package Time::Local;
-require 5.6.0;
+
require Exporter;
use Carp;
+use Config;
use strict;
+use integer;
+
+use vars qw( $VERSION @ISA @EXPORT @EXPORT_OK );
+$VERSION = '1.17';
-our $VERSION = '1.02';
-our @ISA = qw( Exporter );
-our @EXPORT = qw( timegm timelocal );
-our @EXPORT_OK = qw( timegm_nocheck timelocal_nocheck );
+@ISA = qw( Exporter );
+@EXPORT = qw( timegm timelocal );
+@EXPORT_OK = qw( timegm_nocheck timelocal_nocheck );
+
+my @MonthDays = ( 31, 28, 31, 30, 31, 30, 31, 31, 30, 31, 30, 31 );
-# Set up constants
-our $SEC = 1;
-our $MIN = 60 * $SEC;
-our $HR = 60 * $MIN;
-our $DAY = 24 * $HR;
# Determine breakpoint for rolling century
- my $ThisYear = (localtime())[5];
- my $NextCentury = int($ThisYear / 100) * 100;
- my $Breakpoint = ($ThisYear + 50) % 100;
- $NextCentury += 100 if $Breakpoint < 50;
+my $ThisYear = ( localtime() )[5];
+my $Breakpoint = ( $ThisYear + 50 ) % 100;
+my $NextCentury = $ThisYear - $ThisYear % 100;
+$NextCentury += 100 if $Breakpoint < 50;
+my $Century = $NextCentury - 100;
+my $SecOff = 0;
+
+my ( %Options, %Cheat );
+
+use constant SECS_PER_MINUTE => 60;
+use constant SECS_PER_HOUR => 3600;
+use constant SECS_PER_DAY => 86400;
+
+my $MaxInt = ( ( 1 << ( 8 * $Config{intsize} - 2 ) ) -1 ) * 2 + 1;
+my $MaxDay = int( ( $MaxInt - ( SECS_PER_DAY / 2 ) ) / SECS_PER_DAY ) - 1;
+
+if ( $^O eq 'MacOS' ) {
+ # time_t is unsigned...
+ $MaxInt = ( 1 << ( 8 * $Config{intsize} ) ) - 1;
+}
+else {
+ $MaxInt = ( ( 1 << ( 8 * $Config{intsize} - 2 ) ) - 1 ) * 2 + 1;
+}
+
+# Determine the EPOC day for this machine
+my $Epoc = 0;
+if ( $^O eq 'vos' ) {
+ # work around posix-977 -- VOS doesn't handle dates in the range
+ # 1970-1980.
+ $Epoc = _daygm( 0, 0, 0, 1, 0, 70, 4, 0 );
+}
+elsif ( $^O eq 'MacOS' ) {
+ $MaxDay *=2 if $^O eq 'MacOS'; # time_t unsigned ... quick hack?
+ # MacOS time() is seconds since 1 Jan 1904, localtime
+ # so we need to calculate an offset to apply later
+ $Epoc = 693901;
+ $SecOff = timelocal( localtime(0)) - timelocal( gmtime(0) ) ;
+ $Epoc += _daygm( gmtime(0) );
+}
+else {
+ $Epoc = _daygm( gmtime(0) );
+}
+
+%Cheat = (); # clear the cache as epoc has changed
+
+sub _daygm {
+
+ # This is written in such a byzantine way in order to avoid
+ # lexical variables and sub calls, for speed
+ return $_[3] + (
+ $Cheat{ pack( 'ss', @_[ 4, 5 ] ) } ||= do {
+ my $month = ( $_[4] + 10 ) % 12;
+ my $year = $_[5] + 1900 - $month / 10;
+
+ ( ( 365 * $year )
+ + ( $year / 4 )
+ - ( $year / 100 )
+ + ( $year / 400 )
+ + ( ( ( $month * 306 ) + 5 ) / 10 )
+ )
+ - $Epoc;
+ }
+ );
+}
-our(%Options, %Cheat);
+sub _timegm {
+ my $sec =
+ $SecOff + $_[0] + ( SECS_PER_MINUTE * $_[1] ) + ( SECS_PER_HOUR * $_[2] );
+
+ return $sec + ( SECS_PER_DAY * &_daygm );
+}
sub timegm {
- my (@date) = @_;
- if ($date[5] > 999) {
- $date[5] -= 1900;
+ my ( $sec, $min, $hour, $mday, $month, $year ) = @_;
+
+ if ( $year >= 1000 ) {
+ $year -= 1900;
}
- elsif ($date[5] >= 0 && $date[5] < 100) {
- $date[5] -= 100 if $date[5] > $Breakpoint;
- $date[5] += $NextCentury;
+ elsif ( $year < 100 and $year >= 0 ) {
+ $year += ( $year > $Breakpoint ) ? $Century : $NextCentury;
+ }
+
+ unless ( $Options{no_range_check} ) {
+ if ( abs($year) >= 0x7fff ) {
+ $year += 1900;
+ croak
+ "Cannot handle date ($sec, $min, $hour, $mday, $month, *$year*)";
+ }
+
+ croak "Month '$month' out of range 0..11"
+ if $month > 11
+ or $month < 0;
+
+ my $md = $MonthDays[$month];
+ ++$md
+ if $month == 1 && _is_leap_year( $year + 1900 );
+
+ croak "Day '$mday' out of range 1..$md" if $mday > $md or $mday < 1;
+ croak "Hour '$hour' out of range 0..23" if $hour > 23 or $hour < 0;
+ croak "Minute '$min' out of range 0..59" if $min > 59 or $min < 0;
+ croak "Second '$sec' out of range 0..59" if $sec > 59 or $sec < 0;
}
- my $ym = pack('C2', @date[5,4]);
- my $cheat = $Cheat{$ym} || &cheat($ym, @date);
- $cheat
- + $date[0] * $SEC
- + $date[1] * $MIN
- + $date[2] * $HR
- + ($date[3]-1) * $DAY;
+
+ my $days = _daygm( undef, undef, undef, $mday, $month, $year );
+
+ unless ($Options{no_range_check} or abs($days) < $MaxDay) {
+ my $msg = '';
+ $msg .= "Day too big - $days > $MaxDay\n" if $days > $MaxDay;
+
+ $year += 1900;
+ $msg .= "Cannot handle date ($sec, $min, $hour, $mday, $month, $year)";
+
+ croak $msg;
+ }
+
+ return $sec
+ + $SecOff
+ + ( SECS_PER_MINUTE * $min )
+ + ( SECS_PER_HOUR * $hour )
+ + ( SECS_PER_DAY * $days );
+}
+
+sub _is_leap_year {
+ return 0 if $_[0] % 4;
+ return 1 if $_[0] % 100;
+ return 0 if $_[0] % 400;
+
+ return 1;
}
sub timegm_nocheck {
local $Options{no_range_check} = 1;
- &timegm;
+ return &timegm;
}
sub timelocal {
- my $t = &timegm;
- my $tt = $t;
-
- my (@lt) = localtime($t);
- my (@gt) = gmtime($t);
- if ($t < $DAY and ($lt[5] >= 70 or $gt[5] >= 70 )) {
- # Wrap error, too early a date
- # Try a safer date
- $tt += $DAY;
- @lt = localtime($tt);
- @gt = gmtime($tt);
- }
+ my $ref_t = &timegm;
+ my $loc_for_ref_t = _timegm( localtime($ref_t) );
- my $tzsec = ($gt[1] - $lt[1]) * $MIN + ($gt[2] - $lt[2]) * $HR;
+ my $zone_off = $loc_for_ref_t - $ref_t
+ or return $loc_for_ref_t;
- if($lt[5] > $gt[5]) {
- $tzsec -= $DAY;
- }
- elsif($gt[5] > $lt[5]) {
- $tzsec += $DAY;
- }
- else {
- $tzsec += ($gt[7] - $lt[7]) * $DAY;
+ # Adjust for timezone
+ my $loc_t = $ref_t - $zone_off;
+
+ # Are we close to a DST change or are we done
+ my $dst_off = $ref_t - _timegm( localtime($loc_t) );
+
+ # If this evaluates to true, it means that the value in $loc_t is
+ # the _second_ hour after a DST change where the local time moves
+ # backward.
+ if ( ! $dst_off &&
+ ( ( $ref_t - SECS_PER_HOUR ) - _timegm( localtime( $loc_t - SECS_PER_HOUR ) ) < 0 )
+ ) {
+ return $loc_t - SECS_PER_HOUR;
}
- $tzsec += $HR if($lt[8]);
-
- my $time = $t + $tzsec;
- my @test = localtime($time + ($tt - $t));
- $time -= $HR if $test[2] != $_[2];
- $time;
+ # Adjust for DST change
+ $loc_t += $dst_off;
+
+ return $loc_t if $dst_off > 0;
+
+ # If the original date was a non-extent gap in a forward DST jump,
+ # we should now have the wrong answer - undo the DST adjustment
+ my ( $s, $m, $h ) = localtime($loc_t);
+ $loc_t -= $dst_off if $s != $_[0] || $m != $_[1] || $h != $_[2];
+
+ return $loc_t;
}
sub timelocal_nocheck {
local $Options{no_range_check} = 1;
- &timelocal;
-}
-
-sub cheat {
- my($ym, @date) = @_;
- my($sec, $min, $hour, $day, $month, $year) = @date;
- unless ($Options{no_range_check}) {
- croak "Month '$month' out of range 0..11" if $month > 11 || $month < 0;
- my $md = (31, 28, 31, 30, 31, 30, 31, 31, 30, 31, 30, 31)[$month];
- $md++ if $month == 1 &&
- $year % 4 == 0 && ($year % 100 > 0 || $year % 400 == 100); # leap
- croak "Day '$day' out of range 1..$md" if $day > $md || $day < 1;
- croak "Hour '$hour' out of range 0..23" if $hour > 23 || $hour < 0;
- croak "Minute '$min' out of range 0..59" if $min > 59 || $min < 0;
- croak "Second '$sec' out of range 0..59" if $sec > 59 || $sec < 0;
- }
- my $guess = $^T;
- my @g = gmtime($guess);
- my $lastguess = "";
- my $counter = 0;
- while (my $diff = $year - $g[5]) {
- my $thisguess;
- croak "Can't handle date (".join(", ",@date).")" if ++$counter > 255;
- $guess += $diff * (363 * $DAY);
- @g = gmtime($guess);
- if (($thisguess = "@g") eq $lastguess){
- croak "Can't handle date (".join(", ",@date).")";
- #date beyond this machine's integer limit
- }
- $lastguess = $thisguess;
- }
- while (my $diff = $month - $g[4]) {
- my $thisguess;
- croak "Can't handle date (".join(", ",@date).")" if ++$counter > 255;
- $guess += $diff * (27 * $DAY);
- @g = gmtime($guess);
- if (($thisguess = "@g") eq $lastguess){
- croak "Can't handle date (".join(", ",@date).")";
- #date beyond this machine's integer limit
- }
- $lastguess = $thisguess;
- }
- my @gfake = gmtime($guess-1); #still being sceptic
- if ("@gfake" eq $lastguess){
- croak "Can't handle date (".join(", ",@date).")";
- #date beyond this machine's integer limit
- }
- $g[3]--;
- $guess -= $g[0] * $SEC + $g[1] * $MIN + $g[2] * $HR + $g[3] * $DAY;
- $Cheat{$ym} = $guess;
+ return &timelocal;
}
1;
=head1 DESCRIPTION
-These routines are the inverse of built-in perl functions localtime()
-and gmtime(). They accept a date as a six-element array, and return
-the corresponding time(2) value in seconds since the Epoch (Midnight,
-January 1, 1970). This value can be positive or negative.
+This module provides functions that are the inverse of built-in perl
+functions C<localtime()> and C<gmtime()>. They accept a date as a
+six-element array, and return the corresponding C<time(2)> value in
+seconds since the system epoch (Midnight, January 1, 1970 GMT on Unix,
+for example). This value can be positive or negative, though POSIX
+only requires support for positive values, so dates before the
+system's epoch may not work on all operating systems.
It is worth drawing particular attention to the expected ranges for
-the values provided. The value for the day of the month is the actual day
-(ie 1..31), while the month is the number of months since January (0..11).
-This is consistent with the values returned from localtime() and gmtime().
+the values provided. The value for the day of the month is the actual
+day (ie 1..31), while the month is the number of months since January
+(0..11). This is consistent with the values returned from
+C<localtime()> and C<gmtime()>.
-The timelocal() and timegm() functions perform range checking on the
-input $sec, $min, $hour, $mday, and $mon values by default. If you'd
-rather they didn't, you can explicitly import the timelocal_nocheck()
-and timegm_nocheck() functions.
+=head1 FUNCTIONS
- use Time::Local 'timelocal_nocheck';
+This module exports two functions by default, C<timelocal()> and
+C<timegm()>.
- {
- # The 365th day of 1999
- print scalar localtime timelocal_nocheck 0,0,0,365,0,99;
+The C<timelocal()> and C<timegm()> functions perform range checking on
+the input $sec, $min, $hour, $mday, and $mon values by default.
- # The twenty thousandth day since 1970
- print scalar localtime timelocal_nocheck 0,0,0,20000,0,70;
+If you are working with data you know to be valid, you can speed your
+code up by using the "nocheck" variants, C<timelocal_nocheck()> and
+C<timegm_nocheck()>. These variants must be explicitly imported.
- # And even the 10,000,000th second since 1999!
- print scalar localtime timelocal_nocheck 10000000,0,0,1,0,99;
- }
+ use Time::Local 'timelocal_nocheck';
-Your mileage may vary when trying these with minutes and hours,
-and it doesn't work at all for months.
+ # The 365th day of 1999
+ print scalar localtime timelocal_nocheck 0,0,0,365,0,99;
-Strictly speaking, the year should also be specified in a form consistent
-with localtime(), i.e. the offset from 1900.
-In order to make the interpretation of the year easier for humans,
-however, who are more accustomed to seeing years as two-digit or four-digit
-values, the following conventions are followed:
+If you supply data which is not valid (month 27, second 1,000) the
+results will be unpredictable (so don't do that).
+
+=head2 Year Value Interpretation
+
+Strictly speaking, the year should be specified in a form consistent
+with C<localtime()>, i.e. the offset from 1900. In order to make the
+interpretation of the year easier for humans, however, who are more
+accustomed to seeing years as two-digit or four-digit values, the
+following conventions are followed:
=over 4
=item *
Years greater than 999 are interpreted as being the actual year,
-rather than the offset from 1900. Thus, 1963 would indicate the year
-Martin Luther King won the Nobel prize, not the year 2863.
+rather than the offset from 1900. Thus, 1964 would indicate the year
+Martin Luther King won the Nobel prize, not the year 3864.
=item *
-Years in the range 100..999 are interpreted as offset from 1900,
-so that 112 indicates 2012. This rule also applies to years less than zero
-(but see note below regarding date range).
+Years in the range 100..999 are interpreted as offset from 1900, so
+that 112 indicates 2012. This rule also applies to years less than
+zero (but see note below regarding date range).
=item *
Years in the range 0..99 are interpreted as shorthand for years in the
-rolling "current century," defined as 50 years on either side of the current
-year. Thus, today, in 1999, 0 would refer to 2000, and 45 to 2045,
-but 55 would refer to 1955. Twenty years from now, 55 would instead refer
-to 2055. This is messy, but matches the way people currently think about
-two digit dates. Whenever possible, use an absolute four digit year instead.
+rolling "current century," defined as 50 years on either side of the
+current year. Thus, today, in 1999, 0 would refer to 2000, and 45 to
+2045, but 55 would refer to 1955. Twenty years from now, 55 would
+instead refer to 2055. This is messy, but matches the way people
+currently think about two digit dates. Whenever possible, use an
+absolute four digit year instead.
=back
-The scheme above allows interpretation of a wide range of dates, particularly
-if 4-digit years are used.
+The scheme above allows interpretation of a wide range of dates,
+particularly if 4-digit years are used.
+
+=head2 Limits of time_t
-Please note, however, that the range of dates that can be actually be handled
-depends on the size of an integer (time_t) on a given platform.
-Currently, this is 32 bits for most systems, yielding an approximate range
-from Dec 1901 to Jan 2038.
+The range of dates that can be actually be handled depends on the size
+of C<time_t> (usually a signed integer) on the given
+platform. Currently, this is 32 bits for most systems, yielding an
+approximate range from Dec 1901 to Jan 2038.
-Both timelocal() and timegm() croak if given dates outside the supported
-range.
+Both C<timelocal()> and C<timegm()> croak if given dates outside the
+supported range.
+
+=head2 Ambiguous Local Times (DST)
+
+Because of DST changes, there are many time zones where the same local
+time occurs for two different GMT times on the same day. For example,
+in the "Europe/Paris" time zone, the local time of 2001-10-28 02:30:00
+can represent either 2001-10-28 00:30:00 GMT, B<or> 2001-10-28
+01:30:00 GMT.
+
+When given an ambiguous local time, the timelocal() function should
+always return the epoch for the I<earlier> of the two possible GMT
+times.
+
+=head2 Non-Existent Local Times (DST)
+
+When a DST change causes a locale clock to skip one hour forward,
+there will be an hour's worth of local times that don't exist. Again,
+for the "Europe/Paris" time zone, the local clock jumped from
+2001-03-25 01:59:59 to 2001-03-25 03:00:00.
+
+If the C<timelocal()> function is given a non-existent local time, it
+will simply return an epoch value for the time one hour later.
+
+=head2 Negative Epoch Values
+
+Negative epoch (C<time_t>) values are not officially supported by the
+POSIX standards, so this module's tests do not test them. On some
+systems, they are known not to work. These include MacOS (pre-OSX) and
+Win32.
+
+On systems which do support negative epoch values, this module should
+be able to cope with dates before the start of the epoch, down the
+minimum value of time_t for the system.
=head1 IMPLEMENTATION
-These routines are quite efficient and yet are always guaranteed to agree
-with localtime() and gmtime(). We manage this by caching the start times
-of any months we've seen before. If we know the start time of the month,
-we can always calculate any time within the month. The start times
-themselves are guessed by successive approximation starting at the
-current time, since most dates seen in practice are close to the
-current date. Unlike algorithms that do a binary search (calling gmtime
-once for each bit of the time value, resulting in 32 calls), this algorithm
-calls it at most 6 times, and usually only once or twice. If you hit
-the month cache, of course, it doesn't call it at all.
-
-timelocal() is implemented using the same cache. We just assume that we're
-translating a GMT time, and then fudge it when we're done for the timezone
-and daylight savings arguments. Note that the timezone is evaluated for
-each date because countries occasionally change their official timezones.
-Assuming that localtime() corrects for these changes, this routine will
-also be correct. The daylight savings offset is currently assumed
-to be one hour.
+These routines are quite efficient and yet are always guaranteed to
+agree with C<localtime()> and C<gmtime()>. We manage this by caching
+the start times of any months we've seen before. If we know the start
+time of the month, we can always calculate any time within the month.
+The start times are calculated using a mathematical formula. Unlike
+other algorithms that do multiple calls to C<gmtime()>.
+
+The C<timelocal()> function is implemented using the same cache. We
+just assume that we're translating a GMT time, and then fudge it when
+we're done for the timezone and daylight savings arguments. Note that
+the timezone is evaluated for each date because countries occasionally
+change their official timezones. Assuming that C<localtime()> corrects
+for these changes, this routine will also be correct.
=head1 BUGS
-The whole scheme for interpreting two-digit years can be considered a bug.
+The whole scheme for interpreting two-digit years can be considered a
+bug.
+
+=head1 SUPPORT
+
+Support for this module is provided via the datetime@perl.org email
+list. See http://lists.perl.org/ for more details.
+
+Please submit bugs to the CPAN RT system at
+http://rt.cpan.org/NoAuth/ReportBug.html?Queue=Time-Local or via email
+at bug-time-local@rt.cpan.org.
+
+=head1 AUTHOR
+
+This module is based on a Perl 4 library, timelocal.pl, that was
+included with Perl 4.036, and was most likely written by Tom
+Christiansen.
-Note that the cache currently handles only years from 1900 through 2155.
+The current version was written by Graham Barr.
-The proclivity to croak() is probably a bug.
+It is now being maintained separately from the Perl core by Dave
+Rolsky, <autarch@urth.org>.
=cut