| blob | 0eb8c17e331ab35c92230c96d37ea6f8e0a4df71 |
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 2011 Nexenta Systems, Inc. All rights reserved.
24 * Copyright (c) 2012, 2017 by Delphix. All rights reserved.
25 */
27 #include <sys/dmu.h>
28 #include <sys/dmu_impl.h>
29 #include <sys/dbuf.h>
30 #include <sys/dmu_tx.h>
31 #include <sys/dmu_objset.h>
32 #include <sys/dsl_dataset.h>
33 #include <sys/dsl_dir.h>
34 #include <sys/dsl_pool.h>
35 #include <sys/zap_impl.h>
36 #include <sys/spa.h>
37 #include <sys/sa.h>
38 #include <sys/sa_impl.h>
39 #include <sys/zfs_context.h>
40 #include <sys/trace_zfs.h>
45 dmu_tx_stats_t dmu_tx_stats = {
59 };
63 dmu_tx_t *
65 {
76 }
78 dmu_tx_t *
80 {
84 }
86 dmu_tx_t *
88 {
97 }
99 int
101 {
103 }
105 int
107 {
109 }
114 {
121 /*
122 * dn->dn_assigned_txg == tx->tx_txg doesn't pose a
123 * problem, but there's no way for it to happen (for
124 * now, at least).
125 */
130 }
131 }
144 }
149 {
159 }
160 }
165 }
167 void
169 {
170 /*
171 * If we're syncing, they can manipulate any object anyhow, and
172 * the hold on the dnode_t can cause problems.
173 */
176 }
178 /*
179 * This function reads specified data from disk. The specified data will
180 * be needed to perform the transaction -- i.e, it will be read after
181 * we do dmu_tx_assign(). There are two reasons that we read the data now
182 * (before dmu_tx_assign()):
183 *
184 * 1. Reading it now has potentially better performance. The transaction
185 * has not yet been assigned, so the TXG is not held open, and also the
186 * caller typically has less locks held when calling dmu_tx_hold_*() than
187 * after the transaction has been assigned. This reduces the lock (and txg)
188 * hold times, thus reducing lock contention.
189 *
190 * 2. It is easier for callers (primarily the ZPL) to handle i/o errors
191 * that are detected before they start making changes to the DMU state
192 * (i.e. now). Once the transaction has been assigned, and some DMU
193 * state has been changed, it can be difficult to recover from an i/o
194 * error (e.g. to undo the changes already made in memory at the DMU
195 * layer). Typically code to do so does not exist in the caller -- it
196 * assumes that the data has already been cached and thus i/o errors are
197 * not possible.
198 *
199 * It has been observed that the i/o initiated here can be a performance
200 * problem, and it appears to be optional, because we don't look at the
201 * data which is read. However, removing this read would only serve to
202 * move the work elsewhere (after the dmu_tx_assign()), where it may
203 * have a greater impact on performance (in addition to the impact on
204 * fault tolerance noted above).
205 */
206 static int
208 {
217 /*
218 * PARTIAL_FIRST allows caching for uncacheable blocks. It will
219 * be cleared after dmu_buf_will_dirty() call dbuf_read() again.
220 */
225 }
227 static void
229 {
241 /*
242 * For i/o error checking, read the blocks that will be needed
243 * to perform the write: the first and last level-0 blocks (if
244 * they are not aligned, i.e. if they are partial-block writes),
245 * and all the level-1 blocks.
246 */
253 }
254 }
259 /* first level-0 block */
265 }
266 }
268 /* last level-0 block */
275 }
276 }
278 /* level-1 blocks */
286 }
287 }
288 }
293 }
294 }
295 }
297 static void
299 {
311 /*
312 * For i/o error checking, read the blocks that will be needed
313 * to perform the append; first level-0 block (if not aligned, i.e.
314 * if they are partial-block writes), no additional blocks are read.
315 */
322 }
323 }
328 /* first level-0 block */
334 }
335 }
340 }
341 }
342 }
344 static void
346 {
349 }
351 void
353 {
365 }
366 }
368 void
370 {
381 }
382 }
384 /*
385 * Should be used when appending to an object and the exact offset is unknown.
386 * The write must occur at or beyond the specified offset. Only the L0 block
387 * at provided offset will be prefetched.
388 */
389 void
391 {
402 }
403 }
405 void
407 {
417 }
418 }
420 /*
421 * This function marks the transaction as being a "net free". The end
422 * result is that refquotas will be disabled for this transaction, and
423 * this transaction will be able to use half of the pool space overhead
424 * (see dsl_pool_adjustedsize()). Therefore this function should only
425 * be called for transactions that we expect will not cause a net increase
426 * in the amount of space used (but it's OK if that is occasionally not true).
427 */
428 void
430 {
432 }
434 static void
436 {
448 /*
449 * For i/o error checking, we read the first and last level-0
450 * blocks if they are not aligned, and all the level-1 blocks.
451 *
452 * Note: dbuf_free_range() assumes that we have not instantiated
453 * any level-0 dbufs that will be completely freed. Therefore we must
454 * exercise care to not read or count the first and last blocks
455 * if they are blocksize-aligned.
456 */
461 /* first block will be modified if it is not aligned */
464 /* last block will be modified if it is not aligned */
467 }
469 /*
470 * Check level-1 blocks.
471 */
474 SPA_BLKPTRSHIFT;
480 /*
481 * dnode_reallocate() can result in an object with indirect
482 * blocks having an odd data block size. In this case,
483 * just check the single block.
484 */
500 }
510 }
511 }
516 }
517 }
518 }
520 void
522 {
530 }
531 }
533 void
535 {
542 }
543 }
545 static void
547 {
549 /*
550 * Reuse dmu_tx_count_free(), it does exactly what we need for clone.
551 */
553 }
555 void
557 {
567 }
568 }
570 static void
572 {
582 /*
583 * Modifying a almost-full microzap is around the worst case (128KB)
584 *
585 * If it is a fat zap, the worst case would be 7*16KB=112KB:
586 * - 3 blocks overwritten: target leaf, ptrtbl block, header block
587 * - 4 new blocks written if adding:
588 * - 2 blocks for possibly split leaves,
589 * - 2 grown ptrtbl blocks
590 */
600 /*
601 * This is a microzap (only one block), or we don't know
602 * the name. Check the first block for i/o errors.
603 */
607 }
609 /*
610 * Access the name so that we'll check for i/o errors to
611 * the leaf blocks, etc. We ignore ENOENT, as this name
612 * may not yet exist.
613 */
617 }
618 }
619 }
621 void
623 {
632 }
634 void
636 {
645 }
647 void
649 {
658 }
660 void
662 {
670 }
672 void
674 {
684 }
685 }
687 #ifdef ZFS_DEBUG
688 void
690 {
703 }
705 /* XXX No checking on the meta dnode for now */
709 }
727 /* XXX txh_arg2 better not be zero... */
737 /*
738 * We will let this hold work for the bonus
739 * or spill buffer so that we don't need to
740 * hold it when creating a new object.
741 */
745 /*
746 * They might have to increase nlevels,
747 * thus dirtying the new TLIBs. Or the
748 * might have to change the block size,
749 * thus dirying the new lvl=0 blk=0.
750 */
759 /*
760 * THT_WRITE used for bonus and spill blocks.
761 */
765 /*
766 * They might have to increase nlevels,
767 * thus dirtying the new TLIBs. Or the
768 * might have to change the block size,
769 * thus dirying the new lvl=0 blk=0.
770 */
775 /*
776 * We will dirty all the level 1 blocks in
777 * the free range and perhaps the first and
778 * last level 0 block.
779 */
805 }
806 }
810 }
811 }
816 }
817 #endif
819 /*
820 * If we can't do 10 iops, something is wrong. Let us go ahead
821 * and hit zfs_dirty_data_max.
822 */
825 /*
826 * We delay transactions when we've determined that the backend storage
827 * isn't able to accommodate the rate of incoming writes.
828 *
829 * If there is already a transaction waiting, we delay relative to when
830 * that transaction finishes waiting. This way the calculated min_time
831 * is independent of the number of threads concurrently executing
832 * transactions.
833 *
834 * If we are the only waiter, wait relative to when the transaction
835 * started, rather than the current time. This credits the transaction for
836 * "time already served", e.g. reading indirect blocks.
837 *
838 * The minimum time for a transaction to take is calculated as:
839 * min_time = scale * (dirty - min) / (max - dirty)
840 * min_time is then capped at zfs_delay_max_ns.
841 *
842 * The delay has two degrees of freedom that can be adjusted via tunables.
843 * The percentage of dirty data at which we start to delay is defined by
844 * zfs_delay_min_dirty_percent. This should typically be at or above
845 * zfs_vdev_async_write_active_max_dirty_percent so that we only start to
846 * delay after writing at full speed has failed to keep up with the incoming
847 * write rate. The scale of the curve is defined by zfs_delay_scale. Roughly
848 * speaking, this variable determines the amount of delay at the midpoint of
849 * the curve.
850 *
851 * delay
852 * 10ms +-------------------------------------------------------------*+
853 * | *|
854 * 9ms + *+
855 * | *|
856 * 8ms + *+
857 * | * |
858 * 7ms + * +
859 * | * |
860 * 6ms + * +
861 * | * |
862 * 5ms + * +
863 * | * |
864 * 4ms + * +
865 * | * |
866 * 3ms + * +
867 * | * |
868 * 2ms + (midpoint) * +
869 * | | ** |
870 * 1ms + v *** +
871 * | zfs_delay_scale ----------> ******** |
872 * 0 +-------------------------------------*********----------------+
873 * 0% <- zfs_dirty_data_max -> 100%
874 *
875 * Note that since the delay is added to the outstanding time remaining on the
876 * most recent transaction, the delay is effectively the inverse of IOPS.
877 * Here the midpoint of 500us translates to 2000 IOPS. The shape of the curve
878 * was chosen such that small changes in the amount of accumulated dirty data
879 * in the first 3/4 of the curve yield relatively small differences in the
880 * amount of delay.
881 *
882 * The effects can be easier to understand when the amount of delay is
883 * represented on a log scale:
884 *
885 * delay
886 * 100ms +-------------------------------------------------------------++
887 * + +
888 * | |
889 * + *+
890 * 10ms + *+
891 * + ** +
892 * | (midpoint) ** |
893 * + | ** +
894 * 1ms + v **** +
895 * + zfs_delay_scale ----------> ***** +
896 * | **** |
897 * + **** +
898 * 100us + ** +
899 * + * +
900 * | * |
901 * + * +
902 * 10us + * +
903 * + +
904 * | |
905 * + +
906 * +--------------------------------------------------------------+
907 * 0% <- zfs_dirty_data_max -> 100%
908 *
909 * Note here that only as the amount of dirty data approaches its limit does
910 * the delay start to increase rapidly. The goal of a properly tuned system
911 * should be to keep the amount of dirty data out of that range by first
912 * ensuring that the appropriate limits are set for the I/O scheduler to reach
913 * optimal throughput on the backend storage, and then by changing the value
914 * of zfs_delay_scale to increase the steepness of the curve.
915 */
916 static void
918 {
923 /* Calculate minimum transaction time for the dirty data amount. */
924 delay_min_bytes =
927 /*
928 * The caller has already waited until we are under the max.
929 * We make them pass us the amount of dirty data so we don't
930 * have to handle the case of it being >= the max, which
931 * could cause a divide-by-zero if it's == the max.
932 */
937 }
939 /* Calculate minimum transaction time for the TX_WRITE log size. */
941 delay_min_bytes =
948 }
967 }
969 /*
970 * This routine attempts to assign the transaction to a transaction group.
971 * To do so, we must determine if there is sufficient free space on disk.
972 *
973 * If this is a "netfree" transaction (i.e. we called dmu_tx_mark_netfree()
974 * on it), then it is assumed that there is sufficient free space,
975 * unless there's insufficient slop space in the pool (see the comment
976 * above spa_slop_shift in spa_misc.c).
977 *
978 * If it is not a "netfree" transaction, then if the data already on disk
979 * is over the allowed usage (e.g. quota), this will fail with EDQUOT or
980 * ENOSPC. Otherwise, if the current rough estimate of pending changes,
981 * plus the rough estimate of this transaction's changes, may exceed the
982 * allowed usage, then this will fail with ERESTART, which will cause the
983 * caller to wait for the pending changes to be written to disk (by waiting
984 * for the next TXG to open), and then check the space usage again.
985 *
986 * The rough estimate of pending changes is comprised of the sum of:
987 *
988 * - this transaction's holds' txh_space_towrite
989 *
990 * - dd_tempreserved[], which is the sum of in-flight transactions'
991 * holds' txh_space_towrite (i.e. those transactions that have called
992 * dmu_tx_assign() but not yet called dmu_tx_commit()).
993 *
994 * - dd_space_towrite[], which is the amount of dirtied dbufs.
995 *
996 * Note that all of these values are inflated by spa_get_worst_case_asize(),
997 * which means that we may get ERESTART well before we are actually in danger
998 * of running out of space, but this also mitigates any small inaccuracies
999 * in the rough estimate (e.g. txh_space_towrite doesn't take into account
1000 * indirect blocks, and dd_space_towrite[] doesn't take into account changes
1001 * to the MOS).
1002 *
1003 * Note that due to this algorithm, it is possible to exceed the allowed
1004 * usage by one transaction. Also, as we approach the allowed usage,
1005 * we will allow a very limited amount of changes into each TXG, thus
1006 * decreasing performance.
1007 */
1008 static int
1010 {
1018 }
1023 /*
1024 * If the user has indicated a blocking failure mode
1025 * then return ERESTART which will block in dmu_tx_wait().
1026 * Otherwise, return EIO so that an error can get
1027 * propagated back to the VOP calls.
1028 *
1029 * Note that we always honor the txg_how flag regardless
1030 * of the failuremode setting.
1031 */
1037 }
1044 }
1051 }
1056 /*
1057 * NB: No error returns are allowed after txg_hold_open, but
1058 * before processing the dnode holds, due to the
1059 * dmu_tx_unassign() logic.
1060 */
1068 /*
1069 * This thread can't hold the dn_struct_rwlock
1070 * while assigning the tx, because this can lead to
1071 * deadlock. Specifically, if this dnode is already
1072 * assigned to an earlier txg, this thread may need
1073 * to wait for that txg to sync (the ERESTART case
1074 * below). The other thread that has assigned this
1075 * dnode to an earlier txg prevents this txg from
1076 * syncing until its tx can complete (calling
1077 * dmu_tx_commit()), but it may need to acquire the
1078 * dn_struct_rwlock to do so (e.g. via
1079 * dmu_buf_hold*()).
1080 *
1081 * Note that this thread can't hold the lock for
1082 * read either, but the rwlock doesn't record
1083 * enough information to make that assertion.
1084 */
1093 }
1099 }
1102 }
1104 /* needed allocation: worst-case estimate of write space */
1106 /* calculate memory footprint estimate */
1114 }
1119 }
1121 static void
1123 {
1129 /*
1130 * Walk the transaction's hold list, removing the hold on the
1131 * associated dnode, and notifying waiters if the refcount drops to 0.
1132 */
1146 }
1148 }
1154 }
1156 /*
1157 * Assign tx to a transaction group; txg_how is a bitmask:
1158 *
1159 * If TXG_WAIT is set and the currently open txg is full, this function
1160 * will wait until there's a new txg. This should be used when no locks
1161 * are being held. With this bit set, this function will only fail if
1162 * we're truly out of space (or over quota).
1163 *
1164 * If TXG_WAIT is *not* set and we can't assign into the currently open
1165 * txg without blocking, this function will return immediately with
1166 * ERESTART. This should be used whenever locks are being held. On an
1167 * ERESTART error, the caller should drop all locks, call dmu_tx_wait(),
1168 * and try again.
1169 *
1170 * If TXG_NOTHROTTLE is set, this indicates that this tx should not be
1171 * delayed due on the ZFS Write Throttle (see comments in dsl_pool.c for
1172 * details on the throttle). This is used by the VFS operations, after
1173 * they have already called dmu_tx_wait() (though most likely on a
1174 * different tx).
1175 *
1176 * It is guaranteed that subsequent successful calls to dmu_tx_assign()
1177 * will assign the tx to monotonically increasing txgs. Of course this is
1178 * not strong monotonicity, because the same txg can be returned multiple
1179 * times in a row. This guarantee holds both for subsequent calls from
1180 * one thread and for multiple threads. For example, it is impossible to
1181 * observe the following sequence of events:
1182 *
1183 * Thread 1 Thread 2
1184 *
1185 * dmu_tx_assign(T1, ...)
1186 * 1 <- dmu_tx_get_txg(T1)
1187 * dmu_tx_assign(T2, ...)
1188 * 2 <- dmu_tx_get_txg(T2)
1189 * dmu_tx_assign(T3, ...)
1190 * 1 <- dmu_tx_get_txg(T3)
1191 */
1192 int
1194 {
1201 /* If we might wait, we must not hold the config lock. */
1214 }
1219 }
1221 void
1223 {
1226 hrtime_t before;
1236 /*
1237 * dmu_tx_try_assign() has determined that we need to wait
1238 * because we've consumed much or all of the dirty buffer
1239 * space.
1240 */
1253 /*
1254 * Note: setting tx_dirty_delayed only has effect if the
1255 * caller used TX_WAIT. Otherwise they are going to
1256 * destroy this tx and try again. The common case,
1257 * zfs_write(), uses TX_WAIT.
1258 */
1261 /*
1262 * If the pool is suspended we need to wait until it
1263 * is resumed. Note that it's possible that the pool
1264 * has become active after this thread has tried to
1265 * obtain a tx. If that's the case then tx_lasttried_txg
1266 * would not have been set.
1267 */
1278 /*
1279 * If we have a lot of dirty data just wait until we sync
1280 * out a TXG at which point we'll hopefully have synced
1281 * a portion of the changes.
1282 */
1284 }
1287 }
1289 static void
1291 {
1305 }
1310 }
1312 void
1314 {
1317 /*
1318 * Go through the transaction's hold list and remove holds on
1319 * associated dnodes, notifying waiters if no holds remain.
1320 */
1334 }
1336 }
1348 }
1350 void
1352 {
1355 /*
1356 * Call any registered callbacks with an error code.
1357 */
1362 }
1364 uint64_t
1366 {
1369 }
1371 dsl_pool_t *
1373 {
1376 }
1378 void
1380 {
1389 }
1391 /*
1392 * Call all the commit callbacks on a list, with a given error code.
1393 */
1394 void
1396 {
1402 }
1403 }
1405 /*
1406 * Interface to hold a bunch of attributes.
1407 * used for creating new files.
1408 * attrsize is the total size of all attributes
1409 * to be added during object creation
1410 *
1411 * For updating/adding a single attribute dmu_tx_hold_sa() should be used.
1412 */
1414 /*
1415 * hold necessary attribute name for attribute registration.
1416 * should be a very rare case where this is needed. If it does
1417 * happen it would only happen on the first write to the file system.
1418 */
1419 static void
1421 {
1430 else
1433 }
1434 }
1435 }
1437 void
1439 {
1447 }
1449 void
1451 {
1466 }
1475 }
1477 /*
1478 * Hold SA attribute
1479 *
1480 * dmu_tx_hold_sa(dmu_tx_t *tx, sa_handle_t *, attribute, add, size)
1481 *
1482 * variable_size is the total size of all variable sized attributes
1483 * passed to this function. It is not the total size of all
1484 * variable size attributes that *may* exist on this object.
1485 */
1486 void
1488 {
1510 }
1528 }
1530 }
1531 }
1533 void
1535 {
1538 KSTAT_FLAG_VIRTUAL);
1543 }
1544 }
1546 void
1548 {
1552 }
1553 }
1555 #if defined(_KERNEL)
1578 #endif