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/* -*- mode: C++; indent-tabs-mode: nil; -*-
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*
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* This file is a part of LEMON, a generic C++ optimization library.
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*
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* Copyright (C) 2003-2008
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* Egervary Jeno Kombinatorikus Optimalizalasi Kutatocsoport
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* (Egervary Research Group on Combinatorial Optimization, EGRES).
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*
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* Permission to use, modify and distribute this software is granted
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* provided that this copyright notice appears in all copies. For
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* precise terms see the accompanying LICENSE file.
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*
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* This software is provided "AS IS" with no warranty of any kind,
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* express or implied, and with no claim as to its suitability for any
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* purpose.
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*
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*/
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#ifndef LEMON_KRUSKAL_H
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#define LEMON_KRUSKAL_H
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#include <algorithm>
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#include <vector>
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#include <lemon/unionfind.h>
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// #include <lemon/graph_utils.h>
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#include <lemon/maps.h>
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// #include <lemon/radix_sort.h>
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#include <lemon/bits/utility.h>
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#include <lemon/bits/traits.h>
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///\ingroup spantree
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///\file
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///\brief Kruskal's algorithm to compute a minimum cost spanning tree
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///
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///Kruskal's algorithm to compute a minimum cost spanning tree.
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///
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namespace lemon {
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namespace _kruskal_bits {
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// Kruskal for directed graphs.
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template <typename Digraph, typename In, typename Out>
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typename disable_if<lemon::UndirectedTagIndicator<Digraph>,
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typename In::value_type::second_type >::type
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kruskal(const Digraph& digraph, const In& in, Out& out,dummy<0> = 0) {
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typedef typename In::value_type::second_type Value;
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typedef typename Digraph::template NodeMap<int> IndexMap;
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typedef typename Digraph::Node Node;
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IndexMap index(digraph);
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UnionFind<IndexMap> uf(index);
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for (typename Digraph::NodeIt it(digraph); it != INVALID; ++it) {
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uf.insert(it);
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}
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Value tree_value = 0;
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for (typename In::const_iterator it = in.begin(); it != in.end(); ++it) {
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if (uf.join(digraph.target(it->first),digraph.source(it->first))) {
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out.set(it->first, true);
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tree_value += it->second;
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}
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else {
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out.set(it->first, false);
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}
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}
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return tree_value;
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}
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// Kruskal for undirected graphs.
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template <typename Graph, typename In, typename Out>
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typename enable_if<lemon::UndirectedTagIndicator<Graph>,
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typename In::value_type::second_type >::type
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kruskal(const Graph& graph, const In& in, Out& out,dummy<1> = 1) {
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typedef typename In::value_type::second_type Value;
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typedef typename Graph::template NodeMap<int> IndexMap;
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typedef typename Graph::Node Node;
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IndexMap index(graph);
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UnionFind<IndexMap> uf(index);
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for (typename Graph::NodeIt it(graph); it != INVALID; ++it) {
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uf.insert(it);
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}
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Value tree_value = 0;
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for (typename In::const_iterator it = in.begin(); it != in.end(); ++it) {
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if (uf.join(graph.u(it->first),graph.v(it->first))) {
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out.set(it->first, true);
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tree_value += it->second;
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}
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else {
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out.set(it->first, false);
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}
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}
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return tree_value;
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}
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template <typename Sequence>
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struct PairComp {
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typedef typename Sequence::value_type Value;
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bool operator()(const Value& left, const Value& right) {
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return left.second < right.second;
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}
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};
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template <typename In, typename Enable = void>
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struct SequenceInputIndicator {
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static const bool value = false;
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};
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template <typename In>
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struct SequenceInputIndicator<In,
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typename exists<typename In::value_type::first_type>::type> {
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static const bool value = true;
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};
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template <typename In, typename Enable = void>
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struct MapInputIndicator {
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static const bool value = false;
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};
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template <typename In>
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struct MapInputIndicator<In,
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typename exists<typename In::Value>::type> {
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static const bool value = true;
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};
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template <typename In, typename Enable = void>
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struct SequenceOutputIndicator {
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static const bool value = false;
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};
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template <typename Out>
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struct SequenceOutputIndicator<Out,
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typename exists<typename Out::value_type>::type> {
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static const bool value = true;
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};
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template <typename Out, typename Enable = void>
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struct MapOutputIndicator {
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static const bool value = false;
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};
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template <typename Out>
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struct MapOutputIndicator<Out,
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typename exists<typename Out::Value>::type> {
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static const bool value = true;
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};
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template <typename In, typename InEnable = void>
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struct KruskalValueSelector {};
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template <typename In>
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struct KruskalValueSelector<In,
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typename enable_if<SequenceInputIndicator<In>, void>::type>
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{
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typedef typename In::value_type::second_type Value;
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};
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template <typename In>
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struct KruskalValueSelector<In,
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typename enable_if<MapInputIndicator<In>, void>::type>
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{
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typedef typename In::Value Value;
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};
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template <typename Graph, typename In, typename Out,
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typename InEnable = void>
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struct KruskalInputSelector {};
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template <typename Graph, typename In, typename Out,
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typename InEnable = void>
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struct KruskalOutputSelector {};
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template <typename Graph, typename In, typename Out>
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struct KruskalInputSelector<Graph, In, Out,
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typename enable_if<SequenceInputIndicator<In>, void>::type >
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{
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typedef typename In::value_type::second_type Value;
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static Value kruskal(const Graph& graph, const In& in, Out& out) {
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return KruskalOutputSelector<Graph, In, Out>::
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kruskal(graph, in, out);
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}
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};
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template <typename Graph, typename In, typename Out>
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struct KruskalInputSelector<Graph, In, Out,
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typename enable_if<MapInputIndicator<In>, void>::type >
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{
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typedef typename In::Value Value;
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static Value kruskal(const Graph& graph, const In& in, Out& out) {
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typedef typename In::Key MapArc;
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typedef typename In::Value Value;
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typedef typename ItemSetTraits<Graph, MapArc>::ItemIt MapArcIt;
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typedef std::vector<std::pair<MapArc, Value> > Sequence;
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Sequence seq;
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for (MapArcIt it(graph); it != INVALID; ++it) {
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seq.push_back(std::make_pair(it, in[it]));
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}
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std::sort(seq.begin(), seq.end(), PairComp<Sequence>());
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return KruskalOutputSelector<Graph, Sequence, Out>::
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kruskal(graph, seq, out);
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}
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};
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template <typename T>
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struct RemoveConst {
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typedef T type;
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};
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template <typename T>
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struct RemoveConst<const T> {
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typedef T type;
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};
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deba@136
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template <typename Graph, typename In, typename Out>
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struct KruskalOutputSelector<Graph, In, Out,
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typename enable_if<SequenceOutputIndicator<Out>, void>::type >
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{
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typedef typename In::value_type::second_type Value;
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static Value kruskal(const Graph& graph, const In& in, Out& out) {
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typedef LoggerBoolMap<typename RemoveConst<Out>::type> Map;
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Map map(out);
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return _kruskal_bits::kruskal(graph, in, map);
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}
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};
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template <typename Graph, typename In, typename Out>
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struct KruskalOutputSelector<Graph, In, Out,
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typename enable_if<MapOutputIndicator<Out>, void>::type >
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{
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typedef typename In::value_type::second_type Value;
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static Value kruskal(const Graph& graph, const In& in, Out& out) {
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return _kruskal_bits::kruskal(graph, in, out);
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}
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};
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}
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/// \ingroup spantree
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///
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kpeter@194
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/// \brief Kruskal algorithm to find a minimum cost spanning tree of
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/// a graph.
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///
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/// This function runs Kruskal's algorithm to find a minimum cost
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/// spanning tree.
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/// Due to some C++ hacking, it accepts various input and output types.
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///
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/// \param g The graph the algorithm runs on.
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/// It can be either \ref concepts::Digraph "directed" or
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/// \ref concepts::Graph "undirected".
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/// If the graph is directed, the algorithm consider it to be
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/// undirected by disregarding the direction of the arcs.
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///
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/// \param in This object is used to describe the arc/edge costs.
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/// It can be one of the following choices.
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/// - An STL compatible 'Forward Container' with
|
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/// <tt>std::pair<GR::Arc,X></tt> or
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kpeter@194
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/// <tt>std::pair<GR::Edge,X></tt> as its <tt>value_type</tt>, where
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/// \c X is the type of the costs. The pairs indicates the arcs/edges
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/// along with the assigned cost. <em>They must be in a
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/// cost-ascending order.</em>
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/// - Any readable arc/edge map. The values of the map indicate the
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/// arc/edge costs.
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///
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/// \retval out Here we also have a choice.
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/// - It can be a writable \c bool arc/edge map. After running the
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/// algorithm it will contain the found minimum cost spanning
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/// tree: the value of an arc/edge will be set to \c true if it belongs
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/// to the tree, otherwise it will be set to \c false. The value of
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kpeter@194
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/// each arc/edge will be set exactly once.
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/// - It can also be an iteraror of an STL Container with
|
kpeter@194
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/// <tt>GR::Arc</tt> or <tt>GR::Edge</tt> as its
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/// <tt>value_type</tt>. The algorithm copies the elements of the
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/// found tree into this sequence. For example, if we know that the
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/// spanning tree of the graph \c g has say 53 arcs, then we can
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/// put its arcs into an STL vector \c tree with a code like this.
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///\code
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alpar@103
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/// std::vector<Arc> tree(53);
|
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/// kruskal(g,cost,tree.begin());
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///\endcode
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alpar@103
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/// Or if we don't know in advance the size of the tree, we can
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alpar@209
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/// write this.
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kpeter@194
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///\code
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kpeter@194
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/// std::vector<Arc> tree;
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alpar@209
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/// kruskal(g,cost,std::back_inserter(tree));
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alpar@103
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///\endcode
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///
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kpeter@194
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/// \return The total cost of the found spanning tree.
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///
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kpeter@194
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/// \warning If Kruskal runs on an be consistent of using the same
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alpar@103
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/// Arc type for input and output.
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alpar@103
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///
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alpar@103
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|
alpar@103
|
307 |
#ifdef DOXYGEN
|
alpar@103
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template <class Graph, class In, class Out>
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alpar@103
|
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Value kruskal(GR const& g, const In& in, Out& out)
|
alpar@209
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310 |
#else
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alpar@103
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template <class Graph, class In, class Out>
|
alpar@209
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inline typename _kruskal_bits::KruskalValueSelector<In>::Value
|
alpar@209
|
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kruskal(const Graph& graph, const In& in, Out& out)
|
alpar@103
|
314 |
#endif
|
alpar@103
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315 |
{
|
alpar@103
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316 |
return _kruskal_bits::KruskalInputSelector<Graph, In, Out>::
|
alpar@103
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317 |
kruskal(graph, in, out);
|
alpar@103
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318 |
}
|
alpar@103
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|
alpar@209
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alpar@209
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|
alpar@103
|
323 |
template <class Graph, class In, class Out>
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alpar@103
|
324 |
inline typename _kruskal_bits::KruskalValueSelector<In>::Value
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alpar@103
|
325 |
kruskal(const Graph& graph, const In& in, const Out& out)
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alpar@103
|
326 |
{
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alpar@103
|
327 |
return _kruskal_bits::KruskalInputSelector<Graph, In, const Out>::
|
alpar@103
|
328 |
kruskal(graph, in, out);
|
alpar@209
|
329 |
}
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alpar@103
|
330 |
|
alpar@103
|
331 |
} //namespace lemon
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alpar@103
|
332 |
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alpar@103
|
333 |
#endif //LEMON_KRUSKAL_H
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