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/* -*- C++ -*-

 *

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

 *

 * Copyright (C) 2003-2008

 * 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.

 *

 */

#ifndef LEMON_KRUSKAL_H

#define LEMON_KRUSKAL_H

#include <algorithm>

#include <vector>

#include <lemon/unionfind.h>

// #include <lemon/graph_utils.h>

#include <lemon/maps.h>

// #include <lemon/radix_sort.h>

#include <lemon/bits/utility.h>

#include <lemon/bits/traits.h>

///\ingroup spantree

///\file

///\brief Kruskal's algorithm to compute a minimum cost tree

///

///Kruskal's algorithm to compute a minimum cost tree.

///

namespace lemon {

  namespace _kruskal_bits {

    // Kruskal for directed graphs.

    template <typename Digraph, typename In, typename Out>

    typename disable_if<lemon::UndirectedTagIndicator<Digraph>,

		       typename In::value_type::second_type >::type

    kruskal(const Digraph& digraph, const In& in, Out& out,dummy<0> = 0) {

      typedef typename In::value_type::second_type Value;

      typedef typename Digraph::template NodeMap<int> IndexMap;

      typedef typename Digraph::Node Node;

      IndexMap index(digraph);

      UnionFind<IndexMap> uf(index);

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

        uf.insert(it);

      }

      Value tree_value = 0;

      for (typename In::const_iterator it = in.begin(); it != in.end(); ++it) {

        if (uf.join(digraph.target(it->first),digraph.source(it->first))) {

          out.set(it->first, true);

          tree_value += it->second;

        }

        else {

          out.set(it->first, false);

        }

      }

      return tree_value;

    }

    // Kruskal for undirected graphs.

    template <typename Graph, typename In, typename Out>

    typename enable_if<lemon::UndirectedTagIndicator<Graph>,

		       typename In::value_type::second_type >::type

    kruskal(const Graph& graph, const In& in, Out& out,dummy<1> = 1) {

      typedef typename In::value_type::second_type Value;

      typedef typename Graph::template NodeMap<int> IndexMap;

      typedef typename Graph::Node Node;

      IndexMap index(graph);

      UnionFind<IndexMap> uf(index);

      for (typename Graph::NodeIt it(graph); it != INVALID; ++it) {

        uf.insert(it);

      }

      Value tree_value = 0;

      for (typename In::const_iterator it = in.begin(); it != in.end(); ++it) {

        if (uf.join(graph.u(it->first),graph.v(it->first))) {

          out.set(it->first, true);

          tree_value += it->second;

        }

        else {

          out.set(it->first, false);

        }

      }

      return tree_value;

    }

    template <typename Sequence>

    struct PairComp {

      typedef typename Sequence::value_type Value;

      bool operator()(const Value& left, const Value& right) {

	return left.second < right.second;

      }

    };

    template <typename In, typename Enable = void>

    struct SequenceInputIndicator {

      static const bool value = false;

    };

    template <typename In>

    struct SequenceInputIndicator<In, 

      typename exists<typename In::value_type::first_type>::type> {

      static const bool value = true;

    };

    template <typename In, typename Enable = void>

    struct MapInputIndicator {

      static const bool value = false;

    };

    template <typename In>

    struct MapInputIndicator<In, 

      typename exists<typename In::Value>::type> {

      static const bool value = true;

    };

    template <typename In, typename Enable = void>

    struct SequenceOutputIndicator {

      static const bool value = false;

    };

    template <typename Out>

    struct SequenceOutputIndicator<Out, 

      typename exists<typename Out::value_type>::type> {

      static const bool value = true;

    };

    template <typename Out, typename Enable = void>

    struct MapOutputIndicator {

      static const bool value = false;

    };

    template <typename Out>

    struct MapOutputIndicator<Out, 

      typename exists<typename Out::Value>::type> {

      static const bool value = true;

    };

    template <typename In, typename InEnable = void>

    struct KruskalValueSelector {};

    template <typename In>

    struct KruskalValueSelector<In,

      typename enable_if<SequenceInputIndicator<In>, void>::type> 

    {

      typedef typename In::value_type::second_type Value;

    };    

    template <typename In>

    struct KruskalValueSelector<In,

      typename enable_if<MapInputIndicator<In>, void>::type> 

    {

      typedef typename In::Value Value;

    };    

    template <typename Graph, typename In, typename Out,

              typename InEnable = void>

    struct KruskalInputSelector {};

    template <typename Graph, typename In, typename Out,

              typename InEnable = void>

    struct KruskalOutputSelector {};

    template <typename Graph, typename In, typename Out>

    struct KruskalInputSelector<Graph, In, Out,

      typename enable_if<SequenceInputIndicator<In>, void>::type > 

    {

      typedef typename In::value_type::second_type Value;

      static Value kruskal(const Graph& graph, const In& in, Out& out) {

        return KruskalOutputSelector<Graph, In, Out>::

          kruskal(graph, in, out);

      }

    };

    template <typename Graph, typename In, typename Out>

    struct KruskalInputSelector<Graph, In, Out,

      typename enable_if<MapInputIndicator<In>, void>::type > 

    {

      typedef typename In::Value Value;

      static Value kruskal(const Graph& graph, const In& in, Out& out) {

        typedef typename In::Key MapArc;

        typedef typename In::Value Value;

        typedef typename ItemSetTraits<Graph, MapArc>::ItemIt MapArcIt;

        typedef std::vector<std::pair<MapArc, Value> > Sequence;

        Sequence seq;

        for (MapArcIt it(graph); it != INVALID; ++it) {

          seq.push_back(std::make_pair(it, in[it]));

        }

        std::sort(seq.begin(), seq.end(), PairComp<Sequence>());

        return KruskalOutputSelector<Graph, Sequence, Out>::

          kruskal(graph, seq, out);

      }

    };

    template <typename Graph, typename In, typename Out>

    struct KruskalOutputSelector<Graph, In, Out,

      typename enable_if<SequenceOutputIndicator<Out>, void>::type > 

    {

      typedef typename In::value_type::second_type Value;

      static Value kruskal(const Graph& graph, const In& in, Out& out) {

        typedef StoreBoolMap<Out> Map;

        Map map(out);

        return _kruskal_bits::kruskal(graph, in, map);

      }

    };

    template <typename Graph, typename In, typename Out>

    struct KruskalOutputSelector<Graph, In, Out,

      typename enable_if<MapOutputIndicator<Out>, void>::type > 

    {

      typedef typename In::value_type::second_type Value;

      static Value kruskal(const Graph& graph, const In& in, Out& out) {

        return _kruskal_bits::kruskal(graph, in, out);

      }

    };

  }

  /// \ingroup spantree

  ///

  /// \brief Kruskal's algorithm to find a minimum cost tree of a graph.

  ///

  /// This function runs Kruskal's algorithm to find a minimum cost tree.

  /// Due to some C++ hacking, it accepts various input and output types.

  ///

  /// \param g The graph the algorithm runs on.

  /// It can be either \ref concepts::Digraph "directed" or 

  /// \ref concepts::Graph "undirected".

  /// If the graph is directed, the algorithm consider it to be 

  /// undirected by disregarding the direction of the arcs.

  ///

  /// \param in This object is used to describe the arc costs. It can be one

  /// of the following choices.

  /// - An STL compatible 'Forward Container' with

  /// <tt>std::pair<GR::Edge,X></tt> or

  /// <tt>std::pair<GR::Arc,X></tt> as its <tt>value_type</tt>, where

  /// \c X is the type of the costs. The pairs indicates the arcs

  /// along with the assigned cost. <em>They must be in a

  /// cost-ascending order.</em>

  /// - Any readable Arc map. The values of the map indicate the arc costs.

  ///

  /// \retval out Here we also have a choise.

  /// - It can be a writable \c bool arc map.  After running the

  /// algorithm this will contain the found minimum cost spanning

  /// tree: the value of an arc will be set to \c true if it belongs

  /// to the tree, otherwise it will be set to \c false. The value of

  /// each arc will be set exactly once.

  /// - It can also be an iteraror of an STL Container with

  /// <tt>GR::Edge</tt> or <tt>GR::Arc</tt> as its

  /// <tt>value_type</tt>.  The algorithm copies the elements of the

  /// found tree into this sequence.  For example, if we know that the

  /// spanning tree of the graph \c g has say 53 arcs, then we can

  /// put its arcs into an STL vector \c tree with a code like this.

  ///\code

  /// std::vector<Arc> tree(53);

  /// kruskal(g,cost,tree.begin());

  ///\endcode

  /// Or if we don't know in advance the size of the tree, we can

  /// write this.  

  ///\code std::vector<Arc> tree;

  /// kruskal(g,cost,std::back_inserter(tree)); 

  ///\endcode

  ///

  /// \return The total cost of the found tree.

  ///

  /// \warning If kruskal runs on an be consistent of using the same

  /// Arc type for input and output.

  ///

#ifdef DOXYGEN

  template <class Graph, class In, class Out>

  Value kruskal(GR const& g, const In& in, Out& out)

#else 

  template <class Graph, class In, class Out>

  inline typename _kruskal_bits::KruskalValueSelector<In>::Value 

  kruskal(const Graph& graph, const In& in, Out& out) 

#endif

  {

    return _kruskal_bits::KruskalInputSelector<Graph, In, Out>::

      kruskal(graph, in, out);

  }

  template <class Graph, class In, class Out>

  inline typename _kruskal_bits::KruskalValueSelector<In>::Value

  kruskal(const Graph& graph, const In& in, const Out& out)

  {

    return _kruskal_bits::KruskalInputSelector<Graph, In, const Out>::

      kruskal(graph, in, out);

  }  

} //namespace lemon

#endif //LEMON_KRUSKAL_H

/* -*- C++ -*-

 *

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

 *

 * Copyright (C) 2003-2008

 * 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.

 *

 */

#ifndef LEMON_UNION_FIND_H

#define LEMON_UNION_FIND_H

//!\ingroup auxdat

//!\file

//!\brief Union-Find data structures.

//!

#include <vector>

#include <list>

#include <utility>

#include <algorithm>

#include <functional>

#include <lemon/bits/invalid.h>

namespace lemon {

  /// \ingroup auxdat

  ///

  /// \brief A \e Union-Find data structure implementation

  ///

  /// The class implements the \e Union-Find data structure. 

  /// The union operation uses rank heuristic, while

  /// the find operation uses path compression.

  /// This is a very simple but efficient implementation, providing 

  /// only four methods: join (union), find, insert and size.

  /// For more features see the \ref UnionFindEnum class.

  ///

  /// It is primarily used in Kruskal algorithm for finding minimal

  /// cost spanning tree in a graph.

  /// \sa kruskal()

  ///

  /// \pre You need to add all the elements by the \ref insert()

  /// method.  

  template <typename _ItemIntMap>

  class UnionFind {

  public:

    typedef _ItemIntMap ItemIntMap;

    typedef typename ItemIntMap::Key Item;

  private:

    // If the items vector stores negative value for an item then

    // that item is root item and it has -items[it] component size.

    // Else the items[it] contains the index of the parent.

    std::vector<int> items;

    ItemIntMap& index;

    bool rep(int idx) const {

      return items[idx] < 0;

    }

    int repIndex(int idx) const {

      int k = idx;

      while (!rep(k)) {

        k = items[k] ;

      }

      while (idx != k) {

        int next = items[idx];

        const_cast<int&>(items[idx]) = k;

        idx = next;

      }

      return k;

    }

  public:

    /// \brief Constructor

    ///

    /// Constructor of the UnionFind class. You should give an item to

    /// integer map which will be used from the data structure. If you

    /// modify directly this map that may cause segmentation fault,

    /// invalid data structure, or infinite loop when you use again

    /// the union-find.

    UnionFind(ItemIntMap& m) : index(m) {}

    /// \brief Returns the index of the element's component.

    ///

    /// The method returns the index of the element's component.

    /// This is an integer between zero and the number of inserted elements.

    ///

    int find(const Item& a) {

      return repIndex(index[a]);

    }

    /// \brief Clears the union-find data structure

    ///

    /// Erase each item from the data structure.

    void clear() {

      items.clear();

    }

    /// \brief Inserts a new element into the structure.

    ///

    /// This method inserts a new element into the data structure. 

    ///

    /// The method returns the index of the new component.

    int insert(const Item& a) {

      int n = items.size();

      items.push_back(-1);

      index.set(a,n);

      return n;

    }

    /// \brief Joining the components of element \e a and element \e b.

    ///

    /// This is the \e union operation of the Union-Find structure. 

    /// Joins the component of element \e a and component of

    /// element \e b. If \e a and \e b are in the same component then

    /// it returns false otherwise it returns true.

    bool join(const Item& a, const Item& b) {

      int ka = repIndex(index[a]);

      int kb = repIndex(index[b]);

      if ( ka == kb ) 

	return false;

      if (items[ka] < items[kb]) {

	items[ka] += items[kb];

	items[kb] = ka;

      } else {

	items[kb] += items[ka];

	items[ka] = kb;

      }

      return true;

    }

    /// \brief Returns the size of the component of element \e a.

    ///

    /// Returns the size of the component of element \e a.

    int size(const Item& a) {

      int k = repIndex(index[a]);

      return - items[k];

    }

  };

  /// \ingroup auxdat

  ///

  /// \brief A \e Union-Find data structure implementation which

  /// is able to enumerate the components.

  ///

  /// The class implements a \e Union-Find data structure

  /// which is able to enumerate the components and the items in

  /// a component. If you don't need this feature then perhaps it's

  /// better to use the \ref UnionFind class which is more efficient.

  ///

  /// The union operation uses rank heuristic, while

  /// the find operation uses path compression.

  ///

  /// \pre You need to add all the elements by the \ref insert()

  /// method.

  ///

  template <typename _ItemIntMap>

  class UnionFindEnum {

  public:

    typedef _ItemIntMap ItemIntMap;

    typedef typename ItemIntMap::Key Item;

  private:

    ItemIntMap& index;

    // If the parent stores negative value for an item then that item

    // is root item and it has ~(items[it].parent) component id.  Else

    // the items[it].parent contains the index of the parent.

    //

    // The \c next and \c prev provides the double-linked

    // cyclic list of one component's items.

    struct ItemT {

      int parent;

      Item item;

      int next, prev;

    };

    std::vector<ItemT> items;

    int firstFreeItem;

    struct ClassT {

      int size;

      int firstItem;

      int next, prev;

    };

    std::vector<ClassT> classes;

    int firstClass, firstFreeClass;

    int newClass() {

      if (firstFreeClass == -1) {

	int cdx = classes.size();

	classes.push_back(ClassT());

	return cdx;

      } else {

	int cdx = firstFreeClass;

	firstFreeClass = classes[firstFreeClass].next;

	return cdx;

      }

    }

    int newItem() {

      if (firstFreeItem == -1) {

	int idx = items.size();

	items.push_back(ItemT());

	return idx;

      } else {

	int idx = firstFreeItem;

	firstFreeItem = items[firstFreeItem].next;

	return idx;

      }

    }

    bool rep(int idx) const {

      return items[idx].parent < 0;

    }

    int repIndex(int idx) const {

      int k = idx;

      while (!rep(k)) {

        k = items[k].parent;

      }

      while (idx != k) {

        int next = items[idx].parent;

        const_cast<int&>(items[idx].parent) = k;

        idx = next;

      }

      return k;

    }

    int classIndex(int idx) const {

      return ~(items[repIndex(idx)].parent);

    }

    void singletonItem(int idx) {

      items[idx].next = idx;

      items[idx].prev = idx;

    }

    void laceItem(int idx, int rdx) {

      items[idx].prev = rdx;

      items[idx].next = items[rdx].next;

      items[items[rdx].next].prev = idx;

      items[rdx].next = idx;

    }

    void unlaceItem(int idx) {

      items[items[idx].prev].next = items[idx].next;

      items[items[idx].next].prev = items[idx].prev;

      items[idx].next = firstFreeItem;

      firstFreeItem = idx;

    }

    void spliceItems(int ak, int bk) {

      items[items[ak].prev].next = bk;

      items[items[bk].prev].next = ak;

      int tmp = items[ak].prev;

      items[ak].prev = items[bk].prev;

      items[bk].prev = tmp;

    }

    void laceClass(int cls) {

      if (firstClass != -1) {

        classes[firstClass].prev = cls;

      }

      classes[cls].next = firstClass;

      classes[cls].prev = -1;

      firstClass = cls;

    } 

    void unlaceClass(int cls) {

      if (classes[cls].prev != -1) {

        classes[classes[cls].prev].next = classes[cls].next;

      } else {

        firstClass = classes[cls].next;

      }

      if (classes[cls].next != -1) {

        classes[classes[cls].next].prev = classes[cls].prev;

      }

      classes[cls].next = firstFreeClass;

      firstFreeClass = cls;

    } 

  public:

    UnionFindEnum(ItemIntMap& _index) 

      : index(_index), items(), firstFreeItem(-1), 

	firstClass(-1), firstFreeClass(-1) {}

    /// \brief Inserts the given element into a new component.

    ///

    /// This method creates a new component consisting only of the

    /// given element.

    ///

    int insert(const Item& item) {

      int idx = newItem();

      index.set(item, idx);

      singletonItem(idx);

      items[idx].item = item;

      int cdx = newClass();

      items[idx].parent = ~cdx;

      laceClass(cdx);

      classes[cdx].size = 1;

      classes[cdx].firstItem = idx;

      firstClass = cdx;

      return cdx;

    }

    /// \brief Inserts the given element into the component of the others.

    ///

    /// This methods inserts the element \e a into the component of the

    /// element \e comp. 

    void insert(const Item& item, int cls) {

      int rdx = classes[cls].firstItem;

      int idx = newItem();

      index.set(item, idx);

      laceItem(idx, rdx);

      items[idx].item = item;

      items[idx].parent = rdx;

      ++classes[~(items[rdx].parent)].size;

    }

    /// \brief Clears the union-find data structure

    ///

    /// Erase each item from the data structure.

    void clear() {

      items.clear();

      firstClass = -1;

      firstFreeItem = -1;

    }

    /// \brief Finds the component of the given element.

    ///

    /// The method returns the component id of the given element.

    int find(const Item &item) const {

      return ~(items[repIndex(index[item])].parent);

    }

    /// \brief Joining the component of element \e a and element \e b.

    ///

    /// This is the \e union operation of the Union-Find structure. 

    /// Joins the component of element \e a and component of

    /// element \e b. If \e a and \e b are in the same component then

    /// returns -1 else returns the remaining class.

    int join(const Item& a, const Item& b) {

      int ak = repIndex(index[a]);

      int bk = repIndex(index[b]);

      if (ak == bk) {

	return -1;

      }

      int acx = ~(items[ak].parent);

      int bcx = ~(items[bk].parent);

      int rcx;

      if (classes[acx].size > classes[bcx].size) {

	classes[acx].size += classes[bcx].size;

	items[bk].parent = ak;

        unlaceClass(bcx);

	rcx = acx;

      } else {

	classes[bcx].size += classes[acx].size;

	items[ak].parent = bk;

        unlaceClass(acx);

	rcx = bcx;

      }

      spliceItems(ak, bk);

      return rcx;

    }

    /// \brief Returns the size of the class.

    ///

    /// Returns the size of the class.

    int size(int cls) const {

      return classes[cls].size;

    }

    /// \brief Splits up the component. 

    ///

    /// Splitting the component into singleton components (component

    /// of size one).

    void split(int cls) {

      int fdx = classes[cls].firstItem;

      int idx = items[fdx].next;

      while (idx != fdx) {

        int next = items[idx].next;

	singletonItem(idx);

	int cdx = newClass();        

        items[idx].parent = ~cdx;

	laceClass(cdx);

	classes[cdx].size = 1;

	classes[cdx].firstItem = idx;

        idx = next;

      }

      items[idx].prev = idx;

      items[idx].next = idx;

      classes[~(items[idx].parent)].size = 1;

    }

    /// \brief Removes the given element from the structure.

    ///

    /// Removes the element from its component and if the component becomes

    /// empty then removes that component from the component list.

    ///

    /// \warning It is an error to remove an element which is not in

    /// the structure.

    /// \warning This running time of this operation is proportional to the

    /// number of the items in this class.

    void erase(const Item& item) {

      int idx = index[item];

      int fdx = items[idx].next;

      int cdx = classIndex(idx);

      if (idx == fdx) {

	unlaceClass(cdx);

	items[idx].next = firstFreeItem;

	firstFreeItem = idx;

	return;

      } else {

	classes[cdx].firstItem = fdx;

	--classes[cdx].size;

	items[fdx].parent = ~cdx;

	unlaceItem(idx);

	idx = items[fdx].next;

	while (idx != fdx) {

	  items[idx].parent = fdx;

	  idx = items[idx].next;

	}

      }

    }

    /// \brief Gives back a representant item of the component.

    ///

    /// Gives back a representant item of the component.

    Item item(int cls) const {

      return items[classes[cls].firstItem].item;

    }

    /// \brief Removes the component of the given element from the structure.

    ///

    /// Removes the component of the given element from the structure.

    ///

    /// \warning It is an error to give an element which is not in the

    /// structure.

    void eraseClass(int cls) {

      int fdx = classes[cls].firstItem;

      unlaceClass(cls);

      items[items[fdx].prev].next = firstFreeItem;

      firstFreeItem = fdx;

    }

    /// \brief Lemon style iterator for the representant items.

    ///

    /// ClassIt is a lemon style iterator for the components. It iterates

    /// on the ids of the classes.

    class ClassIt {

    public:

      /// \brief Constructor of the iterator

      ///

      /// Constructor of the iterator

      ClassIt(const UnionFindEnum& ufe) : unionFind(&ufe) {

        cdx = unionFind->firstClass;

      }

      /// \brief Constructor to get invalid iterator

      ///

      /// Constructor to get invalid iterator

      ClassIt(Invalid) : unionFind(0), cdx(-1) {}

      /// \brief Increment operator

      ///

      /// It steps to the next representant item.

      ClassIt& operator++() {

        cdx = unionFind->classes[cdx].next;

        return *this;

      }

      /// \brief Conversion operator

      ///

      /// It converts the iterator to the current representant item.

      operator int() const {

        return cdx;

      }

      /// \brief Equality operator

      ///

      /// Equality operator

      bool operator==(const ClassIt& i) { 

        return i.cdx == cdx;

      }

      /// \brief Inequality operator

      ///

      /// Inequality operator

      bool operator!=(const ClassIt& i) { 

        return i.cdx != cdx;

      }

    private:

      const UnionFindEnum* unionFind;

      int cdx;

    };

    /// \brief Lemon style iterator for the items of a component.

    ///

    /// ClassIt is a lemon style iterator for the components. It iterates

    /// on the items of a class. By example if you want to iterate on

    /// each items of each classes then you may write the next code.

    ///\code

    /// for (ClassIt cit(ufe); cit != INVALID; ++cit) {

    ///   std::cout << "Class: ";

    ///   for (ItemIt iit(ufe, cit); iit != INVALID; ++iit) {

    ///     std::cout << toString(iit) << ' ' << std::endl;

    ///   }

    ///   std::cout << std::endl;

    /// }

    ///\endcode

    class ItemIt {

    public:

      /// \brief Constructor of the iterator

      ///

      /// Constructor of the iterator. The iterator iterates

      /// on the class of the \c item.

      ItemIt(const UnionFindEnum& ufe, int cls) : unionFind(&ufe) {

        fdx = idx = unionFind->classes[cls].firstItem;

      }

      /// \brief Constructor to get invalid iterator

      ///

      /// Constructor to get invalid iterator

      ItemIt(Invalid) : unionFind(0), idx(-1) {}

      /// \brief Increment operator

      ///

      /// It steps to the next item in the class.

      ItemIt& operator++() {

        idx = unionFind->items[idx].next;

        if (idx == fdx) idx = -1;

        return *this;

      }

      /// \brief Conversion operator

      ///

      /// It converts the iterator to the current item.

      operator const Item&() const {

        return unionFind->items[idx].item;

      }

      /// \brief Equality operator

      ///

      /// Equality operator

      bool operator==(const ItemIt& i) { 

        return i.idx == idx;

      }

      /// \brief Inequality operator

      ///

      /// Inequality operator

      bool operator!=(const ItemIt& i) { 

        return i.idx != idx;

      }

    private:

      const UnionFindEnum* unionFind;

      int idx, fdx;

    };

  };

  /// \ingroup auxdat

  ///

  /// \brief A \e Extend-Find data structure implementation which

  /// is able to enumerate the components.

  ///

  /// The class implements an \e Extend-Find data structure which is

  /// able to enumerate the components and the items in a

  /// component. The data structure is a simplification of the

  /// Union-Find structure, and it does not allow to merge two components.

  ///

  /// \pre You need to add all the elements by the \ref insert()

  /// method.

  template <typename _ItemIntMap>

  class ExtendFindEnum {

  public:

    typedef _ItemIntMap ItemIntMap;

    typedef typename ItemIntMap::Key Item;

  private:

    ItemIntMap& index;

    struct ItemT {

      int cls;

      Item item;

      int next, prev;

    };

    std::vector<ItemT> items;

    int firstFreeItem;

    struct ClassT {

      int firstItem;

      int next, prev;

    };

    std::vector<ClassT> classes;

    int firstClass, firstFreeClass;

    int newClass() {

      if (firstFreeClass != -1) {

	int cdx = firstFreeClass;

	firstFreeClass = classes[cdx].next;

	return cdx;

      } else {

	classes.push_back(ClassT());

	return classes.size() - 1;

      }

    }

    int newItem() {

      if (firstFreeItem != -1) {

	int idx = firstFreeItem;

	firstFreeItem = items[idx].next;

	return idx;

      } else {

	items.push_back(ItemT());

	return items.size() - 1;

      }

    }

  public:

    /// \brief Constructor

    ExtendFindEnum(ItemIntMap& _index) 

      : index(_index), items(), firstFreeItem(-1), 

	classes(), firstClass(-1), firstFreeClass(-1) {}

    /// \brief Inserts the given element into a new component.

    ///

    /// This method creates a new component consisting only of the

    /// given element.

    int insert(const Item& item) {

      int cdx = newClass();

      classes[cdx].prev = -1;

      classes[cdx].next = firstClass;

      if (firstClass != -1) {

	classes[firstClass].prev = cdx;

      }

      firstClass = cdx;

      int idx = newItem();

      items[idx].item = item;

      items[idx].cls = cdx;

      items[idx].prev = idx;

      items[idx].next = idx;

      classes[cdx].firstItem = idx;

      index.set(item, idx);

      return cdx;

    }

    /// \brief Inserts the given element into the given component.

    ///

    /// This methods inserts the element \e item a into the \e cls class.

    void insert(const Item& item, int cls) {

      int idx = newItem();

      int rdx = classes[cls].firstItem;

      items[idx].item = item;

      items[idx].cls = cls;

      items[idx].prev = rdx;

      items[idx].next = items[rdx].next;

      items[items[rdx].next].prev = idx;

      items[rdx].next = idx;

      index.set(item, idx);

    }

    /// \brief Clears the union-find data structure

    ///

    /// Erase each item from the data structure.

    void clear() {

      items.clear();

      classes.clear;

      firstClass = firstFreeClass = firstFreeItem = -1;

    }

    /// \brief Gives back the class of the \e item.

    ///

    /// Gives back the class of the \e item.

    int find(const Item &item) const {

      return items[index[item]].cls;

    }

    /// \brief Gives back a representant item of the component.

    ///

    /// Gives back a representant item of the component.

    Item item(int cls) const {

      return items[classes[cls].firstItem].item;

    }

    /// \brief Removes the given element from the structure.

    ///

    /// Removes the element from its component and if the component becomes

    /// empty then removes that component from the component list.

    ///

    /// \warning It is an error to remove an element which is not in

    /// the structure.

    void erase(const Item &item) {

      int idx = index[item];

      int cdx = items[idx].cls;

      if (idx == items[idx].next) {

	if (classes[cdx].prev != -1) {

	  classes[classes[cdx].prev].next = classes[cdx].next; 

	} else {

	  firstClass = classes[cdx].next;

	}

	if (classes[cdx].next != -1) {

	  classes[classes[cdx].next].prev = classes[cdx].prev; 

	}

	classes[cdx].next = firstFreeClass;

	firstFreeClass = cdx;

      } else {

	classes[cdx].firstItem = items[idx].next;

	items[items[idx].next].prev = items[idx].prev;

	items[items[idx].prev].next = items[idx].next;

      }

      items[idx].next = firstFreeItem;

      firstFreeItem = idx;

    }    

    /// \brief Removes the component of the given element from the structure.

    ///

    /// Removes the component of the given element from the structure.

    ///

    /// \warning It is an error to give an element which is not in the

    /// structure.