llvm/include/llvm/Analysis/DivergenceAnalysis.h - llvm-project - Git at Google

 //===- llvm/Analysis/DivergenceAnalysis.h - Divergence Analysis -*- C++ -*-===//
 //
 // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
 // See https://llvm.org/LICENSE.txt for license information.
 // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
 //
 //===----------------------------------------------------------------------===//
 //
 // \file
 // The divergence analysis determines which instructions and branches are
 // divergent given a set of divergent source instructions.
 //
 //===----------------------------------------------------------------------===//

 #ifndef LLVM_ANALYSIS_DIVERGENCE_ANALYSIS_H
 #define LLVM_ANALYSIS_DIVERGENCE_ANALYSIS_H

 #include "llvm/ADT/DenseSet.h"
 #include "llvm/Analysis/SyncDependenceAnalysis.h"
 #include "llvm/IR/Function.h"
 #include "llvm/Pass.h"
 #include <vector>

 namespace llvm {
 class Module;
 class Value;
 class Instruction;
 class Loop;
 class raw_ostream;
 class TargetTransformInfo;

 /// \brief Generic divergence analysis for reducible CFGs.
 ///
 /// This analysis propagates divergence in a data-parallel context from sources
 /// of divergence to all users. It requires reducible CFGs. All assignments
 /// should be in SSA form.
 class DivergenceAnalysis {
 public:
   /// \brief This instance will analyze the whole function \p F or the loop \p
   /// RegionLoop.
   ///
   /// \param RegionLoop if non-null the analysis is restricted to \p RegionLoop.
   /// Otherwise the whole function is analyzed.
   /// \param IsLCSSAForm whether the analysis may assume that the IR in the
   /// region in in LCSSA form.
   DivergenceAnalysis(const Function &F, const Loop *RegionLoop,
                      const DominatorTree &DT, const LoopInfo &LI,
                      SyncDependenceAnalysis &SDA, bool IsLCSSAForm);

   /// \brief The loop that defines the analyzed region (if any).
   const Loop *getRegionLoop() const { return RegionLoop; }
   const Function &getFunction() const { return F; }

   /// \brief Whether \p BB is part of the region.
   bool inRegion(const BasicBlock &BB) const;
   /// \brief Whether \p I is part of the region.
   bool inRegion(const Instruction &I) const;

   /// \brief Mark \p UniVal as a value that is always uniform.
   void addUniformOverride(const Value &UniVal);

   /// \brief Mark \p DivVal as a value that is always divergent. Will not do so
   /// if `isAlwaysUniform(DivVal)`.
   /// \returns Whether the tracked divergence state of \p DivVal changed.
   bool markDivergent(const Value &DivVal);

   /// \brief Propagate divergence to all instructions in the region.
   /// Divergence is seeded by calls to \p markDivergent.
   void compute();

   /// \brief Whether any value was marked or analyzed to be divergent.
   bool hasDetectedDivergence() const { return !DivergentValues.empty(); }

   /// \brief Whether \p Val will always return a uniform value regardless of its
   /// operands
   bool isAlwaysUniform(const Value &Val) const;

   /// \brief Whether \p Val is divergent at its definition.
   bool isDivergent(const Value &Val) const;

   /// \brief Whether \p U is divergent. Uses of a uniform value can be
   /// divergent.
   bool isDivergentUse(const Use &U) const;

   void print(raw_ostream &OS, const Module *) const;

 private:
   /// \brief Mark \p Term as divergent and push all Instructions that become
   /// divergent as a result on the worklist.
   void analyzeControlDivergence(const Instruction &Term);
   /// \brief Mark all phi nodes in \p JoinBlock as divergent and push them on
   /// the worklist.
   void taintAndPushPhiNodes(const BasicBlock &JoinBlock);

   /// \brief Identify all Instructions that become divergent because \p DivExit
   /// is a divergent loop exit of \p DivLoop. Mark those instructions as
   /// divergent and push them on the worklist.
   void propagateLoopExitDivergence(const BasicBlock &DivExit,
                                    const Loop &DivLoop);

   /// \brief Internal implementation function for propagateLoopExitDivergence.
   void analyzeLoopExitDivergence(const BasicBlock &DivExit,
                                  const Loop &OuterDivLoop);

   /// \brief Mark all instruction as divergent that use a value defined in \p
   /// OuterDivLoop. Push their users on the worklist.
   void analyzeTemporalDivergence(const Instruction &I,
                                  const Loop &OuterDivLoop);

   /// \brief Push all users of \p Val (in the region) to the worklist.
   void pushUsers(const Value &I);

   /// \brief Whether \p Val is divergent when read in \p ObservingBlock.
   bool isTemporalDivergent(const BasicBlock &ObservingBlock,
                            const Value &Val) const;

   /// \brief Whether \p Block is join divergent
   ///
   /// (see markBlockJoinDivergent).
   bool isJoinDivergent(const BasicBlock &Block) const {
     return DivergentJoinBlocks.contains(&Block);
   }

 private:
   const Function &F;
   // If regionLoop != nullptr, analysis is only performed within \p RegionLoop.
   // Otherwise, analyze the whole function
   const Loop *RegionLoop;

   const DominatorTree &DT;
   const LoopInfo &LI;

   // Recognized divergent loops
   DenseSet<const Loop *> DivergentLoops;

   // The SDA links divergent branches to divergent control-flow joins.
   SyncDependenceAnalysis &SDA;

   // Use simplified code path for LCSSA form.
   bool IsLCSSAForm;

   // Set of known-uniform values.
   DenseSet<const Value *> UniformOverrides;

   // Blocks with joining divergent control from different predecessors.
   DenseSet<const BasicBlock *> DivergentJoinBlocks; // FIXME Deprecated

   // Detected/marked divergent values.
   DenseSet<const Value *> DivergentValues;

   // Internal worklist for divergence propagation.
   std::vector<const Instruction *> Worklist;
 };

 /// \brief Divergence analysis frontend for GPU kernels.
 class GPUDivergenceAnalysis {
   SyncDependenceAnalysis SDA;
   DivergenceAnalysis DA;

 public:
   /// Runs the divergence analysis on @F, a GPU kernel
   GPUDivergenceAnalysis(Function &F, const DominatorTree &DT,
                         const PostDominatorTree &PDT, const LoopInfo &LI,
                         const TargetTransformInfo &TTI);

   /// Whether any divergence was detected.
   bool hasDivergence() const { return DA.hasDetectedDivergence(); }

   /// The GPU kernel this analysis result is for
   const Function &getFunction() const { return DA.getFunction(); }

   /// Whether \p V is divergent at its definition.
   bool isDivergent(const Value &V) const;

   /// Whether \p U is divergent. Uses of a uniform value can be divergent.
   bool isDivergentUse(const Use &U) const;

   /// Whether \p V is uniform/non-divergent.
   bool isUniform(const Value &V) const { return !isDivergent(V); }

   /// Whether \p U is uniform/non-divergent. Uses of a uniform value can be
   /// divergent.
   bool isUniformUse(const Use &U) const { return !isDivergentUse(U); }

   /// Print all divergent values in the kernel.
   void print(raw_ostream &OS, const Module *) const;
 };

 } // namespace llvm

 #endif // LLVM_ANALYSIS_DIVERGENCE_ANALYSIS_H
	//===- llvm/Analysis/DivergenceAnalysis.h - Divergence Analysis -- C++ --===//
	//
	// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
	// See https://llvm.org/LICENSE.txt for license information.
	// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
	//
	//===----------------------------------------------------------------------===//
	//
	// \file
	// The divergence analysis determines which instructions and branches are
	// divergent given a set of divergent source instructions.
	//
	//===----------------------------------------------------------------------===//

	#ifndef LLVM_ANALYSIS_DIVERGENCE_ANALYSIS_H
	#define LLVM_ANALYSIS_DIVERGENCE_ANALYSIS_H

	#include "llvm/ADT/DenseSet.h"
	#include "llvm/Analysis/SyncDependenceAnalysis.h"
	#include "llvm/IR/Function.h"
	#include "llvm/Pass.h"
	#include <vector>

	namespace llvm {
	class Module;
	class Value;
	class Instruction;
	class Loop;
	class raw_ostream;
	class TargetTransformInfo;

	/// \brief Generic divergence analysis for reducible CFGs.
	///
	/// This analysis propagates divergence in a data-parallel context from sources
	/// of divergence to all users. It requires reducible CFGs. All assignments
	/// should be in SSA form.
	class DivergenceAnalysis {
	public:
	/// \brief This instance will analyze the whole function \p F or the loop \p
	/// RegionLoop.
	///
	/// \param RegionLoop if non-null the analysis is restricted to \p RegionLoop.
	/// Otherwise the whole function is analyzed.
	/// \param IsLCSSAForm whether the analysis may assume that the IR in the
	/// region in in LCSSA form.
	DivergenceAnalysis(const Function &F, const Loop *RegionLoop,
	const DominatorTree &DT, const LoopInfo &LI,
	SyncDependenceAnalysis &SDA, bool IsLCSSAForm);

	/// \brief The loop that defines the analyzed region (if any).
	const Loop *getRegionLoop() const { return RegionLoop; }
	const Function &getFunction() const { return F; }

	/// \brief Whether \p BB is part of the region.
	bool inRegion(const BasicBlock &BB) const;
	/// \brief Whether \p I is part of the region.
	bool inRegion(const Instruction &I) const;

	/// \brief Mark \p UniVal as a value that is always uniform.
	void addUniformOverride(const Value &UniVal);

	/// \brief Mark \p DivVal as a value that is always divergent. Will not do so
	/// if `isAlwaysUniform(DivVal)`.
	/// \returns Whether the tracked divergence state of \p DivVal changed.
	bool markDivergent(const Value &DivVal);

	/// \brief Propagate divergence to all instructions in the region.
	/// Divergence is seeded by calls to \p markDivergent.
	void compute();

	/// \brief Whether any value was marked or analyzed to be divergent.
	bool hasDetectedDivergence() const { return !DivergentValues.empty(); }

	/// \brief Whether \p Val will always return a uniform value regardless of its
	/// operands
	bool isAlwaysUniform(const Value &Val) const;

	/// \brief Whether \p Val is divergent at its definition.
	bool isDivergent(const Value &Val) const;

	/// \brief Whether \p U is divergent. Uses of a uniform value can be
	/// divergent.
	bool isDivergentUse(const Use &U) const;

	void print(raw_ostream &OS, const Module *) const;

	private:
	/// \brief Mark \p Term as divergent and push all Instructions that become
	/// divergent as a result on the worklist.
	void analyzeControlDivergence(const Instruction &Term);
	/// \brief Mark all phi nodes in \p JoinBlock as divergent and push them on
	/// the worklist.
	void taintAndPushPhiNodes(const BasicBlock &JoinBlock);

	/// \brief Identify all Instructions that become divergent because \p DivExit
	/// is a divergent loop exit of \p DivLoop. Mark those instructions as
	/// divergent and push them on the worklist.
	void propagateLoopExitDivergence(const BasicBlock &DivExit,
	const Loop &DivLoop);

	/// \brief Internal implementation function for propagateLoopExitDivergence.
	void analyzeLoopExitDivergence(const BasicBlock &DivExit,
	const Loop &OuterDivLoop);

	/// \brief Mark all instruction as divergent that use a value defined in \p
	/// OuterDivLoop. Push their users on the worklist.
	void analyzeTemporalDivergence(const Instruction &I,
	const Loop &OuterDivLoop);

	/// \brief Push all users of \p Val (in the region) to the worklist.
	void pushUsers(const Value &I);

	/// \brief Whether \p Val is divergent when read in \p ObservingBlock.
	bool isTemporalDivergent(const BasicBlock &ObservingBlock,
	const Value &Val) const;

	/// \brief Whether \p Block is join divergent
	///
	/// (see markBlockJoinDivergent).
	bool isJoinDivergent(const BasicBlock &Block) const {
	return DivergentJoinBlocks.contains(&Block);
	}

	private:
	const Function &F;
	// If regionLoop != nullptr, analysis is only performed within \p RegionLoop.
	// Otherwise, analyze the whole function
	const Loop *RegionLoop;

	const DominatorTree &DT;
	const LoopInfo &LI;

	// Recognized divergent loops
	DenseSet<const Loop *> DivergentLoops;

	// The SDA links divergent branches to divergent control-flow joins.
	SyncDependenceAnalysis &SDA;

	// Use simplified code path for LCSSA form.
	bool IsLCSSAForm;

	// Set of known-uniform values.
	DenseSet<const Value *> UniformOverrides;

	// Blocks with joining divergent control from different predecessors.
	DenseSet<const BasicBlock *> DivergentJoinBlocks; // FIXME Deprecated

	// Detected/marked divergent values.
	DenseSet<const Value *> DivergentValues;

	// Internal worklist for divergence propagation.
	std::vector<const Instruction *> Worklist;
	};

	/// \brief Divergence analysis frontend for GPU kernels.
	class GPUDivergenceAnalysis {
	SyncDependenceAnalysis SDA;
	DivergenceAnalysis DA;

	public:
	/// Runs the divergence analysis on @F, a GPU kernel
	GPUDivergenceAnalysis(Function &F, const DominatorTree &DT,
	const PostDominatorTree &PDT, const LoopInfo &LI,
	const TargetTransformInfo &TTI);

	/// Whether any divergence was detected.
	bool hasDivergence() const { return DA.hasDetectedDivergence(); }

	/// The GPU kernel this analysis result is for
	const Function &getFunction() const { return DA.getFunction(); }

	/// Whether \p V is divergent at its definition.
	bool isDivergent(const Value &V) const;

	/// Whether \p U is divergent. Uses of a uniform value can be divergent.
	bool isDivergentUse(const Use &U) const;

	/// Whether \p V is uniform/non-divergent.
	bool isUniform(const Value &V) const { return !isDivergent(V); }

	/// Whether \p U is uniform/non-divergent. Uses of a uniform value can be
	/// divergent.
	bool isUniformUse(const Use &U) const { return !isDivergentUse(U); }

	/// Print all divergent values in the kernel.
	void print(raw_ostream &OS, const Module *) const;
	};

	} // namespace llvm

	#endif // LLVM_ANALYSIS_DIVERGENCE_ANALYSIS_H