file-hierarchy — File system hierarchy overview
Operating systems using the
systemd(1) system and
service manager are organized based on a file system hierarchy inspired by UNIX, more specifically the
hierarchy described in the File
System Hierarchy specification and hier(7), with
various extensions, partially documented in the XDG Base Directory
Specification and XDG User
Directories. This manual page describes a more generalized, though minimal and modernized subset
of these specifications that defines more strictly the suggestions and restrictions systemd makes on the
file system hierarchy. Note that this document makes no attempt to define the directory structure
comprehensively, it only documents a skeleton of a directory tree, that downstreams can extend. Because
of that traditional directories such as /usr/include/
or
/var/spool/
are not covered, even though it might (or might not) make a lot of sense
to include them in the structure of an actually deployed OS.
Many of the paths described here can be queried with the systemd-path(1) tool.
/
¶The file system root. Usually writable, but this is not required. Possibly a
temporary file system ("tmpfs
"). Not shared with other hosts (unless
read-only).
/boot/
¶The boot partition used for bringing up the system. On EFI systems, this is possibly the EFI System Partition (ESP), also see systemd-gpt-auto-generator(8). This directory is usually strictly local to the host, and should be considered read-only, except when a new kernel or boot loader is installed. This directory only exists on systems that run on physical or emulated hardware that requires boot loaders.
/efi/
¶If the boot partition /boot/
is maintained separately from the
EFI System Partition (ESP), the latter is mounted here. Tools that need to operate on the EFI system
partition should look for it at this mount point first, and fall back to /boot/
— if the former doesn't qualify (for example if it is not a mount point or does not have the correct
file system type MSDOS_SUPER_MAGIC
).
/etc/
¶System-specific configuration. This directory may or may not be read-only. Frequently, this directory is pre-populated with vendor-supplied configuration files, but applications should not make assumptions about this directory being fully populated or populated at all, and should fall back to defaults if configuration is missing.
/home/
¶The location for normal user's home directories. Possibly shared with other systems,
and never read-only. This directory should only be used for normal users, never for system
users. This directory and possibly the directories contained within it might only become available or
writable in late boot or even only after user authentication. This directory might be placed on
limited-functionality network file systems, hence applications should not assume the full set of file
API is available on this directory. Applications should generally not reference this directory
directly, but via the per-user $HOME
environment variable, or via the home
directory field of the user database.
/root/
¶The home directory of the root user. The root user's home directory is located
outside of /home/
in order to make sure the root user may log in even without
/home/
being available and mounted.
/srv/
¶The place to store general server payload, managed by the administrator. No restrictions are made how this directory is organized internally. Generally writable, and possibly shared among systems. This directory might become available or writable only very late during boot.
/tmp/
¶The place for small temporary files. This directory is usually mounted as a
"tmpfs
" instance, and should hence not be used for larger files. (Use
/var/tmp/
for larger files.) This directory is usually flushed at boot-up. Also,
files that are not accessed within a certain time may be automatically deleted.
If applications find the environment variable $TMPDIR
set, they should use
the directory specified in it instead of /tmp/
(see environ(7) and
IEEE
Std 1003.1 for details).
Since /tmp/
is accessible to other users of the system, it is essential
that files and subdirectories under this directory are only created with mkstemp(3),
mkdtemp(3),
and similar calls. For more details, see Using
/tmp/ and /var/tmp/ Safely.
/run/
¶A "tmpfs
" file system for system packages to place runtime data,
socket files, and similar. This directory is flushed on boot, and generally writable for privileged
programs only. Always writable.
/run/log/
¶Runtime system logs. System components may place private logs in this
directory. Always writable, even when /var/log/
might not be accessible
yet.
/run/user/
¶Contains per-user runtime directories, each usually individually mounted
"tmpfs
" instances. Always writable, flushed at each reboot and when the user logs
out. User code should not reference this directory directly, but via the
$XDG_RUNTIME_DIR
environment variable, as documented in the XDG Base Directory
Specification.
/usr/
¶Vendor-supplied operating system resources. Usually read-only, but this is not required. Possibly shared between multiple hosts. This directory should not be modified by the administrator, except when installing or removing vendor-supplied packages.
/usr/bin/
¶Binaries and executables for user commands that shall appear in the
$PATH
search path. It is recommended not to place binaries in this directory that
are not useful for invocation from a shell (such as daemon binaries); these should be placed in a
subdirectory of /usr/lib/
instead.
/usr/lib/
¶Static, private vendor data that is compatible with all architectures (though not
necessarily architecture-independent). Note that this includes internal executables or other binaries
that are not regularly invoked from a shell. Such binaries may be for any architecture supported by
the system. Do not place public libraries in this directory, use $libdir
(see
below), instead.
/usr/lib/arch-id
/
¶Location for placing dynamic libraries into, also called
$libdir
. The architecture identifier to use is defined on Multiarch Architecture Specifiers (Tuples)
list. Legacy locations of $libdir
are /usr/lib/
,
/usr/lib64/
. This directory should not be used for package-specific data, unless
this data is architecture-dependent, too.
To query $libdir
for the primary architecture of the system, invoke:
systemd-path system-library-arch
Resources shared between multiple packages, such as documentation, man pages, time zone information, fonts and other resources. Usually, the precise location and format of files stored below this directory is subject to specifications that ensure interoperability.
Note that resources placed in this directory typically are under shared ownership,
i.e. multiple different packages have provide and consume these resources, on equal footing, without
any obvious primary owner. This makes makes things systematically different from
/usr/lib/
, where ownership is generally not shared.
Documentation for the operating system or system packages.
Repository for vendor-supplied default configuration files. This directory should be
populated with pristine vendor versions of all configuration files that may be placed in
/etc/
. This is useful to compare the local configuration of a system with vendor
defaults and to populate the local configuration with defaults.
Similar to
/usr/share/factory/etc/
, but for vendor
versions of files in the variable, persistent data directory
/var/
.
/var/
¶Persistent, variable system data. Writable during normal system operation. This directory might be pre-populated with vendor-supplied data, but applications should be able to reconstruct necessary files and directories in this subhierarchy should they be missing, as the system might start up without this directory being populated. Persistency is recommended, but optional, to support ephemeral systems. This directory might become available or writable only very late during boot. Components that are required to operate during early boot hence shall not unconditionally rely on this directory.
/var/cache/
¶Persistent system cache data. System components may place non-essential data in this directory. Flushing this directory should have no effect on operation of programs, except for increased runtimes necessary to rebuild these caches.
/var/lib/
¶Persistent system data. System components may place private data in this directory.
/var/log/
¶Persistent system logs. System components may place private logs in this directory, though it is recommended to do most logging via the syslog(3) and sd_journal_print(3) calls.
/var/tmp/
¶The place for larger and persistent temporary files. In contrast to
/tmp/
, this directory is usually mounted from a persistent physical file system
and can thus accept larger files. (Use /tmp/
for small ephemeral files.) This
directory is generally not flushed at boot-up, but time-based cleanup of files that have not been
accessed for a certain time is applied.
If applications find the environment variable $TMPDIR
set, they should use
the directory specified in it instead of /var/tmp/
(see environ(7) for
details).
The same security restrictions as with /tmp/
apply: mkstemp(3),
mkdtemp(3),
and similar calls should be used. For further details about this directory, see Using /tmp/ and /var/tmp/
Safely.
/dev/
¶The root directory for device nodes. Usually, this directory is mounted as a
"devtmpfs
" instance, but might be of a different type in sandboxed/containerized
setups. This directory is managed jointly by the kernel and
systemd-udevd(8),
and should not be written to by other components. A number of special purpose virtual file systems
might be mounted below this directory.
/dev/shm/
¶Place for POSIX shared memory segments, as created via shm_open(3).
This directory is flushed on boot, and is a "tmpfs
" file system. Since all users
have write access to this directory, special care should be taken to avoid name clashes and
vulnerabilities. For normal users, shared memory segments in this directory are usually deleted when
the user logs out. Usually, it is a better idea to use memory mapped files in
/run/
(for system programs) or $XDG_RUNTIME_DIR
(for user
programs) instead of POSIX shared memory segments, since these directories are not world-writable and
hence not vulnerable to security-sensitive name clashes.
/proc/
¶A virtual kernel file system exposing the process list and other functionality. This file system is mostly an API to interface with the kernel and not a place where normal files may be stored. For details, see proc(5). A number of special purpose virtual file systems might be mounted below this directory.
/proc/sys/
¶A hierarchy below /proc/
that exposes a number of kernel
tunables. The primary way to configure the settings in this API file tree is via
sysctl.d(5)
files. In sandboxed/containerized setups, this directory is generally mounted
read-only.
/sys/
¶A virtual kernel file system exposing discovered devices and other functionality. This file system is mostly an API to interface with the kernel and not a place where normal files may be stored. In sandboxed/containerized setups, this directory is generally mounted read-only. A number of special purpose virtual file systems might be mounted below this directory.
/sys/fs/cgroup/
¶A virtual kernel file system exposing process control groups (cgroups). This file
system is an API to interface with the kernel and not a place where normal files may be stored. On
current systems running in the default "unified" mode, this directory serves as the mount point for
the "cgroup2
" filesystem, which provides a unified cgroup hierarchy for all resource
controllers. On systems with non-default configurations, this directory may instead be a tmpfs
filesystem containing mount points for various "cgroup
" (v1) resource controllers;
in such configurations, if "cgroup2
" is mounted it will be mounted on
/sys/fs/cgroup/unified/
, but cgroup2 will not have resource controllers
attached. In sandboxed/containerized setups, this directory may either not exist or may include a
subset of functionality.
/bin/
, /sbin/
, /usr/sbin/
¶These compatibility symlinks point to /usr/bin/
, ensuring that
scripts and binaries referencing these legacy paths correctly find their binaries.
/lib/
¶This compatibility symlink points to /usr/lib/
, ensuring that
programs referencing this legacy path correctly find their resources.
/lib64/
¶On some architecture ABIs, this compatibility symlink points to
$libdir
, ensuring that binaries referencing this legacy path correctly find their
dynamic loader. This symlink only exists on architectures whose ABI places the dynamic loader in this
path.
/var/run/
¶This compatibility symlink points to /run/
, ensuring that
programs referencing this legacy path correctly find their runtime data.
User applications may want to place files and directories in the user's home directory. They should follow the following basic structure. Note that some of these directories are also standardized (though more weakly) by the XDG Base Directory Specification. Additional locations for high-level user resources are defined by xdg-user-dirs.
~/.cache/
¶Persistent user cache data. User programs may place non-essential data in this
directory. Flushing this directory should have no effect on operation of programs, except for
increased runtimes necessary to rebuild these caches. If an application finds
$XDG_CACHE_HOME
set, it should use the directory specified in it instead of this
directory.
~/.config/
¶Application configuration. When a new user is created, this directory will be empty
or not exist at all. Applications should fall back to defaults should their configuration in this
directory be missing. If an application finds $XDG_CONFIG_HOME
set, it should use
the directory specified in it instead of this directory.
~/.local/bin/
¶Executables that shall appear in the user's $PATH
search path. It
is recommended not to place executables in this directory that are not useful for invocation from a
shell; these should be placed in a subdirectory of ~/.local/lib/
instead. Care
should be taken when placing architecture-dependent binaries in this place, which might be
problematic if the home directory is shared between multiple hosts with different
architectures.
~/.local/lib/
¶Static, private vendor data that is compatible with all architectures.
~/.local/lib/arch-id
/
¶Location for placing public dynamic libraries. The architecture identifier to use is defined on Multiarch Architecture Specifiers (Tuples) list.
Resources shared between multiple packages, such as fonts or artwork. Usually, the
precise location and format of files stored below this directory is subject to specifications that
ensure interoperability. If an application finds $XDG_DATA_HOME
set, it should use
the directory specified in it instead of this directory.
~/.local/state/
¶Application state. When a new user is created, this directory will be empty or not
exist at all. Applications should fall back to defaults should their state in this directory be
missing. If an application finds $XDG_STATE_HOME
set, it should use the directory
specified in it instead of this directory.
Unprivileged processes generally lack write access to most of the hierarchy.
The exceptions for normal users are
/tmp/
,
/var/tmp/
,
/dev/shm/
, as well as the home directory
$HOME
(usually found below
/home/
) and the runtime directory
$XDG_RUNTIME_DIR
(found below
/run/user/
) of the user, which are all
writable.
For unprivileged system processes, only
/tmp/
,
/var/tmp/
and
/dev/shm/
are writable. If an
unprivileged system process needs a private writable directory in
/var/
or /run/
, it is
recommended to either create it before dropping privileges in the
daemon code, to create it via
tmpfiles.d(5)
fragments during boot, or via the
StateDirectory=
and RuntimeDirectory=
directives of service units (see
systemd.unit(5)
for details).
/tmp/
, /var/tmp/
and /dev/shm/
should be mounted nosuid
and nodev
, which means that set-user-id mode
and character or block special devices are not interpreted on those file systems. In general it is not
possible to mount them noexec
, because various programs use those directories for
dynamically generated or optimized code, and with that flag those use cases would break. Using this
flag is OK on special-purpose installations or systems where all software that may be installed is
known and doesn't require such functionality. See the discussion of
nosuid
/nodev
/noexec
in mount(8) and
PROT_EXEC
in mmap(2).
As noted above, some systems operate with the /usr
and
/etc
hierarchies mounted read-only, possibly only allowing write access during
package upgrades. Other part of the hierarchy are generally mounted read-write (in particular
/var
and /var/tmp
), but may be read-only when the kernel
remounts the file system read-only in response to errors, or when the system is booted read-only for
recovery purposes. To the extent reasonable, applications should be prepared to execute without write
access, so that for example, failure to save non-essential data to /var/cache/
or
failure to create a custom log file under /var/log
does not prevent the
application from running.
The /run/
directory is available since the earliest boot and is always
writable. It should be used for any runtime data and sockets, so that write access to e.g.
/etc
or /var
is not needed.
Unix file systems support different types of file nodes, including regular files, directories, symlinks, character and block device nodes, sockets and FIFOs.
It is strongly recommended that /dev/
is
the only location below which device nodes shall be placed.
Similarly, /run/
shall be the only location to
place sockets and FIFOs. Regular files, directories and symlinks
may be used in all directories.
Applications should expect that a security policy might be enforced on a system that enforces these rules.
Developers of system packages should follow strict rules when placing their files in the file system. The following table lists recommended locations for specific types of files supplied by the vendor.
Table 1. System package vendor files locations
Directory | Purpose |
---|---|
/usr/bin/ | Package executables that shall appear in the $PATH executable search path, compiled for any of the supported architectures compatible with the operating system. It is not recommended to place internal binaries or binaries that are not commonly invoked from the shell in this directory, such as daemon binaries. As this directory is shared with most other packages of the system, special care should be taken to pick unique names for files placed here, that are unlikely to clash with other package's files. |
/usr/lib/ | Public shared libraries of the package. As above, be careful with using too generic names, and pick unique names for your libraries to place here to avoid name clashes. |
/usr/lib/ | Private static vendor resources of the package, including private binaries and libraries, or any other kind of read-only vendor data. |
/usr/lib/ | Private other vendor resources of the package that are architecture-specific and cannot be shared between architectures. Note that this generally does not include private executables since binaries of a specific architecture may be freely invoked from any other supported system architecture. |
Additional static vendor files with shared ownership may be installed in the
/usr/share/
hierarchy to the locations defined by the various relevant
specifications.
The following directories shall be used by the package for local configuration and files created during runtime:
Table 2. System package variable files locations
Directory | Purpose |
---|---|
/etc/ | System-specific configuration for the package. It is recommended to default to safe fallbacks if this configuration is missing, if this is possible. Alternatively, a tmpfiles.d(5) fragment may be used to copy or symlink the necessary files and directories from /usr/share/factory/ during boot, via the "L " or "C " directives. |
/run/ | Runtime data for the package. Packages must be able to create the necessary subdirectories in this tree on their own, since the directory is flushed automatically on boot. Alternatively, a tmpfiles.d(5) fragment may be used to create the necessary directories during boot, or the RuntimeDirectory= directive of service units may be used to create them at service startup (see systemd.unit(5) for details). |
/run/log/ | Runtime log data for the package. As above, the package needs to make sure to create this directory if necessary, as it will be flushed on every boot. |
/var/cache/ | Persistent cache data of the package. If this directory is flushed, the application should work correctly on next invocation, though possibly slowed down due to the need to rebuild any local cache files. The application must be capable of recreating this directory should it be missing and necessary. To create an empty directory, a tmpfiles.d(5) fragment or the CacheDirectory= directive of service units (see systemd.unit(5)) may be used. |
/var/lib/ | Persistent private data of the package. This is the primary place to put persistent data that does not fall into the other categories listed. Packages should be able to create the necessary subdirectories in this tree on their own, since the directory might be missing on boot. To create an empty directory, a tmpfiles.d(5) fragment or the StateDirectory= directive of service units (see systemd.unit(5)) may be used. |
/var/log/ | Persistent log data of the package. As above, the package should make sure to create this directory if necessary, possibly using tmpfiles.d(5) or LogsDirectory= (see systemd.exec(5)), as it might be missing. |
Programs running in user context should follow strict rules when placing their own files in the user's home directory. The following table lists recommended locations in the home directory for specific types of files supplied by the vendor if the application is installed in the home directory. (User applications installed system-wide are covered by the rules outlined above for vendor files.)
Table 3. Vendor package file locations under the home directory of the user
Directory | Purpose |
---|---|
~/.local/bin/ | Package executables that shall appear in the $PATH executable search path. It is not recommended to place internal executables or executables that are not commonly invoked from the shell in this directory, such as daemon executables. As this directory is shared with most other packages of the user, special care should be taken to pick unique names for files placed here, that are unlikely to clash with other package's files. |
~/.local/lib/ | Public shared libraries of the package. As above, be careful with using overly generic names, and pick unique names for your libraries to place here to avoid name clashes. |
~/.local/lib/ | Private, static vendor resources of the package, compatible with any architecture, or any other kind of read-only vendor data. |
~/.local/lib/ | Private other vendor resources of the package that are architecture-specific and cannot be shared between architectures. |
Additional static vendor files with shared ownership may be installed in the
~/.local/share/
hierarchy, mirroring the subdirectories specified in the section
"Vendor-supplied operating system resources" above.
The following directories shall be used by the package for per-user local configuration and files created during runtime:
Table 4. User package variable file locations
Directory | Purpose |
---|---|
~/.config/ | User-specific configuration for the package. It is required to default to safe fallbacks if this configuration is missing. |
| User runtime data for the package. |
~/.cache/ | Persistent cache data of the package. If this directory is flushed, the application should work correctly on next invocation, though possibly slowed down due to the need to rebuild any local cache files. The application must be capable of recreating this directory should it be missing and necessary. |
~/.local/state/ | Persistent state data of the package. |