Provided by: manpages-dev_2.77-1_all
getpriority, setpriority - get/set program scheduling priority
int getpriority(int which, int who);
int setpriority(int which, int who, int prio);
The scheduling priority of the process, process group, or user, as
indicated by which and who is obtained with the getpriority() call and
set with the setpriority() call.
The value which is one of PRIO_PROCESS, PRIO_PGRP, or PRIO_USER, and
who is interpreted relative to which (a process identifier for
PRIO_PROCESS, process group identifier for PRIO_PGRP, and a user ID for
PRIO_USER). A zero value for who denotes (respectively) the calling
process, the process group of the calling process, or the real user ID
of the calling process. Prio is a value in the range -20 to 19 (but
see the Notes below). The default priority is 0; lower priorities
cause more favorable scheduling.
The getpriority() call returns the highest priority (lowest numerical
value) enjoyed by any of the specified processes. The setpriority()
call sets the priorities of all of the specified processes to the
specified value. Only the superuser may lower priorities.
Since getpriority() can legitimately return the value -1, it is
necessary to clear the external variable errno prior to the call, then
check it afterwards to determine if a -1 is an error or a legitimate
value. The setpriority() call returns 0 if there is no error, or -1 if
EINVAL which was not one of PRIO_PROCESS, PRIO_PGRP, or PRIO_USER.
ESRCH No process was located using the which and who values specified.
In addition to the errors indicated above, setpriority() may fail if:
EACCES The caller attempted to lower a process priority, but did not
have the required privilege (on Linux: did not have the
CAP_SYS_NICE capability). Since Linux 2.6.12, this error only
occurs if the caller attempts to set a process priority outside
the range of the RLIMIT_NICE soft resource limit of the target
process; see getrlimit(2) for details.
EPERM A process was located, but its effective user ID did not match
either the effective or the real user ID of the caller, and was
not privileged (on Linux: did not have the CAP_SYS_NICE
capability). But see NOTES below.
SVr4, 4.4BSD (these function calls first appeared in 4.2BSD),
A child created by fork(2) inherits its parent’s nice value. The nice
value is preserved across execve(2).
The details on the condition for EPERM depend on the system. The above
description is what POSIX.1-2001 says, and seems to be followed on all
System V-like systems. Linux kernels before 2.6.12 required the real
or effective user ID of the caller to match the real user of the
process who (instead of its effective user ID). Linux 2.6.12 and later
require the effective user ID of the caller to match the real or
effective user ID of the process who. All BSD-like systems (SunOS
4.1.3, Ultrix 4.2, 4.3BSD, FreeBSD 4.3, OpenBSD-2.5, ...) behave in the
same manner as Linux >= 2.6.12.
The actual priority range varies between kernel versions. Linux before
1.3.36 had -infinity..15. Since kernel 1.3.43 Linux has the range
-20..19. Within the kernel, nice values are actually represented using
the corresponding range 40..1 (since negative numbers are error codes)
and these are the values employed by the setpriority() and
getpriority() system calls. The glibc wrapper functions for these
system calls handle the translations between the user-land and kernel
representations of the nice value according to the formula
unice = 20 - knice.
On some systems, the range of nice values is -20..20.
Including <sys/time.h> is not required these days, but increases
portability. (Indeed, <sys/resource.h> defines the rusage structure
with fields of type struct timeval defined in <sys/time.h>.)
nice(1), fork(2), capabilities(7), renice(8)
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description of the project, and information about reporting bugs, can
be found at http://www.kernel.org/doc/man-pages/.