| blob | 8bf88d690729e38e8cb278df108adcbb06d882e7 |
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 #include <linux/time.h>
12 #include <linux/string.h>
13 #include <linux/pagemap.h>
14 #include <linux/bio.h>
16 #include <linux/buffer_head.h>
17 #include <linux/quotaops.h>
19 /* Does the buffer contain a disk block which is in the tree. */
21 {
27 }
29 /* to get item head in le form */
32 {
34 }
36 /*
37 * k1 is pointer to on-disk structure which is stored in little-endian
38 * form. k2 is pointer to cpu variable. For key of items of the same
39 * object this returns 0.
40 * Returns: -1 if key1 < key2
41 * 0 if key1 == key2
42 * 1 if key1 > key2
43 */
46 {
47 __u32 n;
59 }
61 /*
62 * k1 is pointer to on-disk structure which is stored in little-endian
63 * form. k2 is pointer to cpu variable.
64 * Compare keys using all 4 key fields.
65 * Returns: -1 if key1 < key2 0
66 * if key1 = key2 1 if key1 > key2
67 */
70 {
86 /* this part is needed only when tail conversion is in progress */
96 }
100 {
111 }
113 }
116 {
121 /* find out version of the key */
126 }
128 /*
129 * this does not say which one is bigger, it only returns 1 if keys
130 * are not equal, 0 otherwise
131 */
134 {
136 }
138 /**************************************************************************
139 * Binary search toolkit function *
140 * Search for an item in the array by the item key *
141 * Returns: 1 if found, 0 if not found; *
142 * *pos = number of the searched element if found, else the *
143 * number of the first element that is larger than key. *
144 **************************************************************************/
145 /*
146 * For those not familiar with binary search: lbound is the leftmost item
147 * that it could be, rbound the rightmost item that it could be. We examine
148 * the item halfway between lbound and rbound, and that tells us either
149 * that we can increase lbound, or decrease rbound, or that we have found it,
150 * or if lbound <= rbound that there are no possible items, and we have not
151 * found it. With each examination we cut the number of possible items it
152 * could be by one more than half rounded down, or we find it.
153 */
157 /*
158 * Item size in the array. searched. Lest the
159 * reader be confused, note that this is crafted
160 * as a general function, and when it is applied
161 * specifically to the array of item headers in a
162 * node, width is actually the item header size
163 * not the item size.
164 */
167 )
168 {
185 }
187 /*
188 * bin_search did not find given key, it returns position of key,
189 * that is minimal and greater than the given one.
190 */
193 }
196 /* Minimal possible key. It is never in the tree. */
199 /* Maximal possible key. It is never in the tree. */
205 };
207 /*
208 * Get delimiting key of the buffer by looking for it in the buffers in the
209 * path, starting from the bottom of the path, and going upwards. We must
210 * check the path's validity at each step. If the key is not in the path,
211 * there is no delimiting key in the tree (buffer is first or last buffer
212 * in tree), and in this case we return a special key, either MIN_KEY or
213 * MAX_KEY.
214 */
217 {
224 /* While not higher in path than first element. */
231 /* Parent at the path is not in the tree now. */
236 /* Check whether position in the parent is correct. */
239 path_offset)) >
242 /* Check whether parent at the path really points to the child. */
247 /*
248 * Return delimiting key if position in the parent
249 * is not equal to zero.
250 */
253 }
254 /* Return MIN_KEY if we are in the root of the buffer tree. */
259 }
261 /* Get delimiting key of the buffer at the path and its right neighbor. */
264 {
277 /* Parent at the path is not in the tree now. */
282 /* Check whether position in the parent is correct. */
285 path_offset)) >
288 /*
289 * Check whether parent at the path really points
290 * to the child.
291 */
297 /*
298 * Return delimiting key if position in the parent
299 * is not the last one.
300 */
303 }
305 /* Return MAX_KEY if we are in the root of the buffer tree. */
310 }
312 /*
313 * Check whether a key is contained in the tree rooted from a buffer at a path.
314 * This works by looking at the left and right delimiting keys for the buffer
315 * in the last path_element in the path. These delimiting keys are stored
316 * at least one level above that buffer in the tree. If the buffer is the
317 * first or last node in the tree order then one of the delimiting keys may
318 * be absent, and in this case get_lkey and get_rkey return a special key
319 * which is MIN_KEY or MAX_KEY.
320 */
322 /* Path which should be checked. */
324 /* Key which should be checked. */
327 )
328 {
338 /* left delimiting key is bigger, that the key we look for */
340 /* if ( comp_keys(key, get_rkey(chk_path, sb)) != -1 ) */
342 /* key must be less than right delimitiing key */
345 }
348 {
352 }
354 /*
355 * Drop the reference to each buffer in a path and restore
356 * dirty bits clean when preparing the buffer for the log.
357 * This version should only be called from fix_nodes()
358 */
361 {
372 }
374 }
376 /* Drop the reference to each buffer in a path */
378 {
388 }
391 {
404 }
408 /* item number is too big or too small */
412 }
416 /* free space does not match to calculated amount of use space */
421 }
422 /*
423 * FIXME: it is_leaf will hit performance too much - we may have
424 * return 1 here
425 */
427 /* check tables of item heads */
434 ih);
436 }
441 ih);
443 }
448 ih);
450 }
453 "item location seems wrong "
456 }
458 }
460 /* one may imagine many more checks */
462 }
464 /* returns 1 if buf looks like an internal node, 0 otherwise */
466 {
474 /* this level is not possible for internal nodes */
478 }
481 /* for internal which is not root we might check min number of keys */
486 }
493 }
495 /* one may imagine many more checks */
497 }
499 /*
500 * make sure that bh contains formatted node of reiserfs tree of
501 * 'level'-th level
502 */
504 {
510 }
515 }
517 #define SEARCH_BY_KEY_READA 16
519 /*
520 * The function is NOT SCHEDULE-SAFE!
521 * It might unlock the write lock if we needed to wait for a block
522 * to be read. Note that in this case it won't recover the lock to avoid
523 * high contention resulting from too much lock requests, especially
524 * the caller (search_by_key) will perform other schedule-unsafe
525 * operations just after calling this function.
526 *
527 * @return depth of lock to be restored after read completes
528 */
532 {
538 }
539 /*
540 * We are going to read some blocks on which we
541 * have a reference. It's safe, though we might be
542 * reading blocks concurrently changed if we release
543 * the lock. But it's still fine because we check later
544 * if the tree changed
545 */
547 /*
548 * note, this needs attention if we are getting rid of the BKL
549 * you have to make sure the prepared bit isn't set on this
550 * buffer
551 */
556 }
558 }
560 }
562 /*
563 * This function fills up the path from the root to the leaf as it
564 * descends the tree looking for the key. It uses reiserfs_bread to
565 * try to find buffers in the cache given their block number. If it
566 * does not find them in the cache it reads them from disk. For each
567 * node search_by_key finds using reiserfs_bread it then uses
568 * bin_search to look through that node. bin_search will find the
569 * position of the block_number of the next node if it is looking
570 * through an internal node. If it is looking through a leaf node
571 * bin_search will find the position of the item which has key either
572 * equal to given key, or which is the maximal key less than the given
573 * key. search_by_key returns a path that must be checked for the
574 * correctness of the top of the path but need not be checked for the
575 * correctness of the bottom of the path
576 */
577 /*
578 * search_by_key - search for key (and item) in stree
579 * @sb: superblock
580 * @key: pointer to key to search for
581 * @search_path: Allocated and initialized struct treepath; Returned filled
582 * on success.
583 * @stop_level: How far down the tree to search, Use DISK_LEAF_NODE_LEVEL to
584 * stop at leaf level.
585 *
586 * The function is NOT SCHEDULE-SAFE!
587 */
590 {
591 b_blocknr_t block_number;
601 #ifdef CONFIG_REISERFS_CHECK
603 #endif
607 /*
608 * As we add each node to a path we increase its count. This means
609 * that we must be careful to release all nodes in a path before we
610 * either discard the path struct or re-use the path struct, as we
611 * do here.
612 */
616 /*
617 * With each iteration of this loop we search through the items in the
618 * current node, and calculate the next current node(next path element)
619 * for the next iteration of this loop..
620 */
625 #ifdef CONFIG_REISERFS_CHECK
628 "%s: there were %d iterations of "
631 key);
632 #endif
634 /* prep path to have another element added to it. */
635 last_element =
640 /*
641 * Read the next tree node, and set the last element
642 * in the path to have a pointer to it.
643 */
647 /*
648 * We'll need to drop the lock if we encounter any
649 * buffers that need to be read. If all of them are
650 * already up to date, we don't need to drop the lock.
651 */
669 io_error:
673 }
677 expected_level--;
679 /*
680 * It is possible that schedule occurred. We must check
681 * whether the key to search is still in the tree rooted
682 * from the current buffer. If not then repeat search
683 * from the root.
684 */
695 /*
696 * Get the root block number so that we can
697 * repeat the search starting from the root.
698 */
702 /* repeat search from the root */
704 }
706 /*
707 * only check that the key is in the buffer if key is not
708 * equal to the MAX_KEY. Latter case is only possible in
709 * "finish_unfinished()" processing during mount.
710 */
714 #ifdef CONFIG_REISERFS_CHECK
719 }
720 #endif
722 /*
723 * make sure, that the node contents look like a node of
724 * certain level
725 */
728 "invalid format found in block %ld. "
732 }
734 /* ok, we have acquired next formatted node in the tree */
747 KEY_SIZE,
751 }
753 /* we are not in the stop level */
754 /*
755 * item has been found, so we choose the pointer which
756 * is to the right of the found one
757 */
761 /*
762 * if item was not found we choose the position which is to
763 * the left of the found item. This requires no code,
764 * bin_search did it already.
765 */
767 /*
768 * So we have chosen a position in the current node which is
769 * an internal node. Now we calculate child block number by
770 * position in the node.
771 */
772 block_number =
775 /*
776 * if we are going to read leaf nodes, try for read
777 * ahead as well
778 */
793 pos--;
794 else
795 pos++;
797 /*
798 * check to make sure we're in the same object
799 */
804 }
805 }
806 }
807 }
808 }
810 /*
811 * Form the path to an item and position in this item which contains
812 * file byte defined by key. If there is no such item
813 * corresponding to the key, we point the path to the item with
814 * maximal key less than key, and *pos_in_item is set to one
815 * past the last entry/byte in the item. If searching for entry in a
816 * directory item, and it is not found, *pos_in_item is set to one
817 * entry more than the entry with maximal key which is less than the
818 * sought key.
819 *
820 * Note that if there is no entry in this same node which is one more,
821 * then we point to an imaginary entry. for direct items, the
822 * position is in units of bytes, for indirect items the position is
823 * in units of blocknr entries, for directory items the position is in
824 * units of directory entries.
825 */
826 /* The function is NOT SCHEDULE-SAFE! */
828 /* Key to search (cpu variable) */
830 /* Filled up by this function. */
832 {
839 /* If searching for directory entry. */
844 /* If not searching for directory entry. */
846 /* If item is found. */
853 (item_head
860 }
865 /* Item is not found. Set path to the previous item. */
866 p_le_ih =
874 /* FIXME: quite ugly this far */
879 /* Needed byte is contained in the item pointed to by the path. */
885 }
887 }
889 /*
890 * Needed byte is not contained in the item pointed to by the
891 * path. Set pos_in_item out of the item.
892 */
896 else
900 }
902 /* Compare given item and item pointed to by the path. */
904 {
908 /* Last buffer at the path is not in the tree. */
912 /* Last path position is invalid. */
916 /* we need only to know, whether it is the same item */
919 }
921 /* prepare for delete or cut of direct item */
926 {
927 loff_t round_len;
930 /* item has to be deleted */
933 }
934 /* new file gets truncated */
937 /* this was new_file_length < le_ih ... */
941 }
942 /* Calculate first position and size for cutting from item. */
947 }
949 /* old file: items may have any length */
954 }
956 /* Calculate first position and size for cutting from item. */
961 }
966 loff_t new_file_length,
968 {
974 /* Delete the directory item containing "." and ".." entry. */
976 }
979 /*
980 * Delete the directory item such as there is one record only
981 * in this item
982 */
985 }
987 /* Cut one record from the directory item. */
992 }
994 #define JOURNAL_FOR_FREE_BLOCK_AND_UPDATE_SD (2 * JOURNAL_PER_BALANCE_CNT + 1)
996 /*
997 * If the path points to a directory or direct item, calculate mode
998 * and the size cut, for balance.
999 * If the path points to an indirect item, remove some number of its
1000 * unformatted nodes.
1001 * In case of file truncate calculate whether this item must be
1002 * deleted/truncated or last unformatted node of this item will be
1003 * converted to a direct item.
1004 * This function returns a determination of what balance mode the
1005 * calling function should employ.
1006 */
1011 /*
1012 * Number of unformatted nodes
1013 * which were removed from end
1014 * of the file.
1015 */
1018 /* MAX_KEY_OFFSET in case of delete. */
1019 unsigned long long new_file_length
1020 )
1021 {
1028 /* Stat_data item. */
1036 }
1038 /* Directory item. */
1041 new_file_length,
1042 cut_size);
1044 /* Direct item. */
1049 /* Case of an indirect item. */
1050 {
1059 /*
1060 * prepare_for_delete_or_cut() is called by
1061 * reiserfs_delete_item()
1062 */
1065 }
1076 __u32 block;
1078 /*
1079 * Each unformatted block deletion may involve
1080 * one additional bitmap block into the transaction,
1081 * thereby the initial journal space reservation
1082 * might not be enough.
1083 */
1096 }
1103 }
1105 pos --;
1113 }
1114 }
1115 /*
1116 * a trick. If the buffer has been logged, this will
1117 * do nothing. If we've broken the loop without logging
1118 * it, it will restore the buffer
1119 */
1126 /*
1127 * Nothing was cut. maybe convert last unformatted node to the
1128 * direct item?
1129 */
1131 }
1133 }
1134 }
1136 /* Calculate number of bytes which will be deleted or cut during balance */
1138 {
1145 del_size =
1149 /*
1150 * return EMPTY_DIR_SIZE; We delete emty directories only.
1151 * we can't use EMPTY_DIR_SIZE, as old format dirs have a
1152 * different empty size. ick. FIXME, is this right?
1153 */
1155 }
1161 }
1167 {
1178 }
1181 {
1186 }
1188 #ifdef REISERQUOTA_DEBUG
1190 {
1200 }
1203 {
1213 }
1214 #endif
1216 /*
1217 * Delete object item.
1218 * th - active transaction handle
1219 * path - path to the deleted item
1220 * item_key - key to search for the deleted item
1221 * indode - used for updating i_blocks and quotas
1222 * un_bh - NULL or unformatted node pointer
1223 */
1227 {
1236 #ifdef CONFIG_REISERFS_CHECK
1239 #endif
1249 #ifdef CONFIG_REISERFS_CHECK
1250 iter++;
1251 mode =
1252 #endif
1269 /* file system changed, repeat search */
1270 ret_value =
1277 item_key);
1279 }
1285 }
1287 /* reiserfs_delete_item returns item length when success */
1292 /*
1293 * hack so the quota code doesn't have to guess if the file has a
1294 * tail. On tail insert, we allocate quota for 1 unformatted node.
1295 * We test the offset because the tail might have been
1296 * split into multiple items, and we only want to decrement for
1297 * the unfm node once
1298 */
1304 }
1305 }
1311 /*
1312 * We are in direct2indirect conversion, so move tail contents
1313 * to the unformatted node
1314 */
1315 /*
1316 * note, we do the copy before preparing the buffer because we
1317 * don't care about the contents of the unformatted node yet.
1318 * the only thing we really care about is the direct item's
1319 * data is in the unformatted node.
1320 *
1321 * Otherwise, we would have to call
1322 * reiserfs_prepare_for_journal on the unformatted node,
1323 * which might schedule, meaning we'd have to loop all the
1324 * way back up to the start of the while loop.
1325 *
1326 * The unformatted node must be dirtied later on. We can't be
1327 * sure here if the entire tail has been deleted yet.
1328 *
1329 * un_bh is from the page cache (all unformatted nodes are
1330 * from the page cache) and might be a highmem page. So, we
1331 * can't use un_bh->b_data.
1332 * -clm
1333 */
1339 ret_value);
1341 }
1343 /* Perform balancing after all resources have been collected at once. */
1346 #ifdef REISERQUOTA_DEBUG
1350 #endif
1355 /* Return deleted body length */
1357 }
1359 /*
1360 * Summary Of Mechanisms For Handling Collisions Between Processes:
1361 *
1362 * deletion of the body of the object is performed by iput(), with the
1363 * result that if multiple processes are operating on a file, the
1364 * deletion of the body of the file is deferred until the last process
1365 * that has an open inode performs its iput().
1366 *
1367 * writes and truncates are protected from collisions by use of
1368 * semaphores.
1369 *
1370 * creates, linking, and mknod are protected from collisions with other
1371 * processes by making the reiserfs_add_entry() the last step in the
1372 * creation, and then rolling back all changes if there was a collision.
1373 * - Hans
1374 */
1376 /* this deletes item which never gets split */
1379 {
1397 "i/o failure occurred trying "
1400 }
1403 /*
1404 * No need for a warning, if there is just no free
1405 * space to insert '..' item into the
1406 * newly-created subdir
1407 */
1419 }
1425 }
1432 }
1436 /*
1437 * Should we count quota for item? (we don't
1438 * count quotas for save-links)
1439 */
1442 #ifdef REISERQUOTA_DEBUG
1447 #endif
1450 quota_cut_bytes);
1452 }
1454 }
1456 /* IO_ERROR, NO_DISK_SPACE, etc */
1462 }
1465 }
1469 {
1474 /* for directory this deletes item containing "." and ".." */
1475 err =
1480 #if defined( USE_INODE_GENERATION_COUNTER )
1484 inode_generation =
1487 }
1488 /* USE_INODE_GENERATION_COUNTER */
1489 #endif
1493 }
1496 {
1512 /*
1513 * we want to unmap the buffers that contain
1514 * the tail, and all the buffers after it
1515 * (since the tail must be at the end of the
1516 * file). We don't want to unmap file data
1517 * before the tail, since it might be dirty
1518 * and waiting to reach disk
1519 */
1523 }
1526 }
1527 }
1528 }
1536 {
1543 /*
1544 * the page being sent in could be NULL if there was an i/o error
1545 * reading in the last block. The user will hit problems trying to
1546 * read the file, but for now we just skip the indirect2direct
1547 */
1551 /* leave tail in an unformatted node */
1553 cut_bytes =
1557 }
1559 /* Perform the conversion to a direct_item. */
1562 }
1564 /*
1565 * we did indirect_to_direct conversion. And we have inserted direct
1566 * item successesfully, but there were no disk space to cut unfm
1567 * pointer being converted. Therefore we have to delete inserted
1568 * direct item(s)
1569 */
1572 {
1581 tail_len =
1584 /* look for the last byte of the tail */
1586 POSITION_NOT_FOUND)
1594 removed =
1604 }
1606 "conversion has been rolled back due to "
1609 }
1611 /* (Truncate or cut entry) or delete object item. Returns < 0 on failure */
1617 {
1619 /*
1620 * Every function which is going to call do_balance must first
1621 * create a tree_balance structure. Then it must fill up this
1622 * structure by using the init_tb_struct and fix_nodes functions.
1623 * After that we can make tree balancing.
1624 */
1640 cut_size);
1642 /*
1643 * Repeat this loop until we either cut the item without needing
1644 * to balance, or we fix_nodes without schedule occurring
1645 */
1647 /*
1648 * Determine the balance mode, position of the first byte to
1649 * be cut, and size to be cut. In case of the indirect item
1650 * free unformatted nodes which are pointed to by the cut
1651 * pointers.
1652 */
1654 mode =
1659 /*
1660 * convert last unformatted node to direct item or
1661 * leave tail in the unformatted node
1662 */
1666 ret_value =
1671 /* tail has been left in the unformatted node */
1676 /*
1677 * removing of last unformatted node will
1678 * change value we have to return to truncate.
1679 * Save it
1680 */
1683 /*
1684 * So, we have performed the first part of the
1685 * conversion:
1686 * inserting the new direct item. Now we are
1687 * removing the last unformatted node pointer.
1688 * Set key to search for it.
1689 */
1692 new_file_size -=
1704 item_key);
1705 }
1707 }
1711 }
1721 ret_value =
1727 item_key);
1732 /* check fix_nodes results (IO_ERROR or NO_DISK_SPACE) */
1735 /*
1736 * FIXME: this seems to be not needed: we are always
1737 * able to cut item
1738 */
1740 }
1746 }
1748 /* go ahead and perform balancing */
1752 /* Calculate number of bytes that need to be cut from the item. */
1753 quota_cut_bytes =
1759 else
1762 /*
1763 * For direct items, we only change the quota when deleting the last
1764 * item.
1765 */
1771 /* FIXME: this is to keep 3.5 happy */
1776 }
1777 }
1778 #ifdef CONFIG_REISERFS_CHECK
1782 /*
1783 * we are going to complete indirect2direct conversion. Make
1784 * sure, that we exactly remove last unformatted node pointer
1785 * of the item
1786 */
1793 "indirect2direct conversion indirect "
1794 "item %h being deleted must be of "
1800 "indirect2direct conversion of %h "
1803 }
1804 /*
1805 * it would be useful to make sure, that right neighboring
1806 * item is direct item of this file
1807 */
1808 }
1809 #endif
1813 /*
1814 * we've done an indirect->direct conversion. when the
1815 * data block was freed, it was removed from the list of
1816 * blocks that must be flushed before the transaction
1817 * commits, make sure to unmap and invalidate it
1818 */
1821 }
1822 #ifdef REISERQUOTA_DEBUG
1826 #endif
1831 }
1835 {
1846 }
1848 /*
1849 * Truncate file to the new size. Note, this must be called with a
1850 * transaction already started
1851 */
1855 /*
1856 * when it is called by file_release to convert
1857 * the tail - no timestamps should be updated
1858 */
1859 int update_timestamps
1860 )
1861 {
1865 /* Key to search for a previous file item. */
1879 /* deletion of directory - no need to update timestamps */
1883 }
1885 /* Get new file size. */
1888 /* FIXME: note, that key type is unimportant here */
1892 retval =
1901 }
1909 }
1913 /* Get real file size (total length of all file items) */
1922 /*
1923 * this may mismatch with real file size: if last direct item
1924 * had no padding zeros and last unformatted node had no free
1925 * space, this file would have this file size
1926 */
1928 }
1929 /*
1930 * are we doing a full truncate or delete, if so
1931 * kick in the reada code
1932 */
1938 }
1940 /* Update key to search for the last file item. */
1944 /* Cut or delete file item. */
1945 deleted =
1953 }
1956 "PAP-5670: reiserfs_cut_from_item: too many bytes deleted: deleted %d, file_size %lu, item_key %K",
1959 /* Change key to search the last file item. */
1964 /*
1965 * While there are bytes to truncate and previous
1966 * file item is presented in the tree.
1967 */
1969 /*
1970 * This loop could take a really long time, and could log
1971 * many more blocks than a transaction can hold. So, we do
1972 * a polite journal end here, and if the transaction needs
1973 * ending, we make sure the file is consistent before ending
1974 * the current trans and starting a new one
1975 */
1983 }
1994 }
2003 update_and_out:
2005 /* this is truncate, not file closing */
2008 }
2011 out:
2014 }
2016 #ifdef CONFIG_REISERFS_CHECK
2017 /* this makes sure, that we __append__, not overwrite or add holes */
2020 {
2032 "%h or position (%d) does not match "
2035 }
2044 "item (%h) or position (%d) does not "
2047 }
2048 }
2051 /*
2052 * Paste bytes to the existing item.
2053 * Returns bytes number pasted into the item.
2054 */
2056 /* Path to the pasted item. */
2058 /* Key to search for the needed item. */
2060 /* Inode item belongs to */
2062 /* Pointer to the bytes to paste. */
2064 /* Size of pasted bytes. */
2066 {
2077 #ifdef REISERQUOTA_DEBUG
2082 #endif
2090 }
2092 pasted_size);
2093 #ifdef DISPLACE_NEW_PACKING_LOCALITIES
2095 #endif
2097 /* DQUOT_* can schedule, must check before the fix_nodes */
2100 }
2105 search_again:
2106 /* file system changed while we were in the fix_nodes */
2108 retval =
2110 search_path);
2114 }
2118 key);
2121 }
2122 #ifdef CONFIG_REISERFS_CHECK
2124 #endif
2125 }
2127 /*
2128 * Perform balancing after all resources are collected by fix_nodes,
2129 * and accessing them will not risk triggering schedule.
2130 */
2134 }
2136 error_out:
2137 /* this also releases the path */
2139 #ifdef REISERQUOTA_DEBUG
2144 #endif
2149 }
2151 /*
2152 * Insert new item into the buffer at the path.
2153 * th - active transaction handle
2154 * path - path to the inserted item
2155 * ih - pointer to the item header to insert
2156 * body - pointer to the bytes to insert
2157 */
2162 {
2175 /*
2176 * hack so the quota code doesn't have to guess
2177 * if the file has a tail, links are always tails,
2178 * so there's no guessing needed
2179 */
2182 #ifdef REISERQUOTA_DEBUG
2186 #endif
2187 /*
2188 * We can't dirty inode here. It would be immediately
2189 * written but appropriate stat item isn't inserted yet...
2190 */
2197 }
2198 }
2201 #ifdef DISPLACE_NEW_PACKING_LOCALITIES
2203 #endif
2204 /*
2205 * DQUOT_* can schedule, must check to be sure calling
2206 * fix_nodes is safe
2207 */
2210 }
2215 search_again:
2216 /* file system changed while we were in the fix_nodes */
2222 }
2226 key);
2229 }
2230 }
2232 /* make balancing after all resources will be collected at a time */
2236 }
2239 error_out:
2240 /* also releases the path */
2242 #ifdef REISERQUOTA_DEBUG
2247 #endif
2252 }
2254 }