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

 //===- llvm/Analysis/DependenceGraphBuilder.h -------------------*- 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
 //
 //===----------------------------------------------------------------------===//
 //
 // This file defines a builder interface that can be used to populate dependence
 // graphs such as DDG and PDG.
 //
 //===----------------------------------------------------------------------===//

 #ifndef LLVM_ANALYSIS_DEPENDENCEGRAPHBUILDER_H
 #define LLVM_ANALYSIS_DEPENDENCEGRAPHBUILDER_H

 #include "llvm/ADT/DenseMap.h"
 #include "llvm/ADT/EquivalenceClasses.h"
 #include "llvm/ADT/SmallVector.h"

 namespace llvm {

 class BasicBlock;
 class DependenceInfo;
 class Instruction;

 /// This abstract builder class defines a set of high-level steps for creating
 /// DDG-like graphs. The client code is expected to inherit from this class and
 /// define concrete implementation for each of the pure virtual functions used
 /// in the high-level algorithm.
 template <class GraphType> class AbstractDependenceGraphBuilder {
 protected:
   using BasicBlockListType = SmallVectorImpl<BasicBlock *>;

 private:
   using NodeType = typename GraphType::NodeType;
   using EdgeType = typename GraphType::EdgeType;

 public:
   using ClassesType = EquivalenceClasses<BasicBlock *>;
   using NodeListType = SmallVector<NodeType *, 4>;

   AbstractDependenceGraphBuilder(GraphType &G, DependenceInfo &D,
                                  const BasicBlockListType &BBs)
       : Graph(G), DI(D), BBList(BBs) {}
   virtual ~AbstractDependenceGraphBuilder() {}

   /// The main entry to the graph construction algorithm. It starts by
   /// creating nodes in increasing order of granularity and then
   /// adds def-use and memory edges. As one of the final stages, it
   /// also creates pi-block nodes to facilitate codegen in transformations
   /// that use dependence graphs.
   ///
   /// The algorithmic complexity of this implementation is O(V^2 * I^2), where V
   /// is the number of vertecies (nodes) and I is the number of instructions in
   /// each node. The total number of instructions, N, is equal to V * I,
   /// therefore the worst-case time complexity is O(N^2). The average time
   /// complexity is O((N^2)/2).
   void populate() {
     computeInstructionOrdinals();
     createFineGrainedNodes();
     createDefUseEdges();
     createMemoryDependencyEdges();
     simplify();
     createAndConnectRootNode();
     createPiBlocks();
     sortNodesTopologically();
   }

   /// Compute ordinal numbers for each instruction and store them in a map for
   /// future look up. These ordinals are used to compute node ordinals which are
   /// in turn used to order nodes that are part of a cycle.
   /// Instruction ordinals are assigned based on lexical program order.
   void computeInstructionOrdinals();

   /// Create fine grained nodes. These are typically atomic nodes that
   /// consist of a single instruction.
   void createFineGrainedNodes();

   /// Analyze the def-use chains and create edges from the nodes containing
   /// definitions to the nodes containing the uses.
   void createDefUseEdges();

   /// Analyze data dependencies that exist between memory loads or stores,
   /// in the graph nodes and create edges between them.
   void createMemoryDependencyEdges();

   /// Create a root node and add edges such that each node in the graph is
   /// reachable from the root.
   void createAndConnectRootNode();

   /// Apply graph abstraction to groups of nodes that belong to a strongly
   /// connected component of the graph to create larger compound nodes
   /// called pi-blocks. The purpose of this abstraction is to isolate sets of
   /// program elements that need to stay together during codegen and turn
   /// the dependence graph into an acyclic graph.
   void createPiBlocks();

   /// Go through all the nodes in the graph and collapse any two nodes
   /// 'a' and 'b' if all of the following are true:
   ///   - the only edge from 'a' is a def-use edge to 'b' and
   ///   - the only edge to 'b' is a def-use edge from 'a' and
   ///   - there is no cyclic edge from 'b' to 'a' and
   ///   - all instructions in 'a' and 'b' belong to the same basic block and
   ///   - both 'a' and 'b' are simple (single or multi instruction) nodes.
   void simplify();

   /// Topologically sort the graph nodes.
   void sortNodesTopologically();

 protected:
   /// Create the root node of the graph.
   virtual NodeType &createRootNode() = 0;

   /// Create an atomic node in the graph given a single instruction.
   virtual NodeType &createFineGrainedNode(Instruction &I) = 0;

   /// Create a pi-block node in the graph representing a group of nodes in an
   /// SCC of the graph.
   virtual NodeType &createPiBlock(const NodeListType &L) = 0;

   /// Create a def-use edge going from \p Src to \p Tgt.
   virtual EdgeType &createDefUseEdge(NodeType &Src, NodeType &Tgt) = 0;

   /// Create a memory dependence edge going from \p Src to \p Tgt.
   virtual EdgeType &createMemoryEdge(NodeType &Src, NodeType &Tgt) = 0;

   /// Create a rooted edge going from \p Src to \p Tgt .
   virtual EdgeType &createRootedEdge(NodeType &Src, NodeType &Tgt) = 0;

   /// Given a pi-block node, return a vector of all the nodes contained within
   /// it.
   virtual const NodeListType &getNodesInPiBlock(const NodeType &N) = 0;

   /// Deallocate memory of edge \p E.
   virtual void destroyEdge(EdgeType &E) { delete &E; }

   /// Deallocate memory of node \p N.
   virtual void destroyNode(NodeType &N) { delete &N; }

   /// Return true if creation of pi-blocks are supported and desired,
   /// and false otherwise.
   virtual bool shouldCreatePiBlocks() const { return true; }

   /// Return true if graph simplification step is requested, and false
   /// otherwise.
   virtual bool shouldSimplify() const { return true; }

   /// Return true if it's safe to merge the two nodes.
   virtual bool areNodesMergeable(const NodeType &A,
                                  const NodeType &B) const = 0;

   /// Append the content of node \p B into node \p A and remove \p B and
   /// the edge between \p A and \p B from the graph.
   virtual void mergeNodes(NodeType &A, NodeType &B) = 0;

   /// Given an instruction \p I return its associated ordinal number.
   size_t getOrdinal(Instruction &I) {
     assert(InstOrdinalMap.find(&I) != InstOrdinalMap.end() &&
            "No ordinal computed for this instruction.");
     return InstOrdinalMap[&I];
   }

   /// Given a node \p N return its associated ordinal number.
   size_t getOrdinal(NodeType &N) {
     assert(NodeOrdinalMap.find(&N) != NodeOrdinalMap.end() &&
            "No ordinal computed for this node.");
     return NodeOrdinalMap[&N];
   }

   /// Map types to map instructions to nodes used when populating the graph.
   using InstToNodeMap = DenseMap<Instruction *, NodeType *>;

   /// Map Types to map instruction/nodes to an ordinal number.
   using InstToOrdinalMap = DenseMap<Instruction *, size_t>;
   using NodeToOrdinalMap = DenseMap<NodeType *, size_t>;

   /// Reference to the graph that gets built by a concrete implementation of
   /// this builder.
   GraphType &Graph;

   /// Dependence information used to create memory dependence edges in the
   /// graph.
   DependenceInfo &DI;

   /// The list of basic blocks to consider when building the graph.
   const BasicBlockListType &BBList;

   /// A mapping from instructions to the corresponding nodes in the graph.
   InstToNodeMap IMap;

   /// A mapping from each instruction to an ordinal number. This map is used to
   /// populate the \p NodeOrdinalMap.
   InstToOrdinalMap InstOrdinalMap;

   /// A mapping from nodes to an ordinal number. This map is used to sort nodes
   /// in a pi-block based on program order.
   NodeToOrdinalMap NodeOrdinalMap;
 };

 } // namespace llvm

 #endif // LLVM_ANALYSIS_DEPENDENCEGRAPHBUILDER_H
	//===- llvm/Analysis/DependenceGraphBuilder.h -------------------- 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
	//
	//===----------------------------------------------------------------------===//
	//
	// This file defines a builder interface that can be used to populate dependence
	// graphs such as DDG and PDG.
	//
	//===----------------------------------------------------------------------===//

	#ifndef LLVM_ANALYSIS_DEPENDENCEGRAPHBUILDER_H
	#define LLVM_ANALYSIS_DEPENDENCEGRAPHBUILDER_H

	#include "llvm/ADT/DenseMap.h"
	#include "llvm/ADT/EquivalenceClasses.h"
	#include "llvm/ADT/SmallVector.h"

	namespace llvm {

	class BasicBlock;
	class DependenceInfo;
	class Instruction;

	/// This abstract builder class defines a set of high-level steps for creating
	/// DDG-like graphs. The client code is expected to inherit from this class and
	/// define concrete implementation for each of the pure virtual functions used
	/// in the high-level algorithm.
	template <class GraphType> class AbstractDependenceGraphBuilder {
	protected:
	using BasicBlockListType = SmallVectorImpl<BasicBlock *>;

	private:
	using NodeType = typename GraphType::NodeType;
	using EdgeType = typename GraphType::EdgeType;

	public:
	using ClassesType = EquivalenceClasses<BasicBlock *>;
	using NodeListType = SmallVector<NodeType *, 4>;

	AbstractDependenceGraphBuilder(GraphType &G, DependenceInfo &D,
	const BasicBlockListType &BBs)
	: Graph(G), DI(D), BBList(BBs) {}
	virtual ~AbstractDependenceGraphBuilder() {}

	/// The main entry to the graph construction algorithm. It starts by
	/// creating nodes in increasing order of granularity and then
	/// adds def-use and memory edges. As one of the final stages, it
	/// also creates pi-block nodes to facilitate codegen in transformations
	/// that use dependence graphs.
	///
	/// The algorithmic complexity of this implementation is O(V^2 * I^2), where V
	/// is the number of vertecies (nodes) and I is the number of instructions in
	/// each node. The total number of instructions, N, is equal to V * I,
	/// therefore the worst-case time complexity is O(N^2). The average time
	/// complexity is O((N^2)/2).
	void populate() {
	computeInstructionOrdinals();
	createFineGrainedNodes();
	createDefUseEdges();
	createMemoryDependencyEdges();
	simplify();
	createAndConnectRootNode();
	createPiBlocks();
	sortNodesTopologically();
	}

	/// Compute ordinal numbers for each instruction and store them in a map for
	/// future look up. These ordinals are used to compute node ordinals which are
	/// in turn used to order nodes that are part of a cycle.
	/// Instruction ordinals are assigned based on lexical program order.
	void computeInstructionOrdinals();

	/// Create fine grained nodes. These are typically atomic nodes that
	/// consist of a single instruction.
	void createFineGrainedNodes();

	/// Analyze the def-use chains and create edges from the nodes containing
	/// definitions to the nodes containing the uses.
	void createDefUseEdges();

	/// Analyze data dependencies that exist between memory loads or stores,
	/// in the graph nodes and create edges between them.
	void createMemoryDependencyEdges();

	/// Create a root node and add edges such that each node in the graph is
	/// reachable from the root.
	void createAndConnectRootNode();

	/// Apply graph abstraction to groups of nodes that belong to a strongly
	/// connected component of the graph to create larger compound nodes
	/// called pi-blocks. The purpose of this abstraction is to isolate sets of
	/// program elements that need to stay together during codegen and turn
	/// the dependence graph into an acyclic graph.
	void createPiBlocks();

	/// Go through all the nodes in the graph and collapse any two nodes
	/// 'a' and 'b' if all of the following are true:
	/// - the only edge from 'a' is a def-use edge to 'b' and
	/// - the only edge to 'b' is a def-use edge from 'a' and
	/// - there is no cyclic edge from 'b' to 'a' and
	/// - all instructions in 'a' and 'b' belong to the same basic block and
	/// - both 'a' and 'b' are simple (single or multi instruction) nodes.
	void simplify();

	/// Topologically sort the graph nodes.
	void sortNodesTopologically();

	protected:
	/// Create the root node of the graph.
	virtual NodeType &createRootNode() = 0;

	/// Create an atomic node in the graph given a single instruction.
	virtual NodeType &createFineGrainedNode(Instruction &I) = 0;

	/// Create a pi-block node in the graph representing a group of nodes in an
	/// SCC of the graph.
	virtual NodeType &createPiBlock(const NodeListType &L) = 0;

	/// Create a def-use edge going from \p Src to \p Tgt.
	virtual EdgeType &createDefUseEdge(NodeType &Src, NodeType &Tgt) = 0;

	/// Create a memory dependence edge going from \p Src to \p Tgt.
	virtual EdgeType &createMemoryEdge(NodeType &Src, NodeType &Tgt) = 0;

	/// Create a rooted edge going from \p Src to \p Tgt .
	virtual EdgeType &createRootedEdge(NodeType &Src, NodeType &Tgt) = 0;

	/// Given a pi-block node, return a vector of all the nodes contained within
	/// it.
	virtual const NodeListType &getNodesInPiBlock(const NodeType &N) = 0;

	/// Deallocate memory of edge \p E.
	virtual void destroyEdge(EdgeType &E) { delete &E; }

	/// Deallocate memory of node \p N.
	virtual void destroyNode(NodeType &N) { delete &N; }

	/// Return true if creation of pi-blocks are supported and desired,
	/// and false otherwise.
	virtual bool shouldCreatePiBlocks() const { return true; }

	/// Return true if graph simplification step is requested, and false
	/// otherwise.
	virtual bool shouldSimplify() const { return true; }

	/// Return true if it's safe to merge the two nodes.
	virtual bool areNodesMergeable(const NodeType &A,
	const NodeType &B) const = 0;

	/// Append the content of node \p B into node \p A and remove \p B and
	/// the edge between \p A and \p B from the graph.
	virtual void mergeNodes(NodeType &A, NodeType &B) = 0;

	/// Given an instruction \p I return its associated ordinal number.
	size_t getOrdinal(Instruction &I) {
	assert(InstOrdinalMap.find(&I) != InstOrdinalMap.end() &&
	"No ordinal computed for this instruction.");
	return InstOrdinalMap[&I];
	}

	/// Given a node \p N return its associated ordinal number.
	size_t getOrdinal(NodeType &N) {
	assert(NodeOrdinalMap.find(&N) != NodeOrdinalMap.end() &&
	"No ordinal computed for this node.");
	return NodeOrdinalMap[&N];
	}

	/// Map types to map instructions to nodes used when populating the graph.
	using InstToNodeMap = DenseMap<Instruction , NodeType >;

	/// Map Types to map instruction/nodes to an ordinal number.
	using InstToOrdinalMap = DenseMap<Instruction *, size_t>;
	using NodeToOrdinalMap = DenseMap<NodeType *, size_t>;

	/// Reference to the graph that gets built by a concrete implementation of
	/// this builder.
	GraphType &Graph;

	/// Dependence information used to create memory dependence edges in the
	/// graph.
	DependenceInfo &DI;

	/// The list of basic blocks to consider when building the graph.
	const BasicBlockListType &BBList;

	/// A mapping from instructions to the corresponding nodes in the graph.
	InstToNodeMap IMap;

	/// A mapping from each instruction to an ordinal number. This map is used to
	/// populate the \p NodeOrdinalMap.
	InstToOrdinalMap InstOrdinalMap;

	/// A mapping from nodes to an ordinal number. This map is used to sort nodes
	/// in a pi-block based on program order.
	NodeToOrdinalMap NodeOrdinalMap;
	};

	} // namespace llvm

	#endif // LLVM_ANALYSIS_DEPENDENCEGRAPHBUILDER_H