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SCHED_SETAFFINITY(2)                                                    Linux Programmer's Manual                                                   SCHED_SETAFFINITY(2)

NAME
       sched_setaffinity, sched_getaffinity - set and get a thread's CPU affinity mask

SYNOPSIS
       #define _GNU_SOURCE             /* See feature_test_macros(7) */
       #include <sched.h>

       int sched_setaffinity(pid_t pid, size_t cpusetsize,
                             const cpu_set_t *mask);
       int sched_getaffinity(pid_t pid, size_t cpusetsize,
                             cpu_set_t *mask);

DESCRIPTION
       A thread's CPU affinity mask determines the set of CPUs on which it is eligible to run.  On a multiprocessor system, setting the CPU affinity mask can be used to
       obtain performance benefits.  For example, by dedicating one CPU to a particular thread (i.e., setting the affinity mask of that thread to specify a single  CPU,
       and  setting the affinity mask of all other threads to exclude that CPU), it is possible to ensure maximum execution speed for that thread.  Restricting a thread
       to run on a single CPU also avoids the performance cost caused by the cache invalidation that occurs when a thread ceases to execute on one CPU and  then  recom‐
       mences execution on a different CPU.

       A  CPU  affinity  mask  is  represented  by  the cpu_set_t structure, a "CPU set", pointed to by mask.  A set of macros for manipulating CPU sets is described in
       CPU_SET(3).

       sched_setaffinity() sets the CPU affinity mask of the thread whose ID is pid to the value specified by mask.  If pid is zero, then the calling  thread  is  used.
       The argument cpusetsize is the length (in bytes) of the data pointed to by mask.  Normally this argument would be specified as sizeof(cpu_set_t).

       If the thread specified by pid is not currently running on one of the CPUs specified in mask, then that thread is migrated to one of the CPUs specified in mask.

       sched_getaffinity()  writes  the  affinity mask of the thread whose ID is pid into the cpu_set_t structure pointed to by mask.  The cpusetsize argument specifies
       the size (in bytes) of mask.  If pid is zero, then the mask of the calling thread is returned.

RETURN VALUE
       On success, sched_setaffinity() and sched_getaffinity() return 0 (but see "C library/kernel differences" below, which notes that the  underlying  sched_getaffin‐
       ity() differs in its return value).  On failure, -1 is returned, and errno is set to indicate the error.

ERRORS
       EFAULT A supplied memory address was invalid.

       EINVAL The  affinity  bit  mask mask contains no processors that are currently physically on the system and permitted to the thread according to any restrictions
              that may be imposed by cpuset cgroups or the "cpuset" mechanism described in cpuset(7).

       EINVAL (sched_getaffinity() and, in kernels before 2.6.9, sched_setaffinity()) cpusetsize is smaller than the size of the affinity mask used by the kernel.

       EPERM  (sched_setaffinity()) The calling thread does not have appropriate privileges.  The caller needs an effective user ID equal to the real user ID or  effec‐
              tive user ID of the thread identified by pid, or it must possess the CAP_SYS_NICE capability in the user namespace of the thread pid.

       ESRCH  The thread whose ID is pid could not be found.

VERSIONS
       The CPU affinity system calls were introduced in Linux kernel 2.5.8.  The system call wrappers were introduced in glibc 2.3.  Initially, the glibc interfaces in‐
       cluded a cpusetsize argument, typed as unsigned int.  In glibc 2.3.3, the cpusetsize argument was removed, but was  then  restored  in  glibc  2.3.4,  with  type
       size_t.

CONFORMING TO
       These system calls are Linux-specific.

NOTES
       After  a call to sched_setaffinity(), the set of CPUs on which the thread will actually run is the intersection of the set specified in the mask argument and the
       set of CPUs actually present on the system.  The system may further restrict the set of CPUs on which the thread runs if  the  "cpuset"  mechanism  described  in
       cpuset(7) is being used.  These restrictions on the actual set of CPUs on which the thread will run are silently imposed by the kernel.

       There are various ways of determining the number of CPUs available on the system, including: inspecting the contents of /proc/cpuinfo; using sysconf(3) to obtain
       the values of the _SC_NPROCESSORS_CONF and _SC_NPROCESSORS_ONLN parameters; and inspecting the list of CPU directories under /sys/devices/system/cpu/.

       sched(7) has a description of the Linux scheduling scheme.

       The affinity mask is a per-thread attribute that can be adjusted independently for each of the threads in a thread group.  The value returned from a call to get‐
       tid(2)  can be passed in the argument pid.  Specifying pid as 0 will set the attribute for the calling thread, and passing the value returned from a call to get‐
       pid(2) will set the attribute for the main thread of the thread group.  (If you are using the POSIX threads API, then use  pthread_setaffinity_np(3)  instead  of
       sched_setaffinity().)

       The  isolcpus  boot  option  can be used to isolate one or more CPUs at boot time, so that no processes are scheduled onto those CPUs.  Following the use of this
       boot option, the only way to schedule processes onto the isolated CPUs is via sched_setaffinity() or the cpuset(7) mechanism.  For further information,  see  the
       kernel source file Documentation/admin-guide/kernel-parameters.txt.  As noted in that file, isolcpus is the preferred mechanism of isolating CPUs (versus the al‐
       ternative of manually setting the CPU affinity of all processes on the system).

       A child created via fork(2) inherits its parent's CPU affinity mask.  The affinity mask is preserved across an execve(2).

   C library/kernel differences
       This manual page describes the glibc interface for the CPU affinity calls.  The actual system call interface is slightly different, with the mask being typed  as
       unsigned long *, reflecting the fact that the underlying implementation of CPU sets is a simple bit mask.

       On  success,  the  raw sched_getaffinity() system call returns the number of bytes placed copied into the mask buffer; this will be the minimum of cpusetsize and
       the size (in bytes) of the cpumask_t data type that is used internally by the kernel to represent the CPU set bit mask.

   Handling systems with large CPU affinity masks
       The underlying system calls (which represent CPU masks as bit masks of type unsigned long *) impose no restriction on the size of the  CPU  mask.   However,  the
       cpu_set_t data type used by glibc has a fixed size of 128 bytes, meaning that the maximum CPU number that can be represented is 1023.  If the kernel CPU affinity
       mask is larger than 1024, then calls of the form:

           sched_getaffinity(pid, sizeof(cpu_set_t), &mask);

       fail with the error EINVAL, the error produced by the underlying system call for the case where the mask size specified in cpusetsize is smaller than the size of
       the affinity mask used by the kernel.  (Depending on the system CPU topology, the kernel affinity mask can be substantially larger than the number of active CPUs
       in the system.)

       When working on systems with large kernel CPU affinity masks, one must dynamically allocate the mask argument (see CPU_ALLOC(3)).  Currently, the only way to  do
       this is by probing for the size of the required mask using sched_getaffinity() calls with increasing mask sizes (until the call does not fail with the error EIN‐
       VAL).

       Be aware that CPU_ALLOC(3) may allocate a slightly larger CPU set than requested  (because  CPU  sets  are  implemented  as  bit  masks  allocated  in  units  of
       sizeof(long)).   Consequently,  sched_getaffinity() can set bits beyond the requested allocation size, because the kernel sees a few additional bits.  Therefore,
       the caller should iterate over the bits in the returned set, counting those which are set, and stop upon reaching the value returned by CPU_COUNT(3) (rather than
       iterating over the number of bits requested to be allocated).

EXAMPLES
       The program below creates a child process.  The parent and child then each assign themselves to a specified CPU and execute identical loops that consume some CPU
       time.  Before terminating, the parent waits for the child to complete.  The program takes three command-line arguments: the CPU number for the  parent,  the  CPU
       number for the child, and the number of loop iterations that both processes should perform.

       As the sample runs below demonstrate, the amount of real and CPU time consumed when running the program will depend on intra-core caching effects and whether the
       processes are using the same CPU.

       We first employ lscpu(1) to determine that this (x86) system has two cores, each with two CPUs:

           $ lscpu | egrep -i 'core.*:|socket'
           Thread(s) per core:    2
           Core(s) per socket:    2
           Socket(s):             1

       We then time the operation of the example program for three cases: both processes running on the same CPU; both processes running on different CPUs on  the  same
       core; and both processes running on different CPUs on different cores.

           $ time -p ./a.out 0 0 100000000
           real 14.75
           user 3.02
           sys 11.73
           $ time -p ./a.out 0 1 100000000
           real 11.52
           user 3.98
           sys 19.06
           $ time -p ./a.out 0 3 100000000
           real 7.89
           user 3.29
           sys 12.07

   Program source

       #define _GNU_SOURCE
       #include <sched.h>
       #include <stdio.h>
       #include <stdlib.h>
       #include <unistd.h>
       #include <sys/wait.h>

       #define errExit(msg)    do { perror(msg); exit(EXIT_FAILURE); \
                               } while (0)

       int
       main(int argc, char *argv[])
       {
           cpu_set_t set;
           int parentCPU, childCPU;
           int nloops;

           if (argc != 4) {
               fprintf(stderr, "Usage: %s parent-cpu child-cpu num-loops\n",
                       argv[0]);
               exit(EXIT_FAILURE);
           }

           parentCPU = atoi(argv[1]);
           childCPU = atoi(argv[2]);
           nloops = atoi(argv[3]);

           CPU_ZERO(&set);

           switch (fork()) {
           case -1:            /* Error */
               errExit("fork");

           case 0:             /* Child */
               CPU_SET(childCPU, &set);

               if (sched_setaffinity(getpid(), sizeof(set), &set) == -1)
                   errExit("sched_setaffinity");

               for (int j = 0; j < nloops; j++)
                   getppid();

               exit(EXIT_SUCCESS);

           default:            /* Parent */
               CPU_SET(parentCPU, &set);

               if (sched_setaffinity(getpid(), sizeof(set), &set) == -1)
                   errExit("sched_setaffinity");

               for (int j = 0; j < nloops; j++)
                   getppid();

               wait(NULL);     /* Wait for child to terminate */
               exit(EXIT_SUCCESS);
           }
       }

SEE ALSO
       lscpu(1), nproc(1), taskset(1), clone(2), getcpu(2), getpriority(2), gettid(2), nice(2), sched_get_priority_max(2), sched_get_priority_min(2),
       sched_getscheduler(2), sched_setscheduler(2), setpriority(2), CPU_SET(3), get_nprocs(3), pthread_setaffinity_np(3), sched_getcpu(3), capabilities(7), cpuset(7),
       sched(7), numactl(8)

Linux                                                                          2021-03-22                                                           SCHED_SETAFFINITY(2)