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1 771 jeremybenn
/* Arrays.java -- Utility class with methods to operate on arrays
2
   Copyright (C) 1998, 1999, 2000, 2001, 2002, 2003, 2004, 2005, 2006, 2007,
3
   Free Software Foundation, Inc.
4
 
5
This file is part of GNU Classpath.
6
 
7
GNU Classpath 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 2, or (at your option)
10
any later version.
11
 
12
GNU Classpath is distributed in the hope that it will be useful, but
13
WITHOUT ANY WARRANTY; without even the implied warranty of
14
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU
15
General Public License for more details.
16
 
17
You should have received a copy of the GNU General Public License
18
along with GNU Classpath; see the file COPYING.  If not, write to the
19
Free Software Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA
20
02110-1301 USA.
21
 
22
Linking this library statically or dynamically with other modules is
23
making a combined work based on this library.  Thus, the terms and
24
conditions of the GNU General Public License cover the whole
25
combination.
26
 
27
As a special exception, the copyright holders of this library give you
28
permission to link this library with independent modules to produce an
29
executable, regardless of the license terms of these independent
30
modules, and to copy and distribute the resulting executable under
31
terms of your choice, provided that you also meet, for each linked
32
independent module, the terms and conditions of the license of that
33
module.  An independent module is a module which is not derived from
34
or based on this library.  If you modify this library, you may extend
35
this exception to your version of the library, but you are not
36
obligated to do so.  If you do not wish to do so, delete this
37
exception statement from your version. */
38
 
39
 
40
package java.util;
41
 
42
import gnu.java.lang.CPStringBuilder;
43
 
44
import java.io.Serializable;
45
import java.lang.reflect.Array;
46
 
47
/**
48
 * This class contains various static utility methods performing operations on
49
 * arrays, and a method to provide a List "view" of an array to facilitate
50
 * using arrays with Collection-based APIs. All methods throw a
51
 * {@link NullPointerException} if the parameter array is null.
52
 * <p>
53
 *
54
 * Implementations may use their own algorithms, but must obey the general
55
 * properties; for example, the sort must be stable and n*log(n) complexity.
56
 * Sun's implementation of sort, and therefore ours, is a tuned quicksort,
57
 * adapted from Jon L. Bentley and M. Douglas McIlroy's "Engineering a Sort
58
 * Function", Software-Practice and Experience, Vol. 23(11) P. 1249-1265
59
 * (November 1993). This algorithm offers n*log(n) performance on many data
60
 * sets that cause other quicksorts to degrade to quadratic performance.
61
 *
62
 * @author Original author unknown
63
 * @author Bryce McKinlay
64
 * @author Eric Blake (ebb9@email.byu.edu)
65
 * @see Comparable
66
 * @see Comparator
67
 * @since 1.2
68
 * @status updated to 1.4
69
 */
70
public class Arrays
71
{
72
  /**
73
   * This class is non-instantiable.
74
   */
75
  private Arrays()
76
  {
77
  }
78
 
79
 
80
// binarySearch
81
  /**
82
   * Perform a binary search of a byte array for a key. The array must be
83
   * sorted (as by the sort() method) - if it is not, the behaviour of this
84
   * method is undefined, and may be an infinite loop. If the array contains
85
   * the key more than once, any one of them may be found. Note: although the
86
   * specification allows for an infinite loop if the array is unsorted, it
87
   * will not happen in this implementation.
88
   *
89
   * @param a the array to search (must be sorted)
90
   * @param key the value to search for
91
   * @return the index at which the key was found, or -n-1 if it was not
92
   *         found, where n is the index of the first value higher than key or
93
   *         a.length if there is no such value.
94
   */
95
  public static int binarySearch(byte[] a, byte key)
96
  {
97
    if (a.length == 0)
98
      return -1;
99
    return binarySearch(a, 0, a.length - 1, key);
100
  }
101
 
102
  /**
103
   * Perform a binary search of a range of a byte array for a key. The range
104
   * must be sorted (as by the <code>sort(byte[], int, int)</code> method) -
105
   * if it is not, the behaviour of this method is undefined, and may be an
106
   * infinite loop. If the array contains the key more than once, any one of
107
   * them may be found. Note: although the specification allows for an infinite
108
   * loop if the array is unsorted, it will not happen in this implementation.
109
   *
110
   * @param a the array to search (must be sorted)
111
   * @param low the lowest index to search from.
112
   * @param hi the highest index to search to.
113
   * @param key the value to search for
114
   * @return the index at which the key was found, or -n-1 if it was not
115
   *         found, where n is the index of the first value higher than key or
116
   *         a.length if there is no such value.
117
   * @throws IllegalArgumentException if <code>low > hi</code>
118
   * @throws ArrayIndexOutOfBoundsException if <code>low < 0</code> or
119
   *                                        <code>hi > a.length</code>.
120
   */
121
  public static int binarySearch(byte[] a, int low, int hi, byte key)
122
  {
123
    if (low > hi)
124
      throw new IllegalArgumentException("The start index is higher than " +
125
                                         "the finish index.");
126
    if (low < 0 || hi > a.length)
127
      throw new ArrayIndexOutOfBoundsException("One of the indices is out " +
128
                                               "of bounds.");
129
    int mid = 0;
130
    while (low <= hi)
131
      {
132
        mid = (low + hi) >>> 1;
133
        final byte d = a[mid];
134
        if (d == key)
135
          return mid;
136
        else if (d > key)
137
          hi = mid - 1;
138
        else
139
          // This gets the insertion point right on the last loop.
140
          low = ++mid;
141
      }
142
    return -mid - 1;
143
  }
144
 
145
  /**
146
   * Perform a binary search of a char array for a key. The array must be
147
   * sorted (as by the sort() method) - if it is not, the behaviour of this
148
   * method is undefined, and may be an infinite loop. If the array contains
149
   * the key more than once, any one of them may be found. Note: although the
150
   * specification allows for an infinite loop if the array is unsorted, it
151
   * will not happen in this implementation.
152
   *
153
   * @param a the array to search (must be sorted)
154
   * @param key the value to search for
155
   * @return the index at which the key was found, or -n-1 if it was not
156
   *         found, where n is the index of the first value higher than key or
157
   *         a.length if there is no such value.
158
   */
159
  public static int binarySearch(char[] a, char key)
160
  {
161
    if (a.length == 0)
162
      return -1;
163
    return binarySearch(a, 0, a.length - 1, key);
164
  }
165
 
166
  /**
167
   * Perform a binary search of a range of a char array for a key. The range
168
   * must be sorted (as by the <code>sort(char[], int, int)</code> method) -
169
   * if it is not, the behaviour of this method is undefined, and may be an
170
   * infinite loop. If the array contains the key more than once, any one of
171
   * them may be found. Note: although the specification allows for an infinite
172
   * loop if the array is unsorted, it will not happen in this implementation.
173
   *
174
   * @param a the array to search (must be sorted)
175
   * @param low the lowest index to search from.
176
   * @param hi the highest index to search to.
177
   * @param key the value to search for
178
   * @return the index at which the key was found, or -n-1 if it was not
179
   *         found, where n is the index of the first value higher than key or
180
   *         a.length if there is no such value.
181
   * @throws IllegalArgumentException if <code>low > hi</code>
182
   * @throws ArrayIndexOutOfBoundsException if <code>low < 0</code> or
183
   *                                        <code>hi > a.length</code>.
184
   */
185
  public static int binarySearch(char[] a, int low, int hi, char key)
186
  {
187
    if (low > hi)
188
      throw new IllegalArgumentException("The start index is higher than " +
189
                                         "the finish index.");
190
    if (low < 0 || hi > a.length)
191
      throw new ArrayIndexOutOfBoundsException("One of the indices is out " +
192
                                               "of bounds.");
193
    int mid = 0;
194
    while (low <= hi)
195
      {
196
        mid = (low + hi) >>> 1;
197
        final char d = a[mid];
198
        if (d == key)
199
          return mid;
200
        else if (d > key)
201
          hi = mid - 1;
202
        else
203
          // This gets the insertion point right on the last loop.
204
          low = ++mid;
205
      }
206
    return -mid - 1;
207
  }
208
 
209
  /**
210
   * Perform a binary search of a short array for a key. The array must be
211
   * sorted (as by the sort() method) - if it is not, the behaviour of this
212
   * method is undefined, and may be an infinite loop. If the array contains
213
   * the key more than once, any one of them may be found. Note: although the
214
   * specification allows for an infinite loop if the array is unsorted, it
215
   * will not happen in this implementation.
216
   *
217
   * @param a the array to search (must be sorted)
218
   * @param key the value to search for
219
   * @return the index at which the key was found, or -n-1 if it was not
220
   *         found, where n is the index of the first value higher than key or
221
   *         a.length if there is no such value.
222
   */
223
  public static int binarySearch(short[] a, short key)
224
  {
225
    if (a.length == 0)
226
      return -1;
227
    return binarySearch(a, 0, a.length - 1, key);
228
  }
229
 
230
  /**
231
   * Perform a binary search of a range of a short array for a key. The range
232
   * must be sorted (as by the <code>sort(short[], int, int)</code> method) -
233
   * if it is not, the behaviour of this method is undefined, and may be an
234
   * infinite loop. If the array contains the key more than once, any one of
235
   * them may be found. Note: although the specification allows for an infinite
236
   * loop if the array is unsorted, it will not happen in this implementation.
237
   *
238
   * @param a the array to search (must be sorted)
239
   * @param low the lowest index to search from.
240
   * @param hi the highest index to search to.
241
   * @param key the value to search for
242
   * @return the index at which the key was found, or -n-1 if it was not
243
   *         found, where n is the index of the first value higher than key or
244
   *         a.length if there is no such value.
245
   * @throws IllegalArgumentException if <code>low > hi</code>
246
   * @throws ArrayIndexOutOfBoundsException if <code>low < 0</code> or
247
   *                                        <code>hi > a.length</code>.
248
   */
249
  public static int binarySearch(short[] a, int low, int hi, short key)
250
  {
251
    if (low > hi)
252
      throw new IllegalArgumentException("The start index is higher than " +
253
                                         "the finish index.");
254
    if (low < 0 || hi > a.length)
255
      throw new ArrayIndexOutOfBoundsException("One of the indices is out " +
256
                                               "of bounds.");
257
    int mid = 0;
258
    while (low <= hi)
259
      {
260
        mid = (low + hi) >>> 1;
261
        final short d = a[mid];
262
        if (d == key)
263
          return mid;
264
        else if (d > key)
265
          hi = mid - 1;
266
        else
267
          // This gets the insertion point right on the last loop.
268
          low = ++mid;
269
      }
270
    return -mid - 1;
271
  }
272
 
273
  /**
274
   * Perform a binary search of an int array for a key. The array must be
275
   * sorted (as by the sort() method) - if it is not, the behaviour of this
276
   * method is undefined, and may be an infinite loop. If the array contains
277
   * the key more than once, any one of them may be found. Note: although the
278
   * specification allows for an infinite loop if the array is unsorted, it
279
   * will not happen in this implementation.
280
   *
281
   * @param a the array to search (must be sorted)
282
   * @param key the value to search for
283
   * @return the index at which the key was found, or -n-1 if it was not
284
   *         found, where n is the index of the first value higher than key or
285
   *         a.length if there is no such value.
286
   */
287
  public static int binarySearch(int[] a, int key)
288
  {
289
    if (a.length == 0)
290
      return -1;
291
    return binarySearch(a, 0, a.length - 1, key);
292
  }
293
 
294
  /**
295
   * Perform a binary search of a range of an integer array for a key. The range
296
   * must be sorted (as by the <code>sort(int[], int, int)</code> method) -
297
   * if it is not, the behaviour of this method is undefined, and may be an
298
   * infinite loop. If the array contains the key more than once, any one of
299
   * them may be found. Note: although the specification allows for an infinite
300
   * loop if the array is unsorted, it will not happen in this implementation.
301
   *
302
   * @param a the array to search (must be sorted)
303
   * @param low the lowest index to search from.
304
   * @param hi the highest index to search to.
305
   * @param key the value to search for
306
   * @return the index at which the key was found, or -n-1 if it was not
307
   *         found, where n is the index of the first value higher than key or
308
   *         a.length if there is no such value.
309
   * @throws IllegalArgumentException if <code>low > hi</code>
310
   * @throws ArrayIndexOutOfBoundsException if <code>low < 0</code> or
311
   *                                        <code>hi > a.length</code>.
312
   */
313
  public static int binarySearch(int[] a, int low, int hi, int key)
314
  {
315
    if (low > hi)
316
      throw new IllegalArgumentException("The start index is higher than " +
317
                                         "the finish index.");
318
    if (low < 0 || hi > a.length)
319
      throw new ArrayIndexOutOfBoundsException("One of the indices is out " +
320
                                               "of bounds.");
321
    int mid = 0;
322
    while (low <= hi)
323
      {
324
        mid = (low + hi) >>> 1;
325
        final int d = a[mid];
326
        if (d == key)
327
          return mid;
328
        else if (d > key)
329
          hi = mid - 1;
330
        else
331
          // This gets the insertion point right on the last loop.
332
          low = ++mid;
333
      }
334
    return -mid - 1;
335
  }
336
 
337
  /**
338
   * Perform a binary search of a long array for a key. The array must be
339
   * sorted (as by the sort() method) - if it is not, the behaviour of this
340
   * method is undefined, and may be an infinite loop. If the array contains
341
   * the key more than once, any one of them may be found. Note: although the
342
   * specification allows for an infinite loop if the array is unsorted, it
343
   * will not happen in this implementation.
344
   *
345
   * @param a the array to search (must be sorted)
346
   * @param key the value to search for
347
   * @return the index at which the key was found, or -n-1 if it was not
348
   *         found, where n is the index of the first value higher than key or
349
   *         a.length if there is no such value.
350
   */
351
  public static int binarySearch(long[] a, long key)
352
  {
353
    if (a.length == 0)
354
      return -1;
355
    return binarySearch(a, 0, a.length - 1, key);
356
  }
357
 
358
  /**
359
   * Perform a binary search of a range of a long array for a key. The range
360
   * must be sorted (as by the <code>sort(long[], int, int)</code> method) -
361
   * if it is not, the behaviour of this method is undefined, and may be an
362
   * infinite loop. If the array contains the key more than once, any one of
363
   * them may be found. Note: although the specification allows for an infinite
364
   * loop if the array is unsorted, it will not happen in this implementation.
365
   *
366
   * @param a the array to search (must be sorted)
367
   * @param low the lowest index to search from.
368
   * @param hi the highest index to search to.
369
   * @param key the value to search for
370
   * @return the index at which the key was found, or -n-1 if it was not
371
   *         found, where n is the index of the first value higher than key or
372
   *         a.length if there is no such value.
373
   * @throws IllegalArgumentException if <code>low > hi</code>
374
   * @throws ArrayIndexOutOfBoundsException if <code>low < 0</code> or
375
   *                                        <code>hi > a.length</code>.
376
   */
377
  public static int binarySearch(long[] a, int low, int hi, long key)
378
  {
379
    if (low > hi)
380
      throw new IllegalArgumentException("The start index is higher than " +
381
                                         "the finish index.");
382
    if (low < 0 || hi > a.length)
383
      throw new ArrayIndexOutOfBoundsException("One of the indices is out " +
384
                                               "of bounds.");
385
    int mid = 0;
386
    while (low <= hi)
387
      {
388
        mid = (low + hi) >>> 1;
389
        final long d = a[mid];
390
        if (d == key)
391
          return mid;
392
        else if (d > key)
393
          hi = mid - 1;
394
        else
395
          // This gets the insertion point right on the last loop.
396
          low = ++mid;
397
      }
398
    return -mid - 1;
399
  }
400
 
401
  /**
402
   * Perform a binary search of a float array for a key. The array must be
403
   * sorted (as by the sort() method) - if it is not, the behaviour of this
404
   * method is undefined, and may be an infinite loop. If the array contains
405
   * the key more than once, any one of them may be found. Note: although the
406
   * specification allows for an infinite loop if the array is unsorted, it
407
   * will not happen in this implementation.
408
   *
409
   * @param a the array to search (must be sorted)
410
   * @param key the value to search for
411
   * @return the index at which the key was found, or -n-1 if it was not
412
   *         found, where n is the index of the first value higher than key or
413
   *         a.length if there is no such value.
414
   */
415
  public static int binarySearch(float[] a, float key)
416
  {
417
    if (a.length == 0)
418
      return -1;
419
    return binarySearch(a, 0, a.length - 1, key);
420
  }
421
 
422
  /**
423
   * Perform a binary search of a range of a float array for a key. The range
424
   * must be sorted (as by the <code>sort(float[], int, int)</code> method) -
425
   * if it is not, the behaviour of this method is undefined, and may be an
426
   * infinite loop. If the array contains the key more than once, any one of
427
   * them may be found. Note: although the specification allows for an infinite
428
   * loop if the array is unsorted, it will not happen in this implementation.
429
   *
430
   * @param a the array to search (must be sorted)
431
   * @param low the lowest index to search from.
432
   * @param hi the highest index to search to.
433
   * @param key the value to search for
434
   * @return the index at which the key was found, or -n-1 if it was not
435
   *         found, where n is the index of the first value higher than key or
436
   *         a.length if there is no such value.
437
   * @throws IllegalArgumentException if <code>low > hi</code>
438
   * @throws ArrayIndexOutOfBoundsException if <code>low < 0</code> or
439
   *                                        <code>hi > a.length</code>.
440
   */
441
  public static int binarySearch(float[] a, int low, int hi, float key)
442
  {
443
    if (low > hi)
444
      throw new IllegalArgumentException("The start index is higher than " +
445
                                         "the finish index.");
446
    if (low < 0 || hi > a.length)
447
      throw new ArrayIndexOutOfBoundsException("One of the indices is out " +
448
                                               "of bounds.");
449
    // Must use Float.compare to take into account NaN, +-0.
450
    int mid = 0;
451
    while (low <= hi)
452
      {
453
        mid = (low + hi) >>> 1;
454
        final int r = Float.compare(a[mid], key);
455
        if (r == 0)
456
          return mid;
457
        else if (r > 0)
458
          hi = mid - 1;
459
        else
460
          // This gets the insertion point right on the last loop
461
          low = ++mid;
462
      }
463
    return -mid - 1;
464
  }
465
 
466
  /**
467
   * Perform a binary search of a double array for a key. The array must be
468
   * sorted (as by the sort() method) - if it is not, the behaviour of this
469
   * method is undefined, and may be an infinite loop. If the array contains
470
   * the key more than once, any one of them may be found. Note: although the
471
   * specification allows for an infinite loop if the array is unsorted, it
472
   * will not happen in this implementation.
473
   *
474
   * @param a the array to search (must be sorted)
475
   * @param key the value to search for
476
   * @return the index at which the key was found, or -n-1 if it was not
477
   *         found, where n is the index of the first value higher than key or
478
   *         a.length if there is no such value.
479
   */
480
  public static int binarySearch(double[] a, double key)
481
  {
482
    if (a.length == 0)
483
      return -1;
484
    return binarySearch(a, 0, a.length - 1, key);
485
  }
486
 
487
  /**
488
   * Perform a binary search of a range of a double array for a key. The range
489
   * must be sorted (as by the <code>sort(double[], int, int)</code> method) -
490
   * if it is not, the behaviour of this method is undefined, and may be an
491
   * infinite loop. If the array contains the key more than once, any one of
492
   * them may be found. Note: although the specification allows for an infinite
493
   * loop if the array is unsorted, it will not happen in this implementation.
494
   *
495
   * @param a the array to search (must be sorted)
496
   * @param low the lowest index to search from.
497
   * @param hi the highest index to search to.
498
   * @param key the value to search for
499
   * @return the index at which the key was found, or -n-1 if it was not
500
   *         found, where n is the index of the first value higher than key or
501
   *         a.length if there is no such value.
502
   * @throws IllegalArgumentException if <code>low > hi</code>
503
   * @throws ArrayIndexOutOfBoundsException if <code>low < 0</code> or
504
   *                                        <code>hi > a.length</code>.
505
   */
506
  public static int binarySearch(double[] a, int low, int hi, double key)
507
  {
508
    if (low > hi)
509
      throw new IllegalArgumentException("The start index is higher than " +
510
                                         "the finish index.");
511
    if (low < 0 || hi > a.length)
512
      throw new ArrayIndexOutOfBoundsException("One of the indices is out " +
513
                                               "of bounds.");
514
    // Must use Double.compare to take into account NaN, +-0.
515
    int mid = 0;
516
    while (low <= hi)
517
      {
518
        mid = (low + hi) >>> 1;
519
        final int r = Double.compare(a[mid], key);
520
        if (r == 0)
521
          return mid;
522
        else if (r > 0)
523
          hi = mid - 1;
524
        else
525
          // This gets the insertion point right on the last loop
526
          low = ++mid;
527
      }
528
    return -mid - 1;
529
  }
530
 
531
  /**
532
   * Perform a binary search of an Object array for a key, using the natural
533
   * ordering of the elements. The array must be sorted (as by the sort()
534
   * method) - if it is not, the behaviour of this method is undefined, and may
535
   * be an infinite loop. Further, the key must be comparable with every item
536
   * in the array. If the array contains the key more than once, any one of
537
   * them may be found. Note: although the specification allows for an infinite
538
   * loop if the array is unsorted, it will not happen in this (JCL)
539
   * implementation.
540
   *
541
   * @param a the array to search (must be sorted)
542
   * @param key the value to search for
543
   * @return the index at which the key was found, or -n-1 if it was not
544
   *         found, where n is the index of the first value higher than key or
545
   *         a.length if there is no such value.
546
   * @throws ClassCastException if key could not be compared with one of the
547
   *         elements of a
548
   * @throws NullPointerException if a null element in a is compared
549
   */
550
  public static int binarySearch(Object[] a, Object key)
551
  {
552
    if (a.length == 0)
553
      return -1;
554
    return binarySearch(a, key, null);
555
  }
556
 
557
  /**
558
   * Perform a binary search of a range of an Object array for a key. The range
559
   * must be sorted (as by the <code>sort(Object[], int, int)</code> method) -
560
   * if it is not, the behaviour of this method is undefined, and may be an
561
   * infinite loop. If the array contains the key more than once, any one of
562
   * them may be found. Note: although the specification allows for an infinite
563
   * loop if the array is unsorted, it will not happen in this implementation.
564
   *
565
   * @param a the array to search (must be sorted)
566
   * @param low the lowest index to search from.
567
   * @param hi the highest index to search to.
568
   * @param key the value to search for
569
   * @return the index at which the key was found, or -n-1 if it was not
570
   *         found, where n is the index of the first value higher than key or
571
   *         a.length if there is no such value.
572
   */
573
  public static int binarySearch(Object[] a, int low, int hi, Object key)
574
  {
575
    return binarySearch(a, low, hi, key, null);
576
  }
577
 
578
  /**
579
   * Perform a binary search of an Object array for a key, using a supplied
580
   * Comparator. The array must be sorted (as by the sort() method with the
581
   * same Comparator) - if it is not, the behaviour of this method is
582
   * undefined, and may be an infinite loop. Further, the key must be
583
   * comparable with every item in the array. If the array contains the key
584
   * more than once, any one of them may be found. Note: although the
585
   * specification allows for an infinite loop if the array is unsorted, it
586
   * will not happen in this (JCL) implementation.
587
   *
588
   * @param a the array to search (must be sorted)
589
   * @param key the value to search for
590
   * @param c the comparator by which the array is sorted; or null to
591
   *        use the elements' natural order
592
   * @return the index at which the key was found, or -n-1 if it was not
593
   *         found, where n is the index of the first value higher than key or
594
   *         a.length if there is no such value.
595
   * @throws ClassCastException if key could not be compared with one of the
596
   *         elements of a
597
   * @throws NullPointerException if a null element is compared with natural
598
   *         ordering (only possible when c is null)
599
   */
600
  public static <T> int binarySearch(T[] a, T key, Comparator<? super T> c)
601
  {
602
    if (a.length == 0)
603
      return -1;
604
    return binarySearch(a, 0, a.length - 1, key, c);
605
  }
606
 
607
  /**
608
   * Perform a binary search of a range of an Object array for a key using
609
   * a {@link Comparator}. The range must be sorted (as by the
610
   * <code>sort(Object[], int, int)</code> method) - if it is not, the
611
   * behaviour of this method is undefined, and may be an infinite loop. If
612
   * the array contains the key more than once, any one of them may be found.
613
   * Note: although the specification allows for an infinite loop if the array
614
   * is unsorted, it will not happen in this implementation.
615
   *
616
   * @param a the array to search (must be sorted)
617
   * @param low the lowest index to search from.
618
   * @param hi the highest index to search to.
619
   * @param key the value to search for
620
   * @param c the comparator by which the array is sorted; or null to
621
   *        use the elements' natural order
622
   * @return the index at which the key was found, or -n-1 if it was not
623
   *         found, where n is the index of the first value higher than key or
624
   *         a.length if there is no such value.
625
   * @throws ClassCastException if key could not be compared with one of the
626
   *         elements of a
627
   * @throws IllegalArgumentException if <code>low > hi</code>
628
   * @throws ArrayIndexOutOfBoundsException if <code>low < 0</code> or
629
   *                                        <code>hi > a.length</code>.
630
   */
631
  public static <T> int binarySearch(T[] a, int low, int hi, T key,
632
                                     Comparator<? super T> c)
633
  {
634
    if (low > hi)
635
      throw new IllegalArgumentException("The start index is higher than " +
636
                                         "the finish index.");
637
    if (low < 0 || hi > a.length)
638
      throw new ArrayIndexOutOfBoundsException("One of the indices is out " +
639
                                               "of bounds.");
640
    int mid = 0;
641
    while (low <= hi)
642
      {
643
        mid = (low + hi) >>> 1;
644
        // NOTE: Please keep the order of a[mid] and key.  Although
645
        // not required by the specs, the RI has it in this order as
646
        // well, and real programs (erroneously) depend on it.
647
        final int d = Collections.compare(a[mid], key, c);
648
        if (d == 0)
649
          return mid;
650
        else if (d > 0)
651
          hi = mid - 1;
652
        else
653
          // This gets the insertion point right on the last loop
654
          low = ++mid;
655
      }
656
    return -mid - 1;
657
  }
658
 
659
 
660
// equals
661
  /**
662
   * Compare two boolean arrays for equality.
663
   *
664
   * @param a1 the first array to compare
665
   * @param a2 the second array to compare
666
   * @return true if a1 and a2 are both null, or if a2 is of the same length
667
   *         as a1, and for each 0 <= i < a1.length, a1[i] == a2[i]
668
   */
669
  public static boolean equals(boolean[] a1, boolean[] a2)
670
  {
671
    // Quick test which saves comparing elements of the same array, and also
672
    // catches the case that both are null.
673
    if (a1 == a2)
674
      return true;
675
 
676
    if (null == a1 || null == a2)
677
      return false;
678
 
679
    // If they're the same length, test each element
680
    if (a1.length == a2.length)
681
      {
682
        int i = a1.length;
683
        while (--i >= 0)
684
          if (a1[i] != a2[i])
685
            return false;
686
        return true;
687
      }
688
    return false;
689
  }
690
 
691
  /**
692
   * Compare two byte arrays for equality.
693
   *
694
   * @param a1 the first array to compare
695
   * @param a2 the second array to compare
696
   * @return true if a1 and a2 are both null, or if a2 is of the same length
697
   *         as a1, and for each 0 <= i < a1.length, a1[i] == a2[i]
698
   */
699
  public static boolean equals(byte[] a1, byte[] a2)
700
  {
701
    // Quick test which saves comparing elements of the same array, and also
702
    // catches the case that both are null.
703
    if (a1 == a2)
704
      return true;
705
 
706
    if (null == a1 || null == a2)
707
      return false;
708
 
709
    // If they're the same length, test each element
710
    if (a1.length == a2.length)
711
      {
712
        int i = a1.length;
713
        while (--i >= 0)
714
          if (a1[i] != a2[i])
715
            return false;
716
        return true;
717
      }
718
    return false;
719
  }
720
 
721
  /**
722
   * Compare two char arrays for equality.
723
   *
724
   * @param a1 the first array to compare
725
   * @param a2 the second array to compare
726
   * @return true if a1 and a2 are both null, or if a2 is of the same length
727
   *         as a1, and for each 0 <= i < a1.length, a1[i] == a2[i]
728
   */
729
  public static boolean equals(char[] a1, char[] a2)
730
  {
731
    // Quick test which saves comparing elements of the same array, and also
732
    // catches the case that both are null.
733
    if (a1 == a2)
734
      return true;
735
 
736
    if (null == a1 || null == a2)
737
      return false;
738
 
739
    // If they're the same length, test each element
740
    if (a1.length == a2.length)
741
      {
742
        int i = a1.length;
743
        while (--i >= 0)
744
          if (a1[i] != a2[i])
745
            return false;
746
        return true;
747
      }
748
    return false;
749
  }
750
 
751
  /**
752
   * Compare two short arrays for equality.
753
   *
754
   * @param a1 the first array to compare
755
   * @param a2 the second array to compare
756
   * @return true if a1 and a2 are both null, or if a2 is of the same length
757
   *         as a1, and for each 0 <= i < a1.length, a1[i] == a2[i]
758
   */
759
  public static boolean equals(short[] a1, short[] a2)
760
  {
761
    // Quick test which saves comparing elements of the same array, and also
762
    // catches the case that both are null.
763
    if (a1 == a2)
764
      return true;
765
 
766
    if (null == a1 || null == a2)
767
      return false;
768
 
769
    // If they're the same length, test each element
770
    if (a1.length == a2.length)
771
      {
772
        int i = a1.length;
773
        while (--i >= 0)
774
          if (a1[i] != a2[i])
775
            return false;
776
        return true;
777
      }
778
    return false;
779
  }
780
 
781
  /**
782
   * Compare two int arrays for equality.
783
   *
784
   * @param a1 the first array to compare
785
   * @param a2 the second array to compare
786
   * @return true if a1 and a2 are both null, or if a2 is of the same length
787
   *         as a1, and for each 0 <= i < a1.length, a1[i] == a2[i]
788
   */
789
  public static boolean equals(int[] a1, int[] a2)
790
  {
791
    // Quick test which saves comparing elements of the same array, and also
792
    // catches the case that both are null.
793
    if (a1 == a2)
794
      return true;
795
 
796
    if (null == a1 || null == a2)
797
      return false;
798
 
799
    // If they're the same length, test each element
800
    if (a1.length == a2.length)
801
      {
802
        int i = a1.length;
803
        while (--i >= 0)
804
          if (a1[i] != a2[i])
805
            return false;
806
        return true;
807
      }
808
    return false;
809
  }
810
 
811
  /**
812
   * Compare two long arrays for equality.
813
   *
814
   * @param a1 the first array to compare
815
   * @param a2 the second array to compare
816
   * @return true if a1 and a2 are both null, or if a2 is of the same length
817
   *         as a1, and for each 0 <= i < a1.length, a1[i] == a2[i]
818
   */
819
  public static boolean equals(long[] a1, long[] a2)
820
  {
821
    // Quick test which saves comparing elements of the same array, and also
822
    // catches the case that both are null.
823
    if (a1 == a2)
824
      return true;
825
 
826
    if (null == a1 || null == a2)
827
      return false;
828
 
829
    // If they're the same length, test each element
830
    if (a1.length == a2.length)
831
      {
832
        int i = a1.length;
833
        while (--i >= 0)
834
          if (a1[i] != a2[i])
835
            return false;
836
        return true;
837
      }
838
    return false;
839
  }
840
 
841
  /**
842
   * Compare two float arrays for equality.
843
   *
844
   * @param a1 the first array to compare
845
   * @param a2 the second array to compare
846
   * @return true if a1 and a2 are both null, or if a2 is of the same length
847
   *         as a1, and for each 0 <= i < a1.length, a1[i] == a2[i]
848
   */
849
  public static boolean equals(float[] a1, float[] a2)
850
  {
851
    // Quick test which saves comparing elements of the same array, and also
852
    // catches the case that both are null.
853
    if (a1 == a2)
854
      return true;
855
 
856
    if (null == a1 || null == a2)
857
      return false;
858
 
859
    // Must use Float.compare to take into account NaN, +-0.
860
    // If they're the same length, test each element
861
    if (a1.length == a2.length)
862
      {
863
        int i = a1.length;
864
        while (--i >= 0)
865
          if (Float.compare(a1[i], a2[i]) != 0)
866
            return false;
867
        return true;
868
      }
869
    return false;
870
  }
871
 
872
  /**
873
   * Compare two double arrays for equality.
874
   *
875
   * @param a1 the first array to compare
876
   * @param a2 the second array to compare
877
   * @return true if a1 and a2 are both null, or if a2 is of the same length
878
   *         as a1, and for each 0 <= i < a1.length, a1[i] == a2[i]
879
   */
880
  public static boolean equals(double[] a1, double[] a2)
881
  {
882
    // Quick test which saves comparing elements of the same array, and also
883
    // catches the case that both are null.
884
    if (a1 == a2)
885
      return true;
886
 
887
    if (null == a1 || null == a2)
888
      return false;
889
 
890
    // Must use Double.compare to take into account NaN, +-0.
891
    // If they're the same length, test each element
892
    if (a1.length == a2.length)
893
      {
894
        int i = a1.length;
895
        while (--i >= 0)
896
          if (Double.compare(a1[i], a2[i]) != 0)
897
            return false;
898
        return true;
899
      }
900
    return false;
901
  }
902
 
903
  /**
904
   * Compare two Object arrays for equality.
905
   *
906
   * @param a1 the first array to compare
907
   * @param a2 the second array to compare
908
   * @return true if a1 and a2 are both null, or if a1 is of the same length
909
   *         as a2, and for each 0 <= i < a.length, a1[i] == null ?
910
   *         a2[i] == null : a1[i].equals(a2[i]).
911
   */
912
  public static boolean equals(Object[] a1, Object[] a2)
913
  {
914
    // Quick test which saves comparing elements of the same array, and also
915
    // catches the case that both are null.
916
    if (a1 == a2)
917
      return true;
918
 
919
    if (null == a1 || null == a2)
920
      return false;
921
 
922
    // If they're the same length, test each element
923
    if (a1.length == a2.length)
924
      {
925
        int i = a1.length;
926
        while (--i >= 0)
927
          if (! AbstractCollection.equals(a1[i], a2[i]))
928
            return false;
929
        return true;
930
      }
931
    return false;
932
  }
933
 
934
 
935
// fill
936
  /**
937
   * Fill an array with a boolean value.
938
   *
939
   * @param a the array to fill
940
   * @param val the value to fill it with
941
   */
942
  public static void fill(boolean[] a, boolean val)
943
  {
944
    fill(a, 0, a.length, val);
945
  }
946
 
947
  /**
948
   * Fill a range of an array with a boolean value.
949
   *
950
   * @param a the array to fill
951
   * @param fromIndex the index to fill from, inclusive
952
   * @param toIndex the index to fill to, exclusive
953
   * @param val the value to fill with
954
   * @throws IllegalArgumentException if fromIndex &gt; toIndex
955
   * @throws ArrayIndexOutOfBoundsException if fromIndex &lt; 0
956
   *         || toIndex &gt; a.length
957
   */
958
  public static void fill(boolean[] a, int fromIndex, int toIndex, boolean val)
959
  {
960
    if (fromIndex > toIndex)
961
      throw new IllegalArgumentException();
962
    for (int i = fromIndex; i < toIndex; i++)
963
      a[i] = val;
964
  }
965
 
966
  /**
967
   * Fill an array with a byte value.
968
   *
969
   * @param a the array to fill
970
   * @param val the value to fill it with
971
   */
972
  public static void fill(byte[] a, byte val)
973
  {
974
    fill(a, 0, a.length, val);
975
  }
976
 
977
  /**
978
   * Fill a range of an array with a byte value.
979
   *
980
   * @param a the array to fill
981
   * @param fromIndex the index to fill from, inclusive
982
   * @param toIndex the index to fill to, exclusive
983
   * @param val the value to fill with
984
   * @throws IllegalArgumentException if fromIndex &gt; toIndex
985
   * @throws ArrayIndexOutOfBoundsException if fromIndex &lt; 0
986
   *         || toIndex &gt; a.length
987
   */
988
  public static void fill(byte[] a, int fromIndex, int toIndex, byte val)
989
  {
990
    if (fromIndex > toIndex)
991
      throw new IllegalArgumentException();
992
    for (int i = fromIndex; i < toIndex; i++)
993
      a[i] = val;
994
  }
995
 
996
  /**
997
   * Fill an array with a char value.
998
   *
999
   * @param a the array to fill
1000
   * @param val the value to fill it with
1001
   */
1002
  public static void fill(char[] a, char val)
1003
  {
1004
    fill(a, 0, a.length, val);
1005
  }
1006
 
1007
  /**
1008
   * Fill a range of an array with a char value.
1009
   *
1010
   * @param a the array to fill
1011
   * @param fromIndex the index to fill from, inclusive
1012
   * @param toIndex the index to fill to, exclusive
1013
   * @param val the value to fill with
1014
   * @throws IllegalArgumentException if fromIndex &gt; toIndex
1015
   * @throws ArrayIndexOutOfBoundsException if fromIndex &lt; 0
1016
   *         || toIndex &gt; a.length
1017
   */
1018
  public static void fill(char[] a, int fromIndex, int toIndex, char val)
1019
  {
1020
    if (fromIndex > toIndex)
1021
      throw new IllegalArgumentException();
1022
    for (int i = fromIndex; i < toIndex; i++)
1023
      a[i] = val;
1024
  }
1025
 
1026
  /**
1027
   * Fill an array with a short value.
1028
   *
1029
   * @param a the array to fill
1030
   * @param val the value to fill it with
1031
   */
1032
  public static void fill(short[] a, short val)
1033
  {
1034
    fill(a, 0, a.length, val);
1035
  }
1036
 
1037
  /**
1038
   * Fill a range of an array with a short value.
1039
   *
1040
   * @param a the array to fill
1041
   * @param fromIndex the index to fill from, inclusive
1042
   * @param toIndex the index to fill to, exclusive
1043
   * @param val the value to fill with
1044
   * @throws IllegalArgumentException if fromIndex &gt; toIndex
1045
   * @throws ArrayIndexOutOfBoundsException if fromIndex &lt; 0
1046
   *         || toIndex &gt; a.length
1047
   */
1048
  public static void fill(short[] a, int fromIndex, int toIndex, short val)
1049
  {
1050
    if (fromIndex > toIndex)
1051
      throw new IllegalArgumentException();
1052
    for (int i = fromIndex; i < toIndex; i++)
1053
      a[i] = val;
1054
  }
1055
 
1056
  /**
1057
   * Fill an array with an int value.
1058
   *
1059
   * @param a the array to fill
1060
   * @param val the value to fill it with
1061
   */
1062
  public static void fill(int[] a, int val)
1063
  {
1064
    fill(a, 0, a.length, val);
1065
  }
1066
 
1067
  /**
1068
   * Fill a range of an array with an int value.
1069
   *
1070
   * @param a the array to fill
1071
   * @param fromIndex the index to fill from, inclusive
1072
   * @param toIndex the index to fill to, exclusive
1073
   * @param val the value to fill with
1074
   * @throws IllegalArgumentException if fromIndex &gt; toIndex
1075
   * @throws ArrayIndexOutOfBoundsException if fromIndex &lt; 0
1076
   *         || toIndex &gt; a.length
1077
   */
1078
  public static void fill(int[] a, int fromIndex, int toIndex, int val)
1079
  {
1080
    if (fromIndex > toIndex)
1081
      throw new IllegalArgumentException();
1082
    for (int i = fromIndex; i < toIndex; i++)
1083
      a[i] = val;
1084
  }
1085
 
1086
  /**
1087
   * Fill an array with a long value.
1088
   *
1089
   * @param a the array to fill
1090
   * @param val the value to fill it with
1091
   */
1092
  public static void fill(long[] a, long val)
1093
  {
1094
    fill(a, 0, a.length, val);
1095
  }
1096
 
1097
  /**
1098
   * Fill a range of an array with a long value.
1099
   *
1100
   * @param a the array to fill
1101
   * @param fromIndex the index to fill from, inclusive
1102
   * @param toIndex the index to fill to, exclusive
1103
   * @param val the value to fill with
1104
   * @throws IllegalArgumentException if fromIndex &gt; toIndex
1105
   * @throws ArrayIndexOutOfBoundsException if fromIndex &lt; 0
1106
   *         || toIndex &gt; a.length
1107
   */
1108
  public static void fill(long[] a, int fromIndex, int toIndex, long val)
1109
  {
1110
    if (fromIndex > toIndex)
1111
      throw new IllegalArgumentException();
1112
    for (int i = fromIndex; i < toIndex; i++)
1113
      a[i] = val;
1114
  }
1115
 
1116
  /**
1117
   * Fill an array with a float value.
1118
   *
1119
   * @param a the array to fill
1120
   * @param val the value to fill it with
1121
   */
1122
  public static void fill(float[] a, float val)
1123
  {
1124
    fill(a, 0, a.length, val);
1125
  }
1126
 
1127
  /**
1128
   * Fill a range of an array with a float value.
1129
   *
1130
   * @param a the array to fill
1131
   * @param fromIndex the index to fill from, inclusive
1132
   * @param toIndex the index to fill to, exclusive
1133
   * @param val the value to fill with
1134
   * @throws IllegalArgumentException if fromIndex &gt; toIndex
1135
   * @throws ArrayIndexOutOfBoundsException if fromIndex &lt; 0
1136
   *         || toIndex &gt; a.length
1137
   */
1138
  public static void fill(float[] a, int fromIndex, int toIndex, float val)
1139
  {
1140
    if (fromIndex > toIndex)
1141
      throw new IllegalArgumentException();
1142
    for (int i = fromIndex; i < toIndex; i++)
1143
      a[i] = val;
1144
  }
1145
 
1146
  /**
1147
   * Fill an array with a double value.
1148
   *
1149
   * @param a the array to fill
1150
   * @param val the value to fill it with
1151
   */
1152
  public static void fill(double[] a, double val)
1153
  {
1154
    fill(a, 0, a.length, val);
1155
  }
1156
 
1157
  /**
1158
   * Fill a range of an array with a double value.
1159
   *
1160
   * @param a the array to fill
1161
   * @param fromIndex the index to fill from, inclusive
1162
   * @param toIndex the index to fill to, exclusive
1163
   * @param val the value to fill with
1164
   * @throws IllegalArgumentException if fromIndex &gt; toIndex
1165
   * @throws ArrayIndexOutOfBoundsException if fromIndex &lt; 0
1166
   *         || toIndex &gt; a.length
1167
   */
1168
  public static void fill(double[] a, int fromIndex, int toIndex, double val)
1169
  {
1170
    if (fromIndex > toIndex)
1171
      throw new IllegalArgumentException();
1172
    for (int i = fromIndex; i < toIndex; i++)
1173
      a[i] = val;
1174
  }
1175
 
1176
  /**
1177
   * Fill an array with an Object value.
1178
   *
1179
   * @param a the array to fill
1180
   * @param val the value to fill it with
1181
   * @throws ClassCastException if val is not an instance of the element
1182
   *         type of a.
1183
   */
1184
  public static void fill(Object[] a, Object val)
1185
  {
1186
    fill(a, 0, a.length, val);
1187
  }
1188
 
1189
  /**
1190
   * Fill a range of an array with an Object value.
1191
   *
1192
   * @param a the array to fill
1193
   * @param fromIndex the index to fill from, inclusive
1194
   * @param toIndex the index to fill to, exclusive
1195
   * @param val the value to fill with
1196
   * @throws ClassCastException if val is not an instance of the element
1197
   *         type of a.
1198
   * @throws IllegalArgumentException if fromIndex &gt; toIndex
1199
   * @throws ArrayIndexOutOfBoundsException if fromIndex &lt; 0
1200
   *         || toIndex &gt; a.length
1201
   */
1202
  public static void fill(Object[] a, int fromIndex, int toIndex, Object val)
1203
  {
1204
    if (fromIndex > toIndex)
1205
      throw new IllegalArgumentException();
1206
    for (int i = fromIndex; i < toIndex; i++)
1207
      a[i] = val;
1208
  }
1209
 
1210
 
1211
// sort
1212
  // Thanks to Paul Fisher (rao@gnu.org) for finding this quicksort algorithm
1213
  // as specified by Sun and porting it to Java. The algorithm is an optimised
1214
  // quicksort, as described in Jon L. Bentley and M. Douglas McIlroy's
1215
  // "Engineering a Sort Function", Software-Practice and Experience, Vol.
1216
  // 23(11) P. 1249-1265 (November 1993). This algorithm gives n*log(n)
1217
  // performance on many arrays that would take quadratic time with a standard
1218
  // quicksort.
1219
 
1220
  /**
1221
   * Performs a stable sort on the elements, arranging them according to their
1222
   * natural order.
1223
   *
1224
   * @param a the byte array to sort
1225
   */
1226
  public static void sort(byte[] a)
1227
  {
1228
    qsort(a, 0, a.length);
1229
  }
1230
 
1231
  /**
1232
   * Performs a stable sort on the elements, arranging them according to their
1233
   * natural order.
1234
   *
1235
   * @param a the byte array to sort
1236
   * @param fromIndex the first index to sort (inclusive)
1237
   * @param toIndex the last index to sort (exclusive)
1238
   * @throws IllegalArgumentException if fromIndex &gt; toIndex
1239
   * @throws ArrayIndexOutOfBoundsException if fromIndex &lt; 0
1240
   *         || toIndex &gt; a.length
1241
   */
1242
  public static void sort(byte[] a, int fromIndex, int toIndex)
1243
  {
1244
    if (fromIndex > toIndex)
1245
      throw new IllegalArgumentException();
1246
    if (fromIndex < 0)
1247
      throw new ArrayIndexOutOfBoundsException();
1248
    qsort(a, fromIndex, toIndex - fromIndex);
1249
  }
1250
 
1251
  /**
1252
   * Finds the index of the median of three array elements.
1253
   *
1254
   * @param a the first index
1255
   * @param b the second index
1256
   * @param c the third index
1257
   * @param d the array
1258
   * @return the index (a, b, or c) which has the middle value of the three
1259
   */
1260
  private static int med3(int a, int b, int c, byte[] d)
1261
  {
1262
    return (d[a] < d[b]
1263
            ? (d[b] < d[c] ? b : d[a] < d[c] ? c : a)
1264
            : (d[b] > d[c] ? b : d[a] > d[c] ? c : a));
1265
  }
1266
 
1267
  /**
1268
   * Swaps the elements at two locations of an array
1269
   *
1270
   * @param i the first index
1271
   * @param j the second index
1272
   * @param a the array
1273
   */
1274
  private static void swap(int i, int j, byte[] a)
1275
  {
1276
    byte c = a[i];
1277
    a[i] = a[j];
1278
    a[j] = c;
1279
  }
1280
 
1281
  /**
1282
   * Swaps two ranges of an array.
1283
   *
1284
   * @param i the first range start
1285
   * @param j the second range start
1286
   * @param n the element count
1287
   * @param a the array
1288
   */
1289
  private static void vecswap(int i, int j, int n, byte[] a)
1290
  {
1291
    for ( ; n > 0; i++, j++, n--)
1292
      swap(i, j, a);
1293
  }
1294
 
1295
  /**
1296
   * Performs a recursive modified quicksort.
1297
   *
1298
   * @param array the array to sort
1299
   * @param from the start index (inclusive)
1300
   * @param count the number of elements to sort
1301
   */
1302
  private static void qsort(byte[] array, int from, int count)
1303
  {
1304
    // Use an insertion sort on small arrays.
1305
    if (count <= 7)
1306
      {
1307
        for (int i = from + 1; i < from + count; i++)
1308
          for (int j = i; j > from && array[j - 1] > array[j]; j--)
1309
            swap(j, j - 1, array);
1310
        return;
1311
      }
1312
 
1313
    // Determine a good median element.
1314
    int mid = from + count / 2;
1315
    int lo = from;
1316
    int hi = from + count - 1;
1317
 
1318
    if (count > 40)
1319
      { // big arrays, pseudomedian of 9
1320
        int s = count / 8;
1321
        lo = med3(lo, lo + s, lo + 2 * s, array);
1322
        mid = med3(mid - s, mid, mid + s, array);
1323
        hi = med3(hi - 2 * s, hi - s, hi, array);
1324
      }
1325
    mid = med3(lo, mid, hi, array);
1326
 
1327
    int a, b, c, d;
1328
    int comp;
1329
 
1330
    // Pull the median element out of the fray, and use it as a pivot.
1331
    swap(from, mid, array);
1332
    a = b = from;
1333
    c = d = from + count - 1;
1334
 
1335
    // Repeatedly move b and c to each other, swapping elements so
1336
    // that all elements before index b are less than the pivot, and all
1337
    // elements after index c are greater than the pivot. a and b track
1338
    // the elements equal to the pivot.
1339
    while (true)
1340
      {
1341
        while (b <= c && (comp = array[b] - array[from]) <= 0)
1342
          {
1343
            if (comp == 0)
1344
              {
1345
                swap(a, b, array);
1346
                a++;
1347
              }
1348
            b++;
1349
          }
1350
        while (c >= b && (comp = array[c] - array[from]) >= 0)
1351
          {
1352
            if (comp == 0)
1353
              {
1354
                swap(c, d, array);
1355
                d--;
1356
              }
1357
            c--;
1358
          }
1359
        if (b > c)
1360
          break;
1361
        swap(b, c, array);
1362
        b++;
1363
        c--;
1364
      }
1365
 
1366
    // Swap pivot(s) back in place, the recurse on left and right sections.
1367
    hi = from + count;
1368
    int span;
1369
    span = Math.min(a - from, b - a);
1370
    vecswap(from, b - span, span, array);
1371
 
1372
    span = Math.min(d - c, hi - d - 1);
1373
    vecswap(b, hi - span, span, array);
1374
 
1375
    span = b - a;
1376
    if (span > 1)
1377
      qsort(array, from, span);
1378
 
1379
    span = d - c;
1380
    if (span > 1)
1381
      qsort(array, hi - span, span);
1382
  }
1383
 
1384
  /**
1385
   * Performs a stable sort on the elements, arranging them according to their
1386
   * natural order.
1387
   *
1388
   * @param a the char array to sort
1389
   */
1390
  public static void sort(char[] a)
1391
  {
1392
    qsort(a, 0, a.length);
1393
  }
1394
 
1395
  /**
1396
   * Performs a stable sort on the elements, arranging them according to their
1397
   * natural order.
1398
   *
1399
   * @param a the char array to sort
1400
   * @param fromIndex the first index to sort (inclusive)
1401
   * @param toIndex the last index to sort (exclusive)
1402
   * @throws IllegalArgumentException if fromIndex &gt; toIndex
1403
   * @throws ArrayIndexOutOfBoundsException if fromIndex &lt; 0
1404
   *         || toIndex &gt; a.length
1405
   */
1406
  public static void sort(char[] a, int fromIndex, int toIndex)
1407
  {
1408
    if (fromIndex > toIndex)
1409
      throw new IllegalArgumentException();
1410
    if (fromIndex < 0)
1411
      throw new ArrayIndexOutOfBoundsException();
1412
    qsort(a, fromIndex, toIndex - fromIndex);
1413
  }
1414
 
1415
  /**
1416
   * Finds the index of the median of three array elements.
1417
   *
1418
   * @param a the first index
1419
   * @param b the second index
1420
   * @param c the third index
1421
   * @param d the array
1422
   * @return the index (a, b, or c) which has the middle value of the three
1423
   */
1424
  private static int med3(int a, int b, int c, char[] d)
1425
  {
1426
    return (d[a] < d[b]
1427
            ? (d[b] < d[c] ? b : d[a] < d[c] ? c : a)
1428
            : (d[b] > d[c] ? b : d[a] > d[c] ? c : a));
1429
  }
1430
 
1431
  /**
1432
   * Swaps the elements at two locations of an array
1433
   *
1434
   * @param i the first index
1435
   * @param j the second index
1436
   * @param a the array
1437
   */
1438
  private static void swap(int i, int j, char[] a)
1439
  {
1440
    char c = a[i];
1441
    a[i] = a[j];
1442
    a[j] = c;
1443
  }
1444
 
1445
  /**
1446
   * Swaps two ranges of an array.
1447
   *
1448
   * @param i the first range start
1449
   * @param j the second range start
1450
   * @param n the element count
1451
   * @param a the array
1452
   */
1453
  private static void vecswap(int i, int j, int n, char[] a)
1454
  {
1455
    for ( ; n > 0; i++, j++, n--)
1456
      swap(i, j, a);
1457
  }
1458
 
1459
  /**
1460
   * Performs a recursive modified quicksort.
1461
   *
1462
   * @param array the array to sort
1463
   * @param from the start index (inclusive)
1464
   * @param count the number of elements to sort
1465
   */
1466
  private static void qsort(char[] array, int from, int count)
1467
  {
1468
    // Use an insertion sort on small arrays.
1469
    if (count <= 7)
1470
      {
1471
        for (int i = from + 1; i < from + count; i++)
1472
          for (int j = i; j > from && array[j - 1] > array[j]; j--)
1473
            swap(j, j - 1, array);
1474
        return;
1475
      }
1476
 
1477
    // Determine a good median element.
1478
    int mid = from + count / 2;
1479
    int lo = from;
1480
    int hi = from + count - 1;
1481
 
1482
    if (count > 40)
1483
      { // big arrays, pseudomedian of 9
1484
        int s = count / 8;
1485
        lo = med3(lo, lo + s, lo + 2 * s, array);
1486
        mid = med3(mid - s, mid, mid + s, array);
1487
        hi = med3(hi - 2 * s, hi - s, hi, array);
1488
      }
1489
    mid = med3(lo, mid, hi, array);
1490
 
1491
    int a, b, c, d;
1492
    int comp;
1493
 
1494
    // Pull the median element out of the fray, and use it as a pivot.
1495
    swap(from, mid, array);
1496
    a = b = from;
1497
    c = d = from + count - 1;
1498
 
1499
    // Repeatedly move b and c to each other, swapping elements so
1500
    // that all elements before index b are less than the pivot, and all
1501
    // elements after index c are greater than the pivot. a and b track
1502
    // the elements equal to the pivot.
1503
    while (true)
1504
      {
1505
        while (b <= c && (comp = array[b] - array[from]) <= 0)
1506
          {
1507
            if (comp == 0)
1508
              {
1509
                swap(a, b, array);
1510
                a++;
1511
              }
1512
            b++;
1513
          }
1514
        while (c >= b && (comp = array[c] - array[from]) >= 0)
1515
          {
1516
            if (comp == 0)
1517
              {
1518
                swap(c, d, array);
1519
                d--;
1520
              }
1521
            c--;
1522
          }
1523
        if (b > c)
1524
          break;
1525
        swap(b, c, array);
1526
        b++;
1527
        c--;
1528
      }
1529
 
1530
    // Swap pivot(s) back in place, the recurse on left and right sections.
1531
    hi = from + count;
1532
    int span;
1533
    span = Math.min(a - from, b - a);
1534
    vecswap(from, b - span, span, array);
1535
 
1536
    span = Math.min(d - c, hi - d - 1);
1537
    vecswap(b, hi - span, span, array);
1538
 
1539
    span = b - a;
1540
    if (span > 1)
1541
      qsort(array, from, span);
1542
 
1543
    span = d - c;
1544
    if (span > 1)
1545
      qsort(array, hi - span, span);
1546
  }
1547
 
1548
  /**
1549
   * Performs a stable sort on the elements, arranging them according to their
1550
   * natural order.
1551
   *
1552
   * @param a the short array to sort
1553
   */
1554
  public static void sort(short[] a)
1555
  {
1556
    qsort(a, 0, a.length);
1557
  }
1558
 
1559
  /**
1560
   * Performs a stable sort on the elements, arranging them according to their
1561
   * natural order.
1562
   *
1563
   * @param a the short array to sort
1564
   * @param fromIndex the first index to sort (inclusive)
1565
   * @param toIndex the last index to sort (exclusive)
1566
   * @throws IllegalArgumentException if fromIndex &gt; toIndex
1567
   * @throws ArrayIndexOutOfBoundsException if fromIndex &lt; 0
1568
   *         || toIndex &gt; a.length
1569
   */
1570
  public static void sort(short[] a, int fromIndex, int toIndex)
1571
  {
1572
    if (fromIndex > toIndex)
1573
      throw new IllegalArgumentException();
1574
    if (fromIndex < 0)
1575
      throw new ArrayIndexOutOfBoundsException();
1576
    qsort(a, fromIndex, toIndex - fromIndex);
1577
  }
1578
 
1579
  /**
1580
   * Finds the index of the median of three array elements.
1581
   *
1582
   * @param a the first index
1583
   * @param b the second index
1584
   * @param c the third index
1585
   * @param d the array
1586
   * @return the index (a, b, or c) which has the middle value of the three
1587
   */
1588
  private static int med3(int a, int b, int c, short[] d)
1589
  {
1590
    return (d[a] < d[b]
1591
            ? (d[b] < d[c] ? b : d[a] < d[c] ? c : a)
1592
            : (d[b] > d[c] ? b : d[a] > d[c] ? c : a));
1593
  }
1594
 
1595
  /**
1596
   * Swaps the elements at two locations of an array
1597
   *
1598
   * @param i the first index
1599
   * @param j the second index
1600
   * @param a the array
1601
   */
1602
  private static void swap(int i, int j, short[] a)
1603
  {
1604
    short c = a[i];
1605
    a[i] = a[j];
1606
    a[j] = c;
1607
  }
1608
 
1609
  /**
1610
   * Swaps two ranges of an array.
1611
   *
1612
   * @param i the first range start
1613
   * @param j the second range start
1614
   * @param n the element count
1615
   * @param a the array
1616
   */
1617
  private static void vecswap(int i, int j, int n, short[] a)
1618
  {
1619
    for ( ; n > 0; i++, j++, n--)
1620
      swap(i, j, a);
1621
  }
1622
 
1623
  /**
1624
   * Performs a recursive modified quicksort.
1625
   *
1626
   * @param array the array to sort
1627
   * @param from the start index (inclusive)
1628
   * @param count the number of elements to sort
1629
   */
1630
  private static void qsort(short[] array, int from, int count)
1631
  {
1632
    // Use an insertion sort on small arrays.
1633
    if (count <= 7)
1634
      {
1635
        for (int i = from + 1; i < from + count; i++)
1636
          for (int j = i; j > from && array[j - 1] > array[j]; j--)
1637
            swap(j, j - 1, array);
1638
        return;
1639
      }
1640
 
1641
    // Determine a good median element.
1642
    int mid = from + count / 2;
1643
    int lo = from;
1644
    int hi = from + count - 1;
1645
 
1646
    if (count > 40)
1647
      { // big arrays, pseudomedian of 9
1648
        int s = count / 8;
1649
        lo = med3(lo, lo + s, lo + 2 * s, array);
1650
        mid = med3(mid - s, mid, mid + s, array);
1651
        hi = med3(hi - 2 * s, hi - s, hi, array);
1652
      }
1653
    mid = med3(lo, mid, hi, array);
1654
 
1655
    int a, b, c, d;
1656
    int comp;
1657
 
1658
    // Pull the median element out of the fray, and use it as a pivot.
1659
    swap(from, mid, array);
1660
    a = b = from;
1661
    c = d = from + count - 1;
1662
 
1663
    // Repeatedly move b and c to each other, swapping elements so
1664
    // that all elements before index b are less than the pivot, and all
1665
    // elements after index c are greater than the pivot. a and b track
1666
    // the elements equal to the pivot.
1667
    while (true)
1668
      {
1669
        while (b <= c && (comp = array[b] - array[from]) <= 0)
1670
          {
1671
            if (comp == 0)
1672
              {
1673
                swap(a, b, array);
1674
                a++;
1675
              }
1676
            b++;
1677
          }
1678
        while (c >= b && (comp = array[c] - array[from]) >= 0)
1679
          {
1680
            if (comp == 0)
1681
              {
1682
                swap(c, d, array);
1683
                d--;
1684
              }
1685
            c--;
1686
          }
1687
        if (b > c)
1688
          break;
1689
        swap(b, c, array);
1690
        b++;
1691
        c--;
1692
      }
1693
 
1694
    // Swap pivot(s) back in place, the recurse on left and right sections.
1695
    hi = from + count;
1696
    int span;
1697
    span = Math.min(a - from, b - a);
1698
    vecswap(from, b - span, span, array);
1699
 
1700
    span = Math.min(d - c, hi - d - 1);
1701
    vecswap(b, hi - span, span, array);
1702
 
1703
    span = b - a;
1704
    if (span > 1)
1705
      qsort(array, from, span);
1706
 
1707
    span = d - c;
1708
    if (span > 1)
1709
      qsort(array, hi - span, span);
1710
  }
1711
 
1712
  /**
1713
   * Performs a stable sort on the elements, arranging them according to their
1714
   * natural order.
1715
   *
1716
   * @param a the int array to sort
1717
   */
1718
  public static void sort(int[] a)
1719
  {
1720
    qsort(a, 0, a.length);
1721
  }
1722
 
1723
  /**
1724
   * Performs a stable sort on the elements, arranging them according to their
1725
   * natural order.
1726
   *
1727
   * @param a the int array to sort
1728
   * @param fromIndex the first index to sort (inclusive)
1729
   * @param toIndex the last index to sort (exclusive)
1730
   * @throws IllegalArgumentException if fromIndex &gt; toIndex
1731
   * @throws ArrayIndexOutOfBoundsException if fromIndex &lt; 0
1732
   *         || toIndex &gt; a.length
1733
   */
1734
  public static void sort(int[] a, int fromIndex, int toIndex)
1735
  {
1736
    if (fromIndex > toIndex)
1737
      throw new IllegalArgumentException();
1738
    if (fromIndex < 0)
1739
      throw new ArrayIndexOutOfBoundsException();
1740
    qsort(a, fromIndex, toIndex - fromIndex);
1741
  }
1742
 
1743
  /**
1744
   * Finds the index of the median of three array elements.
1745
   *
1746
   * @param a the first index
1747
   * @param b the second index
1748
   * @param c the third index
1749
   * @param d the array
1750
   * @return the index (a, b, or c) which has the middle value of the three
1751
   */
1752
  private static int med3(int a, int b, int c, int[] d)
1753
  {
1754
    return (d[a] < d[b]
1755
            ? (d[b] < d[c] ? b : d[a] < d[c] ? c : a)
1756
            : (d[b] > d[c] ? b : d[a] > d[c] ? c : a));
1757
  }
1758
 
1759
  /**
1760
   * Swaps the elements at two locations of an array
1761
   *
1762
   * @param i the first index
1763
   * @param j the second index
1764
   * @param a the array
1765
   */
1766
  private static void swap(int i, int j, int[] a)
1767
  {
1768
    int c = a[i];
1769
    a[i] = a[j];
1770
    a[j] = c;
1771
  }
1772
 
1773
  /**
1774
   * Swaps two ranges of an array.
1775
   *
1776
   * @param i the first range start
1777
   * @param j the second range start
1778
   * @param n the element count
1779
   * @param a the array
1780
   */
1781
  private static void vecswap(int i, int j, int n, int[] a)
1782
  {
1783
    for ( ; n > 0; i++, j++, n--)
1784
      swap(i, j, a);
1785
  }
1786
 
1787
  /**
1788
   * Compares two integers in natural order, since a - b is inadequate.
1789
   *
1790
   * @param a the first int
1791
   * @param b the second int
1792
   * @return &lt; 0, 0, or &gt; 0 accorting to the comparison
1793
   */
1794
  private static int compare(int a, int b)
1795
  {
1796
    return a < b ? -1 : a == b ? 0 : 1;
1797
  }
1798
 
1799
  /**
1800
   * Performs a recursive modified quicksort.
1801
   *
1802
   * @param array the array to sort
1803
   * @param from the start index (inclusive)
1804
   * @param count the number of elements to sort
1805
   */
1806
  private static void qsort(int[] array, int from, int count)
1807
  {
1808
    // Use an insertion sort on small arrays.
1809
    if (count <= 7)
1810
      {
1811
        for (int i = from + 1; i < from + count; i++)
1812
          for (int j = i; j > from && array[j - 1] > array[j]; j--)
1813
            swap(j, j - 1, array);
1814
        return;
1815
      }
1816
 
1817
    // Determine a good median element.
1818
    int mid = from + count / 2;
1819
    int lo = from;
1820
    int hi = from + count - 1;
1821
 
1822
    if (count > 40)
1823
      { // big arrays, pseudomedian of 9
1824
        int s = count / 8;
1825
        lo = med3(lo, lo + s, lo + 2 * s, array);
1826
        mid = med3(mid - s, mid, mid + s, array);
1827
        hi = med3(hi - 2 * s, hi - s, hi, array);
1828
      }
1829
    mid = med3(lo, mid, hi, array);
1830
 
1831
    int a, b, c, d;
1832
    int comp;
1833
 
1834
    // Pull the median element out of the fray, and use it as a pivot.
1835
    swap(from, mid, array);
1836
    a = b = from;
1837
    c = d = from + count - 1;
1838
 
1839
    // Repeatedly move b and c to each other, swapping elements so
1840
    // that all elements before index b are less than the pivot, and all
1841
    // elements after index c are greater than the pivot. a and b track
1842
    // the elements equal to the pivot.
1843
    while (true)
1844
      {
1845
        while (b <= c && (comp = compare(array[b], array[from])) <= 0)
1846
          {
1847
            if (comp == 0)
1848
              {
1849
                swap(a, b, array);
1850
                a++;
1851
              }
1852
            b++;
1853
          }
1854
        while (c >= b && (comp = compare(array[c], array[from])) >= 0)
1855
          {
1856
            if (comp == 0)
1857
              {
1858
                swap(c, d, array);
1859
                d--;
1860
              }
1861
            c--;
1862
          }
1863
        if (b > c)
1864
          break;
1865
        swap(b, c, array);
1866
        b++;
1867
        c--;
1868
      }
1869
 
1870
    // Swap pivot(s) back in place, the recurse on left and right sections.
1871
    hi = from + count;
1872
    int span;
1873
    span = Math.min(a - from, b - a);
1874
    vecswap(from, b - span, span, array);
1875
 
1876
    span = Math.min(d - c, hi - d - 1);
1877
    vecswap(b, hi - span, span, array);
1878
 
1879
    span = b - a;
1880
    if (span > 1)
1881
      qsort(array, from, span);
1882
 
1883
    span = d - c;
1884
    if (span > 1)
1885
      qsort(array, hi - span, span);
1886
  }
1887
 
1888
  /**
1889
   * Performs a stable sort on the elements, arranging them according to their
1890
   * natural order.
1891
   *
1892
   * @param a the long array to sort
1893
   */
1894
  public static void sort(long[] a)
1895
  {
1896
    qsort(a, 0, a.length);
1897
  }
1898
 
1899
  /**
1900
   * Performs a stable sort on the elements, arranging them according to their
1901
   * natural order.
1902
   *
1903
   * @param a the long array to sort
1904
   * @param fromIndex the first index to sort (inclusive)
1905
   * @param toIndex the last index to sort (exclusive)
1906
   * @throws IllegalArgumentException if fromIndex &gt; toIndex
1907
   * @throws ArrayIndexOutOfBoundsException if fromIndex &lt; 0
1908
   *         || toIndex &gt; a.length
1909
   */
1910
  public static void sort(long[] a, int fromIndex, int toIndex)
1911
  {
1912
    if (fromIndex > toIndex)
1913
      throw new IllegalArgumentException();
1914
    if (fromIndex < 0)
1915
      throw new ArrayIndexOutOfBoundsException();
1916
    qsort(a, fromIndex, toIndex - fromIndex);
1917
  }
1918
 
1919
  /**
1920
   * Finds the index of the median of three array elements.
1921
   *
1922
   * @param a the first index
1923
   * @param b the second index
1924
   * @param c the third index
1925
   * @param d the array
1926
   * @return the index (a, b, or c) which has the middle value of the three
1927
   */
1928
  private static int med3(int a, int b, int c, long[] d)
1929
  {
1930
    return (d[a] < d[b]
1931
            ? (d[b] < d[c] ? b : d[a] < d[c] ? c : a)
1932
            : (d[b] > d[c] ? b : d[a] > d[c] ? c : a));
1933
  }
1934
 
1935
  /**
1936
   * Swaps the elements at two locations of an array
1937
   *
1938
   * @param i the first index
1939
   * @param j the second index
1940
   * @param a the array
1941
   */
1942
  private static void swap(int i, int j, long[] a)
1943
  {
1944
    long c = a[i];
1945
    a[i] = a[j];
1946
    a[j] = c;
1947
  }
1948
 
1949
  /**
1950
   * Swaps two ranges of an array.
1951
   *
1952
   * @param i the first range start
1953
   * @param j the second range start
1954
   * @param n the element count
1955
   * @param a the array
1956
   */
1957
  private static void vecswap(int i, int j, int n, long[] a)
1958
  {
1959
    for ( ; n > 0; i++, j++, n--)
1960
      swap(i, j, a);
1961
  }
1962
 
1963
  /**
1964
   * Compares two longs in natural order, since a - b is inadequate.
1965
   *
1966
   * @param a the first long
1967
   * @param b the second long
1968
   * @return &lt; 0, 0, or &gt; 0 accorting to the comparison
1969
   */
1970
  private static int compare(long a, long b)
1971
  {
1972
    return a < b ? -1 : a == b ? 0 : 1;
1973
  }
1974
 
1975
  /**
1976
   * Performs a recursive modified quicksort.
1977
   *
1978
   * @param array the array to sort
1979
   * @param from the start index (inclusive)
1980
   * @param count the number of elements to sort
1981
   */
1982
  private static void qsort(long[] array, int from, int count)
1983
  {
1984
    // Use an insertion sort on small arrays.
1985
    if (count <= 7)
1986
      {
1987
        for (int i = from + 1; i < from + count; i++)
1988
          for (int j = i; j > from && array[j - 1] > array[j]; j--)
1989
            swap(j, j - 1, array);
1990
        return;
1991
      }
1992
 
1993
    // Determine a good median element.
1994
    int mid = from + count / 2;
1995
    int lo = from;
1996
    int hi = from + count - 1;
1997
 
1998
    if (count > 40)
1999
      { // big arrays, pseudomedian of 9
2000
        int s = count / 8;
2001
        lo = med3(lo, lo + s, lo + 2 * s, array);
2002
        mid = med3(mid - s, mid, mid + s, array);
2003
        hi = med3(hi - 2 * s, hi - s, hi, array);
2004
      }
2005
    mid = med3(lo, mid, hi, array);
2006
 
2007
    int a, b, c, d;
2008
    int comp;
2009
 
2010
    // Pull the median element out of the fray, and use it as a pivot.
2011
    swap(from, mid, array);
2012
    a = b = from;
2013
    c = d = from + count - 1;
2014
 
2015
    // Repeatedly move b and c to each other, swapping elements so
2016
    // that all elements before index b are less than the pivot, and all
2017
    // elements after index c are greater than the pivot. a and b track
2018
    // the elements equal to the pivot.
2019
    while (true)
2020
      {
2021
        while (b <= c && (comp = compare(array[b], array[from])) <= 0)
2022
          {
2023
            if (comp == 0)
2024
              {
2025
                swap(a, b, array);
2026
                a++;
2027
              }
2028
            b++;
2029
          }
2030
        while (c >= b && (comp = compare(array[c], array[from])) >= 0)
2031
          {
2032
            if (comp == 0)
2033
              {
2034
                swap(c, d, array);
2035
                d--;
2036
              }
2037
            c--;
2038
          }
2039
        if (b > c)
2040
          break;
2041
        swap(b, c, array);
2042
        b++;
2043
        c--;
2044
      }
2045
 
2046
    // Swap pivot(s) back in place, the recurse on left and right sections.
2047
    hi = from + count;
2048
    int span;
2049
    span = Math.min(a - from, b - a);
2050
    vecswap(from, b - span, span, array);
2051
 
2052
    span = Math.min(d - c, hi - d - 1);
2053
    vecswap(b, hi - span, span, array);
2054
 
2055
    span = b - a;
2056
    if (span > 1)
2057
      qsort(array, from, span);
2058
 
2059
    span = d - c;
2060
    if (span > 1)
2061
      qsort(array, hi - span, span);
2062
  }
2063
 
2064
  /**
2065
   * Performs a stable sort on the elements, arranging them according to their
2066
   * natural order.
2067
   *
2068
   * @param a the float array to sort
2069
   */
2070
  public static void sort(float[] a)
2071
  {
2072
    qsort(a, 0, a.length);
2073
  }
2074
 
2075
  /**
2076
   * Performs a stable sort on the elements, arranging them according to their
2077
   * natural order.
2078
   *
2079
   * @param a the float array to sort
2080
   * @param fromIndex the first index to sort (inclusive)
2081
   * @param toIndex the last index to sort (exclusive)
2082
   * @throws IllegalArgumentException if fromIndex &gt; toIndex
2083
   * @throws ArrayIndexOutOfBoundsException if fromIndex &lt; 0
2084
   *         || toIndex &gt; a.length
2085
   */
2086
  public static void sort(float[] a, int fromIndex, int toIndex)
2087
  {
2088
    if (fromIndex > toIndex)
2089
      throw new IllegalArgumentException();
2090
    if (fromIndex < 0)
2091
      throw new ArrayIndexOutOfBoundsException();
2092
    qsort(a, fromIndex, toIndex - fromIndex);
2093
  }
2094
 
2095
  /**
2096
   * Finds the index of the median of three array elements.
2097
   *
2098
   * @param a the first index
2099
   * @param b the second index
2100
   * @param c the third index
2101
   * @param d the array
2102
   * @return the index (a, b, or c) which has the middle value of the three
2103
   */
2104
  private static int med3(int a, int b, int c, float[] d)
2105
  {
2106
    return (Float.compare(d[a], d[b]) < 0
2107
            ? (Float.compare(d[b], d[c]) < 0 ? b
2108
               : Float.compare(d[a], d[c]) < 0 ? c : a)
2109
            : (Float.compare(d[b], d[c]) > 0 ? b
2110
               : Float.compare(d[a], d[c]) > 0 ? c : a));
2111
  }
2112
 
2113
  /**
2114
   * Swaps the elements at two locations of an array
2115
   *
2116
   * @param i the first index
2117
   * @param j the second index
2118
   * @param a the array
2119
   */
2120
  private static void swap(int i, int j, float[] a)
2121
  {
2122
    float c = a[i];
2123
    a[i] = a[j];
2124
    a[j] = c;
2125
  }
2126
 
2127
  /**
2128
   * Swaps two ranges of an array.
2129
   *
2130
   * @param i the first range start
2131
   * @param j the second range start
2132
   * @param n the element count
2133
   * @param a the array
2134
   */
2135
  private static void vecswap(int i, int j, int n, float[] a)
2136
  {
2137
    for ( ; n > 0; i++, j++, n--)
2138
      swap(i, j, a);
2139
  }
2140
 
2141
  /**
2142
   * Performs a recursive modified quicksort.
2143
   *
2144
   * @param array the array to sort
2145
   * @param from the start index (inclusive)
2146
   * @param count the number of elements to sort
2147
   */
2148
  private static void qsort(float[] array, int from, int count)
2149
  {
2150
    // Use an insertion sort on small arrays.
2151
    if (count <= 7)
2152
      {
2153
        for (int i = from + 1; i < from + count; i++)
2154
          for (int j = i;
2155
               j > from && Float.compare(array[j - 1], array[j]) > 0;
2156
               j--)
2157
            {
2158
              swap(j, j - 1, array);
2159
            }
2160
        return;
2161
      }
2162
 
2163
    // Determine a good median element.
2164
    int mid = from + count / 2;
2165
    int lo = from;
2166
    int hi = from + count - 1;
2167
 
2168
    if (count > 40)
2169
      { // big arrays, pseudomedian of 9
2170
        int s = count / 8;
2171
        lo = med3(lo, lo + s, lo + 2 * s, array);
2172
        mid = med3(mid - s, mid, mid + s, array);
2173
        hi = med3(hi - 2 * s, hi - s, hi, array);
2174
      }
2175
    mid = med3(lo, mid, hi, array);
2176
 
2177
    int a, b, c, d;
2178
    int comp;
2179
 
2180
    // Pull the median element out of the fray, and use it as a pivot.
2181
    swap(from, mid, array);
2182
    a = b = from;
2183
    c = d = from + count - 1;
2184
 
2185
    // Repeatedly move b and c to each other, swapping elements so
2186
    // that all elements before index b are less than the pivot, and all
2187
    // elements after index c are greater than the pivot. a and b track
2188
    // the elements equal to the pivot.
2189
    while (true)
2190
      {
2191
        while (b <= c && (comp = Float.compare(array[b], array[from])) <= 0)
2192
          {
2193
            if (comp == 0)
2194
              {
2195
                swap(a, b, array);
2196
                a++;
2197
              }
2198
            b++;
2199
          }
2200
        while (c >= b && (comp = Float.compare(array[c], array[from])) >= 0)
2201
          {
2202
            if (comp == 0)
2203
              {
2204
                swap(c, d, array);
2205
                d--;
2206
              }
2207
            c--;
2208
          }
2209
        if (b > c)
2210
          break;
2211
        swap(b, c, array);
2212
        b++;
2213
        c--;
2214
      }
2215
 
2216
    // Swap pivot(s) back in place, the recurse on left and right sections.
2217
    hi = from + count;
2218
    int span;
2219
    span = Math.min(a - from, b - a);
2220
    vecswap(from, b - span, span, array);
2221
 
2222
    span = Math.min(d - c, hi - d - 1);
2223
    vecswap(b, hi - span, span, array);
2224
 
2225
    span = b - a;
2226
    if (span > 1)
2227
      qsort(array, from, span);
2228
 
2229
    span = d - c;
2230
    if (span > 1)
2231
      qsort(array, hi - span, span);
2232
  }
2233
 
2234
  /**
2235
   * Performs a stable sort on the elements, arranging them according to their
2236
   * natural order.
2237
   *
2238
   * @param a the double array to sort
2239
   */
2240
  public static void sort(double[] a)
2241
  {
2242
    qsort(a, 0, a.length);
2243
  }
2244
 
2245
  /**
2246
   * Performs a stable sort on the elements, arranging them according to their
2247
   * natural order.
2248
   *
2249
   * @param a the double array to sort
2250
   * @param fromIndex the first index to sort (inclusive)
2251
   * @param toIndex the last index to sort (exclusive)
2252
   * @throws IllegalArgumentException if fromIndex &gt; toIndex
2253
   * @throws ArrayIndexOutOfBoundsException if fromIndex &lt; 0
2254
   *         || toIndex &gt; a.length
2255
   */
2256
  public static void sort(double[] a, int fromIndex, int toIndex)
2257
  {
2258
    if (fromIndex > toIndex)
2259
      throw new IllegalArgumentException();
2260
    if (fromIndex < 0)
2261
      throw new ArrayIndexOutOfBoundsException();
2262
    qsort(a, fromIndex, toIndex - fromIndex);
2263
  }
2264
 
2265
  /**
2266
   * Finds the index of the median of three array elements.
2267
   *
2268
   * @param a the first index
2269
   * @param b the second index
2270
   * @param c the third index
2271
   * @param d the array
2272
   * @return the index (a, b, or c) which has the middle value of the three
2273
   */
2274
  private static int med3(int a, int b, int c, double[] d)
2275
  {
2276
    return (Double.compare(d[a], d[b]) < 0
2277
            ? (Double.compare(d[b], d[c]) < 0 ? b
2278
               : Double.compare(d[a], d[c]) < 0 ? c : a)
2279
            : (Double.compare(d[b], d[c]) > 0 ? b
2280
               : Double.compare(d[a], d[c]) > 0 ? c : a));
2281
  }
2282
 
2283
  /**
2284
   * Swaps the elements at two locations of an array
2285
   *
2286
   * @param i the first index
2287
   * @param j the second index
2288
   * @param a the array
2289
   */
2290
  private static void swap(int i, int j, double[] a)
2291
  {
2292
    double c = a[i];
2293
    a[i] = a[j];
2294
    a[j] = c;
2295
  }
2296
 
2297
  /**
2298
   * Swaps two ranges of an array.
2299
   *
2300
   * @param i the first range start
2301
   * @param j the second range start
2302
   * @param n the element count
2303
   * @param a the array
2304
   */
2305
  private static void vecswap(int i, int j, int n, double[] a)
2306
  {
2307
    for ( ; n > 0; i++, j++, n--)
2308
      swap(i, j, a);
2309
  }
2310
 
2311
  /**
2312
   * Performs a recursive modified quicksort.
2313
   *
2314
   * @param array the array to sort
2315
   * @param from the start index (inclusive)
2316
   * @param count the number of elements to sort
2317
   */
2318
  private static void qsort(double[] array, int from, int count)
2319
  {
2320
    // Use an insertion sort on small arrays.
2321
    if (count <= 7)
2322
      {
2323
        for (int i = from + 1; i < from + count; i++)
2324
          for (int j = i;
2325
               j > from && Double.compare(array[j - 1], array[j]) > 0;
2326
               j--)
2327
            {
2328
              swap(j, j - 1, array);
2329
            }
2330
        return;
2331
      }
2332
 
2333
    // Determine a good median element.
2334
    int mid = from + count / 2;
2335
    int lo = from;
2336
    int hi = from + count - 1;
2337
 
2338
    if (count > 40)
2339
      { // big arrays, pseudomedian of 9
2340
        int s = count / 8;
2341
        lo = med3(lo, lo + s, lo + 2 * s, array);
2342
        mid = med3(mid - s, mid, mid + s, array);
2343
        hi = med3(hi - 2 * s, hi - s, hi, array);
2344
      }
2345
    mid = med3(lo, mid, hi, array);
2346
 
2347
    int a, b, c, d;
2348
    int comp;
2349
 
2350
    // Pull the median element out of the fray, and use it as a pivot.
2351
    swap(from, mid, array);
2352
    a = b = from;
2353
    c = d = from + count - 1;
2354
 
2355
    // Repeatedly move b and c to each other, swapping elements so
2356
    // that all elements before index b are less than the pivot, and all
2357
    // elements after index c are greater than the pivot. a and b track
2358
    // the elements equal to the pivot.
2359
    while (true)
2360
      {
2361
        while (b <= c && (comp = Double.compare(array[b], array[from])) <= 0)
2362
          {
2363
            if (comp == 0)
2364
              {
2365
                swap(a, b, array);
2366
                a++;
2367
              }
2368
            b++;
2369
          }
2370
        while (c >= b && (comp = Double.compare(array[c], array[from])) >= 0)
2371
          {
2372
            if (comp == 0)
2373
              {
2374
                swap(c, d, array);
2375
                d--;
2376
              }
2377
            c--;
2378
          }
2379
        if (b > c)
2380
          break;
2381
        swap(b, c, array);
2382
        b++;
2383
        c--;
2384
      }
2385
 
2386
    // Swap pivot(s) back in place, the recurse on left and right sections.
2387
    hi = from + count;
2388
    int span;
2389
    span = Math.min(a - from, b - a);
2390
    vecswap(from, b - span, span, array);
2391
 
2392
    span = Math.min(d - c, hi - d - 1);
2393
    vecswap(b, hi - span, span, array);
2394
 
2395
    span = b - a;
2396
    if (span > 1)
2397
      qsort(array, from, span);
2398
 
2399
    span = d - c;
2400
    if (span > 1)
2401
      qsort(array, hi - span, span);
2402
  }
2403
 
2404
  /**
2405
   * Sort an array of Objects according to their natural ordering. The sort is
2406
   * guaranteed to be stable, that is, equal elements will not be reordered.
2407
   * The sort algorithm is a mergesort with the merge omitted if the last
2408
   * element of one half comes before the first element of the other half. This
2409
   * algorithm gives guaranteed O(n*log(n)) time, at the expense of making a
2410
   * copy of the array.
2411
   *
2412
   * @param a the array to be sorted
2413
   * @throws ClassCastException if any two elements are not mutually
2414
   *         comparable
2415
   * @throws NullPointerException if an element is null (since
2416
   *         null.compareTo cannot work)
2417
   * @see Comparable
2418
   */
2419
  public static void sort(Object[] a)
2420
  {
2421
    sort(a, 0, a.length, null);
2422
  }
2423
 
2424
  /**
2425
   * Sort an array of Objects according to a Comparator. The sort is
2426
   * guaranteed to be stable, that is, equal elements will not be reordered.
2427
   * The sort algorithm is a mergesort with the merge omitted if the last
2428
   * element of one half comes before the first element of the other half. This
2429
   * algorithm gives guaranteed O(n*log(n)) time, at the expense of making a
2430
   * copy of the array.
2431
   *
2432
   * @param a the array to be sorted
2433
   * @param c a Comparator to use in sorting the array; or null to indicate
2434
   *        the elements' natural order
2435
   * @throws ClassCastException if any two elements are not mutually
2436
   *         comparable by the Comparator provided
2437
   * @throws NullPointerException if a null element is compared with natural
2438
   *         ordering (only possible when c is null)
2439
   */
2440
  public static <T> void sort(T[] a, Comparator<? super T> c)
2441
  {
2442
    sort(a, 0, a.length, c);
2443
  }
2444
 
2445
  /**
2446
   * Sort an array of Objects according to their natural ordering. The sort is
2447
   * guaranteed to be stable, that is, equal elements will not be reordered.
2448
   * The sort algorithm is a mergesort with the merge omitted if the last
2449
   * element of one half comes before the first element of the other half. This
2450
   * algorithm gives guaranteed O(n*log(n)) time, at the expense of making a
2451
   * copy of the array.
2452
   *
2453
   * @param a the array to be sorted
2454
   * @param fromIndex the index of the first element to be sorted
2455
   * @param toIndex the index of the last element to be sorted plus one
2456
   * @throws ClassCastException if any two elements are not mutually
2457
   *         comparable
2458
   * @throws NullPointerException if an element is null (since
2459
   *         null.compareTo cannot work)
2460
   * @throws ArrayIndexOutOfBoundsException if fromIndex and toIndex
2461
   *         are not in range.
2462
   * @throws IllegalArgumentException if fromIndex &gt; toIndex
2463
   */
2464
  public static void sort(Object[] a, int fromIndex, int toIndex)
2465
  {
2466
    sort(a, fromIndex, toIndex, null);
2467
  }
2468
 
2469
  /**
2470
   * Sort an array of Objects according to a Comparator. The sort is
2471
   * guaranteed to be stable, that is, equal elements will not be reordered.
2472
   * The sort algorithm is a mergesort with the merge omitted if the last
2473
   * element of one half comes before the first element of the other half. This
2474
   * algorithm gives guaranteed O(n*log(n)) time, at the expense of making a
2475
   * copy of the array.
2476
   *
2477
   * @param a the array to be sorted
2478
   * @param fromIndex the index of the first element to be sorted
2479
   * @param toIndex the index of the last element to be sorted plus one
2480
   * @param c a Comparator to use in sorting the array; or null to indicate
2481
   *        the elements' natural order
2482
   * @throws ClassCastException if any two elements are not mutually
2483
   *         comparable by the Comparator provided
2484
   * @throws ArrayIndexOutOfBoundsException if fromIndex and toIndex
2485
   *         are not in range.
2486
   * @throws IllegalArgumentException if fromIndex &gt; toIndex
2487
   * @throws NullPointerException if a null element is compared with natural
2488
   *         ordering (only possible when c is null)
2489
   */
2490
  public static <T> void sort(T[] a, int fromIndex, int toIndex,
2491
                              Comparator<? super T> c)
2492
  {
2493
    if (fromIndex > toIndex)
2494
      throw new IllegalArgumentException("fromIndex " + fromIndex
2495
                                         + " > toIndex " + toIndex);
2496
    if (fromIndex < 0)
2497
      throw new ArrayIndexOutOfBoundsException();
2498
 
2499
    // In general, the code attempts to be simple rather than fast, the
2500
    // idea being that a good optimising JIT will be able to optimise it
2501
    // better than I can, and if I try it will make it more confusing for
2502
    // the JIT. First presort the array in chunks of length 6 with insertion
2503
    // sort. A mergesort would give too much overhead for this length.
2504
    for (int chunk = fromIndex; chunk < toIndex; chunk += 6)
2505
      {
2506
        int end = Math.min(chunk + 6, toIndex);
2507
        for (int i = chunk + 1; i < end; i++)
2508
          {
2509
            if (Collections.compare(a[i - 1], a[i], c) > 0)
2510
              {
2511
                // not already sorted
2512
                int j = i;
2513
                T elem = a[j];
2514
                do
2515
                  {
2516
                    a[j] = a[j - 1];
2517
                    j--;
2518
                  }
2519
                while (j > chunk
2520
                       && Collections.compare(a[j - 1], elem, c) > 0);
2521
                a[j] = elem;
2522
              }
2523
          }
2524
      }
2525
 
2526
    int len = toIndex - fromIndex;
2527
    // If length is smaller or equal 6 we are done.
2528
    if (len <= 6)
2529
      return;
2530
 
2531
    T[] src = a;
2532
    T[] dest = (T[]) new Object[len];
2533
    T[] t = null; // t is used for swapping src and dest
2534
 
2535
    // The difference of the fromIndex of the src and dest array.
2536
    int srcDestDiff = -fromIndex;
2537
 
2538
    // The merges are done in this loop
2539
    for (int size = 6; size < len; size <<= 1)
2540
      {
2541
        for (int start = fromIndex; start < toIndex; start += size << 1)
2542
          {
2543
            // mid is the start of the second sublist;
2544
            // end the start of the next sublist (or end of array).
2545
            int mid = start + size;
2546
            int end = Math.min(toIndex, mid + size);
2547
 
2548
            // The second list is empty or the elements are already in
2549
            // order - no need to merge
2550
            if (mid >= end
2551
                || Collections.compare(src[mid - 1], src[mid], c) <= 0)
2552
              {
2553
                System.arraycopy(src, start,
2554
                                 dest, start + srcDestDiff, end - start);
2555
 
2556
                // The two halves just need swapping - no need to merge
2557
              }
2558
            else if (Collections.compare(src[start], src[end - 1], c) > 0)
2559
              {
2560
                System.arraycopy(src, start,
2561
                                 dest, end - size + srcDestDiff, size);
2562
                System.arraycopy(src, mid,
2563
                                 dest, start + srcDestDiff, end - mid);
2564
 
2565
              }
2566
            else
2567
              {
2568
                // Declare a lot of variables to save repeating
2569
                // calculations.  Hopefully a decent JIT will put these
2570
                // in registers and make this fast
2571
                int p1 = start;
2572
                int p2 = mid;
2573
                int i = start + srcDestDiff;
2574
 
2575
                // The main merge loop; terminates as soon as either
2576
                // half is ended
2577
                while (p1 < mid && p2 < end)
2578
                  {
2579
                    dest[i++] =
2580
                      src[(Collections.compare(src[p1], src[p2], c) <= 0
2581
                           ? p1++ : p2++)];
2582
                  }
2583
 
2584
                // Finish up by copying the remainder of whichever half
2585
                // wasn't finished.
2586
                if (p1 < mid)
2587
                  System.arraycopy(src, p1, dest, i, mid - p1);
2588
                else
2589
                  System.arraycopy(src, p2, dest, i, end - p2);
2590
              }
2591
          }
2592
        // swap src and dest ready for the next merge
2593
        t = src;
2594
        src = dest;
2595
        dest = t;
2596
        fromIndex += srcDestDiff;
2597
        toIndex += srcDestDiff;
2598
        srcDestDiff = -srcDestDiff;
2599
      }
2600
 
2601
    // make sure the result ends up back in the right place.  Note
2602
    // that src and dest may have been swapped above, so src
2603
    // contains the sorted array.
2604
    if (src != a)
2605
      {
2606
        // Note that fromIndex == 0.
2607
        System.arraycopy(src, 0, a, srcDestDiff, toIndex);
2608
      }
2609
  }
2610
 
2611
  /**
2612
   * Returns a list "view" of the specified array. This method is intended to
2613
   * make it easy to use the Collections API with existing array-based APIs and
2614
   * programs. Changes in the list or the array show up in both places. The
2615
   * list does not support element addition or removal, but does permit
2616
   * value modification. The returned list implements both Serializable and
2617
   * RandomAccess.
2618
   *
2619
   * @param a the array to return a view of (<code>null</code> not permitted)
2620
   * @return a fixed-size list, changes to which "write through" to the array
2621
   *
2622
   * @throws NullPointerException if <code>a</code> is <code>null</code>.
2623
   * @see Serializable
2624
   * @see RandomAccess
2625
   * @see Arrays.ArrayList
2626
   */
2627
  public static <T> List<T> asList(final T... a)
2628
  {
2629
    return new Arrays.ArrayList(a);
2630
  }
2631
 
2632
  /**
2633
   * Returns the hashcode of an array of long numbers.  If two arrays
2634
   * are equal, according to <code>equals()</code>, they should have the
2635
   * same hashcode.  The hashcode returned by the method is equal to that
2636
   * obtained by the corresponding <code>List</code> object.  This has the same
2637
   * data, but represents longs in their wrapper class, <code>Long</code>.
2638
   * For <code>null</code>, 0 is returned.
2639
   *
2640
   * @param v an array of long numbers for which the hash code should be
2641
   *          computed.
2642
   * @return the hash code of the array, or 0 if null was given.
2643
   * @since 1.5
2644
   */
2645
  public static int hashCode(long[] v)
2646
  {
2647
    if (v == null)
2648
      return 0;
2649
    int result = 1;
2650
    for (int i = 0; i < v.length; ++i)
2651
      {
2652
        int elt = (int) (v[i] ^ (v[i] >>> 32));
2653
        result = 31 * result + elt;
2654
      }
2655
    return result;
2656
  }
2657
 
2658
  /**
2659
   * Returns the hashcode of an array of integer numbers.  If two arrays
2660
   * are equal, according to <code>equals()</code>, they should have the
2661
   * same hashcode.  The hashcode returned by the method is equal to that
2662
   * obtained by the corresponding <code>List</code> object.  This has the same
2663
   * data, but represents ints in their wrapper class, <code>Integer</code>.
2664
   * For <code>null</code>, 0 is returned.
2665
   *
2666
   * @param v an array of integer numbers for which the hash code should be
2667
   *          computed.
2668
   * @return the hash code of the array, or 0 if null was given.
2669
   * @since 1.5
2670
   */
2671
  public static int hashCode(int[] v)
2672
  {
2673
    if (v == null)
2674
      return 0;
2675
    int result = 1;
2676
    for (int i = 0; i < v.length; ++i)
2677
      result = 31 * result + v[i];
2678
    return result;
2679
  }
2680
 
2681
  /**
2682
   * Returns the hashcode of an array of short numbers.  If two arrays
2683
   * are equal, according to <code>equals()</code>, they should have the
2684
   * same hashcode.  The hashcode returned by the method is equal to that
2685
   * obtained by the corresponding <code>List</code> object.  This has the same
2686
   * data, but represents shorts in their wrapper class, <code>Short</code>.
2687
   * For <code>null</code>, 0 is returned.
2688
   *
2689
   * @param v an array of short numbers for which the hash code should be
2690
   *          computed.
2691
   * @return the hash code of the array, or 0 if null was given.
2692
   * @since 1.5
2693
   */
2694
  public static int hashCode(short[] v)
2695
  {
2696
    if (v == null)
2697
      return 0;
2698
    int result = 1;
2699
    for (int i = 0; i < v.length; ++i)
2700
      result = 31 * result + v[i];
2701
    return result;
2702
  }
2703
 
2704
  /**
2705
   * Returns the hashcode of an array of characters.  If two arrays
2706
   * are equal, according to <code>equals()</code>, they should have the
2707
   * same hashcode.  The hashcode returned by the method is equal to that
2708
   * obtained by the corresponding <code>List</code> object.  This has the same
2709
   * data, but represents chars in their wrapper class, <code>Character</code>.
2710
   * For <code>null</code>, 0 is returned.
2711
   *
2712
   * @param v an array of characters for which the hash code should be
2713
   *          computed.
2714
   * @return the hash code of the array, or 0 if null was given.
2715
   * @since 1.5
2716
   */
2717
  public static int hashCode(char[] v)
2718
  {
2719
    if (v == null)
2720
      return 0;
2721
    int result = 1;
2722
    for (int i = 0; i < v.length; ++i)
2723
      result = 31 * result + v[i];
2724
    return result;
2725
  }
2726
 
2727
  /**
2728
   * Returns the hashcode of an array of bytes.  If two arrays
2729
   * are equal, according to <code>equals()</code>, they should have the
2730
   * same hashcode.  The hashcode returned by the method is equal to that
2731
   * obtained by the corresponding <code>List</code> object.  This has the same
2732
   * data, but represents bytes in their wrapper class, <code>Byte</code>.
2733
   * For <code>null</code>, 0 is returned.
2734
   *
2735
   * @param v an array of bytes for which the hash code should be
2736
   *          computed.
2737
   * @return the hash code of the array, or 0 if null was given.
2738
   * @since 1.5
2739
   */
2740
  public static int hashCode(byte[] v)
2741
  {
2742
    if (v == null)
2743
      return 0;
2744
    int result = 1;
2745
    for (int i = 0; i < v.length; ++i)
2746
      result = 31 * result + v[i];
2747
    return result;
2748
  }
2749
 
2750
  /**
2751
   * Returns the hashcode of an array of booleans.  If two arrays
2752
   * are equal, according to <code>equals()</code>, they should have the
2753
   * same hashcode.  The hashcode returned by the method is equal to that
2754
   * obtained by the corresponding <code>List</code> object.  This has the same
2755
   * data, but represents booleans in their wrapper class,
2756
   * <code>Boolean</code>.  For <code>null</code>, 0 is returned.
2757
   *
2758
   * @param v an array of booleans for which the hash code should be
2759
   *          computed.
2760
   * @return the hash code of the array, or 0 if null was given.
2761
   * @since 1.5
2762
   */
2763
  public static int hashCode(boolean[] v)
2764
  {
2765
    if (v == null)
2766
      return 0;
2767
    int result = 1;
2768
    for (int i = 0; i < v.length; ++i)
2769
      result = 31 * result + (v[i] ? 1231 : 1237);
2770
    return result;
2771
  }
2772
 
2773
  /**
2774
   * Returns the hashcode of an array of floats.  If two arrays
2775
   * are equal, according to <code>equals()</code>, they should have the
2776
   * same hashcode.  The hashcode returned by the method is equal to that
2777
   * obtained by the corresponding <code>List</code> object.  This has the same
2778
   * data, but represents floats in their wrapper class, <code>Float</code>.
2779
   * For <code>null</code>, 0 is returned.
2780
   *
2781
   * @param v an array of floats for which the hash code should be
2782
   *          computed.
2783
   * @return the hash code of the array, or 0 if null was given.
2784
   * @since 1.5
2785
   */
2786
  public static int hashCode(float[] v)
2787
  {
2788
    if (v == null)
2789
      return 0;
2790
    int result = 1;
2791
    for (int i = 0; i < v.length; ++i)
2792
      result = 31 * result + Float.floatToIntBits(v[i]);
2793
    return result;
2794
  }
2795
 
2796
  /**
2797
   * Returns the hashcode of an array of doubles.  If two arrays
2798
   * are equal, according to <code>equals()</code>, they should have the
2799
   * same hashcode.  The hashcode returned by the method is equal to that
2800
   * obtained by the corresponding <code>List</code> object.  This has the same
2801
   * data, but represents doubles in their wrapper class, <code>Double</code>.
2802
   * For <code>null</code>, 0 is returned.
2803
   *
2804
   * @param v an array of doubles for which the hash code should be
2805
   *          computed.
2806
   * @return the hash code of the array, or 0 if null was given.
2807
   * @since 1.5
2808
   */
2809
  public static int hashCode(double[] v)
2810
  {
2811
    if (v == null)
2812
      return 0;
2813
    int result = 1;
2814
    for (int i = 0; i < v.length; ++i)
2815
      {
2816
        long l = Double.doubleToLongBits(v[i]);
2817
        int elt = (int) (l ^ (l >>> 32));
2818
        result = 31 * result + elt;
2819
      }
2820
    return result;
2821
  }
2822
 
2823
  /**
2824
   * Returns the hashcode of an array of objects.  If two arrays
2825
   * are equal, according to <code>equals()</code>, they should have the
2826
   * same hashcode.  The hashcode returned by the method is equal to that
2827
   * obtained by the corresponding <code>List</code> object.
2828
   * For <code>null</code>, 0 is returned.
2829
   *
2830
   * @param v an array of integer numbers for which the hash code should be
2831
   *          computed.
2832
   * @return the hash code of the array, or 0 if null was given.
2833
   * @since 1.5
2834
   */
2835
  public static int hashCode(Object[] v)
2836
  {
2837
    if (v == null)
2838
      return 0;
2839
    int result = 1;
2840
    for (int i = 0; i < v.length; ++i)
2841
      {
2842
        int elt = v[i] == null ? 0 : v[i].hashCode();
2843
        result = 31 * result + elt;
2844
      }
2845
    return result;
2846
  }
2847
 
2848
  public static int deepHashCode(Object[] v)
2849
  {
2850
    if (v == null)
2851
      return 0;
2852
    int result = 1;
2853
    for (int i = 0; i < v.length; ++i)
2854
      {
2855
        int elt;
2856
        if (v[i] == null)
2857
          elt = 0;
2858
        else if (v[i] instanceof boolean[])
2859
          elt = hashCode((boolean[]) v[i]);
2860
        else if (v[i] instanceof byte[])
2861
          elt = hashCode((byte[]) v[i]);
2862
        else if (v[i] instanceof char[])
2863
          elt = hashCode((char[]) v[i]);
2864
        else if (v[i] instanceof short[])
2865
          elt = hashCode((short[]) v[i]);
2866
        else if (v[i] instanceof int[])
2867
          elt = hashCode((int[]) v[i]);
2868
        else if (v[i] instanceof long[])
2869
          elt = hashCode((long[]) v[i]);
2870
        else if (v[i] instanceof float[])
2871
          elt = hashCode((float[]) v[i]);
2872
        else if (v[i] instanceof double[])
2873
          elt = hashCode((double[]) v[i]);
2874
        else if (v[i] instanceof Object[])
2875
          elt = hashCode((Object[]) v[i]);
2876
        else
2877
          elt = v[i].hashCode();
2878
        result = 31 * result + elt;
2879
      }
2880
    return result;
2881
  }
2882
 
2883
  /** @since 1.5 */
2884
  public static boolean deepEquals(Object[] v1, Object[] v2)
2885
  {
2886
    if (v1 == null)
2887
      return v2 == null;
2888
    if (v2 == null || v1.length != v2.length)
2889
      return false;
2890
 
2891
    for (int i = 0; i < v1.length; ++i)
2892
      {
2893
        Object e1 = v1[i];
2894
        Object e2 = v2[i];
2895
 
2896
        if (e1 == e2)
2897
          continue;
2898
        if (e1 == null || e2 == null)
2899
          return false;
2900
 
2901
        boolean check;
2902
        if (e1 instanceof boolean[] && e2 instanceof boolean[])
2903
          check = equals((boolean[]) e1, (boolean[]) e2);
2904
        else if (e1 instanceof byte[] && e2 instanceof byte[])
2905
          check = equals((byte[]) e1, (byte[]) e2);
2906
        else if (e1 instanceof char[] && e2 instanceof char[])
2907
          check = equals((char[]) e1, (char[]) e2);
2908
        else if (e1 instanceof short[] && e2 instanceof short[])
2909
          check = equals((short[]) e1, (short[]) e2);
2910
        else if (e1 instanceof int[] && e2 instanceof int[])
2911
          check = equals((int[]) e1, (int[]) e2);
2912
        else if (e1 instanceof long[] && e2 instanceof long[])
2913
          check = equals((long[]) e1, (long[]) e2);
2914
        else if (e1 instanceof float[] && e2 instanceof float[])
2915
          check = equals((float[]) e1, (float[]) e2);
2916
        else if (e1 instanceof double[] && e2 instanceof double[])
2917
          check = equals((double[]) e1, (double[]) e2);
2918
        else if (e1 instanceof Object[] && e2 instanceof Object[])
2919
          check = equals((Object[]) e1, (Object[]) e2);
2920
        else
2921
          check = e1.equals(e2);
2922
        if (! check)
2923
          return false;
2924
      }
2925
 
2926
    return true;
2927
  }
2928
 
2929
  /**
2930
   * Returns a String representation of the argument array.  Returns "null"
2931
   * if <code>a</code> is null.
2932
   * @param v the array to represent
2933
   * @return a String representing this array
2934
   * @since 1.5
2935
   */
2936
  public static String toString(boolean[] v)
2937
  {
2938
    if (v == null)
2939
      return "null";
2940
    CPStringBuilder b = new CPStringBuilder("[");
2941
    for (int i = 0; i < v.length; ++i)
2942
      {
2943
        if (i > 0)
2944
          b.append(", ");
2945
        b.append(v[i]);
2946
      }
2947
    b.append("]");
2948
    return b.toString();
2949
  }
2950
 
2951
  /**
2952
   * Returns a String representation of the argument array.  Returns "null"
2953
   * if <code>a</code> is null.
2954
   * @param v the array to represent
2955
   * @return a String representing this array
2956
   * @since 1.5
2957
   */
2958
  public static String toString(byte[] v)
2959
  {
2960
    if (v == null)
2961
      return "null";
2962
    CPStringBuilder b = new CPStringBuilder("[");
2963
    for (int i = 0; i < v.length; ++i)
2964
      {
2965
        if (i > 0)
2966
          b.append(", ");
2967
        b.append(v[i]);
2968
      }
2969
    b.append("]");
2970
    return b.toString();
2971
  }
2972
 
2973
  /**
2974
   * Returns a String representation of the argument array.  Returns "null"
2975
   * if <code>a</code> is null.
2976
   * @param v the array to represent
2977
   * @return a String representing this array
2978
   * @since 1.5
2979
   */
2980
  public static String toString(char[] v)
2981
  {
2982
    if (v == null)
2983
      return "null";
2984
    CPStringBuilder b = new CPStringBuilder("[");
2985
    for (int i = 0; i < v.length; ++i)
2986
      {
2987
        if (i > 0)
2988
          b.append(", ");
2989
        b.append(v[i]);
2990
      }
2991
    b.append("]");
2992
    return b.toString();
2993
  }
2994
 
2995
  /**
2996
   * Returns a String representation of the argument array.  Returns "null"
2997
   * if <code>a</code> is null.
2998
   * @param v the array to represent
2999
   * @return a String representing this array
3000
   * @since 1.5
3001
   */
3002
  public static String toString(short[] v)
3003
  {
3004
    if (v == null)
3005
      return "null";
3006
    CPStringBuilder b = new CPStringBuilder("[");
3007
    for (int i = 0; i < v.length; ++i)
3008
      {
3009
        if (i > 0)
3010
          b.append(", ");
3011
        b.append(v[i]);
3012
      }
3013
    b.append("]");
3014
    return b.toString();
3015
  }
3016
 
3017
  /**
3018
   * Returns a String representation of the argument array.  Returns "null"
3019
   * if <code>a</code> is null.
3020
   * @param v the array to represent
3021
   * @return a String representing this array
3022
   * @since 1.5
3023
   */
3024
  public static String toString(int[] v)
3025
  {
3026
    if (v == null)
3027
      return "null";
3028
    CPStringBuilder b = new CPStringBuilder("[");
3029
    for (int i = 0; i < v.length; ++i)
3030
      {
3031
        if (i > 0)
3032
          b.append(", ");
3033
        b.append(v[i]);
3034
      }
3035
    b.append("]");
3036
    return b.toString();
3037
  }
3038
 
3039
  /**
3040
   * Returns a String representation of the argument array.  Returns "null"
3041
   * if <code>a</code> is null.
3042
   * @param v the array to represent
3043
   * @return a String representing this array
3044
   * @since 1.5
3045
   */
3046
  public static String toString(long[] v)
3047
  {
3048
    if (v == null)
3049
      return "null";
3050
    CPStringBuilder b = new CPStringBuilder("[");
3051
    for (int i = 0; i < v.length; ++i)
3052
      {
3053
        if (i > 0)
3054
          b.append(", ");
3055
        b.append(v[i]);
3056
      }
3057
    b.append("]");
3058
    return b.toString();
3059
  }
3060
 
3061
  /**
3062
   * Returns a String representation of the argument array.  Returns "null"
3063
   * if <code>a</code> is null.
3064
   * @param v the array to represent
3065
   * @return a String representing this array
3066
   * @since 1.5
3067
   */
3068
  public static String toString(float[] v)
3069
  {
3070
    if (v == null)
3071
      return "null";
3072
    CPStringBuilder b = new CPStringBuilder("[");
3073
    for (int i = 0; i < v.length; ++i)
3074
      {
3075
        if (i > 0)
3076
          b.append(", ");
3077
        b.append(v[i]);
3078
      }
3079
    b.append("]");
3080
    return b.toString();
3081
  }
3082
 
3083
  /**
3084
   * Returns a String representation of the argument array.  Returns "null"
3085
   * if <code>a</code> is null.
3086
   * @param v the array to represent
3087
   * @return a String representing this array
3088
   * @since 1.5
3089
   */
3090
  public static String toString(double[] v)
3091
  {
3092
    if (v == null)
3093
      return "null";
3094
    CPStringBuilder b = new CPStringBuilder("[");
3095
    for (int i = 0; i < v.length; ++i)
3096
      {
3097
        if (i > 0)
3098
          b.append(", ");
3099
        b.append(v[i]);
3100
      }
3101
    b.append("]");
3102
    return b.toString();
3103
  }
3104
 
3105
  /**
3106
   * Returns a String representation of the argument array.  Returns "null"
3107
   * if <code>a</code> is null.
3108
   * @param v the array to represent
3109
   * @return a String representing this array
3110
   * @since 1.5
3111
   */
3112
  public static String toString(Object[] v)
3113
  {
3114
    if (v == null)
3115
      return "null";
3116
    CPStringBuilder b = new CPStringBuilder("[");
3117
    for (int i = 0; i < v.length; ++i)
3118
      {
3119
        if (i > 0)
3120
          b.append(", ");
3121
        b.append(v[i]);
3122
      }
3123
    b.append("]");
3124
    return b.toString();
3125
  }
3126
 
3127
  private static void deepToString(Object[] v, CPStringBuilder b, HashSet seen)
3128
  {
3129
    b.append("[");
3130
    for (int i = 0; i < v.length; ++i)
3131
      {
3132
        if (i > 0)
3133
          b.append(", ");
3134
        Object elt = v[i];
3135
        if (elt == null)
3136
          b.append("null");
3137
        else if (elt instanceof boolean[])
3138
          b.append(toString((boolean[]) elt));
3139
        else if (elt instanceof byte[])
3140
          b.append(toString((byte[]) elt));
3141
        else if (elt instanceof char[])
3142
          b.append(toString((char[]) elt));
3143
        else if (elt instanceof short[])
3144
          b.append(toString((short[]) elt));
3145
        else if (elt instanceof int[])
3146
          b.append(toString((int[]) elt));
3147
        else if (elt instanceof long[])
3148
          b.append(toString((long[]) elt));
3149
        else if (elt instanceof float[])
3150
          b.append(toString((float[]) elt));
3151
        else if (elt instanceof double[])
3152
          b.append(toString((double[]) elt));
3153
        else if (elt instanceof Object[])
3154
          {
3155
            Object[] os = (Object[]) elt;
3156
            if (seen.contains(os))
3157
              b.append("[...]");
3158
            else
3159
              {
3160
                seen.add(os);
3161
                deepToString(os, b, seen);
3162
              }
3163
          }
3164
        else
3165
          b.append(elt);
3166
      }
3167
    b.append("]");
3168
  }
3169
 
3170
  /** @since 1.5 */
3171
  public static String deepToString(Object[] v)
3172
  {
3173
    if (v == null)
3174
      return "null";
3175
    HashSet seen = new HashSet();
3176
    CPStringBuilder b = new CPStringBuilder();
3177
    deepToString(v, b, seen);
3178
    return b.toString();
3179
  }
3180
 
3181
  /**
3182
   * Inner class used by {@link #asList(Object[])} to provide a list interface
3183
   * to an array. The name, though it clashes with java.util.ArrayList, is
3184
   * Sun's choice for Serialization purposes. Element addition and removal
3185
   * is prohibited, but values can be modified.
3186
   *
3187
   * @author Eric Blake (ebb9@email.byu.edu)
3188
   * @status updated to 1.4
3189
   */
3190
  private static final class ArrayList<E> extends AbstractList<E>
3191
    implements Serializable, RandomAccess
3192
  {
3193
    // We override the necessary methods, plus others which will be much
3194
    // more efficient with direct iteration rather than relying on iterator().
3195
 
3196
    /**
3197
     * Compatible with JDK 1.4.
3198
     */
3199
    private static final long serialVersionUID = -2764017481108945198L;
3200
 
3201
    /**
3202
     * The array we are viewing.
3203
     * @serial the array
3204
     */
3205
    private final E[] a;
3206
 
3207
    /**
3208
     * Construct a list view of the array.
3209
     * @param a the array to view
3210
     * @throws NullPointerException if a is null
3211
     */
3212
    ArrayList(E[] a)
3213
    {
3214
      // We have to explicitly check.
3215
      if (a == null)
3216
        throw new NullPointerException();
3217
      this.a = a;
3218
    }
3219
 
3220
    /**
3221
     * Returns the object at the specified index in
3222
     * the array.
3223
     *
3224
     * @param index The index to retrieve an object from.
3225
     * @return The object at the array index specified.
3226
     */
3227
    public E get(int index)
3228
    {
3229
      return a[index];
3230
    }
3231
 
3232
    /**
3233
     * Returns the size of the array.
3234
     *
3235
     * @return The size.
3236
     */
3237
    public int size()
3238
    {
3239
      return a.length;
3240
    }
3241
 
3242
    /**
3243
     * Replaces the object at the specified index
3244
     * with the supplied element.
3245
     *
3246
     * @param index The index at which to place the new object.
3247
     * @param element The new object.
3248
     * @return The object replaced by this operation.
3249
     */
3250
    public E set(int index, E element)
3251
    {
3252
      E old = a[index];
3253
      a[index] = element;
3254
      return old;
3255
    }
3256
 
3257
    /**
3258
     * Returns true if the array contains the
3259
     * supplied object.
3260
     *
3261
     * @param o The object to look for.
3262
     * @return True if the object was found.
3263
     */
3264
    public boolean contains(Object o)
3265
    {
3266
      return lastIndexOf(o) >= 0;
3267
    }
3268
 
3269
    /**
3270
     * Returns the first index at which the
3271
     * object, o, occurs in the array.
3272
     *
3273
     * @param o The object to search for.
3274
     * @return The first relevant index.
3275
     */
3276
    public int indexOf(Object o)
3277
    {
3278
      int size = a.length;
3279
      for (int i = 0; i < size; i++)
3280
        if (ArrayList.equals(o, a[i]))
3281
          return i;
3282
      return -1;
3283
    }
3284
 
3285
    /**
3286
     * Returns the last index at which the
3287
     * object, o, occurs in the array.
3288
     *
3289
     * @param o The object to search for.
3290
     * @return The last relevant index.
3291
     */
3292
    public int lastIndexOf(Object o)
3293
    {
3294
      int i = a.length;
3295
      while (--i >= 0)
3296
        if (ArrayList.equals(o, a[i]))
3297
          return i;
3298
      return -1;
3299
    }
3300
 
3301
    /**
3302
     * Transforms the list into an array of
3303
     * objects, by simplying cloning the array
3304
     * wrapped by this list.
3305
     *
3306
     * @return A clone of the internal array.
3307
     */
3308
    public Object[] toArray()
3309
    {
3310
      return (Object[]) a.clone();
3311
    }
3312
 
3313
    /**
3314
     * Copies the objects from this list into
3315
     * the supplied array.  The supplied array
3316
     * is shrunk or enlarged to the size of the
3317
     * internal array, and filled with its objects.
3318
     *
3319
     * @param array The array to fill with the objects in this list.
3320
     * @return The array containing the objects in this list,
3321
     *         which may or may not be == to array.
3322
     */
3323
    public <T> T[] toArray(T[] array)
3324
    {
3325
      int size = a.length;
3326
      if (array.length < size)
3327
        array = (T[]) Array.newInstance(array.getClass().getComponentType(),
3328
                                        size);
3329
      else if (array.length > size)
3330
        array[size] = null;
3331
 
3332
      System.arraycopy(a, 0, array, 0, size);
3333
      return array;
3334
    }
3335
  }
3336
 
3337
  /**
3338
   * Returns a copy of the supplied array, truncating or padding as
3339
   * necessary with <code>false</code> to obtain the specified length.
3340
   * Indices that are valid for both arrays will return the same value.
3341
   * Indices that only exist in the returned array (due to the new length
3342
   * being greater than the original length) will return <code>false</code>.
3343
   * This is equivalent to calling
3344
   * <code>copyOfRange(original, 0, newLength)</code>.
3345
   *
3346
   * @param original the original array to be copied.
3347
   * @param newLength the length of the returned array.
3348
   * @return a copy of the original array, truncated or padded with
3349
   *         <code>false</code> to obtain the required length.
3350
   * @throws NegativeArraySizeException if <code>newLength</code> is negative.
3351
   * @throws NullPointerException if <code>original</code> is <code>null</code>.
3352
   * @since 1.6
3353
   * @see #copyOfRange(boolean[],int,int)
3354
   */
3355
  public static boolean[] copyOf(boolean[] original, int newLength)
3356
  {
3357
    if (newLength < 0)
3358
      throw new NegativeArraySizeException("The array size is negative.");
3359
    return copyOfRange(original, 0, newLength);
3360
  }
3361
 
3362
  /**
3363
   * Copies the specified range of the supplied array to a new
3364
   * array, padding as necessary with <code>false</code>
3365
   * if <code>to</code> is greater than the length of the original
3366
   * array.  <code>from</code> must be in the range zero to
3367
   * <code>original.length</code> and can not be greater than
3368
   * <code>to</code>.  The initial element of the
3369
   * returned array will be equal to <code>original[from]</code>,
3370
   * except where <code>from</code> is equal to <code>to</code>
3371
   * (where a zero-length array will be returned) or <code>
3372
   * <code>from</code> is equal to <code>original.length</code>
3373
   * (where an array padded with <code>false</code> will be
3374
   * returned).  The returned array is always of length
3375
   * <code>to - from</code>.
3376
   *
3377
   * @param original the array from which to copy.
3378
   * @param from the initial index of the range, inclusive.
3379
   * @param to the final index of the range, exclusive.
3380
   * @return a copy of the specified range, with padding to
3381
   *         obtain the required length.
3382
   * @throws ArrayIndexOutOfBoundsException if <code>from < 0</code>
3383
   *                                        or <code>from > original.length</code>
3384
   * @throws IllegalArgumentException if <code>from > to</code>
3385
   * @throws NullPointerException if <code>original</code> is <code>null</code>.
3386
   * @since 1.6
3387
   * @see #copyOf(boolean[],int)
3388
   */
3389
  public static boolean[] copyOfRange(boolean[] original, int from, int to)
3390
  {
3391
    if (from > to)
3392
      throw new IllegalArgumentException("The initial index is after " +
3393
                                         "the final index.");
3394
    boolean[] newArray = new boolean[to - from];
3395
    if (to > original.length)
3396
      {
3397
        System.arraycopy(original, from, newArray, 0,
3398
                         original.length - from);
3399
        fill(newArray, original.length, newArray.length, false);
3400
      }
3401
    else
3402
      System.arraycopy(original, from, newArray, 0, to - from);
3403
    return newArray;
3404
  }
3405
 
3406
  /**
3407
   * Returns a copy of the supplied array, truncating or padding as
3408
   * necessary with <code>(byte)0</code> to obtain the specified length.
3409
   * Indices that are valid for both arrays will return the same value.
3410
   * Indices that only exist in the returned array (due to the new length
3411
   * being greater than the original length) will return <code>(byte)0</code>.
3412
   * This is equivalent to calling
3413
   * <code>copyOfRange(original, 0, newLength)</code>.
3414
   *
3415
   * @param original the original array to be copied.
3416
   * @param newLength the length of the returned array.
3417
   * @return a copy of the original array, truncated or padded with
3418
   *         <code>(byte)0</code> to obtain the required length.
3419
   * @throws NegativeArraySizeException if <code>newLength</code> is negative.
3420
   * @throws NullPointerException if <code>original</code> is <code>null</code>.
3421
   * @since 1.6
3422
   * @see #copyOfRange(byte[],int,int)
3423
   */
3424
  public static byte[] copyOf(byte[] original, int newLength)
3425
  {
3426
    if (newLength < 0)
3427
      throw new NegativeArraySizeException("The array size is negative.");
3428
    return copyOfRange(original, 0, newLength);
3429
  }
3430
 
3431
  /**
3432
   * Copies the specified range of the supplied array to a new
3433
   * array, padding as necessary with <code>(byte)0</code>
3434
   * if <code>to</code> is greater than the length of the original
3435
   * array.  <code>from</code> must be in the range zero to
3436
   * <code>original.length</code> and can not be greater than
3437
   * <code>to</code>.  The initial element of the
3438
   * returned array will be equal to <code>original[from]</code>,
3439
   * except where <code>from</code> is equal to <code>to</code>
3440
   * (where a zero-length array will be returned) or <code>
3441
   * <code>from</code> is equal to <code>original.length</code>
3442
   * (where an array padded with <code>(byte)0</code> will be
3443
   * returned).  The returned array is always of length
3444
   * <code>to - from</code>.
3445
   *
3446
   * @param original the array from which to copy.
3447
   * @param from the initial index of the range, inclusive.
3448
   * @param to the final index of the range, exclusive.
3449
   * @return a copy of the specified range, with padding to
3450
   *         obtain the required length.
3451
   * @throws ArrayIndexOutOfBoundsException if <code>from < 0</code>
3452
   *                                        or <code>from > original.length</code>
3453
   * @throws IllegalArgumentException if <code>from > to</code>
3454
   * @throws NullPointerException if <code>original</code> is <code>null</code>.
3455
   * @since 1.6
3456
   * @see #copyOf(byte[],int)
3457
   */
3458
  public static byte[] copyOfRange(byte[] original, int from, int to)
3459
  {
3460
    if (from > to)
3461
      throw new IllegalArgumentException("The initial index is after " +
3462
                                         "the final index.");
3463
    byte[] newArray = new byte[to - from];
3464
    if (to > original.length)
3465
      {
3466
        System.arraycopy(original, from, newArray, 0,
3467
                         original.length - from);
3468
        fill(newArray, original.length, newArray.length, (byte)0);
3469
      }
3470
    else
3471
      System.arraycopy(original, from, newArray, 0, to - from);
3472
    return newArray;
3473
  }
3474
 
3475
  /**
3476
   * Returns a copy of the supplied array, truncating or padding as
3477
   * necessary with <code>'\0'</code> to obtain the specified length.
3478
   * Indices that are valid for both arrays will return the same value.
3479
   * Indices that only exist in the returned array (due to the new length
3480
   * being greater than the original length) will return <code>'\0'</code>.
3481
   * This is equivalent to calling
3482
   * <code>copyOfRange(original, 0, newLength)</code>.
3483
   *
3484
   * @param original the original array to be copied.
3485
   * @param newLength the length of the returned array.
3486
   * @return a copy of the original array, truncated or padded with
3487
   *         <code>'\0'</code> to obtain the required length.
3488
   * @throws NegativeArraySizeException if <code>newLength</code> is negative.
3489
   * @throws NullPointerException if <code>original</code> is <code>null</code>.
3490
   * @since 1.6
3491
   * @see #copyOfRange(char[],int,int)
3492
   */
3493
  public static char[] copyOf(char[] original, int newLength)
3494
  {
3495
    if (newLength < 0)
3496
      throw new NegativeArraySizeException("The array size is negative.");
3497
    return copyOfRange(original, 0, newLength);
3498
  }
3499
 
3500
  /**
3501
   * Copies the specified range of the supplied array to a new
3502
   * array, padding as necessary with <code>'\0'</code>
3503
   * if <code>to</code> is greater than the length of the original
3504
   * array.  <code>from</code> must be in the range zero to
3505
   * <code>original.length</code> and can not be greater than
3506
   * <code>to</code>.  The initial element of the
3507
   * returned array will be equal to <code>original[from]</code>,
3508
   * except where <code>from</code> is equal to <code>to</code>
3509
   * (where a zero-length array will be returned) or <code>
3510
   * <code>from</code> is equal to <code>original.length</code>
3511
   * (where an array padded with <code>'\0'</code> will be
3512
   * returned).  The returned array is always of length
3513
   * <code>to - from</code>.
3514
   *
3515
   * @param original the array from which to copy.
3516
   * @param from the initial index of the range, inclusive.
3517
   * @param to the final index of the range, exclusive.
3518
   * @return a copy of the specified range, with padding to
3519
   *         obtain the required length.
3520
   * @throws ArrayIndexOutOfBoundsException if <code>from < 0</code>
3521
   *                                        or <code>from > original.length</code>
3522
   * @throws IllegalArgumentException if <code>from > to</code>
3523
   * @throws NullPointerException if <code>original</code> is <code>null</code>.
3524
   * @since 1.6
3525
   * @see #copyOf(char[],int)
3526
   */
3527
  public static char[] copyOfRange(char[] original, int from, int to)
3528
  {
3529
    if (from > to)
3530
      throw new IllegalArgumentException("The initial index is after " +
3531
                                         "the final index.");
3532
    char[] newArray = new char[to - from];
3533
    if (to > original.length)
3534
      {
3535
        System.arraycopy(original, from, newArray, 0,
3536
                         original.length - from);
3537
        fill(newArray, original.length, newArray.length, '\0');
3538
      }
3539
    else
3540
      System.arraycopy(original, from, newArray, 0, to - from);
3541
    return newArray;
3542
  }
3543
 
3544
  /**
3545
   * Returns a copy of the supplied array, truncating or padding as
3546
   * necessary with <code>0d</code> to obtain the specified length.
3547
   * Indices that are valid for both arrays will return the same value.
3548
   * Indices that only exist in the returned array (due to the new length
3549
   * being greater than the original length) will return <code>0d</code>.
3550
   * This is equivalent to calling
3551
   * <code>copyOfRange(original, 0, newLength)</code>.
3552
   *
3553
   * @param original the original array to be copied.
3554
   * @param newLength the length of the returned array.
3555
   * @return a copy of the original array, truncated or padded with
3556
   *         <code>0d</code> to obtain the required length.
3557
   * @throws NegativeArraySizeException if <code>newLength</code> is negative.
3558
   * @throws NullPointerException if <code>original</code> is <code>null</code>.
3559
   * @since 1.6
3560
   * @see #copyOfRange(double[],int,int)
3561
   */
3562
  public static double[] copyOf(double[] original, int newLength)
3563
  {
3564
    if (newLength < 0)
3565
      throw new NegativeArraySizeException("The array size is negative.");
3566
    return copyOfRange(original, 0, newLength);
3567
  }
3568
 
3569
  /**
3570
   * Copies the specified range of the supplied array to a new
3571
   * array, padding as necessary with <code>0d</code>
3572
   * if <code>to</code> is greater than the length of the original
3573
   * array.  <code>from</code> must be in the range zero to
3574
   * <code>original.length</code> and can not be greater than
3575
   * <code>to</code>.  The initial element of the
3576
   * returned array will be equal to <code>original[from]</code>,
3577
   * except where <code>from</code> is equal to <code>to</code>
3578
   * (where a zero-length array will be returned) or <code>
3579
   * <code>from</code> is equal to <code>original.length</code>
3580
   * (where an array padded with <code>0d</code> will be
3581
   * returned).  The returned array is always of length
3582
   * <code>to - from</code>.
3583
   *
3584
   * @param original the array from which to copy.
3585
   * @param from the initial index of the range, inclusive.
3586
   * @param to the final index of the range, exclusive.
3587
   * @return a copy of the specified range, with padding to
3588
   *         obtain the required length.
3589
   * @throws ArrayIndexOutOfBoundsException if <code>from < 0</code>
3590
   *                                        or <code>from > original.length</code>
3591
   * @throws IllegalArgumentException if <code>from > to</code>
3592
   * @throws NullPointerException if <code>original</code> is <code>null</code>.
3593
   * @since 1.6
3594
   * @see #copyOf(double[],int)
3595
   */
3596
  public static double[] copyOfRange(double[] original, int from, int to)
3597
  {
3598
    if (from > to)
3599
      throw new IllegalArgumentException("The initial index is after " +
3600
                                         "the final index.");
3601
    double[] newArray = new double[to - from];
3602
    if (to > original.length)
3603
      {
3604
        System.arraycopy(original, from, newArray, 0,
3605
                         original.length - from);
3606
        fill(newArray, original.length, newArray.length, 0d);
3607
      }
3608
    else
3609
      System.arraycopy(original, from, newArray, 0, to - from);
3610
    return newArray;
3611
  }
3612
 
3613
  /**
3614
   * Returns a copy of the supplied array, truncating or padding as
3615
   * necessary with <code>0f</code> to obtain the specified length.
3616
   * Indices that are valid for both arrays will return the same value.
3617
   * Indices that only exist in the returned array (due to the new length
3618
   * being greater than the original length) will return <code>0f</code>.
3619
   * This is equivalent to calling
3620
   * <code>copyOfRange(original, 0, newLength)</code>.
3621
   *
3622
   * @param original the original array to be copied.
3623
   * @param newLength the length of the returned array.
3624
   * @return a copy of the original array, truncated or padded with
3625
   *         <code>0f</code> to obtain the required length.
3626
   * @throws NegativeArraySizeException if <code>newLength</code> is negative.
3627
   * @throws NullPointerException if <code>original</code> is <code>null</code>.
3628
   * @since 1.6
3629
   * @see #copyOfRange(float[],int,int)
3630
   */
3631
  public static float[] copyOf(float[] original, int newLength)
3632
  {
3633
    if (newLength < 0)
3634
      throw new NegativeArraySizeException("The array size is negative.");
3635
    return copyOfRange(original, 0, newLength);
3636
  }
3637
 
3638
  /**
3639
   * Copies the specified range of the supplied array to a new
3640
   * array, padding as necessary with <code>0f</code>
3641
   * if <code>to</code> is greater than the length of the original
3642
   * array.  <code>from</code> must be in the range zero to
3643
   * <code>original.length</code> and can not be greater than
3644
   * <code>to</code>.  The initial element of the
3645
   * returned array will be equal to <code>original[from]</code>,
3646
   * except where <code>from</code> is equal to <code>to</code>
3647
   * (where a zero-length array will be returned) or <code>
3648
   * <code>from</code> is equal to <code>original.length</code>
3649
   * (where an array padded with <code>0f</code> will be
3650
   * returned).  The returned array is always of length
3651
   * <code>to - from</code>.
3652
   *
3653
   * @param original the array from which to copy.
3654
   * @param from the initial index of the range, inclusive.
3655
   * @param to the final index of the range, exclusive.
3656
   * @return a copy of the specified range, with padding to
3657
   *         obtain the required length.
3658
   * @throws ArrayIndexOutOfBoundsException if <code>from < 0</code>
3659
   *                                        or <code>from > original.length</code>
3660
   * @throws IllegalArgumentException if <code>from > to</code>
3661
   * @throws NullPointerException if <code>original</code> is <code>null</code>.
3662
   * @since 1.6
3663
   * @see #copyOf(float[],int)
3664
   */
3665
  public static float[] copyOfRange(float[] original, int from, int to)
3666
  {
3667
    if (from > to)
3668
      throw new IllegalArgumentException("The initial index is after " +
3669
                                         "the final index.");
3670
    float[] newArray = new float[to - from];
3671
    if (to > original.length)
3672
      {
3673
        System.arraycopy(original, from, newArray, 0,
3674
                         original.length - from);
3675
        fill(newArray, original.length, newArray.length, 0f);
3676
      }
3677
    else
3678
      System.arraycopy(original, from, newArray, 0, to - from);
3679
    return newArray;
3680
  }
3681
 
3682
  /**
3683
   * Returns a copy of the supplied array, truncating or padding as
3684
   * necessary with <code>0</code> to obtain the specified length.
3685
   * Indices that are valid for both arrays will return the same value.
3686
   * Indices that only exist in the returned array (due to the new length
3687
   * being greater than the original length) will return <code>0</code>.
3688
   * This is equivalent to calling
3689
   * <code>copyOfRange(original, 0, newLength)</code>.
3690
   *
3691
   * @param original the original array to be copied.
3692
   * @param newLength the length of the returned array.
3693
   * @return a copy of the original array, truncated or padded with
3694
   *         <code>0</code> to obtain the required length.
3695
   * @throws NegativeArraySizeException if <code>newLength</code> is negative.
3696
   * @throws NullPointerException if <code>original</code> is <code>null</code>.
3697
   * @since 1.6
3698
   * @see #copyOfRange(int[],int,int)
3699
   */
3700
  public static int[] copyOf(int[] original, int newLength)
3701
  {
3702
    if (newLength < 0)
3703
      throw new NegativeArraySizeException("The array size is negative.");
3704
    return copyOfRange(original, 0, newLength);
3705
  }
3706
 
3707
  /**
3708
   * Copies the specified range of the supplied array to a new
3709
   * array, padding as necessary with <code>0</code>
3710
   * if <code>to</code> is greater than the length of the original
3711
   * array.  <code>from</code> must be in the range zero to
3712
   * <code>original.length</code> and can not be greater than
3713
   * <code>to</code>.  The initial element of the
3714
   * returned array will be equal to <code>original[from]</code>,
3715
   * except where <code>from</code> is equal to <code>to</code>
3716
   * (where a zero-length array will be returned) or <code>
3717
   * <code>from</code> is equal to <code>original.length</code>
3718
   * (where an array padded with <code>0</code> will be
3719
   * returned).  The returned array is always of length
3720
   * <code>to - from</code>.
3721
   *
3722
   * @param original the array from which to copy.
3723
   * @param from the initial index of the range, inclusive.
3724
   * @param to the final index of the range, exclusive.
3725
   * @return a copy of the specified range, with padding to
3726
   *         obtain the required length.
3727
   * @throws ArrayIndexOutOfBoundsException if <code>from < 0</code>
3728
   *                                        or <code>from > original.length</code>
3729
   * @throws IllegalArgumentException if <code>from > to</code>
3730
   * @throws NullPointerException if <code>original</code> is <code>null</code>.
3731
   * @since 1.6
3732
   * @see #copyOf(int[],int)
3733
   */
3734
  public static int[] copyOfRange(int[] original, int from, int to)
3735
  {
3736
    if (from > to)
3737
      throw new IllegalArgumentException("The initial index is after " +
3738
                                         "the final index.");
3739
    int[] newArray = new int[to - from];
3740
    if (to > original.length)
3741
      {
3742
        System.arraycopy(original, from, newArray, 0,
3743
                         original.length - from);
3744
        fill(newArray, original.length, newArray.length, 0);
3745
      }
3746
    else
3747
      System.arraycopy(original, from, newArray, 0, to - from);
3748
    return newArray;
3749
  }
3750
 
3751
  /**
3752
   * Returns a copy of the supplied array, truncating or padding as
3753
   * necessary with <code>0L</code> to obtain the specified length.
3754
   * Indices that are valid for both arrays will return the same value.
3755
   * Indices that only exist in the returned array (due to the new length
3756
   * being greater than the original length) will return <code>0L</code>.
3757
   * This is equivalent to calling
3758
   * <code>copyOfRange(original, 0, newLength)</code>.
3759
   *
3760
   * @param original the original array to be copied.
3761
   * @param newLength the length of the returned array.
3762
   * @return a copy of the original array, truncated or padded with
3763
   *         <code>0L</code> to obtain the required length.
3764
   * @throws NegativeArraySizeException if <code>newLength</code> is negative.
3765
   * @throws NullPointerException if <code>original</code> is <code>null</code>.
3766
   * @since 1.6
3767
   * @see #copyOfRange(long[],int,int)
3768
   */
3769
  public static long[] copyOf(long[] original, int newLength)
3770
  {
3771
    if (newLength < 0)
3772
      throw new NegativeArraySizeException("The array size is negative.");
3773
    return copyOfRange(original, 0, newLength);
3774
  }
3775
 
3776
  /**
3777
   * Copies the specified range of the supplied array to a new
3778
   * array, padding as necessary with <code>0L</code>
3779
   * if <code>to</code> is greater than the length of the original
3780
   * array.  <code>from</code> must be in the range zero to
3781
   * <code>original.length</code> and can not be greater than
3782
   * <code>to</code>.  The initial element of the
3783
   * returned array will be equal to <code>original[from]</code>,
3784
   * except where <code>from</code> is equal to <code>to</code>
3785
   * (where a zero-length array will be returned) or <code>
3786
   * <code>from</code> is equal to <code>original.length</code>
3787
   * (where an array padded with <code>0L</code> will be
3788
   * returned).  The returned array is always of length
3789
   * <code>to - from</code>.
3790
   *
3791
   * @param original the array from which to copy.
3792
   * @param from the initial index of the range, inclusive.
3793
   * @param to the final index of the range, exclusive.
3794
   * @return a copy of the specified range, with padding to
3795
   *         obtain the required length.
3796
   * @throws ArrayIndexOutOfBoundsException if <code>from < 0</code>
3797
   *                                        or <code>from > original.length</code>
3798
   * @throws IllegalArgumentException if <code>from > to</code>
3799
   * @throws NullPointerException if <code>original</code> is <code>null</code>.
3800
   * @since 1.6
3801
   * @see #copyOf(long[],int)
3802
   */
3803
  public static long[] copyOfRange(long[] original, int from, int to)
3804
  {
3805
    if (from > to)
3806
      throw new IllegalArgumentException("The initial index is after " +
3807
                                         "the final index.");
3808
    long[] newArray = new long[to - from];
3809
    if (to > original.length)
3810
      {
3811
        System.arraycopy(original, from, newArray, 0,
3812
                         original.length - from);
3813
        fill(newArray, original.length, newArray.length, 0L);
3814
      }
3815
    else
3816
      System.arraycopy(original, from, newArray, 0, to - from);
3817
    return newArray;
3818
  }
3819
 
3820
  /**
3821
   * Returns a copy of the supplied array, truncating or padding as
3822
   * necessary with <code>(short)0</code> to obtain the specified length.
3823
   * Indices that are valid for both arrays will return the same value.
3824
   * Indices that only exist in the returned array (due to the new length
3825
   * being greater than the original length) will return <code>(short)0</code>.
3826
   * This is equivalent to calling
3827
   * <code>copyOfRange(original, 0, newLength)</code>.
3828
   *
3829
   * @param original the original array to be copied.
3830
   * @param newLength the length of the returned array.
3831
   * @return a copy of the original array, truncated or padded with
3832
   *         <code>(short)0</code> to obtain the required length.
3833
   * @throws NegativeArraySizeException if <code>newLength</code> is negative.
3834
   * @throws NullPointerException if <code>original</code> is <code>null</code>.
3835
   * @since 1.6
3836
   * @see #copyOfRange(short[],int,int)
3837
   */
3838
  public static short[] copyOf(short[] original, int newLength)
3839
  {
3840
    if (newLength < 0)
3841
      throw new NegativeArraySizeException("The array size is negative.");
3842
    return copyOfRange(original, 0, newLength);
3843
  }
3844
 
3845
  /**
3846
   * Copies the specified range of the supplied array to a new
3847
   * array, padding as necessary with <code>(short)0</code>
3848
   * if <code>to</code> is greater than the length of the original
3849
   * array.  <code>from</code> must be in the range zero to
3850
   * <code>original.length</code> and can not be greater than
3851
   * <code>to</code>.  The initial element of the
3852
   * returned array will be equal to <code>original[from]</code>,
3853
   * except where <code>from</code> is equal to <code>to</code>
3854
   * (where a zero-length array will be returned) or <code>
3855
   * <code>from</code> is equal to <code>original.length</code>
3856
   * (where an array padded with <code>(short)0</code> will be
3857
   * returned).  The returned array is always of length
3858
   * <code>to - from</code>.
3859
   *
3860
   * @param original the array from which to copy.
3861
   * @param from the initial index of the range, inclusive.
3862
   * @param to the final index of the range, exclusive.
3863
   * @return a copy of the specified range, with padding to
3864
   *         obtain the required length.
3865
   * @throws ArrayIndexOutOfBoundsException if <code>from < 0</code>
3866
   *                                        or <code>from > original.length</code>
3867
   * @throws IllegalArgumentException if <code>from > to</code>
3868
   * @throws NullPointerException if <code>original</code> is <code>null</code>.
3869
   * @since 1.6
3870
   * @see #copyOf(short[],int)
3871
   */
3872
  public static short[] copyOfRange(short[] original, int from, int to)
3873
  {
3874
    if (from > to)
3875
      throw new IllegalArgumentException("The initial index is after " +
3876
                                         "the final index.");
3877
    short[] newArray = new short[to - from];
3878
    if (to > original.length)
3879
      {
3880
        System.arraycopy(original, from, newArray, 0,
3881
                         original.length - from);
3882
        fill(newArray, original.length, newArray.length, (short)0);
3883
      }
3884
    else
3885
      System.arraycopy(original, from, newArray, 0, to - from);
3886
    return newArray;
3887
  }
3888
 
3889
  /**
3890
   * Returns a copy of the supplied array, truncating or padding as
3891
   * necessary with <code>null</code> to obtain the specified length.
3892
   * Indices that are valid for both arrays will return the same value.
3893
   * Indices that only exist in the returned array (due to the new length
3894
   * being greater than the original length) will return <code>null</code>.
3895
   * This is equivalent to calling
3896
   * <code>copyOfRange(original, 0, newLength)</code>.
3897
   *
3898
   * @param original the original array to be copied.
3899
   * @param newLength the length of the returned array.
3900
   * @return a copy of the original array, truncated or padded with
3901
   *         <code>null</code> to obtain the required length.
3902
   * @throws NegativeArraySizeException if <code>newLength</code> is negative.
3903
   * @throws NullPointerException if <code>original</code> is <code>null</code>.
3904
   * @since 1.6
3905
   * @see #copyOfRange(T[],int,int)
3906
   */
3907
  public static <T> T[] copyOf(T[] original, int newLength)
3908
  {
3909
    if (newLength < 0)
3910
      throw new NegativeArraySizeException("The array size is negative.");
3911
    return copyOfRange(original, 0, newLength);
3912
  }
3913
 
3914
  /**
3915
   * Copies the specified range of the supplied array to a new
3916
   * array, padding as necessary with <code>null</code>
3917
   * if <code>to</code> is greater than the length of the original
3918
   * array.  <code>from</code> must be in the range zero to
3919
   * <code>original.length</code> and can not be greater than
3920
   * <code>to</code>.  The initial element of the
3921
   * returned array will be equal to <code>original[from]</code>,
3922
   * except where <code>from</code> is equal to <code>to</code>
3923
   * (where a zero-length array will be returned) or <code>
3924
   * <code>from</code> is equal to <code>original.length</code>
3925
   * (where an array padded with <code>null</code> will be
3926
   * returned).  The returned array is always of length
3927
   * <code>to - from</code>.
3928
   *
3929
   * @param original the array from which to copy.
3930
   * @param from the initial index of the range, inclusive.
3931
   * @param to the final index of the range, exclusive.
3932
   * @return a copy of the specified range, with padding to
3933
   *         obtain the required length.
3934
   * @throws ArrayIndexOutOfBoundsException if <code>from < 0</code>
3935
   *                                        or <code>from > original.length</code>
3936
   * @throws IllegalArgumentException if <code>from > to</code>
3937
   * @throws NullPointerException if <code>original</code> is <code>null</code>.
3938
   * @since 1.6
3939
   * @see #copyOf(T[],int)
3940
   */
3941
  public static <T> T[] copyOfRange(T[] original, int from, int to)
3942
  {
3943
    if (from > to)
3944
      throw new IllegalArgumentException("The initial index is after " +
3945
                                         "the final index.");
3946
    Class elemType = original.getClass().getComponentType();
3947
    T[] newArray = (T[]) Array.newInstance(elemType, to - from);
3948
    if (to > original.length)
3949
      {
3950
        System.arraycopy(original, from, newArray, 0,
3951
                         original.length - from);
3952
        fill(newArray, original.length, newArray.length, null);
3953
      }
3954
    else
3955
      System.arraycopy(original, from, newArray, 0, to - from);
3956
    return newArray;
3957
  }
3958
 
3959
  /**
3960
   * Returns a copy of the supplied array, truncating or padding as
3961
   * necessary with <code>null</code> to obtain the specified length.
3962
   * Indices that are valid for both arrays will return the same value.
3963
   * Indices that only exist in the returned array (due to the new length
3964
   * being greater than the original length) will return <code>null</code>.
3965
   * This is equivalent to calling
3966
   * <code>copyOfRange(original, 0, newLength, newType)</code>.  The returned
3967
   * array will be of the specified type, <code>newType</code>.
3968
   *
3969
   * @param original the original array to be copied.
3970
   * @param newLength the length of the returned array.
3971
   * @param newType the type of the returned array.
3972
   * @return a copy of the original array, truncated or padded with
3973
   *         <code>null</code> to obtain the required length.
3974
   * @throws NegativeArraySizeException if <code>newLength</code> is negative.
3975
   * @throws NullPointerException if <code>original</code> is <code>null</code>.
3976
   * @since 1.6
3977
   * @see #copyOfRange(U[],int,int,Class)
3978
   */
3979
  public static <T,U> T[] copyOf(U[] original, int newLength,
3980
                                 Class<? extends T[]> newType)
3981
  {
3982
    if (newLength < 0)
3983
      throw new NegativeArraySizeException("The array size is negative.");
3984
    return copyOfRange(original, 0, newLength, newType);
3985
  }
3986
 
3987
  /**
3988
   * Copies the specified range of the supplied array to a new
3989
   * array, padding as necessary with <code>null</code>
3990
   * if <code>to</code> is greater than the length of the original
3991
   * array.  <code>from</code> must be in the range zero to
3992
   * <code>original.length</code> and can not be greater than
3993
   * <code>to</code>.  The initial element of the
3994
   * returned array will be equal to <code>original[from]</code>,
3995
   * except where <code>from</code> is equal to <code>to</code>
3996
   * (where a zero-length array will be returned) or <code>
3997
   * <code>from</code> is equal to <code>original.length</code>
3998
   * (where an array padded with <code>null</code> will be
3999
   * returned).  The returned array is always of length
4000
   * <code>to - from</code> and will be of the specified type,
4001
   * <code>newType</code>.
4002
   *
4003
   * @param original the array from which to copy.
4004
   * @param from the initial index of the range, inclusive.
4005
   * @param to the final index of the range, exclusive.
4006
   * @param newType the type of the returned array.
4007
   * @return a copy of the specified range, with padding to
4008
   *         obtain the required length.
4009
   * @throws ArrayIndexOutOfBoundsException if <code>from < 0</code>
4010
   *                                        or <code>from > original.length</code>
4011
   * @throws IllegalArgumentException if <code>from > to</code>
4012
   * @throws NullPointerException if <code>original</code> is <code>null</code>.
4013
   * @since 1.6
4014
   * @see #copyOf(T[],int)
4015
   */
4016
  public static <T,U> T[] copyOfRange(U[] original, int from, int to,
4017
                                      Class<? extends T[]> newType)
4018
  {
4019
    if (from > to)
4020
      throw new IllegalArgumentException("The initial index is after " +
4021
                                         "the final index.");
4022
    T[] newArray = (T[]) Array.newInstance(newType.getComponentType(),
4023
                                           to - from);
4024
    if (to > original.length)
4025
      {
4026
        System.arraycopy(original, from, newArray, 0,
4027
                         original.length - from);
4028
        fill(newArray, original.length, newArray.length, null);
4029
      }
4030
    else
4031
      System.arraycopy(original, from, newArray, 0, to - from);
4032
    return newArray;
4033
  }
4034
}

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