1
2 /*--------------------------------------------------------------------*/
3 /*--- An AVL tree based finite map for word keys and word values. ---*/
4 /*--- Inspired by Haskell's "FiniteMap" library. ---*/
5 /*--- m_wordfm.c ---*/
6 /*--------------------------------------------------------------------*/
7
8 /*
9 This file is part of Valgrind, a dynamic binary instrumentation
10 framework.
11
12 Copyright (C) 2007-2015 Julian Seward
13 jseward@acm.org
14
15 This code is based on previous work by Nicholas Nethercote
16 (coregrind/m_oset.c) which is
17
18 Copyright (C) 2005-2015 Nicholas Nethercote
19 njn@valgrind.org
20
21 which in turn was derived partially from:
22
23 AVL C library
24 Copyright (C) 2000,2002 Daniel Nagy
25
26 This program is free software; you can redistribute it and/or
27 modify it under the terms of the GNU General Public License as
28 published by the Free Software Foundation; either version 2 of
29 the License, or (at your option) any later version.
30 [...]
31
32 (taken from libavl-0.4/debian/copyright)
33
34 This program is free software; you can redistribute it and/or
35 modify it under the terms of the GNU General Public License as
36 published by the Free Software Foundation; either version 2 of the
37 License, or (at your option) any later version.
38
39 This program is distributed in the hope that it will be useful, but
40 WITHOUT ANY WARRANTY; without even the implied warranty of
41 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
42 General Public License for more details.
43
44 You should have received a copy of the GNU General Public License
45 along with this program; if not, write to the Free Software
46 Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA
47 02111-1307, USA.
48
49 The GNU General Public License is contained in the file COPYING.
50 */
51
52 #include "pub_core_basics.h"
53 #include "pub_core_libcassert.h"
54 #include "pub_core_libcbase.h"
55 #include "pub_core_wordfm.h" /* self */
56
57
58 //------------------------------------------------------------------//
59 //--- WordFM ---//
60 //--- Implementation ---//
61 //------------------------------------------------------------------//
62
63 /* One element of the AVL tree */
64 typedef
65 struct _AvlNode {
66 UWord key;
67 UWord val;
68 struct _AvlNode* child[2]; /* [0] is left subtree, [1] is right */
69 Char balance; /* do not make this unsigned */
70 }
71 AvlNode;
72
73 typedef
74 struct {
75 UWord w;
76 Bool b;
77 }
78 MaybeWord;
79
80 #define WFM_STKMAX 32 // At most 2**32 entries can be iterated over
81
82 struct _WordFM {
83 AvlNode* root;
84 void* (*alloc_nofail)( const HChar*, SizeT );
85 const HChar* cc;
86 void (*dealloc)(void*);
87 Word (*kCmp)(UWord,UWord);
88 AvlNode* nodeStack[WFM_STKMAX]; // Iterator node stack
89 Int numStack[WFM_STKMAX]; // Iterator num stack
90 Int stackTop; // Iterator stack pointer, one past end
91 };
92
93 /* forward */
94 static Bool avl_removeroot_wrk(AvlNode** t, Word(*kCmp)(UWord,UWord));
95
96 /* Swing to the left. Warning: no balance maintainance. */
avl_swl(AvlNode ** root)97 static void avl_swl ( AvlNode** root )
98 {
99 AvlNode* a = *root;
100 AvlNode* b = a->child[1];
101 *root = b;
102 a->child[1] = b->child[0];
103 b->child[0] = a;
104 }
105
106 /* Swing to the right. Warning: no balance maintainance. */
avl_swr(AvlNode ** root)107 static void avl_swr ( AvlNode** root )
108 {
109 AvlNode* a = *root;
110 AvlNode* b = a->child[0];
111 *root = b;
112 a->child[0] = b->child[1];
113 b->child[1] = a;
114 }
115
116 /* Balance maintainance after especially nasty swings. */
avl_nasty(AvlNode * root)117 static void avl_nasty ( AvlNode* root )
118 {
119 switch (root->balance) {
120 case -1:
121 root->child[0]->balance = 0;
122 root->child[1]->balance = 1;
123 break;
124 case 1:
125 root->child[0]->balance = -1;
126 root->child[1]->balance = 0;
127 break;
128 case 0:
129 root->child[0]->balance = 0;
130 root->child[1]->balance = 0;
131 break;
132 default:
133 vg_assert(0);
134 }
135 root->balance=0;
136 }
137
138 /* Find size of a non-NULL tree. */
size_avl_nonNull(const AvlNode * nd)139 static UWord size_avl_nonNull ( const AvlNode* nd )
140 {
141 return 1 + (nd->child[0] ? size_avl_nonNull(nd->child[0]) : 0)
142 + (nd->child[1] ? size_avl_nonNull(nd->child[1]) : 0);
143 }
144
145 /* Unsignedly compare w1 and w2. If w1 < w2, produce a negative
146 number; if w1 > w2 produce a positive number, and if w1 == w2
147 produce zero. */
cmp_unsigned_Words(UWord w1,UWord w2)148 static inline Word cmp_unsigned_Words ( UWord w1, UWord w2 ) {
149 if (w1 < w2) return -1;
150 if (w1 > w2) return 1;
151 return 0;
152 }
153
154 /* Insert element a into the AVL tree t. Returns True if the depth of
155 the tree has grown. If element with that key is already present,
156 just copy a->val to existing node, first returning old ->val field
157 of existing node in *oldV, so that the caller can finalize it
158 however it wants.
159 */
160 static
avl_insert_wrk(AvlNode ** rootp,MaybeWord * oldV,AvlNode * a,Word (* kCmp)(UWord,UWord))161 Bool avl_insert_wrk ( AvlNode** rootp,
162 /*OUT*/MaybeWord* oldV,
163 AvlNode* a,
164 Word (*kCmp)(UWord,UWord) )
165 {
166 Word cmpres;
167
168 /* initialize */
169 a->child[0] = 0;
170 a->child[1] = 0;
171 a->balance = 0;
172 oldV->b = False;
173
174 /* insert into an empty tree? */
175 if (!(*rootp)) {
176 (*rootp) = a;
177 return True;
178 }
179
180 cmpres = kCmp ? /*boxed*/ kCmp( (*rootp)->key, a->key )
181 : /*unboxed*/ cmp_unsigned_Words( (UWord)(*rootp)->key,
182 (UWord)a->key );
183
184 if (cmpres > 0) {
185 /* insert into the left subtree */
186 if ((*rootp)->child[0]) {
187 AvlNode* left_subtree = (*rootp)->child[0];
188 if (avl_insert_wrk(&left_subtree, oldV, a, kCmp)) {
189 switch ((*rootp)->balance--) {
190 case 1: return False;
191 case 0: return True;
192 case -1: break;
193 default: vg_assert(0);
194 }
195 if ((*rootp)->child[0]->balance < 0) {
196 avl_swr( rootp );
197 (*rootp)->balance = 0;
198 (*rootp)->child[1]->balance = 0;
199 } else {
200 avl_swl( &((*rootp)->child[0]) );
201 avl_swr( rootp );
202 avl_nasty( *rootp );
203 }
204 } else {
205 (*rootp)->child[0] = left_subtree;
206 }
207 return False;
208 } else {
209 (*rootp)->child[0] = a;
210 if ((*rootp)->balance--)
211 return False;
212 return True;
213 }
214 vg_assert(0);/*NOTREACHED*/
215 }
216 else
217 if (cmpres < 0) {
218 /* insert into the right subtree */
219 if ((*rootp)->child[1]) {
220 AvlNode* right_subtree = (*rootp)->child[1];
221 if (avl_insert_wrk(&right_subtree, oldV, a, kCmp)) {
222 switch((*rootp)->balance++){
223 case -1: return False;
224 case 0: return True;
225 case 1: break;
226 default: vg_assert(0);
227 }
228 if ((*rootp)->child[1]->balance > 0) {
229 avl_swl( rootp );
230 (*rootp)->balance = 0;
231 (*rootp)->child[0]->balance = 0;
232 } else {
233 avl_swr( &((*rootp)->child[1]) );
234 avl_swl( rootp );
235 avl_nasty( *rootp );
236 }
237 } else {
238 (*rootp)->child[1] = right_subtree;
239 }
240 return False;
241 } else {
242 (*rootp)->child[1] = a;
243 if ((*rootp)->balance++)
244 return False;
245 return True;
246 }
247 vg_assert(0);/*NOTREACHED*/
248 }
249 else {
250 /* cmpres == 0, a duplicate - replace the val, but don't
251 incorporate the node in the tree */
252 oldV->b = True;
253 oldV->w = (*rootp)->val;
254 (*rootp)->val = a->val;
255 return False;
256 }
257 }
258
259 /* Remove an element a from the AVL tree t. a must be part of
260 the tree. Returns True if the depth of the tree has shrunk.
261 */
262 static
avl_remove_wrk(AvlNode ** rootp,AvlNode * a,Word (* kCmp)(UWord,UWord))263 Bool avl_remove_wrk ( AvlNode** rootp,
264 AvlNode* a,
265 Word(*kCmp)(UWord,UWord) )
266 {
267 Bool ch;
268 Word cmpres;
269 cmpres = kCmp ? /*boxed*/ kCmp( (*rootp)->key, a->key )
270 : /*unboxed*/ cmp_unsigned_Words( (UWord)(*rootp)->key,
271 (UWord)a->key );
272
273 if (cmpres > 0){
274 /* remove from the left subtree */
275 AvlNode* left_subtree = (*rootp)->child[0];
276 vg_assert(left_subtree);
277 ch = avl_remove_wrk(&left_subtree, a, kCmp);
278 (*rootp)->child[0]=left_subtree;
279 if (ch) {
280 switch ((*rootp)->balance++) {
281 case -1: return True;
282 case 0: return False;
283 case 1: break;
284 default: vg_assert(0);
285 }
286 switch ((*rootp)->child[1]->balance) {
287 case 0:
288 avl_swl( rootp );
289 (*rootp)->balance = -1;
290 (*rootp)->child[0]->balance = 1;
291 return False;
292 case 1:
293 avl_swl( rootp );
294 (*rootp)->balance = 0;
295 (*rootp)->child[0]->balance = 0;
296 return True;
297 case -1:
298 break;
299 default:
300 vg_assert(0);
301 }
302 avl_swr( &((*rootp)->child[1]) );
303 avl_swl( rootp );
304 avl_nasty( *rootp );
305 return True;
306 }
307 }
308 else
309 if (cmpres < 0) {
310 /* remove from the right subtree */
311 AvlNode* right_subtree = (*rootp)->child[1];
312 vg_assert(right_subtree);
313 ch = avl_remove_wrk(&right_subtree, a, kCmp);
314 (*rootp)->child[1] = right_subtree;
315 if (ch) {
316 switch ((*rootp)->balance--) {
317 case 1: return True;
318 case 0: return False;
319 case -1: break;
320 default: vg_assert(0);
321 }
322 switch ((*rootp)->child[0]->balance) {
323 case 0:
324 avl_swr( rootp );
325 (*rootp)->balance = 1;
326 (*rootp)->child[1]->balance = -1;
327 return False;
328 case -1:
329 avl_swr( rootp );
330 (*rootp)->balance = 0;
331 (*rootp)->child[1]->balance = 0;
332 return True;
333 case 1:
334 break;
335 default:
336 vg_assert(0);
337 }
338 avl_swl( &((*rootp)->child[0]) );
339 avl_swr( rootp );
340 avl_nasty( *rootp );
341 return True;
342 }
343 }
344 else {
345 vg_assert(cmpres == 0);
346 vg_assert((*rootp)==a);
347 return avl_removeroot_wrk(rootp, kCmp);
348 }
349 return 0;
350 }
351
352 /* Remove the root of the AVL tree *rootp.
353 * Warning: dumps core if *rootp is empty
354 */
355 static
avl_removeroot_wrk(AvlNode ** rootp,Word (* kCmp)(UWord,UWord))356 Bool avl_removeroot_wrk ( AvlNode** rootp,
357 Word(*kCmp)(UWord,UWord) )
358 {
359 Bool ch;
360 AvlNode* a;
361 if (!(*rootp)->child[0]) {
362 if (!(*rootp)->child[1]) {
363 (*rootp) = 0;
364 return True;
365 }
366 (*rootp) = (*rootp)->child[1];
367 return True;
368 }
369 if (!(*rootp)->child[1]) {
370 (*rootp) = (*rootp)->child[0];
371 return True;
372 }
373 if ((*rootp)->balance < 0) {
374 /* remove from the left subtree */
375 a = (*rootp)->child[0];
376 while (a->child[1]) a = a->child[1];
377 } else {
378 /* remove from the right subtree */
379 a = (*rootp)->child[1];
380 while (a->child[0]) a = a->child[0];
381 }
382 ch = avl_remove_wrk(rootp, a, kCmp);
383 a->child[0] = (*rootp)->child[0];
384 a->child[1] = (*rootp)->child[1];
385 a->balance = (*rootp)->balance;
386 (*rootp) = a;
387 if(a->balance == 0) return ch;
388 return False;
389 }
390
391 static
avl_find_node(AvlNode * t,Word k,Word (* kCmp)(UWord,UWord))392 AvlNode* avl_find_node ( AvlNode* t, Word k, Word(*kCmp)(UWord,UWord) )
393 {
394 if (kCmp) {
395 /* Boxed comparisons */
396 Word cmpresS;
397 while (True) {
398 if (t == NULL) return NULL;
399 cmpresS = kCmp(t->key, k);
400 if (cmpresS > 0) t = t->child[0]; else
401 if (cmpresS < 0) t = t->child[1]; else
402 return t;
403 }
404 } else {
405 /* Unboxed comparisons */
406 Word cmpresS; /* signed */
407 UWord cmpresU; /* unsigned */
408 while (True) {
409 if (t == NULL) return NULL; /* unlikely ==> predictable */
410 cmpresS = cmp_unsigned_Words( (UWord)t->key, (UWord)k );
411 if (cmpresS == 0) return t; /* unlikely ==> predictable */
412 cmpresU = (UWord)cmpresS;
413 cmpresU >>=/*unsigned*/ (8 * sizeof(cmpresU) - 1);
414 t = t->child[cmpresU];
415 }
416 }
417 }
418
419 static
avl_find_bounds(const AvlNode * t,UWord * kMinP,UWord * vMinP,UWord * kMaxP,UWord * vMaxP,UWord minKey,UWord minVal,UWord maxKey,UWord maxVal,UWord key,Word (* kCmp)(UWord,UWord))420 Bool avl_find_bounds ( const AvlNode* t,
421 /*OUT*/UWord* kMinP, /*OUT*/UWord* vMinP,
422 /*OUT*/UWord* kMaxP, /*OUT*/UWord* vMaxP,
423 UWord minKey, UWord minVal,
424 UWord maxKey, UWord maxVal,
425 UWord key,
426 Word(*kCmp)(UWord,UWord) )
427 {
428 UWord kLowerBound = minKey;
429 UWord vLowerBound = minVal;
430 UWord kUpperBound = maxKey;
431 UWord vUpperBound = maxVal;
432 while (t) {
433 Word cmpresS = kCmp ? kCmp(t->key, key)
434 : cmp_unsigned_Words(t->key, key);
435 if (cmpresS < 0) {
436 kLowerBound = t->key;
437 vLowerBound = t->val;
438 t = t->child[1];
439 continue;
440 }
441 if (cmpresS > 0) {
442 kUpperBound = t->key;
443 vUpperBound = t->val;
444 t = t->child[0];
445 continue;
446 }
447 /* We should never get here. If we do, it means the given key
448 is actually present in the tree, which means the original
449 call was invalid -- an error on the caller's part, and we
450 cannot give any meaningful values for the bounds. (Well,
451 maybe we could, but we're not gonna. Ner!) */
452 return False;
453 }
454 if (kMinP) *kMinP = kLowerBound;
455 if (vMinP) *vMinP = vLowerBound;
456 if (kMaxP) *kMaxP = kUpperBound;
457 if (vMaxP) *vMaxP = vUpperBound;
458 return True;
459 }
460
461 // Clear the iterator stack.
stackClear(WordFM * fm)462 static void stackClear(WordFM* fm)
463 {
464 Int i;
465 vg_assert(fm);
466 for (i = 0; i < WFM_STKMAX; i++) {
467 fm->nodeStack[i] = NULL;
468 fm->numStack[i] = 0;
469 }
470 fm->stackTop = 0;
471 }
472
473 // Push onto the iterator stack.
stackPush(WordFM * fm,AvlNode * n,Int i)474 static inline void stackPush(WordFM* fm, AvlNode* n, Int i)
475 {
476 vg_assert(fm->stackTop < WFM_STKMAX);
477 vg_assert(1 <= i && i <= 3);
478 fm->nodeStack[fm->stackTop] = n;
479 fm-> numStack[fm->stackTop] = i;
480 fm->stackTop++;
481 }
482
483 // Pop from the iterator stack.
stackPop(WordFM * fm,AvlNode ** n,Int * i)484 static inline Bool stackPop(WordFM* fm, AvlNode** n, Int* i)
485 {
486 vg_assert(fm->stackTop <= WFM_STKMAX);
487
488 if (fm->stackTop > 0) {
489 fm->stackTop--;
490 *n = fm->nodeStack[fm->stackTop];
491 *i = fm-> numStack[fm->stackTop];
492 vg_assert(1 <= *i && *i <= 3);
493 fm->nodeStack[fm->stackTop] = NULL;
494 fm-> numStack[fm->stackTop] = 0;
495 return True;
496 } else {
497 return False;
498 }
499 }
500
501 static
avl_dopy(const AvlNode * nd,UWord (* dopyK)(UWord),UWord (* dopyV)(UWord),void * (alloc_nofail)(const HChar *,SizeT),const HChar * cc)502 AvlNode* avl_dopy ( const AvlNode* nd,
503 UWord(*dopyK)(UWord),
504 UWord(*dopyV)(UWord),
505 void*(alloc_nofail)(const HChar*,SizeT),
506 const HChar* cc )
507 {
508 AvlNode* nyu;
509
510 vg_assert(nd != NULL);
511
512 nyu = alloc_nofail(cc, sizeof(AvlNode));
513
514 nyu->child[0] = nd->child[0];
515 nyu->child[1] = nd->child[1];
516 nyu->balance = nd->balance;
517
518 /* Copy key */
519 if (dopyK) {
520 nyu->key = dopyK( nd->key );
521 } else {
522 /* copying assumedly unboxed keys */
523 nyu->key = nd->key;
524 }
525
526 /* Copy val */
527 if (dopyV) {
528 nyu->val = dopyV( nd->val );
529 } else {
530 /* copying assumedly unboxed vals */
531 nyu->val = nd->val;
532 }
533
534 /* Copy subtrees */
535 if (nyu->child[0]) {
536 nyu->child[0] = avl_dopy( nyu->child[0], dopyK, dopyV,
537 alloc_nofail, cc );
538 }
539 if (nyu->child[1]) {
540 nyu->child[1] = avl_dopy( nyu->child[1], dopyK, dopyV,
541 alloc_nofail, cc );
542 }
543
544 return nyu;
545 }
546
547 /* Initialise a WordFM. */
initFM(WordFM * fm,void * (* alloc_nofail)(const HChar *,SizeT),const HChar * cc,void (* dealloc)(void *),Word (* kCmp)(UWord,UWord))548 static void initFM ( WordFM* fm,
549 void* (*alloc_nofail)( const HChar*, SizeT ),
550 const HChar* cc,
551 void (*dealloc)(void*),
552 Word (*kCmp)(UWord,UWord) )
553 {
554 fm->root = 0;
555 fm->kCmp = kCmp;
556 fm->alloc_nofail = alloc_nofail;
557 fm->cc = cc;
558 fm->dealloc = dealloc;
559 fm->stackTop = 0;
560 }
561
562 /* --- Public interface functions --- */
563
564 /* Allocate and initialise a WordFM. If kCmp is non-NULL, elements in
565 the set are ordered according to the ordering specified by kCmp,
566 which becomes obvious if you use VG_(initIterFM),
567 VG_(initIterAtFM), VG_(nextIterFM), VG_(doneIterFM) to iterate over
568 sections of the map, or the whole thing. If kCmp is NULL then the
569 ordering used is unsigned word ordering (UWord) on the key
570 values. */
VG_(newFM)571 WordFM* VG_(newFM) ( void* (*alloc_nofail)( const HChar*, SizeT ),
572 const HChar* cc,
573 void (*dealloc)(void*),
574 Word (*kCmp)(UWord,UWord) )
575 {
576 WordFM* fm = alloc_nofail(cc, sizeof(WordFM));
577 initFM(fm, alloc_nofail, cc, dealloc, kCmp);
578 return fm;
579 }
580
avl_free(AvlNode * nd,void (* kFin)(UWord),void (* vFin)(UWord),void (* dealloc)(void *))581 static void avl_free ( AvlNode* nd,
582 void(*kFin)(UWord),
583 void(*vFin)(UWord),
584 void(*dealloc)(void*) )
585 {
586 if (!nd)
587 return;
588 if (nd->child[0])
589 avl_free(nd->child[0], kFin, vFin, dealloc);
590 if (nd->child[1])
591 avl_free(nd->child[1], kFin, vFin, dealloc);
592 if (kFin)
593 kFin( nd->key );
594 if (vFin)
595 vFin( nd->val );
596 VG_(memset)(nd, 0, sizeof(AvlNode));
597 dealloc(nd);
598 }
599
600 /* Free up the FM. If kFin is non-NULL, it is applied to keys
601 before the FM is deleted; ditto with vFin for vals. */
VG_(deleteFM)602 void VG_(deleteFM) ( WordFM* fm, void(*kFin)(UWord), void(*vFin)(UWord) )
603 {
604 void(*dealloc)(void*) = fm->dealloc;
605 avl_free( fm->root, kFin, vFin, dealloc );
606 VG_(memset)(fm, 0, sizeof(WordFM) );
607 dealloc(fm);
608 }
609
610 /* Add (k,v) to fm. */
VG_(addToFM)611 Bool VG_(addToFM) ( WordFM* fm, UWord k, UWord v )
612 {
613 MaybeWord oldV;
614 AvlNode* node;
615 node = fm->alloc_nofail( fm->cc, sizeof(AvlNode) );
616 node->key = k;
617 node->val = v;
618 oldV.b = False;
619 oldV.w = 0;
620 avl_insert_wrk( &fm->root, &oldV, node, fm->kCmp );
621 //if (oldV.b && fm->vFin)
622 // fm->vFin( oldV.w );
623 if (oldV.b)
624 fm->dealloc(node);
625 return oldV.b;
626 }
627
628 // Delete key from fm, returning associated key and val if found
VG_(delFromFM)629 Bool VG_(delFromFM) ( WordFM* fm,
630 /*OUT*/UWord* oldK, /*OUT*/UWord* oldV, UWord key )
631 {
632 AvlNode* node = avl_find_node( fm->root, key, fm->kCmp );
633 if (node) {
634 avl_remove_wrk( &fm->root, node, fm->kCmp );
635 if (oldK)
636 *oldK = node->key;
637 if (oldV)
638 *oldV = node->val;
639 fm->dealloc(node);
640 return True;
641 } else {
642 return False;
643 }
644 }
645
646 // Look up in fm, assigning found key & val at spec'd addresses
VG_(lookupFM)647 Bool VG_(lookupFM) ( const WordFM* fm,
648 /*OUT*/UWord* keyP, /*OUT*/UWord* valP, UWord key )
649 {
650 AvlNode* node = avl_find_node( fm->root, key, fm->kCmp );
651 if (node) {
652 if (keyP)
653 *keyP = node->key;
654 if (valP)
655 *valP = node->val;
656 return True;
657 } else {
658 return False;
659 }
660 }
661
662 // See comment in pub_tool_wordfm.h for explanation
VG_(findBoundsFM)663 Bool VG_(findBoundsFM)( const WordFM* fm,
664 /*OUT*/UWord* kMinP, /*OUT*/UWord* vMinP,
665 /*OUT*/UWord* kMaxP, /*OUT*/UWord* vMaxP,
666 UWord minKey, UWord minVal,
667 UWord maxKey, UWord maxVal,
668 UWord key )
669 {
670 /* really we should assert that minKey <= key <= maxKey,
671 where <= is as defined by fm->kCmp. */
672 return avl_find_bounds( fm->root, kMinP, vMinP,
673 kMaxP, vMaxP,
674 minKey, minVal,
675 maxKey, maxVal,
676 key, fm->kCmp );
677 }
678
679 // See comment in pub_tool_wordfm.h for performance warning
VG_(sizeFM)680 UWord VG_(sizeFM) ( const WordFM* fm )
681 {
682 // Hmm, this is a bad way to do this
683 return fm->root ? size_avl_nonNull( fm->root ) : 0;
684 }
685
686 // NB UNTESTED! TEST BEFORE USE!
687 //Bool VG_(isEmptyFM)( const WordFM* fm )
688 //{
689 // return fm->root ? False : True;
690 //}
691
692 // set up FM for iteration
VG_(initIterFM)693 void VG_(initIterFM) ( WordFM* fm )
694 {
695 vg_assert(fm);
696 stackClear(fm);
697 if (fm->root)
698 stackPush(fm, fm->root, 1);
699 }
700
701 // set up FM for iteration so that the first key subsequently produced
702 // by VG_(nextIterFM) is the smallest key in the map >= start_at.
703 // Naturally ">=" is defined by the comparison function supplied to
704 // VG_(newFM), as documented above.
VG_(initIterAtFM)705 void VG_(initIterAtFM) ( WordFM* fm, UWord start_at )
706 {
707 Int i;
708 AvlNode *n, *t;
709 Word cmpresS; /* signed */
710 UWord cmpresU; /* unsigned */
711
712 vg_assert(fm);
713 stackClear(fm);
714
715 if (!fm->root)
716 return;
717
718 n = NULL;
719 // We need to do regular search and fill in the stack.
720 t = fm->root;
721
722 while (True) {
723 if (t == NULL) return;
724
725 cmpresS
726 = fm->kCmp ? /*boxed*/ fm->kCmp( t->key, start_at )
727 : /*unboxed*/ cmp_unsigned_Words( t->key, start_at );
728
729 if (cmpresS == 0) {
730 // We found the exact key -- we are done.
731 // The iteration should start with this node.
732 stackPush(fm, t, 2);
733 // The stack now looks like {2, 2, ... ,2, 2}
734 return;
735 }
736 cmpresU = (UWord)cmpresS;
737 cmpresU >>=/*unsigned*/ (8 * sizeof(cmpresU) - 1);
738 if (!cmpresU) {
739 // Push this node only if we go to the left child.
740 stackPush(fm, t, 2);
741 }
742 t = t->child[cmpresU];
743 }
744 if (stackPop(fm, &n, &i)) {
745 // If we've pushed something to stack and did not find the exact key,
746 // we must fix the top element of stack.
747 vg_assert(i == 2);
748 stackPush(fm, n, 3);
749 // the stack looks like {2, 2, ..., 2, 3}
750 }
751 }
752
753 // get next key/val pair. Will vg_assert if fm has been modified
754 // or looked up in since initIter{,At}FM was called.
VG_(nextIterFM)755 Bool VG_(nextIterFM) ( WordFM* fm, /*OUT*/UWord* pKey, /*OUT*/UWord* pVal )
756 {
757 Int i = 0;
758 AvlNode* n = NULL;
759
760 vg_assert(fm);
761
762 // This in-order traversal requires each node to be pushed and popped
763 // three times. These could be avoided by updating nodes in-situ on the
764 // top of the stack, but the push/pop cost is so small that it's worth
765 // keeping this loop in this simpler form.
766 while (stackPop(fm, &n, &i)) {
767 switch (i) {
768 case 1: case_1:
769 stackPush(fm, n, 2);
770 /* if (n->child[0]) stackPush(fm, n->child[0], 1); */
771 if (n->child[0]) { n = n->child[0]; goto case_1; }
772 break;
773 case 2:
774 stackPush(fm, n, 3);
775 if (pKey) *pKey = n->key;
776 if (pVal) *pVal = n->val;
777 return True;
778 case 3:
779 /* if (n->child[1]) stackPush(fm, n->child[1], 1); */
780 if (n->child[1]) { n = n->child[1]; goto case_1; }
781 break;
782 default:
783 vg_assert(0);
784 }
785 }
786
787 // Stack empty, iterator is exhausted, return NULL
788 return False;
789 }
790
791 // Finish an FM iteration
VG_(doneIterFM)792 void VG_(doneIterFM) ( WordFM* fm )
793 {
794 }
795
VG_(dopyFM)796 WordFM* VG_(dopyFM) ( WordFM* fm, UWord(*dopyK)(UWord),
797 UWord(*dopyV)(UWord) )
798 {
799 WordFM* nyu;
800
801 /* can't clone the fm whilst iterating on it */
802 vg_assert(fm->stackTop == 0);
803
804 nyu = fm->alloc_nofail( fm->cc, sizeof(WordFM) );
805
806 *nyu = *fm;
807
808 fm->stackTop = 0;
809 VG_(memset)(fm->nodeStack, 0, sizeof(fm->nodeStack));
810 VG_(memset)(fm->numStack, 0, sizeof(fm->numStack));
811
812 if (nyu->root) {
813 nyu->root = avl_dopy( nyu->root, dopyK, dopyV,
814 fm->alloc_nofail, fm->cc );
815 if (! nyu->root)
816 return NULL;
817 }
818
819 return nyu;
820 }
821
822 //------------------------------------------------------------------//
823 //--- end WordFM ---//
824 //--- Implementation ---//
825 //------------------------------------------------------------------//
826
827 //------------------------------------------------------------------//
828 //--- WordBag (unboxed words only) ---//
829 //--- Implementation ---//
830 //------------------------------------------------------------------//
831
832 /* A trivial container, to make it opaque. */
833 struct _WordBag {
834 WordFM* fm;
835 };
836
VG_(newBag)837 WordBag* VG_(newBag) ( void* (*alloc_nofail)( const HChar*, SizeT ),
838 const HChar* cc,
839 void (*dealloc)(void*) )
840 {
841 WordBag* bag = alloc_nofail(cc, sizeof(WordBag));
842 bag->fm = VG_(newFM)( alloc_nofail, cc, dealloc, NULL );
843 return bag;
844 }
845
VG_(deleteBag)846 void VG_(deleteBag) ( WordBag* bag )
847 {
848 void (*dealloc)(void*) = bag->fm->dealloc;
849 VG_(deleteFM)( bag->fm, NULL, NULL );
850 VG_(memset)(bag, 0, sizeof(WordBag));
851 dealloc(bag);
852 }
853
VG_(addToBag)854 void VG_(addToBag)( WordBag* bag, UWord w )
855 {
856 UWord key, count;
857 if (VG_(lookupFM)(bag->fm, &key, &count, w)) {
858 vg_assert(key == w);
859 vg_assert(count >= 1);
860 VG_(addToFM)(bag->fm, w, count+1);
861 } else {
862 VG_(addToFM)(bag->fm, w, 1);
863 }
864 }
865
VG_(elemBag)866 UWord VG_(elemBag) ( const WordBag* bag, UWord w )
867 {
868 UWord key, count;
869 if (VG_(lookupFM)( bag->fm, &key, &count, w)) {
870 vg_assert(key == w);
871 vg_assert(count >= 1);
872 return count;
873 } else {
874 return 0;
875 }
876 }
877
VG_(sizeUniqueBag)878 UWord VG_(sizeUniqueBag) ( const WordBag* bag )
879 {
880 return VG_(sizeFM)( bag->fm );
881 }
882
sizeTotalBag_wrk(const AvlNode * nd)883 static UWord sizeTotalBag_wrk ( const AvlNode* nd )
884 {
885 /* unchecked pre: nd is non-NULL */
886 UWord w = nd->val;
887 vg_assert(w >= 1);
888 if (nd->child[0])
889 w += sizeTotalBag_wrk(nd->child[0]);
890 if (nd->child[1])
891 w += sizeTotalBag_wrk(nd->child[1]);
892 return w;
893 }
VG_(sizeTotalBag)894 UWord VG_(sizeTotalBag)( const WordBag* bag )
895 {
896 if (bag->fm->root)
897 return sizeTotalBag_wrk(bag->fm->root);
898 else
899 return 0;
900 }
901
VG_(delFromBag)902 Bool VG_(delFromBag)( WordBag* bag, UWord w )
903 {
904 UWord key, count;
905 if (VG_(lookupFM)(bag->fm, &key, &count, w)) {
906 vg_assert(key == w);
907 vg_assert(count >= 1);
908 if (count > 1) {
909 VG_(addToFM)(bag->fm, w, count-1);
910 } else {
911 vg_assert(count == 1);
912 VG_(delFromFM)( bag->fm, NULL, NULL, w );
913 }
914 return True;
915 } else {
916 return False;
917 }
918 }
919
VG_(isEmptyBag)920 Bool VG_(isEmptyBag)( const WordBag* bag )
921 {
922 return VG_(sizeFM)(bag->fm) == 0;
923 }
924
VG_(isSingletonTotalBag)925 Bool VG_(isSingletonTotalBag)( const WordBag* bag )
926 {
927 AvlNode* nd;
928 if (VG_(sizeFM)(bag->fm) != 1)
929 return False;
930 nd = bag->fm->root;
931 vg_assert(nd);
932 vg_assert(!nd->child[0]);
933 vg_assert(!nd->child[1]);
934 return nd->val == 1;
935 }
936
VG_(anyElementOfBag)937 UWord VG_(anyElementOfBag)( const WordBag* bag )
938 {
939 /* Return an arbitrarily chosen element in the bag. We might as
940 well return the one at the root of the underlying AVL tree. */
941 AvlNode* nd = bag->fm->root;
942 vg_assert(nd); /* if this fails, 'bag' is empty - caller is in error. */
943 vg_assert(nd->val >= 1);
944 return nd->key;
945 }
946
VG_(initIterBag)947 void VG_(initIterBag)( WordBag* bag )
948 {
949 VG_(initIterFM)(bag->fm);
950 }
951
VG_(nextIterBag)952 Bool VG_(nextIterBag)( WordBag* bag, /*OUT*/UWord* pVal, /*OUT*/UWord* pCount )
953 {
954 return VG_(nextIterFM)( bag->fm, pVal, pCount );
955 }
956
VG_(doneIterBag)957 void VG_(doneIterBag)( WordBag* bag )
958 {
959 VG_(doneIterFM)( bag->fm );
960 }
961
962 //------------------------------------------------------------------//
963 //--- end WordBag (unboxed words only) ---//
964 //--- Implementation ---//
965 //------------------------------------------------------------------//
966
967 /*--------------------------------------------------------------------*/
968 /*--- end m_wordfm.c ---*/
969 /*--------------------------------------------------------------------*/
970