lemon/radix_sort.h
author jacint
Thu, 30 Mar 2006 15:34:56 +0000
changeset 2024 4ab8a25def3c
parent 1956 a055123339d5
child 2033 7bf1f64962c2
permissions -rw-r--r--
tolerance class incorporated
     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 RADIX_SORT_H
    20 #define RADIX_SORT_H
    21 
    22 /// \ingroup auxdat
    23 /// \file
    24 /// \brief Radix sort
    25 ///
    26 
    27 #include <vector>
    28 #include <limits>
    29 #include <iterator>
    30 #include <algorithm>
    31 
    32 #include <lemon/error.h>
    33 
    34 namespace lemon {
    35 
    36   namespace _radix_sort_bits {
    37 
    38     template <typename Value>
    39     struct Identity {
    40       const Value& operator()(const Value& val) {
    41 	return val;
    42       }
    43     };
    44 
    45   }
    46 
    47   template <typename Value, typename Iterator, typename Functor>
    48   Iterator radixSortPartition(Iterator first, Iterator last, 
    49 			      Functor functor, Value mask) {
    50     while (first != last && !(functor(*first) & mask)) {
    51       ++first;
    52     }
    53     if (first == last) {
    54       return first;
    55     }
    56     --last;
    57     while (first != last && (functor(*last) & mask)) {
    58       --last;
    59     }
    60     if (first == last) {
    61       return first;
    62     }
    63     std::iter_swap(first, last);
    64     ++first;
    65     if (!(first < last)) {
    66       return first;
    67     }
    68     while (true) {
    69       while (!(functor(*first) & mask)) {
    70 	++first;
    71       }
    72       --last;
    73       while (functor(*last) & mask) {
    74 	--last;
    75       }
    76       if (!(first < last)) {
    77 	return first;
    78       }
    79       std::iter_swap(first, last);
    80       ++first;
    81     }
    82   }
    83 
    84   template <typename Iterator, typename Functor>
    85   Iterator radixSortSignPartition(Iterator first, Iterator last, 
    86 				  Functor functor) {
    87     while (first != last && functor(*first) < 0) {
    88       ++first;
    89     }
    90     if (first == last) {
    91       return first;
    92     }
    93     --last;
    94     while (first != last && functor(*last) >= 0) {
    95       --last;
    96     }
    97     if (first == last) {
    98       return first;
    99     }
   100     std::iter_swap(first, last);
   101     ++first;
   102     if (!(first < last)) {
   103       return first;
   104     }
   105     while (true) {
   106       while (functor(*first) < 0) {
   107 	++first;
   108       }
   109       --last;
   110       while (functor(*last) >= 0) {
   111 	--last;
   112       }
   113       if (!(first < last)) {
   114 	return first;
   115       }
   116       std::iter_swap(first, last);
   117       ++first;
   118     }
   119   }
   120 
   121   template <typename Value, typename Iterator, typename Functor>
   122   void radixIntroSort(Iterator first, Iterator last, 
   123 		      Functor functor, Value mask) {
   124     while (mask != 0 && last - first > 1) {
   125       Iterator cut = radixSortPartition(first, last, functor, mask);
   126       mask >>= 1;
   127       radixIntroSort(first, cut, functor, mask);
   128       first = cut;
   129     }
   130   }
   131 
   132   template <typename Value, typename Iterator, typename Functor>
   133   void radixSignedSort(Iterator first, Iterator last, Functor functor) {
   134     Iterator cut = radixSortSignPartition(first, last, functor);
   135 
   136     Value mask;
   137     int max_digit;
   138     Iterator it;
   139 
   140     mask = 0; max_digit = 0;
   141     for (it = first; it != cut; ++it) {
   142       if ((mask | functor(*it)) != ~0) {
   143 	++max_digit;
   144 	mask <<= 1; 
   145 	mask |= 1;
   146       }
   147     }
   148     radixIntroSort(first, cut, functor, 1 << max_digit);
   149 
   150     mask = ~0; max_digit = 0;
   151     for (it = cut; it != last; ++it) {
   152       if (mask & functor(*it)) {
   153 	++max_digit;
   154 	mask <<= 1;
   155       }
   156     }
   157     radixIntroSort(cut, last, functor, 1 << max_digit);
   158   }
   159 
   160   template <typename Value, typename Iterator, typename Functor>
   161   void radixUnsignedSort(Iterator first, Iterator last, Functor functor) {
   162 
   163     Value mask = ~0;
   164     int max_digit = 0;
   165 
   166     Iterator it;
   167     for (it = first; it != last; ++it) {
   168       if (mask & functor(*it)) {
   169 	++max_digit;
   170 	mask <<= 1;
   171       }
   172     }
   173     radixIntroSort(first, last, functor, 1 << max_digit);
   174   }
   175 
   176   namespace _radix_sort_bits {
   177 
   178     template <typename Value, 
   179 	      bool sign = std::numeric_limits<Value>::is_signed >
   180     struct RadixSortSelector {
   181       template <typename Iterator, typename Functor>
   182       static void sort(Iterator first, Iterator last, Functor functor) {
   183 	radixSignedSort<Value>(first, last, functor);
   184       }
   185     };
   186 
   187     template <typename Value>
   188     struct RadixSortSelector<Value, false> {
   189       template <typename Iterator, typename Functor>
   190       static void sort(Iterator first, Iterator last, Functor functor) {
   191 	radixUnsignedSort<Value>(first, last, functor);
   192       }
   193     };
   194 
   195   }
   196 
   197   /// \ingroup auxdat
   198   ///
   199   /// \brief Sorts the stl compatible range into ascending order.
   200   ///
   201   /// The \c radixSort sorts the stl compatible range into ascending order.
   202   /// The radix sort algorithm can sort the items which mapped to an
   203   /// integer by the adaptable unary function \c functor and the order
   204   /// will be ascending by these mapped values. As function specialization
   205   /// there is possible to use a normal function as the functor object
   206   /// or if the functor is not given it will use an identity function instead.
   207   ///
   208   /// This implemented radix sort is a special quick sort which pivot value
   209   /// is choosen to partite the items on the next bit. This way, let be
   210   /// \c c the maximal capacity and \c n the number of the items in
   211   /// the container, the time complexity of the algorithm \c O(log(c)*n)
   212   /// and the additional space complexity is \c O(log(c)).
   213   ///
   214   /// \param first The begin of the given range.
   215   /// \param last The end of the given range.
   216   /// \param functor An adaptible unary function or a normal function which
   217   /// maps the items to any integer type which can be wheter signed or 
   218   /// unsigned.
   219   template <typename Iterator, typename Functor>
   220   void radixSort(Iterator first, Iterator last, Functor functor) {
   221     using namespace _radix_sort_bits;
   222     typedef typename Functor::result_type Value;
   223     RadixSortSelector<Value>::sort(first, last, functor);
   224   }
   225 
   226   template <typename Iterator, typename Value, typename Key>
   227   void radixSort(Iterator first, Iterator last, Value (*functor)(Key)) {
   228     using namespace _radix_sort_bits;
   229     RadixSortSelector<Value>::sort(first, last, functor);
   230   }
   231 
   232   template <typename Iterator, typename Value, typename Key>
   233   void radixSort(Iterator first, Iterator last, Value& (*functor)(Key)) {
   234     using namespace _radix_sort_bits;
   235     RadixSortSelector<Value>::sort(first, last, functor);
   236   }
   237 
   238   template <typename Iterator, typename Value, typename Key>
   239   void radixSort(Iterator first, Iterator last, Value (*functor)(Key&)) {
   240     using namespace _radix_sort_bits;
   241     RadixSortSelector<Value>::sort(first, last, functor);
   242   }
   243 
   244   template <typename Iterator, typename Value, typename Key>
   245   void radixSort(Iterator first, Iterator last, Value& (*functor)(Key&)) {
   246     using namespace _radix_sort_bits;
   247     RadixSortSelector<Value>::sort(first, last, functor);
   248   }
   249 
   250   template <typename Iterator>
   251   void radixSort(Iterator first, Iterator last) {
   252     using namespace _radix_sort_bits;
   253     typedef typename std::iterator_traits<Iterator>::value_type Value;
   254     RadixSortSelector<Value>::sort(first, last, Identity<Value>());
   255   }
   256 
   257   template <typename Value>
   258   unsigned char valueByte(Value value, int byte) {
   259     return value >> (std::numeric_limits<unsigned char>::digits * byte);
   260   }
   261 
   262   template <typename Functor, typename Key>
   263   void counterIntroSort(Key *first, Key *last, Key *target, 
   264 		       int byte, Functor functor) {
   265     const int size = 
   266       (unsigned int)std::numeric_limits<unsigned char>::max() + 1;
   267     std::vector<int> counter(size);
   268     for (int i = 0; i < size; ++i) {
   269       counter[i] = 0;
   270     }
   271     Key *it = first;
   272     while (first != last) {
   273       ++counter[valueByte(functor(*first), byte)]; 
   274       ++first;
   275     }
   276     int prev, num = 0;
   277     for (int i = 0; i < size; ++i) {
   278       prev = num;
   279       num += counter[i];
   280       counter[i] = prev;
   281     }
   282     while (it != last) {
   283       target[counter[valueByte(functor(*it), byte)]++] = *it;
   284       ++it;
   285     }
   286   }
   287 
   288   template <typename Functor, typename Key>
   289   void signedCounterIntroSort(Key *first, Key *last, Key *target, 
   290 			     int byte, Functor functor) {
   291     const int size = 
   292       (unsigned int)std::numeric_limits<unsigned char>::max() + 1;
   293     std::vector<int> counter(size);
   294     for (int i = 0; i < size; ++i) {
   295       counter[i] = 0;
   296     }
   297     Key *it = first;
   298     while (first != last) {
   299       counter[valueByte(functor(*first), byte)]++;
   300       ++first;
   301     }
   302     int prev, num = 0;
   303     for (int i = size / 2; i < size; ++i) {
   304       prev = num;
   305       num += counter[i];
   306       counter[i] = prev;
   307     }
   308     for (int i = 0; i < size / 2; ++i) {
   309       prev = num;
   310       num += counter[i];
   311       counter[i] = prev;
   312     }
   313     while (it != last) {
   314       target[counter[valueByte(functor(*it), byte)]++] = *it;
   315       ++it;
   316     }
   317   }
   318 
   319   
   320   template <typename Value, typename Iterator, typename Functor>
   321   void counterSignedSort(Iterator first, Iterator last, Functor functor) {
   322     if (first == last) return;
   323     typedef typename std::iterator_traits<Iterator>::value_type Key;
   324     typedef std::allocator<Key> Allocator;
   325     Allocator allocator;
   326 
   327     int length = std::distance(first, last);
   328     Key* buffer;
   329     buffer = allocator.allocate(2 * length);
   330     try {
   331       bool dir = true;
   332       std::copy(first, last, buffer);
   333       for (int i = 0; i < (int)sizeof(Value) - 1; ++i) {
   334 	if (dir) {
   335 	  counterIntroSort(buffer, buffer + length, buffer + length, 
   336 			   i, functor);
   337 	} else {
   338 	  counterIntroSort(buffer + length, buffer + 2 * length, buffer, 
   339 			   i, functor);
   340 	}
   341 	dir = !dir;
   342       }
   343       if (dir) {
   344 	signedCounterIntroSort(buffer, buffer + length, buffer + length, 
   345 			       sizeof(Value) - 1, functor);
   346 	std::copy(buffer + length, buffer + 2 * length, first);
   347       }	else {
   348 	signedCounterIntroSort(buffer + length, buffer + 2 * length, buffer, 
   349 			       sizeof(Value) - 1, functor);
   350 	std::copy(buffer, buffer + length, first);
   351       }
   352     } catch (...) {
   353       allocator.deallocate(buffer, 2 * length);
   354       throw;
   355     }
   356     allocator.deallocate(buffer, 2 * length);
   357   }
   358 
   359   template <typename Value, typename Iterator, typename Functor>
   360   void counterUnsignedSort(Iterator first, Iterator last, Functor functor) {
   361     if (first == last) return;
   362     typedef typename std::iterator_traits<Iterator>::value_type Key;
   363     typedef std::allocator<Key> Allocator;
   364     Allocator allocator;
   365 
   366     int length = std::distance(first, last);
   367     Key *buffer;
   368     buffer = allocator.allocate(2 * length);
   369     try {
   370       bool dir = true;
   371       std::copy(first, last, buffer);
   372       for (int i = 0; i < (int)sizeof(Value); ++i) {
   373 	if (dir) {
   374 	  counterIntroSort(buffer, buffer + length, buffer + length, i, functor);
   375 	} else {
   376 	  counterIntroSort(buffer + length, buffer + 2 * length, buffer, i, functor);
   377 	}
   378 	dir = !dir;
   379       }
   380       if (dir) {
   381 	std::copy(buffer, buffer + length, first);
   382       }	else {
   383 	std::copy(buffer + length, buffer + 2 * length, first);
   384       }
   385     } catch (...) {
   386       allocator.deallocate(buffer, 2 * length);
   387       throw;
   388     }
   389     allocator.deallocate(buffer, 2 * length);
   390   }
   391 
   392   namespace _radix_sort_bits {
   393 
   394     template <typename Value, 
   395 	      bool sign = std::numeric_limits<Value>::is_signed >
   396     struct CounterSortSelector {
   397       template <typename Iterator, typename Functor>
   398       static void sort(Iterator first, Iterator last, Functor functor) {
   399 	counterSignedSort<Value>(first, last, functor);
   400       }
   401     };
   402 
   403     template <typename Value>
   404     struct CounterSortSelector<Value, false> {
   405       template <typename Iterator, typename Functor>
   406       static void sort(Iterator first, Iterator last, Functor functor) {
   407 	counterUnsignedSort<Value>(first, last, functor);
   408       }
   409     };
   410 
   411   }
   412 
   413   /// \ingroup auxdat
   414   ///
   415   /// \brief Sorts stable the stl compatible range into ascending order.
   416   ///
   417   /// The \c counterSort sorts the stl compatible range into ascending order.
   418   /// The counter sort algorithm can sort the items which mapped to an
   419   /// integer by the adaptable unary function \c functor and the order
   420   /// will be ascending by these mapped values. As function specialization
   421   /// there is possible to use a normal function as the functor object
   422   /// or if the functor is not given it will use an identity function instead.
   423   ///
   424   /// This implemented counter sort use a radix forward sort on the bytes of
   425   /// the integer. The algorithm can sort the items on a given byte. 
   426   /// First time it counts how many times occurs a byte value in the container.
   427   /// By the occurence number it is possible to copy the container
   428   /// in the right order in \c O(n) time. The algorithm sorts the container
   429   /// by each bytes in forward direction which sorts the container by the
   430   /// whole value. This way, let be \c c the maximal capacity of the integer 
   431   /// type and \c n the number of the items in
   432   /// the container, the time complexity of the algorithm \c O(log(c)*n)
   433   /// and the additional space complexity is \c O(n).
   434   ///
   435   /// This sorting algorithm is stable so the order of two equal element
   436   /// stay in the same order.
   437   ///
   438   /// \param first The begin of the given range.
   439   /// \param last The end of the given range.
   440   /// \param functor An adaptible unary function or a normal function which
   441   /// maps the items to any integer type which can be wheter signed or 
   442   /// unsigned.
   443   template <typename Iterator, typename Functor>
   444   void counterSort(Iterator first, Iterator last, Functor functor) {
   445     using namespace _radix_sort_bits;
   446     typedef typename Functor::result_type Value;
   447     CounterSortSelector<Value>::sort(first, last, functor);
   448   }
   449 
   450   template <typename Iterator, typename Value, typename Key>
   451   void counterSort(Iterator first, Iterator last, Value (*functor)(Key)) {
   452     using namespace _radix_sort_bits;
   453     CounterSortSelector<Value>::sort(first, last, functor);
   454   }
   455 
   456   template <typename Iterator, typename Value, typename Key>
   457   void counterSort(Iterator first, Iterator last, Value& (*functor)(Key)) {
   458     using namespace _radix_sort_bits;
   459     CounterSortSelector<Value>::sort(first, last, functor);
   460   }
   461 
   462   template <typename Iterator, typename Value, typename Key>
   463   void counterSort(Iterator first, Iterator last, Value (*functor)(Key&)) {
   464     using namespace _radix_sort_bits;
   465     CounterSortSelector<Value>::sort(first, last, functor);
   466   }
   467 
   468   template <typename Iterator, typename Value, typename Key>
   469   void counterSort(Iterator first, Iterator last, Value& (*functor)(Key&)) {
   470     using namespace _radix_sort_bits;
   471     CounterSortSelector<Value>::sort(first, last, functor);
   472   }
   473 
   474   template <typename Iterator>
   475   void counterSort(Iterator first, Iterator last) {
   476     using namespace _radix_sort_bits;
   477     typedef typename std::iterator_traits<Iterator>::value_type Value;
   478     CounterSortSelector<Value>::sort(first, last, Identity<Value>());
   479   }
   480 
   481 }
   482 
   483 
   484 
   485 #endif