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package DateTime::Duration; use strict; use Carp (); use DateTime::Helpers; use Params::Validate qw( validate SCALAR ); use overload ( fallback => 1, '+' => '_add_overload', '-' => '_subtract_overload', '*' => '_multiply_overload', '<=>' => '_compare_overload', 'cmp' => '_compare_overload', ); use constant MAX_NANOSECONDS => 1_000_000_000; # 1E9 = almost 32 bits my @all_units = qw( months days minutes seconds nanoseconds ); # XXX - need to reject non-integers but accept infinity, NaN, & # 1.56e+18 sub new { my $class = shift; my %p = validate( @_, { years => { type => SCALAR, default => 0 }, months => { type => SCALAR, default => 0 }, weeks => { type => SCALAR, default => 0 }, days => { type => SCALAR, default => 0 }, hours => { type => SCALAR, default => 0 }, minutes => { type => SCALAR, default => 0 }, seconds => { type => SCALAR, default => 0 }, nanoseconds => { type => SCALAR, default => 0 }, end_of_month => { type => SCALAR, default => undef, regex => qr/^(?:wrap|limit|preserve)$/ }, } ); my $self = bless {}, $class; $self->{months} = ( $p{years} * 12 ) + $p{months}; $self->{days} = ( $p{weeks} * 7 ) + $p{days}; $self->{minutes} = ( $p{hours} * 60 ) + $p{minutes}; $self->{seconds} = $p{seconds}; if ( $p{nanoseconds} ) { $self->{nanoseconds} = $p{nanoseconds}; $self->_normalize_nanoseconds; } else { # shortcut - if they don't need nanoseconds $self->{nanoseconds} = 0; } $self->{end_of_month} = ( defined $p{end_of_month} ? $p{end_of_month} : $self->{months} < 0 ? 'preserve' : 'wrap' ); return $self; } # make the signs of seconds, nanos the same; 0 < abs(nanos) < MAX_NANOS # NB this requires nanoseconds != 0 (callers check this already) sub _normalize_nanoseconds { my $self = shift; return if ( $self->{nanoseconds} == DateTime::INFINITY() || $self->{nanoseconds} == DateTime::NEG_INFINITY() || $self->{nanoseconds} eq DateTime::NAN() ); my $seconds = $self->{seconds} + $self->{nanoseconds} / MAX_NANOSECONDS; $self->{seconds} = int( $seconds ); $self->{nanoseconds} = $self->{nanoseconds} % MAX_NANOSECONDS; $self->{nanoseconds} -= MAX_NANOSECONDS if $seconds < 0; } sub clone { bless { %{ $_[0] } }, ref $_[0] } sub years { abs( $_[0]->in_units( 'years' ) ) } sub months { abs( $_[0]->in_units( 'months', 'years' ) ) } sub weeks { abs( $_[0]->in_units( 'weeks' ) ) } sub days { abs( $_[0]->in_units( 'days', 'weeks' ) ) } sub hours { abs( $_[0]->in_units( 'hours' ) ) } sub minutes { abs( $_[0]->in_units( 'minutes', 'hours' ) ) } sub seconds { abs( $_[0]->in_units( 'seconds' ) ) } sub nanoseconds { abs( $_[0]->in_units( 'nanoseconds', 'seconds' ) ) } sub is_positive { $_[0]->_has_positive && ! $_[0]->_has_negative } sub is_negative { ! $_[0]->_has_positive && $_[0]->_has_negative } sub _has_positive { ( grep { $_ > 0 } @{ $_[0] }{@all_units} ) ? 1 : 0} sub _has_negative { ( grep { $_ < 0 } @{ $_[0] }{@all_units} ) ? 1 : 0 } sub is_zero { return 0 if grep { $_ != 0 } @{ $_[0] }{@all_units}; return 1 } sub delta_months { $_[0]->{months} } sub delta_days { $_[0]->{days} } sub delta_minutes { $_[0]->{minutes} } sub delta_seconds { $_[0]->{seconds} } sub delta_nanoseconds { $_[0]->{nanoseconds} } sub deltas { map { $_ => $_[0]->{$_} } @all_units; } sub in_units { my $self = shift; my @units = @_; my %units = map { $_ => 1 } @units; my %ret; my ( $months, $days, $minutes, $seconds ) = @{ $self }{qw( months days minutes seconds )}; if ( $units{years} ) { $ret{years} = int( $months / 12 ); $months -= $ret{years} * 12; } if ( $units{months} ) { $ret{months} = $months; } if ( $units{weeks} ) { $ret{weeks} = int( $days / 7 ); $days -= $ret{weeks} * 7; } if ( $units{days} ) { $ret{days} = $days; } if ( $units{hours} ) { $ret{hours} = int( $minutes / 60 ); $minutes -= $ret{hours} * 60; } if ( $units{minutes} ) { $ret{minutes} = $minutes } if ( $units{seconds} ) { $ret{seconds} = $seconds; $seconds = 0; } if ( $units{nanoseconds} ) { $ret{nanoseconds} = $seconds * MAX_NANOSECONDS + $self->{nanoseconds}; } wantarray ? @ret{@units} : $ret{ $units[0] }; } sub is_wrap_mode { $_[0]->{end_of_month} eq 'wrap' ? 1 : 0 } sub is_limit_mode { $_[0]->{end_of_month} eq 'limit' ? 1 : 0 } sub is_preserve_mode { $_[0]->{end_of_month} eq 'preserve' ? 1 : 0 } sub end_of_month_mode { $_[0]->{end_of_month} } sub calendar_duration { my $self = shift; return (ref $self)->new( map { $_ => $self->{$_} } qw( months days end_of_month ) ) } sub clock_duration { my $self = shift; return (ref $self)->new( map { $_ => $self->{$_} } qw( minutes seconds nanoseconds end_of_month ) ) } sub inverse { my $self = shift; my %new; foreach my $u (@all_units) { $new{$u} = $self->{$u}; # avoid -0 bug $new{$u} *= -1 if $new{$u}; } return (ref $self)->new(%new); } sub add_duration { my ( $self, $dur ) = @_; foreach my $u (@all_units) { $self->{$u} += $dur->{$u}; } $self->_normalize_nanoseconds if $self->{nanoseconds}; return $self; } sub add { my $self = shift; return $self->add_duration( (ref $self)->new(@_) ); } sub subtract_duration { return $_[0]->add_duration( $_[1]->inverse ) } sub subtract { my $self = shift; return $self->subtract_duration( (ref $self)->new(@_) ) } sub multiply { my $self = shift; my $multiplier = shift; foreach my $u (@all_units) { $self->{$u} *= $multiplier; } $self->_normalize_nanoseconds if $self->{nanoseconds}; return $self; } sub compare { my ( $class, $dur1, $dur2, $dt ) = @_; $dt ||= DateTime->now; return DateTime->compare( $dt->clone->add_duration($dur1), $dt->clone->add_duration($dur2) ); } sub _add_overload { my ( $d1, $d2, $rev ) = @_; ($d1, $d2) = ($d2, $d1) if $rev; if ( DateTime::Helpers::isa( $d2, 'DateTime' ) ) { $d2->add_duration($d1); return; } # will also work if $d1 is a DateTime.pm object return $d1->clone->add_duration($d2); } sub _subtract_overload { my ( $d1, $d2, $rev ) = @_; ($d1, $d2) = ($d2, $d1) if $rev; Carp::croak( "Cannot subtract a DateTime object from a DateTime::Duration object" ) if DateTime::Helpers::isa( $d2, 'DateTime' ); return $d1->clone->subtract_duration($d2); } sub _multiply_overload { my $self = shift; my $new = $self->clone; return $new->multiply(@_); } sub _compare_overload { Carp::croak( 'DateTime::Duration does not overload comparison.' . ' See the documentation on the compare() method for details.' ); } 1; __END__ =head1 NAME DateTime::Duration - Duration objects for date math =head1 SYNOPSIS use DateTime::Duration; $d = DateTime::Duration->new( years => 3, months => 5, weeks => 1, days => 1, hours => 6, minutes => 15, seconds => 45, nanoseconds => 12000 ); # Convert to different units $d->in_units('days', 'hours', 'seconds'); # The important parts for date math $d->delta_months $d->delta_days $d->delta_minutes $d->delta_seconds $d->delta_nanoseconds my %deltas = $d->deltas $d->is_wrap_mode $d->is_limit_mode $d->is_preserve_mode print $d->end_of_month_mode; # Multiple all deltas by -1 my $opposite = $d->inverse; my $bigger = $dur1 + $dur2; my $smaller = $dur1 - $dur2; # the result could be negative my $bigger = $dur1 * 3; my $base_dt = DateTime->new( year => 2000 ); my @sorted = sort { DateTime::Duration->compare( $a, $b, $base_dt ) } @durations; # Human-readable accessors, always positive, but use # DateTime::Format::Duration instead $d->years; $d->months; $d->weeks; $d->days; $d->hours; $d->minutes; $d->seconds; $d->nanoseconds; if ( $d->is_positive ) { ... } if ( $d->is_zero ) { ... } if ( $d->is_negative ) { ... } =head1 DESCRIPTION This is a simple class for representing duration objects. These objects are used whenever you do date math with DateTime.pm. See the L<How Date Math is Done|DateTime/"How Date Math is Done"> section of the DateTime.pm documentation for more details. The short course: One cannot in general convert between seconds, minutes, days, and months, so this class will never do so. Instead, create the duration with the desired units to begin with, for example by calling the appropriate subtraction/delta method on a C<DateTime.pm> object. =head1 METHODS Like C<DateTime> itself, C<DateTime::Duration> returns the object from mutator methods in order to make method chaining possible. C<DateTime::Duration> has the following methods: =over 4 =item * new( ... ) This method takes the parameters "years", "months", "weeks", "days", "hours", "minutes", "seconds", "nanoseconds", and "end_of_month". All of these except "end_of_month" are numbers. If any of the numbers are negative, the entire duration is negative. All of the numbers B<must be integers>. Internally, years as just treated as 12 months. Similarly, weeks are treated as 7 days, and hours are converted to minutes. Seconds and nanoseconds are both treated separately. The "end_of_month" parameter must be either "wrap", "limit", or "preserve". This parameter specifies how date math that crosses the end of a month is handled. In "wrap" mode, adding months or years that result in days beyond the end of the new month will roll over into the following month. For instance, adding one year to Feb 29 will result in Mar 1. If you specify "end_of_month" mode as "limit", the end of the month is never crossed. Thus, adding one year to Feb 29, 2000 will result in Feb 28, 2001. If you were to then add three more years this will result in Feb 28, 2004. If you specify "end_of_month" mode as "preserve", the same calculation is done as for "limit" except that if the original date is at the end of the month the new date will also be. For instance, adding one month to Feb 29, 2000 will result in Mar 31, 2000. For positive durations, the "end_of_month" parameter defaults to wrap. For negative durations, the default is "limit". This should match how most people "intuitively" expect datetime math to work. =item * clone Returns a new object with the same properties as the object on which this method was called. =item * in_units( ... ) Returns the length of the duration in the units (any of those that can be passed to L<new>) given as arguments. All lengths are integral, but may be negative. Smaller units are computed from what remains after taking away the larger units given, so for example: my $dur = DateTime::Duration->new( years => 1, months => 15 ); $dur->in_units( 'years' ); # 2 $dur->in_units( 'months' ); # 27 $dur->in_units( 'years', 'months' ); # (2, 3) $dur->in_units( 'weeks', 'days' ); # (0, 0) ! The last example demonstrates that there will not be any conversion between units which don't have a fixed conversion rate. The only conversions possible are: =over 8 =item * years <=> months =item * weeks <=> days =item * hours <=> minutes =item * seconds <=> nanoseconds =back For the explanation of why this happens, please see the L<How Date Math is Done|DateTime/"How Date Math is Done"> section of the DateTime.pm documentation Note that the numbers returned by this method may not match the values given to the constructor. In list context, in_units returns the lengths in the order of the units given. In scalar context, it returns the length in the first unit (but still computes in terms of all given units). If you need more flexibility in presenting information about durations, please take a look a C<DateTime::Format::Duration>. =item * delta_months, delta_days, delta_minutes, delta_seconds, delta_nanoseconds These methods provide the information C<DateTime.pm> needs for doing date math. The numbers returned may be positive or negative. =item * deltas Returns a hash with the keys "months", "days", "minutes", "seconds", and "nanoseconds", containing all the delta information for the object. =item * is_positive, is_zero, is_negative Indicates whether or not the duration is positive, zero, or negative. If the duration contains both positive and negative units, then it will return false for B<all> of these methods. =item * is_wrap_mode, is_limit_mode, is_preserve_mode Indicates what mode is used for end of month wrapping. =item * end_of_month_mode Returns one of "wrap", "limit", or "preserve". =item * calendar_duration Returns a new object with the same I<calendar> delta (months and days only) and end of month mode as the current object. =item * clock_duration Returns a new object with the same I<clock> deltas (minutes, seconds, and nanoseconds) and end of month mode as the current object. =item * inverse Returns a new object with the same deltas as the current object, but multiple by -1. The end of month mode for the new object will be the default end of month mode, which depends on whether the new duration is positive or negative. =item * add_duration( $duration_object ), subtract_duration( $duration_object ) Adds or subtracts one duration from another. =item * add( ... ), subtract( ... ) Syntactic sugar for addition and subtraction. The parameters given to these methods are used to create a new object, which is then passed to C<add_duration()> or C<subtract_duration()>, as appropriate. =item * multiply( $number ) Multiplies each unit in the by the specified number. =item * DateTime::Duration->compare( $duration1, $duration2, $base_datetime ) This is a class method that can be used to compare or sort durations. Comparison is done by adding each duration to the specified C<DateTime.pm> object and comparing the resulting datetimes. This is necessary because without a base, many durations are not comparable. For example, 1 month may or may not be longer than 29 days, depending on what datetime it is added to. If no base datetime is given, then the result of C<< DateTime->now >> is used instead. Using this default will give non-repeatable results if used to compare two duration objects containing different units. It will also give non-repeatable results if the durations contain multiple types of units, such as months and days. However, if you know that both objects only consist of one type of unit (months I<or> days I<or> hours, etc.), and each duration contains the same type of unit, then the results of the comparison will be repeatable. =item * years, months, weeks, days, hours, minutes, seconds, nanoseconds These methods return numbers indicating how many of the given unit the object represents, after having done a conversion to any larger units. For example, days are first converted to weeks, and then the remainder is returned. These numbers are always positive. Here's what each method returns: $dur->years() == abs( $dur->in_units('years') ) $dur->months() == abs( ( $dur->in_units( 'months', 'years' ) )[0] ) $dur->weeks() == abs( $dur->in_units( 'weeks' ) ) $dur->days() == abs( ( $dur->in_units( 'days', 'weeks' ) )[0] ) $dur->hours() == abs( $dur->in_units( 'hours' ) ) $dur->minutes == abs( ( $dur->in_units( 'minutes', 'hours' ) )[0] ) $dur->seconds == abs( $dur->in_units( 'seconds' ) ) $dur->nanoseconds() == abs( ( $dur->in_units( 'nanoseconds', 'seconds' ) )[0] ) If this seems confusing, remember that you can always use the C<in_units()> method to specify exactly what you want. Better yet, if you are trying to generate output suitable for humans, use the C<DateTime::Format::Duration> module. =back =head2 Overloading This class overloads addition, subtraction, and mutiplication. Comparison is B<not> overloaded. If you attempt to compare durations using C<< <=> >> or C<cmp>, then an exception will be thrown! Use the C<compare()> class method instead. =head1 SUPPORT Support for this module is provided via the datetime@perl.org email list. See http://lists.perl.org/ for more details. =head1 AUTHOR Dave Rolsky <autarch@urth.org> However, please see the CREDITS file for more details on who I really stole all the code from. =head1 COPYRIGHT Copyright (c) 2003-2006 David Rolsky. All rights reserved. This program is free software; you can redistribute it and/or modify it under the same terms as Perl itself. Portions of the code in this distribution are derived from other works. Please see the CREDITS file for more details. The full text of the license can be found in the LICENSE file included with this module. =head1 SEE ALSO datetime@perl.org mailing list http://datetime.perl.org/ =cut