compiler/optimizing/scheduler.h - platform/art - Git at Google

 /*
  * 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_SCHEDULER_H_
 #define ART_COMPILER_OPTIMIZING_SCHEDULER_H_

 #include <fstream>

 #include "base/scoped_arena_allocator.h"
 #include "base/scoped_arena_containers.h"
 #include "base/time_utils.h"
 #include "code_generator.h"
 #include "load_store_analysis.h"
 #include "nodes.h"
 #include "optimization.h"

 namespace art {

 // General description of instruction scheduling.
 //
 // This pass tries to improve the quality of the generated code by reordering
 // instructions in the graph to avoid execution delays caused by execution
 // dependencies.
 // Currently, scheduling is performed at the block level, so no `HInstruction`
 // ever leaves its block in this pass.
 //
 // The scheduling process iterates through blocks in the graph. For blocks that
 // we can and want to schedule:
 // 1) Build a dependency graph for instructions.
 //    It includes data dependencies (inputs/uses), but also environment
 //    dependencies and side-effect dependencies.
 // 2) Schedule the dependency graph.
 //    This is a topological sort of the dependency graph, using heuristics to
 //    decide what node to scheduler first when there are multiple candidates.
 //
 // A few factors impacting the quality of the scheduling are:
 // - The heuristics used to decide what node to schedule in the topological sort
 //   when there are multiple valid candidates. There is a wide range of
 //   complexity possible here, going from a simple model only considering
 //   latencies, to a super detailed CPU pipeline model.
 // - Fewer dependencies in the dependency graph give more freedom for the
 //   scheduling heuristics. For example de-aliasing can allow possibilities for
 //   reordering of memory accesses.
 // - The level of abstraction of the IR. It is easier to evaluate scheduling for
 //   IRs that translate to a single assembly instruction than for IRs
 //   that generate multiple assembly instructions or generate different code
 //   depending on properties of the IR.
 // - Scheduling is performed before register allocation, it is not aware of the
 //   impact of moving instructions on register allocation.
 //
 //
 // The scheduling code uses the terms predecessors, successors, and dependencies.
 // This can be confusing at times, so here are clarifications.
 // These terms are used from the point of view of the program dependency graph. So
 // the inputs of an instruction are part of its dependencies, and hence part its
 // predecessors. So the uses of an instruction are (part of) its successors.
 // (Side-effect dependencies can yield predecessors or successors that are not
 // inputs or uses.)
 //
 // Here is a trivial example. For the Java code:
 //
 //    int a = 1 + 2;
 //
 // we would have the instructions
 //
 //    i1 HIntConstant 1
 //    i2 HIntConstant 2
 //    i3 HAdd [i1,i2]
 //
 // `i1` and `i2` are predecessors of `i3`.
 // `i3` is a successor of `i1` and a successor of `i2`.
 // In a scheduling graph for this code we would have three nodes `n1`, `n2`,
 // and `n3` (respectively for instructions `i1`, `i1`, and `i3`).
 // Conceptually the program dependency graph for this would contain two edges
 //
 //    n1 -> n3
 //    n2 -> n3
 //
 // Since we schedule backwards (starting from the last instruction in each basic
 // block), the implementation of nodes keeps a list of pointers their
 // predecessors. So `n3` would keep pointers to its predecessors `n1` and `n2`.
 //
 // Node dependencies are also referred to from the program dependency graph
 // point of view: we say that node `B` immediately depends on `A` if there is an
 // edge from `A` to `B` in the program dependency graph. `A` is a predecessor of
 // `B`, `B` is a successor of `A`. In the example above `n3` depends on `n1` and
 // `n2`.
 // Since nodes in the scheduling graph keep a list of their predecessors, node
 // `B` will have a pointer to its predecessor `A`.
 // As we schedule backwards, `B` will be selected for scheduling before `A` is.
 //
 // So the scheduling for the example above could happen as follow
 //
 //    |---------------------------+------------------------|
 //    | candidates for scheduling | instructions scheduled |
 //    | --------------------------+------------------------|
 //
 // The only node without successors is `n3`, so it is the only initial
 // candidate.
 //
 //    | n3                        | (none)                 |
 //
 // We schedule `n3` as the last (and only) instruction. All its predecessors
 // that do not have any unscheduled successors become candidate. That is, `n1`
 // and `n2` become candidates.
 //
 //    | n1, n2                    | n3                     |
 //
 // One of the candidates is selected. In practice this is where scheduling
 // heuristics kick in, to decide which of the candidates should be selected.
 // In this example, let it be `n1`. It is scheduled before previously scheduled
 // nodes (in program order). There are no other nodes to add to the list of
 // candidates.
 //
 //    | n2                        | n1                     |
 //    |                           | n3                     |
 //
 // The only candidate available for scheduling is `n2`. Schedule it before
 // (in program order) the previously scheduled nodes.
 //
 //    | (none)                    | n2                     |
 //    |                           | n1                     |
 //    |                           | n3                     |
 //    |---------------------------+------------------------|
 //
 // So finally the instructions will be executed in the order `i2`, `i1`, and `i3`.
 // In this trivial example, it does not matter which of `i1` and `i2` is
 // scheduled first since they are constants. However the same process would
 // apply if `i1` and `i2` were actual operations (for example `HMul` and `HDiv`).

 // Set to true to have instruction scheduling dump scheduling graphs to the file
 // `scheduling_graphs.dot`. See `SchedulingGraph::DumpAsDotGraph()`.
 static constexpr bool kDumpDotSchedulingGraphs = false;

 // Typically used as a default instruction latency.
 static constexpr uint32_t kGenericInstructionLatency = 1;

 class HScheduler;

 /**
  * A node representing an `HInstruction` in the `SchedulingGraph`.
  */
 class SchedulingNode : public DeletableArenaObject<kArenaAllocScheduler> {
  public:
   SchedulingNode(HInstruction* instr, ScopedArenaAllocator* allocator, bool is_scheduling_barrier)
       : latency_(0),
         internal_latency_(0),
         critical_path_(0),
         instruction_(instr),
         is_scheduling_barrier_(is_scheduling_barrier),
         data_predecessors_(allocator->Adapter(kArenaAllocScheduler)),
         other_predecessors_(allocator->Adapter(kArenaAllocScheduler)),
         num_unscheduled_successors_(0) {
     data_predecessors_.reserve(kPreallocatedPredecessors);
   }

   void AddDataPredecessor(SchedulingNode* predecessor) {
     data_predecessors_.push_back(predecessor);
     predecessor->num_unscheduled_successors_++;
   }

   const ScopedArenaVector<SchedulingNode*>& GetDataPredecessors() const {
     return data_predecessors_;
   }

   void AddOtherPredecessor(SchedulingNode* predecessor) {
     other_predecessors_.push_back(predecessor);
     predecessor->num_unscheduled_successors_++;
   }

   const ScopedArenaVector<SchedulingNode*>& GetOtherPredecessors() const {
     return other_predecessors_;
   }

   void DecrementNumberOfUnscheduledSuccessors() {
     num_unscheduled_successors_--;
   }

   void MaybeUpdateCriticalPath(uint32_t other_critical_path) {
     critical_path_ = std::max(critical_path_, other_critical_path);
   }

   bool HasUnscheduledSuccessors() const {
     return num_unscheduled_successors_ != 0;
   }

   HInstruction* GetInstruction() const { return instruction_; }
   uint32_t GetLatency() const { return latency_; }
   void SetLatency(uint32_t latency) { latency_ = latency; }
   uint32_t GetInternalLatency() const { return internal_latency_; }
   void SetInternalLatency(uint32_t internal_latency) { internal_latency_ = internal_latency; }
   uint32_t GetCriticalPath() const { return critical_path_; }
   bool IsSchedulingBarrier() const { return is_scheduling_barrier_; }

  private:
   // The latency of this node. It represents the latency between the moment the
   // last instruction for this node has executed to the moment the result
   // produced by this node is available to users.
   uint32_t latency_;
   // This represents the time spent *within* the generated code for this node.
   // It should be zero for nodes that only generate a single instruction.
   uint32_t internal_latency_;

   // The critical path from this instruction to the end of scheduling. It is
   // used by the scheduling heuristics to measure the priority of this instruction.
   // It is defined as
   //     critical_path_ = latency_ + max((use.internal_latency_ + use.critical_path_) for all uses)
   // (Note that here 'uses' is equivalent to 'data successors'. Also see comments in
   // `HScheduler::Schedule(SchedulingNode* scheduling_node)`).
   uint32_t critical_path_;

   // The instruction that this node represents.
   HInstruction* const instruction_;

   // If a node is scheduling barrier, other nodes cannot be scheduled before it.
   const bool is_scheduling_barrier_;

   // The lists of predecessors. They cannot be scheduled before this node. Once
   // this node is scheduled, we check whether any of its predecessors has become a
   // valid candidate for scheduling.
   // Predecessors in `data_predecessors_` are data dependencies. Those in
   // `other_predecessors_` contain side-effect dependencies, environment
   // dependencies, and scheduling barrier dependencies.
   ScopedArenaVector<SchedulingNode*> data_predecessors_;
   ScopedArenaVector<SchedulingNode*> other_predecessors_;

   // The number of unscheduled successors for this node. This number is
   // decremented as successors are scheduled. When it reaches zero this node
   // becomes a valid candidate to schedule.
   uint32_t num_unscheduled_successors_;

   static constexpr size_t kPreallocatedPredecessors = 4;
 };

 /*
  * Directed acyclic graph for scheduling.
  */
 class SchedulingGraph : public ValueObject {
  public:
   SchedulingGraph(const HScheduler* scheduler,
                   ScopedArenaAllocator* allocator,
                   const HeapLocationCollector* heap_location_collector)
       : scheduler_(scheduler),
         allocator_(allocator),
         contains_scheduling_barrier_(false),
         nodes_map_(allocator_->Adapter(kArenaAllocScheduler)),
         heap_location_collector_(heap_location_collector) {}

   SchedulingNode* AddNode(HInstruction* instr, bool is_scheduling_barrier = false) {
     std::unique_ptr<SchedulingNode> node(
         new (allocator_) SchedulingNode(instr, allocator_, is_scheduling_barrier));
     SchedulingNode* result = node.get();
     nodes_map_.insert(std::make_pair(instr, std::move(node)));
     contains_scheduling_barrier_ |= is_scheduling_barrier;
     AddDependencies(instr, is_scheduling_barrier);
     return result;
   }

   SchedulingNode* GetNode(const HInstruction* instr) const {
     auto it = nodes_map_.find(instr);
     if (it == nodes_map_.end()) {
       return nullptr;
     } else {
       return it->second.get();
     }
   }

   bool IsSchedulingBarrier(const HInstruction* instruction) const;

   bool HasImmediateDataDependency(const SchedulingNode* node, const SchedulingNode* other) const;
   bool HasImmediateDataDependency(const HInstruction* node, const HInstruction* other) const;
   bool HasImmediateOtherDependency(const SchedulingNode* node, const SchedulingNode* other) const;
   bool HasImmediateOtherDependency(const HInstruction* node, const HInstruction* other) const;

   size_t Size() const {
     return nodes_map_.size();
   }

   // Dump the scheduling graph, in dot file format, appending it to the file
   // `scheduling_graphs.dot`.
   void DumpAsDotGraph(const std::string& description,
                       const ScopedArenaVector<SchedulingNode*>& initial_candidates);

  protected:
   void AddDependency(SchedulingNode* node, SchedulingNode* dependency, bool is_data_dependency);
   void AddDataDependency(SchedulingNode* node, SchedulingNode* dependency) {
     AddDependency(node, dependency, /*is_data_dependency*/true);
   }
   void AddOtherDependency(SchedulingNode* node, SchedulingNode* dependency) {
     AddDependency(node, dependency, /*is_data_dependency*/false);
   }
   bool HasMemoryDependency(HInstruction* node, HInstruction* other) const;
   bool HasExceptionDependency(const HInstruction* node, const HInstruction* other) const;
   bool HasSideEffectDependency(HInstruction* node, HInstruction* other) const;
   bool ArrayAccessMayAlias(HInstruction* node, HInstruction* other) const;
   bool FieldAccessMayAlias(const HInstruction* node, const HInstruction* other) const;
   size_t ArrayAccessHeapLocation(HInstruction* instruction) const;
   size_t FieldAccessHeapLocation(HInstruction* obj, const FieldInfo* field) const;

   // Add dependencies nodes for the given `HInstruction`: inputs, environments, and side-effects.
   void AddDependencies(HInstruction* instruction, bool is_scheduling_barrier = false);

   const HScheduler* const scheduler_;

   ScopedArenaAllocator* const allocator_;

   bool contains_scheduling_barrier_;

   ScopedArenaHashMap<const HInstruction*, std::unique_ptr<SchedulingNode>> nodes_map_;

   const HeapLocationCollector* const heap_location_collector_;
 };

 /*
  * The visitors derived from this base class are used by schedulers to evaluate
  * the latencies of `HInstruction`s.
  */
 class SchedulingLatencyVisitor : public HGraphDelegateVisitor {
  public:
   // This class and its sub-classes will never be used to drive a visit of an
   // `HGraph` but only to visit `HInstructions` one at a time, so we do not need
   // to pass a valid graph to `HGraphDelegateVisitor()`.
   SchedulingLatencyVisitor()
       : HGraphDelegateVisitor(nullptr),
         last_visited_latency_(0),
         last_visited_internal_latency_(0) {}

   void VisitInstruction(HInstruction* instruction) override {
     LOG(FATAL) << "Error visiting " << instruction->DebugName() << ". "
         "Architecture-specific scheduling latency visitors must handle all instructions"
         " (potentially by overriding the generic `VisitInstruction()`.";
     UNREACHABLE();
   }

   void Visit(HInstruction* instruction) {
     instruction->Accept(this);
   }

   void CalculateLatency(SchedulingNode* node) {
     // By default nodes have no internal latency.
     last_visited_internal_latency_ = 0;
     Visit(node->GetInstruction());
   }

   uint32_t GetLastVisitedLatency() const { return last_visited_latency_; }
   uint32_t GetLastVisitedInternalLatency() const { return last_visited_internal_latency_; }

  protected:
   // The latency of the most recent visited SchedulingNode.
   // This is for reporting the latency value to the user of this visitor.
   uint32_t last_visited_latency_;
   // This represents the time spent *within* the generated code for the most recent visited
   // SchedulingNode. This is for reporting the internal latency value to the user of this visitor.
   uint32_t last_visited_internal_latency_;
 };

 class SchedulingNodeSelector : public ArenaObject<kArenaAllocScheduler> {
  public:
   virtual void Reset() {}
   virtual SchedulingNode* PopHighestPriorityNode(ScopedArenaVector<SchedulingNode*>* nodes,
                                                  const SchedulingGraph& graph) = 0;
   virtual ~SchedulingNodeSelector() {}
  protected:
   static void DeleteNodeAtIndex(ScopedArenaVector<SchedulingNode*>* nodes, size_t index) {
     (*nodes)[index] = nodes->back();
     nodes->pop_back();
   }
 };

 /*
  * Select a `SchedulingNode` at random within the candidates.
  */
 class RandomSchedulingNodeSelector : public SchedulingNodeSelector {
  public:
   RandomSchedulingNodeSelector() : seed_(0) {
     seed_  = static_cast<uint32_t>(NanoTime());
     srand(seed_);
   }

   SchedulingNode* PopHighestPriorityNode(ScopedArenaVector<SchedulingNode*>* nodes,
                                          const SchedulingGraph& graph) override {
     UNUSED(graph);
     DCHECK(!nodes->empty());
     size_t select = rand_r(&seed_) % nodes->size();
     SchedulingNode* select_node = (*nodes)[select];
     DeleteNodeAtIndex(nodes, select);
     return select_node;
   }

   uint32_t seed_;
 };

 /*
  * Select a `SchedulingNode` according to critical path information,
  * with heuristics to favor certain instruction patterns like materialized condition.
  */
 class CriticalPathSchedulingNodeSelector : public SchedulingNodeSelector {
  public:
   CriticalPathSchedulingNodeSelector() : prev_select_(nullptr) {}

   void Reset() override { prev_select_ = nullptr; }
   SchedulingNode* PopHighestPriorityNode(ScopedArenaVector<SchedulingNode*>* nodes,
                                          const SchedulingGraph& graph) override;

  protected:
   SchedulingNode* GetHigherPrioritySchedulingNode(SchedulingNode* candidate,
                                                   SchedulingNode* check) const;

   SchedulingNode* SelectMaterializedCondition(ScopedArenaVector<SchedulingNode*>* nodes,
                                               const SchedulingGraph& graph) const;

  private:
   const SchedulingNode* prev_select_;
 };

 class HScheduler {
  public:
   HScheduler(SchedulingLatencyVisitor* latency_visitor, SchedulingNodeSelector* selector)
       : latency_visitor_(latency_visitor),
         selector_(selector),
         only_optimize_loop_blocks_(true),
         cursor_(nullptr) {}
   virtual ~HScheduler() {}

   void Schedule(HGraph* graph);

   void SetOnlyOptimizeLoopBlocks(bool loop_only) { only_optimize_loop_blocks_ = loop_only; }

   // Instructions can not be rescheduled across a scheduling barrier.
   virtual bool IsSchedulingBarrier(const HInstruction* instruction) const;

  protected:
   void Schedule(HBasicBlock* block, const HeapLocationCollector* heap_location_collector);
   void Schedule(SchedulingNode* scheduling_node,
                 /*inout*/ ScopedArenaVector<SchedulingNode*>* candidates);
   void Schedule(HInstruction* instruction);

   // Any instruction returning `false` via this method will prevent its
   // containing basic block from being scheduled.
   // This method is used to restrict scheduling to instructions that we know are
   // safe to handle.
   //
   // For newly introduced instructions by default HScheduler::IsSchedulable returns false.
   // HScheduler${ARCH}::IsSchedulable can be overridden to return true for an instruction (see
   // scheduler_arm64.h for example) if it is safe to schedule it; in this case one *must* also
   // look at/update HScheduler${ARCH}::IsSchedulingBarrier for this instruction.
   virtual bool IsSchedulable(const HInstruction* instruction) const;
   bool IsSchedulable(const HBasicBlock* block) const;

   void CalculateLatency(SchedulingNode* node) {
     latency_visitor_->CalculateLatency(node);
     node->SetLatency(latency_visitor_->GetLastVisitedLatency());
     node->SetInternalLatency(latency_visitor_->GetLastVisitedInternalLatency());
   }

   SchedulingLatencyVisitor* const latency_visitor_;
   SchedulingNodeSelector* const selector_;
   bool only_optimize_loop_blocks_;

   // A pointer indicating where the next instruction to be scheduled will be inserted.
   HInstruction* cursor_;

  private:
   DISALLOW_COPY_AND_ASSIGN(HScheduler);
 };

 inline bool SchedulingGraph::IsSchedulingBarrier(const HInstruction* instruction) const {
   return scheduler_->IsSchedulingBarrier(instruction);
 }

 class HInstructionScheduling : public HOptimization {
  public:
   HInstructionScheduling(HGraph* graph,
                          InstructionSet instruction_set,
                          CodeGenerator* cg = nullptr,
                          const char* name = kInstructionSchedulingPassName)
       : HOptimization(graph, name),
         codegen_(cg),
         instruction_set_(instruction_set) {}

   bool Run() override {
     return Run(/*only_optimize_loop_blocks*/ true, /*schedule_randomly*/ false);
   }

   bool Run(bool only_optimize_loop_blocks, bool schedule_randomly);

   static constexpr const char* kInstructionSchedulingPassName = "scheduler";

  private:
   CodeGenerator* const codegen_;
   const InstructionSet instruction_set_;
   DISALLOW_COPY_AND_ASSIGN(HInstructionScheduling);
 };

 }  // namespace art

 #endif  // ART_COMPILER_OPTIMIZING_SCHEDULER_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_SCHEDULER_H_
	#define ART_COMPILER_OPTIMIZING_SCHEDULER_H_

	#include <fstream>

	#include "base/scoped_arena_allocator.h"
	#include "base/scoped_arena_containers.h"
	#include "base/time_utils.h"
	#include "code_generator.h"
	#include "load_store_analysis.h"
	#include "nodes.h"
	#include "optimization.h"

	namespace art {

	// General description of instruction scheduling.
	//
	// This pass tries to improve the quality of the generated code by reordering
	// instructions in the graph to avoid execution delays caused by execution
	// dependencies.
	// Currently, scheduling is performed at the block level, so no `HInstruction`
	// ever leaves its block in this pass.
	//
	// The scheduling process iterates through blocks in the graph. For blocks that
	// we can and want to schedule:
	// 1) Build a dependency graph for instructions.
	// It includes data dependencies (inputs/uses), but also environment
	// dependencies and side-effect dependencies.
	// 2) Schedule the dependency graph.
	// This is a topological sort of the dependency graph, using heuristics to
	// decide what node to scheduler first when there are multiple candidates.
	//
	// A few factors impacting the quality of the scheduling are:
	// - The heuristics used to decide what node to schedule in the topological sort
	// when there are multiple valid candidates. There is a wide range of
	// complexity possible here, going from a simple model only considering
	// latencies, to a super detailed CPU pipeline model.
	// - Fewer dependencies in the dependency graph give more freedom for the
	// scheduling heuristics. For example de-aliasing can allow possibilities for
	// reordering of memory accesses.
	// - The level of abstraction of the IR. It is easier to evaluate scheduling for
	// IRs that translate to a single assembly instruction than for IRs
	// that generate multiple assembly instructions or generate different code
	// depending on properties of the IR.
	// - Scheduling is performed before register allocation, it is not aware of the
	// impact of moving instructions on register allocation.
	//
	//
	// The scheduling code uses the terms predecessors, successors, and dependencies.
	// This can be confusing at times, so here are clarifications.
	// These terms are used from the point of view of the program dependency graph. So
	// the inputs of an instruction are part of its dependencies, and hence part its
	// predecessors. So the uses of an instruction are (part of) its successors.
	// (Side-effect dependencies can yield predecessors or successors that are not
	// inputs or uses.)
	//
	// Here is a trivial example. For the Java code:
	//
	// int a = 1 + 2;
	//
	// we would have the instructions
	//
	// i1 HIntConstant 1
	// i2 HIntConstant 2
	// i3 HAdd [i1,i2]
	//
	// `i1` and `i2` are predecessors of `i3`.
	// `i3` is a successor of `i1` and a successor of `i2`.
	// In a scheduling graph for this code we would have three nodes `n1`, `n2`,
	// and `n3` (respectively for instructions `i1`, `i1`, and `i3`).
	// Conceptually the program dependency graph for this would contain two edges
	//
	// n1 -> n3
	// n2 -> n3
	//
	// Since we schedule backwards (starting from the last instruction in each basic
	// block), the implementation of nodes keeps a list of pointers their
	// predecessors. So `n3` would keep pointers to its predecessors `n1` and `n2`.
	//
	// Node dependencies are also referred to from the program dependency graph
	// point of view: we say that node `B` immediately depends on `A` if there is an
	// edge from `A` to `B` in the program dependency graph. `A` is a predecessor of
	// `B`, `B` is a successor of `A`. In the example above `n3` depends on `n1` and
	// `n2`.
	// Since nodes in the scheduling graph keep a list of their predecessors, node
	// `B` will have a pointer to its predecessor `A`.
	// As we schedule backwards, `B` will be selected for scheduling before `A` is.
	//
	// So the scheduling for the example above could happen as follow
	//
	// \|---------------------------+------------------------\|
	// \| candidates for scheduling \| instructions scheduled \|
	// \| --------------------------+------------------------\|
	//
	// The only node without successors is `n3`, so it is the only initial
	// candidate.
	//
	// \| n3 \| (none) \|
	//
	// We schedule `n3` as the last (and only) instruction. All its predecessors
	// that do not have any unscheduled successors become candidate. That is, `n1`
	// and `n2` become candidates.
	//
	// \| n1, n2 \| n3 \|
	//
	// One of the candidates is selected. In practice this is where scheduling
	// heuristics kick in, to decide which of the candidates should be selected.
	// In this example, let it be `n1`. It is scheduled before previously scheduled
	// nodes (in program order). There are no other nodes to add to the list of
	// candidates.
	//
	// \| n2 \| n1 \|
	// \| \| n3 \|
	//
	// The only candidate available for scheduling is `n2`. Schedule it before
	// (in program order) the previously scheduled nodes.
	//
	// \| (none) \| n2 \|
	// \| \| n1 \|
	// \| \| n3 \|
	// \|---------------------------+------------------------\|
	//
	// So finally the instructions will be executed in the order `i2`, `i1`, and `i3`.
	// In this trivial example, it does not matter which of `i1` and `i2` is
	// scheduled first since they are constants. However the same process would
	// apply if `i1` and `i2` were actual operations (for example `HMul` and `HDiv`).

	// Set to true to have instruction scheduling dump scheduling graphs to the file
	// `scheduling_graphs.dot`. See `SchedulingGraph::DumpAsDotGraph()`.
	static constexpr bool kDumpDotSchedulingGraphs = false;

	// Typically used as a default instruction latency.
	static constexpr uint32_t kGenericInstructionLatency = 1;

	class HScheduler;

	/**
	* A node representing an `HInstruction` in the `SchedulingGraph`.
	*/
	class SchedulingNode : public DeletableArenaObject<kArenaAllocScheduler> {
	public:
	SchedulingNode(HInstruction* instr, ScopedArenaAllocator* allocator, bool is_scheduling_barrier)
	: latency_(0),
	internal_latency_(0),
	critical_path_(0),
	instruction_(instr),
	is_scheduling_barrier_(is_scheduling_barrier),
	data_predecessors_(allocator->Adapter(kArenaAllocScheduler)),
	other_predecessors_(allocator->Adapter(kArenaAllocScheduler)),
	num_unscheduled_successors_(0) {
	data_predecessors_.reserve(kPreallocatedPredecessors);
	}

	void AddDataPredecessor(SchedulingNode* predecessor) {
	data_predecessors_.push_back(predecessor);
	predecessor->num_unscheduled_successors_++;
	}

	const ScopedArenaVector<SchedulingNode*>& GetDataPredecessors() const {
	return data_predecessors_;
	}

	void AddOtherPredecessor(SchedulingNode* predecessor) {
	other_predecessors_.push_back(predecessor);
	predecessor->num_unscheduled_successors_++;
	}

	const ScopedArenaVector<SchedulingNode*>& GetOtherPredecessors() const {
	return other_predecessors_;
	}

	void DecrementNumberOfUnscheduledSuccessors() {
	num_unscheduled_successors_--;
	}

	void MaybeUpdateCriticalPath(uint32_t other_critical_path) {
	critical_path_ = std::max(critical_path_, other_critical_path);
	}

	bool HasUnscheduledSuccessors() const {
	return num_unscheduled_successors_ != 0;
	}

	HInstruction* GetInstruction() const { return instruction_; }
	uint32_t GetLatency() const { return latency_; }
	void SetLatency(uint32_t latency) { latency_ = latency; }
	uint32_t GetInternalLatency() const { return internal_latency_; }
	void SetInternalLatency(uint32_t internal_latency) { internal_latency_ = internal_latency; }
	uint32_t GetCriticalPath() const { return critical_path_; }
	bool IsSchedulingBarrier() const { return is_scheduling_barrier_; }

	private:
	// The latency of this node. It represents the latency between the moment the
	// last instruction for this node has executed to the moment the result
	// produced by this node is available to users.
	uint32_t latency_;
	// This represents the time spent within the generated code for this node.
	// It should be zero for nodes that only generate a single instruction.
	uint32_t internal_latency_;

	// The critical path from this instruction to the end of scheduling. It is
	// used by the scheduling heuristics to measure the priority of this instruction.
	// It is defined as
	// critical_path_ = latency_ + max((use.internal_latency_ + use.critical_path_) for all uses)
	// (Note that here 'uses' is equivalent to 'data successors'. Also see comments in
	// `HScheduler::Schedule(SchedulingNode* scheduling_node)`).
	uint32_t critical_path_;

	// The instruction that this node represents.
	HInstruction* const instruction_;

	// If a node is scheduling barrier, other nodes cannot be scheduled before it.
	const bool is_scheduling_barrier_;

	// The lists of predecessors. They cannot be scheduled before this node. Once
	// this node is scheduled, we check whether any of its predecessors has become a
	// valid candidate for scheduling.
	// Predecessors in `data_predecessors_` are data dependencies. Those in
	// `other_predecessors_` contain side-effect dependencies, environment
	// dependencies, and scheduling barrier dependencies.
	ScopedArenaVector<SchedulingNode*> data_predecessors_;
	ScopedArenaVector<SchedulingNode*> other_predecessors_;

	// The number of unscheduled successors for this node. This number is
	// decremented as successors are scheduled. When it reaches zero this node
	// becomes a valid candidate to schedule.
	uint32_t num_unscheduled_successors_;

	static constexpr size_t kPreallocatedPredecessors = 4;
	};

	/*
	* Directed acyclic graph for scheduling.
	*/
	class SchedulingGraph : public ValueObject {
	public:
	SchedulingGraph(const HScheduler* scheduler,
	ScopedArenaAllocator* allocator,
	const HeapLocationCollector* heap_location_collector)
	: scheduler_(scheduler),
	allocator_(allocator),
	contains_scheduling_barrier_(false),
	nodes_map_(allocator_->Adapter(kArenaAllocScheduler)),
	heap_location_collector_(heap_location_collector) {}

	SchedulingNode* AddNode(HInstruction* instr, bool is_scheduling_barrier = false) {
	std::unique_ptr<SchedulingNode> node(
	new (allocator_) SchedulingNode(instr, allocator_, is_scheduling_barrier));
	SchedulingNode* result = node.get();
	nodes_map_.insert(std::make_pair(instr, std::move(node)));
	contains_scheduling_barrier_ \|= is_scheduling_barrier;
	AddDependencies(instr, is_scheduling_barrier);
	return result;
	}

	SchedulingNode* GetNode(const HInstruction* instr) const {
	auto it = nodes_map_.find(instr);
	if (it == nodes_map_.end()) {
	return nullptr;
	} else {
	return it->second.get();
	}
	}

	bool IsSchedulingBarrier(const HInstruction* instruction) const;

	bool HasImmediateDataDependency(const SchedulingNode* node, const SchedulingNode* other) const;
	bool HasImmediateDataDependency(const HInstruction* node, const HInstruction* other) const;
	bool HasImmediateOtherDependency(const SchedulingNode* node, const SchedulingNode* other) const;
	bool HasImmediateOtherDependency(const HInstruction* node, const HInstruction* other) const;

	size_t Size() const {
	return nodes_map_.size();
	}

	// Dump the scheduling graph, in dot file format, appending it to the file
	// `scheduling_graphs.dot`.
	void DumpAsDotGraph(const std::string& description,
	const ScopedArenaVector<SchedulingNode*>& initial_candidates);

	protected:
	void AddDependency(SchedulingNode* node, SchedulingNode* dependency, bool is_data_dependency);
	void AddDataDependency(SchedulingNode* node, SchedulingNode* dependency) {
	AddDependency(node, dependency, /is_data_dependency/true);
	}
	void AddOtherDependency(SchedulingNode* node, SchedulingNode* dependency) {
	AddDependency(node, dependency, /is_data_dependency/false);
	}
	bool HasMemoryDependency(HInstruction* node, HInstruction* other) const;
	bool HasExceptionDependency(const HInstruction* node, const HInstruction* other) const;
	bool HasSideEffectDependency(HInstruction* node, HInstruction* other) const;
	bool ArrayAccessMayAlias(HInstruction* node, HInstruction* other) const;
	bool FieldAccessMayAlias(const HInstruction* node, const HInstruction* other) const;
	size_t ArrayAccessHeapLocation(HInstruction* instruction) const;
	size_t FieldAccessHeapLocation(HInstruction* obj, const FieldInfo* field) const;

	// Add dependencies nodes for the given `HInstruction`: inputs, environments, and side-effects.
	void AddDependencies(HInstruction* instruction, bool is_scheduling_barrier = false);

	const HScheduler* const scheduler_;

	ScopedArenaAllocator* const allocator_;

	bool contains_scheduling_barrier_;

	ScopedArenaHashMap<const HInstruction*, std::unique_ptr<SchedulingNode>> nodes_map_;

	const HeapLocationCollector* const heap_location_collector_;
	};

	/*
	* The visitors derived from this base class are used by schedulers to evaluate
	* the latencies of `HInstruction`s.
	*/
	class SchedulingLatencyVisitor : public HGraphDelegateVisitor {
	public:
	// This class and its sub-classes will never be used to drive a visit of an
	// `HGraph` but only to visit `HInstructions` one at a time, so we do not need
	// to pass a valid graph to `HGraphDelegateVisitor()`.
	SchedulingLatencyVisitor()
	: HGraphDelegateVisitor(nullptr),
	last_visited_latency_(0),
	last_visited_internal_latency_(0) {}

	void VisitInstruction(HInstruction* instruction) override {
	LOG(FATAL) << "Error visiting " << instruction->DebugName() << ". "
	"Architecture-specific scheduling latency visitors must handle all instructions"
	" (potentially by overriding the generic `VisitInstruction()`.";
	UNREACHABLE();
	}

	void Visit(HInstruction* instruction) {
	instruction->Accept(this);
	}

	void CalculateLatency(SchedulingNode* node) {
	// By default nodes have no internal latency.
	last_visited_internal_latency_ = 0;
	Visit(node->GetInstruction());
	}

	uint32_t GetLastVisitedLatency() const { return last_visited_latency_; }
	uint32_t GetLastVisitedInternalLatency() const { return last_visited_internal_latency_; }

	protected:
	// The latency of the most recent visited SchedulingNode.
	// This is for reporting the latency value to the user of this visitor.
	uint32_t last_visited_latency_;
	// This represents the time spent within the generated code for the most recent visited
	// SchedulingNode. This is for reporting the internal latency value to the user of this visitor.
	uint32_t last_visited_internal_latency_;
	};

	class SchedulingNodeSelector : public ArenaObject<kArenaAllocScheduler> {
	public:
	virtual void Reset() {}
	virtual SchedulingNode* PopHighestPriorityNode(ScopedArenaVector<SchedulingNode> nodes,
	const SchedulingGraph& graph) = 0;
	virtual ~SchedulingNodeSelector() {}
	protected:
	static void DeleteNodeAtIndex(ScopedArenaVector<SchedulingNode> nodes, size_t index) {
	(*nodes)[index] = nodes->back();
	nodes->pop_back();
	}
	};

	/*
	* Select a `SchedulingNode` at random within the candidates.
	*/
	class RandomSchedulingNodeSelector : public SchedulingNodeSelector {
	public:
	RandomSchedulingNodeSelector() : seed_(0) {
	seed_ = static_cast<uint32_t>(NanoTime());
	srand(seed_);
	}

	SchedulingNode* PopHighestPriorityNode(ScopedArenaVector<SchedulingNode> nodes,
	const SchedulingGraph& graph) override {
	UNUSED(graph);
	DCHECK(!nodes->empty());
	size_t select = rand_r(&seed_) % nodes->size();
	SchedulingNode* select_node = (*nodes)[select];
	DeleteNodeAtIndex(nodes, select);
	return select_node;
	}

	uint32_t seed_;
	};

	/*
	* Select a `SchedulingNode` according to critical path information,
	* with heuristics to favor certain instruction patterns like materialized condition.
	*/
	class CriticalPathSchedulingNodeSelector : public SchedulingNodeSelector {
	public:
	CriticalPathSchedulingNodeSelector() : prev_select_(nullptr) {}

	void Reset() override { prev_select_ = nullptr; }
	SchedulingNode* PopHighestPriorityNode(ScopedArenaVector<SchedulingNode> nodes,
	const SchedulingGraph& graph) override;

	protected:
	SchedulingNode* GetHigherPrioritySchedulingNode(SchedulingNode* candidate,
	SchedulingNode* check) const;

	SchedulingNode* SelectMaterializedCondition(ScopedArenaVector<SchedulingNode> nodes,
	const SchedulingGraph& graph) const;

	private:
	const SchedulingNode* prev_select_;
	};

	class HScheduler {
	public:
	HScheduler(SchedulingLatencyVisitor* latency_visitor, SchedulingNodeSelector* selector)
	: latency_visitor_(latency_visitor),
	selector_(selector),
	only_optimize_loop_blocks_(true),
	cursor_(nullptr) {}
	virtual ~HScheduler() {}

	void Schedule(HGraph* graph);

	void SetOnlyOptimizeLoopBlocks(bool loop_only) { only_optimize_loop_blocks_ = loop_only; }

	// Instructions can not be rescheduled across a scheduling barrier.
	virtual bool IsSchedulingBarrier(const HInstruction* instruction) const;

	protected:
	void Schedule(HBasicBlock* block, const HeapLocationCollector* heap_location_collector);
	void Schedule(SchedulingNode* scheduling_node,
	/inout/ ScopedArenaVector<SchedulingNode> candidates);
	void Schedule(HInstruction* instruction);

	// Any instruction returning `false` via this method will prevent its
	// containing basic block from being scheduled.
	// This method is used to restrict scheduling to instructions that we know are
	// safe to handle.
	//
	// For newly introduced instructions by default HScheduler::IsSchedulable returns false.
	// HScheduler${ARCH}::IsSchedulable can be overridden to return true for an instruction (see
	// scheduler_arm64.h for example) if it is safe to schedule it; in this case one must also
	// look at/update HScheduler${ARCH}::IsSchedulingBarrier for this instruction.
	virtual bool IsSchedulable(const HInstruction* instruction) const;
	bool IsSchedulable(const HBasicBlock* block) const;

	void CalculateLatency(SchedulingNode* node) {
	latency_visitor_->CalculateLatency(node);
	node->SetLatency(latency_visitor_->GetLastVisitedLatency());
	node->SetInternalLatency(latency_visitor_->GetLastVisitedInternalLatency());
	}

	SchedulingLatencyVisitor* const latency_visitor_;
	SchedulingNodeSelector* const selector_;
	bool only_optimize_loop_blocks_;

	// A pointer indicating where the next instruction to be scheduled will be inserted.
	HInstruction* cursor_;

	private:
	DISALLOW_COPY_AND_ASSIGN(HScheduler);
	};

	inline bool SchedulingGraph::IsSchedulingBarrier(const HInstruction* instruction) const {
	return scheduler_->IsSchedulingBarrier(instruction);
	}

	class HInstructionScheduling : public HOptimization {
	public:
	HInstructionScheduling(HGraph* graph,
	InstructionSet instruction_set,
	CodeGenerator* cg = nullptr,
	const char* name = kInstructionSchedulingPassName)
	: HOptimization(graph, name),
	codegen_(cg),
	instruction_set_(instruction_set) {}

	bool Run() override {
	return Run(/only_optimize_loop_blocks/ true, /schedule_randomly/ false);
	}

	bool Run(bool only_optimize_loop_blocks, bool schedule_randomly);

	static constexpr const char* kInstructionSchedulingPassName = "scheduler";

	private:
	CodeGenerator* const codegen_;
	const InstructionSet instruction_set_;
	DISALLOW_COPY_AND_ASSIGN(HInstructionScheduling);
	};

	} // namespace art

	#endif // ART_COMPILER_OPTIMIZING_SCHEDULER_H_