WHY THIS MODULE DOESN'T USE STANDARD POSIX TIME FUNCTIONS
As it is said in description of Date, this module implements and uses its own time functions: gmtime
, timegm
, localtime
, timelocal
.
The first and the main reason is that POSIX's reverse functions (which make epoch from YMDHMS - timegm, timelocal) are very very slow on BSD systems (FreeBSD, MacOS, etc). See PERFORMANCE at the bottom of this page.
The second reason is that POSIX's functions do not expose a timezone object to user, so that you can't pass this object to localtime/timelocal to make calculations in that zone. It's not a big deal if you only use GMT zone or localzone. But if you want to use multiple zone simultaneously
$date1 = date("2019-01-01 10:00:00", 'Europe/Moscow');
$date2 = date("2019-01-01 09:00:00", 'Europe/Kiev');
$date1 == $date2; # true
with POSIX it is impossible, you can only set some zone globally via extremely slow function tzset()
.
To implement such a behaviour, this module internally (in C interface) has additional functions anytime/timeany, which receives additional parameter - Timezone*
object in which calculations should be made.
The third reason is that POSIX's implementation has various bugs, see "POSIX BUGS".
Normally, these very fast and correctly re-implemented time functions are not needed at perl level, as perl's interface cannot provide perfomance which these functions have at C level.
However they are exposed to perl via Date::gmtime/...etc
functions in case you need them.
POSIX BUGS
While developing all the time functions from scratch and comparing results with POSIX's system functions i discovered that many operating systems have buggy implementations of localtime/timelocal functions which causes them to return wrong results in case of certain dates (actually rare dates). Therefore in such cases the result won't match with POSIX functions because this module handles all these cases correctly.
Bugs i discovered (exact times may for now differ as many timezones have changed since i first wrote this):
Linux and FreeBSD (and possibly more Unix-like systems)
- timelocal cannot correctly handle forward time jump at last transition.
-
For example Europe/Moscow, date "2011/03/27 02:00:00" Must return 1301180400 ("2011/03/27 03:00:00") In fact returns - linux: 1301176800 ("2011/03/27 01:00:00") - freebsd: -1 If transition is not the last one, it works correctly: "2010/03/28 02:00:00" returns 1269730800 ("2010/03/28 03:00:00")
- localtime/timelocal handles DST transitions in future (outside of transitions) incorrectly when using leap second zones
-
$ TZ=right/Australia/Melbourne perl -E 'say scalar localtime 4284028799' Sun Oct 4 01:59:34 2105 $ TZ=right/Australia/Melbourne perl -E 'say scalar localtime 4284028800' Sun Oct 4 02:59:35 2105
FreeBSD only
- America/Anchorage timezone behaves like it has no POSIX string (no DST changes after last transition)
- timelocal cannot handle dates before year 1900
- Wrong forward jump normalization with non-DST transitions
-
- Simple forward jump 1h somewhy normalized back CORRECT: epoch=-1539492257 (1921/03/21 00:15:43 MSD) from 1921/03/20 23:15:43 DST=-1 (Europe/Moscow) POSIX: epoch=-1539495857 (1921/03/20 22:15:43 MSD) from 1921/03/20 23:15:43 DST=-1 (Europe/Moscow) - Forward jump 2h normalized just 1h CORRECT: epoch=-1627961251 (1918/06/01 01:03:17 MDST) from 1918/05/31 23:03:17 DST=-1 (Europe/Moscow) POSIX: epoch=-1627964851 (1918/06/01 00:03:17 MDST) from 1918/05/31 23:03:17 DST=-1 (Europe/Moscow) - Simple forward jump 1h somewhy normalized 30min CORRECT: epoch=372787481 (1981/10/25 03:34:41 LHST) from 1981/10/25 02:34:41 DST=-1 (Australia/Lord_Howe) POSIX: epoch=372785681 (1981/10/25 03:04:41 LHST) from 1981/10/25 02:34:41 DST=-1 (Australia/Lord_Howe) - Simple forward jump 1h somewhy normalized 2h CORRECT: epoch=449595541 (1984/04/01 01:39:01 CHOST) from 1984/04/01 00:39:01 DST=-1 (Asia/Choibalsan) POSIX: epoch=449599141 (1984/04/01 02:39:01 CHOST) from 1984/04/01 00:39:01 DST=-1 (Asia/Choibalsan) - Forward jump 3h normalized 2h CORRECT: epoch=354905851 (1981/04/01 04:57:31 MAGST) from 1981/04/01 01:57:31 DST=-1 (Asia/Ust-Nera) POSIX: epoch=354902251 (1981/04/01 03:57:31 MAGST) from 1981/04/01 01:57:31 DST=-1 (Asia/Ust-Nera)
Linux only
- Complex bug with static variable deep inside POSIX code
-
Steps to reproduce: (TZ=Europe/Moscow, date strings are for compactness, actually 'struct tm' required)
mktime("1998/10/25 03:-1:61"); // returns 909273601 (Sun Oct 25 03:00:01 1998) - that's ok mktime("2011/-2/1 00:00:00"); // returns 1285876800 (Fri Oct 1 00:00:00 2010) - that's ok // now run the first line again mktime("1998/10/25 03:-1:61"); // returns 909270001 (Sun Oct 25 02:00:01 1998) - OOPS // again and again mktime("1998/10/25 03:-1:61"); // returns 909270001 (Sun Oct 25 02:00:01 1998) - OOPS forever :(
PERFORMANCE
Tests were performed on MacOSX, Core i7 3.2Ghz 2012.
-------------------------------------------------------------------------------------------------
| Function | This module | libc(MacOSX) | libc(Linux) | libc(FreeBSD) |
-------------------------------------------------------------------------------------------------
| gmtime(epoch, &date) | 53 M/s | 11 M/s | 15 M/s | 12 M/s |
| timegm(&date) | 30 M/s | 0.4 M/s | 10 M/s | 0.15 M/s |
| timegml(&date)* | 135 M/s | -- | -- | -- |
| localtime(epoch, &date) | 26 M/s | 5.5 M/s | 7 M/s | 3 M/s |
| timelocal(&date) | 23 M/s | 0.5 M/s | 1.2 M/s | 0.1 M/s |
| timelocall(&date)* | 50 M/s | -- | -- | -- |
-------------------------------------------------------------------------------------------------
* additional functions ('l' stands for 'lite') behave like original ones, but do not normalize struct values, only calculates epoch. Calculations are done correctly even when input values are not normalized, these functions just don't put normalized values back to struct.
** there are 2 more functions with 'll' (superlite) at the end, which only allows normalized input struct. They run even faster.