.\" Copyright (C) Markus Kuhn, 1996 .\" and Copyright (C) Linux Foundation, 2008, written by Michael Kerrisk .\" .\" .\" SPDX-License-Identifier: GPL-2.0-or-later .\" .\" 1996-04-10 Markus Kuhn .\" First version written .\" Modified, 2004-10-24, aeb .\" 2008-06-24, mtk .\" Minor rewrites of some parts. .\" NOTES: describe case where clock_nanosleep() can be preferable. .\" NOTES: describe CLOCK_REALTIME versus CLOCK_NANOSLEEP .\" Replace crufty discussion of HZ with a pointer to time(7). .TH nanosleep 2 2024-03-03 "Linux man-pages 6.7" .SH NAME nanosleep \- high-resolution sleep .SH LIBRARY Standard C library .RI ( libc ", " \-lc ) .SH SYNOPSIS .nf .B #include .P .BI "int nanosleep(const struct timespec *" duration , .BI " struct timespec *_Nullable " rem ); .fi .P .RS -4 Feature Test Macro Requirements for glibc (see .BR feature_test_macros (7)): .RE .P .BR nanosleep (): .nf _POSIX_C_SOURCE >= 199309L .fi .SH DESCRIPTION .BR nanosleep () suspends the execution of the calling thread until either at least the time specified in .I *duration has elapsed, or the delivery of a signal that triggers the invocation of a handler in the calling thread or that terminates the process. .P If the call is interrupted by a signal handler, .BR nanosleep () returns \-1, sets .I errno to .BR EINTR , and writes the remaining time into the structure pointed to by .I rem unless .I rem is NULL. The value of .I *rem can then be used to call .BR nanosleep () again and complete the specified pause (but see NOTES). .P The .BR timespec (3) structure is used to specify intervals of time with nanosecond precision. .P The value of the nanoseconds field must be in the range [0, 999999999]. .P Compared to .BR sleep (3) and .BR usleep (3), .BR nanosleep () has the following advantages: it provides a higher resolution for specifying the sleep interval; POSIX.1 explicitly specifies that it does not interact with signals; and it makes the task of resuming a sleep that has been interrupted by a signal handler easier. .SH RETURN VALUE On successfully sleeping for the requested duration, .BR nanosleep () returns 0. If the call is interrupted by a signal handler or encounters an error, then it returns \-1, with .I errno set to indicate the error. .SH ERRORS .TP .B EFAULT Problem with copying information from user space. .TP .B EINTR The pause has been interrupted by a signal that was delivered to the thread (see .BR signal (7)). The remaining sleep time has been written into .I *rem so that the thread can easily call .BR nanosleep () again and continue with the pause. .TP .B EINVAL The value in the .I tv_nsec field was not in the range [0, 999999999] or .I tv_sec was negative. .SH VERSIONS POSIX.1 specifies that .BR nanosleep () should measure time against the .B CLOCK_REALTIME clock. However, Linux measures the time using the .B CLOCK_MONOTONIC clock. .\" See also http://thread.gmane.org/gmane.linux.kernel/696854/ .\" Subject: nanosleep() uses CLOCK_MONOTONIC, should be CLOCK_REALTIME? .\" Date: 2008-06-22 07:35:41 GMT This probably does not matter, since the POSIX.1 specification for .BR clock_settime (2) says that discontinuous changes in .B CLOCK_REALTIME should not affect .BR nanosleep (): .RS .P Setting the value of the .B CLOCK_REALTIME clock via .BR clock_settime (2) shall have no effect on threads that are blocked waiting for a relative time service based upon this clock, including the .BR nanosleep () function; ... Consequently, these time services shall expire when the requested duration elapses, independently of the new or old value of the clock. .RE .SH STANDARDS POSIX.1-2008. .SH HISTORY POSIX.1-2001. .P In order to support applications requiring much more precise pauses (e.g., in order to control some time-critical hardware), .BR nanosleep () would handle pauses of up to 2 milliseconds by busy waiting with microsecond precision when called from a thread scheduled under a real-time policy like .B SCHED_FIFO or .BR SCHED_RR . This special extension was removed in Linux 2.5.39, and is thus not available in Linux 2.6.0 and later kernels. .SH NOTES If the .I duration is not an exact multiple of the granularity underlying clock (see .BR time (7)), then the interval will be rounded up to the next multiple. Furthermore, after the sleep completes, there may still be a delay before the CPU becomes free to once again execute the calling thread. .P The fact that .BR nanosleep () sleeps for a relative interval can be problematic if the call is repeatedly restarted after being interrupted by signals, since the time between the interruptions and restarts of the call will lead to drift in the time when the sleep finally completes. This problem can be avoided by using .BR clock_nanosleep (2) with an absolute time value. .SH BUGS If a program that catches signals and uses .BR nanosleep () receives signals at a very high rate, then scheduling delays and rounding errors in the kernel's calculation of the sleep interval and the returned .I remain value mean that the .I remain value may steadily .I increase on successive restarts of the .BR nanosleep () call. To avoid such problems, use .BR clock_nanosleep (2) with the .B TIMER_ABSTIME flag to sleep to an absolute deadline. .P In Linux 2.4, if .BR nanosleep () is stopped by a signal (e.g., .BR SIGTSTP ), then the call fails with the error .B EINTR after the thread is resumed by a .B SIGCONT signal. If the system call is subsequently restarted, then the time that the thread spent in the stopped state is .I not counted against the sleep interval. This problem is fixed in Linux 2.6.0 and later kernels. .SH SEE ALSO .BR clock_nanosleep (2), .BR restart_syscall (2), .BR sched_setscheduler (2), .BR timer_create (2), .BR sleep (3), .BR timespec (3), .BR usleep (3), .BR time (7)