dart/runtime/vm/flow_graph_optimizer.h - external/dart - Git at Google

 // Copyright (c) 2012, the Dart project authors.  Please see the AUTHORS file
 // for details. All rights reserved. Use of this source code is governed by a
 // BSD-style license that can be found in the LICENSE file.

 #ifndef VM_FLOW_GRAPH_OPTIMIZER_H_
 #define VM_FLOW_GRAPH_OPTIMIZER_H_

 #include "vm/intermediate_language.h"
 #include "vm/flow_graph.h"

 namespace dart {

 class CSEInstructionMap;
 template <typename T> class GrowableArray;
 class ParsedFunction;

 class FlowGraphOptimizer : public FlowGraphVisitor {
  public:
   explicit FlowGraphOptimizer(FlowGraph* flow_graph)
       : FlowGraphVisitor(flow_graph->reverse_postorder()),
         flow_graph_(flow_graph) { }
   virtual ~FlowGraphOptimizer() {}

   FlowGraph* flow_graph() const { return flow_graph_; }

   // Use ICData to optimize, replace or eliminate instructions.
   void ApplyICData();

   // Use propagated class ids to optimize, replace or eliminate instructions.
   void ApplyClassIds();

   // Optimize (a << b) & c pattern: if c is a positive Smi or zero, then the
   // shift can be a truncating Smi shift-left and result is always Smi.
   // Merge instructions (only per basic-block).
   void TryOptimizePatterns();

   // Returns true if any instructions were canonicalized away.
   bool Canonicalize();

   void EliminateDeadPhis();

   void SelectRepresentations();

   void WidenSmiToInt32();

   void InferIntRanges();

   void SelectIntegerInstructions();

   void AnalyzeTryCatch();

   bool TryInlineRecognizedMethod(intptr_t receiver_cid,
                                  const Function& target,
                                  Instruction* call,
                                  Definition* receiver,
                                  intptr_t token_pos,
                                  const ICData& ic_data,
                                  TargetEntryInstr** entry,
                                  Definition** last);

   // Remove environments from the instructions which do not deoptimize.
   void EliminateEnvironments();

   virtual void VisitStaticCall(StaticCallInstr* instr);
   virtual void VisitInstanceCall(InstanceCallInstr* instr);
   virtual void VisitStoreInstanceField(StoreInstanceFieldInstr* instr);
   virtual void VisitAllocateContext(AllocateContextInstr* instr);
   virtual void VisitLoadCodeUnits(LoadCodeUnitsInstr* instr);

   void InsertBefore(Instruction* next,
                     Instruction* instr,
                     Environment* env,
                     FlowGraph::UseKind use_kind) {
     flow_graph_->InsertBefore(next, instr, env, use_kind);
   }

  private:
   // Attempt to build ICData for call using propagated class-ids.
   bool TryCreateICData(InstanceCallInstr* call);
   const ICData& TrySpecializeICData(const ICData& ic_data, intptr_t cid);

   void SpecializePolymorphicInstanceCall(PolymorphicInstanceCallInstr* call);

   bool TryReplaceWithIndexedOp(InstanceCallInstr* call);
   bool InlineSetIndexed(MethodRecognizer::Kind kind,
                         const Function& target,
                         Instruction* call,
                         Definition* receiver,
                         intptr_t token_pos,
                         const ICData& value_check,
                         TargetEntryInstr** entry,
                         Definition** last);
   bool InlineGetIndexed(MethodRecognizer::Kind kind,
                         Instruction* call,
                         Definition* receiver,
                         TargetEntryInstr** entry,
                         Definition** last);
   intptr_t PrepareInlineIndexedOp(Instruction* call,
                                   intptr_t array_cid,
                                   Definition** array,
                                   Definition* index,
                                   Instruction** cursor);


   bool TryReplaceWithBinaryOp(InstanceCallInstr* call, Token::Kind op_kind);
   bool TryReplaceWithUnaryOp(InstanceCallInstr* call, Token::Kind op_kind);

   bool TryReplaceWithEqualityOp(InstanceCallInstr* call, Token::Kind op_kind);
   bool TryReplaceWithRelationalOp(InstanceCallInstr* call, Token::Kind op_kind);

   bool TryInlineInstanceGetter(InstanceCallInstr* call);
   bool TryInlineInstanceSetter(InstanceCallInstr* call,
                                const ICData& unary_ic_data);

   bool TryInlineInstanceMethod(InstanceCallInstr* call);
   bool TryInlineFloat32x4Constructor(StaticCallInstr* call,
                                      MethodRecognizer::Kind recognized_kind);
   bool TryInlineFloat64x2Constructor(StaticCallInstr* call,
                                      MethodRecognizer::Kind recognized_kind);
   bool TryInlineInt32x4Constructor(StaticCallInstr* call,
                                     MethodRecognizer::Kind recognized_kind);
   bool TryInlineFloat32x4Method(InstanceCallInstr* call,
                                 MethodRecognizer::Kind recognized_kind);
   bool TryInlineFloat64x2Method(InstanceCallInstr* call,
                                 MethodRecognizer::Kind recognized_kind);
   bool TryInlineInt32x4Method(InstanceCallInstr* call,
                                MethodRecognizer::Kind recognized_kind);
   void ReplaceWithInstanceOf(InstanceCallInstr* instr);
   bool TypeCheckAsClassEquality(const AbstractType& type);
   void ReplaceWithTypeCast(InstanceCallInstr* instr);

   bool TryReplaceInstanceCallWithInline(InstanceCallInstr* call);

   Definition* PrepareInlineStringIndexOp(Instruction* call,
                                          intptr_t cid,
                                          Definition* str,
                                          Definition* index,
                                          Instruction* cursor);

   bool InlineStringCodeUnitAt(Instruction* call,
                               intptr_t cid,
                               TargetEntryInstr** entry,
                               Definition** last);

   bool InlineStringBaseCharAt(Instruction* call,
                               intptr_t cid,
                               TargetEntryInstr** entry,
                               Definition** last);

   bool InlineDoubleOp(Token::Kind op_kind,
                       Instruction* call,
                       TargetEntryInstr** entry,
                       Definition** last);

   bool InlineByteArrayBaseLoad(Instruction* call,
                                Definition* receiver,
                                intptr_t array_cid,
                                intptr_t view_cid,
                                const ICData& ic_data,
                                TargetEntryInstr** entry,
                                Definition** last);

   bool InlineByteArrayBaseStore(const Function& target,
                                 Instruction* call,
                                 Definition* receiver,
                                 intptr_t array_cid,
                                 intptr_t view_cid,
                                 const ICData& ic_data,
                                 TargetEntryInstr** entry,
                                 Definition** last);

   intptr_t PrepareInlineByteArrayBaseOp(Instruction* call,
                                         intptr_t array_cid,
                                         intptr_t view_cid,
                                         Definition** array,
                                         Definition* index,
                                         Instruction** cursor);

   bool BuildByteArrayBaseLoad(InstanceCallInstr* call,
                               intptr_t view_cid);
   bool BuildByteArrayBaseStore(InstanceCallInstr* call,
                                intptr_t view_cid);

   // Insert a check of 'to_check' determined by 'unary_checks'.  If the
   // check fails it will deoptimize to 'deopt_id' using the deoptimization
   // environment 'deopt_environment'.  The check is inserted immediately
   // before 'insert_before'.
   void AddCheckClass(Definition* to_check,
                      const ICData& unary_checks,
                      intptr_t deopt_id,
                      Environment* deopt_environment,
                      Instruction* insert_before);
   Instruction* GetCheckClass(Definition* to_check,
                              const ICData& unary_checks,
                              intptr_t deopt_id,
                              intptr_t token_pos);

   // Insert a Smi check if needed.
   void AddCheckSmi(Definition* to_check,
                    intptr_t deopt_id,
                    Environment* deopt_environment,
                    Instruction* insert_before);

   // Add a class check for a call's first argument immediately before the
   // call, using the call's IC data to determine the check, and the call's
   // deopt ID and deoptimization environment if the check fails.
   void AddReceiverCheck(InstanceCallInstr* call);

   void ReplaceCall(Definition* call, Definition* replacement);

   void InsertConversionsFor(Definition* def);

   void ConvertUse(Value* use, Representation from);
   void ConvertEnvironmentUse(Value* use, Representation from);

   void InsertConversion(Representation from,
                         Representation to,
                         Value* use,
                         bool is_environment_use);

   bool InstanceCallNeedsClassCheck(InstanceCallInstr* call,
                                    RawFunction::Kind kind) const;

   bool InlineFloat32x4Getter(InstanceCallInstr* call,
                              MethodRecognizer::Kind getter);
   bool InlineFloat64x2Getter(InstanceCallInstr* call,
                              MethodRecognizer::Kind getter);
   bool InlineInt32x4Getter(InstanceCallInstr* call,
                             MethodRecognizer::Kind getter);
   bool InlineFloat32x4BinaryOp(InstanceCallInstr* call,
                                Token::Kind op_kind);
   bool InlineInt32x4BinaryOp(InstanceCallInstr* call,
                               Token::Kind op_kind);
   bool InlineFloat64x2BinaryOp(InstanceCallInstr* call,
                                Token::Kind op_kind);
   void InlineImplicitInstanceGetter(InstanceCallInstr* call);

   RawBool* InstanceOfAsBool(const ICData& ic_data,
                             const AbstractType& type,
                             ZoneGrowableArray<intptr_t>* results) const;

   void ReplaceWithMathCFunction(InstanceCallInstr* call,
                                 MethodRecognizer::Kind recognized_kind);

   void OptimizeLeftShiftBitAndSmiOp(Definition* bit_and_instr,
                                     Definition* left_instr,
                                     Definition* right_instr);
   void TryMergeTruncDivMod(GrowableArray<BinarySmiOpInstr*>* merge_candidates);
   void TryMergeMathUnary(GrowableArray<MathUnaryInstr*>* merge_candidates);

   void AppendLoadIndexedForMerged(Definition* instr, intptr_t ix, intptr_t cid);
   void AppendExtractNthOutputForMerged(Definition* instr, intptr_t ix,
                                        Representation rep, intptr_t cid);
   bool TryStringLengthOneEquality(InstanceCallInstr* call, Token::Kind op_kind);

   Thread* thread() const { return flow_graph_->thread(); }
   Isolate* isolate() const { return flow_graph_->isolate(); }
   Zone* zone() const { return flow_graph_->zone(); }

   FlowGraph* flow_graph_;

   DISALLOW_COPY_AND_ASSIGN(FlowGraphOptimizer);
 };


 // Loop invariant code motion.
 class LICM : public ValueObject {
  public:
   explicit LICM(FlowGraph* flow_graph);

   void Optimize();

   void OptimisticallySpecializeSmiPhis();

  private:
   FlowGraph* flow_graph() const { return flow_graph_; }

   void Hoist(ForwardInstructionIterator* it,
              BlockEntryInstr* pre_header,
              Instruction* current);

   void TrySpecializeSmiPhi(PhiInstr* phi,
                            BlockEntryInstr* header,
                            BlockEntryInstr* pre_header);

   FlowGraph* const flow_graph_;
 };


 // A simple common subexpression elimination based
 // on the dominator tree.
 class DominatorBasedCSE : public AllStatic {
  public:
   // Return true, if the optimization changed the flow graph.
   // False, if nothing changed.
   static bool Optimize(FlowGraph* graph);

  private:
   static bool OptimizeRecursive(
       FlowGraph* graph,
       BlockEntryInstr* entry,
       CSEInstructionMap* map);
 };


 class DeadStoreElimination : public AllStatic {
  public:
   static void Optimize(FlowGraph* graph);
 };


 class DeadCodeElimination : public AllStatic {
  public:
   static void EliminateDeadPhis(FlowGraph* graph);
 };


 // Rewrite branches to eliminate materialization of boolean values after
 // inlining, and to expose other optimizations (e.g., constant folding of
 // branches, unreachable code elimination).
 class BranchSimplifier : public AllStatic {
  public:
   static void Simplify(FlowGraph* flow_graph);

   // Replace a target entry instruction with a join entry instruction.  Does
   // not update the original target's predecessors to point to the new block
   // and does not replace the target in already computed block order lists.
   static JoinEntryInstr* ToJoinEntry(Zone* zone,
                                      TargetEntryInstr* target);

  private:
   // Match an instance of the pattern to rewrite.  See the implementation
   // for the patterns that are handled by this pass.
   static bool Match(JoinEntryInstr* block);

   // Duplicate a branch while replacing its comparison's left and right
   // inputs.
   static BranchInstr* CloneBranch(Zone* zone,
                                   BranchInstr* branch,
                                   Value* new_left,
                                   Value* new_right);
 };


 // Rewrite diamond control flow patterns that materialize values to use more
 // efficient branchless code patterns if such are supported on the current
 // platform.
 class IfConverter : public AllStatic {
  public:
   static void Simplify(FlowGraph* flow_graph);
 };


 class AllocationSinking : public ZoneAllocated {
  public:
   explicit AllocationSinking(FlowGraph* flow_graph)
       : flow_graph_(flow_graph),
         candidates_(5),
         materializations_(5) { }

   const GrowableArray<Definition*>& candidates() const {
     return candidates_;
   }

   // Find the materialization insterted for the given allocation
   // at the given exit.
   MaterializeObjectInstr* MaterializationFor(Definition* alloc,
                                              Instruction* exit);

   void Optimize();

   void DetachMaterializations();

  private:
   // Helper class to collect deoptimization exits that might need to
   // rematerialize an object: that is either instructions that reference
   // this object explicitly in their deoptimization environment or
   // reference some other allocation sinking candidate that points to
   // this object.
   class ExitsCollector : public ValueObject {
    public:
     ExitsCollector() : exits_(10), worklist_(3) { }

     const GrowableArray<Instruction*>& exits() const { return exits_; }

     void CollectTransitively(Definition* alloc);

    private:
     // Collect immediate uses of this object in the environments.
     // If this object is stored into other allocation sinking candidates
     // put them onto worklist so that CollectTransitively will process them.
     void Collect(Definition* alloc);

     GrowableArray<Instruction*> exits_;
     GrowableArray<Definition*> worklist_;
   };

   void CollectCandidates();

   void NormalizeMaterializations();

   void RemoveUnusedMaterializations();

   void DiscoverFailedCandidates();

   void InsertMaterializations(Definition* alloc);

   void CreateMaterializationAt(
       Instruction* exit,
       Definition* alloc,
       const ZoneGrowableArray<const Object*>& fields);

   void EliminateAllocation(Definition* alloc);

   Isolate* isolate() const { return flow_graph_->isolate(); }
   Zone* zone() const { return flow_graph_->zone(); }

   FlowGraph* flow_graph_;

   GrowableArray<Definition*> candidates_;
   GrowableArray<MaterializeObjectInstr*> materializations_;

   ExitsCollector exits_collector_;
 };


 // Optimize spill stores inside try-blocks by identifying values that always
 // contain a single known constant at catch block entry.
 class TryCatchAnalyzer : public AllStatic {
  public:
   static void Optimize(FlowGraph* flow_graph);
 };

 }  // namespace dart

 #endif  // VM_FLOW_GRAPH_OPTIMIZER_H_
	// Copyright (c) 2012, the Dart project authors. Please see the AUTHORS file
	// for details. All rights reserved. Use of this source code is governed by a
	// BSD-style license that can be found in the LICENSE file.

	#ifndef VM_FLOW_GRAPH_OPTIMIZER_H_
	#define VM_FLOW_GRAPH_OPTIMIZER_H_

	#include "vm/intermediate_language.h"
	#include "vm/flow_graph.h"

	namespace dart {

	class CSEInstructionMap;
	template <typename T> class GrowableArray;
	class ParsedFunction;

	class FlowGraphOptimizer : public FlowGraphVisitor {
	public:
	explicit FlowGraphOptimizer(FlowGraph* flow_graph)
	: FlowGraphVisitor(flow_graph->reverse_postorder()),
	flow_graph_(flow_graph) { }
	virtual ~FlowGraphOptimizer() {}

	FlowGraph* flow_graph() const { return flow_graph_; }

	// Use ICData to optimize, replace or eliminate instructions.
	void ApplyICData();

	// Use propagated class ids to optimize, replace or eliminate instructions.
	void ApplyClassIds();

	// Optimize (a << b) & c pattern: if c is a positive Smi or zero, then the
	// shift can be a truncating Smi shift-left and result is always Smi.
	// Merge instructions (only per basic-block).
	void TryOptimizePatterns();

	// Returns true if any instructions were canonicalized away.
	bool Canonicalize();

	void EliminateDeadPhis();

	void SelectRepresentations();

	void WidenSmiToInt32();

	void InferIntRanges();

	void SelectIntegerInstructions();

	void AnalyzeTryCatch();

	bool TryInlineRecognizedMethod(intptr_t receiver_cid,
	const Function& target,
	Instruction* call,
	Definition* receiver,
	intptr_t token_pos,
	const ICData& ic_data,
	TargetEntryInstr** entry,
	Definition** last);

	// Remove environments from the instructions which do not deoptimize.
	void EliminateEnvironments();

	virtual void VisitStaticCall(StaticCallInstr* instr);
	virtual void VisitInstanceCall(InstanceCallInstr* instr);
	virtual void VisitStoreInstanceField(StoreInstanceFieldInstr* instr);
	virtual void VisitAllocateContext(AllocateContextInstr* instr);
	virtual void VisitLoadCodeUnits(LoadCodeUnitsInstr* instr);

	void InsertBefore(Instruction* next,
	Instruction* instr,
	Environment* env,
	FlowGraph::UseKind use_kind) {
	flow_graph_->InsertBefore(next, instr, env, use_kind);
	}

	private:
	// Attempt to build ICData for call using propagated class-ids.
	bool TryCreateICData(InstanceCallInstr* call);
	const ICData& TrySpecializeICData(const ICData& ic_data, intptr_t cid);

	void SpecializePolymorphicInstanceCall(PolymorphicInstanceCallInstr* call);

	bool TryReplaceWithIndexedOp(InstanceCallInstr* call);
	bool InlineSetIndexed(MethodRecognizer::Kind kind,
	const Function& target,
	Instruction* call,
	Definition* receiver,
	intptr_t token_pos,
	const ICData& value_check,
	TargetEntryInstr** entry,
	Definition** last);
	bool InlineGetIndexed(MethodRecognizer::Kind kind,
	Instruction* call,
	Definition* receiver,
	TargetEntryInstr** entry,
	Definition** last);
	intptr_t PrepareInlineIndexedOp(Instruction* call,
	intptr_t array_cid,
	Definition** array,
	Definition* index,
	Instruction** cursor);


	bool TryReplaceWithBinaryOp(InstanceCallInstr* call, Token::Kind op_kind);
	bool TryReplaceWithUnaryOp(InstanceCallInstr* call, Token::Kind op_kind);

	bool TryReplaceWithEqualityOp(InstanceCallInstr* call, Token::Kind op_kind);
	bool TryReplaceWithRelationalOp(InstanceCallInstr* call, Token::Kind op_kind);

	bool TryInlineInstanceGetter(InstanceCallInstr* call);
	bool TryInlineInstanceSetter(InstanceCallInstr* call,
	const ICData& unary_ic_data);

	bool TryInlineInstanceMethod(InstanceCallInstr* call);
	bool TryInlineFloat32x4Constructor(StaticCallInstr* call,
	MethodRecognizer::Kind recognized_kind);
	bool TryInlineFloat64x2Constructor(StaticCallInstr* call,
	MethodRecognizer::Kind recognized_kind);
	bool TryInlineInt32x4Constructor(StaticCallInstr* call,
	MethodRecognizer::Kind recognized_kind);
	bool TryInlineFloat32x4Method(InstanceCallInstr* call,
	MethodRecognizer::Kind recognized_kind);
	bool TryInlineFloat64x2Method(InstanceCallInstr* call,
	MethodRecognizer::Kind recognized_kind);
	bool TryInlineInt32x4Method(InstanceCallInstr* call,
	MethodRecognizer::Kind recognized_kind);
	void ReplaceWithInstanceOf(InstanceCallInstr* instr);
	bool TypeCheckAsClassEquality(const AbstractType& type);
	void ReplaceWithTypeCast(InstanceCallInstr* instr);

	bool TryReplaceInstanceCallWithInline(InstanceCallInstr* call);

	Definition* PrepareInlineStringIndexOp(Instruction* call,
	intptr_t cid,
	Definition* str,
	Definition* index,
	Instruction* cursor);

	bool InlineStringCodeUnitAt(Instruction* call,
	intptr_t cid,
	TargetEntryInstr** entry,
	Definition** last);

	bool InlineStringBaseCharAt(Instruction* call,
	intptr_t cid,
	TargetEntryInstr** entry,
	Definition** last);

	bool InlineDoubleOp(Token::Kind op_kind,
	Instruction* call,
	TargetEntryInstr** entry,
	Definition** last);

	bool InlineByteArrayBaseLoad(Instruction* call,
	Definition* receiver,
	intptr_t array_cid,
	intptr_t view_cid,
	const ICData& ic_data,
	TargetEntryInstr** entry,
	Definition** last);

	bool InlineByteArrayBaseStore(const Function& target,
	Instruction* call,
	Definition* receiver,
	intptr_t array_cid,
	intptr_t view_cid,
	const ICData& ic_data,
	TargetEntryInstr** entry,
	Definition** last);

	intptr_t PrepareInlineByteArrayBaseOp(Instruction* call,
	intptr_t array_cid,
	intptr_t view_cid,
	Definition** array,
	Definition* index,
	Instruction** cursor);

	bool BuildByteArrayBaseLoad(InstanceCallInstr* call,
	intptr_t view_cid);
	bool BuildByteArrayBaseStore(InstanceCallInstr* call,
	intptr_t view_cid);

	// Insert a check of 'to_check' determined by 'unary_checks'. If the
	// check fails it will deoptimize to 'deopt_id' using the deoptimization
	// environment 'deopt_environment'. The check is inserted immediately
	// before 'insert_before'.
	void AddCheckClass(Definition* to_check,
	const ICData& unary_checks,
	intptr_t deopt_id,
	Environment* deopt_environment,
	Instruction* insert_before);
	Instruction* GetCheckClass(Definition* to_check,
	const ICData& unary_checks,
	intptr_t deopt_id,
	intptr_t token_pos);

	// Insert a Smi check if needed.
	void AddCheckSmi(Definition* to_check,
	intptr_t deopt_id,
	Environment* deopt_environment,
	Instruction* insert_before);

	// Add a class check for a call's first argument immediately before the
	// call, using the call's IC data to determine the check, and the call's
	// deopt ID and deoptimization environment if the check fails.
	void AddReceiverCheck(InstanceCallInstr* call);

	void ReplaceCall(Definition* call, Definition* replacement);

	void InsertConversionsFor(Definition* def);

	void ConvertUse(Value* use, Representation from);
	void ConvertEnvironmentUse(Value* use, Representation from);

	void InsertConversion(Representation from,
	Representation to,
	Value* use,
	bool is_environment_use);

	bool InstanceCallNeedsClassCheck(InstanceCallInstr* call,
	RawFunction::Kind kind) const;

	bool InlineFloat32x4Getter(InstanceCallInstr* call,
	MethodRecognizer::Kind getter);
	bool InlineFloat64x2Getter(InstanceCallInstr* call,
	MethodRecognizer::Kind getter);
	bool InlineInt32x4Getter(InstanceCallInstr* call,
	MethodRecognizer::Kind getter);
	bool InlineFloat32x4BinaryOp(InstanceCallInstr* call,
	Token::Kind op_kind);
	bool InlineInt32x4BinaryOp(InstanceCallInstr* call,
	Token::Kind op_kind);
	bool InlineFloat64x2BinaryOp(InstanceCallInstr* call,
	Token::Kind op_kind);
	void InlineImplicitInstanceGetter(InstanceCallInstr* call);

	RawBool* InstanceOfAsBool(const ICData& ic_data,
	const AbstractType& type,
	ZoneGrowableArray<intptr_t>* results) const;

	void ReplaceWithMathCFunction(InstanceCallInstr* call,
	MethodRecognizer::Kind recognized_kind);

	void OptimizeLeftShiftBitAndSmiOp(Definition* bit_and_instr,
	Definition* left_instr,
	Definition* right_instr);
	void TryMergeTruncDivMod(GrowableArray<BinarySmiOpInstr> merge_candidates);
	void TryMergeMathUnary(GrowableArray<MathUnaryInstr> merge_candidates);

	void AppendLoadIndexedForMerged(Definition* instr, intptr_t ix, intptr_t cid);
	void AppendExtractNthOutputForMerged(Definition* instr, intptr_t ix,
	Representation rep, intptr_t cid);
	bool TryStringLengthOneEquality(InstanceCallInstr* call, Token::Kind op_kind);

	Thread* thread() const { return flow_graph_->thread(); }
	Isolate* isolate() const { return flow_graph_->isolate(); }
	Zone* zone() const { return flow_graph_->zone(); }

	FlowGraph* flow_graph_;

	DISALLOW_COPY_AND_ASSIGN(FlowGraphOptimizer);
	};


	// Loop invariant code motion.
	class LICM : public ValueObject {
	public:
	explicit LICM(FlowGraph* flow_graph);

	void Optimize();

	void OptimisticallySpecializeSmiPhis();

	private:
	FlowGraph* flow_graph() const { return flow_graph_; }

	void Hoist(ForwardInstructionIterator* it,
	BlockEntryInstr* pre_header,
	Instruction* current);

	void TrySpecializeSmiPhi(PhiInstr* phi,
	BlockEntryInstr* header,
	BlockEntryInstr* pre_header);

	FlowGraph* const flow_graph_;
	};


	// A simple common subexpression elimination based
	// on the dominator tree.
	class DominatorBasedCSE : public AllStatic {
	public:
	// Return true, if the optimization changed the flow graph.
	// False, if nothing changed.
	static bool Optimize(FlowGraph* graph);

	private:
	static bool OptimizeRecursive(
	FlowGraph* graph,
	BlockEntryInstr* entry,
	CSEInstructionMap* map);
	};


	class DeadStoreElimination : public AllStatic {
	public:
	static void Optimize(FlowGraph* graph);
	};


	class DeadCodeElimination : public AllStatic {
	public:
	static void EliminateDeadPhis(FlowGraph* graph);
	};


	// Rewrite branches to eliminate materialization of boolean values after
	// inlining, and to expose other optimizations (e.g., constant folding of
	// branches, unreachable code elimination).
	class BranchSimplifier : public AllStatic {
	public:
	static void Simplify(FlowGraph* flow_graph);

	// Replace a target entry instruction with a join entry instruction. Does
	// not update the original target's predecessors to point to the new block
	// and does not replace the target in already computed block order lists.
	static JoinEntryInstr* ToJoinEntry(Zone* zone,
	TargetEntryInstr* target);

	private:
	// Match an instance of the pattern to rewrite. See the implementation
	// for the patterns that are handled by this pass.
	static bool Match(JoinEntryInstr* block);

	// Duplicate a branch while replacing its comparison's left and right
	// inputs.
	static BranchInstr* CloneBranch(Zone* zone,
	BranchInstr* branch,
	Value* new_left,
	Value* new_right);
	};


	// Rewrite diamond control flow patterns that materialize values to use more
	// efficient branchless code patterns if such are supported on the current
	// platform.
	class IfConverter : public AllStatic {
	public:
	static void Simplify(FlowGraph* flow_graph);
	};


	class AllocationSinking : public ZoneAllocated {
	public:
	explicit AllocationSinking(FlowGraph* flow_graph)
	: flow_graph_(flow_graph),
	candidates_(5),
	materializations_(5) { }

	const GrowableArray<Definition*>& candidates() const {
	return candidates_;
	}

	// Find the materialization insterted for the given allocation
	// at the given exit.
	MaterializeObjectInstr* MaterializationFor(Definition* alloc,
	Instruction* exit);

	void Optimize();

	void DetachMaterializations();

	private:
	// Helper class to collect deoptimization exits that might need to
	// rematerialize an object: that is either instructions that reference
	// this object explicitly in their deoptimization environment or
	// reference some other allocation sinking candidate that points to
	// this object.
	class ExitsCollector : public ValueObject {
	public:
	ExitsCollector() : exits_(10), worklist_(3) { }

	const GrowableArray<Instruction*>& exits() const { return exits_; }

	void CollectTransitively(Definition* alloc);

	private:
	// Collect immediate uses of this object in the environments.
	// If this object is stored into other allocation sinking candidates
	// put them onto worklist so that CollectTransitively will process them.
	void Collect(Definition* alloc);

	GrowableArray<Instruction*> exits_;
	GrowableArray<Definition*> worklist_;
	};

	void CollectCandidates();

	void NormalizeMaterializations();

	void RemoveUnusedMaterializations();

	void DiscoverFailedCandidates();

	void InsertMaterializations(Definition* alloc);

	void CreateMaterializationAt(
	Instruction* exit,
	Definition* alloc,
	const ZoneGrowableArray<const Object*>& fields);

	void EliminateAllocation(Definition* alloc);

	Isolate* isolate() const { return flow_graph_->isolate(); }
	Zone* zone() const { return flow_graph_->zone(); }

	FlowGraph* flow_graph_;

	GrowableArray<Definition*> candidates_;
	GrowableArray<MaterializeObjectInstr*> materializations_;

	ExitsCollector exits_collector_;
	};


	// Optimize spill stores inside try-blocks by identifying values that always
	// contain a single known constant at catch block entry.
	class TryCatchAnalyzer : public AllStatic {
	public:
	static void Optimize(FlowGraph* flow_graph);
	};

	} // namespace dart

	#endif // VM_FLOW_GRAPH_OPTIMIZER_H_