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source: trunk/sources/HeuristicLab.Random/3.3/RandomEnumerable.cs @ 10906

Last change on this file since 10906 was 10503, checked in by gkronber, 11 years ago

#2146: minor efficiency tweak (removed unnecessary .ToArray() call)

File size: 13.6 KB
Line 
1#region License Information
2/* HeuristicLab
3 * Copyright (C) 2002-2013 Heuristic and Evolutionary Algorithms Laboratory (HEAL)
4 *
5 * This file is part of HeuristicLab.
6 *
7 * HeuristicLab is free software: you can redistribute it and/or modify
8 * it under the terms of the GNU General Public License as published by
9 * the Free Software Foundation, either version 3 of the License, or
10 * (at your option) any later version.
11 *
12 * HeuristicLab is distributed in the hope that it will be useful,
13 * but WITHOUT ANY WARRANTY; without even the implied warranty of
14 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
15 * GNU General Public License for more details.
16 *
17 * You should have received a copy of the GNU General Public License
18 * along with HeuristicLab. If not, see <http://www.gnu.org/licenses/>.
19 */
20#endregion
21
22using System;
23using System.Collections.Generic;
24using System.Linq;
25using HeuristicLab.Core;
26
27namespace HeuristicLab.Random {
28  public static class RandomEnumerable {
29    public static IEnumerable<int> SampleRandomNumbers(int maxElement, int count) {
30      return SampleRandomNumbers(Environment.TickCount, 0, maxElement, count);
31    }
32
33    public static IEnumerable<int> SampleRandomNumbers(int start, int end, int count) {
34      return SampleRandomNumbers(Environment.TickCount, start, end, count);
35    }
36
37    //algorithm taken from progamming pearls page 127
38    //IMPORTANT because IEnumerables with yield are used the seed must be specified to return always
39    //the same sequence of numbers without caching the values.
40    public static IEnumerable<int> SampleRandomNumbers(int seed, int start, int end, int count) {
41      int remaining = end - start;
42      var mt = new FastRandom(seed);
43      for (int i = start; i < end && count > 0; i++) {
44        double probability = mt.NextDouble();
45        if (probability < ((double)count) / remaining) {
46          count--;
47          yield return i;
48        }
49        remaining--;
50      }
51    }
52
53    /// <summary>
54    /// Chooses one elements from a sequence giving each element an equal chance.
55    /// </summary>
56    /// <remarks>
57    /// Runtime complexity is O(1) for sequences that are of type <see cref="IList{T}"/> and
58    /// O(N) for all other.
59    /// </remarks>
60    /// <exception cref="ArgumentException">If the sequence is empty.</exception>
61    /// <typeparam name="T">The type of the items to be selected.</typeparam>
62    /// <param name="source">The sequence of elements.</param>
63    /// <param name="random">The random number generator to use, its NextDouble() method must produce values in the range [0;1)</param>
64    /// <param name="count">The number of items to be selected.</param>
65    /// <returns>An element that has been chosen randomly from the sequence.</returns>
66    public static T SampleRandom<T>(this IEnumerable<T> source, IRandom random) {
67      if (!source.Any()) throw new ArgumentException("sequence is empty.", "source");
68      return source.SampleRandom(random, 1).First();
69    }
70
71    /// <summary>
72    /// Chooses <paramref name="count"/> elements from a sequence with repetition with equal chances for each element.
73    /// </summary>
74    /// <remarks>
75    /// Runtime complexity is O(count) for sequences that are <see cref="IList{T}"/> and
76    /// O(N * count) for all other. No exception is thrown if the sequence is empty.
77    ///
78    /// The method is online.
79    /// </remarks>
80    /// <typeparam name="T">The type of the items to be selected.</typeparam>
81    /// <param name="source">The sequence of elements.</param>
82    /// <param name="random">The random number generator to use, its NextDouble() method must produce values in the range [0;1)</param>
83    /// <param name="count">The number of items to be selected.</param>
84    /// <returns>A sequence of elements that have been chosen randomly.</returns>
85    public static IEnumerable<T> SampleRandom<T>(this IEnumerable<T> source, IRandom random, int count) {
86      var listSource = source as IList<T>;
87      if (listSource != null) {
88        while (count > 0) {
89          yield return listSource[random.Next(listSource.Count)];
90          count--;
91        }
92      } else {
93        while (count > 0) {
94          var enumerator = source.GetEnumerator();
95          enumerator.MoveNext();
96          T selectedItem = enumerator.Current;
97          int counter = 1;
98          while (enumerator.MoveNext()) {
99            counter++;
100            if (counter * random.NextDouble() < 1.0)
101              selectedItem = enumerator.Current;
102          }
103          yield return selectedItem;
104          count--;
105        }
106      }
107    }
108
109    /// <summary>
110    /// Chooses <paramref name="count"/> elements from a sequence without repetition with equal chances for each element.
111    /// The items are returned in the same order as they appear in the sequence.
112    /// </summary>
113    /// <remarks>
114    /// Runtime complexity is O(N) for all sequences.
115    /// No exception is thrown if the sequence contains less items than there are to be selected.
116    ///
117    /// The method is online.
118    /// </remarks>
119    /// <typeparam name="T">The type of the items to be selected.</typeparam>
120    /// <param name="source">The sequence of elements.</param>
121    /// <param name="random">The random number generator to use, its NextDouble() method must produce values in the range [0;1)</param>
122    /// <param name="count">The number of items to be selected.</param>
123    /// <param name="sourceCount">Optional parameter specifying the number of elements in the source enumerations</param>
124    /// <returns>A sequence of elements that have been chosen randomly.</returns>
125    public static IEnumerable<T> SampleRandomWithoutRepetition<T>(this IEnumerable<T> source, IRandom random, int count, int sourceCount = -1) {
126      if (sourceCount == -1) sourceCount = source.Count();
127      int remaining = sourceCount;
128      foreach (var item in source) {
129        if (random.NextDouble() * remaining < count) {
130          count--;
131          yield return item;
132          if (count <= 0) break;
133        }
134        remaining--;
135      }
136    }
137
138    /// <summary>
139    /// Chooses elements out of a sequence with repetition. The chance that an item is selected is proportional or inverse-proportional
140    /// to the <paramref name="weights"/>.
141    /// </summary>
142    /// <remarks>
143    /// In case both <paramref name="inverseProportional"/> and <paramref name="windowing"/> are false values must be &gt; 0,
144    /// otherwise an InvalidOperationException is thrown.
145    ///
146    /// The method internally holds two arrays: One that is the sequence itself and another one for the values.
147    /// </remarks>
148    /// <typeparam name="T">The type of the items to be selected.</typeparam>
149    /// <param name="source">The sequence of elements.</param>
150    /// <param name="random">The random number generator to use, its NextDouble() method must produce values in the range [0;1)</param>
151    /// <param name="count">The number of items to be selected.</param>
152    /// <param name="weights">The weight values for the items.</param>
153    /// <param name="windowing">Whether to scale the proportional values or not.</param>
154    /// <param name="inverseProportional">Determines whether to choose proportionally (false) or inverse-proportionally (true).</param>
155    /// <returns>A sequence of selected items. The sequence might contain the same item more than once.</returns>
156    public static IEnumerable<T> SampleProportional<T>(this IEnumerable<T> source, IRandom random, int count, IEnumerable<double> weights, bool windowing = true, bool inverseProportional = false) {
157      return source.SampleProportional(random, weights, windowing, inverseProportional).Take(count);
158    }
159
160    /// <summary>
161    /// Same as <seealso cref="SampleProportional<T>"/>, but chooses an item exactly once.
162    /// </summary>
163    /// <remarks>
164    /// In case both <paramref name="inverseProportional"/> and <paramref name="windowing"/> are false values must be &gt; 0,
165    /// otherwise an InvalidOperationException is thrown.
166    ///
167    /// The method internally holds two arrays: One that is the sequence itself and another one for the values.
168    ///
169    /// The method does not check if the number of elements in source and weights are the same.
170    /// </remarks>
171    /// <typeparam name="T">The type of the items to be selected.</typeparam>
172    /// <param name="source">The sequence of elements.</param>
173    /// <param name="random">The random number generator to use, its NextDouble() method must produce values in the range [0;1)</param>
174    /// <param name="count">The number of items to be selected.</param>
175    /// <param name="weights">The weight values for the items.</param>
176    /// <param name="windowing">Whether to scale the proportional values or not.</param>
177    /// <param name="inverseProportional">Determines whether to choose proportionally (true) or inverse-proportionally (false).</param>
178    /// <returns>A sequence of selected items. Might actually be shorter than <paramref name="count"/> elements if source has less than <paramref name="count"/> elements.</returns>
179    public static IEnumerable<T> SampleProportionalWithoutRepetition<T>(this IEnumerable<T> source, IRandom random, int count, IEnumerable<double> weights, bool windowing = true, bool inverseProportional = false) {
180      return source.SampleProportionalWithoutRepetition(random, weights, windowing, inverseProportional).Take(count);
181    }
182    #region Proportional Helpers
183    private static IEnumerable<T> SampleProportional<T>(this IEnumerable<T> source, IRandom random, IEnumerable<double> weights, bool windowing, bool inverseProportional) {
184      var sourceArray = source.ToArray();
185      var valueArray = PrepareProportional(weights, windowing, inverseProportional);
186      double total = valueArray.Sum();
187
188      while (true) {
189        int index = 0;
190        double ball = valueArray[index], sum = random.NextDouble() * total;
191        while (ball < sum)
192          ball += valueArray[++index];
193        yield return sourceArray[index];
194      }
195    }
196    private static IEnumerable<T> SampleProportionalWithoutRepetition<T>(this IEnumerable<T> source, IRandom random, IEnumerable<double> weights, bool windowing, bool inverseProportional) {
197      var valueArray = PrepareProportional(weights, windowing, inverseProportional);
198      var list = new LinkedList<Tuple<T, double>>(source.Zip(valueArray, Tuple.Create));
199      double total = valueArray.Sum();
200
201      while (list.Count > 0) {
202        var cur = list.First;
203        double ball = cur.Value.Item2, sum = random.NextDouble() * total; // assert: sum < total. When there is only one item remaining: sum < ball
204        while (ball < sum) {
205          cur = cur.Next;
206          ball += cur.Value.Item2;
207        }
208        yield return cur.Value.Item1;
209        list.Remove(cur);
210        total -= cur.Value.Item2;
211      }
212    }
213
214    private static double[] PrepareProportional(IEnumerable<double> weights, bool windowing, bool inverseProportional) {
215      double maxValue = double.MinValue, minValue = double.MaxValue;
216      double[] valueArray = weights.ToArray();
217
218      for (int i = 0; i < valueArray.Length; i++) {
219        if (valueArray[i] > maxValue) maxValue = valueArray[i];
220        if (valueArray[i] < minValue) minValue = valueArray[i];
221      }
222      if (minValue == maxValue) {  // all values are equal
223        for (int i = 0; i < valueArray.Length; i++) {
224          valueArray[i] = 1.0;
225        }
226      } else {
227        if (windowing) {
228          if (inverseProportional) InverseProportionalScale(valueArray, maxValue);
229          else ProportionalScale(valueArray, minValue);
230        } else {
231          if (minValue < 0.0) throw new InvalidOperationException("Proportional selection without windowing does not work with values < 0.");
232          if (inverseProportional) InverseProportionalScale(valueArray, 2 * maxValue);
233        }
234      }
235      return valueArray;
236    }
237    private static void ProportionalScale(double[] values, double minValue) {
238      for (int i = 0; i < values.Length; i++) {
239        values[i] = values[i] - minValue;
240      }
241    }
242    private static void InverseProportionalScale(double[] values, double maxValue) {
243      for (int i = 0; i < values.Length; i++) {
244        values[i] = maxValue - values[i];
245      }
246    }
247    #endregion
248
249    /// <summary>
250    /// Shuffles an enumerable and returns a new enumerable according to the Fisher-Yates shuffle.
251    /// </summary>
252    /// <remarks>
253    /// Note that the source enumerable is transformed into an array.
254    ///
255    /// The implementation is described in http://stackoverflow.com/questions/1287567/c-is-using-random-and-orderby-a-good-shuffle-algorithm.
256    /// </remarks>
257    /// <typeparam name="T">The type of the items that are to be shuffled.</typeparam>
258    /// <param name="source">The enumerable that contains the items.</param>
259    /// <param name="random">The random number generator, its Next(n) method must deliver uniformly distributed random numbers in the range [0;n).</param>
260    /// <returns>An enumerable with the elements shuffled.</returns>
261    public static IEnumerable<T> Shuffle<T>(this IEnumerable<T> source, IRandom random) {
262      T[] elements = source.ToArray();
263      for (int i = elements.Length - 1; i > 0; i--) {
264        // Swap element "i" with a random earlier element (including itself)
265        int swapIndex = random.Next(i + 1);
266        yield return elements[swapIndex];
267        elements[swapIndex] = elements[i];
268        // we don't actually perform the swap, we can forget about the
269        // swapped element because we already returned it.
270      }
271      yield return elements[0];
272    }
273  }
274}
275
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