credentials - process identifiers
Each process has a unique nonnegative integer identifier that is
assigned when the process is created using fork(2). A
process can obtain its PID using getpid(2). A PID is
represented using the type
pid_t (defined in
PIDs are used in a range of system calls to identify the process affected by the call, for example: kill(2), ptrace(2), setpriority(2) setpgid(2), setsid(2), sigqueue(3), and waitpid(2).
A process's PID is preserved across an execve(2).
A process's parent process ID identifies the process that created
this process using fork(2). A process can obtain its
PPID using getppid(2). A PPID is represented using the
A process's PPID is preserved across an execve(2).
Each process has a session ID and a process group ID, both
represented using the type
pid_t. A process can obtain its
session ID using getsid(2), and its process group ID
A child created by fork(2) inherits its parent's session ID and process group ID. A process's session ID and process group ID are preserved across an execve(2).
Sessions and process groups are abstractions devised to support shell job control. A process group (sometimes called a "job") is a collection of processes that share the same process group ID; the shell creates a new process group for the process(es) used to execute single command or pipeline (e.g., the two processes created to execute the command "ls | wc" are placed in the same process group). A process's group membership can be set using setpgid(2). The process whose process ID is the same as its process group ID is the process group leader for that group.
A session is a collection of processes that share the same session
ID. All of the members of a process group also have the same session ID
(i.e., all of the members of a process group always belong to the same
session, so that sessions and process groups form a strict two-level
hierarchy of processes.) A new session is created when a process calls
setsid(2), which creates a new session whose session ID
is the same as the PID of the process that called
setsid(2). The creator of the session is called the
All of the processes in a session share a controlling terminal. The controlling terminal is established when the session leader first opens a terminal (unless the O_NOCTTY flag is specified when calling open(2)). A terminal may be the controlling terminal of at most one session.
At most one of the jobs in a session may be the foreground
job; other jobs in the session are
background jobs. Only
the foreground job may read from the terminal; when a process in the
background attempts to read from the terminal, its process group is sent
a SIGTTIN signal, which suspends the job. If the
TOSTOP flag has been set for the terminal (see
termios(3)), then only the foreground job may write to
the terminal; writes from background job cause a
SIGTTOU signal to be generated, which suspends the job.
When terminal keys that generate a signal (such as the
interrupt key, normally control-C) are pressed, the signal is
sent to the processes in the foreground job.
Various system calls and library functions may operate on all members of a process group, including kill(2), killpg(3), getpriority(2), setpriority(2), ioprio_get(2), ioprio_set(2), waitid(2), and waitpid(2). See also the discussion of the F_GETOWN, F_GETOWN_EX, F_SETOWN, and F_SETOWN_EX operations in fcntl(2).
Each process has various associated user and group IDs. These IDs are
integers, respectively represented using the types
gid_t (defined in
On Linux, each process has the following user and group identifiers:
Real user ID and real group ID. These IDs determine who owns the process. A process can obtain its real user (group) ID using getuid(2) (getgid(2)).
Effective user ID and effective group ID. These IDs are used by the kernel to determine the permissions that the process will have when accessing shared resources such as message queues, shared memory, and semaphores. On most UNIX systems, these IDs also determine the permissions when accessing files. However, Linux uses the filesystem IDs described below for this task. A process can obtain its effective user (group) ID using geteuid(2) (getegid(2)).
Saved set-user-ID and saved set-group-ID. These IDs are used in set-user-ID and set-group-ID programs to save a copy of the corresponding effective IDs that were set when the program was executed (see execve(2)). A set-user-ID program can assume and drop privileges by switching its effective user ID back and forth between the values in its real user ID and saved set-user-ID. This switching is done via calls to seteuid(2), setreuid(2), or setresuid(2). A set-group-ID program performs the analogous tasks using setegid(2), setregid(2), or setresgid(2). A process can obtain its saved set-user-ID (set-group-ID) using getresuid(2) (getresgid(2)).
Filesystem user ID and filesystem group ID (Linux-specific). These IDs, in conjunction with the supplementary group IDs described below, are used to determine permissions for accessing files; see path_resolution(7) for details. Whenever a process's effective user (group) ID is changed, the kernel also automatically changes the filesystem user (group) ID to the same value. Consequently, the filesystem IDs normally have the same values as the corresponding effective ID, and the semantics for file-permission checks are thus the same on Linux as on other UNIX systems. The filesystem IDs can be made to differ from the effective IDs by calling setfsuid(2) and setfsgid(2).
Supplementary group IDs. This is a set of additional group IDs
that are used for permission checks when accessing files and other
shared resources. On Linux kernels before 2.6.4, a process can be a
member of up to 32 supplementary groups; since kernel 2.6.4, a process
can be a member of up to 65536 supplementary groups. The call
sysconf(_SC_NGROUPS_MAX) can be used to determine the number of
supplementary groups of which a process may be a member. A process can
obtain its set of supplementary group IDs using
A child process created by fork(2) inherits copies of its parent's user and groups IDs. During an execve(2), a process's real user and group ID and supplementary group IDs are preserved; the effective and saved set IDs may be changed, as described in execve(2).
Aside from the purposes noted above, a process's user IDs are also employed in a number of other contexts:
when determining the permissions for sending signals (see kill(2));
when determining the permissions for setting process-scheduling parameters (nice value, real time scheduling policy and priority, CPU affinity, I/O priority) using setpriority(2), sched_setaffinity(2), sched_setscheduler(2), sched_setparam(2), sched_setattr(2), and ioprio_set(2);
when checking resource limits (see getrlimit(2));
when checking the limit on the number of inotify instances that the process may create (see inotify(7)).
Subject to rules described in the relevant manual pages, a process can use the following APIs to modify its user and group IDs:
Modify the process's real (and possibly effective and saved-set) user (group) IDs.
Modify the process's effective user (group) ID.
Modify the process's filesystem user (group) ID.
Modify the process's real and effective (and possibly saved-set) user (group) IDs.
Modify the process's real, effective, and saved-set user (group) IDs.
Modify the process's supplementary group list.
Any changes to a process's effective user (group) ID are automatically carried over to the process's filesystem user (group) ID. Changes to a process's effective user or group ID can also affect the process "dumpable" attribute, as described in prctl(2).
Changes to process user and group IDs can affect the capabilities of the process, as described in capabilities(7).
Process IDs, parent process IDs, process group IDs, and session IDs are specified in POSIX.1. The real, effective, and saved set user and groups IDs, and the supplementary group IDs, are specified in POSIX.1. The filesystem user and group IDs are a Linux extension.
Various fields in the
/proc/[pid]/status file show the
process credentials described above. See proc(5) for
The POSIX threads specification requires that credentials are shared by all of the threads in a process. However, at the kernel level, Linux maintains separate user and group credentials for each thread. The NPTL threading implementation does some work to ensure that any change to user or group credentials (e.g., calls to setuid(2), setresuid(2)) is carried through to all of the POSIX threads in a process. See nptl(7) for further details.
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