| blob | b67ce93540485af0762014f7c9213bfed390aabe |
1 /*
2 * Copyright 2000 by Hans Reiser, licensing governed by reiserfs/README
3 */
5 #include <linux/time.h>
6 #include <linux/reiserfs_fs.h>
7 #include <linux/reiserfs_acl.h>
8 #include <linux/reiserfs_xattr.h>
9 #include <linux/smp_lock.h>
10 #include <asm/uaccess.h>
11 #include <linux/pagemap.h>
12 #include <linux/swap.h>
13 #include <linux/writeback.h>
14 #include <linux/blkdev.h>
15 #include <linux/buffer_head.h>
16 #include <linux/quotaops.h>
18 /*
19 ** We pack the tails of files on file close, not at the time they are written.
20 ** This implies an unnecessary copy of the tail and an unnecessary indirect item
21 ** insertion/balancing, for files that are written in one write.
22 ** It avoids unnecessary tail packings (balances) for files that are written in
23 ** multiple writes and are small enough to have tails.
24 **
25 ** file_release is called by the VFS layer when the file is closed. If
26 ** this is the last open file descriptor, and the file
27 ** small enough to have a tail, and the tail is currently in an
28 ** unformatted node, the tail is converted back into a direct item.
29 **
30 ** We use reiserfs_truncate_file to pack the tail, since it already has
31 ** all the conditions coded.
32 */
34 {
42 /* fast out for when nothing needs to be done */
48 }
52 /* freeing preallocation only involves relogging blocks that
53 * are already in the current transaction. preallocation gets
54 * freed at the end of each transaction, so it is impossible for
55 * us to log any additional blocks (including quota blocks)
56 */
59 /* uh oh, we can't allow the inode to go away while there
60 * is still preallocation blocks pending. Try to join the
61 * aborted transaction
62 */
67 /* hmpf, our choices here aren't good. We can pin the inode
68 * which will disallow unmount from every happening, we can
69 * do nothing, which will corrupt random memory on unmount,
70 * or we can forcibly remove the file from the preallocation
71 * list, which will leak blocks on disk. Lets pin the inode
72 * and let the admin know what is going on.
73 */
76 "pinning inode %lu because the "
79 }
80 }
83 #ifdef REISERFS_PREALLOCATE
85 #endif
88 /* copy back the error code from journal_begin */
95 /* if regular file is released by last holder and it has been
96 appended (we append by unformatted node only) or its direct
97 item(s) had to be converted, then it may have to be
98 indirect2direct converted */
100 }
101 out:
105 }
108 {
110 }
112 /* Sync a reiserfs file. */
114 /*
115 * FIXME: sync_mapping_buffers() never has anything to sync. Can
116 * be removed...
117 */
121 {
136 }
138 /* I really do not want to play with memory shortage right now, so
139 to simplify the code, we are not going to write more than this much pages at
140 a time. This still should considerably improve performance compared to 4k
141 at a time case. This is 32 pages of 4k size. */
142 #define REISERFS_WRITE_PAGES_AT_A_TIME (128 * 1024) / PAGE_CACHE_SIZE
144 /* Allocates blocks for a file to fulfil write request.
145 Maps all unmapped but prepared pages from the list.
146 Updates metadata with newly allocated blocknumbers as needed */
147 static int reiserfs_allocate_blocks_for_region(struct reiserfs_transaction_handle *th, struct inode *inode, /* Inode we work with */
150 to touch */
153 prepared pages
154 */
156 need to allocate to
157 fit the data into file
158 */
159 )
160 {
166 b_blocknr_t *allocated_blocks; // Pointer to a place where allocated blocknumbers would be stored.
173 // first page
174 unsigned int to = ((pos + write_bytes - 1) & (PAGE_CACHE_SIZE - 1)) + 1; /* last modified byte offset in last page */
177 // of the fact that we already prepared
178 // current block for journal
183 /* only preallocate if this is a small write */
186 blocks_to_allocate <
188 will_prealloc =
196 /* First we compose a key to point at the writing position, we want to do
197 that outside of any locking region. */
200 /* If we came here, it means we absolutely need to open a transaction,
201 since we need to allocate some blocks */
203 res = journal_begin(th, inode->i_sb, JOURNAL_PER_BALANCE_CNT * 3 + 1 + 2 * REISERFS_QUOTA_TRANS_BLOCKS(inode->i_sb)); // Wish I know if this number enough
208 /* Look for the in-tree position of our write, need path for block allocator */
213 }
215 /* Allocate blocks */
216 /* First fill in "hint" structure for block allocator */
218 hint.path = &path; // Path, so that block allocator can determine packing locality or whatever it needs to determine.
222 hint.block = inode->i_blocks >> (inode->i_sb->s_blocksize_bits - 9); // Number of disk blocks this file occupies already.
226 /* Call block allocator to allocate blocks */
227 res =
232 /* We flush the transaction in case of no space. This way some
233 blocks might become free */
239 /* We might have scheduled, so search again */
240 res =
246 }
248 /* update changed info for hint structure. */
249 res =
251 blocks_to_allocate,
252 blocks_to_allocate);
257 }
262 }
263 }
264 #ifdef __BIG_ENDIAN
265 // Too bad, I have not found any way to convert a given region from
266 // cpu format to little endian format
267 {
271 }
272 #endif
274 /* Blocks allocating well might have scheduled and tree might have changed,
275 let's search the tree again */
276 /* find where in the tree our write should go */
281 }
287 /* Let's see what we have found */
289 might need to append file with holes
290 first */
291 // Since we are writing past the file's end, we need to find out if
292 // there is a hole that needs to be inserted before our writing
293 // position, and how many blocks it is going to cover (we need to
294 // populate pointers to file blocks representing the hole with zeros)
296 {
298 /*
299 * if ih is stat data, its offset is 0 and we don't want to
300 * add 1 to pos in the hole_size calculation
301 */
305 (le_key_k_offset
308 inode->
309 i_sb->
310 s_blocksize)))
312 }
315 int to_paste = min_t(__u64, hole_size, MAX_ITEM_LEN(inode->i_sb->s_blocksize) / UNFM_P_SIZE); // How much data to insert first time.
316 /* area filled with zeroes, to supply as list of zero blocknumbers
317 We allocate it outside of loop just in case loop would spin for
318 several iterations. */
319 char *zeros = kmalloc(to_paste * UNFM_P_SIZE, GFP_ATOMIC); // We cannot insert more than MAX_ITEM_LEN bytes anyway.
323 }
326 to_paste =
329 s_blocksize) /
330 UNFM_P_SIZE);
332 /* Ok, there is existing indirect item already. Need to append it */
333 /* Calculate position past inserted item */
335 le_key_k_offset
336 (get_inode_item_key_version
340 inode->
341 i_sb->
342 s_blocksize),
344 res =
347 inode,
349 zeros,
350 UNFM_P_SIZE
351 *
352 to_paste);
356 }
358 /* No existing item, create it */
359 /* item head for new item */
362 /* create a key for our new item */
366 /* Create new item head for our new item */
369 TYPE_INDIRECT,
370 to_paste *
371 UNFM_P_SIZE,
374 /* Find where such item should live in the tree */
375 res =
379 /* item should not exist, otherwise we have error */
382 i_sb,
385 res);
386 }
390 }
391 res =
394 inode,
400 }
404 }
405 /* Now we want to check if transaction is too full, and if it is
406 we restart it. This will also free the path. */
409 res =
416 }
417 }
419 /* Well, need to recalculate path and stuff */
423 i_blkbits));
424 res =
431 }
438 }
439 }
440 // Go through existing indirect items first
441 // replace all zeroes with blocknumbers from list
442 // Note that if no corresponding item was found, by previous search,
443 // it means there are no existing in-tree representation for file area
444 // we are going to overwrite, so there is nothing to scan through for holes.
447 retry:
450 /* We run out of data in this indirect item, let's look for another
451 one. */
452 /* First if we are already modifying current item, log it */
456 }
457 /* Then set the key to look for a new indirect item (offset of old
458 item is added to old item length */
460 le_key_k_offset
465 s_blocksize));
466 /* Search ofor position of new key in the tree. */
467 res =
473 }
479 }
480 /* Ok, we have correct position in item now, so let's see if it is
481 representing file hole (blocknumber is zero) and fill it if needed */
483 /* Ok, a hole. Now we need to check if we already prepared this
484 block to be journaled */
486 /* Well, this item is not journaled yet, so we must prepare
487 it for journal first, before we can change it */
489 // here to detect if fs changed under
490 // us while we were preparing for
491 // journal.
493 // changes fs under our feet
497 reiserfs_prepare_for_journal(inode->i_sb, bh, 1); // Prepare a buffer within which indirect item is stored for changing.
500 // Sigh, fs was changed under us, we need to look for new
501 // location of item we are working with
503 /* unmark prepaerd area as journaled and search for it's
504 new position */
506 i_sb,
507 bh);
508 res =
510 i_sb,
516 }
522 }
524 }
526 curr_block++;
527 }
528 itempos++;
529 }
532 // was modified, but not logged yet.
534 }
537 // Oh, well need to append to indirect item, or to create indirect item
538 // if there weren't any
540 // Existing indirect item - append. First calculate key for append
541 // position. We do not need to recalculate path as it should
542 // already point to correct place.
550 res =
553 curr_block),
554 UNFM_P_SIZE *
556 curr_block));
559 }
561 // Last found item was statdata. That means we need to create indirect item.
564 /* create a key for our new item */
566 // because that's
567 // where first
568 // indirect item
569 // begins
570 /* Create new item head for our new item */
572 TYPE_INDIRECT,
576 /* Find where such item should live in the tree */
579 /* Well, if we have found such item already, or some error
580 occured, we need to warn user and return error */
583 "green-9009: search_by_key (%K) "
585 res);
586 }
589 }
590 /* Insert item into the tree with the data as its body */
591 res =
593 inode,
595 curr_block));
600 }
601 }
602 // the caller is responsible for closing the transaction
603 // unless we return an error, they are also responsible for logging
604 // the inode.
605 //
607 /*
608 * cleanup prellocation from previous writes
609 * if this is a partial block write
610 */
615 // go through all the pages/buffers and map the buffers to newly allocated
616 // blocks (so that system knows where to write these pages later).
627 /* For each buffer in page */
635 /* if this buffer is before requested data to map, skip it */
638 /* If this buffer is after requested data to map, abort
639 processing of current page */
646 curr_block++;
648 }
649 }
650 }
658 // Need to deal with transaction here.
659 error_exit_free_blocks:
661 // free blocks
666 error_exit:
669 // update any changes we made to blk count
671 err =
677 }
682 }
684 /* Unlock pages prepared by reiserfs_prepare_file_region_for_write */
687 {
696 }
697 }
699 /* This function will copy data from userspace to specified pages within
700 supplied byte range */
705 array to
706 prepared pages
707 */
709 data */
710 )
711 {
718 size_t count = min_t(size_t, PAGE_CACHE_SIZE - offset, write_bytes); // How much of bytes to write to this page
723 /* Copy data from userspace to the current page */
726 /* Flush processor's dcache for this page */
734 }
737 }
739 /* taken fs/buffer.c:__block_commit_write */
742 {
764 }
782 /* do data=ordered on any page past the end
783 * of file and any buffer marked BH_New.
784 */
788 }
789 }
790 }
791 }
794 drop_write_lock:
796 }
797 /*
798 * If this is a partial write which happened to make all buffers
799 * uptodate then we can optimize away a bogus readpage() for
800 * the next read(). Here we 'discover' whether the page went
801 * uptodate as a result of this (potentially partial) write.
802 */
806 }
808 /* Submit pages for write. This was separated from actual file copying
809 because we might want to allocate block numbers in-between.
810 This function assumes that caller will adjust file size to correct value. */
811 static int reiserfs_submit_file_region_for_write(struct reiserfs_transaction_handle *th, struct inode *inode, loff_t pos, /* Writing position offset */
815 )
816 {
826 int count = min_t(int, PAGE_CACHE_SIZE - offset, write_bytes); // How much of bytes to write to this page
829 status =
833 // submit all the pages even if there was error.
834 // we only remember error status to report it on
835 // exit.
837 }
838 /* now that we've gotten all the ordered buffers marked dirty,
839 * we can safely update i_size and close any running transaction
840 */
843 /* If the file have grown so much that tail packing is no
844 * longer possible, reset "need to pack" flag */
858 // this sets the proper flags for O_SYNC to trigger a commit
866 }
869 }
878 }
881 /*
882 * we have to unlock the pages after updating i_size, otherwise
883 * we race with writepage
884 */
890 }
892 }
894 /* Look if passed writing region is going to touch file's tail
895 (if it is present). And if it is, convert the tail to unformatted node */
899 )
900 {
906 // This can be int just because tails are created
907 // only for small files.
909 /* this embodies a dependency on a particular tail policy */
911 /* such a big files do not have tails, so we won't bother ourselves
912 to look for tails, simply return */
914 }
917 /* find the item containing the last byte to be written, or if
918 * writing past the end of the file then the last item of the
919 * file (and then we check its type). */
926 }
930 /* Ok, closest item is file tail (tails are stored in "direct"
931 * items), so we need to unpack it. */
932 /* To not overcomplicate matters, we just call generic_cont_expand
933 which will in turn call other stuff and finally will boil down to
934 reiserfs_get_block() that would do necessary conversion. */
935 cont_expand_offset =
945 }
947 /* This function locks pages starting from @pos for @inode.
948 @num_pages pages are locked and stored in
949 @prepared_pages array. Also buffers are allocated for these pages.
950 First and last page of the region is read if it is overwritten only
951 partially. If last page did not exist before write (file hole or file
952 append), it is zeroed, then.
953 Returns number of unallocated blocks that should be allocated to cover
954 new file data.*/
959 prepare */
961 overwritten from
962 @pos */
964 where to store
965 prepared pages */
966 )
967 {
972 /* offset of last modified byte in last
973 page */
978 // of a page.
980 // buffer in the page.
982 // Page appeared to be not up
983 // to date. Note how we have
984 // at most 2 buffers, this is
985 // because we at most may
986 // partially overwrite two
987 // buffers for one page. One at // the beginning of write area
988 // and one at the end.
989 // Everything inthe middle gets // overwritten totally.
993 struct buffer_head *itembuf = NULL; // Buffer head that contains items that we are going to deal with
1000 "green-9001: reiserfs_prepare_file_region_for_write "
1003 }
1005 /* We have 2 loops for pages. In first loop we grab and lock the pages, so
1006 that nobody would touch these until we release the pages. Then
1007 we'd start to deal with mapping buffers to blocks. */
1013 }
1017 }
1019 /* Let's count amount of blocks for a case where all the blocks
1020 overwritten are new (we will substract already allocated blocks later) */
1022 /* These are full-overwritten pages so we count all the blocks in
1023 these pages are counted as needed to be allocated */
1024 blocks =
1027 /* count blocks needed for first page (possibly partially written) */
1028 blocks += ((PAGE_CACHE_SIZE - from) >> inode->i_blkbits) + !!(from & (inode->i_sb->s_blocksize - 1)); /* roundup */
1030 /* Now we account for last page. If last page == first page (we
1031 overwrite only one page), we substract all the blocks past the
1032 last writing position in a page out of already calculated number
1033 of blocks */
1036 /* Note how we do not roundup here since partial blocks still
1037 should be allocated */
1039 /* Now if all the write area lies past the file end, no point in
1040 maping blocks, since there is none, so we just zero out remaining
1041 parts of first and last pages in write area (if needed) */
1047 }
1051 KM_USER0);
1054 }
1056 /* Since all blocks are new - use already calculated value */
1058 }
1060 /* Well, since we write somewhere into the middle of a file, there is
1061 possibility we are writing over some already allocated blocks, so
1062 let's map these blocks and substract number of such blocks out of blocks
1063 we need to allocate (calculated above) */
1064 /* Mask write position to start on blocksize, we do it out of the
1065 loop for performance reasons */
1067 /* Set cpu key to the starting position in a file (on left block boundary) */
1076 /* For each buffer in the page */
1082 /* Find where this buffer ends */
1085 /* if this buffer is before requested data to map, skip it */
1089 /* If this buffer is after requested data to map, abort
1090 processing of current page */
1092 }
1095 /* This is optimisation for a case where buffer is mapped
1096 and have blocknumber assigned. In case significant amount
1097 of such buffers are present, we may avoid some amount
1098 of search_by_key calls.
1099 Probably it would be possible to move parts of this code
1100 out of BKL, but I afraid that would overcomplicate code
1101 without any noticeable benefit.
1102 */
1103 item_pos++;
1104 /* Update the key */
1109 // allocated
1111 }
1115 current unformatted_item */
1116 /* Try to find next item */
1117 res =
1120 /* Abort if no more items */
1122 /* make sure later loops don't use this item */
1126 }
1128 /* Update information about current indirect item */
1136 }
1138 /* See if there is some block associated with the file
1139 at that position, map the buffer to this block */
1144 // allocated
1145 }
1146 item_pos++;
1147 /* Update the key */
1151 }
1152 }
1156 /* Now zero out unmappend buffers for the first and last pages of
1157 write area or issue read requests if page is mapped. */
1158 /* First page, see if it is not uptodate */
1162 /* For each buffer in page */
1169 /* Find where this buffer ends */
1172 /* if this buffer is before requested data to map, skip it */
1176 issue READ request for it to
1177 not loose data */
1183 KM_USER0);
1188 }
1189 }
1190 }
1191 }
1193 /* Last page, see if it is not uptodate, or if the last page is past the end of the file. */
1199 /* for each buffer in page */
1206 /* Find where this buffer ends */
1209 /* if this buffer is after requested data to map, skip it */
1213 issue READ request for it to
1214 not loose data */
1221 KM_USER0);
1225 }
1226 }
1227 }
1228 }
1230 /* Wait for read requests we made to happen, if necessary */
1236 }
1237 }
1240 failed_page_grabbing:
1242 failed_read:
1245 }
1247 /* Write @count bytes at position @ppos in a file indicated by @file
1248 from the buffer @buf.
1250 generic_file_write() is only appropriate for filesystems that are not seeking to optimize performance and want
1251 something simple that works. It is not for serious use by general purpose filesystems, excepting the one that it was
1252 written for (ext2/3). This is for several reasons:
1254 * It has no understanding of any filesystem specific optimizations.
1256 * It enters the filesystem repeatedly for each page that is written.
1258 * It depends on reiserfs_get_block() function which if implemented by reiserfs performs costly search_by_key
1259 * operation for each page it is supplied with. By contrast reiserfs_file_write() feeds as much as possible at a time
1260 * to reiserfs which allows for fewer tree traversals.
1262 * Each indirect pointer insertion takes a lot of cpu, because it involves memory moves inside of blocks.
1264 * Asking the block allocation code for blocks one at a time is slightly less efficient.
1266 All of these reasons for not using only generic file write were understood back when reiserfs was first miscoded to
1267 use it, but we were in a hurry to make code freeze, and so it couldn't be revised then. This new code should make
1268 things right finally.
1270 Future Features: providing search_by_key with hints.
1272 */
1273 static ssize_t reiserfs_file_write(struct file *file, /* the file we are going to write into */
1275 (in userspace) */
1278 * new current position before returning. */
1279 )
1280 {
1286 /* To simplify coding at this time, we store
1287 locked pages in array for now */
1292 /* If a filesystem is converted from 3.5 to 3.6, we'll have v3.5 items
1293 * lying around (most of the disk, in fact). Despite the filesystem
1294 * now being a v3.6 format, the old items still can't support large
1295 * file sizes. Catch this case here, as the rest of the VFS layer is
1296 * oblivious to the different limitations between old and new items.
1297 * reiserfs_setattr catches this for truncates. This chunk is lifted
1298 * from generic_write_checks. */
1304 }
1307 }
1313 /* If we are appending a file, we need to put this savelink in here.
1314 If we will crash while doing direct io, finish_unfinished will
1315 cut the garbage from the file end. */
1317 err =
1319 JOURNAL_PER_BALANCE_CNT);
1323 }
1327 err =
1329 JOURNAL_PER_BALANCE_CNT);
1333 }
1343 }
1350 }
1355 }
1358 }
1370 /* Check if we can write to specified region of file, file
1371 is not overly big and this kind of stuff. Adjust pos and
1372 count, if needed */
1386 // Ok, we are done with all the checks.
1388 // Now we should start real work
1390 /* If we are going to write past the file's packed tail or if we are going
1391 to overwrite part of the tail, we need that tail to be converted into
1392 unformatted node */
1398 /* This is the main loop in which we running until some error occures
1399 or until we write all of the data. */
1404 /* (pos & (PAGE_CACHE_SIZE-1)) is an idiom for offset into a page of pos */
1406 pages */
1409 /* convert size to amount of
1410 pages */
1414 /* If we were asked to write more data than we want to or if there
1415 is not that much space, then we shorten amount of data to write
1416 for this iteration. */
1417 num_pages =
1420 /* Also we should not forget to set size in bytes accordingly */
1423 /* If position is not on the
1424 start of the page, we need
1425 to substract the offset
1426 within page */
1430 /* reserve the blocks to be allocated later, so that later on
1431 we still have the space to write the blocks to */
1433 num_pages <<
1444 }
1445 // Otherwise we are possibly overwriting the file, so
1446 // let's set write size to be equal or less than blocksize.
1447 // This way we get it correctly for file holes.
1448 // But overwriting files on absolutelly full volumes would not
1449 // be very efficient. Well, people are not supposed to fill
1450 // 100% of disk space anyway.
1451 write_bytes =
1456 // No blocks were claimed before, so do it now.
1459 (PAGE_CACHE_SHIFT
1460 -
1461 inode->
1462 i_blkbits));
1463 }
1465 /* Prepare for writing into the region, read in all the
1466 partially overwritten pages, if needed. And lock the pages,
1467 so that nobody else can access these until we are done.
1468 We get number of actual blocks needed as a result. */
1470 num_pages,
1471 write_bytes,
1472 prepared_pages);
1475 num_pages <<
1479 }
1483 /* First we correct our estimate of how many blocks we need */
1488 s_blocksize_bits)) -
1489 blocks_to_allocate);
1492 /* Fill in all the possible holes and append the file if needed */
1493 res =
1495 num_pages,
1496 write_bytes,
1497 prepared_pages,
1498 blocks_to_allocate);
1499 }
1501 /* well, we have allocated the blocks, so it is time to free
1502 the reservation we made earlier. */
1504 blocks_to_allocate);
1508 }
1510 /* NOTE that allocating blocks and filling blocks can be done in reverse order
1511 and probably we would do that just to get rid of garbage in files after a
1512 crash */
1514 /* Copy data from user-supplied buffer to file's pages */
1515 res =
1517 write_bytes,
1522 }
1524 /* Send the pages to disk and unlock them. */
1525 res =
1527 num_pages,
1528 write_bytes,
1529 prepared_pages);
1538 }
1540 /* this is only true on error */
1548 }
1549 }
1560 out:
1563 }
1569 #ifdef CONFIG_COMPAT
1571 #endif
1581 };
1591 };