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With this the concept is now called the same way everywhere except where historical info is relevant or where the other names are API.
327 lines
18 KiB
Markdown
327 lines
18 KiB
Markdown
---
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title: Users, Groups, UIDs and GIDs on systemd Systems
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category: Users, Groups and Home Directories
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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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# Users, Groups, UIDs and GIDs on systemd Systems
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Here's a summary of the requirements `systemd` (and Linux) make on UID/GID
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assignments and their ranges.
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Note that while in theory UIDs and GIDs are orthogonal concepts they really
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aren't IRL. With that in mind, when we discuss UIDs below it should be assumed
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that whatever we say about UIDs applies to GIDs in mostly the same way, and all
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the special assignments and ranges for UIDs always have mostly the same
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validity for GIDs too.
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## Special Linux UIDs
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In theory, the range of the C type `uid_t` is 32bit wide on Linux,
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i.e. 0…4294967295. However, four UIDs are special on Linux:
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1. 0 → The `root` super-user
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2. 65534 → The `nobody` UID, also called the "overflow" UID or similar. It's
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where various subsystems map unmappable users to, for example file systems
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only supporting 16bit UIDs, NFS or user namespacing. (The latter can be
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changed with a sysctl during runtime, but that's not supported on
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`systemd`. If you do change it you void your warranty.) Because Fedora is a
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bit confused the `nobody` user is called `nfsnobody` there (and they have a
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different `nobody` user at UID 99). I hope this will be corrected eventually
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though. (Also, some distributions call the `nobody` group `nogroup`. I wish
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they didn't.)
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3. 4294967295, aka "32bit `(uid_t) -1`" → This UID is not a valid user ID, as
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`setresuid()`, `chown()` and friends treat -1 as a special request to not
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change the UID of the process/file. This UID is hence not available for
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assignment to users in the user database.
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4. 65535, aka "16bit `(uid_t) -1`" → Before Linux kernel 2.4 `uid_t` used to be
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16bit, and programs compiled for that would hence assume that `(uid_t) -1`
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is 65535. This UID is hence not usable either.
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The `nss-systemd` glibc NSS module will synthesize user database records for
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the UIDs 0 and 65534 if the system user database doesn't list them. This means
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that any system where this module is enabled works to some minimal level
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without `/etc/passwd`.
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## Special Distribution UID ranges
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Distributions generally split the available UID range in two:
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1. 1…999 → System users. These are users that do not map to actual "human"
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users, but are used as security identities for system daemons, to implement
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privilege separation and run system daemons with minimal privileges.
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2. 1000…65533 and 65536…4294967294 → Everything else, i.e. regular (human) users.
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Note that most distributions allow changing the boundary between system and
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regular users, even during runtime as user configuration. Moreover, some older
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systems placed the boundary at 499/500, or even 99/100. In `systemd`, the
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boundary is configurable only during compilation time, as this should be a
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decision for distribution builders, not for users. Moreover, we strongly
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discourage downstreams to change the boundary from the upstream default of
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999/1000.
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Also note that programs such as `adduser` tend to allocate from a subset of the
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available regular user range only, usually 1000..60000. And it's also usually
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user-configurable, too.
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Note that systemd requires that system users and groups are resolvable without
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networking available — a requirement that is not made for regular users. This
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means regular users may be stored in remote LDAP or NIS databases, but system
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users may not (except when there's a consistent local cache kept, that is
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available during earliest boot, including in the initrd).
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## Special `systemd` GIDs
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`systemd` defines no special UIDs beyond what Linux already defines (see
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above). However, it does define some special group/GID assignments, which are
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primarily used for `systemd-udevd`'s device management. The precise list of the
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currently defined groups is found in this `sysusers.d` snippet:
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[basic.conf](https://raw.githubusercontent.com/systemd/systemd/main/sysusers.d/basic.conf.in)
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It's strongly recommended that downstream distributions include these groups in
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their default group databases.
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Note that the actual GID numbers assigned to these groups do not have to be
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constant beyond a specific system. There's one exception however: the `tty`
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group must have the GID 5. That's because it must be encoded in the `devpts`
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mount parameters during earliest boot, at a time where NSS lookups are not
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possible. (Note that the actual GID can be changed during `systemd` build time,
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but downstreams are strongly advised against doing that.)
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## Special `systemd` UID ranges
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`systemd` defines a number of special UID ranges:
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1. 60001…60513 → UIDs for home directories managed by
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[`systemd-homed.service(8)`](https://www.freedesktop.org/software/systemd/man/systemd-homed.service.html). UIDs
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from this range are automatically assigned to any home directory discovered,
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and persisted locally on first login. On different systems the same user
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might get different UIDs assigned in case of conflict, though it is
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attempted to make UID assignments stable, by deriving them from a hash of
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the user name.
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2. 61184…65519 → UIDs for dynamic users are allocated from this range (see the
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`DynamicUser=` documentation in
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[`systemd.exec(5)`](https://www.freedesktop.org/software/systemd/man/systemd.exec.html)). This
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range has been chosen so that it is below the 16bit boundary (i.e. below
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65535), in order to provide compatibility with container environments that
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assign a 64K range of UIDs to containers using user namespacing. This range
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is above the 60000 boundary, so that its allocations are unlikely to be
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affected by `adduser` allocations (see above). And we leave some room
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upwards for other purposes. (And if you wonder why precisely these numbers:
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if you write them in hexadecimal, they might make more sense: 0xEF00 and
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0xFFEF). The `nss-systemd` module will synthesize user records implicitly
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for all currently allocated dynamic users from this range. Thus, NSS-based
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user record resolving works correctly without those users being in
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`/etc/passwd`.
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3. 524288…1879048191 → UID range for `systemd-nspawn`'s automatic allocation of
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per-container UID ranges. When the `--private-users=pick` switch is used (or
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`-U`) then it will automatically find a so far unused 16bit subrange of this
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range and assign it to the container. The range is picked so that the upper
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16bit of the 32bit UIDs are constant for all users of the container, while
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the lower 16bit directly encode the 65536 UIDs assigned to the
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container. This mode of allocation means that the upper 16bit of any UID
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assigned to a container are kind of a "container ID", while the lower 16bit
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directly expose the container's own UID numbers. If you wonder why precisely
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these numbers, consider them in hexadecimal: 0x00080000…0x6FFFFFFF. This
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range is above the 16bit boundary. Moreover it's below the 31bit boundary,
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as some broken code (specifically: the kernel's `devpts` file system)
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erroneously considers UIDs signed integers, and hence can't deal with values
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above 2^31. The `systemd-machined.service` service will synthesize user
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database records for all UIDs assigned to a running container from this
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range.
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Note for both allocation ranges: when an UID allocation takes place NSS is
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checked for collisions first, and a different UID is picked if an entry is
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found. Thus, the user database is used as synchronization mechanism to ensure
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exclusive ownership of UIDs and UID ranges. To ensure compatibility with other
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subsystems allocating from the same ranges it is hence essential that they
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ensure that whatever they pick shows up in the user/group databases, either by
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providing an NSS module, or by adding entries directly to `/etc/passwd` and
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`/etc/group`. For performance reasons, do note that `systemd-nspawn` will only
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do an NSS check for the first UID of the range it allocates, not all 65536 of
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them. Also note that while the allocation logic is operating, the glibc
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`lckpwdf()` user database lock is taken, in order to make this logic race-free.
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## Figuring out the system's UID boundaries
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The most important boundaries of the local system may be queried with
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`pkg-config`:
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```
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$ pkg-config --variable=systemuidmax systemd
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999
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$ pkg-config --variable=dynamicuidmin systemd
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61184
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$ pkg-config --variable=dynamicuidmax systemd
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65519
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$ pkg-config --variable=containeruidbasemin systemd
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524288
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$ pkg-config --variable=containeruidbasemax systemd
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1878982656
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```
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(Note that the latter encodes the maximum UID *base* `systemd-nspawn` might
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pick — given that 64K UIDs are assigned to each container according to this
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allocation logic, the maximum UID used for this range is hence
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1878982656+65535=1879048191.)
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Systemd has compile-time default for these boundaries. Using those defaults is
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recommended. It will nevertheless query `/etc/login.defs` at runtime, when
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compiled with `-Dcompat-mutable-uid-boundaries=true` and that file is present.
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Support for this is considered only a compatibility feature and should not be
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used except when upgrading systems which were created with different defaults.
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## Considerations for container managers
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If you hack on a container manager, and wonder how and how many UIDs best to
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assign to your containers, here are a few recommendations:
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1. Definitely, don't assign less than 65536 UIDs/GIDs. After all the `nobody`
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user has magic properties, and hence should be available in your container, and
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given that it's assigned the UID 65534, you should really cover the full 16bit
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range in your container. Note that systemd will — as mentioned — synthesize
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user records for the `nobody` user, and assumes its availability in various
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other parts of its codebase, too, hence assigning fewer users means you lose
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compatibility with running systemd code inside your container. And most likely
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other packages make similar restrictions.
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2. While it's fine to assign more than 65536 UIDs/GIDs to a container, there's
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most likely not much value in doing so, as Linux distributions won't use the
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higher ranges by default (as mentioned neither `adduser` nor `systemd`'s
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dynamic user concept allocate from above the 16bit range). Unless you actively
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care for nested containers, it's hence probably a good idea to allocate exactly
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65536 UIDs per container, and neither less nor more. A pretty side-effect is
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that by doing so, you expose the same number of UIDs per container as Linux 2.2
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supported for the whole system, back in the days.
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3. Consider allocating UID ranges for containers so that the first UID you
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assign has the lower 16bits all set to zero. That way, the upper 16bits become
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a container ID of some kind, while the lower 16bits directly encode the
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internal container UID. This is the way `systemd-nspawn` allocates UID ranges
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(see above). Following this allocation logic ensures best compatibility with
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`systemd-nspawn` and all other container managers following the scheme, as it
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is sufficient then to check NSS for the first UID you pick regarding conflicts,
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as that's what they do, too. Moreover, it makes `chown()`ing container file
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system trees nicely robust to interruptions: as the external UID encodes the
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internal UID in a fixed way, it's very easy to adjust the container's base UID
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without the need to know the original base UID: to change the container base,
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just mask away the upper 16bit, and insert the upper 16bit of the new container
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base instead. Here are the easy conversions to derive the internal UID, the
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external UID, and the container base UID from each other:
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```
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INTERNAL_UID = EXTERNAL_UID & 0x0000FFFF
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CONTAINER_BASE_UID = EXTERNAL_UID & 0xFFFF0000
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EXTERNAL_UID = INTERNAL_UID | CONTAINER_BASE_UID
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```
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4. When picking a UID range for containers, make sure to check NSS first, with
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a simple `getpwuid()` call: if there's already a user record for the first UID
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you want to pick, then it's already in use: pick a different one. Wrap that
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call in a `lckpwdf()` + `ulckpwdf()` pair, to make allocation
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race-free. Provide an NSS module that makes all UIDs you end up taking show up
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in the user database, and make sure that the NSS module returns up-to-date
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information before you release the lock, so that other system components can
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safely use the NSS user database as allocation check, too. Note that if you
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follow this scheme no changes to `/etc/passwd` need to be made, thus minimizing
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the artifacts the container manager persistently leaves in the system.
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5. `systemd-homed` by default mounts the home directories it manages with UID
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mapping applied. It will map four UID ranges into that uidmap, and leave
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everything else unmapped: the range from 0…60000, the user's own UID, the range
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60514…65534, and the container range 524288…1879048191. This means
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files/directories in home directories managed by `systemd-homed` cannot be
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owned by UIDs/GIDs outside of these four ranges (attempts to `chown()` files to
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UIDs outside of these ranges will fail). Thus, if container trees are to be
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placed within a home directory managed by `systemd-homed` they should take
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these ranges into consideration and either place the trees at base UID 0 (and
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then map them to a higher UID range for use in user namespacing via another
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level of UID mapped mounts, at *runtime*) or at a base UID from the container
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UID range. That said, placing container trees (and in fact any
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files/directories not owned by the home directory's user) in home directories
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is generally a questionable idea (regardless of whether `systemd-homed` is used
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or not), given this typically breaks quota assumptions, makes it impossible for
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users to properly manage all files in their own home directory due to
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permission problems, introduces security issues around SETUID and severely
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restricts compatibility with networked home directories. Typically, it's a much
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better idea to place container images outside of the home directory,
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i.e. somewhere below `/var/` or similar.
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## Summary
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| UID/GID | Purpose | Defined By | Listed in |
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|-----------------------|-----------------------|---------------|-------------------------------|
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| 0 | `root` user | Linux | `/etc/passwd` + `nss-systemd` |
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| 1…4 | System users | Distributions | `/etc/passwd` |
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| 5 | `tty` group | `systemd` | `/etc/passwd` |
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| 6…999 | System users | Distributions | `/etc/passwd` |
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| 1000…60000 | Regular users | Distributions | `/etc/passwd` + LDAP/NIS/… |
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| 60001…60513 | Human users (homed) | `systemd` | `nss-systemd` |
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| 60514…60577 | Host users mapped into containers | `systemd` | `systemd-nspawn` |
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| 60578…61183 | Unused | | |
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| 61184…65519 | Dynamic service users | `systemd` | `nss-systemd` |
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| 65520…65533 | Unused | | |
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| 65534 | `nobody` user | Linux | `/etc/passwd` + `nss-systemd` |
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| 65535 | 16bit `(uid_t) -1` | Linux | |
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| 65536…524287 | Unused | | |
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| 524288…1879048191 | Container UID ranges | `systemd` | `nss-systemd` |
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| 1879048192…2147483647 | Unused | | |
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| 2147483648…4294967294 | HIC SVNT LEONES | | |
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| 4294967295 | 32bit `(uid_t) -1` | Linux | |
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Note that "Unused" in the table above doesn't mean that these ranges are
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really unused. It just means that these ranges have no well-established
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pre-defined purposes between Linux, generic low-level distributions and
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`systemd`. There might very well be other packages that allocate from these
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ranges.
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Note that the range 2147483648…4294967294 (i.e. 2^31…2^32-2) should be handled
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with care. Various programs (including kernel file systems — see `devpts` — or
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even kernel syscalls – see `setfsuid()`) have trouble with UIDs outside of the
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signed 32bit range, i.e any UIDs equal to or above 2147483648. It is thus
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strongly recommended to stay away from this range in order to avoid
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complications. This range should be considered reserved for future, special
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purposes.
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## Notes on resolvability of user and group names
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User names, UIDs, group names and GIDs don't have to be resolvable using NSS
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(i.e. getpwuid() and getpwnam() and friends) all the time. However, systemd
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makes the following requirements:
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System users generally have to be resolvable during early boot already. This
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means they should not be provided by any networked service (as those usually
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become available during late boot only), except if a local cache is kept that
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makes them available during early boot too (i.e. before networking is
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up). Specifically, system users need to be resolvable at least before
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`systemd-udevd.service` and `systemd-tmpfiles.service` are started, as both
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need to resolve system users — but note that there might be more services
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requiring full resolvability of system users than just these two.
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Regular users do not need to be resolvable during early boot, it is sufficient
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if they become resolvable during late boot. Specifically, regular users need to
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be resolvable at the point in time the `nss-user-lookup.target` unit is
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reached. This target unit is generally used as synchronization point between
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providers of the user database and consumers of it. Services that require that
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the user database is fully available (for example, the login service
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`systemd-logind.service`) are ordered *after* it, while services that provide
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parts of the user database (for example an LDAP user database client) are
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ordered *before* it. Note that `nss-user-lookup.target` is a *passive* unit: in
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order to minimize synchronization points on systems that don't need it the unit
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is pulled into the initial transaction only if there's at least one service
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that really needs it, and that means only if there's a service providing the
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local user database somehow through IPC or suchlike. Or in other words: if you
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hack on some networked user database project, then make sure you order your
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service `Before=nss-user-lookup.target` and that you pull it in with
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`Wants=nss-user-lookup.target`. However, if you hack on some project that needs
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the user database to be up in full, then order your service
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`After=nss-user-lookup.target`, but do *not* pull it in via a `Wants=`
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dependency.
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