runtime/vm/compiler/backend/redundancy_elimination.h - sdk.git - Git at Google

 // Copyright (c) 2016, 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 RUNTIME_VM_COMPILER_BACKEND_REDUNDANCY_ELIMINATION_H_
 #define RUNTIME_VM_COMPILER_BACKEND_REDUNDANCY_ELIMINATION_H_

 #if defined(DART_PRECOMPILED_RUNTIME)
 #error "AOT runtime should not use compiler sources (including header files)"
 #endif  // defined(DART_PRECOMPILED_RUNTIME)

 #include "vm/compiler/backend/flow_graph.h"
 #include "vm/compiler/backend/il.h"

 namespace dart {

 class CSEInstructionMap;

 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 inserted 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 Slot*>& fields);

   void EliminateAllocation(Definition* alloc);

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

   FlowGraph* flow_graph_;

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

   ExitsCollector exits_collector_;
 };

 // 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:
   // Discover phis that have no real (non-phi) uses and don't escape into
   // deoptimization environments and eliminate them.
   static void EliminateDeadPhis(FlowGraph* graph);

   // Remove phis that are not marked alive from the graph.
   static void RemoveDeadAndRedundantPhisFromTheGraph(FlowGraph* graph);

   // Remove instructions which do not have any effect.
   static void EliminateDeadCode(FlowGraph* graph);
 };

 // Optimize spill stores inside try-blocks by identifying values that always
 // contain a single known constant at catch block entry.
 // If is_aot is passed then this optimization can assume that no deoptimization
 // can occur and environments assigned to instructions are only used to
 // compute try/catch sync moves.
 void OptimizeCatchEntryStates(FlowGraph* flow_graph, bool is_aot);

 // 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_;
 };

 // Move allocations down to their first use. Improves write barrier elimination.
 class DelayAllocations : public AllStatic {
  public:
   static void Optimize(FlowGraph* graph);

  private:
   static Instruction* DominantUse(Definition* def);
   static bool IsOneTimeUse(Instruction* use, Definition* def);
 };

 class CheckStackOverflowElimination : public AllStatic {
  public:
   // For leaf functions with only a single [StackOverflowInstr] we remove it.
   static void EliminateStackOverflow(FlowGraph* graph);
 };

 }  // namespace dart

 #endif  // RUNTIME_VM_COMPILER_BACKEND_REDUNDANCY_ELIMINATION_H_
	// Copyright (c) 2016, 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 RUNTIME_VM_COMPILER_BACKEND_REDUNDANCY_ELIMINATION_H_
	#define RUNTIME_VM_COMPILER_BACKEND_REDUNDANCY_ELIMINATION_H_

	#if defined(DART_PRECOMPILED_RUNTIME)
	#error "AOT runtime should not use compiler sources (including header files)"
	#endif // defined(DART_PRECOMPILED_RUNTIME)

	#include "vm/compiler/backend/flow_graph.h"
	#include "vm/compiler/backend/il.h"

	namespace dart {

	class CSEInstructionMap;

	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 inserted 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 Slot*>& fields);

	void EliminateAllocation(Definition* alloc);

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

	FlowGraph* flow_graph_;

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

	ExitsCollector exits_collector_;
	};

	// 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:
	// Discover phis that have no real (non-phi) uses and don't escape into
	// deoptimization environments and eliminate them.
	static void EliminateDeadPhis(FlowGraph* graph);

	// Remove phis that are not marked alive from the graph.
	static void RemoveDeadAndRedundantPhisFromTheGraph(FlowGraph* graph);

	// Remove instructions which do not have any effect.
	static void EliminateDeadCode(FlowGraph* graph);
	};

	// Optimize spill stores inside try-blocks by identifying values that always
	// contain a single known constant at catch block entry.
	// If is_aot is passed then this optimization can assume that no deoptimization
	// can occur and environments assigned to instructions are only used to
	// compute try/catch sync moves.
	void OptimizeCatchEntryStates(FlowGraph* flow_graph, bool is_aot);

	// 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_;
	};

	// Move allocations down to their first use. Improves write barrier elimination.
	class DelayAllocations : public AllStatic {
	public:
	static void Optimize(FlowGraph* graph);

	private:
	static Instruction* DominantUse(Definition* def);
	static bool IsOneTimeUse(Instruction* use, Definition* def);
	};

	class CheckStackOverflowElimination : public AllStatic {
	public:
	// For leaf functions with only a single [StackOverflowInstr] we remove it.
	static void EliminateStackOverflow(FlowGraph* graph);
	};

	} // namespace dart

	#endif // RUNTIME_VM_COMPILER_BACKEND_REDUNDANCY_ELIMINATION_H_