lemon/connectivity.h
author Peter Kovacs <kpeter@inf.elte.hu>
Thu, 12 Nov 2009 23:26:13 +0100
changeset 806 fa6f37d7a25b
parent 647 dcba640438c7
child 877 141f9c0db4a3
child 1089 552e3d1242c6
permissions -rw-r--r--
Entirely rework CapacityScaling (#180)

- Use the new interface similarly to NetworkSimplex.
- Rework the implementation using an efficient internal structure
for handling the residual network. This improvement made the
code much faster (up to 2-5 times faster on large graphs).
- Handle GEQ supply type (LEQ is not supported).
- Handle negative costs for arcs of finite capacity.
(Note that this algorithm cannot handle arcs of negative cost
and infinite upper bound, thus it returns UNBOUNDED if such
an arc exists.)
- Extend the documentation.
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/* -*- mode: C++; indent-tabs-mode: nil; -*-
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 *
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 * This file is a part of LEMON, a generic C++ optimization library.
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 *
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 * Copyright (C) 2003-2009
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 * Egervary Jeno Kombinatorikus Optimalizalasi Kutatocsoport
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 * (Egervary Research Group on Combinatorial Optimization, EGRES).
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 *
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 * Permission to use, modify and distribute this software is granted
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 * provided that this copyright notice appears in all copies. For
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 * precise terms see the accompanying LICENSE file.
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 *
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 * This software is provided "AS IS" with no warranty of any kind,
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 * express or implied, and with no claim as to its suitability for any
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 * purpose.
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 *
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 */
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#ifndef LEMON_CONNECTIVITY_H
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#define LEMON_CONNECTIVITY_H
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#include <lemon/dfs.h>
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#include <lemon/bfs.h>
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#include <lemon/core.h>
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#include <lemon/maps.h>
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#include <lemon/adaptors.h>
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#include <lemon/concepts/digraph.h>
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#include <lemon/concepts/graph.h>
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#include <lemon/concept_check.h>
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#include <stack>
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#include <functional>
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/// \ingroup graph_properties
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/// \file
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/// \brief Connectivity algorithms
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///
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/// Connectivity algorithms
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namespace lemon {
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  /// \ingroup graph_properties
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  ///
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  /// \brief Check whether an undirected graph is connected.
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  ///
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  /// This function checks whether the given undirected graph is connected,
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  /// i.e. there is a path between any two nodes in the graph.
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  ///
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  /// \return \c true if the graph is connected.
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  /// \note By definition, the empty graph is connected.
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  ///
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  /// \see countConnectedComponents(), connectedComponents()
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  /// \see stronglyConnected()
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  template <typename Graph>
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  bool connected(const Graph& graph) {
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    checkConcept<concepts::Graph, Graph>();
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    typedef typename Graph::NodeIt NodeIt;
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    if (NodeIt(graph) == INVALID) return true;
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    Dfs<Graph> dfs(graph);
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    dfs.run(NodeIt(graph));
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    for (NodeIt it(graph); it != INVALID; ++it) {
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      if (!dfs.reached(it)) {
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        return false;
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      }
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    }
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    return true;
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  }
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  /// \ingroup graph_properties
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  ///
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  /// \brief Count the number of connected components of an undirected graph
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  ///
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  /// This function counts the number of connected components of the given
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  /// undirected graph.
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  ///
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  /// The connected components are the classes of an equivalence relation
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  /// on the nodes of an undirected graph. Two nodes are in the same class
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  /// if they are connected with a path.
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  ///
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  /// \return The number of connected components.
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  /// \note By definition, the empty graph consists
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  /// of zero connected components.
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  ///
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  /// \see connected(), connectedComponents()
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  template <typename Graph>
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  int countConnectedComponents(const Graph &graph) {
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    checkConcept<concepts::Graph, Graph>();
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    typedef typename Graph::Node Node;
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    typedef typename Graph::Arc Arc;
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    typedef NullMap<Node, Arc> PredMap;
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    typedef NullMap<Node, int> DistMap;
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    int compNum = 0;
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    typename Bfs<Graph>::
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      template SetPredMap<PredMap>::
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      template SetDistMap<DistMap>::
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      Create bfs(graph);
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    PredMap predMap;
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    bfs.predMap(predMap);
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    DistMap distMap;
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    bfs.distMap(distMap);
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    bfs.init();
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    for(typename Graph::NodeIt n(graph); n != INVALID; ++n) {
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      if (!bfs.reached(n)) {
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        bfs.addSource(n);
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        bfs.start();
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        ++compNum;
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      }
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    }
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    return compNum;
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  }
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  /// \ingroup graph_properties
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  ///
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  /// \brief Find the connected components of an undirected graph
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  ///
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  /// This function finds the connected components of the given undirected
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  /// graph.
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  ///
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  /// The connected components are the classes of an equivalence relation
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  /// on the nodes of an undirected graph. Two nodes are in the same class
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  /// if they are connected with a path.
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  ///
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  /// \image html connected_components.png
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  /// \image latex connected_components.eps "Connected components" width=\textwidth
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  ///
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  /// \param graph The undirected graph.
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  /// \retval compMap A writable node map. The values will be set from 0 to
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  /// the number of the connected components minus one. Each value of the map
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  /// will be set exactly once, and the values of a certain component will be
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  /// set continuously.
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  /// \return The number of connected components.
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  /// \note By definition, the empty graph consists
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  /// of zero connected components.
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  ///
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  /// \see connected(), countConnectedComponents()
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  template <class Graph, class NodeMap>
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  int connectedComponents(const Graph &graph, NodeMap &compMap) {
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    checkConcept<concepts::Graph, Graph>();
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    typedef typename Graph::Node Node;
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    typedef typename Graph::Arc Arc;
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    checkConcept<concepts::WriteMap<Node, int>, NodeMap>();
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    typedef NullMap<Node, Arc> PredMap;
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    typedef NullMap<Node, int> DistMap;
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    int compNum = 0;
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    typename Bfs<Graph>::
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      template SetPredMap<PredMap>::
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      template SetDistMap<DistMap>::
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      Create bfs(graph);
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    PredMap predMap;
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    bfs.predMap(predMap);
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    DistMap distMap;
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    bfs.distMap(distMap);
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    bfs.init();
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    for(typename Graph::NodeIt n(graph); n != INVALID; ++n) {
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      if(!bfs.reached(n)) {
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        bfs.addSource(n);
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        while (!bfs.emptyQueue()) {
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          compMap.set(bfs.nextNode(), compNum);
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          bfs.processNextNode();
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        }
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        ++compNum;
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      }
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    }
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    return compNum;
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  }
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  namespace _connectivity_bits {
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    template <typename Digraph, typename Iterator >
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    struct LeaveOrderVisitor : public DfsVisitor<Digraph> {
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    public:
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      typedef typename Digraph::Node Node;
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      LeaveOrderVisitor(Iterator it) : _it(it) {}
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      void leave(const Node& node) {
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        *(_it++) = node;
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      }
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    private:
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      Iterator _it;
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    };
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    template <typename Digraph, typename Map>
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    struct FillMapVisitor : public DfsVisitor<Digraph> {
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    public:
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      typedef typename Digraph::Node Node;
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      typedef typename Map::Value Value;
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      FillMapVisitor(Map& map, Value& value)
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        : _map(map), _value(value) {}
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      void reach(const Node& node) {
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        _map.set(node, _value);
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      }
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    private:
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      Map& _map;
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      Value& _value;
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    };
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    template <typename Digraph, typename ArcMap>
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    struct StronglyConnectedCutArcsVisitor : public DfsVisitor<Digraph> {
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    public:
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      typedef typename Digraph::Node Node;
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      typedef typename Digraph::Arc Arc;
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      StronglyConnectedCutArcsVisitor(const Digraph& digraph,
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                                      ArcMap& cutMap,
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                                      int& cutNum)
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        : _digraph(digraph), _cutMap(cutMap), _cutNum(cutNum),
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          _compMap(digraph, -1), _num(-1) {
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      }
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      void start(const Node&) {
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        ++_num;
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      }
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      void reach(const Node& node) {
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        _compMap.set(node, _num);
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      }
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      void examine(const Arc& arc) {
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         if (_compMap[_digraph.source(arc)] !=
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             _compMap[_digraph.target(arc)]) {
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           _cutMap.set(arc, true);
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           ++_cutNum;
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         }
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      }
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    private:
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      const Digraph& _digraph;
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      ArcMap& _cutMap;
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      int& _cutNum;
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      typename Digraph::template NodeMap<int> _compMap;
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      int _num;
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    };
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  }
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  /// \ingroup graph_properties
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  ///
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  /// \brief Check whether a directed graph is strongly connected.
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  ///
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  /// This function checks whether the given directed graph is strongly
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  /// connected, i.e. any two nodes of the digraph are
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  /// connected with directed paths in both direction.
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  ///
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  /// \return \c true if the digraph is strongly connected.
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  /// \note By definition, the empty digraph is strongly connected.
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  /// 
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  /// \see countStronglyConnectedComponents(), stronglyConnectedComponents()
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  /// \see connected()
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  template <typename Digraph>
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  bool stronglyConnected(const Digraph& digraph) {
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    checkConcept<concepts::Digraph, Digraph>();
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    typedef typename Digraph::Node Node;
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    typedef typename Digraph::NodeIt NodeIt;
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    typename Digraph::Node source = NodeIt(digraph);
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    if (source == INVALID) return true;
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    using namespace _connectivity_bits;
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    typedef DfsVisitor<Digraph> Visitor;
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    Visitor visitor;
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    DfsVisit<Digraph, Visitor> dfs(digraph, visitor);
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    dfs.init();
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    dfs.addSource(source);
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    dfs.start();
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    for (NodeIt it(digraph); it != INVALID; ++it) {
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      if (!dfs.reached(it)) {
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        return false;
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      }
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    }
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    typedef ReverseDigraph<const Digraph> RDigraph;
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    typedef typename RDigraph::NodeIt RNodeIt;
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    RDigraph rdigraph(digraph);
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    typedef DfsVisitor<RDigraph> RVisitor;
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    RVisitor rvisitor;
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    DfsVisit<RDigraph, RVisitor> rdfs(rdigraph, rvisitor);
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    rdfs.init();
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    rdfs.addSource(source);
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    rdfs.start();
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    for (RNodeIt it(rdigraph); it != INVALID; ++it) {
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      if (!rdfs.reached(it)) {
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        return false;
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      }
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    }
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    return true;
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  }
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  /// \ingroup graph_properties
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  ///
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  /// \brief Count the number of strongly connected components of a 
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  /// directed graph
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  ///
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  /// This function counts the number of strongly connected components of
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  /// the given directed graph.
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  ///
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  /// The strongly connected components are the classes of an
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  /// equivalence relation on the nodes of a digraph. Two nodes are in
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  /// the same class if they are connected with directed paths in both
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  /// direction.
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  ///
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  /// \return The number of strongly connected components.
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  /// \note By definition, the empty digraph has zero
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  /// strongly connected components.
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  ///
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  /// \see stronglyConnected(), stronglyConnectedComponents()
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  template <typename Digraph>
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  int countStronglyConnectedComponents(const Digraph& digraph) {
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    checkConcept<concepts::Digraph, Digraph>();
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    using namespace _connectivity_bits;
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    typedef typename Digraph::Node Node;
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    typedef typename Digraph::Arc Arc;
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    typedef typename Digraph::NodeIt NodeIt;
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    typedef typename Digraph::ArcIt ArcIt;
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    typedef std::vector<Node> Container;
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    typedef typename Container::iterator Iterator;
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    Container nodes(countNodes(digraph));
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    typedef LeaveOrderVisitor<Digraph, Iterator> Visitor;
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    Visitor visitor(nodes.begin());
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    DfsVisit<Digraph, Visitor> dfs(digraph, visitor);
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    dfs.init();
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    for (NodeIt it(digraph); it != INVALID; ++it) {
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      if (!dfs.reached(it)) {
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        dfs.addSource(it);
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        dfs.start();
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      }
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    }
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    typedef typename Container::reverse_iterator RIterator;
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    typedef ReverseDigraph<const Digraph> RDigraph;
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    RDigraph rdigraph(digraph);
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    typedef DfsVisitor<Digraph> RVisitor;
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    RVisitor rvisitor;
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    DfsVisit<RDigraph, RVisitor> rdfs(rdigraph, rvisitor);
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    int compNum = 0;
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    rdfs.init();
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    for (RIterator it = nodes.rbegin(); it != nodes.rend(); ++it) {
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      if (!rdfs.reached(*it)) {
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        rdfs.addSource(*it);
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        rdfs.start();
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        ++compNum;
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      }
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    }
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    return compNum;
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  }
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  /// \ingroup graph_properties
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  ///
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  /// \brief Find the strongly connected components of a directed graph
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  ///
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  /// This function finds the strongly connected components of the given
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  /// directed graph. In addition, the numbering of the components will
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  /// satisfy that there is no arc going from a higher numbered component
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  /// to a lower one (i.e. it provides a topological order of the components).
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  ///
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  /// The strongly connected components are the classes of an
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  /// equivalence relation on the nodes of a digraph. Two nodes are in
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  /// the same class if they are connected with directed paths in both
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  /// direction.
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  ///
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  /// \image html strongly_connected_components.png
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  /// \image latex strongly_connected_components.eps "Strongly connected components" width=\textwidth
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  ///
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  /// \param digraph The digraph.
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  /// \retval compMap A writable node map. The values will be set from 0 to
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  /// the number of the strongly connected components minus one. Each value
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  /// of the map will be set exactly once, and the values of a certain
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  /// component will be set continuously.
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  /// \return The number of strongly connected components.
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  /// \note By definition, the empty digraph has zero
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  /// strongly connected components.
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  ///
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  /// \see stronglyConnected(), countStronglyConnectedComponents()
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  template <typename Digraph, typename NodeMap>
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  int stronglyConnectedComponents(const Digraph& digraph, NodeMap& compMap) {
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    checkConcept<concepts::Digraph, Digraph>();
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    typedef typename Digraph::Node Node;
deba@417
   410
    typedef typename Digraph::NodeIt NodeIt;
deba@417
   411
    checkConcept<concepts::WriteMap<Node, int>, NodeMap>();
deba@417
   412
deba@419
   413
    using namespace _connectivity_bits;
deba@417
   414
deba@417
   415
    typedef std::vector<Node> Container;
deba@417
   416
    typedef typename Container::iterator Iterator;
deba@417
   417
deba@417
   418
    Container nodes(countNodes(digraph));
deba@417
   419
    typedef LeaveOrderVisitor<Digraph, Iterator> Visitor;
deba@417
   420
    Visitor visitor(nodes.begin());
deba@417
   421
deba@417
   422
    DfsVisit<Digraph, Visitor> dfs(digraph, visitor);
deba@417
   423
    dfs.init();
deba@417
   424
    for (NodeIt it(digraph); it != INVALID; ++it) {
deba@417
   425
      if (!dfs.reached(it)) {
deba@417
   426
        dfs.addSource(it);
deba@417
   427
        dfs.start();
deba@417
   428
      }
deba@417
   429
    }
deba@417
   430
deba@417
   431
    typedef typename Container::reverse_iterator RIterator;
deba@417
   432
    typedef ReverseDigraph<const Digraph> RDigraph;
deba@417
   433
deba@417
   434
    RDigraph rdigraph(digraph);
deba@417
   435
deba@417
   436
    int compNum = 0;
deba@417
   437
deba@417
   438
    typedef FillMapVisitor<RDigraph, NodeMap> RVisitor;
deba@417
   439
    RVisitor rvisitor(compMap, compNum);
deba@417
   440
deba@417
   441
    DfsVisit<RDigraph, RVisitor> rdfs(rdigraph, rvisitor);
deba@417
   442
deba@417
   443
    rdfs.init();
deba@417
   444
    for (RIterator it = nodes.rbegin(); it != nodes.rend(); ++it) {
deba@417
   445
      if (!rdfs.reached(*it)) {
deba@417
   446
        rdfs.addSource(*it);
deba@417
   447
        rdfs.start();
deba@417
   448
        ++compNum;
deba@417
   449
      }
deba@417
   450
    }
deba@417
   451
    return compNum;
deba@417
   452
  }
deba@417
   453
kpeter@586
   454
  /// \ingroup graph_properties
deba@417
   455
  ///
deba@417
   456
  /// \brief Find the cut arcs of the strongly connected components.
deba@417
   457
  ///
kpeter@648
   458
  /// This function finds the cut arcs of the strongly connected components
kpeter@648
   459
  /// of the given digraph.
kpeter@648
   460
  ///
kpeter@648
   461
  /// The strongly connected components are the classes of an
kpeter@648
   462
  /// equivalence relation on the nodes of a digraph. Two nodes are in
kpeter@648
   463
  /// the same class if they are connected with directed paths in both
kpeter@648
   464
  /// direction.
deba@417
   465
  /// The strongly connected components are separated by the cut arcs.
deba@417
   466
  ///
kpeter@648
   467
  /// \param digraph The digraph.
kpeter@648
   468
  /// \retval cutMap A writable arc map. The values will be set to \c true
kpeter@648
   469
  /// for the cut arcs (exactly once for each cut arc), and will not be
kpeter@648
   470
  /// changed for other arcs.
kpeter@648
   471
  /// \return The number of cut arcs.
deba@417
   472
  ///
kpeter@648
   473
  /// \see stronglyConnected(), stronglyConnectedComponents()
deba@417
   474
  template <typename Digraph, typename ArcMap>
kpeter@648
   475
  int stronglyConnectedCutArcs(const Digraph& digraph, ArcMap& cutMap) {
deba@417
   476
    checkConcept<concepts::Digraph, Digraph>();
deba@417
   477
    typedef typename Digraph::Node Node;
deba@417
   478
    typedef typename Digraph::Arc Arc;
deba@417
   479
    typedef typename Digraph::NodeIt NodeIt;
deba@417
   480
    checkConcept<concepts::WriteMap<Arc, bool>, ArcMap>();
deba@417
   481
deba@419
   482
    using namespace _connectivity_bits;
deba@417
   483
deba@417
   484
    typedef std::vector<Node> Container;
deba@417
   485
    typedef typename Container::iterator Iterator;
deba@417
   486
kpeter@648
   487
    Container nodes(countNodes(digraph));
deba@417
   488
    typedef LeaveOrderVisitor<Digraph, Iterator> Visitor;
deba@417
   489
    Visitor visitor(nodes.begin());
deba@417
   490
kpeter@648
   491
    DfsVisit<Digraph, Visitor> dfs(digraph, visitor);
deba@417
   492
    dfs.init();
kpeter@648
   493
    for (NodeIt it(digraph); it != INVALID; ++it) {
deba@417
   494
      if (!dfs.reached(it)) {
deba@417
   495
        dfs.addSource(it);
deba@417
   496
        dfs.start();
deba@417
   497
      }
deba@417
   498
    }
deba@417
   499
deba@417
   500
    typedef typename Container::reverse_iterator RIterator;
deba@417
   501
    typedef ReverseDigraph<const Digraph> RDigraph;
deba@417
   502
kpeter@648
   503
    RDigraph rdigraph(digraph);
deba@417
   504
deba@417
   505
    int cutNum = 0;
deba@417
   506
deba@419
   507
    typedef StronglyConnectedCutArcsVisitor<RDigraph, ArcMap> RVisitor;
kpeter@648
   508
    RVisitor rvisitor(rdigraph, cutMap, cutNum);
deba@417
   509
kpeter@648
   510
    DfsVisit<RDigraph, RVisitor> rdfs(rdigraph, rvisitor);
deba@417
   511
deba@417
   512
    rdfs.init();
deba@417
   513
    for (RIterator it = nodes.rbegin(); it != nodes.rend(); ++it) {
deba@417
   514
      if (!rdfs.reached(*it)) {
deba@417
   515
        rdfs.addSource(*it);
deba@417
   516
        rdfs.start();
deba@417
   517
      }
deba@417
   518
    }
deba@417
   519
    return cutNum;
deba@417
   520
  }
deba@417
   521
deba@419
   522
  namespace _connectivity_bits {
deba@417
   523
deba@417
   524
    template <typename Digraph>
deba@417
   525
    class CountBiNodeConnectedComponentsVisitor : public DfsVisitor<Digraph> {
deba@417
   526
    public:
deba@417
   527
      typedef typename Digraph::Node Node;
deba@417
   528
      typedef typename Digraph::Arc Arc;
deba@417
   529
      typedef typename Digraph::Edge Edge;
deba@417
   530
deba@417
   531
      CountBiNodeConnectedComponentsVisitor(const Digraph& graph, int &compNum)
deba@417
   532
        : _graph(graph), _compNum(compNum),
deba@417
   533
          _numMap(graph), _retMap(graph), _predMap(graph), _num(0) {}
deba@417
   534
deba@417
   535
      void start(const Node& node) {
deba@417
   536
        _predMap.set(node, INVALID);
deba@417
   537
      }
deba@417
   538
deba@417
   539
      void reach(const Node& node) {
deba@417
   540
        _numMap.set(node, _num);
deba@417
   541
        _retMap.set(node, _num);
deba@417
   542
        ++_num;
deba@417
   543
      }
deba@417
   544
deba@417
   545
      void discover(const Arc& edge) {
deba@417
   546
        _predMap.set(_graph.target(edge), _graph.source(edge));
deba@417
   547
      }
deba@417
   548
deba@417
   549
      void examine(const Arc& edge) {
deba@417
   550
        if (_graph.source(edge) == _graph.target(edge) &&
deba@417
   551
            _graph.direction(edge)) {
deba@417
   552
          ++_compNum;
deba@417
   553
          return;
deba@417
   554
        }
deba@417
   555
        if (_predMap[_graph.source(edge)] == _graph.target(edge)) {
deba@417
   556
          return;
deba@417
   557
        }
deba@417
   558
        if (_retMap[_graph.source(edge)] > _numMap[_graph.target(edge)]) {
deba@417
   559
          _retMap.set(_graph.source(edge), _numMap[_graph.target(edge)]);
deba@417
   560
        }
deba@417
   561
      }
deba@417
   562
deba@417
   563
      void backtrack(const Arc& edge) {
deba@417
   564
        if (_retMap[_graph.source(edge)] > _retMap[_graph.target(edge)]) {
deba@417
   565
          _retMap.set(_graph.source(edge), _retMap[_graph.target(edge)]);
deba@417
   566
        }
deba@417
   567
        if (_numMap[_graph.source(edge)] <= _retMap[_graph.target(edge)]) {
deba@417
   568
          ++_compNum;
deba@417
   569
        }
deba@417
   570
      }
deba@417
   571
deba@417
   572
    private:
deba@417
   573
      const Digraph& _graph;
deba@417
   574
      int& _compNum;
deba@417
   575
deba@417
   576
      typename Digraph::template NodeMap<int> _numMap;
deba@417
   577
      typename Digraph::template NodeMap<int> _retMap;
deba@417
   578
      typename Digraph::template NodeMap<Node> _predMap;
deba@417
   579
      int _num;
deba@417
   580
    };
deba@417
   581
deba@417
   582
    template <typename Digraph, typename ArcMap>
deba@417
   583
    class BiNodeConnectedComponentsVisitor : public DfsVisitor<Digraph> {
deba@417
   584
    public:
deba@417
   585
      typedef typename Digraph::Node Node;
deba@417
   586
      typedef typename Digraph::Arc Arc;
deba@417
   587
      typedef typename Digraph::Edge Edge;
deba@417
   588
deba@417
   589
      BiNodeConnectedComponentsVisitor(const Digraph& graph,
deba@417
   590
                                       ArcMap& compMap, int &compNum)
deba@417
   591
        : _graph(graph), _compMap(compMap), _compNum(compNum),
deba@417
   592
          _numMap(graph), _retMap(graph), _predMap(graph), _num(0) {}
deba@417
   593
deba@417
   594
      void start(const Node& node) {
deba@417
   595
        _predMap.set(node, INVALID);
deba@417
   596
      }
deba@417
   597
deba@417
   598
      void reach(const Node& node) {
deba@417
   599
        _numMap.set(node, _num);
deba@417
   600
        _retMap.set(node, _num);
deba@417
   601
        ++_num;
deba@417
   602
      }
deba@417
   603
deba@417
   604
      void discover(const Arc& edge) {
deba@417
   605
        Node target = _graph.target(edge);
deba@417
   606
        _predMap.set(target, edge);
deba@417
   607
        _edgeStack.push(edge);
deba@417
   608
      }
deba@417
   609
deba@417
   610
      void examine(const Arc& edge) {
deba@417
   611
        Node source = _graph.source(edge);
deba@417
   612
        Node target = _graph.target(edge);
deba@417
   613
        if (source == target && _graph.direction(edge)) {
deba@417
   614
          _compMap.set(edge, _compNum);
deba@417
   615
          ++_compNum;
deba@417
   616
          return;
deba@417
   617
        }
deba@417
   618
        if (_numMap[target] < _numMap[source]) {
deba@417
   619
          if (_predMap[source] != _graph.oppositeArc(edge)) {
deba@417
   620
            _edgeStack.push(edge);
deba@417
   621
          }
deba@417
   622
        }
deba@417
   623
        if (_predMap[source] != INVALID &&
deba@417
   624
            target == _graph.source(_predMap[source])) {
deba@417
   625
          return;
deba@417
   626
        }
deba@417
   627
        if (_retMap[source] > _numMap[target]) {
deba@417
   628
          _retMap.set(source, _numMap[target]);
deba@417
   629
        }
deba@417
   630
      }
deba@417
   631
deba@417
   632
      void backtrack(const Arc& edge) {
deba@417
   633
        Node source = _graph.source(edge);
deba@417
   634
        Node target = _graph.target(edge);
deba@417
   635
        if (_retMap[source] > _retMap[target]) {
deba@417
   636
          _retMap.set(source, _retMap[target]);
deba@417
   637
        }
deba@417
   638
        if (_numMap[source] <= _retMap[target]) {
deba@417
   639
          while (_edgeStack.top() != edge) {
deba@417
   640
            _compMap.set(_edgeStack.top(), _compNum);
deba@417
   641
            _edgeStack.pop();
deba@417
   642
          }
deba@417
   643
          _compMap.set(edge, _compNum);
deba@417
   644
          _edgeStack.pop();
deba@417
   645
          ++_compNum;
deba@417
   646
        }
deba@417
   647
      }
deba@417
   648
deba@417
   649
    private:
deba@417
   650
      const Digraph& _graph;
deba@417
   651
      ArcMap& _compMap;
deba@417
   652
      int& _compNum;
deba@417
   653
deba@417
   654
      typename Digraph::template NodeMap<int> _numMap;
deba@417
   655
      typename Digraph::template NodeMap<int> _retMap;
deba@417
   656
      typename Digraph::template NodeMap<Arc> _predMap;
deba@417
   657
      std::stack<Edge> _edgeStack;
deba@417
   658
      int _num;
deba@417
   659
    };
deba@417
   660
deba@417
   661
deba@417
   662
    template <typename Digraph, typename NodeMap>
deba@417
   663
    class BiNodeConnectedCutNodesVisitor : public DfsVisitor<Digraph> {
deba@417
   664
    public:
deba@417
   665
      typedef typename Digraph::Node Node;
deba@417
   666
      typedef typename Digraph::Arc Arc;
deba@417
   667
      typedef typename Digraph::Edge Edge;
deba@417
   668
deba@417
   669
      BiNodeConnectedCutNodesVisitor(const Digraph& graph, NodeMap& cutMap,
deba@417
   670
                                     int& cutNum)
deba@417
   671
        : _graph(graph), _cutMap(cutMap), _cutNum(cutNum),
deba@417
   672
          _numMap(graph), _retMap(graph), _predMap(graph), _num(0) {}
deba@417
   673
deba@417
   674
      void start(const Node& node) {
deba@417
   675
        _predMap.set(node, INVALID);
deba@417
   676
        rootCut = false;
deba@417
   677
      }
deba@417
   678
deba@417
   679
      void reach(const Node& node) {
deba@417
   680
        _numMap.set(node, _num);
deba@417
   681
        _retMap.set(node, _num);
deba@417
   682
        ++_num;
deba@417
   683
      }
deba@417
   684
deba@417
   685
      void discover(const Arc& edge) {
deba@417
   686
        _predMap.set(_graph.target(edge), _graph.source(edge));
deba@417
   687
      }
deba@417
   688
deba@417
   689
      void examine(const Arc& edge) {
deba@417
   690
        if (_graph.source(edge) == _graph.target(edge) &&
deba@417
   691
            _graph.direction(edge)) {
deba@417
   692
          if (!_cutMap[_graph.source(edge)]) {
deba@417
   693
            _cutMap.set(_graph.source(edge), true);
deba@417
   694
            ++_cutNum;
deba@417
   695
          }
deba@417
   696
          return;
deba@417
   697
        }
deba@417
   698
        if (_predMap[_graph.source(edge)] == _graph.target(edge)) return;
deba@417
   699
        if (_retMap[_graph.source(edge)] > _numMap[_graph.target(edge)]) {
deba@417
   700
          _retMap.set(_graph.source(edge), _numMap[_graph.target(edge)]);
deba@417
   701
        }
deba@417
   702
      }
deba@417
   703
deba@417
   704
      void backtrack(const Arc& edge) {
deba@417
   705
        if (_retMap[_graph.source(edge)] > _retMap[_graph.target(edge)]) {
deba@417
   706
          _retMap.set(_graph.source(edge), _retMap[_graph.target(edge)]);
deba@417
   707
        }
deba@417
   708
        if (_numMap[_graph.source(edge)] <= _retMap[_graph.target(edge)]) {
deba@417
   709
          if (_predMap[_graph.source(edge)] != INVALID) {
deba@417
   710
            if (!_cutMap[_graph.source(edge)]) {
deba@417
   711
              _cutMap.set(_graph.source(edge), true);
deba@417
   712
              ++_cutNum;
deba@417
   713
            }
deba@417
   714
          } else if (rootCut) {
deba@417
   715
            if (!_cutMap[_graph.source(edge)]) {
deba@417
   716
              _cutMap.set(_graph.source(edge), true);
deba@417
   717
              ++_cutNum;
deba@417
   718
            }
deba@417
   719
          } else {
deba@417
   720
            rootCut = true;
deba@417
   721
          }
deba@417
   722
        }
deba@417
   723
      }
deba@417
   724
deba@417
   725
    private:
deba@417
   726
      const Digraph& _graph;
deba@417
   727
      NodeMap& _cutMap;
deba@417
   728
      int& _cutNum;
deba@417
   729
deba@417
   730
      typename Digraph::template NodeMap<int> _numMap;
deba@417
   731
      typename Digraph::template NodeMap<int> _retMap;
deba@417
   732
      typename Digraph::template NodeMap<Node> _predMap;
deba@417
   733
      std::stack<Edge> _edgeStack;
deba@417
   734
      int _num;
deba@417
   735
      bool rootCut;
deba@417
   736
    };
deba@417
   737
deba@417
   738
  }
deba@417
   739
deba@417
   740
  template <typename Graph>
deba@417
   741
  int countBiNodeConnectedComponents(const Graph& graph);
deba@417
   742
kpeter@586
   743
  /// \ingroup graph_properties
deba@417
   744
  ///
kpeter@648
   745
  /// \brief Check whether an undirected graph is bi-node-connected.
deba@417
   746
  ///
kpeter@648
   747
  /// This function checks whether the given undirected graph is 
kpeter@648
   748
  /// bi-node-connected, i.e. any two edges are on same circle.
deba@417
   749
  ///
kpeter@648
   750
  /// \return \c true if the graph bi-node-connected.
kpeter@648
   751
  /// \note By definition, the empty graph is bi-node-connected.
kpeter@648
   752
  ///
kpeter@648
   753
  /// \see countBiNodeConnectedComponents(), biNodeConnectedComponents()
deba@417
   754
  template <typename Graph>
deba@417
   755
  bool biNodeConnected(const Graph& graph) {
deba@417
   756
    return countBiNodeConnectedComponents(graph) <= 1;
deba@417
   757
  }
deba@417
   758
kpeter@586
   759
  /// \ingroup graph_properties
deba@417
   760
  ///
kpeter@648
   761
  /// \brief Count the number of bi-node-connected components of an 
kpeter@648
   762
  /// undirected graph.
deba@417
   763
  ///
kpeter@648
   764
  /// This function counts the number of bi-node-connected components of
kpeter@648
   765
  /// the given undirected graph.
deba@417
   766
  ///
kpeter@648
   767
  /// The bi-node-connected components are the classes of an equivalence
kpeter@648
   768
  /// relation on the edges of a undirected graph. Two edges are in the
kpeter@648
   769
  /// same class if they are on same circle.
kpeter@648
   770
  ///
kpeter@648
   771
  /// \return The number of bi-node-connected components.
kpeter@648
   772
  ///
kpeter@648
   773
  /// \see biNodeConnected(), biNodeConnectedComponents()
deba@417
   774
  template <typename Graph>
deba@417
   775
  int countBiNodeConnectedComponents(const Graph& graph) {
deba@417
   776
    checkConcept<concepts::Graph, Graph>();
deba@417
   777
    typedef typename Graph::NodeIt NodeIt;
deba@417
   778
deba@419
   779
    using namespace _connectivity_bits;
deba@417
   780
deba@417
   781
    typedef CountBiNodeConnectedComponentsVisitor<Graph> Visitor;
deba@417
   782
deba@417
   783
    int compNum = 0;
deba@417
   784
    Visitor visitor(graph, compNum);
deba@417
   785
deba@417
   786
    DfsVisit<Graph, Visitor> dfs(graph, visitor);
deba@417
   787
    dfs.init();
deba@417
   788
deba@417
   789
    for (NodeIt it(graph); it != INVALID; ++it) {
deba@417
   790
      if (!dfs.reached(it)) {
deba@417
   791
        dfs.addSource(it);
deba@417
   792
        dfs.start();
deba@417
   793
      }
deba@417
   794
    }
deba@417
   795
    return compNum;
deba@417
   796
  }
deba@417
   797
kpeter@586
   798
  /// \ingroup graph_properties
deba@417
   799
  ///
kpeter@648
   800
  /// \brief Find the bi-node-connected components of an undirected graph.
deba@417
   801
  ///
kpeter@648
   802
  /// This function finds the bi-node-connected components of the given
kpeter@648
   803
  /// undirected graph.
kpeter@648
   804
  ///
kpeter@648
   805
  /// The bi-node-connected components are the classes of an equivalence
kpeter@648
   806
  /// relation on the edges of a undirected graph. Two edges are in the
kpeter@648
   807
  /// same class if they are on same circle.
deba@417
   808
  ///
kpeter@586
   809
  /// \image html node_biconnected_components.png
kpeter@586
   810
  /// \image latex node_biconnected_components.eps "bi-node-connected components" width=\textwidth
kpeter@586
   811
  ///
kpeter@648
   812
  /// \param graph The undirected graph.
kpeter@648
   813
  /// \retval compMap A writable edge map. The values will be set from 0
kpeter@648
   814
  /// to the number of the bi-node-connected components minus one. Each
kpeter@648
   815
  /// value of the map will be set exactly once, and the values of a 
kpeter@648
   816
  /// certain component will be set continuously.
kpeter@648
   817
  /// \return The number of bi-node-connected components.
kpeter@648
   818
  ///
kpeter@648
   819
  /// \see biNodeConnected(), countBiNodeConnectedComponents()
deba@417
   820
  template <typename Graph, typename EdgeMap>
deba@417
   821
  int biNodeConnectedComponents(const Graph& graph,
deba@417
   822
                                EdgeMap& compMap) {
deba@417
   823
    checkConcept<concepts::Graph, Graph>();
deba@417
   824
    typedef typename Graph::NodeIt NodeIt;
deba@417
   825
    typedef typename Graph::Edge Edge;
deba@417
   826
    checkConcept<concepts::WriteMap<Edge, int>, EdgeMap>();
deba@417
   827
deba@419
   828
    using namespace _connectivity_bits;
deba@417
   829
deba@417
   830
    typedef BiNodeConnectedComponentsVisitor<Graph, EdgeMap> Visitor;
deba@417
   831
deba@417
   832
    int compNum = 0;
deba@417
   833
    Visitor visitor(graph, compMap, compNum);
deba@417
   834
deba@417
   835
    DfsVisit<Graph, Visitor> dfs(graph, visitor);
deba@417
   836
    dfs.init();
deba@417
   837
deba@417
   838
    for (NodeIt it(graph); it != INVALID; ++it) {
deba@417
   839
      if (!dfs.reached(it)) {
deba@417
   840
        dfs.addSource(it);
deba@417
   841
        dfs.start();
deba@417
   842
      }
deba@417
   843
    }
deba@417
   844
    return compNum;
deba@417
   845
  }
deba@417
   846
kpeter@586
   847
  /// \ingroup graph_properties
deba@417
   848
  ///
kpeter@648
   849
  /// \brief Find the bi-node-connected cut nodes in an undirected graph.
deba@417
   850
  ///
kpeter@648
   851
  /// This function finds the bi-node-connected cut nodes in the given
kpeter@648
   852
  /// undirected graph.
deba@417
   853
  ///
kpeter@648
   854
  /// The bi-node-connected components are the classes of an equivalence
kpeter@648
   855
  /// relation on the edges of a undirected graph. Two edges are in the
kpeter@648
   856
  /// same class if they are on same circle.
kpeter@648
   857
  /// The bi-node-connected components are separted by the cut nodes of
kpeter@648
   858
  /// the components.
kpeter@648
   859
  ///
kpeter@648
   860
  /// \param graph The undirected graph.
kpeter@648
   861
  /// \retval cutMap A writable node map. The values will be set to 
kpeter@648
   862
  /// \c true for the nodes that separate two or more components
kpeter@648
   863
  /// (exactly once for each cut node), and will not be changed for
kpeter@648
   864
  /// other nodes.
deba@417
   865
  /// \return The number of the cut nodes.
kpeter@648
   866
  ///
kpeter@648
   867
  /// \see biNodeConnected(), biNodeConnectedComponents()
deba@417
   868
  template <typename Graph, typename NodeMap>
deba@417
   869
  int biNodeConnectedCutNodes(const Graph& graph, NodeMap& cutMap) {
deba@417
   870
    checkConcept<concepts::Graph, Graph>();
deba@417
   871
    typedef typename Graph::Node Node;
deba@417
   872
    typedef typename Graph::NodeIt NodeIt;
deba@417
   873
    checkConcept<concepts::WriteMap<Node, bool>, NodeMap>();
deba@417
   874
deba@419
   875
    using namespace _connectivity_bits;
deba@417
   876
deba@417
   877
    typedef BiNodeConnectedCutNodesVisitor<Graph, NodeMap> Visitor;
deba@417
   878
deba@417
   879
    int cutNum = 0;
deba@417
   880
    Visitor visitor(graph, cutMap, cutNum);
deba@417
   881
deba@417
   882
    DfsVisit<Graph, Visitor> dfs(graph, visitor);
deba@417
   883
    dfs.init();
deba@417
   884
deba@417
   885
    for (NodeIt it(graph); it != INVALID; ++it) {
deba@417
   886
      if (!dfs.reached(it)) {
deba@417
   887
        dfs.addSource(it);
deba@417
   888
        dfs.start();
deba@417
   889
      }
deba@417
   890
    }
deba@417
   891
    return cutNum;
deba@417
   892
  }
deba@417
   893
deba@419
   894
  namespace _connectivity_bits {
deba@417
   895
deba@417
   896
    template <typename Digraph>
deba@417
   897
    class CountBiEdgeConnectedComponentsVisitor : public DfsVisitor<Digraph> {
deba@417
   898
    public:
deba@417
   899
      typedef typename Digraph::Node Node;
deba@417
   900
      typedef typename Digraph::Arc Arc;
deba@417
   901
      typedef typename Digraph::Edge Edge;
deba@417
   902
deba@417
   903
      CountBiEdgeConnectedComponentsVisitor(const Digraph& graph, int &compNum)
deba@417
   904
        : _graph(graph), _compNum(compNum),
deba@417
   905
          _numMap(graph), _retMap(graph), _predMap(graph), _num(0) {}
deba@417
   906
deba@417
   907
      void start(const Node& node) {
deba@417
   908
        _predMap.set(node, INVALID);
deba@417
   909
      }
deba@417
   910
deba@417
   911
      void reach(const Node& node) {
deba@417
   912
        _numMap.set(node, _num);
deba@417
   913
        _retMap.set(node, _num);
deba@417
   914
        ++_num;
deba@417
   915
      }
deba@417
   916
deba@417
   917
      void leave(const Node& node) {
deba@417
   918
        if (_numMap[node] <= _retMap[node]) {
deba@417
   919
          ++_compNum;
deba@417
   920
        }
deba@417
   921
      }
deba@417
   922
deba@417
   923
      void discover(const Arc& edge) {
deba@417
   924
        _predMap.set(_graph.target(edge), edge);
deba@417
   925
      }
deba@417
   926
deba@417
   927
      void examine(const Arc& edge) {
deba@417
   928
        if (_predMap[_graph.source(edge)] == _graph.oppositeArc(edge)) {
deba@417
   929
          return;
deba@417
   930
        }
deba@417
   931
        if (_retMap[_graph.source(edge)] > _retMap[_graph.target(edge)]) {
deba@417
   932
          _retMap.set(_graph.source(edge), _retMap[_graph.target(edge)]);
deba@417
   933
        }
deba@417
   934
      }
deba@417
   935
deba@417
   936
      void backtrack(const Arc& edge) {
deba@417
   937
        if (_retMap[_graph.source(edge)] > _retMap[_graph.target(edge)]) {
deba@417
   938
          _retMap.set(_graph.source(edge), _retMap[_graph.target(edge)]);
deba@417
   939
        }
deba@417
   940
      }
deba@417
   941
deba@417
   942
    private:
deba@417
   943
      const Digraph& _graph;
deba@417
   944
      int& _compNum;
deba@417
   945
deba@417
   946
      typename Digraph::template NodeMap<int> _numMap;
deba@417
   947
      typename Digraph::template NodeMap<int> _retMap;
deba@417
   948
      typename Digraph::template NodeMap<Arc> _predMap;
deba@417
   949
      int _num;
deba@417
   950
    };
deba@417
   951
deba@417
   952
    template <typename Digraph, typename NodeMap>
deba@417
   953
    class BiEdgeConnectedComponentsVisitor : public DfsVisitor<Digraph> {
deba@417
   954
    public:
deba@417
   955
      typedef typename Digraph::Node Node;
deba@417
   956
      typedef typename Digraph::Arc Arc;
deba@417
   957
      typedef typename Digraph::Edge Edge;
deba@417
   958
deba@417
   959
      BiEdgeConnectedComponentsVisitor(const Digraph& graph,
deba@417
   960
                                       NodeMap& compMap, int &compNum)
deba@417
   961
        : _graph(graph), _compMap(compMap), _compNum(compNum),
deba@417
   962
          _numMap(graph), _retMap(graph), _predMap(graph), _num(0) {}
deba@417
   963
deba@417
   964
      void start(const Node& node) {
deba@417
   965
        _predMap.set(node, INVALID);
deba@417
   966
      }
deba@417
   967
deba@417
   968
      void reach(const Node& node) {
deba@417
   969
        _numMap.set(node, _num);
deba@417
   970
        _retMap.set(node, _num);
deba@417
   971
        _nodeStack.push(node);
deba@417
   972
        ++_num;
deba@417
   973
      }
deba@417
   974
deba@417
   975
      void leave(const Node& node) {
deba@417
   976
        if (_numMap[node] <= _retMap[node]) {
deba@417
   977
          while (_nodeStack.top() != node) {
deba@417
   978
            _compMap.set(_nodeStack.top(), _compNum);
deba@417
   979
            _nodeStack.pop();
deba@417
   980
          }
deba@417
   981
          _compMap.set(node, _compNum);
deba@417
   982
          _nodeStack.pop();
deba@417
   983
          ++_compNum;
deba@417
   984
        }
deba@417
   985
      }
deba@417
   986
deba@417
   987
      void discover(const Arc& edge) {
deba@417
   988
        _predMap.set(_graph.target(edge), edge);
deba@417
   989
      }
deba@417
   990
deba@417
   991
      void examine(const Arc& edge) {
deba@417
   992
        if (_predMap[_graph.source(edge)] == _graph.oppositeArc(edge)) {
deba@417
   993
          return;
deba@417
   994
        }
deba@417
   995
        if (_retMap[_graph.source(edge)] > _retMap[_graph.target(edge)]) {
deba@417
   996
          _retMap.set(_graph.source(edge), _retMap[_graph.target(edge)]);
deba@417
   997
        }
deba@417
   998
      }
deba@417
   999
deba@417
  1000
      void backtrack(const Arc& edge) {
deba@417
  1001
        if (_retMap[_graph.source(edge)] > _retMap[_graph.target(edge)]) {
deba@417
  1002
          _retMap.set(_graph.source(edge), _retMap[_graph.target(edge)]);
deba@417
  1003
        }
deba@417
  1004
      }
deba@417
  1005
deba@417
  1006
    private:
deba@417
  1007
      const Digraph& _graph;
deba@417
  1008
      NodeMap& _compMap;
deba@417
  1009
      int& _compNum;
deba@417
  1010
deba@417
  1011
      typename Digraph::template NodeMap<int> _numMap;
deba@417
  1012
      typename Digraph::template NodeMap<int> _retMap;
deba@417
  1013
      typename Digraph::template NodeMap<Arc> _predMap;
deba@417
  1014
      std::stack<Node> _nodeStack;
deba@417
  1015
      int _num;
deba@417
  1016
    };
deba@417
  1017
deba@417
  1018
deba@417
  1019
    template <typename Digraph, typename ArcMap>
deba@417
  1020
    class BiEdgeConnectedCutEdgesVisitor : public DfsVisitor<Digraph> {
deba@417
  1021
    public:
deba@417
  1022
      typedef typename Digraph::Node Node;
deba@417
  1023
      typedef typename Digraph::Arc Arc;
deba@417
  1024
      typedef typename Digraph::Edge Edge;
deba@417
  1025
deba@417
  1026
      BiEdgeConnectedCutEdgesVisitor(const Digraph& graph,
deba@417
  1027
                                     ArcMap& cutMap, int &cutNum)
deba@417
  1028
        : _graph(graph), _cutMap(cutMap), _cutNum(cutNum),
deba@417
  1029
          _numMap(graph), _retMap(graph), _predMap(graph), _num(0) {}
deba@417
  1030
deba@417
  1031
      void start(const Node& node) {
deba@417
  1032
        _predMap[node] = INVALID;
deba@417
  1033
      }
deba@417
  1034
deba@417
  1035
      void reach(const Node& node) {
deba@417
  1036
        _numMap.set(node, _num);
deba@417
  1037
        _retMap.set(node, _num);
deba@417
  1038
        ++_num;
deba@417
  1039
      }
deba@417
  1040
deba@417
  1041
      void leave(const Node& node) {
deba@417
  1042
        if (_numMap[node] <= _retMap[node]) {
deba@417
  1043
          if (_predMap[node] != INVALID) {
deba@417
  1044
            _cutMap.set(_predMap[node], true);
deba@417
  1045
            ++_cutNum;
deba@417
  1046
          }
deba@417
  1047
        }
deba@417
  1048
      }
deba@417
  1049
deba@417
  1050
      void discover(const Arc& edge) {
deba@417
  1051
        _predMap.set(_graph.target(edge), edge);
deba@417
  1052
      }
deba@417
  1053
deba@417
  1054
      void examine(const Arc& edge) {
deba@417
  1055
        if (_predMap[_graph.source(edge)] == _graph.oppositeArc(edge)) {
deba@417
  1056
          return;
deba@417
  1057
        }
deba@417
  1058
        if (_retMap[_graph.source(edge)] > _retMap[_graph.target(edge)]) {
deba@417
  1059
          _retMap.set(_graph.source(edge), _retMap[_graph.target(edge)]);
deba@417
  1060
        }
deba@417
  1061
      }
deba@417
  1062
deba@417
  1063
      void backtrack(const Arc& edge) {
deba@417
  1064
        if (_retMap[_graph.source(edge)] > _retMap[_graph.target(edge)]) {
deba@417
  1065
          _retMap.set(_graph.source(edge), _retMap[_graph.target(edge)]);
deba@417
  1066
        }
deba@417
  1067
      }
deba@417
  1068
deba@417
  1069
    private:
deba@417
  1070
      const Digraph& _graph;
deba@417
  1071
      ArcMap& _cutMap;
deba@417
  1072
      int& _cutNum;
deba@417
  1073
deba@417
  1074
      typename Digraph::template NodeMap<int> _numMap;
deba@417
  1075
      typename Digraph::template NodeMap<int> _retMap;
deba@417
  1076
      typename Digraph::template NodeMap<Arc> _predMap;
deba@417
  1077
      int _num;
deba@417
  1078
    };
deba@417
  1079
  }
deba@417
  1080
deba@417
  1081
  template <typename Graph>
deba@417
  1082
  int countBiEdgeConnectedComponents(const Graph& graph);
deba@417
  1083
kpeter@586
  1084
  /// \ingroup graph_properties
deba@417
  1085
  ///
kpeter@648
  1086
  /// \brief Check whether an undirected graph is bi-edge-connected.
deba@417
  1087
  ///
kpeter@648
  1088
  /// This function checks whether the given undirected graph is 
kpeter@648
  1089
  /// bi-edge-connected, i.e. any two nodes are connected with at least
kpeter@648
  1090
  /// two edge-disjoint paths.
deba@417
  1091
  ///
kpeter@648
  1092
  /// \return \c true if the graph is bi-edge-connected.
kpeter@648
  1093
  /// \note By definition, the empty graph is bi-edge-connected.
kpeter@648
  1094
  ///
kpeter@648
  1095
  /// \see countBiEdgeConnectedComponents(), biEdgeConnectedComponents()
deba@417
  1096
  template <typename Graph>
deba@417
  1097
  bool biEdgeConnected(const Graph& graph) {
deba@417
  1098
    return countBiEdgeConnectedComponents(graph) <= 1;
deba@417
  1099
  }
deba@417
  1100
kpeter@586
  1101
  /// \ingroup graph_properties
deba@417
  1102
  ///
kpeter@648
  1103
  /// \brief Count the number of bi-edge-connected components of an
kpeter@648
  1104
  /// undirected graph.
deba@417
  1105
  ///
kpeter@648
  1106
  /// This function counts the number of bi-edge-connected components of
kpeter@648
  1107
  /// the given undirected graph.
deba@417
  1108
  ///
kpeter@648
  1109
  /// The bi-edge-connected components are the classes of an equivalence
kpeter@648
  1110
  /// relation on the nodes of an undirected graph. Two nodes are in the
kpeter@648
  1111
  /// same class if they are connected with at least two edge-disjoint
kpeter@648
  1112
  /// paths.
kpeter@648
  1113
  ///
kpeter@648
  1114
  /// \return The number of bi-edge-connected components.
kpeter@648
  1115
  ///
kpeter@648
  1116
  /// \see biEdgeConnected(), biEdgeConnectedComponents()
deba@417
  1117
  template <typename Graph>
deba@417
  1118
  int countBiEdgeConnectedComponents(const Graph& graph) {
deba@417
  1119
    checkConcept<concepts::Graph, Graph>();
deba@417
  1120
    typedef typename Graph::NodeIt NodeIt;
deba@417
  1121
deba@419
  1122
    using namespace _connectivity_bits;
deba@417
  1123
deba@417
  1124
    typedef CountBiEdgeConnectedComponentsVisitor<Graph> Visitor;
deba@417
  1125
deba@417
  1126
    int compNum = 0;
deba@417
  1127
    Visitor visitor(graph, compNum);
deba@417
  1128
deba@417
  1129
    DfsVisit<Graph, Visitor> dfs(graph, visitor);
deba@417
  1130
    dfs.init();
deba@417
  1131
deba@417
  1132
    for (NodeIt it(graph); it != INVALID; ++it) {
deba@417
  1133
      if (!dfs.reached(it)) {
deba@417
  1134
        dfs.addSource(it);
deba@417
  1135
        dfs.start();
deba@417
  1136
      }
deba@417
  1137
    }
deba@417
  1138
    return compNum;
deba@417
  1139
  }
deba@417
  1140
kpeter@586
  1141
  /// \ingroup graph_properties
deba@417
  1142
  ///
kpeter@648
  1143
  /// \brief Find the bi-edge-connected components of an undirected graph.
deba@417
  1144
  ///
kpeter@648
  1145
  /// This function finds the bi-edge-connected components of the given
kpeter@648
  1146
  /// undirected graph.
kpeter@648
  1147
  ///
kpeter@648
  1148
  /// The bi-edge-connected components are the classes of an equivalence
kpeter@648
  1149
  /// relation on the nodes of an undirected graph. Two nodes are in the
kpeter@648
  1150
  /// same class if they are connected with at least two edge-disjoint
kpeter@648
  1151
  /// paths.
deba@417
  1152
  ///
kpeter@586
  1153
  /// \image html edge_biconnected_components.png
kpeter@586
  1154
  /// \image latex edge_biconnected_components.eps "bi-edge-connected components" width=\textwidth
kpeter@586
  1155
  ///
kpeter@648
  1156
  /// \param graph The undirected graph.
deba@417
  1157
  /// \retval compMap A writable node map. The values will be set from 0 to
kpeter@648
  1158
  /// the number of the bi-edge-connected components minus one. Each value
kpeter@648
  1159
  /// of the map will be set exactly once, and the values of a certain
kpeter@648
  1160
  /// component will be set continuously.
kpeter@648
  1161
  /// \return The number of bi-edge-connected components.
kpeter@648
  1162
  ///
kpeter@648
  1163
  /// \see biEdgeConnected(), countBiEdgeConnectedComponents()
deba@417
  1164
  template <typename Graph, typename NodeMap>
deba@417
  1165
  int biEdgeConnectedComponents(const Graph& graph, NodeMap& compMap) {
deba@417
  1166
    checkConcept<concepts::Graph, Graph>();
deba@417
  1167
    typedef typename Graph::NodeIt NodeIt;
deba@417
  1168
    typedef typename Graph::Node Node;
deba@417
  1169
    checkConcept<concepts::WriteMap<Node, int>, NodeMap>();
deba@417
  1170
deba@419
  1171
    using namespace _connectivity_bits;
deba@417
  1172
deba@417
  1173
    typedef BiEdgeConnectedComponentsVisitor<Graph, NodeMap> Visitor;
deba@417
  1174
deba@417
  1175
    int compNum = 0;
deba@417
  1176
    Visitor visitor(graph, compMap, compNum);
deba@417
  1177
deba@417
  1178
    DfsVisit<Graph, Visitor> dfs(graph, visitor);
deba@417
  1179
    dfs.init();
deba@417
  1180
deba@417
  1181
    for (NodeIt it(graph); it != INVALID; ++it) {
deba@417
  1182
      if (!dfs.reached(it)) {
deba@417
  1183
        dfs.addSource(it);
deba@417
  1184
        dfs.start();
deba@417
  1185
      }
deba@417
  1186
    }
deba@417
  1187
    return compNum;
deba@417
  1188
  }
deba@417
  1189
kpeter@586
  1190
  /// \ingroup graph_properties
deba@417
  1191
  ///
kpeter@648
  1192
  /// \brief Find the bi-edge-connected cut edges in an undirected graph.
deba@417
  1193
  ///
kpeter@648
  1194
  /// This function finds the bi-edge-connected cut edges in the given
kpeter@648
  1195
  /// undirected graph. 
deba@417
  1196
  ///
kpeter@648
  1197
  /// The bi-edge-connected components are the classes of an equivalence
kpeter@648
  1198
  /// relation on the nodes of an undirected graph. Two nodes are in the
kpeter@648
  1199
  /// same class if they are connected with at least two edge-disjoint
kpeter@648
  1200
  /// paths.
kpeter@648
  1201
  /// The bi-edge-connected components are separted by the cut edges of
kpeter@648
  1202
  /// the components.
kpeter@648
  1203
  ///
kpeter@648
  1204
  /// \param graph The undirected graph.
kpeter@648
  1205
  /// \retval cutMap A writable edge map. The values will be set to \c true
kpeter@648
  1206
  /// for the cut edges (exactly once for each cut edge), and will not be
kpeter@648
  1207
  /// changed for other edges.
deba@417
  1208
  /// \return The number of cut edges.
kpeter@648
  1209
  ///
kpeter@648
  1210
  /// \see biEdgeConnected(), biEdgeConnectedComponents()
deba@417
  1211
  template <typename Graph, typename EdgeMap>
deba@417
  1212
  int biEdgeConnectedCutEdges(const Graph& graph, EdgeMap& cutMap) {
deba@417
  1213
    checkConcept<concepts::Graph, Graph>();
deba@417
  1214
    typedef typename Graph::NodeIt NodeIt;
deba@417
  1215
    typedef typename Graph::Edge Edge;
deba@417
  1216
    checkConcept<concepts::WriteMap<Edge, bool>, EdgeMap>();
deba@417
  1217
deba@419
  1218
    using namespace _connectivity_bits;
deba@417
  1219
deba@417
  1220
    typedef BiEdgeConnectedCutEdgesVisitor<Graph, EdgeMap> Visitor;
deba@417
  1221
deba@417
  1222
    int cutNum = 0;
deba@417
  1223
    Visitor visitor(graph, cutMap, cutNum);
deba@417
  1224
deba@417
  1225
    DfsVisit<Graph, Visitor> dfs(graph, visitor);
deba@417
  1226
    dfs.init();
deba@417
  1227
deba@417
  1228
    for (NodeIt it(graph); it != INVALID; ++it) {
deba@417
  1229
      if (!dfs.reached(it)) {
deba@417
  1230
        dfs.addSource(it);
deba@417
  1231
        dfs.start();
deba@417
  1232
      }
deba@417
  1233
    }
deba@417
  1234
    return cutNum;
deba@417
  1235
  }
deba@417
  1236
deba@417
  1237
deba@419
  1238
  namespace _connectivity_bits {
deba@417
  1239
deba@417
  1240
    template <typename Digraph, typename IntNodeMap>
deba@417
  1241
    class TopologicalSortVisitor : public DfsVisitor<Digraph> {
deba@417
  1242
    public:
deba@417
  1243
      typedef typename Digraph::Node Node;
deba@417
  1244
      typedef typename Digraph::Arc edge;
deba@417
  1245
deba@417
  1246
      TopologicalSortVisitor(IntNodeMap& order, int num)
deba@417
  1247
        : _order(order), _num(num) {}
deba@417
  1248
deba@417
  1249
      void leave(const Node& node) {
deba@417
  1250
        _order.set(node, --_num);
deba@417
  1251
      }
deba@417
  1252
deba@417
  1253
    private:
deba@417
  1254
      IntNodeMap& _order;
deba@417
  1255
      int _num;
deba@417
  1256
    };
deba@417
  1257
deba@417
  1258
  }
deba@417
  1259
kpeter@586
  1260
  /// \ingroup graph_properties
deba@417
  1261
  ///
kpeter@648
  1262
  /// \brief Check whether a digraph is DAG.
kpeter@648
  1263
  ///
kpeter@648
  1264
  /// This function checks whether the given digraph is DAG, i.e.
kpeter@648
  1265
  /// \e Directed \e Acyclic \e Graph.
kpeter@648
  1266
  /// \return \c true if there is no directed cycle in the digraph.
kpeter@648
  1267
  /// \see acyclic()
kpeter@648
  1268
  template <typename Digraph>
kpeter@648
  1269
  bool dag(const Digraph& digraph) {
kpeter@648
  1270
kpeter@648
  1271
    checkConcept<concepts::Digraph, Digraph>();
kpeter@648
  1272
kpeter@648
  1273
    typedef typename Digraph::Node Node;
kpeter@648
  1274
    typedef typename Digraph::NodeIt NodeIt;
kpeter@648
  1275
    typedef typename Digraph::Arc Arc;
kpeter@648
  1276
kpeter@648
  1277
    typedef typename Digraph::template NodeMap<bool> ProcessedMap;
kpeter@648
  1278
kpeter@648
  1279
    typename Dfs<Digraph>::template SetProcessedMap<ProcessedMap>::
kpeter@648
  1280
      Create dfs(digraph);
kpeter@648
  1281
kpeter@648
  1282
    ProcessedMap processed(digraph);
kpeter@648
  1283
    dfs.processedMap(processed);
kpeter@648
  1284
kpeter@648
  1285
    dfs.init();
kpeter@648
  1286
    for (NodeIt it(digraph); it != INVALID; ++it) {
kpeter@648
  1287
      if (!dfs.reached(it)) {
kpeter@648
  1288
        dfs.addSource(it);
kpeter@648
  1289
        while (!dfs.emptyQueue()) {
kpeter@648
  1290
          Arc arc = dfs.nextArc();
kpeter@648
  1291
          Node target = digraph.target(arc);
kpeter@648
  1292
          if (dfs.reached(target) && !processed[target]) {
kpeter@648
  1293
            return false;
kpeter@648
  1294
          }
kpeter@648
  1295
          dfs.processNextArc();
kpeter@648
  1296
        }
kpeter@648
  1297
      }
kpeter@648
  1298
    }
kpeter@648
  1299
    return true;
kpeter@648
  1300
  }
kpeter@648
  1301
kpeter@648
  1302
  /// \ingroup graph_properties
kpeter@648
  1303
  ///
deba@417
  1304
  /// \brief Sort the nodes of a DAG into topolgical order.
deba@417
  1305
  ///
kpeter@648
  1306
  /// This function sorts the nodes of the given acyclic digraph (DAG)
kpeter@648
  1307
  /// into topolgical order.
deba@417
  1308
  ///
kpeter@648
  1309
  /// \param digraph The digraph, which must be DAG.
deba@417
  1310
  /// \retval order A writable node map. The values will be set from 0 to
kpeter@648
  1311
  /// the number of the nodes in the digraph minus one. Each value of the
kpeter@648
  1312
  /// map will be set exactly once, and the values will be set descending
kpeter@648
  1313
  /// order.
deba@417
  1314
  ///
kpeter@648
  1315
  /// \see dag(), checkedTopologicalSort()
deba@417
  1316
  template <typename Digraph, typename NodeMap>
kpeter@648
  1317
  void topologicalSort(const Digraph& digraph, NodeMap& order) {
deba@419
  1318
    using namespace _connectivity_bits;
deba@417
  1319
deba@417
  1320
    checkConcept<concepts::Digraph, Digraph>();
deba@417
  1321
    checkConcept<concepts::WriteMap<typename Digraph::Node, int>, NodeMap>();
deba@417
  1322
deba@417
  1323
    typedef typename Digraph::Node Node;
deba@417
  1324
    typedef typename Digraph::NodeIt NodeIt;
deba@417
  1325
    typedef typename Digraph::Arc Arc;
deba@417
  1326
deba@417
  1327
    TopologicalSortVisitor<Digraph, NodeMap>
kpeter@648
  1328
      visitor(order, countNodes(digraph));
deba@417
  1329
deba@417
  1330
    DfsVisit<Digraph, TopologicalSortVisitor<Digraph, NodeMap> >
kpeter@648
  1331
      dfs(digraph, visitor);
deba@417
  1332
deba@417
  1333
    dfs.init();
kpeter@648
  1334
    for (NodeIt it(digraph); it != INVALID; ++it) {
deba@417
  1335
      if (!dfs.reached(it)) {
deba@417
  1336
        dfs.addSource(it);
deba@417
  1337
        dfs.start();
deba@417
  1338
      }
deba@417
  1339
    }
deba@417
  1340
  }
deba@417
  1341
kpeter@586
  1342
  /// \ingroup graph_properties
deba@417
  1343
  ///
deba@417
  1344
  /// \brief Sort the nodes of a DAG into topolgical order.
deba@417
  1345
  ///
kpeter@648
  1346
  /// This function sorts the nodes of the given acyclic digraph (DAG)
kpeter@648
  1347
  /// into topolgical order and also checks whether the given digraph
kpeter@648
  1348
  /// is DAG.
deba@417
  1349
  ///
kpeter@648
  1350
  /// \param digraph The digraph.
kpeter@648
  1351
  /// \retval order A readable and writable node map. The values will be
kpeter@648
  1352
  /// set from 0 to the number of the nodes in the digraph minus one. 
kpeter@648
  1353
  /// Each value of the map will be set exactly once, and the values will
kpeter@648
  1354
  /// be set descending order.
kpeter@648
  1355
  /// \return \c false if the digraph is not DAG.
deba@417
  1356
  ///
kpeter@648
  1357
  /// \see dag(), topologicalSort()
deba@417
  1358
  template <typename Digraph, typename NodeMap>
deba@419
  1359
  bool checkedTopologicalSort(const Digraph& digraph, NodeMap& order) {
deba@419
  1360
    using namespace _connectivity_bits;
deba@417
  1361
deba@417
  1362
    checkConcept<concepts::Digraph, Digraph>();
deba@417
  1363
    checkConcept<concepts::ReadWriteMap<typename Digraph::Node, int>,
deba@417
  1364
      NodeMap>();
deba@417
  1365
deba@417
  1366
    typedef typename Digraph::Node Node;
deba@417
  1367
    typedef typename Digraph::NodeIt NodeIt;
deba@417
  1368
    typedef typename Digraph::Arc Arc;
deba@417
  1369
deba@419
  1370
    for (NodeIt it(digraph); it != INVALID; ++it) {
deba@419
  1371
      order.set(it, -1);
deba@419
  1372
    }
deba@417
  1373
deba@417
  1374
    TopologicalSortVisitor<Digraph, NodeMap>
deba@419
  1375
      visitor(order, countNodes(digraph));
deba@417
  1376
deba@417
  1377
    DfsVisit<Digraph, TopologicalSortVisitor<Digraph, NodeMap> >
deba@419
  1378
      dfs(digraph, visitor);
deba@417
  1379
deba@417
  1380
    dfs.init();
deba@419
  1381
    for (NodeIt it(digraph); it != INVALID; ++it) {
deba@417
  1382
      if (!dfs.reached(it)) {
deba@417
  1383
        dfs.addSource(it);
deba@417
  1384
        while (!dfs.emptyQueue()) {
deba@419
  1385
           Arc arc = dfs.nextArc();
deba@419
  1386
           Node target = digraph.target(arc);
deba@417
  1387
           if (dfs.reached(target) && order[target] == -1) {
deba@417
  1388
             return false;
deba@417
  1389
           }
deba@417
  1390
           dfs.processNextArc();
deba@417
  1391
         }
deba@417
  1392
      }
deba@417
  1393
    }
deba@417
  1394
    return true;
deba@417
  1395
  }
deba@417
  1396
kpeter@586
  1397
  /// \ingroup graph_properties
deba@417
  1398
  ///
kpeter@648
  1399
  /// \brief Check whether an undirected graph is acyclic.
deba@417
  1400
  ///
kpeter@648
  1401
  /// This function checks whether the given undirected graph is acyclic.
kpeter@648
  1402
  /// \return \c true if there is no cycle in the graph.
kpeter@648
  1403
  /// \see dag()
deba@417
  1404
  template <typename Graph>
deba@417
  1405
  bool acyclic(const Graph& graph) {
deba@417
  1406
    checkConcept<concepts::Graph, Graph>();
deba@417
  1407
    typedef typename Graph::Node Node;
deba@417
  1408
    typedef typename Graph::NodeIt NodeIt;
deba@417
  1409
    typedef typename Graph::Arc Arc;
deba@417
  1410
    Dfs<Graph> dfs(graph);
deba@417
  1411
    dfs.init();
deba@417
  1412
    for (NodeIt it(graph); it != INVALID; ++it) {
deba@417
  1413
      if (!dfs.reached(it)) {
deba@417
  1414
        dfs.addSource(it);
deba@417
  1415
        while (!dfs.emptyQueue()) {
kpeter@648
  1416
          Arc arc = dfs.nextArc();
kpeter@648
  1417
          Node source = graph.source(arc);
kpeter@648
  1418
          Node target = graph.target(arc);
deba@417
  1419
          if (dfs.reached(target) &&
kpeter@648
  1420
              dfs.predArc(source) != graph.oppositeArc(arc)) {
deba@417
  1421
            return false;
deba@417
  1422
          }
deba@417
  1423
          dfs.processNextArc();
deba@417
  1424
        }
deba@417
  1425
      }
deba@417
  1426
    }
deba@417
  1427
    return true;
deba@417
  1428
  }
deba@417
  1429
kpeter@586
  1430
  /// \ingroup graph_properties
deba@417
  1431
  ///
kpeter@648
  1432
  /// \brief Check whether an undirected graph is tree.
deba@417
  1433
  ///
kpeter@648
  1434
  /// This function checks whether the given undirected graph is tree.
kpeter@648
  1435
  /// \return \c true if the graph is acyclic and connected.
kpeter@648
  1436
  /// \see acyclic(), connected()
deba@417
  1437
  template <typename Graph>
deba@417
  1438
  bool tree(const Graph& graph) {
deba@417
  1439
    checkConcept<concepts::Graph, Graph>();
deba@417
  1440
    typedef typename Graph::Node Node;
deba@417
  1441
    typedef typename Graph::NodeIt NodeIt;
deba@417
  1442
    typedef typename Graph::Arc Arc;
kpeter@647
  1443
    if (NodeIt(graph) == INVALID) return true;
deba@417
  1444
    Dfs<Graph> dfs(graph);
deba@417
  1445
    dfs.init();
deba@417
  1446
    dfs.addSource(NodeIt(graph));
deba@417
  1447
    while (!dfs.emptyQueue()) {
kpeter@648
  1448
      Arc arc = dfs.nextArc();
kpeter@648
  1449
      Node source = graph.source(arc);
kpeter@648
  1450
      Node target = graph.target(arc);
deba@417
  1451
      if (dfs.reached(target) &&
kpeter@648
  1452
          dfs.predArc(source) != graph.oppositeArc(arc)) {
deba@417
  1453
        return false;
deba@417
  1454
      }
deba@417
  1455
      dfs.processNextArc();
deba@417
  1456
    }
deba@417
  1457
    for (NodeIt it(graph); it != INVALID; ++it) {
deba@417
  1458
      if (!dfs.reached(it)) {
deba@417
  1459
        return false;
deba@417
  1460
      }
deba@417
  1461
    }
deba@417
  1462
    return true;
deba@417
  1463
  }
deba@417
  1464
deba@419
  1465
  namespace _connectivity_bits {
deba@417
  1466
deba@417
  1467
    template <typename Digraph>
deba@417
  1468
    class BipartiteVisitor : public BfsVisitor<Digraph> {
deba@417
  1469
    public:
deba@417
  1470
      typedef typename Digraph::Arc Arc;
deba@417
  1471
      typedef typename Digraph::Node Node;
deba@417
  1472
deba@417
  1473
      BipartiteVisitor(const Digraph& graph, bool& bipartite)
deba@417
  1474
        : _graph(graph), _part(graph), _bipartite(bipartite) {}
deba@417
  1475
deba@417
  1476
      void start(const Node& node) {
deba@417
  1477
        _part[node] = true;
deba@417
  1478
      }
deba@417
  1479
      void discover(const Arc& edge) {
deba@417
  1480
        _part.set(_graph.target(edge), !_part[_graph.source(edge)]);
deba@417
  1481
      }
deba@417
  1482
      void examine(const Arc& edge) {
deba@417
  1483
        _bipartite = _bipartite &&
deba@417
  1484
          _part[_graph.target(edge)] != _part[_graph.source(edge)];
deba@417
  1485
      }
deba@417
  1486
deba@417
  1487
    private:
deba@417
  1488
deba@417
  1489
      const Digraph& _graph;
deba@417
  1490
      typename Digraph::template NodeMap<bool> _part;
deba@417
  1491
      bool& _bipartite;
deba@417
  1492
    };
deba@417
  1493
deba@417
  1494
    template <typename Digraph, typename PartMap>
deba@417
  1495
    class BipartitePartitionsVisitor : public BfsVisitor<Digraph> {
deba@417
  1496
    public:
deba@417
  1497
      typedef typename Digraph::Arc Arc;
deba@417
  1498
      typedef typename Digraph::Node Node;
deba@417
  1499
deba@417
  1500
      BipartitePartitionsVisitor(const Digraph& graph,
deba@417
  1501
                                 PartMap& part, bool& bipartite)
deba@417
  1502
        : _graph(graph), _part(part), _bipartite(bipartite) {}
deba@417
  1503
deba@417
  1504
      void start(const Node& node) {
deba@417
  1505
        _part.set(node, true);
deba@417
  1506
      }
deba@417
  1507
      void discover(const Arc& edge) {
deba@417
  1508
        _part.set(_graph.target(edge), !_part[_graph.source(edge)]);
deba@417
  1509
      }
deba@417
  1510
      void examine(const Arc& edge) {
deba@417
  1511
        _bipartite = _bipartite &&
deba@417
  1512
          _part[_graph.target(edge)] != _part[_graph.source(edge)];
deba@417
  1513
      }
deba@417
  1514
deba@417
  1515
    private:
deba@417
  1516
deba@417
  1517
      const Digraph& _graph;
deba@417
  1518
      PartMap& _part;
deba@417
  1519
      bool& _bipartite;
deba@417
  1520
    };
deba@417
  1521
  }
deba@417
  1522
kpeter@586
  1523
  /// \ingroup graph_properties
deba@417
  1524
  ///
kpeter@648
  1525
  /// \brief Check whether an undirected graph is bipartite.
deba@417
  1526
  ///
kpeter@648
  1527
  /// The function checks whether the given undirected graph is bipartite.
kpeter@648
  1528
  /// \return \c true if the graph is bipartite.
kpeter@648
  1529
  ///
kpeter@648
  1530
  /// \see bipartitePartitions()
deba@417
  1531
  template<typename Graph>
kpeter@648
  1532
  bool bipartite(const Graph &graph){
deba@419
  1533
    using namespace _connectivity_bits;
deba@417
  1534
deba@417
  1535
    checkConcept<concepts::Graph, Graph>();
deba@417
  1536
deba@417
  1537
    typedef typename Graph::NodeIt NodeIt;
deba@417
  1538
    typedef typename Graph::ArcIt ArcIt;
deba@417
  1539
deba@417
  1540
    bool bipartite = true;
deba@417
  1541
deba@417
  1542
    BipartiteVisitor<Graph>
deba@417
  1543
      visitor(graph, bipartite);
deba@417
  1544
    BfsVisit<Graph, BipartiteVisitor<Graph> >
deba@417
  1545
      bfs(graph, visitor);
deba@417
  1546
    bfs.init();
deba@417
  1547
    for(NodeIt it(graph); it != INVALID; ++it) {
deba@417
  1548
      if(!bfs.reached(it)){
deba@417
  1549
        bfs.addSource(it);
deba@417
  1550
        while (!bfs.emptyQueue()) {
deba@417
  1551
          bfs.processNextNode();
deba@417
  1552
          if (!bipartite) return false;
deba@417
  1553
        }
deba@417
  1554
      }
deba@417
  1555
    }
deba@417
  1556
    return true;
deba@417
  1557
  }
deba@417
  1558
kpeter@586
  1559
  /// \ingroup graph_properties
deba@417
  1560
  ///
kpeter@648
  1561
  /// \brief Find the bipartite partitions of an undirected graph.
deba@417
  1562
  ///
kpeter@648
  1563
  /// This function checks whether the given undirected graph is bipartite
kpeter@648
  1564
  /// and gives back the bipartite partitions.
kpeter@586
  1565
  ///
kpeter@586
  1566
  /// \image html bipartite_partitions.png
kpeter@586
  1567
  /// \image latex bipartite_partitions.eps "Bipartite partititions" width=\textwidth
kpeter@586
  1568
  ///
deba@417
  1569
  /// \param graph The undirected graph.
kpeter@648
  1570
  /// \retval partMap A writable node map of \c bool (or convertible) value
kpeter@648
  1571
  /// type. The values will be set to \c true for one component and
kpeter@648
  1572
  /// \c false for the other one.
kpeter@648
  1573
  /// \return \c true if the graph is bipartite, \c false otherwise.
kpeter@648
  1574
  ///
kpeter@648
  1575
  /// \see bipartite()
deba@417
  1576
  template<typename Graph, typename NodeMap>
kpeter@648
  1577
  bool bipartitePartitions(const Graph &graph, NodeMap &partMap){
deba@419
  1578
    using namespace _connectivity_bits;
deba@417
  1579
deba@417
  1580
    checkConcept<concepts::Graph, Graph>();
kpeter@648
  1581
    checkConcept<concepts::WriteMap<typename Graph::Node, bool>, NodeMap>();
deba@417
  1582
deba@417
  1583
    typedef typename Graph::Node Node;
deba@417
  1584
    typedef typename Graph::NodeIt NodeIt;
deba@417
  1585
    typedef typename Graph::ArcIt ArcIt;
deba@417
  1586
deba@417
  1587
    bool bipartite = true;
deba@417
  1588
deba@417
  1589
    BipartitePartitionsVisitor<Graph, NodeMap>
deba@417
  1590
      visitor(graph, partMap, bipartite);
deba@417
  1591
    BfsVisit<Graph, BipartitePartitionsVisitor<Graph, NodeMap> >
deba@417
  1592
      bfs(graph, visitor);
deba@417
  1593
    bfs.init();
deba@417
  1594
    for(NodeIt it(graph); it != INVALID; ++it) {
deba@417
  1595
      if(!bfs.reached(it)){
deba@417
  1596
        bfs.addSource(it);
deba@417
  1597
        while (!bfs.emptyQueue()) {
deba@417
  1598
          bfs.processNextNode();
deba@417
  1599
          if (!bipartite) return false;
deba@417
  1600
        }
deba@417
  1601
      }
deba@417
  1602
    }
deba@417
  1603
    return true;
deba@417
  1604
  }
deba@417
  1605
kpeter@648
  1606
  /// \ingroup graph_properties
deba@417
  1607
  ///
kpeter@648
  1608
  /// \brief Check whether the given graph contains no loop arcs/edges.
kpeter@648
  1609
  ///
kpeter@648
  1610
  /// This function returns \c true if there are no loop arcs/edges in
kpeter@648
  1611
  /// the given graph. It works for both directed and undirected graphs.
kpeter@648
  1612
  template <typename Graph>
kpeter@648
  1613
  bool loopFree(const Graph& graph) {
kpeter@648
  1614
    for (typename Graph::ArcIt it(graph); it != INVALID; ++it) {
kpeter@648
  1615
      if (graph.source(it) == graph.target(it)) return false;
deba@417
  1616
    }
deba@417
  1617
    return true;
deba@417
  1618
  }
deba@417
  1619
kpeter@648
  1620
  /// \ingroup graph_properties
deba@417
  1621
  ///
kpeter@648
  1622
  /// \brief Check whether the given graph contains no parallel arcs/edges.
kpeter@648
  1623
  ///
kpeter@648
  1624
  /// This function returns \c true if there are no parallel arcs/edges in
kpeter@648
  1625
  /// the given graph. It works for both directed and undirected graphs.
kpeter@647
  1626
  template <typename Graph>
kpeter@647
  1627
  bool parallelFree(const Graph& graph) {
kpeter@647
  1628
    typename Graph::template NodeMap<int> reached(graph, 0);
kpeter@647
  1629
    int cnt = 1;
kpeter@647
  1630
    for (typename Graph::NodeIt n(graph); n != INVALID; ++n) {
kpeter@647
  1631
      for (typename Graph::OutArcIt a(graph, n); a != INVALID; ++a) {
kpeter@647
  1632
        if (reached[graph.target(a)] == cnt) return false;
kpeter@647
  1633
        reached[graph.target(a)] = cnt;
deba@417
  1634
      }
kpeter@647
  1635
      ++cnt;
deba@417
  1636
    }
deba@417
  1637
    return true;
deba@417
  1638
  }
deba@417
  1639
kpeter@648
  1640
  /// \ingroup graph_properties
deba@417
  1641
  ///
kpeter@648
  1642
  /// \brief Check whether the given graph is simple.
kpeter@648
  1643
  ///
kpeter@648
  1644
  /// This function returns \c true if the given graph is simple, i.e.
kpeter@648
  1645
  /// it contains no loop arcs/edges and no parallel arcs/edges.
kpeter@648
  1646
  /// The function works for both directed and undirected graphs.
kpeter@648
  1647
  /// \see loopFree(), parallelFree()
kpeter@647
  1648
  template <typename Graph>
kpeter@647
  1649
  bool simpleGraph(const Graph& graph) {
kpeter@647
  1650
    typename Graph::template NodeMap<int> reached(graph, 0);
kpeter@647
  1651
    int cnt = 1;
kpeter@647
  1652
    for (typename Graph::NodeIt n(graph); n != INVALID; ++n) {
kpeter@647
  1653
      reached[n] = cnt;
kpeter@647
  1654
      for (typename Graph::OutArcIt a(graph, n); a != INVALID; ++a) {
kpeter@647
  1655
        if (reached[graph.target(a)] == cnt) return false;
kpeter@647
  1656
        reached[graph.target(a)] = cnt;
deba@417
  1657
      }
kpeter@647
  1658
      ++cnt;
deba@417
  1659
    }
deba@417
  1660
    return true;
deba@417
  1661
  }
deba@417
  1662
deba@417
  1663
} //namespace lemon
deba@417
  1664
deba@419
  1665
#endif //LEMON_CONNECTIVITY_H