.TH LVCREATE 8 "LVM TOOLS #VERSION#" "Sistina Software UK" \" -*- nroff -*- .SH NAME lvcreate \- create a logical volume in an existing volume group .SH SYNOPSIS .B lvcreate .RB [ \-\-addtag .IR Tag ] .RB [ \-\-alloc .IR AllocationPolicy ] .RB [ \-a | \-\-activate .RI [ a | e | l ]{ y | n }] .RB [ \-A | \-\-autobackup .RI { y | n }] .RB [ \-C | \-\-contiguous .RI { y | n }] .RB [ \-d | \-\-debug ] .RB [ \-h | \-? | \-\-help ] .RB [ \-\-noudevsync ] .RB [ \-\-ignoremonitoring ] .RB [ \-\-monitor .RI { y | n }] .RB [ \-i | \-\-stripes .IR Stripes .RB [ \-I | \-\-stripesize .IR StripeSize ]] .RB {[ \-l | \-\-extents .IR LogicalExtentsNumber [ % { VG | PVS | FREE }] | .BR \-L | \-\-size .IR LogicalVolumeSize [ bBsSkKmMgGtTpPeE ]] | .BR \-V | \-\-virtualsize .IR VirtualSize [ bBsSkKmMgGtTpPeE ]} .RB [ \-M | \-\-persistent .RI { y | n }] .RB [ \-\-minor .IR minor ] .RB [ \-m | \-\-mirrors .IR Mirrors .RB [ \-\-nosync ] .RB [ \-\-mirrorlog .RI { disk | core | mirrored } | .BR \-\-corelog ] .RB [ \-R | \-\-regionsize .IR MirrorLogRegionSize ]] .RB [ \-n | \-\-name .IR LogicalVolume { Name | Path }] .RB [ \-p | \-\-permission .RI { r | rw }] .RB [ \-r | \-\-readahead .RI { ReadAheadSectors | auto | none }] .RB [ \-t | \-\-test ] .RB [ \-T | \-\-thin .RB [ \-c | \-\-chunksize .IR ChunkSize ] .RB [ \-\-discards .RI { ignore | nopassdown | passdown }] .RB [ \-\-poolmetadatasize .IR MetadataSize [ bBsSkKmMgG ]]] .RB [ \-\-thinpool .IR ThinPoolLogicalVolume { Name | Path }] .RB [ \-\-type .IR SegmentType ] .RB [ \-v | \-\-verbose ] .RB [ \-Z | \-\-zero .RI { y | n }] .IR VolumeGroup { Name | Path }[/ ThinPoolLogicalVolumeName ] .RI [ PhysicalVolumePath [ :PE [ -PE ]]...] .br .B lvcreate .RB [ \-l | \-\-extents .IR LogicalExtentsNumber [ % { VG | FREE | ORIGIN }] | .BR \-L | \-\-size .IR LogicalVolumeSize [ bBsSkKmMgGtTpPeE ]] .RB [ \-c | \-\-chunksize .IR ChunkSize ] .RB [ \-\-noudevsync ] .RB [ \-\-ignoremonitoring ] .RB [ \-\-monitor " {" \fIy | \fIn }] .RB [ \-n | \-\-name .IR SnapshotLogicalVolume { Name | Path }] .BR \-s | \-\-snapshot .RI {[ VolumeGroup { Name | Path }/] OriginalLogicalVolumeName .BR \-V | \-\-virtualsize .IR VirtualSize [ bBsSkKmMgGtTpPeE ]} .br .SH DESCRIPTION lvcreate creates a new logical volume in a volume group (see .BR vgcreate "(8), " vgchange (8)) by allocating logical extents from the free physical extent pool of that volume group. If there are not enough free physical extents then the volume group can be extended (see .BR vgextend (8)) with other physical volumes or by reducing existing logical volumes of this volume group in size (see .BR lvreduce (8)). If you specify one or more PhysicalVolumes, allocation of physical extents will be restricted to these volumes. .br .br The second form supports the creation of snapshot logical volumes which keep the contents of the original logical volume for backup purposes. .SH OPTIONS See .BR lvm (8) for common options. .TP .IR \fB\-a ", " \fB\-\-activate " {" y | ay | n | ey | en | ly | ln } Controls the availability of the Logical Volumes for immediate use after the command finishes running. By default, new Logical Volumes are activated (\fB-a\fIy\fR). If it is possible technically, \fB-a\fIn\fR will leave the new Logical Volume inactive. But for example, snapshots can only be created in the active state so \fB\-a\fIn\fR cannot be used with \fB\-\-snapshot\fP. Normally the \fB\-\-zero n\fP argument has to be supplied too because zeroing (the default behaviour) also requires activation. If autoactivation option is used (\fB\-a\fIay\fR), the logical volume is activated only if it matches an item in the activation/auto_activation_volume_list set in lvm.conf. For autoactivated logical volumes, \fB\-\-zero n\fP is always assumed and it can't be overridden. If clustered locking is enabled, \fB\-a\fIey\fR will activate exclusively on one node and \fB\-a\fIly\fR will activate only on the local node. .TP .BR \-c ", " \-\-chunksize " " \fIChunkSize Gives the size of chunk for snapshot and thin pool logical volumes. For snapshots the value must be power of 2 between 4KiB and 512KiB and the default value is 4. For thin pools the value must be power of 2 between 64KiB and 1048576KiB and the default value starts with 64 and scales up to fit the pool metadata size within 128MB, if the poolmetadata size is not specified. Default unit is in kilobytes. .TP .BR \-C ", " \-\-contiguous " {" \fIy | \fIn } Sets or resets the contiguous allocation policy for logical volumes. Default is no contiguous allocation based on a next free principle. .TP .BR \-\-discards " {" \fIignore | \fInopassdown | \fIpassdown } Set discards behavior. Default is \fIpassdown\fP. .TP .BR \-i ", " \-\-stripes " " \fIStripes Gives the number of stripes. This is equal to the number of physical volumes to scatter the logical volume. .TP .BR \-I ", " \-\-stripesize " " \fIStripeSize Gives the number of kilobytes for the granularity of the stripes. .br StripeSize must be 2^n (n = 2 to 9) for metadata in LVM1 format. For metadata in LVM2 format, the stripe size may be a larger power of 2 but must not exceed the physical extent size. .TP .IR \fB\-l ", " \fB\-\-extents " " LogicalExtentsNumber [ % { VG | PVS | FREE | ORIGIN }] Gives the number of logical extents to allocate for the new logical volume. The number can also be expressed as a percentage of the total space in the Volume Group with the suffix \fI%VG\fR, as a percentage of the remaining free space in the Volume Group with the suffix \fI%FREE\fR, as a percentage of the remaining free space for the specified PhysicalVolume(s) with the suffix \fI%PVS\fR, or (for a snapshot) as a percentage of the total space in the Origin Logical Volume with the suffix \fI%ORIGIN\fR. .TP .IR \fB\-L ", " \fB\-\-size " " LogicalVolumeSize [ bBsSkKmMgGtTpPeE ] Gives the size to allocate for the new logical volume. A size suffix of \fIK\fR for kilobytes, \fIM\fR for megabytes, \fIG\fR for gigabytes, \fIT\fR for terabytes, \fIP\fR for petabytes or \fIE\fR for exabytes is optional. .br Default unit is megabytes. .TP .B \-\-minor \fIminor Set the minor number. .TP .IR \fB\-M ", " \fB\-\-persistent " {" y | n } Set to y to make the minor number specified persistent. .TP .BR \-m ", " \-\-mirrors " " \fIMirrors Creates a mirrored logical volume with Mirrors copies. For example, specifying "-m 1" would result in a mirror with two-sides; that is, a linear volume plus one copy. Specifying the optional argument --nosync will cause the creation of the mirror to skip the initial resynchronization. Any data written afterwards will be mirrored, but the original contents will not be copied. This is useful for skipping a potentially long and resource intensive initial sync of an empty device. The optional argument --mirrorlog specifies the type of log to be used. The default is disk, which is persistent and requires a small amount of storage space, usually on a separate device from the data being mirrored. Using core means the mirror is regenerated by copying the data from the first device again each time the device is activated, for example, after every reboot. Using "mirrored" will create a persistent log that is itself mirrored. The optional argument --corelog is equivalent to --mirrorlog core. .TP .IR \fB\-n ", " \fB\-\-name " " LogicalVolume { Name | Path } The name for the new logical volume. .br Without this option a default names of "lvol#" will be generated where # is the LVM internal number of the logical volume. .TP .B \-\-noudevsync Disable udev synchronisation. The process will not wait for notification from udev. It will continue irrespective of any possible udev processing in the background. You should only use this if udev is not running or has rules that ignore the devices LVM2 creates. .TP .BR \-\-monitor " {" \fIy | \fIn } Start or avoid monitoring a mirrored or snapshot logical volume with dmeventd, if it is installed. If a device used by a monitored mirror reports an I/O error, the failure is handled according to \fBmirror_image_fault_policy\fP and \fBmirror_log_fault_policy\fP set in \fBlvm.conf\fP. .TP .B \-\-ignoremonitoring Make no attempt to interact with dmeventd unless \-\-monitor is specified. .TP .BR \-p ", " \-\-permission " {" \fIr | \fIrw } Set access permissions to read only or read and write. .br Default is read and write. .TP .IR \fB\-\-poolmetadatasize " " MetadataSize [ bBsSkKmMgG ] Set the size of thin pool's metadata logical volume. Supported value is in range between 2MiB and 16GiB. Default value is (Pool_LV_size / Pool_LV_chunk_size * 64b). Default unit is megabytes. .TP .IR \fB\-r ", " \fB\-\-readahead " {" ReadAheadSectors | auto | none } Set read ahead sector count of this logical volume. For volume groups with metadata in lvm1 format, this must be a value between 2 and 120. The default value is "auto" which allows the kernel to choose a suitable value automatically. "None" is equivalent to specifying zero. .TP .BR \-R ", " \-\-regionsize " " \fIMirrorLogRegionSize A mirror is divided into regions of this size (in MB), and the mirror log uses this granularity to track which regions are in sync. .TP .IR \fB\-s ", " \fB\-\-snapshot " " OriginalLogicalVolume { Name | Path } Create a snapshot logical volume (or snapshot) for an existing, so called original logical volume (or origin). Snapshots provide a 'frozen image' of the contents of the origin while the origin can still be updated. They enable consistent backups and online recovery of removed/overwritten data/files. Thin snapshot is created when the origin is a thin volume and the size is not specified. Thin snapshot shares same blocks within the thin pool volume. The snapshot with the specified size does not need the same amount of storage the origin has. In a typical scenario, 15-20% might be enough. In case the snapshot runs out of storage, use .BR lvextend (8) to grow it. Shrinking a snapshot is supported by .BR lvreduce (8) as well. Run .BR lvdisplay (8) on the snapshot in order to check how much data is allocated to it. Note that a small amount of the space you allocate to the snapshot is used to track the locations of the chunks of data, so you should allocate slightly more space than you actually need and monitor the rate at which the snapshot data is growing so you can avoid running out of space. .TP .IR \fB\-T ", " \fB\-\-thin ", " \fB\-\-thinpool " " ThinPoolLogicalVolume { Name | Path } Creates thin pool or thin logical volume or both. Specifying the optional argument \fB\-\-size\fP will cause the creation of the thin pool logical volume. Specifying the optional argument \fB\-\-virtualsize\fP will cause the creation of the thin logical volume from given thin pool volume. Specifying both arguments will cause the creation of both thin pool and thin volume using this pool. Requires device mapper kernel driver for thin provisioning from kernel 3.2 or newer. .TP .B \-\-type \fISegmentType Create a logical volume that uses the specified segment type (e.g. "raid5", "mirror", "snapshot", "thin", "thin-pool"). Many segment types have a commandline switch alias that will enable their use (\fB\-s\fP is an alias for \fB\-\-type snapshot\fP). However, this argument must be used when no existing commandline switch alias is available for the desired type, as is the case with .IR error ", " zero ", " raid1 ", " raid4 ", " raid5 " or " raid6 . .TP .BR \-V ", " \-\-virtualsize " " \fIVirtualSize [ \fIbBsSkKmMgGtTpPeE ] Create a sparse device of the given size (in MB by default) using a snapshot or thinly provisioned device when thin pool is specified. Anything written to the device will be returned when reading from it. Reading from other areas of the device will return blocks of zeros. Virtual snapshot is implemented by creating a hidden virtual device of the requested size using the zero target. A suffix of _vorigin is used for this device. .TP .BR \-Z ", " \-\-zero " {" \fIy | \fIn } Controls zeroing of the first KB of data in the new logical volume. .br Default is yes. .br Volume will not be zeroed if read only flag is set. .br Snapshot volumes are zeroed always. .br Warning: trying to mount an unzeroed logical volume can cause the system to hang. .SH Examples Creates a striped logical volume with 3 stripes, a stripesize of 8KB and a size of 100MB in the volume group named vg00. The logical volume name will be chosen by lvcreate: .sp .B lvcreate \-i 3 \-I 8 \-L 100M vg00 Creates a mirror logical volume with 2 sides with a useable size of 500 MiB. This operation would require 3 devices (or option --alloc anywhere) - two for the mirror devices and one for the disk log: .sp .B lvcreate \-m1 \-L 500M vg00 Creates a mirror logical volume with 2 sides with a useable size of 500 MiB. This operation would require 2 devices - the log is "in-memory": .sp .B lvcreate \-m1 \-\-mirrorlog core \-L 500M vg00 Creates a snapshot logical volume named /dev/vg00/snap which has access to the contents of the original logical volume named /dev/vg00/lvol1 at snapshot logical volume creation time. If the original logical volume contains a file system, you can mount the snapshot logical volume on an arbitrary directory in order to access the contents of the filesystem to run a backup while the original filesystem continues to get updated: .sp .B lvcreate \-\-size 100m \-\-snapshot \-\-name snap /dev/vg00/lvol1 Creates a sparse device named /dev/vg1/sparse of size 1TiB with space for just under 100MiB of actual data on it: .sp .B lvcreate \-\-virtualsize 1T \-\-size 100M \-\-snapshot \-\-name sparse vg1 Creates a linear logical volume "vg00/lvol1" using physical extents /dev/sda:0-7 and /dev/sdb:0-7 for allocation of extents: .sp .B lvcreate \-L 64M -n lvol1 vg00 /dev/sda:0\-7 /dev/sdb:0\-7 Creates a 5GiB RAID5 logical volume "vg00/my_lv", with 3 stripes (plus a parity drive for a total of 4 devices) and a stripesize of 64KiB: .sp .B lvcreate \-\-type raid5 \-L 5G \-i 3 \-I 64 \-n my_lv vg00 Creates 100MiB pool logical volume for thin provisioning build with 2 stripes 64KiB and chunk size 128KiB together with 1TiB thin provisioned logical volume "vg00/thin_lv": .sp .B lvcreate \-i 2 \-I 64 \-c 256 \-L100M \-T vg00/pool \-V 1T \-\-name thin_lv .SH SEE ALSO .BR lvm (8), .BR vgcreate (8), .BR lvchange (8), .BR lvremove (8), .BR lvrename (8) .BR lvextend (8), .BR lvreduce (8), .BR lvdisplay (8), .BR lvscan (8)