LVM(8)LVM(8)NAMElvm - LVM2 tools
SYNOPSISlvm [command | file]
DESCRIPTIONlvm provides the command-line tools for LVM2. A separate manual page
describes each command in detail.
If lvm is invoked with no arguments it presents a readline prompt
(assuming it was compiled with readline support). LVM commands may be
entered interactively at this prompt with readline facilities including
history and command name and option completion. Refer to readline(3)
for details.
If lvm is invoked with argv[0] set to the name of a specific LVM com‐
mand (for example by using a hard or soft link) it acts as that com‐
mand.
On invocation, lvm requires that only the standard file descriptors
stdin, stdout and stderr are available. If others are found, they get
closed and messages are issued warning about the leak. This warning
can be suppressed by setting the environment variable LVM_SUP‐
PRESS_FD_WARNINGS.
Where commands take VG or LV names as arguments, the full path name is
optional. An LV called "lvol0" in a VG called "vg0" can be specified
as "vg0/lvol0". Where a list of VGs is required but is left empty, a
list of all VGs will be substituted. Where a list of LVs is required
but a VG is given, a list of all the LVs in that VG will be substi‐
tuted. So lvdisplay vg0 will display all the LVs in "vg0". Tags can
also be used - see --addtag below.
One advantage of using the built-in shell is that configuration infor‐
mation gets cached internally between commands.
A file containing a simple script with one command per line can also be
given on the command line. The script can also be executed directly if
the first line is #! followed by the absolute path of lvm.
BUILT-IN COMMANDS
The following commands are built into lvm without links normally being
created in the filesystem for them.
dumpconfig — Display the configuration information after
loading lvm.conf(5) and any other configuration files.
devtypes — Display the recognised built-in block device types.
formats — Display recognised metadata formats.
help — Display the help text.
pvdata — Not implemented in LVM2.
segtypes — Display recognised Logical Volume segment types.
tags — Display any tags defined on this host.
version — Display version information.
COMMANDS
The following commands implement the core LVM functionality.
pvchange — Change attributes of a Physical Volume.
pvck — Check Physical Volume metadata.
pvcreate — Initialize a disk or partition for use by LVM.
pvdisplay — Display attributes of a Physical Volume.
pvmove — Move Physical Extents.
pvremove — Remove a Physical Volume.
pvresize — Resize a disk or partition in use by LVM2.
pvs — Report information about Physical Volumes.
pvscan — Scan all disks for Physical Volumes.
vgcfgbackup — Backup Volume Group descriptor area.
vgcfgrestore — Restore Volume Group descriptor area.
vgchange — Change attributes of a Volume Group.
vgck — Check Volume Group metadata.
vgconvert — Convert Volume Group metadata format.
vgcreate — Create a Volume Group.
vgdisplay — Display attributes of Volume Groups.
vgexport — Make volume Groups unknown to the system.
vgextend — Add Physical Volumes to a Volume Group.
vgimport — Make exported Volume Groups known to the system.
vgimportclone — Import and rename duplicated Volume Group (e.g. a hard‐
ware snapshot).
vgmerge — Merge two Volume Groups.
vgmknodes — Recreate Volume Group directory and Logical Volume special
files
vgreduce — Reduce a Volume Group by removing one or more
Physical Volumes.
vgremove — Remove a Volume Group.
vgrename — Rename a Volume Group.
vgs — Report information about Volume Groups.
vgscan — Scan all disks for Volume Groups and rebuild caches.
vgsplit — Split a Volume Group into two, moving any logical
volumes from one Volume Group to another by moving entire Physi‐
cal Volumes.
lvchange — Change attributes of a Logical Volume.
lvconvert — Convert a Logical Volume from linear to mirror or snapshot.
lvcreate — Create a Logical Volume in an existing Volume Group.
lvdisplay — Display attributes of a Logical Volume.
lvextend — Extend the size of a Logical Volume.
lvmchange — Change attributes of the Logical Volume Manager.
lvmdiskscan — Scan for all devices visible to LVM2.
lvmdump — Create lvm2 information dumps for diagnostic purposes.
lvreduce — Reduce the size of a Logical Volume.
lvremove — Remove a Logical Volume.
lvrename — Rename a Logical Volume.
lvresize — Resize a Logical Volume.
lvs — Report information about Logical Volumes.
lvscan — Scan (all disks) for Logical Volumes.
The following commands are not implemented in LVM2 but might be in the
future: lvmsadc, lvmsar, pvdata.
OPTIONS
The following options are available for many of the commands. They are
implemented generically and documented here rather than repeated on
individual manual pages.
-h, -?, --help
Display the help text.
--version
Display version information.
-v, --verbose
Set verbose level. Repeat from 1 to 3 times to increase the
detail of messages sent to stdout and stderr. Overrides config
file setting.
-d, --debug
Set debug level. Repeat from 1 to 6 times to increase the detail
of messages sent to the log file and/or syslog (if configured).
Overrides config file setting.
-q, --quiet
Suppress output and log messages. Overrides -d and -v.
--yes Don't prompt for confirmation interactively but instead always
assume the answer is 'yes'. Take great care if you use this!
-t, --test
Run in test mode. Commands will not update metadata. This is
implemented by disabling all metadata writing but nevertheless
returning success to the calling function. This may lead to
unusual error messages in multi-stage operations if a tool
relies on reading back metadata it believes has changed but
hasn't.
--driverloaded {y|n}
Whether or not the device-mapper kernel driver is loaded. If
you set this to n, no attempt will be made to contact the
driver.
-A, --autobackup {y|n}
Whether or not to metadata should be backed up automatically
after a change. You are strongly advised not to disable this!
See vgcfgbackup(8).
-P, --partial
When set, the tools will do their best to provide access to Vol‐
ume Groups that are only partially available (one or more Physi‐
cal Volumes belonging to the Volume Group are missing from the
system). Where part of a logical volume is missing, /dev/ioer‐
ror will be substituted, and you could use dmsetup(8) to set
this up to return I/O errors when accessed, or create it as a
large block device of nulls. Metadata may not be changed with
this option. To insert a replacement Physical Volume of the same
or large size use pvcreate -u to set the uuid to match the orig‐
inal followed by vgcfgrestore(8).
-M, --metadatatype Type
Specifies which type of on-disk metadata to use, such as lvm1 or
lvm2, which can be abbreviated to 1 or 2 respectively. The
default (lvm2) can be changed by setting format in the global
section of the config file.
--ignorelockingfailure
This lets you proceed with read-only metadata operations such as
lvchange -ay and vgchange -ay even if the locking module fails.
One use for this is in a system init script if the lock direc‐
tory is mounted read-only when the script runs.
--ignoreskippedcluster
Use to avoid exiting with an non-zero status code if the command
is run without clustered locking and some clustered Volume
Groups have to be skipped over.
--addtag Tag
Add the tag Tag to a PV, VG or LV. Supply this argument multi‐
ple times to add more than one tag at once. A tag is a word
that can be used to group LVM2 objects of the same type
together. Tags can be given on the command line in place of PV,
VG or LV arguments. Tags should be prefixed with @ to avoid
ambiguity. Each tag is expanded by replacing it with all
objects possessing that tag which are of the type expected by
its position on the command line. PVs can only possess tags
while they are part of a Volume Group: PV tags are discarded if
the PV is removed from the VG. As an example, you could tag
some LVs as database and others as userdata and then activate
the database ones with lvchange -ay @database. Objects can pos‐
sess multiple tags simultaneously. Only the new LVM2 metadata
format supports tagging: objects using the LVM1 metadata format
cannot be tagged because the on-disk format does not support it.
Characters allowed in tags are: A-Z a-z 0-9 _ + . - and as of
version 2.02.78 the following characters are also accepted: / =
! : # &
--deltag Tag
Delete the tag Tag from a PV, VG or LV, if it's present. Supply
this argument multiple times to remove more than one tag at
once.
--alloc {anywhere|contiguous|cling|inherit|normal}
Selects the allocation policy when a command needs to allocate
Physical Extents from the Volume Group. Each Volume Group and
Logical Volume has an allocation policy defined. The default
for a Volume Group is normal which applies common-sense rules
such as not placing parallel stripes on the same Physical Vol‐
ume. The default for a Logical Volume is inherit which applies
the same policy as for the Volume Group. These policies can be
changed using lvchange(8) and vgchange(8) or overridden on the
command line of any command that performs allocation. The con‐
tiguous policy requires that new Physical Extents be placed
adjacent to existing Physical Extents. The cling policy places
new Physical Extents on the same Physical Volume as existing
Physical Extents in the same stripe of the Logical Volume. If
there are sufficient free Physical Extents to satisfy an alloca‐
tion request but normal doesn't use them, anywhere will - even
if that reduces performance by placing two stripes on the same
Physical Volume.
--profile ProfileName
Selects the configuration profile to use when processing an LVM
command. In addition to that, when creating a Volume Group or a
Logical Volume, it causes the ProfileName to be stored in meta‐
data for each Volume Group or Logical Volume. If the profile is
stored in metadata, it is automatically applied next time the
Volume Group or the Logical Volume is processed and the use of
--profile is not necessary when running LVM commands further.
See also lvm.conf(5) for more information about profile config
and the way it fits with other LVM configuration methods.
--config ConfigurationString
Uses the ConfigurationString as direct string representation of
the configuration to override the existing configuration. The
ConfigurationString is of exactly the same format as used in any
LVM configuration file. See lvm.conf(5) for more information
about direct config override on command line and the way it fits
with other LVM configuration methods.
ENVIRONMENT VARIABLES
HOME Directory containing .lvm_history if the internal readline shell
is invoked.
LVM_SYSTEM_DIR
Directory containing lvm.conf(5) and other LVM system files.
Defaults to "/etc/lvm".
LVM_SUPPRESS_FD_WARNINGS
Suppress warnings about openned file descriptors, when lvm com‐
mand is executed.
LVM_VG_NAME
The Volume Group name that is assumed for any reference to a
Logical Volume that doesn't specify a path. Not set by default.
LVM_LVMETAD_PIDFILE
Path for the lvmetad pid file.
LVM_LVMETAD_SOCKET
Path for the lvmetad socket file.
VALID NAMES
The following characters are valid for VG and LV names: a-z A-Z 0-9 + _
. -
VG and LV names cannot begin with a hyphen. There are also various
reserved names that are used internally by lvm that can not be used as
LV or VG names. A VG cannot be called anything that exists in /dev/ at
the time of creation, nor can it be called '.' or '..'. A LV cannot be
called '.' '..' 'snapshot' or 'pvmove'. The LV name may also not con‐
tain the strings '_mlog', '_mimage', '_rimage', '_tdata', '_tmeta'.
ALLOCATION
When an operation needs to allocate Physical Extents for one or more
Logical Volumes, the tools proceed as follows:
First of all, they generate the complete set of unallocated Physical
Extents in the Volume Group. If any ranges of Physical Extents are
supplied at the end of the command line, only unallocated Physical
Extents within those ranges on the specified Physical Volumes are con‐
sidered.
Then they try each allocation policy in turn, starting with the
strictest policy (contiguous) and ending with the allocation policy
specified using --alloc or set as the default for the particular Logi‐
cal Volume or Volume Group concerned. For each policy, working from
the lowest-numbered Logical Extent of the empty Logical Volume space
that needs to be filled, they allocate as much space as possible
according to the restrictions imposed by the policy. If more space is
needed, they move on to the next policy.
The restrictions are as follows:
Contiguous requires that the physical location of any Logical Extent
that is not the first Logical Extent of a Logical Volume is adjacent to
the physical location of the Logical Extent immediately preceding it.
Cling requires that the Physical Volume used for any Logical Extent to
be added to an existing Logical Volume is already in use by at least
one Logical Extent earlier in that Logical Volume. If the configura‐
tion parameter allocation/cling_tag_list is defined, then two Physical
Volumes are considered to match if any of the listed tags is present on
both Physical Volumes. This allows groups of Physical Volumes with
similar properties (such as their physical location) to be tagged and
treated as equivalent for allocation purposes.
When a Logical Volume is striped or mirrored, the above restrictions
are applied independently to each stripe or mirror image (leg) that
needs space.
Normal will not choose a Physical Extent that shares the same Physical
Volume as a Logical Extent already allocated to a parallel Logical Vol‐
ume (i.e. a different stripe or mirror image/leg) at the same offset
within that parallel Logical Volume.
When allocating a mirror log at the same time as Logical Volumes to
hold the mirror data, Normal will first try to select different Physi‐
cal Volumes for the log and the data. If that's not possible and the
allocation/mirror_logs_require_separate_pvs configuration parameter is
set to 0, it will then allow the log to share Physical Volume(s) with
part of the data.
When allocating thin pool metadata, similar considerations to those of
a mirror log in the last paragraph apply based on the value of the
allocation/thin_pool_metadata_require_separate_pvs configuration param‐
eter.
If you rely upon any layout behaviour beyond that documented here, be
aware that it might change in future versions of the code.
For example, if you supply on the command line two empty Physical Vol‐
umes that have an identical number of free Physical Extents available
for allocation, the current code considers using each of them in the
order they are listed, but there is no guarantee that future releases
will maintain that property. If it is important to obtain a specific
layout for a particular Logical Volume, then you should build it up
through a sequence of lvcreate(8) and lvconvert(8) steps such that the
restrictions described above applied to each step leave the tools no
discretion over the layout.
To view the way the allocation process currently works in any specific
case, read the debug logging output, for example by adding -vvvv to a
command.
LOGICAL VOLUME TYPES
Some logical volume types are simple to create and can be done with a
single lvcreate(8) command. The linear and striped logical volume
types are an example of this. Other logical volume types may require
more than one command to create. The cache and thin provisioning types
are examples of this.
Cache
The cache logical volume type uses a small and fast LV to improve the
performance of a large and slow LV. It does this by storing the fre‐
quently used blocks on the faster LV. LVM refers to the small fast LV
as a cache pool LV. The large slow LV is called the origin LV. Due to
requirements from dm-cache (the kernel driver), LVM further splits the
cache pool LV into two devices - the cache data LV and cache metadata
LV. The cache data LV is where copies of data blocks are kept from the
origin LV to increase speed. The cache metadata LV holds the account‐
ing information that specifies where data blocks are stored (e.g. on
the origin LV or on the cache data LV). Users should be familiar with
these LVs if they wish to create the best and most robust cached logi‐
cal volumes.
Cache Terms
origin LV OriginLV large slow LV
cache data LV CacheDataLV small fast LV for cache pool data
cache metadata LV CacheMetaLV small fast LV for cache pool metadata
cache pool LV CachePoolLV CacheDataLV + CacheMetaLV
cache LV CacheLV OriginLV + CachePoolLV
Cache Steps
The steps to create a logical volume of cache type are as follows:
0. Create an LV or identify an existing LV to be the origin LV.
1. Create the cache data LV. The size of this LV is the size of
the cache and will be reported as the size of the cache pool LV.
2. Create the cache metadata LV. The size of this LV should be
1000 times smaller than the cache data LV with a minimum size of
8MiB.
3. Create the cache pool LV by combining the cache data LV (from
step 1) and cache metadata LV (from step 2). When performing
this step, behavioral characteristics of the cache pool LV can
be set. The name of the cache pool LV takes the name of the
cache data LV and the cache data LV and cache metadata LV are
renamed to CachePoolLV_cdata and CachePoolLV_cmeta.
4. Create a cache LV by linking the cache pool LV to the origin LV.
The user accessible cache LV takes the name of the origin LV,
while the origin LV becomes a hidden LV with the name
OriginLV_corig. Users can perform this step while the origin LV
is in use.
The steps above represent the best way to create a cache LV. They pro‐
vide the most options and have the ability to create the most robust
logical volumes. The examples below illustrate how these steps might
be used in practice.
Cache Commands
0. create OriginLV
lvcreate -L LargeSize -n OriginLV VG SlowPVs
1. create CacheDataLV
lvcreate -L CacheSize -n CacheDataLV VG FastPVs
2. create CacheMetaLV
lvcreate -L MetaSize -n CacheMetaLV VG FastPVs
3. create CachePoolLV
lvconvert --type cache-pool --poolmetadata VG/CacheMetaLV VG/CacheDataLV
CachePoolLV takes the name of CacheDataLV.
CacheDataLV is renamed CachePoolLV_cdata and becomes hidden.
CacheMetaLV is renamed CachePoolLV_cmeta and becomes hidden.
4. create CacheLV
lvconvert --type cache --cachepool VG/CachePoolLV VG/OriginLV
CacheLV takes the name of OriginLV.
OriginLV is renamed OriginLV_corig and becomes hidden.
Cache Examples
Example 1: Creating a simple cache LV.
0. Create the origin LV
# lvcreate -L 10G -n lvx vg /dev/slow_dev
1. Create a cache data LV
# lvcreate -L 1G -n lvx_cache vg /dev/fast_dev
2. Create a cache metadata LV (~1/1000th size of CacheDataLV or 8MiB)
# lvcreate -L 8M -n lvx_cache_meta vg /dev/fast_dev
3. Create a cache pool LV, combining cache data LV and cache metadata LV
# lvconvert --type cache-pool --poolmetadata vg/lvx_cache_meta \
vg/lvx_cache
4. Create a cached LV by combining the cache pool LV and origin LV
# lvconvert --type cache --cachepool vg/lvx_cache vg/lvx
Example 2: Creating a cache LV with a fault tolerant cache pool LV.
Users who are concerned about the possibility of failures in their fast
devices that could lead to data loss might consider making their cache
pool sub-LVs redundant. Example 2 illustrates how to do that. Note
that only steps 1 & 2 change.
0. Create an origin LV we wish to cache
# lvcreate -L 10G -n lvx vg /dev/slow_devs
1. Create a 2-way RAID1 cache data LV
# lvcreate --type raid1 -m 1 -L 1G -n lvx_cache vg \
/dev/fast1 /dev/fast2
2. Create a 2-way RAID1 cache metadata LV
# lvcreate --type raid1 -m 1 -L 8M -n lvx_cache_meta vg \
/dev/fast1 /dev/fast2
3. Create a cache pool LV combining cache data LV and cache metadata LV
# lvconvert --type cache-pool --poolmetadata vg/lvx_cache_meta \
vg/lvx_cache
4. Create a cached LV by combining the cache pool LV and origin LV
# lvconvert --type cache --cachepool vg/lvx_cache vg/lvx
Example 3: Creating a simple cache LV with writethough caching.
Some users wish to ensure that any data written will be stored both in
the cache pool LV and on the origin LV. The loss of a device associ‐
ated with the cache pool LV in this case would not mean the loss of any
data. When combining the cache data LV and the cache metadata LV to
form the cache pool LV, properties of the cache can be specified - in
this case, writethrough vs. writeback. Note that only step 3 is
affected in this case.
0. Create an origin LV we wish to cache (yours may already exist)
# lvcreate -L 10G -n lvx vg /dev/slow
1. Create a cache data LV
# lvcreate -L 1G -n lvx_cache vg /dev/fast
2. Create a cache metadata LV
# lvcreate -L 8M -n lvx_cache_meta vg /dev/fast
3. Create a cache pool LV specifying cache mode "writethrough"
# lvconvert --type cache-pool --poolmetadata vg/lvx_cache_meta \
--cachemode writethrough vg/lvx_cache
4. Create a cache LV by combining the cache pool LV and origin LV
# lvconvert --type cache --cachepool vg/lvx_cache vg/lvx
Removing Cache Logical Volumes
If you wish to remove all logical volumes associated with a cache LV,
you must remove both top-level, user-visible devices. The cache meta‐
data LV and cache data LV cannot be removed directly. If only the
cache pool LV is specfied for removal, any cached blocks not yet on the
origin LV will be flush, the cache pool LV will be removed, and the now
un-cached origin LV will remain. If the user specifies a cache LV for
removal, then the origin LV is removed and only the cache pool LV will
remain. The cache pool LV can then be used to create another cache LV
with a different origin LV if desired.
When users intend to remove all logical volumes associated with a cache
LV, it is generally better to start with the origin LV and then remove
the cache pool LV. If the operations are performed in the reverse
order, the user will have to wait for the contents of the cache pool LV
to be flushed before the origin LV is removed. This could take some
time.
DIAGNOSTICS
All tools return a status code of zero on success or non-zero on fail‐
ure.
FILES
/etc/lvm/lvm.conf
$HOME/.lvm_history
SEE ALSOlvm.conf(5), lvmdumpconfig(8), clvmd(8), lvchange(8), lvcreate(8),
lvdisplay(8), lvextend(8), lvmchange(8), lvmdiskscan(8), lvreduce(8),
lvremove(8), lvrename(8), lvresize(8), lvs(8), lvscan(8), pvchange(8),
pvck(8), pvcreate(8), pvdisplay(8), pvmove(8), pvremove(8), pvs(8),
pvscan(8), vgcfgbackup(8), vgchange(8), vgck(8), vgconvert(8), vgcre‐
ate(8), vgdisplay(8), vgextend(8), vgimport(8), vgimportclone(8),
vgmerge(8), vgmknodes(8), vgreduce(8), vgremove(8), vgrename(8),
vgs(8), vgscan(8), vgsplit(8), readline(3)Sistina Software UK LVM TOOLS 2.02.106(2) (2014-04-10) LVM(8)