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/* -*- C++ -*-
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*
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* src/lemon/concept/undir_graph_component.h - Part of LEMON, a generic
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* C++ optimization library
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*
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* Copyright (C) 2004 Egervary Jeno Kombinatorikus Optimalizalasi
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* Kutatocsoport (Egervary Combinatorial Optimization Research Group,
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* EGRES).
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*
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* Permission to use, modify and distribute this software is granted
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* provided that this copyright notice appears in all copies. For
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* precise terms see the accompanying LICENSE file.
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*
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* This software is provided "AS IS" with no warranty of any kind,
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* express or implied, and with no claim as to its suitability for any
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* purpose.
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*
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*/
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///\ingroup graph_concepts
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///\file
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///\brief Undirected graphs and components of.
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#ifndef LEMON_CONCEPT_UNDIR_GRAPH_H
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#define LEMON_CONCEPT_UNDIR_GRAPH_H
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#include <lemon/concept/graph_component.h>
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namespace lemon {
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namespace concept {
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/// \addtogroup graph_concepts
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/// @{
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/// Skeleton class which describes an edge with direction in \ref
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/// UndirGraph "undirected graph".
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template <typename UndirGraph>
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class UndirGraphEdge : public UndirGraph::UndirEdge {
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typedef typename UndirGraph::UndirEdge UndirEdge;
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typedef typename UndirGraph::Node Node;
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public:
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/// \e
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UndirGraphEdge() {}
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/// \e
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UndirGraphEdge(const UndirGraphEdge&) {}
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/// \e
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UndirGraphEdge(Invalid) {}
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/// \brief Directed edge from undirected edge and a source node.
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///
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/// Constructs a directed edge from undirected edge and a source node.
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///
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/// \note You have to specify the graph for this constructor.
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UndirGraphEdge(const UndirGraph &g,
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UndirEdge undir_edge, Node n) {
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ignore_unused_variable_warning(undir_edge);
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ignore_unused_variable_warning(g);
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ignore_unused_variable_warning(n);
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}
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/// \e
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UndirGraphEdge& operator=(UndirGraphEdge) { return *this; }
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/// \e
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bool operator==(UndirGraphEdge) const { return true; }
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/// \e
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bool operator!=(UndirGraphEdge) const { return false; }
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/// \e
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bool operator<(UndirGraphEdge) const { return false; }
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template <typename Edge>
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struct Constraints {
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void constraints() {
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const_constraints();
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}
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void const_constraints() const {
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/// \bug This should be is_base_and_derived ...
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UndirEdge ue = e;
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ue = e;
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Edge e_with_source(graph,ue,n);
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ignore_unused_variable_warning(e_with_source);
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}
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Edge e;
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UndirEdge ue;
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UndirGraph graph;
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Node n;
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};
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};
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struct BaseIterableUndirGraphConcept {
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template <typename Graph>
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struct Constraints {
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typedef typename Graph::UndirEdge UndirEdge;
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typedef typename Graph::Edge Edge;
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typedef typename Graph::Node Node;
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void constraints() {
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checkConcept<BaseIterableGraphComponent, Graph>();
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checkConcept<GraphItem<>, UndirEdge>();
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checkConcept<UndirGraphEdge<Graph>, Edge>();
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graph.first(ue);
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graph.next(ue);
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const_constraints();
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}
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void const_constraints() {
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Node n;
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n = graph.target(ue);
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n = graph.source(ue);
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n = graph.oppositeNode(n0, ue);
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bool b;
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b = graph.forward(e);
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ignore_unused_variable_warning(b);
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}
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Graph graph;
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Edge e;
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Node n0;
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UndirEdge ue;
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};
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};
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struct IterableUndirGraphConcept {
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template <typename Graph>
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struct Constraints {
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void constraints() {
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/// \todo we don't need the iterable component to be base iterable
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/// Don't we really???
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//checkConcept< BaseIterableUndirGraphConcept, Graph > ();
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checkConcept<IterableGraphComponent, Graph> ();
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typedef typename Graph::UndirEdge UndirEdge;
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typedef typename Graph::UndirEdgeIt UndirEdgeIt;
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typedef typename Graph::IncEdgeIt IncEdgeIt;
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checkConcept<GraphIterator<Graph, UndirEdge>, UndirEdgeIt>();
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checkConcept<GraphIncIterator<Graph, UndirEdge>, IncEdgeIt>();
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}
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};
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};
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struct MappableUndirGraphConcept {
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template <typename Graph>
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struct Constraints {
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struct Dummy {
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int value;
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Dummy() : value(0) {}
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Dummy(int _v) : value(_v) {}
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};
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void constraints() {
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checkConcept<MappableGraphComponent, Graph>();
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typedef typename Graph::template UndirEdgeMap<int> IntMap;
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checkConcept<GraphMap<Graph, typename Graph::UndirEdge, int>,
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IntMap >();
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typedef typename Graph::template UndirEdgeMap<bool> BoolMap;
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checkConcept<GraphMap<Graph, typename Graph::UndirEdge, bool>,
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BoolMap >();
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typedef typename Graph::template UndirEdgeMap<Dummy> DummyMap;
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checkConcept<GraphMap<Graph, typename Graph::UndirEdge, Dummy>,
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DummyMap >();
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}
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};
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};
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struct ExtendableUndirGraphConcept {
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template <typename Graph>
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struct Constraints {
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void constraints() {
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node_a = graph.addNode();
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uedge = graph.addEdge(node_a, node_b);
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}
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typename Graph::Node node_a, node_b;
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typename Graph::UndirEdge uedge;
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Graph graph;
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};
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};
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struct ErasableUndirGraphConcept {
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template <typename Graph>
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struct Constraints {
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void constraints() {
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graph.erase(n);
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graph.erase(e);
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}
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Graph graph;
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typename Graph::Node n;
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typename Graph::UndirEdge e;
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};
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};
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/// Class describing the concept of Undirected Graphs.
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/// This class describes the common interface of all Undirected
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/// Graphs.
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///
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/// As all concept describing classes it provides only interface
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/// without any sensible implementation. So any algorithm for
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/// undirected graph should compile with this class, but it will not
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/// run properly, of couse.
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///
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/// In LEMON undirected graphs also fulfill the concept of directed
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/// graphs (\ref lemon::concept::Graph "Graph Concept"). For
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/// explanation of this and more see also the page \ref undir_graphs,
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/// a tutorial about undirected graphs.
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class UndirGraph {
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public:
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/// Type describing a node in the graph
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typedef GraphNode Node;
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/// Type describing an undirected edge
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typedef GraphItem<'u'> UndirEdge;
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/// Type describing an UndirEdge with direction
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#ifndef DOXYGEN
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typedef UndirGraphEdge<UndirGraph> Edge;
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#else
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typedef UndirGraphEdge Edge;
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#endif
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/// Iterator type which iterates over all nodes
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#ifndef DOXYGEN
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typedef GraphIterator<UndirGraph, Node> NodeIt;
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#else
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typedef GraphIterator NodeIt;
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#endif
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/// Iterator type which iterates over all undirected edges
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#ifndef DOXYGEN
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typedef GraphIterator<UndirGraph, UndirEdge> UndirEdgeIt;
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#else
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typedef GraphIterator UndirEdgeIt;
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#endif
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/// Iterator type which iterates over all directed edges.
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/// Iterator type which iterates over all edges (each undirected
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/// edge occurs twice with both directions.
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#ifndef DOXYGEN
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typedef GraphIterator<UndirGraph, Edge> EdgeIt;
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#else
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typedef GraphIterator EdgeIt;
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#endif
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/// Iterator of undirected edges incident to a node
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#ifndef DOXYGEN
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typedef GraphIncIterator<UndirGraph, UndirEdge, 'u'> IncEdgeIt;
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#else
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typedef GraphIncIterator IncEdgeIt;
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#endif
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/// Iterator of edges incoming to a node
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#ifndef DOXYGEN
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typedef GraphIncIterator<UndirGraph, Edge, 'i'> InEdgeIt;
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#else
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typedef GraphIncIterator InEdgeIt;
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#endif
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/// Iterator of edges outgoing from a node
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#ifndef DOXYGEN
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typedef GraphIncIterator<UndirGraph, Edge, 'o'> OutEdgeIt;
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#else
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typedef GraphIncIterator OutEdgeIt;
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#endif
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/// NodeMap template
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#ifdef DOXYGEN
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typedef GraphMap NodeMap<T>;
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#endif
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/// UndirEdgeMap template
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#ifdef DOXYGEN
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typedef GraphMap UndirEdgeMap<T>;
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#endif
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/// EdgeMap template
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#ifdef DOXYGEN
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typedef GraphMap EdgeMap<T>;
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#endif
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template <typename T>
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class NodeMap : public GraphMap<UndirGraph, Node, T> {
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typedef GraphMap<UndirGraph, Node, T> Parent;
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public:
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explicit NodeMap(const UndirGraph &g) : Parent(g) {}
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NodeMap(const UndirGraph &g, T t) : Parent(g, t) {}
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};
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template <typename T>
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class UndirEdgeMap : public GraphMap<UndirGraph, UndirEdge, T> {
|
klao@1030
|
322 |
typedef GraphMap<UndirGraph, UndirEdge, T> Parent;
|
klao@1030
|
323 |
public:
|
klao@1030
|
324 |
|
klao@1030
|
325 |
explicit UndirEdgeMap(const UndirGraph &g) : Parent(g) {}
|
klao@1030
|
326 |
UndirEdgeMap(const UndirGraph &g, T t) : Parent(g, t) {}
|
klao@1030
|
327 |
};
|
klao@1030
|
328 |
|
klao@1030
|
329 |
template <typename T>
|
klao@1030
|
330 |
class EdgeMap : public GraphMap<UndirGraph, Edge, T> {
|
klao@1030
|
331 |
typedef GraphMap<UndirGraph, Edge, T> Parent;
|
klao@1030
|
332 |
public:
|
klao@1030
|
333 |
|
klao@1030
|
334 |
explicit EdgeMap(const UndirGraph &g) : Parent(g) {}
|
klao@1030
|
335 |
EdgeMap(const UndirGraph &g, T t) : Parent(g, t) {}
|
klao@1030
|
336 |
};
|
klao@1030
|
337 |
|
klao@1030
|
338 |
/// Is the Edge oriented "forward"?
|
klao@1030
|
339 |
|
klao@1030
|
340 |
/// Returns whether the given directed edge is same orientation as
|
klao@1030
|
341 |
/// the corresponding undirected edge.
|
klao@1030
|
342 |
///
|
klao@1030
|
343 |
/// \todo "What does the direction of an undirected edge mean?"
|
klao@1030
|
344 |
bool forward(Edge) const { return true; }
|
klao@1030
|
345 |
|
klao@1030
|
346 |
/// Opposite node on an edge
|
klao@1030
|
347 |
|
klao@1030
|
348 |
/// \return the opposite of the given Node on the given Edge
|
klao@1030
|
349 |
///
|
klao@1030
|
350 |
/// \todo What should we do if given Node and Edge are not incident?
|
klao@1030
|
351 |
Node oppositeNode(Node, UndirEdge) const { return INVALID; }
|
klao@1030
|
352 |
|
klao@1030
|
353 |
/// First node of the undirected edge.
|
klao@1030
|
354 |
|
klao@1030
|
355 |
/// \return the first node of the given UndirEdge.
|
klao@1030
|
356 |
///
|
klao@1030
|
357 |
/// Naturally undirectected edges don't have direction and thus
|
klao@1030
|
358 |
/// don't have source and target node. But we use these two methods
|
klao@1030
|
359 |
/// to query the two endnodes of the edge. The direction of the edge
|
klao@1030
|
360 |
/// which arises this way is called the inherent direction of the
|
klao@1030
|
361 |
/// undirected edge, and is used to define the "forward" direction
|
klao@1030
|
362 |
/// of the directed versions of the edges.
|
klao@1030
|
363 |
/// \sa forward
|
klao@1030
|
364 |
Node source(UndirEdge) const { return INVALID; }
|
klao@1030
|
365 |
|
klao@1030
|
366 |
/// Second node of the undirected edge.
|
klao@1030
|
367 |
Node target(UndirEdge) const { return INVALID; }
|
klao@1030
|
368 |
|
klao@1030
|
369 |
/// Source node of the directed edge.
|
klao@1030
|
370 |
Node source(Edge) const { return INVALID; }
|
klao@1030
|
371 |
|
klao@1030
|
372 |
/// Target node of the directed edge.
|
klao@1030
|
373 |
Node target(Edge) const { return INVALID; }
|
klao@1030
|
374 |
|
klao@1030
|
375 |
/// First node of the graph
|
klao@1030
|
376 |
|
klao@1030
|
377 |
/// \note This method is part of so called \ref
|
klao@1030
|
378 |
/// developpers_interface "Developpers' interface", so it shouldn't
|
klao@1030
|
379 |
/// be used in an end-user program.
|
klao@1030
|
380 |
void first(Node&) const {}
|
klao@1030
|
381 |
/// Next node of the graph
|
klao@1030
|
382 |
|
klao@1030
|
383 |
/// \note This method is part of so called \ref
|
klao@1030
|
384 |
/// developpers_interface "Developpers' interface", so it shouldn't
|
klao@1030
|
385 |
/// be used in an end-user program.
|
klao@1030
|
386 |
void next(Node&) const {}
|
klao@1030
|
387 |
|
klao@1030
|
388 |
/// First undirected edge of the graph
|
klao@1030
|
389 |
|
klao@1030
|
390 |
/// \note This method is part of so called \ref
|
klao@1030
|
391 |
/// developpers_interface "Developpers' interface", so it shouldn't
|
klao@1030
|
392 |
/// be used in an end-user program.
|
klao@1030
|
393 |
void first(UndirEdge&) const {}
|
klao@1030
|
394 |
/// Next undirected edge of the graph
|
klao@1030
|
395 |
|
klao@1030
|
396 |
/// \note This method is part of so called \ref
|
klao@1030
|
397 |
/// developpers_interface "Developpers' interface", so it shouldn't
|
klao@1030
|
398 |
/// be used in an end-user program.
|
klao@1030
|
399 |
void next(UndirEdge&) const {}
|
klao@1030
|
400 |
|
klao@1030
|
401 |
/// First directed edge of the graph
|
klao@1030
|
402 |
|
klao@1030
|
403 |
/// \note This method is part of so called \ref
|
klao@1030
|
404 |
/// developpers_interface "Developpers' interface", so it shouldn't
|
klao@1030
|
405 |
/// be used in an end-user program.
|
klao@1030
|
406 |
void first(Edge&) const {}
|
klao@1030
|
407 |
/// Next directed edge of the graph
|
klao@1030
|
408 |
|
klao@1030
|
409 |
/// \note This method is part of so called \ref
|
klao@1030
|
410 |
/// developpers_interface "Developpers' interface", so it shouldn't
|
klao@1030
|
411 |
/// be used in an end-user program.
|
klao@1030
|
412 |
void next(Edge&) const {}
|
klao@1030
|
413 |
|
klao@1030
|
414 |
/// First outgoing edge from a given node
|
klao@1030
|
415 |
|
klao@1030
|
416 |
/// \note This method is part of so called \ref
|
klao@1030
|
417 |
/// developpers_interface "Developpers' interface", so it shouldn't
|
klao@1030
|
418 |
/// be used in an end-user program.
|
klao@1030
|
419 |
void firstOut(Edge&, Node) const {}
|
klao@1030
|
420 |
/// Next outgoing edge to a node
|
klao@1030
|
421 |
|
klao@1030
|
422 |
/// \note This method is part of so called \ref
|
klao@1030
|
423 |
/// developpers_interface "Developpers' interface", so it shouldn't
|
klao@1030
|
424 |
/// be used in an end-user program.
|
klao@1030
|
425 |
void nextOut(Edge&) const {}
|
klao@1030
|
426 |
|
klao@1030
|
427 |
/// First incoming edge to a given node
|
klao@1030
|
428 |
|
klao@1030
|
429 |
/// \note This method is part of so called \ref
|
klao@1030
|
430 |
/// developpers_interface "Developpers' interface", so it shouldn't
|
klao@1030
|
431 |
/// be used in an end-user program.
|
klao@1030
|
432 |
void firstIn(Edge&, Node) const {}
|
klao@1030
|
433 |
/// Next incoming edge to a node
|
klao@1030
|
434 |
|
klao@1030
|
435 |
/// \note This method is part of so called \ref
|
klao@1030
|
436 |
/// developpers_interface "Developpers' interface", so it shouldn't
|
klao@1030
|
437 |
/// be used in an end-user program.
|
klao@1030
|
438 |
void nextIn(Edge&) const {}
|
klao@1030
|
439 |
|
klao@1030
|
440 |
|
klao@1158
|
441 |
/// Base node of the iterator
|
klao@1158
|
442 |
///
|
klao@1158
|
443 |
/// Returns the base node (the source in this case) of the iterator
|
klao@1158
|
444 |
Node baseNode(OutEdgeIt e) const {
|
klao@1158
|
445 |
return source(e);
|
klao@1158
|
446 |
}
|
klao@1158
|
447 |
/// Running node of the iterator
|
klao@1158
|
448 |
///
|
klao@1158
|
449 |
/// Returns the running node (the target in this case) of the
|
klao@1158
|
450 |
/// iterator
|
klao@1158
|
451 |
Node runningNode(OutEdgeIt e) const {
|
klao@1158
|
452 |
return target(e);
|
klao@1158
|
453 |
}
|
klao@1158
|
454 |
|
klao@1158
|
455 |
/// Base node of the iterator
|
klao@1158
|
456 |
///
|
klao@1158
|
457 |
/// Returns the base node (the target in this case) of the iterator
|
klao@1158
|
458 |
Node baseNode(InEdgeIt e) const {
|
klao@1158
|
459 |
return target(e);
|
klao@1158
|
460 |
}
|
klao@1158
|
461 |
/// Running node of the iterator
|
klao@1158
|
462 |
///
|
klao@1158
|
463 |
/// Returns the running node (the source in this case) of the
|
klao@1158
|
464 |
/// iterator
|
klao@1158
|
465 |
Node runningNode(InEdgeIt e) const {
|
klao@1158
|
466 |
return source(e);
|
klao@1158
|
467 |
}
|
klao@1158
|
468 |
|
klao@1158
|
469 |
/// Base node of the iterator
|
klao@1158
|
470 |
///
|
klao@1158
|
471 |
/// Returns the base node of the iterator
|
klao@1158
|
472 |
Node baseNode(IncEdgeIt e) const {
|
klao@1158
|
473 |
return INVALID;
|
klao@1158
|
474 |
}
|
klao@1158
|
475 |
/// Running node of the iterator
|
klao@1158
|
476 |
///
|
klao@1158
|
477 |
/// Returns the running node of the iterator
|
klao@1158
|
478 |
Node runningNode(IncEdgeIt e) const {
|
klao@1158
|
479 |
return INVALID;
|
klao@1158
|
480 |
}
|
klao@1158
|
481 |
|
klao@1158
|
482 |
|
klao@1022
|
483 |
template <typename Graph>
|
klao@1022
|
484 |
struct Constraints {
|
klao@1022
|
485 |
void constraints() {
|
klao@1022
|
486 |
checkConcept<BaseIterableUndirGraphConcept, Graph>();
|
klao@1022
|
487 |
checkConcept<IterableUndirGraphConcept, Graph>();
|
klao@1022
|
488 |
checkConcept<MappableUndirGraphConcept, Graph>();
|
klao@1022
|
489 |
}
|
klao@1022
|
490 |
};
|
klao@1022
|
491 |
|
klao@1022
|
492 |
};
|
klao@1022
|
493 |
|
klao@1022
|
494 |
class ExtendableUndirGraph : public UndirGraph {
|
klao@1022
|
495 |
public:
|
klao@1022
|
496 |
|
klao@1022
|
497 |
template <typename Graph>
|
klao@1022
|
498 |
struct Constraints {
|
klao@1022
|
499 |
void constraints() {
|
klao@1022
|
500 |
checkConcept<BaseIterableUndirGraphConcept, Graph>();
|
klao@1022
|
501 |
checkConcept<IterableUndirGraphConcept, Graph>();
|
klao@1022
|
502 |
checkConcept<MappableUndirGraphConcept, Graph>();
|
klao@1022
|
503 |
|
klao@1022
|
504 |
checkConcept<UndirGraph, Graph>();
|
klao@1022
|
505 |
checkConcept<ExtendableUndirGraphConcept, Graph>();
|
klao@1022
|
506 |
checkConcept<ClearableGraphComponent, Graph>();
|
klao@1022
|
507 |
}
|
klao@1022
|
508 |
};
|
klao@1022
|
509 |
|
klao@1022
|
510 |
};
|
klao@1022
|
511 |
|
klao@1022
|
512 |
class ErasableUndirGraph : public ExtendableUndirGraph {
|
klao@1022
|
513 |
public:
|
klao@1022
|
514 |
|
klao@1022
|
515 |
template <typename Graph>
|
klao@1022
|
516 |
struct Constraints {
|
klao@1022
|
517 |
void constraints() {
|
klao@1022
|
518 |
checkConcept<ExtendableUndirGraph, Graph>();
|
klao@1022
|
519 |
checkConcept<ErasableUndirGraphConcept, Graph>();
|
klao@1022
|
520 |
}
|
klao@1022
|
521 |
};
|
klao@1022
|
522 |
|
klao@962
|
523 |
};
|
klao@962
|
524 |
|
klao@1030
|
525 |
/// @}
|
klao@1030
|
526 |
|
klao@962
|
527 |
}
|
klao@962
|
528 |
|
klao@962
|
529 |
}
|
klao@962
|
530 |
|
klao@962
|
531 |
#endif
|