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+==========================
+BlueStore Config Reference
+==========================
+
+Devices
+=======
+
+BlueStore manages either one, two, or (in certain cases) three storage
+devices.
+
+In the simplest case, BlueStore consumes a single (primary) storage device.
+The storage device is normally used as a whole, occupying the full device that
+is managed directly by BlueStore. This *primary device* is normally identified
+by a ``block`` symlink in the data directory.
+
+The data directory is a ``tmpfs`` mount which gets populated (at boot time, or
+when ``ceph-volume`` activates it) with all the common OSD files that hold
+information about the OSD, like: its identifier, which cluster it belongs to,
+and its private keyring.
+
+It is also possible to deploy BlueStore across one or two additional devices:
+
+* A *write-ahead log (WAL) device* (identified as ``block.wal`` in the data directory) can be
+  used for BlueStore's internal journal or write-ahead log. It is only useful
+  to use a WAL device if the device is faster than the primary device (e.g.,
+  when it is on an SSD and the primary device is an HDD).
+* A *DB device* (identified as ``block.db`` in the data directory) can be used
+  for storing BlueStore's internal metadata.  BlueStore (or rather, the
+  embedded RocksDB) will put as much metadata as it can on the DB device to
+  improve performance.  If the DB device fills up, metadata will spill back
+  onto the primary device (where it would have been otherwise).  Again, it is
+  only helpful to provision a DB device if it is faster than the primary
+  device.
+
+If there is only a small amount of fast storage available (e.g., less
+than a gigabyte), we recommend using it as a WAL device.  If there is
+more, provisioning a DB device makes more sense.  The BlueStore
+journal will always be placed on the fastest device available, so
+using a DB device will provide the same benefit that the WAL device
+would while *also* allowing additional metadata to be stored there (if
+it will fit).  This means that if a DB device is specified but an explicit
+WAL device is not, the WAL will be implicitly colocated with the DB on the faster
+device.
+
+A single-device (colocated) BlueStore OSD can be provisioned with:
+
+.. prompt:: bash $
+
+   ceph-volume lvm prepare --bluestore --data <device>
+
+To specify a WAL device and/or DB device:
+   
+.. prompt:: bash $
+
+   ceph-volume lvm prepare --bluestore --data <device> --block.wal <wal-device> --block.db <db-device>
+
+.. note:: ``--data`` can be a Logical Volume using  *vg/lv* notation. Other
+          devices can be existing logical volumes or GPT partitions.
+
+Provisioning strategies
+-----------------------
+Although there are multiple ways to deploy a BlueStore OSD (unlike Filestore
+which had just one), there are two common arrangements that should help clarify
+the deployment strategy:
+
+.. _bluestore-single-type-device-config:
+
+**block (data) only**
+^^^^^^^^^^^^^^^^^^^^^
+If all devices are the same type, for example all rotational drives, and
+there are no fast devices to use for metadata, it makes sense to specify the
+block device only and to not separate ``block.db`` or ``block.wal``. The
+:ref:`ceph-volume-lvm` command for a single ``/dev/sda`` device looks like:
+
+.. prompt:: bash $
+
+   ceph-volume lvm create --bluestore --data /dev/sda
+
+If logical volumes have already been created for each device, (a single LV
+using 100% of the device), then the :ref:`ceph-volume-lvm` call for an LV named
+``ceph-vg/block-lv`` would look like:
+
+.. prompt:: bash $
+
+   ceph-volume lvm create --bluestore --data ceph-vg/block-lv
+
+.. _bluestore-mixed-device-config:
+
+**block and block.db**
+^^^^^^^^^^^^^^^^^^^^^^
+If you have a mix of fast and slow devices (SSD / NVMe and rotational),
+it is recommended to place ``block.db`` on the faster device while ``block``
+(data) lives on the slower (spinning drive).
+
+You must create these volume groups and logical volumes manually as 
+the ``ceph-volume`` tool is currently not able to do so automatically.
+
+For the below example, let us assume four rotational (``sda``, ``sdb``, ``sdc``, and ``sdd``)
+and one (fast) solid state drive (``sdx``). First create the volume groups:
+
+.. prompt:: bash $
+
+   vgcreate ceph-block-0 /dev/sda
+   vgcreate ceph-block-1 /dev/sdb
+   vgcreate ceph-block-2 /dev/sdc
+   vgcreate ceph-block-3 /dev/sdd
+
+Now create the logical volumes for ``block``:
+
+.. prompt:: bash $
+
+   lvcreate -l 100%FREE -n block-0 ceph-block-0
+   lvcreate -l 100%FREE -n block-1 ceph-block-1
+   lvcreate -l 100%FREE -n block-2 ceph-block-2
+   lvcreate -l 100%FREE -n block-3 ceph-block-3
+
+We are creating 4 OSDs for the four slow spinning devices, so assuming a 200GB
+SSD in ``/dev/sdx`` we will create 4 logical volumes, each of 50GB:
+
+.. prompt:: bash $
+
+   vgcreate ceph-db-0 /dev/sdx
+   lvcreate -L 50GB -n db-0 ceph-db-0
+   lvcreate -L 50GB -n db-1 ceph-db-0
+   lvcreate -L 50GB -n db-2 ceph-db-0
+   lvcreate -L 50GB -n db-3 ceph-db-0
+
+Finally, create the 4 OSDs with ``ceph-volume``:
+
+.. prompt:: bash $
+
+   ceph-volume lvm create --bluestore --data ceph-block-0/block-0 --block.db ceph-db-0/db-0
+   ceph-volume lvm create --bluestore --data ceph-block-1/block-1 --block.db ceph-db-0/db-1
+   ceph-volume lvm create --bluestore --data ceph-block-2/block-2 --block.db ceph-db-0/db-2
+   ceph-volume lvm create --bluestore --data ceph-block-3/block-3 --block.db ceph-db-0/db-3
+
+These operations should end up creating four OSDs, with ``block`` on the slower
+rotational drives with a 50 GB logical volume (DB) for each on the solid state
+drive.
+
+Sizing
+======
+When using a :ref:`mixed spinning and solid drive setup
+<bluestore-mixed-device-config>` it is important to make a large enough
+``block.db`` logical volume for BlueStore. Generally, ``block.db`` should have
+*as large as possible* logical volumes.
+
+The general recommendation is to have ``block.db`` size in between 1% to 4%
+of ``block`` size. For RGW workloads, it is recommended that the ``block.db``
+size isn't smaller than 4% of ``block``, because RGW heavily uses it to store
+metadata (omap keys). For example, if the ``block`` size is 1TB, then ``block.db`` shouldn't
+be less than 40GB. For RBD workloads, 1% to 2% of ``block`` size is usually enough.
+
+In older releases, internal level sizes mean that the DB can fully utilize only
+specific partition / LV sizes that correspond to sums of L0, L0+L1, L1+L2,
+etc. sizes, which with default settings means roughly 3 GB, 30 GB, 300 GB, and
+so forth.  Most deployments will not substantially benefit from sizing to
+accommodate L3 and higher, though DB compaction can be facilitated by doubling
+these figures to 6GB, 60GB, and 600GB.
+
+Improvements in releases beginning with Nautilus 14.2.12 and Octopus 15.2.6
+enable better utilization of arbitrary DB device sizes, and the Pacific
+release brings experimental dynamic level support.  Users of older releases may
+thus wish to plan ahead by provisioning larger DB devices today so that their
+benefits may be realized with future upgrades.
+
+When *not* using a mix of fast and slow devices, it isn't required to create
+separate logical volumes for ``block.db`` (or ``block.wal``). BlueStore will
+automatically colocate these within the space of ``block``.
+
+
+Automatic Cache Sizing
+======================
+
+BlueStore can be configured to automatically resize its caches when TCMalloc
+is configured as the memory allocator and the ``bluestore_cache_autotune``
+setting is enabled.  This option is currently enabled by default.  BlueStore
+will attempt to keep OSD heap memory usage under a designated target size via
+the ``osd_memory_target`` configuration option.  This is a best effort
+algorithm and caches will not shrink smaller than the amount specified by
+``osd_memory_cache_min``.  Cache ratios will be chosen based on a hierarchy
+of priorities.  If priority information is not available, the
+``bluestore_cache_meta_ratio`` and ``bluestore_cache_kv_ratio`` options are
+used as fallbacks.
+
+Manual Cache Sizing
+===================
+
+The amount of memory consumed by each OSD for BlueStore caches is
+determined by the ``bluestore_cache_size`` configuration option.  If
+that config option is not set (i.e., remains at 0), there is a
+different default value that is used depending on whether an HDD or
+SSD is used for the primary device (set by the
+``bluestore_cache_size_ssd`` and ``bluestore_cache_size_hdd`` config
+options).
+
+BlueStore and the rest of the Ceph OSD daemon do the best they can
+to work within this memory budget.  Note that on top of the configured
+cache size, there is also memory consumed by the OSD itself, and
+some additional utilization due to memory fragmentation and other
+allocator overhead.
+
+The configured cache memory budget can be used in a few different ways:
+
+* Key/Value metadata (i.e., RocksDB's internal cache)
+* BlueStore metadata
+* BlueStore data (i.e., recently read or written object data)
+
+Cache memory usage is governed by the following options:
+``bluestore_cache_meta_ratio`` and ``bluestore_cache_kv_ratio``.
+The fraction of the cache devoted to data
+is governed by the effective bluestore cache size (depending on
+``bluestore_cache_size[_ssd|_hdd]`` settings and the device class of the primary
+device) as well as the meta and kv ratios.
+The data fraction can be calculated by
+``<effective_cache_size> * (1 - bluestore_cache_meta_ratio - bluestore_cache_kv_ratio)``
+
+Checksums
+=========
+
+BlueStore checksums all metadata and data written to disk.  Metadata
+checksumming is handled by RocksDB and uses `crc32c`. Data
+checksumming is done by BlueStore and can make use of `crc32c`,
+`xxhash32`, or `xxhash64`.  The default is `crc32c` and should be
+suitable for most purposes.
+
+Full data checksumming does increase the amount of metadata that
+BlueStore must store and manage.  When possible, e.g., when clients
+hint that data is written and read sequentially, BlueStore will
+checksum larger blocks, but in many cases it must store a checksum
+value (usually 4 bytes) for every 4 kilobyte block of data.
+
+It is possible to use a smaller checksum value by truncating the
+checksum to two or one byte, reducing the metadata overhead.  The
+trade-off is that the probability that a random error will not be
+detected is higher with a smaller checksum, going from about one in
+four billion with a 32-bit (4 byte) checksum to one in 65,536 for a
+16-bit (2 byte) checksum or one in 256 for an 8-bit (1 byte) checksum.
+The smaller checksum values can be used by selecting `crc32c_16` or
+`crc32c_8` as the checksum algorithm.
+
+The *checksum algorithm* can be set either via a per-pool
+``csum_type`` property or the global config option.  For example:
+
+.. prompt:: bash $
+
+   ceph osd pool set <pool-name> csum_type <algorithm>
+
+Inline Compression
+==================
+
+BlueStore supports inline compression using `snappy`, `zlib`, or
+`lz4`. Please note that the `lz4` compression plugin is not
+distributed in the official release.
+
+Whether data in BlueStore is compressed is determined by a combination
+of the *compression mode* and any hints associated with a write
+operation.  The modes are:
+
+* **none**: Never compress data.
+* **passive**: Do not compress data unless the write operation has a
+  *compressible* hint set.
+* **aggressive**: Compress data unless the write operation has an
+  *incompressible* hint set.
+* **force**: Try to compress data no matter what.
+
+For more information about the *compressible* and *incompressible* IO
+hints, see :c:func:`rados_set_alloc_hint`.
+
+Note that regardless of the mode, if the size of the data chunk is not
+reduced sufficiently it will not be used and the original
+(uncompressed) data will be stored.  For example, if the ``bluestore
+compression required ratio`` is set to ``.7`` then the compressed data
+must be 70% of the size of the original (or smaller).
+
+The *compression mode*, *compression algorithm*, *compression required
+ratio*, *min blob size*, and *max blob size* can be set either via a
+per-pool property or a global config option.  Pool properties can be
+set with:
+
+.. prompt:: bash $
+
+   ceph osd pool set <pool-name> compression_algorithm <algorithm>
+   ceph osd pool set <pool-name> compression_mode <mode>
+   ceph osd pool set <pool-name> compression_required_ratio <ratio>
+   ceph osd pool set <pool-name> compression_min_blob_size <size>
+   ceph osd pool set <pool-name> compression_max_blob_size <size>
+
+.. _bluestore-rocksdb-sharding:
+
+RocksDB Sharding
+================
+
+Internally BlueStore uses multiple types of key-value data,
+stored in RocksDB.  Each data type in BlueStore is assigned a
+unique prefix. Until Pacific all key-value data was stored in
+single RocksDB column family: 'default'.  Since Pacific,
+BlueStore can divide this data into multiple RocksDB column
+families. When keys have similar access frequency, modification
+frequency and lifetime, BlueStore benefits from better caching
+and more precise compaction. This improves performance, and also
+requires less disk space during compaction, since each column
+family is smaller and can compact independent of others.
+
+OSDs deployed in Pacific or later use RocksDB sharding by default.
+If Ceph is upgraded to Pacific from a previous version, sharding is off.
+
+To enable sharding and apply the Pacific defaults, stop an OSD and run
+
+    .. prompt:: bash #
+
+      ceph-bluestore-tool \
+        --path <data path> \
+        --sharding="m(3) p(3,0-12) O(3,0-13)=block_cache={type=binned_lru} L P" \
+        reshard
+
+
+Throttling
+==========
+
+SPDK Usage
+==================
+
+If you want to use the SPDK driver for NVMe devices, you must prepare your system.
+Refer to `SPDK document`__ for more details.
+
+.. __: http://www.spdk.io/doc/getting_started.html#getting_started_examples
+
+SPDK offers a script to configure the device automatically. Users can run the
+script as root:
+
+.. prompt:: bash $
+
+   sudo src/spdk/scripts/setup.sh
+
+You will need to specify the subject NVMe device's device selector with
+the "spdk:" prefix for ``bluestore_block_path``.
+
+For example, you can find the device selector of an Intel PCIe SSD with:
+
+.. prompt:: bash $
+
+   lspci -mm -n -D -d 8086:0953
+
+The device selector always has the form of ``DDDD:BB:DD.FF`` or ``DDDD.BB.DD.FF``.
+
+and then set::
+
+  bluestore_block_path = "spdk:trtype:PCIe traddr:0000:01:00.0"
+
+Where ``0000:01:00.0`` is the device selector found in the output of ``lspci``
+command above.
+
+You may also specify a remote NVMeoF target over the TCP transport as in the
+following example::
+
+  bluestore_block_path = "spdk:trtype:TCP traddr:10.67.110.197 trsvcid:4420 subnqn:nqn.2019-02.io.spdk:cnode1"
+
+To run multiple SPDK instances per node, you must specify the
+amount of dpdk memory in MB that each instance will use, to make sure each
+instance uses its own DPDK memory.
+
+In most cases, a single device can be used for data, DB, and WAL.  We describe
+this strategy as *colocating* these components. Be sure to enter the below
+settings to ensure that all IOs are issued through SPDK.::
+
+  bluestore_block_db_path = ""
+  bluestore_block_db_size = 0
+  bluestore_block_wal_path = ""
+  bluestore_block_wal_size = 0
+
+Otherwise, the current implementation will populate the SPDK map files with
+kernel file system symbols and will use the kernel driver to issue DB/WAL IO.
+
+Minimum Allocation Size
+========================
+
+There is a configured minimum amount of storage that BlueStore will allocate on
+an OSD.  In practice, this is the least amount of capacity that a RADOS object
+can consume.  The value of `bluestore_min_alloc_size` is derived from the
+value of `bluestore_min_alloc_size_hdd` or `bluestore_min_alloc_size_ssd`
+depending on the OSD's ``rotational`` attribute.  This means that when an OSD
+is created on an HDD, BlueStore will be initialized with the current value
+of `bluestore_min_alloc_size_hdd`, and SSD OSDs (including NVMe devices)
+with the value of `bluestore_min_alloc_size_ssd`.
+
+Through the Mimic release, the default values were 64KB and 16KB for rotational
+(HDD) and non-rotational (SSD) media respectively.  Octopus changed the default
+for SSD (non-rotational) media to 4KB, and Pacific changed the default for HDD
+(rotational) media to 4KB as well.
+
+These changes were driven by space amplification experienced by Ceph RADOS
+GateWay (RGW) deployments that host large numbers of small files
+(S3/Swift objects).
+
+For example, when an RGW client stores a 1KB S3 object, it is written to a
+single RADOS object.  With the default `min_alloc_size` value, 4KB of
+underlying drive space is allocated.  This means that roughly
+(4KB - 1KB) == 3KB is allocated but never used, which corresponds to 300%
+overhead or 25% efficiency. Similarly, a 5KB user object will be stored
+as one 4KB and one 1KB RADOS object, again stranding 4KB of device capcity,
+though in this case the overhead is a much smaller percentage.  Think of this
+in terms of the remainder from a modulus operation. The overhead *percentage*
+thus decreases rapidly as user object size increases.
+
+An easily missed additional subtlety is that this
+takes place for *each* replica.  So when using the default three copies of
+data (3R), a 1KB S3 object actually consumes roughly 9KB of storage device
+capacity.  If erasure coding (EC) is used instead of replication, the
+amplification may be even higher: for a ``k=4,m=2`` pool, our 1KB S3 object
+will allocate (6 * 4KB) = 24KB of device capacity.
+
+When an RGW bucket pool contains many relatively large user objects, the effect
+of this phenomenon is often negligible, but should be considered for deployments
+that expect a signficiant fraction of relatively small objects.
+
+The 4KB default value aligns well with conventional HDD and SSD devices.  Some
+new coarse-IU (Indirection Unit) QLC SSDs however perform and wear best
+when `bluestore_min_alloc_size_ssd`
+is set at OSD creation to match the device's IU:. 8KB, 16KB, or even 64KB.
+These novel storage drives allow one to achieve read performance competitive
+with conventional TLC SSDs and write performance faster than HDDs, with
+high density and lower cost than TLC SSDs.
+
+Note that when creating OSDs on these devices, one must carefully apply the
+non-default value only to appropriate devices, and not to conventional SSD and
+HDD devices.  This may be done through careful ordering of OSD creation, custom
+OSD device classes, and especially by the use of central configuration _masks_.
+
+Quincy and later releases add
+the `bluestore_use_optimal_io_size_for_min_alloc_size`
+option that enables automatic discovery of the appropriate value as each OSD is
+created.  Note that the use of ``bcache``, ``OpenCAS``, ``dmcrypt``,
+``ATA over Ethernet``, `iSCSI`, or other device layering / abstraction
+technologies may confound the determination of appropriate values. OSDs
+deployed on top of VMware storage have been reported to also
+sometimes report a ``rotational`` attribute that does not match the underlying
+hardware.
+
+We suggest inspecting such OSDs at startup via logs and admin sockets to ensure that
+behavior is appropriate.  Note that this also may not work as desired with
+older kernels.  You can check for this by examining the presence and value
+of ``/sys/block/<drive>/queue/optimal_io_size``.
+
+You may also inspect a given OSD:
+
+.. prompt:: bash #
+
+   ceph osd metadata osd.1701 | grep rotational
+
+This space amplification may manifest as an unusually high ratio of raw to
+stored data reported by ``ceph df``.  ``ceph osd df`` may also report
+anomalously high ``%USE`` / ``VAR`` values when
+compared to other, ostensibly identical OSDs.  A pool using OSDs with
+mismatched ``min_alloc_size`` values may experience unexpected balancer
+behavior as well.
+
+Note that this BlueStore attribute takes effect *only* at OSD creation; if
+changed later, a given OSD's behavior will not change unless / until it is
+destroyed and redeployed with the appropriate option value(s).  Upgrading
+to a later Ceph release will *not* change the value used by OSDs deployed
+under older releases or with other settings.
+
+DSA (Data Streaming Accelerator Usage)
+======================================
+
+If you want to use the DML library to drive DSA device for offloading
+read/write operations on Persist memory in Bluestore. You need to install
+`DML`_ and `idxd-config`_ library in your machine with SPR (Sapphire Rapids) CPU.
+
+.. _DML: https://github.com/intel/DML
+.. _idxd-config: https://github.com/intel/idxd-config
+
+After installing the DML software, you need to configure the shared
+work queues (WQs) with the following WQ configuration example via accel-config tool:
+
+.. prompt:: bash $
+
+   accel-config config-wq --group-id=1 --mode=shared --wq-size=16 --threshold=15 --type=user --name="MyApp1" --priority=10 --block-on-fault=1 dsa0/wq0.1
+   accel-config config-engine dsa0/engine0.1 --group-id=1
+   accel-config enable-device dsa0
+   accel-config enable-wq dsa0/wq0.1