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276 lines
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276 lines
15 KiB
Markdown
---
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title: Safely Building Images
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category: Concepts
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layout: default
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SPDX-License-Identifier: LGPL-2.1-or-later
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---
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# Building Images Safely
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In many scenarios OS installations are shipped as pre-built images, that
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require no further installation process beyond simple `dd`-ing the image to
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disk and booting it up. When building such "golden" OS images for
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`systemd`-based OSes a few points should be taken into account.
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Most of the points described here are implemented by the
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[`mkosi`](https://github.com/systemd/mkosi) OS image builder developed and
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maintained by the systemd project. If you are using or working on another image
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builder it's recommended to keep the following concepts and recommendations in
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mind.
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## Resources to Reset
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Typically the same OS image shall be deployable in multiple instances, and each
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instance should automatically acquire its own identifying credentials on first
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boot. For that it's essential to:
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1. Remove the
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[`/etc/machine-id`](https://www.freedesktop.org/software/systemd/man/machine-id.html)
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file or write the string `uninitialized\n` into it. This file is supposed to
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carry a 128-bit identifier unique to the system. Only when it is reset it
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will be auto-generated on first boot and thus be truly unique. If this file
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is not reset, and carries a valid ID every instance of the system will come
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up with the same ID and that will likely lead to problems sooner or later,
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as many network-visible identifiers are commonly derived from the machine
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ID, for example, IPv6 addresses or transient MAC addresses.
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2. Remove the `/var/lib/systemd/random-seed` file (see
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[`systemd-random-seed(8)`](https://www.freedesktop.org/software/systemd/man/systemd-random-seed.service.html)),
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which is used to seed the kernel's random pool on boot. If this file is
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shipped pre-initialized, every instance will seed its random pool with the
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same random data that is included in the image, and thus possibly generate
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random data that is more similar to other instances booted off the same
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image than advisable.
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3. Remove the `/loader/random-seed` file (see
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[`systemd-boot(7)`](https://www.freedesktop.org/software/systemd/man/systemd-boot.html))
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from the UEFI System Partition (ESP), in case the `systemd-boot` boot loader
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is used in the image.
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4. It might also make sense to remove
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[`/etc/hostname`](https://www.freedesktop.org/software/systemd/man/hostname.html)
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and
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[`/etc/machine-info`](https://www.freedesktop.org/software/systemd/man/machine-info.html)
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which carry additional identifying information about the OS image.
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5. Remove `/var/lib/systemd/credential.secret` which is used for protecting
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service credentials, see
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[`systemd.exec(5)`](https://www.freedesktop.org/software/systemd/man/systemd.exec.html#Credentials)
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and
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[`systemd-creds(1)`](https://www.freedesktop.org/software/systemd/man/systemd-creds.html)
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for details. Note that by removing this file access to previously encrypted
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credentials from this image is lost. The file is automatically generated if
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a new credential is encrypted and the file does not exist yet.
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## Boot Menu Entry Identifiers
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The
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[`kernel-install(8)`](https://www.freedesktop.org/software/systemd/man/kernel-install.html)
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logic used to generate
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[Boot Loader Specification Type #1](https://uapi-group.org/specifications/specs/boot_loader_specification/#type-1-boot-loader-specification-entries)
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entries by default uses the machine ID as stored in `/etc/machine-id` for
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naming boot menu entries and the directories in the ESP to place kernel images
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in. This is done in order to allow multiple installations of the same OS on the
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same system without conflicts. However, this is problematic if the machine ID
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shall be generated automatically on first boot: if the ID is not known before
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the first boot it cannot be used to name the most basic resources required for
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the boot process to complete.
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Thus, for images that shall acquire their identity on first boot only, it is
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required to use a different identifier for naming boot menu entries. To allow
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this the `kernel-install` logic knows the generalized *entry* *token* concept,
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which can be a freely chosen string to use for identifying the boot menu
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resources of the OS. If not configured explicitly it defaults to the machine
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ID. The file `/etc/kernel/entry-token` may be used to configure this string
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explicitly. Thus, golden image builders should write a suitable identifier into
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this file, for example, the `IMAGE_ID=` or `ID=` field from
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[`/etc/os-release`](https://www.freedesktop.org/software/systemd/man/os-release.html)
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(also see below). It is recommended to do this before the `kernel-install`
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functionality is invoked (i.e. before the package manager is used to install
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packages into the OS tree being prepared), so that the selected string is
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automatically used for all entries to be generated.
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## Booting with Empty `/var/` and/or Empty Root File System
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`systemd` is designed to be able to come up safely and robustly if the `/var/`
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file system or even the entire root file system (with exception of `/usr/`,
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i.e. the vendor OS resources) is empty (i.e. "unpopulated"). With this in mind
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it's relatively easy to build images that only ship a `/usr/` tree, and
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otherwise carry no other data, populating the rest of the directory hierarchy
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on first boot as needed.
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Specifically, the following mechanisms are in place:
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1. The `switch-root` logic in systemd, that is used to switch from the initrd
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phase to the host will create the basic OS hierarchy skeleton if missing. It
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will create a couple of directories strictly necessary to boot up
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successfully, plus essential symlinks (such as those necessary for the
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dynamic loader `ld.so` to function).
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2. PID 1 will initialize `/etc/machine-id` automatically if not initialized yet
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(see above).
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3. The
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[`nss-systemd(8)`](https://www.freedesktop.org/software/systemd/man/nss-systemd.html)
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glibc NSS module ensures the `root` and `nobody` users and groups remain
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resolvable, even without `/etc/passwd` and `/etc/group` around.
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4. The
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[`systemd-sysusers(8)`](https://www.freedesktop.org/software/systemd/man/systemd-sysusers.service.html)
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component will automatically populate `/etc/passwd` and `/etc/group` on
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first boot with further necessary system users.
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5. The
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[`systemd-tmpfiles(8)`](https://www.freedesktop.org/software/systemd/man/systemd-tmpfiles-setup.service.html)
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component ensures that various files and directories below `/etc/`, `/var/`
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and other places are created automatically at boot if missing. Unlike the
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directories/symlinks created by the `switch-root` logic above this logic is
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extensible by packages, and can adjust access modes, file ownership and
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more. Among others this will also link `/etc/os-release` →
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`/usr/lib/os-release`, ensuring that the OS release information is
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unconditionally accessible through `/etc/os-release`.
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6. The
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[`nss-myhostname(8)`](https://www.freedesktop.org/software/systemd/man/nss-myhostname.html)
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glibc NSS module will ensure the local host name as well as `localhost`
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remains resolvable, even without `/etc/hosts` around.
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With these mechanisms the hierarchies below `/var/` and `/etc/` can be safely
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and robustly populated on first boot, so that the OS can safely boot up. Note
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that some auxiliary package are not prepared to operate correctly if their
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configuration data in `/etc/` or their state directories in `/var/` are
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missing. This can typically be addressed via `systemd-tmpfiles` lines that
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ensure the missing files and directories are created if missing. In particular,
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configuration files that are necessary for operation can be automatically
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copied or symlinked from the `/usr/share/factory/etc/` tree via the `C` or `L`
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line types. That said, we recommend that all packages safely fall back to
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internal defaults if their configuration is missing, making such additional
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steps unnecessary.
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Note that while `systemd` itself explicitly supports booting up with entirely
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unpopulated images (`/usr/` being the only required directory to be populated)
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distributions might not be there yet: depending on your distribution further,
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manual work might be required to make this scenario work.
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## Adapting OS Images to Storage
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Typically, if an image is `dd`-ed onto a target disk it will be minimal:
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i.e. only consist of necessary vendor data, and lack "payload" data, that shall
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be individual to the system, and dependent on host parameters. On first boot,
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the OS should take possession of the backing storage as necessary, dynamically
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using available space. Specifically:
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1. Additional partitions should be created, that make no sense to ship
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pre-built in the image. For example, `/tmp/` or `/home/` partitions, or even
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`/var/` or the root file system (see above).
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2. Additional partitions should be created that shall function as A/B
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secondaries for partitions shipped in the original image. In other words: if
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the `/usr/` file system shall be updated in an A/B fashion it typically
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makes sense to ship the original A file system in the deployed image, but
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create the B partition on first boot.
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3. Partitions covering only a part of the disk should be grown to the full
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extent of the disk.
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4. File systems in uninitialized partitions should be formatted with a file
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system of choice.
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5. File systems covering only a part of a partition should be grown to the full
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extent of the partition.
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6. Partitions should be encrypted with cryptographic keys generated locally on
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the machine the system is first booted on, ensuring these keys remain local
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and are not shared with any other instance of the OS image.
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Or any combination of the above: i.e. first create a partition, then encrypt
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it, then format it.
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`systemd` provides multiple tools to implement the above logic:
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1. The
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[`systemd-repart(8)`](https://www.freedesktop.org/software/systemd/man/systemd-repart.service.html)
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component may manipulate GPT partition tables automatically on boot, growing
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partitions or adding in partitions taking the backing storage size into
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account. It can also encrypt partitions automatically it creates (even bind
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to TPM2, automatically) and populate partitions from various sources. It
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does this all in a robust fashion so that aborted invocations will not leave
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incompletely set up partitions around.
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2. The
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[`systemd-growfs@(8).service`](https://www.freedesktop.org/software/systemd/man/systemd-growfs.html)
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tool can automatically grow a file system to the partition it is contained
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in. The `x-systemd.growfs` mount option in `/etc/fstab` is sufficient to
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enable this logic for specific mounts. Alternatively appropriately set up
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partitions can set GPT partition flag 59 to request this behaviour, see the
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[Discoverable Partitions Specification](https://uapi-group.org/specifications/specs/discoverable_partitions_specification)
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for details. If the file system is already grown it executes no operation.
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3. Similar, the `systemd-makefs@.service` and `systemd-makeswap@.service`
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services can format file systems and swap spaces before first use, if they
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carry no file system signature yet. The `x-systemd.makefs` mount option in
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`/etc/fstab` may be used to request this functionality.
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## Provisioning Image Settings
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While a lot of work has gone into ensuring `systemd` systems can safely boot
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with unpopulated `/etc/` trees, it sometimes is desirable to set a couple of
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basic settings *after* `dd`-ing the image to disk, but *before* first boot. For
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this the tool
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[`systemd-firstboot(1)`](https://www.freedesktop.org/software/systemd/man/systemd-firstboot.html)
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can be useful, with its `--image=` switch. It may be used to set very basic
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settings, such as the root password or hostname on an OS disk image or
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installed block device.
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## Distinguishing First Boot
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For various purposes it's useful to be able to distinguish the first boot-up of
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the system from later boot-ups (for example, to set up TPM hardware
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specifically, or register a system somewhere). `systemd` provides mechanisms to
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implement that. Specifically, the `ConditionFirstBoot=` and `AssertFirstBoot=`
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settings may be used to conditionalize units to only run on first boot. See
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[`systemd.unit(5)`](https://www.freedesktop.org/software/systemd/man/systemd.unit.html#ConditionFirstBoot=)
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for details.
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A special target unit `first-boot-complete.target` may be used as milestone to
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safely handle first boots where the system is powered off too early: if the
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first boot process is aborted before this target is reached, the following boot
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process will be considered a first boot, too. Once the target is reached,
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subsequent boots will not be considered first boots anymore, even if the boot
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process is aborted immediately after. Thus, services that must complete fully
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before a system shall be considered fully past the first boot should be ordered
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before this target unit.
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Whether a system will come up in first boot state or not is derived from the
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initialization status of `/etc/machine-id`: if the file already carries a valid
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ID the system is already past the first boot. If it is not initialized yet it
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is still considered in the first boot state. For details see
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[`machine-id(5)`](https://www.freedesktop.org/software/systemd/man/machine-id.html).
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## Image Metadata
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Typically, when operating with golden disk images it is useful to be able to
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identify them and their version. For this the two fields `IMAGE_ID=` and
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`IMAGE_VERSION=` have been defined in
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[`os-release(5)`](https://www.freedesktop.org/software/systemd/man/os-release.html). These
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fields may be accessed from unit files and similar via the `%M` and `%A`
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specifiers.
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Depending on how the images are put together it might make sense to leave the
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OS distribution's `os-release` file as is in `/usr/lib/os-release` but to
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replace the usual `/etc/os-release` symlink with a regular file that extends
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the distribution's file with one augmented with these two additional
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fields.
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## Links
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[`machine-id(5)`](https://www.freedesktop.org/software/systemd/man/machine-id.html)<br>
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[`systemd-random-seed(8)`](https://www.freedesktop.org/software/systemd/man/systemd-random-seed.service.html)<br>
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[`os-release(5)`](https://www.freedesktop.org/software/systemd/man/os-release.html)<br>
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[Boot Loader Specification](https://uapi-group.org/specifications/specs/boot_loader_specification)<br>
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[Discoverable Partitions Specification](https://uapi-group.org/specifications/specs/discoverable_partitions_specification)<br>
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[`mkosi`](https://github.com/systemd/mkosi)<br>
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[`systemd-boot(7)`](https://www.freedesktop.org/software/systemd/man/systemd-boot.html)<br>
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[`systemd-repart(8)`](https://www.freedesktop.org/software/systemd/man/systemd-repart.service.html)<br>
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[`systemd-growfs@(8).service`](https://www.freedesktop.org/software/systemd/man/systemd-growfs.html)<br>
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