class Time
time.rb¶ ↑
When 'time' is required, Time is extended with additional methods for parsing and converting Times.
Features¶ ↑
This library extends the Time class with the following conversions between date strings and Time objects:
-
date-time defined by RFC 2822
-
HTTP-date defined by RFC 2616
-
various formats handled by Date._parse
-
custom formats handled by Date._strptime
Examples¶ ↑
All examples assume you have loaded Time with:
require 'time'
All of these examples were done using the EST timezone which is GMT-5.
Converting to a String¶ ↑
t = Time.now t.iso8601 # => "2011-10-05T22:26:12-04:00" t.rfc2822 # => "Wed, 05 Oct 2011 22:26:12 -0400" t.httpdate # => "Thu, 06 Oct 2011 02:26:12 GMT"
::parse¶ ↑
parse takes a string representation of a Time and attempts to parse it using a heuristic.
Date.parse("2010-10-31") #=> 2010-10-31 00:00:00 -0500
Any missing pieces of the date are inferred based on the current date.
# assuming the current date is "2011-10-31" Time.parse("12:00") #=> 2011-10-31 12:00:00 -0500
We can change the date used to infer our missing elements by passing a second object that responds to mon, day and year, such as Date, Time or DateTime. We can also use our own object.
class MyDate attr_reader :mon, :day, :year def initialize(mon, day, year) @mon, @day, @year = mon, day, year end end d = Date.parse("2010-10-28") t = Time.parse("2010-10-29") dt = DateTime.parse("2010-10-30") md = MyDate.new(10,31,2010) Time.parse("12:00", d) #=> 2010-10-28 12:00:00 -0500 Time.parse("12:00", t) #=> 2010-10-29 12:00:00 -0500 Time.parse("12:00", dt) #=> 2010-10-30 12:00:00 -0500 Time.parse("12:00", md) #=> 2010-10-31 12:00:00 -0500
parse also accepts an optional block. You can use this block to specify how to handle the year component of the date. This is specifically designed for handling two digit years. For example, if you wanted to treat all two digit years prior to 70 as the year 2000+ you could write this:
Time.parse("01-10-31") {|year| year + (year < 70 ? 2000 : 1900)} #=> 2001-10-31 00:00:00 -0500 Time.parse("70-10-31") {|year| year + (year < 70 ? 2000 : 1900)} #=> 1970-10-31 00:00:00 -0500
::strptime¶ ↑
strptime works similar to parse except that instead of using a
heuristic to detect the format of the input string, you provide a second
argument that describes the format of the string. For example:
Time.strptime("2000-10-31", "%Y-%m-%d") #=> 2000-10-31 00:00:00 -0500
Time is an abstraction of dates and times. Time is stored internally as the number of seconds with fraction since the Epoch, January 1, 1970 00:00 UTC. Also see the library module Date. The Time class treats GMT (Greenwich Mean Time) and UTC (Coordinated Universal Time) as equivalent. GMT is the older way of referring to these baseline times but persists in the names of calls on POSIX systems.
All times may have fraction. Be aware of this fact when comparing times with each other – times that are apparently equal when displayed may be different when compared.
Since Ruby 1.9.2, Time implementation uses a signed 63 bit integer, Bignum or Rational. The integer is a number of nanoseconds since the Epoch which can represent 1823-11-12 to 2116-02-20. When Bignum or Rational is used (before 1823, after 2116, under nanosecond), Time works slower as when integer is used.
Examples¶ ↑
All of these examples were done using the EST timezone which is GMT-5.
Creating a new Time instance¶ ↑
You can create a new instance of Time with ::new. This will use the current system time. ::now is an alias for this. You can also pass parts of the time to ::new such as year, month, minute, etc. When you want to construct a time this way you must pass at least a year. If you pass the year with nothing else time will default to January 1 of that year at 00:00:00 with the current system timezone. Here are some examples:
Time.new(2002) #=> 2002-01-01 00:00:00 -0500 Time.new(2002, 10) #=> 2002-10-01 00:00:00 -0500 Time.new(2002, 10, 31) #=> 2002-10-31 00:00:00 -0500 Time.new(2002, 10, 31, 2, 2, 2, "+02:00") #=> 2002-10-31 02:02:02 +0200
You can also use gm, local and utc to infer GMT, local and UTC timezones instead of using the current system setting.
You can also create a new time using ::at which takes the number of seconds (or fraction of seconds) since the Unix Epoch.
Time.at(628232400) #=> 1989-11-28 00:00:00 -0500
Working with an instance of Time¶ ↑
Once you have an instance of Time there is a multitude of things you can do with it. Below are some examples. For all of the following examples, we will work on the assumption that you have done the following:
t = Time.new(1993, 02, 24, 12, 0, 0, "+09:00")
Was that a monday?
t.monday? #=> false
What year was that again?
t.year #=> 1993
Was is daylight savings at the time?
t.dst? #=> false
What's the day a year later?
t + (60*60*24*365) #=> 1994-02-24 12:00:00 +0900
How many seconds was that since the Unix Epoch?
t.to_i #=> 730522800
You can also do standard functions like compare two times.
t1 = Time.new(2010) t2 = Time.new(2011) t1 == t2 #=> false t1 == t1 #=> true t1 < t2 #=> true t1 > t2 #=> false Time.new(2010,10,31).between?(t1, t2) #=> true
Public Class Methods
Creates a new Time object with the value given by
time, the given number of seconds_with_frac, or
seconds and microseconds_with_frac since the
Epoch. seconds_with_frac and
microseconds_with_frac can be an Integer, Float, Rational, or other Numeric. non-portable feature allows the offset to
be negative on some systems.
If a numeric argument is given, the result is in local time.
Time.at(0) #=> 1969-12-31 18:00:00 -0600 Time.at(Time.at(0)) #=> 1969-12-31 18:00:00 -0600 Time.at(946702800) #=> 1999-12-31 23:00:00 -0600 Time.at(-284061600) #=> 1960-12-31 00:00:00 -0600 Time.at(946684800.2).usec #=> 200000 Time.at(946684800, 123456.789).nsec #=> 123456789
static VALUE
time_s_at(int argc, VALUE *argv, VALUE klass)
{
VALUE time, t;
wideval_t timew;
if (rb_scan_args(argc, argv, "11", &time, &t) == 2) {
time = num_exact(time);
t = num_exact(t);
timew = wadd(rb_time_magnify(v2w(time)), wmulquoll(v2w(t), TIME_SCALE, 1000000));
t = time_new_timew(klass, timew);
}
else if (IsTimeval(time)) {
struct time_object *tobj, *tobj2;
GetTimeval(time, tobj);
t = time_new_timew(klass, tobj->timew);
GetTimeval(t, tobj2);
TIME_COPY_GMT(tobj2, tobj);
}
else {
timew = rb_time_magnify(v2w(num_exact(time)));
t = time_new_timew(klass, timew);
}
return t;
}
Creates a Time object based on given values,
interpreted as UTC (GMT). The year must be specified. Other values default
to the minimum value for that field (and may be nil or
omitted). Months may be specified by numbers from 1 to 12, or by the
three-letter English month names. Hours are
specified on a 24-hour clock (0..23). Raises an ArgumentError if any values are out of range.
Will also accept ten arguments in the order output by #to_a.
sec_with_frac and usec_with_frac can have a
fractional part.
Time.utc(2000,"jan",1,20,15,1) #=> 2000-01-01 20:15:01 UTC Time.gm(2000,"jan",1,20,15,1) #=> 2000-01-01 20:15:01 UTC
static VALUE
time_s_mkutc(int argc, VALUE *argv, VALUE klass)
{
return time_utc_or_local(argc, argv, TRUE, klass);
}
Parses date as an HTTP-date defined by RFC 2616 and converts
it to a Time object.
ArgumentError is raised if
date is not compliant with RFC 2616 or if the Time class cannot represent specified date.
See httpdate for more information on this format.
You must require 'time' to use this method.
# File lib/time.rb, line 517 def httpdate(date) if /\A\s* (?:Mon|Tue|Wed|Thu|Fri|Sat|Sun),\x20 (\d{2})\x20 (Jan|Feb|Mar|Apr|May|Jun|Jul|Aug|Sep|Oct|Nov|Dec)\x20 (\d{4})\x20 (\d{2}):(\d{2}):(\d{2})\x20 GMT \s*\z/ix =~ date self.rfc2822(date).utc elsif /\A\s* (?:Monday|Tuesday|Wednesday|Thursday|Friday|Saturday|Sunday),\x20 (\d\d)-(Jan|Feb|Mar|Apr|May|Jun|Jul|Aug|Sep|Oct|Nov|Dec)-(\d\d)\x20 (\d\d):(\d\d):(\d\d)\x20 GMT \s*\z/ix =~ date year = $3.to_i if year < 50 year += 2000 else year += 1900 end self.utc(year, $2, $1.to_i, $4.to_i, $5.to_i, $6.to_i) elsif /\A\s* (?:Mon|Tue|Wed|Thu|Fri|Sat|Sun)\x20 (Jan|Feb|Mar|Apr|May|Jun|Jul|Aug|Sep|Oct|Nov|Dec)\x20 (\d\d|\x20\d)\x20 (\d\d):(\d\d):(\d\d)\x20 (\d{4}) \s*\z/ix =~ date self.utc($6.to_i, MonthValue[$1.upcase], $2.to_i, $3.to_i, $4.to_i, $5.to_i) else raise ArgumentError.new("not RFC 2616 compliant date: #{date.inspect}") end end
Deserializes JSON string by converting time since epoch to Time
# File ext/json/lib/json/add/time.rb, line 8 def self.json_create(object) if usec = object.delete('u') # used to be tv_usec -> tv_nsec object['n'] = usec * 1000 end if instance_methods.include?(:tv_nsec) at(object['s'], Rational(object['n'], 1000)) else at(object['s'], object['n'] / 1000) end end
Same as ::gm, but interprets the values in the local time zone.
Time.local(2000,"jan",1,20,15,1) #=> 2000-01-01 20:15:01 -0600
static VALUE
time_s_mktime(int argc, VALUE *argv, VALUE klass)
{
return time_utc_or_local(argc, argv, FALSE, klass);
}
Same as ::gm, but interprets the values in the local time zone.
Time.local(2000,"jan",1,20,15,1) #=> 2000-01-01 20:15:01 -0600
static VALUE
time_s_mktime(int argc, VALUE *argv, VALUE klass)
{
return time_utc_or_local(argc, argv, FALSE, klass);
}
Returns a Time object.
It is initialized to the current system time if no argument is given.
Note: The new object will use the resolution available on your system clock, and may include fractional seconds.
If one or more arguments specified, the time is initialized to the specified time.
sec may have fraction if it is a rational.
utc_offset is the offset from UTC. It can be a string such as
“+09:00” or a number of seconds such as 32400.
a = Time.new #=> 2007-11-19 07:50:02 -0600 b = Time.new #=> 2007-11-19 07:50:02 -0600 a == b #=> false "%.6f" % a.to_f #=> "1195480202.282373" "%.6f" % b.to_f #=> "1195480202.283415" Time.new(2008,6,21, 13,30,0, "+09:00") #=> 2008-06-21 13:30:00 +0900 # A trip for RubyConf 2007 t1 = Time.new(2007,11,1,15,25,0, "+09:00") # JST (Narita) t2 = Time.new(2007,11,1,12, 5,0, "-05:00") # CDT (Minneapolis) t3 = Time.new(2007,11,1,13,25,0, "-05:00") # CDT (Minneapolis) t4 = Time.new(2007,11,1,16,53,0, "-04:00") # EDT (Charlotte) t5 = Time.new(2007,11,5, 9,24,0, "-05:00") # EST (Charlotte) t6 = Time.new(2007,11,5,11,21,0, "-05:00") # EST (Detroit) t7 = Time.new(2007,11,5,13,45,0, "-05:00") # EST (Detroit) t8 = Time.new(2007,11,6,17,10,0, "+09:00") # JST (Narita) p((t2-t1)/3600.0) #=> 10.666666666666666 p((t4-t3)/3600.0) #=> 2.466666666666667 p((t6-t5)/3600.0) #=> 1.95 p((t8-t7)/3600.0) #=> 13.416666666666666
static VALUE
time_init(int argc, VALUE *argv, VALUE time)
{
if (argc == 0)
return time_init_0(time);
else
return time_init_1(argc, argv, time);
}
Parses date using Date._parse and
converts it to a Time object.
If a block is given, the year described in date is converted
by the block. For example:
Time.parse(...) {|y| 0 <= y && y < 100 ? (y >= 69 ? y + 1900 : y + 2000) : y}
If the upper components of the given time are broken or missing, they are
supplied with those of now. For the lower components, the
minimum values (1 or 0) are assumed if broken or missing. For example:
# Suppose it is "Thu Nov 29 14:33:20 2001" now and # your time zone is EST which is GMT-5. now = Time.parse("Thu Nov 29 14:33:20 2001") Time.parse("16:30", now) #=> 2001-11-29 16:30:00 -0500 Time.parse("7/23", now) #=> 2001-07-23 00:00:00 -0500 Time.parse("Aug 31", now) #=> 2001-08-31 00:00:00 -0500 Time.parse("Aug 2000", now) #=> 2000-08-01 00:00:00 -0500
Since there are numerous conflicts among locally defined time zone abbreviations all over the world, this method is not intended to understand all of them. For example, the abbreviation “CST” is used variously as:
-06:00 in America/Chicago, -05:00 in America/Havana, +08:00 in Asia/Harbin, +09:30 in Australia/Darwin, +10:30 in Australia/Adelaide, etc.
Based on this fact, this method only understands the time zone
abbreviations described in RFC 822 and the system time zone, in the order
named. (i.e. a definition in RFC 822 overrides the system time zone
definition.) The system time zone is taken from Time.local(year, 1,
1).zone and Time.local(year, 7, 1).zone. If the
extracted time zone abbreviation does not match any of them, it is ignored
and the given time is regarded as a local time.
ArgumentError is raised if Date._parse cannot extract information from
date or if the Time class cannot
represent specified date.
This method can be used as a fail-safe for other parsing methods as:
Time.rfc2822(date) rescue Time.parse(date) Time.httpdate(date) rescue Time.parse(date) Time.xmlschema(date) rescue Time.parse(date)
A failure of ::parse should be checked, though.
You must require 'time' to use this method.
# File lib/time.rb, line 359 def parse(date, now=self.now) comp = !block_given? d = Date._parse(date, comp) year = d[:year] year = yield(year) if year && !comp make_time(date, year, d[:mon], d[:mday], d[:hour], d[:min], d[:sec], d[:sec_fraction], d[:zone], now) end
Parses date as date-time defined by RFC 2822 and converts it
to a Time object. The format is identical to the
date format defined by RFC 822 and updated by RFC 1123.
ArgumentError is raised if
date is not compliant with RFC 2822 or if the Time class cannot represent specified date.
See rfc2822 for more information on this format.
You must require 'time' to use this method.
# File lib/time.rb, line 464 def rfc2822(date) if /\A\s* (?:(?:Mon|Tue|Wed|Thu|Fri|Sat|Sun)\s*,\s*)? (\d{1,2})\s+ (Jan|Feb|Mar|Apr|May|Jun|Jul|Aug|Sep|Oct|Nov|Dec)\s+ (\d{2,})\s+ (\d{2})\s* :\s*(\d{2})\s* (?::\s*(\d{2}))?\s+ ([+-]\d{4}| UT|GMT|EST|EDT|CST|CDT|MST|MDT|PST|PDT|[A-IK-Z])/ix =~ date # Since RFC 2822 permit comments, the regexp has no right anchor. day = $1.to_i mon = MonthValue[$2.upcase] year = $3.to_i short_year_p = $3.length <= 3 hour = $4.to_i min = $5.to_i sec = $6 ? $6.to_i : 0 zone = $7 if short_year_p # following year completion is compliant with RFC 2822. year = if year < 50 2000 + year else 1900 + year end end off = zone_offset(zone) year, mon, day, hour, min, sec = apply_offset(year, mon, day, hour, min, sec, off) t = self.utc(year, mon, day, hour, min, sec) force_zone!(t, zone, off) t else raise ArgumentError.new("not RFC 2822 compliant date: #{date.inspect}") end end
Parses date using Date._strptime and
converts it to a Time object.
If a block is given, the year described in date is converted
by the block. For example:
Time.strptime(...) {|y| y < 100 ? (y >= 69 ? y + 1900 : y + 2000) : y}
Below is a list of the formatting options:
- %a
-
The abbreviated weekday name (“Sun”)
- %A
-
The full weekday name (“Sunday”)
- %b
-
The abbreviated month name (“Jan”)
- %B
-
The full month name (“January”)
- %c
-
The preferred local date and time representation
- %C
-
Century (20 in 2009)
- %d
-
Day of the month (01..31)
- %D
-
Date (%m/%d/%y)
- %e
-
Day of the month, blank-padded ( 1..31)
- %F
-
Equivalent to %Y-%m-%d (the ISO 8601 date format)
- %h
-
Equivalent to %b
- %H
-
Hour of the day, 24-hour clock (00..23)
- %I
-
Hour of the day, 12-hour clock (01..12)
- %j
-
Day of the year (001..366)
- %k
-
hour, 24-hour clock, blank-padded ( 0..23)
- %l
-
hour, 12-hour clock, blank-padded ( 0..12)
- %L
-
Millisecond of the second (000..999)
- %m
-
Month of the year (01..12)
- %M
-
Minute of the hour (00..59)
- %n
-
Newline (n)
- %N
-
Fractional seconds digits, default is 9 digits (nanosecond)
- %3N
-
millisecond (3 digits)
- %6N
-
microsecond (6 digits)
- %9N
-
nanosecond (9 digits)
- %p
-
Meridian indicator (“AM” or “PM”)
- %P
-
Meridian indicator (“am” or “pm”)
- %r
-
time, 12-hour (same as %I:%M:%S %p)
- %R
-
time, 24-hour (%H:%M)
- %s
-
Number of seconds since 1970-01-01 00:00:00 UTC.
- %S
-
Second of the minute (00..60)
- %t
-
Tab character (t)
- %T
-
time, 24-hour (%H:%M:%S)
- %u
-
Day of the week as a decimal, Monday being 1. (1..7)
- %U
-
Week number of the current year, starting with the first Sunday as the first day of the first week (00..53)
- %v
-
VMS date (%e-%b-%Y)
- %V
-
Week number of year according to ISO 8601 (01..53)
- %W
-
Week number of the current year, starting with the first Monday as the first day of the first week (00..53)
- %w
-
Day of the week (Sunday is 0, 0..6)
- %x
-
Preferred representation for the date alone, no time
- %X
-
Preferred representation for the time alone, no date
- %y
-
Year without a century (00..99)
- %Y
-
Year which may include century, if provided
- %z
-
Time zone as hour offset from UTC (e.g. +0900)
- %Z
-
Time zone name
- %%
-
Literal “%” character
# File lib/time.rb, line 425 def strptime(date, format, now=self.now) d = Date._strptime(date, format) raise ArgumentError, "invalid strptime format - `#{format}'" unless d if seconds = d[:seconds] if sec_fraction = d[:sec_fraction] usec = sec_fraction * 1000000 usec *= -1 if seconds < 0 else usec = 0 end t = Time.at(seconds, usec) if zone = d[:zone] force_zone!(t, zone) end else year = d[:year] year = yield(year) if year && block_given? t = make_time(date, year, d[:mon], d[:mday], d[:hour], d[:min], d[:sec], d[:sec_fraction], d[:zone], now) end t end
Creates a Time object based on given values,
interpreted as UTC (GMT). The year must be specified. Other values default
to the minimum value for that field (and may be nil or
omitted). Months may be specified by numbers from 1 to 12, or by the
three-letter English month names. Hours are
specified on a 24-hour clock (0..23). Raises an ArgumentError if any values are out of range.
Will also accept ten arguments in the order output by #to_a.
sec_with_frac and usec_with_frac can have a
fractional part.
Time.utc(2000,"jan",1,20,15,1) #=> 2000-01-01 20:15:01 UTC Time.gm(2000,"jan",1,20,15,1) #=> 2000-01-01 20:15:01 UTC
static VALUE
time_s_mkutc(int argc, VALUE *argv, VALUE klass)
{
return time_utc_or_local(argc, argv, TRUE, klass);
}
This method converts a W3CDTF string date/time format to Time object.
The W3CDTF format is defined here: www.w3.org/TR/NOTE-datetime
Time.w3cdtf('2003-02-15T13:50:05-05:00') # => 2003-02-15 10:50:05 -0800 Time.w3cdtf('2003-02-15T13:50:05-05:00').class # => Time
# File lib/rss/rss.rb, line 14 def w3cdtf(date) if /\A\s* (-?\d+)-(\d\d)-(\d\d) (?:T (\d\d):(\d\d)(?::(\d\d))? (\.\d+)? (Z|[+-]\d\d:\d\d)?)? \s*\z/ix =~ date and (($5 and $8) or (!$5 and !$8)) datetime = [$1.to_i, $2.to_i, $3.to_i, $4.to_i, $5.to_i, $6.to_i] usec = 0 usec = $7.to_f * 1000000 if $7 zone = $8 if zone off = zone_offset(zone, datetime[0]) datetime = apply_offset(*(datetime + [off])) datetime << usec time = Time.utc(*datetime) force_zone!(time, zone, off) time else datetime << usec Time.local(*datetime) end else raise ArgumentError.new("invalid date: #{date.inspect}") end end
Parses date as a dateTime defined by the XML Schema and converts it to a Time object. The format is a restricted version of
the format defined by ISO 8601.
ArgumentError is raised if
date is not compliant with the format or if the Time class cannot represent specified date.
See xmlschema for more information on this format.
You must require 'time' to use this method.
# File lib/time.rb, line 566 def xmlschema(date) if /\A\s* (-?\d+)-(\d\d)-(\d\d) T (\d\d):(\d\d):(\d\d) (\.\d+)? (Z|[+-]\d\d:\d\d)? \s*\z/ix =~ date year = $1.to_i mon = $2.to_i day = $3.to_i hour = $4.to_i min = $5.to_i sec = $6.to_i usec = 0 if $7 usec = Rational($7) * 1000000 end if $8 zone = $8 off = zone_offset(zone) year, mon, day, hour, min, sec = apply_offset(year, mon, day, hour, min, sec, off) t = self.utc(year, mon, day, hour, min, sec, usec) force_zone!(t, zone, off) t else self.local(year, mon, day, hour, min, sec, usec) end else raise ArgumentError.new("invalid date: #{date.inspect}") end end
Return the number of seconds the specified time zone differs from UTC.
Numeric time zones that include minutes, such as
-10:00 or +1330 will work, as will simpler
hour-only time zones like -10 or +13.
Textual time zones listed in ZoneOffset are also supported.
If the time zone does not match any of the above, zone_offset
will check if the local time zone (both with and without potential Daylight
Saving Time changes being in effect) matches zone. Specifying
a value for year will change the year used to find the local
time zone.
If zone_offset is unable to determine the offset, nil will be
returned.
# File lib/time.rb, line 132 def zone_offset(zone, year=self.now.year) off = nil zone = zone.upcase if /\A([+-])(\d\d):?(\d\d)\z/ =~ zone off = ($1 == '-' ? -1 : 1) * ($2.to_i * 60 + $3.to_i) * 60 elsif /\A[+-]\d\d\z/ =~ zone off = zone.to_i * 3600 elsif ZoneOffset.include?(zone) off = ZoneOffset[zone] * 3600 elsif ((t = self.local(year, 1, 1)).zone.upcase == zone rescue false) off = t.utc_offset elsif ((t = self.local(year, 7, 1)).zone.upcase == zone rescue false) off = t.utc_offset end off end
Private Class Methods
# File lib/time.rb, line 206 def apply_offset(year, mon, day, hour, min, sec, off) if off < 0 off = -off off, o = off.divmod(60) if o != 0 then sec += o; o, sec = sec.divmod(60); off += o end off, o = off.divmod(60) if o != 0 then min += o; o, min = min.divmod(60); off += o end off, o = off.divmod(24) if o != 0 then hour += o; o, hour = hour.divmod(24); off += o end if off != 0 day += off days = month_days(year, mon) if days and days < day mon += 1 if 12 < mon mon = 1 year += 1 end day = 1 end end elsif 0 < off off, o = off.divmod(60) if o != 0 then sec -= o; o, sec = sec.divmod(60); off -= o end off, o = off.divmod(60) if o != 0 then min -= o; o, min = min.divmod(60); off -= o end off, o = off.divmod(24) if o != 0 then hour -= o; o, hour = hour.divmod(24); off -= o end if off != 0 then day -= off if day < 1 mon -= 1 if mon < 1 year -= 1 mon = 12 end day = month_days(year, mon) end end end return year, mon, day, hour, min, sec end
# File lib/time.rb, line 177 def force_zone!(t, zone, offset=nil) if zone_utc?(zone) t.utc elsif offset ||= zone_offset(zone) # Prefer the local timezone over the fixed offset timezone because # the former is a real timezone and latter is an artificial timezone. t.localtime if t.utc_offset != offset # Use the fixed offset timezone only if the local timezone cannot # represent the given offset. t.localtime(offset) end else t.localtime end end
# File lib/time.rb, line 250 def make_time(date, year, mon, day, hour, min, sec, sec_fraction, zone, now) if !year && !mon && !day && !hour && !min && !sec && !sec_fraction raise ArgumentError, "no time information in #{date.inspect}" end off_year = year || now.year off = nil off = zone_offset(zone, off_year) if zone if off now = now.getlocal(off) if now.utc_offset != off else now = now.getlocal end usec = nil usec = sec_fraction * 1000000 if sec_fraction if now begin break if year; year = now.year break if mon; mon = now.mon break if day; day = now.day break if hour; hour = now.hour break if min; min = now.min break if sec; sec = now.sec break if sec_fraction; usec = now.tv_usec end until true end year ||= 1970 mon ||= 1 day ||= 1 hour ||= 0 min ||= 0 sec ||= 0 usec ||= 0 if year != off_year off = nil off = zone_offset(zone, year) if zone end if off year, mon, day, hour, min, sec = apply_offset(year, mon, day, hour, min, sec, off) t = self.utc(year, mon, day, hour, min, sec, usec) force_zone!(t, zone, off) t else self.local(year, mon, day, hour, min, sec, usec) end end
# File lib/time.rb, line 197 def month_days(y, m) if ((y % 4 == 0) && (y % 100 != 0)) || (y % 400 == 0) LeapYearMonthDays[m-1] else CommonYearMonthDays[m-1] end end
# File lib/time.rb, line 149 def zone_utc?(zone) # * +0000 # In RFC 2822, +0000 indicate a time zone at Universal Time. # Europe/Lisbon is "a time zone at Universal Time" in Winter. # Atlantic/Reykjavik is "a time zone at Universal Time". # Africa/Dakar is "a time zone at Universal Time". # So +0000 is a local time such as Europe/London, etc. # * GMT # GMT is used as a time zone abbreviation in Europe/London, # Africa/Dakar, etc. # So it is a local time. # # * -0000, -00:00 # In RFC 2822, -0000 the date-time contains no information about the # local time zone. # In RFC 3339, -00:00 is used for the time in UTC is known, # but the offset to local time is unknown. # They are not appropriate for specific time zone such as # Europe/London because time zone neutral, # So -00:00 and -0000 are treated as UTC. if /\A(?:-00:00|-0000|-00|UTC|Z|UT)\z/i =~ zone true else false end end
Public Instance Methods
Addition — Adds some number of seconds (possibly fractional) to time and returns that value as a new Time object.
t = Time.now #=> 2007-11-19 08:22:21 -0600 t + (60 * 60 * 24) #=> 2007-11-20 08:22:21 -0600
static VALUE
time_plus(VALUE time1, VALUE time2)
{
struct time_object *tobj;
GetTimeval(time1, tobj);
if (IsTimeval(time2)) {
rb_raise(rb_eTypeError, "time + time?");
}
return time_add(tobj, time2, 1);
}
Difference — Returns a new Time object that
represents the difference between time and
other_time, or subtracts the given number of seconds in
numeric from time.
t = Time.now #=> 2007-11-19 08:23:10 -0600 t2 = t + 2592000 #=> 2007-12-19 08:23:10 -0600 t2 - t #=> 2592000.0 t2 - 2592000 #=> 2007-11-19 08:23:10 -0600
static VALUE
time_minus(VALUE time1, VALUE time2)
{
struct time_object *tobj;
GetTimeval(time1, tobj);
if (IsTimeval(time2)) {
struct time_object *tobj2;
GetTimeval(time2, tobj2);
return rb_Float(rb_time_unmagnify_to_float(wsub(tobj->timew, tobj2->timew)));
}
return time_add(tobj, time2, -1);
}
Comparison—Compares time with other_time.
-1, 0, +1 or nil depending on whether time is less than,
equal to, or greater than other_time.
nil is returned if the two values are incomparable.
t = Time.now #=> 2007-11-19 08:12:12 -0600 t2 = t + 2592000 #=> 2007-12-19 08:12:12 -0600 t <=> t2 #=> -1 t2 <=> t #=> 1 t = Time.now #=> 2007-11-19 08:13:38 -0600 t2 = t + 0.1 #=> 2007-11-19 08:13:38 -0600 t.nsec #=> 98222999 t2.nsec #=> 198222999 t <=> t2 #=> -1 t2 <=> t #=> 1 t <=> t #=> 0
static VALUE
time_cmp(VALUE time1, VALUE time2)
{
struct time_object *tobj1, *tobj2;
int n;
GetTimeval(time1, tobj1);
if (IsTimeval(time2)) {
GetTimeval(time2, tobj2);
n = wcmp(tobj1->timew, tobj2->timew);
}
else {
return rb_invcmp(time1, time2);
}
if (n == 0) return INT2FIX(0);
if (n > 0) return INT2FIX(1);
return INT2FIX(-1);
}
Returns a hash, that will be turned into a JSON object and represent this object.
# File ext/json/lib/json/add/time.rb, line 21 def as_json(*) nanoseconds = [ tv_usec * 1000 ] respond_to?(:tv_nsec) and nanoseconds << tv_nsec nanoseconds = nanoseconds.max { JSON.create_id => self.class.name, 's' => tv_sec, 'n' => nanoseconds, } end
Returns a canonical string representation of time.
Time.now.asctime #=> "Wed Apr 9 08:56:03 2003"
static VALUE
time_asctime(VALUE time)
{
return strftimev("%a %b %e %T %Y", time, rb_usascii_encoding());
}
Returns a canonical string representation of time.
Time.now.asctime #=> "Wed Apr 9 08:56:03 2003"
static VALUE
time_asctime(VALUE time)
{
return strftimev("%a %b %e %T %Y", time, rb_usascii_encoding());
}
Returns the day of the month (1..n) for time.
t = Time.now #=> 2007-11-19 08:27:03 -0600 t.day #=> 19 t.mday #=> 19
static VALUE
time_mday(VALUE time)
{
struct time_object *tobj;
GetTimeval(time, tobj);
MAKE_TM(time, tobj);
return INT2FIX(tobj->vtm.mday);
}
Returns true if time occurs during Daylight Saving Time in its time zone.
# CST6CDT: Time.local(2000, 1, 1).zone #=> "CST" Time.local(2000, 1, 1).isdst #=> false Time.local(2000, 1, 1).dst? #=> false Time.local(2000, 7, 1).zone #=> "CDT" Time.local(2000, 7, 1).isdst #=> true Time.local(2000, 7, 1).dst? #=> true # Asia/Tokyo: Time.local(2000, 1, 1).zone #=> "JST" Time.local(2000, 1, 1).isdst #=> false Time.local(2000, 1, 1).dst? #=> false Time.local(2000, 7, 1).zone #=> "JST" Time.local(2000, 7, 1).isdst #=> false Time.local(2000, 7, 1).dst? #=> false
static VALUE
time_isdst(VALUE time)
{
struct time_object *tobj;
GetTimeval(time, tobj);
MAKE_TM(time, tobj);
return tobj->vtm.isdst ? Qtrue : Qfalse;
}
Returns true if time and other_time are
both Time objects with the same seconds and
fractional seconds.
static VALUE
time_eql(VALUE time1, VALUE time2)
{
struct time_object *tobj1, *tobj2;
GetTimeval(time1, tobj1);
if (IsTimeval(time2)) {
GetTimeval(time2, tobj2);
return rb_equal(w2v(tobj1->timew), w2v(tobj2->timew));
}
return Qfalse;
}
Returns true if time represents Friday.
t = Time.local(1987, 12, 18) #=> 1987-12-18 00:00:00 -0600 t.friday? #=> true
static VALUE
time_friday(VALUE time)
{
wday_p(5);
}
Returns a new Time object representing time in UTC.
t = Time.local(2000,1,1,20,15,1) #=> 2000-01-01 20:15:01 -0600 t.gmt? #=> false y = t.getgm #=> 2000-01-02 02:15:01 UTC y.gmt? #=> true t == y #=> true
static VALUE
time_getgmtime(VALUE time)
{
return time_gmtime(time_dup(time));
}
Returns a new Time object representing time in local time (using the local time zone in effect for this process).
If utc_offset is given, it is used instead of the local time.
t = Time.utc(2000,1,1,20,15,1) #=> 2000-01-01 20:15:01 UTC t.utc? #=> true l = t.getlocal #=> 2000-01-01 14:15:01 -0600 l.utc? #=> false t == l #=> true j = t.getlocal("+09:00") #=> 2000-01-02 05:15:01 +0900 j.utc? #=> false t == j #=> true
static VALUE
time_getlocaltime(int argc, VALUE *argv, VALUE time)
{
VALUE off;
rb_scan_args(argc, argv, "01", &off);
if (!NIL_P(off)) {
off = utc_offset_arg(off);
validate_utc_offset(off);
time = time_dup(time);
time_set_utc_offset(time, off);
return time_fixoff(time);
}
return time_localtime(time_dup(time));
}
Returns a new Time object representing time in UTC.
t = Time.local(2000,1,1,20,15,1) #=> 2000-01-01 20:15:01 -0600 t.gmt? #=> false y = t.getgm #=> 2000-01-02 02:15:01 UTC y.gmt? #=> true t == y #=> true
static VALUE
time_getgmtime(VALUE time)
{
return time_gmtime(time_dup(time));
}
Returns true if time represents a time in UTC (GMT).
t = Time.now #=> 2007-11-19 08:15:23 -0600 t.utc? #=> false t = Time.gm(2000,"jan",1,20,15,1) #=> 2000-01-01 20:15:01 UTC t.utc? #=> true t = Time.now #=> 2007-11-19 08:16:03 -0600 t.gmt? #=> false t = Time.gm(2000,1,1,20,15,1) #=> 2000-01-01 20:15:01 UTC t.gmt? #=> true
static VALUE
time_utc_p(VALUE time)
{
struct time_object *tobj;
GetTimeval(time, tobj);
if (TIME_UTC_P(tobj)) return Qtrue;
return Qfalse;
}
Returns the offset in seconds between the timezone of time and UTC.
t = Time.gm(2000,1,1,20,15,1) #=> 2000-01-01 20:15:01 UTC t.gmt_offset #=> 0 l = t.getlocal #=> 2000-01-01 14:15:01 -0600 l.gmt_offset #=> -21600
static VALUE
time_utc_offset(VALUE time)
{
struct time_object *tobj;
GetTimeval(time, tobj);
MAKE_TM(time, tobj);
if (TIME_UTC_P(tobj)) {
return INT2FIX(0);
}
else {
return tobj->vtm.utc_offset;
}
}
Converts time to UTC (GMT), modifying the receiver.
t = Time.now #=> 2007-11-19 08:18:31 -0600 t.gmt? #=> false t.gmtime #=> 2007-11-19 14:18:31 UTC t.gmt? #=> true t = Time.now #=> 2007-11-19 08:18:51 -0600 t.utc? #=> false t.utc #=> 2007-11-19 14:18:51 UTC t.utc? #=> true
static VALUE
time_gmtime(VALUE time)
{
struct time_object *tobj;
struct vtm vtm;
GetTimeval(time, tobj);
if (TIME_UTC_P(tobj)) {
if (tobj->tm_got)
return time;
}
else {
time_modify(time);
}
if (!gmtimew(tobj->timew, &vtm))
rb_raise(rb_eArgError, "gmtime error");
tobj->vtm = vtm;
tobj->tm_got = 1;
TIME_SET_UTC(tobj);
return time;
}
Returns the offset in seconds between the timezone of time and UTC.
t = Time.gm(2000,1,1,20,15,1) #=> 2000-01-01 20:15:01 UTC t.gmt_offset #=> 0 l = t.getlocal #=> 2000-01-01 14:15:01 -0600 l.gmt_offset #=> -21600
static VALUE
time_utc_offset(VALUE time)
{
struct time_object *tobj;
GetTimeval(time, tobj);
MAKE_TM(time, tobj);
if (TIME_UTC_P(tobj)) {
return INT2FIX(0);
}
else {
return tobj->vtm.utc_offset;
}
}
Returns a hash code for this Time object.
See also Object#hash.
static VALUE
time_hash(VALUE time)
{
struct time_object *tobj;
GetTimeval(time, tobj);
return rb_hash(w2v(tobj->timew));
}
Returns the hour of the day (0..23) for time.
t = Time.now #=> 2007-11-19 08:26:20 -0600 t.hour #=> 8
static VALUE
time_hour(VALUE time)
{
struct time_object *tobj;
GetTimeval(time, tobj);
MAKE_TM(time, tobj);
return INT2FIX(tobj->vtm.hour);
}
Returns a string which represents the time as RFC 1123 date of HTTP-date defined by RFC 2616:
day-of-week, DD month-name CCYY hh:mm:ss GMT
Note that the result is always UTC (GMT).
You must require 'time' to use this method.
# File lib/time.rb, line 648 def httpdate t = dup.utc sprintf('%s, %02d %s %0*d %02d:%02d:%02d GMT', RFC2822_DAY_NAME[t.wday], t.day, RFC2822_MONTH_NAME[t.mon-1], t.year < 0 ? 5 : 4, t.year, t.hour, t.min, t.sec) end
Returns a string representing time. Equivalent to calling strftime with the appropriate format string.
t = Time.now t.to_s => "2012-11-10 18:16:12 +0100" t.strftime "%Y-%m-%d %H:%M:%S %z" => "2012-11-10 18:16:12 +0100" t.utc.to_s => "2012-11-10 17:16:12 UTC" t.strftime "%Y-%m-%d %H:%M:%S UTC" => "2012-11-10 17:16:12 UTC"
static VALUE
time_to_s(VALUE time)
{
struct time_object *tobj;
GetTimeval(time, tobj);
if (TIME_UTC_P(tobj))
return strftimev("%Y-%m-%d %H:%M:%S UTC", time, rb_usascii_encoding());
else
return strftimev("%Y-%m-%d %H:%M:%S %z", time, rb_usascii_encoding());
}
Returns true if time occurs during Daylight Saving Time in its time zone.
# CST6CDT: Time.local(2000, 1, 1).zone #=> "CST" Time.local(2000, 1, 1).isdst #=> false Time.local(2000, 1, 1).dst? #=> false Time.local(2000, 7, 1).zone #=> "CDT" Time.local(2000, 7, 1).isdst #=> true Time.local(2000, 7, 1).dst? #=> true # Asia/Tokyo: Time.local(2000, 1, 1).zone #=> "JST" Time.local(2000, 1, 1).isdst #=> false Time.local(2000, 1, 1).dst? #=> false Time.local(2000, 7, 1).zone #=> "JST" Time.local(2000, 7, 1).isdst #=> false Time.local(2000, 7, 1).dst? #=> false
static VALUE
time_isdst(VALUE time)
{
struct time_object *tobj;
GetTimeval(time, tobj);
MAKE_TM(time, tobj);
return tobj->vtm.isdst ? Qtrue : Qfalse;
}
Converts time to local time (using the local time zone in effect for this process) modifying the receiver.
If utc_offset is given, it is used instead of the local time.
t = Time.utc(2000, "jan", 1, 20, 15, 1) #=> 2000-01-01 20:15:01 UTC t.utc? #=> true t.localtime #=> 2000-01-01 14:15:01 -0600 t.utc? #=> false t.localtime("+09:00") #=> 2000-01-02 05:15:01 +0900 t.utc? #=> false
static VALUE
time_localtime_m(int argc, VALUE *argv, VALUE time)
{
VALUE off;
rb_scan_args(argc, argv, "01", &off);
if (!NIL_P(off)) {
off = utc_offset_arg(off);
validate_utc_offset(off);
time_set_utc_offset(time, off);
return time_fixoff(time);
}
return time_localtime(time);
}
Returns the day of the month (1..n) for time.
t = Time.now #=> 2007-11-19 08:27:03 -0600 t.day #=> 19 t.mday #=> 19
static VALUE
time_mday(VALUE time)
{
struct time_object *tobj;
GetTimeval(time, tobj);
MAKE_TM(time, tobj);
return INT2FIX(tobj->vtm.mday);
}
Returns the minute of the hour (0..59) for time.
t = Time.now #=> 2007-11-19 08:25:51 -0600 t.min #=> 25
static VALUE
time_min(VALUE time)
{
struct time_object *tobj;
GetTimeval(time, tobj);
MAKE_TM(time, tobj);
return INT2FIX(tobj->vtm.min);
}
Returns the month of the year (1..12) for time.
t = Time.now #=> 2007-11-19 08:27:30 -0600 t.mon #=> 11 t.month #=> 11
static VALUE
time_mon(VALUE time)
{
struct time_object *tobj;
GetTimeval(time, tobj);
MAKE_TM(time, tobj);
return INT2FIX(tobj->vtm.mon);
}
Returns true if time represents Monday.
t = Time.local(2003, 8, 4) #=> 2003-08-04 00:00:00 -0500 p t.monday? #=> true
static VALUE
time_monday(VALUE time)
{
wday_p(1);
}
Returns the month of the year (1..12) for time.
t = Time.now #=> 2007-11-19 08:27:30 -0600 t.mon #=> 11 t.month #=> 11
static VALUE
time_mon(VALUE time)
{
struct time_object *tobj;
GetTimeval(time, tobj);
MAKE_TM(time, tobj);
return INT2FIX(tobj->vtm.mon);
}
Returns the number of nanoseconds for time.
t = Time.now #=> 2007-11-17 15:18:03 +0900 "%10.9f" % t.to_f #=> "1195280283.536151409" t.nsec #=> 536151406
The lowest digits of to_f and nsec are different because IEEE 754 double is not accurate enough to represent the exact number of nanoseconds since the Epoch.
The more accurate value is returned by nsec.
static VALUE
time_nsec(VALUE time)
{
struct time_object *tobj;
GetTimeval(time, tobj);
return rb_to_int(w2v(wmulquoll(wmod(tobj->timew, WINT2WV(TIME_SCALE)), 1000000000, TIME_SCALE)));
}
Returns a string which represents the time as date-time defined by RFC 2822:
day-of-week, DD month-name CCYY hh:mm:ss zone
where zone is [+-]hhmm.
If self is a UTC time, -0000 is used as zone.
You must require 'time' to use this method.
# File lib/time.rb, line 613 def rfc2822 sprintf('%s, %02d %s %0*d %02d:%02d:%02d ', RFC2822_DAY_NAME[wday], day, RFC2822_MONTH_NAME[mon-1], year < 0 ? 5 : 4, year, hour, min, sec) + if utc? '-0000' else off = utc_offset sign = off < 0 ? '-' : '+' sprintf('%s%02d%02d', sign, *(off.abs / 60).divmod(60)) end end
Rounds sub seconds to a given precision in decimal digits (0 digits by
default). It returns a new Time object.
ndigits should be zero or positive integer.
require 'time' t = Time.utc(2010,3,30, 5,43,"25.123456789".to_r) p t.iso8601(10) #=> "2010-03-30T05:43:25.1234567890Z" p t.round.iso8601(10) #=> "2010-03-30T05:43:25.0000000000Z" p t.round(0).iso8601(10) #=> "2010-03-30T05:43:25.0000000000Z" p t.round(1).iso8601(10) #=> "2010-03-30T05:43:25.1000000000Z" p t.round(2).iso8601(10) #=> "2010-03-30T05:43:25.1200000000Z" p t.round(3).iso8601(10) #=> "2010-03-30T05:43:25.1230000000Z" p t.round(4).iso8601(10) #=> "2010-03-30T05:43:25.1235000000Z" p t.round(5).iso8601(10) #=> "2010-03-30T05:43:25.1234600000Z" p t.round(6).iso8601(10) #=> "2010-03-30T05:43:25.1234570000Z" p t.round(7).iso8601(10) #=> "2010-03-30T05:43:25.1234568000Z" p t.round(8).iso8601(10) #=> "2010-03-30T05:43:25.1234567900Z" p t.round(9).iso8601(10) #=> "2010-03-30T05:43:25.1234567890Z" p t.round(10).iso8601(10) #=> "2010-03-30T05:43:25.1234567890Z" t = Time.utc(1999,12,31, 23,59,59) p((t + 0.4).round.iso8601(3)) #=> "1999-12-31T23:59:59.000Z" p((t + 0.49).round.iso8601(3)) #=> "1999-12-31T23:59:59.000Z" p((t + 0.5).round.iso8601(3)) #=> "2000-01-01T00:00:00.000Z" p((t + 1.4).round.iso8601(3)) #=> "2000-01-01T00:00:00.000Z" p((t + 1.49).round.iso8601(3)) #=> "2000-01-01T00:00:00.000Z" p((t + 1.5).round.iso8601(3)) #=> "2000-01-01T00:00:01.000Z" t = Time.utc(1999,12,31, 23,59,59) p (t + 0.123456789).round(4).iso8601(6) #=> "1999-12-31T23:59:59.123500Z"
static VALUE
time_round(int argc, VALUE *argv, VALUE time)
{
VALUE ndigits, v, a, b, den;
long nd;
struct time_object *tobj;
rb_scan_args(argc, argv, "01", &ndigits);
if (NIL_P(ndigits))
ndigits = INT2FIX(0);
else
ndigits = rb_to_int(ndigits);
nd = NUM2LONG(ndigits);
if (nd < 0)
rb_raise(rb_eArgError, "negative ndigits given");
GetTimeval(time, tobj);
v = w2v(rb_time_unmagnify(tobj->timew));
a = INT2FIX(1);
b = INT2FIX(10);
while (0 < nd) {
if (nd & 1)
a = mul(a, b);
b = mul(b, b);
nd = nd >> 1;
}
den = quo(INT2FIX(1), a);
v = mod(v, den);
if (lt(v, quo(den, INT2FIX(2))))
return time_add(tobj, v, -1);
else
return time_add(tobj, sub(den, v), 1);
}
Returns true if time represents Saturday.
t = Time.local(2006, 6, 10) #=> 2006-06-10 00:00:00 -0500 t.saturday? #=> true
static VALUE
time_saturday(VALUE time)
{
wday_p(6);
}
Returns the second of the minute (0..60) for time.
Note: Seconds range from zero to 60 to allow the system to inject leap seconds. See en.wikipedia.org/wiki/Leap_second for further details.
t = Time.now #=> 2007-11-19 08:25:02 -0600 t.sec #=> 2
static VALUE
time_sec(VALUE time)
{
struct time_object *tobj;
GetTimeval(time, tobj);
MAKE_TM(time, tobj);
return INT2FIX(tobj->vtm.sec);
}
Formats time according to the directives in the given format string.
The directives begin with a percent (%) character. Any text not listed as a directive will be passed through to the output string.
The directive consists of a percent (%) character, zero or more flags, optional minimum field width, optional modifier and a conversion specifier as follows:
%<flags><width><modifier><conversion>
Flags:
- don't pad a numerical output _ use spaces for padding 0 use zeros for padding ^ upcase the result string # change case : use colons for %z
The minimum field width specifies the minimum width.
The modifiers are “E” and “O”. They are ignored.
Format directives:
Date (Year, Month, Day):
%Y - Year with century if provided, will pad result at least 4 digits.
-0001, 0000, 1995, 2009, 14292, etc.
%C - year / 100 (rounded down such as 20 in 2009)
%y - year % 100 (00..99)
%m - Month of the year, zero-padded (01..12)
%_m blank-padded ( 1..12)
%-m no-padded (1..12)
%B - The full month name (``January'')
%^B uppercased (``JANUARY'')
%b - The abbreviated month name (``Jan'')
%^b uppercased (``JAN'')
%h - Equivalent to %b
%d - Day of the month, zero-padded (01..31)
%-d no-padded (1..31)
%e - Day of the month, blank-padded ( 1..31)
%j - Day of the year (001..366)
Time (Hour, Minute, Second, Subsecond):
%H - Hour of the day, 24-hour clock, zero-padded (00..23)
%k - Hour of the day, 24-hour clock, blank-padded ( 0..23)
%I - Hour of the day, 12-hour clock, zero-padded (01..12)
%l - Hour of the day, 12-hour clock, blank-padded ( 1..12)
%P - Meridian indicator, lowercase (``am'' or ``pm'')
%p - Meridian indicator, uppercase (``AM'' or ``PM'')
%M - Minute of the hour (00..59)
%S - Second of the minute (00..60)
%L - Millisecond of the second (000..999)
The digits under millisecond are truncated to not produce 1000.
%N - Fractional seconds digits, default is 9 digits (nanosecond)
%3N millisecond (3 digits)
%6N microsecond (6 digits)
%9N nanosecond (9 digits)
%12N picosecond (12 digits)
%15N femtosecond (15 digits)
%18N attosecond (18 digits)
%21N zeptosecond (21 digits)
%24N yoctosecond (24 digits)
The digits under the specified length are truncated to avoid
carry up.
Time zone:
%z - Time zone as hour and minute offset from UTC (e.g. +0900)
%:z - hour and minute offset from UTC with a colon (e.g. +09:00)
%::z - hour, minute and second offset from UTC (e.g. +09:00:00)
%Z - Abbreviated time zone name or similar information. (OS dependent)
Weekday:
%A - The full weekday name (``Sunday'')
%^A uppercased (``SUNDAY'')
%a - The abbreviated name (``Sun'')
%^a uppercased (``SUN'')
%u - Day of the week (Monday is 1, 1..7)
%w - Day of the week (Sunday is 0, 0..6)
ISO 8601 week-based year and week number:
The first week of YYYY starts with a Monday and includes YYYY-01-04.
The days in the year before the first week are in the last week of
the previous year.
%G - The week-based year
%g - The last 2 digits of the week-based year (00..99)
%V - Week number of the week-based year (01..53)
Week number:
The first week of YYYY that starts with a Sunday or Monday (according to %U
or %W). The days in the year before the first week are in week 0.
%U - Week number of the year. The week starts with Sunday. (00..53)
%W - Week number of the year. The week starts with Monday. (00..53)
Seconds since the Epoch:
%s - Number of seconds since 1970-01-01 00:00:00 UTC.
Literal string:
%n - Newline character (\n)
%t - Tab character (\t)
%% - Literal ``%'' character
Combination:
%c - date and time (%a %b %e %T %Y)
%D - Date (%m/%d/%y)
%F - The ISO 8601 date format (%Y-%m-%d)
%v - VMS date (%e-%^b-%4Y)
%x - Same as %D
%X - Same as %T
%r - 12-hour time (%I:%M:%S %p)
%R - 24-hour time (%H:%M)
%T - 24-hour time (%H:%M:%S)
This method is similar to strftime() function defined in ISO C and POSIX.
While all directives are locale independent since Ruby 1.9, %Z is platform dependent. So, the result may differ even if the same format string is used in other systems such as C.
%z is recommended over %Z. %Z doesn't identify the timezone. For example, “CST” is used at America/Chicago (-06:00), America/Havana (-05:00), Asia/Harbin (+08:00), Australia/Darwin (+09:30) and Australia/Adelaide (+10:30). Also, %Z is highly dependent on the operating system. For example, it may generate a non ASCII string on Japanese Windows. i.e. the result can be different to “JST”. So the numeric time zone offset, %z, is recommended.
Examples:
t = Time.new(2007,11,19,8,37,48,"-06:00") #=> 2007-11-19 08:37:48 -0600 t.strftime("Printed on %m/%d/%Y") #=> "Printed on 11/19/2007" t.strftime("at %I:%M%p") #=> "at 08:37AM"
Various ISO 8601 formats:
%Y%m%d => 20071119 Calendar date (basic) %F => 2007-11-19 Calendar date (extended) %Y-%m => 2007-11 Calendar date, reduced accuracy, specific month %Y => 2007 Calendar date, reduced accuracy, specific year %C => 20 Calendar date, reduced accuracy, specific century %Y%j => 2007323 Ordinal date (basic) %Y-%j => 2007-323 Ordinal date (extended) %GW%V%u => 2007W471 Week date (basic) %G-W%V-%u => 2007-W47-1 Week date (extended) %GW%V => 2007W47 Week date, reduced accuracy, specific week (basic) %G-W%V => 2007-W47 Week date, reduced accuracy, specific week (extended) %H%M%S => 083748 Local time (basic) %T => 08:37:48 Local time (extended) %H%M => 0837 Local time, reduced accuracy, specific minute (basic) %H:%M => 08:37 Local time, reduced accuracy, specific minute (extended) %H => 08 Local time, reduced accuracy, specific hour %H%M%S,%L => 083748,000 Local time with decimal fraction, comma as decimal sign (basic) %T,%L => 08:37:48,000 Local time with decimal fraction, comma as decimal sign (extended) %H%M%S.%L => 083748.000 Local time with decimal fraction, full stop as decimal sign (basic) %T.%L => 08:37:48.000 Local time with decimal fraction, full stop as decimal sign (extended) %H%M%S%z => 083748-0600 Local time and the difference from UTC (basic) %T%:z => 08:37:48-06:00 Local time and the difference from UTC (extended) %Y%m%dT%H%M%S%z => 20071119T083748-0600 Date and time of day for calendar date (basic) %FT%T%:z => 2007-11-19T08:37:48-06:00 Date and time of day for calendar date (extended) %Y%jT%H%M%S%z => 2007323T083748-0600 Date and time of day for ordinal date (basic) %Y-%jT%T%:z => 2007-323T08:37:48-06:00 Date and time of day for ordinal date (extended) %GW%V%uT%H%M%S%z => 2007W471T083748-0600 Date and time of day for week date (basic) %G-W%V-%uT%T%:z => 2007-W47-1T08:37:48-06:00 Date and time of day for week date (extended) %Y%m%dT%H%M => 20071119T0837 Calendar date and local time (basic) %FT%R => 2007-11-19T08:37 Calendar date and local time (extended) %Y%jT%H%MZ => 2007323T0837Z Ordinal date and UTC of day (basic) %Y-%jT%RZ => 2007-323T08:37Z Ordinal date and UTC of day (extended) %GW%V%uT%H%M%z => 2007W471T0837-0600 Week date and local time and difference from UTC (basic) %G-W%V-%uT%R%:z => 2007-W47-1T08:37-06:00 Week date and local time and difference from UTC (extended)
static VALUE
time_strftime(VALUE time, VALUE format)
{
struct time_object *tobj;
char buffer[SMALLBUF], *buf = buffer;
const char *fmt;
long len;
rb_encoding *enc;
VALUE str;
GetTimeval(time, tobj);
MAKE_TM(time, tobj);
StringValue(format);
if (!rb_enc_str_asciicompat_p(format)) {
rb_raise(rb_eArgError, "format should have ASCII compatible encoding");
}
format = rb_str_new4(format);
fmt = RSTRING_PTR(format);
len = RSTRING_LEN(format);
enc = rb_enc_get(format);
if (len == 0) {
rb_warning("strftime called with empty format string");
}
else if (fmt[len] || memchr(fmt, '\0', len)) {
/* Ruby string may contain \0's. */
const char *p = fmt, *pe = fmt + len;
str = rb_str_new(0, 0);
while (p < pe) {
len = rb_strftime_alloc(&buf, format, p, enc,
&tobj->vtm, tobj->timew, TIME_UTC_P(tobj));
rb_str_cat(str, buf, len);
p += strlen(p);
if (buf != buffer) {
xfree(buf);
buf = buffer;
}
for (fmt = p; p < pe && !*p; ++p);
if (p > fmt) rb_str_cat(str, fmt, p - fmt);
}
return str;
}
else {
len = rb_strftime_alloc(&buf, format, RSTRING_PTR(format), enc,
&tobj->vtm, tobj->timew, TIME_UTC_P(tobj));
}
str = rb_enc_str_new(buf, len, enc);
if (buf != buffer) xfree(buf);
return str;
}
Returns the fraction for time.
The return value can be a rational number.
t = Time.now #=> 2009-03-26 22:33:12 +0900 "%10.9f" % t.to_f #=> "1238074392.940563917" t.subsec #=> (94056401/100000000)
The lowest digits of to_f and subsec are different because IEEE 754 double is not accurate enough to represent the rational number.
The more accurate value is returned by subsec.
static VALUE
time_subsec(VALUE time)
{
struct time_object *tobj;
GetTimeval(time, tobj);
return quo(w2v(wmod(tobj->timew, WINT2FIXWV(TIME_SCALE))), INT2FIX(TIME_SCALE));
}
Returns a new Time object, one second later than time. #succ is obsolete since 1.9.2 for time is not a discrete value.
t = Time.now #=> 2007-11-19 08:23:57 -0600 t.succ #=> 2007-11-19 08:23:58 -0600
Use instead time + 1
t + 1 #=> 2007-11-19 08:23:58 -0600
VALUE
rb_time_succ(VALUE time)
{
struct time_object *tobj;
struct time_object *tobj2;
rb_warn("Time#succ is obsolete; use time + 1");
GetTimeval(time, tobj);
time = time_new_timew(rb_cTime, wadd(tobj->timew, WINT2FIXWV(TIME_SCALE)));
GetTimeval(time, tobj2);
TIME_COPY_GMT(tobj2, tobj);
return time;
}
Returns true if time represents Sunday.
t = Time.local(1990, 4, 1) #=> 1990-04-01 00:00:00 -0600 t.sunday? #=> true
static VALUE
time_sunday(VALUE time)
{
wday_p(0);
}
Returns true if time represents Thursday.
t = Time.local(1995, 12, 21) #=> 1995-12-21 00:00:00 -0600 p t.thursday? #=> true
static VALUE
time_thursday(VALUE time)
{
wday_p(4);
}
Returns a ten-element array of values for time:
[sec, min, hour, day, month, year, wday, yday, isdst, zone]
See the individual methods for an explanation of the valid ranges of each value. The ten elements can be passed directly to ::utc or ::local to create a new Time object.
t = Time.now #=> 2007-11-19 08:36:01 -0600 now = t.to_a #=> [1, 36, 8, 19, 11, 2007, 1, 323, false, "CST"]
static VALUE
time_to_a(VALUE time)
{
struct time_object *tobj;
GetTimeval(time, tobj);
MAKE_TM(time, tobj);
return rb_ary_new3(10,
INT2FIX(tobj->vtm.sec),
INT2FIX(tobj->vtm.min),
INT2FIX(tobj->vtm.hour),
INT2FIX(tobj->vtm.mday),
INT2FIX(tobj->vtm.mon),
tobj->vtm.year,
INT2FIX(tobj->vtm.wday),
INT2FIX(tobj->vtm.yday),
tobj->vtm.isdst?Qtrue:Qfalse,
time_zone(time));
}
Returns a Date object which denotes self.
static VALUE
time_to_date(VALUE self)
{
VALUE y, nth, ret;
int ry, m, d;
y = f_year(self);
m = FIX2INT(f_mon(self));
d = FIX2INT(f_mday(self));
decode_year(y, -1, &nth, &ry);
ret = d_simple_new_internal(cDate,
nth, 0,
GREGORIAN,
ry, m, d,
HAVE_CIVIL);
{
get_d1(ret);
set_sg(dat, DEFAULT_SG);
}
return ret;
}
Returns a DateTime object which denotes self.
static VALUE
time_to_datetime(VALUE self)
{
VALUE y, sf, nth, ret;
int ry, m, d, h, min, s, of;
y = f_year(self);
m = FIX2INT(f_mon(self));
d = FIX2INT(f_mday(self));
h = FIX2INT(f_hour(self));
min = FIX2INT(f_min(self));
s = FIX2INT(f_sec(self));
if (s == 60)
s = 59;
sf = sec_to_ns(f_subsec(self));
of = FIX2INT(f_utc_offset(self));
decode_year(y, -1, &nth, &ry);
ret = d_complex_new_internal(cDateTime,
nth, 0,
0, sf,
of, DEFAULT_SG,
ry, m, d,
h, min, s,
HAVE_CIVIL | HAVE_TIME);
{
get_d1(ret);
set_sg(dat, DEFAULT_SG);
}
return ret;
}
Returns the value of time as a floating point number of seconds since the Epoch.
t = Time.now "%10.5f" % t.to_f #=> "1270968744.77658" t.to_i #=> 1270968744
Note that IEEE 754 double is not accurate enough to represent the number of nanoseconds since the Epoch.
static VALUE
time_to_f(VALUE time)
{
struct time_object *tobj;
GetTimeval(time, tobj);
return rb_Float(rb_time_unmagnify_to_float(tobj->timew));
}
Returns the value of time as an integer number of seconds since the Epoch.
t = Time.now "%10.5f" % t.to_f #=> "1270968656.89607" t.to_i #=> 1270968656
static VALUE
time_to_i(VALUE time)
{
struct time_object *tobj;
GetTimeval(time, tobj);
return w2v(wdiv(tobj->timew, WINT2FIXWV(TIME_SCALE)));
}
Returns the value of time as a rational number of seconds since the Epoch.
t = Time.now p t.to_r #=> (1270968792716287611/1000000000)
This methods is intended to be used to get an accurate value representing the nanoseconds since the Epoch. You can use this method to convert time to another Epoch.
static VALUE
time_to_r(VALUE time)
{
struct time_object *tobj;
VALUE v;
GetTimeval(time, tobj);
v = w2v(rb_time_unmagnify(tobj->timew));
if (!RB_TYPE_P(v, T_RATIONAL)) {
v = rb_Rational1(v);
}
return v;
}
Returns a string representing time. Equivalent to calling strftime with the appropriate format string.
t = Time.now t.to_s => "2012-11-10 18:16:12 +0100" t.strftime "%Y-%m-%d %H:%M:%S %z" => "2012-11-10 18:16:12 +0100" t.utc.to_s => "2012-11-10 17:16:12 UTC" t.strftime "%Y-%m-%d %H:%M:%S UTC" => "2012-11-10 17:16:12 UTC"
static VALUE
time_to_s(VALUE time)
{
struct time_object *tobj;
GetTimeval(time, tobj);
if (TIME_UTC_P(tobj))
return strftimev("%Y-%m-%d %H:%M:%S UTC", time, rb_usascii_encoding());
else
return strftimev("%Y-%m-%d %H:%M:%S %z", time, rb_usascii_encoding());
}
Returns a copy of self as local mode.
static VALUE
time_to_time(VALUE self)
{
return f_getlocal(self);
}
Returns true if time represents Tuesday.
t = Time.local(1991, 2, 19) #=> 1991-02-19 00:00:00 -0600 p t.tuesday? #=> true
static VALUE
time_tuesday(VALUE time)
{
wday_p(2);
}
Returns the number of nanoseconds for time.
t = Time.now #=> 2007-11-17 15:18:03 +0900 "%10.9f" % t.to_f #=> "1195280283.536151409" t.nsec #=> 536151406
The lowest digits of to_f and nsec are different because IEEE 754 double is not accurate enough to represent the exact number of nanoseconds since the Epoch.
The more accurate value is returned by nsec.
static VALUE
time_nsec(VALUE time)
{
struct time_object *tobj;
GetTimeval(time, tobj);
return rb_to_int(w2v(wmulquoll(wmod(tobj->timew, WINT2WV(TIME_SCALE)), 1000000000, TIME_SCALE)));
}
Returns the value of time as an integer number of seconds since the Epoch.
t = Time.now "%10.5f" % t.to_f #=> "1270968656.89607" t.to_i #=> 1270968656
static VALUE
time_to_i(VALUE time)
{
struct time_object *tobj;
GetTimeval(time, tobj);
return w2v(wdiv(tobj->timew, WINT2FIXWV(TIME_SCALE)));
}
Returns the number of microseconds for time.
t = Time.now #=> 2007-11-19 08:03:26 -0600 "%10.6f" % t.to_f #=> "1195481006.775195" t.usec #=> 775195
static VALUE
time_usec(VALUE time)
{
struct time_object *tobj;
wideval_t w, q, r;
GetTimeval(time, tobj);
w = wmod(tobj->timew, WINT2WV(TIME_SCALE));
wmuldivmod(w, WINT2FIXWV(1000000), WINT2FIXWV(TIME_SCALE), &q, &r);
return rb_to_int(w2v(q));
}
Returns the number of microseconds for time.
t = Time.now #=> 2007-11-19 08:03:26 -0600 "%10.6f" % t.to_f #=> "1195481006.775195" t.usec #=> 775195
static VALUE
time_usec(VALUE time)
{
struct time_object *tobj;
wideval_t w, q, r;
GetTimeval(time, tobj);
w = wmod(tobj->timew, WINT2WV(TIME_SCALE));
wmuldivmod(w, WINT2FIXWV(1000000), WINT2FIXWV(TIME_SCALE), &q, &r);
return rb_to_int(w2v(q));
}
Converts time to UTC (GMT), modifying the receiver.
t = Time.now #=> 2007-11-19 08:18:31 -0600 t.gmt? #=> false t.gmtime #=> 2007-11-19 14:18:31 UTC t.gmt? #=> true t = Time.now #=> 2007-11-19 08:18:51 -0600 t.utc? #=> false t.utc #=> 2007-11-19 14:18:51 UTC t.utc? #=> true
static VALUE
time_gmtime(VALUE time)
{
struct time_object *tobj;
struct vtm vtm;
GetTimeval(time, tobj);
if (TIME_UTC_P(tobj)) {
if (tobj->tm_got)
return time;
}
else {
time_modify(time);
}
if (!gmtimew(tobj->timew, &vtm))
rb_raise(rb_eArgError, "gmtime error");
tobj->vtm = vtm;
tobj->tm_got = 1;
TIME_SET_UTC(tobj);
return time;
}
Returns true if time represents a time in UTC (GMT).
t = Time.now #=> 2007-11-19 08:15:23 -0600 t.utc? #=> false t = Time.gm(2000,"jan",1,20,15,1) #=> 2000-01-01 20:15:01 UTC t.utc? #=> true t = Time.now #=> 2007-11-19 08:16:03 -0600 t.gmt? #=> false t = Time.gm(2000,1,1,20,15,1) #=> 2000-01-01 20:15:01 UTC t.gmt? #=> true
static VALUE
time_utc_p(VALUE time)
{
struct time_object *tobj;
GetTimeval(time, tobj);
if (TIME_UTC_P(tobj)) return Qtrue;
return Qfalse;
}
Returns the offset in seconds between the timezone of time and UTC.
t = Time.gm(2000,1,1,20,15,1) #=> 2000-01-01 20:15:01 UTC t.gmt_offset #=> 0 l = t.getlocal #=> 2000-01-01 14:15:01 -0600 l.gmt_offset #=> -21600
static VALUE
time_utc_offset(VALUE time)
{
struct time_object *tobj;
GetTimeval(time, tobj);
MAKE_TM(time, tobj);
if (TIME_UTC_P(tobj)) {
return INT2FIX(0);
}
else {
return tobj->vtm.utc_offset;
}
}
This method converts a Time object to a String. The String contains the time in W3CDTF date/time format.
The W3CDTF format is defined here: www.w3.org/TR/NOTE-datetime
Time.now.w3cdtf # => "2013-08-26T14:12:10.817124-07:00"
# File lib/rss/rss.rb, line 52 def w3cdtf if usec.zero? fraction_digits = 0 else fraction_digits = strftime('%6N').index(/0*\z/) end xmlschema(fraction_digits) end
Returns an integer representing the day of the week, 0..6, with Sunday == 0.
t = Time.now #=> 2007-11-20 02:35:35 -0600 t.wday #=> 2 t.sunday? #=> false t.monday? #=> false t.tuesday? #=> true t.wednesday? #=> false t.thursday? #=> false t.friday? #=> false t.saturday? #=> false
static VALUE
time_wday(VALUE time)
{
struct time_object *tobj;
GetTimeval(time, tobj);
MAKE_TM(time, tobj);
return INT2FIX((int)tobj->vtm.wday);
}
Returns true if time represents Wednesday.
t = Time.local(1993, 2, 24) #=> 1993-02-24 00:00:00 -0600 p t.wednesday? #=> true
static VALUE
time_wednesday(VALUE time)
{
wday_p(3);
}
Returns a string which represents the time as a dateTime defined by XML Schema:
CCYY-MM-DDThh:mm:ssTZD CCYY-MM-DDThh:mm:ss.sssTZD
where TZD is Z or [+-]hh:mm.
If self is a UTC time, Z is used as TZD. [+-]hh:mm is used otherwise.
fractional_digits specifies a number of digits to use for
fractional seconds. Its default value is 0.
You must require 'time' to use this method.
# File lib/time.rb, line 672 def xmlschema(fraction_digits=0) fraction_digits = fraction_digits.to_i s = strftime("%FT%T") if fraction_digits > 0 s << strftime(".%#{fraction_digits}N") end s << (utc? ? 'Z' : strftime("%:z")) end
Returns an integer representing the day of the year, 1..366.
t = Time.now #=> 2007-11-19 08:32:31 -0600 t.yday #=> 323
static VALUE
time_yday(VALUE time)
{
struct time_object *tobj;
GetTimeval(time, tobj);
MAKE_TM(time, tobj);
return INT2FIX(tobj->vtm.yday);
}
Returns the year for time (including the century).
t = Time.now #=> 2007-11-19 08:27:51 -0600 t.year #=> 2007
static VALUE
time_year(VALUE time)
{
struct time_object *tobj;
GetTimeval(time, tobj);
MAKE_TM(time, tobj);
return tobj->vtm.year;
}
Returns the name of the time zone used for time. As of Ruby 1.8, returns “UTC'' rather than “GMT'' for UTC times.
t = Time.gm(2000, "jan", 1, 20, 15, 1) t.zone #=> "UTC" t = Time.local(2000, "jan", 1, 20, 15, 1) t.zone #=> "CST"
static VALUE
time_zone(VALUE time)
{
struct time_object *tobj;
GetTimeval(time, tobj);
MAKE_TM(time, tobj);
if (TIME_UTC_P(tobj)) {
return rb_usascii_str_new_cstr("UTC");
}
if (tobj->vtm.zone == NULL)
return Qnil;
return time_zone_name(tobj->vtm.zone);
}