SCHED_SETSCHEDULER(2) Linux Programmer's Manual SCHED_SETSCHEDULER(2)NAME
sched_setscheduler, sched_getscheduler - set and get scheduling pol‐
icy/parameters
SYNOPSIS
#include <sched.h>
int sched_setscheduler(pid_t pid, int policy,
const struct sched_param *param);
int sched_getscheduler(pid_t pid);
struct sched_param {
...
int sched_priority;
...
};
DESCRIPTIONsched_setscheduler() sets both the scheduling policy and the associated
parameters for the thread whose ID is specified in pid. If pid equals
zero, the scheduling policy and parameters of the calling thread will
be set. The interpretation of the argument param depends on the
selected policy. Currently, Linux supports the following "normal"
(i.e., non-real-time) scheduling policies:
SCHED_OTHER the standard round-robin time-sharing policy;
SCHED_BATCH for "batch" style execution of processes; and
SCHED_IDLE for running very low priority background jobs.
The following "real-time" policies are also supported, for special
time-critical applications that need precise control over the way in
which runnable threads are selected for execution:
SCHED_FIFO a first-in, first-out policy; and
SCHED_RR a round-robin policy.
The semantics of each of these policies are detailed below.
sched_getscheduler() queries the scheduling policy currently applied to
the thread identified by pid. If pid equals zero, the policy of the
calling thread will be retrieved.
Scheduling policies
The scheduler is the kernel component that decides which runnable
thread will be executed by the CPU next. Each thread has an associated
scheduling policy and a static scheduling priority, sched_priority;
these are the settings that are modified by sched_setscheduler(). The
scheduler makes it decisions based on knowledge of the scheduling pol‐
icy and static priority of all threads on the system.
For threads scheduled under one of the normal scheduling policies
(SCHED_OTHER, SCHED_IDLE, SCHED_BATCH), sched_priority is not used in
scheduling decisions (it must be specified as 0).
Processes scheduled under one of the real-time policies (SCHED_FIFO,
SCHED_RR) have a sched_priority value in the range 1 (low) to 99
(high). (As the numbers imply, real-time threads always have higher
priority than normal threads.) Note well: POSIX.1-2001 requires an
implementation to support only a minimum 32 distinct priority levels
for the real-time policies, and some systems supply just this minimum.
Portable programs should use sched_get_priority_min(2) and
sched_get_priority_max(2) to find the range of priorities supported for
a particular policy.
Conceptually, the scheduler maintains a list of runnable threads for
each possible sched_priority value. In order to determine which thread
runs next, the scheduler looks for the nonempty list with the highest
static priority and selects the thread at the head of this list.
A thread's scheduling policy determines where it will be inserted into
the list of threads with equal static priority and how it will move
inside this list.
All scheduling is preemptive: if a thread with a higher static priority
becomes ready to run, the currently running thread will be preempted
and returned to the wait list for its static priority level. The
scheduling policy determines the ordering only within the list of
runnable threads with equal static priority.
SCHED_FIFO: First in-first out scheduling
SCHED_FIFO can be used only with static priorities higher than 0, which
means that when a SCHED_FIFO threads becomes runnable, it will always
immediately preempt any currently running SCHED_OTHER, SCHED_BATCH, or
SCHED_IDLE thread. SCHED_FIFO is a simple scheduling algorithm without
time slicing. For threads scheduled under the SCHED_FIFO policy, the
following rules apply:
* A SCHED_FIFO thread that has been preempted by another thread of
higher priority will stay at the head of the list for its priority
and will resume execution as soon as all threads of higher priority
are blocked again.
* When a SCHED_FIFO thread becomes runnable, it will be inserted at
the end of the list for its priority.
* A call to sched_setscheduler() or sched_setparam(2) will put the
SCHED_FIFO (or SCHED_RR) thread identified by pid at the start of
the list if it was runnable. As a consequence, it may preempt the
currently running thread if it has the same priority. (POSIX.1-2001
specifies that the thread should go to the end of the list.)
* A thread calling sched_yield(2) will be put at the end of the list.
No other events will move a thread scheduled under the SCHED_FIFO pol‐
icy in the wait list of runnable threads with equal static priority.
A SCHED_FIFO thread runs until either it is blocked by an I/O request,
it is preempted by a higher priority thread, or it calls
sched_yield(2).
SCHED_RR: Round-robin scheduling
SCHED_RR is a simple enhancement of SCHED_FIFO. Everything described
above for SCHED_FIFO also applies to SCHED_RR, except that each thread
is allowed to run only for a maximum time quantum. If a SCHED_RR
thread has been running for a time period equal to or longer than the
time quantum, it will be put at the end of the list for its priority.
A SCHED_RR thread that has been preempted by a higher priority thread
and subsequently resumes execution as a running thread will complete
the unexpired portion of its round-robin time quantum. The length of
the time quantum can be retrieved using sched_rr_get_interval(2).
SCHED_OTHER: Default Linux time-sharing scheduling
SCHED_OTHER can be used at only static priority 0. SCHED_OTHER is the
standard Linux time-sharing scheduler that is intended for all threads
that do not require the special real-time mechanisms. The thread to
run is chosen from the static priority 0 list based on a dynamic prior‐
ity that is determined only inside this list. The dynamic priority is
based on the nice value (set by nice(2) or setpriority(2)) and
increased for each time quantum the thread is ready to run, but denied
to run by the scheduler. This ensures fair progress among all
SCHED_OTHER threads.
SCHED_BATCH: Scheduling batch processes
(Since Linux 2.6.16.) SCHED_BATCH can be used only at static priority
0. This policy is similar to SCHED_OTHER in that it schedules the
thread according to its dynamic priority (based on the nice value).
The difference is that this policy will cause the scheduler to always
assume that the thread is CPU-intensive. Consequently, the scheduler
will apply a small scheduling penalty with respect to wakeup behaviour,
so that this thread is mildly disfavored in scheduling decisions.
This policy is useful for workloads that are noninteractive, but do not
want to lower their nice value, and for workloads that want a determin‐
istic scheduling policy without interactivity causing extra preemptions
(between the workload's tasks).
SCHED_IDLE: Scheduling very low priority jobs
(Since Linux 2.6.23.) SCHED_IDLE can be used only at static priority
0; the process nice value has no influence for this policy.
This policy is intended for running jobs at extremely low priority
(lower even than a +19 nice value with the SCHED_OTHER or SCHED_BATCH
policies).
Resetting scheduling policy for child processes
Since Linux 2.6.32, the SCHED_RESET_ON_FORK flag can be ORed in policy
when calling sched_setscheduler(). As a result of including this flag,
children created by fork(2) do not inherit privileged scheduling poli‐
cies. This feature is intended for media-playback applications, and
can be used to prevent applications evading the RLIMIT_RTTIME resource
limit (see getrlimit(2)) by creating multiple child processes.
More precisely, if the SCHED_RESET_ON_FORK flag is specified, the fol‐
lowing rules apply for subsequently created children:
* If the calling thread has a scheduling policy of SCHED_FIFO or
SCHED_RR, the policy is reset to SCHED_OTHER in child processes.
* If the calling process has a negative nice value, the nice value is
reset to zero in child processes.
After the SCHED_RESET_ON_FORK flag has been enabled, it can be reset
only if the thread has the CAP_SYS_NICE capability. This flag is dis‐
abled in child processes created by fork(2).
The SCHED_RESET_ON_FORK flag is visible in the policy value returned by
sched_getscheduler()
Privileges and resource limits
In Linux kernels before 2.6.12, only privileged (CAP_SYS_NICE) threads
can set a nonzero static priority (i.e., set a real-time scheduling
policy). The only change that an unprivileged thread can make is to
set the SCHED_OTHER policy, and this can be done only if the effective
user ID of the caller of sched_setscheduler() matches the real or
effective user ID of the target thread (i.e., the thread specified by
pid) whose policy is being changed.
Since Linux 2.6.12, the RLIMIT_RTPRIO resource limit defines a ceiling
on an unprivileged thread's static priority for the SCHED_RR and
SCHED_FIFO policies. The rules for changing scheduling policy and pri‐
ority are as follows:
* If an unprivileged thread has a nonzero RLIMIT_RTPRIO soft limit,
then it can change its scheduling policy and priority, subject to
the restriction that the priority cannot be set to a value higher
than the maximum of its current priority and its RLIMIT_RTPRIO soft
limit.
* If the RLIMIT_RTPRIO soft limit is 0, then the only permitted
changes are to lower the priority, or to switch to a non-real-time
policy.
* Subject to the same rules, another unprivileged thread can also make
these changes, as long as the effective user ID of the thread making
the change matches the real or effective user ID of the target
thread.
* Special rules apply for the SCHED_IDLE. In Linux kernels before
2.6.39, an unprivileged thread operating under this policy cannot
change its policy, regardless of the value of its RLIMIT_RTPRIO
resource limit. In Linux kernels since 2.6.39, an unprivileged
thread can switch to either the SCHED_BATCH or the SCHED_NORMAL pol‐
icy so long as its nice value falls within the range permitted by
its RLIMIT_NICE resource limit (see getrlimit(2)).
Privileged (CAP_SYS_NICE) threads ignore the RLIMIT_RTPRIO limit; as
with older kernels, they can make arbitrary changes to scheduling pol‐
icy and priority. See getrlimit(2) for further information on
RLIMIT_RTPRIO.
Response time
A blocked high priority thread waiting for the I/O has a certain
response time before it is scheduled again. The device driver writer
can greatly reduce this response time by using a "slow interrupt"
interrupt handler.
Miscellaneous
Child processes inherit the scheduling policy and parameters across a
fork(2). The scheduling policy and parameters are preserved across
execve(2).
Memory locking is usually needed for real-time processes to avoid pag‐
ing delays; this can be done with mlock(2) or mlockall(2).
Since a nonblocking infinite loop in a thread scheduled under
SCHED_FIFO or SCHED_RR will block all threads with lower priority for‐
ever, a software developer should always keep available on the console
a shell scheduled under a higher static priority than the tested appli‐
cation. This will allow an emergency kill of tested real-time applica‐
tions that do not block or terminate as expected. See also the
description of the RLIMIT_RTTIME resource limit in getrlimit(2).
POSIX systems on which sched_setscheduler() and sched_getscheduler()
are available define _POSIX_PRIORITY_SCHEDULING in <unistd.h>.
RETURN VALUE
On success, sched_setscheduler() returns zero. On success,
sched_getscheduler() returns the policy for the thread (a nonnegative
integer). On error, -1 is returned, and errno is set appropriately.
ERRORS
EINVAL The scheduling policy is not one of the recognized policies,
param is NULL, or param does not make sense for the policy.
EPERM The calling thread does not have appropriate privileges.
ESRCH The thread whose ID is pid could not be found.
CONFORMING TO
POSIX.1-2001 (but see BUGS below). The SCHED_BATCH and SCHED_IDLE
policies are Linux-specific.
NOTES
POSIX.1 does not detail the permissions that an unprivileged thread
requires in order to call sched_setscheduler(), and details vary across
systems. For example, the Solaris 7 manual page says that the real or
effective user ID of the caller must match the real user ID or the save
set-user-ID of the target.
The scheduling policy and parameters are in fact per-thread attributes
on Linux. The value returned from a call to gettid(2) can be passed in
the argument pid. Specifying pid as 0 will operate on the attribute
for the calling thread, and passing the value returned from a call to
getpid(2) will operate on the attribute for the main thread of the
thread group. (If you are using the POSIX threads API, then use
pthread_setschedparam(3), pthread_getschedparam(3), and
pthread_setschedprio(3), instead of the sched_*(2) system calls.)
Originally, Standard Linux was intended as a general-purpose operating
system being able to handle background processes, interactive applica‐
tions, and less demanding real-time applications (applications that
need to usually meet timing deadlines). Although the Linux kernel 2.6
allowed for kernel preemption and the newly introduced O(1) scheduler
ensures that the time needed to schedule is fixed and deterministic
irrespective of the number of active tasks, true real-time computing
was not possible up to kernel version 2.6.17.
Real-time features in the mainline Linux kernel
From kernel version 2.6.18 onward, however, Linux is gradually becoming
equipped with real-time capabilities, most of which are derived from
the former realtime-preempt patches developed by Ingo Molnar, Thomas
Gleixner, Steven Rostedt, and others. Until the patches have been com‐
pletely merged into the mainline kernel (this is expected to be around
kernel version 2.6.30), they must be installed to achieve the best
real-time performance. These patches are named:
patch-kernelversion-rtpatchversion
and can be downloaded from ⟨http://www.kernel.org/pub/linux/kernel
/projects/rt/⟩.
Without the patches and prior to their full inclusion into the mainline
kernel, the kernel configuration offers only the three preemption
classes CONFIG_PREEMPT_NONE, CONFIG_PREEMPT_VOLUNTARY, and CONFIG_PRE‐
EMPT_DESKTOP which respectively provide no, some, and considerable
reduction of the worst-case scheduling latency.
With the patches applied or after their full inclusion into the main‐
line kernel, the additional configuration item CONFIG_PREEMPT_RT
becomes available. If this is selected, Linux is transformed into a
regular real-time operating system. The FIFO and RR scheduling poli‐
cies that can be selected using sched_setscheduler() are then used to
run a thread with true real-time priority and a minimum worst-case
scheduling latency.
BUGS
POSIX says that on success, sched_setscheduler() should return the pre‐
vious scheduling policy. Linux sched_setscheduler() does not conform
to this requirement, since it always returns 0 on success.
SEE ALSOchrt(1), getpriority(2), mlock(2), mlockall(2), munlock(2),
munlockall(2), nice(2), sched_get_priority_max(2),
sched_get_priority_min(2), sched_getaffinity(2), sched_getparam(2),
sched_rr_get_interval(2), sched_setaffinity(2), sched_setparam(2),
sched_yield(2), setpriority(2), capabilities(7), cpuset(7)
Programming for the real world - POSIX.4 by Bill O. Gallmeister,
O'Reilly & Associates, Inc., ISBN 1-56592-074-0.
The Linux kernel source file Documentation/scheduler/sched-rt-group.txt
COLOPHON
This page is part of release 3.55 of the Linux man-pages project. A
description of the project, and information about reporting bugs, can
be found at http://www.kernel.org/doc/man-pages/.
Linux 2013-09-17 SCHED_SETSCHEDULER(2)