lemon/edmonds_karp.h
author deba
Tue, 30 May 2006 10:33:50 +0000
changeset 2098 12f67fa3df7d
parent 2037 32e4bebee616
child 2113 48ec8161f9e1
permissions -rw-r--r--
Bug fix in the list bipartite undirected graph
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/* -*- C++ -*-
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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) 2003-2006
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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_EDMONDS_KARP_H
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#define LEMON_EDMONDS_KARP_H
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/// \file
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/// \ingroup flowalgs
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/// \brief Implementation of the Edmonds-Karp algorithm.
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#include <lemon/graph_adaptor.h>
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#include <lemon/tolerance.h>
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#include <lemon/bfs.h>
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namespace lemon {
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  /// \ingroup flowalgs
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  /// \brief Edmonds-Karp algorithms class.
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  ///
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  /// This class provides an implementation of the \e Edmonds-Karp \e
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  /// algorithm producing a flow of maximum value in a directed
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  /// graph. The Edmonds-Karp algorithm is slower than the Preflow algorithm
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  /// but it has an advantage of the step-by-step execution control with
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  /// feasible flow solutions. The \e source node, the \e target node, the \e
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  /// capacity of the edges and the \e starting \e flow value of the
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  /// edges should be passed to the algorithm through the
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  /// constructor.
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  ///
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  /// The time complexity of the algorithm is \f$ O(n * e^2) \f$ in
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  /// worst case.  Always try the preflow algorithm instead of this if
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  /// you does not have some additional reason than to compute the
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  /// optimal flow which has \f$ O(n^3) \f$ time complexity.
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  ///
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  /// \param _Graph The directed graph type the algorithm runs on.
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  /// \param _Number The number type of the capacities and the flow values.
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  /// \param _CapacityMap The capacity map type.
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  /// \param _FlowMap The flow map type.
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  /// \param _Tolerance The tolerance class to handle computation problems.
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  ///
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  /// \author Balazs Dezso 
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#ifdef DOXYGEN
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  template <typename _Graph, typename _Number,
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	    typename _CapacityMap, typename _FlowMap, typename _Tolerance>
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#else
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  template <typename _Graph, typename _Number,
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	    typename _CapacityMap = typename _Graph::template EdgeMap<_Number>,
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            typename _FlowMap = typename _Graph::template EdgeMap<_Number>,
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	    typename _Tolerance = Tolerance<_Number> >
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#endif
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  class EdmondsKarp {
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  public:
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    /// \brief \ref Exception for the case when the source equals the target.
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    ///
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    /// \ref Exception for the case when the source equals the target.
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    ///
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    class InvalidArgument : public lemon::LogicError {
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    public:
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      virtual const char* exceptionName() const {
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	return "lemon::EdmondsKarp::InvalidArgument";
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      }
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    };
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    /// \brief The graph type the algorithm runs on. 
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    typedef _Graph Graph;
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    /// \brief The value type of the algorithms.
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    typedef _Number Number;
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    /// \brief The capacity map on the edges.
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    typedef _CapacityMap CapacityMap;
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    /// \brief The flow map on the edges.
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    typedef _FlowMap FlowMap;
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    /// \brief The tolerance used by the algorithm.
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    typedef _Tolerance Tolerance;
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    typedef ResGraphAdaptor<Graph, Number, CapacityMap, 
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                            FlowMap, Tolerance> ResGraph;
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  private:
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    typedef typename Graph::Node Node;
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    typedef typename Graph::Edge Edge;
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    typedef typename Graph::NodeIt NodeIt;
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    typedef typename Graph::EdgeIt EdgeIt;
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    typedef typename Graph::InEdgeIt InEdgeIt;
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    typedef typename Graph::OutEdgeIt OutEdgeIt;
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  public:
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    /// \brief The constructor of the class.
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    ///
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    /// The constructor of the class. 
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    /// \param graph The directed graph the algorithm runs on. 
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    /// \param source The source node.
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    /// \param target The target node.
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    /// \param capacity The capacity of the edges. 
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    /// \param flow The flow of the edges. 
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    /// \param tolerance Tolerance class.
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    EdmondsKarp(const Graph& graph, Node source, Node target,
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                const CapacityMap& capacity, FlowMap& flow, 
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                const Tolerance& tolerance = Tolerance())
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      : _graph(graph), _capacity(capacity), _flow(flow), 
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        _tolerance(tolerance), _resgraph(graph, capacity, flow, tolerance), 
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        _source(source), _target(target) 
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    {
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      if (_source == _target) {
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        throw InvalidArgument();
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      }
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    }
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    /// \brief Initializes the algorithm
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    /// 
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    /// It sets the flow to empty flow.
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    void init() {
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      for (EdgeIt it(_graph); it != INVALID; ++it) {
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        _flow.set(it, 0);
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      }
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      _value = 0;
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    }
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    /// \brief Initializes the algorithm
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    /// 
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    /// If the flow map initially flow this let the flow map
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    /// unchanged but the flow value will be set by the flow
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    /// on the outedges from the source.
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    void flowInit() {
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      _value = 0;
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      for (OutEdgeIt jt(_graph, _source); jt != INVALID; ++jt) {
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        _value += _flow[jt];
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      }
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      for (InEdgeIt jt(_graph, _source); jt != INVALID; ++jt) {
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        _value -= _flow[jt];
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      }
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    }
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    /// \brief Initializes the algorithm
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    /// 
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    /// If the flow map initially flow this let the flow map
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    /// unchanged but the flow value will be set by the flow
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    /// on the outedges from the source. It also checks that
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    /// the flow map really contains a flow.
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    /// \return %True when the flow map really a flow.
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    bool checkedFlowInit() {
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      _value = 0;
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      for (OutEdgeIt jt(_graph, _source); jt != INVALID; ++jt) {
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        _value += _flow[jt];
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      }
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      for (InEdgeIt jt(_graph, _source); jt != INVALID; ++jt) {
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        _value -= _flow[jt];
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      }
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      for (NodeIt it(_graph); it != INVALID; ++it) {
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        if (it == _source || it == _target) continue;
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        Number outFlow = 0;
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        for (OutEdgeIt jt(_graph, it); jt != INVALID; ++jt) {
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          outFlow += _flow[jt];
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        }
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        Number inFlow = 0;
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        for (InEdgeIt jt(_graph, it); jt != INVALID; ++jt) {
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          inFlow += _flow[jt];
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        }
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        if (_tolerance.different(outFlow, inFlow)) {
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          return false;
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        }
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      }
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      for (EdgeIt it(_graph); it != INVALID; ++it) {
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        if (_tolerance.less(_flow[it], 0)) return false;
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        if (_tolerance.less(_capacity[it], _flow[it])) return false;
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      }
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      return true;
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    }
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    /// \brief Augment the solution on an edge shortest path.
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    /// 
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    /// Augment the solution on an edge shortest path. It search an
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    /// edge shortest path between the source and the target
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    /// in the residual graph with the bfs algoritm.
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    /// Then it increase the flow on this path with the minimal residual
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    /// capacity on the path. If there is not such path it gives back
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    /// false.
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    /// \return %False when the augmenting is not success so the
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    /// current flow is a feasible and optimal solution.
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    bool augment() {
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      typename Bfs<ResGraph>
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      ::template DefDistMap<NullMap<Node, int> >
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      ::Create bfs(_resgraph);
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      NullMap<Node, int> distMap;
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      bfs.distMap(distMap);
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      bfs.init();
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      bfs.addSource(_source);
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      bfs.start(_target);
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      if (!bfs.reached(_target)) {
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        return false;
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      }
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      Number min = _resgraph.rescap(bfs.predEdge(_target));
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      for (Node it = bfs.predNode(_target); it != _source; 
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           it = bfs.predNode(it)) {
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        if (min > _resgraph.rescap(bfs.predEdge(it))) {
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          min = _resgraph.rescap(bfs.predEdge(it));
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        }
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      } 
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      for (Node it = _target; it != _source; it = bfs.predNode(it)) {
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        _resgraph.augment(bfs.predEdge(it), min);
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      }
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      _value += min;
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      return true;
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    }
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    /// \brief Executes the algorithm
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    ///
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    /// It runs augmenting phases until the optimal solution is reached. 
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    void start() {
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      while (augment()) {}
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    }
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    /// \brief Gives back the current flow value.
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    ///
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    /// Gives back the current flow _value.
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    Number flowValue() const {
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      return _value;
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    }
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    /// \brief runs the algorithm.
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    /// 
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    /// It is just a shorthand for:
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    ///
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    ///\code 
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    /// ek.init();
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    /// ek.start();
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    ///\endcode
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    void run() {
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      init();
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      start();
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    }
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    /// \brief Returns a minimum value cut.
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    ///
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    /// Sets \c cut to the characteristic vector of a minimum value cut
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    /// It simply calls the minMinCut member.
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    /// \retval cut Write node bool map. 
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    template <typename CutMap>
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    void minCut(CutMap& cut) const {
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      minMinCut(cut);
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    }
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    /// \brief Returns the inclusionwise minimum of the minimum value cuts.
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    ///
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    /// Sets \c cut to the characteristic vector of the minimum value cut
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    /// which is inclusionwise minimum. It is computed by processing a
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    /// bfs from the source node \c source in the residual graph.  
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    /// \retval cut Write node bool map. 
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    template <typename CutMap>
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    void minMinCut(CutMap& cut) const {
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      typename Bfs<ResGraph>
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      ::template DefDistMap<NullMap<Node, int> >
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      ::template DefProcessedMap<CutMap>
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      ::Create bfs(_resgraph);
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      NullMap<Node, int> distMap;
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      bfs.distMap(distMap);
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      bfs.processedMap(cut);
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      bfs.run(_source);
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    }
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    /// \brief Returns the inclusionwise minimum of the minimum value cuts.
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    ///
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    /// Sets \c cut to the characteristic vector of the minimum value cut
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    /// which is inclusionwise minimum. It is computed by processing a
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    /// bfs from the source node \c source in the residual graph.  
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    /// \retval cut Write node bool map. 
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    template <typename CutMap>
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    void maxMinCut(CutMap& cut) const {
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      typedef RevGraphAdaptor<const ResGraph> RevGraph;
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      RevGraph revgraph(_resgraph);
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      typename Bfs<RevGraph>
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      ::template DefDistMap<NullMap<Node, int> >
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      ::template DefPredMap<NullMap<Node, Edge> >
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      ::template DefProcessedMap<NotWriteMap<CutMap> >
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      ::Create bfs(revgraph);
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      NullMap<Node, int> distMap;
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      bfs.distMap(distMap);
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      NullMap<Node, Edge> predMap;
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      bfs.predMap(predMap);
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      NotWriteMap<CutMap> notcut(cut);
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      bfs.processedMap(notcut);
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      bfs.run(_target);
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    }
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    /// \brief Returns the source node.
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    ///
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    /// Returns the source node.
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    /// 
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    Node source() const { 
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      return _source;
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    }
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    /// \brief Returns the target node.
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    ///
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    /// Returns the target node.
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    /// 
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    Node target() const { 
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      return _target;
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    }
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    /// \brief Returns a reference to capacity map.
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    ///
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    /// Returns a reference to capacity map.
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    /// 
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    const CapacityMap &capacityMap() const { 
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      return *_capacity;
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    }
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    /// \brief Returns a reference to flow map.
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    ///
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    /// Returns a reference to flow map.
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    /// 
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    const FlowMap &flowMap() const { 
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      return *_flow;
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    }
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    /// \brief Returns the tolerance used by algorithm.
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    ///
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    /// Returns the tolerance used by algorithm.
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    const Tolerance& tolerance() const {
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      return tolerance;
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    } 
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  private:
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    const Graph& _graph;
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    const CapacityMap& _capacity;
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    FlowMap& _flow;
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    Tolerance _tolerance;
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    ResGraph _resgraph;
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    Node _source, _target;
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    Number _value;
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  };
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}
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#endif