Time::HiRes - High resolution alarm, sleep, gettimeofday, interval timers |
Time::HiRes - High resolution alarm, sleep, gettimeofday, interval timers
use Time::HiRes qw( usleep ualarm gettimeofday tv_interval nanosleep clock_gettime clock_getres clock_nanosleep clock stat );
usleep ($microseconds); nanosleep ($nanoseconds);
ualarm ($microseconds); ualarm ($microseconds, $interval_microseconds);
$t0 = [gettimeofday]; ($seconds, $microseconds) = gettimeofday;
$elapsed = tv_interval ( $t0, [$seconds, $microseconds]); $elapsed = tv_interval ( $t0, [gettimeofday]); $elapsed = tv_interval ( $t0 );
use Time::HiRes qw ( time alarm sleep );
$now_fractions = time; sleep ($floating_seconds); alarm ($floating_seconds); alarm ($floating_seconds, $floating_interval);
use Time::HiRes qw( setitimer getitimer );
setitimer ($which, $floating_seconds, $floating_interval ); getitimer ($which);
use Time::HiRes qw( clock_gettime clock_getres clock_nanosleep ITIMER_REAL ITIMER_VIRTUAL ITIMER_PROF ITIMER_REALPROF );
$realtime = clock_gettime(CLOCK_REALTIME); $resolution = clock_getres(CLOCK_REALTIME);
clock_nanosleep(CLOCK_REALTIME, 1.5e9); clock_nanosleep(CLOCK_REALTIME, time()*1e9 + 10e9, TIMER_ABSTIME);
my $ticktock = clock();
use Time::HiRes qw( stat );
my @stat = stat("file"); my @stat = stat(FH);
The Time::HiRes
module implements a Perl interface to the
usleep
, nanosleep
, ualarm
, gettimeofday
, and
setitimer
/getitimer
system calls, in other words, high
resolution time and timers. See the EXAMPLES section below and the
test scripts for usage; see your system documentation for the
description of the underlying nanosleep
or usleep
, ualarm
,
gettimeofday
, and setitimer
/getitimer
calls.
If your system lacks gettimeofday()
or an emulation of it you don't
get gettimeofday()
or the one-argument form of tv_interval()
.
If your system lacks all of nanosleep()
, usleep()
,
select()
, and poll
, you don't get Time::HiRes::usleep()
,
Time::HiRes::nanosleep()
, or Time::HiRes::sleep()
.
If your system lacks both ualarm()
and setitimer()
you don't get
Time::HiRes::ualarm()
or Time::HiRes::alarm()
.
If you try to import an unimplemented function in the use
statement
it will fail at compile time.
If your subsecond sleeping is implemented with nanosleep()
instead
of usleep()
, you can mix subsecond sleeping with signals since
nanosleep()
does not use signals. This, however, is not portable,
and you should first check for the truth value of
&Time::HiRes::d_nanosleep
to see whether you have nanosleep, and
then carefully read your nanosleep()
C API documentation for any
peculiarities.
If you are using nanosleep
for something else than mixing sleeping
with signals, give some thought to whether Perl is the tool you should
be using for work requiring nanosecond accuracies.
Remember that unless you are working on a hard realtime system, any clocks and timers will be imprecise, especially so if you are working in a pre-emptive multiuser system. Understand the difference between wallclock time and process time (in UNIX-like systems the sum of user and system times). Any attempt to sleep for X seconds will most probably end up sleeping more than that, but don't be surpised if you end up sleeping slightly less.
The following functions can be imported from this module. No functions are exported by default.
Time::HiRes::time()
(see below).
usleep
system call.
Can also sleep for zero seconds, which often works like a thread yield.
See also Time::HiRes::usleep()
, Time::HiRes::sleep()
, and
Time::HiRes::clock_nanosleep()
.
Do not expect usleep()
to be exact down to one microsecond.
Time::HiRes::sleep()
,
Time::HiRes::usleep()
, and Time::HiRes::clock_nanosleep()
.
Do not expect nanosleep()
to be exact down to one nanosecond.
Getting even accuracy of one thousand nanoseconds is good.
ualarm
call; the $interval_useconds
is optional and
will be zero if unspecified, resulting in alarm
-like behaviour.
Returns the remaining time in the alarm in microseconds, or undef
if an error occurred.
ualarm(0)
will cancel an outstanding ualarm().
Note that the interaction between alarms and sleeps is unspecified.
Returns the floating seconds between the two times, which should have
been returned by gettimeofday()
. If the second argument is omitted,
then the current time is used.
time
provided with core Perl; see the EXAMPLES below.
NOTE 1: This higher resolution timer can return values either less
or more than the core time()
, depending on whether your platform
rounds the higher resolution timer values up, down, or to the nearest second
to get the core time()
, but naturally the difference should be never
more than half a second. See also clock_getres, if available
in your system.
NOTE 2: Since Sunday, September 9th, 2001 at 01:46:40 AM GMT, when
the time()
seconds since epoch rolled over to 1_000_000_000, the
default floating point format of Perl and the seconds since epoch have
conspired to produce an apparent bug: if you print the value of
Time::HiRes::time()
you seem to be getting only five decimals, not
six as promised (microseconds). Not to worry, the microseconds are
there (assuming your platform supports such granularity in the first
place). What is going on is that the default floating point format of
Perl only outputs 15 digits. In this case that means ten digits
before the decimal separator and five after. To see the microseconds
you can use either printf
/sprintf
with "%.6f"
, or the
gettimeofday()
function in list context, which will give you the
seconds and microseconds as two separate values.
sleep
provided with perl, see the EXAMPLES below.
Note that the interaction between alarms and sleeps is unspecified.
SIGALRM
signal is sent after the specified number of seconds.
Implemented using setitimer()
if available, ualarm()
if not.
The $interval_floating_seconds
argument is optional and will be
zero if unspecified, resulting in alarm()
-like behaviour. This
function can be imported, resulting in a nice drop-in replacement for
the alarm
provided with perl, see the EXAMPLES below.
Returns the remaining time in the alarm in seconds, or undef
if an error occurred.
NOTE 1: With some combinations of operating systems and Perl
releases SIGALRM
restarts select()
, instead of interrupting it.
This means that an alarm()
followed by a select()
may together
take the sum of the times specified for the the alarm()
and the
select()
, not just the time of the alarm()
.
Note that the interaction between alarms and sleeps is unspecified.
$floating_seconds
of zero. If the
$interval_floating_seconds
is set to zero (or unspecified), the
timer is disabled after the next delivered signal.
Use of interval timers may interfere with alarm()
, sleep()
,
and usleep()
. In standard-speak the ``interaction is unspecified'',
which means that anything may happen: it may work, it may not.
In scalar context, the remaining time in the timer is returned.
In list context, both the remaining time and the interval are returned.
There are usually three or four interval timers (signals) available: the
$which
can be ITIMER_REAL
, ITIMER_VIRTUAL
, ITIMER_PROF
, or
ITIMER_REALPROF
. Note that which ones are available depends: true
UNIX platforms usually have the first three, but (for example) Win32
and Cygwin have only ITIMER_REAL
, and only Solaris seems to have
ITIMER_REALPROF
(which is used to profile multithreaded programs).
ITIMER_REAL
results in alarm()
-like behaviour. Time is counted in
real time; that is, wallclock time. SIGALRM
is delivered when
the timer expires.
ITIMER_VIRTUAL
counts time in (process) virtual time; that is,
only when the process is running. In multiprocessor/user/CPU systems
this may be more or less than real or wallclock time. (This time is
also known as the user time.) SIGVTALRM
is delivered when the
timer expires.
ITIMER_PROF
counts time when either the process virtual time or when
the operating system is running on behalf of the process (such as I/O).
(This time is also known as the system time.) (The sum of user
time and system time is known as the CPU time.) SIGPROF
is
delivered when the timer expires. SIGPROF
can interrupt system calls.
The semantics of interval timers for multithreaded programs are
system-specific, and some systems may support additional interval
timers. For example, it is unspecified which thread gets the signals.
See your setitimer()
documentation.
$which
.
In scalar context, the remaining time is returned.
In list context, both the remaining time and the interval are returned.
The interval is always what you put in using setitimer()
.
$which
. All implementations that support POSIX high
resolution timers are supposed to support at least the $which
value
of CLOCK_REALTIME
, which is supposed to return results close to the
results of gettimeofday
, or the number of seconds since 00:00:00:00
January 1, 1970 Greenwich Mean Time (GMT). Do not assume that
CLOCK_REALTIME is zero, it might be one, or something else.
Another potentially useful (but not available everywhere) value is
CLOCK_MONOTONIC
, which guarantees a monotonically increasing time
value (unlike time(), which can be adjusted). See your system
documentation for other possibly supported values.
$which
. All implementations that support POSIX high
resolution timers are supposed to support at least the $which
value
of CLOCK_REALTIME
, see clock_gettime.
clock_gettime()
and clock_getres(). The flags
default to zero but TIMER_ABSTIME
can specified (must be exported
explicitly) which means that $nanoseconds
is not a time interval
(as is the default) but instead an absolute time. Can sleep for more
than one second. Can also sleep for zero seconds, which often works
like a thread yield. See also Time::HiRes::sleep()
,
Time::HiRes::usleep()
, and Time::HiRes::nanosleep()
.
Do not expect clock_nanosleep()
to be exact down to one nanosecond.
Getting even accuracy of one thousand nanoseconds is good.
clock()
clock()
(the definition is not
``since the start of the process'', though if you are lucky these times
may be quite close to each other, depending on the system). What this
means is that you probably need to store the result of your first call
to clock(), and subtract that value from the following results of clock().
The time returned also includes the process times of the terminated
child processes for which wait()
has been executed. This value is
somewhat like the second value returned by the times()
of core Perl,
but not necessarily identical. Note that due to backward
compatibility limitations the returned value may wrap around at about
2147 seconds or at about 36 minutes.
use Time::HiRes qw(stat);
Test for the value of &Time::HiRes::d_hires_stat to find out whether the operating system supports subsecond file timestamps: a value larger than zero means yes. There are unfortunately no easy ways to find out whether the filesystem supports such timestamps. UNIX filesystems often do; NTFS does; FAT doesn't (FAT timestamp granularity is two seconds).
A zero return value of &Time::HiRes::d_hires_stat means that Time::HiRes::stat is a no-op passthrough for CORE::stat(), and therefore the timestamps will stay integers. The same thing will happen if the filesystem does not do subsecond timestamps, even if the &Time::HiRes::d_hires_stat is non-zero.
In any case do not expect nanosecond resolution, or even a microsecond resolution. Also note that the modify/access timestamps might have different resolutions, and that they need not be synchronized, e.g. if the operations are
write stat # t1 read stat # t2
the access time stamp from t2 need not be greater-than the modify time stamp from t1: it may be equal or less.
use Time::HiRes qw(usleep ualarm gettimeofday tv_interval);
$microseconds = 750_000; usleep($microseconds);
# signal alarm in 2.5s & every .1s thereafter ualarm(2_500_000, 100_000); # cancel that ualarm ualarm(0);
# get seconds and microseconds since the epoch ($s, $usec) = gettimeofday();
# measure elapsed time # (could also do by subtracting 2 gettimeofday return values) $t0 = [gettimeofday]; # do bunch of stuff here $t1 = [gettimeofday]; # do more stuff here $t0_t1 = tv_interval $t0, $t1;
$elapsed = tv_interval ($t0, [gettimeofday]); $elapsed = tv_interval ($t0); # equivalent code
# # replacements for time, alarm and sleep that know about # floating seconds # use Time::HiRes; $now_fractions = Time::HiRes::time; Time::HiRes::sleep (2.5); Time::HiRes::alarm (10.6666666);
use Time::HiRes qw ( time alarm sleep ); $now_fractions = time; sleep (2.5); alarm (10.6666666);
# Arm an interval timer to go off first at 10 seconds and # after that every 2.5 seconds, in process virtual time
use Time::HiRes qw ( setitimer ITIMER_VIRTUAL time );
$SIG{VTALRM} = sub { print time, "\n" }; setitimer(ITIMER_VIRTUAL, 10, 2.5);
use Time::HiRes qw( clock_gettime clock_getres CLOCK_REALTIME ); # Read the POSIX high resolution timer. my $high = clock_getres(CLOCK_REALTIME); # But how accurate we can be, really? my $reso = clock_getres(CLOCK_REALTIME);
use Time::HiRes qw( clock_nanosleep TIMER_ABSTIME ); clock_nanosleep(CLOCK_REALTIME, 1e6); clock_nanosleep(CLOCK_REALTIME, 2e9, TIMER_ABSTIME);
use Time::HiRes qw( clock ); my $clock0 = clock(); ... # Do something. my $clock1 = clock(); my $clockd = $clock1 - $clock0;
use Time::HiRes qw( stat ); my ($atime, $mtime, $ctime) = (stat("istics"))[8, 9, 10];
In addition to the perl API described above, a C API is available for extension writers. The following C functions are available in the modglobal hash:
name C prototype --------------- ---------------------- Time::NVtime double (*)() Time::U2time void (*)(pTHX_ UV ret[2])
Both functions return equivalent information (like gettimeofday
)
but with different representations. The names NVtime
and U2time
were selected mainly because they are operating system independent.
(gettimeofday
is Unix-centric, though some platforms like Win32 and
VMS have emulations for it.)
Here is an example of using NVtime
from C:
double (*myNVtime)(); /* Returns -1 on failure. */ SV **svp = hv_fetch(PL_modglobal, "Time::NVtime", 12, 0); if (!svp) croak("Time::HiRes is required"); if (!SvIOK(*svp)) croak("Time::NVtime isn't a function pointer"); myNVtime = INT2PTR(double(*)(), SvIV(*svp)); printf("The current time is: %f\n", (*myNVtime)());
In ualarm()
you tried to use number of microseconds or interval (also
in microseconds) more than 1_000_000 and setitimer()
is not available
in your system to emulate that case.
You tried to use a negative time argument.
Something went horribly wrong-- the number of microseconds that cannot become negative just became negative. Maybe your compiler is broken?
In some platforms it is not possible to get an alarm with subsecond resolution and later than one second.
Some calls simply aren't available, real or emulated, on every platform.
Notice that the core time()
maybe rounding rather than truncating.
What this means is that the core time()
may be reporting the time
as one second later than gettimeofday()
and Time::HiRes::time()
.
Adjusting the system clock (either manually or by services like ntp)
may cause problems, especially for long running programs that assume
a monotonously increasing time (note that all platforms do not adjust
time as gracefully as UNIX ntp does). For example in Win32 (and derived
platforms like Cygwin and MinGW) the Time::HiRes::time() may temporarily
drift off from the system clock (and the original time())
by up to 0.5
seconds. Time::HiRes will notice this eventually and recalibrate.
Note that since Time::HiRes 1.77 the clock_gettime(CLOCK_MONOTONIC)
might help in this (in case your system supports CLOCK_MONOTONIC).
Perl modules the BSD::Resource manpage, the Time::TAI64 manpage.
Your system documentation for clock
, clock_gettime
,
clock_getres
, clock_nanosleep
, clock_settime
, getitimer
,
gettimeofday
, setitimer
, sleep
, stat
, ualarm
.
D. Wegscheid <wegscd@whirlpool.com> R. Schertler <roderick@argon.org> J. Hietaniemi <jhi@iki.fi> G. Aas <gisle@aas.no>
Copyright (c) 1996-2002 Douglas E. Wegscheid. All rights reserved.
Copyright (c) 2002, 2003, 2004, 2005, 2006, 2007, 2008 Jarkko Hietaniemi. All rights reserved.
This program is free software; you can redistribute it and/or modify it under the same terms as Perl itself.
Time::HiRes - High resolution alarm, sleep, gettimeofday, interval timers |