Provided by: zfsutils-linux_2.2.2-0ubuntu9.1_amd64 
NAME
zfs — tuning of the ZFS kernel module
DESCRIPTION
The ZFS module supports these parameters:
dbuf_cache_max_bytes=UINT64_MAXB (u64)
Maximum size in bytes of the dbuf cache. The target size is determined by the MIN
versus 1/2^dbuf_cache_shift (1/32nd) of the target ARC size. The behavior of the
dbuf cache and its associated settings can be observed via the
/proc/spl/kstat/zfs/dbufstats kstat.
dbuf_metadata_cache_max_bytes=UINT64_MAXB (u64)
Maximum size in bytes of the metadata dbuf cache. The target size is determined by
the MIN versus 1/2^dbuf_metadata_cache_shift (1/64th) of the target ARC size. The
behavior of the metadata dbuf cache and its associated settings can be observed via
the /proc/spl/kstat/zfs/dbufstats kstat.
dbuf_cache_hiwater_pct=10% (uint)
The percentage over dbuf_cache_max_bytes when dbufs must be evicted directly.
dbuf_cache_lowater_pct=10% (uint)
The percentage below dbuf_cache_max_bytes when the evict thread stops evicting
dbufs.
dbuf_cache_shift=5 (uint)
Set the size of the dbuf cache (dbuf_cache_max_bytes) to a log2 fraction of the
target ARC size.
dbuf_metadata_cache_shift=6 (uint)
Set the size of the dbuf metadata cache (dbuf_metadata_cache_max_bytes) to a log2
fraction of the target ARC size.
dbuf_mutex_cache_shift=0 (uint)
Set the size of the mutex array for the dbuf cache. When set to 0 the array is
dynamically sized based on total system memory.
dmu_object_alloc_chunk_shift=7 (128) (uint)
dnode slots allocated in a single operation as a power of 2. The default value
minimizes lock contention for the bulk operation performed.
dmu_prefetch_max=134217728B (128 MiB) (uint)
Limit the amount we can prefetch with one call to this amount in bytes. This helps
to limit the amount of memory that can be used by prefetching.
ignore_hole_birth (int)
Alias for send_holes_without_birth_time.
l2arc_feed_again=1|0 (int)
Turbo L2ARC warm-up. When the L2ARC is cold the fill interval will be set as fast
as possible.
l2arc_feed_min_ms=200 (u64)
Min feed interval in milliseconds. Requires l2arc_feed_again=1 and only applicable
in related situations.
l2arc_feed_secs=1 (u64)
Seconds between L2ARC writing.
l2arc_headroom=2 (u64)
How far through the ARC lists to search for L2ARC cacheable content, expressed as a
multiplier of l2arc_write_max. ARC persistence across reboots can be achieved with
persistent L2ARC by setting this parameter to 0, allowing the full length of ARC
lists to be searched for cacheable content.
l2arc_headroom_boost=200% (u64)
Scales l2arc_headroom by this percentage when L2ARC contents are being successfully
compressed before writing. A value of 100 disables this feature.
l2arc_exclude_special=0|1 (int)
Controls whether buffers present on special vdevs are eligible for caching into
L2ARC. If set to 1, exclude dbufs on special vdevs from being cached to L2ARC.
l2arc_mfuonly=0|1 (int)
Controls whether only MFU metadata and data are cached from ARC into L2ARC. This
may be desired to avoid wasting space on L2ARC when reading/writing large amounts of
data that are not expected to be accessed more than once.
The default is off, meaning both MRU and MFU data and metadata are cached. When
turning off this feature, some MRU buffers will still be present in ARC and
eventually cached on L2ARC. If l2arc_noprefetch=0, some prefetched buffers will be
cached to L2ARC, and those might later transition to MRU, in which case the
l2arc_mru_asize arcstat will not be 0.
Regardless of l2arc_noprefetch, some MFU buffers might be evicted from ARC, accessed
later on as prefetches and transition to MRU as prefetches. If accessed again they
are counted as MRU and the l2arc_mru_asize arcstat will not be 0.
The ARC status of L2ARC buffers when they were first cached in L2ARC can be seen in
the l2arc_mru_asize, l2arc_mfu_asize, and l2arc_prefetch_asize arcstats when
importing the pool or onlining a cache device if persistent L2ARC is enabled.
The evict_l2_eligible_mru arcstat does not take into account if this option is
enabled as the information provided by the evict_l2_eligible_m[rf]u arcstats can be
used to decide if toggling this option is appropriate for the current workload.
l2arc_meta_percent=33% (uint)
Percent of ARC size allowed for L2ARC-only headers. Since L2ARC buffers are not
evicted on memory pressure, too many headers on a system with an irrationally large
L2ARC can render it slow or unusable. This parameter limits L2ARC writes and
rebuilds to achieve the target.
l2arc_trim_ahead=0% (u64)
Trims ahead of the current write size (l2arc_write_max) on L2ARC devices by this
percentage of write size if we have filled the device. If set to 100 we TRIM twice
the space required to accommodate upcoming writes. A minimum of 64 MiB will be
trimmed. It also enables TRIM of the whole L2ARC device upon creation or addition
to an existing pool or if the header of the device is invalid upon importing a pool
or onlining a cache device. A value of 0 disables TRIM on L2ARC altogether and is
the default as it can put significant stress on the underlying storage devices.
This will vary depending of how well the specific device handles these commands.
l2arc_noprefetch=1|0 (int)
Do not write buffers to L2ARC if they were prefetched but not used by applications.
In case there are prefetched buffers in L2ARC and this option is later set, we do
not read the prefetched buffers from L2ARC. Unsetting this option is useful for
caching sequential reads from the disks to L2ARC and serve those reads from L2ARC
later on. This may be beneficial in case the L2ARC device is significantly faster
in sequential reads than the disks of the pool.
Use 1 to disable and 0 to enable caching/reading prefetches to/from L2ARC.
l2arc_norw=0|1 (int)
No reads during writes.
l2arc_write_boost=8388608B (8 MiB) (u64)
Cold L2ARC devices will have l2arc_write_max increased by this amount while they
remain cold.
l2arc_write_max=8388608B (8 MiB) (u64)
Max write bytes per interval.
l2arc_rebuild_enabled=1|0 (int)
Rebuild the L2ARC when importing a pool (persistent L2ARC). This can be disabled if
there are problems importing a pool or attaching an L2ARC device (e.g. the L2ARC
device is slow in reading stored log metadata, or the metadata has become somehow
fragmented/unusable).
l2arc_rebuild_blocks_min_l2size=1073741824B (1 GiB) (u64)
Mininum size of an L2ARC device required in order to write log blocks in it. The
log blocks are used upon importing the pool to rebuild the persistent L2ARC.
For L2ARC devices less than 1 GiB, the amount of data l2arc_evict() evicts is
significant compared to the amount of restored L2ARC data. In this case, do not
write log blocks in L2ARC in order not to waste space.
metaslab_aliquot=1048576B (1 MiB) (u64)
Metaslab granularity, in bytes. This is roughly similar to what would be referred
to as the "stripe size" in traditional RAID arrays. In normal operation, ZFS will
try to write this amount of data to each disk before moving on to the next top-level
vdev.
metaslab_bias_enabled=1|0 (int)
Enable metaslab group biasing based on their vdevs' over- or under-utilization
relative to the pool.
metaslab_force_ganging=16777217B (16 MiB + 1 B) (u64)
Make some blocks above a certain size be gang blocks. This option is used by the
test suite to facilitate testing.
metaslab_force_ganging_pct=3% (uint)
For blocks that could be forced to be a gang block (due to metaslab_force_ganging),
force this many of them to be gang blocks.
zfs_ddt_zap_default_bs=15 (32 KiB) (int)
Default DDT ZAP data block size as a power of 2. Note that changing this after
creating a DDT on the pool will not affect existing DDTs, only newly created ones.
zfs_ddt_zap_default_ibs=15 (32 KiB) (int)
Default DDT ZAP indirect block size as a power of 2. Note that changing this after
creating a DDT on the pool will not affect existing DDTs, only newly created ones.
zfs_default_bs=9 (512 B) (int)
Default dnode block size as a power of 2.
zfs_default_ibs=17 (128 KiB) (int)
Default dnode indirect block size as a power of 2.
zfs_history_output_max=1048576B (1 MiB) (u64)
When attempting to log an output nvlist of an ioctl in the on-disk history, the
output will not be stored if it is larger than this size (in bytes). This must be
less than DMU_MAX_ACCESS (64 MiB). This applies primarily to
zfs_ioc_channel_program() (cf. zfs-program(8)).
zfs_keep_log_spacemaps_at_export=0|1 (int)
Prevent log spacemaps from being destroyed during pool exports and destroys.
zfs_metaslab_segment_weight_enabled=1|0 (int)
Enable/disable segment-based metaslab selection.
zfs_metaslab_switch_threshold=2 (int)
When using segment-based metaslab selection, continue allocating from the active
metaslab until this option's worth of buckets have been exhausted.
metaslab_debug_load=0|1 (int)
Load all metaslabs during pool import.
metaslab_debug_unload=0|1 (int)
Prevent metaslabs from being unloaded.
metaslab_fragmentation_factor_enabled=1|0 (int)
Enable use of the fragmentation metric in computing metaslab weights.
metaslab_df_max_search=16777216B (16 MiB) (uint)
Maximum distance to search forward from the last offset. Without this limit,
fragmented pools can see >100`000 iterations and metaslab_block_picker() becomes the
performance limiting factor on high-performance storage.
With the default setting of 16 MiB, we typically see less than 500 iterations, even
with very fragmented ashift=9 pools. The maximum number of iterations possible is
metaslab_df_max_search / 2^(ashift+1). With the default setting of 16 MiB this is
16*1024 (with ashift=9) or 2*1024 (with ashift=12).
metaslab_df_use_largest_segment=0|1 (int)
If not searching forward (due to metaslab_df_max_search, metaslab_df_free_pct, or
metaslab_df_alloc_threshold), this tunable controls which segment is used. If set,
we will use the largest free segment. If unset, we will use a segment of at least
the requested size.
zfs_metaslab_max_size_cache_sec=3600s (1 hour) (u64)
When we unload a metaslab, we cache the size of the largest free chunk. We use that
cached size to determine whether or not to load a metaslab for a given allocation.
As more frees accumulate in that metaslab while it's unloaded, the cached max size
becomes less and less accurate. After a number of seconds controlled by this
tunable, we stop considering the cached max size and start considering only the
histogram instead.
zfs_metaslab_mem_limit=25% (uint)
When we are loading a new metaslab, we check the amount of memory being used to
store metaslab range trees. If it is over a threshold, we attempt to unload the
least recently used metaslab to prevent the system from clogging all of its memory
with range trees. This tunable sets the percentage of total system memory that is
the threshold.
zfs_metaslab_try_hard_before_gang=0|1 (int)
If unset, we will first try normal allocation.
If that fails then we will do a gang allocation.
If that fails then we will do a "try hard" gang allocation.
If that fails then we will have a multi-layer gang block.
If set, we will first try normal allocation.
If that fails then we will do a "try hard" allocation.
If that fails we will do a gang allocation.
If that fails we will do a "try hard" gang allocation.
If that fails then we will have a multi-layer gang block.
zfs_metaslab_find_max_tries=100 (uint)
When not trying hard, we only consider this number of the best metaslabs. This
improves performance, especially when there are many metaslabs per vdev and the
allocation can't actually be satisfied (so we would otherwise iterate all
metaslabs).
zfs_vdev_default_ms_count=200 (uint)
When a vdev is added, target this number of metaslabs per top-level vdev.
zfs_vdev_default_ms_shift=29 (512 MiB) (uint)
Default lower limit for metaslab size.
zfs_vdev_max_ms_shift=34 (16 GiB) (uint)
Default upper limit for metaslab size.
zfs_vdev_max_auto_ashift=14 (uint)
Maximum ashift used when optimizing for logical → physical sector size on new top-
level vdevs. May be increased up to ASHIFT_MAX (16), but this may negatively impact
pool space efficiency.
zfs_vdev_min_auto_ashift=ASHIFT_MIN (9) (uint)
Minimum ashift used when creating new top-level vdevs.
zfs_vdev_min_ms_count=16 (uint)
Minimum number of metaslabs to create in a top-level vdev.
vdev_validate_skip=0|1 (int)
Skip label validation steps during pool import. Changing is not recommended unless
you know what you're doing and are recovering a damaged label.
zfs_vdev_ms_count_limit=131072 (128k) (uint)
Practical upper limit of total metaslabs per top-level vdev.
metaslab_preload_enabled=1|0 (int)
Enable metaslab group preloading.
metaslab_preload_limit=10 (uint)
Maximum number of metaslabs per group to preload
metaslab_preload_pct=50 (uint)
Percentage of CPUs to run a metaslab preload taskq
metaslab_lba_weighting_enabled=1|0 (int)
Give more weight to metaslabs with lower LBAs, assuming they have greater bandwidth,
as is typically the case on a modern constant angular velocity disk drive.
metaslab_unload_delay=32 (uint)
After a metaslab is used, we keep it loaded for this many TXGs, to attempt to reduce
unnecessary reloading. Note that both this many TXGs and metaslab_unload_delay_ms
milliseconds must pass before unloading will occur.
metaslab_unload_delay_ms=600000ms (10 min) (uint)
After a metaslab is used, we keep it loaded for this many milliseconds, to attempt
to reduce unnecessary reloading. Note, that both this many milliseconds and
metaslab_unload_delay TXGs must pass before unloading will occur.
reference_history=3 (uint)
Maximum reference holders being tracked when reference_tracking_enable is active.
reference_tracking_enable=0|1 (int)
Track reference holders to refcount_t objects (debug builds only).
send_holes_without_birth_time=1|0 (int)
When set, the hole_birth optimization will not be used, and all holes will always be
sent during a zfs send. This is useful if you suspect your datasets are affected by
a bug in hole_birth.
spa_config_path=/etc/zfs/zpool.cache (charp)
SPA config file.
spa_asize_inflation=24 (uint)
Multiplication factor used to estimate actual disk consumption from the size of data
being written. The default value is a worst case estimate, but lower values may be
valid for a given pool depending on its configuration. Pool administrators who
understand the factors involved may wish to specify a more realistic inflation
factor, particularly if they operate close to quota or capacity limits.
spa_load_print_vdev_tree=0|1 (int)
Whether to print the vdev tree in the debugging message buffer during pool import.
spa_load_verify_data=1|0 (int)
Whether to traverse data blocks during an "extreme rewind" (-X) import.
An extreme rewind import normally performs a full traversal of all blocks in the
pool for verification. If this parameter is unset, the traversal skips non-metadata
blocks. It can be toggled once the import has started to stop or start the
traversal of non-metadata blocks.
spa_load_verify_metadata=1|0 (int)
Whether to traverse blocks during an "extreme rewind" (-X) pool import.
An extreme rewind import normally performs a full traversal of all blocks in the
pool for verification. If this parameter is unset, the traversal is not performed.
It can be toggled once the import has started to stop or start the traversal.
spa_load_verify_shift=4 (1/16th) (uint)
Sets the maximum number of bytes to consume during pool import to the log2 fraction
of the target ARC size.
spa_slop_shift=5 (1/32nd) (int)
Normally, we don't allow the last 3.2% (1/2^spa_slop_shift) of space in the pool to
be consumed. This ensures that we don't run the pool completely out of space, due
to unaccounted changes (e.g. to the MOS). It also limits the worst-case time to
allocate space. If we have less than this amount of free space, most ZPL operations
(e.g. write, create) will return ENOSPC.
spa_upgrade_errlog_limit=0 (uint)
Limits the number of on-disk error log entries that will be converted to the new
format when enabling the head_errlog feature. The default is to convert all log
entries.
vdev_removal_max_span=32768B (32 KiB) (uint)
During top-level vdev removal, chunks of data are copied from the vdev which may
include free space in order to trade bandwidth for IOPS. This parameter determines
the maximum span of free space, in bytes, which will be included as "unnecessary"
data in a chunk of copied data.
The default value here was chosen to align with zfs_vdev_read_gap_limit, which is a
similar concept when doing regular reads (but there's no reason it has to be the
same).
vdev_file_logical_ashift=9 (512 B) (u64)
Logical ashift for file-based devices.
vdev_file_physical_ashift=9 (512 B) (u64)
Physical ashift for file-based devices.
zap_iterate_prefetch=1|0 (int)
If set, when we start iterating over a ZAP object, prefetch the entire object (all
leaf blocks). However, this is limited by dmu_prefetch_max.
zap_micro_max_size=131072B (128 KiB) (int)
Maximum micro ZAP size. A micro ZAP is upgraded to a fat ZAP, once it grows beyond
the specified size.
zfetch_min_distance=4194304B (4 MiB) (uint)
Min bytes to prefetch per stream. Prefetch distance starts from the demand access
size and quickly grows to this value, doubling on each hit. After that it may grow
further by 1/8 per hit, but only if some prefetch since last time haven't completed
in time to satisfy demand request, i.e. prefetch depth didn't cover the read
latency or the pool got saturated.
zfetch_max_distance=67108864B (64 MiB) (uint)
Max bytes to prefetch per stream.
zfetch_max_idistance=67108864B (64 MiB) (uint)
Max bytes to prefetch indirects for per stream.
zfetch_max_streams=8 (uint)
Max number of streams per zfetch (prefetch streams per file).
zfetch_min_sec_reap=1 (uint)
Min time before inactive prefetch stream can be reclaimed
zfetch_max_sec_reap=2 (uint)
Max time before inactive prefetch stream can be deleted
zfs_abd_scatter_enabled=1|0 (int)
Enables ARC from using scatter/gather lists and forces all allocations to be linear
in kernel memory. Disabling can improve performance in some code paths at the
expense of fragmented kernel memory.
zfs_abd_scatter_max_order=MAX_ORDER-1 (uint)
Maximum number of consecutive memory pages allocated in a single block for
scatter/gather lists.
The value of MAX_ORDER depends on kernel configuration.
zfs_abd_scatter_min_size=1536B (1.5 KiB) (uint)
This is the minimum allocation size that will use scatter (page-based) ABDs.
Smaller allocations will use linear ABDs.
zfs_arc_dnode_limit=0B (u64)
When the number of bytes consumed by dnodes in the ARC exceeds this number of bytes,
try to unpin some of it in response to demand for non-metadata. This value acts as
a ceiling to the amount of dnode metadata, and defaults to 0, which indicates that a
percent which is based on zfs_arc_dnode_limit_percent of the ARC meta buffers that
may be used for dnodes.
zfs_arc_dnode_limit_percent=10% (u64)
Percentage that can be consumed by dnodes of ARC meta buffers.
See also zfs_arc_dnode_limit, which serves a similar purpose but has a higher
priority if nonzero.
zfs_arc_dnode_reduce_percent=10% (u64)
Percentage of ARC dnodes to try to scan in response to demand for non-metadata when
the number of bytes consumed by dnodes exceeds zfs_arc_dnode_limit.
zfs_arc_average_blocksize=8192B (8 KiB) (uint)
The ARC's buffer hash table is sized based on the assumption of an average block
size of this value. This works out to roughly 1 MiB of hash table per 1 GiB of
physical memory with 8-byte pointers. For configurations with a known larger
average block size, this value can be increased to reduce the memory footprint.
zfs_arc_eviction_pct=200% (uint)
When arc_is_overflowing(), arc_get_data_impl() waits for this percent of the
requested amount of data to be evicted. For example, by default, for every 2 KiB
that's evicted, 1 KiB of it may be "reused" by a new allocation. Since this is
above 100%, it ensures that progress is made towards getting arc_size under arc_c.
Since this is finite, it ensures that allocations can still happen, even during the
potentially long time that arc_size is more than arc_c.
zfs_arc_evict_batch_limit=10 (uint)
Number ARC headers to evict per sub-list before proceeding to another sub-list.
This batch-style operation prevents entire sub-lists from being evicted at once but
comes at a cost of additional unlocking and locking.
zfs_arc_grow_retry=0s (uint)
If set to a non zero value, it will replace the arc_grow_retry value with this
value. The arc_grow_retry value (default 5s) is the number of seconds the ARC will
wait before trying to resume growth after a memory pressure event.
zfs_arc_lotsfree_percent=10% (int)
Throttle I/O when free system memory drops below this percentage of total system
memory. Setting this value to 0 will disable the throttle.
zfs_arc_max=0B (u64)
Max size of ARC in bytes. If 0, then the max size of ARC is determined by the
amount of system memory installed. Under Linux, half of system memory will be used
as the limit. Under FreeBSD, the larger of all_system_memory - 1 GiB and 5/8 ×
all_system_memory will be used as the limit. This value must be at least 67108864B
(64 MiB).
This value can be changed dynamically, with some caveats. It cannot be set back to
0 while running, and reducing it below the current ARC size will not cause the ARC
to shrink without memory pressure to induce shrinking.
zfs_arc_meta_balance=500 (uint)
Balance between metadata and data on ghost hits. Values above 100 increase metadata
caching by proportionally reducing effect of ghost data hits on target data/metadata
rate.
zfs_arc_min=0B (u64)
Min size of ARC in bytes. If set to 0, arc_c_min will default to consuming the
larger of 32 MiB and all_system_memory / 32.
zfs_arc_min_prefetch_ms=0ms(≡1s) (uint)
Minimum time prefetched blocks are locked in the ARC.
zfs_arc_min_prescient_prefetch_ms=0ms(≡6s) (uint)
Minimum time "prescient prefetched" blocks are locked in the ARC. These blocks are
meant to be prefetched fairly aggressively ahead of the code that may use them.
zfs_arc_prune_task_threads=1 (int)
Number of arc_prune threads. FreeBSD does not need more than one. Linux may
theoretically use one per mount point up to number of CPUs, but that was not proven
to be useful.
zfs_max_missing_tvds=0 (int)
Number of missing top-level vdevs which will be allowed during pool import (only in
read-only mode).
zfs_max_nvlist_src_size= 0 (u64)
Maximum size in bytes allowed to be passed as zc_nvlist_src_size for ioctls on
/dev/zfs. This prevents a user from causing the kernel to allocate an excessive
amount of memory. When the limit is exceeded, the ioctl fails with EINVAL and a
description of the error is sent to the zfs-dbgmsg log. This parameter should not
need to be touched under normal circumstances. If 0, equivalent to a quarter of the
user-wired memory limit under FreeBSD and to 134217728B (128 MiB) under Linux.
zfs_multilist_num_sublists=0 (uint)
To allow more fine-grained locking, each ARC state contains a series of lists for
both data and metadata objects. Locking is performed at the level of these "sub-
lists". This parameters controls the number of sub-lists per ARC state, and also
applies to other uses of the multilist data structure.
If 0, equivalent to the greater of the number of online CPUs and 4.
zfs_arc_overflow_shift=8 (int)
The ARC size is considered to be overflowing if it exceeds the current ARC target
size (arc_c) by thresholds determined by this parameter. Exceeding by (arc_c >>
zfs_arc_overflow_shift) / 2 starts ARC reclamation process. If that appears
insufficient, exceeding by (arc_c >> zfs_arc_overflow_shift) × 1.5 blocks new buffer
allocation until the reclaim thread catches up. Started reclamation process
continues till ARC size returns below the target size.
The default value of 8 causes the ARC to start reclamation if it exceeds the target
size by 0.2% of the target size, and block allocations by 0.6%.
zfs_arc_shrink_shift=0 (uint)
If nonzero, this will update arc_shrink_shift (default 7) with the new value.
zfs_arc_pc_percent=0% (off) (uint)
Percent of pagecache to reclaim ARC to.
This tunable allows the ZFS ARC to play more nicely with the kernel's LRU pagecache.
It can guarantee that the ARC size won't collapse under scanning pressure on the
pagecache, yet still allows the ARC to be reclaimed down to zfs_arc_min if
necessary. This value is specified as percent of pagecache size (as measured by
NR_FILE_PAGES), where that percent may exceed 100. This only operates during memory
pressure/reclaim.
zfs_arc_shrinker_limit=10000 (int)
This is a limit on how many pages the ARC shrinker makes available for eviction in
response to one page allocation attempt. Note that in practice, the kernel's
shrinker can ask us to evict up to about four times this for one allocation attempt.
The default limit of 10000 (in practice, 160 MiB per allocation attempt with 4 KiB
pages) limits the amount of time spent attempting to reclaim ARC memory to less than
100 ms per allocation attempt, even with a small average compressed block size of ~8
KiB.
The parameter can be set to 0 (zero) to disable the limit, and only applies on
Linux.
zfs_arc_sys_free=0B (u64)
The target number of bytes the ARC should leave as free memory on the system. If
zero, equivalent to the bigger of 512 KiB and all_system_memory/64.
zfs_autoimport_disable=1|0 (int)
Disable pool import at module load by ignoring the cache file (spa_config_path).
zfs_checksum_events_per_second=20/s (uint)
Rate limit checksum events to this many per second. Note that this should not be
set below the ZED thresholds (currently 10 checksums over 10 seconds) or else the
daemon may not trigger any action.
zfs_commit_timeout_pct=5% (uint)
This controls the amount of time that a ZIL block (lwb) will remain "open" when it
isn't "full", and it has a thread waiting for it to be committed to stable storage.
The timeout is scaled based on a percentage of the last lwb latency to avoid
significantly impacting the latency of each individual transaction record (itx).
zfs_condense_indirect_commit_entry_delay_ms=0ms (int)
Vdev indirection layer (used for device removal) sleeps for this many milliseconds
during mapping generation. Intended for use with the test suite to throttle vdev
removal speed.
zfs_condense_indirect_obsolete_pct=25% (uint)
Minimum percent of obsolete bytes in vdev mapping required to attempt to condense
(see zfs_condense_indirect_vdevs_enable). Intended for use with the test suite to
facilitate triggering condensing as needed.
zfs_condense_indirect_vdevs_enable=1|0 (int)
Enable condensing indirect vdev mappings. When set, attempt to condense indirect
vdev mappings if the mapping uses more than zfs_condense_min_mapping_bytes bytes of
memory and if the obsolete space map object uses more than
zfs_condense_max_obsolete_bytes bytes on-disk. The condensing process is an attempt
to save memory by removing obsolete mappings.
zfs_condense_max_obsolete_bytes=1073741824B (1 GiB) (u64)
Only attempt to condense indirect vdev mappings if the on-disk size of the obsolete
space map object is greater than this number of bytes (see
zfs_condense_indirect_vdevs_enable).
zfs_condense_min_mapping_bytes=131072B (128 KiB) (u64)
Minimum size vdev mapping to attempt to condense (see
zfs_condense_indirect_vdevs_enable).
zfs_dbgmsg_enable=1|0 (int)
Internally ZFS keeps a small log to facilitate debugging. The log is enabled by
default, and can be disabled by unsetting this option. The contents of the log can
be accessed by reading /proc/spl/kstat/zfs/dbgmsg. Writing 0 to the file clears the
log.
This setting does not influence debug prints due to zfs_flags.
zfs_dbgmsg_maxsize=4194304B (4 MiB) (uint)
Maximum size of the internal ZFS debug log.
zfs_dbuf_state_index=0 (int)
Historically used for controlling what reporting was available under
/proc/spl/kstat/zfs. No effect.
zfs_deadman_enabled=1|0 (int)
When a pool sync operation takes longer than zfs_deadman_synctime_ms, or when an
individual I/O operation takes longer than zfs_deadman_ziotime_ms, then the
operation is considered to be "hung". If zfs_deadman_enabled is set, then the
deadman behavior is invoked as described by zfs_deadman_failmode. By default, the
deadman is enabled and set to wait which results in "hung" I/O operations only being
logged. The deadman is automatically disabled when a pool gets suspended.
zfs_deadman_failmode=wait (charp)
Controls the failure behavior when the deadman detects a "hung" I/O operation.
Valid values are:
wait Wait for a "hung" operation to complete. For each "hung" operation a
"deadman" event will be posted describing that operation.
continue Attempt to recover from a "hung" operation by re-dispatching it to the
I/O pipeline if possible.
panic Panic the system. This can be used to facilitate automatic fail-over
to a properly configured fail-over partner.
zfs_deadman_checktime_ms=60000ms (1 min) (u64)
Check time in milliseconds. This defines the frequency at which we check for hung
I/O requests and potentially invoke the zfs_deadman_failmode behavior.
zfs_deadman_synctime_ms=600000ms (10 min) (u64)
Interval in milliseconds after which the deadman is triggered and also the interval
after which a pool sync operation is considered to be "hung". Once this limit is
exceeded the deadman will be invoked every zfs_deadman_checktime_ms milliseconds
until the pool sync completes.
zfs_deadman_ziotime_ms=300000ms (5 min) (u64)
Interval in milliseconds after which the deadman is triggered and an individual I/O
operation is considered to be "hung". As long as the operation remains "hung", the
deadman will be invoked every zfs_deadman_checktime_ms milliseconds until the
operation completes.
zfs_dedup_prefetch=0|1 (int)
Enable prefetching dedup-ed blocks which are going to be freed.
zfs_delay_min_dirty_percent=60% (uint)
Start to delay each transaction once there is this amount of dirty data, expressed
as a percentage of zfs_dirty_data_max. This value should be at least
zfs_vdev_async_write_active_max_dirty_percent. See ZFS TRANSACTION DELAY.
zfs_delay_scale=500000 (int)
This controls how quickly the transaction delay approaches infinity. Larger values
cause longer delays for a given amount of dirty data.
For the smoothest delay, this value should be about 1 billion divided by the maximum
number of operations per second. This will smoothly handle between ten times and a
tenth of this number. See ZFS TRANSACTION DELAY.
zfs_delay_scale × zfs_dirty_data_max must be smaller than 2^64.
zfs_disable_ivset_guid_check=0|1 (int)
Disables requirement for IVset GUIDs to be present and match when doing a raw
receive of encrypted datasets. Intended for users whose pools were created with
OpenZFS pre-release versions and now have compatibility issues.
zfs_key_max_salt_uses=400000000 (4*10^8) (ulong)
Maximum number of uses of a single salt value before generating a new one for
encrypted datasets. The default value is also the maximum.
zfs_object_mutex_size=64 (uint)
Size of the znode hashtable used for holds.
Due to the need to hold locks on objects that may not exist yet, kernel mutexes are
not created per-object and instead a hashtable is used where collisions will result
in objects waiting when there is not actually contention on the same object.
zfs_slow_io_events_per_second=20/s (int)
Rate limit delay and deadman zevents (which report slow I/O operations) to this many
per second.
zfs_unflushed_max_mem_amt=1073741824B (1 GiB) (u64)
Upper-bound limit for unflushed metadata changes to be held by the log spacemap in
memory, in bytes.
zfs_unflushed_max_mem_ppm=1000ppm (0.1%) (u64)
Part of overall system memory that ZFS allows to be used for unflushed metadata
changes by the log spacemap, in millionths.
zfs_unflushed_log_block_max=131072 (128k) (u64)
Describes the maximum number of log spacemap blocks allowed for each pool. The
default value means that the space in all the log spacemaps can add up to no more
than 131072 blocks (which means 16 GiB of logical space before compression and ditto
blocks, assuming that blocksize is 128 KiB).
This tunable is important because it involves a trade-off between import time after
an unclean export and the frequency of flushing metaslabs. The higher this number
is, the more log blocks we allow when the pool is active which means that we flush
metaslabs less often and thus decrease the number of I/O operations for spacemap
updates per TXG. At the same time though, that means that in the event of an
unclean export, there will be more log spacemap blocks for us to read, inducing
overhead in the import time of the pool. The lower the number, the amount of
flushing increases, destroying log blocks quicker as they become obsolete faster,
which leaves less blocks to be read during import time after a crash.
Each log spacemap block existing during pool import leads to approximately one extra
logical I/O issued. This is the reason why this tunable is exposed in terms of
blocks rather than space used.
zfs_unflushed_log_block_min=1000 (u64)
If the number of metaslabs is small and our incoming rate is high, we could get into
a situation that we are flushing all our metaslabs every TXG. Thus we always allow
at least this many log blocks.
zfs_unflushed_log_block_pct=400% (u64)
Tunable used to determine the number of blocks that can be used for the spacemap
log, expressed as a percentage of the total number of unflushed metaslabs in the
pool.
zfs_unflushed_log_txg_max=1000 (u64)
Tunable limiting maximum time in TXGs any metaslab may remain unflushed. It
effectively limits maximum number of unflushed per-TXG spacemap logs that need to be
read after unclean pool export.
zfs_unlink_suspend_progress=0|1 (uint)
When enabled, files will not be asynchronously removed from the list of pending
unlinks and the space they consume will be leaked. Once this option has been
disabled and the dataset is remounted, the pending unlinks will be processed and the
freed space returned to the pool. This option is used by the test suite.
zfs_delete_blocks=20480 (ulong)
This is the used to define a large file for the purposes of deletion. Files
containing more than zfs_delete_blocks will be deleted asynchronously, while smaller
files are deleted synchronously. Decreasing this value will reduce the time spent
in an unlink(2) system call, at the expense of a longer delay before the freed space
is available. This only applies on Linux.
zfs_dirty_data_max= (int)
Determines the dirty space limit in bytes. Once this limit is exceeded, new writes
are halted until space frees up. This parameter takes precedence over
zfs_dirty_data_max_percent. See ZFS TRANSACTION DELAY.
Defaults to physical_ram/10, capped at zfs_dirty_data_max_max.
zfs_dirty_data_max_max= (int)
Maximum allowable value of zfs_dirty_data_max, expressed in bytes. This limit is
only enforced at module load time, and will be ignored if zfs_dirty_data_max is
later changed. This parameter takes precedence over zfs_dirty_data_max_max_percent.
See ZFS TRANSACTION DELAY.
Defaults to min(physical_ram/4, 4GiB), or min(physical_ram/4, 1GiB) for 32-bit
systems.
zfs_dirty_data_max_max_percent=25% (uint)
Maximum allowable value of zfs_dirty_data_max, expressed as a percentage of physical
RAM. This limit is only enforced at module load time, and will be ignored if
zfs_dirty_data_max is later changed. The parameter zfs_dirty_data_max_max takes
precedence over this one. See ZFS TRANSACTION DELAY.
zfs_dirty_data_max_percent=10% (uint)
Determines the dirty space limit, expressed as a percentage of all memory. Once
this limit is exceeded, new writes are halted until space frees up. The parameter
zfs_dirty_data_max takes precedence over this one. See ZFS TRANSACTION DELAY.
Subject to zfs_dirty_data_max_max.
zfs_dirty_data_sync_percent=20% (uint)
Start syncing out a transaction group if there's at least this much dirty data (as a
percentage of zfs_dirty_data_max). This should be less than
zfs_vdev_async_write_active_min_dirty_percent.
zfs_wrlog_data_max= (int)
The upper limit of write-transaction zil log data size in bytes. Write operations
are throttled when approaching the limit until log data is cleared out after
transaction group sync. Because of some overhead, it should be set at least 2 times
the size of zfs_dirty_data_max to prevent harming normal write throughput. It also
should be smaller than the size of the slog device if slog is present.
Defaults to zfs_dirty_data_max*2
zfs_fallocate_reserve_percent=110% (uint)
Since ZFS is a copy-on-write filesystem with snapshots, blocks cannot be
preallocated for a file in order to guarantee that later writes will not run out of
space. Instead, fallocate(2) space preallocation only checks that sufficient space
is currently available in the pool or the user's project quota allocation, and then
creates a sparse file of the requested size. The requested space is multiplied by
zfs_fallocate_reserve_percent to allow additional space for indirect blocks and
other internal metadata. Setting this to 0 disables support for fallocate(2) and
causes it to return EOPNOTSUPP.
zfs_fletcher_4_impl=fastest (string)
Select a fletcher 4 implementation.
Supported selectors are: fastest, scalar, sse2, ssse3, avx2, avx512f, avx512bw, and
aarch64_neon. All except fastest and scalar require instruction set extensions to
be available, and will only appear if ZFS detects that they are present at runtime.
If multiple implementations of fletcher 4 are available, the fastest will be chosen
using a micro benchmark. Selecting scalar results in the original CPU-based
calculation being used. Selecting any option other than fastest or scalar results
in vector instructions from the respective CPU instruction set being used.
zfs_bclone_enabled=1|0 (int)
Enable the experimental block cloning feature. If this setting is 0, then even if
feature@block_cloning is enabled, attempts to clone blocks will act as though the
feature is disabled.
zfs_blake3_impl=fastest (string)
Select a BLAKE3 implementation.
Supported selectors are: cycle, fastest, generic, sse2, sse41, avx2, avx512. All
except cycle, fastest and generic require instruction set extensions to be
available, and will only appear if ZFS detects that they are present at runtime. If
multiple implementations of BLAKE3 are available, the fastest will be chosen using a
micro benchmark. You can see the benchmark results by reading this kstat file:
/proc/spl/kstat/zfs/chksum_bench.
zfs_free_bpobj_enabled=1|0 (int)
Enable/disable the processing of the free_bpobj object.
zfs_async_block_max_blocks=UINT64_MAX (unlimited) (u64)
Maximum number of blocks freed in a single TXG.
zfs_max_async_dedup_frees=100000 (10^5) (u64)
Maximum number of dedup blocks freed in a single TXG.
zfs_vdev_async_read_max_active=3 (uint)
Maximum asynchronous read I/O operations active to each device. See ZFS I/O
SCHEDULER.
zfs_vdev_async_read_min_active=1 (uint)
Minimum asynchronous read I/O operation active to each device. See ZFS I/O
SCHEDULER.
zfs_vdev_async_write_active_max_dirty_percent=60% (uint)
When the pool has more than this much dirty data, use
zfs_vdev_async_write_max_active to limit active async writes. If the dirty data is
between the minimum and maximum, the active I/O limit is linearly interpolated. See
ZFS I/O SCHEDULER.
zfs_vdev_async_write_active_min_dirty_percent=30% (uint)
When the pool has less than this much dirty data, use
zfs_vdev_async_write_min_active to limit active async writes. If the dirty data is
between the minimum and maximum, the active I/O limit is linearly interpolated. See
ZFS I/O SCHEDULER.
zfs_vdev_async_write_max_active=10 (uint)
Maximum asynchronous write I/O operations active to each device. See ZFS I/O
SCHEDULER.
zfs_vdev_async_write_min_active=2 (uint)
Minimum asynchronous write I/O operations active to each device. See ZFS I/O
SCHEDULER.
Lower values are associated with better latency on rotational media but poorer
resilver performance. The default value of 2 was chosen as a compromise. A value
of 3 has been shown to improve resilver performance further at a cost of further
increasing latency.
zfs_vdev_initializing_max_active=1 (uint)
Maximum initializing I/O operations active to each device. See ZFS I/O SCHEDULER.
zfs_vdev_initializing_min_active=1 (uint)
Minimum initializing I/O operations active to each device. See ZFS I/O SCHEDULER.
zfs_vdev_max_active=1000 (uint)
The maximum number of I/O operations active to each device. Ideally, this will be
at least the sum of each queue's max_active. See ZFS I/O SCHEDULER.
zfs_vdev_open_timeout_ms=1000 (uint)
Timeout value to wait before determining a device is missing during import. This is
helpful for transient missing paths due to links being briefly removed and recreated
in response to udev events.
zfs_vdev_rebuild_max_active=3 (uint)
Maximum sequential resilver I/O operations active to each device. See ZFS I/O
SCHEDULER.
zfs_vdev_rebuild_min_active=1 (uint)
Minimum sequential resilver I/O operations active to each device. See ZFS I/O
SCHEDULER.
zfs_vdev_removal_max_active=2 (uint)
Maximum removal I/O operations active to each device. See ZFS I/O SCHEDULER.
zfs_vdev_removal_min_active=1 (uint)
Minimum removal I/O operations active to each device. See ZFS I/O SCHEDULER.
zfs_vdev_scrub_max_active=2 (uint)
Maximum scrub I/O operations active to each device. See ZFS I/O SCHEDULER.
zfs_vdev_scrub_min_active=1 (uint)
Minimum scrub I/O operations active to each device. See ZFS I/O SCHEDULER.
zfs_vdev_sync_read_max_active=10 (uint)
Maximum synchronous read I/O operations active to each device. See ZFS I/O
SCHEDULER.
zfs_vdev_sync_read_min_active=10 (uint)
Minimum synchronous read I/O operations active to each device. See ZFS I/O
SCHEDULER.
zfs_vdev_sync_write_max_active=10 (uint)
Maximum synchronous write I/O operations active to each device. See ZFS I/O
SCHEDULER.
zfs_vdev_sync_write_min_active=10 (uint)
Minimum synchronous write I/O operations active to each device. See ZFS I/O
SCHEDULER.
zfs_vdev_trim_max_active=2 (uint)
Maximum trim/discard I/O operations active to each device. See ZFS I/O SCHEDULER.
zfs_vdev_trim_min_active=1 (uint)
Minimum trim/discard I/O operations active to each device. See ZFS I/O SCHEDULER.
zfs_vdev_nia_delay=5 (uint)
For non-interactive I/O (scrub, resilver, removal, initialize and rebuild), the
number of concurrently-active I/O operations is limited to zfs_*_min_active, unless
the vdev is "idle". When there are no interactive I/O operations active
(synchronous or otherwise), and zfs_vdev_nia_delay operations have completed since
the last interactive operation, then the vdev is considered to be "idle", and the
number of concurrently-active non-interactive operations is increased to
zfs_*_max_active. See ZFS I/O SCHEDULER.
zfs_vdev_nia_credit=5 (uint)
Some HDDs tend to prioritize sequential I/O so strongly, that concurrent random I/O
latency reaches several seconds. On some HDDs this happens even if sequential I/O
operations are submitted one at a time, and so setting zfs_*_max_active= 1 does not
help. To prevent non-interactive I/O, like scrub, from monopolizing the device, no
more than zfs_vdev_nia_credit operations can be sent while there are outstanding
incomplete interactive operations. This enforced wait ensures the HDD services the
interactive I/O within a reasonable amount of time. See ZFS I/O SCHEDULER.
zfs_vdev_queue_depth_pct=1000% (uint)
Maximum number of queued allocations per top-level vdev expressed as a percentage of
zfs_vdev_async_write_max_active, which allows the system to detect devices that are
more capable of handling allocations and to allocate more blocks to those devices.
This allows for dynamic allocation distribution when devices are imbalanced, as
fuller devices will tend to be slower than empty devices.
Also see zio_dva_throttle_enabled.
zfs_vdev_def_queue_depth=32 (uint)
Default queue depth for each vdev IO allocator. Higher values allow for better
coalescing of sequential writes before sending them to the disk, but can increase
transaction commit times.
zfs_vdev_failfast_mask=1 (uint)
Defines if the driver should retire on a given error type. The following options
may be bitwise-ored together:
┌───────────────────────────────────────────────────────────────┐
│ Value Name Description │
├───────────────────────────────────────────────────────────────┤
│ 1 Device No driver retries on device errors │
│ 2 Transport No driver retries on transport errors. │
│ 4 Driver No driver retries on driver errors. │
└───────────────────────────────────────────────────────────────┘
zfs_expire_snapshot=300s (int)
Time before expiring .zfs/snapshot.
zfs_admin_snapshot=0|1 (int)
Allow the creation, removal, or renaming of entries in the .zfs/snapshot directory
to cause the creation, destruction, or renaming of snapshots. When enabled, this
functionality works both locally and over NFS exports which have the no_root_squash
option set.
zfs_flags=0 (int)
Set additional debugging flags. The following flags may be bitwise-ored together:
┌──────────────────────────────────────────────────────────────────────────────────────────────────────────┐
│ Value Name Description │
├──────────────────────────────────────────────────────────────────────────────────────────────────────────┤
│ 1 ZFS_DEBUG_DPRINTF Enable dprintf entries in the debug log. │
│* 2 ZFS_DEBUG_DBUF_VERIFY Enable extra dbuf verifications. │
│* 4 ZFS_DEBUG_DNODE_VERIFY Enable extra dnode verifications. │
│ 8 ZFS_DEBUG_SNAPNAMES Enable snapshot name verification. │
│* 16 ZFS_DEBUG_MODIFY Check for illegally modified ARC buffers. │
│ 64 ZFS_DEBUG_ZIO_FREE Enable verification of block frees. │
│ 128 ZFS_DEBUG_HISTOGRAM_VERIFY Enable extra spacemap histogram verifications. │
│ 256 ZFS_DEBUG_METASLAB_VERIFY Verify space accounting on disk matches in-memory range_trees. │
│ 512 ZFS_DEBUG_SET_ERROR Enable SET_ERROR and dprintf entries in the debug log. │
│ 1024 ZFS_DEBUG_INDIRECT_REMAP Verify split blocks created by device removal. │
│ 2048 ZFS_DEBUG_TRIM Verify TRIM ranges are always within the allocatable range tree. │
│ 4096 ZFS_DEBUG_LOG_SPACEMAP Verify that the log summary is consistent with the spacemap log │
│ and enable zfs_dbgmsgs for metaslab loading and flushing. │
--
ZFS I/O SCHEDULER
ZFS issues I/O operations to leaf vdevs to satisfy and complete I/O operations. The
scheduler determines when and in what order those operations are issued. The scheduler
divides operations into five I/O classes, prioritized in the following order: sync read,
sync write, async read, async write, and scrub/resilver. Each queue defines the minimum and
maximum number of concurrent operations that may be issued to the device. In addition, the
device has an aggregate maximum, zfs_vdev_max_active. Note that the sum of the per-queue
minima must not exceed the aggregate maximum. If the sum of the per-queue maxima exceeds
the aggregate maximum, then the number of active operations may reach zfs_vdev_max_active,
in which case no further operations will be issued, regardless of whether all per-queue
minima have been met.
For many physical devices, throughput increases with the number of concurrent operations,
but latency typically suffers. Furthermore, physical devices typically have a limit at
which more concurrent operations have no effect on throughput or can actually cause it to
decrease.
The scheduler selects the next operation to issue by first looking for an I/O class whose
minimum has not been satisfied. Once all are satisfied and the aggregate maximum has not
been hit, the scheduler looks for classes whose maximum has not been satisfied. Iteration
through the I/O classes is done in the order specified above. No further operations are
issued if the aggregate maximum number of concurrent operations has been hit, or if there
are no operations queued for an I/O class that has not hit its maximum. Every time an I/O
operation is queued or an operation completes, the scheduler looks for new operations to
issue.
In general, smaller max_actives will lead to lower latency of synchronous operations.
Larger max_actives may lead to higher overall throughput, depending on underlying storage.
The ratio of the queues' max_actives determines the balance of performance between reads,
writes, and scrubs. For example, increasing zfs_vdev_scrub_max_active will cause the scrub
or resilver to complete more quickly, but reads and writes to have higher latency and lower
throughput.
All I/O classes have a fixed maximum number of outstanding operations, except for the async
write class. Asynchronous writes represent the data that is committed to stable storage
during the syncing stage for transaction groups. Transaction groups enter the syncing state
periodically, so the number of queued async writes will quickly burst up and then bleed down
to zero. Rather than servicing them as quickly as possible, the I/O scheduler changes the
maximum number of active async write operations according to the amount of dirty data in the
pool. Since both throughput and latency typically increase with the number of concurrent
operations issued to physical devices, reducing the burstiness in the number of simultaneous
operations also stabilizes the response time of operations from other queues, in particular
synchronous ones. In broad strokes, the I/O scheduler will issue more concurrent operations
from the async write queue as there is more dirty data in the pool.
Async Writes
The number of concurrent operations issued for the async write I/O class follows a piece-
wise linear function defined by a few adjustable points:
| o---------| <-- zfs_vdev_async_write_max_active
^ | /^ |
| | / | |
active | / | |
I/O | / | |
count | / | |
| / | |
|-------o | | <-- zfs_vdev_async_write_min_active
0|_______^______|_________|
0% | | 100% of zfs_dirty_data_max
| |
| `-- zfs_vdev_async_write_active_max_dirty_percent
`--------- zfs_vdev_async_write_active_min_dirty_percent
Until the amount of dirty data exceeds a minimum percentage of the dirty data allowed in the
pool, the I/O scheduler will limit the number of concurrent operations to the minimum. As
that threshold is crossed, the number of concurrent operations issued increases linearly to
the maximum at the specified maximum percentage of the dirty data allowed in the pool.
Ideally, the amount of dirty data on a busy pool will stay in the sloped part of the
function between zfs_vdev_async_write_active_min_dirty_percent and
zfs_vdev_async_write_active_max_dirty_percent. If it exceeds the maximum percentage, this
indicates that the rate of incoming data is greater than the rate that the backend storage
can handle. In this case, we must further throttle incoming writes, as described in the
next section.
ZFS TRANSACTION DELAY
We delay transactions when we've determined that the backend storage isn't able to
accommodate the rate of incoming writes.
If there is already a transaction waiting, we delay relative to when that transaction will
finish waiting. This way the calculated delay time is independent of the number of threads
concurrently executing transactions.
If we are the only waiter, wait relative to when the transaction started, rather than the
current time. This credits the transaction for "time already served", e.g. reading indirect
blocks.
The minimum time for a transaction to take is calculated as
min_time = min(zfs_delay_scale × (dirty - min) / (max - dirty), 100ms)
The delay has two degrees of freedom that can be adjusted via tunables. The percentage of
dirty data at which we start to delay is defined by zfs_delay_min_dirty_percent. This
should typically be at or above zfs_vdev_async_write_active_max_dirty_percent, so that we
only start to delay after writing at full speed has failed to keep up with the incoming
write rate. The scale of the curve is defined by zfs_delay_scale. Roughly speaking, this
variable determines the amount of delay at the midpoint of the curve.
delay
10ms +-------------------------------------------------------------*+
| *|
9ms + *+
| *|
8ms + *+
| * |
7ms + * +
| * |
6ms + * +
| * |
5ms + * +
| * |
4ms + * +
| * |
3ms + * +
| * |
2ms + (midpoint) * +
| | ** |
1ms + v *** +
| zfs_delay_scale ----------> ******** |
0 +-------------------------------------*********----------------+
0% <- zfs_dirty_data_max -> 100%
Note, that since the delay is added to the outstanding time remaining on the most recent
transaction it's effectively the inverse of IOPS. Here, the midpoint of 500 us translates
to 2000 IOPS. The shape of the curve was chosen such that small changes in the amount of
accumulated dirty data in the first three quarters of the curve yield relatively small
differences in the amount of delay.
The effects can be easier to understand when the amount of delay is represented on a
logarithmic scale:
delay
100ms +-------------------------------------------------------------++
+ +
| |
+ *+
10ms + *+
+ ** +
| (midpoint) ** |
+ | ** +
1ms + v **** +
+ zfs_delay_scale ----------> ***** +
| **** |
+ **** +
100us + ** +
+ * +
| * |
+ * +
10us + * +
+ +
| |
+ +
+--------------------------------------------------------------+
0% <- zfs_dirty_data_max -> 100%
Note here that only as the amount of dirty data approaches its limit does the delay start to
increase rapidly. The goal of a properly tuned system should be to keep the amount of dirty
data out of that range by first ensuring that the appropriate limits are set for the I/O
scheduler to reach optimal throughput on the back-end storage, and then by changing the
value of zfs_delay_scale to increase the steepness of the curve.