Library
Module
Module type
Parameter
Class
Class type
Date time reasoning
Timere provides a set of highly expressive APIs to describe scheduling constraints, and an efficient resolution algorithm
type timestamp = Timedesc.timestamp
This is the core type of Timere that represents sets of points in time, more precisely, unions of time intervals. For example, "all Mondays of year 2000 at the UTC timezone".
We call Timere.t
values "timere object"; internally they are rich expressions representing the time computations (union, intersection, etc.), lazily forced into more low-level descriptions (lazy sequences of intervals).
val now : unit -> t
Time right now
val always : t
Entire interval that Timere can handle, i.e. [0000 Jan 01 14:00:00 +00:00:00, 9999 Dec 31 09:59:58 +00:00:00)
val empty : t
Empty interval
val before : Timedesc.t -> t
val since : Timedesc.t -> t
val after : Timedesc.t -> t
val date_time : Timedesc.t -> t
val date_times : Timedesc.t list -> t
val date_time_seq : Timedesc.t Seq.t -> t
val sorted_date_times : Timedesc.t list -> t
val sorted_date_time_seq : Timedesc.t Seq.t -> t
val timestamp : Timedesc.timestamp -> t
val before_timestamp : Timedesc.timestamp -> t
val since_timestamp : Timedesc.timestamp -> t
val after_timestamp : Timedesc.timestamp -> t
val timestamps : ?skip_invalid:bool -> Timedesc.timestamp list -> t
timestamps l
skip_invalid
defaults to false
timestamps s
skip_invalid
defaults to false
val pattern :
?years:int list ->
?year_ranges:int range list ->
?months:int list ->
?month_ranges:int range list ->
?days:int list ->
?day_ranges:int range list ->
?weekdays:Timedesc.weekday list ->
?weekday_ranges:Timedesc.weekday range list ->
?hours:int list ->
?hour_ranges:int range list ->
?minutes:int list ->
?minute_ranges:int range list ->
?seconds:int list ->
?second_ranges:int range list ->
?ns:int list ->
?ns_ranges:int range list ->
unit ->
t
Pattern matches over date times.
A pattern p
matches date time dt
if
(year of dt is in p.years or p.year_ranges) && (month of dt is in p.months or p.month_ranges) && (month day of dt is in p.month_days or p.month_day_ranges) && (weekday of dt is in p.weekdays or p.weekday_ranges) && (hour of dt is in p.hours or p.hour_ranges) && (minute of dt is in p.minutes or p.minute_ranges) && (second of dt is in p.seconds or p.second_ranges) && (ns of dt is in p.ns or p.ns_ranges)
Empty pattern levels are treated as wildcard, e.g. if p.years
and p.year_ranges
are both empty, then (dt.year is in p.years or p.year_ranges)
is true
.
val years : int list -> t
years l
is a shorthand for pattern ~years:l ()
val months : int list -> t
months l
is a shorthand for pattern ~months:l ()
val days : int list -> t
days l
is a shorthand for pattern ~month_days:l ()
val weekdays : Timedesc.weekday list -> t
weekdays l
is a shorthand for pattern ~weekdays:l ()
val weekday_ranges : Timedesc.weekday range list -> t
weekday_ranges l
is a shorthand for pattern ~weekday_ranges:l ()
val hours : int list -> t
hours l
is a shorthand for pattern ~hours:l ()
val minutes : int list -> t
minutes l
is a shorthand for pattern ~minutes:l ()
minute_ranges l
is a shorthand for pattern ~minute_ranges:l ()
val seconds : int list -> t
seconds l
is a shorthand for pattern ~seconds:l ()
second_ranges l
is a shorthand for pattern ~second_ranges:l ()
val ns : int list -> t
ns l
is a shorthand for pattern ~ns:l ()
val nth_weekday_of_month : int -> Timedesc.weekday -> t
nth_weekday_of_month n wday
picks the nth weekday of all months, where 1 <= n && n <= 5
val intervals : ?skip_invalid:bool -> Timedesc.Interval.t list -> t
intervals l
skip_invalid
defaults to false
val interval_seq : ?skip_invalid:bool -> Timedesc.Interval.t Seq.t -> t
interval_seq s
skip_invalid
defaults to false
val sorted_intervals : ?skip_invalid:bool -> Timedesc.Interval.t list -> t
sorted_intervals l
skip_invalid
defaults to false
val sorted_interval_seq : ?skip_invalid:bool -> Timedesc.Interval.t Seq.t -> t
sorted_interval_seq s
skip_invalid
defaults to false
Pattern matching intervals are designed to handle intervals where start and end points follow some pattern, but cannot be captured by pattern
efficiently, e.g. you cannot represent "5:30pm to 6:11pm" via a single pattern
module Points : sig ... end
type points = Points.t
val pattern_intervals :
?inc_exc:inc_exc ->
?bound:Timedesc.Span.t ->
[ `Whole | `Fst | `Snd ] ->
points ->
points ->
t
pattern_intervals mode p1 p2
for each point x
matched by p1
, then for the earliest point y
matched by p2
such that x < y && y - x <= bound
mode = `Whole && inc_exc = `Exc
, yields (x, y)mode = `Whole && inc_exc = `Inc
, yields (x, y + 1)mode = `Fst
, yields (x, x + 1)mode = `Snd
, yields (y, y + 1)above implies inc_exc
does not impact operations if mode is `Fst
or `Snd
.
inc_exc
defaults to `Exc
.
Default bound
is inferred as follows, and should suffice in yielding desired results for most cases:
if p2 is YMDHMS then (year of p2 - year of p1 + 1) * 366 days if p2 is MDHMS then 366 days if p2 is DHMS then if day of p1 < day of p2 then 31 - day of p2 days else 31 days if p2 is HMS then 30 hours if p2 is MS then 1 hours if p2 is S then 1 minutes
where we say p2 is YMDHMS
if p2 = Points.make_exn ~year:_ ... ()
and so on.
Examples:
pattern_intervals `Whole
(Points.make ~hour:13 ~minute:0 ~second:0 ()) (* p1 *)
(Points.make ~hour:14 ~minute:0 ~second:0 ()) (* p2 *)
yields all the "1pm to 2pm" intervals, since at each "1pm" mark represented by p1
, searching forward up to 24 hour period, we can find a "2pm" mark in p2
pattern_intervals `Whole
(Points.make ~month:2 ~day:10 ~hour:13 ~minute:0 ~second:0 ()) (* p1 *)
(Points.make ~hour:14 ~minute:0 ~second:0 ()) (* p2 *)
yields all the "Feb 10th 1pm to 2pm" intervals (or specifically "Feb 10th 1pm to Feb 10th 2pm")
pattern_intervals `Whole
(Points.make ~month:`Feb ~day:10 ~hour:23 ~minute:0 ~second:0 ()) (* p1 *)
(Points.make ~hour:3 ~minute:0 ~second:0 ()) (* p2 *)
yields all the "Feb 10th 11pm to 3am" intervals (or specifically "Feb 10th 11pm to Feb 11th 3am")
Convenience wrappers around points
and pattern_intervals
val hms_intervals : ?inc_exc:inc_exc -> Timedesc.Time.t -> Timedesc.Time.t -> t
Same as pattern_intervals ...
with bound fixed to Span.For_human.make ~days:1 ()
inc_exc
defaults to `Exc
val shift : Timedesc.Span.t -> t -> t
val lengthen : Timedesc.Span.t -> t -> t
val with_tz : Timedesc.Time_zone.t -> t -> t
with_tz tz t
changes the time zone to evaluate t
in to tz
type chunking = [
| `Disjoint_intervals
| `By_duration of Timedesc.Span.t
| `By_duration_drop_partial of Timedesc.Span.t
| `At_year_boundary
| `At_month_boundary
]
Ways to chunk/slice time intervals for the selector.
`Disjoint_intervals
gives a sequence of disjoint intervals to the selector, specifically they are in ascending order, non-overlapping, non-connecting, and unique`By_duration
slices in the fixed size specified by the duration. Partial chunks (chunks less than the fixed size) are preserved.`By_duration_drop_partial
slices in the fixed size specified by the duration. Partial chunks (chunks less than the fixed size) are discarded.`At_year_boundary
slices at the year boundary (e.g. 2021 Jan 1st 00:00:00
)`At_month_boundary
slices at the month boundary (e.g. Aug 1st 00:00:00
)chunk chunking f t
applies chunked
selector f
on t
.
You may find (%>)
useful for chaining selectors together, e.g. drop 5 %> take 2
chunk_again chunking f
applies chunked
selector f
as a selector
Take every nth chunk, specifically 0
th, n
th, 2n
th, 3n
th, ...
Composition, mainly for chunked selectors
f1 %> f2
is equivalent to fun x -> x |> f1 |> f2
.
val resolve :
?search_using_tz:Timedesc.Time_zone.t ->
t ->
(Timedesc.Interval.t Seq.t, string) result
Resolves a Timere object into a concrete interval sequence. * * Intervals are left-closed, right-open, i.e. each interval is * of the form [x, y)
, which includes x and excludes y. *
val resolve_exn :
?search_using_tz:Timedesc.Time_zone.t ->
t ->
Timedesc.Interval.t Seq.t
These functions are suitable for debugging, serializing and deserializing timeres.
The sexp is a precise description of the steps used to construct a timere. As such deserialization is accurate and goes through the exact same construction steps (including validation) as one would using the construction API directly.
val to_sexp : t -> Sexplib.Sexp.t
val to_sexp_string : t -> string
val of_sexp : Sexplib.Sexp.t -> (t, string) result
val pp_sexp : Format.formatter -> t -> unit
module Utils : sig ... end