lemon/graph_adaptor.h
author athos
Fri, 24 Jun 2005 08:44:54 +0000
changeset 1511 d6b95a59da26
parent 1435 8e85e6bbefdf
child 1536 308150155bb5
permissions -rw-r--r--
Half-done, but I want to continue from home.
     1 /* -*- C++ -*-
     2  * lemon/graph_adaptor.h - Part of LEMON, a generic C++ optimization library
     3  *
     4  * Copyright (C) 2005 Egervary Jeno Kombinatorikus Optimalizalasi Kutatocsoport
     5  * (Egervary Research Group on Combinatorial Optimization, EGRES).
     6  *
     7  * Permission to use, modify and distribute this software is granted
     8  * provided that this copyright notice appears in all copies. For
     9  * precise terms see the accompanying LICENSE file.
    10  *
    11  * This software is provided "AS IS" with no warranty of any kind,
    12  * express or implied, and with no claim as to its suitability for any
    13  * purpose.
    14  *
    15  */
    16 
    17 #ifndef LEMON_GRAPH_ADAPTOR_H
    18 #define LEMON_GRAPH_ADAPTOR_H
    19 
    20 ///\ingroup graph_adaptors
    21 ///\file
    22 ///\brief Several graph adaptors.
    23 ///
    24 ///This file contains several useful graph adaptor functions.
    25 ///
    26 ///\author Marton Makai
    27 
    28 #include <lemon/invalid.h>
    29 #include <lemon/maps.h>
    30 #include <lemon/bits/erasable_graph_extender.h>
    31 #include <lemon/bits/clearable_graph_extender.h>
    32 #include <lemon/bits/extendable_graph_extender.h>
    33 #include <lemon/bits/iterable_graph_extender.h>
    34 #include <lemon/bits/alteration_notifier.h>
    35 #include <lemon/bits/default_map.h>
    36 #include <lemon/bits/undir_graph_extender.h>
    37 #include <iostream>
    38 
    39 namespace lemon {
    40 
    41   // Graph adaptors
    42 
    43   /*!
    44     \addtogroup graph_adaptors
    45     @{
    46    */
    47 
    48   /*! 
    49     Base type for the Graph Adaptors
    50     
    51     \warning Graph adaptors are in even more experimental state than the other
    52     parts of the lib. Use them at you own risk.
    53     
    54     This is the base type for most of LEMON graph adaptors. 
    55     This class implements a trivial graph adaptor i.e. it only wraps the 
    56     functions and types of the graph. The purpose of this class is to 
    57     make easier implementing graph adaptors. E.g. if an adaptor is 
    58     considered which differs from the wrapped graph only in some of its 
    59     functions or types, then it can be derived from GraphAdaptor, and only the 
    60     differences should be implemented.
    61   
    62     \author Marton Makai 
    63   */
    64   template<typename _Graph>
    65   class GraphAdaptorBase {
    66   public:
    67     typedef _Graph Graph;
    68     /// \todo Is it needed?
    69     typedef Graph BaseGraph;
    70     typedef Graph ParentGraph;
    71 
    72   protected:
    73     Graph* graph;
    74     GraphAdaptorBase() : graph(0) { }
    75     void setGraph(Graph& _graph) { graph=&_graph; }
    76 
    77   public:
    78     GraphAdaptorBase(Graph& _graph) : graph(&_graph) { }
    79  
    80     typedef typename Graph::Node Node;
    81     typedef typename Graph::Edge Edge;
    82    
    83     void first(Node& i) const { graph->first(i); }
    84     void first(Edge& i) const { graph->first(i); }
    85     void firstIn(Edge& i, const Node& n) const { graph->firstIn(i, n); }
    86     void firstOut(Edge& i, const Node& n ) const { graph->firstOut(i, n); }
    87 
    88     void next(Node& i) const { graph->next(i); }
    89     void next(Edge& i) const { graph->next(i); }
    90     void nextIn(Edge& i) const { graph->nextIn(i); }
    91     void nextOut(Edge& i) const { graph->nextOut(i); }
    92 
    93     Node source(const Edge& e) const { return graph->source(e); }
    94     Node target(const Edge& e) const { return graph->target(e); }
    95 
    96     int nodeNum() const { return graph->nodeNum(); }
    97     int edgeNum() const { return graph->edgeNum(); }
    98   
    99     Node addNode() const { return Node(graph->addNode()); }
   100     Edge addEdge(const Node& source, const Node& target) const { 
   101       return Edge(graph->addEdge(source, target)); }
   102 
   103     void erase(const Node& i) const { graph->erase(i); }
   104     void erase(const Edge& i) const { graph->erase(i); }
   105   
   106     void clear() const { graph->clear(); }
   107     
   108     bool forward(const Edge& e) const { return graph->forward(e); }
   109     bool backward(const Edge& e) const { return graph->backward(e); }
   110 
   111     int id(const Node& v) const { return graph->id(v); }
   112     int id(const Edge& e) const { return graph->id(e); }
   113     
   114     Edge opposite(const Edge& e) const { return Edge(graph->opposite(e)); }
   115 
   116     template <typename _Value>
   117     class NodeMap : public _Graph::template NodeMap<_Value> {
   118     public:
   119       typedef typename _Graph::template NodeMap<_Value> Parent;
   120       NodeMap(const GraphAdaptorBase<_Graph>& gw) : Parent(*gw.graph) { }
   121       NodeMap(const GraphAdaptorBase<_Graph>& gw, const _Value& value)
   122       : Parent(*gw.graph, value) { }
   123     };
   124 
   125     template <typename _Value>
   126     class EdgeMap : public _Graph::template EdgeMap<_Value> {
   127     public:
   128       typedef typename _Graph::template EdgeMap<_Value> Parent;
   129       EdgeMap(const GraphAdaptorBase<_Graph>& gw) : Parent(*gw.graph) { }
   130       EdgeMap(const GraphAdaptorBase<_Graph>& gw, const _Value& value)
   131       : Parent(*gw.graph, value) { }
   132     };
   133 
   134   };
   135 
   136   template <typename _Graph>
   137   class GraphAdaptor :
   138     public IterableGraphExtender<GraphAdaptorBase<_Graph> > { 
   139   public:
   140     typedef _Graph Graph;
   141     typedef IterableGraphExtender<GraphAdaptorBase<_Graph> > Parent;
   142   protected:
   143     GraphAdaptor() : Parent() { }
   144 
   145   public:
   146     GraphAdaptor(Graph& _graph) { setGraph(_graph); }
   147   };
   148 
   149   template <typename _Graph>
   150   class RevGraphAdaptorBase : public GraphAdaptorBase<_Graph> {
   151   public:
   152     typedef _Graph Graph;
   153     typedef GraphAdaptorBase<_Graph> Parent;
   154   protected:
   155     RevGraphAdaptorBase() : Parent() { }
   156   public:
   157     typedef typename Parent::Node Node;
   158     typedef typename Parent::Edge Edge;
   159 
   160     //    using Parent::first;
   161     void firstIn(Edge& i, const Node& n) const { Parent::firstOut(i, n); }
   162     void firstOut(Edge& i, const Node& n ) const { Parent::firstIn(i, n); }
   163 
   164     //    using Parent::next;
   165     void nextIn(Edge& i) const { Parent::nextOut(i); }
   166     void nextOut(Edge& i) const { Parent::nextIn(i); }
   167 
   168     Node source(const Edge& e) const { return Parent::target(e); }
   169     Node target(const Edge& e) const { return Parent::source(e); }
   170   };
   171     
   172 
   173   /// A graph adaptor which reverses the orientation of the edges.
   174 
   175   ///\warning Graph adaptors are in even more experimental state than the other
   176   ///parts of the lib. Use them at you own risk.
   177   ///
   178   /// Let \f$G=(V, A)\f$ be a directed graph and 
   179   /// suppose that a graph instange \c g of type 
   180   /// \c ListGraph implements \f$G\f$.
   181   /// \code
   182   /// ListGraph g;
   183   /// \endcode
   184   /// For each directed edge 
   185   /// \f$e\in A\f$, let \f$\bar e\f$ denote the edge obtained by 
   186   /// reversing its orientation. 
   187   /// Then RevGraphAdaptor implements the graph structure with node-set 
   188   /// \f$V\f$ and edge-set 
   189   /// \f$\{\bar e : e\in A \}\f$, i.e. the graph obtained from \f$G\f$ be 
   190   /// reversing the orientation of its edges. The following code shows how 
   191   /// such an instance can be constructed.
   192   /// \code
   193   /// RevGraphAdaptor<ListGraph> gw(g);
   194   /// \endcode
   195   ///\author Marton Makai
   196   template<typename _Graph>
   197   class RevGraphAdaptor : 
   198     public IterableGraphExtender<RevGraphAdaptorBase<_Graph> > {
   199   public:
   200     typedef _Graph Graph;
   201     typedef IterableGraphExtender<
   202       RevGraphAdaptorBase<_Graph> > Parent;
   203   protected:
   204     RevGraphAdaptor() { }
   205   public:
   206     RevGraphAdaptor(_Graph& _graph) { setGraph(_graph); }
   207   };
   208 
   209   
   210   template <typename _Graph, typename NodeFilterMap, typename EdgeFilterMap>
   211   class SubGraphAdaptorBase : public GraphAdaptorBase<_Graph> {
   212   public:
   213     typedef _Graph Graph;
   214     typedef GraphAdaptorBase<_Graph> Parent;
   215   protected:
   216     NodeFilterMap* node_filter_map;
   217     EdgeFilterMap* edge_filter_map;
   218     SubGraphAdaptorBase() : Parent(), 
   219 			    node_filter_map(0), edge_filter_map(0) { }
   220 
   221     void setNodeFilterMap(NodeFilterMap& _node_filter_map) {
   222       node_filter_map=&_node_filter_map;
   223     }
   224     void setEdgeFilterMap(EdgeFilterMap& _edge_filter_map) {
   225       edge_filter_map=&_edge_filter_map;
   226     }
   227 
   228   public:
   229 //     SubGraphAdaptorBase(Graph& _graph, 
   230 // 			NodeFilterMap& _node_filter_map, 
   231 // 			EdgeFilterMap& _edge_filter_map) : 
   232 //       Parent(&_graph), 
   233 //       node_filter_map(&node_filter_map), 
   234 //       edge_filter_map(&edge_filter_map) { }
   235 
   236     typedef typename Parent::Node Node;
   237     typedef typename Parent::Edge Edge;
   238 
   239     void first(Node& i) const { 
   240       Parent::first(i); 
   241       while (i!=INVALID && !(*node_filter_map)[i]) Parent::next(i); 
   242     }
   243     void first(Edge& i) const { 
   244       Parent::first(i); 
   245       while (i!=INVALID && !(*edge_filter_map)[i]) Parent::next(i); 
   246     }
   247     void firstIn(Edge& i, const Node& n) const { 
   248       Parent::firstIn(i, n); 
   249       while (i!=INVALID && !(*edge_filter_map)[i]) Parent::nextIn(i); 
   250     }
   251     void firstOut(Edge& i, const Node& n) const { 
   252       Parent::firstOut(i, n); 
   253       while (i!=INVALID && !(*edge_filter_map)[i]) Parent::nextOut(i); 
   254     }
   255 
   256     void next(Node& i) const { 
   257       Parent::next(i); 
   258       while (i!=INVALID && !(*node_filter_map)[i]) Parent::next(i); 
   259     }
   260     void next(Edge& i) const { 
   261       Parent::next(i); 
   262       while (i!=INVALID && !(*edge_filter_map)[i]) Parent::next(i); 
   263     }
   264     void nextIn(Edge& i) const { 
   265       Parent::nextIn(i); 
   266       while (i!=INVALID && !(*edge_filter_map)[i]) Parent::nextIn(i); 
   267     }
   268     void nextOut(Edge& i) const { 
   269       Parent::nextOut(i); 
   270       while (i!=INVALID && !(*edge_filter_map)[i]) Parent::nextOut(i); 
   271     }
   272 
   273     /// This function hides \c n in the graph, i.e. the iteration 
   274     /// jumps over it. This is done by simply setting the value of \c n  
   275     /// to be false in the corresponding node-map.
   276     void hide(const Node& n) const { node_filter_map->set(n, false); }
   277 
   278     /// This function hides \c e in the graph, i.e. the iteration 
   279     /// jumps over it. This is done by simply setting the value of \c e  
   280     /// to be false in the corresponding edge-map.
   281     void hide(const Edge& e) const { edge_filter_map->set(e, false); }
   282 
   283     /// The value of \c n is set to be true in the node-map which stores 
   284     /// hide information. If \c n was hidden previuosly, then it is shown 
   285     /// again
   286      void unHide(const Node& n) const { node_filter_map->set(n, true); }
   287 
   288     /// The value of \c e is set to be true in the edge-map which stores 
   289     /// hide information. If \c e was hidden previuosly, then it is shown 
   290     /// again
   291     void unHide(const Edge& e) const { edge_filter_map->set(e, true); }
   292 
   293     /// Returns true if \c n is hidden.
   294     bool hidden(const Node& n) const { return !(*node_filter_map)[n]; }
   295 
   296     /// Returns true if \c n is hidden.
   297     bool hidden(const Edge& e) const { return !(*edge_filter_map)[e]; }
   298 
   299     /// \warning This is a linear time operation and works only if s
   300     /// \c Graph::NodeIt is defined.
   301     /// \todo assign tags.
   302     int nodeNum() const { 
   303       int i=0;
   304       Node n;
   305       for (first(n); n!=INVALID; next(n)) ++i;
   306       return i; 
   307     }
   308 
   309     /// \warning This is a linear time operation and works only if 
   310     /// \c Graph::EdgeIt is defined.
   311     /// \todo assign tags.
   312     int edgeNum() const { 
   313       int i=0;
   314       Edge e;
   315       for (first(e); e!=INVALID; next(e)) ++i;
   316       return i; 
   317     }
   318 
   319 
   320   };
   321 
   322   /*! \brief A graph adaptor for hiding nodes and edges from a graph.
   323     
   324   \warning Graph adaptors are in even more experimental state than the other
   325   parts of the lib. Use them at you own risk.
   326   
   327   SubGraphAdaptor shows the graph with filtered node-set and 
   328   edge-set. 
   329   Let \f$G=(V, A)\f$ be a directed graph 
   330   and suppose that the graph instance \c g of type ListGraph implements 
   331   \f$G\f$. 
   332   Let moreover \f$b_V\f$ and 
   333   \f$b_A\f$ be bool-valued functions resp. on the node-set and edge-set. 
   334   SubGraphAdaptor<...>::NodeIt iterates 
   335   on the node-set \f$\{v\in V : b_V(v)=true\}\f$ and 
   336   SubGraphAdaptor<...>::EdgeIt iterates 
   337   on the edge-set \f$\{e\in A : b_A(e)=true\}\f$. Similarly, 
   338   SubGraphAdaptor<...>::OutEdgeIt and SubGraphAdaptor<...>::InEdgeIt iterates 
   339   only on edges leaving and entering a specific node which have true value.
   340 
   341   We have to note that this does not mean that an 
   342   induced subgraph is obtained, the node-iterator cares only the filter 
   343   on the node-set, and the edge-iterators care only the filter on the 
   344   edge-set. 
   345   \code
   346   typedef ListGraph Graph;
   347   Graph g;
   348   typedef Graph::Node Node;
   349   typedef Graph::Edge Edge;
   350   Node u=g.addNode(); //node of id 0
   351   Node v=g.addNode(); //node of id 1
   352   Node e=g.addEdge(u, v); //edge of id 0
   353   Node f=g.addEdge(v, u); //edge of id 1
   354   Graph::NodeMap<bool> nm(g, true);
   355   nm.set(u, false);
   356   Graph::EdgeMap<bool> em(g, true);
   357   em.set(e, false);
   358   typedef SubGraphAdaptor<Graph, Graph::NodeMap<bool>, Graph::EdgeMap<bool> > SubGW;
   359   SubGW gw(g, nm, em);
   360   for (SubGW::NodeIt n(gw); n!=INVALID; ++n) std::cout << g.id(n) << std::endl;
   361   std::cout << ":-)" << std::endl;
   362   for (SubGW::EdgeIt e(gw); e!=INVALID; ++e) std::cout << g.id(e) << std::endl;
   363   \endcode
   364   The output of the above code is the following.
   365   \code
   366   1
   367   :-)
   368   1
   369   \endcode
   370   Note that \c n is of type \c SubGW::NodeIt, but it can be converted to
   371   \c Graph::Node that is why \c g.id(n) can be applied.
   372 
   373   For other examples see also the documentation of NodeSubGraphAdaptor and 
   374   EdgeSubGraphAdaptor.
   375 
   376   \author Marton Makai
   377   */
   378   template<typename _Graph, typename NodeFilterMap, 
   379 	   typename EdgeFilterMap>
   380   class SubGraphAdaptor : 
   381     public IterableGraphExtender<
   382     SubGraphAdaptorBase<_Graph, NodeFilterMap, EdgeFilterMap> > {
   383   public:
   384     typedef _Graph Graph;
   385     typedef IterableGraphExtender<
   386       SubGraphAdaptorBase<_Graph, NodeFilterMap, EdgeFilterMap> > Parent;
   387   protected:
   388     SubGraphAdaptor() { }
   389   public:
   390     SubGraphAdaptor(_Graph& _graph, NodeFilterMap& _node_filter_map, 
   391 		    EdgeFilterMap& _edge_filter_map) { 
   392       setGraph(_graph);
   393       setNodeFilterMap(_node_filter_map);
   394       setEdgeFilterMap(_edge_filter_map);
   395     }
   396   };
   397 
   398 
   399 
   400   /*! \brief An adaptor for hiding nodes from a graph.
   401 
   402   \warning Graph adaptors are in even more experimental state than the other
   403   parts of the lib. Use them at you own risk.
   404   
   405   An adaptor for hiding nodes from a graph.
   406   This adaptor specializes SubGraphAdaptor in the way that only the node-set 
   407   can be filtered. Note that this does not mean of considering induced 
   408   subgraph, the edge-iterators consider the original edge-set.
   409   \author Marton Makai
   410   */
   411   template<typename Graph, typename NodeFilterMap>
   412   class NodeSubGraphAdaptor : 
   413     public SubGraphAdaptor<Graph, NodeFilterMap, 
   414 			   ConstMap<typename Graph::Edge,bool> > {
   415   public:
   416     typedef SubGraphAdaptor<Graph, NodeFilterMap, 
   417 			    ConstMap<typename Graph::Edge,bool> > Parent;
   418   protected:
   419     ConstMap<typename Graph::Edge, bool> const_true_map;
   420   public:
   421     NodeSubGraphAdaptor(Graph& _graph, NodeFilterMap& _node_filter_map) : 
   422       Parent(), const_true_map(true) { 
   423       Parent::setGraph(_graph);
   424       Parent::setNodeFilterMap(_node_filter_map);
   425       Parent::setEdgeFilterMap(const_true_map);
   426     }
   427   };
   428 
   429 
   430   /*! \brief An adaptor for hiding edges from a graph.
   431 
   432   \warning Graph adaptors are in even more experimental state than the other
   433   parts of the lib. Use them at you own risk.
   434   
   435   An adaptor for hiding edges from a graph.
   436   This adaptor specializes SubGraphAdaptor in the way that only the edge-set 
   437   can be filtered. The usefulness of this adaptor is demonstrated in the 
   438   problem of searching a maximum number of edge-disjoint shortest paths 
   439   between 
   440   two nodes \c s and \c t. Shortest here means being shortest w.r.t. 
   441   non-negative edge-lengths. Note that 
   442   the comprehension of the presented solution 
   443   need's some elementary knowledge from combinatorial optimization. 
   444 
   445   If a single shortest path is to be 
   446   searched between \c s and \c t, then this can be done easily by 
   447   applying the Dijkstra algorithm. What happens, if a maximum number of 
   448   edge-disjoint shortest paths is to be computed. It can be proved that an 
   449   edge can be in a shortest path if and only if it is tight with respect to 
   450   the potential function computed by Dijkstra. Moreover, any path containing 
   451   only such edges is a shortest one. Thus we have to compute a maximum number 
   452   of edge-disjoint paths between \c s and \c t in the graph which has edge-set 
   453   all the tight edges. The computation will be demonstrated on the following 
   454   graph, which is read from the dimacs file \ref sub_graph_adaptor_demo.dim. 
   455   The full source code is available in \ref sub_graph_adaptor_demo.cc. 
   456   If you are interested in more demo programs, you can use 
   457   \ref dim_to_dot.cc to generate .dot files from dimacs files. 
   458   The .dot file of the following figure of was generated generated by  
   459   the demo program \ref dim_to_dot.cc.
   460 
   461   \dot
   462   digraph lemon_dot_example {
   463   node [ shape=ellipse, fontname=Helvetica, fontsize=10 ];
   464   n0 [ label="0 (s)" ];
   465   n1 [ label="1" ];
   466   n2 [ label="2" ];
   467   n3 [ label="3" ];
   468   n4 [ label="4" ];
   469   n5 [ label="5" ];
   470   n6 [ label="6 (t)" ];
   471   edge [ shape=ellipse, fontname=Helvetica, fontsize=10 ];
   472   n5 ->  n6 [ label="9, length:4" ];
   473   n4 ->  n6 [ label="8, length:2" ];
   474   n3 ->  n5 [ label="7, length:1" ];
   475   n2 ->  n5 [ label="6, length:3" ];
   476   n2 ->  n6 [ label="5, length:5" ];
   477   n2 ->  n4 [ label="4, length:2" ];
   478   n1 ->  n4 [ label="3, length:3" ];
   479   n0 ->  n3 [ label="2, length:1" ];
   480   n0 ->  n2 [ label="1, length:2" ];
   481   n0 ->  n1 [ label="0, length:3" ];
   482   }
   483   \enddot
   484 
   485   \code
   486   Graph g;
   487   Node s, t;
   488   LengthMap length(g);
   489 
   490   readDimacs(std::cin, g, length, s, t);
   491 
   492   cout << "edges with lengths (of form id, source--length->target): " << endl;
   493   for(EdgeIt e(g); e!=INVALID; ++e) 
   494     cout << g.id(e) << ", " << g.id(g.source(e)) << "--" 
   495          << length[e] << "->" << g.id(g.target(e)) << endl;
   496 
   497   cout << "s: " << g.id(s) << " t: " << g.id(t) << endl;
   498   \endcode
   499   Next, the potential function is computed with Dijkstra.
   500   \code
   501   typedef Dijkstra<Graph, LengthMap> Dijkstra;
   502   Dijkstra dijkstra(g, length);
   503   dijkstra.run(s);
   504   \endcode
   505   Next, we consrtruct a map which filters the edge-set to the tight edges.
   506   \code
   507   typedef TightEdgeFilterMap<Graph, const Dijkstra::DistMap, LengthMap> 
   508     TightEdgeFilter;
   509   TightEdgeFilter tight_edge_filter(g, dijkstra.distMap(), length);
   510   
   511   typedef EdgeSubGraphAdaptor<Graph, TightEdgeFilter> SubGW;
   512   SubGW gw(g, tight_edge_filter);
   513   \endcode
   514   Then, the maximum nimber of edge-disjoint \c s-\c t paths are computed 
   515   with a max flow algorithm Preflow.
   516   \code
   517   ConstMap<Edge, int> const_1_map(1);
   518   Graph::EdgeMap<int> flow(g, 0);
   519 
   520   Preflow<SubGW, int, ConstMap<Edge, int>, Graph::EdgeMap<int> > 
   521     preflow(gw, s, t, const_1_map, flow);
   522   preflow.run();
   523   \endcode
   524   Last, the output is:
   525   \code  
   526   cout << "maximum number of edge-disjoint shortest path: " 
   527        << preflow.flowValue() << endl;
   528   cout << "edges of the maximum number of edge-disjoint shortest s-t paths: " 
   529        << endl;
   530   for(EdgeIt e(g); e!=INVALID; ++e) 
   531     if (flow[e])
   532       cout << " " << g.id(g.source(e)) << "--" 
   533 	   << length[e] << "->" << g.id(g.target(e)) << endl;
   534   \endcode
   535   The program has the following (expected :-)) output:
   536   \code
   537   edges with lengths (of form id, source--length->target):
   538    9, 5--4->6
   539    8, 4--2->6
   540    7, 3--1->5
   541    6, 2--3->5
   542    5, 2--5->6
   543    4, 2--2->4
   544    3, 1--3->4
   545    2, 0--1->3
   546    1, 0--2->2
   547    0, 0--3->1
   548   s: 0 t: 6
   549   maximum number of edge-disjoint shortest path: 2
   550   edges of the maximum number of edge-disjoint shortest s-t paths:
   551    9, 5--4->6
   552    8, 4--2->6
   553    7, 3--1->5
   554    4, 2--2->4
   555    2, 0--1->3
   556    1, 0--2->2
   557   \endcode
   558 
   559   \author Marton Makai
   560   */
   561   template<typename Graph, typename EdgeFilterMap>
   562   class EdgeSubGraphAdaptor : 
   563     public SubGraphAdaptor<Graph, ConstMap<typename Graph::Node,bool>, 
   564 			   EdgeFilterMap> {
   565   public:
   566     typedef SubGraphAdaptor<Graph, ConstMap<typename Graph::Node,bool>, 
   567 			    EdgeFilterMap> Parent;
   568   protected:
   569     ConstMap<typename Graph::Node, bool> const_true_map;
   570   public:
   571     EdgeSubGraphAdaptor(Graph& _graph, EdgeFilterMap& _edge_filter_map) : 
   572       Parent(), const_true_map(true) { 
   573       Parent::setGraph(_graph);
   574       Parent::setNodeFilterMap(const_true_map);
   575       Parent::setEdgeFilterMap(_edge_filter_map);
   576     }
   577   };
   578 
   579   template <typename _Graph>
   580   class UndirGraphAdaptorBase : 
   581     public UndirGraphExtender<GraphAdaptorBase<_Graph> > {
   582   public:
   583     typedef _Graph Graph;
   584     typedef UndirGraphExtender<GraphAdaptorBase<_Graph> > Parent;
   585   protected:
   586     UndirGraphAdaptorBase() : Parent() { }
   587   public:
   588     typedef typename Parent::UndirEdge UndirEdge;
   589     typedef typename Parent::Edge Edge;
   590     
   591     /// \bug Why cant an edge say that it is forward or not??? 
   592     /// By this, a pointer to the graph have to be stored
   593     /// The implementation
   594     template <typename T>
   595     class EdgeMap {
   596     protected:
   597       const UndirGraphAdaptorBase<_Graph>* g;
   598       template <typename TT> friend class EdgeMap;
   599       typename _Graph::template EdgeMap<T> forward_map, backward_map; 
   600     public:
   601       typedef T Value;
   602       typedef Edge Key;
   603       
   604       EdgeMap(const UndirGraphAdaptorBase<_Graph>& _g) : g(&_g), 
   605 	forward_map(*(g->graph)), backward_map(*(g->graph)) { }
   606 
   607       EdgeMap(const UndirGraphAdaptorBase<_Graph>& _g, T a) : g(&_g), 
   608 	forward_map(*(g->graph), a), backward_map(*(g->graph), a) { }
   609       
   610       void set(Edge e, T a) { 
   611 	if (g->forward(e)) 
   612 	  forward_map.set(e, a); 
   613 	else 
   614 	  backward_map.set(e, a); 
   615       }
   616 
   617       T operator[](Edge e) const { 
   618 	if (g->forward(e)) 
   619 	  return forward_map[e]; 
   620 	else 
   621 	  return backward_map[e]; 
   622       }
   623     };
   624         
   625     template <typename T>
   626     class UndirEdgeMap {
   627       template <typename TT> friend class UndirEdgeMap;
   628       typename _Graph::template EdgeMap<T> map; 
   629     public:
   630       typedef T Value;
   631       typedef UndirEdge Key;
   632       
   633       UndirEdgeMap(const UndirGraphAdaptorBase<_Graph>& g) : 
   634 	map(*(g.graph)) { }
   635 
   636       UndirEdgeMap(const UndirGraphAdaptorBase<_Graph>& g, T a) : 
   637 	map(*(g.graph), a) { }
   638       
   639       void set(UndirEdge e, T a) { 
   640 	map.set(e, a); 
   641       }
   642 
   643       T operator[](UndirEdge e) const { 
   644 	return map[e]; 
   645       }
   646     };
   647       
   648   };
   649 
   650   /// \brief An undirected graph is made from a directed graph by an adaptor
   651   ///
   652   /// Undocumented, untested!!!
   653   /// If somebody knows nice demo application, let's polulate it.
   654   /// 
   655   /// \author Marton Makai
   656   template<typename _Graph>
   657   class UndirGraphAdaptor : 
   658     public IterableUndirGraphExtender<
   659     UndirGraphAdaptorBase<_Graph> > {
   660   public:
   661     typedef _Graph Graph;
   662     typedef IterableUndirGraphExtender<
   663       UndirGraphAdaptorBase<_Graph> > Parent;
   664   protected:
   665     UndirGraphAdaptor() { }
   666   public:
   667     UndirGraphAdaptor(_Graph& _graph) { 
   668       setGraph(_graph);
   669     }
   670   };
   671 
   672   
   673   template <typename _Graph, 
   674 	    typename ForwardFilterMap, typename BackwardFilterMap>
   675   class SubBidirGraphAdaptorBase : public GraphAdaptorBase<_Graph> {
   676   public:
   677     typedef _Graph Graph;
   678     typedef GraphAdaptorBase<_Graph> Parent;
   679   protected:
   680     ForwardFilterMap* forward_filter;
   681     BackwardFilterMap* backward_filter;
   682     SubBidirGraphAdaptorBase() : Parent(), 
   683 				 forward_filter(0), backward_filter(0) { }
   684 
   685     void setForwardFilterMap(ForwardFilterMap& _forward_filter) {
   686       forward_filter=&_forward_filter;
   687     }
   688     void setBackwardFilterMap(BackwardFilterMap& _backward_filter) {
   689       backward_filter=&_backward_filter;
   690     }
   691 
   692   public:
   693 //     SubGraphAdaptorBase(Graph& _graph, 
   694 // 			NodeFilterMap& _node_filter_map, 
   695 // 			EdgeFilterMap& _edge_filter_map) : 
   696 //       Parent(&_graph), 
   697 //       node_filter_map(&node_filter_map), 
   698 //       edge_filter_map(&edge_filter_map) { }
   699 
   700     typedef typename Parent::Node Node;
   701     typedef typename _Graph::Edge GraphEdge;
   702     template <typename T> class EdgeMap;
   703     /// SubBidirGraphAdaptorBase<..., ..., ...>::Edge is inherited from 
   704     /// _Graph::Edge. It contains an extra bool flag which is true 
   705     /// if and only if the 
   706     /// edge is the backward version of the original edge.
   707     class Edge : public _Graph::Edge {
   708       friend class SubBidirGraphAdaptorBase<
   709 	Graph, ForwardFilterMap, BackwardFilterMap>;
   710       template<typename T> friend class EdgeMap;
   711     protected:
   712       bool backward; //true, iff backward
   713     public:
   714       Edge() { }
   715       /// \todo =false is needed, or causes problems?
   716       /// If \c _backward is false, then we get an edge corresponding to the 
   717       /// original one, otherwise its oppositely directed pair is obtained.
   718       Edge(const typename _Graph::Edge& e, bool _backward/*=false*/) : 
   719 	_Graph::Edge(e), backward(_backward) { }
   720       Edge(Invalid i) : _Graph::Edge(i), backward(true) { }
   721       bool operator==(const Edge& v) const { 
   722 	return (this->backward==v.backward && 
   723 		static_cast<typename _Graph::Edge>(*this)==
   724 		static_cast<typename _Graph::Edge>(v));
   725       } 
   726       bool operator!=(const Edge& v) const { 
   727 	return (this->backward!=v.backward || 
   728 		static_cast<typename _Graph::Edge>(*this)!=
   729 		static_cast<typename _Graph::Edge>(v));
   730       }
   731     };
   732 
   733     void first(Node& i) const { 
   734       Parent::first(i); 
   735     }
   736 
   737     void first(Edge& i) const { 
   738       Parent::first(i); 
   739       i.backward=false;
   740       while (*static_cast<GraphEdge*>(&i)!=INVALID && 
   741 	     !(*forward_filter)[i]) Parent::next(i);
   742       if (*static_cast<GraphEdge*>(&i)==INVALID) {
   743 	Parent::first(i); 
   744 	i.backward=true;
   745 	while (*static_cast<GraphEdge*>(&i)!=INVALID && 
   746 	       !(*backward_filter)[i]) Parent::next(i);
   747       }
   748     }
   749 
   750     void firstIn(Edge& i, const Node& n) const { 
   751       Parent::firstIn(i, n); 
   752       i.backward=false;
   753       while (*static_cast<GraphEdge*>(&i)!=INVALID && 
   754 	     !(*forward_filter)[i]) Parent::nextIn(i);
   755       if (*static_cast<GraphEdge*>(&i)==INVALID) {
   756 	Parent::firstOut(i, n); 
   757 	i.backward=true;
   758 	while (*static_cast<GraphEdge*>(&i)!=INVALID && 
   759 	       !(*backward_filter)[i]) Parent::nextOut(i);
   760       }
   761     }
   762 
   763     void firstOut(Edge& i, const Node& n) const { 
   764       Parent::firstOut(i, n); 
   765       i.backward=false;
   766       while (*static_cast<GraphEdge*>(&i)!=INVALID && 
   767 	     !(*forward_filter)[i]) Parent::nextOut(i);
   768       if (*static_cast<GraphEdge*>(&i)==INVALID) {
   769 	Parent::firstIn(i, n); 
   770 	i.backward=true;
   771 	while (*static_cast<GraphEdge*>(&i)!=INVALID && 
   772 	       !(*backward_filter)[i]) Parent::nextIn(i);
   773       }
   774     }
   775 
   776     void next(Node& i) const { 
   777       Parent::next(i); 
   778     }
   779 
   780     void next(Edge& i) const { 
   781       if (!(i.backward)) {
   782 	Parent::next(i);
   783 	while (*static_cast<GraphEdge*>(&i)!=INVALID && 
   784 	       !(*forward_filter)[i]) Parent::next(i);
   785 	if (*static_cast<GraphEdge*>(&i)==INVALID) {
   786 	  Parent::first(i); 
   787 	  i.backward=true;
   788 	  while (*static_cast<GraphEdge*>(&i)!=INVALID && 
   789 		 !(*backward_filter)[i]) Parent::next(i);
   790 	}
   791       } else {
   792 	Parent::next(i);
   793 	while (*static_cast<GraphEdge*>(&i)!=INVALID && 
   794 	       !(*backward_filter)[i]) Parent::next(i);
   795       }
   796     }
   797 
   798     void nextIn(Edge& i) const { 
   799       if (!(i.backward)) {
   800 	Node n=Parent::target(i);
   801 	Parent::nextIn(i);
   802 	while (*static_cast<GraphEdge*>(&i)!=INVALID && 
   803 	       !(*forward_filter)[i]) Parent::nextIn(i);
   804 	if (*static_cast<GraphEdge*>(&i)==INVALID) {
   805 	  Parent::firstOut(i, n); 
   806 	  i.backward=true;
   807 	  while (*static_cast<GraphEdge*>(&i)!=INVALID && 
   808 		 !(*backward_filter)[i]) Parent::nextOut(i);
   809 	}
   810       } else {
   811 	Parent::nextOut(i);
   812 	while (*static_cast<GraphEdge*>(&i)!=INVALID && 
   813 	       !(*backward_filter)[i]) Parent::nextOut(i);
   814       }
   815     }
   816 
   817     void nextOut(Edge& i) const { 
   818       if (!(i.backward)) {
   819 	Node n=Parent::source(i);
   820 	Parent::nextOut(i);
   821 	while (*static_cast<GraphEdge*>(&i)!=INVALID && 
   822 	       !(*forward_filter)[i]) Parent::nextOut(i);
   823 	if (*static_cast<GraphEdge*>(&i)==INVALID) {
   824 	  Parent::firstIn(i, n); 
   825 	  i.backward=true;
   826 	  while (*static_cast<GraphEdge*>(&i)!=INVALID && 
   827 		 !(*backward_filter)[i]) Parent::nextIn(i);
   828 	}
   829       } else {
   830 	Parent::nextIn(i);
   831 	while (*static_cast<GraphEdge*>(&i)!=INVALID && 
   832 	       !(*backward_filter)[i]) Parent::nextIn(i);
   833       }
   834     }
   835 
   836     Node source(Edge e) const { 
   837       return ((!e.backward) ? this->graph->source(e) : this->graph->target(e)); }
   838     Node target(Edge e) const { 
   839       return ((!e.backward) ? this->graph->target(e) : this->graph->source(e)); }
   840 
   841     /// Gives back the opposite edge.
   842     Edge opposite(const Edge& e) const { 
   843       Edge f=e;
   844       f.backward=!f.backward;
   845       return f;
   846     }
   847 
   848     /// \warning This is a linear time operation and works only if 
   849     /// \c Graph::EdgeIt is defined.
   850     /// \todo hmm
   851     int edgeNum() const { 
   852       int i=0;
   853       Edge e;
   854       for (first(e); e!=INVALID; next(e)) ++i;
   855       return i; 
   856     }
   857 
   858     bool forward(const Edge& e) const { return !e.backward; }
   859     bool backward(const Edge& e) const { return e.backward; }
   860 
   861     template <typename T>
   862     /// \c SubBidirGraphAdaptorBase<..., ..., ...>::EdgeMap contains two 
   863     /// _Graph::EdgeMap one for the forward edges and 
   864     /// one for the backward edges.
   865     class EdgeMap {
   866       template <typename TT> friend class EdgeMap;
   867       typename _Graph::template EdgeMap<T> forward_map, backward_map; 
   868     public:
   869       typedef T Value;
   870       typedef Edge Key;
   871 
   872       EdgeMap(const SubBidirGraphAdaptorBase<_Graph, 
   873 	      ForwardFilterMap, BackwardFilterMap>& g) : 
   874 	forward_map(*(g.graph)), backward_map(*(g.graph)) { }
   875 
   876       EdgeMap(const SubBidirGraphAdaptorBase<_Graph, 
   877 	      ForwardFilterMap, BackwardFilterMap>& g, T a) : 
   878 	forward_map(*(g.graph), a), backward_map(*(g.graph), a) { }
   879       
   880       void set(Edge e, T a) { 
   881 	if (!e.backward) 
   882 	  forward_map.set(e, a); 
   883 	else 
   884 	  backward_map.set(e, a); 
   885       }
   886 
   887 //       typename _Graph::template EdgeMap<T>::ConstReference 
   888 //       operator[](Edge e) const { 
   889 // 	if (!e.backward) 
   890 // 	  return forward_map[e]; 
   891 // 	else 
   892 // 	  return backward_map[e]; 
   893 //       }
   894 
   895 //      typename _Graph::template EdgeMap<T>::Reference 
   896       T operator[](Edge e) const { 
   897 	if (!e.backward) 
   898 	  return forward_map[e]; 
   899 	else 
   900 	  return backward_map[e]; 
   901       }
   902 
   903       void update() { 
   904 	forward_map.update(); 
   905 	backward_map.update();
   906       }
   907     };
   908 
   909   };
   910 
   911 
   912   ///\brief An adaptor for composing a subgraph of a 
   913   /// bidirected graph made from a directed one. 
   914   ///
   915   /// An adaptor for composing a subgraph of a 
   916   /// bidirected graph made from a directed one. 
   917   ///
   918   ///\warning Graph adaptors are in even more experimental state than the other
   919   ///parts of the lib. Use them at you own risk.
   920   ///
   921   /// Let \f$G=(V, A)\f$ be a directed graph and for each directed edge 
   922   /// \f$e\in A\f$, let \f$\bar e\f$ denote the edge obtained by
   923   /// reversing its orientation. We are given moreover two bool valued 
   924   /// maps on the edge-set, 
   925   /// \f$forward\_filter\f$, and \f$backward\_filter\f$. 
   926   /// SubBidirGraphAdaptor implements the graph structure with node-set 
   927   /// \f$V\f$ and edge-set 
   928   /// \f$\{e : e\in A \mbox{ and } forward\_filter(e) \mbox{ is true}\}+\{\bar e : e\in A \mbox{ and } backward\_filter(e) \mbox{ is true}\}\f$. 
   929   /// The purpose of writing + instead of union is because parallel 
   930   /// edges can arise. (Similarly, antiparallel edges also can arise).
   931   /// In other words, a subgraph of the bidirected graph obtained, which 
   932   /// is given by orienting the edges of the original graph in both directions.
   933   /// As the oppositely directed edges are logically different, 
   934   /// the maps are able to attach different values for them. 
   935   ///
   936   /// An example for such a construction is \c RevGraphAdaptor where the 
   937   /// forward_filter is everywhere false and the backward_filter is 
   938   /// everywhere true. We note that for sake of efficiency, 
   939   /// \c RevGraphAdaptor is implemented in a different way. 
   940   /// But BidirGraphAdaptor is obtained from 
   941   /// SubBidirGraphAdaptor by considering everywhere true 
   942   /// valued maps both for forward_filter and backward_filter. 
   943   ///
   944   /// The most important application of SubBidirGraphAdaptor 
   945   /// is ResGraphAdaptor, which stands for the residual graph in directed 
   946   /// flow and circulation problems. 
   947   /// As adaptors usually, the SubBidirGraphAdaptor implements the 
   948   /// above mentioned graph structure without its physical storage, 
   949   /// that is the whole stuff is stored in constant memory. 
   950   template<typename _Graph, 
   951 	   typename ForwardFilterMap, typename BackwardFilterMap>
   952   class SubBidirGraphAdaptor : 
   953     public IterableGraphExtender<
   954     SubBidirGraphAdaptorBase<_Graph, ForwardFilterMap, BackwardFilterMap> > {
   955   public:
   956     typedef _Graph Graph;
   957     typedef IterableGraphExtender<
   958       SubBidirGraphAdaptorBase<
   959       _Graph, ForwardFilterMap, BackwardFilterMap> > Parent;
   960   protected:
   961     SubBidirGraphAdaptor() { }
   962   public:
   963     SubBidirGraphAdaptor(_Graph& _graph, ForwardFilterMap& _forward_filter, 
   964 			 BackwardFilterMap& _backward_filter) { 
   965       setGraph(_graph);
   966       setForwardFilterMap(_forward_filter);
   967       setBackwardFilterMap(_backward_filter);
   968     }
   969   };
   970 
   971 
   972 
   973   ///\brief An adaptor for composing bidirected graph from a directed one. 
   974   ///
   975   ///\warning Graph adaptors are in even more experimental state than the other
   976   ///parts of the lib. Use them at you own risk.
   977   ///
   978   /// An adaptor for composing bidirected graph from a directed one. 
   979   /// A bidirected graph is composed over the directed one without physical 
   980   /// storage. As the oppositely directed edges are logically different ones 
   981   /// the maps are able to attach different values for them.
   982   template<typename Graph>
   983   class BidirGraphAdaptor : 
   984     public SubBidirGraphAdaptor<
   985     Graph, 
   986     ConstMap<typename Graph::Edge, bool>, 
   987     ConstMap<typename Graph::Edge, bool> > {
   988   public:
   989     typedef  SubBidirGraphAdaptor<
   990       Graph, 
   991       ConstMap<typename Graph::Edge, bool>, 
   992       ConstMap<typename Graph::Edge, bool> > Parent; 
   993   protected:
   994     ConstMap<typename Graph::Edge, bool> cm;
   995 
   996     BidirGraphAdaptor() : Parent(), cm(true) { 
   997       Parent::setForwardFilterMap(cm);
   998       Parent::setBackwardFilterMap(cm);
   999     }
  1000   public:
  1001     BidirGraphAdaptor(Graph& _graph) : Parent(), cm(true) { 
  1002       Parent::setGraph(_graph);
  1003       Parent::setForwardFilterMap(cm);
  1004       Parent::setBackwardFilterMap(cm);
  1005     }
  1006 
  1007     int edgeNum() const { 
  1008       return 2*this->graph->edgeNum();
  1009     }
  1010     //    KEEP_MAPS(Parent, BidirGraphAdaptor);
  1011   };
  1012 
  1013 
  1014   template<typename Graph, typename Number,
  1015 	   typename CapacityMap, typename FlowMap>
  1016   class ResForwardFilter {
  1017     //    const Graph* graph;
  1018     const CapacityMap* capacity;
  1019     const FlowMap* flow;
  1020   public:
  1021     ResForwardFilter(/*const Graph& _graph, */
  1022 		     const CapacityMap& _capacity, const FlowMap& _flow) :
  1023       /*graph(&_graph),*/ capacity(&_capacity), flow(&_flow) { }
  1024     ResForwardFilter() : /*graph(0),*/ capacity(0), flow(0) { }
  1025     void setCapacity(const CapacityMap& _capacity) { capacity=&_capacity; }
  1026     void setFlow(const FlowMap& _flow) { flow=&_flow; }
  1027     bool operator[](const typename Graph::Edge& e) const {
  1028       return (Number((*flow)[e]) < Number((*capacity)[e]));
  1029     }
  1030   };
  1031 
  1032   template<typename Graph, typename Number,
  1033 	   typename CapacityMap, typename FlowMap>
  1034   class ResBackwardFilter {
  1035     const CapacityMap* capacity;
  1036     const FlowMap* flow;
  1037   public:
  1038     ResBackwardFilter(/*const Graph& _graph,*/ 
  1039 		      const CapacityMap& _capacity, const FlowMap& _flow) :
  1040       /*graph(&_graph),*/ capacity(&_capacity), flow(&_flow) { }
  1041     ResBackwardFilter() : /*graph(0),*/ capacity(0), flow(0) { }
  1042     void setCapacity(const CapacityMap& _capacity) { capacity=&_capacity; }
  1043     void setFlow(const FlowMap& _flow) { flow=&_flow; }
  1044     bool operator[](const typename Graph::Edge& e) const {
  1045       return (Number(0) < Number((*flow)[e]));
  1046     }
  1047   };
  1048 
  1049   
  1050   /*! \brief An adaptor for composing the residual graph for directed flow and circulation problems.
  1051 
  1052   An adaptor for composing the residual graph for directed flow and circulation problems. 
  1053   Let \f$G=(V, A)\f$ be a directed graph and let \f$F\f$ be a 
  1054   number type. Let moreover 
  1055   \f$f,c:A\to F\f$, be functions on the edge-set. 
  1056   In the appications of ResGraphAdaptor, \f$f\f$ usually stands for a flow 
  1057   and \f$c\f$ for a capacity function.   
  1058   Suppose that a graph instange \c g of type 
  1059   \c ListGraph implements \f$G\f$.
  1060   \code
  1061   ListGraph g;
  1062   \endcode
  1063   Then RevGraphAdaptor implements the graph structure with node-set 
  1064   \f$V\f$ and edge-set \f$A_{forward}\cup A_{backward}\f$, where 
  1065   \f$A_{forward}=\{uv : uv\in A, f(uv)<c(uv)\}\f$ and 
  1066   \f$A_{backward}=\{vu : uv\in A, f(uv)>0\}\f$, 
  1067   i.e. the so called residual graph. 
  1068   When we take the union \f$A_{forward}\cup A_{backward}\f$, 
  1069   multilicities are counted, i.e. if an edge is in both 
  1070   \f$A_{forward}\f$ and \f$A_{backward}\f$, then in the adaptor it 
  1071   appears twice. 
  1072   The following code shows how 
  1073   such an instance can be constructed.
  1074   \code
  1075   typedef ListGraph Graph;
  1076   Graph::EdgeMap<int> f(g);
  1077   Graph::EdgeMap<int> c(g);
  1078   ResGraphAdaptor<Graph, int, Graph::EdgeMap<int>, Graph::EdgeMap<int> > gw(g);
  1079   \endcode
  1080   \author Marton Makai
  1081   */
  1082   template<typename Graph, typename Number, 
  1083 	   typename CapacityMap, typename FlowMap>
  1084   class ResGraphAdaptor : 
  1085     public SubBidirGraphAdaptor< 
  1086     Graph, 
  1087     ResForwardFilter<Graph, Number, CapacityMap, FlowMap>,  
  1088     ResBackwardFilter<Graph, Number, CapacityMap, FlowMap> > {
  1089   public:
  1090     typedef SubBidirGraphAdaptor< 
  1091       Graph, 
  1092       ResForwardFilter<Graph, Number, CapacityMap, FlowMap>,  
  1093       ResBackwardFilter<Graph, Number, CapacityMap, FlowMap> > Parent;
  1094   protected:
  1095     const CapacityMap* capacity;
  1096     FlowMap* flow;
  1097     ResForwardFilter<Graph, Number, CapacityMap, FlowMap> forward_filter;
  1098     ResBackwardFilter<Graph, Number, CapacityMap, FlowMap> backward_filter;
  1099     ResGraphAdaptor() : Parent(), 
  1100  			capacity(0), flow(0) { }
  1101     void setCapacityMap(const CapacityMap& _capacity) {
  1102       capacity=&_capacity;
  1103       forward_filter.setCapacity(_capacity);
  1104       backward_filter.setCapacity(_capacity);
  1105     }
  1106     void setFlowMap(FlowMap& _flow) {
  1107       flow=&_flow;
  1108       forward_filter.setFlow(_flow);
  1109       backward_filter.setFlow(_flow);
  1110     }
  1111   public:
  1112     ResGraphAdaptor(Graph& _graph, const CapacityMap& _capacity, 
  1113 		       FlowMap& _flow) : 
  1114       Parent(), capacity(&_capacity), flow(&_flow), 
  1115       forward_filter(/*_graph,*/ _capacity, _flow), 
  1116       backward_filter(/*_graph,*/ _capacity, _flow) {
  1117       Parent::setGraph(_graph);
  1118       Parent::setForwardFilterMap(forward_filter);
  1119       Parent::setBackwardFilterMap(backward_filter);
  1120     }
  1121 
  1122     typedef typename Parent::Edge Edge;
  1123 
  1124     void augment(const Edge& e, Number a) const {
  1125       if (Parent::forward(e))  
  1126 	flow->set(e, (*flow)[e]+a);
  1127       else  
  1128 	flow->set(e, (*flow)[e]-a);
  1129     }
  1130 
  1131     /// \brief Residual capacity map.
  1132     ///
  1133     /// In generic residual graphs the residual capacity can be obtained 
  1134     /// as a map. 
  1135     class ResCap {
  1136     protected:
  1137       const ResGraphAdaptor<Graph, Number, CapacityMap, FlowMap>* res_graph;
  1138     public:
  1139       typedef Number Value;
  1140       typedef Edge Key;
  1141       ResCap(const ResGraphAdaptor<Graph, Number, CapacityMap, FlowMap>& 
  1142 	     _res_graph) : res_graph(&_res_graph) { }
  1143       Number operator[](const Edge& e) const { 
  1144 	if (res_graph->forward(e)) 
  1145 	  return (*(res_graph->capacity))[e]-(*(res_graph->flow))[e]; 
  1146 	else 
  1147 	  return (*(res_graph->flow))[e]; 
  1148       }
  1149     };
  1150 
  1151     //    KEEP_MAPS(Parent, ResGraphAdaptor);
  1152   };
  1153 
  1154 
  1155 
  1156   template <typename _Graph, typename FirstOutEdgesMap>
  1157   class ErasingFirstGraphAdaptorBase : public GraphAdaptorBase<_Graph> {
  1158   public:
  1159     typedef _Graph Graph;
  1160     typedef GraphAdaptorBase<_Graph> Parent;
  1161   protected:
  1162     FirstOutEdgesMap* first_out_edges;
  1163     ErasingFirstGraphAdaptorBase() : Parent(), 
  1164 				     first_out_edges(0) { }
  1165 
  1166     void setFirstOutEdgesMap(FirstOutEdgesMap& _first_out_edges) {
  1167       first_out_edges=&_first_out_edges;
  1168     }
  1169 
  1170   public:
  1171 
  1172     typedef typename Parent::Node Node;
  1173     typedef typename Parent::Edge Edge;
  1174 
  1175     void firstOut(Edge& i, const Node& n) const { 
  1176       i=(*first_out_edges)[n];
  1177     }
  1178 
  1179     void erase(const Edge& e) const {
  1180       Node n=source(e);
  1181       Edge f=e;
  1182       Parent::nextOut(f);
  1183       first_out_edges->set(n, f);
  1184     }    
  1185   };
  1186 
  1187 
  1188   /// For blocking flows.
  1189 
  1190   ///\warning Graph adaptors are in even more experimental state than the other
  1191   ///parts of the lib. Use them at you own risk.
  1192   ///
  1193   /// This graph adaptor is used for on-the-fly 
  1194   /// Dinits blocking flow computations.
  1195   /// For each node, an out-edge is stored which is used when the 
  1196   /// \code 
  1197   /// OutEdgeIt& first(OutEdgeIt&, const Node&)
  1198   /// \endcode
  1199   /// is called. 
  1200   ///
  1201   /// \author Marton Makai
  1202   template <typename _Graph, typename FirstOutEdgesMap>
  1203   class ErasingFirstGraphAdaptor : 
  1204     public IterableGraphExtender<
  1205     ErasingFirstGraphAdaptorBase<_Graph, FirstOutEdgesMap> > {
  1206   public:
  1207     typedef _Graph Graph;
  1208     typedef IterableGraphExtender<
  1209       ErasingFirstGraphAdaptorBase<_Graph, FirstOutEdgesMap> > Parent;
  1210     ErasingFirstGraphAdaptor(Graph& _graph, 
  1211 			     FirstOutEdgesMap& _first_out_edges) { 
  1212       setGraph(_graph);
  1213       setFirstOutEdgesMap(_first_out_edges);
  1214     } 
  1215 
  1216   };
  1217 
  1218   /// \e
  1219   template <typename _Graph>
  1220   class NewEdgeSetAdaptorBase {
  1221   public:
  1222 
  1223     typedef _Graph Graph;
  1224     typedef typename Graph::Node Node;
  1225     typedef typename Graph::NodeIt NodeIt;
  1226 
  1227   protected:
  1228 
  1229     struct NodeT {
  1230       int first_out, first_in;
  1231       NodeT() : first_out(-1), first_in(-1) {}
  1232     };
  1233     
  1234     class NodesImpl : protected Graph::template NodeMap<NodeT> {
  1235 
  1236       typedef typename Graph::template NodeMap<NodeT> Parent;
  1237       typedef NewEdgeSetAdaptorBase<Graph> Adaptor;
  1238 
  1239       Adaptor& adaptor;
  1240 
  1241     public:
  1242 
  1243       NodesImpl(Adaptor& _adaptor, const Graph& _graph) 
  1244 	: Parent(_graph), adaptor(_adaptor) {}
  1245 
  1246       virtual ~NodesImpl() {}
  1247 
  1248       virtual void build() {
  1249 	Parent::build();
  1250       }
  1251 
  1252       virtual void clear() {
  1253 	adaptor._clear();
  1254 	Parent::clear();
  1255       }
  1256       
  1257       virtual void add(const Node& node) {
  1258 	Parent::add(node);
  1259 	adaptor._add(node);
  1260       }
  1261       
  1262       virtual void erase(const Node& node) {
  1263 	adaptor._erase(node);
  1264 	Parent::erase(node);
  1265       }
  1266 
  1267       NodeT& operator[](const Node& node) {
  1268 	return Parent::operator[](node);
  1269       }
  1270 
  1271       const NodeT& operator[](const Node& node) const {
  1272 	return Parent::operator[](node);
  1273       }
  1274       
  1275     };
  1276 
  1277     NodesImpl* nodes;
  1278 
  1279     struct EdgeT {
  1280       Node source, target;
  1281       int next_out, next_in;
  1282       int prev_out, prev_in;
  1283       EdgeT() : prev_out(-1), prev_in(-1) {}
  1284     };
  1285 
  1286     std::vector<EdgeT> edges;
  1287 
  1288     int first_edge;
  1289     int first_free_edge;
  1290 
  1291     virtual void _clear() = 0;
  1292     virtual void _add(const Node& node) = 0;
  1293     virtual void _erase(const Node& node) = 0;
  1294     
  1295     const Graph* graph;
  1296 
  1297     void initalize(const Graph& _graph, NodesImpl& _nodes) {
  1298       graph = &_graph;
  1299       nodes = &_nodes;
  1300     }
  1301     
  1302   public:
  1303 
  1304     class Edge {
  1305       friend class NewEdgeSetAdaptorBase<Graph>;
  1306     protected:
  1307       Edge(int _id) : id(_id) {}
  1308       int id;
  1309     public:
  1310       Edge() {}
  1311       Edge(Invalid) : id(-1) {}
  1312       bool operator==(const Edge& edge) const { return id == edge.id; }
  1313       bool operator!=(const Edge& edge) const { return id != edge.id; }
  1314       bool operator<(const Edge& edge) const { return id < edge.id; }
  1315     };
  1316 
  1317     NewEdgeSetAdaptorBase() : first_edge(-1), first_free_edge(-1) {} 
  1318     virtual ~NewEdgeSetAdaptorBase() {}
  1319 
  1320     Edge addEdge(const Node& source, const Node& target) {
  1321       int n;
  1322       if (first_free_edge == -1) {
  1323 	n = edges.size();
  1324 	edges.push_back(EdgeT());
  1325       } else {
  1326 	n = first_free_edge;
  1327 	first_free_edge = edges[first_free_edge].next_in;
  1328       }
  1329       edges[n].next_in = (*nodes)[target].first_in;
  1330       (*nodes)[target].first_in = n;
  1331       edges[n].next_out = (*nodes)[source].first_out;
  1332       (*nodes)[source].first_out = n;
  1333       edges[n].source = source;
  1334       edges[n].target = target;
  1335       return Edge(n);
  1336     }
  1337 
  1338     void erase(const Edge& edge) {
  1339       int n = edge.id;
  1340       if (edges[n].prev_in != -1) {
  1341 	edges[edges[n].prev_in].next_in = edges[n].next_in;
  1342       } else {
  1343 	(*nodes)[edges[n].target].first_in = edges[n].next_in;
  1344       }
  1345       if (edges[n].next_in != -1) {
  1346 	edges[edges[n].next_in].prev_in = edges[n].prev_in;
  1347       }
  1348 
  1349       if (edges[n].prev_out != -1) {
  1350 	edges[edges[n].prev_out].next_out = edges[n].next_out;
  1351       } else {
  1352 	(*nodes)[edges[n].source].first_out = edges[n].next_out;
  1353       }
  1354       if (edges[n].next_out != -1) {
  1355 	edges[edges[n].next_out].prev_out = edges[n].prev_out;
  1356       }
  1357            
  1358     }
  1359 
  1360     void first(Node& node) const {
  1361       graph->first(node);
  1362     }
  1363 
  1364     void next(Node& node) const {
  1365       graph->next(node);
  1366     }
  1367 
  1368     void first(Edge& edge) const {
  1369       Node node;
  1370       for (first(node); node != INVALID && (*nodes)[node].first_in == -1; 
  1371 	   next(node));
  1372       edge.id = (node == INVALID) ? -1 : (*nodes)[node].first_in;
  1373     }
  1374 
  1375     void next(Edge& edge) const {
  1376       if (edges[edge.id].next_in != -1) {
  1377 	edge.id = edges[edge.id].next_in;
  1378       } else {
  1379 	Node node = edges[edge.id].target;
  1380 	for (next(node); node != INVALID && (*nodes)[node].first_in == -1; 
  1381 	     next(node));
  1382 	edge.id = (node == INVALID) ? -1 : (*nodes)[node].first_in;
  1383       }      
  1384     }
  1385 
  1386     void firstOut(Edge& edge, const Node& node) const {
  1387       edge.id = (*nodes)[node].first_out;    
  1388     }
  1389     
  1390     void nextOut(Edge& edge) const {
  1391       edge.id = edges[edge.id].next_out;        
  1392     }
  1393 
  1394     void firstIn(Edge& edge, const Node& node) const {
  1395       edge.id = (*nodes)[node].first_in;          
  1396     }
  1397 
  1398     void nextIn(Edge& edge) const {
  1399       edge.id = edges[edge.id].next_in;    
  1400     }
  1401 
  1402     int id(const Node& node) const { return graph->id(node); }
  1403     int id(const Edge& edge) const { return edge.id; }
  1404 
  1405     Node fromId(int id, Node) const { return graph->fromId(id, Node()); }
  1406     Edge fromId(int id, Edge) const { return Edge(id); }
  1407 
  1408     int maxId(Node) const { return graph->maxId(Node()); };
  1409     int maxId(Edge) const { return edges.size() - 1; }
  1410 
  1411     Node source(const Edge& edge) const { return edges[edge.id].source;}
  1412     Node target(const Edge& edge) const { return edges[edge.id].target;}
  1413 
  1414   };
  1415 
  1416   template <typename _Graph>
  1417   class NewEdgeSetAdaptor :
  1418     public ErasableGraphExtender<
  1419     ClearableGraphExtender<
  1420     ExtendableGraphExtender<
  1421     DefaultMappableGraphExtender<
  1422     IterableGraphExtender<
  1423     AlterableGraphExtender<
  1424     NewEdgeSetAdaptorBase<_Graph> > > > > > > {
  1425 
  1426   public:
  1427 
  1428     typedef ErasableGraphExtender<
  1429       ClearableGraphExtender<
  1430       ExtendableGraphExtender<
  1431       DefaultMappableGraphExtender<
  1432       IterableGraphExtender<
  1433       AlterableGraphExtender<
  1434       NewEdgeSetAdaptorBase<_Graph> > > > > > > Parent;
  1435     
  1436 
  1437     typedef typename Parent::Node Node;
  1438     typedef typename Parent::Edge Edge;
  1439 
  1440   private:
  1441 
  1442     virtual void _clear() {
  1443       Parent::edges.clear();
  1444       Parent::first_edge = -1;
  1445       Parent::first_free_edge = -1;
  1446       Parent::getNotifier(Edge()).clear();
  1447       Parent::getNotifier(Node()).clear();
  1448     }
  1449 
  1450     virtual void _add(const Node& node) {
  1451       Parent::getNotifier(Node()).add(node);
  1452     }
  1453 
  1454     virtual void _erase(const Node& node) {
  1455       Edge edge;
  1456       Parent::firstOut(edge, node);
  1457       while (edge != INVALID) {
  1458 	Parent::erase(edge);
  1459 	Parent::firstOut(edge, node);
  1460       }
  1461 
  1462       Parent::firstIn(edge, node);
  1463       while (edge != INVALID) {
  1464 	Parent::erase(edge);
  1465 	Parent::firstIn(edge, node);
  1466       }
  1467       
  1468       Parent::getNotifier(Node()).erase(node);
  1469     }
  1470 
  1471 
  1472     typedef typename Parent::NodesImpl NodesImpl;
  1473 
  1474     NodesImpl nodes;
  1475     
  1476   public:
  1477 
  1478     NewEdgeSetAdaptor(const _Graph& _graph) : nodes(*this, _graph) {
  1479       Parent::initalize(_graph, nodes);
  1480     }
  1481 
  1482     void clear() {
  1483       Parent::edges.clear();
  1484       Parent::first_edge = -1;
  1485       Parent::first_free_edge = -1;
  1486 
  1487       Parent::getNotifier(Edge()).clear();      
  1488     }
  1489     
  1490   };
  1491 
  1492   ///@}
  1493 
  1494 } //namespace lemon
  1495 
  1496 #endif //LEMON_GRAPH_ADAPTOR_H
  1497