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- 1 Introduction
- 2 Advantages
- 3 Installation
- 4 Configuration
- 5 Troubleshooting
- 6 Additional resources
LVM (Logical Volume Management) makes use of the device-mapper feature of the Linux kernel to provide a system of partitions that is independent of the underlying disk's layout. With LVM you can abstract your storage space and have "virtual partitions" which makes it easier to extend and shrink partitions (subject to the filesystem you use allowing this) and add/remove partitions without worrying about whether you have enough contiguous space on a particular disk, without getting caught up in the problems of fdisking a disk that is in use (and wondering whether the kernel is using the old or new partition table) and without having to move other partition out of the way. This is strictly an ease-of-management issue: it does not provide any addition security. However, it sits nicely with the other two technologies we are using.
Note that LVM is not used for the boot partition, because of the bootloader problem.
The basic building blocks of LVM are:
- Physical volume (PV): Partition on hard disk (or even hard disk itself or loopback file) on which you can have volume groups. It has a special header and is divided into physical extents. Think of physical volumes as big building blocks which can be used to build your hard drive.
- Volume group (VG): Group of physical volumes that are used as storage volume (as one disk). They contain logical volumes. Think of volume groups as hard drives.
- Logical volume (LV): A "virtual/logical partition" that resides in a volume group and is composed of physical extents. Think of logical volumes as normal partitions.
- Physical extent (PE): A small part of a disk (usually 4MB) that can be assigned to a logical Volume. Think of physical extents as parts of disks that can be allocated to any partition.
With LVM you can more easily handle your partitions (logical volumes) than normal hard drive partitions. For example, you can:
- Use any number of disks as one big disk(VG)
- Have partitions(LV) stretched over several disks (they can be as big as all of your disk storage together)
- Resize/create/delete partitions(LV) and disks(VG) as you like (it does not depend on position of the logical volumes within volume groups as with normal partitions)
- Resize/create/delete partitions(LV) and disks(VG) online (filesystems on them still need to be resized, but some support online resizing)
- Name your disks(VG) and partitions(LV) as you like
- Create small partitions(LV) and resize them "dynamically" as they get more filled (growing must be still done by hand, but you can do it online with some filesystems)
Physical disks Disk1 (/dev/sda): _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ |Partition1 50GB (Physical volume) |Partition2 80GB (Physical volume) | |/dev/sda1 |/dev/sda2 | |_ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ |_ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ | Disk2 (/dev/sdb): _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ |Partition1 120GB (Physical volume) | |/dev/sdb1 | | _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ __ _ _|
LVM logical volumes Volume Group1 (/dev/MyStorage/ = /dev/sda1 + /dev/sda2 + /dev/sdb1): _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ |Logical volume1 15GB |Logical volume2 35GB |Logical volume3 200GB | |/dev/MyStorage/rootvol|/dev/MyStorage/homevol |/dev/MyStorage/mediavol | |_ _ _ _ _ _ _ _ _ _ _ |_ _ _ _ _ _ _ _ _ _ _ _ _ |_ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ |
To sum it all up: With LVM you can use all your storage space as one big disk (volume group) and have more flexibility over your partitions (logical volumes).
Here are some things you can do with LVM that you cannot (or cannot do easily) with just mdadm, MBR partitions, GPT partitions, parted/gparted and a file-level tool like rsync.
- Online/live partition resizing
- No need for an extended partition (not relevant for GPT)
- Resize partitions regardless of their order on disk (no need to ensure surrounding available space)
- Online/live migration of partitions being used by services without having to restart services
These can be very helpful in a server situation, desktop less so, but you must decide if the features are worth the abstraction.
Before doing anything we need to load the appropriate module:
# modprobe dm-mod
If you already have Arch Linux installed and you just want to add/try a partition with LVM, jump to partition disks.
Installing Arch Linux on LVM
Prior to running Arch Linux install scripts (/arch/setup) to install Arch Linux, you need to partition your disk with
cfdisk (or any other tool of your liking). Because grub legacy (grub with version less than 1.0) cannot boot from LVM logical volumes you cannot have
/boot in LVM, so you need to create a boot partition. 100MB should be enough. The other solution would be to use lilo or grub with version 1.95 or newer.
Next you need to create a partition for LVM. Its filesystem type should be 'Linux LVM', so use a partition id 0x8e (filesystem type: 8e). You need to create only one LVM partition on each disk you want to use with LVM. Your logical volumes will reside inside these partitions so size them accordingly. If you will use only LVM and no other external partitions, use all the free space on each disk.
Create physical volumes
Now you need to initialize these partitions so they can be used by LVM. Use
fdisk -l to find out which partitions have filesystem type 'Linux LVM' and create a physical volume on them:
# pvcreate /dev/sda2
/dev/sda2 with all your partitions to create physical volumes on all of them. This command creates a header on each partition so it can be used for LVM.
You can track created physical volumes with:
pvcreate --dataalignment 1m /dev/sda2(for erase block size < 1MiB), see e.g. here
Create volume group
Next step is to create a volume group on this physical volume. First you need to create a volume group on one of the new partitions and then add to it all other physical volumes you want to have in it:
# vgcreate VolGroup00 /dev/sda2 # vgextend VolGroup00 /dev/sdb1
Also you can use any other name you like instead of VolGroup00 for a volume group when creating it. You can track how your volume group grows with:
Create logical volumes
Now we need to create logical volumes on this volume group. You create a logical volume with the next command by giving the name of a new logical volume, its size, and the volume group it will live on:
# lvcreate -L 10G VolGroup00 -n lvolhome
This will create a logical volume that you can access later with
/dev/VolGroup00/lvolhome. Same as with the volume groups, you can use any name you want for your logical volume when creating it.
To create swap on a logical volume, an additional argument is needed:
# lvcreate -C y -L 10G VolGroup00 -n lvolswap
-C y is used to create a contiguous partition, which means that your swap space does not get partitioned over one or more disks nor over non-contiguous physical extents.
If you want to fill all the free space left on a volume group, use the next command:
# lvcreate -l +100%FREE VolGroup00 -n lvolmedia
You can track created logical volumes with:
Create filesystems and mount logical volumes
Your logical volumes should now be located in
/dev/YourVolumeGroupName. If you cannot find them, use the next commands to bring up the module for creating device nodes and to make volume groups available:
# modprobe dm-mod # vgscan # vgchange -ay
Now you can create filesystems on logical volumes and mount them as normal partitions (if you are installing Arch linux, refer to mounting the partitions for additional details):
# mkfs.ext4 /dev/mapper/VolGroup00-lvolhome # mount /dev/mapper/VolGroup00-lvolhome /home
If you are installing Arch linux, start /arch/setup, go to Prepare Hard Drive directly to step 3 Set Filesystem Mountpoints and read the Important section below before proceeding with installation!
Set filesystem mountpoints
- When choosing mountpoints, just select your newly created logical volumes (use:
Do NOT select the actual partitions on which logical volumes were created (do not use:
For late-boot activation (non-root-filesystem) of volume groups, enable the
lvm unit file,
# systemctl enable lvm.service
If you are using LVM on an encrypted device, use this instead:
# systemctl enable lvm-on-crypt.service
Or, if you still use sysvinit, modify
For early-boot activation of volume groups (namely for root filesystem containers), you'll need to make sure the
udev mkinitcpio hooks are enabled.
HOOKS="base udev ... lvm2 filesystems"
Also make sure the
dm_mod module is enabled.
You will need to rebuild the initramfs to commit any changes you made.
In kernel options, you may need
Grow logical volume
To grow a logical volume you first need to grow the logical volume and then the filesystem to use the newly created free space. Let us say we have a logical volume of 15GB with ext3 on it and we want to grow it to 20G. We need to do the following steps:
# lvextend -L 20G VolGroup00/lvolhome (or lvresize -L +5G VolGroup00/lvolhome) # resize2fs /dev/VolGroup00/lvolhome
You may use
lvresize instead of
If you want to fill all the free space on a volume group, use the next command:
# lvextend -l +100%FREE VolGroup00/lvolhome
Shrink logical volume
Because your filesystem is probably as big as the logical volume it resides on, you need to shrink the filesystem first and then shrink the logical volume. Depending on your filesystem, you may need to unmount it first. Let us say we have a logical volume of 15GB with ext3 on it and we want to shrink it to 10G. We need to do the following steps:
# resize2fs /dev/VolGroup00/lvolhome 9G # lvreduce -L 10G VolGroup00/lvolhome (or lvresize -L -5G VolGroup00/lvolhome) # resize2fs /dev/VolGroup00/lvolhome
Here we shrunk the filesystem more than needed so that when we shrunk the logical volume we did not accidentally cut off the end of the filesystem. After that we normally grow the filesystem to fill all free space left on logical volume. You may use
lvresize instead of
- Do not reduce the filesystem size to less than the amount of space occupied by data or you risk data loss.
- Not all filesystems support shrinking without loss of data and/or shrinking online.
Remove logical volume
First, find out the name of the logical volume you want to remove. You can get a list of all logical volumes installed on the system with:
Next, look up the mountpoint for your chosen logical volume...:
$ df -h
... and unmount it:
# umount /your_mountpoint
Finally, remove the logical volume:
# lvremove /dev/yourVG/yourLV
Confirm by typing Template:Keypress and you are done.
Do not forget, to update
You can verify the removal of your logical volume by typing "lvs" as root again (see first step of this section).
Add physical volume to a volume group
You first create a new physical volume on the block device you wish to use, then extend your volume group
# pvcreate /dev/sdb1 # vgextend VolGroup00 /dev/sdb1
This of course will increase the total number of physical extents on your volume group, which can be allocated by logical volumes as you see fit.
8efor MBR, and
8e00for GPT partitions.
Remove partition from a volume group
All of the data on that partition needs to be moved to another partition. Fortunately, LVM makes this easy:
# pvmove /dev/sdb1
If you want to have the data on a specific physical volume, specify that as the second argument to
# pvmove /dev/sdb1 /dev/sdf1
Then the physical volume needs to be removed from the volume group:
# vgreduce myVg /dev/sdb1
Or remove all empty physical volumes:
# vgreduce --all vg0
And lastly, if you want to use the partition for something else, and want to avoid LVM thinking that the partition is a physical volume:
# pvremove /dev/sdb1
LVM allows you to take a snapshot of your system in a much more efficient way than a traditional backup. It does this efficiently by using a COW (copy-on-write) policy. The initial snapshot you take simply contains hard-links to the inodes of your actual data. So long as your data remains unchanged, the snapshot merely contains its inode pointers and not the data itself. Whenever you modify a file or directory that the snapshot points to, LVM automatically clones the data, the old copy referenced by the snapshot, and the new copy referenced by your active system. Thus, you can snapshot a system with 35GB of data using just 2GB of free space so long as you modify less than 2GB (on both the original and snapshot).
You create snapshot logical volumes just like normal ones.
# lvcreate --size 100M --snapshot --name snap01 /dev/mapper/vg0-pv
With that volume, you may modify less than 100M of data, before the snapshot volume fills up.
It is important to have the dm-snapshot module listed in the MODULES variable of
/etc/mkinitcpio.conf, otherwise the system will not boot. If you do this on an already installed system, make sure to rebuild the image with
# mkinitcpio -g /boot/initramfs-linux.img
Todo: scripts to automate snapshots of root before updates, to rollback... updating
menu.lst to boot snapshots (separate article?)
snapshots are primarily used to provide a frozen copy of a filesystem to make backups; a backup taking two hours provides a more consistent image of the filesystem than directly backing up the partition.
LVM commands do not work
- Load proper module:
# modprobe dm_mod
- Try preceding commands with lvm like this:
# lvm pvdisplay
Set filesystem mountpoints page does not show logical volumes
If you are installing on a system where there is an existing volume group, you may find that even after doing "modprobe dm-mod" you do not see the list of logical volumes.
In this case, you may also need to do:
# vgchange -ay <volgroup>
in order to activate the volume group and make the logical volumes available.
LVM on removable media
~$ sudo vgscan Reading all physical volumes. This may take a while... /dev/backupdrive1/backup: read failed after 0 of 4096 at 319836585984: Input/output error /dev/backupdrive1/backup: read failed after 0 of 4096 at 319836643328: Input/output error /dev/backupdrive1/backup: read failed after 0 of 4096 at 0: Input/output error /dev/backupdrive1/backup: read failed after 0 of 4096 at 4096: Input/output error Found volume group "backupdrive1" using metadata type lvm2 Found volume group "networkdrive" using metadata type lvm2
- Removing an external LVM drive without deactivating the volume group(s) first. Before you disconnect, make sure to:
# vgchange -an <volume group name>
Fix: (assuming you already tried to activate the volume group with vgchange -ay <vg>, and are receiving the Input/output errors
# vgchange -an <volume group name>
- Unplug the external drive and wait a few minutes
# vgscan # vgchange -ay <volume group name>