	Node* BuildThrowIfStaticPrototype(Node* name, BailoutId bailout_id);

	// Builders for non-local control flow.
	Node* BuildReturn(Node* return_value);
	Node* BuildThrow(Node* exception_value);

	// Builders for binary operations.
	Node* BuildBinaryOp(Node* left, Node* right, Token::Value op);

	// Process arguments to a call by popping {arity} elements off the operand
	// stack and build a call node using the given call operator.
	Node* ProcessArguments(const Operator* op, int arity);

	// ===========================================================================
	// The following visitation methods all recursively visit a subtree of the
	// underlying AST and extent the graph. The operand stack is mutated in a way
	// consistent with other compilers:
	// - Expressions pop operands and push result, depending on {AstContext}.
	// - Statements keep the operand stack balanced.

	// Visit statements.
	void VisitIfNotNull(Statement* stmt);

	// Visit expressions.
	void Visit(Expression* expr);
	void VisitForTest(Expression* expr);
	void VisitForEffect(Expression* expr);
	void VisitForValue(Expression* expr);
	void VisitForValueOrNull(Expression* expr);
	void VisitForValueOrTheHole(Expression* expr);
	void VisitForValues(ZoneList<Expression> exprs);

	// Common for all IterationStatement bodies.
	void VisitIterationBody(IterationStatement* stmt, LoopBuilder* loop);

	// Dispatched from VisitCallRuntime.
	void VisitCallJSRuntime(CallRuntime* expr);

	// Dispatched from VisitUnaryOperation.
	void VisitDelete(UnaryOperation* expr);
	void VisitVoid(UnaryOperation* expr);
	void VisitTypeof(UnaryOperation* expr);
	void VisitNot(UnaryOperation* expr);

	// Dispatched from VisitBinaryOperation.
	void VisitComma(BinaryOperation* expr);
	void VisitLogicalExpression(BinaryOperation* expr);
	void VisitArithmeticExpression(BinaryOperation* expr);

	// Dispatched from VisitForInStatement.
	void VisitForInAssignment(Expression* expr, Node* value,
	BailoutId bailout_id);
	void VisitForInBody(ForInStatement* stmt);

	// Dispatched from VisitClassLiteral.
	void VisitClassLiteralContents(ClassLiteral* expr);

	DEFINE_AST_VISITOR_SUBCLASS_MEMBERS();
	DISALLOW_COPY_AND_ASSIGN(AstGraphBuilder);
	};


	// The abstract execution environment for generated code consists of
	// parameter variables, local variables and the operand stack. The
	// environment will perform proper SSA-renaming of all tracked nodes
	// at split and merge points in the control flow. Internally all the
	// values are stored in one list using the following layout:
	//
	// [parameters (+receiver)] [locals] [operand stack]
	//
	class AstGraphBuilder::Environment : public ZoneObject {
	public:
	Environment(AstGraphBuilder* builder, Scope* scope, Node* control_dependency);

	int parameters_count() const { return parameters_count_; }
	int locals_count() const { return locals_count_; }
	int context_chain_length() { return static_cast<int>(contexts_.size()); }
	int stack_height() {
	return static_cast<int>(values()->size()) - parameters_count_ -
	locals_count_;
	}

	// Operations on parameter or local variables.
	void Bind(Variable* variable, Node* node);
	Node* Lookup(Variable* variable);
	void MarkAllLocalsLive();

	// Operations on the context chain.
	Node* Context() const { return contexts_.back(); }
	void PushContext(Node* context) { contexts()->push_back(context); }
	void PopContext() { contexts()->pop_back(); }
	void TrimContextChain(int trim_to_length) {
	contexts()->resize(trim_to_length);
	}

	// Operations on the operand stack.
	void Push(Node* node) {
	values()->push_back(node);
	}
	Node* Top() {
	DCHECK(stack_height() > 0);
	return values()->back();
	}
	Node* Pop() {
	DCHECK(stack_height() > 0);
	Node* back = values()->back();
	values()->pop_back();
	return back;
	}

	// Direct mutations of the operand stack.
	void Poke(int depth, Node* node) {
	DCHECK(depth >= 0 && depth < stack_height());
	int index = static_cast<int>(values()->size()) - depth - 1;
	values()->at(index) = node;
	}
	Node* Peek(int depth) {
	DCHECK(depth >= 0 && depth < stack_height());
	int index = static_cast<int>(values()->size()) - depth - 1;
	return values()->at(index);
	}
	void Drop(int depth) {
	DCHECK(depth >= 0 && depth <= stack_height());
	values()->erase(values()->end() - depth, values()->end());
	}
	void TrimStack(int trim_to_height) {
	int depth = stack_height() - trim_to_height;
	DCHECK(depth >= 0 && depth <= stack_height());
	values()->erase(values()->end() - depth, values()->end());
	}

	// Preserve a checkpoint of the environment for the IR graph. Any
	// further mutation of the environment will not affect checkpoints.
	Node* Checkpoint(BailoutId ast_id, OutputFrameStateCombine combine =
	OutputFrameStateCombine::Ignore());

	// Control dependency tracked by this environment.
	Node* GetControlDependency() { return control_dependency_; }
	void UpdateControlDependency(Node* dependency) {
	control_dependency_ = dependency;
	}

	// Effect dependency tracked by this environment.
	Node* GetEffectDependency() { return effect_dependency_; }
	void UpdateEffectDependency(Node* dependency) {
	effect_dependency_ = dependency;
	}

	// Mark this environment as being unreachable.
	void MarkAsUnreachable() {
	UpdateControlDependency(builder()->jsgraph()->DeadControl());
	}
	bool IsMarkedAsUnreachable() {
	return GetControlDependency()->opcode() == IrOpcode::kDead;
	}

	// Merge another environment into this one.
	void Merge(Environment* other);

	// Copies this environment at a control-flow split point.
	Environment* CopyForConditional() { return Copy(); }

	// Copies this environment to a potentially unreachable control-flow point.
	Environment* CopyAsUnreachable() {
	Environment* env = Copy();
	env->MarkAsUnreachable();
	return env;
	}

	// Copies this environment at a loop header control-flow point.
	Environment* CopyForLoop(BitVector* assigned, bool is_osr = false) {
	PrepareForLoop(assigned, is_osr);
	return CopyAndShareLiveness();
	}

	private:
	AstGraphBuilder* builder_;
	int parameters_count_;
	int locals_count_;
	LivenessAnalyzerBlock* liveness_block_;
	NodeVector values_;
	NodeVector contexts_;
	Node* control_dependency_;
	Node* effect_dependency_;
	Node* parameters_node_;
	Node* locals_node_;
	Node* stack_node_;

	explicit Environment(Environment* copy);
	Environment* Copy() { return new (zone()) Environment(this); }
	Environment* CopyAndShareLiveness();
	void UpdateStateValues(Node** state_values, int offset, int count);
	void UpdateStateValuesWithCache(Node** state_values, int offset, int count);
	Zone* zone() const { return builder_->local_zone(); }
	Graph* graph() const { return builder_->graph(); }
	AstGraphBuilder* builder() const { return builder_; }
	CommonOperatorBuilder* common() { return builder_->common(); }
	NodeVector* values() { return &values_; }
	NodeVector* contexts() { return &contexts_; }
	LivenessAnalyzerBlock* liveness_block() { return liveness_block_; }

	// Prepare environment to be used as loop header.
	void PrepareForLoop(BitVector* assigned, bool is_osr = false);
	};

	} // namespace compiler
	} // namespace internal
	} // namespace v8

	#endif // V8_COMPILER_AST_GRAPH_BUILDER_H_