lvmcache(category35-downloads.html) - phpMan

LVMCACHE(7)                                                        LVMCACHE(7)
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). When caching, varying subsets  of
       an  LV's  data are temporarily stored on a smaller, faster device (e.g.
       an SSD) to improve the performance of the LV.
       To do this with lvm, a new special LV is first created from the  faster
       device.  This LV will hold the cache. Then, the new fast LV is attached
       to the main LV by way of an lvconvert command. lvconvert inserts one of
       the  device  mapper  caching  targets  into the main LV's i/o path. The
       device mapper target combines the main LV and fast  LV  into  a  hybrid
       device  that  looks like the main LV, but has better performance. While
       the main LV is being used, portions of its data will be temporarily and
       transparently stored on the special fast LV.
       The two kinds of caching are:
       o A  read  and  write hot-spot cache, using the dm-cache kernel module.
         This cache tracks access patterns and adjusts  its  content  deliber-
         ately  so  that  commonly  used parts of the main LV are likely to be
         found on the fast storage. LVM refers  to  this  using  the  LV  type
         cache.
       o A write cache, using the dm-writecache kernel module.  This cache can
         be used with SSD or PMEM devices to speed up all writes to  the  main
         LV. Data read from the main LV is not stored in the cache, only newly
         written data.  LVM refers to this using the LV type writecache.
USAGE
   1. Identify main LV that needs caching
       The main LV may  already  exist,  and  is  located  on  larger,  slower
       devices.  A main LV would be created with a command like:
       # lvcreate -n main -L Size vg /dev/slow_hhd
   2. Identify fast LV to use as the cache
       A fast LV is created using one or more fast devices, like an SSD.  This
       special LV will be used to hold the cache:
       # lvcreate -n fast -L Size vg /dev/fast_ssd
       # lvs -a
         LV   Attr       Type   Devices
         fast -wi------- linear /dev/fast_ssd
         main -wi------- linear /dev/slow_hhd
   3. Start caching the main LV
       To start caching the main LV,  convert  the  main  LV  to  the  desired
       caching type, and specify the fast LV to use as the cache:
       using dm-cache (with cachepool):
       # lvconvert --type cache --cachepool fast vg/main
       using dm-cache (with cachevol):
       # lvconvert --type cache --cachevol fast vg/main
       using dm-writecache (with cachevol):
       # lvconvert --type writecache --cachevol fast vg/main
       For more alternatives see:
       dm-cache command shortcut
       dm-cache with separate data and metadata LVs
   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 renamed with a _cvol or
       _cpool suffix.  It is displayed by lvs -a.  The _corig  or  _wcorig  LV
       represents the original LV without the cache.
       using dm-cache (with cachepool):
       # lvs -ao+devices
         LV                 Pool         Type       Devices
         main               [fast_cpool] cache      main_corig(0)
         [fast_cpool]                    cache-pool fast_pool_cdata(0)
         [fast_cpool_cdata]              linear     /dev/fast_ssd
         [fast_cpool_cmeta]              linear     /dev/fast_ssd
         [main_corig]                    linear     /dev/slow_hhd
       using dm-cache (with cachevol):
       # lvs -ao+devices
         LV           Pool        Type   Devices
         main         [fast_cvol] cache  main_corig(0)
         [fast_cvol]              linear /dev/fast_ssd
         [main_corig]             linear /dev/slow_hhd
       using dm-writecache (with cachevol):
       # lvs -ao+devices
         LV            Pool        Type       Devices
         main          [fast_cvol] writecache main_wcorig(0)
         [fast_cvol]               linear     /dev/fast_ssd
         [main_wcorig]             linear     /dev/slow_hhd
   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 and also remove unneeded cache pool, use
       the --uncache:
       # lvconvert --uncache vg/main
       # lvs -a
         LV   VG Attr       Type   Devices
         main vg -wi------- linear /dev/slow_hhd
       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
       # lvs -a
         LV   VG Attr       Type   Devices
         fast vg -wi------- linear /dev/fast_ssd
         main vg -wi------- linear /dev/slow_hhd
   7. Create a new LV with caching
       A new LV can be created with caching attached at the time  of  creation
       using the following command:
       # lvcreate --type cache|writecache -n Name -L Size
            --cachedevice /dev/fast_ssd vg /dev/slow_hhd
       The  main  LV  is  created  with  the  specified Name and Size from the
       slow_hhd.  A hidden fast LV is created on  the  fast_ssd  and  is  then
       attached  to  the  new  main LV.  If the fast_ssd is unused, the entire
       disk will be used as the cache unless the --cachesize option is used to
       specify  a  size  for  the  fast  LV.   The --cachedevice option can be
       repeated to use multiple disks for the fast LV.
OPTIONS
   option args
       --cachepool CachePoolLV|LV
       Pass this option a cachepool LV or a standard LV.  When using  a  cache
       pool,  lvm  places cache data and cache metadata on different LVs.  The
       two LVs together are called a cache pool.  This has a bit  better  per-
       formance  for  dm-cache and permits specific placement and segment type
       selection for data and metadata volumes.  A cache pool  is  represented
       as a special type of LV that cannot be used directly.  If a standard LV
       is passed with this option, lvm will first convert it to a  cache  pool
       by  combining  it with another LV to use for metadata.  This option can
       be used with dm-cache.
       --cachevol LV
       Pass this option a fast LV that should be used to hold the cache.  With
       a  cachevol,  cache  data and metadata are stored in different parts of
       the same fast LV.  This option can be used with  dm-writecache  or  dm-
       cache.
       --cachedevice PV
       This  option  can  be  used  in  place  of  --cachevol, in which case a
       cachevol LV will be created using the specified  device.   This  option
       can  be  repeated to create a cachevol using multiple devices, or a tag
       name can be specified in which case the cachevol will be created  using
       any  of  the  devices  with  the given tag.  If a named cache device is
       unused, the entire device will be used to create the cachevol.  To cre-
       ate  a  cachevol of a specific size from the cache devices, include the
       --cachesize option.
   dm-cache block size
       A cache pool will have a logical block size of 4096 bytes if it is cre-
       ated on a device with a logical block size of 4096 bytes.
       If a main LV has logical block size 512 (with an existing xfs file sys-
       tem using that size), then it cannot use a cache pool with a 4096 logi-
       cal block size.  If the cache pool is attached, the main LV will likely
       fail to mount.
       To avoid this problem, use a mkfs option to specify a 4096  block  size
       for the file system, or attach the cache pool before running mkfs.
   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 --cachesettings  block_size=4096|512  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.
       The writecache block size is displayed by the command:
       lvs -o writecacheblocksize VG/LV
   dm-writecache memory usage
       The amount of main system memory used by dm-writecache can be a  factor
       when  selecting  the  writecache cachevol size and the writecache block
       size.
       o writecache block size 4096: each 100 GiB of writecache cachevol  uses
         slightly over 2 GiB of system memory.
       o writecache block size 512: each 100 GiB of writecache cachevol uses a
         little over 16 GiB of system memory.
   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 --cachevol fast \
            --cachesettings 'high_watermark=N writeback_jobs=N' vg/main
       Tunable options are:
       high_watermark = <percent>
              Start  writeback  when the writecache usage reaches this percent
              (0-100).
       low_watermark = <percent>
              Stop writeback when the writecache usage  reaches  this  percent
              (0-100).
       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 issu-
              ing the FLUSH request, the blocks are automatically committed.
       autocommit_time = <milliseconds>
              The data is automatically committed 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.
       cleaner = 0|1
              Setting  cleaner=1  enables the writecache cleaner mode in which
              data is gradually flushed from the cache.  If this is done prior
              to  detaching  the  writecache, then the splitcache command will
              have little or no flushing to perform.  If not done  beforehand,
              the  splitcache  command  enables the cleaner mode and waits for
              flushing to complete before detaching  the  writecache.   Adding
              cleaner=0  to the splitcache command will skip the cleaner mode,
              and any required flushing is performed in device suspend.
   dm-cache with separate data and metadata LVs
       Preferred way of using dm-cache is to  place  the  cache  metadata  and
       cache  data  on  separate  LVs.  To do this, a "cache pool" is created,
       which is a special LV that references two sub LVs, one for data and one
       for metadata.
       To create a cache pool of given data size and let lvm2 calculate appro-
       priate metadata size:
       # lvcreate --type cache-pool -L DataSize -n fast vg /dev/fast_ssd1
       To create a cache pool from separate LV and let lvm2  calculate  appro-
       priate cache metadata size:
       # lvcreate -n fast -L DataSize vg /dev/fast_ssd1
       # lvconvert --type cache-pool vg/fast /dev/fast_ssd1
       To create a cache pool from two separate LVs:
       # lvcreate -n fast -L DataSize vg /dev/fast_ssd1
       # lvcreate -n fastmeta -L MetadataSize vg /dev/fast_ssd2
       # lvconvert --type cache-pool --poolmetadata fastmeta vg/fast
       Then use the cache pool LV to start caching the main LV:
       # lvconvert --type cache --cachepool fast 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 fast -L DataSize vg /dev/fast_ssd1
       # lvcreate -n fastmeta -L MetadataSize vg /dev/fast_ssd2
       # lvconvert --type cache --cachepool fast \
               --poolmetadata fastmeta 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 --cachemode writethrough \
               --cachepool fast vg/main
       # lvconvert --type cache --cachemode writethrough \
               --cachevol fast  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. Cache
       chunks bigger then 512KiB shall be only used when necessary.
       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.  It  can  also  require  increasing  migration
       threshold  which  defaults to 2048 sectors (1 MiB). Lvm2 ensures migra-
       tion threshold is at least 8 chunks in size. This  may  in  some  cases
       result  in  very  high  bandwidth load of transferring data between the
       cache LV and its cache origin LV. 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) allocation/cache_pool_chunk_size
       controls the default chunk size.
       The default value is shown by:
       lvmconfig --type default allocation/cache_pool_chunk_size
       Checking migration threshold (in sectors) of running cached LV:
       lvs -o+kernel_cache_settings VG/LV
   dm-cache migration threshold
       Migrating data between the origin and cache  LV  uses  bandwidth.   The
       user can set a throttle to prevent more than a certain amount of migra-
       tion occurring at any one time.  Currently dm-cache is not  taking  any
       account of normal io traffic going to the devices.
       User  can  set migration threshold via cache policy settings as "migra-
       tion_threshold=<#sectors>" to set the maximum number of  sectors  being
       migrated, the default being 2048 sectors (1MiB).
       Command to set migration threshold to 2MiB (4096 sectors):
       lvcreate --cachepolicy 'migration_threshold=4096' VG/LV
       Command to display the migration threshold:
       lvs -o+kernel_cache_settings,cache_settings VG/LV
       lvs -o+chunksize VG/LV
   dm-cache cache policy
       The dm-cache subsystem has additional per-LV parameters: the cache pol-
       icy 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 using metadata profiles
       Cache  pools allows to set a variety of options. Lots of these settings
       can be specified in lvm.conf or profile settings.  You  can  prepare  a
       number of different profiles in the /etc/lvm/profile directory and just
       specify the metadata profile file name  when  caching  LV  or  creating
       cache-pool.   Check  the  output of lvmconfig --type default --withcom-
       ments for a detailed description of all individual cache settings.
       Example
       # cat <<EOF > /etc/lvm/profile/cache_big_chunk.profile
       allocation {
              cache_pool_metadata_require_separate_pvs=0
              cache_pool_chunk_size=512
              cache_metadata_format=2
              cache_mode="writethrough"
              cache_policy="smq"
              cache_settings {
                     smq {
                            migration_threshold=8192
                            random_threshold=4096
                     }
              }
       }
       EOF
       # lvcreate --cache -L10G --metadataprofile cache_big_chunk vg/main \
               /dev/fast_ssd
       # lvcreate --cache -L10G vg/main --config \
               'allocation/cache_pool_chunk_size=512' /dev/fast_ssd
   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.
   RAID1 cache device
       RAID1 can be used to create the fast LV holding the cache  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/ssd1 /dev/ssd2
       # lvconvert --type cache --cachevol fast vg/main
   dm-cache command shortcut
       A single command can be used to cache main LV with  automatic  creation
       of a cache-pool:
       # lvcreate --cache --size CacheDataSize VG/LV [FastPVs]
       or the longer variant
       # lvcreate --type cache --size CacheDataSize \
               --name NameCachePool VG/LV [FastPVs]
       In this command, the specified LV already exists, and is the main LV to
       be cached.  The command creates a new cache pool with  size  and  given
       name or the name is automatically selected from a sequence lvolX_cpool,
       using the optionally specified fast PV(s) (typically an ssd).  Then  it
       attaches the new cache pool to the existing main LV to begin caching.
       (Note:  ensure that the specified main LV is a standard LV.  If a cache
       pool LV is mistakenly specified, then the command does  something  dif-
       ferent.)
       (Note:  the type option is interpreted differently by this command than
       by normal lvcreate commands in which --type specifies the type  of  the
       newly  created  LV.   In this case, an LV with type cache-pool is being
       created, and the existing main LV is being converted to type cache.)
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),
       cache_check(8), cache_dump(8), cache_repair(8)
Red Hat, Inc        LVM TOOLS 2.03.14(2)-RHEL8 (2021-10-20)        LVMCACHE(7)