1 /* 2 * This file is part of UBIFS. 3 * 4 * Copyright (C) 2006-2008 Nokia Corporation. 5 * 6 * SPDX-License-Identifier: GPL-2.0+ 7 * 8 * Authors: Adrian Hunter 9 * Artem Bityutskiy (Битюцкий Артём) 10 */ 11 12 /* 13 * This file implements TNC (Tree Node Cache) which caches indexing nodes of 14 * the UBIFS B-tree. 15 * 16 * At the moment the locking rules of the TNC tree are quite simple and 17 * straightforward. We just have a mutex and lock it when we traverse the 18 * tree. If a znode is not in memory, we read it from flash while still having 19 * the mutex locked. 20 */ 21 22 #ifndef __UBOOT__ 23 #include <linux/crc32.h> 24 #include <linux/slab.h> 25 #else 26 #include <linux/compat.h> 27 #include <linux/err.h> 28 #include <linux/stat.h> 29 #endif 30 #include "ubifs.h" 31 32 /* 33 * Returned codes of 'matches_name()' and 'fallible_matches_name()' functions. 34 * @NAME_LESS: name corresponding to the first argument is less than second 35 * @NAME_MATCHES: names match 36 * @NAME_GREATER: name corresponding to the second argument is greater than 37 * first 38 * @NOT_ON_MEDIA: node referred by zbranch does not exist on the media 39 * 40 * These constants were introduce to improve readability. 41 */ 42 enum { 43 NAME_LESS = 0, 44 NAME_MATCHES = 1, 45 NAME_GREATER = 2, 46 NOT_ON_MEDIA = 3, 47 }; 48 49 /** 50 * insert_old_idx - record an index node obsoleted since the last commit start. 51 * @c: UBIFS file-system description object 52 * @lnum: LEB number of obsoleted index node 53 * @offs: offset of obsoleted index node 54 * 55 * Returns %0 on success, and a negative error code on failure. 56 * 57 * For recovery, there must always be a complete intact version of the index on 58 * flash at all times. That is called the "old index". It is the index as at the 59 * time of the last successful commit. Many of the index nodes in the old index 60 * may be dirty, but they must not be erased until the next successful commit 61 * (at which point that index becomes the old index). 62 * 63 * That means that the garbage collection and the in-the-gaps method of 64 * committing must be able to determine if an index node is in the old index. 65 * Most of the old index nodes can be found by looking up the TNC using the 66 * 'lookup_znode()' function. However, some of the old index nodes may have 67 * been deleted from the current index or may have been changed so much that 68 * they cannot be easily found. In those cases, an entry is added to an RB-tree. 69 * That is what this function does. The RB-tree is ordered by LEB number and 70 * offset because they uniquely identify the old index node. 71 */ 72 static int insert_old_idx(struct ubifs_info *c, int lnum, int offs) 73 { 74 struct ubifs_old_idx *old_idx, *o; 75 struct rb_node **p, *parent = NULL; 76 77 old_idx = kmalloc(sizeof(struct ubifs_old_idx), GFP_NOFS); 78 if (unlikely(!old_idx)) 79 return -ENOMEM; 80 old_idx->lnum = lnum; 81 old_idx->offs = offs; 82 83 p = &c->old_idx.rb_node; 84 while (*p) { 85 parent = *p; 86 o = rb_entry(parent, struct ubifs_old_idx, rb); 87 if (lnum < o->lnum) 88 p = &(*p)->rb_left; 89 else if (lnum > o->lnum) 90 p = &(*p)->rb_right; 91 else if (offs < o->offs) 92 p = &(*p)->rb_left; 93 else if (offs > o->offs) 94 p = &(*p)->rb_right; 95 else { 96 ubifs_err("old idx added twice!"); 97 kfree(old_idx); 98 return 0; 99 } 100 } 101 rb_link_node(&old_idx->rb, parent, p); 102 rb_insert_color(&old_idx->rb, &c->old_idx); 103 return 0; 104 } 105 106 /** 107 * insert_old_idx_znode - record a znode obsoleted since last commit start. 108 * @c: UBIFS file-system description object 109 * @znode: znode of obsoleted index node 110 * 111 * Returns %0 on success, and a negative error code on failure. 112 */ 113 int insert_old_idx_znode(struct ubifs_info *c, struct ubifs_znode *znode) 114 { 115 if (znode->parent) { 116 struct ubifs_zbranch *zbr; 117 118 zbr = &znode->parent->zbranch[znode->iip]; 119 if (zbr->len) 120 return insert_old_idx(c, zbr->lnum, zbr->offs); 121 } else 122 if (c->zroot.len) 123 return insert_old_idx(c, c->zroot.lnum, 124 c->zroot.offs); 125 return 0; 126 } 127 128 /** 129 * ins_clr_old_idx_znode - record a znode obsoleted since last commit start. 130 * @c: UBIFS file-system description object 131 * @znode: znode of obsoleted index node 132 * 133 * Returns %0 on success, and a negative error code on failure. 134 */ 135 static int ins_clr_old_idx_znode(struct ubifs_info *c, 136 struct ubifs_znode *znode) 137 { 138 int err; 139 140 if (znode->parent) { 141 struct ubifs_zbranch *zbr; 142 143 zbr = &znode->parent->zbranch[znode->iip]; 144 if (zbr->len) { 145 err = insert_old_idx(c, zbr->lnum, zbr->offs); 146 if (err) 147 return err; 148 zbr->lnum = 0; 149 zbr->offs = 0; 150 zbr->len = 0; 151 } 152 } else 153 if (c->zroot.len) { 154 err = insert_old_idx(c, c->zroot.lnum, c->zroot.offs); 155 if (err) 156 return err; 157 c->zroot.lnum = 0; 158 c->zroot.offs = 0; 159 c->zroot.len = 0; 160 } 161 return 0; 162 } 163 164 /** 165 * destroy_old_idx - destroy the old_idx RB-tree. 166 * @c: UBIFS file-system description object 167 * 168 * During start commit, the old_idx RB-tree is used to avoid overwriting index 169 * nodes that were in the index last commit but have since been deleted. This 170 * is necessary for recovery i.e. the old index must be kept intact until the 171 * new index is successfully written. The old-idx RB-tree is used for the 172 * in-the-gaps method of writing index nodes and is destroyed every commit. 173 */ 174 void destroy_old_idx(struct ubifs_info *c) 175 { 176 struct ubifs_old_idx *old_idx, *n; 177 178 rbtree_postorder_for_each_entry_safe(old_idx, n, &c->old_idx, rb) 179 kfree(old_idx); 180 181 c->old_idx = RB_ROOT; 182 } 183 184 /** 185 * copy_znode - copy a dirty znode. 186 * @c: UBIFS file-system description object 187 * @znode: znode to copy 188 * 189 * A dirty znode being committed may not be changed, so it is copied. 190 */ 191 static struct ubifs_znode *copy_znode(struct ubifs_info *c, 192 struct ubifs_znode *znode) 193 { 194 struct ubifs_znode *zn; 195 196 zn = kmalloc(c->max_znode_sz, GFP_NOFS); 197 if (unlikely(!zn)) 198 return ERR_PTR(-ENOMEM); 199 200 memcpy(zn, znode, c->max_znode_sz); 201 zn->cnext = NULL; 202 __set_bit(DIRTY_ZNODE, &zn->flags); 203 __clear_bit(COW_ZNODE, &zn->flags); 204 205 ubifs_assert(!ubifs_zn_obsolete(znode)); 206 __set_bit(OBSOLETE_ZNODE, &znode->flags); 207 208 if (znode->level != 0) { 209 int i; 210 const int n = zn->child_cnt; 211 212 /* The children now have new parent */ 213 for (i = 0; i < n; i++) { 214 struct ubifs_zbranch *zbr = &zn->zbranch[i]; 215 216 if (zbr->znode) 217 zbr->znode->parent = zn; 218 } 219 } 220 221 atomic_long_inc(&c->dirty_zn_cnt); 222 return zn; 223 } 224 225 /** 226 * add_idx_dirt - add dirt due to a dirty znode. 227 * @c: UBIFS file-system description object 228 * @lnum: LEB number of index node 229 * @dirt: size of index node 230 * 231 * This function updates lprops dirty space and the new size of the index. 232 */ 233 static int add_idx_dirt(struct ubifs_info *c, int lnum, int dirt) 234 { 235 c->calc_idx_sz -= ALIGN(dirt, 8); 236 return ubifs_add_dirt(c, lnum, dirt); 237 } 238 239 /** 240 * dirty_cow_znode - ensure a znode is not being committed. 241 * @c: UBIFS file-system description object 242 * @zbr: branch of znode to check 243 * 244 * Returns dirtied znode on success or negative error code on failure. 245 */ 246 static struct ubifs_znode *dirty_cow_znode(struct ubifs_info *c, 247 struct ubifs_zbranch *zbr) 248 { 249 struct ubifs_znode *znode = zbr->znode; 250 struct ubifs_znode *zn; 251 int err; 252 253 if (!ubifs_zn_cow(znode)) { 254 /* znode is not being committed */ 255 if (!test_and_set_bit(DIRTY_ZNODE, &znode->flags)) { 256 atomic_long_inc(&c->dirty_zn_cnt); 257 atomic_long_dec(&c->clean_zn_cnt); 258 atomic_long_dec(&ubifs_clean_zn_cnt); 259 err = add_idx_dirt(c, zbr->lnum, zbr->len); 260 if (unlikely(err)) 261 return ERR_PTR(err); 262 } 263 return znode; 264 } 265 266 zn = copy_znode(c, znode); 267 if (IS_ERR(zn)) 268 return zn; 269 270 if (zbr->len) { 271 err = insert_old_idx(c, zbr->lnum, zbr->offs); 272 if (unlikely(err)) 273 return ERR_PTR(err); 274 err = add_idx_dirt(c, zbr->lnum, zbr->len); 275 } else 276 err = 0; 277 278 zbr->znode = zn; 279 zbr->lnum = 0; 280 zbr->offs = 0; 281 zbr->len = 0; 282 283 if (unlikely(err)) 284 return ERR_PTR(err); 285 return zn; 286 } 287 288 /** 289 * lnc_add - add a leaf node to the leaf node cache. 290 * @c: UBIFS file-system description object 291 * @zbr: zbranch of leaf node 292 * @node: leaf node 293 * 294 * Leaf nodes are non-index nodes directory entry nodes or data nodes. The 295 * purpose of the leaf node cache is to save re-reading the same leaf node over 296 * and over again. Most things are cached by VFS, however the file system must 297 * cache directory entries for readdir and for resolving hash collisions. The 298 * present implementation of the leaf node cache is extremely simple, and 299 * allows for error returns that are not used but that may be needed if a more 300 * complex implementation is created. 301 * 302 * Note, this function does not add the @node object to LNC directly, but 303 * allocates a copy of the object and adds the copy to LNC. The reason for this 304 * is that @node has been allocated outside of the TNC subsystem and will be 305 * used with @c->tnc_mutex unlock upon return from the TNC subsystem. But LNC 306 * may be changed at any time, e.g. freed by the shrinker. 307 */ 308 static int lnc_add(struct ubifs_info *c, struct ubifs_zbranch *zbr, 309 const void *node) 310 { 311 int err; 312 void *lnc_node; 313 const struct ubifs_dent_node *dent = node; 314 315 ubifs_assert(!zbr->leaf); 316 ubifs_assert(zbr->len != 0); 317 ubifs_assert(is_hash_key(c, &zbr->key)); 318 319 err = ubifs_validate_entry(c, dent); 320 if (err) { 321 dump_stack(); 322 ubifs_dump_node(c, dent); 323 return err; 324 } 325 326 lnc_node = kmemdup(node, zbr->len, GFP_NOFS); 327 if (!lnc_node) 328 /* We don't have to have the cache, so no error */ 329 return 0; 330 331 zbr->leaf = lnc_node; 332 return 0; 333 } 334 335 /** 336 * lnc_add_directly - add a leaf node to the leaf-node-cache. 337 * @c: UBIFS file-system description object 338 * @zbr: zbranch of leaf node 339 * @node: leaf node 340 * 341 * This function is similar to 'lnc_add()', but it does not create a copy of 342 * @node but inserts @node to TNC directly. 343 */ 344 static int lnc_add_directly(struct ubifs_info *c, struct ubifs_zbranch *zbr, 345 void *node) 346 { 347 int err; 348 349 ubifs_assert(!zbr->leaf); 350 ubifs_assert(zbr->len != 0); 351 352 err = ubifs_validate_entry(c, node); 353 if (err) { 354 dump_stack(); 355 ubifs_dump_node(c, node); 356 return err; 357 } 358 359 zbr->leaf = node; 360 return 0; 361 } 362 363 /** 364 * lnc_free - remove a leaf node from the leaf node cache. 365 * @zbr: zbranch of leaf node 366 * @node: leaf node 367 */ 368 static void lnc_free(struct ubifs_zbranch *zbr) 369 { 370 if (!zbr->leaf) 371 return; 372 kfree(zbr->leaf); 373 zbr->leaf = NULL; 374 } 375 376 /** 377 * tnc_read_node_nm - read a "hashed" leaf node. 378 * @c: UBIFS file-system description object 379 * @zbr: key and position of the node 380 * @node: node is returned here 381 * 382 * This function reads a "hashed" node defined by @zbr from the leaf node cache 383 * (in it is there) or from the hash media, in which case the node is also 384 * added to LNC. Returns zero in case of success or a negative negative error 385 * code in case of failure. 386 */ 387 static int tnc_read_node_nm(struct ubifs_info *c, struct ubifs_zbranch *zbr, 388 void *node) 389 { 390 int err; 391 392 ubifs_assert(is_hash_key(c, &zbr->key)); 393 394 if (zbr->leaf) { 395 /* Read from the leaf node cache */ 396 ubifs_assert(zbr->len != 0); 397 memcpy(node, zbr->leaf, zbr->len); 398 return 0; 399 } 400 401 err = ubifs_tnc_read_node(c, zbr, node); 402 if (err) 403 return err; 404 405 /* Add the node to the leaf node cache */ 406 err = lnc_add(c, zbr, node); 407 return err; 408 } 409 410 /** 411 * try_read_node - read a node if it is a node. 412 * @c: UBIFS file-system description object 413 * @buf: buffer to read to 414 * @type: node type 415 * @len: node length (not aligned) 416 * @lnum: LEB number of node to read 417 * @offs: offset of node to read 418 * 419 * This function tries to read a node of known type and length, checks it and 420 * stores it in @buf. This function returns %1 if a node is present and %0 if 421 * a node is not present. A negative error code is returned for I/O errors. 422 * This function performs that same function as ubifs_read_node except that 423 * it does not require that there is actually a node present and instead 424 * the return code indicates if a node was read. 425 * 426 * Note, this function does not check CRC of data nodes if @c->no_chk_data_crc 427 * is true (it is controlled by corresponding mount option). However, if 428 * @c->mounting or @c->remounting_rw is true (we are mounting or re-mounting to 429 * R/W mode), @c->no_chk_data_crc is ignored and CRC is checked. This is 430 * because during mounting or re-mounting from R/O mode to R/W mode we may read 431 * journal nodes (when replying the journal or doing the recovery) and the 432 * journal nodes may potentially be corrupted, so checking is required. 433 */ 434 static int try_read_node(const struct ubifs_info *c, void *buf, int type, 435 int len, int lnum, int offs) 436 { 437 int err, node_len; 438 struct ubifs_ch *ch = buf; 439 uint32_t crc, node_crc; 440 441 dbg_io("LEB %d:%d, %s, length %d", lnum, offs, dbg_ntype(type), len); 442 443 err = ubifs_leb_read(c, lnum, buf, offs, len, 1); 444 if (err) { 445 ubifs_err("cannot read node type %d from LEB %d:%d, error %d", 446 type, lnum, offs, err); 447 return err; 448 } 449 450 if (le32_to_cpu(ch->magic) != UBIFS_NODE_MAGIC) 451 return 0; 452 453 if (ch->node_type != type) 454 return 0; 455 456 node_len = le32_to_cpu(ch->len); 457 if (node_len != len) 458 return 0; 459 460 if (type == UBIFS_DATA_NODE && c->no_chk_data_crc && !c->mounting && 461 !c->remounting_rw) 462 return 1; 463 464 crc = crc32(UBIFS_CRC32_INIT, buf + 8, node_len - 8); 465 node_crc = le32_to_cpu(ch->crc); 466 if (crc != node_crc) 467 return 0; 468 469 return 1; 470 } 471 472 /** 473 * fallible_read_node - try to read a leaf node. 474 * @c: UBIFS file-system description object 475 * @key: key of node to read 476 * @zbr: position of node 477 * @node: node returned 478 * 479 * This function tries to read a node and returns %1 if the node is read, %0 480 * if the node is not present, and a negative error code in the case of error. 481 */ 482 static int fallible_read_node(struct ubifs_info *c, const union ubifs_key *key, 483 struct ubifs_zbranch *zbr, void *node) 484 { 485 int ret; 486 487 dbg_tnck(key, "LEB %d:%d, key ", zbr->lnum, zbr->offs); 488 489 ret = try_read_node(c, node, key_type(c, key), zbr->len, zbr->lnum, 490 zbr->offs); 491 if (ret == 1) { 492 union ubifs_key node_key; 493 struct ubifs_dent_node *dent = node; 494 495 /* All nodes have key in the same place */ 496 key_read(c, &dent->key, &node_key); 497 if (keys_cmp(c, key, &node_key) != 0) 498 ret = 0; 499 } 500 if (ret == 0 && c->replaying) 501 dbg_mntk(key, "dangling branch LEB %d:%d len %d, key ", 502 zbr->lnum, zbr->offs, zbr->len); 503 return ret; 504 } 505 506 /** 507 * matches_name - determine if a direntry or xattr entry matches a given name. 508 * @c: UBIFS file-system description object 509 * @zbr: zbranch of dent 510 * @nm: name to match 511 * 512 * This function checks if xentry/direntry referred by zbranch @zbr matches name 513 * @nm. Returns %NAME_MATCHES if it does, %NAME_LESS if the name referred by 514 * @zbr is less than @nm, and %NAME_GREATER if it is greater than @nm. In case 515 * of failure, a negative error code is returned. 516 */ 517 static int matches_name(struct ubifs_info *c, struct ubifs_zbranch *zbr, 518 const struct qstr *nm) 519 { 520 struct ubifs_dent_node *dent; 521 int nlen, err; 522 523 /* If possible, match against the dent in the leaf node cache */ 524 if (!zbr->leaf) { 525 dent = kmalloc(zbr->len, GFP_NOFS); 526 if (!dent) 527 return -ENOMEM; 528 529 err = ubifs_tnc_read_node(c, zbr, dent); 530 if (err) 531 goto out_free; 532 533 /* Add the node to the leaf node cache */ 534 err = lnc_add_directly(c, zbr, dent); 535 if (err) 536 goto out_free; 537 } else 538 dent = zbr->leaf; 539 540 nlen = le16_to_cpu(dent->nlen); 541 err = memcmp(dent->name, nm->name, min_t(int, nlen, nm->len)); 542 if (err == 0) { 543 if (nlen == nm->len) 544 return NAME_MATCHES; 545 else if (nlen < nm->len) 546 return NAME_LESS; 547 else 548 return NAME_GREATER; 549 } else if (err < 0) 550 return NAME_LESS; 551 else 552 return NAME_GREATER; 553 554 out_free: 555 kfree(dent); 556 return err; 557 } 558 559 /** 560 * get_znode - get a TNC znode that may not be loaded yet. 561 * @c: UBIFS file-system description object 562 * @znode: parent znode 563 * @n: znode branch slot number 564 * 565 * This function returns the znode or a negative error code. 566 */ 567 static struct ubifs_znode *get_znode(struct ubifs_info *c, 568 struct ubifs_znode *znode, int n) 569 { 570 struct ubifs_zbranch *zbr; 571 572 zbr = &znode->zbranch[n]; 573 if (zbr->znode) 574 znode = zbr->znode; 575 else 576 znode = ubifs_load_znode(c, zbr, znode, n); 577 return znode; 578 } 579 580 /** 581 * tnc_next - find next TNC entry. 582 * @c: UBIFS file-system description object 583 * @zn: znode is passed and returned here 584 * @n: znode branch slot number is passed and returned here 585 * 586 * This function returns %0 if the next TNC entry is found, %-ENOENT if there is 587 * no next entry, or a negative error code otherwise. 588 */ 589 static int tnc_next(struct ubifs_info *c, struct ubifs_znode **zn, int *n) 590 { 591 struct ubifs_znode *znode = *zn; 592 int nn = *n; 593 594 nn += 1; 595 if (nn < znode->child_cnt) { 596 *n = nn; 597 return 0; 598 } 599 while (1) { 600 struct ubifs_znode *zp; 601 602 zp = znode->parent; 603 if (!zp) 604 return -ENOENT; 605 nn = znode->iip + 1; 606 znode = zp; 607 if (nn < znode->child_cnt) { 608 znode = get_znode(c, znode, nn); 609 if (IS_ERR(znode)) 610 return PTR_ERR(znode); 611 while (znode->level != 0) { 612 znode = get_znode(c, znode, 0); 613 if (IS_ERR(znode)) 614 return PTR_ERR(znode); 615 } 616 nn = 0; 617 break; 618 } 619 } 620 *zn = znode; 621 *n = nn; 622 return 0; 623 } 624 625 /** 626 * tnc_prev - find previous TNC entry. 627 * @c: UBIFS file-system description object 628 * @zn: znode is returned here 629 * @n: znode branch slot number is passed and returned here 630 * 631 * This function returns %0 if the previous TNC entry is found, %-ENOENT if 632 * there is no next entry, or a negative error code otherwise. 633 */ 634 static int tnc_prev(struct ubifs_info *c, struct ubifs_znode **zn, int *n) 635 { 636 struct ubifs_znode *znode = *zn; 637 int nn = *n; 638 639 if (nn > 0) { 640 *n = nn - 1; 641 return 0; 642 } 643 while (1) { 644 struct ubifs_znode *zp; 645 646 zp = znode->parent; 647 if (!zp) 648 return -ENOENT; 649 nn = znode->iip - 1; 650 znode = zp; 651 if (nn >= 0) { 652 znode = get_znode(c, znode, nn); 653 if (IS_ERR(znode)) 654 return PTR_ERR(znode); 655 while (znode->level != 0) { 656 nn = znode->child_cnt - 1; 657 znode = get_znode(c, znode, nn); 658 if (IS_ERR(znode)) 659 return PTR_ERR(znode); 660 } 661 nn = znode->child_cnt - 1; 662 break; 663 } 664 } 665 *zn = znode; 666 *n = nn; 667 return 0; 668 } 669 670 /** 671 * resolve_collision - resolve a collision. 672 * @c: UBIFS file-system description object 673 * @key: key of a directory or extended attribute entry 674 * @zn: znode is returned here 675 * @n: zbranch number is passed and returned here 676 * @nm: name of the entry 677 * 678 * This function is called for "hashed" keys to make sure that the found key 679 * really corresponds to the looked up node (directory or extended attribute 680 * entry). It returns %1 and sets @zn and @n if the collision is resolved. 681 * %0 is returned if @nm is not found and @zn and @n are set to the previous 682 * entry, i.e. to the entry after which @nm could follow if it were in TNC. 683 * This means that @n may be set to %-1 if the leftmost key in @zn is the 684 * previous one. A negative error code is returned on failures. 685 */ 686 static int resolve_collision(struct ubifs_info *c, const union ubifs_key *key, 687 struct ubifs_znode **zn, int *n, 688 const struct qstr *nm) 689 { 690 int err; 691 692 err = matches_name(c, &(*zn)->zbranch[*n], nm); 693 if (unlikely(err < 0)) 694 return err; 695 if (err == NAME_MATCHES) 696 return 1; 697 698 if (err == NAME_GREATER) { 699 /* Look left */ 700 while (1) { 701 err = tnc_prev(c, zn, n); 702 if (err == -ENOENT) { 703 ubifs_assert(*n == 0); 704 *n = -1; 705 return 0; 706 } 707 if (err < 0) 708 return err; 709 if (keys_cmp(c, &(*zn)->zbranch[*n].key, key)) { 710 /* 711 * We have found the branch after which we would 712 * like to insert, but inserting in this znode 713 * may still be wrong. Consider the following 3 714 * znodes, in the case where we are resolving a 715 * collision with Key2. 716 * 717 * znode zp 718 * ---------------------- 719 * level 1 | Key0 | Key1 | 720 * ----------------------- 721 * | | 722 * znode za | | znode zb 723 * ------------ ------------ 724 * level 0 | Key0 | | Key2 | 725 * ------------ ------------ 726 * 727 * The lookup finds Key2 in znode zb. Lets say 728 * there is no match and the name is greater so 729 * we look left. When we find Key0, we end up 730 * here. If we return now, we will insert into 731 * znode za at slot n = 1. But that is invalid 732 * according to the parent's keys. Key2 must 733 * be inserted into znode zb. 734 * 735 * Note, this problem is not relevant for the 736 * case when we go right, because 737 * 'tnc_insert()' would correct the parent key. 738 */ 739 if (*n == (*zn)->child_cnt - 1) { 740 err = tnc_next(c, zn, n); 741 if (err) { 742 /* Should be impossible */ 743 ubifs_assert(0); 744 if (err == -ENOENT) 745 err = -EINVAL; 746 return err; 747 } 748 ubifs_assert(*n == 0); 749 *n = -1; 750 } 751 return 0; 752 } 753 err = matches_name(c, &(*zn)->zbranch[*n], nm); 754 if (err < 0) 755 return err; 756 if (err == NAME_LESS) 757 return 0; 758 if (err == NAME_MATCHES) 759 return 1; 760 ubifs_assert(err == NAME_GREATER); 761 } 762 } else { 763 int nn = *n; 764 struct ubifs_znode *znode = *zn; 765 766 /* Look right */ 767 while (1) { 768 err = tnc_next(c, &znode, &nn); 769 if (err == -ENOENT) 770 return 0; 771 if (err < 0) 772 return err; 773 if (keys_cmp(c, &znode->zbranch[nn].key, key)) 774 return 0; 775 err = matches_name(c, &znode->zbranch[nn], nm); 776 if (err < 0) 777 return err; 778 if (err == NAME_GREATER) 779 return 0; 780 *zn = znode; 781 *n = nn; 782 if (err == NAME_MATCHES) 783 return 1; 784 ubifs_assert(err == NAME_LESS); 785 } 786 } 787 } 788 789 /** 790 * fallible_matches_name - determine if a dent matches a given name. 791 * @c: UBIFS file-system description object 792 * @zbr: zbranch of dent 793 * @nm: name to match 794 * 795 * This is a "fallible" version of 'matches_name()' function which does not 796 * panic if the direntry/xentry referred by @zbr does not exist on the media. 797 * 798 * This function checks if xentry/direntry referred by zbranch @zbr matches name 799 * @nm. Returns %NAME_MATCHES it does, %NAME_LESS if the name referred by @zbr 800 * is less than @nm, %NAME_GREATER if it is greater than @nm, and @NOT_ON_MEDIA 801 * if xentry/direntry referred by @zbr does not exist on the media. A negative 802 * error code is returned in case of failure. 803 */ 804 static int fallible_matches_name(struct ubifs_info *c, 805 struct ubifs_zbranch *zbr, 806 const struct qstr *nm) 807 { 808 struct ubifs_dent_node *dent; 809 int nlen, err; 810 811 /* If possible, match against the dent in the leaf node cache */ 812 if (!zbr->leaf) { 813 dent = kmalloc(zbr->len, GFP_NOFS); 814 if (!dent) 815 return -ENOMEM; 816 817 err = fallible_read_node(c, &zbr->key, zbr, dent); 818 if (err < 0) 819 goto out_free; 820 if (err == 0) { 821 /* The node was not present */ 822 err = NOT_ON_MEDIA; 823 goto out_free; 824 } 825 ubifs_assert(err == 1); 826 827 err = lnc_add_directly(c, zbr, dent); 828 if (err) 829 goto out_free; 830 } else 831 dent = zbr->leaf; 832 833 nlen = le16_to_cpu(dent->nlen); 834 err = memcmp(dent->name, nm->name, min_t(int, nlen, nm->len)); 835 if (err == 0) { 836 if (nlen == nm->len) 837 return NAME_MATCHES; 838 else if (nlen < nm->len) 839 return NAME_LESS; 840 else 841 return NAME_GREATER; 842 } else if (err < 0) 843 return NAME_LESS; 844 else 845 return NAME_GREATER; 846 847 out_free: 848 kfree(dent); 849 return err; 850 } 851 852 /** 853 * fallible_resolve_collision - resolve a collision even if nodes are missing. 854 * @c: UBIFS file-system description object 855 * @key: key 856 * @zn: znode is returned here 857 * @n: branch number is passed and returned here 858 * @nm: name of directory entry 859 * @adding: indicates caller is adding a key to the TNC 860 * 861 * This is a "fallible" version of the 'resolve_collision()' function which 862 * does not panic if one of the nodes referred to by TNC does not exist on the 863 * media. This may happen when replaying the journal if a deleted node was 864 * Garbage-collected and the commit was not done. A branch that refers to a node 865 * that is not present is called a dangling branch. The following are the return 866 * codes for this function: 867 * o if @nm was found, %1 is returned and @zn and @n are set to the found 868 * branch; 869 * o if we are @adding and @nm was not found, %0 is returned; 870 * o if we are not @adding and @nm was not found, but a dangling branch was 871 * found, then %1 is returned and @zn and @n are set to the dangling branch; 872 * o a negative error code is returned in case of failure. 873 */ 874 static int fallible_resolve_collision(struct ubifs_info *c, 875 const union ubifs_key *key, 876 struct ubifs_znode **zn, int *n, 877 const struct qstr *nm, int adding) 878 { 879 struct ubifs_znode *o_znode = NULL, *znode = *zn; 880 int uninitialized_var(o_n), err, cmp, unsure = 0, nn = *n; 881 882 cmp = fallible_matches_name(c, &znode->zbranch[nn], nm); 883 if (unlikely(cmp < 0)) 884 return cmp; 885 if (cmp == NAME_MATCHES) 886 return 1; 887 if (cmp == NOT_ON_MEDIA) { 888 o_znode = znode; 889 o_n = nn; 890 /* 891 * We are unlucky and hit a dangling branch straight away. 892 * Now we do not really know where to go to find the needed 893 * branch - to the left or to the right. Well, let's try left. 894 */ 895 unsure = 1; 896 } else if (!adding) 897 unsure = 1; /* Remove a dangling branch wherever it is */ 898 899 if (cmp == NAME_GREATER || unsure) { 900 /* Look left */ 901 while (1) { 902 err = tnc_prev(c, zn, n); 903 if (err == -ENOENT) { 904 ubifs_assert(*n == 0); 905 *n = -1; 906 break; 907 } 908 if (err < 0) 909 return err; 910 if (keys_cmp(c, &(*zn)->zbranch[*n].key, key)) { 911 /* See comments in 'resolve_collision()' */ 912 if (*n == (*zn)->child_cnt - 1) { 913 err = tnc_next(c, zn, n); 914 if (err) { 915 /* Should be impossible */ 916 ubifs_assert(0); 917 if (err == -ENOENT) 918 err = -EINVAL; 919 return err; 920 } 921 ubifs_assert(*n == 0); 922 *n = -1; 923 } 924 break; 925 } 926 err = fallible_matches_name(c, &(*zn)->zbranch[*n], nm); 927 if (err < 0) 928 return err; 929 if (err == NAME_MATCHES) 930 return 1; 931 if (err == NOT_ON_MEDIA) { 932 o_znode = *zn; 933 o_n = *n; 934 continue; 935 } 936 if (!adding) 937 continue; 938 if (err == NAME_LESS) 939 break; 940 else 941 unsure = 0; 942 } 943 } 944 945 if (cmp == NAME_LESS || unsure) { 946 /* Look right */ 947 *zn = znode; 948 *n = nn; 949 while (1) { 950 err = tnc_next(c, &znode, &nn); 951 if (err == -ENOENT) 952 break; 953 if (err < 0) 954 return err; 955 if (keys_cmp(c, &znode->zbranch[nn].key, key)) 956 break; 957 err = fallible_matches_name(c, &znode->zbranch[nn], nm); 958 if (err < 0) 959 return err; 960 if (err == NAME_GREATER) 961 break; 962 *zn = znode; 963 *n = nn; 964 if (err == NAME_MATCHES) 965 return 1; 966 if (err == NOT_ON_MEDIA) { 967 o_znode = znode; 968 o_n = nn; 969 } 970 } 971 } 972 973 /* Never match a dangling branch when adding */ 974 if (adding || !o_znode) 975 return 0; 976 977 dbg_mntk(key, "dangling match LEB %d:%d len %d key ", 978 o_znode->zbranch[o_n].lnum, o_znode->zbranch[o_n].offs, 979 o_znode->zbranch[o_n].len); 980 *zn = o_znode; 981 *n = o_n; 982 return 1; 983 } 984 985 /** 986 * matches_position - determine if a zbranch matches a given position. 987 * @zbr: zbranch of dent 988 * @lnum: LEB number of dent to match 989 * @offs: offset of dent to match 990 * 991 * This function returns %1 if @lnum:@offs matches, and %0 otherwise. 992 */ 993 static int matches_position(struct ubifs_zbranch *zbr, int lnum, int offs) 994 { 995 if (zbr->lnum == lnum && zbr->offs == offs) 996 return 1; 997 else 998 return 0; 999 } 1000 1001 /** 1002 * resolve_collision_directly - resolve a collision directly. 1003 * @c: UBIFS file-system description object 1004 * @key: key of directory entry 1005 * @zn: znode is passed and returned here 1006 * @n: zbranch number is passed and returned here 1007 * @lnum: LEB number of dent node to match 1008 * @offs: offset of dent node to match 1009 * 1010 * This function is used for "hashed" keys to make sure the found directory or 1011 * extended attribute entry node is what was looked for. It is used when the 1012 * flash address of the right node is known (@lnum:@offs) which makes it much 1013 * easier to resolve collisions (no need to read entries and match full 1014 * names). This function returns %1 and sets @zn and @n if the collision is 1015 * resolved, %0 if @lnum:@offs is not found and @zn and @n are set to the 1016 * previous directory entry. Otherwise a negative error code is returned. 1017 */ 1018 static int resolve_collision_directly(struct ubifs_info *c, 1019 const union ubifs_key *key, 1020 struct ubifs_znode **zn, int *n, 1021 int lnum, int offs) 1022 { 1023 struct ubifs_znode *znode; 1024 int nn, err; 1025 1026 znode = *zn; 1027 nn = *n; 1028 if (matches_position(&znode->zbranch[nn], lnum, offs)) 1029 return 1; 1030 1031 /* Look left */ 1032 while (1) { 1033 err = tnc_prev(c, &znode, &nn); 1034 if (err == -ENOENT) 1035 break; 1036 if (err < 0) 1037 return err; 1038 if (keys_cmp(c, &znode->zbranch[nn].key, key)) 1039 break; 1040 if (matches_position(&znode->zbranch[nn], lnum, offs)) { 1041 *zn = znode; 1042 *n = nn; 1043 return 1; 1044 } 1045 } 1046 1047 /* Look right */ 1048 znode = *zn; 1049 nn = *n; 1050 while (1) { 1051 err = tnc_next(c, &znode, &nn); 1052 if (err == -ENOENT) 1053 return 0; 1054 if (err < 0) 1055 return err; 1056 if (keys_cmp(c, &znode->zbranch[nn].key, key)) 1057 return 0; 1058 *zn = znode; 1059 *n = nn; 1060 if (matches_position(&znode->zbranch[nn], lnum, offs)) 1061 return 1; 1062 } 1063 } 1064 1065 /** 1066 * dirty_cow_bottom_up - dirty a znode and its ancestors. 1067 * @c: UBIFS file-system description object 1068 * @znode: znode to dirty 1069 * 1070 * If we do not have a unique key that resides in a znode, then we cannot 1071 * dirty that znode from the top down (i.e. by using lookup_level0_dirty) 1072 * This function records the path back to the last dirty ancestor, and then 1073 * dirties the znodes on that path. 1074 */ 1075 static struct ubifs_znode *dirty_cow_bottom_up(struct ubifs_info *c, 1076 struct ubifs_znode *znode) 1077 { 1078 struct ubifs_znode *zp; 1079 int *path = c->bottom_up_buf, p = 0; 1080 1081 ubifs_assert(c->zroot.znode); 1082 ubifs_assert(znode); 1083 if (c->zroot.znode->level > BOTTOM_UP_HEIGHT) { 1084 kfree(c->bottom_up_buf); 1085 c->bottom_up_buf = kmalloc(c->zroot.znode->level * sizeof(int), 1086 GFP_NOFS); 1087 if (!c->bottom_up_buf) 1088 return ERR_PTR(-ENOMEM); 1089 path = c->bottom_up_buf; 1090 } 1091 if (c->zroot.znode->level) { 1092 /* Go up until parent is dirty */ 1093 while (1) { 1094 int n; 1095 1096 zp = znode->parent; 1097 if (!zp) 1098 break; 1099 n = znode->iip; 1100 ubifs_assert(p < c->zroot.znode->level); 1101 path[p++] = n; 1102 if (!zp->cnext && ubifs_zn_dirty(znode)) 1103 break; 1104 znode = zp; 1105 } 1106 } 1107 1108 /* Come back down, dirtying as we go */ 1109 while (1) { 1110 struct ubifs_zbranch *zbr; 1111 1112 zp = znode->parent; 1113 if (zp) { 1114 ubifs_assert(path[p - 1] >= 0); 1115 ubifs_assert(path[p - 1] < zp->child_cnt); 1116 zbr = &zp->zbranch[path[--p]]; 1117 znode = dirty_cow_znode(c, zbr); 1118 } else { 1119 ubifs_assert(znode == c->zroot.znode); 1120 znode = dirty_cow_znode(c, &c->zroot); 1121 } 1122 if (IS_ERR(znode) || !p) 1123 break; 1124 ubifs_assert(path[p - 1] >= 0); 1125 ubifs_assert(path[p - 1] < znode->child_cnt); 1126 znode = znode->zbranch[path[p - 1]].znode; 1127 } 1128 1129 return znode; 1130 } 1131 1132 /** 1133 * ubifs_lookup_level0 - search for zero-level znode. 1134 * @c: UBIFS file-system description object 1135 * @key: key to lookup 1136 * @zn: znode is returned here 1137 * @n: znode branch slot number is returned here 1138 * 1139 * This function looks up the TNC tree and search for zero-level znode which 1140 * refers key @key. The found zero-level znode is returned in @zn. There are 3 1141 * cases: 1142 * o exact match, i.e. the found zero-level znode contains key @key, then %1 1143 * is returned and slot number of the matched branch is stored in @n; 1144 * o not exact match, which means that zero-level znode does not contain 1145 * @key, then %0 is returned and slot number of the closest branch is stored 1146 * in @n; 1147 * o @key is so small that it is even less than the lowest key of the 1148 * leftmost zero-level node, then %0 is returned and %0 is stored in @n. 1149 * 1150 * Note, when the TNC tree is traversed, some znodes may be absent, then this 1151 * function reads corresponding indexing nodes and inserts them to TNC. In 1152 * case of failure, a negative error code is returned. 1153 */ 1154 int ubifs_lookup_level0(struct ubifs_info *c, const union ubifs_key *key, 1155 struct ubifs_znode **zn, int *n) 1156 { 1157 int err, exact; 1158 struct ubifs_znode *znode; 1159 unsigned long time = get_seconds(); 1160 1161 dbg_tnck(key, "search key "); 1162 ubifs_assert(key_type(c, key) < UBIFS_INVALID_KEY); 1163 1164 znode = c->zroot.znode; 1165 if (unlikely(!znode)) { 1166 znode = ubifs_load_znode(c, &c->zroot, NULL, 0); 1167 if (IS_ERR(znode)) 1168 return PTR_ERR(znode); 1169 } 1170 1171 znode->time = time; 1172 1173 while (1) { 1174 struct ubifs_zbranch *zbr; 1175 1176 exact = ubifs_search_zbranch(c, znode, key, n); 1177 1178 if (znode->level == 0) 1179 break; 1180 1181 if (*n < 0) 1182 *n = 0; 1183 zbr = &znode->zbranch[*n]; 1184 1185 if (zbr->znode) { 1186 znode->time = time; 1187 znode = zbr->znode; 1188 continue; 1189 } 1190 1191 /* znode is not in TNC cache, load it from the media */ 1192 znode = ubifs_load_znode(c, zbr, znode, *n); 1193 if (IS_ERR(znode)) 1194 return PTR_ERR(znode); 1195 } 1196 1197 *zn = znode; 1198 if (exact || !is_hash_key(c, key) || *n != -1) { 1199 dbg_tnc("found %d, lvl %d, n %d", exact, znode->level, *n); 1200 return exact; 1201 } 1202 1203 /* 1204 * Here is a tricky place. We have not found the key and this is a 1205 * "hashed" key, which may collide. The rest of the code deals with 1206 * situations like this: 1207 * 1208 * | 3 | 5 | 1209 * / \ 1210 * | 3 | 5 | | 6 | 7 | (x) 1211 * 1212 * Or more a complex example: 1213 * 1214 * | 1 | 5 | 1215 * / \ 1216 * | 1 | 3 | | 5 | 8 | 1217 * \ / 1218 * | 5 | 5 | | 6 | 7 | (x) 1219 * 1220 * In the examples, if we are looking for key "5", we may reach nodes 1221 * marked with "(x)". In this case what we have do is to look at the 1222 * left and see if there is "5" key there. If there is, we have to 1223 * return it. 1224 * 1225 * Note, this whole situation is possible because we allow to have 1226 * elements which are equivalent to the next key in the parent in the 1227 * children of current znode. For example, this happens if we split a 1228 * znode like this: | 3 | 5 | 5 | 6 | 7 |, which results in something 1229 * like this: 1230 * | 3 | 5 | 1231 * / \ 1232 * | 3 | 5 | | 5 | 6 | 7 | 1233 * ^ 1234 * And this becomes what is at the first "picture" after key "5" marked 1235 * with "^" is removed. What could be done is we could prohibit 1236 * splitting in the middle of the colliding sequence. Also, when 1237 * removing the leftmost key, we would have to correct the key of the 1238 * parent node, which would introduce additional complications. Namely, 1239 * if we changed the leftmost key of the parent znode, the garbage 1240 * collector would be unable to find it (GC is doing this when GC'ing 1241 * indexing LEBs). Although we already have an additional RB-tree where 1242 * we save such changed znodes (see 'ins_clr_old_idx_znode()') until 1243 * after the commit. But anyway, this does not look easy to implement 1244 * so we did not try this. 1245 */ 1246 err = tnc_prev(c, &znode, n); 1247 if (err == -ENOENT) { 1248 dbg_tnc("found 0, lvl %d, n -1", znode->level); 1249 *n = -1; 1250 return 0; 1251 } 1252 if (unlikely(err < 0)) 1253 return err; 1254 if (keys_cmp(c, key, &znode->zbranch[*n].key)) { 1255 dbg_tnc("found 0, lvl %d, n -1", znode->level); 1256 *n = -1; 1257 return 0; 1258 } 1259 1260 dbg_tnc("found 1, lvl %d, n %d", znode->level, *n); 1261 *zn = znode; 1262 return 1; 1263 } 1264 1265 /** 1266 * lookup_level0_dirty - search for zero-level znode dirtying. 1267 * @c: UBIFS file-system description object 1268 * @key: key to lookup 1269 * @zn: znode is returned here 1270 * @n: znode branch slot number is returned here 1271 * 1272 * This function looks up the TNC tree and search for zero-level znode which 1273 * refers key @key. The found zero-level znode is returned in @zn. There are 3 1274 * cases: 1275 * o exact match, i.e. the found zero-level znode contains key @key, then %1 1276 * is returned and slot number of the matched branch is stored in @n; 1277 * o not exact match, which means that zero-level znode does not contain @key 1278 * then %0 is returned and slot number of the closed branch is stored in 1279 * @n; 1280 * o @key is so small that it is even less than the lowest key of the 1281 * leftmost zero-level node, then %0 is returned and %-1 is stored in @n. 1282 * 1283 * Additionally all znodes in the path from the root to the located zero-level 1284 * znode are marked as dirty. 1285 * 1286 * Note, when the TNC tree is traversed, some znodes may be absent, then this 1287 * function reads corresponding indexing nodes and inserts them to TNC. In 1288 * case of failure, a negative error code is returned. 1289 */ 1290 static int lookup_level0_dirty(struct ubifs_info *c, const union ubifs_key *key, 1291 struct ubifs_znode **zn, int *n) 1292 { 1293 int err, exact; 1294 struct ubifs_znode *znode; 1295 unsigned long time = get_seconds(); 1296 1297 dbg_tnck(key, "search and dirty key "); 1298 1299 znode = c->zroot.znode; 1300 if (unlikely(!znode)) { 1301 znode = ubifs_load_znode(c, &c->zroot, NULL, 0); 1302 if (IS_ERR(znode)) 1303 return PTR_ERR(znode); 1304 } 1305 1306 znode = dirty_cow_znode(c, &c->zroot); 1307 if (IS_ERR(znode)) 1308 return PTR_ERR(znode); 1309 1310 znode->time = time; 1311 1312 while (1) { 1313 struct ubifs_zbranch *zbr; 1314 1315 exact = ubifs_search_zbranch(c, znode, key, n); 1316 1317 if (znode->level == 0) 1318 break; 1319 1320 if (*n < 0) 1321 *n = 0; 1322 zbr = &znode->zbranch[*n]; 1323 1324 if (zbr->znode) { 1325 znode->time = time; 1326 znode = dirty_cow_znode(c, zbr); 1327 if (IS_ERR(znode)) 1328 return PTR_ERR(znode); 1329 continue; 1330 } 1331 1332 /* znode is not in TNC cache, load it from the media */ 1333 znode = ubifs_load_znode(c, zbr, znode, *n); 1334 if (IS_ERR(znode)) 1335 return PTR_ERR(znode); 1336 znode = dirty_cow_znode(c, zbr); 1337 if (IS_ERR(znode)) 1338 return PTR_ERR(znode); 1339 } 1340 1341 *zn = znode; 1342 if (exact || !is_hash_key(c, key) || *n != -1) { 1343 dbg_tnc("found %d, lvl %d, n %d", exact, znode->level, *n); 1344 return exact; 1345 } 1346 1347 /* 1348 * See huge comment at 'lookup_level0_dirty()' what is the rest of the 1349 * code. 1350 */ 1351 err = tnc_prev(c, &znode, n); 1352 if (err == -ENOENT) { 1353 *n = -1; 1354 dbg_tnc("found 0, lvl %d, n -1", znode->level); 1355 return 0; 1356 } 1357 if (unlikely(err < 0)) 1358 return err; 1359 if (keys_cmp(c, key, &znode->zbranch[*n].key)) { 1360 *n = -1; 1361 dbg_tnc("found 0, lvl %d, n -1", znode->level); 1362 return 0; 1363 } 1364 1365 if (znode->cnext || !ubifs_zn_dirty(znode)) { 1366 znode = dirty_cow_bottom_up(c, znode); 1367 if (IS_ERR(znode)) 1368 return PTR_ERR(znode); 1369 } 1370 1371 dbg_tnc("found 1, lvl %d, n %d", znode->level, *n); 1372 *zn = znode; 1373 return 1; 1374 } 1375 1376 /** 1377 * maybe_leb_gced - determine if a LEB may have been garbage collected. 1378 * @c: UBIFS file-system description object 1379 * @lnum: LEB number 1380 * @gc_seq1: garbage collection sequence number 1381 * 1382 * This function determines if @lnum may have been garbage collected since 1383 * sequence number @gc_seq1. If it may have been then %1 is returned, otherwise 1384 * %0 is returned. 1385 */ 1386 static int maybe_leb_gced(struct ubifs_info *c, int lnum, int gc_seq1) 1387 { 1388 #ifndef __UBOOT__ 1389 int gc_seq2, gced_lnum; 1390 1391 gced_lnum = c->gced_lnum; 1392 smp_rmb(); 1393 gc_seq2 = c->gc_seq; 1394 /* Same seq means no GC */ 1395 if (gc_seq1 == gc_seq2) 1396 return 0; 1397 /* Different by more than 1 means we don't know */ 1398 if (gc_seq1 + 1 != gc_seq2) 1399 return 1; 1400 /* 1401 * We have seen the sequence number has increased by 1. Now we need to 1402 * be sure we read the right LEB number, so read it again. 1403 */ 1404 smp_rmb(); 1405 if (gced_lnum != c->gced_lnum) 1406 return 1; 1407 /* Finally we can check lnum */ 1408 if (gced_lnum == lnum) 1409 return 1; 1410 #else 1411 /* No garbage collection in the read-only U-Boot implementation */ 1412 #endif 1413 return 0; 1414 } 1415 1416 /** 1417 * ubifs_tnc_locate - look up a file-system node and return it and its location. 1418 * @c: UBIFS file-system description object 1419 * @key: node key to lookup 1420 * @node: the node is returned here 1421 * @lnum: LEB number is returned here 1422 * @offs: offset is returned here 1423 * 1424 * This function looks up and reads node with key @key. The caller has to make 1425 * sure the @node buffer is large enough to fit the node. Returns zero in case 1426 * of success, %-ENOENT if the node was not found, and a negative error code in 1427 * case of failure. The node location can be returned in @lnum and @offs. 1428 */ 1429 int ubifs_tnc_locate(struct ubifs_info *c, const union ubifs_key *key, 1430 void *node, int *lnum, int *offs) 1431 { 1432 int found, n, err, safely = 0, gc_seq1; 1433 struct ubifs_znode *znode; 1434 struct ubifs_zbranch zbr, *zt; 1435 1436 again: 1437 mutex_lock(&c->tnc_mutex); 1438 found = ubifs_lookup_level0(c, key, &znode, &n); 1439 if (!found) { 1440 err = -ENOENT; 1441 goto out; 1442 } else if (found < 0) { 1443 err = found; 1444 goto out; 1445 } 1446 zt = &znode->zbranch[n]; 1447 if (lnum) { 1448 *lnum = zt->lnum; 1449 *offs = zt->offs; 1450 } 1451 if (is_hash_key(c, key)) { 1452 /* 1453 * In this case the leaf node cache gets used, so we pass the 1454 * address of the zbranch and keep the mutex locked 1455 */ 1456 err = tnc_read_node_nm(c, zt, node); 1457 goto out; 1458 } 1459 if (safely) { 1460 err = ubifs_tnc_read_node(c, zt, node); 1461 goto out; 1462 } 1463 /* Drop the TNC mutex prematurely and race with garbage collection */ 1464 zbr = znode->zbranch[n]; 1465 gc_seq1 = c->gc_seq; 1466 mutex_unlock(&c->tnc_mutex); 1467 1468 if (ubifs_get_wbuf(c, zbr.lnum)) { 1469 /* We do not GC journal heads */ 1470 err = ubifs_tnc_read_node(c, &zbr, node); 1471 return err; 1472 } 1473 1474 err = fallible_read_node(c, key, &zbr, node); 1475 if (err <= 0 || maybe_leb_gced(c, zbr.lnum, gc_seq1)) { 1476 /* 1477 * The node may have been GC'ed out from under us so try again 1478 * while keeping the TNC mutex locked. 1479 */ 1480 safely = 1; 1481 goto again; 1482 } 1483 return 0; 1484 1485 out: 1486 mutex_unlock(&c->tnc_mutex); 1487 return err; 1488 } 1489 1490 /** 1491 * ubifs_tnc_get_bu_keys - lookup keys for bulk-read. 1492 * @c: UBIFS file-system description object 1493 * @bu: bulk-read parameters and results 1494 * 1495 * Lookup consecutive data node keys for the same inode that reside 1496 * consecutively in the same LEB. This function returns zero in case of success 1497 * and a negative error code in case of failure. 1498 * 1499 * Note, if the bulk-read buffer length (@bu->buf_len) is known, this function 1500 * makes sure bulk-read nodes fit the buffer. Otherwise, this function prepares 1501 * maximum possible amount of nodes for bulk-read. 1502 */ 1503 int ubifs_tnc_get_bu_keys(struct ubifs_info *c, struct bu_info *bu) 1504 { 1505 int n, err = 0, lnum = -1, uninitialized_var(offs); 1506 int uninitialized_var(len); 1507 unsigned int block = key_block(c, &bu->key); 1508 struct ubifs_znode *znode; 1509 1510 bu->cnt = 0; 1511 bu->blk_cnt = 0; 1512 bu->eof = 0; 1513 1514 mutex_lock(&c->tnc_mutex); 1515 /* Find first key */ 1516 err = ubifs_lookup_level0(c, &bu->key, &znode, &n); 1517 if (err < 0) 1518 goto out; 1519 if (err) { 1520 /* Key found */ 1521 len = znode->zbranch[n].len; 1522 /* The buffer must be big enough for at least 1 node */ 1523 if (len > bu->buf_len) { 1524 err = -EINVAL; 1525 goto out; 1526 } 1527 /* Add this key */ 1528 bu->zbranch[bu->cnt++] = znode->zbranch[n]; 1529 bu->blk_cnt += 1; 1530 lnum = znode->zbranch[n].lnum; 1531 offs = ALIGN(znode->zbranch[n].offs + len, 8); 1532 } 1533 while (1) { 1534 struct ubifs_zbranch *zbr; 1535 union ubifs_key *key; 1536 unsigned int next_block; 1537 1538 /* Find next key */ 1539 err = tnc_next(c, &znode, &n); 1540 if (err) 1541 goto out; 1542 zbr = &znode->zbranch[n]; 1543 key = &zbr->key; 1544 /* See if there is another data key for this file */ 1545 if (key_inum(c, key) != key_inum(c, &bu->key) || 1546 key_type(c, key) != UBIFS_DATA_KEY) { 1547 err = -ENOENT; 1548 goto out; 1549 } 1550 if (lnum < 0) { 1551 /* First key found */ 1552 lnum = zbr->lnum; 1553 offs = ALIGN(zbr->offs + zbr->len, 8); 1554 len = zbr->len; 1555 if (len > bu->buf_len) { 1556 err = -EINVAL; 1557 goto out; 1558 } 1559 } else { 1560 /* 1561 * The data nodes must be in consecutive positions in 1562 * the same LEB. 1563 */ 1564 if (zbr->lnum != lnum || zbr->offs != offs) 1565 goto out; 1566 offs += ALIGN(zbr->len, 8); 1567 len = ALIGN(len, 8) + zbr->len; 1568 /* Must not exceed buffer length */ 1569 if (len > bu->buf_len) 1570 goto out; 1571 } 1572 /* Allow for holes */ 1573 next_block = key_block(c, key); 1574 bu->blk_cnt += (next_block - block - 1); 1575 if (bu->blk_cnt >= UBIFS_MAX_BULK_READ) 1576 goto out; 1577 block = next_block; 1578 /* Add this key */ 1579 bu->zbranch[bu->cnt++] = *zbr; 1580 bu->blk_cnt += 1; 1581 /* See if we have room for more */ 1582 if (bu->cnt >= UBIFS_MAX_BULK_READ) 1583 goto out; 1584 if (bu->blk_cnt >= UBIFS_MAX_BULK_READ) 1585 goto out; 1586 } 1587 out: 1588 if (err == -ENOENT) { 1589 bu->eof = 1; 1590 err = 0; 1591 } 1592 bu->gc_seq = c->gc_seq; 1593 mutex_unlock(&c->tnc_mutex); 1594 if (err) 1595 return err; 1596 /* 1597 * An enormous hole could cause bulk-read to encompass too many 1598 * page cache pages, so limit the number here. 1599 */ 1600 if (bu->blk_cnt > UBIFS_MAX_BULK_READ) 1601 bu->blk_cnt = UBIFS_MAX_BULK_READ; 1602 /* 1603 * Ensure that bulk-read covers a whole number of page cache 1604 * pages. 1605 */ 1606 if (UBIFS_BLOCKS_PER_PAGE == 1 || 1607 !(bu->blk_cnt & (UBIFS_BLOCKS_PER_PAGE - 1))) 1608 return 0; 1609 if (bu->eof) { 1610 /* At the end of file we can round up */ 1611 bu->blk_cnt += UBIFS_BLOCKS_PER_PAGE - 1; 1612 return 0; 1613 } 1614 /* Exclude data nodes that do not make up a whole page cache page */ 1615 block = key_block(c, &bu->key) + bu->blk_cnt; 1616 block &= ~(UBIFS_BLOCKS_PER_PAGE - 1); 1617 while (bu->cnt) { 1618 if (key_block(c, &bu->zbranch[bu->cnt - 1].key) < block) 1619 break; 1620 bu->cnt -= 1; 1621 } 1622 return 0; 1623 } 1624 1625 /** 1626 * read_wbuf - bulk-read from a LEB with a wbuf. 1627 * @wbuf: wbuf that may overlap the read 1628 * @buf: buffer into which to read 1629 * @len: read length 1630 * @lnum: LEB number from which to read 1631 * @offs: offset from which to read 1632 * 1633 * This functions returns %0 on success or a negative error code on failure. 1634 */ 1635 static int read_wbuf(struct ubifs_wbuf *wbuf, void *buf, int len, int lnum, 1636 int offs) 1637 { 1638 const struct ubifs_info *c = wbuf->c; 1639 int rlen, overlap; 1640 1641 dbg_io("LEB %d:%d, length %d", lnum, offs, len); 1642 ubifs_assert(wbuf && lnum >= 0 && lnum < c->leb_cnt && offs >= 0); 1643 ubifs_assert(!(offs & 7) && offs < c->leb_size); 1644 ubifs_assert(offs + len <= c->leb_size); 1645 1646 spin_lock(&wbuf->lock); 1647 overlap = (lnum == wbuf->lnum && offs + len > wbuf->offs); 1648 if (!overlap) { 1649 /* We may safely unlock the write-buffer and read the data */ 1650 spin_unlock(&wbuf->lock); 1651 return ubifs_leb_read(c, lnum, buf, offs, len, 0); 1652 } 1653 1654 /* Don't read under wbuf */ 1655 rlen = wbuf->offs - offs; 1656 if (rlen < 0) 1657 rlen = 0; 1658 1659 /* Copy the rest from the write-buffer */ 1660 memcpy(buf + rlen, wbuf->buf + offs + rlen - wbuf->offs, len - rlen); 1661 spin_unlock(&wbuf->lock); 1662 1663 if (rlen > 0) 1664 /* Read everything that goes before write-buffer */ 1665 return ubifs_leb_read(c, lnum, buf, offs, rlen, 0); 1666 1667 return 0; 1668 } 1669 1670 /** 1671 * validate_data_node - validate data nodes for bulk-read. 1672 * @c: UBIFS file-system description object 1673 * @buf: buffer containing data node to validate 1674 * @zbr: zbranch of data node to validate 1675 * 1676 * This functions returns %0 on success or a negative error code on failure. 1677 */ 1678 static int validate_data_node(struct ubifs_info *c, void *buf, 1679 struct ubifs_zbranch *zbr) 1680 { 1681 union ubifs_key key1; 1682 struct ubifs_ch *ch = buf; 1683 int err, len; 1684 1685 if (ch->node_type != UBIFS_DATA_NODE) { 1686 ubifs_err("bad node type (%d but expected %d)", 1687 ch->node_type, UBIFS_DATA_NODE); 1688 goto out_err; 1689 } 1690 1691 err = ubifs_check_node(c, buf, zbr->lnum, zbr->offs, 0, 0); 1692 if (err) { 1693 ubifs_err("expected node type %d", UBIFS_DATA_NODE); 1694 goto out; 1695 } 1696 1697 len = le32_to_cpu(ch->len); 1698 if (len != zbr->len) { 1699 ubifs_err("bad node length %d, expected %d", len, zbr->len); 1700 goto out_err; 1701 } 1702 1703 /* Make sure the key of the read node is correct */ 1704 key_read(c, buf + UBIFS_KEY_OFFSET, &key1); 1705 if (!keys_eq(c, &zbr->key, &key1)) { 1706 ubifs_err("bad key in node at LEB %d:%d", 1707 zbr->lnum, zbr->offs); 1708 dbg_tnck(&zbr->key, "looked for key "); 1709 dbg_tnck(&key1, "found node's key "); 1710 goto out_err; 1711 } 1712 1713 return 0; 1714 1715 out_err: 1716 err = -EINVAL; 1717 out: 1718 ubifs_err("bad node at LEB %d:%d", zbr->lnum, zbr->offs); 1719 ubifs_dump_node(c, buf); 1720 dump_stack(); 1721 return err; 1722 } 1723 1724 /** 1725 * ubifs_tnc_bulk_read - read a number of data nodes in one go. 1726 * @c: UBIFS file-system description object 1727 * @bu: bulk-read parameters and results 1728 * 1729 * This functions reads and validates the data nodes that were identified by the 1730 * 'ubifs_tnc_get_bu_keys()' function. This functions returns %0 on success, 1731 * -EAGAIN to indicate a race with GC, or another negative error code on 1732 * failure. 1733 */ 1734 int ubifs_tnc_bulk_read(struct ubifs_info *c, struct bu_info *bu) 1735 { 1736 int lnum = bu->zbranch[0].lnum, offs = bu->zbranch[0].offs, len, err, i; 1737 struct ubifs_wbuf *wbuf; 1738 void *buf; 1739 1740 len = bu->zbranch[bu->cnt - 1].offs; 1741 len += bu->zbranch[bu->cnt - 1].len - offs; 1742 if (len > bu->buf_len) { 1743 ubifs_err("buffer too small %d vs %d", bu->buf_len, len); 1744 return -EINVAL; 1745 } 1746 1747 /* Do the read */ 1748 wbuf = ubifs_get_wbuf(c, lnum); 1749 if (wbuf) 1750 err = read_wbuf(wbuf, bu->buf, len, lnum, offs); 1751 else 1752 err = ubifs_leb_read(c, lnum, bu->buf, offs, len, 0); 1753 1754 /* Check for a race with GC */ 1755 if (maybe_leb_gced(c, lnum, bu->gc_seq)) 1756 return -EAGAIN; 1757 1758 if (err && err != -EBADMSG) { 1759 ubifs_err("failed to read from LEB %d:%d, error %d", 1760 lnum, offs, err); 1761 dump_stack(); 1762 dbg_tnck(&bu->key, "key "); 1763 return err; 1764 } 1765 1766 /* Validate the nodes read */ 1767 buf = bu->buf; 1768 for (i = 0; i < bu->cnt; i++) { 1769 err = validate_data_node(c, buf, &bu->zbranch[i]); 1770 if (err) 1771 return err; 1772 buf = buf + ALIGN(bu->zbranch[i].len, 8); 1773 } 1774 1775 return 0; 1776 } 1777 1778 /** 1779 * do_lookup_nm- look up a "hashed" node. 1780 * @c: UBIFS file-system description object 1781 * @key: node key to lookup 1782 * @node: the node is returned here 1783 * @nm: node name 1784 * 1785 * This function look up and reads a node which contains name hash in the key. 1786 * Since the hash may have collisions, there may be many nodes with the same 1787 * key, so we have to sequentially look to all of them until the needed one is 1788 * found. This function returns zero in case of success, %-ENOENT if the node 1789 * was not found, and a negative error code in case of failure. 1790 */ 1791 static int do_lookup_nm(struct ubifs_info *c, const union ubifs_key *key, 1792 void *node, const struct qstr *nm) 1793 { 1794 int found, n, err; 1795 struct ubifs_znode *znode; 1796 1797 dbg_tnck(key, "name '%.*s' key ", nm->len, nm->name); 1798 mutex_lock(&c->tnc_mutex); 1799 found = ubifs_lookup_level0(c, key, &znode, &n); 1800 if (!found) { 1801 err = -ENOENT; 1802 goto out_unlock; 1803 } else if (found < 0) { 1804 err = found; 1805 goto out_unlock; 1806 } 1807 1808 ubifs_assert(n >= 0); 1809 1810 err = resolve_collision(c, key, &znode, &n, nm); 1811 dbg_tnc("rc returned %d, znode %p, n %d", err, znode, n); 1812 if (unlikely(err < 0)) 1813 goto out_unlock; 1814 if (err == 0) { 1815 err = -ENOENT; 1816 goto out_unlock; 1817 } 1818 1819 err = tnc_read_node_nm(c, &znode->zbranch[n], node); 1820 1821 out_unlock: 1822 mutex_unlock(&c->tnc_mutex); 1823 return err; 1824 } 1825 1826 /** 1827 * ubifs_tnc_lookup_nm - look up a "hashed" node. 1828 * @c: UBIFS file-system description object 1829 * @key: node key to lookup 1830 * @node: the node is returned here 1831 * @nm: node name 1832 * 1833 * This function look up and reads a node which contains name hash in the key. 1834 * Since the hash may have collisions, there may be many nodes with the same 1835 * key, so we have to sequentially look to all of them until the needed one is 1836 * found. This function returns zero in case of success, %-ENOENT if the node 1837 * was not found, and a negative error code in case of failure. 1838 */ 1839 int ubifs_tnc_lookup_nm(struct ubifs_info *c, const union ubifs_key *key, 1840 void *node, const struct qstr *nm) 1841 { 1842 int err, len; 1843 const struct ubifs_dent_node *dent = node; 1844 1845 /* 1846 * We assume that in most of the cases there are no name collisions and 1847 * 'ubifs_tnc_lookup()' returns us the right direntry. 1848 */ 1849 err = ubifs_tnc_lookup(c, key, node); 1850 if (err) 1851 return err; 1852 1853 len = le16_to_cpu(dent->nlen); 1854 if (nm->len == len && !memcmp(dent->name, nm->name, len)) 1855 return 0; 1856 1857 /* 1858 * Unluckily, there are hash collisions and we have to iterate over 1859 * them look at each direntry with colliding name hash sequentially. 1860 */ 1861 return do_lookup_nm(c, key, node, nm); 1862 } 1863 1864 /** 1865 * correct_parent_keys - correct parent znodes' keys. 1866 * @c: UBIFS file-system description object 1867 * @znode: znode to correct parent znodes for 1868 * 1869 * This is a helper function for 'tnc_insert()'. When the key of the leftmost 1870 * zbranch changes, keys of parent znodes have to be corrected. This helper 1871 * function is called in such situations and corrects the keys if needed. 1872 */ 1873 static void correct_parent_keys(const struct ubifs_info *c, 1874 struct ubifs_znode *znode) 1875 { 1876 union ubifs_key *key, *key1; 1877 1878 ubifs_assert(znode->parent); 1879 ubifs_assert(znode->iip == 0); 1880 1881 key = &znode->zbranch[0].key; 1882 key1 = &znode->parent->zbranch[0].key; 1883 1884 while (keys_cmp(c, key, key1) < 0) { 1885 key_copy(c, key, key1); 1886 znode = znode->parent; 1887 znode->alt = 1; 1888 if (!znode->parent || znode->iip) 1889 break; 1890 key1 = &znode->parent->zbranch[0].key; 1891 } 1892 } 1893 1894 /** 1895 * insert_zbranch - insert a zbranch into a znode. 1896 * @znode: znode into which to insert 1897 * @zbr: zbranch to insert 1898 * @n: slot number to insert to 1899 * 1900 * This is a helper function for 'tnc_insert()'. UBIFS does not allow "gaps" in 1901 * znode's array of zbranches and keeps zbranches consolidated, so when a new 1902 * zbranch has to be inserted to the @znode->zbranches[]' array at the @n-th 1903 * slot, zbranches starting from @n have to be moved right. 1904 */ 1905 static void insert_zbranch(struct ubifs_znode *znode, 1906 const struct ubifs_zbranch *zbr, int n) 1907 { 1908 int i; 1909 1910 ubifs_assert(ubifs_zn_dirty(znode)); 1911 1912 if (znode->level) { 1913 for (i = znode->child_cnt; i > n; i--) { 1914 znode->zbranch[i] = znode->zbranch[i - 1]; 1915 if (znode->zbranch[i].znode) 1916 znode->zbranch[i].znode->iip = i; 1917 } 1918 if (zbr->znode) 1919 zbr->znode->iip = n; 1920 } else 1921 for (i = znode->child_cnt; i > n; i--) 1922 znode->zbranch[i] = znode->zbranch[i - 1]; 1923 1924 znode->zbranch[n] = *zbr; 1925 znode->child_cnt += 1; 1926 1927 /* 1928 * After inserting at slot zero, the lower bound of the key range of 1929 * this znode may have changed. If this znode is subsequently split 1930 * then the upper bound of the key range may change, and furthermore 1931 * it could change to be lower than the original lower bound. If that 1932 * happens, then it will no longer be possible to find this znode in the 1933 * TNC using the key from the index node on flash. That is bad because 1934 * if it is not found, we will assume it is obsolete and may overwrite 1935 * it. Then if there is an unclean unmount, we will start using the 1936 * old index which will be broken. 1937 * 1938 * So we first mark znodes that have insertions at slot zero, and then 1939 * if they are split we add their lnum/offs to the old_idx tree. 1940 */ 1941 if (n == 0) 1942 znode->alt = 1; 1943 } 1944 1945 /** 1946 * tnc_insert - insert a node into TNC. 1947 * @c: UBIFS file-system description object 1948 * @znode: znode to insert into 1949 * @zbr: branch to insert 1950 * @n: slot number to insert new zbranch to 1951 * 1952 * This function inserts a new node described by @zbr into znode @znode. If 1953 * znode does not have a free slot for new zbranch, it is split. Parent znodes 1954 * are splat as well if needed. Returns zero in case of success or a negative 1955 * error code in case of failure. 1956 */ 1957 static int tnc_insert(struct ubifs_info *c, struct ubifs_znode *znode, 1958 struct ubifs_zbranch *zbr, int n) 1959 { 1960 struct ubifs_znode *zn, *zi, *zp; 1961 int i, keep, move, appending = 0; 1962 union ubifs_key *key = &zbr->key, *key1; 1963 1964 ubifs_assert(n >= 0 && n <= c->fanout); 1965 1966 /* Implement naive insert for now */ 1967 again: 1968 zp = znode->parent; 1969 if (znode->child_cnt < c->fanout) { 1970 ubifs_assert(n != c->fanout); 1971 dbg_tnck(key, "inserted at %d level %d, key ", n, znode->level); 1972 1973 insert_zbranch(znode, zbr, n); 1974 1975 /* Ensure parent's key is correct */ 1976 if (n == 0 && zp && znode->iip == 0) 1977 correct_parent_keys(c, znode); 1978 1979 return 0; 1980 } 1981 1982 /* 1983 * Unfortunately, @znode does not have more empty slots and we have to 1984 * split it. 1985 */ 1986 dbg_tnck(key, "splitting level %d, key ", znode->level); 1987 1988 if (znode->alt) 1989 /* 1990 * We can no longer be sure of finding this znode by key, so we 1991 * record it in the old_idx tree. 1992 */ 1993 ins_clr_old_idx_znode(c, znode); 1994 1995 zn = kzalloc(c->max_znode_sz, GFP_NOFS); 1996 if (!zn) 1997 return -ENOMEM; 1998 zn->parent = zp; 1999 zn->level = znode->level; 2000 2001 /* Decide where to split */ 2002 if (znode->level == 0 && key_type(c, key) == UBIFS_DATA_KEY) { 2003 /* Try not to split consecutive data keys */ 2004 if (n == c->fanout) { 2005 key1 = &znode->zbranch[n - 1].key; 2006 if (key_inum(c, key1) == key_inum(c, key) && 2007 key_type(c, key1) == UBIFS_DATA_KEY) 2008 appending = 1; 2009 } else 2010 goto check_split; 2011 } else if (appending && n != c->fanout) { 2012 /* Try not to split consecutive data keys */ 2013 appending = 0; 2014 check_split: 2015 if (n >= (c->fanout + 1) / 2) { 2016 key1 = &znode->zbranch[0].key; 2017 if (key_inum(c, key1) == key_inum(c, key) && 2018 key_type(c, key1) == UBIFS_DATA_KEY) { 2019 key1 = &znode->zbranch[n].key; 2020 if (key_inum(c, key1) != key_inum(c, key) || 2021 key_type(c, key1) != UBIFS_DATA_KEY) { 2022 keep = n; 2023 move = c->fanout - keep; 2024 zi = znode; 2025 goto do_split; 2026 } 2027 } 2028 } 2029 } 2030 2031 if (appending) { 2032 keep = c->fanout; 2033 move = 0; 2034 } else { 2035 keep = (c->fanout + 1) / 2; 2036 move = c->fanout - keep; 2037 } 2038 2039 /* 2040 * Although we don't at present, we could look at the neighbors and see 2041 * if we can move some zbranches there. 2042 */ 2043 2044 if (n < keep) { 2045 /* Insert into existing znode */ 2046 zi = znode; 2047 move += 1; 2048 keep -= 1; 2049 } else { 2050 /* Insert into new znode */ 2051 zi = zn; 2052 n -= keep; 2053 /* Re-parent */ 2054 if (zn->level != 0) 2055 zbr->znode->parent = zn; 2056 } 2057 2058 do_split: 2059 2060 __set_bit(DIRTY_ZNODE, &zn->flags); 2061 atomic_long_inc(&c->dirty_zn_cnt); 2062 2063 zn->child_cnt = move; 2064 znode->child_cnt = keep; 2065 2066 dbg_tnc("moving %d, keeping %d", move, keep); 2067 2068 /* Move zbranch */ 2069 for (i = 0; i < move; i++) { 2070 zn->zbranch[i] = znode->zbranch[keep + i]; 2071 /* Re-parent */ 2072 if (zn->level != 0) 2073 if (zn->zbranch[i].znode) { 2074 zn->zbranch[i].znode->parent = zn; 2075 zn->zbranch[i].znode->iip = i; 2076 } 2077 } 2078 2079 /* Insert new key and branch */ 2080 dbg_tnck(key, "inserting at %d level %d, key ", n, zn->level); 2081 2082 insert_zbranch(zi, zbr, n); 2083 2084 /* Insert new znode (produced by spitting) into the parent */ 2085 if (zp) { 2086 if (n == 0 && zi == znode && znode->iip == 0) 2087 correct_parent_keys(c, znode); 2088 2089 /* Locate insertion point */ 2090 n = znode->iip + 1; 2091 2092 /* Tail recursion */ 2093 zbr->key = zn->zbranch[0].key; 2094 zbr->znode = zn; 2095 zbr->lnum = 0; 2096 zbr->offs = 0; 2097 zbr->len = 0; 2098 znode = zp; 2099 2100 goto again; 2101 } 2102 2103 /* We have to split root znode */ 2104 dbg_tnc("creating new zroot at level %d", znode->level + 1); 2105 2106 zi = kzalloc(c->max_znode_sz, GFP_NOFS); 2107 if (!zi) 2108 return -ENOMEM; 2109 2110 zi->child_cnt = 2; 2111 zi->level = znode->level + 1; 2112 2113 __set_bit(DIRTY_ZNODE, &zi->flags); 2114 atomic_long_inc(&c->dirty_zn_cnt); 2115 2116 zi->zbranch[0].key = znode->zbranch[0].key; 2117 zi->zbranch[0].znode = znode; 2118 zi->zbranch[0].lnum = c->zroot.lnum; 2119 zi->zbranch[0].offs = c->zroot.offs; 2120 zi->zbranch[0].len = c->zroot.len; 2121 zi->zbranch[1].key = zn->zbranch[0].key; 2122 zi->zbranch[1].znode = zn; 2123 2124 c->zroot.lnum = 0; 2125 c->zroot.offs = 0; 2126 c->zroot.len = 0; 2127 c->zroot.znode = zi; 2128 2129 zn->parent = zi; 2130 zn->iip = 1; 2131 znode->parent = zi; 2132 znode->iip = 0; 2133 2134 return 0; 2135 } 2136 2137 /** 2138 * ubifs_tnc_add - add a node to TNC. 2139 * @c: UBIFS file-system description object 2140 * @key: key to add 2141 * @lnum: LEB number of node 2142 * @offs: node offset 2143 * @len: node length 2144 * 2145 * This function adds a node with key @key to TNC. The node may be new or it may 2146 * obsolete some existing one. Returns %0 on success or negative error code on 2147 * failure. 2148 */ 2149 int ubifs_tnc_add(struct ubifs_info *c, const union ubifs_key *key, int lnum, 2150 int offs, int len) 2151 { 2152 int found, n, err = 0; 2153 struct ubifs_znode *znode; 2154 2155 mutex_lock(&c->tnc_mutex); 2156 dbg_tnck(key, "%d:%d, len %d, key ", lnum, offs, len); 2157 found = lookup_level0_dirty(c, key, &znode, &n); 2158 if (!found) { 2159 struct ubifs_zbranch zbr; 2160 2161 zbr.znode = NULL; 2162 zbr.lnum = lnum; 2163 zbr.offs = offs; 2164 zbr.len = len; 2165 key_copy(c, key, &zbr.key); 2166 err = tnc_insert(c, znode, &zbr, n + 1); 2167 } else if (found == 1) { 2168 struct ubifs_zbranch *zbr = &znode->zbranch[n]; 2169 2170 lnc_free(zbr); 2171 err = ubifs_add_dirt(c, zbr->lnum, zbr->len); 2172 zbr->lnum = lnum; 2173 zbr->offs = offs; 2174 zbr->len = len; 2175 } else 2176 err = found; 2177 if (!err) 2178 err = dbg_check_tnc(c, 0); 2179 mutex_unlock(&c->tnc_mutex); 2180 2181 return err; 2182 } 2183 2184 /** 2185 * ubifs_tnc_replace - replace a node in the TNC only if the old node is found. 2186 * @c: UBIFS file-system description object 2187 * @key: key to add 2188 * @old_lnum: LEB number of old node 2189 * @old_offs: old node offset 2190 * @lnum: LEB number of node 2191 * @offs: node offset 2192 * @len: node length 2193 * 2194 * This function replaces a node with key @key in the TNC only if the old node 2195 * is found. This function is called by garbage collection when node are moved. 2196 * Returns %0 on success or negative error code on failure. 2197 */ 2198 int ubifs_tnc_replace(struct ubifs_info *c, const union ubifs_key *key, 2199 int old_lnum, int old_offs, int lnum, int offs, int len) 2200 { 2201 int found, n, err = 0; 2202 struct ubifs_znode *znode; 2203 2204 mutex_lock(&c->tnc_mutex); 2205 dbg_tnck(key, "old LEB %d:%d, new LEB %d:%d, len %d, key ", old_lnum, 2206 old_offs, lnum, offs, len); 2207 found = lookup_level0_dirty(c, key, &znode, &n); 2208 if (found < 0) { 2209 err = found; 2210 goto out_unlock; 2211 } 2212 2213 if (found == 1) { 2214 struct ubifs_zbranch *zbr = &znode->zbranch[n]; 2215 2216 found = 0; 2217 if (zbr->lnum == old_lnum && zbr->offs == old_offs) { 2218 lnc_free(zbr); 2219 err = ubifs_add_dirt(c, zbr->lnum, zbr->len); 2220 if (err) 2221 goto out_unlock; 2222 zbr->lnum = lnum; 2223 zbr->offs = offs; 2224 zbr->len = len; 2225 found = 1; 2226 } else if (is_hash_key(c, key)) { 2227 found = resolve_collision_directly(c, key, &znode, &n, 2228 old_lnum, old_offs); 2229 dbg_tnc("rc returned %d, znode %p, n %d, LEB %d:%d", 2230 found, znode, n, old_lnum, old_offs); 2231 if (found < 0) { 2232 err = found; 2233 goto out_unlock; 2234 } 2235 2236 if (found) { 2237 /* Ensure the znode is dirtied */ 2238 if (znode->cnext || !ubifs_zn_dirty(znode)) { 2239 znode = dirty_cow_bottom_up(c, znode); 2240 if (IS_ERR(znode)) { 2241 err = PTR_ERR(znode); 2242 goto out_unlock; 2243 } 2244 } 2245 zbr = &znode->zbranch[n]; 2246 lnc_free(zbr); 2247 err = ubifs_add_dirt(c, zbr->lnum, 2248 zbr->len); 2249 if (err) 2250 goto out_unlock; 2251 zbr->lnum = lnum; 2252 zbr->offs = offs; 2253 zbr->len = len; 2254 } 2255 } 2256 } 2257 2258 if (!found) 2259 err = ubifs_add_dirt(c, lnum, len); 2260 2261 if (!err) 2262 err = dbg_check_tnc(c, 0); 2263 2264 out_unlock: 2265 mutex_unlock(&c->tnc_mutex); 2266 return err; 2267 } 2268 2269 /** 2270 * ubifs_tnc_add_nm - add a "hashed" node to TNC. 2271 * @c: UBIFS file-system description object 2272 * @key: key to add 2273 * @lnum: LEB number of node 2274 * @offs: node offset 2275 * @len: node length 2276 * @nm: node name 2277 * 2278 * This is the same as 'ubifs_tnc_add()' but it should be used with keys which 2279 * may have collisions, like directory entry keys. 2280 */ 2281 int ubifs_tnc_add_nm(struct ubifs_info *c, const union ubifs_key *key, 2282 int lnum, int offs, int len, const struct qstr *nm) 2283 { 2284 int found, n, err = 0; 2285 struct ubifs_znode *znode; 2286 2287 mutex_lock(&c->tnc_mutex); 2288 dbg_tnck(key, "LEB %d:%d, name '%.*s', key ", 2289 lnum, offs, nm->len, nm->name); 2290 found = lookup_level0_dirty(c, key, &znode, &n); 2291 if (found < 0) { 2292 err = found; 2293 goto out_unlock; 2294 } 2295 2296 if (found == 1) { 2297 if (c->replaying) 2298 found = fallible_resolve_collision(c, key, &znode, &n, 2299 nm, 1); 2300 else 2301 found = resolve_collision(c, key, &znode, &n, nm); 2302 dbg_tnc("rc returned %d, znode %p, n %d", found, znode, n); 2303 if (found < 0) { 2304 err = found; 2305 goto out_unlock; 2306 } 2307 2308 /* Ensure the znode is dirtied */ 2309 if (znode->cnext || !ubifs_zn_dirty(znode)) { 2310 znode = dirty_cow_bottom_up(c, znode); 2311 if (IS_ERR(znode)) { 2312 err = PTR_ERR(znode); 2313 goto out_unlock; 2314 } 2315 } 2316 2317 if (found == 1) { 2318 struct ubifs_zbranch *zbr = &znode->zbranch[n]; 2319 2320 lnc_free(zbr); 2321 err = ubifs_add_dirt(c, zbr->lnum, zbr->len); 2322 zbr->lnum = lnum; 2323 zbr->offs = offs; 2324 zbr->len = len; 2325 goto out_unlock; 2326 } 2327 } 2328 2329 if (!found) { 2330 struct ubifs_zbranch zbr; 2331 2332 zbr.znode = NULL; 2333 zbr.lnum = lnum; 2334 zbr.offs = offs; 2335 zbr.len = len; 2336 key_copy(c, key, &zbr.key); 2337 err = tnc_insert(c, znode, &zbr, n + 1); 2338 if (err) 2339 goto out_unlock; 2340 if (c->replaying) { 2341 /* 2342 * We did not find it in the index so there may be a 2343 * dangling branch still in the index. So we remove it 2344 * by passing 'ubifs_tnc_remove_nm()' the same key but 2345 * an unmatchable name. 2346 */ 2347 struct qstr noname = { .name = "" }; 2348 2349 err = dbg_check_tnc(c, 0); 2350 mutex_unlock(&c->tnc_mutex); 2351 if (err) 2352 return err; 2353 return ubifs_tnc_remove_nm(c, key, &noname); 2354 } 2355 } 2356 2357 out_unlock: 2358 if (!err) 2359 err = dbg_check_tnc(c, 0); 2360 mutex_unlock(&c->tnc_mutex); 2361 return err; 2362 } 2363 2364 /** 2365 * tnc_delete - delete a znode form TNC. 2366 * @c: UBIFS file-system description object 2367 * @znode: znode to delete from 2368 * @n: zbranch slot number to delete 2369 * 2370 * This function deletes a leaf node from @n-th slot of @znode. Returns zero in 2371 * case of success and a negative error code in case of failure. 2372 */ 2373 static int tnc_delete(struct ubifs_info *c, struct ubifs_znode *znode, int n) 2374 { 2375 struct ubifs_zbranch *zbr; 2376 struct ubifs_znode *zp; 2377 int i, err; 2378 2379 /* Delete without merge for now */ 2380 ubifs_assert(znode->level == 0); 2381 ubifs_assert(n >= 0 && n < c->fanout); 2382 dbg_tnck(&znode->zbranch[n].key, "deleting key "); 2383 2384 zbr = &znode->zbranch[n]; 2385 lnc_free(zbr); 2386 2387 err = ubifs_add_dirt(c, zbr->lnum, zbr->len); 2388 if (err) { 2389 ubifs_dump_znode(c, znode); 2390 return err; 2391 } 2392 2393 /* We do not "gap" zbranch slots */ 2394 for (i = n; i < znode->child_cnt - 1; i++) 2395 znode->zbranch[i] = znode->zbranch[i + 1]; 2396 znode->child_cnt -= 1; 2397 2398 if (znode->child_cnt > 0) 2399 return 0; 2400 2401 /* 2402 * This was the last zbranch, we have to delete this znode from the 2403 * parent. 2404 */ 2405 2406 do { 2407 ubifs_assert(!ubifs_zn_obsolete(znode)); 2408 ubifs_assert(ubifs_zn_dirty(znode)); 2409 2410 zp = znode->parent; 2411 n = znode->iip; 2412 2413 atomic_long_dec(&c->dirty_zn_cnt); 2414 2415 err = insert_old_idx_znode(c, znode); 2416 if (err) 2417 return err; 2418 2419 if (znode->cnext) { 2420 __set_bit(OBSOLETE_ZNODE, &znode->flags); 2421 atomic_long_inc(&c->clean_zn_cnt); 2422 atomic_long_inc(&ubifs_clean_zn_cnt); 2423 } else 2424 kfree(znode); 2425 znode = zp; 2426 } while (znode->child_cnt == 1); /* while removing last child */ 2427 2428 /* Remove from znode, entry n - 1 */ 2429 znode->child_cnt -= 1; 2430 ubifs_assert(znode->level != 0); 2431 for (i = n; i < znode->child_cnt; i++) { 2432 znode->zbranch[i] = znode->zbranch[i + 1]; 2433 if (znode->zbranch[i].znode) 2434 znode->zbranch[i].znode->iip = i; 2435 } 2436 2437 /* 2438 * If this is the root and it has only 1 child then 2439 * collapse the tree. 2440 */ 2441 if (!znode->parent) { 2442 while (znode->child_cnt == 1 && znode->level != 0) { 2443 zp = znode; 2444 zbr = &znode->zbranch[0]; 2445 znode = get_znode(c, znode, 0); 2446 if (IS_ERR(znode)) 2447 return PTR_ERR(znode); 2448 znode = dirty_cow_znode(c, zbr); 2449 if (IS_ERR(znode)) 2450 return PTR_ERR(znode); 2451 znode->parent = NULL; 2452 znode->iip = 0; 2453 if (c->zroot.len) { 2454 err = insert_old_idx(c, c->zroot.lnum, 2455 c->zroot.offs); 2456 if (err) 2457 return err; 2458 } 2459 c->zroot.lnum = zbr->lnum; 2460 c->zroot.offs = zbr->offs; 2461 c->zroot.len = zbr->len; 2462 c->zroot.znode = znode; 2463 ubifs_assert(!ubifs_zn_obsolete(zp)); 2464 ubifs_assert(ubifs_zn_dirty(zp)); 2465 atomic_long_dec(&c->dirty_zn_cnt); 2466 2467 if (zp->cnext) { 2468 __set_bit(OBSOLETE_ZNODE, &zp->flags); 2469 atomic_long_inc(&c->clean_zn_cnt); 2470 atomic_long_inc(&ubifs_clean_zn_cnt); 2471 } else 2472 kfree(zp); 2473 } 2474 } 2475 2476 return 0; 2477 } 2478 2479 /** 2480 * ubifs_tnc_remove - remove an index entry of a node. 2481 * @c: UBIFS file-system description object 2482 * @key: key of node 2483 * 2484 * Returns %0 on success or negative error code on failure. 2485 */ 2486 int ubifs_tnc_remove(struct ubifs_info *c, const union ubifs_key *key) 2487 { 2488 int found, n, err = 0; 2489 struct ubifs_znode *znode; 2490 2491 mutex_lock(&c->tnc_mutex); 2492 dbg_tnck(key, "key "); 2493 found = lookup_level0_dirty(c, key, &znode, &n); 2494 if (found < 0) { 2495 err = found; 2496 goto out_unlock; 2497 } 2498 if (found == 1) 2499 err = tnc_delete(c, znode, n); 2500 if (!err) 2501 err = dbg_check_tnc(c, 0); 2502 2503 out_unlock: 2504 mutex_unlock(&c->tnc_mutex); 2505 return err; 2506 } 2507 2508 /** 2509 * ubifs_tnc_remove_nm - remove an index entry for a "hashed" node. 2510 * @c: UBIFS file-system description object 2511 * @key: key of node 2512 * @nm: directory entry name 2513 * 2514 * Returns %0 on success or negative error code on failure. 2515 */ 2516 int ubifs_tnc_remove_nm(struct ubifs_info *c, const union ubifs_key *key, 2517 const struct qstr *nm) 2518 { 2519 int n, err; 2520 struct ubifs_znode *znode; 2521 2522 mutex_lock(&c->tnc_mutex); 2523 dbg_tnck(key, "%.*s, key ", nm->len, nm->name); 2524 err = lookup_level0_dirty(c, key, &znode, &n); 2525 if (err < 0) 2526 goto out_unlock; 2527 2528 if (err) { 2529 if (c->replaying) 2530 err = fallible_resolve_collision(c, key, &znode, &n, 2531 nm, 0); 2532 else 2533 err = resolve_collision(c, key, &znode, &n, nm); 2534 dbg_tnc("rc returned %d, znode %p, n %d", err, znode, n); 2535 if (err < 0) 2536 goto out_unlock; 2537 if (err) { 2538 /* Ensure the znode is dirtied */ 2539 if (znode->cnext || !ubifs_zn_dirty(znode)) { 2540 znode = dirty_cow_bottom_up(c, znode); 2541 if (IS_ERR(znode)) { 2542 err = PTR_ERR(znode); 2543 goto out_unlock; 2544 } 2545 } 2546 err = tnc_delete(c, znode, n); 2547 } 2548 } 2549 2550 out_unlock: 2551 if (!err) 2552 err = dbg_check_tnc(c, 0); 2553 mutex_unlock(&c->tnc_mutex); 2554 return err; 2555 } 2556 2557 /** 2558 * key_in_range - determine if a key falls within a range of keys. 2559 * @c: UBIFS file-system description object 2560 * @key: key to check 2561 * @from_key: lowest key in range 2562 * @to_key: highest key in range 2563 * 2564 * This function returns %1 if the key is in range and %0 otherwise. 2565 */ 2566 static int key_in_range(struct ubifs_info *c, union ubifs_key *key, 2567 union ubifs_key *from_key, union ubifs_key *to_key) 2568 { 2569 if (keys_cmp(c, key, from_key) < 0) 2570 return 0; 2571 if (keys_cmp(c, key, to_key) > 0) 2572 return 0; 2573 return 1; 2574 } 2575 2576 /** 2577 * ubifs_tnc_remove_range - remove index entries in range. 2578 * @c: UBIFS file-system description object 2579 * @from_key: lowest key to remove 2580 * @to_key: highest key to remove 2581 * 2582 * This function removes index entries starting at @from_key and ending at 2583 * @to_key. This function returns zero in case of success and a negative error 2584 * code in case of failure. 2585 */ 2586 int ubifs_tnc_remove_range(struct ubifs_info *c, union ubifs_key *from_key, 2587 union ubifs_key *to_key) 2588 { 2589 int i, n, k, err = 0; 2590 struct ubifs_znode *znode; 2591 union ubifs_key *key; 2592 2593 mutex_lock(&c->tnc_mutex); 2594 while (1) { 2595 /* Find first level 0 znode that contains keys to remove */ 2596 err = ubifs_lookup_level0(c, from_key, &znode, &n); 2597 if (err < 0) 2598 goto out_unlock; 2599 2600 if (err) 2601 key = from_key; 2602 else { 2603 err = tnc_next(c, &znode, &n); 2604 if (err == -ENOENT) { 2605 err = 0; 2606 goto out_unlock; 2607 } 2608 if (err < 0) 2609 goto out_unlock; 2610 key = &znode->zbranch[n].key; 2611 if (!key_in_range(c, key, from_key, to_key)) { 2612 err = 0; 2613 goto out_unlock; 2614 } 2615 } 2616 2617 /* Ensure the znode is dirtied */ 2618 if (znode->cnext || !ubifs_zn_dirty(znode)) { 2619 znode = dirty_cow_bottom_up(c, znode); 2620 if (IS_ERR(znode)) { 2621 err = PTR_ERR(znode); 2622 goto out_unlock; 2623 } 2624 } 2625 2626 /* Remove all keys in range except the first */ 2627 for (i = n + 1, k = 0; i < znode->child_cnt; i++, k++) { 2628 key = &znode->zbranch[i].key; 2629 if (!key_in_range(c, key, from_key, to_key)) 2630 break; 2631 lnc_free(&znode->zbranch[i]); 2632 err = ubifs_add_dirt(c, znode->zbranch[i].lnum, 2633 znode->zbranch[i].len); 2634 if (err) { 2635 ubifs_dump_znode(c, znode); 2636 goto out_unlock; 2637 } 2638 dbg_tnck(key, "removing key "); 2639 } 2640 if (k) { 2641 for (i = n + 1 + k; i < znode->child_cnt; i++) 2642 znode->zbranch[i - k] = znode->zbranch[i]; 2643 znode->child_cnt -= k; 2644 } 2645 2646 /* Now delete the first */ 2647 err = tnc_delete(c, znode, n); 2648 if (err) 2649 goto out_unlock; 2650 } 2651 2652 out_unlock: 2653 if (!err) 2654 err = dbg_check_tnc(c, 0); 2655 mutex_unlock(&c->tnc_mutex); 2656 return err; 2657 } 2658 2659 /** 2660 * ubifs_tnc_remove_ino - remove an inode from TNC. 2661 * @c: UBIFS file-system description object 2662 * @inum: inode number to remove 2663 * 2664 * This function remove inode @inum and all the extended attributes associated 2665 * with the anode from TNC and returns zero in case of success or a negative 2666 * error code in case of failure. 2667 */ 2668 int ubifs_tnc_remove_ino(struct ubifs_info *c, ino_t inum) 2669 { 2670 union ubifs_key key1, key2; 2671 struct ubifs_dent_node *xent, *pxent = NULL; 2672 struct qstr nm = { .name = NULL }; 2673 2674 dbg_tnc("ino %lu", (unsigned long)inum); 2675 2676 /* 2677 * Walk all extended attribute entries and remove them together with 2678 * corresponding extended attribute inodes. 2679 */ 2680 lowest_xent_key(c, &key1, inum); 2681 while (1) { 2682 ino_t xattr_inum; 2683 int err; 2684 2685 xent = ubifs_tnc_next_ent(c, &key1, &nm); 2686 if (IS_ERR(xent)) { 2687 err = PTR_ERR(xent); 2688 if (err == -ENOENT) 2689 break; 2690 return err; 2691 } 2692 2693 xattr_inum = le64_to_cpu(xent->inum); 2694 dbg_tnc("xent '%s', ino %lu", xent->name, 2695 (unsigned long)xattr_inum); 2696 2697 nm.name = xent->name; 2698 nm.len = le16_to_cpu(xent->nlen); 2699 err = ubifs_tnc_remove_nm(c, &key1, &nm); 2700 if (err) { 2701 kfree(xent); 2702 return err; 2703 } 2704 2705 lowest_ino_key(c, &key1, xattr_inum); 2706 highest_ino_key(c, &key2, xattr_inum); 2707 err = ubifs_tnc_remove_range(c, &key1, &key2); 2708 if (err) { 2709 kfree(xent); 2710 return err; 2711 } 2712 2713 kfree(pxent); 2714 pxent = xent; 2715 key_read(c, &xent->key, &key1); 2716 } 2717 2718 kfree(pxent); 2719 lowest_ino_key(c, &key1, inum); 2720 highest_ino_key(c, &key2, inum); 2721 2722 return ubifs_tnc_remove_range(c, &key1, &key2); 2723 } 2724 2725 /** 2726 * ubifs_tnc_next_ent - walk directory or extended attribute entries. 2727 * @c: UBIFS file-system description object 2728 * @key: key of last entry 2729 * @nm: name of last entry found or %NULL 2730 * 2731 * This function finds and reads the next directory or extended attribute entry 2732 * after the given key (@key) if there is one. @nm is used to resolve 2733 * collisions. 2734 * 2735 * If the name of the current entry is not known and only the key is known, 2736 * @nm->name has to be %NULL. In this case the semantics of this function is a 2737 * little bit different and it returns the entry corresponding to this key, not 2738 * the next one. If the key was not found, the closest "right" entry is 2739 * returned. 2740 * 2741 * If the fist entry has to be found, @key has to contain the lowest possible 2742 * key value for this inode and @name has to be %NULL. 2743 * 2744 * This function returns the found directory or extended attribute entry node 2745 * in case of success, %-ENOENT is returned if no entry was found, and a 2746 * negative error code is returned in case of failure. 2747 */ 2748 struct ubifs_dent_node *ubifs_tnc_next_ent(struct ubifs_info *c, 2749 union ubifs_key *key, 2750 const struct qstr *nm) 2751 { 2752 int n, err, type = key_type(c, key); 2753 struct ubifs_znode *znode; 2754 struct ubifs_dent_node *dent; 2755 struct ubifs_zbranch *zbr; 2756 union ubifs_key *dkey; 2757 2758 dbg_tnck(key, "%s ", nm->name ? (char *)nm->name : "(lowest)"); 2759 ubifs_assert(is_hash_key(c, key)); 2760 2761 mutex_lock(&c->tnc_mutex); 2762 err = ubifs_lookup_level0(c, key, &znode, &n); 2763 if (unlikely(err < 0)) 2764 goto out_unlock; 2765 2766 if (nm->name) { 2767 if (err) { 2768 /* Handle collisions */ 2769 err = resolve_collision(c, key, &znode, &n, nm); 2770 dbg_tnc("rc returned %d, znode %p, n %d", 2771 err, znode, n); 2772 if (unlikely(err < 0)) 2773 goto out_unlock; 2774 } 2775 2776 /* Now find next entry */ 2777 err = tnc_next(c, &znode, &n); 2778 if (unlikely(err)) 2779 goto out_unlock; 2780 } else { 2781 /* 2782 * The full name of the entry was not given, in which case the 2783 * behavior of this function is a little different and it 2784 * returns current entry, not the next one. 2785 */ 2786 if (!err) { 2787 /* 2788 * However, the given key does not exist in the TNC 2789 * tree and @znode/@n variables contain the closest 2790 * "preceding" element. Switch to the next one. 2791 */ 2792 err = tnc_next(c, &znode, &n); 2793 if (err) 2794 goto out_unlock; 2795 } 2796 } 2797 2798 zbr = &znode->zbranch[n]; 2799 dent = kmalloc(zbr->len, GFP_NOFS); 2800 if (unlikely(!dent)) { 2801 err = -ENOMEM; 2802 goto out_unlock; 2803 } 2804 2805 /* 2806 * The above 'tnc_next()' call could lead us to the next inode, check 2807 * this. 2808 */ 2809 dkey = &zbr->key; 2810 if (key_inum(c, dkey) != key_inum(c, key) || 2811 key_type(c, dkey) != type) { 2812 err = -ENOENT; 2813 goto out_free; 2814 } 2815 2816 err = tnc_read_node_nm(c, zbr, dent); 2817 if (unlikely(err)) 2818 goto out_free; 2819 2820 mutex_unlock(&c->tnc_mutex); 2821 return dent; 2822 2823 out_free: 2824 kfree(dent); 2825 out_unlock: 2826 mutex_unlock(&c->tnc_mutex); 2827 return ERR_PTR(err); 2828 } 2829 2830 /** 2831 * tnc_destroy_cnext - destroy left-over obsolete znodes from a failed commit. 2832 * @c: UBIFS file-system description object 2833 * 2834 * Destroy left-over obsolete znodes from a failed commit. 2835 */ 2836 static void tnc_destroy_cnext(struct ubifs_info *c) 2837 { 2838 struct ubifs_znode *cnext; 2839 2840 if (!c->cnext) 2841 return; 2842 ubifs_assert(c->cmt_state == COMMIT_BROKEN); 2843 cnext = c->cnext; 2844 do { 2845 struct ubifs_znode *znode = cnext; 2846 2847 cnext = cnext->cnext; 2848 if (ubifs_zn_obsolete(znode)) 2849 kfree(znode); 2850 } while (cnext && cnext != c->cnext); 2851 } 2852 2853 /** 2854 * ubifs_tnc_close - close TNC subsystem and free all related resources. 2855 * @c: UBIFS file-system description object 2856 */ 2857 void ubifs_tnc_close(struct ubifs_info *c) 2858 { 2859 tnc_destroy_cnext(c); 2860 if (c->zroot.znode) { 2861 long n; 2862 2863 ubifs_destroy_tnc_subtree(c->zroot.znode); 2864 n = atomic_long_read(&c->clean_zn_cnt); 2865 atomic_long_sub(n, &ubifs_clean_zn_cnt); 2866 } 2867 kfree(c->gap_lebs); 2868 kfree(c->ilebs); 2869 destroy_old_idx(c); 2870 } 2871 2872 /** 2873 * left_znode - get the znode to the left. 2874 * @c: UBIFS file-system description object 2875 * @znode: znode 2876 * 2877 * This function returns a pointer to the znode to the left of @znode or NULL if 2878 * there is not one. A negative error code is returned on failure. 2879 */ 2880 static struct ubifs_znode *left_znode(struct ubifs_info *c, 2881 struct ubifs_znode *znode) 2882 { 2883 int level = znode->level; 2884 2885 while (1) { 2886 int n = znode->iip - 1; 2887 2888 /* Go up until we can go left */ 2889 znode = znode->parent; 2890 if (!znode) 2891 return NULL; 2892 if (n >= 0) { 2893 /* Now go down the rightmost branch to 'level' */ 2894 znode = get_znode(c, znode, n); 2895 if (IS_ERR(znode)) 2896 return znode; 2897 while (znode->level != level) { 2898 n = znode->child_cnt - 1; 2899 znode = get_znode(c, znode, n); 2900 if (IS_ERR(znode)) 2901 return znode; 2902 } 2903 break; 2904 } 2905 } 2906 return znode; 2907 } 2908 2909 /** 2910 * right_znode - get the znode to the right. 2911 * @c: UBIFS file-system description object 2912 * @znode: znode 2913 * 2914 * This function returns a pointer to the znode to the right of @znode or NULL 2915 * if there is not one. A negative error code is returned on failure. 2916 */ 2917 static struct ubifs_znode *right_znode(struct ubifs_info *c, 2918 struct ubifs_znode *znode) 2919 { 2920 int level = znode->level; 2921 2922 while (1) { 2923 int n = znode->iip + 1; 2924 2925 /* Go up until we can go right */ 2926 znode = znode->parent; 2927 if (!znode) 2928 return NULL; 2929 if (n < znode->child_cnt) { 2930 /* Now go down the leftmost branch to 'level' */ 2931 znode = get_znode(c, znode, n); 2932 if (IS_ERR(znode)) 2933 return znode; 2934 while (znode->level != level) { 2935 znode = get_znode(c, znode, 0); 2936 if (IS_ERR(znode)) 2937 return znode; 2938 } 2939 break; 2940 } 2941 } 2942 return znode; 2943 } 2944 2945 /** 2946 * lookup_znode - find a particular indexing node from TNC. 2947 * @c: UBIFS file-system description object 2948 * @key: index node key to lookup 2949 * @level: index node level 2950 * @lnum: index node LEB number 2951 * @offs: index node offset 2952 * 2953 * This function searches an indexing node by its first key @key and its 2954 * address @lnum:@offs. It looks up the indexing tree by pulling all indexing 2955 * nodes it traverses to TNC. This function is called for indexing nodes which 2956 * were found on the media by scanning, for example when garbage-collecting or 2957 * when doing in-the-gaps commit. This means that the indexing node which is 2958 * looked for does not have to have exactly the same leftmost key @key, because 2959 * the leftmost key may have been changed, in which case TNC will contain a 2960 * dirty znode which still refers the same @lnum:@offs. This function is clever 2961 * enough to recognize such indexing nodes. 2962 * 2963 * Note, if a znode was deleted or changed too much, then this function will 2964 * not find it. For situations like this UBIFS has the old index RB-tree 2965 * (indexed by @lnum:@offs). 2966 * 2967 * This function returns a pointer to the znode found or %NULL if it is not 2968 * found. A negative error code is returned on failure. 2969 */ 2970 static struct ubifs_znode *lookup_znode(struct ubifs_info *c, 2971 union ubifs_key *key, int level, 2972 int lnum, int offs) 2973 { 2974 struct ubifs_znode *znode, *zn; 2975 int n, nn; 2976 2977 ubifs_assert(key_type(c, key) < UBIFS_INVALID_KEY); 2978 2979 /* 2980 * The arguments have probably been read off flash, so don't assume 2981 * they are valid. 2982 */ 2983 if (level < 0) 2984 return ERR_PTR(-EINVAL); 2985 2986 /* Get the root znode */ 2987 znode = c->zroot.znode; 2988 if (!znode) { 2989 znode = ubifs_load_znode(c, &c->zroot, NULL, 0); 2990 if (IS_ERR(znode)) 2991 return znode; 2992 } 2993 /* Check if it is the one we are looking for */ 2994 if (c->zroot.lnum == lnum && c->zroot.offs == offs) 2995 return znode; 2996 /* Descend to the parent level i.e. (level + 1) */ 2997 if (level >= znode->level) 2998 return NULL; 2999 while (1) { 3000 ubifs_search_zbranch(c, znode, key, &n); 3001 if (n < 0) { 3002 /* 3003 * We reached a znode where the leftmost key is greater 3004 * than the key we are searching for. This is the same 3005 * situation as the one described in a huge comment at 3006 * the end of the 'ubifs_lookup_level0()' function. And 3007 * for exactly the same reasons we have to try to look 3008 * left before giving up. 3009 */ 3010 znode = left_znode(c, znode); 3011 if (!znode) 3012 return NULL; 3013 if (IS_ERR(znode)) 3014 return znode; 3015 ubifs_search_zbranch(c, znode, key, &n); 3016 ubifs_assert(n >= 0); 3017 } 3018 if (znode->level == level + 1) 3019 break; 3020 znode = get_znode(c, znode, n); 3021 if (IS_ERR(znode)) 3022 return znode; 3023 } 3024 /* Check if the child is the one we are looking for */ 3025 if (znode->zbranch[n].lnum == lnum && znode->zbranch[n].offs == offs) 3026 return get_znode(c, znode, n); 3027 /* If the key is unique, there is nowhere else to look */ 3028 if (!is_hash_key(c, key)) 3029 return NULL; 3030 /* 3031 * The key is not unique and so may be also in the znodes to either 3032 * side. 3033 */ 3034 zn = znode; 3035 nn = n; 3036 /* Look left */ 3037 while (1) { 3038 /* Move one branch to the left */ 3039 if (n) 3040 n -= 1; 3041 else { 3042 znode = left_znode(c, znode); 3043 if (!znode) 3044 break; 3045 if (IS_ERR(znode)) 3046 return znode; 3047 n = znode->child_cnt - 1; 3048 } 3049 /* Check it */ 3050 if (znode->zbranch[n].lnum == lnum && 3051 znode->zbranch[n].offs == offs) 3052 return get_znode(c, znode, n); 3053 /* Stop if the key is less than the one we are looking for */ 3054 if (keys_cmp(c, &znode->zbranch[n].key, key) < 0) 3055 break; 3056 } 3057 /* Back to the middle */ 3058 znode = zn; 3059 n = nn; 3060 /* Look right */ 3061 while (1) { 3062 /* Move one branch to the right */ 3063 if (++n >= znode->child_cnt) { 3064 znode = right_znode(c, znode); 3065 if (!znode) 3066 break; 3067 if (IS_ERR(znode)) 3068 return znode; 3069 n = 0; 3070 } 3071 /* Check it */ 3072 if (znode->zbranch[n].lnum == lnum && 3073 znode->zbranch[n].offs == offs) 3074 return get_znode(c, znode, n); 3075 /* Stop if the key is greater than the one we are looking for */ 3076 if (keys_cmp(c, &znode->zbranch[n].key, key) > 0) 3077 break; 3078 } 3079 return NULL; 3080 } 3081 3082 /** 3083 * is_idx_node_in_tnc - determine if an index node is in the TNC. 3084 * @c: UBIFS file-system description object 3085 * @key: key of index node 3086 * @level: index node level 3087 * @lnum: LEB number of index node 3088 * @offs: offset of index node 3089 * 3090 * This function returns %0 if the index node is not referred to in the TNC, %1 3091 * if the index node is referred to in the TNC and the corresponding znode is 3092 * dirty, %2 if an index node is referred to in the TNC and the corresponding 3093 * znode is clean, and a negative error code in case of failure. 3094 * 3095 * Note, the @key argument has to be the key of the first child. Also note, 3096 * this function relies on the fact that 0:0 is never a valid LEB number and 3097 * offset for a main-area node. 3098 */ 3099 int is_idx_node_in_tnc(struct ubifs_info *c, union ubifs_key *key, int level, 3100 int lnum, int offs) 3101 { 3102 struct ubifs_znode *znode; 3103 3104 znode = lookup_znode(c, key, level, lnum, offs); 3105 if (!znode) 3106 return 0; 3107 if (IS_ERR(znode)) 3108 return PTR_ERR(znode); 3109 3110 return ubifs_zn_dirty(znode) ? 1 : 2; 3111 } 3112 3113 /** 3114 * is_leaf_node_in_tnc - determine if a non-indexing not is in the TNC. 3115 * @c: UBIFS file-system description object 3116 * @key: node key 3117 * @lnum: node LEB number 3118 * @offs: node offset 3119 * 3120 * This function returns %1 if the node is referred to in the TNC, %0 if it is 3121 * not, and a negative error code in case of failure. 3122 * 3123 * Note, this function relies on the fact that 0:0 is never a valid LEB number 3124 * and offset for a main-area node. 3125 */ 3126 static int is_leaf_node_in_tnc(struct ubifs_info *c, union ubifs_key *key, 3127 int lnum, int offs) 3128 { 3129 struct ubifs_zbranch *zbr; 3130 struct ubifs_znode *znode, *zn; 3131 int n, found, err, nn; 3132 const int unique = !is_hash_key(c, key); 3133 3134 found = ubifs_lookup_level0(c, key, &znode, &n); 3135 if (found < 0) 3136 return found; /* Error code */ 3137 if (!found) 3138 return 0; 3139 zbr = &znode->zbranch[n]; 3140 if (lnum == zbr->lnum && offs == zbr->offs) 3141 return 1; /* Found it */ 3142 if (unique) 3143 return 0; 3144 /* 3145 * Because the key is not unique, we have to look left 3146 * and right as well 3147 */ 3148 zn = znode; 3149 nn = n; 3150 /* Look left */ 3151 while (1) { 3152 err = tnc_prev(c, &znode, &n); 3153 if (err == -ENOENT) 3154 break; 3155 if (err) 3156 return err; 3157 if (keys_cmp(c, key, &znode->zbranch[n].key)) 3158 break; 3159 zbr = &znode->zbranch[n]; 3160 if (lnum == zbr->lnum && offs == zbr->offs) 3161 return 1; /* Found it */ 3162 } 3163 /* Look right */ 3164 znode = zn; 3165 n = nn; 3166 while (1) { 3167 err = tnc_next(c, &znode, &n); 3168 if (err) { 3169 if (err == -ENOENT) 3170 return 0; 3171 return err; 3172 } 3173 if (keys_cmp(c, key, &znode->zbranch[n].key)) 3174 break; 3175 zbr = &znode->zbranch[n]; 3176 if (lnum == zbr->lnum && offs == zbr->offs) 3177 return 1; /* Found it */ 3178 } 3179 return 0; 3180 } 3181 3182 /** 3183 * ubifs_tnc_has_node - determine whether a node is in the TNC. 3184 * @c: UBIFS file-system description object 3185 * @key: node key 3186 * @level: index node level (if it is an index node) 3187 * @lnum: node LEB number 3188 * @offs: node offset 3189 * @is_idx: non-zero if the node is an index node 3190 * 3191 * This function returns %1 if the node is in the TNC, %0 if it is not, and a 3192 * negative error code in case of failure. For index nodes, @key has to be the 3193 * key of the first child. An index node is considered to be in the TNC only if 3194 * the corresponding znode is clean or has not been loaded. 3195 */ 3196 int ubifs_tnc_has_node(struct ubifs_info *c, union ubifs_key *key, int level, 3197 int lnum, int offs, int is_idx) 3198 { 3199 int err; 3200 3201 mutex_lock(&c->tnc_mutex); 3202 if (is_idx) { 3203 err = is_idx_node_in_tnc(c, key, level, lnum, offs); 3204 if (err < 0) 3205 goto out_unlock; 3206 if (err == 1) 3207 /* The index node was found but it was dirty */ 3208 err = 0; 3209 else if (err == 2) 3210 /* The index node was found and it was clean */ 3211 err = 1; 3212 else 3213 BUG_ON(err != 0); 3214 } else 3215 err = is_leaf_node_in_tnc(c, key, lnum, offs); 3216 3217 out_unlock: 3218 mutex_unlock(&c->tnc_mutex); 3219 return err; 3220 } 3221 3222 /** 3223 * ubifs_dirty_idx_node - dirty an index node. 3224 * @c: UBIFS file-system description object 3225 * @key: index node key 3226 * @level: index node level 3227 * @lnum: index node LEB number 3228 * @offs: index node offset 3229 * 3230 * This function loads and dirties an index node so that it can be garbage 3231 * collected. The @key argument has to be the key of the first child. This 3232 * function relies on the fact that 0:0 is never a valid LEB number and offset 3233 * for a main-area node. Returns %0 on success and a negative error code on 3234 * failure. 3235 */ 3236 int ubifs_dirty_idx_node(struct ubifs_info *c, union ubifs_key *key, int level, 3237 int lnum, int offs) 3238 { 3239 struct ubifs_znode *znode; 3240 int err = 0; 3241 3242 mutex_lock(&c->tnc_mutex); 3243 znode = lookup_znode(c, key, level, lnum, offs); 3244 if (!znode) 3245 goto out_unlock; 3246 if (IS_ERR(znode)) { 3247 err = PTR_ERR(znode); 3248 goto out_unlock; 3249 } 3250 znode = dirty_cow_bottom_up(c, znode); 3251 if (IS_ERR(znode)) { 3252 err = PTR_ERR(znode); 3253 goto out_unlock; 3254 } 3255 3256 out_unlock: 3257 mutex_unlock(&c->tnc_mutex); 3258 return err; 3259 } 3260 3261 /** 3262 * dbg_check_inode_size - check if inode size is correct. 3263 * @c: UBIFS file-system description object 3264 * @inum: inode number 3265 * @size: inode size 3266 * 3267 * This function makes sure that the inode size (@size) is correct and it does 3268 * not have any pages beyond @size. Returns zero if the inode is OK, %-EINVAL 3269 * if it has a data page beyond @size, and other negative error code in case of 3270 * other errors. 3271 */ 3272 int dbg_check_inode_size(struct ubifs_info *c, const struct inode *inode, 3273 loff_t size) 3274 { 3275 int err, n; 3276 union ubifs_key from_key, to_key, *key; 3277 struct ubifs_znode *znode; 3278 unsigned int block; 3279 3280 if (!S_ISREG(inode->i_mode)) 3281 return 0; 3282 if (!dbg_is_chk_gen(c)) 3283 return 0; 3284 3285 block = (size + UBIFS_BLOCK_SIZE - 1) >> UBIFS_BLOCK_SHIFT; 3286 data_key_init(c, &from_key, inode->i_ino, block); 3287 highest_data_key(c, &to_key, inode->i_ino); 3288 3289 mutex_lock(&c->tnc_mutex); 3290 err = ubifs_lookup_level0(c, &from_key, &znode, &n); 3291 if (err < 0) 3292 goto out_unlock; 3293 3294 if (err) { 3295 err = -EINVAL; 3296 key = &from_key; 3297 goto out_dump; 3298 } 3299 3300 err = tnc_next(c, &znode, &n); 3301 if (err == -ENOENT) { 3302 err = 0; 3303 goto out_unlock; 3304 } 3305 if (err < 0) 3306 goto out_unlock; 3307 3308 ubifs_assert(err == 0); 3309 key = &znode->zbranch[n].key; 3310 if (!key_in_range(c, key, &from_key, &to_key)) 3311 goto out_unlock; 3312 3313 out_dump: 3314 block = key_block(c, key); 3315 ubifs_err("inode %lu has size %lld, but there are data at offset %lld", 3316 (unsigned long)inode->i_ino, size, 3317 ((loff_t)block) << UBIFS_BLOCK_SHIFT); 3318 mutex_unlock(&c->tnc_mutex); 3319 ubifs_dump_inode(c, inode); 3320 dump_stack(); 3321 return -EINVAL; 3322 3323 out_unlock: 3324 mutex_unlock(&c->tnc_mutex); 3325 return err; 3326 } 3327