Setting up disks manually
Alpine Linux can be installed and run in following three modes using setup-disk
script. For traditional or classic harddisk install, refer System Disk Mode Installation.
Diskless Mode
In Diskless mode the entire operating system with all applications are first loaded into RAM and then only run from there. This is the method already used to boot the .iso installation images, however setup-alpine
can also configure the installed system to continue to boot like this if "disk=none" is specified. The mode is extremely fast and can save on unnecessary disk spin-ups, power, and wear. It is similar to what other linux distributions may call a "frugal" install or boot into with a "toram" option.
Custom configurations and package installations may optionally still be preserved or "persist" across reboots by using the Alpine local backup tool lbu
. It enables committing and reverting system states by using .apkovl files that are saved to writable storage and loaded when booting. If additional or updated packages have been added to the system, these may also be made available for automatic (re)installation during the boot phase without any (re)downloading, by enabling a local package cache on the writable storage.
Diskless Mode Installation
Following the Installation steps to complete the base configuration completes the pre-setup of "diskless" Alpine Linux system.
If a writable partition is available, setup-alpine
can be told to store the configs and the package cache on that writable partition. (Later, another directory on that same partition or another available partition may also be mounted as /home, or for example, for selected important applications to keep their run-time and user data on it.)
Alternately, use the setup-lbu
script to configure a "local backup" location for the diskless system, and lbu commit
to then save the local configuration state.
The boot device of the newly configured local "diskless" system may remain the initial (and possibly read-only) installation media. But it is also possible to copy the boot system to a partition (e.g. /dev/sdXY) with setup-bootable
. Refer Creating a bootable device for creating a bootable medium to boot the Diskless Mode Installation of your Alpine Linux.
This requires some manual steps, as the setup-scripts auto-detect usable partitions only on removable devices (not internal harddisks). They do not support creating new, writable partitions to be used by Alpine. To prepare writable storage refer manual partitioning.
Refer Saving and loading ISO image customizations related to loading an .apkovl volume from system partitions.
As per Issue #10473 Storing local configs and the package cache on internal disks requires manual steps}} to have the partition listed, i.e. making a /etc/fstab entry, mountpoint, and mount, *before* running setup-alpine. The linked workaround also still requires to commit these configurations to disk manually before rebooting.]
- Be aware of this Bug: #11589. The APKOVL loading of diskless setups doesn't work on btrfs and xfs filesystems, or nvme-based devices => So, for the moment, use only ext4 filesystem partitions on classic drives to store diskless mode states.
- The following creates an ext4 partition with disabled journaling, to reduce write operations and allow the disk to spin down after the .apkovl and the packages have been read from the partition during the boot.
# mkfs.ext4 -O ^has_journal /dev/sdXY # the "-O ^has_journal" DISABLES journaling ("^" means "not")
Data Disk Mode
In Data Disk mode also the operating system runs from system RAM, thus it enjoys the same accelerated operation speed as "diskless" mode. However, swap storage and the entire /var directory tree get mounted from a persistent storage device (two newly created partitions). The directory /var holds e.g. all log files, mailspools, databases, etc., as well as lbu
backup commits and the package cache. This mode is useful for having RAM accelerated servers with variable amounts of user-data that exceed the available RAM size. It enables the entire current system state (not just the boot state) to survive a system crash in accordance with the particular filesystem guarantees.
Data Disk Mode Installation
Following the Installation steps to complete the base configuration completes the pre-setup of "diskless" Alpine Linux system. In data disk mode, the boot device may also remain the initial (and possibly read-only) installation media, or be copied to a partition (e.g. /dev/sdXY) with setup-bootable
. Refer Creating a bootable device for creating a bootable medium to boot the Data Disk Mode Installation.
As per Issue #10474 Setup-alpine will create the data partition and mount it as /var, but setup-alpine's "data" disk mode can not yet configure lbu config storage settings automatically. The current workaround, is to select "none" at the 'where to store configs' prompt (as the new data partition is not listed anyway) and configure lbu manually after setup-alpine
exits, and before rebooting:
- Identify the created data partition, e.g.
/dev/sdXY
, and its filesystemtype, e.g. usinglsblk
- Manually edit the lbu backups location in
/etc/lbu/lbu.conf
and configureLBU_MEDIA=sdXY
(according to the previous findings). - Save the configuration on that partition for the next boot with
lbu commit
. - If (a new) partition fails to get mounted, execute:
mkdir /media/sdXY ; echo "/dev/sdXY /media/sdXY fstype noauto,rw 0 0" >> /etc/fstab
, and trylbu commit
again.
System Disk Mode
System Disk Mode is the traditional harddisk installation. This is the mode suitable for most use cases including generic desktop, development machines etc..
System Disk Mode Installation
If entire hard disk(s) is available for Alpine Linux and default layout is sufficient, using setup-alpine
script with optional environment variables is the quickest and easiest way to install Alpine Linux. Refer custom layout for all other use cases.
Environment variables
The optional environment variables can be called either by setup-alpine
script at the beginning of Installation or by setup-disk
script later.
- BOOTFS - The filesystem to use on /boot, defaults to ext4, also allows ext2, ext3, (flat) btrfs, xfs and vfat (required on UEFI).
- BOOTLOADER - Bootloader to use. Defaults to syslinux, but also allows using grub, unless UEFI is used, in which case grub is required.
- BOOTSIZE - The size of /boot.
- DISKLABEL - The type of partition table to use. Defaults to dos, but also allows using gpt, unless UEFI is used, in which case gpt is required.
- ROOTFS - The filesystem to use on /, defaults to ext4, also allows ext2, ext3, (flat) btrfs and xfs.
- USE_EFI - Enable this to force using UEFI.
Environment variables can be combined. For e.g, the following command creates 512MB /boot partition on the selected hard disk, with vfat filesystem and uses grub
as bootloader. The disk will set to use gpt partition table.
# USE_EFI=1 BOOTSIZE=512 setup-alpine
Default Layout
All existing partitions on the chosen hard disk(s) are deleted by setup-disk
and it creates 3 partitions i.e (/)root partition, a /boot partition and a swap partition. The manual pages of setup-disk
refers this as DISKDEV mode.
The setup-alpine
script based installation supports only default layout.
When setup-disk
is called and multiple hard disks are selected, then setup-disk
sets them up in a RAID array. If there are more than 2 disks, then raid level 5 is used instead of RAID level 1.
Custom Layout
To perform a traditional hard-disk installation of Alpine Linux without any constraints, setup-disk
must be called with a MOUNTPOINT. setup-disk
will then perform a traditional harddisk or System Disk mode install with MOUNTPOINT as root.
To install Alpine Linux using custom layout follow the Installation guide to complete the base configuration. If necessary partition(s) are unavailable, manually create, format and mount them on a mount point i.e say /mnt or any other as follows:
# mount /dev/sdXY /mnt
If you're using EFI, make sure you create a mount point /mnt/boot
.
# mkdir -p /mnt/boot
Find the correct partition name for esp
partition and mount it on the above mount point :
# mount /dev/sdXY /mnt/boot
If swap partition is available, you can also enable it now:
# swapon /dev/sdXY
Additional partitions like /home, /var etc can be created and mounted on the mountpoint(/mnt).
Then install Alpine Linux using the following command:
# setup-disk -m sys /mnt
setup-disk
will install Alpine Linux system on the mounted root, uses the filesystem used during [#Formatting_partitions|formatting]] step and generates /etc/fstab automatically and also installs an appropriate bootloader. In most cases, you can just reboot to boot into newly installed Alpine Linux. You can also choose to customize further.
Manual partitioning
Partitioning tools
The installation image enviroment may have only the very basic busybox built-in fdisk
command available. Busybox `fdisk` is rather limited for edit operations. Instead, alpine allows you to install more complete partitioning tool packages like sfdisk
(scriptable fdisk), gptfdisk
, parted
(CLI), cfdisk
(text menus), or even gparted
(after setting up a graphical environment).
These tools can be installed even during Installation immediately after setting up base configuration.
cfdisk
will be used in all examples here as it is based on text menu without any dependencies:
The following step installs cfdisk
:
# apk add cfdisk
Creating partitions
cfdisk
will be used to create partitions. Before using cfdisk
, the disk name must be identified by using blkid
:
# blkid
/dev/sdX1: LABEL="some" UUID="..." TYPE="vfat" /dev/sdX2: LABEL="other" UUID="..." TYPE="ext4"
When cfdisk
is run as follows, it looks for existing partitions on the disk /dev/sdX :
# cfdisk /dev/sdX
For Alpine Linux, only the (/)root partition is mandatory to. Even a /boot partition and swap are optional, when using
Resizing an existing partition
cfdisk
and resize2fs
can be used to resize existing partitions of ext2/3/4 filsystem on the disk. For other filsystems, the necessary filesystem tools must be installed. This can be done while booted.
To resize disk, launch the cfdisk
:
# cfdisk /dev/sda
- Select the target partition, here as per image /dev/sda3
- Select Resize from the bottom menu.
- Enter the new Size at the prompt.
- Select Write, then Quit
If a filesystem is resized with -f (online mode), then the system must be rebooted immediately after the change is made.
# resize2fs -f /dev/sda3 # reboot
Formatting partitions
Install the necessary filesystem tools to format the newly created partitions. Refer the filesystem page for the choices available in Alpine Linux.
Disk layouts
This material is work-in-progress ... This entire section including RAID, Encryption and LVM needs to be updated. |
It is possible to have one or more of RAID, encrypted, and/or Logical Volume on your / (root) volume. However, the Alpine init script only knows how to handle them when they're layered in that order, and your initram and extlinux.conf files in the /boot partition are configured properly.
Your /boot directory cannot reside on an encrypted or LVM volume, at least not with Alpine's default bootloader (extlinux). (Grub2 can deal with /boot being on an LVM volume.) The usual practice is to create a small partition for /boot, then devote the rest of your disk to a separate partition on which you layer one or more of RAID, encryption, and/or Logical Volumes.
Sometimes /boot is also set up as a mirrored (RAID1) volume. However, this is just for post-init access. That way, when you write a new kernel or bootloader config file to /boot, it gets written to multiple physical partitions. During the pre-init, bootloader phase, only one of those partitions will be read from.
A typical setup might look like this:
One-disk system --------------- +------------------------------------------------+ | small partition (32--100M), holding | | only /boot, filesystem needn't be journaled | +------------------------------------------------+ | rest of disk in second partition | | +------------------------------------------+ | | | cryptsetup volume | | | | +-------------------------------------+ | | | | | LVM PV, containing single VG, | | | | | | containing multiple LVs, holding | | | | | | /, /home, swap, etc | | | | | +-------------------------------------+ | | | +------------------------------------------+ | +------------------------------------------------+ Two-disk system --------------- +------------------------------------------------+ +------------------------------------------------+ | small partition (32--100M), holding | | small partition (32--100M), holding | These 2 partitions might | only /boot, filesystem needn't be journaled | | only /boot, filesystem needn't be journaled | form a mirrored (RAID1) +------------------------------------------------+ +------------------------------------------------+ volume | rest of disk in second partition | | rest of disk in second partition | | T================================================================================================T | These 2 partitions form | T +--------------------------------------------------------------------------------------------+ T | a second mirrored | T | cryptsetup volume | T | (RAID1) volume | T | +---------------------------------------------------------------------------------------+ | T | | T | | LVM PV, containing single VG, | | T | | T | | containing multiple LVs, holding | | T | | T | | /, /home, swap, etc | | T | | T | +---------------------------------------------------------------------------------------+ | T | | T +--------------------------------------------------------------------------------------------+ T | | T================================================================================================T | | | | | +------------------------------------------------+ +------------------------------------------------+
In a three-disk system, the /boot would still be RAID1, but the larger partition might, in that case, be RAID5.
RAID
setup-disk
will automatically build a RAID array if you supply the -r switch, or if you specify more than one device.
If you want to build your RAID array manually, see Setting up a software RAID array. Then you can add additional layers of encryption and/or Logical Volumes, or just assemble the RAID array, and supply the /dev/mdi device directly to setup-disk. When you're finished, be sure to disassemble the RAID array before rebooting.
If setup-disk
sees that you're using RAID, either because you gave it the -r
switch, or multiple devices, or a /dev/mdi device, then it will set up your initramfs and extlinux.conf file properly. However, in other cases, such as when you're also using encryption, or you invoke setup-disk
with a mounted directory argument, these might not be properly set up for RAID. In that case, you may need to manually edit/rebuild them. The following assumes that $MNT
holds the root directory you're installing into:
echo "/sbin/mdadm" > $MNT/etc/mkinitfs/files.d/raid echo "/etc/mdadm.conf" >> $MNT/etc/mkinitfs/files.d/raid # edit $MNT/etc/mkinitfs/mkinitfs.conf to make sure features="..." # includes raid (this field is space-separated and quoted) mkinitfs -c $MNT/etc/mkinitfs/mkinitfs.conf -b $MNT # edit $MNT/etc/update-extlinux.conf to make sure modules=... contains # raid1 or raid456 (whichever your / is on; this field is comma-separated) # also check the root= setting extlinux --raid --install $MNT/boot --update
--update
option to extlinux ...
suffice to make /boot/extlinux.conf be regenerated? Or do we need to manually tweak that file, or run update-extlinux
, as well?
You might also need to manually tweak $MNT/etc/fstab. And you might need to copy /usr/share/syslinux/mbr.bin to your disk's MBR.
Encryption
See Setting up encrypted volumes with LUKS. You can add an additional Logical Volume layer, or just unlock the volume you've created (using cryptsetup luksOpen ...
), and supply the /dev/mapper/something device directly to setup-disk. When you're finished, be sure to relock the volume (using cryptsetup luksClose ...
) before rebooting.
If you install your / (root) on an encrypted volume, you'll need to manually edit/rebuild your initram and your extlinux.conf file. The following assumes that $MNT
holds the root directory you're installing into, that you've created the cryptvolume on the device /dev/md2, and that you want to unlock the encrypted volume into a virtual volume named "crypt":
# edit $MNT/etc/mkinitfs/mkinitfs.conf to make sure features="..." # includes cryptsetup (this field is space-separated and quoted) mkinitfs -c $MNT/etc/mkinitfs/mkinitfs.conf -b $MNT # edit $MNT/etc/update-extlinux.conf to make sure default_kernel_opts="..." # contains cryptroot=/dev/md1 and cryptdm=crypt (this field is also space-separated and quoted) # also check the root= setting extlinux --install $MNT/boot --update
--update
option to extlinux ...
suffice to make /boot/extlinux.conf be regenerated? Or do we need to manually tweak that file, or run update-extlinux
, as well?
You might also need to manually tweak $MNT/etc/fstab.
LVM
setup-disk
will automatically build and use volumes in a LVM group if you supply the -L switch.
If you instead want to build your LVM system manually, see Setting up Logical Volumes with LVM. Then vgchange -ay
, format and mount your volumes, and supply the root mountpoint to setup-disk. When you're finished, be sure to
umount ... vgchange -an
before rebooting.
If setup-disk
sees that you're using LVM, perhaps because you gave it the -L
switch, then it will set up your initram and extlinux.conf file properly. However, in other cases, these might not be properly set up. In that case, you may need to manually edit/rebuild them. The following assumes that $MNT
holds the root directory you're installing into:
# edit $MNT/etc/mkinitfs/mkinitfs.conf to make sure features="..." # includes lvm (this field is space-separated and quoted) mkinitfs -c $MNT/etc/mkinitfs/mkinitfs.conf -b $MNT # edit $MNT/etc/update-extlinux.conf to make sure root= is set correctly extlinux --install $MNT/boot --update
--update
option to extlinux ...
suffice to make /boot/extlinux.conf be regenerated? Or do we need to manually tweak that file, or run update-extlinux
, as well?
You might also need to manually tweak $MNT/etc/fstab.