third_party/SPIRV-Tools/source/opt/dataflow.h - SwiftShader - Git at Google

 // Copyright (c) 2021 Google LLC.
 //
 // 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 SOURCE_OPT_DATAFLOW_H_
 #define SOURCE_OPT_DATAFLOW_H_

 #include <queue>
 #include <unordered_map>
 #include <vector>

 #include "source/opt/instruction.h"
 #include "source/opt/ir_context.h"

 namespace spvtools {
 namespace opt {

 // Generic data-flow analysis.
 // Maintains a worklist of instructions to process and processes them in a
 // specified order. See also ForwardDataFlowAnalysis, which is specialized for
 // forward data-flow analysis.
 class DataFlowAnalysis {
  public:
   // The result of a |Visit| operation on an instruction.
   // This is used to determine when analysis has reached a fixpoint.
   enum class VisitResult {
     // The analysis result for this instruction has changed.
     // This means that any instructions that depend on it (its successors) must
     // be recomputed.
     kResultChanged,
     // The analysis result for this instruction has not changed.
     // When all visit operations return |kResultFixed|, the analysis has reached
     // a fixpoint (converged).
     kResultFixed,
   };

   virtual ~DataFlowAnalysis() {}

   // Run this analysis on a given function.
   // For analyses which work interprocedurally, |function| may be ignored.
   void Run(Function* function);

  protected:
   DataFlowAnalysis(IRContext& context) : context_(context) {}

   // Initialize the worklist for a given function.
   // |is_first_iteration| is true on the first call to |Run| and false
   // afterwards. All subsequent runs are only necessary to check if the analysis
   // has converged; if |EnqueueSuccessors| is complete, |InitializeWorklist|
   // should do nothing after the first iteration.
   virtual void InitializeWorklist(Function* function,
                                   bool is_first_iteration) = 0;

   // Enqueues the successors (instructions which use the analysis result) of
   // |inst|. This is not required to be complete, but convergence is faster when
   // it is. This is called whenever |Visit| returns |kResultChanged|.
   virtual void EnqueueSuccessors(Instruction* inst) = 0;

   // Visits the given instruction, recomputing the analysis result. This is
   // called once per instruction queued in |InitializeWorklist| and afterward
   // when a predecessor is changed, through |EnqueueSuccessors|.
   virtual VisitResult Visit(Instruction* inst) = 0;

   // Enqueues the given instruction to be visited. Ignored if already in the
   // worklist.
   bool Enqueue(Instruction* inst);

   IRContext& context() { return context_; }

  private:
   // Runs one pass, calling |InitializeWorklist| and then iterating through the
   // worklist until all fixed.
   VisitResult RunOnce(Function* function, bool is_first_iteration);

   IRContext& context_;
   std::unordered_map<Instruction*, bool> on_worklist_;
   // The worklist, which contains the list of instructions to be visited.
   //
   // The choice of data structure was influenced by the data in "Iterative
   // Data-flow Analysis, Revisited" (Cooper et al, 2002).
   // https://citeseerx.ist.psu.edu/viewdoc/download?doi=10.1.1.125.1549&rep=rep1&type=pdf
   // The paper shows that the overall performance benefit of a priority queue
   // over a regular queue or stack is relatively small (or negative).
   //
   // A queue has the advantage that nodes are visited in the same order they are
   // enqueued, which relieves the analysis from inserting nodes "backwards", for
   // example in worklist initialization. Also, as the paper claims that sorting
   // successors does not improve runtime, we can use a single queue which is
   // modified during iteration.
   std::queue<Instruction*> worklist_;
 };

 // A generic data flow analysis, specialized for forward analysis.
 class ForwardDataFlowAnalysis : public DataFlowAnalysis {
  public:
   // Indicates where labels should be in the worklist RPO ordering.
   enum class LabelPosition {
     // Labels should be placed at the beginning of their blocks.
     kLabelsAtBeginning,
     // Labels should be placed at the end of their blocks.
     kLabelsAtEnd,
     // Labels should not be in the worklist.
     kNoLabels,
     // Only labels should be placed in the worklist.
     kLabelsOnly,
   };

   ForwardDataFlowAnalysis(IRContext& context, LabelPosition label_position)
       : DataFlowAnalysis(context), label_position_(label_position) {}

  protected:
   // Initializes the worklist in reverse postorder, regardless of
   // |is_first_iteration|. Labels are placed according to the label position
   // specified in the constructor.
   void InitializeWorklist(Function* function, bool is_first_iteration) override;

   // Enqueues the users and block successors of the given instruction.
   // See |EnqueueUsers| and |EnqueueBlockSuccessors|.
   void EnqueueSuccessors(Instruction* inst) override {
     EnqueueUsers(inst);
     EnqueueBlockSuccessors(inst);
   }

   // Enqueues the users of the given instruction.
   void EnqueueUsers(Instruction* inst);

   // Enqueues the labels of the successors of the block corresponding to the
   // given label instruction. Does nothing for other instructions.
   void EnqueueBlockSuccessors(Instruction* inst);

  private:
   LabelPosition label_position_;
 };

 }  // namespace opt
 }  // namespace spvtools

 #endif  // SOURCE_OPT_DATAFLOW_H_
	// Copyright (c) 2021 Google LLC.
	//
	// 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 SOURCE_OPT_DATAFLOW_H_
	#define SOURCE_OPT_DATAFLOW_H_

	#include <queue>
	#include <unordered_map>
	#include <vector>

	#include "source/opt/instruction.h"
	#include "source/opt/ir_context.h"

	namespace spvtools {
	namespace opt {

	// Generic data-flow analysis.
	// Maintains a worklist of instructions to process and processes them in a
	// specified order. See also ForwardDataFlowAnalysis, which is specialized for
	// forward data-flow analysis.
	class DataFlowAnalysis {
	public:
	// The result of a \|Visit\| operation on an instruction.
	// This is used to determine when analysis has reached a fixpoint.
	enum class VisitResult {
	// The analysis result for this instruction has changed.
	// This means that any instructions that depend on it (its successors) must
	// be recomputed.
	kResultChanged,
	// The analysis result for this instruction has not changed.
	// When all visit operations return \|kResultFixed\|, the analysis has reached
	// a fixpoint (converged).
	kResultFixed,
	};

	virtual ~DataFlowAnalysis() {}

	// Run this analysis on a given function.
	// For analyses which work interprocedurally, \|function\| may be ignored.
	void Run(Function* function);

	protected:
	DataFlowAnalysis(IRContext& context) : context_(context) {}

	// Initialize the worklist for a given function.
	// \|is_first_iteration\| is true on the first call to \|Run\| and false
	// afterwards. All subsequent runs are only necessary to check if the analysis
	// has converged; if \|EnqueueSuccessors\| is complete, \|InitializeWorklist\|
	// should do nothing after the first iteration.
	virtual void InitializeWorklist(Function* function,
	bool is_first_iteration) = 0;

	// Enqueues the successors (instructions which use the analysis result) of
	// \|inst\|. This is not required to be complete, but convergence is faster when
	// it is. This is called whenever \|Visit\| returns \|kResultChanged\|.
	virtual void EnqueueSuccessors(Instruction* inst) = 0;

	// Visits the given instruction, recomputing the analysis result. This is
	// called once per instruction queued in \|InitializeWorklist\| and afterward
	// when a predecessor is changed, through \|EnqueueSuccessors\|.
	virtual VisitResult Visit(Instruction* inst) = 0;

	// Enqueues the given instruction to be visited. Ignored if already in the
	// worklist.
	bool Enqueue(Instruction* inst);

	IRContext& context() { return context_; }

	private:
	// Runs one pass, calling \|InitializeWorklist\| and then iterating through the
	// worklist until all fixed.
	VisitResult RunOnce(Function* function, bool is_first_iteration);

	IRContext& context_;
	std::unordered_map<Instruction*, bool> on_worklist_;
	// The worklist, which contains the list of instructions to be visited.
	//
	// The choice of data structure was influenced by the data in "Iterative
	// Data-flow Analysis, Revisited" (Cooper et al, 2002).
	// https://citeseerx.ist.psu.edu/viewdoc/download?doi=10.1.1.125.1549&rep=rep1&type=pdf
	// The paper shows that the overall performance benefit of a priority queue
	// over a regular queue or stack is relatively small (or negative).
	//
	// A queue has the advantage that nodes are visited in the same order they are
	// enqueued, which relieves the analysis from inserting nodes "backwards", for
	// example in worklist initialization. Also, as the paper claims that sorting
	// successors does not improve runtime, we can use a single queue which is
	// modified during iteration.
	std::queue<Instruction*> worklist_;
	};

	// A generic data flow analysis, specialized for forward analysis.
	class ForwardDataFlowAnalysis : public DataFlowAnalysis {
	public:
	// Indicates where labels should be in the worklist RPO ordering.
	enum class LabelPosition {
	// Labels should be placed at the beginning of their blocks.
	kLabelsAtBeginning,
	// Labels should be placed at the end of their blocks.
	kLabelsAtEnd,
	// Labels should not be in the worklist.
	kNoLabels,
	// Only labels should be placed in the worklist.
	kLabelsOnly,
	};

	ForwardDataFlowAnalysis(IRContext& context, LabelPosition label_position)
	: DataFlowAnalysis(context), label_position_(label_position) {}

	protected:
	// Initializes the worklist in reverse postorder, regardless of
	// \|is_first_iteration\|. Labels are placed according to the label position
	// specified in the constructor.
	void InitializeWorklist(Function* function, bool is_first_iteration) override;

	// Enqueues the users and block successors of the given instruction.
	// See \|EnqueueUsers\| and \|EnqueueBlockSuccessors\|.
	void EnqueueSuccessors(Instruction* inst) override {
	EnqueueUsers(inst);
	EnqueueBlockSuccessors(inst);
	}

	// Enqueues the users of the given instruction.
	void EnqueueUsers(Instruction* inst);

	// Enqueues the labels of the successors of the block corresponding to the
	// given label instruction. Does nothing for other instructions.
	void EnqueueBlockSuccessors(Instruction* inst);

	private:
	LabelPosition label_position_;
	};

	} // namespace opt
	} // namespace spvtools

	#endif // SOURCE_OPT_DATAFLOW_H_