Library
Module
Module type
Parameter
Class
Class type
POSIX time values.
Ptime
has platform independent support for POSIX time. It provides a type to represent a well-defined range of POSIX timestamps with picosecond precision, conversion with date-time values, conversion with RFC 3339 timestamps and pretty printing to a human-readable, locale-independent representation.
Ptime_clock
provides access to a system POSIX clock and the system's current time zone offset. Ptime
is not a calendar library.
Consult the basics and a few notes and limitations.
References
v0.8.5 - homepage
The type for signed picosecond precision POSIX time spans. A value of this type represent the POSIX duration between two POSIX timestamps.
module Span : sig ... end
POSIX time spans.
val v : (int * int64) -> t
v s
is of_span (Span.v s)
but
val epoch : t
epoch
is 1970-01-01 00:00:00 UTC.
val max : t
max
is 9999-12-31 23:59:59.999999999999 UTC, the latest timestamp representable by Ptime
.
val of_float_s : float -> t option
of_float_s d
is like of_span
but with d
as a floating point second POSIX span d
. This function is compatible with the result of Unix.gettimeofday
. Decimal fractional seconds beyond 1e-12
are truncated.
val to_float_s : t -> float
to_float_s t
is like to_span
but returns a floating point second POSIX span.
Warning. Due to floating point inaccuracies do not expect the function to round trip with of_float_s
; especially near Ptime.min
and Ptime.max
.
truncate ~frac_s t
is t
truncated to the frac_s
decimal fractional second. Effectively this reduces precision without rounding, the timestamp remains in the second it is in. frac_s
is clipped to the range [0
;12
].
compare t t'
is a total order on timestamps that is compatible with timeline order.
WARNING. A POSIX time span is not equal to an SI second based time span, see the basics. Do not use these functions to perform calendar arithmetic or measure wall-clock durations, you will fail.
diff t t'
is the signed POSIX span t - t'
that happens between the timestamps t
and t'
.
The type for time zone offsets between local and UTC timelines in seconds. This is the signed difference in seconds between the local timeline and the UTC timeline:
tz_offset_s = local - UTC
-3600
means that the local timeline is sixty minutes behind the UTC timeline.3600
means that the local timeline is sixty minutes ahead the UTC timeline.A date-time represents a point on the UTC timeline by pairing a date in the proleptic Gregorian calendar and a second precision daytime in a local timeline with stated relationship to the UTC timeline.
The type for big-endian proleptic Gregorian dates. A triple (y, m, d)
with:
y
the year from 0
to 9999
. 0
denotes -1 BCE (this follows the ISO 8601 convention).m
is the month from 1
to 12
d
is the day from 1
to 28
, 29
, 30
or 31
depending on m
and y
A date is said to be valid iff the values (y, m, d)
are in the range mentioned above and represent an existing date in the proleptic Gregorian calendar.
type time = (int * int * int) * tz_offset_s
The type for daytimes on a local timeline. Pairs a triple (hh,
mm, ss)
denoting the time on the local timeline and a tz_offset
stating the relationship of the local timeline to the UTC timeline.
The (hh, mm, ss)
components are understood and constrainted as follows:
hh
is the hour from 0
to 23
.mm
is the minute from 0
to 59
.ss
is the seconds from 0
to 60
. 60
may happen whenever a leap second is added.A time
value is said to be valid iff the values (hh, mm, ss)
are in the ranges mentioned above.
of_date_time dt
is the POSIX timestamp corresponding to date-time dt
or None
if dt
has an invalid date, invalid time or the date-time is not in the range [min
;max
].
Leap seconds. Any date-time with a seconds value of 60
, hence representing a leap second addition, is mapped to the date-time that happens 1 second later. Any date-time with a seconds value of 59
is mapped to the POSIX timestamp that represents this instant, if a leap second was subtracted at that point, this is the POSIX timestamp that represents this inexisting instant. See the basics.
val to_date_time : ?tz_offset_s:tz_offset_s -> t -> date * time
to_date_time ~tz_offset_s t
is the date-time of the timestamp t
.
tz_offset_s
hints the time zone offset used for the resulting daytime component (defaults to 0
, i.e. UTC). The offset is not honoured and fallbacks to 0
in case the resulting date-time rendering of the timestamp would yield an invalid date. This means that you should always interpret the resulting time component with the time zone offset it is paired with in the result and not assume it will be the one you gave to the function. Note that for real-world time zone offsets the fallback to 0
will only happen around Ptime.min
and Ptime.max
. Formally the fallback occurs whenever add_span t (Span.of_int_s
tz_offset_s)
is None
.
Leap seconds. No POSIX timestamp can represent a date-time with a leap second added, hence this function will never return a date-time with a 60
seconds value. This function does return inexisting UTC date-times with 59
seconds whenever a leap second is subtracted since POSIX timestamps do represent them. See the basics.
Subsecond precision. POSIX timestamps with subsecond precision are floored, i.e. the date-time always has the second mentioned in the timestamp.
val weekday :
?tz_offset_s:tz_offset_s ->
t ->
[ `Mon | `Tue | `Wed | `Thu | `Fri | `Sat | `Sun ]
weekday ~tz_offset_s t
is the day in the 7-day week of timestamp t
expressed in the time zone offset ts_offset_s
(defaults to 0
).
This can be used with the time zone offset result of to_date_time
to convert timestamps to denormalized timestamp formats.
val pp_rfc3339_error : Stdlib.Format.formatter -> rfc3339_error -> unit
pp_rfc3339_error ppf e
prints an unspecified representation of e
on ppf
.
val rfc3339_error_to_msg :
('a, [ `RFC3339 of error_range * rfc3339_error ]) Result.result ->
('a, [> `Msg of string ]) Result.result
rfc3339_error_to_msg r
converts RFC 3339 parse errors to error messages.
val of_rfc3339 :
?strict:bool ->
?sub:bool ->
?start:int ->
string ->
(t * tz_offset_s option * int, [> `RFC3339 of error_range * rfc3339_error ])
Result.result
of_rfc3339 ~strict ~sub ~start s
parses an RFC 3339 date-time
starting at start
(defaults to 0
) in s
to a triple (t, tz, count)
with:
t
the POSIX timestamp (hence on the UTC timeline).tz
, the optional time zone offset found in the timestamp. None
is returned iff the date-time satisfies the unknown local offset convention.count
the number of bytes read starting at start
to parse the timestamp. If sub
is false
(default) this is always String.length s - start
and Error `Trailing_input
is returned if there are still bytes in s
after the date-time was parsed. Use ~sub:true
for allowing trailing input to exist.If strict
is true
(defaults to false
) the parsing function errors on timestamps with lowercase 'T'
or 'Z'
characters or space separated date and times.
Notes and limitations.
start
is not an index of s
, Error ((start, start), `Eoi)
is returned.0000-01-01T00:00:00+00:01
). The function errors on these timestamps with `Invalid_stamp
as they cannot be represented in the range [min
;max
].of_date_time
1e-12
) are truncated.val to_rfc3339 :
?space:bool ->
?frac_s:int ->
?tz_offset_s:tz_offset_s ->
t ->
string
to_rfc3339_tz ~space ~frac_s ~tz_offset_s t
formats the timestamp t
according to a RFC 3339 date-time
production with:
tz_offset_s
hints the time zone offset to use, use 0
for UTC. The hint is ignored in the following cases: if tz_offset_s
is not an integral number of minutes and its magnitude not in the range permitted by the standard, if add_span t (Span.of_int_s tz_offset_s)
is None
(the resulting timestamp rendering would not be RFC 3339 compliant). If either the hint is ignored or tz_offset_s
is unspecified then the unknown local offset convention is used to render the time zone component.frac_s
, clipped to the range [0
;12
] specifies that exactly frac_s
decimal digits of the fractional second of t
are rendered (defaults to 0
).space
if true
the date and time separator is a space rather than a 'T'
(not recommended but may be allowed by the protocol you are dealing with, defaults to false
).val pp_rfc3339 :
?space:bool ->
?frac_s:int ->
?tz_offset_s:tz_offset_s ->
unit ->
Stdlib.Format.formatter ->
t ->
unit
pp_rfc3339 ?space ?frac_s ?tz_offset_s () ppf t
is Format.fprintf ppf "%s" (to_rfc3339 ?space ?frac_s ?tz_offset_s t)
.
val pp_human :
?frac_s:int ->
?tz_offset_s:tz_offset_s ->
unit ->
Stdlib.Format.formatter ->
t ->
unit
pp_human ~frac_s ~tz_offset_s () ppf t
prints an unspecified, human readable, locale-independent, representation of t
with:
tz_offset_s
hints the time zone offset to use. The hint is ignored in the following cases: if tz_offset_s
is not an integral number of minutes and its magnitude not in the range permitted by the standard, if add_span t (Span.of_int_s tz_offset_s)
is None
. If either the hint is ignored or tz_offset_s
is unspecified then RFC 3339's unknown local offset convention is used to render the time zone component.frac_s
clipped to the range [0
;12
] specifies that exactly frac_s
decimal digits of the fractional second of t
are rendered (defaults to 0
).Note. The output of this function is similar to but not compliant with RFC 3339, it should only be used for presentation, not as a serialization format.
val pp : Stdlib.Format.formatter -> t -> unit
pp
is pp_human ~tz_offset_s:0
.
val dump : Stdlib.Format.formatter -> t -> unit
dump ppf t
prints an unspecified raw representation of t
on ppf
.
POSIX time counts POSIX seconds since the epoch 1970-01-01 00:00:00 UTC. As such a POSIX timestamp is always on the UTC timeline.
POSIX time doesn't count leap seconds, so by definition it cannot represent them. One way of viewing this is that whenever a leap second is added a POSIX second lasts two SI seconds and whenever a leap second is subtracted a POSIX second lasts zero SI second.
Ptime
does not provide any mean to convert the duration between two POSIX timestamps to SI seconds. The reason is that in order to accurately find this number, a leap second table is needed. However since this table may change every six months, Ptime
decides not to include it so as not to potentially become incorrect every six months.
This decision has the following implications. First it should be realised that the durations mentioned by the add_span
, sub_span
and diff
functions are expressed in POSIX seconds which may represent zero, one, or two SI seconds. For example if we add 1 second with add_span
to the POSIX timestamp for 1998-12-31 23:59:59 UTC, what we get is the timestamp for 1999-01-01 00:00:00 UTC:
let get = function None -> assert false | Some v -> v
let utc d t = get @@ Ptime.of_date_time (d, (t, 0))
let t0 = utc (1998, 12, 31) (23, 59, 59)
let t1 = utc (1999, 01, 01) (00, 00, 00)
let one_s = Ptime.Span.of_int_s 1
let () = assert (Ptime.equal (get @@ Ptime.add_span t0 one_s) t1)
However since the leap second 1998-12-31 23:59:60 UTC exists, two actual SI seconds elapsed between t0
and t1
. Now if we use diff
to find the POSIX duration that elapsed between t0
and t1
we get one POSIX second:
let () = assert (Ptime.Span.equal (Ptime.diff t1 t0) one_s)
But still, two SI seconds elapsed between these two points in time. Note also that no value of type t
can represent the UTC timetamp 1998-12-31 23:59:60 and hence Ptime.to_date_time
will never return a date-time with a seconds value of 60
. In fact both 1998-12-31 23:59:60 UTC and 1999-01-01 00:00:00 UTC are represented by the same timestamp:
let t2 = utc (1998, 12, 31) (23, 59, 60)
let () = assert (Ptime.equal t1 t2)
This is true of any added leap second, we map it on the first second of the next minute, thus matching the behaviour of POSIX's mktime function.
If a leap second is subtracted on a day the following occurs – 2015, as of writing this never happened. Let YYYY-06-30 23:59:58 be the instant a leap second is subtracted, this means that the next UTC date-time, one SI second later, is YYYY-07-01 00:00:00. However if we diff the two instants:
let y = 9999 (* hypothetical year were this happens *)
let t0 = utc (y, 06, 30) (23, 59, 58)
let t1 = utc (y, 07, 01) (00, 00, 00)
let two_s = Ptime.Span.of_int_s 2
let () = assert (Ptime.Span.equal (Ptime.diff t1 t0) two_s)
We get two POSIX seconds, but only one SI second elapsed between these two points in time. It should also be noted that POSIX time will represent a point that never existed in time namely YYYY-06-30 23:59:59, the POSIX second with 0 SI second duration and that Ptime.to_date_time
will return a date-time value for this timestamp even though it never existed:
let t2 = utc (y, 06, 30) (23, 59, 59)
let () = assert (Ptime.equal (get @@ Ptime.add_span t0 one_s) t2)
The following points should be taken into account
Ptime
is not a calendar library and will never be.Ptime
can only represent picosecond precision timestamps in the range [Ptime.min
;Ptime.max
]. It is however able to convert any of these timestamps to a valid date-time or RFC 3339 timestamp.POSIX time in general is ill-suited to measure wall-clock time spans for the following reasons.
Ptime
offers no mechanism to determine the SI duration between two timestamps, see the basics.Mtime
).