This SRFI is currently in ``final'' status. To see an explanation of each status that a SRFI can hold, see here. You can access the discussion via the archive of the mailing list.
~D
fixed: 2003-05-30A date is a representation of a point in time in the Gregorian calendar, a 24 hour clock (with nanosecond precision) and a time zone offset from UTC. Procedures for converting between time and dates are provided, as well as for reading and writing string representations of dates.
A Time object, which is distinct from all existing types, defines a point in time or a time duration in some standard time system. The standard time systems are:
A time object consists of three components:
TIME-TAI
,
TIME-UTC
, TIME-MONOTONIC
,
TIME-THREAD
, TIME-PROCESS
, and
TIME-DURATION
must be provided for these
symbols. Implementations should provide constants for time type
extensions.
A Date object, which is distinct from all existing types, represents a point in time as represented by the Gregorian calendar as well as by a time zone. Dates are immutable. A date consists of the following components:
A Julian Day represents a point in time as a real number of days since -4714-11-24T12:00:00Z (November 24, -4714 at noon, UTC).
A Modified Julian Day represents a point in time as a real number of days since 1858-11-17T00:00:00Z (November 17, 1858 at midnight, UTC).
The following constants are required:
time-duration
time-monotonic
time-process
time-tai
time-thread
time-utc
The following procedures are required:
current-date
[tz-offset] -> date
current-julian-day
-> jdn
current-modified-julian-day
-> mjdn
current-time
[time-type] -> time
time-type
system, which defaults to TIME-UTC
.
time-resolution
[time-type] -> integer
time-type
system, which defaults to TIME-UTC
.
The following procedures are required:
make-time
type nanosecond second -> time
time?
object -> boolean
#t
if object is a time object, otherwise, #f
.
time-type
time -> time-type
time-nanosecond
time -> integer
time-second
time -> integer
set-time-type!
time time-type
set-time-nanosecond!
time integer
set-time-second!
time integer
copy-time
time1 -> time2
All of the time comparison procedures require the time objects to
be of the same type. It is an error to use these procedures on time
objects of different types. For the point-in-time measurements (e.g.,
TIME-TAI
and TIME-UTC
), the semantics are
described in plain text. For durations, (e.g.,
TIME-DURATION
, TIME-CPU
, the semantics are
described in parentheses.
The following procedures are required:
time<=?
time1 time2 -> boolean
#t
if time1 is before or at (less than or equal to) time2, #f
otherwise.
time<?
time1 time2 -> boolean
#t
if time1 is before (less than) time2, #f
otherwise.
time=?
time1 time2 -> boolean
#t
if time1 at (equal) time2, #f
otherwise.
time>=?
time1 time2 -> boolean
#t
if time1 is at or after (greater than or equal to) time2, #f
otherwise.
time>?
time1 time2 -> boolean
#t
if time1 is after (greater than) time2, #f
otherwise.
The following procedures are required.
time-difference
time1 time2 -> time-duration
TIME-DURATION
between time1 and time2. It is an error if time1 and time2 are of different time types. A new time object is created.
time-difference!
time1 time2 -> time-duration
TIME-DURATION
between time1 and time2. It is an error if time1 and time2 are of different time types. Time1 may be used to create the resulting TIME-DURATION
object.
add-duration
time1 time-duration -> time
add-duration!
time1 time-duration -> time
subtract-duration
time1 time-duration -> time
subtract-duration!
time1 time-duration -> time
Date objects are immutable once created. The following procedures are required.
make-date
nanosecond second minute hour day month year zone-offset -> date
date?
date -> boolean
#t
if object is a time object, otherwise, #f
.
date-nanosecond
date -> integer
date-second
date -> integer
date-minute
date -> integer
date-hour
date -> integer
date-day
date -> integer
date-month
date -> integer
date-year
date -> integer
date-zone-offset
date -> integer
date-year-day
date -> integer
date-week-day
date -> integer
date-week-number
date day-of-week-starting-week -> integer
date->julian-day
date -> jd
date->modified-julian-day
date -> mjd
date->time-monotonic
date -> time-monotonic
date->time-tai
date -> time-tai
date->time-utc
date -> time-utc
julian-day->date
jd [tz-offset] -> date
julian-day->time-monotonic
jd -> time-monotonic
julian-day->time-tai
jd -> time-tai
julian-day->time-utc
jd -> time-utc
modified-julian-day->date
mjd [tz-offset] -> date
modified-julian-day->time-monotonic
mjd -> time-monotonic
modified-julian-day->time-tai
mjd -> time-tai
modified-julian-day->time-utc
mjd -> time-utc
time-monotonic->date
time-monotonic [tz-offset] -> date
time-monotonic->julian-day
time-monotonic -> jd
time-monotonic->modified-julian-day
time-monotonic -> mjd
time-monotonic->time-tai
time-monotonic -> time-tai
time-monotonic->time-tai!
time-monotonic -> time-tai
time-monotonic->time-utc
time-monotonic -> time-utc
time-monotonic->time-utc!
time-monotonic -> time-utc
time-tai->date
time-tai [tz-offset] -> date
time-tai->julian-day
time-tai -> jd
time-tai->modified-julian-day
time-tai -> mjd
time-tai->time-monotonic
time-tai -> time-monotonic
time-tai->time-monotonic!
time-tai -> time-monotonic
time-tai->time-utc
time-tai -> time-utc
time-tai->time-utc!
time-tai -> time-utc
time-utc->date
time-utc [tz-offset] -> time-utc
time-utc->julian-day
time-utc -> jd
time-utc->modified-julian-day
time-utc -> mjd
time-utc->time-monotonic
time-utc -> time-monotonic
time-utc->time-monotonic!
time-utc -> time-monotonic
time-utc->time-tai
time-utc -> time-tai
time-utc->time-tai!
time-utc -> time-tai
date->string
date [format-string] -> string
string->date
input-string template-string -> date
Ch | Conversion |
---|---|
~~ | a literal ~ |
~a | locale's abbreviated weekday name (Sun...Sat) |
~A | locale's full weekday name (Sunday...Saturday) |
~b | locale's abbreviate month name (Jan...Dec) |
~B | locale's full month day (January...December) |
~c | locale's date and time (e.g., "Fri Jul 14 20:28:42-0400 2000") |
~d | day of month, zero padded (01...31) |
~D | date (mm/dd/yy) |
~e | day of month, blank padded ( 1...31) |
~f | seconds+fractional seconds, using locale's decimal separator (e.g. 5.2). |
~h | same as ~b |
~H | hour, zero padded, 24-hour clock (00...23) |
~I | hour, zero padded, 12-hour clock (01...12) |
~j | day of year, zero padded |
~k | hour, blank padded, 24-hour clock (00...23) |
~l | hour, blank padded, 12-hour clock (01...12) |
~m | month, zero padded (01...12) |
~M | minute, zero padded (00...59) |
~n | new line |
~N | nanosecond, zero padded |
~p | locale's AM or PM |
~r | time, 12 hour clock, same as "~I:~M:~S ~p" |
~s | number of full seconds since "the epoch" (in UTC) |
~S | second, zero padded (00...60) |
~t | horizontal tab |
~T | time, 24 hour clock, same as "~H:~M:~S" |
~U | week number of year with Sunday as first day of week (00...53) |
~V | week number of year with Monday as first day of week (01...52) |
~w | day of week (0...6) |
~W | week number of year with Monday as first day of week (01...52) |
~x | week number of year with Monday as first day of week (00...53) |
~X | locale's date representation, for example: "07/31/00" |
~y | last two digits of year (00...99) |
~Y | year |
~z | time zone in RFC-822 style |
~Z | symbol time zone (not-implemented) |
~1 | ISO-8601 year-month-day format |
~2 | ISO-8601 hour-minute-second-timezone format |
~3 | ISO-8601 hour-minute-second format |
~4 | ISO-8601 year-month-day-hour-minute-second-timezone format |
~5 | ISO-8601 year-month-day-hour-minute-second format |
Table 1: DATE->STRING conversion specifiers | |
Ch | Skip to | Read | Set |
---|---|---|---|
~~ | any | read literal ~ | nothing |
~a | char-alphabetic? | abbreviated weekday in locale | nothing |
~A | char-alphabetic? | full weekday in locale | nothing |
~b | char-alphabetic? | abbreviated month name in locale | nothing |
~B | char-alphabetic? | full month name in locale | nothing |
~d | char-numeric? | day of month | date-day |
~e | any | day of month, blank padded | date-day |
~h | char-alphabetic? | same as ~b | nothing |
~H | char-numeric? | hour | date-hour |
~k | any | hour, blank padded | date-hour |
~m | char-numeric? | month | date-month |
~M | char-numeric? | minute | date-minute |
~S | char-numeric? | second | date-second |
~y | any | 2-digit year | date-year within 50 years |
~Y | char-numeric? | year | date-year |
~z | any | time zone | date-zone-offset |
Table 2: STRING->DATE conversion specifiers | |||
CURRENT-TIME
. The GNU C function,
gettimeofday
might prove useful to implementors.
The difference between TAI and UTC is not determinate, and implementations must provide some method for getting TAI. A procedure is provided in the accompany implmentation for reading the leap second table provided by the Time Service of the US Naval Observatory (available at ftp://maia.usno.navy.mil/ser7/tai-utc.dat).
The accompanying implementation assumes SRFI 6 Basic String Ports.
The accompanying implementation also assumes an error
procedure. The accompanying implementation also assumes SRFI 8 RECEIVE: Binding to
multiple values. which is easy to implement with the following
syntax:
(define-syntax receive
(syntax-rules ()
((receive formals expression body ...)
(call-with-values (lambda () expression)
(lambda formals body ...)))))
Note that it contains TAI-UTC.DAT reader.
The accompanying
implementation is written in MzScheme. MzScheme provides the procedure
current-seconds
, which returns the number of seconds (UTC)
since 1970-01-01T00:00:00Z+00:00, and
current-milliseconds
, which is a monotonic time
clock. Combining these provides an implementation of
(current-time time-utc)
. Monontonic time, in this
implementation, is the same as TAI time; differences between TAI and
UTC are resolved through a leap second table. According to the
International Earth Rotation Service, there will be no leap second in
December, 2000. Thus, the leap second table is guaranteed to be
correct through June, 2000.
Also, MzScheme (as of version 102, I believe) provides a method for returning the current time zone offset, via its SECONDS->DATE and CURRENT-DATE procedures.
MzScheme's DEFINE-STRUCT
was used to define the time
and date objects. SRFI 9, Defining Record
Types, could be used instead.
Procedures meant to be used internally have names beginning with
TM:
. Locale-related constants and procedures have
locale
in their name; if a 'locale' SRFI is ever written,
it might be good to use that code instead.
From this, the rest of the implementation was built.
There is also a test suite.
Mike Sperber, Marc Feely, Dave Mason, and "Prfnoff" all made useful comments on previous versions of this draft. Thanks to Shriram Krishnamurthi for his editing help.
The DATE->STRING
procedure uses a format string, based on
GNU C's date
procedure, as well as scsh
's
FORMAT-DATE
procedure.
Copyright (C) Neodesic Corporation (2000). All Rights Reserved.
Permission is hereby granted, free of charge, to any person obtaining a copy of this software and associated documentation files (the "Software"), to deal in the Software without restriction, including without limitation the rights to use, copy, modify, merge, publish, distribute, sublicense, and/or sell copies of the Software, and to permit persons to whom the Software is furnished to do so, subject to the following conditions:
The above copyright notice and this permission notice shall be included in all copies or substantial portions of the Software.
THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
(display (date->string (current-date 0)
"~4"))
: 2004-03-15T02:21:15Z