package Time::Clock; use strict; use Carp; our $VERSION = '0.12'; use overload ( '""' => sub { shift->as_string }, fallback => 1, ); eval { require Time::HiRes }; our $Have_HiRes_Time = $@ ? 0 : 1; # Allow an hour value of 24 our $Allow_Hour_24 = 0; use constant NANOSECONDS_IN_A_SECOND => 1_000_000_000; use constant SECONDS_IN_A_MINUTE => 60; use constant SECONDS_IN_AN_HOUR => SECONDS_IN_A_MINUTE * 60; use constant SECONDS_IN_A_CLOCK => SECONDS_IN_AN_HOUR * 24; use constant DEFAULT_FORMAT => '%H:%M:%S%n'; our %Default_Format; __PACKAGE__->default_format(DEFAULT_FORMAT); sub default_format { my($invocant) = shift; # Called as object method if(ref $invocant) { return $invocant->{'default_format'} = shift if(@_); return ref($invocant)->default_format; } # Called as class method return $Default_Format{$invocant} = shift if(@_); return $Default_Format{$invocant} ||= DEFAULT_FORMAT; } sub new { my($class) = shift; my $self = bless {}, $class; @_ = (parse => @_) if(@_ == 1); $self->init(@_); return $self; } sub init { my($self) = shift; while(@_) { my $method = shift; $self->$method(shift); } } sub hour { my($self) = shift; if(@_) { my $hour = shift; if($Allow_Hour_24) { croak "hour must be between 0 and 24" unless(!defined $hour || ($hour >= 0 && $hour <= 24)); } else { croak "hour must be between 0 and 23" unless(!defined $hour || ($hour >= 0 && $hour <= 23)); } return $self->{'hour'} = $hour; } return $self->{'hour'} ||= 0; } sub minute { my($self) = shift; if(@_) { my $minute = shift; croak "minute must be between 0 and 59" unless(!defined $minute || ($minute >= 0 && $minute <= 59)); return $self->{'minute'} = $minute; } return $self->{'minute'} ||= 0; } sub second { my($self) = shift; if(@_) { my $second = shift; croak "second must be between 0 and 59" unless(!defined $second || ($second >= 0 && $second <= 59)); return $self->{'second'} = $second; } return $self->{'second'} ||= 0; } sub nanosecond { my($self) = shift; if(@_) { my $nanosecond = shift; croak "nanosecond must be between 0 and ", (NANOSECONDS_IN_A_SECOND - 1) unless(!defined $nanosecond || ($nanosecond >= 0 && $nanosecond < NANOSECONDS_IN_A_SECOND)); return $self->{'nanosecond'} = $nanosecond; } return $self->{'nanosecond'}; } sub ampm { my($self) = shift; if(@_ && defined $_[0]) { my $ampm = shift; if($ampm =~ /^a\.?m\.?$/i) { if($self->hour > 12) { croak "Cannot set AM/PM to AM when hour is set to ", $self->hour; } elsif($self->hour == 12) { $self->hour(0); } return 'am'; } elsif($ampm =~ /^p\.?m\.?$/i) { if($self->hour < 12) { $self->hour($self->hour + 12); } return 'pm'; } else { croak "AM/PM value not understood: $ampm" } } return ($self->hour >= 12) ? 'PM' : 'AM'; } sub as_string { my($self) = shift; return $self->format($self->default_format); } sub format { my($self, $format) = @_; $format ||= ref($self)->default_format; my $hour = $self->hour; my $ihour = $hour > 12 ? ($hour - 12) : $hour; my $ns = $self->nanosecond; my %formats = ( 'H' => sprintf('%02d', $hour), 'I' => sprintf('%02d', $ihour), 'i' => $ihour, 'k' => $hour, 'M' => sprintf('%02d', $self->minute), 'S' => sprintf('%02d', $self->second), 'N' => sprintf('%09d', $ns || 0), 'n' => defined $ns ? sprintf('.%09d', $ns) : '', 'p' => $self->ampm, 'P' => lc $self->ampm, 's' => $self->as_integer_seconds, ); $formats{'n'} =~ s/\.?0+$//; for($format) { s{ ((?:%%|[^%]+)*) %T }{$1%H:%M:%S}gx; s/%([HIikMSsNnpP])/$formats{$1}/g; no warnings 'uninitialized'; s{ ((?:%%|[^%]+)*) % ([1-9]) N }{ $1 . substr(sprintf("%09d", $ns || 0), 0, $2) }gex; if(defined $ns) { s{ ((?:%%|[^%]+)*) % ([1-9]) n }{ "$1." . substr(sprintf("%09d", $ns || 0), 0, $2) }gex; } else { s{ ((?:%%|[^%]+)*) % ([1-9]) n }{$1}gx; } s/%%/%/g; } return $format; } sub parse { my($self, $time) = @_; if(my($hour, $min, $sec, $fsec, $ampm) = ($time =~ m{^ (\d\d?) # hour (?::(\d\d)(?::(\d\d))?)?(?:\.(\d{0,9}))? # min? sec? nanosec? (?:\s*([aApP]\.?[mM]\.?))? # am/pm $ }x)) { # Special case to allow times of 24:00:00, which the Postgres # database considers valid (presumably in order to account for # leap seconds) if($hour == 24) { no warnings 'uninitialized'; if($min == 0 && $sec == 0 && $fsec == 0) { local $Allow_Hour_24 = 1; $self->hour($hour); } else { croak "Could not parse time '$time' - an hour value of 24 is only ", "allowed if minutes, seconds, and nanoseconds are all zero" } } else { $self->hour($hour) } $self->minute($min); $self->second($sec); $self->ampm($ampm); if(defined $fsec) { my $len = length $fsec; if($len < 9) { $fsec .= ('0' x (9 - $len)); } elsif($len > 9) { $fsec = substr($fsec, 0, 9); } } $self->nanosecond($fsec); } elsif($time eq 'now') { if($Have_HiRes_Time) { (my $fsecs = Time::HiRes::time()) =~ s/^.*\.//; return $self->parse(sprintf("%d:%02d:%02d.$fsecs", (localtime(time))[2,1,0])); } else { return $self->parse(sprintf('%d:%02d:%02d', (localtime(time))[2,1,0])); } } else { croak "Could not parse time '$time'"; } return $self; } sub as_integer_seconds { my($self) = shift; return ($self->hour * SECONDS_IN_AN_HOUR) + ($self->minute * SECONDS_IN_A_MINUTE) + $self->second; } sub delta_as_integer_seconds { my($self, %args) = @_; return (($args{'hours'} || 0) * SECONDS_IN_AN_HOUR) + (($args{'minutes'} || 0) * SECONDS_IN_A_MINUTE) + ($args{'seconds'} || 0); } sub parse_delta { my($self) = shift; if(@_ == 1) { my $delta = shift; if(my($hour, $min, $sec, $fsec) = ($delta =~ m{^ (\d+) # hours (?::(\d+))? # minutes (?::(\d+))? # seconds (?:\.(\d{0,9}))? # nanoseconds $ }x)) { if(defined $fsec) { my $len = length $fsec; if($len < 9) { $fsec .= ('0' x (9 - $len)); } $fsec = $fsec + 0; } return ( hours => $hour, minutes => $min, seconds => $sec, nanoseconds => $fsec, ); } else { croak "Time delta not understood: $delta" } } return @_; } sub add { my($self) = shift; my %args = $self->parse_delta(@_); my $secs = $self->as_integer_seconds + $self->delta_as_integer_seconds(%args); if(defined $args{'nanoseconds'}) { my $ns_arg = $args{'nanoseconds'}; my $nsec = $self->nanosecond || 0; if($ns_arg + $nsec < NANOSECONDS_IN_A_SECOND) { $self->nanosecond($ns_arg + $nsec); } else { $secs += int(($ns_arg + $nsec) / NANOSECONDS_IN_A_SECOND); $self->nanosecond(($ns_arg + $nsec) % NANOSECONDS_IN_A_SECOND); } } $self->init_with_seconds($secs); return; } sub subtract { my($self) = shift; my %args = $self->parse_delta(@_); my $secs = $self->as_integer_seconds - $self->delta_as_integer_seconds(%args); if(defined $args{'nanoseconds'}) { my $ns_arg = $args{'nanoseconds'}; my $nsec = $self->nanosecond || 0; if($nsec - $ns_arg >= 0) { $self->nanosecond($nsec - $ns_arg); } else { if(abs($nsec - $ns_arg) >= NANOSECONDS_IN_A_SECOND) { $secs -= int($ns_arg / NANOSECONDS_IN_A_SECOND); } else { $secs--; } $self->nanosecond(($nsec - $ns_arg) % NANOSECONDS_IN_A_SECOND); } } if($secs < 0) { $secs = $secs % SECONDS_IN_A_CLOCK; } $self->init_with_seconds($secs); return; } sub init_with_seconds { my($self, $secs) = @_; if($secs >= SECONDS_IN_A_CLOCK) { $secs = $secs % SECONDS_IN_A_CLOCK; } if($secs >= SECONDS_IN_AN_HOUR) { $self->hour(int($secs / SECONDS_IN_AN_HOUR)); $secs -= $self->hour * SECONDS_IN_AN_HOUR; } else { $self->hour(0) } if($secs >= SECONDS_IN_A_MINUTE) { $self->minute(int($secs / SECONDS_IN_A_MINUTE)); $secs -= $self->minute * SECONDS_IN_A_MINUTE; } else { $self->minute(0) } $self->second($secs); return; } 1; __END__ =head1 NAME Time::Clock - Twenty-four hour clock object with nanosecond precision. =head1 SYNOPSIS $t = Time::Clock->new(hour => 12, minute => 34, second => 56); print $t->as_string; # 12:34:56 $t->parse('8pm'); print "$t"; # 20:00:00 print $t->format('%I:%M %p'); # 08:00 PM $t->add(minutes => 15, nanoseconds => 123000000); print $t->as_string; # 20:15:00.123 $t->subtract(hours => 30); print $t->as_string; # 14:15:00.123 ... =head1 DESCRIPTION A L object is a twenty-four hour clock with nanosecond precision and wrap-around. It is a clock only; it has absolutely no concept of dates. Vagaries of date/time such as leap seconds and daylight savings time are unsupported. When a L object hits 23:59:59.999999999 and at least one more nanosecond is added, it will wrap around to 00:00:00.000000000. This works in reverse when time is subtracted. L objects automatically stringify to a user-definable format. =head1 CLASS METHODS =over 4 =item B Set the default format used by the L method for all objects of this class. Defaults to "%H:%M:%S%n". See the documentation for the L method for a complete list of format specifiers. Note that this method may also be called as an object method, in which case it sets the default format for the individual object only. =back =head1 CONSTRUCTOR =over 4 =item B Constructs a new L object based on PARAMS, where PARAMS are name/value pairs. Any object method is a valid parameter name. Example: $t = Time::Clock->new(hour => 12, minute => 34, second => 56); If a single argument is passed to L, it is equivalent to calling the L method. That is, this: $t = Time::Clock->new('12:34:56'); is equivalent to this: $t = Time::Clock->new; $t->parse('12:34:56'); Returns the newly constructed L object. =back =head1 OBJECT METHODS =over 4 =item B Add the time specified by PARAMS to the clock. Valid PARAMS are: =over 4 =item C An integer number of hours. =item C An integer number of minutes. =item C An integer number of seconds. =item C An integer number of nanoseconds. =back If the amount of time added is large enough, the clock will wrap around from 23:59:59.999999999 to 00:00:00.000000000 as needed. =item B Get or set the AM/PM attribute of the clock. Valid values of AM/PM must contain the letters "AM" or "PM" (case-insensitive), optionally followed by periods. A clock whose L is greater than 12 cannot be set to AM. Any attempt to do so will cause a fatal error. Setting a clock whose L is less than 12 to PM will cause its L to be increased by 12. Example: $t = Time::Clock->new('8:00'); print $t->as_string; # 08:00:00 $t->ampm('PM'); print $t->as_string; # 20:00:00 Return the string "AM" if the L is less than 12, "PM" otherwise. =item B Returns the integer number of seconds since 00:00:00. =item B Returns a string representation of the clock, formatted according to the clock object's L. =item B Set the default format used by the L method for this object. Defaults to "%H:%M:%S%n". See the documentation for the L method for a complete list of format specifiers. Note that this method may also be called as a class method, in which case it sets the default format all objects of this class. =item B Returns the clock value formatted according to the FORMAT string containing "%"-prefixed format specifiers. Valid format specifiers are: =over 4 =item C<%H> The hour as a two-digit, zero-padded integer using a 24-hour clock (range 00 to 23). =item C<%I> The hour as a two-digit, zero-padded integer using a 12-hour clock (range 01 to 12). =item C<%i> The hour as an integer using a 12-hour clock (range 1 to 12). =item C<%k> The hour as an integer using a 24-hour clock (range 0 to 23). =item C<%M> The minute as a two-digit, zero-padded integer (range 00 to 59). =item C<%n> If the clock has a non-zero L value, then this format produces a decimal point followed by the fractional seconds up to and including the last non-zero digit. If no L value is defined, or if it is zero, then this format produces an empty string. Examples: $t = Time::Clock->new('12:34:56'); print $t->format('%H:%M:%S%n'); # 12:34:56 $t->nanosecond(0); print $t->format('%H:%M:%S%n'); # 12:34:56 $t->nanosecond(123000000); print $t->format('%H:%M:%S%n'); # 12:34:56.123 =item C<%[1-9]n> If the clock has a defined L value, then this format produces a decimal point followed by the specified number of digits of fractional seconds (1-9). Examples: $t = Time::Clock->new('12:34:56'); print $t->format('%H:%M:%S%4n'); # 12:34:56 $t->nanosecond(0); print $t->format('%H:%M:%S%4n'); # 12:34:56.0000 $t->nanosecond(123000000); print $t->format('%H:%M:%S%4n'); # 12:34:56.1230 =item C<%N> Nanoseconds as a nine-digit, zero-padded integer (range 000000000 to 999999999) =item C<%[1-9]N> Fractional seconds as a one- to nine-digit, zero-padded integer. Examples: $t = Time::Clock->new('12:34:56'); print $t->format('%H:%M:%S.%4N'); # 12:34:56.0000 $t->nanosecond(123000000); print $t->format('%H:%M:%S.%6N'); # 12:34:56.123000 $t->nanosecond(123000000); print $t->format('%H:%M:%S.%2N'); # 12:34:56.12 =item C<%p> Either "AM" or "PM" according to the value return by the L method. =item C<%P> Like %p but lowercase: "am" or "pm" =item C<%S> The second as a two-digit, zero-padded integer (range 00 to 61). =item C<%s> The integer number of seconds since 00:00:00. =item C<%T> The time in 24-hour notation (%H:%M:%S). =item C<%%> A literal "%" character. =back =item B Get or set the hour of the clock. INT must be an integer from 0 to 23. =item B Get or set the minute of the clock. INT must be an integer from 0 to 59. =item B Get or set the nanosecond of the clock. INT must be an integer from 0 to 999999999. =item B Set the clock time by parsing STRING. Valid string values contain an hour with optional minutes, seconds, fractional seconds, and AM/PM string. There should be a colon (":") between hours, minutes, and seconds, and a decimal point (".") between the seconds and fractional seconds. Fractional seconds may contain up to 9 digits. The AM/PM string is case-insensitive and may have periods after each letter. The string "now" will initialize the clock object with the current (local) time. If the L module is installed, this time will have fractional seconds. A time value with an hour of 24 and zero minutes, seconds, and nanoseconds is also accepted by this method. Here are some examples of valid time strings: 12:34:56.123456789 12:34:56.123 PM 24:00 8:30pm 6 A.m. now =item B Get or set the second of the clock. INT must be an integer from 0 to 59. =item B Subtract the time specified by PARAMS from the clock. Valid PARAMS are: =over 4 =item C An integer number of hours. =item C An integer number of minutes. =item C An integer number of seconds. =item C An integer number of nanoseconds. =back If the amount of time subtracted is large enough, the clock will wrap around from 00:00:00.000000000 to 23:59:59.999999999 as needed. =back =head1 AUTHOR John C. Siracusa (siracusa@gmail.com) =head1 COPYRIGHT Copyright (c) 2006 by John C. Siracusa. All rights reserved. This program is free software; you can redistribute it and/or modify it under the same terms as Perl itself.