| blob | 778a850b4634755c897c9708b2e2062e995e589b |
1 /* -*- mode: c; c-basic-offset: 8; -*-
2 * vim: noexpandtab sw=8 ts=8 sts=0:
3 *
4 * alloc.c
5 *
6 * Extent allocs and frees
7 *
8 * Copyright (C) 2002, 2004 Oracle. All rights reserved.
9 *
10 * This program is free software; you can redistribute it and/or
11 * modify it under the terms of the GNU General Public
12 * License as published by the Free Software Foundation; either
13 * version 2 of the License, or (at your option) any later version.
14 *
15 * This program is distributed in the hope that it will be useful,
16 * but WITHOUT ANY WARRANTY; without even the implied warranty of
17 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
18 * General Public License for more details.
19 *
20 * You should have received a copy of the GNU General Public
21 * License along with this program; if not, write to the
22 * Free Software Foundation, Inc., 59 Temple Place - Suite 330,
23 * Boston, MA 021110-1307, USA.
24 */
26 #include <linux/fs.h>
27 #include <linux/types.h>
28 #include <linux/slab.h>
29 #include <linux/highmem.h>
30 #include <linux/swap.h>
32 #define MLOG_MASK_PREFIX ML_DISK_ALLOC
33 #include <cluster/masklog.h>
56 /*
57 * Structures which describe a path through a btree, and functions to
58 * manipulate them.
59 *
60 * The idea here is to be as generic as possible with the tree
61 * manipulation code.
62 */
66 };
68 #define OCFS2_MAX_PATH_DEPTH 5
73 };
75 #define path_root_bh(_path) ((_path)->p_node[0].bh)
76 #define path_root_el(_path) ((_path)->p_node[0].el)
77 #define path_leaf_bh(_path) ((_path)->p_node[(_path)->p_tree_depth].bh)
78 #define path_leaf_el(_path) ((_path)->p_node[(_path)->p_tree_depth].el)
79 #define path_num_items(_path) ((_path)->p_tree_depth + 1)
81 /*
82 * Reset the actual path elements so that we can re-use the structure
83 * to build another path. Generally, this involves freeing the buffer
84 * heads.
85 */
87 {
100 }
102 /*
103 * Tree depth may change during truncate, or insert. If we're
104 * keeping the root extent list, then make sure that our path
105 * structure reflects the proper depth.
106 */
111 }
114 {
118 }
119 }
121 /*
122 * All the elements of src into dest. After this call, src could be freed
123 * without affecting dest.
124 *
125 * Both paths should have the same root. Any non-root elements of dest
126 * will be freed.
127 */
129 {
143 }
144 }
146 /*
147 * Make the *dest path the same as src and re-initialize src path to
148 * have a root only.
149 */
151 {
164 }
165 }
167 /*
168 * Insert an extent block at given index.
169 *
170 * This will not take an additional reference on eb_bh.
171 */
174 {
177 /*
178 * Right now, no root bh is an extent block, so this helps
179 * catch code errors with dinode trees. The assertion can be
180 * safely removed if we ever need to insert extent block
181 * structures at the root.
182 */
187 }
191 {
202 }
205 }
207 /*
208 * Allocate and initialize a new path based on a disk inode tree.
209 */
211 {
216 }
218 /*
219 * Convenience function to journal all components in a path.
220 */
223 {
231 OCFS2_JOURNAL_ACCESS_WRITE);
235 }
236 }
238 out:
240 }
242 /*
243 * Return the index of the extent record which contains cluster #v_cluster.
244 * -1 is returned if it was not found.
245 *
246 * Should work fine on interior and exterior nodes.
247 */
249 {
266 }
267 }
270 }
274 CONTIG_LEFT,
275 CONTIG_RIGHT,
276 CONTIG_LEFTRIGHT,
277 };
280 /*
281 * NOTE: ocfs2_block_extent_contig(), ocfs2_extents_adjacent() and
282 * ocfs2_extent_contig only work properly against leaf nodes!
283 */
286 u64 blkno)
287 {
294 }
298 {
299 u32 left_range;
305 }
307 static enum ocfs2_contig_type
311 {
314 /*
315 * Refuse to coalesce extent records with different flag
316 * fields - we don't want to mix unwritten extents with user
317 * data.
318 */
332 }
334 /*
335 * NOTE: We can have pretty much any combination of contiguousness and
336 * appending.
337 *
338 * The usefulness of APPEND_TAIL is more in that it lets us know that
339 * we'll have to update the path to that leaf.
340 */
343 APPEND_TAIL,
344 };
348 SPLIT_LEFT,
349 SPLIT_RIGHT,
350 };
359 };
366 };
368 /*
369 * How many free extents have we got before we need more meta data?
370 */
374 {
386 }
394 }
403 bail:
409 }
411 /* expects array to already be allocated
412 *
413 * sets h_signature, h_blkno, h_suballoc_bit, h_suballoc_slot, and
414 * l_count for you
415 */
422 {
424 u16 suballoc_bit_start;
425 u32 num_got;
426 u64 first_blkno;
434 handle,
435 meta_ac,
443 }
451 }
455 OCFS2_JOURNAL_ACCESS_CREATE);
459 }
463 /* Ok, setup the minimal stuff here. */
472 suballoc_bit_start++;
473 first_blkno++;
475 /* We'll also be dirtied by the caller, so
476 * this isn't absolutely necessary. */
481 }
482 }
485 }
488 bail:
494 }
495 }
498 }
500 /*
501 * Helper function for ocfs2_add_branch() and ocfs2_shift_tree_depth().
502 *
503 * Returns the sum of the rightmost extent rec logical offset and
504 * cluster count.
505 *
506 * ocfs2_add_branch() uses this to determine what logical cluster
507 * value should be populated into the leftmost new branch records.
508 *
509 * ocfs2_shift_tree_depth() uses this to determine the # clusters
510 * value for the new topmost tree record.
511 */
513 {
520 }
522 /*
523 * Add an entire tree branch to our inode. eb_bh is the extent block
524 * to start at, if we don't want to start the branch at the dinode
525 * structure.
526 *
527 * last_eb_bh is required as we have to update it's next_leaf pointer
528 * for the new last extent block.
529 *
530 * the new branch will be 'empty' in the sense that every block will
531 * contain a single record with cluster count == 0.
532 */
540 {
549 u32 new_cpos;
563 /* we never add a branch to a leaf. */
568 /* allocate the number of new eb blocks we need */
570 GFP_KERNEL);
575 }
582 }
587 /* Note: new_eb_bhs[new_blocks - 1] is the guy which will be
588 * linked with the rest of the tree.
589 * conversly, new_eb_bhs[0] is the new bottommost leaf.
590 *
591 * when we leave the loop, new_last_eb_blk will point to the
592 * newest leaf, and next_blkno will point to the topmost extent
593 * block. */
602 }
606 OCFS2_JOURNAL_ACCESS_CREATE);
610 }
615 /*
616 * This actually counts as an empty extent as
617 * c_clusters == 0
618 */
621 /*
622 * eb_el isn't always an interior node, but even leaf
623 * nodes want a zero'd flags and reserved field so
624 * this gets the whole 32 bits regardless of use.
625 */
634 }
637 }
639 /* This is a bit hairy. We want to update up to three blocks
640 * here without leaving any of them in an inconsistent state
641 * in case of error. We don't have to worry about
642 * journal_dirty erroring as it won't unless we've aborted the
643 * handle (in which case we would never be here) so reserving
644 * the write with journal_access is all we need to do. */
646 OCFS2_JOURNAL_ACCESS_WRITE);
650 }
652 OCFS2_JOURNAL_ACCESS_WRITE);
656 }
659 OCFS2_JOURNAL_ACCESS_WRITE);
663 }
664 }
666 /* Link the new branch into the rest of the tree (el will
667 * either be on the fe, or the extent block passed in. */
674 /* fe needs a new last extent block pointer, as does the
675 * next_leaf on the previously last-extent-block. */
691 }
693 /*
694 * Some callers want to track the rightmost leaf so pass it
695 * back here.
696 */
702 bail:
708 }
712 }
714 /*
715 * adds another level to the allocation tree.
716 * returns back the new extent block so you can add a branch to it
717 * after this call.
718 */
725 {
727 u32 new_clusters;
741 }
748 }
755 OCFS2_JOURNAL_ACCESS_CREATE);
759 }
761 /* copy the fe data into the new extent block */
771 }
774 OCFS2_JOURNAL_ACCESS_WRITE);
778 }
782 /* update fe now */
791 /* If this is our 1st tree depth shift, then last_eb_blk
792 * becomes the allocated extent block */
800 }
805 bail:
811 }
813 /*
814 * Should only be called when there is no space left in any of the
815 * leaf nodes. What we want to do is find the lowest tree depth
816 * non-leaf extent block with room for new records. There are three
817 * valid results of this search:
818 *
819 * 1) a lowest extent block is found, then we pass it back in
820 * *lowest_eb_bh and return '0'
821 *
822 * 2) the search fails to find anything, but the dinode has room. We
823 * pass NULL back in *lowest_eb_bh, but still return '0'
824 *
825 * 3) the search fails to find anything AND the dinode is full, in
826 * which case we return > 0
827 *
828 * return status < 0 indicates an error.
829 */
834 {
836 u64 blkno;
857 }
862 "list where extent # %d has no physical "
867 }
872 }
875 inode);
879 }
886 }
895 }
896 }
898 /* If we didn't find one and the fe doesn't have any room,
899 * then return '1' */
905 bail:
911 }
913 /*
914 * Grow a b-tree so that it has more records.
915 *
916 * We might shift the tree depth in which case existing paths should
917 * be considered invalid.
918 *
919 * Tree depth after the grow is returned via *final_depth.
920 *
921 * *last_eb_bh will be updated by ocfs2_add_branch().
922 */
927 {
941 }
943 /* We traveled all the way to the bottom of the allocation tree
944 * and didn't find room for any more extents - we need to add
945 * another tree level */
950 /* ocfs2_shift_tree_depth will return us a buffer with
951 * the new extent block (so we can pass that to
952 * ocfs2_add_branch). */
958 }
959 depth++;
961 /*
962 * Special case: we have room now if we shifted from
963 * tree_depth 0, so no more work needs to be done.
964 *
965 * We won't be calling add_branch, so pass
966 * back *last_eb_bh as the new leaf. At depth
967 * zero, it should always be null so there's
968 * no reason to brelse.
969 */
974 }
975 }
977 /* call ocfs2_add_branch to add the final part of the tree with
978 * the new data. */
981 meta_ac);
985 }
987 out:
992 }
994 /*
995 * This is only valid for leaf nodes, which are the only ones that can
996 * have empty extents anyway.
997 */
999 {
1001 }
1003 /*
1004 * This function will discard the rightmost extent record.
1005 */
1007 {
1013 /* This will cause us to go off the end of our extent list. */
1019 }
1023 {
1033 /* The tree code before us didn't allow enough room in the leaf. */
1037 /*
1038 * The easiest way to approach this is to just remove the
1039 * empty extent and temporarily decrement next_free.
1040 */
1042 /*
1043 * If next_free was 1 (only an empty extent), this
1044 * loop won't execute, which is fine. We still want
1045 * the decrement above to happen.
1046 */
1050 next_free--;
1051 }
1053 /*
1054 * Figure out what the new record index should be.
1055 */
1061 }
1071 /*
1072 * No need to memmove if we're just adding to the tail.
1073 */
1081 num_bytes);
1082 }
1084 /*
1085 * Either we had an empty extent, and need to re-increment or
1086 * there was no empty extent on a non full rightmost leaf node,
1087 * in which case we still need to increment.
1088 */
1089 next_free++;
1091 /*
1092 * Make sure none of the math above just messed up our tree.
1093 */
1098 }
1101 {
1107 num_recs--;
1113 }
1114 }
1116 /*
1117 * Create an empty extent record .
1118 *
1119 * l_next_free_rec may be updated.
1120 *
1121 * If an empty extent already exists do nothing.
1122 */
1124 {
1143 set_and_inc:
1146 }
1148 /*
1149 * For a rotation which involves two leaf nodes, the "root node" is
1150 * the lowest level tree node which contains a path to both leafs. This
1151 * resulting set of information can be used to form a complete "subtree"
1152 *
1153 * This function is passed two full paths from the dinode down to a
1154 * pair of adjacent leaves. It's task is to figure out which path
1155 * index contains the subtree root - this can be the root index itself
1156 * in a worst-case rotation.
1157 *
1158 * The array index of the subtree root is passed back.
1159 */
1163 {
1166 /*
1167 * Check that the caller passed in two paths from the same tree.
1168 */
1172 i++;
1174 /*
1175 * The caller didn't pass two adjacent paths.
1176 */
1188 }
1192 /*
1193 * Traverse a btree path in search of cpos, starting at root_el.
1194 *
1195 * This code can be called with a cpos larger than the tree, in which
1196 * case it will return the rightmost path.
1197 */
1201 {
1203 u32 range;
1204 u64 blkno;
1215 "Inode %llu has empty extent list at "
1222 }
1227 /*
1228 * In the case that cpos is off the allocation
1229 * tree, this should just wind up returning the
1230 * rightmost record.
1231 */
1236 }
1241 "Inode %llu has bad blkno in extent list "
1247 }
1256 }
1264 }
1269 "Inode %llu has bad count in extent list "
1277 }
1281 }
1283 out:
1284 /*
1285 * Catch any trailing bh that the loop didn't handle.
1286 */
1290 }
1292 /*
1293 * Given an initialized path (that is, it has a valid root extent
1294 * list), this function will traverse the btree in search of the path
1295 * which would contain cpos.
1296 *
1297 * The path traveled is recorded in the path structure.
1298 *
1299 * Note that this will not do any comparisons on leaf node extent
1300 * records, so it will work fine in the case that we just added a tree
1301 * branch.
1302 */
1306 };
1308 {
1314 }
1316 u32 cpos)
1317 {
1324 }
1327 {
1332 /* We want to retain only the leaf block. */
1336 }
1337 }
1338 /*
1339 * Find the leaf block in the tree which would contain cpos. No
1340 * checking of the actual leaf is done.
1341 *
1342 * Some paths want to call this instead of allocating a path structure
1343 * and calling ocfs2_find_path().
1344 *
1345 * This function doesn't handle non btree extent lists.
1346 */
1349 {
1357 }
1360 out:
1362 }
1364 /*
1365 * Adjust the adjacent records (left_rec, right_rec) involved in a rotation.
1366 *
1367 * Basically, we've moved stuff around at the bottom of the tree and
1368 * we need to fix up the extent records above the changes to reflect
1369 * the new changes.
1370 *
1371 * left_rec: the record on the left.
1372 * left_child_el: is the child list pointed to by left_rec
1373 * right_rec: the record to the right of left_rec
1374 * right_child_el: is the child list pointed to by right_rec
1375 *
1376 * By definition, this only works on interior nodes.
1377 */
1382 {
1385 /*
1386 * Interior nodes never have holes. Their cpos is the cpos of
1387 * the leftmost record in their child list. Their cluster
1388 * count covers the full theoretical range of their child list
1389 * - the range between their cpos and the cpos of the record
1390 * immediately to their right.
1391 */
1396 }
1400 /*
1401 * Calculate the rightmost cluster count boundary before
1402 * moving cpos - we will need to adjust clusters after
1403 * updating e_cpos to keep the same highest cluster count.
1404 */
1413 }
1415 /*
1416 * Adjust the adjacent root node records involved in a
1417 * rotation. left_el_blkno is passed in as a key so that we can easily
1418 * find it's index in the root list.
1419 */
1423 u64 left_el_blkno)
1424 {
1433 }
1435 /*
1436 * The path walking code should have never returned a root and
1437 * two paths which are not adjacent.
1438 */
1443 }
1445 /*
1446 * We've changed a leaf block (in right_path) and need to reflect that
1447 * change back up the subtree.
1448 *
1449 * This happens in multiple places:
1450 * - When we've moved an extent record from the left path leaf to the right
1451 * path leaf to make room for an empty extent in the left path leaf.
1452 * - When our insert into the right path leaf is at the leftmost edge
1453 * and requires an update of the path immediately to it's left. This
1454 * can occur at the end of some types of rotation and appending inserts.
1455 */
1460 {
1466 /*
1467 * Update the counts and position values within all the
1468 * interior nodes to reflect the leaf rotation we just did.
1469 *
1470 * The root node is handled below the loop.
1471 *
1472 * We begin the loop with right_el and left_el pointing to the
1473 * leaf lists and work our way up.
1474 *
1475 * NOTE: within this loop, left_el and right_el always refer
1476 * to the *child* lists.
1477 */
1483 /*
1484 * One nice property of knowing that all of these
1485 * nodes are below the root is that we only deal with
1486 * the leftmost right node record and the rightmost
1487 * left node record.
1488 */
1497 right_el);
1507 /*
1508 * Setup our list pointers now so that the current
1509 * parents become children in the next iteration.
1510 */
1513 }
1515 /*
1516 * At the root node, adjust the two adjacent records which
1517 * begin our path to the leaves.
1518 */
1532 }
1539 {
1552 "Inode %llu has non-full interior leaf node %llu"
1558 }
1560 /*
1561 * This extent block may already have an empty record, so we
1562 * return early if so.
1563 */
1571 OCFS2_JOURNAL_ACCESS_WRITE);
1575 }
1580 OCFS2_JOURNAL_ACCESS_WRITE);
1584 }
1588 OCFS2_JOURNAL_ACCESS_WRITE);
1592 }
1593 }
1598 /* This is a code error, not a disk corruption. */
1610 }
1612 /* Do the copy now. */
1617 /*
1618 * Clear out the record we just copied and shift everything
1619 * over, leaving an empty extent in the left leaf.
1620 *
1621 * We temporarily subtract from next_free_rec so that the
1622 * shift will lose the tail record (which is now defunct).
1623 */
1633 }
1636 subtree_index);
1638 out:
1640 }
1642 /*
1643 * Given a full path, determine what cpos value would return us a path
1644 * containing the leaf immediately to the left of the current one.
1645 *
1646 * Will return zero if the path passed in is already the leftmost path.
1647 */
1650 {
1652 u64 blkno;
1661 /* Start at the tree node just above the leaf and work our way up. */
1666 /*
1667 * Find the extent record just before the one in our
1668 * path.
1669 */
1674 /*
1675 * We've determined that the
1676 * path specified is already
1677 * the leftmost one - return a
1678 * cpos of zero.
1679 */
1681 }
1682 /*
1683 * The leftmost record points to our
1684 * leaf - we need to travel up the
1685 * tree one level.
1686 */
1688 }
1695 }
1696 }
1698 /*
1699 * If we got here, we never found a valid node where
1700 * the tree indicated one should be.
1701 */
1708 next_node:
1710 i--;
1711 }
1713 out:
1715 }
1717 /*
1718 * Extend the transaction by enough credits to complete the rotation,
1719 * and still leave at least the original number of credits allocated
1720 * to this transaction.
1721 */
1725 {
1732 }
1734 /*
1735 * Trap the case where we're inserting into the theoretical range past
1736 * the _actual_ left leaf range. Otherwise, we'll rotate a record
1737 * whose cpos is less than ours into the right leaf.
1738 *
1739 * It's only necessary to look at the rightmost record of the left
1740 * leaf because the logic that calls us should ensure that the
1741 * theoretical ranges in the path components above the leaves are
1742 * correct.
1743 */
1745 u32 insert_cpos)
1746 {
1758 }
1761 {
1771 /* Empty list. */
1775 }
1781 }
1783 /*
1784 * Rotate all the records in a btree right one record, starting at insert_cpos.
1785 *
1786 * The path to the rightmost leaf should be passed in.
1787 *
1788 * The array is assumed to be large enough to hold an entire path (tree depth).
1789 *
1790 * Upon succesful return from this function:
1791 *
1792 * - The 'right_path' array will contain a path to the leaf block
1793 * whose range contains e_cpos.
1794 * - That leaf block will have a single empty extent in list index 0.
1795 * - In the case that the rotation requires a post-insert update,
1796 * *ret_left_path will contain a valid path which can be passed to
1797 * ocfs2_insert_path().
1798 */
1802 u32 insert_cpos,
1805 {
1807 u32 cpos;
1818 }
1824 }
1828 /*
1829 * What we want to do here is:
1830 *
1831 * 1) Start with the rightmost path.
1832 *
1833 * 2) Determine a path to the leaf block directly to the left
1834 * of that leaf.
1835 *
1836 * 3) Determine the 'subtree root' - the lowest level tree node
1837 * which contains a path to both leaves.
1838 *
1839 * 4) Rotate the subtree.
1840 *
1841 * 5) Find the next subtree by considering the left path to be
1842 * the new right path.
1843 *
1844 * The check at the top of this while loop also accepts
1845 * insert_cpos == cpos because cpos is only a _theoretical_
1846 * value to get us the left path - insert_cpos might very well
1847 * be filling that hole.
1848 *
1849 * Stop at a cpos of '0' because we either started at the
1850 * leftmost branch (i.e., a tree with one branch and a
1851 * rotation inside of it), or we've gone as far as we can in
1852 * rotating subtrees.
1853 */
1862 }
1866 "Inode %lu: error during insert of %u "
1867 "(left path cpos %u) results in two identical "
1875 insert_cpos)) {
1877 /*
1878 * We've rotated the tree as much as we
1879 * should. The rest is up to
1880 * ocfs2_insert_path() to complete, after the
1881 * record insertion. We indicate this
1882 * situation by returning the left path.
1883 *
1884 * The reason we don't adjust the records here
1885 * before the record insert is that an error
1886 * later might break the rule where a parent
1887 * record e_cpos will reflect the actual
1888 * e_cpos of the 1st nonempty record of the
1889 * child list.
1890 */
1893 }
1898 start,
1907 }
1914 }
1918 insert_cpos)) {
1919 /*
1920 * A rotate moves the rightmost left leaf
1921 * record over to the leftmost right leaf
1922 * slot. If we're doing an extent split
1923 * instead of a real insert, then we have to
1924 * check that the extent to be split wasn't
1925 * just moved over. If it was, then we can
1926 * exit here, passing left_path back -
1927 * ocfs2_split_extent() is smart enough to
1928 * search both leaves.
1929 */
1932 }
1934 /*
1935 * There is no need to re-read the next right path
1936 * as we know that it'll be our current left
1937 * path. Optimize by copying values instead.
1938 */
1946 }
1947 }
1949 out:
1952 out_ret_path:
1954 }
1958 {
1963 u32 range;
1965 /* Path should always be rightmost. */
1984 }
1985 }
1990 {
2000 /*
2001 * Not all nodes might have had their final count
2002 * decremented by the caller - handle this here.
2003 */
2007 "Inode %llu, attempted to remove extent block "
2016 }
2028 }
2029 }
2036 {
2064 }
2072 {
2091 /*
2092 * It's legal for us to proceed if the right leaf is
2093 * the rightmost one and it has an empty extent. There
2094 * are two cases to handle - whether the leaf will be
2095 * empty after removal or not. If the leaf isn't empty
2096 * then just remove the empty extent up front. The
2097 * next block will handle empty leaves by flagging
2098 * them for unlink.
2099 *
2100 * Non rightmost leaves will throw -EAGAIN and the
2101 * caller can manually move the subtree and retry.
2102 */
2110 OCFS2_JOURNAL_ACCESS_WRITE);
2114 }
2119 }
2123 /*
2124 * We have to update i_last_eb_blk during the meta
2125 * data delete.
2126 */
2128 OCFS2_JOURNAL_ACCESS_WRITE);
2132 }
2135 }
2137 /*
2138 * Getting here with an empty extent in the right path implies
2139 * that it's the rightmost path and will be deleted.
2140 */
2144 OCFS2_JOURNAL_ACCESS_WRITE);
2148 }
2153 OCFS2_JOURNAL_ACCESS_WRITE);
2157 }
2161 OCFS2_JOURNAL_ACCESS_WRITE);
2165 }
2166 }
2169 /*
2170 * Only do this if we're moving a real
2171 * record. Otherwise, the action is delayed until
2172 * after removal of the right path in which case we
2173 * can do a simple shift to remove the empty extent.
2174 */
2178 }
2180 /*
2181 * Move recs over to get rid of empty extent, decrease
2182 * next_free. This is allowed to remove the last
2183 * extent in our leaf (setting l_next_free_rec to
2184 * zero) - the delete code below won't care.
2185 */
2187 }
2204 /*
2205 * Removal of the extent in the left leaf was skipped
2206 * above so we could delete the right path
2207 * 1st.
2208 */
2219 subtree_index);
2221 out:
2223 }
2225 /*
2226 * Given a full path, determine what cpos value would return us a path
2227 * containing the leaf immediately to the right of the current one.
2228 *
2229 * Will return zero if the path passed in is already the rightmost path.
2230 *
2231 * This looks similar, but is subtly different to
2232 * ocfs2_find_cpos_for_left_leaf().
2233 */
2236 {
2238 u64 blkno;
2248 /* Start at the tree node just above the leaf and work our way up. */
2255 /*
2256 * Find the extent record just after the one in our
2257 * path.
2258 */
2264 /*
2265 * We've determined that the
2266 * path specified is already
2267 * the rightmost one - return a
2268 * cpos of zero.
2269 */
2271 }
2272 /*
2273 * The rightmost record points to our
2274 * leaf - we need to travel up the
2275 * tree one level.
2276 */
2278 }
2282 }
2283 }
2285 /*
2286 * If we got here, we never found a valid node where
2287 * the tree indicated one should be.
2288 */
2295 next_node:
2297 i--;
2298 }
2300 out:
2302 }
2308 {
2315 OCFS2_JOURNAL_ACCESS_WRITE);
2319 }
2327 out:
2329 }
2336 {
2338 u32 right_cpos;
2351 }
2359 }
2369 }
2376 }
2379 right_path);
2382 subtree_root,
2392 }
2398 /*
2399 * The rotation has to temporarily stop due to
2400 * the right subtree having an empty
2401 * extent. Pass it back to the caller for a
2402 * fixup.
2403 */
2407 }
2411 }
2413 /*
2414 * The subtree rotate might have removed records on
2415 * the rightmost edge. If so, then rotation is
2416 * complete.
2417 */
2428 }
2429 }
2431 out:
2436 }
2441 {
2443 u32 cpos;
2449 /*
2450 * XXX: This code assumes that the root is an inode, which is
2451 * true for now but may change as tree code gets generic.
2452 */
2460 }
2462 /*
2463 * There's two ways we handle this depending on
2464 * whether path is the only existing one.
2465 */
2468 path);
2472 }
2478 }
2484 }
2487 /*
2488 * We have a path to the left of this one - it needs
2489 * an update too.
2490 */
2497 }
2503 }
2509 }
2520 /*
2521 * 'path' is also the leftmost path which
2522 * means it must be the only one. This gets
2523 * handled differently because we want to
2524 * revert the inode back to having extents
2525 * in-line.
2526 */
2535 }
2539 out:
2542 }
2544 /*
2545 * Left rotation of btree records.
2546 *
2547 * In many ways, this is (unsurprisingly) the opposite of right
2548 * rotation. We start at some non-rightmost path containing an empty
2549 * extent in the leaf block. The code works its way to the rightmost
2550 * path by rotating records to the left in every subtree.
2551 *
2552 * This is used by any code which reduces the number of extent records
2553 * in a leaf. After removal, an empty record should be placed in the
2554 * leftmost list position.
2555 *
2556 * This won't handle a length update of the rightmost path records if
2557 * the rightmost tree leaf record is removed so the caller is
2558 * responsible for detecting and correcting that.
2559 */
2563 {
2574 rightmost_no_delete:
2575 /*
2576 * In-inode extents. This is trivially handled, so do
2577 * it up front.
2578 */
2585 }
2587 /*
2588 * Handle rightmost branch now. There's several cases:
2589 * 1) simple rotation leaving records in there. That's trivial.
2590 * 2) rotation requiring a branch delete - there's no more
2591 * records left. Two cases of this:
2592 * a) There are branches to the left.
2593 * b) This is also the leftmost (the only) branch.
2594 *
2595 * 1) is handled via ocfs2_rotate_rightmost_leaf_left()
2596 * 2a) we need the left branch so that we can update it with the unlink
2597 * 2b) we need to bring the inode back to inline extents.
2598 */
2603 /*
2604 * This gets a bit tricky if we're going to delete the
2605 * rightmost path. Get the other cases out of the way
2606 * 1st.
2607 */
2618 }
2620 /*
2621 * XXX: The caller can not trust "path" any more after
2622 * this as it will have been deleted. What do we do?
2623 *
2624 * In theory the rotate-for-merge code will never get
2625 * here because it'll always ask for a rotate in a
2626 * nonempty list.
2627 */
2630 dealloc);
2634 }
2636 /*
2637 * Now we can loop, remembering the path we get from -EAGAIN
2638 * and restarting from there.
2639 */
2640 try_rotate:
2646 }
2658 }
2665 }
2667 out:
2671 }
2675 {
2680 /*
2681 * We consumed all of the merged-from record. An empty
2682 * extent cannot exist anywhere but the 1st array
2683 * position, so move things over if the merged-from
2684 * record doesn't occupy that position.
2685 *
2686 * This creates a new empty extent so the caller
2687 * should be smart enough to have removed any existing
2688 * ones.
2689 */
2694 }
2696 /*
2697 * Always memset - the caller doesn't check whether it
2698 * created an empty extent, so there could be junk in
2699 * the other fields.
2700 */
2702 }
2703 }
2705 /*
2706 * Remove split_rec clusters from the record at index and merge them
2707 * onto the beginning of the record at index + 1.
2708 */
2713 {
2725 OCFS2_JOURNAL_ACCESS_WRITE);
2729 }
2744 out:
2746 }
2748 /*
2749 * Remove split_rec clusters from the record at index and merge them
2750 * onto the tail of the record at index - 1.
2751 */
2756 {
2770 OCFS2_JOURNAL_ACCESS_WRITE);
2774 }
2777 /*
2778 * The easy case - we can just plop the record right in.
2779 */
2785 }
2798 out:
2800 }
2810 {
2818 delete_tail_recs++;
2822 delete_tail_recs++;
2825 /*
2826 * The merge code will need to create an empty
2827 * extent to take the place of the newly
2828 * emptied slot. Remove any pre-existing empty
2829 * extents - having more than one in a leaf is
2830 * illegal.
2831 */
2833 dealloc);
2837 }
2838 split_index--;
2840 }
2841 }
2844 /*
2845 * Left-right contig implies this.
2846 */
2850 /*
2851 * Since the leftright insert always covers the entire
2852 * extent, this call will delete the insert record
2853 * entirely, resulting in an empty extent record added to
2854 * the extent block.
2855 *
2856 * Since the adding of an empty extent shifts
2857 * everything back to the right, there's no need to
2858 * update split_index here.
2859 */
2865 }
2867 /*
2868 * We can only get this from logic error above.
2869 */
2872 /*
2873 * The left merge left us with an empty extent, remove
2874 * it.
2875 */
2880 }
2881 split_index--;
2884 /*
2885 * Note that we don't pass split_rec here on purpose -
2886 * we've merged it into the left side.
2887 */
2893 }
2898 dealloc);
2899 /*
2900 * Error from this last rotate is not critical, so
2901 * print but don't bubble it up.
2902 */
2907 /*
2908 * Merge a record to the left or right.
2909 *
2910 * 'contig_type' is relative to the existing record,
2911 * so for example, if we're "right contig", it's to
2912 * the record on the left (hence the left merge).
2913 */
2918 split_index);
2922 }
2927 split_index);
2931 }
2932 }
2935 /*
2936 * The merge may have left an empty extent in
2937 * our leaf. Try to rotate it away.
2938 */
2940 dealloc);
2944 }
2945 }
2947 out:
2949 }
2955 {
2956 u64 len_blocks;
2962 /*
2963 * Region is on the left edge of the existing
2964 * record.
2965 */
2972 /*
2973 * Region is on the right edge of the existing
2974 * record.
2975 */
2978 }
2979 }
2981 /*
2982 * Do the final bits of extent record insertion at the target leaf
2983 * list. If this leaf is part of an allocation tree, it is assumed
2984 * that the tree above has been prepared.
2985 */
2990 {
3002 insert_rec);
3004 }
3006 /*
3007 * Contiguous insert - either left or right.
3008 */
3014 }
3018 }
3020 /*
3021 * Handle insert into an empty leaf.
3022 */
3029 }
3031 /*
3032 * Appending insert.
3033 */
3043 "inode %lu, depth %u, count %u, next free %u, "
3044 "rec.cpos %u, rec.clusters %u, "
3054 i++;
3058 }
3060 rotate:
3061 /*
3062 * Ok, we have to rotate.
3063 *
3064 * At this point, it is safe to assume that inserting into an
3065 * empty leaf and appending to a leaf have both been handled
3066 * above.
3067 *
3068 * This leaf needs to have space, either by the empty 1st
3069 * extent record, or by virtue of an l_next_rec < l_count.
3070 */
3072 }
3076 u32 clusters)
3077 {
3082 }
3088 {
3094 /*
3095 * Update everything except the leaf block.
3096 */
3108 }
3122 }
3123 }
3129 {
3136 /*
3137 * This shouldn't happen for non-trees. The extent rec cluster
3138 * count manipulation below only works for interior nodes.
3139 */
3142 /*
3143 * If our appending insert is at the leftmost edge of a leaf,
3144 * then we might need to update the rightmost records of the
3145 * neighboring path.
3146 */
3151 u32 left_cpos;
3158 }
3162 left_cpos);
3164 /*
3165 * No need to worry if the append is already in the
3166 * leftmost leaf.
3167 */
3175 }
3181 }
3183 /*
3184 * ocfs2_insert_path() will pass the left_path to the
3185 * journal for us.
3186 */
3187 }
3188 }
3194 }
3200 out:
3205 }
3212 {
3229 /*
3230 * This typically means that the record
3231 * started in the left path but moved to the
3232 * right as a result of rotation. We either
3233 * move the existing record to the left, or we
3234 * do the later insert there.
3235 *
3236 * In this case, the left path should always
3237 * exist as the rotate code will have passed
3238 * it back for a post-insert update.
3239 */
3242 /*
3243 * It's a left split. Since we know
3244 * that the rotate code gave us an
3245 * empty extent in the left path, we
3246 * can just do the insert there.
3247 */
3250 /*
3251 * Right split - we have to move the
3252 * existing record over to the left
3253 * leaf. The insert will be into the
3254 * newly created empty extent in the
3255 * right leaf.
3256 */
3264 }
3265 }
3269 /*
3270 * Left path is easy - we can just allow the insert to
3271 * happen.
3272 */
3277 }
3282 }
3284 /*
3285 * This function only does inserts on an allocation b-tree. For dinode
3286 * lists, ocfs2_insert_at_leaf() is called directly.
3287 *
3288 * right_path is the path we want to do the actual insert
3289 * in. left_path should only be passed in if we need to update that
3290 * portion of the tree after an edge insert.
3291 */
3298 {
3302 /*
3303 * Pass both paths to the journal. The majority of inserts
3304 * will be touching all components anyway.
3305 */
3310 }
3315 /*
3316 * There's a chance that left_path got passed back to
3317 * us without being accounted for in the
3318 * journal. Extend our transaction here to be sure we
3319 * can change those blocks.
3320 */
3327 }
3333 }
3334 }
3337 /*
3338 * We could call ocfs2_insert_at_leaf() for some types
3339 * of splits, but it's easier to just let one seperate
3340 * function sort it all out.
3341 */
3353 /*
3354 * The rotate code has indicated that we need to fix
3355 * up portions of the tree after the insert.
3356 *
3357 * XXX: Should we extend the transaction here?
3358 */
3360 right_path);
3363 }
3366 out:
3368 }
3375 {
3377 u32 cpos;
3387 OCFS2_JOURNAL_ACCESS_WRITE);
3391 }
3396 }
3403 }
3405 /*
3406 * Determine the path to start with. Rotations need the
3407 * rightmost path, everything else can go directly to the
3408 * target leaf.
3409 */
3415 }
3421 }
3423 /*
3424 * Rotations and appends need special treatment - they modify
3425 * parts of the tree's above them.
3426 *
3427 * Both might pass back a path immediate to the left of the
3428 * one being inserted to. This will be cause
3429 * ocfs2_insert_path() to modify the rightmost records of
3430 * left_path to account for an edge insert.
3431 *
3432 * XXX: When modifying this code, keep in mind that an insert
3433 * can wind up skipping both of these two special cases...
3434 */
3442 }
3450 }
3451 }
3458 }
3460 out_update_clusters:
3469 out:
3474 }
3476 static enum ocfs2_contig_type
3480 {
3484 /*
3485 * We're careful to check for an empty extent record here -
3486 * the merge code will know what to do if it sees one.
3487 */
3496 }
3497 }
3509 }
3512 }
3518 {
3526 insert_rec);
3530 }
3531 }
3533 }
3535 /*
3536 * This should only be called against the righmost leaf extent list.
3537 *
3538 * ocfs2_figure_appending_type() will figure out whether we'll have to
3539 * insert at the tail of the rightmost leaf.
3540 *
3541 * This should also work against the dinode list for tree's with 0
3542 * depth. If we consider the dinode list to be the rightmost leaf node
3543 * then the logic here makes sense.
3544 */
3548 {
3561 /* Were all records empty? */
3564 }
3575 set_tail_append:
3577 }
3579 /*
3580 * Helper function called at the begining of an insert.
3581 *
3582 * This computes a few things that are commonly used in the process of
3583 * inserting into the btree:
3584 * - Whether the new extent is contiguous with an existing one.
3585 * - The current tree depth.
3586 * - Whether the insert is an appending one.
3587 * - The total # of free records in the tree.
3588 *
3589 * All of the information is stored on the ocfs2_insert_type
3590 * structure.
3591 */
3597 {
3611 /*
3612 * If we have tree depth, we read in the
3613 * rightmost extent block ahead of time as
3614 * ocfs2_figure_insert_type() and ocfs2_add_branch()
3615 * may want it later.
3616 */
3623 }
3626 }
3628 /*
3629 * Unless we have a contiguous insert, we'll need to know if
3630 * there is room left in our allocation tree for another
3631 * extent record.
3632 *
3633 * XXX: This test is simplistic, we can search for empty
3634 * extent records too.
3635 */
3643 }
3650 }
3652 /*
3653 * In the case that we're inserting past what the tree
3654 * currently accounts for, ocfs2_find_path() will return for
3655 * us the rightmost tree path. This is accounted for below in
3656 * the appending code.
3657 */
3662 }
3666 /*
3667 * Now that we have the path, there's two things we want to determine:
3668 * 1) Contiguousness (also set contig_index if this is so)
3669 *
3670 * 2) Are we doing an append? We can trivially break this up
3671 * into two types of appends: simple record append, or a
3672 * rotate inside the tail leaf.
3673 */
3676 /*
3677 * The insert code isn't quite ready to deal with all cases of
3678 * left contiguousness. Specifically, if it's an insert into
3679 * the 1st record in a leaf, it will require the adjustment of
3680 * cluster count on the last record of the path directly to it's
3681 * left. For now, just catch that case and fool the layers
3682 * above us. This works just fine for tree_depth == 0, which
3683 * is why we allow that above.
3684 */
3689 /*
3690 * Ok, so we can simply compare against last_eb to figure out
3691 * whether the path doesn't exist. This will only happen in
3692 * the case that we're doing a tail append, so maybe we can
3693 * take advantage of that information somehow.
3694 */
3696 /*
3697 * Ok, ocfs2_find_path() returned us the rightmost
3698 * tree path. This might be an appending insert. There are
3699 * two cases:
3700 * 1) We're doing a true append at the tail:
3701 * -This might even be off the end of the leaf
3702 * 2) We're "appending" by rotating in the tail
3703 */
3705 }
3707 out:
3712 else
3715 }
3717 /*
3718 * Insert an extent into an inode btree.
3719 *
3720 * The caller needs to update fe->i_clusters
3721 */
3726 u32 cpos,
3727 u64 start_blk,
3728 u32 new_clusters,
3729 u8 flags,
3731 {
3742 "Device %s, asking for sparse allocation: inode %llu, "
3759 }
3762 "Insert.contig_index: %d, Insert.free_records: %d, "
3770 meta_ac);
3774 }
3775 }
3777 /* Finally, we can add clusters. This might rotate the tree for us. */
3781 else
3784 bail:
3790 }
3794 u32 cpos,
3796 {
3810 }
3820 {
3831 leftright:
3832 /*
3833 * Store a copy of the record on the stack - it might move
3834 * around as the tree is manipulated below.
3835 */
3846 }
3853 meta_ac);
3857 }
3862 }
3863 }
3882 /*
3883 * Left/right split. We fake this as a right split
3884 * first and then make a second pass as a left split.
3885 */
3895 }
3902 }
3905 u32 cpos;
3908 do_leftright++;
3918 }
3923 }
3924 out:
3927 }
3929 /*
3930 * Mark part or all of the extent record at split_index in the leaf
3931 * pointed to by path as written. This removes the unwritten
3932 * extent flag.
3933 *
3934 * Care is taken to handle contiguousness so as to not grow the tree.
3935 *
3936 * meta_ac is not strictly necessary - we only truly need it if growth
3937 * of the tree is required. All other cases will degrade into a less
3938 * optimal tree layout.
3939 *
3940 * last_eb_bh should be the rightmost leaf block for any inode with a
3941 * btree. Since a split may grow the tree or a merge might shrink it, the caller cannot trust the contents of that buffer after this call.
3942 *
3943 * This code is optimized for readability - several passes might be
3944 * made over certain portions of the tree. All of those blocks will
3945 * have been brought into cache (and pinned via the journal), so the
3946 * extra overhead is not expressed in terms of disk reads.
3947 */
3956 {
3968 }
3976 }
3980 OCFS2_JOURNAL_ACCESS_WRITE);
3984 }
3987 split_index,
3988 split_rec);
3990 /*
3991 * The core merge / split code wants to know how much room is
3992 * left in this inodes allocation tree, so we pass the
3993 * rightmost extent list.
3994 */
4005 }
4012 }
4026 else
4039 else
4051 }
4055 out:
4058 }
4060 /*
4061 * Mark the already-existing extent at cpos as written for len clusters.
4062 *
4063 * If the existing extent is larger than the request, initiate a
4064 * split. An attempt will be made at merging with adjacent extents.
4065 *
4066 * The caller is responsible for passing down meta_ac if we'll need it.
4067 */
4072 {
4084 "that are being written to, but the feature bit "
4089 }
4091 /*
4092 * XXX: This should be fixed up so that we just re-insert the
4093 * next extent records.
4094 */
4102 }
4108 }
4114 "Inode %llu has an extent at cpos %u which can no "
4119 }
4133 out:
4136 }
4142 {
4152 /*
4153 * Setup the record to split before we grow the tree.
4154 */
4167 }
4179 }
4186 meta_ac);
4190 }
4195 }
4196 }
4210 out:
4213 }
4219 {
4234 }
4236 index--;
4237 }
4241 /*
4242 * Check whether this is the rightmost tree record. If
4243 * we remove all of this record or part of its right
4244 * edge then an update of the record lengths above it
4245 * will be required.
4246 */
4250 }
4255 /*
4256 * Changing the leftmost offset (via partial or whole
4257 * record truncate) of an interior (or rightmost) path
4258 * means we have to update the subtree that is formed
4259 * by this leaf and the one to it's left.
4260 *
4261 * There are two cases we can skip:
4262 * 1) Path is the leftmost one in our inode tree.
4263 * 2) The leaf is rightmost and will be empty after
4264 * we remove the extent record - the rotate code
4265 * knows how to update the newly formed edge.
4266 */
4273 }
4282 }
4288 }
4289 }
4290 }
4294 path);
4298 }
4304 }
4310 }
4324 /*
4325 * We skip the edge update if this path will
4326 * be deleted by the rotate code.
4327 */
4330 rec);
4331 }
4333 /* Remove leftmost portion of the record. */
4338 /* Remove rightmost portion of the record */
4343 /* Caller should have trapped this. */
4349 }
4356 subtree_index);
4357 }
4365 }
4367 out:
4370 }
4376 {
4390 }
4396 }
4402 "Inode %llu has an extent at cpos %u which can no "
4407 }
4409 /*
4410 * We have 3 cases of extent removal:
4411 * 1) Range covers the entire extent rec
4412 * 2) Range begins or ends on one edge of the extent rec
4413 * 3) Range is in the middle of the extent rec (no shared edges)
4414 *
4415 * For case 1 we remove the extent rec and left rotate to
4416 * fill the hole.
4417 *
4418 * For case 2 we just shrink the existing extent rec, with a
4419 * tree update if the shrinking edge is also the edge of an
4420 * extent block.
4421 *
4422 * For case 3 we do a right split to turn the extent rec into
4423 * something case 2 can handle.
4424 */
4442 }
4449 }
4451 /*
4452 * The split could have manipulated the tree enough to
4453 * move the record location, so we have to look for it again.
4454 */
4461 }
4469 cpos);
4472 }
4474 /*
4475 * Double check our values here. If anything is fishy,
4476 * it's easier to catch it at the top level.
4477 */
4483 "Inode %llu: error after split at cpos %u"
4490 }
4497 }
4498 }
4500 out:
4503 }
4506 {
4515 "slot %d, invalid truncate log parameters: used = "
4519 }
4523 {
4527 /* No records, nothing to coalesce */
4536 }
4540 u64 start_blk,
4542 {
4563 }
4568 "Truncate record count on #%llu invalid "
4574 /* Caller should have known to flush before calling us. */
4580 }
4583 OCFS2_JOURNAL_ACCESS_WRITE);
4587 }
4594 /*
4595 * Move index back to the record we are coalescing with.
4596 * ocfs2_truncate_log_can_coalesce() guarantees nonzero
4597 */
4598 index--;
4603 num_clusters);
4607 }
4614 }
4616 bail:
4619 }
4625 {
4629 u64 start_blk;
4642 /* Caller has given us at least enough credits to
4643 * update the truncate log dinode */
4645 OCFS2_JOURNAL_ACCESS_WRITE);
4649 }
4657 }
4659 /* TODO: Perhaps we can calculate the bulk of the
4660 * credits up front rather than extending like
4661 * this. */
4663 OCFS2_TRUNCATE_LOG_FLUSH_ONE_REC);
4667 }
4674 /* if start_blk is not set, we ignore the record as
4675 * invalid. */
4682 num_clusters);
4686 }
4687 }
4688 i--;
4689 }
4691 bail:
4694 }
4696 /* Expects you to already be holding tl_inode->i_mutex */
4698 {
4719 }
4727 }
4730 GLOBAL_BITMAP_SYSTEM_INODE,
4731 OCFS2_INVALID_SLOT);
4736 }
4744 }
4751 }
4754 data_alloc_bh);
4760 out_unlock:
4764 out_mutex:
4768 out:
4771 }
4774 {
4783 }
4786 {
4799 }
4801 #define OCFS2_TRUNCATE_LOG_FLUSH_INTERVAL (2 * HZ)
4804 {
4806 /* We want to push off log flushes while truncates are
4807 * still running. */
4812 OCFS2_TRUNCATE_LOG_FLUSH_INTERVAL);
4813 }
4814 }
4820 {
4826 TRUNCATE_LOG_SYSTEM_INODE,
4827 slot_num);
4832 }
4840 }
4844 bail:
4847 }
4849 /* called during the 1st stage of node recovery. we stamp a clean
4850 * truncate log and pass back a copy for processing later. if the
4851 * truncate log does not require processing, a *tl_copy is set to
4852 * NULL. */
4856 {
4871 }
4879 }
4890 }
4892 /* Assuming the write-out below goes well, this copy
4893 * will be passed back to recovery for processing. */
4896 /* All we need to do to clear the truncate log is set
4897 * tl_used. */
4904 }
4905 }
4907 bail:
4916 }
4920 }
4924 {
4928 u64 start_blk;
4938 }
4952 }
4953 }
4960 }
4972 }
4973 }
4975 bail_up:
4980 }
4983 {
4999 }
5002 }
5005 {
5019 /* ocfs2_truncate_log_shutdown keys on the existence of
5020 * osb->osb_tl_inode so we don't set any of the osb variables
5021 * until we're sure all is well. */
5023 ocfs2_truncate_log_worker);
5029 }
5031 /*
5032 * Delayed de-allocation of suballocator blocks.
5033 *
5034 * Some sets of block de-allocations might involve multiple suballocator inodes.
5035 *
5036 * The locking for this can get extremely complicated, especially when
5037 * the suballocator inodes to delete from aren't known until deep
5038 * within an unrelated codepath.
5039 *
5040 * ocfs2_extent_block structures are a good example of this - an inode
5041 * btree could have been grown by any number of nodes each allocating
5042 * out of their own suballoc inode.
5043 *
5044 * These structures allow the delay of block de-allocation until a
5045 * later time, when locking of multiple cluster inodes won't cause
5046 * deadlock.
5047 */
5049 /*
5050 * Describes a single block free from a suballocator
5051 */
5054 u64 free_blk;
5056 };
5063 };
5069 {
5071 u64 bg_blkno;
5082 }
5090 }
5097 }
5110 }
5116 }
5121 }
5123 out_journal:
5126 out_unlock:
5129 out_mutex:
5132 out:
5134 /* Premature exit may have left some dangling items. */
5138 }
5141 }
5145 {
5164 }
5168 }
5171 }
5177 {
5185 }
5195 }
5197 }
5202 {
5212 }
5219 }
5231 out:
5233 }
5237 {
5242 }
5244 /* This function will figure out whether the currently last extent
5245 * block will be deleted, and if it will, what the new last extent
5246 * block will be so we can update his h_next_leaf_blk field, as well
5247 * as the dinodes i_last_eb_blk */
5252 {
5254 u32 cpos;
5262 /* we have no tree, so of course, no last_eb. */
5266 /* trunc to zero special case - this makes tree_depth = 0
5267 * regardless of what it is. */
5274 /*
5275 * Make sure that this extent list will actually be empty
5276 * after we clear away the data. We can shortcut out if
5277 * there's more than one non-empty extent in the
5278 * list. Otherwise, a check of the remaining extent is
5279 * necessary.
5280 */
5287 /* We may have a valid extent in index 1, check it. */
5291 /*
5292 * Fall through - no more nonempty extents, so we want
5293 * to delete this leaf.
5294 */
5300 }
5303 /*
5304 * Check it we'll only be trimming off the end of this
5305 * cluster.
5306 */
5309 }
5315 }
5321 }
5329 }
5335 out:
5339 }
5341 /*
5342 * Trim some clusters off the rightmost edge of a tree. Only called
5343 * during truncate.
5344 *
5345 * The caller needs to:
5346 * - start journaling of each path component.
5347 * - compute and fully set up any new last ext block
5348 */
5352 {
5379 }
5381 find_tail_record:
5394 /*
5395 * If the leaf block contains a single empty
5396 * extent and no records, we can just remove
5397 * the block.
5398 */
5405 }
5407 /*
5408 * Remove any empty extents by shifting things
5409 * left. That should make life much easier on
5410 * the code below. This condition is rare
5411 * enough that we shouldn't see a performance
5412 * hit.
5413 */
5424 /*
5425 * We've modified our extent list. The
5426 * simplest way to handle this change
5427 * is to being the search from the
5428 * start again.
5429 */
5431 }
5435 /*
5436 * We'll use "new_edge" on our way back up the
5437 * tree to know what our rightmost cpos is.
5438 */
5442 /*
5443 * The caller will use this to delete data blocks.
5444 */
5449 /*
5450 * If it's now empty, remove this record.
5451 */
5456 }
5464 }
5466 /* Can this actually happen? */
5470 /*
5471 * We never actually deleted any clusters
5472 * because our leaf was empty. There's no
5473 * reason to adjust the rightmost edge then.
5474 */
5482 /*
5483 * A deleted child record should have been
5484 * caught above.
5485 */
5487 }
5494 }
5503 /*
5504 * We must be careful to only attempt delete of an
5505 * extent block (and not the root inode block).
5506 */
5511 /*
5512 * Save this for use when processing the
5513 * parent block.
5514 */
5526 /* An error here is not fatal. */
5531 }
5533 index--;
5534 }
5537 out:
5539 }
5548 {
5563 }
5565 /*
5566 * Each component will be touched, so we might as well journal
5567 * here to avoid having to handle errors later.
5568 */
5573 }
5577 OCFS2_JOURNAL_ACCESS_WRITE);
5581 }
5584 }
5588 /*
5589 * Lower levels depend on this never happening, but it's best
5590 * to check it up here before changing the tree.
5591 */
5598 }
5602 clusters_to_del;
5612 }
5615 /* trunc to zero is a special case. */
5625 }
5628 /* If there will be a new last extent block, then by
5629 * definition, there cannot be any leaves to the right of
5630 * him. */
5636 }
5637 }
5641 clusters_to_del);
5645 }
5646 }
5648 bail:
5652 }
5655 {
5659 }
5662 {
5666 }
5671 {
5702 /*
5703 * Need to set the buffers we zero'd into uptodate
5704 * here if they aren't - ocfs2_map_page_blocks()
5705 * might've skipped some
5706 */
5711 ocfs2_ordered_zero_func);
5717 ocfs2_writeback_zero_func);
5720 }
5728 }
5729 out:
5736 }
5737 }
5738 }
5742 {
5748 loff_t last_page_bytes;
5764 }
5766 /* Tail is a hole. */
5770 /* Tail is marked as unwritten, we can count on write to zero
5771 * in that case. */
5783 }
5785 numpages++;
5786 index++;
5789 out:
5796 }
5797 }
5798 }
5800 }
5805 }
5807 /*
5808 * Zero the area past i_size but still within an allocated
5809 * cluster. This avoids exposing nonzero data on subsequent file
5810 * extends.
5811 *
5812 * We need to call this before i_size is updated on the inode because
5813 * otherwise block_write_full_page() will skip writeout of pages past
5814 * i_size. The new_i_size parameter is passed for this reason.
5815 */
5818 {
5821 u64 phys;
5823 /*
5824 * File systems which don't support sparse files zero on every
5825 * extend.
5826 */
5836 }
5843 }
5851 /*
5852 * Initiate writeout of the pages we zero'd here. We don't
5853 * wait on them - the truncate_inode_pages() call later will
5854 * do that for us.
5855 */
5861 out:
5866 }
5868 /*
5869 * It is expected, that by the time you call this function,
5870 * inode->i_size and fe->i_size have been adjusted.
5871 *
5872 * WARNING: This will kfree the truncate context
5873 */
5878 {
5896 }
5900 start:
5901 /*
5902 * Check that we still have allocation to delete.
5903 */
5907 }
5909 /*
5910 * Truncate always works against the rightmost tree branch.
5911 */
5916 }
5921 /*
5922 * By now, el will point to the extent list on the bottom most
5923 * portion of this tree. Only the tail record is considered in
5924 * each pass.
5925 *
5926 * We handle the following cases, in order:
5927 * - empty extent: delete the remaining branch
5928 * - remove the entire record
5929 * - remove a partial record
5930 * - no record needs to be removed (truncate has completed)
5931 */
5940 }
5952 new_highest_cpos;
5956 }
5965 /* ocfs2_truncate_log_needs_flush guarantees us at least one
5966 * record is free for use. If there isn't any, we flush to get
5967 * an empty truncate log. */
5973 }
5974 }
5978 el);
5985 }
5992 }
6002 /*
6003 * The check above will catch the case where we've truncated
6004 * away all allocation.
6005 */
6008 bail:
6022 /* This will drop the ext_alloc cluster lock for us */
6027 }
6029 /*
6030 * Expects the inode to already be locked.
6031 */
6036 {
6060 }
6069 }
6077 }
6078 }
6083 bail:
6088 }
6091 }
6094 {
6095 /*
6096 * The caller is responsible for completing deallocation
6097 * before freeing the context.
6098 */
6107 }