| blob | d654a6458648d1a3427be4924f5463f5d77d5f40 |
1 /*
2 * Copyright (C) International Business Machines Corp., 2000-2005
3 *
4 * This program is free software; you can redistribute it and/or modify
5 * it under the terms of the GNU General Public License as published by
6 * the Free Software Foundation; either version 2 of the License, or
7 * (at your option) any later version.
8 *
9 * This program is distributed in the hope that it will be useful,
10 * but WITHOUT ANY WARRANTY; without even the implied warranty of
11 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See
12 * the GNU General Public License for more details.
13 *
14 * You should have received a copy of the GNU General Public License
15 * along with this program; if not, write to the Free Software
16 * Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
17 */
18 /*
19 * jfs_xtree.c: extent allocation descriptor B+-tree manager
20 */
22 #include <linux/fs.h>
23 #include <linux/module.h>
24 #include <linux/quotaops.h>
25 #include <linux/seq_file.h>
34 /*
35 * xtree local flag
36 */
37 #define XT_INSERT 0x00000001
39 /*
40 * xtree key/entry comparison: extent offset
41 *
42 * return:
43 * -1: k < start of extent
44 * 0: start_of_extent <= k <= end_of_extent
45 * 1: k > end_of_extent
46 */
47 #define XT_CMP(CMP, K, X, OFFSET64)\
48 {\
49 OFFSET64 = offsetXAD(X);\
50 (CMP) = ((K) >= OFFSET64 + lengthXAD(X)) ? 1 :\
51 ((K) < OFFSET64) ? -1 : 0;\
52 }
54 /* write a xad entry */
55 #define XT_PUTENTRY(XAD, FLAG, OFF, LEN, ADDR)\
56 {\
57 (XAD)->flag = (FLAG);\
58 XADoffset((XAD), (OFF));\
59 XADlength((XAD), (LEN));\
60 XADaddress((XAD), (ADDR));\
61 }
63 #define XT_PAGE(IP, MP) BT_PAGE(IP, MP, xtpage_t, i_xtroot)
65 /* get page buffer for specified block address */
66 /* ToDo: Replace this ugly macro with a function */
67 #define XT_GETPAGE(IP, BN, MP, SIZE, P, RC)\
68 {\
69 BT_GETPAGE(IP, BN, MP, xtpage_t, SIZE, P, RC, i_xtroot)\
70 if (!(RC))\
71 {\
72 if ((le16_to_cpu((P)->header.nextindex) < XTENTRYSTART) ||\
73 (le16_to_cpu((P)->header.nextindex) > le16_to_cpu((P)->header.maxentry)) ||\
74 (le16_to_cpu((P)->header.maxentry) > (((BN)==0)?XTROOTMAXSLOT:PSIZE>>L2XTSLOTSIZE)))\
75 {\
77 BT_PUTPAGE(MP);\
78 MP = NULL;\
79 RC = -EIO;\
80 }\
81 }\
82 }
84 /* for consistency */
85 #define XT_PUTPAGE(MP) BT_PUTPAGE(MP)
87 #define XT_GETSEARCH(IP, LEAF, BN, MP, P, INDEX) \
88 BT_GETSEARCH(IP, LEAF, BN, MP, xtpage_t, P, INDEX, i_xtroot)
89 /* xtree entry parameter descriptor */
92 s16 index;
93 u8 flag;
94 s64 off;
95 s64 addr;
98 };
101 /*
102 * statistics
103 */
104 #ifdef CONFIG_JFS_STATISTICS
106 uint search;
107 uint fastSearch;
108 uint split;
110 #endif
113 /*
114 * forward references
115 */
129 #ifdef _STILL_TO_PORT
140 /*
141 * xtLookup()
142 *
143 * function: map a single page into a physical extent;
144 */
147 {
151 s64 bn;
158 s64 xaddr;
164 /* is lookup offset beyond eof ? */
169 }
171 /*
172 * search for the xad entry covering the logical extent
173 */
174 //search:
178 }
180 /*
181 * compute the physical extent covering logical extent
182 *
183 * N.B. search may have failed (e.g., hole in sparse file),
184 * and returned the index of the next entry.
185 */
186 /* retrieve search result */
189 /* is xad found covering start of logical extent ?
190 * lstart is a page start address,
191 * i.e., lstart cannot start in a hole;
192 */
197 }
199 /*
200 * lxd covered by xad
201 */
208 /* initialize new pxd */
211 /* a page must be fully covered by an xad */
214 out:
218 }
220 /*
221 * xtSearch()
222 *
223 * function: search for the xad entry covering specified offset.
224 *
225 * parameters:
226 * ip - file object;
227 * xoff - extent offset;
228 * nextp - address of next extent (if any) for search miss
229 * cmpp - comparison result:
230 * btstack - traverse stack;
231 * flag - search process flag (XT_INSERT);
232 *
233 * returns:
234 * btstack contains (bn, index) of search path traversed to the entry.
235 * *cmpp is set to result of comparison with the entry returned.
236 * the page containing the entry is pinned at exit.
237 */
240 {
251 s64 t64;
260 /*
261 * search down tree from root:
262 *
263 * between two consecutive entries of <Ki, Pi> and <Kj, Pj> of
264 * internal page, child page Pi contains entry with k, Ki <= K < Kj.
265 *
266 * if entry with search key K is not found
267 * internal page search find the entry with largest key Ki
268 * less than K which point to the child page to search;
269 * leaf page search find the entry with smallest key Kj
270 * greater than K so that the returned index is the position of
271 * the entry to be shifted right for insertion of new entry.
272 * for empty tree, search key is greater than any key of the tree.
273 *
274 * by convention, root bn = 0.
275 */
277 /* get/pin the page to search */
282 /* try sequential access heuristics with the previous
283 * access entry in target leaf page:
284 * once search narrowed down into the target leaf,
285 * key must either match an entry in the leaf or
286 * key entry does not exist in the tree;
287 */
288 //fastSearch:
299 }
301 /* stop sequential access heuristics */
305 /* try next sequential entry */
306 index++;
309 xad++;
315 }
317 /* miss: key falls between
318 * previous and this entry
319 */
323 }
325 /* (xoff >= t64 + lengthXAD(xad));
326 * matching entry may be further out:
327 * stop heuristic search
328 */
329 /* stop sequential access heuristics */
331 }
333 /* (index == p->header.nextindex);
334 * miss: key entry does not exist in
335 * the target leaf/tree
336 */
339 }
341 /*
342 * if hit, return index of the entry found, and
343 * if miss, where new entry with search key is
344 * to be inserted;
345 */
346 out:
347 /* compute number of pages to split */
351 nsplit++;
352 else
355 }
357 /* save search result */
363 /* update sequential access heuristics */
371 }
373 /* well, ... full search now */
374 binarySearch:
377 /*
378 * binary search with search key K on the current page
379 */
385 /*
386 * search hit
387 */
388 /* search hit - leaf page:
389 * return the entry found
390 */
394 /* compute number of pages to split */
398 nsplit++;
399 else
402 }
404 /* save search result */
410 /* init sequential access heuristics */
415 else
420 }
421 /* search hit - internal page:
422 * descend/search its child page
423 */
427 }
432 }
433 }
435 /*
436 * search miss
437 *
438 * base is the smallest index with key (Kj) greater than
439 * search key (K) and may be zero or maxentry index.
440 */
443 /*
444 * search miss - leaf page:
445 *
446 * return location of entry (base) where new entry with
447 * search key K is to be inserted.
448 */
452 /* compute number of pages to split */
456 nsplit++;
457 else
460 }
462 /* save search result */
468 /* init sequential access heuristics */
472 else
480 }
482 /*
483 * search miss - non-leaf page:
484 *
485 * if base is non-zero, decrement base by one to get the parent
486 * entry of the child page to search.
487 */
490 /*
491 * go down to child page
492 */
493 next:
494 /* update number of pages to split */
496 nsplit++;
497 else
500 /* push (bn, index) of the parent page/entry */
505 }
508 /* get the child page block number */
511 /* unpin the parent page */
513 }
514 }
516 /*
517 * xtInsert()
518 *
519 * function:
520 *
521 * parameter:
522 * tid - transaction id;
523 * ip - file object;
524 * xflag - extent flag (XAD_NOTRECORDED):
525 * xoff - extent offset;
526 * xlen - extent length;
527 * xaddrp - extent address pointer (in/out):
528 * if (*xaddrp)
529 * caller allocated data extent at *xaddrp;
530 * else
531 * allocate data extent and return its xaddr;
532 * flag -
533 *
534 * return:
535 */
539 {
544 s64 bn;
550 s64 next;
556 /*
557 * search for the entry location at which to insert:
558 *
559 * xtFastSearch() and xtSearch() both returns (leaf page
560 * pinned, index at which to insert).
561 * n.b. xtSearch() may return index of maxentry of
562 * the full page.
563 */
567 /* retrieve search result */
570 /* This test must follow XT_GETSEARCH since mp must be valid if
571 * we branch to out: */
575 }
577 /*
578 * allocate data extent requested
579 *
580 * allocation hint: last xad
581 */
593 }
594 }
596 /*
597 * insert entry for new extent
598 */
601 /*
602 * if the leaf page is full, split the page and
603 * propagate up the router entry for the new page from split
604 *
605 * The xtSplitUp() will insert the entry and unpin the leaf page.
606 */
617 /* undo data extent allocation */
621 }
623 }
627 }
629 /*
630 * insert the new entry into the leaf page
631 */
632 /*
633 * acquire a transaction lock on the leaf page;
634 *
635 * action: xad insertion/extension;
636 */
639 /* if insert into middle, shift right remaining entries. */
644 /* insert the new entry: mark the entry NEW */
648 /* advance next available entry index */
651 /* Don't log it if there are no links to the file */
660 }
664 out:
665 /* unpin the leaf page */
669 }
672 /*
673 * xtSplitUp()
674 *
675 * function:
676 * split full pages as propagating insertion up the tree
677 *
678 * parameter:
679 * tid - transaction id;
680 * ip - file object;
681 * split - entry parameter descriptor;
682 * btstack - traverse stack from xtSearch()
683 *
684 * return:
685 */
686 static int
689 {
702 s64 xaddr;
713 /* is inode xtree root extension/inline EA area free ? */
721 /*
722 * acquire a transaction lock on the leaf page;
723 *
724 * action: xad insertion/extension;
725 */
727 /* if insert into middle, shift right remaining entries. */
734 /* insert the new entry: mark the entry NEW */
739 /* advance next available entry index */
742 /* Don't log it if there are no links to the file */
751 }
754 }
756 /*
757 * allocate new index blocks to cover index page split(s)
758 *
759 * allocation hint: ?
760 */
776 }
778 /* undo allocation */
782 }
783 }
785 /*
786 * Split leaf page <sp> into <sp> and a new right page <rp>.
787 *
788 * The split routines insert the new entry into the leaf page,
789 * and acquire txLock as appropriate.
790 * return <rp> pinned and its block number <rpbn>.
791 */
800 /*
801 * propagate up the router entry for the leaf page just split
802 *
803 * insert a router entry for the new page into the parent page,
804 * propagate the insert/split up the tree by walking back the stack
805 * of (bn of parent page, index of child page entry in parent page)
806 * that were traversed during the search for the page that split.
807 *
808 * the propagation of insert/split up the tree stops if the root
809 * splits or the page inserted into doesn't have to split to hold
810 * the new entry.
811 *
812 * the parent entry for the split page remains the same, and
813 * a new entry is inserted at its right with the first key and
814 * block number of the new right page.
815 *
816 * There are a maximum of 3 pages pinned at any time:
817 * right child, left parent and right parent (when the parent splits)
818 * to keep the child page pinned while working on the parent.
819 * make sure that all pins are released at exit.
820 */
822 /* parent page specified by stack frame <parent> */
824 /* keep current child pages <rcp> pinned */
829 /*
830 * insert router entry in parent for new right child page <rp>
831 */
832 /* get/pin the parent page <sp> */
837 }
839 /*
840 * The new key entry goes ONE AFTER the index of parent entry,
841 * because the split was to the right.
842 */
845 /*
846 * split or shift right remaining entries of the parent page
847 */
849 /*
850 * parent page is full - split the parent page
851 */
853 /* init for parent page split */
861 /* unpin previous right child page */
864 /* The split routines insert the new entry,
865 * and acquire txLock as appropriate.
866 * return <rp> pinned and its block number <rpbn>.
867 */
874 }
877 /* keep new child page <rp> pinned */
878 }
879 /*
880 * parent page is not full - insert in parent page
881 */
883 /*
884 * insert router entry in parent for the right child
885 * page from the first entry of the right child page:
886 */
887 /*
888 * acquire a transaction lock on the parent page;
889 *
890 * action: router xad insertion;
891 */
894 /*
895 * if insert into middle, shift right remaining entries
896 */
902 /* insert the router entry */
908 /* advance next available entry index. */
911 /* Don't log it if there are no links to the file */
921 }
923 /* unpin parent page */
926 /* exit propagate up */
928 }
929 }
931 /* unpin current right page */
935 }
938 /*
939 * xtSplitPage()
940 *
941 * function:
942 * split a full non-root page into
943 * original/split/left page and new right page
944 * i.e., the original/split page remains as left page.
945 *
946 * parameter:
947 * int tid,
948 * struct inode *ip,
949 * struct xtsplit *split,
950 * struct metapage **rmpp,
951 * u64 *rbnp,
952 *
953 * return:
954 * Pointer to page in which to insert or NULL on error.
955 */
956 static int
959 {
968 s64 nextbn;
987 /* Allocate blocks to quota. */
991 }
995 /*
996 * allocate the new right page for the split
997 */
1002 }
1007 /*
1008 * action: new page;
1009 */
1018 /* Don't log it if there are no links to the file */
1020 /*
1021 * acquire a transaction lock on the new right page;
1022 */
1026 /*
1027 * acquire a transaction lock on the split page
1028 */
1031 }
1033 /*
1034 * initialize/update sibling pointers of <sp> and <rp>
1035 */
1043 /*
1044 * sequential append at tail (after last entry of last page)
1045 *
1046 * if splitting the last page on a level because of appending
1047 * a entry to it (skip is maxentry), it's likely that the access is
1048 * sequential. adding an empty page on the side of the level is less
1049 * work and can push the fill factor much higher than normal.
1050 * if we're wrong it's no big deal - we will do the split the right
1051 * way next time.
1052 * (it may look like it's equally easy to do a similar hack for
1053 * reverse sorted data, that is, split the tree left, but it's not.
1054 * Be my guest.)
1055 */
1057 /*
1058 * acquire a transaction lock on the new/right page;
1059 *
1060 * action: xad insertion;
1061 */
1062 /* insert entry at the first entry of the new right page */
1070 /* rxtlck->lwm.offset = XTENTRYSTART; */
1072 }
1079 }
1081 /*
1082 * non-sequential insert (at possibly middle page)
1083 */
1085 /*
1086 * update previous pointer of old next/right page of <sp>
1087 */
1093 }
1096 /*
1097 * acquire a transaction lock on the next page;
1098 *
1099 * action:sibling pointer update;
1100 */
1106 /* sibling page may have been updated previously, or
1107 * it may be updated later;
1108 */
1111 }
1113 /*
1114 * split the data between the split and new/right pages
1115 */
1120 /*
1121 * skip index in old split/left page - insert into left page:
1122 */
1124 /* move right half of split page to the new right page */
1128 /* shift right tail of left half to make room for new entry */
1133 /* insert new entry */
1138 /* update page header */
1143 }
1147 }
1148 /*
1149 * skip index in new right page - insert into right page:
1150 */
1152 /* move left head of right half to right page */
1157 /* insert new entry */
1163 /* move right tail of right half to right page */
1168 /* update page header */
1173 }
1177 }
1183 /* rxtlck->lwm.offset = XTENTRYSTART; */
1185 XTENTRYSTART;
1186 }
1194 clean_up:
1196 /* Rollback quota allocation. */
1201 }
1204 /*
1205 * xtSplitRoot()
1206 *
1207 * function:
1208 * split the full root page into original/root/split page and new
1209 * right page
1210 * i.e., root remains fixed in tree anchor (inode) and the root is
1211 * copied to a single new right child page since root page <<
1212 * non-root page, and the split root page contains a single entry
1213 * for the new right child page.
1214 *
1215 * parameter:
1216 * int tid,
1217 * struct inode *ip,
1218 * struct xtsplit *split,
1219 * struct metapage **rmpp)
1220 *
1221 * return:
1222 * Pointer to page in which to insert or NULL on error.
1223 */
1224 static int
1227 {
1231 s64 rbn;
1243 /*
1244 * allocate a single (right) child page
1245 */
1254 /* Allocate blocks to quota. */
1258 }
1262 /*
1263 * acquire a transaction lock on the new right page;
1264 *
1265 * action: new page;
1266 */
1276 /* initialize sibling pointers */
1280 /*
1281 * copy the in-line root page into new right page extent
1282 */
1287 /*
1288 * insert the new entry into the new right/child page
1289 * (skip index in the new right page will not change)
1290 */
1292 /* if insert into middle, shift right remaining entries */
1300 /* update page header */
1308 XTENTRYSTART;
1309 }
1311 /*
1312 * reset the root
1313 *
1314 * init root with the single entry for the new right page
1315 * set the 1st entry offset to 0, which force the left-most key
1316 * at any level of the tree to be less than any search key.
1317 */
1318 /*
1319 * acquire a transaction lock on the root page (in-memory inode);
1320 *
1321 * action: root split;
1322 */
1328 /* update page header of root */
1339 }
1345 }
1348 /*
1349 * xtExtend()
1350 *
1351 * function: extend in-place;
1352 *
1353 * note: existing extent may or may not have been committed.
1354 * caller is responsible for pager buffer cache update, and
1355 * working block allocation map update;
1356 * update pmap: alloc whole extended extent;
1357 */
1362 {
1367 s64 bn;
1372 s64 xaddr;
1378 /* there must exist extent to be extended */
1382 /* retrieve search result */
1389 }
1391 /* extension must be contiguous */
1397 }
1399 /*
1400 * acquire a transaction lock on the leaf page;
1401 *
1402 * action: xad insertion/extension;
1403 */
1408 }
1410 /* extend will overflow extent ? */
1415 /*
1416 * extent overflow: insert entry for new extent
1417 */
1418 //insertNew:
1423 /*
1424 * if the leaf page is full, insert the new entry and
1425 * propagate up the router entry for the new page from split
1426 *
1427 * The xtSplitUp() will insert the entry and unpin the leaf page.
1428 */
1430 /* xtSpliUp() unpins leaf pages */
1441 /* get back old page */
1445 /*
1446 * if leaf root has been split, original root has been
1447 * copied to new child page, i.e., original entry now
1448 * resides on the new child page;
1449 */
1457 /* get new child page */
1466 }
1467 }
1468 }
1469 /*
1470 * insert the new entry into the leaf page
1471 */
1473 /* insert the new entry: mark the entry NEW */
1477 /* advance next available entry index */
1479 }
1481 /* get back old entry */
1485 /*
1486 * extend old extent
1487 */
1488 extendOld:
1499 }
1501 /* unpin the leaf page */
1505 }
1507 #ifdef _NOTYET
1508 /*
1509 * xtTailgate()
1510 *
1511 * function: split existing 'tail' extent
1512 * (split offset >= start offset of tail extent), and
1513 * relocate and extend the split tail half;
1514 *
1515 * note: existing extent may or may not have been committed.
1516 * caller is responsible for pager buffer cache update, and
1517 * working block allocation map update;
1518 * update pmap: free old split tail extent, alloc new extent;
1519 */
1525 {
1530 s64 bn;
1540 /*
1541 printf("xtTailgate: nxoff:0x%lx nxlen:0x%x nxaddr:0x%lx\n",
1542 (ulong)xoff, xlen, (ulong)xaddr);
1543 */
1545 /* there must exist extent to be tailgated */
1549 /* retrieve search result */
1556 }
1558 /* entry found must be last entry */
1565 }
1568 /*
1569 * acquire tlock of the leaf page containing original entry
1570 */
1574 }
1576 /* completely replace extent ? */
1578 /*
1579 printf("xtTailgate: xoff:0x%lx xlen:0x%x xaddr:0x%lx\n",
1580 (ulong)offsetXAD(xad), lengthXAD(xad), (ulong)addressXAD(xad));
1581 */
1585 /*
1586 * partially replace extent: insert entry for new extent
1587 */
1588 //insertNew:
1589 /*
1590 * if the leaf page is full, insert the new entry and
1591 * propagate up the router entry for the new page from split
1592 *
1593 * The xtSplitUp() will insert the entry and unpin the leaf page.
1594 */
1596 /* xtSpliUp() unpins leaf pages */
1607 /* get back old page */
1611 /*
1612 * if leaf root has been split, original root has been
1613 * copied to new child page, i.e., original entry now
1614 * resides on the new child page;
1615 */
1623 /* get new child page */
1632 }
1633 }
1634 }
1635 /*
1636 * insert the new entry into the leaf page
1637 */
1639 /* insert the new entry: mark the entry NEW */
1643 /* advance next available entry index */
1645 }
1647 /* get back old XAD */
1650 /*
1651 * truncate/relocate old extent at split offset
1652 */
1653 updateOld:
1654 /* update dmap for old/committed/truncated extent */
1657 /* free from PWMAP at commit */
1665 }
1667 /* free from WMAP */
1671 /* truncate */
1673 else
1674 /* replace */
1682 }
1684 /* unpin the leaf page */
1688 }
1691 /*
1692 * xtUpdate()
1693 *
1694 * function: update XAD;
1695 *
1696 * update extent for allocated_but_not_recorded or
1697 * compressed extent;
1698 *
1699 * parameter:
1700 * nxad - new XAD;
1701 * logical extent of the specified XAD must be completely
1702 * contained by an existing XAD;
1703 */
1710 s64 bn;
1723 /* there must exist extent to be tailgated */
1731 /* retrieve search result */
1738 }
1741 /*
1742 * acquire tlock of the leaf page containing original entry
1743 */
1747 }
1755 /* nXAD must be completely contained within XAD */
1762 }
1768 #ifdef _JFS_WIP_NOCOALESCE
1772 /*
1773 * replace XAD with nXAD
1774 */
1777 /* replace XAD with nXAD:recorded */
1786 /* #ifdef _JFS_WIP_COALESCE */
1790 /*
1791 * coalesce with left XAD
1792 */
1793 //coalesceLeft: /* (xoff == nxoff) */
1794 /* is XAD first entry of page ? */
1798 /* is nXAD logically and physically contiguous with lXAD ? */
1805 /* extend right lXAD */
1809 /* If we just merged two extents together, need to make sure the
1810 * right extent gets logged. If the left one is marked XAD_NEW,
1811 * then we know it will be logged. Otherwise, mark as
1812 * XAD_EXTENDED
1813 */
1818 /* truncate XAD */
1825 /* remove XAD */
1842 }
1843 }
1845 /*
1846 * replace XAD with nXAD
1847 */
1850 /* replace XAD with nXAD:recorded */
1858 /*
1859 * coalesce with right XAD
1860 */
1862 /* is XAD last entry of page ? */
1867 }
1869 /* is nXAD logically and physically contiguous with rXAD ? */
1876 /* extend left rXAD */
1881 /* If we just merged two extents together, need to make sure
1882 * the left extent gets logged. If the right one is marked
1883 * XAD_NEW, then we know it will be logged. Otherwise, mark as
1884 * XAD_EXTENDED
1885 */
1890 /* truncate XAD */
1894 /* remove XAD */
1901 }
1911 }
1912 /* #endif _JFS_WIP_COALESCE */
1914 /*
1915 * split XAD into (lXAD, nXAD):
1916 *
1917 * |---nXAD--->
1918 * --|----------XAD----------|--
1919 * |-lXAD-|
1920 */
1922 /* truncate old XAD as lXAD:not_recorded */
1926 /* insert nXAD:recorded */
1929 /* xtSpliUp() unpins leaf pages */
1940 /* get back old page */
1944 /*
1945 * if leaf root has been split, original root has been
1946 * copied to new child page, i.e., original entry now
1947 * resides on the new child page;
1948 */
1956 /* get new child page */
1965 }
1967 /* is nXAD on new page ? */
1970 newindex =
1971 newindex -
1973 XTENTRYSTART;
1975 }
1976 }
1978 /* if insert into middle, shift right remaining entries */
1983 /* insert the entry */
1988 /* advance next available entry index. */
1991 }
1993 /*
1994 * does nXAD force 3-way split ?
1995 *
1996 * |---nXAD--->|
1997 * --|----------XAD-------------|--
1998 * |-lXAD-| |-rXAD -|
1999 */
2003 /* reorient nXAD as XAD for further split XAD into (nXAD, rXAD) */
2005 /* close out old page */
2012 }
2017 /* get new right page */
2026 }
2030 index++;
2038 /* recompute split pages */
2045 /* retrieve search result */
2052 }
2059 }
2060 }
2062 /*
2063 * split XAD into (nXAD, rXAD)
2064 *
2065 * ---nXAD---|
2066 * --|----------XAD----------|--
2067 * |-rXAD-|
2068 */
2070 /* update old XAD with nXAD:recorded */
2075 /* insert rXAD:not_recorded */
2080 /*
2081 printf("xtUpdate.updateLeft.split p:0x%p\n", p);
2082 */
2083 /* xtSpliUp() unpins leaf pages */
2094 /* get back old page */
2099 /*
2100 * if leaf root has been split, original root has been
2101 * copied to new child page, i.e., original entry now
2102 * resides on the new child page;
2103 */
2111 /* get new child page */
2120 }
2121 }
2123 /* if insert into middle, shift right remaining entries */
2128 /* insert the entry */
2132 /* advance next available entry index. */
2135 }
2137 out:
2143 }
2145 /* unpin the leaf page */
2149 }
2152 /*
2153 * xtAppend()
2154 *
2155 * function: grow in append mode from contiguous region specified ;
2156 *
2157 * parameter:
2158 * tid - transaction id;
2159 * ip - file object;
2160 * xflag - extent flag:
2161 * xoff - extent offset;
2162 * maxblocks - max extent length;
2163 * xlen - extent length (in/out);
2164 * xaddrp - extent address pointer (in/out):
2165 * flag -
2166 *
2167 * return:
2168 */
2174 {
2189 s64 next;
2196 /*
2197 * search for the entry location at which to insert:
2198 *
2199 * xtFastSearch() and xtSearch() both returns (leaf page
2200 * pinned, index at which to insert).
2201 * n.b. xtSearch() may return index of maxentry of
2202 * the full page.
2203 */
2207 /* retrieve search result */
2213 }
2217 //insert:
2218 /*
2219 * insert entry for new extent
2220 */
2223 /*
2224 * if the leaf page is full, split the page and
2225 * propagate up the router entry for the new page from split
2226 *
2227 * The xtSplitUp() will insert the entry and unpin the leaf page.
2228 */
2233 /*
2234 * allocate new index blocks to cover index page split(s)
2235 */
2249 }
2251 /* undo allocation */
2254 }
2258 /*
2259 * allocate data extent requested
2260 */
2271 /* undo data extent allocation */
2275 }
2281 /*
2282 * insert the new entry into the leaf page
2283 */
2284 insertLeaf:
2285 /*
2286 * allocate data extent requested
2287 */
2292 /*
2293 * acquire a transaction lock on the leaf page;
2294 *
2295 * action: xad insertion/extension;
2296 */
2300 /* insert the new entry: mark the entry NEW */
2304 /* advance next available entry index */
2315 out:
2316 /* unpin the leaf page */
2320 }
2321 #ifdef _STILL_TO_PORT
2323 /* - TBD for defragmentaion/reorganization -
2324 *
2325 * xtDelete()
2326 *
2327 * function:
2328 * delete the entry with the specified key.
2329 *
2330 * N.B.: whole extent of the entry is assumed to be deleted.
2331 *
2332 * parameter:
2333 *
2334 * return:
2335 * ENOENT: if the entry is not found.
2336 *
2337 * exception:
2338 */
2340 {
2344 s64 bn;
2351 /*
2352 * find the matching entry; xtSearch() pins the page
2353 */
2359 /* unpin the leaf page */
2362 }
2364 /*
2365 * delete the entry from the leaf page
2366 */
2370 /*
2371 * if the leaf page bocome empty, free the page
2372 */
2377 /*
2378 * acquire a transaction lock on the leaf page;
2379 *
2380 * action:xad deletion;
2381 */
2387 /* if delete from middle, shift left/compact the remaining entries */
2395 }
2398 /* - TBD for defragmentaion/reorganization -
2399 *
2400 * xtDeleteUp()
2401 *
2402 * function:
2403 * free empty pages as propagating deletion up the tree
2404 *
2405 * parameter:
2406 *
2407 * return:
2408 */
2409 static int
2412 {
2417 s64 xaddr;
2423 /*
2424 * keep root leaf page which has become empty
2425 */
2427 /* keep the root page */
2432 /* XT_PUTPAGE(fmp); */
2435 }
2437 /*
2438 * free non-root leaf page
2439 */
2443 }
2447 /* free the page extent */
2450 /* free the buffer page */
2453 /*
2454 * propagate page deletion up the index tree
2455 *
2456 * If the delete from the parent page makes it empty,
2457 * continue all the way up the tree.
2458 * stop if the root page is reached (which is never deleted) or
2459 * if the entry deletion does not empty the page.
2460 */
2462 /* get/pin the parent page <sp> */
2469 /* delete the entry for the freed child page from parent.
2470 */
2473 /*
2474 * the parent has the single entry being deleted:
2475 * free the parent page which has become empty.
2476 */
2479 /* keep the root page */
2485 /* XT_PUTPAGE(mp); */
2489 /* free the parent page */
2494 /* free the page extent */
2498 /* unpin/free the buffer page */
2501 /* propagate up */
2503 }
2504 }
2505 /*
2506 * the parent has other entries remaining:
2507 * delete the router entry from the parent page.
2508 */
2511 /*
2512 * acquire a transaction lock on the leaf page;
2513 *
2514 * action:xad deletion;
2515 */
2523 /* if delete from middle,
2524 * shift left/compact the remaining entries in the page
2525 */
2534 }
2536 /* unpin the parent page */
2539 /* exit propagation up */
2541 }
2544 }
2547 /*
2548 * NAME: xtRelocate()
2549 *
2550 * FUNCTION: relocate xtpage or data extent of regular file;
2551 * This function is mainly used by defragfs utility.
2552 *
2553 * NOTE: This routine does not have the logic to handle
2554 * uncommitted allocated extent. The caller should call
2555 * txCommit() to commit all the allocation before call
2556 * this routine.
2557 */
2558 int
2577 s64 bn;
2589 /* validate extent offset */
2597 /*
2598 * 1. get and validate the parent xtpage/xad entry
2599 * covering the source extent to be relocated;
2600 */
2602 /* search in leaf entry */
2607 /* retrieve search result */
2613 }
2615 /* validate for exact match with a single entry */
2620 }
2623 /* search in internal entry */
2628 /* retrieve search result */
2634 }
2636 /* xtSearchNode() validated for exact match with a single entry
2637 */
2639 }
2642 /*
2643 * 2. relocate the extent
2644 */
2646 /* if the extent is allocated-but-not-recorded
2647 * there is no real data to be moved in this extent,
2648 */
2651 else
2652 /* release xtpage for cmRead()/xtLookup() */
2655 /*
2656 * cmRelocate()
2657 *
2658 * copy target data pages to be relocated;
2659 *
2660 * data extent must start at page boundary and
2661 * multiple of page size (except the last data extent);
2662 * read in each page of the source data extent into cbuf,
2663 * update the cbuf extent descriptor of the page to be
2664 * homeward bound to new dst data extent
2665 * copy the data from the old extent to new extent.
2666 * copy is essential for compressed files to avoid problems
2667 * that can arise if there was a change in compression
2668 * algorithms.
2669 * it is a good strategy because it may disrupt cache
2670 * policy to keep the pages in memory afterwards.
2671 */
2677 /*
2678 npages = ((offset + nbytes - 1) >> CM_L2BSIZE) -
2679 (offset >> CM_L2BSIZE) + 1;
2680 */
2684 /* process the request one cache buffer at a time */
2687 /* compute page size */
2690 /* get the cache buffer of the page */
2697 /* bind buffer with the new extent address */
2701 /* release the cbuf, mark it as modified */
2706 }
2708 /* get back parent page */
2716 /*
2717 * read in the target xtpage from the source extent;
2718 */
2723 }
2725 /*
2726 * read in sibling pages if any to update sibling pointers;
2727 */
2736 }
2737 }
2749 }
2750 }
2752 /* at this point, all xtpages to be updated are in memory */
2754 /*
2755 * update sibling pointers of sibling xtpages if any;
2756 */
2762 }
2769 }
2771 /*
2772 * update the target xtpage to be relocated
2773 *
2774 * update the self address of the target page
2775 * and write to destination extent;
2776 * redo image covers the whole xtpage since it is new page
2777 * to the destination extent;
2778 * update of bmap for the free of source extent
2779 * of the target xtpage itself:
2780 * update of bmap for the allocation of destination extent
2781 * of the target xtpage itself:
2782 * update of bmap for the extents covered by xad entries in
2783 * the target xtpage is not necessary since they are not
2784 * updated;
2785 * if not committed before this relocation,
2786 * target page may contain XAD_NEW entries which must
2787 * be scanned for bmap update (logredo() always
2788 * scan xtpage REDOPAGE image for bmap update);
2789 * if committed before this relocation (tlckRELOCATE),
2790 * scan may be skipped by commit() and logredo();
2791 */
2793 /* tlckNEW init xtlck->lwm.offset = XTENTRYSTART; */
2797 /* update the self address in the xtpage header */
2801 /* linelock for the after image of the whole page */
2805 /* update the buffer extent descriptor of target xtpage */
2809 /* unpin the target page to new homeward bound */
2812 }
2814 /*
2815 * 3. acquire maplock for the source extent to be freed;
2816 *
2817 * acquire a maplock saving the src relocated extent address;
2818 * to free of the extent at commit time;
2819 */
2820 out:
2821 /* if DATAEXT relocation, write a LOG_UPDATEMAP record for
2822 * free PXD of the source data extent (logredo() will update
2823 * bmap for free of source data extent), and update bmap for
2824 * free of the source data extent;
2825 */
2828 /* if XTPAGE relocation, write a LOG_NOREDOPAGE record
2829 * for the source xtpage (logredo() will init NoRedoPage
2830 * filter and will also update bmap for free of the source
2831 * xtpage), and update bmap for free of the source xtpage;
2832 * N.B. We use tlckMAP instead of tlkcXTREE because there
2833 * is no buffer associated with this lock since the buffer
2834 * has been redirected to the target location.
2835 */
2845 /*
2846 * 4. update the parent xad entry for relocation;
2847 *
2848 * acquire tlck for the parent entry with XAD_NEW as entry
2849 * update which will write LOG_REDOPAGE and update bmap for
2850 * allocation of XAD_NEW destination extent;
2851 */
2857 /* update the XAD with the new destination extent; */
2866 /* unpin the parent xtpage */
2870 }
2873 /*
2874 * xtSearchNode()
2875 *
2876 * function: search for the internal xad entry covering specified extent.
2877 * This function is mainly used by defragfs utility.
2878 *
2879 * parameters:
2880 * ip - file object;
2881 * xad - extent to find;
2882 * cmpp - comparison result:
2883 * btstack - traverse stack;
2884 * flag - search process flag;
2885 *
2886 * returns:
2887 * btstack contains (bn, index) of search path traversed to the entry.
2888 * *cmpp is set to result of comparison with the entry returned.
2889 * the page containing the entry is pinned at exit.
2890 */
2893 {
2903 s64 t64;
2911 /*
2912 * search down tree from root:
2913 *
2914 * between two consecutive entries of <Ki, Pi> and <Kj, Pj> of
2915 * internal page, child page Pi contains entry with k, Ki <= K < Kj.
2916 *
2917 * if entry with search key K is not found
2918 * internal page search find the entry with largest key Ki
2919 * less than K which point to the child page to search;
2920 * leaf page search find the entry with smallest key Kj
2921 * greater than K so that the returned index is the position of
2922 * the entry to be shifted right for insertion of new entry.
2923 * for empty tree, search key is greater than any key of the tree.
2924 *
2925 * by convention, root bn = 0.
2926 */
2928 /* get/pin the page to search */
2935 }
2939 /*
2940 * binary search with search key K on the current page
2941 */
2947 /*
2948 * search hit
2949 *
2950 * verify for exact match;
2951 */
2956 /* save search result */
2963 }
2965 /* descend/search its child page */
2967 }
2972 }
2973 }
2975 /*
2976 * search miss - non-leaf page:
2977 *
2978 * base is the smallest index with key (Kj) greater than
2979 * search key (K) and may be zero or maxentry index.
2980 * if base is non-zero, decrement base by one to get the parent
2981 * entry of the child page to search.
2982 */
2985 /*
2986 * go down to child page
2987 */
2988 next:
2989 /* get the child page block number */
2992 /* unpin the parent page */
2994 }
2995 }
2998 /*
2999 * xtRelink()
3000 *
3001 * function:
3002 * link around a freed page.
3003 *
3004 * Parameter:
3005 * int tid,
3006 * struct inode *ip,
3007 * xtpage_t *p)
3008 *
3009 * returns:
3010 */
3012 {
3021 /* update prev pointer of the next page */
3027 /*
3028 * acquire a transaction lock on the page;
3029 *
3030 * action: update prev pointer;
3031 */
3035 /* the page may already have been tlock'd */
3040 }
3042 /* update next pointer of the previous page */
3048 /*
3049 * acquire a transaction lock on the page;
3050 *
3051 * action: update next pointer;
3052 */
3056 /* the page may already have been tlock'd */
3061 }
3064 }
3068 /*
3069 * xtInitRoot()
3070 *
3071 * initialize file root (inline in inode)
3072 */
3074 {
3077 /*
3078 * acquire a transaction lock on the root
3079 *
3080 * action:
3081 */
3094 }
3098 }
3101 /*
3102 * We can run into a deadlock truncating a file with a large number of
3103 * xtree pages (large fragmented file). A robust fix would entail a
3104 * reservation system where we would reserve a number of metadata pages
3105 * and tlocks which we would be guaranteed without a deadlock. Without
3106 * this, a partial fix is to limit number of metadata pages we will lock
3107 * in a single transaction. Currently we will truncate the file so that
3108 * no more than 50 leaf pages will be locked. The caller of xtTruncate
3109 * will be responsible for ensuring that the current transaction gets
3110 * committed, and that subsequent transactions are created to truncate
3111 * the file further if needed.
3112 */
3113 #define MAX_TRUNCATE_LEAVES 50
3115 /*
3116 * xtTruncate()
3117 *
3118 * function:
3119 * traverse for truncation logging backward bottom up;
3120 * terminate at the last extent entry at the current subtree
3121 * root page covering new down size.
3122 * truncation may occur within the last extent entry.
3123 *
3124 * parameter:
3125 * int tid,
3126 * struct inode *ip,
3127 * s64 newsize,
3128 * int type) {PWMAP, PMAP, WMAP; DELETE, TRUNCATE}
3129 *
3130 * return:
3131 *
3132 * note:
3133 * PWMAP:
3134 * 1. truncate (non-COMMIT_NOLINK file)
3135 * by jfs_truncate() or jfs_open(O_TRUNC):
3136 * xtree is updated;
3137 * 2. truncate index table of directory when last entry removed
3138 * map update via tlock at commit time;
3139 * PMAP:
3140 * Call xtTruncate_pmap instead
3141 * WMAP:
3142 * 1. remove (free zero link count) on last reference release
3143 * (pmap has been freed at commit zero link count);
3144 * 2. truncate (COMMIT_NOLINK file, i.e., tmp file):
3145 * xtree is updated;
3146 * map update directly at truncation time;
3147 *
3148 * if (DELETE)
3149 * no LOG_NOREDOPAGE is required (NOREDOFILE is sufficient);
3150 * else if (TRUNCATE)
3151 * must write LOG_NOREDOPAGE for deleted index page;
3152 *
3153 * pages may already have been tlocked by anonymous transactions
3154 * during file growth (i.e., write) before truncation;
3155 *
3156 * except last truncated entry, deleted entries remains as is
3157 * in the page (nextindex is updated) for other use
3158 * (e.g., log/update allocation map): this avoid copying the page
3159 * info but delay free of pages;
3160 *
3161 */
3163 {
3165 s64 teof;
3168 s64 bn;
3180 s64 nfreed;
3184 /* save object truncation type */
3188 }
3201 }
3203 /*
3204 * if the newsize is not an integral number of pages,
3205 * the file between newsize and next page boundary will
3206 * be cleared.
3207 * if truncating into a file hole, it will cause
3208 * a full block to be allocated for the logical block.
3209 */
3211 /*
3212 * release page blocks of truncated region <teof, eof>
3213 *
3214 * free the data blocks from the leaf index blocks.
3215 * delete the parent index entries corresponding to
3216 * the freed child data/index blocks.
3217 * free the index blocks themselves which aren't needed
3218 * in new sized file.
3219 *
3220 * index blocks are updated only if the blocks are to be
3221 * retained in the new sized file.
3222 * if type is PMAP, the data and index pages are NOT
3223 * freed, and the data and index blocks are NOT freed
3224 * from working map.
3225 * (this will allow continued access of data/index of
3226 * temporary file (zerolink count file truncated to zero-length)).
3227 */
3231 /* clear stack */
3234 /*
3235 * start with root
3236 *
3237 * root resides in the inode
3238 */
3241 /*
3242 * first access of each page:
3243 */
3244 getPage:
3249 /* process entries backward from last index */
3253 /* Since this is the rightmost page at this level, and we may have
3254 * already freed a page that was formerly to the right, let's make
3255 * sure that the next pointer is zero.
3256 */
3259 /*
3260 * Make sure this change to the header is logged.
3261 * If we really truncate this leaf, the flag
3262 * will be changed to tlckTRUNCATE
3263 */
3267 }
3272 /*
3273 * leaf page
3274 */
3277 /* does region covered by leaf page precede Teof ? */
3284 }
3286 /* (re)acquire tlock of the leaf page */
3289 /*
3290 * We need to limit the size of the transaction
3291 * to avoid exhausting pagecache & tlocks
3292 */
3296 }
3301 }
3304 /*
3305 * scan backward leaf page entries
3306 */
3313 /*
3314 * The "data" for a directory is indexed by the block
3315 * device's address space. This metadata must be invalidated
3316 * here
3317 */
3320 /*
3321 * entry beyond eof: continue scan of current page
3322 * xad
3323 * ---|---=======------->
3324 * eof
3325 */
3329 }
3331 /*
3332 * (xoff <= teof): last entry to be deleted from page;
3333 * If other entries remain in page: keep and update the page.
3334 */
3336 /*
3337 * eof == entry_start: delete the entry
3338 * xad
3339 * -------|=======------->
3340 * eof
3341 *
3342 */
3350 }
3351 /*
3352 * eof within the entry: truncate the entry.
3353 * xad
3354 * -------===|===------->
3355 * eof
3356 */
3358 /* update truncated entry */
3363 /* save pxd of truncated extent in tlck */
3375 }
3376 /* free truncated extent */
3385 /* reset map lock */
3387 }
3389 /* current entry is new last entry; */
3393 }
3394 /*
3395 * eof beyond the entry:
3396 * xad
3397 * -------=======---|--->
3398 * eof
3399 */
3403 }
3410 nextindex;
3413 }
3415 }
3419 /* assert(freed == 0); */
3425 /*
3426 * leaf page become empty: free the page if type != PMAP
3427 */
3429 /* txCommit() with tlckFREE:
3430 * free data extents covered by leaf [XTENTRYSTART:hwm);
3431 * invalidate leaf if COMMIT_PWMAP;
3432 * if (TRUNCATE), will write LOG_NOREDOPAGE;
3433 */
3437 /* free data extents covered by leaf */
3442 }
3453 /* page will be invalidated at tx completion
3454 */
3461 /* invalidate empty leaf page */
3463 }
3464 }
3466 /*
3467 * the leaf page become empty: delete the parent entry
3468 * for the leaf page if the parent page is to be kept
3469 * in the new sized file.
3470 */
3472 /*
3473 * go back up to the parent page
3474 */
3475 getParent:
3476 /* pop/restore parent entry for the current child page */
3478 /* current page must have been root */
3481 /* get back the parent page */
3489 /*
3490 * child page was not empty:
3491 */
3493 /* has any entry deleted from parent ? */
3495 /* (re)acquire tlock on the parent page */
3497 /* txCommit() with tlckTRUNCATE:
3498 * free child extents covered by parent [);
3499 */
3508 }
3511 /* free child extents covered by parent */
3518 }
3522 }
3525 }
3527 /*
3528 * child page was empty:
3529 */
3532 /*
3533 * During working map update, child page's tlock must be handled
3534 * before parent's. This is because the parent's tlock will cause
3535 * the child's disk space to be marked available in the wmap, so
3536 * it's important that the child page be released by that time.
3537 *
3538 * ToDo: tlocks should be on doubly-linked list, so we can
3539 * quickly remove it and add it to the end.
3540 */
3542 /*
3543 * Move parent page's tlock to the end of the tid's tlock list
3544 */
3559 }
3561 }
3565 }
3567 /*
3568 * parent page become empty: free the page
3569 */
3572 /* txCommit() with tlckFREE:
3573 * free child extents covered by parent;
3574 * invalidate parent if COMMIT_PWMAP;
3575 */
3583 /* free child extents covered by parent */
3587 XTENTRYSTART;
3589 COMMIT_WMAP);
3590 }
3598 /*
3599 * Shrink root down to allow inline
3600 * EA (otherwise fsck complains)
3601 */
3605 }
3611 /* page will be invalidated at tx completion
3612 */
3618 tlckFREELOCK;
3620 /* invalidate parent page */
3622 }
3624 /* parent has become empty and freed:
3625 * go back up to its parent page
3626 */
3627 /* freed = 1; */
3629 }
3630 }
3631 /*
3632 * parent page still has entries for front region;
3633 */
3635 /* try truncate region covered by preceding entry
3636 * (process backward)
3637 */
3638 index--;
3640 /* go back down to the child page corresponding
3641 * to the entry
3642 */
3644 }
3646 /*
3647 * internal page: go down to child page of current entry
3648 */
3649 getChild:
3650 /* save current parent entry for the child page */
3655 }
3658 /* get child page */
3662 /*
3663 * first access of each internal entry:
3664 */
3665 /* release parent page */
3668 /* process the child page */
3671 out:
3672 /*
3673 * update file resource stat
3674 */
3675 /* set size
3676 */
3679 else
3682 /* update quota allocation to reflect freed blocks */
3685 /*
3686 * free tlock of invalidated pages
3687 */
3692 }
3695 /*
3696 * xtTruncate_pmap()
3697 *
3698 * function:
3699 * Perform truncate to zero length for deleted file, leaving the
3700 * the xtree and working map untouched. This allows the file to
3701 * be accessed via open file handles, while the delete of the file
3702 * is committed to disk.
3703 *
3704 * parameter:
3705 * tid_t tid,
3706 * struct inode *ip,
3707 * s64 committed_size)
3708 *
3709 * return: new committed size
3710 *
3711 * note:
3712 *
3713 * To avoid deadlock by holding too many transaction locks, the
3714 * truncation may be broken up into multiple transactions.
3715 * The committed_size keeps track of part of the file has been
3716 * freed from the pmaps.
3717 */
3719 {
3720 s64 bn;
3733 s64 xoff;
3736 /* save object truncation type */
3740 /* clear stack */
3756 }
3758 /*
3759 * start with root
3760 *
3761 * root resides in the inode
3762 */
3765 /*
3766 * first access of each page:
3767 */
3768 getPage:
3773 /* process entries backward from last index */
3778 }
3780 /*
3781 * leaf page
3782 */
3785 /*
3786 * We need to limit the size of the transaction
3787 * to avoid exhausting pagecache & tlocks
3788 */
3794 }
3803 /*
3804 * go back up to the parent page
3805 */
3806 getParent:
3807 /* pop/restore parent entry for the current child page */
3809 /* current page must have been root */
3812 /* get back the parent page */
3820 /*
3821 * parent page become empty: free the page
3822 */
3824 /* txCommit() with tlckFREE:
3825 * free child extents covered by parent;
3826 * invalidate parent if COMMIT_PWMAP;
3827 */
3840 }
3841 }
3842 /*
3843 * parent page still has entries for front region;
3844 */
3845 else
3846 index--;
3847 /*
3848 * internal page: go down to child page of current entry
3849 */
3850 getChild:
3851 /* save current parent entry for the child page */
3856 }
3859 /* get child page */
3863 /*
3864 * first access of each internal entry:
3865 */
3866 /* release parent page */
3869 /* process the child page */
3872 out:
3875 }
3877 #ifdef CONFIG_JFS_STATISTICS
3879 {
3890 }
3893 {
3895 }
3903 };
3904 #endif