1 /* 2 * rbtree.c -- generic red black tree 3 * 4 * Copyright (c) 2001-2007, NLnet Labs. All rights reserved. 5 * 6 * This software is open source. 7 * 8 * Redistribution and use in source and binary forms, with or without 9 * modification, are permitted provided that the following conditions 10 * are met: 11 * 12 * Redistributions of source code must retain the above copyright notice, 13 * this list of conditions and the following disclaimer. 14 * 15 * Redistributions in binary form must reproduce the above copyright notice, 16 * this list of conditions and the following disclaimer in the documentation 17 * and/or other materials provided with the distribution. 18 * 19 * Neither the name of the NLNET LABS nor the names of its contributors may 20 * be used to endorse or promote products derived from this software without 21 * specific prior written permission. 22 * 23 * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS 24 * "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT 25 * LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR 26 * A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT 27 * HOLDER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, 28 * SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED 29 * TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR 30 * PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF 31 * LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING 32 * NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS 33 * SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. 34 * 35 */ 36 37 /** 38 * \file 39 * Implementation of a redblack tree. 40 */ 41 42 #include "config.h" 43 #include "log.h" 44 #include "fptr_wlist.h" 45 #include "util/rbtree.h" 46 47 /** Node colour black */ 48 #define BLACK 0 49 /** Node colour red */ 50 #define RED 1 51 52 /** the NULL node, global alloc */ 53 rbnode_t rbtree_null_node = { 54 RBTREE_NULL, /* Parent. */ 55 RBTREE_NULL, /* Left. */ 56 RBTREE_NULL, /* Right. */ 57 NULL, /* Key. */ 58 BLACK /* Color. */ 59 }; 60 61 /** rotate subtree left (to preserve redblack property) */ 62 static void rbtree_rotate_left(rbtree_t *rbtree, rbnode_t *node); 63 /** rotate subtree right (to preserve redblack property) */ 64 static void rbtree_rotate_right(rbtree_t *rbtree, rbnode_t *node); 65 /** Fixup node colours when insert happened */ 66 static void rbtree_insert_fixup(rbtree_t *rbtree, rbnode_t *node); 67 /** Fixup node colours when delete happened */ 68 static void rbtree_delete_fixup(rbtree_t* rbtree, rbnode_t* child, rbnode_t* child_parent); 69 70 /* 71 * Creates a new red black tree, intializes and returns a pointer to it. 72 * 73 * Return NULL on failure. 74 * 75 */ 76 rbtree_t * 77 rbtree_create (int (*cmpf)(const void *, const void *)) 78 { 79 rbtree_t *rbtree; 80 81 /* Allocate memory for it */ 82 rbtree = (rbtree_t *) malloc(sizeof(rbtree_t)); 83 if (!rbtree) { 84 return NULL; 85 } 86 87 /* Initialize it */ 88 rbtree_init(rbtree, cmpf); 89 90 return rbtree; 91 } 92 93 void 94 rbtree_init(rbtree_t *rbtree, int (*cmpf)(const void *, const void *)) 95 { 96 /* Initialize it */ 97 rbtree->root = RBTREE_NULL; 98 rbtree->count = 0; 99 rbtree->cmp = cmpf; 100 } 101 102 /* 103 * Rotates the node to the left. 104 * 105 */ 106 static void 107 rbtree_rotate_left(rbtree_t *rbtree, rbnode_t *node) 108 { 109 rbnode_t *right = node->right; 110 node->right = right->left; 111 if (right->left != RBTREE_NULL) 112 right->left->parent = node; 113 114 right->parent = node->parent; 115 116 if (node->parent != RBTREE_NULL) { 117 if (node == node->parent->left) { 118 node->parent->left = right; 119 } else { 120 node->parent->right = right; 121 } 122 } else { 123 rbtree->root = right; 124 } 125 right->left = node; 126 node->parent = right; 127 } 128 129 /* 130 * Rotates the node to the right. 131 * 132 */ 133 static void 134 rbtree_rotate_right(rbtree_t *rbtree, rbnode_t *node) 135 { 136 rbnode_t *left = node->left; 137 node->left = left->right; 138 if (left->right != RBTREE_NULL) 139 left->right->parent = node; 140 141 left->parent = node->parent; 142 143 if (node->parent != RBTREE_NULL) { 144 if (node == node->parent->right) { 145 node->parent->right = left; 146 } else { 147 node->parent->left = left; 148 } 149 } else { 150 rbtree->root = left; 151 } 152 left->right = node; 153 node->parent = left; 154 } 155 156 static void 157 rbtree_insert_fixup(rbtree_t *rbtree, rbnode_t *node) 158 { 159 rbnode_t *uncle; 160 161 /* While not at the root and need fixing... */ 162 while (node != rbtree->root && node->parent->color == RED) { 163 /* If our parent is left child of our grandparent... */ 164 if (node->parent == node->parent->parent->left) { 165 uncle = node->parent->parent->right; 166 167 /* If our uncle is red... */ 168 if (uncle->color == RED) { 169 /* Paint the parent and the uncle black... */ 170 node->parent->color = BLACK; 171 uncle->color = BLACK; 172 173 /* And the grandparent red... */ 174 node->parent->parent->color = RED; 175 176 /* And continue fixing the grandparent */ 177 node = node->parent->parent; 178 } else { /* Our uncle is black... */ 179 /* Are we the right child? */ 180 if (node == node->parent->right) { 181 node = node->parent; 182 rbtree_rotate_left(rbtree, node); 183 } 184 /* Now we're the left child, repaint and rotate... */ 185 node->parent->color = BLACK; 186 node->parent->parent->color = RED; 187 rbtree_rotate_right(rbtree, node->parent->parent); 188 } 189 } else { 190 uncle = node->parent->parent->left; 191 192 /* If our uncle is red... */ 193 if (uncle->color == RED) { 194 /* Paint the parent and the uncle black... */ 195 node->parent->color = BLACK; 196 uncle->color = BLACK; 197 198 /* And the grandparent red... */ 199 node->parent->parent->color = RED; 200 201 /* And continue fixing the grandparent */ 202 node = node->parent->parent; 203 } else { /* Our uncle is black... */ 204 /* Are we the right child? */ 205 if (node == node->parent->left) { 206 node = node->parent; 207 rbtree_rotate_right(rbtree, node); 208 } 209 /* Now we're the right child, repaint and rotate... */ 210 node->parent->color = BLACK; 211 node->parent->parent->color = RED; 212 rbtree_rotate_left(rbtree, node->parent->parent); 213 } 214 } 215 } 216 rbtree->root->color = BLACK; 217 } 218 219 220 /* 221 * Inserts a node into a red black tree. 222 * 223 * Returns NULL on failure or the pointer to the newly added node 224 * otherwise. 225 */ 226 rbnode_t * 227 rbtree_insert (rbtree_t *rbtree, rbnode_t *data) 228 { 229 /* XXX Not necessary, but keeps compiler quiet... */ 230 int r = 0; 231 232 /* We start at the root of the tree */ 233 rbnode_t *node = rbtree->root; 234 rbnode_t *parent = RBTREE_NULL; 235 236 fptr_ok(fptr_whitelist_rbtree_cmp(rbtree->cmp)); 237 /* Lets find the new parent... */ 238 while (node != RBTREE_NULL) { 239 /* Compare two keys, do we have a duplicate? */ 240 if ((r = rbtree->cmp(data->key, node->key)) == 0) { 241 return NULL; 242 } 243 parent = node; 244 245 if (r < 0) { 246 node = node->left; 247 } else { 248 node = node->right; 249 } 250 } 251 252 /* Initialize the new node */ 253 data->parent = parent; 254 data->left = data->right = RBTREE_NULL; 255 data->color = RED; 256 rbtree->count++; 257 258 /* Insert it into the tree... */ 259 if (parent != RBTREE_NULL) { 260 if (r < 0) { 261 parent->left = data; 262 } else { 263 parent->right = data; 264 } 265 } else { 266 rbtree->root = data; 267 } 268 269 /* Fix up the red-black properties... */ 270 rbtree_insert_fixup(rbtree, data); 271 272 return data; 273 } 274 275 /* 276 * Searches the red black tree, returns the data if key is found or NULL otherwise. 277 * 278 */ 279 rbnode_t * 280 rbtree_search (rbtree_t *rbtree, const void *key) 281 { 282 rbnode_t *node; 283 284 if (rbtree_find_less_equal(rbtree, key, &node)) { 285 return node; 286 } else { 287 return NULL; 288 } 289 } 290 291 /** helpers for delete: swap node colours */ 292 static void swap_int8(uint8_t* x, uint8_t* y) 293 { 294 uint8_t t = *x; *x = *y; *y = t; 295 } 296 297 /** helpers for delete: swap node pointers */ 298 static void swap_np(rbnode_t** x, rbnode_t** y) 299 { 300 rbnode_t* t = *x; *x = *y; *y = t; 301 } 302 303 /** Update parent pointers of child trees of 'parent' */ 304 static void change_parent_ptr(rbtree_t* rbtree, rbnode_t* parent, rbnode_t* old, rbnode_t* new) 305 { 306 if(parent == RBTREE_NULL) 307 { 308 log_assert(rbtree->root == old); 309 if(rbtree->root == old) rbtree->root = new; 310 return; 311 } 312 log_assert(parent->left == old || parent->right == old 313 || parent->left == new || parent->right == new); 314 if(parent->left == old) parent->left = new; 315 if(parent->right == old) parent->right = new; 316 } 317 /** Update parent pointer of a node 'child' */ 318 static void change_child_ptr(rbnode_t* child, rbnode_t* old, rbnode_t* new) 319 { 320 if(child == RBTREE_NULL) return; 321 log_assert(child->parent == old || child->parent == new); 322 if(child->parent == old) child->parent = new; 323 } 324 325 rbnode_t* 326 rbtree_delete(rbtree_t *rbtree, const void *key) 327 { 328 rbnode_t *to_delete; 329 rbnode_t *child; 330 if((to_delete = rbtree_search(rbtree, key)) == 0) return 0; 331 rbtree->count--; 332 333 /* make sure we have at most one non-leaf child */ 334 if(to_delete->left != RBTREE_NULL && to_delete->right != RBTREE_NULL) 335 { 336 /* swap with smallest from right subtree (or largest from left) */ 337 rbnode_t *smright = to_delete->right; 338 while(smright->left != RBTREE_NULL) 339 smright = smright->left; 340 /* swap the smright and to_delete elements in the tree, 341 * but the rbnode_t is first part of user data struct 342 * so cannot just swap the keys and data pointers. Instead 343 * readjust the pointers left,right,parent */ 344 345 /* swap colors - colors are tied to the position in the tree */ 346 swap_int8(&to_delete->color, &smright->color); 347 348 /* swap child pointers in parents of smright/to_delete */ 349 change_parent_ptr(rbtree, to_delete->parent, to_delete, smright); 350 if(to_delete->right != smright) 351 change_parent_ptr(rbtree, smright->parent, smright, to_delete); 352 353 /* swap parent pointers in children of smright/to_delete */ 354 change_child_ptr(smright->left, smright, to_delete); 355 change_child_ptr(smright->left, smright, to_delete); 356 change_child_ptr(smright->right, smright, to_delete); 357 change_child_ptr(smright->right, smright, to_delete); 358 change_child_ptr(to_delete->left, to_delete, smright); 359 if(to_delete->right != smright) 360 change_child_ptr(to_delete->right, to_delete, smright); 361 if(to_delete->right == smright) 362 { 363 /* set up so after swap they work */ 364 to_delete->right = to_delete; 365 smright->parent = smright; 366 } 367 368 /* swap pointers in to_delete/smright nodes */ 369 swap_np(&to_delete->parent, &smright->parent); 370 swap_np(&to_delete->left, &smright->left); 371 swap_np(&to_delete->right, &smright->right); 372 373 /* now delete to_delete (which is at the location where the smright previously was) */ 374 } 375 log_assert(to_delete->left == RBTREE_NULL || to_delete->right == RBTREE_NULL); 376 377 if(to_delete->left != RBTREE_NULL) child = to_delete->left; 378 else child = to_delete->right; 379 380 /* unlink to_delete from the tree, replace to_delete with child */ 381 change_parent_ptr(rbtree, to_delete->parent, to_delete, child); 382 change_child_ptr(child, to_delete, to_delete->parent); 383 384 if(to_delete->color == RED) 385 { 386 /* if node is red then the child (black) can be swapped in */ 387 } 388 else if(child->color == RED) 389 { 390 /* change child to BLACK, removing a RED node is no problem */ 391 if(child!=RBTREE_NULL) child->color = BLACK; 392 } 393 else rbtree_delete_fixup(rbtree, child, to_delete->parent); 394 395 /* unlink completely */ 396 to_delete->parent = RBTREE_NULL; 397 to_delete->left = RBTREE_NULL; 398 to_delete->right = RBTREE_NULL; 399 to_delete->color = BLACK; 400 return to_delete; 401 } 402 403 static void rbtree_delete_fixup(rbtree_t* rbtree, rbnode_t* child, rbnode_t* child_parent) 404 { 405 rbnode_t* sibling; 406 int go_up = 1; 407 408 /* determine sibling to the node that is one-black short */ 409 if(child_parent->right == child) sibling = child_parent->left; 410 else sibling = child_parent->right; 411 412 while(go_up) 413 { 414 if(child_parent == RBTREE_NULL) 415 { 416 /* removed parent==black from root, every path, so ok */ 417 return; 418 } 419 420 if(sibling->color == RED) 421 { /* rotate to get a black sibling */ 422 child_parent->color = RED; 423 sibling->color = BLACK; 424 if(child_parent->right == child) 425 rbtree_rotate_right(rbtree, child_parent); 426 else rbtree_rotate_left(rbtree, child_parent); 427 /* new sibling after rotation */ 428 if(child_parent->right == child) sibling = child_parent->left; 429 else sibling = child_parent->right; 430 } 431 432 if(child_parent->color == BLACK 433 && sibling->color == BLACK 434 && sibling->left->color == BLACK 435 && sibling->right->color == BLACK) 436 { /* fixup local with recolor of sibling */ 437 if(sibling != RBTREE_NULL) 438 sibling->color = RED; 439 440 child = child_parent; 441 child_parent = child_parent->parent; 442 /* prepare to go up, new sibling */ 443 if(child_parent->right == child) sibling = child_parent->left; 444 else sibling = child_parent->right; 445 } 446 else go_up = 0; 447 } 448 449 if(child_parent->color == RED 450 && sibling->color == BLACK 451 && sibling->left->color == BLACK 452 && sibling->right->color == BLACK) 453 { 454 /* move red to sibling to rebalance */ 455 if(sibling != RBTREE_NULL) 456 sibling->color = RED; 457 child_parent->color = BLACK; 458 return; 459 } 460 log_assert(sibling != RBTREE_NULL); 461 462 /* get a new sibling, by rotating at sibling. See which child 463 of sibling is red */ 464 if(child_parent->right == child 465 && sibling->color == BLACK 466 && sibling->right->color == RED 467 && sibling->left->color == BLACK) 468 { 469 sibling->color = RED; 470 sibling->right->color = BLACK; 471 rbtree_rotate_left(rbtree, sibling); 472 /* new sibling after rotation */ 473 if(child_parent->right == child) sibling = child_parent->left; 474 else sibling = child_parent->right; 475 } 476 else if(child_parent->left == child 477 && sibling->color == BLACK 478 && sibling->left->color == RED 479 && sibling->right->color == BLACK) 480 { 481 sibling->color = RED; 482 sibling->left->color = BLACK; 483 rbtree_rotate_right(rbtree, sibling); 484 /* new sibling after rotation */ 485 if(child_parent->right == child) sibling = child_parent->left; 486 else sibling = child_parent->right; 487 } 488 489 /* now we have a black sibling with a red child. rotate and exchange colors. */ 490 sibling->color = child_parent->color; 491 child_parent->color = BLACK; 492 if(child_parent->right == child) 493 { 494 log_assert(sibling->left->color == RED); 495 sibling->left->color = BLACK; 496 rbtree_rotate_right(rbtree, child_parent); 497 } 498 else 499 { 500 log_assert(sibling->right->color == RED); 501 sibling->right->color = BLACK; 502 rbtree_rotate_left(rbtree, child_parent); 503 } 504 } 505 506 int 507 rbtree_find_less_equal(rbtree_t *rbtree, const void *key, rbnode_t **result) 508 { 509 int r; 510 rbnode_t *node; 511 512 log_assert(result); 513 514 /* We start at root... */ 515 node = rbtree->root; 516 517 *result = NULL; 518 fptr_ok(fptr_whitelist_rbtree_cmp(rbtree->cmp)); 519 520 /* While there are children... */ 521 while (node != RBTREE_NULL) { 522 r = rbtree->cmp(key, node->key); 523 if (r == 0) { 524 /* Exact match */ 525 *result = node; 526 return 1; 527 } 528 if (r < 0) { 529 node = node->left; 530 } else { 531 /* Temporary match */ 532 *result = node; 533 node = node->right; 534 } 535 } 536 return 0; 537 } 538 539 /* 540 * Finds the first element in the red black tree 541 * 542 */ 543 rbnode_t * 544 rbtree_first (rbtree_t *rbtree) 545 { 546 rbnode_t *node; 547 548 for (node = rbtree->root; node->left != RBTREE_NULL; node = node->left); 549 return node; 550 } 551 552 rbnode_t * 553 rbtree_last (rbtree_t *rbtree) 554 { 555 rbnode_t *node; 556 557 for (node = rbtree->root; node->right != RBTREE_NULL; node = node->right); 558 return node; 559 } 560 561 /* 562 * Returns the next node... 563 * 564 */ 565 rbnode_t * 566 rbtree_next (rbnode_t *node) 567 { 568 rbnode_t *parent; 569 570 if (node->right != RBTREE_NULL) { 571 /* One right, then keep on going left... */ 572 for (node = node->right; node->left != RBTREE_NULL; node = node->left); 573 } else { 574 parent = node->parent; 575 while (parent != RBTREE_NULL && node == parent->right) { 576 node = parent; 577 parent = parent->parent; 578 } 579 node = parent; 580 } 581 return node; 582 } 583 584 rbnode_t * 585 rbtree_previous(rbnode_t *node) 586 { 587 rbnode_t *parent; 588 589 if (node->left != RBTREE_NULL) { 590 /* One left, then keep on going right... */ 591 for (node = node->left; node->right != RBTREE_NULL; node = node->right); 592 } else { 593 parent = node->parent; 594 while (parent != RBTREE_NULL && node == parent->left) { 595 node = parent; 596 parent = parent->parent; 597 } 598 node = parent; 599 } 600 return node; 601 } 602 603 /** recursive descent traverse */ 604 static void 605 traverse_post(void (*func)(rbnode_t*, void*), void* arg, rbnode_t* node) 606 { 607 if(!node || node == RBTREE_NULL) 608 return; 609 /* recurse */ 610 traverse_post(func, arg, node->left); 611 traverse_post(func, arg, node->right); 612 /* call user func */ 613 (*func)(node, arg); 614 } 615 616 void 617 traverse_postorder(rbtree_t* tree, void (*func)(rbnode_t*, void*), void* arg) 618 { 619 traverse_post(func, arg, tree->root); 620 } 621