compiler/optimizing/loop_optimization.h - LeafOS-Project/android_art - Gitiles

 /*
  * Copyright (C) 2016 The Android Open Source Project
  *
  * Licensed under the Apache License, Version 2.0 (the "License");
  * you may not use this file except in compliance with the License.
  * You may obtain a copy of the License at
  *
  *      http://www.apache.org/licenses/LICENSE-2.0
  *
  * Unless required by applicable law or agreed to in writing, software
  * distributed under the License is distributed on an "AS IS" BASIS,
  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
  * See the License for the specific language governing permissions and
  * limitations under the License.
  */

 #ifndef ART_COMPILER_OPTIMIZING_LOOP_OPTIMIZATION_H_
 #define ART_COMPILER_OPTIMIZING_LOOP_OPTIMIZATION_H_

 #include "base/macros.h"
 #include "base/scoped_arena_allocator.h"
 #include "base/scoped_arena_containers.h"
 #include "induction_var_range.h"
 #include "loop_analysis.h"
 #include "nodes.h"
 #include "optimization.h"
 #include "superblock_cloner.h"

 namespace art HIDDEN {

 class CompilerOptions;
 class ArchNoOptsLoopHelper;

 /**
  * Loop optimizations. Builds a loop hierarchy and applies optimizations to
  * the detected nested loops, such as removal of dead induction and empty loops
  * and inner loop vectorization.
  */
 class HLoopOptimization : public HOptimization {
  public:
   HLoopOptimization(HGraph* graph,
                     const CodeGenerator& codegen,    // Needs info about the target.
                     HInductionVarAnalysis* induction_analysis,
                     OptimizingCompilerStats* stats,
                     const char* name = kLoopOptimizationPassName);

   bool Run() override;

   static constexpr const char* kLoopOptimizationPassName = "loop_optimization";

   // The maximum number of total instructions (trip_count * instruction_count),
   // where the optimization of removing SuspendChecks from the loop header could
   // be performed.
   static constexpr int64_t kMaxTotalInstRemoveSuspendCheck = 128;

  private:
   /**
    * A single loop inside the loop hierarchy representation.
    */
   struct LoopNode : public ArenaObject<kArenaAllocLoopOptimization> {
     explicit LoopNode(HLoopInformation* lp_info)
         : loop_info(lp_info),
           outer(nullptr),
           inner(nullptr),
           previous(nullptr),
           next(nullptr),
           try_catch_kind(TryCatchKind::kUnknown) {}

     enum class TryCatchKind {
       kUnknown,
       // Either if we have a try catch in the loop, or if the loop is inside of an outer try catch,
       // we set `kHasTryCatch`.
       kHasTryCatch,
       kNoTryCatch
     };

     HLoopInformation* loop_info;
     LoopNode* outer;
     LoopNode* inner;
     LoopNode* previous;
     LoopNode* next;
     TryCatchKind try_catch_kind;
   };

   /*
    * Vectorization restrictions (bit mask).
    */
   enum VectorRestrictions {
     kNone            = 0,        // no restrictions
     kNoMul           = 1 << 0,   // no multiplication
     kNoDiv           = 1 << 1,   // no division
     kNoShift         = 1 << 2,   // no shift
     kNoShr           = 1 << 3,   // no arithmetic shift right
     kNoHiBits        = 1 << 4,   // "wider" operations cannot bring in higher order bits
     kNoSignedHAdd    = 1 << 5,   // no signed halving add
     kNoUnsignedHAdd  = 1 << 6,   // no unsigned halving add
     kNoUnroundedHAdd = 1 << 7,   // no unrounded halving add
     kNoAbs           = 1 << 8,   // no absolute value
     kNoStringCharAt  = 1 << 9,   // no StringCharAt
     kNoReduction     = 1 << 10,  // no reduction
     kNoSAD           = 1 << 11,  // no sum of absolute differences (SAD)
     kNoWideSAD       = 1 << 12,  // no sum of absolute differences (SAD) with operand widening
     kNoDotProd       = 1 << 13,  // no dot product
   };

   /*
    * Vectorization mode during synthesis
    * (sequential peeling/cleanup loop or vector loop).
    */
   enum VectorMode {
     kSequential,
     kVector
   };

   /*
    * Representation of a unit-stride array reference.
    */
   struct ArrayReference {
     ArrayReference(HInstruction* b, HInstruction* o, DataType::Type t, bool l, bool c = false)
         : base(b), offset(o), type(t), lhs(l), is_string_char_at(c) { }
     bool operator<(const ArrayReference& other) const {
       return
           (base < other.base) ||
           (base == other.base &&
            (offset < other.offset || (offset == other.offset &&
                                       (type < other.type ||
                                        (type == other.type &&
                                         (lhs < other.lhs ||
                                          (lhs == other.lhs &&
                                           is_string_char_at < other.is_string_char_at)))))));
     }
     HInstruction* base;      // base address
     HInstruction* offset;    // offset + i
     DataType::Type type;     // component type
     bool lhs;                // def/use
     bool is_string_char_at;  // compressed string read
   };

   //
   // Loop setup and traversal.
   //

   bool LocalRun();
   void AddLoop(HLoopInformation* loop_info);
   void RemoveLoop(LoopNode* node);

   // Traverses all loops inner to outer to perform simplifications and optimizations.
   // Returns true if loops nested inside current loop (node) have changed.
   bool TraverseLoopsInnerToOuter(LoopNode* node);

   // Calculates `node`'s `try_catch_kind` and sets it to:
   // 1) kHasTryCatch if it has try catches (or if it's inside of an outer try catch)
   // 2) kNoTryCatch otherwise.
   void CalculateAndSetTryCatchKind(LoopNode* node);

   //
   // Optimization.
   //

   void SimplifyInduction(LoopNode* node);
   void SimplifyBlocks(LoopNode* node);

   // Performs optimizations specific to inner loop with finite header logic (empty loop removal,
   // unrolling, vectorization). Returns true if anything changed.
   bool TryOptimizeInnerLoopFinite(LoopNode* node);

   // Performs optimizations specific to inner loop. Returns true if anything changed.
   bool OptimizeInnerLoop(LoopNode* node);

   // Tries to apply loop unrolling for branch penalty reduction and better instruction scheduling
   // opportunities. Returns whether transformation happened. 'generate_code' determines whether the
   // optimization should be actually applied.
   bool TryUnrollingForBranchPenaltyReduction(LoopAnalysisInfo* analysis_info,
                                              bool generate_code = true);

   // Tries to apply loop peeling for loop invariant exits elimination. Returns whether
   // transformation happened. 'generate_code' determines whether the optimization should be
   // actually applied.
   bool TryPeelingForLoopInvariantExitsElimination(LoopAnalysisInfo* analysis_info,
                                                   bool generate_code = true);

   // Tries to perform whole loop unrolling for a small loop with a small trip count to eliminate
   // the loop check overhead and to have more opportunities for inter-iteration optimizations.
   // Returns whether transformation happened. 'generate_code' determines whether the optimization
   // should be actually applied.
   bool TryFullUnrolling(LoopAnalysisInfo* analysis_info, bool generate_code = true);

   // Tries to remove SuspendCheck for plain loops with a low trip count. The
   // SuspendCheck in the codegen makes sure that the thread can be interrupted
   // during execution for GC. Not being able to do so might decrease the
   // responsiveness of GC when a very long loop or a long recursion is being
   // executed. However, for plain loops with a small trip count, the removal of
   // SuspendCheck should not affect the GC's responsiveness by a large margin.
   // Consequently, since the thread won't be interrupted for plain loops, it is
   // assumed that the performance might increase by removing SuspendCheck.
   bool TryToRemoveSuspendCheckFromLoopHeader(LoopAnalysisInfo* analysis_info,
                                              bool generate_code = true);

   // Tries to apply scalar loop optimizations.
   bool TryLoopScalarOpts(LoopNode* node);

   //
   // Vectorization analysis and synthesis.
   //

   bool ShouldVectorize(LoopNode* node, HBasicBlock* block, int64_t trip_count);
   void Vectorize(LoopNode* node, HBasicBlock* block, HBasicBlock* exit, int64_t trip_count);
   void GenerateNewLoop(LoopNode* node,
                        HBasicBlock* block,
                        HBasicBlock* new_preheader,
                        HInstruction* lo,
                        HInstruction* hi,
                        HInstruction* step,
                        uint32_t unroll);
   bool VectorizeDef(LoopNode* node, HInstruction* instruction, bool generate_code);
   bool VectorizeUse(LoopNode* node,
                     HInstruction* instruction,
                     bool generate_code,
                     DataType::Type type,
                     uint64_t restrictions);
   uint32_t GetVectorSizeInBytes();
   bool TrySetVectorType(DataType::Type type, /*out*/ uint64_t* restrictions);
   bool TrySetVectorLengthImpl(uint32_t length);

   bool TrySetVectorLength(DataType::Type type, uint32_t length) {
     bool res = TrySetVectorLengthImpl(length);
     // Currently the vectorizer supports only the mode when full SIMD registers are used.
     DCHECK_IMPLIES(res, DataType::Size(type) * length == GetVectorSizeInBytes());
     return res;
   }

   void GenerateVecInv(HInstruction* org, DataType::Type type);
   void GenerateVecSub(HInstruction* org, HInstruction* offset);
   void GenerateVecMem(HInstruction* org,
                       HInstruction* opa,
                       HInstruction* opb,
                       HInstruction* offset,
                       DataType::Type type);
   void GenerateVecReductionPhi(HPhi* phi);
   void GenerateVecReductionPhiInputs(HPhi* phi, HInstruction* reduction);
   HInstruction* ReduceAndExtractIfNeeded(HInstruction* instruction);
   void GenerateVecOp(HInstruction* org,
                      HInstruction* opa,
                      HInstruction* opb,
                      DataType::Type type);

   // Vectorization idioms.
   bool VectorizeSaturationIdiom(LoopNode* node,
                                 HInstruction* instruction,
                                 bool generate_code,
                                 DataType::Type type,
                                 uint64_t restrictions);
   bool VectorizeHalvingAddIdiom(LoopNode* node,
                                 HInstruction* instruction,
                                 bool generate_code,
                                 DataType::Type type,
                                 uint64_t restrictions);
   bool VectorizeSADIdiom(LoopNode* node,
                          HInstruction* instruction,
                          bool generate_code,
                          DataType::Type type,
                          uint64_t restrictions);
   bool VectorizeDotProdIdiom(LoopNode* node,
                              HInstruction* instruction,
                              bool generate_code,
                              DataType::Type type,
                              uint64_t restrictions);

   // Vectorization heuristics.
   Alignment ComputeAlignment(HInstruction* offset,
                              DataType::Type type,
                              bool is_string_char_at,
                              uint32_t peeling = 0);
   void SetAlignmentStrategy(const ScopedArenaVector<uint32_t>& peeling_votes,
                             const ArrayReference* peeling_candidate);
   uint32_t MaxNumberPeeled();
   bool IsVectorizationProfitable(int64_t trip_count);

   //
   // Helpers.
   //

   bool TrySetPhiInduction(HPhi* phi, bool restrict_uses);
   bool TrySetPhiReduction(HPhi* phi);

   // Detects loop header with a single induction (returned in main_phi), possibly
   // other phis for reductions, but no other side effects. Returns true on success.
   bool TrySetSimpleLoopHeader(HBasicBlock* block, /*out*/ HPhi** main_phi);

   bool IsEmptyBody(HBasicBlock* block);
   bool IsOnlyUsedAfterLoop(HLoopInformation* loop_info,
                            HInstruction* instruction,
                            bool collect_loop_uses,
                            /*out*/ uint32_t* use_count);
   bool IsUsedOutsideLoop(HLoopInformation* loop_info,
                          HInstruction* instruction);
   bool TryReplaceWithLastValue(HLoopInformation* loop_info,
                                HInstruction* instruction,
                                HBasicBlock* block);
   bool TryAssignLastValue(HLoopInformation* loop_info,
                           HInstruction* instruction,
                           HBasicBlock* block,
                           bool collect_loop_uses);
   void RemoveDeadInstructions(const HInstructionList& list);
   bool CanRemoveCycle();  // Whether the current 'iset_' is removable.

   bool IsInPredicatedVectorizationMode() const { return predicated_vectorization_mode_; }

   // Compiler options (to query ISA features).
   const CompilerOptions* compiler_options_;

   // Cached target SIMD vector register size in bytes.
   const size_t simd_register_size_;

   // Range information based on prior induction variable analysis.
   InductionVarRange induction_range_;

   // Phase-local heap memory allocator for the loop optimizer. Storage obtained
   // through this allocator is immediately released when the loop optimizer is done.
   ScopedArenaAllocator* loop_allocator_;

   // Global heap memory allocator. Used to build HIR.
   ArenaAllocator* global_allocator_;

   // Entries into the loop hierarchy representation. The hierarchy resides
   // in phase-local heap memory.
   LoopNode* top_loop_;
   LoopNode* last_loop_;

   // Temporary bookkeeping of a set of instructions.
   // Contents reside in phase-local heap memory.
   ScopedArenaSet<HInstruction*>* iset_;

   // Temporary bookkeeping of reduction instructions. Mapping is two-fold:
   // (1) reductions in the loop-body are mapped back to their phi definition,
   // (2) phi definitions are mapped to their initial value (updated during
   //     code generation to feed the proper values into the new chain).
   // Contents reside in phase-local heap memory.
   ScopedArenaSafeMap<HInstruction*, HInstruction*>* reductions_;

   // Flag that tracks if any simplifications have occurred.
   bool simplified_;

   // Whether to use predicated loop vectorization (e.g. for arm64 SVE target).
   bool predicated_vectorization_mode_;

   // Number of "lanes" for selected packed type.
   uint32_t vector_length_;

   // Set of array references in the vector loop.
   // Contents reside in phase-local heap memory.
   ScopedArenaSet<ArrayReference>* vector_refs_;

   // Static or dynamic loop peeling for alignment.
   uint32_t vector_static_peeling_factor_;
   const ArrayReference* vector_dynamic_peeling_candidate_;

   // Dynamic data dependence test of the form a != b.
   HInstruction* vector_runtime_test_a_;
   HInstruction* vector_runtime_test_b_;

   // Mapping used during vectorization synthesis for both the scalar peeling/cleanup
   // loop (mode is kSequential) and the actual vector loop (mode is kVector). The data
   // structure maps original instructions into the new instructions.
   // Contents reside in phase-local heap memory.
   ScopedArenaSafeMap<HInstruction*, HInstruction*>* vector_map_;

   // Permanent mapping used during vectorization synthesis.
   // Contents reside in phase-local heap memory.
   ScopedArenaSafeMap<HInstruction*, HInstruction*>* vector_permanent_map_;

   // Temporary vectorization bookkeeping.
   VectorMode vector_mode_;  // synthesis mode
   HBasicBlock* vector_preheader_;  // preheader of the new loop
   HBasicBlock* vector_header_;  // header of the new loop
   HBasicBlock* vector_body_;  // body of the new loop
   HInstruction* vector_index_;  // normalized index of the new loop

   // Helper for target-specific behaviour for loop optimizations.
   ArchNoOptsLoopHelper* arch_loop_helper_;

   friend class LoopOptimizationTest;

   DISALLOW_COPY_AND_ASSIGN(HLoopOptimization);
 };

 }  // namespace art

 #endif  // ART_COMPILER_OPTIMIZING_LOOP_OPTIMIZATION_H_
	/*
	* Copyright (C) 2016 The Android Open Source Project
	*
	* Licensed under the Apache License, Version 2.0 (the "License");
	* you may not use this file except in compliance with the License.
	* You may obtain a copy of the License at
	*
	* http://www.apache.org/licenses/LICENSE-2.0
	*
	* Unless required by applicable law or agreed to in writing, software
	* distributed under the License is distributed on an "AS IS" BASIS,
	* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	* See the License for the specific language governing permissions and
	* limitations under the License.
	*/

	#ifndef ART_COMPILER_OPTIMIZING_LOOP_OPTIMIZATION_H_
	#define ART_COMPILER_OPTIMIZING_LOOP_OPTIMIZATION_H_

	#include "base/macros.h"
	#include "base/scoped_arena_allocator.h"
	#include "base/scoped_arena_containers.h"
	#include "induction_var_range.h"
	#include "loop_analysis.h"
	#include "nodes.h"
	#include "optimization.h"
	#include "superblock_cloner.h"

	namespace art HIDDEN {

	class CompilerOptions;
	class ArchNoOptsLoopHelper;

	/**
	* Loop optimizations. Builds a loop hierarchy and applies optimizations to
	* the detected nested loops, such as removal of dead induction and empty loops
	* and inner loop vectorization.
	*/
	class HLoopOptimization : public HOptimization {
	public:
	HLoopOptimization(HGraph* graph,
	const CodeGenerator& codegen, // Needs info about the target.
	HInductionVarAnalysis* induction_analysis,
	OptimizingCompilerStats* stats,
	const char* name = kLoopOptimizationPassName);

	bool Run() override;

	static constexpr const char* kLoopOptimizationPassName = "loop_optimization";

	// The maximum number of total instructions (trip_count * instruction_count),
	// where the optimization of removing SuspendChecks from the loop header could
	// be performed.
	static constexpr int64_t kMaxTotalInstRemoveSuspendCheck = 128;

	private:
	/**
	* A single loop inside the loop hierarchy representation.
	*/
	struct LoopNode : public ArenaObject<kArenaAllocLoopOptimization> {
	explicit LoopNode(HLoopInformation* lp_info)
	: loop_info(lp_info),
	outer(nullptr),
	inner(nullptr),
	previous(nullptr),
	next(nullptr),
	try_catch_kind(TryCatchKind::kUnknown) {}

	enum class TryCatchKind {
	kUnknown,
	// Either if we have a try catch in the loop, or if the loop is inside of an outer try catch,
	// we set `kHasTryCatch`.
	kHasTryCatch,
	kNoTryCatch
	};

	HLoopInformation* loop_info;
	LoopNode* outer;
	LoopNode* inner;
	LoopNode* previous;
	LoopNode* next;
	TryCatchKind try_catch_kind;
	};

	/*
	* Vectorization restrictions (bit mask).
	*/
	enum VectorRestrictions {
	kNone = 0, // no restrictions
	kNoMul = 1 << 0, // no multiplication
	kNoDiv = 1 << 1, // no division
	kNoShift = 1 << 2, // no shift
	kNoShr = 1 << 3, // no arithmetic shift right
	kNoHiBits = 1 << 4, // "wider" operations cannot bring in higher order bits
	kNoSignedHAdd = 1 << 5, // no signed halving add
	kNoUnsignedHAdd = 1 << 6, // no unsigned halving add
	kNoUnroundedHAdd = 1 << 7, // no unrounded halving add
	kNoAbs = 1 << 8, // no absolute value
	kNoStringCharAt = 1 << 9, // no StringCharAt
	kNoReduction = 1 << 10, // no reduction
	kNoSAD = 1 << 11, // no sum of absolute differences (SAD)
	kNoWideSAD = 1 << 12, // no sum of absolute differences (SAD) with operand widening
	kNoDotProd = 1 << 13, // no dot product
	};

	/*
	* Vectorization mode during synthesis
	* (sequential peeling/cleanup loop or vector loop).
	*/
	enum VectorMode {
	kSequential,
	kVector
	};

	/*
	* Representation of a unit-stride array reference.
	*/
	struct ArrayReference {
	ArrayReference(HInstruction* b, HInstruction* o, DataType::Type t, bool l, bool c = false)
	: base(b), offset(o), type(t), lhs(l), is_string_char_at(c) { }
	bool operator<(const ArrayReference& other) const {
	return
	(base < other.base) \|\|
	(base == other.base &&
	(offset < other.offset \|\| (offset == other.offset &&
	(type < other.type \|\|
	(type == other.type &&
	(lhs < other.lhs \|\|
	(lhs == other.lhs &&
	is_string_char_at < other.is_string_char_at)))))));
	}
	HInstruction* base; // base address
	HInstruction* offset; // offset + i
	DataType::Type type; // component type
	bool lhs; // def/use
	bool is_string_char_at; // compressed string read
	};

	//
	// Loop setup and traversal.
	//

	bool LocalRun();
	void AddLoop(HLoopInformation* loop_info);
	void RemoveLoop(LoopNode* node);

	// Traverses all loops inner to outer to perform simplifications and optimizations.
	// Returns true if loops nested inside current loop (node) have changed.
	bool TraverseLoopsInnerToOuter(LoopNode* node);

	// Calculates `node`'s `try_catch_kind` and sets it to:
	// 1) kHasTryCatch if it has try catches (or if it's inside of an outer try catch)
	// 2) kNoTryCatch otherwise.
	void CalculateAndSetTryCatchKind(LoopNode* node);

	//
	// Optimization.
	//

	void SimplifyInduction(LoopNode* node);
	void SimplifyBlocks(LoopNode* node);

	// Performs optimizations specific to inner loop with finite header logic (empty loop removal,
	// unrolling, vectorization). Returns true if anything changed.
	bool TryOptimizeInnerLoopFinite(LoopNode* node);

	// Performs optimizations specific to inner loop. Returns true if anything changed.
	bool OptimizeInnerLoop(LoopNode* node);

	// Tries to apply loop unrolling for branch penalty reduction and better instruction scheduling
	// opportunities. Returns whether transformation happened. 'generate_code' determines whether the
	// optimization should be actually applied.
	bool TryUnrollingForBranchPenaltyReduction(LoopAnalysisInfo* analysis_info,
	bool generate_code = true);

	// Tries to apply loop peeling for loop invariant exits elimination. Returns whether
	// transformation happened. 'generate_code' determines whether the optimization should be
	// actually applied.
	bool TryPeelingForLoopInvariantExitsElimination(LoopAnalysisInfo* analysis_info,
	bool generate_code = true);

	// Tries to perform whole loop unrolling for a small loop with a small trip count to eliminate
	// the loop check overhead and to have more opportunities for inter-iteration optimizations.
	// Returns whether transformation happened. 'generate_code' determines whether the optimization
	// should be actually applied.
	bool TryFullUnrolling(LoopAnalysisInfo* analysis_info, bool generate_code = true);

	// Tries to remove SuspendCheck for plain loops with a low trip count. The
	// SuspendCheck in the codegen makes sure that the thread can be interrupted
	// during execution for GC. Not being able to do so might decrease the
	// responsiveness of GC when a very long loop or a long recursion is being
	// executed. However, for plain loops with a small trip count, the removal of
	// SuspendCheck should not affect the GC's responsiveness by a large margin.
	// Consequently, since the thread won't be interrupted for plain loops, it is
	// assumed that the performance might increase by removing SuspendCheck.
	bool TryToRemoveSuspendCheckFromLoopHeader(LoopAnalysisInfo* analysis_info,
	bool generate_code = true);

	// Tries to apply scalar loop optimizations.
	bool TryLoopScalarOpts(LoopNode* node);

	//
	// Vectorization analysis and synthesis.
	//

	bool ShouldVectorize(LoopNode* node, HBasicBlock* block, int64_t trip_count);
	void Vectorize(LoopNode* node, HBasicBlock* block, HBasicBlock* exit, int64_t trip_count);
	void GenerateNewLoop(LoopNode* node,
	HBasicBlock* block,
	HBasicBlock* new_preheader,
	HInstruction* lo,
	HInstruction* hi,
	HInstruction* step,
	uint32_t unroll);
	bool VectorizeDef(LoopNode* node, HInstruction* instruction, bool generate_code);
	bool VectorizeUse(LoopNode* node,
	HInstruction* instruction,
	bool generate_code,
	DataType::Type type,
	uint64_t restrictions);
	uint32_t GetVectorSizeInBytes();
	bool TrySetVectorType(DataType::Type type, /out/ uint64_t* restrictions);
	bool TrySetVectorLengthImpl(uint32_t length);

	bool TrySetVectorLength(DataType::Type type, uint32_t length) {
	bool res = TrySetVectorLengthImpl(length);
	// Currently the vectorizer supports only the mode when full SIMD registers are used.
	DCHECK_IMPLIES(res, DataType::Size(type) * length == GetVectorSizeInBytes());
	return res;
	}

	void GenerateVecInv(HInstruction* org, DataType::Type type);
	void GenerateVecSub(HInstruction* org, HInstruction* offset);
	void GenerateVecMem(HInstruction* org,
	HInstruction* opa,
	HInstruction* opb,
	HInstruction* offset,
	DataType::Type type);
	void GenerateVecReductionPhi(HPhi* phi);
	void GenerateVecReductionPhiInputs(HPhi* phi, HInstruction* reduction);
	HInstruction* ReduceAndExtractIfNeeded(HInstruction* instruction);
	void GenerateVecOp(HInstruction* org,
	HInstruction* opa,
	HInstruction* opb,
	DataType::Type type);

	// Vectorization idioms.
	bool VectorizeSaturationIdiom(LoopNode* node,
	HInstruction* instruction,
	bool generate_code,
	DataType::Type type,
	uint64_t restrictions);
	bool VectorizeHalvingAddIdiom(LoopNode* node,
	HInstruction* instruction,
	bool generate_code,
	DataType::Type type,
	uint64_t restrictions);
	bool VectorizeSADIdiom(LoopNode* node,
	HInstruction* instruction,
	bool generate_code,
	DataType::Type type,
	uint64_t restrictions);
	bool VectorizeDotProdIdiom(LoopNode* node,
	HInstruction* instruction,
	bool generate_code,
	DataType::Type type,
	uint64_t restrictions);

	// Vectorization heuristics.
	Alignment ComputeAlignment(HInstruction* offset,
	DataType::Type type,
	bool is_string_char_at,
	uint32_t peeling = 0);
	void SetAlignmentStrategy(const ScopedArenaVector<uint32_t>& peeling_votes,
	const ArrayReference* peeling_candidate);
	uint32_t MaxNumberPeeled();
	bool IsVectorizationProfitable(int64_t trip_count);

	//
	// Helpers.
	//

	bool TrySetPhiInduction(HPhi* phi, bool restrict_uses);
	bool TrySetPhiReduction(HPhi* phi);

	// Detects loop header with a single induction (returned in main_phi), possibly
	// other phis for reductions, but no other side effects. Returns true on success.
	bool TrySetSimpleLoopHeader(HBasicBlock* block, /out/ HPhi** main_phi);

	bool IsEmptyBody(HBasicBlock* block);
	bool IsOnlyUsedAfterLoop(HLoopInformation* loop_info,
	HInstruction* instruction,
	bool collect_loop_uses,
	/out/ uint32_t* use_count);
	bool IsUsedOutsideLoop(HLoopInformation* loop_info,
	HInstruction* instruction);
	bool TryReplaceWithLastValue(HLoopInformation* loop_info,
	HInstruction* instruction,
	HBasicBlock* block);
	bool TryAssignLastValue(HLoopInformation* loop_info,
	HInstruction* instruction,
	HBasicBlock* block,
	bool collect_loop_uses);
	void RemoveDeadInstructions(const HInstructionList& list);
	bool CanRemoveCycle(); // Whether the current 'iset_' is removable.

	bool IsInPredicatedVectorizationMode() const { return predicated_vectorization_mode_; }

	// Compiler options (to query ISA features).
	const CompilerOptions* compiler_options_;

	// Cached target SIMD vector register size in bytes.
	const size_t simd_register_size_;

	// Range information based on prior induction variable analysis.
	InductionVarRange induction_range_;

	// Phase-local heap memory allocator for the loop optimizer. Storage obtained
	// through this allocator is immediately released when the loop optimizer is done.
	ScopedArenaAllocator* loop_allocator_;

	// Global heap memory allocator. Used to build HIR.
	ArenaAllocator* global_allocator_;

	// Entries into the loop hierarchy representation. The hierarchy resides
	// in phase-local heap memory.
	LoopNode* top_loop_;
	LoopNode* last_loop_;

	// Temporary bookkeeping of a set of instructions.
	// Contents reside in phase-local heap memory.
	ScopedArenaSet<HInstruction> iset_;

	// Temporary bookkeeping of reduction instructions. Mapping is two-fold:
	// (1) reductions in the loop-body are mapped back to their phi definition,
	// (2) phi definitions are mapped to their initial value (updated during
	// code generation to feed the proper values into the new chain).
	// Contents reside in phase-local heap memory.
	ScopedArenaSafeMap<HInstruction, HInstruction>* reductions_;

	// Flag that tracks if any simplifications have occurred.
	bool simplified_;

	// Whether to use predicated loop vectorization (e.g. for arm64 SVE target).
	bool predicated_vectorization_mode_;

	// Number of "lanes" for selected packed type.
	uint32_t vector_length_;

	// Set of array references in the vector loop.
	// Contents reside in phase-local heap memory.
	ScopedArenaSet<ArrayReference>* vector_refs_;

	// Static or dynamic loop peeling for alignment.
	uint32_t vector_static_peeling_factor_;
	const ArrayReference* vector_dynamic_peeling_candidate_;

	// Dynamic data dependence test of the form a != b.
	HInstruction* vector_runtime_test_a_;
	HInstruction* vector_runtime_test_b_;

	// Mapping used during vectorization synthesis for both the scalar peeling/cleanup
	// loop (mode is kSequential) and the actual vector loop (mode is kVector). The data
	// structure maps original instructions into the new instructions.
	// Contents reside in phase-local heap memory.
	ScopedArenaSafeMap<HInstruction, HInstruction>* vector_map_;

	// Permanent mapping used during vectorization synthesis.
	// Contents reside in phase-local heap memory.
	ScopedArenaSafeMap<HInstruction, HInstruction>* vector_permanent_map_;

	// Temporary vectorization bookkeeping.
	VectorMode vector_mode_; // synthesis mode
	HBasicBlock* vector_preheader_; // preheader of the new loop
	HBasicBlock* vector_header_; // header of the new loop
	HBasicBlock* vector_body_; // body of the new loop
	HInstruction* vector_index_; // normalized index of the new loop

	// Helper for target-specific behaviour for loop optimizations.
	ArchNoOptsLoopHelper* arch_loop_helper_;

	friend class LoopOptimizationTest;

	DISALLOW_COPY_AND_ASSIGN(HLoopOptimization);
	};

	} // namespace art

	#endif // ART_COMPILER_OPTIMIZING_LOOP_OPTIMIZATION_H_