| blob | d036ee5b1c81a8bd43d8f8836fbd78b68c462acb |
1 /*
2 * Copyright 2000 by Hans Reiser, licensing governed by reiserfs/README
3 */
5 /*
6 * Written by Anatoly P. Pinchuk pap@namesys.botik.ru
7 * Programm System Institute
8 * Pereslavl-Zalessky Russia
9 */
11 /*
12 * This file contains functions dealing with S+tree
13 *
14 * B_IS_IN_TREE
15 * copy_item_head
16 * comp_short_keys
17 * comp_keys
18 * comp_short_le_keys
19 * le_key2cpu_key
20 * comp_le_keys
21 * bin_search
22 * get_lkey
23 * get_rkey
24 * key_in_buffer
25 * decrement_bcount
26 * reiserfs_check_path
27 * pathrelse_and_restore
28 * pathrelse
29 * search_by_key_reada
30 * search_by_key
31 * search_for_position_by_key
32 * comp_items
33 * prepare_for_direct_item
34 * prepare_for_direntry_item
35 * prepare_for_delete_or_cut
36 * calc_deleted_bytes_number
37 * init_tb_struct
38 * padd_item
39 * reiserfs_delete_item
40 * reiserfs_delete_solid_item
41 * reiserfs_delete_object
42 * maybe_indirect_to_direct
43 * indirect_to_direct_roll_back
44 * reiserfs_cut_from_item
45 * truncate_directory
46 * reiserfs_do_truncate
47 * reiserfs_paste_into_item
48 * reiserfs_insert_item
49 */
51 #include <linux/time.h>
52 #include <linux/string.h>
53 #include <linux/pagemap.h>
54 #include <linux/reiserfs_fs.h>
55 #include <linux/buffer_head.h>
56 #include <linux/quotaops.h>
58 /* Does the buffer contain a disk block which is in the tree. */
60 {
66 }
68 //
69 // to gets item head in le form
70 //
73 {
75 }
77 /* k1 is pointer to on-disk structure which is stored in little-endian
78 form. k2 is pointer to cpu variable. For key of items of the same
79 object this returns 0.
80 Returns: -1 if key1 < key2
81 0 if key1 == key2
82 1 if key1 > key2 */
85 {
86 __u32 n;
98 }
100 /* k1 is pointer to on-disk structure which is stored in little-endian
101 form. k2 is pointer to cpu variable.
102 Compare keys using all 4 key fields.
103 Returns: -1 if key1 < key2 0
104 if key1 = key2 1 if key1 > key2 */
107 {
123 /* this part is needed only when tail conversion is in progress */
133 }
137 {
148 }
150 }
153 {
158 // find out version of the key
163 }
165 // this does not say which one is bigger, it only returns 1 if keys
166 // are not equal, 0 otherwise
169 {
171 }
173 /**************************************************************************
174 * Binary search toolkit function *
175 * Search for an item in the array by the item key *
176 * Returns: 1 if found, 0 if not found; *
177 * *pos = number of the searched element if found, else the *
178 * number of the first element that is larger than key. *
179 **************************************************************************/
180 /* For those not familiar with binary search: lbound is the leftmost item that it
181 could be, rbound the rightmost item that it could be. We examine the item
182 halfway between lbound and rbound, and that tells us either that we can increase
183 lbound, or decrease rbound, or that we have found it, or if lbound <= rbound that
184 there are no possible items, and we have not found it. With each examination we
185 cut the number of possible items it could be by one more than half rounded down,
186 or we find it. */
191 searched. Lest the reader be
192 confused, note that this is crafted
193 as a general function, and when it
194 is applied specifically to the array
195 of item headers in a node, width
196 is actually the item header size not
197 the item size. */
199 )
200 {
217 }
219 /* bin_search did not find given key, it returns position of key,
220 that is minimal and greater than the given one. */
223 }
225 #ifdef CONFIG_REISERFS_CHECK
227 #endif
229 /* Minimal possible key. It is never in the tree. */
232 /* Maximal possible key. It is never in the tree. */
238 };
240 /* Get delimiting key of the buffer by looking for it in the buffers in the path, starting from the bottom
241 of the path, and going upwards. We must check the path's validity at each step. If the key is not in
242 the path, there is no delimiting key in the tree (buffer is first or last buffer in tree), and in this
243 case we return a special key, either MIN_KEY or MAX_KEY. */
246 {
253 /* While not higher in path than first element. */
260 /* Parent at the path is not in the tree now. */
265 /* Check whether position in the parent is correct. */
268 path_offset)) >
271 /* Check whether parent at the path really points to the child. */
276 /* Return delimiting key if position in the parent is not equal to zero. */
279 }
280 /* Return MIN_KEY if we are in the root of the buffer tree. */
285 }
287 /* Get delimiting key of the buffer at the path and its right neighbor. */
290 {
303 /* Parent at the path is not in the tree now. */
308 /* Check whether position in the parent is correct. */
311 path_offset)) >
314 /* Check whether parent at the path really points to the child. */
319 /* Return delimiting key if position in the parent is not the last one. */
322 }
323 /* Return MAX_KEY if we are in the root of the buffer tree. */
328 }
330 /* Check whether a key is contained in the tree rooted from a buffer at a path. */
331 /* This works by looking at the left and right delimiting keys for the buffer in the last path_element in
332 the path. These delimiting keys are stored at least one level above that buffer in the tree. If the
333 buffer is the first or last node in the tree order then one of the delimiting keys may be absent, and in
334 this case get_lkey and get_rkey return a special key which is MIN_KEY or MAX_KEY. */
338 )
339 {
349 /* left delimiting key is bigger, that the key we look for */
351 /* if ( comp_keys(key, get_rkey(chk_path, sb)) != -1 ) */
353 /* key must be less than right delimitiing key */
356 }
359 {
363 }
365 /* Drop the reference to each buffer in a path and restore
366 * dirty bits clean when preparing the buffer for the log.
367 * This version should only be called from fix_nodes() */
370 {
381 }
383 }
385 /* Drop the reference to each buffer in a path */
387 {
397 }
400 {
413 }
417 /* item number is too big or too small */
421 }
425 /* free space does not match to calculated amount of use space */
429 }
430 // FIXME: it is_leaf will hit performance too much - we may have
431 // return 1 here
433 /* check tables of item heads */
440 ih);
442 }
447 ih);
449 }
454 ih);
456 }
459 "item location seems wrong "
462 }
464 }
466 // one may imagine much more checks
468 }
470 /* returns 1 if buf looks like an internal node, 0 otherwise */
472 {
480 /* this level is not possible for internal nodes */
484 }
488 /* for internal which is not root we might check min number of keys */
492 }
499 }
500 // one may imagine much more checks
502 }
504 // make sure that bh contains formatted node of reiserfs tree of
505 // 'level'-th level
507 {
513 }
518 }
520 #define SEARCH_BY_KEY_READA 16
522 /* The function is NOT SCHEDULE-SAFE! */
526 {
531 }
533 /*
534 * note, this needs attention if we are getting rid of the BKL
535 * you have to make sure the prepared bit isn't set on this buffer
536 */
540 }
541 }
543 /**************************************************************************
544 * Algorithm SearchByKey *
545 * look for item in the Disk S+Tree by its key *
546 * Input: sb - super block *
547 * key - pointer to the key to search *
548 * Output: ITEM_FOUND, ITEM_NOT_FOUND or IO_ERROR *
549 * search_path - path from the root to the needed leaf *
550 **************************************************************************/
552 /* This function fills up the path from the root to the leaf as it
553 descends the tree looking for the key. It uses reiserfs_bread to
554 try to find buffers in the cache given their block number. If it
555 does not find them in the cache it reads them from disk. For each
556 node search_by_key finds using reiserfs_bread it then uses
557 bin_search to look through that node. bin_search will find the
558 position of the block_number of the next node if it is looking
559 through an internal node. If it is looking through a leaf node
560 bin_search will find the position of the item which has key either
561 equal to given key, or which is the maximal key less than the given
562 key. search_by_key returns a path that must be checked for the
563 correctness of the top of the path but need not be checked for the
564 correctness of the bottom of the path */
565 /* The function is NOT SCHEDULE-SAFE! */
568 allocated and initialized
569 by the calling
570 function. It is filled up
571 by this function. */
573 stop at leaf level - set to
574 DISK_LEAF_NODE_LEVEL */
575 )
576 {
577 b_blocknr_t block_number;
588 #ifdef CONFIG_REISERFS_CHECK
590 #endif
594 /* As we add each node to a path we increase its count. This means that
595 we must be careful to release all nodes in a path before we either
596 discard the path struct or re-use the path struct, as we do here. */
602 /* With each iteration of this loop we search through the items in the
603 current node, and calculate the next current node(next path element)
604 for the next iteration of this loop.. */
609 #ifdef CONFIG_REISERFS_CHECK
612 "%s: there were %d iterations of "
615 key);
616 #endif
618 /* prep path to have another element added to it. */
619 last_element =
624 /* Read the next tree node, and set the last element in the path to
625 have a pointer to it. */
636 io_error:
640 }
644 expected_level--;
646 /* It is possible that schedule occurred. We must check whether the key
647 to search is still in the tree rooted from the current buffer. If
648 not then repeat search from the root. */
659 /* Get the root block number so that we can repeat the search
660 starting from the root. */
665 /* repeat search from the root */
667 }
669 /* only check that the key is in the buffer if key is not
670 equal to the MAX_KEY. Latter case is only possible in
671 "finish_unfinished()" processing during mount. */
675 #ifdef CONFIG_REISERFS_CHECK
680 }
681 #endif
683 // make sure, that the node contents look like a node of
684 // certain level
687 "invalid format found in block %ld. "
691 }
693 /* ok, we have acquired next formatted node in the tree */
706 KEY_SIZE,
710 }
712 /* we are not in the stop level */
714 /* item has been found, so we choose the pointer which is to the right of the found one */
717 /* if item was not found we choose the position which is to
718 the left of the found item. This requires no code,
719 bin_search did it already. */
721 /* So we have chosen a position in the current node which is
722 an internal node. Now we calculate child block number by
723 position in the node. */
724 block_number =
727 /* if we are going to read leaf nodes, try for read ahead as well */
742 pos--;
743 else
744 pos++;
746 /*
747 * check to make sure we're in the same object
748 */
753 }
754 }
755 }
756 }
757 }
759 /* Form the path to an item and position in this item which contains
760 file byte defined by key. If there is no such item
761 corresponding to the key, we point the path to the item with
762 maximal key less than key, and *pos_in_item is set to one
763 past the last entry/byte in the item. If searching for entry in a
764 directory item, and it is not found, *pos_in_item is set to one
765 entry more than the entry with maximal key which is less than the
766 sought key.
768 Note that if there is no entry in this same node which is one more,
769 then we point to an imaginary entry. for direct items, the
770 position is in units of bytes, for indirect items the position is
771 in units of blocknr entries, for directory items the position is in
772 units of directory entries. */
774 /* The function is NOT SCHEDULE-SAFE! */
778 )
779 {
786 /* If searching for directory entry. */
791 /* If not searching for directory entry. */
793 /* If item is found. */
800 (B_N_PITEM_HEAD
807 }
812 /* Item is not found. Set path to the previous item. */
813 p_le_ih =
820 }
821 // FIXME: quite ugly this far
826 /* Needed byte is contained in the item pointed to by the path. */
832 }
834 }
836 /* Needed byte is not contained in the item pointed to by the
837 path. Set pos_in_item out of the item. */
841 else
845 }
847 /* Compare given item and item pointed to by the path. */
849 {
853 /* Last buffer at the path is not in the tree. */
857 /* Last path position is invalid. */
861 /* we need only to know, whether it is the same item */
864 }
866 /* unformatted nodes are not logged anymore, ever. This is safe
867 ** now
868 */
869 #define held_by_others(bh) (atomic_read(&(bh)->b_count) > 1)
871 // block can not be forgotten as it is in I/O or held by someone
872 #define block_in_use(bh) (buffer_locked(bh) || (held_by_others(bh)))
874 // prepare for delete or cut of direct item
879 {
880 loff_t round_len;
883 /* item has to be deleted */
886 }
887 // new file gets truncated
889 //
891 /* this was new_file_length < le_ih ... */
895 }
896 /* Calculate first position and size for cutting from item. */
901 }
903 // old file: items may have any length
908 }
909 /* Calculate first position and size for cutting from item. */
914 }
919 loff_t new_file_length,
921 {
928 }
931 /* Delete the directory item such as there is one record only
932 in this item */
935 }
937 /* Cut one record from the directory item. */
942 }
944 #define JOURNAL_FOR_FREE_BLOCK_AND_UPDATE_SD (2 * JOURNAL_PER_BALANCE_CNT + 1)
946 /* If the path points to a directory or direct item, calculate mode and the size cut, for balance.
947 If the path points to an indirect item, remove some number of its unformatted nodes.
948 In case of file truncate calculate whether this item must be deleted/truncated or last
949 unformatted node of this item will be converted to a direct item.
950 This function returns a determination of what balance mode the calling function should employ. */
951 static char prepare_for_delete_or_cut(struct reiserfs_transaction_handle *th, struct inode *inode, struct treepath *path, const struct cpu_key *item_key, int *removed, /* Number of unformatted nodes which were removed
952 from end of the file. */
954 )
955 {
962 /* Stat_data item. */
970 }
972 /* Directory item. */
975 new_file_length,
976 cut_size);
978 /* Direct item. */
983 /* Case of an indirect item. */
984 {
993 /* prepare_for_delete_or_cut() is called by
994 * reiserfs_delete_item() */
997 }
1008 __u32 block;
1010 /* Each unformatted block deletion may involve one additional
1011 * bitmap block into the transaction, thereby the initial
1012 * journal space reservation might not be enough. */
1025 }
1032 }
1034 pos --;
1042 }
1043 }
1044 /* a trick. If the buffer has been logged, this will do nothing. If
1045 ** we've broken the loop without logging it, it will restore the
1046 ** buffer */
1053 /* Nothing were cut. maybe convert last unformatted node to the
1054 * direct item? */
1056 }
1058 }
1059 }
1061 /* Calculate number of bytes which will be deleted or cut during balance */
1063 {
1070 del_size =
1074 /* return EMPTY_DIR_SIZE; We delete emty directoris only.
1075 * we can't use EMPTY_DIR_SIZE, as old format dirs have a different
1076 * empty size. ick. FIXME, is this right? */
1078 }
1084 }
1090 {
1101 }
1104 {
1109 }
1111 #ifdef REISERQUOTA_DEBUG
1113 {
1123 }
1126 {
1136 }
1137 #endif
1139 /* Delete object item.
1140 * th - active transaction handle
1141 * path - path to the deleted item
1142 * item_key - key to search for the deleted item
1143 * indode - used for updating i_blocks and quotas
1144 * un_bh - NULL or unformatted node pointer
1145 */
1149 {
1157 #ifdef CONFIG_REISERFS_CHECK
1160 #endif
1170 #ifdef CONFIG_REISERFS_CHECK
1171 iter++;
1172 mode =
1173 #endif
1190 // file system changed, repeat search
1191 ret_value =
1198 item_key);
1200 }
1206 }
1207 // reiserfs_delete_item returns item length when success
1212 /* hack so the quota code doesn't have to guess if the file
1213 ** has a tail. On tail insert, we allocate quota for 1 unformatted node.
1214 ** We test the offset because the tail might have been
1215 ** split into multiple items, and we only want to decrement for
1216 ** the unfm node once
1217 */
1223 }
1224 }
1230 /* We are in direct2indirect conversion, so move tail contents
1231 to the unformatted node */
1232 /* note, we do the copy before preparing the buffer because we
1233 ** don't care about the contents of the unformatted node yet.
1234 ** the only thing we really care about is the direct item's data
1235 ** is in the unformatted node.
1236 **
1237 ** Otherwise, we would have to call reiserfs_prepare_for_journal on
1238 ** the unformatted node, which might schedule, meaning we'd have to
1239 ** loop all the way back up to the start of the while loop.
1240 **
1241 ** The unformatted node must be dirtied later on. We can't be
1242 ** sure here if the entire tail has been deleted yet.
1243 **
1244 ** un_bh is from the page cache (all unformatted nodes are
1245 ** from the page cache) and might be a highmem page. So, we
1246 ** can't use un_bh->b_data.
1247 ** -clm
1248 */
1254 ret_value);
1256 }
1257 /* Perform balancing after all resources have been collected at once. */
1260 #ifdef REISERQUOTA_DEBUG
1264 #endif
1267 /* Return deleted body length */
1269 }
1271 /* Summary Of Mechanisms For Handling Collisions Between Processes:
1273 deletion of the body of the object is performed by iput(), with the
1274 result that if multiple processes are operating on a file, the
1275 deletion of the body of the file is deferred until the last process
1276 that has an open inode performs its iput().
1278 writes and truncates are protected from collisions by use of
1279 semaphores.
1281 creates, linking, and mknod are protected from collisions with other
1282 processes by making the reiserfs_add_entry() the last step in the
1283 creation, and then rolling back all changes if there was a collision.
1284 - Hans
1285 */
1287 /* this deletes item which never gets split */
1290 {
1307 "i/o failure occurred trying "
1310 }
1313 // No need for a warning, if there is just no free space to insert '..' item into the newly-created subdir
1325 }
1331 }
1338 }
1343 #ifdef REISERQUOTA_DEBUG
1348 #endif
1350 quota_cut_bytes);
1351 }
1353 }
1354 // IO_ERROR, NO_DISK_SPACE, etc
1360 }
1363 }
1367 {
1372 /* for directory this deletes item containing "." and ".." */
1373 err =
1378 #if defined( USE_INODE_GENERATION_COUNTER )
1382 inode_generation =
1385 }
1386 /* USE_INODE_GENERATION_COUNTER */
1387 #endif
1391 }
1394 {
1410 /* we want to unmap the buffers that contain the tail, and
1411 ** all the buffers after it (since the tail must be at the
1412 ** end of the file). We don't want to unmap file data
1413 ** before the tail, since it might be dirty and waiting to
1414 ** reach disk
1415 */
1419 }
1422 }
1423 }
1424 }
1432 {
1439 /* the page being sent in could be NULL if there was an i/o error
1440 ** reading in the last block. The user will hit problems trying to
1441 ** read the file, but for now we just skip the indirect2direct
1442 */
1446 /* leave tail in an unformatted node */
1448 cut_bytes =
1452 }
1453 /* Perform the conversion to a direct_item. */
1454 /* return indirect_to_direct(inode, path, item_key,
1455 new_file_size, mode); */
1458 }
1460 /* we did indirect_to_direct conversion. And we have inserted direct
1461 item successesfully, but there were no disk space to cut unfm
1462 pointer being converted. Therefore we have to delete inserted
1463 direct item(s) */
1466 {
1475 tail_len =
1478 /* look for the last byte of the tail */
1480 POSITION_NOT_FOUND)
1488 removed =
1498 }
1500 "conversion has been rolled back due to "
1502 //mark_file_without_tail (inode);
1504 }
1506 /* (Truncate or cut entry) or delete object item. Returns < 0 on failure */
1512 {
1514 /* Every function which is going to call do_balance must first
1515 create a tree_balance structure. Then it must fill up this
1516 structure by using the init_tb_struct and fix_nodes functions.
1517 After that we can make tree balancing. */
1531 cut_size);
1533 /* Repeat this loop until we either cut the item without needing
1534 to balance, or we fix_nodes without schedule occurring */
1536 /* Determine the balance mode, position of the first byte to
1537 be cut, and size to be cut. In case of the indirect item
1538 free unformatted nodes which are pointed to by the cut
1539 pointers. */
1541 mode =
1546 /* convert last unformatted node to direct item or leave
1547 tail in the unformatted node */
1551 ret_value =
1556 /* tail has been left in the unformatted node */
1561 /* removing of last unformatted node will change value we
1562 have to return to truncate. Save it */
1564 /*retval2 = sb->s_blocksize - (new_file_size & (sb->s_blocksize - 1)); */
1566 /* So, we have performed the first part of the conversion:
1567 inserting the new direct item. Now we are removing the
1568 last unformatted node pointer. Set key to search for
1569 it. */
1572 new_file_size -=
1584 item_key);
1585 }
1587 }
1591 }
1601 ret_value =
1607 item_key);
1612 // check fix_nodes results (IO_ERROR or NO_DISK_SPACE)
1615 // FIXME: this seems to be not needed: we are always able
1616 // to cut item
1618 }
1624 }
1626 /* go ahead and perform balancing */
1630 /* Calculate number of bytes that need to be cut from the item. */
1631 quota_cut_bytes =
1637 else
1640 /* For direct items, we only change the quota when deleting the last
1641 ** item.
1642 */
1648 // FIXME: this is to keep 3.5 happy
1653 }
1654 }
1655 #ifdef CONFIG_REISERFS_CHECK
1659 /* we are going to complete indirect2direct conversion. Make
1660 sure, that we exactly remove last unformatted node pointer
1661 of the item */
1668 "indirect2direct conversion indirect "
1669 "item %h being deleted must be of "
1675 "indirect2direct conversion of %h "
1678 }
1679 /* it would be useful to make sure, that right neighboring
1680 item is direct item of this file */
1681 }
1682 #endif
1686 /* we've done an indirect->direct conversion. when the data block
1687 ** was freed, it was removed from the list of blocks that must
1688 ** be flushed before the transaction commits, make sure to
1689 ** unmap and invalidate it
1690 */
1693 }
1694 #ifdef REISERQUOTA_DEBUG
1698 #endif
1701 }
1705 {
1716 }
1718 /* Truncate file to the new size. Note, this must be called with a transaction
1719 already started */
1724 file_release to convert
1725 the tail - no timestamps
1726 should be updated */
1727 )
1728 {
1745 // deletion of directory - no need to update timestamps
1748 }
1750 /* Get new file size. */
1753 // FIXME: note, that key type is unimportant here
1757 retval =
1766 }
1774 }
1778 /* Get real file size (total length of all file items) */
1787 /* this may mismatch with real file size: if last direct item
1788 had no padding zeros and last unformatted node had no free
1789 space, this file would have this file size */
1791 }
1792 /*
1793 * are we doing a full truncate or delete, if so
1794 * kick in the reada code
1795 */
1801 }
1803 /* Update key to search for the last file item. */
1807 /* Cut or delete file item. */
1808 deleted =
1816 }
1819 "PAP-5670: reiserfs_cut_from_item: too many bytes deleted: deleted %d, file_size %lu, item_key %K",
1822 /* Change key to search the last file item. */
1827 /* While there are bytes to truncate and previous file item is presented in the tree. */
1829 /*
1830 ** This loop could take a really long time, and could log
1831 ** many more blocks than a transaction can hold. So, we do a polite
1832 ** journal end here, and if the transaction needs ending, we make
1833 ** sure the file is consistent before ending the current trans
1834 ** and starting a new one
1835 */
1844 }
1855 }
1864 update_and_out:
1866 // this is truncate, not file closing
1869 }
1872 out:
1875 }
1877 #ifdef CONFIG_REISERFS_CHECK
1878 // this makes sure, that we __append__, not overwrite or add holes
1881 {
1893 "%h or position (%d) does not match "
1896 }
1905 "item (%h) or position (%d) does not "
1908 }
1909 }
1912 /* Paste bytes to the existing item. Returns bytes number pasted into the item. */
1913 int reiserfs_paste_into_item(struct reiserfs_transaction_handle *th, struct treepath *search_path, /* Path to the pasted item. */
1927 #ifdef REISERQUOTA_DEBUG
1932 #endif
1937 }
1939 pasted_size);
1940 #ifdef DISPLACE_NEW_PACKING_LOCALITIES
1942 #endif
1944 /* DQUOT_* can schedule, must check before the fix_nodes */
1947 }
1952 search_again:
1953 /* file system changed while we were in the fix_nodes */
1955 retval =
1957 search_path);
1961 }
1965 key);
1968 }
1969 #ifdef CONFIG_REISERFS_CHECK
1971 #endif
1972 }
1974 /* Perform balancing after all resources are collected by fix_nodes, and
1975 accessing them will not risk triggering schedule. */
1979 }
1981 error_out:
1982 /* this also releases the path */
1984 #ifdef REISERQUOTA_DEBUG
1989 #endif
1992 }
1994 /* Insert new item into the buffer at the path.
1995 * th - active transaction handle
1996 * path - path to the inserted item
1997 * ih - pointer to the item header to insert
1998 * body - pointer to the bytes to insert
1999 */
2004 {
2016 /* hack so the quota code doesn't have to guess if the file has
2017 ** a tail, links are always tails, so there's no guessing needed
2018 */
2021 #ifdef REISERQUOTA_DEBUG
2025 #endif
2026 /* We can't dirty inode here. It would be immediately written but
2027 * appropriate stat item isn't inserted yet... */
2031 }
2032 }
2035 #ifdef DISPLACE_NEW_PACKING_LOCALITIES
2037 #endif
2038 /* DQUOT_* can schedule, must check to be sure calling fix_nodes is safe */
2041 }
2046 search_again:
2047 /* file system changed while we were in the fix_nodes */
2053 }
2057 key);
2060 }
2061 }
2063 /* make balancing after all resources will be collected at a time */
2067 }
2070 error_out:
2071 /* also releases the path */
2073 #ifdef REISERQUOTA_DEBUG
2077 #endif
2081 }