Most of the ZFS kernel module parameters are accessible in the SysFS
/sys/module/zfs/parameters
directory. Current values can be observed
by
cat /sys/module/zfs/parameters/PARAMETER
Many of these can be changed by writing new values. These are denoted by Change|Dynamic in the PARAMETER details below.
echo NEWVALUE >> /sys/module/zfs/parameters/PARAMETER
If the parameter is not dynamically adjustable, an error can occur and the value will not be set. It can be helpful to check the permissions for the PARAMETER file in SysFS.
In some cases, the parameter must be set prior to loading the kernel
modules or it is desired to have the parameters set automatically at
boot time. For many distros, this can be accomplished by creating a file
named /etc/modprobe.d/zfs.conf
containing a text line for each
module parameter using the format:
# change PARAMETER for workload XZY to solve problem PROBLEM_DESCRIPTION # changed by YOUR_NAME on DATE options zfs PARAMETER=VALUE
Some parameters related to ZFS operations are located in module
parameters other than in the zfs
kernel module. These are documented
in the individual parameter description. Unless otherwise noted, the
tunable applies to the zfs
kernel module. For example, the icp
kernel module parameters are visible in the
/sys/module/icp/parameters
directory and can be set by default at
boot time by changing the /etc/modprobe.d/icp.conf
file.
See the man page for modprobe.d for more information.
The zfs(4) and spl(4) man
pages (previously zfs-
and spl-module-parameters(5)
, respectively,
prior to OpenZFS 2.1) contain brief descriptions of
the module parameters. Alas, man pages are not as suitable for quick
reference as documentation pages. This page is intended to be a better
cross-reference and capture some of the wisdom of ZFS developers and
practitioners.
The ZFS kernel module, zfs.ko
, parameters are detailed below.
To observe the list of parameters along with a short synopsis of each
parameter, use the modinfo
command:
modinfo zfs
The list of parameters is quite large and resists hierarchical representation. To assist in finding relevant information quickly, each module parameter has a "Tags" row with keywords for frequent searches.
- dmu_object_alloc_chunk_shift
- metaslab_aliquot
- metaslab_bias_enabled
- metaslab_debug_load
- metaslab_debug_unload
- metaslab_force_ganging
- metaslab_fragmentation_factor_enabled
- zfs_metaslab_fragmentation_threshold
- metaslab_lba_weighting_enabled
- metaslab_preload_enabled
- zfs_metaslab_segment_weight_enabled
- zfs_metaslab_switch_threshold
- metaslabs_per_vdev
- zfs_mg_fragmentation_threshold
- zfs_mg_noalloc_threshold
- spa_asize_inflation
- spa_load_verify_data
- spa_slop_shift
- zfs_vdev_default_ms_count
- zfs_abd_scatter_min_size
- zfs_arc_average_blocksize
- zfs_arc_dnode_limit
- zfs_arc_dnode_limit_percent
- zfs_arc_dnode_reduce_percent
- zfs_arc_evict_batch_limit
- zfs_arc_grow_retry
- zfs_arc_lotsfree_percent
- zfs_arc_max
- zfs_arc_meta_adjust_restarts
- zfs_arc_meta_limit
- zfs_arc_meta_limit_percent
- zfs_arc_meta_min
- zfs_arc_meta_prune
- zfs_arc_meta_strategy
- zfs_arc_min
- zfs_arc_min_prefetch_lifespan
- zfs_arc_min_prefetch_ms
- zfs_arc_min_prescient_prefetch_ms
- zfs_arc_overflow_shift
- zfs_arc_p_dampener_disable
- zfs_arc_p_min_shift
- zfs_arc_pc_percent
- zfs_arc_shrink_shift
- zfs_arc_sys_free
- dbuf_cache_max_bytes
- dbuf_cache_shift
- dbuf_metadata_cache_shift
- zfs_disable_dup_eviction
- l2arc_exclude_special
- l2arc_feed_again
- l2arc_feed_min_ms
- l2arc_feed_secs
- l2arc_headroom
- l2arc_headroom_boost
- l2arc_meta_percent
- l2arc_mfuonly
- l2arc_nocompress
- l2arc_noprefetch
- l2arc_norw
- l2arc_rebuild_blocks_min_l2size
- l2arc_rebuild_enabled
- l2arc_trim_ahead
- l2arc_write_boost
- l2arc_write_max
- zfs_multilist_num_sublists
- spa_load_verify_shift
- zfs_fletcher_4_impl
- zfs_mdcomp_disable
- spl_kmem_cache_kmem_threads
- spl_kmem_cache_magazine_size
- spl_taskq_thread_bind
- spl_taskq_thread_priority
- spl_taskq_thread_sequential
- zfs_vdev_raidz_impl
- dbuf_cache_hiwater_pct
- dbuf_cache_lowater_pct
- dbuf_cache_max_bytes
- dbuf_cache_max_bytes
- dbuf_cache_max_shift
- dbuf_cache_shift
- dbuf_metadata_cache_max_bytes
- dbuf_metadata_cache_shift
- zfs_dbgmsg_enable
- zfs_dbgmsg_maxsize
- zfs_dbuf_state_index
- zfs_deadman_checktime_ms
- zfs_deadman_enabled
- zfs_deadman_failmode
- zfs_deadman_synctime_ms
- zfs_deadman_ziotime_ms
- zfs_flags
- zfs_free_leak_on_eio
- zfs_nopwrite_enabled
- zfs_object_mutex_size
- zfs_read_history
- zfs_read_history_hits
- spl_panic_halt
- zfs_txg_history
- zfs_zevent_cols
- zfs_zevent_console
- zfs_zevent_len_max
- zil_replay_disable
- zio_deadman_log_all
- zio_decompress_fail_fraction
- zio_delay_max
- zfs_async_block_max_blocks
- zfs_delete_blocks
- zfs_free_bpobj_enabled
- zfs_free_max_blocks
- zfs_free_min_time_ms
- zfs_obsolete_min_time_ms
- zfs_per_txg_dirty_frees_percent
- zfs_admin_snapshot
- zfs_delete_blocks
- zfs_expire_snapshot
- zfs_free_max_blocks
- zfs_max_recordsize
- zfs_read_chunk_size
- metaslab_lba_weighting_enabled
- zfs_vdev_mirror_rotating_inc
- zfs_vdev_mirror_rotating_seek_inc
- zfs_vdev_mirror_rotating_seek_offset
- zfs_autoimport_disable
- zfs_max_missing_tvds
- zfs_multihost_fail_intervals
- zfs_multihost_history
- zfs_multihost_import_intervals
- zfs_multihost_interval
- zfs_recover
- spa_config_path
- spa_load_print_vdev_tree
- spa_load_verify_maxinflight
- spa_load_verify_metadata
- spa_load_verify_shift
- zvol_inhibit_dev
- l2arc_exclude_special
- l2arc_feed_again
- l2arc_feed_min_ms
- l2arc_feed_secs
- l2arc_headroom
- l2arc_headroom_boost
- l2arc_meta_percent
- l2arc_mfuonly
- l2arc_nocompress
- l2arc_noprefetch
- l2arc_norw
- l2arc_rebuild_blocks_min_l2size
- l2arc_rebuild_enabled
- l2arc_trim_ahead
- l2arc_write_boost
- l2arc_write_max
- zfs_abd_scatter_enabled
- zfs_abd_scatter_max_order
- zfs_arc_average_blocksize
- zfs_arc_grow_retry
- zfs_arc_lotsfree_percent
- zfs_arc_max
- zfs_arc_pc_percent
- zfs_arc_shrink_shift
- zfs_arc_sys_free
- zfs_dedup_prefetch
- zfs_max_recordsize
- metaslab_debug_load
- metaslab_debug_unload
- zfs_scan_mem_lim_fact
- zfs_scan_strict_mem_lim
- spl_kmem_alloc_max
- spl_kmem_alloc_warn
- spl_kmem_cache_expire
- spl_kmem_cache_kmem_limit
- spl_kmem_cache_kmem_threads
- spl_kmem_cache_magazine_size
- spl_kmem_cache_max_size
- spl_kmem_cache_obj_per_slab
- spl_kmem_cache_obj_per_slab_min
- spl_kmem_cache_reclaim
- spl_kmem_cache_slab_limit
- metaslab_aliquot
- metaslab_bias_enabled
- metaslab_debug_load
- metaslab_debug_unload
- metaslab_fragmentation_factor_enabled
- metaslab_lba_weighting_enabled
- metaslab_preload_enabled
- zfs_metaslab_segment_weight_enabled
- zfs_metaslab_switch_threshold
- metaslabs_per_vdev
- zfs_vdev_min_ms_count
- zfs_vdev_ms_count_limit
- zfs_vdev_mirror_non_rotating_inc
- zfs_vdev_mirror_non_rotating_seek_inc
- zfs_vdev_mirror_rotating_inc
- zfs_vdev_mirror_rotating_seek_inc
- zfs_vdev_mirror_rotating_seek_offset
- zfs_multihost_fail_intervals
- zfs_multihost_history
- zfs_multihost_import_intervals
- zfs_multihost_interval
- spl_hostid
- spl_hostid_path
- zfs_arc_min_prefetch_ms
- zfs_arc_min_prescient_prefetch_ms
- zfs_dedup_prefetch
- l2arc_noprefetch
- zfs_no_scrub_prefetch
- zfs_pd_bytes_max
- zfs_prefetch_disable
- zfetch_array_rd_sz
- zfetch_max_distance
- zfetch_max_streams
- zfetch_min_sec_reap
- zvol_prefetch_bytes
- zfs_resilver_delay
- zfs_resilver_disable_defer
- zfs_resilver_min_time_ms
- zfs_scan_checkpoint_intval
- zfs_scan_fill_weight
- zfs_scan_idle
- zfs_scan_ignore_errors
- zfs_scan_issue_strategy
- zfs_scan_legacy
- zfs_scan_max_ext_gap
- zfs_scan_mem_lim_fact
- zfs_scan_mem_lim_soft_fact
- zfs_scan_strict_mem_lim
- zfs_scan_suspend_progress
- zfs_scan_vdev_limit
- zfs_top_maxinflight
- zfs_vdev_scrub_max_active
- zfs_vdev_scrub_min_active
- zfs_no_scrub_io
- zfs_no_scrub_prefetch
- zfs_scan_checkpoint_intval
- zfs_scan_fill_weight
- zfs_scan_idle
- zfs_scan_issue_strategy
- zfs_scan_legacy
- zfs_scan_max_ext_gap
- zfs_scan_mem_lim_fact
- zfs_scan_mem_lim_soft_fact
- zfs_scan_min_time_ms
- zfs_scan_strict_mem_lim
- zfs_scan_suspend_progress
- zfs_scan_vdev_limit
- zfs_scrub_delay
- zfs_scrub_min_time_ms
- zfs_top_maxinflight
- zfs_vdev_scrub_max_active
- zfs_vdev_scrub_min_active
- ignore_hole_birth
- zfs_override_estimate_recordsize
- zfs_pd_bytes_max
- zfs_send_corrupt_data
- zfs_send_queue_length
- zfs_send_unmodified_spill_blocks
- spa_asize_inflation
- spa_load_print_vdev_tree
- spa_load_verify_data
- spa_load_verify_shift
- spa_slop_shift
- zfs_sync_pass_deferred_free
- zfs_sync_pass_dont_compress
- zfs_sync_pass_rewrite
- zfs_sync_taskq_batch_pct
- zfs_txg_timeout
- l2arc_exclude_special
- zfs_ddt_data_is_special
- zfs_special_class_metadata_reserve_pct
- zfs_user_indirect_is_special
- metaslab_lba_weighting_enabled
- zfs_vdev_mirror_non_rotating_inc
- zfs_vdev_mirror_non_rotating_seek_inc
- spl_max_show_tasks
- spl_taskq_kick
- spl_taskq_thread_bind
- spl_taskq_thread_dynamic
- spl_taskq_thread_priority
- spl_taskq_thread_sequential
- zfs_zil_clean_taskq_nthr_pct
- zio_taskq_batch_pct
- zfs_trim_extent_bytes_max
- zfs_trim_extent_bytes_min
- zfs_trim_metaslab_skip
- zfs_trim_queue_limit
- zfs_trim_txg_batch
- zfs_vdev_aggregate_trim
- zfs_checksum_events_per_second
- metaslab_aliquot
- metaslab_bias_enabled
- zfs_metaslab_fragmentation_threshold
- metaslabs_per_vdev
- zfs_mg_fragmentation_threshold
- zfs_mg_noalloc_threshold
- zfs_multihost_interval
- zfs_scan_vdev_limit
- zfs_slow_io_events_per_second
- zfs_vdev_aggregate_trim
- zfs_vdev_aggregation_limit
- zfs_vdev_aggregation_limit_non_rotating
- zfs_vdev_async_read_max_active
- zfs_vdev_async_read_min_active
- zfs_vdev_async_write_active_max_dirty_percent
- zfs_vdev_async_write_active_min_dirty_percent
- zfs_vdev_async_write_max_active
- zfs_vdev_async_write_min_active
- zfs_vdev_cache_bshift
- zfs_vdev_cache_max
- zfs_vdev_cache_size
- zfs_vdev_initializing_max_active
- zfs_vdev_initializing_min_active
- zfs_vdev_max_active
- zfs_vdev_min_ms_count
- zfs_vdev_mirror_non_rotating_inc
- zfs_vdev_mirror_non_rotating_seek_inc
- zfs_vdev_mirror_rotating_inc
- zfs_vdev_mirror_rotating_seek_inc
- zfs_vdev_mirror_rotating_seek_offset
- zfs_vdev_ms_count_limit
- zfs_vdev_queue_depth_pct
- zfs_vdev_raidz_impl
- zfs_vdev_read_gap_limit
- zfs_vdev_removal_max_active
- zfs_vdev_removal_min_active
- zfs_vdev_scheduler
- zfs_vdev_scrub_max_active
- zfs_vdev_scrub_min_active
- zfs_vdev_sync_read_max_active
- zfs_vdev_sync_read_min_active
- zfs_vdev_sync_write_max_active
- zfs_vdev_sync_write_min_active
- zfs_vdev_trim_max_active
- zfs_vdev_trim_min_active
- vdev_validate_skip
- zfs_vdev_write_gap_limit
- zio_dva_throttle_enabled
- zio_slow_io_ms
- zfs_condense_indirect_commit_entry_delay_ms
- zfs_condense_indirect_vdevs_enable
- zfs_condense_max_obsolete_bytes
- zfs_condense_min_mapping_bytes
- zfs_reconstruct_indirect_combinations_max
- zfs_removal_ignore_errors
- zfs_removal_suspend_progress
- vdev_removal_max_span
- zfs_max_recordsize
- zvol_inhibit_dev
- zvol_major
- zvol_max_discard_blocks
- zvol_prefetch_bytes
- zvol_request_sync
- zvol_threads
- zvol_volmode
- zfs_delay_min_dirty_percent
- zfs_delay_scale
- zfs_dirty_data_max
- zfs_dirty_data_max_max
- zfs_dirty_data_max_max_percent
- zfs_dirty_data_max_percent
- zfs_dirty_data_sync
- zfs_dirty_data_sync_percent
- zfs_commit_timeout_pct
- zfs_immediate_write_sz
- zfs_zil_clean_taskq_maxalloc
- zfs_zil_clean_taskq_minalloc
- zfs_zil_clean_taskq_nthr_pct
- zil_nocacheflush
- zil_replay_disable
- zil_slog_bulk
- zfs_dirty_data_sync
- zfs_dirty_data_sync_percent
- zfs_resilver_delay
- zfs_scan_idle
- zfs_scrub_delay
- zfs_top_maxinflight
- zfs_txg_timeout
- zfs_vdev_aggregate_trim
- zfs_vdev_aggregation_limit
- zfs_vdev_aggregation_limit_non_rotating
- zfs_vdev_async_read_max_active
- zfs_vdev_async_read_min_active
- zfs_vdev_async_write_active_max_dirty_percent
- zfs_vdev_async_write_active_min_dirty_percent
- zfs_vdev_async_write_max_active
- zfs_vdev_async_write_min_active
- zfs_vdev_initializing_max_active
- zfs_vdev_initializing_min_active
- zfs_vdev_max_active
- zfs_vdev_queue_depth_pct
- zfs_vdev_read_gap_limit
- zfs_vdev_removal_max_active
- zfs_vdev_removal_min_active
- zfs_vdev_scheduler
- zfs_vdev_scrub_max_active
- zfs_vdev_scrub_min_active
- zfs_vdev_sync_read_max_active
- zfs_vdev_sync_read_min_active
- zfs_vdev_sync_write_max_active
- zfs_vdev_sync_write_min_active
- zfs_vdev_trim_max_active
- zfs_vdev_trim_min_active
- zfs_vdev_write_gap_limit
- zio_dva_throttle_enabled
- zio_requeue_io_start_cut_in_line
- zio_taskq_batch_pct
- zfs_abd_scatter_enabled
- zfs_abd_scatter_max_order
- zfs_abd_scatter_min_size
- zfs_admin_snapshot
- zfs_arc_average_blocksize
- zfs_arc_dnode_limit
- zfs_arc_dnode_limit_percent
- zfs_arc_dnode_reduce_percent
- zfs_arc_evict_batch_limit
- zfs_arc_grow_retry
- zfs_arc_lotsfree_percent
- zfs_arc_max
- zfs_arc_meta_adjust_restarts
- zfs_arc_meta_limit
- zfs_arc_meta_limit_percent
- zfs_arc_meta_min
- zfs_arc_meta_prune
- zfs_arc_meta_strategy
- zfs_arc_min
- zfs_arc_min_prefetch_lifespan
- zfs_arc_min_prefetch_ms
- zfs_arc_min_prescient_prefetch_ms
- zfs_arc_overflow_shift
- zfs_arc_p_dampener_disable
- zfs_arc_p_min_shift
- zfs_arc_pc_percent
- zfs_arc_shrink_shift
- zfs_arc_sys_free
- zfs_async_block_max_blocks
- zfs_autoimport_disable
- zfs_checksum_events_per_second
- zfs_checksums_per_second
- zfs_commit_timeout_pct
- zfs_compressed_arc_enabled
- zfs_condense_indirect_commit_entry_delay_ms
- zfs_condense_indirect_vdevs_enable
- zfs_condense_max_obsolete_bytes
- zfs_condense_min_mapping_bytes
- zfs_dbgmsg_enable
- zfs_dbgmsg_maxsize
- dbuf_cache_hiwater_pct
- dbuf_cache_lowater_pct
- dbuf_cache_max_bytes
- dbuf_cache_max_shift
- dbuf_cache_shift
- dbuf_metadata_cache_max_bytes
- dbuf_metadata_cache_shift
- zfs_dbuf_state_index
- zfs_ddt_data_is_special
- zfs_deadman_checktime_ms
- zfs_deadman_enabled
- zfs_deadman_failmode
- zfs_deadman_synctime_ms
- zfs_deadman_ziotime_ms
- zfs_dedup_prefetch
- zfs_delay_min_dirty_percent
- zfs_delay_scale
- zfs_delays_per_second
- zfs_delete_blocks
- zfs_dirty_data_max
- zfs_dirty_data_max_max
- zfs_dirty_data_max_max_percent
- zfs_dirty_data_max_percent
- zfs_dirty_data_sync
- zfs_dirty_data_sync_percent
- zfs_disable_dup_eviction
- zfs_disable_ivset_guid_check
- dmu_object_alloc_chunk_shift
- zfs_dmu_offset_next_sync
- zfs_expire_snapshot
- zfs_flags
- zfs_fletcher_4_impl
- zfs_free_bpobj_enabled
- zfs_free_leak_on_eio
- zfs_free_max_blocks
- zfs_free_min_time_ms
- icp_aes_impl
- icp_gcm_impl
- ignore_hole_birth
- zfs_immediate_write_sz
- zfs_initialize_value
- zfs_key_max_salt_uses
- l2arc_exclude_special
- l2arc_feed_again
- l2arc_feed_min_ms
- l2arc_feed_secs
- l2arc_headroom
- l2arc_headroom_boost
- l2arc_meta_percent
- l2arc_mfuonly
- l2arc_nocompress
- l2arc_noprefetch
- l2arc_norw
- l2arc_rebuild_blocks_min_l2size
- l2arc_rebuild_enabled
- l2arc_trim_ahead
- l2arc_write_boost
- l2arc_write_max
- zfs_lua_max_instrlimit
- zfs_lua_max_memlimit
- zfs_max_dataset_nesting
- zfs_max_missing_tvds
- zfs_max_recordsize
- zfs_mdcomp_disable
- metaslab_aliquot
- metaslab_bias_enabled
- metaslab_debug_load
- metaslab_debug_unload
- metaslab_force_ganging
- metaslab_fragmentation_factor_enabled
- zfs_metaslab_fragmentation_threshold
- metaslab_lba_weighting_enabled
- metaslab_preload_enabled
- zfs_metaslab_segment_weight_enabled
- zfs_metaslab_switch_threshold
- metaslabs_per_vdev
- zfs_mg_fragmentation_threshold
- zfs_mg_noalloc_threshold
- zfs_multihost_fail_intervals
- zfs_multihost_history
- zfs_multihost_import_intervals
- zfs_multihost_interval
- zfs_multilist_num_sublists
- zfs_no_scrub_io
- zfs_no_scrub_prefetch
- zfs_nocacheflush
- zfs_nopwrite_enabled
- zfs_object_mutex_size
- zfs_obsolete_min_time_ms
- zfs_override_estimate_recordsize
- zfs_pd_bytes_max
- zfs_per_txg_dirty_frees_percent
- zfs_prefetch_disable
- zfs_qat_checksum_disable
- zfs_qat_compress_disable
- zfs_qat_disable
- zfs_qat_encrypt_disable
- zfs_read_chunk_size
- zfs_read_history
- zfs_read_history_hits
- zfs_reconstruct_indirect_combinations_max
- zfs_recover
- zfs_recv_queue_length
- zfs_removal_ignore_errors
- zfs_removal_suspend_progress
- zfs_remove_max_segment
- zfs_resilver_delay
- zfs_resilver_disable_defer
- zfs_resilver_min_time_ms
- zfs_scan_checkpoint_intval
- zfs_scan_fill_weight
- zfs_scan_idle
- zfs_scan_ignore_errors
- zfs_scan_issue_strategy
- zfs_scan_legacy
- zfs_scan_max_ext_gap
- zfs_scan_mem_lim_fact
- zfs_scan_mem_lim_soft_fact
- zfs_scan_min_time_ms
- zfs_scan_strict_mem_lim
- zfs_scan_suspend_progress
- zfs_scan_vdev_limit
- zfs_scrub_delay
- zfs_scrub_min_time_ms
- zfs_send_corrupt_data
- send_holes_without_birth_time
- zfs_send_queue_length
- zfs_send_unmodified_spill_blocks
- zfs_slow_io_events_per_second
- spa_asize_inflation
- spa_config_path
- zfs_spa_discard_memory_limit
- spa_load_print_vdev_tree
- spa_load_verify_data
- spa_load_verify_maxinflight
- spa_load_verify_metadata
- spa_load_verify_shift
- spa_slop_shift
- zfs_special_class_metadata_reserve_pct
- spl_hostid
- spl_hostid_path
- spl_kmem_alloc_max
- spl_kmem_alloc_warn
- spl_kmem_cache_expire
- spl_kmem_cache_kmem_limit
- spl_kmem_cache_kmem_threads
- spl_kmem_cache_magazine_size
- spl_kmem_cache_max_size
- spl_kmem_cache_obj_per_slab
- spl_kmem_cache_obj_per_slab_min
- spl_kmem_cache_reclaim
- spl_kmem_cache_slab_limit
- spl_max_show_tasks
- spl_panic_halt
- spl_taskq_kick
- spl_taskq_thread_bind
- spl_taskq_thread_dynamic
- spl_taskq_thread_priority
- spl_taskq_thread_sequential
- zfs_sync_pass_deferred_free
- zfs_sync_pass_dont_compress
- zfs_sync_pass_rewrite
- zfs_sync_taskq_batch_pct
- zfs_top_maxinflight
- zfs_trim_extent_bytes_max
- zfs_trim_extent_bytes_min
- zfs_trim_metaslab_skip
- zfs_trim_queue_limit
- zfs_trim_txg_batch
- zfs_txg_history
- zfs_txg_timeout
- zfs_unlink_suspend_progress
- zfs_user_indirect_is_special
- zfs_vdev_aggregate_trim
- zfs_vdev_aggregation_limit
- zfs_vdev_aggregation_limit_non_rotating
- zfs_vdev_async_read_max_active
- zfs_vdev_async_read_min_active
- zfs_vdev_async_write_active_max_dirty_percent
- zfs_vdev_async_write_active_min_dirty_percent
- zfs_vdev_async_write_max_active
- zfs_vdev_async_write_min_active
- zfs_vdev_cache_bshift
- zfs_vdev_cache_max
- zfs_vdev_cache_size
- zfs_vdev_default_ms_count
- zfs_vdev_initializing_max_active
- zfs_vdev_initializing_min_active
- zfs_vdev_max_active
- zfs_vdev_min_ms_count
- zfs_vdev_mirror_non_rotating_inc
- zfs_vdev_mirror_non_rotating_seek_inc
- zfs_vdev_mirror_rotating_inc
- zfs_vdev_mirror_rotating_seek_inc
- zfs_vdev_mirror_rotating_seek_offset
- zfs_vdev_ms_count_limit
- zfs_vdev_queue_depth_pct
- zfs_vdev_raidz_impl
- zfs_vdev_read_gap_limit
- zfs_vdev_removal_max_active
- vdev_removal_max_span
- zfs_vdev_removal_min_active
- zfs_vdev_scheduler
- zfs_vdev_scrub_max_active
- zfs_vdev_scrub_min_active
- zfs_vdev_sync_read_max_active
- zfs_vdev_sync_read_min_active
- zfs_vdev_sync_write_max_active
- zfs_vdev_sync_write_min_active
- zfs_vdev_trim_max_active
- zfs_vdev_trim_min_active
- vdev_validate_skip
- zfs_vdev_write_gap_limit
- zfs_zevent_cols
- zfs_zevent_console
- zfs_zevent_len_max
- zfetch_array_rd_sz
- zfetch_max_distance
- zfetch_max_streams
- zfetch_min_sec_reap
- zfs_zil_clean_taskq_maxalloc
- zfs_zil_clean_taskq_minalloc
- zfs_zil_clean_taskq_nthr_pct
- zil_nocacheflush
- zil_replay_disable
- zil_slog_bulk
- zio_deadman_log_all
- zio_decompress_fail_fraction
- zio_delay_max
- zio_dva_throttle_enabled
- zio_requeue_io_start_cut_in_line
- zio_slow_io_ms
- zio_taskq_batch_pct
- zvol_inhibit_dev
- zvol_major
- zvol_max_discard_blocks
- zvol_prefetch_bytes
- zvol_request_sync
- zvol_threads
- zvol_volmode
When set, the hole_birth optimization will not be used and all holes
will always be sent by zfs send
In the source code,
ignore_hole_birth is an alias for and SysFS PARAMETER for
send_holes_without_birth_time.
ignore_hole_birth | Notes |
---|---|
Tags | send |
When to change | Enable if you suspect your datasets are
affected by a bug in hole_birth during
zfs send operations |
Data Type | boolean |
Range | 0=disabled, 1=enabled |
Default | 1 (hole birth optimization is ignored) |
Change | Dynamic |
Versions Affected | TBD |
Controls whether buffers present on special vdevs are eligible for caching into L2ARC.
l2arc_exclude_special | Notes |
---|---|
Tags | ARC, L2ARC, special_vdev, |
When to change | If cache and special devices exist and caching data on special devices in L2ARC is not desired |
Data Type | boolean |
Range | 0=disabled, 1=enabled |
Default | 0 |
Change | Dynamic |
Versions Affected | TBD |
Turbo L2ARC cache warm-up. When the L2ARC is cold the fill interval will be set to aggressively fill as fast as possible.
l2arc_feed_again | Notes |
---|---|
Tags | ARC, L2ARC |
When to change | If cache devices exist and it is desired to fill them as fast as possible |
Data Type | boolean |
Range | 0=disabled, 1=enabled |
Default | 1 |
Change | Dynamic |
Versions Affected | TBD |
Minimum time period for aggressively feeding the L2ARC. The L2ARC feed
thread wakes up once per second (see
l2arc_feed_secs) to look for data to feed into
the L2ARC. l2arc_feed_min_ms
only affects the turbo L2ARC cache
warm-up and allows the aggressiveness to be adjusted.
l2arc_feed_min_ms | Notes |
---|---|
Tags | ARC, L2ARC |
When to change | If cache devices exist and l2arc_feed_again and the feed is too aggressive, then this tunable can be adjusted to reduce the impact of the fill |
Data Type | uint64 |
Units | milliseconds |
Range | 0 to (1000 * l2arc_feed_secs) |
Default | 200 |
Change | Dynamic |
Versions Affected | 0.6 and later |
Seconds between waking the L2ARC feed thread. One feed thread works for all cache devices in turn.
If the pool that owns a cache device is imported readonly, then the feed thread is delayed 5 * l2arc_feed_secs before moving onto the next cache device. If multiple pools are imported with cache devices and one pool with cache is imported readonly, the L2ARC feed rate to all caches can be slowed.
l2arc_feed_secs | Notes |
---|---|
Tags | ARC, L2ARC |
When to change | Do not change |
Data Type | uint64 |
Units | seconds |
Range | 1 to UINT64_MAX |
Default | 1 |
Change | Dynamic |
Versions Affected | 0.6 and later |
How far through the ARC lists to search for L2ARC cacheable content, expressed as a multiplier of l2arc_write_max
l2arc_headroom | Notes |
---|---|
Tags | ARC, L2ARC |
When to change | If the rate of change in the ARC is faster than the overall L2ARC feed rate, then increasing l2arc_headroom can increase L2ARC efficiency. Setting the value too large can cause the L2ARC feed thread to consume more CPU time looking for data to feed. |
Data Type | uint64 |
Units | unit |
Range | 0 to UINT64_MAX |
Default | 2 |
Change | Dynamic |
Versions Affected | 0.6 and later |
Percentage scale for l2arc_headroom when L2ARC contents are being successfully compressed before writing.
l2arc_headroom_boost | Notes |
---|---|
Tags | ARC, L2ARC |
When to change | If average compression efficiency is greater than 2:1, then increasing l2a rc_headroom_boost can increase the L2ARC feed rate |
Data Type | uint64 |
Units | percent |
Range | 100 to UINT64_MAX, when set to 100, the L2ARC headroom boost feature is effectively disabled |
Default | 200 |
Change | Dynamic |
Versions Affected | all |
Disable writing compressed data to cache devices. Disabling allows the legacy behavior of writing decompressed data to cache devices.
l2arc_nocompress | Notes |
---|---|
Tags | ARC, L2ARC |
When to change | When testing compressed L2ARC feature |
Data Type | boolean |
Range | 0=store compressed blocks in cache device, 1=store uncompressed blocks in cache device |
Default | 0 |
Change | Dynamic |
Versions Affected | deprecated in v0.7.0 by new compressed ARC design |
Percent of ARC size allowed for L2ARC-only headers. Since L2ARC buffers are not evicted on memory pressure, too large amount of headers on system with irrationaly large L2ARC can render it slow or unusable. This parameter limits L2ARC writes and rebuild to achieve it.
l2arc_nocompress | Notes |
---|---|
Tags | ARC, L2ARC |
When to change | When workload really require enormous L2ARC. |
Data Type | int |
Range | 0 to 100 |
Default | 33 |
Change | Dynamic |
Versions Affected | v2.0 and later |
Controls whether only MFU metadata and data are cached from ARC into L2ARC. This may be desirable to avoid wasting space on L2ARC when reading/writing large amounts of data that are not expected to be accessed more than once. By default both MRU and MFU data and metadata are cached in the L2ARC.
l2arc_mfuonly | Notes |
---|---|
Tags | ARC, L2ARC |
When to change | When accessing a large amount of data only once. |
Data Type | boolean |
Range | 0=store MRU and MFU blocks in cache device, 1=store MFU blocks in cache device |
Default | 0 |
Change | Dynamic |
Versions Affected | v2.0 and later |
Disables writing prefetched, but unused, buffers to cache devices.
l2arc_noprefetch | Notes |
---|---|
Tags | ARC, L2ARC, prefetch |
When to change | Setting to 0 can increase L2ARC hit rates for workloads where the ARC is too small for a read workload that benefits from prefetching. Also, if the main pool devices are very slow, setting to 0 can improve some workloads such as backups. |
Data Type | boolean |
Range | 0=write prefetched but unused buffers to cache devices, 1=do not write prefetched but unused buffers to cache devices |
Default | 1 |
Change | Dynamic |
Versions Affected | v0.6.0 and later |
Disables writing to cache devices while they are being read.
l2arc_norw | Notes |
---|---|
Tags | ARC, L2ARC |
When to change | In the early days of SSDs, some devices did not perform well when reading and writing simultaneously. Modern SSDs do not have these issues. |
Data Type | boolean |
Range | 0=read and write simultaneously, 1=avoid writes when reading for antique SSDs |
Default | 0 |
Change | Dynamic |
Versions Affected | all |
The minimum required size (in bytes) of an L2ARC device 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 1GB the overhead involved offsets most of benefit so log blocks are not written for cache devices smaller than this.
l2arc_rebuild_blocks_min_l2size | Notes |
---|---|
Tags | ARC, L2ARC |
When to change | The cache device is small and the pool is frequently imported. |
Data Type | bytes |
Range | 0 to UINT64_MAX |
Default | 1,073,741,824 |
Change | Dynamic |
Versions Affected | v2.0 and later |
Rebuild the persistent L2ARC when importing a pool.
l2arc_rebuild_enabled | Notes |
---|---|
Tags | ARC, L2ARC |
When to change | If there are problems importing a pool or attaching an L2ARC device. |
Data Type | boolean |
Range | 0=disable persistent L2ARC rebuild, 1=enable persistent L2ARC rebuild |
Default | 1 |
Change | Dynamic |
Versions Affected | v2.0 and later |
Once the cache device has been filled TRIM ahead of the current write size
l2arc_write_max
on L2ARC devices by this percentage. This can speed
up future writes depending on the performance characteristics of the
cache device.
When set to 100% TRIM twice the space required to accommodate upcoming writes. A minimum of 64MB will be trimmed. If set it enables TRIM of the whole L2ARC device when it is added to a pool. By default, this option is disabled since it can put significant stress on the underlying storage devices.
l2arc_trim_ahead | Notes |
---|---|
Tags | ARC, L2ARC |
When to change | Consider setting for cache devices which effeciently handle TRIM commands. |
Data Type | ulong |
Units | percent of l2arc_write_max |
Range | 0 to 100 |
Default | 0 |
Change | Dynamic |
Versions Affected | v2.0 and later |
Until the ARC fills, increases the L2ARC fill rate
l2arc_write_max by l2arc_write_boost
.
l2arc_write_boost | Notes |
---|---|
Tags | ARC, L2ARC |
When to change | To fill the cache devices more aggressively after pool import. |
Data Type | uint64 |
Units | bytes |
Range | 0 to UINT64_MAX |
Default | 8,388,608 |
Change | Dynamic |
Versions Affected | all |
Maximum number of bytes to be written to each cache device for each L2ARC feed thread interval (see l2arc_feed_secs). The actual limit can be adjusted by l2arc_write_boost. By default l2arc_feed_secs is 1 second, delivering a maximum write workload to cache devices of 8 MiB/sec.
l2arc_write_max | Notes |
---|---|
Tags | ARC, L2ARC |
When to change | If the cache devices can sustain the write workload, increasing the rate of cache device fill when workloads generate new data at a rate higher than l2arc_write_max can increase L2ARC hit rate |
Data Type | uint64 |
Units | bytes |
Range | 1 to UINT64_MAX |
Default | 8,388,608 |
Change | Dynamic |
Versions Affected | all |
Sets the metaslab granularity. Nominally, ZFS will try to allocate this amount of data to a top-level vdev before moving on to the next top-level vdev. This is roughly similar to what would be referred to as the "stripe size" in traditional RAID arrays.
When tuning for HDDs, it can be more efficient to have a few larger,
sequential writes to a device rather than switching to the next device.
Monitoring the size of contiguous writes to the disks relative to the
write throughput can be used to determine if increasing
metaslab_aliquot
can help. For modern devices, it is unlikely that
decreasing metaslab_aliquot
from the default will help.
If there is only one top-level vdev, this tunable is not used.
metaslab_aliquot | Notes |
---|---|
Tags | allocation, metaslab, vdev |
When to change | If write performance increases as devices more efficiently write larger, contiguous blocks |
Data Type | uint64 |
Units | bytes |
Range | 0 to UINT64_MAX |
Default | 524,288 |
Change | Dynamic |
Versions Affected | all |
Enables metaslab group biasing based on a top-level vdev's utilization relative to the pool. Nominally, all top-level devs are the same size and the allocation is spread evenly. When the top-level vdevs are not of the same size, for example if a new (empty) top-level is added to the pool, this allows the new top-level vdev to get a larger portion of new allocations.
metaslab_bias_enabled | Notes |
---|---|
Tags | allocation, metaslab, vdev |
When to change | If a new top-level vdev is added and you do not want to bias new allocations to the new top-level vdev |
Data Type | boolean |
Range | 0=spread evenly across top-level vdevs, 1=bias spread to favor less full top-level vdevs |
Default | 1 |
Change | Dynamic |
Versions Affected | v0.6.4 and later |
Enables metaslab allocation based on largest free segment rather than total amount of free space. The goal is to avoid metaslabs that exhibit free space fragmentation: when there is a lot of small free spaces, but few larger free spaces.
If zfs_metaslab_segment_weight_enabled
is enabled, then
metaslab_fragmentation_factor_enabled
is ignored.
zfs _metaslab_segment_weight_enabled | Notes |
---|---|
Tags | allocation, metaslab |
When to change | When testing allocation and fragmentation |
Data Type | boolean |
Range | 0=do not consider metaslab fragmentation, 1=avoid metaslabs where free space is highly fragmented |
Default | 1 |
Change | Dynamic |
Versions Affected | v0.7.0 and later |
When using segment-based metaslab selection (see
zfs_metaslab_segment_weight_enabled),
continue allocating from the active metaslab until
zfs_metaslab_switch_threshold
worth of free space buckets have been
exhausted.
zfs_metaslab_switch_threshold | Notes |
---|---|
Tags | allocation, metaslab |
When to change | When testing allocation and fragmentation |
Data Type | uint64 |
Units | free spaces |
Range | 0 to UINT64_MAX |
Default | 2 |
Change | Dynamic |
Versions Affected | v0.7.0 and later |
When enabled, all metaslabs are loaded into memory during pool import. Nominally, metaslab space map information is loaded and unloaded as needed (see metaslab_debug_unload)
It is difficult to predict how much RAM is required to store a space map. An empty or completely full metaslab has a small space map. However, a highly fragmented space map can consume significantly more memory.
Enabling metaslab_debug_load
can increase pool import time.
metaslab_debug_load | Notes |
---|---|
Tags | allocation, memory, metaslab |
When to change | When RAM is plentiful and pool import time is not a consideration |
Data Type | boolean |
Range | 0=do not load all metaslab info at pool import, 1=dynamically load metaslab info as needed |
Default | 0 |
Change | Dynamic |
Versions Affected | v0.6.4 and later |
When enabled, prevents metaslab information from being dynamically unloaded from RAM. Nominally, metaslab space map information is loaded and unloaded as needed (see metaslab_debug_load)
It is difficult to predict how much RAM is required to store a space map. An empty or completely full metaslab has a small space map. However, a highly fragmented space map can consume significantly more memory.
Enabling metaslab_debug_unload
consumes RAM that would otherwise be
freed.
metaslab_debug_unload | Notes |
---|---|
Tags | allocation, memory, metaslab |
When to change | When RAM is plentiful and the penalty for dynamically reloading metaslab info from the pool is high |
Data Type | boolean |
Range | 0=dynamically unload metaslab info, 1=unload metaslab info only upon pool export |
Default | 0 |
Change | Dynamic |
Versions Affected | v0.6.4 and later |
Enable use of the fragmentation metric in computing metaslab weights.
In version v0.7.0, if
zfs_metaslab_segment_weight_enabled
is enabled, then metaslab_fragmentation_factor_enabled
is ignored.
metas lab_fragmentation_factor_enabled | Notes |
---|---|
Tags | allocation, metaslab |
When to change | To test metaslab fragmentation |
Data Type | boolean |
Range | 0=do not consider metaslab free space fragmentation, 1=try to avoid fragmented metaslabs |
Default | 1 |
Change | Dynamic |
Versions Affected | v0.6.4 and later |
When a vdev is added, it will be divided into approximately, but no more than, this number of metaslabs.
metaslabs_per_vdev | Notes |
---|---|
Tags | allocation, metaslab, vdev |
When to change | When testing metaslab allocation |
Data Type | uint64 |
Units | metaslabs |
Range | 16 to UINT64_MAX |
Default | 200 |
Change | Prior to pool creation or adding new top-level vdevs |
Versions Affected | all |
Enable metaslab group preloading. Each top-level vdev has a metaslab
group. By default, up to 3 copies of metadata can exist and are
distributed across multiple top-level vdevs.
metaslab_preload_enabled
allows the corresponding metaslabs to be
preloaded, thus improving allocation efficiency.
metaslab_preload_enabled | Notes |
---|---|
Tags | allocation, metaslab |
When to change | When testing metaslab allocation |
Data Type | boolean |
Range | 0=do not preload metaslab info, 1=preload up to 3 metaslabs |
Default | 1 |
Change | Dynamic |
Versions Affected | v0.6.4 and later |
Modern HDDs have uniform bit density and constant angular velocity.
Therefore, the outer recording zones are faster (higher bandwidth) than
the inner zones by the ratio of outer to inner track diameter. The
difference in bandwidth can be 2:1, and is often available in the HDD
detailed specifications or drive manual. For HDDs when
metaslab_lba_weighting_enabled
is true, write allocation preference
is given to the metaslabs representing the outer recording zones. Thus
the allocation to metaslabs prefers faster bandwidth over free space.
If the devices are not rotational, yet misrepresent themselves to the OS
as rotational, then disabling metaslab_lba_weighting_enabled
can
result in more even, free-space-based allocation.
metaslab_lba_weighting_enabled | Notes |
---|---|
Tags | allocation, metaslab, HDD, SSD |
When to change | disable if using only SSDs and version v0.6.4 or earlier |
Data Type | boolean |
Range | 0=do not use LBA weighting, 1=use LBA weighting |
Default | 1 |
Change | Dynamic |
Verification | The rotational setting described
by a block device in sysfs by
observing
/sys/
block/DISK_NAME/queue/rotational |
Versions Affected | prior to v0.6.5, the check for non-rotation media did not exist |
By default, the zpool import
command searches for pool information
in the zpool.cache
file. If the pool to be imported has an entry in
zpool.cache
then the devices do not have to be scanned to determine
if they are pool members. The path to the cache file is spa_config_path.
For more information on zpool import
and the -o cachefile
and
-d
options, see the man page for zpool(8)
See also zfs_autoimport_disable
spa_config_path | Notes |
---|---|
Tags | import |
When to change | If creating a non-standard distribution and the cachefile property is inconvenient |
Data Type | string |
Default | /etc/zfs/zpool.cache |
Change | Dynamic, applies only to the next invocation of
zpool import |
Versions Affected | all |
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.
The worst case space requirement for allocation is single-sector
max-parity RAIDZ blocks, in which case the space requirement is exactly
4 times the size, accounting for a maximum of 3 parity blocks. This is
added to the maximum number of ZFS copies
parameter (copies max=3).
Additional space is required if the block could impact deduplication
tables. Altogether, the worst case is 24.
If the estimation is not correct, then quotas or out-of-space conditions can lead to optimistic expectations of the ability to allocate. Applications are typically not prepared to deal with such failures and can misbehave.
spa_asize_inflation | Notes |
---|---|
Tags | allocation, SPA |
When to change | If the allocation requirements for the workload are well known and quotas are used |
Data Type | uint64 |
Units | unit |
Range | 1 to 24 |
Default | 24 |
Change | Dynamic |
Versions Affected | v0.6.3 and later |
An extreme rewind import (see zpool import -X
) normally performs a
full traversal of all blocks in the pool for verification. If this
parameter is set to 0, 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. See also
spa_load_verify_metadata.
spa_load_verify_data | Notes |
---|---|
Tags | allocation, SPA |
When to change | At the risk of data integrity, to speed extreme import of large pool |
Data Type | boolean |
Range | 0=do not verify data upon pool import, 1=verify pool data upon import |
Default | 1 |
Change | Dynamic |
Versions Affected | v0.6.4 and later |
An extreme rewind import (see zpool import -X
) normally performs a
full traversal of all blocks in the pool for verification. If this
parameter is set to 0, the traversal is not performed. It can be toggled
once the import has started to stop or start the traversal. See
spa_load_verify_data
spa_load_verify_metadata | Notes |
---|---|
Tags | import |
When to change | At the risk of data integrity, to speed extreme import of large pool |
Data Type | boolean |
Range | 0=do not verify metadata upon pool import, 1=verify pool metadata upon import |
Default | 1 |
Change | Dynamic |
Versions Affected | v0.6.4 and later |
Maximum number of concurrent I/Os during the data verification performed
during an extreme rewind import (see zpool import -X
)
spa_load_verify_maxinflight | Notes |
---|---|
Tags | import |
When to change | During an extreme rewind import, to match the concurrent I/O capabilities of the pool devices |
Data Type | int |
Units | I/Os |
Range | 1 to MAX_INT |
Default | 10,000 |
Change | Dynamic |
Versions Affected | v0.6.4 and later |
Normally, the last 3.2% (1/(2^spa_slop_shift
)) of pool space is
reserved to ensure the pool doesn't run completely out of space, due to
unaccounted changes (e.g. to the MOS). This also limits the worst-case
time to allocate space. When less than this amount of free space exists,
most ZPL operations (e.g. write, create) return error:no space (ENOSPC).
Changing spa_slop_shift affects the currently loaded ZFS module and all imported pools. spa_slop_shift is not stored on disk. Beware when importing full pools on systems with larger spa_slop_shift can lead to over-full conditions.
The minimum SPA slop space is limited to 128 MiB. The maximum SPA slop space is limited to 128 GiB.
spa_slop_shift | Notes |
---|---|
Tags | allocation, SPA |
When to change | For large pools, when 3.2% may be too
conservative and more usable space is desired,
consider increasing spa_slop_shift |
Data Type | int |
Units | shift |
Range | 1 to MAX_INT, however the practical upper limit is 15 for a system with 4TB of RAM |
Default | 5 |
Change | Dynamic |
Versions Affected | v0.6.5 and later (max. slop space since v2.1.0) |
If prefetching is enabled, do not prefetch blocks larger than
zfetch_array_rd_sz
size.
zfetch_array_rd_sz | Notes |
---|---|
Tags | prefetch |
When to change | To allow prefetching when using large block sizes |
Data Type | unsigned long |
Units | bytes |
Range | 0 to MAX_ULONG |
Default | 1,048,576 (1 MiB) |
Change | Dynamic |
Versions Affected | all |
Limits the maximum number of bytes to prefetch per stream.
zfetch_max_distance | Notes |
---|---|
Tags | prefetch |
When to change | Consider increasing read workloads that use large blocks and exhibit high prefetch hit ratios |
Data Type | uint |
Units | bytes |
Range | 0 to UINT_MAX |
Default | 8,388,608 |
Change | Dynamic |
Versions Affected | v0.7.0 |
Maximum number of prefetch streams per file.
For version v0.7.0 and later, when prefetching small files the number of prefetch streams is automatically reduced below to prevent the streams from overlapping.
zfetch_max_streams | Notes |
---|---|
Tags | prefetch |
When to change | If the workload benefits from prefetching and
has more than zfetch_max_streams
concurrent reader threads |
Data Type | uint |
Units | streams |
Range | 1 to MAX_UINT |
Default | 8 |
Change | Dynamic |
Versions Affected | all |
Prefetch streams that have been accessed in zfetch_min_sec_reap
seconds are automatically stopped.
zfetch_min_sec_reap | Notes |
---|---|
Tags | prefetch |
When to change | To test prefetch efficiency |
Data Type | uint |
Units | seconds |
Range | 0 to MAX_UINT |
Default | 2 |
Change | Dynamic |
Versions Affected | all |
Percentage of ARC metadata space that can be used for dnodes.
The value calculated for zfs_arc_dnode_limit_percent
can be
overridden by zfs_arc_dnode_limit.
zfs_arc_dnode_limit_percent | Notes |
---|---|
Tags | ARC |
When to change | Consider increasing if arc_prune
is using excessive system time and
/proc/spl/kstat/zfs/arcstats
shows arc_dnode_size is near or
over arc_dnode_limit |
Data Type | int |
Units | percent of arc_meta_limit |
Range | 0 to 100 |
Default | 10 |
Change | Dynamic |
Versions Affected | v0.7.0 and later |
When the number of bytes consumed by dnodes in the ARC exceeds
zfs_arc_dnode_limit
bytes, demand for new metadata can take from the
space consumed by dnodes.
The default value 0, 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
is similar to
zfs_arc_meta_prune which serves a similar
purpose for metadata.
zfs_arc_dnode_limit | Notes |
---|---|
Tags | ARC |
When to change | Consider increasing if arc_prune is using
excessive system time and
/proc/spl/kstat/zfs/arcstats shows
arc_dnode_size is near or over
arc_dnode_limit |
Data Type | uint64 |
Units | bytes |
Range | 0 to MAX_UINT64 |
Default | 0 (uses zfs_arc_dnode_lim it_percent) |
Change | Dynamic |
Versions Affected | v0.7.0 and later |
Percentage of ARC dnodes to try to evict in response to demand for non-metadata when the number of bytes consumed by dnodes exceeds zfs_arc_dnode_limit.
zfs_arc_dnode_reduce_percent | Notes |
---|---|
Tags | ARC |
When to change | Testing dnode cache efficiency |
Data Type | uint64 |
Units | percent of size of dnode space used above zfs_arc_d node_limit |
Range | 0 to 100 |
Default | 10 |
Change | Dynamic |
Versions Affected | v0.7.0 and later |
The ARC's buffer hash table is sized based on the assumption of an
average block size of zfs_arc_average_blocksize
. The default of 8
KiB uses approximately 1 MiB of hash table per 1 GiB of physical memory
with 8-byte pointers.
zfs_arc_average_blocksize | Notes |
---|---|
Tags | ARC, memory |
When to change | For workloads where the known average
blocksize is larger, increasing
zfs_arc_average_blocksize can
reduce memory usage |
Data Type | int |
Units | bytes |
Range | 512 to 16,777,216 |
Default | 8,192 |
Change | Prior to zfs module load |
Versions Affected | all |
Number ARC headers to evict per sublist before proceeding to another sublist. This batch-style operation prevents entire sublists from being evicted at once but comes at a cost of additional unlocking and locking.
zfs_arc_evict_batch_limit | Notes |
---|---|
Tags | ARC |
When to change | Testing ARC multilist features |
Data Type | int |
Units | count of ARC headers |
Range | 1 to INT_MAX |
Default | 10 |
Change | Dynamic |
Versions Affected | v0.6.5 and later |
When the ARC is shrunk due to memory demand, do not retry growing the
ARC for zfs_arc_grow_retry
seconds. This operates as a damper to
prevent oscillating grow/shrink cycles when there is memory pressure.
If zfs_arc_grow_retry
= 0, the internal default of 5 seconds is
used.
zfs_arc_grow_retry | Notes |
---|---|
Tags | ARC, memory |
When to change | TBD |
Data Type | int |
Units | seconds |
Range | 1 to MAX_INT |
Default | 0 |
Change | Dynamic |
Versions Affected | v0.6.5 and later |
Throttle ARC memory consumption, effectively throttling I/O, when free
system memory drops below this percentage of total system memory.
Setting zfs_arc_lotsfree_percent
to 0 disables the throttle.
The arcstat_memory_throttle_count counter in
/proc/spl/kstat/arcstats
can indicate throttle activity.
zfs_arc_lotsfree_percent | Notes |
---|---|
Tags | ARC, memory |
When to change | TBD |
Data Type | int |
Units | percent |
Range | 0 to 100 |
Default | 10 |
Change | Dynamic |
Versions Affected | v0.6.5 and later |
Maximum size of ARC in bytes.
If set to 0 then the maximum size of ARC is determined by the amount of system memory installed:
- Linux: 1/2 of system memory
- FreeBSD: the larger of
all_system_memory - 1GB
and5/8 × all_system_memory
zfs_arc_max
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_max | Notes |
---|---|
Tags | ARC, memory |
When to change | Reduce if ARC competes too much with other applications, increase if ZFS is the primary application and can use more RAM |
Data Type | uint64 |
Units | bytes |
Range | 67,108,864 to RAM size in bytes |
Default | 0 (see description above, OS-dependent) |
Change | Dynamic (see description above) |
Verification | c column in arcstats.py or
/proc/spl/kstat/zfs/arcstats entry
c_max |
Versions Affected | all |
The number of restart passes to make while scanning the ARC attempting the free buffers in order to stay below the zfs_arc_meta_limit.
zfs_arc_meta_adjust_restarts | Notes |
---|---|
Tags | ARC |
When to change | Testing ARC metadata adjustment feature |
Data Type | int |
Units | restarts |
Range | 0 to INT_MAX |
Default | 4,096 |
Change | Dynamic |
Versions Affected | v0.6.5 and later |
Sets the maximum allowed size metadata buffers in the ARC. When
zfs_arc_meta_limit is reached metadata buffers
are reclaimed, even if the overall c_max
has not been reached.
In version v0.7.0, with a default value = 0,
zfs_arc_meta_limit_percent
is used to set arc_meta_limit
zfs_arc_meta_limit | Notes |
---|---|
Tags | ARC |
When to change | For workloads where the metadata to data ratio in the ARC can be changed to improve ARC hit rates |
Data Type | uint64 |
Units | bytes |
Range | 0 to c_max |
Default | 0 |
Change | Dynamic, except that it cannot be set back to 0 for a specific percent of the ARC; it must be set to an explicit value |
Verification | /proc/spl/kstat/zfs/arcstats entry
arc_meta_limit |
Versions Affected | all |
Sets the limit to ARC metadata, arc_meta_limit
, as a percentage of
the maximum size target of the ARC, c_max
Prior to version v0.7.0, the
zfs_arc_meta_limit was used to set the limit
as a fixed size. zfs_arc_meta_limit_percent
provides a more
convenient interface for setting the limit.
zfs_arc_meta_limit_percent | Notes |
---|---|
Tags | ARC |
When to change | For workloads where the metadata to data ratio in the ARC can be changed to improve ARC hit rates |
Data Type | uint64 |
Units | percent of c_max |
Range | 0 to 100 |
Default | 75 |
Change | Dynamic |
Verification | /proc/spl/kstat/zfs/arcstats entry
arc_meta_limit |
Versions Affected | v0.7.0 and later |
The minimum allowed size in bytes that metadata buffers may consume in the ARC. This value defaults to 0 which disables a floor on the amount of the ARC devoted meta data.
When evicting data from the ARC, if the metadata_size
is less than
arc_meta_min
then data is evicted instead of metadata.
zfs_arc_meta_min | Notes |
---|---|
Tags | ARC |
When to change | |
Data Type | uint64 |
Units | bytes |
Range | 16,777,216 to c_max |
Default | 0 (use internal default 16 MiB) |
Change | Dynamic |
Verification | /proc/spl/kstat/zfs/arcstats entry arc_meta_min |
Versions Affected | all |
zfs_arc_meta_prune
sets the number of dentries and znodes to be
scanned looking for entries which can be dropped. This provides a
mechanism to ensure the ARC can honor the arc_meta_limit and
reclaim
otherwise pinned ARC buffers. Pruning may be required when the ARC size
drops to arc_meta_limit
because dentries and znodes can pin buffers
in the ARC. Increasing this value will cause to dentry and znode caches
to be pruned more aggressively and the arc_prune thread becomes more
active. Setting zfs_arc_meta_prune
to 0 will disable pruning.
zfs_arc_meta_prune | Notes |
---|---|
Tags | ARC |
When to change | TBD |
Data Type | uint64 |
Units | entries |
Range | 0 to INT_MAX |
Default | 10,000 |
Change | Dynamic |
! Verification | Prune activity is counted by the
/proc/spl/kstat/zfs/arcstats entry
arc_prune |
Versions Affected | v0.6.5 and later |
Defines the strategy for ARC metadata eviction (meta reclaim strategy). A value of 0 (META_ONLY) will evict only the ARC metadata. A value of 1 (BALANCED) indicates that additional data may be evicted if required in order to evict the requested amount of metadata.
zfs_arc_meta_strategy | Notes |
---|---|
Tags | ARC |
When to change | Testing ARC metadata eviction |
Data Type | int |
Units | enum |
Range | 0=evict metadata only, 1=also evict data buffers if they can free metadata buffers for eviction |
Default | 1 (BALANCED) |
Change | Dynamic |
Versions Affected | v0.6.5 and later |
Minimum ARC size limit. When the ARC is asked to shrink, it will stop
shrinking at c_min
as tuned by zfs_arc_min
.
zfs_arc_min | Notes |
---|---|
Tags | ARC |
When to change | If the primary focus of the system is ZFS, then increasing can ensure the ARC gets a minimum amount of RAM |
Data Type | uint64 |
Units | bytes |
Range | 33,554,432 to c_max |
Default | For kernel: greater of 33,554,432 (32 MiB) and
memory size / 32. For user-land: greater of
33,554,432 (32 MiB) and c_max / 2. |
Change | Dynamic |
Verification | /proc/spl/kstat/zfs/arcstats entry
c_min |
Versions Affected | all |
Minimum time prefetched blocks are locked in the ARC.
A value of 0 represents the default of 1 second. However, once changed, dynamically setting to 0 will not return to the default.
zfs_arc_min_prefetch_ms | Notes |
---|---|
Tags | ARC, prefetch |
When to change | TBD |
Data Type | int |
Units | milliseconds |
Range | 1 to INT_MAX |
Default | 0 (use internal default of 1000 ms) |
Change | Dynamic |
Versions Affected | v0.8.0 and later |
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.
A value of 0 represents the default of 6 seconds. However, once changed, dynamically setting to 0 will not return to the default.
z fs_arc_min_prescient_prefetch_ms | Notes |
---|---|
Tags | ARC, prefetch |
When to change | TBD |
Data Type | int |
Units | milliseconds |
Range | 1 to INT_MAX |
Default | 0 (use internal default of 6000 ms) |
Change | Dynamic |
Versions Affected | v0.8.0 and later |
To allow more fine-grained locking, each ARC state contains a series of lists (sublists) for both data and metadata objects. Locking is performed at the sublist level. This parameters controls the number of sublists per ARC state, and also applies to other uses of the multilist data structure.
zfs_multilist_num_sublists | Notes |
---|---|
Tags | ARC |
When to change | TBD |
Data Type | int |
Units | lists |
Range | 1 to INT_MAX |
Default | 0 (internal value is greater of number of online CPUs or 4) |
Change | Prior to zfs module load |
Versions Affected | v0.7.0 and later |
The ARC size is considered to be overflowing if it exceeds the current
ARC target size (/proc/spl/kstat/zfs/arcstats
entry c
) by a
threshold determined by zfs_arc_overflow_shift
. The threshold is
calculated as a fraction of c using the formula: (ARC target size)
c >> zfs_arc_overflow_shift
The default value of 8 causes the ARC to be considered to be overflowing if it exceeds the target size by 1/256th (0.3%) of the target size.
When the ARC is overflowing, new buffer allocations are stalled until the reclaim thread catches up and the overflow condition no longer exists.
zfs_arc_overflow_shift | Notes |
---|---|
Tags | ARC |
When to change | TBD |
Data Type | int |
Units | shift |
Range | 1 to INT_MAX |
Default | 8 |
Change | Dynamic |
Versions Affected | v0.6.5 and later |
arc_p_min_shift is used to shift of ARC target size
(/proc/spl/kstat/zfs/arcstats
entry c
) for calculating both
minimum and maximum most recently used (MRU) target size
(/proc/spl/kstat/zfs/arcstats
entry p
)
A value of 0 represents the default setting of arc_p_min_shift
= 4.
However, once changed, dynamically setting zfs_arc_p_min_shift
to 0
will not return to the default.
zfs_arc_p_min_shift | Notes |
---|---|
Tags | ARC |
When to change | TBD |
Data Type | int |
Units | shift |
Range | 1 to INT_MAX |
Default | 0 (internal default = 4) |
Change | Dynamic |
Verification | Observe changes to
/proc/spl/kstat/zfs/arcstats entry p |
Versions Affected | all |
When data is being added to the ghost lists, the MRU target size is adjusted. The amount of adjustment is based on the ratio of the MRU/MFU sizes. When enabled, the ratio is capped to 10, avoiding large adjustments.
zfs_arc_p_dampener_disable | Notes |
---|---|
Tags | ARC |
When to change | Testing ARC ghost list behaviour |
Data Type | boolean |
Range | 0=avoid large adjustments, 1=permit large adjustments |
Default | 1 |
Change | Dynamic |
Versions Affected | v0.6.4 and later |
arc_shrink_shift
is used to adjust the ARC target sizes when large
reduction is required. The current ARC target size, c
, and MRU size
p
can be reduced by by the current size >> arc_shrink_shift
. For
the default value of 7, this reduces the target by approximately 0.8%.
A value of 0 represents the default setting of arc_shrink_shift = 7. However, once changed, dynamically setting arc_shrink_shift to 0 will not return to the default.
zfs_arc_shrink_shift | Notes |
---|---|
Tags | ARC, memory |
When to change | During memory shortfall, reducing
zfs_arc_shrink_shift increases the rate
of ARC shrinkage |
Data Type | int |
Units | shift |
Range | 1 to INT_MAX |
Default | 0 (arc_shrink_shift = 7) |
Change | Dynamic |
Versions Affected | all |
zfs_arc_pc_percent
allows 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 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_pc_percent | Notes |
---|---|
Tags | ARC, memory |
When to change | When using file systems under memory
shortfall, if the page scanner causes the ARC
to shrink too fast, then adjusting
zfs_arc_pc_percent can reduce the shrink
rate |
Data Type | int |
Units | percent |
Range | 0 to 100 |
Default | 0 (disabled) |
Change | Dynamic |
Versions Affected | v0.7.0 and later |
zfs_arc_sys_free
is the target number of bytes the ARC should leave
as free memory on the system. Defaults to the larger of 1/64 of physical
memory or 512K. Setting this option to a non-zero value will override
the default.
A value of 0 represents the default setting of larger of 1/64 of physical memory or 512 KiB. However, once changed, dynamically setting zfs_arc_sys_free to 0 will not return to the default.
zfs_arc_sys_free | Notes |
---|---|
Tags | ARC, memory |
When to change | Change if more free memory is desired as a margin against memory demand by applications |
Data Type | ulong |
Units | bytes |
Range | 0 to ULONG_MAX |
Default | 0 (default to larger of 1/64 of physical memory or 512 KiB) |
Change | Dynamic |
Versions Affected | v0.6.5 and later |
Disable reading zpool.cache file (see spa_config_path) when loading the zfs module.
zfs_autoimport_disable | Notes |
---|---|
Tags | import |
When to change | Leave as default so that zfs behaves as other Linux kernel modules |
Data Type | boolean |
Range | 0=read zpool.cache at module load,
1=do not read zpool.cache at module
load |
Default | 1 |
Change | Dynamic |
Versions Affected | v0.6.4 and later |
zfs_commit_timeout_pct
controls the amount of time that a log (ZIL)
write block (lwb) remains "open" when it isn't "full" and it has a
thread waiting to commit 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 intent log transaction (itx).
zfs_commit_timeout_pct | Notes |
---|---|
Tags | ZIL |
When to change | TBD |
Data Type | int |
Units | percent |
Range | 1 to 100 |
Default | 5 |
Change | Dynamic |
Versions Affected | v0.8.0 |
/proc/spl/kstat/zfs/dbgmsg
file./proc/spl/kstat/zfs/dbgmsg
file clears the log.See also zfs_dbgmsg_maxsize
zfs_dbgmsg_enable | Notes |
---|---|
Tags | debug |
When to change | To view ZFS internal debug log |
Data Type | boolean |
Range | 0=do not log debug messages, 1=log debug messages |
Default | 0 (1 for debug builds) |
Change | Dynamic |
Versions Affected | v0.6.5 and later |
The /proc/spl/kstat/zfs/dbgmsg
file size limit is set by
zfs_dbgmsg_maxsize.
See also zfs_dbgmsg_enable
zfs_dbgmsg_maxsize | Notes |
---|---|
Tags | debug |
When to change | TBD |
Data Type | int |
Units | bytes |
Range | 0 to INT_MAX |
Default | 4 MiB |
Change | Dynamic |
Versions Affected | v0.6.5 and later |
The zfs_dbuf_state_index
feature is currently unused. It is normally
used for controlling values in the /proc/spl/kstat/zfs/dbufs
file.
zfs_dbuf_state_index | Notes |
---|---|
Tags | debug |
When to change | Do not change |
Data Type | int |
Units | TBD |
Range | TBD |
Default | 0 |
Change | Dynamic |
Versions Affected | v0.6.5 and later |
When a pool sync operation takes longer than zfs_deadman_synctime_ms
milliseconds, a "slow spa_sync" message is logged to the debug log (see
zfs_dbgmsg_enable). If zfs_deadman_enabled
is set to 1, then all pending IO operations are also checked and if any
haven't completed within zfs_deadman_synctime_ms milliseconds, a "SLOW
IO" message is logged to the debug log and a "deadman" system event (see
zpool events command) with the details of the hung IO is posted.
zfs_deadman_enabled | Notes |
---|---|
Tags | debug |
When to change | To disable logging of slow I/O |
Data Type | boolean |
Range | 0=do not log slow I/O, 1=log slow I/O |
Default | 1 |
Change | Dynamic |
Versions Affected | v0.8.0 |
Once a pool sync operation has taken longer than zfs_deadman_synctime_ms milliseconds, continue to check for slow operations every zfs_deadman_checktime_ms milliseconds.
zfs_deadman_checktime_ms | Notes |
---|---|
Tags | debug |
When to change | When debugging slow I/O |
Data Type | ulong |
Units | milliseconds |
Range | 1 to ULONG_MAX |
Default | 60,000 (1 minute) |
Change | Dynamic |
Versions Affected | v0.8.0 |
When an individual I/O takes longer than zfs_deadman_ziotime_ms
milliseconds, then the operation is considered to be "hung". If
zfs_deadman_enabled is set then the deadman
behaviour is invoked as described by the
zfs_deadman_failmode option.
zfs_deadman_ziotime_ms | Notes |
---|---|
Tags | debug |
When to change | Testing ABD features |
Data Type | ulong |
Units | milliseconds |
Range | 1 to ULONG_MAX |
Default | 300,000 (5 minutes) |
Change | Dynamic |
Versions Affected | v0.8.0 |
The I/O deadman timer expiration time has two meanings
- determines when the
spa_deadman()
logic should fire, indicating the txg sync has not completed in a timely manner - determines if an I/O is considered "hung"
In version v0.8.0, any I/O that has not completed in
zfs_deadman_synctime_ms
is considered "hung" resulting in one of
three behaviors controlled by the
zfs_deadman_failmode parameter.
zfs_deadman_synctime_ms
takes effect if
zfs_deadman_enabled = 1.
zfs_deadman_synctime_ms | Notes |
---|---|
Tags | debug |
When to change | When debugging slow I/O |
Data Type | ulong |
Units | milliseconds |
Range | 1 to ULONG_MAX |
Default | 600,000 (10 minutes) |
Change | Dynamic |
Versions Affected | v0.6.5 and later |
zfs_deadman_failmode controls the behavior of the I/O deadman timer when it detects a "hung" I/O. Valid values are:
- wait - Wait for the "hung" I/O (default)
- continue - Attempt to recover from a "hung" I/O
- panic - Panic the system
zfs_deadman_failmode | Notes |
---|---|
Tags | debug |
When to change | In some cluster cases, panic can be appropriate |
Data Type | string |
Range | wait, continue, or panic |
Default | wait |
Change | Dynamic |
Versions Affected | v0.8.0 |
ZFS can prefetch deduplication table (DDT) entries.
zfs_dedup_prefetch
allows DDT prefetches to be enabled.
zfs_dedup_prefetch | Notes |
---|---|
Tags | prefetch, memory |
When to change | For systems with limited RAM using the dedup feature, disabling deduplication table prefetch can reduce memory pressure |
Data Type | boolean |
Range | 0=do not prefetch, 1=prefetch dedup table entries |
Default | 0 |
Change | Dynamic |
Versions Affected | v0.6.5 and later |
zfs_delete_blocks
defines a large file for the purposes of delete.
Files containing more than zfs_delete_blocks
will be deleted
asynchronously while smaller files are deleted synchronously. Decreasing
this value reduces the time spent in an unlink(2)
system call at the
expense of a longer delay before the freed space is available.
The zfs_delete_blocks
value is specified in blocks, not bytes. The
size of blocks can vary and is ultimately limited by the filesystem's
recordsize property.
zfs_delete_blocks | Notes |
---|---|
Tags | filesystem, delete |
When to change | If applications delete large files and blocking
on unlink(2) is not desired |
Data Type | ulong |
Units | blocks |
Range | 1 to ULONG_MAX |
Default | 20,480 |
Change | Dynamic |
Versions Affected | all |
The ZFS write throttle begins to delay each transaction when the amount
of dirty data reaches the threshold zfs_delay_min_dirty_percent
of
zfs_dirty_data_max. This value should be >=
zfs_vdev_async_write_active_max_dirty_percent.
zfs_delay_min_dirty_percent | Notes |
---|---|
Tags | write_throttle |
When to change | See section "ZFS TRANSACTION DELAY" |
Data Type | int |
Units | percent |
Range | 0 to 100 |
Default | 60 |
Change | Dynamic |
Versions Affected | v0.6.4 and later |
zfs_delay_scale
controls how quickly the ZFS write throttle
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 write operations per second the pool can sustain.
The throttle will smoothly handle between 10x and 1/10th
zfs_delay_scale
.
Note: zfs_delay_scale
*
zfs_dirty_data_max must be < 2^64.
zfs_delay_scale | Notes |
---|---|
Tags | write_throttle |
When to change | See section "ZFS TRANSACTION DELAY" |
Data Type | ulong |
Units | scalar (nanoseconds) |
Range | 0 to ULONG_MAX |
Default | 500,000 |
Change | Dynamic |
Versions Affected | v0.6.4 and later |
zfs_dirty_data_max
is the ZFS write throttle dirty space limit. Once
this limit is exceeded, new writes are delayed until space is freed by
writes being committed to the pool.
zfs_dirty_data_max takes precedence over zfs_dirty_data_max_percent.
zfs_dirty_data_max | Notes |
---|---|
Tags | write_throttle |
When to change | See section "ZFS TRANSACTION DELAY" |
Data Type | ulong |
Units | bytes |
Range | 1 to zfs_d irty_data_max_max |
Default | 10% of physical RAM |
Change | Dynamic |
Versions Affected | v0.6.4 and later |
zfs_dirty_data_max_percent
is an alternative method of specifying
zfs_dirty_data_max, the ZFS write throttle
dirty space limit. Once this limit is exceeded, new writes are delayed
until space is freed by writes being committed to the pool.
zfs_dirty_data_max takes precedence over
zfs_dirty_data_max_percent
.
zfs_dirty_data_max_percent | Notes |
---|---|
Tags | write_throttle |
When to change | See section "ZFS TRANSACTION DELAY" |
Data Type | int |
Units | percent |
Range | 1 to 100 |
Default | 10% of physical RAM |
Change | Prior to zfs module load or a memory hot plug event |
Versions Affected | v0.6.4 and later |
zfs_dirty_data_max_max
is the maximum allowable value of
zfs_dirty_data_max.
zfs_dirty_data_max_max
takes precedence over
zfs_dirty_data_max_max_percent.
zfs_dirty_data_max_max | Notes |
---|---|
Tags | write_throttle |
When to change | See section "ZFS TRANSACTION DELAY" |
Data Type | ulong |
Units | bytes |
Range | 1 to physical RAM size |
Default | physical_ram/4 since v0.7: min(physical_ram/4, 4GiB) since v2.0 for 32-bit systems: min(physical_ram/4, 1GiB) |
Change | Prior to zfs module load |
Versions Affected | v0.6.4 and later |
zfs_dirty_data_max_max_percent
an alternative to
zfs_dirty_data_max_max for setting the
maximum allowable value of zfs_dirty_data_max
zfs_dirty_data_max_max takes precedence
over zfs_dirty_data_max_max_percent
zfs_dirty_data_max_max_percent | Notes |
---|---|
Tags | write_throttle |
When to change | See section "ZFS TRANSACTION DELAY" |
Data Type | int |
Units | percent |
Range | 1 to 100 |
Default | 25% of physical RAM |
Change | Prior to zfs module load |
Versions Affected | v0.6.4 and later |
When there is at least zfs_dirty_data_sync
dirty data, a transaction
group sync is started. This allows a transaction group sync to occur
more frequently than the transaction group timeout interval (see
zfs_txg_timeout) when there is dirty data to be
written.
zfs_dirty_data_sync | Notes |
---|---|
Tags | write_throttle, ZIO_scheduler |
When to change | TBD |
Data Type | ulong |
Units | bytes |
Range | 1 to ULONG_MAX |
Default | 67,108,864 (64 MiB) |
Change | Dynamic |
Versions Affected | v0.6.4 through v0.8.x, deprecation planned for v2 |
When there is at least zfs_dirty_data_sync_percent
of
zfs_dirty_data_max dirty data, a transaction
group sync is started. This allows a transaction group sync to occur
more frequently than the transaction group timeout interval (see
zfs_txg_timeout) when there is dirty data to be
written.
zfs_dirty_data_sync_percent | Notes |
---|---|
Tags | write_throttle, ZIO_scheduler |
When to change | TBD |
Data Type | int |
Units | percent |
Range | 1 to zfs_vdev_async_write_ac tive_min_dirty_percent |
Default | 20 |
Change | Dynamic |
Versions Affected | planned for v2, deprecates zfs_dirt y_data_sync |
Fletcher-4 is the default checksum algorithm for metadata and data. When
the zfs kernel module is loaded, a set of microbenchmarks are run to
determine the fastest algorithm for the current hardware. The
zfs_fletcher_4_impl
parameter allows a specific implementation to be
specified other than the default (fastest). Selectors other than
fastest and scalar require instruction set extensions to be
available and will only appear if ZFS detects their presence. The
scalar implementation works on all processors.
The results of the microbenchmark are visible in the
/proc/spl/kstat/zfs/fletcher_4_bench
file. Larger numbers indicate
better performance. Since ZFS is processor endian-independent, the
microbenchmark is run against both big and little-endian transformation.
zfs_fletcher_4_impl | Notes |
---|---|
Tags | CPU, checksum |
When to change | Testing Fletcher-4 algorithms |
Data Type | string |
Range | fastest, scalar, superscalar, superscalar4, sse2, ssse3, avx2, avx512f, or aarch64_neon depending on hardware support |
Default | fastest |
Change | Dynamic |
Versions Affected | v0.7.0 and later |
The processing of the free_bpobj object can be enabled by
zfs_free_bpobj_enabled
zfs_free_bpobj_enabled | Notes |
---|---|
Tags | delete |
When to change | If there's a problem with processing free_bpobj (e.g. i/o error or bug) |
Data Type | boolean |
Range | 0=do not process free_bpobj objects, 1=process free_bpobj objects |
Default | 1 |
Change | Dynamic |
Versions Affected | v0.7.0 and later |
zfs_free_max_blocks
sets the maximum number of blocks to be freed in
a single transaction group (txg). For workloads that delete (free) large
numbers of blocks in a short period of time, the processing of the frees
can negatively impact other operations, including txg commits.
zfs_free_max_blocks
acts as a limit to reduce the impact.
zfs_free_max_blocks | Notes |
---|---|
Tags | filesystem, delete |
When to change | For workloads that delete large files,
zfs_free_max_blocks can be adjusted to
meet performance requirements while reducing
the impacts of deletion |
Data Type | ulong |
Units | blocks |
Range | 1 to ULONG_MAX |
Default | 100,000 |
Change | Dynamic |
Versions Affected | v0.7.0 and later |
Maximum asynchronous read I/Os active to each device.
zfs_vdev_async_read_max_active | Notes |
---|---|
Tags | vdev, ZIO_scheduler |
When to change | See ZFS I/O Scheduler |
Data Type | uint32 |
Units | I/O operations |
Range | 1 to zfs_vdev_ma x_active |
Default | 3 |
Change | Dynamic |
Versions Affected | v0.6.4 and later |
Minimum asynchronous read I/Os active to each device.
zfs_vdev_async_read_min_active | Notes |
---|---|
Tags | vdev, ZIO_scheduler |
When to change | See ZFS I/O Scheduler |
Data Type | uint32 |
Units | I/O operations |
Range | 1 to ( zfs_vdev_async_read_max_active - 1) |
Default | 1 |
Change | Dynamic |
Versions Affected | v0.6.4 and later |
When the amount of dirty data exceeds the threshold
zfs_vdev_async_write_active_max_dirty_percent
of
zfs_dirty_data_max dirty data, then
zfs_vdev_async_write_max_active
is used to limit active async writes. If the dirty data is between
zfs_vdev_async_write_active_min_dirty_percent
and zfs_vdev_async_write_active_max_dirty_percent
, the active I/O
limit is linearly interpolated between
zfs_vdev_async_write_min_active
and
zfs_vdev_async_write_max_active
zfs_vdev_asyn c_write_active_max_dirty_percent | Notes |
---|---|
Tags | vdev, Z IO_scheduler |
When to change | See ZFS I/O Sch eduler |
Data Type | int |
Units | percent of zfs_dirty_d ata_max |
Range | 0 to 100 |
Default | 60 |
Change | Dynamic |
Versions Affected | v0.6.4 and later |
If the amount of dirty data is between
zfs_vdev_async_write_active_min_dirty_percent
and
zfs_vdev_async_write_active_max_dirty_percent
of zfs_dirty_data_max, the active I/O limit is
linearly interpolated between
zfs_vdev_async_write_min_active
and
zfs_vdev_async_write_max_active
zfs_vdev_asyn c_write_active_min_dirty_percent | Notes |
---|---|
Tags | vdev, Z IO_scheduler |
When to change | See ZFS I/O Sch eduler |
Data Type | int |
Units | percent of zfs_dirty_data_max |
Range | 0 to (z fs_vdev_async_write_active_max_d irty_percent - 1) |
Default | 30 |
Change | Dynamic |
Versions Affected | v0.6.4 and later |
zfs_vdev_async_write_max_active
sets the maximum asynchronous write
I/Os active to each device.
zfs_vdev_async_write_max_active | Notes |
---|---|
Tags | vdev, ` ZIO_scheduler <#zio-scheduler>`__ |
When to change | See ZFS I/O S cheduler |
Data Type | uint32 |
Units | I/O operations |
Range | 1 to zfs_vdev_max _active |
Default | 10 |
Change | Dynamic |
Versions Affected | v0.6.4 and later |
zfs_vdev_async_write_min_active
sets the minimum asynchronous write
I/Os active to each device.
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_async_write_min_active | Notes |
---|---|
Tags | vdev, ` ZIO_scheduler <#zio-scheduler>`__ |
When to change | See ZFS I/O S cheduler |
Data Type | uint32 |
Units | I/O operations |
Range | 1 to zfs _vdev_async_write_max_active |
Default | 1 for v0.6.x, 2 for v0.7.0 and later |
Change | Dynamic |
Versions Affected | v0.6.4 and later |
The maximum number of I/Os active to each device. Ideally,
zfs_vdev_max_active
>= the sum of each queue's max_active.
Once queued to the device, the ZFS I/O scheduler is no longer able to prioritize I/O operations. The underlying device drivers have their own scheduler and queue depth limits. Values larger than the device's maximum queue depth can have the affect of increased latency as the I/Os are queued in the intervening device driver layers.
zfs_vdev_max_active | Notes |
---|---|
Tags | vdev, ZIO_scheduler |
When to change | See ZFS I/O Scheduler |
Data Type | uint32 |
Units | I/O operations |
Range | sum of each queue's min_active to UINT32_MAX |
Default | 1,000 |
Change | Dynamic |
Versions Affected | v0.6.4 and later |
zfs_vdev_scrub_max_active
sets the maximum scrub or scan read I/Os
active to each device.
zfs_vdev_scrub_max_active | Notes |
---|---|
Tags | vdev, ZIO_scheduler, scrub, resilver |
When to change | See ZFS I/O Scheduler |
Data Type | uint32 |
Units | I/O operations |
Range | 1 to zfs_vd ev_max_active |
Default | 2 |
Change | Dynamic |
Versions Affected | v0.6.4 and later |
zfs_vdev_scrub_min_active
sets the minimum scrub or scan read I/Os
active to each device.
zfs_vdev_scrub_min_active | Notes |
---|---|
Tags | vdev, ZIO_scheduler, scrub, resilver |
When to change | See ZFS I/O Scheduler |
Data Type | uint32 |
Units | I/O operations |
Range | 1 to zfs_vdev_scrub_max _active |
Default | 1 |
Change | Dynamic |
Versions Affected | v0.6.4 and later |
Maximum synchronous read I/Os active to each device.
zfs_vdev_sync_read_max_active | Notes |
---|---|
Tags | vdev, ZIO_scheduler |
When to change | See ZFS I/O Scheduler |
Data Type | uint32 |
Units | I/O operations |
Range | 1 to zfs_vdev_m ax_active |
Default | 10 |
Change | Dynamic |
Versions Affected | v0.6.4 and later |
zfs_vdev_sync_read_min_active
sets the minimum synchronous read I/Os
active to each device.
zfs_vdev_sync_read_min_active | Notes |
---|---|
Tags | vdev, ZIO_scheduler |
When to change | See ZFS I/O Scheduler |
Data Type | uint32 |
Units | I/O operations |
Range | 1 to zfs_vdev_sync_read_max_active |
Default | 10 |
Change | Dynamic |
Versions Affected | v0.6.4 and later |
zfs_vdev_sync_write_max_active
sets the maximum synchronous write
I/Os active to each device.
zfs_vdev_sync_write_max_active | Notes |
---|---|
Tags | vdev, ZIO_scheduler |
When to change | See ZFS I/O Scheduler |
Data Type | uint32 |
Units | I/O operations |
Range | 1 to zfs_vdev_ma x_active |
Default | 10 |
Change | Dynamic |
Versions Affected | v0.6.4 and later |
zfs_vdev_sync_write_min_active
sets the minimum synchronous write
I/Os active to each device.
zfs_vdev_sync_write_min_active | Notes |
---|---|
Tags | vdev, ZIO_scheduler |
When to change | See ZFS I/O Scheduler |
Data Type | uint32 |
Units | I/O operations |
Range | 1 to zfs_vdev_sync_write_max_active |
Default | 10 |
Change | Dynamic |
Versions Affected | v0.6.4 and later |
Maximum number of queued allocations per top-level vdev expressed as a
percentage of
zfs_vdev_async_write_max_active.
This allows the system to detect devices that are more capable of
handling allocations and to allocate more blocks to those devices. It
also allows for dynamic allocation distribution when devices are
imbalanced as fuller devices will tend to be slower than empty devices.
Once the queue depth reaches (zfs_vdev_queue_depth_pct
*
zfs_vdev_async_write_max_active /
100) then allocator will stop allocating blocks on that top-level device
and switch to the next.
See also zio_dva_throttle_enabled
zfs_vdev_queue_depth_pct | Notes |
---|---|
Tags | vdev, ZIO_scheduler |
When to change | See ZFS I/O Scheduler |
Data Type | uint32 |
Units | I/O operations |
Range | 1 to UINT32_MAX |
Default | 1,000 |
Change | Dynamic |
Versions Affected | v0.7.0 and later |
Disable duplicate buffer eviction from ARC.
zfs_disable_dup_eviction | Notes |
---|---|
Tags | ARC, dedup |
When to change | TBD |
Data Type | boolean |
Range | 0=duplicate buffers can be evicted, 1=do not evict duplicate buffers |
Default | 0 |
Change | Dynamic |
Versions Affected | v0.6.5, deprecated in v0.7.0 |
Snapshots of filesystems are normally automounted under the filesystem's
.zfs/snapshot
subdirectory. When not in use, snapshots are unmounted
after zfs_expire_snapshot seconds.
zfs_expire_snapshot | Notes |
---|---|
Tags | filesystem, snapshot |
When to change | TBD |
Data Type | int |
Units | seconds |
Range | 0 disables automatic unmounting, maximum time is INT_MAX |
Default | 300 |
Change | Dynamic |
Versions Affected | v0.6.1 and later |
Allow the creation, removal, or renaming of entries in the
.zfs/snapshot
subdirectory 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_admin_snapshot | Notes |
---|---|
Tags | filesystem, snapshot |
When to change | TBD |
Data Type | boolean |
Range | 0=do not allow snapshot manipulation via the filesystem, 1=allow snapshot manipulation via the filesystem |
Default | 1 |
Change | Dynamic |
Versions Affected | v0.6.5 and later |
Set additional debugging flags (see zfs_dbgmsg_enable)
flag value | symbolic name | description |
---|---|---|
0x1 | ZFS_DEBUG_DPRINTF | Enable dprintf entries in the debug log |
0x2 | ZFS_DEBUG_DBUF_VERIFY | Enable extra dnode verifications |
0x4 | ZFS_DEBUG_DNODE_VERIFY | Enable extra dnode verifications |
0x8 | ZFS_DEBUG_SNAPNAMES | Enable snapshot name verification |
0x10 | ZFS_DEBUG_MODIFY | Check for illegally modified ARC buffers |
0x20 | ZFS_DEBUG_SPA | Enable spa_dbgmsg entries in the debug log |
0x40 | ZFS_DEBUG_ZIO_FREE | Enable verification of block frees |
0x80 | Z FS_DEBUG_HISTOGRAM_VERIFY | Enable extra spacemap histogram verifications |
0x100 | ZFS_DEBUG_METASLAB_VERIFY | Verify space accounting on disk matches in-core range_trees |
0x200 | ZFS_DEBUG_SET_ERROR | Enable SET_ERROR and dprintf entries in the debug log |
zfs_flags | Notes |
---|---|
Tags | debug |
When to change | When debugging ZFS |
Data Type | int |
Default | 0 no debug flags set, for debug builds: all except ZFS_DEBUG_DPRINTF and ZFS_DEBUG_SPA |
Change | Dynamic |
Versions Affected | v0.6.4 and later |
If destroy encounters an I/O error (EIO) while reading metadata (eg
indirect blocks), space referenced by the missing metadata cannot be
freed. Normally, this causes the background destroy to become "stalled",
as the destroy is unable to make forward progress. While in this stalled
state, all remaining space to free from the error-encountering
filesystem is temporarily leaked. Set zfs_free_leak_on_eio = 1
to
ignore the EIO, permanently leak the space from indirect blocks that can
not be read, and continue to free everything else that it can.
The default, stalling behavior is useful if the storage partially fails (eg some but not all I/Os fail), and then later recovers. In this case, we will be able to continue pool operations while it is partially failed, and when it recovers, we can continue to free the space, with no leaks. However, note that this case is rare.
Typically pools either:
- fail completely (but perhaps temporarily (eg a top-level vdev going offline)
- have localized, permanent errors (eg disk returns the wrong data due to bit flip or firmware bug)
In case (1), the zfs_free_leak_on_eio
setting does not matter
because the pool will be suspended and the sync thread will not be able
to make forward progress. In case (2), because the error is permanent,
the best effort do is leak the minimum amount of space. Therefore, it is
reasonable for zfs_free_leak_on_eio
be set, but by default the more
conservative approach is taken, so that there is no possibility of
leaking space in the "partial temporary" failure case.
zfs_free_leak_on_eio | Notes |
---|---|
Tags | debug |
When to change | When debugging I/O errors during destroy |
Data Type | boolean |
Range | 0=normal behavior, 1=ignore error and permanently leak space |
Default | 0 |
Change | Dynamic |
Versions Affected | v0.6.5 and later |
During a zfs destroy
operation using feature@async_destroy
a
minimum of zfs_free_min_time_ms
time will be spent working on
freeing blocks per txg commit.
zfs_free_min_time_ms | Notes |
---|---|
Tags | delete |
When to change | TBD |
Data Type | int |
Units | milliseconds |
Range | 1 to (zfs_txg_timeout * 1000) |
Default | 1,000 |
Change | Dynamic |
Versions Affected | v0.6.0 and later |
If a pool does not have a log device, data blocks equal to or larger
than zfs_immediate_write_sz
are treated as if the dataset being
written to had the property setting logbias=throughput
Terminology note: logbias=throughput
writes the blocks in "indirect
mode" to the ZIL where the data is written to the pool and a pointer to
the data is written to the ZIL.
zfs_immediate_write_sz | Notes |
---|---|
Tags | ZIL |
When to change | TBD |
Data Type | long |
Units | bytes |
Range | 512 to 16,777,216 (valid block sizes) |
Default | 32,768 (32 KiB) |
Change | Dynamic |
Verification | Data blocks that exceed
zfs_immediate_write_sz or are written
as logbias=throughput increment the
zil_itx_indirect_count entry in
/proc/spl/kstat/zfs/zil |
Versions Affected | all |
ZFS supports logical record (block) sizes from 512 bytes to 16 MiB. The
benefits of larger blocks, and thus larger average I/O sizes, can be
weighed against the cost of copy-on-write of large block to modify one
byte. Additionally, very large blocks can have a negative impact on both
I/O latency at the device level and the memory allocator. The
zfs_max_recordsize
parameter limits the upper bound of the dataset
volblocksize and recordsize properties.
Larger blocks can be created by enabling zpool
large_blocks
feature and changing this zfs_max_recordsize
. Pools with larger
blocks can always be imported and used, regardless of the value of
zfs_max_recordsize
.
For 32-bit systems, zfs_max_recordsize
also limits the size of
kernel virtual memory caches used in the ZFS I/O pipeline (zio_buf_*
and zio_data_buf_*
).
See also the zpool
large_blocks
feature.
zfs_max_recordsize | Notes |
---|---|
Tags | filesystem, memory, volume |
When to change | To create datasets with larger volblocksize or recordsize |
Data Type | int |
Units | bytes |
Range | 512 to 16,777,216 (valid block sizes) |
Default | 1,048,576 |
Change | Dynamic, set prior to creating volumes or changing filesystem recordsize |
Versions Affected | v0.6.5 and later |
zfs_mdcomp_disable
allows metadata compression to be disabled.
zfs_mdcomp_disable | Notes |
---|---|
Tags | CPU, metadata |
When to change | When CPU cycles cost less than I/O |
Data Type | boolean |
Range | 0=compress metadata, 1=do not compress metadata |
Default | 0 |
Change | Dynamic |
Versions Affected | from v0.6.0 to v0.8.0 |
Allow metaslabs to keep their active state as long as their
fragmentation percentage is less than or equal to this value. When
writing, an active metaslab whose fragmentation percentage exceeds
zfs_metaslab_fragmentation_threshold
is avoided allowing metaslabs
with less fragmentation to be preferred.
Metaslab fragmentation is used to calculate the overall pool
fragmentation
property value. However, individual metaslab
fragmentation levels are observable using the zdb
with the -mm
option.
zfs_metaslab_fragmentation_threshold
works at the metaslab level and
each top-level vdev has approximately
metaslabs_per_vdev metaslabs. See also
zfs_mg_fragmentation_threshold
zfs_metaslab_fragmentation_thresh old | Notes |
---|---|
Tags | allocation, fr agmentation, vdev |
When to change | Testing metaslab allocation |
Data Type | int |
Units | percent |
Range | 1 to 100 |
Default | 70 |
Change | Dynamic |
Versions Affected | v0.6.4 and later |
Metaslab groups (top-level vdevs) are considered eligible for
allocations if their fragmentation percentage metric is less than or
equal to zfs_mg_fragmentation_threshold
. If a metaslab group exceeds
this threshold then it will be skipped unless all metaslab groups within
the metaslab class have also crossed the
zfs_mg_fragmentation_threshold
threshold.
zfs_mg_fragmentation_threshold | Notes |
---|---|
Tags | allocation, ` fragmentation <#fragmentation>`__, vdev |
When to change | Testing metaslab allocation |
Data Type | int |
Units | percent |
Range | 1 to 100 |
Default | 85 |
Change | Dynamic |
Versions Affected | v0.6.4 and later |
Metaslab groups (top-level vdevs) with free space percentage greater
than zfs_mg_noalloc_threshold
are eligible for new allocations. If a
metaslab group's free space is less than or equal to the threshold, the
allocator avoids allocating to that group unless all groups in the pool
have reached the threshold. Once all metaslab groups have reached the
threshold, all metaslab groups are allowed to accept allocations. The
default value of 0 disables the feature and causes all metaslab groups
to be eligible for allocations.
This parameter allows one to deal with pools having heavily imbalanced
vdevs such as would be the case when a new vdev has been added. Setting
the threshold to a non-zero percentage will stop allocations from being
made to vdevs that aren't filled to the specified percentage and allow
lesser filled vdevs to acquire more allocations than they otherwise
would under the older zfs_mg_alloc_failures
facility.
zfs_mg_noalloc_threshold | Notes |
---|---|
Tags | allocation, fragmentation, vdev |
When to change | To force rebalancing as top-level vdevs are added or expanded |
Data Type | int |
Units | percent |
Range | 0 to 100 |
Default | 0 (disabled) |
Change | Dynamic |
Versions Affected | v0.7.0 and later |
The pool multihost
multimodifier protection (MMP) subsystem can
record historical updates in the
/proc/spl/kstat/zfs/POOL_NAME/multihost
file for debugging purposes.
The number of lines of history is determined by zfs_multihost_history.
zfs_multihost_history | Notes |
---|---|
Tags | MMP, import |
When to change | When testing multihost feature |
Data Type | int |
Units | lines |
Range | 0 to INT_MAX |
Default | 0 |
Change | Dynamic |
Versions Affected | v0.7.0 and later |
zfs_multihost_interval
controls the frequency of multihost writes
performed by the pool multihost multimodifier protection (MMP)
subsystem. The multihost write period is (zfs_multihost_interval
/
number of leaf-vdevs) milliseconds. Thus on average a multihost write
will be issued for each leaf vdev every zfs_multihost_interval
milliseconds. In practice, the observed period can vary with the I/O
load and this observed value is the delay which is stored in the
uberblock.
On import the multihost activity check waits a minimum amount of time
determined by (zfs_multihost_interval
*
zfs_multihost_import_intervals)
with a lower bound of 1 second. The activity check time may be further
extended if the value of mmp delay found in the best uberblock indicates
actual multihost updates happened at longer intervals than
zfs_multihost_interval
Note: the multihost protection feature applies to storage devices that can be shared between multiple systems.
zfs_multihost_interval | Notes |
---|---|
Tags | MMP, import, vdev |
When to change | To optimize pool import time against possibility of simultaneous import by another system |
Data Type | ulong |
Units | milliseconds |
Range | 100 to ULONG_MAX |
Default | 1000 |
Change | Dynamic |
Versions Affected | v0.7.0 and later |
zfs_multihost_import_intervals
controls the duration of the activity
test on pool import for the multihost multimodifier protection (MMP)
subsystem. The activity test can be expected to take a minimum time of
(zfs_multihost_import_interval
s *
zfs_multihost_interval * random(25%)
)
milliseconds. The random period of up to 25% improves simultaneous
import detection. For example, if two hosts are rebooted at the same
time and automatically attempt to import the pool, then is is highly
probable that one host will win.
Smaller values of zfs_multihost_import_intervals
reduces the import
time but increases the risk of failing to detect an active pool. The
total activity check time is never allowed to drop below one second.
Note: the multihost protection feature applies to storage devices that can be shared between multiple systems.
zfs_multihost_import_intervals | Notes |
---|---|
Tags | MMP, import |
When to change | TBD |
Data Type | uint |
Units | intervals |
Range | 1 to UINT_MAX |
Default | 20 since v0.8, previously 10 |
Change | Dynamic |
Versions Affected | v0.7.0 and later |
zfs_multihost_fail_intervals
controls the behavior of the pool when
write failures are detected in the multihost multimodifier protection
(MMP) subsystem.
If zfs_multihost_fail_intervals = 0
then multihost write failures
are ignored. The write failures are reported to the ZFS event daemon
(zed
) which can take action such as suspending the pool or offlining
a device.
zfs_multihost_fail_intervals > 0
then sequential multihost
write failures will cause the pool to be suspended. This occurs when
(zfs_multihost_fail_intervals
*
zfs_multihost_interval) milliseconds
have passed since the last successful multihost write.zfs_multihost_fail_intervals | Notes |
---|---|
Tags | MMP, import |
When to change | TBD |
Data Type | uint |
Units | intervals |
Range | 0 to UINT_MAX |
Default | 10 since v0.8, previously 5 |
Change | Dynamic |
Versions Affected | v0.7.0 and later |
The ZFS Event Daemon (zed) processes events from ZFS. However, it can be
overwhelmed by high rates of error reports which can be generated by
failing, high-performance devices. zfs_delays_per_second
limits the
rate of delay events reported to zed.
zfs_delays_per_second | Notes |
---|---|
Tags | zed, delay |
When to change | If processing delay events at a higher rate is desired |
Data Type | uint |
Units | events per second |
Range | 0 to UINT_MAX |
Default | 20 |
Change | Dynamic |
Versions Affected | v0.7.7 and later |
The ZFS Event Daemon (zed) processes events from ZFS. However, it can be
overwhelmed by high rates of error reports which can be generated by
failing, high-performance devices. zfs_checksums_per_second
limits
the rate of checksum events reported to zed.
Note: do not set this value lower than the SERD limit for checksum
in zed. By default, checksum_N
= 10 and checksum_T
= 10 minutes,
resulting in a practical lower limit of 1.
zfs_checksums_per_second | Notes |
---|---|
Tags | zed, checksum |
When to change | If processing checksum error events at a higher rate is desired |
Data Type | uint |
Units | events per second |
Range | 0 to UINT_MAX |
Default | 20 |
Change | Dynamic |
Versions Affected | v0.7.7 and later |
When zfs_no_scrub_io = 1
scrubs do not actually scrub data and
simply doing a metadata crawl of the pool instead.
zfs_no_scrub_io | Notes |
---|---|
Tags | scrub |
When to change | Testing scrub feature |
Data Type | boolean |
Range | 0=perform scrub I/O, 1=do not perform scrub I/O |
Default | 0 |
Change | Dynamic |
Versions Affected | v0.6.0 and later |
When zfs_no_scrub_prefetch = 1
, prefetch is disabled for scrub I/Os.
zfs_no_scrub_prefetch | Notes |
---|---|
Tags | prefetch, scrub |
When to change | Testing scrub feature |
Data Type | boolean |
Range | 0=prefetch scrub I/Os, 1=do not prefetch scrub I/Os |
Default | 0 |
Change | Dynamic |
Versions Affected | v0.6.4 and later |
ZFS uses barriers (volatile cache flush commands) to ensure data is committed to permanent media by devices. This ensures consistent on-media state for devices where caches are volatile (eg HDDs).
For devices with nonvolatile caches, the cache flush operation can be a no-op. However, in some RAID arrays, cache flushes can cause the entire cache to be flushed to the backing devices.
To ensure on-media consistency, keep cache flush enabled.
zfs_nocacheflush | Notes |
---|---|
Tags | disks |
When to change | If the storage device has nonvolatile cache, then disabling cache flush can save the cost of occasional cache flush commands |
Data Type | boolean |
Range | 0=send cache flush commands, 1=do not send cache flush commands |
Default | 0 |
Change | Dynamic |
Versions Affected | all |
The NOP-write feature is enabled by default when a
crytographically-secure checksum algorithm is in use by the dataset.
zfs_nopwrite_enabled
allows the NOP-write feature to be completely
disabled.
zfs_nopwrite_enabled | Notes |
---|---|
Tags | checksum, debug |
When to change | TBD |
Data Type | boolean |
Range | 0=disable NOP-write feature, 1=enable NOP-write feature |
Default | 1 |
Change | Dynamic |
Versions Affected | v0.6.0 and later |
zfs_dmu_offset_next_sync
enables forcing txg sync to find holes.
This causes ZFS to act like older versions when SEEK_HOLE
or
SEEK_DATA
flags are used: when a dirty dnode causes txgs to be
synced so the previous data can be found.
zfs_dmu_offset_next_sync | Notes |
---|---|
Tags | DMU |
When to change | to exchange strict hole reporting for performance |
Data Type | boolean |
Range | 0=do not force txg sync to find holes, 1=force txg sync to find holes |
Default | 1 since v2.1.5, previously 0 |
Change | Dynamic |
Versions Affected | v0.7.0 and later |
zfs_pd_bytes_max
limits the number of bytes prefetched during a pool
traversal (eg zfs send
or other data crawling operations). These
prefetches are referred to as "prescient prefetches" and are always 100%
hit rate. The traversal operations do not use the default data or
metadata prefetcher.
zfs_pd_bytes_max | Notes |
---|---|
Tags | prefetch, send |
When to change | TBD |
Data Type | int32 |
Units | bytes |
Range | 0 to INT32_MAX |
Default | 52,428,800 (50 MiB) |
Change | Dynamic |
Versions Affected | TBD |
zfs_per_txg_dirty_frees_percent
as a percentage of
zfs_dirty_data_max controls the percentage of
dirtied blocks from frees in one txg. After the threshold is crossed,
additional dirty blocks from frees wait until the next txg. Thus, when
deleting large files, filling consecutive txgs with deletes/frees, does
not throttle other, perhaps more important, writes.
A side effect of this throttle can impact zfs receive
workloads that
contain a large number of frees and the
ignore_hole_birth optimization is disabled. The
symptom is that the receive workload causes an increase in the frequency
of txg commits. The frequency of txg commits is observable via the
otime
column of /proc/spl/kstat/zfs/POOLNAME/txgs
. Since txg
commits also flush data from volatile caches in HDDs to media, HDD
performance can be negatively impacted. Also, since the frees do not
consume much bandwidth over the pipe, the pipe can appear to stall. Thus
the overall progress of receives is slower than expected.
A value of zero will disable this throttle.
zfs_per_txg_dirty_frees_percent | Notes |
---|---|
Tags | delete |
When to change | For zfs receive workloads,
consider increasing or disabling.
See section ZFS I/O
S
cheduler |
Data Type | ulong |
Units | percent |
Range | 0 to 100 |
Default | 30 |
Change | Dynamic |
Versions Affected | v0.7.0 and later |
zfs_prefetch_disable
controls the predictive prefetcher.
Note that it leaves "prescient" prefetch (eg prefetch for zfs send
)
intact (see zfs_pd_bytes_max)
zfs_prefetch_disable | Notes |
---|---|
Tags | prefetch |
When to change | In some case where the workload is completely random reads, overall performance can be better if prefetch is disabled |
Data Type | boolean |
Range | 0=prefetch enabled, 1=prefetch disabled |
Default | 0 |
Change | Dynamic |
Verification | prefetch efficacy is observed by
arcstat , arc_summary , and the
relevant entries in
/proc/spl/kstat/zfs/arcstats |
Versions Affected | all |
zfs_read_chunk_size
is the limit for ZFS filesystem reads. If an
application issues a read()
larger than zfs_read_chunk_size
,
then the read()
is divided into multiple operations no larger than
zfs_read_chunk_size
zfs_read_chunk_size | Notes |
---|---|
Tags | filesystem |
When to change | TBD |
Data Type | ulong |
Units | bytes |
Range | 512 to ULONG_MAX |
Default | 1,048,576 |
Change | Dynamic |
Versions Affected | all |
Historical statistics for the last zfs_read_history
reads are
available in /proc/spl/kstat/zfs/POOL_NAME/reads
zfs_read_history | Notes |
---|---|
Tags | debug |
When to change | To observe read operation details |
Data Type | int |
Units | lines |
Range | 0 to INT_MAX |
Default | 0 |
Change | Dynamic |
Versions Affected | all |
When zfs_read_history> 0
,
zfs_read_history_hits controls whether ARC hits are displayed in the
read history file, /proc/spl/kstat/zfs/POOL_NAME/reads
zfs_read_history_hits | Notes |
---|---|
Tags | debug |
When to change | To observe read operation details with ARC hits |
Data Type | boolean |
Range | 0=do not include data for ARC hits, 1=include ARC hit data |
Default | 0 |
Change | Dynamic |
Versions Affected | all |
zfs_recover
can be set to true (1) to attempt to recover from
otherwise-fatal errors, typically caused by on-disk corruption. When
set, calls to zfs_panic_recover()
will turn into warning messages
rather than calling panic()
zfs_recover | Notes |
---|---|
Tags | import |
When to change | zfs_recover should only be used as a last resort, as it typically results in leaked space, or worse |
Data Type | boolean |
Range | 0=normal operation, 1=attempt recovery zpool import |
Default | 0 |
Change | Dynamic |
Verification | check output of dmesg and other logs for
details |
Versions Affected | v0.6.4 or later |
Resilvers are processed by the sync thread in syncing context. While
resilvering, ZFS spends at least zfs_resilver_min_time_ms
time
working on a resilver between txg commits.
The zfs_txg_timeout tunable sets a nominal
timeout value for the txg commits. By default, this timeout is 5 seconds
and the zfs_resilver_min_time_ms
is 3 seconds. However, many
variables contribute to changing the actual txg times. The measured txg
interval is observed as the otime
column (in nanoseconds) in the
/proc/spl/kstat/zfs/POOL_NAME/txgs
file.
See also zfs_txg_timeout and zfs_scan_min_time_ms
zfs_resilver_min_time_ms | Notes |
---|---|
Tags | resilver |
When to change | In some resilvering cases, increasing
zfs_resilver_min_time_ms can result
in faster completion |
Data Type | int |
Units | milliseconds |
Range | 1 to zfs_txg_timeout converted to milliseconds |
Default | 3,000 |
Change | Dynamic |
Versions Affected | all |
Scrubs are processed by the sync thread in syncing context. While
scrubbing, ZFS spends at least zfs_scan_min_time_ms
time working on
a scrub between txg commits.
See also zfs_txg_timeout and zfs_resilver_min_time_ms
zfs_scan_min_time_ms | Notes |
---|---|
Tags | scrub |
When to change | In some scrub cases, increasing
zfs_scan_min_time_ms can result in
faster completion |
Data Type | int |
Units | milliseconds |
Range | 1 to zfs_txg_timeout converted to milliseconds |
Default | 1,000 |
Change | Dynamic |
Versions Affected | all |
To preserve progress across reboots the sequential scan algorithm
periodically needs to stop metadata scanning and issue all the
verifications I/Os to disk every zfs_scan_checkpoint_intval
seconds.
zfs_scan_checkpoint_intval | Notes |
---|---|
Tags | resilver, scrub |
When to change | TBD |
Data Type | int |
Units | seconds |
Range | 1 to INT_MAX |
Default | 7,200 (2 hours) |
Change | Dynamic |
Versions Affected | v0.8.0 and later |
This tunable affects how scrub and resilver I/O segments are ordered. A higher number indicates that we care more about how filled in a segment is, while a lower number indicates we care more about the size of the extent without considering the gaps within a segment.
zfs_scan_fill_weight | Notes |
---|---|
Tags | resilver, scrub |
When to change | Testing sequential scrub and resilver |
Data Type | int |
Units | scalar |
Range | 0 to INT_MAX |
Default | 3 |
Change | Prior to zfs module load |
Versions Affected | v0.8.0 and later |
zfs_scan_issue_strategy
controls the order of data verification
while scrubbing or resilvering.
value | description |
---|---|
0 | fs will use strategy 1 during normal verification and strategy 2 while taking a checkpoint |
1 | data is verified as sequentially as possible, given the amount of memory reserved for scrubbing (see zfs_scan_mem_lim_fact). This can improve scrub performance if the pool's data is heavily fragmented. |
2 | the largest mostly-contiguous chunk of found data is verified first. By deferring scrubbing of small segments, we may later find adjacent data to coalesce and increase the segment size. |
zfs_scan_issue_strategy | Notes |
---|---|
Tags | resilver, scrub |
When to change | TBD |
Data Type | enum |
Range | 0 to 2 |
Default | 0 |
Change | Dynamic |
Versions Affected | TBD |
Setting zfs_scan_legacy = 1
enables the legacy scan and scrub
behavior instead of the newer sequential behavior.
zfs_scan_legacy | Notes |
---|---|
Tags | resilver, scrub |
When to change | In some cases, the new scan mode can consumer more memory as it collects and sorts I/Os; using the legacy algorithm can be more memory efficient at the expense of HDD read efficiency |
Data Type | boolean |
Range | 0=use new method: scrubs and resilvers will gather metadata in memory before issuing sequential I/O, 1=use legacy algorithm will be used where I/O is initiated as soon as it is discovered |
Default | 0 |
Change | Dynamic, however changing to 0 does not affect in-progress scrubs or resilvers |
Versions Affected | v0.8.0 and later |
zfs_scan_max_ext_gap
limits the largest gap in bytes between scrub
and resilver I/Os that will still be considered sequential for sorting
purposes.
zfs_scan_max_ext_gap | Notes |
---|---|
Tags | resilver, scrub |
When to change | TBD |
Data Type | ulong |
Units | bytes |
Range | 512 to ULONG_MAX |
Default | 2,097,152 (2 MiB) |
Change | Dynamic, however changing to 0 does not affect in-progress scrubs or resilvers |
Versions Affected | v0.8.0 and later |
zfs_scan_mem_lim_fact
limits the maximum fraction of RAM used for
I/O sorting by sequential scan algorithm. When the limit is reached
scanning metadata is stopped and data verification I/O is started. Data
verification I/O continues until the memory used by the sorting
algorithm drops by
zfs_scan_mem_lim_soft_fact
Memory used by the sequential scan algorithm can be observed as the kmem
sio_cache. This is visible from procfs as
grep sio_cache /proc/slabinfo
and can be monitored using
slab-monitoring tools such as slabtop
zfs_scan_mem_lim_fact | Notes |
---|---|
Tags | memory, resilver, scrub |
When to change | TBD |
Data Type | int |
Units | divisor of physical RAM |
Range | TBD |
Default | 20 (physical RAM / 20 or 5%) |
Change | Dynamic |
Versions Affected | v0.8.0 and later |
zfs_scan_mem_lim_soft_fact
sets the fraction of the hard limit,
zfs_scan_mem_lim_fact, used to determined
the RAM soft limit for I/O sorting by the sequential scan algorithm.
After zfs_scan_mem_lim_fact has been
reached, metadata scanning is stopped until the RAM usage drops by
zfs_scan_mem_lim_soft_fact
zfs_scan_mem_lim_soft_fact | Notes |
---|---|
Tags | resilver, scrub |
When to change | TBD |
Data Type | int |
Units | divisor of (physical RAM / zfs_scan_mem _lim_fact) |
Range | 1 to INT_MAX |
Default | 20 (for default zfs_scan_mem _lim_fact, 0.25% of physical RAM) |
Change | Dynamic |
Versions Affected | v0.8.0 and later |
zfs_scan_vdev_limit
is the maximum amount of data that can be
concurrently issued at once for scrubs and resilvers per leaf vdev.
zfs_scan_vdev_limit
attempts to strike a balance between keeping the
leaf vdev queues full of I/Os while not overflowing the queues causing
high latency resulting in long txg sync times. While
zfs_scan_vdev_limit
represents a bandwidth limit, the existing I/O
limit of zfs_vdev_scrub_max_active
remains in effect, too.
zfs_scan_vdev_limit | Notes |
---|---|
Tags | resilver, scrub, vdev |
When to change | TBD |
Data Type | ulong |
Units | bytes |
Range | 512 to ULONG_MAX |
Default | 4,194,304 (4 MiB) |
Change | Dynamic |
Versions Affected | v0.8.0 and later |
zfs_send_corrupt_data
enables zfs send
to send of corrupt data
by ignoring read and checksum errors. The corrupted or unreadable blocks
are replaced with the value 0x2f5baddb10c
(ZFS bad block)
zfs_send_corrupt_data | Notes |
---|---|
Tags | send |
When to change | When data corruption exists and an attempt
to recover at least some data via
zfs send is needed |
Data Type | boolean |
Range | 0=do not send corrupt data, 1=replace corrupt data with cookie |
Default | 0 |
Change | Dynamic |
Versions Affected | v0.6.0 and later |
The SPA sync process is performed in multiple passes. Once the pass
number reaches zfs_sync_pass_deferred_free
, frees are no long
processed and must wait for the next SPA sync.
The zfs_sync_pass_deferred_free
value is expected to be removed as a
tunable once the optimal value is determined during field testing.
The zfs_sync_pass_deferred_free
pass must be greater than 1 to
ensure that regular blocks are not deferred.
zfs_sync_pass_deferred_free | Notes |
---|---|
Tags | SPA |
When to change | Testing SPA sync process |
Data Type | int |
Units | SPA sync passes |
Range | 1 to INT_MAX |
Default | 2 |
Change | Dynamic |
Versions Affected | all |
The SPA sync process is performed in multiple passes. Once the pass
number reaches zfs_sync_pass_dont_compress
, data block compression
is no longer processed and must wait for the next SPA sync.
The zfs_sync_pass_dont_compress
value is expected to be removed as a
tunable once the optimal value is determined during field testing.
zfs_sync_pass_dont_compress | Notes |
---|---|
Tags | SPA |
When to change | Testing SPA sync process |
Data Type | int |
Units | SPA sync passes |
Range | 1 to INT_MAX |
Default | 5 |
Change | Dynamic |
Versions Affected | all |
The SPA sync process is performed in multiple passes. Once the pass
number reaches zfs_sync_pass_rewrite
, blocks can be split into gang
blocks.
The zfs_sync_pass_rewrite
value is expected to be removed as a
tunable once the optimal value is determined during field testing.
zfs_sync_pass_rewrite | Notes |
---|---|
Tags | SPA |
When to change | Testing SPA sync process |
Data Type | int |
Units | SPA sync passes |
Range | 1 to INT_MAX |
Default | 2 |
Change | Dynamic |
Versions Affected | all |
zfs_sync_taskq_batch_pct
controls the number of threads used by the
DSL pool sync taskq, dp_sync_taskq
zfs_sync_taskq_batch_pct | Notes |
---|---|
Tags | SPA |
When to change | to adjust the number of
dp_sync_taskq threads |
Data Type | int |
Units | percent of number of online CPUs |
Range | 1 to 100 |
Default | 75 |
Change | Prior to zfs module load |
Versions Affected | v0.7.0 and later |
Historical statistics for the last zfs_txg_history
txg commits are
available in /proc/spl/kstat/zfs/POOL_NAME/txgs
The work required to measure the txg commit (SPA statistics) is low. However, for debugging purposes, it can be useful to observe the SPA statistics.
zfs_txg_history | Notes |
---|---|
Tags | debug |
When to change | To observe details of SPA sync behavior. |
Data Type | int |
Units | lines |
Range | 0 to INT_MAX |
Default | 0 for version v0.6.0 to v0.7.6, 100 for version v0.8.0 |
Change | Dynamic |
Versions Affected | all |
The open txg is committed to the pool periodically (SPA sync) and
zfs_txg_timeout
represents the default target upper limit.
txg commits can occur more frequently and a rapid rate of txg commits often indicates a busy write workload, quota limits reached, or the free space is critically low.
Many variables contribute to changing the actual txg times. txg commits
can also take longer than zfs_txg_timeout
if the ZFS write throttle
is not properly tuned or the time to sync is otherwise delayed (eg slow
device). Shorter txg commit intervals can occur due to
zfs_dirty_data_sync for write-intensive
workloads. The measured txg interval is observed as the otime
column
(in nanoseconds) in the /proc/spl/kstat/zfs/POOL_NAME/txgs
file.
See also zfs_dirty_data_sync and zfs_txg_history
zfs_txg_timeout | Notes |
---|---|
Tags | SPA, ZIO_scheduler |
When to change | To optimize the work done by txg commit relative to the pool requirements. See also section ZFS I/O Scheduler |
Data Type | int |
Units | seconds |
Range | 1 to INT_MAX |
Default | 5 |
Change | Dynamic |
Versions Affected | all |
To reduce IOPs, small, adjacent I/Os can be aggregated (coalesced) into
a large I/O. For reads, aggregations occur across small adjacency gaps.
For writes, aggregation can occur at the ZFS or disk level.
zfs_vdev_aggregation_limit
is the upper bound on the size of the
larger, aggregated I/O.
Setting zfs_vdev_aggregation_limit = 0
effectively disables
aggregation by ZFS. However, the block device scheduler can still merge
(aggregate) I/Os. Also, many devices, such as modern HDDs, contain
schedulers that can aggregate I/Os.
In general, I/O aggregation can improve performance for devices, such as
HDDs, where ordering I/O operations for contiguous LBAs is a benefit.
For random access devices, such as SSDs, aggregation might not improve
performance relative to the CPU cycles needed to aggregate. For devices
that represent themselves as having no rotation, the
zfs_vdev_aggregation_limit_non_rotating
parameter is used instead of zfs_vdev_aggregation_limit
zfs_vdev_aggregation_limit | Notes |
---|---|
Tags | vdev, ZIO_scheduler |
When to change | If the workload does not benefit from
aggregation, the
zfs_vdev_aggregation_limit can be
reduced to avoid aggregation attempts |
Data Type | int |
Units | bytes |
Range | 0 to 1,048,576 (default) or 16,777,216
(if zpool large_blocks feature
is enabled) |
Default | 1,048,576, or 131,072 for <v0.8 |
Change | Dynamic |
Verification | ZFS aggregation is observed with
zpool iostat -r and the block
scheduler merging is observed with
iostat -x |
Versions Affected | all |
Note: with the current ZFS code, the vdev cache is not helpful and in
some cases actually harmful. Thusit is disabled by setting the
zfs_vdev_cache_size = 0
zfs_vdev_cache_size
is the size of the vdev cache.
zfs_vdev_cache_size | Notes |
---|---|
Tags | vdev, vdev_cache |
When to change | Do not change |
Data Type | int |
Units | bytes |
Range | 0 to MAX_INT |
Default | 0 (vdev cache is disabled) |
Change | Dynamic |
Verification | vdev cache statistics are available in the
/proc/spl/kstat/zfs/vdev_cache_stats file |
Versions Affected | all |
Note: with the current ZFS code, the vdev cache is not helpful and in some cases actually harmful. Thus it is disabled by setting the zfs_vdev_cache_size to zero. This related tunable is, by default, inoperative.
All read I/Os smaller than zfs_vdev_cache_max
are turned into (1 << zfs_vdev_cache_bshift
) byte reads by the vdev
cache. At most zfs_vdev_cache_size bytes will
be kept in each vdev's cache.
zfs_vdev_cache_bshift | Notes |
---|---|
Tags | vdev, vdev_cache |
When to change | Do not change |
Data Type | int |
Units | shift |
Range | 1 to INT_MAX |
Default | 16 (65,536 bytes) |
Change | Dynamic |
Versions Affected | all |
Note: with the current ZFS code, the vdev cache is not helpful and in some cases actually harmful. Thus it is disabled by setting the zfs_vdev_cache_size to zero. This related tunable is, by default, inoperative.
All read I/Os smaller than zfs_vdev_cache_max will be turned into
(1 <<
zfs_vdev_cache_bshift byte reads
by the vdev cache. At most zfs_vdev_cache_size
bytes will be kept in
each vdev's cache.
zfs_vdev_cache_max | Notes |
---|---|
Tags | vdev, vdev_cache |
When to change | Do not change |
Data Type | int |
Units | bytes |
Range | 512 to INT_MAX |
Default | 16,384 (16 KiB) |
Change | Dynamic |
Versions Affected | all |
The mirror read algorithm uses current load and an incremental weighting
value to determine the vdev to service a read operation. Lower values
determine the preferred vdev. The weighting value is
zfs_vdev_mirror_rotating_inc
for rotating media and
zfs_vdev_mirror_non_rotating_inc
for nonrotating media.
Verify the rotational setting described by a block device in sysfs by
observing /sys/block/DISK_NAME/queue/rotational
zfs_vdev_mirror_rotating_inc | Notes |
---|---|
Tags | vdev, mirror, HDD |
When to change | Increasing for mirrors with both rotating and nonrotating media more strongly favors the nonrotating media |
Data Type | int |
Units | scalar |
Range | 0 to MAX_INT |
Default | 0 |
Change | Dynamic |
Versions Affected | v0.7.0 and later |
The mirror read algorithm uses current load and an incremental weighting
value to determine the vdev to service a read operation. Lower values
determine the preferred vdev. The weighting value is
zfs_vdev_mirror_rotating_inc for
rotating media and zfs_vdev_mirror_non_rotating_inc
for nonrotating
media.
Verify the rotational setting described by a block device in sysfs by
observing /sys/block/DISK_NAME/queue/rotational
zfs_vdev_mirror_non_rotating_inc | Notes |
---|---|
Tags | vdev, mirror, SSD |
When to change | TBD |
Data Type | int |
Units | scalar |
Range | 0 to INT_MAX |
Default | 0 |
Change | Dynamic |
Versions Affected | v0.7.0 and later |
For rotating media in a mirror, if the next I/O offset is within
zfs_vdev_mirror_rotating_seek_offset
then the weighting factor is incremented by
(zfs_vdev_mirror_rotating_seek_inc / 2
). Otherwise the weighting
factor is increased by zfs_vdev_mirror_rotating_seek_inc
. This
algorithm prefers rotating media with lower seek distance.
Verify the rotational setting described by a block device in sysfs by
observing /sys/block/DISK_NAME/queue/rotational
z fs_vdev_mirror_rotating_seek_inc | Notes |
---|---|
Tags | vdev, mirror, HDD |
When to change | TBD |
Data Type | int |
Units | scalar |
Range | 0 to INT_MAX |
Default | 5 |
Change | Dynamic |
Versions Affected | v0.7.0 and later |
For rotating media in a mirror, if the next I/O offset is within
zfs_vdev_mirror_rotating_seek_offset
then the weighting factor is
incremented by
(zfs_vdev_mirror_rotating_seek_inc/ 2
).
Otherwise the weighting factor is increased by
zfs_vdev_mirror_rotating_seek_inc
. This algorithm prefers rotating
media with lower seek distance.
Verify the rotational setting described by a block device in sysfs by
observing /sys/block/DISK_NAME/queue/rotational
zfs_vdev_mirror_rotating_seek_off set | Notes |
---|---|
Tags | vdev, mirror, HDD |
When to change | TBD |
Data Type | int |
Units | bytes |
Range | 0 to INT_MAX |
Default | 1,048,576 (1 MiB) |
Change | Dynamic |
Versions Affected | v0.7.0 and later |
For nonrotating media in a mirror, a seek penalty is applied as sequential I/O's can be aggregated into fewer operations, avoiding unnecessary per-command overhead, often boosting performance.
Verify the rotational setting described by a block device in SysFS by
observing /sys/block/DISK_NAME/queue/rotational
zfs_v dev_mirror_non_rotating_seek_inc | Notes |
---|---|
Tags | vdev, mirror, SSD |
When to change | TBD |
Data Type | int |
Units | scalar |
Range | 0 to INT_MAX |
Default | 1 |
Change | Dynamic |
Versions Affected | v0.7.0 and later |
To reduce IOPs, small, adjacent I/Os are aggregated (coalesced) into
into a large I/O. For reads, aggregations occur across small adjacency
gaps where the gap is less than zfs_vdev_read_gap_limit
zfs_vdev_read_gap_limit | Notes |
---|---|
Tags | vdev, ZIO_scheduler |
When to change | TBD |
Data Type | int |
Units | bytes |
Range | 0 to INT_MAX |
Default | 32,768 (32 KiB) |
Change | Dynamic |
Versions Affected | all |
To reduce IOPs, small, adjacent I/Os are aggregated (coalesced) into
into a large I/O. For writes, aggregations occur across small adjacency
gaps where the gap is less than zfs_vdev_write_gap_limit
zfs_vdev_write_gap_limit | Notes |
---|---|
Tags | vdev, ZIO_scheduler |
When to change | TBD |
Data Type | int |
Units | bytes |
Range | 0 to INT_MAX |
Default | 4,096 (4 KiB) |
Change | Dynamic |
Versions Affected | all |
Prior to version 0.8.3, when the pool is imported, for whole disk vdevs,
the block device I/O scheduler is set to zfs_vdev_scheduler
.
The most common schedulers are: noop, cfq, bfq, and deadline.
In some cases, the scheduler is not changeable using this method.
Known schedulers that cannot be changed are: scsi_mq and none.
In these cases, the scheduler is unchanged and an error message can be
reported to logs.
The parameter was disabled in v0.8.3 but left in place to avoid breaking
loading of the zfs
module if the parameter is specified in modprobe
configuration on existing installations. It is recommended that users
leave the default scheduler "unless you're encountering a specific
problem, or have clearly measured a performance improvement for your
workload,"
and if so, to change it via the /sys/block/<device>/queue/scheduler
interface and/or udev rule.
zfs_vdev_scheduler | Notes |
---|---|
Tags | vdev, ZIO_scheduler |
When to change | since ZFS has its own I/O scheduler, using a simple scheduler can result in more consistent performance |
Data Type | string |
Range | expected: noop, cfq, bfq, and deadline |
Default | noop |
Change | Dynamic, but takes effect upon pool creation or import |
Versions Affected | all, but no effect since v0.8.3 |
zfs_vdev_raidz_impl
overrides the raidz parity algorithm. By
default, the algorithm is selected at zfs module load time by the
results of a microbenchmark of algorithms based on the current hardware.
Once the module is loaded, the content of
/sys/module/zfs/parameters/zfs_vdev_raidz_impl
shows available
options with the currently selected enclosed in []
. Details of the
results of the microbenchmark are observable in the
/proc/spl/kstat/zfs/vdev_raidz_bench
file.
algorithm | architecture | description |
---|---|---|
fastest | all | fastest implementation selected by microbenchmark |
original | all | original raidz implementation |
scalar | all | scalar raidz implementation |
sse2 | 64-bit x86 | uses SSE2 instruction set |
ssse3 | 64-bit x86 | uses SSSE3 instruction set |
avx2 | 64-bit x86 | uses AVX2 instruction set |
avx512f | 64-bit x86 | uses AVX512F instruction set |
avx512bw | 64-bit x86 | uses AVX512F & AVX512BW instruction sets |
aarch64_neon | aarch64/64 bit ARMv8 | uses NEON |
aarch64_neonx2 | aarch64/64 bit ARMv8 | uses NEON with more unrolling |
zfs_vdev_raidz_impl | Notes |
---|---|
Tags | CPU, raidz, vdev |
When to change | testing raidz algorithms |
Data Type | string |
Range | see table above |
Default | fastest |
Change | Dynamic |
Versions Affected | v0.7.0 and later |
zfs_zevent_cols
is a soft wrap limit in columns (characters) for ZFS
events logged to the console.
zfs_zevent_cols | Notes |
---|---|
Tags | debug |
When to change | if 80 columns isn't enough |
Data Type | int |
Units | characters |
Range | 1 to INT_MAX |
Default | 80 |
Change | Dynamic |
Versions Affected | all |
If zfs_zevent_console
is true (1), then ZFS events are logged to the
console.
More logging and log filtering capabilities are provided by zed
zfs_zevent_console | Notes |
---|---|
Tags | debug |
When to change | to log ZFS events to the console |
Data Type | boolean |
Range | 0=do not log to console, 1=log to console |
Default | 0 |
Change | Dynamic |
Versions Affected | all |
zfs_zevent_len_max
is the maximum ZFS event queue length. A value of
0 results in a calculated value (16 * number of CPUs) with a minimum of
64. Events in the queue can be viewed with the zpool events
command.
zfs_zevent_len_max | Notes |
---|---|
Tags | debug |
When to change | increase to see more ZFS events |
Data Type | int |
Units | events |
Range | 0 to INT_MAX |
Default | 0 (calculate as described above) |
Change | Dynamic |
Versions Affected | all |
During a SPA sync, intent log transaction groups (itxg) are cleaned. The
cleaning work is dispatched to the DSL pool ZIL clean taskq
(dp_zil_clean_taskq
).
zfs_zil_clean_taskq_minalloc is the
minimum and zfs_zil_clean_taskq_maxalloc
is the maximum number of
cached taskq entries for dp_zil_clean_taskq
. The actual number of
taskq entries dynamically varies between these values.
When zfs_zil_clean_taskq_maxalloc
is exceeded transaction records
(itxs) are cleaned synchronously with possible negative impact to the
performance of SPA sync.
Ideally taskq entries are pre-allocated prior to being needed by
zil_clean()
, thus avoiding dynamic allocation of new taskq entries.
zfs_zil_clean_taskq_maxalloc | Notes |
---|---|
Tags | ZIL |
When to change | If more dp_zil_clean_taskq
entries are needed to prevent the
itxs from being synchronously
cleaned |
Data Type | int |
Units | dp_zil_clean_taskq taskq entries |
Range | zfs_zil_clean_taskq_minallo
c
to INT_MAX |
Default | 1,048,576 |
Change | Dynamic, takes effect per-pool when the pool is imported |
Versions Affected | v0.8.0 |
During a SPA sync, intent log transaction groups (itxg) are cleaned. The
cleaning work is dispatched to the DSL pool ZIL clean taskq
(dp_zil_clean_taskq
). zfs_zil_clean_taskq_minalloc
is the
minimum and
zfs_zil_clean_taskq_maxalloc is the
maximum number of cached taskq entries for dp_zil_clean_taskq
. The
actual number of taskq entries dynamically varies between these values.
zfs_zil_clean_taskq_minalloc
is the minimum number of ZIL
transaction records (itxs).
Ideally taskq entries are pre-allocated prior to being needed by
zil_clean()
, thus avoiding dynamic allocation of new taskq entries.
zfs_zil_clean_taskq_minalloc | Notes |
---|---|
Tags | ZIL |
When to change | TBD |
Data Type | int |
Units | dp_zil_clean_taskq taskq entries |
Range | 1 to zfs_zil_clean_taskq_maxallo c |
Default | 1,024 |
Change | Dynamic, takes effect per-pool when the pool is imported |
Versions Affected | v0.8.0 |
zfs_zil_clean_taskq_nthr_pct
controls the number of threads used by
the DSL pool ZIL clean taskq (dp_zil_clean_taskq
). The default value
of 100% will create a maximum of one thread per cpu.
zfs_zil_clean_taskq_nthr_pct | Notes |
---|---|
Tags | taskq, ZIL |
When to change | Testing ZIL clean and SPA sync performance |
Data Type | int |
Units | percent of number of CPUs |
Range | 1 to 100 |
Default | 100 |
Change | Dynamic, takes effect per-pool when the pool is imported |
Versions Affected | v0.8.0 |
If zil_replay_disable = 1
, then when a volume or filesystem is
brought online, no attempt to replay the ZIL is made and any existing
ZIL is destroyed. This can result in loss of data without notice.
zil_replay_disable | Notes |
---|---|
Tags | debug, ZIL |
When to change | Do not change |
Data Type | boolean |
Range | 0=replay ZIL, 1=destroy ZIL |
Default | 0 |
Change | Dynamic |
Versions Affected | v0.6.5 |
zil_slog_bulk
is the log device write size limit per commit executed
with synchronous priority. Writes below zil_slog_bulk
are executed
with synchronous priority. Writes above zil_slog_bulk
are executed
with lower (asynchronous) priority to reduct potential log device abuse
by a single active ZIL writer.
zil_slog_bulk | Notes |
---|---|
Tags | ZIL |
When to change | See ZFS I/O Scheduler |
Data Type | ulong |
Units | bytes |
Range | 0 to ULONG_MAX |
Default | 786,432 |
Change | Dynamic |
Versions Affected | v0.8.0 |
If a ZFS I/O operation takes more than zio_delay_max
milliseconds to
complete, then an event is logged. Note that this is only a logging
facility, not a timeout on operations. See also zpool events
zio_delay_max | Notes |
---|---|
Tags | debug |
When to change | when debugging slow I/O |
Data Type | int |
Units | milliseconds |
Range | 1 to INT_MAX |
Default | 30,000 (30 seconds) |
Change | Dynamic |
Versions Affected | all |
zio_dva_throttle_enabled
controls throttling of block allocations in
the ZFS I/O (ZIO) pipeline. When enabled, the maximum number of pending
allocations per top-level vdev is limited by
zfs_vdev_queue_depth_pct
zio_dva_throttle_enabled | Notes |
---|---|
Tags | vdev, ZIO_scheduler |
When to change | Testing ZIO block allocation algorithms |
Data Type | boolean |
Range | 0=do not throttle ZIO block allocations, 1=throttle ZIO block allocations |
Default | 1 |
Change | Dynamic |
Versions Affected | v0.7.0 and later |
zio_requeue_io_start_cut_in_line
controls prioritization of a
re-queued ZFS I/O (ZIO) in the ZIO pipeline by the ZIO taskq.
zio_requeue_io_start_cut_in_line | Notes |
---|---|
Tags | Z IO_scheduler |
When to change | Do not change |
Data Type | boolean |
Range | 0=don't prioritize re-queued I/Os, 1=prioritize re-queued I/Os |
Default | 1 |
Change | Dynamic |
Versions Affected | all |
zio_taskq_batch_pct
sets the number of I/O worker threads as a
percentage of online CPUs. These workers threads are responsible for IO
work such as compression and checksum calculations.
Each block is handled by one worker thread, so maximum overall worker thread throughput is function of the number of concurrent blocks being processed, the number of worker threads, and the algorithms used. The default value of 75% is chosen to avoid using all CPUs which can result in latency issues and inconsistent application performance, especially when high compression is enabled.
The taskq batch processes are:
taskq | process name | Notes |
---|---|---|
Write issue | z_wr_iss[_#] | Can be CPU intensive, runs at lower priority than other taskqs |
Other taskqs exist, but most have fixed numbers of instances and therefore require recompiling the kernel module to adjust.
zio_taskq_batch_pct | Notes |
---|---|
Tags | taskq, ZIO_scheduler |
When to change | To tune parallelism in multiprocessor systems |
Data Type | int |
Units | percent of number of CPUs |
Range | 1 to 100, fractional number of CPUs are rounded down |
Default | 75 for versions before v.2.2.0, 80 after |
Change | Prior to zfs module load |
Verification | The number of taskqs for each batch group can
be observed using ps and counting the
threads |
Versions Affected | TBD |
zvol_inhibit_dev
controls the creation of volume device nodes upon
pool import.
zvol_inhibit_dev | Notes |
---|---|
Tags | import, volume |
When to change | Inhibiting can slightly improve startup time on systems with a very large number of volumes |
Data Type | boolean |
Range | 0=create volume device nodes, 1=do not create volume device nodes |
Default | 0 |
Change | Dynamic, takes effect per-pool when the pool is imported |
Versions Affected | v0.6.0 and later |
zvol_major
is the default major number for volume devices.
zvol_major | Notes |
---|---|
Tags | volume |
When to change | Do not change |
Data Type | uint |
Default | 230 |
Change | Dynamic, takes effect per-pool when the pool is imported or volumes are created |
Versions Affected | all |
Discard (aka ATA TRIM or SCSI UNMAP) operations done on volumes are done
in batches zvol_max_discard_blocks
blocks. The block size is
determined by the volblocksize
property of a volume.
Some applications, such as mkfs
, discard the whole volume at once
using the maximum possible discard size. As a result, many gigabytes of
discard requests are not uncommon. Unfortunately, if a large amount of
data is already allocated in the volume, ZFS can be quite slow to
process discard requests. This is especially true if the volblocksize is
small (eg default=8KB). As a result, very large discard requests can
take a very long time (perhaps minutes under heavy load) to complete.
This can cause a number of problems, most notably if the volume is
accessed remotely (eg via iSCSI), in which case the client has a high
probability of timing out on the request.
Limiting the zvol_max_discard_blocks
can decrease the amount of
discard workload request by setting the discard_max_bytes
and
discard_max_hw_bytes
for the volume's block device in SysFS. This
value is readable by volume device consumers.
zvol_max_discard_blocks | Notes |
---|---|
Tags | discard, volume |
When to change | if volume discard activity severely impacts other workloads |
Data Type | ulong |
Units | number of blocks of size volblocksize |
Range | 0 to ULONG_MAX |
Default | 16,384 |
Change | Dynamic, takes effect per-pool when the pool is imported or volumes are created |
Verification | Observe value of
/sys/block/
VOLUME_INSTANCE/queue/discard_max_bytes |
Versions Affected | v0.6.0 and later |
When importing a pool with volumes or adding a volume to a pool,
zvol_prefetch_bytes
are prefetch from the start and end of the
volume. Prefetching these regions of the volume is desirable because
they are likely to be accessed immediately by blkid(8)
or by the
kernel scanning for a partition table.
zvol_prefetch_bytes | Notes |
---|---|
Tags | prefetch, volume |
When to change | TBD |
Data Type | uint |
Units | bytes |
Range | 0 to UINT_MAX |
Default | 131,072 |
Change | Dynamic |
Versions Affected | v0.6.5 and later |
When processing I/O requests for a volume submit them synchronously. This effectively limits the queue depth to 1 for each I/O submitter. When set to 0 requests are handled asynchronously by the "zvol" thread pool.
See also zvol_threads
zvol_request_sync | Notes |
---|---|
Tags | volume |
When to change | Testing concurrent volume requests |
Data Type | boolean |
Range | 0=do concurrent (async) volume requests, 1=do sync volume requests |
Default | 0 |
Change | Dynamic |
Versions Affected | v0.7.2 and later |
zvol_threads controls the maximum number of threads handling concurrent volume I/O requests.
The default of 32 threads behaves similarly to a disk with a 32-entry command queue. The actual number of threads required can vary widely by workload and available CPUs. If lock analysis shows high contention in the zvol taskq threads, then reducing the number of zvol_threads or workload queue depth can improve overall throughput.
See also zvol_request_sync
zvol_threads | Notes |
---|---|
Tags | volume |
When to change | Matching the number of concurrent volume requests with workload requirements can improve concurrency |
Data Type | uint |
Units | threads |
Range | 1 to UINT_MAX |
Default | 32 |
Change | Dynamic, takes effect per-volume when the pool is imported or volumes are created |
Verification | iostat using avgqu-sz or aqu-sz
results |
Versions Affected | v0.7.0 and later |
zvol_volmode
defines volume block devices behaviour when the
volmode
property is set to default
Note: to maintain compatibility with ZFS on BSD, "geom" is synonymous with "full"
value | volmode | Description |
---|---|---|
1 | full | legacy fully functional behaviour (default) |
2 | dev | hide partitions on volume block devices |
3 | none | not exposing volumes outside ZFS |
zvol_volmode | Notes |
---|---|
Tags | volume |
When to change | TBD |
Data Type | enum |
Range | 1, 2, or 3 |
Default | 1 |
Change | Dynamic |
Versions Affected | v0.7.0 and later |
zfs_qat_disable
controls the Intel QuickAssist Technology (QAT)
driver providing hardware acceleration for gzip compression. When the
QAT hardware is present and qat driver available, the default behaviour
is to enable QAT.
zfs_qat_disable | Notes |
---|---|
Tags | compression, QAT |
When to change | Testing QAT functionality |
Data Type | boolean |
Range | 0=use QAT acceleration if available, 1=do not use QAT acceleration |
Default | 0 |
Change | Dynamic |
Versions Affected | v0.7, renamed to zfs_qat_ compress_disable in v0.8 |
zfs_qat_checksum_disable
controls the Intel QuickAssist Technology
(QAT) driver providing hardware acceleration for checksums. When the QAT
hardware is present and qat driver available, the default behaviour is
to enable QAT.
zfs_qat_checksum_disable | Notes |
---|---|
Tags | checksum, QAT |
When to change | Testing QAT functionality |
Data Type | boolean |
Range | 0=use QAT acceleration if available, 1=do not use QAT acceleration |
Default | 0 |
Change | Dynamic |
Versions Affected | v0.8.0 |
zfs_qat_compress_disable
controls the Intel QuickAssist Technology
(QAT) driver providing hardware acceleration for gzip compression. When
the QAT hardware is present and qat driver available, the default
behaviour is to enable QAT.
zfs_qat_compress_disable | Notes |
---|---|
Tags | compression, QAT |
When to change | Testing QAT functionality |
Data Type | boolean |
Range | 0=use QAT acceleration if available, 1=do not use QAT acceleration |
Default | 0 |
Change | Dynamic |
Versions Affected | v0.8.0 |
zfs_qat_encrypt_disable
controls the Intel QuickAssist Technology
(QAT) driver providing hardware acceleration for encryption. When the
QAT hardware is present and qat driver available, the default behaviour
is to enable QAT.
zfs_qat_encrypt_disable | Notes |
---|---|
Tags | encryption, QAT |
When to change | Testing QAT functionality |
Data Type | boolean |
Range | 0=use QAT acceleration if available, 1=do not use QAT acceleration |
Default | 0 |
Change | Dynamic |
Versions Affected | v0.8.0 |
The dbuf_cache_hiwater_pct
and
dbuf_cache_lowater_pct define the
operating range for dbuf cache evict thread. The hiwater and lowater are
percentages of the dbuf_cache_max_bytes
value. When the dbuf cache grows above ((100% +
dbuf_cache_hiwater_pct
) *
dbuf_cache_max_bytes) then the dbuf cache
thread begins evicting. When the dbug cache falls below ((100% -
dbuf_cache_lowater_pct) *
dbuf_cache_max_bytes) then the dbuf cache
thread stops evicting.
dbuf_cache_hiwater_pct | Notes |
---|---|
Tags | dbuf_cache |
When to change | Testing dbuf cache algorithms |
Data Type | uint |
Units | percent |
Range | 0 to UINT_MAX |
Default | 10 |
Change | Dynamic |
Versions Affected | v0.7.0 and later |
The dbuf_cache_hiwater_pct and dbuf_cache_lowater_pct define the
operating range for dbuf cache evict thread. The hiwater and lowater are
percentages of the dbuf_cache_max_bytes
value. When the dbuf cache grows above ((100% +
dbuf_cache_hiwater_pct) *
dbuf_cache_max_bytes) then the dbuf cache
thread begins evicting. When the dbug cache falls below ((100% -
dbuf_cache_lowater_pct
) *
dbuf_cache_max_bytes) then the dbuf cache
thread stops evicting.
dbuf_cache_lowater_pct | Notes |
---|---|
Tags | dbuf_cache |
When to change | Testing dbuf cache algorithms |
Data Type | uint |
Units | percent |
Range | 0 to UINT_MAX |
Default | 10 |
Change | Dynamic |
Versions Affected | v0.7.0 and later |
The dbuf cache maintains a list of dbufs that are not currently held but have been recently released. These dbufs are not eligible for ARC eviction until they are aged out of the dbuf cache. Dbufs are added to the dbuf cache once the last hold is released. If a dbuf is later accessed and still exists in the dbuf cache, then it will be removed from the cache and later re-added to the head of the cache. Dbufs that are aged out of the cache will be immediately destroyed and become eligible for ARC eviction.
The size of the dbuf cache is set by dbuf_cache_max_bytes
. The
actual size is dynamically adjusted to the minimum of current ARC target
size (c
) >> dbuf_cache_max_shift and the
default dbuf_cache_max_bytes
dbuf_cache_max_bytes | Notes |
---|---|
Tags | dbuf_cache |
When to change | Testing dbuf cache algorithms |
Data Type | ulong |
Units | bytes |
Range | 16,777,216 to ULONG_MAX |
Default | 104,857,600 (100 MiB) |
Change | Dynamic |
Versions Affected | v0.7.0 and later |
The dbuf_cache_max_bytes minimum is the
lesser of dbuf_cache_max_bytes and the
current ARC target size (c
) >> dbuf_cache_max_shift
dbuf_cache_max_shift | Notes |
---|---|
Tags | dbuf_cache |
When to change | Testing dbuf cache algorithms |
Data Type | int |
Units | shift |
Range | 1 to 63 |
Default | 5 |
Change | Dynamic |
Versions Affected | v0.7.0 and later |
Each of the concurrent object allocators grabs
2^dmu_object_alloc_chunk_shift
dnode slots at a time. The default is
to grab 128 slots, or 4 blocks worth. This default value was
experimentally determined to be the lowest value that eliminates the
measurable effect of lock contention in the DMU object allocation code
path.
dmu_object_alloc_chunk_shift | Notes |
---|---|
Tags | allocation, DMU |
When to change | If the workload creates many files
concurrently on a system with many
CPUs, then increasing
dmu_object_alloc_chunk_shift can
decrease lock contention |
Data Type | int |
Units | shift |
Range | 7 to 9 |
Default | 7 |
Change | Dynamic |
Versions Affected | v0.7.0 and later |
Alias for ignore_hole_birth
zfs_abd_scatter_enabled
controls the ARC Buffer Data (ABD)
scatter/gather feature.
When disabled, the legacy behaviour is selected using linear buffers.
For linear buffers, all the data in the ABD is stored in one contiguous
buffer in memory (from a zio_[data_]buf_*
kmem cache).
When enabled (default), the data in the ABD is split into equal-sized
chunks (from the abd_chunk_cache
kmem_cache), with pointers to the
chunks recorded in an array at the end of the ABD structure. This allows
more efficient memory allocation for buffers, especially when large
recordsizes are used.
zfs_abd_scatter_enabled | Notes |
---|---|
Tags | ABD, memory |
When to change | Testing ABD |
Data Type | boolean |
Range | 0=use linear allocation only, 1=allow scatter/gather |
Default | 1 |
Change | Dynamic |
Verification | ABD statistics are observable in
/proc/spl/kstat/zfs/abdstats . Slab
allocations are observable in
/proc/slabinfo |
Versions Affected | v0.7.0 and later |
zfs_abd_scatter_max_order
sets the maximum order for physical page
allocation when ABD is enabled (see
zfs_abd_scatter_enabled)
See also Buddy Memory Allocation in the Linux kernel documentation.
zfs_abd_scatter_max_order | Notes |
---|---|
Tags | ABD, memory |
When to change | Testing ABD features |
Data Type | int |
Units | orders |
Range | 1 to 10 (upper limit is hardware-dependent) |
Default | 10 |
Change | Dynamic |
Verification | ABD statistics are observable in
/proc/spl/kstat/zfs/abdstats |
Versions Affected | v0.7.0 and later |
When compression is enabled for a dataset, later reads of the data can store the blocks in ARC in their on-disk, compressed state. This can increse the effective size of the ARC, as counted in blocks, and thus improve the ARC hit ratio.
zfs_compressed_arc_enabled | Notes |
---|---|
Tags | ABD, compression |
When to change | Testing ARC compression feature |
Data Type | boolean |
Range | 0=compressed ARC disabled (legacy behaviour), 1=compress ARC data |
Default | 1 |
Change | Dynamic |
Verification | raw ARC statistics are observable in
/proc/spl/kstat/zfs/arcstats and
ARC hit ratios can be observed using
arcstat |
Versions Affected | v0.7.0 and later |
For encrypted datasets, the salt is regenerated every
zfs_key_max_salt_uses
blocks. This automatic regeneration reduces
the probability of collisions due to the Birthday problem. When set to
the default (400,000,000) the probability of collision is approximately
1 in 1 trillion.
zfs_key_max_salt_uses | Notes |
---|---|
Tags | encryption |
When to change | Testing encryption features |
Data Type | ulong |
Units | blocks encrypted |
Range | 1 to ULONG_MAX |
Default | 400,000,000 |
Change | Dynamic |
Versions Affected | v0.8.0 and later |
zfs_object_mutex_size
facilitates resizing the the per-dataset znode
mutex array for testing deadlocks therein.
zfs_object_mutex_size | Notes |
---|---|
Tags | debug |
When to change | Testing znode mutex array deadlocks |
Data Type | uint |
Units | orders |
Range | 1 to UINT_MAX |
Default | 64 |
Change | Dynamic |
Versions Affected | v0.7.0 and later |
When scrubbing or resilvering, by default, ZFS checks to ensure it is
not over the hard memory limit before each txg commit. If finer-grained
control of this is needed zfs_scan_strict_mem_lim
can be set to 1 to
enable checking before scanning each block.
zfs_scan_strict_mem_lim | Notes |
---|---|
Tags | memory, resilver, scrub |
When to change | Do not change |
Data Type | boolean |
Range | 0=normal scan behaviour, 1=check hard memory limit strictly during scan |
Default | 0 |
Change | Dynamic |
Versions Affected | v0.8.0 |
zfs_send_queue_length
is the maximum number of bytes allowed in the
zfs send queue.
zfs_send_queue_length | Notes |
---|---|
Tags | send |
When to change | When using the largest recordsize or volblocksize (16 MiB), increasing can improve send efficiency |
Data Type | int |
Units | bytes |
Range | Must be at least twice the maximum recordsize or volblocksize in use |
Default | 16,777,216 bytes (16 MiB) |
Change | Dynamic |
Versions Affected | v0.8.1 |
zfs_recv_queue_length
is the maximum number of bytes allowed in the
zfs receive queue.
zfs_recv_queue_length | Notes |
---|---|
Tags | receive |
When to change | When using the largest recordsize or volblocksize (16 MiB), increasing can improve receive efficiency |
Data Type | int |
Units | bytes |
Range | Must be at least twice the maximum recordsize or volblocksize in use |
Default | 16,777,216 bytes (16 MiB) |
Change | Dynamic |
Versions Affected | v0.8.1 |
arc_min_prefetch_lifespan
is the minimum time for a prefetched block
to remain in ARC before it is eligible for eviction.
zfs_arc_min_prefetch_lifespan | Notes |
---|---|
Tags | ARC |
When to change | TBD |
Data Type | int |
Units | clock ticks |
Range | 0 = use default value |
Default | 1 second (as expressed in clock ticks) |
Change | Dynamic |
Versions Affected | v0.7.0 |
zfs_scan_ignore_errors
allows errors discovered during scrub or
resilver to be ignored. This can be tuned as a workaround to remove the
dirty time list (DTL) when completing a pool scan. It is intended to be
used during pool repair or recovery to prevent resilvering when the pool
is imported.
zfs_scan_ignore_errors | Notes |
---|---|
Tags | resilver |
When to change | See description above |
Data Type | boolean |
Range | 0 = do not ignore errors, 1 = ignore errors during pool scrub or resilver |
Default | 0 |
Change | Dynamic |
Versions Affected | v0.8.1 |
zfs_top_maxinflight
is used to limit the maximum number of I/Os
queued to top-level vdevs during scrub or resilver operations. The
actual top-level vdev limit is calculated by multiplying the number of
child vdevs by zfs_top_maxinflight
This limit is an additional cap
over and above the scan limits
zfs_top_maxinflight | Notes |
---|---|
Tags | resilver, scrub, ZIO_scheduler |
When to change | for modern ZFS versions, the ZIO scheduler limits usually take precedence |
Data Type | int |
Units | I/O operations |
Range | 1 to MAX_INT |
Default | 32 |
Change | Dynamic |
Versions Affected | v0.6.0 |
zfs_resilver_delay
sets a time-based delay for resilver I/Os. This
delay is in addition to the ZIO scheduler's treatment of scrub
workloads. See also zfs_scan_idle
zfs_resilver_delay | Notes |
---|---|
Tags | resilver, ZIO_scheduler |
When to change | increasing can reduce impact of resilver workload on dynamic workloads |
Data Type | int |
Units | clock ticks |
Range | 0 to MAX_INT |
Default | 2 |
Change | Dynamic |
Versions Affected | v0.6.0 |
zfs_scrub_delay
sets a time-based delay for scrub I/Os. This delay
is in addition to the ZIO scheduler's treatment of scrub workloads. See
also zfs_scan_idle
zfs_scrub_delay | Notes |
---|---|
Tags | scrub, ZIO_scheduler |
When to change | increasing can reduce impact of scrub workload on dynamic workloads |
Data Type | int |
Units | clock ticks |
Range | 0 to MAX_INT |
Default | 4 |
Change | Dynamic |
Versions Affected | v0.6.0 |
When a non-scan I/O has occurred in the past zfs_scan_idle
clock
ticks, then zfs_resilver_delay or
zfs_scrub_delay are enabled.
zfs_scan_idle | Notes |
---|---|
Tags | resilver, scrub, ZIO_scheduler |
When to change | as part of a resilver/scrub tuning effort |
Data Type | int |
Units | clock ticks |
Range | 0 to MAX_INT |
Default | 50 |
Change | Dynamic |
Versions Affected | v0.6.0 |
By default, ZFS will choose the highest performance, hardware-optimized
implementation of the AES encryption algorithm. The icp_aes_impl
tunable overrides this automatic choice.
Note: icp_aes_impl
is set in the icp
kernel module, not the
zfs
kernel module.
To observe the available options
cat /sys/module/icp/parameters/icp_aes_impl
The default option is
shown in brackets '[]'
icp_aes_impl | Notes |
---|---|
Tags | encryption |
Kernel module | icp |
When to change | debugging ZFS encryption on hardware |
Data Type | string |
Range | varies by hardware |
Default | automatic, depends on the hardware |
Change | dynamic |
Versions Affected | planned for v2 |
By default, ZFS will choose the highest performance, hardware-optimized
implementation of the GCM encryption algorithm. The icp_gcm_impl
tunable overrides this automatic choice.
Note: icp_gcm_impl
is set in the icp
kernel module, not the
zfs
kernel module.
To observe the available options
cat /sys/module/icp/parameters/icp_gcm_impl
The default option is
shown in brackets '[]'
icp_gcm_impl | Notes |
---|---|
Tags | encryption |
Kernel module | icp |
When to change | debugging ZFS encryption on hardware |
Data Type | string |
Range | varies by hardware |
Default | automatic, depends on the hardware |
Change | Dynamic |
Versions Affected | planned for v2 |
zfs_abd_scatter_min_size
changes the ARC buffer data (ABD)
allocator's threshold for using linear or page-based scatter buffers.
Allocations smaller than zfs_abd_scatter_min_size
use linear ABDs.
Scatter ABD's use at least one page each, so sub-page allocations waste some space when allocated as scatter allocations. For example, 2KB scatter allocation wastes half of each page. Using linear ABD's for small allocations results in slabs containing many allocations. This can improve memory efficiency, at the expense of more work for ARC evictions attempting to free pages, because all the buffers on one slab need to be freed in order to free the slab and its underlying pages.
Typically, 512B and 1KB kmem caches have 16 buffers per slab, so it's possible for them to actually waste more memory than scatter allocations:
- one page per buf = wasting 3/4 or 7/8
- one buf per slab = wasting 15/16
Spill blocks are typically 512B and are heavily used on systems running
selinux with the default dnode size and the xattr=sa
property set.
By default, linear allocations for 512B and 1KB, and scatter allocations for larger (>= 1.5KB) allocation requests.
zfs_abd_scatter_min_size | Notes |
---|---|
Tags | ARC |
When to change | debugging memory allocation, especially for large pages |
Data Type | int |
Units | bytes |
Range | 0 to MAX_INT |
Default | 1536 (512B and 1KB allocations will be linear) |
Change | Dynamic |
Versions Affected | planned for v2 |
zfs_unlink_suspend_progress
changes the policy for removing pending
unlinks. 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.
zfs_unlink_suspend_progress | Notes |
---|---|
Tags | |
When to change | used by the ZFS test suite (ZTS) to facilitate testing |
Data Type | boolean |
Range | 0 = use async unlink removal, 1 = do not async unlink thus leaking space |
Default | 0 |
Change | prior to dataset mount |
Versions Affected | planned for v2 |
spa_load_verify_shift
sets the fraction of ARC that can be used by
inflight I/Os when verifying the pool during import. This value is a
"shift" representing the fraction of ARC target size
(grep -w c /proc/spl/kstat/zfs/arcstats
). The ARC target size is
shifted to the right. Thus a value of '2' results in the fraction = 1/4,
while a value of '4' results in the fraction = 1/8.
For large memory machines, pool import can consume large amounts of ARC:
much larger than the value of maxinflight. This can result in
spa_load_verify_maxinflight having a
value of 0 causing the system to hang. Setting spa_load_verify_shift
can reduce this limit and allow importing without hanging.
spa_load_verify_shift | Notes |
---|---|
Tags | import, ARC, SPA |
When to change | troubleshooting pool import on large memory machines |
Data Type | int |
Units | shift |
Range | 1 to MAX_INT |
Default | 4 |
Change | prior to importing a pool |
Versions Affected | planned for v2 |
spa_load_print_vdev_tree
enables printing of the attempted pool
import's vdev tree to kernel message to the ZFS debug message log
/proc/spl/kstat/zfs/dbgmsg
Both the provided vdev tree and MOS vdev
tree are printed, which can be useful for debugging problems with the
zpool cachefile
spa_load_print_vdev_tree | Notes |
---|---|
Tags | import, SPA |
When to change | troubleshooting pool import failures |
Data Type | boolean |
Range | 0 = do not print pool configuration in logs, 1 = print pool configuration in logs |
Default | 0 |
Change | prior to pool import |
Versions Affected | planned for v2 |
When importing a pool in readonly mode
(zpool import -o readonly=on ...
) then up to
zfs_max_missing_tvds
top-level vdevs can be missing, but the import
can attempt to progress.
Note: This is strictly intended for advanced pool recovery cases since
missing data is almost inevitable. Pools with missing devices can only
be imported read-only for safety reasons, and the pool's failmode
property is automatically set to continue
The expected use case is to recover pool data immediately after accidentally adding a non-protected vdev to a protected pool.
- With 1 missing top-level vdev, ZFS should be able to import the pool and mount all datasets. User data that was not modified after the missing device has been added should be recoverable. Thus snapshots created prior to the addition of that device should be completely intact.
- With 2 missing top-level vdevs, some datasets may fail to mount since there are dataset statistics that are stored as regular metadata. Some data might be recoverable if those vdevs were added recently.
- With 3 or more top-level missing vdevs, the pool is severely damaged and MOS entries may be missing entirely. Chances of data recovery are very low. Note that there are also risks of performing an inadvertent rewind as we might be missing all the vdevs with the latest uberblocks.
zfs_max_missing_tvds | Notes |
---|---|
Tags | import |
When to change | troubleshooting pools with missing devices |
Data Type | int |
Units | missing top-level vdevs |
Range | 0 to MAX_INT |
Default | 0 |
Change | prior to pool import |
Versions Affected | planned for v2 |
dbuf_metadata_cache_shift
sets the size of the dbuf metadata cache
as a fraction of ARC target size. This is an alternate method for
setting dbuf metadata cache size than
dbuf_metadata_cache_max_bytes.
dbuf_metadata_cache_max_bytes
overrides dbuf_metadata_cache_shift
This value is a "shift" representing the fraction of ARC target size
(grep -w c /proc/spl/kstat/zfs/arcstats
). The ARC target size is
shifted to the right. Thus a value of '2' results in the fraction = 1/4,
while a value of '6' results in the fraction = 1/64.
dbuf_metadata_cache_shift | Notes |
---|---|
Tags | ARC, dbuf_cache |
When to change | |
Data Type | int |
Units | shift |
Range | practical range is (` dbuf_cache_shift <#dbuf-cache-shift>`__ + 1) to MAX_INT |
Default | 6 |
Change | Dynamic |
Versions Affected | planned for v2 |
dbuf_metadata_cache_max_bytes
sets the size of the dbuf metadata
cache as a number of bytes. This is an alternate method for setting dbuf
metadata cache size than
dbuf_metadata_cache_shift
dbuf_metadata_cache_max_bytes
overrides dbuf_metadata_cache_shift
dbuf_metadata_cache_max_bytes | Notes |
---|---|
Tags | dbuf_cache |
When to change | |
Data Type | int |
Units | bytes |
Range | 0 = use
dbuf_metadata_cache_sh
ift
to ARC c_max |
Default | 0 |
Change | Dynamic |
Versions Affected | planned for v2 |
dbuf_cache_shift
sets the size of the dbuf cache as a fraction of
ARC target size. This is an alternate method for setting dbuf cache size
than dbuf_cache_max_bytes.
dbuf_cache_max_bytes overrides
dbuf_cache_shift
This value is a "shift" representing the fraction of ARC target size
(grep -w c /proc/spl/kstat/zfs/arcstats
). The ARC target size is
shifted to the right. Thus a value of '2' results in the fraction = 1/4,
while a value of '5' results in the fraction = 1/32.
Performance tuning of dbuf cache can be monitored using:
dbufstat
command- node_exporter ZFS module for prometheus environments
- telegraf ZFS plugin for general-purpose metric collection
/proc/spl/kstat/zfs/dbufstats
kstat
dbuf_cache_shift | Notes |
---|---|
Tags | ARC, dbuf_cache |
When to change | to improve performance of read-intensive channel programs |
Data Type | int |
Units | shift |
Range | 5 to MAX_INT |
Default | 5 |
Change | Dynamic |
Versions Affected | planned for v2 |
dbuf_cache_max_bytes
sets the size of the dbuf cache in bytes. This
is an alternate method for setting dbuf cache size than
dbuf_cache_shift
Performance tuning of dbuf cache can be monitored using:
dbufstat
command- node_exporter ZFS module for prometheus environments
- telegraf ZFS plugin for general-purpose metric collection
/proc/spl/kstat/zfs/dbufstats
kstat
dbuf_cache_max_bytes | Notes |
---|---|
Tags | ARC, dbuf_cache |
When to change | |
Data Type | int |
Units | bytes |
Range | 0 = use
dbuf_cache_shift to
ARC c_max |
Default | 0 |
Change | Dynamic |
Versions Affected | planned for v2 |
When testing allocation code, metaslab_force_ganging
forces blocks
above the specified size to be ganged.
metaslab_force_ganging | Notes |
---|---|
Tags | allocation |
When to change | for development testing purposes only |
Data Type | ulong |
Units | bytes |
Range | SPA_MINBLOCKSIZE to (SPA_MAXBLOCKSIZE + 1) |
Default | SPA_MAXBLOCKSIZE + 1 (16,777,217 bytes) |
Change | Dynamic |
Versions Affected | planned for v2 |
When adding a top-level vdev, zfs_vdev_default_ms_count
is the
target number of metaslabs.
zfs_vdev_default_ms_count | Notes |
---|---|
Tags | allocation |
When to change | for development testing purposes only |
Data Type | int |
Range | 16 to MAX_INT |
Default | 200 |
Change | prior to creating a pool or adding a top-level vdev |
Versions Affected | planned for v2 |
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.
vdev_removal_max_span
sets the maximum span of free space included
as unnecessary data in a chunk of copied data.
vdev_removal_max_span | Notes |
---|---|
Tags | vdev_removal |
When to change | TBD |
Data Type | int |
Units | bytes |
Range | 0 to MAX_INT |
Default | 32,768 (32 MiB) |
Change | Dynamic |
Versions Affected | planned for v2 |
When removing a device, zfs_removal_ignore_errors
controls the
process for handling hard I/O errors. When set, if a device encounters a
hard IO error during the removal process the removal will not be
cancelled. This can result in a normally recoverable block becoming
permanently damaged and is not recommended. This should only be used as
a last resort when the pool cannot be returned to a healthy state prior
to removing the device.
zfs_removal_ignore_errors | Notes |
---|---|
Tags | vdev_removal |
When to change | See description for caveat |
Data Type | boolean |
Range | during device removal: 0 = hard errors are not ignored, 1 = hard errors are ignored |
Default | 0 |
Change | Dynamic |
Versions Affected | planned for v2 |
zfs_removal_suspend_progress
is used during automated testing of the
ZFS code to incease test coverage.
zfs_removal_suspend_progress | Notes |
---|---|
Tags | vdev_removal |
When to change | do not change |
Data Type | boolean |
Range | 0 = do not suspend during vdev removal |
Default | 0 |
Change | Dynamic |
Versions Affected | planned for v2 |
During vdev removal, the vdev indirection layer sleeps for
zfs_condense_indirect_commit_entry_delay_ms
milliseconds during
mapping generation. This parameter is used during automated testing of
the ZFS code to improve test coverage.
zfs_condens e_indirect_commit_entry_delay_ms | Notes |
---|---|
Tags | vdev_removal |
When to change | do not change |
Data Type | int |
Units | milliseconds |
Range | 0 to MAX_INT |
Default | 0 |
Change | Dynamic |
Versions Affected | planned for v2 |
During vdev removal, condensing process is an attempt to save memory by
removing obsolete mappings. zfs_condense_indirect_vdevs_enable
enables condensing indirect vdev mappings. When set, ZFS attempts 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.
zf s_condense_indirect_vdevs_enable | Notes |
---|---|
Tags | vdev_removal |
When to change | TBD |
Data Type | boolean |
Range | 0 = do not save memory, 1 = save memory by condensing obsolete mapping after vdev removal |
Default | 1 |
Change | Dynamic |
Versions Affected | planned for v2 |
After vdev removal, zfs_condense_max_obsolete_bytes
sets the limit
for beginning the condensing process. Condensing begins if the obsolete
space map takes up more than zfs_condense_max_obsolete_bytes
of
space on disk (logically). The default of 1 GiB is small enough relative
to a typical pool that the space consumed by the obsolete space map is
minimal.
See also zfs_condense_indirect_vdevs_enable
zfs_condense_max_obsolete_bytes | Notes |
---|---|
Tags | vdev_removal |
When to change | no not change |
Data Type | ulong |
Units | bytes |
Range | 0 to MAX_ULONG |
Default | 1,073,741,824 (1 GiB) |
Change | Dynamic |
Versions Affected | planned for v2 |
After vdev removal, zfs_condense_min_mapping_bytes
is the lower
limit for determining when to condense the in-memory obsolete space map.
The condensing process will not continue unless a minimum of
zfs_condense_min_mapping_bytes
of memory can be freed.
See also zfs_condense_indirect_vdevs_enable
zfs_condense_min_mapping_bytes | Notes |
---|---|
Tags | vdev_removal |
When to change | do not change |
Data Type | ulong |
Units | bytes |
Range | 0 to MAX_ULONG |
Default | 128 KiB |
Change | Dynamic |
Versions Affected | planned for v2 |
zfs_vdev_initializing_max_active
sets the maximum initializing I/Os
active to each device.
zfs_vdev_initializing_max_active | Notes |
---|---|
Tags | vdev, Z IO_scheduler |
When to change | See ZFS I/O Sch eduler |
Data Type | uint32 |
Units | I/O operations |
Range | 1 to zfs_vdev_max_ active |
Default | 1 |
Change | Dynamic |
Versions Affected | planned for v2 |
zfs_vdev_initializing_min_active
sets the minimum initializing I/Os
active to each device.
zfs_vdev_initializing_min_active | Notes |
---|---|
Tags | vdev, Z IO_scheduler |
When to change | See ZFS I/O Sch eduler |
Data Type | uint32 |
Units | I/O operations |
Range | 1 to zfs_vde v_initializing_max_active |
Default | 1 |
Change | Dynamic |
Versions Affected | planned for v2 |
zfs_vdev_removal_max_active
sets the maximum top-level vdev removal
I/Os active to each device.
zfs_vdev_removal_max_active | Notes |
---|---|
Tags | vdev, ZIO_scheduler |
When to change | See ZFS I/O Scheduler |
Data Type | uint32 |
Units | I/O operations |
Range | 1 to zfs_vdev _max_active |
Default | 2 |
Change | Dynamic |
Versions Affected | planned for v2 |
zfs_vdev_removal_min_active
sets the minimum top-level vdev removal
I/Os active to each device.
zfs_vdev_removal_min_active | Notes |
---|---|
Tags | vdev, ZIO_scheduler |
When to change | See ZFS I/O Scheduler |
Data Type | uint32 |
Units | I/O operations |
Range | 1 to zfs_vdev_removal_max_act ive |
Default | 1 |
Change | Dynamic |
Versions Affected | planned for v2 |
zfs_vdev_trim_max_active
sets the maximum trim I/Os active to each
device.
zfs_vdev_trim_max_active | Notes |
---|---|
Tags | vdev, ZIO_scheduler |
When to change | See ZFS I/O Scheduler |
Data Type | uint32 |
Units | I/O operations |
Range | 1 to zfs_v dev_max_active |
Default | 2 |
Change | Dynamic |
Versions Affected | planned for v2 |
zfs_vdev_trim_min_active
sets the minimum trim I/Os active to each
device.
zfs_vdev_trim_min_active | Notes |
---|---|
Tags | vdev, ZIO_scheduler |
When to change | See ZFS I/O Scheduler |
Data Type | uint32 |
Units | I/O operations |
Range | 1 to zfs_vdev_trim_m ax_active |
Default | 1 |
Change | Dynamic |
Versions Affected | planned for v2 |
When initializing a vdev, ZFS writes patterns of
zfs_initialize_value
bytes to the device.
zfs_initialize_value | Notes |
---|---|
Tags | vdev_initialize |
When to change | when debugging initialization code |
Data Type | uint32 or uint64 |
Default | 0xdeadbeef for 32-bit systems, 0xdeadbeefdeadbeee for 64-bit systems |
Change | prior to running zpool initialize |
Versions Affected | planned for v2 |
zfs_lua_max_instrlimit
limits the maximum time for a ZFS channel
program to run.
zfs_lua_max_instrlimit | Notes |
---|---|
Tags | channel_programs |
When to change | to enforce a CPU usage limit on ZFS channel programs |
Data Type | ulong |
Units | LUA instructions |
Range | 0 to MAX_ULONG |
Default | 100,000,000 |
Change | Dynamic |
Versions Affected | planned for v2 |
'zfs_lua_max_memlimit' is the maximum memory limit for a ZFS channel program.
zfs_lua_max_memlimit | Notes |
---|---|
Tags | channel_programs |
When to change | |
Data Type | ulong |
Units | bytes |
Range | 0 to MAX_ULONG |
Default | 104,857,600 (100 MiB) |
Change | Dynamic |
Versions Affected | planned for v2 |
zfs_max_dataset_nesting
limits the depth of nested datasets. Deeply
nested datasets can overflow the stack. The maximum stack depth depends
on kernel compilation options, so it is impractical to predict the
possible limits. For kernels compiled with small stack sizes,
zfs_max_dataset_nesting
may require changes.
zfs_max_dataset_nesting | Notes |
---|---|
Tags | dataset |
When to change | can be tuned temporarily to fix existing datasets that exceed the predefined limit |
Data Type | int |
Units | datasets |
Range | 0 to MAX_INT |
Default | 50 |
Change | Dynamic, though once on-disk the value for the pool is set |
Versions Affected | planned for v2 |
zfs_ddt_data_is_special
enables the deduplication table (DDT) to
reside on a special top-level vdev.
zfs_ddt_data_is_special | Notes |
---|---|
Tags | dedup, special_vdev |
When to change | when using a special top-level vdev and no dedup top-level vdev and it is desired to store the DDT in the main pool top-level vdevs |
Data Type | boolean |
Range | 0=do not use special vdevs to store DDT, 1=store DDT in special vdevs |
Default | 1 |
Change | Dynamic |
Versions Affected | planned for v2 |
If special vdevs are in use, zfs_user_indirect_is_special
enables
user data indirect blocks (a form of metadata) to be written to the
special vdevs.
zfs_user_indirect_is_special | Notes |
---|---|
Tags | special_vdev |
When to change | to force user data indirect blocks to remain in the main pool top-level vdevs |
Data Type | boolean |
Range | 0=do not write user indirect blocks to a special vdev, 1=write user indirect blocks to a special vdev |
Default | 1 |
Change | Dynamic |
Versions Affected | planned for v2 |
After device removal, if an indirect split block contains more than
zfs_reconstruct_indirect_combinations_max
many possible unique
combinations when being reconstructed, it can be considered too
computationally expensive to check them all. Instead, at most
zfs_reconstruct_indirect_combinations_max
randomly-selected
combinations are attempted each time the block is accessed. This allows
all segment copies to participate fairly in the reconstruction when all
combinations cannot be checked and prevents repeated use of one bad
copy.
zfs_recon struct_indirect_combinations_max | Notes |
---|---|
Tags | vdev_removal |
When to change | TBD |
Data Type | int |
Units | attempts |
Range | 0=do not limit attempts, 1 to MAX_INT = limit for attempts |
Default | 4096 |
Change | Dynamic |
Versions Affected | planned for v2 |
zfs_send_unmodified_spill_blocks
enables sending of unmodified spill
blocks in the send stream. Under certain circumstances, previous
versions of ZFS could incorrectly remove the spill block from an
existing object. Including unmodified copies of the spill blocks creates
a backwards compatible stream which will recreate a spill block if it
was incorrectly removed.
zfs_send_unmodified_spill_blocks | Notes |
---|---|
Tags | send |
When to change | TBD |
Data Type | boolean |
Range | 0=do not send unmodified spill blocks, 1=send unmodified spill blocks |
Default | 1 |
Change | Dynamic |
Versions Affected | planned for v2 |
zfs_spa_discard_memory_limit
sets the limit for maximum memory used
for prefetching a pool's checkpoint space map on each vdev while
discarding a pool checkpoint.
zfs_spa_discard_memory_limit | Notes |
---|---|
Tags | checkpoint |
When to change | TBD |
Data Type | int |
Units | bytes |
Range | 0 to MAX_INT |
Default | 16,777,216 (16 MiB) |
Change | Dynamic |
Versions Affected | planned for v2 |
zfs_special_class_metadata_reserve_pct
sets a threshold for space in
special vdevs to be reserved exclusively for metadata. This prevents
small data blocks from completely consuming a special vdev.
zfs_special_class_metadata_reserve_pct | Notes |
---|---|
Tags | special_vdev |
When to change | TBD |
Data Type | int |
Units | percent |
Range | 0 to 100 |
Default | 25 |
Change | Dynamic |
Versions Affected | planned for v2 |
zfs_trim_extent_bytes_max
sets the maximum size of a trim (aka
discard, scsi unmap) command. Ranges larger than
zfs_trim_extent_bytes_max
are split in to chunks no larger than
zfs_trim_extent_bytes_max
bytes prior to being issued to the device.
Use zpool iostat -w
to observe the latency of trim commands.
zfs_trim_extent_bytes_max | Notes |
---|---|
Tags | trim |
When to change | if the device can efficiently handle larger trim requests |
Data Type | uint |
Units | bytes |
Range | zfs_trim_extent_by tes_min to MAX_UINT |
Default | 134,217,728 (128 MiB) |
Change | Dynamic |
Versions Affected | planned for v2 |
zfs_trim_extent_bytes_min
sets the minimum size of trim (aka
discard, scsi unmap) commands. Trim ranges smaller than
zfs_trim_extent_bytes_min
are skipped unless they're part of a
larger range which was broken in to chunks. Some devices have
performance degradation during trim operations, so using a larger
zfs_trim_extent_bytes_min
can reduce the total amount of space
trimmed. Use zpool iostat -w
to observe the latency of trim
commands.
zfs_trim_extent_bytes_min | Notes |
---|---|
Tags | trim |
When to change | when trim is in use and device performance suffers from trimming small allocations |
Data Type | uint |
Units | bytes |
Range | 0=trim all unallocated space, otherwise minimum physical block size to MAX_ |
Default | 32,768 (32 KiB) |
Change | Dynamic |
Versions Affected | planned for v2 |
zfs_trim_metaslab_skip
enables uninitialized metaslabs to be
skipped during the trim (aka discard, scsi unmap) process.
zfs_trim_metaslab_skip
can be useful for pools constructed from
large thinly-provisioned devices where trim operations perform slowly.zpool iostat -w
to observe
the latency of trim commands.zfs_trim_metaslab_skip | Notes |
---|---|
Tags | trim |
When to change | |
Data Type | boolean |
Range | 0=do not skip uninitialized metaslabs during trim, 1=skip uninitialized metaslabs during trim |
Default | 0 |
Change | Dynamic |
Versions Affected | planned for v2 |
zfs_trim_queue_limit
sets the maximum queue depth for leaf vdevs.
See also zfs_vdev_trim_max_active and
zfs_trim_extent_bytes_max Use
zpool iostat -q
to observe trim queue depth.
zfs_trim_queue_limit | Notes |
---|---|
Tags | trim |
When to change | to restrict the number of trim commands in the queue |
Data Type | uint |
Units | I/O operations |
Range | 1 to MAX_UINT |
Default | 10 |
Change | Dynamic |
Versions Affected | planned for v2 |
zfs_trim_txg_batch
sets the number of transaction groups worth of
frees which should be aggregated before trim (aka discard, scsi unmap)
commands are issued to a device. This setting represents a trade-off
between issuing larger, more efficient trim commands and the delay
before the recently trimmed space is available for use by the device.
Increasing this value will allow frees to be aggregated for a longer time. This will result is larger trim operations and potentially increased memory usage. Decreasing this value will have the opposite effect. The default value of 32 was empirically determined to be a reasonable compromise.
zfs_trim_txg_batch | Notes |
---|---|
Tags | trim |
When to change | TBD |
Data Type | uint |
Units | metaslabs to stride |
Range | 1 to MAX_UINT |
Default | 32 |
Change | Dynamic |
Versions Affected | planned for v2 |
zfs_vdev_aggregate_trim
allows trim I/Os to be aggregated. This is
normally not helpful because the extents to be trimmed will have been
already been aggregated by the metaslab.
zfs_vdev_aggregate_trim | Notes |
---|---|
Tags | trim, vdev, ZIO_scheduler |
When to change | when debugging trim code or trim performance issues |
Data Type | boolean |
Range | 0=do not attempt to aggregate trim commands, 1=attempt to aggregate trim commands |
Default | 0 |
Change | Dynamic |
Versions Affected | planned for v2 |
zfs_vdev_aggregation_limit_non_rotating
is the equivalent of
zfs_vdev_aggregation_limit for devices
which represent themselves as non-rotating to the Linux blkdev
interfaces. Such devices have a value of 0 in
/sys/block/DEVICE/queue/rotational
and are expected to be SSDs.
zfs_vde v_aggregation_limit_non_rotating | Notes |
---|---|
Tags | vdev, Z IO_scheduler |
When to change | see zfs_vdev_aggregation_limit |
Data Type | int |
Units | bytes |
Range | 0 to MAX_INT |
Default | 131,072 bytes (128 KiB) |
Change | Dynamic |
Versions Affected | planned for v2 |
ZFS uses barriers (volatile cache flush commands) to ensure data is committed to permanent media by devices. This ensures consistent on-media state for devices where caches are volatile (eg HDDs).
zil_nocacheflush
disables the cache flush commands that are normally
sent to devices by the ZIL after a log write has completed.
The difference between zil_nocacheflush
and
zfs_nocacheflush is zil_nocacheflush
applies
to ZIL writes while zfs_nocacheflush disables
barrier writes to the pool devices at the end of transaction group syncs.
WARNING: setting this can cause ZIL corruption on power loss if the device has a volatile write cache.
zil_nocacheflush | Notes |
---|---|
Tags | disks, ZIL |
When to change | If the storage device has nonvolatile cache, then disabling cache flush can save the cost of occasional cache flush commands |
Data Type | boolean |
Range | 0=send cache flush commands, 1=do not send cache flush commands |
Default | 0 |
Change | Dynamic |
Versions Affected | planned for v2 |
zio_deadman_log_all
enables debugging messages for all ZFS I/Os,
rather than only for leaf ZFS I/Os for a vdev. This is meant to be used
by developers to gain diagnostic information for hang conditions which
don't involve a mutex or other locking primitive. Typically these are
conditions where a thread in the zio pipeline is looping indefinitely.
See also zfs_dbgmsg_enable
zio_deadman_log_all | Notes |
---|---|
Tags | debug |
When to change | when debugging ZFS I/O pipeline |
Data Type | boolean |
Range | 0=do not log all deadman events, 1=log all deadman events |
Default | 0 |
Change | Dynamic |
Versions Affected | planned for v2 |
If non-zero, zio_decompress_fail_fraction
represents the denominator
of the probability that ZFS should induce a decompression failure. For
instance, for a 5% decompression failure rate, this value should be set
to 20.
zio_decompress_fail_fraction | Notes |
---|---|
Tags | debug |
When to change | when debugging ZFS internal compressed buffer code |
Data Type | ulong |
Units | probability of induced decompression
failure is
1/zio_decompress_fail_fraction |
Range | 0 = do not induce failures, or 1 to MAX_ULONG |
Default | 0 |
Change | Dynamic |
Versions Affected | planned for v2 |
An I/O operation taking more than zio_slow_io_ms
milliseconds to
complete is marked as a slow I/O. Slow I/O counters can be observed with
zpool status -s
. Each slow I/O causes a delay zevent, observable
using zpool events
. See also zfs-events(5)
.
zio_slow_io_ms | Notes |
---|---|
Tags | vdev, zed |
When to change | when debugging slow devices and the default value is inappropriate |
Data Type | int |
Units | milliseconds |
Range | 0 to MAX_INT |
Default | 30,000 (30 seconds) |
Change | Dynamic |
Versions Affected | planned for v2 |
vdev_validate_skip
disables label validation steps during pool
import. Changing is not recommended unless you know what you are doing
and are recovering a damaged label.
vdev_validate_skip | Notes |
---|---|
Tags | vdev |
When to change | do not change |
Data Type | boolean |
Range | 0=validate labels during pool import, 1=do not validate vdev labels during pool import |
Default | 0 |
Change | prior to pool import |
Versions Affected | planned for v2 |
zfs_async_block_max_blocks
limits the number of blocks freed in a
single transaction group commit. During deletes of large objects, such
as snapshots, the number of freed blocks can cause the DMU to extend txg
sync times well beyond zfs_txg_timeout.
zfs_async_block_max_blocks
is used to limit these effects.
zfs_async_block_max_blocks | Notes |
---|---|
Tags | delete, DMU |
When to change | TBD |
Data Type | ulong |
Units | blocks |
Range | 1 to MAX_ULONG |
Default | MAX_ULONG (do not limit) |
Change | Dynamic |
Versions Affected | planned for v2 |
zfs_checksum_events_per_second
is a rate limit for checksum events.
Note that this should not be set below the zed
thresholds (currently
10 checksums over 10 sec) or else zed
may not trigger any action.
zfs_checksum_events_per_second | Notes |
---|---|
Tags | vdev |
When to change | TBD |
Data Type | uint |
Units | checksum events |
Range | zed threshold to MAX_UINT |
Default | 20 |
Change | Dynamic |
Versions Affected | planned for v2 |
zfs_disable_ivset_guid_check
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 ZFS on Linux
pre-release versions and now have compatibility issues.
For a ZFS raw receive, from a send stream created by zfs send --raw
,
the crypt_keydata nvlist includes a to_ivset_guid to be set on the new
snapshot. This value will override the value generated by the snapshot
code. However, this value may not be present, because older
implementations of the raw send code did not include this value. When
zfs_disable_ivset_guid_check
is enabled, the receive proceeds and a
newly-generated value is used.
zfs_disable_ivset_guid_check | Notes |
---|---|
Tags | receive |
When to change | debugging pre-release ZFS raw sends |
Data Type | boolean |
Range | 0=check IVset guid, 1=do not check IVset guid |
Default | 0 |
Change | Dynamic |
Versions Affected | planned for v2 |
zfs_obsolete_min_time_ms
is similar to
zfs_free_min_time_ms and used for cleanup of
old indirection records for vdevs removed using the zpool remove
command.
zfs_obsolete_min_time_ms | Notes |
---|---|
Tags | delete, remove |
When to change | TBD |
Data Type | int |
Units | milliseconds |
Range | 0 to MAX_INT |
Default | 500 |
Change | Dynamic |
Versions Affected | planned for v2 |
zfs_override_estimate_recordsize
overrides the default logic for
estimating block sizes when doing a zfs send. The default heuristic is
that the average block size will be the current recordsize.
zfs_override_estimate_recordsize | Notes |
---|---|
Tags | send |
When to change | if most data in your dataset is not of the current recordsize and you require accurate zfs send size estimates |
Data Type | ulong |
Units | bytes |
Range | 0=do not override, 1 to MAX_ULONG |
Default | 0 |
Change | Dynamic |
Versions Affected | planned for v2 |
zfs_remove_max_segment
sets the largest contiguous segment that ZFS
attempts to allocate when removing a vdev. This can be no larger than
16MB. If there is a performance problem with attempting to allocate
large blocks, consider decreasing this. The value is rounded up to a
power-of-2.
zfs_remove_max_segment | Notes |
---|---|
Tags | remove |
When to change | after removing a top-level vdev, consider decreasing if there is a performance degradation when attempting to allocate large blocks |
Data Type | int |
Units | bytes |
Range | maximum of the physical block size of all vdevs in the pool to 16,777,216 bytes (16 MiB) |
Default | 16,777,216 bytes (16 MiB) |
Change | Dynamic |
Versions Affected | planned for v2 |
zfs_resilver_disable_defer
disables the resilver_defer
pool
feature. The resilver_defer
feature allows ZFS to postpone new
resilvers if an existing resilver is in progress.
zfs_resilver_disable_defer | Notes |
---|---|
Tags | resilver |
When to change | if resilver postponement is not desired due to overall resilver time constraints |
Data Type | boolean |
Range | 0=allow resilver_defer to postpone
new resilver operations, 1=immediately
restart resilver when needed |
Default | 0 |
Change | Dynamic |
Versions Affected | planned for v2 |
zfs_scan_suspend_progress
causes a scrub or resilver scan to freeze
without actually pausing.
zfs_scan_suspend_progress | Notes |
---|---|
Tags | resilver, scrub |
When to change | testing or debugging scan code |
Data Type | boolean |
Range | 0=do not freeze scans, 1=freeze scans |
Default | 0 |
Change | Dynamic |
Versions Affected | planned for v2 |
Scrubs are processed by the sync thread. While scrubbing at least
zfs_scrub_min_time_ms
time is spent working on a scrub between txg
syncs.
zfs_scrub_min_time_ms | Notes |
---|---|
Tags | scrub |
When to change | |
Data Type | int |
Units | milliseconds |
Range | 1 to (zfs_txg_timeout - 1) |
Default | 1,000 |
Change | Dynamic |
Versions Affected | planned for v2 |
zfs_slow_io_events_per_second
is a rate limit for slow I/O events.
Note that this should not be set below the zed
thresholds (currently
10 checksums over 10 sec) or else zed
may not trigger any action.
zfs_slow_io_events_per_second | Notes |
---|---|
Tags | vdev |
When to change | TBD |
Data Type | uint |
Units | slow I/O events |
Range | zed threshold to MAX_UINT |
Default | 20 |
Change | Dynamic |
Versions Affected | planned for v2 |
zfs_vdev_min_ms_count
is the minimum number of metaslabs to create
in a top-level vdev.
zfs_vdev_min_ms_count | Notes |
---|---|
Tags | metaslab, vdev |
When to change | TBD |
Data Type | int |
Units | metaslabs |
Range | 16 to zfs_vdev_m s_count_limit |
Default | 16 |
Change | prior to creating a pool or adding a top-level vdev |
Versions Affected | planned for v2 |
zfs_vdev_ms_count_limit
is the practical upper limit for the number
of metaslabs per top-level vdev.
zfs_vdev_ms_count_limit | Notes |
---|---|
Tags | metaslab, vdev |
When to change | TBD |
Data Type | int |
Units | metaslabs |
Range | zfs_vdev _min_ms_count to 131,072 |
Default | 131,072 |
Change | prior to creating a pool or adding a top-level vdev |
Versions Affected | planned for v2 |
spl_hostid
is a unique system id number. It originated in Sun's
products where most systems had a unique id assigned at the factory.
This assignment does not exist in modern hardware.spl_hostid
can be used to uniquely identify a system. By default
this value is set to zero which indicates the hostid is disabled. It
can be explicitly enabled by placing a unique non-zero value in the
file shown in spl_hostid_pathspl_hostid | Notes |
---|---|
Tags | hostid, MMP |
Kernel module | spl |
When to change | to uniquely identify a system when vdevs can be shared across multiple systems |
Data Type | ulong |
Range | 0=ignore hostid, 1 to 4,294,967,295 (32-bits or 0xffffffff) |
Default | 0 |
Change | prior to importing pool |
Versions Affected | v0.6.1 |
spl_hostid_path
is the path name for a file that can contain a
unique hostid. For testing purposes, spl_hostid_path
can be
overridden by the ZFS_HOSTID environment variable.
spl_hostid_path | Notes |
---|---|
Tags | hostid, MMP |
Kernel module | spl |
When to change | when creating a new ZFS distribution where the default value is inappropriate |
Data Type | string |
Default | "/etc/hostid" |
Change | read-only, can only be changed prior to spl module load |
Versions Affected | v0.6.1 |
Large kmem_alloc()
allocations fail if they exceed KMALLOC_MAX_SIZE,
as determined by the kernel source. Allocations which are marginally
smaller than this limit may succeed but should still be avoided due to
the expense of locating a contiguous range of free pages. Therefore, a
maximum kmem size with reasonable safely margin of 4x is set.
kmem_alloc()
allocations larger than this maximum will quickly fail.
vmem_alloc()
allocations less than or equal to this value will use
kmalloc()
, but shift to vmalloc()
when exceeding this value.
spl_kmem_alloc_max | Notes |
---|---|
Tags | memory |
Kernel module | spl |
When to change | TBD |
Data Type | uint |
Units | bytes |
Range | TBD |
Default | KMALLOC_MAX_SIZE / 4 |
Change | Dynamic |
Versions Affected | v0.7.0 |
As a general rule kmem_alloc()
allocations should be small,
preferably just a few pages since they must by physically contiguous.
Therefore, a rate limited warning is printed to the console for any
kmem_alloc()
which exceeds the threshold spl_kmem_alloc_warn
The default warning threshold is set to eight pages but capped at 32K to accommodate systems using large pages. This value was selected to be small enough to ensure the largest allocations are quickly noticed and fixed. But large enough to avoid logging any warnings when a allocation size is larger than optimal but not a serious concern. Since this value is tunable, developers are encouraged to set it lower when testing so any new largish allocations are quickly caught. These warnings may be disabled by setting the threshold to zero.
spl_kmem_alloc_warn | Notes |
---|---|
Tags | memory |
Kernel module | spl |
When to change | developers are encouraged lower when testing so any new, large allocations are quickly caught |
Data Type | uint |
Units | bytes |
Range | 0=disable the warnings, |
Default | 32,768 (32 KiB) |
Change | Dynamic |
Versions Affected | v0.7.0 |
Cache expiration is part of default illumos cache behavior. The idea is that objects in magazines which have not been recently accessed should be returned to the slabs periodically. This is known as cache aging and when enabled objects will be typically returned after 15 seconds.
On the other hand Linux slabs are designed to never move objects back to the slabs unless there is memory pressure. This is possible because under Linux the cache will be notified when memory is low and objects can be released.
By default only the Linux method is enabled. It has been shown to
improve responsiveness on low memory systems and not negatively impact
the performance of systems with more memory. This policy may be changed
by setting the spl_kmem_cache_expire
bit mask as follows, both
policies may be enabled concurrently.
spl_kmem_cache_expire | Notes |
---|---|
Tags | memory |
Kernel module | spl |
When to change | TBD |
Data Type | bitmask |
Range | 0x01 - Aging (illumos), 0x02 - Low memory (Linux) |
Default | 0x02 |
Change | Dynamic |
Versions Affected | v0.6.1 to v0.8.x |
Depending on the size of a memory cache object it may be backed by
kmalloc()
or vmalloc()
memory. This is because the size of the
required allocation greatly impacts the best way to allocate the memory.
When objects are small and only a small number of memory pages need to
be allocated, ideally just one, then kmalloc()
is very efficient.
However, allocating multiple pages with kmalloc()
gets increasingly
expensive because the pages must be physically contiguous.
For this reason we shift to vmalloc()
for slabs of large objects
which which removes the need for contiguous pages. vmalloc()
cannot
be used in all cases because there is significant locking overhead
involved. This function takes a single global lock over the entire
virtual address range which serializes all allocations. Using slightly
different allocation functions for small and large objects allows us to
handle a wide range of object sizes.
The spl_kmem_cache_kmem_limit
value is used to determine this cutoff
size. One quarter of the kernel's compiled PAGE_SIZE is used as the
default value because
spl_kmem_cache_obj_per_slab defaults
to 16. With these default values, at most four contiguous pages are
allocated.
spl_kmem_cache_kmem_limit | Notes |
---|---|
Tags | memory |
Kernel module | spl |
When to change | TBD |
Data Type | uint |
Units | pages |
Range | TBD |
Default | PAGE_SIZE / 4 |
Change | Dynamic |
Versions Affected | v0.7.0 to v0.8.x |
spl_kmem_cache_max_size
is the maximum size of a kmem cache slab in
MiB. This effectively limits the maximum cache object size to
spl_kmem_cache_max_size
/
spl_kmem_cache_obj_per_slab Kmem
caches may not be created with object sized larger than this limit.
spl_kmem_cache_max_size | Notes |
---|---|
Tags | memory |
Kernel module | spl |
When to change | TBD |
Data Type | uint |
Units | MiB |
Range | TBD |
Default | 4 for 32-bit kernel, 32 for 64-bit kernel |
Change | Dynamic |
Versions Affected | v0.7.0 |
spl_kmem_cache_obj_per_slab
is the preferred number of objects per
slab in the kmem cache. In general, a larger value will increase the
caches memory footprint while decreasing the time required to perform an
allocation. Conversely, a smaller value will minimize the footprint and
improve cache reclaim time but individual allocations may take longer.
spl_kmem_cache_obj_per_slab | Notes |
---|---|
Tags | memory |
Kernel module | spl |
When to change | TBD |
Data Type | uint |
Units | kmem cache objects |
Range | TBD |
Default | 8 |
Change | Dynamic |
Versions Affected | v0.7.0 to v0.8.x |
spl_kmem_cache_obj_per_slab_min
is the minimum number of objects
allowed per slab. Normally slabs will contain
spl_kmem_cache_obj_per_slab objects
but for caches that contain very large objects it's desirable to only
have a few, or even just one, object per slab.
spl_kmem_cache_obj_per_slab_min | Notes |
---|---|
Tags | memory |
Kernel module | spl |
When to change | debugging kmem cache operations |
Data Type | uint |
Units | kmem cache objects |
Range | TBD |
Default | 1 |
Change | Dynamic |
Versions Affected | v0.7.0 |
spl_kmem_cache_reclaim
prevents Linux from being able to rapidly
reclaim all the memory held by the kmem caches. This may be useful in
circumstances where it's preferable that Linux reclaim memory from some
other subsystem first. Setting spl_kmem_cache_reclaim
increases the
likelihood out of memory events on a memory constrained system.
spl_kmem_cache_reclaim | Notes |
---|---|
Tags | memory |
Kernel module | spl |
When to change | TBD |
Data Type | boolean |
Range | 0=enable rapid memory reclaim from kmem caches, 1=disable rapid memory reclaim from kmem caches |
Default | 0 |
Change | Dynamic |
Versions Affected | v0.7.0 |
For small objects the Linux slab allocator should be used to make the
most efficient use of the memory. However, large objects are not
supported by the Linux slab allocator and therefore the SPL
implementation is preferred. spl_kmem_cache_slab_limit
is used to
determine the cutoff between a small and large object.
Objects of spl_kmem_cache_slab_limit
or smaller will be allocated
using the Linux slab allocator, large objects use the SPL allocator. A
cutoff of 16 KiB was determined to be optimal for architectures using 4
KiB pages.
spl_kmem_cache_slab_limit | Notes |
---|---|
Tags | memory |
Kernel module | spl |
When to change | TBD |
Data Type | uint |
Units | bytes |
Range | TBD |
Default | 16,384 (16 KiB) when kernel PAGE_SIZE = 4KiB, 0 for other PAGE_SIZE values |
Change | Dynamic |
Versions Affected | v0.7.0 |
spl_max_show_tasks
is the limit of tasks per pending list in each
taskq shown in /proc/spl/taskq
and /proc/spl/taskq-all
. Reading
the ProcFS files walks the lists with lock held and it could cause a
lock up if the list grow too large. If the list is larger than the
limit, the string `"(truncated)" is printed.
spl_max_show_tasks | Notes |
---|---|
Tags | taskq |
Kernel module | spl |
When to change | TBD |
Data Type | uint |
Units | tasks reported |
Range | 0 disables the limit, 1 to MAX_UINT |
Default | 512 |
Change | Dynamic |
Versions Affected | v0.7.0 |
spl_panic_halt
enables kernel panic upon assertion failures. When
not enabled, the asserting thread is halted to facilitate further
debugging.
spl_panic_halt | Notes |
---|---|
Tags | debug, panic |
Kernel module | spl |
When to change | when debugging assertions and kernel core dumps are desired |
Data Type | boolean |
Range | 0=halt thread upon assertion, 1=panic kernel upon assertion |
Default | 0 |
Change | Dynamic |
Versions Affected | v0.7.0 |
Upon writing a non-zero value to spl_taskq_kick
, all taskqs are
scanned. If any taskq has a pending task more than 5 seconds old, the
taskq spawns more threads. This can be useful in rare deadlock
situations caused by one or more taskqs not spawning a thread when it
should.
spl_taskq_kick | Notes |
---|---|
Tags | taskq |
Kernel module | spl |
When to change | See description above |
Data Type | uint |
Units | N/A |
Default | 0 |
Change | Dynamic |
Versions Affected | v0.7.0 |
spl_taskq_thread_bind
enables binding taskq threads to specific
CPUs, distributed evenly over the available CPUs. By default, this
behavior is disabled to allow the Linux scheduler the maximum
flexibility to determine where a thread should run.
spl_taskq_thread_bind | Notes |
---|---|
Tags | CPU, taskq |
Kernel module | spl |
When to change | when debugging CPU scheduling options |
Data Type | boolean |
Range | 0=taskqs are not bound to specific CPUs, 1=taskqs are bound to CPUs |
Default | 0 |
Change | prior to loading spl kernel module |
Versions Affected | v0.7.0 |
spl_taskq_thread_dynamic
enables taskqs to set the TASKQ_DYNAMIC
flag will by default create only a single thread. New threads will be
created on demand up to a maximum allowed number to facilitate the
completion of outstanding tasks. Threads which are no longer needed are
promptly destroyed. By default this behavior is enabled but it can be d.
See also zfs_zil_clean_taskq_nthr_pct, zio_taskq_batch_pct
spl_taskq_thread_dynamic | Notes |
---|---|
Tags | taskq |
Kernel module | spl |
When to change | disable for performance analysis or troubleshooting |
Data Type | boolean |
Range | 0=taskq threads are not dynamic, 1=taskq threads are dynamically created and destroyed |
Default | 1 |
Change | prior to loading spl kernel module |
Versions Affected | v0.7.0 |
spl_taskq_thread_priority
allows newly created taskq threads to
set a non-default scheduler priority. When enabled the priority
specified when a taskq is created will be applied to all threads
created by that taskq.spl_taskq_thread_priority | Notes |
---|---|
Tags | CPU, taskq |
Kernel module | spl |
When to change | when troubleshooting CPU scheduling-related performance issues |
Data Type | boolean |
Range | 0=taskq threads use the default Linux kernel thread priority, 1= |
Default | 1 |
Change | prior to loading spl kernel module |
Versions Affected | v0.7.0 |
spl_taskq_thread_sequential
is the number of items a taskq worker
thread must handle without interruption before requesting a new worker
thread be spawned. spl_taskq_thread_sequential
controls how quickly
taskqs ramp up the number of threads processing the queue. Because Linux
thread creation and destruction are relatively inexpensive a small
default value has been selected. Thus threads are created aggressively,
which is typically desirable. Increasing this value results in a slower
thread creation rate which may be preferable for some configurations.
spl_taskq_thread_sequential | Notes |
---|---|
Tags | CPU, taskq |
Kernel module | spl |
When to change | TBD |
Data Type | int |
Units | taskq items |
Range | 1 to MAX_INT |
Default | 4 |
Change | Dynamic |
Versions Affected | v0.7.0 |
spl_kmem_cache_kmem_threads
shows the current number of
spl_kmem_cache
threads. This task queue is responsible for
allocating new slabs for use by the kmem caches. For the majority of
systems and workloads only a small number of threads are required.
spl_kmem_cache_kmem_threads | Notes |
---|---|
Tags | CPU, memory |
Kernel module | spl |
When to change | read-only |
Data Type | int |
Range | 1 to MAX_INT |
Units | threads |
Default | 4 |
Change | read-only, can only be changed prior to spl module load |
Versions Affected | v0.7.0 |
spl_kmem_cache_magazine_size
shows the current . Cache magazines are
an optimization designed to minimize the cost of allocating memory. They
do this by keeping a per-cpu cache of recently freed objects, which can
then be reallocated without taking a lock. This can improve performance
on highly contended caches. However, because objects in magazines will
prevent otherwise empty slabs from being immediately released this may
not be ideal for low memory machines.
For this reason spl_kmem_cache_magazine_size can be used to set a maximum magazine size. When this value is set to 0 the magazine size will be automatically determined based on the object size. Otherwise magazines will be limited to 2-256 objects per magazine (eg per CPU). Magazines cannot be disabled entirely in this implementation.
spl_kmem_cache_magazine_size | Notes |
---|---|
Tags | CPU, memory |
Kernel module | spl |
When to change | |
Data Type | int |
Units | threads |
Range | 0=automatically scale magazine size, otherwise 2 to 256 |
Default | 0 |
Change | read-only, can only be changed prior to spl module load |
Versions Affected | v0.7.0 |