nixpkgs-suyu/nixos/lib/make-zfs-image.nix

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nixos/make-zfs-image: init This is a private interface for internal NixOS use. It is similar to `make-disk-image` except it is much more opinionated about what kind of disk image it'll make. Specifically, it will always create *two* disks: 1. a `boot` disk formatted with FAT in a hybrid GPT mode. 2. a `root` disk which is completely owned by a single zpool. The partitioning and FAT decisions should make the resulting images bootable under EFI or BIOS, with systemd-boot or grub. The root disk's zpools options are highly customizable, including fully customizable datasets and their options. Because the boot disk and partition are highly opinionated, it is expected that the `boot` disk will be mounted at `/boot`. It is always labeled ESP even on BIOS boot systems. In order for the datasets to be mounted properly, the `datasets` passed in to `make-zfs-image` are turned in to NixOS configuration stored at /etc/nixos/configuration.nix inside the VM. NOTE: The function accepts a system configuration in the `config` argument. The *caller* must manually configure the system in `config` to have each specified `dataset` be represented by a corresponding `fileSystems` entry. One way to test the resulting images is with qemu: ```sh boot=$(find ./result/ -name '*.boot.*'); root=$(find ./result/ -name '*.root.*'); echo '`Ctrl-a h` to get help on the monitor'; echo '`Ctrl-a x` to exit'; qemu-kvm \ -nographic \ -cpu max \ -m 16G \ -drive file=$boot,snapshot=on,index=0,media=disk \ -drive file=$root,snapshot=on,index=1,media=disk \ -boot c \ -net user \ -net nic \ -msg timestamp=on ```
2021-08-25 15:38:37 +02:00
# Note: This is a private API, internal to NixOS. Its interface is subject
# to change without notice.
#
# The result of this builder is two disk images:
#
# * `boot` - a small disk formatted with FAT to be used for /boot. FAT is
# chosen to support EFI.
# * `root` - a larger disk with a zpool taking the entire disk.
#
# This two-disk approach is taken to satisfy ZFS's requirements for
# autoexpand.
#
# # Why doesn't autoexpand work with ZFS in a partition?
#
# When ZFS owns the whole disk doesnt really use a partition: it has
# a marker partition at the start and a marker partition at the end of
# the disk.
#
# If ZFS is constrained to a partition, ZFS leaves expanding the partition
# up to the user. Obviously, the user may not choose to do so.
#
# Once the user expands the partition, calling zpool online -e expands the
# vdev to use the whole partition. It doesnt happen automatically
# presumably because zed doesnt get an event saying its partition grew,
# whereas it can and does get an event saying the whole disk it is on is
# now larger.
{ lib
, pkgs
, # The NixOS configuration to be installed onto the disk image.
config
, # size of the FAT boot disk, in megabytes.
bootSize ? 1024
, # The size of the root disk, in megabytes.
rootSize ? 2048
, # The name of the ZFS pool
rootPoolName ? "tank"
, # zpool properties
rootPoolProperties ? {
autoexpand = "on";
}
, # pool-wide filesystem properties
rootPoolFilesystemProperties ? {
acltype = "posixacl";
atime = "off";
compression = "on";
mountpoint = "legacy";
xattr = "sa";
}
, # datasets, with per-attribute options:
# mount: (optional) mount point in the VM
# properties: (optional) ZFS properties on the dataset, like filesystemProperties
# Notes:
# 1. datasets will be created from shorter to longer names as a simple topo-sort
# 2. you should define a root's dataset's mount for `/`
datasets ? { }
, # The files and directories to be placed in the target file system.
# This is a list of attribute sets {source, target} where `source'
# is the file system object (regular file or directory) to be
# grafted in the file system at path `target'.
contents ? []
, # The initial NixOS configuration file to be copied to
# /etc/nixos/configuration.nix. This configuration will be embedded
# inside a configuration which includes the described ZFS fileSystems.
configFile ? null
, # Shell code executed after the VM has finished.
postVM ? ""
, name ? "nixos-disk-image"
, # Disk image format, one of qcow2, qcow2-compressed, vdi, vpc, raw.
format ? "raw"
, # Include a copy of Nixpkgs in the disk image
includeChannel ? true
}:
let
formatOpt = if format == "qcow2-compressed" then "qcow2" else format;
compress = lib.optionalString (format == "qcow2-compressed") "-c";
filenameSuffix = "." + {
qcow2 = "qcow2";
vdi = "vdi";
vpc = "vhd";
raw = "img";
}.${formatOpt} or formatOpt;
bootFilename = "nixos.boot${filenameSuffix}";
rootFilename = "nixos.root${filenameSuffix}";
# FIXME: merge with channel.nix / make-channel.nix.
channelSources =
let
nixpkgs = lib.cleanSource pkgs.path;
in
pkgs.runCommand "nixos-${config.system.nixos.version}" {} ''
mkdir -p $out
cp -prd ${nixpkgs.outPath} $out/nixos
chmod -R u+w $out/nixos
if [ ! -e $out/nixos/nixpkgs ]; then
ln -s . $out/nixos/nixpkgs
fi
rm -rf $out/nixos/.git
echo -n ${config.system.nixos.versionSuffix} > $out/nixos/.version-suffix
'';
closureInfo = pkgs.closureInfo {
rootPaths = [ config.system.build.toplevel ]
++ (lib.optional includeChannel channelSources);
};
modulesTree = pkgs.aggregateModules
(with config.boot.kernelPackages; [ kernel zfs ]);
tools = lib.makeBinPath (
with pkgs; [
config.system.build.nixos-enter
config.system.build.nixos-install
dosfstools
e2fsprogs
gptfdisk
nix
parted
utillinux
zfs
]
);
hasDefinedMount = disk: ((disk.mount or null) != null);
stringifyProperties = prefix: properties: lib.concatStringsSep " \\\n" (
lib.mapAttrsToList
(
property: value: "${prefix} ${lib.escapeShellArg property}=${lib.escapeShellArg value}"
)
properties
);
featuresToProperties = features:
lib.listToAttrs
(builtins.map (feature: {
name = "feature@${feature}";
value = "enabled";
}) features);
createDatasets =
let
datasetlist = lib.mapAttrsToList lib.nameValuePair datasets;
sorted = lib.sort (left: right: (lib.stringLength left.name) < (lib.stringLength right.name)) datasetlist;
cmd = { name, value }:
let
properties = stringifyProperties "-o" (value.properties or {});
in
"zfs create -p ${properties} ${name}";
in
lib.concatMapStringsSep "\n" cmd sorted;
mountDatasets =
let
datasetlist = lib.mapAttrsToList lib.nameValuePair datasets;
mounts = lib.filter ({ value, ... }: hasDefinedMount value) datasetlist;
sorted = lib.sort (left: right: (lib.stringLength left.value.mount) < (lib.stringLength right.value.mount)) mounts;
cmd = { name, value }:
''
mkdir -p /mnt${lib.escapeShellArg value.mount}
mount -t zfs ${name} /mnt${lib.escapeShellArg value.mount}
'';
in
lib.concatMapStringsSep "\n" cmd sorted;
unmountDatasets =
let
datasetlist = lib.mapAttrsToList lib.nameValuePair datasets;
mounts = lib.filter ({ value, ... }: hasDefinedMount value) datasetlist;
sorted = lib.sort (left: right: (lib.stringLength left.value.mount) > (lib.stringLength right.value.mount)) mounts;
cmd = { name, value }:
''
umount /mnt${lib.escapeShellArg value.mount}
'';
in
lib.concatMapStringsSep "\n" cmd sorted;
fileSystemsCfgFile =
let
mountable = lib.filterAttrs (_: value: hasDefinedMount value) datasets;
in
pkgs.runCommand "filesystem-config.nix" {
buildInputs = with pkgs; [ jq nixpkgs-fmt ];
filesystems = builtins.toJSON {
fileSystems = lib.mapAttrs'
(
dataset: attrs:
{
name = attrs.mount;
value = {
fsType = "zfs";
device = "${dataset}";
};
}
)
mountable;
};
passAsFile = [ "filesystems" ];
} ''
(
echo "builtins.fromJSON '''"
jq . < "$filesystemsPath"
echo "'''"
) > $out
nixpkgs-fmt $out
'';
mergedConfig =
if configFile == null
then fileSystemsCfgFile
else
pkgs.runCommand "configuration.nix" {
buildInputs = with pkgs; [ nixpkgs-fmt ];
}
''
(
echo '{ imports = ['
printf "(%s)\n" "$(cat ${fileSystemsCfgFile})";
printf "(%s)\n" "$(cat ${configFile})";
echo ']; }'
) > $out
nixpkgs-fmt $out
'';
image = (
pkgs.vmTools.override {
rootModules =
[ "zfs" "9p" "9pnet_virtio" "virtio_pci" "virtio_blk" ] ++
(pkgs.lib.optional pkgs.stdenv.hostPlatform.isx86 "rtc_cmos");
nixos/make-zfs-image: init This is a private interface for internal NixOS use. It is similar to `make-disk-image` except it is much more opinionated about what kind of disk image it'll make. Specifically, it will always create *two* disks: 1. a `boot` disk formatted with FAT in a hybrid GPT mode. 2. a `root` disk which is completely owned by a single zpool. The partitioning and FAT decisions should make the resulting images bootable under EFI or BIOS, with systemd-boot or grub. The root disk's zpools options are highly customizable, including fully customizable datasets and their options. Because the boot disk and partition are highly opinionated, it is expected that the `boot` disk will be mounted at `/boot`. It is always labeled ESP even on BIOS boot systems. In order for the datasets to be mounted properly, the `datasets` passed in to `make-zfs-image` are turned in to NixOS configuration stored at /etc/nixos/configuration.nix inside the VM. NOTE: The function accepts a system configuration in the `config` argument. The *caller* must manually configure the system in `config` to have each specified `dataset` be represented by a corresponding `fileSystems` entry. One way to test the resulting images is with qemu: ```sh boot=$(find ./result/ -name '*.boot.*'); root=$(find ./result/ -name '*.root.*'); echo '`Ctrl-a h` to get help on the monitor'; echo '`Ctrl-a x` to exit'; qemu-kvm \ -nographic \ -cpu max \ -m 16G \ -drive file=$boot,snapshot=on,index=0,media=disk \ -drive file=$root,snapshot=on,index=1,media=disk \ -boot c \ -net user \ -net nic \ -msg timestamp=on ```
2021-08-25 15:38:37 +02:00
kernel = modulesTree;
}
).runInLinuxVM (
pkgs.runCommand name
{
QEMU_OPTS = "-drive file=$bootDiskImage,if=virtio,cache=unsafe,werror=report"
+ " -drive file=$rootDiskImage,if=virtio,cache=unsafe,werror=report";
preVM = ''
PATH=$PATH:${pkgs.qemu_kvm}/bin
mkdir $out
bootDiskImage=boot.raw
qemu-img create -f raw $bootDiskImage ${toString bootSize}M
rootDiskImage=root.raw
qemu-img create -f raw $rootDiskImage ${toString rootSize}M
'';
postVM = ''
${if formatOpt == "raw" then ''
mv $bootDiskImage $out/${bootFilename}
mv $rootDiskImage $out/${rootFilename}
'' else ''
${pkgs.qemu}/bin/qemu-img convert -f raw -O ${formatOpt} ${compress} $bootDiskImage $out/${bootFilename}
${pkgs.qemu}/bin/qemu-img convert -f raw -O ${formatOpt} ${compress} $rootDiskImage $out/${rootFilename}
''}
bootDiskImage=$out/${bootFilename}
rootDiskImage=$out/${rootFilename}
set -x
${postVM}
'';
} ''
export PATH=${tools}:$PATH
set -x
cp -sv /dev/vda /dev/sda
cp -sv /dev/vda /dev/xvda
parted --script /dev/vda -- \
mklabel gpt \
mkpart no-fs 1MiB 2MiB \
set 1 bios_grub on \
align-check optimal 1 \
mkpart ESP fat32 2MiB -1MiB \
align-check optimal 2 \
print
sfdisk --dump /dev/vda
zpool create \
${stringifyProperties " -o" rootPoolProperties} \
${stringifyProperties " -O" rootPoolFilesystemProperties} \
${rootPoolName} /dev/vdb
parted --script /dev/vdb -- print
${createDatasets}
${mountDatasets}
mkdir -p /mnt/boot
mkfs.vfat -n ESP /dev/vda2
mount /dev/vda2 /mnt/boot
mount
# Install a configuration.nix
mkdir -p /mnt/etc/nixos
# `cat` so it is mutable on the fs
cat ${mergedConfig} > /mnt/etc/nixos/configuration.nix
export NIX_STATE_DIR=$TMPDIR/state
nix-store --load-db < ${closureInfo}/registration
nixos-install \
--root /mnt \
--no-root-passwd \
--system ${config.system.build.toplevel} \
--substituters "" \
${lib.optionalString includeChannel ''--channel ${channelSources}''}
df -h
umount /mnt/boot
${unmountDatasets}
zpool export ${rootPoolName}
''
);
in
image