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[[NixOS]] has native support for ZFS ([[wikipedia:ZFS]]). It uses the code from the [http://zfsonlinux.org/ ZFS on Linux project], including kernel modules and userspace utilities. The installation isos also come with zfs.
[https://zfsonlinux.org/ {{PAGENAME}}] ([[wikipedia:en:{{PAGENAME}}]]) - also known as [https://openzfs.org/ OpenZFS] ([[wikipedia:en:OpenZFS]]) - is a modern filesystem[[category:filesystem]] which is well supported on [[NixOS]].


== What works ==
There are a lot of packages for [[{{PAGENAME}}]]. For example there is the ''zfs'' package (''ZFS Filesystem Linux Kernel module'') itself.<ref>https://search.nixos.org/packages?channel=unstable&show=zfs&query=zfs</ref> But there are also a lot of packages of the [[{{PAGENAME}}]] ecosystem available.


All functionality supported by ZFS on Linux, including:
[[{{PAGENAME}}]] integrates into NixOS via its [[module]] system.  Examples:
* Using ZFS as the root filesystem (using either MS-DOS or GPT partitions)
* ''boot.zfs''<ref>https://search.nixos.org/options?channel=unstable&query=boot.zfs</ref>
* Encrypted ZFS pools (using either native encryption or Linux's dm-crypt)
* ''service.zfs''<ref>https://search.nixos.org/options?channel=unstable&query=services.zfs</ref>
* All the other ZFS goodies (cheap snapshotting, checksumming, compression, RAID-Z, …)
* Auto-snapshotting service


== Known issues ==
== Limitations ==
{{note|Setting <code><nowiki>boot.zfs.enableUnstable = true;</nowiki></code> is required if you are running an newer kernel which is not yet officially supported by zfs, otherwise the zfs module will refuse to evaluate and show up as ''broken''. This will install a pre-release of zfs. This might be not as stable as a released version. However in the past this rarely lead to problems/stability issues}}


* Using NixOS on a ZFS root file system might result in the boot error ''external pointer tables not supported'' when the number of hardlinks in the nix store gets very high. This can be avoided by adding this option to your <code>configuration.nix</code> file:
==== latestCompatibleLinuxPackages of ZFS for boot.kernelPackages ====
<syntaxhighlight lang="nix">
boot.loader.grub.copyKernels = true;
</syntaxhighlight>


* In contrast to many native Linux filesystems, ZFS misses support for freeze/thaw operations.This means that using ZFS together with hibernation (suspend to disk) may cause filesystem corruption.See https://github.com/openzfs/zfs/issues/260.  
Newest kernels might not be supported by ZFS yet. If you are running an newer kernel which is not yet officially supported by zfs, the zfs module will refuse to evaluate and show up as ''broken''.  Use <code>boot.kernelPackages = config.boot.zfs.package.latestCompatibleLinuxPackages;</code> to use the latest compatible kernel.


{{note|For now, setting <code><nowiki>boot.kernelParams = [ "nohibernate" ];</nowiki></code>is necessary to avoid the issue described above.}}
==== partial support for SWAP on ZFS ====


ZFS does not support swapfiles. SWAP devices must be used instead. Additionally, hibernation is disabled by default due to a [https://github.com/NixOS/nixpkgs/pull/208037 high risk] of data corruption. Note that even if / after that pull request is merged, it does not fully mitigate the risk. If you wish to enable hibernation regardless, set <code>boot.zfs.allowHibernation = true</code>.


== Caveats ==  
==== boot.zfs.devNodes ====


* (ZFS, unrelated to Nix- see https://github.com/openzfs/zfs/issues/7734) You shouldn't use a ZVol as a swap device, as it can deadlock under memory pressure.
If NixOS fails to import the zpool on reboot, you may need to add <syntaxhighlight lang="nix" inline>boot.zfs.devNodes = "/dev/disk/by-path";</syntaxhighlight> or <syntaxhighlight lang="nix" inline>boot.zfs.devNodes = "/dev/disk/by-partuuid";</syntaxhighlight> to your configuration.nix file.
* You should set the <code>mountpoint</code> property of your ZFS filesystems to be <code>legacy</code> and let NixOS mount them like any other filesystem (such as ''ext4'' or ''btrfs''), otherwise some filesystems may fail to mount due to ordering issues.
* By default, all ZFS pools available to the system will be forcibly imported during boot, regardless if you had imported them before or not. You should be careful not to have any other system accessing them at the same time, otherwise it will corrupt your pools. Normally (for the common desktop user) this should not be a problem, as a hard disk is usually only directly connected to one machine. This behaviour can be disabled by setting <code>boot.zfs.forceImportAll = false</code>.
* If you create a zpool in the installer, make sure you run `zpool export <pool name>` after `nixos-install`, or else when you reboot into your new system, zfs will fail to import the zpool.


The differences can be tested by running <code>zpool import -d /dev/disk/by-id</code> when none of the pools are discovered, eg. a live iso.


== How to use it ==
==== declarative mounting of ZFS datasets ====


{{warning|Add all mounts to your configuration as legacy mounts as described in this article instead of zfs's own mount mechanism. Otherwise mounts might be not mounted in the correct order during boot!}}
When using legacy mountpoints (created with eg<code>zfs create -o mountpoint=legacy</code>) mountpoints must be specified with <code>fileSystems."/mount/point" = {};</code>. 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 <code>systemd.services.zfs-mount.enable = false;</code>.


Just add the following to your <code>configuration.nix</code> file:
== Guides ==
<syntaxhighlight lang="nix">
boot.initrd.supportedFilesystems = ["zfs"]; # boot from zfs
boot.supportedFilesystems = [ "zfs" ];
</syntaxhighlight>


Be sure to also set <code>networking.hostId</code>, see https://nixos.org/nixos/manual/options.html#opt-networking.hostId (Why- https://discourse.nixos.org/t/feedback-on-a-user-guide-i-created-on-installing-nixos-with-zfs/5986/4?u=srgom)
==== '''OpenZFS Documentation for installing''' ====


To activate the configuration and load the ZFS kernel module, run:
{{warning|This guide is not endorsed by NixOS and some features like immutable root do not have upstream support and could break on updates. If an issue arises while following this guide, please consult the guides support channels.}}
<syntaxhighlight lang="bash">
nixos-rebuild switch
</syntaxhighlight>


All ZFS functionality should now be available.
One guide for a NixOS installation with ZFS is maintained at [https://openzfs.github.io/openzfs-docs/Getting%20Started/NixOS/ OpenZFS Documentation (''Getting Started'' for ''NixOS'')]


If you want NixOS to auto-mount your ZFS filesystems during boot, you should set their <code>mountpoint</code> property to <code>legacy</code> and treat it like if it were any other filesystem, i.e.: mount the filesystem manually and regenerate your list of filesystems, as such:
It is about:
* [https://openzfs.github.io/openzfs-docs/Getting%20Started/NixOS/index.html#installation enabling ZFS on an existing NixOS installation] and
* [https://openzfs.github.io/openzfs-docs/Getting%20Started/NixOS/#root-on-zfs (installing NixOS with) Root on ZFS].


<syntaxhighlight lang="bash">
It is not about:
zfs set mountpoint=legacy <pool>/<fs>
* Give understandable, easy to follow and close to the standard installation guide instructions
</syntaxhighlight>
* integrating ZFS into your existing config


<syntaxhighlight lang="bash">
mount -t zfs <pool>/<fs> <mountpoint>
</syntaxhighlight>


This will regenerate your /etc/nixos/hardware-configuration.nix file:
==== '''Simple NixOS ZFS installation''' ====
<syntaxhighlight lang="bash">
nixos-generate-config
</syntaxhighlight>


<syntaxhighlight lang="bash">
Start from here in the NixOS manual: [https://nixos.org/manual/nixos/stable/#sec-installation-manual].
nixos-rebuild switch
Under manual partitioning [https://nixos.org/manual/nixos/stable/#sec-installation-manual-partitioning] do this instead:
</syntaxhighlight>


NixOS will now make sure that your filesystem is always mounted during boot.
'''Partition your disk with your favorite partition tool.'''


The <code>nixos-generate-config</code> command regenerates your <code>/etc/nixos/hardware-configuration.nix</code> file, which includes the list of filesystems for NixOS to mount during boot, e.g.:
We need the following partitions:
<syntaxhighlight lang="nix">
  fileSystems."/home" =
    { device = "rpool/home";
      fsType = "zfs";
    };


  fileSystems."/backup" =
* 1G for boot partition with "boot" as the partition label (also called name in some tools) and ef00 as partition code
    { device = "rpool/backup";
* 10G 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.
      fsType = "zfs";
* The rest of disk space for zfs with "root" as the partition label and 8300 as partition code (default code)
    };
</syntaxhighlight>


== Changing the Cache Size ==
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.


ZFS has a complicated cache system.  The cache you're most likely to want to fiddle with is the called Adaptive Replacement Cache, usually abbreviated ARC.  This is the first-level (fastest) of ZFS's caches.
Example output from fdisk:


You can increase or decrease a parameter which represents approximately the maximum size of the ARC cache. You can't set its actual size (ZFS does that adaptively according to its workload), nor can you set its exact maximum size.
<syntaxhighlight lang="bash">
sudo gdisk /dev/nvme0n1
GPT fdisk (gdisk) version 1.0.9.1
...
Command (? for help): p
Disk /dev/nvme0n1: 500118192 sectors, 238.5 GiB
Sector size (logical/physical): 512/512 bytes
Disk identifier (GUID): CA926E8C-47F6-416A-AD1A-C2190CF5D1F8
Partition table holds up to 128 entries
Main partition table begins at sector 2 and ends at sector 33
First usable sector is 34, last usable sector is 500118158
Partitions will be aligned on 2048-sector boundaries
Total free space is 2669 sectors (1.3 MiB)


To change the maximum size of the ARC cache to (for example) 12 GB, add this to your NixOS configuration:
Number  Start (sector)   End (sector)  Size      Code  Name
<syntaxhighlight lang="nix">
  1            2048        2099199  1024.0 MiB  EF00  boot
boot.kernelParams = ["zfs.zfs_arc_max=12884901888"];
  2        2099200        23070719  10.0 GiB    8200  swap
</syntaxhighlight>
  3        23070720      500117503  227.5 GiB  8300  root


In some versions of ZFS, you can change the maximum size of the ARC on the fly, but in NixOS 18.03 this is not possible.  (Nor is it possible in other versions of ZFS on Linux yet, according to Stack Exchange.)
Command (? for help):  
 
== Automatic Scrubbing ==
 
Regular scrubbing of ZFS pools is recommended and can be enabled in your NixOS configuration via:
<syntaxhighlight lang="nix">
services.zfs.autoScrub.enable = true;
</syntaxhighlight>
</syntaxhighlight>


You can tweak the interval (defaults to once a week) and which pools should be scrubbed (defaults to all).
'''Make zfs pool with encryption and mount points:'''
 
== Reservations ==
 
Since zfs is a copy-on-write filesystem even for deleting files disk space is needed. Therefore it should be avoided to run out of disk space. Luckily it is possible to reserve disk space for datasets to prevent this.
 
To reserve space create a new unused dataset that gets a guaranteed disk space of 1GB.


'''Note:''' zpool config can significantly affect performance (especially the ashift option) so you may want to do some research. The [https://jrs-s.net/2018/08/17/zfs-tuning-cheat-sheet/ ZFS tuning cheatsheet] or [https://wiki.archlinux.org/title/ZFS#Storage_pools ArchWiki] is a good place to start.
<syntaxhighlight lang="bash">
<syntaxhighlight lang="bash">
zfs create -o refreservation=1G -o mountpoint=none zroot/reserved
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 /dev/nvme0n1p2
</syntaxhighlight>
 
where <code>zroot</code> should be replaced by a dataset in your pool.
The dataset itself should not be used. In case you would run out of space you can shrink the reservation to reclaim enough disk space to cleanup the other data from the pool:
 
<syntaxhighlight lang="bash">
zfs set refreservation=none zroot/reserved
</syntaxhighlight>
 
== How to use the auto-snapshotting service ==
 
To auto-snapshot a ZFS filesystem or a ZVol, set its <code>com.sun:auto-snapshot</code> property to <code>true</code>, like this:


<syntaxhighlight lang="bash">
zfs create zpool/root
zfs set com.sun:auto-snapshot=true <pool>/<fs>
zfs create zpool/nix
</syntaxhighlight>
zfs create zpool/var
zfs create zpool/home


(Note that by default this property will be inherited by all descendent datasets, but you can set their properties to false if you prefer.)
mkdir -p /mnt
mount -t zfs zpool/root /mnt -o zfsutil
mkdir /mnt/nix /mnt/var /mnt/home


Then, to enable the auto-snapshot service, add this to your <code>configuration.nix</code>:
mount -t zfs zpool/nix /mnt/nix -o zfsutil
<syntaxhighlight lang="nix">
mount -t zfs zpool/var /mnt/var -o zfsutil
services.zfs.autoSnapshot.enable = true;
mount -t zfs zpool/home /mnt/home -o zfsutil
</syntaxhighlight>
</syntaxhighlight>


And finally, run <code>nixos-rebuild switch</code> to activate the new configuration!
Output from <syntaxhighlight lang="bash" inline>zpool status</syntaxhighlight>:
<syntaxhighlight >
zpool status
  pool: zpool
state: ONLINE
...
config:


By default, the auto-snapshot service will keep the latest four 15-minute, 24 hourly, 7 daily, 4 weekly and 12 monthly snapshots.
NAME                              STATE    READ WRITE CKSUM
You can globally override this configuration by setting the desired number of snapshots in your <code>configuration.nix</code>, like this:
zpool                              ONLINE      0    0    0
  nvme-eui.0025384b21406566-part2  ONLINE      0    0    0


<syntaxhighlight lang="nix">
services.zfs.autoSnapshot = {
  enable = true;
  frequent = 8; # keep the latest eight 15-minute snapshots (instead of four)
  monthly = 1;  # keep only one monthly snapshot (instead of twelve)
};
</syntaxhighlight>
</syntaxhighlight>


You can also disable a given type of snapshots on a per-dataset basis by setting a ZFS property, like this:
'''Make fat filesystem on boot partition'''
 
<syntaxhighlight lang="bash">
<syntaxhighlight lang="bash">
zfs set com.sun:auto-snapshot:weekly=false <pool>/<fs>
mkfs.fat -F 32 -n boot /dev/nvme0n1p1
</syntaxhighlight>
</syntaxhighlight>


This would disable only weekly snapshots on the given filesystem.


== How to install NixOS on a ZFS root filesystem ==
'''Installation:'''


Another guide titled "Encrypted ZFS mirror with mirrored boot on NixOS" is available at https://elis.nu/blog/2019/08/encrypted-zfs-mirror-with-mirrored-boot-on-nixos/.
Install: [https://nixos.org/manual/nixos/stable/#sec-installation-manual-installing]
=== Pool Layout Considerations ===


it is important to keep <code>/nix</code> and the rest of the filesystem in
Jump to "2. UEFI systems"
different sections of the dataset hierarchy, like this:


<syntaxhighlight lang="none">
<syntaxhighlight lang="bash">
rpool/
mkdir -p /mnt/boot
      local/
mount /dev/disk/by-partlabel/boot /mnt/boot
            nix        mounted to /nix
      safe/
            root        mounted to /
            home        mounted to /home
            ...
</syntaxhighlight>
</syntaxhighlight>


the name of `local` and `safe` can change, but them being peers
Jump to "4." ... /mnt/etc/nixos/configuration.nix ...
is important.


ZFS can take consistent and atomic snapshots recursively down a
Continue from here and add this boot loader and filesystems config to your configuration.nix:
dataset's hierarchy. Since Nix is good at being Nix, most users will want their server's ''data'' backed up, and don't
mind reinstalling NixOS and then restoring data. If this is sufficient, only snapshot and back up the <code>safe</code> hierarchy. Users who want to be able to restore a service with only ZFS snapshots will want to snapshot the entire tree, at the significant expense of snapshotting the Nix store.


=== Dataset Properties ===
<syntaxhighlight lang="nix">
{
  # Boot loader config for configuration.nix:
  boot.loader.systemd-boot.enable = true;


The following is a list of recommended dataset properties which have no drawbacks under regular uses:
  # for local disks that are not shared over the network, we don't need this to be random
  networking.hostId = "8425e349";


* <code>compression=lz4</code>
  fileSystems."/" = {
* <code>xattr=sa</code> for Journald
    device = "zpool/root";
* <code>acltype=posixacl</code> also for Journald
    fsType = "zfs";
    # the zfsutil option is needed when mounting zfs datasets without "legacy" mountpoints
    options = [ "zfsutil" ];
  };


The following is a list of dataset properties which are often useful, but do have drawbacks:
  fileSystems."/nix" = {
    device = "zpool/nix";
    fsType = "zfs";
    options = [ "zfsutil" ];
  };


* <code>atime=off</code> disables if a file's access time is updated when the file is read. This can result in significant performance gains, but might confuse some software like mailers.
  fileSystems."/var" = {
    device = "zpool/var";
    fsType = "zfs";
    options = [ "zfsutil" ];
  };


==== Journald ====
  fileSystems."/home" = {
    device = "zpool/home";
    fsType = "zfs";
    options = [ "zfsutil" ];
  };


Journald requires some properties for <code>journalctl</code> to work for non-root users. The dataset containing <code>/var/log/journal</code> (probably the <code>/</code> dataset for simple configurations) should be created with <code>xattr=sa</code> and <code>acltype=posixacl</code>.
  fileSystems."/boot" = {
  device = "/dev/disk/by-partlabel/boot";
  fsType = "vfat";
  };


For example:
  swapDevices = [{
 
    device = "/dev/disk/by-partlabel/swap";
<syntaxhighlight lang="console">
    randomEncryption = true;
$ zpool create  -O xattr=sa -O acltype=posixacl rpool ...
  }];
}
</syntaxhighlight>
</syntaxhighlight>


or:
== Importing on boot ==
<syntaxhighlight lang="console">
$ zfs create -o xattr=sa -o acltype=posixacl rpool/root
</syntaxhighlight>


If you have already created the dataset, these properties can be set later:
If you create a zpool, it will not be imported on the next boot unless you either add the zpool name to <syntaxhighlight lang="nix" inline>boot.zfs.extraPools</syntaxhighlight>:


<syntaxhighlight lang="console">
<syntaxhighlight lang="nix">
$ zfs set xattr=sa acltype=posixacl rpool/root
## In /etc/nixos/configuration.nix:
boot.zfs.extraPools = [ "zpool_name" ];
</syntaxhighlight>
</syntaxhighlight>


=== Single-disk ===
or if you are using legacy mountpoints, add a <syntaxhighlight lang="nix" inline>fileSystems</syntaxhighlight> entry and NixOS will automatically detect that the pool needs to be imported:


These instructions will get you started with a single-disk ZFS setup. If you're interested in setting up RAID, see below.
<syntaxhighlight lang="nix">
## In /etc/nixos/configuration.nix:
fileSystems."/mount/point" = {
  device = "zpool_name";
  fsType = "zfs";
};
</syntaxhighlight>


<syntaxhighlight lang="bash">
=== Zpool created with bus-based disk names ===
# Always use the by-id aliases for devices, otherwise ZFS can choke on imports.
If you used bus-based disk names in the <syntaxhighlight inline>zpool create</syntaxhighlight> command, e.g., <syntaxhighlight inline>/dev/sda</syntaxhighlight>, NixOS may run into issues importing the pool if the names change. Even if the pool is able to be mounted (with <syntaxhighlight lang="nix" inline>boot.zfs.devNodes = "/dev/disk/by-partuuid";</syntaxhighlight> set), this may manifest as a <syntaxhighlight inline>FAULTED</syntaxhighlight> disk and a <syntaxhighlight inline>DEGRADED</syntaxhighlight> pool reported by <syntaxhighlight inline>zpool status</syntaxhighlight>. The fix is to re-import the pool using disk IDs:
DISK=/dev/disk/by-id/...


# Partition 2 will be the boot partition, needed for legacy (BIOS) boot
<syntaxhighlight>
sgdisk -a1 -n2:34:2047 -t2:EF02 $DISK
# zpool export zpool_name
# If you need EFI support, make an EFI partition:
# zpool import -d /dev/disk/by-id zpool_name
sgdisk -n3:1M:+512M -t3:EF00 $DISK
</syntaxhighlight>
# Partition 1 will be the main ZFS partition, using up the remaining space on the drive.
sgdisk -n1:0:0 -t1:BF01 $DISK


# Create the pool. If you want to tweak this a bit and you're feeling adventurous, you
The import setting is reflected in <syntaxhighlight inline="" lang="bash">/etc/zfs/zpool.cache</syntaxhighlight>, so it should persist through subsequent boots.  
# might try adding one or more of the following additional options:
# To disable writing access times:
#  -O atime=off
# To enable filesystem compression:
#  -O compression=lz4
# To improve performance of certain extended attributes:
#  -O xattr=sa
# For systemd-journald posixacls are required
#  -O  acltype=posixacl
# To specify that your drive uses 4K sectors instead of relying on the size reported
# by the hardware (note small 'o'):
#  -o ashift=12
#
# The 'mountpoint=none' option disables ZFS's automount machinery; we'll use the
# normal fstab-based mounting machinery in Linux.
# '-R /mnt' is not a persistent property of the FS, it'll just be used while we're installing.
zpool create -O mountpoint=none rpool $DISK-part1


# Create the filesystems. This layout is designed so that /home is separate from the root
=== Zpool created with disk IDs ===
# filesystem, as you'll likely want to snapshot it differently for backup purposes. It also
If you used disk IDs to refer to disks in the <code>zpool create</code> command, e.g., <code>/dev/disk/by-id</code>, then NixOS may consistently fail to import the pool unless <code>boot.zfs.devNodes = "/dev/disk/by-id"</code> is also set.
# makes a "nixos" filesystem underneath the root, to support installing multiple OSes if
# that's something you choose to do in future.
zfs create -o mountpoint=legacy rpool/root
zfs create -o mountpoint=legacy rpool/root/nixos
zfs create -o mountpoint=legacy rpool/home


# Mount the filesystems manually. The nixos installer will detect these mountpoints
== Mount datasets at boot ==
# and save them to /mnt/nixos/hardware-configuration.nix during the install process.
zfs-mount service is enabled by default on NixOS 22.05.
mount -t zfs rpool/root/nixos /mnt
mkdir /mnt/home
mount -t zfs rpool/home /mnt/home


# If you need to boot EFI, you'll need to set up /boot as a non-ZFS partition.
To automatically mount a dataset at boot, you only need to set <code>canmount=on</code> and <code>mountpoint=/mount/point</code> on the respective datasets.
mkfs.vfat $DISK-part3
mkdir /mnt/boot
mount $DISK-part3 /mnt/boot


# Generate the NixOS configuration, as per the NixOS manual.
== Changing the Adaptive Replacement Cache size ==
nixos-generate-config --root /mnt


# Edit /mnt/etc/nixos/configuration.nix and add the following line:
To change the maximum size of the ARC to (for example) 12 GB, add this to your NixOS configuration:
## ---8<-------------------------8<---
<syntaxhighlight lang="nix">
  boot.supportedFilesystems = [ "zfs" ];
boot.kernelParams = [ "zfs.zfs_arc_max=12884901888" ];
## ---8<-------------------------8<---
</syntaxhighlight>


# Also, make sure you set the networking.hostId option, which ZFS requires:
== Tuning other parameters ==
## ---8<-------------------------8<---
  networking.hostId = "<random 8-digit hex string>";
## ---8<-------------------------8<---
# See https://nixos.org/nixos/manual/options.html#opt-networking.hostId for more.


# Continue with installation!
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!):
nixos-install
<syntaxhighlight lang="nix">
    boot.extraModprobeConfig = ''
      options zfs l2arc_noprefetch=0 l2arc_write_boost=33554432 l2arc_write_max=16777216 zfs_arc_max=2147483648
    '';
</syntaxhighlight>
</syntaxhighlight>


=== With RAID ===
You can confirm whether any specified configuration/tuning got applied via commands like <code>arc_summary</code> and <code>arcstat -a -s " "</code>.


Here's an example of how to create a ZFS root pool using 4 disks in RAID-10 mode (striping+mirroring), create a ZFS root+home filesystems and install NixOS on them:
== Automatic scrubbing ==
(thanks to Danny Wilson for the instructions)


<syntaxhighlight lang="bash">
Regular scrubbing of ZFS pools is recommended and can be enabled in your NixOS configuration via:
# Verify that the installer environment has loaded the ZFS kernel module (default since 18.09)
<syntaxhighlight lang="nix">
lsmod | grep zfs
services.zfs.autoScrub.enable = true;
</syntaxhighlight>


# Create boot partition and (zfs) data partition
You can tweak the interval (defaults to once a week) and which pools should be scrubbed (defaults to all).
# For information on the ZFS partitions see https://openzfs.github.io/openzfs-docs/Getting%20Started/Ubuntu/Ubuntu%2018.04%20Root%20on%20ZFS.html#step-2-disk-formatting
# The linked guide assumes a pure ZFS setup which is not the same suitable for this guide. You will have to create the partitions for the /boot raid by yourself.
fdisk /dev/sda


# Copy the partition table to the other disks
sfdisk --dump /dev/sda | sfdisk /dev/sdb
sfdisk --dump /dev/sda | sfdisk /dev/sdc
sfdisk --dump /dev/sda | sfdisk /dev/sdd


# Create a RAID-10 ZFS pool. Use "-o ashift=12" to create your ZFS pool with 4K sectors
== Remote unlock ==
# enable posixacls, otherwise journalctl is broken for users
=== Unlock encrypted zfs via ssh on boot ===
zpool create -o ashift=12 -o altroot=/mnt -O  acltype=posixacl -O xattr=sa rpool mirror /dev/sda2 /dev/sdb2 mirror /dev/sdc2 /dev/sdd2


# Create the filesystems
{{note|As of 22.05, rebuilding your config with the below directions may result in a situation where, if you want to revert the changes, you may need to do some pretty hairy nix-store manipulation to be able to successfully rebuild, see https://github.com/NixOS/nixpkgs/issues/101462#issuecomment-1172926129}}
zfs create -o mountpoint=none rpool/root
zfs create -o mountpoint=legacy rpool/root/nixos
zfs create -o mountpoint=legacy rpool/home
zfs set compression=lz4 rpool/home    # compress the home directories automatically


# Mount the filesystems manually
In case you want unlock a machine remotely (after an update), having an ssh service in initrd for the password prompt is handy:
mount -t zfs rpool/root/nixos /mnt


mkdir /mnt/home
<syntaxhighlight lang="nix">
mount -t zfs rpool/home /mnt/home
boot = {
 
  initrd.network = {
# Create a raid mirror of the first partitions for /boot (GRUB)
    # This will use udhcp to get an ip address.
mdadm --create /dev/md127 --metadata=0.90 --level=1 --raid-devices=4 /dev/sd[a,b,c,d]1
    # Make sure you have added the kernel module for your network driver to `boot.initrd.availableKernelModules`,  
mkfs.ext4 -m 0 -L boot -j /dev/md127
    # so your initrd can load it!
 
    # Static ip addresses might be configured using the ip argument in kernel command line:
mkdir /mnt/boot
    # https://www.kernel.org/doc/Documentation/filesystems/nfs/nfsroot.txt
mount /dev/md127 /mnt/boot
    enable = true;
 
    ssh = {
# Generate the NixOS configuration, as per the NixOS manual
      enable = true;
nixos-generate-config --root /mnt
      # 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)
# Now edit the generated hardware config:
      port = 2222;
nano /mnt/etc/nixos/hardware-configuration.nix
      # 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
## ---8<-------------------------8<---
      # you can generate any number of host keys using
# This is what you want:
      # `ssh-keygen -t ed25519 -N "" -f /path/to/ssh_host_ed25519_key`
 
      hostKeys = [ /path/to/ssh_host_rsa_key ];
  fileSystems."/" =
       # public ssh key used for login
    { device = "rpool/root/nixos";
      authorizedKeys = [ "ssh-rsa AAAA..." ];
       fsType = "zfs";
     };
     };
  };
};
</syntaxhighlight>
* In order to use DHCP in the initrd, network manager must not be enabled and <syntaxhighlight lang="nix" inline>networking.useDHCP = true;</syntaxhighlight> 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. <syntaxhighlight lang="nix">
boot.kernelModules = [ "r8169" ];
boot.initrd.kernelModules = [ "r8169" ];</syntaxhighlight>


  fileSystems."/home" =
After that you can unlock your datasets using the following ssh command:
    { device = "rpool/home";
      fsType = "zfs";
    };


  fileSystems."/boot" =
<syntaxhighlight>
    { device = "/dev/md127";
ssh -p 2222 root@host "zpool import -a; zfs load-key -a && killall zfs"
      fsType = "ext4";
</syntaxhighlight>
    };
## ---8<-------------------------8<---


# configuration.nix needs an adjustment:
Alternatively you could also add the commands as postCommands to your configuration.nix, then you just have to ssh into the initrd:
nano /mnt/etc/nixos/configuration.nix


## ---8<-------------------------8<---
<syntaxhighlight>
# This is some more of what you want:
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
    '';
  };
};
</syntaxhighlight>


  boot.loader.grub.devices = [ "/dev/sda" "/dev/sdb" "/dev/sdc" "/dev/sdd" ];
After that you can unlock your datasets using the following ssh command:
  boot.supportedFilesystems = [ "zfs" ];
## ---8<-------------------------8<---


# Ready to go!
<syntaxhighlight>
nixos-install
ssh -p 2222 root@host
</syntaxhighlight>
</syntaxhighlight>


== Encrypted ZFS ==
== Reservations ==


Assuming that a zpool named <code>zroot</code> has been already created as described.
On ZFS, the performance will deteriorate significantly when more than 80% of the available space is usedTo avoid this, reserve disk space beforehand.
Encrypted datasets can be added on top as follow:
: posixacl are needed for journald
<syntaxhighlight lang="bash">
zfs create -o acltype=posixacl -o xattr=sa -o encryption=aes-256-gcm -o keyformat=passphrase -o mountpoint=none zroot/root
</syntaxHighlight>


Instead of encrypting just a dataset (and all its child datasets) you can also directly encrypt the whole pool upon creation:
To reserve space create a new unused dataset that gets a guaranteed disk space of 10GB.
<syntaxhighlight lang="bash">
zpool create -o ashift=12 -o altroot="/mnt" -O mountpoint=none -O encryption=aes-256-gcm -O keyformat=passphrase zroot /dev/sdxy
</syntaxHighlight>


All child datasets will inherit the encryption.
<syntaxhighlight lang="console">
 
# zfs create -o refreservation=10G -o mountpoint=none zroot/reserved
Note that using grub to boot directly from zfs with encryption enabled might not work at the moment, so a separate boot partition is required.
</syntaxhighlight>
 
A full encrypted nixos installation on an UEFI system could look like this:
<syntaxhighlight lang="bash">
zfs create -o mountpoint=legacy -o sync=disabled zroot/root/tmp
zfs create -o mountpoint=legacy -o com.sun:auto-snapshot=true zroot/root/home
zfs create -o mountpoint=legacy -o com.sun:auto-snapshot=true zroot/root/nixos
</syntaxHighlight>
 
<syntaxhighlight lang="bash">
mount -t zfs zroot/root/nixos /mnt
mkdir /mnt/{home,tmp,boot}
</syntaxHighlight>
: assuming that /dev/sda1 is the boot partition
<syntaxhighlight lang="bash">
mkfs.vfat /dev/sda1
mount /dev/sda1 /mnt/boot/
</syntaxHighlight>
 
<syntaxhighlight lang="bash">
mount -t zfs zroot/root/home /mnt/home/
mount -t zfs zroot/root/tmp /mnt/tmp/
</syntaxHighlight>
 
<syntaxhighlight lang="bash">
nixos-generate-config  --root /mnt
</syntaxHighlight>


To unlock the zfs dataset at root also the <code>boot.zfs.requestEncryptionCredentials</code> option must be set to <code>true</code>. Note that at the moment one can only use passphrases (<code>keylocation=prompt</code>) for pools that are mounted as the root fs. Data pools are mounted by a background systemd service and need a key (<code>keylocation=file://</code>). A key file could be for example put on a root filesystem if it is encrypted.
== Auto ZFS trimming ==


If the key is not on the root filesystem, you will also need to set <code>zfs-import-poolname.serviceConfig.RequiresMountsFor=/path/to/key</code>, where <code>poolname</code> is the name of the data pool. This makes sure that systemd will mount the filesystem for <code>/path/to/key</code> first before importing the zfs pool.
<syntaxhighlight lang="nix" inline>services.zfs.trim.enable = true;</syntaxhighlight>.


=== Unlock encrypted zfs via ssh on boot ===
This will periodically run <code>zpool trim</code>. Note that this is different from the <code>autotrim</code> pool property. For further information, see the <code>zpool-trim</code> and <code>zpoolprops</code> man pages.


In case you want unlock a machine remotely (after an update), having an ssh service in initrd for the password prompt is handy:
== Take snapshots automatically ==


<syntaxhighlight lang="nix">
See <code>services.sanoid</code> section in <code>man configuration.nix</code>.
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..." ];
    };
    # this will automatically load the zfs password prompt on login
    # and kill the other prompt so boot can continue
    postCommands = ''
      echo "zfs load-key -a; killall zfs" >> /root/.profile
    '';
  };
};
</syntaxHighlight>
* In order to use DHCP in the initrd, network manager must not be enabled and <code>networking.useDHCP = true;</code> must be set.
* If your network card isn't started, you'll need to add the according kernel module to the initrd as well, e.g. <code>boot.initrd.kernelModules = [ "r8169" ];</code>


=== Import and unlock multiple encrypted pools/dataset at boot ===
== NFS share ==


If you have not only one encrypted pool/dataset but multiple ones and you want to import and unlock them at boot, so that they can be automounted using the hardware-configuration.nix, you could just amend the <code>boot.initrd.network.postCommands</code> option.
With <code>sharenfs</code> property, ZFS has build-in support for generating <code>/etc/exports.d/zfs.exports</code> file, which in turn is processed by NFS service automatically.


Unfortunately having an unlock key file stored in an encrypted zfs dataset cannot be used directly, so the pool must use <code>keyformat=passphrase</code> and <code>keylocation=prompt</code>.
{{warning|If you are intending on defining an IPv6 subnet as part of your sharenfs rule, as of ZFS 2.0.6 (2021-09-23) please note that due to a bug in openzfs '''your rule will not correctly apply''', and may result in a security vulnerability (CVE-2013-20001). A fix has been implemented in the next yet-to-be-released upstream version - [https://github.com/openzfs/zfs/pull/11939 openzfs/zfs#11939]}}


The following example follows the remote unlocking with OpenSSH, but imports another pool also and prompts for unlocking (either when at the machine itself or when logging in remotely:
To enable NFS share on a dataset, only two steps are needed:


First, enable [[NFS|NFS service]]:
<syntaxhighlight lang="nix">
<syntaxhighlight lang="nix">
boot = {
services.nfs.server.enable = true;
  initrd.network = {
</syntaxhighlight>
    enable = true;
Only this line is needed. Configure firewall if necessary, as described in [[NFS]] article.
    ssh = {
        enable = true;
        port = 2222;
        hostKeys = [ /path/to/ssh_host_rsa_key ];
        authorizedKeys = [ "ssh-rsa AAAA..." ];
    };
    postCommands = ''
      zpool import tankXXX
      echo "zfs load-key -a; killall zfs" >> /root/.profile
    '';
  };
};
</syntaxHighlight>


When you login by SSH into the box or when you have physical access to the machine itself, you will be prompted to supply the unlocking password for your zroot and tankXXX pools.
Then, set <code>sharenfs</code> property:
 
<syntaxhighlight lang="console">
== ZFS Trim Support for SSDs ==
# zfs set sharenfs="ro=192.168.1.0/24,all_squash,anonuid=70,anongid=70" rpool/myData
 
</syntaxhighlight>
ZFS 0.8 now also features trim support for SSDs.
For more options, see <code>man 5 exports</code>.
 
=== How to use ZFS trimming ===
 
ZFS trimming works on one or more zpools and will trim each ssd inside it. There are two modes of it. One mode will manually trim the specified pool and the other will auto-trim pools. However the main difference is, that auto-trim will skip ranges that it considers too small while manually issued trim will trim all ranges.
 
To manually start trimming of a zpool run: <code>zpool trim tank</code>.
Since [https://github.com/NixOS/nixpkgs/pull/65331 PR-65331] this can be also done periodically (by default once a week) by setting <code>services.zfs.trim.enable = true</code>.
 
To set a pool for auto-trim run: <code>zpool set autotrim=on tank</code>
 
To check the status of the manual trim, you can just run <code>zpool status -t</code>
 
To see the effects of trimming, you can run <code>zpool iostat -r</code> and <code>zpool iostat -w</code>
 
To see whether auto-trimming works, just run <code>zpool iostat -r</code> note the results and run it later again. The trim entries should change.
 
For further information read the [https://github.com/zfsonlinux/zfs/pull/8419 PR description].
 
[[Category:Guide]]


Todo: sharesmb property for Samba.


Following are a few discourse posts on zfs, serving as pointers, form your own opinion
== Mail notification for ZFS Event Daemon ==


* https://discourse.nixos.org/t/zfs-dedup-on-nix-store-is-it-worth-it/4959
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. [https://search.nixos.org/options?query=services.zfs.zed zed options]
* https://discourse.nixos.org/t/how-to-add-extra-build-input-to-linux-kernel/8208/3


==Mail notification for ZFS Event Daemon==
=== Alternative 1: Enable Mail Notification without Re-compliation ===
 
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.


First, we need to configure a mail transfer agent, the program that sends email:
First, we need to configure a mail transfer agent, the program that sends email:
<pre>
<syntaxhighlight lang="nix">
{
{
    programs.msmtp = {
  programs.msmtp = {
      enable = true;
    enable = true;
      setSendmail = true;
    setSendmail = true;
      defaults = {
    defaults = {
        aliases = "/etc/aliases";
      aliases = "/etc/aliases";
        port = 465;
      port = 465;
        tls_trust_file = "/etc/ssl/certs/ca-certificates.crt";
      tls_trust_file = "/etc/ssl/certs/ca-certificates.crt";
        tls = "on";
      tls = "on";
        auth = "login";
      auth = "login";
        tls_starttls = "off";
      tls_starttls = "off";
      };
    };
      accounts = {
    accounts = {
        default = {
      default = {
          host = "mail.example.com";
        host = "mail.example.com";
          passwordeval = "cat /etc/emailpass.txt";
        passwordeval = "cat /etc/emailpass.txt";
          user = "user@example.com";
        user = "user@example.com";
          from = "user@example.com";
        from = "user@example.com";
        };
       };
       };
     };
     };
  };
}
}
</pre>
</syntaxhighlight>


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.
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.


<pre>
<syntaxhighlight lang="bash">
tee -a /etc/aliases <<EOF
tee -a /etc/aliases <<EOF
root: user@example.com
root: user@example.com
EOF
EOF
</pre>
</syntaxhighlight>


Finally, override default zed settings with a custom one:
Finally, override default zed settings with a custom one:
<pre>
<syntaxhighlight lang="nix">
{
{
   services.zfs.zed.settings =
   services.zfs.zed.settings = {
{
    ZED_DEBUG_LOG = "/tmp/zed.debug.log";
  ZED_DEBUG_LOG = "/tmp/zed.debug.log";
    ZED_EMAIL_ADDR = [ "root" ];
  ZED_EMAIL_ADDR = [ "root" ];
    ZED_EMAIL_PROG = "${pkgs.msmtp}/bin/msmtp";
  ZED_EMAIL_PROG = "${ pkgs.msmtp }/bin/msmtp";
     ZED_EMAIL_OPTS = "@ADDRESS@";
     ZED_EMAIL_OPTS = "@ADDRESS@";


Line 563: Line 413:
     ZED_USE_ENCLOSURE_LEDS = true;
     ZED_USE_ENCLOSURE_LEDS = true;
     ZED_SCRUB_AFTER_RESILVER = true;
     ZED_SCRUB_AFTER_RESILVER = true;
};
  };
   # this option does not work; will return error
   # this option does not work; will return error
   services.zfs.zed.enableMail = false;
   services.zfs.zed.enableMail = false;
}
}
</pre>
</syntaxhighlight>


You can now test this by performing a scrub
You can now test this by performing a scrub
<pre>
<syntaxhighlight lang="console">
zpool scrub $pool
# zpool scrub $pool
</pre>
</syntaxhighlight>
 
=== Alternative 2: Rebuild ZFS with Mail Support ===
The <code>zfs</code> 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 <code>zfs</code> is implicitly used in partition mounting:
 
<syntaxhighlight lang="nix">
nixpkgs.config.packageOverrides = pkgs: {
  zfsStable = pkgs.zfsStable.override { enableMail = true; };
};
</syntaxhighlight>
 
A mail sender like [[msmtp]] or [[postfix]] is required.
 
A minimal, testable ZED configuration example:
 
<syntaxhighlight lang="nix">
services.zfs.zed.enableMail = true;
services.zfs.zed.settings = {
  ZED_EMAIL_ADDR = [ "root" ];
  ZED_NOTIFY_VERBOSE = true;
};
</syntaxhighlight>
 
Above, <code>ZED_EMAIL_ADDR</code> is set to <code>root</code>, which most people will have an alias for in their mailer. You can change it to directly mail you: <code>ZED_EMAIL_ADDR = [ "you@example.com" ];</code>
 
ZED pulls in <code>mailutils</code> and runs <code>mail</code> by default, but you can override it with <code>ZED_EMAIL_PROG</code>. If using msmtp, you may need <code>ZED_EMAIL_PROG = "${pkgs.msmtp}/bin/msmtp";</code>.
 
You can customize the mail command with <code>ZED_EMAIL_OPTS</code>. For example, if your upstream mail server requires a certain FROM address: <code>ZED_EMAIL_OPTS = "-r 'noreply@example.com' -s '@SUBJECT@' @ADDRESS@";</code>
 
[[Category:Guide]]

Latest revision as of 23:48, 3 June 2024

ZFS (wikipedia:en:ZFS) - also known as OpenZFS (wikipedia:en:OpenZFS) - is a modern filesystem which is well supported on NixOS.

There are a lot of packages for ZFS. For example there is the zfs package (ZFS Filesystem Linux Kernel module) itself.[1] But there are also a lot of packages of the ZFS ecosystem available.

ZFS integrates into NixOS via its module system. Examples:

Limitations

latestCompatibleLinuxPackages of ZFS for boot.kernelPackages

Newest kernels might not be supported by ZFS yet. If you are running an newer kernel which is not yet officially supported by zfs, the zfs module will refuse to evaluate and show up as broken. Use boot.kernelPackages = config.boot.zfs.package.latestCompatibleLinuxPackages; to use the latest compatible kernel.

partial support for SWAP on ZFS

ZFS does not support swapfiles. SWAP devices must be used instead. Additionally, hibernation is disabled by default due to a high risk of data corruption. Note that even if / after that pull request is merged, it does not fully mitigate the risk. If you wish to enable hibernation regardless, set boot.zfs.allowHibernation = true.

boot.zfs.devNodes

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 egzfs 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

Warning: This guide is not endorsed by NixOS and some features like immutable root do not have upstream support and could break on updates. If an issue arises while following this guide, please consult the guides support channels.

One guide for a NixOS installation with ZFS is maintained at OpenZFS Documentation (Getting Started for NixOS)

It is about:

It is not about:

  • Give understandable, easy to follow and close to the standard installation guide instructions
  • integrating ZFS into your existing config


Simple NixOS ZFS 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
  • 10G 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 output from fdisk: 

sudo gdisk /dev/nvme0n1
GPT fdisk (gdisk) version 1.0.9.1
...
Command (? for help): p
Disk /dev/nvme0n1: 500118192 sectors, 238.5 GiB
Sector size (logical/physical): 512/512 bytes
Disk identifier (GUID): CA926E8C-47F6-416A-AD1A-C2190CF5D1F8
Partition table holds up to 128 entries
Main partition table begins at sector 2 and ends at sector 33
First usable sector is 34, last usable sector is 500118158
Partitions will be aligned on 2048-sector boundaries
Total free space is 2669 sectors (1.3 MiB)

Number  Start (sector)    End (sector)  Size       Code  Name
   1            2048         2099199   1024.0 MiB  EF00  boot
   2         2099200        23070719   10.0 GiB    8200  swap
   3        23070720       500117503   227.5 GiB   8300  root

Command (? for help):

Make 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 /dev/nvme0n1p2

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

Make fat filesystem on boot partition 

mkfs.fat -F 32 -n boot /dev/nvme0n1p1


Installation:

Install: [3]

Jump to "2. UEFI systems" 

mkdir -p /mnt/boot
mount /dev/disk/by-partlabel/boot /mnt/boot

Jump to "4." ... /mnt/etc/nixos/configuration.nix ...

Continue from here and add this boot loader and filesystems config to your configuration.nix: 

{
  # 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";

  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-partlabel/boot";
   fsType = "vfat";
  };

  swapDevices = [{
    device = "/dev/disk/by-partlabel/swap";
    randomEncryption = true;
  }];
}

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

Note: As of 22.05, rebuilding your config with the below directions may result in a situation where, if you want to revert the changes, you may need to do some pretty hairy nix-store manipulation to be able to successfully rebuild, see https://github.com/NixOS/nixpkgs/issues/101462#issuecomment-1172926129

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.

NFS share

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.

Warning: If you are intending on defining an IPv6 subnet as part of your sharenfs rule, as of ZFS 2.0.6 (2021-09-23) please note that due to a bug in openzfs your rule will not correctly apply, and may result in a security vulnerability (CVE-2013-20001). A fix has been implemented in the next yet-to-be-released upstream version - openzfs/zfs#11939

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 notification for 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

Alternative 1: Enable Mail Notification 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

Alternative 2: 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@";

  1. https://search.nixos.org/packages?channel=unstable&show=zfs&query=zfs
  2. https://search.nixos.org/options?channel=unstable&query=boot.zfs
  3. https://search.nixos.org/options?channel=unstable&query=services.zfs
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