Immutable root with atomic upgrades: Difference between revisions

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While Alpine Linux has it's killer features it lacks mentioned above ones on default setup. This is a proof of concept that it's possible to implement them in a minimal way on a minimal system.
While Alpine Linux has it's killer features it lacks mentioned above ones on default setup. This is a proof of concept that it's possible to implement them in a minimal way on a minimal system.


{{Note|But Alpine Linux can boot in '''diskless mode''' (see [[Installation]]) which supports loading custom states from an .apkovl file. And the Alpine local backup tool <code>[[Alpine_local_backup|lbu]]</code>, that is used to save modified states to .apkovl files, supports to keep older versions (by configuring BACKUP_LIMIT) and to revert to booting older .apkovl versions. (The partitions are only temporarily re-mounted writable during the lbu operations, and are mounted read-only otherwise. (Manually jumpering the storage device read-only wouldn't interfere with the regular operation, either.)
{{Note|Alpine Linux can also boot from RAM in '''diskless mode''' (see [[Installation]]) which supports preserving changes between reboots using [[lbu]].}}
}}


= Partitioning disks =
= Partitioning disks =
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These steps prepare kernel and generate <code>initramfs</code> which later will be used to boot from our first snapshot.<br>
These steps prepare kernel and generate <code>initramfs</code> which later will be used to boot from our first snapshot.<br>
After that you should install any package you may need on first boot.
After that you should install any package you may need on first boot.
{{Warning|In case your PC only has wireless connection you should also install and configure any suitable networking software, like <code>iwd</code>, so you won't end up severed from network on your first boot.}}
{{Warning|In case your PC only has wireless connection you should also install and configure any suitable networking software, like <code>iwd</code>, so you won't end up severed from network on your first boot.}}


{{Note|Due to root being immutable during operation, it's recommended to install package <code>openresolv</code> to support changing netork connection. Then <code>/etc/resolvconf.conf</code> should have <code>resolv_conf{{=}}/tmp/resolv.conf</code>, <code>/etc/resolv.conf</code> should be moved to <code>/tmp/resolv.conf</code> and a link should be created <code>ln -sfn /tmp/resolv.conf /etc/resolv.conf</code>.
{{Note|Due to root being immutable during operation, it's recommended to install package <code>openresolv</code> to support changing network connection. In this case <code>/etc/resolvconf.conf</code> should have <code>resolv_conf{{=}}/tmp/resolv.conf</code>, <code>/etc/resolv.conf</code> should be moved to <code>/tmp/resolv.conf</code> and a link to the new resolv.conf location should be created: <code>ln -sfn /tmp/resolv.conf /etc/resolv.conf</code>.
 
You may also use static DNS, but this would make your network activity directly identifiable to the DNS server provider, therefore it's not recommended.
(The use of central DNS servers would transmit network activity from your machine directly identifyable to the DNS server's provider.)
}}
}}



Revision as of 22:52, 31 May 2021

This page is a work in progress ...

This page is still being developed.

What?

This article provides a basic guide to setting up a read-only-root-based Alpine Linux system with several boot environments and atomic upgrades using rEFInd and btrfs.

Why?

Read-only root and atomic upgrades with ability to easily rollback or boot previous configurations is a concept that got some popularity recently. Distributions providing and promoting such features, for example, are Fedora Silverblue, Opensuse MicroOS, NixOS and GNU Guix.

While Alpine Linux has it's killer features it lacks mentioned above ones on default setup. This is a proof of concept that it's possible to implement them in a minimal way on a minimal system.

Note: Alpine Linux can also boot from RAM in diskless mode (see Installation) which supports preserving changes between reboots using lbu.

Partitioning disks

In this guide it is assumed that you have a fresh UEFI system without OS and just managed to boot into live Alpine using USB flash drive or CD. The first step is creating partition table on your HDD/SSD target device (/dev/sda here):

# apk add gptfdisk
# gdisk /dev/sda
> o ↵
> y ↵
> w ↵
> y ↵

Now we can define the partitions:

# cgdisk /dev/sda

Partition creation process consists of several steps:

  1. Start sector - you can safely use default value by pressing ↵
  2. Size
  3. Type (as hex code) - EFI is ef00, Linux filesystem is 8300, Swap is 8200.

Result table:

Part.     #     Size        Partition Type            Partition Name
----------------------------------------------------------------
1               200.0 MiB   EFI System                EFI
2               200.0 GiB   Linux filesystem          ROOT
3               32.0 GiB    Linux swap                SWAP

ROOT partition name will later be used in rEFInd configuration to identify boot volume. Next step is creating filesystems:

# mkfs.vfat -F32 /dev/sda1
# mkfs.btrfs /dev/sda2
# mkswap /dev/sda3

Now we can mount our root volume:

# mount -t btrfs /dev/sda2 /mnt

File system structure

Now we should create file structure that would provide reliable atomic system upgrades.
Start with following directories:

# mkdir /mnt/next

Stores next current link.

# mkdir /mnt/commons

Stores common non-snapshotting subvolumes, is necessary due to how busybox mv does atomic link replacement.
We may populate it right away:

# btrfs subvolume create /mnt/commons/@var@tmp
# btrfs subvolume create /mnt/commons/@var@cache
# btrfs subvolume create /mnt/commons/@var@log
# btrfs subvolume create /mnt/commons/@home

If you use flatpak, you may also want to keep it's directory separate:

# btrfs subvolume create /mnt/commons/@var@lib@flatpak

Next, most important directories:

# mkdir /mnt/snapshots

Stores directories containing snapshots belonging to one generation.

# mkdir /mnt/links

Stores generations of directories containing links to snapshot generations.
Let's create first generation and populate it with one OS root snapshot @:

# NEWSNAPSHOTS="$(date -u +"%Y%m%d%H%M%S")$(cat /dev/urandom | tr -dc 'a-zA-Z' | fold -w 8 | head -n 1)"
# mkdir "/mnt/$NEWSNAPSHOTS"
# btrfs subvolume create /mnt/$NEWSNAPSHOTS/@

Populate links:

# NEWLINKS="$(date -u +"%Y%m%d%H%M%S")$(cat /dev/urandom | tr -dc 'a-zA-Z' | fold -w 8 | head -n 1)"
# mkdir "/mnt/links/$NEWLINKS"
# ln -s "../../snapshots/$NEWSNAPSHOTS" "/mnt/links/$NEWLINKS/0"
# ln -s "../../snapshots/$NEWSNAPSHOTS" "/mnt/links/$NEWLINKS/1"
# ln -s "../../snapshots/$NEWSNAPSHOTS" "/mnt/links/$NEWLINKS/2"
# ln -s "../../snapshots/$NEWSNAPSHOTS" "/mnt/links/$NEWLINKS/3"

You can have as many links as you like, just apply changes to rEFInd config and upgrade scripts described below accordingly.
Link that will point to latest links generation:

# ln -s "./links/$NEWLINKS" /mnt/current

This setup allows us to just have static rEFInd config that points to to /current/0/@, /current/1/@, etc. while the actual underlying boot environment will change with each upgrade.
But how will fs mounting services know which snapshot generation is currently loaded?
The answer is common fstab in the btrfs root.
Get UUIDs of the partitions first:

# blkid > /mnt/fstab

Now edit fstab accordingly:

# vi /mnt/fstab

Example:

UUID=b9ff5e7b-e128-4e64-861a-2fdd794a9828 / btrfs subvol=CURRENT_SNAPSHOTS_PATH/@,ro,noatime 0 0
UUID=b9ff5e7b-e128-4e64-861a-2fdd794a9828 /var/tmp btrfs subvol=/commons/@var@tmp,rw,noatime 0 0
UUID=b9ff5e7b-e128-4e64-861a-2fdd794a9828 /var/cache btrfs subvol=/commons/@var@cache,rw,noatime 0 0
UUID=b9ff5e7b-e128-4e64-861a-2fdd794a9828 /var/log btrfs subvol=/commons/@var@log,rw,noatime 0 0
UUID=b9ff5e7b-e128-4e64-861a-2fdd794a9828 /var/lib/flatpak btrfs subvol=/commons/@var@lib@flatpak,rw,noatime 0 0
UUID=b9ff5e7b-e128-4e64-861a-2fdd794a9828 /home btrfs subvol=/commons/@home,rw,noatime 0 0
# UUID=2FE6-837A /boot/efi vfat rw,noatime,discard 0 2
tmpfs /tmp tmpfs mode=1777,noatime,nosuid,nodev,size=2G 0 0
UUID=f0239163-9d46-47c1-67a4-3ee1d63d0676 swap swap rw,noatime,discard 0 0

CURRENT_SNAPSHOTS_PATH will be replaced by scripts with, for example, /snapshots/20210411212549sdBXyLxg, and the result will be piped into /etc/fstab of a created @ snapshot during new generation preparations.
Root btrfs volume structure mounted on /mnt:

|--mnt
| |--commons
| | |--@var@tmp
| | |--@var@cache
| | |--@var@log
| | |--@var@lib@flatpak
| | |--@home
| |--current
| |--fstab
| |--links
| | |--20210411213742qwrXAJBz
| | | |--0
| | | |--1
| | | |--2
| | | |--3
| |--next
| |--snapshots
| | |--20210411212549sdBXyLxg
| | | |--@

Base system install

With the directory strtucture prepared we can start installation of a basic Alpine Linux system.
Considering that installation is done from Alpine system, we only need following parts of the process:

# apk -X https://dl-cdn.alpinelinux.org/alpine/latest-stable/main -U --allow-untrusted -p /mnt/snapshots/20210411212549sdBXyLxg/@ --initdb add alpine-base

Now we can setup basic chroot to complete the installation process:

# export SNP="/mnt/snapshots/20210411212549sdBXyLxg/@"

# mount -o bind /dev $SNP/dev
# mount -t proc none $SNP/proc
# mount -o bind /sys $SNP/sys

# mkdir -p $SNP/var/tmp
# mount -o bind /mnt/commons/@var@tmp $SNP/var/tmp

# mkdir -p $SNP/var/cache
# mount -o bind /mnt/commons/@var@cache $SNP/var/cache

# mkdir -p $SNP/var/log
# mount -o bind /mnt/commons/@var@log $SNP/var/log

# mkdir -p $SNP/var/lib/flatpak
# mount -o bind /mnt/commons/@var@lib@flatpak $SNP/var/lib/flatpak

# mkdir -p $SNP/home
# mount -o bind /mnt/commons/@home $SNP/home

# cp -L /etc/resolv.conf /mnt/etc/
# chroot /mnt /bin/sh

As soon as you in chroot, define repositories:

# mkdir -p /etc/apk
# echo "https://dl-cdn.alpinelinux.org/alpine/latest-stable/main" > /etc/apk/repositories

Example shows only main, but you should also add testing and community if you need any packages in those.
Now it's time for firmware, kernel and btrfs packages:

# apk add -U linux-firmware linux-lts btrfs-progs

You may want to change linux-firmware to a custom set of firmware packages suitable for you system, for example linux-firmware-amd linux-firmware-amd-ucode linux-firmware-amdgpu linux-firmware-ath10k linux-firmware-qca for typical AMD laptop.
It is also important to add btrfs feature to mkinitfs.conf and run mkinitfs manually:

# vi /etc/mkinitfs/mkinitfs.conf
# mkinitfs

These steps prepare kernel and generate initramfs which later will be used to boot from our first snapshot.
After that you should install any package you may need on first boot.

Warning: In case your PC only has wireless connection you should also install and configure any suitable networking software, like iwd, so you won't end up severed from network on your first boot.


Note: Due to root being immutable during operation, it's recommended to install package openresolv to support changing network connection. In this case /etc/resolvconf.conf should have resolv_conf=/tmp/resolv.conf, /etc/resolv.conf should be moved to /tmp/resolv.conf and a link to the new resolv.conf location should be created: ln -sfn /tmp/resolv.conf /etc/resolv.conf.

You may also use static DNS, but this would make your network activity directly identifiable to the DNS server provider, therefore it's not recommended.

With the snapshot prepared we can chroot out of it and unmount everything:

# exit
# umount $SNP/dev
# umount $SNP/proc
# umount $SNP/sys

# umount $SNP/var/tmp

# umount $SNP/var/cache

# umount $SNP/var/log

# umount $SNP/var/lib/flatpak

# umount $SNP/home

...and inject fstab:

# sed "s#CURRENT_SNAPSHOTS_PATH#/snapshots/20210411212549sdBXyLxg#g" /mnt/fstab > "/mnt/snapshots/20210411212549sdBXyLxg/@/etc/fstab"

Finish editing snapshot by setting ro flag:

# btrfs property set -ts "/mnt/snapshots/20210411212549sdBXyLxg/@" ro true

Bootloader installation

Todo: