/* -*- mode: C++; indent-tabs-mode: nil; -*-

  *

  * This file is a part of LEMON, a generic C++ optimization library.

  *

  * Copyright (C) 2003-2009

  * Egervary Jeno Kombinatorikus Optimalizalasi Kutatocsoport

  * (Egervary Research Group on Combinatorial Optimization, EGRES).

  *

  * Permission to use, modify and distribute this software is granted

  * provided that this copyright notice appears in all copies. For

  * precise terms see the accompanying LICENSE file.

  *

  * This software is provided "AS IS" with no warranty of any kind,

  * express or implied, and with no claim as to its suitability for any

  * purpose.

  *

  */

 #include <iostream>

 #include <limits>

 #include <lemon/list_graph.h>

 #include <lemon/grid_graph.h>

 #include <lemon/bfs.h>

 #include <lemon/path.h>

 #include <lemon/concepts/digraph.h>

 #include <lemon/concepts/graph.h>

 #include <lemon/concepts/graph_components.h>

 #include <lemon/concepts/maps.h>

 #include <lemon/concept_check.h>

 #include <lemon/adaptors.h>

 #include "test/test_tools.h"

 #include "test/graph_test.h"

 using namespace lemon;

 void checkReverseDigraph() {

   // Check concepts

   checkConcept<concepts::Digraph, ReverseDigraph<concepts::Digraph> >();

   checkConcept<concepts::Digraph, ReverseDigraph<ListDigraph> >();

   checkConcept<concepts::AlterableDigraphComponent<>,

                ReverseDigraph<ListDigraph> >();

   checkConcept<concepts::ExtendableDigraphComponent<>,

                ReverseDigraph<ListDigraph> >();

   checkConcept<concepts::ErasableDigraphComponent<>,

                ReverseDigraph<ListDigraph> >();

   checkConcept<concepts::ClearableDigraphComponent<>,

                ReverseDigraph<ListDigraph> >();

   // Create a digraph and an adaptor

   typedef ListDigraph Digraph;

   typedef ReverseDigraph<Digraph> Adaptor;

   Digraph digraph;

   Adaptor adaptor(digraph);

   // Add nodes and arcs to the original digraph

   Digraph::Node n1 = digraph.addNode();

   Digraph::Node n2 = digraph.addNode();

   Digraph::Node n3 = digraph.addNode();

   Digraph::Arc a1 = digraph.addArc(n1, n2);

   Digraph::Arc a2 = digraph.addArc(n1, n3);

   Digraph::Arc a3 = digraph.addArc(n2, n3);

   // Check the adaptor

   checkGraphNodeList(adaptor, 3);

   checkGraphArcList(adaptor, 3);

   checkGraphConArcList(adaptor, 3);

   checkGraphOutArcList(adaptor, n1, 0);

   checkGraphOutArcList(adaptor, n2, 1);

   checkGraphOutArcList(adaptor, n3, 2);

   checkGraphInArcList(adaptor, n1, 2);

   checkGraphInArcList(adaptor, n2, 1);

   checkGraphInArcList(adaptor, n3, 0);

   checkNodeIds(adaptor);

   checkArcIds(adaptor);

   checkGraphNodeMap(adaptor);

   checkGraphArcMap(adaptor);

   // Check the orientation of the arcs

   for (Adaptor::ArcIt a(adaptor); a != INVALID; ++a) {

     check(adaptor.source(a) == digraph.target(a), "Wrong reverse");

     check(adaptor.target(a) == digraph.source(a), "Wrong reverse");

   }

   // Add and erase nodes and arcs in the digraph through the adaptor

   Adaptor::Node n4 = adaptor.addNode();

   Adaptor::Arc a4 = adaptor.addArc(n4, n3);

   Adaptor::Arc a5 = adaptor.addArc(n2, n4);

   Adaptor::Arc a6 = adaptor.addArc(n2, n4);

   Adaptor::Arc a7 = adaptor.addArc(n1, n4);

   Adaptor::Arc a8 = adaptor.addArc(n1, n2);

   adaptor.erase(a1);

   adaptor.erase(n3);

   // Check the adaptor

   checkGraphNodeList(adaptor, 3);

   checkGraphArcList(adaptor, 4);

   checkGraphConArcList(adaptor, 4);

   checkGraphOutArcList(adaptor, n1, 2);

   checkGraphOutArcList(adaptor, n2, 2);

   checkGraphOutArcList(adaptor, n4, 0);

   checkGraphInArcList(adaptor, n1, 0);

   checkGraphInArcList(adaptor, n2, 1);

   checkGraphInArcList(adaptor, n4, 3);

   checkNodeIds(adaptor);

   checkArcIds(adaptor);

   checkGraphNodeMap(adaptor);

   checkGraphArcMap(adaptor);

   // Check the digraph

   checkGraphNodeList(digraph, 3);

   checkGraphArcList(digraph, 4);

   checkGraphConArcList(digraph, 4);

   checkGraphOutArcList(digraph, n1, 0);

   checkGraphOutArcList(digraph, n2, 1);

   checkGraphOutArcList(digraph, n4, 3);

   checkGraphInArcList(digraph, n1, 2);

   checkGraphInArcList(digraph, n2, 2);

   checkGraphInArcList(digraph, n4, 0);

   checkNodeIds(digraph);

   checkArcIds(digraph);

   checkGraphNodeMap(digraph);

   checkGraphArcMap(digraph);

   // Check the conversion of nodes and arcs

   Digraph::Node nd = n4;

   nd = n4;

   Adaptor::Node na = n1;

   na = n2;

   Digraph::Arc ad = a4;

   ad = a5;

   Adaptor::Arc aa = a1;

   aa = a2;

 }

 void checkSubDigraph() {

   // Check concepts

   checkConcept<concepts::Digraph, SubDigraph<concepts::Digraph> >();

   checkConcept<concepts::Digraph, SubDigraph<ListDigraph> >();

   checkConcept<concepts::AlterableDigraphComponent<>,

                SubDigraph<ListDigraph> >();

   checkConcept<concepts::ExtendableDigraphComponent<>,

                SubDigraph<ListDigraph> >();

   checkConcept<concepts::ErasableDigraphComponent<>,

                SubDigraph<ListDigraph> >();

   checkConcept<concepts::ClearableDigraphComponent<>,

                SubDigraph<ListDigraph> >();

   // Create a digraph and an adaptor

   typedef ListDigraph Digraph;

   typedef Digraph::NodeMap<bool> NodeFilter;

   typedef Digraph::ArcMap<bool> ArcFilter;

   typedef SubDigraph<Digraph, NodeFilter, ArcFilter> Adaptor;

   Digraph digraph;

   NodeFilter node_filter(digraph);

   ArcFilter arc_filter(digraph);

   Adaptor adaptor(digraph, node_filter, arc_filter);

   // Add nodes and arcs to the original digraph and the adaptor

   Digraph::Node n1 = digraph.addNode();

   Digraph::Node n2 = digraph.addNode();

   Adaptor::Node n3 = adaptor.addNode();

   node_filter[n1] = node_filter[n2] = node_filter[n3] = true;

   Digraph::Arc a1 = digraph.addArc(n1, n2);

   Digraph::Arc a2 = digraph.addArc(n1, n3);

   Adaptor::Arc a3 = adaptor.addArc(n2, n3);

   arc_filter[a1] = arc_filter[a2] = arc_filter[a3] = true;

   checkGraphNodeList(adaptor, 3);

   checkGraphArcList(adaptor, 3);

   checkGraphConArcList(adaptor, 3);

   checkGraphOutArcList(adaptor, n1, 2);

   checkGraphOutArcList(adaptor, n2, 1);

   checkGraphOutArcList(adaptor, n3, 0);

   checkGraphInArcList(adaptor, n1, 0);

   checkGraphInArcList(adaptor, n2, 1);

   checkGraphInArcList(adaptor, n3, 2);

   checkNodeIds(adaptor);

   checkArcIds(adaptor);

   checkGraphNodeMap(adaptor);

   checkGraphArcMap(adaptor);

   // Hide an arc

   adaptor.status(a2, false);

   adaptor.disable(a3);

   if (!adaptor.status(a3)) adaptor.enable(a3);

   checkGraphNodeList(adaptor, 3);

   checkGraphArcList(adaptor, 2);

   checkGraphConArcList(adaptor, 2);

   checkGraphOutArcList(adaptor, n1, 1);

   checkGraphOutArcList(adaptor, n2, 1);

   checkGraphOutArcList(adaptor, n3, 0);

   checkGraphInArcList(adaptor, n1, 0);

   checkGraphInArcList(adaptor, n2, 1);

   checkGraphInArcList(adaptor, n3, 1);

   checkNodeIds(adaptor);

   checkArcIds(adaptor);

   checkGraphNodeMap(adaptor);

   checkGraphArcMap(adaptor);

   // Hide a node

   adaptor.status(n1, false);

   adaptor.disable(n3);

   if (!adaptor.status(n3)) adaptor.enable(n3);

   checkGraphNodeList(adaptor, 2);

   checkGraphArcList(adaptor, 1);

   checkGraphConArcList(adaptor, 1);

   checkGraphOutArcList(adaptor, n2, 1);

   checkGraphOutArcList(adaptor, n3, 0);

   checkGraphInArcList(adaptor, n2, 0);

   checkGraphInArcList(adaptor, n3, 1);

   checkNodeIds(adaptor);

   checkArcIds(adaptor);

   checkGraphNodeMap(adaptor);

   checkGraphArcMap(adaptor);

   // Hide all nodes and arcs

   node_filter[n1] = node_filter[n2] = node_filter[n3] = false;

   arc_filter[a1] = arc_filter[a2] = arc_filter[a3] = false;

   checkGraphNodeList(adaptor, 0);

   checkGraphArcList(adaptor, 0);

   checkGraphConArcList(adaptor, 0);

   checkNodeIds(adaptor);

   checkArcIds(adaptor);

   checkGraphNodeMap(adaptor);

   checkGraphArcMap(adaptor);

   // Check the conversion of nodes and arcs

   Digraph::Node nd = n3;

   nd = n3;

   Adaptor::Node na = n1;

   na = n2;

   Digraph::Arc ad = a3;

   ad = a3;

   Adaptor::Arc aa = a1;

   aa = a2;

 }

 void checkFilterNodes1() {

   // Check concepts

   checkConcept<concepts::Digraph, FilterNodes<concepts::Digraph> >();

   checkConcept<concepts::Digraph, FilterNodes<ListDigraph> >();

   checkConcept<concepts::AlterableDigraphComponent<>,

                FilterNodes<ListDigraph> >();

   checkConcept<concepts::ExtendableDigraphComponent<>,

                FilterNodes<ListDigraph> >();

   checkConcept<concepts::ErasableDigraphComponent<>,

                FilterNodes<ListDigraph> >();

   checkConcept<concepts::ClearableDigraphComponent<>,

                FilterNodes<ListDigraph> >();

   // Create a digraph and an adaptor

   typedef ListDigraph Digraph;

   typedef Digraph::NodeMap<bool> NodeFilter;

   typedef FilterNodes<Digraph, NodeFilter> Adaptor;

   Digraph digraph;

   NodeFilter node_filter(digraph);

   Adaptor adaptor(digraph, node_filter);

   // Add nodes and arcs to the original digraph and the adaptor

   Digraph::Node n1 = digraph.addNode();

   Digraph::Node n2 = digraph.addNode();

   Adaptor::Node n3 = adaptor.addNode();

   node_filter[n1] = node_filter[n2] = node_filter[n3] = true;

   Digraph::Arc a1 = digraph.addArc(n1, n2);

   Digraph::Arc a2 = digraph.addArc(n1, n3);

   Adaptor::Arc a3 = adaptor.addArc(n2, n3);

   checkGraphNodeList(adaptor, 3);

   checkGraphArcList(adaptor, 3);

   checkGraphConArcList(adaptor, 3);

   checkGraphOutArcList(adaptor, n1, 2);

   checkGraphOutArcList(adaptor, n2, 1);

   checkGraphOutArcList(adaptor, n3, 0);

   checkGraphInArcList(adaptor, n1, 0);

   checkGraphInArcList(adaptor, n2, 1);

   checkGraphInArcList(adaptor, n3, 2);

   checkNodeIds(adaptor);

   checkArcIds(adaptor);

   checkGraphNodeMap(adaptor);

   checkGraphArcMap(adaptor);

   // Hide a node

   adaptor.status(n1, false);

   adaptor.disable(n3);

   if (!adaptor.status(n3)) adaptor.enable(n3);

   checkGraphNodeList(adaptor, 2);

   checkGraphArcList(adaptor, 1);

   checkGraphConArcList(adaptor, 1);

   checkGraphOutArcList(adaptor, n2, 1);

   checkGraphOutArcList(adaptor, n3, 0);

   checkGraphInArcList(adaptor, n2, 0);

   checkGraphInArcList(adaptor, n3, 1);

   checkNodeIds(adaptor);

   checkArcIds(adaptor);

   checkGraphNodeMap(adaptor);

   checkGraphArcMap(adaptor);

   // Hide all nodes

   node_filter[n1] = node_filter[n2] = node_filter[n3] = false;

   checkGraphNodeList(adaptor, 0);

   checkGraphArcList(adaptor, 0);

   checkGraphConArcList(adaptor, 0);

   checkNodeIds(adaptor);

   checkArcIds(adaptor);

   checkGraphNodeMap(adaptor);

   checkGraphArcMap(adaptor);

   // Check the conversion of nodes and arcs

   Digraph::Node nd = n3;

   nd = n3;

   Adaptor::Node na = n1;

   na = n2;

   Digraph::Arc ad = a3;

   ad = a3;

   Adaptor::Arc aa = a1;

   aa = a2;

 }

 void checkFilterArcs() {

   // Check concepts

   checkConcept<concepts::Digraph, FilterArcs<concepts::Digraph> >();

   checkConcept<concepts::Digraph, FilterArcs<ListDigraph> >();

   checkConcept<concepts::AlterableDigraphComponent<>,

                FilterArcs<ListDigraph> >();

   checkConcept<concepts::ExtendableDigraphComponent<>,

                FilterArcs<ListDigraph> >();

   checkConcept<concepts::ErasableDigraphComponent<>,

                FilterArcs<ListDigraph> >();

   checkConcept<concepts::ClearableDigraphComponent<>,

                FilterArcs<ListDigraph> >();

   // Create a digraph and an adaptor

   typedef ListDigraph Digraph;

   typedef Digraph::ArcMap<bool> ArcFilter;

   typedef FilterArcs<Digraph, ArcFilter> Adaptor;

   Digraph digraph;

   ArcFilter arc_filter(digraph);

   Adaptor adaptor(digraph, arc_filter);

   // Add nodes and arcs to the original digraph and the adaptor

   Digraph::Node n1 = digraph.addNode();

   Digraph::Node n2 = digraph.addNode();

   Adaptor::Node n3 = adaptor.addNode();

   Digraph::Arc a1 = digraph.addArc(n1, n2);

   Digraph::Arc a2 = digraph.addArc(n1, n3);

   Adaptor::Arc a3 = adaptor.addArc(n2, n3);

   arc_filter[a1] = arc_filter[a2] = arc_filter[a3] = true;

   checkGraphNodeList(adaptor, 3);

   checkGraphArcList(adaptor, 3);

   checkGraphConArcList(adaptor, 3);

   checkGraphOutArcList(adaptor, n1, 2);

   checkGraphOutArcList(adaptor, n2, 1);

   checkGraphOutArcList(adaptor, n3, 0);

   checkGraphInArcList(adaptor, n1, 0);

   checkGraphInArcList(adaptor, n2, 1);

   checkGraphInArcList(adaptor, n3, 2);

   checkNodeIds(adaptor);

   checkArcIds(adaptor);

   checkGraphNodeMap(adaptor);

   checkGraphArcMap(adaptor);

   // Hide an arc

   adaptor.status(a2, false);

   adaptor.disable(a3);

   if (!adaptor.status(a3)) adaptor.enable(a3);

   checkGraphNodeList(adaptor, 3);

   checkGraphArcList(adaptor, 2);

   checkGraphConArcList(adaptor, 2);

   checkGraphOutArcList(adaptor, n1, 1);

   checkGraphOutArcList(adaptor, n2, 1);

   checkGraphOutArcList(adaptor, n3, 0);

   checkGraphInArcList(adaptor, n1, 0);

   checkGraphInArcList(adaptor, n2, 1);

   checkGraphInArcList(adaptor, n3, 1);

   checkNodeIds(adaptor);

   checkArcIds(adaptor);

   checkGraphNodeMap(adaptor);

   checkGraphArcMap(adaptor);

   // Hide all arcs

   arc_filter[a1] = arc_filter[a2] = arc_filter[a3] = false;

   checkGraphNodeList(adaptor, 3);

   checkGraphArcList(adaptor, 0);

   checkGraphConArcList(adaptor, 0);

   checkNodeIds(adaptor);

   checkArcIds(adaptor);

   checkGraphNodeMap(adaptor);

   checkGraphArcMap(adaptor);

   // Check the conversion of nodes and arcs

   Digraph::Node nd = n3;

   nd = n3;

   Adaptor::Node na = n1;

   na = n2;

   Digraph::Arc ad = a3;

   ad = a3;

   Adaptor::Arc aa = a1;

   aa = a2;

 }

 void checkUndirector() {

   // Check concepts

   checkConcept<concepts::Graph, Undirector<concepts::Digraph> >();

   checkConcept<concepts::Graph, Undirector<ListDigraph> >();

   checkConcept<concepts::AlterableGraphComponent<>,

                Undirector<ListDigraph> >();

   checkConcept<concepts::ExtendableGraphComponent<>,

                Undirector<ListDigraph> >();

   checkConcept<concepts::ErasableGraphComponent<>,

                Undirector<ListDigraph> >();

   checkConcept<concepts::ClearableGraphComponent<>,

                Undirector<ListDigraph> >();

   // Create a digraph and an adaptor

   typedef ListDigraph Digraph;

   typedef Undirector<Digraph> Adaptor;

   Digraph digraph;

   Adaptor adaptor(digraph);

   // Add nodes and arcs/edges to the original digraph and the adaptor

   Digraph::Node n1 = digraph.addNode();

   Digraph::Node n2 = digraph.addNode();

   Adaptor::Node n3 = adaptor.addNode();

   Digraph::Arc a1 = digraph.addArc(n1, n2);

   Digraph::Arc a2 = digraph.addArc(n1, n3);

   Adaptor::Edge e3 = adaptor.addEdge(n2, n3);

   // Check the original digraph

   checkGraphNodeList(digraph, 3);

   checkGraphArcList(digraph, 3);

   checkGraphConArcList(digraph, 3);

   checkGraphOutArcList(digraph, n1, 2);

   checkGraphOutArcList(digraph, n2, 1);

   checkGraphOutArcList(digraph, n3, 0);

   checkGraphInArcList(digraph, n1, 0);

   checkGraphInArcList(digraph, n2, 1);

   checkGraphInArcList(digraph, n3, 2);

   checkNodeIds(digraph);

   checkArcIds(digraph);

   checkGraphNodeMap(digraph);

   checkGraphArcMap(digraph);

   // Check the adaptor

   checkGraphNodeList(adaptor, 3);

   checkGraphArcList(adaptor, 6);

   checkGraphEdgeList(adaptor, 3);

   checkGraphConArcList(adaptor, 6);

   checkGraphConEdgeList(adaptor, 3);

   checkGraphIncEdgeArcLists(adaptor, n1, 2);

   checkGraphIncEdgeArcLists(adaptor, n2, 2);

   checkGraphIncEdgeArcLists(adaptor, n3, 2);

   checkNodeIds(adaptor);

   checkArcIds(adaptor);

   checkEdgeIds(adaptor);

   checkGraphNodeMap(adaptor);

   checkGraphArcMap(adaptor);

   checkGraphEdgeMap(adaptor);

   // Check the edges of the adaptor

   for (Adaptor::EdgeIt e(adaptor); e != INVALID; ++e) {

     check(adaptor.u(e) == digraph.source(e), "Wrong undir");

     check(adaptor.v(e) == digraph.target(e), "Wrong undir");

   }

   // Check CombinedArcMap

   typedef Adaptor::CombinedArcMap

     <Digraph::ArcMap<int>, Digraph::ArcMap<int> > IntCombinedMap;

   typedef Adaptor::CombinedArcMap

     <Digraph::ArcMap<bool>, Digraph::ArcMap<bool> > BoolCombinedMap;

   checkConcept<concepts::ReferenceMap<Adaptor::Arc, int, int&, const int&>,

     IntCombinedMap>();

   checkConcept<concepts::ReferenceMap<Adaptor::Arc, bool, bool&, const bool&>,

     BoolCombinedMap>();

   Digraph::ArcMap<int> fw_map(digraph), bk_map(digraph);

   for (Digraph::ArcIt a(digraph); a != INVALID; ++a) {

     fw_map[a] = digraph.id(a);

     bk_map[a] = -digraph.id(a);

   }

   Adaptor::CombinedArcMap<Digraph::ArcMap<int>, Digraph::ArcMap<int> >

     comb_map(fw_map, bk_map);

   for (Adaptor::ArcIt a(adaptor); a != INVALID; ++a) {

     if (adaptor.source(a) == digraph.source(a)) {

       check(comb_map[a] == fw_map[a], "Wrong combined map");

     } else {

       check(comb_map[a] == bk_map[a], "Wrong combined map");

     }

   }

   // Check the conversion of nodes and arcs/edges

   Digraph::Node nd = n3;

   nd = n3;

   Adaptor::Node na = n1;

   na = n2;

   Digraph::Arc ad = e3;

   ad = e3;

   Adaptor::Edge ea = a1;

   ea = a2;

 }

 void checkResidualDigraph() {

   // Check concepts

   checkConcept<concepts::Digraph, ResidualDigraph<concepts::Digraph> >();

   checkConcept<concepts::Digraph, ResidualDigraph<ListDigraph> >();

   // Create a digraph and an adaptor

   typedef ListDigraph Digraph;

   typedef Digraph::ArcMap<int> IntArcMap;

   typedef ResidualDigraph<Digraph, IntArcMap> Adaptor;

   Digraph digraph;

   IntArcMap capacity(digraph), flow(digraph);

   Adaptor adaptor(digraph, capacity, flow);

   Digraph::Node n1 = digraph.addNode();

   Digraph::Node n2 = digraph.addNode();

   Digraph::Node n3 = digraph.addNode();

   Digraph::Node n4 = digraph.addNode();

   Digraph::Arc a1 = digraph.addArc(n1, n2);

   Digraph::Arc a2 = digraph.addArc(n1, n3);

   Digraph::Arc a3 = digraph.addArc(n1, n4);

   Digraph::Arc a4 = digraph.addArc(n2, n3);

   Digraph::Arc a5 = digraph.addArc(n2, n4);

   Digraph::Arc a6 = digraph.addArc(n3, n4);

   capacity[a1] = 8;

   capacity[a2] = 6;

   capacity[a3] = 4;

   capacity[a4] = 4;

   capacity[a5] = 6;

   capacity[a6] = 10;

   // Check the adaptor with various flow values

   for (Digraph::ArcIt a(digraph); a != INVALID; ++a) {

     flow[a] = 0;

   }

   checkGraphNodeList(adaptor, 4);

   checkGraphArcList(adaptor, 6);

   checkGraphConArcList(adaptor, 6);

   checkGraphOutArcList(adaptor, n1, 3);

   checkGraphOutArcList(adaptor, n2, 2);

   checkGraphOutArcList(adaptor, n3, 1);

   checkGraphOutArcList(adaptor, n4, 0);

   checkGraphInArcList(adaptor, n1, 0);

   checkGraphInArcList(adaptor, n2, 1);

   checkGraphInArcList(adaptor, n3, 2);

   checkGraphInArcList(adaptor, n4, 3);

   for (Digraph::ArcIt a(digraph); a != INVALID; ++a) {

     flow[a] = capacity[a] / 2;

   }

   checkGraphNodeList(adaptor, 4);

   checkGraphArcList(adaptor, 12);

   checkGraphConArcList(adaptor, 12);

   checkGraphOutArcList(adaptor, n1, 3);

   checkGraphOutArcList(adaptor, n2, 3);

   checkGraphOutArcList(adaptor, n3, 3);

   checkGraphOutArcList(adaptor, n4, 3);

   checkGraphInArcList(adaptor, n1, 3);

   checkGraphInArcList(adaptor, n2, 3);

   checkGraphInArcList(adaptor, n3, 3);

   checkGraphInArcList(adaptor, n4, 3);

   checkNodeIds(adaptor);

   checkArcIds(adaptor);

   checkGraphNodeMap(adaptor);

   checkGraphArcMap(adaptor);

   for (Digraph::ArcIt a(digraph); a != INVALID; ++a) {

     flow[a] = capacity[a];

   }

   checkGraphNodeList(adaptor, 4);

   checkGraphArcList(adaptor, 6);

   checkGraphConArcList(adaptor, 6);

   checkGraphOutArcList(adaptor, n1, 0);

   checkGraphOutArcList(adaptor, n2, 1);

   checkGraphOutArcList(adaptor, n3, 2);

   checkGraphOutArcList(adaptor, n4, 3);

   checkGraphInArcList(adaptor, n1, 3);

   checkGraphInArcList(adaptor, n2, 2);

   checkGraphInArcList(adaptor, n3, 1);

   checkGraphInArcList(adaptor, n4, 0);

   // Saturate all backward arcs

   // (set the flow to zero on all forward arcs)

   for (Adaptor::ArcIt a(adaptor); a != INVALID; ++a) {

     if (adaptor.backward(a))

       adaptor.augment(a, adaptor.residualCapacity(a));

   }

   checkGraphNodeList(adaptor, 4);

   checkGraphArcList(adaptor, 6);

   checkGraphConArcList(adaptor, 6);

   checkGraphOutArcList(adaptor, n1, 3);

   checkGraphOutArcList(adaptor, n2, 2);

   checkGraphOutArcList(adaptor, n3, 1);

   checkGraphOutArcList(adaptor, n4, 0);

   checkGraphInArcList(adaptor, n1, 0);

   checkGraphInArcList(adaptor, n2, 1);

   checkGraphInArcList(adaptor, n3, 2);

   checkGraphInArcList(adaptor, n4, 3);

   // Find maximum flow by augmenting along shortest paths

   int flow_value = 0;

   Adaptor::ResidualCapacity res_cap(adaptor);

   while (true) {

     Bfs<Adaptor> bfs(adaptor);

     bfs.run(n1, n4);

     if (!bfs.reached(n4)) break;

     Path<Adaptor> p = bfs.path(n4);

     int min = std::numeric_limits<int>::max();

     for (Path<Adaptor>::ArcIt a(p); a != INVALID; ++a) {

       if (res_cap[a] < min) min = res_cap[a];

     }

     for (Path<Adaptor>::ArcIt a(p); a != INVALID; ++a) {

       adaptor.augment(a, min);

     }

     flow_value += min;

   }

   check(flow_value == 18, "Wrong flow with res graph adaptor");

   // Check forward() and backward()

   for (Adaptor::ArcIt a(adaptor); a != INVALID; ++a) {

     check(adaptor.forward(a) != adaptor.backward(a),

           "Wrong forward() or backward()");

     check((adaptor.forward(a) && adaptor.forward(Digraph::Arc(a)) == a) ||

           (adaptor.backward(a) && adaptor.backward(Digraph::Arc(a)) == a),

           "Wrong forward() or backward()");

   }

   // Check the conversion of nodes and arcs

   Digraph::Node nd = Adaptor::NodeIt(adaptor);

   nd = ++Adaptor::NodeIt(adaptor);

   Adaptor::Node na = n1;

   na = n2;

   Digraph::Arc ad = Adaptor::ArcIt(adaptor);

   ad = ++Adaptor::ArcIt(adaptor);

 }

 void checkSplitNodes() {

   // Check concepts

   checkConcept<concepts::Digraph, SplitNodes<concepts::Digraph> >();

   checkConcept<concepts::Digraph, SplitNodes<ListDigraph> >();

   // Create a digraph and an adaptor

   typedef ListDigraph Digraph;

   typedef SplitNodes<Digraph> Adaptor;

   Digraph digraph;

   Adaptor adaptor(digraph);

   Digraph::Node n1 = digraph.addNode();

   Digraph::Node n2 = digraph.addNode();

   Digraph::Node n3 = digraph.addNode();

   Digraph::Arc a1 = digraph.addArc(n1, n2);

   Digraph::Arc a2 = digraph.addArc(n1, n3);

   Digraph::Arc a3 = digraph.addArc(n2, n3);

   checkGraphNodeList(adaptor, 6);

   checkGraphArcList(adaptor, 6);

   checkGraphConArcList(adaptor, 6);

   checkGraphOutArcList(adaptor, adaptor.inNode(n1), 1);

   checkGraphOutArcList(adaptor, adaptor.outNode(n1), 2);

   checkGraphOutArcList(adaptor, adaptor.inNode(n2), 1);

   checkGraphOutArcList(adaptor, adaptor.outNode(n2), 1);

   checkGraphOutArcList(adaptor, adaptor.inNode(n3), 1);

   checkGraphOutArcList(adaptor, adaptor.outNode(n3), 0);

   checkGraphInArcList(adaptor, adaptor.inNode(n1), 0);

   checkGraphInArcList(adaptor, adaptor.outNode(n1), 1);

   checkGraphInArcList(adaptor, adaptor.inNode(n2), 1);

   checkGraphInArcList(adaptor, adaptor.outNode(n2), 1);

   checkGraphInArcList(adaptor, adaptor.inNode(n3), 2);

   checkGraphInArcList(adaptor, adaptor.outNode(n3), 1);

   checkNodeIds(adaptor);

   checkArcIds(adaptor);

   checkGraphNodeMap(adaptor);

   checkGraphArcMap(adaptor);

   // Check split

   for (Adaptor::ArcIt a(adaptor); a != INVALID; ++a) {

     if (adaptor.origArc(a)) {

       Digraph::Arc oa = a;

       check(adaptor.source(a) == adaptor.outNode(digraph.source(oa)),

             "Wrong split");

       check(adaptor.target(a) == adaptor.inNode(digraph.target(oa)),

             "Wrong split");

     } else {

       Digraph::Node on = a;

       check(adaptor.source(a) == adaptor.inNode(on), "Wrong split");

       check(adaptor.target(a) == adaptor.outNode(on), "Wrong split");

     }

   }

   // Check combined node map

   typedef Adaptor::CombinedNodeMap

     <Digraph::NodeMap<int>, Digraph::NodeMap<int> > IntCombinedNodeMap;

   typedef Adaptor::CombinedNodeMap

     <Digraph::NodeMap<bool>, Digraph::NodeMap<bool> > BoolCombinedNodeMap;

   checkConcept<concepts::ReferenceMap<Adaptor::Node, int, int&, const int&>,

     IntCombinedNodeMap>();

 //checkConcept<concepts::ReferenceMap<Adaptor::Node, bool, bool&, const bool&>,

 //  BoolCombinedNodeMap>();

   checkConcept<concepts::ReadWriteMap<Adaptor::Node, bool>,

     BoolCombinedNodeMap>();

   Digraph::NodeMap<int> in_map(digraph), out_map(digraph);

   for (Digraph::NodeIt n(digraph); n != INVALID; ++n) {

     in_map[n] = digraph.id(n);

     out_map[n] = -digraph.id(n);

   }

   Adaptor::CombinedNodeMap<Digraph::NodeMap<int>, Digraph::NodeMap<int> >

     node_map(in_map, out_map);

   for (Adaptor::NodeIt n(adaptor); n != INVALID; ++n) {

     if (adaptor.inNode(n)) {

       check(node_map[n] == in_map[n], "Wrong combined node map");

     } else {

       check(node_map[n] == out_map[n], "Wrong combined node map");

     }

   }

   // Check combined arc map

   typedef Adaptor::CombinedArcMap

     <Digraph::ArcMap<int>, Digraph::NodeMap<int> > IntCombinedArcMap;

   typedef Adaptor::CombinedArcMap

     <Digraph::ArcMap<bool>, Digraph::NodeMap<bool> > BoolCombinedArcMap;

   checkConcept<concepts::ReferenceMap<Adaptor::Arc, int, int&, const int&>,

     IntCombinedArcMap>();

 //checkConcept<concepts::ReferenceMap<Adaptor::Arc, bool, bool&, const bool&>,

 //  BoolCombinedArcMap>();

   checkConcept<concepts::ReadWriteMap<Adaptor::Arc, bool>,

     BoolCombinedArcMap>();

   Digraph::ArcMap<int> a_map(digraph);

   for (Digraph::ArcIt a(digraph); a != INVALID; ++a) {

     a_map[a] = digraph.id(a);

   }

   Adaptor::CombinedArcMap<Digraph::ArcMap<int>, Digraph::NodeMap<int> >

     arc_map(a_map, out_map);

   for (Digraph::ArcIt a(digraph); a != INVALID; ++a) {

     check(arc_map[adaptor.arc(a)] == a_map[a],  "Wrong combined arc map");

   }

   for (Digraph::NodeIt n(digraph); n != INVALID; ++n) {

     check(arc_map[adaptor.arc(n)] == out_map[n],  "Wrong combined arc map");

   }

   // Check the conversion of nodes

   Digraph::Node nd = adaptor.inNode(n1);

   check (nd == n1, "Wrong node conversion");

   nd = adaptor.outNode(n2);

   check (nd == n2, "Wrong node conversion");

 }

 void checkSubGraph() {

   // Check concepts

   checkConcept<concepts::Graph, SubGraph<concepts::Graph> >();

   checkConcept<concepts::Graph, SubGraph<ListGraph> >();

   checkConcept<concepts::AlterableGraphComponent<>,

                SubGraph<ListGraph> >();

   checkConcept<concepts::ExtendableGraphComponent<>,

                SubGraph<ListGraph> >();

   checkConcept<concepts::ErasableGraphComponent<>,

                SubGraph<ListGraph> >();

   checkConcept<concepts::ClearableGraphComponent<>,

                SubGraph<ListGraph> >();

   // Create a graph and an adaptor

   typedef ListGraph Graph;

   typedef Graph::NodeMap<bool> NodeFilter;

   typedef Graph::EdgeMap<bool> EdgeFilter;

   typedef SubGraph<Graph, NodeFilter, EdgeFilter> Adaptor;

   Graph graph;

   NodeFilter node_filter(graph);

   EdgeFilter edge_filter(graph);

   Adaptor adaptor(graph, node_filter, edge_filter);

   // Add nodes and edges to the original graph and the adaptor

   Graph::Node n1 = graph.addNode();

   Graph::Node n2 = graph.addNode();

   Adaptor::Node n3 = adaptor.addNode();

   Adaptor::Node n4 = adaptor.addNode();

   node_filter[n1] = node_filter[n2] = node_filter[n3] = node_filter[n4] = true;

   Graph::Edge e1 = graph.addEdge(n1, n2);

   Graph::Edge e2 = graph.addEdge(n1, n3);

   Adaptor::Edge e3 = adaptor.addEdge(n2, n3);

   Adaptor::Edge e4 = adaptor.addEdge(n3, n4);

   edge_filter[e1] = edge_filter[e2] = edge_filter[e3] = edge_filter[e4] = true;

   checkGraphNodeList(adaptor, 4);

   checkGraphArcList(adaptor, 8);

   checkGraphEdgeList(adaptor, 4);

   checkGraphConArcList(adaptor, 8);

   checkGraphConEdgeList(adaptor, 4);

   checkGraphIncEdgeArcLists(adaptor, n1, 2);

   checkGraphIncEdgeArcLists(adaptor, n2, 2);

   checkGraphIncEdgeArcLists(adaptor, n3, 3);

   checkGraphIncEdgeArcLists(adaptor, n4, 1);

   checkNodeIds(adaptor);

   checkArcIds(adaptor);

   checkEdgeIds(adaptor);

   checkGraphNodeMap(adaptor);

   checkGraphArcMap(adaptor);

   checkGraphEdgeMap(adaptor);

   // Hide an edge

   adaptor.status(e2, false);

   adaptor.disable(e3);

   if (!adaptor.status(e3)) adaptor.enable(e3);

   checkGraphNodeList(adaptor, 4);

   checkGraphArcList(adaptor, 6);

   checkGraphEdgeList(adaptor, 3);

   checkGraphConArcList(adaptor, 6);

   checkGraphConEdgeList(adaptor, 3);

   checkGraphIncEdgeArcLists(adaptor, n1, 1);

   checkGraphIncEdgeArcLists(adaptor, n2, 2);

   checkGraphIncEdgeArcLists(adaptor, n3, 2);

   checkGraphIncEdgeArcLists(adaptor, n4, 1);

   checkNodeIds(adaptor);

   checkArcIds(adaptor);

   checkEdgeIds(adaptor);

   checkGraphNodeMap(adaptor);

   checkGraphArcMap(adaptor);

   checkGraphEdgeMap(adaptor);

   // Hide a node

   adaptor.status(n1, false);

   adaptor.disable(n3);

   if (!adaptor.status(n3)) adaptor.enable(n3);

   checkGraphNodeList(adaptor, 3);

   checkGraphArcList(adaptor, 4);

   checkGraphEdgeList(adaptor, 2);

   checkGraphConArcList(adaptor, 4);

   checkGraphConEdgeList(adaptor, 2);

   checkGraphIncEdgeArcLists(adaptor, n2, 1);

   checkGraphIncEdgeArcLists(adaptor, n3, 2);

   checkGraphIncEdgeArcLists(adaptor, n4, 1);

   checkNodeIds(adaptor);

   checkArcIds(adaptor);

   checkEdgeIds(adaptor);

   checkGraphNodeMap(adaptor);

   checkGraphArcMap(adaptor);

   checkGraphEdgeMap(adaptor);

   // Hide all nodes and edges

   node_filter[n1] = node_filter[n2] = node_filter[n3] = node_filter[n4] = false;

   edge_filter[e1] = edge_filter[e2] = edge_filter[e3] = edge_filter[e4] = false;

   checkGraphNodeList(adaptor, 0);

   checkGraphArcList(adaptor, 0);

   checkGraphEdgeList(adaptor, 0);

   checkGraphConArcList(adaptor, 0);

   checkGraphConEdgeList(adaptor, 0);

   checkNodeIds(adaptor);

   checkArcIds(adaptor);

   checkEdgeIds(adaptor);

   checkGraphNodeMap(adaptor);

   checkGraphArcMap(adaptor);

   checkGraphEdgeMap(adaptor);

   // Check the conversion of nodes and edges

   Graph::Node ng = n3;

   ng = n4;

   Adaptor::Node na = n1;

   na = n2;

   Graph::Edge eg = e3;

   eg = e4;

   Adaptor::Edge ea = e1;

   ea = e2;

 }

 void checkFilterNodes2() {

   // Check concepts

   checkConcept<concepts::Graph, FilterNodes<concepts::Graph> >();

   checkConcept<concepts::Graph, FilterNodes<ListGraph> >();

   checkConcept<concepts::AlterableGraphComponent<>,

                FilterNodes<ListGraph> >();

   checkConcept<concepts::ExtendableGraphComponent<>,

                FilterNodes<ListGraph> >();

   checkConcept<concepts::ErasableGraphComponent<>,

                FilterNodes<ListGraph> >();

   checkConcept<concepts::ClearableGraphComponent<>,

                FilterNodes<ListGraph> >();

   // Create a graph and an adaptor

   typedef ListGraph Graph;

   typedef Graph::NodeMap<bool> NodeFilter;

   typedef FilterNodes<Graph, NodeFilter> Adaptor;

   // Add nodes and edges to the original graph and the adaptor

   Graph graph;

   NodeFilter node_filter(graph);

   Adaptor adaptor(graph, node_filter);

   Graph::Node n1 = graph.addNode();

   Graph::Node n2 = graph.addNode();

   Adaptor::Node n3 = adaptor.addNode();

   Adaptor::Node n4 = adaptor.addNode();

   node_filter[n1] = node_filter[n2] = node_filter[n3] = node_filter[n4] = true;

   Graph::Edge e1 = graph.addEdge(n1, n2);

   Graph::Edge e2 = graph.addEdge(n1, n3);

   Adaptor::Edge e3 = adaptor.addEdge(n2, n3);

   Adaptor::Edge e4 = adaptor.addEdge(n3, n4);

   checkGraphNodeList(adaptor, 4);

   checkGraphArcList(adaptor, 8);

   checkGraphEdgeList(adaptor, 4);

   checkGraphConArcList(adaptor, 8);

   checkGraphConEdgeList(adaptor, 4);

   checkGraphIncEdgeArcLists(adaptor, n1, 2);

   checkGraphIncEdgeArcLists(adaptor, n2, 2);

   checkGraphIncEdgeArcLists(adaptor, n3, 3);

   checkGraphIncEdgeArcLists(adaptor, n4, 1);

   checkNodeIds(adaptor);

   checkArcIds(adaptor);

   checkEdgeIds(adaptor);

   checkGraphNodeMap(adaptor);

   checkGraphArcMap(adaptor);

   checkGraphEdgeMap(adaptor);

   // Hide a node

   adaptor.status(n1, false);

   adaptor.disable(n3);

   if (!adaptor.status(n3)) adaptor.enable(n3);

   checkGraphNodeList(adaptor, 3);

   checkGraphArcList(adaptor, 4);

   checkGraphEdgeList(adaptor, 2);

   checkGraphConArcList(adaptor, 4);

   checkGraphConEdgeList(adaptor, 2);

   checkGraphIncEdgeArcLists(adaptor, n2, 1);

   checkGraphIncEdgeArcLists(adaptor, n3, 2);

   checkGraphIncEdgeArcLists(adaptor, n4, 1);

   checkNodeIds(adaptor);

   checkArcIds(adaptor);

   checkEdgeIds(adaptor);

   checkGraphNodeMap(adaptor);

   checkGraphArcMap(adaptor);

   checkGraphEdgeMap(adaptor);

   // Hide all nodes

   node_filter[n1] = node_filter[n2] = node_filter[n3] = node_filter[n4] = false;

   checkGraphNodeList(adaptor, 0);

   checkGraphArcList(adaptor, 0);

   checkGraphEdgeList(adaptor, 0);

   checkGraphConArcList(adaptor, 0);

   checkGraphConEdgeList(adaptor, 0);

   checkNodeIds(adaptor);

   checkArcIds(adaptor);

   checkEdgeIds(adaptor);

   checkGraphNodeMap(adaptor);

   checkGraphArcMap(adaptor);

   checkGraphEdgeMap(adaptor);

   // Check the conversion of nodes and edges

   Graph::Node ng = n3;

   ng = n4;

   Adaptor::Node na = n1;

   na = n2;

   Graph::Edge eg = e3;

   eg = e4;

   Adaptor::Edge ea = e1;

   ea = e2;

 }

 void checkFilterEdges() {

   // Check concepts

   checkConcept<concepts::Graph, FilterEdges<concepts::Graph> >();

   checkConcept<concepts::Graph, FilterEdges<ListGraph> >();

   checkConcept<concepts::AlterableGraphComponent<>,

                FilterEdges<ListGraph> >();

   checkConcept<concepts::ExtendableGraphComponent<>,

                FilterEdges<ListGraph> >();

   checkConcept<concepts::ErasableGraphComponent<>,

                FilterEdges<ListGraph> >();

   checkConcept<concepts::ClearableGraphComponent<>,

                FilterEdges<ListGraph> >();

   // Create a graph and an adaptor

   typedef ListGraph Graph;

   typedef Graph::EdgeMap<bool> EdgeFilter;

   typedef FilterEdges<Graph, EdgeFilter> Adaptor;

   Graph graph;

   EdgeFilter edge_filter(graph);

   Adaptor adaptor(graph, edge_filter);

   // Add nodes and edges to the original graph and the adaptor

   Graph::Node n1 = graph.addNode();

   Graph::Node n2 = graph.addNode();

   Adaptor::Node n3 = adaptor.addNode();

   Adaptor::Node n4 = adaptor.addNode();

   Graph::Edge e1 = graph.addEdge(n1, n2);

   Graph::Edge e2 = graph.addEdge(n1, n3);

   Adaptor::Edge e3 = adaptor.addEdge(n2, n3);

   Adaptor::Edge e4 = adaptor.addEdge(n3, n4);

   edge_filter[e1] = edge_filter[e2] = edge_filter[e3] = edge_filter[e4] = true;

   checkGraphNodeList(adaptor, 4);

   checkGraphArcList(adaptor, 8);

   checkGraphEdgeList(adaptor, 4);

   checkGraphConArcList(adaptor, 8);

   checkGraphConEdgeList(adaptor, 4);

   checkGraphIncEdgeArcLists(adaptor, n1, 2);

   checkGraphIncEdgeArcLists(adaptor, n2, 2);

   checkGraphIncEdgeArcLists(adaptor, n3, 3);

   checkGraphIncEdgeArcLists(adaptor, n4, 1);

   checkNodeIds(adaptor);

   checkArcIds(adaptor);

   checkEdgeIds(adaptor);

   checkGraphNodeMap(adaptor);

   checkGraphArcMap(adaptor);

   checkGraphEdgeMap(adaptor);

   // Hide an edge

   adaptor.status(e2, false);

   adaptor.disable(e3);

   if (!adaptor.status(e3)) adaptor.enable(e3);

   checkGraphNodeList(adaptor, 4);

   checkGraphArcList(adaptor, 6);

   checkGraphEdgeList(adaptor, 3);

   checkGraphConArcList(adaptor, 6);

   checkGraphConEdgeList(adaptor, 3);

   checkGraphIncEdgeArcLists(adaptor, n1, 1);

   checkGraphIncEdgeArcLists(adaptor, n2, 2);

   checkGraphIncEdgeArcLists(adaptor, n3, 2);

   checkGraphIncEdgeArcLists(adaptor, n4, 1);

   checkNodeIds(adaptor);

   checkArcIds(adaptor);

   checkEdgeIds(adaptor);

   checkGraphNodeMap(adaptor);

   checkGraphArcMap(adaptor);

   checkGraphEdgeMap(adaptor);

   // Hide all edges

   edge_filter[e1] = edge_filter[e2] = edge_filter[e3] = edge_filter[e4] = false;

   checkGraphNodeList(adaptor, 4);

   checkGraphArcList(adaptor, 0);

   checkGraphEdgeList(adaptor, 0);

   checkGraphConArcList(adaptor, 0);

   checkGraphConEdgeList(adaptor, 0);

   checkNodeIds(adaptor);

   checkArcIds(adaptor);

   checkEdgeIds(adaptor);

   checkGraphNodeMap(adaptor);

   checkGraphArcMap(adaptor);

   checkGraphEdgeMap(adaptor);

   // Check the conversion of nodes and edges

   Graph::Node ng = n3;

   ng = n4;

   Adaptor::Node na = n1;

   na = n2;

   Graph::Edge eg = e3;

   eg = e4;

   Adaptor::Edge ea = e1;

   ea = e2;

 }

 void checkOrienter() {

   // Check concepts

   checkConcept<concepts::Digraph, Orienter<concepts::Graph> >();

   checkConcept<concepts::Digraph, Orienter<ListGraph> >();

   checkConcept<concepts::AlterableDigraphComponent<>,

                Orienter<ListGraph> >();

   checkConcept<concepts::ExtendableDigraphComponent<>,

                Orienter<ListGraph> >();

   checkConcept<concepts::ErasableDigraphComponent<>,

                Orienter<ListGraph> >();

   checkConcept<concepts::ClearableDigraphComponent<>,

                Orienter<ListGraph> >();

   // Create a graph and an adaptor

   typedef ListGraph Graph;

   typedef ListGraph::EdgeMap<bool> DirMap;

   typedef Orienter<Graph> Adaptor;

   Graph graph;

   DirMap dir(graph);

   Adaptor adaptor(graph, dir);

   // Add nodes and edges to the original graph and the adaptor

   Graph::Node n1 = graph.addNode();

   Graph::Node n2 = graph.addNode();

   Adaptor::Node n3 = adaptor.addNode();

   Graph::Edge e1 = graph.addEdge(n1, n2);

   Graph::Edge e2 = graph.addEdge(n1, n3);

   Adaptor::Arc e3 = adaptor.addArc(n2, n3);

   dir[e1] = dir[e2] = dir[e3] = true;

   // Check the original graph

   checkGraphNodeList(graph, 3);

   checkGraphArcList(graph, 6);

   checkGraphConArcList(graph, 6);

   checkGraphEdgeList(graph, 3);

   checkGraphConEdgeList(graph, 3);

   checkGraphIncEdgeArcLists(graph, n1, 2);

   checkGraphIncEdgeArcLists(graph, n2, 2);

   checkGraphIncEdgeArcLists(graph, n3, 2);

   checkNodeIds(graph);

   checkArcIds(graph);

   checkEdgeIds(graph);

   checkGraphNodeMap(graph);

   checkGraphArcMap(graph);

   checkGraphEdgeMap(graph);

   // Check the adaptor

   checkGraphNodeList(adaptor, 3);

   checkGraphArcList(adaptor, 3);

   checkGraphConArcList(adaptor, 3);

   checkGraphOutArcList(adaptor, n1, 2);

   checkGraphOutArcList(adaptor, n2, 1);

   checkGraphOutArcList(adaptor, n3, 0);

   checkGraphInArcList(adaptor, n1, 0);

   checkGraphInArcList(adaptor, n2, 1);

   checkGraphInArcList(adaptor, n3, 2);

   checkNodeIds(adaptor);

   checkArcIds(adaptor);

   checkGraphNodeMap(adaptor);

   checkGraphArcMap(adaptor);

   // Check direction changing

   {

     dir[e1] = true;

     Adaptor::Node u = adaptor.source(e1);

     Adaptor::Node v = adaptor.target(e1);

     dir[e1] = false;

     check (u == adaptor.target(e1), "Wrong dir");

     check (v == adaptor.source(e1), "Wrong dir");

     check ((u == n1 && v == n2) || (u == n2 && v == n1), "Wrong dir");

     dir[e1] = n1 == u;

   }

   {

     dir[e2] = true;

     Adaptor::Node u = adaptor.source(e2);

     Adaptor::Node v = adaptor.target(e2);

     dir[e2] = false;

     check (u == adaptor.target(e2), "Wrong dir");

     check (v == adaptor.source(e2), "Wrong dir");

     check ((u == n1 && v == n3) || (u == n3 && v == n1), "Wrong dir");

     dir[e2] = n3 == u;

   }

   {

     dir[e3] = true;

     Adaptor::Node u = adaptor.source(e3);

     Adaptor::Node v = adaptor.target(e3);

     dir[e3] = false;

     check (u == adaptor.target(e3), "Wrong dir");

     check (v == adaptor.source(e3), "Wrong dir");

     check ((u == n2 && v == n3) || (u == n3 && v == n2), "Wrong dir");

     dir[e3] = n2 == u;

   }

   // Check the adaptor again

   checkGraphNodeList(adaptor, 3);

   checkGraphArcList(adaptor, 3);

   checkGraphConArcList(adaptor, 3);

   checkGraphOutArcList(adaptor, n1, 1);

   checkGraphOutArcList(adaptor, n2, 1);

   checkGraphOutArcList(adaptor, n3, 1);

   checkGraphInArcList(adaptor, n1, 1);

   checkGraphInArcList(adaptor, n2, 1);

   checkGraphInArcList(adaptor, n3, 1);

   checkNodeIds(adaptor);

   checkArcIds(adaptor);

   checkGraphNodeMap(adaptor);

   checkGraphArcMap(adaptor);

   // Check reverseArc()

   adaptor.reverseArc(e2);

   adaptor.reverseArc(e3);

   adaptor.reverseArc(e2);

   checkGraphNodeList(adaptor, 3);

   checkGraphArcList(adaptor, 3);

   checkGraphConArcList(adaptor, 3);

   checkGraphOutArcList(adaptor, n1, 1);

   checkGraphOutArcList(adaptor, n2, 0);

   checkGraphOutArcList(adaptor, n3, 2);

   checkGraphInArcList(adaptor, n1, 1);

   checkGraphInArcList(adaptor, n2, 2);

   checkGraphInArcList(adaptor, n3, 0);

   // Check the conversion of nodes and arcs/edges

   Graph::Node ng = n3;

   ng = n3;

   Adaptor::Node na = n1;

   na = n2;

   Graph::Edge eg = e3;

   eg = e3;

   Adaptor::Arc aa = e1;

   aa = e2;

 }

 void checkCombiningAdaptors() {

   // Create a grid graph

   GridGraph graph(2,2);

   GridGraph::Node n1 = graph(0,0);

   GridGraph::Node n2 = graph(0,1);

   GridGraph::Node n3 = graph(1,0);

   GridGraph::Node n4 = graph(1,1);

   GridGraph::EdgeMap<bool> dir_map(graph);

   dir_map[graph.right(n1)] = graph.u(graph.right(n1)) != n1;

   dir_map[graph.up(n1)] = graph.u(graph.up(n1)) == n1;

   dir_map[graph.left(n4)] = graph.u(graph.left(n4)) == n4;

   dir_map[graph.down(n4)] = graph.u(graph.down(n4)) == n4;

   // Apply several adaptors on the grid graph

   typedef SplitNodes<Orienter< const GridGraph, GridGraph::EdgeMap<bool> > >

     SplitGridGraph;

   typedef Undirector<const SplitGridGraph> USplitGridGraph;

   checkConcept<concepts::Digraph, SplitGridGraph>();

   checkConcept<concepts::Graph, USplitGridGraph>();

   SplitGridGraph adaptor = splitNodes(orienter(graph, dir_map));

   USplitGridGraph uadaptor = undirector(adaptor);

   // Check adaptor

   checkGraphNodeList(adaptor, 8);

   checkGraphArcList(adaptor, 8);

   checkGraphConArcList(adaptor, 8);

   checkGraphOutArcList(adaptor, adaptor.inNode(n1), 1);

   checkGraphOutArcList(adaptor, adaptor.outNode(n1), 1);

   checkGraphOutArcList(adaptor, adaptor.inNode(n2), 1);

   checkGraphOutArcList(adaptor, adaptor.outNode(n2), 0);

   checkGraphOutArcList(adaptor, adaptor.inNode(n3), 1);

   checkGraphOutArcList(adaptor, adaptor.outNode(n3), 1);

   checkGraphOutArcList(adaptor, adaptor.inNode(n4), 1);

   checkGraphOutArcList(adaptor, adaptor.outNode(n4), 2);

   checkGraphInArcList(adaptor, adaptor.inNode(n1), 1);

   checkGraphInArcList(adaptor, adaptor.outNode(n1), 1);

   checkGraphInArcList(adaptor, adaptor.inNode(n2), 2);

   checkGraphInArcList(adaptor, adaptor.outNode(n2), 1);

   checkGraphInArcList(adaptor, adaptor.inNode(n3), 1);

   checkGraphInArcList(adaptor, adaptor.outNode(n3), 1);

   checkGraphInArcList(adaptor, adaptor.inNode(n4), 0);

   checkGraphInArcList(adaptor, adaptor.outNode(n4), 1);

   checkNodeIds(adaptor);

   checkArcIds(adaptor);

   checkGraphNodeMap(adaptor);

   checkGraphArcMap(adaptor);

   // Check uadaptor

   checkGraphNodeList(uadaptor, 8);

   checkGraphEdgeList(uadaptor, 8);

   checkGraphArcList(uadaptor, 16);

   checkGraphConEdgeList(uadaptor, 8);

   checkGraphConArcList(uadaptor, 16);

   checkNodeIds(uadaptor);

   checkEdgeIds(uadaptor);

   checkArcIds(uadaptor);

   checkGraphNodeMap(uadaptor);

   checkGraphEdgeMap(uadaptor);

   checkGraphArcMap(uadaptor);

   checkGraphIncEdgeArcLists(uadaptor, adaptor.inNode(n1), 2);

   checkGraphIncEdgeArcLists(uadaptor, adaptor.outNode(n1), 2);

   checkGraphIncEdgeArcLists(uadaptor, adaptor.inNode(n2), 3);

   checkGraphIncEdgeArcLists(uadaptor, adaptor.outNode(n2), 1);

   checkGraphIncEdgeArcLists(uadaptor, adaptor.inNode(n3), 2);

   checkGraphIncEdgeArcLists(uadaptor, adaptor.outNode(n3), 2);

   checkGraphIncEdgeArcLists(uadaptor, adaptor.inNode(n4), 1);

   checkGraphIncEdgeArcLists(uadaptor, adaptor.outNode(n4), 3);

 }

 int main(int, const char **) {

   // Check the digraph adaptors (using ListDigraph)

   checkReverseDigraph();

   checkSubDigraph();

   checkFilterNodes1();

   checkFilterArcs();

   checkUndirector();

   checkResidualDigraph();

   checkSplitNodes();

   // Check the graph adaptors (using ListGraph)

   checkSubGraph();

   checkFilterNodes2();

   checkFilterEdges();

   checkOrienter();

   // Combine adaptors (using GridGraph)

   checkCombiningAdaptors();

   return 0;

 }