src/v8/src/compiler/escape-analysis.h - cobalt - Git at Google

 // Copyright 2017 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_ESCAPE_ANALYSIS_H_
 #define V8_COMPILER_ESCAPE_ANALYSIS_H_

 #include "src/base/functional.h"
 #include "src/common/globals.h"
 #include "src/compiler/graph-reducer.h"
 #include "src/compiler/js-graph.h"
 #include "src/compiler/persistent-map.h"
 #include "src/objects/name.h"

 namespace v8 {
 namespace internal {

 class TickCounter;

 namespace compiler {

 class CommonOperatorBuilder;
 class VariableTracker;
 class EscapeAnalysisTracker;

 // {EffectGraphReducer} reduces up to a fixed point. It distinguishes changes to
 // the effect output of a node from changes to the value output to reduce the
 // number of revisitations.
 class EffectGraphReducer {
  public:
   class Reduction {
    public:
     bool value_changed() const { return value_changed_; }
     void set_value_changed() { value_changed_ = true; }
     bool effect_changed() const { return effect_changed_; }
     void set_effect_changed() { effect_changed_ = true; }

    private:
     bool value_changed_ = false;
     bool effect_changed_ = false;
   };

   EffectGraphReducer(Graph* graph,
                      std::function<void(Node*, Reduction*)> reduce,
                      TickCounter* tick_counter, Zone* zone);

   void ReduceGraph() { ReduceFrom(graph_->end()); }

   // Mark node for revisitation.
   void Revisit(Node* node);

   // Add a new root node to start reduction from. This is useful if the reducer
   // adds nodes that are not yet reachable, but should already be considered
   // part of the graph.
   void AddRoot(Node* node) {
     DCHECK_EQ(State::kUnvisited, state_.Get(node));
     state_.Set(node, State::kRevisit);
     revisit_.push(node);
   }

   bool Complete() { return stack_.empty() && revisit_.empty(); }

   TickCounter* tick_counter() const { return tick_counter_; }

  private:
   struct NodeState {
     Node* node;
     int input_index;
   };
   void ReduceFrom(Node* node);
   enum class State : uint8_t { kUnvisited = 0, kRevisit, kOnStack, kVisited };
   const uint8_t kNumStates = static_cast<uint8_t>(State::kVisited) + 1;
   Graph* graph_;
   NodeMarker<State> state_;
   ZoneStack<Node*> revisit_;
   ZoneStack<NodeState> stack_;
   std::function<void(Node*, Reduction*)> reduce_;
   TickCounter* const tick_counter_;
 };

 // A variable is an abstract storage location, which is lowered to SSA values
 // and phi nodes by {VariableTracker}.
 class Variable {
  public:
   Variable() : id_(kInvalid) {}
   bool operator==(Variable other) const { return id_ == other.id_; }
   bool operator!=(Variable other) const { return id_ != other.id_; }
   bool operator<(Variable other) const { return id_ < other.id_; }
   static Variable Invalid() { return Variable(kInvalid); }
   friend V8_INLINE size_t hash_value(Variable v) {
     return base::hash_value(v.id_);
   }
   friend std::ostream& operator<<(std::ostream& os, Variable var) {
     return os << var.id_;
   }

  private:
   using Id = int;
   explicit Variable(Id id) : id_(id) {}
   Id id_;
   static const Id kInvalid = -1;

   friend class VariableTracker;
 };

 // An object that can track the nodes in the graph whose current reduction
 // depends on the value of the object.
 class Dependable : public ZoneObject {
  public:
   explicit Dependable(Zone* zone) : dependants_(zone) {}
   void AddDependency(Node* node) { dependants_.push_back(node); }
   void RevisitDependants(EffectGraphReducer* reducer) {
     for (Node* node : dependants_) {
       reducer->Revisit(node);
     }
     dependants_.clear();
   }

  private:
   ZoneVector<Node*> dependants_;
 };

 // A virtual object represents an allocation site and tracks the Variables
 // associated with its fields as well as its global escape status.
 class VirtualObject : public Dependable {
  public:
   using Id = uint32_t;
   using const_iterator = ZoneVector<Variable>::const_iterator;
   VirtualObject(VariableTracker* var_states, Id id, int size);
   Maybe<Variable> FieldAt(int offset) const {
     CHECK(IsAligned(offset, kTaggedSize));
     CHECK(!HasEscaped());
     if (offset >= size()) {
       // TODO(tebbi): Reading out-of-bounds can only happen in unreachable
       // code. In this case, we have to mark the object as escaping to avoid
       // dead nodes in the graph. This is a workaround that should be removed
       // once we can handle dead nodes everywhere.
       return Nothing<Variable>();
     }
     return Just(fields_.at(offset / kTaggedSize));
   }
   Id id() const { return id_; }
   int size() const { return static_cast<int>(kTaggedSize * fields_.size()); }
   // Escaped might mean that the object escaped to untracked memory or that it
   // is used in an operation that requires materialization.
   void SetEscaped() { escaped_ = true; }
   bool HasEscaped() const { return escaped_; }
   const_iterator begin() const { return fields_.begin(); }
   const_iterator end() const { return fields_.end(); }

  private:
   bool escaped_ = false;
   Id id_;
   ZoneVector<Variable> fields_;
 };

 class EscapeAnalysisResult {
  public:
   explicit EscapeAnalysisResult(EscapeAnalysisTracker* tracker)
       : tracker_(tracker) {}

   const VirtualObject* GetVirtualObject(Node* node);
   Node* GetVirtualObjectField(const VirtualObject* vobject, int field,
                               Node* effect);
   Node* GetReplacementOf(Node* node);

  private:
   EscapeAnalysisTracker* tracker_;
 };

 class V8_EXPORT_PRIVATE EscapeAnalysis final
     : public NON_EXPORTED_BASE(EffectGraphReducer) {
  public:
   EscapeAnalysis(JSGraph* jsgraph, TickCounter* tick_counter, Zone* zone);

   EscapeAnalysisResult analysis_result() {
     DCHECK(Complete());
     return EscapeAnalysisResult(tracker_);
   }

  private:
   void Reduce(Node* node, Reduction* reduction);
   JSGraph* jsgraph() { return jsgraph_; }
   Isolate* isolate() const { return jsgraph_->isolate(); }
   EscapeAnalysisTracker* tracker_;
   JSGraph* jsgraph_;
 };

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

 #endif  // V8_COMPILER_ESCAPE_ANALYSIS_H_
	// Copyright 2017 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_ESCAPE_ANALYSIS_H_
	#define V8_COMPILER_ESCAPE_ANALYSIS_H_

	#include "src/base/functional.h"
	#include "src/common/globals.h"
	#include "src/compiler/graph-reducer.h"
	#include "src/compiler/js-graph.h"
	#include "src/compiler/persistent-map.h"
	#include "src/objects/name.h"

	namespace v8 {
	namespace internal {

	class TickCounter;

	namespace compiler {

	class CommonOperatorBuilder;
	class VariableTracker;
	class EscapeAnalysisTracker;

	// {EffectGraphReducer} reduces up to a fixed point. It distinguishes changes to
	// the effect output of a node from changes to the value output to reduce the
	// number of revisitations.
	class EffectGraphReducer {
	public:
	class Reduction {
	public:
	bool value_changed() const { return value_changed_; }
	void set_value_changed() { value_changed_ = true; }
	bool effect_changed() const { return effect_changed_; }
	void set_effect_changed() { effect_changed_ = true; }

	private:
	bool value_changed_ = false;
	bool effect_changed_ = false;
	};

	EffectGraphReducer(Graph* graph,
	std::function<void(Node, Reduction)> reduce,
	TickCounter* tick_counter, Zone* zone);

	void ReduceGraph() { ReduceFrom(graph_->end()); }

	// Mark node for revisitation.
	void Revisit(Node* node);

	// Add a new root node to start reduction from. This is useful if the reducer
	// adds nodes that are not yet reachable, but should already be considered
	// part of the graph.
	void AddRoot(Node* node) {
	DCHECK_EQ(State::kUnvisited, state_.Get(node));
	state_.Set(node, State::kRevisit);
	revisit_.push(node);
	}

	bool Complete() { return stack_.empty() && revisit_.empty(); }

	TickCounter* tick_counter() const { return tick_counter_; }

	private:
	struct NodeState {
	Node* node;
	int input_index;
	};
	void ReduceFrom(Node* node);
	enum class State : uint8_t { kUnvisited = 0, kRevisit, kOnStack, kVisited };
	const uint8_t kNumStates = static_cast<uint8_t>(State::kVisited) + 1;
	Graph* graph_;
	NodeMarker<State> state_;
	ZoneStack<Node*> revisit_;
	ZoneStack<NodeState> stack_;
	std::function<void(Node, Reduction)> reduce_;
	TickCounter* const tick_counter_;
	};

	// A variable is an abstract storage location, which is lowered to SSA values
	// and phi nodes by {VariableTracker}.
	class Variable {
	public:
	Variable() : id_(kInvalid) {}
	bool operator==(Variable other) const { return id_ == other.id_; }
	bool operator!=(Variable other) const { return id_ != other.id_; }
	bool operator<(Variable other) const { return id_ < other.id_; }
	static Variable Invalid() { return Variable(kInvalid); }
	friend V8_INLINE size_t hash_value(Variable v) {
	return base::hash_value(v.id_);
	}
	friend std::ostream& operator<<(std::ostream& os, Variable var) {
	return os << var.id_;
	}

	private:
	using Id = int;
	explicit Variable(Id id) : id_(id) {}
	Id id_;
	static const Id kInvalid = -1;

	friend class VariableTracker;
	};

	// An object that can track the nodes in the graph whose current reduction
	// depends on the value of the object.
	class Dependable : public ZoneObject {
	public:
	explicit Dependable(Zone* zone) : dependants_(zone) {}
	void AddDependency(Node* node) { dependants_.push_back(node); }
	void RevisitDependants(EffectGraphReducer* reducer) {
	for (Node* node : dependants_) {
	reducer->Revisit(node);
	}
	dependants_.clear();
	}

	private:
	ZoneVector<Node*> dependants_;
	};

	// A virtual object represents an allocation site and tracks the Variables
	// associated with its fields as well as its global escape status.
	class VirtualObject : public Dependable {
	public:
	using Id = uint32_t;
	using const_iterator = ZoneVector<Variable>::const_iterator;
	VirtualObject(VariableTracker* var_states, Id id, int size);
	Maybe<Variable> FieldAt(int offset) const {
	CHECK(IsAligned(offset, kTaggedSize));
	CHECK(!HasEscaped());
	if (offset >= size()) {
	// TODO(tebbi): Reading out-of-bounds can only happen in unreachable
	// code. In this case, we have to mark the object as escaping to avoid
	// dead nodes in the graph. This is a workaround that should be removed
	// once we can handle dead nodes everywhere.
	return Nothing<Variable>();
	}
	return Just(fields_.at(offset / kTaggedSize));
	}
	Id id() const { return id_; }
	int size() const { return static_cast<int>(kTaggedSize * fields_.size()); }
	// Escaped might mean that the object escaped to untracked memory or that it
	// is used in an operation that requires materialization.
	void SetEscaped() { escaped_ = true; }
	bool HasEscaped() const { return escaped_; }
	const_iterator begin() const { return fields_.begin(); }
	const_iterator end() const { return fields_.end(); }

	private:
	bool escaped_ = false;
	Id id_;
	ZoneVector<Variable> fields_;
	};

	class EscapeAnalysisResult {
	public:
	explicit EscapeAnalysisResult(EscapeAnalysisTracker* tracker)
	: tracker_(tracker) {}

	const VirtualObject* GetVirtualObject(Node* node);
	Node* GetVirtualObjectField(const VirtualObject* vobject, int field,
	Node* effect);
	Node* GetReplacementOf(Node* node);

	private:
	EscapeAnalysisTracker* tracker_;
	};

	class V8_EXPORT_PRIVATE EscapeAnalysis final
	: public NON_EXPORTED_BASE(EffectGraphReducer) {
	public:
	EscapeAnalysis(JSGraph* jsgraph, TickCounter* tick_counter, Zone* zone);

	EscapeAnalysisResult analysis_result() {
	DCHECK(Complete());
	return EscapeAnalysisResult(tracker_);
	}

	private:
	void Reduce(Node* node, Reduction* reduction);
	JSGraph* jsgraph() { return jsgraph_; }
	Isolate* isolate() const { return jsgraph_->isolate(); }
	EscapeAnalysisTracker* tracker_;
	JSGraph* jsgraph_;
	};

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

	#endif // V8_COMPILER_ESCAPE_ANALYSIS_H_