lemon/unionfind.h
author alpar
Mon, 13 Nov 2006 18:46:19 +0000
changeset 2301 eb378706bd3d
parent 2006 00d59f733817
child 2308 cddae1c4fee6
permissions -rw-r--r--
Test the automatic compilation checker 1/2: make a bug
     1 /* -*- C++ -*-
     2  *
     3  * This file is a part of LEMON, a generic C++ optimization library
     4  *
     5  * Copyright (C) 2003-2006
     6  * Egervary Jeno Kombinatorikus Optimalizalasi Kutatocsoport
     7  * (Egervary Research Group on Combinatorial Optimization, EGRES).
     8  *
     9  * Permission to use, modify and distribute this software is granted
    10  * provided that this copyright notice appears in all copies. For
    11  * precise terms see the accompanying LICENSE file.
    12  *
    13  * This software is provided "AS IS" with no warranty of any kind,
    14  * express or implied, and with no claim as to its suitability for any
    15  * purpose.
    16  *
    17  */
    18 
    19 #ifndef LEMON_UNION_FIND_H
    20 #define LEMON_UNION_FIND_H
    21 
    22 //!\ingroup auxdat
    23 //!\file
    24 //!\brief Union-Find data structures.
    25 //!
    26 
    27 #include <vector>
    28 #include <list>
    29 #include <utility>
    30 #include <algorithm>
    31 
    32 #include <lemon/bits/invalid.h>
    33 
    34 namespace lemon {
    35 
    36   //! \addtogroup auxdat
    37   //! @{
    38 
    39   /// \brief A \e Union-Find data structure implementation
    40   ///
    41   /// The class implements the \e Union-Find data structure. 
    42   /// The union operation uses rank heuristic, while
    43   /// the find operation uses path compression.
    44   /// This is a very simple but efficient implementation, providing 
    45   /// only four methods: join (union), find, insert and size.
    46   /// For more features see the \ref UnionFindEnum class.
    47   ///
    48   /// It is primarily used in Kruskal algorithm for finding minimal
    49   /// cost spanning tree in a graph.
    50   /// \sa kruskal()
    51   ///
    52   /// \pre You need to add all the elements by the \ref insert()
    53   /// method.  
    54   template <typename Item, typename ItemIntMap>
    55   class UnionFind {
    56     
    57   public:
    58     typedef Item ElementType;
    59 
    60   private:
    61     // If the items vector stores negative value for an item then
    62     // that item is root item and it has -items[it] component size.
    63     // Else the items[it] contains the index of the parent.
    64     std::vector<int> items;
    65     ItemIntMap& index;
    66 
    67     bool rep(int idx) const {
    68       return items[idx] < 0;
    69     }
    70 
    71     int repIndex(int idx) const {
    72       int k = idx;
    73       while (!rep(k)) {
    74         k = items[k] ;
    75       }
    76       while (idx != k) {
    77         int next = items[idx];
    78         const_cast<int&>(items[idx]) = k;
    79         idx = next;
    80       }
    81       return k;
    82     }
    83 
    84   public:
    85 
    86     /// \brief Constructor
    87     ///
    88     /// Constructor of the UnionFind class. You should give an item to
    89     /// integer map which will be used from the data structure. If you
    90     /// modify directly this map that may cause segmentation fault,
    91     /// invalid data structure, or infinite loop when you use again
    92     /// the union-find.
    93     UnionFind(ItemIntMap& m) : index(m) {}
    94 
    95     /// \brief Returns the index of the element's component.
    96     ///
    97     /// The method returns the index of the element's component.
    98     /// This is an integer between zero and the number of inserted elements.
    99     ///
   100     int find(const Item& a) {
   101       return repIndex(index[a]);
   102     }
   103 
   104     /// \brief Inserts a new element into the structure.
   105     ///
   106     /// This method inserts a new element into the data structure. 
   107     ///
   108     /// The method returns the index of the new component.
   109     int insert(const Item& a) {
   110       int n = items.size();
   111       items.push_back(-1);
   112       index.set(a,n);
   113       return n;
   114     }
   115 
   116     /// \brief Joining the components of element \e a and element \e b.
   117     ///
   118     /// This is the \e union operation of the Union-Find structure. 
   119     /// Joins the component of element \e a and component of
   120     /// element \e b. If \e a and \e b are in the same component then
   121     /// it returns false otherwise it returns true.
   122     bool join(const Item& a, const Item& b) {
   123       int ka = repIndex(index[a]);
   124       int kb = repIndex(index[b]);
   125 
   126       if ( ka == kb ) 
   127 	return false;
   128 
   129       if (items[ka] < items[kb]) {
   130 	items[ka] += items[kb];
   131 	items[kb] = ka;
   132       } else {
   133 	items[kb] += items[ka];
   134 	items[ka] = kb;
   135       }
   136       return true;
   137     }
   138 
   139     /// \brief Returns the size of the component of element \e a.
   140     ///
   141     /// Returns the size of the component of element \e a.
   142     int size(const Item& a) {
   143       int k = repIndex(index[a]);
   144       return - items[k];
   145     }
   146 
   147   };
   148 
   149 
   150   /// \brief A \e Union-Find data structure implementation which
   151   /// is able to enumerate the components.
   152   ///
   153   /// The class implements a \e Union-Find data structure
   154   /// which is able to enumerate the components and the items in
   155   /// a component. If you don't need this feature then perhaps it's
   156   /// better to use the \ref UnionFind class which is more efficient.
   157   ///
   158   /// The union operation uses rank heuristic, while
   159   /// the find operation uses path compression.
   160   ///
   161   /// \pre You need to add all the elements by the \ref insert()
   162   /// method.
   163   ///
   164   template <typename _Item, typename _ItemIntMap>
   165   class UnionFindEnum {
   166   public:
   167     
   168     typedef _Item Item;
   169     typedef _ItemIntMap ItemIntMap;
   170     
   171   private:
   172     
   173     // If the parent stores negative value for an item then that item
   174     // is root item and it has -items[it].parent component size.  Else
   175     // the items[it].parent contains the index of the parent.
   176     //
   177     // The \c nextItem and \c prevItem provides the double-linked
   178     // cyclic list of one component's items. The \c prevClass and
   179     // \c nextClass gives the double linked list of the representant
   180     // items. 
   181     struct ItemT {
   182       int parent;
   183       Item item;
   184 
   185       int nextItem, prevItem;
   186       int nextClass, prevClass;
   187     };
   188 
   189     std::vector<ItemT> items;
   190     ItemIntMap& index;
   191 
   192     int firstClass;
   193 
   194 
   195     bool rep(int idx) const {
   196       return items[idx].parent < 0;
   197     }
   198 
   199     int repIndex(int idx) const {
   200       int k = idx;
   201       while (!rep(k)) {
   202         k = items[k].parent;
   203       }
   204       while (idx != k) {
   205         int next = items[idx].parent;
   206         const_cast<int&>(items[idx].parent) = k;
   207         idx = next;
   208       }
   209       return k;
   210     }
   211 
   212     void unlaceClass(int k) {
   213       if (items[k].prevClass != -1) {
   214         items[items[k].prevClass].nextClass = items[k].nextClass;
   215       } else {
   216         firstClass = items[k].nextClass;
   217       }
   218       if (items[k].nextClass != -1) {
   219         items[items[k].nextClass].prevClass = items[k].prevClass;
   220       }
   221     } 
   222 
   223     void spliceItems(int ak, int bk) {
   224       items[items[ak].prevItem].nextItem = bk;
   225       items[items[bk].prevItem].nextItem = ak;
   226       int tmp = items[ak].prevItem;
   227       items[ak].prevItem = items[bk].prevItem;
   228       items[bk].prevItem = tmp;
   229         
   230     }
   231 
   232   public:
   233 
   234     UnionFindEnum(ItemIntMap& _index) 
   235       : items(), index(_index), firstClass(-1) {}
   236     
   237     /// \brief Inserts the given element into a new component.
   238     ///
   239     /// This method creates a new component consisting only of the
   240     /// given element.
   241     ///
   242     void insert(const Item& item) {
   243       ItemT t;
   244 
   245       int idx = items.size();
   246       index.set(item, idx);
   247 
   248       t.nextItem = idx;
   249       t.prevItem = idx;
   250       t.item = item;
   251       t.parent = -1;
   252       
   253       t.nextClass = firstClass;
   254       if (firstClass != -1) {
   255         items[firstClass].prevClass = idx;
   256       }
   257       t.prevClass = -1;
   258       firstClass = idx;
   259 
   260       items.push_back(t);
   261     }
   262 
   263     /// \brief Inserts the given element into the component of the others.
   264     ///
   265     /// This methods inserts the element \e a into the component of the
   266     /// element \e comp. 
   267     void insert(const Item& item, const Item& comp) {
   268       int k = repIndex(index[comp]);
   269       ItemT t;
   270 
   271       int idx = items.size();
   272       index.set(item, idx);
   273 
   274       t.prevItem = k;
   275       t.nextItem = items[k].nextItem;
   276       items[items[k].nextItem].prevItem = idx;
   277       items[k].nextItem = idx;
   278 
   279       t.item = item;
   280       t.parent = k;
   281 
   282       --items[k].parent;
   283 
   284       items.push_back(t);
   285     }
   286 
   287     /// \brief Finds the leader of the component of the given element.
   288     ///
   289     /// The method returns the leader of the component of the given element.
   290     const Item& find(const Item &item) const {
   291       return items[repIndex(index[item])].item;
   292     }
   293 
   294     /// \brief Joining the component of element \e a and element \e b.
   295     ///
   296     /// This is the \e union operation of the Union-Find structure. 
   297     /// Joins the component of element \e a and component of
   298     /// element \e b. If \e a and \e b are in the same component then
   299     /// returns false else returns true.
   300     bool join(const Item& a, const Item& b) {
   301 
   302       int ak = repIndex(index[a]);
   303       int bk = repIndex(index[b]);
   304 
   305       if (ak == bk) {
   306 	return false;
   307       }
   308 
   309       if ( items[ak].parent < items[bk].parent ) {
   310         unlaceClass(bk);
   311         items[ak].parent += items[bk].parent;
   312 	items[bk].parent = ak;
   313       } else {
   314         unlaceClass(bk);
   315         items[bk].parent += items[ak].parent;
   316 	items[ak].parent = bk;
   317       }
   318       spliceItems(ak, bk);
   319 
   320       return true;
   321     }
   322 
   323     /// \brief Returns the size of the component of element \e a.
   324     ///
   325     /// Returns the size of the component of element \e a.
   326     int size(const Item &item) const {
   327       return - items[repIndex(index[item])].parent;
   328     }
   329 
   330     /// \brief Splits up the component of the element. 
   331     ///
   332     /// Splitting the component of the element into sigleton
   333     /// components (component of size one).
   334     void split(const Item &item) {
   335       int k = repIndex(index[item]);
   336       int idx = items[k].nextItem;
   337       while (idx != k) {
   338         int next = items[idx].nextItem;
   339         
   340         items[idx].parent = -1;
   341         items[idx].prevItem = idx;
   342         items[idx].nextItem = idx;
   343         
   344         items[idx].nextClass = firstClass;
   345         items[firstClass].prevClass = idx;
   346         firstClass = idx;
   347 
   348         idx = next;
   349       }
   350 
   351       items[idx].parent = -1;
   352       items[idx].prevItem = idx;
   353       items[idx].nextItem = idx;
   354       
   355       items[firstClass].prevClass = -1;
   356     }
   357 
   358     /// \brief Sets the given element to the leader element of its component.
   359     ///
   360     /// Sets the given element to the leader element of its component.
   361     void makeRep(const Item &item) {
   362       int nk = index[item];
   363       int k = repIndex(nk);
   364       if (nk == k) return;
   365       
   366       if (items[k].prevClass != -1) {
   367         items[items[k].prevClass].nextClass = nk;
   368       } else {
   369         firstClass = nk;
   370       }
   371       if (items[k].nextClass != -1) {
   372         items[items[k].nextClass].prevClass = nk;
   373       }
   374       
   375       int idx = items[k].nextItem;
   376       while (idx != k) {
   377         items[idx].parent = nk;
   378         idx = items[idx].nextItem;
   379       }
   380       
   381       items[nk].parent = items[k].parent;
   382       items[k].parent = nk;
   383     }
   384 
   385     /// \brief Removes the given element from the structure.
   386     ///
   387     /// Removes the element from its component and if the component becomes
   388     /// empty then removes that component from the component list.
   389     ///
   390     /// \warning It is an error to remove an element which is not in
   391     /// the structure.
   392     void erase(const Item &item) {
   393       int idx = index[item];
   394       if (rep(idx)) {
   395         int k = idx;
   396         if (items[k].parent == -1) {
   397           unlaceClass(idx);
   398           return;
   399         } else {
   400           int nk = items[k].nextItem;
   401           if (items[k].prevClass != -1) {
   402             items[items[k].prevClass].nextClass = nk;
   403           } else {
   404             firstClass = nk;
   405           }
   406           if (items[k].nextClass != -1) {
   407             items[items[k].nextClass].prevClass = nk;
   408           }
   409       
   410           int idx = items[k].nextItem;
   411           while (idx != k) {
   412             items[idx].parent = nk;
   413             idx = items[idx].nextItem;
   414           }
   415           
   416           items[nk].parent = items[k].parent + 1;
   417         }
   418       } else {
   419         
   420         int k = repIndex(idx);
   421         idx = items[k].nextItem;
   422         while (idx != k) {
   423           items[idx].parent = k;
   424           idx = items[idx].nextItem;
   425         }
   426 
   427         ++items[k].parent;
   428       }
   429 
   430       idx = index[item];      
   431       items[items[idx].prevItem].nextItem = items[idx].nextItem;
   432       items[items[idx].nextItem].prevItem = items[idx].prevItem;
   433 
   434     }    
   435 
   436     /// \brief Moves the given element to another component.
   437     ///
   438     /// This method moves the element \e a from its component
   439     /// to the component of \e comp.
   440     /// If \e a and \e comp are in the same component then
   441     /// it returns false otherwise it returns true.
   442     bool move(const Item &item, const Item &comp) {
   443       if (repIndex(index[item]) == repIndex(index[comp])) return false;
   444       erase(item);
   445       insert(item, comp);
   446       return true;
   447     }
   448 
   449 
   450     /// \brief Removes the component of the given element from the structure.
   451     ///
   452     /// Removes the component of the given element from the structure.
   453     ///
   454     /// \warning It is an error to give an element which is not in the
   455     /// structure.
   456     void eraseClass(const Item &item) {
   457       unlaceClass(repIndex(index[item]));
   458     }
   459 
   460     /// \brief Lemon style iterator for the representant items.
   461     ///
   462     /// ClassIt is a lemon style iterator for the components. It iterates
   463     /// on the representant items of the classes.
   464     class ClassIt {
   465     public:
   466       /// \brief Constructor of the iterator
   467       ///
   468       /// Constructor of the iterator
   469       ClassIt(const UnionFindEnum& ufe) : unionFind(&ufe) {
   470         idx = unionFind->firstClass;
   471       }
   472 
   473       /// \brief Constructor to get invalid iterator
   474       ///
   475       /// Constructor to get invalid iterator
   476       ClassIt(Invalid) : unionFind(0), idx(-1) {}
   477       
   478       /// \brief Increment operator
   479       ///
   480       /// It steps to the next representant item.
   481       ClassIt& operator++() {
   482         idx = unionFind->items[idx].nextClass;
   483         return *this;
   484       }
   485       
   486       /// \brief Conversion operator
   487       ///
   488       /// It converts the iterator to the current representant item.
   489       operator const Item&() const {
   490         return unionFind->items[idx].item;
   491       }
   492 
   493       /// \brief Equality operator
   494       ///
   495       /// Equality operator
   496       bool operator==(const ClassIt& i) { 
   497         return i.idx == idx;
   498       }
   499 
   500       /// \brief Inequality operator
   501       ///
   502       /// Inequality operator
   503       bool operator!=(const ClassIt& i) { 
   504         return i.idx != idx;
   505       }
   506       
   507     private:
   508       const UnionFindEnum* unionFind;
   509       int idx;
   510     };
   511 
   512     /// \brief Lemon style iterator for the items of a component.
   513     ///
   514     /// ClassIt is a lemon style iterator for the components. It iterates
   515     /// on the items of a class. By example if you want to iterate on
   516     /// each items of each classes then you may write the next code.
   517     ///\code
   518     /// for (ClassIt cit(ufe); cit != INVALID; ++cit) {
   519     ///   std::cout << "Class: ";
   520     ///   for (ItemIt iit(ufe, cit); iit != INVALID; ++iit) {
   521     ///     std::cout << toString(iit) << ' ' << std::endl;
   522     ///   }
   523     ///   std::cout << std::endl;
   524     /// }
   525     ///\endcode
   526     class ItemIt {
   527     public:
   528       /// \brief Constructor of the iterator
   529       ///
   530       /// Constructor of the iterator. The iterator iterates
   531       /// on the class of the \c item.
   532       ItemIt(const UnionFindEnum& ufe, const Item& item) : unionFind(&ufe) {
   533         idx = unionFind->repIndex(unionFind->index[item]);
   534       }
   535 
   536       /// \brief Constructor to get invalid iterator
   537       ///
   538       /// Constructor to get invalid iterator
   539       ItemIt(Invalid) : unionFind(0), idx(-1) {}
   540       
   541       /// \brief Increment operator
   542       ///
   543       /// It steps to the next item in the class.
   544       ItemIt& operator++() {
   545         idx = unionFind->items[idx].nextItem;
   546         if (unionFind->rep(idx)) idx = -1;
   547         return *this;
   548       }
   549       
   550       /// \brief Conversion operator
   551       ///
   552       /// It converts the iterator to the current item.
   553       operator const Item&() const {
   554         return unionFind->items[idx].item;
   555       }
   556 
   557       /// \brief Equality operator
   558       ///
   559       /// Equality operator
   560       bool operator==(const ItemIt& i) { 
   561         return i.idx == idx;
   562       }
   563 
   564       /// \brief Inequality operator
   565       ///
   566       /// Inequality operator
   567       bool operator!=(const ItemIt& i) { 
   568         return i.idx != idx;
   569       }
   570       
   571     private:
   572       const UnionFindEnum* unionFind;
   573       int idx;
   574     };
   575 
   576   };
   577 
   578 
   579   //! @}
   580 
   581 } //namespace lemon
   582 
   583 #endif //LEMON_UNION_FIND_H