third_party/llvm-10.0/llvm/include/llvm/Analysis/DDG.h - SwiftShader - Git at Google

 //===- llvm/Analysis/DDG.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 the Data-Dependence Graph (DDG).
 //
 //===----------------------------------------------------------------------===//

 #ifndef LLVM_ANALYSIS_DDG_H
 #define LLVM_ANALYSIS_DDG_H

 #include "llvm/ADT/DenseMap.h"
 #include "llvm/ADT/DirectedGraph.h"
 #include "llvm/Analysis/DependenceAnalysis.h"
 #include "llvm/Analysis/DependenceGraphBuilder.h"
 #include "llvm/Analysis/LoopAnalysisManager.h"
 #include "llvm/IR/Instructions.h"

 namespace llvm {
 class DDGNode;
 class DDGEdge;
 using DDGNodeBase = DGNode<DDGNode, DDGEdge>;
 using DDGEdgeBase = DGEdge<DDGNode, DDGEdge>;
 using DDGBase = DirectedGraph<DDGNode, DDGEdge>;
 class LPMUpdater;

 /// Data Dependence Graph Node
 /// The graph can represent the following types of nodes:
 /// 1. Single instruction node containing just one instruction.
 /// 2. Multiple instruction node where two or more instructions from
 ///    the same basic block are merged into one node.
 /// 3. Pi-block node which is a group of other DDG nodes that are part of a
 ///    strongly-connected component of the graph.
 ///    A pi-block node contains more than one single or multiple instruction
 ///    nodes. The root node cannot be part of a pi-block.
 /// 4. Root node is a special node that connects to all components such that
 ///    there is always a path from it to any node in the graph.
 class DDGNode : public DDGNodeBase {
 public:
   using InstructionListType = SmallVectorImpl<Instruction *>;

   enum class NodeKind {
     Unknown,
     SingleInstruction,
     MultiInstruction,
     PiBlock,
     Root,
   };

   DDGNode() = delete;
   DDGNode(const NodeKind K) : DDGNodeBase(), Kind(K) {}
   DDGNode(const DDGNode &N) : DDGNodeBase(N), Kind(N.Kind) {}
   DDGNode(DDGNode &&N) : DDGNodeBase(std::move(N)), Kind(N.Kind) {}
   virtual ~DDGNode() = 0;

   DDGNode &operator=(const DDGNode &N) {
     DGNode::operator=(N);
     Kind = N.Kind;
     return *this;
   }

   DDGNode &operator=(DDGNode &&N) {
     DGNode::operator=(std::move(N));
     Kind = N.Kind;
     return *this;
   }

   /// Getter for the kind of this node.
   NodeKind getKind() const { return Kind; }

   /// Collect a list of instructions, in \p IList, for which predicate \p Pred
   /// evaluates to true when iterating over instructions of this node. Return
   /// true if at least one instruction was collected, and false otherwise.
   bool collectInstructions(llvm::function_ref<bool(Instruction *)> const &Pred,
                            InstructionListType &IList) const;

 protected:
   /// Setter for the kind of this node.
   void setKind(NodeKind K) { Kind = K; }

 private:
   NodeKind Kind;
 };

 /// Subclass of DDGNode representing the root node of the graph.
 /// There should only be one such node in a given graph.
 class RootDDGNode : public DDGNode {
 public:
   RootDDGNode() : DDGNode(NodeKind::Root) {}
   RootDDGNode(const RootDDGNode &N) = delete;
   RootDDGNode(RootDDGNode &&N) : DDGNode(std::move(N)) {}
   ~RootDDGNode() {}

   /// Define classof to be able to use isa<>, cast<>, dyn_cast<>, etc.
   static bool classof(const DDGNode *N) {
     return N->getKind() == NodeKind::Root;
   }
   static bool classof(const RootDDGNode *N) { return true; }
 };

 /// Subclass of DDGNode representing single or multi-instruction nodes.
 class SimpleDDGNode : public DDGNode {
 public:
   SimpleDDGNode() = delete;
   SimpleDDGNode(Instruction &I);
   SimpleDDGNode(const SimpleDDGNode &N);
   SimpleDDGNode(SimpleDDGNode &&N);
   ~SimpleDDGNode();

   SimpleDDGNode &operator=(const SimpleDDGNode &N) {
     DDGNode::operator=(N);
     InstList = N.InstList;
     return *this;
   }

   SimpleDDGNode &operator=(SimpleDDGNode &&N) {
     DDGNode::operator=(std::move(N));
     InstList = std::move(N.InstList);
     return *this;
   }

   /// Get the list of instructions in this node.
   const InstructionListType &getInstructions() const {
     assert(!InstList.empty() && "Instruction List is empty.");
     return InstList;
   }
   InstructionListType &getInstructions() {
     return const_cast<InstructionListType &>(
         static_cast<const SimpleDDGNode *>(this)->getInstructions());
   }

   /// Get the first/last instruction in the node.
   Instruction *getFirstInstruction() const { return getInstructions().front(); }
   Instruction *getLastInstruction() const { return getInstructions().back(); }

   /// Define classof to be able to use isa<>, cast<>, dyn_cast<>, etc.
   static bool classof(const DDGNode *N) {
     return N->getKind() == NodeKind::SingleInstruction ||
            N->getKind() == NodeKind::MultiInstruction;
   }
   static bool classof(const SimpleDDGNode *N) { return true; }

 private:
   /// Append the list of instructions in \p Input to this node.
   void appendInstructions(const InstructionListType &Input) {
     setKind((InstList.size() == 0 && Input.size() == 1)
                 ? NodeKind::SingleInstruction
                 : NodeKind::MultiInstruction);
     InstList.insert(InstList.end(), Input.begin(), Input.end());
   }
   void appendInstructions(const SimpleDDGNode &Input) {
     appendInstructions(Input.getInstructions());
   }

   /// List of instructions associated with a single or multi-instruction node.
   SmallVector<Instruction *, 2> InstList;
 };

 /// Subclass of DDGNode representing a pi-block. A pi-block represents a group
 /// of DDG nodes that are part of a strongly-connected component of the graph.
 /// Replacing all the SCCs with pi-blocks results in an acyclic representation
 /// of the DDG. For example if we have:
 /// {a -> b}, {b -> c, d}, {c -> a}
 /// the cycle a -> b -> c -> a is abstracted into a pi-block "p" as follows:
 /// {p -> d} with "p" containing: {a -> b}, {b -> c}, {c -> a}
 class PiBlockDDGNode : public DDGNode {
 public:
   using PiNodeList = SmallVector<DDGNode *, 4>;

   PiBlockDDGNode() = delete;
   PiBlockDDGNode(const PiNodeList &List);
   PiBlockDDGNode(const PiBlockDDGNode &N);
   PiBlockDDGNode(PiBlockDDGNode &&N);
   ~PiBlockDDGNode();

   PiBlockDDGNode &operator=(const PiBlockDDGNode &N) {
     DDGNode::operator=(N);
     NodeList = N.NodeList;
     return *this;
   }

   PiBlockDDGNode &operator=(PiBlockDDGNode &&N) {
     DDGNode::operator=(std::move(N));
     NodeList = std::move(N.NodeList);
     return *this;
   }

   /// Get the list of nodes in this pi-block.
   const PiNodeList &getNodes() const {
     assert(!NodeList.empty() && "Node list is empty.");
     return NodeList;
   }
   PiNodeList &getNodes() {
     return const_cast<PiNodeList &>(
         static_cast<const PiBlockDDGNode *>(this)->getNodes());
   }

   /// Define classof to be able to use isa<>, cast<>, dyn_cast<>, etc.
   static bool classof(const DDGNode *N) {
     return N->getKind() == NodeKind::PiBlock;
   }

 private:
   /// List of nodes in this pi-block.
   PiNodeList NodeList;
 };

 /// Data Dependency Graph Edge.
 /// An edge in the DDG can represent a def-use relationship or
 /// a memory dependence based on the result of DependenceAnalysis.
 /// A rooted edge connects the root node to one of the components
 /// of the graph.
 class DDGEdge : public DDGEdgeBase {
 public:
   /// The kind of edge in the DDG
   enum class EdgeKind {
     Unknown,
     RegisterDefUse,
     MemoryDependence,
     Rooted,
     Last = Rooted // Must be equal to the largest enum value.
   };

   explicit DDGEdge(DDGNode &N) = delete;
   DDGEdge(DDGNode &N, EdgeKind K) : DDGEdgeBase(N), Kind(K) {}
   DDGEdge(const DDGEdge &E) : DDGEdgeBase(E), Kind(E.getKind()) {}
   DDGEdge(DDGEdge &&E) : DDGEdgeBase(std::move(E)), Kind(E.Kind) {}
   DDGEdge &operator=(const DDGEdge &E) {
     DDGEdgeBase::operator=(E);
     Kind = E.Kind;
     return *this;
   }

   DDGEdge &operator=(DDGEdge &&E) {
     DDGEdgeBase::operator=(std::move(E));
     Kind = E.Kind;
     return *this;
   }

   /// Get the edge kind
   EdgeKind getKind() const { return Kind; };

   /// Return true if this is a def-use edge, and false otherwise.
   bool isDefUse() const { return Kind == EdgeKind::RegisterDefUse; }

   /// Return true if this is a memory dependence edge, and false otherwise.
   bool isMemoryDependence() const { return Kind == EdgeKind::MemoryDependence; }

   /// Return true if this is an edge stemming from the root node, and false
   /// otherwise.
   bool isRooted() const { return Kind == EdgeKind::Rooted; }

 private:
   EdgeKind Kind;
 };

 /// Encapsulate some common data and functionality needed for different
 /// variations of data dependence graphs.
 template <typename NodeType> class DependenceGraphInfo {
 public:
   using DependenceList = SmallVector<std::unique_ptr<Dependence>, 1>;

   DependenceGraphInfo() = delete;
   DependenceGraphInfo(const DependenceGraphInfo &G) = delete;
   DependenceGraphInfo(const std::string &N, const DependenceInfo &DepInfo)
       : Name(N), DI(DepInfo), Root(nullptr) {}
   DependenceGraphInfo(DependenceGraphInfo &&G)
       : Name(std::move(G.Name)), DI(std::move(G.DI)), Root(G.Root) {}
   virtual ~DependenceGraphInfo() {}

   /// Return the label that is used to name this graph.
   const StringRef getName() const { return Name; }

   /// Return the root node of the graph.
   NodeType &getRoot() const {
     assert(Root && "Root node is not available yet. Graph construction may "
                    "still be in progress\n");
     return *Root;
   }

 protected:
   // Name of the graph.
   std::string Name;

   // Store a copy of DependenceInfo in the graph, so that individual memory
   // dependencies don't need to be stored. Instead when the dependence is
   // queried it is recomputed using @DI.
   const DependenceInfo DI;

   // A special node in the graph that has an edge to every connected component of
   // the graph, to ensure all nodes are reachable in a graph walk.
   NodeType *Root = nullptr;
 };

 using DDGInfo = DependenceGraphInfo<DDGNode>;

 /// Data Dependency Graph
 class DataDependenceGraph : public DDGBase, public DDGInfo {
   friend AbstractDependenceGraphBuilder<DataDependenceGraph>;
   friend class DDGBuilder;

 public:
   using NodeType = DDGNode;
   using EdgeType = DDGEdge;

   DataDependenceGraph() = delete;
   DataDependenceGraph(const DataDependenceGraph &G) = delete;
   DataDependenceGraph(DataDependenceGraph &&G)
       : DDGBase(std::move(G)), DDGInfo(std::move(G)) {}
   DataDependenceGraph(Function &F, DependenceInfo &DI);
   DataDependenceGraph(Loop &L, LoopInfo &LI, DependenceInfo &DI);
   ~DataDependenceGraph();

   /// If node \p N belongs to a pi-block return a pointer to the pi-block,
   /// otherwise return null.
   const PiBlockDDGNode *getPiBlock(const NodeType &N) const;

 protected:
   /// Add node \p N to the graph, if it's not added yet, and keep track of the
   /// root node as well as pi-blocks and their members. Return true if node is
   /// successfully added.
   bool addNode(NodeType &N);

 private:
   using PiBlockMapType = DenseMap<const NodeType *, const PiBlockDDGNode *>;

   /// Mapping from graph nodes to their containing pi-blocks. If a node is not
   /// part of a pi-block, it will not appear in this map.
   PiBlockMapType PiBlockMap;
 };

 /// Concrete implementation of a pure data dependence graph builder. This class
 /// provides custom implementation for the pure-virtual functions used in the
 /// generic dependence graph build algorithm.
 ///
 /// For information about time complexity of the build algorithm see the
 /// comments near the declaration of AbstractDependenceGraphBuilder.
 class DDGBuilder : public AbstractDependenceGraphBuilder<DataDependenceGraph> {
 public:
   DDGBuilder(DataDependenceGraph &G, DependenceInfo &D,
              const BasicBlockListType &BBs)
       : AbstractDependenceGraphBuilder(G, D, BBs) {}
   DDGNode &createRootNode() final override {
     auto *RN = new RootDDGNode();
     assert(RN && "Failed to allocate memory for DDG root node.");
     Graph.addNode(*RN);
     return *RN;
   }
   DDGNode &createFineGrainedNode(Instruction &I) final override {
     auto *SN = new SimpleDDGNode(I);
     assert(SN && "Failed to allocate memory for simple DDG node.");
     Graph.addNode(*SN);
     return *SN;
   }
   DDGNode &createPiBlock(const NodeListType &L) final override {
     auto *Pi = new PiBlockDDGNode(L);
     assert(Pi && "Failed to allocate memory for pi-block node.");
     Graph.addNode(*Pi);
     return *Pi;
   }
   DDGEdge &createDefUseEdge(DDGNode &Src, DDGNode &Tgt) final override {
     auto *E = new DDGEdge(Tgt, DDGEdge::EdgeKind::RegisterDefUse);
     assert(E && "Failed to allocate memory for edge");
     Graph.connect(Src, Tgt, *E);
     return *E;
   }
   DDGEdge &createMemoryEdge(DDGNode &Src, DDGNode &Tgt) final override {
     auto *E = new DDGEdge(Tgt, DDGEdge::EdgeKind::MemoryDependence);
     assert(E && "Failed to allocate memory for edge");
     Graph.connect(Src, Tgt, *E);
     return *E;
   }
   DDGEdge &createRootedEdge(DDGNode &Src, DDGNode &Tgt) final override {
     auto *E = new DDGEdge(Tgt, DDGEdge::EdgeKind::Rooted);
     assert(E && "Failed to allocate memory for edge");
     assert(isa<RootDDGNode>(Src) && "Expected root node");
     Graph.connect(Src, Tgt, *E);
     return *E;
   }

   const NodeListType &getNodesInPiBlock(const DDGNode &N) final override {
     auto *PiNode = dyn_cast<const PiBlockDDGNode>(&N);
     assert(PiNode && "Expected a pi-block node.");
     return PiNode->getNodes();
   }

   bool shouldCreatePiBlocks() const final override;
 };

 raw_ostream &operator<<(raw_ostream &OS, const DDGNode &N);
 raw_ostream &operator<<(raw_ostream &OS, const DDGNode::NodeKind K);
 raw_ostream &operator<<(raw_ostream &OS, const DDGEdge &E);
 raw_ostream &operator<<(raw_ostream &OS, const DDGEdge::EdgeKind K);
 raw_ostream &operator<<(raw_ostream &OS, const DataDependenceGraph &G);

 //===--------------------------------------------------------------------===//
 // DDG Analysis Passes
 //===--------------------------------------------------------------------===//

 /// Analysis pass that builds the DDG for a loop.
 class DDGAnalysis : public AnalysisInfoMixin<DDGAnalysis> {
 public:
   using Result = std::unique_ptr<DataDependenceGraph>;
   Result run(Loop &L, LoopAnalysisManager &AM, LoopStandardAnalysisResults &AR);

 private:
   friend AnalysisInfoMixin<DDGAnalysis>;
   static AnalysisKey Key;
 };

 /// Textual printer pass for the DDG of a loop.
 class DDGAnalysisPrinterPass : public PassInfoMixin<DDGAnalysisPrinterPass> {
 public:
   explicit DDGAnalysisPrinterPass(raw_ostream &OS) : OS(OS) {}
   PreservedAnalyses run(Loop &L, LoopAnalysisManager &AM,
                         LoopStandardAnalysisResults &AR, LPMUpdater &U);

 private:
   raw_ostream &OS;
 };

 //===--------------------------------------------------------------------===//
 // GraphTraits specializations for the DDG
 //===--------------------------------------------------------------------===//

 /// non-const versions of the grapth trait specializations for DDG
 template <> struct GraphTraits<DDGNode *> {
   using NodeRef = DDGNode *;

   static DDGNode *DDGGetTargetNode(DGEdge<DDGNode, DDGEdge> *P) {
     return &P->getTargetNode();
   }

   // Provide a mapped iterator so that the GraphTrait-based implementations can
   // find the target nodes without having to explicitly go through the edges.
   using ChildIteratorType =
       mapped_iterator<DDGNode::iterator, decltype(&DDGGetTargetNode)>;
   using ChildEdgeIteratorType = DDGNode::iterator;

   static NodeRef getEntryNode(NodeRef N) { return N; }
   static ChildIteratorType child_begin(NodeRef N) {
     return ChildIteratorType(N->begin(), &DDGGetTargetNode);
   }
   static ChildIteratorType child_end(NodeRef N) {
     return ChildIteratorType(N->end(), &DDGGetTargetNode);
   }

   static ChildEdgeIteratorType child_edge_begin(NodeRef N) {
     return N->begin();
   }
   static ChildEdgeIteratorType child_edge_end(NodeRef N) { return N->end(); }
 };

 template <>
 struct GraphTraits<DataDependenceGraph *> : public GraphTraits<DDGNode *> {
   using nodes_iterator = DataDependenceGraph::iterator;
   static NodeRef getEntryNode(DataDependenceGraph *DG) {
     return &DG->getRoot();
   }
   static nodes_iterator nodes_begin(DataDependenceGraph *DG) {
     return DG->begin();
   }
   static nodes_iterator nodes_end(DataDependenceGraph *DG) { return DG->end(); }
 };

 /// const versions of the grapth trait specializations for DDG
 template <> struct GraphTraits<const DDGNode *> {
   using NodeRef = const DDGNode *;

   static const DDGNode *DDGGetTargetNode(const DGEdge<DDGNode, DDGEdge> *P) {
     return &P->getTargetNode();
   }

   // Provide a mapped iterator so that the GraphTrait-based implementations can
   // find the target nodes without having to explicitly go through the edges.
   using ChildIteratorType =
       mapped_iterator<DDGNode::const_iterator, decltype(&DDGGetTargetNode)>;
   using ChildEdgeIteratorType = DDGNode::const_iterator;

   static NodeRef getEntryNode(NodeRef N) { return N; }
   static ChildIteratorType child_begin(NodeRef N) {
     return ChildIteratorType(N->begin(), &DDGGetTargetNode);
   }
   static ChildIteratorType child_end(NodeRef N) {
     return ChildIteratorType(N->end(), &DDGGetTargetNode);
   }

   static ChildEdgeIteratorType child_edge_begin(NodeRef N) {
     return N->begin();
   }
   static ChildEdgeIteratorType child_edge_end(NodeRef N) { return N->end(); }
 };

 template <>
 struct GraphTraits<const DataDependenceGraph *>
     : public GraphTraits<const DDGNode *> {
   using nodes_iterator = DataDependenceGraph::const_iterator;
   static NodeRef getEntryNode(const DataDependenceGraph *DG) {
     return &DG->getRoot();
   }
   static nodes_iterator nodes_begin(const DataDependenceGraph *DG) {
     return DG->begin();
   }
   static nodes_iterator nodes_end(const DataDependenceGraph *DG) {
     return DG->end();
   }
 };

 } // namespace llvm

 #endif // LLVM_ANALYSIS_DDG_H
	//===- llvm/Analysis/DDG.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 the Data-Dependence Graph (DDG).
	//
	//===----------------------------------------------------------------------===//

	#ifndef LLVM_ANALYSIS_DDG_H
	#define LLVM_ANALYSIS_DDG_H

	#include "llvm/ADT/DenseMap.h"
	#include "llvm/ADT/DirectedGraph.h"
	#include "llvm/Analysis/DependenceAnalysis.h"
	#include "llvm/Analysis/DependenceGraphBuilder.h"
	#include "llvm/Analysis/LoopAnalysisManager.h"
	#include "llvm/IR/Instructions.h"

	namespace llvm {
	class DDGNode;
	class DDGEdge;
	using DDGNodeBase = DGNode<DDGNode, DDGEdge>;
	using DDGEdgeBase = DGEdge<DDGNode, DDGEdge>;
	using DDGBase = DirectedGraph<DDGNode, DDGEdge>;
	class LPMUpdater;

	/// Data Dependence Graph Node
	/// The graph can represent the following types of nodes:
	/// 1. Single instruction node containing just one instruction.
	/// 2. Multiple instruction node where two or more instructions from
	/// the same basic block are merged into one node.
	/// 3. Pi-block node which is a group of other DDG nodes that are part of a
	/// strongly-connected component of the graph.
	/// A pi-block node contains more than one single or multiple instruction
	/// nodes. The root node cannot be part of a pi-block.
	/// 4. Root node is a special node that connects to all components such that
	/// there is always a path from it to any node in the graph.
	class DDGNode : public DDGNodeBase {
	public:
	using InstructionListType = SmallVectorImpl<Instruction *>;

	enum class NodeKind {
	Unknown,
	SingleInstruction,
	MultiInstruction,
	PiBlock,
	Root,
	};

	DDGNode() = delete;
	DDGNode(const NodeKind K) : DDGNodeBase(), Kind(K) {}
	DDGNode(const DDGNode &N) : DDGNodeBase(N), Kind(N.Kind) {}
	DDGNode(DDGNode &&N) : DDGNodeBase(std::move(N)), Kind(N.Kind) {}
	virtual ~DDGNode() = 0;

	DDGNode &operator=(const DDGNode &N) {
	DGNode::operator=(N);
	Kind = N.Kind;
	return *this;
	}

	DDGNode &operator=(DDGNode &&N) {
	DGNode::operator=(std::move(N));
	Kind = N.Kind;
	return *this;
	}

	/// Getter for the kind of this node.
	NodeKind getKind() const { return Kind; }

	/// Collect a list of instructions, in \p IList, for which predicate \p Pred
	/// evaluates to true when iterating over instructions of this node. Return
	/// true if at least one instruction was collected, and false otherwise.
	bool collectInstructions(llvm::function_ref<bool(Instruction *)> const &Pred,
	InstructionListType &IList) const;

	protected:
	/// Setter for the kind of this node.
	void setKind(NodeKind K) { Kind = K; }

	private:
	NodeKind Kind;
	};

	/// Subclass of DDGNode representing the root node of the graph.
	/// There should only be one such node in a given graph.
	class RootDDGNode : public DDGNode {
	public:
	RootDDGNode() : DDGNode(NodeKind::Root) {}
	RootDDGNode(const RootDDGNode &N) = delete;
	RootDDGNode(RootDDGNode &&N) : DDGNode(std::move(N)) {}
	~RootDDGNode() {}

	/// Define classof to be able to use isa<>, cast<>, dyn_cast<>, etc.
	static bool classof(const DDGNode *N) {
	return N->getKind() == NodeKind::Root;
	}
	static bool classof(const RootDDGNode *N) { return true; }
	};

	/// Subclass of DDGNode representing single or multi-instruction nodes.
	class SimpleDDGNode : public DDGNode {
	public:
	SimpleDDGNode() = delete;
	SimpleDDGNode(Instruction &I);
	SimpleDDGNode(const SimpleDDGNode &N);
	SimpleDDGNode(SimpleDDGNode &&N);
	~SimpleDDGNode();

	SimpleDDGNode &operator=(const SimpleDDGNode &N) {
	DDGNode::operator=(N);
	InstList = N.InstList;
	return *this;
	}

	SimpleDDGNode &operator=(SimpleDDGNode &&N) {
	DDGNode::operator=(std::move(N));
	InstList = std::move(N.InstList);
	return *this;
	}

	/// Get the list of instructions in this node.
	const InstructionListType &getInstructions() const {
	assert(!InstList.empty() && "Instruction List is empty.");
	return InstList;
	}
	InstructionListType &getInstructions() {
	return const_cast<InstructionListType &>(
	static_cast<const SimpleDDGNode *>(this)->getInstructions());
	}

	/// Get the first/last instruction in the node.
	Instruction *getFirstInstruction() const { return getInstructions().front(); }
	Instruction *getLastInstruction() const { return getInstructions().back(); }

	/// Define classof to be able to use isa<>, cast<>, dyn_cast<>, etc.
	static bool classof(const DDGNode *N) {
	return N->getKind() == NodeKind::SingleInstruction \|\|
	N->getKind() == NodeKind::MultiInstruction;
	}
	static bool classof(const SimpleDDGNode *N) { return true; }

	private:
	/// Append the list of instructions in \p Input to this node.
	void appendInstructions(const InstructionListType &Input) {
	setKind((InstList.size() == 0 && Input.size() == 1)
	? NodeKind::SingleInstruction
	: NodeKind::MultiInstruction);
	InstList.insert(InstList.end(), Input.begin(), Input.end());
	}
	void appendInstructions(const SimpleDDGNode &Input) {
	appendInstructions(Input.getInstructions());
	}

	/// List of instructions associated with a single or multi-instruction node.
	SmallVector<Instruction *, 2> InstList;
	};

	/// Subclass of DDGNode representing a pi-block. A pi-block represents a group
	/// of DDG nodes that are part of a strongly-connected component of the graph.
	/// Replacing all the SCCs with pi-blocks results in an acyclic representation
	/// of the DDG. For example if we have:
	/// {a -> b}, {b -> c, d}, {c -> a}
	/// the cycle a -> b -> c -> a is abstracted into a pi-block "p" as follows:
	/// {p -> d} with "p" containing: {a -> b}, {b -> c}, {c -> a}
	class PiBlockDDGNode : public DDGNode {
	public:
	using PiNodeList = SmallVector<DDGNode *, 4>;

	PiBlockDDGNode() = delete;
	PiBlockDDGNode(const PiNodeList &List);
	PiBlockDDGNode(const PiBlockDDGNode &N);
	PiBlockDDGNode(PiBlockDDGNode &&N);
	~PiBlockDDGNode();

	PiBlockDDGNode &operator=(const PiBlockDDGNode &N) {
	DDGNode::operator=(N);
	NodeList = N.NodeList;
	return *this;
	}

	PiBlockDDGNode &operator=(PiBlockDDGNode &&N) {
	DDGNode::operator=(std::move(N));
	NodeList = std::move(N.NodeList);
	return *this;
	}

	/// Get the list of nodes in this pi-block.
	const PiNodeList &getNodes() const {
	assert(!NodeList.empty() && "Node list is empty.");
	return NodeList;
	}
	PiNodeList &getNodes() {
	return const_cast<PiNodeList &>(
	static_cast<const PiBlockDDGNode *>(this)->getNodes());
	}

	/// Define classof to be able to use isa<>, cast<>, dyn_cast<>, etc.
	static bool classof(const DDGNode *N) {
	return N->getKind() == NodeKind::PiBlock;
	}

	private:
	/// List of nodes in this pi-block.
	PiNodeList NodeList;
	};

	/// Data Dependency Graph Edge.
	/// An edge in the DDG can represent a def-use relationship or
	/// a memory dependence based on the result of DependenceAnalysis.
	/// A rooted edge connects the root node to one of the components
	/// of the graph.
	class DDGEdge : public DDGEdgeBase {
	public:
	/// The kind of edge in the DDG
	enum class EdgeKind {
	Unknown,
	RegisterDefUse,
	MemoryDependence,
	Rooted,
	Last = Rooted // Must be equal to the largest enum value.
	};

	explicit DDGEdge(DDGNode &N) = delete;
	DDGEdge(DDGNode &N, EdgeKind K) : DDGEdgeBase(N), Kind(K) {}
	DDGEdge(const DDGEdge &E) : DDGEdgeBase(E), Kind(E.getKind()) {}
	DDGEdge(DDGEdge &&E) : DDGEdgeBase(std::move(E)), Kind(E.Kind) {}
	DDGEdge &operator=(const DDGEdge &E) {
	DDGEdgeBase::operator=(E);
	Kind = E.Kind;
	return *this;
	}

	DDGEdge &operator=(DDGEdge &&E) {
	DDGEdgeBase::operator=(std::move(E));
	Kind = E.Kind;
	return *this;
	}

	/// Get the edge kind
	EdgeKind getKind() const { return Kind; };

	/// Return true if this is a def-use edge, and false otherwise.
	bool isDefUse() const { return Kind == EdgeKind::RegisterDefUse; }

	/// Return true if this is a memory dependence edge, and false otherwise.
	bool isMemoryDependence() const { return Kind == EdgeKind::MemoryDependence; }

	/// Return true if this is an edge stemming from the root node, and false
	/// otherwise.
	bool isRooted() const { return Kind == EdgeKind::Rooted; }

	private:
	EdgeKind Kind;
	};

	/// Encapsulate some common data and functionality needed for different
	/// variations of data dependence graphs.
	template <typename NodeType> class DependenceGraphInfo {
	public:
	using DependenceList = SmallVector<std::unique_ptr<Dependence>, 1>;

	DependenceGraphInfo() = delete;
	DependenceGraphInfo(const DependenceGraphInfo &G) = delete;
	DependenceGraphInfo(const std::string &N, const DependenceInfo &DepInfo)
	: Name(N), DI(DepInfo), Root(nullptr) {}
	DependenceGraphInfo(DependenceGraphInfo &&G)
	: Name(std::move(G.Name)), DI(std::move(G.DI)), Root(G.Root) {}
	virtual ~DependenceGraphInfo() {}

	/// Return the label that is used to name this graph.
	const StringRef getName() const { return Name; }

	/// Return the root node of the graph.
	NodeType &getRoot() const {
	assert(Root && "Root node is not available yet. Graph construction may "
	"still be in progress\n");
	return *Root;
	}

	protected:
	// Name of the graph.
	std::string Name;

	// Store a copy of DependenceInfo in the graph, so that individual memory
	// dependencies don't need to be stored. Instead when the dependence is
	// queried it is recomputed using @DI.
	const DependenceInfo DI;

	// A special node in the graph that has an edge to every connected component of
	// the graph, to ensure all nodes are reachable in a graph walk.
	NodeType *Root = nullptr;
	};

	using DDGInfo = DependenceGraphInfo<DDGNode>;

	/// Data Dependency Graph
	class DataDependenceGraph : public DDGBase, public DDGInfo {
	friend AbstractDependenceGraphBuilder<DataDependenceGraph>;
	friend class DDGBuilder;

	public:
	using NodeType = DDGNode;
	using EdgeType = DDGEdge;

	DataDependenceGraph() = delete;
	DataDependenceGraph(const DataDependenceGraph &G) = delete;
	DataDependenceGraph(DataDependenceGraph &&G)
	: DDGBase(std::move(G)), DDGInfo(std::move(G)) {}
	DataDependenceGraph(Function &F, DependenceInfo &DI);
	DataDependenceGraph(Loop &L, LoopInfo &LI, DependenceInfo &DI);
	~DataDependenceGraph();

	/// If node \p N belongs to a pi-block return a pointer to the pi-block,
	/// otherwise return null.
	const PiBlockDDGNode *getPiBlock(const NodeType &N) const;

	protected:
	/// Add node \p N to the graph, if it's not added yet, and keep track of the
	/// root node as well as pi-blocks and their members. Return true if node is
	/// successfully added.
	bool addNode(NodeType &N);

	private:
	using PiBlockMapType = DenseMap<const NodeType , const PiBlockDDGNode >;

	/// Mapping from graph nodes to their containing pi-blocks. If a node is not
	/// part of a pi-block, it will not appear in this map.
	PiBlockMapType PiBlockMap;
	};

	/// Concrete implementation of a pure data dependence graph builder. This class
	/// provides custom implementation for the pure-virtual functions used in the
	/// generic dependence graph build algorithm.
	///
	/// For information about time complexity of the build algorithm see the
	/// comments near the declaration of AbstractDependenceGraphBuilder.
	class DDGBuilder : public AbstractDependenceGraphBuilder<DataDependenceGraph> {
	public:
	DDGBuilder(DataDependenceGraph &G, DependenceInfo &D,
	const BasicBlockListType &BBs)
	: AbstractDependenceGraphBuilder(G, D, BBs) {}
	DDGNode &createRootNode() final override {
	auto *RN = new RootDDGNode();
	assert(RN && "Failed to allocate memory for DDG root node.");
	Graph.addNode(*RN);
	return *RN;
	}
	DDGNode &createFineGrainedNode(Instruction &I) final override {
	auto *SN = new SimpleDDGNode(I);
	assert(SN && "Failed to allocate memory for simple DDG node.");
	Graph.addNode(*SN);
	return *SN;
	}
	DDGNode &createPiBlock(const NodeListType &L) final override {
	auto *Pi = new PiBlockDDGNode(L);
	assert(Pi && "Failed to allocate memory for pi-block node.");
	Graph.addNode(*Pi);
	return *Pi;
	}
	DDGEdge &createDefUseEdge(DDGNode &Src, DDGNode &Tgt) final override {
	auto *E = new DDGEdge(Tgt, DDGEdge::EdgeKind::RegisterDefUse);
	assert(E && "Failed to allocate memory for edge");
	Graph.connect(Src, Tgt, *E);
	return *E;
	}
	DDGEdge &createMemoryEdge(DDGNode &Src, DDGNode &Tgt) final override {
	auto *E = new DDGEdge(Tgt, DDGEdge::EdgeKind::MemoryDependence);
	assert(E && "Failed to allocate memory for edge");
	Graph.connect(Src, Tgt, *E);
	return *E;
	}
	DDGEdge &createRootedEdge(DDGNode &Src, DDGNode &Tgt) final override {
	auto *E = new DDGEdge(Tgt, DDGEdge::EdgeKind::Rooted);
	assert(E && "Failed to allocate memory for edge");
	assert(isa<RootDDGNode>(Src) && "Expected root node");
	Graph.connect(Src, Tgt, *E);
	return *E;
	}

	const NodeListType &getNodesInPiBlock(const DDGNode &N) final override {
	auto *PiNode = dyn_cast<const PiBlockDDGNode>(&N);
	assert(PiNode && "Expected a pi-block node.");
	return PiNode->getNodes();
	}

	bool shouldCreatePiBlocks() const final override;
	};

	raw_ostream &operator<<(raw_ostream &OS, const DDGNode &N);
	raw_ostream &operator<<(raw_ostream &OS, const DDGNode::NodeKind K);
	raw_ostream &operator<<(raw_ostream &OS, const DDGEdge &E);
	raw_ostream &operator<<(raw_ostream &OS, const DDGEdge::EdgeKind K);
	raw_ostream &operator<<(raw_ostream &OS, const DataDependenceGraph &G);

	//===--------------------------------------------------------------------===//
	// DDG Analysis Passes
	//===--------------------------------------------------------------------===//

	/// Analysis pass that builds the DDG for a loop.
	class DDGAnalysis : public AnalysisInfoMixin<DDGAnalysis> {
	public:
	using Result = std::unique_ptr<DataDependenceGraph>;
	Result run(Loop &L, LoopAnalysisManager &AM, LoopStandardAnalysisResults &AR);

	private:
	friend AnalysisInfoMixin<DDGAnalysis>;
	static AnalysisKey Key;
	};

	/// Textual printer pass for the DDG of a loop.
	class DDGAnalysisPrinterPass : public PassInfoMixin<DDGAnalysisPrinterPass> {
	public:
	explicit DDGAnalysisPrinterPass(raw_ostream &OS) : OS(OS) {}
	PreservedAnalyses run(Loop &L, LoopAnalysisManager &AM,
	LoopStandardAnalysisResults &AR, LPMUpdater &U);

	private:
	raw_ostream &OS;
	};

	//===--------------------------------------------------------------------===//
	// GraphTraits specializations for the DDG
	//===--------------------------------------------------------------------===//

	/// non-const versions of the grapth trait specializations for DDG
	template <> struct GraphTraits<DDGNode *> {
	using NodeRef = DDGNode *;

	static DDGNode DDGGetTargetNode(DGEdge<DDGNode, DDGEdge> P) {
	return &P->getTargetNode();
	}

	// Provide a mapped iterator so that the GraphTrait-based implementations can
	// find the target nodes without having to explicitly go through the edges.
	using ChildIteratorType =
	mapped_iterator<DDGNode::iterator, decltype(&DDGGetTargetNode)>;
	using ChildEdgeIteratorType = DDGNode::iterator;

	static NodeRef getEntryNode(NodeRef N) { return N; }
	static ChildIteratorType child_begin(NodeRef N) {
	return ChildIteratorType(N->begin(), &DDGGetTargetNode);
	}
	static ChildIteratorType child_end(NodeRef N) {
	return ChildIteratorType(N->end(), &DDGGetTargetNode);
	}

	static ChildEdgeIteratorType child_edge_begin(NodeRef N) {
	return N->begin();
	}
	static ChildEdgeIteratorType child_edge_end(NodeRef N) { return N->end(); }
	};

	template <>
	struct GraphTraits<DataDependenceGraph > : public GraphTraits<DDGNode > {
	using nodes_iterator = DataDependenceGraph::iterator;
	static NodeRef getEntryNode(DataDependenceGraph *DG) {
	return &DG->getRoot();
	}
	static nodes_iterator nodes_begin(DataDependenceGraph *DG) {
	return DG->begin();
	}
	static nodes_iterator nodes_end(DataDependenceGraph *DG) { return DG->end(); }
	};

	/// const versions of the grapth trait specializations for DDG
	template <> struct GraphTraits<const DDGNode *> {
	using NodeRef = const DDGNode *;

	static const DDGNode DDGGetTargetNode(const DGEdge<DDGNode, DDGEdge> P) {
	return &P->getTargetNode();
	}

	// Provide a mapped iterator so that the GraphTrait-based implementations can
	// find the target nodes without having to explicitly go through the edges.
	using ChildIteratorType =
	mapped_iterator<DDGNode::const_iterator, decltype(&DDGGetTargetNode)>;
	using ChildEdgeIteratorType = DDGNode::const_iterator;

	static NodeRef getEntryNode(NodeRef N) { return N; }
	static ChildIteratorType child_begin(NodeRef N) {
	return ChildIteratorType(N->begin(), &DDGGetTargetNode);
	}
	static ChildIteratorType child_end(NodeRef N) {
	return ChildIteratorType(N->end(), &DDGGetTargetNode);
	}

	static ChildEdgeIteratorType child_edge_begin(NodeRef N) {
	return N->begin();
	}
	static ChildEdgeIteratorType child_edge_end(NodeRef N) { return N->end(); }
	};

	template <>
	struct GraphTraits<const DataDependenceGraph *>
	: public GraphTraits<const DDGNode *> {
	using nodes_iterator = DataDependenceGraph::const_iterator;
	static NodeRef getEntryNode(const DataDependenceGraph *DG) {
	return &DG->getRoot();
	}
	static nodes_iterator nodes_begin(const DataDependenceGraph *DG) {
	return DG->begin();
	}
	static nodes_iterator nodes_end(const DataDependenceGraph *DG) {
	return DG->end();
	}
	};

	} // namespace llvm

	#endif // LLVM_ANALYSIS_DDG_H