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