lemon/sub_graph.h
author alpar
Thu, 02 Feb 2006 15:53:01 +0000
changeset 1944 89d5cf6e6abb
parent 1875 98698b69a902
child 1956 a055123339d5
permissions -rw-r--r--
Use short icpc paths
     1 /* -*- C++ -*-
     2  * lemon/sub_graph.h - Part of LEMON, a generic C++ optimization library
     3  *
     4  * Copyright (C) 2006 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_SUB_GRAPH_H
    18 #define LEMON_SUB_GRAPH_H
    19 
    20 #include <lemon/graph_adaptor.h>
    21 
    22 namespace lemon {
    23 
    24   /// \brief Base for the SubGraph.
    25   ///
    26   /// Base for the SubGraph.
    27   template <typename _Graph>
    28   class SubGraphBase : public GraphAdaptorBase<const _Graph> {
    29   public:
    30     typedef _Graph Graph;
    31     typedef SubGraphBase<_Graph> SubGraph;
    32     typedef GraphAdaptorBase<const _Graph> Parent;
    33     typedef Parent Base;
    34 
    35     typedef typename Parent::Node Node;
    36     typedef typename Parent::Edge Edge;
    37 
    38 
    39   protected:
    40 
    41     class NodesImpl;
    42     class EdgesImpl;
    43 
    44     SubGraphBase() {}
    45 
    46     void construct(const Graph& _graph, NodesImpl& _nodes, EdgesImpl& _edges) {
    47       Parent::setGraph(_graph);
    48       nodes = &_nodes;
    49       edges = &_edges;
    50       firstNode = INVALID;
    51 
    52       Node node;
    53       Parent::first(node);
    54       while (node != INVALID) {
    55 	(*nodes)[node].prev = node;
    56 	(*nodes)[node].firstIn = INVALID;
    57 	(*nodes)[node].firstOut = INVALID;
    58 	Parent::next(node);
    59       }
    60 
    61       Edge edge;
    62       Parent::first(edge);
    63       while (edge != INVALID) {
    64 	(*edges)[edge].prevOut = edge;
    65 	Parent::next(edge);
    66       }
    67     }
    68 
    69   public:
    70 
    71     void first(Node& node) const {
    72       node = firstNode;
    73     }
    74     void next(Node& node) const {
    75       node = (*nodes)[node].next;
    76     }
    77 
    78     void first(Edge& edge) const {
    79       Node node = firstNode;
    80       while (node != INVALID && (*nodes)[node].firstOut == INVALID) {
    81 	node = (*nodes)[node].next;
    82       }
    83       if (node == INVALID) {
    84 	edge = INVALID;
    85       } else {
    86 	edge = (*nodes)[node].firstOut;
    87       }
    88     }
    89     void next(Edge& edge) const {
    90       if ((*edges)[edge].nextOut != INVALID) {
    91 	edge = (*edges)[edge].nextOut;
    92       } else {
    93 	Node node = (*nodes)[source(edge)].next;
    94 	while (node != INVALID && (*nodes)[node].firstOut == INVALID) {
    95 	  node = (*nodes)[node].next;
    96 	}
    97 	if (node == INVALID) {
    98 	  edge = INVALID;
    99 	} else {
   100 	  edge = (*nodes)[node].firstOut;
   101 	}
   102       }
   103     }
   104 
   105     void firstOut(Edge& edge, const Node& node) const {
   106       edge = (*nodes)[node].firstOut;
   107     }
   108     void nextOut(Edge& edge) const {
   109       edge = (*edges)[edge].nextOut;
   110     }
   111 
   112     void firstIn(Edge& edge, const Node& node) const {
   113       edge = (*nodes)[node].firstIn;
   114     }
   115     void nextIn(Edge& edge) const {
   116       edge = (*edges)[edge].nextIn;
   117     }
   118 
   119     /// \brief Returns true when the given node is hidden.
   120     ///
   121     /// Returns true when the given node is hidden.
   122     bool hidden(const Node& node) const {
   123       return (*nodes)[node].prev == node;
   124     }
   125 
   126     /// \brief Hide the given node in the sub-graph.
   127     ///
   128     /// Hide the given node in the sub graph. It just lace out from
   129     /// the linked lists the given node. If there are incoming or outgoing
   130     /// edges into or from this node then all of these will be hidden.
   131     void hide(const Node& node) {
   132       if (hidden(node)) return;
   133       Edge edge;
   134       firstOut(edge, node);
   135       while (edge != INVALID) {
   136 	hide(edge);
   137 	firstOut(edge, node);
   138       }
   139 
   140       firstOut(edge, node);
   141       while (edge != INVALID) {
   142 	hide(edge);
   143 	firstOut(edge, node);
   144       }
   145       if ((*nodes)[node].prev != INVALID) {
   146 	(*nodes)[(*nodes)[node].prev].next = (*nodes)[node].next;
   147       } else {
   148 	firstNode = (*nodes)[node].next;
   149       }
   150       if ((*nodes)[node].next != INVALID) {
   151 	(*nodes)[(*nodes)[node].next].prev = (*nodes)[node].prev;
   152       }
   153       (*nodes)[node].prev = node;
   154       (*nodes)[node].firstIn = INVALID;
   155       (*nodes)[node].firstOut = INVALID;
   156     }
   157 
   158     /// \brief Unhide the given node in the sub-graph.
   159     ///
   160     /// Unhide the given node in the sub graph. It just lace in the given
   161     /// node into the linked lists.
   162     void unHide(const Node& node) {
   163       if (!hidden(node)) return;
   164       (*nodes)[node].next = firstNode;
   165       (*nodes)[node].prev = INVALID;
   166       if ((*nodes)[node].next != INVALID) {
   167 	(*nodes)[(*nodes)[node].next].prev = node;
   168       }
   169       firstNode = node;
   170     }
   171 
   172     /// \brief Returns true when the given edge is hidden.
   173     ///
   174     /// Returns true when the given edge is hidden.
   175     bool hidden(const Edge& edge) const {
   176       return (*edges)[edge].prevOut == edge;
   177     }
   178 
   179     /// \brief Hide the given edge in the sub-graph.
   180     ///
   181     /// Hide the given edge in the sub graph. It just lace out from
   182     /// the linked lists the given edge.
   183     void hide(const Edge& edge) {
   184       if (hidden(edge)) return;
   185       if ((*edges)[edge].prevOut == edge) return;
   186       if ((*edges)[edge].prevOut != INVALID) {
   187 	(*edges)[(*edges)[edge].prevOut].nextOut = (*edges)[edge].nextOut;
   188       } else {
   189 	(*nodes)[source(edge)].firstOut = (*edges)[edge].nextOut;
   190       }
   191       if ((*edges)[edge].nextOut != INVALID) {
   192 	(*edges)[(*edges)[edge].nextOut].prevOut = (*edges)[edge].prevOut;
   193       }
   194 
   195       if ((*edges)[edge].prevIn != INVALID) {
   196 	(*edges)[(*edges)[edge].prevIn].nextIn = (*edges)[edge].nextIn;
   197       } else {
   198 	(*nodes)[target(edge)].firstIn = (*edges)[edge].nextIn;
   199       }
   200       if ((*edges)[edge].nextIn != INVALID) {
   201 	(*edges)[(*edges)[edge].nextIn].prevIn = (*edges)[edge].prevIn;
   202       }
   203       (*edges)[edge].next = edge;
   204     }
   205 
   206     /// \brief Unhide the given edge in the sub-graph.
   207     ///
   208     /// Unhide the given edge in the sub graph. It just lace in the given
   209     /// edge into the linked lists. If the source or the target of the
   210     /// node is hidden then it will unhide it.
   211     void unHide(const Edge& edge) {
   212       if (!hidden(edge)) return;
   213 
   214       Node node;
   215 
   216       node = Parent::source(edge);
   217       unHide(node);
   218       (*edges)[edge].nextOut = (*nodes)[node].firstOut;
   219       (*edges)[edge].prevOut = INVALID;
   220       if ((*edges)[edge].nextOut != INVALID) {
   221 	(*edges)[(*edges)[edge].nextOut].prevOut = edge;
   222       }
   223       (*nodes)[node].firstOut = edge;
   224 
   225       node = Parent::target(edge);
   226       unHide(node);
   227       (*edges)[edge].nextIn = (*nodes)[node].firstIn;
   228       (*edges)[edge].prevIn = INVALID;
   229       if ((*edges)[edge].nextIn != INVALID) {
   230 	(*edges)[(*edges)[edge].nextIn].prevIn = edge;
   231       }
   232       (*nodes)[node].firstIn = edge;      
   233     }
   234     
   235     typedef False NodeNumTag;
   236     typedef False EdgeNumTag;
   237 
   238   protected:
   239     struct NodeT {
   240       Node prev, next;
   241       Edge firstIn, firstOut;
   242     };
   243     class NodesImpl : public Graph::template NodeMap<NodeT> {
   244       friend class SubGraphBase;
   245     public:
   246       typedef typename Graph::template NodeMap<NodeT> Parent;
   247 
   248       NodesImpl(SubGraph& _adaptor, const Graph& _graph) 
   249 	: Parent(_graph), adaptor(_adaptor) {}
   250 
   251       virtual ~NodesImpl() {}
   252 
   253       virtual void build() {
   254 	Parent::build();
   255 	Node node;
   256 	adaptor.Base::first(node);
   257 	while (node != INVALID) {
   258 	  Parent::operator[](node).prev = node;
   259 	  Parent::operator[](node).firstIn = INVALID;
   260 	  Parent::operator[](node).firstOut = INVALID;
   261 	  adaptor.Base::next(node);
   262 	}
   263       }
   264 
   265       virtual void clear() {
   266 	adaptor.firstNode = INVALID;
   267 	Parent::clear();
   268       }
   269 
   270       virtual void add(const Node& node) {
   271 	Parent::add(node);
   272 	Parent::operator[](node).prev = node;
   273 	Parent::operator[](node).firstIn = INVALID;
   274 	Parent::operator[](node).firstOut = INVALID;
   275       }
   276       virtual void add(const std::vector<Node>& nodes) {
   277 	Parent::add(nodes);
   278 	for (int i = 0; i < (int)nodes.size(); ++i) {
   279 	  Parent::operator[](nodes[i]).prev = nodes[i];
   280 	  Parent::operator[](nodes[i]).firstIn = INVALID;
   281 	  Parent::operator[](nodes[i]).firstOut = INVALID;
   282 	}
   283       } 
   284 
   285       virtual void erase(const Node& node) {
   286 	adaptor.hide(node);
   287 	Parent::erase(node);
   288       }
   289 
   290       virtual void erase(const std::vector<Node>& nodes) {
   291 	for (int i = 0; i < (int)nodes.size(); ++i) {
   292 	  adaptor.hide(nodes[i]);
   293 	}
   294 	Parent::erase(nodes);
   295       }
   296 
   297     private:
   298       SubGraph& adaptor;
   299     };
   300 
   301     struct EdgeT {
   302       Edge prevOut, nextOut;
   303       Edge prevIn, nextIn;
   304     };
   305     class EdgesImpl : public Graph::template EdgeMap<EdgeT> {
   306       friend class SubGraphBase;
   307     public:
   308       typedef typename Graph::template EdgeMap<EdgeT> Parent;
   309 
   310       EdgesImpl(SubGraph& _adaptor, const Graph& _graph) 
   311 	: Parent(_graph), adaptor(_adaptor) {}
   312 
   313       virtual ~EdgesImpl() {}
   314 
   315       virtual void build() {
   316 	Parent::build();
   317 	Edge edge;
   318 	adaptor.Base::first(edge);
   319 	while (edge != INVALID) {
   320 	  Parent::operator[](edge).prevOut = edge;
   321 	  adaptor.Base::next(edge);
   322 	}
   323       }
   324 
   325       virtual void clear() {
   326 	Node node;
   327 	adaptor.first(node);
   328 	while (node != INVALID) {
   329 	  (*adaptor.nodes).firstIn = INVALID;
   330 	  (*adaptor.nodes).firstOut = INVALID;
   331 	  adaptor.next(node);
   332 	}
   333 	Parent::clear();
   334       }
   335 
   336       virtual void add(const Edge& edge) {
   337 	Parent::add(edge);
   338 	Parent::operator[](edge).prevOut = edge;
   339       }
   340 
   341       virtual void add(const std::vector<Edge>& edges) {
   342 	Parent::add(edges);
   343 	for (int i = 0; i < (int)edges.size(); ++i) {
   344 	  Parent::operator[](edges[i]).prevOut = edges[i];
   345 	}
   346       }
   347 
   348       virtual void erase(const Edge& edge) {
   349 	adaptor.hide(edge);
   350 	Parent::erase(edge);
   351       }
   352 
   353       virtual void erase(const std::vector<Edge>& edges) {
   354 	for (int i = 0; i < (int)edges.size(); ++i) {
   355 	  adaptor.hide(edges[i]);
   356 	}
   357 	Parent::erase(edge);
   358       }
   359 
   360     private:
   361       SubGraph& adaptor;
   362     };
   363 
   364     NodesImpl* nodes;
   365     EdgesImpl* edges;
   366     Node firstNode;
   367   };
   368 
   369   /// \ingroup semi_adaptors
   370   ///
   371   /// \brief Graph which uses a subset of an other graph's nodes and edges.
   372   ///
   373   /// Graph which uses a subset of an other graph's nodes and edges. This class
   374   /// is an alternative to the SubGraphAdaptor which is created for the
   375   /// same reason. The main difference between the two class that it
   376   /// makes linked lists on the unhidden nodes and edges what cause that
   377   /// on sparse subgraphs the algorithms can be more efficient and some times
   378   /// provide better time complexity. On other way this implemetation is
   379   /// less efficient in most case when the subgraph filters out only
   380   /// a few nodes or edges.
   381   /// 
   382   /// \see SubGraphAdaptor
   383   /// \see EdgeSubGraphBase
   384   template <typename Graph>
   385   class SubGraph 
   386     : public IterableGraphExtender< SubGraphBase<Graph> > {
   387   public:
   388     typedef IterableGraphExtender< SubGraphBase<Graph> > Parent;
   389   public:
   390     /// \brief Constructor for sub-graph.
   391     ///
   392     /// Constructor for sub-graph. Initially all the edges and nodes
   393     /// are hidden in the graph.
   394     SubGraph(const Graph& _graph) 
   395       : Parent(), nodes(*this, _graph), edges(*this, _graph) { 
   396       Parent::construct(_graph, nodes, edges);
   397     }
   398   private:
   399     typename Parent::NodesImpl nodes;
   400     typename Parent::EdgesImpl edges;
   401   };
   402 
   403   /// \brief Base for the EdgeSubGraph.
   404   ///
   405   /// Base for the EdgeSubGraph.
   406   template <typename _Graph>
   407   class EdgeSubGraphBase : public GraphAdaptorBase<const _Graph> {
   408   public:
   409     typedef _Graph Graph;
   410     typedef EdgeSubGraphBase<_Graph> SubGraph;
   411     typedef GraphAdaptorBase<const _Graph> Parent;
   412     typedef Parent Base;
   413 
   414     typedef typename Parent::Node Node;
   415     typedef typename Parent::Edge Edge;
   416 
   417 
   418   protected:
   419 
   420     class NodesImpl;
   421     class EdgesImpl;
   422 
   423     EdgeSubGraphBase() {}
   424 
   425     void construct(const Graph& _graph, NodesImpl& _nodes, EdgesImpl& _edges) {
   426       Parent::setGraph(_graph);
   427       nodes = &_nodes;
   428       edges = &_edges;
   429 
   430       Node node;
   431       Parent::first(node);
   432       while (node != INVALID) {
   433 	(*nodes)[node].firstIn = INVALID;
   434 	(*nodes)[node].firstOut = INVALID;
   435 	Parent::next(node);
   436       }
   437 
   438       Edge edge;
   439       Parent::first(edge);
   440       while (edge != INVALID) {
   441 	(*edges)[edge].prevOut = edge;
   442 	Parent::next(edge);
   443       }
   444     }
   445 
   446   public:
   447 
   448     void first(Node& node) const {
   449       Parent::first(node);
   450     }
   451     void next(Node& node) const {
   452       Parent::next(node);
   453     }
   454 
   455     void first(Edge& edge) const {
   456       Node node;
   457       Parent::first(node);
   458       while (node != INVALID && (*nodes)[node].firstOut == INVALID) {
   459 	Parent::next(node);
   460       }
   461       if (node == INVALID) {
   462 	edge = INVALID;
   463       } else {
   464 	edge = (*nodes)[node].firstOut;
   465       }
   466     }
   467     void next(Edge& edge) const {
   468       if ((*edges)[edge].nextOut != INVALID) {
   469 	edge = (*edges)[edge].nextOut;
   470       } else {
   471 	Node node = source(edge);
   472 	Parent::next(node);
   473 	while (node != INVALID && (*nodes)[node].firstOut == INVALID) {
   474 	  Parent::next(node);
   475 	}
   476 	if (node == INVALID) {
   477 	  edge = INVALID;
   478 	} else {
   479 	  edge = (*nodes)[node].firstOut;
   480 	}
   481       }
   482     }
   483 
   484     void firstOut(Edge& edge, const Node& node) const {
   485       edge = (*nodes)[node].firstOut;
   486     }
   487     void nextOut(Edge& edge) const {
   488       edge = (*edges)[edge].nextOut;
   489     }
   490 
   491     void firstIn(Edge& edge, const Node& node) const {
   492       edge = (*nodes)[node].firstIn;
   493     }
   494     void nextIn(Edge& edge) const {
   495       edge = (*edges)[edge].nextIn;
   496     }
   497 
   498     /// \brief Returns true when the given edge is hidden.
   499     ///
   500     /// Returns true when the given edge is hidden.
   501     bool hidden(const Edge& edge) const {
   502       return (*edges)[edge].prevOut == edge;
   503     }
   504 
   505     /// \brief Hide the given edge in the sub-graph.
   506     ///
   507     /// Hide the given edge in the sub graph. It just lace out from
   508     /// the linked lists the given edge.
   509     void hide(const Edge& edge) {
   510       if (hidden(edge)) return;
   511       if ((*edges)[edge].prevOut != INVALID) {
   512 	(*edges)[(*edges)[edge].prevOut].nextOut = (*edges)[edge].nextOut;
   513       } else {
   514 	(*nodes)[source(edge)].firstOut = (*edges)[edge].nextOut;
   515       }
   516       if ((*edges)[edge].nextOut != INVALID) {
   517 	(*edges)[(*edges)[edge].nextOut].prevOut = (*edges)[edge].prevOut;
   518       }
   519 
   520       if ((*edges)[edge].prevIn != INVALID) {
   521 	(*edges)[(*edges)[edge].prevIn].nextIn = (*edges)[edge].nextIn;
   522       } else {
   523 	(*nodes)[target(edge)].firstIn = (*edges)[edge].nextIn;
   524       }
   525       if ((*edges)[edge].nextIn != INVALID) {
   526 	(*edges)[(*edges)[edge].nextIn].prevIn = (*edges)[edge].prevIn;
   527       }
   528       (*edges)[edge].prevOut = edge;
   529     }
   530 
   531     /// \brief Unhide the given edge in the sub-graph.
   532     ///
   533     /// Unhide the given edge in the sub graph. It just lace in the given
   534     /// edge into the linked lists.
   535     void unHide(const Edge& edge) {
   536       if (!hidden(edge)) return;
   537       Node node;
   538 
   539       node = Parent::source(edge);
   540       (*edges)[edge].nextOut = (*nodes)[node].firstOut;
   541       (*edges)[edge].prevOut = INVALID;
   542       if ((*edges)[edge].nextOut != INVALID) {
   543 	(*edges)[(*edges)[edge].nextOut].prevOut = edge;
   544       }
   545       (*nodes)[node].firstOut = edge;
   546 
   547       node = Parent::target(edge);
   548       (*edges)[edge].nextIn = (*nodes)[node].firstIn;
   549       (*edges)[edge].prevIn = INVALID;
   550       if ((*edges)[edge].nextIn != INVALID) {
   551 	(*edges)[(*edges)[edge].nextIn].prevIn = edge;
   552       }
   553       (*nodes)[node].firstIn = edge;      
   554     }
   555     
   556   protected:
   557     struct NodeT {
   558       Edge firstIn, firstOut;
   559     };
   560     class NodesImpl : public Graph::template NodeMap<NodeT> {
   561       friend class EdgeSubGraphBase;
   562     public:
   563       typedef typename Graph::template NodeMap<NodeT> Parent;
   564 
   565       NodesImpl(SubGraph& _adaptor, const Graph& _graph) 
   566 	: Parent(_graph), adaptor(_adaptor) {}
   567 
   568       virtual ~NodesImpl() {}
   569 
   570       virtual void build() {
   571 	Parent::build();
   572 	Node node;
   573 	adaptor.Base::first(node);
   574 	while (node != INVALID) {
   575 	  Parent::operator[](node).firstIn = INVALID;
   576 	  Parent::operator[](node).firstOut = INVALID;
   577 	  adaptor.Base::next(node);
   578 	}
   579       }
   580 
   581       virtual void add(const Node& node) {
   582 	Parent::add(node);
   583 	Parent::operator[](node).firstIn = INVALID;
   584 	Parent::operator[](node).firstOut = INVALID;
   585       }
   586 
   587     private:
   588       SubGraph& adaptor;
   589     };
   590 
   591     struct EdgeT {
   592       Edge prevOut, nextOut;
   593       Edge prevIn, nextIn;
   594     };
   595     class EdgesImpl : public Graph::template EdgeMap<EdgeT> {
   596       friend class EdgeSubGraphBase;
   597     public:
   598       typedef typename Graph::template EdgeMap<EdgeT> Parent;
   599 
   600       EdgesImpl(SubGraph& _adaptor, const Graph& _graph) 
   601 	: Parent(_graph), adaptor(_adaptor) {}
   602 
   603       virtual ~EdgesImpl() {}
   604 
   605       virtual void build() {
   606 	Parent::build();
   607 	Edge edge;
   608 	adaptor.Base::first(edge);
   609 	while (edge != INVALID) {
   610 	  Parent::operator[](edge).prevOut = edge;
   611 	  adaptor.Base::next(edge);
   612 	}
   613       }
   614 
   615       virtual void clear() {
   616 	Node node;
   617 	adaptor.Base::first(node);
   618 	while (node != INVALID) {
   619 	  (*adaptor.nodes)[node].firstIn = INVALID;
   620 	  (*adaptor.nodes)[node].firstOut = INVALID;
   621 	  adaptor.Base::next(node);
   622 	}
   623 	Parent::clear();
   624       }
   625 
   626       virtual void add(const Edge& edge) {
   627 	Parent::add(edge);
   628 	Parent::operator[](edge).prevOut = edge;
   629       }
   630 
   631       virtual void add(const std::vector<Edge>& edges) {
   632 	Parent::add(edges);
   633 	for (int i = 0; i < (int)edges.size(); ++i) {
   634 	  Parent::operator[](edges[i]).prevOut = edges[i];
   635 	}
   636       }
   637 
   638       virtual void erase(const Edge& edge) {
   639 	adaptor.hide(edge);
   640 	Parent::erase(edge);
   641       }
   642 
   643       virtual void erase(const std::vector<Edge>& edges) {
   644 	for (int i = 0; i < (int)edges.size(); ++i) {
   645 	  adaptor.hide(edges[i]);
   646 	}
   647 	Parent::erase(edge);
   648       }
   649 
   650     private:
   651       SubGraph& adaptor;
   652     };
   653 
   654     NodesImpl* nodes;
   655     EdgesImpl* edges;
   656   };
   657 
   658   /// \ingroup semi_adaptors
   659   ///
   660   /// \brief Graph which uses a subset of an other graph's edges.
   661   ///
   662   /// Graph which uses a subset of an other graph's edges. This class
   663   /// is an alternative to the EdgeSubGraphAdaptor which is created for the
   664   /// same reason. The main difference between the two class that it
   665   /// makes linked lists on the unhidden edges what cause that
   666   /// on sparse subgraphs the algorithms can be more efficient and some times
   667   /// provide better time complexity. On other way this implemetation is
   668   /// less efficient in most case when the subgraph filters out only
   669   /// a few edges.
   670   /// 
   671   /// \see EdgeSubGraphAdaptor
   672   /// \see EdgeSubGraphBase
   673   template <typename Graph>
   674   class EdgeSubGraph 
   675     : public IterableGraphExtender< EdgeSubGraphBase<Graph> > {
   676   public:
   677     typedef IterableGraphExtender< EdgeSubGraphBase<Graph> > Parent;
   678   public:
   679     /// \brief Constructor for sub-graph.
   680     ///
   681     /// Constructor for sub-graph. Initially all the edges are hidden in the 
   682     /// graph.
   683     EdgeSubGraph(const Graph& _graph) 
   684       : Parent(), nodes(*this, _graph), edges(*this, _graph) { 
   685       Parent::construct(_graph, nodes, edges);
   686     }
   687   private:
   688     typename Parent::NodesImpl nodes;
   689     typename Parent::EdgesImpl edges;
   690   };
   691 
   692 
   693 //   template<typename Graph, typename Number, 
   694 // 	   typename CapacityMap, typename FlowMap>
   695 //   class ResGraph
   696 //     : public IterableGraphExtender<EdgeSubGraphBase<
   697 //     UGraphAdaptor<Graph> > > {
   698 //   public:
   699 //     typedef IterableGraphExtender<EdgeSubGraphBase<
   700 //       UGraphAdaptor<Graph> > > Parent;
   701 
   702 //   protected:
   703 //     UGraphAdaptor<Graph> u;
   704 
   705 //     const CapacityMap* capacity;
   706 //     FlowMap* flow;
   707 
   708 //     typename Parent::NodesImpl nodes;
   709 //     typename Parent::EdgesImpl edges;
   710 
   711 //     void setCapacityMap(const CapacityMap& _capacity) {
   712 //       capacity=&_capacity;
   713 //     }
   714 
   715 //     void setFlowMap(FlowMap& _flow) {
   716 //       flow=&_flow;
   717 //     }
   718 
   719 //   public:
   720 
   721 //     typedef typename UGraphAdaptor<Graph>::Node Node;
   722 //     typedef typename UGraphAdaptor<Graph>::Edge Edge;
   723 //     typedef typename UGraphAdaptor<Graph>::UEdge UEdge;
   724 
   725 //     ResGraphAdaptor(Graph& _graph, 
   726 // 		    const CapacityMap& _capacity, FlowMap& _flow) 
   727 //       : Parent(), u(_graph), capacity(&_capacity), flow(&_flow),
   728 // 	nodes(*this, _graph), edges(*this, _graph) {
   729 //       Parent::construct(u, nodes, edges);
   730 //       setFlowMap(_flow);
   731 //       setCapacityMap(_capacity);
   732 //       typename Graph::Edge edge; 
   733 //       for (_graph.first(edge); edge != INVALID; _graph.next(edge)) {
   734 // 	if ((*flow)[edge] != (*capacity)[edge]) {
   735 // 	  Parent::unHide(direct(edge, true));
   736 // 	}
   737 // 	if ((*flow)[edge] != 0) {
   738 // 	  Parent::unHide(direct(edge, false));
   739 // 	}
   740 //       }
   741 //     }
   742 
   743 //     void augment(const Edge& e, Number a) {
   744 //       if (direction(e)) {
   745 // 	flow->set(e, (*flow)[e]+a);
   746 //       } else { 
   747 // 	flow->set(e, (*flow)[e]-a);
   748 //       }
   749 //       if ((*flow)[e] == (*capacity)[e]) {
   750 // 	Parent::hide(e);
   751 //       } else {
   752 // 	Parent::unHide(e);
   753 //       }
   754 //       if ((*flow)[e] == 0) {
   755 // 	Parent::hide(oppositeEdge(e));
   756 //       } else {
   757 // 	Parent::unHide(oppositeEdge(e));
   758 //       }
   759 //     }
   760 
   761 //     Number resCap(const Edge& e) {
   762 //       if (direction(e)) { 
   763 // 	return (*capacity)[e]-(*flow)[e]; 
   764 //       } else { 
   765 // 	return (*flow)[e];
   766 //       }
   767 //     }
   768     
   769 //     bool direction(const Edge& edge) const {
   770 //       return Parent::getGraph().direction(edge);
   771 //     }
   772 
   773 //     Edge direct(const UEdge& edge, bool direction) const {
   774 //       return Parent::getGraph().direct(edge, direction);
   775 //     }
   776 
   777 //     Edge direct(const UEdge& edge, const Node& node) const {
   778 //       return Parent::getGraph().direct(edge, node);
   779 //     }
   780 
   781 //     Edge oppositeEdge(const Edge& edge) const {
   782 //       return Parent::getGraph().oppositeEdge(edge);
   783 //     }
   784 
   785 //     /// \brief Residual capacity map.
   786 //     ///
   787 //     /// In generic residual graphs the residual capacity can be obtained 
   788 //     /// as a map. 
   789 //     class ResCap {
   790 //     protected:
   791 //       const ResGraphAdaptor* res_graph;
   792 //     public:
   793 //       typedef Number Value;
   794 //       typedef Edge Key;
   795 //       ResCap(const ResGraphAdaptor& _res_graph) 
   796 // 	: res_graph(&_res_graph) {}
   797 //       Number operator[](const Edge& e) const {
   798 // 	return res_graph->resCap(e);
   799 //       }
   800 //     };
   801 //   };
   802 
   803 }
   804 
   805 #endif