| blob | 4830f4850a31fab43aab39af20aa2618815562ae |
1 /*
2 * CDDL HEADER START
3 *
4 * The contents of this file are subject to the terms of the
5 * Common Development and Distribution License (the "License").
6 * You may not use this file except in compliance with the License.
7 *
8 * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE
9 * or https://opensource.org/licenses/CDDL-1.0.
10 * See the License for the specific language governing permissions
11 * and limitations under the License.
12 *
13 * When distributing Covered Code, include this CDDL HEADER in each
14 * file and include the License file at usr/src/OPENSOLARIS.LICENSE.
15 * If applicable, add the following below this CDDL HEADER, with the
16 * fields enclosed by brackets "[]" replaced with your own identifying
17 * information: Portions Copyright [yyyy] [name of copyright owner]
18 *
19 * CDDL HEADER END
20 */
21 /*
22 * Copyright (c) 2005, 2010, Oracle and/or its affiliates. All rights reserved.
23 * Copyright (c) 2011, 2020 by Delphix. All rights reserved.
24 * Copyright (c) 2013 by Saso Kiselkov. All rights reserved.
25 * Copyright (c) 2013, Joyent, Inc. All rights reserved.
26 * Copyright (c) 2016, Nexenta Systems, Inc. All rights reserved.
27 * Copyright (c) 2015 by Chunwei Chen. All rights reserved.
28 * Copyright (c) 2019 Datto Inc.
29 * Copyright (c) 2019, 2023, Klara Inc.
30 * Copyright (c) 2019, Allan Jude
31 * Copyright (c) 2022 Hewlett Packard Enterprise Development LP.
32 * Copyright (c) 2021, 2022 by Pawel Jakub Dawidek
33 */
35 #include <sys/dmu.h>
36 #include <sys/dmu_impl.h>
37 #include <sys/dmu_tx.h>
38 #include <sys/dbuf.h>
39 #include <sys/dnode.h>
40 #include <sys/zfs_context.h>
41 #include <sys/dmu_objset.h>
42 #include <sys/dmu_traverse.h>
43 #include <sys/dsl_dataset.h>
44 #include <sys/dsl_dir.h>
45 #include <sys/dsl_pool.h>
46 #include <sys/dsl_synctask.h>
47 #include <sys/dsl_prop.h>
48 #include <sys/dmu_zfetch.h>
49 #include <sys/zfs_ioctl.h>
50 #include <sys/zap.h>
51 #include <sys/zio_checksum.h>
52 #include <sys/zio_compress.h>
53 #include <sys/sa.h>
54 #include <sys/zfeature.h>
55 #include <sys/abd.h>
56 #include <sys/brt.h>
57 #include <sys/trace_zfs.h>
58 #include <sys/zfs_racct.h>
59 #include <sys/zfs_rlock.h>
60 #ifdef _KERNEL
61 #include <sys/vmsystm.h>
62 #include <sys/zfs_znode.h>
63 #endif
65 /*
66 * Enable/disable nopwrite feature.
67 */
70 /*
71 * Tunable to control percentage of dirtied L1 blocks from frees allowed into
72 * one TXG. After this threshold is crossed, additional dirty blocks from frees
73 * will wait until the next TXG.
74 * A value of zero will disable this throttle.
75 */
78 /*
79 * Enable/disable forcing txg sync when dirty checking for holes with lseek().
80 * By default this is enabled to ensure accurate hole reporting, it can result
81 * in a significant performance penalty for lseek(SEEK_HOLE) heavy workloads.
82 * Disabling this option will result in holes never being reported in dirty
83 * files which is always safe.
84 */
87 /*
88 * Limit the amount we can prefetch with one call to this amount. This
89 * helps to limit the amount of memory that can be used by prefetching.
90 * Larger objects should be prefetched a bit at a time.
91 */
92 #ifdef _ILP32
94 #else
96 #endif
98 /*
99 * Override copies= for dedup state objects. 0 means the traditional behaviour
100 * (ie the default for the containing objset ie 3 for the MOS).
101 */
159 };
172 };
174 int
177 {
189 }
193 }
195 int
198 {
216 }
220 }
222 int
225 {
241 }
242 }
245 }
247 int
250 {
266 }
267 }
270 }
272 int
274 {
276 }
278 int
280 {
296 }
300 }
302 int
304 {
320 }
324 }
326 dmu_object_type_t
328 {
330 dmu_object_type_t type;
337 }
339 int
341 {
352 }
354 /*
355 * Lookup and hold the bonus buffer for the provided dnode. If the dnode
356 * has not yet been allocated a new bonus dbuf a will be allocated.
357 * Returns ENOENT, EIO, or 0.
358 */
361 {
376 }
379 }
382 /* as long as the bonus buf is held, the dnode will be held */
386 }
388 /*
389 * Wait to drop dn_struct_rwlock until after adding the bonus dbuf's
390 * hold and incrementing the dbuf count to ensure that dnode_move() sees
391 * a dnode hold for every dbuf.
392 */
401 }
405 }
407 int
409 {
421 }
423 /*
424 * returns ENOENT, EIO, or 0.
425 *
426 * This interface will allocate a blank spill dbuf when a spill blk
427 * doesn't already exist on the dnode.
428 *
429 * if you only want to find an already existing spill db, then
430 * dmu_spill_hold_existing() should be used.
431 */
432 int
435 {
450 }
457 }
459 }
461 int
463 {
481 }
484 }
488 }
490 int
493 {
506 }
508 /*
509 * Note: longer-term, we should modify all of the dmu_buf_*() interfaces
510 * to take a held dnode rather than <os, object> -- the lookup is wasteful,
511 * and can induce severe lock contention when writing to several files
512 * whose dnodes are in the same block.
513 */
514 int
518 {
529 /*
530 * Note: We directly notify the prefetch code of this read, so that
531 * we can tell it about the multi-block read. dbuf_read() only knows
532 * about the one block it is accessing.
533 */
535 DB_RF_NOPREFETCH;
556 }
558 }
563 ZIO_FLAG_CANFAIL);
566 /*
567 * Prepare the zfetch before initiating the demand reads, so
568 * that if multiple threads block on same indirect block, we
569 * base predictions on the original less racy request order.
570 */
572 B_TRUE);
573 }
579 B_TRUE);
580 }
586 }
588 /*
589 * Initiate async demand data read.
590 * We check the db_state after calling dbuf_read() because
591 * (1) dbuf_read() may change the state to CACHED due to a
592 * hit in the ARC, and (2) on a cache miss, a child will
593 * have been added to "zio" but not yet completed, so the
594 * state will not yet be CACHED.
595 */
602 else
604 }
608 }
610 }
612 /*
613 * If we are doing O_DIRECT we still hold the dbufs, even for reads,
614 * but we do not issue any reads here. We do not want to account for
615 * writes in this case.
616 *
617 * O_DIRECT write/read accounting takes place in
618 * dmu_{write/read}_abd().
619 */
628 /* wait for async read i/o */
633 }
635 /* wait for other io to complete */
648 }
649 }
650 }
655 }
657 int
661 {
675 }
677 int
681 {
691 }
693 void
695 {
705 }
708 }
710 /*
711 * Issue prefetch I/Os for the given blocks. If level is greater than 0, the
712 * indirect blocks prefetched will be those that point to the blocks containing
713 * the data starting at offset, and continuing to offset + len. If the range
714 * is too long, prefetch the first dmu_prefetch_max bytes as requested, while
715 * for the rest only a higher level, also fitting within dmu_prefetch_max. It
716 * should primarily help random reads, since for long sequential reads there is
717 * a speculative prefetcher.
718 *
719 * Note that if the indirect blocks above the blocks being prefetched are not
720 * in cache, they will be asynchronously read in. Dnode read by dnode_hold()
721 * is currently synchronous.
722 */
723 void
726 {
732 }
740 }
742 void
745 {
749 /*
750 * Depending on len we may do two prefetches: blocks [start, end) at
751 * level, and following blocks [start2, end2) at higher level2.
752 */
755 /*
756 * The object has multiple blocks. Calculate the full range
757 * of blocks [start, end2) and then split it into two parts,
758 * so that the first [start, end) fits into dmu_prefetch_max.
759 */
767 /*
768 * Find level2 where [start2, end2) fits into dmu_prefetch_max.
769 */
773 level2++;
778 /* There is only one block. Prefetch it or nothing. */
781 }
788 }
791 kmutex_t dpa_lock;
792 kcondvar_t dpa_cv;
796 static void
798 {
809 }
811 static void
813 {
814 dmu_prefetch_arg_t dpa;
828 }
832 /* wait for prefetch L0 reads to finish */
837 }
842 }
844 /*
845 * Issue prefetch I/Os for the given L0 block range and wait for the I/O
846 * to complete. This does not enforce dmu_prefetch_max and will prefetch
847 * the entire range. The blocks are read from disk into the ARC but no
848 * decompression occurs (i.e., the dbuf cache is not required).
849 */
850 int
852 {
860 /*
861 * Chunk the requests (16 indirects worth) so that we can be interrupted
862 */
869 }
882 }
883 }
888 }
890 /*
891 * Issue prefetch I/Os for the given object's dnode.
892 */
893 void
895 {
904 }
906 /*
907 * Get the next "chunk" of file data to free. We traverse the file from
908 * the end so that the file gets shorter over time (if we crash in the
909 * middle, this will leave us in a better state). We find allocated file
910 * data by simply searching the allocated level 1 indirects.
911 *
912 * On input, *start should be the first offset that does not need to be
913 * freed (e.g. "offset + length"). On return, *start will be the first
914 * offset that should be freed and l1blks is set to the number of level 1
915 * indirect blocks found within the chunk.
916 */
917 static int
919 {
922 /* bytes of data covered by a level-1 indirect block */
928 /* dn_nlevels == 1 means we don't have any L1 blocks */
933 }
935 /*
936 * Check if we can free the entire range assuming that all of the
937 * L1 blocks in this range have data. If we can, we use this
938 * worst case value as an estimate so we can avoid having to look
939 * at the object's actual data.
940 */
943 iblkrange;
948 }
954 /*
955 * dnode_next_offset(BACKWARDS) will find an allocated L1
956 * indirect block at or before the input offset. We must
957 * decrement *start so that it is at the end of the region
958 * to search.
959 */
965 /* if there are no indirect blocks before start, we are done */
972 }
974 /* set start to the beginning of this L1 indirect */
976 }
982 }
984 /*
985 * If this objset is of type OST_ZFS return true if vfs's unmounted flag is set,
986 * otherwise return false.
987 * Used below in dmu_free_long_range_impl() to enable abort when unmounting
988 */
989 static boolean_t
991 {
992 #ifdef _KERNEL
995 #else
997 #endif
999 }
1001 static int
1004 {
1018 dirty_frees_threshold =
1020 else
1036 /* move chunk_begin backwards to the beginning of this chunk */
1048 /*
1049 * Mark this transaction as typically resulting in a net
1050 * reduction in space used.
1051 */
1057 }
1066 /*
1067 * To avoid filling up a TXG with just frees, wait for
1068 * the next TXG to open before freeing more chunks if
1069 * we have reached the threshold of frees.
1070 */
1077 }
1079 /*
1080 * In order to prevent unnecessary write throttling, for each
1081 * TXG, we track the cumulative size of L1 blocks being dirtied
1082 * in dnode_free_range() below. We compare this number to a
1083 * tunable threshold, past which we prevent new L1 dirty freeing
1084 * blocks from being added into the open TXG. See
1085 * dmu_free_long_range_impl() for details. The threshold
1086 * prevents write throttle activation due to dirty freeing L1
1087 * blocks taking up a large percentage of zfs_dirty_data_max.
1088 */
1101 }
1103 }
1105 int
1108 {
1117 /*
1118 * It is important to zero out the maxblkid when freeing the entire
1119 * file, so that (a) subsequent calls to dmu_free_long_range_impl()
1120 * will take the fast path, and (b) dnode_reallocate() can verify
1121 * that the entire file has been freed.
1122 */
1128 }
1130 int
1132 {
1150 }
1153 }
1155 int
1158 {
1168 }
1170 static int
1173 {
1177 /*
1178 * Deal with odd block sizes, where there can't be data past the first
1179 * block. If we ever do the tail block optimization, we will need to
1180 * handle that here as well.
1181 */
1187 }
1192 /* Allow Direct I/O when requested and properly aligned */
1199 }
1205 /*
1206 * NB: we could do this block-at-a-time, but it's nice
1207 * to be reading in parallel.
1208 */
1230 }
1232 }
1234 }
1236 int
1239 {
1250 }
1252 int
1255 {
1257 }
1259 static void
1262 {
1279 else
1291 }
1292 }
1294 void
1297 {
1308 }
1310 /*
1311 * This interface is not used internally by ZFS but is provided for
1312 * use by Lustre which is built on the DMU interfaces.
1313 */
1314 int
1317 {
1325 /* Allow Direct I/O when requested and properly aligned */
1332 }
1339 }
1341 int
1344 {
1346 }
1348 void
1351 {
1365 }
1367 }
1369 void
1373 {
1386 }
1388 void
1391 {
1400 }
1402 #ifdef _KERNEL
1403 int
1405 {
1412 /*
1413 * NB: we could do this block-at-a-time, but it's nice
1414 * to be reading in parallel.
1415 */
1439 }
1443 }
1445 /*
1446 * Read 'size' bytes into the uio buffer.
1447 * From object zdb->db_object.
1448 * Starting at zfs_uio_offset(uio).
1449 *
1450 * If the caller already has a dbuf in the target object
1451 * (e.g. its bonus buffer), this routine is faster than dmu_read_uio(),
1452 * because we don't have to find the dnode_t for the object.
1453 */
1454 int
1456 {
1468 }
1470 /*
1471 * Read 'size' bytes into the uio buffer.
1472 * From the specified object
1473 * Starting at offset zfs_uio_offset(uio).
1474 */
1475 int
1477 {
1493 }
1495 int
1497 {
1503 top:
1506 /*
1507 * We only allow Direct I/O writes to happen if we are block
1508 * sized aligned. Otherwise, we pass the write off to the ARC.
1509 */
1518 write_size =
1526 }
1528 write_size =
1530 }
1531 }
1553 else
1561 /* The fill was reverted. Undo any uio progress. */
1563 }
1570 }
1578 }
1581 }
1583 /*
1584 * Write 'size' bytes from the uio buffer.
1585 * To object zdb->db_object.
1586 * Starting at offset zfs_uio_offset(uio).
1587 *
1588 * If the caller already has a dbuf in the target object
1589 * (e.g. its bonus buffer), this routine is faster than dmu_write_uio(),
1590 * because we don't have to find the dnode_t for the object.
1591 */
1592 int
1595 {
1607 }
1609 /*
1610 * Write 'size' bytes from the uio buffer.
1611 * To the specified object.
1612 * Starting at offset zfs_uio_offset(uio).
1613 */
1614 int
1617 {
1633 }
1636 static void
1639 {
1656 ARC_CACHED_IN_L2)
1658 else
1660 }
1661 }
1663 /*
1664 * Estimate DMU object cached size.
1665 */
1666 int
1669 {
1671 dmu_object_info_t doi;
1682 }
1688 /* dbuf_read doesn't prefetch L1 blocks. */
1691 }
1693 /*
1694 * Hold all valid L1 blocks, asking ARC the status of each BP
1695 * contained in each such L1 block.
1696 */
1705 /*
1706 * On interrupt, get out, and bubble up EINTR
1707 */
1710 }
1712 /*
1713 * If we get an i/o error here, the L1 can't be read,
1714 * and nothing under it could be cached, so we just
1715 * continue. Ignoring the error from dbuf_hold_impl
1716 * or from dbuf_read is then a reasonable choice.
1717 */
1720 /*
1721 * ignore error and continue
1722 */
1725 }
1731 }
1732 /*
1733 * error may be ignored, and we continue
1734 */
1737 }
1742 }
1744 /*
1745 * Allocate a loaned anonymous arc buffer.
1746 */
1747 arc_buf_t *
1749 {
1753 }
1755 /*
1756 * Free a loaned arc buffer.
1757 */
1758 void
1760 {
1763 }
1765 /*
1766 * A "lightweight" write is faster than a regular write (e.g.
1767 * dmu_write_by_dnode() or dmu_assign_arcbuf_by_dnode()), because it avoids the
1768 * CPU cost of creating a dmu_buf_impl_t and arc_buf_[hdr_]_t. However, the
1769 * data can not be read or overwritten until the transaction's txg has been
1770 * synced. This makes it appropriate for workloads that are known to be
1771 * (temporarily) write-only, like "zfs receive".
1772 *
1773 * A single block is written, starting at the specified offset in bytes. If
1774 * the call is successful, it returns 0 and the provided abd has been
1775 * consumed (the caller should not free it).
1776 */
1777 int
1780 {
1789 }
1791 /*
1792 * When possible directly assign passed loaned arc buffer to a dbuf.
1793 * If this is not possible copy the contents of passed arc buf via
1794 * dmu_write().
1795 */
1796 int
1799 {
1813 /*
1814 * We can only assign if the offset is aligned and the arc buf is the
1815 * same size as the dbuf.
1816 */
1822 /* compressed bufs must always be assignable to their dbuf */
1829 }
1832 }
1834 int
1837 {
1846 }
1848 void
1850 {
1862 else
1864 /*
1865 * A block of zeros may compress to a hole, but the
1866 * block size still needs to be known for replay.
1867 */
1872 }
1873 }
1874 }
1876 static void
1878 {
1880 }
1882 void
1884 {
1891 /*
1892 * Record the vdev(s) backing this blkptr so they can be flushed after
1893 * the writes for the lwb have completed.
1894 */
1897 }
1913 ZCHECKSUM_FLAG_NOPWRITE);
1914 }
1919 /*
1920 * Old style holes are filled with all zeros, whereas
1921 * new-style holes maintain their lsize, type, level,
1922 * and birth time (see zio_write_compress). While we
1923 * need to reset the BP_SET_LSIZE() call that happened
1924 * in dmu_sync_ready for old style holes, we do *not*
1925 * want to wipe out the information contained in new
1926 * style holes. Thus, only zero out the block pointer if
1927 * it's an old style hole.
1928 */
1934 }
1943 }
1945 static void
1947 {
1953 /*
1954 * Record the vdev(s) backing this blkptr so they can be
1955 * flushed after the writes for the lwb have completed.
1956 */
1966 }
1967 }
1975 }
1977 static int
1980 {
1992 /*
1993 * This transaction does not produce any dirty data or log blocks, so
1994 * it should not be throttled. All other cases wait for TXG sync, by
1995 * which time the log block we are writing will be obsolete, so we can
1996 * skip waiting and just return error here instead.
1997 */
2000 /* Make zl_get_data do txg_waited_synced() */
2002 }
2004 /*
2005 * In order to prevent the zgd's lwb from being free'd prior to
2006 * dmu_sync_late_arrival_done() being called, we have to ensure
2007 * the lwb's "max txg" takes this tx's txg into account.
2008 */
2017 /*
2018 * Since we are currently syncing this txg, it's nontrivial to
2019 * determine what BP to nopwrite against, so we disable nopwrite.
2020 *
2021 * When syncing, the db_blkptr is initially the BP of the previous
2022 * txg. We can not nopwrite against it because it will be changed
2023 * (this is similar to the non-late-arrival case where the dbuf is
2024 * dirty in a future txg).
2025 *
2026 * Then dbuf_write_ready() sets bp_blkptr to the location we will write.
2027 * We can not nopwrite against it because although the BP will not
2028 * (typically) be changed, the data has not yet been persisted to this
2029 * location.
2030 *
2031 * Finally, when dbuf_write_done() is called, it is theoretically
2032 * possible to always nopwrite, because the data that was written in
2033 * this txg is the same data that we are trying to write. However we
2034 * would need to check that this dbuf is not dirty in any future
2035 * txg's (as we do in the normal dmu_sync() path). For simplicity, we
2036 * don't nopwrite in this case.
2037 */
2047 }
2049 /*
2050 * Intent log support: sync the block associated with db to disk.
2051 * N.B. and XXX: the caller is responsible for making sure that the
2052 * data isn't changing while dmu_sync() is writing it.
2053 *
2054 * Return values:
2055 *
2056 * EEXIST: this txg has already been synced, so there's nothing to do.
2057 * The caller should not log the write.
2058 *
2059 * ENOENT: the block was dbuf_free_range()'d, so there's nothing to do.
2060 * The caller should not log the write.
2061 *
2062 * EALREADY: this block is already in the process of being synced.
2063 * The caller should track its progress (somehow).
2064 *
2065 * EIO: could not do the I/O.
2066 * The caller should do a txg_wait_synced().
2067 *
2068 * 0: the I/O has been initiated.
2069 * The caller should log this blkptr in the done callback.
2070 * It is possible that the I/O will fail, in which case
2071 * the error will be reported to the done callback and
2072 * propagated to pio from zio_done().
2073 */
2074 int
2076 {
2082 zbookmark_phys_t zb;
2083 zio_prop_t zp;
2095 /*
2096 * If we're frozen (running ziltest), we always need to generate a bp.
2097 */
2101 /*
2102 * Grabbing db_mtx now provides a barrier between dbuf_sync_leaf()
2103 * and us. If we determine that this txg is not yet syncing,
2104 * but it begins to sync a moment later, that's OK because the
2105 * sync thread will block in dbuf_sync_leaf() until we drop db_mtx.
2106 */
2110 /*
2111 * This txg has already synced. There's nothing to do.
2112 */
2115 }
2118 /*
2119 * This txg is currently syncing, so we can't mess with
2120 * the dirty record anymore; just write a new log block.
2121 */
2124 }
2129 /*
2130 * There's no dr for this dbuf, so it must have been freed.
2131 * There's no need to log writes to freed blocks, so we're done.
2132 */
2135 }
2141 /*
2142 * We need to fill in zgd_bp with the current blkptr so that
2143 * the nopwrite code can check if we're writing the same
2144 * data that's already on disk. We can only nopwrite if we
2145 * are sure that after making the copy, db_blkptr will not
2146 * change until our i/o completes. We ensure this by
2147 * holding the db_mtx, and only allowing nopwrite if the
2148 * block is not already dirty (see below). This is verified
2149 * by dmu_sync_done(), which VERIFYs that the db_blkptr has
2150 * not changed.
2151 */
2153 }
2155 /*
2156 * Assume the on-disk data is X, the current syncing data (in
2157 * txg - 1) is Y, and the current in-memory data is Z (currently
2158 * in dmu_sync).
2159 *
2160 * We usually want to perform a nopwrite if X and Z are the
2161 * same. However, if Y is different (i.e. the BP is going to
2162 * change before this write takes effect), then a nopwrite will
2163 * be incorrect - we would override with X, which could have
2164 * been freed when Y was written.
2165 *
2166 * (Note that this is not a concern when we are nop-writing from
2167 * syncing context, because X and Y must be identical, because
2168 * all previous txgs have been synced.)
2169 *
2170 * Therefore, we disable nopwrite if the current BP could change
2171 * before this TXG. There are two ways it could change: by
2172 * being dirty (dr_next is non-NULL), or by being freed
2173 * (dnode_block_freed()). This behavior is verified by
2174 * zio_done(), which VERIFYs that the override BP is identical
2175 * to the on-disk BP.
2176 */
2184 }
2189 /*
2190 * We have already issued a sync write for this buffer,
2191 * or this buffer has already been synced. It could not
2192 * have been dirtied since, or we would have cleared the state.
2193 */
2196 }
2216 }
2218 int
2220 {
2230 }
2232 int
2235 {
2245 }
2247 int
2250 {
2262 }
2264 void
2267 {
2270 /*
2271 * Send streams include each object's checksum function. This
2272 * check ensures that the receiving system can understand the
2273 * checksum function transmitted.
2274 */
2282 }
2284 void
2287 {
2290 /*
2291 * Send streams include each object's compression function. This
2292 * check ensures that the receiving system can understand the
2293 * compression function transmitted.
2294 */
2301 }
2303 /*
2304 * When the "redundant_metadata" property is set to "most", only indirect
2305 * blocks of this level and higher will have an additional ditto block.
2306 */
2309 void
2311 {
2325 /*
2326 * We maintain different write policies for each of the following
2327 * types of data:
2328 * 1. metadata
2329 * 2. preallocated blocks (i.e. level-0 blocks of a dump device)
2330 * 3. all other level 0 blocks
2331 */
2333 /*
2334 * XXX -- we should design a compression algorithm
2335 * that specializes in arrays of bps.
2336 */
2340 /*
2341 * Metadata always gets checksummed. If the data
2342 * checksum is multi-bit correctable, and it's not a
2343 * ZBT-style checksum, then it's suitable for metadata
2344 * as well. Otherwise, the metadata checksum defaults
2345 * to fletcher4.
2346 */
2348 ZCHECKSUM_FLAG_METADATA) ||
2350 ZCHECKSUM_FLAG_EMBEDDED))
2355 copies++;
2360 copies++;
2364 copies++;
2368 }
2371 /*
2372 * If this tuneable is set, and this is a write for a
2373 * dedup entry store (zap or log), then we treat it
2374 * something like ZFS_REDUNDANT_METADATA_MOST on a
2375 * regular dataset: this many copies, and one more for
2376 * "higher" indirect blocks. This specific exception is
2377 * necessary because dedup objects are stored in the
2378 * MOS, which always has the highest possible copies.
2379 */
2380 dmu_object_type_t stype =
2387 zfs_redundant_metadata_most_ditto_level)
2388 copies++;
2389 }
2390 }
2394 /*
2395 * If we're writing preallocated blocks, we aren't actually
2396 * writing them so don't set any policy properties. These
2397 * blocks are currently only used by an external subsystem
2398 * outside of zfs (i.e. dump) and not written by the zio
2399 * pipeline.
2400 */
2405 compress);
2411 dedup_checksum;
2413 /*
2414 * Determine dedup setting. If we are in dmu_sync(),
2415 * we won't actually dedup now because that's all
2416 * done in syncing context; but we do want to use the
2417 * dedup checksum. If the checksum is not strong
2418 * enough to ensure unique signatures, force
2419 * dedup_verify.
2420 */
2424 ZCHECKSUM_FLAG_DEDUP))
2426 }
2428 /*
2429 * Enable nopwrite if we have secure enough checksum
2430 * algorithm (see comment in zio_nop_write) and
2431 * compression is enabled. We don't enable nopwrite if
2432 * dedup is enabled as the two features are mutually
2433 * exclusive.
2434 */
2436 ZCHECKSUM_FLAG_NOPWRITE) &&
2438 }
2440 /*
2441 * All objects in an encrypted objset are protected from modification
2442 * via a MAC. Encrypted objects store their IV and salt in the last DVA
2443 * in the bp, so we cannot use all copies. Encrypted objects are also
2444 * not subject to nopwrite since writing the same data will still
2445 * result in a new ciphertext. Only encrypted blocks can be dedup'd
2446 * to avoid ambiguity in the dedup code since the DDT does not store
2447 * object types.
2448 */
2457 }
2462 }
2463 }
2485 }
2487 /*
2488 * Reports the location of data and holes in an object. In order to
2489 * accurately report holes all dirty data must be synced to disk. This
2490 * causes extremely poor performance when seeking for holes in a dirty file.
2491 * As a compromise, only provide hole data when the dnode is clean. When
2492 * a dnode is dirty report the dnode as having no holes by returning EBUSY
2493 * which is always safe to do.
2494 */
2495 int
2497 {
2501 restart:
2509 /*
2510 * If the zfs_dmu_offset_next_sync module option is enabled
2511 * then hole reporting has been requested. Dirty dnodes
2512 * must be synced to disk to accurately report holes.
2513 *
2514 * Provided a RL_READER rangelock spanning 0-UINT64_MAX is
2515 * held by the caller only a single restart will be required.
2516 * We tolerate callers which do not hold the rangelock by
2517 * returning EBUSY and not reporting holes after one restart.
2518 */
2529 }
2535 }
2541 }
2543 int
2546 {
2557 }
2559 }
2574 /*
2575 * This is very special case where we clone a
2576 * block and in the same transaction group we
2577 * read its BP (most likely to clone the clone).
2578 */
2581 /*
2582 * The block was modified in the same
2583 * transaction group.
2584 */
2588 }
2591 }
2596 /*
2597 * The file size was increased, but the block was never
2598 * written, otherwise we would either have the block
2599 * pointer or the dirty record and would not get here.
2600 * It is effectively a hole, so report it as such.
2601 */
2604 }
2605 /*
2606 * Make sure we clone only data blocks.
2607 */
2611 }
2613 /*
2614 * If the block was allocated in transaction group that is not
2615 * yet synced, we could clone it, but we couldn't write this
2616 * operation into ZIL, or it may be impossible to replay, since
2617 * the block may appear not yet allocated at that point.
2618 */
2622 }
2626 }
2629 }
2632 out:
2636 }
2638 int
2641 {
2656 /*
2657 * Before we start cloning make sure that the dbufs sizes match new BPs
2658 * sizes. If they don't, that's a no-go, as we are not able to shrink
2659 * dbufs.
2660 */
2674 }
2675 }
2699 }
2700 }
2706 /*
2707 * When data in embedded into BP there is no need to create
2708 * BRT entry as there is no data block. Just copy the BP as
2709 * it contains the data.
2710 */
2713 }
2714 }
2715 out:
2719 }
2721 void
2723 {
2742 }
2744 void
2746 {
2754 }
2756 /*
2757 * Get information on a DMU object.
2758 * If doi is NULL, just indicates whether the object exists.
2759 */
2760 int
2762 {
2774 }
2776 /*
2777 * As above, but faster; can be used when you have a held dbuf in hand.
2778 */
2779 void
2781 {
2787 }
2789 /*
2790 * Faster still when you only care about the size.
2791 */
2792 void
2795 {
2803 /* add in number of slots used for the dnode itself */
2807 }
2809 void
2811 {
2817 }
2819 void
2821 {
2830 }
2832 void
2834 {
2843 }
2845 void
2847 {
2856 }
2858 void
2860 {
2862 }
2864 void
2866 {
2877 }
2879 void
2881 {
2892 }
2945 /* CSTYLED */
2949 /* CSTYLED */