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24 .Nd tuning of the ZFS kernel module
27 The ZFS module supports these parameters:
29 .It Sy dbuf_cache_max_bytes Ns = Ns Sy UINT64_MAX Ns B Pq u64
30 Maximum size in bytes of the dbuf cache.
31 The target size is determined by the MIN versus
32 .No 1/2^ Ns Sy dbuf_cache_shift Pq 1/32nd
33 of the target ARC size.
34 The behavior of the dbuf cache and its associated settings
35 can be observed via the
36 .Pa /proc/spl/kstat/zfs/dbufstats
39 .It Sy dbuf_metadata_cache_max_bytes Ns = Ns Sy UINT64_MAX Ns B Pq u64
40 Maximum size in bytes of the metadata dbuf cache.
41 The target size is determined by the MIN versus
42 .No 1/2^ Ns Sy dbuf_metadata_cache_shift Pq 1/64th
43 of the target ARC size.
44 The behavior of the metadata dbuf cache and its associated settings
45 can be observed via the
46 .Pa /proc/spl/kstat/zfs/dbufstats
49 .It Sy dbuf_cache_hiwater_pct Ns = Ns Sy 10 Ns % Pq uint
51 .Sy dbuf_cache_max_bytes
52 when dbufs must be evicted directly.
54 .It Sy dbuf_cache_lowater_pct Ns = Ns Sy 10 Ns % Pq uint
56 .Sy dbuf_cache_max_bytes
57 when the evict thread stops evicting dbufs.
59 .It Sy dbuf_cache_shift Ns = Ns Sy 5 Pq uint
60 Set the size of the dbuf cache
61 .Pq Sy dbuf_cache_max_bytes
62 to a log2 fraction of the target ARC size.
64 .It Sy dbuf_metadata_cache_shift Ns = Ns Sy 6 Pq uint
65 Set the size of the dbuf metadata cache
66 .Pq Sy dbuf_metadata_cache_max_bytes
67 to a log2 fraction of the target ARC size.
69 .It Sy dbuf_mutex_cache_shift Ns = Ns Sy 0 Pq uint
70 Set the size of the mutex array for the dbuf cache.
73 the array is dynamically sized based on total system memory.
75 .It Sy dmu_object_alloc_chunk_shift Ns = Ns Sy 7 Po 128 Pc Pq uint
76 dnode slots allocated in a single operation as a power of 2.
77 The default value minimizes lock contention for the bulk operation performed.
79 .It Sy dmu_prefetch_max Ns = Ns Sy 134217728 Ns B Po 128 MiB Pc Pq uint
80 Limit the amount we can prefetch with one call to this amount in bytes.
81 This helps to limit the amount of memory that can be used by prefetching.
83 .It Sy ignore_hole_birth Pq int
85 .Sy send_holes_without_birth_time .
87 .It Sy l2arc_feed_again Ns = Ns Sy 1 Ns | Ns 0 Pq int
89 When the L2ARC is cold the fill interval will be set as fast as possible.
91 .It Sy l2arc_feed_min_ms Ns = Ns Sy 200 Pq u64
92 Min feed interval in milliseconds.
94 .Sy l2arc_feed_again Ns = Ns Ar 1
95 and only applicable in related situations.
97 .It Sy l2arc_feed_secs Ns = Ns Sy 1 Pq u64
98 Seconds between L2ARC writing.
100 .It Sy l2arc_headroom Ns = Ns Sy 2 Pq u64
101 How far through the ARC lists to search for L2ARC cacheable content,
102 expressed as a multiplier of
103 .Sy l2arc_write_max .
104 ARC persistence across reboots can be achieved with persistent L2ARC
105 by setting this parameter to
107 allowing the full length of ARC lists to be searched for cacheable content.
109 .It Sy l2arc_headroom_boost Ns = Ns Sy 200 Ns % Pq u64
112 by this percentage when L2ARC contents are being successfully compressed
116 disables this feature.
118 .It Sy l2arc_exclude_special Ns = Ns Sy 0 Ns | Ns 1 Pq int
119 Controls whether buffers present on special vdevs are eligible for caching
121 If set to 1, exclude dbufs on special vdevs from being cached to L2ARC.
123 .It Sy l2arc_mfuonly Ns = Ns Sy 0 Ns | Ns 1 Pq int
124 Controls whether only MFU metadata and data are cached from ARC into L2ARC.
125 This may be desired to avoid wasting space on L2ARC when reading/writing large
126 amounts of data that are not expected to be accessed more than once.
129 meaning both MRU and MFU data and metadata are cached.
130 When turning off this feature, some MRU buffers will still be present
131 in ARC and eventually cached on L2ARC.
132 .No If Sy l2arc_noprefetch Ns = Ns Sy 0 ,
133 some prefetched buffers will be cached to L2ARC, and those might later
134 transition to MRU, in which case the
135 .Sy l2arc_mru_asize No arcstat will not be Sy 0 .
138 .Sy l2arc_noprefetch ,
139 some MFU buffers might be evicted from ARC,
140 accessed later on as prefetches and transition to MRU as prefetches.
141 If accessed again they are counted as MRU and the
142 .Sy l2arc_mru_asize No arcstat will not be Sy 0 .
144 The ARC status of L2ARC buffers when they were first cached in
145 L2ARC can be seen in the
146 .Sy l2arc_mru_asize , Sy l2arc_mfu_asize , No and Sy l2arc_prefetch_asize
147 arcstats when importing the pool or onlining a cache
148 device if persistent L2ARC is enabled.
151 .Sy evict_l2_eligible_mru
152 arcstat does not take into account if this option is enabled as the information
154 .Sy evict_l2_eligible_m[rf]u
155 arcstats can be used to decide if toggling this option is appropriate
156 for the current workload.
158 .It Sy l2arc_meta_percent Ns = Ns Sy 33 Ns % Pq uint
159 Percent of ARC size allowed for L2ARC-only headers.
160 Since L2ARC buffers are not evicted on memory pressure,
161 too many headers on a system with an irrationally large L2ARC
162 can render it slow or unusable.
163 This parameter limits L2ARC writes and rebuilds to achieve the target.
165 .It Sy l2arc_trim_ahead Ns = Ns Sy 0 Ns % Pq u64
166 Trims ahead of the current write size
167 .Pq Sy l2arc_write_max
168 on L2ARC devices by this percentage of write size if we have filled the device.
171 we TRIM twice the space required to accommodate upcoming writes.
175 It also enables TRIM of the whole L2ARC device upon creation
176 or addition to an existing pool or if the header of the device is
177 invalid upon importing a pool or onlining a cache device.
180 disables TRIM on L2ARC altogether and is the default as it can put significant
181 stress on the underlying storage devices.
182 This will vary depending of how well the specific device handles these commands.
184 .It Sy l2arc_noprefetch Ns = Ns Sy 1 Ns | Ns 0 Pq int
185 Do not write buffers to L2ARC if they were prefetched but not used by
187 In case there are prefetched buffers in L2ARC and this option
188 is later set, we do not read the prefetched buffers from L2ARC.
189 Unsetting this option is useful for caching sequential reads from the
190 disks to L2ARC and serve those reads from L2ARC later on.
191 This may be beneficial in case the L2ARC device is significantly faster
192 in sequential reads than the disks of the pool.
198 to enable caching/reading prefetches to/from L2ARC.
200 .It Sy l2arc_norw Ns = Ns Sy 0 Ns | Ns 1 Pq int
201 No reads during writes.
203 .It Sy l2arc_write_boost Ns = Ns Sy 8388608 Ns B Po 8 MiB Pc Pq u64
204 Cold L2ARC devices will have
206 increased by this amount while they remain cold.
208 .It Sy l2arc_write_max Ns = Ns Sy 8388608 Ns B Po 8 MiB Pc Pq u64
209 Max write bytes per interval.
211 .It Sy l2arc_rebuild_enabled Ns = Ns Sy 1 Ns | Ns 0 Pq int
212 Rebuild the L2ARC when importing a pool (persistent L2ARC).
213 This can be disabled if there are problems importing a pool
214 or attaching an L2ARC device (e.g. the L2ARC device is slow
215 in reading stored log metadata, or the metadata
216 has become somehow fragmented/unusable).
218 .It Sy l2arc_rebuild_blocks_min_l2size Ns = Ns Sy 1073741824 Ns B Po 1 GiB Pc Pq u64
219 Mininum size of an L2ARC device required in order to write log blocks in it.
220 The log blocks are used upon importing the pool to rebuild the persistent L2ARC.
222 For L2ARC devices less than 1 GiB, the amount of data
224 evicts is significant compared to the amount of restored L2ARC data.
225 In this case, do not write log blocks in L2ARC in order not to waste space.
227 .It Sy metaslab_aliquot Ns = Ns Sy 1048576 Ns B Po 1 MiB Pc Pq u64
228 Metaslab granularity, in bytes.
229 This is roughly similar to what would be referred to as the "stripe size"
230 in traditional RAID arrays.
231 In normal operation, ZFS will try to write this amount of data to each disk
232 before moving on to the next top-level vdev.
234 .It Sy metaslab_bias_enabled Ns = Ns Sy 1 Ns | Ns 0 Pq int
235 Enable metaslab group biasing based on their vdevs' over- or under-utilization
236 relative to the pool.
238 .It Sy metaslab_force_ganging Ns = Ns Sy 16777217 Ns B Po 16 MiB + 1 B Pc Pq u64
239 Make some blocks above a certain size be gang blocks.
240 This option is used by the test suite to facilitate testing.
242 .It Sy zfs_default_bs Ns = Ns Sy 9 Po 512 B Pc Pq int
243 Default dnode block size as a power of 2.
245 .It Sy zfs_default_ibs Ns = Ns Sy 17 Po 128 KiB Pc Pq int
246 Default dnode indirect block size as a power of 2.
248 .It Sy zfs_history_output_max Ns = Ns Sy 1048576 Ns B Po 1 MiB Pc Pq u64
249 When attempting to log an output nvlist of an ioctl in the on-disk history,
250 the output will not be stored if it is larger than this size (in bytes).
251 This must be less than
252 .Sy DMU_MAX_ACCESS Pq 64 MiB .
253 This applies primarily to
254 .Fn zfs_ioc_channel_program Pq cf. Xr zfs-program 8 .
256 .It Sy zfs_keep_log_spacemaps_at_export Ns = Ns Sy 0 Ns | Ns 1 Pq int
257 Prevent log spacemaps from being destroyed during pool exports and destroys.
259 .It Sy zfs_metaslab_segment_weight_enabled Ns = Ns Sy 1 Ns | Ns 0 Pq int
260 Enable/disable segment-based metaslab selection.
262 .It Sy zfs_metaslab_switch_threshold Ns = Ns Sy 2 Pq int
263 When using segment-based metaslab selection, continue allocating
264 from the active metaslab until this option's
265 worth of buckets have been exhausted.
267 .It Sy metaslab_debug_load Ns = Ns Sy 0 Ns | Ns 1 Pq int
268 Load all metaslabs during pool import.
270 .It Sy metaslab_debug_unload Ns = Ns Sy 0 Ns | Ns 1 Pq int
271 Prevent metaslabs from being unloaded.
273 .It Sy metaslab_fragmentation_factor_enabled Ns = Ns Sy 1 Ns | Ns 0 Pq int
274 Enable use of the fragmentation metric in computing metaslab weights.
276 .It Sy metaslab_df_max_search Ns = Ns Sy 16777216 Ns B Po 16 MiB Pc Pq uint
277 Maximum distance to search forward from the last offset.
278 Without this limit, fragmented pools can see
281 .Fn metaslab_block_picker
282 becomes the performance limiting factor on high-performance storage.
284 With the default setting of
286 we typically see less than
288 iterations, even with very fragmented
289 .Sy ashift Ns = Ns Sy 9
291 The maximum number of iterations possible is
292 .Sy metaslab_df_max_search / 2^(ashift+1) .
293 With the default setting of
296 .Em 16*1024 Pq with Sy ashift Ns = Ns Sy 9
298 .Em 2*1024 Pq with Sy ashift Ns = Ns Sy 12 .
300 .It Sy metaslab_df_use_largest_segment Ns = Ns Sy 0 Ns | Ns 1 Pq int
301 If not searching forward (due to
302 .Sy metaslab_df_max_search , metaslab_df_free_pct ,
303 .No or Sy metaslab_df_alloc_threshold ) ,
304 this tunable controls which segment is used.
305 If set, we will use the largest free segment.
306 If unset, we will use a segment of at least the requested size.
308 .It Sy zfs_metaslab_max_size_cache_sec Ns = Ns Sy 3600 Ns s Po 1 hour Pc Pq u64
309 When we unload a metaslab, we cache the size of the largest free chunk.
310 We use that cached size to determine whether or not to load a metaslab
311 for a given allocation.
312 As more frees accumulate in that metaslab while it's unloaded,
313 the cached max size becomes less and less accurate.
314 After a number of seconds controlled by this tunable,
315 we stop considering the cached max size and start
316 considering only the histogram instead.
318 .It Sy zfs_metaslab_mem_limit Ns = Ns Sy 25 Ns % Pq uint
319 When we are loading a new metaslab, we check the amount of memory being used
320 to store metaslab range trees.
321 If it is over a threshold, we attempt to unload the least recently used metaslab
322 to prevent the system from clogging all of its memory with range trees.
323 This tunable sets the percentage of total system memory that is the threshold.
325 .It Sy zfs_metaslab_try_hard_before_gang Ns = Ns Sy 0 Ns | Ns 1 Pq int
328 If unset, we will first try normal allocation.
330 If that fails then we will do a gang allocation.
332 If that fails then we will do a "try hard" gang allocation.
334 If that fails then we will have a multi-layer gang block.
339 If set, we will first try normal allocation.
341 If that fails then we will do a "try hard" allocation.
343 If that fails we will do a gang allocation.
345 If that fails we will do a "try hard" gang allocation.
347 If that fails then we will have a multi-layer gang block.
350 .It Sy zfs_metaslab_find_max_tries Ns = Ns Sy 100 Pq uint
351 When not trying hard, we only consider this number of the best metaslabs.
352 This improves performance, especially when there are many metaslabs per vdev
353 and the allocation can't actually be satisfied
354 (so we would otherwise iterate all metaslabs).
356 .It Sy zfs_vdev_default_ms_count Ns = Ns Sy 200 Pq uint
357 When a vdev is added, target this number of metaslabs per top-level vdev.
359 .It Sy zfs_vdev_default_ms_shift Ns = Ns Sy 29 Po 512 MiB Pc Pq uint
360 Default lower limit for metaslab size.
362 .It Sy zfs_vdev_max_ms_shift Ns = Ns Sy 34 Po 16 GiB Pc Pq uint
363 Default upper limit for metaslab size.
365 .It Sy zfs_vdev_max_auto_ashift Ns = Ns Sy 14 Pq uint
366 Maximum ashift used when optimizing for logical \[->] physical sector size on
369 May be increased up to
370 .Sy ASHIFT_MAX Po 16 Pc ,
371 but this may negatively impact pool space efficiency.
373 .It Sy zfs_vdev_min_auto_ashift Ns = Ns Sy ASHIFT_MIN Po 9 Pc Pq uint
374 Minimum ashift used when creating new top-level vdevs.
376 .It Sy zfs_vdev_min_ms_count Ns = Ns Sy 16 Pq uint
377 Minimum number of metaslabs to create in a top-level vdev.
379 .It Sy vdev_validate_skip Ns = Ns Sy 0 Ns | Ns 1 Pq int
380 Skip label validation steps during pool import.
381 Changing is not recommended unless you know what you're doing
382 and are recovering a damaged label.
384 .It Sy zfs_vdev_ms_count_limit Ns = Ns Sy 131072 Po 128k Pc Pq uint
385 Practical upper limit of total metaslabs per top-level vdev.
387 .It Sy metaslab_preload_enabled Ns = Ns Sy 1 Ns | Ns 0 Pq int
388 Enable metaslab group preloading.
390 .It Sy metaslab_lba_weighting_enabled Ns = Ns Sy 1 Ns | Ns 0 Pq int
391 Give more weight to metaslabs with lower LBAs,
392 assuming they have greater bandwidth,
393 as is typically the case on a modern constant angular velocity disk drive.
395 .It Sy metaslab_unload_delay Ns = Ns Sy 32 Pq uint
396 After a metaslab is used, we keep it loaded for this many TXGs, to attempt to
397 reduce unnecessary reloading.
398 Note that both this many TXGs and
399 .Sy metaslab_unload_delay_ms
400 milliseconds must pass before unloading will occur.
402 .It Sy metaslab_unload_delay_ms Ns = Ns Sy 600000 Ns ms Po 10 min Pc Pq uint
403 After a metaslab is used, we keep it loaded for this many milliseconds,
404 to attempt to reduce unnecessary reloading.
405 Note, that both this many milliseconds and
406 .Sy metaslab_unload_delay
407 TXGs must pass before unloading will occur.
409 .It Sy reference_history Ns = Ns Sy 3 Pq uint
410 Maximum reference holders being tracked when reference_tracking_enable is
413 .It Sy reference_tracking_enable Ns = Ns Sy 0 Ns | Ns 1 Pq int
414 Track reference holders to
416 objects (debug builds only).
418 .It Sy send_holes_without_birth_time Ns = Ns Sy 1 Ns | Ns 0 Pq int
421 optimization will not be used, and all holes will always be sent during a
423 This is useful if you suspect your datasets are affected by a bug in
426 .It Sy spa_config_path Ns = Ns Pa /etc/zfs/zpool.cache Pq charp
429 .It Sy spa_asize_inflation Ns = Ns Sy 24 Pq uint
430 Multiplication factor used to estimate actual disk consumption from the
431 size of data being written.
432 The default value is a worst case estimate,
433 but lower values may be valid for a given pool depending on its configuration.
434 Pool administrators who understand the factors involved
435 may wish to specify a more realistic inflation factor,
436 particularly if they operate close to quota or capacity limits.
438 .It Sy spa_load_print_vdev_tree Ns = Ns Sy 0 Ns | Ns 1 Pq int
439 Whether to print the vdev tree in the debugging message buffer during pool
442 .It Sy spa_load_verify_data Ns = Ns Sy 1 Ns | Ns 0 Pq int
443 Whether to traverse data blocks during an "extreme rewind"
447 An extreme rewind import normally performs a full traversal of all
448 blocks in the pool for verification.
449 If this parameter is unset, the traversal skips non-metadata blocks.
450 It can be toggled once the
451 import has started to stop or start the traversal of non-metadata blocks.
453 .It Sy spa_load_verify_metadata Ns = Ns Sy 1 Ns | Ns 0 Pq int
454 Whether to traverse blocks during an "extreme rewind"
458 An extreme rewind import normally performs a full traversal of all
459 blocks in the pool for verification.
460 If this parameter is unset, the traversal is not performed.
461 It can be toggled once the import has started to stop or start the traversal.
463 .It Sy spa_load_verify_shift Ns = Ns Sy 4 Po 1/16th Pc Pq uint
464 Sets the maximum number of bytes to consume during pool import to the log2
465 fraction of the target ARC size.
467 .It Sy spa_slop_shift Ns = Ns Sy 5 Po 1/32nd Pc Pq int
468 Normally, we don't allow the last
469 .Sy 3.2% Pq Sy 1/2^spa_slop_shift
470 of space in the pool to be consumed.
471 This ensures that we don't run the pool completely out of space,
472 due to unaccounted changes (e.g. to the MOS).
473 It also limits the worst-case time to allocate space.
474 If we have less than this amount of free space,
475 most ZPL operations (e.g. write, create) will return
478 .It Sy spa_upgrade_errlog_limit Ns = Ns Sy 0 Pq uint
479 Limits the number of on-disk error log entries that will be converted to the
480 new format when enabling the
483 The default is to convert all log entries.
485 .It Sy vdev_removal_max_span Ns = Ns Sy 32768 Ns B Po 32 KiB Pc Pq uint
486 During top-level vdev removal, chunks of data are copied from the vdev
487 which may include free space in order to trade bandwidth for IOPS.
488 This parameter determines the maximum span of free space, in bytes,
489 which will be included as "unnecessary" data in a chunk of copied data.
491 The default value here was chosen to align with
492 .Sy zfs_vdev_read_gap_limit ,
493 which is a similar concept when doing
494 regular reads (but there's no reason it has to be the same).
496 .It Sy vdev_file_logical_ashift Ns = Ns Sy 9 Po 512 B Pc Pq u64
497 Logical ashift for file-based devices.
499 .It Sy vdev_file_physical_ashift Ns = Ns Sy 9 Po 512 B Pc Pq u64
500 Physical ashift for file-based devices.
502 .It Sy zap_iterate_prefetch Ns = Ns Sy 1 Ns | Ns 0 Pq int
503 If set, when we start iterating over a ZAP object,
504 prefetch the entire object (all leaf blocks).
505 However, this is limited by
506 .Sy dmu_prefetch_max .
508 .It Sy zap_micro_max_size Ns = Ns Sy 131072 Ns B Po 128 KiB Pc Pq int
509 Maximum micro ZAP size.
510 A micro ZAP is upgraded to a fat ZAP, once it grows beyond the specified size.
512 .It Sy zfetch_array_rd_sz Ns = Ns Sy 1048576 Ns B Po 1 MiB Pc Pq u64
513 If prefetching is enabled, disable prefetching for reads larger than this size.
515 .It Sy zfetch_min_distance Ns = Ns Sy 4194304 Ns B Po 4 MiB Pc Pq uint
516 Min bytes to prefetch per stream.
517 Prefetch distance starts from the demand access size and quickly grows to
518 this value, doubling on each hit.
519 After that it may grow further by 1/8 per hit, but only if some prefetch
520 since last time haven't completed in time to satisfy demand request, i.e.
521 prefetch depth didn't cover the read latency or the pool got saturated.
523 .It Sy zfetch_max_distance Ns = Ns Sy 67108864 Ns B Po 64 MiB Pc Pq uint
524 Max bytes to prefetch per stream.
526 .It Sy zfetch_max_idistance Ns = Ns Sy 67108864 Ns B Po 64 MiB Pc Pq uint
527 Max bytes to prefetch indirects for per stream.
529 .It Sy zfetch_max_streams Ns = Ns Sy 8 Pq uint
530 Max number of streams per zfetch (prefetch streams per file).
532 .It Sy zfetch_min_sec_reap Ns = Ns Sy 1 Pq uint
533 Min time before inactive prefetch stream can be reclaimed
535 .It Sy zfetch_max_sec_reap Ns = Ns Sy 2 Pq uint
536 Max time before inactive prefetch stream can be deleted
538 .It Sy zfs_abd_scatter_enabled Ns = Ns Sy 1 Ns | Ns 0 Pq int
539 Enables ARC from using scatter/gather lists and forces all allocations to be
540 linear in kernel memory.
541 Disabling can improve performance in some code paths
542 at the expense of fragmented kernel memory.
544 .It Sy zfs_abd_scatter_max_order Ns = Ns Sy MAX_ORDER\-1 Pq uint
545 Maximum number of consecutive memory pages allocated in a single block for
546 scatter/gather lists.
550 depends on kernel configuration.
552 .It Sy zfs_abd_scatter_min_size Ns = Ns Sy 1536 Ns B Po 1.5 KiB Pc Pq uint
553 This is the minimum allocation size that will use scatter (page-based) ABDs.
554 Smaller allocations will use linear ABDs.
556 .It Sy zfs_arc_dnode_limit Ns = Ns Sy 0 Ns B Pq u64
557 When the number of bytes consumed by dnodes in the ARC exceeds this number of
558 bytes, try to unpin some of it in response to demand for non-metadata.
559 This value acts as a ceiling to the amount of dnode metadata, and defaults to
561 which indicates that a percent which is based on
562 .Sy zfs_arc_dnode_limit_percent
563 of the ARC meta buffers that may be used for dnodes.
564 .It Sy zfs_arc_dnode_limit_percent Ns = Ns Sy 10 Ns % Pq u64
565 Percentage that can be consumed by dnodes of ARC meta buffers.
568 .Sy zfs_arc_dnode_limit ,
569 which serves a similar purpose but has a higher priority if nonzero.
571 .It Sy zfs_arc_dnode_reduce_percent Ns = Ns Sy 10 Ns % Pq u64
572 Percentage of ARC dnodes to try to scan in response to demand for non-metadata
573 when the number of bytes consumed by dnodes exceeds
574 .Sy zfs_arc_dnode_limit .
576 .It Sy zfs_arc_average_blocksize Ns = Ns Sy 8192 Ns B Po 8 KiB Pc Pq uint
577 The ARC's buffer hash table is sized based on the assumption of an average
578 block size of this value.
579 This works out to roughly 1 MiB of hash table per 1 GiB of physical memory
580 with 8-byte pointers.
581 For configurations with a known larger average block size,
582 this value can be increased to reduce the memory footprint.
584 .It Sy zfs_arc_eviction_pct Ns = Ns Sy 200 Ns % Pq uint
586 .Fn arc_is_overflowing ,
587 .Fn arc_get_data_impl
588 waits for this percent of the requested amount of data to be evicted.
589 For example, by default, for every
593 of it may be "reused" by a new allocation.
596 it ensures that progress is made towards getting
597 .Sy arc_size No under Sy arc_c .
598 Since this is finite, it ensures that allocations can still happen,
599 even during the potentially long time that
600 .Sy arc_size No is more than Sy arc_c .
602 .It Sy zfs_arc_evict_batch_limit Ns = Ns Sy 10 Pq uint
603 Number ARC headers to evict per sub-list before proceeding to another sub-list.
604 This batch-style operation prevents entire sub-lists from being evicted at once
605 but comes at a cost of additional unlocking and locking.
607 .It Sy zfs_arc_grow_retry Ns = Ns Sy 0 Ns s Pq uint
608 If set to a non zero value, it will replace the
610 value with this value.
613 .No value Pq default Sy 5 Ns s
614 is the number of seconds the ARC will wait before
615 trying to resume growth after a memory pressure event.
617 .It Sy zfs_arc_lotsfree_percent Ns = Ns Sy 10 Ns % Pq int
618 Throttle I/O when free system memory drops below this percentage of total
620 Setting this value to
622 will disable the throttle.
624 .It Sy zfs_arc_max Ns = Ns Sy 0 Ns B Pq u64
625 Max size of ARC in bytes.
628 then the max size of ARC is determined by the amount of system memory installed.
629 Under Linux, half of system memory will be used as the limit.
633 .Sy all_system_memory No \- Sy 1 GiB
635 .Sy 5/8 No \(mu Sy all_system_memory
636 will be used as the limit.
637 This value must be at least
638 .Sy 67108864 Ns B Pq 64 MiB .
640 This value can be changed dynamically, with some caveats.
641 It cannot be set back to
643 while running, and reducing it below the current ARC size will not cause
644 the ARC to shrink without memory pressure to induce shrinking.
646 .It Sy zfs_arc_meta_balance Ns = Ns Sy 500 Pq uint
647 Balance between metadata and data on ghost hits.
648 Values above 100 increase metadata caching by proportionally reducing effect
649 of ghost data hits on target data/metadata rate.
651 .It Sy zfs_arc_min Ns = Ns Sy 0 Ns B Pq u64
652 Min size of ARC in bytes.
653 .No If set to Sy 0 , arc_c_min
654 will default to consuming the larger of
657 .Sy all_system_memory No / Sy 32 .
659 .It Sy zfs_arc_min_prefetch_ms Ns = Ns Sy 0 Ns ms Ns Po Ns ≡ Ns 1s Pc Pq uint
660 Minimum time prefetched blocks are locked in the ARC.
662 .It Sy zfs_arc_min_prescient_prefetch_ms Ns = Ns Sy 0 Ns ms Ns Po Ns ≡ Ns 6s Pc Pq uint
663 Minimum time "prescient prefetched" blocks are locked in the ARC.
664 These blocks are meant to be prefetched fairly aggressively ahead of
665 the code that may use them.
667 .It Sy zfs_arc_prune_task_threads Ns = Ns Sy 1 Pq int
668 Number of arc_prune threads.
670 does not need more than one.
671 Linux may theoretically use one per mount point up to number of CPUs,
672 but that was not proven to be useful.
674 .It Sy zfs_max_missing_tvds Ns = Ns Sy 0 Pq int
675 Number of missing top-level vdevs which will be allowed during
676 pool import (only in read-only mode).
678 .It Sy zfs_max_nvlist_src_size Ns = Sy 0 Pq u64
679 Maximum size in bytes allowed to be passed as
680 .Sy zc_nvlist_src_size
683 This prevents a user from causing the kernel to allocate
684 an excessive amount of memory.
685 When the limit is exceeded, the ioctl fails with
687 and a description of the error is sent to the
690 This parameter should not need to be touched under normal circumstances.
693 equivalent to a quarter of the user-wired memory limit under
696 .Sy 134217728 Ns B Pq 128 MiB
699 .It Sy zfs_multilist_num_sublists Ns = Ns Sy 0 Pq uint
700 To allow more fine-grained locking, each ARC state contains a series
701 of lists for both data and metadata objects.
702 Locking is performed at the level of these "sub-lists".
703 This parameters controls the number of sub-lists per ARC state,
704 and also applies to other uses of the multilist data structure.
708 equivalent to the greater of the number of online CPUs and
711 .It Sy zfs_arc_overflow_shift Ns = Ns Sy 8 Pq int
712 The ARC size is considered to be overflowing if it exceeds the current
715 by thresholds determined by this parameter.
717 .Sy ( arc_c No >> Sy zfs_arc_overflow_shift ) No / Sy 2
718 starts ARC reclamation process.
719 If that appears insufficient, exceeding by
720 .Sy ( arc_c No >> Sy zfs_arc_overflow_shift ) No \(mu Sy 1.5
721 blocks new buffer allocation until the reclaim thread catches up.
722 Started reclamation process continues till ARC size returns below the
727 causes the ARC to start reclamation if it exceeds the target size by
729 of the target size, and block allocations by
732 .It Sy zfs_arc_shrink_shift Ns = Ns Sy 0 Pq uint
733 If nonzero, this will update
734 .Sy arc_shrink_shift Pq default Sy 7
737 .It Sy zfs_arc_pc_percent Ns = Ns Sy 0 Ns % Po off Pc Pq uint
738 Percent of pagecache to reclaim ARC to.
740 This tunable allows the ZFS ARC to play more nicely
741 with the kernel's LRU pagecache.
742 It can guarantee that the ARC size won't collapse under scanning
743 pressure on the pagecache, yet still allows the ARC to be reclaimed down to
746 This value is specified as percent of pagecache size (as measured by
747 .Sy NR_FILE_PAGES ) ,
748 where that percent may exceed
751 only operates during memory pressure/reclaim.
753 .It Sy zfs_arc_shrinker_limit Ns = Ns Sy 10000 Pq int
754 This is a limit on how many pages the ARC shrinker makes available for
755 eviction in response to one page allocation attempt.
756 Note that in practice, the kernel's shrinker can ask us to evict
757 up to about four times this for one allocation attempt.
760 .Sy 10000 Pq in practice, Em 160 MiB No per allocation attempt with 4 KiB pages
761 limits the amount of time spent attempting to reclaim ARC memory to
762 less than 100 ms per allocation attempt,
763 even with a small average compressed block size of ~8 KiB.
765 The parameter can be set to 0 (zero) to disable the limit,
766 and only applies on Linux.
768 .It Sy zfs_arc_sys_free Ns = Ns Sy 0 Ns B Pq u64
769 The target number of bytes the ARC should leave as free memory on the system.
770 If zero, equivalent to the bigger of
771 .Sy 512 KiB No and Sy all_system_memory/64 .
773 .It Sy zfs_autoimport_disable Ns = Ns Sy 1 Ns | Ns 0 Pq int
774 Disable pool import at module load by ignoring the cache file
775 .Pq Sy spa_config_path .
777 .It Sy zfs_checksum_events_per_second Ns = Ns Sy 20 Ns /s Pq uint
778 Rate limit checksum events to this many per second.
779 Note that this should not be set below the ZED thresholds
780 (currently 10 checksums over 10 seconds)
781 or else the daemon may not trigger any action.
783 .It Sy zfs_commit_timeout_pct Ns = Ns Sy 5 Ns % Pq uint
784 This controls the amount of time that a ZIL block (lwb) will remain "open"
785 when it isn't "full", and it has a thread waiting for it to be committed to
787 The timeout is scaled based on a percentage of the last lwb
788 latency to avoid significantly impacting the latency of each individual
789 transaction record (itx).
791 .It Sy zfs_condense_indirect_commit_entry_delay_ms Ns = Ns Sy 0 Ns ms Pq int
792 Vdev indirection layer (used for device removal) sleeps for this many
793 milliseconds during mapping generation.
794 Intended for use with the test suite to throttle vdev removal speed.
796 .It Sy zfs_condense_indirect_obsolete_pct Ns = Ns Sy 25 Ns % Pq uint
797 Minimum percent of obsolete bytes in vdev mapping required to attempt to
799 .Pq see Sy zfs_condense_indirect_vdevs_enable .
800 Intended for use with the test suite
801 to facilitate triggering condensing as needed.
803 .It Sy zfs_condense_indirect_vdevs_enable Ns = Ns Sy 1 Ns | Ns 0 Pq int
804 Enable condensing indirect vdev mappings.
805 When set, attempt to condense indirect vdev mappings
806 if the mapping uses more than
807 .Sy zfs_condense_min_mapping_bytes
808 bytes of memory and if the obsolete space map object uses more than
809 .Sy zfs_condense_max_obsolete_bytes
811 The condensing process is an attempt to save memory by removing obsolete
814 .It Sy zfs_condense_max_obsolete_bytes Ns = Ns Sy 1073741824 Ns B Po 1 GiB Pc Pq u64
815 Only attempt to condense indirect vdev mappings if the on-disk size
816 of the obsolete space map object is greater than this number of bytes
817 .Pq see Sy zfs_condense_indirect_vdevs_enable .
819 .It Sy zfs_condense_min_mapping_bytes Ns = Ns Sy 131072 Ns B Po 128 KiB Pc Pq u64
820 Minimum size vdev mapping to attempt to condense
821 .Pq see Sy zfs_condense_indirect_vdevs_enable .
823 .It Sy zfs_dbgmsg_enable Ns = Ns Sy 1 Ns | Ns 0 Pq int
824 Internally ZFS keeps a small log to facilitate debugging.
825 The log is enabled by default, and can be disabled by unsetting this option.
826 The contents of the log can be accessed by reading
827 .Pa /proc/spl/kstat/zfs/dbgmsg .
830 to the file clears the log.
832 This setting does not influence debug prints due to
835 .It Sy zfs_dbgmsg_maxsize Ns = Ns Sy 4194304 Ns B Po 4 MiB Pc Pq uint
836 Maximum size of the internal ZFS debug log.
838 .It Sy zfs_dbuf_state_index Ns = Ns Sy 0 Pq int
839 Historically used for controlling what reporting was available under
840 .Pa /proc/spl/kstat/zfs .
843 .It Sy zfs_deadman_enabled Ns = Ns Sy 1 Ns | Ns 0 Pq int
844 When a pool sync operation takes longer than
845 .Sy zfs_deadman_synctime_ms ,
846 or when an individual I/O operation takes longer than
847 .Sy zfs_deadman_ziotime_ms ,
848 then the operation is considered to be "hung".
850 .Sy zfs_deadman_enabled
851 is set, then the deadman behavior is invoked as described by
852 .Sy zfs_deadman_failmode .
853 By default, the deadman is enabled and set to
855 which results in "hung" I/O operations only being logged.
856 The deadman is automatically disabled when a pool gets suspended.
858 .It Sy zfs_deadman_failmode Ns = Ns Sy wait Pq charp
859 Controls the failure behavior when the deadman detects a "hung" I/O operation.
861 .Bl -tag -compact -offset 4n -width "continue"
863 Wait for a "hung" operation to complete.
864 For each "hung" operation a "deadman" event will be posted
865 describing that operation.
867 Attempt to recover from a "hung" operation by re-dispatching it
868 to the I/O pipeline if possible.
871 This can be used to facilitate automatic fail-over
872 to a properly configured fail-over partner.
875 .It Sy zfs_deadman_checktime_ms Ns = Ns Sy 60000 Ns ms Po 1 min Pc Pq u64
876 Check time in milliseconds.
877 This defines the frequency at which we check for hung I/O requests
878 and potentially invoke the
879 .Sy zfs_deadman_failmode
882 .It Sy zfs_deadman_synctime_ms Ns = Ns Sy 600000 Ns ms Po 10 min Pc Pq u64
883 Interval in milliseconds after which the deadman is triggered and also
884 the interval after which a pool sync operation is considered to be "hung".
885 Once this limit is exceeded the deadman will be invoked every
886 .Sy zfs_deadman_checktime_ms
887 milliseconds until the pool sync completes.
889 .It Sy zfs_deadman_ziotime_ms Ns = Ns Sy 300000 Ns ms Po 5 min Pc Pq u64
890 Interval in milliseconds after which the deadman is triggered and an
891 individual I/O operation is considered to be "hung".
892 As long as the operation remains "hung",
893 the deadman will be invoked every
894 .Sy zfs_deadman_checktime_ms
895 milliseconds until the operation completes.
897 .It Sy zfs_dedup_prefetch Ns = Ns Sy 0 Ns | Ns 1 Pq int
898 Enable prefetching dedup-ed blocks which are going to be freed.
900 .It Sy zfs_delay_min_dirty_percent Ns = Ns Sy 60 Ns % Pq uint
901 Start to delay each transaction once there is this amount of dirty data,
902 expressed as a percentage of
903 .Sy zfs_dirty_data_max .
904 This value should be at least
905 .Sy zfs_vdev_async_write_active_max_dirty_percent .
906 .No See Sx ZFS TRANSACTION DELAY .
908 .It Sy zfs_delay_scale Ns = Ns Sy 500000 Pq int
909 This controls how quickly the transaction delay approaches infinity.
910 Larger values cause longer delays for a given amount of dirty data.
912 For the smoothest delay, this value should be about 1 billion divided
913 by the maximum number of operations per second.
914 This will smoothly handle between ten times and a tenth of this number.
915 .No See Sx ZFS TRANSACTION DELAY .
917 .Sy zfs_delay_scale No \(mu Sy zfs_dirty_data_max Em must No be smaller than Sy 2^64 .
919 .It Sy zfs_disable_ivset_guid_check Ns = Ns Sy 0 Ns | Ns 1 Pq int
920 Disables requirement for IVset GUIDs to be present and match when doing a raw
921 receive of encrypted datasets.
922 Intended for users whose pools were created with
923 OpenZFS pre-release versions and now have compatibility issues.
925 .It Sy zfs_key_max_salt_uses Ns = Ns Sy 400000000 Po 4*10^8 Pc Pq ulong
926 Maximum number of uses of a single salt value before generating a new one for
928 The default value is also the maximum.
930 .It Sy zfs_object_mutex_size Ns = Ns Sy 64 Pq uint
931 Size of the znode hashtable used for holds.
933 Due to the need to hold locks on objects that may not exist yet, kernel mutexes
934 are not created per-object and instead a hashtable is used where collisions
935 will result in objects waiting when there is not actually contention on the
938 .It Sy zfs_slow_io_events_per_second Ns = Ns Sy 20 Ns /s Pq int
939 Rate limit delay and deadman zevents (which report slow I/O operations) to this
943 .It Sy zfs_unflushed_max_mem_amt Ns = Ns Sy 1073741824 Ns B Po 1 GiB Pc Pq u64
944 Upper-bound limit for unflushed metadata changes to be held by the
945 log spacemap in memory, in bytes.
947 .It Sy zfs_unflushed_max_mem_ppm Ns = Ns Sy 1000 Ns ppm Po 0.1% Pc Pq u64
948 Part of overall system memory that ZFS allows to be used
949 for unflushed metadata changes by the log spacemap, in millionths.
951 .It Sy zfs_unflushed_log_block_max Ns = Ns Sy 131072 Po 128k Pc Pq u64
952 Describes the maximum number of log spacemap blocks allowed for each pool.
953 The default value means that the space in all the log spacemaps
954 can add up to no more than
958 of logical space before compression and ditto blocks,
959 assuming that blocksize is
962 This tunable is important because it involves a trade-off between import
963 time after an unclean export and the frequency of flushing metaslabs.
964 The higher this number is, the more log blocks we allow when the pool is
965 active which means that we flush metaslabs less often and thus decrease
966 the number of I/O operations for spacemap updates per TXG.
967 At the same time though, that means that in the event of an unclean export,
968 there will be more log spacemap blocks for us to read, inducing overhead
969 in the import time of the pool.
970 The lower the number, the amount of flushing increases, destroying log
971 blocks quicker as they become obsolete faster, which leaves less blocks
972 to be read during import time after a crash.
974 Each log spacemap block existing during pool import leads to approximately
975 one extra logical I/O issued.
976 This is the reason why this tunable is exposed in terms of blocks rather
979 .It Sy zfs_unflushed_log_block_min Ns = Ns Sy 1000 Pq u64
980 If the number of metaslabs is small and our incoming rate is high,
981 we could get into a situation that we are flushing all our metaslabs every TXG.
982 Thus we always allow at least this many log blocks.
984 .It Sy zfs_unflushed_log_block_pct Ns = Ns Sy 400 Ns % Pq u64
985 Tunable used to determine the number of blocks that can be used for
986 the spacemap log, expressed as a percentage of the total number of
987 unflushed metaslabs in the pool.
989 .It Sy zfs_unflushed_log_txg_max Ns = Ns Sy 1000 Pq u64
990 Tunable limiting maximum time in TXGs any metaslab may remain unflushed.
991 It effectively limits maximum number of unflushed per-TXG spacemap logs
992 that need to be read after unclean pool export.
994 .It Sy zfs_unlink_suspend_progress Ns = Ns Sy 0 Ns | Ns 1 Pq uint
995 When enabled, files will not be asynchronously removed from the list of pending
996 unlinks and the space they consume will be leaked.
997 Once this option has been disabled and the dataset is remounted,
998 the pending unlinks will be processed and the freed space returned to the pool.
999 This option is used by the test suite.
1001 .It Sy zfs_delete_blocks Ns = Ns Sy 20480 Pq ulong
1002 This is the used to define a large file for the purposes of deletion.
1003 Files containing more than
1004 .Sy zfs_delete_blocks
1005 will be deleted asynchronously, while smaller files are deleted synchronously.
1006 Decreasing this value will reduce the time spent in an
1008 system call, at the expense of a longer delay before the freed space is
1010 This only applies on Linux.
1012 .It Sy zfs_dirty_data_max Ns = Pq int
1013 Determines the dirty space limit in bytes.
1014 Once this limit is exceeded, new writes are halted until space frees up.
1015 This parameter takes precedence over
1016 .Sy zfs_dirty_data_max_percent .
1017 .No See Sx ZFS TRANSACTION DELAY .
1020 .Sy physical_ram/10 ,
1022 .Sy zfs_dirty_data_max_max .
1024 .It Sy zfs_dirty_data_max_max Ns = Pq int
1025 Maximum allowable value of
1026 .Sy zfs_dirty_data_max ,
1028 This limit is only enforced at module load time, and will be ignored if
1029 .Sy zfs_dirty_data_max
1031 This parameter takes precedence over
1032 .Sy zfs_dirty_data_max_max_percent .
1033 .No See Sx ZFS TRANSACTION DELAY .
1036 .Sy min(physical_ram/4, 4GiB) ,
1038 .Sy min(physical_ram/4, 1GiB)
1041 .It Sy zfs_dirty_data_max_max_percent Ns = Ns Sy 25 Ns % Pq uint
1042 Maximum allowable value of
1043 .Sy zfs_dirty_data_max ,
1044 expressed as a percentage of physical RAM.
1045 This limit is only enforced at module load time, and will be ignored if
1046 .Sy zfs_dirty_data_max
1049 .Sy zfs_dirty_data_max_max
1050 takes precedence over this one.
1051 .No See Sx ZFS TRANSACTION DELAY .
1053 .It Sy zfs_dirty_data_max_percent Ns = Ns Sy 10 Ns % Pq uint
1054 Determines the dirty space limit, expressed as a percentage of all memory.
1055 Once this limit is exceeded, new writes are halted until space frees up.
1057 .Sy zfs_dirty_data_max
1058 takes precedence over this one.
1059 .No See Sx ZFS TRANSACTION DELAY .
1062 .Sy zfs_dirty_data_max_max .
1064 .It Sy zfs_dirty_data_sync_percent Ns = Ns Sy 20 Ns % Pq uint
1065 Start syncing out a transaction group if there's at least this much dirty data
1066 .Pq as a percentage of Sy zfs_dirty_data_max .
1067 This should be less than
1068 .Sy zfs_vdev_async_write_active_min_dirty_percent .
1070 .It Sy zfs_wrlog_data_max Ns = Pq int
1071 The upper limit of write-transaction zil log data size in bytes.
1072 Write operations are throttled when approaching the limit until log data is
1073 cleared out after transaction group sync.
1074 Because of some overhead, it should be set at least 2 times the size of
1075 .Sy zfs_dirty_data_max
1076 .No to prevent harming normal write throughput .
1077 It also should be smaller than the size of the slog device if slog is present.
1080 .Sy zfs_dirty_data_max*2
1082 .It Sy zfs_fallocate_reserve_percent Ns = Ns Sy 110 Ns % Pq uint
1083 Since ZFS is a copy-on-write filesystem with snapshots, blocks cannot be
1084 preallocated for a file in order to guarantee that later writes will not
1088 space preallocation only checks that sufficient space is currently available
1089 in the pool or the user's project quota allocation,
1090 and then creates a sparse file of the requested size.
1091 The requested space is multiplied by
1092 .Sy zfs_fallocate_reserve_percent
1093 to allow additional space for indirect blocks and other internal metadata.
1096 disables support for
1098 and causes it to return
1101 .It Sy zfs_fletcher_4_impl Ns = Ns Sy fastest Pq string
1102 Select a fletcher 4 implementation.
1104 Supported selectors are:
1105 .Sy fastest , scalar , sse2 , ssse3 , avx2 , avx512f , avx512bw ,
1106 .No and Sy aarch64_neon .
1108 .Sy fastest No and Sy scalar
1109 require instruction set extensions to be available,
1110 and will only appear if ZFS detects that they are present at runtime.
1111 If multiple implementations of fletcher 4 are available, the
1113 will be chosen using a micro benchmark.
1116 results in the original CPU-based calculation being used.
1117 Selecting any option other than
1118 .Sy fastest No or Sy scalar
1119 results in vector instructions
1120 from the respective CPU instruction set being used.
1122 .It Sy zfs_blake3_impl Ns = Ns Sy fastest Pq string
1123 Select a BLAKE3 implementation.
1125 Supported selectors are:
1126 .Sy cycle , fastest , generic , sse2 , sse41 , avx2 , avx512 .
1128 .Sy cycle , fastest No and Sy generic
1129 require instruction set extensions to be available,
1130 and will only appear if ZFS detects that they are present at runtime.
1131 If multiple implementations of BLAKE3 are available, the
1132 .Sy fastest will be chosen using a micro benchmark. You can see the
1133 benchmark results by reading this kstat file:
1134 .Pa /proc/spl/kstat/zfs/chksum_bench .
1136 .It Sy zfs_free_bpobj_enabled Ns = Ns Sy 1 Ns | Ns 0 Pq int
1137 Enable/disable the processing of the free_bpobj object.
1139 .It Sy zfs_async_block_max_blocks Ns = Ns Sy UINT64_MAX Po unlimited Pc Pq u64
1140 Maximum number of blocks freed in a single TXG.
1142 .It Sy zfs_max_async_dedup_frees Ns = Ns Sy 100000 Po 10^5 Pc Pq u64
1143 Maximum number of dedup blocks freed in a single TXG.
1145 .It Sy zfs_vdev_async_read_max_active Ns = Ns Sy 3 Pq uint
1146 Maximum asynchronous read I/O operations active to each device.
1147 .No See Sx ZFS I/O SCHEDULER .
1149 .It Sy zfs_vdev_async_read_min_active Ns = Ns Sy 1 Pq uint
1150 Minimum asynchronous read I/O operation active to each device.
1151 .No See Sx ZFS I/O SCHEDULER .
1153 .It Sy zfs_vdev_async_write_active_max_dirty_percent Ns = Ns Sy 60 Ns % Pq uint
1154 When the pool has more than this much dirty data, use
1155 .Sy zfs_vdev_async_write_max_active
1156 to limit active async writes.
1157 If the dirty data is between the minimum and maximum,
1158 the active I/O limit is linearly interpolated.
1159 .No See Sx ZFS I/O SCHEDULER .
1161 .It Sy zfs_vdev_async_write_active_min_dirty_percent Ns = Ns Sy 30 Ns % Pq uint
1162 When the pool has less than this much dirty data, use
1163 .Sy zfs_vdev_async_write_min_active
1164 to limit active async writes.
1165 If the dirty data is between the minimum and maximum,
1166 the active I/O limit is linearly
1168 .No See Sx ZFS I/O SCHEDULER .
1170 .It Sy zfs_vdev_async_write_max_active Ns = Ns Sy 10 Pq uint
1171 Maximum asynchronous write I/O operations active to each device.
1172 .No See Sx ZFS I/O SCHEDULER .
1174 .It Sy zfs_vdev_async_write_min_active Ns = Ns Sy 2 Pq uint
1175 Minimum asynchronous write I/O operations active to each device.
1176 .No See Sx ZFS I/O SCHEDULER .
1178 Lower values are associated with better latency on rotational media but poorer
1179 resilver performance.
1180 The default value of
1182 was chosen as a compromise.
1185 has been shown to improve resilver performance further at a cost of
1186 further increasing latency.
1188 .It Sy zfs_vdev_initializing_max_active Ns = Ns Sy 1 Pq uint
1189 Maximum initializing I/O operations active to each device.
1190 .No See Sx ZFS I/O SCHEDULER .
1192 .It Sy zfs_vdev_initializing_min_active Ns = Ns Sy 1 Pq uint
1193 Minimum initializing I/O operations active to each device.
1194 .No See Sx ZFS I/O SCHEDULER .
1196 .It Sy zfs_vdev_max_active Ns = Ns Sy 1000 Pq uint
1197 The maximum number of I/O operations active to each device.
1198 Ideally, this will be at least the sum of each queue's
1200 .No See Sx ZFS I/O SCHEDULER .
1202 .It Sy zfs_vdev_open_timeout_ms Ns = Ns Sy 1000 Pq uint
1203 Timeout value to wait before determining a device is missing
1205 This is helpful for transient missing paths due
1206 to links being briefly removed and recreated in response to
1209 .It Sy zfs_vdev_rebuild_max_active Ns = Ns Sy 3 Pq uint
1210 Maximum sequential resilver I/O operations active to each device.
1211 .No See Sx ZFS I/O SCHEDULER .
1213 .It Sy zfs_vdev_rebuild_min_active Ns = Ns Sy 1 Pq uint
1214 Minimum sequential resilver I/O operations active to each device.
1215 .No See Sx ZFS I/O SCHEDULER .
1217 .It Sy zfs_vdev_removal_max_active Ns = Ns Sy 2 Pq uint
1218 Maximum removal I/O operations active to each device.
1219 .No See Sx ZFS I/O SCHEDULER .
1221 .It Sy zfs_vdev_removal_min_active Ns = Ns Sy 1 Pq uint
1222 Minimum removal I/O operations active to each device.
1223 .No See Sx ZFS I/O SCHEDULER .
1225 .It Sy zfs_vdev_scrub_max_active Ns = Ns Sy 2 Pq uint
1226 Maximum scrub I/O operations active to each device.
1227 .No See Sx ZFS I/O SCHEDULER .
1229 .It Sy zfs_vdev_scrub_min_active Ns = Ns Sy 1 Pq uint
1230 Minimum scrub I/O operations active to each device.
1231 .No See Sx ZFS I/O SCHEDULER .
1233 .It Sy zfs_vdev_sync_read_max_active Ns = Ns Sy 10 Pq uint
1234 Maximum synchronous read I/O operations active to each device.
1235 .No See Sx ZFS I/O SCHEDULER .
1237 .It Sy zfs_vdev_sync_read_min_active Ns = Ns Sy 10 Pq uint
1238 Minimum synchronous read I/O operations active to each device.
1239 .No See Sx ZFS I/O SCHEDULER .
1241 .It Sy zfs_vdev_sync_write_max_active Ns = Ns Sy 10 Pq uint
1242 Maximum synchronous write I/O operations active to each device.
1243 .No See Sx ZFS I/O SCHEDULER .
1245 .It Sy zfs_vdev_sync_write_min_active Ns = Ns Sy 10 Pq uint
1246 Minimum synchronous write I/O operations active to each device.
1247 .No See Sx ZFS I/O SCHEDULER .
1249 .It Sy zfs_vdev_trim_max_active Ns = Ns Sy 2 Pq uint
1250 Maximum trim/discard I/O operations active to each device.
1251 .No See Sx ZFS I/O SCHEDULER .
1253 .It Sy zfs_vdev_trim_min_active Ns = Ns Sy 1 Pq uint
1254 Minimum trim/discard I/O operations active to each device.
1255 .No See Sx ZFS I/O SCHEDULER .
1257 .It Sy zfs_vdev_nia_delay Ns = Ns Sy 5 Pq uint
1258 For non-interactive I/O (scrub, resilver, removal, initialize and rebuild),
1259 the number of concurrently-active I/O operations is limited to
1260 .Sy zfs_*_min_active ,
1261 unless the vdev is "idle".
1262 When there are no interactive I/O operations active (synchronous or otherwise),
1264 .Sy zfs_vdev_nia_delay
1265 operations have completed since the last interactive operation,
1266 then the vdev is considered to be "idle",
1267 and the number of concurrently-active non-interactive operations is increased to
1268 .Sy zfs_*_max_active .
1269 .No See Sx ZFS I/O SCHEDULER .
1271 .It Sy zfs_vdev_nia_credit Ns = Ns Sy 5 Pq uint
1272 Some HDDs tend to prioritize sequential I/O so strongly, that concurrent
1273 random I/O latency reaches several seconds.
1274 On some HDDs this happens even if sequential I/O operations
1275 are submitted one at a time, and so setting
1276 .Sy zfs_*_max_active Ns = Sy 1
1278 To prevent non-interactive I/O, like scrub,
1279 from monopolizing the device, no more than
1280 .Sy zfs_vdev_nia_credit operations can be sent
1281 while there are outstanding incomplete interactive operations.
1282 This enforced wait ensures the HDD services the interactive I/O
1283 within a reasonable amount of time.
1284 .No See Sx ZFS I/O SCHEDULER .
1286 .It Sy zfs_vdev_queue_depth_pct Ns = Ns Sy 1000 Ns % Pq uint
1287 Maximum number of queued allocations per top-level vdev expressed as
1289 .Sy zfs_vdev_async_write_max_active ,
1290 which allows the system to detect devices that are more capable
1291 of handling allocations and to allocate more blocks to those devices.
1292 This allows for dynamic allocation distribution when devices are imbalanced,
1293 as fuller devices will tend to be slower than empty devices.
1296 .Sy zio_dva_throttle_enabled .
1298 .It Sy zfs_vdev_def_queue_depth Ns = Ns Sy 32 Pq uint
1299 Default queue depth for each vdev IO allocator.
1300 Higher values allow for better coalescing of sequential writes before sending
1301 them to the disk, but can increase transaction commit times.
1303 .It Sy zfs_vdev_failfast_mask Ns = Ns Sy 1 Pq uint
1304 Defines if the driver should retire on a given error type.
1305 The following options may be bitwise-ored together:
1309 Value Name Description
1311 1 Device No driver retries on device errors
1312 2 Transport No driver retries on transport errors.
1313 4 Driver No driver retries on driver errors.
1316 .It Sy zfs_expire_snapshot Ns = Ns Sy 300 Ns s Pq int
1317 Time before expiring
1320 .It Sy zfs_admin_snapshot Ns = Ns Sy 0 Ns | Ns 1 Pq int
1321 Allow the creation, removal, or renaming of entries in the
1323 directory to cause the creation, destruction, or renaming of snapshots.
1324 When enabled, this functionality works both locally and over NFS exports
1329 .It Sy zfs_flags Ns = Ns Sy 0 Pq int
1330 Set additional debugging flags.
1331 The following flags may be bitwise-ored together:
1335 Value Name Description
1337 1 ZFS_DEBUG_DPRINTF Enable dprintf entries in the debug log.
1338 * 2 ZFS_DEBUG_DBUF_VERIFY Enable extra dbuf verifications.
1339 * 4 ZFS_DEBUG_DNODE_VERIFY Enable extra dnode verifications.
1340 8 ZFS_DEBUG_SNAPNAMES Enable snapshot name verification.
1341 * 16 ZFS_DEBUG_MODIFY Check for illegally modified ARC buffers.
1342 64 ZFS_DEBUG_ZIO_FREE Enable verification of block frees.
1343 128 ZFS_DEBUG_HISTOGRAM_VERIFY Enable extra spacemap histogram verifications.
1344 256 ZFS_DEBUG_METASLAB_VERIFY Verify space accounting on disk matches in-memory \fBrange_trees\fP.
1345 512 ZFS_DEBUG_SET_ERROR Enable \fBSET_ERROR\fP and dprintf entries in the debug log.
1346 1024 ZFS_DEBUG_INDIRECT_REMAP Verify split blocks created by device removal.
1347 2048 ZFS_DEBUG_TRIM Verify TRIM ranges are always within the allocatable range tree.
1348 4096 ZFS_DEBUG_LOG_SPACEMAP Verify that the log summary is consistent with the spacemap log
1349 and enable \fBzfs_dbgmsgs\fP for metaslab loading and flushing.
1351 .Sy \& * No Requires debug build .
1353 .It Sy zfs_btree_verify_intensity Ns = Ns Sy 0 Pq uint
1354 Enables btree verification.
1355 The following settings are culminative:
1362 2 Verify pointers from children to parent.
1363 3 Verify element counts.
1364 4 Verify element order. (expensive)
1365 * 5 Verify unused memory is poisoned. (expensive)
1367 .Sy \& * No Requires debug build .
1369 .It Sy zfs_free_leak_on_eio Ns = Ns Sy 0 Ns | Ns 1 Pq int
1370 If destroy encounters an
1372 while reading metadata (e.g. indirect blocks),
1373 space referenced by the missing metadata can not be freed.
1374 Normally this causes the background destroy to become "stalled",
1375 as it is unable to make forward progress.
1376 While in this stalled state, all remaining space to free
1377 from the error-encountering filesystem is "temporarily leaked".
1378 Set this flag to cause it to ignore the
1380 permanently leak the space from indirect blocks that can not be read,
1381 and continue to free everything else that it can.
1383 The default "stalling" behavior is useful if the storage partially
1384 fails (i.e. some but not all I/O operations fail), and then later recovers.
1385 In this case, we will be able to continue pool operations while it is
1386 partially failed, and when it recovers, we can continue to free the
1387 space, with no leaks.
1388 Note, however, that this case is actually fairly rare.
1390 Typically pools either
1391 .Bl -enum -compact -offset 4n -width "1."
1393 fail completely (but perhaps temporarily,
1394 e.g. due to a top-level vdev going offline), or
1396 have localized, permanent errors (e.g. disk returns the wrong data
1397 due to bit flip or firmware bug).
1399 In the former case, this setting does not matter because the
1400 pool will be suspended and the sync thread will not be able to make
1401 forward progress regardless.
1402 In the latter, because the error is permanent, the best we can do
1403 is leak the minimum amount of space,
1404 which is what setting this flag will do.
1405 It is therefore reasonable for this flag to normally be set,
1406 but we chose the more conservative approach of not setting it,
1407 so that there is no possibility of
1408 leaking space in the "partial temporary" failure case.
1410 .It Sy zfs_free_min_time_ms Ns = Ns Sy 1000 Ns ms Po 1s Pc Pq uint
1416 a minimum of this much time will be spent working on freeing blocks per TXG.
1418 .It Sy zfs_obsolete_min_time_ms Ns = Ns Sy 500 Ns ms Pq uint
1420 .Sy zfs_free_min_time_ms ,
1421 but for cleanup of old indirection records for removed vdevs.
1423 .It Sy zfs_immediate_write_sz Ns = Ns Sy 32768 Ns B Po 32 KiB Pc Pq s64
1424 Largest data block to write to the ZIL.
1425 Larger blocks will be treated as if the dataset being written to had the
1426 .Sy logbias Ns = Ns Sy throughput
1429 .It Sy zfs_initialize_value Ns = Ns Sy 16045690984833335022 Po 0xDEADBEEFDEADBEEE Pc Pq u64
1430 Pattern written to vdev free space by
1431 .Xr zpool-initialize 8 .
1433 .It Sy zfs_initialize_chunk_size Ns = Ns Sy 1048576 Ns B Po 1 MiB Pc Pq u64
1434 Size of writes used by
1435 .Xr zpool-initialize 8 .
1436 This option is used by the test suite.
1438 .It Sy zfs_livelist_max_entries Ns = Ns Sy 500000 Po 5*10^5 Pc Pq u64
1439 The threshold size (in block pointers) at which we create a new sub-livelist.
1440 Larger sublists are more costly from a memory perspective but the fewer
1441 sublists there are, the lower the cost of insertion.
1443 .It Sy zfs_livelist_min_percent_shared Ns = Ns Sy 75 Ns % Pq int
1444 If the amount of shared space between a snapshot and its clone drops below
1445 this threshold, the clone turns off the livelist and reverts to the old
1447 This is in place because livelists no long give us a benefit
1448 once a clone has been overwritten enough.
1450 .It Sy zfs_livelist_condense_new_alloc Ns = Ns Sy 0 Pq int
1451 Incremented each time an extra ALLOC blkptr is added to a livelist entry while
1452 it is being condensed.
1453 This option is used by the test suite to track race conditions.
1455 .It Sy zfs_livelist_condense_sync_cancel Ns = Ns Sy 0 Pq int
1456 Incremented each time livelist condensing is canceled while in
1457 .Fn spa_livelist_condense_sync .
1458 This option is used by the test suite to track race conditions.
1460 .It Sy zfs_livelist_condense_sync_pause Ns = Ns Sy 0 Ns | Ns 1 Pq int
1461 When set, the livelist condense process pauses indefinitely before
1462 executing the synctask \(em
1463 .Fn spa_livelist_condense_sync .
1464 This option is used by the test suite to trigger race conditions.
1466 .It Sy zfs_livelist_condense_zthr_cancel Ns = Ns Sy 0 Pq int
1467 Incremented each time livelist condensing is canceled while in
1468 .Fn spa_livelist_condense_cb .
1469 This option is used by the test suite to track race conditions.
1471 .It Sy zfs_livelist_condense_zthr_pause Ns = Ns Sy 0 Ns | Ns 1 Pq int
1472 When set, the livelist condense process pauses indefinitely before
1473 executing the open context condensing work in
1474 .Fn spa_livelist_condense_cb .
1475 This option is used by the test suite to trigger race conditions.
1477 .It Sy zfs_lua_max_instrlimit Ns = Ns Sy 100000000 Po 10^8 Pc Pq u64
1478 The maximum execution time limit that can be set for a ZFS channel program,
1479 specified as a number of Lua instructions.
1481 .It Sy zfs_lua_max_memlimit Ns = Ns Sy 104857600 Po 100 MiB Pc Pq u64
1482 The maximum memory limit that can be set for a ZFS channel program, specified
1485 .It Sy zfs_max_dataset_nesting Ns = Ns Sy 50 Pq int
1486 The maximum depth of nested datasets.
1487 This value can be tuned temporarily to
1488 fix existing datasets that exceed the predefined limit.
1490 .It Sy zfs_max_log_walking Ns = Ns Sy 5 Pq u64
1491 The number of past TXGs that the flushing algorithm of the log spacemap
1492 feature uses to estimate incoming log blocks.
1494 .It Sy zfs_max_logsm_summary_length Ns = Ns Sy 10 Pq u64
1495 Maximum number of rows allowed in the summary of the spacemap log.
1497 .It Sy zfs_max_recordsize Ns = Ns Sy 16777216 Po 16 MiB Pc Pq uint
1498 We currently support block sizes from
1499 .Em 512 Po 512 B Pc No to Em 16777216 Po 16 MiB Pc .
1500 The benefits of larger blocks, and thus larger I/O,
1501 need to be weighed against the cost of COWing a giant block to modify one byte.
1502 Additionally, very large blocks can have an impact on I/O latency,
1503 and also potentially on the memory allocator.
1504 Therefore, we formerly forbade creating blocks larger than 1M.
1505 Larger blocks could be created by changing it,
1506 and pools with larger blocks can always be imported and used,
1507 regardless of this setting.
1509 .It Sy zfs_allow_redacted_dataset_mount Ns = Ns Sy 0 Ns | Ns 1 Pq int
1510 Allow datasets received with redacted send/receive to be mounted.
1511 Normally disabled because these datasets may be missing key data.
1513 .It Sy zfs_min_metaslabs_to_flush Ns = Ns Sy 1 Pq u64
1514 Minimum number of metaslabs to flush per dirty TXG.
1516 .It Sy zfs_metaslab_fragmentation_threshold Ns = Ns Sy 70 Ns % Pq uint
1517 Allow metaslabs to keep their active state as long as their fragmentation
1518 percentage is no more than this value.
1519 An active metaslab that exceeds this threshold
1520 will no longer keep its active status allowing better metaslabs to be selected.
1522 .It Sy zfs_mg_fragmentation_threshold Ns = Ns Sy 95 Ns % Pq uint
1523 Metaslab groups are considered eligible for allocations if their
1524 fragmentation metric (measured as a percentage) is less than or equal to
1526 If a metaslab group exceeds this threshold then it will be
1527 skipped unless all metaslab groups within the metaslab class have also
1528 crossed this threshold.
1530 .It Sy zfs_mg_noalloc_threshold Ns = Ns Sy 0 Ns % Pq uint
1531 Defines a threshold at which metaslab groups should be eligible for allocations.
1532 The value is expressed as a percentage of free space
1533 beyond which a metaslab group is always eligible for allocations.
1534 If a metaslab group's free space is less than or equal to the
1535 threshold, the allocator will avoid allocating to that group
1536 unless all groups in the pool have reached the threshold.
1537 Once all groups have reached the threshold, all groups are allowed to accept
1539 The default value of
1541 disables the feature and causes all metaslab groups to be eligible for
1544 This parameter allows one to deal with pools having heavily imbalanced
1545 vdevs such as would be the case when a new vdev has been added.
1546 Setting the threshold to a non-zero percentage will stop allocations
1547 from being made to vdevs that aren't filled to the specified percentage
1548 and allow lesser filled vdevs to acquire more allocations than they
1549 otherwise would under the old
1550 .Sy zfs_mg_alloc_failures
1553 .It Sy zfs_ddt_data_is_special Ns = Ns Sy 1 Ns | Ns 0 Pq int
1554 If enabled, ZFS will place DDT data into the special allocation class.
1556 .It Sy zfs_user_indirect_is_special Ns = Ns Sy 1 Ns | Ns 0 Pq int
1557 If enabled, ZFS will place user data indirect blocks
1558 into the special allocation class.
1560 .It Sy zfs_multihost_history Ns = Ns Sy 0 Pq uint
1561 Historical statistics for this many latest multihost updates will be available
1563 .Pa /proc/spl/kstat/zfs/ Ns Ao Ar pool Ac Ns Pa /multihost .
1565 .It Sy zfs_multihost_interval Ns = Ns Sy 1000 Ns ms Po 1 s Pc Pq u64
1566 Used to control the frequency of multihost writes which are performed when the
1568 pool property is on.
1569 This is one of the factors used to determine the
1570 length of the activity check during import.
1572 The multihost write period is
1573 .Sy zfs_multihost_interval No / Sy leaf-vdevs .
1574 On average a multihost write will be issued for each leaf vdev
1576 .Sy zfs_multihost_interval
1578 In practice, the observed period can vary with the I/O load
1579 and this observed value is the delay which is stored in the uberblock.
1581 .It Sy zfs_multihost_import_intervals Ns = Ns Sy 20 Pq uint
1582 Used to control the duration of the activity test on import.
1584 .Sy zfs_multihost_import_intervals
1585 will reduce the import time but increase
1586 the risk of failing to detect an active pool.
1587 The total activity check time is never allowed to drop below one second.
1589 On import the activity check waits a minimum amount of time determined by
1590 .Sy zfs_multihost_interval No \(mu Sy zfs_multihost_import_intervals ,
1591 or the same product computed on the host which last had the pool imported,
1592 whichever is greater.
1593 The activity check time may be further extended if the value of MMP
1594 delay found in the best uberblock indicates actual multihost updates happened
1595 at longer intervals than
1596 .Sy zfs_multihost_interval .
1601 .Sy 0 No is equivalent to Sy 1 .
1603 .It Sy zfs_multihost_fail_intervals Ns = Ns Sy 10 Pq uint
1604 Controls the behavior of the pool when multihost write failures or delays are
1609 multihost write failures or delays are ignored.
1610 The failures will still be reported to the ZED which depending on
1611 its configuration may take action such as suspending the pool or offlining a
1614 Otherwise, the pool will be suspended if
1615 .Sy zfs_multihost_fail_intervals No \(mu Sy zfs_multihost_interval
1616 milliseconds pass without a successful MMP write.
1617 This guarantees the activity test will see MMP writes if the pool is imported.
1618 .Sy 1 No is equivalent to Sy 2 ;
1619 this is necessary to prevent the pool from being suspended
1620 due to normal, small I/O latency variations.
1622 .It Sy zfs_no_scrub_io Ns = Ns Sy 0 Ns | Ns 1 Pq int
1623 Set to disable scrub I/O.
1624 This results in scrubs not actually scrubbing data and
1625 simply doing a metadata crawl of the pool instead.
1627 .It Sy zfs_no_scrub_prefetch Ns = Ns Sy 0 Ns | Ns 1 Pq int
1628 Set to disable block prefetching for scrubs.
1630 .It Sy zfs_nocacheflush Ns = Ns Sy 0 Ns | Ns 1 Pq int
1631 Disable cache flush operations on disks when writing.
1632 Setting this will cause pool corruption on power loss
1633 if a volatile out-of-order write cache is enabled.
1635 .It Sy zfs_nopwrite_enabled Ns = Ns Sy 1 Ns | Ns 0 Pq int
1636 Allow no-operation writes.
1637 The occurrence of nopwrites will further depend on other pool properties
1638 .Pq i.a. the checksumming and compression algorithms .
1640 .It Sy zfs_dmu_offset_next_sync Ns = Ns Sy 1 Ns | Ns 0 Pq int
1641 Enable forcing TXG sync to find holes.
1642 When enabled forces ZFS to sync data when
1643 .Sy SEEK_HOLE No or Sy SEEK_DATA
1644 flags are used allowing holes in a file to be accurately reported.
1645 When disabled holes will not be reported in recently dirtied files.
1647 .It Sy zfs_pd_bytes_max Ns = Ns Sy 52428800 Ns B Po 50 MiB Pc Pq int
1648 The number of bytes which should be prefetched during a pool traversal, like
1650 or other data crawling operations.
1652 .It Sy zfs_traverse_indirect_prefetch_limit Ns = Ns Sy 32 Pq uint
1653 The number of blocks pointed by indirect (non-L0) block which should be
1654 prefetched during a pool traversal, like
1656 or other data crawling operations.
1658 .It Sy zfs_per_txg_dirty_frees_percent Ns = Ns Sy 30 Ns % Pq u64
1659 Control percentage of dirtied indirect blocks from frees allowed into one TXG.
1660 After this threshold is crossed, additional frees will wait until the next TXG.
1661 .Sy 0 No disables this throttle .
1663 .It Sy zfs_prefetch_disable Ns = Ns Sy 0 Ns | Ns 1 Pq int
1664 Disable predictive prefetch.
1665 Note that it leaves "prescient" prefetch
1666 .Pq for, e.g., Nm zfs Cm send
1668 Unlike predictive prefetch, prescient prefetch never issues I/O
1669 that ends up not being needed, so it can't hurt performance.
1671 .It Sy zfs_qat_checksum_disable Ns = Ns Sy 0 Ns | Ns 1 Pq int
1672 Disable QAT hardware acceleration for SHA256 checksums.
1673 May be unset after the ZFS modules have been loaded to initialize the QAT
1674 hardware as long as support is compiled in and the QAT driver is present.
1676 .It Sy zfs_qat_compress_disable Ns = Ns Sy 0 Ns | Ns 1 Pq int
1677 Disable QAT hardware acceleration for gzip compression.
1678 May be unset after the ZFS modules have been loaded to initialize the QAT
1679 hardware as long as support is compiled in and the QAT driver is present.
1681 .It Sy zfs_qat_encrypt_disable Ns = Ns Sy 0 Ns | Ns 1 Pq int
1682 Disable QAT hardware acceleration for AES-GCM encryption.
1683 May be unset after the ZFS modules have been loaded to initialize the QAT
1684 hardware as long as support is compiled in and the QAT driver is present.
1686 .It Sy zfs_vnops_read_chunk_size Ns = Ns Sy 1048576 Ns B Po 1 MiB Pc Pq u64
1687 Bytes to read per chunk.
1689 .It Sy zfs_read_history Ns = Ns Sy 0 Pq uint
1690 Historical statistics for this many latest reads will be available in
1691 .Pa /proc/spl/kstat/zfs/ Ns Ao Ar pool Ac Ns Pa /reads .
1693 .It Sy zfs_read_history_hits Ns = Ns Sy 0 Ns | Ns 1 Pq int
1694 Include cache hits in read history
1696 .It Sy zfs_rebuild_max_segment Ns = Ns Sy 1048576 Ns B Po 1 MiB Pc Pq u64
1697 Maximum read segment size to issue when sequentially resilvering a
1700 .It Sy zfs_rebuild_scrub_enabled Ns = Ns Sy 1 Ns | Ns 0 Pq int
1701 Automatically start a pool scrub when the last active sequential resilver
1702 completes in order to verify the checksums of all blocks which have been
1704 This is enabled by default and strongly recommended.
1706 .It Sy zfs_rebuild_vdev_limit Ns = Ns Sy 67108864 Ns B Po 64 MiB Pc Pq u64
1707 Maximum amount of I/O that can be concurrently issued for a sequential
1708 resilver per leaf device, given in bytes.
1710 .It Sy zfs_reconstruct_indirect_combinations_max Ns = Ns Sy 4096 Pq int
1711 If an indirect split block contains more than this many possible unique
1712 combinations when being reconstructed, consider it too computationally
1713 expensive to check them all.
1714 Instead, try at most this many randomly selected
1715 combinations each time the block is accessed.
1716 This allows all segment copies to participate fairly
1717 in the reconstruction when all combinations
1718 cannot be checked and prevents repeated use of one bad copy.
1720 .It Sy zfs_recover Ns = Ns Sy 0 Ns | Ns 1 Pq int
1721 Set to attempt to recover from fatal errors.
1722 This should only be used as a last resort,
1723 as it typically results in leaked space, or worse.
1725 .It Sy zfs_removal_ignore_errors Ns = Ns Sy 0 Ns | Ns 1 Pq int
1726 Ignore hard I/O errors during device removal.
1727 When set, if a device encounters a hard I/O error during the removal process
1728 the removal will not be cancelled.
1729 This can result in a normally recoverable block becoming permanently damaged
1730 and is hence not recommended.
1731 This should only be used as a last resort when the
1732 pool cannot be returned to a healthy state prior to removing the device.
1734 .It Sy zfs_removal_suspend_progress Ns = Ns Sy 0 Ns | Ns 1 Pq uint
1735 This is used by the test suite so that it can ensure that certain actions
1736 happen while in the middle of a removal.
1738 .It Sy zfs_remove_max_segment Ns = Ns Sy 16777216 Ns B Po 16 MiB Pc Pq uint
1739 The largest contiguous segment that we will attempt to allocate when removing
1741 If there is a performance problem with attempting to allocate large blocks,
1742 consider decreasing this.
1743 The default value is also the maximum.
1745 .It Sy zfs_resilver_disable_defer Ns = Ns Sy 0 Ns | Ns 1 Pq int
1748 feature, causing an operation that would start a resilver to
1749 immediately restart the one in progress.
1751 .It Sy zfs_resilver_min_time_ms Ns = Ns Sy 3000 Ns ms Po 3 s Pc Pq uint
1752 Resilvers are processed by the sync thread.
1753 While resilvering, it will spend at least this much time
1754 working on a resilver between TXG flushes.
1756 .It Sy zfs_scan_ignore_errors Ns = Ns Sy 0 Ns | Ns 1 Pq int
1757 If set, remove the DTL (dirty time list) upon completion of a pool scan (scrub),
1758 even if there were unrepairable errors.
1759 Intended to be used during pool repair or recovery to
1760 stop resilvering when the pool is next imported.
1762 .It Sy zfs_scrub_min_time_ms Ns = Ns Sy 1000 Ns ms Po 1 s Pc Pq uint
1763 Scrubs are processed by the sync thread.
1764 While scrubbing, it will spend at least this much time
1765 working on a scrub between TXG flushes.
1767 .It Sy zfs_scan_checkpoint_intval Ns = Ns Sy 7200 Ns s Po 2 hour Pc Pq uint
1768 To preserve progress across reboots, the sequential scan algorithm periodically
1769 needs to stop metadata scanning and issue all the verification I/O to disk.
1770 The frequency of this flushing is determined by this tunable.
1772 .It Sy zfs_scan_fill_weight Ns = Ns Sy 3 Pq uint
1773 This tunable affects how scrub and resilver I/O segments are ordered.
1774 A higher number indicates that we care more about how filled in a segment is,
1775 while a lower number indicates we care more about the size of the extent without
1776 considering the gaps within a segment.
1777 This value is only tunable upon module insertion.
1778 Changing the value afterwards will have no effect on scrub or resilver
1781 .It Sy zfs_scan_issue_strategy Ns = Ns Sy 0 Pq uint
1782 Determines the order that data will be verified while scrubbing or resilvering:
1783 .Bl -tag -compact -offset 4n -width "a"
1785 Data will be verified as sequentially as possible, given the
1786 amount of memory reserved for scrubbing
1787 .Pq see Sy zfs_scan_mem_lim_fact .
1788 This may improve scrub performance if the pool's data is very fragmented.
1790 The largest mostly-contiguous chunk of found data will be verified first.
1791 By deferring scrubbing of small segments, we may later find adjacent data
1792 to coalesce and increase the segment size.
1794 .No Use strategy Sy 1 No during normal verification
1795 .No and strategy Sy 2 No while taking a checkpoint .
1798 .It Sy zfs_scan_legacy Ns = Ns Sy 0 Ns | Ns 1 Pq int
1799 If unset, indicates that scrubs and resilvers will gather metadata in
1800 memory before issuing sequential I/O.
1801 Otherwise indicates that the legacy algorithm will be used,
1802 where I/O is initiated as soon as it is discovered.
1803 Unsetting will not affect scrubs or resilvers that are already in progress.
1805 .It Sy zfs_scan_max_ext_gap Ns = Ns Sy 2097152 Ns B Po 2 MiB Pc Pq int
1806 Sets the largest gap in bytes between scrub/resilver I/O operations
1807 that will still be considered sequential for sorting purposes.
1808 Changing this value will not
1809 affect scrubs or resilvers that are already in progress.
1811 .It Sy zfs_scan_mem_lim_fact Ns = Ns Sy 20 Ns ^-1 Pq uint
1812 Maximum fraction of RAM used for I/O sorting by sequential scan algorithm.
1813 This tunable determines the hard limit for I/O sorting memory usage.
1814 When the hard limit is reached we stop scanning metadata and start issuing
1815 data verification I/O.
1816 This is done until we get below the soft limit.
1818 .It Sy zfs_scan_mem_lim_soft_fact Ns = Ns Sy 20 Ns ^-1 Pq uint
1819 The fraction of the hard limit used to determined the soft limit for I/O sorting
1820 by the sequential scan algorithm.
1821 When we cross this limit from below no action is taken.
1822 When we cross this limit from above it is because we are issuing verification
1824 In this case (unless the metadata scan is done) we stop issuing verification I/O
1825 and start scanning metadata again until we get to the hard limit.
1827 .It Sy zfs_scan_report_txgs Ns = Ns Sy 0 Ns | Ns 1 Pq uint
1828 When reporting resilver throughput and estimated completion time use the
1829 performance observed over roughly the last
1830 .Sy zfs_scan_report_txgs
1832 When set to zero performance is calculated over the time between checkpoints.
1834 .It Sy zfs_scan_strict_mem_lim Ns = Ns Sy 0 Ns | Ns 1 Pq int
1835 Enforce tight memory limits on pool scans when a sequential scan is in progress.
1836 When disabled, the memory limit may be exceeded by fast disks.
1838 .It Sy zfs_scan_suspend_progress Ns = Ns Sy 0 Ns | Ns 1 Pq int
1839 Freezes a scrub/resilver in progress without actually pausing it.
1840 Intended for testing/debugging.
1842 .It Sy zfs_scan_vdev_limit Ns = Ns Sy 16777216 Ns B Po 16 MiB Pc Pq int
1843 Maximum amount of data that can be concurrently issued at once for scrubs and
1844 resilvers per leaf device, given in bytes.
1846 .It Sy zfs_send_corrupt_data Ns = Ns Sy 0 Ns | Ns 1 Pq int
1847 Allow sending of corrupt data (ignore read/checksum errors when sending).
1849 .It Sy zfs_send_unmodified_spill_blocks Ns = Ns Sy 1 Ns | Ns 0 Pq int
1850 Include unmodified spill blocks in the send stream.
1851 Under certain circumstances, previous versions of ZFS could incorrectly
1852 remove the spill block from an existing object.
1853 Including unmodified copies of the spill blocks creates a backwards-compatible
1854 stream which will recreate a spill block if it was incorrectly removed.
1856 .It Sy zfs_send_no_prefetch_queue_ff Ns = Ns Sy 20 Ns ^\-1 Pq uint
1857 The fill fraction of the
1860 The fill fraction controls the timing with which internal threads are woken up.
1862 .It Sy zfs_send_no_prefetch_queue_length Ns = Ns Sy 1048576 Ns B Po 1 MiB Pc Pq uint
1863 The maximum number of bytes allowed in
1864 .Nm zfs Cm send Ns 's
1867 .It Sy zfs_send_queue_ff Ns = Ns Sy 20 Ns ^\-1 Pq uint
1868 The fill fraction of the
1871 The fill fraction controls the timing with which internal threads are woken up.
1873 .It Sy zfs_send_queue_length Ns = Ns Sy 16777216 Ns B Po 16 MiB Pc Pq uint
1874 The maximum number of bytes allowed that will be prefetched by
1876 This value must be at least twice the maximum block size in use.
1878 .It Sy zfs_recv_queue_ff Ns = Ns Sy 20 Ns ^\-1 Pq uint
1879 The fill fraction of the
1882 The fill fraction controls the timing with which internal threads are woken up.
1884 .It Sy zfs_recv_queue_length Ns = Ns Sy 16777216 Ns B Po 16 MiB Pc Pq uint
1885 The maximum number of bytes allowed in the
1888 This value must be at least twice the maximum block size in use.
1890 .It Sy zfs_recv_write_batch_size Ns = Ns Sy 1048576 Ns B Po 1 MiB Pc Pq uint
1891 The maximum amount of data, in bytes, that
1893 will write in one DMU transaction.
1894 This is the uncompressed size, even when receiving a compressed send stream.
1895 This setting will not reduce the write size below a single block.
1896 Capped at a maximum of
1899 .It Sy zfs_recv_best_effort_corrective Ns = Ns Sy 0 Pq int
1900 When this variable is set to non-zero a corrective receive:
1901 .Bl -enum -compact -offset 4n -width "1."
1903 Does not enforce the restriction of source & destination snapshot GUIDs
1906 If there is an error during healing, the healing receive is not
1907 terminated instead it moves on to the next record.
1910 .It Sy zfs_override_estimate_recordsize Ns = Ns Sy 0 Ns | Ns 1 Pq uint
1911 Setting this variable overrides the default logic for estimating block
1914 The default heuristic is that the average block size
1915 will be the current recordsize.
1916 Override this value if most data in your dataset is not of that size
1917 and you require accurate zfs send size estimates.
1919 .It Sy zfs_sync_pass_deferred_free Ns = Ns Sy 2 Pq uint
1920 Flushing of data to disk is done in passes.
1921 Defer frees starting in this pass.
1923 .It Sy zfs_spa_discard_memory_limit Ns = Ns Sy 16777216 Ns B Po 16 MiB Pc Pq int
1924 Maximum memory used for prefetching a checkpoint's space map on each
1925 vdev while discarding the checkpoint.
1927 .It Sy zfs_special_class_metadata_reserve_pct Ns = Ns Sy 25 Ns % Pq uint
1928 Only allow small data blocks to be allocated on the special and dedup vdev
1929 types when the available free space percentage on these vdevs exceeds this
1931 This ensures reserved space is available for pool metadata as the
1932 special vdevs approach capacity.
1934 .It Sy zfs_sync_pass_dont_compress Ns = Ns Sy 8 Pq uint
1935 Starting in this sync pass, disable compression (including of metadata).
1936 With the default setting, in practice, we don't have this many sync passes,
1937 so this has no effect.
1939 The original intent was that disabling compression would help the sync passes
1941 However, in practice, disabling compression increases
1942 the average number of sync passes; because when we turn compression off,
1943 many blocks' size will change, and thus we have to re-allocate
1944 (not overwrite) them.
1945 It also increases the number of
1947 allocations (e.g. for indirect blocks and spacemaps)
1948 because these will not be compressed.
1951 allocations are especially detrimental to performance
1952 on highly fragmented systems, which may have very few free segments of this
1954 and may need to load new metaslabs to satisfy these allocations.
1956 .It Sy zfs_sync_pass_rewrite Ns = Ns Sy 2 Pq uint
1957 Rewrite new block pointers starting in this pass.
1959 .It Sy zfs_sync_taskq_batch_pct Ns = Ns Sy 75 Ns % Pq int
1960 This controls the number of threads used by
1962 The default value of
1964 will create a maximum of one thread per CPU.
1966 .It Sy zfs_trim_extent_bytes_max Ns = Ns Sy 134217728 Ns B Po 128 MiB Pc Pq uint
1967 Maximum size of TRIM command.
1968 Larger ranges will be split into chunks no larger than this value before
1971 .It Sy zfs_trim_extent_bytes_min Ns = Ns Sy 32768 Ns B Po 32 KiB Pc Pq uint
1972 Minimum size of TRIM commands.
1973 TRIM ranges smaller than this will be skipped,
1974 unless they're part of a larger range which was chunked.
1975 This is done because it's common for these small TRIMs
1976 to negatively impact overall performance.
1978 .It Sy zfs_trim_metaslab_skip Ns = Ns Sy 0 Ns | Ns 1 Pq uint
1979 Skip uninitialized metaslabs during the TRIM process.
1980 This option is useful for pools constructed from large thinly-provisioned
1982 where TRIM operations are slow.
1983 As a pool ages, an increasing fraction of the pool's metaslabs
1984 will be initialized, progressively degrading the usefulness of this option.
1985 This setting is stored when starting a manual TRIM and will
1986 persist for the duration of the requested TRIM.
1988 .It Sy zfs_trim_queue_limit Ns = Ns Sy 10 Pq uint
1989 Maximum number of queued TRIMs outstanding per leaf vdev.
1990 The number of concurrent TRIM commands issued to the device is controlled by
1991 .Sy zfs_vdev_trim_min_active No and Sy zfs_vdev_trim_max_active .
1993 .It Sy zfs_trim_txg_batch Ns = Ns Sy 32 Pq uint
1994 The number of transaction groups' worth of frees which should be aggregated
1995 before TRIM operations are issued to the device.
1996 This setting represents a trade-off between issuing larger,
1997 more efficient TRIM operations and the delay
1998 before the recently trimmed space is available for use by the device.
2000 Increasing this value will allow frees to be aggregated for a longer time.
2001 This will result is larger TRIM operations and potentially increased memory
2003 Decreasing this value will have the opposite effect.
2006 was determined to be a reasonable compromise.
2008 .It Sy zfs_txg_history Ns = Ns Sy 0 Pq uint
2009 Historical statistics for this many latest TXGs will be available in
2010 .Pa /proc/spl/kstat/zfs/ Ns Ao Ar pool Ac Ns Pa /TXGs .
2012 .It Sy zfs_txg_timeout Ns = Ns Sy 5 Ns s Pq uint
2013 Flush dirty data to disk at least every this many seconds (maximum TXG
2016 .It Sy zfs_vdev_aggregate_trim Ns = Ns Sy 0 Ns | Ns 1 Pq uint
2017 Allow TRIM I/O operations to be aggregated.
2018 This is normally not helpful because the extents to be trimmed
2019 will have been already been aggregated by the metaslab.
2020 This option is provided for debugging and performance analysis.
2022 .It Sy zfs_vdev_aggregation_limit Ns = Ns Sy 1048576 Ns B Po 1 MiB Pc Pq uint
2023 Max vdev I/O aggregation size.
2025 .It Sy zfs_vdev_aggregation_limit_non_rotating Ns = Ns Sy 131072 Ns B Po 128 KiB Pc Pq uint
2026 Max vdev I/O aggregation size for non-rotating media.
2028 .It Sy zfs_vdev_cache_bshift Ns = Ns Sy 16 Po 64 KiB Pc Pq uint
2029 Shift size to inflate reads to.
2031 .It Sy zfs_vdev_cache_max Ns = Ns Sy 16384 Ns B Po 16 KiB Pc Pq uint
2032 Inflate reads smaller than this value to meet the
2033 .Sy zfs_vdev_cache_bshift
2035 .Pq default Sy 64 KiB .
2037 .It Sy zfs_vdev_cache_size Ns = Ns Sy 0 Pq uint
2038 Total size of the per-disk cache in bytes.
2040 Currently this feature is disabled, as it has been found to not be helpful
2041 for performance and in some cases harmful.
2043 .It Sy zfs_vdev_mirror_rotating_inc Ns = Ns Sy 0 Pq int
2044 A number by which the balancing algorithm increments the load calculation for
2045 the purpose of selecting the least busy mirror member when an I/O operation
2046 immediately follows its predecessor on rotational vdevs
2047 for the purpose of making decisions based on load.
2049 .It Sy zfs_vdev_mirror_rotating_seek_inc Ns = Ns Sy 5 Pq int
2050 A number by which the balancing algorithm increments the load calculation for
2051 the purpose of selecting the least busy mirror member when an I/O operation
2052 lacks locality as defined by
2053 .Sy zfs_vdev_mirror_rotating_seek_offset .
2054 Operations within this that are not immediately following the previous operation
2055 are incremented by half.
2057 .It Sy zfs_vdev_mirror_rotating_seek_offset Ns = Ns Sy 1048576 Ns B Po 1 MiB Pc Pq int
2058 The maximum distance for the last queued I/O operation in which
2059 the balancing algorithm considers an operation to have locality.
2060 .No See Sx ZFS I/O SCHEDULER .
2062 .It Sy zfs_vdev_mirror_non_rotating_inc Ns = Ns Sy 0 Pq int
2063 A number by which the balancing algorithm increments the load calculation for
2064 the purpose of selecting the least busy mirror member on non-rotational vdevs
2065 when I/O operations do not immediately follow one another.
2067 .It Sy zfs_vdev_mirror_non_rotating_seek_inc Ns = Ns Sy 1 Pq int
2068 A number by which the balancing algorithm increments the load calculation for
2069 the purpose of selecting the least busy mirror member when an I/O operation
2071 locality as defined by the
2072 .Sy zfs_vdev_mirror_rotating_seek_offset .
2073 Operations within this that are not immediately following the previous operation
2074 are incremented by half.
2076 .It Sy zfs_vdev_read_gap_limit Ns = Ns Sy 32768 Ns B Po 32 KiB Pc Pq uint
2077 Aggregate read I/O operations if the on-disk gap between them is within this
2080 .It Sy zfs_vdev_write_gap_limit Ns = Ns Sy 4096 Ns B Po 4 KiB Pc Pq uint
2081 Aggregate write I/O operations if the on-disk gap between them is within this
2084 .It Sy zfs_vdev_raidz_impl Ns = Ns Sy fastest Pq string
2085 Select the raidz parity implementation to use.
2087 Variants that don't depend on CPU-specific features
2088 may be selected on module load, as they are supported on all systems.
2089 The remaining options may only be set after the module is loaded,
2090 as they are available only if the implementations are compiled in
2091 and supported on the running system.
2093 Once the module is loaded,
2094 .Pa /sys/module/zfs/parameters/zfs_vdev_raidz_impl
2095 will show the available options,
2096 with the currently selected one enclosed in square brackets.
2100 fastest selected by built-in benchmark
2101 original original implementation
2102 scalar scalar implementation
2103 sse2 SSE2 instruction set 64-bit x86
2104 ssse3 SSSE3 instruction set 64-bit x86
2105 avx2 AVX2 instruction set 64-bit x86
2106 avx512f AVX512F instruction set 64-bit x86
2107 avx512bw AVX512F & AVX512BW instruction sets 64-bit x86
2108 aarch64_neon NEON Aarch64/64-bit ARMv8
2109 aarch64_neonx2 NEON with more unrolling Aarch64/64-bit ARMv8
2110 powerpc_altivec Altivec PowerPC
2113 .It Sy zfs_vdev_scheduler Pq charp
2115 Prints warning to kernel log for compatibility.
2117 .It Sy zfs_zevent_len_max Ns = Ns Sy 512 Pq uint
2118 Max event queue length.
2119 Events in the queue can be viewed with
2120 .Xr zpool-events 8 .
2122 .It Sy zfs_zevent_retain_max Ns = Ns Sy 2000 Pq int
2123 Maximum recent zevent records to retain for duplicate checking.
2126 disables duplicate detection.
2128 .It Sy zfs_zevent_retain_expire_secs Ns = Ns Sy 900 Ns s Po 15 min Pc Pq int
2129 Lifespan for a recent ereport that was retained for duplicate checking.
2131 .It Sy zfs_zil_clean_taskq_maxalloc Ns = Ns Sy 1048576 Pq int
2132 The maximum number of taskq entries that are allowed to be cached.
2133 When this limit is exceeded transaction records (itxs)
2134 will be cleaned synchronously.
2136 .It Sy zfs_zil_clean_taskq_minalloc Ns = Ns Sy 1024 Pq int
2137 The number of taskq entries that are pre-populated when the taskq is first
2138 created and are immediately available for use.
2140 .It Sy zfs_zil_clean_taskq_nthr_pct Ns = Ns Sy 100 Ns % Pq int
2141 This controls the number of threads used by
2142 .Sy dp_zil_clean_taskq .
2143 The default value of
2145 will create a maximum of one thread per cpu.
2147 .It Sy zil_maxblocksize Ns = Ns Sy 131072 Ns B Po 128 KiB Pc Pq uint
2148 This sets the maximum block size used by the ZIL.
2149 On very fragmented pools, lowering this
2150 .Pq typically to Sy 36 KiB
2151 can improve performance.
2153 .It Sy zil_min_commit_timeout Ns = Ns Sy 5000 Pq u64
2154 This sets the minimum delay in nanoseconds ZIL care to delay block commit,
2155 waiting for more records.
2156 If ZIL writes are too fast, kernel may not be able sleep for so short interval,
2157 increasing log latency above allowed by
2158 .Sy zfs_commit_timeout_pct .
2160 .It Sy zil_nocacheflush Ns = Ns Sy 0 Ns | Ns 1 Pq int
2161 Disable the cache flush commands that are normally sent to disk by
2162 the ZIL after an LWB write has completed.
2163 Setting this will cause ZIL corruption on power loss
2164 if a volatile out-of-order write cache is enabled.
2166 .It Sy zil_replay_disable Ns = Ns Sy 0 Ns | Ns 1 Pq int
2167 Disable intent logging replay.
2168 Can be disabled for recovery from corrupted ZIL.
2170 .It Sy zil_slog_bulk Ns = Ns Sy 786432 Ns B Po 768 KiB Pc Pq u64
2171 Limit SLOG write size per commit executed with synchronous priority.
2172 Any writes above that will be executed with lower (asynchronous) priority
2173 to limit potential SLOG device abuse by single active ZIL writer.
2175 .It Sy zfs_zil_saxattr Ns = Ns Sy 1 Ns | Ns 0 Pq int
2176 Setting this tunable to zero disables ZIL logging of new
2177 .Sy xattr Ns = Ns Sy sa
2179 .Sy org.openzfs:zilsaxattr
2180 feature is enabled on the pool.
2181 This would only be necessary to work around bugs in the ZIL logging or replay
2182 code for this record type.
2183 The tunable has no effect if the feature is disabled.
2185 .It Sy zfs_embedded_slog_min_ms Ns = Ns Sy 64 Pq uint
2186 Usually, one metaslab from each normal-class vdev is dedicated for use by
2187 the ZIL to log synchronous writes.
2188 However, if there are fewer than
2189 .Sy zfs_embedded_slog_min_ms
2190 metaslabs in the vdev, this functionality is disabled.
2191 This ensures that we don't set aside an unreasonable amount of space for the
2194 .It Sy zstd_earlyabort_pass Ns = Ns Sy 1 Pq uint
2195 Whether heuristic for detection of incompressible data with zstd levels >= 3
2196 using LZ4 and zstd-1 passes is enabled.
2198 .It Sy zstd_abort_size Ns = Ns Sy 131072 Pq uint
2199 Minimal uncompressed size (inclusive) of a record before the early abort
2200 heuristic will be attempted.
2202 .It Sy zio_deadman_log_all Ns = Ns Sy 0 Ns | Ns 1 Pq int
2203 If non-zero, the zio deadman will produce debugging messages
2204 .Pq see Sy zfs_dbgmsg_enable
2205 for all zios, rather than only for leaf zios possessing a vdev.
2206 This is meant to be used by developers to gain
2207 diagnostic information for hang conditions which don't involve a mutex
2208 or other locking primitive: typically conditions in which a thread in
2209 the zio pipeline is looping indefinitely.
2211 .It Sy zio_slow_io_ms Ns = Ns Sy 30000 Ns ms Po 30 s Pc Pq int
2212 When an I/O operation takes more than this much time to complete,
2213 it's marked as slow.
2214 Each slow operation causes a delay zevent.
2215 Slow I/O counters can be seen with
2216 .Nm zpool Cm status Fl s .
2218 .It Sy zio_dva_throttle_enabled Ns = Ns Sy 1 Ns | Ns 0 Pq int
2219 Throttle block allocations in the I/O pipeline.
2220 This allows for dynamic allocation distribution when devices are imbalanced.
2221 When enabled, the maximum number of pending allocations per top-level vdev
2223 .Sy zfs_vdev_queue_depth_pct .
2225 .It Sy zfs_xattr_compat Ns = Ns 0 Ns | Ns 1 Pq int
2226 Control the naming scheme used when setting new xattrs in the user namespace.
2229 .Pq the default on Linux ,
2230 user namespace xattr names are prefixed with the namespace, to be backwards
2231 compatible with previous versions of ZFS on Linux.
2234 .Pq the default on Fx ,
2235 user namespace xattr names are not prefixed, to be backwards compatible with
2236 previous versions of ZFS on illumos and
2239 Either naming scheme can be read on this and future versions of ZFS, regardless
2240 of this tunable, but legacy ZFS on illumos or
2242 are unable to read user namespace xattrs written in the Linux format, and
2243 legacy versions of ZFS on Linux are unable to read user namespace xattrs written
2244 in the legacy ZFS format.
2246 An existing xattr with the alternate naming scheme is removed when overwriting
2247 the xattr so as to not accumulate duplicates.
2249 .It Sy zio_requeue_io_start_cut_in_line Ns = Ns Sy 0 Ns | Ns 1 Pq int
2250 Prioritize requeued I/O.
2252 .It Sy zio_taskq_batch_pct Ns = Ns Sy 80 Ns % Pq uint
2253 Percentage of online CPUs which will run a worker thread for I/O.
2254 These workers are responsible for I/O work such as compression and
2255 checksum calculations.
2256 Fractional number of CPUs will be rounded down.
2258 The default value of
2260 was chosen to avoid using all CPUs which can result in
2261 latency issues and inconsistent application performance,
2262 especially when slower compression and/or checksumming is enabled.
2264 .It Sy zio_taskq_batch_tpq Ns = Ns Sy 0 Pq uint
2265 Number of worker threads per taskq.
2266 Lower values improve I/O ordering and CPU utilization,
2267 while higher reduces lock contention.
2271 generate a system-dependent value close to 6 threads per taskq.
2273 .It Sy zvol_inhibit_dev Ns = Ns Sy 0 Ns | Ns 1 Pq uint
2274 Do not create zvol device nodes.
2275 This may slightly improve startup time on
2276 systems with a very large number of zvols.
2278 .It Sy zvol_major Ns = Ns Sy 230 Pq uint
2279 Major number for zvol block devices.
2281 .It Sy zvol_max_discard_blocks Ns = Ns Sy 16384 Pq long
2282 Discard (TRIM) operations done on zvols will be done in batches of this
2283 many blocks, where block size is determined by the
2287 .It Sy zvol_prefetch_bytes Ns = Ns Sy 131072 Ns B Po 128 KiB Pc Pq uint
2288 When adding a zvol to the system, prefetch this many bytes
2289 from the start and end of the volume.
2290 Prefetching these regions of the volume is desirable,
2291 because they are likely to be accessed immediately by
2293 or the kernel partitioner.
2295 .It Sy zvol_request_sync Ns = Ns Sy 0 Ns | Ns 1 Pq uint
2296 When processing I/O requests for a zvol, submit them synchronously.
2297 This effectively limits the queue depth to
2299 for each I/O submitter.
2300 When unset, requests are handled asynchronously by a thread pool.
2301 The number of requests which can be handled concurrently is controlled by
2303 .Sy zvol_request_sync
2304 is ignored when running on a kernel that supports block multiqueue
2307 .It Sy zvol_threads Ns = Ns Sy 0 Pq uint
2308 The number of system wide threads to use for processing zvol block IOs.
2311 (the default) then internally set
2313 to the number of CPUs present or 32 (whichever is greater).
2315 .It Sy zvol_blk_mq_threads Ns = Ns Sy 0 Pq uint
2316 The number of threads per zvol to use for queuing IO requests.
2317 This parameter will only appear if your kernel supports
2319 and is only read and assigned to a zvol at zvol load time.
2322 (the default) then internally set
2323 .Sy zvol_blk_mq_threads
2324 to the number of CPUs present.
2326 .It Sy zvol_use_blk_mq Ns = Ns Sy 0 Ns | Ns 1 Pq uint
2334 (the default) to use the legacy zvol APIs.
2335 This setting can give better or worse zvol performance depending on
2337 This parameter will only appear if your kernel supports
2339 and is only read and assigned to a zvol at zvol load time.
2341 .It Sy zvol_blk_mq_blocks_per_thread Ns = Ns Sy 8 Pq uint
2344 is enabled, then process this number of
2345 .Sy volblocksize Ns -sized blocks per zvol thread.
2346 This tunable can be use to favor better performance for zvol reads (lower
2347 values) or writes (higher values).
2350 then the zvol layer will process the maximum number of blocks
2351 per thread that it can.
2352 This parameter will only appear if your kernel supports
2354 and is only applied at each zvol's load time.
2356 .It Sy zvol_blk_mq_queue_depth Ns = Ns Sy 0 Pq uint
2357 The queue_depth value for the zvol
2360 This parameter will only appear if your kernel supports
2362 and is only applied at each zvol's load time.
2365 (the default) then use the kernel's default queue depth.
2366 Values are clamped to the kernel's
2369 .Dv BLKDEV_MAX_RQ Ns / Ns Dv BLKDEV_DEFAULT_RQ
2372 .It Sy zvol_volmode Ns = Ns Sy 1 Pq uint
2373 Defines zvol block devices behaviour when
2374 .Sy volmode Ns = Ns Sy default :
2375 .Bl -tag -compact -offset 4n -width "a"
2377 .No equivalent to Sy full
2379 .No equivalent to Sy dev
2381 .No equivalent to Sy none
2384 .It Sy zvol_enforce_quotas Ns = Ns Sy 0 Ns | Ns 1 Pq uint
2385 Enable strict ZVOL quota enforcement.
2386 The strict quota enforcement may have a performance impact.
2389 .Sh ZFS I/O SCHEDULER
2390 ZFS issues I/O operations to leaf vdevs to satisfy and complete I/O operations.
2391 The scheduler determines when and in what order those operations are issued.
2392 The scheduler divides operations into five I/O classes,
2393 prioritized in the following order: sync read, sync write, async read,
2394 async write, and scrub/resilver.
2395 Each queue defines the minimum and maximum number of concurrent operations
2396 that may be issued to the device.
2397 In addition, the device has an aggregate maximum,
2398 .Sy zfs_vdev_max_active .
2399 Note that the sum of the per-queue minima must not exceed the aggregate maximum.
2400 If the sum of the per-queue maxima exceeds the aggregate maximum,
2401 then the number of active operations may reach
2402 .Sy zfs_vdev_max_active ,
2403 in which case no further operations will be issued,
2404 regardless of whether all per-queue minima have been met.
2406 For many physical devices, throughput increases with the number of
2407 concurrent operations, but latency typically suffers.
2408 Furthermore, physical devices typically have a limit
2409 at which more concurrent operations have no
2410 effect on throughput or can actually cause it to decrease.
2412 The scheduler selects the next operation to issue by first looking for an
2413 I/O class whose minimum has not been satisfied.
2414 Once all are satisfied and the aggregate maximum has not been hit,
2415 the scheduler looks for classes whose maximum has not been satisfied.
2416 Iteration through the I/O classes is done in the order specified above.
2417 No further operations are issued
2418 if the aggregate maximum number of concurrent operations has been hit,
2419 or if there are no operations queued for an I/O class that has not hit its
2421 Every time an I/O operation is queued or an operation completes,
2422 the scheduler looks for new operations to issue.
2426 will lead to lower latency of synchronous operations.
2429 may lead to higher overall throughput, depending on underlying storage.
2431 The ratio of the queues'
2433 determines the balance of performance between reads, writes, and scrubs.
2434 For example, increasing
2435 .Sy zfs_vdev_scrub_max_active
2436 will cause the scrub or resilver to complete more quickly,
2437 but reads and writes to have higher latency and lower throughput.
2439 All I/O classes have a fixed maximum number of outstanding operations,
2440 except for the async write class.
2441 Asynchronous writes represent the data that is committed to stable storage
2442 during the syncing stage for transaction groups.
2443 Transaction groups enter the syncing state periodically,
2444 so the number of queued async writes will quickly burst up
2445 and then bleed down to zero.
2446 Rather than servicing them as quickly as possible,
2447 the I/O scheduler changes the maximum number of active async write operations
2448 according to the amount of dirty data in the pool.
2449 Since both throughput and latency typically increase with the number of
2450 concurrent operations issued to physical devices, reducing the
2451 burstiness in the number of simultaneous operations also stabilizes the
2452 response time of operations from other queues, in particular synchronous ones.
2453 In broad strokes, the I/O scheduler will issue more concurrent operations
2454 from the async write queue as there is more dirty data in the pool.
2457 The number of concurrent operations issued for the async write I/O class
2458 follows a piece-wise linear function defined by a few adjustable points:
2460 | o---------| <-- \fBzfs_vdev_async_write_max_active\fP
2467 |-------o | | <-- \fBzfs_vdev_async_write_min_active\fP
2468 0|_______^______|_________|
2469 0% | | 100% of \fBzfs_dirty_data_max\fP
2471 | `-- \fBzfs_vdev_async_write_active_max_dirty_percent\fP
2472 `--------- \fBzfs_vdev_async_write_active_min_dirty_percent\fP
2475 Until the amount of dirty data exceeds a minimum percentage of the dirty
2476 data allowed in the pool, the I/O scheduler will limit the number of
2477 concurrent operations to the minimum.
2478 As that threshold is crossed, the number of concurrent operations issued
2479 increases linearly to the maximum at the specified maximum percentage
2480 of the dirty data allowed in the pool.
2482 Ideally, the amount of dirty data on a busy pool will stay in the sloped
2483 part of the function between
2484 .Sy zfs_vdev_async_write_active_min_dirty_percent
2486 .Sy zfs_vdev_async_write_active_max_dirty_percent .
2487 If it exceeds the maximum percentage,
2488 this indicates that the rate of incoming data is
2489 greater than the rate that the backend storage can handle.
2490 In this case, we must further throttle incoming writes,
2491 as described in the next section.
2493 .Sh ZFS TRANSACTION DELAY
2494 We delay transactions when we've determined that the backend storage
2495 isn't able to accommodate the rate of incoming writes.
2497 If there is already a transaction waiting, we delay relative to when
2498 that transaction will finish waiting.
2499 This way the calculated delay time
2500 is independent of the number of threads concurrently executing transactions.
2502 If we are the only waiter, wait relative to when the transaction started,
2503 rather than the current time.
2504 This credits the transaction for "time already served",
2505 e.g. reading indirect blocks.
2507 The minimum time for a transaction to take is calculated as
2508 .D1 min_time = min( Ns Sy zfs_delay_scale No \(mu Po Sy dirty No \- Sy min Pc / Po Sy max No \- Sy dirty Pc , 100ms)
2510 The delay has two degrees of freedom that can be adjusted via tunables.
2511 The percentage of dirty data at which we start to delay is defined by
2512 .Sy zfs_delay_min_dirty_percent .
2513 This should typically be at or above
2514 .Sy zfs_vdev_async_write_active_max_dirty_percent ,
2515 so that we only start to delay after writing at full speed
2516 has failed to keep up with the incoming write rate.
2517 The scale of the curve is defined by
2518 .Sy zfs_delay_scale .
2519 Roughly speaking, this variable determines the amount of delay at the midpoint
2523 10ms +-------------------------------------------------------------*+
2539 2ms + (midpoint) * +
2542 | \fBzfs_delay_scale\fP ----------> ******** |
2543 0 +-------------------------------------*********----------------+
2544 0% <- \fBzfs_dirty_data_max\fP -> 100%
2547 Note, that since the delay is added to the outstanding time remaining on the
2548 most recent transaction it's effectively the inverse of IOPS.
2549 Here, the midpoint of
2553 The shape of the curve
2554 was chosen such that small changes in the amount of accumulated dirty data
2555 in the first three quarters of the curve yield relatively small differences
2556 in the amount of delay.
2558 The effects can be easier to understand when the amount of delay is
2559 represented on a logarithmic scale:
2562 100ms +-------------------------------------------------------------++
2571 + \fBzfs_delay_scale\fP ----------> ***** +
2582 +--------------------------------------------------------------+
2583 0% <- \fBzfs_dirty_data_max\fP -> 100%
2586 Note here that only as the amount of dirty data approaches its limit does
2587 the delay start to increase rapidly.
2588 The goal of a properly tuned system should be to keep the amount of dirty data
2589 out of that range by first ensuring that the appropriate limits are set
2590 for the I/O scheduler to reach optimal throughput on the back-end storage,
2591 and then by changing the value of
2593 to increase the steepness of the curve.