| blob | e34cd0e6247385f5827d7232ae4257c664f47c7b |
1 /*
2 * raid10.c : Multiple Devices driver for Linux
3 *
4 * Copyright (C) 2000-2004 Neil Brown
5 *
6 * RAID-10 support for md.
7 *
8 * Base on code in raid1.c. See raid1.c for futher copyright information.
9 *
10 *
11 * This program is free software; you can redistribute it and/or modify
12 * it under the terms of the GNU General Public License as published by
13 * the Free Software Foundation; either version 2, or (at your option)
14 * any later version.
15 *
16 * You should have received a copy of the GNU General Public License
17 * (for example /usr/src/linux/COPYING); if not, write to the Free
18 * Software Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA.
19 */
22 #include <linux/raid/raid10.h>
23 #include <linux/raid/bitmap.h>
25 /*
26 * RAID10 provides a combination of RAID0 and RAID1 functionality.
27 * The layout of data is defined by
28 * chunk_size
29 * raid_disks
30 * near_copies (stored in low byte of layout)
31 * far_copies (stored in second byte of layout)
32 * far_offset (stored in bit 16 of layout )
33 *
34 * The data to be stored is divided into chunks using chunksize.
35 * Each device is divided into far_copies sections.
36 * In each section, chunks are laid out in a style similar to raid0, but
37 * near_copies copies of each chunk is stored (each on a different drive).
38 * The starting device for each section is offset near_copies from the starting
39 * device of the previous section.
40 * Thus they are (near_copies*far_copies) of each chunk, and each is on a different
41 * drive.
42 * near_copies and far_copies must be at least one, and their product is at most
43 * raid_disks.
44 *
45 * If far_offset is true, then the far_copies are handled a bit differently.
46 * The copies are still in different stripes, but instead of be very far apart
47 * on disk, there are adjacent stripes.
48 */
50 /*
51 * Number of guaranteed r10bios in case of extreme VM load:
52 */
53 #define NR_RAID10_BIOS 256
61 {
66 /* allocate a r10bio with room for raid_disks entries in the bios array */
72 }
75 {
77 }
79 /* Maximum size of each resync request */
80 #define RESYNC_BLOCK_SIZE (64*1024)
81 #define RESYNC_PAGES ((RESYNC_BLOCK_SIZE + PAGE_SIZE-1) / PAGE_SIZE)
82 /* amount of memory to reserve for resync requests */
83 #define RESYNC_WINDOW (1024*1024)
84 /* maximum number of concurrent requests, memory permitting */
85 #define RESYNC_DEPTH (32*1024*1024/RESYNC_BLOCK_SIZE)
87 /*
88 * When performing a resync, we need to read and compare, so
89 * we need as many pages are there are copies.
90 * When performing a recovery, we need 2 bios, one for read,
91 * one for write (we recover only one drive per r10buf)
92 *
93 */
95 {
107 }
111 else
114 /*
115 * Allocate bios.
116 */
122 }
123 /*
124 * Allocate RESYNC_PAGES data pages and attach them
125 * where needed.
126 */
135 }
136 }
140 out_free_pages:
147 out_free_bio:
152 }
155 {
167 }
169 }
170 }
172 }
175 {
183 }
184 }
187 {
190 /*
191 * Wake up any possible resync thread that waits for the device
192 * to go idle.
193 */
198 }
201 {
207 }
210 {
220 /* wake up frozen array... */
224 }
226 /*
227 * raid_end_bio_io() is called when we have finished servicing a mirrored
228 * operation and are ready to return a success/failure code to the buffer
229 * cache layer.
230 */
232 {
238 }
240 /*
241 * Update disk head position estimator based on IRQ completion info.
242 */
244 {
249 }
252 {
261 /*
262 * this branch is our 'one mirror IO has finished' event handler:
263 */
267 /*
268 * Set R10BIO_Uptodate in our master bio, so that
269 * we will return a good error code to the higher
270 * levels even if IO on some other mirrored buffer fails.
271 *
272 * The 'master' represents the composite IO operation to
273 * user-side. So if something waits for IO, then it will
274 * wait for the 'master' bio.
275 */
279 /*
280 * oops, read error:
281 */
287 }
290 }
293 {
304 /*
305 * this branch is our 'one mirror IO has finished' event handler:
306 */
309 /* an I/O failed, we can't clear the bitmap */
312 /*
313 * Set R10BIO_Uptodate in our master bio, so that
314 * we will return a good error code for to the higher
315 * levels even if IO on some other mirrored buffer fails.
316 *
317 * The 'master' represents the composite IO operation to
318 * user-side. So if something waits for IO, then it will
319 * wait for the 'master' bio.
320 */
325 /*
326 *
327 * Let's see if all mirrored write operations have finished
328 * already.
329 */
331 /* clear the bitmap if all writes complete successfully */
338 }
341 }
344 /*
345 * RAID10 layout manager
346 * Aswell as the chunksize and raid_disks count, there are two
347 * parameters: near_copies and far_copies.
348 * near_copies * far_copies must be <= raid_disks.
349 * Normally one of these will be 1.
350 * If both are 1, we get raid0.
351 * If near_copies == raid_disks, we get raid1.
352 *
353 * Chunks are layed out in raid0 style with near_copies copies of the
354 * first chunk, followed by near_copies copies of the next chunk and
355 * so on.
356 * If far_copies > 1, then after 1/far_copies of the array has been assigned
357 * as described above, we start again with a device offset of near_copies.
358 * So we effectively have another copy of the whole array further down all
359 * the drives, but with blocks on different drives.
360 * With this layout, and block is never stored twice on the one device.
361 *
362 * raid10_find_phys finds the sector offset of a given virtual sector
363 * on each device that it is on.
364 *
365 * raid10_find_virt does the reverse mapping, from a device and a
366 * sector offset to a virtual address
367 */
370 {
372 sector_t sector;
373 sector_t chunk;
374 sector_t stripe;
379 /* now calculate first sector/dev */
391 /* and calculate all the others */
397 slot++;
406 slot++;
407 }
408 dev++;
412 }
413 }
415 }
418 {
434 else
436 }
438 }
442 }
444 /**
445 * raid10_mergeable_bvec -- tell bio layer if a two requests can be merged
446 * @q: request queue
447 * @bvm: properties of new bio
448 * @biovec: the request that could be merged to it.
449 *
450 * Return amount of bytes we can accept at this offset
451 * If near_copies == raid_disk, there are no striping issues,
452 * but in that case, the function isn't called at all.
453 */
457 {
468 else
470 }
472 /*
473 * This routine returns the disk from which the requested read should
474 * be done. There is a per-array 'next expected sequential IO' sector
475 * number - if this matches on the next IO then we use the last disk.
476 * There is also a per-disk 'last know head position' sector that is
477 * maintained from IRQ contexts, both the normal and the resync IO
478 * completion handlers update this position correctly. If there is no
479 * perfect sequential match then we pick the disk whose head is closest.
480 *
481 * If there are 2 mirrors in the same 2 devices, performance degrades
482 * because position is mirror, not device based.
483 *
484 * The rdev for the device selected will have nr_pending incremented.
485 */
487 /*
488 * FIXME: possibly should rethink readbalancing and do it differently
489 * depending on near_copies / far_copies geometry.
490 */
492 {
501 /*
502 * Check if we can balance. We can balance on the whole
503 * device if no resync is going on (recovery is ok), or below
504 * the resync window. We take the first readable disk when
505 * above the resync window.
506 */
509 /* make sure that disk is operational */
516 slot++;
521 }
523 }
525 }
528 /* make sure the disk is operational */
534 slot ++;
538 }
540 }
546 /* Find the disk whose head is closest,
547 * or - for far > 1 - find the closest to partition beginning */
558 /* This optimisation is debatable, and completely destroys
559 * sequential read speed for 'far copies' arrays. So only
560 * keep it for 'near' arrays, and review those later.
561 */
566 }
568 /* for far > 1 always use the lowest address */
571 else
578 }
579 }
581 rb_out:
583 /* conf->next_seq_sect = this_sector + sectors;*/
587 else
592 }
595 {
612 }
613 }
615 }
618 {
623 }
626 {
638 }
639 }
642 }
645 {
646 /* Any writes that have been queued but are awaiting
647 * bitmap updates get flushed here.
648 * We return 1 if any requests were actually submitted.
649 */
659 /* flush any pending bitmap writes to disk
660 * before proceeding w/ I/O */
668 }
673 }
674 /* Barriers....
675 * Sometimes we need to suspend IO while we do something else,
676 * either some resync/recovery, or reconfigure the array.
677 * To do this we raise a 'barrier'.
678 * The 'barrier' is a counter that can be raised multiple times
679 * to count how many activities are happening which preclude
680 * normal IO.
681 * We can only raise the barrier if there is no pending IO.
682 * i.e. if nr_pending == 0.
683 * We choose only to raise the barrier if no-one is waiting for the
684 * barrier to go down. This means that as soon as an IO request
685 * is ready, no other operations which require a barrier will start
686 * until the IO request has had a chance.
687 *
688 * So: regular IO calls 'wait_barrier'. When that returns there
689 * is no backgroup IO happening, It must arrange to call
690 * allow_barrier when it has finished its IO.
691 * backgroup IO calls must call raise_barrier. Once that returns
692 * there is no normal IO happeing. It must arrange to call
693 * lower_barrier when the particular background IO completes.
694 */
697 {
701 /* Wait until no block IO is waiting (unless 'force') */
706 /* block any new IO from starting */
709 /* No wait for all pending IO to complete */
716 }
719 {
725 }
728 {
736 }
739 }
742 {
748 }
751 {
752 /* stop syncio and normal IO and wait for everything to
753 * go quiet.
754 * We increment barrier and nr_waiting, and then
755 * wait until nr_pending match nr_queued+1
756 * This is called in the context of one normal IO request
757 * that has failed. Thus any sync request that might be pending
758 * will be blocked by nr_pending, and we need to wait for
759 * pending IO requests to complete or be queued for re-try.
760 * Thus the number queued (nr_queued) plus this request (1)
761 * must match the number of pending IOs (nr_pending) before
762 * we continue.
763 */
773 }
776 {
777 /* reverse the effect of the freeze */
783 }
786 {
803 }
805 /* If this request crosses a chunk boundary, we need to
806 * split it. This will only happen for 1 PAGE (or less) requests.
807 */
812 /* Sanity check -- queue functions should prevent this happening */
816 /* This is a one page bio that upper layers
817 * refuse to split for us, so we need to split it.
818 */
828 bad_map:
835 }
839 /*
840 * Register the new request and wait if the reconstruction
841 * thread has put up a bar for new requests.
842 * Continue immediately if no resync is active currently.
843 */
859 /*
860 * read balancing logic:
861 */
867 }
883 }
885 /*
886 * WRITE:
887 */
888 /* first select target devices under rcu_lock and
889 * inc refcount on their rdev. Record them by setting
890 * bios[x] to bio
891 */
893 retry_write:
903 }
910 }
911 }
915 /* Have to wait for this device to get unblocked, then retry */
923 }
928 }
951 }
954 /* the array is dead */
958 }
966 /* In case raid10d snuck in to freeze_array */
973 }
976 {
987 else
989 }
997 }
1000 {
1004 /*
1005 * If it is not operational, then we have already marked it as dead
1006 * else if it is the last working disks, ignore the error, let the
1007 * next level up know.
1008 * else mark the drive as failed
1009 */
1012 /*
1013 * Don't fail the drive, just return an IO error.
1014 * The test should really be more sophisticated than
1015 * "working_disks == 1", but it isn't critical, and
1016 * can wait until we do more sophisticated "is the drive
1017 * really dead" tests...
1018 */
1025 /*
1026 * if recovery is running, make sure it aborts.
1027 */
1029 }
1035 }
1038 {
1046 }
1058 }
1059 }
1062 {
1068 }
1070 /* check if there are enough drives for
1071 * every block to appear on atleast one
1072 */
1074 {
1082 cnt++;
1084 }
1089 }
1092 {
1097 /*
1098 * Find all non-in_sync disks within the RAID10 configuration
1099 * and mark them in_sync
1100 */
1110 }
1111 }
1115 }
1119 {
1128 /* only hot-add to in-sync arrays, as recovery is
1129 * very different from resync
1130 */
1142 else
1149 /* as we don't honour merge_bvec_fn, we must never risk
1150 * violating it, so limit ->max_sector to one PAGE, as
1151 * a one page request is never in violation.
1152 */
1164 }
1168 }
1171 {
1184 }
1185 /* Only remove faulty devices in recovery
1186 * is not possible.
1187 */
1192 }
1196 /* lost the race, try later */
1199 }
1200 }
1201 abort:
1205 }
1209 {
1229 }
1231 /* for reconstruct, we always reschedule after a read.
1232 * for resync, only after all reads
1233 */
1236 /* we have read all the blocks,
1237 * do the comparison in process context in raid10d
1238 */
1240 }
1242 }
1245 {
1264 /* the primary of several recovery bios */
1272 }
1273 }
1275 }
1277 /*
1278 * Note: sync and recover and handled very differently for raid10
1279 * This code is for resync.
1280 * For resync, we read through virtual addresses and read all blocks.
1281 * If there is any error, we schedule a write. The lowest numbered
1282 * drive is authoritative.
1283 * However requests come for physical address, so we need to map.
1284 * For every physical address there are raid_disks/copies virtual addresses,
1285 * which is always are least one, but is not necessarly an integer.
1286 * This means that a physical address can span multiple chunks, so we may
1287 * have to submit multiple io requests for a single sync request.
1288 */
1289 /*
1290 * We check if all blocks are in-sync and only write to blocks that
1291 * aren't in sync
1292 */
1294 {
1301 /* find the first device with a block */
1312 /* now find blocks with errors */
1324 /* We know that the bi_io_vec layout is the same for
1325 * both 'first' and 'i', so we just compare them.
1326 * All vec entries are PAGE_SIZE;
1327 */
1331 PAGE_SIZE))
1336 }
1338 /* Don't fix anything. */
1340 /* Ok, we need to write this bio
1341 * First we need to fixup bv_offset, bv_len and
1342 * bi_vecs, as the read request might have corrupted these
1343 */
1364 PAGE_SIZE);
1365 }
1376 }
1378 done:
1382 }
1383 }
1385 /*
1386 * Now for the recovery code.
1387 * Recovery happens across physical sectors.
1388 * We recover all non-is_sync drives by finding the virtual address of
1389 * each, and then choose a working drive that also has that virt address.
1390 * There is a separate r10_bio for each non-in_sync drive.
1391 * Only the first two slots are in use. The first for reading,
1392 * The second for writing.
1393 *
1394 */
1397 {
1403 /* move the pages across to the second bio
1404 * and submit the write request
1405 */
1412 }
1419 else
1421 }
1424 /*
1425 * This is a kernel thread which:
1426 *
1427 * 1. Retries failed read operations on working mirrors.
1428 * 2. Updates the raid superblock when problems encounter.
1429 * 3. Performs writes following reads for array synchronising.
1430 */
1433 {
1463 }
1464 sl++;
1471 /* Cannot read from anywhere -- bye bye array */
1475 }
1478 /* write it back and re-read */
1484 sl--;
1497 /* Well, this device is dead */
1501 }
1502 }
1508 sl--;
1520 /* Well, this device is dead */
1522 else
1524 "raid10:%s: read error corrected"
1533 }
1534 }
1539 }
1540 }
1543 {
1563 }
1579 /* we got a read error. Maybe the drive is bad. Maybe just
1580 * the block and we can fix it.
1581 * We freeze all other IO, and try reading the block from
1582 * other devices. When we find one, we re-write
1583 * and check it that fixes the read error.
1584 * This is all done synchronously while the array is
1585 * frozen.
1586 */
1591 }
1623 }
1624 }
1625 }
1628 }
1632 {
1642 }
1644 /*
1645 * perform a "sync" on one "block"
1646 *
1647 * We need to make sure that no normal I/O request - particularly write
1648 * requests - conflict with active sync requests.
1649 *
1650 * This is achieved by tracking pending requests and a 'barrier' concept
1651 * that can be installed to exclude normal IO requests.
1652 *
1653 * Resync and recovery are handled very differently.
1654 * We differentiate by looking at MD_RECOVERY_SYNC in mddev->recovery.
1655 *
1656 * For resync, we iterate over virtual addresses, read all copies,
1657 * and update if there are differences. If only one copy is live,
1658 * skip it.
1659 * For recovery, we iterate over physical addresses, read a good
1660 * value for each non-in_sync drive, and over-write.
1661 *
1662 * So, for recovery we may have several outstanding complex requests for a
1663 * given address, one for each out-of-sync device. We model this by allocating
1664 * a number of r10_bio structures, one for each out-of-sync device.
1665 * As we setup these structures, we collect all bio's together into a list
1666 * which we then process collectively to add pages, and then process again
1667 * to pass to generic_make_request.
1668 *
1669 * The r10_bio structures are linked using a borrowed master_bio pointer.
1670 * This link is counted in ->remaining. When the r10_bio that points to NULL
1671 * has its remaining count decremented to 0, the whole complex operation
1672 * is complete.
1673 *
1674 */
1677 {
1694 skipped:
1699 /* If we aborted, we need to abort the
1700 * sync on the 'current' bitmap chucks (there can
1701 * be several when recovering multiple devices).
1702 * as we may have started syncing it but not finished.
1703 * We can find the current address in
1704 * mddev->curr_resync, but for recovery,
1705 * we need to convert that to several
1706 * virtual addresses.
1707 */
1713 sector_t sect =
1717 }
1725 }
1727 /* if there has been nothing to do on any drive,
1728 * then there is nothing to do at all..
1729 */
1732 }
1737 /* make sure whole request will fit in a chunk - if chunks
1738 * are meaningful
1739 */
1743 /*
1744 * If there is non-resync activity waiting for us then
1745 * put in a delay to throttle resync.
1746 */
1752 /* Again, very different code for resync and recovery.
1753 * Both must result in an r10bio with a list of bios that
1754 * have bi_end_io, bi_sector, bi_bdev set,
1755 * and bi_private set to the r10bio.
1756 * For recovery, we may actually create several r10bios
1757 * with 2 bios in each, that correspond to the bios in the main one.
1758 * In this case, the subordinate r10bios link back through a
1759 * borrowed master_bio pointer, and the counter in the master
1760 * includes a ref from each subordinate.
1761 */
1762 /* First, we decide what to do and set ->bi_end_io
1763 * To end_sync_read if we want to read, and
1764 * end_sync_write if we will want to write.
1765 */
1769 /* recovery... the complicated one */
1777 /* want to reconstruct this device */
1781 /* Unless we are doing a full sync, we only need
1782 * to recover the block if it is set in the bitmap
1783 */
1790 /* yep, skip the sync_blocks here, but don't assume
1791 * that there will never be anything to do here
1792 */
1795 }
1809 /* Need to check if this section will still be
1810 * degraded
1811 */
1818 }
1819 }
1827 /* This is where we read from */
1839 /* and we write to 'i' */
1859 }
1860 }
1862 /* Cannot recover, so abort the recovery */
1872 }
1873 }
1880 }
1882 }
1884 /* resync. Schedule a read for every block at this virt offset */
1890 /* We can skip this block */
1893 }
1927 count++;
1928 }
1935 }
1939 }
1940 }
1952 }
1968 /* stop here */
1972 /* remove last page from this bio */
1976 }
1978 }
1980 }
1984 bio_full:
1998 }
1999 }
2002 /* pretend they weren't skipped, it makes
2003 * no important difference in this case
2004 */
2008 giveup:
2009 /* There is nowhere to write, so all non-sync
2010 * drives must be failed, so try the next chunk...
2011 */
2012 {
2015 chunks_skipped ++;
2018 }
2019 }
2022 {
2034 }
2044 }
2045 /*
2046 * copy the already verified devices into our private RAID10
2047 * bookkeeping area. [whatever we allocate in run(),
2048 * should be freed in stop()]
2049 */
2056 }
2058 GFP_KERNEL);
2063 }
2081 /* 'size' is now the number of chunks in the array */
2082 /* calculate "used chunks per device" in 'stride' */
2085 /* We need to round up when dividing by raid_disks to
2086 * get the stride size.
2087 */
2094 else
2104 }
2120 /* as we don't honour merge_bvec_fn, we must never risk
2121 * violating it, so limit ->max_sector to one PAGE, as
2122 * a one page request is never in violation.
2123 */
2129 }
2135 /* need to check that every block has at least one working mirror */
2140 }
2153 }
2154 }
2163 }
2169 /*
2170 * Ok, everything is just fine now
2171 */
2179 /* Calculate max read-ahead size.
2180 * We need to readahead at least twice a whole stripe....
2181 * maybe...
2182 */
2183 {
2188 }
2194 out_free_conf:
2201 out:
2203 }
2206 {
2218 }
2221 {
2231 }
2235 else
2238 }
2239 }
2242 {
2256 };
2259 {
2261 }
2264 {
2266 }