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

NAME
       clock_getres, clock_gettime, clock_settime - clock and time functions

SYNOPSIS
       #include <time.h>

       int clock_getres(clockid_t clockid, struct timespec *res);

       int clock_gettime(clockid_t clockid, struct timespec *tp);
       int clock_settime(clockid_t clockid, const struct timespec *tp);

       Link with -lrt (only for glibc versions before 2.17).

   Feature Test Macro Requirements for glibc (see feature_test_macros(7)):

       clock_getres(), clock_gettime(), clock_settime():
           _POSIX_C_SOURCE >= 199309L

DESCRIPTION
       The function clock_getres() finds the resolution (precision) of the specified clock clockid, and, if res is non-NULL, stores it in the struct timespec pointed to
       by res.  The resolution of clocks depends on the implementation and cannot be configured by a particular process.  If the time value pointed to by  the  argument
       tp of clock_settime() is not a multiple of res, then it is truncated to a multiple of res.

       The functions clock_gettime() and clock_settime() retrieve and set the time of the specified clock clockid.

       The res and tp arguments are timespec structures, as specified in <time.h>:

           struct timespec {
               time_t   tv_sec;        /* seconds */
               long     tv_nsec;       /* nanoseconds */
           };

       The  clockid  argument is the identifier of the particular clock on which to act.  A clock may be system-wide and hence visible for all processes, or per-process
       if it measures time only within a single process.

       All implementations support the system-wide real-time clock, which is identified by CLOCK_REALTIME.  Its time represents seconds and nanoseconds since the Epoch.
       When its time is changed, timers for a relative interval are unaffected, but timers for an absolute point in time are affected.

       More clocks may be implemented.  The interpretation of the corresponding time values and the effect on timers is unspecified.

       Sufficiently recent versions of glibc and the Linux kernel support the following clocks:

       CLOCK_REALTIME
              A  settable  system-wide clock that measures real (i.e., wall-clock) time.  Setting this clock requires appropriate privileges.  This clock is affected by
              discontinuous jumps in the system time (e.g., if the system administrator manually changes the clock), and by the incremental adjustments performed by ad‐
              jtime(3) and NTP.

       CLOCK_REALTIME_ALARM (since Linux 3.0; Linux-specific)
              Like CLOCK_REALTIME, but not settable.  See timer_create(2) for further details.

       CLOCK_REALTIME_COARSE (since Linux 2.6.32; Linux-specific)
              A faster but less precise version of CLOCK_REALTIME.  This clock is not settable.  Use when you need very fast, but not fine-grained timestamps.  Requires
              per-architecture support, and probably also architecture support for this flag in the vdso(7).

       CLOCK_TAI (since Linux 3.10; Linux-specific)
              A nonsettable system-wide clock derived from wall-clock time but ignoring leap seconds.  This clock does  not  experience  discontinuities  and  backwards
              jumps caused by NTP inserting leap seconds as CLOCK_REALTIME does.

              The acronym TAI refers to International Atomic Time.

       CLOCK_MONOTONIC
              A  nonsettable  system-wide  clock  that represents monotonic time sinceβ€”as described by POSIXβ€”"some unspecified point in the past".  On Linux, that point
              corresponds to the number of seconds that the system has been running since it was booted.

              The CLOCK_MONOTONIC clock is not affected by discontinuous jumps in the system time (e.g., if the system administrator manually changes the clock), but is
              affected  by  the  incremental adjustments performed by adjtime(3) and NTP.  This clock does not count time that the system is suspended.  All CLOCK_MONO‐
              TONIC variants guarantee that the time returned by consecutive calls will not go backwards, but successive calls mayβ€”depending on the  architectureβ€”return
              identical (not-increased) time values.

       CLOCK_MONOTONIC_COARSE (since Linux 2.6.32; Linux-specific)
              A  faster  but less precise version of CLOCK_MONOTONIC.  Use when you need very fast, but not fine-grained timestamps.  Requires per-architecture support,
              and probably also architecture support for this flag in the vdso(7).

       CLOCK_MONOTONIC_RAW (since Linux 2.6.28; Linux-specific)
              Similar to CLOCK_MONOTONIC, but provides access to a raw hardware-based time that is not subject to NTP adjustments or the  incremental  adjustments  per‐
              formed by adjtime(3).  This clock does not count time that the system is suspended.

       CLOCK_BOOTTIME (since Linux 2.6.39; Linux-specific)
              A nonsettable system-wide clock that is identical to CLOCK_MONOTONIC, except that it also includes any time that the system is suspended.  This allows ap‐
              plications to get a suspend-aware monotonic clock without having to deal with the complications of CLOCK_REALTIME, which may have discontinuities  if  the
              time is changed using settimeofday(2) or similar.

       CLOCK_BOOTTIME_ALARM (since Linux 3.0; Linux-specific)
              Like CLOCK_BOOTTIME.  See timer_create(2) for further details.

       CLOCK_PROCESS_CPUTIME_ID (since Linux 2.6.12)
              This is a clock that measures CPU time consumed by this process (i.e., CPU time consumed by all threads in the process).  On Linux, this clock is not set‐
              table.

       CLOCK_THREAD_CPUTIME_ID (since Linux 2.6.12)
              This is a clock that measures CPU time consumed by this thread.  On Linux, this clock is not settable.

       Linux also implements dynamic clock instances as described below.

   Dynamic clocks
       In addition to the hard-coded System-V style clock IDs described above, Linux also supports POSIX clock operations on certain character  devices.   Such  devices
       are called "dynamic" clocks, and are supported since Linux 2.6.39.

       Using  the  appropriate  macros, open file descriptors may be converted into clock IDs and passed to clock_gettime(), clock_settime(), and clock_adjtime(2).  The
       following example shows how to convert a file descriptor into a dynamic clock ID.

           #define CLOCKFD 3
           #define FD_TO_CLOCKID(fd)   ((~(clockid_t) (fd) << 3) | CLOCKFD)
           #define CLOCKID_TO_FD(clk)  ((unsigned int) ~((clk) >> 3))

           struct timespec ts;
           clockid_t clkid;
           int fd;

           fd = open("/dev/ptp0", O_RDWR);
           clkid = FD_TO_CLOCKID(fd);
           clock_gettime(clkid, &ts);

RETURN VALUE
       clock_gettime(), clock_settime(), and clock_getres() return 0 for success.  On error, -1 is returned and errno is set to indicate the error.

ERRORS
       EACCES clock_settime() does not have write permission for the dynamic POSIX clock device indicated.

       EFAULT tp points outside the accessible address space.

       EINVAL The clockid specified is invalid for one of two reasons.  Either the System-V style hard coded positive value is out of range, or  the  dynamic  clock  ID
              does not refer to a valid instance of a clock object.

       EINVAL (clock_settime()): tp.tv_sec is negative or tp.tv_nsec is outside the range [0..999,999,999].

       EINVAL The clockid specified in a call to clock_settime() is not a settable clock.

       EINVAL (since Linux 4.3)
              A call to clock_settime() with a clockid of CLOCK_REALTIME attempted to set the time to a value less than the current value of the CLOCK_MONOTONIC clock.

       ENODEV The hot-pluggable device (like USB for example) represented by a dynamic clk_id has disappeared after its character device was opened.

       ENOTSUP
              The operation is not supported by the dynamic POSIX clock device specified.

       EPERM  clock_settime() does not have permission to set the clock indicated.

VERSIONS
       These system calls first appeared in Linux 2.6.

ATTRIBUTES
       For an explanation of the terms used in this section, see attributes(7).

       β”Œβ”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”¬β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”¬β”€β”€β”€β”€β”€β”€β”€β”€β”€β”
       β”‚Interface                                                                                                                             β”‚ Attribute     β”‚ Value   β”‚
       β”œβ”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”Όβ”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”Όβ”€β”€β”€β”€β”€β”€β”€β”€β”€β”€
       β”‚clock_getres(), clock_gettime(), clock_settime()                                                                                      β”‚ Thread safety β”‚ MT-Safe β”‚
       β””β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”΄β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”΄β”€β”€β”€β”€β”€β”€β”€β”€β”€β”˜

CONFORMING TO
       POSIX.1-2001, POSIX.1-2008, SUSv2.

       On  POSIX  systems on which these functions are available, the symbol _POSIX_TIMERS is defined in <unistd.h> to a value greater than 0.  The symbols _POSIX_MONO‐
       TONIC_CLOCK, _POSIX_CPUTIME, _POSIX_THREAD_CPUTIME indicate that CLOCK_MONOTONIC, CLOCK_PROCESS_CPUTIME_ID, CLOCK_THREAD_CPUTIME_ID  are  available.   (See  also
       sysconf(3).)

NOTES
       POSIX.1 specifies the following:

              Setting  the  value  of  the CLOCK_REALTIME clock via clock_settime() shall have no effect on threads that are blocked waiting for a relative time service
              based upon this clock, including the nanosleep() function; nor on the expiration of relative timers based upon this clock.  Consequently, these time  ser‐
              vices shall expire when the requested relative interval elapses, independently of the new or old value of the clock.

       According to POSIX.1-2001, a process with "appropriate privileges" may set the CLOCK_PROCESS_CPUTIME_ID and CLOCK_THREAD_CPUTIME_ID clocks using clock_settime().
       On Linux, these clocks are not settable (i.e., no process has "appropriate privileges").

   C library/kernel differences
       On some architectures, an implementation of clock_gettime() is provided in the vdso(7).

   Historical note for SMP systems
       Before Linux added kernel support for CLOCK_PROCESS_CPUTIME_ID and CLOCK_THREAD_CPUTIME_ID, glibc implemented these clocks on many platforms using  timer  regis‐
       ters  from  the  CPUs  (TSC on i386, AR.ITC on Itanium).  These registers may differ between CPUs and as a consequence these clocks may return bogus results if a
       process is migrated to another CPU.

       If the CPUs in an SMP system have different clock sources, then there is no way to maintain a correlation between the timer registers since each CPU will run  at
       a slightly different frequency.  If that is the case, then clock_getcpuclockid(0) will return ENOENT to signify this condition.  The two clocks will then be use‐
       ful only if it can be ensured that a process stays on a certain CPU.

       The processors in an SMP system do not start all at exactly the same time and therefore the timer registers are typically running at an offset.   Some  architec‐
       tures  include code that attempts to limit these offsets on bootup.  However, the code cannot guarantee to accurately tune the offsets.  Glibc contains no provi‐
       sions to deal with these offsets (unlike the Linux Kernel).  Typically these offsets are small and therefore the effects may be negligible in most cases.

       Since glibc 2.4, the wrapper functions for the system calls described in this page avoid the abovementioned problems by employing the  kernel  implementation  of
       CLOCK_PROCESS_CPUTIME_ID and CLOCK_THREAD_CPUTIME_ID, on systems that provide such an implementation (i.e., Linux 2.6.12 and later).

EXAMPLES
       The  program below demonstrates the use of clock_gettime() and clock_getres() with various clocks.  This is an example of what we might see when running the pro‐
       gram:

           $ ./clock_times x
           CLOCK_REALTIME : 1585985459.446 (18356 days +  7h 30m 59s)
                resolution:          0.000000001
           CLOCK_TAI      : 1585985496.447 (18356 days +  7h 31m 36s)
                resolution:          0.000000001
           CLOCK_MONOTONIC:      52395.722 (14h 33m 15s)
                resolution:          0.000000001
           CLOCK_BOOTTIME :      72691.019 (20h 11m 31s)
                resolution:          0.000000001

   Program source

       /* clock_times.c

          Licensed under GNU General Public License v2 or later.
       */
       #define _XOPEN_SOURCE 600
       #include <time.h>
       #include <stdint.h>
       #include <stdio.h>
       #include <stdlib.h>
       #include <stdbool.h>
       #include <unistd.h>

       #define SECS_IN_DAY (24 * 60 * 60)

       static void
       displayClock(clockid_t clock, const char *name, bool showRes)
       {
           struct timespec ts;

           if (clock_gettime(clock, &ts) == -1) {
               perror("clock_gettime");
               exit(EXIT_FAILURE);
           }

           printf("%-15s: %10jd.%03ld (", name,
                   (intmax_t) ts.tv_sec, ts.tv_nsec / 1000000);

           long days = ts.tv_sec / SECS_IN_DAY;
           if (days > 0)
               printf("%ld days + ", days);

           printf("%2dh %2dm %2ds",
                   (int) (ts.tv_sec % SECS_IN_DAY) / 3600,
                   (int) (ts.tv_sec % 3600) / 60,
                   (int) ts.tv_sec % 60);
           printf(")\n");

           if (clock_getres(clock, &ts) == -1) {
               perror("clock_getres");
               exit(EXIT_FAILURE);
           }

           if (showRes)
               printf("     resolution: %10jd.%09ld\n",
                       (intmax_t) ts.tv_sec, ts.tv_nsec);
       }

       int
       main(int argc, char *argv[])
       {
           bool showRes = argc > 1;

           displayClock(CLOCK_REALTIME, "CLOCK_REALTIME", showRes);
       #ifdef CLOCK_TAI
           displayClock(CLOCK_TAI, "CLOCK_TAI", showRes);
       #endif
           displayClock(CLOCK_MONOTONIC, "CLOCK_MONOTONIC", showRes);
       #ifdef CLOCK_BOOTTIME
           displayClock(CLOCK_BOOTTIME, "CLOCK_BOOTTIME", showRes);
       #endif
           exit(EXIT_SUCCESS);
       }

SEE ALSO
       date(1), gettimeofday(2), settimeofday(2), time(2),  adjtime(3),  clock_getcpuclockid(3),  ctime(3),  ftime(3),  pthread_getcpuclockid(3),  sysconf(3),  time(7),
       time_namespaces(7), vdso(7), hwclock(8)

                                                                               2021-03-22                                                                CLOCK_GETRES(2)