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1 /* hash - hashing table processing.
2 Copyright (C) 1998, 1999, 2000, 2001, 2002 Free Software Foundation, Inc.
3 Written by Jim Meyering, 1992.
4
5 This program is free software; you can redistribute it and/or modify
6 it under the terms of the GNU General Public License as published by
7 the Free Software Foundation; either version 2, or (at your option)
8 any later version.
9
10 This program is distributed in the hope that it will be useful,
11 but WITHOUT ANY WARRANTY; without even the implied warranty of
12 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
13 GNU General Public License for more details.
14
15 You should have received a copy of the GNU General Public License
16 along with this program; if not, write to the Free Software Foundation,
17 Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. */
18
19 /* A generic hash table package. */
20
21 /* Define USE_OBSTACK to 1 if you want the allocator to use obstacks instead
22 of malloc. If you change USE_OBSTACK, you have to recompile! */
23
24 #if HAVE_CONFIG_H
25 # include <config.h>
26 #endif
27 #if HAVE_STDLIB_H
28 # include <stdlib.h>
29 #endif
30 #if HAVE_STDBOOL_H
31 # include <stdbool.h>
32 #else
33 typedef enum {false = 0, true = 1} bool;
34 #endif
35 #include <stdio.h>
36
37 #ifndef HAVE_DECL_FREE
38 "this configure-time declaration test was not run"
39 #endif
40 #if !HAVE_DECL_FREE
41 void free ();
42 #endif
43
44 #ifndef HAVE_DECL_MALLOC
45 "this configure-time declaration test was not run"
46 #endif
47 #if !HAVE_DECL_MALLOC
48 char *malloc ();
49 #endif
50
51 #if USE_OBSTACK
52 # include "obstack.h"
53 # ifndef obstack_chunk_alloc
54 # define obstack_chunk_alloc malloc
55 # endif
56 # ifndef obstack_chunk_free
57 # define obstack_chunk_free free
58 # endif
59 #endif
60
61 #include "hash.h"
62
63 struct hash_table
64 {
65 /* The array of buckets starts at BUCKET and extends to BUCKET_LIMIT-1,
66 for a possibility of N_BUCKETS. Among those, N_BUCKETS_USED buckets
67 are not empty, there are N_ENTRIES active entries in the table. */
68 struct hash_entry *bucket;
69 struct hash_entry *bucket_limit;
70 unsigned n_buckets;
71 unsigned n_buckets_used;
72 unsigned n_entries;
73
74 /* Tuning arguments, kept in a physicaly separate structure. */
75 const Hash_tuning *tuning;
76
77 /* Three functions are given to `hash_initialize', see the documentation
78 block for this function. In a word, HASHER randomizes a user entry
79 into a number up from 0 up to some maximum minus 1; COMPARATOR returns
80 true if two user entries compare equally; and DATA_FREER is the cleanup
81 function for a user entry. */
82 Hash_hasher hasher;
83 Hash_comparator comparator;
84 Hash_data_freer data_freer;
85
86 /* A linked list of freed struct hash_entry structs. */
87 struct hash_entry *free_entry_list;
88
89 #if USE_OBSTACK
90 /* Whenever obstacks are used, it is possible to allocate all overflowed
91 entries into a single stack, so they all can be freed in a single
92 operation. It is not clear if the speedup is worth the trouble. */
93 struct obstack entry_stack;
94 #endif
95 };
96
97 /* A hash table contains many internal entries, each holding a pointer to
98 some user provided data (also called a user entry). An entry indistinctly
99 refers to both the internal entry and its associated user entry. A user
100 entry contents may be hashed by a randomization function (the hashing
101 function, or just `hasher' for short) into a number (or `slot') between 0
102 and the current table size. At each slot position in the hash table,
103 starts a linked chain of entries for which the user data all hash to this
104 slot. A bucket is the collection of all entries hashing to the same slot.
105
106 A good `hasher' function will distribute entries rather evenly in buckets.
107 In the ideal case, the length of each bucket is roughly the number of
108 entries divided by the table size. Finding the slot for a data is usually
109 done in constant time by the `hasher', and the later finding of a precise
110 entry is linear in time with the size of the bucket. Consequently, a
111 larger hash table size (that is, a larger number of buckets) is prone to
112 yielding shorter chains, *given* the `hasher' function behaves properly.
113
114 Long buckets slow down the lookup algorithm. One might use big hash table
115 sizes in hope to reduce the average length of buckets, but this might
116 become inordinate, as unused slots in the hash table take some space. The
117 best bet is to make sure you are using a good `hasher' function (beware
118 that those are not that easy to write! :-), and to use a table size
119 larger than the actual number of entries. */
120
121 /* If an insertion makes the ratio of nonempty buckets to table size larger
122 than the growth threshold (a number between 0.0 and 1.0), then increase
123 the table size by multiplying by the growth factor (a number greater than
124 1.0). The growth threshold defaults to 0.8, and the growth factor
125 defaults to 1.414, meaning that the table will have doubled its size
126 every second time 80% of the buckets get used. */
127 #define DEFAULT_GROWTH_THRESHOLD 0.8
128 #define DEFAULT_GROWTH_FACTOR 1.414
129
130 /* If a deletion empties a bucket and causes the ratio of used buckets to
131 table size to become smaller than the shrink threshold (a number between
132 0.0 and 1.0), then shrink the table by multiplying by the shrink factor (a
133 number greater than the shrink threshold but smaller than 1.0). The shrink
134 threshold and factor default to 0.0 and 1.0, meaning that the table never
135 shrinks. */
136 #define DEFAULT_SHRINK_THRESHOLD 0.0
137 #define DEFAULT_SHRINK_FACTOR 1.0
138
139 /* Use this to initialize or reset a TUNING structure to
140 some sensible values. */
141 static const Hash_tuning default_tuning =
142 {
143 DEFAULT_SHRINK_THRESHOLD,
144 DEFAULT_SHRINK_FACTOR,
145 DEFAULT_GROWTH_THRESHOLD,
146 DEFAULT_GROWTH_FACTOR,
147 false
148 };
149
150 /* Information and lookup. */
151
152 /* The following few functions provide information about the overall hash
153 table organization: the number of entries, number of buckets and maximum
154 length of buckets. */
155
156 /* Return the number of buckets in the hash table. The table size, the total
157 number of buckets (used plus unused), or the maximum number of slots, are
158 the same quantity. */
159
160 unsigned
161 hash_get_n_buckets (const Hash_table *table)
162 {
163 return table->n_buckets;
164 }
165
166 /* Return the number of slots in use (non-empty buckets). */
167
168 unsigned
169 hash_get_n_buckets_used (const Hash_table *table)
170 {
171 return table->n_buckets_used;
172 }
173
174 /* Return the number of active entries. */
175
176 unsigned
177 hash_get_n_entries (const Hash_table *table)
178 {
179 return table->n_entries;
180 }
181
182 /* Return the length of the longest chain (bucket). */
183
184 unsigned
185 hash_get_max_bucket_length (const Hash_table *table)
186 {
187 struct hash_entry *bucket;
188 unsigned max_bucket_length = 0;
189
190 for (bucket = table->bucket; bucket < table->bucket_limit; bucket++)
191 {
192 if (bucket->data)
193 {
194 struct hash_entry *cursor = bucket;
195 unsigned bucket_length = 1;
196
197 while (cursor = cursor->next, cursor)
198 bucket_length++;
199
200 if (bucket_length > max_bucket_length)
201 max_bucket_length = bucket_length;
202 }
203 }
204
205 return max_bucket_length;
206 }
207
208 /* Do a mild validation of a hash table, by traversing it and checking two
209 statistics. */
210
211 bool
212 hash_table_ok (const Hash_table *table)
213 {
214 struct hash_entry *bucket;
215 unsigned n_buckets_used = 0;
216 unsigned n_entries = 0;
217
218 for (bucket = table->bucket; bucket < table->bucket_limit; bucket++)
219 {
220 if (bucket->data)
221 {
222 struct hash_entry *cursor = bucket;
223
224 /* Count bucket head. */
225 n_buckets_used++;
226 n_entries++;
227
228 /* Count bucket overflow. */
229 while (cursor = cursor->next, cursor)
230 n_entries++;
231 }
232 }
233
234 if (n_buckets_used == table->n_buckets_used && n_entries == table->n_entries)
235 return true;
236
237 return false;
238 }
239
240 void
241 hash_print_statistics (const Hash_table *table, FILE *stream)
242 {
243 unsigned n_entries = hash_get_n_entries (table);
244 unsigned n_buckets = hash_get_n_buckets (table);
245 unsigned n_buckets_used = hash_get_n_buckets_used (table);
246 unsigned max_bucket_length = hash_get_max_bucket_length (table);
247
248 fprintf (stream, "# entries: %u\n", n_entries);
249 fprintf (stream, "# buckets: %u\n", n_buckets);
250 fprintf (stream, "# buckets used: %u (%.2f%%)\n", n_buckets_used,
251 (100.0 * n_buckets_used) / n_buckets);
252 fprintf (stream, "max bucket length: %u\n", max_bucket_length);
253 }
254
255 /* If ENTRY matches an entry already in the hash table, return the
256 entry from the table. Otherwise, return NULL. */
257
258 void *
259 hash_lookup (const Hash_table *table, const void *entry)
260 {
261 struct hash_entry *bucket
262 = table->bucket + table->hasher (entry, table->n_buckets);
263 struct hash_entry *cursor;
264
265 if (! (bucket < table->bucket_limit))
266 abort ();
267
268 if (bucket->data == NULL)
269 return NULL;
270
271 for (cursor = bucket; cursor; cursor = cursor->next)
272 if (table->comparator (entry, cursor->data))
273 return cursor->data;
274
275 return NULL;
276 }
277
278 /* Walking. */
279
280 /* The functions in this page traverse the hash table and process the
281 contained entries. For the traversal to work properly, the hash table
282 should not be resized nor modified while any particular entry is being
283 processed. In particular, entries should not be added or removed. */
284
285 /* Return the first data in the table, or NULL if the table is empty. */
286
287 void *
288 hash_get_first (const Hash_table *table)
289 {
290 struct hash_entry *bucket;
291
292 if (table->n_entries == 0)
293 return NULL;
294
295 for (bucket = table->bucket; ; bucket++)
296 if (! (bucket < table->bucket_limit))
297 abort ();
298 else if (bucket->data)
299 return bucket->data;
300 }
301
302 /* Return the user data for the entry following ENTRY, where ENTRY has been
303 returned by a previous call to either `hash_get_first' or `hash_get_next'.
304 Return NULL if there are no more entries. */
305
306 void *
307 hash_get_next (const Hash_table *table, const void *entry)
308 {
309 struct hash_entry *bucket
310 = table->bucket + table->hasher (entry, table->n_buckets);
311 struct hash_entry *cursor;
312
313 if (! (bucket < table->bucket_limit))
314 abort ();
315
316 /* Find next entry in the same bucket. */
317 for (cursor = bucket; cursor; cursor = cursor->next)
318 if (cursor->data == entry && cursor->next)
319 return cursor->next->data;
320
321 /* Find first entry in any subsequent bucket. */
322 while (++bucket < table->bucket_limit)
323 if (bucket->data)
324 return bucket->data;
325
326 /* None found. */
327 return NULL;
328 }
329
330 /* Fill BUFFER with pointers to active user entries in the hash table, then
331 return the number of pointers copied. Do not copy more than BUFFER_SIZE
332 pointers. */
333
334 unsigned
335 hash_get_entries (const Hash_table *table, void **buffer,
336 unsigned buffer_size)
337 {
338 unsigned counter = 0;
339 struct hash_entry *bucket;
340 struct hash_entry *cursor;
341
342 for (bucket = table->bucket; bucket < table->bucket_limit; bucket++)
343 {
344 if (bucket->data)
345 {
346 for (cursor = bucket; cursor; cursor = cursor->next)
347 {
348 if (counter >= buffer_size)
349 return counter;
350 buffer[counter++] = cursor->data;
351 }
352 }
353 }
354
355 return counter;
356 }
357
358 /* Call a PROCESSOR function for each entry of a hash table, and return the
359 number of entries for which the processor function returned success. A
360 pointer to some PROCESSOR_DATA which will be made available to each call to
361 the processor function. The PROCESSOR accepts two arguments: the first is
362 the user entry being walked into, the second is the value of PROCESSOR_DATA
363 as received. The walking continue for as long as the PROCESSOR function
364 returns nonzero. When it returns zero, the walking is interrupted. */
365
366 unsigned
367 hash_do_for_each (const Hash_table *table, Hash_processor processor,
368 void *processor_data)
369 {
370 unsigned counter = 0;
371 struct hash_entry *bucket;
372 struct hash_entry *cursor;
373
374 for (bucket = table->bucket; bucket < table->bucket_limit; bucket++)
375 {
376 if (bucket->data)
377 {
378 for (cursor = bucket; cursor; cursor = cursor->next)
379 {
380 if (!(*processor) (cursor->data, processor_data))
381 return counter;
382 counter++;
383 }
384 }
385 }
386
387 return counter;
388 }
389
390 /* Allocation and clean-up. */
391
392 /* Return a hash index for a NUL-terminated STRING between 0 and N_BUCKETS-1.
393 This is a convenience routine for constructing other hashing functions. */
394
395 #if USE_DIFF_HASH
396
397 /* About hashings, Paul Eggert writes to me (FP), on 1994-01-01: "Please see
398 B. J. McKenzie, R. Harries & T. Bell, Selecting a hashing algorithm,
399 Software--practice & experience 20, 2 (Feb 1990), 209-224. Good hash
400 algorithms tend to be domain-specific, so what's good for [diffutils'] io.c
401 may not be good for your application." */
402
403 unsigned
404 hash_string (const char *string, unsigned n_buckets)
405 {
406 # ifndef CHAR_BIT
407 # define CHAR_BIT 8
408 # endif
409 # define ROTATE_LEFT(Value, Shift) \
410 ((Value) << (Shift) | (Value) >> ((sizeof (unsigned) * CHAR_BIT) - (Shift)))
411 # define HASH_ONE_CHAR(Value, Byte) \
412 ((Byte) + ROTATE_LEFT (Value, 7))
413
414 unsigned value = 0;
415
416 for (; *string; string++)
417 value = HASH_ONE_CHAR (value, *(const unsigned char *) string);
418 return value % n_buckets;
419
420 # undef ROTATE_LEFT
421 # undef HASH_ONE_CHAR
422 }
423
424 #else /* not USE_DIFF_HASH */
425
426 /* This one comes from `recode', and performs a bit better than the above as
427 per a few experiments. It is inspired from a hashing routine found in the
428 very old Cyber `snoop', itself written in typical Greg Mansfield style.
429 (By the way, what happened to this excellent man? Is he still alive?) */
430
431 unsigned
432 hash_string (const char *string, unsigned n_buckets)
433 {
434 unsigned value = 0;
435
436 while (*string)
437 value = ((value * 31 + (int) *(const unsigned char *) string++)
438 % n_buckets);
439 return value;
440 }
441
442 #endif /* not USE_DIFF_HASH */
443
444 /* Return true if CANDIDATE is a prime number. CANDIDATE should be an odd
445 number at least equal to 11. */
446
447 static bool
448 is_prime (unsigned long candidate)
449 {
450 unsigned long divisor = 3;
451 unsigned long square = divisor * divisor;
452
453 while (square < candidate && (candidate % divisor))
454 {
455 divisor++;
456 square += 4 * divisor;
457 divisor++;
458 }
459
460 return (candidate % divisor ? true : false);
461 }
462
463 /* Round a given CANDIDATE number up to the nearest prime, and return that
464 prime. Primes lower than 10 are merely skipped. */
465
466 static unsigned long
467 next_prime (unsigned long candidate)
468 {
469 /* Skip small primes. */
470 if (candidate < 10)
471 candidate = 10;
472
473 /* Make it definitely odd. */
474 candidate |= 1;
475
476 while (!is_prime (candidate))
477 candidate += 2;
478
479 return candidate;
480 }
481
482 void
483 hash_reset_tuning (Hash_tuning *tuning)
484 {
485 *tuning = default_tuning;
486 }
487
488 /* For the given hash TABLE, check the user supplied tuning structure for
489 reasonable values, and return true if there is no gross error with it.
490 Otherwise, definitively reset the TUNING field to some acceptable default
491 in the hash table (that is, the user loses the right of further modifying
492 tuning arguments), and return false. */
493
494 static bool
495 check_tuning (Hash_table *table)
496 {
497 const Hash_tuning *tuning = table->tuning;
498
499 if (tuning->growth_threshold > 0.0
500 && tuning->growth_threshold < 1.0
501 && tuning->growth_factor > 1.0
502 && tuning->shrink_threshold >= 0.0
503 && tuning->shrink_threshold < 1.0
504 && tuning->shrink_factor > tuning->shrink_threshold
505 && tuning->shrink_factor <= 1.0
506 && tuning->shrink_threshold < tuning->growth_threshold)
507 return true;
508
509 table->tuning = &default_tuning;
510 return false;
511 }
512
513 /* Allocate and return a new hash table, or NULL upon failure. The initial
514 number of buckets is automatically selected so as to _guarantee_ that you
515 may insert at least CANDIDATE different user entries before any growth of
516 the hash table size occurs. So, if have a reasonably tight a-priori upper
517 bound on the number of entries you intend to insert in the hash table, you
518 may save some table memory and insertion time, by specifying it here. If
519 the IS_N_BUCKETS field of the TUNING structure is true, the CANDIDATE
520 argument has its meaning changed to the wanted number of buckets.
521
522 TUNING points to a structure of user-supplied values, in case some fine
523 tuning is wanted over the default behavior of the hasher. If TUNING is
524 NULL, the default tuning parameters are used instead.
525
526 The user-supplied HASHER function should be provided. It accepts two
527 arguments ENTRY and TABLE_SIZE. It computes, by hashing ENTRY contents, a
528 slot number for that entry which should be in the range 0..TABLE_SIZE-1.
529 This slot number is then returned.
530
531 The user-supplied COMPARATOR function should be provided. It accepts two
532 arguments pointing to user data, it then returns true for a pair of entries
533 that compare equal, or false otherwise. This function is internally called
534 on entries which are already known to hash to the same bucket index.
535
536 The user-supplied DATA_FREER function, when not NULL, may be later called
537 with the user data as an argument, just before the entry containing the
538 data gets freed. This happens from within `hash_free' or `hash_clear'.
539 You should specify this function only if you want these functions to free
540 all of your `data' data. This is typically the case when your data is
541 simply an auxiliary struct that you have malloc'd to aggregate several
542 values. */
543
544 Hash_table *
545 hash_initialize (unsigned candidate, const Hash_tuning *tuning,
546 Hash_hasher hasher, Hash_comparator comparator,
547 Hash_data_freer data_freer)
548 {
549 Hash_table *table;
550 struct hash_entry *bucket;
551
552 if (hasher == NULL || comparator == NULL)
553 return NULL;
554
555 table = (Hash_table *) malloc (sizeof (Hash_table));
556 if (table == NULL)
557 return NULL;
558
559 if (!tuning)
560 tuning = &default_tuning;
561 table->tuning = tuning;
562 if (!check_tuning (table))
563 {
564 /* Fail if the tuning options are invalid. This is the only occasion
565 when the user gets some feedback about it. Once the table is created,
566 if the user provides invalid tuning options, we silently revert to
567 using the defaults, and ignore further request to change the tuning
568 options. */
569 free (table);
570 return NULL;
571 }
572
573 table->n_buckets
574 = next_prime (tuning->is_n_buckets ? candidate
575 : (unsigned) (candidate / tuning->growth_threshold));
576
577 table->bucket = (struct hash_entry *)
578 malloc (table->n_buckets * sizeof (struct hash_entry));
579 if (table->bucket == NULL)
580 {
581 free (table);
582 return NULL;
583 }
584 table->bucket_limit = table->bucket + table->n_buckets;
585
586 for (bucket = table->bucket; bucket < table->bucket_limit; bucket++)
587 {
588 bucket->data = NULL;
589 bucket->next = NULL;
590 }
591 table->n_buckets_used = 0;
592 table->n_entries = 0;
593
594 table->hasher = hasher;
595 table->comparator = comparator;
596 table->data_freer = data_freer;
597
598 table->free_entry_list = NULL;
599 #if USE_OBSTACK
600 obstack_init (&table->entry_stack);
601 #endif
602 return table;
603 }
604
605 /* Make all buckets empty, placing any chained entries on the free list.
606 Apply the user-specified function data_freer (if any) to the datas of any
607 affected entries. */
608
609 void
610 hash_clear (Hash_table *table)
611 {
612 struct hash_entry *bucket;
613
614 for (bucket = table->bucket; bucket < table->bucket_limit; bucket++)
615 {
616 if (bucket->data)
617 {
618 struct hash_entry *cursor;
619 struct hash_entry *next;
620
621 /* Free the bucket overflow. */
622 for (cursor = bucket->next; cursor; cursor = next)
623 {
624 if (table->data_freer)
625 (*table->data_freer) (cursor->data);
626 cursor->data = NULL;
627
628 next = cursor->next;
629 /* Relinking is done one entry at a time, as it is to be expected
630 that overflows are either rare or short. */
631 cursor->next = table->free_entry_list;
632 table->free_entry_list = cursor;
633 }
634
635 /* Free the bucket head. */
636 if (table->data_freer)
637 (*table->data_freer) (bucket->data);
638 bucket->data = NULL;
639 bucket->next = NULL;
640 }
641 }
642
643 table->n_buckets_used = 0;
644 table->n_entries = 0;
645 }
646
647 /* Reclaim all storage associated with a hash table. If a data_freer
648 function has been supplied by the user when the hash table was created,
649 this function applies it to the data of each entry before freeing that
650 entry. */
651
652 void
653 hash_free (Hash_table *table)
654 {
655 struct hash_entry *bucket;
656 struct hash_entry *cursor;
657 struct hash_entry *next;
658
659 /* Call the user data_freer function. */
660 if (table->data_freer && table->n_entries)
661 {
662 for (bucket = table->bucket; bucket < table->bucket_limit; bucket++)
663 {
664 if (bucket->data)
665 {
666 for (cursor = bucket; cursor; cursor = cursor->next)
667 {
668 (*table->data_freer) (cursor->data);
669 }
670 }
671 }
672 }
673
674 #if USE_OBSTACK
675
676 obstack_free (&table->entry_stack, NULL);
677
678 #else
679
680 /* Free all bucket overflowed entries. */
681 for (bucket = table->bucket; bucket < table->bucket_limit; bucket++)
682 {
683 for (cursor = bucket->next; cursor; cursor = next)
684 {
685 next = cursor->next;
686 free (cursor);
687 }
688 }
689
690 /* Also reclaim the internal list of previously freed entries. */
691 for (cursor = table->free_entry_list; cursor; cursor = next)
692 {
693 next = cursor->next;
694 free (cursor);
695 }
696
697 #endif
698
699 /* Free the remainder of the hash table structure. */
700 free (table->bucket);
701 free (table);
702 }
703
704 /* Insertion and deletion. */
705
706 /* Get a new hash entry for a bucket overflow, possibly by reclying a
707 previously freed one. If this is not possible, allocate a new one. */
708
709 static struct hash_entry *
710 allocate_entry (Hash_table *table)
711 {
712 struct hash_entry *new;
713
714 if (table->free_entry_list)
715 {
716 new = table->free_entry_list;
717 table->free_entry_list = new->next;
718 }
719 else
720 {
721 #if USE_OBSTACK
722 new = (struct hash_entry *)
723 obstack_alloc (&table->entry_stack, sizeof (struct hash_entry));
724 #else
725 new = (struct hash_entry *) malloc (sizeof (struct hash_entry));
726 #endif
727 }
728
729 return new;
730 }
731
732 /* Free a hash entry which was part of some bucket overflow,
733 saving it for later recycling. */
734
735 static void
736 free_entry (Hash_table *table, struct hash_entry *entry)
737 {
738 entry->data = NULL;
739 entry->next = table->free_entry_list;
740 table->free_entry_list = entry;
741 }
742
743 /* This private function is used to help with insertion and deletion. When
744 ENTRY matches an entry in the table, return a pointer to the corresponding
745 user data and set *BUCKET_HEAD to the head of the selected bucket.
746 Otherwise, return NULL. When DELETE is true and ENTRY matches an entry in
747 the table, unlink the matching entry. */
748
749 static void *
750 hash_find_entry (Hash_table *table, const void *entry,
751 struct hash_entry **bucket_head, bool delete)
752 {
753 struct hash_entry *bucket
754 = table->bucket + table->hasher (entry, table->n_buckets);
755 struct hash_entry *cursor;
756
757 if (! (bucket < table->bucket_limit))
758 abort ();
759
760 *bucket_head = bucket;
761
762 /* Test for empty bucket. */
763 if (bucket->data == NULL)
764 return NULL;
765
766 /* See if the entry is the first in the bucket. */
767 if ((*table->comparator) (entry, bucket->data))
768 {
769 void *data = bucket->data;
770
771 if (delete)
772 {
773 if (bucket->next)
774 {
775 struct hash_entry *next = bucket->next;
776
777 /* Bump the first overflow entry into the bucket head, then save
778 the previous first overflow entry for later recycling. */
779 *bucket = *next;
780 free_entry (table, next);
781 }
782 else
783 {
784 bucket->data = NULL;
785 }
786 }
787
788 return data;
789 }
790
791 /* Scan the bucket overflow. */
792 for (cursor = bucket; cursor->next; cursor = cursor->next)
793 {
794 if ((*table->comparator) (entry, cursor->next->data))
795 {
796 void *data = cursor->next->data;
797
798 if (delete)
799 {
800 struct hash_entry *next = cursor->next;
801
802 /* Unlink the entry to delete, then save the freed entry for later
803 recycling. */
804 cursor->next = next->next;
805 free_entry (table, next);
806 }
807
808 return data;
809 }
810 }
811
812 /* No entry found. */
813 return NULL;
814 }
815
816 /* For an already existing hash table, change the number of buckets through
817 specifying CANDIDATE. The contents of the hash table are preserved. The
818 new number of buckets is automatically selected so as to _guarantee_ that
819 the table may receive at least CANDIDATE different user entries, including
820 those already in the table, before any other growth of the hash table size
821 occurs. If TUNING->IS_N_BUCKETS is true, then CANDIDATE specifies the
822 exact number of buckets desired. */
823
824 bool
825 hash_rehash (Hash_table *table, unsigned candidate)
826 {
827 Hash_table *new_table;
828 struct hash_entry *bucket;
829 struct hash_entry *cursor;
830 struct hash_entry *next;
831
832 new_table = hash_initialize (candidate, table->tuning, table->hasher,
833 table->comparator, table->data_freer);
834 if (new_table == NULL)
835 return false;
836
837 /* Merely reuse the extra old space into the new table. */
838 #if USE_OBSTACK
839 obstack_free (&new_table->entry_stack, NULL);
840 new_table->entry_stack = table->entry_stack;
841 #endif
842 new_table->free_entry_list = table->free_entry_list;
843
844 for (bucket = table->bucket; bucket < table->bucket_limit; bucket++)
845 if (bucket->data)
846 for (cursor = bucket; cursor; cursor = next)
847 {
848 void *data = cursor->data;
849 struct hash_entry *new_bucket
850 = (new_table->bucket
851 + new_table->hasher (data, new_table->n_buckets));
852
853 if (! (new_bucket < new_table->bucket_limit))
854 abort ();
855
856 next = cursor->next;
857
858 if (new_bucket->data)
859 {
860 if (cursor == bucket)
861 {
862 /* Allocate or recycle an entry, when moving from a bucket
863 header into a bucket overflow. */
864 struct hash_entry *new_entry = allocate_entry (new_table);
865
866 if (new_entry == NULL)
867 return false;
868
869 new_entry->data = data;
870 new_entry->next = new_bucket->next;
871 new_bucket->next = new_entry;
872 }
873 else
874 {
875 /* Merely relink an existing entry, when moving from a
876 bucket overflow into a bucket overflow. */
877 cursor->next = new_bucket->next;
878 new_bucket->next = cursor;
879 }
880 }
881 else
882 {
883 /* Free an existing entry, when moving from a bucket
884 overflow into a bucket header. Also take care of the
885 simple case of moving from a bucket header into a bucket
886 header. */
887 new_bucket->data = data;
888 new_table->n_buckets_used++;
889 if (cursor != bucket)
890 free_entry (new_table, cursor);
891 }
892 }
893
894 free (table->bucket);
895 table->bucket = new_table->bucket;
896 table->bucket_limit = new_table->bucket_limit;
897 table->n_buckets = new_table->n_buckets;
898 table->n_buckets_used = new_table->n_buckets_used;
899 table->free_entry_list = new_table->free_entry_list;
900 /* table->n_entries already holds its value. */
901 #if USE_OBSTACK
902 table->entry_stack = new_table->entry_stack;
903 #endif
904 free (new_table);
905
906 return true;
907 }
908
909 /* If ENTRY matches an entry already in the hash table, return the pointer
910 to the entry from the table. Otherwise, insert ENTRY and return ENTRY.
911 Return NULL if the storage required for insertion cannot be allocated. */
912
913 void *
914 hash_insert (Hash_table *table, const void *entry)
915 {
916 void *data;
917 struct hash_entry *bucket;
918
919 /* The caller cannot insert a NULL entry. */
920 if (! entry)
921 abort ();
922
923 /* If there's a matching entry already in the table, return that. */
924 if ((data = hash_find_entry (table, entry, &bucket, false)) != NULL)
925 return data;
926
927 /* ENTRY is not matched, it should be inserted. */
928
929 if (bucket->data)
930 {
931 struct hash_entry *new_entry = allocate_entry (table);
932
933 if (new_entry == NULL)
934 return NULL;
935
936 /* Add ENTRY in the overflow of the bucket. */
937
938 new_entry->data = (void *) entry;
939 new_entry->next = bucket->next;
940 bucket->next = new_entry;
941 table->n_entries++;
942 return (void *) entry;
943 }
944
945 /* Add ENTRY right in the bucket head. */
946
947 bucket->data = (void *) entry;
948 table->n_entries++;
949 table->n_buckets_used++;
950
951 /* If the growth threshold of the buckets in use has been reached, increase
952 the table size and rehash. There's no point in checking the number of
953 entries: if the hashing function is ill-conditioned, rehashing is not
954 likely to improve it. */
955
956 if (table->n_buckets_used
957 > table->tuning->growth_threshold * table->n_buckets)
958 {
959 /* Check more fully, before starting real work. If tuning arguments
960 became invalid, the second check will rely on proper defaults. */
961 check_tuning (table);
962 if (table->n_buckets_used
963 > table->tuning->growth_threshold * table->n_buckets)
964 {
965 const Hash_tuning *tuning = table->tuning;
966 unsigned candidate
967 = (unsigned) (tuning->is_n_buckets
968 ? (table->n_buckets * tuning->growth_factor)
969 : (table->n_buckets * tuning->growth_factor
970 * tuning->growth_threshold));
971
972 /* If the rehash fails, arrange to return NULL. */
973 if (!hash_rehash (table, candidate))
974 entry = NULL;
975 }
976 }
977
978 return (void *) entry;
979 }
980
981 /* If ENTRY is already in the table, remove it and return the just-deleted
982 data (the user may want to deallocate its storage). If ENTRY is not in the
983 table, don't modify the table and return NULL. */
984
985 void *
986 hash_delete (Hash_table *table, const void *entry)
987 {
988 void *data;
989 struct hash_entry *bucket;
990
991 data = hash_find_entry (table, entry, &bucket, true);
992 if (!data)
993 return NULL;
994
995 table->n_entries--;
996 if (!bucket->data)
997 {
998 table->n_buckets_used--;
999
1000 /* If the shrink threshold of the buckets in use has been reached,
1001 rehash into a smaller table. */
1002
1003 if (table->n_buckets_used
1004 < table->tuning->shrink_threshold * table->n_buckets)
1005 {
1006 /* Check more fully, before starting real work. If tuning arguments
1007 became invalid, the second check will rely on proper defaults. */
1008 check_tuning (table);
1009 if (table->n_buckets_used
1010 < table->tuning->shrink_threshold * table->n_buckets)
1011 {
1012 const Hash_tuning *tuning = table->tuning;
1013 unsigned candidate
1014 = (unsigned) (tuning->is_n_buckets
1015 ? table->n_buckets * tuning->shrink_factor
1016 : (table->n_buckets * tuning->shrink_factor
1017 * tuning->growth_threshold));
1018
1019 hash_rehash (table, candidate);
1020 }
1021 }
1022 }
1023
1024 return data;
1025 }
1026
1027 /* Testing. */
1028
1029 #if TESTING
1030
1031 void
1032 hash_print (const Hash_table *table)
1033 {
1034 struct hash_entry *bucket;
1035
1036 for (bucket = table->bucket; bucket < table->bucket_limit; bucket++)
1037 {
1038 struct hash_entry *cursor;
1039
1040 if (bucket)
1041 printf ("%d:\n", bucket - table->bucket);
1042
1043 for (cursor = bucket; cursor; cursor = cursor->next)
1044 {
1045 char *s = (char *) cursor->data;
1046 /* FIXME */
1047 if (s)
1048 printf (" %s\n", s);
1049 }
1050 }
1051 }
1052
1053 #endif /* TESTING */