libc/gen/t_sleep.c

1.10  christos /* $NetBSD: t_sleep.c,v 1.10 2017/01/10 15:31:11 christos Exp $ */
 1.1  pgoyette
 1.1  pgoyette /*-
 1.1  pgoyette  * Copyright (c) 2006 Frank Kardel
 1.1  pgoyette  * All rights reserved.
 1.1  pgoyette  *
 1.1  pgoyette  * Redistribution and use in source and binary forms, with or without
 1.1  pgoyette  * modification, are permitted provided that the following conditions
 1.1  pgoyette  * are met:
 1.1  pgoyette  * 1. Redistributions of source code must retain the above copyright
 1.1  pgoyette  *    notice, this list of conditions and the following disclaimer.
 1.1  pgoyette  * 2. Redistributions in binary form must reproduce the above copyright
 1.1  pgoyette  *    notice, this list of conditions and the following disclaimer in the
 1.1  pgoyette  *    documentation and/or other materials provided with the distribution.
 1.1  pgoyette  *
 1.1  pgoyette  * THIS SOFTWARE IS PROVIDED BY THE NETBSD FOUNDATION, INC. AND CONTRIBUTORS
 1.1  pgoyette  * ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED
 1.1  pgoyette  * TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
 1.1  pgoyette  * PURPOSE ARE DISCLAIMED.  IN NO EVENT SHALL THE FOUNDATION OR CONTRIBUTORS
 1.1  pgoyette  * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
 1.1  pgoyette  * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
 1.1  pgoyette  * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
 1.1  pgoyette  * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
 1.1  pgoyette  * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
 1.1  pgoyette  * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
 1.1  pgoyette  * POSSIBILITY OF SUCH DAMAGE.
 1.1  pgoyette  */
 1.1  pgoyette
1.10  christos #include <sys/cdefs.h>
1.10  christos #include <sys/event.h>
1.10  christos #include <sys/signal.h>
1.10  christos #include <sys/time.h>		/* for TIMESPEC_TO_TIMEVAL on FreeBSD */
1.10  christos
 1.1  pgoyette #include <atf-c.h>
 1.1  pgoyette #include <errno.h>
 1.1  pgoyette #include <poll.h>
 1.1  pgoyette #include <stdio.h>
 1.1  pgoyette #include <stdlib.h>
1.10  christos #include <inttypes.h>
 1.1  pgoyette #include <string.h>
1.10  christos #include <inttypes.h>
 1.1  pgoyette #include <time.h>
 1.1  pgoyette #include <unistd.h>
 1.1  pgoyette
 1.7  christos #include "isqemu.h"
 1.7  christos
 1.1  pgoyette #define BILLION		1000000000LL	/* nano-seconds per second */
 1.1  pgoyette #define MILLION		1000000LL	/* nano-seconds per milli-second */
 1.1  pgoyette
 1.5  pgoyette #define ALARM		6		/* SIGALRM after this many seconds */
 1.5  pgoyette #define MAXSLEEP	22		/* Maximum delay in seconds */
 1.5  pgoyette #define KEVNT_TIMEOUT	10300		/* measured in milli-seconds */
 1.4  pgoyette #define FUZZ		(40 * MILLION)	/* scheduling fuzz accepted - 40 ms */
 1.4  pgoyette
 1.4  pgoyette /*
 1.4  pgoyette  * Timer notes
 1.4  pgoyette  *
 1.4  pgoyette  * Most tests use FUZZ as their initial delay value, but 'sleep'
 1.4  pgoyette  * starts at 1sec (since it cannot handle sub-second intervals).
 1.4  pgoyette  * Subsequent passes double the previous interval, up to MAXSLEEP.
 1.4  pgoyette  *
 1.5  pgoyette  * The current values result in 5 passes for the 'sleep' test (at 1,
 1.5  pgoyette  * 2, 4, 8, and 16 seconds) and 10 passes for the other tests (at
 1.5  pgoyette  * 0.04, 0.08, 0.16, 0.32, 0.64, 1.28, 2.56, 5.12, 10.24, and 20.48
 1.5  pgoyette  * seconds).
 1.4  pgoyette  *
 1.5  pgoyette  * The ALARM is only set if the current pass's delay is longer, and
 1.5  pgoyette  * only if the ALARM has not already been triggered.
 1.4  pgoyette  *
 1.5  pgoyette  * The 'kevent' test needs the ALARM to be set on a different pass
 1.5  pgoyette  * from when the KEVNT_TIMEOUT fires.  So set ALARM to fire on the
 1.5  pgoyette  * penultimate pass, and the KEVNT_TIMEOUT on the final pass.  We
 1.5  pgoyette  * set KEVNT_TIMEOUT just barely long enough to put it into the
 1.5  pgoyette  * last test pass, and set MAXSLEEP a couple seconds longer than
 1.8      gson  * necessary, in order to avoid a QEMU bug which nearly doubles
 1.5  pgoyette  * some timers.
 1.4  pgoyette  */
 1.4  pgoyette
 1.4  pgoyette static volatile int sig;
 1.1  pgoyette
 1.1  pgoyette int sleeptest(int (*)(struct timespec *, struct timespec *), bool, bool);
 1.1  pgoyette int do_nanosleep(struct timespec *, struct timespec *);
 1.1  pgoyette int do_select(struct timespec *, struct timespec *);
 1.1  pgoyette int do_poll(struct timespec *, struct timespec *);
 1.1  pgoyette int do_sleep(struct timespec *, struct timespec *);
 1.1  pgoyette int do_kevent(struct timespec *, struct timespec *);
 1.1  pgoyette void sigalrm(int);
 1.1  pgoyette
 1.1  pgoyette void
 1.1  pgoyette sigalrm(int s)
 1.1  pgoyette {
 1.4  pgoyette
 1.1  pgoyette 	sig++;
 1.1  pgoyette }
 1.1  pgoyette
 1.1  pgoyette int
 1.1  pgoyette do_nanosleep(struct timespec *delay, struct timespec *remain)
 1.1  pgoyette {
 1.1  pgoyette 	int ret;
 1.1  pgoyette
 1.1  pgoyette 	if (nanosleep(delay, remain) == -1)
 1.1  pgoyette 		ret = (errno == EINTR ? 0 : errno);
 1.1  pgoyette 	else
 1.1  pgoyette 		ret = 0;
 1.1  pgoyette 	return ret;
 1.1  pgoyette }
 1.1  pgoyette
 1.1  pgoyette int
 1.1  pgoyette do_select(struct timespec *delay, struct timespec *remain)
 1.1  pgoyette {
 1.1  pgoyette 	int ret;
 1.1  pgoyette 	struct timeval tv;
 1.1  pgoyette
 1.1  pgoyette 	TIMESPEC_TO_TIMEVAL(&tv, delay);
 1.1  pgoyette 	if (select(0, NULL, NULL, NULL, &tv) == -1)
 1.1  pgoyette 		ret = (errno == EINTR ? 0 : errno);
 1.1  pgoyette 	else
 1.1  pgoyette 		ret = 0;
 1.1  pgoyette 	return ret;
 1.1  pgoyette }
 1.1  pgoyette
 1.1  pgoyette int
 1.1  pgoyette do_poll(struct timespec *delay, struct timespec *remain)
 1.1  pgoyette {
 1.1  pgoyette 	int ret;
 1.1  pgoyette 	struct timeval tv;
 1.1  pgoyette
 1.1  pgoyette 	TIMESPEC_TO_TIMEVAL(&tv, delay);
 1.1  pgoyette 	if (pollts(NULL, 0, delay, NULL) == -1)
 1.1  pgoyette 		ret = (errno == EINTR ? 0 : errno);
 1.1  pgoyette 	else
 1.1  pgoyette 		ret = 0;
 1.1  pgoyette 	return ret;
 1.1  pgoyette }
 1.1  pgoyette
 1.1  pgoyette int
 1.1  pgoyette do_sleep(struct timespec *delay, struct timespec *remain)
 1.1  pgoyette {
 1.1  pgoyette 	struct timeval tv;
 1.1  pgoyette
 1.1  pgoyette 	TIMESPEC_TO_TIMEVAL(&tv, delay);
 1.1  pgoyette 	remain->tv_sec = sleep(delay->tv_sec);
 1.1  pgoyette 	remain->tv_nsec = 0;
 1.1  pgoyette
 1.1  pgoyette 	return 0;
 1.1  pgoyette }
 1.1  pgoyette
 1.1  pgoyette int
 1.1  pgoyette do_kevent(struct timespec *delay, struct timespec *remain)
 1.1  pgoyette {
 1.1  pgoyette 	struct kevent ktimer;
 1.1  pgoyette 	struct kevent kresult;
 1.1  pgoyette 	int rtc, kq, kerrno;
 1.4  pgoyette 	int tmo;
 1.1  pgoyette
 1.1  pgoyette 	ATF_REQUIRE_MSG((kq = kqueue()) != -1, "kqueue: %s", strerror(errno));
 1.1  pgoyette
 1.4  pgoyette 	tmo = KEVNT_TIMEOUT;
 1.5  pgoyette
 1.5  pgoyette 	/*
 1.5  pgoyette 	 * If we expect the KEVNT_TIMEOUT to fire, and we're running
 1.5  pgoyette 	 * under QEMU, make sure the delay is long enough to account
 1.5  pgoyette 	 * for the effects of PR kern/43997 !
 1.5  pgoyette 	 */
 1.7  christos 	if (isQEMU() &&
 1.5  pgoyette 	    tmo/1000 < delay->tv_sec && tmo/500 > delay->tv_sec)
 1.5  pgoyette 		delay->tv_sec = MAXSLEEP;
 1.5  pgoyette
 1.1  pgoyette 	EV_SET(&ktimer, 1, EVFILT_TIMER, EV_ADD, 0, tmo, 0);
 1.1  pgoyette
 1.1  pgoyette 	rtc = kevent(kq, &ktimer, 1, &kresult, 1, delay);
 1.1  pgoyette 	kerrno = errno;
 1.1  pgoyette
 1.1  pgoyette 	(void)close(kq);
 1.1  pgoyette
 1.4  pgoyette 	if (rtc == -1) {
 1.9       kre 		ATF_REQUIRE_MSG(kerrno == EINTR, "kevent: %s",
 1.9       kre 		    strerror(kerrno));
 1.4  pgoyette 		return 0;
 1.4  pgoyette 	}
 1.1  pgoyette
 1.3  pgoyette 	if (delay->tv_sec * BILLION + delay->tv_nsec > tmo * MILLION)
 1.3  pgoyette 		ATF_REQUIRE_MSG(rtc > 0,
 1.5  pgoyette 		    "kevent: KEVNT_TIMEOUT did not cause EVFILT_TIMER event");
 1.1  pgoyette
 1.1  pgoyette 	return 0;
 1.1  pgoyette }
 1.1  pgoyette
 1.1  pgoyette ATF_TC(nanosleep);
 1.1  pgoyette ATF_TC_HEAD(nanosleep, tc)
 1.1  pgoyette {
 1.1  pgoyette
 1.1  pgoyette 	atf_tc_set_md_var(tc, "descr", "Test nanosleep(2) timing");
 1.1  pgoyette 	atf_tc_set_md_var(tc, "timeout", "65");
 1.1  pgoyette }
 1.1  pgoyette
 1.1  pgoyette ATF_TC_BODY(nanosleep, tc)
 1.1  pgoyette {
 1.1  pgoyette
 1.1  pgoyette 	sleeptest(do_nanosleep, true, false);
 1.1  pgoyette }
 1.1  pgoyette
 1.1  pgoyette ATF_TC(select);
 1.1  pgoyette ATF_TC_HEAD(select, tc)
 1.1  pgoyette {
 1.1  pgoyette
 1.1  pgoyette 	atf_tc_set_md_var(tc, "descr", "Test select(2) timing");
 1.1  pgoyette 	atf_tc_set_md_var(tc, "timeout", "65");
 1.1  pgoyette }
 1.1  pgoyette
 1.1  pgoyette ATF_TC_BODY(select, tc)
 1.1  pgoyette {
 1.1  pgoyette
 1.1  pgoyette 	sleeptest(do_select, true, true);
 1.1  pgoyette }
 1.1  pgoyette
 1.1  pgoyette ATF_TC(poll);
 1.1  pgoyette ATF_TC_HEAD(poll, tc)
 1.1  pgoyette {
 1.1  pgoyette
 1.1  pgoyette 	atf_tc_set_md_var(tc, "descr", "Test poll(2) timing");
 1.1  pgoyette 	atf_tc_set_md_var(tc, "timeout", "65");
 1.1  pgoyette }
 1.1  pgoyette
 1.1  pgoyette ATF_TC_BODY(poll, tc)
 1.1  pgoyette {
 1.1  pgoyette
 1.1  pgoyette 	sleeptest(do_poll, true, true);
 1.1  pgoyette }
 1.1  pgoyette
 1.1  pgoyette ATF_TC(sleep);
 1.1  pgoyette ATF_TC_HEAD(sleep, tc)
 1.1  pgoyette {
 1.1  pgoyette
 1.1  pgoyette 	atf_tc_set_md_var(tc, "descr", "Test sleep(3) timing");
 1.1  pgoyette 	atf_tc_set_md_var(tc, "timeout", "65");
 1.1  pgoyette }
 1.1  pgoyette
 1.1  pgoyette ATF_TC_BODY(sleep, tc)
 1.1  pgoyette {
 1.1  pgoyette
 1.1  pgoyette 	sleeptest(do_sleep, false, false);
 1.1  pgoyette }
 1.1  pgoyette
 1.1  pgoyette ATF_TC(kevent);
 1.1  pgoyette ATF_TC_HEAD(kevent, tc)
 1.1  pgoyette {
 1.1  pgoyette
 1.1  pgoyette 	atf_tc_set_md_var(tc, "descr", "Test kevent(2) timing");
 1.1  pgoyette 	atf_tc_set_md_var(tc, "timeout", "65");
 1.1  pgoyette }
 1.1  pgoyette
 1.1  pgoyette ATF_TC_BODY(kevent, tc)
 1.1  pgoyette {
 1.1  pgoyette
 1.1  pgoyette 	sleeptest(do_kevent, true, true);
 1.1  pgoyette }
 1.1  pgoyette
 1.1  pgoyette int
 1.1  pgoyette sleeptest(int (*test)(struct timespec *, struct timespec *),
 1.1  pgoyette 	   bool subsec, bool sim_remain)
 1.1  pgoyette {
 1.1  pgoyette 	struct timespec tsa, tsb, tslp, tremain;
 1.1  pgoyette 	int64_t delta1, delta2, delta3, round;
 1.1  pgoyette
 1.1  pgoyette 	sig = 0;
 1.1  pgoyette 	signal(SIGALRM, sigalrm);
 1.1  pgoyette
 1.1  pgoyette 	if (subsec) {
 1.1  pgoyette 		round = 1;
 1.1  pgoyette 		delta3 = FUZZ;
 1.1  pgoyette 	} else {
 1.1  pgoyette 		round = 1000000000;
 1.1  pgoyette 		delta3 = round;
 1.1  pgoyette 	}
 1.1  pgoyette
 1.1  pgoyette 	tslp.tv_sec = delta3 / 1000000000;
 1.1  pgoyette 	tslp.tv_nsec = delta3 % 1000000000;
 1.1  pgoyette
 1.5  pgoyette 	while (tslp.tv_sec <= MAXSLEEP) {
 1.1  pgoyette 		/*
 1.1  pgoyette 		 * disturb sleep by signal on purpose
 1.1  pgoyette 		 */
 1.5  pgoyette 		if (tslp.tv_sec > ALARM && sig == 0)
 1.1  pgoyette 			alarm(ALARM);
 1.1  pgoyette
 1.1  pgoyette 		clock_gettime(CLOCK_REALTIME, &tsa);
 1.1  pgoyette 		(*test)(&tslp, &tremain);
 1.1  pgoyette 		clock_gettime(CLOCK_REALTIME, &tsb);
 1.1  pgoyette
 1.1  pgoyette 		if (sim_remain) {
 1.1  pgoyette 			timespecsub(&tsb, &tsa, &tremain);
 1.1  pgoyette 			timespecsub(&tslp, &tremain, &tremain);
 1.1  pgoyette 		}
 1.1  pgoyette
 1.1  pgoyette 		delta1 = (int64_t)tsb.tv_sec - (int64_t)tsa.tv_sec;
 1.1  pgoyette 		delta1 *= BILLION;
 1.1  pgoyette 		delta1 += (int64_t)tsb.tv_nsec - (int64_t)tsa.tv_nsec;
 1.1  pgoyette
 1.1  pgoyette 		delta2 = (int64_t)tremain.tv_sec * BILLION;
 1.1  pgoyette 		delta2 += (int64_t)tremain.tv_nsec;
 1.1  pgoyette
 1.1  pgoyette 		delta3 = (int64_t)tslp.tv_sec * BILLION;
 1.1  pgoyette 		delta3 += (int64_t)tslp.tv_nsec - delta1 - delta2;
 1.1  pgoyette
 1.1  pgoyette 		delta3 /= round;
 1.1  pgoyette 		delta3 *= round;
 1.1  pgoyette
 1.4  pgoyette 		if (delta3 > FUZZ || delta3 < -FUZZ) {
 1.6      jmmv 			if (!sim_remain)
 1.4  pgoyette 				atf_tc_expect_fail("Long reschedule latency "
 1.4  pgoyette 				    "due to PR kern/43997");
 1.1  pgoyette
 1.4  pgoyette 			atf_tc_fail("Reschedule latency %"PRId64" exceeds "
 1.4  pgoyette 			    "allowable fuzz %lld", delta3, FUZZ);
 1.4  pgoyette 		}
 1.1  pgoyette 		delta3 = (int64_t)tslp.tv_sec * 2 * BILLION;
 1.1  pgoyette 		delta3 += (int64_t)tslp.tv_nsec * 2;
 1.1  pgoyette
 1.1  pgoyette 		delta3 /= round;
 1.1  pgoyette 		delta3 *= round;
 1.1  pgoyette 		if (delta3 < FUZZ)
 1.1  pgoyette 			break;
 1.1  pgoyette 		tslp.tv_sec = delta3 / BILLION;
 1.1  pgoyette 		tslp.tv_nsec = delta3 % BILLION;
 1.1  pgoyette 	}
 1.1  pgoyette 	ATF_REQUIRE_MSG(sig == 1, "Alarm did not fire!");
 1.1  pgoyette
 1.1  pgoyette 	atf_tc_pass();
 1.1  pgoyette }
 1.1  pgoyette
 1.1  pgoyette ATF_TP_ADD_TCS(tp)
 1.1  pgoyette {
 1.1  pgoyette 	ATF_TP_ADD_TC(tp, nanosleep);
 1.1  pgoyette 	ATF_TP_ADD_TC(tp, select);
 1.1  pgoyette 	ATF_TP_ADD_TC(tp, poll);
 1.1  pgoyette 	ATF_TP_ADD_TC(tp, sleep);
 1.1  pgoyette 	ATF_TP_ADD_TC(tp, kevent);
 1.1  pgoyette
 1.1  pgoyette 	return atf_no_error();
 1.1  pgoyette }