280 lines
9.6 KiB
C++
280 lines
9.6 KiB
C++
//===- llvm/ADT/DirectedGraph.h - Directed Graph ----------------*- C++ -*-===//
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//
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// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
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// See https://llvm.org/LICENSE.txt for license information.
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// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
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//
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//===----------------------------------------------------------------------===//
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//
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// This file defines the interface and a base class implementation for a
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// directed graph.
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//
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//===----------------------------------------------------------------------===//
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#ifndef LLVM_ADT_DIRECTEDGRAPH_H
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#define LLVM_ADT_DIRECTEDGRAPH_H
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#include "llvm/ADT/GraphTraits.h"
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#include "llvm/ADT/SetVector.h"
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#include "llvm/ADT/SmallVector.h"
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#include "llvm/Support/Debug.h"
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#include "llvm/Support/raw_ostream.h"
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namespace llvm {
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/// Represent an edge in the directed graph.
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/// The edge contains the target node it connects to.
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template <class NodeType, class EdgeType> class DGEdge {
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public:
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DGEdge() = delete;
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/// Create an edge pointing to the given node \p N.
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explicit DGEdge(NodeType &N) : TargetNode(N) {}
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explicit DGEdge(const DGEdge<NodeType, EdgeType> &E)
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: TargetNode(E.TargetNode) {}
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DGEdge<NodeType, EdgeType> &operator=(const DGEdge<NodeType, EdgeType> &E) {
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TargetNode = E.TargetNode;
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return *this;
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}
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/// Static polymorphism: delegate implementation (via isEqualTo) to the
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/// derived class.
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bool operator==(const DGEdge &E) const {
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return getDerived().isEqualTo(E.getDerived());
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}
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bool operator!=(const DGEdge &E) const { return !operator==(E); }
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/// Retrieve the target node this edge connects to.
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const NodeType &getTargetNode() const { return TargetNode; }
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NodeType &getTargetNode() {
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return const_cast<NodeType &>(
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static_cast<const DGEdge<NodeType, EdgeType> &>(*this).getTargetNode());
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}
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/// Set the target node this edge connects to.
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void setTargetNode(const NodeType &N) { TargetNode = N; }
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protected:
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// As the default implementation use address comparison for equality.
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bool isEqualTo(const EdgeType &E) const { return this == &E; }
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// Cast the 'this' pointer to the derived type and return a reference.
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EdgeType &getDerived() { return *static_cast<EdgeType *>(this); }
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const EdgeType &getDerived() const {
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return *static_cast<const EdgeType *>(this);
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}
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// The target node this edge connects to.
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NodeType &TargetNode;
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};
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/// Represent a node in the directed graph.
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/// The node has a (possibly empty) list of outgoing edges.
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template <class NodeType, class EdgeType> class DGNode {
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public:
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using EdgeListTy = SetVector<EdgeType *>;
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using iterator = typename EdgeListTy::iterator;
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using const_iterator = typename EdgeListTy::const_iterator;
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/// Create a node with a single outgoing edge \p E.
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explicit DGNode(EdgeType &E) : Edges() { Edges.insert(&E); }
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DGNode() = default;
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explicit DGNode(const DGNode<NodeType, EdgeType> &N) : Edges(N.Edges) {}
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DGNode(DGNode<NodeType, EdgeType> &&N) : Edges(std::move(N.Edges)) {}
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DGNode<NodeType, EdgeType> &operator=(const DGNode<NodeType, EdgeType> &N) {
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Edges = N.Edges;
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return *this;
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}
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DGNode<NodeType, EdgeType> &operator=(const DGNode<NodeType, EdgeType> &&N) {
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Edges = std::move(N.Edges);
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return *this;
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}
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/// Static polymorphism: delegate implementation (via isEqualTo) to the
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/// derived class.
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friend bool operator==(const NodeType &M, const NodeType &N) {
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return M.isEqualTo(N);
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}
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friend bool operator!=(const NodeType &M, const NodeType &N) {
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return !(M == N);
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}
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const_iterator begin() const { return Edges.begin(); }
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const_iterator end() const { return Edges.end(); }
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iterator begin() { return Edges.begin(); }
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iterator end() { return Edges.end(); }
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const EdgeType &front() const { return *Edges.front(); }
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EdgeType &front() { return *Edges.front(); }
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const EdgeType &back() const { return *Edges.back(); }
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EdgeType &back() { return *Edges.back(); }
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/// Collect in \p EL, all the edges from this node to \p N.
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/// Return true if at least one edge was found, and false otherwise.
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/// Note that this implementation allows more than one edge to connect
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/// a given pair of nodes.
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bool findEdgesTo(const NodeType &N, SmallVectorImpl<EdgeType *> &EL) const {
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assert(EL.empty() && "Expected the list of edges to be empty.");
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for (auto *E : Edges)
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if (E->getTargetNode() == N)
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EL.push_back(E);
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return !EL.empty();
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}
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/// Add the given edge \p E to this node, if it doesn't exist already. Returns
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/// true if the edge is added and false otherwise.
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bool addEdge(EdgeType &E) { return Edges.insert(&E); }
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/// Remove the given edge \p E from this node, if it exists.
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void removeEdge(EdgeType &E) { Edges.remove(&E); }
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/// Test whether there is an edge that goes from this node to \p N.
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bool hasEdgeTo(const NodeType &N) const {
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return (findEdgeTo(N) != Edges.end());
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}
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/// Retrieve the outgoing edges for the node.
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const EdgeListTy &getEdges() const { return Edges; }
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EdgeListTy &getEdges() {
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return const_cast<EdgeListTy &>(
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static_cast<const DGNode<NodeType, EdgeType> &>(*this).Edges);
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}
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/// Clear the outgoing edges.
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void clear() { Edges.clear(); }
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protected:
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// As the default implementation use address comparison for equality.
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bool isEqualTo(const NodeType &N) const { return this == &N; }
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// Cast the 'this' pointer to the derived type and return a reference.
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NodeType &getDerived() { return *static_cast<NodeType *>(this); }
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const NodeType &getDerived() const {
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return *static_cast<const NodeType *>(this);
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}
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/// Find an edge to \p N. If more than one edge exists, this will return
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/// the first one in the list of edges.
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const_iterator findEdgeTo(const NodeType &N) const {
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return llvm::find_if(
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Edges, [&N](const EdgeType *E) { return E->getTargetNode() == N; });
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}
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// The list of outgoing edges.
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EdgeListTy Edges;
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};
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/// Directed graph
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///
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/// The graph is represented by a table of nodes.
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/// Each node contains a (possibly empty) list of outgoing edges.
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/// Each edge contains the target node it connects to.
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template <class NodeType, class EdgeType> class DirectedGraph {
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protected:
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using NodeListTy = SmallVector<NodeType *, 10>;
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using EdgeListTy = SmallVector<EdgeType *, 10>;
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public:
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using iterator = typename NodeListTy::iterator;
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using const_iterator = typename NodeListTy::const_iterator;
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using DGraphType = DirectedGraph<NodeType, EdgeType>;
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DirectedGraph() = default;
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explicit DirectedGraph(NodeType &N) : Nodes() { addNode(N); }
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DirectedGraph(const DGraphType &G) : Nodes(G.Nodes) {}
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DirectedGraph(DGraphType &&RHS) : Nodes(std::move(RHS.Nodes)) {}
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DGraphType &operator=(const DGraphType &G) {
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Nodes = G.Nodes;
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return *this;
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}
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DGraphType &operator=(const DGraphType &&G) {
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Nodes = std::move(G.Nodes);
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return *this;
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}
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const_iterator begin() const { return Nodes.begin(); }
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const_iterator end() const { return Nodes.end(); }
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iterator begin() { return Nodes.begin(); }
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iterator end() { return Nodes.end(); }
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const NodeType &front() const { return *Nodes.front(); }
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NodeType &front() { return *Nodes.front(); }
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const NodeType &back() const { return *Nodes.back(); }
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NodeType &back() { return *Nodes.back(); }
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size_t size() const { return Nodes.size(); }
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/// Find the given node \p N in the table.
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const_iterator findNode(const NodeType &N) const {
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return llvm::find_if(Nodes,
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[&N](const NodeType *Node) { return *Node == N; });
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}
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iterator findNode(const NodeType &N) {
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return const_cast<iterator>(
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static_cast<const DGraphType &>(*this).findNode(N));
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}
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/// Add the given node \p N to the graph if it is not already present.
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bool addNode(NodeType &N) {
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if (findNode(N) != Nodes.end())
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return false;
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Nodes.push_back(&N);
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return true;
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}
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/// Collect in \p EL all edges that are coming into node \p N. Return true
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/// if at least one edge was found, and false otherwise.
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bool findIncomingEdgesToNode(const NodeType &N, SmallVectorImpl<EdgeType*> &EL) const {
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assert(EL.empty() && "Expected the list of edges to be empty.");
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EdgeListTy TempList;
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for (auto *Node : Nodes) {
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if (*Node == N)
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continue;
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Node->findEdgesTo(N, TempList);
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llvm::append_range(EL, TempList);
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TempList.clear();
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}
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return !EL.empty();
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}
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/// Remove the given node \p N from the graph. If the node has incoming or
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/// outgoing edges, they are also removed. Return true if the node was found
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/// and then removed, and false if the node was not found in the graph to
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/// begin with.
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bool removeNode(NodeType &N) {
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iterator IT = findNode(N);
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if (IT == Nodes.end())
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return false;
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// Remove incoming edges.
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EdgeListTy EL;
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for (auto *Node : Nodes) {
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if (*Node == N)
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continue;
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Node->findEdgesTo(N, EL);
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for (auto *E : EL)
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Node->removeEdge(*E);
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EL.clear();
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}
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N.clear();
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Nodes.erase(IT);
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return true;
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}
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/// Assuming nodes \p Src and \p Dst are already in the graph, connect node \p
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/// Src to node \p Dst using the provided edge \p E. Return true if \p Src is
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/// not already connected to \p Dst via \p E, and false otherwise.
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bool connect(NodeType &Src, NodeType &Dst, EdgeType &E) {
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assert(findNode(Src) != Nodes.end() && "Src node should be present.");
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assert(findNode(Dst) != Nodes.end() && "Dst node should be present.");
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assert((E.getTargetNode() == Dst) &&
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"Target of the given edge does not match Dst.");
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return Src.addEdge(E);
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}
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protected:
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// The list of nodes in the graph.
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NodeListTy Nodes;
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};
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} // namespace llvm
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#endif // LLVM_ADT_DIRECTEDGRAPH_H
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