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title | category | layout |
---|---|---|
Discoverable Partitions Specification | Concepts | default |
The Discoverable Partitions Specification
TL;DR: Let's automatically discover, mount and enable the root partition,
/home/
, /srv/
, /var/
and /var/tmp/
and the swap partitions based on
GUID Partition Tables (GPT)!
This specification describes the use of GUID Partition Table (GPT) UUIDs to enable automatic discovery of partitions and their intended mountpoints. Traditionally Linux has made little use of partition types, mostly just defining one UUID for file system/data partitions and another one for swap partitions. With this specification, we introduce additional partition types for specific uses. This has many benefits:
- OS installers can automatically discover and make sense of partitions of existing Linux installations.
- The OS can discover and mount the necessary file systems with a non-existent
or incomplete
/etc/fstab
file and without theroot=
kernel command line option. - Container managers (such as nspawn and libvirt-lxc) can introspect and set up file systems contained in GPT disk images automatically and mount them to the right places, thus allowing booting the same, identical images on bare metal and in Linux containers. This enables true, natural portability of disk images between physical machines and Linux containers.
- As a help to administrators and users partition manager tools can show more descriptive information about partitions tables.
Note that the OS side of this specification is currently implemented in systemd 211 and newer in the systemd-gpt-auto-generator(8) generator tool. Note that automatic discovery of the root only works if the boot loader communicates this information to the OS, by implementing the Boot Loader Interface.
Defined Partition Type UUIDs
Partition Type UUID | Name | Allowed File Systems | Explanation |
---|---|---|---|
44479540-f297-41b2-9af7-d131d5f0458a |
Root Partition (x86) | Any native, optionally in LUKS | On systems with matching architecture, the first partition with this type UUID on the disk containing the active EFI ESP is automatically mounted to the root directory /. If the partition is encrypted with LUKS or has dm-verity integrity data (see below), the device mapper file will be named /dev/mapper/root . |
4f68bce3-e8cd-4db1-96e7-fbcaf984b709 |
Root Partition (x86-64) | ditto | ditto |
69dad710-2ce4-4e3c-b16c-21a1d49abed3 |
Root Partition (32-bit ARM) | ditto | ditto |
b921b045-1df0-41c3-af44-4c6f280d3fae |
Root Partition (64-bit ARM/AArch64) | ditto | ditto |
993d8d3d-f80e-4225-855a-9daf8ed7ea97 |
Root Partition (Itanium/IA-64) | ditto | ditto |
60d5a7fe-8e7d-435c-b714-3dd8162144e1 |
Root Partition (RISC-V 32-bit) | ditto | ditto |
72ec70a6-cf74-40e6-bd49-4bda08e8f224 |
Root Partition (RISC-V 64-bit) | ditto | ditto |
d13c5d3b-b5d1-422a-b29f-9454fdc89d76 |
Root Verity Partition (x86) | A dm-verity superblock followed by hash data | On systems with matching architecture, contains dm-verity integrity hash data for the matching root partition. If this feature is used the partition UUID of the root partition should be the first 128bit of the root hash of the dm-verity hash data, and the partition UUID of this dm-verity partition should be the final 128bit of it, so that the root partition and its verity partition can be discovered easily, simply by specifying the root hash. |
2c7357ed-ebd2-46d9-aec1-23d437ec2bf5 |
Root Verity Partition (x86-64) | ditto | ditto |
7386cdf2-203c-47a9-a498-f2ecce45a2d6 |
Root Verity Partition (32-bit ARM) | ditto | ditto |
df3300ce-d69f-4c92-978c-9bfb0f38d820 |
Root Verity Partition (64-bit ARM/AArch64) | ditto | ditto |
86ed10d5-b607-45bb-8957-d350f23d0571 |
Root Verity Partition (Itanium/IA-64) | ditto | ditto |
ae0253be-1167-4007-ac68-43926c14c5de |
Root Verity Partition (RISC-V 32-bit) | ditto | ditto |
b6ed5582-440b-4209-b8da-5ff7c419ea3d |
Root Verity Partition (RISC-V 64-bit) | ditto | ditto |
75250d76-8cc6-458e-bd66-bd47cc81a812 |
/usr/ Partition (x86) |
Any native, optionally in LUKS | Similar semantics to root partition, but just the /usr/ partition. |
8484680c-9521-48c6-9c11-b0720656f69e |
/usr/ Partition (x86-64) |
ditto | ditto |
7d0359a3-02b3-4f0a-865c-654403e70625 |
/usr/ Partition (32-bit ARM) |
ditto | ditto |
b0e01050-ee5f-4390-949a-9101b17104e9 |
/usr/ Partition (64-bit ARM/AArch64) |
ditto | ditto |
4301d2a6-4e3b-4b2a-bb94-9e0b2c4225ea |
/usr/ Partition (Itanium/IA-64) |
ditto | ditto |
b933fb22-5c3f-4f91-af90-e2bb0fa50702 |
/usr/ Partition (RISC-V 32-bit) |
ditto | ditto |
beaec34b-8442-439b-a40b-984381ed097d |
/usr/ Partition (RISC-V 64-bit) |
ditto | ditto |
8f461b0d-14ee-4e81-9aa9-049b6fb97abd |
/usr/ Verity Partition (x86) |
Any native, optionally in LUKS | Similar semantics to root Verity partition, but just for the /usr/ partition. |
77ff5f63-e7b6-4633-acf4-1565b864c0e6 |
/usr/ Verity Partition (x86-64) |
ditto | ditto |
c215d751-7bcd-4649-be90-6627490a4c05 |
/usr/ Verity Partition (32-bit ARM) |
ditto | ditto |
6e11a4e7-fbca-4ded-b9e9-e1a512bb664e |
/usr/ Verity Partition (64-bit ARM/AArch64) |
ditto | ditto |
6a491e03-3be7-4545-8e38-83320e0ea880 |
/usr/ Verity Partition (Itanium/IA-64) |
ditto | ditto |
cb1ee4e3-8cd0-4136-a0a4-aa61a32e8730 |
/usr/ Verity Partition (RISC-V 32-bit) |
ditto | ditto |
8f1056be-9b05-47c4-81d6-be53128e5b54 |
/usr/ Verity Partition (RISC-V 64-bit) |
ditto | ditto |
933ac7e1-2eb4-4f13-b844-0e14e2aef915 |
Home Partition | Any native, optionally in LUKS | The first partition with this type UUID on the disk containing the root partition is automatically mounted to /home/ . If the partition is encrypted with LUKS, the device mapper file will be named /dev/mapper/home . |
3b8f8425-20e0-4f3b-907f-1a25a76f98e8 |
Server Data Partition | Any native, optionally in LUKS | The first partition with this type UUID on the disk containing the root partition is automatically mounted to /srv/ . If the partition is encrypted with LUKS, the device mapper file will be named /dev/mapper/srv . |
4d21b016-b534-45c2-a9fb-5c16e091fd2d |
Variable Data Partition | Any native, optionally in LUKS | The first partition with this type UUID on the disk containing the root partition is automatically mounted to /var/ — under the condition that its partition UUID matches the first 128 bit of HMAC-SHA256(machine-id, 0x4d21b016b53445c2a9fb5c16e091fd2d) (i.e. the SHA256 HMAC hash of the binary type UUID keyed by the machine ID as read from /etc/machine-id . This special requirement is made because /var/ (unlike the other partition types listed here) is inherently private to a specific installation and cannot possibly be shared between multiple OS installations on the same disk, and thus should be bound to a specific instance of the OS, identified by its machine ID. If the partition is encrypted with LUKS, the device mapper file will be named /dev/mapper/var . |
7ec6f557-3bc5-4aca-b293-16ef5df639d1 |
Temporary Data Partition | Any native, optionally in LUKS | The first partition with this type UUID on the disk containing the root partition is automatically mounted to /var/tmp/ . If the partition is encrypted with LUKS, the device mapper file will be named /dev/mapper/tmp . Note that the intended mount point is indeed /var/tmp/ , not /tmp/ . The latter is typically maintained in memory via tmpfs and does not require a partition on disk. In some cases it might be desirable to make /tmp/ persistent too, in which case it is recommended to make it a symlink or bind mount to /var/tmp/ , thus not requiring its own partition type UUID. |
0657fd6d-a4ab-43c4-84e5-0933c84b4f4f |
Swap | Swap | All swap partitions on the disk containing the root partition are automatically enabled. |
c12a7328-f81f-11d2-ba4b-00a0c93ec93b |
EFI System Partition | VFAT | The ESP used for the current boot is automatically mounted to /efi/ (or /boot/ as fallback), unless a different partition is mounted there (possibly via /etc/fstab , or because the Extended Boot Loader Partition — see below — exists) or the directory is non-empty on the root disk. This partition type is defined by the UEFI Specification. |
bc13c2ff-59e6-4262-a352-b275fd6f7172 |
Extended Boot Loader Partition | Typically VFAT | The Extended Boot Loader Partition (XBOOTLDR) used for the current boot is automatically mounted to /boot/, unless a different partition is mounted there (possibly via /etc/fstab) or the directory is non-empty on the root disk. This partition type is defined by the Boot Loader Specification. |
0fc63daf-8483-4772-8e79-3d69d8477de4 |
Other Data Partitions | Any native, optionally in LUKS | No automatic mounting takes place for other Linux data partitions. This partition type should be used for all partitions that carry Linux file systems. The installer needs to mount them explicitly via entries in /etc/fstab. Optionally, these partitions may be encrypted with LUKS. |
Other GPT type IDs might be used on Linux, for example to mark software RAID or LVM partitions. The definitions of those GPT types is outside of the scope of this specification.
systemd-id128(1) may be used to list those UUIDs.
Partition Names
For partitions of the types listed above it is recommended to use human-friendly, descriptive partition names in the GPT partition table, for example "Home", "Server Data", "Fedora Root" and similar, possibly localized.
Partition Flags
For the root, /usr/
, server data, home, variable data, temporary data and swap
partitions, the partition flag bit 63 ("no-auto") may be used to turn off
auto-discovery for the specific partition. If set, the partition will not be
automatically mounted or enabled.
For the root, /usr/
, server data, home, variable data and temporary data
partitions, the partition flag bit 60 ("read-only") may be used to mark a
partition for read-only mounts only. If set, the partition will be mounted
read-only instead of read-write. Note that the variable data partition and the
temporary data partition will generally not be able to serve their purpose if
marked read-only, since by their very definition they are supposed to be
mutable. (The home and server data partitions are generally assumed to be
mutable as well, but the requirement for them is not equally strong.) Because
of that, while the read-only flag is defined and supported, it's almost never a
good idea to actually use it for these partitions.
Note that these two flag definitions happen to map nicely to the ones used by Microsoft Basic Data Partitions.
Suggested Mode of Operation
An installer that repartitions the hard disk should use the above UUID partition types for appropriate partitions it creates.
An installer which supports a "manual partitioning" interface may choose to
pre-populate the interface with swap, /home/
, /srv/
, /var/tmp/
partitions
of pre-existing Linux installations, identified with the GPT type UUIDs
above. The installer should not pre-populate such an interface with any
identified root, /usr
or /var/
partition unless the intention is to
overwrite an existing operating system that might be installed.
An installer may omit creating entries in /etc/fstab
for root, /home/
,
/srv/
, /var/
, /var/tmp
and for the swap partitions if they use these UUID
partition types, and are the first partitions on the disk of each type. If the
ESP shall be mounted to /efi/
(or /boot/
), it may additionally omit
creating the entry for it in /etc/fstab
. If an extended boot partition is
used, or if the EFI partition shall not be mounted to /efi/
or /boot/
, it
must create /etc/fstab
entries for them. If other partitions are used (for
example for /usr/
or /var/lib/mysql/
), the installer must register these
in /etc/fstab
. The root=
parameter passed to the kernel by the boot loader
may be omitted if the root partition is the first one on the disk of its type.
If the root partition is not the first one on the disk, the root=
parameter
must be passed to the kernel by the boot loader. An installer that mounts a
root, /usr/
, /home/
, /srv/
, /var/
, or /var/tmp/
file system with the
partition types defined as above which contains a LUKS header must call the
device mapper device "root", "usr", "home", "srv", "var" or "tmp",
respectively. This is necessary to ensure that the automatic discovery will
never result in different device mapper names than any static configuration by
the installer, thus eliminating possible naming conflicts and ambiguities.
An operating system should automatically discover and mount the first
root partition that does not have the no-auto flag set (as described above) by
scanning the disk containing the currently used EFI ESP. It should
automatically discover and mount the first /usr/
, /home/
, /srv/
, /var/
,
/var/tmp/
and swap partitions that do not have the no-auto flag set by
scanning the disk containing the discovered root partition. It should
automatically discover and mount the partition containing the currently used
EFI ESP to /efi/
(or /boot/
as fallback). It should automatically discover
and mount the partition containing the currently used Extended Boot Loader
Partition to /boot/
. It should not discover or automatically mount
partitions with other UUID partition types, or partitions located on other
disks, or partitions with the no-auto flag set. User configuration shall
always override automatic discovery and mounting. If a root, /usr/
,
/home/
, /srv/
, /boot/
, /var/
, /var/tmp/
, /efi/
, /boot/
or swap
partition is listed in /etc/fstab
or with root=
on the kernel command line,
it must take precedence over automatically discovered partitions. If a
/home/
, /usr/
, /srv/
, /boot/
, /var/
, /var/tmp/
, /efi/
or /boot/
directory is found to be populated already in the root partition, the automatic
discovery must not mount any discovered file system over it. Optionally, in
case of the root, /usr/
and their Verity partitions instead of strictly
mounting the first suitable partition an OS might choose to mount the partition
whose label compares the highest according to strverscmp()
or a similar
logic, in order to implement a simple partition-based A/B versioning
scheme. The precise rules are left for the implementation to decide, but when
in doubt earlier partitions (by their index) should always win over later
partitions if the label comparison is inconclusive.
A container manager should automatically discover and mount the root,
/usr/
, /home/
, /srv/
, /var/
, /var/tmp/
partitions inside a container
disk image. It may choose to mount any discovered ESP and/or XBOOOTLDR
partition to /efi/
or /boot/
. It should ignore any swap should they be
included in a container disk image.
If a btrfs file system is automatically discovered and mounted by the operating system/container manager it will be mounted with its default subvolume. The installer should make sure to set the default subvolume correctly using "btrfs subvolume set-default".
Sharing of File Systems between Installations
If two Linux-based operating systems are installed on the same disk, the scheme
above suggests that they may share the swap, /home/
, /srv/
, /var/tmp/
,
ESP, XBOOTLDR. However, they should each have their own root, /usr/
and
/var/
partition.
Frequently Asked Questions
Why are you taking my /etc/fstab
away?
We are not. /etc/fstab
always overrides automatic discovery and is indeed
mentioned in the specifications. We are simply trying to make the boot and
installation processes of Linux a bit more robust and self-descriptive.
Why did you only define the root partition for x86, x86-64, ARM, ARM64, ia64?
The automatic discovery of the root partition is defined to operate on the disk containing the current EFI System Partition (ESP). Since EFI only exists on x86, x86-64, ia64, and ARM so far, we only defined root partition UUIDs for these architectures. Should EFI become more common on other architectures, we can define additional UUIDs for them.
Why define distinct root partition UUIDs for the various architectures?
This allows disk images that may be booted on multiple architectures to use discovery of the appropriate root partition on each architecture.
Doesn't this break multi-boot scenarios?
No, it doesn't. The specification says that installers may not stop creating
/etc/fstab
or stop including root=
on the kernel command line, unless the used
partitions are the first ones of their type on the disk. Additionally,
/etc/fstab
and root=
both override automatic discovery. Multi-boot is hence
well supported, since it doesn't change anything for anything but the first
installation.
That all said, it's not expected that generic installers generally stop setting
root=
and creating /etc/fstab
anyway. The option to drop these configuration
bits is primarily something for appliance-like devices. However, generic
installers should still set the right GPT partition types for the partitions
they create so that container managers, partition tools and administrators can
benefit. Phrased differently, this specification introduces A) the
recommendation to use the newly defined partition types to tag things
properly and B) the option to then drop root=
and /etc/fstab
. While we
advertise A) to all installers, we only propose B) for simpler,
appliance-like installations.
What partitioning tools will create a DPS-compliant partition table?
As of util-linux 2.25.2, the fdisk
tool provides type codes to create the
root, home, and swap partitions that the DPS expects. By default, fdisk
will
create an old-style MBR, not a GPT, so typing l
to list partition types will
not show the choices to let you set the correct UUID. Make sure to first create
an empty GPT, then type l
in order for the DPS-compliant type codes to be
available.
The gdisk
tool (from version 1.0.5 onward) and its variants (sgdisk
,
cgdisk
) also support creation of partitions with a matching type code.