/*
* %CopyrightBegin%
*
* Copyright Ericsson AB 1999-2010. All Rights Reserved.
*
* The contents of this file are subject to the Erlang Public License,
* Version 1.1, (the "License"); you may not use this file except in
* compliance with the License. You should have received a copy of the
* Erlang Public License along with this software. If not, it can be
* retrieved online at http://www.erlang.org/.
*
* Software distributed under the License is distributed on an "AS IS"
* basis, WITHOUT WARRANTY OF ANY KIND, either express or implied. See
* the License for the specific language governing rights and limitations
* under the License.
*
* %CopyrightEnd%
*/
/*
** Support routines for the timer wheel
**
** This code contains two strategies for dealing with
** date/time changes in the system.
** If the system has some kind of high resolution timer (HAVE_GETHRTIME),
** the high resolution timer is used to correct the time-of-day and the
** timeouts, the base source is the hrtimer, but at certain intervals the
** OS time-of-day is checked and if it is not within certain bounds, the
** delivered time gets slowly adjusted for each call until
** it corresponds to the system time (built-in adjtime...).
** The call gethrtime() is detected by autoconf on Unix, but other
** platforms may define it in erl_*_sys.h and implement
** their own high resolution timer. The high resolution timer
** strategy is (probably) best on all systems where the timer have
** a resolution higher or equal to gettimeofday (or what's implemented
** is sys_gettimeofday()). The actual resolution is the interesting thing,
** not the unit's thats used (i.e. on VxWorks, nanoseconds can be
** retrieved in terms of units, but the actual resolution is the same as
** for the clock ticks).
** If the systems best timer routine is kernel ticks returned from
** sys_times(), and the actual resolution of sys_gettimeofday() is
** better (like most unixes that does not have any realtime extensions),
** another strategy is used. The tolerant gettimeofday() corrects
** the value with respect to uptime (sys_times() return value) and checks
** for correction both when delivering timeticks and delivering nowtime.
** this strategy is slower, but accurate on systems without better timer
** routines. The kernel tick resolution is not enough to implement
** a gethrtime routine. On Linux and other non solaris unix-boxes the second
** strategy is used, on all other platforms we use the first.
**
** The following is expected (from sys.[ch] and erl_*_sys.h):
**
** 64 bit integers. So it is, and so it will be.
**
** sys_init_time(), will return the clock resolution in MS and
** that's about it. More could be added of course
** If the clock-rate is constant (i.e. 1 ms) one can define
** SYS_CLOCK_RESOLUTION (to 1),
** which makes erts_deliver_time/erts_time_remaining a bit faster.
**
** if HAVE_GETHRTIME is defined:
** sys_gethrtime() will return a SysHrTime (long long) representing
** nanoseconds, sys_init_hrtime() will do any initialization.
** else
** a long (64bit) integer type called Sint64 should be defined.
**
** sys_times() will return clock_ticks since start and
** fill in a SysTimes structure (struct tms). Instead of CLK_TCK,
** SYS_CLK_TCK is used to determine the resolution of kernel ticks.
**
** sys_gettimeofday() will take a SysTimeval (a struct timeval) as parameter
** and fill it in as gettimeofday(X,NULL).
**
*/
#ifdef HAVE_CONFIG_H
# include "config.h"
#endif
#include "sys.h"
#include "erl_vm.h"
#include "global.h"
static erts_smp_mtx_t erts_timeofday_mtx;
static SysTimeval inittv; /* Used everywhere, the initial time-of-day */
static SysTimes t_start; /* Used in elapsed_time_both */
static SysTimeval gtv; /* Used in wall_clock_elapsed_time_both */
static SysTimeval then; /* Used in get_now */
static SysTimeval last_emu_time; /* Used in erts_get_emu_time() */
SysTimeval erts_first_emu_time; /* Used in erts_get_emu_time() */
#ifdef HAVE_GETHRTIME
int erts_disable_tolerant_timeofday;
static SysHrTime hr_init_time, hr_last_correction_check,
hr_correction, hr_last_time;
static void init_tolerant_timeofday(void)
{
/* Should be in sys.c */
#if defined(HAVE_SYSCONF) && defined(_SC_NPROCESSORS_CONF)
if (sysconf(_SC_NPROCESSORS_CONF) > 1) {
char b[1024];
int maj,min,build;
os_flavor(b,1024);
os_version(&maj,&min,&build);
if (!strcmp(b,"sunos") && maj <= 5 && min <= 7) {
erts_disable_tolerant_timeofday = 1;
}
}
#endif
hr_init_time = sys_gethrtime();
hr_last_correction_check = hr_last_time = hr_init_time;
hr_correction = 0;
}
static void get_tolerant_timeofday(SysTimeval *tv)
{
SysHrTime diff_time, curr;
if (erts_disable_tolerant_timeofday) {
sys_gettimeofday(tv);
return;
}
*tv = inittv;
diff_time = ((curr = sys_gethrtime()) + hr_correction - hr_init_time) / 1000;
if (curr < hr_init_time) {
erl_exit(1,"Unexpected behaviour from operating system high "
"resolution timer");
}
if ((curr - hr_last_correction_check) / 1000 > 1000000) {
/* Check the correction need */
SysHrTime tv_diff, diffdiff;
SysTimeval tmp;
int done = 0;
sys_gettimeofday(&tmp);
tv_diff = ((SysHrTime) tmp.tv_sec) * 1000000 + tmp.tv_usec;
tv_diff -= ((SysHrTime) inittv.tv_sec) * 1000000 + inittv.tv_usec;
diffdiff = diff_time - tv_diff;
if (diffdiff > 10000) {
SysHrTime corr = (curr - hr_last_time) / 100;
if (corr / 1000 >= diffdiff) {
++done;
hr_correction -= ((SysHrTime)diffdiff) * 1000;
} else {
hr_correction -= corr;
}
diff_time = (curr + hr_correction - hr_init_time) / 1000;
} else if (diffdiff < -10000) {
SysHrTime corr = (curr - hr_last_time) / 100;
if (corr / 1000 >= -diffdiff) {
++done;
hr_correction -= ((SysHrTime)diffdiff) * 1000;
} else {
hr_correction += corr;
}
diff_time = (curr + hr_correction - hr_init_time) / 1000;
} else {
++done;
}
if (done) {
hr_last_correction_check = curr;
}
}
tv->tv_sec += (int) (diff_time / ((SysHrTime) 1000000));
tv->tv_usec += (int) (diff_time % ((SysHrTime) 1000000));
if (tv->tv_usec >= 1000000) {
tv->tv_usec -= 1000000;
tv->tv_sec += 1;
}
hr_last_time = curr;
}
#define correction (hr_correction/1000000)
#else /* !HAVE_GETHRTIME */
#if !defined(CORRECT_USING_TIMES)
#define init_tolerant_timeofday()
#define get_tolerant_timeofday(tvp) sys_gettimeofday(tvp)
#else
typedef Sint64 Milli;
static clock_t init_ct;
static Sint64 ct_wrap;
static Milli init_tv_m;
static Milli correction_supress;
static Milli last_ct_diff;
static Milli last_cc;
static clock_t last_ct;
/* sys_times() might need to be wrapped and the values shifted (right)
a bit to cope with newer linux (2.5.*) kernels, this has to be taken care
of dynamically to start with, a special version that uses
the times() return value as a high resolution timer can be made
to fully utilize the faster ticks, like on windows, but for now, we'll
settle with this silly workaround */
#ifdef ERTS_WRAP_SYS_TIMES
#define KERNEL_TICKS() (sys_times_wrap() & \
((1UL << ((sizeof(clock_t) * 8) - 1)) - 1))
#else
SysTimes dummy_tms;
#define KERNEL_TICKS() (sys_times(&dummy_tms) & \
((1UL << ((sizeof(clock_t) * 8) - 1)) - 1))
#endif
static void init_tolerant_timeofday(void)
{
last_ct = init_ct = KERNEL_TICKS();
last_cc = 0;
init_tv_m = (((Milli) inittv.tv_sec) * 1000) +
(inittv.tv_usec / 1000);
ct_wrap = 0;
correction_supress = 0;
}
static void get_tolerant_timeofday(SysTimeval *tvp)
{
clock_t current_ct;
SysTimeval current_tv;
Milli ct_diff;
Milli tv_diff;
Milli current_correction;
Milli act_correction; /* long shown to be too small */
Milli max_adjust;
if (erts_disable_tolerant_timeofday) {
sys_gettimeofday(tvp);
return;
}
#ifdef ERTS_WRAP_SYS_TIMES
#define TICK_MS (1000 / SYS_CLK_TCK_WRAP)
#else
#define TICK_MS (1000 / SYS_CLK_TCK)
#endif
current_ct = KERNEL_TICKS();
sys_gettimeofday(¤t_tv);
/* I dont know if uptime can move some units backwards
on some systems, but I allow for small backward
jumps to avoid such problems if they exist...*/
if (last_ct > 100 && current_ct < (last_ct - 100)) {
ct_wrap += ((Sint64) 1) << ((sizeof(clock_t) * 8) - 1);
}
last_ct = current_ct;
ct_diff = ((ct_wrap + current_ct) - init_ct) * TICK_MS;
/*
* We will adjust the time in milliseconds and we allow for 1%
* adjustments, but if this function is called more often then every 100
* millisecond (which is obviously possible), we will never adjust, so
* we accumulate small times by setting last_ct_diff iff max_adjust > 0
*/
if ((max_adjust = (ct_diff - last_ct_diff)/100) > 0)
last_ct_diff = ct_diff;
tv_diff = ((((Milli) current_tv.tv_sec) * 1000) +
(current_tv.tv_usec / 1000)) - init_tv_m;
current_correction = ((ct_diff - tv_diff) / TICK_MS) * TICK_MS; /* trunc */
/*
* We allow the current_correction value to wobble a little, as it
* suffers from the low resolution of the kernel ticks.
* if it hasn't changed more than one tick in either direction,
* we will keep the old value.
*/
if ((last_cc > current_correction + TICK_MS) ||
(last_cc < current_correction - TICK_MS)) {
last_cc = current_correction;
} else {
current_correction = last_cc;
}
/*
* As time goes, we try to get the actual correction to 0,
* that is, make erlangs time correspond to the systems dito.
* The act correction is what we seem to need (current_correction)
* minus the correction suppression. The correction supression
* will change slowly (max 1% of elapsed time) but in millisecond steps.
*/
act_correction = current_correction - correction_supress;
if (max_adjust > 0) {
/*
* Here we slowly adjust erlangs time to correspond with the
* system time by changing the correction_supress variable.
* It can change max_adjust milliseconds which is 1% of elapsed time
*/
if (act_correction > 0) {
if (current_correction - correction_supress > max_adjust) {
correction_supress += max_adjust;
} else {
correction_supress = current_correction;
}
act_correction = current_correction - correction_supress;
} else if (act_correction < 0) {
if (correction_supress - current_correction > max_adjust) {
correction_supress -= max_adjust;
} else {
correction_supress = current_correction;
}
act_correction = current_correction - correction_supress;
}
}
/*
* The actual correction will correct the timeval so that system
* time warps gets smothed down.
*/
current_tv.tv_sec += act_correction / 1000;
current_tv.tv_usec += (act_correction % 1000) * 1000;
if (current_tv.tv_usec >= 1000000) {
++current_tv.tv_sec ;
current_tv.tv_usec -= 1000000;
} else if (current_tv.tv_usec < 0) {
--current_tv.tv_sec;
current_tv.tv_usec += 1000000;
}
*tvp = current_tv;
#undef TICK_MS
}
#endif /* CORRECT_USING_TIMES */
#endif /* !HAVE_GETHRTIME */
/*
** Why this? Well, most platforms have a constant clock resolution of 1,
** we dont want the deliver_time/time_remaining routines to waste
** time dividing and multiplying by/with a variable that's always one.
** so the return value of sys_init_time is ignored on those platforms.
*/
#ifndef SYS_CLOCK_RESOLUTION
static int clock_resolution;
#define CLOCK_RESOLUTION clock_resolution
#else
#define CLOCK_RESOLUTION SYS_CLOCK_RESOLUTION
#endif
/*
** The clock resolution should really be the resolution of the
** time function in use, which on most platforms
** is 1. On VxWorks the resolution shold be
** the number of ticks per second (or 1, which would work nicely to).
**
** Setting lower resolutions is mostly interesting when timers are used
** instead of something like select.
*/
static SysTimeval last_delivered;
static void init_erts_deliver_time(const SysTimeval *inittv)
{
/* We set the initial values for deliver_time here */
last_delivered = *inittv;
last_delivered.tv_usec = 1000 * (last_delivered.tv_usec / 1000);
/* ms resolution */
}
static void do_erts_deliver_time(const SysTimeval *current)
{
SysTimeval cur_time;
long elapsed;
/* calculate and deliver appropriate number of ticks */
cur_time = *current;
cur_time.tv_usec = 1000 * (cur_time.tv_usec / 1000); /* ms resolution */
elapsed = (1000 * (cur_time.tv_sec - last_delivered.tv_sec) +
(cur_time.tv_usec - last_delivered.tv_usec) / 1000) /
CLOCK_RESOLUTION;
/* Sometimes the time jump backwards,
resulting in a negative elapsed time. We compensate for
this by simply pretend as if the time stood still. :) */
if (elapsed > 0) {
erts_do_time_add(elapsed);
last_delivered = cur_time;
}
}
int
erts_init_time_sup(void)
{
erts_smp_mtx_init(&erts_timeofday_mtx, "timeofday");
last_emu_time.tv_sec = 0;
last_emu_time.tv_usec = 0;
#ifndef SYS_CLOCK_RESOLUTION
clock_resolution = sys_init_time();
#else
(void) sys_init_time();
#endif
sys_gettimeofday(&inittv);
#ifdef HAVE_GETHRTIME
sys_init_hrtime();
#endif
init_tolerant_timeofday();
init_erts_deliver_time(&inittv);
gtv = inittv;
then.tv_sec = then.tv_usec = 0;
erts_get_emu_time(&erts_first_emu_time);
return CLOCK_RESOLUTION;
}
/* info functions */
void
elapsed_time_both(UWord *ms_user, UWord *ms_sys,
UWord *ms_user_diff, UWord *ms_sys_diff)
{
UWord prev_total_user, prev_total_sys;
UWord total_user, total_sys;
SysTimes now;
sys_times(&now);
total_user = (now.tms_utime * 1000) / SYS_CLK_TCK;
total_sys = (now.tms_stime * 1000) / SYS_CLK_TCK;
if (ms_user != NULL)
*ms_user = total_user;
if (ms_sys != NULL)
*ms_sys = total_sys;
erts_smp_mtx_lock(&erts_timeofday_mtx);
prev_total_user = (t_start.tms_utime * 1000) / SYS_CLK_TCK;
prev_total_sys = (t_start.tms_stime * 1000) / SYS_CLK_TCK;
t_start = now;
erts_smp_mtx_unlock(&erts_timeofday_mtx);
if (ms_user_diff != NULL)
*ms_user_diff = total_user - prev_total_user;
if (ms_sys_diff != NULL)
*ms_sys_diff = total_sys - prev_total_sys;
}
/* wall clock routines */
void
wall_clock_elapsed_time_both(UWord *ms_total, UWord *ms_diff)
{
UWord prev_total;
SysTimeval tv;
erts_smp_mtx_lock(&erts_timeofday_mtx);
get_tolerant_timeofday(&tv);
*ms_total = 1000 * (tv.tv_sec - inittv.tv_sec) +
(tv.tv_usec - inittv.tv_usec) / 1000;
prev_total = 1000 * (gtv.tv_sec - inittv.tv_sec) +
(gtv.tv_usec - inittv.tv_usec) / 1000;
*ms_diff = *ms_total - prev_total;
gtv = tv;
/* must sync the machine's idea of time here */
do_erts_deliver_time(&tv);
erts_smp_mtx_unlock(&erts_timeofday_mtx);
}
/* get current time */
void
get_time(int *hour, int *minute, int *second)
{
time_t the_clock;
struct tm *tm;
#ifdef HAVE_LOCALTIME_R
struct tm tmbuf;
#endif
the_clock = time((time_t *)0);
#ifdef HAVE_LOCALTIME_R
localtime_r(&the_clock, (tm = &tmbuf));
#else
tm = localtime(&the_clock);
#endif
*hour = tm->tm_hour;
*minute = tm->tm_min;
*second = tm->tm_sec;
}
/* get current date */
void
get_date(int *year, int *month, int *day)
{
time_t the_clock;
struct tm *tm;
#ifdef HAVE_LOCALTIME_R
struct tm tmbuf;
#endif
the_clock = time((time_t *)0);
#ifdef HAVE_LOCALTIME_R
localtime_r(&the_clock, (tm = &tmbuf));
#else
tm = localtime(&the_clock);
#endif
*year = tm->tm_year + 1900;
*month = tm->tm_mon +1;
*day = tm->tm_mday;
}
/* get localtime */
void
get_localtime(int *year, int *month, int *day,
int *hour, int *minute, int *second)
{
time_t the_clock;
struct tm *tm;
#ifdef HAVE_LOCALTIME_R
struct tm tmbuf;
#endif
the_clock = time((time_t *)0);
#ifdef HAVE_LOCALTIME_R
localtime_r(&the_clock, (tm = &tmbuf));
#else
tm = localtime(&the_clock);
#endif
*year = tm->tm_year + 1900;
*month = tm->tm_mon +1;
*day = tm->tm_mday;
*hour = tm->tm_hour;
*minute = tm->tm_min;
*second = tm->tm_sec;
}
/* get universaltime */
void
get_universaltime(int *year, int *month, int *day,
int *hour, int *minute, int *second)
{
time_t the_clock;
struct tm *tm;
#ifdef HAVE_GMTIME_R
struct tm tmbuf;
#endif
the_clock = time((time_t *)0);
#ifdef HAVE_GMTIME_R
gmtime_r(&the_clock, (tm = &tmbuf));
#else
tm = gmtime(&the_clock);
#endif
*year = tm->tm_year + 1900;
*month = tm->tm_mon +1;
*day = tm->tm_mday;
*hour = tm->tm_hour;
*minute = tm->tm_min;
*second = tm->tm_sec;
}
/* days in month = 1, 2, ..., 12 */
static const int mdays[14] = {0, 31, 28, 31, 30, 31, 30,
31, 31, 30, 31, 30, 31};
#define IN_RANGE(a,x,b) (((a) <= (x)) && ((x) <= (b)))
#define is_leap_year(y) (((((y) % 4) == 0) && \
(((y) % 100) != 0)) || \
(((y) % 400) == 0))
#define BASEYEAR INT_MIN
/* A more "clever" mktime
* return 1, if successful
* return -1, if not successful
*/
static int erl_mktime(time_t *c, struct tm *tm) {
time_t clock;
clock = mktime(tm);
if (clock != -1) {
*c = clock;
return 1;
}
/* in rare occasions mktime returns -1
* when a correct value has been entered
*
* decrease seconds with one second
* if the result is -2, epochs should be -1
*/
tm->tm_sec = tm->tm_sec - 1;
clock = mktime(tm);
tm->tm_sec = tm->tm_sec + 1;
*c = -1;
if (clock == -2) {
return 1;
}
return -1;
}
/*
* gregday
*
* Returns the number of days since Jan 1, 1600, if year is
* greater of equal to 1600 , and month [1-12] and day [1-31]
* are within range. Otherwise it returns -1.
*/
static time_t gregday(Sint year, Sint month, Sint day)
{
int long ndays = 0;
int gyear, pyear, m;
/* number of days in previous years */
gyear = year - 1600;
if (gyear > 0) {
pyear = gyear - 1;
ndays = (pyear/4) - (pyear/100) + (pyear/400) + pyear*365 + 366;
}
/* number of days in all months preceeding month */
for (m = 1; m < month; m++)
ndays += mdays[m];
/* Extra day if leap year and March or later */
if (is_leap_year(year) && (month > 2))
ndays++;
ndays += day - 1;
return ndays - 135140; /* 135140 = Jan 1, 1970 */
}
#define SECONDS_PER_MINUTE (60)
#define SECONDS_PER_HOUR (60 * SECONDS_PER_MINUTE)
#define SECONDS_PER_DAY (24 * SECONDS_PER_HOUR)
#define SECONDS_PER_YEAR (86400)
int univ_to_seconds(Sint year, Sint month, Sint day, Sint hour, Sint minute, Sint second, Sint64 *time) {
Sint days;
if (!(IN_RANGE(1600, year, INT_MAX - 1) &&
IN_RANGE(1, month, 12) &&
IN_RANGE(1, day, (mdays[month] +
(month == 2
&& (year % 4 == 0)
&& (year % 100 != 0 || year % 400 == 0)))) &&
IN_RANGE(0, hour, 23) &&
IN_RANGE(0, minute, 59) &&
IN_RANGE(0, second, 59))) {
return 0;
}
days = gregday(year, month, day);
*time = SECONDS_PER_DAY;
*time *= days; /* don't try overflow it, it hurts */
*time += SECONDS_PER_HOUR * hour;
*time += SECONDS_PER_MINUTE * minute;
*time += second;
return 1;
}
int
local_to_univ(Sint *year, Sint *month, Sint *day,
Sint *hour, Sint *minute, Sint *second, int isdst)
{
time_t the_clock;
struct tm *tm, t;
#ifdef HAVE_GMTIME_R
struct tm tmbuf;
#endif
if (!(IN_RANGE(BASEYEAR, *year, INT_MAX - 1) &&
IN_RANGE(1, *month, 12) &&
IN_RANGE(1, *day, (mdays[*month] +
(*month == 2
&& (*year % 4 == 0)
&& (*year % 100 != 0 || *year % 400 == 0)))) &&
IN_RANGE(0, *hour, 23) &&
IN_RANGE(0, *minute, 59) &&
IN_RANGE(0, *second, 59))) {
return 0;
}
t.tm_year = *year - 1900;
t.tm_mon = *month - 1;
t.tm_mday = *day;
t.tm_hour = *hour;
t.tm_min = *minute;
t.tm_sec = *second;
t.tm_isdst = isdst;
/* the nature of mktime makes this a bit interesting,
* up to four mktime calls could happen here
*/
if (erl_mktime(&the_clock, &t) < 0) {
if (isdst) {
/* If this is a timezone without DST and the OS (correctly)
refuses to give us a DST time, we simulate the Linux/Solaris
behaviour of giving the same data as if is_dst was not set. */
t.tm_isdst = 0;
if (erl_mktime(&the_clock, &t)) {
/* Failed anyway, something else is bad - will be a badarg */
return 0;
}
} else {
/* Something else is the matter, badarg. */
return 0;
}
}
#ifdef HAVE_GMTIME_R
gmtime_r(&the_clock, (tm = &tmbuf));
#else
tm = gmtime(&the_clock);
#endif
*year = tm->tm_year + 1900;
*month = tm->tm_mon +1;
*day = tm->tm_mday;
*hour = tm->tm_hour;
*minute = tm->tm_min;
*second = tm->tm_sec;
return 1;
}
#if defined(HAVE_POSIX2TIME) && defined(HAVE_DECL_POSIX2TIME) && \
!HAVE_DECL_POSIX2TIME
extern time_t posix2time(time_t);
#endif
int
univ_to_local(Sint *year, Sint *month, Sint *day,
Sint *hour, Sint *minute, Sint *second)
{
time_t the_clock;
struct tm *tm;
#ifdef HAVE_LOCALTIME_R
struct tm tmbuf;
#endif
if (!(IN_RANGE(BASEYEAR, *year, INT_MAX - 1) &&
IN_RANGE(1, *month, 12) &&
IN_RANGE(1, *day, (mdays[*month] +
(*month == 2
&& (*year % 4 == 0)
&& (*year % 100 != 0 || *year % 400 == 0)))) &&
IN_RANGE(0, *hour, 23) &&
IN_RANGE(0, *minute, 59) &&
IN_RANGE(0, *second, 59))) {
return 0;
}
the_clock = *second + 60 * (*minute + 60 * (*hour + 24 *
gregday(*year, *month, *day)));
#ifdef HAVE_POSIX2TIME
/*
* Addition from OpenSource - affects FreeBSD.
* No valid test case /PaN
*
* leap-second correction performed
* if system is configured so;
* do nothing if not
* See FreeBSD 6.x and 7.x
* /usr/src/lib/libc/stdtime/localtime.c
* for the details
*/
the_clock = posix2time(the_clock);
#endif
#ifdef HAVE_LOCALTIME_R
tm = localtime_r(&the_clock, &tmbuf);
#else
tm = localtime(&the_clock);
#endif
if (tm) {
*year = tm->tm_year + 1900;
*month = tm->tm_mon +1;
*day = tm->tm_mday;
*hour = tm->tm_hour;
*minute = tm->tm_min;
*second = tm->tm_sec;
return 1;
}
return 0;
}
/* get a timestamp */
void
get_now(Uint* megasec, Uint* sec, Uint* microsec)
{
SysTimeval now;
erts_smp_mtx_lock(&erts_timeofday_mtx);
get_tolerant_timeofday(&now);
do_erts_deliver_time(&now);
/* Make sure time is later than last */
if (then.tv_sec > now.tv_sec ||
(then.tv_sec == now.tv_sec && then.tv_usec >= now.tv_usec)) {
now = then;
now.tv_usec++;
}
/* Check for carry from above + general reasonability */
if (now.tv_usec >= 1000000) {
now.tv_usec = 0;
now.tv_sec++;
}
then = now;
erts_smp_mtx_unlock(&erts_timeofday_mtx);
*megasec = (Uint) (now.tv_sec / 1000000);
*sec = (Uint) (now.tv_sec % 1000000);
*microsec = (Uint) (now.tv_usec);
}
void
get_sys_now(Uint* megasec, Uint* sec, Uint* microsec)
{
SysTimeval now;
sys_gettimeofday(&now);
*megasec = (Uint) (now.tv_sec / 1000000);
*sec = (Uint) (now.tv_sec % 1000000);
*microsec = (Uint) (now.tv_usec);
}
/* deliver elapsed *ticks* to the machine - takes a pointer
to a struct timeval representing current time (to save
a gettimeofday() where possible) or NULL */
void erts_deliver_time(void) {
SysTimeval now;
erts_smp_mtx_lock(&erts_timeofday_mtx);
get_tolerant_timeofday(&now);
do_erts_deliver_time(&now);
erts_smp_mtx_unlock(&erts_timeofday_mtx);
}
/* get *real* time (not ticks) remaining until next timeout - if there
isn't one, give a "long" time, that is guaranteed
to not cause overflow when we report elapsed time later on */
void erts_time_remaining(SysTimeval *rem_time)
{
int ticks;
SysTimeval cur_time;
long elapsed;
/* erts_next_time() returns no of ticks to next timeout or -1 if none */
if ((ticks = erts_next_time()) == -1) {
/* timer queue empty */
/* this will cause at most 100000000 ticks */
rem_time->tv_sec = 100000;
rem_time->tv_usec = 0;
} else {
/* next timeout after ticks ticks */
ticks *= CLOCK_RESOLUTION;
erts_smp_mtx_lock(&erts_timeofday_mtx);
get_tolerant_timeofday(&cur_time);
cur_time.tv_usec = 1000 *
(cur_time.tv_usec / 1000);/* ms resolution*/
elapsed = 1000 * (cur_time.tv_sec - last_delivered.tv_sec) +
(cur_time.tv_usec - last_delivered.tv_usec) / 1000;
erts_smp_mtx_unlock(&erts_timeofday_mtx);
if (ticks <= elapsed) { /* Ooops, better hurry */
rem_time->tv_sec = rem_time->tv_usec = 0;
return;
}
rem_time->tv_sec = (ticks - elapsed) / 1000;
rem_time->tv_usec = 1000 * ((ticks - elapsed) % 1000);
}
}
void erts_get_timeval(SysTimeval *tv)
{
erts_smp_mtx_lock(&erts_timeofday_mtx);
get_tolerant_timeofday(tv);
erts_smp_mtx_unlock(&erts_timeofday_mtx);
}
long
erts_get_time(void)
{
SysTimeval sys_tv;
erts_smp_mtx_lock(&erts_timeofday_mtx);
get_tolerant_timeofday(&sys_tv);
erts_smp_mtx_unlock(&erts_timeofday_mtx);
return sys_tv.tv_sec;
}
#ifdef HAVE_ERTS_NOW_CPU
void erts_get_now_cpu(Uint* megasec, Uint* sec, Uint* microsec) {
SysCpuTime t;
SysTimespec tp;
sys_get_proc_cputime(t, tp);
*microsec = (Uint)(tp.tv_nsec / 1000);
t = (tp.tv_sec / 1000000);
*megasec = (Uint)(t % 1000000);
*sec = (Uint)(tp.tv_sec % 1000000);
}
#endif
/*
* erts_get_emu_time() is similar to get_now(). You will
* always get different times from erts_get_emu_time(), but they
* may equal a time from get_now().
*
* erts_get_emu_time() is only used internally in the emulator in
* order to order emulator internal events.
*/
void
erts_get_emu_time(SysTimeval *this_emu_time_p)
{
erts_smp_mtx_lock(&erts_timeofday_mtx);
get_tolerant_timeofday(this_emu_time_p);
/* Make sure time is later than last */
if (last_emu_time.tv_sec > this_emu_time_p->tv_sec ||
(last_emu_time.tv_sec == this_emu_time_p->tv_sec
&& last_emu_time.tv_usec >= this_emu_time_p->tv_usec)) {
*this_emu_time_p = last_emu_time;
this_emu_time_p->tv_usec++;
}
/* Check for carry from above + general reasonability */
if (this_emu_time_p->tv_usec >= 1000000) {
this_emu_time_p->tv_usec = 0;
this_emu_time_p->tv_sec++;
}
last_emu_time = *this_emu_time_p;
erts_smp_mtx_unlock(&erts_timeofday_mtx);
}