| blob | d1a0848cb52eca6698cd2a224f3f78179be2e9ad |
1 // SPDX-License-Identifier: GPL-2.0
2 /*
3 * Copyright (c) 2000-2003,2005 Silicon Graphics, Inc.
4 * Copyright (C) 2010 Red Hat, Inc.
5 * All Rights Reserved.
6 */
23 #define _ALLOC true
24 #define _FREE false
26 /*
27 * A buffer has a format structure overhead in the log in addition
28 * to the data, so we need to take this into account when reserving
29 * space in a transaction for a buffer. Round the space required up
30 * to a multiple of 128 bytes so that we don't change the historical
31 * reservation that has been used for this overhead.
32 */
33 STATIC uint
35 {
38 }
40 /*
41 * Calculate out transaction log reservation per item in bytes.
42 *
43 * The nbufs argument is used to indicate the number of items that
44 * will be changed in a transaction. size is used to tell how many
45 * bytes should be reserved per item.
46 */
47 STATIC uint
49 uint nbufs,
50 uint size)
51 {
53 }
55 /*
56 * Per-extent log reservation for the btree changes involved in freeing or
57 * allocating an extent. In classic XFS there were two trees that will be
58 * modified (bnobt + cntbt). With rmap enabled, there are three trees
59 * (rmapbt). With reflink, there are four trees (refcountbt). The number of
60 * blocks reserved is based on the formula:
61 *
62 * num trees * ((2 blocks/level * max depth) - 1)
63 *
64 * Keep in mind that max depth is calculated separately for each type of tree.
65 */
66 uint
69 uint num_ops)
70 {
71 uint blocks;
80 }
82 /*
83 * Logging inodes is really tricksy. They are logged in memory format,
84 * which means that what we write into the log doesn't directly translate into
85 * the amount of space they use on disk.
86 *
87 * Case in point - btree format forks in memory format use more space than the
88 * on-disk format. In memory, the buffer contains a normal btree block header so
89 * the btree code can treat it as though it is just another generic buffer.
90 * However, when we write it to the inode fork, we don't write all of this
91 * header as it isn't needed. e.g. the root is only ever in the inode, so
92 * there's no need for sibling pointers which would waste 16 bytes of space.
93 *
94 * Hence when we have an inode with a maximally sized btree format fork, then
95 * amount of information we actually log is greater than the size of the inode
96 * on disk. Hence we need an inode reservation function that calculates all this
97 * correctly. So, we log:
98 *
99 * - 4 log op headers for object
100 * - for the ilf, the inode core and 2 forks
101 * - inode log format object
102 * - the inode core
103 * - two inode forks containing bmap btree root blocks.
104 * - the btree data contained by both forks will fit into the inode size,
105 * hence when combined with the inode core above, we have a total of the
106 * actual inode size.
107 * - the BMBT headers need to be accounted separately, as they are
108 * additional to the records and pointers that fit inside the inode
109 * forks.
110 */
111 STATIC uint
114 uint ninodes)
115 {
121 }
123 /*
124 * Inode btree record insertion/removal modifies the inode btree and free space
125 * btrees (since the inobt does not use the agfl). This requires the following
126 * reservation:
127 *
128 * the inode btree: max depth * blocksize
129 * the allocation btrees: 2 trees * (max depth - 1) * block size
130 *
131 * The caller must account for SB and AG header modifications, etc.
132 */
133 STATIC uint
136 {
141 }
143 /*
144 * The free inode btree is a conditional feature. The behavior differs slightly
145 * from that of the traditional inode btree in that the finobt tracks records
146 * for inode chunks with at least one free inode. A record can be removed from
147 * the tree during individual inode allocation. Therefore the finobt
148 * reservation is unconditional for both the inode chunk allocation and
149 * individual inode allocation (modify) cases.
150 *
151 * Behavior aside, the reservation for finobt modification is equivalent to the
152 * traditional inobt: cover a full finobt shape change plus block allocation.
153 */
154 STATIC uint
157 {
162 }
164 /*
165 * Calculate the reservation required to allocate or free an inode chunk. This
166 * includes:
167 *
168 * the allocation btrees: 2 trees * (max depth - 1) * block size
169 * the inode chunk: m_ino_geo.ialloc_blks * N
170 *
171 * The size N of the inode chunk reservation depends on whether it is for
172 * allocation or free and which type of create transaction is in use. An inode
173 * chunk free always invalidates the buffers and only requires reservation for
174 * headers (N == 0). An inode chunk allocation requires a chunk sized
175 * reservation on v4 and older superblocks to initialize the chunk. No chunk
176 * reservation is required for allocation on v5 supers, which use ordered
177 * buffers to initialize.
178 */
179 STATIC uint
183 {
189 /* icreate tx uses ordered buffers */
193 }
197 }
199 /*
200 * Per-extent log reservation for the btree changes involved in freeing or
201 * allocating a realtime extent. We have to be able to log as many rtbitmap
202 * blocks as needed to mark inuse MAXEXTLEN blocks' worth of realtime extents,
203 * as well as the realtime summary block.
204 */
205 static unsigned int
209 {
215 }
217 /*
218 * Various log reservation values.
219 *
220 * These are based on the size of the file system block because that is what
221 * most transactions manipulate. Each adds in an additional 128 bytes per
222 * item logged to try to account for the overhead of the transaction mechanism.
223 *
224 * Note: Most of the reservations underestimate the number of allocation
225 * groups into which they could free extents in the xfs_defer_finish() call.
226 * This is because the number in the worst case is quite high and quite
227 * unusual. In order to fix this we need to change xfs_defer_finish() to free
228 * extents in only a single AG at a time. This will require changes to the
229 * EFI code as well, however, so that the EFI for the extents not freed is
230 * logged again in each transaction. See SGI PV #261917.
231 *
232 * Reservation functions here avoid a huge stack in xfs_trans_init due to
233 * register overflow from temporaries in the calculations.
234 */
237 /*
238 * In a write transaction we can allocate a maximum of 2
239 * extents. This gives (t1):
240 * the inode getting the new extents: inode size
241 * the inode's bmap btree: max depth * block size
242 * the agfs of the ags from which the extents are allocated: 2 * sector
243 * the superblock free block counter: sector size
244 * the allocation btrees: 2 exts * 2 trees * (2 * max depth - 1) * block size
245 * Or, if we're writing to a realtime file (t2):
246 * the inode getting the new extents: inode size
247 * the inode's bmap btree: max depth * block size
248 * the agfs of the ags from which the extents are allocated: 2 * sector
249 * the superblock free block counter: sector size
250 * the realtime bitmap: ((MAXEXTLEN / rtextsize) / NBBY) bytes
251 * the realtime summary: 1 block
252 * the allocation btrees: 2 trees * (2 * max depth - 1) * block size
253 * And the bmap_finish transaction can free bmap blocks in a join (t3):
254 * the agfs of the ags containing the blocks: 2 * sector size
255 * the agfls of the ags containing the blocks: 2 * sector size
256 * the super block free block counter: sector size
257 * the allocation btrees: 2 exts * 2 trees * (2 * max depth - 1) * block size
258 */
259 STATIC uint
262 {
274 blksz) +
280 }
286 }
288 /*
289 * In truncating a file we free up to two extents at once. We can modify (t1):
290 * the inode being truncated: inode size
291 * the inode's bmap btree: (max depth + 1) * block size
292 * And the bmap_finish transaction can free the blocks and bmap blocks (t2):
293 * the agf for each of the ags: 4 * sector size
294 * the agfl for each of the ags: 4 * sector size
295 * the super block to reflect the freed blocks: sector size
296 * worst case split in allocation btrees per extent assuming 4 extents:
297 * 4 exts * 2 trees * (2 * max depth - 1) * block size
298 * Or, if it's a realtime file (t3):
299 * the agf for each of the ags: 2 * sector size
300 * the agfl for each of the ags: 2 * sector size
301 * the super block to reflect the freed blocks: sector size
302 * the realtime bitmap: 2 exts * ((MAXEXTLEN / rtextsize) / NBBY) bytes
303 * the realtime summary: 2 exts * 1 block
304 * worst case split in allocation btrees per extent assuming 2 extents:
305 * 2 exts * 2 trees * (2 * max depth - 1) * block size
306 */
307 STATIC uint
310 {
326 }
329 }
331 /*
332 * In renaming a files we can modify:
333 * the four inodes involved: 4 * inode size
334 * the two directory btrees: 2 * (max depth + v2) * dir block size
335 * the two directory bmap btrees: 2 * max depth * block size
336 * And the bmap_finish transaction can free dir and bmap blocks (two sets
337 * of bmap blocks) giving:
338 * the agf for the ags in which the blocks live: 3 * sector size
339 * the agfl for the ags in which the blocks live: 3 * sector size
340 * the superblock for the free block count: sector size
341 * the allocation btrees: 3 exts * 2 trees * (2 * max depth - 1) * block size
342 */
343 STATIC uint
346 {
354 }
356 /*
357 * For removing an inode from unlinked list at first, we can modify:
358 * the agi hash list and counters: sector size
359 * the on disk inode before ours in the agi hash list: inode cluster size
360 * the on disk inode in the agi hash list: inode cluster size
361 */
362 STATIC uint
365 {
368 }
370 /*
371 * For creating a link to an inode:
372 * the parent directory inode: inode size
373 * the linked inode: inode size
374 * the directory btree could split: (max depth + v2) * dir block size
375 * the directory bmap btree could join or split: (max depth + v2) * blocksize
376 * And the bmap_finish transaction can free some bmap blocks giving:
377 * the agf for the ag in which the blocks live: sector size
378 * the agfl for the ag in which the blocks live: sector size
379 * the superblock for the free block count: sector size
380 * the allocation btrees: 2 trees * (2 * max depth - 1) * block size
381 */
382 STATIC uint
385 {
394 }
396 /*
397 * For adding an inode to unlinked list we can modify:
398 * the agi hash list: sector size
399 * the on disk inode: inode cluster size
400 */
401 STATIC uint
403 {
406 }
408 /*
409 * For removing a directory entry we can modify:
410 * the parent directory inode: inode size
411 * the removed inode: inode size
412 * the directory btree could join: (max depth + v2) * dir block size
413 * the directory bmap btree could join or split: (max depth + v2) * blocksize
414 * And the bmap_finish transaction can free the dir and bmap blocks giving:
415 * the agf for the ag in which the blocks live: 2 * sector size
416 * the agfl for the ag in which the blocks live: 2 * sector size
417 * the superblock for the free block count: sector size
418 * the allocation btrees: 2 exts * 2 trees * (2 * max depth - 1) * block size
419 */
420 STATIC uint
423 {
432 }
434 /*
435 * For create, break it in to the two cases that the transaction
436 * covers. We start with the modify case - allocation done by modification
437 * of the state of existing inodes - and the allocation case.
438 */
440 /*
441 * For create we can modify:
442 * the parent directory inode: inode size
443 * the new inode: inode size
444 * the inode btree entry: block size
445 * the superblock for the nlink flag: sector size
446 * the directory btree: (max depth + v2) * dir block size
447 * the directory inode's bmap btree: (max depth + v2) * block size
448 * the finobt (record modification and allocation btrees)
449 */
450 STATIC uint
453 {
459 }
461 /*
462 * For icreate we can allocate some inodes giving:
463 * the agi and agf of the ag getting the new inodes: 2 * sectorsize
464 * the superblock for the nlink flag: sector size
465 * the inode chunk (allocation, optional init)
466 * the inobt (record insertion)
467 * the finobt (optional, record insertion)
468 */
469 STATIC uint
472 {
478 }
480 STATIC uint
482 {
486 }
488 STATIC uint
491 {
496 }
498 /*
499 * Making a new directory is the same as creating a new file.
500 */
501 STATIC uint
504 {
506 }
509 /*
510 * Making a new symplink is the same as creating a new file, but
511 * with the added blocks for remote symlink data which can be up to 1kB in
512 * length (XFS_SYMLINK_MAXLEN).
513 */
514 STATIC uint
517 {
520 }
522 /*
523 * In freeing an inode we can modify:
524 * the inode being freed: inode size
525 * the super block free inode counter, AGF and AGFL: sector size
526 * the on disk inode (agi unlinked list removal)
527 * the inode chunk (invalidated, headers only)
528 * the inode btree
529 * the finobt (record insertion, removal or modification)
530 *
531 * Note that the inode chunk res. includes an allocfree res. for freeing of the
532 * inode chunk. This is technically extraneous because the inode chunk free is
533 * deferred (it occurs after a transaction roll). Include the extra reservation
534 * anyways since we've had reports of ifree transaction overruns due to too many
535 * agfl fixups during inode chunk frees.
536 */
537 STATIC uint
540 {
548 }
550 /*
551 * When only changing the inode we log the inode and possibly the superblock
552 * We also add a bit of slop for the transaction stuff.
553 */
554 STATIC uint
557 {
562 }
564 /*
565 * Growing the data section of the filesystem.
566 * superblock
567 * agi and agf
568 * allocation btrees
569 */
570 STATIC uint
573 {
577 }
579 /*
580 * Growing the rt section of the filesystem.
581 * In the first set of transactions (ALLOC) we allocate space to the
582 * bitmap or summary files.
583 * superblock: sector size
584 * agf of the ag from which the extent is allocated: sector size
585 * bmap btree for bitmap/summary inode: max depth * blocksize
586 * bitmap/summary inode: inode size
587 * allocation btrees for 1 block alloc: 2 * (2 * maxdepth - 1) * blocksize
588 */
589 STATIC uint
592 {
599 }
601 /*
602 * Growing the rt section of the filesystem.
603 * In the second set of transactions (ZERO) we zero the new metadata blocks.
604 * one bitmap/summary block: blocksize
605 */
606 STATIC uint
609 {
611 }
613 /*
614 * Growing the rt section of the filesystem.
615 * In the third set of transactions (FREE) we update metadata without
616 * allocating any new blocks.
617 * superblock: sector size
618 * bitmap inode: inode size
619 * summary inode: inode size
620 * one bitmap block: blocksize
621 * summary blocks: new summary size
622 */
623 STATIC uint
626 {
631 }
633 /*
634 * Logging the inode modification timestamp on a synchronous write.
635 * inode
636 */
637 STATIC uint
640 {
642 }
644 /*
645 * Logging the inode mode bits when writing a setuid/setgid file
646 * inode
647 */
648 STATIC uint
651 {
653 }
655 /*
656 * Converting the inode from non-attributed to attributed.
657 * the inode being converted: inode size
658 * agf block and superblock (for block allocation)
659 * the new block (directory sized)
660 * bmap blocks for the new directory block
661 * allocation btrees
662 */
663 STATIC uint
666 {
675 }
677 /*
678 * Removing the attribute fork of a file
679 * the inode being truncated: inode size
680 * the inode's bmap btree: max depth * block size
681 * And the bmap_finish transaction can free the blocks and bmap blocks:
682 * the agf for each of the ags: 4 * sector size
683 * the agfl for each of the ags: 4 * sector size
684 * the super block to reflect the freed blocks: sector size
685 * worst case split in allocation btrees per extent assuming 4 extents:
686 * 4 exts * 2 trees * (2 * max depth - 1) * block size
687 */
688 STATIC uint
691 {
698 }
700 /*
701 * Setting an attribute at mount time.
702 * the inode getting the attribute
703 * the superblock for allocations
704 * the agfs extents are allocated from
705 * the attribute btree * max depth
706 * the inode allocation btree
707 * Since attribute transaction space is dependent on the size of the attribute,
708 * the calculation is done partially at mount time and partially at runtime(see
709 * below).
710 */
711 STATIC uint
714 {
719 }
721 /*
722 * Setting an attribute at runtime, transaction space unit per block.
723 * the superblock for allocations: sector size
724 * the inode bmap btree could join or split: max depth * block size
725 * Since the runtime attribute transaction space is dependent on the total
726 * blocks needed for the 1st bmap, here we calculate out the space unit for
727 * one block so that the caller could figure out the total space according
728 * to the attibute extent length in blocks by:
729 * ext * M_RES(mp)->tr_attrsetrt.tr_logres
730 */
731 STATIC uint
734 {
738 }
740 /*
741 * Removing an attribute.
742 * the inode: inode size
743 * the attribute btree could join: max depth * block size
744 * the inode bmap btree could join or split: max depth * block size
745 * And the bmap_finish transaction can free the attr blocks freed giving:
746 * the agf for the ag in which the blocks live: 2 * sector size
747 * the agfl for the ag in which the blocks live: 2 * sector size
748 * the superblock for the free block count: sector size
749 * the allocation btrees: 2 exts * 2 trees * (2 * max depth - 1) * block size
750 */
751 STATIC uint
754 {
765 }
767 /*
768 * Clearing a bad agino number in an agi hash bucket.
769 */
770 STATIC uint
773 {
775 }
777 /*
778 * Adjusting quota limits.
779 * the disk quota buffer: sizeof(struct xfs_disk_dquot)
780 */
781 STATIC uint
783 {
785 }
787 /*
788 * Allocating quota on disk if needed.
789 * the write transaction log space for quota file extent allocation
790 * the unit of quota allocation: one system block size
791 */
792 STATIC uint
795 {
799 }
801 /*
802 * Turning off quotas.
803 * the quota off logitems: sizeof(struct xfs_qoff_logitem) * 2
804 * the superblock for the quota flags: sector size
805 */
806 STATIC uint
809 {
812 }
814 /*
815 * End of turning off quotas.
816 * the quota off logitems: sizeof(struct xfs_qoff_logitem) * 2
817 */
818 STATIC uint
820 {
822 }
824 /*
825 * Syncing the incore super block changes to disk.
826 * the super block to reflect the changes: sector size
827 */
828 STATIC uint
831 {
833 }
835 void
839 {
840 /*
841 * The following transactions are logged in physical format and
842 * require a permanent reservation on space.
843 */
847 else
854 XFS_ITRUNCATE_LOG_COUNT_REFLINK;
855 else
915 else
919 /*
920 * The following transactions are logged in logical format with
921 * a default log count.
922 */
936 /* growdata requires permanent res; it can free space to the last AG */
941 /* The following transaction are logged in logical format */
949 }