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1 /*
2 * tclHash.c --
3 *
4 * Implementation of in-memory hash tables for Tcl and Tcl-based
5 * applications.
6 *
7 * Copyright 1991 Regents of the University of California
8 * Permission to use, copy, modify, and distribute this
9 * software and its documentation for any purpose and without
10 * fee is hereby granted, provided that this copyright
11 * notice appears in all copies. The University of California
12 * makes no representations about the suitability of this
13 * software for any purpose. It is provided "as is" without
14 * express or implied warranty.
15 */
16
17 #ifndef lint
18 static char rcsid[] = "$Header: /user6/ouster/tcl/RCS/tclHash.c,v 1.9 92/01/04 15:45:21 ouster Exp $ SPRITE (Berkeley)";
19 #endif /* not lint */
20
21 #include "tclint.h"
22
23 /*
24 * Imported library procedures for which there are no header files:
25 */
26
27 extern void panic();
28
29 /*
30 * When there are this many entries per bucket, on average, rebuild
31 * the hash table to make it larger.
32 */
33
34 #define REBUILD_MULTIPLIER 3
35
36
37 /*
38 * The following macro takes a preliminary integer hash value and
39 * produces an index into a hash tables bucket list. The idea is
40 * to make it so that preliminary values that are arbitrarily similar
41 * will end up in different buckets. The hash function was taken
42 * from a random-number generator.
43 */
44
45 #define RANDOM_INDEX(tablePtr, i) \
46 (((((long) (i))*1103515245) >> (tablePtr)->downShift) & (tablePtr)->mask)
47
48 /*
49 * Procedure prototypes for static procedures in this file:
50 */
51
52 static Tcl_HashEntry * ArrayFind _ANSI_ARGS_((Tcl_HashTable *tablePtr,
53 char *key));
54 static Tcl_HashEntry * ArrayCreate _ANSI_ARGS_((Tcl_HashTable *tablePtr,
55 char *key, int *newPtr));
56 static Tcl_HashEntry * BogusFind _ANSI_ARGS_((Tcl_HashTable *tablePtr,
57 char *key));
58 static Tcl_HashEntry * BogusCreate _ANSI_ARGS_((Tcl_HashTable *tablePtr,
59 char *key, int *newPtr));
60 static int HashString _ANSI_ARGS_((char *string));
61 static void RebuildTable _ANSI_ARGS_((Tcl_HashTable *tablePtr));
62 static Tcl_HashEntry * StringFind _ANSI_ARGS_((Tcl_HashTable *tablePtr,
63 char *key));
64 static Tcl_HashEntry * StringCreate _ANSI_ARGS_((Tcl_HashTable *tablePtr,
65 char *key, int *newPtr));
66 static Tcl_HashEntry * OneWordFind _ANSI_ARGS_((Tcl_HashTable *tablePtr,
67 char *key));
68 static Tcl_HashEntry * OneWordCreate _ANSI_ARGS_((Tcl_HashTable *tablePtr,
69 char *key, int *newPtr));
70 \f
71 /*
72 *----------------------------------------------------------------------
73 *
74 * Tcl_InitHashTable --
75 *
76 * Given storage for a hash table, set up the fields to prepare
77 * the hash table for use.
78 *
79 * Results:
80 * None.
81 *
82 * Side effects:
83 * TablePtr is now ready to be passed to Tcl_FindHashEntry and
84 * Tcl_CreateHashEntry.
85 *
86 *----------------------------------------------------------------------
87 */
88
89 void
90 Tcl_InitHashTable(tablePtr, keyType)
91 register Tcl_HashTable *tablePtr; /* Pointer to table record, which
92 * is supplied by the caller. */
93 int keyType; /* Type of keys to use in table:
94 * TCL_STRING_KEYS, TCL_ONE_WORD_KEYS,
95 * or an integer >= 2. */
96 {
97 tablePtr->buckets = tablePtr->staticBuckets;
98 tablePtr->staticBuckets[0] = tablePtr->staticBuckets[1] = 0;
99 tablePtr->staticBuckets[2] = tablePtr->staticBuckets[3] = 0;
100 tablePtr->numBuckets = TCL_SMALL_HASH_TABLE;
101 tablePtr->numEntries = 0;
102 tablePtr->rebuildSize = TCL_SMALL_HASH_TABLE*REBUILD_MULTIPLIER;
103 tablePtr->downShift = 28;
104 tablePtr->mask = 3;
105 tablePtr->keyType = keyType;
106 if (keyType == TCL_STRING_KEYS) {
107 tablePtr->findProc = StringFind;
108 tablePtr->createProc = StringCreate;
109 } else if (keyType == TCL_ONE_WORD_KEYS) {
110 tablePtr->findProc = OneWordFind;
111 tablePtr->createProc = OneWordCreate;
112 } else {
113 tablePtr->findProc = ArrayFind;
114 tablePtr->createProc = ArrayCreate;
115 };
116 }
117 \f
118 /*
119 *----------------------------------------------------------------------
120 *
121 * Tcl_DeleteHashEntry --
122 *
123 * Remove a single entry from a hash table.
124 *
125 * Results:
126 * None.
127 *
128 * Side effects:
129 * The entry given by entryPtr is deleted from its table and
130 * should never again be used by the caller. It is up to the
131 * caller to free the clientData field of the entry, if that
132 * is relevant.
133 *
134 *----------------------------------------------------------------------
135 */
136
137 void
138 Tcl_DeleteHashEntry(entryPtr)
139 Tcl_HashEntry *entryPtr;
140 {
141 register Tcl_HashEntry *prevPtr;
142
143 if (*entryPtr->bucketPtr == entryPtr) {
144 *entryPtr->bucketPtr = entryPtr->nextPtr;
145 } else {
146 for (prevPtr = *entryPtr->bucketPtr; ; prevPtr = prevPtr->nextPtr) {
147 if (prevPtr == NULL) {
148 panic("malformed bucket chain in Tcl_DeleteHashEntry");
149 }
150 if (prevPtr->nextPtr == entryPtr) {
151 prevPtr->nextPtr = entryPtr->nextPtr;
152 break;
153 }
154 }
155 }
156 entryPtr->tablePtr->numEntries--;
157 ckfree((char *) entryPtr);
158 }
159 \f
160 /*
161 *----------------------------------------------------------------------
162 *
163 * Tcl_DeleteHashTable --
164 *
165 * Free up everything associated with a hash table except for
166 * the record for the table itself.
167 *
168 * Results:
169 * None.
170 *
171 * Side effects:
172 * The hash table is no longer useable.
173 *
174 *----------------------------------------------------------------------
175 */
176
177 void
178 Tcl_DeleteHashTable(tablePtr)
179 register Tcl_HashTable *tablePtr; /* Table to delete. */
180 {
181 register Tcl_HashEntry *hPtr, *nextPtr;
182 int i;
183
184 /*
185 * Free up all the entries in the table.
186 */
187
188 for (i = 0; i < tablePtr->numBuckets; i++) {
189 hPtr = tablePtr->buckets[i];
190 while (hPtr != NULL) {
191 nextPtr = hPtr->nextPtr;
192 ckfree((char *) hPtr);
193 hPtr = nextPtr;
194 }
195 }
196
197 /*
198 * Free up the bucket array, if it was dynamically allocated.
199 */
200
201 if (tablePtr->buckets != tablePtr->staticBuckets) {
202 ckfree((char *) tablePtr->buckets);
203 }
204
205 /*
206 * Arrange for panics if the table is used again without
207 * re-initialization.
208 */
209
210 tablePtr->findProc = BogusFind;
211 tablePtr->createProc = BogusCreate;
212 }
213 \f
214 /*
215 *----------------------------------------------------------------------
216 *
217 * Tcl_FirstHashEntry --
218 *
219 * Locate the first entry in a hash table and set up a record
220 * that can be used to step through all the remaining entries
221 * of the table.
222 *
223 * Results:
224 * The return value is a pointer to the first entry in tablePtr,
225 * or NULL if tablePtr has no entries in it. The memory at
226 * *searchPtr is initialized so that subsequent calls to
227 * Tcl_NextHashEntry will return all of the entries in the table,
228 * one at a time.
229 *
230 * Side effects:
231 * None.
232 *
233 *----------------------------------------------------------------------
234 */
235
236 Tcl_HashEntry *
237 Tcl_FirstHashEntry(tablePtr, searchPtr)
238 Tcl_HashTable *tablePtr; /* Table to search. */
239 Tcl_HashSearch *searchPtr; /* Place to store information about
240 * progress through the table. */
241 {
242 searchPtr->tablePtr = tablePtr;
243 searchPtr->nextIndex = 0;
244 searchPtr->nextEntryPtr = NULL;
245 return Tcl_NextHashEntry(searchPtr);
246 }
247 \f
248 /*
249 *----------------------------------------------------------------------
250 *
251 * Tcl_NextHashEntry --
252 *
253 * Once a hash table enumeration has been initiated by calling
254 * Tcl_FirstHashEntry, this procedure may be called to return
255 * successive elements of the table.
256 *
257 * Results:
258 * The return value is the next entry in the hash table being
259 * enumerated, or NULL if the end of the table is reached.
260 *
261 * Side effects:
262 * None.
263 *
264 *----------------------------------------------------------------------
265 */
266
267 Tcl_HashEntry *
268 Tcl_NextHashEntry(searchPtr)
269 register Tcl_HashSearch *searchPtr; /* Place to store information about
270 * progress through the table. Must
271 * have been initialized by calling
272 * Tcl_FirstHashEntry. */
273 {
274 Tcl_HashEntry *hPtr;
275
276 while (searchPtr->nextEntryPtr == NULL) {
277 if (searchPtr->nextIndex >= searchPtr->tablePtr->numBuckets) {
278 return NULL;
279 }
280 searchPtr->nextEntryPtr =
281 searchPtr->tablePtr->buckets[searchPtr->nextIndex];
282 searchPtr->nextIndex++;
283 }
284 hPtr = searchPtr->nextEntryPtr;
285 searchPtr->nextEntryPtr = hPtr->nextPtr;
286 return hPtr;
287 }
288 \f
289 /*
290 *----------------------------------------------------------------------
291 *
292 * Tcl_HashStats --
293 *
294 * Return statistics describing the layout of the hash table
295 * in its hash buckets.
296 *
297 * Results:
298 * The return value is a malloc-ed string containing information
299 * about tablePtr. It is the caller's responsibility to free
300 * this string.
301 *
302 * Side effects:
303 * None.
304 *
305 *----------------------------------------------------------------------
306 */
307
308 char *
309 Tcl_HashStats(tablePtr)
310 Tcl_HashTable *tablePtr; /* Table for which to produce stats. */
311 {
312 #define NUM_COUNTERS 10
313 int count[NUM_COUNTERS], overflow, i, j;
314 double average, tmp;
315 register Tcl_HashEntry *hPtr;
316 char *result, *p;
317
318 /*
319 * Compute a histogram of bucket usage.
320 */
321
322 for (i = 0; i < NUM_COUNTERS; i++) {
323 count[i] = 0;
324 }
325 overflow = 0;
326 average = 0.0;
327 for (i = 0; i < tablePtr->numBuckets; i++) {
328 j = 0;
329 for (hPtr = tablePtr->buckets[i]; hPtr != NULL; hPtr = hPtr->nextPtr) {
330 j++;
331 }
332 if (j < NUM_COUNTERS) {
333 count[j]++;
334 } else {
335 overflow++;
336 }
337 tmp = j;
338 average += (tmp+1.0)*(tmp/tablePtr->numEntries)/2.0;
339 }
340
341 /*
342 * Print out the histogram and a few other pieces of information.
343 */
344
345 result = (char *) ckalloc((unsigned) ((NUM_COUNTERS*60) + 300));
346 sprintf(result, "%d entries in table, %d buckets\n",
347 tablePtr->numEntries, tablePtr->numBuckets);
348 p = result + strlen(result);
349 for (i = 0; i < NUM_COUNTERS; i++) {
350 sprintf(p, "number of buckets with %d entries: %d\n",
351 i, count[i]);
352 p += strlen(p);
353 }
354 sprintf(p, "number of buckets with more %d or more entries: %d\n",
355 NUM_COUNTERS, overflow);
356 p += strlen(p);
357 sprintf(p, "average search distance for entry: %.1f", average);
358 return result;
359 }
360 \f
361 /*
362 *----------------------------------------------------------------------
363 *
364 * HashString --
365 *
366 * Compute a one-word summary of a text string, which can be
367 * used to generate a hash index.
368 *
369 * Results:
370 * The return value is a one-word summary of the information in
371 * string.
372 *
373 * Side effects:
374 * None.
375 *
376 *----------------------------------------------------------------------
377 */
378
379 static int
380 HashString(string)
381 register char *string; /* String from which to compute hash value. */
382 {
383 register int result, c;
384
385 /*
386 * I tried a zillion different hash functions and asked many other
387 * people for advice. Many people had their own favorite functions,
388 * all different, but no-one had much idea why they were good ones.
389 * I chose the one below (multiply by 9 and add new character)
390 * because of the following reasons:
391 *
392 * 1. Multiplying by 10 is perfect for keys that are decimal strings,
393 * and multiplying by 9 is just about as good.
394 * 2. Times-9 is (shift-left-3) plus (old). This means that each
395 * character's bits hang around in the low-order bits of the
396 * hash value for ever, plus they spread fairly rapidly up to
397 * the high-order bits to fill out the hash value. This seems
398 * works well both for decimal and non-decimal strings.
399 */
400
401 result = 0;
402 while (1) {
403 c = *string;
404 string++;
405 if (c == 0) {
406 break;
407 }
408 result += (result<<3) + c;
409 }
410 return result;
411 }
412 \f
413 /*
414 *----------------------------------------------------------------------
415 *
416 * StringFind --
417 *
418 * Given a hash table with string keys, and a string key, find
419 * the entry with a matching key.
420 *
421 * Results:
422 * The return value is a token for the matching entry in the
423 * hash table, or NULL if there was no matching entry.
424 *
425 * Side effects:
426 * None.
427 *
428 *----------------------------------------------------------------------
429 */
430
431 static Tcl_HashEntry *
432 StringFind(tablePtr, key)
433 Tcl_HashTable *tablePtr; /* Table in which to lookup entry. */
434 char *key; /* Key to use to find matching entry. */
435 {
436 register Tcl_HashEntry *hPtr;
437 register char *p1, *p2;
438 int index;
439
440 index = HashString(key) & tablePtr->mask;
441
442 /*
443 * Search all of the entries in the appropriate bucket.
444 */
445
446 for (hPtr = tablePtr->buckets[index]; hPtr != NULL;
447 hPtr = hPtr->nextPtr) {
448 for (p1 = key, p2 = hPtr->key.string; ; p1++, p2++) {
449 if (*p1 != *p2) {
450 break;
451 }
452 if (*p1 == '\0') {
453 return hPtr;
454 }
455 }
456 }
457 return NULL;
458 }
459 \f
460 /*
461 *----------------------------------------------------------------------
462 *
463 * StringCreate --
464 *
465 * Given a hash table with string keys, and a string key, find
466 * the entry with a matching key. If there is no matching entry,
467 * then create a new entry that does match.
468 *
469 * Results:
470 * The return value is a pointer to the matching entry. If this
471 * is a newly-created entry, then *newPtr will be set to a non-zero
472 * value; otherwise *newPtr will be set to 0. If this is a new
473 * entry the value stored in the entry will initially be 0.
474 *
475 * Side effects:
476 * A new entry may be added to the hash table.
477 *
478 *----------------------------------------------------------------------
479 */
480
481 static Tcl_HashEntry *
482 StringCreate(tablePtr, key, newPtr)
483 Tcl_HashTable *tablePtr; /* Table in which to lookup entry. */
484 char *key; /* Key to use to find or create matching
485 * entry. */
486 int *newPtr; /* Store info here telling whether a new
487 * entry was created. */
488 {
489 register Tcl_HashEntry *hPtr;
490 register char *p1, *p2;
491 int index;
492
493 index = HashString(key) & tablePtr->mask;
494
495 /*
496 * Search all of the entries in this bucket.
497 */
498
499 for (hPtr = tablePtr->buckets[index]; hPtr != NULL;
500 hPtr = hPtr->nextPtr) {
501 for (p1 = key, p2 = hPtr->key.string; ; p1++, p2++) {
502 if (*p1 != *p2) {
503 break;
504 }
505 if (*p1 == '\0') {
506 *newPtr = 0;
507 return hPtr;
508 }
509 }
510 }
511
512 /*
513 * Entry not found. Add a new one to the bucket.
514 */
515
516 *newPtr = 1;
517 hPtr = (Tcl_HashEntry *) ckalloc((unsigned)
518 (sizeof(Tcl_HashEntry) + strlen(key) - (sizeof(hPtr->key) -1)));
519 hPtr->tablePtr = tablePtr;
520 hPtr->bucketPtr = &(tablePtr->buckets[index]);
521 hPtr->nextPtr = *hPtr->bucketPtr;
522 hPtr->clientData = 0;
523 strcpy(hPtr->key.string, key);
524 *hPtr->bucketPtr = hPtr;
525 tablePtr->numEntries++;
526
527 /*
528 * If the table has exceeded a decent size, rebuild it with many
529 * more buckets.
530 */
531
532 if (tablePtr->numEntries >= tablePtr->rebuildSize) {
533 RebuildTable(tablePtr);
534 }
535 return hPtr;
536 }
537 \f
538 /*
539 *----------------------------------------------------------------------
540 *
541 * OneWordFind --
542 *
543 * Given a hash table with one-word keys, and a one-word key, find
544 * the entry with a matching key.
545 *
546 * Results:
547 * The return value is a token for the matching entry in the
548 * hash table, or NULL if there was no matching entry.
549 *
550 * Side effects:
551 * None.
552 *
553 *----------------------------------------------------------------------
554 */
555
556 static Tcl_HashEntry *
557 OneWordFind(tablePtr, key)
558 Tcl_HashTable *tablePtr; /* Table in which to lookup entry. */
559 register char *key; /* Key to use to find matching entry. */
560 {
561 register Tcl_HashEntry *hPtr;
562 int index;
563
564 index = RANDOM_INDEX(tablePtr, key);
565
566 /*
567 * Search all of the entries in the appropriate bucket.
568 */
569
570 for (hPtr = tablePtr->buckets[index]; hPtr != NULL;
571 hPtr = hPtr->nextPtr) {
572 if (hPtr->key.oneWordValue == key) {
573 return hPtr;
574 }
575 }
576 return NULL;
577 }
578 \f
579 /*
580 *----------------------------------------------------------------------
581 *
582 * OneWordCreate --
583 *
584 * Given a hash table with one-word keys, and a one-word key, find
585 * the entry with a matching key. If there is no matching entry,
586 * then create a new entry that does match.
587 *
588 * Results:
589 * The return value is a pointer to the matching entry. If this
590 * is a newly-created entry, then *newPtr will be set to a non-zero
591 * value; otherwise *newPtr will be set to 0. If this is a new
592 * entry the value stored in the entry will initially be 0.
593 *
594 * Side effects:
595 * A new entry may be added to the hash table.
596 *
597 *----------------------------------------------------------------------
598 */
599
600 static Tcl_HashEntry *
601 OneWordCreate(tablePtr, key, newPtr)
602 Tcl_HashTable *tablePtr; /* Table in which to lookup entry. */
603 register char *key; /* Key to use to find or create matching
604 * entry. */
605 int *newPtr; /* Store info here telling whether a new
606 * entry was created. */
607 {
608 register Tcl_HashEntry *hPtr;
609 int index;
610
611 index = RANDOM_INDEX(tablePtr, key);
612
613 /*
614 * Search all of the entries in this bucket.
615 */
616
617 for (hPtr = tablePtr->buckets[index]; hPtr != NULL;
618 hPtr = hPtr->nextPtr) {
619 if (hPtr->key.oneWordValue == key) {
620 *newPtr = 0;
621 return hPtr;
622 }
623 }
624
625 /*
626 * Entry not found. Add a new one to the bucket.
627 */
628
629 *newPtr = 1;
630 hPtr = (Tcl_HashEntry *) ckalloc(sizeof(Tcl_HashEntry));
631 hPtr->tablePtr = tablePtr;
632 hPtr->bucketPtr = &(tablePtr->buckets[index]);
633 hPtr->nextPtr = *hPtr->bucketPtr;
634 hPtr->clientData = 0;
635 hPtr->key.oneWordValue = key;
636 *hPtr->bucketPtr = hPtr;
637 tablePtr->numEntries++;
638
639 /*
640 * If the table has exceeded a decent size, rebuild it with many
641 * more buckets.
642 */
643
644 if (tablePtr->numEntries >= tablePtr->rebuildSize) {
645 RebuildTable(tablePtr);
646 }
647 return hPtr;
648 }
649 \f
650 /*
651 *----------------------------------------------------------------------
652 *
653 * ArrayFind --
654 *
655 * Given a hash table with array-of-int keys, and a key, find
656 * the entry with a matching key.
657 *
658 * Results:
659 * The return value is a token for the matching entry in the
660 * hash table, or NULL if there was no matching entry.
661 *
662 * Side effects:
663 * None.
664 *
665 *----------------------------------------------------------------------
666 */
667
668 static Tcl_HashEntry *
669 ArrayFind(tablePtr, key)
670 Tcl_HashTable *tablePtr; /* Table in which to lookup entry. */
671 char *key; /* Key to use to find matching entry. */
672 {
673 register Tcl_HashEntry *hPtr;
674 int *arrayPtr = (int *) key;
675 register int *iPtr1, *iPtr2;
676 int index, count;
677
678 for (index = 0, count = tablePtr->keyType, iPtr1 = arrayPtr;
679 count > 0; count--, iPtr1++) {
680 index += *iPtr1;
681 }
682 index = RANDOM_INDEX(tablePtr, index);
683
684 /*
685 * Search all of the entries in the appropriate bucket.
686 */
687
688 for (hPtr = tablePtr->buckets[index]; hPtr != NULL;
689 hPtr = hPtr->nextPtr) {
690 for (iPtr1 = arrayPtr, iPtr2 = hPtr->key.words,
691 count = tablePtr->keyType; ; count--, iPtr1++, iPtr2++) {
692 if (count == 0) {
693 return hPtr;
694 }
695 if (*iPtr1 != *iPtr2) {
696 break;
697 }
698 }
699 }
700 return NULL;
701 }
702 \f
703 /*
704 *----------------------------------------------------------------------
705 *
706 * ArrayCreate --
707 *
708 * Given a hash table with one-word keys, and a one-word key, find
709 * the entry with a matching key. If there is no matching entry,
710 * then create a new entry that does match.
711 *
712 * Results:
713 * The return value is a pointer to the matching entry. If this
714 * is a newly-created entry, then *newPtr will be set to a non-zero
715 * value; otherwise *newPtr will be set to 0. If this is a new
716 * entry the value stored in the entry will initially be 0.
717 *
718 * Side effects:
719 * A new entry may be added to the hash table.
720 *
721 *----------------------------------------------------------------------
722 */
723
724 static Tcl_HashEntry *
725 ArrayCreate(tablePtr, key, newPtr)
726 Tcl_HashTable *tablePtr; /* Table in which to lookup entry. */
727 register char *key; /* Key to use to find or create matching
728 * entry. */
729 int *newPtr; /* Store info here telling whether a new
730 * entry was created. */
731 {
732 register Tcl_HashEntry *hPtr;
733 int *arrayPtr = (int *) key;
734 register int *iPtr1, *iPtr2;
735 int index, count;
736
737 for (index = 0, count = tablePtr->keyType, iPtr1 = arrayPtr;
738 count > 0; count--, iPtr1++) {
739 index += *iPtr1;
740 }
741 index = RANDOM_INDEX(tablePtr, index);
742
743 /*
744 * Search all of the entries in the appropriate bucket.
745 */
746
747 for (hPtr = tablePtr->buckets[index]; hPtr != NULL;
748 hPtr = hPtr->nextPtr) {
749 for (iPtr1 = arrayPtr, iPtr2 = hPtr->key.words,
750 count = tablePtr->keyType; ; count--, iPtr1++, iPtr2++) {
751 if (count == 0) {
752 *newPtr = 0;
753 return hPtr;
754 }
755 if (*iPtr1 != *iPtr2) {
756 break;
757 }
758 }
759 }
760
761 /*
762 * Entry not found. Add a new one to the bucket.
763 */
764
765 *newPtr = 1;
766 hPtr = (Tcl_HashEntry *) ckalloc((unsigned) (sizeof(Tcl_HashEntry)
767 + (tablePtr->keyType*sizeof(int)) - 4));
768 hPtr->tablePtr = tablePtr;
769 hPtr->bucketPtr = &(tablePtr->buckets[index]);
770 hPtr->nextPtr = *hPtr->bucketPtr;
771 hPtr->clientData = 0;
772 for (iPtr1 = arrayPtr, iPtr2 = hPtr->key.words, count = tablePtr->keyType;
773 count > 0; count--, iPtr1++, iPtr2++) {
774 *iPtr2 = *iPtr1;
775 }
776 *hPtr->bucketPtr = hPtr;
777 tablePtr->numEntries++;
778
779 /*
780 * If the table has exceeded a decent size, rebuild it with many
781 * more buckets.
782 */
783
784 if (tablePtr->numEntries >= tablePtr->rebuildSize) {
785 RebuildTable(tablePtr);
786 }
787 return hPtr;
788 }
789 \f
790 /*
791 *----------------------------------------------------------------------
792 *
793 * BogusFind --
794 *
795 * This procedure is invoked when an Tcl_FindHashEntry is called
796 * on a table that has been deleted.
797 *
798 * Results:
799 * If panic returns (which it shouldn't) this procedure returns
800 * NULL.
801 *
802 * Side effects:
803 * Generates a panic.
804 *
805 *----------------------------------------------------------------------
806 */
807
808 /* ARGSUSED */
809 static Tcl_HashEntry *
810 BogusFind(tablePtr, key)
811 Tcl_HashTable *tablePtr; /* Table in which to lookup entry. */
812 char *key; /* Key to use to find matching entry. */
813 {
814 panic("called Tcl_FindHashEntry on deleted table");
815 return NULL;
816 }
817 \f
818 /*
819 *----------------------------------------------------------------------
820 *
821 * BogusCreate --
822 *
823 * This procedure is invoked when an Tcl_CreateHashEntry is called
824 * on a table that has been deleted.
825 *
826 * Results:
827 * If panic returns (which it shouldn't) this procedure returns
828 * NULL.
829 *
830 * Side effects:
831 * Generates a panic.
832 *
833 *----------------------------------------------------------------------
834 */
835
836 /* ARGSUSED */
837 static Tcl_HashEntry *
838 BogusCreate(tablePtr, key, newPtr)
839 Tcl_HashTable *tablePtr; /* Table in which to lookup entry. */
840 char *key; /* Key to use to find or create matching
841 * entry. */
842 int *newPtr; /* Store info here telling whether a new
843 * entry was created. */
844 {
845 panic("called Tcl_CreateHashEntry on deleted table");
846 return NULL;
847 }
848 \f
849 /*
850 *----------------------------------------------------------------------
851 *
852 * RebuildTable --
853 *
854 * This procedure is invoked when the ratio of entries to hash
855 * buckets becomes too large. It creates a new table with a
856 * larger bucket array and moves all of the entries into the
857 * new table.
858 *
859 * Results:
860 * None.
861 *
862 * Side effects:
863 * Memory gets reallocated and entries get re-hashed to new
864 * buckets.
865 *
866 *----------------------------------------------------------------------
867 */
868
869 static void
870 RebuildTable(tablePtr)
871 register Tcl_HashTable *tablePtr; /* Table to enlarge. */
872 {
873 int oldSize, count, index;
874 Tcl_HashEntry **oldBuckets;
875 register Tcl_HashEntry **oldChainPtr, **newChainPtr;
876 register Tcl_HashEntry *hPtr;
877
878 oldSize = tablePtr->numBuckets;
879 oldBuckets = tablePtr->buckets;
880
881 /*
882 * Allocate and initialize the new bucket array, and set up
883 * hashing constants for new array size.
884 */
885
886 tablePtr->numBuckets *= 4;
887 tablePtr->buckets = (Tcl_HashEntry **) ckalloc((unsigned)
888 (tablePtr->numBuckets * sizeof(Tcl_HashEntry *)));
889 for (count = tablePtr->numBuckets, newChainPtr = tablePtr->buckets;
890 count > 0; count--, newChainPtr++) {
891 *newChainPtr = NULL;
892 }
893 tablePtr->rebuildSize *= 4;
894 tablePtr->downShift -= 2;
895 tablePtr->mask = (tablePtr->mask << 2) + 3;
896
897 /*
898 * Rehash all of the existing entries into the new bucket array.
899 */
900
901 for (oldChainPtr = oldBuckets; oldSize > 0; oldSize--, oldChainPtr++) {
902 for (hPtr = *oldChainPtr; hPtr != NULL; hPtr = *oldChainPtr) {
903 *oldChainPtr = hPtr->nextPtr;
904 if (tablePtr->keyType == TCL_STRING_KEYS) {
905 index = HashString(hPtr->key.string) & tablePtr->mask;
906 } else if (tablePtr->keyType == TCL_ONE_WORD_KEYS) {
907 index = RANDOM_INDEX(tablePtr, hPtr->key.oneWordValue);
908 } else {
909 register int *iPtr;
910 int count;
911
912 for (index = 0, count = tablePtr->keyType,
913 iPtr = hPtr->key.words; count > 0; count--, iPtr++) {
914 index += *iPtr;
915 }
916 index = RANDOM_INDEX(tablePtr, index);
917 }
918 hPtr->bucketPtr = &(tablePtr->buckets[index]);
919 hPtr->nextPtr = *hPtr->bucketPtr;
920 *hPtr->bucketPtr = hPtr;
921 }
922 }
923
924 /*
925 * Free up the old bucket array, if it was dynamically allocated.
926 */
927
928 if (oldBuckets != tablePtr->staticBuckets) {
929 ckfree((char *) oldBuckets);
930 }
931 }
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