ZFS: Difference between revisions
Fix and simplify snippet for selecting latest compatible Kernel |
m rm an extra bracket in the latest compatible Kernel selector left from the previous edit |
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&& (builtins.tryEval kernelPackages).success | && (builtins.tryEval kernelPackages).success | ||
&& (!kernelPackages.${config.boot.zfs.package.kernelModuleAttribute}.meta.broken) | && (!kernelPackages.${config.boot.zfs.package.kernelModuleAttribute}.meta.broken) | ||
) pkgs.linuxKernel.packages; | ) pkgs.linuxKernel.packages; | ||
latestKernelPackage = lib.last ( | latestKernelPackage = lib.last ( |
Latest revision as of 10:57, 6 November 2024
ZFS (wikipedia:en:ZFS), also known as OpenZFS (wikipedia:en:OpenZFS), is a modern filesystem which is well supported on NixOS. Besides the zfs package (ZFS Filesystem Linux Kernel module) [1] itself, there are many packages in the ZFS ecosystem available.
ZFS integrates into NixOS via the boot.zfs
[2] and service.zfs
[3] options.
Limitations
Latest Kernel compatible with ZFS
ZFS often does not support the latest Kernel versions. It is recommended to use an LTS Kernel version whenever possible; the NixOS default Kernel is generally suitable. See Linux Kernel for more information about configuring a specific Kernel version.
If your config specifies a Kernel version that is not officially supported by upstream ZFS, the ZFS module will fail to evaluate with an error that the ZFS package is "broken".
Selecting the latest ZFS-compatible Kernel
To use the latest ZFS-compatible Kernel currently available, the following configuration may be used.
{
config,
lib,
pkgs,
...
}:
let
zfsCompatibleKernelPackages = lib.filterAttrs (
name: kernelPackages:
(builtins.match "linux_[0-9]+_[0-9]+" name) != null
&& (builtins.tryEval kernelPackages).success
&& (!kernelPackages.${config.boot.zfs.package.kernelModuleAttribute}.meta.broken)
) pkgs.linuxKernel.packages;
latestKernelPackage = lib.last (
lib.sort (a: b: (lib.versionOlder a.kernel.version b.kernel.version)) (
builtins.attrValues zfsCompatibleKernelPackages
)
);
in
{
# Note this might jump back and forth as kernels are added or removed.
boot.kernelPackages = latestKernelPackage;
}
Using unstable, pre-release ZFS
In some cases, a pre-release version of ZFS may be available that supports a newer Kernel. Use it with boot.zfs.package = pkgs.zfs_unstable;
.
Partial support for swap on ZFS
ZFS does not support swapfiles. swap devices can be used instead. Additionally, hibernation is disabled by default due to a high risk of data corruption. Note that even if that pull request is merged, it does not fully mitigate the risk. If you wish to enable hibernation regardless and made sure that swapfiles on ZFS are not used, set boot.zfs.allowHibernation = true
.
Zpool not found
If NixOS fails to import the zpool on reboot, you may need to add boot.zfs.devNodes = "/dev/disk/by-path";
or boot.zfs.devNodes = "/dev/disk/by-partuuid";
to your configuration.nix file.
The differences can be tested by running zpool import -d /dev/disk/by-id
when none of the pools are discovered, eg. a live iso.
Declarative mounting of ZFS datasets
When using legacy mountpoints (created with e.g. zfs create -o mountpoint=legacy
) mountpoints must be specified with fileSystems."/mount/point" = {};
. ZFS native mountpoints are not managed as part of the system configuration but better support hibernation with a separate swap partition. This can lead to conflicts if ZFS mount service is also enabled for the same datasets. Disable it with systemd.services.zfs-mount.enable = false;
.
Guides
OpenZFS Documentation for installing
One guide for a NixOS installation with ZFS is maintained at OpenZFS Documentation (Getting Started for NixOS)
It is about:
It is not about:
- Giving understandable, easy to follow instructions which are close to the standard installation guide
- Integrating ZFS into your existing config
Simple NixOS ZFS on root installation
Start from here in the NixOS manual: [1]. Under manual partitioning [2] do this instead:
Partition your disk with your favorite partition tool
We need the following partitions:
- 1G for boot partition with "boot" as the partition label (also called name in some tools) and ef00 as partition code
- 4G for a swap partition with "swap" as the partition label and 8200 as partition code. We will encrypt this with a random secret on each boot.
- The rest of disk space for zfs with "root" as the partition label and 8300 as partition code (default code)
Reason for swap partition: ZFS does use a caching mechanism that is different from the normal Linux cache infrastructure. In low-memory situations, ZFS therefore might need a bit longer to free up memory from its cache. The swap partition will help with that.
Example with gdisk:
sudo gdisk /dev/nvme0n1
GPT fdisk (gdisk) version 1.0.10
...
# boot partition
Command (? for help): n
Partition number (1-128, default 1):
First sector (2048-1000215182, default = 2048) or {+-}size{KMGTP}:
Last sector (2048-1000215182, default = 1000215175) or {+-}size{KMGTP}: +1G
Current type is 8300 (Linux filesystem)
Hex code or GUID (L to show codes, Enter = 8300): ef00
Changed type of partition to 'EFI system partition'
# Swap partition
Command (? for help): n
Partition number (2-128, default 2):
First sector (2099200-1000215182, default = 2099200) or {+-}size{KMGTP}:
Last sector (2099200-1000215182, default = 1000215175) or {+-}size{KMGTP}: +4G
Current type is 8300 (Linux filesystem)
Hex code or GUID (L to show codes, Enter = 8300): 8200
Changed type of partition to 'Linux swap'
# root partition
Command (? for help): n
Partition number (3-128, default 3):
First sector (10487808-1000215182, default = 10487808) or {+-}size{KMGTP}:
Last sector (10487808-1000215182, default = 1000215175) or {+-}size{KMGTP}:
Current type is 8300 (Linux filesystem)
Hex code or GUID (L to show codes, Enter = 8300):
Changed type of partition to 'Linux filesystem'
# write changes
Command (? for help): w
Final checks complete. About to write GPT data. THIS WILL OVERWRITE EXISTING
PARTITIONS!!
Do you want to proceed? (Y/N): y
OK; writing new GUID partition table (GPT) to /dev/nvme0n1.
The operation has completed successfully.
Final partition table
Number Start (sector) End (sector) Size Code Name
1 2048 2099199 1024.0 MiB EF00 EFI system partition
2 2099200 10487807 4.0 GiB 8200 Linux swap
3 10487808 1000215175 471.9 GiB 8300 Linux filesystem
Let's use variables from now on for simplicity.
Get the device ID in /dev/disk/by-id/
, in our case here it is nvme-SKHynix_HFS512GDE9X081N_FNB6N634510106K5O
BOOT=/dev/disk/by-id/nvme-SKHynix_HFS512GDE9X081N_FNB6N634510106K5O-part1
SWAP=/dev/disk/by-id/nvme-SKHynix_HFS512GDE9X081N_FNB6N634510106K5O-part2
DISK=/dev/disk/by-id/nvme-SKHynix_HFS512GDE9X081N_FNB6N634510106K5O-part3
Make a ZFS pool with encryption and mount points
Note: zpool config can significantly affect performance (especially the ashift option) so you may want to do some research. The ZFS tuning cheatsheet or ArchWiki is a good place to start.
zpool create -O encryption=on -O keyformat=passphrase -O keylocation=prompt -O compression=zstd -O mountpoint=none -O xattr=sa -O acltype=posixacl -o ashift=12 zpool $DISK
# enter the password to decrypt the pool at boot
Enter new passphrase:
Re-enter new passphrase:
# Create datasets
zfs create zpool/root
zfs create zpool/nix
zfs create zpool/var
zfs create zpool/home
mkdir -p /mnt
mount -t zfs zpool/root /mnt -o zfsutil
mkdir /mnt/nix /mnt/var /mnt/home
mount -t zfs zpool/nix /mnt/nix -o zfsutil
mount -t zfs zpool/var /mnt/var -o zfsutil
mount -t zfs zpool/home /mnt/home -o zfsutil
Output from zpool status
:
zpool status
pool: zpool
state: ONLINE
...
config:
NAME STATE READ WRITE CKSUM
zpool ONLINE 0 0 0
nvme-eui.0025384b21406566-part2 ONLINE 0 0 0
Format boot partition with FAT as filesystem
mkfs.fat -F 32 -n boot $BOOT
Enable swap
mkswap -L swap $SWAP
swapon $SWAP
Installation
- Mount boot
mkdir -p /mnt/boot
mount $BOOT /mnt/boot
# Generate the nixos config
nixos-generate-config --root /mnt
...
writing /mnt/etc/nixos/hardware-configuration.nix...
writing /mnt/etc/nixos/configuration.nix...
For more hardware-specific settings, see https://github.com/NixOS/nixos-hardware.
Now edit the configuration.nix that was just created in /mnt/etc/nixos/configuration.nix
and make sure to have at least the following content in it.
{
...
# Boot loader config for configuration.nix:
boot.loader.systemd-boot.enable = true;
# for local disks that are not shared over the network, we don't need this to be random
networking.hostId = "8425e349";
...
Now check the hardware-configuration.nix in /mnt/etc/nixos/hardware-configuration.nix
and add whats missing e.g. options = [ "zfsutil" ]
for all filesystems except boot and randomEncryption = true;
for the swap partition. Also change the generated swap device to the partition we created e.g. /dev/disk/by-id/nvme-SKHynix_HFS512GDE9X081N_FNB6N634510106K5O-part2
in this case and /dev/disk/by-id/nvme-SKHynix_HFS512GDE9X081N_FNB6N634510106K5O-part1
for boot.
...
fileSystems."/" = {
device = "zpool/root";
fsType = "zfs";
# the zfsutil option is needed when mounting zfs datasets without "legacy" mountpoints
options = [ "zfsutil" ];
};
fileSystems."/nix" = {
device = "zpool/nix";
fsType = "zfs";
options = [ "zfsutil" ];
};
fileSystems."/var" = {
device = "zpool/var";
fsType = "zfs";
options = [ "zfsutil" ];
};
fileSystems."/home" = {
device = "zpool/home";
fsType = "zfs";
options = [ "zfsutil" ];
};
fileSystems."/boot" = {
device = "/dev/disk/by-id/nvme-SKHynix_HFS512GDE9X081N_FNB6N634510106K5O-part1";
fsType = "vfat";
};
swapDevices = [{
device = "/dev/disk/by-id/nvme-SKHynix_HFS512GDE9X081N_FNB6N634510106K5O-part2";
randomEncryption = true;
}];
}
Now you may install NixOS with nixos-install
.
Importing on boot
If you create a zpool, it will not be imported on the next boot unless you either add the zpool name to boot.zfs.extraPools
:
## In /etc/nixos/configuration.nix:
boot.zfs.extraPools = [ "zpool_name" ];
or if you are using legacy mountpoints, add a fileSystems
entry and NixOS will automatically detect that the pool needs to be imported:
## In /etc/nixos/configuration.nix:
fileSystems."/mount/point" = {
device = "zpool_name";
fsType = "zfs";
};
Zpool created with bus-based disk names
If you used bus-based disk names in the zpool create
command, e.g., /dev/sda
, NixOS may run into issues importing the pool if the names change. Even if the pool is able to be mounted (with boot.zfs.devNodes = "/dev/disk/by-partuuid";
set), this may manifest as a FAULTED
disk and a DEGRADED
pool reported by zpool status
. The fix is to re-import the pool using disk IDs:
# zpool export zpool_name
# zpool import -d /dev/disk/by-id zpool_name
The import setting is reflected in /etc/zfs/zpool.cache
, so it should persist through subsequent boots.
Zpool created with disk IDs
If you used disk IDs to refer to disks in the zpool create
command, e.g., /dev/disk/by-id
, then NixOS may consistently fail to import the pool unless boot.zfs.devNodes = "/dev/disk/by-id"
is also set.
Mount datasets at boot
zfs-mount service is enabled by default on NixOS 22.05.
To automatically mount a dataset at boot, you only need to set canmount=on
and mountpoint=/mount/point
on the respective datasets.
Changing the Adaptive Replacement Cache size
To change the maximum size of the ARC to (for example) 12 GB, add this to your NixOS configuration:
boot.kernelParams = [ "zfs.zfs_arc_max=12884901888" ];
Tuning other parameters
To tune other attributes of ARC, L2ARC or of ZFS itself via runtime modprobe config, add this to your NixOS configuration (keys and values are examples only!):
boot.extraModprobeConfig = ''
options zfs l2arc_noprefetch=0 l2arc_write_boost=33554432 l2arc_write_max=16777216 zfs_arc_max=2147483648
'';
You can confirm whether any specified configuration/tuning got applied via commands like arc_summary
and arcstat -a -s " "
.
Automatic scrubbing
Regular scrubbing of ZFS pools is recommended and can be enabled in your NixOS configuration via:
services.zfs.autoScrub.enable = true;
You can tweak the interval (defaults to once a week) and which pools should be scrubbed (defaults to all).
Remote unlock
Unlock encrypted ZFS via SSH on boot
In case you want unlock a machine remotely (after an update), having an ssh service in initrd for the password prompt is handy:
boot = {
initrd.network = {
# This will use udhcp to get an ip address.
# Make sure you have added the kernel module for your network driver to `boot.initrd.availableKernelModules`,
# so your initrd can load it!
# Static ip addresses might be configured using the ip argument in kernel command line:
# https://www.kernel.org/doc/Documentation/filesystems/nfs/nfsroot.txt
enable = true;
ssh = {
enable = true;
# To prevent ssh clients from freaking out because a different host key is used,
# a different port for ssh is useful (assuming the same host has also a regular sshd running)
port = 2222;
# hostKeys paths must be unquoted strings, otherwise you'll run into issues with boot.initrd.secrets
# the keys are copied to initrd from the path specified; multiple keys can be set
# you can generate any number of host keys using
# `ssh-keygen -t ed25519 -N "" -f /path/to/ssh_host_ed25519_key`
hostKeys = [ /path/to/ssh_host_rsa_key ];
# public ssh key used for login
authorizedKeys = [ "ssh-rsa AAAA..." ];
};
};
};
- In order to use DHCP in the initrd, network manager must not be enabled and
networking.useDHCP = true;
must be set. - If your network card isn't started, you'll need to add the according Kernel module to the Kernel and initrd as well, e.g.
boot.kernelModules = [ "r8169" ]; boot.initrd.kernelModules = [ "r8169" ];
After that you can unlock your datasets using the following ssh command:
ssh -p 2222 root@host "zpool import -a; zfs load-key -a && killall zfs"
Alternatively you could also add the commands as postCommands to your configuration.nix, then you just have to ssh into the initrd:
boot = {
initrd.network = {
postCommands = ''
# Import all pools
zpool import -a
# Or import selected pools
zpool import pool2
zpool import pool3
zpool import pool4
# Add the load-key command to the .profile
echo "zfs load-key -a; killall zfs" >> /root/.profile
'';
};
};
After that you can unlock your datasets using the following ssh command:
ssh -p 2222 root@host
Reservations
On ZFS, the performance will deteriorate significantly when more than 80% of the available space is used. To avoid this, reserve disk space beforehand.
To reserve space create a new unused dataset that gets a guaranteed disk space of 10GB.
# zfs create -o refreservation=10G -o mountpoint=none zroot/reserved
Auto ZFS trimming
services.zfs.trim.enable = true;
.
This will periodically run zpool trim
. Note that this is different from the autotrim
pool property. For further information, see the zpool-trim
and zpoolprops
man pages.
Take snapshots automatically
See services.sanoid
section in man configuration.nix
.
With sharenfs
property, ZFS has build-in support for generating /etc/exports.d/zfs.exports
file, which in turn is processed by NFS service automatically.
To enable NFS share on a dataset, only two steps are needed:
First, enable NFS service:
services.nfs.server.enable = true;
Only this line is needed. Configure firewall if necessary, as described in NFS article.
Then, set sharenfs
property:
zfs set sharenfs="ro=192.168.1.0/24,all_squash,anonuid=70,anongid=70" rpool/myData
For more options, see man 5 exports
.
Todo: sharesmb property for Samba.
Mail notifications (ZFS Event Daemon)
ZFS Event Daemon (zed) monitors events generated by the ZFS Kernel module and runs configured tasks. It can be configured to send an email when a pool scrub is finished or a disk has failed. zed options
Option A: enable mail notifications without re-compliation
First, we need to configure a mail transfer agent, the program that sends email:
{
programs.msmtp = {
enable = true;
setSendmail = true;
defaults = {
aliases = "/etc/aliases";
port = 465;
tls_trust_file = "/etc/ssl/certs/ca-certificates.crt";
tls = "on";
auth = "login";
tls_starttls = "off";
};
accounts = {
default = {
host = "mail.example.com";
passwordeval = "cat /etc/emailpass.txt";
user = "user@example.com";
from = "user@example.com";
};
};
};
}
Then, configure an alias for root account. With this alias configured, all mails sent to root, such as cron job results and failed sudo login events, will be redirected to the configured email account.
tee -a /etc/aliases <<EOF
root: user@example.com
EOF
Finally, override default zed settings with a custom one:
{
services.zfs.zed.settings = {
ZED_DEBUG_LOG = "/tmp/zed.debug.log";
ZED_EMAIL_ADDR = [ "root" ];
ZED_EMAIL_PROG = "${pkgs.msmtp}/bin/msmtp";
ZED_EMAIL_OPTS = "@ADDRESS@";
ZED_NOTIFY_INTERVAL_SECS = 3600;
ZED_NOTIFY_VERBOSE = true;
ZED_USE_ENCLOSURE_LEDS = true;
ZED_SCRUB_AFTER_RESILVER = true;
};
# this option does not work; will return error
services.zfs.zed.enableMail = false;
}
You can now test this by performing a scrub
# zpool scrub $pool
Option B: Rebuild ZFS with mail support
The zfs
package can be rebuilt with mail features. However, please note that this will cause Nix to recompile the entire ZFS package on the computer, and on every Kernel update, which could be very time-consuming on lower-end NAS systems.
An alternative solution that does not involve recompliation can be found above.
The following override is needed as zfs
is implicitly used in partition mounting:
nixpkgs.config.packageOverrides = pkgs: {
zfsStable = pkgs.zfsStable.override { enableMail = true; };
};
A mail sender like msmtp or postfix is required.
A minimal, testable ZED configuration example:
services.zfs.zed.enableMail = true;
services.zfs.zed.settings = {
ZED_EMAIL_ADDR = [ "root" ];
ZED_NOTIFY_VERBOSE = true;
};
Above, ZED_EMAIL_ADDR
is set to root
, which most people will have an alias for in their mailer. You can change it to directly mail you: ZED_EMAIL_ADDR = [ "you@example.com" ];
ZED pulls in mailutils
and runs mail
by default, but you can override it with ZED_EMAIL_PROG
. If using msmtp, you may need ZED_EMAIL_PROG = "${pkgs.msmtp}/bin/msmtp";
.
You can customize the mail command with ZED_EMAIL_OPTS
. For example, if your upstream mail server requires a certain FROM address: ZED_EMAIL_OPTS = "-r 'noreply@example.com' -s '@SUBJECT@' @ADDRESS@";