====================== OSD Config Reference ====================== .. index:: OSD; configuration You can configure Ceph OSD Daemons in the Ceph configuration file (or in recent releases, the central config store), but Ceph OSD Daemons can use the default values and a very minimal configuration. A minimal Ceph OSD Daemon configuration sets ``osd journal size`` (for Filestore), ``host``, and uses default values for nearly everything else. Ceph OSD Daemons are numerically identified in incremental fashion, beginning with ``0`` using the following convention. :: osd.0 osd.1 osd.2 In a configuration file, you may specify settings for all Ceph OSD Daemons in the cluster by adding configuration settings to the ``[osd]`` section of your configuration file. To add settings directly to a specific Ceph OSD Daemon (e.g., ``host``), enter it in an OSD-specific section of your configuration file. For example: .. code-block:: ini [osd] osd_journal_size = 5120 [osd.0] host = osd-host-a [osd.1] host = osd-host-b .. index:: OSD; config settings General Settings ================ The following settings provide a Ceph OSD Daemon's ID, and determine paths to data and journals. Ceph deployment scripts typically generate the UUID automatically. .. warning:: **DO NOT** change the default paths for data or journals, as it makes it more problematic to troubleshoot Ceph later. When using Filestore, the journal size should be at least twice the product of the expected drive speed multiplied by ``filestore_max_sync_interval``. However, the most common practice is to partition the journal drive (often an SSD), and mount it such that Ceph uses the entire partition for the journal. ``osd_uuid`` :Description: The universally unique identifier (UUID) for the Ceph OSD Daemon. :Type: UUID :Default: The UUID. :Note: The ``osd_uuid`` applies to a single Ceph OSD Daemon. The ``fsid`` applies to the entire cluster. ``osd_data`` :Description: The path to the OSDs data. You must create the directory when deploying Ceph. You should mount a drive for OSD data at this mount point. We do not recommend changing the default. :Type: String :Default: ``/var/lib/ceph/osd/$cluster-$id`` ``osd_max_write_size`` :Description: The maximum size of a write in megabytes. :Type: 32-bit Integer :Default: ``90`` ``osd_max_object_size`` :Description: The maximum size of a RADOS object in bytes. :Type: 32-bit Unsigned Integer :Default: 128MB ``osd_client_message_size_cap`` :Description: The largest client data message allowed in memory. :Type: 64-bit Unsigned Integer :Default: 500MB default. ``500*1024L*1024L`` ``osd_class_dir`` :Description: The class path for RADOS class plug-ins. :Type: String :Default: ``$libdir/rados-classes`` .. index:: OSD; file system File System Settings ==================== Ceph builds and mounts file systems which are used for Ceph OSDs. ``osd_mkfs_options {fs-type}`` :Description: Options used when creating a new Ceph Filestore OSD of type {fs-type}. :Type: String :Default for xfs: ``-f -i 2048`` :Default for other file systems: {empty string} For example:: ``osd_mkfs_options_xfs = -f -d agcount=24`` ``osd_mount_options {fs-type}`` :Description: Options used when mounting a Ceph Filestore OSD of type {fs-type}. :Type: String :Default for xfs: ``rw,noatime,inode64`` :Default for other file systems: ``rw, noatime`` For example:: ``osd_mount_options_xfs = rw, noatime, inode64, logbufs=8`` .. index:: OSD; journal settings Journal Settings ================ This section applies only to the older Filestore OSD back end. Since Luminous BlueStore has been default and preferred. By default, Ceph expects that you will provision a Ceph OSD Daemon's journal at the following path, which is usually a symlink to a device or partition:: /var/lib/ceph/osd/$cluster-$id/journal When using a single device type (for example, spinning drives), the journals should be *colocated*: the logical volume (or partition) should be in the same device as the ``data`` logical volume. When using a mix of fast (SSDs, NVMe) devices with slower ones (like spinning drives) it makes sense to place the journal on the faster device, while ``data`` occupies the slower device fully. The default ``osd_journal_size`` value is 5120 (5 gigabytes), but it can be larger, in which case it will need to be set in the ``ceph.conf`` file. A value of 10 gigabytes is common in practice:: osd_journal_size = 10240 ``osd_journal`` :Description: The path to the OSD's journal. This may be a path to a file or a block device (such as a partition of an SSD). If it is a file, you must create the directory to contain it. We recommend using a separate fast device when the ``osd_data`` drive is an HDD. :Type: String :Default: ``/var/lib/ceph/osd/$cluster-$id/journal`` ``osd_journal_size`` :Description: The size of the journal in megabytes. :Type: 32-bit Integer :Default: ``5120`` See `Journal Config Reference`_ for additional details. Monitor OSD Interaction ======================= Ceph OSD Daemons check each other's heartbeats and report to monitors periodically. Ceph can use default values in many cases. However, if your network has latency issues, you may need to adopt longer intervals. See `Configuring Monitor/OSD Interaction`_ for a detailed discussion of heartbeats. Data Placement ============== See `Pool & PG Config Reference`_ for details. .. index:: OSD; scrubbing Scrubbing ========= In addition to making multiple copies of objects, Ceph ensures data integrity by scrubbing placement groups. Ceph scrubbing is analogous to ``fsck`` on the object storage layer. For each placement group, Ceph generates a catalog of all objects and compares each primary object and its replicas to ensure that no objects are missing or mismatched. Light scrubbing (daily) checks the object size and attributes. Deep scrubbing (weekly) reads the data and uses checksums to ensure data integrity. Scrubbing is important for maintaining data integrity, but it can reduce performance. You can adjust the following settings to increase or decrease scrubbing operations. ``osd_max_scrubs`` :Description: The maximum number of simultaneous scrub operations for a Ceph OSD Daemon. :Type: 32-bit Int :Default: ``1`` ``osd_scrub_begin_hour`` :Description: This restricts scrubbing to this hour of the day or later. Use ``osd_scrub_begin_hour = 0`` and ``osd_scrub_end_hour = 0`` to allow scrubbing the entire day. Along with ``osd_scrub_end_hour``, they define a time window, in which the scrubs can happen. But a scrub will be performed no matter whether the time window allows or not, as long as the placement group's scrub interval exceeds ``osd_scrub_max_interval``. :Type: Integer in the range of 0 to 23 :Default: ``0`` ``osd_scrub_end_hour`` :Description: This restricts scrubbing to the hour earlier than this. Use ``osd_scrub_begin_hour = 0`` and ``osd_scrub_end_hour = 0`` to allow scrubbing for the entire day. Along with ``osd_scrub_begin_hour``, they define a time window, in which the scrubs can happen. But a scrub will be performed no matter whether the time window allows or not, as long as the placement group's scrub interval exceeds ``osd_scrub_max_interval``. :Type: Integer in the range of 0 to 23 :Default: ``0`` ``osd_scrub_begin_week_day`` :Description: This restricts scrubbing to this day of the week or later. 0 = Sunday, 1 = Monday, etc. Use ``osd_scrub_begin_week_day = 0`` and ``osd_scrub_end_week_day = 0`` to allow scrubbing for the entire week. Along with ``osd_scrub_end_week_day``, they define a time window in which scrubs can happen. But a scrub will be performed no matter whether the time window allows or not, when the PG's scrub interval exceeds ``osd_scrub_max_interval``. :Type: Integer in the range of 0 to 6 :Default: ``0`` ``osd_scrub_end_week_day`` :Description: This restricts scrubbing to days of the week earlier than this. 0 = Sunday, 1 = Monday, etc. Use ``osd_scrub_begin_week_day = 0`` and ``osd_scrub_end_week_day = 0`` to allow scrubbing for the entire week. Along with ``osd_scrub_begin_week_day``, they define a time window, in which the scrubs can happen. But a scrub will be performed no matter whether the time window allows or not, as long as the placement group's scrub interval exceeds ``osd_scrub_max_interval``. :Type: Integer in the range of 0 to 6 :Default: ``0`` ``osd scrub during recovery`` :Description: Allow scrub during recovery. Setting this to ``false`` will disable scheduling new scrub (and deep--scrub) while there is active recovery. Already running scrubs will be continued. This might be useful to reduce load on busy clusters. :Type: Boolean :Default: ``false`` ``osd_scrub_thread_timeout`` :Description: The maximum time in seconds before timing out a scrub thread. :Type: 32-bit Integer :Default: ``60`` ``osd_scrub_finalize_thread_timeout`` :Description: The maximum time in seconds before timing out a scrub finalize thread. :Type: 32-bit Integer :Default: ``10*60`` ``osd_scrub_load_threshold`` :Description: The normalized maximum load. Ceph will not scrub when the system load (as defined by ``getloadavg() / number of online CPUs``) is higher than this number. Default is ``0.5``. :Type: Float :Default: ``0.5`` ``osd_scrub_min_interval`` :Description: The minimal interval in seconds for scrubbing the Ceph OSD Daemon when the Ceph Storage Cluster load is low. :Type: Float :Default: Once per day. ``24*60*60`` .. _osd_scrub_max_interval: ``osd_scrub_max_interval`` :Description: The maximum interval in seconds for scrubbing the Ceph OSD Daemon irrespective of cluster load. :Type: Float :Default: Once per week. ``7*24*60*60`` ``osd_scrub_chunk_min`` :Description: The minimal number of object store chunks to scrub during single operation. Ceph blocks writes to single chunk during scrub. :Type: 32-bit Integer :Default: 5 ``osd_scrub_chunk_max`` :Description: The maximum number of object store chunks to scrub during single operation. :Type: 32-bit Integer :Default: 25 ``osd_scrub_sleep`` :Description: Time to sleep before scrubbing the next group of chunks. Increasing this value will slow down the overall rate of scrubbing so that client operations will be less impacted. :Type: Float :Default: 0 ``osd_deep_scrub_interval`` :Description: The interval for "deep" scrubbing (fully reading all data). The ``osd_scrub_load_threshold`` does not affect this setting. :Type: Float :Default: Once per week. ``7*24*60*60`` ``osd_scrub_interval_randomize_ratio`` :Description: Add a random delay to ``osd_scrub_min_interval`` when scheduling the next scrub job for a PG. The delay is a random value less than ``osd_scrub_min_interval`` \* ``osd_scrub_interval_randomized_ratio``. The default setting spreads scrubs throughout the allowed time window of ``[1, 1.5]`` \* ``osd_scrub_min_interval``. :Type: Float :Default: ``0.5`` ``osd_deep_scrub_stride`` :Description: Read size when doing a deep scrub. :Type: 32-bit Integer :Default: 512 KB. ``524288`` ``osd_scrub_auto_repair`` :Description: Setting this to ``true`` will enable automatic PG repair when errors are found by scrubs or deep-scrubs. However, if more than ``osd_scrub_auto_repair_num_errors`` errors are found a repair is NOT performed. :Type: Boolean :Default: ``false`` ``osd_scrub_auto_repair_num_errors`` :Description: Auto repair will not occur if more than this many errors are found. :Type: 32-bit Integer :Default: ``5`` .. index:: OSD; operations settings Operations ========== ``osd_op_queue`` :Description: This sets the type of queue to be used for prioritizing ops within each OSD. Both queues feature a strict sub-queue which is dequeued before the normal queue. The normal queue is different between implementations. The WeightedPriorityQueue (``wpq``) dequeues operations in relation to their priorities to prevent starvation of any queue. WPQ should help in cases where a few OSDs are more overloaded than others. The new mClockQueue (``mclock_scheduler``) prioritizes operations based on which class they belong to (recovery, scrub, snaptrim, client op, osd subop). See `QoS Based on mClock`_. Requires a restart. :Type: String :Valid Choices: wpq, mclock_scheduler :Default: ``wpq`` ``osd_op_queue_cut_off`` :Description: This selects which priority ops will be sent to the strict queue verses the normal queue. The ``low`` setting sends all replication ops and higher to the strict queue, while the ``high`` option sends only replication acknowledgment ops and higher to the strict queue. Setting this to ``high`` should help when a few OSDs in the cluster are very busy especially when combined with ``wpq`` in the ``osd_op_queue`` setting. OSDs that are very busy handling replication traffic could starve primary client traffic on these OSDs without these settings. Requires a restart. :Type: String :Valid Choices: low, high :Default: ``high`` ``osd_client_op_priority`` :Description: The priority set for client operations. This value is relative to that of ``osd_recovery_op_priority`` below. The default strongly favors client ops over recovery. :Type: 32-bit Integer :Default: ``63`` :Valid Range: 1-63 ``osd_recovery_op_priority`` :Description: The priority of recovery operations vs client operations, if not specified by the pool's ``recovery_op_priority``. The default value prioritizes client ops (see above) over recovery ops. You may adjust the tradeoff of client impact against the time to restore cluster health by lowering this value for increased prioritization of client ops, or by increasing it to favor recovery. :Type: 32-bit Integer :Default: ``3`` :Valid Range: 1-63 ``osd_scrub_priority`` :Description: The default work queue priority for scheduled scrubs when the pool doesn't specify a value of ``scrub_priority``. This can be boosted to the value of ``osd_client_op_priority`` when scrubs are blocking client operations. :Type: 32-bit Integer :Default: ``5`` :Valid Range: 1-63 ``osd_requested_scrub_priority`` :Description: The priority set for user requested scrub on the work queue. If this value were to be smaller than ``osd_client_op_priority`` it can be boosted to the value of ``osd_client_op_priority`` when scrub is blocking client operations. :Type: 32-bit Integer :Default: ``120`` ``osd_snap_trim_priority`` :Description: The priority set for the snap trim work queue. :Type: 32-bit Integer :Default: ``5`` :Valid Range: 1-63 ``osd_snap_trim_sleep`` :Description: Time in seconds to sleep before next snap trim op. Increasing this value will slow down snap trimming. This option overrides backend specific variants. :Type: Float :Default: ``0`` ``osd_snap_trim_sleep_hdd`` :Description: Time in seconds to sleep before next snap trim op for HDDs. :Type: Float :Default: ``5`` ``osd_snap_trim_sleep_ssd`` :Description: Time in seconds to sleep before next snap trim op for SSD OSDs (including NVMe). :Type: Float :Default: ``0`` ``osd_snap_trim_sleep_hybrid`` :Description: Time in seconds to sleep before next snap trim op when OSD data is on an HDD and the OSD journal or WAL+DB is on an SSD. :Type: Float :Default: ``2`` ``osd_op_thread_timeout`` :Description: The Ceph OSD Daemon operation thread timeout in seconds. :Type: 32-bit Integer :Default: ``15`` ``osd_op_complaint_time`` :Description: An operation becomes complaint worthy after the specified number of seconds have elapsed. :Type: Float :Default: ``30`` ``osd_op_history_size`` :Description: The maximum number of completed operations to track. :Type: 32-bit Unsigned Integer :Default: ``20`` ``osd_op_history_duration`` :Description: The oldest completed operation to track. :Type: 32-bit Unsigned Integer :Default: ``600`` ``osd_op_log_threshold`` :Description: How many operations logs to display at once. :Type: 32-bit Integer :Default: ``5`` .. _dmclock-qos: QoS Based on mClock ------------------- Ceph's use of mClock is now more refined and can be used by following the steps as described in `mClock Config Reference`_. Core Concepts ````````````` Ceph's QoS support is implemented using a queueing scheduler based on `the dmClock algorithm`_. This algorithm allocates the I/O resources of the Ceph cluster in proportion to weights, and enforces the constraints of minimum reservation and maximum limitation, so that the services can compete for the resources fairly. Currently the *mclock_scheduler* operation queue divides Ceph services involving I/O resources into following buckets: - client op: the iops issued by client - osd subop: the iops issued by primary OSD - snap trim: the snap trimming related requests - pg recovery: the recovery related requests - pg scrub: the scrub related requests And the resources are partitioned using following three sets of tags. In other words, the share of each type of service is controlled by three tags: #. reservation: the minimum IOPS allocated for the service. #. limitation: the maximum IOPS allocated for the service. #. weight: the proportional share of capacity if extra capacity or system oversubscribed. In Ceph, operations are graded with "cost". And the resources allocated for serving various services are consumed by these "costs". So, for example, the more reservation a services has, the more resource it is guaranteed to possess, as long as it requires. Assuming there are 2 services: recovery and client ops: - recovery: (r:1, l:5, w:1) - client ops: (r:2, l:0, w:9) The settings above ensure that the recovery won't get more than 5 requests per second serviced, even if it requires so (see CURRENT IMPLEMENTATION NOTE below), and no other services are competing with it. But if the clients start to issue large amount of I/O requests, neither will they exhaust all the I/O resources. 1 request per second is always allocated for recovery jobs as long as there are any such requests. So the recovery jobs won't be starved even in a cluster with high load. And in the meantime, the client ops can enjoy a larger portion of the I/O resource, because its weight is "9", while its competitor "1". In the case of client ops, it is not clamped by the limit setting, so it can make use of all the resources if there is no recovery ongoing. CURRENT IMPLEMENTATION NOTE: the current implementation enforces the limit values. Therefore, if a service crosses the enforced limit, the op remains in the operation queue until the limit is restored. Subtleties of mClock ```````````````````` The reservation and limit values have a unit of requests per second. The weight, however, does not technically have a unit and the weights are relative to one another. So if one class of requests has a weight of 1 and another a weight of 9, then the latter class of requests should get 9 executed at a 9 to 1 ratio as the first class. However that will only happen once the reservations are met and those values include the operations executed under the reservation phase. Even though the weights do not have units, one must be careful in choosing their values due how the algorithm assigns weight tags to requests. If the weight is *W*, then for a given class of requests, the next one that comes in will have a weight tag of *1/W* plus the previous weight tag or the current time, whichever is larger. That means if *W* is sufficiently large and therefore *1/W* is sufficiently small, the calculated tag may never be assigned as it will get a value of the current time. The ultimate lesson is that values for weight should not be too large. They should be under the number of requests one expects to be serviced each second. Caveats ``````` There are some factors that can reduce the impact of the mClock op queues within Ceph. First, requests to an OSD are sharded by their placement group identifier. Each shard has its own mClock queue and these queues neither interact nor share information among them. The number of shards can be controlled with the configuration options ``osd_op_num_shards``, ``osd_op_num_shards_hdd``, and ``osd_op_num_shards_ssd``. A lower number of shards will increase the impact of the mClock queues, but may have other deleterious effects. Second, requests are transferred from the operation queue to the operation sequencer, in which they go through the phases of execution. The operation queue is where mClock resides and mClock determines the next op to transfer to the operation sequencer. The number of operations allowed in the operation sequencer is a complex issue. In general we want to keep enough operations in the sequencer so it's always getting work done on some operations while it's waiting for disk and network access to complete on other operations. On the other hand, once an operation is transferred to the operation sequencer, mClock no longer has control over it. Therefore to maximize the impact of mClock, we want to keep as few operations in the operation sequencer as possible. So we have an inherent tension. The configuration options that influence the number of operations in the operation sequencer are ``bluestore_throttle_bytes``, ``bluestore_throttle_deferred_bytes``, ``bluestore_throttle_cost_per_io``, ``bluestore_throttle_cost_per_io_hdd``, and ``bluestore_throttle_cost_per_io_ssd``. A third factor that affects the impact of the mClock algorithm is that we're using a distributed system, where requests are made to multiple OSDs and each OSD has (can have) multiple shards. Yet we're currently using the mClock algorithm, which is not distributed (note: dmClock is the distributed version of mClock). Various organizations and individuals are currently experimenting with mClock as it exists in this code base along with their modifications to the code base. We hope you'll share you're experiences with your mClock and dmClock experiments on the ``ceph-devel`` mailing list. ``osd_push_per_object_cost`` :Description: the overhead for serving a push op :Type: Unsigned Integer :Default: 1000 ``osd_recovery_max_chunk`` :Description: the maximum total size of data chunks a recovery op can carry. :Type: Unsigned Integer :Default: 8 MiB ``osd_mclock_scheduler_client_res`` :Description: IO proportion reserved for each client (default). :Type: Unsigned Integer :Default: 1 ``osd_mclock_scheduler_client_wgt`` :Description: IO share for each client (default) over reservation. :Type: Unsigned Integer :Default: 1 ``osd_mclock_scheduler_client_lim`` :Description: IO limit for each client (default) over reservation. :Type: Unsigned Integer :Default: 999999 ``osd_mclock_scheduler_background_recovery_res`` :Description: IO proportion reserved for background recovery (default). :Type: Unsigned Integer :Default: 1 ``osd_mclock_scheduler_background_recovery_wgt`` :Description: IO share for each background recovery over reservation. :Type: Unsigned Integer :Default: 1 ``osd_mclock_scheduler_background_recovery_lim`` :Description: IO limit for background recovery over reservation. :Type: Unsigned Integer :Default: 999999 ``osd_mclock_scheduler_background_best_effort_res`` :Description: IO proportion reserved for background best_effort (default). :Type: Unsigned Integer :Default: 1 ``osd_mclock_scheduler_background_best_effort_wgt`` :Description: IO share for each background best_effort over reservation. :Type: Unsigned Integer :Default: 1 ``osd_mclock_scheduler_background_best_effort_lim`` :Description: IO limit for background best_effort over reservation. :Type: Unsigned Integer :Default: 999999 .. _the dmClock algorithm: https://www.usenix.org/legacy/event/osdi10/tech/full_papers/Gulati.pdf .. index:: OSD; backfilling Backfilling =========== When you add or remove Ceph OSD Daemons to a cluster, CRUSH will rebalance the cluster by moving placement groups to or from Ceph OSDs to restore balanced utilization. The process of migrating placement groups and the objects they contain can reduce the cluster's operational performance considerably. To maintain operational performance, Ceph performs this migration with 'backfilling', which allows Ceph to set backfill operations to a lower priority than requests to read or write data. ``osd_max_backfills`` :Description: The maximum number of backfills allowed to or from a single OSD. Note that this is applied separately for read and write operations. :Type: 64-bit Unsigned Integer :Default: ``1`` ``osd_backfill_scan_min`` :Description: The minimum number of objects per backfill scan. :Type: 32-bit Integer :Default: ``64`` ``osd_backfill_scan_max`` :Description: The maximum number of objects per backfill scan. :Type: 32-bit Integer :Default: ``512`` ``osd_backfill_retry_interval`` :Description: The number of seconds to wait before retrying backfill requests. :Type: Double :Default: ``10.0`` .. index:: OSD; osdmap OSD Map ======= OSD maps reflect the OSD daemons operating in the cluster. Over time, the number of map epochs increases. Ceph provides some settings to ensure that Ceph performs well as the OSD map grows larger. ``osd_map_dedup`` :Description: Enable removing duplicates in the OSD map. :Type: Boolean :Default: ``true`` ``osd_map_cache_size`` :Description: The number of OSD maps to keep cached. :Type: 32-bit Integer :Default: ``50`` ``osd_map_message_max`` :Description: The maximum map entries allowed per MOSDMap message. :Type: 32-bit Integer :Default: ``40`` .. index:: OSD; recovery Recovery ======== When the cluster starts or when a Ceph OSD Daemon crashes and restarts, the OSD begins peering with other Ceph OSD Daemons before writes can occur. See `Monitoring OSDs and PGs`_ for details. If a Ceph OSD Daemon crashes and comes back online, usually it will be out of sync with other Ceph OSD Daemons containing more recent versions of objects in the placement groups. When this happens, the Ceph OSD Daemon goes into recovery mode and seeks to get the latest copy of the data and bring its map back up to date. Depending upon how long the Ceph OSD Daemon was down, the OSD's objects and placement groups may be significantly out of date. Also, if a failure domain went down (e.g., a rack), more than one Ceph OSD Daemon may come back online at the same time. This can make the recovery process time consuming and resource intensive. To maintain operational performance, Ceph performs recovery with limitations on the number recovery requests, threads and object chunk sizes which allows Ceph perform well in a degraded state. ``osd_recovery_delay_start`` :Description: After peering completes, Ceph will delay for the specified number of seconds before starting to recover RADOS objects. :Type: Float :Default: ``0`` ``osd_recovery_max_active`` :Description: The number of active recovery requests per OSD at one time. More requests will accelerate recovery, but the requests places an increased load on the cluster. This value is only used if it is non-zero. Normally it is ``0``, which means that the ``hdd`` or ``ssd`` values (below) are used, depending on the type of the primary device backing the OSD. :Type: 32-bit Integer :Default: ``0`` ``osd_recovery_max_active_hdd`` :Description: The number of active recovery requests per OSD at one time, if the primary device is rotational. :Type: 32-bit Integer :Default: ``3`` ``osd_recovery_max_active_ssd`` :Description: The number of active recovery requests per OSD at one time, if the primary device is non-rotational (i.e., an SSD). :Type: 32-bit Integer :Default: ``10`` ``osd_recovery_max_chunk`` :Description: The maximum size of a recovered chunk of data to push. :Type: 64-bit Unsigned Integer :Default: ``8 << 20`` ``osd_recovery_max_single_start`` :Description: The maximum number of recovery operations per OSD that will be newly started when an OSD is recovering. :Type: 64-bit Unsigned Integer :Default: ``1`` ``osd_recovery_thread_timeout`` :Description: The maximum time in seconds before timing out a recovery thread. :Type: 32-bit Integer :Default: ``30`` ``osd_recover_clone_overlap`` :Description: Preserves clone overlap during recovery. Should always be set to ``true``. :Type: Boolean :Default: ``true`` ``osd_recovery_sleep`` :Description: Time in seconds to sleep before the next recovery or backfill op. Increasing this value will slow down recovery operation while client operations will be less impacted. :Type: Float :Default: ``0`` ``osd_recovery_sleep_hdd`` :Description: Time in seconds to sleep before next recovery or backfill op for HDDs. :Type: Float :Default: ``0.1`` ``osd_recovery_sleep_ssd`` :Description: Time in seconds to sleep before the next recovery or backfill op for SSDs. :Type: Float :Default: ``0`` ``osd_recovery_sleep_hybrid`` :Description: Time in seconds to sleep before the next recovery or backfill op when OSD data is on HDD and OSD journal / WAL+DB is on SSD. :Type: Float :Default: ``0.025`` ``osd_recovery_priority`` :Description: The default priority set for recovery work queue. Not related to a pool's ``recovery_priority``. :Type: 32-bit Integer :Default: ``5`` Tiering ======= ``osd_agent_max_ops`` :Description: The maximum number of simultaneous flushing ops per tiering agent in the high speed mode. :Type: 32-bit Integer :Default: ``4`` ``osd_agent_max_low_ops`` :Description: The maximum number of simultaneous flushing ops per tiering agent in the low speed mode. :Type: 32-bit Integer :Default: ``2`` See `cache target dirty high ratio`_ for when the tiering agent flushes dirty objects within the high speed mode. Miscellaneous ============= ``osd_snap_trim_thread_timeout`` :Description: The maximum time in seconds before timing out a snap trim thread. :Type: 32-bit Integer :Default: ``1*60*60`` ``osd_backlog_thread_timeout`` :Description: The maximum time in seconds before timing out a backlog thread. :Type: 32-bit Integer :Default: ``1*60*60`` ``osd_default_notify_timeout`` :Description: The OSD default notification timeout (in seconds). :Type: 32-bit Unsigned Integer :Default: ``30`` ``osd_check_for_log_corruption`` :Description: Check log files for corruption. Can be computationally expensive. :Type: Boolean :Default: ``false`` ``osd_remove_thread_timeout`` :Description: The maximum time in seconds before timing out a remove OSD thread. :Type: 32-bit Integer :Default: ``60*60`` ``osd_command_thread_timeout`` :Description: The maximum time in seconds before timing out a command thread. :Type: 32-bit Integer :Default: ``10*60`` ``osd_delete_sleep`` :Description: Time in seconds to sleep before the next removal transaction. This throttles the PG deletion process. :Type: Float :Default: ``0`` ``osd_delete_sleep_hdd`` :Description: Time in seconds to sleep before the next removal transaction for HDDs. :Type: Float :Default: ``5`` ``osd_delete_sleep_ssd`` :Description: Time in seconds to sleep before the next removal transaction for SSDs. :Type: Float :Default: ``0`` ``osd_delete_sleep_hybrid`` :Description: Time in seconds to sleep before the next removal transaction when OSD data is on HDD and OSD journal or WAL+DB is on SSD. :Type: Float :Default: ``1`` ``osd_command_max_records`` :Description: Limits the number of lost objects to return. :Type: 32-bit Integer :Default: ``256`` ``osd_fast_fail_on_connection_refused`` :Description: If this option is enabled, crashed OSDs are marked down immediately by connected peers and MONs (assuming that the crashed OSD host survives). Disable it to restore old behavior, at the expense of possible long I/O stalls when OSDs crash in the middle of I/O operations. :Type: Boolean :Default: ``true`` .. _pool: ../../operations/pools .. _Configuring Monitor/OSD Interaction: ../mon-osd-interaction .. _Monitoring OSDs and PGs: ../../operations/monitoring-osd-pg#peering .. _Pool & PG Config Reference: ../pool-pg-config-ref .. _Journal Config Reference: ../journal-ref .. _cache target dirty high ratio: ../../operations/pools#cache-target-dirty-high-ratio .. _mClock Config Reference: ../mclock-config-ref