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

 // Copyright 2015 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_BYTECODE_GRAPH_BUILDER_H_
 #define V8_COMPILER_BYTECODE_GRAPH_BUILDER_H_

 #include "src/compiler/bytecode-analysis.h"
 #include "src/compiler/js-graph.h"
 #include "src/compiler/liveness-analyzer.h"
 #include "src/compiler/state-values-utils.h"
 #include "src/interpreter/bytecode-array-iterator.h"
 #include "src/interpreter/bytecode-flags.h"
 #include "src/interpreter/bytecodes.h"
 #include "src/source-position-table.h"

 namespace v8 {
 namespace internal {
 namespace compiler {

 class SourcePositionTable;

 // The BytecodeGraphBuilder produces a high-level IR graph based on
 // interpreter bytecodes.
 class BytecodeGraphBuilder {
  public:
   BytecodeGraphBuilder(Zone* local_zone, Handle<SharedFunctionInfo> shared,
                        Handle<TypeFeedbackVector> feedback_vector,
                        BailoutId osr_ast_id, JSGraph* jsgraph,
                        float invocation_frequency,
                        SourcePositionTable* source_positions,
                        int inlining_id = SourcePosition::kNotInlined);

   // Creates a graph by visiting bytecodes.
   bool CreateGraph(bool stack_check = true);

  private:
   class Environment;

   void VisitBytecodes(bool stack_check);

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

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

   // Get or create the node that represents the incoming new target value.
   Node* GetNewTarget();

   // Builder for loading the a native context field.
   Node* BuildLoadNativeContextField(int index);

   // Helper function for creating a pair containing type feedback vector and
   // a feedback slot.
   VectorSlotPair CreateVectorSlotPair(int slot_id);

   void set_environment(Environment* env) { environment_ = env; }
   const Environment* environment() const { return environment_; }
   Environment* environment() { return environment_; }

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

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

   // 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);
   }

   // 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);

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

   Node** EnsureInputBufferSize(int size);

   Node* ProcessCallArguments(const Operator* call_op, Node* callee,
                              interpreter::Register receiver, size_t arity);
   Node* ProcessCallNewArguments(const Operator* call_new_op, Node* callee,
                                 Node* new_target,
                                 interpreter::Register first_arg, size_t arity);
   Node* ProcessCallRuntimeArguments(const Operator* call_runtime_op,
                                     interpreter::Register first_arg,
                                     size_t arity);

   // Prepare information for eager deoptimization. This information is carried
   // by dedicated {Checkpoint} nodes that are wired into the effect chain.
   // Conceptually this frame state is "before" a given operation.
   void PrepareEagerCheckpoint();

   // Prepare information for lazy deoptimization. This information is attached
   // to the given node and the output value produced by the node is combined.
   // Conceptually this frame state is "after" a given operation.
   void PrepareFrameState(Node* node, OutputFrameStateCombine combine);

   void BuildCreateArguments(CreateArgumentsType type);
   Node* BuildLoadGlobal(Handle<Name> name, uint32_t feedback_slot_index,
                         TypeofMode typeof_mode);
   void BuildStoreGlobal(LanguageMode language_mode);
   void BuildNamedStore(LanguageMode language_mode);
   void BuildKeyedStore(LanguageMode language_mode);
   void BuildLdaLookupSlot(TypeofMode typeof_mode);
   void BuildLdaLookupContextSlot(TypeofMode typeof_mode);
   void BuildLdaLookupGlobalSlot(TypeofMode typeof_mode);
   void BuildStaLookupSlot(LanguageMode language_mode);
   void BuildCall(TailCallMode tail_call_mode,
                  ConvertReceiverMode receiver_hint);
   void BuildThrow();
   void BuildBinaryOp(const Operator* op);
   void BuildBinaryOpWithImmediate(const Operator* op);
   void BuildCompareOp(const Operator* op);
   void BuildDelete(LanguageMode language_mode);
   void BuildCastOperator(const Operator* op);
   void BuildForInPrepare();
   void BuildForInNext();
   void BuildInvokeIntrinsic();

   // Check the context chain for extensions, for lookup fast paths.
   Environment* CheckContextExtensions(uint32_t depth);

   // Helper function to create binary operation hint from the recorded
   // type feedback.
   BinaryOperationHint GetBinaryOperationHint(int operand_index);

   // Helper function to create compare operation hint from the recorded
   // type feedback.
   CompareOperationHint GetCompareOperationHint();

   // Helper function to compute call frequency from the recorded type
   // feedback.
   float ComputeCallFrequency(int slot_id) const;

   // Control flow plumbing.
   void BuildJump();
   void BuildJumpIf(Node* condition);
   void BuildJumpIfNot(Node* condition);
   void BuildJumpIfEqual(Node* comperand);
   void BuildJumpIfTrue();
   void BuildJumpIfFalse();
   void BuildJumpIfToBooleanTrue();
   void BuildJumpIfToBooleanFalse();
   void BuildJumpIfNotHole();
   void BuildJumpIfJSReceiver();

   // Simulates control flow by forward-propagating environments.
   void MergeIntoSuccessorEnvironment(int target_offset);
   void BuildLoopHeaderEnvironment(int current_offset);
   void SwitchToMergeEnvironment(int current_offset);

   // Simulates control flow that exits the function body.
   void MergeControlToLeaveFunction(Node* exit);

   // Builds entry points that are used by OSR deconstruction.
   void BuildOSRLoopEntryPoint(int current_offset);
   void BuildOSRNormalEntryPoint();

   // Builds loop exit nodes for every exited loop between the current bytecode
   // offset and {target_offset}.
   void BuildLoopExitsForBranch(int target_offset);
   void BuildLoopExitsForFunctionExit();
   void BuildLoopExitsUntilLoop(int loop_offset);

   // Simulates entry and exit of exception handlers.
   void EnterAndExitExceptionHandlers(int current_offset);

   // Update the current position of the {SourcePositionTable} to that of the
   // bytecode at {offset}, if any.
   void UpdateCurrentSourcePosition(SourcePositionTableIterator* it, int offset);

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

   // An abstract representation for an exception handler that is being
   // entered and exited while the graph builder is iterating over the
   // underlying bytecode. The exception handlers within the bytecode are
   // well scoped, hence will form a stack during iteration.
   struct ExceptionHandler {
     int start_offset_;      // Start offset of the handled area in the bytecode.
     int end_offset_;        // End offset of the handled area in the bytecode.
     int handler_offset_;    // Handler entry offset within the bytecode.
     int context_register_;  // Index of register holding handler context.
   };

   // Field accessors
   Graph* graph() const { return jsgraph_->graph(); }
   CommonOperatorBuilder* common() const { return jsgraph_->common(); }
   Zone* graph_zone() const { return graph()->zone(); }
   JSGraph* jsgraph() const { return jsgraph_; }
   JSOperatorBuilder* javascript() const { return jsgraph_->javascript(); }
   SimplifiedOperatorBuilder* simplified() const {
     return jsgraph_->simplified();
   }
   Zone* local_zone() const { return local_zone_; }
   const Handle<BytecodeArray>& bytecode_array() const {
     return bytecode_array_;
   }
   const Handle<HandlerTable>& exception_handler_table() const {
     return exception_handler_table_;
   }
   const Handle<TypeFeedbackVector>& feedback_vector() const {
     return feedback_vector_;
   }
   const FrameStateFunctionInfo* frame_state_function_info() const {
     return frame_state_function_info_;
   }

   const interpreter::BytecodeArrayIterator& bytecode_iterator() const {
     return *bytecode_iterator_;
   }

   void set_bytecode_iterator(
       const interpreter::BytecodeArrayIterator* bytecode_iterator) {
     bytecode_iterator_ = bytecode_iterator;
   }

   const BytecodeAnalysis* bytecode_analysis() const {
     return bytecode_analysis_;
   }

   void set_bytecode_analysis(const BytecodeAnalysis* bytecode_analysis) {
     bytecode_analysis_ = bytecode_analysis;
   }

   bool IsLivenessAnalysisEnabled() const {
     return this->is_liveness_analysis_enabled_;
   }

 #define DECLARE_VISIT_BYTECODE(name, ...) void Visit##name();
   BYTECODE_LIST(DECLARE_VISIT_BYTECODE)
 #undef DECLARE_VISIT_BYTECODE

   Zone* local_zone_;
   JSGraph* jsgraph_;
   float const invocation_frequency_;
   Handle<BytecodeArray> bytecode_array_;
   Handle<HandlerTable> exception_handler_table_;
   Handle<TypeFeedbackVector> feedback_vector_;
   const FrameStateFunctionInfo* frame_state_function_info_;
   const interpreter::BytecodeArrayIterator* bytecode_iterator_;
   const BytecodeAnalysis* bytecode_analysis_;
   Environment* environment_;
   BailoutId osr_ast_id_;
   int osr_loop_offset_;

   // Merge environments are snapshots of the environment at points where the
   // control flow merges. This models a forward data flow propagation of all
   // values from all predecessors of the merge in question.
   ZoneMap<int, Environment*> merge_environments_;

   // Exception handlers currently entered by the iteration.
   ZoneStack<ExceptionHandler> exception_handlers_;
   int current_exception_handler_;

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

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

   // Control nodes that exit the function body.
   ZoneVector<Node*> exit_controls_;

   bool const is_liveness_analysis_enabled_;

   StateValuesCache state_values_cache_;

   // The source position table, to be populated.
   SourcePositionTable* source_positions_;

   SourcePosition const start_position_;

   static int const kBinaryOperationHintIndex = 1;
   static int const kCountOperationHintIndex = 0;
   static int const kBinaryOperationSmiHintIndex = 2;

   DISALLOW_COPY_AND_ASSIGN(BytecodeGraphBuilder);
 };

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

 #endif  // V8_COMPILER_BYTECODE_GRAPH_BUILDER_H_
	// Copyright 2015 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_BYTECODE_GRAPH_BUILDER_H_
	#define V8_COMPILER_BYTECODE_GRAPH_BUILDER_H_

	#include "src/compiler/bytecode-analysis.h"
	#include "src/compiler/js-graph.h"
	#include "src/compiler/liveness-analyzer.h"
	#include "src/compiler/state-values-utils.h"
	#include "src/interpreter/bytecode-array-iterator.h"
	#include "src/interpreter/bytecode-flags.h"
	#include "src/interpreter/bytecodes.h"
	#include "src/source-position-table.h"

	namespace v8 {
	namespace internal {
	namespace compiler {

	class SourcePositionTable;

	// The BytecodeGraphBuilder produces a high-level IR graph based on
	// interpreter bytecodes.
	class BytecodeGraphBuilder {
	public:
	BytecodeGraphBuilder(Zone* local_zone, Handle<SharedFunctionInfo> shared,
	Handle<TypeFeedbackVector> feedback_vector,
	BailoutId osr_ast_id, JSGraph* jsgraph,
	float invocation_frequency,
	SourcePositionTable* source_positions,
	int inlining_id = SourcePosition::kNotInlined);

	// Creates a graph by visiting bytecodes.
	bool CreateGraph(bool stack_check = true);

	private:
	class Environment;

	void VisitBytecodes(bool stack_check);

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

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

	// Get or create the node that represents the incoming new target value.
	Node* GetNewTarget();

	// Builder for loading the a native context field.
	Node* BuildLoadNativeContextField(int index);

	// Helper function for creating a pair containing type feedback vector and
	// a feedback slot.
	VectorSlotPair CreateVectorSlotPair(int slot_id);

	void set_environment(Environment* env) { environment_ = env; }
	const Environment* environment() const { return environment_; }
	Environment* environment() { return environment_; }

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

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

	// 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);
	}

	// 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);

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

	Node** EnsureInputBufferSize(int size);

	Node* ProcessCallArguments(const Operator* call_op, Node* callee,
	interpreter::Register receiver, size_t arity);
	Node* ProcessCallNewArguments(const Operator* call_new_op, Node* callee,
	Node* new_target,
	interpreter::Register first_arg, size_t arity);
	Node* ProcessCallRuntimeArguments(const Operator* call_runtime_op,
	interpreter::Register first_arg,
	size_t arity);

	// Prepare information for eager deoptimization. This information is carried
	// by dedicated {Checkpoint} nodes that are wired into the effect chain.
	// Conceptually this frame state is "before" a given operation.
	void PrepareEagerCheckpoint();

	// Prepare information for lazy deoptimization. This information is attached
	// to the given node and the output value produced by the node is combined.
	// Conceptually this frame state is "after" a given operation.
	void PrepareFrameState(Node* node, OutputFrameStateCombine combine);

	void BuildCreateArguments(CreateArgumentsType type);
	Node* BuildLoadGlobal(Handle<Name> name, uint32_t feedback_slot_index,
	TypeofMode typeof_mode);
	void BuildStoreGlobal(LanguageMode language_mode);
	void BuildNamedStore(LanguageMode language_mode);
	void BuildKeyedStore(LanguageMode language_mode);
	void BuildLdaLookupSlot(TypeofMode typeof_mode);
	void BuildLdaLookupContextSlot(TypeofMode typeof_mode);
	void BuildLdaLookupGlobalSlot(TypeofMode typeof_mode);
	void BuildStaLookupSlot(LanguageMode language_mode);
	void BuildCall(TailCallMode tail_call_mode,
	ConvertReceiverMode receiver_hint);
	void BuildThrow();
	void BuildBinaryOp(const Operator* op);
	void BuildBinaryOpWithImmediate(const Operator* op);
	void BuildCompareOp(const Operator* op);
	void BuildDelete(LanguageMode language_mode);
	void BuildCastOperator(const Operator* op);
	void BuildForInPrepare();
	void BuildForInNext();
	void BuildInvokeIntrinsic();

	// Check the context chain for extensions, for lookup fast paths.
	Environment* CheckContextExtensions(uint32_t depth);

	// Helper function to create binary operation hint from the recorded
	// type feedback.
	BinaryOperationHint GetBinaryOperationHint(int operand_index);

	// Helper function to create compare operation hint from the recorded
	// type feedback.
	CompareOperationHint GetCompareOperationHint();

	// Helper function to compute call frequency from the recorded type
	// feedback.
	float ComputeCallFrequency(int slot_id) const;

	// Control flow plumbing.
	void BuildJump();
	void BuildJumpIf(Node* condition);
	void BuildJumpIfNot(Node* condition);
	void BuildJumpIfEqual(Node* comperand);
	void BuildJumpIfTrue();
	void BuildJumpIfFalse();
	void BuildJumpIfToBooleanTrue();
	void BuildJumpIfToBooleanFalse();
	void BuildJumpIfNotHole();
	void BuildJumpIfJSReceiver();

	// Simulates control flow by forward-propagating environments.
	void MergeIntoSuccessorEnvironment(int target_offset);
	void BuildLoopHeaderEnvironment(int current_offset);
	void SwitchToMergeEnvironment(int current_offset);

	// Simulates control flow that exits the function body.
	void MergeControlToLeaveFunction(Node* exit);

	// Builds entry points that are used by OSR deconstruction.
	void BuildOSRLoopEntryPoint(int current_offset);
	void BuildOSRNormalEntryPoint();

	// Builds loop exit nodes for every exited loop between the current bytecode
	// offset and {target_offset}.
	void BuildLoopExitsForBranch(int target_offset);
	void BuildLoopExitsForFunctionExit();
	void BuildLoopExitsUntilLoop(int loop_offset);

	// Simulates entry and exit of exception handlers.
	void EnterAndExitExceptionHandlers(int current_offset);

	// Update the current position of the {SourcePositionTable} to that of the
	// bytecode at {offset}, if any.
	void UpdateCurrentSourcePosition(SourcePositionTableIterator* it, int offset);

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

	// An abstract representation for an exception handler that is being
	// entered and exited while the graph builder is iterating over the
	// underlying bytecode. The exception handlers within the bytecode are
	// well scoped, hence will form a stack during iteration.
	struct ExceptionHandler {
	int start_offset_; // Start offset of the handled area in the bytecode.
	int end_offset_; // End offset of the handled area in the bytecode.
	int handler_offset_; // Handler entry offset within the bytecode.
	int context_register_; // Index of register holding handler context.
	};

	// Field accessors
	Graph* graph() const { return jsgraph_->graph(); }
	CommonOperatorBuilder* common() const { return jsgraph_->common(); }
	Zone* graph_zone() const { return graph()->zone(); }
	JSGraph* jsgraph() const { return jsgraph_; }
	JSOperatorBuilder* javascript() const { return jsgraph_->javascript(); }
	SimplifiedOperatorBuilder* simplified() const {
	return jsgraph_->simplified();
	}
	Zone* local_zone() const { return local_zone_; }
	const Handle<BytecodeArray>& bytecode_array() const {
	return bytecode_array_;
	}
	const Handle<HandlerTable>& exception_handler_table() const {
	return exception_handler_table_;
	}
	const Handle<TypeFeedbackVector>& feedback_vector() const {
	return feedback_vector_;
	}
	const FrameStateFunctionInfo* frame_state_function_info() const {
	return frame_state_function_info_;
	}

	const interpreter::BytecodeArrayIterator& bytecode_iterator() const {
	return *bytecode_iterator_;
	}

	void set_bytecode_iterator(
	const interpreter::BytecodeArrayIterator* bytecode_iterator) {
	bytecode_iterator_ = bytecode_iterator;
	}

	const BytecodeAnalysis* bytecode_analysis() const {
	return bytecode_analysis_;
	}

	void set_bytecode_analysis(const BytecodeAnalysis* bytecode_analysis) {
	bytecode_analysis_ = bytecode_analysis;
	}

	bool IsLivenessAnalysisEnabled() const {
	return this->is_liveness_analysis_enabled_;
	}

	#define DECLARE_VISIT_BYTECODE(name, ...) void Visit##name();
	BYTECODE_LIST(DECLARE_VISIT_BYTECODE)
	#undef DECLARE_VISIT_BYTECODE

	Zone* local_zone_;
	JSGraph* jsgraph_;
	float const invocation_frequency_;
	Handle<BytecodeArray> bytecode_array_;
	Handle<HandlerTable> exception_handler_table_;
	Handle<TypeFeedbackVector> feedback_vector_;
	const FrameStateFunctionInfo* frame_state_function_info_;
	const interpreter::BytecodeArrayIterator* bytecode_iterator_;
	const BytecodeAnalysis* bytecode_analysis_;
	Environment* environment_;
	BailoutId osr_ast_id_;
	int osr_loop_offset_;

	// Merge environments are snapshots of the environment at points where the
	// control flow merges. This models a forward data flow propagation of all
	// values from all predecessors of the merge in question.
	ZoneMap<int, Environment*> merge_environments_;

	// Exception handlers currently entered by the iteration.
	ZoneStack<ExceptionHandler> exception_handlers_;
	int current_exception_handler_;

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

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

	// Control nodes that exit the function body.
	ZoneVector<Node*> exit_controls_;

	bool const is_liveness_analysis_enabled_;

	StateValuesCache state_values_cache_;

	// The source position table, to be populated.
	SourcePositionTable* source_positions_;

	SourcePosition const start_position_;

	static int const kBinaryOperationHintIndex = 1;
	static int const kCountOperationHintIndex = 0;
	static int const kBinaryOperationSmiHintIndex = 2;

	DISALLOW_COPY_AND_ASSIGN(BytecodeGraphBuilder);
	};

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

	#endif // V8_COMPILER_BYTECODE_GRAPH_BUILDER_H_