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) 2007-2012 Julian Seward 13 jseward (at) 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) 2005-2012 Nicholas Nethercote 19 njn (at) 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)( HChar*, SizeT ); 85 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. */ 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. */ 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. */ 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 tl_assert(0); 134 } 135 root->balance=0; 136 } 137 138 /* Find size of a non-NULL tree. */ 139 static UWord size_avl_nonNull ( 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. */ 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 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: tl_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 tl_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: tl_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 tl_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 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 tl_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: tl_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 tl_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 tl_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: tl_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 tl_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 tl_assert(cmpres == 0); 346 tl_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 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 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 420 Bool avl_find_bounds ( 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. 462 static void stackClear(WordFM* fm) 463 { 464 Int i; 465 tl_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. 474 static inline void stackPush(WordFM* fm, AvlNode* n, Int i) 475 { 476 tl_assert(fm->stackTop < WFM_STKMAX); 477 tl_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. 484 static inline Bool stackPop(WordFM* fm, AvlNode** n, Int* i) 485 { 486 tl_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 tl_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 502 AvlNode* avl_dopy ( AvlNode* nd, 503 UWord(*dopyK)(UWord), 504 UWord(*dopyV)(UWord), 505 void*(alloc_nofail)(HChar*,SizeT), 506 HChar* cc ) 507 { 508 AvlNode* nyu; 509 if (! nd) 510 return NULL; 511 nyu = alloc_nofail(cc, sizeof(AvlNode)); 512 tl_assert(nyu); 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 if (nd->key != 0 && nyu->key == 0) 522 return NULL; /* oom in key dcopy */ 523 } else { 524 /* copying assumedly unboxed keys */ 525 nyu->key = nd->key; 526 } 527 528 /* Copy val */ 529 if (dopyV) { 530 nyu->val = dopyV( nd->val ); 531 if (nd->val != 0 && nyu->val == 0) 532 return NULL; /* oom in val dcopy */ 533 } else { 534 /* copying assumedly unboxed vals */ 535 nyu->val = nd->val; 536 } 537 538 /* Copy subtrees */ 539 if (nyu->child[0]) { 540 nyu->child[0] = avl_dopy( nyu->child[0], dopyK, dopyV, 541 alloc_nofail, cc ); 542 if (! nyu->child[0]) 543 return NULL; 544 } 545 if (nyu->child[1]) { 546 nyu->child[1] = avl_dopy( nyu->child[1], dopyK, dopyV, 547 alloc_nofail, cc ); 548 if (! nyu->child[1]) 549 return NULL; 550 } 551 552 return nyu; 553 } 554 555 /* Initialise a WordFM. */ 556 static void initFM ( WordFM* fm, 557 void* (*alloc_nofail)( HChar*, SizeT ), 558 HChar* cc, 559 void (*dealloc)(void*), 560 Word (*kCmp)(UWord,UWord) ) 561 { 562 fm->root = 0; 563 fm->kCmp = kCmp; 564 fm->alloc_nofail = alloc_nofail; 565 fm->cc = cc; 566 fm->dealloc = dealloc; 567 fm->stackTop = 0; 568 } 569 570 /* --- Public interface functions --- */ 571 572 /* Allocate and initialise a WordFM. If kCmp is non-NULL, elements in 573 the set are ordered according to the ordering specified by kCmp, 574 which becomes obvious if you use VG_(initIterFM), 575 VG_(initIterAtFM), VG_(nextIterFM), VG_(doneIterFM) to iterate over 576 sections of the map, or the whole thing. If kCmp is NULL then the 577 ordering used is unsigned word ordering (UWord) on the key 578 values. */ 579 WordFM* VG_(newFM) ( void* (*alloc_nofail)( HChar*, SizeT ), 580 HChar* cc, 581 void (*dealloc)(void*), 582 Word (*kCmp)(UWord,UWord) ) 583 { 584 WordFM* fm = alloc_nofail(cc, sizeof(WordFM)); 585 tl_assert(fm); 586 initFM(fm, alloc_nofail, cc, dealloc, kCmp); 587 return fm; 588 } 589 590 static void avl_free ( AvlNode* nd, 591 void(*kFin)(UWord), 592 void(*vFin)(UWord), 593 void(*dealloc)(void*) ) 594 { 595 if (!nd) 596 return; 597 if (nd->child[0]) 598 avl_free(nd->child[0], kFin, vFin, dealloc); 599 if (nd->child[1]) 600 avl_free(nd->child[1], kFin, vFin, dealloc); 601 if (kFin) 602 kFin( nd->key ); 603 if (vFin) 604 vFin( nd->val ); 605 VG_(memset)(nd, 0, sizeof(AvlNode)); 606 dealloc(nd); 607 } 608 609 /* Free up the FM. If kFin is non-NULL, it is applied to keys 610 before the FM is deleted; ditto with vFin for vals. */ 611 void VG_(deleteFM) ( WordFM* fm, void(*kFin)(UWord), void(*vFin)(UWord) ) 612 { 613 void(*dealloc)(void*) = fm->dealloc; 614 avl_free( fm->root, kFin, vFin, dealloc ); 615 VG_(memset)(fm, 0, sizeof(WordFM) ); 616 dealloc(fm); 617 } 618 619 /* Add (k,v) to fm. */ 620 Bool VG_(addToFM) ( WordFM* fm, UWord k, UWord v ) 621 { 622 MaybeWord oldV; 623 AvlNode* node; 624 node = fm->alloc_nofail( fm->cc, sizeof(AvlNode) ); 625 node->key = k; 626 node->val = v; 627 oldV.b = False; 628 oldV.w = 0; 629 avl_insert_wrk( &fm->root, &oldV, node, fm->kCmp ); 630 //if (oldV.b && fm->vFin) 631 // fm->vFin( oldV.w ); 632 if (oldV.b) 633 fm->dealloc(node); 634 return oldV.b; 635 } 636 637 // Delete key from fm, returning associated key and val if found 638 Bool VG_(delFromFM) ( WordFM* fm, 639 /*OUT*/UWord* oldK, /*OUT*/UWord* oldV, UWord key ) 640 { 641 AvlNode* node = avl_find_node( fm->root, key, fm->kCmp ); 642 if (node) { 643 avl_remove_wrk( &fm->root, node, fm->kCmp ); 644 if (oldK) 645 *oldK = node->key; 646 if (oldV) 647 *oldV = node->val; 648 fm->dealloc(node); 649 return True; 650 } else { 651 return False; 652 } 653 } 654 655 // Look up in fm, assigning found key & val at spec'd addresses 656 Bool VG_(lookupFM) ( WordFM* fm, 657 /*OUT*/UWord* keyP, /*OUT*/UWord* valP, UWord key ) 658 { 659 AvlNode* node = avl_find_node( fm->root, key, fm->kCmp ); 660 if (node) { 661 if (keyP) 662 *keyP = node->key; 663 if (valP) 664 *valP = node->val; 665 return True; 666 } else { 667 return False; 668 } 669 } 670 671 // See comment in pub_tool_wordfm.h for explanation 672 Bool VG_(findBoundsFM)( WordFM* fm, 673 /*OUT*/UWord* kMinP, /*OUT*/UWord* vMinP, 674 /*OUT*/UWord* kMaxP, /*OUT*/UWord* vMaxP, 675 UWord minKey, UWord minVal, 676 UWord maxKey, UWord maxVal, 677 UWord key ) 678 { 679 /* really we should assert that minKey <= key <= maxKey, 680 where <= is as defined by fm->kCmp. */ 681 return avl_find_bounds( fm->root, kMinP, vMinP, 682 kMaxP, vMaxP, 683 minKey, minVal, 684 maxKey, maxVal, 685 key, fm->kCmp ); 686 } 687 688 // See comment in pub_tool_wordfm.h for performance warning 689 UWord VG_(sizeFM) ( WordFM* fm ) 690 { 691 // Hmm, this is a bad way to do this 692 return fm->root ? size_avl_nonNull( fm->root ) : 0; 693 } 694 695 // NB UNTESTED! TEST BEFORE USE! 696 //Bool VG_(isEmptyFM)( WordFM* fm ) 697 //{ 698 // return fm->root ? False : True; 699 //} 700 701 // set up FM for iteration 702 void VG_(initIterFM) ( WordFM* fm ) 703 { 704 tl_assert(fm); 705 stackClear(fm); 706 if (fm->root) 707 stackPush(fm, fm->root, 1); 708 } 709 710 // set up FM for iteration so that the first key subsequently produced 711 // by VG_(nextIterFM) is the smallest key in the map >= start_at. 712 // Naturally ">=" is defined by the comparison function supplied to 713 // VG_(newFM), as documented above. 714 void VG_(initIterAtFM) ( WordFM* fm, UWord start_at ) 715 { 716 Int i; 717 AvlNode *n, *t; 718 Word cmpresS; /* signed */ 719 UWord cmpresU; /* unsigned */ 720 721 tl_assert(fm); 722 stackClear(fm); 723 724 if (!fm->root) 725 return; 726 727 n = NULL; 728 // We need to do regular search and fill in the stack. 729 t = fm->root; 730 731 while (True) { 732 if (t == NULL) return; 733 734 cmpresS 735 = fm->kCmp ? /*boxed*/ fm->kCmp( t->key, start_at ) 736 : /*unboxed*/ cmp_unsigned_Words( t->key, start_at ); 737 738 if (cmpresS == 0) { 739 // We found the exact key -- we are done. 740 // The iteration should start with this node. 741 stackPush(fm, t, 2); 742 // The stack now looks like {2, 2, ... ,2, 2} 743 return; 744 } 745 cmpresU = (UWord)cmpresS; 746 cmpresU >>=/*unsigned*/ (8 * sizeof(cmpresU) - 1); 747 if (!cmpresU) { 748 // Push this node only if we go to the left child. 749 stackPush(fm, t, 2); 750 } 751 t = t->child[cmpresU]; 752 } 753 if (stackPop(fm, &n, &i)) { 754 // If we've pushed something to stack and did not find the exact key, 755 // we must fix the top element of stack. 756 tl_assert(i == 2); 757 stackPush(fm, n, 3); 758 // the stack looks like {2, 2, ..., 2, 3} 759 } 760 } 761 762 // get next key/val pair. Will tl_assert if fm has been modified 763 // or looked up in since initIter{,At}FM was called. 764 Bool VG_(nextIterFM) ( WordFM* fm, /*OUT*/UWord* pKey, /*OUT*/UWord* pVal ) 765 { 766 Int i = 0; 767 AvlNode* n = NULL; 768 769 tl_assert(fm); 770 771 // This in-order traversal requires each node to be pushed and popped 772 // three times. These could be avoided by updating nodes in-situ on the 773 // top of the stack, but the push/pop cost is so small that it's worth 774 // keeping this loop in this simpler form. 775 while (stackPop(fm, &n, &i)) { 776 switch (i) { 777 case 1: case_1: 778 stackPush(fm, n, 2); 779 /* if (n->child[0]) stackPush(fm, n->child[0], 1); */ 780 if (n->child[0]) { n = n->child[0]; goto case_1; } 781 break; 782 case 2: 783 stackPush(fm, n, 3); 784 if (pKey) *pKey = n->key; 785 if (pVal) *pVal = n->val; 786 return True; 787 case 3: 788 /* if (n->child[1]) stackPush(fm, n->child[1], 1); */ 789 if (n->child[1]) { n = n->child[1]; goto case_1; } 790 break; 791 default: 792 tl_assert(0); 793 } 794 } 795 796 // Stack empty, iterator is exhausted, return NULL 797 return False; 798 } 799 800 // clear the I'm iterating flag 801 void VG_(doneIterFM) ( WordFM* fm ) 802 { 803 } 804 805 WordFM* VG_(dopyFM) ( WordFM* fm, UWord(*dopyK)(UWord), UWord(*dopyV)(UWord) ) 806 { 807 WordFM* nyu; 808 809 /* can't clone the fm whilst iterating on it */ 810 tl_assert(fm->stackTop == 0); 811 812 nyu = fm->alloc_nofail( fm->cc, sizeof(WordFM) ); 813 tl_assert(nyu); 814 815 *nyu = *fm; 816 817 fm->stackTop = 0; 818 VG_(memset)(fm->nodeStack, 0, sizeof(fm->nodeStack)); 819 VG_(memset)(fm->numStack, 0, sizeof(fm->numStack)); 820 821 if (nyu->root) { 822 nyu->root = avl_dopy( nyu->root, dopyK, dopyV, 823 fm->alloc_nofail, fm->cc ); 824 if (! nyu->root) 825 return NULL; 826 } 827 828 return nyu; 829 } 830 831 // admin: what's the 'common' allocation size (for tree nodes?) 832 SizeT VG_(getNodeSizeFM)( void ) 833 { 834 return sizeof(AvlNode); 835 } 836 837 //------------------------------------------------------------------// 838 //--- end WordFM ---// 839 //--- Implementation ---// 840 //------------------------------------------------------------------// 841 842 //------------------------------------------------------------------// 843 //--- WordBag (unboxed words only) ---// 844 //--- Implementation ---// 845 //------------------------------------------------------------------// 846 847 /* A trivial container, to make it opaque. */ 848 struct _WordBag { 849 WordFM* fm; 850 }; 851 852 WordBag* VG_(newBag) ( void* (*alloc_nofail)( HChar*, SizeT ), 853 HChar* cc, 854 void (*dealloc)(void*) ) 855 { 856 WordBag* bag = alloc_nofail(cc, sizeof(WordBag)); 857 bag->fm = VG_(newFM)( alloc_nofail, cc, dealloc, NULL ); 858 return bag; 859 } 860 861 void VG_(deleteBag) ( WordBag* bag ) 862 { 863 void (*dealloc)(void*) = bag->fm->dealloc; 864 VG_(deleteFM)( bag->fm, NULL, NULL ); 865 VG_(memset)(bag, 0, sizeof(WordBag)); 866 dealloc(bag); 867 } 868 869 void VG_(addToBag)( WordBag* bag, UWord w ) 870 { 871 UWord key, count; 872 if (VG_(lookupFM)(bag->fm, &key, &count, w)) { 873 tl_assert(key == w); 874 tl_assert(count >= 1); 875 VG_(addToFM)(bag->fm, w, count+1); 876 } else { 877 VG_(addToFM)(bag->fm, w, 1); 878 } 879 } 880 881 UWord VG_(elemBag) ( WordBag* bag, UWord w ) 882 { 883 UWord key, count; 884 if (VG_(lookupFM)( bag->fm, &key, &count, w)) { 885 tl_assert(key == w); 886 tl_assert(count >= 1); 887 return count; 888 } else { 889 return 0; 890 } 891 } 892 893 UWord VG_(sizeUniqueBag) ( WordBag* bag ) 894 { 895 return VG_(sizeFM)( bag->fm ); 896 } 897 898 static UWord sizeTotalBag_wrk ( AvlNode* nd ) 899 { 900 /* unchecked pre: nd is non-NULL */ 901 UWord w = nd->val; 902 tl_assert(w >= 1); 903 if (nd->child[0]) 904 w += sizeTotalBag_wrk(nd->child[0]); 905 if (nd->child[1]) 906 w += sizeTotalBag_wrk(nd->child[1]); 907 return w; 908 } 909 UWord VG_(sizeTotalBag)( WordBag* bag ) 910 { 911 if (bag->fm->root) 912 return sizeTotalBag_wrk(bag->fm->root); 913 else 914 return 0; 915 } 916 917 Bool VG_(delFromBag)( WordBag* bag, UWord w ) 918 { 919 UWord key, count; 920 if (VG_(lookupFM)(bag->fm, &key, &count, w)) { 921 tl_assert(key == w); 922 tl_assert(count >= 1); 923 if (count > 1) { 924 VG_(addToFM)(bag->fm, w, count-1); 925 } else { 926 tl_assert(count == 1); 927 VG_(delFromFM)( bag->fm, NULL, NULL, w ); 928 } 929 return True; 930 } else { 931 return False; 932 } 933 } 934 935 Bool VG_(isEmptyBag)( WordBag* bag ) 936 { 937 return VG_(sizeFM)(bag->fm) == 0; 938 } 939 940 Bool VG_(isSingletonTotalBag)( WordBag* bag ) 941 { 942 AvlNode* nd; 943 if (VG_(sizeFM)(bag->fm) != 1) 944 return False; 945 nd = bag->fm->root; 946 tl_assert(nd); 947 tl_assert(!nd->child[0]); 948 tl_assert(!nd->child[1]); 949 return nd->val == 1; 950 } 951 952 UWord VG_(anyElementOfBag)( WordBag* bag ) 953 { 954 /* Return an arbitrarily chosen element in the bag. We might as 955 well return the one at the root of the underlying AVL tree. */ 956 AvlNode* nd = bag->fm->root; 957 tl_assert(nd); /* if this fails, 'bag' is empty - caller is in error. */ 958 tl_assert(nd->val >= 1); 959 return nd->key; 960 } 961 962 void VG_(initIterBag)( WordBag* bag ) 963 { 964 VG_(initIterFM)(bag->fm); 965 } 966 967 Bool VG_(nextIterBag)( WordBag* bag, /*OUT*/UWord* pVal, /*OUT*/UWord* pCount ) 968 { 969 return VG_(nextIterFM)( bag->fm, pVal, pCount ); 970 } 971 972 void VG_(doneIterBag)( WordBag* bag ) 973 { 974 VG_(doneIterFM)( bag->fm ); 975 } 976 977 //------------------------------------------------------------------// 978 //--- end WordBag (unboxed words only) ---// 979 //--- Implementation ---// 980 //------------------------------------------------------------------// 981 982 /*--------------------------------------------------------------------*/ 983 /*--- end m_wordfm.c ---*/ 984 /*--------------------------------------------------------------------*/ 985
