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NAME

lvmcache — LVM caching

DESCRIPTION

lvm(8) includes two kinds of caching that can be used to improve the performance of a Logical Volume (LV). Typically, a smaller, faster device is used to improve i/o performance of a larger, slower LV. To do this, a separate LV is created from the faster device, and then the original LV is converted to start using the fast LV.

The two kinds of caching are:

A read and write hot-spot cache, using the dm-cache kernel module. This cache is slow moving, and adjusts the cache content over time so that the most used parts of the LV are kept on the faster device. Both reads and writes use the cache. LVM refers to this using the LV type cache.

A streaming write cache, using the dm-writecache kernel module. This cache is intended to be used with SSD or PMEM devices to speed up all writes to an LV. Reads do not use this cache. LVM refers to this using the LV type writecache.

USAGE

Both kinds of caching use similar lvm commands:

1. Identify main LV that needs caching

A main LV exists on slower devices.

$ lvcreate −n main −L Size vg /dev/slow

2. Identify fast LV to use as the cache

A fast LV exists on faster devices. This LV will be used to hold the cache.

$ lvcreate −n fast −L Size vg /dev/fast

$ lvs vg −o+devices
LV VG Attr LSize Devices
fast vg −wi−−−−−−− xx.00m /dev/fast(0)
main vg −wi−−−−−−− yyy.00m /dev/slow(0)

3. Start caching the main LV

To start caching the main LV using the fast LV, convert the main LV to the desired caching type, and specify the fast LV to use:

using dm-cache:

$ lvconvert −−type cache −−cachepool fast vg/main

or dm-writecache:

$ lvconvert −−type writecache −−cachepool fast vg/main

4. Display LVs

Once the fast LV has been attached to the main LV, lvm reports the main LV type as either cache or writecache depending on the type used. While attached, the fast LV is hidden, and only displayed when lvs is given −a. The _corig or _wcorig LV represents the original LV without the cache.

using dm-cache:

$ lvs −a −o name,vgname,lvattr,origin,segtype,devices vg
LV VG Attr Origin Type Devices
[fast] vg Cwi-aoC−−− linear /dev/fast(xx)
main vg Cwi−a-C−−− [main_corig] cache main_corig(0)
[main_corig] vg owi-aoC−−− linear /dev/slow(0)

or dm-writecache:

$ lvs −a −o name,vgname,lvattr,origin,segtype,devices vg
LV VG Attr Origin Type Devices
[fast] vg −wi-ao−−−− linear /dev/fast(xx)
main vg Cwi−a−−−−− [main_wcorig] writecache main_wcorig(0)
[main_wcorig] vg −wi-ao−−−− linear /dev/slow(0)

5. Use the main LV

Use the LV until the cache is no longer wanted, or needs to be changed.

6. Stop caching

To stop caching the main LV, separate the fast LV from the main LV. This changes the type of the main LV back to what it was before the cache was attached.

$ lvconvert −−splitcache vg/main

OPTIONS

dm-writecache block size

The dm-writecache block size can be 4096 bytes (the default), or 512 bytes. The default 4096 has better performance and should be used except when 512 is necessary for compatibility. The dm-writecache block size is specified with −−writecacheblocksize 4096b|512b when caching is started.

When a file system like xfs already exists on the main LV prior to caching, and the file system is using a block size of 512, then the writecache block size should be set to 512. (The file system will likely fail to mount if writecache block size of 4096 is used in this case.)

Check the xfs sector size while the fs is mounted:

$ xfs_info /dev/vg/main
Look for sectsz=512 or sectsz=4096

The writecache block size should be chosen to match the xfs sectsz value.

It is also possible to specify a sector size of 4096 to mkfs.xfs when creating the file system. In this case the writecache block size of 4096 can be used.

dm-writecache settings

Tunable parameters can be passed to the dm-writecache kernel module using the −−cachesettings option when caching is started, e.g.

$ lvconvert −−type writecache −−cachepool fast \

-−cachesettings ’high_watermark=N writeback_jobs=N’ vg/main

Tunable options are:

high_watermark = <count>

Start writeback when the number of used blocks reach this watermark

low_watermark = <count>

Stop writeback when the number of used blocks drops below this watermark

writeback_jobs = <count>

Limit the number of blocks that are in flight during writeback. Setting this value reduces writeback throughput, but it may improve latency of read requests.

autocommit_blocks = <count>

When the application writes this amount of blocks without issuing the FLUSH request, the blocks are automatically commited.

autocommit_time = <milliseconds>

The data is automatically commited if this time passes and no FLUSH request is received.

fua = 0|1

Use the FUA flag when writing data from persistent memory back to the underlying device. Applicable only to persistent memory.

nofua = 0|1

Don’t use the FUA flag when writing back data and send the FLUSH request afterwards. Some underlying devices perform better with fua, some with nofua. Testing is necessary to determine which. Applicable only to persistent memory.

dm-cache with separate data and metadata LVs

When using dm-cache, the cache metadata and cache data can be stored on separate LVs. To do this, a "cache−pool LV" is created, which is a special LV that references two sub LVs, one for data and one for metadata.

To create a cache−pool LV from two separate LVs:

$ lvcreate −n fastpool −L DataSize vg /dev/fast1
$ lvcreate −n fastpoolmeta −L MetadataSize vg /dev/fast2
$ lvconvert −−type cache−pool −−poolmetadata fastpoolmeta vg/fastpool

Then use the cache−pool LV to start caching the main LV:

$ lvconvert −−type cache −−cachepool fastpool vg/main

A variation of the same procedure automatically creates a cache−pool when caching is started. To do this, use a standard LV as the −−cachepool (this will hold cache data), and use another standard LV as the -−poolmetadata (this will hold cache metadata). LVM will create a cache−pool LV from the two specified LVs, and use the cache−pool to start caching the main LV.

$ lvcreate −n fastpool −L DataSize vg /dev/fast1
$ lvcreate −n fastpoolmeta −L MetadataSize vg /dev/fast2
$ lvconvert −−type cache −−cachepool fastpool \

-−poolmetadata fastpoolmeta vg/main

dm-cache cache modes

The default dm-cache cache mode is "writethrough". Writethrough ensures that any data written will be stored both in the cache and on the origin LV. The loss of a device associated with the cache in this case would not mean the loss of any data.

A second cache mode is "writeback". Writeback delays writing data blocks from the cache back to the origin LV. This mode will increase performance, but the loss of a cache device can result in lost data.

With the −−cachemode option, the cache mode can be set when caching is started, or changed on an LV that is already cached. The current cache mode can be displayed with the cache_mode reporting option:

lvs −o+cache_mode VG/LV

lvm.conf(5) allocation/cache_mode
defines the default cache mode.

$ lvconvert −−type cache −−cachepool fast \

-−cachemode writethrough vg/main

dm-cache chunk size

The size of data blocks managed by dm-cache can be specified with the -−chunksize option when caching is started. The default unit is KiB. The value must be a multiple of 32KiB between 32KiB and 1GiB.

Using a chunk size that is too large can result in wasteful use of the cache, in which small reads and writes cause large sections of an LV to be stored in the cache. However, choosing a chunk size that is too small can result in more overhead trying to manage the numerous chunks that become mapped into the cache. Overhead can include both excessive CPU time searching for chunks, and excessive memory tracking chunks.

Command to display the chunk size:
lvs −o+chunksize VG/LV

lvm.conf(5) cache_pool_chunk_size
controls the default chunk size.

The default value is shown by:
lvmconfig −−type default allocation/cache_pool_chunk_size

dm-cache cache policy

The dm-cache subsystem has additional per-LV parameters: the cache policy to use, and possibly tunable parameters for the cache policy. Three policies are currently available: "smq" is the default policy, "mq" is an older implementation, and "cleaner" is used to force the cache to write back (flush) all cached writes to the origin LV.

The older "mq" policy has a number of tunable parameters. The defaults are chosen to be suitable for the majority of systems, but in special circumstances, changing the settings can improve performance.

With the −−cachepolicy and −−cachesettings options, the cache policy and settings can be set when caching is started, or changed on an existing cached LV (both options can be used together). The current cache policy and settings can be displayed with the cache_policy and cache_settings reporting options:

lvs −o+cache_policy,cache_settings VG/LV

Change the cache policy and settings of an existing LV.

$ lvchange −−cachepolicy mq −−cachesettings \

'migration_threshold=2048 random_threshold=4' vg/main

lvm.conf(5) allocation/cache_policy
defines the default cache policy.

lvm.conf(5) allocation/cache_settings
defines the default cache settings.

dm-cache spare metadata LV

See lvmthin(7) for a description of the "pool metadata spare" LV. The same concept is used for cache pools.

dm-cache metadata formats

There are two disk formats for dm-cache metadata. The metadata format can be specified with −−cachemetadataformat when caching is started, and cannot be changed. Format 2 has better performance; it is more compact, and stores dirty bits in a separate btree, which improves the speed of shutting down the cache. With auto, lvm selects the best option provided by the current dm-cache kernel module.

mirrored cache device

The fast LV holding the cache can be created as a raid1 mirror so that it can tolerate a device failure. (When using dm-cache with separate data and metadata LVs, each of the sub-LVs can use raid1.)

$ lvcreate −n main −L Size vg /dev/slow
$ lvcreate −−type raid1 −m 1 −n fast −L Size vg /dev/fast1 /dev/fast2
$ lvconvert −−type cache −−cachepool fast vg/main

SEE ALSO

lvm.conf(5), lvchange(8), lvcreate(8), lvdisplay(8), lvextend(8), lvremove(8), lvrename(8), lvresize(8), lvs(8), vgchange(8), vgmerge(8), vgreduce(8), vgsplit(8)

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